From 35f5c9ced443ea6a231be48956bbc0bdbbd8020e Mon Sep 17 00:00:00 2001 From: Arun Raghavan Date: Thu, 15 Sep 2011 08:08:41 +0530 Subject: Initial commit of source files --- AUTHORS | 7 + COPYING | 29 + ChangeLog | 0 NEWS | 0 PATENTS | 24 + src/common_audio/signal_processing_library/OWNERS | 3 + .../main/interface/signal_processing_library.h | 1672 +++++++++++++ .../main/interface/spl_inl.h | 166 ++ .../main/interface/spl_inl_armv7.h | 122 + .../main/source/auto_corr_to_refl_coef.c | 103 + .../main/source/auto_correlation.c | 141 ++ .../main/source/complex_bit_reverse.c | 51 + .../main/source/complex_fft.c | 150 ++ .../main/source/complex_ifft.c | 161 ++ .../main/source/copy_set_operations.c | 108 + .../main/source/cos_table.c | 60 + .../main/source/cross_correlation.c | 267 +++ .../main/source/division_operations.c | 144 ++ .../main/source/dot_product_with_scale.c | 91 + .../main/source/downsample_fast.c | 59 + .../signal_processing_library/main/source/energy.c | 36 + .../main/source/filter_ar.c | 89 + .../main/source/filter_ar_fast_q12.c | 49 + .../main/source/filter_ma_fast_q12.c | 49 + .../main/source/get_hanning_window.c | 41 + .../main/source/get_scaling_square.c | 44 + .../main/source/hanning_table.c | 53 + .../main/source/ilbc_specific_functions.c | 120 + .../main/source/levinson_durbin.c | 259 ++ .../main/source/lpc_to_refl_coef.c | 57 + .../main/source/min_max_operations.c | 265 +++ .../main/source/min_max_operations_neon.c | 47 + .../main/source/randn_table.c | 85 + .../main/source/randomization_functions.c | 52 + .../main/source/refl_coef_to_lpc.c | 60 + .../main/source/resample.c | 505 ++++ .../main/source/resample_48khz.c | 186 ++ .../main/source/resample_by_2.c | 170 ++ .../main/source/resample_by_2_internal.c | 679 ++++++ .../main/source/resample_by_2_internal.h | 47 + .../main/source/resample_fractional.c | 242 ++ .../main/source/sin_table.c | 60 + .../main/source/sin_table_1024.c | 150 ++ .../signal_processing_library/main/source/spl.gypi | 73 + .../main/source/spl_sqrt.c | 184 ++ .../main/source/spl_sqrt_floor.c | 53 + .../main/source/spl_version.c | 25 + .../main/source/splitting_filter.c | 200 ++ .../main/source/sqrt_of_one_minus_x_squared.c | 35 + .../main/source/vector_scaling_operations.c | 151 ++ .../main/source/webrtc_fft_t_1024_8.c | 704 ++++++ .../main/source/webrtc_fft_t_rad.c | 27 + .../main/test/unit_test/unit_test.cc | 494 ++++ .../main/test/unit_test/unit_test.h | 30 + src/common_audio/vad/OWNERS | 2 + src/common_audio/vad/main/interface/webrtc_vad.h | 159 ++ src/common_audio/vad/main/source/vad.gypi | 48 + src/common_audio/vad/main/source/vad_const.c | 80 + src/common_audio/vad/main/source/vad_const.h | 59 + src/common_audio/vad/main/source/vad_core.c | 685 ++++++ src/common_audio/vad/main/source/vad_core.h | 132 ++ src/common_audio/vad/main/source/vad_defines.h | 95 + src/common_audio/vad/main/source/vad_filterbank.c | 267 +++ src/common_audio/vad/main/source/vad_filterbank.h | 143 ++ src/common_audio/vad/main/source/vad_gmm.c | 70 + src/common_audio/vad/main/source/vad_gmm.h | 47 + src/common_audio/vad/main/source/vad_sp.c | 231 ++ src/common_audio/vad/main/source/vad_sp.h | 60 + src/common_audio/vad/main/source/webrtc_vad.c | 197 ++ .../vad/main/test/unit_test/unit_test.cc | 123 + .../vad/main/test/unit_test/unit_test.h | 28 + src/common_types.h | 595 +++++ src/modules/audio_processing/OWNERS | 2 + .../aec/main/interface/echo_cancellation.h | 260 ++ .../audio_processing/aec/main/matlab/fullaec.m | 953 ++++++++ .../audio_processing/aec/main/source/aec.gypi | 46 + .../audio_processing/aec/main/source/aec_core.c | 1430 +++++++++++ .../audio_processing/aec/main/source/aec_core.h | 176 ++ .../aec/main/source/aec_core_sse2.c | 429 ++++ .../audio_processing/aec/main/source/aec_rdft.c | 587 +++++ .../audio_processing/aec/main/source/aec_rdft.h | 49 + .../aec/main/source/aec_rdft_sse2.c | 397 ++++ .../aec/main/source/echo_cancellation.c | 824 +++++++ .../audio_processing/aec/main/source/resampler.c | 233 ++ .../audio_processing/aec/main/source/resampler.h | 32 + .../aecm/main/interface/echo_control_mobile.h | 250 ++ .../audio_processing/aecm/main/matlab/compsup.m | 447 ++++ .../aecm/main/matlab/getBspectrum.m | 22 + .../audio_processing/aecm/main/matlab/hisser2.m | 21 + .../audio_processing/aecm/main/matlab/main2.m | 19 + .../aecm/main/matlab/matlab/AECMobile.m | 269 +++ .../aecm/main/matlab/matlab/align.m | 98 + .../aecm/main/matlab/matlab/calcFilterGain.m | 88 + .../aecm/main/matlab/matlab/calcStepSize.m | 105 + .../aecm/main/matlab/matlab/fallerEstimator.m | 42 + .../aecm/main/matlab/matlab/getBspectrum.m | 22 + .../aecm/main/matlab/matlab/hisser2.m | 21 + .../aecm/main/matlab/matlab/mainProgram.m | 283 +++ .../aecm/main/matlab/matlab/simEnvironment.m | 15 + .../aecm/main/matlab/matlab/updateSettings.m | 94 + .../audio_processing/aecm/main/matlab/waitbar_j.m | 234 ++ .../audio_processing/aecm/main/source/aecm.gypi | 42 + .../audio_processing/aecm/main/source/aecm_core.c | 1926 +++++++++++++++ .../audio_processing/aecm/main/source/aecm_core.h | 358 +++ .../aecm/main/source/aecm_core_neon.c | 314 +++ .../aecm/main/source/aecm_delay_estimator.c | 604 +++++ .../aecm/main/source/aecm_delay_estimator.h | 112 + .../aecm/main/source/echo_control_mobile.c | 800 +++++++ .../agc/main/interface/gain_control.h | 273 +++ .../audio_processing/agc/main/matlab/getGains.m | 32 + .../audio_processing/agc/main/source/agc.gypi | 40 + .../audio_processing/agc/main/source/analog_agc.c | 1709 ++++++++++++++ .../audio_processing/agc/main/source/analog_agc.h | 133 ++ .../audio_processing/agc/main/source/digital_agc.c | 786 ++++++ .../audio_processing/agc/main/source/digital_agc.h | 76 + src/modules/audio_processing/main/apm_tests.gypi | 107 + .../main/interface/audio_processing.h | 586 +++++ src/modules/audio_processing/main/source/apm.gypi | 136 ++ .../audio_processing/main/source/audio_buffer.cc | 278 +++ .../audio_processing/main/source/audio_buffer.h | 68 + .../main/source/audio_processing_impl.cc | 651 +++++ .../main/source/audio_processing_impl.h | 117 + .../audio_processing/main/source/debug.proto | 37 + .../main/source/echo_cancellation_impl.cc | 348 +++ .../main/source/echo_cancellation_impl.h | 72 + .../main/source/echo_control_mobile_impl.cc | 309 +++ .../main/source/echo_control_mobile_impl.h | 62 + .../main/source/gain_control_impl.cc | 391 +++ .../main/source/gain_control_impl.h | 80 + .../main/source/high_pass_filter_impl.cc | 180 ++ .../main/source/high_pass_filter_impl.h | 51 + .../main/source/level_estimator_impl.cc | 182 ++ .../main/source/level_estimator_impl.h | 53 + .../main/source/noise_suppression_impl.cc | 179 ++ .../main/source/noise_suppression_impl.h | 54 + .../main/source/processing_component.cc | 112 + .../main/source/processing_component.h | 63 + .../main/source/splitting_filter.cc | 33 + .../main/source/splitting_filter.h | 63 + .../main/source/voice_detection_impl.cc | 202 ++ .../main/source/voice_detection_impl.h | 63 + .../main/test/android/apmtest/AndroidManifest.xml | 30 + .../main/test/android/apmtest/default.properties | 11 + .../main/test/android/apmtest/jni/Application.mk | 1 + .../main/test/android/apmtest/jni/main.c | 307 +++ .../test/android/apmtest/res/values/strings.xml | 4 + .../main/test/process_test/apmtest.m | 355 +++ .../main/test/process_test/process_test.cc | 897 +++++++ .../main/test/unit_test/unit_test.cc | 1008 ++++++++ .../main/test/unit_test/unittest.proto | 43 + .../ns/main/interface/noise_suppression.h | 124 + .../ns/main/interface/noise_suppression_x.h | 123 + .../audio_processing/ns/main/source/defines.h | 53 + .../ns/main/source/noise_suppression.c | 69 + .../ns/main/source/noise_suppression_x.c | 74 + .../audio_processing/ns/main/source/ns.gypi | 64 + .../audio_processing/ns/main/source/ns_core.c | 1500 ++++++++++++ .../audio_processing/ns/main/source/ns_core.h | 179 ++ .../audio_processing/ns/main/source/nsx_core.c | 2494 ++++++++++++++++++++ .../audio_processing/ns/main/source/nsx_core.h | 181 ++ .../ns/main/source/nsx_core_neon.c | 225 ++ .../audio_processing/ns/main/source/nsx_defines.h | 58 + .../ns/main/source/windows_private.h | 573 +++++ src/modules/audio_processing/utility/fft4g.c | 1356 +++++++++++ src/modules/audio_processing/utility/fft4g.h | 18 + src/modules/audio_processing/utility/ring_buffer.c | 239 ++ src/modules/audio_processing/utility/ring_buffer.h | 41 + src/modules/audio_processing/utility/util.gypi | 33 + src/modules/interface/module.h | 70 + src/modules/interface/module_common_types.h | 1029 ++++++++ src/system_wrappers/OWNERS | 7 + .../interface/cpu_features_wrapper.h | 34 + .../interface/critical_section_wrapper.h | 66 + src/system_wrappers/source/cpu_features.cc | 74 + src/system_wrappers/source/critical_section.cc | 27 + .../source/critical_section_posix.cc | 38 + .../source/critical_section_posix.h | 35 + .../source/critical_section_windows.cc | 35 + .../source/critical_section_windows.h | 36 + src/system_wrappers/source/system_wrappers.gyp | 167 ++ src/typedefs.h | 140 ++ 181 files changed, 42648 insertions(+) create mode 100644 AUTHORS create mode 100644 COPYING create mode 100644 ChangeLog create mode 100644 NEWS create mode 100644 PATENTS create mode 100644 src/common_audio/signal_processing_library/OWNERS create mode 100644 src/common_audio/signal_processing_library/main/interface/signal_processing_library.h create mode 100644 src/common_audio/signal_processing_library/main/interface/spl_inl.h create mode 100644 src/common_audio/signal_processing_library/main/interface/spl_inl_armv7.h create mode 100644 src/common_audio/signal_processing_library/main/source/auto_corr_to_refl_coef.c create mode 100644 src/common_audio/signal_processing_library/main/source/auto_correlation.c create mode 100644 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src/modules/audio_processing/utility/ring_buffer.h create mode 100644 src/modules/audio_processing/utility/util.gypi create mode 100644 src/modules/interface/module.h create mode 100644 src/modules/interface/module_common_types.h create mode 100644 src/system_wrappers/OWNERS create mode 100644 src/system_wrappers/interface/cpu_features_wrapper.h create mode 100644 src/system_wrappers/interface/critical_section_wrapper.h create mode 100644 src/system_wrappers/source/cpu_features.cc create mode 100644 src/system_wrappers/source/critical_section.cc create mode 100644 src/system_wrappers/source/critical_section_posix.cc create mode 100644 src/system_wrappers/source/critical_section_posix.h create mode 100644 src/system_wrappers/source/critical_section_windows.cc create mode 100644 src/system_wrappers/source/critical_section_windows.h create mode 100644 src/system_wrappers/source/system_wrappers.gyp create mode 100644 src/typedefs.h diff --git a/AUTHORS b/AUTHORS new file mode 100644 index 0000000..29d0e15 --- /dev/null +++ b/AUTHORS @@ -0,0 +1,7 @@ +# Names should be added to this file like so: +# Name or Organization + +Google Inc. + +# autofoo-based build system +Arun Raghavan diff --git a/COPYING b/COPYING new file mode 100644 index 0000000..da40b33 --- /dev/null +++ b/COPYING @@ -0,0 +1,29 @@ +Copyright (c) 2011, Google Inc. All rights reserved. + +Redistribution and use in source and binary forms, with or without +modification, are permitted provided that the following conditions are +met: + + * Redistributions of source code must retain the above copyright + notice, this list of conditions and the following disclaimer. + + * Redistributions in binary form must reproduce the above copyright + notice, this list of conditions and the following disclaimer in + the documentation and/or other materials provided with the + distribution. + + * Neither the name of Google nor the names of its contributors may + be used to endorse or promote products derived from this software + without specific prior written permission. + +THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS +"AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT +LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR +A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT +HOLDER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, +SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT +LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, +DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY +THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT +(INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE +OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. diff --git a/ChangeLog b/ChangeLog new file mode 100644 index 0000000..e69de29 diff --git a/NEWS b/NEWS new file mode 100644 index 0000000..e69de29 diff --git a/PATENTS b/PATENTS new file mode 100644 index 0000000..190607a --- /dev/null +++ b/PATENTS @@ -0,0 +1,24 @@ +Additional IP Rights Grant (Patents) + +"This implementation" means the copyrightable works distributed by +Google as part of the WebRTC code package. + +Google hereby grants to you a perpetual, worldwide, non-exclusive, +no-charge, irrevocable (except as stated in this section) patent +license to make, have made, use, offer to sell, sell, import, +transfer, and otherwise run, modify and propagate the contents of this +implementation of the WebRTC code package, where such license applies +only to those patent claims, both currently owned by Google and +acquired in the future, licensable by Google that are necessarily +infringed by this implementation of the WebRTC code package. This +grant does not include claims that would be infringed only as a +consequence of further modification of this implementation. If you or +your agent or exclusive licensee institute or order or agree to the +institution of patent litigation against any entity (including a +cross-claim or counterclaim in a lawsuit) alleging that this +implementation of the WebRTC code package or any code incorporated +within this implementation of the WebRTC code package constitutes +direct or contributory patent infringement, or inducement of patent +infringement, then any patent rights granted to you under this License +for this implementation of the WebRTC code package shall terminate as +of the date such litigation is filed. diff --git a/src/common_audio/signal_processing_library/OWNERS b/src/common_audio/signal_processing_library/OWNERS new file mode 100644 index 0000000..97d0283 --- /dev/null +++ b/src/common_audio/signal_processing_library/OWNERS @@ -0,0 +1,3 @@ +bjornv@webrtc.org +tina.legrand@webrtc.org +jan.skoglund@webrtc.org diff --git a/src/common_audio/signal_processing_library/main/interface/signal_processing_library.h b/src/common_audio/signal_processing_library/main/interface/signal_processing_library.h new file mode 100644 index 0000000..1cdea71 --- /dev/null +++ b/src/common_audio/signal_processing_library/main/interface/signal_processing_library.h @@ -0,0 +1,1672 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + + +/* + * This header file includes all of the fix point signal processing library (SPL) function + * descriptions and declarations. + * For specific function calls, see bottom of file. + */ + +#ifndef WEBRTC_SPL_SIGNAL_PROCESSING_LIBRARY_H_ +#define WEBRTC_SPL_SIGNAL_PROCESSING_LIBRARY_H_ + +#include +#include "typedefs.h" + +#ifdef ARM_WINM +#include // intrinsic file for windows mobile +#endif + +// Macros specific for the fixed point implementation +#define WEBRTC_SPL_WORD16_MAX 32767 +#define WEBRTC_SPL_WORD16_MIN -32768 +#define WEBRTC_SPL_WORD32_MAX (WebRtc_Word32)0x7fffffff +#define WEBRTC_SPL_WORD32_MIN (WebRtc_Word32)0x80000000 +#define WEBRTC_SPL_MAX_LPC_ORDER 14 +#define WEBRTC_SPL_MAX_SEED_USED 0x80000000L +#define WEBRTC_SPL_MIN(A, B) (A < B ? A : B) // Get min value +#define WEBRTC_SPL_MAX(A, B) (A > B ? A : B) // Get max value +#define WEBRTC_SPL_ABS_W16(a) \ + (((WebRtc_Word16)a >= 0) ? ((WebRtc_Word16)a) : -((WebRtc_Word16)a)) +#define WEBRTC_SPL_ABS_W32(a) \ + (((WebRtc_Word32)a >= 0) ? ((WebRtc_Word32)a) : -((WebRtc_Word32)a)) + +#if (defined WEBRTC_TARGET_PC)||(defined __TARGET_XSCALE) +#define WEBRTC_SPL_GET_BYTE(a, nr) (((WebRtc_Word8 *)a)[nr]) +#define WEBRTC_SPL_SET_BYTE(d_ptr, val, index) \ + (((WebRtc_Word8 *)d_ptr)[index] = (val)) +#elif defined WEBRTC_BIG_ENDIAN +#define WEBRTC_SPL_GET_BYTE(a, nr) \ + ((((WebRtc_Word16 *)a)[nr >> 1]) >> (((nr + 1) & 0x1) * 8) & 0x00ff) +#define WEBRTC_SPL_SET_BYTE(d_ptr, val, index) \ + ((WebRtc_Word16 *)d_ptr)[index >> 1] = \ + ((((WebRtc_Word16 *)d_ptr)[index >> 1]) \ + & (0x00ff << (8 * ((index) & 0x1)))) | (val << (8 * ((index + 1) & 0x1))) +#else +#define WEBRTC_SPL_GET_BYTE(a,nr) \ + ((((WebRtc_Word16 *)(a))[(nr) >> 1]) >> (((nr) & 0x1) * 8) & 0x00ff) +#define WEBRTC_SPL_SET_BYTE(d_ptr, val, index) \ + ((WebRtc_Word16 *)(d_ptr))[(index) >> 1] = \ + ((((WebRtc_Word16 *)(d_ptr))[(index) >> 1]) \ + & (0x00ff << (8 * (((index) + 1) & 0x1)))) | \ + ((val) << (8 * ((index) & 0x1))) +#endif + +#define WEBRTC_SPL_MUL(a, b) \ + ((WebRtc_Word32) ((WebRtc_Word32)(a) * (WebRtc_Word32)(b))) +#define WEBRTC_SPL_UMUL(a, b) \ + ((WebRtc_UWord32) ((WebRtc_UWord32)(a) * (WebRtc_UWord32)(b))) +#define WEBRTC_SPL_UMUL_RSFT16(a, b) \ + ((WebRtc_UWord32) ((WebRtc_UWord32)(a) * (WebRtc_UWord32)(b)) >> 16) +#define WEBRTC_SPL_UMUL_16_16(a, b) \ + ((WebRtc_UWord32) (WebRtc_UWord16)(a) * (WebRtc_UWord16)(b)) +#define WEBRTC_SPL_UMUL_16_16_RSFT16(a, b) \ + (((WebRtc_UWord32) (WebRtc_UWord16)(a) * (WebRtc_UWord16)(b)) >> 16) +#define WEBRTC_SPL_UMUL_32_16(a, b) \ + ((WebRtc_UWord32) ((WebRtc_UWord32)(a) * (WebRtc_UWord16)(b))) +#define WEBRTC_SPL_UMUL_32_16_RSFT16(a, b) \ + ((WebRtc_UWord32) ((WebRtc_UWord32)(a) * (WebRtc_UWord16)(b)) >> 16) +#define WEBRTC_SPL_MUL_16_U16(a, b) \ + ((WebRtc_Word32)(WebRtc_Word16)(a) * (WebRtc_UWord16)(b)) +#define WEBRTC_SPL_DIV(a, b) \ + ((WebRtc_Word32) ((WebRtc_Word32)(a) / (WebRtc_Word32)(b))) +#define WEBRTC_SPL_UDIV(a, b) \ + ((WebRtc_UWord32) ((WebRtc_UWord32)(a) / (WebRtc_UWord32)(b))) + +#ifndef WEBRTC_ARCH_ARM_V7A +// For ARMv7 platforms, these are inline functions in spl_inl_armv7.h +#define WEBRTC_SPL_MUL_16_16(a, b) \ + ((WebRtc_Word32) (((WebRtc_Word16)(a)) * ((WebRtc_Word16)(b)))) +#define WEBRTC_SPL_MUL_16_32_RSFT16(a, b) \ + (WEBRTC_SPL_MUL_16_16(a, b >> 16) \ + + ((WEBRTC_SPL_MUL_16_16(a, (b & 0xffff) >> 1) + 0x4000) >> 15)) +#define WEBRTC_SPL_MUL_32_32_RSFT32(a32a, a32b, b32) \ + ((WebRtc_Word32)(WEBRTC_SPL_MUL_16_32_RSFT16(a32a, b32) \ + + (WEBRTC_SPL_MUL_16_32_RSFT16(a32b, b32) >> 16))) +#define WEBRTC_SPL_MUL_32_32_RSFT32BI(a32, b32) \ + ((WebRtc_Word32)(WEBRTC_SPL_MUL_16_32_RSFT16(( \ + (WebRtc_Word16)(a32 >> 16)), b32) + \ + (WEBRTC_SPL_MUL_16_32_RSFT16(( \ + (WebRtc_Word16)((a32 & 0x0000FFFF) >> 1)), b32) >> 15))) +#endif + +#define WEBRTC_SPL_MUL_16_32_RSFT11(a, b) \ + ((WEBRTC_SPL_MUL_16_16(a, (b) >> 16) << 5) \ + + (((WEBRTC_SPL_MUL_16_U16(a, (WebRtc_UWord16)(b)) >> 1) + 0x0200) >> 10)) +#define WEBRTC_SPL_MUL_16_32_RSFT14(a, b) \ + ((WEBRTC_SPL_MUL_16_16(a, (b) >> 16) << 2) \ + + (((WEBRTC_SPL_MUL_16_U16(a, (WebRtc_UWord16)(b)) >> 1) + 0x1000) >> 13)) +#define WEBRTC_SPL_MUL_16_32_RSFT15(a, b) \ + ((WEBRTC_SPL_MUL_16_16(a, (b) >> 16) << 1) \ + + (((WEBRTC_SPL_MUL_16_U16(a, (WebRtc_UWord16)(b)) >> 1) + 0x2000) >> 14)) + +#ifdef ARM_WINM +#define WEBRTC_SPL_MUL_16_16(a, b) \ + _SmulLo_SW_SL((WebRtc_Word16)(a), (WebRtc_Word16)(b)) +#endif + +#define WEBRTC_SPL_MUL_16_16_RSFT(a, b, c) \ + (WEBRTC_SPL_MUL_16_16(a, b) >> (c)) + +#define WEBRTC_SPL_MUL_16_16_RSFT_WITH_ROUND(a, b, c) \ + ((WEBRTC_SPL_MUL_16_16(a, b) + ((WebRtc_Word32) \ + (((WebRtc_Word32)1) << ((c) - 1)))) >> (c)) +#define WEBRTC_SPL_MUL_16_16_RSFT_WITH_FIXROUND(a, b) \ + ((WEBRTC_SPL_MUL_16_16(a, b) + ((WebRtc_Word32) (1 << 14))) >> 15) + +// C + the 32 most significant bits of A * B +#define WEBRTC_SPL_SCALEDIFF32(A, B, C) \ + (C + (B >> 16) * A + (((WebRtc_UWord32)(0x0000FFFF & B) * A) >> 16)) + +#define WEBRTC_SPL_ADD_SAT_W32(a, b) WebRtcSpl_AddSatW32(a, b) +#define WEBRTC_SPL_SAT(a, b, c) (b > a ? a : b < c ? c : b) +#define WEBRTC_SPL_MUL_32_16(a, b) ((a) * (b)) + +#define WEBRTC_SPL_SUB_SAT_W32(a, b) WebRtcSpl_SubSatW32(a, b) +#define WEBRTC_SPL_ADD_SAT_W16(a, b) WebRtcSpl_AddSatW16(a, b) +#define WEBRTC_SPL_SUB_SAT_W16(a, b) WebRtcSpl_SubSatW16(a, b) + +// We cannot do casting here due to signed/unsigned problem +#define WEBRTC_SPL_IS_NEG(a) ((a) & 0x80000000) +// Shifting with negative numbers allowed +// Positive means left shift +#define WEBRTC_SPL_SHIFT_W16(x, c) \ + (((c) >= 0) ? ((x) << (c)) : ((x) >> (-(c)))) +#define WEBRTC_SPL_SHIFT_W32(x, c) \ + (((c) >= 0) ? ((x) << (c)) : ((x) >> (-(c)))) + +// Shifting with negative numbers not allowed +// We cannot do casting here due to signed/unsigned problem +#define WEBRTC_SPL_RSHIFT_W16(x, c) ((x) >> (c)) +#define WEBRTC_SPL_LSHIFT_W16(x, c) ((x) << (c)) +#define WEBRTC_SPL_RSHIFT_W32(x, c) ((x) >> (c)) +#define WEBRTC_SPL_LSHIFT_W32(x, c) ((x) << (c)) + +#define WEBRTC_SPL_RSHIFT_U16(x, c) ((WebRtc_UWord16)(x) >> (c)) +#define WEBRTC_SPL_LSHIFT_U16(x, c) ((WebRtc_UWord16)(x) << (c)) +#define WEBRTC_SPL_RSHIFT_U32(x, c) ((WebRtc_UWord32)(x) >> (c)) +#define WEBRTC_SPL_LSHIFT_U32(x, c) ((WebRtc_UWord32)(x) << (c)) + +#define WEBRTC_SPL_VNEW(t, n) (t *) malloc (sizeof (t) * (n)) +#define WEBRTC_SPL_FREE free + +#define WEBRTC_SPL_RAND(a) \ + ((WebRtc_Word16)(WEBRTC_SPL_MUL_16_16_RSFT((a), 18816, 7) & 0x00007fff)) + +#ifdef __cplusplus +extern "C" +{ +#endif + +#define WEBRTC_SPL_MEMCPY_W8(v1, v2, length) \ + memcpy(v1, v2, (length) * sizeof(char)) +#define WEBRTC_SPL_MEMCPY_W16(v1, v2, length) \ + memcpy(v1, v2, (length) * sizeof(WebRtc_Word16)) + +#define WEBRTC_SPL_MEMMOVE_W16(v1, v2, length) \ + memmove(v1, v2, (length) * sizeof(WebRtc_Word16)) + +// Trigonometric tables used for quick lookup +// default declarations +extern WebRtc_Word16 WebRtcSpl_kCosTable[]; +extern WebRtc_Word16 WebRtcSpl_kSinTable[]; +extern WebRtc_Word16 WebRtcSpl_kSinTable1024[]; +// Hanning table +extern WebRtc_Word16 WebRtcSpl_kHanningTable[]; +// Random table +extern WebRtc_Word16 WebRtcSpl_kRandNTable[]; + +// inline functions: +#include "spl_inl.h" + +// Get SPL Version +WebRtc_Word16 WebRtcSpl_get_version(char* version, + WebRtc_Word16 length_in_bytes); + +int WebRtcSpl_GetScalingSquare(WebRtc_Word16* in_vector, + int in_vector_length, + int times); + +// Copy and set operations. Implementation in copy_set_operations.c. +// Descriptions at bottom of file. +void WebRtcSpl_MemSetW16(WebRtc_Word16* vector, + WebRtc_Word16 set_value, + int vector_length); +void WebRtcSpl_MemSetW32(WebRtc_Word32* vector, + WebRtc_Word32 set_value, + int vector_length); +void WebRtcSpl_MemCpyReversedOrder(WebRtc_Word16* out_vector, + WebRtc_Word16* in_vector, + int vector_length); +WebRtc_Word16 WebRtcSpl_CopyFromEndW16(G_CONST WebRtc_Word16* in_vector, + WebRtc_Word16 in_vector_length, + WebRtc_Word16 samples, + WebRtc_Word16* out_vector); +WebRtc_Word16 WebRtcSpl_ZerosArrayW16(WebRtc_Word16* vector, + WebRtc_Word16 vector_length); +WebRtc_Word16 WebRtcSpl_ZerosArrayW32(WebRtc_Word32* vector, + WebRtc_Word16 vector_length); +WebRtc_Word16 WebRtcSpl_OnesArrayW16(WebRtc_Word16* vector, + WebRtc_Word16 vector_length); +WebRtc_Word16 WebRtcSpl_OnesArrayW32(WebRtc_Word32* vector, + WebRtc_Word16 vector_length); +// End: Copy and set operations. + +// Minimum and maximum operations. Implementation in min_max_operations.c. +// Descriptions at bottom of file. +WebRtc_Word16 WebRtcSpl_MaxAbsValueW16(const WebRtc_Word16* vector, + WebRtc_Word16 length); +WebRtc_Word32 WebRtcSpl_MaxAbsValueW32(G_CONST WebRtc_Word32* vector, + WebRtc_Word16 length); +WebRtc_Word16 WebRtcSpl_MinValueW16(G_CONST WebRtc_Word16* vector, + WebRtc_Word16 length); +WebRtc_Word32 WebRtcSpl_MinValueW32(G_CONST WebRtc_Word32* vector, + WebRtc_Word16 length); +WebRtc_Word16 WebRtcSpl_MaxValueW16(G_CONST WebRtc_Word16* vector, + WebRtc_Word16 length); + +WebRtc_Word16 WebRtcSpl_MaxAbsIndexW16(G_CONST WebRtc_Word16* vector, + WebRtc_Word16 length); +WebRtc_Word32 WebRtcSpl_MaxValueW32(G_CONST WebRtc_Word32* vector, + WebRtc_Word16 length); +WebRtc_Word16 WebRtcSpl_MinIndexW16(G_CONST WebRtc_Word16* vector, + WebRtc_Word16 length); +WebRtc_Word16 WebRtcSpl_MinIndexW32(G_CONST WebRtc_Word32* vector, + WebRtc_Word16 length); +WebRtc_Word16 WebRtcSpl_MaxIndexW16(G_CONST WebRtc_Word16* vector, + WebRtc_Word16 length); +WebRtc_Word16 WebRtcSpl_MaxIndexW32(G_CONST WebRtc_Word32* vector, + WebRtc_Word16 length); +// End: Minimum and maximum operations. + +// Vector scaling operations. Implementation in vector_scaling_operations.c. +// Description at bottom of file. +void WebRtcSpl_VectorBitShiftW16(WebRtc_Word16* out_vector, + WebRtc_Word16 vector_length, + G_CONST WebRtc_Word16* in_vector, + WebRtc_Word16 right_shifts); +void WebRtcSpl_VectorBitShiftW32(WebRtc_Word32* out_vector, + WebRtc_Word16 vector_length, + G_CONST WebRtc_Word32* in_vector, + WebRtc_Word16 right_shifts); +void WebRtcSpl_VectorBitShiftW32ToW16(WebRtc_Word16* out_vector, + WebRtc_Word16 vector_length, + G_CONST WebRtc_Word32* in_vector, + WebRtc_Word16 right_shifts); + +void WebRtcSpl_ScaleVector(G_CONST WebRtc_Word16* in_vector, + WebRtc_Word16* out_vector, + WebRtc_Word16 gain, + WebRtc_Word16 vector_length, + WebRtc_Word16 right_shifts); +void WebRtcSpl_ScaleVectorWithSat(G_CONST WebRtc_Word16* in_vector, + WebRtc_Word16* out_vector, + WebRtc_Word16 gain, + WebRtc_Word16 vector_length, + WebRtc_Word16 right_shifts); +void WebRtcSpl_ScaleAndAddVectors(G_CONST WebRtc_Word16* in_vector1, + WebRtc_Word16 gain1, int right_shifts1, + G_CONST WebRtc_Word16* in_vector2, + WebRtc_Word16 gain2, int right_shifts2, + WebRtc_Word16* out_vector, + int vector_length); +// End: Vector scaling operations. + +// iLBC specific functions. Implementations in ilbc_specific_functions.c. +// Description at bottom of file. +void WebRtcSpl_ScaleAndAddVectorsWithRound(WebRtc_Word16* in_vector1, + WebRtc_Word16 scale1, + WebRtc_Word16* in_vector2, + WebRtc_Word16 scale2, + WebRtc_Word16 right_shifts, + WebRtc_Word16* out_vector, + WebRtc_Word16 vector_length); +void WebRtcSpl_ReverseOrderMultArrayElements(WebRtc_Word16* out_vector, + G_CONST WebRtc_Word16* in_vector, + G_CONST WebRtc_Word16* window, + WebRtc_Word16 vector_length, + WebRtc_Word16 right_shifts); +void WebRtcSpl_ElementwiseVectorMult(WebRtc_Word16* out_vector, + G_CONST WebRtc_Word16* in_vector, + G_CONST WebRtc_Word16* window, + WebRtc_Word16 vector_length, + WebRtc_Word16 right_shifts); +void WebRtcSpl_AddVectorsAndShift(WebRtc_Word16* out_vector, + G_CONST WebRtc_Word16* in_vector1, + G_CONST WebRtc_Word16* in_vector2, + WebRtc_Word16 vector_length, + WebRtc_Word16 right_shifts); +void WebRtcSpl_AddAffineVectorToVector(WebRtc_Word16* out_vector, + WebRtc_Word16* in_vector, + WebRtc_Word16 gain, + WebRtc_Word32 add_constant, + WebRtc_Word16 right_shifts, + int vector_length); +void WebRtcSpl_AffineTransformVector(WebRtc_Word16* out_vector, + WebRtc_Word16* in_vector, + WebRtc_Word16 gain, + WebRtc_Word32 add_constant, + WebRtc_Word16 right_shifts, + int vector_length); +// End: iLBC specific functions. + +// Signal processing operations. Descriptions at bottom of this file. +int WebRtcSpl_AutoCorrelation(G_CONST WebRtc_Word16* vector, + int vector_length, int order, + WebRtc_Word32* result_vector, + int* scale); +WebRtc_Word16 WebRtcSpl_LevinsonDurbin(WebRtc_Word32* auto_corr, + WebRtc_Word16* lpc_coef, + WebRtc_Word16* refl_coef, + WebRtc_Word16 order); +void WebRtcSpl_ReflCoefToLpc(G_CONST WebRtc_Word16* refl_coef, + int use_order, + WebRtc_Word16* lpc_coef); +void WebRtcSpl_LpcToReflCoef(WebRtc_Word16* lpc_coef, + int use_order, + WebRtc_Word16* refl_coef); +void WebRtcSpl_AutoCorrToReflCoef(G_CONST WebRtc_Word32* auto_corr, + int use_order, + WebRtc_Word16* refl_coef); +void WebRtcSpl_CrossCorrelation(WebRtc_Word32* cross_corr, + WebRtc_Word16* vector1, + WebRtc_Word16* vector2, + WebRtc_Word16 dim_vector, + WebRtc_Word16 dim_cross_corr, + WebRtc_Word16 right_shifts, + WebRtc_Word16 step_vector2); +void WebRtcSpl_GetHanningWindow(WebRtc_Word16* window, WebRtc_Word16 size); +void WebRtcSpl_SqrtOfOneMinusXSquared(WebRtc_Word16* in_vector, + int vector_length, + WebRtc_Word16* out_vector); +// End: Signal processing operations. + +// Randomization functions. Implementations collected in randomization_functions.c and +// descriptions at bottom of this file. +WebRtc_UWord32 WebRtcSpl_IncreaseSeed(WebRtc_UWord32* seed); +WebRtc_Word16 WebRtcSpl_RandU(WebRtc_UWord32* seed); +WebRtc_Word16 WebRtcSpl_RandN(WebRtc_UWord32* seed); +WebRtc_Word16 WebRtcSpl_RandUArray(WebRtc_Word16* vector, + WebRtc_Word16 vector_length, + WebRtc_UWord32* seed); +// End: Randomization functions. + +// Math functions +WebRtc_Word32 WebRtcSpl_Sqrt(WebRtc_Word32 value); +WebRtc_Word32 WebRtcSpl_SqrtFloor(WebRtc_Word32 value); + +// Divisions. Implementations collected in division_operations.c and +// descriptions at bottom of this file. +WebRtc_UWord32 WebRtcSpl_DivU32U16(WebRtc_UWord32 num, WebRtc_UWord16 den); +WebRtc_Word32 WebRtcSpl_DivW32W16(WebRtc_Word32 num, WebRtc_Word16 den); +WebRtc_Word16 WebRtcSpl_DivW32W16ResW16(WebRtc_Word32 num, WebRtc_Word16 den); +WebRtc_Word32 WebRtcSpl_DivResultInQ31(WebRtc_Word32 num, WebRtc_Word32 den); +WebRtc_Word32 WebRtcSpl_DivW32HiLow(WebRtc_Word32 num, WebRtc_Word16 den_hi, + WebRtc_Word16 den_low); +// End: Divisions. + +WebRtc_Word32 WebRtcSpl_Energy(WebRtc_Word16* vector, + int vector_length, + int* scale_factor); + +WebRtc_Word32 WebRtcSpl_DotProductWithScale(WebRtc_Word16* vector1, + WebRtc_Word16* vector2, + int vector_length, + int scaling); + +// Filter operations. +int WebRtcSpl_FilterAR(G_CONST WebRtc_Word16* ar_coef, int ar_coef_length, + G_CONST WebRtc_Word16* in_vector, int in_vector_length, + WebRtc_Word16* filter_state, int filter_state_length, + WebRtc_Word16* filter_state_low, + int filter_state_low_length, WebRtc_Word16* out_vector, + WebRtc_Word16* out_vector_low, int out_vector_low_length); + +void WebRtcSpl_FilterMAFastQ12(WebRtc_Word16* in_vector, + WebRtc_Word16* out_vector, + WebRtc_Word16* ma_coef, + WebRtc_Word16 ma_coef_length, + WebRtc_Word16 vector_length); +void WebRtcSpl_FilterARFastQ12(WebRtc_Word16* in_vector, + WebRtc_Word16* out_vector, + WebRtc_Word16* ar_coef, + WebRtc_Word16 ar_coef_length, + WebRtc_Word16 vector_length); +int WebRtcSpl_DownsampleFast(WebRtc_Word16* in_vector, + WebRtc_Word16 in_vector_length, + WebRtc_Word16* out_vector, + WebRtc_Word16 out_vector_length, + WebRtc_Word16* ma_coef, + WebRtc_Word16 ma_coef_length, + WebRtc_Word16 factor, + WebRtc_Word16 delay); +// End: Filter operations. + +// FFT operations +int WebRtcSpl_ComplexFFT(WebRtc_Word16 vector[], int stages, int mode); +int WebRtcSpl_ComplexIFFT(WebRtc_Word16 vector[], int stages, int mode); +void WebRtcSpl_ComplexBitReverse(WebRtc_Word16 vector[], int stages); +// End: FFT operations + +/************************************************************ + * + * RESAMPLING FUNCTIONS AND THEIR STRUCTS ARE DEFINED BELOW + * + ************************************************************/ + +/******************************************************************* + * resample.c + * + * Includes the following resampling combinations + * 22 kHz -> 16 kHz + * 16 kHz -> 22 kHz + * 22 kHz -> 8 kHz + * 8 kHz -> 22 kHz + * + ******************************************************************/ + +// state structure for 22 -> 16 resampler +typedef struct +{ + WebRtc_Word32 S_22_44[8]; + WebRtc_Word32 S_44_32[8]; + WebRtc_Word32 S_32_16[8]; +} WebRtcSpl_State22khzTo16khz; + +void WebRtcSpl_Resample22khzTo16khz(const WebRtc_Word16* in, + WebRtc_Word16* out, + WebRtcSpl_State22khzTo16khz* state, + WebRtc_Word32* tmpmem); + +void WebRtcSpl_ResetResample22khzTo16khz(WebRtcSpl_State22khzTo16khz* state); + +// state structure for 16 -> 22 resampler +typedef struct +{ + WebRtc_Word32 S_16_32[8]; + WebRtc_Word32 S_32_22[8]; +} WebRtcSpl_State16khzTo22khz; + +void WebRtcSpl_Resample16khzTo22khz(const WebRtc_Word16* in, + WebRtc_Word16* out, + WebRtcSpl_State16khzTo22khz* state, + WebRtc_Word32* tmpmem); + +void WebRtcSpl_ResetResample16khzTo22khz(WebRtcSpl_State16khzTo22khz* state); + +// state structure for 22 -> 8 resampler +typedef struct +{ + WebRtc_Word32 S_22_22[16]; + WebRtc_Word32 S_22_16[8]; + WebRtc_Word32 S_16_8[8]; +} WebRtcSpl_State22khzTo8khz; + +void WebRtcSpl_Resample22khzTo8khz(const WebRtc_Word16* in, WebRtc_Word16* out, + WebRtcSpl_State22khzTo8khz* state, + WebRtc_Word32* tmpmem); + +void WebRtcSpl_ResetResample22khzTo8khz(WebRtcSpl_State22khzTo8khz* state); + +// state structure for 8 -> 22 resampler +typedef struct +{ + WebRtc_Word32 S_8_16[8]; + WebRtc_Word32 S_16_11[8]; + WebRtc_Word32 S_11_22[8]; +} WebRtcSpl_State8khzTo22khz; + +void WebRtcSpl_Resample8khzTo22khz(const WebRtc_Word16* in, WebRtc_Word16* out, + WebRtcSpl_State8khzTo22khz* state, + WebRtc_Word32* tmpmem); + +void WebRtcSpl_ResetResample8khzTo22khz(WebRtcSpl_State8khzTo22khz* state); + +/******************************************************************* + * resample_fractional.c + * Functions for internal use in the other resample functions + * + * Includes the following resampling combinations + * 48 kHz -> 32 kHz + * 32 kHz -> 24 kHz + * 44 kHz -> 32 kHz + * + ******************************************************************/ + +void WebRtcSpl_Resample48khzTo32khz(const WebRtc_Word32* In, WebRtc_Word32* Out, + const WebRtc_Word32 K); + +void WebRtcSpl_Resample32khzTo24khz(const WebRtc_Word32* In, WebRtc_Word32* Out, + const WebRtc_Word32 K); + +void WebRtcSpl_Resample44khzTo32khz(const WebRtc_Word32* In, WebRtc_Word32* Out, + const WebRtc_Word32 K); + +/******************************************************************* + * resample_48khz.c + * + * Includes the following resampling combinations + * 48 kHz -> 16 kHz + * 16 kHz -> 48 kHz + * 48 kHz -> 8 kHz + * 8 kHz -> 48 kHz + * + ******************************************************************/ + +typedef struct +{ + WebRtc_Word32 S_48_48[16]; + WebRtc_Word32 S_48_32[8]; + WebRtc_Word32 S_32_16[8]; +} WebRtcSpl_State48khzTo16khz; + +void WebRtcSpl_Resample48khzTo16khz(const WebRtc_Word16* in, WebRtc_Word16* out, + WebRtcSpl_State48khzTo16khz* state, + WebRtc_Word32* tmpmem); + +void WebRtcSpl_ResetResample48khzTo16khz(WebRtcSpl_State48khzTo16khz* state); + +typedef struct +{ + WebRtc_Word32 S_16_32[8]; + WebRtc_Word32 S_32_24[8]; + WebRtc_Word32 S_24_48[8]; +} WebRtcSpl_State16khzTo48khz; + +void WebRtcSpl_Resample16khzTo48khz(const WebRtc_Word16* in, WebRtc_Word16* out, + WebRtcSpl_State16khzTo48khz* state, + WebRtc_Word32* tmpmem); + +void WebRtcSpl_ResetResample16khzTo48khz(WebRtcSpl_State16khzTo48khz* state); + +typedef struct +{ + WebRtc_Word32 S_48_24[8]; + WebRtc_Word32 S_24_24[16]; + WebRtc_Word32 S_24_16[8]; + WebRtc_Word32 S_16_8[8]; +} WebRtcSpl_State48khzTo8khz; + +void WebRtcSpl_Resample48khzTo8khz(const WebRtc_Word16* in, WebRtc_Word16* out, + WebRtcSpl_State48khzTo8khz* state, + WebRtc_Word32* tmpmem); + +void WebRtcSpl_ResetResample48khzTo8khz(WebRtcSpl_State48khzTo8khz* state); + +typedef struct +{ + WebRtc_Word32 S_8_16[8]; + WebRtc_Word32 S_16_12[8]; + WebRtc_Word32 S_12_24[8]; + WebRtc_Word32 S_24_48[8]; +} WebRtcSpl_State8khzTo48khz; + +void WebRtcSpl_Resample8khzTo48khz(const WebRtc_Word16* in, WebRtc_Word16* out, + WebRtcSpl_State8khzTo48khz* state, + WebRtc_Word32* tmpmem); + +void WebRtcSpl_ResetResample8khzTo48khz(WebRtcSpl_State8khzTo48khz* state); + +/******************************************************************* + * resample_by_2.c + * + * Includes down and up sampling by a factor of two. + * + ******************************************************************/ + +void WebRtcSpl_DownsampleBy2(const WebRtc_Word16* in, const WebRtc_Word16 len, + WebRtc_Word16* out, WebRtc_Word32* filtState); + +void WebRtcSpl_UpsampleBy2(const WebRtc_Word16* in, WebRtc_Word16 len, WebRtc_Word16* out, + WebRtc_Word32* filtState); + +/************************************************************ + * END OF RESAMPLING FUNCTIONS + ************************************************************/ +void WebRtcSpl_AnalysisQMF(const WebRtc_Word16* in_data, + WebRtc_Word16* low_band, + WebRtc_Word16* high_band, + WebRtc_Word32* filter_state1, + WebRtc_Word32* filter_state2); +void WebRtcSpl_SynthesisQMF(const WebRtc_Word16* low_band, + const WebRtc_Word16* high_band, + WebRtc_Word16* out_data, + WebRtc_Word32* filter_state1, + WebRtc_Word32* filter_state2); + +#ifdef __cplusplus +} +#endif // __cplusplus +#endif // WEBRTC_SPL_SIGNAL_PROCESSING_LIBRARY_H_ + +// +// WebRtcSpl_AddSatW16(...) +// WebRtcSpl_AddSatW32(...) +// +// Returns the result of a saturated 16-bit, respectively 32-bit, addition of +// the numbers specified by the |var1| and |var2| parameters. +// +// Input: +// - var1 : Input variable 1 +// - var2 : Input variable 2 +// +// Return value : Added and saturated value +// + +// +// WebRtcSpl_SubSatW16(...) +// WebRtcSpl_SubSatW32(...) +// +// Returns the result of a saturated 16-bit, respectively 32-bit, subtraction +// of the numbers specified by the |var1| and |var2| parameters. +// +// Input: +// - var1 : Input variable 1 +// - var2 : Input variable 2 +// +// Returned value : Subtracted and saturated value +// + +// +// WebRtcSpl_GetSizeInBits(...) +// +// Returns the # of bits that are needed at the most to represent the number +// specified by the |value| parameter. +// +// Input: +// - value : Input value +// +// Return value : Number of bits needed to represent |value| +// + +// +// WebRtcSpl_NormW32(...) +// +// Norm returns the # of left shifts required to 32-bit normalize the 32-bit +// signed number specified by the |value| parameter. +// +// Input: +// - value : Input value +// +// Return value : Number of bit shifts needed to 32-bit normalize |value| +// + +// +// WebRtcSpl_NormW16(...) +// +// Norm returns the # of left shifts required to 16-bit normalize the 16-bit +// signed number specified by the |value| parameter. +// +// Input: +// - value : Input value +// +// Return value : Number of bit shifts needed to 32-bit normalize |value| +// + +// +// WebRtcSpl_NormU32(...) +// +// Norm returns the # of left shifts required to 32-bit normalize the unsigned +// 32-bit number specified by the |value| parameter. +// +// Input: +// - value : Input value +// +// Return value : Number of bit shifts needed to 32-bit normalize |value| +// + +// +// WebRtcSpl_GetScalingSquare(...) +// +// Returns the # of bits required to scale the samples specified in the +// |in_vector| parameter so that, if the squares of the samples are added the +// # of times specified by the |times| parameter, the 32-bit addition will not +// overflow (result in WebRtc_Word32). +// +// Input: +// - in_vector : Input vector to check scaling on +// - in_vector_length : Samples in |in_vector| +// - times : Number of additions to be performed +// +// Return value : Number of right bit shifts needed to avoid +// overflow in the addition calculation +// + +// +// WebRtcSpl_MemSetW16(...) +// +// Sets all the values in the WebRtc_Word16 vector |vector| of length +// |vector_length| to the specified value |set_value| +// +// Input: +// - vector : Pointer to the WebRtc_Word16 vector +// - set_value : Value specified +// - vector_length : Length of vector +// + +// +// WebRtcSpl_MemSetW32(...) +// +// Sets all the values in the WebRtc_Word32 vector |vector| of length +// |vector_length| to the specified value |set_value| +// +// Input: +// - vector : Pointer to the WebRtc_Word16 vector +// - set_value : Value specified +// - vector_length : Length of vector +// + +// +// WebRtcSpl_MemCpyReversedOrder(...) +// +// Copies all the values from the source WebRtc_Word16 vector |in_vector| to a +// destination WebRtc_Word16 vector |out_vector|. It is done in reversed order, +// meaning that the first sample of |in_vector| is copied to the last sample of +// the |out_vector|. The procedure continues until the last sample of +// |in_vector| has been copied to the first sample of |out_vector|. This +// creates a reversed vector. Used in e.g. prediction in iLBC. +// +// Input: +// - in_vector : Pointer to the first sample in a WebRtc_Word16 vector +// of length |length| +// - vector_length : Number of elements to copy +// +// Output: +// - out_vector : Pointer to the last sample in a WebRtc_Word16 vector +// of length |length| +// + +// +// WebRtcSpl_CopyFromEndW16(...) +// +// Copies the rightmost |samples| of |in_vector| (of length |in_vector_length|) +// to the vector |out_vector|. +// +// Input: +// - in_vector : Input vector +// - in_vector_length : Number of samples in |in_vector| +// - samples : Number of samples to extract (from right side) +// from |in_vector| +// +// Output: +// - out_vector : Vector with the requested samples +// +// Return value : Number of copied samples in |out_vector| +// + +// +// WebRtcSpl_ZerosArrayW16(...) +// WebRtcSpl_ZerosArrayW32(...) +// +// Inserts the value "zero" in all positions of a w16 and a w32 vector +// respectively. +// +// Input: +// - vector_length : Number of samples in vector +// +// Output: +// - vector : Vector containing all zeros +// +// Return value : Number of samples in vector +// + +// +// WebRtcSpl_OnesArrayW16(...) +// WebRtcSpl_OnesArrayW32(...) +// +// Inserts the value "one" in all positions of a w16 and a w32 vector +// respectively. +// +// Input: +// - vector_length : Number of samples in vector +// +// Output: +// - vector : Vector containing all ones +// +// Return value : Number of samples in vector +// + +// +// WebRtcSpl_MinValueW16(...) +// WebRtcSpl_MinValueW32(...) +// +// Returns the minimum value of a vector +// +// Input: +// - vector : Input vector +// - vector_length : Number of samples in vector +// +// Return value : Minimum sample value in vector +// + +// +// WebRtcSpl_MaxValueW16(...) +// WebRtcSpl_MaxValueW32(...) +// +// Returns the maximum value of a vector +// +// Input: +// - vector : Input vector +// - vector_length : Number of samples in vector +// +// Return value : Maximum sample value in vector +// + +// +// WebRtcSpl_MaxAbsValueW16(...) +// WebRtcSpl_MaxAbsValueW32(...) +// +// Returns the largest absolute value of a vector +// +// Input: +// - vector : Input vector +// - vector_length : Number of samples in vector +// +// Return value : Maximum absolute value in vector +// + +// +// WebRtcSpl_MaxAbsIndexW16(...) +// +// Returns the vector index to the largest absolute value of a vector +// +// Input: +// - vector : Input vector +// - vector_length : Number of samples in vector +// +// Return value : Index to maximum absolute value in vector +// + +// +// WebRtcSpl_MinIndexW16(...) +// WebRtcSpl_MinIndexW32(...) +// +// Returns the vector index to the minimum sample value of a vector +// +// Input: +// - vector : Input vector +// - vector_length : Number of samples in vector +// +// Return value : Index to minimum sample value in vector +// + +// +// WebRtcSpl_MaxIndexW16(...) +// WebRtcSpl_MaxIndexW32(...) +// +// Returns the vector index to the maximum sample value of a vector +// +// Input: +// - vector : Input vector +// - vector_length : Number of samples in vector +// +// Return value : Index to maximum sample value in vector +// + +// +// WebRtcSpl_VectorBitShiftW16(...) +// WebRtcSpl_VectorBitShiftW32(...) +// +// Bit shifts all the values in a vector up or downwards. Different calls for +// WebRtc_Word16 and WebRtc_Word32 vectors respectively. +// +// Input: +// - vector_length : Length of vector +// - in_vector : Pointer to the vector that should be bit shifted +// - right_shifts : Number of right bit shifts (negative value gives left +// shifts) +// +// Output: +// - out_vector : Pointer to the result vector (can be the same as +// |in_vector|) +// + +// +// WebRtcSpl_VectorBitShiftW32ToW16(...) +// +// Bit shifts all the values in a WebRtc_Word32 vector up or downwards and +// stores the result as a WebRtc_Word16 vector +// +// Input: +// - vector_length : Length of vector +// - in_vector : Pointer to the vector that should be bit shifted +// - right_shifts : Number of right bit shifts (negative value gives left +// shifts) +// +// Output: +// - out_vector : Pointer to the result vector (can be the same as +// |in_vector|) +// + +// +// WebRtcSpl_ScaleVector(...) +// +// Performs the vector operation: +// out_vector[k] = (gain*in_vector[k])>>right_shifts +// +// Input: +// - in_vector : Input vector +// - gain : Scaling gain +// - vector_length : Elements in the |in_vector| +// - right_shifts : Number of right bit shifts applied +// +// Output: +// - out_vector : Output vector (can be the same as |in_vector|) +// + +// +// WebRtcSpl_ScaleVectorWithSat(...) +// +// Performs the vector operation: +// out_vector[k] = SATURATE( (gain*in_vector[k])>>right_shifts ) +// +// Input: +// - in_vector : Input vector +// - gain : Scaling gain +// - vector_length : Elements in the |in_vector| +// - right_shifts : Number of right bit shifts applied +// +// Output: +// - out_vector : Output vector (can be the same as |in_vector|) +// + +// +// WebRtcSpl_ScaleAndAddVectors(...) +// +// Performs the vector operation: +// out_vector[k] = (gain1*in_vector1[k])>>right_shifts1 +// + (gain2*in_vector2[k])>>right_shifts2 +// +// Input: +// - in_vector1 : Input vector 1 +// - gain1 : Gain to be used for vector 1 +// - right_shifts1 : Right bit shift to be used for vector 1 +// - in_vector2 : Input vector 2 +// - gain2 : Gain to be used for vector 2 +// - right_shifts2 : Right bit shift to be used for vector 2 +// - vector_length : Elements in the input vectors +// +// Output: +// - out_vector : Output vector +// + +// +// WebRtcSpl_ScaleAndAddVectorsWithRound(...) +// +// Performs the vector operation: +// +// out_vector[k] = ((scale1*in_vector1[k]) + (scale2*in_vector2[k]) +// + round_value) >> right_shifts +// +// where: +// +// round_value = (1<>1 +// +// Input: +// - in_vector1 : Input vector 1 +// - scale1 : Gain to be used for vector 1 +// - in_vector2 : Input vector 2 +// - scale2 : Gain to be used for vector 2 +// - right_shifts : Number of right bit shifts to be applied +// - vector_length : Number of elements in the input vectors +// +// Output: +// - out_vector : Output vector +// + +// +// WebRtcSpl_ReverseOrderMultArrayElements(...) +// +// Performs the vector operation: +// out_vector[n] = (in_vector[n]*window[-n])>>right_shifts +// +// Input: +// - in_vector : Input vector +// - window : Window vector (should be reversed). The pointer +// should be set to the last value in the vector +// - right_shifts : Number of right bit shift to be applied after the +// multiplication +// - vector_length : Number of elements in |in_vector| +// +// Output: +// - out_vector : Output vector (can be same as |in_vector|) +// + +// +// WebRtcSpl_ElementwiseVectorMult(...) +// +// Performs the vector operation: +// out_vector[n] = (in_vector[n]*window[n])>>right_shifts +// +// Input: +// - in_vector : Input vector +// - window : Window vector. +// - right_shifts : Number of right bit shift to be applied after the +// multiplication +// - vector_length : Number of elements in |in_vector| +// +// Output: +// - out_vector : Output vector (can be same as |in_vector|) +// + +// +// WebRtcSpl_AddVectorsAndShift(...) +// +// Performs the vector operation: +// out_vector[k] = (in_vector1[k] + in_vector2[k])>>right_shifts +// +// Input: +// - in_vector1 : Input vector 1 +// - in_vector2 : Input vector 2 +// - right_shifts : Number of right bit shift to be applied after the +// multiplication +// - vector_length : Number of elements in |in_vector1| and |in_vector2| +// +// Output: +// - out_vector : Output vector (can be same as |in_vector1|) +// + +// +// WebRtcSpl_AddAffineVectorToVector(...) +// +// Adds an affine transformed vector to another vector |out_vector|, i.e, +// performs +// out_vector[k] += (in_vector[k]*gain+add_constant)>>right_shifts +// +// Input: +// - in_vector : Input vector +// - gain : Gain value, used to multiply the in vector with +// - add_constant : Constant value to add (usually 1<<(right_shifts-1), +// but others can be used as well +// - right_shifts : Number of right bit shifts (0-16) +// - vector_length : Number of samples in |in_vector| and |out_vector| +// +// Output: +// - out_vector : Vector with the output +// + +// +// WebRtcSpl_AffineTransformVector(...) +// +// Affine transforms a vector, i.e, performs +// out_vector[k] = (in_vector[k]*gain+add_constant)>>right_shifts +// +// Input: +// - in_vector : Input vector +// - gain : Gain value, used to multiply the in vector with +// - add_constant : Constant value to add (usually 1<<(right_shifts-1), +// but others can be used as well +// - right_shifts : Number of right bit shifts (0-16) +// - vector_length : Number of samples in |in_vector| and |out_vector| +// +// Output: +// - out_vector : Vector with the output +// + +// +// WebRtcSpl_AutoCorrelation(...) +// +// A 32-bit fix-point implementation of auto-correlation computation +// +// Input: +// - vector : Vector to calculate autocorrelation upon +// - vector_length : Length (in samples) of |vector| +// - order : The order up to which the autocorrelation should be +// calculated +// +// Output: +// - result_vector : auto-correlation values (values should be seen +// relative to each other since the absolute values +// might have been down shifted to avoid overflow) +// +// - scale : The number of left shifts required to obtain the +// auto-correlation in Q0 +// +// Return value : Number of samples in |result_vector|, i.e., (order+1) +// + +// +// WebRtcSpl_LevinsonDurbin(...) +// +// A 32-bit fix-point implementation of the Levinson-Durbin algorithm that +// does NOT use the 64 bit class +// +// Input: +// - auto_corr : Vector with autocorrelation values of length >= +// |use_order|+1 +// - use_order : The LPC filter order (support up to order 20) +// +// Output: +// - lpc_coef : lpc_coef[0..use_order] LPC coefficients in Q12 +// - refl_coef : refl_coef[0...use_order-1]| Reflection coefficients in +// Q15 +// +// Return value : 1 for stable 0 for unstable +// + +// +// WebRtcSpl_ReflCoefToLpc(...) +// +// Converts reflection coefficients |refl_coef| to LPC coefficients |lpc_coef|. +// This version is a 16 bit operation. +// +// NOTE: The 16 bit refl_coef -> lpc_coef conversion might result in a +// "slightly unstable" filter (i.e., a pole just outside the unit circle) in +// "rare" cases even if the reflection coefficients are stable. +// +// Input: +// - refl_coef : Reflection coefficients in Q15 that should be converted +// to LPC coefficients +// - use_order : Number of coefficients in |refl_coef| +// +// Output: +// - lpc_coef : LPC coefficients in Q12 +// + +// +// WebRtcSpl_LpcToReflCoef(...) +// +// Converts LPC coefficients |lpc_coef| to reflection coefficients |refl_coef|. +// This version is a 16 bit operation. +// The conversion is implemented by the step-down algorithm. +// +// Input: +// - lpc_coef : LPC coefficients in Q12, that should be converted to +// reflection coefficients +// - use_order : Number of coefficients in |lpc_coef| +// +// Output: +// - refl_coef : Reflection coefficients in Q15. +// + +// +// WebRtcSpl_AutoCorrToReflCoef(...) +// +// Calculates reflection coefficients (16 bit) from auto-correlation values +// +// Input: +// - auto_corr : Auto-correlation values +// - use_order : Number of coefficients wanted be calculated +// +// Output: +// - refl_coef : Reflection coefficients in Q15. +// + +// +// WebRtcSpl_CrossCorrelation(...) +// +// Calculates the cross-correlation between two sequences |vector1| and +// |vector2|. |vector1| is fixed and |vector2| slides as the pointer is +// increased with the amount |step_vector2| +// +// Input: +// - vector1 : First sequence (fixed throughout the correlation) +// - vector2 : Second sequence (slides |step_vector2| for each +// new correlation) +// - dim_vector : Number of samples to use in the cross-correlation +// - dim_cross_corr : Number of cross-correlations to calculate (the +// start position for |vector2| is updated for each +// new one) +// - right_shifts : Number of right bit shifts to use. This will +// become the output Q-domain. +// - step_vector2 : How many (positive or negative) steps the +// |vector2| pointer should be updated for each new +// cross-correlation value. +// +// Output: +// - cross_corr : The cross-correlation in Q(-right_shifts) +// + +// +// WebRtcSpl_GetHanningWindow(...) +// +// Creates (the first half of) a Hanning window. Size must be at least 1 and +// at most 512. +// +// Input: +// - size : Length of the requested Hanning window (1 to 512) +// +// Output: +// - window : Hanning vector in Q14. +// + +// +// WebRtcSpl_SqrtOfOneMinusXSquared(...) +// +// Calculates y[k] = sqrt(1 - x[k]^2) for each element of the input vector +// |in_vector|. Input and output values are in Q15. +// +// Inputs: +// - in_vector : Values to calculate sqrt(1 - x^2) of +// - vector_length : Length of vector |in_vector| +// +// Output: +// - out_vector : Output values in Q15 +// + +// +// WebRtcSpl_IncreaseSeed(...) +// +// Increases the seed (and returns the new value) +// +// Input: +// - seed : Seed for random calculation +// +// Output: +// - seed : Updated seed value +// +// Return value : The new seed value +// + +// +// WebRtcSpl_RandU(...) +// +// Produces a uniformly distributed value in the WebRtc_Word16 range +// +// Input: +// - seed : Seed for random calculation +// +// Output: +// - seed : Updated seed value +// +// Return value : Uniformly distributed value in the range +// [Word16_MIN...Word16_MAX] +// + +// +// WebRtcSpl_RandN(...) +// +// Produces a normal distributed value in the WebRtc_Word16 range +// +// Input: +// - seed : Seed for random calculation +// +// Output: +// - seed : Updated seed value +// +// Return value : N(0,1) value in the Q13 domain +// + +// +// WebRtcSpl_RandUArray(...) +// +// Produces a uniformly distributed vector with elements in the WebRtc_Word16 +// range +// +// Input: +// - vector_length : Samples wanted in the vector +// - seed : Seed for random calculation +// +// Output: +// - vector : Vector with the uniform values +// - seed : Updated seed value +// +// Return value : Number of samples in vector, i.e., |vector_length| +// + +// +// WebRtcSpl_Sqrt(...) +// +// Returns the square root of the input value |value|. The precision of this +// function is integer precision, i.e., sqrt(8) gives 2 as answer. +// If |value| is a negative number then 0 is returned. +// +// Algorithm: +// +// A sixth order Taylor Series expansion is used here to compute the square +// root of a number y^0.5 = (1+x)^0.5 +// where +// x = y-1 +// = 1+(x/2)-0.5*((x/2)^2+0.5*((x/2)^3-0.625*((x/2)^4+0.875*((x/2)^5) +// 0.5 <= x < 1 +// +// Input: +// - value : Value to calculate sqrt of +// +// Return value : Result of the sqrt calculation +// + +// +// WebRtcSpl_SqrtFloor(...) +// +// Returns the square root of the input value |value|. The precision of this +// function is rounding down integer precision, i.e., sqrt(8) gives 2 as answer. +// If |value| is a negative number then 0 is returned. +// +// Algorithm: +// +// An iterative 4 cylce/bit routine +// +// Input: +// - value : Value to calculate sqrt of +// +// Return value : Result of the sqrt calculation +// + +// +// WebRtcSpl_DivU32U16(...) +// +// Divides a WebRtc_UWord32 |num| by a WebRtc_UWord16 |den|. +// +// If |den|==0, (WebRtc_UWord32)0xFFFFFFFF is returned. +// +// Input: +// - num : Numerator +// - den : Denominator +// +// Return value : Result of the division (as a WebRtc_UWord32), i.e., the +// integer part of num/den. +// + +// +// WebRtcSpl_DivW32W16(...) +// +// Divides a WebRtc_Word32 |num| by a WebRtc_Word16 |den|. +// +// If |den|==0, (WebRtc_Word32)0x7FFFFFFF is returned. +// +// Input: +// - num : Numerator +// - den : Denominator +// +// Return value : Result of the division (as a WebRtc_Word32), i.e., the +// integer part of num/den. +// + +// +// WebRtcSpl_DivW32W16ResW16(...) +// +// Divides a WebRtc_Word32 |num| by a WebRtc_Word16 |den|, assuming that the +// result is less than 32768, otherwise an unpredictable result will occur. +// +// If |den|==0, (WebRtc_Word16)0x7FFF is returned. +// +// Input: +// - num : Numerator +// - den : Denominator +// +// Return value : Result of the division (as a WebRtc_Word16), i.e., the +// integer part of num/den. +// + +// +// WebRtcSpl_DivResultInQ31(...) +// +// Divides a WebRtc_Word32 |num| by a WebRtc_Word16 |den|, assuming that the +// absolute value of the denominator is larger than the numerator, otherwise +// an unpredictable result will occur. +// +// Input: +// - num : Numerator +// - den : Denominator +// +// Return value : Result of the division in Q31. +// + +// +// WebRtcSpl_DivW32HiLow(...) +// +// Divides a WebRtc_Word32 |num| by a denominator in hi, low format. The +// absolute value of the denominator has to be larger (or equal to) the +// numerator. +// +// Input: +// - num : Numerator +// - den_hi : High part of denominator +// - den_low : Low part of denominator +// +// Return value : Divided value in Q31 +// + +// +// WebRtcSpl_Energy(...) +// +// Calculates the energy of a vector +// +// Input: +// - vector : Vector which the energy should be calculated on +// - vector_length : Number of samples in vector +// +// Output: +// - scale_factor : Number of left bit shifts needed to get the physical +// energy value, i.e, to get the Q0 value +// +// Return value : Energy value in Q(-|scale_factor|) +// + +// +// WebRtcSpl_FilterAR(...) +// +// Performs a 32-bit AR filtering on a vector in Q12 +// +// Input: +// - ar_coef : AR-coefficient vector (values in Q12), +// ar_coef[0] must be 4096. +// - ar_coef_length : Number of coefficients in |ar_coef|. +// - in_vector : Vector to be filtered. +// - in_vector_length : Number of samples in |in_vector|. +// - filter_state : Current state (higher part) of the filter. +// - filter_state_length : Length (in samples) of |filter_state|. +// - filter_state_low : Current state (lower part) of the filter. +// - filter_state_low_length : Length (in samples) of |filter_state_low|. +// - out_vector_low_length : Maximum length (in samples) of +// |out_vector_low|. +// +// Output: +// - filter_state : Updated state (upper part) vector. +// - filter_state_low : Updated state (lower part) vector. +// - out_vector : Vector containing the upper part of the +// filtered values. +// - out_vector_low : Vector containing the lower part of the +// filtered values. +// +// Return value : Number of samples in the |out_vector|. +// + +// +// WebRtcSpl_FilterMAFastQ12(...) +// +// Performs a MA filtering on a vector in Q12 +// +// Input: +// - in_vector : Input samples (state in positions +// in_vector[-order] .. in_vector[-1]) +// - ma_coef : Filter coefficients (in Q12) +// - ma_coef_length : Number of B coefficients (order+1) +// - vector_length : Number of samples to be filtered +// +// Output: +// - out_vector : Filtered samples +// + +// +// WebRtcSpl_FilterARFastQ12(...) +// +// Performs a AR filtering on a vector in Q12 +// +// Input: +// - in_vector : Input samples +// - out_vector : State information in positions +// out_vector[-order] .. out_vector[-1] +// - ar_coef : Filter coefficients (in Q12) +// - ar_coef_length : Number of B coefficients (order+1) +// - vector_length : Number of samples to be filtered +// +// Output: +// - out_vector : Filtered samples +// + +// +// WebRtcSpl_DownsampleFast(...) +// +// Performs a MA down sampling filter on a vector +// +// Input: +// - in_vector : Input samples (state in positions +// in_vector[-order] .. in_vector[-1]) +// - in_vector_length : Number of samples in |in_vector| to be filtered. +// This must be at least +// |delay| + |factor|*(|out_vector_length|-1) + 1) +// - out_vector_length : Number of down sampled samples desired +// - ma_coef : Filter coefficients (in Q12) +// - ma_coef_length : Number of B coefficients (order+1) +// - factor : Decimation factor +// - delay : Delay of filter (compensated for in out_vector) +// +// Output: +// - out_vector : Filtered samples +// +// Return value : 0 if OK, -1 if |in_vector| is too short +// + +// +// WebRtcSpl_DotProductWithScale(...) +// +// Calculates the dot product between two (WebRtc_Word16) vectors +// +// Input: +// - vector1 : Vector 1 +// - vector2 : Vector 2 +// - vector_length : Number of samples used in the dot product +// - scaling : The number of right bit shifts to apply on each term +// during calculation to avoid overflow, i.e., the +// output will be in Q(-|scaling|) +// +// Return value : The dot product in Q(-scaling) +// + +// +// WebRtcSpl_ComplexIFFT(...) +// +// Complex Inverse FFT +// +// Computes an inverse complex 2^|stages|-point FFT on the input vector, which +// is in bit-reversed order. The original content of the vector is destroyed in +// the process, since the input is overwritten by the output, normal-ordered, +// FFT vector. With X as the input complex vector, y as the output complex +// vector and with M = 2^|stages|, the following is computed: +// +// M-1 +// y(k) = sum[X(i)*[cos(2*pi*i*k/M) + j*sin(2*pi*i*k/M)]] +// i=0 +// +// The implementations are optimized for speed, not for code size. It uses the +// decimation-in-time algorithm with radix-2 butterfly technique. +// +// Input: +// - vector : In pointer to complex vector containing 2^|stages| +// real elements interleaved with 2^|stages| imaginary +// elements. +// [ReImReImReIm....] +// The elements are in Q(-scale) domain, see more on Return +// Value below. +// +// - stages : Number of FFT stages. Must be at least 3 and at most 10, +// since the table WebRtcSpl_kSinTable1024[] is 1024 +// elements long. +// +// - mode : This parameter gives the user to choose how the FFT +// should work. +// mode==0: Low-complexity and Low-accuracy mode +// mode==1: High-complexity and High-accuracy mode +// +// Output: +// - vector : Out pointer to the FFT vector (the same as input). +// +// Return Value : The scale value that tells the number of left bit shifts +// that the elements in the |vector| should be shifted with +// in order to get Q0 values, i.e. the physically correct +// values. The scale parameter is always 0 or positive, +// except if N>1024 (|stages|>10), which returns a scale +// value of -1, indicating error. +// + +// +// WebRtcSpl_ComplexFFT(...) +// +// Complex FFT +// +// Computes a complex 2^|stages|-point FFT on the input vector, which is in +// bit-reversed order. The original content of the vector is destroyed in +// the process, since the input is overwritten by the output, normal-ordered, +// FFT vector. With x as the input complex vector, Y as the output complex +// vector and with M = 2^|stages|, the following is computed: +// +// M-1 +// Y(k) = 1/M * sum[x(i)*[cos(2*pi*i*k/M) + j*sin(2*pi*i*k/M)]] +// i=0 +// +// The implementations are optimized for speed, not for code size. It uses the +// decimation-in-time algorithm with radix-2 butterfly technique. +// +// This routine prevents overflow by scaling by 2 before each FFT stage. This is +// a fixed scaling, for proper normalization - there will be log2(n) passes, so +// this results in an overall factor of 1/n, distributed to maximize arithmetic +// accuracy. +// +// Input: +// - vector : In pointer to complex vector containing 2^|stages| real +// elements interleaved with 2^|stages| imaginary elements. +// [ReImReImReIm....] +// The output is in the Q0 domain. +// +// - stages : Number of FFT stages. Must be at least 3 and at most 10, +// since the table WebRtcSpl_kSinTable1024[] is 1024 +// elements long. +// +// - mode : This parameter gives the user to choose how the FFT +// should work. +// mode==0: Low-complexity and Low-accuracy mode +// mode==1: High-complexity and High-accuracy mode +// +// Output: +// - vector : The output FFT vector is in the Q0 domain. +// +// Return value : The scale parameter is always 0, except if N>1024, +// which returns a scale value of -1, indicating error. +// + +// +// WebRtcSpl_ComplexBitReverse(...) +// +// Complex Bit Reverse +// +// This function bit-reverses the position of elements in the complex input +// vector into the output vector. +// +// If you bit-reverse a linear-order array, you obtain a bit-reversed order +// array. If you bit-reverse a bit-reversed order array, you obtain a +// linear-order array. +// +// Input: +// - vector : In pointer to complex vector containing 2^|stages| real +// elements interleaved with 2^|stages| imaginary elements. +// [ReImReImReIm....] +// - stages : Number of FFT stages. Must be at least 3 and at most 10, +// since the table WebRtcSpl_kSinTable1024[] is 1024 +// elements long. +// +// Output: +// - vector : Out pointer to complex vector in bit-reversed order. +// The input vector is over written. +// + +// +// WebRtcSpl_AnalysisQMF(...) +// +// Splits a 0-2*F Hz signal into two sub bands: 0-F Hz and F-2*F Hz. The +// current version has F = 8000, therefore, a super-wideband audio signal is +// split to lower-band 0-8 kHz and upper-band 8-16 kHz. +// +// Input: +// - in_data : Wide band speech signal, 320 samples (10 ms) +// +// Input & Output: +// - filter_state1 : Filter state for first All-pass filter +// - filter_state2 : Filter state for second All-pass filter +// +// Output: +// - low_band : Lower-band signal 0-8 kHz band, 160 samples (10 ms) +// - high_band : Upper-band signal 8-16 kHz band (flipped in frequency +// domain), 160 samples (10 ms) +// + +// +// WebRtcSpl_SynthesisQMF(...) +// +// Combines the two sub bands (0-F and F-2*F Hz) into a signal of 0-2*F +// Hz, (current version has F = 8000 Hz). So the filter combines lower-band +// (0-8 kHz) and upper-band (8-16 kHz) channels to obtain super-wideband 0-16 +// kHz audio. +// +// Input: +// - low_band : The signal with the 0-8 kHz band, 160 samples (10 ms) +// - high_band : The signal with the 8-16 kHz band, 160 samples (10 ms) +// +// Input & Output: +// - filter_state1 : Filter state for first All-pass filter +// - filter_state2 : Filter state for second All-pass filter +// +// Output: +// - out_data : Super-wideband speech signal, 0-16 kHz +// + +// WebRtc_Word16 WebRtcSpl_get_version(...) +// +// This function gives the version string of the Signal Processing Library. +// +// Input: +// - length_in_bytes : The size of Allocated space (in Bytes) where +// the version number is written to (in string format). +// +// Output: +// - version : Pointer to a buffer where the version number is written to. +// diff --git a/src/common_audio/signal_processing_library/main/interface/spl_inl.h b/src/common_audio/signal_processing_library/main/interface/spl_inl.h new file mode 100644 index 0000000..e9edd87 --- /dev/null +++ b/src/common_audio/signal_processing_library/main/interface/spl_inl.h @@ -0,0 +1,166 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + + +// This header file includes the inline functions in +// the fix point signal processing library. + +#ifndef WEBRTC_SPL_SPL_INL_H_ +#define WEBRTC_SPL_SPL_INL_H_ + +#ifdef WEBRTC_ARCH_ARM_V7A +#include "spl_inl_armv7.h" +#else + +static __inline WebRtc_Word16 WebRtcSpl_AddSatW16(WebRtc_Word16 a, + WebRtc_Word16 b) { + WebRtc_Word32 s_sum = (WebRtc_Word32) a + (WebRtc_Word32) b; + + if (s_sum > WEBRTC_SPL_WORD16_MAX) + s_sum = WEBRTC_SPL_WORD16_MAX; + else if (s_sum < WEBRTC_SPL_WORD16_MIN) + s_sum = WEBRTC_SPL_WORD16_MIN; + + return (WebRtc_Word16)s_sum; +} + +static __inline WebRtc_Word32 WebRtcSpl_AddSatW32(WebRtc_Word32 l_var1, + WebRtc_Word32 l_var2) { + WebRtc_Word32 l_sum; + + // perform long addition + l_sum = l_var1 + l_var2; + + // check for under or overflow + if (WEBRTC_SPL_IS_NEG(l_var1)) { + if (WEBRTC_SPL_IS_NEG(l_var2) && !WEBRTC_SPL_IS_NEG(l_sum)) { + l_sum = (WebRtc_Word32)0x80000000; + } + } else { + if (!WEBRTC_SPL_IS_NEG(l_var2) && WEBRTC_SPL_IS_NEG(l_sum)) { + l_sum = (WebRtc_Word32)0x7FFFFFFF; + } + } + + return l_sum; +} + +static __inline WebRtc_Word16 WebRtcSpl_SubSatW16(WebRtc_Word16 var1, + WebRtc_Word16 var2) { + WebRtc_Word32 l_diff; + WebRtc_Word16 s_diff; + + // perform subtraction + l_diff = (WebRtc_Word32)var1 - (WebRtc_Word32)var2; + + // default setting + s_diff = (WebRtc_Word16) l_diff; + + // check for overflow + if (l_diff > (WebRtc_Word32)32767) + s_diff = (WebRtc_Word16)32767; + + // check for underflow + if (l_diff < (WebRtc_Word32)-32768) + s_diff = (WebRtc_Word16)-32768; + + return s_diff; +} + +static __inline WebRtc_Word32 WebRtcSpl_SubSatW32(WebRtc_Word32 l_var1, + WebRtc_Word32 l_var2) { + WebRtc_Word32 l_diff; + + // perform subtraction + l_diff = l_var1 - l_var2; + + // check for underflow + if ((l_var1 < 0) && (l_var2 > 0) && (l_diff > 0)) + l_diff = (WebRtc_Word32)0x80000000; + // check for overflow + if ((l_var1 > 0) && (l_var2 < 0) && (l_diff < 0)) + l_diff = (WebRtc_Word32)0x7FFFFFFF; + + return l_diff; +} + +static __inline WebRtc_Word16 WebRtcSpl_GetSizeInBits(WebRtc_UWord32 n) { + int bits; + + if (0xFFFF0000 & n) { + bits = 16; + } else { + bits = 0; + } + if (0x0000FF00 & (n >> bits)) bits += 8; + if (0x000000F0 & (n >> bits)) bits += 4; + if (0x0000000C & (n >> bits)) bits += 2; + if (0x00000002 & (n >> bits)) bits += 1; + if (0x00000001 & (n >> bits)) bits += 1; + + return bits; +} + +static __inline int WebRtcSpl_NormW32(WebRtc_Word32 a) { + int zeros; + + if (a <= 0) a ^= 0xFFFFFFFF; + + if (!(0xFFFF8000 & a)) { + zeros = 16; + } else { + zeros = 0; + } + if (!(0xFF800000 & (a << zeros))) zeros += 8; + if (!(0xF8000000 & (a << zeros))) zeros += 4; + if (!(0xE0000000 & (a << zeros))) zeros += 2; + if (!(0xC0000000 & (a << zeros))) zeros += 1; + + return zeros; +} + +static __inline int WebRtcSpl_NormU32(WebRtc_UWord32 a) { + int zeros; + + if (a == 0) return 0; + + if (!(0xFFFF0000 & a)) { + zeros = 16; + } else { + zeros = 0; + } + if (!(0xFF000000 & (a << zeros))) zeros += 8; + if (!(0xF0000000 & (a << zeros))) zeros += 4; + if (!(0xC0000000 & (a << zeros))) zeros += 2; + if (!(0x80000000 & (a << zeros))) zeros += 1; + + return zeros; +} + +static __inline int WebRtcSpl_NormW16(WebRtc_Word16 a) { + int zeros; + + if (a <= 0) a ^= 0xFFFF; + + if (!(0xFF80 & a)) { + zeros = 8; + } else { + zeros = 0; + } + if (!(0xF800 & (a << zeros))) zeros += 4; + if (!(0xE000 & (a << zeros))) zeros += 2; + if (!(0xC000 & (a << zeros))) zeros += 1; + + return zeros; +} + +#endif // WEBRTC_ARCH_ARM_V7A + +#endif // WEBRTC_SPL_SPL_INL_H_ diff --git a/src/common_audio/signal_processing_library/main/interface/spl_inl_armv7.h b/src/common_audio/signal_processing_library/main/interface/spl_inl_armv7.h new file mode 100644 index 0000000..5d94936 --- /dev/null +++ b/src/common_audio/signal_processing_library/main/interface/spl_inl_armv7.h @@ -0,0 +1,122 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + + +// This header file includes the inline functions for ARM processors in +// the fix point signal processing library. + +#ifndef WEBRTC_SPL_SPL_INL_ARMV7_H_ +#define WEBRTC_SPL_SPL_INL_ARMV7_H_ + +static __inline WebRtc_Word32 WEBRTC_SPL_MUL_16_32_RSFT16(WebRtc_Word16 a, + WebRtc_Word32 b) { + WebRtc_Word32 tmp; + __asm__("smulwb %0, %1, %2":"=r"(tmp):"r"(b), "r"(a)); + return tmp; +} + +static __inline WebRtc_Word32 WEBRTC_SPL_MUL_32_32_RSFT32(WebRtc_Word16 a, + WebRtc_Word16 b, + WebRtc_Word32 c) { + WebRtc_Word32 tmp; + __asm__("pkhbt %0, %1, %2, lsl #16" : "=r"(tmp) : "r"(b), "r"(a)); + __asm__("smmul %0, %1, %2":"=r"(tmp):"r"(tmp), "r"(c)); + return tmp; +} + +static __inline WebRtc_Word32 WEBRTC_SPL_MUL_32_32_RSFT32BI(WebRtc_Word32 a, + WebRtc_Word32 b) { + WebRtc_Word32 tmp; + __asm__("smmul %0, %1, %2":"=r"(tmp):"r"(a), "r"(b)); + return tmp; +} + +static __inline WebRtc_Word32 WEBRTC_SPL_MUL_16_16(WebRtc_Word16 a, + WebRtc_Word16 b) { + WebRtc_Word32 tmp; + __asm__("smulbb %0, %1, %2":"=r"(tmp):"r"(a), "r"(b)); + return tmp; +} + +static __inline WebRtc_Word16 WebRtcSpl_AddSatW16(WebRtc_Word16 a, + WebRtc_Word16 b) { + WebRtc_Word32 s_sum; + + __asm__("qadd16 %0, %1, %2":"=r"(s_sum):"r"(a), "r"(b)); + + return (WebRtc_Word16) s_sum; +} + +static __inline WebRtc_Word32 WebRtcSpl_AddSatW32(WebRtc_Word32 l_var1, + WebRtc_Word32 l_var2) { + WebRtc_Word32 l_sum; + + __asm__("qadd %0, %1, %2":"=r"(l_sum):"r"(l_var1), "r"(l_var2)); + + return l_sum; +} + +static __inline WebRtc_Word16 WebRtcSpl_SubSatW16(WebRtc_Word16 var1, + WebRtc_Word16 var2) { + WebRtc_Word32 s_sub; + + __asm__("qsub16 %0, %1, %2":"=r"(s_sub):"r"(var1), "r"(var2)); + + return (WebRtc_Word16)s_sub; +} + +static __inline WebRtc_Word32 WebRtcSpl_SubSatW32(WebRtc_Word32 l_var1, + WebRtc_Word32 l_var2) { + WebRtc_Word32 l_sub; + + __asm__("qsub %0, %1, %2":"=r"(l_sub):"r"(l_var1), "r"(l_var2)); + + return l_sub; +} + +static __inline WebRtc_Word16 WebRtcSpl_GetSizeInBits(WebRtc_UWord32 n) { + WebRtc_Word32 tmp; + + __asm__("clz %0, %1":"=r"(tmp):"r"(n)); + + return (WebRtc_Word16)(32 - tmp); +} + +static __inline int WebRtcSpl_NormW32(WebRtc_Word32 a) { + WebRtc_Word32 tmp; + + if (a <= 0) a ^= 0xFFFFFFFF; + + __asm__("clz %0, %1":"=r"(tmp):"r"(a)); + + return tmp - 1; +} + +static __inline int WebRtcSpl_NormU32(WebRtc_UWord32 a) { + int tmp; + + if (a == 0) return 0; + + __asm__("clz %0, %1":"=r"(tmp):"r"(a)); + + return tmp; +} + +static __inline int WebRtcSpl_NormW16(WebRtc_Word16 a) { + WebRtc_Word32 tmp; + + if (a <= 0) a ^= 0xFFFFFFFF; + + __asm__("clz %0, %1":"=r"(tmp):"r"(a)); + + return tmp - 17; +} + +#endif // WEBRTC_SPL_SPL_INL_ARMV7_H_ diff --git a/src/common_audio/signal_processing_library/main/source/auto_corr_to_refl_coef.c b/src/common_audio/signal_processing_library/main/source/auto_corr_to_refl_coef.c new file mode 100644 index 0000000..b7e8858 --- /dev/null +++ b/src/common_audio/signal_processing_library/main/source/auto_corr_to_refl_coef.c @@ -0,0 +1,103 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + + +/* + * This file contains the function WebRtcSpl_AutoCorrToReflCoef(). + * The description header can be found in signal_processing_library.h + * + */ + +#include "signal_processing_library.h" + +void WebRtcSpl_AutoCorrToReflCoef(G_CONST WebRtc_Word32 *R, int use_order, WebRtc_Word16 *K) +{ + int i, n; + WebRtc_Word16 tmp; + G_CONST WebRtc_Word32 *rptr; + WebRtc_Word32 L_num, L_den; + WebRtc_Word16 *acfptr, *pptr, *wptr, *p1ptr, *w1ptr, ACF[WEBRTC_SPL_MAX_LPC_ORDER], + P[WEBRTC_SPL_MAX_LPC_ORDER], W[WEBRTC_SPL_MAX_LPC_ORDER]; + + // Initialize loop and pointers. + acfptr = ACF; + rptr = R; + pptr = P; + p1ptr = &P[1]; + w1ptr = &W[1]; + wptr = w1ptr; + + // First loop; n=0. Determine shifting. + tmp = WebRtcSpl_NormW32(*R); + *acfptr = (WebRtc_Word16)((*rptr++ << tmp) >> 16); + *pptr++ = *acfptr++; + + // Initialize ACF, P and W. + for (i = 1; i <= use_order; i++) + { + *acfptr = (WebRtc_Word16)((*rptr++ << tmp) >> 16); + *wptr++ = *acfptr; + *pptr++ = *acfptr++; + } + + // Compute reflection coefficients. + for (n = 1; n <= use_order; n++, K++) + { + tmp = WEBRTC_SPL_ABS_W16(*p1ptr); + if (*P < tmp) + { + for (i = n; i <= use_order; i++) + *K++ = 0; + + return; + } + + // Division: WebRtcSpl_div(tmp, *P) + *K = 0; + if (tmp != 0) + { + L_num = tmp; + L_den = *P; + i = 15; + while (i--) + { + (*K) <<= 1; + L_num <<= 1; + if (L_num >= L_den) + { + L_num -= L_den; + (*K)++; + } + } + if (*p1ptr > 0) + *K = -*K; + } + + // Last iteration; don't do Schur recursion. + if (n == use_order) + return; + + // Schur recursion. + pptr = P; + wptr = w1ptr; + tmp = (WebRtc_Word16)(((WebRtc_Word32)*p1ptr * (WebRtc_Word32)*K + 16384) >> 15); + *pptr = WEBRTC_SPL_ADD_SAT_W16( *pptr, tmp ); + pptr++; + for (i = 1; i <= use_order - n; i++) + { + tmp = (WebRtc_Word16)(((WebRtc_Word32)*wptr * (WebRtc_Word32)*K + 16384) >> 15); + *pptr = WEBRTC_SPL_ADD_SAT_W16( *(pptr+1), tmp ); + pptr++; + tmp = (WebRtc_Word16)(((WebRtc_Word32)*pptr * (WebRtc_Word32)*K + 16384) >> 15); + *wptr = WEBRTC_SPL_ADD_SAT_W16( *wptr, tmp ); + wptr++; + } + } +} diff --git a/src/common_audio/signal_processing_library/main/source/auto_correlation.c b/src/common_audio/signal_processing_library/main/source/auto_correlation.c new file mode 100644 index 0000000..a00fde4 --- /dev/null +++ b/src/common_audio/signal_processing_library/main/source/auto_correlation.c @@ -0,0 +1,141 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + + +/* + * This file contains the function WebRtcSpl_AutoCorrelation(). + * The description header can be found in signal_processing_library.h + * + */ + +#include "signal_processing_library.h" + +int WebRtcSpl_AutoCorrelation(G_CONST WebRtc_Word16* in_vector, + int in_vector_length, + int order, + WebRtc_Word32* result, + int* scale) +{ + WebRtc_Word32 sum; + int i, j; + WebRtc_Word16 smax; // Sample max + G_CONST WebRtc_Word16* xptr1; + G_CONST WebRtc_Word16* xptr2; + WebRtc_Word32* resultptr; + int scaling = 0; + +#ifdef _ARM_OPT_ +#pragma message("NOTE: _ARM_OPT_ optimizations are used") + WebRtc_Word16 loops4; +#endif + + if (order < 0) + order = in_vector_length; + + // Find the max. sample + smax = WebRtcSpl_MaxAbsValueW16(in_vector, in_vector_length); + + // In order to avoid overflow when computing the sum we should scale the samples so that + // (in_vector_length * smax * smax) will not overflow. + + if (smax == 0) + { + scaling = 0; + } else + { + int nbits = WebRtcSpl_GetSizeInBits(in_vector_length); // # of bits in the sum loop + int t = WebRtcSpl_NormW32(WEBRTC_SPL_MUL(smax, smax)); // # of bits to normalize smax + + if (t > nbits) + { + scaling = 0; + } else + { + scaling = nbits - t; + } + + } + + resultptr = result; + + // Perform the actual correlation calculation + for (i = 0; i < order + 1; i++) + { + int loops = (in_vector_length - i); + sum = 0; + xptr1 = in_vector; + xptr2 = &in_vector[i]; +#ifndef _ARM_OPT_ + for (j = loops; j > 0; j--) + { + sum += WEBRTC_SPL_MUL_16_16_RSFT(*xptr1++, *xptr2++, scaling); + } +#else + loops4 = (loops >> 2) << 2; + + if (scaling == 0) + { + for (j = 0; j < loops4; j = j + 4) + { + sum += WEBRTC_SPL_MUL_16_16(*xptr1, *xptr2); + xptr1++; + xptr2++; + sum += WEBRTC_SPL_MUL_16_16(*xptr1, *xptr2); + xptr1++; + xptr2++; + sum += WEBRTC_SPL_MUL_16_16(*xptr1, *xptr2); + xptr1++; + xptr2++; + sum += WEBRTC_SPL_MUL_16_16(*xptr1, *xptr2); + xptr1++; + xptr2++; + } + + for (j = loops4; j < loops; j++) + { + sum += WEBRTC_SPL_MUL_16_16(*xptr1, *xptr2); + xptr1++; + xptr2++; + } + } + else + { + for (j = 0; j < loops4; j = j + 4) + { + sum += WEBRTC_SPL_MUL_16_16_RSFT(*xptr1, *xptr2, scaling); + xptr1++; + xptr2++; + sum += WEBRTC_SPL_MUL_16_16_RSFT(*xptr1, *xptr2, scaling); + xptr1++; + xptr2++; + sum += WEBRTC_SPL_MUL_16_16_RSFT(*xptr1, *xptr2, scaling); + xptr1++; + xptr2++; + sum += WEBRTC_SPL_MUL_16_16_RSFT(*xptr1, *xptr2, scaling); + xptr1++; + xptr2++; + } + + for (j = loops4; j < loops; j++) + { + sum += WEBRTC_SPL_MUL_16_16_RSFT(*xptr1, *xptr2, scaling); + xptr1++; + xptr2++; + } + } + +#endif + *resultptr++ = sum; + } + + *scale = scaling; + + return order + 1; +} diff --git a/src/common_audio/signal_processing_library/main/source/complex_bit_reverse.c b/src/common_audio/signal_processing_library/main/source/complex_bit_reverse.c new file mode 100644 index 0000000..85c76f8 --- /dev/null +++ b/src/common_audio/signal_processing_library/main/source/complex_bit_reverse.c @@ -0,0 +1,51 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + + +/* + * This file contains the function WebRtcSpl_ComplexBitReverse(). + * The description header can be found in signal_processing_library.h + * + */ + +#include "signal_processing_library.h" + +void WebRtcSpl_ComplexBitReverse(WebRtc_Word16 frfi[], int stages) +{ + int mr, nn, n, l, m; + WebRtc_Word16 tr, ti; + + n = 1 << stages; + + mr = 0; + nn = n - 1; + + // decimation in time - re-order data + for (m = 1; m <= nn; ++m) + { + l = n; + do + { + l >>= 1; + } while (mr + l > nn); + mr = (mr & (l - 1)) + l; + + if (mr <= m) + continue; + + tr = frfi[2 * m]; + frfi[2 * m] = frfi[2 * mr]; + frfi[2 * mr] = tr; + + ti = frfi[2 * m + 1]; + frfi[2 * m + 1] = frfi[2 * mr + 1]; + frfi[2 * mr + 1] = ti; + } +} diff --git a/src/common_audio/signal_processing_library/main/source/complex_fft.c b/src/common_audio/signal_processing_library/main/source/complex_fft.c new file mode 100644 index 0000000..bcaa076 --- /dev/null +++ b/src/common_audio/signal_processing_library/main/source/complex_fft.c @@ -0,0 +1,150 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + + +/* + * This file contains the function WebRtcSpl_ComplexFFT(). + * The description header can be found in signal_processing_library.h + * + */ + +#include "signal_processing_library.h" + +#define CFFTSFT 14 +#define CFFTRND 1 +#define CFFTRND2 16384 + +int WebRtcSpl_ComplexFFT(WebRtc_Word16 frfi[], int stages, int mode) +{ + int i, j, l, k, istep, n, m; + WebRtc_Word16 wr, wi; + WebRtc_Word32 tr32, ti32, qr32, qi32; + + /* The 1024-value is a constant given from the size of WebRtcSpl_kSinTable1024[], + * and should not be changed depending on the input parameter 'stages' + */ + n = 1 << stages; + if (n > 1024) + return -1; + + l = 1; + k = 10 - 1; /* Constant for given WebRtcSpl_kSinTable1024[]. Do not change + depending on the input parameter 'stages' */ + + if (mode == 0) + { + // mode==0: Low-complexity and Low-accuracy mode + while (l < n) + { + istep = l << 1; + + for (m = 0; m < l; ++m) + { + j = m << k; + + /* The 256-value is a constant given as 1/4 of the size of + * WebRtcSpl_kSinTable1024[], and should not be changed depending on the input + * parameter 'stages'. It will result in 0 <= j < N_SINE_WAVE/2 + */ + wr = WebRtcSpl_kSinTable1024[j + 256]; + wi = -WebRtcSpl_kSinTable1024[j]; + + for (i = m; i < n; i += istep) + { + j = i + l; + + tr32 = WEBRTC_SPL_RSHIFT_W32((WEBRTC_SPL_MUL_16_16(wr, frfi[2 * j]) + - WEBRTC_SPL_MUL_16_16(wi, frfi[2 * j + 1])), 15); + + ti32 = WEBRTC_SPL_RSHIFT_W32((WEBRTC_SPL_MUL_16_16(wr, frfi[2 * j + 1]) + + WEBRTC_SPL_MUL_16_16(wi, frfi[2 * j])), 15); + + qr32 = (WebRtc_Word32)frfi[2 * i]; + qi32 = (WebRtc_Word32)frfi[2 * i + 1]; + frfi[2 * j] = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32(qr32 - tr32, 1); + frfi[2 * j + 1] = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32(qi32 - ti32, 1); + frfi[2 * i] = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32(qr32 + tr32, 1); + frfi[2 * i + 1] = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32(qi32 + ti32, 1); + } + } + + --k; + l = istep; + + } + + } else + { + // mode==1: High-complexity and High-accuracy mode + while (l < n) + { + istep = l << 1; + + for (m = 0; m < l; ++m) + { + j = m << k; + + /* The 256-value is a constant given as 1/4 of the size of + * WebRtcSpl_kSinTable1024[], and should not be changed depending on the input + * parameter 'stages'. It will result in 0 <= j < N_SINE_WAVE/2 + */ + wr = WebRtcSpl_kSinTable1024[j + 256]; + wi = -WebRtcSpl_kSinTable1024[j]; + +#ifdef WEBRTC_ARCH_ARM_V7A + WebRtc_Word32 wri; + WebRtc_Word32 frfi_r; + __asm__("pkhbt %0, %1, %2, lsl #16" : "=r"(wri) : + "r"((WebRtc_Word32)wr), "r"((WebRtc_Word32)wi)); +#endif + + for (i = m; i < n; i += istep) + { + j = i + l; + +#ifdef WEBRTC_ARCH_ARM_V7A + __asm__("pkhbt %0, %1, %2, lsl #16" : "=r"(frfi_r) : + "r"((WebRtc_Word32)frfi[2*j]), "r"((WebRtc_Word32)frfi[2*j +1])); + __asm__("smlsd %0, %1, %2, %3" : "=r"(tr32) : + "r"(wri), "r"(frfi_r), "r"(CFFTRND)); + __asm__("smladx %0, %1, %2, %3" : "=r"(ti32) : + "r"(wri), "r"(frfi_r), "r"(CFFTRND)); + +#else + tr32 = WEBRTC_SPL_MUL_16_16(wr, frfi[2 * j]) + - WEBRTC_SPL_MUL_16_16(wi, frfi[2 * j + 1]) + CFFTRND; + + ti32 = WEBRTC_SPL_MUL_16_16(wr, frfi[2 * j + 1]) + + WEBRTC_SPL_MUL_16_16(wi, frfi[2 * j]) + CFFTRND; +#endif + + tr32 = WEBRTC_SPL_RSHIFT_W32(tr32, 15 - CFFTSFT); + ti32 = WEBRTC_SPL_RSHIFT_W32(ti32, 15 - CFFTSFT); + + qr32 = ((WebRtc_Word32)frfi[2 * i]) << CFFTSFT; + qi32 = ((WebRtc_Word32)frfi[2 * i + 1]) << CFFTSFT; + + frfi[2 * j] = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32( + (qr32 - tr32 + CFFTRND2), 1 + CFFTSFT); + frfi[2 * j + 1] = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32( + (qi32 - ti32 + CFFTRND2), 1 + CFFTSFT); + frfi[2 * i] = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32( + (qr32 + tr32 + CFFTRND2), 1 + CFFTSFT); + frfi[2 * i + 1] = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32( + (qi32 + ti32 + CFFTRND2), 1 + CFFTSFT); + } + } + + --k; + l = istep; + } + } + return 0; +} diff --git a/src/common_audio/signal_processing_library/main/source/complex_ifft.c b/src/common_audio/signal_processing_library/main/source/complex_ifft.c new file mode 100644 index 0000000..c2e4b4f --- /dev/null +++ b/src/common_audio/signal_processing_library/main/source/complex_ifft.c @@ -0,0 +1,161 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + + +/* + * This file contains the function WebRtcSpl_ComplexIFFT(). + * The description header can be found in signal_processing_library.h + * + */ + +#include "signal_processing_library.h" + +#define CIFFTSFT 14 +#define CIFFTRND 1 + +int WebRtcSpl_ComplexIFFT(WebRtc_Word16 frfi[], int stages, int mode) +{ + int i, j, l, k, istep, n, m, scale, shift; + WebRtc_Word16 wr, wi; + WebRtc_Word32 tr32, ti32, qr32, qi32; + WebRtc_Word32 tmp32, round2; + + /* The 1024-value is a constant given from the size of WebRtcSpl_kSinTable1024[], + * and should not be changed depending on the input parameter 'stages' + */ + n = 1 << stages; + if (n > 1024) + return -1; + + scale = 0; + + l = 1; + k = 10 - 1; /* Constant for given WebRtcSpl_kSinTable1024[]. Do not change + depending on the input parameter 'stages' */ + + while (l < n) + { + // variable scaling, depending upon data + shift = 0; + round2 = 8192; + + tmp32 = (WebRtc_Word32)WebRtcSpl_MaxAbsValueW16(frfi, 2 * n); + if (tmp32 > 13573) + { + shift++; + scale++; + round2 <<= 1; + } + if (tmp32 > 27146) + { + shift++; + scale++; + round2 <<= 1; + } + + istep = l << 1; + + if (mode == 0) + { + // mode==0: Low-complexity and Low-accuracy mode + for (m = 0; m < l; ++m) + { + j = m << k; + + /* The 256-value is a constant given as 1/4 of the size of + * WebRtcSpl_kSinTable1024[], and should not be changed depending on the input + * parameter 'stages'. It will result in 0 <= j < N_SINE_WAVE/2 + */ + wr = WebRtcSpl_kSinTable1024[j + 256]; + wi = WebRtcSpl_kSinTable1024[j]; + + for (i = m; i < n; i += istep) + { + j = i + l; + + tr32 = WEBRTC_SPL_RSHIFT_W32((WEBRTC_SPL_MUL_16_16_RSFT(wr, frfi[2 * j], 0) + - WEBRTC_SPL_MUL_16_16_RSFT(wi, frfi[2 * j + 1], 0)), 15); + + ti32 = WEBRTC_SPL_RSHIFT_W32( + (WEBRTC_SPL_MUL_16_16_RSFT(wr, frfi[2 * j + 1], 0) + + WEBRTC_SPL_MUL_16_16_RSFT(wi,frfi[2*j],0)), 15); + + qr32 = (WebRtc_Word32)frfi[2 * i]; + qi32 = (WebRtc_Word32)frfi[2 * i + 1]; + frfi[2 * j] = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32(qr32 - tr32, shift); + frfi[2 * j + 1] = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32(qi32 - ti32, shift); + frfi[2 * i] = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32(qr32 + tr32, shift); + frfi[2 * i + 1] = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32(qi32 + ti32, shift); + } + } + } else + { + // mode==1: High-complexity and High-accuracy mode + + for (m = 0; m < l; ++m) + { + j = m << k; + + /* The 256-value is a constant given as 1/4 of the size of + * WebRtcSpl_kSinTable1024[], and should not be changed depending on the input + * parameter 'stages'. It will result in 0 <= j < N_SINE_WAVE/2 + */ + wr = WebRtcSpl_kSinTable1024[j + 256]; + wi = WebRtcSpl_kSinTable1024[j]; + +#ifdef WEBRTC_ARCH_ARM_V7A + WebRtc_Word32 wri; + WebRtc_Word32 frfi_r; + __asm__("pkhbt %0, %1, %2, lsl #16" : "=r"(wri) : + "r"((WebRtc_Word32)wr), "r"((WebRtc_Word32)wi)); +#endif + + for (i = m; i < n; i += istep) + { + j = i + l; + +#ifdef WEBRTC_ARCH_ARM_V7A + __asm__("pkhbt %0, %1, %2, lsl #16" : "=r"(frfi_r) : + "r"((WebRtc_Word32)frfi[2*j]), "r"((WebRtc_Word32)frfi[2*j +1])); + __asm__("smlsd %0, %1, %2, %3" : "=r"(tr32) : + "r"(wri), "r"(frfi_r), "r"(CIFFTRND)); + __asm__("smladx %0, %1, %2, %3" : "=r"(ti32) : + "r"(wri), "r"(frfi_r), "r"(CIFFTRND)); +#else + + tr32 = WEBRTC_SPL_MUL_16_16(wr, frfi[2 * j]) + - WEBRTC_SPL_MUL_16_16(wi, frfi[2 * j + 1]) + CIFFTRND; + + ti32 = WEBRTC_SPL_MUL_16_16(wr, frfi[2 * j + 1]) + + WEBRTC_SPL_MUL_16_16(wi, frfi[2 * j]) + CIFFTRND; +#endif + tr32 = WEBRTC_SPL_RSHIFT_W32(tr32, 15 - CIFFTSFT); + ti32 = WEBRTC_SPL_RSHIFT_W32(ti32, 15 - CIFFTSFT); + + qr32 = ((WebRtc_Word32)frfi[2 * i]) << CIFFTSFT; + qi32 = ((WebRtc_Word32)frfi[2 * i + 1]) << CIFFTSFT; + + frfi[2 * j] = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32((qr32 - tr32+round2), + shift+CIFFTSFT); + frfi[2 * j + 1] = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32( + (qi32 - ti32 + round2), shift + CIFFTSFT); + frfi[2 * i] = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32((qr32 + tr32 + round2), + shift + CIFFTSFT); + frfi[2 * i + 1] = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32( + (qi32 + ti32 + round2), shift + CIFFTSFT); + } + } + + } + --k; + l = istep; + } + return scale; +} diff --git a/src/common_audio/signal_processing_library/main/source/copy_set_operations.c b/src/common_audio/signal_processing_library/main/source/copy_set_operations.c new file mode 100644 index 0000000..8247337 --- /dev/null +++ b/src/common_audio/signal_processing_library/main/source/copy_set_operations.c @@ -0,0 +1,108 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + + +/* + * This file contains the implementation of functions + * WebRtcSpl_MemSetW16() + * WebRtcSpl_MemSetW32() + * WebRtcSpl_MemCpyReversedOrder() + * WebRtcSpl_CopyFromEndW16() + * WebRtcSpl_ZerosArrayW16() + * WebRtcSpl_ZerosArrayW32() + * WebRtcSpl_OnesArrayW16() + * WebRtcSpl_OnesArrayW32() + * + * The description header can be found in signal_processing_library.h + * + */ + +#include +#include "signal_processing_library.h" + + +void WebRtcSpl_MemSetW16(WebRtc_Word16 *ptr, WebRtc_Word16 set_value, int length) +{ + int j; + WebRtc_Word16 *arrptr = ptr; + + for (j = length; j > 0; j--) + { + *arrptr++ = set_value; + } +} + +void WebRtcSpl_MemSetW32(WebRtc_Word32 *ptr, WebRtc_Word32 set_value, int length) +{ + int j; + WebRtc_Word32 *arrptr = ptr; + + for (j = length; j > 0; j--) + { + *arrptr++ = set_value; + } +} + +void WebRtcSpl_MemCpyReversedOrder(WebRtc_Word16* dest, WebRtc_Word16* source, int length) +{ + int j; + WebRtc_Word16* destPtr = dest; + WebRtc_Word16* sourcePtr = source; + + for (j = 0; j < length; j++) + { + *destPtr-- = *sourcePtr++; + } +} + +WebRtc_Word16 WebRtcSpl_CopyFromEndW16(G_CONST WebRtc_Word16 *vector_in, + WebRtc_Word16 length, + WebRtc_Word16 samples, + WebRtc_Word16 *vector_out) +{ + // Copy the last of the input vector to vector_out + WEBRTC_SPL_MEMCPY_W16(vector_out, &vector_in[length - samples], samples); + + return samples; +} + +WebRtc_Word16 WebRtcSpl_ZerosArrayW16(WebRtc_Word16 *vector, WebRtc_Word16 length) +{ + WebRtcSpl_MemSetW16(vector, 0, length); + return length; +} + +WebRtc_Word16 WebRtcSpl_ZerosArrayW32(WebRtc_Word32 *vector, WebRtc_Word16 length) +{ + WebRtcSpl_MemSetW32(vector, 0, length); + return length; +} + +WebRtc_Word16 WebRtcSpl_OnesArrayW16(WebRtc_Word16 *vector, WebRtc_Word16 length) +{ + WebRtc_Word16 i; + WebRtc_Word16 *tmpvec = vector; + for (i = 0; i < length; i++) + { + *tmpvec++ = 1; + } + return length; +} + +WebRtc_Word16 WebRtcSpl_OnesArrayW32(WebRtc_Word32 *vector, WebRtc_Word16 length) +{ + WebRtc_Word16 i; + WebRtc_Word32 *tmpvec = vector; + for (i = 0; i < length; i++) + { + *tmpvec++ = 1; + } + return length; +} diff --git a/src/common_audio/signal_processing_library/main/source/cos_table.c b/src/common_audio/signal_processing_library/main/source/cos_table.c new file mode 100644 index 0000000..7dba4b0 --- /dev/null +++ b/src/common_audio/signal_processing_library/main/source/cos_table.c @@ -0,0 +1,60 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + + +/* + * This file contains the 360 degree cos table. + * + */ + +#include "signal_processing_library.h" + +WebRtc_Word16 WebRtcSpl_kCosTable[] = { + 8192, 8190, 8187, 8180, 8172, 8160, 8147, 8130, 8112, + 8091, 8067, 8041, 8012, 7982, 7948, 7912, 7874, 7834, + 7791, 7745, 7697, 7647, 7595, 7540, 7483, 7424, 7362, + 7299, 7233, 7164, 7094, 7021, 6947, 6870, 6791, 6710, + 6627, 6542, 6455, 6366, 6275, 6182, 6087, 5991, 5892, + 5792, 5690, 5586, 5481, 5374, 5265, 5155, 5043, 4930, + 4815, 4698, 4580, 4461, 4341, 4219, 4096, 3971, 3845, + 3719, 3591, 3462, 3331, 3200, 3068, 2935, 2801, 2667, + 2531, 2395, 2258, 2120, 1981, 1842, 1703, 1563, 1422, + 1281, 1140, 998, 856, 713, 571, 428, 285, 142, + 0, -142, -285, -428, -571, -713, -856, -998, -1140, + -1281, -1422, -1563, -1703, -1842, -1981, -2120, -2258, -2395, + -2531, -2667, -2801, -2935, -3068, -3200, -3331, -3462, -3591, + -3719, -3845, -3971, -4095, -4219, -4341, -4461, -4580, -4698, + -4815, -4930, -5043, -5155, -5265, -5374, -5481, -5586, -5690, + -5792, -5892, -5991, -6087, -6182, -6275, -6366, -6455, -6542, + -6627, -6710, -6791, -6870, -6947, -7021, -7094, -7164, -7233, + -7299, -7362, -7424, -7483, -7540, -7595, -7647, -7697, -7745, + -7791, -7834, -7874, -7912, -7948, -7982, -8012, -8041, -8067, + -8091, -8112, -8130, -8147, -8160, -8172, -8180, -8187, -8190, + -8191, -8190, -8187, -8180, -8172, -8160, -8147, -8130, -8112, + -8091, -8067, -8041, -8012, -7982, -7948, -7912, -7874, -7834, + -7791, -7745, -7697, -7647, -7595, -7540, -7483, -7424, -7362, + -7299, -7233, -7164, -7094, -7021, -6947, -6870, -6791, -6710, + -6627, -6542, -6455, -6366, -6275, -6182, -6087, -5991, -5892, + -5792, -5690, -5586, -5481, -5374, -5265, -5155, -5043, -4930, + -4815, -4698, -4580, -4461, -4341, -4219, -4096, -3971, -3845, + -3719, -3591, -3462, -3331, -3200, -3068, -2935, -2801, -2667, + -2531, -2395, -2258, -2120, -1981, -1842, -1703, -1563, -1422, + -1281, -1140, -998, -856, -713, -571, -428, -285, -142, + 0, 142, 285, 428, 571, 713, 856, 998, 1140, + 1281, 1422, 1563, 1703, 1842, 1981, 2120, 2258, 2395, + 2531, 2667, 2801, 2935, 3068, 3200, 3331, 3462, 3591, + 3719, 3845, 3971, 4095, 4219, 4341, 4461, 4580, 4698, + 4815, 4930, 5043, 5155, 5265, 5374, 5481, 5586, 5690, + 5792, 5892, 5991, 6087, 6182, 6275, 6366, 6455, 6542, + 6627, 6710, 6791, 6870, 6947, 7021, 7094, 7164, 7233, + 7299, 7362, 7424, 7483, 7540, 7595, 7647, 7697, 7745, + 7791, 7834, 7874, 7912, 7948, 7982, 8012, 8041, 8067, + 8091, 8112, 8130, 8147, 8160, 8172, 8180, 8187, 8190 +}; diff --git a/src/common_audio/signal_processing_library/main/source/cross_correlation.c b/src/common_audio/signal_processing_library/main/source/cross_correlation.c new file mode 100644 index 0000000..1133d09 --- /dev/null +++ b/src/common_audio/signal_processing_library/main/source/cross_correlation.c @@ -0,0 +1,267 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + + +/* + * This file contains the function WebRtcSpl_CrossCorrelation(). + * The description header can be found in signal_processing_library.h + * + */ + +#include "signal_processing_library.h" + +void WebRtcSpl_CrossCorrelation(WebRtc_Word32* cross_correlation, WebRtc_Word16* seq1, + WebRtc_Word16* seq2, WebRtc_Word16 dim_seq, + WebRtc_Word16 dim_cross_correlation, + WebRtc_Word16 right_shifts, + WebRtc_Word16 step_seq2) +{ + int i, j; + WebRtc_Word16* seq1Ptr; + WebRtc_Word16* seq2Ptr; + WebRtc_Word32* CrossCorrPtr; + +#ifdef _XSCALE_OPT_ + +#ifdef _WIN32 +#pragma message("NOTE: _XSCALE_OPT_ optimizations are used (overrides _ARM_OPT_ and requires /QRxscale compiler flag)") +#endif + + __int64 macc40; + + int iseq1[250]; + int iseq2[250]; + int iseq3[250]; + int * iseq1Ptr; + int * iseq2Ptr; + int * iseq3Ptr; + int len, i_len; + + seq1Ptr = seq1; + iseq1Ptr = iseq1; + for(i = 0; i < ((dim_seq + 1) >> 1); i++) + { + *iseq1Ptr = (unsigned short)*seq1Ptr++; + *iseq1Ptr++ |= (WebRtc_Word32)*seq1Ptr++ << 16; + + } + + if(dim_seq%2) + { + *(iseq1Ptr-1) &= 0x0000ffff; + } + *iseq1Ptr = 0; + iseq1Ptr++; + *iseq1Ptr = 0; + iseq1Ptr++; + *iseq1Ptr = 0; + + if(step_seq2 < 0) + { + seq2Ptr = seq2 - dim_cross_correlation + 1; + CrossCorrPtr = &cross_correlation[dim_cross_correlation - 1]; + } + else + { + seq2Ptr = seq2; + CrossCorrPtr = cross_correlation; + } + + len = dim_seq + dim_cross_correlation - 1; + i_len = (len + 1) >> 1; + iseq2Ptr = iseq2; + + iseq3Ptr = iseq3; + for(i = 0; i < i_len; i++) + { + *iseq2Ptr = (unsigned short)*seq2Ptr++; + *iseq3Ptr = (unsigned short)*seq2Ptr; + *iseq2Ptr++ |= (WebRtc_Word32)*seq2Ptr++ << 16; + *iseq3Ptr++ |= (WebRtc_Word32)*seq2Ptr << 16; + } + + if(len % 2) + { + iseq2[i_len - 1] &= 0x0000ffff; + iseq3[i_len - 1] = 0; + } + else + iseq3[i_len - 1] &= 0x0000ffff; + + iseq2[i_len] = 0; + iseq3[i_len] = 0; + iseq2[i_len + 1] = 0; + iseq3[i_len + 1] = 0; + iseq2[i_len + 2] = 0; + iseq3[i_len + 2] = 0; + + // Set pointer to start value + iseq2Ptr = iseq2; + iseq3Ptr = iseq3; + + i_len = (dim_seq + 7) >> 3; + for (i = 0; i < dim_cross_correlation; i++) + { + + iseq1Ptr = iseq1; + + macc40 = 0; + + _WriteCoProcessor(macc40, 0); + + if((i & 1)) + { + iseq3Ptr = iseq3 + (i >> 1); + for (j = i_len; j > 0; j--) + { + _SmulAddPack_2SW_ACC(*iseq1Ptr++, *iseq3Ptr++); + _SmulAddPack_2SW_ACC(*iseq1Ptr++, *iseq3Ptr++); + _SmulAddPack_2SW_ACC(*iseq1Ptr++, *iseq3Ptr++); + _SmulAddPack_2SW_ACC(*iseq1Ptr++, *iseq3Ptr++); + } + } + else + { + iseq2Ptr = iseq2 + (i >> 1); + for (j = i_len; j > 0; j--) + { + _SmulAddPack_2SW_ACC(*iseq1Ptr++, *iseq2Ptr++); + _SmulAddPack_2SW_ACC(*iseq1Ptr++, *iseq2Ptr++); + _SmulAddPack_2SW_ACC(*iseq1Ptr++, *iseq2Ptr++); + _SmulAddPack_2SW_ACC(*iseq1Ptr++, *iseq2Ptr++); + } + + } + + macc40 = _ReadCoProcessor(0); + *CrossCorrPtr = (WebRtc_Word32)(macc40 >> right_shifts); + CrossCorrPtr += step_seq2; + } +#else // #ifdef _XSCALE_OPT_ +#ifdef _ARM_OPT_ + WebRtc_Word16 dim_seq8 = (dim_seq >> 3) << 3; +#endif + + CrossCorrPtr = cross_correlation; + + for (i = 0; i < dim_cross_correlation; i++) + { + // Set the pointer to the static vector, set the pointer to the sliding vector + // and initialize cross_correlation + seq1Ptr = seq1; + seq2Ptr = seq2 + (step_seq2 * i); + (*CrossCorrPtr) = 0; + +#ifndef _ARM_OPT_ +#ifdef _WIN32 +#pragma message("NOTE: default implementation is used") +#endif + // Perform the cross correlation + for (j = 0; j < dim_seq; j++) + { + (*CrossCorrPtr) += WEBRTC_SPL_MUL_16_16_RSFT((*seq1Ptr), (*seq2Ptr), right_shifts); + seq1Ptr++; + seq2Ptr++; + } +#else +#ifdef _WIN32 +#pragma message("NOTE: _ARM_OPT_ optimizations are used") +#endif + if (right_shifts == 0) + { + // Perform the optimized cross correlation + for (j = 0; j < dim_seq8; j = j + 8) + { + (*CrossCorrPtr) += WEBRTC_SPL_MUL_16_16((*seq1Ptr), (*seq2Ptr)); + seq1Ptr++; + seq2Ptr++; + (*CrossCorrPtr) += WEBRTC_SPL_MUL_16_16((*seq1Ptr), (*seq2Ptr)); + seq1Ptr++; + seq2Ptr++; + (*CrossCorrPtr) += WEBRTC_SPL_MUL_16_16((*seq1Ptr), (*seq2Ptr)); + seq1Ptr++; + seq2Ptr++; + (*CrossCorrPtr) += WEBRTC_SPL_MUL_16_16((*seq1Ptr), (*seq2Ptr)); + seq1Ptr++; + seq2Ptr++; + (*CrossCorrPtr) += WEBRTC_SPL_MUL_16_16((*seq1Ptr), (*seq2Ptr)); + seq1Ptr++; + seq2Ptr++; + (*CrossCorrPtr) += WEBRTC_SPL_MUL_16_16((*seq1Ptr), (*seq2Ptr)); + seq1Ptr++; + seq2Ptr++; + (*CrossCorrPtr) += WEBRTC_SPL_MUL_16_16((*seq1Ptr), (*seq2Ptr)); + seq1Ptr++; + seq2Ptr++; + (*CrossCorrPtr) += WEBRTC_SPL_MUL_16_16((*seq1Ptr), (*seq2Ptr)); + seq1Ptr++; + seq2Ptr++; + } + + for (j = dim_seq8; j < dim_seq; j++) + { + (*CrossCorrPtr) += WEBRTC_SPL_MUL_16_16((*seq1Ptr), (*seq2Ptr)); + seq1Ptr++; + seq2Ptr++; + } + } + else // right_shifts != 0 + + { + // Perform the optimized cross correlation + for (j = 0; j < dim_seq8; j = j + 8) + { + (*CrossCorrPtr) += WEBRTC_SPL_MUL_16_16_RSFT((*seq1Ptr), (*seq2Ptr), + right_shifts); + seq1Ptr++; + seq2Ptr++; + (*CrossCorrPtr) += WEBRTC_SPL_MUL_16_16_RSFT((*seq1Ptr), (*seq2Ptr), + right_shifts); + seq1Ptr++; + seq2Ptr++; + (*CrossCorrPtr) += WEBRTC_SPL_MUL_16_16_RSFT((*seq1Ptr), (*seq2Ptr), + right_shifts); + seq1Ptr++; + seq2Ptr++; + (*CrossCorrPtr) += WEBRTC_SPL_MUL_16_16_RSFT((*seq1Ptr), (*seq2Ptr), + right_shifts); + seq1Ptr++; + seq2Ptr++; + (*CrossCorrPtr) += WEBRTC_SPL_MUL_16_16_RSFT((*seq1Ptr), (*seq2Ptr), + right_shifts); + seq1Ptr++; + seq2Ptr++; + (*CrossCorrPtr) += WEBRTC_SPL_MUL_16_16_RSFT((*seq1Ptr), (*seq2Ptr), + right_shifts); + seq1Ptr++; + seq2Ptr++; + (*CrossCorrPtr) += WEBRTC_SPL_MUL_16_16_RSFT((*seq1Ptr), (*seq2Ptr), + right_shifts); + seq1Ptr++; + seq2Ptr++; + (*CrossCorrPtr) += WEBRTC_SPL_MUL_16_16_RSFT((*seq1Ptr), (*seq2Ptr), + right_shifts); + seq1Ptr++; + seq2Ptr++; + } + + for (j = dim_seq8; j < dim_seq; j++) + { + (*CrossCorrPtr) += WEBRTC_SPL_MUL_16_16_RSFT((*seq1Ptr), (*seq2Ptr), + right_shifts); + seq1Ptr++; + seq2Ptr++; + } + } +#endif + CrossCorrPtr++; + } +#endif +} diff --git a/src/common_audio/signal_processing_library/main/source/division_operations.c b/src/common_audio/signal_processing_library/main/source/division_operations.c new file mode 100644 index 0000000..b143373 --- /dev/null +++ b/src/common_audio/signal_processing_library/main/source/division_operations.c @@ -0,0 +1,144 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + + +/* + * This file contains implementations of the divisions + * WebRtcSpl_DivU32U16() + * WebRtcSpl_DivW32W16() + * WebRtcSpl_DivW32W16ResW16() + * WebRtcSpl_DivResultInQ31() + * WebRtcSpl_DivW32HiLow() + * + * The description header can be found in signal_processing_library.h + * + */ + +#include "signal_processing_library.h" + +WebRtc_UWord32 WebRtcSpl_DivU32U16(WebRtc_UWord32 num, WebRtc_UWord16 den) +{ + // Guard against division with 0 + if (den != 0) + { + return (WebRtc_UWord32)(num / den); + } else + { + return (WebRtc_UWord32)0xFFFFFFFF; + } +} + +WebRtc_Word32 WebRtcSpl_DivW32W16(WebRtc_Word32 num, WebRtc_Word16 den) +{ + // Guard against division with 0 + if (den != 0) + { + return (WebRtc_Word32)(num / den); + } else + { + return (WebRtc_Word32)0x7FFFFFFF; + } +} + +WebRtc_Word16 WebRtcSpl_DivW32W16ResW16(WebRtc_Word32 num, WebRtc_Word16 den) +{ + // Guard against division with 0 + if (den != 0) + { + return (WebRtc_Word16)(num / den); + } else + { + return (WebRtc_Word16)0x7FFF; + } +} + +WebRtc_Word32 WebRtcSpl_DivResultInQ31(WebRtc_Word32 num, WebRtc_Word32 den) +{ + WebRtc_Word32 L_num = num; + WebRtc_Word32 L_den = den; + WebRtc_Word32 div = 0; + int k = 31; + int change_sign = 0; + + if (num == 0) + return 0; + + if (num < 0) + { + change_sign++; + L_num = -num; + } + if (den < 0) + { + change_sign++; + L_den = -den; + } + while (k--) + { + div <<= 1; + L_num <<= 1; + if (L_num >= L_den) + { + L_num -= L_den; + div++; + } + } + if (change_sign == 1) + { + div = -div; + } + return div; +} + +WebRtc_Word32 WebRtcSpl_DivW32HiLow(WebRtc_Word32 num, WebRtc_Word16 den_hi, + WebRtc_Word16 den_low) +{ + WebRtc_Word16 approx, tmp_hi, tmp_low, num_hi, num_low; + WebRtc_Word32 tmpW32; + + approx = (WebRtc_Word16)WebRtcSpl_DivW32W16((WebRtc_Word32)0x1FFFFFFF, den_hi); + // result in Q14 (Note: 3FFFFFFF = 0.5 in Q30) + + // tmpW32 = 1/den = approx * (2.0 - den * approx) (in Q30) + tmpW32 = (WEBRTC_SPL_MUL_16_16(den_hi, approx) << 1) + + ((WEBRTC_SPL_MUL_16_16(den_low, approx) >> 15) << 1); + // tmpW32 = den * approx + + tmpW32 = (WebRtc_Word32)0x7fffffffL - tmpW32; // result in Q30 (tmpW32 = 2.0-(den*approx)) + + // Store tmpW32 in hi and low format + tmp_hi = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32(tmpW32, 16); + tmp_low = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32((tmpW32 + - WEBRTC_SPL_LSHIFT_W32((WebRtc_Word32)tmp_hi, 16)), 1); + + // tmpW32 = 1/den in Q29 + tmpW32 = ((WEBRTC_SPL_MUL_16_16(tmp_hi, approx) + (WEBRTC_SPL_MUL_16_16(tmp_low, approx) + >> 15)) << 1); + + // 1/den in hi and low format + tmp_hi = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32(tmpW32, 16); + tmp_low = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32((tmpW32 + - WEBRTC_SPL_LSHIFT_W32((WebRtc_Word32)tmp_hi, 16)), 1); + + // Store num in hi and low format + num_hi = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32(num, 16); + num_low = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32((num + - WEBRTC_SPL_LSHIFT_W32((WebRtc_Word32)num_hi, 16)), 1); + + // num * (1/den) by 32 bit multiplication (result in Q28) + + tmpW32 = (WEBRTC_SPL_MUL_16_16(num_hi, tmp_hi) + (WEBRTC_SPL_MUL_16_16(num_hi, tmp_low) + >> 15) + (WEBRTC_SPL_MUL_16_16(num_low, tmp_hi) >> 15)); + + // Put result in Q31 (convert from Q28) + tmpW32 = WEBRTC_SPL_LSHIFT_W32(tmpW32, 3); + + return tmpW32; +} diff --git a/src/common_audio/signal_processing_library/main/source/dot_product_with_scale.c b/src/common_audio/signal_processing_library/main/source/dot_product_with_scale.c new file mode 100644 index 0000000..6e085fd --- /dev/null +++ b/src/common_audio/signal_processing_library/main/source/dot_product_with_scale.c @@ -0,0 +1,91 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + + +/* + * This file contains the function WebRtcSpl_DotProductWithScale(). + * The description header can be found in signal_processing_library.h + * + */ + +#include "signal_processing_library.h" + +WebRtc_Word32 WebRtcSpl_DotProductWithScale(WebRtc_Word16 *vector1, WebRtc_Word16 *vector2, + int length, int scaling) +{ + WebRtc_Word32 sum; + int i; +#ifdef _ARM_OPT_ +#pragma message("NOTE: _ARM_OPT_ optimizations are used") + WebRtc_Word16 len4 = (length >> 2) << 2; +#endif + + sum = 0; + +#ifndef _ARM_OPT_ + for (i = 0; i < length; i++) + { + sum += WEBRTC_SPL_MUL_16_16_RSFT(*vector1++, *vector2++, scaling); + } +#else + if (scaling == 0) + { + for (i = 0; i < len4; i = i + 4) + { + sum += WEBRTC_SPL_MUL_16_16(*vector1, *vector2); + vector1++; + vector2++; + sum += WEBRTC_SPL_MUL_16_16(*vector1, *vector2); + vector1++; + vector2++; + sum += WEBRTC_SPL_MUL_16_16(*vector1, *vector2); + vector1++; + vector2++; + sum += WEBRTC_SPL_MUL_16_16(*vector1, *vector2); + vector1++; + vector2++; + } + + for (i = len4; i < length; i++) + { + sum += WEBRTC_SPL_MUL_16_16(*vector1, *vector2); + vector1++; + vector2++; + } + } + else + { + for (i = 0; i < len4; i = i + 4) + { + sum += WEBRTC_SPL_MUL_16_16_RSFT(*vector1, *vector2, scaling); + vector1++; + vector2++; + sum += WEBRTC_SPL_MUL_16_16_RSFT(*vector1, *vector2, scaling); + vector1++; + vector2++; + sum += WEBRTC_SPL_MUL_16_16_RSFT(*vector1, *vector2, scaling); + vector1++; + vector2++; + sum += WEBRTC_SPL_MUL_16_16_RSFT(*vector1, *vector2, scaling); + vector1++; + vector2++; + } + + for (i = len4; i < length; i++) + { + sum += WEBRTC_SPL_MUL_16_16_RSFT(*vector1, *vector2, scaling); + vector1++; + vector2++; + } + } +#endif + + return sum; +} diff --git a/src/common_audio/signal_processing_library/main/source/downsample_fast.c b/src/common_audio/signal_processing_library/main/source/downsample_fast.c new file mode 100644 index 0000000..9338275 --- /dev/null +++ b/src/common_audio/signal_processing_library/main/source/downsample_fast.c @@ -0,0 +1,59 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + + +/* + * This file contains the function WebRtcSpl_DownsampleFast(). + * The description header can be found in signal_processing_library.h + * + */ + +#include "signal_processing_library.h" + +int WebRtcSpl_DownsampleFast(WebRtc_Word16 *in_ptr, WebRtc_Word16 in_length, + WebRtc_Word16 *out_ptr, WebRtc_Word16 out_length, + WebRtc_Word16 *B, WebRtc_Word16 B_length, WebRtc_Word16 factor, + WebRtc_Word16 delay) +{ + WebRtc_Word32 o; + int i, j; + + WebRtc_Word16 *downsampled_ptr = out_ptr; + WebRtc_Word16 *b_ptr; + WebRtc_Word16 *x_ptr; + WebRtc_Word16 endpos = delay + + (WebRtc_Word16)WEBRTC_SPL_MUL_16_16(factor, (out_length - 1)) + 1; + + if (in_length < endpos) + { + return -1; + } + + for (i = delay; i < endpos; i += factor) + { + b_ptr = &B[0]; + x_ptr = &in_ptr[i]; + + o = (WebRtc_Word32)2048; // Round val + + for (j = 0; j < B_length; j++) + { + o += WEBRTC_SPL_MUL_16_16(*b_ptr++, *x_ptr--); + } + + o = WEBRTC_SPL_RSHIFT_W32(o, 12); + + // If output is higher than 32768, saturate it. Same with negative side + + *downsampled_ptr++ = (WebRtc_Word16)WEBRTC_SPL_SAT(32767, o, -32768); + } + + return 0; +} diff --git a/src/common_audio/signal_processing_library/main/source/energy.c b/src/common_audio/signal_processing_library/main/source/energy.c new file mode 100644 index 0000000..e8fdf94 --- /dev/null +++ b/src/common_audio/signal_processing_library/main/source/energy.c @@ -0,0 +1,36 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + + +/* + * This file contains the function WebRtcSpl_Energy(). + * The description header can be found in signal_processing_library.h + * + */ + +#include "signal_processing_library.h" + +WebRtc_Word32 WebRtcSpl_Energy(WebRtc_Word16* vector, int vector_length, int* scale_factor) +{ + WebRtc_Word32 en = 0; + int i; + int scaling = WebRtcSpl_GetScalingSquare(vector, vector_length, vector_length); + int looptimes = vector_length; + WebRtc_Word16 *vectorptr = vector; + + for (i = 0; i < looptimes; i++) + { + en += WEBRTC_SPL_MUL_16_16_RSFT(*vectorptr, *vectorptr, scaling); + vectorptr++; + } + *scale_factor = scaling; + + return en; +} diff --git a/src/common_audio/signal_processing_library/main/source/filter_ar.c b/src/common_audio/signal_processing_library/main/source/filter_ar.c new file mode 100644 index 0000000..24e83a6 --- /dev/null +++ b/src/common_audio/signal_processing_library/main/source/filter_ar.c @@ -0,0 +1,89 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + + +/* + * This file contains the function WebRtcSpl_FilterAR(). + * The description header can be found in signal_processing_library.h + * + */ + +#include "signal_processing_library.h" + +int WebRtcSpl_FilterAR(G_CONST WebRtc_Word16* a, + int a_length, + G_CONST WebRtc_Word16* x, + int x_length, + WebRtc_Word16* state, + int state_length, + WebRtc_Word16* state_low, + int state_low_length, + WebRtc_Word16* filtered, + WebRtc_Word16* filtered_low, + int filtered_low_length) +{ + WebRtc_Word32 o; + WebRtc_Word32 oLOW; + int i, j, stop; + G_CONST WebRtc_Word16* x_ptr = &x[0]; + WebRtc_Word16* filteredFINAL_ptr = filtered; + WebRtc_Word16* filteredFINAL_LOW_ptr = filtered_low; + + for (i = 0; i < x_length; i++) + { + // Calculate filtered[i] and filtered_low[i] + G_CONST WebRtc_Word16* a_ptr = &a[1]; + WebRtc_Word16* filtered_ptr = &filtered[i - 1]; + WebRtc_Word16* filtered_low_ptr = &filtered_low[i - 1]; + WebRtc_Word16* state_ptr = &state[state_length - 1]; + WebRtc_Word16* state_low_ptr = &state_low[state_length - 1]; + + o = (WebRtc_Word32)(*x_ptr++) << 12; + oLOW = (WebRtc_Word32)0; + + stop = (i < a_length) ? i + 1 : a_length; + for (j = 1; j < stop; j++) + { + o -= WEBRTC_SPL_MUL_16_16(*a_ptr, *filtered_ptr--); + oLOW -= WEBRTC_SPL_MUL_16_16(*a_ptr++, *filtered_low_ptr--); + } + for (j = i + 1; j < a_length; j++) + { + o -= WEBRTC_SPL_MUL_16_16(*a_ptr, *state_ptr--); + oLOW -= WEBRTC_SPL_MUL_16_16(*a_ptr++, *state_low_ptr--); + } + + o += (oLOW >> 12); + *filteredFINAL_ptr = (WebRtc_Word16)((o + (WebRtc_Word32)2048) >> 12); + *filteredFINAL_LOW_ptr++ = (WebRtc_Word16)(o - ((WebRtc_Word32)(*filteredFINAL_ptr++) + << 12)); + } + + // Save the filter state + if (x_length >= state_length) + { + WebRtcSpl_CopyFromEndW16(filtered, x_length, a_length - 1, state); + WebRtcSpl_CopyFromEndW16(filtered_low, x_length, a_length - 1, state_low); + } else + { + for (i = 0; i < state_length - x_length; i++) + { + state[i] = state[i + x_length]; + state_low[i] = state_low[i + x_length]; + } + for (i = 0; i < x_length; i++) + { + state[state_length - x_length + i] = filtered[i]; + state[state_length - x_length + i] = filtered_low[i]; + } + } + + return x_length; +} diff --git a/src/common_audio/signal_processing_library/main/source/filter_ar_fast_q12.c b/src/common_audio/signal_processing_library/main/source/filter_ar_fast_q12.c new file mode 100644 index 0000000..6184da3 --- /dev/null +++ b/src/common_audio/signal_processing_library/main/source/filter_ar_fast_q12.c @@ -0,0 +1,49 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + + +/* + * This file contains the function WebRtcSpl_FilterARFastQ12(). + * The description header can be found in signal_processing_library.h + * + */ + +#include "signal_processing_library.h" + +void WebRtcSpl_FilterARFastQ12(WebRtc_Word16 *in, WebRtc_Word16 *out, WebRtc_Word16 *A, + WebRtc_Word16 A_length, WebRtc_Word16 length) +{ + WebRtc_Word32 o; + int i, j; + + WebRtc_Word16 *x_ptr = &in[0]; + WebRtc_Word16 *filtered_ptr = &out[0]; + + for (i = 0; i < length; i++) + { + // Calculate filtered[i] + G_CONST WebRtc_Word16 *a_ptr = &A[0]; + WebRtc_Word16 *state_ptr = &out[i - 1]; + + o = WEBRTC_SPL_MUL_16_16(*x_ptr++, *a_ptr++); + + for (j = 1; j < A_length; j++) + { + o -= WEBRTC_SPL_MUL_16_16(*a_ptr++,*state_ptr--); + } + + // Saturate the output + o = WEBRTC_SPL_SAT((WebRtc_Word32)134215679, o, (WebRtc_Word32)-134217728); + + *filtered_ptr++ = (WebRtc_Word16)((o + (WebRtc_Word32)2048) >> 12); + } + + return; +} diff --git a/src/common_audio/signal_processing_library/main/source/filter_ma_fast_q12.c b/src/common_audio/signal_processing_library/main/source/filter_ma_fast_q12.c new file mode 100644 index 0000000..19ad9b1 --- /dev/null +++ b/src/common_audio/signal_processing_library/main/source/filter_ma_fast_q12.c @@ -0,0 +1,49 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + + +/* + * This file contains the function WebRtcSpl_FilterMAFastQ12(). + * The description header can be found in signal_processing_library.h + * + */ + +#include "signal_processing_library.h" + +void WebRtcSpl_FilterMAFastQ12(WebRtc_Word16* in_ptr, + WebRtc_Word16* out_ptr, + WebRtc_Word16* B, + WebRtc_Word16 B_length, + WebRtc_Word16 length) +{ + WebRtc_Word32 o; + int i, j; + for (i = 0; i < length; i++) + { + G_CONST WebRtc_Word16* b_ptr = &B[0]; + G_CONST WebRtc_Word16* x_ptr = &in_ptr[i]; + + o = (WebRtc_Word32)0; + + for (j = 0; j < B_length; j++) + { + o += WEBRTC_SPL_MUL_16_16(*b_ptr++, *x_ptr--); + } + + // If output is higher than 32768, saturate it. Same with negative side + // 2^27 = 134217728, which corresponds to 32768 in Q12 + + // Saturate the output + o = WEBRTC_SPL_SAT((WebRtc_Word32)134215679, o, (WebRtc_Word32)-134217728); + + *out_ptr++ = (WebRtc_Word16)((o + (WebRtc_Word32)2048) >> 12); + } + return; +} diff --git a/src/common_audio/signal_processing_library/main/source/get_hanning_window.c b/src/common_audio/signal_processing_library/main/source/get_hanning_window.c new file mode 100644 index 0000000..2845c83 --- /dev/null +++ b/src/common_audio/signal_processing_library/main/source/get_hanning_window.c @@ -0,0 +1,41 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + + +/* + * This file contains the function WebRtcSpl_GetHanningWindow(). + * The description header can be found in signal_processing_library.h + * + */ + +#include "signal_processing_library.h" + +void WebRtcSpl_GetHanningWindow(WebRtc_Word16 *v, WebRtc_Word16 size) +{ + int jj; + WebRtc_Word16 *vptr1; + + WebRtc_Word32 index; + WebRtc_Word32 factor = ((WebRtc_Word32)0x40000000); + + factor = WebRtcSpl_DivW32W16(factor, size); + if (size < 513) + index = (WebRtc_Word32)-0x200000; + else + index = (WebRtc_Word32)-0x100000; + vptr1 = v; + + for (jj = 0; jj < size; jj++) + { + index += factor; + (*vptr1++) = WebRtcSpl_kHanningTable[index >> 22]; + } + +} diff --git a/src/common_audio/signal_processing_library/main/source/get_scaling_square.c b/src/common_audio/signal_processing_library/main/source/get_scaling_square.c new file mode 100644 index 0000000..dccbf33 --- /dev/null +++ b/src/common_audio/signal_processing_library/main/source/get_scaling_square.c @@ -0,0 +1,44 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + + +/* + * This file contains the function WebRtcSpl_GetScalingSquare(). + * The description header can be found in signal_processing_library.h + * + */ + +#include "signal_processing_library.h" + +int WebRtcSpl_GetScalingSquare(WebRtc_Word16 *in_vector, int in_vector_length, int times) +{ + int nbits = WebRtcSpl_GetSizeInBits(times); + int i; + WebRtc_Word16 smax = -1; + WebRtc_Word16 sabs; + WebRtc_Word16 *sptr = in_vector; + int t; + int looptimes = in_vector_length; + + for (i = looptimes; i > 0; i--) + { + sabs = (*sptr > 0 ? *sptr++ : -*sptr++); + smax = (sabs > smax ? sabs : smax); + } + t = WebRtcSpl_NormW32(WEBRTC_SPL_MUL(smax, smax)); + + if (smax == 0) + { + return 0; // Since norm(0) returns 0 + } else + { + return (t > nbits) ? 0 : nbits - t; + } +} diff --git a/src/common_audio/signal_processing_library/main/source/hanning_table.c b/src/common_audio/signal_processing_library/main/source/hanning_table.c new file mode 100644 index 0000000..112d0e5 --- /dev/null +++ b/src/common_audio/signal_processing_library/main/source/hanning_table.c @@ -0,0 +1,53 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + + +/* + * This file contains the Hanning table with 256 entries. + * + */ + +#include "signal_processing_library.h" + +// Hanning table with 256 entries +WebRtc_Word16 WebRtcSpl_kHanningTable[] = { + 1, 2, 6, 10, 15, 22, 30, 39, + 50, 62, 75, 89, 104, 121, 138, 157, + 178, 199, 222, 246, 271, 297, 324, 353, + 383, 413, 446, 479, 513, 549, 586, 624, + 663, 703, 744, 787, 830, 875, 920, 967, + 1015, 1064, 1114, 1165, 1218, 1271, 1325, 1381, + 1437, 1494, 1553, 1612, 1673, 1734, 1796, 1859, + 1924, 1989, 2055, 2122, 2190, 2259, 2329, 2399, + 2471, 2543, 2617, 2691, 2765, 2841, 2918, 2995, + 3073, 3152, 3232, 3312, 3393, 3475, 3558, 3641, + 3725, 3809, 3895, 3980, 4067, 4154, 4242, 4330, + 4419, 4509, 4599, 4689, 4781, 4872, 4964, 5057, + 5150, 5244, 5338, 5432, 5527, 5622, 5718, 5814, + 5910, 6007, 6104, 6202, 6299, 6397, 6495, 6594, + 6693, 6791, 6891, 6990, 7090, 7189, 7289, 7389, + 7489, 7589, 7690, 7790, 7890, 7991, 8091, 8192, + 8293, 8393, 8494, 8594, 8694, 8795, 8895, 8995, + 9095, 9195, 9294, 9394, 9493, 9593, 9691, 9790, + 9889, 9987, 10085, 10182, 10280, 10377, 10474, 10570, +10666, 10762, 10857, 10952, 11046, 11140, 11234, 11327, +11420, 11512, 11603, 11695, 11785, 11875, 11965, 12054, +12142, 12230, 12317, 12404, 12489, 12575, 12659, 12743, +12826, 12909, 12991, 13072, 13152, 13232, 13311, 13389, +13466, 13543, 13619, 13693, 13767, 13841, 13913, 13985, +14055, 14125, 14194, 14262, 14329, 14395, 14460, 14525, +14588, 14650, 14711, 14772, 14831, 14890, 14947, 15003, +15059, 15113, 15166, 15219, 15270, 15320, 15369, 15417, +15464, 15509, 15554, 15597, 15640, 15681, 15721, 15760, +15798, 15835, 15871, 15905, 15938, 15971, 16001, 16031, +16060, 16087, 16113, 16138, 16162, 16185, 16206, 16227, +16246, 16263, 16280, 16295, 16309, 16322, 16334, 16345, +16354, 16362, 16369, 16374, 16378, 16382, 16383, 16384 +}; diff --git a/src/common_audio/signal_processing_library/main/source/ilbc_specific_functions.c b/src/common_audio/signal_processing_library/main/source/ilbc_specific_functions.c new file mode 100644 index 0000000..5a9e577 --- /dev/null +++ b/src/common_audio/signal_processing_library/main/source/ilbc_specific_functions.c @@ -0,0 +1,120 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + + +/* + * This file contains implementations of the iLBC specific functions + * WebRtcSpl_ScaleAndAddVectorsWithRound() + * WebRtcSpl_ReverseOrderMultArrayElements() + * WebRtcSpl_ElementwiseVectorMult() + * WebRtcSpl_AddVectorsAndShift() + * WebRtcSpl_AddAffineVectorToVector() + * WebRtcSpl_AffineTransformVector() + * + * The description header can be found in signal_processing_library.h + * + */ + +#include "signal_processing_library.h" + +void WebRtcSpl_ScaleAndAddVectorsWithRound(WebRtc_Word16 *vector1, WebRtc_Word16 scale1, + WebRtc_Word16 *vector2, WebRtc_Word16 scale2, + WebRtc_Word16 right_shifts, WebRtc_Word16 *out, + WebRtc_Word16 vector_length) +{ + int i; + WebRtc_Word16 roundVal; + roundVal = 1 << right_shifts; + roundVal = roundVal >> 1; + for (i = 0; i < vector_length; i++) + { + out[i] = (WebRtc_Word16)((WEBRTC_SPL_MUL_16_16(vector1[i], scale1) + + WEBRTC_SPL_MUL_16_16(vector2[i], scale2) + roundVal) >> right_shifts); + } +} + +void WebRtcSpl_ReverseOrderMultArrayElements(WebRtc_Word16 *out, G_CONST WebRtc_Word16 *in, + G_CONST WebRtc_Word16 *win, + WebRtc_Word16 vector_length, + WebRtc_Word16 right_shifts) +{ + int i; + WebRtc_Word16 *outptr = out; + G_CONST WebRtc_Word16 *inptr = in; + G_CONST WebRtc_Word16 *winptr = win; + for (i = 0; i < vector_length; i++) + { + (*outptr++) = (WebRtc_Word16)WEBRTC_SPL_MUL_16_16_RSFT(*inptr++, + *winptr--, right_shifts); + } +} + +void WebRtcSpl_ElementwiseVectorMult(WebRtc_Word16 *out, G_CONST WebRtc_Word16 *in, + G_CONST WebRtc_Word16 *win, WebRtc_Word16 vector_length, + WebRtc_Word16 right_shifts) +{ + int i; + WebRtc_Word16 *outptr = out; + G_CONST WebRtc_Word16 *inptr = in; + G_CONST WebRtc_Word16 *winptr = win; + for (i = 0; i < vector_length; i++) + { + (*outptr++) = (WebRtc_Word16)WEBRTC_SPL_MUL_16_16_RSFT(*inptr++, + *winptr++, right_shifts); + } +} + +void WebRtcSpl_AddVectorsAndShift(WebRtc_Word16 *out, G_CONST WebRtc_Word16 *in1, + G_CONST WebRtc_Word16 *in2, WebRtc_Word16 vector_length, + WebRtc_Word16 right_shifts) +{ + int i; + WebRtc_Word16 *outptr = out; + G_CONST WebRtc_Word16 *in1ptr = in1; + G_CONST WebRtc_Word16 *in2ptr = in2; + for (i = vector_length; i > 0; i--) + { + (*outptr++) = (WebRtc_Word16)(((*in1ptr++) + (*in2ptr++)) >> right_shifts); + } +} + +void WebRtcSpl_AddAffineVectorToVector(WebRtc_Word16 *out, WebRtc_Word16 *in, + WebRtc_Word16 gain, WebRtc_Word32 add_constant, + WebRtc_Word16 right_shifts, int vector_length) +{ + WebRtc_Word16 *inPtr; + WebRtc_Word16 *outPtr; + int i; + + inPtr = in; + outPtr = out; + for (i = 0; i < vector_length; i++) + { + (*outPtr++) += (WebRtc_Word16)((WEBRTC_SPL_MUL_16_16((*inPtr++), gain) + + (WebRtc_Word32)add_constant) >> right_shifts); + } +} + +void WebRtcSpl_AffineTransformVector(WebRtc_Word16 *out, WebRtc_Word16 *in, + WebRtc_Word16 gain, WebRtc_Word32 add_constant, + WebRtc_Word16 right_shifts, int vector_length) +{ + WebRtc_Word16 *inPtr; + WebRtc_Word16 *outPtr; + int i; + + inPtr = in; + outPtr = out; + for (i = 0; i < vector_length; i++) + { + (*outPtr++) = (WebRtc_Word16)((WEBRTC_SPL_MUL_16_16((*inPtr++), gain) + + (WebRtc_Word32)add_constant) >> right_shifts); + } +} diff --git a/src/common_audio/signal_processing_library/main/source/levinson_durbin.c b/src/common_audio/signal_processing_library/main/source/levinson_durbin.c new file mode 100644 index 0000000..4e11cdb --- /dev/null +++ b/src/common_audio/signal_processing_library/main/source/levinson_durbin.c @@ -0,0 +1,259 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + + +/* + * This file contains the function WebRtcSpl_LevinsonDurbin(). + * The description header can be found in signal_processing_library.h + * + */ + +#include "signal_processing_library.h" + +#define SPL_LEVINSON_MAXORDER 20 + +WebRtc_Word16 WebRtcSpl_LevinsonDurbin(WebRtc_Word32 *R, WebRtc_Word16 *A, WebRtc_Word16 *K, + WebRtc_Word16 order) +{ + WebRtc_Word16 i, j; + // Auto-correlation coefficients in high precision + WebRtc_Word16 R_hi[SPL_LEVINSON_MAXORDER + 1], R_low[SPL_LEVINSON_MAXORDER + 1]; + // LPC coefficients in high precision + WebRtc_Word16 A_hi[SPL_LEVINSON_MAXORDER + 1], A_low[SPL_LEVINSON_MAXORDER + 1]; + // LPC coefficients for next iteration + WebRtc_Word16 A_upd_hi[SPL_LEVINSON_MAXORDER + 1], A_upd_low[SPL_LEVINSON_MAXORDER + 1]; + // Reflection coefficient in high precision + WebRtc_Word16 K_hi, K_low; + // Prediction gain Alpha in high precision and with scale factor + WebRtc_Word16 Alpha_hi, Alpha_low, Alpha_exp; + WebRtc_Word16 tmp_hi, tmp_low; + WebRtc_Word32 temp1W32, temp2W32, temp3W32; + WebRtc_Word16 norm; + + // Normalize the autocorrelation R[0]...R[order+1] + + norm = WebRtcSpl_NormW32(R[0]); + + for (i = order; i >= 0; i--) + { + temp1W32 = WEBRTC_SPL_LSHIFT_W32(R[i], norm); + // Put R in hi and low format + R_hi[i] = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32(temp1W32, 16); + R_low[i] = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32((temp1W32 + - WEBRTC_SPL_LSHIFT_W32((WebRtc_Word32)R_hi[i], 16)), 1); + } + + // K = A[1] = -R[1] / R[0] + + temp2W32 = WEBRTC_SPL_LSHIFT_W32((WebRtc_Word32)R_hi[1],16) + + WEBRTC_SPL_LSHIFT_W32((WebRtc_Word32)R_low[1],1); // R[1] in Q31 + temp3W32 = WEBRTC_SPL_ABS_W32(temp2W32); // abs R[1] + temp1W32 = WebRtcSpl_DivW32HiLow(temp3W32, R_hi[0], R_low[0]); // abs(R[1])/R[0] in Q31 + // Put back the sign on R[1] + if (temp2W32 > 0) + { + temp1W32 = -temp1W32; + } + + // Put K in hi and low format + K_hi = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32(temp1W32, 16); + K_low = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32((temp1W32 + - WEBRTC_SPL_LSHIFT_W32((WebRtc_Word32)K_hi, 16)), 1); + + // Store first reflection coefficient + K[0] = K_hi; + + temp1W32 = WEBRTC_SPL_RSHIFT_W32(temp1W32, 4); // A[1] in Q27 + + // Put A[1] in hi and low format + A_hi[1] = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32(temp1W32, 16); + A_low[1] = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32((temp1W32 + - WEBRTC_SPL_LSHIFT_W32((WebRtc_Word32)A_hi[1], 16)), 1); + + // Alpha = R[0] * (1-K^2) + + temp1W32 = (((WEBRTC_SPL_MUL_16_16(K_hi, K_low) >> 14) + WEBRTC_SPL_MUL_16_16(K_hi, K_hi)) + << 1); // temp1W32 = k^2 in Q31 + + temp1W32 = WEBRTC_SPL_ABS_W32(temp1W32); // Guard against <0 + temp1W32 = (WebRtc_Word32)0x7fffffffL - temp1W32; // temp1W32 = (1 - K[0]*K[0]) in Q31 + + // Store temp1W32 = 1 - K[0]*K[0] on hi and low format + tmp_hi = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32(temp1W32, 16); + tmp_low = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32((temp1W32 + - WEBRTC_SPL_LSHIFT_W32((WebRtc_Word32)tmp_hi, 16)), 1); + + // Calculate Alpha in Q31 + temp1W32 = ((WEBRTC_SPL_MUL_16_16(R_hi[0], tmp_hi) + + (WEBRTC_SPL_MUL_16_16(R_hi[0], tmp_low) >> 15) + + (WEBRTC_SPL_MUL_16_16(R_low[0], tmp_hi) >> 15)) << 1); + + // Normalize Alpha and put it in hi and low format + + Alpha_exp = WebRtcSpl_NormW32(temp1W32); + temp1W32 = WEBRTC_SPL_LSHIFT_W32(temp1W32, Alpha_exp); + Alpha_hi = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32(temp1W32, 16); + Alpha_low = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32((temp1W32 + - WEBRTC_SPL_LSHIFT_W32((WebRtc_Word32)Alpha_hi, 16)), 1); + + // Perform the iterative calculations in the Levinson-Durbin algorithm + + for (i = 2; i <= order; i++) + { + /* ---- + temp1W32 = R[i] + > R[j]*A[i-j] + / + ---- + j=1..i-1 + */ + + temp1W32 = 0; + + for (j = 1; j < i; j++) + { + // temp1W32 is in Q31 + temp1W32 += ((WEBRTC_SPL_MUL_16_16(R_hi[j], A_hi[i-j]) << 1) + + (((WEBRTC_SPL_MUL_16_16(R_hi[j], A_low[i-j]) >> 15) + + (WEBRTC_SPL_MUL_16_16(R_low[j], A_hi[i-j]) >> 15)) << 1)); + } + + temp1W32 = WEBRTC_SPL_LSHIFT_W32(temp1W32, 4); + temp1W32 += (WEBRTC_SPL_LSHIFT_W32((WebRtc_Word32)R_hi[i], 16) + + WEBRTC_SPL_LSHIFT_W32((WebRtc_Word32)R_low[i], 1)); + + // K = -temp1W32 / Alpha + temp2W32 = WEBRTC_SPL_ABS_W32(temp1W32); // abs(temp1W32) + temp3W32 = WebRtcSpl_DivW32HiLow(temp2W32, Alpha_hi, Alpha_low); // abs(temp1W32)/Alpha + + // Put the sign of temp1W32 back again + if (temp1W32 > 0) + { + temp3W32 = -temp3W32; + } + + // Use the Alpha shifts from earlier to de-normalize + norm = WebRtcSpl_NormW32(temp3W32); + if ((Alpha_exp <= norm) || (temp3W32 == 0)) + { + temp3W32 = WEBRTC_SPL_LSHIFT_W32(temp3W32, Alpha_exp); + } else + { + if (temp3W32 > 0) + { + temp3W32 = (WebRtc_Word32)0x7fffffffL; + } else + { + temp3W32 = (WebRtc_Word32)0x80000000L; + } + } + + // Put K on hi and low format + K_hi = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32(temp3W32, 16); + K_low = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32((temp3W32 + - WEBRTC_SPL_LSHIFT_W32((WebRtc_Word32)K_hi, 16)), 1); + + // Store Reflection coefficient in Q15 + K[i - 1] = K_hi; + + // Test for unstable filter. + // If unstable return 0 and let the user decide what to do in that case + + if ((WebRtc_Word32)WEBRTC_SPL_ABS_W16(K_hi) > (WebRtc_Word32)32750) + { + return 0; // Unstable filter + } + + /* + Compute updated LPC coefficient: Anew[i] + Anew[j]= A[j] + K*A[i-j] for j=1..i-1 + Anew[i]= K + */ + + for (j = 1; j < i; j++) + { + // temp1W32 = A[j] in Q27 + temp1W32 = WEBRTC_SPL_LSHIFT_W32((WebRtc_Word32)A_hi[j],16) + + WEBRTC_SPL_LSHIFT_W32((WebRtc_Word32)A_low[j],1); + + // temp1W32 += K*A[i-j] in Q27 + temp1W32 += ((WEBRTC_SPL_MUL_16_16(K_hi, A_hi[i-j]) + + (WEBRTC_SPL_MUL_16_16(K_hi, A_low[i-j]) >> 15) + + (WEBRTC_SPL_MUL_16_16(K_low, A_hi[i-j]) >> 15)) << 1); + + // Put Anew in hi and low format + A_upd_hi[j] = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32(temp1W32, 16); + A_upd_low[j] = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32((temp1W32 + - WEBRTC_SPL_LSHIFT_W32((WebRtc_Word32)A_upd_hi[j], 16)), 1); + } + + // temp3W32 = K in Q27 (Convert from Q31 to Q27) + temp3W32 = WEBRTC_SPL_RSHIFT_W32(temp3W32, 4); + + // Store Anew in hi and low format + A_upd_hi[i] = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32(temp3W32, 16); + A_upd_low[i] = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32((temp3W32 + - WEBRTC_SPL_LSHIFT_W32((WebRtc_Word32)A_upd_hi[i], 16)), 1); + + // Alpha = Alpha * (1-K^2) + + temp1W32 = (((WEBRTC_SPL_MUL_16_16(K_hi, K_low) >> 14) + + WEBRTC_SPL_MUL_16_16(K_hi, K_hi)) << 1); // K*K in Q31 + + temp1W32 = WEBRTC_SPL_ABS_W32(temp1W32); // Guard against <0 + temp1W32 = (WebRtc_Word32)0x7fffffffL - temp1W32; // 1 - K*K in Q31 + + // Convert 1- K^2 in hi and low format + tmp_hi = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32(temp1W32, 16); + tmp_low = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32((temp1W32 + - WEBRTC_SPL_LSHIFT_W32((WebRtc_Word32)tmp_hi, 16)), 1); + + // Calculate Alpha = Alpha * (1-K^2) in Q31 + temp1W32 = ((WEBRTC_SPL_MUL_16_16(Alpha_hi, tmp_hi) + + (WEBRTC_SPL_MUL_16_16(Alpha_hi, tmp_low) >> 15) + + (WEBRTC_SPL_MUL_16_16(Alpha_low, tmp_hi) >> 15)) << 1); + + // Normalize Alpha and store it on hi and low format + + norm = WebRtcSpl_NormW32(temp1W32); + temp1W32 = WEBRTC_SPL_LSHIFT_W32(temp1W32, norm); + + Alpha_hi = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32(temp1W32, 16); + Alpha_low = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32((temp1W32 + - WEBRTC_SPL_LSHIFT_W32((WebRtc_Word32)Alpha_hi, 16)), 1); + + // Update the total normalization of Alpha + Alpha_exp = Alpha_exp + norm; + + // Update A[] + + for (j = 1; j <= i; j++) + { + A_hi[j] = A_upd_hi[j]; + A_low[j] = A_upd_low[j]; + } + } + + /* + Set A[0] to 1.0 and store the A[i] i=1...order in Q12 + (Convert from Q27 and use rounding) + */ + + A[0] = 4096; + + for (i = 1; i <= order; i++) + { + // temp1W32 in Q27 + temp1W32 = WEBRTC_SPL_LSHIFT_W32((WebRtc_Word32)A_hi[i], 16) + + WEBRTC_SPL_LSHIFT_W32((WebRtc_Word32)A_low[i], 1); + // Round and store upper word + A[i] = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32((temp1W32<<1)+(WebRtc_Word32)32768, 16); + } + return 1; // Stable filters +} diff --git a/src/common_audio/signal_processing_library/main/source/lpc_to_refl_coef.c b/src/common_audio/signal_processing_library/main/source/lpc_to_refl_coef.c new file mode 100644 index 0000000..2cb83c2 --- /dev/null +++ b/src/common_audio/signal_processing_library/main/source/lpc_to_refl_coef.c @@ -0,0 +1,57 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + + +/* + * This file contains the function WebRtcSpl_LpcToReflCoef(). + * The description header can be found in signal_processing_library.h + * + */ + +#include "signal_processing_library.h" + +#define SPL_LPC_TO_REFL_COEF_MAX_AR_MODEL_ORDER 50 + +void WebRtcSpl_LpcToReflCoef(WebRtc_Word16* a16, int use_order, WebRtc_Word16* k16) +{ + int m, k; + WebRtc_Word32 tmp32[SPL_LPC_TO_REFL_COEF_MAX_AR_MODEL_ORDER]; + WebRtc_Word32 tmp_inv_denom32; + WebRtc_Word16 tmp_inv_denom16; + + k16[use_order - 1] = WEBRTC_SPL_LSHIFT_W16(a16[use_order], 3); //Q12<<3 => Q15 + for (m = use_order - 1; m > 0; m--) + { + // (1 - k^2) in Q30 + tmp_inv_denom32 = ((WebRtc_Word32)1073741823) - WEBRTC_SPL_MUL_16_16(k16[m], k16[m]); + // (1 - k^2) in Q15 + tmp_inv_denom16 = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32(tmp_inv_denom32, 15); + + for (k = 1; k <= m; k++) + { + // tmp[k] = (a[k] - RC[m] * a[m-k+1]) / (1.0 - RC[m]*RC[m]); + + // [Q12<<16 - (Q15*Q12)<<1] = [Q28 - Q28] = Q28 + tmp32[k] = WEBRTC_SPL_LSHIFT_W32((WebRtc_Word32)a16[k], 16) + - WEBRTC_SPL_LSHIFT_W32(WEBRTC_SPL_MUL_16_16(k16[m], a16[m-k+1]), 1); + + tmp32[k] = WebRtcSpl_DivW32W16(tmp32[k], tmp_inv_denom16); //Q28/Q15 = Q13 + } + + for (k = 1; k < m; k++) + { + a16[k] = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32(tmp32[k], 1); //Q13>>1 => Q12 + } + + tmp32[m] = WEBRTC_SPL_SAT(8191, tmp32[m], -8191); + k16[m - 1] = (WebRtc_Word16)WEBRTC_SPL_LSHIFT_W32(tmp32[m], 2); //Q13<<2 => Q15 + } + return; +} diff --git a/src/common_audio/signal_processing_library/main/source/min_max_operations.c b/src/common_audio/signal_processing_library/main/source/min_max_operations.c new file mode 100644 index 0000000..57eaff7 --- /dev/null +++ b/src/common_audio/signal_processing_library/main/source/min_max_operations.c @@ -0,0 +1,265 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +/* + * This file contains the implementation of functions + * WebRtcSpl_MaxAbsValueW16() + * WebRtcSpl_MaxAbsIndexW16() + * WebRtcSpl_MaxAbsValueW32() + * WebRtcSpl_MaxValueW16() + * WebRtcSpl_MaxIndexW16() + * WebRtcSpl_MaxValueW32() + * WebRtcSpl_MaxIndexW32() + * WebRtcSpl_MinValueW16() + * WebRtcSpl_MinIndexW16() + * WebRtcSpl_MinValueW32() + * WebRtcSpl_MinIndexW32() + * + * The description header can be found in signal_processing_library.h. + * + */ + +#include "signal_processing_library.h" + +#if !(defined(WEBRTC_ANDROID) && defined(WEBRTC_ARCH_ARM_NEON)) + +// Maximum absolute value of word16 vector. +WebRtc_Word16 WebRtcSpl_MaxAbsValueW16(const WebRtc_Word16 *vector, WebRtc_Word16 length) +{ + WebRtc_Word32 tempMax = 0; + WebRtc_Word32 absVal; + WebRtc_Word16 totMax; + int i; + G_CONST WebRtc_Word16 *tmpvector = vector; + + for (i = 0; i < length; i++) + { + absVal = WEBRTC_SPL_ABS_W32((*tmpvector)); + if (absVal > tempMax) + { + tempMax = absVal; + } + tmpvector++; + } + totMax = (WebRtc_Word16)WEBRTC_SPL_MIN(tempMax, WEBRTC_SPL_WORD16_MAX); + return totMax; +} + +#endif + +// Index of maximum absolute value in a word16 vector. +WebRtc_Word16 WebRtcSpl_MaxAbsIndexW16(G_CONST WebRtc_Word16* vector, WebRtc_Word16 length) +{ + WebRtc_Word16 tempMax; + WebRtc_Word16 absTemp; + WebRtc_Word16 tempMaxIndex = 0; + WebRtc_Word16 i = 0; + G_CONST WebRtc_Word16 *tmpvector = vector; + + tempMax = WEBRTC_SPL_ABS_W16(*tmpvector); + tmpvector++; + for (i = 1; i < length; i++) + { + absTemp = WEBRTC_SPL_ABS_W16(*tmpvector); + tmpvector++; + if (absTemp > tempMax) + { + tempMax = absTemp; + tempMaxIndex = i; + } + } + return tempMaxIndex; +} + +// Maximum absolute value of word32 vector. +WebRtc_Word32 WebRtcSpl_MaxAbsValueW32(G_CONST WebRtc_Word32 *vector, WebRtc_Word16 length) +{ + WebRtc_UWord32 tempMax = 0; + WebRtc_UWord32 absVal; + WebRtc_Word32 retval; + int i; + G_CONST WebRtc_Word32 *tmpvector = vector; + + for (i = 0; i < length; i++) + { + absVal = WEBRTC_SPL_ABS_W32((*tmpvector)); + if (absVal > tempMax) + { + tempMax = absVal; + } + tmpvector++; + } + retval = (WebRtc_Word32)(WEBRTC_SPL_MIN(tempMax, WEBRTC_SPL_WORD32_MAX)); + return retval; +} + +// Maximum value of word16 vector. +#ifndef XSCALE_OPT +WebRtc_Word16 WebRtcSpl_MaxValueW16(G_CONST WebRtc_Word16* vector, WebRtc_Word16 length) +{ + WebRtc_Word16 tempMax; + WebRtc_Word16 i; + G_CONST WebRtc_Word16 *tmpvector = vector; + + tempMax = *tmpvector++; + for (i = 1; i < length; i++) + { + if (*tmpvector++ > tempMax) + tempMax = vector[i]; + } + return tempMax; +} +#else +#pragma message(">> WebRtcSpl_MaxValueW16 is excluded from this build") +#endif + +// Index of maximum value in a word16 vector. +WebRtc_Word16 WebRtcSpl_MaxIndexW16(G_CONST WebRtc_Word16 *vector, WebRtc_Word16 length) +{ + WebRtc_Word16 tempMax; + WebRtc_Word16 tempMaxIndex = 0; + WebRtc_Word16 i = 0; + G_CONST WebRtc_Word16 *tmpvector = vector; + + tempMax = *tmpvector++; + for (i = 1; i < length; i++) + { + if (*tmpvector++ > tempMax) + { + tempMax = vector[i]; + tempMaxIndex = i; + } + } + return tempMaxIndex; +} + +// Maximum value of word32 vector. +#ifndef XSCALE_OPT +WebRtc_Word32 WebRtcSpl_MaxValueW32(G_CONST WebRtc_Word32* vector, WebRtc_Word16 length) +{ + WebRtc_Word32 tempMax; + WebRtc_Word16 i; + G_CONST WebRtc_Word32 *tmpvector = vector; + + tempMax = *tmpvector++; + for (i = 1; i < length; i++) + { + if (*tmpvector++ > tempMax) + tempMax = vector[i]; + } + return tempMax; +} +#else +#pragma message(">> WebRtcSpl_MaxValueW32 is excluded from this build") +#endif + +// Index of maximum value in a word32 vector. +WebRtc_Word16 WebRtcSpl_MaxIndexW32(G_CONST WebRtc_Word32* vector, WebRtc_Word16 length) +{ + WebRtc_Word32 tempMax; + WebRtc_Word16 tempMaxIndex = 0; + WebRtc_Word16 i = 0; + G_CONST WebRtc_Word32 *tmpvector = vector; + + tempMax = *tmpvector++; + for (i = 1; i < length; i++) + { + if (*tmpvector++ > tempMax) + { + tempMax = vector[i]; + tempMaxIndex = i; + } + } + return tempMaxIndex; +} + +// Minimum value of word16 vector. +WebRtc_Word16 WebRtcSpl_MinValueW16(G_CONST WebRtc_Word16 *vector, WebRtc_Word16 length) +{ + WebRtc_Word16 tempMin; + WebRtc_Word16 i; + G_CONST WebRtc_Word16 *tmpvector = vector; + + // Find the minimum value + tempMin = *tmpvector++; + for (i = 1; i < length; i++) + { + if (*tmpvector++ < tempMin) + tempMin = (vector[i]); + } + return tempMin; +} + +// Index of minimum value in a word16 vector. +#ifndef XSCALE_OPT +WebRtc_Word16 WebRtcSpl_MinIndexW16(G_CONST WebRtc_Word16* vector, WebRtc_Word16 length) +{ + WebRtc_Word16 tempMin; + WebRtc_Word16 tempMinIndex = 0; + WebRtc_Word16 i = 0; + G_CONST WebRtc_Word16* tmpvector = vector; + + // Find index of smallest value + tempMin = *tmpvector++; + for (i = 1; i < length; i++) + { + if (*tmpvector++ < tempMin) + { + tempMin = vector[i]; + tempMinIndex = i; + } + } + return tempMinIndex; +} +#else +#pragma message(">> WebRtcSpl_MinIndexW16 is excluded from this build") +#endif + +// Minimum value of word32 vector. +WebRtc_Word32 WebRtcSpl_MinValueW32(G_CONST WebRtc_Word32 *vector, WebRtc_Word16 length) +{ + WebRtc_Word32 tempMin; + WebRtc_Word16 i; + G_CONST WebRtc_Word32 *tmpvector = vector; + + // Find the minimum value + tempMin = *tmpvector++; + for (i = 1; i < length; i++) + { + if (*tmpvector++ < tempMin) + tempMin = (vector[i]); + } + return tempMin; +} + +// Index of minimum value in a word32 vector. +#ifndef XSCALE_OPT +WebRtc_Word16 WebRtcSpl_MinIndexW32(G_CONST WebRtc_Word32* vector, WebRtc_Word16 length) +{ + WebRtc_Word32 tempMin; + WebRtc_Word16 tempMinIndex = 0; + WebRtc_Word16 i = 0; + G_CONST WebRtc_Word32 *tmpvector = vector; + + // Find index of smallest value + tempMin = *tmpvector++; + for (i = 1; i < length; i++) + { + if (*tmpvector++ < tempMin) + { + tempMin = vector[i]; + tempMinIndex = i; + } + } + return tempMinIndex; +} +#else +#pragma message(">> WebRtcSpl_MinIndexW32 is excluded from this build") +#endif diff --git a/src/common_audio/signal_processing_library/main/source/min_max_operations_neon.c b/src/common_audio/signal_processing_library/main/source/min_max_operations_neon.c new file mode 100644 index 0000000..158bcc1 --- /dev/null +++ b/src/common_audio/signal_processing_library/main/source/min_max_operations_neon.c @@ -0,0 +1,47 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +#if (defined(WEBRTC_ANDROID) && defined(WEBRTC_ARCH_ARM_NEON)) + +#include + +#include "signal_processing_library.h" + +// Maximum absolute value of word16 vector. +WebRtc_Word16 WebRtcSpl_MaxAbsValueW16(const WebRtc_Word16* vector, + WebRtc_Word16 length) { + WebRtc_Word32 temp_max = 0; + WebRtc_Word32 abs_val; + WebRtc_Word16 tot_max; + int i; + + __asm__("vmov.i16 d25, #0" : : : "d25"); + + for (i = 0; i < length - 7; i += 8) { + __asm__("vld1.16 {d26, d27}, [%0]" : : "r"(&vector[i]) : "q13"); + __asm__("vabs.s16 q13, q13" : : : "q13"); + __asm__("vpmax.s16 d26, d27" : : : "q13"); + __asm__("vpmax.s16 d25, d26" : : : "d25", "d26"); + } + __asm__("vpmax.s16 d25, d25" : : : "d25"); + __asm__("vpmax.s16 d25, d25" : : : "d25"); + __asm__("vmov.s16 %0, d25[0]" : "=r"(temp_max): : "d25"); + + for (; i < length; i++) { + abs_val = WEBRTC_SPL_ABS_W32((vector[i])); + if (abs_val > temp_max) { + temp_max = abs_val; + } + } + tot_max = (WebRtc_Word16)WEBRTC_SPL_MIN(temp_max, WEBRTC_SPL_WORD16_MAX); + return tot_max; +} + +#endif diff --git a/src/common_audio/signal_processing_library/main/source/randn_table.c b/src/common_audio/signal_processing_library/main/source/randn_table.c new file mode 100644 index 0000000..734fa79 --- /dev/null +++ b/src/common_audio/signal_processing_library/main/source/randn_table.c @@ -0,0 +1,85 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + + +/* + * Table with 512 samples from a normal distribution with mean 1 and std 1 + * The values are shifted up 13 steps (multiplied by 8192) + */ + +#include "signal_processing_library.h" + +WebRtc_Word16 WebRtcSpl_kRandNTable[] = +{ + 9178, -7260, 40, 10189, 4894, -3531, -13779, 14764, + -4008, -8884, -8990, 1008, 7368, 5184, 3251, -5817, + -9786, 5963, 1770, 8066, -7135, 10772, -2298, 1361, + 6484, 2241, -8633, 792, 199, -3344, 6553, -10079, + -15040, 95, 11608, -12469, 14161, -4176, 2476, 6403, + 13685, -16005, 6646, 2239, 10916, -3004, -602, -3141, + 2142, 14144, -5829, 5305, 8209, 4713, 2697, -5112, + 16092, -1210, -2891, -6631, -5360, -11878, -6781, -2739, + -6392, 536, 10923, 10872, 5059, -4748, -7770, 5477, + 38, -1025, -2892, 1638, 6304, 14375, -11028, 1553, + -1565, 10762, -393, 4040, 5257, 12310, 6554, -4799, + 4899, -6354, 1603, -1048, -2220, 8247, -186, -8944, + -12004, 2332, 4801, -4933, 6371, 131, 8614, -5927, + -8287, -22760, 4033, -15162, 3385, 3246, 3153, -5250, + 3766, 784, 6494, -62, 3531, -1582, 15572, 662, + -3952, -330, -3196, 669, 7236, -2678, -6569, 23319, + -8645, -741, 14830, -15976, 4903, 315, -11342, 10311, + 1858, -7777, 2145, 5436, 5677, -113, -10033, 826, + -1353, 17210, 7768, 986, -1471, 8291, -4982, 8207, + -14911, -6255, -2449, -11881, -7059, -11703, -4338, 8025, + 7538, -2823, -12490, 9470, -1613, -2529, -10092, -7807, + 9480, 6970, -12844, 5123, 3532, 4816, 4803, -8455, + -5045, 14032, -4378, -1643, 5756, -11041, -2732, -16618, + -6430, -18375, -3320, 6098, 5131, -4269, -8840, 2482, + -7048, 1547, -21890, -6505, -7414, -424, -11722, 7955, + 1653, -17299, 1823, 473, -9232, 3337, 1111, 873, + 4018, -8982, 9889, 3531, -11763, -3799, 7373, -4539, + 3231, 7054, -8537, 7616, 6244, 16635, 447, -2915, + 13967, 705, -2669, -1520, -1771, -16188, 5956, 5117, + 6371, -9936, -1448, 2480, 5128, 7550, -8130, 5236, + 8213, -6443, 7707, -1950, -13811, 7218, 7031, -3883, + 67, 5731, -2874, 13480, -3743, 9298, -3280, 3552, + -4425, -18, -3785, -9988, -5357, 5477, -11794, 2117, + 1416, -9935, 3376, 802, -5079, -8243, 12652, 66, + 3653, -2368, 6781, -21895, -7227, 2487, 7839, -385, + 6646, -7016, -4658, 5531, -1705, 834, 129, 3694, + -1343, 2238, -22640, -6417, -11139, 11301, -2945, -3494, + -5626, 185, -3615, -2041, -7972, -3106, -60, -23497, + -1566, 17064, 3519, 2518, 304, -6805, -10269, 2105, + 1936, -426, -736, -8122, -1467, 4238, -6939, -13309, + 360, 7402, -7970, 12576, 3287, 12194, -6289, -16006, + 9171, 4042, -9193, 9123, -2512, 6388, -4734, -8739, + 1028, -5406, -1696, 5889, -666, -4736, 4971, 3565, + 9362, -6292, 3876, -3652, -19666, 7523, -4061, 391, + -11773, 7502, -3763, 4929, -9478, 13278, 2805, 4496, + 7814, 16419, 12455, -14773, 2127, -2746, 3763, 4847, + 3698, 6978, 4751, -6957, -3581, -45, 6252, 1513, + -4797, -7925, 11270, 16188, -2359, -5269, 9376, -10777, + 7262, 20031, -6515, -2208, -5353, 8085, -1341, -1303, + 7333, 5576, 3625, 5763, -7931, 9833, -3371, -10305, + 6534, -13539, -9971, 997, 8464, -4064, -1495, 1857, + 13624, 5458, 9490, -11086, -4524, 12022, -550, -198, + 408, -8455, -7068, 10289, 9712, -3366, 9028, -7621, + -5243, 2362, 6909, 4672, -4933, -1799, 4709, -4563, + -62, -566, 1624, -7010, 14730, -17791, -3697, -2344, + -1741, 7099, -9509, -6855, -1989, 3495, -2289, 2031, + 12784, 891, 14189, -3963, -5683, 421, -12575, 1724, + -12682, -5970, -8169, 3143, -1824, -5488, -5130, 8536, + 12799, 794, 5738, 3459, -11689, -258, -3738, -3775, + -8742, 2333, 8312, -9383, 10331, 13119, 8398, 10644, + -19433, -6446, -16277, -11793, 16284, 9345, 15222, 15834, + 2009, -7349, 130, -14547, 338, -5998, 3337, 21492, + 2406, 7703, -951, 11196, -564, 3406, 2217, 4806, + 2374, -5797, 11839, 8940, -11874, 18213, 2855, 10492 +}; diff --git a/src/common_audio/signal_processing_library/main/source/randomization_functions.c b/src/common_audio/signal_processing_library/main/source/randomization_functions.c new file mode 100644 index 0000000..6bc87c7 --- /dev/null +++ b/src/common_audio/signal_processing_library/main/source/randomization_functions.c @@ -0,0 +1,52 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + + +/* + * This file contains implementations of the randomization functions + * WebRtcSpl_IncreaseSeed() + * WebRtcSpl_RandU() + * WebRtcSpl_RandN() + * WebRtcSpl_RandUArray() + * + * The description header can be found in signal_processing_library.h + * + */ + +#include "signal_processing_library.h" + +WebRtc_UWord32 WebRtcSpl_IncreaseSeed(WebRtc_UWord32 *seed) +{ + seed[0] = (seed[0] * ((WebRtc_Word32)69069) + 1) & (WEBRTC_SPL_MAX_SEED_USED - 1); + return seed[0]; +} + +WebRtc_Word16 WebRtcSpl_RandU(WebRtc_UWord32 *seed) +{ + return (WebRtc_Word16)(WebRtcSpl_IncreaseSeed(seed) >> 16); +} + +WebRtc_Word16 WebRtcSpl_RandN(WebRtc_UWord32 *seed) +{ + return WebRtcSpl_kRandNTable[WebRtcSpl_IncreaseSeed(seed) >> 23]; +} + +// Creates an array of uniformly distributed variables +WebRtc_Word16 WebRtcSpl_RandUArray(WebRtc_Word16* vector, + WebRtc_Word16 vector_length, + WebRtc_UWord32* seed) +{ + int i; + for (i = 0; i < vector_length; i++) + { + vector[i] = WebRtcSpl_RandU(seed); + } + return vector_length; +} diff --git a/src/common_audio/signal_processing_library/main/source/refl_coef_to_lpc.c b/src/common_audio/signal_processing_library/main/source/refl_coef_to_lpc.c new file mode 100644 index 0000000..d07804d --- /dev/null +++ b/src/common_audio/signal_processing_library/main/source/refl_coef_to_lpc.c @@ -0,0 +1,60 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + + +/* + * This file contains the function WebRtcSpl_ReflCoefToLpc(). + * The description header can be found in signal_processing_library.h + * + */ + +#include "signal_processing_library.h" + +void WebRtcSpl_ReflCoefToLpc(G_CONST WebRtc_Word16 *k, int use_order, WebRtc_Word16 *a) +{ + WebRtc_Word16 any[WEBRTC_SPL_MAX_LPC_ORDER + 1]; + WebRtc_Word16 *aptr, *aptr2, *anyptr; + G_CONST WebRtc_Word16 *kptr; + int m, i; + + kptr = k; + *a = 4096; // i.e., (Word16_MAX >> 3)+1. + *any = *a; + a[1] = WEBRTC_SPL_RSHIFT_W16((*k), 3); + + for (m = 1; m < use_order; m++) + { + kptr++; + aptr = a; + aptr++; + aptr2 = &a[m]; + anyptr = any; + anyptr++; + + any[m + 1] = WEBRTC_SPL_RSHIFT_W16((*kptr), 3); + for (i = 0; i < m; i++) + { + *anyptr = (*aptr) + + (WebRtc_Word16)WEBRTC_SPL_MUL_16_16_RSFT((*aptr2), (*kptr), 15); + anyptr++; + aptr++; + aptr2--; + } + + aptr = a; + anyptr = any; + for (i = 0; i < (m + 2); i++) + { + *aptr = *anyptr; + aptr++; + anyptr++; + } + } +} diff --git a/src/common_audio/signal_processing_library/main/source/resample.c b/src/common_audio/signal_processing_library/main/source/resample.c new file mode 100644 index 0000000..19d1778 --- /dev/null +++ b/src/common_audio/signal_processing_library/main/source/resample.c @@ -0,0 +1,505 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + + +/* + * This file contains the resampling functions for 22 kHz. + * The description header can be found in signal_processing_library.h + * + */ + +#include "signal_processing_library.h" +#include "resample_by_2_internal.h" + +// Declaration of internally used functions +static void WebRtcSpl_32khzTo22khzIntToShort(const WebRtc_Word32 *In, WebRtc_Word16 *Out, + const WebRtc_Word32 K); + +void WebRtcSpl_32khzTo22khzIntToInt(const WebRtc_Word32 *In, WebRtc_Word32 *Out, + const WebRtc_Word32 K); + +// interpolation coefficients +static const WebRtc_Word16 kCoefficients32To22[5][9] = { + {127, -712, 2359, -6333, 23456, 16775, -3695, 945, -154}, + {-39, 230, -830, 2785, 32366, -2324, 760, -218, 38}, + {117, -663, 2222, -6133, 26634, 13070, -3174, 831, -137}, + {-77, 457, -1677, 5958, 31175, -4136, 1405, -408, 71}, + { 98, -560, 1900, -5406, 29240, 9423, -2480, 663, -110} +}; + +////////////////////// +// 22 kHz -> 16 kHz // +////////////////////// + +// number of subblocks; options: 1, 2, 4, 5, 10 +#define SUB_BLOCKS_22_16 5 + +// 22 -> 16 resampler +void WebRtcSpl_Resample22khzTo16khz(const WebRtc_Word16* in, WebRtc_Word16* out, + WebRtcSpl_State22khzTo16khz* state, WebRtc_Word32* tmpmem) +{ + int k; + + // process two blocks of 10/SUB_BLOCKS_22_16 ms (to reduce temp buffer size) + for (k = 0; k < SUB_BLOCKS_22_16; k++) + { + ///// 22 --> 44 ///// + // WebRtc_Word16 in[220/SUB_BLOCKS_22_16] + // WebRtc_Word32 out[440/SUB_BLOCKS_22_16] + ///// + WebRtcSpl_UpBy2ShortToInt(in, 220 / SUB_BLOCKS_22_16, tmpmem + 16, state->S_22_44); + + ///// 44 --> 32 ///// + // WebRtc_Word32 in[440/SUB_BLOCKS_22_16] + // WebRtc_Word32 out[320/SUB_BLOCKS_22_16] + ///// + // copy state to and from input array + tmpmem[8] = state->S_44_32[0]; + tmpmem[9] = state->S_44_32[1]; + tmpmem[10] = state->S_44_32[2]; + tmpmem[11] = state->S_44_32[3]; + tmpmem[12] = state->S_44_32[4]; + tmpmem[13] = state->S_44_32[5]; + tmpmem[14] = state->S_44_32[6]; + tmpmem[15] = state->S_44_32[7]; + state->S_44_32[0] = tmpmem[440 / SUB_BLOCKS_22_16 + 8]; + state->S_44_32[1] = tmpmem[440 / SUB_BLOCKS_22_16 + 9]; + state->S_44_32[2] = tmpmem[440 / SUB_BLOCKS_22_16 + 10]; + state->S_44_32[3] = tmpmem[440 / SUB_BLOCKS_22_16 + 11]; + state->S_44_32[4] = tmpmem[440 / SUB_BLOCKS_22_16 + 12]; + state->S_44_32[5] = tmpmem[440 / SUB_BLOCKS_22_16 + 13]; + state->S_44_32[6] = tmpmem[440 / SUB_BLOCKS_22_16 + 14]; + state->S_44_32[7] = tmpmem[440 / SUB_BLOCKS_22_16 + 15]; + + WebRtcSpl_Resample44khzTo32khz(tmpmem + 8, tmpmem, 40 / SUB_BLOCKS_22_16); + + ///// 32 --> 16 ///// + // WebRtc_Word32 in[320/SUB_BLOCKS_22_16] + // WebRtc_Word32 out[160/SUB_BLOCKS_22_16] + ///// + WebRtcSpl_DownBy2IntToShort(tmpmem, 320 / SUB_BLOCKS_22_16, out, state->S_32_16); + + // move input/output pointers 10/SUB_BLOCKS_22_16 ms seconds ahead + in += 220 / SUB_BLOCKS_22_16; + out += 160 / SUB_BLOCKS_22_16; + } +} + +// initialize state of 22 -> 16 resampler +void WebRtcSpl_ResetResample22khzTo16khz(WebRtcSpl_State22khzTo16khz* state) +{ + int k; + for (k = 0; k < 8; k++) + { + state->S_22_44[k] = 0; + state->S_44_32[k] = 0; + state->S_32_16[k] = 0; + } +} + +////////////////////// +// 16 kHz -> 22 kHz // +////////////////////// + +// number of subblocks; options: 1, 2, 4, 5, 10 +#define SUB_BLOCKS_16_22 4 + +// 16 -> 22 resampler +void WebRtcSpl_Resample16khzTo22khz(const WebRtc_Word16* in, WebRtc_Word16* out, + WebRtcSpl_State16khzTo22khz* state, WebRtc_Word32* tmpmem) +{ + int k; + + // process two blocks of 10/SUB_BLOCKS_16_22 ms (to reduce temp buffer size) + for (k = 0; k < SUB_BLOCKS_16_22; k++) + { + ///// 16 --> 32 ///// + // WebRtc_Word16 in[160/SUB_BLOCKS_16_22] + // WebRtc_Word32 out[320/SUB_BLOCKS_16_22] + ///// + WebRtcSpl_UpBy2ShortToInt(in, 160 / SUB_BLOCKS_16_22, tmpmem + 8, state->S_16_32); + + ///// 32 --> 22 ///// + // WebRtc_Word32 in[320/SUB_BLOCKS_16_22] + // WebRtc_Word32 out[220/SUB_BLOCKS_16_22] + ///// + // copy state to and from input array + tmpmem[0] = state->S_32_22[0]; + tmpmem[1] = state->S_32_22[1]; + tmpmem[2] = state->S_32_22[2]; + tmpmem[3] = state->S_32_22[3]; + tmpmem[4] = state->S_32_22[4]; + tmpmem[5] = state->S_32_22[5]; + tmpmem[6] = state->S_32_22[6]; + tmpmem[7] = state->S_32_22[7]; + state->S_32_22[0] = tmpmem[320 / SUB_BLOCKS_16_22]; + state->S_32_22[1] = tmpmem[320 / SUB_BLOCKS_16_22 + 1]; + state->S_32_22[2] = tmpmem[320 / SUB_BLOCKS_16_22 + 2]; + state->S_32_22[3] = tmpmem[320 / SUB_BLOCKS_16_22 + 3]; + state->S_32_22[4] = tmpmem[320 / SUB_BLOCKS_16_22 + 4]; + state->S_32_22[5] = tmpmem[320 / SUB_BLOCKS_16_22 + 5]; + state->S_32_22[6] = tmpmem[320 / SUB_BLOCKS_16_22 + 6]; + state->S_32_22[7] = tmpmem[320 / SUB_BLOCKS_16_22 + 7]; + + WebRtcSpl_32khzTo22khzIntToShort(tmpmem, out, 20 / SUB_BLOCKS_16_22); + + // move input/output pointers 10/SUB_BLOCKS_16_22 ms seconds ahead + in += 160 / SUB_BLOCKS_16_22; + out += 220 / SUB_BLOCKS_16_22; + } +} + +// initialize state of 16 -> 22 resampler +void WebRtcSpl_ResetResample16khzTo22khz(WebRtcSpl_State16khzTo22khz* state) +{ + int k; + for (k = 0; k < 8; k++) + { + state->S_16_32[k] = 0; + state->S_32_22[k] = 0; + } +} + +////////////////////// +// 22 kHz -> 8 kHz // +////////////////////// + +// number of subblocks; options: 1, 2, 5, 10 +#define SUB_BLOCKS_22_8 2 + +// 22 -> 8 resampler +void WebRtcSpl_Resample22khzTo8khz(const WebRtc_Word16* in, WebRtc_Word16* out, + WebRtcSpl_State22khzTo8khz* state, WebRtc_Word32* tmpmem) +{ + int k; + + // process two blocks of 10/SUB_BLOCKS_22_8 ms (to reduce temp buffer size) + for (k = 0; k < SUB_BLOCKS_22_8; k++) + { + ///// 22 --> 22 lowpass ///// + // WebRtc_Word16 in[220/SUB_BLOCKS_22_8] + // WebRtc_Word32 out[220/SUB_BLOCKS_22_8] + ///// + WebRtcSpl_LPBy2ShortToInt(in, 220 / SUB_BLOCKS_22_8, tmpmem + 16, state->S_22_22); + + ///// 22 --> 16 ///// + // WebRtc_Word32 in[220/SUB_BLOCKS_22_8] + // WebRtc_Word32 out[160/SUB_BLOCKS_22_8] + ///// + // copy state to and from input array + tmpmem[8] = state->S_22_16[0]; + tmpmem[9] = state->S_22_16[1]; + tmpmem[10] = state->S_22_16[2]; + tmpmem[11] = state->S_22_16[3]; + tmpmem[12] = state->S_22_16[4]; + tmpmem[13] = state->S_22_16[5]; + tmpmem[14] = state->S_22_16[6]; + tmpmem[15] = state->S_22_16[7]; + state->S_22_16[0] = tmpmem[220 / SUB_BLOCKS_22_8 + 8]; + state->S_22_16[1] = tmpmem[220 / SUB_BLOCKS_22_8 + 9]; + state->S_22_16[2] = tmpmem[220 / SUB_BLOCKS_22_8 + 10]; + state->S_22_16[3] = tmpmem[220 / SUB_BLOCKS_22_8 + 11]; + state->S_22_16[4] = tmpmem[220 / SUB_BLOCKS_22_8 + 12]; + state->S_22_16[5] = tmpmem[220 / SUB_BLOCKS_22_8 + 13]; + state->S_22_16[6] = tmpmem[220 / SUB_BLOCKS_22_8 + 14]; + state->S_22_16[7] = tmpmem[220 / SUB_BLOCKS_22_8 + 15]; + + WebRtcSpl_Resample44khzTo32khz(tmpmem + 8, tmpmem, 20 / SUB_BLOCKS_22_8); + + ///// 16 --> 8 ///// + // WebRtc_Word32 in[160/SUB_BLOCKS_22_8] + // WebRtc_Word32 out[80/SUB_BLOCKS_22_8] + ///// + WebRtcSpl_DownBy2IntToShort(tmpmem, 160 / SUB_BLOCKS_22_8, out, state->S_16_8); + + // move input/output pointers 10/SUB_BLOCKS_22_8 ms seconds ahead + in += 220 / SUB_BLOCKS_22_8; + out += 80 / SUB_BLOCKS_22_8; + } +} + +// initialize state of 22 -> 8 resampler +void WebRtcSpl_ResetResample22khzTo8khz(WebRtcSpl_State22khzTo8khz* state) +{ + int k; + for (k = 0; k < 8; k++) + { + state->S_22_22[k] = 0; + state->S_22_22[k + 8] = 0; + state->S_22_16[k] = 0; + state->S_16_8[k] = 0; + } +} + +////////////////////// +// 8 kHz -> 22 kHz // +////////////////////// + +// number of subblocks; options: 1, 2, 5, 10 +#define SUB_BLOCKS_8_22 2 + +// 8 -> 22 resampler +void WebRtcSpl_Resample8khzTo22khz(const WebRtc_Word16* in, WebRtc_Word16* out, + WebRtcSpl_State8khzTo22khz* state, WebRtc_Word32* tmpmem) +{ + int k; + + // process two blocks of 10/SUB_BLOCKS_8_22 ms (to reduce temp buffer size) + for (k = 0; k < SUB_BLOCKS_8_22; k++) + { + ///// 8 --> 16 ///// + // WebRtc_Word16 in[80/SUB_BLOCKS_8_22] + // WebRtc_Word32 out[160/SUB_BLOCKS_8_22] + ///// + WebRtcSpl_UpBy2ShortToInt(in, 80 / SUB_BLOCKS_8_22, tmpmem + 18, state->S_8_16); + + ///// 16 --> 11 ///// + // WebRtc_Word32 in[160/SUB_BLOCKS_8_22] + // WebRtc_Word32 out[110/SUB_BLOCKS_8_22] + ///// + // copy state to and from input array + tmpmem[10] = state->S_16_11[0]; + tmpmem[11] = state->S_16_11[1]; + tmpmem[12] = state->S_16_11[2]; + tmpmem[13] = state->S_16_11[3]; + tmpmem[14] = state->S_16_11[4]; + tmpmem[15] = state->S_16_11[5]; + tmpmem[16] = state->S_16_11[6]; + tmpmem[17] = state->S_16_11[7]; + state->S_16_11[0] = tmpmem[160 / SUB_BLOCKS_8_22 + 10]; + state->S_16_11[1] = tmpmem[160 / SUB_BLOCKS_8_22 + 11]; + state->S_16_11[2] = tmpmem[160 / SUB_BLOCKS_8_22 + 12]; + state->S_16_11[3] = tmpmem[160 / SUB_BLOCKS_8_22 + 13]; + state->S_16_11[4] = tmpmem[160 / SUB_BLOCKS_8_22 + 14]; + state->S_16_11[5] = tmpmem[160 / SUB_BLOCKS_8_22 + 15]; + state->S_16_11[6] = tmpmem[160 / SUB_BLOCKS_8_22 + 16]; + state->S_16_11[7] = tmpmem[160 / SUB_BLOCKS_8_22 + 17]; + + WebRtcSpl_32khzTo22khzIntToInt(tmpmem + 10, tmpmem, 10 / SUB_BLOCKS_8_22); + + ///// 11 --> 22 ///// + // WebRtc_Word32 in[110/SUB_BLOCKS_8_22] + // WebRtc_Word16 out[220/SUB_BLOCKS_8_22] + ///// + WebRtcSpl_UpBy2IntToShort(tmpmem, 110 / SUB_BLOCKS_8_22, out, state->S_11_22); + + // move input/output pointers 10/SUB_BLOCKS_8_22 ms seconds ahead + in += 80 / SUB_BLOCKS_8_22; + out += 220 / SUB_BLOCKS_8_22; + } +} + +// initialize state of 8 -> 22 resampler +void WebRtcSpl_ResetResample8khzTo22khz(WebRtcSpl_State8khzTo22khz* state) +{ + int k; + for (k = 0; k < 8; k++) + { + state->S_8_16[k] = 0; + state->S_16_11[k] = 0; + state->S_11_22[k] = 0; + } +} + +// compute two inner-products and store them to output array +static void WebRtcSpl_DotProdIntToInt(const WebRtc_Word32* in1, const WebRtc_Word32* in2, + const WebRtc_Word16* coef_ptr, WebRtc_Word32* out1, + WebRtc_Word32* out2) +{ + WebRtc_Word32 tmp1 = 16384; + WebRtc_Word32 tmp2 = 16384; + WebRtc_Word16 coef; + + coef = coef_ptr[0]; + tmp1 += coef * in1[0]; + tmp2 += coef * in2[-0]; + + coef = coef_ptr[1]; + tmp1 += coef * in1[1]; + tmp2 += coef * in2[-1]; + + coef = coef_ptr[2]; + tmp1 += coef * in1[2]; + tmp2 += coef * in2[-2]; + + coef = coef_ptr[3]; + tmp1 += coef * in1[3]; + tmp2 += coef * in2[-3]; + + coef = coef_ptr[4]; + tmp1 += coef * in1[4]; + tmp2 += coef * in2[-4]; + + coef = coef_ptr[5]; + tmp1 += coef * in1[5]; + tmp2 += coef * in2[-5]; + + coef = coef_ptr[6]; + tmp1 += coef * in1[6]; + tmp2 += coef * in2[-6]; + + coef = coef_ptr[7]; + tmp1 += coef * in1[7]; + tmp2 += coef * in2[-7]; + + coef = coef_ptr[8]; + *out1 = tmp1 + coef * in1[8]; + *out2 = tmp2 + coef * in2[-8]; +} + +// compute two inner-products and store them to output array +static void WebRtcSpl_DotProdIntToShort(const WebRtc_Word32* in1, const WebRtc_Word32* in2, + const WebRtc_Word16* coef_ptr, WebRtc_Word16* out1, + WebRtc_Word16* out2) +{ + WebRtc_Word32 tmp1 = 16384; + WebRtc_Word32 tmp2 = 16384; + WebRtc_Word16 coef; + + coef = coef_ptr[0]; + tmp1 += coef * in1[0]; + tmp2 += coef * in2[-0]; + + coef = coef_ptr[1]; + tmp1 += coef * in1[1]; + tmp2 += coef * in2[-1]; + + coef = coef_ptr[2]; + tmp1 += coef * in1[2]; + tmp2 += coef * in2[-2]; + + coef = coef_ptr[3]; + tmp1 += coef * in1[3]; + tmp2 += coef * in2[-3]; + + coef = coef_ptr[4]; + tmp1 += coef * in1[4]; + tmp2 += coef * in2[-4]; + + coef = coef_ptr[5]; + tmp1 += coef * in1[5]; + tmp2 += coef * in2[-5]; + + coef = coef_ptr[6]; + tmp1 += coef * in1[6]; + tmp2 += coef * in2[-6]; + + coef = coef_ptr[7]; + tmp1 += coef * in1[7]; + tmp2 += coef * in2[-7]; + + coef = coef_ptr[8]; + tmp1 += coef * in1[8]; + tmp2 += coef * in2[-8]; + + // scale down, round and saturate + tmp1 >>= 15; + if (tmp1 > (WebRtc_Word32)0x00007FFF) + tmp1 = 0x00007FFF; + if (tmp1 < (WebRtc_Word32)0xFFFF8000) + tmp1 = 0xFFFF8000; + tmp2 >>= 15; + if (tmp2 > (WebRtc_Word32)0x00007FFF) + tmp2 = 0x00007FFF; + if (tmp2 < (WebRtc_Word32)0xFFFF8000) + tmp2 = 0xFFFF8000; + *out1 = (WebRtc_Word16)tmp1; + *out2 = (WebRtc_Word16)tmp2; +} + +// Resampling ratio: 11/16 +// input: WebRtc_Word32 (normalized, not saturated) :: size 16 * K +// output: WebRtc_Word32 (shifted 15 positions to the left, + offset 16384) :: size 11 * K +// K: Number of blocks + +void WebRtcSpl_32khzTo22khzIntToInt(const WebRtc_Word32* In, + WebRtc_Word32* Out, + const WebRtc_Word32 K) +{ + ///////////////////////////////////////////////////////////// + // Filter operation: + // + // Perform resampling (16 input samples -> 11 output samples); + // process in sub blocks of size 16 samples. + WebRtc_Word32 m; + + for (m = 0; m < K; m++) + { + // first output sample + Out[0] = ((WebRtc_Word32)In[3] << 15) + (1 << 14); + + // sum and accumulate filter coefficients and input samples + WebRtcSpl_DotProdIntToInt(&In[0], &In[22], kCoefficients32To22[0], &Out[1], &Out[10]); + + // sum and accumulate filter coefficients and input samples + WebRtcSpl_DotProdIntToInt(&In[2], &In[20], kCoefficients32To22[1], &Out[2], &Out[9]); + + // sum and accumulate filter coefficients and input samples + WebRtcSpl_DotProdIntToInt(&In[3], &In[19], kCoefficients32To22[2], &Out[3], &Out[8]); + + // sum and accumulate filter coefficients and input samples + WebRtcSpl_DotProdIntToInt(&In[5], &In[17], kCoefficients32To22[3], &Out[4], &Out[7]); + + // sum and accumulate filter coefficients and input samples + WebRtcSpl_DotProdIntToInt(&In[6], &In[16], kCoefficients32To22[4], &Out[5], &Out[6]); + + // update pointers + In += 16; + Out += 11; + } +} + +// Resampling ratio: 11/16 +// input: WebRtc_Word32 (normalized, not saturated) :: size 16 * K +// output: WebRtc_Word16 (saturated) :: size 11 * K +// K: Number of blocks + +void WebRtcSpl_32khzTo22khzIntToShort(const WebRtc_Word32 *In, + WebRtc_Word16 *Out, + const WebRtc_Word32 K) +{ + ///////////////////////////////////////////////////////////// + // Filter operation: + // + // Perform resampling (16 input samples -> 11 output samples); + // process in sub blocks of size 16 samples. + WebRtc_Word32 tmp; + WebRtc_Word32 m; + + for (m = 0; m < K; m++) + { + // first output sample + tmp = In[3]; + if (tmp > (WebRtc_Word32)0x00007FFF) + tmp = 0x00007FFF; + if (tmp < (WebRtc_Word32)0xFFFF8000) + tmp = 0xFFFF8000; + Out[0] = (WebRtc_Word16)tmp; + + // sum and accumulate filter coefficients and input samples + WebRtcSpl_DotProdIntToShort(&In[0], &In[22], kCoefficients32To22[0], &Out[1], &Out[10]); + + // sum and accumulate filter coefficients and input samples + WebRtcSpl_DotProdIntToShort(&In[2], &In[20], kCoefficients32To22[1], &Out[2], &Out[9]); + + // sum and accumulate filter coefficients and input samples + WebRtcSpl_DotProdIntToShort(&In[3], &In[19], kCoefficients32To22[2], &Out[3], &Out[8]); + + // sum and accumulate filter coefficients and input samples + WebRtcSpl_DotProdIntToShort(&In[5], &In[17], kCoefficients32To22[3], &Out[4], &Out[7]); + + // sum and accumulate filter coefficients and input samples + WebRtcSpl_DotProdIntToShort(&In[6], &In[16], kCoefficients32To22[4], &Out[5], &Out[6]); + + // update pointers + In += 16; + Out += 11; + } +} diff --git a/src/common_audio/signal_processing_library/main/source/resample_48khz.c b/src/common_audio/signal_processing_library/main/source/resample_48khz.c new file mode 100644 index 0000000..31cbe6b --- /dev/null +++ b/src/common_audio/signal_processing_library/main/source/resample_48khz.c @@ -0,0 +1,186 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + + +/* + * This file contains resampling functions between 48 kHz and nb/wb. + * The description header can be found in signal_processing_library.h + * + */ + +#include +#include "signal_processing_library.h" +#include "resample_by_2_internal.h" + +//////////////////////////// +///// 48 kHz -> 16 kHz ///// +//////////////////////////// + +// 48 -> 16 resampler +void WebRtcSpl_Resample48khzTo16khz(const WebRtc_Word16* in, WebRtc_Word16* out, + WebRtcSpl_State48khzTo16khz* state, WebRtc_Word32* tmpmem) +{ + ///// 48 --> 48(LP) ///// + // WebRtc_Word16 in[480] + // WebRtc_Word32 out[480] + ///// + WebRtcSpl_LPBy2ShortToInt(in, 480, tmpmem + 16, state->S_48_48); + + ///// 48 --> 32 ///// + // WebRtc_Word32 in[480] + // WebRtc_Word32 out[320] + ///// + // copy state to and from input array + memcpy(tmpmem + 8, state->S_48_32, 8 * sizeof(WebRtc_Word32)); + memcpy(state->S_48_32, tmpmem + 488, 8 * sizeof(WebRtc_Word32)); + WebRtcSpl_Resample48khzTo32khz(tmpmem + 8, tmpmem, 160); + + ///// 32 --> 16 ///// + // WebRtc_Word32 in[320] + // WebRtc_Word16 out[160] + ///// + WebRtcSpl_DownBy2IntToShort(tmpmem, 320, out, state->S_32_16); +} + +// initialize state of 48 -> 16 resampler +void WebRtcSpl_ResetResample48khzTo16khz(WebRtcSpl_State48khzTo16khz* state) +{ + memset(state->S_48_48, 0, 16 * sizeof(WebRtc_Word32)); + memset(state->S_48_32, 0, 8 * sizeof(WebRtc_Word32)); + memset(state->S_32_16, 0, 8 * sizeof(WebRtc_Word32)); +} + +//////////////////////////// +///// 16 kHz -> 48 kHz ///// +//////////////////////////// + +// 16 -> 48 resampler +void WebRtcSpl_Resample16khzTo48khz(const WebRtc_Word16* in, WebRtc_Word16* out, + WebRtcSpl_State16khzTo48khz* state, WebRtc_Word32* tmpmem) +{ + ///// 16 --> 32 ///// + // WebRtc_Word16 in[160] + // WebRtc_Word32 out[320] + ///// + WebRtcSpl_UpBy2ShortToInt(in, 160, tmpmem + 16, state->S_16_32); + + ///// 32 --> 24 ///// + // WebRtc_Word32 in[320] + // WebRtc_Word32 out[240] + // copy state to and from input array + ///// + memcpy(tmpmem + 8, state->S_32_24, 8 * sizeof(WebRtc_Word32)); + memcpy(state->S_32_24, tmpmem + 328, 8 * sizeof(WebRtc_Word32)); + WebRtcSpl_Resample32khzTo24khz(tmpmem + 8, tmpmem, 80); + + ///// 24 --> 48 ///// + // WebRtc_Word32 in[240] + // WebRtc_Word16 out[480] + ///// + WebRtcSpl_UpBy2IntToShort(tmpmem, 240, out, state->S_24_48); +} + +// initialize state of 16 -> 48 resampler +void WebRtcSpl_ResetResample16khzTo48khz(WebRtcSpl_State16khzTo48khz* state) +{ + memset(state->S_16_32, 0, 8 * sizeof(WebRtc_Word32)); + memset(state->S_32_24, 0, 8 * sizeof(WebRtc_Word32)); + memset(state->S_24_48, 0, 8 * sizeof(WebRtc_Word32)); +} + +//////////////////////////// +///// 48 kHz -> 8 kHz ///// +//////////////////////////// + +// 48 -> 8 resampler +void WebRtcSpl_Resample48khzTo8khz(const WebRtc_Word16* in, WebRtc_Word16* out, + WebRtcSpl_State48khzTo8khz* state, WebRtc_Word32* tmpmem) +{ + ///// 48 --> 24 ///// + // WebRtc_Word16 in[480] + // WebRtc_Word32 out[240] + ///// + WebRtcSpl_DownBy2ShortToInt(in, 480, tmpmem + 256, state->S_48_24); + + ///// 24 --> 24(LP) ///// + // WebRtc_Word32 in[240] + // WebRtc_Word32 out[240] + ///// + WebRtcSpl_LPBy2IntToInt(tmpmem + 256, 240, tmpmem + 16, state->S_24_24); + + ///// 24 --> 16 ///// + // WebRtc_Word32 in[240] + // WebRtc_Word32 out[160] + ///// + // copy state to and from input array + memcpy(tmpmem + 8, state->S_24_16, 8 * sizeof(WebRtc_Word32)); + memcpy(state->S_24_16, tmpmem + 248, 8 * sizeof(WebRtc_Word32)); + WebRtcSpl_Resample48khzTo32khz(tmpmem + 8, tmpmem, 80); + + ///// 16 --> 8 ///// + // WebRtc_Word32 in[160] + // WebRtc_Word16 out[80] + ///// + WebRtcSpl_DownBy2IntToShort(tmpmem, 160, out, state->S_16_8); +} + +// initialize state of 48 -> 8 resampler +void WebRtcSpl_ResetResample48khzTo8khz(WebRtcSpl_State48khzTo8khz* state) +{ + memset(state->S_48_24, 0, 8 * sizeof(WebRtc_Word32)); + memset(state->S_24_24, 0, 16 * sizeof(WebRtc_Word32)); + memset(state->S_24_16, 0, 8 * sizeof(WebRtc_Word32)); + memset(state->S_16_8, 0, 8 * sizeof(WebRtc_Word32)); +} + +//////////////////////////// +///// 8 kHz -> 48 kHz ///// +//////////////////////////// + +// 8 -> 48 resampler +void WebRtcSpl_Resample8khzTo48khz(const WebRtc_Word16* in, WebRtc_Word16* out, + WebRtcSpl_State8khzTo48khz* state, WebRtc_Word32* tmpmem) +{ + ///// 8 --> 16 ///// + // WebRtc_Word16 in[80] + // WebRtc_Word32 out[160] + ///// + WebRtcSpl_UpBy2ShortToInt(in, 80, tmpmem + 264, state->S_8_16); + + ///// 16 --> 12 ///// + // WebRtc_Word32 in[160] + // WebRtc_Word32 out[120] + ///// + // copy state to and from input array + memcpy(tmpmem + 256, state->S_16_12, 8 * sizeof(WebRtc_Word32)); + memcpy(state->S_16_12, tmpmem + 416, 8 * sizeof(WebRtc_Word32)); + WebRtcSpl_Resample32khzTo24khz(tmpmem + 256, tmpmem + 240, 40); + + ///// 12 --> 24 ///// + // WebRtc_Word32 in[120] + // WebRtc_Word16 out[240] + ///// + WebRtcSpl_UpBy2IntToInt(tmpmem + 240, 120, tmpmem, state->S_12_24); + + ///// 24 --> 48 ///// + // WebRtc_Word32 in[240] + // WebRtc_Word16 out[480] + ///// + WebRtcSpl_UpBy2IntToShort(tmpmem, 240, out, state->S_24_48); +} + +// initialize state of 8 -> 48 resampler +void WebRtcSpl_ResetResample8khzTo48khz(WebRtcSpl_State8khzTo48khz* state) +{ + memset(state->S_8_16, 0, 8 * sizeof(WebRtc_Word32)); + memset(state->S_16_12, 0, 8 * sizeof(WebRtc_Word32)); + memset(state->S_12_24, 0, 8 * sizeof(WebRtc_Word32)); + memset(state->S_24_48, 0, 8 * sizeof(WebRtc_Word32)); +} diff --git a/src/common_audio/signal_processing_library/main/source/resample_by_2.c b/src/common_audio/signal_processing_library/main/source/resample_by_2.c new file mode 100644 index 0000000..6c296ba --- /dev/null +++ b/src/common_audio/signal_processing_library/main/source/resample_by_2.c @@ -0,0 +1,170 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + + +/* + * This file contains the resampling by two functions. + * The description header can be found in signal_processing_library.h + * + */ + +#include "signal_processing_library.h" + +// allpass filter coefficients. +static const WebRtc_UWord16 kResampleAllpass1[3] = {3284, 24441, 49528}; +static const WebRtc_UWord16 kResampleAllpass2[3] = {12199, 37471, 60255}; + +// decimator +void WebRtcSpl_DownsampleBy2(const WebRtc_Word16* in, const WebRtc_Word16 len, + WebRtc_Word16* out, WebRtc_Word32* filtState) +{ + WebRtc_Word32 tmp1, tmp2, diff, in32, out32; + WebRtc_Word16 i; + + register WebRtc_Word32 state0 = filtState[0]; + register WebRtc_Word32 state1 = filtState[1]; + register WebRtc_Word32 state2 = filtState[2]; + register WebRtc_Word32 state3 = filtState[3]; + register WebRtc_Word32 state4 = filtState[4]; + register WebRtc_Word32 state5 = filtState[5]; + register WebRtc_Word32 state6 = filtState[6]; + register WebRtc_Word32 state7 = filtState[7]; + + for (i = (len >> 1); i > 0; i--) + { + // lower allpass filter + in32 = (WebRtc_Word32)(*in++) << 10; + diff = in32 - state1; + tmp1 = WEBRTC_SPL_SCALEDIFF32(kResampleAllpass2[0], diff, state0); + state0 = in32; + diff = tmp1 - state2; + tmp2 = WEBRTC_SPL_SCALEDIFF32(kResampleAllpass2[1], diff, state1); + state1 = tmp1; + diff = tmp2 - state3; + state3 = WEBRTC_SPL_SCALEDIFF32(kResampleAllpass2[2], diff, state2); + state2 = tmp2; + + // upper allpass filter + in32 = (WebRtc_Word32)(*in++) << 10; + diff = in32 - state5; + tmp1 = WEBRTC_SPL_SCALEDIFF32(kResampleAllpass1[0], diff, state4); + state4 = in32; + diff = tmp1 - state6; + tmp2 = WEBRTC_SPL_SCALEDIFF32(kResampleAllpass1[1], diff, state5); + state5 = tmp1; + diff = tmp2 - state7; + state7 = WEBRTC_SPL_SCALEDIFF32(kResampleAllpass1[2], diff, state6); + state6 = tmp2; + + // add two allpass outputs, divide by two and round + out32 = (state3 + state7 + 1024) >> 11; + + // limit amplitude to prevent wrap-around, and write to output array +#ifdef WEBRTC_ARCH_ARM_V7A + __asm__("ssat %r0, #16, %r1" : "=r"(*out) : "r"(out32)); + out++; +#else + if (out32 > 32767) + *out++ = 32767; + else if (out32 < -32768) + *out++ = -32768; + else + *out++ = (WebRtc_Word16)out32; +#endif + } + + filtState[0] = state0; + filtState[1] = state1; + filtState[2] = state2; + filtState[3] = state3; + filtState[4] = state4; + filtState[5] = state5; + filtState[6] = state6; + filtState[7] = state7; +} + +void WebRtcSpl_UpsampleBy2(const WebRtc_Word16* in, WebRtc_Word16 len, WebRtc_Word16* out, + WebRtc_Word32* filtState) +{ + WebRtc_Word32 tmp1, tmp2, diff, in32, out32; + WebRtc_Word16 i; + + register WebRtc_Word32 state0 = filtState[0]; + register WebRtc_Word32 state1 = filtState[1]; + register WebRtc_Word32 state2 = filtState[2]; + register WebRtc_Word32 state3 = filtState[3]; + register WebRtc_Word32 state4 = filtState[4]; + register WebRtc_Word32 state5 = filtState[5]; + register WebRtc_Word32 state6 = filtState[6]; + register WebRtc_Word32 state7 = filtState[7]; + + for (i = len; i > 0; i--) + { + // lower allpass filter + in32 = (WebRtc_Word32)(*in++) << 10; + diff = in32 - state1; + tmp1 = WEBRTC_SPL_SCALEDIFF32(kResampleAllpass1[0], diff, state0); + state0 = in32; + diff = tmp1 - state2; + tmp2 = WEBRTC_SPL_SCALEDIFF32(kResampleAllpass1[1], diff, state1); + state1 = tmp1; + diff = tmp2 - state3; + state3 = WEBRTC_SPL_SCALEDIFF32(kResampleAllpass1[2], diff, state2); + state2 = tmp2; + + // round; limit amplitude to prevent wrap-around; write to output array + out32 = (state3 + 512) >> 10; +#ifdef WEBRTC_ARCH_ARM_V7A + __asm__("ssat %r0, #16, %r1":"=r"(*out): "r"(out32)); + out++; +#else + if (out32 > 32767) + *out++ = 32767; + else if (out32 < -32768) + *out++ = -32768; + else + *out++ = (WebRtc_Word16)out32; +#endif + + // upper allpass filter + diff = in32 - state5; + tmp1 = WEBRTC_SPL_SCALEDIFF32(kResampleAllpass2[0], diff, state4); + state4 = in32; + diff = tmp1 - state6; + tmp2 = WEBRTC_SPL_SCALEDIFF32(kResampleAllpass2[1], diff, state5); + state5 = tmp1; + diff = tmp2 - state7; + state7 = WEBRTC_SPL_SCALEDIFF32(kResampleAllpass2[2], diff, state6); + state6 = tmp2; + + // round; limit amplitude to prevent wrap-around; write to output array + out32 = (state7 + 512) >> 10; +#ifdef WEBRTC_ARCH_ARM_V7A + __asm__("ssat %r0, #16, %r1":"=r"(*out): "r"(out32)); + out++; +#else + if (out32 > 32767) + *out++ = 32767; + else if (out32 < -32768) + *out++ = -32768; + else + *out++ = (WebRtc_Word16)out32; +#endif + } + + filtState[0] = state0; + filtState[1] = state1; + filtState[2] = state2; + filtState[3] = state3; + filtState[4] = state4; + filtState[5] = state5; + filtState[6] = state6; + filtState[7] = state7; +} diff --git a/src/common_audio/signal_processing_library/main/source/resample_by_2_internal.c b/src/common_audio/signal_processing_library/main/source/resample_by_2_internal.c new file mode 100644 index 0000000..cbd2395 --- /dev/null +++ b/src/common_audio/signal_processing_library/main/source/resample_by_2_internal.c @@ -0,0 +1,679 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + + +/* + * This header file contains some internal resampling functions. + * + */ + +#include "resample_by_2_internal.h" + +// allpass filter coefficients. +static const WebRtc_Word16 kResampleAllpass[2][3] = { + {821, 6110, 12382}, + {3050, 9368, 15063} +}; + +// +// decimator +// input: WebRtc_Word32 (shifted 15 positions to the left, + offset 16384) OVERWRITTEN! +// output: WebRtc_Word16 (saturated) (of length len/2) +// state: filter state array; length = 8 + +void WebRtcSpl_DownBy2IntToShort(WebRtc_Word32 *in, WebRtc_Word32 len, WebRtc_Word16 *out, + WebRtc_Word32 *state) +{ + WebRtc_Word32 tmp0, tmp1, diff; + WebRtc_Word32 i; + + len >>= 1; + + // lower allpass filter (operates on even input samples) + for (i = 0; i < len; i++) + { + tmp0 = in[i << 1]; + diff = tmp0 - state[1]; + // scale down and round + diff = (diff + (1 << 13)) >> 14; + tmp1 = state[0] + diff * kResampleAllpass[1][0]; + state[0] = tmp0; + diff = tmp1 - state[2]; + // scale down and truncate + diff = diff >> 14; + if (diff < 0) + diff += 1; + tmp0 = state[1] + diff * kResampleAllpass[1][1]; + state[1] = tmp1; + diff = tmp0 - state[3]; + // scale down and truncate + diff = diff >> 14; + if (diff < 0) + diff += 1; + state[3] = state[2] + diff * kResampleAllpass[1][2]; + state[2] = tmp0; + + // divide by two and store temporarily + in[i << 1] = (state[3] >> 1); + } + + in++; + + // upper allpass filter (operates on odd input samples) + for (i = 0; i < len; i++) + { + tmp0 = in[i << 1]; + diff = tmp0 - state[5]; + // scale down and round + diff = (diff + (1 << 13)) >> 14; + tmp1 = state[4] + diff * kResampleAllpass[0][0]; + state[4] = tmp0; + diff = tmp1 - state[6]; + // scale down and round + diff = diff >> 14; + if (diff < 0) + diff += 1; + tmp0 = state[5] + diff * kResampleAllpass[0][1]; + state[5] = tmp1; + diff = tmp0 - state[7]; + // scale down and truncate + diff = diff >> 14; + if (diff < 0) + diff += 1; + state[7] = state[6] + diff * kResampleAllpass[0][2]; + state[6] = tmp0; + + // divide by two and store temporarily + in[i << 1] = (state[7] >> 1); + } + + in--; + + // combine allpass outputs + for (i = 0; i < len; i += 2) + { + // divide by two, add both allpass outputs and round + tmp0 = (in[i << 1] + in[(i << 1) + 1]) >> 15; + tmp1 = (in[(i << 1) + 2] + in[(i << 1) + 3]) >> 15; + if (tmp0 > (WebRtc_Word32)0x00007FFF) + tmp0 = 0x00007FFF; + if (tmp0 < (WebRtc_Word32)0xFFFF8000) + tmp0 = 0xFFFF8000; + out[i] = (WebRtc_Word16)tmp0; + if (tmp1 > (WebRtc_Word32)0x00007FFF) + tmp1 = 0x00007FFF; + if (tmp1 < (WebRtc_Word32)0xFFFF8000) + tmp1 = 0xFFFF8000; + out[i + 1] = (WebRtc_Word16)tmp1; + } +} + +// +// decimator +// input: WebRtc_Word16 +// output: WebRtc_Word32 (shifted 15 positions to the left, + offset 16384) (of length len/2) +// state: filter state array; length = 8 + +void WebRtcSpl_DownBy2ShortToInt(const WebRtc_Word16 *in, + WebRtc_Word32 len, + WebRtc_Word32 *out, + WebRtc_Word32 *state) +{ + WebRtc_Word32 tmp0, tmp1, diff; + WebRtc_Word32 i; + + len >>= 1; + + // lower allpass filter (operates on even input samples) + for (i = 0; i < len; i++) + { + tmp0 = ((WebRtc_Word32)in[i << 1] << 15) + (1 << 14); + diff = tmp0 - state[1]; + // scale down and round + diff = (diff + (1 << 13)) >> 14; + tmp1 = state[0] + diff * kResampleAllpass[1][0]; + state[0] = tmp0; + diff = tmp1 - state[2]; + // scale down and truncate + diff = diff >> 14; + if (diff < 0) + diff += 1; + tmp0 = state[1] + diff * kResampleAllpass[1][1]; + state[1] = tmp1; + diff = tmp0 - state[3]; + // scale down and truncate + diff = diff >> 14; + if (diff < 0) + diff += 1; + state[3] = state[2] + diff * kResampleAllpass[1][2]; + state[2] = tmp0; + + // divide by two and store temporarily + out[i] = (state[3] >> 1); + } + + in++; + + // upper allpass filter (operates on odd input samples) + for (i = 0; i < len; i++) + { + tmp0 = ((WebRtc_Word32)in[i << 1] << 15) + (1 << 14); + diff = tmp0 - state[5]; + // scale down and round + diff = (diff + (1 << 13)) >> 14; + tmp1 = state[4] + diff * kResampleAllpass[0][0]; + state[4] = tmp0; + diff = tmp1 - state[6]; + // scale down and round + diff = diff >> 14; + if (diff < 0) + diff += 1; + tmp0 = state[5] + diff * kResampleAllpass[0][1]; + state[5] = tmp1; + diff = tmp0 - state[7]; + // scale down and truncate + diff = diff >> 14; + if (diff < 0) + diff += 1; + state[7] = state[6] + diff * kResampleAllpass[0][2]; + state[6] = tmp0; + + // divide by two and store temporarily + out[i] += (state[7] >> 1); + } + + in--; +} + +// +// interpolator +// input: WebRtc_Word16 +// output: WebRtc_Word32 (normalized, not saturated) (of length len*2) +// state: filter state array; length = 8 +void WebRtcSpl_UpBy2ShortToInt(const WebRtc_Word16 *in, WebRtc_Word32 len, WebRtc_Word32 *out, + WebRtc_Word32 *state) +{ + WebRtc_Word32 tmp0, tmp1, diff; + WebRtc_Word32 i; + + // upper allpass filter (generates odd output samples) + for (i = 0; i < len; i++) + { + tmp0 = ((WebRtc_Word32)in[i] << 15) + (1 << 14); + diff = tmp0 - state[5]; + // scale down and round + diff = (diff + (1 << 13)) >> 14; + tmp1 = state[4] + diff * kResampleAllpass[0][0]; + state[4] = tmp0; + diff = tmp1 - state[6]; + // scale down and truncate + diff = diff >> 14; + if (diff < 0) + diff += 1; + tmp0 = state[5] + diff * kResampleAllpass[0][1]; + state[5] = tmp1; + diff = tmp0 - state[7]; + // scale down and truncate + diff = diff >> 14; + if (diff < 0) + diff += 1; + state[7] = state[6] + diff * kResampleAllpass[0][2]; + state[6] = tmp0; + + // scale down, round and store + out[i << 1] = state[7] >> 15; + } + + out++; + + // lower allpass filter (generates even output samples) + for (i = 0; i < len; i++) + { + tmp0 = ((WebRtc_Word32)in[i] << 15) + (1 << 14); + diff = tmp0 - state[1]; + // scale down and round + diff = (diff + (1 << 13)) >> 14; + tmp1 = state[0] + diff * kResampleAllpass[1][0]; + state[0] = tmp0; + diff = tmp1 - state[2]; + // scale down and truncate + diff = diff >> 14; + if (diff < 0) + diff += 1; + tmp0 = state[1] + diff * kResampleAllpass[1][1]; + state[1] = tmp1; + diff = tmp0 - state[3]; + // scale down and truncate + diff = diff >> 14; + if (diff < 0) + diff += 1; + state[3] = state[2] + diff * kResampleAllpass[1][2]; + state[2] = tmp0; + + // scale down, round and store + out[i << 1] = state[3] >> 15; + } +} + +// +// interpolator +// input: WebRtc_Word32 (shifted 15 positions to the left, + offset 16384) +// output: WebRtc_Word32 (shifted 15 positions to the left, + offset 16384) (of length len*2) +// state: filter state array; length = 8 +void WebRtcSpl_UpBy2IntToInt(const WebRtc_Word32 *in, WebRtc_Word32 len, WebRtc_Word32 *out, + WebRtc_Word32 *state) +{ + WebRtc_Word32 tmp0, tmp1, diff; + WebRtc_Word32 i; + + // upper allpass filter (generates odd output samples) + for (i = 0; i < len; i++) + { + tmp0 = in[i]; + diff = tmp0 - state[5]; + // scale down and round + diff = (diff + (1 << 13)) >> 14; + tmp1 = state[4] + diff * kResampleAllpass[0][0]; + state[4] = tmp0; + diff = tmp1 - state[6]; + // scale down and truncate + diff = diff >> 14; + if (diff < 0) + diff += 1; + tmp0 = state[5] + diff * kResampleAllpass[0][1]; + state[5] = tmp1; + diff = tmp0 - state[7]; + // scale down and truncate + diff = diff >> 14; + if (diff < 0) + diff += 1; + state[7] = state[6] + diff * kResampleAllpass[0][2]; + state[6] = tmp0; + + // scale down, round and store + out[i << 1] = state[7]; + } + + out++; + + // lower allpass filter (generates even output samples) + for (i = 0; i < len; i++) + { + tmp0 = in[i]; + diff = tmp0 - state[1]; + // scale down and round + diff = (diff + (1 << 13)) >> 14; + tmp1 = state[0] + diff * kResampleAllpass[1][0]; + state[0] = tmp0; + diff = tmp1 - state[2]; + // scale down and truncate + diff = diff >> 14; + if (diff < 0) + diff += 1; + tmp0 = state[1] + diff * kResampleAllpass[1][1]; + state[1] = tmp1; + diff = tmp0 - state[3]; + // scale down and truncate + diff = diff >> 14; + if (diff < 0) + diff += 1; + state[3] = state[2] + diff * kResampleAllpass[1][2]; + state[2] = tmp0; + + // scale down, round and store + out[i << 1] = state[3]; + } +} + +// +// interpolator +// input: WebRtc_Word32 (shifted 15 positions to the left, + offset 16384) +// output: WebRtc_Word16 (saturated) (of length len*2) +// state: filter state array; length = 8 +void WebRtcSpl_UpBy2IntToShort(const WebRtc_Word32 *in, WebRtc_Word32 len, WebRtc_Word16 *out, + WebRtc_Word32 *state) +{ + WebRtc_Word32 tmp0, tmp1, diff; + WebRtc_Word32 i; + + // upper allpass filter (generates odd output samples) + for (i = 0; i < len; i++) + { + tmp0 = in[i]; + diff = tmp0 - state[5]; + // scale down and round + diff = (diff + (1 << 13)) >> 14; + tmp1 = state[4] + diff * kResampleAllpass[0][0]; + state[4] = tmp0; + diff = tmp1 - state[6]; + // scale down and round + diff = diff >> 14; + if (diff < 0) + diff += 1; + tmp0 = state[5] + diff * kResampleAllpass[0][1]; + state[5] = tmp1; + diff = tmp0 - state[7]; + // scale down and truncate + diff = diff >> 14; + if (diff < 0) + diff += 1; + state[7] = state[6] + diff * kResampleAllpass[0][2]; + state[6] = tmp0; + + // scale down, saturate and store + tmp1 = state[7] >> 15; + if (tmp1 > (WebRtc_Word32)0x00007FFF) + tmp1 = 0x00007FFF; + if (tmp1 < (WebRtc_Word32)0xFFFF8000) + tmp1 = 0xFFFF8000; + out[i << 1] = (WebRtc_Word16)tmp1; + } + + out++; + + // lower allpass filter (generates even output samples) + for (i = 0; i < len; i++) + { + tmp0 = in[i]; + diff = tmp0 - state[1]; + // scale down and round + diff = (diff + (1 << 13)) >> 14; + tmp1 = state[0] + diff * kResampleAllpass[1][0]; + state[0] = tmp0; + diff = tmp1 - state[2]; + // scale down and truncate + diff = diff >> 14; + if (diff < 0) + diff += 1; + tmp0 = state[1] + diff * kResampleAllpass[1][1]; + state[1] = tmp1; + diff = tmp0 - state[3]; + // scale down and truncate + diff = diff >> 14; + if (diff < 0) + diff += 1; + state[3] = state[2] + diff * kResampleAllpass[1][2]; + state[2] = tmp0; + + // scale down, saturate and store + tmp1 = state[3] >> 15; + if (tmp1 > (WebRtc_Word32)0x00007FFF) + tmp1 = 0x00007FFF; + if (tmp1 < (WebRtc_Word32)0xFFFF8000) + tmp1 = 0xFFFF8000; + out[i << 1] = (WebRtc_Word16)tmp1; + } +} + +// lowpass filter +// input: WebRtc_Word16 +// output: WebRtc_Word32 (normalized, not saturated) +// state: filter state array; length = 8 +void WebRtcSpl_LPBy2ShortToInt(const WebRtc_Word16* in, WebRtc_Word32 len, WebRtc_Word32* out, + WebRtc_Word32* state) +{ + WebRtc_Word32 tmp0, tmp1, diff; + WebRtc_Word32 i; + + len >>= 1; + + // lower allpass filter: odd input -> even output samples + in++; + // initial state of polyphase delay element + tmp0 = state[12]; + for (i = 0; i < len; i++) + { + diff = tmp0 - state[1]; + // scale down and round + diff = (diff + (1 << 13)) >> 14; + tmp1 = state[0] + diff * kResampleAllpass[1][0]; + state[0] = tmp0; + diff = tmp1 - state[2]; + // scale down and truncate + diff = diff >> 14; + if (diff < 0) + diff += 1; + tmp0 = state[1] + diff * kResampleAllpass[1][1]; + state[1] = tmp1; + diff = tmp0 - state[3]; + // scale down and truncate + diff = diff >> 14; + if (diff < 0) + diff += 1; + state[3] = state[2] + diff * kResampleAllpass[1][2]; + state[2] = tmp0; + + // scale down, round and store + out[i << 1] = state[3] >> 1; + tmp0 = ((WebRtc_Word32)in[i << 1] << 15) + (1 << 14); + } + in--; + + // upper allpass filter: even input -> even output samples + for (i = 0; i < len; i++) + { + tmp0 = ((WebRtc_Word32)in[i << 1] << 15) + (1 << 14); + diff = tmp0 - state[5]; + // scale down and round + diff = (diff + (1 << 13)) >> 14; + tmp1 = state[4] + diff * kResampleAllpass[0][0]; + state[4] = tmp0; + diff = tmp1 - state[6]; + // scale down and round + diff = diff >> 14; + if (diff < 0) + diff += 1; + tmp0 = state[5] + diff * kResampleAllpass[0][1]; + state[5] = tmp1; + diff = tmp0 - state[7]; + // scale down and truncate + diff = diff >> 14; + if (diff < 0) + diff += 1; + state[7] = state[6] + diff * kResampleAllpass[0][2]; + state[6] = tmp0; + + // average the two allpass outputs, scale down and store + out[i << 1] = (out[i << 1] + (state[7] >> 1)) >> 15; + } + + // switch to odd output samples + out++; + + // lower allpass filter: even input -> odd output samples + for (i = 0; i < len; i++) + { + tmp0 = ((WebRtc_Word32)in[i << 1] << 15) + (1 << 14); + diff = tmp0 - state[9]; + // scale down and round + diff = (diff + (1 << 13)) >> 14; + tmp1 = state[8] + diff * kResampleAllpass[1][0]; + state[8] = tmp0; + diff = tmp1 - state[10]; + // scale down and truncate + diff = diff >> 14; + if (diff < 0) + diff += 1; + tmp0 = state[9] + diff * kResampleAllpass[1][1]; + state[9] = tmp1; + diff = tmp0 - state[11]; + // scale down and truncate + diff = diff >> 14; + if (diff < 0) + diff += 1; + state[11] = state[10] + diff * kResampleAllpass[1][2]; + state[10] = tmp0; + + // scale down, round and store + out[i << 1] = state[11] >> 1; + } + + // upper allpass filter: odd input -> odd output samples + in++; + for (i = 0; i < len; i++) + { + tmp0 = ((WebRtc_Word32)in[i << 1] << 15) + (1 << 14); + diff = tmp0 - state[13]; + // scale down and round + diff = (diff + (1 << 13)) >> 14; + tmp1 = state[12] + diff * kResampleAllpass[0][0]; + state[12] = tmp0; + diff = tmp1 - state[14]; + // scale down and round + diff = diff >> 14; + if (diff < 0) + diff += 1; + tmp0 = state[13] + diff * kResampleAllpass[0][1]; + state[13] = tmp1; + diff = tmp0 - state[15]; + // scale down and truncate + diff = diff >> 14; + if (diff < 0) + diff += 1; + state[15] = state[14] + diff * kResampleAllpass[0][2]; + state[14] = tmp0; + + // average the two allpass outputs, scale down and store + out[i << 1] = (out[i << 1] + (state[15] >> 1)) >> 15; + } +} + +// lowpass filter +// input: WebRtc_Word32 (shifted 15 positions to the left, + offset 16384) +// output: WebRtc_Word32 (normalized, not saturated) +// state: filter state array; length = 8 +void WebRtcSpl_LPBy2IntToInt(const WebRtc_Word32* in, WebRtc_Word32 len, WebRtc_Word32* out, + WebRtc_Word32* state) +{ + WebRtc_Word32 tmp0, tmp1, diff; + WebRtc_Word32 i; + + len >>= 1; + + // lower allpass filter: odd input -> even output samples + in++; + // initial state of polyphase delay element + tmp0 = state[12]; + for (i = 0; i < len; i++) + { + diff = tmp0 - state[1]; + // scale down and round + diff = (diff + (1 << 13)) >> 14; + tmp1 = state[0] + diff * kResampleAllpass[1][0]; + state[0] = tmp0; + diff = tmp1 - state[2]; + // scale down and truncate + diff = diff >> 14; + if (diff < 0) + diff += 1; + tmp0 = state[1] + diff * kResampleAllpass[1][1]; + state[1] = tmp1; + diff = tmp0 - state[3]; + // scale down and truncate + diff = diff >> 14; + if (diff < 0) + diff += 1; + state[3] = state[2] + diff * kResampleAllpass[1][2]; + state[2] = tmp0; + + // scale down, round and store + out[i << 1] = state[3] >> 1; + tmp0 = in[i << 1]; + } + in--; + + // upper allpass filter: even input -> even output samples + for (i = 0; i < len; i++) + { + tmp0 = in[i << 1]; + diff = tmp0 - state[5]; + // scale down and round + diff = (diff + (1 << 13)) >> 14; + tmp1 = state[4] + diff * kResampleAllpass[0][0]; + state[4] = tmp0; + diff = tmp1 - state[6]; + // scale down and round + diff = diff >> 14; + if (diff < 0) + diff += 1; + tmp0 = state[5] + diff * kResampleAllpass[0][1]; + state[5] = tmp1; + diff = tmp0 - state[7]; + // scale down and truncate + diff = diff >> 14; + if (diff < 0) + diff += 1; + state[7] = state[6] + diff * kResampleAllpass[0][2]; + state[6] = tmp0; + + // average the two allpass outputs, scale down and store + out[i << 1] = (out[i << 1] + (state[7] >> 1)) >> 15; + } + + // switch to odd output samples + out++; + + // lower allpass filter: even input -> odd output samples + for (i = 0; i < len; i++) + { + tmp0 = in[i << 1]; + diff = tmp0 - state[9]; + // scale down and round + diff = (diff + (1 << 13)) >> 14; + tmp1 = state[8] + diff * kResampleAllpass[1][0]; + state[8] = tmp0; + diff = tmp1 - state[10]; + // scale down and truncate + diff = diff >> 14; + if (diff < 0) + diff += 1; + tmp0 = state[9] + diff * kResampleAllpass[1][1]; + state[9] = tmp1; + diff = tmp0 - state[11]; + // scale down and truncate + diff = diff >> 14; + if (diff < 0) + diff += 1; + state[11] = state[10] + diff * kResampleAllpass[1][2]; + state[10] = tmp0; + + // scale down, round and store + out[i << 1] = state[11] >> 1; + } + + // upper allpass filter: odd input -> odd output samples + in++; + for (i = 0; i < len; i++) + { + tmp0 = in[i << 1]; + diff = tmp0 - state[13]; + // scale down and round + diff = (diff + (1 << 13)) >> 14; + tmp1 = state[12] + diff * kResampleAllpass[0][0]; + state[12] = tmp0; + diff = tmp1 - state[14]; + // scale down and round + diff = diff >> 14; + if (diff < 0) + diff += 1; + tmp0 = state[13] + diff * kResampleAllpass[0][1]; + state[13] = tmp1; + diff = tmp0 - state[15]; + // scale down and truncate + diff = diff >> 14; + if (diff < 0) + diff += 1; + state[15] = state[14] + diff * kResampleAllpass[0][2]; + state[14] = tmp0; + + // average the two allpass outputs, scale down and store + out[i << 1] = (out[i << 1] + (state[15] >> 1)) >> 15; + } +} diff --git a/src/common_audio/signal_processing_library/main/source/resample_by_2_internal.h b/src/common_audio/signal_processing_library/main/source/resample_by_2_internal.h new file mode 100644 index 0000000..b6ac9f0 --- /dev/null +++ b/src/common_audio/signal_processing_library/main/source/resample_by_2_internal.h @@ -0,0 +1,47 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + + +/* + * This header file contains some internal resampling functions. + * + */ + +#ifndef WEBRTC_SPL_RESAMPLE_BY_2_INTERNAL_H_ +#define WEBRTC_SPL_RESAMPLE_BY_2_INTERNAL_H_ + +#include "typedefs.h" + +/******************************************************************* + * resample_by_2_fast.c + * Functions for internal use in the other resample functions + ******************************************************************/ +void WebRtcSpl_DownBy2IntToShort(WebRtc_Word32 *in, WebRtc_Word32 len, WebRtc_Word16 *out, + WebRtc_Word32 *state); + +void WebRtcSpl_DownBy2ShortToInt(const WebRtc_Word16 *in, WebRtc_Word32 len, + WebRtc_Word32 *out, WebRtc_Word32 *state); + +void WebRtcSpl_UpBy2ShortToInt(const WebRtc_Word16 *in, WebRtc_Word32 len, + WebRtc_Word32 *out, WebRtc_Word32 *state); + +void WebRtcSpl_UpBy2IntToInt(const WebRtc_Word32 *in, WebRtc_Word32 len, WebRtc_Word32 *out, + WebRtc_Word32 *state); + +void WebRtcSpl_UpBy2IntToShort(const WebRtc_Word32 *in, WebRtc_Word32 len, + WebRtc_Word16 *out, WebRtc_Word32 *state); + +void WebRtcSpl_LPBy2ShortToInt(const WebRtc_Word16* in, WebRtc_Word32 len, + WebRtc_Word32* out, WebRtc_Word32* state); + +void WebRtcSpl_LPBy2IntToInt(const WebRtc_Word32* in, WebRtc_Word32 len, WebRtc_Word32* out, + WebRtc_Word32* state); + +#endif // WEBRTC_SPL_RESAMPLE_BY_2_INTERNAL_H_ diff --git a/src/common_audio/signal_processing_library/main/source/resample_fractional.c b/src/common_audio/signal_processing_library/main/source/resample_fractional.c new file mode 100644 index 0000000..51003d4 --- /dev/null +++ b/src/common_audio/signal_processing_library/main/source/resample_fractional.c @@ -0,0 +1,242 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + + +/* + * This file contains the resampling functions between 48, 44, 32 and 24 kHz. + * The description headers can be found in signal_processing_library.h + * + */ + +#include "signal_processing_library.h" + +// interpolation coefficients +static const WebRtc_Word16 kCoefficients48To32[2][8] = { + {778, -2050, 1087, 23285, 12903, -3783, 441, 222}, + {222, 441, -3783, 12903, 23285, 1087, -2050, 778} +}; + +static const WebRtc_Word16 kCoefficients32To24[3][8] = { + {767, -2362, 2434, 24406, 10620, -3838, 721, 90}, + {386, -381, -2646, 19062, 19062, -2646, -381, 386}, + {90, 721, -3838, 10620, 24406, 2434, -2362, 767} +}; + +static const WebRtc_Word16 kCoefficients44To32[4][9] = { + {117, -669, 2245, -6183, 26267, 13529, -3245, 845, -138}, + {-101, 612, -2283, 8532, 29790, -5138, 1789, -524, 91}, + {50, -292, 1016, -3064, 32010, 3933, -1147, 315, -53}, + {-156, 974, -3863, 18603, 21691, -6246, 2353, -712, 126} +}; + +// Resampling ratio: 2/3 +// input: WebRtc_Word32 (normalized, not saturated) :: size 3 * K +// output: WebRtc_Word32 (shifted 15 positions to the left, + offset 16384) :: size 2 * K +// K: number of blocks + +void WebRtcSpl_Resample48khzTo32khz(const WebRtc_Word32 *In, WebRtc_Word32 *Out, + const WebRtc_Word32 K) +{ + ///////////////////////////////////////////////////////////// + // Filter operation: + // + // Perform resampling (3 input samples -> 2 output samples); + // process in sub blocks of size 3 samples. + WebRtc_Word32 tmp; + WebRtc_Word32 m; + + for (m = 0; m < K; m++) + { + tmp = 1 << 14; + tmp += kCoefficients48To32[0][0] * In[0]; + tmp += kCoefficients48To32[0][1] * In[1]; + tmp += kCoefficients48To32[0][2] * In[2]; + tmp += kCoefficients48To32[0][3] * In[3]; + tmp += kCoefficients48To32[0][4] * In[4]; + tmp += kCoefficients48To32[0][5] * In[5]; + tmp += kCoefficients48To32[0][6] * In[6]; + tmp += kCoefficients48To32[0][7] * In[7]; + Out[0] = tmp; + + tmp = 1 << 14; + tmp += kCoefficients48To32[1][0] * In[1]; + tmp += kCoefficients48To32[1][1] * In[2]; + tmp += kCoefficients48To32[1][2] * In[3]; + tmp += kCoefficients48To32[1][3] * In[4]; + tmp += kCoefficients48To32[1][4] * In[5]; + tmp += kCoefficients48To32[1][5] * In[6]; + tmp += kCoefficients48To32[1][6] * In[7]; + tmp += kCoefficients48To32[1][7] * In[8]; + Out[1] = tmp; + + // update pointers + In += 3; + Out += 2; + } +} + +// Resampling ratio: 3/4 +// input: WebRtc_Word32 (normalized, not saturated) :: size 4 * K +// output: WebRtc_Word32 (shifted 15 positions to the left, + offset 16384) :: size 3 * K +// K: number of blocks + +void WebRtcSpl_Resample32khzTo24khz(const WebRtc_Word32 *In, WebRtc_Word32 *Out, + const WebRtc_Word32 K) +{ + ///////////////////////////////////////////////////////////// + // Filter operation: + // + // Perform resampling (4 input samples -> 3 output samples); + // process in sub blocks of size 4 samples. + WebRtc_Word32 m; + WebRtc_Word32 tmp; + + for (m = 0; m < K; m++) + { + tmp = 1 << 14; + tmp += kCoefficients32To24[0][0] * In[0]; + tmp += kCoefficients32To24[0][1] * In[1]; + tmp += kCoefficients32To24[0][2] * In[2]; + tmp += kCoefficients32To24[0][3] * In[3]; + tmp += kCoefficients32To24[0][4] * In[4]; + tmp += kCoefficients32To24[0][5] * In[5]; + tmp += kCoefficients32To24[0][6] * In[6]; + tmp += kCoefficients32To24[0][7] * In[7]; + Out[0] = tmp; + + tmp = 1 << 14; + tmp += kCoefficients32To24[1][0] * In[1]; + tmp += kCoefficients32To24[1][1] * In[2]; + tmp += kCoefficients32To24[1][2] * In[3]; + tmp += kCoefficients32To24[1][3] * In[4]; + tmp += kCoefficients32To24[1][4] * In[5]; + tmp += kCoefficients32To24[1][5] * In[6]; + tmp += kCoefficients32To24[1][6] * In[7]; + tmp += kCoefficients32To24[1][7] * In[8]; + Out[1] = tmp; + + tmp = 1 << 14; + tmp += kCoefficients32To24[2][0] * In[2]; + tmp += kCoefficients32To24[2][1] * In[3]; + tmp += kCoefficients32To24[2][2] * In[4]; + tmp += kCoefficients32To24[2][3] * In[5]; + tmp += kCoefficients32To24[2][4] * In[6]; + tmp += kCoefficients32To24[2][5] * In[7]; + tmp += kCoefficients32To24[2][6] * In[8]; + tmp += kCoefficients32To24[2][7] * In[9]; + Out[2] = tmp; + + // update pointers + In += 4; + Out += 3; + } +} + +// +// fractional resampling filters +// Fout = 11/16 * Fin +// Fout = 8/11 * Fin +// + +// compute two inner-products and store them to output array +static void WebRtcSpl_ResampDotProduct(const WebRtc_Word32 *in1, const WebRtc_Word32 *in2, + const WebRtc_Word16 *coef_ptr, WebRtc_Word32 *out1, + WebRtc_Word32 *out2) +{ + WebRtc_Word32 tmp1 = 16384; + WebRtc_Word32 tmp2 = 16384; + WebRtc_Word16 coef; + + coef = coef_ptr[0]; + tmp1 += coef * in1[0]; + tmp2 += coef * in2[-0]; + + coef = coef_ptr[1]; + tmp1 += coef * in1[1]; + tmp2 += coef * in2[-1]; + + coef = coef_ptr[2]; + tmp1 += coef * in1[2]; + tmp2 += coef * in2[-2]; + + coef = coef_ptr[3]; + tmp1 += coef * in1[3]; + tmp2 += coef * in2[-3]; + + coef = coef_ptr[4]; + tmp1 += coef * in1[4]; + tmp2 += coef * in2[-4]; + + coef = coef_ptr[5]; + tmp1 += coef * in1[5]; + tmp2 += coef * in2[-5]; + + coef = coef_ptr[6]; + tmp1 += coef * in1[6]; + tmp2 += coef * in2[-6]; + + coef = coef_ptr[7]; + tmp1 += coef * in1[7]; + tmp2 += coef * in2[-7]; + + coef = coef_ptr[8]; + *out1 = tmp1 + coef * in1[8]; + *out2 = tmp2 + coef * in2[-8]; +} + +// Resampling ratio: 8/11 +// input: WebRtc_Word32 (normalized, not saturated) :: size 11 * K +// output: WebRtc_Word32 (shifted 15 positions to the left, + offset 16384) :: size 8 * K +// K: number of blocks + +void WebRtcSpl_Resample44khzTo32khz(const WebRtc_Word32 *In, WebRtc_Word32 *Out, + const WebRtc_Word32 K) +{ + ///////////////////////////////////////////////////////////// + // Filter operation: + // + // Perform resampling (11 input samples -> 8 output samples); + // process in sub blocks of size 11 samples. + WebRtc_Word32 tmp; + WebRtc_Word32 m; + + for (m = 0; m < K; m++) + { + tmp = 1 << 14; + + // first output sample + Out[0] = ((WebRtc_Word32)In[3] << 15) + tmp; + + // sum and accumulate filter coefficients and input samples + tmp += kCoefficients44To32[3][0] * In[5]; + tmp += kCoefficients44To32[3][1] * In[6]; + tmp += kCoefficients44To32[3][2] * In[7]; + tmp += kCoefficients44To32[3][3] * In[8]; + tmp += kCoefficients44To32[3][4] * In[9]; + tmp += kCoefficients44To32[3][5] * In[10]; + tmp += kCoefficients44To32[3][6] * In[11]; + tmp += kCoefficients44To32[3][7] * In[12]; + tmp += kCoefficients44To32[3][8] * In[13]; + Out[4] = tmp; + + // sum and accumulate filter coefficients and input samples + WebRtcSpl_ResampDotProduct(&In[0], &In[17], kCoefficients44To32[0], &Out[1], &Out[7]); + + // sum and accumulate filter coefficients and input samples + WebRtcSpl_ResampDotProduct(&In[2], &In[15], kCoefficients44To32[1], &Out[2], &Out[6]); + + // sum and accumulate filter coefficients and input samples + WebRtcSpl_ResampDotProduct(&In[3], &In[14], kCoefficients44To32[2], &Out[3], &Out[5]); + + // update pointers + In += 11; + Out += 8; + } +} diff --git a/src/common_audio/signal_processing_library/main/source/sin_table.c b/src/common_audio/signal_processing_library/main/source/sin_table.c new file mode 100644 index 0000000..ea44666 --- /dev/null +++ b/src/common_audio/signal_processing_library/main/source/sin_table.c @@ -0,0 +1,60 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + + +/* + * This file contains the 360 degree sine table. + * + */ + +#include "signal_processing_library.h" + +WebRtc_Word16 WebRtcSpl_kSinTable[] = { + 0, 142, 285, 428, 571, 713, 856, 998, 1140, + 1281, 1422, 1563, 1703, 1842, 1981, 2120, 2258, 2395, + 2531, 2667, 2801, 2935, 3068, 3200, 3331, 3462, 3591, + 3719, 3845, 3971, 4095, 4219, 4341, 4461, 4580, 4698, + 4815, 4930, 5043, 5155, 5265, 5374, 5481, 5586, 5690, + 5792, 5892, 5991, 6087, 6182, 6275, 6366, 6455, 6542, + 6627, 6710, 6791, 6870, 6947, 7021, 7094, 7164, 7233, + 7299, 7362, 7424, 7483, 7540, 7595, 7647, 7697, 7745, + 7791, 7834, 7874, 7912, 7948, 7982, 8012, 8041, 8067, + 8091, 8112, 8130, 8147, 8160, 8172, 8180, 8187, 8190, + 8191, 8190, 8187, 8180, 8172, 8160, 8147, 8130, 8112, + 8091, 8067, 8041, 8012, 7982, 7948, 7912, 7874, 7834, + 7791, 7745, 7697, 7647, 7595, 7540, 7483, 7424, 7362, + 7299, 7233, 7164, 7094, 7021, 6947, 6870, 6791, 6710, + 6627, 6542, 6455, 6366, 6275, 6182, 6087, 5991, 5892, + 5792, 5690, 5586, 5481, 5374, 5265, 5155, 5043, 4930, + 4815, 4698, 4580, 4461, 4341, 4219, 4096, 3971, 3845, + 3719, 3591, 3462, 3331, 3200, 3068, 2935, 2801, 2667, + 2531, 2395, 2258, 2120, 1981, 1842, 1703, 1563, 1422, + 1281, 1140, 998, 856, 713, 571, 428, 285, 142, + 0, -142, -285, -428, -571, -713, -856, -998, -1140, + -1281, -1422, -1563, -1703, -1842, -1981, -2120, -2258, -2395, + -2531, -2667, -2801, -2935, -3068, -3200, -3331, -3462, -3591, + -3719, -3845, -3971, -4095, -4219, -4341, -4461, -4580, -4698, + -4815, -4930, -5043, -5155, -5265, -5374, -5481, -5586, -5690, + -5792, -5892, -5991, -6087, -6182, -6275, -6366, -6455, -6542, + -6627, -6710, -6791, -6870, -6947, -7021, -7094, -7164, -7233, + -7299, -7362, -7424, -7483, -7540, -7595, -7647, -7697, -7745, + -7791, -7834, -7874, -7912, -7948, -7982, -8012, -8041, -8067, + -8091, -8112, -8130, -8147, -8160, -8172, -8180, -8187, -8190, + -8191, -8190, -8187, -8180, -8172, -8160, -8147, -8130, -8112, + -8091, -8067, -8041, -8012, -7982, -7948, -7912, -7874, -7834, + -7791, -7745, -7697, -7647, -7595, -7540, -7483, -7424, -7362, + -7299, -7233, -7164, -7094, -7021, -6947, -6870, -6791, -6710, + -6627, -6542, -6455, -6366, -6275, -6182, -6087, -5991, -5892, + -5792, -5690, -5586, -5481, -5374, -5265, -5155, -5043, -4930, + -4815, -4698, -4580, -4461, -4341, -4219, -4096, -3971, -3845, + -3719, -3591, -3462, -3331, -3200, -3068, -2935, -2801, -2667, + -2531, -2395, -2258, -2120, -1981, -1842, -1703, -1563, -1422, + -1281, -1140, -998, -856, -713, -571, -428, -285, -142 +}; diff --git a/src/common_audio/signal_processing_library/main/source/sin_table_1024.c b/src/common_audio/signal_processing_library/main/source/sin_table_1024.c new file mode 100644 index 0000000..a2007f9 --- /dev/null +++ b/src/common_audio/signal_processing_library/main/source/sin_table_1024.c @@ -0,0 +1,150 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + + +/* + * This file contains the 1024 point sine table. + * + */ + +#include "signal_processing_library.h" + +WebRtc_Word16 WebRtcSpl_kSinTable1024[] = +{ + 0, 201, 402, 603, 804, 1005, 1206, 1406, + 1607, 1808, 2009, 2209, 2410, 2610, 2811, 3011, + 3211, 3411, 3611, 3811, 4011, 4210, 4409, 4608, + 4807, 5006, 5205, 5403, 5601, 5799, 5997, 6195, + 6392, 6589, 6786, 6982, 7179, 7375, 7571, 7766, + 7961, 8156, 8351, 8545, 8739, 8932, 9126, 9319, + 9511, 9703, 9895, 10087, 10278, 10469, 10659, 10849, + 11038, 11227, 11416, 11604, 11792, 11980, 12166, 12353, + 12539, 12724, 12909, 13094, 13278, 13462, 13645, 13827, + 14009, 14191, 14372, 14552, 14732, 14911, 15090, 15268, + 15446, 15623, 15799, 15975, 16150, 16325, 16499, 16672, + 16845, 17017, 17189, 17360, 17530, 17699, 17868, 18036, + 18204, 18371, 18537, 18702, 18867, 19031, 19194, 19357, + 19519, 19680, 19840, 20000, 20159, 20317, 20474, 20631, + 20787, 20942, 21096, 21249, 21402, 21554, 21705, 21855, + 22004, 22153, 22301, 22448, 22594, 22739, 22883, 23027, + 23169, 23311, 23452, 23592, 23731, 23869, 24006, 24143, + 24278, 24413, 24546, 24679, 24811, 24942, 25072, 25201, + 25329, 25456, 25582, 25707, 25831, 25954, 26077, 26198, + 26318, 26437, 26556, 26673, 26789, 26905, 27019, 27132, + 27244, 27355, 27466, 27575, 27683, 27790, 27896, 28001, + 28105, 28208, 28309, 28410, 28510, 28608, 28706, 28802, + 28897, 28992, 29085, 29177, 29268, 29358, 29446, 29534, + 29621, 29706, 29790, 29873, 29955, 30036, 30116, 30195, + 30272, 30349, 30424, 30498, 30571, 30643, 30713, 30783, + 30851, 30918, 30984, 31049, + 31113, 31175, 31236, 31297, + 31356, 31413, 31470, 31525, 31580, 31633, 31684, 31735, + 31785, 31833, 31880, 31926, 31970, 32014, 32056, 32097, + 32137, 32176, 32213, 32249, 32284, 32318, 32350, 32382, + 32412, 32441, 32468, 32495, 32520, 32544, 32567, 32588, + 32609, 32628, 32646, 32662, 32678, 32692, 32705, 32717, + 32727, 32736, 32744, 32751, 32757, 32761, 32764, 32766, + 32767, 32766, 32764, 32761, 32757, 32751, 32744, 32736, + 32727, 32717, 32705, 32692, 32678, 32662, 32646, 32628, + 32609, 32588, 32567, 32544, 32520, 32495, 32468, 32441, + 32412, 32382, 32350, 32318, 32284, 32249, 32213, 32176, + 32137, 32097, 32056, 32014, 31970, 31926, 31880, 31833, + 31785, 31735, 31684, 31633, 31580, 31525, 31470, 31413, + 31356, 31297, 31236, 31175, 31113, 31049, 30984, 30918, + 30851, 30783, 30713, 30643, 30571, 30498, 30424, 30349, + 30272, 30195, 30116, 30036, 29955, 29873, 29790, 29706, + 29621, 29534, 29446, 29358, 29268, 29177, 29085, 28992, + 28897, 28802, 28706, 28608, 28510, 28410, 28309, 28208, + 28105, 28001, 27896, 27790, 27683, 27575, 27466, 27355, + 27244, 27132, 27019, 26905, 26789, 26673, 26556, 26437, + 26318, 26198, 26077, 25954, 25831, 25707, 25582, 25456, + 25329, 25201, 25072, 24942, 24811, 24679, 24546, 24413, + 24278, 24143, 24006, 23869, 23731, 23592, 23452, 23311, + 23169, 23027, 22883, 22739, 22594, 22448, 22301, 22153, + 22004, 21855, 21705, 21554, 21402, 21249, 21096, 20942, + 20787, 20631, 20474, 20317, 20159, 20000, 19840, 19680, + 19519, 19357, 19194, 19031, 18867, 18702, 18537, 18371, + 18204, 18036, 17868, 17699, 17530, 17360, 17189, 17017, + 16845, 16672, 16499, 16325, 16150, 15975, 15799, 15623, + 15446, 15268, 15090, 14911, 14732, 14552, 14372, 14191, + 14009, 13827, 13645, 13462, 13278, 13094, 12909, 12724, + 12539, 12353, 12166, 11980, 11792, 11604, 11416, 11227, + 11038, 10849, 10659, 10469, 10278, 10087, 9895, 9703, + 9511, 9319, 9126, 8932, 8739, 8545, 8351, 8156, + 7961, 7766, 7571, 7375, 7179, 6982, 6786, 6589, + 6392, 6195, 5997, 5799, 5601, 5403, 5205, 5006, + 4807, 4608, 4409, 4210, 4011, 3811, 3611, 3411, + 3211, 3011, 2811, 2610, 2410, 2209, 2009, 1808, + 1607, 1406, 1206, 1005, 804, 603, 402, 201, + 0, -201, -402, -603, -804, -1005, -1206, -1406, + -1607, -1808, -2009, -2209, -2410, -2610, -2811, -3011, + -3211, -3411, -3611, -3811, -4011, -4210, -4409, -4608, + -4807, -5006, -5205, -5403, -5601, -5799, -5997, -6195, + -6392, -6589, -6786, -6982, -7179, -7375, -7571, -7766, + -7961, -8156, -8351, -8545, -8739, -8932, -9126, -9319, + -9511, -9703, -9895, -10087, -10278, -10469, -10659, -10849, + -11038, -11227, -11416, -11604, -11792, -11980, -12166, -12353, + -12539, -12724, -12909, -13094, -13278, -13462, -13645, -13827, + -14009, -14191, -14372, -14552, -14732, -14911, -15090, -15268, + -15446, -15623, -15799, -15975, -16150, -16325, -16499, -16672, + -16845, -17017, -17189, -17360, -17530, -17699, -17868, -18036, + -18204, -18371, -18537, -18702, -18867, -19031, -19194, -19357, + -19519, -19680, -19840, -20000, -20159, -20317, -20474, -20631, + -20787, -20942, -21096, -21249, -21402, -21554, -21705, -21855, + -22004, -22153, -22301, -22448, -22594, -22739, -22883, -23027, + -23169, -23311, -23452, -23592, -23731, -23869, -24006, -24143, + -24278, -24413, -24546, -24679, -24811, -24942, -25072, -25201, + -25329, -25456, -25582, -25707, -25831, -25954, -26077, -26198, + -26318, -26437, -26556, -26673, -26789, -26905, -27019, -27132, + -27244, -27355, -27466, -27575, -27683, -27790, -27896, -28001, + -28105, -28208, -28309, -28410, -28510, -28608, -28706, -28802, + -28897, -28992, -29085, -29177, -29268, -29358, -29446, -29534, + -29621, -29706, -29790, -29873, -29955, -30036, -30116, -30195, + -30272, -30349, -30424, -30498, -30571, -30643, -30713, -30783, + -30851, -30918, -30984, -31049, -31113, -31175, -31236, -31297, + -31356, -31413, -31470, -31525, -31580, -31633, -31684, -31735, + -31785, -31833, -31880, -31926, -31970, -32014, -32056, -32097, + -32137, -32176, -32213, -32249, -32284, -32318, -32350, -32382, + -32412, -32441, -32468, -32495, -32520, -32544, -32567, -32588, + -32609, -32628, -32646, -32662, -32678, -32692, -32705, -32717, + -32727, -32736, -32744, -32751, -32757, -32761, -32764, -32766, + -32767, -32766, -32764, -32761, -32757, -32751, -32744, -32736, + -32727, -32717, -32705, -32692, -32678, -32662, -32646, -32628, + -32609, -32588, -32567, -32544, -32520, -32495, -32468, -32441, + -32412, -32382, -32350, -32318, -32284, -32249, -32213, -32176, + -32137, -32097, -32056, -32014, -31970, -31926, -31880, -31833, + -31785, -31735, -31684, -31633, -31580, -31525, -31470, -31413, + -31356, -31297, -31236, -31175, -31113, -31049, -30984, -30918, + -30851, -30783, -30713, -30643, -30571, -30498, -30424, -30349, + -30272, -30195, -30116, -30036, -29955, -29873, -29790, -29706, + -29621, -29534, -29446, -29358, -29268, -29177, -29085, -28992, + -28897, -28802, -28706, -28608, -28510, -28410, -28309, -28208, + -28105, -28001, -27896, -27790, -27683, -27575, -27466, -27355, + -27244, -27132, -27019, -26905, -26789, -26673, -26556, -26437, + -26318, -26198, -26077, -25954, -25831, -25707, -25582, -25456, + -25329, -25201, -25072, -24942, -24811, -24679, -24546, -24413, + -24278, -24143, -24006, -23869, -23731, -23592, -23452, -23311, + -23169, -23027, -22883, -22739, -22594, -22448, -22301, -22153, + -22004, -21855, -21705, -21554, -21402, -21249, -21096, -20942, + -20787, -20631, -20474, -20317, -20159, -20000, -19840, -19680, + -19519, -19357, -19194, -19031, -18867, -18702, -18537, -18371, + -18204, -18036, -17868, -17699, -17530, -17360, -17189, -17017, + -16845, -16672, -16499, -16325, -16150, -15975, -15799, -15623, + -15446, -15268, -15090, -14911, -14732, -14552, -14372, -14191, + -14009, -13827, -13645, -13462, -13278, -13094, -12909, -12724, + -12539, -12353, -12166, -11980, -11792, -11604, -11416, -11227, + -11038, -10849, -10659, -10469, -10278, -10087, -9895, -9703, + -9511, -9319, -9126, -8932, -8739, -8545, -8351, -8156, + -7961, -7766, -7571, -7375, -7179, -6982, -6786, -6589, + -6392, -6195, -5997, -5799, -5601, -5403, -5205, -5006, + -4807, -4608, -4409, -4210, -4011, -3811, -3611, -3411, + -3211, -3011, -2811, -2610, -2410, -2209, -2009, -1808, + -1607, -1406, -1206, -1005, -804, -603, -402, -201, +}; diff --git a/src/common_audio/signal_processing_library/main/source/spl.gypi b/src/common_audio/signal_processing_library/main/source/spl.gypi new file mode 100644 index 0000000..eea6142 --- /dev/null +++ b/src/common_audio/signal_processing_library/main/source/spl.gypi @@ -0,0 +1,73 @@ +# Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. +# +# Use of this source code is governed by a BSD-style license +# that can be found in the LICENSE file in the root of the source +# tree. An additional intellectual property rights grant can be found +# in the file PATENTS. All contributing project authors may +# be found in the AUTHORS file in the root of the source tree. + +{ + 'targets': [ + { + 'target_name': 'spl', + 'type': '<(library)', + 'include_dirs': [ + '../interface', + ], + 'direct_dependent_settings': { + 'include_dirs': [ + '../interface', + ], + }, + 'sources': [ + '../interface/signal_processing_library.h', + '../interface/spl_inl.h', + 'auto_corr_to_refl_coef.c', + 'auto_correlation.c', + 'complex_fft.c', + 'complex_ifft.c', + 'complex_bit_reverse.c', + 'copy_set_operations.c', + 'cos_table.c', + 'cross_correlation.c', + 'division_operations.c', + 'dot_product_with_scale.c', + 'downsample_fast.c', + 'energy.c', + 'filter_ar.c', + 'filter_ar_fast_q12.c', + 'filter_ma_fast_q12.c', + 'get_hanning_window.c', + 'get_scaling_square.c', + 'hanning_table.c', + 'ilbc_specific_functions.c', + 'levinson_durbin.c', + 'lpc_to_refl_coef.c', + 'min_max_operations.c', + 'randn_table.c', + 'randomization_functions.c', + 'refl_coef_to_lpc.c', + 'resample.c', + 'resample_48khz.c', + 'resample_by_2.c', + 'resample_by_2_internal.c', + 'resample_by_2_internal.h', + 'resample_fractional.c', + 'sin_table.c', + 'sin_table_1024.c', + 'spl_sqrt.c', + 'spl_sqrt_floor.c', + 'spl_version.c', + 'splitting_filter.c', + 'sqrt_of_one_minus_x_squared.c', + 'vector_scaling_operations.c', + ], + }, + ], +} + +# Local Variables: +# tab-width:2 +# indent-tabs-mode:nil +# End: +# vim: set expandtab tabstop=2 shiftwidth=2: diff --git a/src/common_audio/signal_processing_library/main/source/spl_sqrt.c b/src/common_audio/signal_processing_library/main/source/spl_sqrt.c new file mode 100644 index 0000000..cfe2cd3 --- /dev/null +++ b/src/common_audio/signal_processing_library/main/source/spl_sqrt.c @@ -0,0 +1,184 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + + +/* + * This file contains the function WebRtcSpl_Sqrt(). + * The description header can be found in signal_processing_library.h + * + */ + +#include "signal_processing_library.h" + +WebRtc_Word32 WebRtcSpl_SqrtLocal(WebRtc_Word32 in); + +WebRtc_Word32 WebRtcSpl_SqrtLocal(WebRtc_Word32 in) +{ + + WebRtc_Word16 x_half, t16; + WebRtc_Word32 A, B, x2; + + /* The following block performs: + y=in/2 + x=y-2^30 + x_half=x/2^31 + t = 1 + (x_half) - 0.5*((x_half)^2) + 0.5*((x_half)^3) - 0.625*((x_half)^4) + + 0.875*((x_half)^5) + */ + + B = in; + + B = WEBRTC_SPL_RSHIFT_W32(B, 1); // B = in/2 + B = B - ((WebRtc_Word32)0x40000000); // B = in/2 - 1/2 + x_half = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32(B, 16);// x_half = x/2 = (in-1)/2 + B = B + ((WebRtc_Word32)0x40000000); // B = 1 + x/2 + B = B + ((WebRtc_Word32)0x40000000); // Add 0.5 twice (since 1.0 does not exist in Q31) + + x2 = ((WebRtc_Word32)x_half) * ((WebRtc_Word32)x_half) * 2; // A = (x/2)^2 + A = -x2; // A = -(x/2)^2 + B = B + (A >> 1); // B = 1 + x/2 - 0.5*(x/2)^2 + + A = WEBRTC_SPL_RSHIFT_W32(A, 16); + A = A * A * 2; // A = (x/2)^4 + t16 = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32(A, 16); + B = B + WEBRTC_SPL_MUL_16_16(-20480, t16) * 2; // B = B - 0.625*A + // After this, B = 1 + x/2 - 0.5*(x/2)^2 - 0.625*(x/2)^4 + + t16 = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32(A, 16); + A = WEBRTC_SPL_MUL_16_16(x_half, t16) * 2; // A = (x/2)^5 + t16 = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32(A, 16); + B = B + WEBRTC_SPL_MUL_16_16(28672, t16) * 2; // B = B + 0.875*A + // After this, B = 1 + x/2 - 0.5*(x/2)^2 - 0.625*(x/2)^4 + 0.875*(x/2)^5 + + t16 = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32(x2, 16); + A = WEBRTC_SPL_MUL_16_16(x_half, t16) * 2; // A = x/2^3 + + B = B + (A >> 1); // B = B + 0.5*A + // After this, B = 1 + x/2 - 0.5*(x/2)^2 + 0.5*(x/2)^3 - 0.625*(x/2)^4 + 0.875*(x/2)^5 + + B = B + ((WebRtc_Word32)32768); // Round off bit + + return B; +} + +WebRtc_Word32 WebRtcSpl_Sqrt(WebRtc_Word32 value) +{ + /* + Algorithm: + + Six term Taylor Series is used here to compute the square root of a number + y^0.5 = (1+x)^0.5 where x = y-1 + = 1+(x/2)-0.5*((x/2)^2+0.5*((x/2)^3-0.625*((x/2)^4+0.875*((x/2)^5) + 0.5 <= x < 1 + + Example of how the algorithm works, with ut=sqrt(in), and + with in=73632 and ut=271 (even shift value case): + + in=73632 + y= in/131072 + x=y-1 + t = 1 + (x/2) - 0.5*((x/2)^2) + 0.5*((x/2)^3) - 0.625*((x/2)^4) + 0.875*((x/2)^5) + ut=t*(1/sqrt(2))*512 + + or: + + in=73632 + in2=73632*2^14 + y= in2/2^31 + x=y-1 + t = 1 + (x/2) - 0.5*((x/2)^2) + 0.5*((x/2)^3) - 0.625*((x/2)^4) + 0.875*((x/2)^5) + ut=t*(1/sqrt(2)) + ut2=ut*2^9 + + which gives: + + in = 73632 + in2 = 1206386688 + y = 0.56176757812500 + x = -0.43823242187500 + t = 0.74973506527313 + ut = 0.53014274874797 + ut2 = 2.714330873589594e+002 + + or: + + in=73632 + in2=73632*2^14 + y=in2/2 + x=y-2^30 + x_half=x/2^31 + t = 1 + (x_half) - 0.5*((x_half)^2) + 0.5*((x_half)^3) - 0.625*((x_half)^4) + + 0.875*((x_half)^5) + ut=t*(1/sqrt(2)) + ut2=ut*2^9 + + which gives: + + in = 73632 + in2 = 1206386688 + y = 603193344 + x = -470548480 + x_half = -0.21911621093750 + t = 0.74973506527313 + ut = 0.53014274874797 + ut2 = 2.714330873589594e+002 + + */ + + WebRtc_Word16 x_norm, nshift, t16, sh; + WebRtc_Word32 A; + + WebRtc_Word16 k_sqrt_2 = 23170; // 1/sqrt2 (==5a82) + + A = value; + + if (A == 0) + return (WebRtc_Word32)0; // sqrt(0) = 0 + + sh = WebRtcSpl_NormW32(A); // # shifts to normalize A + A = WEBRTC_SPL_LSHIFT_W32(A, sh); // Normalize A + if (A < (WEBRTC_SPL_WORD32_MAX - 32767)) + { + A = A + ((WebRtc_Word32)32768); // Round off bit + } else + { + A = WEBRTC_SPL_WORD32_MAX; + } + + x_norm = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32(A, 16); // x_norm = AH + + nshift = WEBRTC_SPL_RSHIFT_W16(sh, 1); // nshift = sh>>1 + nshift = -nshift; // Negate the power for later de-normalization + + A = (WebRtc_Word32)WEBRTC_SPL_LSHIFT_W32((WebRtc_Word32)x_norm, 16); + A = WEBRTC_SPL_ABS_W32(A); // A = abs(x_norm<<16) + A = WebRtcSpl_SqrtLocal(A); // A = sqrt(A) + + if ((-2 * nshift) == sh) + { // Even shift value case + + t16 = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32(A, 16); // t16 = AH + + A = WEBRTC_SPL_MUL_16_16(k_sqrt_2, t16) * 2; // A = 1/sqrt(2)*t16 + A = A + ((WebRtc_Word32)32768); // Round off + A = A & ((WebRtc_Word32)0x7fff0000); // Round off + + A = WEBRTC_SPL_RSHIFT_W32(A, 15); // A = A>>16 + + } else + { + A = WEBRTC_SPL_RSHIFT_W32(A, 16); // A = A>>16 + } + + A = A & ((WebRtc_Word32)0x0000ffff); + A = (WebRtc_Word32)WEBRTC_SPL_SHIFT_W32(A, nshift); // De-normalize the result + + return A; +} diff --git a/src/common_audio/signal_processing_library/main/source/spl_sqrt_floor.c b/src/common_audio/signal_processing_library/main/source/spl_sqrt_floor.c new file mode 100644 index 0000000..aa36459 --- /dev/null +++ b/src/common_audio/signal_processing_library/main/source/spl_sqrt_floor.c @@ -0,0 +1,53 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +/* + * This file contains the function WebRtcSpl_SqrtFloor(). + * The description header can be found in signal_processing_library.h + * + */ + +#include "signal_processing_library.h" + +#define WEBRTC_SPL_SQRT_ITER(N) \ + try1 = root + (1 << (N)); \ + if (value >= try1 << (N)) \ + { \ + value -= try1 << (N); \ + root |= 2 << (N); \ + } + +// (out) Square root of input parameter +WebRtc_Word32 WebRtcSpl_SqrtFloor(WebRtc_Word32 value) +{ + // new routine for performance, 4 cycles/bit in ARM + // output precision is 16 bits + + WebRtc_Word32 root = 0, try1; + + WEBRTC_SPL_SQRT_ITER (15); + WEBRTC_SPL_SQRT_ITER (14); + WEBRTC_SPL_SQRT_ITER (13); + WEBRTC_SPL_SQRT_ITER (12); + WEBRTC_SPL_SQRT_ITER (11); + WEBRTC_SPL_SQRT_ITER (10); + WEBRTC_SPL_SQRT_ITER ( 9); + WEBRTC_SPL_SQRT_ITER ( 8); + WEBRTC_SPL_SQRT_ITER ( 7); + WEBRTC_SPL_SQRT_ITER ( 6); + WEBRTC_SPL_SQRT_ITER ( 5); + WEBRTC_SPL_SQRT_ITER ( 4); + WEBRTC_SPL_SQRT_ITER ( 3); + WEBRTC_SPL_SQRT_ITER ( 2); + WEBRTC_SPL_SQRT_ITER ( 1); + WEBRTC_SPL_SQRT_ITER ( 0); + + return root >> 1; +} diff --git a/src/common_audio/signal_processing_library/main/source/spl_version.c b/src/common_audio/signal_processing_library/main/source/spl_version.c new file mode 100644 index 0000000..936925e --- /dev/null +++ b/src/common_audio/signal_processing_library/main/source/spl_version.c @@ -0,0 +1,25 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + + +/* + * This file contains the function WebRtcSpl_get_version(). + * The description header can be found in signal_processing_library.h + * + */ + +#include +#include "signal_processing_library.h" + +WebRtc_Word16 WebRtcSpl_get_version(char* version, WebRtc_Word16 length_in_bytes) +{ + strncpy(version, "1.2.0", length_in_bytes); + return 0; +} diff --git a/src/common_audio/signal_processing_library/main/source/splitting_filter.c b/src/common_audio/signal_processing_library/main/source/splitting_filter.c new file mode 100644 index 0000000..98442f4 --- /dev/null +++ b/src/common_audio/signal_processing_library/main/source/splitting_filter.c @@ -0,0 +1,200 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +/* + * This file contains the splitting filter functions. + * + */ + +#include "signal_processing_library.h" + +// Number of samples in a low/high-band frame. +enum +{ + kBandFrameLength = 160 +}; + +// QMF filter coefficients in Q16. +static const WebRtc_UWord16 WebRtcSpl_kAllPassFilter1[3] = {6418, 36982, 57261}; +static const WebRtc_UWord16 WebRtcSpl_kAllPassFilter2[3] = {21333, 49062, 63010}; + +/////////////////////////////////////////////////////////////////////////////////////////////// +// WebRtcSpl_AllPassQMF(...) +// +// Allpass filter used by the analysis and synthesis parts of the QMF filter. +// +// Input: +// - in_data : Input data sequence (Q10) +// - data_length : Length of data sequence (>2) +// - filter_coefficients : Filter coefficients (length 3, Q16) +// +// Input & Output: +// - filter_state : Filter state (length 6, Q10). +// +// Output: +// - out_data : Output data sequence (Q10), length equal to +// |data_length| +// + +void WebRtcSpl_AllPassQMF(WebRtc_Word32* in_data, const WebRtc_Word16 data_length, + WebRtc_Word32* out_data, const WebRtc_UWord16* filter_coefficients, + WebRtc_Word32* filter_state) +{ + // The procedure is to filter the input with three first order all pass filters + // (cascade operations). + // + // a_3 + q^-1 a_2 + q^-1 a_1 + q^-1 + // y[n] = ----------- ----------- ----------- x[n] + // 1 + a_3q^-1 1 + a_2q^-1 1 + a_1q^-1 + // + // The input vector |filter_coefficients| includes these three filter coefficients. + // The filter state contains the in_data state, in_data[-1], followed by + // the out_data state, out_data[-1]. This is repeated for each cascade. + // The first cascade filter will filter the |in_data| and store the output in + // |out_data|. The second will the take the |out_data| as input and make an + // intermediate storage in |in_data|, to save memory. The third, and final, cascade + // filter operation takes the |in_data| (which is the output from the previous cascade + // filter) and store the output in |out_data|. + // Note that the input vector values are changed during the process. + WebRtc_Word16 k; + WebRtc_Word32 diff; + // First all-pass cascade; filter from in_data to out_data. + + // Let y_i[n] indicate the output of cascade filter i (with filter coefficient a_i) at + // vector position n. Then the final output will be y[n] = y_3[n] + + // First loop, use the states stored in memory. + // "diff" should be safe from wrap around since max values are 2^25 + diff = WEBRTC_SPL_SUB_SAT_W32(in_data[0], filter_state[1]); // = (x[0] - y_1[-1]) + // y_1[0] = x[-1] + a_1 * (x[0] - y_1[-1]) + out_data[0] = WEBRTC_SPL_SCALEDIFF32(filter_coefficients[0], diff, filter_state[0]); + + // For the remaining loops, use previous values. + for (k = 1; k < data_length; k++) + { + diff = WEBRTC_SPL_SUB_SAT_W32(in_data[k], out_data[k - 1]); // = (x[n] - y_1[n-1]) + // y_1[n] = x[n-1] + a_1 * (x[n] - y_1[n-1]) + out_data[k] = WEBRTC_SPL_SCALEDIFF32(filter_coefficients[0], diff, in_data[k - 1]); + } + + // Update states. + filter_state[0] = in_data[data_length - 1]; // x[N-1], becomes x[-1] next time + filter_state[1] = out_data[data_length - 1]; // y_1[N-1], becomes y_1[-1] next time + + // Second all-pass cascade; filter from out_data to in_data. + diff = WEBRTC_SPL_SUB_SAT_W32(out_data[0], filter_state[3]); // = (y_1[0] - y_2[-1]) + // y_2[0] = y_1[-1] + a_2 * (y_1[0] - y_2[-1]) + in_data[0] = WEBRTC_SPL_SCALEDIFF32(filter_coefficients[1], diff, filter_state[2]); + for (k = 1; k < data_length; k++) + { + diff = WEBRTC_SPL_SUB_SAT_W32(out_data[k], in_data[k - 1]); // =(y_1[n] - y_2[n-1]) + // y_2[0] = y_1[-1] + a_2 * (y_1[0] - y_2[-1]) + in_data[k] = WEBRTC_SPL_SCALEDIFF32(filter_coefficients[1], diff, out_data[k-1]); + } + + filter_state[2] = out_data[data_length - 1]; // y_1[N-1], becomes y_1[-1] next time + filter_state[3] = in_data[data_length - 1]; // y_2[N-1], becomes y_2[-1] next time + + // Third all-pass cascade; filter from in_data to out_data. + diff = WEBRTC_SPL_SUB_SAT_W32(in_data[0], filter_state[5]); // = (y_2[0] - y[-1]) + // y[0] = y_2[-1] + a_3 * (y_2[0] - y[-1]) + out_data[0] = WEBRTC_SPL_SCALEDIFF32(filter_coefficients[2], diff, filter_state[4]); + for (k = 1; k < data_length; k++) + { + diff = WEBRTC_SPL_SUB_SAT_W32(in_data[k], out_data[k - 1]); // = (y_2[n] - y[n-1]) + // y[n] = y_2[n-1] + a_3 * (y_2[n] - y[n-1]) + out_data[k] = WEBRTC_SPL_SCALEDIFF32(filter_coefficients[2], diff, in_data[k-1]); + } + filter_state[4] = in_data[data_length - 1]; // y_2[N-1], becomes y_2[-1] next time + filter_state[5] = out_data[data_length - 1]; // y[N-1], becomes y[-1] next time +} + +void WebRtcSpl_AnalysisQMF(const WebRtc_Word16* in_data, WebRtc_Word16* low_band, + WebRtc_Word16* high_band, WebRtc_Word32* filter_state1, + WebRtc_Word32* filter_state2) +{ + WebRtc_Word16 i; + WebRtc_Word16 k; + WebRtc_Word32 tmp; + WebRtc_Word32 half_in1[kBandFrameLength]; + WebRtc_Word32 half_in2[kBandFrameLength]; + WebRtc_Word32 filter1[kBandFrameLength]; + WebRtc_Word32 filter2[kBandFrameLength]; + + // Split even and odd samples. Also shift them to Q10. + for (i = 0, k = 0; i < kBandFrameLength; i++, k += 2) + { + half_in2[i] = WEBRTC_SPL_LSHIFT_W32((WebRtc_Word32)in_data[k], 10); + half_in1[i] = WEBRTC_SPL_LSHIFT_W32((WebRtc_Word32)in_data[k + 1], 10); + } + + // All pass filter even and odd samples, independently. + WebRtcSpl_AllPassQMF(half_in1, kBandFrameLength, filter1, WebRtcSpl_kAllPassFilter1, + filter_state1); + WebRtcSpl_AllPassQMF(half_in2, kBandFrameLength, filter2, WebRtcSpl_kAllPassFilter2, + filter_state2); + + // Take the sum and difference of filtered version of odd and even + // branches to get upper & lower band. + for (i = 0; i < kBandFrameLength; i++) + { + tmp = filter1[i] + filter2[i] + 1024; + tmp = WEBRTC_SPL_RSHIFT_W32(tmp, 11); + low_band[i] = (WebRtc_Word16)WEBRTC_SPL_SAT(WEBRTC_SPL_WORD16_MAX, + tmp, WEBRTC_SPL_WORD16_MIN); + + tmp = filter1[i] - filter2[i] + 1024; + tmp = WEBRTC_SPL_RSHIFT_W32(tmp, 11); + high_band[i] = (WebRtc_Word16)WEBRTC_SPL_SAT(WEBRTC_SPL_WORD16_MAX, + tmp, WEBRTC_SPL_WORD16_MIN); + } +} + +void WebRtcSpl_SynthesisQMF(const WebRtc_Word16* low_band, const WebRtc_Word16* high_band, + WebRtc_Word16* out_data, WebRtc_Word32* filter_state1, + WebRtc_Word32* filter_state2) +{ + WebRtc_Word32 tmp; + WebRtc_Word32 half_in1[kBandFrameLength]; + WebRtc_Word32 half_in2[kBandFrameLength]; + WebRtc_Word32 filter1[kBandFrameLength]; + WebRtc_Word32 filter2[kBandFrameLength]; + WebRtc_Word16 i; + WebRtc_Word16 k; + + // Obtain the sum and difference channels out of upper and lower-band channels. + // Also shift to Q10 domain. + for (i = 0; i < kBandFrameLength; i++) + { + tmp = (WebRtc_Word32)low_band[i] + (WebRtc_Word32)high_band[i]; + half_in1[i] = WEBRTC_SPL_LSHIFT_W32(tmp, 10); + tmp = (WebRtc_Word32)low_band[i] - (WebRtc_Word32)high_band[i]; + half_in2[i] = WEBRTC_SPL_LSHIFT_W32(tmp, 10); + } + + // all-pass filter the sum and difference channels + WebRtcSpl_AllPassQMF(half_in1, kBandFrameLength, filter1, WebRtcSpl_kAllPassFilter2, + filter_state1); + WebRtcSpl_AllPassQMF(half_in2, kBandFrameLength, filter2, WebRtcSpl_kAllPassFilter1, + filter_state2); + + // The filtered signals are even and odd samples of the output. Combine + // them. The signals are Q10 should shift them back to Q0 and take care of + // saturation. + for (i = 0, k = 0; i < kBandFrameLength; i++) + { + tmp = WEBRTC_SPL_RSHIFT_W32(filter2[i] + 512, 10); + out_data[k++] = (WebRtc_Word16)WEBRTC_SPL_SAT(32767, tmp, -32768); + + tmp = WEBRTC_SPL_RSHIFT_W32(filter1[i] + 512, 10); + out_data[k++] = (WebRtc_Word16)WEBRTC_SPL_SAT(32767, tmp, -32768); + } + +} diff --git a/src/common_audio/signal_processing_library/main/source/sqrt_of_one_minus_x_squared.c b/src/common_audio/signal_processing_library/main/source/sqrt_of_one_minus_x_squared.c new file mode 100644 index 0000000..9fb2c73 --- /dev/null +++ b/src/common_audio/signal_processing_library/main/source/sqrt_of_one_minus_x_squared.c @@ -0,0 +1,35 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + + +/* + * This file contains the function WebRtcSpl_SqrtOfOneMinusXSquared(). + * The description header can be found in signal_processing_library.h + * + */ + +#include "signal_processing_library.h" + +void WebRtcSpl_SqrtOfOneMinusXSquared(WebRtc_Word16 *xQ15, int vector_length, + WebRtc_Word16 *yQ15) +{ + WebRtc_Word32 sq; + int m; + WebRtc_Word16 tmp; + + for (m = 0; m < vector_length; m++) + { + tmp = xQ15[m]; + sq = WEBRTC_SPL_MUL_16_16(tmp, tmp); // x^2 in Q30 + sq = 1073741823 - sq; // 1-x^2, where 1 ~= 0.99999999906 is 1073741823 in Q30 + sq = WebRtcSpl_Sqrt(sq); // sqrt(1-x^2) in Q15 + yQ15[m] = (WebRtc_Word16)sq; + } +} diff --git a/src/common_audio/signal_processing_library/main/source/vector_scaling_operations.c b/src/common_audio/signal_processing_library/main/source/vector_scaling_operations.c new file mode 100644 index 0000000..47362ee --- /dev/null +++ b/src/common_audio/signal_processing_library/main/source/vector_scaling_operations.c @@ -0,0 +1,151 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + + +/* + * This file contains implementations of the functions + * WebRtcSpl_VectorBitShiftW16() + * WebRtcSpl_VectorBitShiftW32() + * WebRtcSpl_VectorBitShiftW32ToW16() + * WebRtcSpl_ScaleVector() + * WebRtcSpl_ScaleVectorWithSat() + * WebRtcSpl_ScaleAndAddVectors() + * + * The description header can be found in signal_processing_library.h + * + */ + +#include "signal_processing_library.h" + +void WebRtcSpl_VectorBitShiftW16(WebRtc_Word16 *res, + WebRtc_Word16 length, + G_CONST WebRtc_Word16 *in, + WebRtc_Word16 right_shifts) +{ + int i; + + if (right_shifts > 0) + { + for (i = length; i > 0; i--) + { + (*res++) = ((*in++) >> right_shifts); + } + } else + { + for (i = length; i > 0; i--) + { + (*res++) = ((*in++) << (-right_shifts)); + } + } +} + +void WebRtcSpl_VectorBitShiftW32(WebRtc_Word32 *out_vector, + WebRtc_Word16 vector_length, + G_CONST WebRtc_Word32 *in_vector, + WebRtc_Word16 right_shifts) +{ + int i; + + if (right_shifts > 0) + { + for (i = vector_length; i > 0; i--) + { + (*out_vector++) = ((*in_vector++) >> right_shifts); + } + } else + { + for (i = vector_length; i > 0; i--) + { + (*out_vector++) = ((*in_vector++) << (-right_shifts)); + } + } +} + +void WebRtcSpl_VectorBitShiftW32ToW16(WebRtc_Word16 *res, + WebRtc_Word16 length, + G_CONST WebRtc_Word32 *in, + WebRtc_Word16 right_shifts) +{ + int i; + + if (right_shifts >= 0) + { + for (i = length; i > 0; i--) + { + (*res++) = (WebRtc_Word16)((*in++) >> right_shifts); + } + } else + { + WebRtc_Word16 left_shifts = -right_shifts; + for (i = length; i > 0; i--) + { + (*res++) = (WebRtc_Word16)((*in++) << left_shifts); + } + } +} + +void WebRtcSpl_ScaleVector(G_CONST WebRtc_Word16 *in_vector, WebRtc_Word16 *out_vector, + WebRtc_Word16 gain, WebRtc_Word16 in_vector_length, + WebRtc_Word16 right_shifts) +{ + // Performs vector operation: out_vector = (gain*in_vector)>>right_shifts + int i; + G_CONST WebRtc_Word16 *inptr; + WebRtc_Word16 *outptr; + + inptr = in_vector; + outptr = out_vector; + + for (i = 0; i < in_vector_length; i++) + { + (*outptr++) = (WebRtc_Word16)WEBRTC_SPL_MUL_16_16_RSFT(*inptr++, gain, right_shifts); + } +} + +void WebRtcSpl_ScaleVectorWithSat(G_CONST WebRtc_Word16 *in_vector, WebRtc_Word16 *out_vector, + WebRtc_Word16 gain, WebRtc_Word16 in_vector_length, + WebRtc_Word16 right_shifts) +{ + // Performs vector operation: out_vector = (gain*in_vector)>>right_shifts + int i; + WebRtc_Word32 tmpW32; + G_CONST WebRtc_Word16 *inptr; + WebRtc_Word16 *outptr; + + inptr = in_vector; + outptr = out_vector; + + for (i = 0; i < in_vector_length; i++) + { + tmpW32 = WEBRTC_SPL_MUL_16_16_RSFT(*inptr++, gain, right_shifts); + ( *outptr++) = (WebRtc_Word16)WEBRTC_SPL_SAT(32767, tmpW32, -32768); + } +} + +void WebRtcSpl_ScaleAndAddVectors(G_CONST WebRtc_Word16 *in1, WebRtc_Word16 gain1, int shift1, + G_CONST WebRtc_Word16 *in2, WebRtc_Word16 gain2, int shift2, + WebRtc_Word16 *out, int vector_length) +{ + // Performs vector operation: out = (gain1*in1)>>shift1 + (gain2*in2)>>shift2 + int i; + G_CONST WebRtc_Word16 *in1ptr; + G_CONST WebRtc_Word16 *in2ptr; + WebRtc_Word16 *outptr; + + in1ptr = in1; + in2ptr = in2; + outptr = out; + + for (i = 0; i < vector_length; i++) + { + (*outptr++) = (WebRtc_Word16)WEBRTC_SPL_MUL_16_16_RSFT(gain1, *in1ptr++, shift1) + + (WebRtc_Word16)WEBRTC_SPL_MUL_16_16_RSFT(gain2, *in2ptr++, shift2); + } +} diff --git a/src/common_audio/signal_processing_library/main/source/webrtc_fft_t_1024_8.c b/src/common_audio/signal_processing_library/main/source/webrtc_fft_t_1024_8.c new file mode 100644 index 0000000..b587380 --- /dev/null +++ b/src/common_audio/signal_processing_library/main/source/webrtc_fft_t_1024_8.c @@ -0,0 +1,704 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + + +/* + * This file contains the Q14 radix-8 tables used in ARM9e optimizations. + * + */ + +extern const int s_Q14S_8; +const int s_Q14S_8 = 1024; +extern const unsigned short t_Q14S_8[2032]; +const unsigned short t_Q14S_8[2032] = { + 0x4000,0x0000 ,0x4000,0x0000 ,0x4000,0x0000 , + 0x22a3,0x187e ,0x3249,0x0c7c ,0x11a8,0x238e , + 0x0000,0x2d41 ,0x22a3,0x187e ,0xdd5d,0x3b21 , + 0xdd5d,0x3b21 ,0x11a8,0x238e ,0xb4be,0x3ec5 , + 0xc000,0x4000 ,0x0000,0x2d41 ,0xa57e,0x2d41 , + 0xac61,0x3b21 ,0xee58,0x3537 ,0xb4be,0x0c7c , + 0xa57e,0x2d41 ,0xdd5d,0x3b21 ,0xdd5d,0xe782 , + 0xac61,0x187e ,0xcdb7,0x3ec5 ,0x11a8,0xcac9 , + 0x4000,0x0000 ,0x4000,0x0000 ,0x4000,0x0000 , + 0x396b,0x0646 ,0x3cc8,0x0324 ,0x35eb,0x0964 , + 0x3249,0x0c7c ,0x396b,0x0646 ,0x2aaa,0x1294 , + 0x2aaa,0x1294 ,0x35eb,0x0964 ,0x1e7e,0x1b5d , + 0x22a3,0x187e ,0x3249,0x0c7c ,0x11a8,0x238e , + 0x1a46,0x1e2b ,0x2e88,0x0f8d ,0x0471,0x2afb , + 0x11a8,0x238e ,0x2aaa,0x1294 ,0xf721,0x3179 , + 0x08df,0x289a ,0x26b3,0x1590 ,0xea02,0x36e5 , + 0x0000,0x2d41 ,0x22a3,0x187e ,0xdd5d,0x3b21 , + 0xf721,0x3179 ,0x1e7e,0x1b5d ,0xd178,0x3e15 , + 0xee58,0x3537 ,0x1a46,0x1e2b ,0xc695,0x3fb1 , + 0xe5ba,0x3871 ,0x15fe,0x20e7 ,0xbcf0,0x3fec , + 0xdd5d,0x3b21 ,0x11a8,0x238e ,0xb4be,0x3ec5 , + 0xd556,0x3d3f ,0x0d48,0x2620 ,0xae2e,0x3c42 , + 0xcdb7,0x3ec5 ,0x08df,0x289a ,0xa963,0x3871 , + 0xc695,0x3fb1 ,0x0471,0x2afb ,0xa678,0x3368 , + 0xc000,0x4000 ,0x0000,0x2d41 ,0xa57e,0x2d41 , + 0xba09,0x3fb1 ,0xfb8f,0x2f6c ,0xa678,0x2620 , + 0xb4be,0x3ec5 ,0xf721,0x3179 ,0xa963,0x1e2b , + 0xb02d,0x3d3f ,0xf2b8,0x3368 ,0xae2e,0x1590 , + 0xac61,0x3b21 ,0xee58,0x3537 ,0xb4be,0x0c7c , + 0xa963,0x3871 ,0xea02,0x36e5 ,0xbcf0,0x0324 , + 0xa73b,0x3537 ,0xe5ba,0x3871 ,0xc695,0xf9ba , + 0xa5ed,0x3179 ,0xe182,0x39db ,0xd178,0xf073 , + 0xa57e,0x2d41 ,0xdd5d,0x3b21 ,0xdd5d,0xe782 , + 0xa5ed,0x289a ,0xd94d,0x3c42 ,0xea02,0xdf19 , + 0xa73b,0x238e ,0xd556,0x3d3f ,0xf721,0xd766 , + 0xa963,0x1e2b ,0xd178,0x3e15 ,0x0471,0xd094 , + 0xac61,0x187e ,0xcdb7,0x3ec5 ,0x11a8,0xcac9 , + 0xb02d,0x1294 ,0xca15,0x3f4f ,0x1e7e,0xc625 , + 0xb4be,0x0c7c ,0xc695,0x3fb1 ,0x2aaa,0xc2c1 , + 0xba09,0x0646 ,0xc338,0x3fec ,0x35eb,0xc0b1 , + 0x4000,0x0000 ,0x4000,0x0000 ,0x4000,0x0000 , + 0x3e69,0x0192 ,0x3f36,0x00c9 ,0x3d9a,0x025b , + 0x3cc8,0x0324 ,0x3e69,0x0192 ,0x3b1e,0x04b5 , + 0x3b1e,0x04b5 ,0x3d9a,0x025b ,0x388e,0x070e , + 0x396b,0x0646 ,0x3cc8,0x0324 ,0x35eb,0x0964 , + 0x37af,0x07d6 ,0x3bf4,0x03ed ,0x3334,0x0bb7 , + 0x35eb,0x0964 ,0x3b1e,0x04b5 ,0x306c,0x0e06 , + 0x341e,0x0af1 ,0x3a46,0x057e ,0x2d93,0x1050 , + 0x3249,0x0c7c ,0x396b,0x0646 ,0x2aaa,0x1294 , + 0x306c,0x0e06 ,0x388e,0x070e ,0x27b3,0x14d2 , + 0x2e88,0x0f8d ,0x37af,0x07d6 ,0x24ae,0x1709 , + 0x2c9d,0x1112 ,0x36ce,0x089d ,0x219c,0x1937 , + 0x2aaa,0x1294 ,0x35eb,0x0964 ,0x1e7e,0x1b5d , + 0x28b2,0x1413 ,0x3505,0x0a2b ,0x1b56,0x1d79 , + 0x26b3,0x1590 ,0x341e,0x0af1 ,0x1824,0x1f8c , + 0x24ae,0x1709 ,0x3334,0x0bb7 ,0x14ea,0x2193 , + 0x22a3,0x187e ,0x3249,0x0c7c ,0x11a8,0x238e , + 0x2093,0x19ef ,0x315b,0x0d41 ,0x0e61,0x257e , + 0x1e7e,0x1b5d ,0x306c,0x0e06 ,0x0b14,0x2760 , + 0x1c64,0x1cc6 ,0x2f7b,0x0eca ,0x07c4,0x2935 , + 0x1a46,0x1e2b ,0x2e88,0x0f8d ,0x0471,0x2afb , + 0x1824,0x1f8c ,0x2d93,0x1050 ,0x011c,0x2cb2 , + 0x15fe,0x20e7 ,0x2c9d,0x1112 ,0xfdc7,0x2e5a , + 0x13d5,0x223d ,0x2ba4,0x11d3 ,0xfa73,0x2ff2 , + 0x11a8,0x238e ,0x2aaa,0x1294 ,0xf721,0x3179 , + 0x0f79,0x24da ,0x29af,0x1354 ,0xf3d2,0x32ef , + 0x0d48,0x2620 ,0x28b2,0x1413 ,0xf087,0x3453 , + 0x0b14,0x2760 ,0x27b3,0x14d2 ,0xed41,0x35a5 , + 0x08df,0x289a ,0x26b3,0x1590 ,0xea02,0x36e5 , + 0x06a9,0x29ce ,0x25b1,0x164c ,0xe6cb,0x3812 , + 0x0471,0x2afb ,0x24ae,0x1709 ,0xe39c,0x392b , + 0x0239,0x2c21 ,0x23a9,0x17c4 ,0xe077,0x3a30 , + 0x0000,0x2d41 ,0x22a3,0x187e ,0xdd5d,0x3b21 , + 0xfdc7,0x2e5a ,0x219c,0x1937 ,0xda4f,0x3bfd , + 0xfb8f,0x2f6c ,0x2093,0x19ef ,0xd74e,0x3cc5 , + 0xf957,0x3076 ,0x1f89,0x1aa7 ,0xd45c,0x3d78 , + 0xf721,0x3179 ,0x1e7e,0x1b5d ,0xd178,0x3e15 , + 0xf4ec,0x3274 ,0x1d72,0x1c12 ,0xcea5,0x3e9d , + 0xf2b8,0x3368 ,0x1c64,0x1cc6 ,0xcbe2,0x3f0f , + 0xf087,0x3453 ,0x1b56,0x1d79 ,0xc932,0x3f6b , + 0xee58,0x3537 ,0x1a46,0x1e2b ,0xc695,0x3fb1 , + 0xec2b,0x3612 ,0x1935,0x1edc ,0xc40c,0x3fe1 , + 0xea02,0x36e5 ,0x1824,0x1f8c ,0xc197,0x3ffb , + 0xe7dc,0x37b0 ,0x1711,0x203a ,0xbf38,0x3fff , + 0xe5ba,0x3871 ,0x15fe,0x20e7 ,0xbcf0,0x3fec , + 0xe39c,0x392b ,0x14ea,0x2193 ,0xbabf,0x3fc4 , + 0xe182,0x39db ,0x13d5,0x223d ,0xb8a6,0x3f85 , + 0xdf6d,0x3a82 ,0x12bf,0x22e7 ,0xb6a5,0x3f30 , + 0xdd5d,0x3b21 ,0x11a8,0x238e ,0xb4be,0x3ec5 , + 0xdb52,0x3bb6 ,0x1091,0x2435 ,0xb2f2,0x3e45 , + 0xd94d,0x3c42 ,0x0f79,0x24da ,0xb140,0x3daf , + 0xd74e,0x3cc5 ,0x0e61,0x257e ,0xafa9,0x3d03 , + 0xd556,0x3d3f ,0x0d48,0x2620 ,0xae2e,0x3c42 , + 0xd363,0x3daf ,0x0c2e,0x26c1 ,0xacd0,0x3b6d , + 0xd178,0x3e15 ,0x0b14,0x2760 ,0xab8e,0x3a82 , + 0xcf94,0x3e72 ,0x09fa,0x27fe ,0xaa6a,0x3984 , + 0xcdb7,0x3ec5 ,0x08df,0x289a ,0xa963,0x3871 , + 0xcbe2,0x3f0f ,0x07c4,0x2935 ,0xa87b,0x374b , + 0xca15,0x3f4f ,0x06a9,0x29ce ,0xa7b1,0x3612 , + 0xc851,0x3f85 ,0x058d,0x2a65 ,0xa705,0x34c6 , + 0xc695,0x3fb1 ,0x0471,0x2afb ,0xa678,0x3368 , + 0xc4e2,0x3fd4 ,0x0355,0x2b8f ,0xa60b,0x31f8 , + 0xc338,0x3fec ,0x0239,0x2c21 ,0xa5bc,0x3076 , + 0xc197,0x3ffb ,0x011c,0x2cb2 ,0xa58d,0x2ee4 , + 0xc000,0x4000 ,0x0000,0x2d41 ,0xa57e,0x2d41 , + 0xbe73,0x3ffb ,0xfee4,0x2dcf ,0xa58d,0x2b8f , + 0xbcf0,0x3fec ,0xfdc7,0x2e5a ,0xa5bc,0x29ce , + 0xbb77,0x3fd4 ,0xfcab,0x2ee4 ,0xa60b,0x27fe , + 0xba09,0x3fb1 ,0xfb8f,0x2f6c ,0xa678,0x2620 , + 0xb8a6,0x3f85 ,0xfa73,0x2ff2 ,0xa705,0x2435 , + 0xb74d,0x3f4f ,0xf957,0x3076 ,0xa7b1,0x223d , + 0xb600,0x3f0f ,0xf83c,0x30f9 ,0xa87b,0x203a , + 0xb4be,0x3ec5 ,0xf721,0x3179 ,0xa963,0x1e2b , + 0xb388,0x3e72 ,0xf606,0x31f8 ,0xaa6a,0x1c12 , + 0xb25e,0x3e15 ,0xf4ec,0x3274 ,0xab8e,0x19ef , + 0xb140,0x3daf ,0xf3d2,0x32ef ,0xacd0,0x17c4 , + 0xb02d,0x3d3f ,0xf2b8,0x3368 ,0xae2e,0x1590 , + 0xaf28,0x3cc5 ,0xf19f,0x33df ,0xafa9,0x1354 , + 0xae2e,0x3c42 ,0xf087,0x3453 ,0xb140,0x1112 , + 0xad41,0x3bb6 ,0xef6f,0x34c6 ,0xb2f2,0x0eca , + 0xac61,0x3b21 ,0xee58,0x3537 ,0xb4be,0x0c7c , + 0xab8e,0x3a82 ,0xed41,0x35a5 ,0xb6a5,0x0a2b , + 0xaac8,0x39db ,0xec2b,0x3612 ,0xb8a6,0x07d6 , + 0xaa0f,0x392b ,0xeb16,0x367d ,0xbabf,0x057e , + 0xa963,0x3871 ,0xea02,0x36e5 ,0xbcf0,0x0324 , + 0xa8c5,0x37b0 ,0xe8ef,0x374b ,0xbf38,0x00c9 , + 0xa834,0x36e5 ,0xe7dc,0x37b0 ,0xc197,0xfe6e , + 0xa7b1,0x3612 ,0xe6cb,0x3812 ,0xc40c,0xfc13 , + 0xa73b,0x3537 ,0xe5ba,0x3871 ,0xc695,0xf9ba , + 0xa6d3,0x3453 ,0xe4aa,0x38cf ,0xc932,0xf763 , + 0xa678,0x3368 ,0xe39c,0x392b ,0xcbe2,0xf50f , + 0xa62c,0x3274 ,0xe28e,0x3984 ,0xcea5,0xf2bf , + 0xa5ed,0x3179 ,0xe182,0x39db ,0xd178,0xf073 , + 0xa5bc,0x3076 ,0xe077,0x3a30 ,0xd45c,0xee2d , + 0xa599,0x2f6c ,0xdf6d,0x3a82 ,0xd74e,0xebed , + 0xa585,0x2e5a ,0xde64,0x3ad3 ,0xda4f,0xe9b4 , + 0xa57e,0x2d41 ,0xdd5d,0x3b21 ,0xdd5d,0xe782 , + 0xa585,0x2c21 ,0xdc57,0x3b6d ,0xe077,0xe559 , + 0xa599,0x2afb ,0xdb52,0x3bb6 ,0xe39c,0xe33a , + 0xa5bc,0x29ce ,0xda4f,0x3bfd ,0xe6cb,0xe124 , + 0xa5ed,0x289a ,0xd94d,0x3c42 ,0xea02,0xdf19 , + 0xa62c,0x2760 ,0xd84d,0x3c85 ,0xed41,0xdd19 , + 0xa678,0x2620 ,0xd74e,0x3cc5 ,0xf087,0xdb26 , + 0xa6d3,0x24da ,0xd651,0x3d03 ,0xf3d2,0xd93f , + 0xa73b,0x238e ,0xd556,0x3d3f ,0xf721,0xd766 , + 0xa7b1,0x223d ,0xd45c,0x3d78 ,0xfa73,0xd59b , + 0xa834,0x20e7 ,0xd363,0x3daf ,0xfdc7,0xd3df , + 0xa8c5,0x1f8c ,0xd26d,0x3de3 ,0x011c,0xd231 , + 0xa963,0x1e2b ,0xd178,0x3e15 ,0x0471,0xd094 , + 0xaa0f,0x1cc6 ,0xd085,0x3e45 ,0x07c4,0xcf07 , + 0xaac8,0x1b5d ,0xcf94,0x3e72 ,0x0b14,0xcd8c , + 0xab8e,0x19ef ,0xcea5,0x3e9d ,0x0e61,0xcc21 , + 0xac61,0x187e ,0xcdb7,0x3ec5 ,0x11a8,0xcac9 , + 0xad41,0x1709 ,0xcccc,0x3eeb ,0x14ea,0xc983 , + 0xae2e,0x1590 ,0xcbe2,0x3f0f ,0x1824,0xc850 , + 0xaf28,0x1413 ,0xcafb,0x3f30 ,0x1b56,0xc731 , + 0xb02d,0x1294 ,0xca15,0x3f4f ,0x1e7e,0xc625 , + 0xb140,0x1112 ,0xc932,0x3f6b ,0x219c,0xc52d , + 0xb25e,0x0f8d ,0xc851,0x3f85 ,0x24ae,0xc44a , + 0xb388,0x0e06 ,0xc772,0x3f9c ,0x27b3,0xc37b , + 0xb4be,0x0c7c ,0xc695,0x3fb1 ,0x2aaa,0xc2c1 , + 0xb600,0x0af1 ,0xc5ba,0x3fc4 ,0x2d93,0xc21d , + 0xb74d,0x0964 ,0xc4e2,0x3fd4 ,0x306c,0xc18e , + 0xb8a6,0x07d6 ,0xc40c,0x3fe1 ,0x3334,0xc115 , + 0xba09,0x0646 ,0xc338,0x3fec ,0x35eb,0xc0b1 , + 0xbb77,0x04b5 ,0xc266,0x3ff5 ,0x388e,0xc064 , + 0xbcf0,0x0324 ,0xc197,0x3ffb ,0x3b1e,0xc02c , + 0xbe73,0x0192 ,0xc0ca,0x3fff ,0x3d9a,0xc00b , + 0x4000,0x0000 ,0x3f9b,0x0065 ,0x3f36,0x00c9 , + 0x3ed0,0x012e ,0x3e69,0x0192 ,0x3e02,0x01f7 , + 0x3d9a,0x025b ,0x3d31,0x02c0 ,0x3cc8,0x0324 , + 0x3c5f,0x0388 ,0x3bf4,0x03ed ,0x3b8a,0x0451 , + 0x3b1e,0x04b5 ,0x3ab2,0x051a ,0x3a46,0x057e , + 0x39d9,0x05e2 ,0x396b,0x0646 ,0x38fd,0x06aa , + 0x388e,0x070e ,0x381f,0x0772 ,0x37af,0x07d6 , + 0x373f,0x0839 ,0x36ce,0x089d ,0x365d,0x0901 , + 0x35eb,0x0964 ,0x3578,0x09c7 ,0x3505,0x0a2b , + 0x3492,0x0a8e ,0x341e,0x0af1 ,0x33a9,0x0b54 , + 0x3334,0x0bb7 ,0x32bf,0x0c1a ,0x3249,0x0c7c , + 0x31d2,0x0cdf ,0x315b,0x0d41 ,0x30e4,0x0da4 , + 0x306c,0x0e06 ,0x2ff4,0x0e68 ,0x2f7b,0x0eca , + 0x2f02,0x0f2b ,0x2e88,0x0f8d ,0x2e0e,0x0fee , + 0x2d93,0x1050 ,0x2d18,0x10b1 ,0x2c9d,0x1112 , + 0x2c21,0x1173 ,0x2ba4,0x11d3 ,0x2b28,0x1234 , + 0x2aaa,0x1294 ,0x2a2d,0x12f4 ,0x29af,0x1354 , + 0x2931,0x13b4 ,0x28b2,0x1413 ,0x2833,0x1473 , + 0x27b3,0x14d2 ,0x2733,0x1531 ,0x26b3,0x1590 , + 0x2632,0x15ee ,0x25b1,0x164c ,0x252f,0x16ab , + 0x24ae,0x1709 ,0x242b,0x1766 ,0x23a9,0x17c4 , + 0x2326,0x1821 ,0x22a3,0x187e ,0x221f,0x18db , + 0x219c,0x1937 ,0x2117,0x1993 ,0x2093,0x19ef , + 0x200e,0x1a4b ,0x1f89,0x1aa7 ,0x1f04,0x1b02 , + 0x1e7e,0x1b5d ,0x1df8,0x1bb8 ,0x1d72,0x1c12 , + 0x1ceb,0x1c6c ,0x1c64,0x1cc6 ,0x1bdd,0x1d20 , + 0x1b56,0x1d79 ,0x1ace,0x1dd3 ,0x1a46,0x1e2b , + 0x19be,0x1e84 ,0x1935,0x1edc ,0x18ad,0x1f34 , + 0x1824,0x1f8c ,0x179b,0x1fe3 ,0x1711,0x203a , + 0x1688,0x2091 ,0x15fe,0x20e7 ,0x1574,0x213d , + 0x14ea,0x2193 ,0x145f,0x21e8 ,0x13d5,0x223d , + 0x134a,0x2292 ,0x12bf,0x22e7 ,0x1234,0x233b , + 0x11a8,0x238e ,0x111d,0x23e2 ,0x1091,0x2435 , + 0x1005,0x2488 ,0x0f79,0x24da ,0x0eed,0x252c , + 0x0e61,0x257e ,0x0dd4,0x25cf ,0x0d48,0x2620 , + 0x0cbb,0x2671 ,0x0c2e,0x26c1 ,0x0ba1,0x2711 , + 0x0b14,0x2760 ,0x0a87,0x27af ,0x09fa,0x27fe , + 0x096d,0x284c ,0x08df,0x289a ,0x0852,0x28e7 , + 0x07c4,0x2935 ,0x0736,0x2981 ,0x06a9,0x29ce , + 0x061b,0x2a1a ,0x058d,0x2a65 ,0x04ff,0x2ab0 , + 0x0471,0x2afb ,0x03e3,0x2b45 ,0x0355,0x2b8f , + 0x02c7,0x2bd8 ,0x0239,0x2c21 ,0x01aa,0x2c6a , + 0x011c,0x2cb2 ,0x008e,0x2cfa ,0x0000,0x2d41 , + 0xff72,0x2d88 ,0xfee4,0x2dcf ,0xfe56,0x2e15 , + 0xfdc7,0x2e5a ,0xfd39,0x2e9f ,0xfcab,0x2ee4 , + 0xfc1d,0x2f28 ,0xfb8f,0x2f6c ,0xfb01,0x2faf , + 0xfa73,0x2ff2 ,0xf9e5,0x3034 ,0xf957,0x3076 , + 0xf8ca,0x30b8 ,0xf83c,0x30f9 ,0xf7ae,0x3139 , + 0xf721,0x3179 ,0xf693,0x31b9 ,0xf606,0x31f8 , + 0xf579,0x3236 ,0xf4ec,0x3274 ,0xf45f,0x32b2 , + 0xf3d2,0x32ef ,0xf345,0x332c ,0xf2b8,0x3368 , + 0xf22c,0x33a3 ,0xf19f,0x33df ,0xf113,0x3419 , + 0xf087,0x3453 ,0xeffb,0x348d ,0xef6f,0x34c6 , + 0xeee3,0x34ff ,0xee58,0x3537 ,0xedcc,0x356e , + 0xed41,0x35a5 ,0xecb6,0x35dc ,0xec2b,0x3612 , + 0xeba1,0x3648 ,0xeb16,0x367d ,0xea8c,0x36b1 , + 0xea02,0x36e5 ,0xe978,0x3718 ,0xe8ef,0x374b , + 0xe865,0x377e ,0xe7dc,0x37b0 ,0xe753,0x37e1 , + 0xe6cb,0x3812 ,0xe642,0x3842 ,0xe5ba,0x3871 , + 0xe532,0x38a1 ,0xe4aa,0x38cf ,0xe423,0x38fd , + 0xe39c,0x392b ,0xe315,0x3958 ,0xe28e,0x3984 , + 0xe208,0x39b0 ,0xe182,0x39db ,0xe0fc,0x3a06 , + 0xe077,0x3a30 ,0xdff2,0x3a59 ,0xdf6d,0x3a82 , + 0xdee9,0x3aab ,0xde64,0x3ad3 ,0xdde1,0x3afa , + 0xdd5d,0x3b21 ,0xdcda,0x3b47 ,0xdc57,0x3b6d , + 0xdbd5,0x3b92 ,0xdb52,0x3bb6 ,0xdad1,0x3bda , + 0xda4f,0x3bfd ,0xd9ce,0x3c20 ,0xd94d,0x3c42 , + 0xd8cd,0x3c64 ,0xd84d,0x3c85 ,0xd7cd,0x3ca5 , + 0xd74e,0x3cc5 ,0xd6cf,0x3ce4 ,0xd651,0x3d03 , + 0xd5d3,0x3d21 ,0xd556,0x3d3f ,0xd4d8,0x3d5b , + 0xd45c,0x3d78 ,0xd3df,0x3d93 ,0xd363,0x3daf , + 0xd2e8,0x3dc9 ,0xd26d,0x3de3 ,0xd1f2,0x3dfc , + 0xd178,0x3e15 ,0xd0fe,0x3e2d ,0xd085,0x3e45 , + 0xd00c,0x3e5c ,0xcf94,0x3e72 ,0xcf1c,0x3e88 , + 0xcea5,0x3e9d ,0xce2e,0x3eb1 ,0xcdb7,0x3ec5 , + 0xcd41,0x3ed8 ,0xcccc,0x3eeb ,0xcc57,0x3efd , + 0xcbe2,0x3f0f ,0xcb6e,0x3f20 ,0xcafb,0x3f30 , + 0xca88,0x3f40 ,0xca15,0x3f4f ,0xc9a3,0x3f5d , + 0xc932,0x3f6b ,0xc8c1,0x3f78 ,0xc851,0x3f85 , + 0xc7e1,0x3f91 ,0xc772,0x3f9c ,0xc703,0x3fa7 , + 0xc695,0x3fb1 ,0xc627,0x3fbb ,0xc5ba,0x3fc4 , + 0xc54e,0x3fcc ,0xc4e2,0x3fd4 ,0xc476,0x3fdb , + 0xc40c,0x3fe1 ,0xc3a1,0x3fe7 ,0xc338,0x3fec , + 0xc2cf,0x3ff1 ,0xc266,0x3ff5 ,0xc1fe,0x3ff8 , + 0xc197,0x3ffb ,0xc130,0x3ffd ,0xc0ca,0x3fff , + 0xc065,0x4000 ,0xc000,0x4000 ,0xbf9c,0x4000 , + 0xbf38,0x3fff ,0xbed5,0x3ffd ,0xbe73,0x3ffb , + 0xbe11,0x3ff8 ,0xbdb0,0x3ff5 ,0xbd50,0x3ff1 , + 0xbcf0,0x3fec ,0xbc91,0x3fe7 ,0xbc32,0x3fe1 , + 0xbbd4,0x3fdb ,0xbb77,0x3fd4 ,0xbb1b,0x3fcc , + 0xbabf,0x3fc4 ,0xba64,0x3fbb ,0xba09,0x3fb1 , + 0xb9af,0x3fa7 ,0xb956,0x3f9c ,0xb8fd,0x3f91 , + 0xb8a6,0x3f85 ,0xb84f,0x3f78 ,0xb7f8,0x3f6b , + 0xb7a2,0x3f5d ,0xb74d,0x3f4f ,0xb6f9,0x3f40 , + 0xb6a5,0x3f30 ,0xb652,0x3f20 ,0xb600,0x3f0f , + 0xb5af,0x3efd ,0xb55e,0x3eeb ,0xb50e,0x3ed8 , + 0xb4be,0x3ec5 ,0xb470,0x3eb1 ,0xb422,0x3e9d , + 0xb3d5,0x3e88 ,0xb388,0x3e72 ,0xb33d,0x3e5c , + 0xb2f2,0x3e45 ,0xb2a7,0x3e2d ,0xb25e,0x3e15 , + 0xb215,0x3dfc ,0xb1cd,0x3de3 ,0xb186,0x3dc9 , + 0xb140,0x3daf ,0xb0fa,0x3d93 ,0xb0b5,0x3d78 , + 0xb071,0x3d5b ,0xb02d,0x3d3f ,0xafeb,0x3d21 , + 0xafa9,0x3d03 ,0xaf68,0x3ce4 ,0xaf28,0x3cc5 , + 0xaee8,0x3ca5 ,0xaea9,0x3c85 ,0xae6b,0x3c64 , + 0xae2e,0x3c42 ,0xadf2,0x3c20 ,0xadb6,0x3bfd , + 0xad7b,0x3bda ,0xad41,0x3bb6 ,0xad08,0x3b92 , + 0xacd0,0x3b6d ,0xac98,0x3b47 ,0xac61,0x3b21 , + 0xac2b,0x3afa ,0xabf6,0x3ad3 ,0xabc2,0x3aab , + 0xab8e,0x3a82 ,0xab5b,0x3a59 ,0xab29,0x3a30 , + 0xaaf8,0x3a06 ,0xaac8,0x39db ,0xaa98,0x39b0 , + 0xaa6a,0x3984 ,0xaa3c,0x3958 ,0xaa0f,0x392b , + 0xa9e3,0x38fd ,0xa9b7,0x38cf ,0xa98d,0x38a1 , + 0xa963,0x3871 ,0xa93a,0x3842 ,0xa912,0x3812 , + 0xa8eb,0x37e1 ,0xa8c5,0x37b0 ,0xa89f,0x377e , + 0xa87b,0x374b ,0xa857,0x3718 ,0xa834,0x36e5 , + 0xa812,0x36b1 ,0xa7f1,0x367d ,0xa7d0,0x3648 , + 0xa7b1,0x3612 ,0xa792,0x35dc ,0xa774,0x35a5 , + 0xa757,0x356e ,0xa73b,0x3537 ,0xa71f,0x34ff , + 0xa705,0x34c6 ,0xa6eb,0x348d ,0xa6d3,0x3453 , + 0xa6bb,0x3419 ,0xa6a4,0x33df ,0xa68e,0x33a3 , + 0xa678,0x3368 ,0xa664,0x332c ,0xa650,0x32ef , + 0xa63e,0x32b2 ,0xa62c,0x3274 ,0xa61b,0x3236 , + 0xa60b,0x31f8 ,0xa5fb,0x31b9 ,0xa5ed,0x3179 , + 0xa5e0,0x3139 ,0xa5d3,0x30f9 ,0xa5c7,0x30b8 , + 0xa5bc,0x3076 ,0xa5b2,0x3034 ,0xa5a9,0x2ff2 , + 0xa5a1,0x2faf ,0xa599,0x2f6c ,0xa593,0x2f28 , + 0xa58d,0x2ee4 ,0xa588,0x2e9f ,0xa585,0x2e5a , + 0xa581,0x2e15 ,0xa57f,0x2dcf ,0xa57e,0x2d88 , + 0xa57e,0x2d41 ,0xa57e,0x2cfa ,0xa57f,0x2cb2 , + 0xa581,0x2c6a ,0xa585,0x2c21 ,0xa588,0x2bd8 , + 0xa58d,0x2b8f ,0xa593,0x2b45 ,0xa599,0x2afb , + 0xa5a1,0x2ab0 ,0xa5a9,0x2a65 ,0xa5b2,0x2a1a , + 0xa5bc,0x29ce ,0xa5c7,0x2981 ,0xa5d3,0x2935 , + 0xa5e0,0x28e7 ,0xa5ed,0x289a ,0xa5fb,0x284c , + 0xa60b,0x27fe ,0xa61b,0x27af ,0xa62c,0x2760 , + 0xa63e,0x2711 ,0xa650,0x26c1 ,0xa664,0x2671 , + 0xa678,0x2620 ,0xa68e,0x25cf ,0xa6a4,0x257e , + 0xa6bb,0x252c ,0xa6d3,0x24da ,0xa6eb,0x2488 , + 0xa705,0x2435 ,0xa71f,0x23e2 ,0xa73b,0x238e , + 0xa757,0x233b ,0xa774,0x22e7 ,0xa792,0x2292 , + 0xa7b1,0x223d ,0xa7d0,0x21e8 ,0xa7f1,0x2193 , + 0xa812,0x213d ,0xa834,0x20e7 ,0xa857,0x2091 , + 0xa87b,0x203a ,0xa89f,0x1fe3 ,0xa8c5,0x1f8c , + 0xa8eb,0x1f34 ,0xa912,0x1edc ,0xa93a,0x1e84 , + 0xa963,0x1e2b ,0xa98d,0x1dd3 ,0xa9b7,0x1d79 , + 0xa9e3,0x1d20 ,0xaa0f,0x1cc6 ,0xaa3c,0x1c6c , + 0xaa6a,0x1c12 ,0xaa98,0x1bb8 ,0xaac8,0x1b5d , + 0xaaf8,0x1b02 ,0xab29,0x1aa7 ,0xab5b,0x1a4b , + 0xab8e,0x19ef ,0xabc2,0x1993 ,0xabf6,0x1937 , + 0xac2b,0x18db ,0xac61,0x187e ,0xac98,0x1821 , + 0xacd0,0x17c4 ,0xad08,0x1766 ,0xad41,0x1709 , + 0xad7b,0x16ab ,0xadb6,0x164c ,0xadf2,0x15ee , + 0xae2e,0x1590 ,0xae6b,0x1531 ,0xaea9,0x14d2 , + 0xaee8,0x1473 ,0xaf28,0x1413 ,0xaf68,0x13b4 , + 0xafa9,0x1354 ,0xafeb,0x12f4 ,0xb02d,0x1294 , + 0xb071,0x1234 ,0xb0b5,0x11d3 ,0xb0fa,0x1173 , + 0xb140,0x1112 ,0xb186,0x10b1 ,0xb1cd,0x1050 , + 0xb215,0x0fee ,0xb25e,0x0f8d ,0xb2a7,0x0f2b , + 0xb2f2,0x0eca ,0xb33d,0x0e68 ,0xb388,0x0e06 , + 0xb3d5,0x0da4 ,0xb422,0x0d41 ,0xb470,0x0cdf , + 0xb4be,0x0c7c ,0xb50e,0x0c1a ,0xb55e,0x0bb7 , + 0xb5af,0x0b54 ,0xb600,0x0af1 ,0xb652,0x0a8e , + 0xb6a5,0x0a2b ,0xb6f9,0x09c7 ,0xb74d,0x0964 , + 0xb7a2,0x0901 ,0xb7f8,0x089d ,0xb84f,0x0839 , + 0xb8a6,0x07d6 ,0xb8fd,0x0772 ,0xb956,0x070e , + 0xb9af,0x06aa ,0xba09,0x0646 ,0xba64,0x05e2 , + 0xbabf,0x057e ,0xbb1b,0x051a ,0xbb77,0x04b5 , + 0xbbd4,0x0451 ,0xbc32,0x03ed ,0xbc91,0x0388 , + 0xbcf0,0x0324 ,0xbd50,0x02c0 ,0xbdb0,0x025b , + 0xbe11,0x01f7 ,0xbe73,0x0192 ,0xbed5,0x012e , + 0xbf38,0x00c9 ,0xbf9c,0x0065 }; + + +extern const int s_Q14R_8; +const int s_Q14R_8 = 1024; +extern const unsigned short t_Q14R_8[2032]; +const unsigned short t_Q14R_8[2032] = { + 0x4000,0x0000 ,0x4000,0x0000 ,0x4000,0x0000 , + 0x3b21,0x187e ,0x3ec5,0x0c7c ,0x3537,0x238e , + 0x2d41,0x2d41 ,0x3b21,0x187e ,0x187e,0x3b21 , + 0x187e,0x3b21 ,0x3537,0x238e ,0xf384,0x3ec5 , + 0x0000,0x4000 ,0x2d41,0x2d41 ,0xd2bf,0x2d41 , + 0xe782,0x3b21 ,0x238e,0x3537 ,0xc13b,0x0c7c , + 0xd2bf,0x2d41 ,0x187e,0x3b21 ,0xc4df,0xe782 , + 0xc4df,0x187e ,0x0c7c,0x3ec5 ,0xdc72,0xcac9 , + 0x4000,0x0000 ,0x4000,0x0000 ,0x4000,0x0000 , + 0x3fb1,0x0646 ,0x3fec,0x0324 ,0x3f4f,0x0964 , + 0x3ec5,0x0c7c ,0x3fb1,0x0646 ,0x3d3f,0x1294 , + 0x3d3f,0x1294 ,0x3f4f,0x0964 ,0x39db,0x1b5d , + 0x3b21,0x187e ,0x3ec5,0x0c7c ,0x3537,0x238e , + 0x3871,0x1e2b ,0x3e15,0x0f8d ,0x2f6c,0x2afb , + 0x3537,0x238e ,0x3d3f,0x1294 ,0x289a,0x3179 , + 0x3179,0x289a ,0x3c42,0x1590 ,0x20e7,0x36e5 , + 0x2d41,0x2d41 ,0x3b21,0x187e ,0x187e,0x3b21 , + 0x289a,0x3179 ,0x39db,0x1b5d ,0x0f8d,0x3e15 , + 0x238e,0x3537 ,0x3871,0x1e2b ,0x0646,0x3fb1 , + 0x1e2b,0x3871 ,0x36e5,0x20e7 ,0xfcdc,0x3fec , + 0x187e,0x3b21 ,0x3537,0x238e ,0xf384,0x3ec5 , + 0x1294,0x3d3f ,0x3368,0x2620 ,0xea70,0x3c42 , + 0x0c7c,0x3ec5 ,0x3179,0x289a ,0xe1d5,0x3871 , + 0x0646,0x3fb1 ,0x2f6c,0x2afb ,0xd9e0,0x3368 , + 0x0000,0x4000 ,0x2d41,0x2d41 ,0xd2bf,0x2d41 , + 0xf9ba,0x3fb1 ,0x2afb,0x2f6c ,0xcc98,0x2620 , + 0xf384,0x3ec5 ,0x289a,0x3179 ,0xc78f,0x1e2b , + 0xed6c,0x3d3f ,0x2620,0x3368 ,0xc3be,0x1590 , + 0xe782,0x3b21 ,0x238e,0x3537 ,0xc13b,0x0c7c , + 0xe1d5,0x3871 ,0x20e7,0x36e5 ,0xc014,0x0324 , + 0xdc72,0x3537 ,0x1e2b,0x3871 ,0xc04f,0xf9ba , + 0xd766,0x3179 ,0x1b5d,0x39db ,0xc1eb,0xf073 , + 0xd2bf,0x2d41 ,0x187e,0x3b21 ,0xc4df,0xe782 , + 0xce87,0x289a ,0x1590,0x3c42 ,0xc91b,0xdf19 , + 0xcac9,0x238e ,0x1294,0x3d3f ,0xce87,0xd766 , + 0xc78f,0x1e2b ,0x0f8d,0x3e15 ,0xd505,0xd094 , + 0xc4df,0x187e ,0x0c7c,0x3ec5 ,0xdc72,0xcac9 , + 0xc2c1,0x1294 ,0x0964,0x3f4f ,0xe4a3,0xc625 , + 0xc13b,0x0c7c ,0x0646,0x3fb1 ,0xed6c,0xc2c1 , + 0xc04f,0x0646 ,0x0324,0x3fec ,0xf69c,0xc0b1 , + 0x4000,0x0000 ,0x4000,0x0000 ,0x4000,0x0000 , + 0x3ffb,0x0192 ,0x3fff,0x00c9 ,0x3ff5,0x025b , + 0x3fec,0x0324 ,0x3ffb,0x0192 ,0x3fd4,0x04b5 , + 0x3fd4,0x04b5 ,0x3ff5,0x025b ,0x3f9c,0x070e , + 0x3fb1,0x0646 ,0x3fec,0x0324 ,0x3f4f,0x0964 , + 0x3f85,0x07d6 ,0x3fe1,0x03ed ,0x3eeb,0x0bb7 , + 0x3f4f,0x0964 ,0x3fd4,0x04b5 ,0x3e72,0x0e06 , + 0x3f0f,0x0af1 ,0x3fc4,0x057e ,0x3de3,0x1050 , + 0x3ec5,0x0c7c ,0x3fb1,0x0646 ,0x3d3f,0x1294 , + 0x3e72,0x0e06 ,0x3f9c,0x070e ,0x3c85,0x14d2 , + 0x3e15,0x0f8d ,0x3f85,0x07d6 ,0x3bb6,0x1709 , + 0x3daf,0x1112 ,0x3f6b,0x089d ,0x3ad3,0x1937 , + 0x3d3f,0x1294 ,0x3f4f,0x0964 ,0x39db,0x1b5d , + 0x3cc5,0x1413 ,0x3f30,0x0a2b ,0x38cf,0x1d79 , + 0x3c42,0x1590 ,0x3f0f,0x0af1 ,0x37b0,0x1f8c , + 0x3bb6,0x1709 ,0x3eeb,0x0bb7 ,0x367d,0x2193 , + 0x3b21,0x187e ,0x3ec5,0x0c7c ,0x3537,0x238e , + 0x3a82,0x19ef ,0x3e9d,0x0d41 ,0x33df,0x257e , + 0x39db,0x1b5d ,0x3e72,0x0e06 ,0x3274,0x2760 , + 0x392b,0x1cc6 ,0x3e45,0x0eca ,0x30f9,0x2935 , + 0x3871,0x1e2b ,0x3e15,0x0f8d ,0x2f6c,0x2afb , + 0x37b0,0x1f8c ,0x3de3,0x1050 ,0x2dcf,0x2cb2 , + 0x36e5,0x20e7 ,0x3daf,0x1112 ,0x2c21,0x2e5a , + 0x3612,0x223d ,0x3d78,0x11d3 ,0x2a65,0x2ff2 , + 0x3537,0x238e ,0x3d3f,0x1294 ,0x289a,0x3179 , + 0x3453,0x24da ,0x3d03,0x1354 ,0x26c1,0x32ef , + 0x3368,0x2620 ,0x3cc5,0x1413 ,0x24da,0x3453 , + 0x3274,0x2760 ,0x3c85,0x14d2 ,0x22e7,0x35a5 , + 0x3179,0x289a ,0x3c42,0x1590 ,0x20e7,0x36e5 , + 0x3076,0x29ce ,0x3bfd,0x164c ,0x1edc,0x3812 , + 0x2f6c,0x2afb ,0x3bb6,0x1709 ,0x1cc6,0x392b , + 0x2e5a,0x2c21 ,0x3b6d,0x17c4 ,0x1aa7,0x3a30 , + 0x2d41,0x2d41 ,0x3b21,0x187e ,0x187e,0x3b21 , + 0x2c21,0x2e5a ,0x3ad3,0x1937 ,0x164c,0x3bfd , + 0x2afb,0x2f6c ,0x3a82,0x19ef ,0x1413,0x3cc5 , + 0x29ce,0x3076 ,0x3a30,0x1aa7 ,0x11d3,0x3d78 , + 0x289a,0x3179 ,0x39db,0x1b5d ,0x0f8d,0x3e15 , + 0x2760,0x3274 ,0x3984,0x1c12 ,0x0d41,0x3e9d , + 0x2620,0x3368 ,0x392b,0x1cc6 ,0x0af1,0x3f0f , + 0x24da,0x3453 ,0x38cf,0x1d79 ,0x089d,0x3f6b , + 0x238e,0x3537 ,0x3871,0x1e2b ,0x0646,0x3fb1 , + 0x223d,0x3612 ,0x3812,0x1edc ,0x03ed,0x3fe1 , + 0x20e7,0x36e5 ,0x37b0,0x1f8c ,0x0192,0x3ffb , + 0x1f8c,0x37b0 ,0x374b,0x203a ,0xff37,0x3fff , + 0x1e2b,0x3871 ,0x36e5,0x20e7 ,0xfcdc,0x3fec , + 0x1cc6,0x392b ,0x367d,0x2193 ,0xfa82,0x3fc4 , + 0x1b5d,0x39db ,0x3612,0x223d ,0xf82a,0x3f85 , + 0x19ef,0x3a82 ,0x35a5,0x22e7 ,0xf5d5,0x3f30 , + 0x187e,0x3b21 ,0x3537,0x238e ,0xf384,0x3ec5 , + 0x1709,0x3bb6 ,0x34c6,0x2435 ,0xf136,0x3e45 , + 0x1590,0x3c42 ,0x3453,0x24da ,0xeeee,0x3daf , + 0x1413,0x3cc5 ,0x33df,0x257e ,0xecac,0x3d03 , + 0x1294,0x3d3f ,0x3368,0x2620 ,0xea70,0x3c42 , + 0x1112,0x3daf ,0x32ef,0x26c1 ,0xe83c,0x3b6d , + 0x0f8d,0x3e15 ,0x3274,0x2760 ,0xe611,0x3a82 , + 0x0e06,0x3e72 ,0x31f8,0x27fe ,0xe3ee,0x3984 , + 0x0c7c,0x3ec5 ,0x3179,0x289a ,0xe1d5,0x3871 , + 0x0af1,0x3f0f ,0x30f9,0x2935 ,0xdfc6,0x374b , + 0x0964,0x3f4f ,0x3076,0x29ce ,0xddc3,0x3612 , + 0x07d6,0x3f85 ,0x2ff2,0x2a65 ,0xdbcb,0x34c6 , + 0x0646,0x3fb1 ,0x2f6c,0x2afb ,0xd9e0,0x3368 , + 0x04b5,0x3fd4 ,0x2ee4,0x2b8f ,0xd802,0x31f8 , + 0x0324,0x3fec ,0x2e5a,0x2c21 ,0xd632,0x3076 , + 0x0192,0x3ffb ,0x2dcf,0x2cb2 ,0xd471,0x2ee4 , + 0x0000,0x4000 ,0x2d41,0x2d41 ,0xd2bf,0x2d41 , + 0xfe6e,0x3ffb ,0x2cb2,0x2dcf ,0xd11c,0x2b8f , + 0xfcdc,0x3fec ,0x2c21,0x2e5a ,0xcf8a,0x29ce , + 0xfb4b,0x3fd4 ,0x2b8f,0x2ee4 ,0xce08,0x27fe , + 0xf9ba,0x3fb1 ,0x2afb,0x2f6c ,0xcc98,0x2620 , + 0xf82a,0x3f85 ,0x2a65,0x2ff2 ,0xcb3a,0x2435 , + 0xf69c,0x3f4f ,0x29ce,0x3076 ,0xc9ee,0x223d , + 0xf50f,0x3f0f ,0x2935,0x30f9 ,0xc8b5,0x203a , + 0xf384,0x3ec5 ,0x289a,0x3179 ,0xc78f,0x1e2b , + 0xf1fa,0x3e72 ,0x27fe,0x31f8 ,0xc67c,0x1c12 , + 0xf073,0x3e15 ,0x2760,0x3274 ,0xc57e,0x19ef , + 0xeeee,0x3daf ,0x26c1,0x32ef ,0xc493,0x17c4 , + 0xed6c,0x3d3f ,0x2620,0x3368 ,0xc3be,0x1590 , + 0xebed,0x3cc5 ,0x257e,0x33df ,0xc2fd,0x1354 , + 0xea70,0x3c42 ,0x24da,0x3453 ,0xc251,0x1112 , + 0xe8f7,0x3bb6 ,0x2435,0x34c6 ,0xc1bb,0x0eca , + 0xe782,0x3b21 ,0x238e,0x3537 ,0xc13b,0x0c7c , + 0xe611,0x3a82 ,0x22e7,0x35a5 ,0xc0d0,0x0a2b , + 0xe4a3,0x39db ,0x223d,0x3612 ,0xc07b,0x07d6 , + 0xe33a,0x392b ,0x2193,0x367d ,0xc03c,0x057e , + 0xe1d5,0x3871 ,0x20e7,0x36e5 ,0xc014,0x0324 , + 0xe074,0x37b0 ,0x203a,0x374b ,0xc001,0x00c9 , + 0xdf19,0x36e5 ,0x1f8c,0x37b0 ,0xc005,0xfe6e , + 0xddc3,0x3612 ,0x1edc,0x3812 ,0xc01f,0xfc13 , + 0xdc72,0x3537 ,0x1e2b,0x3871 ,0xc04f,0xf9ba , + 0xdb26,0x3453 ,0x1d79,0x38cf ,0xc095,0xf763 , + 0xd9e0,0x3368 ,0x1cc6,0x392b ,0xc0f1,0xf50f , + 0xd8a0,0x3274 ,0x1c12,0x3984 ,0xc163,0xf2bf , + 0xd766,0x3179 ,0x1b5d,0x39db ,0xc1eb,0xf073 , + 0xd632,0x3076 ,0x1aa7,0x3a30 ,0xc288,0xee2d , + 0xd505,0x2f6c ,0x19ef,0x3a82 ,0xc33b,0xebed , + 0xd3df,0x2e5a ,0x1937,0x3ad3 ,0xc403,0xe9b4 , + 0xd2bf,0x2d41 ,0x187e,0x3b21 ,0xc4df,0xe782 , + 0xd1a6,0x2c21 ,0x17c4,0x3b6d ,0xc5d0,0xe559 , + 0xd094,0x2afb ,0x1709,0x3bb6 ,0xc6d5,0xe33a , + 0xcf8a,0x29ce ,0x164c,0x3bfd ,0xc7ee,0xe124 , + 0xce87,0x289a ,0x1590,0x3c42 ,0xc91b,0xdf19 , + 0xcd8c,0x2760 ,0x14d2,0x3c85 ,0xca5b,0xdd19 , + 0xcc98,0x2620 ,0x1413,0x3cc5 ,0xcbad,0xdb26 , + 0xcbad,0x24da ,0x1354,0x3d03 ,0xcd11,0xd93f , + 0xcac9,0x238e ,0x1294,0x3d3f ,0xce87,0xd766 , + 0xc9ee,0x223d ,0x11d3,0x3d78 ,0xd00e,0xd59b , + 0xc91b,0x20e7 ,0x1112,0x3daf ,0xd1a6,0xd3df , + 0xc850,0x1f8c ,0x1050,0x3de3 ,0xd34e,0xd231 , + 0xc78f,0x1e2b ,0x0f8d,0x3e15 ,0xd505,0xd094 , + 0xc6d5,0x1cc6 ,0x0eca,0x3e45 ,0xd6cb,0xcf07 , + 0xc625,0x1b5d ,0x0e06,0x3e72 ,0xd8a0,0xcd8c , + 0xc57e,0x19ef ,0x0d41,0x3e9d ,0xda82,0xcc21 , + 0xc4df,0x187e ,0x0c7c,0x3ec5 ,0xdc72,0xcac9 , + 0xc44a,0x1709 ,0x0bb7,0x3eeb ,0xde6d,0xc983 , + 0xc3be,0x1590 ,0x0af1,0x3f0f ,0xe074,0xc850 , + 0xc33b,0x1413 ,0x0a2b,0x3f30 ,0xe287,0xc731 , + 0xc2c1,0x1294 ,0x0964,0x3f4f ,0xe4a3,0xc625 , + 0xc251,0x1112 ,0x089d,0x3f6b ,0xe6c9,0xc52d , + 0xc1eb,0x0f8d ,0x07d6,0x3f85 ,0xe8f7,0xc44a , + 0xc18e,0x0e06 ,0x070e,0x3f9c ,0xeb2e,0xc37b , + 0xc13b,0x0c7c ,0x0646,0x3fb1 ,0xed6c,0xc2c1 , + 0xc0f1,0x0af1 ,0x057e,0x3fc4 ,0xefb0,0xc21d , + 0xc0b1,0x0964 ,0x04b5,0x3fd4 ,0xf1fa,0xc18e , + 0xc07b,0x07d6 ,0x03ed,0x3fe1 ,0xf449,0xc115 , + 0xc04f,0x0646 ,0x0324,0x3fec ,0xf69c,0xc0b1 , + 0xc02c,0x04b5 ,0x025b,0x3ff5 ,0xf8f2,0xc064 , + 0xc014,0x0324 ,0x0192,0x3ffb ,0xfb4b,0xc02c , + 0xc005,0x0192 ,0x00c9,0x3fff ,0xfda5,0xc00b , + 0x4000,0x0000 ,0x4000,0x0065 ,0x3fff,0x00c9 , + 0x3ffd,0x012e ,0x3ffb,0x0192 ,0x3ff8,0x01f7 , + 0x3ff5,0x025b ,0x3ff1,0x02c0 ,0x3fec,0x0324 , + 0x3fe7,0x0388 ,0x3fe1,0x03ed ,0x3fdb,0x0451 , + 0x3fd4,0x04b5 ,0x3fcc,0x051a ,0x3fc4,0x057e , + 0x3fbb,0x05e2 ,0x3fb1,0x0646 ,0x3fa7,0x06aa , + 0x3f9c,0x070e ,0x3f91,0x0772 ,0x3f85,0x07d6 , + 0x3f78,0x0839 ,0x3f6b,0x089d ,0x3f5d,0x0901 , + 0x3f4f,0x0964 ,0x3f40,0x09c7 ,0x3f30,0x0a2b , + 0x3f20,0x0a8e ,0x3f0f,0x0af1 ,0x3efd,0x0b54 , + 0x3eeb,0x0bb7 ,0x3ed8,0x0c1a ,0x3ec5,0x0c7c , + 0x3eb1,0x0cdf ,0x3e9d,0x0d41 ,0x3e88,0x0da4 , + 0x3e72,0x0e06 ,0x3e5c,0x0e68 ,0x3e45,0x0eca , + 0x3e2d,0x0f2b ,0x3e15,0x0f8d ,0x3dfc,0x0fee , + 0x3de3,0x1050 ,0x3dc9,0x10b1 ,0x3daf,0x1112 , + 0x3d93,0x1173 ,0x3d78,0x11d3 ,0x3d5b,0x1234 , + 0x3d3f,0x1294 ,0x3d21,0x12f4 ,0x3d03,0x1354 , + 0x3ce4,0x13b4 ,0x3cc5,0x1413 ,0x3ca5,0x1473 , + 0x3c85,0x14d2 ,0x3c64,0x1531 ,0x3c42,0x1590 , + 0x3c20,0x15ee ,0x3bfd,0x164c ,0x3bda,0x16ab , + 0x3bb6,0x1709 ,0x3b92,0x1766 ,0x3b6d,0x17c4 , + 0x3b47,0x1821 ,0x3b21,0x187e ,0x3afa,0x18db , + 0x3ad3,0x1937 ,0x3aab,0x1993 ,0x3a82,0x19ef , + 0x3a59,0x1a4b ,0x3a30,0x1aa7 ,0x3a06,0x1b02 , + 0x39db,0x1b5d ,0x39b0,0x1bb8 ,0x3984,0x1c12 , + 0x3958,0x1c6c ,0x392b,0x1cc6 ,0x38fd,0x1d20 , + 0x38cf,0x1d79 ,0x38a1,0x1dd3 ,0x3871,0x1e2b , + 0x3842,0x1e84 ,0x3812,0x1edc ,0x37e1,0x1f34 , + 0x37b0,0x1f8c ,0x377e,0x1fe3 ,0x374b,0x203a , + 0x3718,0x2091 ,0x36e5,0x20e7 ,0x36b1,0x213d , + 0x367d,0x2193 ,0x3648,0x21e8 ,0x3612,0x223d , + 0x35dc,0x2292 ,0x35a5,0x22e7 ,0x356e,0x233b , + 0x3537,0x238e ,0x34ff,0x23e2 ,0x34c6,0x2435 , + 0x348d,0x2488 ,0x3453,0x24da ,0x3419,0x252c , + 0x33df,0x257e ,0x33a3,0x25cf ,0x3368,0x2620 , + 0x332c,0x2671 ,0x32ef,0x26c1 ,0x32b2,0x2711 , + 0x3274,0x2760 ,0x3236,0x27af ,0x31f8,0x27fe , + 0x31b9,0x284c ,0x3179,0x289a ,0x3139,0x28e7 , + 0x30f9,0x2935 ,0x30b8,0x2981 ,0x3076,0x29ce , + 0x3034,0x2a1a ,0x2ff2,0x2a65 ,0x2faf,0x2ab0 , + 0x2f6c,0x2afb ,0x2f28,0x2b45 ,0x2ee4,0x2b8f , + 0x2e9f,0x2bd8 ,0x2e5a,0x2c21 ,0x2e15,0x2c6a , + 0x2dcf,0x2cb2 ,0x2d88,0x2cfa ,0x2d41,0x2d41 , + 0x2cfa,0x2d88 ,0x2cb2,0x2dcf ,0x2c6a,0x2e15 , + 0x2c21,0x2e5a ,0x2bd8,0x2e9f ,0x2b8f,0x2ee4 , + 0x2b45,0x2f28 ,0x2afb,0x2f6c ,0x2ab0,0x2faf , + 0x2a65,0x2ff2 ,0x2a1a,0x3034 ,0x29ce,0x3076 , + 0x2981,0x30b8 ,0x2935,0x30f9 ,0x28e7,0x3139 , + 0x289a,0x3179 ,0x284c,0x31b9 ,0x27fe,0x31f8 , + 0x27af,0x3236 ,0x2760,0x3274 ,0x2711,0x32b2 , + 0x26c1,0x32ef ,0x2671,0x332c ,0x2620,0x3368 , + 0x25cf,0x33a3 ,0x257e,0x33df ,0x252c,0x3419 , + 0x24da,0x3453 ,0x2488,0x348d ,0x2435,0x34c6 , + 0x23e2,0x34ff ,0x238e,0x3537 ,0x233b,0x356e , + 0x22e7,0x35a5 ,0x2292,0x35dc ,0x223d,0x3612 , + 0x21e8,0x3648 ,0x2193,0x367d ,0x213d,0x36b1 , + 0x20e7,0x36e5 ,0x2091,0x3718 ,0x203a,0x374b , + 0x1fe3,0x377e ,0x1f8c,0x37b0 ,0x1f34,0x37e1 , + 0x1edc,0x3812 ,0x1e84,0x3842 ,0x1e2b,0x3871 , + 0x1dd3,0x38a1 ,0x1d79,0x38cf ,0x1d20,0x38fd , + 0x1cc6,0x392b ,0x1c6c,0x3958 ,0x1c12,0x3984 , + 0x1bb8,0x39b0 ,0x1b5d,0x39db ,0x1b02,0x3a06 , + 0x1aa7,0x3a30 ,0x1a4b,0x3a59 ,0x19ef,0x3a82 , + 0x1993,0x3aab ,0x1937,0x3ad3 ,0x18db,0x3afa , + 0x187e,0x3b21 ,0x1821,0x3b47 ,0x17c4,0x3b6d , + 0x1766,0x3b92 ,0x1709,0x3bb6 ,0x16ab,0x3bda , + 0x164c,0x3bfd ,0x15ee,0x3c20 ,0x1590,0x3c42 , + 0x1531,0x3c64 ,0x14d2,0x3c85 ,0x1473,0x3ca5 , + 0x1413,0x3cc5 ,0x13b4,0x3ce4 ,0x1354,0x3d03 , + 0x12f4,0x3d21 ,0x1294,0x3d3f ,0x1234,0x3d5b , + 0x11d3,0x3d78 ,0x1173,0x3d93 ,0x1112,0x3daf , + 0x10b1,0x3dc9 ,0x1050,0x3de3 ,0x0fee,0x3dfc , + 0x0f8d,0x3e15 ,0x0f2b,0x3e2d ,0x0eca,0x3e45 , + 0x0e68,0x3e5c ,0x0e06,0x3e72 ,0x0da4,0x3e88 , + 0x0d41,0x3e9d ,0x0cdf,0x3eb1 ,0x0c7c,0x3ec5 , + 0x0c1a,0x3ed8 ,0x0bb7,0x3eeb ,0x0b54,0x3efd , + 0x0af1,0x3f0f ,0x0a8e,0x3f20 ,0x0a2b,0x3f30 , + 0x09c7,0x3f40 ,0x0964,0x3f4f ,0x0901,0x3f5d , + 0x089d,0x3f6b ,0x0839,0x3f78 ,0x07d6,0x3f85 , + 0x0772,0x3f91 ,0x070e,0x3f9c ,0x06aa,0x3fa7 , + 0x0646,0x3fb1 ,0x05e2,0x3fbb ,0x057e,0x3fc4 , + 0x051a,0x3fcc ,0x04b5,0x3fd4 ,0x0451,0x3fdb , + 0x03ed,0x3fe1 ,0x0388,0x3fe7 ,0x0324,0x3fec , + 0x02c0,0x3ff1 ,0x025b,0x3ff5 ,0x01f7,0x3ff8 , + 0x0192,0x3ffb ,0x012e,0x3ffd ,0x00c9,0x3fff , + 0x0065,0x4000 ,0x0000,0x4000 ,0xff9b,0x4000 , + 0xff37,0x3fff ,0xfed2,0x3ffd ,0xfe6e,0x3ffb , + 0xfe09,0x3ff8 ,0xfda5,0x3ff5 ,0xfd40,0x3ff1 , + 0xfcdc,0x3fec ,0xfc78,0x3fe7 ,0xfc13,0x3fe1 , + 0xfbaf,0x3fdb ,0xfb4b,0x3fd4 ,0xfae6,0x3fcc , + 0xfa82,0x3fc4 ,0xfa1e,0x3fbb ,0xf9ba,0x3fb1 , + 0xf956,0x3fa7 ,0xf8f2,0x3f9c ,0xf88e,0x3f91 , + 0xf82a,0x3f85 ,0xf7c7,0x3f78 ,0xf763,0x3f6b , + 0xf6ff,0x3f5d ,0xf69c,0x3f4f ,0xf639,0x3f40 , + 0xf5d5,0x3f30 ,0xf572,0x3f20 ,0xf50f,0x3f0f , + 0xf4ac,0x3efd ,0xf449,0x3eeb ,0xf3e6,0x3ed8 , + 0xf384,0x3ec5 ,0xf321,0x3eb1 ,0xf2bf,0x3e9d , + 0xf25c,0x3e88 ,0xf1fa,0x3e72 ,0xf198,0x3e5c , + 0xf136,0x3e45 ,0xf0d5,0x3e2d ,0xf073,0x3e15 , + 0xf012,0x3dfc ,0xefb0,0x3de3 ,0xef4f,0x3dc9 , + 0xeeee,0x3daf ,0xee8d,0x3d93 ,0xee2d,0x3d78 , + 0xedcc,0x3d5b ,0xed6c,0x3d3f ,0xed0c,0x3d21 , + 0xecac,0x3d03 ,0xec4c,0x3ce4 ,0xebed,0x3cc5 , + 0xeb8d,0x3ca5 ,0xeb2e,0x3c85 ,0xeacf,0x3c64 , + 0xea70,0x3c42 ,0xea12,0x3c20 ,0xe9b4,0x3bfd , + 0xe955,0x3bda ,0xe8f7,0x3bb6 ,0xe89a,0x3b92 , + 0xe83c,0x3b6d ,0xe7df,0x3b47 ,0xe782,0x3b21 , + 0xe725,0x3afa ,0xe6c9,0x3ad3 ,0xe66d,0x3aab , + 0xe611,0x3a82 ,0xe5b5,0x3a59 ,0xe559,0x3a30 , + 0xe4fe,0x3a06 ,0xe4a3,0x39db ,0xe448,0x39b0 , + 0xe3ee,0x3984 ,0xe394,0x3958 ,0xe33a,0x392b , + 0xe2e0,0x38fd ,0xe287,0x38cf ,0xe22d,0x38a1 , + 0xe1d5,0x3871 ,0xe17c,0x3842 ,0xe124,0x3812 , + 0xe0cc,0x37e1 ,0xe074,0x37b0 ,0xe01d,0x377e , + 0xdfc6,0x374b ,0xdf6f,0x3718 ,0xdf19,0x36e5 , + 0xdec3,0x36b1 ,0xde6d,0x367d ,0xde18,0x3648 , + 0xddc3,0x3612 ,0xdd6e,0x35dc ,0xdd19,0x35a5 , + 0xdcc5,0x356e ,0xdc72,0x3537 ,0xdc1e,0x34ff , + 0xdbcb,0x34c6 ,0xdb78,0x348d ,0xdb26,0x3453 , + 0xdad4,0x3419 ,0xda82,0x33df ,0xda31,0x33a3 , + 0xd9e0,0x3368 ,0xd98f,0x332c ,0xd93f,0x32ef , + 0xd8ef,0x32b2 ,0xd8a0,0x3274 ,0xd851,0x3236 , + 0xd802,0x31f8 ,0xd7b4,0x31b9 ,0xd766,0x3179 , + 0xd719,0x3139 ,0xd6cb,0x30f9 ,0xd67f,0x30b8 , + 0xd632,0x3076 ,0xd5e6,0x3034 ,0xd59b,0x2ff2 , + 0xd550,0x2faf ,0xd505,0x2f6c ,0xd4bb,0x2f28 , + 0xd471,0x2ee4 ,0xd428,0x2e9f ,0xd3df,0x2e5a , + 0xd396,0x2e15 ,0xd34e,0x2dcf ,0xd306,0x2d88 , + 0xd2bf,0x2d41 ,0xd278,0x2cfa ,0xd231,0x2cb2 , + 0xd1eb,0x2c6a ,0xd1a6,0x2c21 ,0xd161,0x2bd8 , + 0xd11c,0x2b8f ,0xd0d8,0x2b45 ,0xd094,0x2afb , + 0xd051,0x2ab0 ,0xd00e,0x2a65 ,0xcfcc,0x2a1a , + 0xcf8a,0x29ce ,0xcf48,0x2981 ,0xcf07,0x2935 , + 0xcec7,0x28e7 ,0xce87,0x289a ,0xce47,0x284c , + 0xce08,0x27fe ,0xcdca,0x27af ,0xcd8c,0x2760 , + 0xcd4e,0x2711 ,0xcd11,0x26c1 ,0xccd4,0x2671 , + 0xcc98,0x2620 ,0xcc5d,0x25cf ,0xcc21,0x257e , + 0xcbe7,0x252c ,0xcbad,0x24da ,0xcb73,0x2488 , + 0xcb3a,0x2435 ,0xcb01,0x23e2 ,0xcac9,0x238e , + 0xca92,0x233b ,0xca5b,0x22e7 ,0xca24,0x2292 , + 0xc9ee,0x223d ,0xc9b8,0x21e8 ,0xc983,0x2193 , + 0xc94f,0x213d ,0xc91b,0x20e7 ,0xc8e8,0x2091 , + 0xc8b5,0x203a ,0xc882,0x1fe3 ,0xc850,0x1f8c , + 0xc81f,0x1f34 ,0xc7ee,0x1edc ,0xc7be,0x1e84 , + 0xc78f,0x1e2b ,0xc75f,0x1dd3 ,0xc731,0x1d79 , + 0xc703,0x1d20 ,0xc6d5,0x1cc6 ,0xc6a8,0x1c6c , + 0xc67c,0x1c12 ,0xc650,0x1bb8 ,0xc625,0x1b5d , + 0xc5fa,0x1b02 ,0xc5d0,0x1aa7 ,0xc5a7,0x1a4b , + 0xc57e,0x19ef ,0xc555,0x1993 ,0xc52d,0x1937 , + 0xc506,0x18db ,0xc4df,0x187e ,0xc4b9,0x1821 , + 0xc493,0x17c4 ,0xc46e,0x1766 ,0xc44a,0x1709 , + 0xc426,0x16ab ,0xc403,0x164c ,0xc3e0,0x15ee , + 0xc3be,0x1590 ,0xc39c,0x1531 ,0xc37b,0x14d2 , + 0xc35b,0x1473 ,0xc33b,0x1413 ,0xc31c,0x13b4 , + 0xc2fd,0x1354 ,0xc2df,0x12f4 ,0xc2c1,0x1294 , + 0xc2a5,0x1234 ,0xc288,0x11d3 ,0xc26d,0x1173 , + 0xc251,0x1112 ,0xc237,0x10b1 ,0xc21d,0x1050 , + 0xc204,0x0fee ,0xc1eb,0x0f8d ,0xc1d3,0x0f2b , + 0xc1bb,0x0eca ,0xc1a4,0x0e68 ,0xc18e,0x0e06 , + 0xc178,0x0da4 ,0xc163,0x0d41 ,0xc14f,0x0cdf , + 0xc13b,0x0c7c ,0xc128,0x0c1a ,0xc115,0x0bb7 , + 0xc103,0x0b54 ,0xc0f1,0x0af1 ,0xc0e0,0x0a8e , + 0xc0d0,0x0a2b ,0xc0c0,0x09c7 ,0xc0b1,0x0964 , + 0xc0a3,0x0901 ,0xc095,0x089d ,0xc088,0x0839 , + 0xc07b,0x07d6 ,0xc06f,0x0772 ,0xc064,0x070e , + 0xc059,0x06aa ,0xc04f,0x0646 ,0xc045,0x05e2 , + 0xc03c,0x057e ,0xc034,0x051a ,0xc02c,0x04b5 , + 0xc025,0x0451 ,0xc01f,0x03ed ,0xc019,0x0388 , + 0xc014,0x0324 ,0xc00f,0x02c0 ,0xc00b,0x025b , + 0xc008,0x01f7 ,0xc005,0x0192 ,0xc003,0x012e , + 0xc001,0x00c9 ,0xc000,0x0065 }; diff --git a/src/common_audio/signal_processing_library/main/source/webrtc_fft_t_rad.c b/src/common_audio/signal_processing_library/main/source/webrtc_fft_t_rad.c new file mode 100644 index 0000000..13fbd9f --- /dev/null +++ b/src/common_audio/signal_processing_library/main/source/webrtc_fft_t_rad.c @@ -0,0 +1,27 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + + +/* + * This file contains the Q14 radix-2 tables used in ARM9E optimization routines. + * + */ + +extern const unsigned short t_Q14S_rad8[2]; +const unsigned short t_Q14S_rad8[2] = { 0x0000,0x2d41 }; + +//extern const int t_Q30S_rad8[2]; +//const int t_Q30S_rad8[2] = { 0x00000000,0x2d413ccd }; + +extern const unsigned short t_Q14R_rad8[2]; +const unsigned short t_Q14R_rad8[2] = { 0x2d41,0x2d41 }; + +//extern const int t_Q30R_rad8[2]; +//const int t_Q30R_rad8[2] = { 0x2d413ccd,0x2d413ccd }; diff --git a/src/common_audio/signal_processing_library/main/test/unit_test/unit_test.cc b/src/common_audio/signal_processing_library/main/test/unit_test/unit_test.cc new file mode 100644 index 0000000..e4348eb --- /dev/null +++ b/src/common_audio/signal_processing_library/main/test/unit_test/unit_test.cc @@ -0,0 +1,494 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + + +/* + * This file contains the SPL unit_test. + * + */ + +#include "unit_test.h" +#include "signal_processing_library.h" + +class SplEnvironment : public ::testing::Environment { + public: + virtual void SetUp() { + } + virtual void TearDown() { + } +}; + +SplTest::SplTest() +{ +} + +void SplTest::SetUp() { +} + +void SplTest::TearDown() { +} + +TEST_F(SplTest, MacroTest) { + // Macros with inputs. + int A = 10; + int B = 21; + int a = -3; + int b = WEBRTC_SPL_WORD32_MAX; + int nr = 2; + int d_ptr1 = 0; + int d_ptr2 = 0; + + EXPECT_EQ(10, WEBRTC_SPL_MIN(A, B)); + EXPECT_EQ(21, WEBRTC_SPL_MAX(A, B)); + + EXPECT_EQ(3, WEBRTC_SPL_ABS_W16(a)); + EXPECT_EQ(3, WEBRTC_SPL_ABS_W32(a)); + EXPECT_EQ(0, WEBRTC_SPL_GET_BYTE(&B, nr)); + WEBRTC_SPL_SET_BYTE(&d_ptr2, 1, nr); + EXPECT_EQ(65536, d_ptr2); + + EXPECT_EQ(-63, WEBRTC_SPL_MUL(a, B)); + EXPECT_EQ(-2147483645, WEBRTC_SPL_MUL(a, b)); + EXPECT_EQ(-2147483645, WEBRTC_SPL_UMUL(a, b)); + b = WEBRTC_SPL_WORD16_MAX >> 1; + EXPECT_EQ(65535, WEBRTC_SPL_UMUL_RSFT16(a, b)); + EXPECT_EQ(1073627139, WEBRTC_SPL_UMUL_16_16(a, b)); + EXPECT_EQ(16382, WEBRTC_SPL_UMUL_16_16_RSFT16(a, b)); + EXPECT_EQ(-49149, WEBRTC_SPL_UMUL_32_16(a, b)); + EXPECT_EQ(65535, WEBRTC_SPL_UMUL_32_16_RSFT16(a, b)); + EXPECT_EQ(-49149, WEBRTC_SPL_MUL_16_U16(a, b)); + + a = b; + b = -3; + EXPECT_EQ(-5461, WEBRTC_SPL_DIV(a, b)); + EXPECT_EQ(0, WEBRTC_SPL_UDIV(a, b)); + + EXPECT_EQ(-1, WEBRTC_SPL_MUL_16_32_RSFT16(a, b)); + EXPECT_EQ(-1, WEBRTC_SPL_MUL_16_32_RSFT15(a, b)); + EXPECT_EQ(-3, WEBRTC_SPL_MUL_16_32_RSFT14(a, b)); + EXPECT_EQ(-24, WEBRTC_SPL_MUL_16_32_RSFT11(a, b)); + + int a32 = WEBRTC_SPL_WORD32_MAX; + int a32a = (WEBRTC_SPL_WORD32_MAX >> 16); + int a32b = (WEBRTC_SPL_WORD32_MAX & 0x0000ffff); + EXPECT_EQ(5, WEBRTC_SPL_MUL_32_32_RSFT32(a32a, a32b, A)); + EXPECT_EQ(5, WEBRTC_SPL_MUL_32_32_RSFT32BI(a32, A)); + + EXPECT_EQ(-49149, WEBRTC_SPL_MUL_16_16(a, b)); + EXPECT_EQ(-12288, WEBRTC_SPL_MUL_16_16_RSFT(a, b, 2)); + + EXPECT_EQ(-12287, WEBRTC_SPL_MUL_16_16_RSFT_WITH_ROUND(a, b, 2)); + EXPECT_EQ(-1, WEBRTC_SPL_MUL_16_16_RSFT_WITH_FIXROUND(a, b)); + + EXPECT_EQ(16380, WEBRTC_SPL_ADD_SAT_W32(a, b)); + EXPECT_EQ(21, WEBRTC_SPL_SAT(a, A, B)); + EXPECT_EQ(21, WEBRTC_SPL_SAT(a, B, A)); + EXPECT_EQ(-49149, WEBRTC_SPL_MUL_32_16(a, b)); + + EXPECT_EQ(16386, WEBRTC_SPL_SUB_SAT_W32(a, b)); + EXPECT_EQ(16380, WEBRTC_SPL_ADD_SAT_W16(a, b)); + EXPECT_EQ(16386, WEBRTC_SPL_SUB_SAT_W16(a, b)); + + EXPECT_TRUE(WEBRTC_SPL_IS_NEG(b)); + + // Shifting with negative numbers allowed + // Positive means left shift + EXPECT_EQ(32766, WEBRTC_SPL_SHIFT_W16(a, 1)); + EXPECT_EQ(32766, WEBRTC_SPL_SHIFT_W32(a, 1)); + + // Shifting with negative numbers not allowed + // We cannot do casting here due to signed/unsigned problem + EXPECT_EQ(8191, WEBRTC_SPL_RSHIFT_W16(a, 1)); + EXPECT_EQ(32766, WEBRTC_SPL_LSHIFT_W16(a, 1)); + EXPECT_EQ(8191, WEBRTC_SPL_RSHIFT_W32(a, 1)); + EXPECT_EQ(32766, WEBRTC_SPL_LSHIFT_W32(a, 1)); + + EXPECT_EQ(8191, WEBRTC_SPL_RSHIFT_U16(a, 1)); + EXPECT_EQ(32766, WEBRTC_SPL_LSHIFT_U16(a, 1)); + EXPECT_EQ(8191, WEBRTC_SPL_RSHIFT_U32(a, 1)); + EXPECT_EQ(32766, WEBRTC_SPL_LSHIFT_U32(a, 1)); + + EXPECT_EQ(1470, WEBRTC_SPL_RAND(A)); +} + +TEST_F(SplTest, InlineTest) { + + WebRtc_Word16 a = 121; + WebRtc_Word16 b = -17; + WebRtc_Word32 A = 111121; + WebRtc_Word32 B = -1711; + char bVersion[8]; + + EXPECT_EQ(104, WebRtcSpl_AddSatW16(a, b)); + EXPECT_EQ(138, WebRtcSpl_SubSatW16(a, b)); + + EXPECT_EQ(109410, WebRtcSpl_AddSatW32(A, B)); + EXPECT_EQ(112832, WebRtcSpl_SubSatW32(A, B)); + + EXPECT_EQ(17, WebRtcSpl_GetSizeInBits(A)); + EXPECT_EQ(14, WebRtcSpl_NormW32(A)); + EXPECT_EQ(4, WebRtcSpl_NormW16(B)); + EXPECT_EQ(15, WebRtcSpl_NormU32(A)); + + EXPECT_EQ(0, WebRtcSpl_get_version(bVersion, 8)); +} + +TEST_F(SplTest, MathOperationsTest) { + + int A = 117; + WebRtc_Word32 num = 117; + WebRtc_Word32 den = -5; + WebRtc_UWord16 denU = 5; + EXPECT_EQ(10, WebRtcSpl_Sqrt(A)); + EXPECT_EQ(10, WebRtcSpl_SqrtFloor(A)); + + + EXPECT_EQ(-91772805, WebRtcSpl_DivResultInQ31(den, num)); + EXPECT_EQ(-23, WebRtcSpl_DivW32W16ResW16(num, (WebRtc_Word16)den)); + EXPECT_EQ(-23, WebRtcSpl_DivW32W16(num, (WebRtc_Word16)den)); + EXPECT_EQ(23, WebRtcSpl_DivU32U16(num, denU)); + EXPECT_EQ(0, WebRtcSpl_DivW32HiLow(128, 0, 256)); +} + +TEST_F(SplTest, BasicArrayOperationsTest) { + + + const int kVectorSize = 4; + int B[] = {4, 12, 133, 1100}; + int Bs[] = {2, 6, 66, 550}; + WebRtc_UWord8 b8[kVectorSize]; + WebRtc_Word16 b16[kVectorSize]; + WebRtc_Word32 b32[kVectorSize]; + + WebRtc_UWord8 bTmp8[kVectorSize]; + WebRtc_Word16 bTmp16[kVectorSize]; + WebRtc_Word32 bTmp32[kVectorSize]; + + WebRtcSpl_MemSetW16(b16, 3, kVectorSize); + for (int kk = 0; kk < kVectorSize; ++kk) { + EXPECT_EQ(3, b16[kk]); + } + EXPECT_EQ(kVectorSize, WebRtcSpl_ZerosArrayW16(b16, kVectorSize)); + for (int kk = 0; kk < kVectorSize; ++kk) { + EXPECT_EQ(0, b16[kk]); + } + EXPECT_EQ(kVectorSize, WebRtcSpl_OnesArrayW16(b16, kVectorSize)); + for (int kk = 0; kk < kVectorSize; ++kk) { + EXPECT_EQ(1, b16[kk]); + } + WebRtcSpl_MemSetW32(b32, 3, kVectorSize); + for (int kk = 0; kk < kVectorSize; ++kk) { + EXPECT_EQ(3, b32[kk]); + } + EXPECT_EQ(kVectorSize, WebRtcSpl_ZerosArrayW32(b32, kVectorSize)); + for (int kk = 0; kk < kVectorSize; ++kk) { + EXPECT_EQ(0, b32[kk]); + } + EXPECT_EQ(kVectorSize, WebRtcSpl_OnesArrayW32(b32, kVectorSize)); + for (int kk = 0; kk < kVectorSize; ++kk) { + EXPECT_EQ(1, b32[kk]); + } + for (int kk = 0; kk < kVectorSize; ++kk) { + bTmp8[kk] = (WebRtc_Word8)kk; + bTmp16[kk] = (WebRtc_Word16)kk; + bTmp32[kk] = (WebRtc_Word32)kk; + } + WEBRTC_SPL_MEMCPY_W8(b8, bTmp8, kVectorSize); + for (int kk = 0; kk < kVectorSize; ++kk) { + EXPECT_EQ(b8[kk], bTmp8[kk]); + } + WEBRTC_SPL_MEMCPY_W16(b16, bTmp16, kVectorSize); + for (int kk = 0; kk < kVectorSize; ++kk) { + EXPECT_EQ(b16[kk], bTmp16[kk]); + } +// WEBRTC_SPL_MEMCPY_W32(b32, bTmp32, kVectorSize); +// for (int kk = 0; kk < kVectorSize; ++kk) { +// EXPECT_EQ(b32[kk], bTmp32[kk]); +// } + EXPECT_EQ(2, WebRtcSpl_CopyFromEndW16(b16, kVectorSize, 2, bTmp16)); + for (int kk = 0; kk < 2; ++kk) { + EXPECT_EQ(kk+2, bTmp16[kk]); + } + + for (int kk = 0; kk < kVectorSize; ++kk) { + b32[kk] = B[kk]; + b16[kk] = (WebRtc_Word16)B[kk]; + } + WebRtcSpl_VectorBitShiftW32ToW16(bTmp16, kVectorSize, b32, 1); + for (int kk = 0; kk < kVectorSize; ++kk) { + EXPECT_EQ((B[kk]>>1), bTmp16[kk]); + } + WebRtcSpl_VectorBitShiftW16(bTmp16, kVectorSize, b16, 1); + for (int kk = 0; kk < kVectorSize; ++kk) { + EXPECT_EQ((B[kk]>>1), bTmp16[kk]); + } + WebRtcSpl_VectorBitShiftW32(bTmp32, kVectorSize, b32, 1); + for (int kk = 0; kk < kVectorSize; ++kk) { + EXPECT_EQ((B[kk]>>1), bTmp32[kk]); + } + + WebRtcSpl_MemCpyReversedOrder(&bTmp16[3], b16, kVectorSize); + for (int kk = 0; kk < kVectorSize; ++kk) { + EXPECT_EQ(b16[3-kk], bTmp16[kk]); + } + +} + +TEST_F(SplTest, MinMaxOperationsTest) { + + + const int kVectorSize = 4; + int B[] = {4, 12, 133, -1100}; + WebRtc_Word16 b16[kVectorSize]; + WebRtc_Word32 b32[kVectorSize]; + + for (int kk = 0; kk < kVectorSize; ++kk) { + b16[kk] = B[kk]; + b32[kk] = B[kk]; + } + + EXPECT_EQ(1100, WebRtcSpl_MaxAbsValueW16(b16, kVectorSize)); + EXPECT_EQ(1100, WebRtcSpl_MaxAbsValueW32(b32, kVectorSize)); + EXPECT_EQ(133, WebRtcSpl_MaxValueW16(b16, kVectorSize)); + EXPECT_EQ(133, WebRtcSpl_MaxValueW32(b32, kVectorSize)); + EXPECT_EQ(3, WebRtcSpl_MaxAbsIndexW16(b16, kVectorSize)); + EXPECT_EQ(2, WebRtcSpl_MaxIndexW16(b16, kVectorSize)); + EXPECT_EQ(2, WebRtcSpl_MaxIndexW32(b32, kVectorSize)); + + EXPECT_EQ(-1100, WebRtcSpl_MinValueW16(b16, kVectorSize)); + EXPECT_EQ(-1100, WebRtcSpl_MinValueW32(b32, kVectorSize)); + EXPECT_EQ(3, WebRtcSpl_MinIndexW16(b16, kVectorSize)); + EXPECT_EQ(3, WebRtcSpl_MinIndexW32(b32, kVectorSize)); + + EXPECT_EQ(0, WebRtcSpl_GetScalingSquare(b16, kVectorSize, 1)); + +} + +TEST_F(SplTest, VectorOperationsTest) { + + + const int kVectorSize = 4; + int B[] = {4, 12, 133, 1100}; + WebRtc_Word16 a16[kVectorSize]; + WebRtc_Word16 b16[kVectorSize]; + WebRtc_Word32 b32[kVectorSize]; + WebRtc_Word16 bTmp16[kVectorSize]; + + for (int kk = 0; kk < kVectorSize; ++kk) { + a16[kk] = B[kk]; + b16[kk] = B[kk]; + } + + WebRtcSpl_AffineTransformVector(bTmp16, b16, 3, 7, 2, kVectorSize); + for (int kk = 0; kk < kVectorSize; ++kk) { + EXPECT_EQ((B[kk]*3+7)>>2, bTmp16[kk]); + } + WebRtcSpl_ScaleAndAddVectorsWithRound(b16, 3, b16, 2, 2, bTmp16, kVectorSize); + for (int kk = 0; kk < kVectorSize; ++kk) { + EXPECT_EQ((B[kk]*3+B[kk]*2+2)>>2, bTmp16[kk]); + } + + WebRtcSpl_AddAffineVectorToVector(bTmp16, b16, 3, 7, 2, kVectorSize); + for (int kk = 0; kk < kVectorSize; ++kk) { + EXPECT_EQ(((B[kk]*3+B[kk]*2+2)>>2)+((b16[kk]*3+7)>>2), bTmp16[kk]); + } + + WebRtcSpl_CrossCorrelation(b32, b16, bTmp16, kVectorSize, 2, 2, 0); + for (int kk = 0; kk < 2; ++kk) { + EXPECT_EQ(614236, b32[kk]); + } +// EXPECT_EQ(, WebRtcSpl_DotProduct(b16, bTmp16, 4)); + EXPECT_EQ(306962, WebRtcSpl_DotProductWithScale(b16, b16, kVectorSize, 2)); + + WebRtcSpl_ScaleVector(b16, bTmp16, 13, kVectorSize, 2); + for (int kk = 0; kk < kVectorSize; ++kk) { + EXPECT_EQ((b16[kk]*13)>>2, bTmp16[kk]); + } + WebRtcSpl_ScaleVectorWithSat(b16, bTmp16, 13, kVectorSize, 2); + for (int kk = 0; kk < kVectorSize; ++kk) { + EXPECT_EQ((b16[kk]*13)>>2, bTmp16[kk]); + } + WebRtcSpl_ScaleAndAddVectors(a16, 13, 2, b16, 7, 2, bTmp16, kVectorSize); + for (int kk = 0; kk < kVectorSize; ++kk) { + EXPECT_EQ(((a16[kk]*13)>>2)+((b16[kk]*7)>>2), bTmp16[kk]); + } + + WebRtcSpl_AddVectorsAndShift(bTmp16, a16, b16, kVectorSize, 2); + for (int kk = 0; kk < kVectorSize; ++kk) { + EXPECT_EQ(B[kk] >> 1, bTmp16[kk]); + } + WebRtcSpl_ReverseOrderMultArrayElements(bTmp16, a16, &b16[3], kVectorSize, 2); + for (int kk = 0; kk < kVectorSize; ++kk) { + EXPECT_EQ((a16[kk]*b16[3-kk])>>2, bTmp16[kk]); + } + WebRtcSpl_ElementwiseVectorMult(bTmp16, a16, b16, kVectorSize, 6); + for (int kk = 0; kk < kVectorSize; ++kk) { + EXPECT_EQ((a16[kk]*b16[kk])>>6, bTmp16[kk]); + } + + WebRtcSpl_SqrtOfOneMinusXSquared(b16, kVectorSize, bTmp16); + for (int kk = 0; kk < kVectorSize - 1; ++kk) { + EXPECT_EQ(32767, bTmp16[kk]); + } + EXPECT_EQ(32749, bTmp16[kVectorSize - 1]); +} + +TEST_F(SplTest, EstimatorsTest) { + + + const int kVectorSize = 4; + int B[] = {4, 12, 133, 1100}; + WebRtc_Word16 b16[kVectorSize]; + WebRtc_Word32 b32[kVectorSize]; + WebRtc_Word16 bTmp16[kVectorSize]; + + for (int kk = 0; kk < kVectorSize; ++kk) { + b16[kk] = B[kk]; + b32[kk] = B[kk]; + } + + EXPECT_EQ(0, WebRtcSpl_LevinsonDurbin(b32, b16, bTmp16, 2)); + +} + +TEST_F(SplTest, FilterTest) { + + + const int kVectorSize = 4; + WebRtc_Word16 A[] = {1, 2, 33, 100}; + WebRtc_Word16 A5[] = {1, 2, 33, 100, -5}; + WebRtc_Word16 B[] = {4, 12, 133, 110}; + WebRtc_Word16 b16[kVectorSize]; + WebRtc_Word16 bTmp16[kVectorSize]; + WebRtc_Word16 bTmp16Low[kVectorSize]; + WebRtc_Word16 bState[kVectorSize]; + WebRtc_Word16 bStateLow[kVectorSize]; + + WebRtcSpl_ZerosArrayW16(bState, kVectorSize); + WebRtcSpl_ZerosArrayW16(bStateLow, kVectorSize); + + for (int kk = 0; kk < kVectorSize; ++kk) { + b16[kk] = A[kk]; + } + + // MA filters + WebRtcSpl_FilterMAFastQ12(b16, bTmp16, B, kVectorSize, kVectorSize); + for (int kk = 0; kk < kVectorSize; ++kk) { + //EXPECT_EQ(aTmp16[kk], bTmp16[kk]); + } + // AR filters + WebRtcSpl_FilterARFastQ12(b16, bTmp16, A, kVectorSize, kVectorSize); + for (int kk = 0; kk < kVectorSize; ++kk) { +// EXPECT_EQ(aTmp16[kk], bTmp16[kk]); + } + EXPECT_EQ(kVectorSize, WebRtcSpl_FilterAR(A5, + 5, + b16, + kVectorSize, + bState, + kVectorSize, + bStateLow, + kVectorSize, + bTmp16, + bTmp16Low, + kVectorSize)); + +} + +TEST_F(SplTest, RandTest) { + + + const int kVectorSize = 4; + WebRtc_Word16 BU[] = {3653, 12446, 8525, 30691}; + WebRtc_Word16 BN[] = {3459, -11689, -258, -3738}; + WebRtc_Word16 b16[kVectorSize]; + WebRtc_UWord32 bSeed = 100000; + + EXPECT_EQ(464449057, WebRtcSpl_IncreaseSeed(&bSeed)); + EXPECT_EQ(31565, WebRtcSpl_RandU(&bSeed)); + EXPECT_EQ(-9786, WebRtcSpl_RandN(&bSeed)); + EXPECT_EQ(kVectorSize, WebRtcSpl_RandUArray(b16, kVectorSize, &bSeed)); + for (int kk = 0; kk < kVectorSize; ++kk) { + EXPECT_EQ(BU[kk], b16[kk]); + } +} + +TEST_F(SplTest, SignalProcessingTest) { + + + const int kVectorSize = 4; + int A[] = {1, 2, 33, 100}; + WebRtc_Word16 b16[kVectorSize]; + WebRtc_Word32 b32[kVectorSize]; + + WebRtc_Word16 bTmp16[kVectorSize]; + WebRtc_Word32 bTmp32[kVectorSize]; + + int bScale = 0; + + for (int kk = 0; kk < kVectorSize; ++kk) { + b16[kk] = A[kk]; + b32[kk] = A[kk]; + } + + EXPECT_EQ(2, WebRtcSpl_AutoCorrelation(b16, kVectorSize, 1, bTmp32, &bScale)); + WebRtcSpl_ReflCoefToLpc(b16, kVectorSize, bTmp16); +// for (int kk = 0; kk < kVectorSize; ++kk) { +// EXPECT_EQ(aTmp16[kk], bTmp16[kk]); +// } + WebRtcSpl_LpcToReflCoef(bTmp16, kVectorSize, b16); +// for (int kk = 0; kk < kVectorSize; ++kk) { +// EXPECT_EQ(a16[kk], b16[kk]); +// } + WebRtcSpl_AutoCorrToReflCoef(b32, kVectorSize, bTmp16); +// for (int kk = 0; kk < kVectorSize; ++kk) { +// EXPECT_EQ(aTmp16[kk], bTmp16[kk]); +// } + WebRtcSpl_GetHanningWindow(bTmp16, kVectorSize); +// for (int kk = 0; kk < kVectorSize; ++kk) { +// EXPECT_EQ(aTmp16[kk], bTmp16[kk]); +// } + + for (int kk = 0; kk < kVectorSize; ++kk) { + b16[kk] = A[kk]; + } + EXPECT_EQ(11094 , WebRtcSpl_Energy(b16, kVectorSize, &bScale)); + EXPECT_EQ(0, bScale); +} + +TEST_F(SplTest, FFTTest) { + + + WebRtc_Word16 B[] = {1, 2, 33, 100, + 2, 3, 34, 101, + 3, 4, 35, 102, + 4, 5, 36, 103}; + + EXPECT_EQ(0, WebRtcSpl_ComplexFFT(B, 3, 1)); +// for (int kk = 0; kk < 16; ++kk) { +// EXPECT_EQ(A[kk], B[kk]); +// } + EXPECT_EQ(0, WebRtcSpl_ComplexIFFT(B, 3, 1)); +// for (int kk = 0; kk < 16; ++kk) { +// EXPECT_EQ(A[kk], B[kk]); +// } + WebRtcSpl_ComplexBitReverse(B, 3); + for (int kk = 0; kk < 16; ++kk) { + //EXPECT_EQ(A[kk], B[kk]); + } +} + +int main(int argc, char** argv) { + ::testing::InitGoogleTest(&argc, argv); + SplEnvironment* env = new SplEnvironment; + ::testing::AddGlobalTestEnvironment(env); + + return RUN_ALL_TESTS(); +} diff --git a/src/common_audio/signal_processing_library/main/test/unit_test/unit_test.h b/src/common_audio/signal_processing_library/main/test/unit_test/unit_test.h new file mode 100644 index 0000000..d7babe7 --- /dev/null +++ b/src/common_audio/signal_processing_library/main/test/unit_test/unit_test.h @@ -0,0 +1,30 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +/* + * This header file contains the function WebRtcSpl_CopyFromBeginU8(). + * The description header can be found in signal_processing_library.h + * + */ + +#ifndef WEBRTC_SPL_UNIT_TEST_H_ +#define WEBRTC_SPL_UNIT_TEST_H_ + +#include + +class SplTest: public ::testing::Test +{ +protected: + SplTest(); + virtual void SetUp(); + virtual void TearDown(); +}; + +#endif // WEBRTC_SPL_UNIT_TEST_H_ diff --git a/src/common_audio/vad/OWNERS b/src/common_audio/vad/OWNERS new file mode 100644 index 0000000..d0e9870 --- /dev/null +++ b/src/common_audio/vad/OWNERS @@ -0,0 +1,2 @@ +bjornv@webrtc.org +jan.skoglund@webrtc.org diff --git a/src/common_audio/vad/main/interface/webrtc_vad.h b/src/common_audio/vad/main/interface/webrtc_vad.h new file mode 100644 index 0000000..6e3eb74 --- /dev/null +++ b/src/common_audio/vad/main/interface/webrtc_vad.h @@ -0,0 +1,159 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + + +/* + * This header file includes the VAD API calls. Specific function calls are given below. + */ + +#ifndef WEBRTC_VAD_WEBRTC_VAD_H_ +#define WEBRTC_VAD_WEBRTC_VAD_H_ + +#include "typedefs.h" + +typedef struct WebRtcVadInst VadInst; + +#ifdef __cplusplus +extern "C" +{ +#endif + +/**************************************************************************** + * WebRtcVad_get_version(...) + * + * This function returns the version number of the code. + * + * Output: + * - version : Pointer to a buffer where the version info will + * be stored. + * Input: + * - size_bytes : Size of the buffer. + * + */ +WebRtc_Word16 WebRtcVad_get_version(char *version, size_t size_bytes); + +/**************************************************************************** + * WebRtcVad_AssignSize(...) + * + * This functions get the size needed for storing the instance for encoder + * and decoder, respectively + * + * Input/Output: + * - size_in_bytes : Pointer to integer where the size is returned + * + * Return value : 0 + */ +WebRtc_Word16 WebRtcVad_AssignSize(int *size_in_bytes); + +/**************************************************************************** + * WebRtcVad_Assign(...) + * + * This functions Assigns memory for the instances. + * + * Input: + * - vad_inst_addr : Address to where to assign memory + * Output: + * - vad_inst : Pointer to the instance that should be created + * + * Return value : 0 - Ok + * -1 - Error + */ +WebRtc_Word16 WebRtcVad_Assign(VadInst **vad_inst, void *vad_inst_addr); + +/**************************************************************************** + * WebRtcVad_Create(...) + * + * This function creates an instance to the VAD structure + * + * Input: + * - vad_inst : Pointer to VAD instance that should be created + * + * Output: + * - vad_inst : Pointer to created VAD instance + * + * Return value : 0 - Ok + * -1 - Error + */ +WebRtc_Word16 WebRtcVad_Create(VadInst **vad_inst); + +/**************************************************************************** + * WebRtcVad_Free(...) + * + * This function frees the dynamic memory of a specified VAD instance + * + * Input: + * - vad_inst : Pointer to VAD instance that should be freed + * + * Return value : 0 - Ok + * -1 - Error + */ +WebRtc_Word16 WebRtcVad_Free(VadInst *vad_inst); + +/**************************************************************************** + * WebRtcVad_Init(...) + * + * This function initializes a VAD instance + * + * Input: + * - vad_inst : Instance that should be initialized + * + * Output: + * - vad_inst : Initialized instance + * + * Return value : 0 - Ok + * -1 - Error + */ +WebRtc_Word16 WebRtcVad_Init(VadInst *vad_inst); + +/**************************************************************************** + * WebRtcVad_set_mode(...) + * + * This function initializes a VAD instance + * + * Input: + * - vad_inst : VAD instance + * - mode : Aggressiveness setting (0, 1, 2, or 3) + * + * Output: + * - vad_inst : Initialized instance + * + * Return value : 0 - Ok + * -1 - Error + */ +WebRtc_Word16 WebRtcVad_set_mode(VadInst *vad_inst, WebRtc_Word16 mode); + +/**************************************************************************** + * WebRtcVad_Process(...) + * + * This functions does a VAD for the inserted speech frame + * + * Input + * - vad_inst : VAD Instance. Needs to be initiated before call. + * - fs : sampling frequency (Hz): 8000, 16000, or 32000 + * - speech_frame : Pointer to speech frame buffer + * - frame_length : Length of speech frame buffer in number of samples + * + * Output: + * - vad_inst : Updated VAD instance + * + * Return value : 1 - Active Voice + * 0 - Non-active Voice + * -1 - Error + */ +WebRtc_Word16 WebRtcVad_Process(VadInst *vad_inst, + WebRtc_Word16 fs, + WebRtc_Word16 *speech_frame, + WebRtc_Word16 frame_length); + +#ifdef __cplusplus +} +#endif + +#endif // WEBRTC_VAD_WEBRTC_VAD_H_ diff --git a/src/common_audio/vad/main/source/vad.gypi b/src/common_audio/vad/main/source/vad.gypi new file mode 100644 index 0000000..7b23ae8 --- /dev/null +++ b/src/common_audio/vad/main/source/vad.gypi @@ -0,0 +1,48 @@ +# Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. +# +# Use of this source code is governed by a BSD-style license +# that can be found in the LICENSE file in the root of the source +# tree. An additional intellectual property rights grant can be found +# in the file PATENTS. All contributing project authors may +# be found in the AUTHORS file in the root of the source tree. + +{ + 'targets': [ + { + 'target_name': 'vad', + 'type': '<(library)', + 'dependencies': [ + 'spl', + ], + 'include_dirs': [ + '../interface', + ], + 'direct_dependent_settings': { + 'include_dirs': [ + '../interface', + ], + }, + 'sources': [ + '../interface/webrtc_vad.h', + 'webrtc_vad.c', + 'vad_const.c', + 'vad_const.h', + 'vad_defines.h', + 'vad_core.c', + 'vad_core.h', + 'vad_filterbank.c', + 'vad_filterbank.h', + 'vad_gmm.c', + 'vad_gmm.h', + 'vad_sp.c', + 'vad_sp.h', + ], + }, + ], +} + +# Local Variables: +# tab-width:2 +# indent-tabs-mode:nil +# End: +# vim: set expandtab tabstop=2 shiftwidth=2: diff --git a/src/common_audio/vad/main/source/vad_const.c b/src/common_audio/vad/main/source/vad_const.c new file mode 100644 index 0000000..47b6a4b --- /dev/null +++ b/src/common_audio/vad/main/source/vad_const.c @@ -0,0 +1,80 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +/* + * This file includes the constant values used internally in VAD. + */ + +#include "vad_const.h" + +// Spectrum Weighting +const WebRtc_Word16 kSpectrumWeight[6] = {6, 8, 10, 12, 14, 16}; + +const WebRtc_Word16 kCompVar = 22005; + +// Constant 160*log10(2) in Q9 +const WebRtc_Word16 kLogConst = 24660; + +// Constant log2(exp(1)) in Q12 +const WebRtc_Word16 kLog10Const = 5909; + +// Q15 +const WebRtc_Word16 kNoiseUpdateConst = 655; +const WebRtc_Word16 kSpeechUpdateConst = 6554; + +// Q8 +const WebRtc_Word16 kBackEta = 154; + +// Coefficients used by WebRtcVad_HpOutput, Q14 +const WebRtc_Word16 kHpZeroCoefs[3] = {6631, -13262, 6631}; +const WebRtc_Word16 kHpPoleCoefs[3] = {16384, -7756, 5620}; + +// Allpass filter coefficients, upper and lower, in Q15 +// Upper: 0.64, Lower: 0.17 +const WebRtc_Word16 kAllPassCoefsQ15[2] = {20972, 5571}; +const WebRtc_Word16 kAllPassCoefsQ13[2] = {5243, 1392}; // Q13 + +// Minimum difference between the two models, Q5 +const WebRtc_Word16 kMinimumDifference[6] = {544, 544, 576, 576, 576, 576}; + +// Upper limit of mean value for speech model, Q7 +const WebRtc_Word16 kMaximumSpeech[6] = {11392, 11392, 11520, 11520, 11520, 11520}; + +// Minimum value for mean value +const WebRtc_Word16 kMinimumMean[2] = {640, 768}; + +// Upper limit of mean value for noise model, Q7 +const WebRtc_Word16 kMaximumNoise[6] = {9216, 9088, 8960, 8832, 8704, 8576}; + +// Adjustment for division with two in WebRtcVad_SplitFilter +const WebRtc_Word16 kOffsetVector[6] = {368, 368, 272, 176, 176, 176}; + +// Start values for the Gaussian models, Q7 +// Weights for the two Gaussians for the six channels (noise) +const WebRtc_Word16 kNoiseDataWeights[12] = {34, 62, 72, 66, 53, 25, 94, 66, 56, 62, 75, 103}; + +// Weights for the two Gaussians for the six channels (speech) +const WebRtc_Word16 kSpeechDataWeights[12] = {48, 82, 45, 87, 50, 47, 80, 46, 83, 41, 78, 81}; + +// Means for the two Gaussians for the six channels (noise) +const WebRtc_Word16 kNoiseDataMeans[12] = {6738, 4892, 7065, 6715, 6771, 3369, 7646, 3863, + 7820, 7266, 5020, 4362}; + +// Means for the two Gaussians for the six channels (speech) +const WebRtc_Word16 kSpeechDataMeans[12] = {8306, 10085, 10078, 11823, 11843, 6309, 9473, + 9571, 10879, 7581, 8180, 7483}; + +// Stds for the two Gaussians for the six channels (noise) +const WebRtc_Word16 kNoiseDataStds[12] = {378, 1064, 493, 582, 688, 593, 474, 697, 475, 688, + 421, 455}; + +// Stds for the two Gaussians for the six channels (speech) +const WebRtc_Word16 kSpeechDataStds[12] = {555, 505, 567, 524, 585, 1231, 509, 828, 492, 1540, + 1079, 850}; diff --git a/src/common_audio/vad/main/source/vad_const.h b/src/common_audio/vad/main/source/vad_const.h new file mode 100644 index 0000000..8980437 --- /dev/null +++ b/src/common_audio/vad/main/source/vad_const.h @@ -0,0 +1,59 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + + +/* + * This header file includes the declarations of the internally used constants. + */ + +#ifndef WEBRTC_VAD_CONST_H_ +#define WEBRTC_VAD_CONST_H_ + +#include "typedefs.h" + +// TODO(ajm): give these internal-linkage by moving to the appropriate file +// where possible, and otherwise tag with WebRtcVad_. + +// Spectrum Weighting +extern const WebRtc_Word16 kSpectrumWeight[]; +extern const WebRtc_Word16 kCompVar; +// Logarithm constant +extern const WebRtc_Word16 kLogConst; +extern const WebRtc_Word16 kLog10Const; +// Q15 +extern const WebRtc_Word16 kNoiseUpdateConst; +extern const WebRtc_Word16 kSpeechUpdateConst; +// Q8 +extern const WebRtc_Word16 kBackEta; +// Coefficients used by WebRtcVad_HpOutput, Q14 +extern const WebRtc_Word16 kHpZeroCoefs[]; +extern const WebRtc_Word16 kHpPoleCoefs[]; +// Allpass filter coefficients, upper and lower, in Q15 resp. Q13 +extern const WebRtc_Word16 kAllPassCoefsQ15[]; +extern const WebRtc_Word16 kAllPassCoefsQ13[]; +// Minimum difference between the two models, Q5 +extern const WebRtc_Word16 kMinimumDifference[]; +// Maximum value when updating the speech model, Q7 +extern const WebRtc_Word16 kMaximumSpeech[]; +// Minimum value for mean value +extern const WebRtc_Word16 kMinimumMean[]; +// Upper limit of mean value for noise model, Q7 +extern const WebRtc_Word16 kMaximumNoise[]; +// Adjustment for division with two in WebRtcVad_SplitFilter +extern const WebRtc_Word16 kOffsetVector[]; +// Start values for the Gaussian models, Q7 +extern const WebRtc_Word16 kNoiseDataWeights[]; +extern const WebRtc_Word16 kSpeechDataWeights[]; +extern const WebRtc_Word16 kNoiseDataMeans[]; +extern const WebRtc_Word16 kSpeechDataMeans[]; +extern const WebRtc_Word16 kNoiseDataStds[]; +extern const WebRtc_Word16 kSpeechDataStds[]; + +#endif // WEBRTC_VAD_CONST_H_ diff --git a/src/common_audio/vad/main/source/vad_core.c b/src/common_audio/vad/main/source/vad_core.c new file mode 100644 index 0000000..85864e1 --- /dev/null +++ b/src/common_audio/vad/main/source/vad_core.c @@ -0,0 +1,685 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + + +/* + * This file includes the implementation of the core functionality in VAD. + * For function description, see vad_core.h. + */ + +#include "vad_core.h" +#include "vad_const.h" +#include "vad_defines.h" +#include "vad_filterbank.h" +#include "vad_gmm.h" +#include "vad_sp.h" +#include "signal_processing_library.h" + +static const int kInitCheck = 42; + +// Initialize VAD +int WebRtcVad_InitCore(VadInstT *inst, short mode) +{ + int i; + + // Initialization of struct + inst->vad = 1; + inst->frame_counter = 0; + inst->over_hang = 0; + inst->num_of_speech = 0; + + // Initialization of downsampling filter state + inst->downsampling_filter_states[0] = 0; + inst->downsampling_filter_states[1] = 0; + inst->downsampling_filter_states[2] = 0; + inst->downsampling_filter_states[3] = 0; + + // Read initial PDF parameters + for (i = 0; i < NUM_TABLE_VALUES; i++) + { + inst->noise_means[i] = kNoiseDataMeans[i]; + inst->speech_means[i] = kSpeechDataMeans[i]; + inst->noise_stds[i] = kNoiseDataStds[i]; + inst->speech_stds[i] = kSpeechDataStds[i]; + } + + // Index and Minimum value vectors are initialized + for (i = 0; i < 16 * NUM_CHANNELS; i++) + { + inst->low_value_vector[i] = 10000; + inst->index_vector[i] = 0; + } + + for (i = 0; i < 5; i++) + { + inst->upper_state[i] = 0; + inst->lower_state[i] = 0; + } + + for (i = 0; i < 4; i++) + { + inst->hp_filter_state[i] = 0; + } + + // Init mean value memory, for FindMin function + inst->mean_value[0] = 1600; + inst->mean_value[1] = 1600; + inst->mean_value[2] = 1600; + inst->mean_value[3] = 1600; + inst->mean_value[4] = 1600; + inst->mean_value[5] = 1600; + + if (mode == 0) + { + // Quality mode + inst->over_hang_max_1[0] = OHMAX1_10MS_Q; // Overhang short speech burst + inst->over_hang_max_1[1] = OHMAX1_20MS_Q; // Overhang short speech burst + inst->over_hang_max_1[2] = OHMAX1_30MS_Q; // Overhang short speech burst + inst->over_hang_max_2[0] = OHMAX2_10MS_Q; // Overhang long speech burst + inst->over_hang_max_2[1] = OHMAX2_20MS_Q; // Overhang long speech burst + inst->over_hang_max_2[2] = OHMAX2_30MS_Q; // Overhang long speech burst + + inst->individual[0] = INDIVIDUAL_10MS_Q; + inst->individual[1] = INDIVIDUAL_20MS_Q; + inst->individual[2] = INDIVIDUAL_30MS_Q; + + inst->total[0] = TOTAL_10MS_Q; + inst->total[1] = TOTAL_20MS_Q; + inst->total[2] = TOTAL_30MS_Q; + } else if (mode == 1) + { + // Low bitrate mode + inst->over_hang_max_1[0] = OHMAX1_10MS_LBR; // Overhang short speech burst + inst->over_hang_max_1[1] = OHMAX1_20MS_LBR; // Overhang short speech burst + inst->over_hang_max_1[2] = OHMAX1_30MS_LBR; // Overhang short speech burst + inst->over_hang_max_2[0] = OHMAX2_10MS_LBR; // Overhang long speech burst + inst->over_hang_max_2[1] = OHMAX2_20MS_LBR; // Overhang long speech burst + inst->over_hang_max_2[2] = OHMAX2_30MS_LBR; // Overhang long speech burst + + inst->individual[0] = INDIVIDUAL_10MS_LBR; + inst->individual[1] = INDIVIDUAL_20MS_LBR; + inst->individual[2] = INDIVIDUAL_30MS_LBR; + + inst->total[0] = TOTAL_10MS_LBR; + inst->total[1] = TOTAL_20MS_LBR; + inst->total[2] = TOTAL_30MS_LBR; + } else if (mode == 2) + { + // Aggressive mode + inst->over_hang_max_1[0] = OHMAX1_10MS_AGG; // Overhang short speech burst + inst->over_hang_max_1[1] = OHMAX1_20MS_AGG; // Overhang short speech burst + inst->over_hang_max_1[2] = OHMAX1_30MS_AGG; // Overhang short speech burst + inst->over_hang_max_2[0] = OHMAX2_10MS_AGG; // Overhang long speech burst + inst->over_hang_max_2[1] = OHMAX2_20MS_AGG; // Overhang long speech burst + inst->over_hang_max_2[2] = OHMAX2_30MS_AGG; // Overhang long speech burst + + inst->individual[0] = INDIVIDUAL_10MS_AGG; + inst->individual[1] = INDIVIDUAL_20MS_AGG; + inst->individual[2] = INDIVIDUAL_30MS_AGG; + + inst->total[0] = TOTAL_10MS_AGG; + inst->total[1] = TOTAL_20MS_AGG; + inst->total[2] = TOTAL_30MS_AGG; + } else + { + // Very aggressive mode + inst->over_hang_max_1[0] = OHMAX1_10MS_VAG; // Overhang short speech burst + inst->over_hang_max_1[1] = OHMAX1_20MS_VAG; // Overhang short speech burst + inst->over_hang_max_1[2] = OHMAX1_30MS_VAG; // Overhang short speech burst + inst->over_hang_max_2[0] = OHMAX2_10MS_VAG; // Overhang long speech burst + inst->over_hang_max_2[1] = OHMAX2_20MS_VAG; // Overhang long speech burst + inst->over_hang_max_2[2] = OHMAX2_30MS_VAG; // Overhang long speech burst + + inst->individual[0] = INDIVIDUAL_10MS_VAG; + inst->individual[1] = INDIVIDUAL_20MS_VAG; + inst->individual[2] = INDIVIDUAL_30MS_VAG; + + inst->total[0] = TOTAL_10MS_VAG; + inst->total[1] = TOTAL_20MS_VAG; + inst->total[2] = TOTAL_30MS_VAG; + } + + inst->init_flag = kInitCheck; + + return 0; +} + +// Set aggressiveness mode +int WebRtcVad_set_mode_core(VadInstT *inst, short mode) +{ + + if (mode == 0) + { + // Quality mode + inst->over_hang_max_1[0] = OHMAX1_10MS_Q; // Overhang short speech burst + inst->over_hang_max_1[1] = OHMAX1_20MS_Q; // Overhang short speech burst + inst->over_hang_max_1[2] = OHMAX1_30MS_Q; // Overhang short speech burst + inst->over_hang_max_2[0] = OHMAX2_10MS_Q; // Overhang long speech burst + inst->over_hang_max_2[1] = OHMAX2_20MS_Q; // Overhang long speech burst + inst->over_hang_max_2[2] = OHMAX2_30MS_Q; // Overhang long speech burst + + inst->individual[0] = INDIVIDUAL_10MS_Q; + inst->individual[1] = INDIVIDUAL_20MS_Q; + inst->individual[2] = INDIVIDUAL_30MS_Q; + + inst->total[0] = TOTAL_10MS_Q; + inst->total[1] = TOTAL_20MS_Q; + inst->total[2] = TOTAL_30MS_Q; + } else if (mode == 1) + { + // Low bitrate mode + inst->over_hang_max_1[0] = OHMAX1_10MS_LBR; // Overhang short speech burst + inst->over_hang_max_1[1] = OHMAX1_20MS_LBR; // Overhang short speech burst + inst->over_hang_max_1[2] = OHMAX1_30MS_LBR; // Overhang short speech burst + inst->over_hang_max_2[0] = OHMAX2_10MS_LBR; // Overhang long speech burst + inst->over_hang_max_2[1] = OHMAX2_20MS_LBR; // Overhang long speech burst + inst->over_hang_max_2[2] = OHMAX2_30MS_LBR; // Overhang long speech burst + + inst->individual[0] = INDIVIDUAL_10MS_LBR; + inst->individual[1] = INDIVIDUAL_20MS_LBR; + inst->individual[2] = INDIVIDUAL_30MS_LBR; + + inst->total[0] = TOTAL_10MS_LBR; + inst->total[1] = TOTAL_20MS_LBR; + inst->total[2] = TOTAL_30MS_LBR; + } else if (mode == 2) + { + // Aggressive mode + inst->over_hang_max_1[0] = OHMAX1_10MS_AGG; // Overhang short speech burst + inst->over_hang_max_1[1] = OHMAX1_20MS_AGG; // Overhang short speech burst + inst->over_hang_max_1[2] = OHMAX1_30MS_AGG; // Overhang short speech burst + inst->over_hang_max_2[0] = OHMAX2_10MS_AGG; // Overhang long speech burst + inst->over_hang_max_2[1] = OHMAX2_20MS_AGG; // Overhang long speech burst + inst->over_hang_max_2[2] = OHMAX2_30MS_AGG; // Overhang long speech burst + + inst->individual[0] = INDIVIDUAL_10MS_AGG; + inst->individual[1] = INDIVIDUAL_20MS_AGG; + inst->individual[2] = INDIVIDUAL_30MS_AGG; + + inst->total[0] = TOTAL_10MS_AGG; + inst->total[1] = TOTAL_20MS_AGG; + inst->total[2] = TOTAL_30MS_AGG; + } else if (mode == 3) + { + // Very aggressive mode + inst->over_hang_max_1[0] = OHMAX1_10MS_VAG; // Overhang short speech burst + inst->over_hang_max_1[1] = OHMAX1_20MS_VAG; // Overhang short speech burst + inst->over_hang_max_1[2] = OHMAX1_30MS_VAG; // Overhang short speech burst + inst->over_hang_max_2[0] = OHMAX2_10MS_VAG; // Overhang long speech burst + inst->over_hang_max_2[1] = OHMAX2_20MS_VAG; // Overhang long speech burst + inst->over_hang_max_2[2] = OHMAX2_30MS_VAG; // Overhang long speech burst + + inst->individual[0] = INDIVIDUAL_10MS_VAG; + inst->individual[1] = INDIVIDUAL_20MS_VAG; + inst->individual[2] = INDIVIDUAL_30MS_VAG; + + inst->total[0] = TOTAL_10MS_VAG; + inst->total[1] = TOTAL_20MS_VAG; + inst->total[2] = TOTAL_30MS_VAG; + } else + { + return -1; + } + + return 0; +} + +// Calculate VAD decision by first extracting feature values and then calculate +// probability for both speech and background noise. + +WebRtc_Word16 WebRtcVad_CalcVad32khz(VadInstT *inst, WebRtc_Word16 *speech_frame, + int frame_length) +{ + WebRtc_Word16 len, vad; + WebRtc_Word16 speechWB[480]; // Downsampled speech frame: 960 samples (30ms in SWB) + WebRtc_Word16 speechNB[240]; // Downsampled speech frame: 480 samples (30ms in WB) + + + // Downsample signal 32->16->8 before doing VAD + WebRtcVad_Downsampling(speech_frame, speechWB, &(inst->downsampling_filter_states[2]), + frame_length); + len = WEBRTC_SPL_RSHIFT_W16(frame_length, 1); + + WebRtcVad_Downsampling(speechWB, speechNB, inst->downsampling_filter_states, len); + len = WEBRTC_SPL_RSHIFT_W16(len, 1); + + // Do VAD on an 8 kHz signal + vad = WebRtcVad_CalcVad8khz(inst, speechNB, len); + + return vad; +} + +WebRtc_Word16 WebRtcVad_CalcVad16khz(VadInstT *inst, WebRtc_Word16 *speech_frame, + int frame_length) +{ + WebRtc_Word16 len, vad; + WebRtc_Word16 speechNB[240]; // Downsampled speech frame: 480 samples (30ms in WB) + + // Wideband: Downsample signal before doing VAD + WebRtcVad_Downsampling(speech_frame, speechNB, inst->downsampling_filter_states, + frame_length); + + len = WEBRTC_SPL_RSHIFT_W16(frame_length, 1); + vad = WebRtcVad_CalcVad8khz(inst, speechNB, len); + + return vad; +} + +WebRtc_Word16 WebRtcVad_CalcVad8khz(VadInstT *inst, WebRtc_Word16 *speech_frame, + int frame_length) +{ + WebRtc_Word16 feature_vector[NUM_CHANNELS], total_power; + + // Get power in the bands + total_power = WebRtcVad_get_features(inst, speech_frame, frame_length, feature_vector); + + // Make a VAD + inst->vad = WebRtcVad_GmmProbability(inst, feature_vector, total_power, frame_length); + + return inst->vad; +} + +// Calculate probability for both speech and background noise, and perform a +// hypothesis-test. +WebRtc_Word16 WebRtcVad_GmmProbability(VadInstT *inst, WebRtc_Word16 *feature_vector, + WebRtc_Word16 total_power, int frame_length) +{ + int n, k; + WebRtc_Word16 backval; + WebRtc_Word16 h0, h1; + WebRtc_Word16 ratvec, xval; + WebRtc_Word16 vadflag; + WebRtc_Word16 shifts0, shifts1; + WebRtc_Word16 tmp16, tmp16_1, tmp16_2; + WebRtc_Word16 diff, nr, pos; + WebRtc_Word16 nmk, nmk2, nmk3, smk, smk2, nsk, ssk; + WebRtc_Word16 delt, ndelt; + WebRtc_Word16 maxspe, maxmu; + WebRtc_Word16 deltaN[NUM_TABLE_VALUES], deltaS[NUM_TABLE_VALUES]; + WebRtc_Word16 ngprvec[NUM_TABLE_VALUES], sgprvec[NUM_TABLE_VALUES]; + WebRtc_Word32 h0test, h1test; + WebRtc_Word32 tmp32_1, tmp32_2; + WebRtc_Word32 dotVal; + WebRtc_Word32 nmid, smid; + WebRtc_Word32 probn[NUM_MODELS], probs[NUM_MODELS]; + WebRtc_Word16 *nmean1ptr, *nmean2ptr, *smean1ptr, *smean2ptr, *nstd1ptr, *nstd2ptr, + *sstd1ptr, *sstd2ptr; + WebRtc_Word16 overhead1, overhead2, individualTest, totalTest; + + // Set the thresholds to different values based on frame length + if (frame_length == 80) + { + // 80 input samples + overhead1 = inst->over_hang_max_1[0]; + overhead2 = inst->over_hang_max_2[0]; + individualTest = inst->individual[0]; + totalTest = inst->total[0]; + } else if (frame_length == 160) + { + // 160 input samples + overhead1 = inst->over_hang_max_1[1]; + overhead2 = inst->over_hang_max_2[1]; + individualTest = inst->individual[1]; + totalTest = inst->total[1]; + } else + { + // 240 input samples + overhead1 = inst->over_hang_max_1[2]; + overhead2 = inst->over_hang_max_2[2]; + individualTest = inst->individual[2]; + totalTest = inst->total[2]; + } + + if (total_power > MIN_ENERGY) + { // If signal present at all + + // Set pointers to the gaussian parameters + nmean1ptr = &inst->noise_means[0]; + nmean2ptr = &inst->noise_means[NUM_CHANNELS]; + smean1ptr = &inst->speech_means[0]; + smean2ptr = &inst->speech_means[NUM_CHANNELS]; + nstd1ptr = &inst->noise_stds[0]; + nstd2ptr = &inst->noise_stds[NUM_CHANNELS]; + sstd1ptr = &inst->speech_stds[0]; + sstd2ptr = &inst->speech_stds[NUM_CHANNELS]; + + vadflag = 0; + dotVal = 0; + for (n = 0; n < NUM_CHANNELS; n++) + { // For all channels + + pos = WEBRTC_SPL_LSHIFT_W16(n, 1); + xval = feature_vector[n]; + + // Probability for Noise, Q7 * Q20 = Q27 + tmp32_1 = WebRtcVad_GaussianProbability(xval, *nmean1ptr++, *nstd1ptr++, + &deltaN[pos]); + probn[0] = (WebRtc_Word32)(kNoiseDataWeights[n] * tmp32_1); + tmp32_1 = WebRtcVad_GaussianProbability(xval, *nmean2ptr++, *nstd2ptr++, + &deltaN[pos + 1]); + probn[1] = (WebRtc_Word32)(kNoiseDataWeights[n + NUM_CHANNELS] * tmp32_1); + h0test = probn[0] + probn[1]; // Q27 + h0 = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32(h0test, 12); // Q15 + + // Probability for Speech + tmp32_1 = WebRtcVad_GaussianProbability(xval, *smean1ptr++, *sstd1ptr++, + &deltaS[pos]); + probs[0] = (WebRtc_Word32)(kSpeechDataWeights[n] * tmp32_1); + tmp32_1 = WebRtcVad_GaussianProbability(xval, *smean2ptr++, *sstd2ptr++, + &deltaS[pos + 1]); + probs[1] = (WebRtc_Word32)(kSpeechDataWeights[n + NUM_CHANNELS] * tmp32_1); + h1test = probs[0] + probs[1]; // Q27 + h1 = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32(h1test, 12); // Q15 + + // Get likelihood ratio. Approximate log2(H1/H0) with shifts0 - shifts1 + shifts0 = WebRtcSpl_NormW32(h0test); + shifts1 = WebRtcSpl_NormW32(h1test); + + if ((h0test > 0) && (h1test > 0)) + { + ratvec = shifts0 - shifts1; + } else if (h1test > 0) + { + ratvec = 31 - shifts1; + } else if (h0test > 0) + { + ratvec = shifts0 - 31; + } else + { + ratvec = 0; + } + + // VAD decision with spectrum weighting + dotVal += WEBRTC_SPL_MUL_16_16(ratvec, kSpectrumWeight[n]); + + // Individual channel test + if ((ratvec << 2) > individualTest) + { + vadflag = 1; + } + + // Probabilities used when updating model + if (h0 > 0) + { + tmp32_1 = probn[0] & 0xFFFFF000; // Q27 + tmp32_2 = WEBRTC_SPL_LSHIFT_W32(tmp32_1, 2); // Q29 + ngprvec[pos] = (WebRtc_Word16)WebRtcSpl_DivW32W16(tmp32_2, h0); + ngprvec[pos + 1] = 16384 - ngprvec[pos]; + } else + { + ngprvec[pos] = 16384; + ngprvec[pos + 1] = 0; + } + + // Probabilities used when updating model + if (h1 > 0) + { + tmp32_1 = probs[0] & 0xFFFFF000; + tmp32_2 = WEBRTC_SPL_LSHIFT_W32(tmp32_1, 2); + sgprvec[pos] = (WebRtc_Word16)WebRtcSpl_DivW32W16(tmp32_2, h1); + sgprvec[pos + 1] = 16384 - sgprvec[pos]; + } else + { + sgprvec[pos] = 0; + sgprvec[pos + 1] = 0; + } + } + + // Overall test + if (dotVal >= totalTest) + { + vadflag |= 1; + } + + // Set pointers to the means and standard deviations. + nmean1ptr = &inst->noise_means[0]; + smean1ptr = &inst->speech_means[0]; + nstd1ptr = &inst->noise_stds[0]; + sstd1ptr = &inst->speech_stds[0]; + + maxspe = 12800; + + // Update the model's parameters + for (n = 0; n < NUM_CHANNELS; n++) + { + + pos = WEBRTC_SPL_LSHIFT_W16(n, 1); + + // Get min value in past which is used for long term correction + backval = WebRtcVad_FindMinimum(inst, feature_vector[n], n); // Q4 + + // Compute the "global" mean, that is the sum of the two means weighted + nmid = WEBRTC_SPL_MUL_16_16(kNoiseDataWeights[n], *nmean1ptr); // Q7 * Q7 + nmid += WEBRTC_SPL_MUL_16_16(kNoiseDataWeights[n+NUM_CHANNELS], + *(nmean1ptr+NUM_CHANNELS)); + tmp16_1 = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32(nmid, 6); // Q8 + + for (k = 0; k < NUM_MODELS; k++) + { + + nr = pos + k; + + nmean2ptr = nmean1ptr + k * NUM_CHANNELS; + smean2ptr = smean1ptr + k * NUM_CHANNELS; + nstd2ptr = nstd1ptr + k * NUM_CHANNELS; + sstd2ptr = sstd1ptr + k * NUM_CHANNELS; + nmk = *nmean2ptr; + smk = *smean2ptr; + nsk = *nstd2ptr; + ssk = *sstd2ptr; + + // Update noise mean vector if the frame consists of noise only + nmk2 = nmk; + if (!vadflag) + { + // deltaN = (x-mu)/sigma^2 + // ngprvec[k] = probn[k]/(probn[0] + probn[1]) + + delt = (WebRtc_Word16)WEBRTC_SPL_MUL_16_16_RSFT(ngprvec[nr], + deltaN[nr], 11); // Q14*Q11 + nmk2 = nmk + (WebRtc_Word16)WEBRTC_SPL_MUL_16_16_RSFT(delt, + kNoiseUpdateConst, + 22); // Q7+(Q14*Q15>>22) + } + + // Long term correction of the noise mean + ndelt = WEBRTC_SPL_LSHIFT_W16(backval, 4); + ndelt -= tmp16_1; // Q8 - Q8 + nmk3 = nmk2 + (WebRtc_Word16)WEBRTC_SPL_MUL_16_16_RSFT(ndelt, + kBackEta, + 9); // Q7+(Q8*Q8)>>9 + + // Control that the noise mean does not drift to much + tmp16 = WEBRTC_SPL_LSHIFT_W16(k+5, 7); + if (nmk3 < tmp16) + nmk3 = tmp16; + tmp16 = WEBRTC_SPL_LSHIFT_W16(72+k-n, 7); + if (nmk3 > tmp16) + nmk3 = tmp16; + *nmean2ptr = nmk3; + + if (vadflag) + { + // Update speech mean vector: + // deltaS = (x-mu)/sigma^2 + // sgprvec[k] = probn[k]/(probn[0] + probn[1]) + + delt = (WebRtc_Word16)WEBRTC_SPL_MUL_16_16_RSFT(sgprvec[nr], + deltaS[nr], + 11); // (Q14*Q11)>>11=Q14 + tmp16 = (WebRtc_Word16)WEBRTC_SPL_MUL_16_16_RSFT(delt, + kSpeechUpdateConst, + 21) + 1; + smk2 = smk + (tmp16 >> 1); // Q7 + (Q14 * Q15 >> 22) + + // Control that the speech mean does not drift to much + maxmu = maxspe + 640; + if (smk2 < kMinimumMean[k]) + smk2 = kMinimumMean[k]; + if (smk2 > maxmu) + smk2 = maxmu; + + *smean2ptr = smk2; + + // (Q7>>3) = Q4 + tmp16 = WEBRTC_SPL_RSHIFT_W16((smk + 4), 3); + + tmp16 = feature_vector[n] - tmp16; // Q4 + tmp32_1 = WEBRTC_SPL_MUL_16_16_RSFT(deltaS[nr], tmp16, 3); + tmp32_2 = tmp32_1 - (WebRtc_Word32)4096; // Q12 + tmp16 = WEBRTC_SPL_RSHIFT_W16((sgprvec[nr]), 2); + tmp32_1 = (WebRtc_Word32)(tmp16 * tmp32_2);// (Q15>>3)*(Q14>>2)=Q12*Q12=Q24 + + tmp32_2 = WEBRTC_SPL_RSHIFT_W32(tmp32_1, 4); // Q20 + + // 0.1 * Q20 / Q7 = Q13 + if (tmp32_2 > 0) + tmp16 = (WebRtc_Word16)WebRtcSpl_DivW32W16(tmp32_2, ssk * 10); + else + { + tmp16 = (WebRtc_Word16)WebRtcSpl_DivW32W16(-tmp32_2, ssk * 10); + tmp16 = -tmp16; + } + // divide by 4 giving an update factor of 0.025 + tmp16 += 128; // Rounding + ssk += WEBRTC_SPL_RSHIFT_W16(tmp16, 8); + // Division with 8 plus Q7 + if (ssk < MIN_STD) + ssk = MIN_STD; + *sstd2ptr = ssk; + } else + { + // Update GMM variance vectors + // deltaN * (feature_vector[n] - nmk) - 1, Q11 * Q4 + tmp16 = feature_vector[n] - WEBRTC_SPL_RSHIFT_W16(nmk, 3); + + // (Q15>>3) * (Q14>>2) = Q12 * Q12 = Q24 + tmp32_1 = WEBRTC_SPL_MUL_16_16_RSFT(deltaN[nr], tmp16, 3) - 4096; + tmp16 = WEBRTC_SPL_RSHIFT_W16((ngprvec[nr]+2), 2); + tmp32_2 = (WebRtc_Word32)(tmp16 * tmp32_1); + tmp32_1 = WEBRTC_SPL_RSHIFT_W32(tmp32_2, 14); + // Q20 * approx 0.001 (2^-10=0.0009766) + + // Q20 / Q7 = Q13 + tmp16 = (WebRtc_Word16)WebRtcSpl_DivW32W16(tmp32_1, nsk); + if (tmp32_1 > 0) + tmp16 = (WebRtc_Word16)WebRtcSpl_DivW32W16(tmp32_1, nsk); + else + { + tmp16 = (WebRtc_Word16)WebRtcSpl_DivW32W16(-tmp32_1, nsk); + tmp16 = -tmp16; + } + tmp16 += 32; // Rounding + nsk += WEBRTC_SPL_RSHIFT_W16(tmp16, 6); + + if (nsk < MIN_STD) + nsk = MIN_STD; + + *nstd2ptr = nsk; + } + } + + // Separate models if they are too close - nmid in Q14 + nmid = WEBRTC_SPL_MUL_16_16(kNoiseDataWeights[n], *nmean1ptr); + nmid += WEBRTC_SPL_MUL_16_16(kNoiseDataWeights[n+NUM_CHANNELS], *nmean2ptr); + + // smid in Q14 + smid = WEBRTC_SPL_MUL_16_16(kSpeechDataWeights[n], *smean1ptr); + smid += WEBRTC_SPL_MUL_16_16(kSpeechDataWeights[n+NUM_CHANNELS], *smean2ptr); + + // diff = "global" speech mean - "global" noise mean + diff = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32(smid, 9); + tmp16 = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32(nmid, 9); + diff -= tmp16; + + if (diff < kMinimumDifference[n]) + { + + tmp16 = kMinimumDifference[n] - diff; // Q5 + + // tmp16_1 = ~0.8 * (kMinimumDifference - diff) in Q7 + // tmp16_2 = ~0.2 * (kMinimumDifference - diff) in Q7 + tmp16_1 = (WebRtc_Word16)WEBRTC_SPL_MUL_16_16_RSFT(13, tmp16, 2); + tmp16_2 = (WebRtc_Word16)WEBRTC_SPL_MUL_16_16_RSFT(3, tmp16, 2); + + // First Gauss, speech model + tmp16 = tmp16_1 + *smean1ptr; + *smean1ptr = tmp16; + smid = WEBRTC_SPL_MUL_16_16(tmp16, kSpeechDataWeights[n]); + + // Second Gauss, speech model + tmp16 = tmp16_1 + *smean2ptr; + *smean2ptr = tmp16; + smid += WEBRTC_SPL_MUL_16_16(tmp16, kSpeechDataWeights[n+NUM_CHANNELS]); + + // First Gauss, noise model + tmp16 = *nmean1ptr - tmp16_2; + *nmean1ptr = tmp16; + + nmid = WEBRTC_SPL_MUL_16_16(tmp16, kNoiseDataWeights[n]); + + // Second Gauss, noise model + tmp16 = *nmean2ptr - tmp16_2; + *nmean2ptr = tmp16; + nmid += WEBRTC_SPL_MUL_16_16(tmp16, kNoiseDataWeights[n+NUM_CHANNELS]); + } + + // Control that the speech & noise means do not drift to much + maxspe = kMaximumSpeech[n]; + tmp16_2 = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32(smid, 7); + if (tmp16_2 > maxspe) + { // Upper limit of speech model + tmp16_2 -= maxspe; + + *smean1ptr -= tmp16_2; + *smean2ptr -= tmp16_2; + } + + tmp16_2 = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32(nmid, 7); + if (tmp16_2 > kMaximumNoise[n]) + { + tmp16_2 -= kMaximumNoise[n]; + + *nmean1ptr -= tmp16_2; + *nmean2ptr -= tmp16_2; + } + + nmean1ptr++; + smean1ptr++; + nstd1ptr++; + sstd1ptr++; + } + inst->frame_counter++; + } else + { + vadflag = 0; + } + + // Hangover smoothing + if (!vadflag) + { + if (inst->over_hang > 0) + { + vadflag = 2 + inst->over_hang; + inst->over_hang = inst->over_hang - 1; + } + inst->num_of_speech = 0; + } else + { + inst->num_of_speech = inst->num_of_speech + 1; + if (inst->num_of_speech > NSP_MAX) + { + inst->num_of_speech = NSP_MAX; + inst->over_hang = overhead2; + } else + inst->over_hang = overhead1; + } + return vadflag; +} diff --git a/src/common_audio/vad/main/source/vad_core.h b/src/common_audio/vad/main/source/vad_core.h new file mode 100644 index 0000000..544caf5 --- /dev/null +++ b/src/common_audio/vad/main/source/vad_core.h @@ -0,0 +1,132 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + + +/* + * This header file includes the descriptions of the core VAD calls. + */ + +#ifndef WEBRTC_VAD_CORE_H_ +#define WEBRTC_VAD_CORE_H_ + +#include "typedefs.h" +#include "vad_defines.h" + +typedef struct VadInstT_ +{ + + WebRtc_Word16 vad; + WebRtc_Word32 downsampling_filter_states[4]; + WebRtc_Word16 noise_means[NUM_TABLE_VALUES]; + WebRtc_Word16 speech_means[NUM_TABLE_VALUES]; + WebRtc_Word16 noise_stds[NUM_TABLE_VALUES]; + WebRtc_Word16 speech_stds[NUM_TABLE_VALUES]; + WebRtc_Word32 frame_counter; + WebRtc_Word16 over_hang; // Over Hang + WebRtc_Word16 num_of_speech; + WebRtc_Word16 index_vector[16 * NUM_CHANNELS]; + WebRtc_Word16 low_value_vector[16 * NUM_CHANNELS]; + WebRtc_Word16 mean_value[NUM_CHANNELS]; + WebRtc_Word16 upper_state[5]; + WebRtc_Word16 lower_state[5]; + WebRtc_Word16 hp_filter_state[4]; + WebRtc_Word16 over_hang_max_1[3]; + WebRtc_Word16 over_hang_max_2[3]; + WebRtc_Word16 individual[3]; + WebRtc_Word16 total[3]; + + short init_flag; + +} VadInstT; + +/**************************************************************************** + * WebRtcVad_InitCore(...) + * + * This function initializes a VAD instance + * + * Input: + * - inst : Instance that should be initialized + * - mode : Aggressiveness degree + * 0 (High quality) - 3 (Highly aggressive) + * + * Output: + * - inst : Initialized instance + * + * Return value : 0 - Ok + * -1 - Error + */ +int WebRtcVad_InitCore(VadInstT* inst, short mode); + +/**************************************************************************** + * WebRtcVad_set_mode_core(...) + * + * This function changes the VAD settings + * + * Input: + * - inst : VAD instance + * - mode : Aggressiveness degree + * 0 (High quality) - 3 (Highly aggressive) + * + * Output: + * - inst : Changed instance + * + * Return value : 0 - Ok + * -1 - Error + */ + +int WebRtcVad_set_mode_core(VadInstT* inst, short mode); + +/**************************************************************************** + * WebRtcVad_CalcVad32khz(...) + * WebRtcVad_CalcVad16khz(...) + * WebRtcVad_CalcVad8khz(...) + * + * Calculate probability for active speech and make VAD decision. + * + * Input: + * - inst : Instance that should be initialized + * - speech_frame : Input speech frame + * - frame_length : Number of input samples + * + * Output: + * - inst : Updated filter states etc. + * + * Return value : VAD decision + * 0 - No active speech + * 1-6 - Active speech + */ +WebRtc_Word16 WebRtcVad_CalcVad32khz(VadInstT* inst, WebRtc_Word16* speech_frame, + int frame_length); +WebRtc_Word16 WebRtcVad_CalcVad16khz(VadInstT* inst, WebRtc_Word16* speech_frame, + int frame_length); +WebRtc_Word16 WebRtcVad_CalcVad8khz(VadInstT* inst, WebRtc_Word16* speech_frame, + int frame_length); + +/**************************************************************************** + * WebRtcVad_GmmProbability(...) + * + * This function calculates the probabilities for background noise and + * speech using Gaussian Mixture Models. A hypothesis-test is performed to decide + * which type of signal is most probable. + * + * Input: + * - inst : Pointer to VAD instance + * - feature_vector : Feature vector = log10(energy in frequency band) + * - total_power : Total power in frame. + * - frame_length : Number of input samples + * + * Output: + * VAD decision : 0 - noise, 1 - speech + * + */ +WebRtc_Word16 WebRtcVad_GmmProbability(VadInstT* inst, WebRtc_Word16* feature_vector, + WebRtc_Word16 total_power, int frame_length); + +#endif // WEBRTC_VAD_CORE_H_ diff --git a/src/common_audio/vad/main/source/vad_defines.h b/src/common_audio/vad/main/source/vad_defines.h new file mode 100644 index 0000000..b33af2e --- /dev/null +++ b/src/common_audio/vad/main/source/vad_defines.h @@ -0,0 +1,95 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + + +/* + * This header file includes the macros used in VAD. + */ + +#ifndef WEBRTC_VAD_DEFINES_H_ +#define WEBRTC_VAD_DEFINES_H_ + +#define NUM_CHANNELS 6 // Eight frequency bands +#define NUM_MODELS 2 // Number of Gaussian models +#define NUM_TABLE_VALUES NUM_CHANNELS * NUM_MODELS + +#define MIN_ENERGY 10 +#define ALPHA1 6553 // 0.2 in Q15 +#define ALPHA2 32439 // 0.99 in Q15 +#define NSP_MAX 6 // Maximum number of VAD=1 frames in a row counted +#define MIN_STD 384 // Minimum standard deviation +// Mode 0, Quality thresholds - Different thresholds for the different frame lengths +#define INDIVIDUAL_10MS_Q 24 +#define INDIVIDUAL_20MS_Q 21 // (log10(2)*66)<<2 ~=16 +#define INDIVIDUAL_30MS_Q 24 + +#define TOTAL_10MS_Q 57 +#define TOTAL_20MS_Q 48 +#define TOTAL_30MS_Q 57 + +#define OHMAX1_10MS_Q 8 // Max Overhang 1 +#define OHMAX2_10MS_Q 14 // Max Overhang 2 +#define OHMAX1_20MS_Q 4 // Max Overhang 1 +#define OHMAX2_20MS_Q 7 // Max Overhang 2 +#define OHMAX1_30MS_Q 3 +#define OHMAX2_30MS_Q 5 + +// Mode 1, Low bitrate thresholds - Different thresholds for the different frame lengths +#define INDIVIDUAL_10MS_LBR 37 +#define INDIVIDUAL_20MS_LBR 32 +#define INDIVIDUAL_30MS_LBR 37 + +#define TOTAL_10MS_LBR 100 +#define TOTAL_20MS_LBR 80 +#define TOTAL_30MS_LBR 100 + +#define OHMAX1_10MS_LBR 8 // Max Overhang 1 +#define OHMAX2_10MS_LBR 14 // Max Overhang 2 +#define OHMAX1_20MS_LBR 4 +#define OHMAX2_20MS_LBR 7 + +#define OHMAX1_30MS_LBR 3 +#define OHMAX2_30MS_LBR 5 + +// Mode 2, Very aggressive thresholds - Different thresholds for the different frame lengths +#define INDIVIDUAL_10MS_AGG 82 +#define INDIVIDUAL_20MS_AGG 78 +#define INDIVIDUAL_30MS_AGG 82 + +#define TOTAL_10MS_AGG 285 //580 +#define TOTAL_20MS_AGG 260 +#define TOTAL_30MS_AGG 285 + +#define OHMAX1_10MS_AGG 6 // Max Overhang 1 +#define OHMAX2_10MS_AGG 9 // Max Overhang 2 +#define OHMAX1_20MS_AGG 3 +#define OHMAX2_20MS_AGG 5 + +#define OHMAX1_30MS_AGG 2 +#define OHMAX2_30MS_AGG 3 + +// Mode 3, Super aggressive thresholds - Different thresholds for the different frame lengths +#define INDIVIDUAL_10MS_VAG 94 +#define INDIVIDUAL_20MS_VAG 94 +#define INDIVIDUAL_30MS_VAG 94 + +#define TOTAL_10MS_VAG 1100 //1700 +#define TOTAL_20MS_VAG 1050 +#define TOTAL_30MS_VAG 1100 + +#define OHMAX1_10MS_VAG 6 // Max Overhang 1 +#define OHMAX2_10MS_VAG 9 // Max Overhang 2 +#define OHMAX1_20MS_VAG 3 +#define OHMAX2_20MS_VAG 5 + +#define OHMAX1_30MS_VAG 2 +#define OHMAX2_30MS_VAG 3 + +#endif // WEBRTC_VAD_DEFINES_H_ diff --git a/src/common_audio/vad/main/source/vad_filterbank.c b/src/common_audio/vad/main/source/vad_filterbank.c new file mode 100644 index 0000000..11392c9 --- /dev/null +++ b/src/common_audio/vad/main/source/vad_filterbank.c @@ -0,0 +1,267 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + + +/* + * This file includes the implementation of the internal filterbank associated functions. + * For function description, see vad_filterbank.h. + */ + +#include "vad_filterbank.h" +#include "vad_defines.h" +#include "vad_const.h" +#include "signal_processing_library.h" + +void WebRtcVad_HpOutput(WebRtc_Word16 *in_vector, + WebRtc_Word16 in_vector_length, + WebRtc_Word16 *out_vector, + WebRtc_Word16 *filter_state) +{ + WebRtc_Word16 i, *pi, *outPtr; + WebRtc_Word32 tmpW32; + + pi = &in_vector[0]; + outPtr = &out_vector[0]; + + // The sum of the absolute values of the impulse response: + // The zero/pole-filter has a max amplification of a single sample of: 1.4546 + // Impulse response: 0.4047 -0.6179 -0.0266 0.1993 0.1035 -0.0194 + // The all-zero section has a max amplification of a single sample of: 1.6189 + // Impulse response: 0.4047 -0.8094 0.4047 0 0 0 + // The all-pole section has a max amplification of a single sample of: 1.9931 + // Impulse response: 1.0000 0.4734 -0.1189 -0.2187 -0.0627 0.04532 + + for (i = 0; i < in_vector_length; i++) + { + // all-zero section (filter coefficients in Q14) + tmpW32 = (WebRtc_Word32)WEBRTC_SPL_MUL_16_16(kHpZeroCoefs[0], (*pi)); + tmpW32 += (WebRtc_Word32)WEBRTC_SPL_MUL_16_16(kHpZeroCoefs[1], filter_state[0]); + tmpW32 += (WebRtc_Word32)WEBRTC_SPL_MUL_16_16(kHpZeroCoefs[2], filter_state[1]); // Q14 + filter_state[1] = filter_state[0]; + filter_state[0] = *pi++; + + // all-pole section + tmpW32 -= (WebRtc_Word32)WEBRTC_SPL_MUL_16_16(kHpPoleCoefs[1], filter_state[2]); // Q14 + tmpW32 -= (WebRtc_Word32)WEBRTC_SPL_MUL_16_16(kHpPoleCoefs[2], filter_state[3]); + filter_state[3] = filter_state[2]; + filter_state[2] = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32 (tmpW32, 14); + *outPtr++ = filter_state[2]; + } +} + +void WebRtcVad_Allpass(WebRtc_Word16 *in_vector, + WebRtc_Word16 *out_vector, + WebRtc_Word16 filter_coefficients, + int vector_length, + WebRtc_Word16 *filter_state) +{ + // The filter can only cause overflow (in the w16 output variable) + // if more than 4 consecutive input numbers are of maximum value and + // has the the same sign as the impulse responses first taps. + // First 6 taps of the impulse response: 0.6399 0.5905 -0.3779 + // 0.2418 -0.1547 0.0990 + + int n; + WebRtc_Word16 tmp16; + WebRtc_Word32 tmp32, in32, state32; + + state32 = WEBRTC_SPL_LSHIFT_W32(((WebRtc_Word32)(*filter_state)), 16); // Q31 + + for (n = 0; n < vector_length; n++) + { + + tmp32 = state32 + WEBRTC_SPL_MUL_16_16(filter_coefficients, (*in_vector)); + tmp16 = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32(tmp32, 16); + *out_vector++ = tmp16; + in32 = WEBRTC_SPL_LSHIFT_W32(((WebRtc_Word32)(*in_vector)), 14); + state32 = in32 - WEBRTC_SPL_MUL_16_16(filter_coefficients, tmp16); + state32 = WEBRTC_SPL_LSHIFT_W32(state32, 1); + in_vector += 2; + } + + *filter_state = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32(state32, 16); +} + +void WebRtcVad_SplitFilter(WebRtc_Word16 *in_vector, + WebRtc_Word16 *out_vector_hp, + WebRtc_Word16 *out_vector_lp, + WebRtc_Word16 *upper_state, + WebRtc_Word16 *lower_state, + int in_vector_length) +{ + WebRtc_Word16 tmpOut; + int k, halflen; + + // Downsampling by 2 and get two branches + halflen = WEBRTC_SPL_RSHIFT_W16(in_vector_length, 1); + + // All-pass filtering upper branch + WebRtcVad_Allpass(&in_vector[0], out_vector_hp, kAllPassCoefsQ15[0], halflen, upper_state); + + // All-pass filtering lower branch + WebRtcVad_Allpass(&in_vector[1], out_vector_lp, kAllPassCoefsQ15[1], halflen, lower_state); + + // Make LP and HP signals + for (k = 0; k < halflen; k++) + { + tmpOut = *out_vector_hp; + *out_vector_hp++ -= *out_vector_lp; + *out_vector_lp++ += tmpOut; + } +} + +WebRtc_Word16 WebRtcVad_get_features(VadInstT *inst, + WebRtc_Word16 *in_vector, + int frame_size, + WebRtc_Word16 *out_vector) +{ + int curlen, filtno; + WebRtc_Word16 vecHP1[120], vecLP1[120]; + WebRtc_Word16 vecHP2[60], vecLP2[60]; + WebRtc_Word16 *ptin; + WebRtc_Word16 *hptout, *lptout; + WebRtc_Word16 power = 0; + + // Split at 2000 Hz and downsample + filtno = 0; + ptin = in_vector; + hptout = vecHP1; + lptout = vecLP1; + curlen = frame_size; + WebRtcVad_SplitFilter(ptin, hptout, lptout, &inst->upper_state[filtno], + &inst->lower_state[filtno], curlen); + + // Split at 3000 Hz and downsample + filtno = 1; + ptin = vecHP1; + hptout = vecHP2; + lptout = vecLP2; + curlen = WEBRTC_SPL_RSHIFT_W16(frame_size, 1); + + WebRtcVad_SplitFilter(ptin, hptout, lptout, &inst->upper_state[filtno], + &inst->lower_state[filtno], curlen); + + // Energy in 3000 Hz - 4000 Hz + curlen = WEBRTC_SPL_RSHIFT_W16(curlen, 1); + WebRtcVad_LogOfEnergy(vecHP2, &out_vector[5], &power, kOffsetVector[5], curlen); + + // Energy in 2000 Hz - 3000 Hz + WebRtcVad_LogOfEnergy(vecLP2, &out_vector[4], &power, kOffsetVector[4], curlen); + + // Split at 1000 Hz and downsample + filtno = 2; + ptin = vecLP1; + hptout = vecHP2; + lptout = vecLP2; + curlen = WEBRTC_SPL_RSHIFT_W16(frame_size, 1); + WebRtcVad_SplitFilter(ptin, hptout, lptout, &inst->upper_state[filtno], + &inst->lower_state[filtno], curlen); + + // Energy in 1000 Hz - 2000 Hz + curlen = WEBRTC_SPL_RSHIFT_W16(curlen, 1); + WebRtcVad_LogOfEnergy(vecHP2, &out_vector[3], &power, kOffsetVector[3], curlen); + + // Split at 500 Hz + filtno = 3; + ptin = vecLP2; + hptout = vecHP1; + lptout = vecLP1; + + WebRtcVad_SplitFilter(ptin, hptout, lptout, &inst->upper_state[filtno], + &inst->lower_state[filtno], curlen); + + // Energy in 500 Hz - 1000 Hz + curlen = WEBRTC_SPL_RSHIFT_W16(curlen, 1); + WebRtcVad_LogOfEnergy(vecHP1, &out_vector[2], &power, kOffsetVector[2], curlen); + // Split at 250 Hz + filtno = 4; + ptin = vecLP1; + hptout = vecHP2; + lptout = vecLP2; + + WebRtcVad_SplitFilter(ptin, hptout, lptout, &inst->upper_state[filtno], + &inst->lower_state[filtno], curlen); + + // Energy in 250 Hz - 500 Hz + curlen = WEBRTC_SPL_RSHIFT_W16(curlen, 1); + WebRtcVad_LogOfEnergy(vecHP2, &out_vector[1], &power, kOffsetVector[1], curlen); + + // Remove DC and LFs + WebRtcVad_HpOutput(vecLP2, curlen, vecHP1, inst->hp_filter_state); + + // Power in 80 Hz - 250 Hz + WebRtcVad_LogOfEnergy(vecHP1, &out_vector[0], &power, kOffsetVector[0], curlen); + + return power; +} + +void WebRtcVad_LogOfEnergy(WebRtc_Word16 *vector, + WebRtc_Word16 *enerlogval, + WebRtc_Word16 *power, + WebRtc_Word16 offset, + int vector_length) +{ + WebRtc_Word16 enerSum = 0; + WebRtc_Word16 zeros, frac, log2; + WebRtc_Word32 energy; + + int shfts = 0, shfts2; + + energy = WebRtcSpl_Energy(vector, vector_length, &shfts); + + if (energy > 0) + { + + shfts2 = 16 - WebRtcSpl_NormW32(energy); + shfts += shfts2; + // "shfts" is the total number of right shifts that has been done to enerSum. + enerSum = (WebRtc_Word16)WEBRTC_SPL_SHIFT_W32(energy, -shfts2); + + // Find: + // 160*log10(enerSum*2^shfts) = 160*log10(2)*log2(enerSum*2^shfts) = + // 160*log10(2)*(log2(enerSum) + log2(2^shfts)) = + // 160*log10(2)*(log2(enerSum) + shfts) + + zeros = WebRtcSpl_NormU32(enerSum); + frac = (WebRtc_Word16)(((WebRtc_UWord32)((WebRtc_Word32)(enerSum) << zeros) + & 0x7FFFFFFF) >> 21); + log2 = (WebRtc_Word16)(((31 - zeros) << 10) + frac); + + *enerlogval = (WebRtc_Word16)WEBRTC_SPL_MUL_16_16_RSFT(kLogConst, log2, 19) + + (WebRtc_Word16)WEBRTC_SPL_MUL_16_16_RSFT(shfts, kLogConst, 9); + + if (*enerlogval < 0) + { + *enerlogval = 0; + } + } else + { + *enerlogval = 0; + shfts = -15; + enerSum = 0; + } + + *enerlogval += offset; + + // Total power in frame + if (*power <= MIN_ENERGY) + { + if (shfts > 0) + { + *power += MIN_ENERGY + 1; + } else if (WEBRTC_SPL_SHIFT_W16(enerSum, shfts) > MIN_ENERGY) + { + *power += MIN_ENERGY + 1; + } else + { + *power += WEBRTC_SPL_SHIFT_W16(enerSum, shfts); + } + } +} diff --git a/src/common_audio/vad/main/source/vad_filterbank.h b/src/common_audio/vad/main/source/vad_filterbank.h new file mode 100644 index 0000000..a5507ea --- /dev/null +++ b/src/common_audio/vad/main/source/vad_filterbank.h @@ -0,0 +1,143 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + + +/* + * This header file includes the description of the internal VAD call + * WebRtcVad_GaussianProbability. + */ + +#ifndef WEBRTC_VAD_FILTERBANK_H_ +#define WEBRTC_VAD_FILTERBANK_H_ + +#include "vad_core.h" + +/**************************************************************************** + * WebRtcVad_HpOutput(...) + * + * This function removes DC from the lowest frequency band + * + * Input: + * - in_vector : Samples in the frequency interval 0 - 250 Hz + * - in_vector_length : Length of input and output vector + * - filter_state : Current state of the filter + * + * Output: + * - out_vector : Samples in the frequency interval 80 - 250 Hz + * - filter_state : Updated state of the filter + * + */ +void WebRtcVad_HpOutput(WebRtc_Word16* in_vector, + WebRtc_Word16 in_vector_length, + WebRtc_Word16* out_vector, + WebRtc_Word16* filter_state); + +/**************************************************************************** + * WebRtcVad_Allpass(...) + * + * This function is used when before splitting a speech file into + * different frequency bands + * + * Note! Do NOT let the arrays in_vector and out_vector correspond to the same address. + * + * Input: + * - in_vector : (Q0) + * - filter_coefficients : (Q15) + * - vector_length : Length of input and output vector + * - filter_state : Current state of the filter (Q(-1)) + * + * Output: + * - out_vector : Output speech signal (Q(-1)) + * - filter_state : Updated state of the filter (Q(-1)) + * + */ +void WebRtcVad_Allpass(WebRtc_Word16* in_vector, + WebRtc_Word16* outw16, + WebRtc_Word16 filter_coefficients, + int vector_length, + WebRtc_Word16* filter_state); + +/**************************************************************************** + * WebRtcVad_SplitFilter(...) + * + * This function is used when before splitting a speech file into + * different frequency bands + * + * Input: + * - in_vector : Input signal to be split into two frequency bands. + * - upper_state : Current state of the upper filter + * - lower_state : Current state of the lower filter + * - in_vector_length : Length of input vector + * + * Output: + * - out_vector_hp : Upper half of the spectrum + * - out_vector_lp : Lower half of the spectrum + * - upper_state : Updated state of the upper filter + * - lower_state : Updated state of the lower filter + * + */ +void WebRtcVad_SplitFilter(WebRtc_Word16* in_vector, + WebRtc_Word16* out_vector_hp, + WebRtc_Word16* out_vector_lp, + WebRtc_Word16* upper_state, + WebRtc_Word16* lower_state, + int in_vector_length); + +/**************************************************************************** + * WebRtcVad_get_features(...) + * + * This function is used to get the logarithm of the power of each of the + * 6 frequency bands used by the VAD: + * 80 Hz - 250 Hz + * 250 Hz - 500 Hz + * 500 Hz - 1000 Hz + * 1000 Hz - 2000 Hz + * 2000 Hz - 3000 Hz + * 3000 Hz - 4000 Hz + * + * Input: + * - inst : Pointer to VAD instance + * - in_vector : Input speech signal + * - frame_size : Frame size, in number of samples + * + * Output: + * - out_vector : 10*log10(power in each freq. band), Q4 + * + * Return: total power in the signal (NOTE! This value is not exact since it + * is only used in a comparison. + */ +WebRtc_Word16 WebRtcVad_get_features(VadInstT* inst, + WebRtc_Word16* in_vector, + int frame_size, + WebRtc_Word16* out_vector); + +/**************************************************************************** + * WebRtcVad_LogOfEnergy(...) + * + * This function is used to get the logarithm of the power of one frequency band. + * + * Input: + * - vector : Input speech samples for one frequency band + * - offset : Offset value for the current frequency band + * - vector_length : Length of input vector + * + * Output: + * - enerlogval : 10*log10(energy); + * - power : Update total power in speech frame. NOTE! This value + * is not exact since it is only used in a comparison. + * + */ +void WebRtcVad_LogOfEnergy(WebRtc_Word16* vector, + WebRtc_Word16* enerlogval, + WebRtc_Word16* power, + WebRtc_Word16 offset, + int vector_length); + +#endif // WEBRTC_VAD_FILTERBANK_H_ diff --git a/src/common_audio/vad/main/source/vad_gmm.c b/src/common_audio/vad/main/source/vad_gmm.c new file mode 100644 index 0000000..23d12fb --- /dev/null +++ b/src/common_audio/vad/main/source/vad_gmm.c @@ -0,0 +1,70 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + + +/* + * This file includes the implementation of the internal VAD call + * WebRtcVad_GaussianProbability. For function description, see vad_gmm.h. + */ + +#include "vad_gmm.h" +#include "signal_processing_library.h" +#include "vad_const.h" + +WebRtc_Word32 WebRtcVad_GaussianProbability(WebRtc_Word16 in_sample, + WebRtc_Word16 mean, + WebRtc_Word16 std, + WebRtc_Word16 *delta) +{ + WebRtc_Word16 tmp16, tmpDiv, tmpDiv2, expVal, tmp16_1, tmp16_2; + WebRtc_Word32 tmp32, y32; + + // Calculate tmpDiv=1/std, in Q10 + tmp32 = (WebRtc_Word32)WEBRTC_SPL_RSHIFT_W16(std,1) + (WebRtc_Word32)131072; // 1 in Q17 + tmpDiv = (WebRtc_Word16)WebRtcSpl_DivW32W16(tmp32, std); // Q17/Q7 = Q10 + + // Calculate tmpDiv2=1/std^2, in Q14 + tmp16 = WEBRTC_SPL_RSHIFT_W16(tmpDiv, 2); // From Q10 to Q8 + tmpDiv2 = (WebRtc_Word16)WEBRTC_SPL_MUL_16_16_RSFT(tmp16, tmp16, 2); // (Q8 * Q8)>>2 = Q14 + + tmp16 = WEBRTC_SPL_LSHIFT_W16(in_sample, 3); // Q7 + tmp16 = tmp16 - mean; // Q7 - Q7 = Q7 + + // To be used later, when updating noise/speech model + // delta = (x-m)/std^2, in Q11 + *delta = (WebRtc_Word16)WEBRTC_SPL_MUL_16_16_RSFT(tmpDiv2, tmp16, 10); //(Q14*Q7)>>10 = Q11 + + // Calculate tmp32=(x-m)^2/(2*std^2), in Q10 + tmp32 = (WebRtc_Word32)WEBRTC_SPL_MUL_16_16_RSFT(*delta, tmp16, 9); // One shift for /2 + + // Calculate expVal ~= exp(-(x-m)^2/(2*std^2)) ~= exp2(-log2(exp(1))*tmp32) + if (tmp32 < kCompVar) + { + // Calculate tmp16 = log2(exp(1))*tmp32 , in Q10 + tmp16 = (WebRtc_Word16)WEBRTC_SPL_MUL_16_16_RSFT((WebRtc_Word16)tmp32, + kLog10Const, 12); + tmp16 = -tmp16; + tmp16_2 = (WebRtc_Word16)(0x0400 | (tmp16 & 0x03FF)); + tmp16_1 = (WebRtc_Word16)(tmp16 ^ 0xFFFF); + tmp16 = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W16(tmp16_1, 10); + tmp16 += 1; + // Calculate expVal=log2(-tmp32), in Q10 + expVal = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32((WebRtc_Word32)tmp16_2, tmp16); + + } else + { + expVal = 0; + } + + // Calculate y32=(1/std)*exp(-(x-m)^2/(2*std^2)), in Q20 + y32 = WEBRTC_SPL_MUL_16_16(tmpDiv, expVal); // Q10 * Q10 = Q20 + + return y32; // Q20 +} diff --git a/src/common_audio/vad/main/source/vad_gmm.h b/src/common_audio/vad/main/source/vad_gmm.h new file mode 100644 index 0000000..e0747fb --- /dev/null +++ b/src/common_audio/vad/main/source/vad_gmm.h @@ -0,0 +1,47 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + + +/* + * This header file includes the description of the internal VAD call + * WebRtcVad_GaussianProbability. + */ + +#ifndef WEBRTC_VAD_GMM_H_ +#define WEBRTC_VAD_GMM_H_ + +#include "typedefs.h" + +/**************************************************************************** + * WebRtcVad_GaussianProbability(...) + * + * This function calculates the probability for the value 'in_sample', given that in_sample + * comes from a normal distribution with mean 'mean' and standard deviation 'std'. + * + * Input: + * - in_sample : Input sample in Q4 + * - mean : mean value in the statistical model, Q7 + * - std : standard deviation, Q7 + * + * Output: + * + * - delta : Value used when updating the model, Q11 + * + * Return: + * - out : out = 1/std * exp(-(x-m)^2/(2*std^2)); + * Probability for x. + * + */ +WebRtc_Word32 WebRtcVad_GaussianProbability(WebRtc_Word16 in_sample, + WebRtc_Word16 mean, + WebRtc_Word16 std, + WebRtc_Word16 *delta); + +#endif // WEBRTC_VAD_GMM_H_ diff --git a/src/common_audio/vad/main/source/vad_sp.c b/src/common_audio/vad/main/source/vad_sp.c new file mode 100644 index 0000000..f347ab5 --- /dev/null +++ b/src/common_audio/vad/main/source/vad_sp.c @@ -0,0 +1,231 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + + +/* + * This file includes the implementation of the VAD internal calls for Downsampling and + * FindMinimum. + * For function call descriptions; See vad_sp.h. + */ + +#include "vad_sp.h" +#include "vad_defines.h" +#include "vad_const.h" +#include "signal_processing_library.h" + +// Downsampling filter based on the splitting filter and the allpass functions +// in vad_filterbank.c +void WebRtcVad_Downsampling(WebRtc_Word16* signal_in, + WebRtc_Word16* signal_out, + WebRtc_Word32* filter_state, + int inlen) +{ + WebRtc_Word16 tmp16_1, tmp16_2; + WebRtc_Word32 tmp32_1, tmp32_2; + int n, halflen; + + // Downsampling by 2 and get two branches + halflen = WEBRTC_SPL_RSHIFT_W16(inlen, 1); + + tmp32_1 = filter_state[0]; + tmp32_2 = filter_state[1]; + + // Filter coefficients in Q13, filter state in Q0 + for (n = 0; n < halflen; n++) + { + // All-pass filtering upper branch + tmp16_1 = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32(tmp32_1, 1) + + (WebRtc_Word16)WEBRTC_SPL_MUL_16_16_RSFT((kAllPassCoefsQ13[0]), + *signal_in, 14); + *signal_out = tmp16_1; + tmp32_1 = (WebRtc_Word32)(*signal_in++) + - (WebRtc_Word32)WEBRTC_SPL_MUL_16_16_RSFT((kAllPassCoefsQ13[0]), tmp16_1, 12); + + // All-pass filtering lower branch + tmp16_2 = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32(tmp32_2, 1) + + (WebRtc_Word16)WEBRTC_SPL_MUL_16_16_RSFT((kAllPassCoefsQ13[1]), + *signal_in, 14); + *signal_out++ += tmp16_2; + tmp32_2 = (WebRtc_Word32)(*signal_in++) + - (WebRtc_Word32)WEBRTC_SPL_MUL_16_16_RSFT((kAllPassCoefsQ13[1]), tmp16_2, 12); + } + filter_state[0] = tmp32_1; + filter_state[1] = tmp32_2; +} + +WebRtc_Word16 WebRtcVad_FindMinimum(VadInstT* inst, + WebRtc_Word16 x, + int n) +{ + int i, j, k, II = -1, offset; + WebRtc_Word16 meanV, alpha; + WebRtc_Word32 tmp32, tmp32_1; + WebRtc_Word16 *valptr, *idxptr, *p1, *p2, *p3; + + // Offset to beginning of the 16 minimum values in memory + offset = WEBRTC_SPL_LSHIFT_W16(n, 4); + + // Pointer to memory for the 16 minimum values and the age of each value + idxptr = &inst->index_vector[offset]; + valptr = &inst->low_value_vector[offset]; + + // Each value in low_value_vector is getting 1 loop older. + // Update age of each value in indexVal, and remove old values. + for (i = 0; i < 16; i++) + { + p3 = idxptr + i; + if (*p3 != 100) + { + *p3 += 1; + } else + { + p1 = valptr + i + 1; + p2 = p3 + 1; + for (j = i; j < 16; j++) + { + *(valptr + j) = *p1++; + *(idxptr + j) = *p2++; + } + *(idxptr + 15) = 101; + *(valptr + 15) = 10000; + } + } + + // Check if x smaller than any of the values in low_value_vector. + // If so, find position. + if (x < *(valptr + 7)) + { + if (x < *(valptr + 3)) + { + if (x < *(valptr + 1)) + { + if (x < *valptr) + { + II = 0; + } else + { + II = 1; + } + } else if (x < *(valptr + 2)) + { + II = 2; + } else + { + II = 3; + } + } else if (x < *(valptr + 5)) + { + if (x < *(valptr + 4)) + { + II = 4; + } else + { + II = 5; + } + } else if (x < *(valptr + 6)) + { + II = 6; + } else + { + II = 7; + } + } else if (x < *(valptr + 15)) + { + if (x < *(valptr + 11)) + { + if (x < *(valptr + 9)) + { + if (x < *(valptr + 8)) + { + II = 8; + } else + { + II = 9; + } + } else if (x < *(valptr + 10)) + { + II = 10; + } else + { + II = 11; + } + } else if (x < *(valptr + 13)) + { + if (x < *(valptr + 12)) + { + II = 12; + } else + { + II = 13; + } + } else if (x < *(valptr + 14)) + { + II = 14; + } else + { + II = 15; + } + } + + // Put new min value on right position and shift bigger values up + if (II > -1) + { + for (i = 15; i > II; i--) + { + k = i - 1; + *(valptr + i) = *(valptr + k); + *(idxptr + i) = *(idxptr + k); + } + *(valptr + II) = x; + *(idxptr + II) = 1; + } + + meanV = 0; + if ((inst->frame_counter) > 4) + { + j = 5; + } else + { + j = inst->frame_counter; + } + + if (j > 2) + { + meanV = *(valptr + 2); + } else if (j > 0) + { + meanV = *valptr; + } else + { + meanV = 1600; + } + + if (inst->frame_counter > 0) + { + if (meanV < inst->mean_value[n]) + { + alpha = (WebRtc_Word16)ALPHA1; // 0.2 in Q15 + } else + { + alpha = (WebRtc_Word16)ALPHA2; // 0.99 in Q15 + } + } else + { + alpha = 0; + } + + tmp32 = WEBRTC_SPL_MUL_16_16((alpha+1), inst->mean_value[n]); + tmp32_1 = WEBRTC_SPL_MUL_16_16(WEBRTC_SPL_WORD16_MAX - alpha, meanV); + tmp32 += tmp32_1; + tmp32 += 16384; + inst->mean_value[n] = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32(tmp32, 15); + + return inst->mean_value[n]; +} diff --git a/src/common_audio/vad/main/source/vad_sp.h b/src/common_audio/vad/main/source/vad_sp.h new file mode 100644 index 0000000..ae15c11 --- /dev/null +++ b/src/common_audio/vad/main/source/vad_sp.h @@ -0,0 +1,60 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + + +/* + * This header file includes the VAD internal calls for Downsampling and FindMinimum. + * Specific function calls are given below. + */ + +#ifndef WEBRTC_VAD_SP_H_ +#define WEBRTC_VAD_SP_H_ + +#include "vad_core.h" + +/**************************************************************************** + * WebRtcVad_Downsampling(...) + * + * Downsamples the signal a factor 2, eg. 32->16 or 16->8 + * + * Input: + * - signal_in : Input signal + * - in_length : Length of input signal in samples + * + * Input & Output: + * - filter_state : Filter state for first all-pass filters + * + * Output: + * - signal_out : Downsampled signal (of length len/2) + */ +void WebRtcVad_Downsampling(WebRtc_Word16* signal_in, + WebRtc_Word16* signal_out, + WebRtc_Word32* filter_state, + int in_length); + +/**************************************************************************** + * WebRtcVad_FindMinimum(...) + * + * Find the five lowest values of x in 100 frames long window. Return a mean + * value of these five values. + * + * Input: + * - feature_value : Feature value + * - channel : Channel number + * + * Input & Output: + * - inst : State information + * + * Output: + * return value : Weighted minimum value for a moving window. + */ +WebRtc_Word16 WebRtcVad_FindMinimum(VadInstT* inst, WebRtc_Word16 feature_value, int channel); + +#endif // WEBRTC_VAD_SP_H_ diff --git a/src/common_audio/vad/main/source/webrtc_vad.c b/src/common_audio/vad/main/source/webrtc_vad.c new file mode 100644 index 0000000..dcfbda1 --- /dev/null +++ b/src/common_audio/vad/main/source/webrtc_vad.c @@ -0,0 +1,197 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + + +/* + * This file includes the VAD API calls. For a specific function call description, + * see webrtc_vad.h + */ + +#include +#include + +#include "webrtc_vad.h" +#include "vad_core.h" + +static const int kInitCheck = 42; + +WebRtc_Word16 WebRtcVad_get_version(char *version, size_t size_bytes) +{ + const char my_version[] = "VAD 1.2.0"; + + if (version == NULL) + { + return -1; + } + + if (size_bytes < sizeof(my_version)) + { + return -1; + } + + memcpy(version, my_version, sizeof(my_version)); + return 0; +} + +WebRtc_Word16 WebRtcVad_AssignSize(int *size_in_bytes) +{ + *size_in_bytes = sizeof(VadInstT) * 2 / sizeof(WebRtc_Word16); + return 0; +} + +WebRtc_Word16 WebRtcVad_Assign(VadInst **vad_inst, void *vad_inst_addr) +{ + + if (vad_inst == NULL) + { + return -1; + } + + if (vad_inst_addr != NULL) + { + *vad_inst = (VadInst*)vad_inst_addr; + return 0; + } else + { + return -1; + } +} + +WebRtc_Word16 WebRtcVad_Create(VadInst **vad_inst) +{ + + VadInstT *vad_ptr = NULL; + + if (vad_inst == NULL) + { + return -1; + } + + *vad_inst = NULL; + + vad_ptr = (VadInstT *)malloc(sizeof(VadInstT)); + *vad_inst = (VadInst *)vad_ptr; + + if (vad_ptr == NULL) + { + return -1; + } + + vad_ptr->init_flag = 0; + + return 0; +} + +WebRtc_Word16 WebRtcVad_Free(VadInst *vad_inst) +{ + + if (vad_inst == NULL) + { + return -1; + } + + free(vad_inst); + return 0; +} + +WebRtc_Word16 WebRtcVad_Init(VadInst *vad_inst) +{ + short mode = 0; // Default high quality + + if (vad_inst == NULL) + { + return -1; + } + + return WebRtcVad_InitCore((VadInstT*)vad_inst, mode); +} + +WebRtc_Word16 WebRtcVad_set_mode(VadInst *vad_inst, WebRtc_Word16 mode) +{ + VadInstT* vad_ptr; + + if (vad_inst == NULL) + { + return -1; + } + + vad_ptr = (VadInstT*)vad_inst; + if (vad_ptr->init_flag != kInitCheck) + { + return -1; + } + + return WebRtcVad_set_mode_core((VadInstT*)vad_inst, mode); +} + +WebRtc_Word16 WebRtcVad_Process(VadInst *vad_inst, + WebRtc_Word16 fs, + WebRtc_Word16 *speech_frame, + WebRtc_Word16 frame_length) +{ + WebRtc_Word16 vad; + VadInstT* vad_ptr; + + if (vad_inst == NULL) + { + return -1; + } + + vad_ptr = (VadInstT*)vad_inst; + if (vad_ptr->init_flag != kInitCheck) + { + return -1; + } + + if (speech_frame == NULL) + { + return -1; + } + + if (fs == 32000) + { + if ((frame_length != 320) && (frame_length != 640) && (frame_length != 960)) + { + return -1; + } + vad = WebRtcVad_CalcVad32khz((VadInstT*)vad_inst, speech_frame, frame_length); + + } else if (fs == 16000) + { + if ((frame_length != 160) && (frame_length != 320) && (frame_length != 480)) + { + return -1; + } + vad = WebRtcVad_CalcVad16khz((VadInstT*)vad_inst, speech_frame, frame_length); + + } else if (fs == 8000) + { + if ((frame_length != 80) && (frame_length != 160) && (frame_length != 240)) + { + return -1; + } + vad = WebRtcVad_CalcVad8khz((VadInstT*)vad_inst, speech_frame, frame_length); + + } else + { + return -1; // Not a supported sampling frequency + } + + if (vad > 0) + { + return 1; + } else if (vad == 0) + { + return 0; + } else + { + return -1; + } +} diff --git a/src/common_audio/vad/main/test/unit_test/unit_test.cc b/src/common_audio/vad/main/test/unit_test/unit_test.cc new file mode 100644 index 0000000..8ac793e --- /dev/null +++ b/src/common_audio/vad/main/test/unit_test/unit_test.cc @@ -0,0 +1,123 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + + +/* + * This file includes the implementation of the VAD unit tests. + */ + +#include +#include "unit_test.h" +#include "webrtc_vad.h" + + +class VadEnvironment : public ::testing::Environment { + public: + virtual void SetUp() { + } + + virtual void TearDown() { + } +}; + +VadTest::VadTest() +{ +} + +void VadTest::SetUp() { +} + +void VadTest::TearDown() { +} + +TEST_F(VadTest, ApiTest) { + VadInst *vad_inst; + int i, j, k; + short zeros[960]; + short speech[960]; + char version[32]; + + // Valid test cases + int fs[3] = {8000, 16000, 32000}; + int nMode[4] = {0, 1, 2, 3}; + int framelen[3][3] = {{80, 160, 240}, + {160, 320, 480}, {320, 640, 960}} ; + int vad_counter = 0; + + memset(zeros, 0, sizeof(short) * 960); + memset(speech, 1, sizeof(short) * 960); + speech[13] = 1374; + speech[73] = -3747; + + + + // WebRtcVad_get_version() + WebRtcVad_get_version(version); + //printf("API Test for %s\n", version); + + // Null instance tests + EXPECT_EQ(-1, WebRtcVad_Create(NULL)); + EXPECT_EQ(-1, WebRtcVad_Init(NULL)); + EXPECT_EQ(-1, WebRtcVad_Assign(NULL, NULL)); + EXPECT_EQ(-1, WebRtcVad_Free(NULL)); + EXPECT_EQ(-1, WebRtcVad_set_mode(NULL, nMode[0])); + EXPECT_EQ(-1, WebRtcVad_Process(NULL, fs[0], speech, framelen[0][0])); + + + EXPECT_EQ(WebRtcVad_Create(&vad_inst), 0); + + // Not initialized tests + EXPECT_EQ(-1, WebRtcVad_Process(vad_inst, fs[0], speech, framelen[0][0])); + EXPECT_EQ(-1, WebRtcVad_set_mode(vad_inst, nMode[0])); + + // WebRtcVad_Init() tests + EXPECT_EQ(WebRtcVad_Init(vad_inst), 0); + + // WebRtcVad_set_mode() tests + EXPECT_EQ(-1, WebRtcVad_set_mode(vad_inst, -1)); + EXPECT_EQ(-1, WebRtcVad_set_mode(vad_inst, 4)); + + for (i = 0; i < sizeof(nMode)/sizeof(nMode[0]); i++) { + EXPECT_EQ(WebRtcVad_set_mode(vad_inst, nMode[i]), 0); + } + + // WebRtcVad_Process() tests + EXPECT_EQ(-1, WebRtcVad_Process(vad_inst, fs[0], NULL, framelen[0][0])); + EXPECT_EQ(-1, WebRtcVad_Process(vad_inst, 12000, speech, framelen[0][0])); + EXPECT_EQ(-1, WebRtcVad_Process(vad_inst, fs[0], speech, framelen[1][1])); + EXPECT_EQ(WebRtcVad_Process(vad_inst, fs[0], zeros, framelen[0][0]), 0); + for (i = 0; i < sizeof(fs)/sizeof(fs[0]); i++) { + for (j = 0; j < sizeof(framelen[0])/sizeof(framelen[0][0]); j++) { + for (k = 0; k < sizeof(nMode)/sizeof(nMode[0]); k++) { + EXPECT_EQ(WebRtcVad_set_mode(vad_inst, nMode[k]), 0); +// printf("%d\n", WebRtcVad_Process(vad_inst, fs[i], speech, framelen[i][j])); + if (vad_counter < 9) + { + EXPECT_EQ(WebRtcVad_Process(vad_inst, fs[i], speech, framelen[i][j]), 1); + } else + { + EXPECT_EQ(WebRtcVad_Process(vad_inst, fs[i], speech, framelen[i][j]), 0); + } + vad_counter++; + } + } + } + + EXPECT_EQ(0, WebRtcVad_Free(vad_inst)); + +} + +int main(int argc, char** argv) { + ::testing::InitGoogleTest(&argc, argv); + VadEnvironment* env = new VadEnvironment; + ::testing::AddGlobalTestEnvironment(env); + + return RUN_ALL_TESTS(); +} diff --git a/src/common_audio/vad/main/test/unit_test/unit_test.h b/src/common_audio/vad/main/test/unit_test/unit_test.h new file mode 100644 index 0000000..62dac11 --- /dev/null +++ b/src/common_audio/vad/main/test/unit_test/unit_test.h @@ -0,0 +1,28 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + + +/* + * This header file includes the declaration of the VAD unit test. + */ + +#ifndef WEBRTC_VAD_UNIT_TEST_H_ +#define WEBRTC_VAD_UNIT_TEST_H_ + +#include + +class VadTest : public ::testing::Test { + protected: + VadTest(); + virtual void SetUp(); + virtual void TearDown(); +}; + +#endif // WEBRTC_VAD_UNIT_TEST_H_ diff --git a/src/common_types.h b/src/common_types.h new file mode 100644 index 0000000..8b0b8a5 --- /dev/null +++ b/src/common_types.h @@ -0,0 +1,595 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +#ifndef WEBRTC_COMMON_TYPES_H +#define WEBRTC_COMMON_TYPES_H + +#include "typedefs.h" + +#ifdef WEBRTC_EXPORT + #define WEBRTC_DLLEXPORT _declspec(dllexport) +#elif WEBRTC_DLL + #define WEBRTC_DLLEXPORT _declspec(dllimport) +#else + #define WEBRTC_DLLEXPORT +#endif + +#ifndef NULL + #define NULL 0 +#endif + +namespace webrtc { + +class InStream +{ +public: + virtual int Read(void *buf,int len) = 0; + virtual int Rewind() {return -1;} + virtual ~InStream() {} +protected: + InStream() {} +}; + +class OutStream +{ +public: + virtual bool Write(const void *buf,int len) = 0; + virtual int Rewind() {return -1;} + virtual ~OutStream() {} +protected: + OutStream() {} +}; + +enum TraceModule +{ + // not a module, triggered from the engine code + kTraceVoice = 0x0001, + // not a module, triggered from the engine code + kTraceVideo = 0x0002, + // not a module, triggered from the utility code + kTraceUtility = 0x0003, + kTraceRtpRtcp = 0x0004, + kTraceTransport = 0x0005, + kTraceSrtp = 0x0006, + kTraceAudioCoding = 0x0007, + kTraceAudioMixerServer = 0x0008, + kTraceAudioMixerClient = 0x0009, + kTraceFile = 0x000a, + kTraceAudioProcessing = 0x000b, + kTraceVideoCoding = 0x0010, + kTraceVideoMixer = 0x0011, + kTraceAudioDevice = 0x0012, + kTraceVideoRenderer = 0x0014, + kTraceVideoCapture = 0x0015, + kTraceVideoPreocessing = 0x0016 +}; + +enum TraceLevel +{ + kTraceNone = 0x0000, // no trace + kTraceStateInfo = 0x0001, + kTraceWarning = 0x0002, + kTraceError = 0x0004, + kTraceCritical = 0x0008, + kTraceApiCall = 0x0010, + kTraceDefault = 0x00ff, + + kTraceModuleCall = 0x0020, + kTraceMemory = 0x0100, // memory info + kTraceTimer = 0x0200, // timing info + kTraceStream = 0x0400, // "continuous" stream of data + + // used for debug purposes + kTraceDebug = 0x0800, // debug + kTraceInfo = 0x1000, // debug info + + kTraceAll = 0xffff +}; + +// External Trace API +class TraceCallback +{ +public: + virtual void Print(const TraceLevel level, + const char *traceString, + const int length) = 0; +protected: + virtual ~TraceCallback() {} + TraceCallback() {} +}; + + +enum FileFormats +{ + kFileFormatWavFile = 1, + kFileFormatCompressedFile = 2, + kFileFormatAviFile = 3, + kFileFormatPreencodedFile = 4, + kFileFormatPcm16kHzFile = 7, + kFileFormatPcm8kHzFile = 8, + kFileFormatPcm32kHzFile = 9 +}; + + +enum ProcessingTypes +{ + kPlaybackPerChannel = 0, + kPlaybackAllChannelsMixed, + kRecordingPerChannel, + kRecordingAllChannelsMixed +}; + +// Encryption enums +enum CipherTypes +{ + kCipherNull = 0, + kCipherAes128CounterMode = 1 +}; + +enum AuthenticationTypes +{ + kAuthNull = 0, + kAuthHmacSha1 = 3 +}; + +enum SecurityLevels +{ + kNoProtection = 0, + kEncryption = 1, + kAuthentication = 2, + kEncryptionAndAuthentication = 3 +}; + +class Encryption +{ +public: + virtual void encrypt( + int channel_no, + unsigned char* in_data, + unsigned char* out_data, + int bytes_in, + int* bytes_out) = 0; + + virtual void decrypt( + int channel_no, + unsigned char* in_data, + unsigned char* out_data, + int bytes_in, + int* bytes_out) = 0; + + virtual void encrypt_rtcp( + int channel_no, + unsigned char* in_data, + unsigned char* out_data, + int bytes_in, + int* bytes_out) = 0; + + virtual void decrypt_rtcp( + int channel_no, + unsigned char* in_data, + unsigned char* out_data, + int bytes_in, + int* bytes_out) = 0; + +protected: + virtual ~Encryption() {} + Encryption() {} +}; + +// External transport callback interface +class Transport +{ +public: + virtual int SendPacket(int channel, const void *data, int len) = 0; + virtual int SendRTCPPacket(int channel, const void *data, int len) = 0; + +protected: + virtual ~Transport() {} + Transport() {} +}; + +// ================================================================== +// Voice specific types +// ================================================================== + +// Each codec supported can be described by this structure. +struct CodecInst +{ + int pltype; + char plname[32]; + int plfreq; + int pacsize; + int channels; + int rate; +}; + +enum FrameType +{ + kFrameEmpty = 0, + kAudioFrameSpeech = 1, + kAudioFrameCN = 2, + kVideoFrameKey = 3, // independent frame + kVideoFrameDelta = 4, // depends on the previus frame + kVideoFrameGolden = 5, // depends on a old known previus frame + kVideoFrameAltRef = 6 +}; + +// RTP +enum {kRtpCsrcSize = 15}; // RFC 3550 page 13 + +enum RTPDirections +{ + kRtpIncoming = 0, + kRtpOutgoing +}; + +enum PayloadFrequencies +{ + kFreq8000Hz = 8000, + kFreq16000Hz = 16000, + kFreq32000Hz = 32000 +}; + +enum VadModes // degree of bandwidth reduction +{ + kVadConventional = 0, // lowest reduction + kVadAggressiveLow, + kVadAggressiveMid, + kVadAggressiveHigh // highest reduction +}; + +struct NetworkStatistics // NETEQ statistics +{ + // current jitter buffer size in ms + WebRtc_UWord16 currentBufferSize; + // preferred (optimal) buffer size in ms + WebRtc_UWord16 preferredBufferSize; + // loss rate (network + late) in percent (in Q14) + WebRtc_UWord16 currentPacketLossRate; + // late loss rate in percent (in Q14) + WebRtc_UWord16 currentDiscardRate; + // fraction (of original stream) of synthesized speech inserted through + // expansion (in Q14) + WebRtc_UWord16 currentExpandRate; + // fraction of synthesized speech inserted through pre-emptive expansion + // (in Q14) + WebRtc_UWord16 currentPreemptiveRate; + // fraction of data removed through acceleration (in Q14) + WebRtc_UWord16 currentAccelerateRate; +}; + +struct JitterStatistics +{ + // smallest Jitter Buffer size during call in ms + WebRtc_UWord32 jbMinSize; + // largest Jitter Buffer size during call in ms + WebRtc_UWord32 jbMaxSize; + // the average JB size, measured over time - ms + WebRtc_UWord32 jbAvgSize; + // number of times the Jitter Buffer changed (using Accelerate or + // Pre-emptive Expand) + WebRtc_UWord32 jbChangeCount; + // amount (in ms) of audio data received late + WebRtc_UWord32 lateLossMs; + // milliseconds removed to reduce jitter buffer size + WebRtc_UWord32 accelerateMs; + // milliseconds discarded through buffer flushing + WebRtc_UWord32 flushedMs; + // milliseconds of generated silence + WebRtc_UWord32 generatedSilentMs; + // milliseconds of synthetic audio data (non-background noise) + WebRtc_UWord32 interpolatedVoiceMs; + // milliseconds of synthetic audio data (background noise level) + WebRtc_UWord32 interpolatedSilentMs; + // count of tiny expansions in output audio + WebRtc_UWord32 countExpandMoreThan120ms; + // count of small expansions in output audio + WebRtc_UWord32 countExpandMoreThan250ms; + // count of medium expansions in output audio + WebRtc_UWord32 countExpandMoreThan500ms; + // count of long expansions in output audio + WebRtc_UWord32 countExpandMoreThan2000ms; + // duration of longest audio drop-out + WebRtc_UWord32 longestExpandDurationMs; + // count of times we got small network outage (inter-arrival time in + // [500, 1000) ms) + WebRtc_UWord32 countIAT500ms; + // count of times we got medium network outage (inter-arrival time in + // [1000, 2000) ms) + WebRtc_UWord32 countIAT1000ms; + // count of times we got large network outage (inter-arrival time >= + // 2000 ms) + WebRtc_UWord32 countIAT2000ms; + // longest packet inter-arrival time in ms + WebRtc_UWord32 longestIATms; + // min time incoming Packet "waited" to be played + WebRtc_UWord32 minPacketDelayMs; + // max time incoming Packet "waited" to be played + WebRtc_UWord32 maxPacketDelayMs; + // avg time incoming Packet "waited" to be played + WebRtc_UWord32 avgPacketDelayMs; +}; + +typedef struct +{ + int min; // minumum + int max; // maximum + int average; // average +} StatVal; + +typedef struct // All levels are reported in dBm0 +{ + StatVal speech_rx; // long-term speech levels on receiving side + StatVal speech_tx; // long-term speech levels on transmitting side + StatVal noise_rx; // long-term noise/silence levels on receiving side + StatVal noise_tx; // long-term noise/silence levels on transmitting side +} LevelStatistics; + +typedef struct // All levels are reported in dB +{ + StatVal erl; // Echo Return Loss + StatVal erle; // Echo Return Loss Enhancement + StatVal rerl; // RERL = ERL + ERLE + // Echo suppression inside EC at the point just before its NLP + StatVal a_nlp; +} EchoStatistics; + +enum TelephoneEventDetectionMethods +{ + kInBand = 0, + kOutOfBand = 1, + kInAndOutOfBand = 2 +}; + +enum NsModes // type of Noise Suppression +{ + kNsUnchanged = 0, // previously set mode + kNsDefault, // platform default + kNsConference, // conferencing default + kNsLowSuppression, // lowest suppression + kNsModerateSuppression, + kNsHighSuppression, + kNsVeryHighSuppression, // highest suppression +}; + +enum AgcModes // type of Automatic Gain Control +{ + kAgcUnchanged = 0, // previously set mode + kAgcDefault, // platform default + // adaptive mode for use when analog volume control exists (e.g. for + // PC softphone) + kAgcAdaptiveAnalog, + // scaling takes place in the digital domain (e.g. for conference servers + // and embedded devices) + kAgcAdaptiveDigital, + // can be used on embedded devices where the the capture signal is level + // is predictable + kAgcFixedDigital +}; + +// EC modes +enum EcModes // type of Echo Control +{ + kEcUnchanged = 0, // previously set mode + kEcDefault, // platform default + kEcConference, // conferencing default (aggressive AEC) + kEcAec, // Acoustic Echo Cancellation + kEcAecm, // AEC mobile +}; + +// AECM modes +enum AecmModes // mode of AECM +{ + kAecmQuietEarpieceOrHeadset = 0, + // Quiet earpiece or headset use + kAecmEarpiece, // most earpiece use + kAecmLoudEarpiece, // Loud earpiece or quiet speakerphone use + kAecmSpeakerphone, // most speakerphone use (default) + kAecmLoudSpeakerphone // Loud speakerphone +}; + +// AGC configuration +typedef struct +{ + unsigned short targetLeveldBOv; + unsigned short digitalCompressionGaindB; + bool limiterEnable; +} AgcConfig; // AGC configuration parameters + +enum StereoChannel +{ + kStereoLeft = 0, + kStereoRight, + kStereoBoth +}; + +// Audio device layers +enum AudioLayers +{ + kAudioPlatformDefault = 0, + kAudioWindowsWave = 1, + kAudioWindowsCore = 2, + kAudioLinuxAlsa = 3, + kAudioLinuxPulse = 4 +}; + +enum NetEqModes // NetEQ playout configurations +{ + // Optimized trade-off between low delay and jitter robustness for two-way + // communication. + kNetEqDefault = 0, + // Improved jitter robustness at the cost of increased delay. Can be + // used in one-way communication. + kNetEqStreaming = 1, + // Optimzed for decodability of fax signals rather than for perceived audio + // quality. + kNetEqFax = 2, +}; + +enum NetEqBgnModes // NetEQ Background Noise (BGN) configurations +{ + // BGN is always on and will be generated when the incoming RTP stream + // stops (default). + kBgnOn = 0, + // The BGN is faded to zero (complete silence) after a few seconds. + kBgnFade = 1, + // BGN is not used at all. Silence is produced after speech extrapolation + // has faded. + kBgnOff = 2, +}; + +enum OnHoldModes // On Hold direction +{ + kHoldSendAndPlay = 0, // Put both sending and playing in on-hold state. + kHoldSendOnly, // Put only sending in on-hold state. + kHoldPlayOnly // Put only playing in on-hold state. +}; + +enum AmrMode +{ + kRfc3267BwEfficient = 0, + kRfc3267OctetAligned = 1, + kRfc3267FileStorage = 2, +}; + +// ================================================================== +// Video specific types +// ================================================================== + +// Raw video types +enum RawVideoType +{ + kVideoI420 = 0, + kVideoYV12 = 1, + kVideoYUY2 = 2, + kVideoUYVY = 3, + kVideoIYUV = 4, + kVideoARGB = 5, + kVideoRGB24 = 6, + kVideoRGB565 = 7, + kVideoARGB4444 = 8, + kVideoARGB1555 = 9, + kVideoMJPEG = 10, + kVideoNV12 = 11, + kVideoNV21 = 12, + kVideoUnknown = 99 +}; + +// Video codec +enum { kConfigParameterSize = 128}; +enum { kPayloadNameSize = 32}; + +// H.263 specific +struct VideoCodecH263 +{ + char quality; +}; + +// H.264 specific +enum H264Packetization +{ + kH264SingleMode = 0, + kH264NonInterleavedMode = 1 +}; + +enum VideoCodecComplexity +{ + kComplexityNormal = 0, + kComplexityHigh = 1, + kComplexityHigher = 2, + kComplexityMax = 3 +}; + +enum VideoCodecProfile +{ + kProfileBase = 0x00, + kProfileMain = 0x01 +}; + +struct VideoCodecH264 +{ + H264Packetization packetization; + VideoCodecComplexity complexity; + VideoCodecProfile profile; + char level; + char quality; + + bool useFMO; + + unsigned char configParameters[kConfigParameterSize]; + unsigned char configParametersSize; +}; + +// VP8 specific +struct VideoCodecVP8 +{ + bool pictureLossIndicationOn; + bool feedbackModeOn; + VideoCodecComplexity complexity; +}; + +// MPEG-4 specific +struct VideoCodecMPEG4 +{ + unsigned char configParameters[kConfigParameterSize]; + unsigned char configParametersSize; + char level; +}; + +// Unknown specific +struct VideoCodecGeneric +{ +}; + +// Video codec types +enum VideoCodecType +{ + kVideoCodecH263, + kVideoCodecH264, + kVideoCodecVP8, + kVideoCodecMPEG4, + kVideoCodecI420, + kVideoCodecRED, + kVideoCodecULPFEC, + kVideoCodecUnknown +}; + +union VideoCodecUnion +{ + VideoCodecH263 H263; + VideoCodecH264 H264; + VideoCodecVP8 VP8; + VideoCodecMPEG4 MPEG4; + VideoCodecGeneric Generic; +}; + +// Common video codec properties +struct VideoCodec +{ + VideoCodecType codecType; + char plName[kPayloadNameSize]; + unsigned char plType; + + unsigned short width; + unsigned short height; + + unsigned int startBitrate; + unsigned int maxBitrate; + unsigned int minBitrate; + unsigned char maxFramerate; + + VideoCodecUnion codecSpecific; + + unsigned int qpMax; +}; + +} // namespace webrtc + +#endif // WEBRTC_COMMON_TYPES_H diff --git a/src/modules/audio_processing/OWNERS b/src/modules/audio_processing/OWNERS new file mode 100644 index 0000000..5a25634 --- /dev/null +++ b/src/modules/audio_processing/OWNERS @@ -0,0 +1,2 @@ +andrew@webrtc.org +bjornv@webrtc.org diff --git a/src/modules/audio_processing/aec/main/interface/echo_cancellation.h b/src/modules/audio_processing/aec/main/interface/echo_cancellation.h new file mode 100644 index 0000000..883357d --- /dev/null +++ b/src/modules/audio_processing/aec/main/interface/echo_cancellation.h @@ -0,0 +1,260 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +#ifndef WEBRTC_MODULES_AUDIO_PROCESSING_AEC_MAIN_INTERFACE_ECHO_CANCELLATION_H_ +#define WEBRTC_MODULES_AUDIO_PROCESSING_AEC_MAIN_INTERFACE_ECHO_CANCELLATION_H_ + +#include "typedefs.h" + +// Errors +#define AEC_UNSPECIFIED_ERROR 12000 +#define AEC_UNSUPPORTED_FUNCTION_ERROR 12001 +#define AEC_UNINITIALIZED_ERROR 12002 +#define AEC_NULL_POINTER_ERROR 12003 +#define AEC_BAD_PARAMETER_ERROR 12004 + +// Warnings +#define AEC_BAD_PARAMETER_WARNING 12050 + +enum { + kAecNlpConservative = 0, + kAecNlpModerate, + kAecNlpAggressive +}; + +enum { + kAecFalse = 0, + kAecTrue +}; + +typedef struct { + WebRtc_Word16 nlpMode; // default kAecNlpModerate + WebRtc_Word16 skewMode; // default kAecFalse + WebRtc_Word16 metricsMode; // default kAecFalse + //float realSkew; +} AecConfig; + +typedef struct { + WebRtc_Word16 instant; + WebRtc_Word16 average; + WebRtc_Word16 max; + WebRtc_Word16 min; +} AecLevel; + +typedef struct { + AecLevel rerl; + AecLevel erl; + AecLevel erle; + AecLevel aNlp; +} AecMetrics; + +#ifdef __cplusplus +extern "C" { +#endif + +/* + * Allocates the memory needed by the AEC. The memory needs to be initialized + * separately using the WebRtcAec_Init() function. + * + * Inputs Description + * ------------------------------------------------------------------- + * void **aecInst Pointer to the AEC instance to be created + * and initilized + * + * Outputs Description + * ------------------------------------------------------------------- + * WebRtc_Word32 return 0: OK + * -1: error + */ +WebRtc_Word32 WebRtcAec_Create(void **aecInst); + +/* + * This function releases the memory allocated by WebRtcAec_Create(). + * + * Inputs Description + * ------------------------------------------------------------------- + * void *aecInst Pointer to the AEC instance + * + * Outputs Description + * ------------------------------------------------------------------- + * WebRtc_Word32 return 0: OK + * -1: error + */ +WebRtc_Word32 WebRtcAec_Free(void *aecInst); + +/* + * Initializes an AEC instance. + * + * Inputs Description + * ------------------------------------------------------------------- + * void *aecInst Pointer to the AEC instance + * WebRtc_Word32 sampFreq Sampling frequency of data + * WebRtc_Word32 scSampFreq Soundcard sampling frequency + * + * Outputs Description + * ------------------------------------------------------------------- + * WebRtc_Word32 return 0: OK + * -1: error + */ +WebRtc_Word32 WebRtcAec_Init(void *aecInst, + WebRtc_Word32 sampFreq, + WebRtc_Word32 scSampFreq); + +/* + * Inserts an 80 or 160 sample block of data into the farend buffer. + * + * Inputs Description + * ------------------------------------------------------------------- + * void *aecInst Pointer to the AEC instance + * WebRtc_Word16 *farend In buffer containing one frame of + * farend signal for L band + * WebRtc_Word16 nrOfSamples Number of samples in farend buffer + * + * Outputs Description + * ------------------------------------------------------------------- + * WebRtc_Word32 return 0: OK + * -1: error + */ +WebRtc_Word32 WebRtcAec_BufferFarend(void *aecInst, + const WebRtc_Word16 *farend, + WebRtc_Word16 nrOfSamples); + +/* + * Runs the echo canceller on an 80 or 160 sample blocks of data. + * + * Inputs Description + * ------------------------------------------------------------------- + * void *aecInst Pointer to the AEC instance + * WebRtc_Word16 *nearend In buffer containing one frame of + * nearend+echo signal for L band + * WebRtc_Word16 *nearendH In buffer containing one frame of + * nearend+echo signal for H band + * WebRtc_Word16 nrOfSamples Number of samples in nearend buffer + * WebRtc_Word16 msInSndCardBuf Delay estimate for sound card and + * system buffers + * WebRtc_Word16 skew Difference between number of samples played + * and recorded at the soundcard (for clock skew + * compensation) + * + * Outputs Description + * ------------------------------------------------------------------- + * WebRtc_Word16 *out Out buffer, one frame of processed nearend + * for L band + * WebRtc_Word16 *outH Out buffer, one frame of processed nearend + * for H band + * WebRtc_Word32 return 0: OK + * -1: error + */ +WebRtc_Word32 WebRtcAec_Process(void *aecInst, + const WebRtc_Word16 *nearend, + const WebRtc_Word16 *nearendH, + WebRtc_Word16 *out, + WebRtc_Word16 *outH, + WebRtc_Word16 nrOfSamples, + WebRtc_Word16 msInSndCardBuf, + WebRtc_Word32 skew); + +/* + * This function enables the user to set certain parameters on-the-fly. + * + * Inputs Description + * ------------------------------------------------------------------- + * void *aecInst Pointer to the AEC instance + * AecConfig config Config instance that contains all + * properties to be set + * + * Outputs Description + * ------------------------------------------------------------------- + * WebRtc_Word32 return 0: OK + * -1: error + */ +WebRtc_Word32 WebRtcAec_set_config(void *aecInst, AecConfig config); + +/* + * Gets the on-the-fly paramters. + * + * Inputs Description + * ------------------------------------------------------------------- + * void *aecInst Pointer to the AEC instance + * + * Outputs Description + * ------------------------------------------------------------------- + * AecConfig *config Pointer to the config instance that + * all properties will be written to + * WebRtc_Word32 return 0: OK + * -1: error + */ +WebRtc_Word32 WebRtcAec_get_config(void *aecInst, AecConfig *config); + +/* + * Gets the current echo status of the nearend signal. + * + * Inputs Description + * ------------------------------------------------------------------- + * void *aecInst Pointer to the AEC instance + * + * Outputs Description + * ------------------------------------------------------------------- + * WebRtc_Word16 *status 0: Almost certainly nearend single-talk + * 1: Might not be neared single-talk + * WebRtc_Word32 return 0: OK + * -1: error + */ +WebRtc_Word32 WebRtcAec_get_echo_status(void *aecInst, WebRtc_Word16 *status); + +/* + * Gets the current echo metrics for the session. + * + * Inputs Description + * ------------------------------------------------------------------- + * void *aecInst Pointer to the AEC instance + * + * Outputs Description + * ------------------------------------------------------------------- + * AecMetrics *metrics Struct which will be filled out with the + * current echo metrics. + * WebRtc_Word32 return 0: OK + * -1: error + */ +WebRtc_Word32 WebRtcAec_GetMetrics(void *aecInst, AecMetrics *metrics); + +/* + * Gets the last error code. + * + * Inputs Description + * ------------------------------------------------------------------- + * void *aecInst Pointer to the AEC instance + * + * Outputs Description + * ------------------------------------------------------------------- + * WebRtc_Word32 return 11000-11100: error code + */ +WebRtc_Word32 WebRtcAec_get_error_code(void *aecInst); + +/* + * Gets a version string. + * + * Inputs Description + * ------------------------------------------------------------------- + * char *versionStr Pointer to a string array + * WebRtc_Word16 len The maximum length of the string + * + * Outputs Description + * ------------------------------------------------------------------- + * WebRtc_Word8 *versionStr Pointer to a string array + * WebRtc_Word32 return 0: OK + * -1: error + */ +WebRtc_Word32 WebRtcAec_get_version(WebRtc_Word8 *versionStr, WebRtc_Word16 len); + +#ifdef __cplusplus +} +#endif +#endif /* WEBRTC_MODULES_AUDIO_PROCESSING_AEC_MAIN_INTERFACE_ECHO_CANCELLATION_H_ */ diff --git a/src/modules/audio_processing/aec/main/matlab/fullaec.m b/src/modules/audio_processing/aec/main/matlab/fullaec.m new file mode 100644 index 0000000..0f86a8c --- /dev/null +++ b/src/modules/audio_processing/aec/main/matlab/fullaec.m @@ -0,0 +1,953 @@ +% Partitioned block frequency domain adaptive filtering NLMS and +% standard time-domain sample-based NLMS +%fid=fopen('aecFar-samsung.pcm', 'rb'); % Load far end +fid=fopen('aecFar.pcm', 'rb'); % Load far end +%fid=fopen(farFile, 'rb'); % Load far end +rrin=fread(fid,inf,'int16'); +fclose(fid); +%rrin=loadsl('data/far_me2.pcm'); % Load far end +%fid=fopen('aecNear-samsung.pcm', 'rb'); % Load near end +fid=fopen('aecNear.pcm', 'rb'); % Load near end +%fid=fopen(nearFile, 'rb'); % Load near end +ssin=fread(fid,inf,'int16'); +%ssin = [zeros(1024,1) ; ssin(1:end-1024)]; + +fclose(fid); +rand('state',13); +fs=16000; +mult=fs/8000; +%rrin=rrin(fs*0+1:round(fs*120)); +%ssin=ssin(fs*0+1:round(fs*120)); +if fs == 8000 + cohRange = 2:3; +elseif fs==16000 + cohRange = 2; +end + +% Flags +NLPon=1; % NLP +CNon=1; % Comfort noise +PLTon=1; % Plotting + +M = 16; % Number of partitions +N = 64; % Partition length +L = M*N; % Filter length +if fs == 8000 + mufb = 0.6; +else + mufb = 0.5; +end +%mufb=1; +VADtd=48; +alp = 0.1; % Power estimation factor alc = 0.1; % Coherence estimation factor +beta = 0.9; % Plotting factor +%% Changed a little %% +step = 0.3;%0.1875; % Downward step size +%% +if fs == 8000 + threshold=2e-6; % DTrob threshold +else + %threshold=0.7e-6; + threshold=1.5e-6; end + +if fs == 8000 + echoBandRange = ceil(300*2/fs*N):floor(1800*2/fs*N); + %echoBandRange = ceil(1500*2/fs*N):floor(2500*2/fs*N); +else + echoBandRange = ceil(300*2/fs*N):floor(1800*2/fs*N); + %echoBandRange = ceil(300*2/fs*N):floor(1800*2/fs*N); +end +%echoBandRange = ceil(1600*2/fs*N):floor(1900*2/fs*N); +%echoBandRange = ceil(2000*2/fs*N):floor(4000*2/fs*N); +suppState = 1; +transCtr = 0; + +Nt=1; +vt=1; + +ramp = 1.0003; % Upward ramp +rampd = 0.999; % Downward ramp +cvt = 20; % Subband VAD threshold; +nnthres = 20; % Noise threshold + +shh=logspace(-1.3,-2.2,N+1)'; +sh=[shh;flipud(shh(2:end-1))]; % Suppression profile + +len=length(ssin); +w=zeros(L,1); % Sample-based TD NLMS +WFb=zeros(N+1,M); % Block-based FD NLMS +WFbOld=zeros(N+1,M); % Block-based FD NLMS +YFb=zeros(N+1,M); +erfb=zeros(len,1); +erfb3=zeros(len,1); + +ercn=zeros(len,1); +zm=zeros(N,1); +XFm=zeros(N+1,M); +YFm=zeros(N+1,M); +pn0=10*ones(N+1,1); +pn=zeros(N+1,1); +NN=len; +Nb=floor(NN/N)-M; +erifb=zeros(Nb+1,1)+0.1; +erifb3=zeros(Nb+1,1)+0.1; +ericn=zeros(Nb+1,1)+0.1; +dri=zeros(Nb+1,1)+0.1; +start=1; +xo=zeros(N,1); +do=xo; +eo=xo; + +echoBands=zeros(Nb+1,1); +cohxdAvg=zeros(Nb+1,1); +cohxdSlow=zeros(Nb+1,N+1); +cohedSlow=zeros(Nb+1,N+1); +%overdriveM=zeros(Nb+1,N+1); +cohxdFastAvg=zeros(Nb+1,1); +cohxdAvgBad=zeros(Nb+1,1); +cohedAvg=zeros(Nb+1,1); +cohedFastAvg=zeros(Nb+1,1); +hnledAvg=zeros(Nb+1,1); +hnlxdAvg=zeros(Nb+1,1); +ovrdV=zeros(Nb+1,1); +dIdxV=zeros(Nb+1,1); +SLxV=zeros(Nb+1,1); +hnlSortQV=zeros(Nb+1,1); +hnlPrefAvgV=zeros(Nb+1,1); +mutInfAvg=zeros(Nb+1,1); +%overdrive=zeros(Nb+1,1); +hnled = zeros(N+1, 1); +weight=zeros(N+1,1); +hnlMax = zeros(N+1, 1); +hnl = zeros(N+1, 1); +overdrive = ones(1, N+1); +xfwm=zeros(N+1,M); +dfm=zeros(N+1,M); +WFbD=ones(N+1,1); + +fbSupp = 0; +hnlLocalMin = 1; +cohxdLocalMin = 1; +hnlLocalMinV=zeros(Nb+1,1); +cohxdLocalMinV=zeros(Nb+1,1); +hnlMinV=zeros(Nb+1,1); +dkEnV=zeros(Nb+1,1); +ekEnV=zeros(Nb+1,1); +ovrd = 2; +ovrdPos = floor((N+1)/4); +ovrdSm = 2; +hnlMin = 1; +minCtr = 0; +SeMin = 0; +SdMin = 0; +SeLocalAvg = 0; +SeMinSm = 0; +divergeFact = 1; +dIdx = 1; +hnlMinCtr = 0; +hnlNewMin = 0; +divergeState = 0; + +Sy=ones(N+1,1); +Sym=1e7*ones(N+1,1); + +wins=[0;sqrt(hanning(2*N-1))]; +ubufn=zeros(2*N,1); +ebuf=zeros(2*N,1); +ebuf2=zeros(2*N,1); +ebuf4=zeros(2*N,1); +mbuf=zeros(2*N,1); + +cohedFast = zeros(N+1,1); +cohxdFast = zeros(N+1,1); +cohxd = zeros(N+1,1); +Se = zeros(N+1,1); +Sd = zeros(N+1,1); +Sx = zeros(N+1,1); +SxBad = zeros(N+1,1); +Sed = zeros(N+1,1); +Sxd = zeros(N+1,1); +SxdBad = zeros(N+1,1); +hnledp=[]; + +cohxdMax = 0; + +%hh=waitbar(0,'Please wait...'); +progressbar(0); + +%spaces = ' '; +%spaces = repmat(spaces, 50, 1); +%spaces = ['[' ; spaces ; ']']; +%fprintf(1, spaces); +%fprintf(1, '\n'); + +for kk=1:Nb + pos = N * (kk-1) + start; + + % FD block method + % ---------------------- Organize data + xk = rrin(pos:pos+N-1); + dk = ssin(pos:pos+N-1); + + xx = [xo;xk]; + xo = xk; + tmp = fft(xx); + XX = tmp(1:N+1); + + dd = [do;dk]; % Overlap + do = dk; + tmp = fft(dd); % Frequency domain + DD = tmp(1:N+1); + + % ------------------------ Power estimation + pn0 = (1 - alp) * pn0 + alp * real(XX.* conj(XX)); + pn = pn0; + %pn = (1 - alp) * pn + alp * M * pn0; + if (CNon) + Yp = real(conj(DD).*DD); % Instantaneous power + Sy = (1 - alp) * Sy + alp * Yp; % Averaged power + + mm = min(Sy,Sym); + diff = Sym - mm; + if (kk>50) + Sym = (mm + step*diff) * ramp; % Estimated background noise power + end + end + + % ---------------------- Filtering + XFm(:,1) = XX; + for mm=0:(M-1) + m=mm+1; + YFb(:,m) = XFm(:,m) .* WFb(:,m); + end + yfk = sum(YFb,2); + tmp = [yfk ; flipud(conj(yfk(2:N)))]; + ykt = real(ifft(tmp)); + ykfb = ykt(end-N+1:end); + + % ---------------------- Error estimation + ekfb = dk - ykfb; + %if sum(abs(ekfb)) < sum(abs(dk)) + %ekfb = dk - ykfb; + % erfb(pos:pos+N-1) = ekfb; + %else + %ekfb = dk; + % erfb(pos:pos+N-1) = dk; + %end + %(kk-1)*(N*2)+1 + erfb(pos:pos+N-1) = ekfb; + tmp = fft([zm;ekfb]); % FD version for cancelling part (overlap-save) + Ek = tmp(1:N+1); + + % ------------------------ Adaptation + Ek2 = Ek ./(M*pn + 0.001); % Normalized error + %Ek2 = Ek ./(pn + 0.001); % Normalized error + %Ek2 = Ek ./(100*pn + 0.001); % Normalized error + + absEf = max(abs(Ek2), threshold); + absEf = ones(N+1,1)*threshold./absEf; + Ek2 = Ek2.*absEf; + + mEk = mufb.*Ek2; + PP = conj(XFm).*(ones(M,1) * mEk')'; + tmp = [PP ; flipud(conj(PP(2:N,:)))]; + IFPP = real(ifft(tmp)); + PH = IFPP(1:N,:); + tmp = fft([PH;zeros(N,M)]); + FPH = tmp(1:N+1,:); + WFb = WFb + FPH; + + if mod(kk, 10*mult) == 0 + WFbEn = sum(real(WFb.*conj(WFb))); + %WFbEn = sum(abs(WFb)); + [tmp, dIdx] = max(WFbEn); + + WFbD = sum(abs(WFb(:, dIdx)),2); + %WFbD = WFbD / (mean(WFbD) + 1e-10); + WFbD = min(max(WFbD, 0.5), 4); + end + dIdxV(kk) = dIdx; + + % NLP + if (NLPon) + + ee = [eo;ekfb]; + eo = ekfb; + window = wins; + if fs == 8000 + %gamma = 0.88; + gamma = 0.9; + else + %gamma = 0.92; + gamma = 0.93; + end + %gamma = 0.9; + + tmp = fft(xx.*window); + xf = tmp(1:N+1); + tmp = fft(dd.*window); + df = tmp(1:N+1); + tmp = fft(ee.*window); + ef = tmp(1:N+1); + + xfwm(:,1) = xf; + xf = xfwm(:,dIdx); + %fprintf(1,'%d: %f\n', kk, xf(4)); + dfm(:,1) = df; + + SxOld = Sx; + + Se = gamma*Se + (1-gamma)*real(ef.*conj(ef)); + Sd = gamma*Sd + (1-gamma)*real(df.*conj(df)); + Sx = gamma*Sx + (1 - gamma)*real(xf.*conj(xf)); + + %xRatio = real(xfwm(:,1).*conj(xfwm(:,1))) ./ ... + % (real(xfwm(:,2).*conj(xfwm(:,2))) + 1e-10); + %xRatio = Sx ./ (SxOld + 1e-10); + %SLx = log(1/(N+1)*sum(xRatio)) - 1/(N+1)*sum(log(xRatio)); + %SLxV(kk) = SLx; + + %freqSm = 0.9; + %Sx = filter(freqSm, [1 -(1-freqSm)], Sx); + %Sx(end:1) = filter(freqSm, [1 -(1-freqSm)], Sx(end:1)); + %Se = filter(freqSm, [1 -(1-freqSm)], Se); + %Se(end:1) = filter(freqSm, [1 -(1-freqSm)], Se(end:1)); + %Sd = filter(freqSm, [1 -(1-freqSm)], Sd); + %Sd(end:1) = filter(freqSm, [1 -(1-freqSm)], Sd(end:1)); + + %SeFast = ef.*conj(ef); + %SdFast = df.*conj(df); + %SxFast = xf.*conj(xf); + %cohedFast = 0.9*cohedFast + 0.1*SeFast ./ (SdFast + 1e-10); + %cohedFast(find(cohedFast > 1)) = 1; + %cohedFast(find(cohedFast > 1)) = 1 ./ cohedFast(find(cohedFast>1)); + %cohedFastAvg(kk) = mean(cohedFast(echoBandRange)); + %cohedFastAvg(kk) = min(cohedFast); + + %cohxdFast = 0.8*cohxdFast + 0.2*log(SdFast ./ (SxFast + 1e-10)); + %cohxdFastAvg(kk) = mean(cohxdFast(echoBandRange)); + + % coherence + Sxd = gamma*Sxd + (1 - gamma)*xf.*conj(df); + Sed = gamma*Sed + (1-gamma)*ef.*conj(df); + + %Sxd = filter(freqSm, [1 -(1-freqSm)], Sxd); + %Sxd(end:1) = filter(freqSm, [1 -(1-freqSm)], Sxd(end:1)); + %Sed = filter(freqSm, [1 -(1-freqSm)], Sed); + %Sed(end:1) = filter(freqSm, [1 -(1-freqSm)], Sed(end:1)); + + cohed = real(Sed.*conj(Sed))./(Se.*Sd + 1e-10); + %cohedAvg(kk) = mean(cohed(echoBandRange)); + %cohedAvg(kk) = cohed(6); + %cohedAvg(kk) = min(cohed); + + cohxd = real(Sxd.*conj(Sxd))./(Sx.*Sd + 1e-10); + %freqSm = 0.5; + %cohxd(3:end) = filter(freqSm, [1 -(1-freqSm)], cohxd(3:end)); + %cohxd(end:3) = filter(freqSm, [1 -(1-freqSm)], cohxd(end:3)); + %cohxdAvg(kk) = mean(cohxd(echoBandRange)); + %cohxdAvg(kk) = (cohxd(32)); + %cohxdAvg(kk) = max(cohxd); + + %xf = xfm(:,dIdx); + %SxBad = gamma*SxBad + (1 - gamma)*real(xf.*conj(xf)); + %SxdBad = gamma*SxdBad + (1 - gamma)*xf.*conj(df); + %cohxdBad = real(SxdBad.*conj(SxdBad))./(SxBad.*Sd + 0.01); + %cohxdAvgBad(kk) = mean(cohxdBad); + + %for j=1:N+1 + % mutInf(j) = 0.9*mutInf(j) + 0.1*information(abs(xfm(j,:)), abs(dfm(j,:))); + %end + %mutInfAvg(kk) = mean(mutInf); + + %hnled = cohedFast; + %xIdx = find(cohxd > 1 - cohed); + %hnled(xIdx) = 1 - cohxd(xIdx); + %hnled = 1 - max(cohxd, 1-cohedFast); + hnled = min(1 - cohxd, cohed); + %hnled = 1 - cohxd; + %hnled = max(1 - (cohxd + (1-cohedFast)), 0); + %hnled = 1 - max(cohxd, 1-cohed); + + if kk > 1 + cohxdSlow(kk,:) = 0.99*cohxdSlow(kk-1,:) + 0.01*cohxd'; + cohedSlow(kk,:) = 0.99*cohedSlow(kk-1,:) + 0.01*(1-cohed)'; + end + + + if 0 + %if kk > 50 + %idx = find(hnled > 0.3); + hnlMax = hnlMax*0.9999; + %hnlMax(idx) = max(hnlMax(idx), hnled(idx)); + hnlMax = max(hnlMax, hnled); + %overdrive(idx) = max(log(hnlMax(idx))/log(0.99), 1); + avgHnl = mean(hnlMax(echoBandRange)); + if avgHnl > 0.3 + overdrive = max(log(avgHnl)/log(0.99), 1); + end + weight(4:end) = max(hnlMax) - hnlMax(4:end); + end + + + + %[hg, gidx] = max(hnled); + %fnrg = Sx(gidx) / (Sd(gidx) + 1e-10); + + %[tmp, bidx] = find((Sx / Sd + 1e-10) > fnrg); + %hnled(bidx) = hg; + + + %cohed1 = mean(cohed(cohRange)); % range depends on bandwidth + %cohed1 = cohed1^2; + %echoBands(kk) = length(find(cohed(echoBandRange) < 0.25))/length(echoBandRange); + + %if (fbSupp == 0) + % if (echoBands(kk) > 0.8) + % fbSupp = 1; + % end + %else + % if (echoBands(kk) < 0.6) + % fbSupp = 0; + % end + %end + %overdrive(kk) = 7.5*echoBands(kk) + 0.5; + + % Factor by which to weight other bands + %if (cohed1 < 0.1) + % w = 0.8 - cohed1*10*0.4; + %else + % w = 0.4; + %end + + % Weight coherence subbands + %hnled = w*cohed1 + (1 - w)*cohed; + %hnled = (hnled).^2; + %cohed(floor(N/2):end) = cohed(floor(N/2):end).^2; + %if fbSupp == 1 + % cohed = zeros(size(cohed)); + %end + %cohed = cohed.^overdrive(kk); + + %hnled = gamma*hnled + (1 - gamma)*cohed; + % Additional hf suppression + %hnledp = [hnledp ; mean(hnled)]; + %hnled(floor(N/2):end) = hnled(floor(N/2):end).^2; + %ef = ef.*((weight*(min(1 - hnled)).^2 + (1 - weight).*(1 - hnled)).^2); + + cohedMean = mean(cohed(echoBandRange)); + %aggrFact = 4*(1-mean(hnled(echoBandRange))) + 1; + %[hnlSort, hnlSortIdx] = sort(hnled(echoBandRange)); + [hnlSort, hnlSortIdx] = sort(1-cohxd(echoBandRange)); + [xSort, xSortIdx] = sort(Sx); + %aggrFact = (1-mean(hnled(echoBandRange))); + %hnlSortQ = hnlSort(qIdx); + hnlSortQ = mean(1 - cohxd(echoBandRange)); + %hnlSortQ = mean(1 - cohxd); + + [hnlSort2, hnlSortIdx2] = sort(hnled(echoBandRange)); + %[hnlSort2, hnlSortIdx2] = sort(hnled); + hnlQuant = 0.75; + hnlQuantLow = 0.5; + qIdx = floor(hnlQuant*length(hnlSort2)); + qIdxLow = floor(hnlQuantLow*length(hnlSort2)); + hnlPrefAvg = hnlSort2(qIdx); + hnlPrefAvgLow = hnlSort2(qIdxLow); + %hnlPrefAvgLow = mean(hnled); + %hnlPrefAvg = max(hnlSort2); + %hnlPrefAvgLow = min(hnlSort2); + + %hnlPref = hnled(echoBandRange); + %hnlPrefAvg = mean(hnlPref(xSortIdx((0.5*length(xSortIdx)):end))); + + %hnlPrefAvg = min(hnlPrefAvg, hnlSortQ); + + %hnlSortQIdx = hnlSortIdx(qIdx); + %SeQ = Se(qIdx + echoBandRange(1) - 1); + %SdQ = Sd(qIdx + echoBandRange(1) - 1); + %SeQ = Se(qIdxLow + echoBandRange(1) - 1); + %SdQ = Sd(qIdxLow + echoBandRange(1) - 1); + %propLow = length(find(hnlSort < 0.1))/length(hnlSort); + %aggrFact = min((1 - hnlSortQ)/2, 0.5); + %aggrTerm = 1/aggrFact; + + %hnlg = mean(hnled(echoBandRange)); + %hnlg = hnlSortQ; + %if suppState == 0 + % if hnlg < 0.05 + % suppState = 2; + % transCtr = 0; + % elseif hnlg < 0.75 + % suppState = 1; + % transCtr = 0; + % end + %elseif suppState == 1 + % if hnlg > 0.8 + % suppState = 0; + % transCtr = 0; + % elseif hnlg < 0.05 + % suppState = 2; + % transCtr = 0; + % end + %else + % if hnlg > 0.8 + % suppState = 0; + % transCtr = 0; + % elseif hnlg > 0.25 + % suppState = 1; + % transCtr = 0; + % end + %end + %if kk > 50 + + if cohedMean > 0.98 & hnlSortQ > 0.9 + %if suppState == 1 + % hnled = 0.5*hnled + 0.5*cohed; + % %hnlSortQ = 0.5*hnlSortQ + 0.5*cohedMean; + % hnlPrefAvg = 0.5*hnlPrefAvg + 0.5*cohedMean; + %else + % hnled = cohed; + % %hnlSortQ = cohedMean; + % hnlPrefAvg = cohedMean; + %end + suppState = 0; + elseif cohedMean < 0.95 | hnlSortQ < 0.8 + %if suppState == 0 + % hnled = 0.5*hnled + 0.5*cohed; + % %hnlSortQ = 0.5*hnlSortQ + 0.5*cohedMean; + % hnlPrefAvg = 0.5*hnlPrefAvg + 0.5*cohedMean; + %end + suppState = 1; + end + + if hnlSortQ < cohxdLocalMin & hnlSortQ < 0.75 + cohxdLocalMin = hnlSortQ; + end + + if cohxdLocalMin == 1 + ovrd = 3; + hnled = 1-cohxd; + hnlPrefAvg = hnlSortQ; + hnlPrefAvgLow = hnlSortQ; + end + + if suppState == 0 + hnled = cohed; + hnlPrefAvg = cohedMean; + hnlPrefAvgLow = cohedMean; + end + + %if hnlPrefAvg < hnlLocalMin & hnlPrefAvg < 0.6 + if hnlPrefAvgLow < hnlLocalMin & hnlPrefAvgLow < 0.6 + %hnlLocalMin = hnlPrefAvg; + %hnlMin = hnlPrefAvg; + hnlLocalMin = hnlPrefAvgLow; + hnlMin = hnlPrefAvgLow; + hnlNewMin = 1; + hnlMinCtr = 0; + %if hnlMinCtr == 0 + % hnlMinCtr = hnlMinCtr + 1; + %else + % hnlMinCtr = 0; + % hnlMin = hnlLocalMin; + %SeLocalMin = SeQ; + %SdLocalMin = SdQ; + %SeLocalAvg = 0; + %minCtr = 0; + % ovrd = max(log(0.0001)/log(hnlMin), 2); + %divergeFact = hnlLocalMin; + end + + if hnlNewMin == 1 + hnlMinCtr = hnlMinCtr + 1; + end + if hnlMinCtr == 2 + hnlNewMin = 0; + hnlMinCtr = 0; + %ovrd = max(log(0.0001)/log(hnlMin), 2); + ovrd = max(log(0.00001)/(log(hnlMin + 1e-10) + 1e-10), 3); + %ovrd = max(log(0.00000001)/(log(hnlMin + 1e-10) + 1e-10), 5); + %ovrd = max(log(0.0001)/log(hnlPrefAvg), 2); + %ovrd = max(log(0.001)/log(hnlMin), 2); + end + hnlLocalMin = min(hnlLocalMin + 0.0008/mult, 1); + cohxdLocalMin = min(cohxdLocalMin + 0.0004/mult, 1); + %divergeFact = hnlSortQ; + + + %if minCtr > 0 & hnlLocalMin < 1 + % hnlMin = hnlLocalMin; + % %SeMin = 0.9*SeMin + 0.1*sqrt(SeLocalMin); + % SdMin = sqrt(SdLocalMin); + % %SeMin = sqrt(SeLocalMin)*hnlSortQ; + % SeMin = sqrt(SeLocalMin); + % %ovrd = log(100/SeMin)/log(hnlSortQ); + % %ovrd = log(100/SeMin)/log(hnlSortQ); + % ovrd = log(0.01)/log(hnlMin); + % ovrd = max(ovrd, 2); + % ovrdPos = hnlSortQIdx; + % %ovrd = max(ovrd, 1); + % %SeMin = sqrt(SeLocalAvg/5); + % minCtr = 0; + %else + % %SeLocalMin = 0.9*SeLocalMin +0.1*SeQ; + % SeLocalAvg = SeLocalAvg + SeQ; + % minCtr = minCtr + 1; + %end + + if ovrd < ovrdSm + ovrdSm = 0.99*ovrdSm + 0.01*ovrd; + else + ovrdSm = 0.9*ovrdSm + 0.1*ovrd; + end + %end + + %ekEn = sum(real(ekfb.^2)); + %dkEn = sum(real(dk.^2)); + ekEn = sum(Se); + dkEn = sum(Sd); + + if divergeState == 0 + if ekEn > dkEn + ef = df; + divergeState = 1; + %hnlPrefAvg = hnlSortQ; + %hnled = (1 - cohxd); + end + else + %if ekEn*1.1 < dkEn + %if ekEn*1.26 < dkEn + if ekEn*1.05 < dkEn + divergeState = 0; + else + ef = df; + end + end + + if ekEn > dkEn*19.95 + WFb=zeros(N+1,M); % Block-based FD NLMS + end + + ekEnV(kk) = ekEn; + dkEnV(kk) = dkEn; + + hnlLocalMinV(kk) = hnlLocalMin; + cohxdLocalMinV(kk) = cohxdLocalMin; + hnlMinV(kk) = hnlMin; + %cohxdMaxLocal = max(cohxdSlow(kk,:)); + %if kk > 50 + %cohxdMaxLocal = 1-hnlSortQ; + %if cohxdMaxLocal > 0.5 + % %if cohxdMaxLocal > cohxdMax + % odScale = max(log(cohxdMaxLocal)/log(0.95), 1); + % %overdrive(7:end) = max(log(cohxdSlow(kk,7:end))/log(0.9), 1); + % cohxdMax = cohxdMaxLocal; + % end + %end + %end + %cohxdMax = cohxdMax*0.999; + + %overdriveM(kk,:) = max(overdrive, 1); + %aggrFact = 0.25; + aggrFact = 0.3; + %aggrFact = 0.5*propLow; + %if fs == 8000 + % wCurve = [0 ; 0 ; aggrFact*sqrt(linspace(0,1,N-1))' + 0.1]; + %else + % wCurve = [0; 0; 0; aggrFact*sqrt(linspace(0,1,N-2))' + 0.1]; + %end + wCurve = [0; aggrFact*sqrt(linspace(0,1,N))' + 0.1]; + % For sync with C + %if fs == 8000 + % wCurve = wCurve(2:end); + %else + % wCurve = wCurve(1:end-1); + %end + %weight = aggrFact*(sqrt(linspace(0,1,N+1)')); + %weight = aggrFact*wCurve; + weight = wCurve; + %weight = aggrFact*ones(N+1,1); + %weight = zeros(N+1,1); + %hnled = weight.*min(hnled) + (1 - weight).*hnled; + %hnled = weight.*min(mean(hnled(echoBandRange)), hnled) + (1 - weight).*hnled; + %hnled = weight.*min(hnlSortQ, hnled) + (1 - weight).*hnled; + + %hnlSortQV(kk) = mean(hnled); + %hnlPrefAvgV(kk) = mean(hnled(echoBandRange)); + + hnled = weight.*min(hnlPrefAvg, hnled) + (1 - weight).*hnled; + + %od = aggrFact*(sqrt(linspace(0,1,N+1)') + aggrTerm); + %od = 4*(sqrt(linspace(0,1,N+1)') + 1/4); + + %ovrdFact = (ovrdSm - 1) / sqrt(ovrdPos/(N+1)); + %ovrdFact = ovrdSm / sqrt(echoBandRange(floor(length(echoBandRange)/2))/(N+1)); + %od = ovrdFact*sqrt(linspace(0,1,N+1))' + 1; + %od = ovrdSm*ones(N+1,1).*abs(WFb(:,dIdx))/(max(abs(WFb(:,dIdx)))+1e-10); + + %od = ovrdSm*ones(N+1,1); + %od = ovrdSm*WFbD.*(sqrt(linspace(0,1,N+1))' + 1); + + od = ovrdSm*(sqrt(linspace(0,1,N+1))' + 1); + %od = 4*(sqrt(linspace(0,1,N+1))' + 1); + + %od = 2*ones(N+1,1); + %od = 2*ones(N+1,1); + %sshift = ((1-hnled)*2-1).^3+1; + sshift = ones(N+1,1); + + hnled = hnled.^(od.*sshift); + + %if hnlg > 0.75 + %if (suppState ~= 0) + % transCtr = 0; + %end + % suppState = 0; + %elseif hnlg < 0.6 & hnlg > 0.2 + % suppState = 1; + %elseif hnlg < 0.1 + %hnled = zeros(N+1, 1); + %if (suppState ~= 2) + % transCtr = 0; + %end + % suppState = 2; + %else + % if (suppState ~= 2) + % transCtr = 0; + % end + % suppState = 2; + %end + %if suppState == 0 + % hnled = ones(N+1, 1); + %elseif suppState == 2 + % hnled = zeros(N+1, 1); + %end + %hnled(find(hnled < 0.1)) = 0; + %hnled = hnled.^2; + %if transCtr < 5 + %hnl = 0.75*hnl + 0.25*hnled; + % transCtr = transCtr + 1; + %else + hnl = hnled; + %end + %hnled(find(hnled < 0.05)) = 0; + ef = ef.*(hnl); + + %ef = ef.*(min(1 - cohxd, cohed).^2); + %ef = ef.*((1-cohxd).^2); + + ovrdV(kk) = ovrdSm; + %ovrdV(kk) = dIdx; + %ovrdV(kk) = divergeFact; + %hnledAvg(kk) = 1-mean(1-cohedFast(echoBandRange)); + hnledAvg(kk) = 1-mean(1-cohed(echoBandRange)); + hnlxdAvg(kk) = 1-mean(cohxd(echoBandRange)); + %hnlxdAvg(kk) = cohxd(5); + %hnlSortQV(kk) = mean(hnled); + hnlSortQV(kk) = hnlPrefAvgLow; + hnlPrefAvgV(kk) = hnlPrefAvg; + %hnlAvg(kk) = propLow; + %ef(N/2:end) = 0; + %ner = (sum(Sd) ./ (sum(Se.*(hnl.^2)) + 1e-10)); + + % Comfort noise + if (CNon) + snn=sqrt(Sym); + snn(1)=0; % Reject LF noise + Un=snn.*exp(j*2*pi.*[0;rand(N-1,1);0]); + + % Weight comfort noise by suppression + Un = sqrt(1-hnled.^2).*Un; + Fmix = ef + Un; + else + Fmix = ef; + end + + % Overlap and add in time domain for smoothness + tmp = [Fmix ; flipud(conj(Fmix(2:N)))]; + mixw = wins.*real(ifft(tmp)); + mola = mbuf(end-N+1:end) + mixw(1:N); + mbuf = mixw; + ercn(pos:pos+N-1) = mola; + end % NLPon + + % Filter update + %Ek2 = Ek ./(12*pn + 0.001); % Normalized error + %Ek2 = Ek2 * divergeFact; + %Ek2 = Ek ./(pn + 0.001); % Normalized error + %Ek2 = Ek ./(100*pn + 0.001); % Normalized error + + %divergeIdx = find(abs(Ek) > abs(DD)); + %divergeIdx = find(Se > Sd); + %threshMod = threshold*ones(N+1,1); + %if length(divergeIdx) > 0 + %if sum(abs(Ek)) > sum(abs(DD)) + %WFb(divergeIdx,:) = WFb(divergeIdx,:) .* repmat(sqrt(Sd(divergeIdx)./(Se(divergeIdx)+1e-10))),1,M); + %Ek2(divergeIdx) = Ek2(divergeIdx) .* sqrt(Sd(divergeIdx)./(Se(divergeIdx)+1e-10)); + %Ek2(divergeIdx) = Ek2(divergeIdx) .* abs(DD(divergeIdx))./(abs(Ek(divergeIdx))+1e-10); + %WFb(divergeIdx,:) = WFbOld(divergeIdx,:); + %WFb = WFbOld; + %threshMod(divergeIdx) = threshMod(divergeIdx) .* abs(DD(divergeIdx))./(abs(Ek(divergeIdx))+1e-10); + % threshMod(divergeIdx) = threshMod(divergeIdx) .* sqrt(Sd(divergeIdx)./(Se(divergeIdx)+1e-10)); + %end + + %absEf = max(abs(Ek2), threshold); + %absEf = ones(N+1,1)*threshold./absEf; + %absEf = max(abs(Ek2), threshMod); + %absEf = threshMod./absEf; + %Ek2 = Ek2.*absEf; + + %if sum(Se) <= sum(Sd) + + % mEk = mufb.*Ek2; + % PP = conj(XFm).*(ones(M,1) * mEk')'; + % tmp = [PP ; flipud(conj(PP(2:N,:)))]; + % IFPP = real(ifft(tmp)); + % PH = IFPP(1:N,:); + % tmp = fft([PH;zeros(N,M)]); + % FPH = tmp(1:N+1,:); + % %WFbOld = WFb; + % WFb = WFb + FPH; + + %else + % WF = WFbOld; + %end + + % Shift old FFTs + %for m=M:-1:2 + % XFm(:,m) = XFm(:,m-1); + % YFm(:,m) = YFm(:,m-1); + %end + XFm(:,2:end) = XFm(:,1:end-1); + YFm(:,2:end) = YFm(:,1:end-1); + xfwm(:,2:end) = xfwm(:,1:end-1); + dfm(:,2:end) = dfm(:,1:end-1); + + %if mod(kk, floor(Nb/50)) == 0 + % fprintf(1, '.'); + %end + + if mod(kk, floor(Nb/100)) == 0 + %if mod(kk, floor(Nb/500)) == 0 + progressbar(kk/Nb); + %figure(5) + %plot(abs(WFb)); + %legend('1','2','3','4','5','6','7','8','9','10','11','12'); + %title(kk*N/fs); + %figure(6) + %plot(WFbD); + %figure(6) + %plot(threshMod) + %if length(divergeIdx) > 0 + % plot(abs(DD)) + % hold on + % plot(abs(Ek), 'r') + % hold off + %plot(min(sqrt(Sd./(Se+1e-10)),1)) + %axis([0 N 0 1]); + %end + %figure(6) + %plot(cohedFast); + %axis([1 N+1 0 1]); + %plot(WFbEn); + + %figure(7) + %plot(weight); + %plot([cohxd 1-cohed]); + %plot([cohxd 1-cohed 1-cohedFast hnled]); + %plot([cohxd cohxdFast/max(cohxdFast)]); + %legend('cohxd', '1-cohed', '1-cohedFast'); + %axis([1 65 0 1]); + %pause(0.5); + %overdrive + end +end +progressbar(1); + +%figure(2); +%plot([feat(:,1) feat(:,2)+1 feat(:,3)+2 mfeat+3]); +%plot([feat(:,1) mfeat+1]); + +%figure(3); +%plot(10*log10([dri erifb erifb3 ericn])); +%legend('Near-end','Error','Post NLP','Final',4); +% Compensate for delay +%ercn=[ercn(N+1:end);zeros(N,1)]; +%ercn_=[ercn_(N+1:end);zeros(N,1)]; + +%figure(11); +%plot(cohxdSlow); + +%figure(12); +%surf(cohxdSlow); +%shading interp; + +%figure(13); +%plot(overdriveM); + +%figure(14); +%surf(overdriveM); +%shading interp; + +figure(10); +t = (0:Nb)*N/fs; +rrinSubSamp = rrin(N*(1:(Nb+1))); +plot(t, rrinSubSamp/max(abs(rrinSubSamp)),'b'); +hold on +plot(t, hnledAvg, 'r'); +plot(t, hnlxdAvg, 'g'); +plot(t, hnlSortQV, 'y'); +plot(t, hnlLocalMinV, 'k'); +plot(t, cohxdLocalMinV, 'c'); +plot(t, hnlPrefAvgV, 'm'); +%plot(t, cohxdAvg, 'r'); +%plot(cohxdFastAvg, 'r'); +%plot(cohxdAvgBad, 'k'); +%plot(t, cohedAvg, 'k'); +%plot(t, 1-cohedFastAvg, 'k'); +%plot(ssin(N*(1:floor(length(ssin)/N)))/max(abs(ssin))); +%plot(echoBands,'r'); +%plot(overdrive, 'g'); +%plot(erfb(N*(1:floor(length(erfb)/N)))/max(abs(erfb))); +hold off +tightx; + +figure(11) +plot(t, ovrdV); +tightx; +%plot(mfeat,'r'); +%plot(1-cohxyp_,'r'); +%plot(Hnlxydp,'y'); +%plot(hnledp,'k'); +%plot(Hnlxydp, 'c'); +%plot(ccohpd_,'k'); +%plot(supplot_, 'g'); +%plot(ones(length(mfeat),1)*rr1_, 'k'); +%plot(ones(length(mfeat),1)*rr2_, 'k'); +%plot(N*(1:length(feat)), feat); +%plot(Sep_,'r'); +%axis([1 floor(length(erfb)/N) -1 1]) +%hold off +%plot(10*log10([Se_, Sx_, Seu_, real(sf_.*conj(sf_))])); +%legend('Se','Sx','Seu','S'); +%figure(5) +%plot([ercn ercn_]); + +figure(12) +plot(t, dIdxV); +%plot(t, SLxV); +tightx; + +%figure(13) +%plot(t, [ekEnV dkEnV]); +%plot(t, dkEnV./(ekEnV+1e-10)); +%tightx; + +%close(hh); +%spclab(fs,ssin,erfb,ercn,'outxd.pcm'); +%spclab(fs,rrin,ssin,erfb,1.78*ercn,'vqeOut-1.pcm'); +%spclab(fs,erfb,'aecOutLp.pcm'); +%spclab(fs,rrin,ssin,erfb,1.78*ercn,'aecOut25.pcm','vqeOut-1.pcm'); +%spclab(fs,rrin,ssin,erfb,ercn,'aecOut-mba.pcm'); +%spclab(fs,rrin,ssin,erfb,ercn,'aecOut.pcm'); +%spclab(fs, ssin, erfb, ercn, 'out0.pcm'); diff --git a/src/modules/audio_processing/aec/main/source/aec.gypi b/src/modules/audio_processing/aec/main/source/aec.gypi new file mode 100644 index 0000000..e28104f --- /dev/null +++ b/src/modules/audio_processing/aec/main/source/aec.gypi @@ -0,0 +1,46 @@ +# Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. +# +# Use of this source code is governed by a BSD-style license +# that can be found in the LICENSE file in the root of the source +# tree. An additional intellectual property rights grant can be found +# in the file PATENTS. All contributing project authors may +# be found in the AUTHORS file in the root of the source tree. + +{ + 'targets': [ + { + 'target_name': 'aec', + 'type': '<(library)', + 'dependencies': [ + '<(webrtc_root)/common_audio/common_audio.gyp:spl', + 'apm_util' + ], + 'include_dirs': [ + '../interface', + ], + 'direct_dependent_settings': { + 'include_dirs': [ + '../interface', + ], + }, + 'sources': [ + '../interface/echo_cancellation.h', + 'echo_cancellation.c', + 'aec_core.h', + 'aec_core.c', + 'aec_core_sse2.c', + 'aec_rdft.h', + 'aec_rdft.c', + 'aec_rdft_sse2.c', + 'resampler.h', + 'resampler.c', + ], + }, + ], +} + +# Local Variables: +# tab-width:2 +# indent-tabs-mode:nil +# End: +# vim: set expandtab tabstop=2 shiftwidth=2: diff --git a/src/modules/audio_processing/aec/main/source/aec_core.c b/src/modules/audio_processing/aec/main/source/aec_core.c new file mode 100644 index 0000000..8782242 --- /dev/null +++ b/src/modules/audio_processing/aec/main/source/aec_core.c @@ -0,0 +1,1430 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +/* + * The core AEC algorithm, which is presented with time-aligned signals. + */ + +#include +#include +#include + +#include "aec_core.h" +#include "aec_rdft.h" +#include "ring_buffer.h" +#include "system_wrappers/interface/cpu_features_wrapper.h" + +// Noise suppression +static const int converged = 250; + +// Metrics +static const int subCountLen = 4; +static const int countLen = 50; + +// Quantities to control H band scaling for SWB input +static const int flagHbandCn = 1; // flag for adding comfort noise in H band +static const float cnScaleHband = (float)0.4; // scale for comfort noise in H band +// Initial bin for averaging nlp gain in low band +static const int freqAvgIc = PART_LEN / 2; + +/* Matlab code to produce table: +win = sqrt(hanning(63)); win = [0 ; win(1:32)]; +fprintf(1, '\t%.14f, %.14f, %.14f,\n', win); +*/ +/* +static const float sqrtHanning[33] = { + 0.00000000000000, 0.04906767432742, 0.09801714032956, + 0.14673047445536, 0.19509032201613, 0.24298017990326, + 0.29028467725446, 0.33688985339222, 0.38268343236509, + 0.42755509343028, 0.47139673682600, 0.51410274419322, + 0.55557023301960, 0.59569930449243, 0.63439328416365, + 0.67155895484702, 0.70710678118655, 0.74095112535496, + 0.77301045336274, 0.80320753148064, 0.83146961230255, + 0.85772861000027, 0.88192126434835, 0.90398929312344, + 0.92387953251129, 0.94154406518302, 0.95694033573221, + 0.97003125319454, 0.98078528040323, 0.98917650996478, + 0.99518472667220, 0.99879545620517, 1.00000000000000 +}; +*/ + +static const float sqrtHanning[65] = { + 0.00000000000000f, 0.02454122852291f, 0.04906767432742f, + 0.07356456359967f, 0.09801714032956f, 0.12241067519922f, + 0.14673047445536f, 0.17096188876030f, 0.19509032201613f, + 0.21910124015687f, 0.24298017990326f, 0.26671275747490f, + 0.29028467725446f, 0.31368174039889f, 0.33688985339222f, + 0.35989503653499f, 0.38268343236509f, 0.40524131400499f, + 0.42755509343028f, 0.44961132965461f, 0.47139673682600f, + 0.49289819222978f, 0.51410274419322f, 0.53499761988710f, + 0.55557023301960f, 0.57580819141785f, 0.59569930449243f, + 0.61523159058063f, 0.63439328416365f, 0.65317284295378f, + 0.67155895484702f, 0.68954054473707f, 0.70710678118655f, + 0.72424708295147f, 0.74095112535496f, 0.75720884650648f, + 0.77301045336274f, 0.78834642762661f, 0.80320753148064f, + 0.81758481315158f, 0.83146961230255f, 0.84485356524971f, + 0.85772861000027f, 0.87008699110871f, 0.88192126434835f, + 0.89322430119552f, 0.90398929312344f, 0.91420975570353f, + 0.92387953251129f, 0.93299279883474f, 0.94154406518302f, + 0.94952818059304f, 0.95694033573221f, 0.96377606579544f, + 0.97003125319454f, 0.97570213003853f, 0.98078528040323f, + 0.98527764238894f, 0.98917650996478f, 0.99247953459871f, + 0.99518472667220f, 0.99729045667869f, 0.99879545620517f, + 0.99969881869620f, 1.00000000000000f +}; + +/* Matlab code to produce table: +weightCurve = [0 ; 0.3 * sqrt(linspace(0,1,64))' + 0.1]; +fprintf(1, '\t%.4f, %.4f, %.4f, %.4f, %.4f, %.4f,\n', weightCurve); +*/ +const float WebRtcAec_weightCurve[65] = { + 0.0000f, 0.1000f, 0.1378f, 0.1535f, 0.1655f, 0.1756f, + 0.1845f, 0.1926f, 0.2000f, 0.2069f, 0.2134f, 0.2195f, + 0.2254f, 0.2309f, 0.2363f, 0.2414f, 0.2464f, 0.2512f, + 0.2558f, 0.2604f, 0.2648f, 0.2690f, 0.2732f, 0.2773f, + 0.2813f, 0.2852f, 0.2890f, 0.2927f, 0.2964f, 0.3000f, + 0.3035f, 0.3070f, 0.3104f, 0.3138f, 0.3171f, 0.3204f, + 0.3236f, 0.3268f, 0.3299f, 0.3330f, 0.3360f, 0.3390f, + 0.3420f, 0.3449f, 0.3478f, 0.3507f, 0.3535f, 0.3563f, + 0.3591f, 0.3619f, 0.3646f, 0.3673f, 0.3699f, 0.3726f, + 0.3752f, 0.3777f, 0.3803f, 0.3828f, 0.3854f, 0.3878f, + 0.3903f, 0.3928f, 0.3952f, 0.3976f, 0.4000f +}; + +/* Matlab code to produce table: +overDriveCurve = [sqrt(linspace(0,1,65))' + 1]; +fprintf(1, '\t%.4f, %.4f, %.4f, %.4f, %.4f, %.4f,\n', overDriveCurve); +*/ +const float WebRtcAec_overDriveCurve[65] = { + 1.0000f, 1.1250f, 1.1768f, 1.2165f, 1.2500f, 1.2795f, + 1.3062f, 1.3307f, 1.3536f, 1.3750f, 1.3953f, 1.4146f, + 1.4330f, 1.4507f, 1.4677f, 1.4841f, 1.5000f, 1.5154f, + 1.5303f, 1.5449f, 1.5590f, 1.5728f, 1.5863f, 1.5995f, + 1.6124f, 1.6250f, 1.6374f, 1.6495f, 1.6614f, 1.6731f, + 1.6847f, 1.6960f, 1.7071f, 1.7181f, 1.7289f, 1.7395f, + 1.7500f, 1.7603f, 1.7706f, 1.7806f, 1.7906f, 1.8004f, + 1.8101f, 1.8197f, 1.8292f, 1.8385f, 1.8478f, 1.8570f, + 1.8660f, 1.8750f, 1.8839f, 1.8927f, 1.9014f, 1.9100f, + 1.9186f, 1.9270f, 1.9354f, 1.9437f, 1.9520f, 1.9601f, + 1.9682f, 1.9763f, 1.9843f, 1.9922f, 2.0000f +}; + +// "Private" function prototypes. +static void ProcessBlock(aec_t *aec, const short *farend, + const short *nearend, const short *nearendH, + short *out, short *outH); + +static void BufferFar(aec_t *aec, const short *farend, int farLen); +static void FetchFar(aec_t *aec, short *farend, int farLen, int knownDelay); + +static void NonLinearProcessing(aec_t *aec, short *output, short *outputH); + +static void GetHighbandGain(const float *lambda, float *nlpGainHband); + +// Comfort_noise also computes noise for H band returned in comfortNoiseHband +static void ComfortNoise(aec_t *aec, float efw[2][PART_LEN1], + complex_t *comfortNoiseHband, + const float *noisePow, const float *lambda); + +static void WebRtcAec_InitLevel(power_level_t *level); +static void WebRtcAec_InitStats(stats_t *stats); +static void UpdateLevel(power_level_t *level, const short *in); +static void UpdateMetrics(aec_t *aec); + +__inline static float MulRe(float aRe, float aIm, float bRe, float bIm) +{ + return aRe * bRe - aIm * bIm; +} + +__inline static float MulIm(float aRe, float aIm, float bRe, float bIm) +{ + return aRe * bIm + aIm * bRe; +} + +static int CmpFloat(const void *a, const void *b) +{ + const float *da = (const float *)a; + const float *db = (const float *)b; + + return (*da > *db) - (*da < *db); +} + +int WebRtcAec_CreateAec(aec_t **aecInst) +{ + aec_t *aec = malloc(sizeof(aec_t)); + *aecInst = aec; + if (aec == NULL) { + return -1; + } + + if (WebRtcApm_CreateBuffer(&aec->farFrBuf, FRAME_LEN + PART_LEN) == -1) { + WebRtcAec_FreeAec(aec); + aec = NULL; + return -1; + } + + if (WebRtcApm_CreateBuffer(&aec->nearFrBuf, FRAME_LEN + PART_LEN) == -1) { + WebRtcAec_FreeAec(aec); + aec = NULL; + return -1; + } + + if (WebRtcApm_CreateBuffer(&aec->outFrBuf, FRAME_LEN + PART_LEN) == -1) { + WebRtcAec_FreeAec(aec); + aec = NULL; + return -1; + } + + if (WebRtcApm_CreateBuffer(&aec->nearFrBufH, FRAME_LEN + PART_LEN) == -1) { + WebRtcAec_FreeAec(aec); + aec = NULL; + return -1; + } + + if (WebRtcApm_CreateBuffer(&aec->outFrBufH, FRAME_LEN + PART_LEN) == -1) { + WebRtcAec_FreeAec(aec); + aec = NULL; + return -1; + } + + return 0; +} + +int WebRtcAec_FreeAec(aec_t *aec) +{ + if (aec == NULL) { + return -1; + } + + WebRtcApm_FreeBuffer(aec->farFrBuf); + WebRtcApm_FreeBuffer(aec->nearFrBuf); + WebRtcApm_FreeBuffer(aec->outFrBuf); + + WebRtcApm_FreeBuffer(aec->nearFrBufH); + WebRtcApm_FreeBuffer(aec->outFrBufH); + + free(aec); + return 0; +} + +static void FilterFar(aec_t *aec, float yf[2][PART_LEN1]) +{ + int i; + for (i = 0; i < NR_PART; i++) { + int j; + int xPos = (i + aec->xfBufBlockPos) * PART_LEN1; + int pos = i * PART_LEN1; + // Check for wrap + if (i + aec->xfBufBlockPos >= NR_PART) { + xPos -= NR_PART*(PART_LEN1); + } + + for (j = 0; j < PART_LEN1; j++) { + yf[0][j] += MulRe(aec->xfBuf[0][xPos + j], aec->xfBuf[1][xPos + j], + aec->wfBuf[0][ pos + j], aec->wfBuf[1][ pos + j]); + yf[1][j] += MulIm(aec->xfBuf[0][xPos + j], aec->xfBuf[1][xPos + j], + aec->wfBuf[0][ pos + j], aec->wfBuf[1][ pos + j]); + } + } +} + +static void ScaleErrorSignal(aec_t *aec, float ef[2][PART_LEN1]) +{ + int i; + float absEf; + for (i = 0; i < (PART_LEN1); i++) { + ef[0][i] /= (aec->xPow[i] + 1e-10f); + ef[1][i] /= (aec->xPow[i] + 1e-10f); + absEf = sqrtf(ef[0][i] * ef[0][i] + ef[1][i] * ef[1][i]); + + if (absEf > aec->errThresh) { + absEf = aec->errThresh / (absEf + 1e-10f); + ef[0][i] *= absEf; + ef[1][i] *= absEf; + } + + // Stepsize factor + ef[0][i] *= aec->mu; + ef[1][i] *= aec->mu; + } +} + +static void FilterAdaptation(aec_t *aec, float *fft, float ef[2][PART_LEN1]) { + int i, j; + for (i = 0; i < NR_PART; i++) { + int xPos = (i + aec->xfBufBlockPos)*(PART_LEN1); + int pos; + // Check for wrap + if (i + aec->xfBufBlockPos >= NR_PART) { + xPos -= NR_PART * PART_LEN1; + } + + pos = i * PART_LEN1; + +#ifdef UNCONSTR + for (j = 0; j < PART_LEN1; j++) { + aec->wfBuf[pos + j][0] += MulRe(aec->xfBuf[xPos + j][0], + -aec->xfBuf[xPos + j][1], + ef[j][0], ef[j][1]); + aec->wfBuf[pos + j][1] += MulIm(aec->xfBuf[xPos + j][0], + -aec->xfBuf[xPos + j][1], + ef[j][0], ef[j][1]); + } +#else + for (j = 0; j < PART_LEN; j++) { + + fft[2 * j] = MulRe(aec->xfBuf[0][xPos + j], + -aec->xfBuf[1][xPos + j], + ef[0][j], ef[1][j]); + fft[2 * j + 1] = MulIm(aec->xfBuf[0][xPos + j], + -aec->xfBuf[1][xPos + j], + ef[0][j], ef[1][j]); + } + fft[1] = MulRe(aec->xfBuf[0][xPos + PART_LEN], + -aec->xfBuf[1][xPos + PART_LEN], + ef[0][PART_LEN], ef[1][PART_LEN]); + + aec_rdft_inverse_128(fft); + memset(fft + PART_LEN, 0, sizeof(float) * PART_LEN); + + // fft scaling + { + float scale = 2.0f / PART_LEN2; + for (j = 0; j < PART_LEN; j++) { + fft[j] *= scale; + } + } + aec_rdft_forward_128(fft); + + aec->wfBuf[0][pos] += fft[0]; + aec->wfBuf[0][pos + PART_LEN] += fft[1]; + + for (j = 1; j < PART_LEN; j++) { + aec->wfBuf[0][pos + j] += fft[2 * j]; + aec->wfBuf[1][pos + j] += fft[2 * j + 1]; + } +#endif // UNCONSTR + } +} + +static void OverdriveAndSuppress(aec_t *aec, float hNl[PART_LEN1], + const float hNlFb, + float efw[2][PART_LEN1]) { + int i; + for (i = 0; i < PART_LEN1; i++) { + // Weight subbands + if (hNl[i] > hNlFb) { + hNl[i] = WebRtcAec_weightCurve[i] * hNlFb + + (1 - WebRtcAec_weightCurve[i]) * hNl[i]; + } + hNl[i] = powf(hNl[i], aec->overDriveSm * WebRtcAec_overDriveCurve[i]); + + // Suppress error signal + efw[0][i] *= hNl[i]; + efw[1][i] *= hNl[i]; + + // Ooura fft returns incorrect sign on imaginary component. It matters here + // because we are making an additive change with comfort noise. + efw[1][i] *= -1; + } +} + +WebRtcAec_FilterFar_t WebRtcAec_FilterFar; +WebRtcAec_ScaleErrorSignal_t WebRtcAec_ScaleErrorSignal; +WebRtcAec_FilterAdaptation_t WebRtcAec_FilterAdaptation; +WebRtcAec_OverdriveAndSuppress_t WebRtcAec_OverdriveAndSuppress; + +int WebRtcAec_InitAec(aec_t *aec, int sampFreq) +{ + int i; + + aec->sampFreq = sampFreq; + + if (sampFreq == 8000) { + aec->mu = 0.6f; + aec->errThresh = 2e-6f; + } + else { + aec->mu = 0.5f; + aec->errThresh = 1.5e-6f; + } + + if (WebRtcApm_InitBuffer(aec->farFrBuf) == -1) { + return -1; + } + + if (WebRtcApm_InitBuffer(aec->nearFrBuf) == -1) { + return -1; + } + + if (WebRtcApm_InitBuffer(aec->outFrBuf) == -1) { + return -1; + } + + if (WebRtcApm_InitBuffer(aec->nearFrBufH) == -1) { + return -1; + } + + if (WebRtcApm_InitBuffer(aec->outFrBufH) == -1) { + return -1; + } + + // Default target suppression level + aec->targetSupp = -11.5; + aec->minOverDrive = 2.0; + + // Sampling frequency multiplier + // SWB is processed as 160 frame size + if (aec->sampFreq == 32000) { + aec->mult = (short)aec->sampFreq / 16000; + } + else { + aec->mult = (short)aec->sampFreq / 8000; + } + + aec->farBufWritePos = 0; + aec->farBufReadPos = 0; + + aec->inSamples = 0; + aec->outSamples = 0; + aec->knownDelay = 0; + + // Initialize buffers + memset(aec->farBuf, 0, sizeof(aec->farBuf)); + memset(aec->xBuf, 0, sizeof(aec->xBuf)); + memset(aec->dBuf, 0, sizeof(aec->dBuf)); + memset(aec->eBuf, 0, sizeof(aec->eBuf)); + // For H band + memset(aec->dBufH, 0, sizeof(aec->dBufH)); + + memset(aec->xPow, 0, sizeof(aec->xPow)); + memset(aec->dPow, 0, sizeof(aec->dPow)); + memset(aec->dInitMinPow, 0, sizeof(aec->dInitMinPow)); + aec->noisePow = aec->dInitMinPow; + aec->noiseEstCtr = 0; + + // Initial comfort noise power + for (i = 0; i < PART_LEN1; i++) { + aec->dMinPow[i] = 1.0e6f; + } + + // Holds the last block written to + aec->xfBufBlockPos = 0; + // TODO: Investigate need for these initializations. Deleting them doesn't + // change the output at all and yields 0.4% overall speedup. + memset(aec->xfBuf, 0, sizeof(complex_t) * NR_PART * PART_LEN1); + memset(aec->wfBuf, 0, sizeof(complex_t) * NR_PART * PART_LEN1); + memset(aec->sde, 0, sizeof(complex_t) * PART_LEN1); + memset(aec->sxd, 0, sizeof(complex_t) * PART_LEN1); + memset(aec->xfwBuf, 0, sizeof(complex_t) * NR_PART * PART_LEN1); + memset(aec->se, 0, sizeof(float) * PART_LEN1); + + // To prevent numerical instability in the first block. + for (i = 0; i < PART_LEN1; i++) { + aec->sd[i] = 1; + } + for (i = 0; i < PART_LEN1; i++) { + aec->sx[i] = 1; + } + + memset(aec->hNs, 0, sizeof(aec->hNs)); + memset(aec->outBuf, 0, sizeof(float) * PART_LEN); + + aec->hNlFbMin = 1; + aec->hNlFbLocalMin = 1; + aec->hNlXdAvgMin = 1; + aec->hNlNewMin = 0; + aec->hNlMinCtr = 0; + aec->overDrive = 2; + aec->overDriveSm = 2; + aec->delayIdx = 0; + aec->stNearState = 0; + aec->echoState = 0; + aec->divergeState = 0; + + aec->seed = 777; + aec->delayEstCtr = 0; + + // Metrics disabled by default + aec->metricsMode = 0; + WebRtcAec_InitMetrics(aec); + + // Assembly optimization + WebRtcAec_FilterFar = FilterFar; + WebRtcAec_ScaleErrorSignal = ScaleErrorSignal; + WebRtcAec_FilterAdaptation = FilterAdaptation; + WebRtcAec_OverdriveAndSuppress = OverdriveAndSuppress; + if (WebRtc_GetCPUInfo(kSSE2)) { +#if defined(WEBRTC_USE_SSE2) + WebRtcAec_InitAec_SSE2(); +#endif + } + aec_rdft_init(); + + return 0; +} + +void WebRtcAec_InitMetrics(aec_t *aec) +{ + aec->stateCounter = 0; + WebRtcAec_InitLevel(&aec->farlevel); + WebRtcAec_InitLevel(&aec->nearlevel); + WebRtcAec_InitLevel(&aec->linoutlevel); + WebRtcAec_InitLevel(&aec->nlpoutlevel); + + WebRtcAec_InitStats(&aec->erl); + WebRtcAec_InitStats(&aec->erle); + WebRtcAec_InitStats(&aec->aNlp); + WebRtcAec_InitStats(&aec->rerl); +} + + +void WebRtcAec_ProcessFrame(aec_t *aec, const short *farend, + const short *nearend, const short *nearendH, + short *out, short *outH, + int knownDelay) +{ + short farBl[PART_LEN], nearBl[PART_LEN], outBl[PART_LEN]; + short farFr[FRAME_LEN]; + // For H band + short nearBlH[PART_LEN], outBlH[PART_LEN]; + + int size = 0; + + // initialize: only used for SWB + memset(nearBlH, 0, sizeof(nearBlH)); + memset(outBlH, 0, sizeof(outBlH)); + + // Buffer the current frame. + // Fetch an older one corresponding to the delay. + BufferFar(aec, farend, FRAME_LEN); + FetchFar(aec, farFr, FRAME_LEN, knownDelay); + + // Buffer the synchronized far and near frames, + // to pass the smaller blocks individually. + WebRtcApm_WriteBuffer(aec->farFrBuf, farFr, FRAME_LEN); + WebRtcApm_WriteBuffer(aec->nearFrBuf, nearend, FRAME_LEN); + // For H band + if (aec->sampFreq == 32000) { + WebRtcApm_WriteBuffer(aec->nearFrBufH, nearendH, FRAME_LEN); + } + + // Process as many blocks as possible. + while (WebRtcApm_get_buffer_size(aec->farFrBuf) >= PART_LEN) { + + WebRtcApm_ReadBuffer(aec->farFrBuf, farBl, PART_LEN); + WebRtcApm_ReadBuffer(aec->nearFrBuf, nearBl, PART_LEN); + + // For H band + if (aec->sampFreq == 32000) { + WebRtcApm_ReadBuffer(aec->nearFrBufH, nearBlH, PART_LEN); + } + + ProcessBlock(aec, farBl, nearBl, nearBlH, outBl, outBlH); + + WebRtcApm_WriteBuffer(aec->outFrBuf, outBl, PART_LEN); + // For H band + if (aec->sampFreq == 32000) { + WebRtcApm_WriteBuffer(aec->outFrBufH, outBlH, PART_LEN); + } + } + + // Stuff the out buffer if we have less than a frame to output. + // This should only happen for the first frame. + size = WebRtcApm_get_buffer_size(aec->outFrBuf); + if (size < FRAME_LEN) { + WebRtcApm_StuffBuffer(aec->outFrBuf, FRAME_LEN - size); + if (aec->sampFreq == 32000) { + WebRtcApm_StuffBuffer(aec->outFrBufH, FRAME_LEN - size); + } + } + + // Obtain an output frame. + WebRtcApm_ReadBuffer(aec->outFrBuf, out, FRAME_LEN); + // For H band + if (aec->sampFreq == 32000) { + WebRtcApm_ReadBuffer(aec->outFrBufH, outH, FRAME_LEN); + } +} + +static void ProcessBlock(aec_t *aec, const short *farend, + const short *nearend, const short *nearendH, + short *output, short *outputH) +{ + int i; + float d[PART_LEN], y[PART_LEN], e[PART_LEN], dH[PART_LEN]; + short eInt16[PART_LEN]; + float scale; + + float fft[PART_LEN2]; + float xf[2][PART_LEN1], yf[2][PART_LEN1], ef[2][PART_LEN1]; + complex_t df[PART_LEN1]; + + const float gPow[2] = {0.9f, 0.1f}; + + // Noise estimate constants. + const int noiseInitBlocks = 500 * aec->mult; + const float step = 0.1f; + const float ramp = 1.0002f; + const float gInitNoise[2] = {0.999f, 0.001f}; + +#ifdef AEC_DEBUG + fwrite(farend, sizeof(short), PART_LEN, aec->farFile); + fwrite(nearend, sizeof(short), PART_LEN, aec->nearFile); +#endif + + memset(dH, 0, sizeof(dH)); + + // ---------- Ooura fft ---------- + // Concatenate old and new farend blocks. + for (i = 0; i < PART_LEN; i++) { + aec->xBuf[i + PART_LEN] = (float)farend[i]; + d[i] = (float)nearend[i]; + } + + if (aec->sampFreq == 32000) { + for (i = 0; i < PART_LEN; i++) { + dH[i] = (float)nearendH[i]; + } + } + + memcpy(fft, aec->xBuf, sizeof(float) * PART_LEN2); + memcpy(aec->dBuf + PART_LEN, d, sizeof(float) * PART_LEN); + // For H band + if (aec->sampFreq == 32000) { + memcpy(aec->dBufH + PART_LEN, dH, sizeof(float) * PART_LEN); + } + + aec_rdft_forward_128(fft); + + // Far fft + xf[1][0] = 0; + xf[1][PART_LEN] = 0; + xf[0][0] = fft[0]; + xf[0][PART_LEN] = fft[1]; + + for (i = 1; i < PART_LEN; i++) { + xf[0][i] = fft[2 * i]; + xf[1][i] = fft[2 * i + 1]; + } + + // Near fft + memcpy(fft, aec->dBuf, sizeof(float) * PART_LEN2); + aec_rdft_forward_128(fft); + df[0][1] = 0; + df[PART_LEN][1] = 0; + df[0][0] = fft[0]; + df[PART_LEN][0] = fft[1]; + + for (i = 1; i < PART_LEN; i++) { + df[i][0] = fft[2 * i]; + df[i][1] = fft[2 * i + 1]; + } + + // Power smoothing + for (i = 0; i < PART_LEN1; i++) { + aec->xPow[i] = gPow[0] * aec->xPow[i] + gPow[1] * NR_PART * + (xf[0][i] * xf[0][i] + xf[1][i] * xf[1][i]); + aec->dPow[i] = gPow[0] * aec->dPow[i] + gPow[1] * + (df[i][0] * df[i][0] + df[i][1] * df[i][1]); + } + + // Estimate noise power. Wait until dPow is more stable. + if (aec->noiseEstCtr > 50) { + for (i = 0; i < PART_LEN1; i++) { + if (aec->dPow[i] < aec->dMinPow[i]) { + aec->dMinPow[i] = (aec->dPow[i] + step * (aec->dMinPow[i] - + aec->dPow[i])) * ramp; + } + else { + aec->dMinPow[i] *= ramp; + } + } + } + + // Smooth increasing noise power from zero at the start, + // to avoid a sudden burst of comfort noise. + if (aec->noiseEstCtr < noiseInitBlocks) { + aec->noiseEstCtr++; + for (i = 0; i < PART_LEN1; i++) { + if (aec->dMinPow[i] > aec->dInitMinPow[i]) { + aec->dInitMinPow[i] = gInitNoise[0] * aec->dInitMinPow[i] + + gInitNoise[1] * aec->dMinPow[i]; + } + else { + aec->dInitMinPow[i] = aec->dMinPow[i]; + } + } + aec->noisePow = aec->dInitMinPow; + } + else { + aec->noisePow = aec->dMinPow; + } + + + // Update the xfBuf block position. + aec->xfBufBlockPos--; + if (aec->xfBufBlockPos == -1) { + aec->xfBufBlockPos = NR_PART - 1; + } + + // Buffer xf + memcpy(aec->xfBuf[0] + aec->xfBufBlockPos * PART_LEN1, xf[0], + sizeof(float) * PART_LEN1); + memcpy(aec->xfBuf[1] + aec->xfBufBlockPos * PART_LEN1, xf[1], + sizeof(float) * PART_LEN1); + + memset(yf[0], 0, sizeof(float) * (PART_LEN1 * 2)); + + // Filter far + WebRtcAec_FilterFar(aec, yf); + + // Inverse fft to obtain echo estimate and error. + fft[0] = yf[0][0]; + fft[1] = yf[0][PART_LEN]; + for (i = 1; i < PART_LEN; i++) { + fft[2 * i] = yf[0][i]; + fft[2 * i + 1] = yf[1][i]; + } + aec_rdft_inverse_128(fft); + + scale = 2.0f / PART_LEN2; + for (i = 0; i < PART_LEN; i++) { + y[i] = fft[PART_LEN + i] * scale; // fft scaling + } + + for (i = 0; i < PART_LEN; i++) { + e[i] = d[i] - y[i]; + } + + // Error fft + memcpy(aec->eBuf + PART_LEN, e, sizeof(float) * PART_LEN); + memset(fft, 0, sizeof(float) * PART_LEN); + memcpy(fft + PART_LEN, e, sizeof(float) * PART_LEN); + aec_rdft_forward_128(fft); + + ef[1][0] = 0; + ef[1][PART_LEN] = 0; + ef[0][0] = fft[0]; + ef[0][PART_LEN] = fft[1]; + for (i = 1; i < PART_LEN; i++) { + ef[0][i] = fft[2 * i]; + ef[1][i] = fft[2 * i + 1]; + } + + // Scale error signal inversely with far power. + WebRtcAec_ScaleErrorSignal(aec, ef); + // Filter adaptation + WebRtcAec_FilterAdaptation(aec, fft, ef); + + NonLinearProcessing(aec, output, outputH); + +#ifdef AEC_DEBUG + for (i = 0; i < PART_LEN; i++) { + eInt16[i] = (short)WEBRTC_SPL_SAT(WEBRTC_SPL_WORD16_MAX, e[i], + WEBRTC_SPL_WORD16_MIN); + } +#endif + + if (aec->metricsMode == 1) { + for (i = 0; i < PART_LEN; i++) { + eInt16[i] = (short)WEBRTC_SPL_SAT(WEBRTC_SPL_WORD16_MAX, e[i], + WEBRTC_SPL_WORD16_MIN); + } + + // Update power levels and echo metrics + UpdateLevel(&aec->farlevel, farend); + UpdateLevel(&aec->nearlevel, nearend); + UpdateLevel(&aec->linoutlevel, eInt16); + UpdateLevel(&aec->nlpoutlevel, output); + UpdateMetrics(aec); + } + +#ifdef AEC_DEBUG + fwrite(eInt16, sizeof(short), PART_LEN, aec->outLpFile); + fwrite(output, sizeof(short), PART_LEN, aec->outFile); +#endif +} + +static void NonLinearProcessing(aec_t *aec, short *output, short *outputH) +{ + float efw[2][PART_LEN1], dfw[2][PART_LEN1]; + complex_t xfw[PART_LEN1]; + complex_t comfortNoiseHband[PART_LEN1]; + float fft[PART_LEN2]; + float scale, dtmp; + float nlpGainHband; + int i, j, pos; + + // Coherence and non-linear filter + float cohde[PART_LEN1], cohxd[PART_LEN1]; + float hNlDeAvg, hNlXdAvg; + float hNl[PART_LEN1]; + float hNlPref[PREF_BAND_SIZE]; + float hNlFb = 0, hNlFbLow = 0; + const float prefBandQuant = 0.75f, prefBandQuantLow = 0.5f; + const int prefBandSize = PREF_BAND_SIZE / aec->mult; + const int minPrefBand = 4 / aec->mult; + + // Near and error power sums + float sdSum = 0, seSum = 0; + + // Power estimate smoothing coefficients + const float gCoh[2][2] = {{0.9f, 0.1f}, {0.93f, 0.07f}}; + const float *ptrGCoh = gCoh[aec->mult - 1]; + + // Filter energey + float wfEnMax = 0, wfEn = 0; + const int delayEstInterval = 10 * aec->mult; + + aec->delayEstCtr++; + if (aec->delayEstCtr == delayEstInterval) { + aec->delayEstCtr = 0; + } + + // initialize comfort noise for H band + memset(comfortNoiseHband, 0, sizeof(comfortNoiseHband)); + nlpGainHband = (float)0.0; + dtmp = (float)0.0; + + // Measure energy in each filter partition to determine delay. + // TODO: Spread by computing one partition per block? + if (aec->delayEstCtr == 0) { + wfEnMax = 0; + aec->delayIdx = 0; + for (i = 0; i < NR_PART; i++) { + pos = i * PART_LEN1; + wfEn = 0; + for (j = 0; j < PART_LEN1; j++) { + wfEn += aec->wfBuf[0][pos + j] * aec->wfBuf[0][pos + j] + + aec->wfBuf[1][pos + j] * aec->wfBuf[1][pos + j]; + } + + if (wfEn > wfEnMax) { + wfEnMax = wfEn; + aec->delayIdx = i; + } + } + } + + // NLP + // Windowed far fft + for (i = 0; i < PART_LEN; i++) { + fft[i] = aec->xBuf[i] * sqrtHanning[i]; + fft[PART_LEN + i] = aec->xBuf[PART_LEN + i] * sqrtHanning[PART_LEN - i]; + } + aec_rdft_forward_128(fft); + + xfw[0][1] = 0; + xfw[PART_LEN][1] = 0; + xfw[0][0] = fft[0]; + xfw[PART_LEN][0] = fft[1]; + for (i = 1; i < PART_LEN; i++) { + xfw[i][0] = fft[2 * i]; + xfw[i][1] = fft[2 * i + 1]; + } + + // Buffer far. + memcpy(aec->xfwBuf, xfw, sizeof(xfw)); + + // Use delayed far. + memcpy(xfw, aec->xfwBuf + aec->delayIdx * PART_LEN1, sizeof(xfw)); + + // Windowed near fft + for (i = 0; i < PART_LEN; i++) { + fft[i] = aec->dBuf[i] * sqrtHanning[i]; + fft[PART_LEN + i] = aec->dBuf[PART_LEN + i] * sqrtHanning[PART_LEN - i]; + } + aec_rdft_forward_128(fft); + + dfw[1][0] = 0; + dfw[1][PART_LEN] = 0; + dfw[0][0] = fft[0]; + dfw[0][PART_LEN] = fft[1]; + for (i = 1; i < PART_LEN; i++) { + dfw[0][i] = fft[2 * i]; + dfw[1][i] = fft[2 * i + 1]; + } + + // Windowed error fft + for (i = 0; i < PART_LEN; i++) { + fft[i] = aec->eBuf[i] * sqrtHanning[i]; + fft[PART_LEN + i] = aec->eBuf[PART_LEN + i] * sqrtHanning[PART_LEN - i]; + } + aec_rdft_forward_128(fft); + efw[1][0] = 0; + efw[1][PART_LEN] = 0; + efw[0][0] = fft[0]; + efw[0][PART_LEN] = fft[1]; + for (i = 1; i < PART_LEN; i++) { + efw[0][i] = fft[2 * i]; + efw[1][i] = fft[2 * i + 1]; + } + + // Smoothed PSD + for (i = 0; i < PART_LEN1; i++) { + aec->sd[i] = ptrGCoh[0] * aec->sd[i] + ptrGCoh[1] * + (dfw[0][i] * dfw[0][i] + dfw[1][i] * dfw[1][i]); + aec->se[i] = ptrGCoh[0] * aec->se[i] + ptrGCoh[1] * + (efw[0][i] * efw[0][i] + efw[1][i] * efw[1][i]); + // We threshold here to protect against the ill-effects of a zero farend. + // The threshold is not arbitrarily chosen, but balances protection and + // adverse interaction with the algorithm's tuning. + // TODO: investigate further why this is so sensitive. + aec->sx[i] = ptrGCoh[0] * aec->sx[i] + ptrGCoh[1] * + WEBRTC_SPL_MAX(xfw[i][0] * xfw[i][0] + xfw[i][1] * xfw[i][1], 15); + + aec->sde[i][0] = ptrGCoh[0] * aec->sde[i][0] + ptrGCoh[1] * + (dfw[0][i] * efw[0][i] + dfw[1][i] * efw[1][i]); + aec->sde[i][1] = ptrGCoh[0] * aec->sde[i][1] + ptrGCoh[1] * + (dfw[0][i] * efw[1][i] - dfw[1][i] * efw[0][i]); + + aec->sxd[i][0] = ptrGCoh[0] * aec->sxd[i][0] + ptrGCoh[1] * + (dfw[0][i] * xfw[i][0] + dfw[1][i] * xfw[i][1]); + aec->sxd[i][1] = ptrGCoh[0] * aec->sxd[i][1] + ptrGCoh[1] * + (dfw[0][i] * xfw[i][1] - dfw[1][i] * xfw[i][0]); + + sdSum += aec->sd[i]; + seSum += aec->se[i]; + } + + // Divergent filter safeguard. + if (aec->divergeState == 0) { + if (seSum > sdSum) { + aec->divergeState = 1; + } + } + else { + if (seSum * 1.05f < sdSum) { + aec->divergeState = 0; + } + } + + if (aec->divergeState == 1) { + memcpy(efw, dfw, sizeof(efw)); + } + + // Reset if error is significantly larger than nearend (13 dB). + if (seSum > (19.95f * sdSum)) { + memset(aec->wfBuf, 0, sizeof(aec->wfBuf)); + } + + // Subband coherence + for (i = 0; i < PART_LEN1; i++) { + cohde[i] = (aec->sde[i][0] * aec->sde[i][0] + aec->sde[i][1] * aec->sde[i][1]) / + (aec->sd[i] * aec->se[i] + 1e-10f); + cohxd[i] = (aec->sxd[i][0] * aec->sxd[i][0] + aec->sxd[i][1] * aec->sxd[i][1]) / + (aec->sx[i] * aec->sd[i] + 1e-10f); + } + + hNlXdAvg = 0; + for (i = minPrefBand; i < prefBandSize + minPrefBand; i++) { + hNlXdAvg += cohxd[i]; + } + hNlXdAvg /= prefBandSize; + hNlXdAvg = 1 - hNlXdAvg; + + hNlDeAvg = 0; + for (i = minPrefBand; i < prefBandSize + minPrefBand; i++) { + hNlDeAvg += cohde[i]; + } + hNlDeAvg /= prefBandSize; + + if (hNlXdAvg < 0.75f && hNlXdAvg < aec->hNlXdAvgMin) { + aec->hNlXdAvgMin = hNlXdAvg; + } + + if (hNlDeAvg > 0.98f && hNlXdAvg > 0.9f) { + aec->stNearState = 1; + } + else if (hNlDeAvg < 0.95f || hNlXdAvg < 0.8f) { + aec->stNearState = 0; + } + + if (aec->hNlXdAvgMin == 1) { + aec->echoState = 0; + aec->overDrive = aec->minOverDrive; + + if (aec->stNearState == 1) { + memcpy(hNl, cohde, sizeof(hNl)); + hNlFb = hNlDeAvg; + hNlFbLow = hNlDeAvg; + } + else { + for (i = 0; i < PART_LEN1; i++) { + hNl[i] = 1 - cohxd[i]; + } + hNlFb = hNlXdAvg; + hNlFbLow = hNlXdAvg; + } + } + else { + + if (aec->stNearState == 1) { + aec->echoState = 0; + memcpy(hNl, cohde, sizeof(hNl)); + hNlFb = hNlDeAvg; + hNlFbLow = hNlDeAvg; + } + else { + aec->echoState = 1; + for (i = 0; i < PART_LEN1; i++) { + hNl[i] = WEBRTC_SPL_MIN(cohde[i], 1 - cohxd[i]); + } + + // Select an order statistic from the preferred bands. + // TODO: Using quicksort now, but a selection algorithm may be preferred. + memcpy(hNlPref, &hNl[minPrefBand], sizeof(float) * prefBandSize); + qsort(hNlPref, prefBandSize, sizeof(float), CmpFloat); + hNlFb = hNlPref[(int)floor(prefBandQuant * (prefBandSize - 1))]; + hNlFbLow = hNlPref[(int)floor(prefBandQuantLow * (prefBandSize - 1))]; + } + } + + // Track the local filter minimum to determine suppression overdrive. + if (hNlFbLow < 0.6f && hNlFbLow < aec->hNlFbLocalMin) { + aec->hNlFbLocalMin = hNlFbLow; + aec->hNlFbMin = hNlFbLow; + aec->hNlNewMin = 1; + aec->hNlMinCtr = 0; + } + aec->hNlFbLocalMin = WEBRTC_SPL_MIN(aec->hNlFbLocalMin + 0.0008f / aec->mult, 1); + aec->hNlXdAvgMin = WEBRTC_SPL_MIN(aec->hNlXdAvgMin + 0.0006f / aec->mult, 1); + + if (aec->hNlNewMin == 1) { + aec->hNlMinCtr++; + } + if (aec->hNlMinCtr == 2) { + aec->hNlNewMin = 0; + aec->hNlMinCtr = 0; + aec->overDrive = WEBRTC_SPL_MAX(aec->targetSupp / + ((float)log(aec->hNlFbMin + 1e-10f) + 1e-10f), aec->minOverDrive); + } + + // Smooth the overdrive. + if (aec->overDrive < aec->overDriveSm) { + aec->overDriveSm = 0.99f * aec->overDriveSm + 0.01f * aec->overDrive; + } + else { + aec->overDriveSm = 0.9f * aec->overDriveSm + 0.1f * aec->overDrive; + } + + WebRtcAec_OverdriveAndSuppress(aec, hNl, hNlFb, efw); + + // Add comfort noise. + ComfortNoise(aec, efw, comfortNoiseHband, aec->noisePow, hNl); + + // Inverse error fft. + fft[0] = efw[0][0]; + fft[1] = efw[0][PART_LEN]; + for (i = 1; i < PART_LEN; i++) { + fft[2*i] = efw[0][i]; + // Sign change required by Ooura fft. + fft[2*i + 1] = -efw[1][i]; + } + aec_rdft_inverse_128(fft); + + // Overlap and add to obtain output. + scale = 2.0f / PART_LEN2; + for (i = 0; i < PART_LEN; i++) { + fft[i] *= scale; // fft scaling + fft[i] = fft[i]*sqrtHanning[i] + aec->outBuf[i]; + + // Saturation protection + output[i] = (short)WEBRTC_SPL_SAT(WEBRTC_SPL_WORD16_MAX, fft[i], + WEBRTC_SPL_WORD16_MIN); + + fft[PART_LEN + i] *= scale; // fft scaling + aec->outBuf[i] = fft[PART_LEN + i] * sqrtHanning[PART_LEN - i]; + } + + // For H band + if (aec->sampFreq == 32000) { + + // H band gain + // average nlp over low band: average over second half of freq spectrum + // (4->8khz) + GetHighbandGain(hNl, &nlpGainHband); + + // Inverse comfort_noise + if (flagHbandCn == 1) { + fft[0] = comfortNoiseHband[0][0]; + fft[1] = comfortNoiseHband[PART_LEN][0]; + for (i = 1; i < PART_LEN; i++) { + fft[2*i] = comfortNoiseHband[i][0]; + fft[2*i + 1] = comfortNoiseHband[i][1]; + } + aec_rdft_inverse_128(fft); + scale = 2.0f / PART_LEN2; + } + + // compute gain factor + for (i = 0; i < PART_LEN; i++) { + dtmp = (float)aec->dBufH[i]; + dtmp = (float)dtmp * nlpGainHband; // for variable gain + + // add some comfort noise where Hband is attenuated + if (flagHbandCn == 1) { + fft[i] *= scale; // fft scaling + dtmp += cnScaleHband * fft[i]; + } + + // Saturation protection + outputH[i] = (short)WEBRTC_SPL_SAT(WEBRTC_SPL_WORD16_MAX, dtmp, + WEBRTC_SPL_WORD16_MIN); + } + } + + // Copy the current block to the old position. + memcpy(aec->xBuf, aec->xBuf + PART_LEN, sizeof(float) * PART_LEN); + memcpy(aec->dBuf, aec->dBuf + PART_LEN, sizeof(float) * PART_LEN); + memcpy(aec->eBuf, aec->eBuf + PART_LEN, sizeof(float) * PART_LEN); + + // Copy the current block to the old position for H band + if (aec->sampFreq == 32000) { + memcpy(aec->dBufH, aec->dBufH + PART_LEN, sizeof(float) * PART_LEN); + } + + memmove(aec->xfwBuf + PART_LEN1, aec->xfwBuf, sizeof(aec->xfwBuf) - + sizeof(complex_t) * PART_LEN1); +} + +static void GetHighbandGain(const float *lambda, float *nlpGainHband) +{ + int i; + + nlpGainHband[0] = (float)0.0; + for (i = freqAvgIc; i < PART_LEN1 - 1; i++) { + nlpGainHband[0] += lambda[i]; + } + nlpGainHband[0] /= (float)(PART_LEN1 - 1 - freqAvgIc); +} + +static void ComfortNoise(aec_t *aec, float efw[2][PART_LEN1], + complex_t *comfortNoiseHband, const float *noisePow, const float *lambda) +{ + int i, num; + float rand[PART_LEN]; + float noise, noiseAvg, tmp, tmpAvg; + WebRtc_Word16 randW16[PART_LEN]; + complex_t u[PART_LEN1]; + + const float pi2 = 6.28318530717959f; + + // Generate a uniform random array on [0 1] + WebRtcSpl_RandUArray(randW16, PART_LEN, &aec->seed); + for (i = 0; i < PART_LEN; i++) { + rand[i] = ((float)randW16[i]) / 32768; + } + + // Reject LF noise + u[0][0] = 0; + u[0][1] = 0; + for (i = 1; i < PART_LEN1; i++) { + tmp = pi2 * rand[i - 1]; + + noise = sqrtf(noisePow[i]); + u[i][0] = noise * (float)cos(tmp); + u[i][1] = -noise * (float)sin(tmp); + } + u[PART_LEN][1] = 0; + + for (i = 0; i < PART_LEN1; i++) { + // This is the proper weighting to match the background noise power + tmp = sqrtf(WEBRTC_SPL_MAX(1 - lambda[i] * lambda[i], 0)); + //tmp = 1 - lambda[i]; + efw[0][i] += tmp * u[i][0]; + efw[1][i] += tmp * u[i][1]; + } + + // For H band comfort noise + // TODO: don't compute noise and "tmp" twice. Use the previous results. + noiseAvg = 0.0; + tmpAvg = 0.0; + num = 0; + if (aec->sampFreq == 32000 && flagHbandCn == 1) { + + // average noise scale + // average over second half of freq spectrum (i.e., 4->8khz) + // TODO: we shouldn't need num. We know how many elements we're summing. + for (i = PART_LEN1 >> 1; i < PART_LEN1; i++) { + num++; + noiseAvg += sqrtf(noisePow[i]); + } + noiseAvg /= (float)num; + + // average nlp scale + // average over second half of freq spectrum (i.e., 4->8khz) + // TODO: we shouldn't need num. We know how many elements we're summing. + num = 0; + for (i = PART_LEN1 >> 1; i < PART_LEN1; i++) { + num++; + tmpAvg += sqrtf(WEBRTC_SPL_MAX(1 - lambda[i] * lambda[i], 0)); + } + tmpAvg /= (float)num; + + // Use average noise for H band + // TODO: we should probably have a new random vector here. + // Reject LF noise + u[0][0] = 0; + u[0][1] = 0; + for (i = 1; i < PART_LEN1; i++) { + tmp = pi2 * rand[i - 1]; + + // Use average noise for H band + u[i][0] = noiseAvg * (float)cos(tmp); + u[i][1] = -noiseAvg * (float)sin(tmp); + } + u[PART_LEN][1] = 0; + + for (i = 0; i < PART_LEN1; i++) { + // Use average NLP weight for H band + comfortNoiseHband[i][0] = tmpAvg * u[i][0]; + comfortNoiseHband[i][1] = tmpAvg * u[i][1]; + } + } +} + +// Buffer the farend to account for knownDelay +static void BufferFar(aec_t *aec, const short *farend, int farLen) +{ + int writeLen = farLen, writePos = 0; + + // Check if the write position must be wrapped. + while (aec->farBufWritePos + writeLen > FAR_BUF_LEN) { + + // Write to remaining buffer space before wrapping. + writeLen = FAR_BUF_LEN - aec->farBufWritePos; + memcpy(aec->farBuf + aec->farBufWritePos, farend + writePos, + sizeof(short) * writeLen); + aec->farBufWritePos = 0; + writePos = writeLen; + writeLen = farLen - writeLen; + } + + memcpy(aec->farBuf + aec->farBufWritePos, farend + writePos, + sizeof(short) * writeLen); + aec->farBufWritePos += writeLen; +} + +static void FetchFar(aec_t *aec, short *farend, int farLen, int knownDelay) +{ + int readLen = farLen, readPos = 0, delayChange = knownDelay - aec->knownDelay; + + aec->farBufReadPos -= delayChange; + + // Check if delay forces a read position wrap. + while(aec->farBufReadPos < 0) { + aec->farBufReadPos += FAR_BUF_LEN; + } + while(aec->farBufReadPos > FAR_BUF_LEN - 1) { + aec->farBufReadPos -= FAR_BUF_LEN; + } + + aec->knownDelay = knownDelay; + + // Check if read position must be wrapped. + while (aec->farBufReadPos + readLen > FAR_BUF_LEN) { + + // Read from remaining buffer space before wrapping. + readLen = FAR_BUF_LEN - aec->farBufReadPos; + memcpy(farend + readPos, aec->farBuf + aec->farBufReadPos, + sizeof(short) * readLen); + aec->farBufReadPos = 0; + readPos = readLen; + readLen = farLen - readLen; + } + memcpy(farend + readPos, aec->farBuf + aec->farBufReadPos, + sizeof(short) * readLen); + aec->farBufReadPos += readLen; +} + +static void WebRtcAec_InitLevel(power_level_t *level) +{ + const float bigFloat = 1E17f; + + level->averagelevel = 0; + level->framelevel = 0; + level->minlevel = bigFloat; + level->frsum = 0; + level->sfrsum = 0; + level->frcounter = 0; + level->sfrcounter = 0; +} + +static void WebRtcAec_InitStats(stats_t *stats) +{ + stats->instant = offsetLevel; + stats->average = offsetLevel; + stats->max = offsetLevel; + stats->min = offsetLevel * (-1); + stats->sum = 0; + stats->hisum = 0; + stats->himean = offsetLevel; + stats->counter = 0; + stats->hicounter = 0; +} + +static void UpdateLevel(power_level_t *level, const short *in) +{ + int k; + + for (k = 0; k < PART_LEN; k++) { + level->sfrsum += in[k] * in[k]; + } + level->sfrcounter++; + + if (level->sfrcounter > subCountLen) { + level->framelevel = level->sfrsum / (subCountLen * PART_LEN); + level->sfrsum = 0; + level->sfrcounter = 0; + + if (level->framelevel > 0) { + if (level->framelevel < level->minlevel) { + level->minlevel = level->framelevel; // New minimum + } else { + level->minlevel *= (1 + 0.001f); // Small increase + } + } + level->frcounter++; + level->frsum += level->framelevel; + + if (level->frcounter > countLen) { + level->averagelevel = level->frsum / countLen; + level->frsum = 0; + level->frcounter = 0; + } + + } +} + +static void UpdateMetrics(aec_t *aec) +{ + float dtmp, dtmp2; + + const float actThresholdNoisy = 8.0f; + const float actThresholdClean = 40.0f; + const float safety = 0.99995f; + const float noisyPower = 300000.0f; + + float actThreshold; + float echo, suppressedEcho; + + if (aec->echoState) { // Check if echo is likely present + aec->stateCounter++; + } + + if (aec->farlevel.frcounter == countLen) { + + if (aec->farlevel.minlevel < noisyPower) { + actThreshold = actThresholdClean; + } + else { + actThreshold = actThresholdNoisy; + } + + if ((aec->stateCounter > (0.5f * countLen * subCountLen)) + && (aec->farlevel.sfrcounter == 0) + + // Estimate in active far-end segments only + && (aec->farlevel.averagelevel > (actThreshold * aec->farlevel.minlevel)) + ) { + + // Subtract noise power + echo = aec->nearlevel.averagelevel - safety * aec->nearlevel.minlevel; + + // ERL + dtmp = 10 * (float)log10(aec->farlevel.averagelevel / + aec->nearlevel.averagelevel + 1e-10f); + dtmp2 = 10 * (float)log10(aec->farlevel.averagelevel / echo + 1e-10f); + + aec->erl.instant = dtmp; + if (dtmp > aec->erl.max) { + aec->erl.max = dtmp; + } + + if (dtmp < aec->erl.min) { + aec->erl.min = dtmp; + } + + aec->erl.counter++; + aec->erl.sum += dtmp; + aec->erl.average = aec->erl.sum / aec->erl.counter; + + // Upper mean + if (dtmp > aec->erl.average) { + aec->erl.hicounter++; + aec->erl.hisum += dtmp; + aec->erl.himean = aec->erl.hisum / aec->erl.hicounter; + } + + // A_NLP + dtmp = 10 * (float)log10(aec->nearlevel.averagelevel / + aec->linoutlevel.averagelevel + 1e-10f); + + // subtract noise power + suppressedEcho = aec->linoutlevel.averagelevel - safety * aec->linoutlevel.minlevel; + + dtmp2 = 10 * (float)log10(echo / suppressedEcho + 1e-10f); + + aec->aNlp.instant = dtmp2; + if (dtmp > aec->aNlp.max) { + aec->aNlp.max = dtmp; + } + + if (dtmp < aec->aNlp.min) { + aec->aNlp.min = dtmp; + } + + aec->aNlp.counter++; + aec->aNlp.sum += dtmp; + aec->aNlp.average = aec->aNlp.sum / aec->aNlp.counter; + + // Upper mean + if (dtmp > aec->aNlp.average) { + aec->aNlp.hicounter++; + aec->aNlp.hisum += dtmp; + aec->aNlp.himean = aec->aNlp.hisum / aec->aNlp.hicounter; + } + + // ERLE + + // subtract noise power + suppressedEcho = aec->nlpoutlevel.averagelevel - safety * aec->nlpoutlevel.minlevel; + + dtmp = 10 * (float)log10(aec->nearlevel.averagelevel / + aec->nlpoutlevel.averagelevel + 1e-10f); + dtmp2 = 10 * (float)log10(echo / suppressedEcho + 1e-10f); + + dtmp = dtmp2; + aec->erle.instant = dtmp; + if (dtmp > aec->erle.max) { + aec->erle.max = dtmp; + } + + if (dtmp < aec->erle.min) { + aec->erle.min = dtmp; + } + + aec->erle.counter++; + aec->erle.sum += dtmp; + aec->erle.average = aec->erle.sum / aec->erle.counter; + + // Upper mean + if (dtmp > aec->erle.average) { + aec->erle.hicounter++; + aec->erle.hisum += dtmp; + aec->erle.himean = aec->erle.hisum / aec->erle.hicounter; + } + } + + aec->stateCounter = 0; + } +} + diff --git a/src/modules/audio_processing/aec/main/source/aec_core.h b/src/modules/audio_processing/aec/main/source/aec_core.h new file mode 100644 index 0000000..8726bd5 --- /dev/null +++ b/src/modules/audio_processing/aec/main/source/aec_core.h @@ -0,0 +1,176 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +/* + * Specifies the interface for the AEC core. + */ + +#ifndef WEBRTC_MODULES_AUDIO_PROCESSING_AEC_MAIN_SOURCE_AEC_CORE_H_ +#define WEBRTC_MODULES_AUDIO_PROCESSING_AEC_MAIN_SOURCE_AEC_CORE_H_ + +#include + +#include "signal_processing_library.h" +#include "typedefs.h" + +//#define UNCONSTR // time-unconstrained filter +//#define AEC_DEBUG // for recording files + +#define FRAME_LEN 80 +#define PART_LEN 64 // Length of partition +#define PART_LEN1 (PART_LEN + 1) // Unique fft coefficients +#define PART_LEN2 (PART_LEN * 2) // Length of partition * 2 +#define NR_PART 12 // Number of partitions +#define FILT_LEN (PART_LEN * NR_PART) // Filter length +#define FILT_LEN2 (FILT_LEN * 2) // Double filter length +#define FAR_BUF_LEN (FILT_LEN2 * 2) +#define PREF_BAND_SIZE 24 + +#define BLOCKL_MAX FRAME_LEN + +typedef float complex_t[2]; +// For performance reasons, some arrays of complex numbers are replaced by twice +// as long arrays of float, all the real parts followed by all the imaginary +// ones (complex_t[SIZE] -> float[2][SIZE]). This allows SIMD optimizations and +// is better than two arrays (one for the real parts and one for the imaginary +// parts) as this other way would require two pointers instead of one and cause +// extra register spilling. This also allows the offsets to be calculated at +// compile time. + +// Metrics +enum {offsetLevel = -100}; + +typedef struct { + float sfrsum; + int sfrcounter; + float framelevel; + float frsum; + int frcounter; + float minlevel; + float averagelevel; +} power_level_t; + +typedef struct { + float instant; + float average; + float min; + float max; + float sum; + float hisum; + float himean; + int counter; + int hicounter; +} stats_t; + +typedef struct { + int farBufWritePos, farBufReadPos; + + int knownDelay; + int inSamples, outSamples; + int delayEstCtr; + + void *farFrBuf, *nearFrBuf, *outFrBuf; + + void *nearFrBufH; + void *outFrBufH; + + float xBuf[PART_LEN2]; // farend + float dBuf[PART_LEN2]; // nearend + float eBuf[PART_LEN2]; // error + + float dBufH[PART_LEN2]; // nearend + + float xPow[PART_LEN1]; + float dPow[PART_LEN1]; + float dMinPow[PART_LEN1]; + float dInitMinPow[PART_LEN1]; + float *noisePow; + + float xfBuf[2][NR_PART * PART_LEN1]; // farend fft buffer + float wfBuf[2][NR_PART * PART_LEN1]; // filter fft + complex_t sde[PART_LEN1]; // cross-psd of nearend and error + complex_t sxd[PART_LEN1]; // cross-psd of farend and nearend + complex_t xfwBuf[NR_PART * PART_LEN1]; // farend windowed fft buffer + + float sx[PART_LEN1], sd[PART_LEN1], se[PART_LEN1]; // far, near and error psd + float hNs[PART_LEN1]; + float hNlFbMin, hNlFbLocalMin; + float hNlXdAvgMin; + int hNlNewMin, hNlMinCtr; + float overDrive, overDriveSm; + float targetSupp, minOverDrive; + float outBuf[PART_LEN]; + int delayIdx; + + short stNearState, echoState; + short divergeState; + + int xfBufBlockPos; + + short farBuf[FILT_LEN2 * 2]; + + short mult; // sampling frequency multiple + int sampFreq; + WebRtc_UWord32 seed; + + float mu; // stepsize + float errThresh; // error threshold + + int noiseEstCtr; + + power_level_t farlevel; + power_level_t nearlevel; + power_level_t linoutlevel; + power_level_t nlpoutlevel; + + int metricsMode; + int stateCounter; + stats_t erl; + stats_t erle; + stats_t aNlp; + stats_t rerl; + + // Quantities to control H band scaling for SWB input + int freq_avg_ic; //initial bin for averaging nlp gain + int flag_Hband_cn; //for comfort noise + float cn_scale_Hband; //scale for comfort noise in H band + +#ifdef AEC_DEBUG + FILE *farFile; + FILE *nearFile; + FILE *outFile; + FILE *outLpFile; +#endif +} aec_t; + +typedef void (*WebRtcAec_FilterFar_t)(aec_t *aec, float yf[2][PART_LEN1]); +extern WebRtcAec_FilterFar_t WebRtcAec_FilterFar; +typedef void (*WebRtcAec_ScaleErrorSignal_t)(aec_t *aec, float ef[2][PART_LEN1]); +extern WebRtcAec_ScaleErrorSignal_t WebRtcAec_ScaleErrorSignal; +typedef void (*WebRtcAec_FilterAdaptation_t) + (aec_t *aec, float *fft, float ef[2][PART_LEN1]); +extern WebRtcAec_FilterAdaptation_t WebRtcAec_FilterAdaptation; +typedef void (*WebRtcAec_OverdriveAndSuppress_t) + (aec_t *aec, float hNl[PART_LEN1], const float hNlFb, float efw[2][PART_LEN1]); +extern WebRtcAec_OverdriveAndSuppress_t WebRtcAec_OverdriveAndSuppress; + +int WebRtcAec_CreateAec(aec_t **aec); +int WebRtcAec_FreeAec(aec_t *aec); +int WebRtcAec_InitAec(aec_t *aec, int sampFreq); +void WebRtcAec_InitAec_SSE2(void); + +void WebRtcAec_InitMetrics(aec_t *aec); +void WebRtcAec_ProcessFrame(aec_t *aec, const short *farend, + const short *nearend, const short *nearendH, + short *out, short *outH, + int knownDelay); + +#endif // WEBRTC_MODULES_AUDIO_PROCESSING_AEC_MAIN_SOURCE_AEC_CORE_H_ + diff --git a/src/modules/audio_processing/aec/main/source/aec_core_sse2.c b/src/modules/audio_processing/aec/main/source/aec_core_sse2.c new file mode 100644 index 0000000..0f732e0 --- /dev/null +++ b/src/modules/audio_processing/aec/main/source/aec_core_sse2.c @@ -0,0 +1,429 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +/* + * The core AEC algorithm, SSE2 version of speed-critical functions. + */ + +#include "typedefs.h" + +#if defined(WEBRTC_USE_SSE2) +#include +#include + +#include "aec_core.h" +#include "aec_rdft.h" + +__inline static float MulRe(float aRe, float aIm, float bRe, float bIm) +{ + return aRe * bRe - aIm * bIm; +} + +__inline static float MulIm(float aRe, float aIm, float bRe, float bIm) +{ + return aRe * bIm + aIm * bRe; +} + +static void FilterFarSSE2(aec_t *aec, float yf[2][PART_LEN1]) +{ + int i; + for (i = 0; i < NR_PART; i++) { + int j; + int xPos = (i + aec->xfBufBlockPos) * PART_LEN1; + int pos = i * PART_LEN1; + // Check for wrap + if (i + aec->xfBufBlockPos >= NR_PART) { + xPos -= NR_PART*(PART_LEN1); + } + + // vectorized code (four at once) + for (j = 0; j + 3 < PART_LEN1; j += 4) { + const __m128 xfBuf_re = _mm_loadu_ps(&aec->xfBuf[0][xPos + j]); + const __m128 xfBuf_im = _mm_loadu_ps(&aec->xfBuf[1][xPos + j]); + const __m128 wfBuf_re = _mm_loadu_ps(&aec->wfBuf[0][pos + j]); + const __m128 wfBuf_im = _mm_loadu_ps(&aec->wfBuf[1][pos + j]); + const __m128 yf_re = _mm_loadu_ps(&yf[0][j]); + const __m128 yf_im = _mm_loadu_ps(&yf[1][j]); + const __m128 a = _mm_mul_ps(xfBuf_re, wfBuf_re); + const __m128 b = _mm_mul_ps(xfBuf_im, wfBuf_im); + const __m128 c = _mm_mul_ps(xfBuf_re, wfBuf_im); + const __m128 d = _mm_mul_ps(xfBuf_im, wfBuf_re); + const __m128 e = _mm_sub_ps(a, b); + const __m128 f = _mm_add_ps(c, d); + const __m128 g = _mm_add_ps(yf_re, e); + const __m128 h = _mm_add_ps(yf_im, f); + _mm_storeu_ps(&yf[0][j], g); + _mm_storeu_ps(&yf[1][j], h); + } + // scalar code for the remaining items. + for (; j < PART_LEN1; j++) { + yf[0][j] += MulRe(aec->xfBuf[0][xPos + j], aec->xfBuf[1][xPos + j], + aec->wfBuf[0][ pos + j], aec->wfBuf[1][ pos + j]); + yf[1][j] += MulIm(aec->xfBuf[0][xPos + j], aec->xfBuf[1][xPos + j], + aec->wfBuf[0][ pos + j], aec->wfBuf[1][ pos + j]); + } + } +} + +static void ScaleErrorSignalSSE2(aec_t *aec, float ef[2][PART_LEN1]) +{ + const __m128 k1e_10f = _mm_set1_ps(1e-10f); + const __m128 kThresh = _mm_set1_ps(aec->errThresh); + const __m128 kMu = _mm_set1_ps(aec->mu); + + int i; + // vectorized code (four at once) + for (i = 0; i + 3 < PART_LEN1; i += 4) { + const __m128 xPow = _mm_loadu_ps(&aec->xPow[i]); + const __m128 ef_re_base = _mm_loadu_ps(&ef[0][i]); + const __m128 ef_im_base = _mm_loadu_ps(&ef[1][i]); + + const __m128 xPowPlus = _mm_add_ps(xPow, k1e_10f); + __m128 ef_re = _mm_div_ps(ef_re_base, xPowPlus); + __m128 ef_im = _mm_div_ps(ef_im_base, xPowPlus); + const __m128 ef_re2 = _mm_mul_ps(ef_re, ef_re); + const __m128 ef_im2 = _mm_mul_ps(ef_im, ef_im); + const __m128 ef_sum2 = _mm_add_ps(ef_re2, ef_im2); + const __m128 absEf = _mm_sqrt_ps(ef_sum2); + const __m128 bigger = _mm_cmpgt_ps(absEf, kThresh); + __m128 absEfPlus = _mm_add_ps(absEf, k1e_10f); + const __m128 absEfInv = _mm_div_ps(kThresh, absEfPlus); + __m128 ef_re_if = _mm_mul_ps(ef_re, absEfInv); + __m128 ef_im_if = _mm_mul_ps(ef_im, absEfInv); + ef_re_if = _mm_and_ps(bigger, ef_re_if); + ef_im_if = _mm_and_ps(bigger, ef_im_if); + ef_re = _mm_andnot_ps(bigger, ef_re); + ef_im = _mm_andnot_ps(bigger, ef_im); + ef_re = _mm_or_ps(ef_re, ef_re_if); + ef_im = _mm_or_ps(ef_im, ef_im_if); + ef_re = _mm_mul_ps(ef_re, kMu); + ef_im = _mm_mul_ps(ef_im, kMu); + + _mm_storeu_ps(&ef[0][i], ef_re); + _mm_storeu_ps(&ef[1][i], ef_im); + } + // scalar code for the remaining items. + for (; i < (PART_LEN1); i++) { + float absEf; + ef[0][i] /= (aec->xPow[i] + 1e-10f); + ef[1][i] /= (aec->xPow[i] + 1e-10f); + absEf = sqrtf(ef[0][i] * ef[0][i] + ef[1][i] * ef[1][i]); + + if (absEf > aec->errThresh) { + absEf = aec->errThresh / (absEf + 1e-10f); + ef[0][i] *= absEf; + ef[1][i] *= absEf; + } + + // Stepsize factor + ef[0][i] *= aec->mu; + ef[1][i] *= aec->mu; + } +} + +static void FilterAdaptationSSE2(aec_t *aec, float *fft, float ef[2][PART_LEN1]) { + int i, j; + for (i = 0; i < NR_PART; i++) { + int xPos = (i + aec->xfBufBlockPos)*(PART_LEN1); + int pos = i * PART_LEN1; + // Check for wrap + if (i + aec->xfBufBlockPos >= NR_PART) { + xPos -= NR_PART * PART_LEN1; + } + +#ifdef UNCONSTR + for (j = 0; j < PART_LEN1; j++) { + aec->wfBuf[pos + j][0] += MulRe(aec->xfBuf[xPos + j][0], + -aec->xfBuf[xPos + j][1], + ef[j][0], ef[j][1]); + aec->wfBuf[pos + j][1] += MulIm(aec->xfBuf[xPos + j][0], + -aec->xfBuf[xPos + j][1], + ef[j][0], ef[j][1]); + } +#else + // Process the whole array... + for (j = 0; j < PART_LEN; j+= 4) { + // Load xfBuf and ef. + const __m128 xfBuf_re = _mm_loadu_ps(&aec->xfBuf[0][xPos + j]); + const __m128 xfBuf_im = _mm_loadu_ps(&aec->xfBuf[1][xPos + j]); + const __m128 ef_re = _mm_loadu_ps(&ef[0][j]); + const __m128 ef_im = _mm_loadu_ps(&ef[1][j]); + // Calculate the product of conjugate(xfBuf) by ef. + // re(conjugate(a) * b) = aRe * bRe + aIm * bIm + // im(conjugate(a) * b)= aRe * bIm - aIm * bRe + const __m128 a = _mm_mul_ps(xfBuf_re, ef_re); + const __m128 b = _mm_mul_ps(xfBuf_im, ef_im); + const __m128 c = _mm_mul_ps(xfBuf_re, ef_im); + const __m128 d = _mm_mul_ps(xfBuf_im, ef_re); + const __m128 e = _mm_add_ps(a, b); + const __m128 f = _mm_sub_ps(c, d); + // Interleave real and imaginary parts. + const __m128 g = _mm_unpacklo_ps(e, f); + const __m128 h = _mm_unpackhi_ps(e, f); + // Store + _mm_storeu_ps(&fft[2*j + 0], g); + _mm_storeu_ps(&fft[2*j + 4], h); + } + // ... and fixup the first imaginary entry. + fft[1] = MulRe(aec->xfBuf[0][xPos + PART_LEN], + -aec->xfBuf[1][xPos + PART_LEN], + ef[0][PART_LEN], ef[1][PART_LEN]); + + aec_rdft_inverse_128(fft); + memset(fft + PART_LEN, 0, sizeof(float)*PART_LEN); + + // fft scaling + { + float scale = 2.0f / PART_LEN2; + const __m128 scale_ps = _mm_load_ps1(&scale); + for (j = 0; j < PART_LEN; j+=4) { + const __m128 fft_ps = _mm_loadu_ps(&fft[j]); + const __m128 fft_scale = _mm_mul_ps(fft_ps, scale_ps); + _mm_storeu_ps(&fft[j], fft_scale); + } + } + aec_rdft_forward_128(fft); + + { + float wt1 = aec->wfBuf[1][pos]; + aec->wfBuf[0][pos + PART_LEN] += fft[1]; + for (j = 0; j < PART_LEN; j+= 4) { + __m128 wtBuf_re = _mm_loadu_ps(&aec->wfBuf[0][pos + j]); + __m128 wtBuf_im = _mm_loadu_ps(&aec->wfBuf[1][pos + j]); + const __m128 fft0 = _mm_loadu_ps(&fft[2 * j + 0]); + const __m128 fft4 = _mm_loadu_ps(&fft[2 * j + 4]); + const __m128 fft_re = _mm_shuffle_ps(fft0, fft4, _MM_SHUFFLE(2, 0, 2 ,0)); + const __m128 fft_im = _mm_shuffle_ps(fft0, fft4, _MM_SHUFFLE(3, 1, 3 ,1)); + wtBuf_re = _mm_add_ps(wtBuf_re, fft_re); + wtBuf_im = _mm_add_ps(wtBuf_im, fft_im); + _mm_storeu_ps(&aec->wfBuf[0][pos + j], wtBuf_re); + _mm_storeu_ps(&aec->wfBuf[1][pos + j], wtBuf_im); + } + aec->wfBuf[1][pos] = wt1; + } +#endif // UNCONSTR + } +} + +static __m128 mm_pow_ps(__m128 a, __m128 b) +{ + // a^b = exp2(b * log2(a)) + // exp2(x) and log2(x) are calculated using polynomial approximations. + __m128 log2_a, b_log2_a, a_exp_b; + + // Calculate log2(x), x = a. + { + // To calculate log2(x), we decompose x like this: + // x = y * 2^n + // n is an integer + // y is in the [1.0, 2.0) range + // + // log2(x) = log2(y) + n + // n can be evaluated by playing with float representation. + // log2(y) in a small range can be approximated, this code uses an order + // five polynomial approximation. The coefficients have been + // estimated with the Remez algorithm and the resulting + // polynomial has a maximum relative error of 0.00086%. + + // Compute n. + // This is done by masking the exponent, shifting it into the top bit of + // the mantissa, putting eight into the biased exponent (to shift/ + // compensate the fact that the exponent has been shifted in the top/ + // fractional part and finally getting rid of the implicit leading one + // from the mantissa by substracting it out. + static const ALIGN16_BEG int float_exponent_mask[4] ALIGN16_END = + {0x7F800000, 0x7F800000, 0x7F800000, 0x7F800000}; + static const ALIGN16_BEG int eight_biased_exponent[4] ALIGN16_END = + {0x43800000, 0x43800000, 0x43800000, 0x43800000}; + static const ALIGN16_BEG int implicit_leading_one[4] ALIGN16_END = + {0x43BF8000, 0x43BF8000, 0x43BF8000, 0x43BF8000}; + static const int shift_exponent_into_top_mantissa = 8; + const __m128 two_n = _mm_and_ps(a, *((__m128 *)float_exponent_mask)); + const __m128 n_1 = (__m128)_mm_srli_epi32((__m128i)two_n, + shift_exponent_into_top_mantissa); + const __m128 n_0 = _mm_or_ps( + (__m128)n_1, *((__m128 *)eight_biased_exponent)); + const __m128 n = _mm_sub_ps(n_0, *((__m128 *)implicit_leading_one)); + + // Compute y. + static const ALIGN16_BEG int mantissa_mask[4] ALIGN16_END = + {0x007FFFFF, 0x007FFFFF, 0x007FFFFF, 0x007FFFFF}; + static const ALIGN16_BEG int zero_biased_exponent_is_one[4] ALIGN16_END = + {0x3F800000, 0x3F800000, 0x3F800000, 0x3F800000}; + const __m128 mantissa = _mm_and_ps(a, *((__m128 *)mantissa_mask)); + const __m128 y = _mm_or_ps( + mantissa, *((__m128 *)zero_biased_exponent_is_one)); + + // Approximate log2(y) ~= (y - 1) * pol5(y). + // pol5(y) = C5 * y^5 + C4 * y^4 + C3 * y^3 + C2 * y^2 + C1 * y + C0 + static const ALIGN16_BEG float ALIGN16_END C5[4] = + {-3.4436006e-2f, -3.4436006e-2f, -3.4436006e-2f, -3.4436006e-2f}; + static const ALIGN16_BEG float ALIGN16_END C4[4] = + {3.1821337e-1f, 3.1821337e-1f, 3.1821337e-1f, 3.1821337e-1f}; + static const ALIGN16_BEG float ALIGN16_END C3[4] = + {-1.2315303f, -1.2315303f, -1.2315303f, -1.2315303f}; + static const ALIGN16_BEG float ALIGN16_END C2[4] = + {2.5988452f, 2.5988452f, 2.5988452f, 2.5988452f}; + static const ALIGN16_BEG float ALIGN16_END C1[4] = + {-3.3241990f, -3.3241990f, -3.3241990f, -3.3241990f}; + static const ALIGN16_BEG float ALIGN16_END C0[4] = + {3.1157899f, 3.1157899f, 3.1157899f, 3.1157899f}; + const __m128 pol5_y_0 = _mm_mul_ps(y, *((__m128 *)C5)); + const __m128 pol5_y_1 = _mm_add_ps(pol5_y_0, *((__m128 *)C4)); + const __m128 pol5_y_2 = _mm_mul_ps(pol5_y_1, y); + const __m128 pol5_y_3 = _mm_add_ps(pol5_y_2, *((__m128 *)C3)); + const __m128 pol5_y_4 = _mm_mul_ps(pol5_y_3, y); + const __m128 pol5_y_5 = _mm_add_ps(pol5_y_4, *((__m128 *)C2)); + const __m128 pol5_y_6 = _mm_mul_ps(pol5_y_5, y); + const __m128 pol5_y_7 = _mm_add_ps(pol5_y_6, *((__m128 *)C1)); + const __m128 pol5_y_8 = _mm_mul_ps(pol5_y_7, y); + const __m128 pol5_y = _mm_add_ps(pol5_y_8, *((__m128 *)C0)); + const __m128 y_minus_one = _mm_sub_ps( + y, *((__m128 *)zero_biased_exponent_is_one)); + const __m128 log2_y = _mm_mul_ps(y_minus_one , pol5_y); + + // Combine parts. + log2_a = _mm_add_ps(n, log2_y); + } + + // b * log2(a) + b_log2_a = _mm_mul_ps(b, log2_a); + + // Calculate exp2(x), x = b * log2(a). + { + // To calculate 2^x, we decompose x like this: + // x = n + y + // n is an integer, the value of x - 0.5 rounded down, therefore + // y is in the [0.5, 1.5) range + // + // 2^x = 2^n * 2^y + // 2^n can be evaluated by playing with float representation. + // 2^y in a small range can be approximated, this code uses an order two + // polynomial approximation. The coefficients have been estimated + // with the Remez algorithm and the resulting polynomial has a + // maximum relative error of 0.17%. + + // To avoid over/underflow, we reduce the range of input to ]-127, 129]. + static const ALIGN16_BEG float max_input[4] ALIGN16_END = + {129.f, 129.f, 129.f, 129.f}; + static const ALIGN16_BEG float min_input[4] ALIGN16_END = + {-126.99999f, -126.99999f, -126.99999f, -126.99999f}; + const __m128 x_min = _mm_min_ps(b_log2_a, *((__m128 *)max_input)); + const __m128 x_max = _mm_max_ps(x_min, *((__m128 *)min_input)); + // Compute n. + static const ALIGN16_BEG float half[4] ALIGN16_END = + {0.5f, 0.5f, 0.5f, 0.5f}; + const __m128 x_minus_half = _mm_sub_ps(x_max, *((__m128 *)half)); + const __m128i x_minus_half_floor = _mm_cvtps_epi32(x_minus_half); + // Compute 2^n. + static const ALIGN16_BEG int float_exponent_bias[4] ALIGN16_END = + {127, 127, 127, 127}; + static const int float_exponent_shift = 23; + const __m128i two_n_exponent = _mm_add_epi32( + x_minus_half_floor, *((__m128i *)float_exponent_bias)); + const __m128 two_n = (__m128)_mm_slli_epi32( + two_n_exponent, float_exponent_shift); + // Compute y. + const __m128 y = _mm_sub_ps(x_max, _mm_cvtepi32_ps(x_minus_half_floor)); + // Approximate 2^y ~= C2 * y^2 + C1 * y + C0. + static const ALIGN16_BEG float C2[4] ALIGN16_END = + {3.3718944e-1f, 3.3718944e-1f, 3.3718944e-1f, 3.3718944e-1f}; + static const ALIGN16_BEG float C1[4] ALIGN16_END = + {6.5763628e-1f, 6.5763628e-1f, 6.5763628e-1f, 6.5763628e-1f}; + static const ALIGN16_BEG float C0[4] ALIGN16_END = + {1.0017247f, 1.0017247f, 1.0017247f, 1.0017247f}; + const __m128 exp2_y_0 = _mm_mul_ps(y, *((__m128 *)C2)); + const __m128 exp2_y_1 = _mm_add_ps(exp2_y_0, *((__m128 *)C1)); + const __m128 exp2_y_2 = _mm_mul_ps(exp2_y_1, y); + const __m128 exp2_y = _mm_add_ps(exp2_y_2, *((__m128 *)C0)); + + // Combine parts. + a_exp_b = _mm_mul_ps(exp2_y, two_n); + } + return a_exp_b; +} + +extern const float WebRtcAec_weightCurve[65]; +extern const float WebRtcAec_overDriveCurve[65]; + +static void OverdriveAndSuppressSSE2(aec_t *aec, float hNl[PART_LEN1], + const float hNlFb, + float efw[2][PART_LEN1]) { + int i; + const __m128 vec_hNlFb = _mm_set1_ps(hNlFb); + const __m128 vec_one = _mm_set1_ps(1.0f); + const __m128 vec_minus_one = _mm_set1_ps(-1.0f); + const __m128 vec_overDriveSm = _mm_set1_ps(aec->overDriveSm); + // vectorized code (four at once) + for (i = 0; i + 3 < PART_LEN1; i+=4) { + // Weight subbands + __m128 vec_hNl = _mm_loadu_ps(&hNl[i]); + const __m128 vec_weightCurve = _mm_loadu_ps(&WebRtcAec_weightCurve[i]); + const __m128 bigger = _mm_cmpgt_ps(vec_hNl, vec_hNlFb); + const __m128 vec_weightCurve_hNlFb = _mm_mul_ps( + vec_weightCurve, vec_hNlFb); + const __m128 vec_one_weightCurve = _mm_sub_ps(vec_one, vec_weightCurve); + const __m128 vec_one_weightCurve_hNl = _mm_mul_ps( + vec_one_weightCurve, vec_hNl); + const __m128 vec_if0 = _mm_andnot_ps(bigger, vec_hNl); + const __m128 vec_if1 = _mm_and_ps( + bigger, _mm_add_ps(vec_weightCurve_hNlFb, vec_one_weightCurve_hNl)); + vec_hNl = _mm_or_ps(vec_if0, vec_if1); + + { + const __m128 vec_overDriveCurve = _mm_loadu_ps( + &WebRtcAec_overDriveCurve[i]); + const __m128 vec_overDriveSm_overDriveCurve = _mm_mul_ps( + vec_overDriveSm, vec_overDriveCurve); + vec_hNl = mm_pow_ps(vec_hNl, vec_overDriveSm_overDriveCurve); + _mm_storeu_ps(&hNl[i], vec_hNl); + } + + // Suppress error signal + { + __m128 vec_efw_re = _mm_loadu_ps(&efw[0][i]); + __m128 vec_efw_im = _mm_loadu_ps(&efw[1][i]); + vec_efw_re = _mm_mul_ps(vec_efw_re, vec_hNl); + vec_efw_im = _mm_mul_ps(vec_efw_im, vec_hNl); + + // Ooura fft returns incorrect sign on imaginary component. It matters + // here because we are making an additive change with comfort noise. + vec_efw_im = _mm_mul_ps(vec_efw_im, vec_minus_one); + _mm_storeu_ps(&efw[0][i], vec_efw_re); + _mm_storeu_ps(&efw[1][i], vec_efw_im); + } + } + // scalar code for the remaining items. + for (; i < PART_LEN1; i++) { + // Weight subbands + if (hNl[i] > hNlFb) { + hNl[i] = WebRtcAec_weightCurve[i] * hNlFb + + (1 - WebRtcAec_weightCurve[i]) * hNl[i]; + } + hNl[i] = powf(hNl[i], aec->overDriveSm * WebRtcAec_overDriveCurve[i]); + + // Suppress error signal + efw[0][i] *= hNl[i]; + efw[1][i] *= hNl[i]; + + // Ooura fft returns incorrect sign on imaginary component. It matters + // here because we are making an additive change with comfort noise. + efw[1][i] *= -1; + } +} + +void WebRtcAec_InitAec_SSE2(void) { + WebRtcAec_FilterFar = FilterFarSSE2; + WebRtcAec_ScaleErrorSignal = ScaleErrorSignalSSE2; + WebRtcAec_FilterAdaptation = FilterAdaptationSSE2; + WebRtcAec_OverdriveAndSuppress = OverdriveAndSuppressSSE2; +} + +#endif // WEBRTC_USE_SSE2 diff --git a/src/modules/audio_processing/aec/main/source/aec_rdft.c b/src/modules/audio_processing/aec/main/source/aec_rdft.c new file mode 100644 index 0000000..9222334 --- /dev/null +++ b/src/modules/audio_processing/aec/main/source/aec_rdft.c @@ -0,0 +1,587 @@ +/* + * http://www.kurims.kyoto-u.ac.jp/~ooura/fft.html + * Copyright Takuya OOURA, 1996-2001 + * + * You may use, copy, modify and distribute this code for any purpose (include + * commercial use) and without fee. Please refer to this package when you modify + * this code. + * + * Changes by the WebRTC authors: + * - Trivial type modifications. + * - Minimal code subset to do rdft of length 128. + * - Optimizations because of known length. + * + * All changes are covered by the WebRTC license and IP grant: + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +#include "aec_rdft.h" + +#include + +#include "system_wrappers/interface/cpu_features_wrapper.h" +#include "typedefs.h" + +// constants shared by all paths (C, SSE2). +float rdft_w[64]; +// constants used by the C path. +float rdft_wk3ri_first[32]; +float rdft_wk3ri_second[32]; +// constants used by SSE2 but initialized in C path. +ALIGN16_BEG float ALIGN16_END rdft_wk1r[32]; +ALIGN16_BEG float ALIGN16_END rdft_wk2r[32]; +ALIGN16_BEG float ALIGN16_END rdft_wk3r[32]; +ALIGN16_BEG float ALIGN16_END rdft_wk1i[32]; +ALIGN16_BEG float ALIGN16_END rdft_wk2i[32]; +ALIGN16_BEG float ALIGN16_END rdft_wk3i[32]; +ALIGN16_BEG float ALIGN16_END cftmdl_wk1r[4]; + +static int ip[16]; + +static void bitrv2_32or128(int n, int *ip, float *a) { + // n is 32 or 128 + int j, j1, k, k1, m, m2; + float xr, xi, yr, yi; + + ip[0] = 0; + { + int l = n; + m = 1; + while ((m << 3) < l) { + l >>= 1; + for (j = 0; j < m; j++) { + ip[m + j] = ip[j] + l; + } + m <<= 1; + } + } + m2 = 2 * m; + for (k = 0; k < m; k++) { + for (j = 0; j < k; j++) { + j1 = 2 * j + ip[k]; + k1 = 2 * k + ip[j]; + xr = a[j1]; + xi = a[j1 + 1]; + yr = a[k1]; + yi = a[k1 + 1]; + a[j1] = yr; + a[j1 + 1] = yi; + a[k1] = xr; + a[k1 + 1] = xi; + j1 += m2; + k1 += 2 * m2; + xr = a[j1]; + xi = a[j1 + 1]; + yr = a[k1]; + yi = a[k1 + 1]; + a[j1] = yr; + a[j1 + 1] = yi; + a[k1] = xr; + a[k1 + 1] = xi; + j1 += m2; + k1 -= m2; + xr = a[j1]; + xi = a[j1 + 1]; + yr = a[k1]; + yi = a[k1 + 1]; + a[j1] = yr; + a[j1 + 1] = yi; + a[k1] = xr; + a[k1 + 1] = xi; + j1 += m2; + k1 += 2 * m2; + xr = a[j1]; + xi = a[j1 + 1]; + yr = a[k1]; + yi = a[k1 + 1]; + a[j1] = yr; + a[j1 + 1] = yi; + a[k1] = xr; + a[k1 + 1] = xi; + } + j1 = 2 * k + m2 + ip[k]; + k1 = j1 + m2; + xr = a[j1]; + xi = a[j1 + 1]; + yr = a[k1]; + yi = a[k1 + 1]; + a[j1] = yr; + a[j1 + 1] = yi; + a[k1] = xr; + a[k1 + 1] = xi; + } +} + +static void makewt_32(void) { + const int nw = 32; + int j, nwh; + float delta, x, y; + + ip[0] = nw; + ip[1] = 1; + nwh = nw >> 1; + delta = atanf(1.0f) / nwh; + rdft_w[0] = 1; + rdft_w[1] = 0; + rdft_w[nwh] = cosf(delta * nwh); + rdft_w[nwh + 1] = rdft_w[nwh]; + for (j = 2; j < nwh; j += 2) { + x = cosf(delta * j); + y = sinf(delta * j); + rdft_w[j] = x; + rdft_w[j + 1] = y; + rdft_w[nw - j] = y; + rdft_w[nw - j + 1] = x; + } + bitrv2_32or128(nw, ip + 2, rdft_w); + + // pre-calculate constants used by cft1st_128 and cftmdl_128... + cftmdl_wk1r[0] = rdft_w[2]; + cftmdl_wk1r[1] = rdft_w[2]; + cftmdl_wk1r[2] = rdft_w[2]; + cftmdl_wk1r[3] = -rdft_w[2]; + { + int k1; + + for (k1 = 0, j = 0; j < 128; j += 16, k1 += 2) { + const int k2 = 2 * k1; + const float wk2r = rdft_w[k1 + 0]; + const float wk2i = rdft_w[k1 + 1]; + float wk1r, wk1i; + // ... scalar version. + wk1r = rdft_w[k2 + 0]; + wk1i = rdft_w[k2 + 1]; + rdft_wk3ri_first[k1 + 0] = wk1r - 2 * wk2i * wk1i; + rdft_wk3ri_first[k1 + 1] = 2 * wk2i * wk1r - wk1i; + wk1r = rdft_w[k2 + 2]; + wk1i = rdft_w[k2 + 3]; + rdft_wk3ri_second[k1 + 0] = wk1r - 2 * wk2r * wk1i; + rdft_wk3ri_second[k1 + 1] = 2 * wk2r * wk1r - wk1i; + // ... vector version. + rdft_wk1r[k2 + 0] = rdft_w[k2 + 0]; + rdft_wk1r[k2 + 1] = rdft_w[k2 + 0]; + rdft_wk1r[k2 + 2] = rdft_w[k2 + 2]; + rdft_wk1r[k2 + 3] = rdft_w[k2 + 2]; + rdft_wk2r[k2 + 0] = rdft_w[k1 + 0]; + rdft_wk2r[k2 + 1] = rdft_w[k1 + 0]; + rdft_wk2r[k2 + 2] = -rdft_w[k1 + 1]; + rdft_wk2r[k2 + 3] = -rdft_w[k1 + 1]; + rdft_wk3r[k2 + 0] = rdft_wk3ri_first[k1 + 0]; + rdft_wk3r[k2 + 1] = rdft_wk3ri_first[k1 + 0]; + rdft_wk3r[k2 + 2] = rdft_wk3ri_second[k1 + 0]; + rdft_wk3r[k2 + 3] = rdft_wk3ri_second[k1 + 0]; + rdft_wk1i[k2 + 0] = -rdft_w[k2 + 1]; + rdft_wk1i[k2 + 1] = rdft_w[k2 + 1]; + rdft_wk1i[k2 + 2] = -rdft_w[k2 + 3]; + rdft_wk1i[k2 + 3] = rdft_w[k2 + 3]; + rdft_wk2i[k2 + 0] = -rdft_w[k1 + 1]; + rdft_wk2i[k2 + 1] = rdft_w[k1 + 1]; + rdft_wk2i[k2 + 2] = -rdft_w[k1 + 0]; + rdft_wk2i[k2 + 3] = rdft_w[k1 + 0]; + rdft_wk3i[k2 + 0] = -rdft_wk3ri_first[k1 + 1]; + rdft_wk3i[k2 + 1] = rdft_wk3ri_first[k1 + 1]; + rdft_wk3i[k2 + 2] = -rdft_wk3ri_second[k1 + 1]; + rdft_wk3i[k2 + 3] = rdft_wk3ri_second[k1 + 1]; + } + } +} + +static void makect_32(void) { + float *c = rdft_w + 32; + const int nc = 32; + int j, nch; + float delta; + + ip[1] = nc; + nch = nc >> 1; + delta = atanf(1.0f) / nch; + c[0] = cosf(delta * nch); + c[nch] = 0.5f * c[0]; + for (j = 1; j < nch; j++) { + c[j] = 0.5f * cosf(delta * j); + c[nc - j] = 0.5f * sinf(delta * j); + } +} + +static void cft1st_128_C(float *a) { + const int n = 128; + int j, k1, k2; + float wk1r, wk1i, wk2r, wk2i, wk3r, wk3i; + float x0r, x0i, x1r, x1i, x2r, x2i, x3r, x3i; + + x0r = a[0] + a[2]; + x0i = a[1] + a[3]; + x1r = a[0] - a[2]; + x1i = a[1] - a[3]; + x2r = a[4] + a[6]; + x2i = a[5] + a[7]; + x3r = a[4] - a[6]; + x3i = a[5] - a[7]; + a[0] = x0r + x2r; + a[1] = x0i + x2i; + a[4] = x0r - x2r; + a[5] = x0i - x2i; + a[2] = x1r - x3i; + a[3] = x1i + x3r; + a[6] = x1r + x3i; + a[7] = x1i - x3r; + wk1r = rdft_w[2]; + x0r = a[8] + a[10]; + x0i = a[9] + a[11]; + x1r = a[8] - a[10]; + x1i = a[9] - a[11]; + x2r = a[12] + a[14]; + x2i = a[13] + a[15]; + x3r = a[12] - a[14]; + x3i = a[13] - a[15]; + a[8] = x0r + x2r; + a[9] = x0i + x2i; + a[12] = x2i - x0i; + a[13] = x0r - x2r; + x0r = x1r - x3i; + x0i = x1i + x3r; + a[10] = wk1r * (x0r - x0i); + a[11] = wk1r * (x0r + x0i); + x0r = x3i + x1r; + x0i = x3r - x1i; + a[14] = wk1r * (x0i - x0r); + a[15] = wk1r * (x0i + x0r); + k1 = 0; + for (j = 16; j < n; j += 16) { + k1 += 2; + k2 = 2 * k1; + wk2r = rdft_w[k1 + 0]; + wk2i = rdft_w[k1 + 1]; + wk1r = rdft_w[k2 + 0]; + wk1i = rdft_w[k2 + 1]; + wk3r = rdft_wk3ri_first[k1 + 0]; + wk3i = rdft_wk3ri_first[k1 + 1]; + x0r = a[j + 0] + a[j + 2]; + x0i = a[j + 1] + a[j + 3]; + x1r = a[j + 0] - a[j + 2]; + x1i = a[j + 1] - a[j + 3]; + x2r = a[j + 4] + a[j + 6]; + x2i = a[j + 5] + a[j + 7]; + x3r = a[j + 4] - a[j + 6]; + x3i = a[j + 5] - a[j + 7]; + a[j + 0] = x0r + x2r; + a[j + 1] = x0i + x2i; + x0r -= x2r; + x0i -= x2i; + a[j + 4] = wk2r * x0r - wk2i * x0i; + a[j + 5] = wk2r * x0i + wk2i * x0r; + x0r = x1r - x3i; + x0i = x1i + x3r; + a[j + 2] = wk1r * x0r - wk1i * x0i; + a[j + 3] = wk1r * x0i + wk1i * x0r; + x0r = x1r + x3i; + x0i = x1i - x3r; + a[j + 6] = wk3r * x0r - wk3i * x0i; + a[j + 7] = wk3r * x0i + wk3i * x0r; + wk1r = rdft_w[k2 + 2]; + wk1i = rdft_w[k2 + 3]; + wk3r = rdft_wk3ri_second[k1 + 0]; + wk3i = rdft_wk3ri_second[k1 + 1]; + x0r = a[j + 8] + a[j + 10]; + x0i = a[j + 9] + a[j + 11]; + x1r = a[j + 8] - a[j + 10]; + x1i = a[j + 9] - a[j + 11]; + x2r = a[j + 12] + a[j + 14]; + x2i = a[j + 13] + a[j + 15]; + x3r = a[j + 12] - a[j + 14]; + x3i = a[j + 13] - a[j + 15]; + a[j + 8] = x0r + x2r; + a[j + 9] = x0i + x2i; + x0r -= x2r; + x0i -= x2i; + a[j + 12] = -wk2i * x0r - wk2r * x0i; + a[j + 13] = -wk2i * x0i + wk2r * x0r; + x0r = x1r - x3i; + x0i = x1i + x3r; + a[j + 10] = wk1r * x0r - wk1i * x0i; + a[j + 11] = wk1r * x0i + wk1i * x0r; + x0r = x1r + x3i; + x0i = x1i - x3r; + a[j + 14] = wk3r * x0r - wk3i * x0i; + a[j + 15] = wk3r * x0i + wk3i * x0r; + } +} + +static void cftmdl_128_C(float *a) { + const int l = 8; + const int n = 128; + const int m = 32; + int j0, j1, j2, j3, k, k1, k2, m2; + float wk1r, wk1i, wk2r, wk2i, wk3r, wk3i; + float x0r, x0i, x1r, x1i, x2r, x2i, x3r, x3i; + + for (j0 = 0; j0 < l; j0 += 2) { + j1 = j0 + 8; + j2 = j0 + 16; + j3 = j0 + 24; + x0r = a[j0 + 0] + a[j1 + 0]; + x0i = a[j0 + 1] + a[j1 + 1]; + x1r = a[j0 + 0] - a[j1 + 0]; + x1i = a[j0 + 1] - a[j1 + 1]; + x2r = a[j2 + 0] + a[j3 + 0]; + x2i = a[j2 + 1] + a[j3 + 1]; + x3r = a[j2 + 0] - a[j3 + 0]; + x3i = a[j2 + 1] - a[j3 + 1]; + a[j0 + 0] = x0r + x2r; + a[j0 + 1] = x0i + x2i; + a[j2 + 0] = x0r - x2r; + a[j2 + 1] = x0i - x2i; + a[j1 + 0] = x1r - x3i; + a[j1 + 1] = x1i + x3r; + a[j3 + 0] = x1r + x3i; + a[j3 + 1] = x1i - x3r; + } + wk1r = rdft_w[2]; + for (j0 = m; j0 < l + m; j0 += 2) { + j1 = j0 + 8; + j2 = j0 + 16; + j3 = j0 + 24; + x0r = a[j0 + 0] + a[j1 + 0]; + x0i = a[j0 + 1] + a[j1 + 1]; + x1r = a[j0 + 0] - a[j1 + 0]; + x1i = a[j0 + 1] - a[j1 + 1]; + x2r = a[j2 + 0] + a[j3 + 0]; + x2i = a[j2 + 1] + a[j3 + 1]; + x3r = a[j2 + 0] - a[j3 + 0]; + x3i = a[j2 + 1] - a[j3 + 1]; + a[j0 + 0] = x0r + x2r; + a[j0 + 1] = x0i + x2i; + a[j2 + 0] = x2i - x0i; + a[j2 + 1] = x0r - x2r; + x0r = x1r - x3i; + x0i = x1i + x3r; + a[j1 + 0] = wk1r * (x0r - x0i); + a[j1 + 1] = wk1r * (x0r + x0i); + x0r = x3i + x1r; + x0i = x3r - x1i; + a[j3 + 0] = wk1r * (x0i - x0r); + a[j3 + 1] = wk1r * (x0i + x0r); + } + k1 = 0; + m2 = 2 * m; + for (k = m2; k < n; k += m2) { + k1 += 2; + k2 = 2 * k1; + wk2r = rdft_w[k1 + 0]; + wk2i = rdft_w[k1 + 1]; + wk1r = rdft_w[k2 + 0]; + wk1i = rdft_w[k2 + 1]; + wk3r = rdft_wk3ri_first[k1 + 0]; + wk3i = rdft_wk3ri_first[k1 + 1]; + for (j0 = k; j0 < l + k; j0 += 2) { + j1 = j0 + 8; + j2 = j0 + 16; + j3 = j0 + 24; + x0r = a[j0 + 0] + a[j1 + 0]; + x0i = a[j0 + 1] + a[j1 + 1]; + x1r = a[j0 + 0] - a[j1 + 0]; + x1i = a[j0 + 1] - a[j1 + 1]; + x2r = a[j2 + 0] + a[j3 + 0]; + x2i = a[j2 + 1] + a[j3 + 1]; + x3r = a[j2 + 0] - a[j3 + 0]; + x3i = a[j2 + 1] - a[j3 + 1]; + a[j0 + 0] = x0r + x2r; + a[j0 + 1] = x0i + x2i; + x0r -= x2r; + x0i -= x2i; + a[j2 + 0] = wk2r * x0r - wk2i * x0i; + a[j2 + 1] = wk2r * x0i + wk2i * x0r; + x0r = x1r - x3i; + x0i = x1i + x3r; + a[j1 + 0] = wk1r * x0r - wk1i * x0i; + a[j1 + 1] = wk1r * x0i + wk1i * x0r; + x0r = x1r + x3i; + x0i = x1i - x3r; + a[j3 + 0] = wk3r * x0r - wk3i * x0i; + a[j3 + 1] = wk3r * x0i + wk3i * x0r; + } + wk1r = rdft_w[k2 + 2]; + wk1i = rdft_w[k2 + 3]; + wk3r = rdft_wk3ri_second[k1 + 0]; + wk3i = rdft_wk3ri_second[k1 + 1]; + for (j0 = k + m; j0 < l + (k + m); j0 += 2) { + j1 = j0 + 8; + j2 = j0 + 16; + j3 = j0 + 24; + x0r = a[j0 + 0] + a[j1 + 0]; + x0i = a[j0 + 1] + a[j1 + 1]; + x1r = a[j0 + 0] - a[j1 + 0]; + x1i = a[j0 + 1] - a[j1 + 1]; + x2r = a[j2 + 0] + a[j3 + 0]; + x2i = a[j2 + 1] + a[j3 + 1]; + x3r = a[j2 + 0] - a[j3 + 0]; + x3i = a[j2 + 1] - a[j3 + 1]; + a[j0 + 0] = x0r + x2r; + a[j0 + 1] = x0i + x2i; + x0r -= x2r; + x0i -= x2i; + a[j2 + 0] = -wk2i * x0r - wk2r * x0i; + a[j2 + 1] = -wk2i * x0i + wk2r * x0r; + x0r = x1r - x3i; + x0i = x1i + x3r; + a[j1 + 0] = wk1r * x0r - wk1i * x0i; + a[j1 + 1] = wk1r * x0i + wk1i * x0r; + x0r = x1r + x3i; + x0i = x1i - x3r; + a[j3 + 0] = wk3r * x0r - wk3i * x0i; + a[j3 + 1] = wk3r * x0i + wk3i * x0r; + } + } +} + +static void cftfsub_128(float *a) { + int j, j1, j2, j3, l; + float x0r, x0i, x1r, x1i, x2r, x2i, x3r, x3i; + + cft1st_128(a); + cftmdl_128(a); + l = 32; + for (j = 0; j < l; j += 2) { + j1 = j + l; + j2 = j1 + l; + j3 = j2 + l; + x0r = a[j] + a[j1]; + x0i = a[j + 1] + a[j1 + 1]; + x1r = a[j] - a[j1]; + x1i = a[j + 1] - a[j1 + 1]; + x2r = a[j2] + a[j3]; + x2i = a[j2 + 1] + a[j3 + 1]; + x3r = a[j2] - a[j3]; + x3i = a[j2 + 1] - a[j3 + 1]; + a[j] = x0r + x2r; + a[j + 1] = x0i + x2i; + a[j2] = x0r - x2r; + a[j2 + 1] = x0i - x2i; + a[j1] = x1r - x3i; + a[j1 + 1] = x1i + x3r; + a[j3] = x1r + x3i; + a[j3 + 1] = x1i - x3r; + } +} + +static void cftbsub_128(float *a) { + int j, j1, j2, j3, l; + float x0r, x0i, x1r, x1i, x2r, x2i, x3r, x3i; + + cft1st_128(a); + cftmdl_128(a); + l = 32; + + for (j = 0; j < l; j += 2) { + j1 = j + l; + j2 = j1 + l; + j3 = j2 + l; + x0r = a[j] + a[j1]; + x0i = -a[j + 1] - a[j1 + 1]; + x1r = a[j] - a[j1]; + x1i = -a[j + 1] + a[j1 + 1]; + x2r = a[j2] + a[j3]; + x2i = a[j2 + 1] + a[j3 + 1]; + x3r = a[j2] - a[j3]; + x3i = a[j2 + 1] - a[j3 + 1]; + a[j] = x0r + x2r; + a[j + 1] = x0i - x2i; + a[j2] = x0r - x2r; + a[j2 + 1] = x0i + x2i; + a[j1] = x1r - x3i; + a[j1 + 1] = x1i - x3r; + a[j3] = x1r + x3i; + a[j3 + 1] = x1i + x3r; + } +} + +static void rftfsub_128_C(float *a) { + const float *c = rdft_w + 32; + int j1, j2, k1, k2; + float wkr, wki, xr, xi, yr, yi; + + for (j1 = 1, j2 = 2; j2 < 64; j1 += 1, j2 += 2) { + k2 = 128 - j2; + k1 = 32 - j1; + wkr = 0.5f - c[k1]; + wki = c[j1]; + xr = a[j2 + 0] - a[k2 + 0]; + xi = a[j2 + 1] + a[k2 + 1]; + yr = wkr * xr - wki * xi; + yi = wkr * xi + wki * xr; + a[j2 + 0] -= yr; + a[j2 + 1] -= yi; + a[k2 + 0] += yr; + a[k2 + 1] -= yi; + } +} + +static void rftbsub_128_C(float *a) { + const float *c = rdft_w + 32; + int j1, j2, k1, k2; + float wkr, wki, xr, xi, yr, yi; + + a[1] = -a[1]; + for (j1 = 1, j2 = 2; j2 < 64; j1 += 1, j2 += 2) { + k2 = 128 - j2; + k1 = 32 - j1; + wkr = 0.5f - c[k1]; + wki = c[j1]; + xr = a[j2 + 0] - a[k2 + 0]; + xi = a[j2 + 1] + a[k2 + 1]; + yr = wkr * xr + wki * xi; + yi = wkr * xi - wki * xr; + a[j2 + 0] = a[j2 + 0] - yr; + a[j2 + 1] = yi - a[j2 + 1]; + a[k2 + 0] = yr + a[k2 + 0]; + a[k2 + 1] = yi - a[k2 + 1]; + } + a[65] = -a[65]; +} + +void aec_rdft_forward_128(float *a) { + const int n = 128; + float xi; + + bitrv2_32or128(n, ip + 2, a); + cftfsub_128(a); + rftfsub_128(a); + xi = a[0] - a[1]; + a[0] += a[1]; + a[1] = xi; +} + +void aec_rdft_inverse_128(float *a) { + const int n = 128; + + a[1] = 0.5f * (a[0] - a[1]); + a[0] -= a[1]; + rftbsub_128(a); + bitrv2_32or128(n, ip + 2, a); + cftbsub_128(a); +} + +// code path selection +rft_sub_128_t cft1st_128; +rft_sub_128_t cftmdl_128; +rft_sub_128_t rftfsub_128; +rft_sub_128_t rftbsub_128; + +void aec_rdft_init(void) { + cft1st_128 = cft1st_128_C; + cftmdl_128 = cftmdl_128_C; + rftfsub_128 = rftfsub_128_C; + rftbsub_128 = rftbsub_128_C; + if (WebRtc_GetCPUInfo(kSSE2)) { +#if defined(WEBRTC_USE_SSE2) + aec_rdft_init_sse2(); +#endif + } + // init library constants. + makewt_32(); + makect_32(); +} diff --git a/src/modules/audio_processing/aec/main/source/aec_rdft.h b/src/modules/audio_processing/aec/main/source/aec_rdft.h new file mode 100644 index 0000000..5f4085b --- /dev/null +++ b/src/modules/audio_processing/aec/main/source/aec_rdft.h @@ -0,0 +1,49 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +#ifndef WEBRTC_MODULES_AUDIO_PROCESSING_AEC_MAIN_SOURCE_AEC_RDFT_H_ +#define WEBRTC_MODULES_AUDIO_PROCESSING_AEC_MAIN_SOURCE_AEC_RDFT_H_ + +#ifdef _MSC_VER /* visual c++ */ +# define ALIGN16_BEG __declspec(align(16)) +# define ALIGN16_END +#else /* gcc or icc */ +# define ALIGN16_BEG +# define ALIGN16_END __attribute__((aligned(16))) +#endif + +// constants shared by all paths (C, SSE2). +extern float rdft_w[64]; +// constants used by the C path. +extern float rdft_wk3ri_first[32]; +extern float rdft_wk3ri_second[32]; +// constants used by SSE2 but initialized in C path. +extern float rdft_wk1r[32]; +extern float rdft_wk2r[32]; +extern float rdft_wk3r[32]; +extern float rdft_wk1i[32]; +extern float rdft_wk2i[32]; +extern float rdft_wk3i[32]; +extern float cftmdl_wk1r[4]; + +// code path selection function pointers +typedef void (*rft_sub_128_t)(float *a); +extern rft_sub_128_t rftfsub_128; +extern rft_sub_128_t rftbsub_128; +extern rft_sub_128_t cft1st_128; +extern rft_sub_128_t cftmdl_128; + +// entry points +void aec_rdft_init(void); +void aec_rdft_init_sse2(void); +void aec_rdft_forward_128(float *a); +void aec_rdft_inverse_128(float *a); + +#endif // WEBRTC_MODULES_AUDIO_PROCESSING_AEC_MAIN_SOURCE_AEC_RDFT_H_ diff --git a/src/modules/audio_processing/aec/main/source/aec_rdft_sse2.c b/src/modules/audio_processing/aec/main/source/aec_rdft_sse2.c new file mode 100644 index 0000000..89aea87 --- /dev/null +++ b/src/modules/audio_processing/aec/main/source/aec_rdft_sse2.c @@ -0,0 +1,397 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +#include "typedefs.h" + +#if defined(WEBRTC_USE_SSE2) +#include + +#include "aec_rdft.h" + +static const ALIGN16_BEG float ALIGN16_END k_swap_sign[4] = + {-1.f, 1.f, -1.f, 1.f}; + +static void cft1st_128_SSE2(float *a) { + const __m128 mm_swap_sign = _mm_load_ps(k_swap_sign); + int j, k2; + + for (k2 = 0, j = 0; j < 128; j += 16, k2 += 4) { + __m128 a00v = _mm_loadu_ps(&a[j + 0]); + __m128 a04v = _mm_loadu_ps(&a[j + 4]); + __m128 a08v = _mm_loadu_ps(&a[j + 8]); + __m128 a12v = _mm_loadu_ps(&a[j + 12]); + __m128 a01v = _mm_shuffle_ps(a00v, a08v, _MM_SHUFFLE(1, 0, 1 ,0)); + __m128 a23v = _mm_shuffle_ps(a00v, a08v, _MM_SHUFFLE(3, 2, 3 ,2)); + __m128 a45v = _mm_shuffle_ps(a04v, a12v, _MM_SHUFFLE(1, 0, 1 ,0)); + __m128 a67v = _mm_shuffle_ps(a04v, a12v, _MM_SHUFFLE(3, 2, 3 ,2)); + + const __m128 wk1rv = _mm_load_ps(&rdft_wk1r[k2]); + const __m128 wk1iv = _mm_load_ps(&rdft_wk1i[k2]); + const __m128 wk2rv = _mm_load_ps(&rdft_wk2r[k2]); + const __m128 wk2iv = _mm_load_ps(&rdft_wk2i[k2]); + const __m128 wk3rv = _mm_load_ps(&rdft_wk3r[k2]); + const __m128 wk3iv = _mm_load_ps(&rdft_wk3i[k2]); + __m128 x0v = _mm_add_ps(a01v, a23v); + const __m128 x1v = _mm_sub_ps(a01v, a23v); + const __m128 x2v = _mm_add_ps(a45v, a67v); + const __m128 x3v = _mm_sub_ps(a45v, a67v); + a01v = _mm_add_ps(x0v, x2v); + x0v = _mm_sub_ps(x0v, x2v); + __m128 x0w = _mm_shuffle_ps(x0v, x0v, _MM_SHUFFLE(2, 3, 0 ,1)); + + const __m128 a45_0v = _mm_mul_ps(wk2rv, x0v); + const __m128 a45_1v = _mm_mul_ps(wk2iv, x0w); + a45v = _mm_add_ps(a45_0v, a45_1v); + + const __m128 x3w = _mm_shuffle_ps(x3v, x3v, _MM_SHUFFLE(2, 3, 0 ,1)); + const __m128 x3s = _mm_mul_ps(mm_swap_sign, x3w); + x0v = _mm_add_ps(x1v, x3s); + x0w = _mm_shuffle_ps(x0v, x0v, _MM_SHUFFLE(2, 3, 0 ,1)); + const __m128 a23_0v = _mm_mul_ps(wk1rv, x0v); + const __m128 a23_1v = _mm_mul_ps(wk1iv, x0w); + a23v = _mm_add_ps(a23_0v, a23_1v); + + x0v = _mm_sub_ps(x1v, x3s); + x0w = _mm_shuffle_ps(x0v, x0v, _MM_SHUFFLE(2, 3, 0 ,1)); + const __m128 a67_0v = _mm_mul_ps(wk3rv, x0v); + const __m128 a67_1v = _mm_mul_ps(wk3iv, x0w); + a67v = _mm_add_ps(a67_0v, a67_1v); + + a00v = _mm_shuffle_ps(a01v, a23v, _MM_SHUFFLE(1, 0, 1 ,0)); + a04v = _mm_shuffle_ps(a45v, a67v, _MM_SHUFFLE(1, 0, 1 ,0)); + a08v = _mm_shuffle_ps(a01v, a23v, _MM_SHUFFLE(3, 2, 3 ,2)); + a12v = _mm_shuffle_ps(a45v, a67v, _MM_SHUFFLE(3, 2, 3 ,2)); + _mm_storeu_ps(&a[j + 0], a00v); + _mm_storeu_ps(&a[j + 4], a04v); + _mm_storeu_ps(&a[j + 8], a08v); + _mm_storeu_ps(&a[j + 12], a12v); + } +} + +static void cftmdl_128_SSE2(float *a) { + const int l = 8; + const __m128 mm_swap_sign = _mm_load_ps(k_swap_sign); + int j0, k, k1, k2; + + __m128 wk1rv = _mm_load_ps(cftmdl_wk1r); + for (j0 = 0; j0 < l; j0 += 2) { + const __m128i a_00 = _mm_loadl_epi64((__m128i*)&a[j0 + 0]); + const __m128i a_08 = _mm_loadl_epi64((__m128i*)&a[j0 + 8]); + const __m128i a_32 = _mm_loadl_epi64((__m128i*)&a[j0 + 32]); + const __m128i a_40 = _mm_loadl_epi64((__m128i*)&a[j0 + 40]); + const __m128 a_00_32 = _mm_shuffle_ps((__m128)a_00, (__m128)a_32, + _MM_SHUFFLE(1, 0, 1 ,0)); + const __m128 a_08_40 = _mm_shuffle_ps((__m128)a_08, (__m128)a_40, + _MM_SHUFFLE(1, 0, 1 ,0)); + __m128 x0r0_0i0_0r1_x0i1 = _mm_add_ps(a_00_32, a_08_40); + const __m128 x1r0_1i0_1r1_x1i1 = _mm_sub_ps(a_00_32, a_08_40); + + const __m128i a_16 = _mm_loadl_epi64((__m128i*)&a[j0 + 16]); + const __m128i a_24 = _mm_loadl_epi64((__m128i*)&a[j0 + 24]); + const __m128i a_48 = _mm_loadl_epi64((__m128i*)&a[j0 + 48]); + const __m128i a_56 = _mm_loadl_epi64((__m128i*)&a[j0 + 56]); + const __m128 a_16_48 = _mm_shuffle_ps((__m128)a_16, (__m128)a_48, + _MM_SHUFFLE(1, 0, 1 ,0)); + const __m128 a_24_56 = _mm_shuffle_ps((__m128)a_24, (__m128)a_56, + _MM_SHUFFLE(1, 0, 1 ,0)); + const __m128 x2r0_2i0_2r1_x2i1 = _mm_add_ps(a_16_48, a_24_56); + const __m128 x3r0_3i0_3r1_x3i1 = _mm_sub_ps(a_16_48, a_24_56); + + const __m128 xx0 = _mm_add_ps(x0r0_0i0_0r1_x0i1, x2r0_2i0_2r1_x2i1); + _mm_storel_epi64((__m128i*)&a[j0 + 0], (__m128i)xx0); + _mm_storel_epi64((__m128i*)&a[j0 + 32], + _mm_shuffle_epi32((__m128i)xx0, _MM_SHUFFLE(3, 2, 3, 2))); + const __m128 xx1 = _mm_sub_ps(x0r0_0i0_0r1_x0i1, x2r0_2i0_2r1_x2i1); + _mm_storel_epi64((__m128i*)&a[j0 + 16], (__m128i)xx1); + _mm_storel_epi64((__m128i*)&a[j0 + 48], + _mm_shuffle_epi32((__m128i)xx1, _MM_SHUFFLE(2, 3, 2, 3))); + a[j0 + 48] = -a[j0 + 48]; + + const __m128 x3i0_3r0_3i1_x3r1 = (__m128) + _mm_shuffle_epi32((__m128i)x3r0_3i0_3r1_x3i1, _MM_SHUFFLE(2, 3, 0, 1)); + const __m128 x3_swapped = _mm_mul_ps(mm_swap_sign, x3i0_3r0_3i1_x3r1); + const __m128 x1_x3_add = _mm_add_ps(x1r0_1i0_1r1_x1i1, x3_swapped); + const __m128 x1_x3_sub = _mm_sub_ps(x1r0_1i0_1r1_x1i1, x3_swapped); + _mm_storel_epi64((__m128i*)&a[j0 + 8], (__m128i)x1_x3_add); + _mm_storel_epi64((__m128i*)&a[j0 + 24], (__m128i)x1_x3_sub); + + const __m128 yy0 = _mm_shuffle_ps(x1_x3_add, x1_x3_sub, + _MM_SHUFFLE(2, 2, 2 ,2)); + const __m128 yy1 = _mm_shuffle_ps(x1_x3_add, x1_x3_sub, + _MM_SHUFFLE(3, 3, 3 ,3)); + const __m128 yy2 = _mm_mul_ps(mm_swap_sign, yy1); + const __m128 yy3 = _mm_add_ps(yy0, yy2); + const __m128 yy4 = _mm_mul_ps(wk1rv, yy3); + _mm_storel_epi64((__m128i*)&a[j0 + 40], (__m128i)yy4); + _mm_storel_epi64((__m128i*)&a[j0 + 56], + _mm_shuffle_epi32((__m128i)yy4, _MM_SHUFFLE(2, 3, 2, 3))); + } + + k1 = 0; + k = 64; + k1 += 2; + k2 = 2 * k1; + const __m128 wk2rv = _mm_load_ps(&rdft_wk2r[k2+0]); + const __m128 wk2iv = _mm_load_ps(&rdft_wk2i[k2+0]); + wk1rv = _mm_load_ps(&rdft_wk1r[k2+0]); + const __m128 wk1iv = _mm_load_ps(&rdft_wk1i[k2+0]); + const __m128 wk3rv = _mm_load_ps(&rdft_wk3r[k2+0]); + const __m128 wk3iv = _mm_load_ps(&rdft_wk3i[k2+0]); + for (j0 = k; j0 < l + k; j0 += 2) { + const __m128i a_00 = _mm_loadl_epi64((__m128i*)&a[j0 + 0]); + const __m128i a_08 = _mm_loadl_epi64((__m128i*)&a[j0 + 8]); + const __m128i a_32 = _mm_loadl_epi64((__m128i*)&a[j0 + 32]); + const __m128i a_40 = _mm_loadl_epi64((__m128i*)&a[j0 + 40]); + const __m128 a_00_32 = _mm_shuffle_ps((__m128)a_00, (__m128)a_32, + _MM_SHUFFLE(1, 0, 1 ,0)); + const __m128 a_08_40 = _mm_shuffle_ps((__m128)a_08, (__m128)a_40, + _MM_SHUFFLE(1, 0, 1 ,0)); + __m128 x0r0_0i0_0r1_x0i1 = _mm_add_ps(a_00_32, a_08_40); + const __m128 x1r0_1i0_1r1_x1i1 = _mm_sub_ps(a_00_32, a_08_40); + + const __m128i a_16 = _mm_loadl_epi64((__m128i*)&a[j0 + 16]); + const __m128i a_24 = _mm_loadl_epi64((__m128i*)&a[j0 + 24]); + const __m128i a_48 = _mm_loadl_epi64((__m128i*)&a[j0 + 48]); + const __m128i a_56 = _mm_loadl_epi64((__m128i*)&a[j0 + 56]); + const __m128 a_16_48 = _mm_shuffle_ps((__m128)a_16, (__m128)a_48, + _MM_SHUFFLE(1, 0, 1 ,0)); + const __m128 a_24_56 = _mm_shuffle_ps((__m128)a_24, (__m128)a_56, + _MM_SHUFFLE(1, 0, 1 ,0)); + const __m128 x2r0_2i0_2r1_x2i1 = _mm_add_ps(a_16_48, a_24_56); + const __m128 x3r0_3i0_3r1_x3i1 = _mm_sub_ps(a_16_48, a_24_56); + + const __m128 xx = _mm_add_ps(x0r0_0i0_0r1_x0i1, x2r0_2i0_2r1_x2i1); + _mm_storel_epi64((__m128i*)&a[j0 + 0], (__m128i)xx); + _mm_storel_epi64((__m128i*)&a[j0 + 32], + _mm_shuffle_epi32((__m128i)xx, _MM_SHUFFLE(3, 2, 3, 2))); + + const __m128 xx1 = _mm_sub_ps(x0r0_0i0_0r1_x0i1, x2r0_2i0_2r1_x2i1); + const __m128 xx2 = _mm_mul_ps(xx1 , wk2rv); + const __m128 xx3 = _mm_mul_ps(wk2iv, + (__m128)_mm_shuffle_epi32((__m128i)xx1, _MM_SHUFFLE(2, 3, 0, 1))); + const __m128 xx4 = _mm_add_ps(xx2, xx3); + _mm_storel_epi64((__m128i*)&a[j0 + 16], (__m128i)xx4); + _mm_storel_epi64((__m128i*)&a[j0 + 48], + _mm_shuffle_epi32((__m128i)xx4, _MM_SHUFFLE(3, 2, 3, 2))); + + const __m128 x3i0_3r0_3i1_x3r1 = (__m128) + _mm_shuffle_epi32((__m128i)x3r0_3i0_3r1_x3i1, _MM_SHUFFLE(2, 3, 0, 1)); + const __m128 x3_swapped = _mm_mul_ps(mm_swap_sign, x3i0_3r0_3i1_x3r1); + const __m128 x1_x3_add = _mm_add_ps(x1r0_1i0_1r1_x1i1, x3_swapped); + const __m128 x1_x3_sub = _mm_sub_ps(x1r0_1i0_1r1_x1i1, x3_swapped); + + const __m128 xx10 = _mm_mul_ps(x1_x3_add, wk1rv); + const __m128 xx11 = _mm_mul_ps(wk1iv, + (__m128)_mm_shuffle_epi32((__m128i)x1_x3_add, _MM_SHUFFLE(2, 3, 0, 1))); + const __m128 xx12 = _mm_add_ps(xx10, xx11); + _mm_storel_epi64((__m128i*)&a[j0 + 8], (__m128i)xx12); + _mm_storel_epi64((__m128i*)&a[j0 + 40], + _mm_shuffle_epi32((__m128i)xx12, _MM_SHUFFLE(3, 2, 3, 2))); + + const __m128 xx20 = _mm_mul_ps(x1_x3_sub, wk3rv); + const __m128 xx21 = _mm_mul_ps(wk3iv, + (__m128)_mm_shuffle_epi32((__m128i)x1_x3_sub, _MM_SHUFFLE(2, 3, 0, 1))); + const __m128 xx22 = _mm_add_ps(xx20, xx21); + _mm_storel_epi64((__m128i*)&a[j0 + 24], (__m128i)xx22); + _mm_storel_epi64((__m128i*)&a[j0 + 56], + _mm_shuffle_epi32((__m128i)xx22, _MM_SHUFFLE(3, 2, 3, 2))); + } +} + +static void rftfsub_128_SSE2(float *a) { + const float *c = rdft_w + 32; + int j1, j2, k1, k2; + float wkr, wki, xr, xi, yr, yi; + + static const ALIGN16_BEG float ALIGN16_END k_half[4] = + {0.5f, 0.5f, 0.5f, 0.5f}; + const __m128 mm_half = _mm_load_ps(k_half); + + // Vectorized code (four at once). + // Note: commented number are indexes for the first iteration of the loop. + for (j1 = 1, j2 = 2; j2 + 7 < 64; j1 += 4, j2 += 8) { + // Load 'wk'. + const __m128 c_j1 = _mm_loadu_ps(&c[ j1]); // 1, 2, 3, 4, + const __m128 c_k1 = _mm_loadu_ps(&c[29 - j1]); // 28, 29, 30, 31, + const __m128 wkrt = _mm_sub_ps(mm_half, c_k1); // 28, 29, 30, 31, + const __m128 wkr_ = + _mm_shuffle_ps(wkrt, wkrt, _MM_SHUFFLE(0, 1, 2, 3)); // 31, 30, 29, 28, + const __m128 wki_ = c_j1; // 1, 2, 3, 4, + // Load and shuffle 'a'. + const __m128 a_j2_0 = _mm_loadu_ps(&a[0 + j2]); // 2, 3, 4, 5, + const __m128 a_j2_4 = _mm_loadu_ps(&a[4 + j2]); // 6, 7, 8, 9, + const __m128 a_k2_0 = _mm_loadu_ps(&a[122 - j2]); // 120, 121, 122, 123, + const __m128 a_k2_4 = _mm_loadu_ps(&a[126 - j2]); // 124, 125, 126, 127, + const __m128 a_j2_p0 = _mm_shuffle_ps(a_j2_0, a_j2_4, + _MM_SHUFFLE(2, 0, 2 ,0)); // 2, 4, 6, 8, + const __m128 a_j2_p1 = _mm_shuffle_ps(a_j2_0, a_j2_4, + _MM_SHUFFLE(3, 1, 3 ,1)); // 3, 5, 7, 9, + const __m128 a_k2_p0 = _mm_shuffle_ps(a_k2_4, a_k2_0, + _MM_SHUFFLE(0, 2, 0 ,2)); // 126, 124, 122, 120, + const __m128 a_k2_p1 = _mm_shuffle_ps(a_k2_4, a_k2_0, + _MM_SHUFFLE(1, 3, 1 ,3)); // 127, 125, 123, 121, + // Calculate 'x'. + const __m128 xr_ = _mm_sub_ps(a_j2_p0, a_k2_p0); + // 2-126, 4-124, 6-122, 8-120, + const __m128 xi_ = _mm_add_ps(a_j2_p1, a_k2_p1); + // 3-127, 5-125, 7-123, 9-121, + // Calculate product into 'y'. + // yr = wkr * xr - wki * xi; + // yi = wkr * xi + wki * xr; + const __m128 a_ = _mm_mul_ps(wkr_, xr_); + const __m128 b_ = _mm_mul_ps(wki_, xi_); + const __m128 c_ = _mm_mul_ps(wkr_, xi_); + const __m128 d_ = _mm_mul_ps(wki_, xr_); + const __m128 yr_ = _mm_sub_ps(a_, b_); // 2-126, 4-124, 6-122, 8-120, + const __m128 yi_ = _mm_add_ps(c_, d_); // 3-127, 5-125, 7-123, 9-121, + // Update 'a'. + // a[j2 + 0] -= yr; + // a[j2 + 1] -= yi; + // a[k2 + 0] += yr; + // a[k2 + 1] -= yi; + const __m128 a_j2_p0n = _mm_sub_ps(a_j2_p0, yr_); // 2, 4, 6, 8, + const __m128 a_j2_p1n = _mm_sub_ps(a_j2_p1, yi_); // 3, 5, 7, 9, + const __m128 a_k2_p0n = _mm_add_ps(a_k2_p0, yr_); // 126, 124, 122, 120, + const __m128 a_k2_p1n = _mm_sub_ps(a_k2_p1, yi_); // 127, 125, 123, 121, + // Shuffle in right order and store. + const __m128 a_j2_0n = _mm_unpacklo_ps(a_j2_p0n, a_j2_p1n); + // 2, 3, 4, 5, + const __m128 a_j2_4n = _mm_unpackhi_ps(a_j2_p0n, a_j2_p1n); + // 6, 7, 8, 9, + const __m128 a_k2_0nt = _mm_unpackhi_ps(a_k2_p0n, a_k2_p1n); + // 122, 123, 120, 121, + const __m128 a_k2_4nt = _mm_unpacklo_ps(a_k2_p0n, a_k2_p1n); + // 126, 127, 124, 125, + const __m128 a_k2_0n = _mm_shuffle_ps(a_k2_0nt, a_k2_0nt, + _MM_SHUFFLE(1, 0, 3 ,2)); // 120, 121, 122, 123, + const __m128 a_k2_4n = _mm_shuffle_ps(a_k2_4nt, a_k2_4nt, + _MM_SHUFFLE(1, 0, 3 ,2)); // 124, 125, 126, 127, + _mm_storeu_ps(&a[0 + j2], a_j2_0n); + _mm_storeu_ps(&a[4 + j2], a_j2_4n); + _mm_storeu_ps(&a[122 - j2], a_k2_0n); + _mm_storeu_ps(&a[126 - j2], a_k2_4n); + } + // Scalar code for the remaining items. + for (; j2 < 64; j1 += 1, j2 += 2) { + k2 = 128 - j2; + k1 = 32 - j1; + wkr = 0.5f - c[k1]; + wki = c[j1]; + xr = a[j2 + 0] - a[k2 + 0]; + xi = a[j2 + 1] + a[k2 + 1]; + yr = wkr * xr - wki * xi; + yi = wkr * xi + wki * xr; + a[j2 + 0] -= yr; + a[j2 + 1] -= yi; + a[k2 + 0] += yr; + a[k2 + 1] -= yi; + } +} + +static void rftbsub_128_SSE2(float *a) { + const float *c = rdft_w + 32; + int j1, j2, k1, k2; + float wkr, wki, xr, xi, yr, yi; + + static const ALIGN16_BEG float ALIGN16_END k_half[4] = + {0.5f, 0.5f, 0.5f, 0.5f}; + const __m128 mm_half = _mm_load_ps(k_half); + + a[1] = -a[1]; + // Vectorized code (four at once). + // Note: commented number are indexes for the first iteration of the loop. + for (j1 = 1, j2 = 2; j2 + 7 < 64; j1 += 4, j2 += 8) { + // Load 'wk'. + const __m128 c_j1 = _mm_loadu_ps(&c[ j1]); // 1, 2, 3, 4, + const __m128 c_k1 = _mm_loadu_ps(&c[29 - j1]); // 28, 29, 30, 31, + const __m128 wkrt = _mm_sub_ps(mm_half, c_k1); // 28, 29, 30, 31, + const __m128 wkr_ = + _mm_shuffle_ps(wkrt, wkrt, _MM_SHUFFLE(0, 1, 2, 3)); // 31, 30, 29, 28, + const __m128 wki_ = c_j1; // 1, 2, 3, 4, + // Load and shuffle 'a'. + const __m128 a_j2_0 = _mm_loadu_ps(&a[0 + j2]); // 2, 3, 4, 5, + const __m128 a_j2_4 = _mm_loadu_ps(&a[4 + j2]); // 6, 7, 8, 9, + const __m128 a_k2_0 = _mm_loadu_ps(&a[122 - j2]); // 120, 121, 122, 123, + const __m128 a_k2_4 = _mm_loadu_ps(&a[126 - j2]); // 124, 125, 126, 127, + const __m128 a_j2_p0 = _mm_shuffle_ps(a_j2_0, a_j2_4, + _MM_SHUFFLE(2, 0, 2 ,0)); // 2, 4, 6, 8, + const __m128 a_j2_p1 = _mm_shuffle_ps(a_j2_0, a_j2_4, + _MM_SHUFFLE(3, 1, 3 ,1)); // 3, 5, 7, 9, + const __m128 a_k2_p0 = _mm_shuffle_ps(a_k2_4, a_k2_0, + _MM_SHUFFLE(0, 2, 0 ,2)); // 126, 124, 122, 120, + const __m128 a_k2_p1 = _mm_shuffle_ps(a_k2_4, a_k2_0, + _MM_SHUFFLE(1, 3, 1 ,3)); // 127, 125, 123, 121, + // Calculate 'x'. + const __m128 xr_ = _mm_sub_ps(a_j2_p0, a_k2_p0); + // 2-126, 4-124, 6-122, 8-120, + const __m128 xi_ = _mm_add_ps(a_j2_p1, a_k2_p1); + // 3-127, 5-125, 7-123, 9-121, + // Calculate product into 'y'. + // yr = wkr * xr + wki * xi; + // yi = wkr * xi - wki * xr; + const __m128 a_ = _mm_mul_ps(wkr_, xr_); + const __m128 b_ = _mm_mul_ps(wki_, xi_); + const __m128 c_ = _mm_mul_ps(wkr_, xi_); + const __m128 d_ = _mm_mul_ps(wki_, xr_); + const __m128 yr_ = _mm_add_ps(a_, b_); // 2-126, 4-124, 6-122, 8-120, + const __m128 yi_ = _mm_sub_ps(c_, d_); // 3-127, 5-125, 7-123, 9-121, + // Update 'a'. + // a[j2 + 0] = a[j2 + 0] - yr; + // a[j2 + 1] = yi - a[j2 + 1]; + // a[k2 + 0] = yr + a[k2 + 0]; + // a[k2 + 1] = yi - a[k2 + 1]; + const __m128 a_j2_p0n = _mm_sub_ps(a_j2_p0, yr_); // 2, 4, 6, 8, + const __m128 a_j2_p1n = _mm_sub_ps(yi_, a_j2_p1); // 3, 5, 7, 9, + const __m128 a_k2_p0n = _mm_add_ps(a_k2_p0, yr_); // 126, 124, 122, 120, + const __m128 a_k2_p1n = _mm_sub_ps(yi_, a_k2_p1); // 127, 125, 123, 121, + // Shuffle in right order and store. + const __m128 a_j2_0n = _mm_unpacklo_ps(a_j2_p0n, a_j2_p1n); + // 2, 3, 4, 5, + const __m128 a_j2_4n = _mm_unpackhi_ps(a_j2_p0n, a_j2_p1n); + // 6, 7, 8, 9, + const __m128 a_k2_0nt = _mm_unpackhi_ps(a_k2_p0n, a_k2_p1n); + // 122, 123, 120, 121, + const __m128 a_k2_4nt = _mm_unpacklo_ps(a_k2_p0n, a_k2_p1n); + // 126, 127, 124, 125, + const __m128 a_k2_0n = _mm_shuffle_ps(a_k2_0nt, a_k2_0nt, + _MM_SHUFFLE(1, 0, 3 ,2)); // 120, 121, 122, 123, + const __m128 a_k2_4n = _mm_shuffle_ps(a_k2_4nt, a_k2_4nt, + _MM_SHUFFLE(1, 0, 3 ,2)); // 124, 125, 126, 127, + _mm_storeu_ps(&a[0 + j2], a_j2_0n); + _mm_storeu_ps(&a[4 + j2], a_j2_4n); + _mm_storeu_ps(&a[122 - j2], a_k2_0n); + _mm_storeu_ps(&a[126 - j2], a_k2_4n); + } + // Scalar code for the remaining items. + for (; j2 < 64; j1 += 1, j2 += 2) { + k2 = 128 - j2; + k1 = 32 - j1; + wkr = 0.5f - c[k1]; + wki = c[j1]; + xr = a[j2 + 0] - a[k2 + 0]; + xi = a[j2 + 1] + a[k2 + 1]; + yr = wkr * xr + wki * xi; + yi = wkr * xi - wki * xr; + a[j2 + 0] = a[j2 + 0] - yr; + a[j2 + 1] = yi - a[j2 + 1]; + a[k2 + 0] = yr + a[k2 + 0]; + a[k2 + 1] = yi - a[k2 + 1]; + } + a[65] = -a[65]; +} + +void aec_rdft_init_sse2(void) { + cft1st_128 = cft1st_128_SSE2; + cftmdl_128 = cftmdl_128_SSE2; + rftfsub_128 = rftfsub_128_SSE2; + rftbsub_128 = rftbsub_128_SSE2; +} + +#endif // WEBRTC_USE_SS2 diff --git a/src/modules/audio_processing/aec/main/source/echo_cancellation.c b/src/modules/audio_processing/aec/main/source/echo_cancellation.c new file mode 100644 index 0000000..f6a2538 --- /dev/null +++ b/src/modules/audio_processing/aec/main/source/echo_cancellation.c @@ -0,0 +1,824 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +/* + * Contains the API functions for the AEC. + */ +#include +#include + +#include "echo_cancellation.h" +#include "aec_core.h" +#include "ring_buffer.h" +#include "resampler.h" +#ifdef AEC_DEBUG + #include +#endif + +#define BUF_SIZE_FRAMES 50 // buffer size (frames) +// Maximum length of resampled signal. Must be an integer multiple of frames +// (ceil(1/(1 + MIN_SKEW)*2) + 1)*FRAME_LEN +// The factor of 2 handles wb, and the + 1 is as a safety margin +#define MAX_RESAMP_LEN (5 * FRAME_LEN) + +static const int bufSizeSamp = BUF_SIZE_FRAMES * FRAME_LEN; // buffer size (samples) +static const int sampMsNb = 8; // samples per ms in nb +// Target suppression levels for nlp modes +// log{0.001, 0.00001, 0.00000001} +static const float targetSupp[3] = {-6.9f, -11.5f, -18.4f}; +static const float minOverDrive[3] = {1.0f, 2.0f, 5.0f}; +static const int initCheck = 42; + +typedef struct { + int delayCtr; + int sampFreq; + int splitSampFreq; + int scSampFreq; + float sampFactor; // scSampRate / sampFreq + short nlpMode; + short autoOnOff; + short activity; + short skewMode; + short bufSizeStart; + //short bufResetCtr; // counts number of noncausal frames + int knownDelay; + + // Stores the last frame added to the farend buffer + short farendOld[2][FRAME_LEN]; + short initFlag; // indicates if AEC has been initialized + + // Variables used for averaging far end buffer size + short counter; + short sum; + short firstVal; + short checkBufSizeCtr; + + // Variables used for delay shifts + short msInSndCardBuf; + short filtDelay; + int timeForDelayChange; + int ECstartup; + int checkBuffSize; + int delayChange; + short lastDelayDiff; + +#ifdef AEC_DEBUG + FILE *bufFile; + FILE *delayFile; + FILE *skewFile; + FILE *preCompFile; + FILE *postCompFile; +#endif // AEC_DEBUG + + // Structures + void *farendBuf; + void *resampler; + + int skewFrCtr; + int resample; // if the skew is small enough we don't resample + int highSkewCtr; + float skew; + + int lastError; + + aec_t *aec; +} aecpc_t; + +// Estimates delay to set the position of the farend buffer read pointer +// (controlled by knownDelay) +static int EstBufDelay(aecpc_t *aecInst, short msInSndCardBuf); + +// Stuffs the farend buffer if the estimated delay is too large +static int DelayComp(aecpc_t *aecInst); + +WebRtc_Word32 WebRtcAec_Create(void **aecInst) +{ + aecpc_t *aecpc; + if (aecInst == NULL) { + return -1; + } + + aecpc = malloc(sizeof(aecpc_t)); + *aecInst = aecpc; + if (aecpc == NULL) { + return -1; + } + + if (WebRtcAec_CreateAec(&aecpc->aec) == -1) { + WebRtcAec_Free(aecpc); + aecpc = NULL; + return -1; + } + + if (WebRtcApm_CreateBuffer(&aecpc->farendBuf, bufSizeSamp) == -1) { + WebRtcAec_Free(aecpc); + aecpc = NULL; + return -1; + } + + if (WebRtcAec_CreateResampler(&aecpc->resampler) == -1) { + WebRtcAec_Free(aecpc); + aecpc = NULL; + return -1; + } + + aecpc->initFlag = 0; + aecpc->lastError = 0; + +#ifdef AEC_DEBUG + aecpc->aec->farFile = fopen("aecFar.pcm","wb"); + aecpc->aec->nearFile = fopen("aecNear.pcm","wb"); + aecpc->aec->outFile = fopen("aecOut.pcm","wb"); + aecpc->aec->outLpFile = fopen("aecOutLp.pcm","wb"); + + aecpc->bufFile = fopen("aecBuf.dat", "wb"); + aecpc->skewFile = fopen("aecSkew.dat", "wb"); + aecpc->delayFile = fopen("aecDelay.dat", "wb"); + aecpc->preCompFile = fopen("preComp.pcm", "wb"); + aecpc->postCompFile = fopen("postComp.pcm", "wb"); +#endif // AEC_DEBUG + + return 0; +} + +WebRtc_Word32 WebRtcAec_Free(void *aecInst) +{ + aecpc_t *aecpc = aecInst; + + if (aecpc == NULL) { + return -1; + } + +#ifdef AEC_DEBUG + fclose(aecpc->aec->farFile); + fclose(aecpc->aec->nearFile); + fclose(aecpc->aec->outFile); + fclose(aecpc->aec->outLpFile); + + fclose(aecpc->bufFile); + fclose(aecpc->skewFile); + fclose(aecpc->delayFile); + fclose(aecpc->preCompFile); + fclose(aecpc->postCompFile); +#endif // AEC_DEBUG + + WebRtcAec_FreeAec(aecpc->aec); + WebRtcApm_FreeBuffer(aecpc->farendBuf); + WebRtcAec_FreeResampler(aecpc->resampler); + free(aecpc); + + return 0; +} + +WebRtc_Word32 WebRtcAec_Init(void *aecInst, WebRtc_Word32 sampFreq, WebRtc_Word32 scSampFreq) +{ + aecpc_t *aecpc = aecInst; + AecConfig aecConfig; + + if (aecpc == NULL) { + return -1; + } + + if (sampFreq != 8000 && sampFreq != 16000 && sampFreq != 32000) { + aecpc->lastError = AEC_BAD_PARAMETER_ERROR; + return -1; + } + aecpc->sampFreq = sampFreq; + + if (scSampFreq < 1 || scSampFreq > 96000) { + aecpc->lastError = AEC_BAD_PARAMETER_ERROR; + return -1; + } + aecpc->scSampFreq = scSampFreq; + + // Initialize echo canceller core + if (WebRtcAec_InitAec(aecpc->aec, aecpc->sampFreq) == -1) { + aecpc->lastError = AEC_UNSPECIFIED_ERROR; + return -1; + } + + // Initialize farend buffer + if (WebRtcApm_InitBuffer(aecpc->farendBuf) == -1) { + aecpc->lastError = AEC_UNSPECIFIED_ERROR; + return -1; + } + + if (WebRtcAec_InitResampler(aecpc->resampler, aecpc->scSampFreq) == -1) { + aecpc->lastError = AEC_UNSPECIFIED_ERROR; + return -1; + } + + aecpc->initFlag = initCheck; // indicates that initilisation has been done + + if (aecpc->sampFreq == 32000) { + aecpc->splitSampFreq = 16000; + } + else { + aecpc->splitSampFreq = sampFreq; + } + + aecpc->skewFrCtr = 0; + aecpc->activity = 0; + + aecpc->delayChange = 1; + aecpc->delayCtr = 0; + + aecpc->sum = 0; + aecpc->counter = 0; + aecpc->checkBuffSize = 1; + aecpc->firstVal = 0; + + aecpc->ECstartup = 1; + aecpc->bufSizeStart = 0; + aecpc->checkBufSizeCtr = 0; + aecpc->filtDelay = 0; + aecpc->timeForDelayChange =0; + aecpc->knownDelay = 0; + aecpc->lastDelayDiff = 0; + + aecpc->skew = 0; + aecpc->resample = kAecFalse; + aecpc->highSkewCtr = 0; + aecpc->sampFactor = (aecpc->scSampFreq * 1.0f) / aecpc->splitSampFreq; + + memset(&aecpc->farendOld[0][0], 0, 160); + + // Default settings. + aecConfig.nlpMode = kAecNlpModerate; + aecConfig.skewMode = kAecFalse; + aecConfig.metricsMode = kAecFalse; + + if (WebRtcAec_set_config(aecpc, aecConfig) == -1) { + aecpc->lastError = AEC_UNSPECIFIED_ERROR; + return -1; + } + + return 0; +} + +// only buffer L band for farend +WebRtc_Word32 WebRtcAec_BufferFarend(void *aecInst, const WebRtc_Word16 *farend, + WebRtc_Word16 nrOfSamples) +{ + aecpc_t *aecpc = aecInst; + WebRtc_Word32 retVal = 0; + short newNrOfSamples; + short newFarend[MAX_RESAMP_LEN]; + float skew; + + if (aecpc == NULL) { + return -1; + } + + if (farend == NULL) { + aecpc->lastError = AEC_NULL_POINTER_ERROR; + return -1; + } + + if (aecpc->initFlag != initCheck) { + aecpc->lastError = AEC_UNINITIALIZED_ERROR; + return -1; + } + + // number of samples == 160 for SWB input + if (nrOfSamples != 80 && nrOfSamples != 160) { + aecpc->lastError = AEC_BAD_PARAMETER_ERROR; + return -1; + } + + skew = aecpc->skew; + + // TODO: Is this really a good idea? + if (!aecpc->ECstartup) { + DelayComp(aecpc); + } + + if (aecpc->skewMode == kAecTrue && aecpc->resample == kAecTrue) { + // Resample and get a new number of samples + newNrOfSamples = WebRtcAec_ResampleLinear(aecpc->resampler, + farend, + nrOfSamples, + skew, + newFarend); + WebRtcApm_WriteBuffer(aecpc->farendBuf, newFarend, newNrOfSamples); + +#ifdef AEC_DEBUG + fwrite(farend, 2, nrOfSamples, aecpc->preCompFile); + fwrite(newFarend, 2, newNrOfSamples, aecpc->postCompFile); +#endif + } + else { + WebRtcApm_WriteBuffer(aecpc->farendBuf, farend, nrOfSamples); + } + + return retVal; +} + +WebRtc_Word32 WebRtcAec_Process(void *aecInst, const WebRtc_Word16 *nearend, + const WebRtc_Word16 *nearendH, WebRtc_Word16 *out, WebRtc_Word16 *outH, + WebRtc_Word16 nrOfSamples, WebRtc_Word16 msInSndCardBuf, WebRtc_Word32 skew) +{ + aecpc_t *aecpc = aecInst; + WebRtc_Word32 retVal = 0; + short i; + short farend[FRAME_LEN]; + short nmbrOfFilledBuffers; + short nBlocks10ms; + short nFrames; +#ifdef AEC_DEBUG + short msInAECBuf; +#endif + // Limit resampling to doubling/halving of signal + const float minSkewEst = -0.5f; + const float maxSkewEst = 1.0f; + + if (aecpc == NULL) { + return -1; + } + + if (nearend == NULL) { + aecpc->lastError = AEC_NULL_POINTER_ERROR; + return -1; + } + + if (out == NULL) { + aecpc->lastError = AEC_NULL_POINTER_ERROR; + return -1; + } + + if (aecpc->initFlag != initCheck) { + aecpc->lastError = AEC_UNINITIALIZED_ERROR; + return -1; + } + + // number of samples == 160 for SWB input + if (nrOfSamples != 80 && nrOfSamples != 160) { + aecpc->lastError = AEC_BAD_PARAMETER_ERROR; + return -1; + } + + // Check for valid pointers based on sampling rate + if (aecpc->sampFreq == 32000 && nearendH == NULL) { + aecpc->lastError = AEC_NULL_POINTER_ERROR; + return -1; + } + + if (msInSndCardBuf < 0) { + msInSndCardBuf = 0; + aecpc->lastError = AEC_BAD_PARAMETER_WARNING; + retVal = -1; + } + else if (msInSndCardBuf > 500) { + msInSndCardBuf = 500; + aecpc->lastError = AEC_BAD_PARAMETER_WARNING; + retVal = -1; + } + msInSndCardBuf += 10; + aecpc->msInSndCardBuf = msInSndCardBuf; + + if (aecpc->skewMode == kAecTrue) { + if (aecpc->skewFrCtr < 25) { + aecpc->skewFrCtr++; + } + else { + retVal = WebRtcAec_GetSkew(aecpc->resampler, skew, &aecpc->skew); + if (retVal == -1) { + aecpc->skew = 0; + aecpc->lastError = AEC_BAD_PARAMETER_WARNING; + } + + aecpc->skew /= aecpc->sampFactor*nrOfSamples; + + if (aecpc->skew < 1.0e-3 && aecpc->skew > -1.0e-3) { + aecpc->resample = kAecFalse; + } + else { + aecpc->resample = kAecTrue; + } + + if (aecpc->skew < minSkewEst) { + aecpc->skew = minSkewEst; + } + else if (aecpc->skew > maxSkewEst) { + aecpc->skew = maxSkewEst; + } + +#ifdef AEC_DEBUG + fwrite(&aecpc->skew, sizeof(aecpc->skew), 1, aecpc->skewFile); +#endif + } + } + + nFrames = nrOfSamples / FRAME_LEN; + nBlocks10ms = nFrames / aecpc->aec->mult; + + if (aecpc->ECstartup) { + if (nearend != out) { + // Only needed if they don't already point to the same place. + memcpy(out, nearend, sizeof(short) * nrOfSamples); + } + nmbrOfFilledBuffers = WebRtcApm_get_buffer_size(aecpc->farendBuf) / FRAME_LEN; + + // The AEC is in the start up mode + // AEC is disabled until the soundcard buffer and farend buffers are OK + + // Mechanism to ensure that the soundcard buffer is reasonably stable. + if (aecpc->checkBuffSize) { + + aecpc->checkBufSizeCtr++; + // Before we fill up the far end buffer we require the amount of data on the + // sound card to be stable (+/-8 ms) compared to the first value. This + // comparison is made during the following 4 consecutive frames. If it seems + // to be stable then we start to fill up the far end buffer. + + if (aecpc->counter == 0) { + aecpc->firstVal = aecpc->msInSndCardBuf; + aecpc->sum = 0; + } + + if (abs(aecpc->firstVal - aecpc->msInSndCardBuf) < + WEBRTC_SPL_MAX(0.2 * aecpc->msInSndCardBuf, sampMsNb)) { + aecpc->sum += aecpc->msInSndCardBuf; + aecpc->counter++; + } + else { + aecpc->counter = 0; + } + + if (aecpc->counter*nBlocks10ms >= 6) { + // The farend buffer size is determined in blocks of 80 samples + // Use 75% of the average value of the soundcard buffer + aecpc->bufSizeStart = WEBRTC_SPL_MIN((int) (0.75 * (aecpc->sum * + aecpc->aec->mult) / (aecpc->counter * 10)), BUF_SIZE_FRAMES); + // buffersize has now been determined + aecpc->checkBuffSize = 0; + } + + if (aecpc->checkBufSizeCtr * nBlocks10ms > 50) { + // for really bad sound cards, don't disable echocanceller for more than 0.5 sec + aecpc->bufSizeStart = WEBRTC_SPL_MIN((int) (0.75 * (aecpc->msInSndCardBuf * + aecpc->aec->mult) / 10), BUF_SIZE_FRAMES); + aecpc->checkBuffSize = 0; + } + } + + // if checkBuffSize changed in the if-statement above + if (!aecpc->checkBuffSize) { + // soundcard buffer is now reasonably stable + // When the far end buffer is filled with approximately the same amount of + // data as the amount on the sound card we end the start up phase and start + // to cancel echoes. + + if (nmbrOfFilledBuffers == aecpc->bufSizeStart) { + aecpc->ECstartup = 0; // Enable the AEC + } + else if (nmbrOfFilledBuffers > aecpc->bufSizeStart) { + WebRtcApm_FlushBuffer(aecpc->farendBuf, WebRtcApm_get_buffer_size(aecpc->farendBuf) - + aecpc->bufSizeStart * FRAME_LEN); + aecpc->ECstartup = 0; + } + } + + } + else { + // AEC is enabled + + // Note only 1 block supported for nb and 2 blocks for wb + for (i = 0; i < nFrames; i++) { + nmbrOfFilledBuffers = WebRtcApm_get_buffer_size(aecpc->farendBuf) / FRAME_LEN; + + // Check that there is data in the far end buffer + if (nmbrOfFilledBuffers > 0) { + // Get the next 80 samples from the farend buffer + WebRtcApm_ReadBuffer(aecpc->farendBuf, farend, FRAME_LEN); + + // Always store the last frame for use when we run out of data + memcpy(&(aecpc->farendOld[i][0]), farend, FRAME_LEN * sizeof(short)); + } + else { + // We have no data so we use the last played frame + memcpy(farend, &(aecpc->farendOld[i][0]), FRAME_LEN * sizeof(short)); + } + + // Call buffer delay estimator when all data is extracted, + // i.e. i = 0 for NB and i = 1 for WB or SWB + if ((i == 0 && aecpc->splitSampFreq == 8000) || + (i == 1 && (aecpc->splitSampFreq == 16000))) { + EstBufDelay(aecpc, aecpc->msInSndCardBuf); + } + + // Call the AEC + WebRtcAec_ProcessFrame(aecpc->aec, farend, &nearend[FRAME_LEN * i], &nearendH[FRAME_LEN * i], + &out[FRAME_LEN * i], &outH[FRAME_LEN * i], aecpc->knownDelay); + } + } + +#ifdef AEC_DEBUG + msInAECBuf = WebRtcApm_get_buffer_size(aecpc->farendBuf) / (sampMsNb*aecpc->aec->mult); + fwrite(&msInAECBuf, 2, 1, aecpc->bufFile); + fwrite(&(aecpc->knownDelay), sizeof(aecpc->knownDelay), 1, aecpc->delayFile); +#endif + + return retVal; +} + +WebRtc_Word32 WebRtcAec_set_config(void *aecInst, AecConfig config) +{ + aecpc_t *aecpc = aecInst; + + if (aecpc == NULL) { + return -1; + } + + if (aecpc->initFlag != initCheck) { + aecpc->lastError = AEC_UNINITIALIZED_ERROR; + return -1; + } + + if (config.skewMode != kAecFalse && config.skewMode != kAecTrue) { + aecpc->lastError = AEC_BAD_PARAMETER_ERROR; + return -1; + } + aecpc->skewMode = config.skewMode; + + if (config.nlpMode != kAecNlpConservative && config.nlpMode != + kAecNlpModerate && config.nlpMode != kAecNlpAggressive) { + aecpc->lastError = AEC_BAD_PARAMETER_ERROR; + return -1; + } + aecpc->nlpMode = config.nlpMode; + aecpc->aec->targetSupp = targetSupp[aecpc->nlpMode]; + aecpc->aec->minOverDrive = minOverDrive[aecpc->nlpMode]; + + if (config.metricsMode != kAecFalse && config.metricsMode != kAecTrue) { + aecpc->lastError = AEC_BAD_PARAMETER_ERROR; + return -1; + } + aecpc->aec->metricsMode = config.metricsMode; + if (aecpc->aec->metricsMode == kAecTrue) { + WebRtcAec_InitMetrics(aecpc->aec); + } + + return 0; +} + +WebRtc_Word32 WebRtcAec_get_config(void *aecInst, AecConfig *config) +{ + aecpc_t *aecpc = aecInst; + + if (aecpc == NULL) { + return -1; + } + + if (config == NULL) { + aecpc->lastError = AEC_NULL_POINTER_ERROR; + return -1; + } + + if (aecpc->initFlag != initCheck) { + aecpc->lastError = AEC_UNINITIALIZED_ERROR; + return -1; + } + + config->nlpMode = aecpc->nlpMode; + config->skewMode = aecpc->skewMode; + config->metricsMode = aecpc->aec->metricsMode; + + return 0; +} + +WebRtc_Word32 WebRtcAec_get_echo_status(void *aecInst, WebRtc_Word16 *status) +{ + aecpc_t *aecpc = aecInst; + + if (aecpc == NULL) { + return -1; + } + + if (status == NULL) { + aecpc->lastError = AEC_NULL_POINTER_ERROR; + return -1; + } + + if (aecpc->initFlag != initCheck) { + aecpc->lastError = AEC_UNINITIALIZED_ERROR; + return -1; + } + + *status = aecpc->aec->echoState; + + return 0; +} + +WebRtc_Word32 WebRtcAec_GetMetrics(void *aecInst, AecMetrics *metrics) +{ + const float upweight = 0.7f; + float dtmp; + short stmp; + aecpc_t *aecpc = aecInst; + + if (aecpc == NULL) { + return -1; + } + + if (metrics == NULL) { + aecpc->lastError = AEC_NULL_POINTER_ERROR; + return -1; + } + + if (aecpc->initFlag != initCheck) { + aecpc->lastError = AEC_UNINITIALIZED_ERROR; + return -1; + } + + // ERL + metrics->erl.instant = (short) aecpc->aec->erl.instant; + + if ((aecpc->aec->erl.himean > offsetLevel) && (aecpc->aec->erl.average > offsetLevel)) { + // Use a mix between regular average and upper part average + dtmp = upweight * aecpc->aec->erl.himean + (1 - upweight) * aecpc->aec->erl.average; + metrics->erl.average = (short) dtmp; + } + else { + metrics->erl.average = offsetLevel; + } + + metrics->erl.max = (short) aecpc->aec->erl.max; + + if (aecpc->aec->erl.min < (offsetLevel * (-1))) { + metrics->erl.min = (short) aecpc->aec->erl.min; + } + else { + metrics->erl.min = offsetLevel; + } + + // ERLE + metrics->erle.instant = (short) aecpc->aec->erle.instant; + + if ((aecpc->aec->erle.himean > offsetLevel) && (aecpc->aec->erle.average > offsetLevel)) { + // Use a mix between regular average and upper part average + dtmp = upweight * aecpc->aec->erle.himean + (1 - upweight) * aecpc->aec->erle.average; + metrics->erle.average = (short) dtmp; + } + else { + metrics->erle.average = offsetLevel; + } + + metrics->erle.max = (short) aecpc->aec->erle.max; + + if (aecpc->aec->erle.min < (offsetLevel * (-1))) { + metrics->erle.min = (short) aecpc->aec->erle.min; + } else { + metrics->erle.min = offsetLevel; + } + + // RERL + if ((metrics->erl.average > offsetLevel) && (metrics->erle.average > offsetLevel)) { + stmp = metrics->erl.average + metrics->erle.average; + } + else { + stmp = offsetLevel; + } + metrics->rerl.average = stmp; + + // No other statistics needed, but returned for completeness + metrics->rerl.instant = stmp; + metrics->rerl.max = stmp; + metrics->rerl.min = stmp; + + // A_NLP + metrics->aNlp.instant = (short) aecpc->aec->aNlp.instant; + + if ((aecpc->aec->aNlp.himean > offsetLevel) && (aecpc->aec->aNlp.average > offsetLevel)) { + // Use a mix between regular average and upper part average + dtmp = upweight * aecpc->aec->aNlp.himean + (1 - upweight) * aecpc->aec->aNlp.average; + metrics->aNlp.average = (short) dtmp; + } + else { + metrics->aNlp.average = offsetLevel; + } + + metrics->aNlp.max = (short) aecpc->aec->aNlp.max; + + if (aecpc->aec->aNlp.min < (offsetLevel * (-1))) { + metrics->aNlp.min = (short) aecpc->aec->aNlp.min; + } + else { + metrics->aNlp.min = offsetLevel; + } + + return 0; +} + +WebRtc_Word32 WebRtcAec_get_version(WebRtc_Word8 *versionStr, WebRtc_Word16 len) +{ + const char version[] = "AEC 2.5.0"; + const short versionLen = (short)strlen(version) + 1; // +1 for null-termination + + if (versionStr == NULL) { + return -1; + } + + if (versionLen > len) { + return -1; + } + + strncpy(versionStr, version, versionLen); + return 0; +} + +WebRtc_Word32 WebRtcAec_get_error_code(void *aecInst) +{ + aecpc_t *aecpc = aecInst; + + if (aecpc == NULL) { + return -1; + } + + return aecpc->lastError; +} + +static int EstBufDelay(aecpc_t *aecpc, short msInSndCardBuf) +{ + short delayNew, nSampFar, nSampSndCard; + short diff; + + nSampFar = WebRtcApm_get_buffer_size(aecpc->farendBuf); + nSampSndCard = msInSndCardBuf * sampMsNb * aecpc->aec->mult; + + delayNew = nSampSndCard - nSampFar; + + // Account for resampling frame delay + if (aecpc->skewMode == kAecTrue && aecpc->resample == kAecTrue) { + delayNew -= kResamplingDelay; + } + + if (delayNew < FRAME_LEN) { + WebRtcApm_FlushBuffer(aecpc->farendBuf, FRAME_LEN); + delayNew += FRAME_LEN; + } + + aecpc->filtDelay = WEBRTC_SPL_MAX(0, (short)(0.8*aecpc->filtDelay + 0.2*delayNew)); + + diff = aecpc->filtDelay - aecpc->knownDelay; + if (diff > 224) { + if (aecpc->lastDelayDiff < 96) { + aecpc->timeForDelayChange = 0; + } + else { + aecpc->timeForDelayChange++; + } + } + else if (diff < 96 && aecpc->knownDelay > 0) { + if (aecpc->lastDelayDiff > 224) { + aecpc->timeForDelayChange = 0; + } + else { + aecpc->timeForDelayChange++; + } + } + else { + aecpc->timeForDelayChange = 0; + } + aecpc->lastDelayDiff = diff; + + if (aecpc->timeForDelayChange > 25) { + aecpc->knownDelay = WEBRTC_SPL_MAX((int)aecpc->filtDelay - 160, 0); + } + return 0; +} + +static int DelayComp(aecpc_t *aecpc) +{ + int nSampFar, nSampSndCard, delayNew, nSampAdd; + const int maxStuffSamp = 10 * FRAME_LEN; + + nSampFar = WebRtcApm_get_buffer_size(aecpc->farendBuf); + nSampSndCard = aecpc->msInSndCardBuf * sampMsNb * aecpc->aec->mult; + delayNew = nSampSndCard - nSampFar; + + // Account for resampling frame delay + if (aecpc->skewMode == kAecTrue && aecpc->resample == kAecTrue) { + delayNew -= kResamplingDelay; + } + + if (delayNew > FAR_BUF_LEN - FRAME_LEN*aecpc->aec->mult) { + // The difference of the buffersizes is larger than the maximum + // allowed known delay. Compensate by stuffing the buffer. + nSampAdd = (int)(WEBRTC_SPL_MAX((int)(0.5 * nSampSndCard - nSampFar), + FRAME_LEN)); + nSampAdd = WEBRTC_SPL_MIN(nSampAdd, maxStuffSamp); + + WebRtcApm_StuffBuffer(aecpc->farendBuf, nSampAdd); + aecpc->delayChange = 1; // the delay needs to be updated + } + + return 0; +} diff --git a/src/modules/audio_processing/aec/main/source/resampler.c b/src/modules/audio_processing/aec/main/source/resampler.c new file mode 100644 index 0000000..468fa8c --- /dev/null +++ b/src/modules/audio_processing/aec/main/source/resampler.c @@ -0,0 +1,233 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +/* Resamples a signal to an arbitrary rate. Used by the AEC to compensate for clock + * skew by resampling the farend signal. + */ + +#include +#include +#include +#include + +#include "resampler.h" +#include "aec_core.h" + +enum { kFrameBufferSize = FRAME_LEN * 4 }; +enum { kEstimateLengthFrames = 400 }; + +typedef struct { + short buffer[kFrameBufferSize]; + float position; + + int deviceSampleRateHz; + int skewData[kEstimateLengthFrames]; + int skewDataIndex; + float skewEstimate; +} resampler_t; + +static int EstimateSkew(const int* rawSkew, + int size, + int absLimit, + float *skewEst); + +int WebRtcAec_CreateResampler(void **resampInst) +{ + resampler_t *obj = malloc(sizeof(resampler_t)); + *resampInst = obj; + if (obj == NULL) { + return -1; + } + + return 0; +} + +int WebRtcAec_InitResampler(void *resampInst, int deviceSampleRateHz) +{ + resampler_t *obj = (resampler_t*) resampInst; + memset(obj->buffer, 0, sizeof(obj->buffer)); + obj->position = 0.0; + + obj->deviceSampleRateHz = deviceSampleRateHz; + memset(obj->skewData, 0, sizeof(obj->skewData)); + obj->skewDataIndex = 0; + obj->skewEstimate = 0.0; + + return 0; +} + +int WebRtcAec_FreeResampler(void *resampInst) +{ + resampler_t *obj = (resampler_t*) resampInst; + free(obj); + + return 0; +} + +int WebRtcAec_ResampleLinear(void *resampInst, + const short *inspeech, + int size, + float skew, + short *outspeech) +{ + resampler_t *obj = (resampler_t*) resampInst; + + short *y; + float be, tnew, interp; + int tn, outsize, mm; + + if (size < 0 || size > 2 * FRAME_LEN) { + return -1; + } + + // Add new frame data in lookahead + memcpy(&obj->buffer[FRAME_LEN + kResamplingDelay], + inspeech, + size * sizeof(short)); + + // Sample rate ratio + be = 1 + skew; + + // Loop over input frame + mm = 0; + y = &obj->buffer[FRAME_LEN]; // Point at current frame + + tnew = be * mm + obj->position; + tn = (int) tnew; + + while (tn < size) { + + // Interpolation + interp = y[tn] + (tnew - tn) * (y[tn+1] - y[tn]); + + if (interp > 32767) { + interp = 32767; + } + else if (interp < -32768) { + interp = -32768; + } + + outspeech[mm] = (short) interp; + mm++; + + tnew = be * mm + obj->position; + tn = (int) tnew; + } + + outsize = mm; + obj->position += outsize * be - size; + + // Shift buffer + memmove(obj->buffer, + &obj->buffer[size], + (kFrameBufferSize - size) * sizeof(short)); + + return outsize; +} + +int WebRtcAec_GetSkew(void *resampInst, int rawSkew, float *skewEst) +{ + resampler_t *obj = (resampler_t*)resampInst; + int err = 0; + + if (obj->skewDataIndex < kEstimateLengthFrames) { + obj->skewData[obj->skewDataIndex] = rawSkew; + obj->skewDataIndex++; + } + else if (obj->skewDataIndex == kEstimateLengthFrames) { + err = EstimateSkew(obj->skewData, + kEstimateLengthFrames, + obj->deviceSampleRateHz, + skewEst); + obj->skewEstimate = *skewEst; + obj->skewDataIndex++; + } + else { + *skewEst = obj->skewEstimate; + } + + return err; +} + +int EstimateSkew(const int* rawSkew, + int size, + int deviceSampleRateHz, + float *skewEst) +{ + const int absLimitOuter = (int)(0.04f * deviceSampleRateHz); + const int absLimitInner = (int)(0.0025f * deviceSampleRateHz); + int i = 0; + int n = 0; + float rawAvg = 0; + float err = 0; + float rawAbsDev = 0; + int upperLimit = 0; + int lowerLimit = 0; + float cumSum = 0; + float x = 0; + float x2 = 0; + float y = 0; + float xy = 0; + float xAvg = 0; + float denom = 0; + float skew = 0; + + *skewEst = 0; // Set in case of error below. + for (i = 0; i < size; i++) { + if ((rawSkew[i] < absLimitOuter && rawSkew[i] > -absLimitOuter)) { + n++; + rawAvg += rawSkew[i]; + } + } + + if (n == 0) { + return -1; + } + assert(n > 0); + rawAvg /= n; + + for (i = 0; i < size; i++) { + if ((rawSkew[i] < absLimitOuter && rawSkew[i] > -absLimitOuter)) { + err = rawSkew[i] - rawAvg; + rawAbsDev += err >= 0 ? err : -err; + } + } + assert(n > 0); + rawAbsDev /= n; + upperLimit = (int)(rawAvg + 5 * rawAbsDev + 1); // +1 for ceiling. + lowerLimit = (int)(rawAvg - 5 * rawAbsDev - 1); // -1 for floor. + + n = 0; + for (i = 0; i < size; i++) { + if ((rawSkew[i] < absLimitInner && rawSkew[i] > -absLimitInner) || + (rawSkew[i] < upperLimit && rawSkew[i] > lowerLimit)) { + n++; + cumSum += rawSkew[i]; + x += n; + x2 += n*n; + y += cumSum; + xy += n * cumSum; + } + } + + if (n == 0) { + return -1; + } + assert(n > 0); + xAvg = x / n; + denom = x2 - xAvg*x; + + if (denom != 0) { + skew = (xy - xAvg*y) / denom; + } + + *skewEst = skew; + return 0; +} diff --git a/src/modules/audio_processing/aec/main/source/resampler.h b/src/modules/audio_processing/aec/main/source/resampler.h new file mode 100644 index 0000000..9cb2837 --- /dev/null +++ b/src/modules/audio_processing/aec/main/source/resampler.h @@ -0,0 +1,32 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +#ifndef WEBRTC_MODULES_AUDIO_PROCESSING_AEC_MAIN_SOURCE_RESAMPLER_H_ +#define WEBRTC_MODULES_AUDIO_PROCESSING_AEC_MAIN_SOURCE_RESAMPLER_H_ + +enum { kResamplingDelay = 1 }; + +// Unless otherwise specified, functions return 0 on success and -1 on error +int WebRtcAec_CreateResampler(void **resampInst); +int WebRtcAec_InitResampler(void *resampInst, int deviceSampleRateHz); +int WebRtcAec_FreeResampler(void *resampInst); + +// Estimates skew from raw measurement. +int WebRtcAec_GetSkew(void *resampInst, int rawSkew, float *skewEst); + +// Resamples input using linear interpolation. +// Returns size of resampled array. +int WebRtcAec_ResampleLinear(void *resampInst, + const short *inspeech, + int size, + float skew, + short *outspeech); + +#endif // WEBRTC_MODULES_AUDIO_PROCESSING_AEC_MAIN_SOURCE_RESAMPLER_H_ diff --git a/src/modules/audio_processing/aecm/main/interface/echo_control_mobile.h b/src/modules/audio_processing/aecm/main/interface/echo_control_mobile.h new file mode 100644 index 0000000..30bea7a --- /dev/null +++ b/src/modules/audio_processing/aecm/main/interface/echo_control_mobile.h @@ -0,0 +1,250 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +#ifndef WEBRTC_MODULES_AUDIO_PROCESSING_AECM_MAIN_INTERFACE_ECHO_CONTROL_MOBILE_H_ +#define WEBRTC_MODULES_AUDIO_PROCESSING_AECM_MAIN_INTERFACE_ECHO_CONTROL_MOBILE_H_ + +#include "typedefs.h" + +enum { + AecmFalse = 0, + AecmTrue +}; + +// Errors +#define AECM_UNSPECIFIED_ERROR 12000 +#define AECM_UNSUPPORTED_FUNCTION_ERROR 12001 +#define AECM_UNINITIALIZED_ERROR 12002 +#define AECM_NULL_POINTER_ERROR 12003 +#define AECM_BAD_PARAMETER_ERROR 12004 + +// Warnings +#define AECM_BAD_PARAMETER_WARNING 12100 + +typedef struct { + WebRtc_Word16 cngMode; // AECM_FALSE, AECM_TRUE (default) + WebRtc_Word16 echoMode; // 0, 1, 2, 3 (default), 4 +} AecmConfig; + +#ifdef __cplusplus +extern "C" { +#endif + +/* + * Allocates the memory needed by the AECM. The memory needs to be + * initialized separately using the WebRtcAecm_Init() function. + * + * Inputs Description + * ------------------------------------------------------------------- + * void **aecmInst Pointer to the AECM instance to be + * created and initialized + * + * Outputs Description + * ------------------------------------------------------------------- + * WebRtc_Word32 return 0: OK + * -1: error + */ +WebRtc_Word32 WebRtcAecm_Create(void **aecmInst); + +/* + * This function releases the memory allocated by WebRtcAecm_Create() + * + * Inputs Description + * ------------------------------------------------------------------- + * void *aecmInst Pointer to the AECM instance + * + * Outputs Description + * ------------------------------------------------------------------- + * WebRtc_Word32 return 0: OK + * -1: error + */ +WebRtc_Word32 WebRtcAecm_Free(void *aecmInst); + +/* + * Initializes an AECM instance. + * + * Inputs Description + * ------------------------------------------------------------------- + * void *aecmInst Pointer to the AECM instance + * WebRtc_Word32 sampFreq Sampling frequency of data + * + * Outputs Description + * ------------------------------------------------------------------- + * WebRtc_Word32 return 0: OK + * -1: error + */ +WebRtc_Word32 WebRtcAecm_Init(void* aecmInst, + WebRtc_Word32 sampFreq); + +/* + * Inserts an 80 or 160 sample block of data into the farend buffer. + * + * Inputs Description + * ------------------------------------------------------------------- + * void *aecmInst Pointer to the AECM instance + * WebRtc_Word16 *farend In buffer containing one frame of + * farend signal + * WebRtc_Word16 nrOfSamples Number of samples in farend buffer + * + * Outputs Description + * ------------------------------------------------------------------- + * WebRtc_Word32 return 0: OK + * -1: error + */ +WebRtc_Word32 WebRtcAecm_BufferFarend(void* aecmInst, + const WebRtc_Word16* farend, + WebRtc_Word16 nrOfSamples); + +/* + * Runs the AECM on an 80 or 160 sample blocks of data. + * + * Inputs Description + * ------------------------------------------------------------------- + * void *aecmInst Pointer to the AECM instance + * WebRtc_Word16 *nearendNoisy In buffer containing one frame of + * reference nearend+echo signal. If + * noise reduction is active, provide + * the noisy signal here. + * WebRtc_Word16 *nearendClean In buffer containing one frame of + * nearend+echo signal. If noise + * reduction is active, provide the + * clean signal here. Otherwise pass a + * NULL pointer. + * WebRtc_Word16 nrOfSamples Number of samples in nearend buffer + * WebRtc_Word16 msInSndCardBuf Delay estimate for sound card and + * system buffers + * + * Outputs Description + * ------------------------------------------------------------------- + * WebRtc_Word16 *out Out buffer, one frame of processed nearend + * WebRtc_Word32 return 0: OK + * -1: error + */ +WebRtc_Word32 WebRtcAecm_Process(void* aecmInst, + const WebRtc_Word16* nearendNoisy, + const WebRtc_Word16* nearendClean, + WebRtc_Word16* out, + WebRtc_Word16 nrOfSamples, + WebRtc_Word16 msInSndCardBuf); + +/* + * This function enables the user to set certain parameters on-the-fly + * + * Inputs Description + * ------------------------------------------------------------------- + * void *aecmInst Pointer to the AECM instance + * AecmConfig config Config instance that contains all + * properties to be set + * + * Outputs Description + * ------------------------------------------------------------------- + * WebRtc_Word32 return 0: OK + * -1: error + */ +WebRtc_Word32 WebRtcAecm_set_config(void* aecmInst, + AecmConfig config); + +/* + * This function enables the user to set certain parameters on-the-fly + * + * Inputs Description + * ------------------------------------------------------------------- + * void *aecmInst Pointer to the AECM instance + * + * Outputs Description + * ------------------------------------------------------------------- + * AecmConfig *config Pointer to the config instance that + * all properties will be written to + * WebRtc_Word32 return 0: OK + * -1: error + */ +WebRtc_Word32 WebRtcAecm_get_config(void *aecmInst, + AecmConfig *config); + +/* + * This function enables the user to set the echo path on-the-fly. + * + * Inputs Description + * ------------------------------------------------------------------- + * void* aecmInst Pointer to the AECM instance + * void* echo_path Pointer to the echo path to be set + * size_t size_bytes Size in bytes of the echo path + * + * Outputs Description + * ------------------------------------------------------------------- + * WebRtc_Word32 return 0: OK + * -1: error + */ +WebRtc_Word32 WebRtcAecm_InitEchoPath(void* aecmInst, + const void* echo_path, + size_t size_bytes); + +/* + * This function enables the user to get the currently used echo path + * on-the-fly + * + * Inputs Description + * ------------------------------------------------------------------- + * void* aecmInst Pointer to the AECM instance + * void* echo_path Pointer to echo path + * size_t size_bytes Size in bytes of the echo path + * + * Outputs Description + * ------------------------------------------------------------------- + * WebRtc_Word32 return 0: OK + * -1: error + */ +WebRtc_Word32 WebRtcAecm_GetEchoPath(void* aecmInst, + void* echo_path, + size_t size_bytes); + +/* + * This function enables the user to get the echo path size in bytes + * + * Outputs Description + * ------------------------------------------------------------------- + * size_t return : size in bytes + */ +size_t WebRtcAecm_echo_path_size_bytes(); + +/* + * Gets the last error code. + * + * Inputs Description + * ------------------------------------------------------------------- + * void *aecmInst Pointer to the AECM instance + * + * Outputs Description + * ------------------------------------------------------------------- + * WebRtc_Word32 return 11000-11100: error code + */ +WebRtc_Word32 WebRtcAecm_get_error_code(void *aecmInst); + +/* + * Gets a version string + * + * Inputs Description + * ------------------------------------------------------------------- + * char *versionStr Pointer to a string array + * WebRtc_Word16 len The maximum length of the string + * + * Outputs Description + * ------------------------------------------------------------------- + * WebRtc_Word8 *versionStr Pointer to a string array + * WebRtc_Word32 return 0: OK + * -1: error + */ +WebRtc_Word32 WebRtcAecm_get_version(WebRtc_Word8 *versionStr, + WebRtc_Word16 len); + +#ifdef __cplusplus +} +#endif +#endif /* WEBRTC_MODULES_AUDIO_PROCESSING_AECM_MAIN_INTERFACE_ECHO_CONTROL_MOBILE_H_ */ diff --git a/src/modules/audio_processing/aecm/main/matlab/compsup.m b/src/modules/audio_processing/aecm/main/matlab/compsup.m new file mode 100644 index 0000000..9575ec4 --- /dev/null +++ b/src/modules/audio_processing/aecm/main/matlab/compsup.m @@ -0,0 +1,447 @@ +function [emicrophone,aaa]=compsup(microphone,TheFarEnd,avtime,samplingfreq); +% microphone = microphone signal +% aaa = nonlinearity input variable +% TheFarEnd = far end signal +% avtime = interval to compute suppression from (seconds) +% samplingfreq = sampling frequency + +%if(nargin==6) +% fprintf(1,'suppress has received a delay sequence\n'); +%end + + +Ap500=[ 1.00, -4.95, 9.801, -9.70299, 4.80298005, -0.9509900499]; +Bp500=[ 0.662743088639636, -2.5841655608125, 3.77668102146288, -2.45182477425154, 0.596566274575251, 0.0]; + + +Ap200=[ 1.00, -4.875, 9.50625, -9.26859375, 4.518439453125, -0.881095693359375]; +Bp200=[ 0.862545460994275, -3.2832804496114, 4.67892032308828, -2.95798023879133, 0.699796870041299, 0.0]; + +maxDelay=0.4; %[s] +histLen=1; %[s] + + +% CONSTANTS THAT YOU CAN EXPERIMENT WITH +A_GAIN=10.0; % for the suppress case +oversampling = 2; % must be power of 2; minimum is 2; 4 works +% fine for support=64, but for support=128, +% 8 gives better results. +support=64; %512 % fft support (frequency resolution; at low +% settings you can hear more distortion +% (e.g. pitch that is left-over from far-end)) +% 128 works well, 64 is ok) + +lowlevel = mean(abs(microphone))*0.0001; + +G_ol = 0; % Use overlapping sets of estimates + +% ECHO SUPPRESSION SPECIFIC PARAMETERS +suppress_overdrive=1.0; % overdrive factor for suppression 1.4 is good +gamma_echo=1.0; % same as suppress_overdrive but at different place +de_echo_bound=0.0; +mLim=10; % rank of matrix G +%limBW = 1; % use bandwidth-limited response for G +if mLim > (support/2+1) + error('mLim in suppress.m too large\n'); +end + + +dynrange=1.0000e-004; + +% other, constants +hsupport = support/2; +hsupport1 = hsupport+1; +factor = 2 / oversampling; +updatel = support/oversampling; +win=sqrt(designwindow(0,support)); +estLen = round(avtime * samplingfreq/updatel) + +runningfmean =0.0; + +mLim = floor(hsupport1/2); +V = sqrt(2/hsupport1)*cos(pi/hsupport1*(repmat((0:hsupport1-1) + 0.5, mLim, 1).* ... + repmat((0:mLim-1)' + 0.5, 1, hsupport1))); + +fprintf(1,'updatel is %5.3f s\n', updatel/samplingfreq); + + + +bandfirst=8; bandlast=25; +dosmooth=0; % to get rid of wavy bin counts (can be worse or better) + +% compute some constants +blockLen = support/oversampling; +maxDelayb = floor(samplingfreq*maxDelay/updatel); % in blocks +histLenb = floor(samplingfreq*histLen/updatel); % in blocks + +x0=TheFarEnd; +y0=microphone; + + +%input +tlength=min([length(microphone),length(TheFarEnd)]); +updateno=floor(tlength/updatel); +tlength=updatel*updateno; +updateno = updateno - oversampling + 1; + +TheFarEnd =TheFarEnd(1:tlength); +microphone =microphone(1:tlength); + +TheFarEnd =[zeros(hsupport,1);TheFarEnd(1:tlength)]; +microphone =[zeros(hsupport,1);microphone(1:tlength)]; + + +% signal length +n = min([floor(length(x0)/support)*support,floor(length(y0)/support)*support]); +nb = n/blockLen - oversampling + 1; % in blocks + +% initialize space +win = sqrt([0 ; hanning(support-1)]); +sxAll2 = zeros(hsupport1,nb); +syAll2 = zeros(hsupport1,nb); + +z500=zeros(5,maxDelayb+1); +z200=zeros(5,hsupport1); + +bxspectrum=uint32(zeros(nb,1)); +bxhist=uint32(zeros(maxDelayb+1,1)); +byspectrum=uint32(zeros(nb,1)); +bcount=zeros(1+maxDelayb,nb); +fcount=zeros(1+maxDelayb,nb); +fout=zeros(1+maxDelayb,nb); +delay=zeros(nb,1); +tdelay=zeros(nb,1); +nlgains=zeros(nb,1); + +% create space (mainly for debugging) +emicrophone=zeros(tlength,1); +femicrophone=complex(zeros(hsupport1,updateno)); +thefilter=zeros(hsupport1,updateno); +thelimiter=ones(hsupport1,updateno); +fTheFarEnd=complex(zeros(hsupport1,updateno)); +afTheFarEnd=zeros(hsupport1,updateno); +fmicrophone=complex(zeros(hsupport1,updateno)); +afmicrophone=zeros(hsupport1,updateno); + +G = zeros(hsupport1, hsupport1); +zerovec = zeros(hsupport1,1); +zeromat = zeros(hsupport1); + +% Reset sums +mmxs_a = zerovec; +mmys_a = zerovec; +s2xs_a = zerovec; +s2ys_a = zerovec; +Rxxs_a = zeromat; +Ryxs_a = zeromat; +count_a = 1; + +mmxs_b = zerovec; +mmys_b = zerovec; +s2xs_b = zerovec; +s2ys_b = zerovec; +Rxxs_b = zeromat; +Ryxs_b = zeromat; +count_b = 1; + +nog=0; + +aaa=zeros(size(TheFarEnd)); + +% loop over signal blocks +fprintf(1,'.. Suppression; averaging G over %5.1f seconds; file length %5.1f seconds ..\n',avtime, length(microphone)/samplingfreq); +fprintf(1,'.. SUPPRESSING ONLY AFTER %5.1f SECONDS! ..\n',avtime); +fprintf(1,'.. 20 seconds is good ..\n'); +hh = waitbar_j(0,'Please wait...'); + + +for i=1:updateno + + sb = (i-1)*updatel + 1; + se=sb+support-1; + + % analysis FFTs + temp=fft(win .* TheFarEnd(sb:se)); + fTheFarEnd(:,i)=temp(1:hsupport1); + xf=fTheFarEnd(:,i); + afTheFarEnd(:,i)= abs(fTheFarEnd(:,i)); + + temp=win .* microphone(sb:se); + + temp=fft(win .* microphone(sb:se)); + fmicrophone(:,i)=temp(1:hsupport1); + yf=fmicrophone(:,i); + afmicrophone(:,i)= abs(fmicrophone(:,i)); + + + ener_orig = afmicrophone(:,i)'*afmicrophone(:,i); + if( ener_orig == 0) + afmicrophone(:,i)=lowlevel*ones(size(afmicrophone(:,i))); + end + + + % use log domain (showed improved performance) +xxf= sqrt(real(xf.*conj(xf))+1e-20); +yyf= sqrt(real(yf.*conj(yf))+1e-20); + sxAll2(:,i) = 20*log10(xxf); + syAll2(:,i) = 20*log10(yyf); + + mD=min(i-1,maxDelayb); + xthreshold = sum(sxAll2(:,i-mD:i),2)/(maxDelayb+1); + + [yout, z200] = filter(Bp200,Ap200,syAll2(:,i),z200,2); + yout=yout/(maxDelayb+1); + ythreshold = mean(syAll2(:,i-mD:i),2); + + + bxspectrum(i)=getBspectrum(sxAll2(:,i),xthreshold,bandfirst,bandlast); + byspectrum(i)=getBspectrum(syAll2(:,i),yout,bandfirst,bandlast); + + bxhist(end-mD:end)=bxspectrum(i-mD:i); + + bcount(:,i)=hisser2( ... + byspectrum(i),flipud(bxhist),bandfirst,bandlast); + + + [fout(:,i), z500] = filter(Bp500,Ap500,bcount(:,i),z500,2); + fcount(:,i)=sum(bcount(:,max(1,i-histLenb+1):i),2); % using the history range + fout(:,i)=round(fout(:,i)); + [value,delay(i)]=min(fout(:,i),[],1); + tdelay(i)=(delay(i)-1)*support/(samplingfreq*oversampling); + + % compensate + + idel = max(i - delay(i) + 1,1); + + + % echo suppression + + noisyspec = afmicrophone(:,i); + + % Estimate G using covariance matrices + + % Cumulative estimates + xx = afTheFarEnd(:,idel); + yy = afmicrophone(:,i); + + % Means + mmxs_a = mmxs_a + xx; + mmys_a = mmys_a + yy; + if (G_ol) + mmxs_b = mmxs_b + xx; + mmys_b = mmys_b + yy; + mmy = mean([mmys_a/count_a mmys_b/count_b],2); + mmx = mean([mmxs_a/count_a mmxs_b/count_b],2); + else + mmx = mmxs_a/count_a; + mmy = mmys_a/count_a; + end + count_a = count_a + 1; + count_b = count_b + 1; + + % Mean removal + xxm = xx - mmx; + yym = yy - mmy; + + % Variances + s2xs_a = s2xs_a + xxm .* xxm; + s2ys_a = s2ys_a + yym .* yym; + s2xs_b = s2xs_b + xxm .* xxm; + s2ys_b = s2ys_b + yym .* yym; + + % Correlation matrices + Rxxs_a = Rxxs_a + xxm * xxm'; + Ryxs_a = Ryxs_a + yym * xxm'; + Rxxs_b = Rxxs_b + xxm * xxm'; + Ryxs_b = Ryxs_b + yym * xxm'; + + + % Gain matrix A + + if mod(i, estLen) == 0 + + + % Cumulative based estimates + Rxxf = Rxxs_a / (estLen - 1); + Ryxf = Ryxs_a / (estLen - 1); + + % Variance normalization + s2x2 = s2xs_a / (estLen - 1); + s2x2 = sqrt(s2x2); + % Sx = diag(max(s2x2,dynrange*max(s2x2))); + Sx = diag(s2x2); + if (sum(s2x2) > 0) + iSx = inv(Sx); + else + iSx= Sx + 0.01; + end + + s2y2 = s2ys_a / (estLen - 1); + s2y2 = sqrt(s2y2); + % Sy = diag(max(s2y2,dynrange*max(s2y2))); + Sy = diag(s2y2); + iSy = inv(Sy); + rx = iSx * Rxxf * iSx; + ryx = iSy * Ryxf * iSx; + + + + dbd= 7; % Us less than the full matrix + + % k x m + % Bandlimited structure on G + LSEon = 0; % Default is using MMSE + if (LSEon) + ryx = ryx*rx; + rx = rx*rx; + end + p = dbd-1; + gaj = min(min(hsupport1,2*p+1),min([p+(1:hsupport1); hsupport1+p+1-(1:hsupport1)])); + cgaj = [0 cumsum(gaj)]; + + G3 = zeros(hsupport1); + for kk=1:hsupport1 + ki = max(0,kk-p-1); + if (sum(sum(rx(ki+1:ki+gaj(kk),ki+1:ki+gaj(kk))))>0) + G3(kk,ki+1:ki+gaj(kk)) = ryx(kk,ki+1:ki+gaj(kk))/rx(ki+1:ki+gaj(kk),ki+1:ki+gaj(kk)); + else + G3(kk,ki+1:ki+gaj(kk)) = ryx(kk,ki+1:ki+gaj(kk)); + end + end + % End Bandlimited structure + + G = G3; + G(abs(G)<0.01)=0; + G = suppress_overdrive * Sy * G * iSx; + + if 1 + figure(32); mi=2; + surf(max(min(G,mi),-mi)); view(2) + title('Unscaled Masked Limited-bandwidth G'); + end + pause(0.05); + + % Reset sums + mmxs_a = zerovec; + mmys_a = zerovec; + s2xs_a = zerovec; + s2ys_a = zerovec; + Rxxs_a = zeromat; + Ryxs_a = zeromat; + count_a = 1; + + end + + if (G_ol) + % Gain matrix B + + if ((mod((i-estLen/2), estLen) == 0) & i>estLen) + + + % Cumulative based estimates + Rxxf = Rxxs_b / (estLen - 1); + Ryxf = Ryxs_b / (estLen - 1); + + % Variance normalization + s2x2 = s2xs_b / (estLen - 1); + s2x2 = sqrt(s2x2); + Sx = diag(max(s2x2,dynrange*max(s2x2))); + iSx = inv(Sx); + s2y2 = s2ys_b / (estLen - 1); + s2y2 = sqrt(s2y2); + Sy = diag(max(s2y2,dynrange*max(s2y2))); + iSy = inv(Sy); + rx = iSx * Rxxf * iSx; + ryx = iSy * Ryxf * iSx; + + + % Bandlimited structure on G + LSEon = 0; % Default is using MMSE + if (LSEon) + ryx = ryx*rx; + rx = rx*rx; + end + p = dbd-1; + gaj = min(min(hsupport1,2*p+1),min([p+(1:hsupport1); hsupport1+p+1-(1:hsupport1)])); + cgaj = [0 cumsum(gaj)]; + + G3 = zeros(hsupport1); + for kk=1:hsupport1 + ki = max(0,kk-p-1); + G3(kk,ki+1:ki+gaj(kk)) = ryx(kk,ki+1:ki+gaj(kk))/rx(ki+1:ki+gaj(kk),ki+1:ki+gaj(kk)); + end + % End Bandlimited structure + + G = G3; + G(abs(G)<0.01)=0; + G = suppress_overdrive * Sy * G * iSx; + + if 1 + figure(32); mi=2; + surf(max(min(G,mi),-mi)); view(2) + title('Unscaled Masked Limited-bandwidth G'); + end + pause(0.05); + + + % Reset sums + mmxs_b = zerovec; + mmys_b = zerovec; + s2xs_b = zerovec; + s2ys_b = zerovec; + Rxxs_b = zeromat; + Ryxs_b = zeromat; + count_b = 1; + + end + + end + + FECestimate2 = G*afTheFarEnd(:,idel); + + % compute Wiener filter and suppressor function + thefilter(:,i) = (noisyspec - gamma_echo*FECestimate2) ./ noisyspec; + ix0 = find(thefilter(:,i)1); % bounding in reasonable range + thefilter(ix0,i) = 1; + + % NONLINEARITY + nl_alpha=0.8; % memory; seems not very critical + nlSeverity=0.3; % nonlinearity severity: 0 does nothing; 1 suppresses all + thefmean=mean(thefilter(8:16,i)); + if (thefmean<1) + disp(''); + end + runningfmean = nl_alpha*runningfmean + (1-nl_alpha)*thefmean; + aaa(sb+20+1:sb+20+updatel)=10000*runningfmean* ones(updatel,1); % debug + slope0=1.0/(1.0-nlSeverity); % + thegain = max(0.0,min(1.0,slope0*(runningfmean-nlSeverity))); + % END NONLINEARITY + thefilter(:,i) = thegain*thefilter(:,i); + + + % Wiener filtering + femicrophone(:,i) = fmicrophone(:,i) .* thefilter(:,i); + thelimiter(:,i) = (noisyspec - A_GAIN*FECestimate2) ./ noisyspec; + index = find(thelimiter(:,i)>1.0); + thelimiter(index,i) = 1.0; + index = find(thelimiter(:,i)<0.0); + thelimiter(index,i) = 0.0; + + if (rem(i,floor(updateno/20))==0) + fprintf(1,'.'); + end + if mod(i,50)==0 + waitbar_j(i/updateno,hh); + end + + + % reconstruction; first make spectrum odd + temp=[femicrophone(:,i);flipud(conj(femicrophone(2:hsupport,i)))]; + emicrophone(sb:se) = emicrophone(sb:se) + factor * win .* real(ifft(temp)); + +end +fprintf(1,'\n'); + +close(hh); \ No newline at end of file diff --git a/src/modules/audio_processing/aecm/main/matlab/getBspectrum.m b/src/modules/audio_processing/aecm/main/matlab/getBspectrum.m new file mode 100644 index 0000000..a4a533d --- /dev/null +++ b/src/modules/audio_processing/aecm/main/matlab/getBspectrum.m @@ -0,0 +1,22 @@ +function bspectrum=getBspectrum(ps,threshold,bandfirst,bandlast) +% function bspectrum=getBspectrum(ps,threshold,bandfirst,bandlast) +% compute binary spectrum using threshold spectrum as pivot +% bspectrum = binary spectrum (binary) +% ps=current power spectrum (float) +% threshold=threshold spectrum (float) +% bandfirst = first band considered +% bandlast = last band considered + +% initialization stuff + if( length(ps)32 | length(ps)~=length(threshold)) + error('BinDelayEst:spectrum:invalid','Dimensionality error'); +end + +% get current binary spectrum +diff = ps - threshold; +bspectrum=uint32(0); +for(i=bandfirst:bandlast) + if( diff(i)>0 ) + bspectrum = bitset(bspectrum,i); + end +end diff --git a/src/modules/audio_processing/aecm/main/matlab/hisser2.m b/src/modules/audio_processing/aecm/main/matlab/hisser2.m new file mode 100644 index 0000000..5a414f9 --- /dev/null +++ b/src/modules/audio_processing/aecm/main/matlab/hisser2.m @@ -0,0 +1,21 @@ +function bcount=hisser2(bs,bsr,bandfirst,bandlast) +% function bcount=hisser(bspectrum,bandfirst,bandlast) +% histogram for the binary spectra +% bcount= array of bit counts +% bs=binary spectrum (one int32 number each) +% bsr=reference binary spectra (one int32 number each) +% blockSize = histogram over blocksize blocks +% bandfirst = first band considered +% bandlast = last band considered + +% weight all delays equally +maxDelay = length(bsr); + +% compute counts (two methods; the first works better and is operational) +bcount=zeros(maxDelay,1); +for(i=1:maxDelay) + % the delay should have low count for low-near&high-far and high-near&low-far + bcount(i)= sum(bitget(bitxor(bs,bsr(i)),bandfirst:bandlast)); + % the delay should have low count for low-near&high-far (works less well) +% bcount(i)= sum(bitget(bitand(bsr(i),bitxor(bs,bsr(i))),bandfirst:bandlast)); +end diff --git a/src/modules/audio_processing/aecm/main/matlab/main2.m b/src/modules/audio_processing/aecm/main/matlab/main2.m new file mode 100644 index 0000000..7e24c69 --- /dev/null +++ b/src/modules/audio_processing/aecm/main/matlab/main2.m @@ -0,0 +1,19 @@ + +fid=fopen('aecfar.pcm'); far=fread(fid,'short'); fclose(fid); +fid=fopen('aecnear.pcm'); mic=fread(fid,'short'); fclose(fid); + +%fid=fopen('QA1far.pcm'); far=fread(fid,'short'); fclose(fid); +%fid=fopen('QA1near.pcm'); mic=fread(fid,'short'); fclose(fid); + +start=0 * 8000+1; +stop= 30 * 8000; +microphone=mic(start:stop); +TheFarEnd=far(start:stop); +avtime=1; + +% 16000 to make it compatible with the C-version +[emicrophone,tdel]=compsup(microphone,TheFarEnd,avtime,16000); + +spclab(8000,TheFarEnd,microphone,emicrophone); + + diff --git a/src/modules/audio_processing/aecm/main/matlab/matlab/AECMobile.m b/src/modules/audio_processing/aecm/main/matlab/matlab/AECMobile.m new file mode 100644 index 0000000..2d3e686 --- /dev/null +++ b/src/modules/audio_processing/aecm/main/matlab/matlab/AECMobile.m @@ -0,0 +1,269 @@ +function [femicrophone, aecmStructNew, enerNear, enerFar] = AECMobile(fmicrophone, afTheFarEnd, setupStruct, aecmStruct) +global NEARENDFFT; +global F; + +aecmStructNew = aecmStruct; + +% Magnitude spectrum of near end signal +afmicrophone = abs(fmicrophone); +%afmicrophone = NEARENDFFT(setupStruct.currentBlock,:)'/2^F(setupStruct.currentBlock,end); +% Near end energy level +ener_orig = afmicrophone'*afmicrophone; +if( ener_orig == 0) + lowlevel = 0.01; + afmicrophone = lowlevel*ones(size(afmicrophone)); +end +%adiff = max(abs(afmicrophone - afTheFarEnd)); +%if (adiff > 0) +% disp([setupStruct.currentBlock adiff]) +%end + +% Store the near end energy +%aecmStructNew.enerNear(setupStruct.currentBlock) = log(afmicrophone'*afmicrophone); +aecmStructNew.enerNear(setupStruct.currentBlock) = log(sum(afmicrophone)); +% Store the far end energy +%aecmStructNew.enerFar(setupStruct.currentBlock) = log(afTheFarEnd'*afTheFarEnd); +aecmStructNew.enerFar(setupStruct.currentBlock) = log(sum(afTheFarEnd)); + +% Update subbands (We currently use all frequency bins, hence .useSubBand is turned off) +if aecmStructNew.useSubBand + internalIndex = 1; + for kk=1:setupStruct.subBandLength+1 + ySubBand(kk) = mean(afmicrophone(internalIndex:internalIndex+setupStruct.numInBand(kk)-1).^aecmStructNew.bandFactor); + xSubBand(kk) = mean(afTheFarEnd(internalIndex:internalIndex+setupStruct.numInBand(kk)-1).^aecmStructNew.bandFactor); + internalIndex = internalIndex + setupStruct.numInBand(kk); + end +else + ySubBand = afmicrophone.^aecmStructNew.bandFactor; + xSubBand = afTheFarEnd.^aecmStructNew.bandFactor; +end + +% Estimated echo energy +if (aecmStructNew.bandFactor == 1) + %aecmStructNew.enerEcho(setupStruct.currentBlock) = log((aecmStructNew.H.*xSubBand)'*(aecmStructNew.H.*xSubBand)); + %aecmStructNew.enerEchoStored(setupStruct.currentBlock) = log((aecmStructNew.HStored.*xSubBand)'*(aecmStructNew.HStored.*xSubBand)); + aecmStructNew.enerEcho(setupStruct.currentBlock) = log(sum(aecmStructNew.H.*xSubBand)); + aecmStructNew.enerEchoStored(setupStruct.currentBlock) = log(sum(aecmStructNew.HStored.*xSubBand)); +elseif (aecmStructNew.bandFactor == 2) + aecmStructNew.enerEcho(setupStruct.currentBlock) = log(aecmStructNew.H'*xSubBand); + aecmStructNew.enerEchoStored(setupStruct.currentBlock) = log(aecmStructNew.HStored'*xSubBand); +end + +% Last 100 blocks of data, used for plotting +n100 = max(1,setupStruct.currentBlock-99):setupStruct.currentBlock; +enerError = aecmStructNew.enerNear(n100)-aecmStructNew.enerEcho(n100); +enerErrorStored = aecmStructNew.enerNear(n100)-aecmStructNew.enerEchoStored(n100); + +% Store the far end sub band. This is needed if we use LSE instead of NLMS +aecmStructNew.X = [xSubBand aecmStructNew.X(:,1:end-1)]; + +% Update energy levels, which control the VAD +if ((aecmStructNew.enerFar(setupStruct.currentBlock) < aecmStructNew.energyMin) & (aecmStructNew.enerFar(setupStruct.currentBlock) >= aecmStruct.FAR_ENERGY_MIN)) + aecmStructNew.energyMin = aecmStructNew.enerFar(setupStruct.currentBlock); + %aecmStructNew.energyMin = max(aecmStructNew.energyMin,12); + aecmStructNew.energyMin = max(aecmStructNew.energyMin,aecmStruct.FAR_ENERGY_MIN); + aecmStructNew.energyLevel = (aecmStructNew.energyMax-aecmStructNew.energyMin)*aecmStructNew.energyThres+aecmStructNew.energyMin; + aecmStructNew.energyLevelMSE = (aecmStructNew.energyMax-aecmStructNew.energyMin)*aecmStructNew.energyThresMSE+aecmStructNew.energyMin; +end +if (aecmStructNew.enerFar(setupStruct.currentBlock) > aecmStructNew.energyMax) + aecmStructNew.energyMax = aecmStructNew.enerFar(setupStruct.currentBlock); + aecmStructNew.energyLevel = (aecmStructNew.energyMax-aecmStructNew.energyMin)*aecmStructNew.energyThres+aecmStructNew.energyMin; + aecmStructNew.energyLevelMSE = (aecmStructNew.energyMax-aecmStructNew.energyMin)*aecmStructNew.energyThresMSE+aecmStructNew.energyMin; +end + +% Calculate current energy error in near end (estimated echo vs. near end) +dE = aecmStructNew.enerNear(setupStruct.currentBlock)-aecmStructNew.enerEcho(setupStruct.currentBlock); + +%%%%%%%% +% Calculate step size used in LMS algorithm, based on current far end energy and near end energy error (dE) +%%%%%%%% +if setupStruct.stepSize_flag + [mu, aecmStructNew] = calcStepSize(aecmStructNew.enerFar(setupStruct.currentBlock), dE, aecmStructNew, setupStruct.currentBlock, 1); +else + mu = 0.25; +end +aecmStructNew.muLog(setupStruct.currentBlock) = mu; % Store the step size + +% Estimate Echo Spectral Shape +[U, aecmStructNew.H] = fallerEstimator(ySubBand,aecmStructNew.X,aecmStructNew.H,mu); + +%%%%% +% Determine if we should store or restore the channel +%%%%% +if ((setupStruct.currentBlock <= aecmStructNew.convLength) | (~setupStruct.channelUpdate_flag)) + aecmStructNew.HStored = aecmStructNew.H; % Store what you have after startup +elseif ((setupStruct.currentBlock > aecmStructNew.convLength) & (setupStruct.channelUpdate_flag)) + if ((aecmStructNew.enerFar(setupStruct.currentBlock) < aecmStructNew.energyLevelMSE) & (aecmStructNew.enerFar(setupStruct.currentBlock-1) >= aecmStructNew.energyLevelMSE)) + xxx = aecmStructNew.countMseH; + if (xxx > 20) + mseStored = mean(abs(aecmStructNew.enerEchoStored(setupStruct.currentBlock-xxx:setupStruct.currentBlock-1)-aecmStructNew.enerNear(setupStruct.currentBlock-xxx:setupStruct.currentBlock-1))); + mseLatest = mean(abs(aecmStructNew.enerEcho(setupStruct.currentBlock-xxx:setupStruct.currentBlock-1)-aecmStructNew.enerNear(setupStruct.currentBlock-xxx:setupStruct.currentBlock-1))); + %fprintf('Stored: %4f Latest: %4f\n', mseStored, mseLatest) % Uncomment if you want to display the MSE values + if ((mseStored < 0.8*mseLatest) & (aecmStructNew.mseHStoredOld < 0.8*aecmStructNew.mseHLatestOld)) + aecmStructNew.H = aecmStructNew.HStored; + fprintf('Restored H at block %d\n',setupStruct.currentBlock) + elseif (((0.8*mseStored > mseLatest) & (mseLatest < aecmStructNew.mseHThreshold) & (aecmStructNew.mseHLatestOld < aecmStructNew.mseHThreshold)) | (mseStored == Inf)) + aecmStructNew.HStored = aecmStructNew.H; + fprintf('Stored new H at block %d\n',setupStruct.currentBlock) + end + aecmStructNew.mseHStoredOld = mseStored; + aecmStructNew.mseHLatestOld = mseLatest; + end + elseif ((aecmStructNew.enerFar(setupStruct.currentBlock) >= aecmStructNew.energyLevelMSE) & (aecmStructNew.enerFar(setupStruct.currentBlock-1) < aecmStructNew.energyLevelMSE)) + aecmStructNew.countMseH = 1; + elseif (aecmStructNew.enerFar(setupStruct.currentBlock) >= aecmStructNew.energyLevelMSE) + aecmStructNew.countMseH = aecmStructNew.countMseH + 1; + end +end + +%%%%% +% Check delay (calculate the delay offset (if we can)) +% The algorithm is not tuned and should be used with care. It runs separately from Bastiaan's algorithm. +%%%%% +yyy = 31; % Correlation buffer length (currently unfortunately hard coded) +dxxx = 25; % Maximum offset (currently unfortunately hard coded) +if (setupStruct.currentBlock > aecmStructNew.convLength) + if (aecmStructNew.enerFar(setupStruct.currentBlock-(yyy+2*dxxx-1):setupStruct.currentBlock) > aecmStructNew.energyLevelMSE) + for xxx = -dxxx:dxxx + aecmStructNew.delayLatestS(xxx+dxxx+1) = sum(sign(aecmStructNew.enerEcho(setupStruct.currentBlock-(yyy+dxxx-xxx)+1:setupStruct.currentBlock+xxx-dxxx)-mean(aecmStructNew.enerEcho(setupStruct.currentBlock-(yyy++dxxx-xxx)+1:setupStruct.currentBlock+xxx-dxxx))).*sign(aecmStructNew.enerNear(setupStruct.currentBlock-yyy-dxxx+1:setupStruct.currentBlock-dxxx)-mean(aecmStructNew.enerNear(setupStruct.currentBlock-yyy-dxxx+1:setupStruct.currentBlock-dxxx)))); + end + aecmStructNew.newDelayCurve = 1; + end +end +if ((setupStruct.currentBlock > 2*aecmStructNew.convLength) & ~rem(setupStruct.currentBlock,yyy*2) & aecmStructNew.newDelayCurve) + [maxV,maxP] = max(aecmStructNew.delayLatestS); + if ((maxP > 2) & (maxP < 2*dxxx)) + maxVLeft = aecmStructNew.delayLatestS(max(1,maxP-4)); + maxVRight = aecmStructNew.delayLatestS(min(2*dxxx+1,maxP+4)); + %fprintf('Max %d, Left %d, Right %d\n',maxV,maxVLeft,maxVRight) % Uncomment if you want to see max value + if ((maxV > 24) & (maxVLeft < maxV - 10) & (maxVRight < maxV - 10)) + aecmStructNew.feedbackDelay = maxP-dxxx-1; + aecmStructNew.newDelayCurve = 0; + aecmStructNew.feedbackDelayUpdate = 1; + fprintf('Feedback Update at block %d\n',setupStruct.currentBlock) + end + end +end +% End of "Check delay" +%%%%%%%% + +%%%%% +% Calculate suppression gain, based on far end energy and near end energy error (dE) +if (setupStruct.supGain_flag) + [gamma_echo, aecmStructNew.cntIn, aecmStructNew.cntOut] = calcFilterGain(aecmStructNew.enerFar(setupStruct.currentBlock), dE, aecmStructNew, setupStruct.currentBlock, aecmStructNew.convLength, aecmStructNew.cntIn, aecmStructNew.cntOut); +else + gamma_echo = 1; +end +aecmStructNew.gammaLog(setupStruct.currentBlock) = gamma_echo; % Store the gain +gamma_use = gamma_echo; + +% Use the stored channel +U = aecmStructNew.HStored.*xSubBand; + +% compute Wiener filter and suppressor function +Iy = find(ySubBand); +subBandFilter = zeros(size(ySubBand)); +if (aecmStructNew.bandFactor == 2) + subBandFilter(Iy) = (1 - gamma_use*sqrt(U(Iy)./ySubBand(Iy))); % For Faller +else + subBandFilter(Iy) = (1 - gamma_use*(U(Iy)./ySubBand(Iy))); % For COV +end +ix0 = find(subBandFilter < 0); % bounding trick 1 +subBandFilter(ix0) = 0; +ix0 = find(subBandFilter > 1); % bounding trick 1 +subBandFilter(ix0) = 1; + +% Interpolate back to normal frequency bins if we use sub bands +if aecmStructNew.useSubBand + thefilter = interp1(setupStruct.centerFreq,subBandFilter,linspace(0,setupStruct.samplingfreq/2,setupStruct.hsupport1)','nearest'); + testfilter = interp1(setupStruct.centerFreq,subBandFilter,linspace(0,setupStruct.samplingfreq/2,1000),'nearest'); + thefilter(end) = subBandFilter(end); + + internalIndex = 1; + for kk=1:setupStruct.subBandLength+1 + internalIndex:internalIndex+setupStruct.numInBand(kk)-1; + thefilter(internalIndex:internalIndex+setupStruct.numInBand(kk)-1) = subBandFilter(kk); + internalIndex = internalIndex + setupStruct.numInBand(kk); + end +else + thefilter = subBandFilter; + testfilter = subBandFilter; +end + +% Bound the filter +ix0 = find(thefilter < setupStruct.de_echo_bound); % bounding trick 1 +thefilter(ix0) = setupStruct.de_echo_bound; % bounding trick 2 +ix0 = find(thefilter > 1); % bounding in reasonable range +thefilter(ix0) = 1; + +%%%% +% NLP +%%%% +thefmean = mean(thefilter(8:16)); +if (thefmean < 1) + disp(''); +end +aecmStructNew.runningfmean = setupStruct.nl_alpha*aecmStructNew.runningfmean + (1-setupStruct.nl_alpha)*thefmean; +slope0 = 1.0/(1.0 - setupStruct.nlSeverity); % +thegain = max(0.0, min(1.0, slope0*(aecmStructNew.runningfmean - setupStruct.nlSeverity))); +if ~setupStruct.nlp_flag + thegain = 1; +end +% END NONLINEARITY +thefilter = thegain*thefilter; + +%%%% +% The suppression +%%%% +femicrophone = fmicrophone .* thefilter; +% Store the output energy (used for plotting) +%aecmStructNew.enerOut(setupStruct.currentBlock) = log(abs(femicrophone)'*abs(femicrophone)); +aecmStructNew.enerOut(setupStruct.currentBlock) = log(sum(abs(femicrophone))); + +if aecmStructNew.plotIt + figure(13) + subplot(311) + %plot(n100,enerFar(n100),'b-',n100,enerNear(n100),'k--',n100,enerEcho(n100),'r-',[n100(1) n100(end)],[1 1]*vadThNew,'b:',[n100(1) n100(end)],[1 1]*((energyMax-energyMin)/4+energyMin),'r-.',[n100(1) n100(end)],[1 1]*vadNearThNew,'g:',[n100(1) n100(end)],[1 1]*energyMax,'r-.',[n100(1) n100(end)],[1 1]*energyMin,'r-.','LineWidth',2) + plot(n100,aecmStructNew.enerFar(n100),'b-',n100,aecmStructNew.enerNear(n100),'k--',n100,aecmStructNew.enerOut(n100),'r-.',n100,aecmStructNew.enerEcho(n100),'r-',n100,aecmStructNew.enerEchoStored(n100),'c-',[n100(1) n100(end)],[1 1]*((aecmStructNew.energyMax-aecmStructNew.energyMin)/4+aecmStructNew.energyMin),'g-.',[n100(1) n100(end)],[1 1]*aecmStructNew.energyMax,'g-.',[n100(1) n100(end)],[1 1]*aecmStructNew.energyMin,'g-.','LineWidth',2) + %title(['Frame ',int2str(i),' av ',int2str(setupStruct.updateno),' State = ',int2str(speechState),' \mu = ',num2str(mu)]) + title(['\gamma = ',num2str(gamma_echo),' \mu = ',num2str(mu)]) + subplot(312) + %plot(n100,enerError,'b-',[n100(1) n100(end)],[1 1]*vadNearTh,'r:',[n100(1) n100(end)],[-1.5 -1.5]*vadNearTh,'r:','LineWidth',2) + %plot(n100,enerError,'b-',[n100(1) n100(end)],[1 1],'r:',[n100(1) n100(end)],[-2 -2],'r:','LineWidth',2) + plot(n100,enerError,'b-',n100,enerErrorStored,'c-',[n100(1) n100(end)],[1 1]*aecmStructNew.varMean,'k--',[n100(1) n100(end)],[1 1],'r:',[n100(1) n100(end)],[-2 -2],'r:','LineWidth',2) + % Plot mu + %plot(n100,log2(aecmStructNew.muLog(n100)),'b-','LineWidth',2) + %plot(n100,log2(aecmStructNew.HGain(n100)),'b-',[n100(1) n100(end)],[1 1]*log2(sum(aecmStructNew.HStored)),'r:','LineWidth',2) + title(['Block ',int2str(setupStruct.currentBlock),' av ',int2str(setupStruct.updateno)]) + subplot(313) + %plot(n100,enerVar(n100),'b-',[n100(1) n100(end)],[1 1],'r:',[n100(1) n100(end)],[-2 -2],'r:','LineWidth',2) + %plot(n100,enerVar(n100),'b-','LineWidth',2) + % Plot correlation curve + + %plot(-25:25,aecmStructNew.delayStored/max(aecmStructNew.delayStored),'c-',-25:25,aecmStructNew.delayLatest/max(aecmStructNew.delayLatest),'r-',-25:25,(max(aecmStructNew.delayStoredS)-aecmStructNew.delayStoredS)/(max(aecmStructNew.delayStoredS)-min(aecmStructNew.delayStoredS)),'c:',-25:25,(max(aecmStructNew.delayLatestS)-aecmStructNew.delayLatestS)/(max(aecmStructNew.delayLatestS)-min(aecmStructNew.delayLatestS)),'r:','LineWidth',2) + %plot(-25:25,aecmStructNew.delayStored,'c-',-25:25,aecmStructNew.delayLatest,'r-',-25:25,(max(aecmStructNew.delayStoredS)-aecmStructNew.delayStoredS)/(max(aecmStructNew.delayStoredS)-min(aecmStructNew.delayStoredS)),'c:',-25:25,(max(aecmStructNew.delayLatestS)-aecmStructNew.delayLatestS)/(max(aecmStructNew.delayLatestS)-min(aecmStructNew.delayLatestS)),'r:','LineWidth',2) + %plot(-25:25,aecmStructNew.delayLatest,'r-',-25:25,(50-aecmStructNew.delayLatestS)/100,'r:','LineWidth',2) + plot(-25:25,aecmStructNew.delayLatestS,'r:','LineWidth',2) + %plot(-25:25,aecmStructNew.delayStored,'c-',-25:25,aecmStructNew.delayLatest,'r-','LineWidth',2) + plot(0:32,aecmStruct.HStored,'bo-','LineWidth',2) + %title(['\gamma | In = ',int2str(aecmStructNew.muStruct.countInInterval),' | Out High = ',int2str(aecmStructNew.muStruct.countOutHighInterval),' | Out Low = ',int2str(aecmStructNew.muStruct.countOutLowInterval)]) + pause(1) + %if ((setupStruct.currentBlock == 860) | (setupStruct.currentBlock == 420) | (setupStruct.currentBlock == 960)) + if 0%(setupStruct.currentBlock == 960) + figure(60) + plot(n100,aecmStructNew.enerNear(n100),'k--',n100,aecmStructNew.enerEcho(n100),'k:','LineWidth',2) + legend('Near End','Estimated Echo') + title('Signal Energy witH offset compensation') + figure(61) + subplot(211) + stem(sign(aecmStructNew.enerNear(n100)-mean(aecmStructNew.enerNear(n100)))) + title('Near End Energy Pattern (around mean value)') + subplot(212) + stem(sign(aecmStructNew.enerEcho(n100)-mean(aecmStructNew.enerEcho(n100)))) + title('Estimated Echo Energy Pattern (around mean value)') + pause + end + drawnow%,pause +elseif ~rem(setupStruct.currentBlock,100) + fprintf('Block %d of %d\n',setupStruct.currentBlock,setupStruct.updateno) +end diff --git a/src/modules/audio_processing/aecm/main/matlab/matlab/align.m b/src/modules/audio_processing/aecm/main/matlab/matlab/align.m new file mode 100644 index 0000000..9b9c0ba --- /dev/null +++ b/src/modules/audio_processing/aecm/main/matlab/matlab/align.m @@ -0,0 +1,98 @@ +function [delayStructNew] = align(xf, yf, delayStruct, i, trueDelay); + +%%%%%%% +% Bastiaan's algorithm copied +%%%%%%% +Ap500 = [1.00, -4.95, 9.801, -9.70299, 4.80298005, -0.9509900499]; +Bp500 = [0.662743088639636, -2.5841655608125, 3.77668102146288, -2.45182477425154, 0.596566274575251, 0.0]; +Ap200 = [1.00, -4.875, 9.50625, -9.26859375, 4.518439453125, -0.881095693359375]; +Bp200 = [0.862545460994275, -3.2832804496114, 4.67892032308828, -2.95798023879133, 0.699796870041299, 0.0]; + +oldMethod = 1; % Turn on or off the old method. The new one is Bastiaan's August 2008 updates +THReSHoLD = 2.0; % ADJUSTABLE threshold factor; 4.0 seems good +%%%%%%%%%%%%%%%%%%% +% use log domain (showed improved performance) +xxf = sqrt(real(xf.*conj(xf))+1e-20); +yyf = sqrt(real(yf.*conj(yf))+1e-20); +delayStruct.sxAll2(:,i) = 20*log10(xxf); +delayStruct.syAll2(:,i) = 20*log10(yyf); + +mD = min(i-1,delayStruct.maxDelayb); +if oldMethod + factor = 1.0; + histLenb = 250; + xthreshold = factor*median(delayStruct.sxAll2(:,i-mD:i),2); + ythreshold = factor*median(delayStruct.syAll2(:,i-mD:i),2); +else + xthreshold = sum(delayStruct.sxAll2(:,i-mD:i),2)/(delayStruct.maxDelayb+1); + + [yout, delayStruct.z200] = filter(Bp200, Ap200, delayStruct.syAll2(:,i), delayStruct.z200, 2); + yout = yout/(delayStruct.maxDelayb+1); + ythreshold = mean(delayStruct.syAll2(:,i-mD:i),2); + ythreshold = yout; +end + +delayStruct.bxspectrum(i) = getBspectrum(delayStruct.sxAll2(:,i), xthreshold, delayStruct.bandfirst, delayStruct.bandlast); +delayStruct.byspectrum(i) = getBspectrum(delayStruct.syAll2(:,i), ythreshold, delayStruct.bandfirst, delayStruct.bandlast); + +delayStruct.bxhist(end-mD:end) = delayStruct.bxspectrum(i-mD:i); + +delayStruct.bcount(:,i) = hisser2(delayStruct.byspectrum(i), flipud(delayStruct.bxhist), delayStruct.bandfirst, delayStruct.bandlast); +[delayStruct.fout(:,i), delayStruct.z500] = filter(Bp500, Ap500, delayStruct.bcount(:,i), delayStruct.z500, 2); +if oldMethod + %delayStruct.new(:,i) = sum(delayStruct.bcount(:,max(1,i-histLenb+1):i),2); % using the history range + tmpVec = [delayStruct.fout(1,i)*ones(2,1); delayStruct.fout(:,i); delayStruct.fout(end,i)*ones(2,1)]; % using the history range + tmpVec = filter(ones(1,5), 1, tmpVec); + delayStruct.new(:,i) = tmpVec(5:end); + %delayStruct.new(:,i) = delayStruct.fout(:,i); % using the history range +else + [delayStruct.fout(:,i), delayStruct.z500] = filter(Bp500, Ap500, delayStruct.bcount(:,i), delayStruct.z500, 2); + % NEW CODE + delayStruct.new(:,i) = filter([-1,-2,1,4,1,-2,-1], 1, delayStruct.fout(:,i)); %remv smth component + delayStruct.new(1:end-3,i) = delayStruct.new(1+3:end,i); + delayStruct.new(1:6,i) = 0.0; + delayStruct.new(end-6:end,i) = 0.0; % ends are no good +end +[valuen, tempdelay] = min(delayStruct.new(:,i)); % find minimum +if oldMethod + threshold = valuen + (max(delayStruct.new(:,i)) - valuen)/4; + thIndex = find(delayStruct.new(:,i) <= threshold); + if (i > 1) + delayDiff = abs(delayStruct.delay(i-1)-tempdelay+1); + if (delayStruct.oneGoodEstimate & (max(diff(thIndex)) > 1) & (delayDiff < 10)) + % We consider this minimum to be significant, hence update the delay + delayStruct.delay(i) = tempdelay; + elseif (~delayStruct.oneGoodEstimate & (max(diff(thIndex)) > 1)) + delayStruct.delay(i) = tempdelay; + if (i > histLenb) + delayStruct.oneGoodEstimate = 1; + end + else + delayStruct.delay(i) = delayStruct.delay(i-1); + end + else + delayStruct.delay(i) = tempdelay; + end +else + threshold = THReSHoLD*std(delayStruct.new(:,i)); % set updata threshold + if ((-valuen > threshold) | (i < delayStruct.smlength)) % see if you want to update delay + delayStruct.delay(i) = tempdelay; + else + delayStruct.delay(i) = delayStruct.delay(i-1); + end + % END NEW CODE +end +delayStructNew = delayStruct; + +% administrative and plotting stuff +if( 0) + figure(10); + plot([1:length(delayStructNew.new(:,i))],delayStructNew.new(:,i),trueDelay*[1 1],[min(delayStructNew.new(:,i)),max(delayStructNew.new(:,i))],'r',[1 length(delayStructNew.new(:,i))],threshold*[1 1],'r:', 'LineWidth',2); + %plot([1:length(delayStructNew.bcount(:,i))],delayStructNew.bcount(:,i),trueDelay*[1 1],[min(delayStructNew.bcount(:,i)),max(delayStructNew.bcount(:,i))],'r','LineWidth',2); + %plot([thedelay,thedelay],[min(fcount(:,i)),max(fcount(:,i))],'r'); + %title(sprintf('bin count and known delay at time %5.1f s\n',(i-1)*(support/(fs*oversampling)))); + title(delayStructNew.oneGoodEstimate) + xlabel('delay in frames'); + %hold off; + drawnow +end diff --git a/src/modules/audio_processing/aecm/main/matlab/matlab/calcFilterGain.m b/src/modules/audio_processing/aecm/main/matlab/matlab/calcFilterGain.m new file mode 100644 index 0000000..a09a7f2 --- /dev/null +++ b/src/modules/audio_processing/aecm/main/matlab/matlab/calcFilterGain.m @@ -0,0 +1,88 @@ +function [gam, cntIn2, cntOut2] = calcFilterGain(energy, dE, aecmStruct, t, T, cntIn, cntOut) + +defaultLevel = 1.2; +cntIn2 = cntIn; +cntOut2 = cntOut; +if (t < T) + gam = 1; +else + dE1 = -5; + dE2 = 1; + gamMid = 0.2; + gam = max(0,min((energy - aecmStruct.energyMin)/(aecmStruct.energyLevel - aecmStruct.energyMin), 1-(1-gamMid)*(aecmStruct.energyMax-energy)/(aecmStruct.energyMax-aecmStruct.energyLevel))); + + dEOffset = -0.5; + dEWidth = 1.5; + %gam2 = max(1,2-((dE-dEOffset)/(dE2-dEOffset)).^2); + gam2 = 1+(abs(dE-dEOffset)<(dE2-dEOffset)); + + gam = gam*gam2; + + + if (energy < aecmStruct.energyLevel) + gam = 0; + else + gam = defaultLevel; + end + dEVec = aecmStruct.enerNear(t-63:t)-aecmStruct.enerEcho(t-63:t); + %dEVec = aecmStruct.enerNear(t-20:t)-aecmStruct.enerEcho(t-20:t); + numCross = 0; + currentState = 0; + for ii=1:64 + if (currentState == 0) + currentState = (dEVec(ii) > dE2) - (dEVec(ii) < -2); + elseif ((currentState == 1) & (dEVec(ii) < -2)) + numCross = numCross + 1; + currentState = -1; + elseif ((currentState == -1) & (dEVec(ii) > dE2)) + numCross = numCross + 1; + currentState = 1; + end + end + gam = max(0, gam - numCross/25); + gam = 1; + + ener_A = 1; + ener_B = 0.8; + ener_C = aecmStruct.energyLevel + (aecmStruct.energyMax-aecmStruct.energyLevel)/5; + dE_A = 4;%2; + dE_B = 3.6;%1.8; + dE_C = 0.9*dEWidth; + dE_D = 1; + timeFactorLength = 10; + ddE = abs(dE-dEOffset); + if (energy < aecmStruct.energyLevel) + gam = 0; + else + gam = 1; + gam2 = max(0, min(ener_B*(energy-aecmStruct.energyLevel)/(ener_C-aecmStruct.energyLevel), ener_B+(ener_A-ener_B)*(energy-ener_C)/(aecmStruct.energyMax-ener_C))); + if (ddE < dEWidth) + % Update counters + cntIn2 = cntIn2 + 1; + if (cntIn2 > 2) + cntOut2 = 0; + end + gam3 = max(dE_D, min(dE_A-(dE_A-dE_B)*(ddE/dE_C), dE_D+(dE_B-dE_D)*(dEWidth-ddE)/(dEWidth-dE_C))); + gam3 = dE_A; + else + % Update counters + cntOut2 = cntOut2 + 1; + if (cntOut2 > 2) + cntIn2 = 0; + end + %gam2 = 1; + gam3 = dE_D; + end + timeFactor = min(1, cntIn2/timeFactorLength); + gam = gam*(1-timeFactor) + timeFactor*gam2*gam3; + end + %gam = gam/floor(numCross/2+1); +end +if isempty(gam) + numCross + timeFactor + cntIn2 + cntOut2 + gam2 + gam3 +end diff --git a/src/modules/audio_processing/aecm/main/matlab/matlab/calcStepSize.m b/src/modules/audio_processing/aecm/main/matlab/matlab/calcStepSize.m new file mode 100644 index 0000000..ae1365f --- /dev/null +++ b/src/modules/audio_processing/aecm/main/matlab/matlab/calcStepSize.m @@ -0,0 +1,105 @@ +function [mu, aecmStructNew] = calcStepSize(energy, dE, aecmStruct, t, logscale) + +if (nargin < 4) + t = 1; + logscale = 1; +elseif (nargin == 4) + logscale = 1; +end +T = aecmStruct.convLength; + +if logscale + currentMuMax = aecmStruct.MU_MIN + (aecmStruct.MU_MAX-aecmStruct.MU_MIN)*min(t,T)/T; + if (aecmStruct.energyMin >= aecmStruct.energyMax) + mu = aecmStruct.MU_MIN; + else + mu = (energy - aecmStruct.energyMin)/(aecmStruct.energyMax - aecmStruct.energyMin)*(currentMuMax-aecmStruct.MU_MIN) + aecmStruct.MU_MIN; + end + mu = 2^mu; + if (energy < aecmStruct.energyLevel) + mu = 0; + end +else + muMin = 0; + muMax = 0.5; + currentMuMax = muMin + (muMax-muMin)*min(t,T)/T; + if (aecmStruct.energyMin >= aecmStruct.energyMax) + mu = muMin; + else + mu = (energy - aecmStruct.energyMin)/(aecmStruct.energyMax - aecmStruct.energyMin)*(currentMuMax-muMin) + muMin; + end +end +dE2 = 1; +dEOffset = -0.5; +offBoost = 5; +if (mu > 0) + if (abs(dE-aecmStruct.ENERGY_DEV_OFFSET) > aecmStruct.ENERGY_DEV_TOL) + aecmStruct.muStruct.countInInterval = 0; + else + aecmStruct.muStruct.countInInterval = aecmStruct.muStruct.countInInterval + 1; + end + if (dE < aecmStruct.ENERGY_DEV_OFFSET - aecmStruct.ENERGY_DEV_TOL) + aecmStruct.muStruct.countOutLowInterval = aecmStruct.muStruct.countOutLowInterval + 1; + else + aecmStruct.muStruct.countOutLowInterval = 0; + end + if (dE > aecmStruct.ENERGY_DEV_OFFSET + aecmStruct.ENERGY_DEV_TOL) + aecmStruct.muStruct.countOutHighInterval = aecmStruct.muStruct.countOutHighInterval + 1; + else + aecmStruct.muStruct.countOutHighInterval = 0; + end +end +muVar = 2^min(-3,5/50*aecmStruct.muStruct.countInInterval-3); +muOff = 2^max(offBoost,min(0,offBoost*(aecmStruct.muStruct.countOutLowInterval-aecmStruct.muStruct.minOutLowInterval)/(aecmStruct.muStruct.maxOutLowInterval-aecmStruct.muStruct.minOutLowInterval))); + +muLow = 1/64; +muVar = 1; +if (t < 2*T) + muDT = 1; + muVar = 1; + mdEVec = 0; + numCross = 0; +else + muDT = min(1,max(muLow,1-(1-muLow)*(dE-aecmStruct.ENERGY_DEV_OFFSET)/aecmStruct.ENERGY_DEV_TOL)); + dEVec = aecmStruct.enerNear(t-63:t)-aecmStruct.enerEcho(t-63:t); + %dEVec = aecmStruct.enerNear(t-20:t)-aecmStruct.enerEcho(t-20:t); + numCross = 0; + currentState = 0; + for ii=1:64 + if (currentState == 0) + currentState = (dEVec(ii) > dE2) - (dEVec(ii) < -2); + elseif ((currentState == 1) & (dEVec(ii) < -2)) + numCross = numCross + 1; + currentState = -1; + elseif ((currentState == -1) & (dEVec(ii) > dE2)) + numCross = numCross + 1; + currentState = 1; + end + end + + %logicDEVec = (dEVec > dE2) - (dEVec < -2); + %numCross = sum(abs(diff(logicDEVec))); + %mdEVec = mean(abs(dEVec-dEOffset)); + %mdEVec = mean(abs(dEVec-mean(dEVec))); + %mdEVec = max(dEVec)-min(dEVec); + %if (mdEVec > 4)%1.5) + % muVar = 0; + %end + muVar = 2^(-floor(numCross/2)); + muVar = 2^(-numCross); +end +%muVar = 1; + + +% if (eStd > (dE2-dEOffset)) +% muVar = 1/8; +% else +% muVar = 1; +% end + +%mu = mu*muDT*muVar*muOff; +mu = mu*muDT*muVar; +mu = min(mu,0.25); +aecmStructNew = aecmStruct; +%aecmStructNew.varMean = mdEVec; +aecmStructNew.varMean = numCross; diff --git a/src/modules/audio_processing/aecm/main/matlab/matlab/fallerEstimator.m b/src/modules/audio_processing/aecm/main/matlab/matlab/fallerEstimator.m new file mode 100644 index 0000000..d038b51 --- /dev/null +++ b/src/modules/audio_processing/aecm/main/matlab/matlab/fallerEstimator.m @@ -0,0 +1,42 @@ +function [U, Hnew] = fallerEstimator(Y, X, H, mu) + +% Near end signal is stacked frame by frame columnwise in matrix Y and far end in X +% +% Possible estimation procedures are +% 1) LSE +% 2) NLMS +% 3) Separated numerator and denomerator filters +regParam = 1; +[numFreqs, numFrames] = size(Y); +[numFreqs, Q] = size(X); +U = zeros(numFreqs, 1); + +if ((nargin == 3) | (nargin == 5)) + dtd = 0; +end +if (nargin == 4) + dtd = H; +end +Emax = 7; +dEH = Emax-sum(sum(H)); +nu = 2*mu; +% if (nargin < 5) +% H = zeros(numFreqs, Q); +% for kk = 1:numFreqs +% Xmatrix = hankel(X(kk,1:Q),X(kk,Q:end)); +% y = Y(kk,1:end-Q+1)'; +% H(kk,:) = (y'*Xmatrix')*inv(Xmatrix*Xmatrix'+regParam); +% U(kk,1) = H(kk,:)*Xmatrix(:,1); +% end +% else + for kk = 1:numFreqs + x = X(kk,1:Q)'; + y = Y(kk,1); + Htmp = mu*(y-H(kk,:)*x)/(x'*x+regParam)*x; + %Htmp = (mu*(y-H(kk,:)*x)/(x'*x+regParam) - nu/dEH)*x; + H(kk,:) = H(kk,:) + Htmp'; + U(kk,1) = H(kk,:)*x; + end +% end + +Hnew = H; diff --git a/src/modules/audio_processing/aecm/main/matlab/matlab/getBspectrum.m b/src/modules/audio_processing/aecm/main/matlab/matlab/getBspectrum.m new file mode 100644 index 0000000..a4a533d --- /dev/null +++ b/src/modules/audio_processing/aecm/main/matlab/matlab/getBspectrum.m @@ -0,0 +1,22 @@ +function bspectrum=getBspectrum(ps,threshold,bandfirst,bandlast) +% function bspectrum=getBspectrum(ps,threshold,bandfirst,bandlast) +% compute binary spectrum using threshold spectrum as pivot +% bspectrum = binary spectrum (binary) +% ps=current power spectrum (float) +% threshold=threshold spectrum (float) +% bandfirst = first band considered +% bandlast = last band considered + +% initialization stuff + if( length(ps)32 | length(ps)~=length(threshold)) + error('BinDelayEst:spectrum:invalid','Dimensionality error'); +end + +% get current binary spectrum +diff = ps - threshold; +bspectrum=uint32(0); +for(i=bandfirst:bandlast) + if( diff(i)>0 ) + bspectrum = bitset(bspectrum,i); + end +end diff --git a/src/modules/audio_processing/aecm/main/matlab/matlab/hisser2.m b/src/modules/audio_processing/aecm/main/matlab/matlab/hisser2.m new file mode 100644 index 0000000..5a414f9 --- /dev/null +++ b/src/modules/audio_processing/aecm/main/matlab/matlab/hisser2.m @@ -0,0 +1,21 @@ +function bcount=hisser2(bs,bsr,bandfirst,bandlast) +% function bcount=hisser(bspectrum,bandfirst,bandlast) +% histogram for the binary spectra +% bcount= array of bit counts +% bs=binary spectrum (one int32 number each) +% bsr=reference binary spectra (one int32 number each) +% blockSize = histogram over blocksize blocks +% bandfirst = first band considered +% bandlast = last band considered + +% weight all delays equally +maxDelay = length(bsr); + +% compute counts (two methods; the first works better and is operational) +bcount=zeros(maxDelay,1); +for(i=1:maxDelay) + % the delay should have low count for low-near&high-far and high-near&low-far + bcount(i)= sum(bitget(bitxor(bs,bsr(i)),bandfirst:bandlast)); + % the delay should have low count for low-near&high-far (works less well) +% bcount(i)= sum(bitget(bitand(bsr(i),bitxor(bs,bsr(i))),bandfirst:bandlast)); +end diff --git a/src/modules/audio_processing/aecm/main/matlab/matlab/mainProgram.m b/src/modules/audio_processing/aecm/main/matlab/matlab/mainProgram.m new file mode 100644 index 0000000..eeb2aaa --- /dev/null +++ b/src/modules/audio_processing/aecm/main/matlab/matlab/mainProgram.m @@ -0,0 +1,283 @@ +useHTC = 1; % Set this if you want to run a single file and set file names below. Otherwise use simEnvironment to run from several scenarios in a row +delayCompensation_flag = 0; % Set this flag to one if you want to turn on the delay compensation/enhancement +global FARENDFFT; +global NEARENDFFT; +global F; + +if useHTC +% fid=fopen('./htcTouchHd/nb/aecFar.pcm'); xFar=fread(fid,'short'); fclose(fid); +% fid=fopen('./htcTouchHd/nb/aecNear.pcm'); yNear=fread(fid,'short'); fclose(fid); +% fid=fopen('./samsungBlackjack/nb/aecFar.pcm'); xFar=fread(fid,'short'); fclose(fid); +% fid=fopen('./samsungBlackjack/nb/aecNear.pcm'); yNear=fread(fid,'short'); fclose(fid); +% fid=fopen('aecFarPoor.pcm'); xFar=fread(fid,'short'); fclose(fid); +% fid=fopen('aecNearPoor.pcm'); yNear=fread(fid,'short'); fclose(fid); +% fid=fopen('out_aes.pcm'); outAES=fread(fid,'short'); fclose(fid); + fid=fopen('aecFar4.pcm'); xFar=fread(fid,'short'); fclose(fid); + fid=fopen('aecNear4.pcm'); yNear=fread(fid,'short'); fclose(fid); + yNearSpeech = zeros(size(xFar)); + fs = 8000; + frameSize = 64; +% frameSize = 128; + fs = 16000; +% frameSize = 256; +%F = load('fftValues.txt'); +%FARENDFFT = F(:,1:33); +%NEARENDFFT = F(:,34:66); + +else + loadFileFar = [speakerType, '_s_',scenario,'_far_b.wav']; + [xFar,fs,nbits] = wavread(loadFileFar); + xFar = xFar*2^(nbits-1); + loadFileNear = [speakerType, '_s_',scenario,'_near_b.wav']; + [yNear,fs,nbits] = wavread(loadFileNear); + yNear = yNear*2^(nbits-1); + loadFileNearSpeech = [speakerType, '_s_',scenario,'_nearSpeech_b.wav']; + [yNearSpeech,fs,nbits] = wavread(loadFileNearSpeech); + yNearSpeech = yNearSpeech*2^(nbits-1); + frameSize = 256; +end + +dtRegions = []; + +% General settings for the AECM +setupStruct = struct(... + 'stepSize_flag', 1,... % This flag turns on the step size calculation. If turned off, mu = 0.25. + 'supGain_flag', 0,... % This flag turns on the suppression gain calculation. If turned off, gam = 1. + 'channelUpdate_flag', 0,... % This flag turns on the channel update. If turned off, H is updated for convLength and then kept constant. + 'nlp_flag', 0,... % Turn on/off NLP + 'withVAD_flag', 0,... % Turn on/off NLP + 'useSubBand', 0,... % Set to 1 if to use subBands + 'useDelayEstimation', 1,... % Set to 1 if to use delay estimation + 'support', frameSize,... % # of samples per frame + 'samplingfreq',fs,... % Sampling frequency + 'oversampling', 2,... % Overlap between blocks/frames + 'updatel', 0,... % # of samples between blocks + 'hsupport1', 0,... % # of bins in frequency domain + 'factor', 0,... % synthesis window amplification + 'tlength', 0,... % # of samples of entire file + 'updateno', 0,... % # of updates + 'nb', 1,... % # of blocks + 'currentBlock', 0,... % + 'win', zeros(frameSize,1),...% Window to apply for fft and synthesis + 'avtime', 1,... % Time (in sec.) to perform averaging + 'estLen', 0,... % Averaging in # of blocks + 'A_GAIN', 10.0,... % + 'suppress_overdrive', 1.0,... % overdrive factor for suppression 1.4 is good + 'gamma_echo', 1.0,... % same as suppress_overdrive but at different place + 'de_echo_bound', 0.0,... % + 'nl_alpha', 0.4,... % memory; seems not very critical + 'nlSeverity', 0.2,... % nonlinearity severity: 0 does nothing; 1 suppresses all + 'numInBand', [],... % # of frequency bins in resp. subBand + 'centerFreq', [],... % Center frequency of resp. subBand + 'dtRegions', dtRegions,... % Regions where we have DT + 'subBandLength', frameSize/2);%All bins + %'subBandLength', 11); %Something's wrong when subBandLength even + %'nl_alpha', 0.8,... % memory; seems not very critical + +delayStruct = struct(... + 'bandfirst', 8,... + 'bandlast', 25,... + 'smlength', 600,... + 'maxDelay', 0.4,... + 'oneGoodEstimate', 0,... + 'delayAdjust', 0,... + 'maxDelayb', 0); +% More parameters in delayStruct are constructed in "updateSettings" below + +% Make struct settings +[setupStruct, delayStruct] = updateSettings(yNear, xFar, setupStruct, delayStruct); +setupStruct.numInBand = ones(setupStruct.hsupport1,1); + +Q = 1; % Time diversity in channel +% General settings for the step size calculation +muStruct = struct(... + 'countInInterval', 0,... + 'countOutHighInterval', 0,... + 'countOutLowInterval', 0,... + 'minInInterval', 50,... + 'minOutHighInterval', 10,... + 'minOutLowInterval', 10,... + 'maxOutLowInterval', 50); +% General settings for the AECM +aecmStruct = struct(... + 'plotIt', 0,... % Set to 0 to turn off plotting + 'useSubBand', 0,... + 'bandFactor', 1,... + 'H', zeros(setupStruct.subBandLength+1,Q),... + 'HStored', zeros(setupStruct.subBandLength+1,Q),... + 'X', zeros(setupStruct.subBandLength+1,Q),... + 'energyThres', 0.28,... + 'energyThresMSE', 0.4,... + 'energyMin', inf,... + 'energyMax', -inf,... + 'energyLevel', 0,... + 'energyLevelMSE', 0,... + 'convLength', 100,... + 'gammaLog', ones(setupStruct.updateno,1),... + 'muLog', ones(setupStruct.updateno,1),... + 'enerFar', zeros(setupStruct.updateno,1),... + 'enerNear', zeros(setupStruct.updateno,1),... + 'enerEcho', zeros(setupStruct.updateno,1),... + 'enerEchoStored', zeros(setupStruct.updateno,1),... + 'enerOut', zeros(setupStruct.updateno,1),... + 'runningfmean', 0,... + 'muStruct', muStruct,... + 'varMean', 0,... + 'countMseH', 0,... + 'mseHThreshold', 1.1,... + 'mseHStoredOld', inf,... + 'mseHLatestOld', inf,... + 'delayLatestS', zeros(1,51),... + 'feedbackDelay', 0,... + 'feedbackDelayUpdate', 0,... + 'cntIn', 0,... + 'cntOut', 0,... + 'FAR_ENERGY_MIN', 1,... + 'ENERGY_DEV_OFFSET', 0.5,... + 'ENERGY_DEV_TOL', 1.5,... + 'MU_MIN', -16,... + 'MU_MAX', -2,... + 'newDelayCurve', 0); + +% Adjust speech signals +xFar = [zeros(setupStruct.hsupport1-1,1);xFar(1:setupStruct.tlength)]; +yNear = [zeros(setupStruct.hsupport1-1,1);yNear(1:setupStruct.tlength)]; +yNearSpeech = [zeros(setupStruct.hsupport1-1,1);yNearSpeech(1:setupStruct.tlength)]; +xFar = xFar(1:setupStruct.tlength); +yNear = yNear(1:setupStruct.tlength); + +% Set figure settings +if aecmStruct.plotIt + figure(13) + set(gcf,'doublebuffer','on') +end +%%%%%%%%%% +% Here starts the algorithm +% Dividing into frames and then estimating the near end speech +%%%%%%%%%% +fTheFarEnd = complex(zeros(setupStruct.hsupport1,1)); +afTheFarEnd = zeros(setupStruct.hsupport1,setupStruct.updateno+1); +fFar = zeros(setupStruct.hsupport1,setupStruct.updateno+1); +fmicrophone = complex(zeros(setupStruct.hsupport1,1)); +afmicrophone = zeros(setupStruct.hsupport1,setupStruct.updateno+1); +fNear = zeros(setupStruct.hsupport1,setupStruct.updateno+1); +femicrophone = complex(zeros(setupStruct.hsupport1,1)); +emicrophone = zeros(setupStruct.tlength,1); + +if (setupStruct.useDelayEstimation == 2) + delSamples = [1641 1895 2032 1895 2311 2000 2350 2222 NaN 2332 2330 2290 2401 2415 NaN 2393 2305 2381 2398]; + delBlocks = round(delSamples/setupStruct.updatel); + delStarts = floor([25138 46844 105991 169901 195739 218536 241803 333905 347703 362660 373753 745135 765887 788078 806257 823835 842443 860139 881869]/setupStruct.updatel); +else + delStarts = []; +end + +for i=1:setupStruct.updateno + setupStruct.currentBlock = i; + + sb = (i-1)*setupStruct.updatel + 1; + se = sb + setupStruct.support - 1; + + %%%%%%% + % Analysis FFTs + %%%%%%% + % Far end signal + temp = fft(setupStruct.win .* xFar(sb:se))/frameSize; + fTheFarEnd = temp(1:setupStruct.hsupport1); + afTheFarEnd(:,i) = abs(fTheFarEnd); + fFar(:,i) = fTheFarEnd; + % Near end signal + temp = fft(setupStruct.win .* yNear(sb:se))/frameSize;%,pause + fmicrophone = temp(1:setupStruct.hsupport1); + afmicrophone(:,i) = abs(fmicrophone); + fNear(:,i) = fmicrophone; + %abs(fmicrophone),pause + % The true near end speaker (if we have such info) + temp = fft(setupStruct.win .* yNearSpeech(sb:se)); + aftrueSpeech = abs(temp(1:setupStruct.hsupport1)); + + if(i == 1000) + %break; + end + + % Perform delay estimation + if (setupStruct.useDelayEstimation == 1) + % Delay Estimation + delayStruct = align(fTheFarEnd, fmicrophone, delayStruct, i); + %delayStruct.delay(i) = 39;%19; + idel = max(i - delayStruct.delay(i) + 1,1); + + if delayCompensation_flag + % If we have a new delay estimate from Bastiaan's alg. update the offset + if (delayStruct.delay(i) ~= delayStruct.delay(max(1,i-1))) + delayStruct.delayAdjust = delayStruct.delayAdjust + delayStruct.delay(i) - delayStruct.delay(i-1); + end + % Store the compensated delay + delayStruct.delayNew(i) = delayStruct.delay(i) - delayStruct.delayAdjust; + if (delayStruct.delayNew(i) < 1) + % Something's wrong + pause,break + end + % Compensate with the offset estimate + idel = idel + delayStruct.delayAdjust; + end + if 0%aecmStruct.plotIt + figure(1) + plot(1:i,delayStruct.delay(1:i),'k:',1:i,delayStruct.delayNew(1:i),'k--','LineWidth',2),drawnow + end + elseif (setupStruct.useDelayEstimation == 2) + % Use "manual delay" + delIndex = find(delStarts=xk(kk))); + else + numInBand(kk) = length(intersect(find(xh>=xk(kk)),find(xh=2 + if ischar(whichbar) + type=2; %we are initializing + name=whichbar; + elseif isnumeric(whichbar) + type=1; %we are updating, given a handle + f=whichbar; + else + error(['Input arguments of type ' class(whichbar) ' not valid.']) + end +elseif nargin==1 + f = findobj(allchild(0),'flat','Tag','TMWWaitbar'); + + if isempty(f) + type=2; + name='Waitbar'; + else + type=1; + f=f(1); + end +else + error('Input arguments not valid.'); +end + +x = max(0,min(100*x,100)); + +switch type + case 1, % waitbar(x) update + p = findobj(f,'Type','patch'); + l = findobj(f,'Type','line'); + if isempty(f) | isempty(p) | isempty(l), + error('Couldn''t find waitbar handles.'); + end + xpatch = get(p,'XData'); + xpatch = [0 x x 0]; + set(p,'XData',xpatch) + xline = get(l,'XData'); + set(l,'XData',xline); + + if nargin>2, + % Update waitbar title: + hAxes = findobj(f,'type','axes'); + hTitle = get(hAxes,'title'); + set(hTitle,'string',varargin{1}); + end + + case 2, % waitbar(x,name) initialize + vertMargin = 0; + if nargin > 2, + % we have optional arguments: property-value pairs + if rem (nargin, 2 ) ~= 0 + error( 'Optional initialization arguments must be passed in pairs' ); + end + end + + oldRootUnits = get(0,'Units'); + + set(0, 'Units', 'points'); + screenSize = get(0,'ScreenSize'); + + axFontSize=get(0,'FactoryAxesFontSize'); + + pointsPerPixel = 72/get(0,'ScreenPixelsPerInch'); + + width = 360 * pointsPerPixel; + height = 75 * pointsPerPixel; + pos = [screenSize(3)/2-width/2 screenSize(4)/2-height/2 width height]; + +%pos= [501.75 589.5 393.75 52.5]; + f = figure(... + 'Units', 'points', ... + 'BusyAction', 'queue', ... + 'Position', pos, ... + 'Resize','on', ... + 'CreateFcn','', ... + 'NumberTitle','off', ... + 'IntegerHandle','off', ... + 'MenuBar', 'none', ... + 'Tag','TMWWaitbar',... + 'Interruptible', 'off', ... + 'Visible','on'); + + %%%%%%%%%%%%%%%%%%%%% + % set figure properties as passed to the fcn + % pay special attention to the 'cancel' request + %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% + if nargin > 2, + propList = varargin(1:2:end); + valueList = varargin(2:2:end); + cancelBtnCreated = 0; + for ii = 1:length( propList ) + try + if strcmp(lower(propList{ii}), 'createcancelbtn' ) & ~cancelBtnCreated + cancelBtnHeight = 23 * pointsPerPixel; + cancelBtnWidth = 60 * pointsPerPixel; + newPos = pos; + vertMargin = vertMargin + cancelBtnHeight; + newPos(4) = newPos(4)+vertMargin; + callbackFcn = [valueList{ii}]; + set( f, 'Position', newPos, 'CloseRequestFcn', callbackFcn ); + cancelButt = uicontrol('Parent',f, ... + 'Units','points', ... + 'Callback',callbackFcn, ... + 'ButtonDownFcn', callbackFcn, ... + 'Enable','on', ... + 'Interruptible','off', ... + 'Position', [pos(3)-cancelBtnWidth*1.4, 7, ... + cancelBtnWidth, cancelBtnHeight], ... + 'String','Cancel', ... + 'Tag','TMWWaitbarCancelButton'); + cancelBtnCreated = 1; + else + % simply set the prop/value pair of the figure + set( f, propList{ii}, valueList{ii}); + end + catch + disp ( ['Warning: could not set property ''' propList{ii} ''' with value ''' num2str(valueList{ii}) '''' ] ); + end + end + end + + %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% + + + colormap([]); + + axNorm=[.05 .3 .9 .2]; + % axNorm=[1 1 1 1]; + axPos=axNorm.*[pos(3:4),pos(3:4)] + [0 vertMargin 0 0]; + + h = axes('XLim',[0 100],... + 'YLim',[0 1],... + 'Box','on', ... + 'Units','Points',... + 'FontSize', axFontSize,... + 'Position',axPos,... + 'XTickMode','manual',... + 'YTickMode','manual',... + 'XTick',[],... + 'YTick',[],... + 'XTickLabelMode','manual',... + 'XTickLabel',[],... + 'YTickLabelMode','manual',... + 'YTickLabel',[]); + + tHandle=title(name); + tHandle=get(h,'title'); + oldTitleUnits=get(tHandle,'Units'); + set(tHandle,... + 'Units', 'points',... + 'String', name); + + tExtent=get(tHandle,'Extent'); + set(tHandle,'Units',oldTitleUnits); + + titleHeight=tExtent(4)+axPos(2)+axPos(4)+5; + if titleHeight>pos(4) + pos(4)=titleHeight; + pos(2)=screenSize(4)/2-pos(4)/2; + figPosDirty=logical(1); + else + figPosDirty=logical(0); + end + + if tExtent(3)>pos(3)*1.10; + pos(3)=min(tExtent(3)*1.10,screenSize(3)); + pos(1)=screenSize(3)/2-pos(3)/2; + + axPos([1,3])=axNorm([1,3])*pos(3); + set(h,'Position',axPos); + + figPosDirty=logical(1); + end + + if figPosDirty + set(f,'Position',pos); + end + + xpatch = [0 x x 0]; + ypatch = [0 0 1 1]; + xline = [100 0 0 100 100]; + yline = [0 0 1 1 0]; + + p = patch(xpatch,ypatch,'r','EdgeColor','r','EraseMode','none'); + l = line(xline,yline,'EraseMode','none'); + set(l,'Color',get(gca,'XColor')); + + + set(f,'HandleVisibility','callback','visible','on', 'resize','off'); + + set(0, 'Units', oldRootUnits); +end % case +drawnow; + +if nargout==1, + fout = f; +end diff --git a/src/modules/audio_processing/aecm/main/source/aecm.gypi b/src/modules/audio_processing/aecm/main/source/aecm.gypi new file mode 100644 index 0000000..3c63c52 --- /dev/null +++ b/src/modules/audio_processing/aecm/main/source/aecm.gypi @@ -0,0 +1,42 @@ +# Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. +# +# Use of this source code is governed by a BSD-style license +# that can be found in the LICENSE file in the root of the source +# tree. An additional intellectual property rights grant can be found +# in the file PATENTS. All contributing project authors may +# be found in the AUTHORS file in the root of the source tree. + +{ + 'targets': [ + { + 'target_name': 'aecm', + 'type': '<(library)', + 'dependencies': [ + '<(webrtc_root)/common_audio/common_audio.gyp:spl', + 'apm_util' + ], + 'include_dirs': [ + '../interface', + ], + 'direct_dependent_settings': { + 'include_dirs': [ + '../interface', + ], + }, + 'sources': [ + '../interface/echo_control_mobile.h', + 'echo_control_mobile.c', + 'aecm_core.c', + 'aecm_core.h', + 'aecm_delay_estimator.c', + 'aecm_delay_estimator.h', + ], + }, + ], +} + +# Local Variables: +# tab-width:2 +# indent-tabs-mode:nil +# End: +# vim: set expandtab tabstop=2 shiftwidth=2: diff --git a/src/modules/audio_processing/aecm/main/source/aecm_core.c b/src/modules/audio_processing/aecm/main/source/aecm_core.c new file mode 100644 index 0000000..b7dae90 --- /dev/null +++ b/src/modules/audio_processing/aecm/main/source/aecm_core.c @@ -0,0 +1,1926 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +#include "aecm_core.h" + +#include +#include + +#include "aecm_delay_estimator.h" +#include "echo_control_mobile.h" +#include "ring_buffer.h" +#include "typedefs.h" + +#ifdef ARM_WINM_LOG +#include +#include +#endif + +#ifdef AEC_DEBUG +FILE *dfile; +FILE *testfile; +#endif + +#ifdef _MSC_VER // visual c++ +#define ALIGN8_BEG __declspec(align(8)) +#define ALIGN8_END +#else // gcc or icc +#define ALIGN8_BEG +#define ALIGN8_END __attribute__((aligned(8))) +#endif + +#ifdef AECM_SHORT + +// Square root of Hanning window in Q14 +const WebRtc_Word16 WebRtcAecm_kSqrtHanning[] = +{ + 0, 804, 1606, 2404, 3196, 3981, 4756, 5520, + 6270, 7005, 7723, 8423, 9102, 9760, 10394, 11003, + 11585, 12140, 12665, 13160, 13623, 14053, 14449, 14811, + 15137, 15426, 15679, 15893, 16069, 16207, 16305, 16364, + 16384 +}; + +#else + +// Square root of Hanning window in Q14 +const ALIGN8_BEG WebRtc_Word16 WebRtcAecm_kSqrtHanning[] ALIGN8_END = +{ + 0, 399, 798, 1196, 1594, 1990, 2386, 2780, 3172, + 3562, 3951, 4337, 4720, 5101, 5478, 5853, 6224, 6591, 6954, 7313, 7668, 8019, 8364, + 8705, 9040, 9370, 9695, 10013, 10326, 10633, 10933, 11227, 11514, 11795, 12068, 12335, + 12594, 12845, 13089, 13325, 13553, 13773, 13985, 14189, 14384, 14571, 14749, 14918, + 15079, 15231, 15373, 15506, 15631, 15746, 15851, 15947, 16034, 16111, 16179, 16237, + 16286, 16325, 16354, 16373, 16384 +}; + +#endif + +//Q15 alpha = 0.99439986968132 const Factor for magnitude approximation +static const WebRtc_UWord16 kAlpha1 = 32584; +//Q15 beta = 0.12967166976970 const Factor for magnitude approximation +static const WebRtc_UWord16 kBeta1 = 4249; +//Q15 alpha = 0.94234827210087 const Factor for magnitude approximation +static const WebRtc_UWord16 kAlpha2 = 30879; +//Q15 beta = 0.33787806009150 const Factor for magnitude approximation +static const WebRtc_UWord16 kBeta2 = 11072; +//Q15 alpha = 0.82247698684306 const Factor for magnitude approximation +static const WebRtc_UWord16 kAlpha3 = 26951; +//Q15 beta = 0.57762063060713 const Factor for magnitude approximation +static const WebRtc_UWord16 kBeta3 = 18927; + +// Initialization table for echo channel in 8 kHz +static const WebRtc_Word16 kChannelStored8kHz[PART_LEN1] = { + 2040, 1815, 1590, 1498, 1405, 1395, 1385, 1418, + 1451, 1506, 1562, 1644, 1726, 1804, 1882, 1918, + 1953, 1982, 2010, 2025, 2040, 2034, 2027, 2021, + 2014, 1997, 1980, 1925, 1869, 1800, 1732, 1683, + 1635, 1604, 1572, 1545, 1517, 1481, 1444, 1405, + 1367, 1331, 1294, 1270, 1245, 1239, 1233, 1247, + 1260, 1282, 1303, 1338, 1373, 1407, 1441, 1470, + 1499, 1524, 1549, 1565, 1582, 1601, 1621, 1649, + 1676 +}; + +// Initialization table for echo channel in 16 kHz +static const WebRtc_Word16 kChannelStored16kHz[PART_LEN1] = { + 2040, 1590, 1405, 1385, 1451, 1562, 1726, 1882, + 1953, 2010, 2040, 2027, 2014, 1980, 1869, 1732, + 1635, 1572, 1517, 1444, 1367, 1294, 1245, 1233, + 1260, 1303, 1373, 1441, 1499, 1549, 1582, 1621, + 1676, 1741, 1802, 1861, 1921, 1983, 2040, 2102, + 2170, 2265, 2375, 2515, 2651, 2781, 2922, 3075, + 3253, 3471, 3738, 3976, 4151, 4258, 4308, 4288, + 4270, 4253, 4237, 4179, 4086, 3947, 3757, 3484, + 3153 +}; + +static const WebRtc_Word16 kNoiseEstQDomain = 15; +static const WebRtc_Word16 kNoiseEstIncCount = 5; + +static void ComfortNoise(AecmCore_t* aecm, + const WebRtc_UWord16* dfa, + complex16_t* out, + const WebRtc_Word16* lambda); + +static WebRtc_Word16 CalcSuppressionGain(AecmCore_t * const aecm); + +#ifdef ARM_WINM_LOG +HANDLE logFile = NULL; +#endif + +int WebRtcAecm_CreateCore(AecmCore_t **aecmInst) +{ + AecmCore_t *aecm = malloc(sizeof(AecmCore_t)); + *aecmInst = aecm; + if (aecm == NULL) + { + return -1; + } + + if (WebRtcApm_CreateBuffer(&aecm->farFrameBuf, FRAME_LEN + PART_LEN) == -1) + { + WebRtcAecm_FreeCore(aecm); + aecm = NULL; + return -1; + } + + if (WebRtcApm_CreateBuffer(&aecm->nearNoisyFrameBuf, FRAME_LEN + PART_LEN) == -1) + { + WebRtcAecm_FreeCore(aecm); + aecm = NULL; + return -1; + } + + if (WebRtcApm_CreateBuffer(&aecm->nearCleanFrameBuf, FRAME_LEN + PART_LEN) == -1) + { + WebRtcAecm_FreeCore(aecm); + aecm = NULL; + return -1; + } + + if (WebRtcApm_CreateBuffer(&aecm->outFrameBuf, FRAME_LEN + PART_LEN) == -1) + { + WebRtcAecm_FreeCore(aecm); + aecm = NULL; + return -1; + } + + if (WebRtcAecm_CreateDelayEstimator(&aecm->delay_estimator, PART_LEN1, MAX_DELAY) == -1) + { + WebRtcAecm_FreeCore(aecm); + aecm = NULL; + return -1; + } + + // Init some aecm pointers. 16 and 32 byte alignment is only necessary + // for Neon code currently. + aecm->xBuf = (WebRtc_Word16*) (((uintptr_t)aecm->xBuf_buf + 31) & ~ 31); + aecm->dBufClean = (WebRtc_Word16*) (((uintptr_t)aecm->dBufClean_buf + 31) & ~ 31); + aecm->dBufNoisy = (WebRtc_Word16*) (((uintptr_t)aecm->dBufNoisy_buf + 31) & ~ 31); + aecm->outBuf = (WebRtc_Word16*) (((uintptr_t)aecm->outBuf_buf + 15) & ~ 15); + aecm->channelStored = (WebRtc_Word16*) (((uintptr_t) + aecm->channelStored_buf + 15) & ~ 15); + aecm->channelAdapt16 = (WebRtc_Word16*) (((uintptr_t) + aecm->channelAdapt16_buf + 15) & ~ 15); + aecm->channelAdapt32 = (WebRtc_Word32*) (((uintptr_t) + aecm->channelAdapt32_buf + 31) & ~ 31); + + return 0; +} + +void WebRtcAecm_InitEchoPathCore(AecmCore_t* aecm, const WebRtc_Word16* echo_path) +{ + int i = 0; + + // Reset the stored channel + memcpy(aecm->channelStored, echo_path, sizeof(WebRtc_Word16) * PART_LEN1); + // Reset the adapted channels + memcpy(aecm->channelAdapt16, echo_path, sizeof(WebRtc_Word16) * PART_LEN1); + for (i = 0; i < PART_LEN1; i++) + { + aecm->channelAdapt32[i] = WEBRTC_SPL_LSHIFT_W32( + (WebRtc_Word32)(aecm->channelAdapt16[i]), 16); + } + + // Reset channel storing variables + aecm->mseAdaptOld = 1000; + aecm->mseStoredOld = 1000; + aecm->mseThreshold = WEBRTC_SPL_WORD32_MAX; + aecm->mseChannelCount = 0; +} + +// WebRtcAecm_InitCore(...) +// +// This function initializes the AECM instant created with WebRtcAecm_CreateCore(...) +// Input: +// - aecm : Pointer to the Echo Suppression instance +// - samplingFreq : Sampling Frequency +// +// Output: +// - aecm : Initialized instance +// +// Return value : 0 - Ok +// -1 - Error +// +int WebRtcAecm_InitCore(AecmCore_t * const aecm, int samplingFreq) +{ + int i = 0; + WebRtc_Word32 tmp32 = PART_LEN1 * PART_LEN1; + WebRtc_Word16 tmp16 = PART_LEN1; + + if (samplingFreq != 8000 && samplingFreq != 16000) + { + samplingFreq = 8000; + return -1; + } + // sanity check of sampling frequency + aecm->mult = (WebRtc_Word16)samplingFreq / 8000; + + aecm->farBufWritePos = 0; + aecm->farBufReadPos = 0; + aecm->knownDelay = 0; + aecm->lastKnownDelay = 0; + + WebRtcApm_InitBuffer(aecm->farFrameBuf); + WebRtcApm_InitBuffer(aecm->nearNoisyFrameBuf); + WebRtcApm_InitBuffer(aecm->nearCleanFrameBuf); + WebRtcApm_InitBuffer(aecm->outFrameBuf); + + memset(aecm->xBuf_buf, 0, sizeof(aecm->xBuf_buf)); + memset(aecm->dBufClean_buf, 0, sizeof(aecm->dBufClean_buf)); + memset(aecm->dBufNoisy_buf, 0, sizeof(aecm->dBufNoisy_buf)); + memset(aecm->outBuf_buf, 0, sizeof(aecm->outBuf_buf)); + + aecm->seed = 666; + aecm->totCount = 0; + + if (WebRtcAecm_InitDelayEstimator(aecm->delay_estimator) != 0) + { + return -1; + } + + // Initialize to reasonable values + aecm->currentDelay = 8; + + aecm->nlpFlag = 1; + aecm->fixedDelay = -1; + + aecm->dfaCleanQDomain = 0; + aecm->dfaCleanQDomainOld = 0; + aecm->dfaNoisyQDomain = 0; + aecm->dfaNoisyQDomainOld = 0; + + memset(aecm->nearLogEnergy, 0, sizeof(aecm->nearLogEnergy)); + aecm->farLogEnergy = 0; + memset(aecm->echoAdaptLogEnergy, 0, sizeof(aecm->echoAdaptLogEnergy)); + memset(aecm->echoStoredLogEnergy, 0, sizeof(aecm->echoStoredLogEnergy)); + + // Initialize the echo channels with a stored shape. + if (samplingFreq == 8000) + { + WebRtcAecm_InitEchoPathCore(aecm, kChannelStored8kHz); + } + else + { + WebRtcAecm_InitEchoPathCore(aecm, kChannelStored16kHz); + } + + memset(aecm->echoFilt, 0, sizeof(aecm->echoFilt)); + memset(aecm->nearFilt, 0, sizeof(aecm->nearFilt)); + aecm->noiseEstCtr = 0; + + aecm->cngMode = AecmTrue; + + memset(aecm->noiseEstTooLowCtr, 0, sizeof(aecm->noiseEstTooLowCtr)); + memset(aecm->noiseEstTooHighCtr, 0, sizeof(aecm->noiseEstTooHighCtr)); + // Shape the initial noise level to an approximate pink noise. + for (i = 0; i < (PART_LEN1 >> 1) - 1; i++) + { + aecm->noiseEst[i] = (tmp32 << 8); + tmp16--; + tmp32 -= (WebRtc_Word32)((tmp16 << 1) + 1); + } + for (; i < PART_LEN1; i++) + { + aecm->noiseEst[i] = (tmp32 << 8); + } + + aecm->farEnergyMin = WEBRTC_SPL_WORD16_MAX; + aecm->farEnergyMax = WEBRTC_SPL_WORD16_MIN; + aecm->farEnergyMaxMin = 0; + aecm->farEnergyVAD = FAR_ENERGY_MIN; // This prevents false speech detection at the + // beginning. + aecm->farEnergyMSE = 0; + aecm->currentVADValue = 0; + aecm->vadUpdateCount = 0; + aecm->firstVAD = 1; + + aecm->startupState = 0; + aecm->supGain = SUPGAIN_DEFAULT; + aecm->supGainOld = SUPGAIN_DEFAULT; + + aecm->supGainErrParamA = SUPGAIN_ERROR_PARAM_A; + aecm->supGainErrParamD = SUPGAIN_ERROR_PARAM_D; + aecm->supGainErrParamDiffAB = SUPGAIN_ERROR_PARAM_A - SUPGAIN_ERROR_PARAM_B; + aecm->supGainErrParamDiffBD = SUPGAIN_ERROR_PARAM_B - SUPGAIN_ERROR_PARAM_D; + + assert(PART_LEN % 16 == 0); + + return 0; +} + +// TODO(bjornv): This function is currently not used. Add support for these +// parameters from a higher level +int WebRtcAecm_Control(AecmCore_t *aecm, int delay, int nlpFlag) +{ + aecm->nlpFlag = nlpFlag; + aecm->fixedDelay = delay; + + return 0; +} + +int WebRtcAecm_FreeCore(AecmCore_t *aecm) +{ + if (aecm == NULL) + { + return -1; + } + + WebRtcApm_FreeBuffer(aecm->farFrameBuf); + WebRtcApm_FreeBuffer(aecm->nearNoisyFrameBuf); + WebRtcApm_FreeBuffer(aecm->nearCleanFrameBuf); + WebRtcApm_FreeBuffer(aecm->outFrameBuf); + + WebRtcAecm_FreeDelayEstimator(aecm->delay_estimator); + free(aecm); + + return 0; +} + +int WebRtcAecm_ProcessFrame(AecmCore_t * aecm, + const WebRtc_Word16 * farend, + const WebRtc_Word16 * nearendNoisy, + const WebRtc_Word16 * nearendClean, + WebRtc_Word16 * out) +{ + WebRtc_Word16 farBlock[PART_LEN]; + WebRtc_Word16 nearNoisyBlock[PART_LEN]; + WebRtc_Word16 nearCleanBlock[PART_LEN]; + WebRtc_Word16 outBlock_buf[PART_LEN + 8]; // Align buffer to 8-byte boundary. + WebRtc_Word16* outBlock = (WebRtc_Word16*) (((uintptr_t) outBlock_buf + 15) & ~ 15); + + WebRtc_Word16 farFrame[FRAME_LEN]; + int size = 0; + + // Buffer the current frame. + // Fetch an older one corresponding to the delay. + WebRtcAecm_BufferFarFrame(aecm, farend, FRAME_LEN); + WebRtcAecm_FetchFarFrame(aecm, farFrame, FRAME_LEN, aecm->knownDelay); + + // Buffer the synchronized far and near frames, + // to pass the smaller blocks individually. + WebRtcApm_WriteBuffer(aecm->farFrameBuf, farFrame, FRAME_LEN); + WebRtcApm_WriteBuffer(aecm->nearNoisyFrameBuf, nearendNoisy, FRAME_LEN); + if (nearendClean != NULL) + { + WebRtcApm_WriteBuffer(aecm->nearCleanFrameBuf, nearendClean, FRAME_LEN); + } + + // Process as many blocks as possible. + while (WebRtcApm_get_buffer_size(aecm->farFrameBuf) >= PART_LEN) + { + WebRtcApm_ReadBuffer(aecm->farFrameBuf, farBlock, PART_LEN); + WebRtcApm_ReadBuffer(aecm->nearNoisyFrameBuf, nearNoisyBlock, PART_LEN); + if (nearendClean != NULL) + { + WebRtcApm_ReadBuffer(aecm->nearCleanFrameBuf, nearCleanBlock, PART_LEN); + if (WebRtcAecm_ProcessBlock(aecm, + farBlock, + nearNoisyBlock, + nearCleanBlock, + outBlock) == -1) + { + return -1; + } + } else + { + if (WebRtcAecm_ProcessBlock(aecm, + farBlock, + nearNoisyBlock, + NULL, + outBlock) == -1) + { + return -1; + } + } + + WebRtcApm_WriteBuffer(aecm->outFrameBuf, outBlock, PART_LEN); + } + + // Stuff the out buffer if we have less than a frame to output. + // This should only happen for the first frame. + size = WebRtcApm_get_buffer_size(aecm->outFrameBuf); + if (size < FRAME_LEN) + { + WebRtcApm_StuffBuffer(aecm->outFrameBuf, FRAME_LEN - size); + } + + // Obtain an output frame. + WebRtcApm_ReadBuffer(aecm->outFrameBuf, out, FRAME_LEN); + + return 0; +} + +// WebRtcAecm_AsymFilt(...) +// +// Performs asymmetric filtering. +// +// Inputs: +// - filtOld : Previous filtered value. +// - inVal : New input value. +// - stepSizePos : Step size when we have a positive contribution. +// - stepSizeNeg : Step size when we have a negative contribution. +// +// Output: +// +// Return: - Filtered value. +// +WebRtc_Word16 WebRtcAecm_AsymFilt(const WebRtc_Word16 filtOld, const WebRtc_Word16 inVal, + const WebRtc_Word16 stepSizePos, + const WebRtc_Word16 stepSizeNeg) +{ + WebRtc_Word16 retVal; + + if ((filtOld == WEBRTC_SPL_WORD16_MAX) | (filtOld == WEBRTC_SPL_WORD16_MIN)) + { + return inVal; + } + retVal = filtOld; + if (filtOld > inVal) + { + retVal -= WEBRTC_SPL_RSHIFT_W16(filtOld - inVal, stepSizeNeg); + } else + { + retVal += WEBRTC_SPL_RSHIFT_W16(inVal - filtOld, stepSizePos); + } + + return retVal; +} + +// WebRtcAecm_CalcEnergies(...) +// +// This function calculates the log of energies for nearend, farend and estimated +// echoes. There is also an update of energy decision levels, i.e. internal VAD. +// +// +// @param aecm [i/o] Handle of the AECM instance. +// @param far_spectrum [in] Pointer to farend spectrum. +// @param far_q [in] Q-domain of farend spectrum. +// @param nearEner [in] Near end energy for current block in +// Q(aecm->dfaQDomain). +// @param echoEst [out] Estimated echo in Q(xfa_q+RESOLUTION_CHANNEL16). +// +void WebRtcAecm_CalcEnergies(AecmCore_t * aecm, + const WebRtc_UWord16* far_spectrum, + const WebRtc_Word16 far_q, + const WebRtc_UWord32 nearEner, + WebRtc_Word32 * echoEst) +{ + // Local variables + WebRtc_UWord32 tmpAdapt = 0; + WebRtc_UWord32 tmpStored = 0; + WebRtc_UWord32 tmpFar = 0; + + int i; + + WebRtc_Word16 zeros, frac; + WebRtc_Word16 tmp16; + WebRtc_Word16 increase_max_shifts = 4; + WebRtc_Word16 decrease_max_shifts = 11; + WebRtc_Word16 increase_min_shifts = 11; + WebRtc_Word16 decrease_min_shifts = 3; + WebRtc_Word16 kLogLowValue = WEBRTC_SPL_LSHIFT_W16(PART_LEN_SHIFT, 7); + + // Get log of near end energy and store in buffer + + // Shift buffer + memmove(aecm->nearLogEnergy + 1, aecm->nearLogEnergy, + sizeof(WebRtc_Word16) * (MAX_BUF_LEN - 1)); + + // Logarithm of integrated magnitude spectrum (nearEner) + tmp16 = kLogLowValue; + if (nearEner) + { + zeros = WebRtcSpl_NormU32(nearEner); + frac = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_U32( + (WEBRTC_SPL_LSHIFT_U32(nearEner, zeros) & 0x7FFFFFFF), + 23); + // log2 in Q8 + tmp16 += WEBRTC_SPL_LSHIFT_W16((31 - zeros), 8) + frac; + tmp16 -= WEBRTC_SPL_LSHIFT_W16(aecm->dfaNoisyQDomain, 8); + } + aecm->nearLogEnergy[0] = tmp16; + // END: Get log of near end energy + + WebRtcAecm_CalcLinearEnergies(aecm, far_spectrum, echoEst, &tmpFar, &tmpAdapt, &tmpStored); + + // Shift buffers + memmove(aecm->echoAdaptLogEnergy + 1, aecm->echoAdaptLogEnergy, + sizeof(WebRtc_Word16) * (MAX_BUF_LEN - 1)); + memmove(aecm->echoStoredLogEnergy + 1, aecm->echoStoredLogEnergy, + sizeof(WebRtc_Word16) * (MAX_BUF_LEN - 1)); + + // Logarithm of delayed far end energy + tmp16 = kLogLowValue; + if (tmpFar) + { + zeros = WebRtcSpl_NormU32(tmpFar); + frac = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_U32((WEBRTC_SPL_LSHIFT_U32(tmpFar, zeros) + & 0x7FFFFFFF), 23); + // log2 in Q8 + tmp16 += WEBRTC_SPL_LSHIFT_W16((31 - zeros), 8) + frac; + tmp16 -= WEBRTC_SPL_LSHIFT_W16(far_q, 8); + } + aecm->farLogEnergy = tmp16; + + // Logarithm of estimated echo energy through adapted channel + tmp16 = kLogLowValue; + if (tmpAdapt) + { + zeros = WebRtcSpl_NormU32(tmpAdapt); + frac = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_U32((WEBRTC_SPL_LSHIFT_U32(tmpAdapt, zeros) + & 0x7FFFFFFF), 23); + //log2 in Q8 + tmp16 += WEBRTC_SPL_LSHIFT_W16((31 - zeros), 8) + frac; + tmp16 -= WEBRTC_SPL_LSHIFT_W16(RESOLUTION_CHANNEL16 + far_q, 8); + } + aecm->echoAdaptLogEnergy[0] = tmp16; + + // Logarithm of estimated echo energy through stored channel + tmp16 = kLogLowValue; + if (tmpStored) + { + zeros = WebRtcSpl_NormU32(tmpStored); + frac = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_U32((WEBRTC_SPL_LSHIFT_U32(tmpStored, zeros) + & 0x7FFFFFFF), 23); + //log2 in Q8 + tmp16 += WEBRTC_SPL_LSHIFT_W16((31 - zeros), 8) + frac; + tmp16 -= WEBRTC_SPL_LSHIFT_W16(RESOLUTION_CHANNEL16 + far_q, 8); + } + aecm->echoStoredLogEnergy[0] = tmp16; + + // Update farend energy levels (min, max, vad, mse) + if (aecm->farLogEnergy > FAR_ENERGY_MIN) + { + if (aecm->startupState == 0) + { + increase_max_shifts = 2; + decrease_min_shifts = 2; + increase_min_shifts = 8; + } + + aecm->farEnergyMin = WebRtcAecm_AsymFilt(aecm->farEnergyMin, aecm->farLogEnergy, + increase_min_shifts, decrease_min_shifts); + aecm->farEnergyMax = WebRtcAecm_AsymFilt(aecm->farEnergyMax, aecm->farLogEnergy, + increase_max_shifts, decrease_max_shifts); + aecm->farEnergyMaxMin = (aecm->farEnergyMax - aecm->farEnergyMin); + + // Dynamic VAD region size + tmp16 = 2560 - aecm->farEnergyMin; + if (tmp16 > 0) + { + tmp16 = (WebRtc_Word16)WEBRTC_SPL_MUL_16_16_RSFT(tmp16, FAR_ENERGY_VAD_REGION, 9); + } else + { + tmp16 = 0; + } + tmp16 += FAR_ENERGY_VAD_REGION; + + if ((aecm->startupState == 0) | (aecm->vadUpdateCount > 1024)) + { + // In startup phase or VAD update halted + aecm->farEnergyVAD = aecm->farEnergyMin + tmp16; + } else + { + if (aecm->farEnergyVAD > aecm->farLogEnergy) + { + aecm->farEnergyVAD += WEBRTC_SPL_RSHIFT_W16(aecm->farLogEnergy + + tmp16 - + aecm->farEnergyVAD, + 6); + aecm->vadUpdateCount = 0; + } else + { + aecm->vadUpdateCount++; + } + } + // Put MSE threshold higher than VAD + aecm->farEnergyMSE = aecm->farEnergyVAD + (1 << 8); + } + + // Update VAD variables + if (aecm->farLogEnergy > aecm->farEnergyVAD) + { + if ((aecm->startupState == 0) | (aecm->farEnergyMaxMin > FAR_ENERGY_DIFF)) + { + // We are in startup or have significant dynamics in input speech level + aecm->currentVADValue = 1; + } + } else + { + aecm->currentVADValue = 0; + } + if ((aecm->currentVADValue) && (aecm->firstVAD)) + { + aecm->firstVAD = 0; + if (aecm->echoAdaptLogEnergy[0] > aecm->nearLogEnergy[0]) + { + // The estimated echo has higher energy than the near end signal. + // This means that the initialization was too aggressive. Scale + // down by a factor 8 + for (i = 0; i < PART_LEN1; i++) + { + aecm->channelAdapt16[i] >>= 3; + } + // Compensate the adapted echo energy level accordingly. + aecm->echoAdaptLogEnergy[0] -= (3 << 8); + aecm->firstVAD = 1; + } + } +} + +// WebRtcAecm_CalcStepSize(...) +// +// This function calculates the step size used in channel estimation +// +// +// @param aecm [in] Handle of the AECM instance. +// @param mu [out] (Return value) Stepsize in log2(), i.e. number of shifts. +// +// +WebRtc_Word16 WebRtcAecm_CalcStepSize(AecmCore_t * const aecm) +{ + + WebRtc_Word32 tmp32; + WebRtc_Word16 tmp16; + WebRtc_Word16 mu = MU_MAX; + + // Here we calculate the step size mu used in the + // following NLMS based Channel estimation algorithm + if (!aecm->currentVADValue) + { + // Far end energy level too low, no channel update + mu = 0; + } else if (aecm->startupState > 0) + { + if (aecm->farEnergyMin >= aecm->farEnergyMax) + { + mu = MU_MIN; + } else + { + tmp16 = (aecm->farLogEnergy - aecm->farEnergyMin); + tmp32 = WEBRTC_SPL_MUL_16_16(tmp16, MU_DIFF); + tmp32 = WebRtcSpl_DivW32W16(tmp32, aecm->farEnergyMaxMin); + mu = MU_MIN - 1 - (WebRtc_Word16)(tmp32); + // The -1 is an alternative to rounding. This way we get a larger + // stepsize, so we in some sense compensate for truncation in NLMS + } + if (mu < MU_MAX) + { + mu = MU_MAX; // Equivalent with maximum step size of 2^-MU_MAX + } + } + + return mu; +} + +// WebRtcAecm_UpdateChannel(...) +// +// This function performs channel estimation. NLMS and decision on channel storage. +// +// +// @param aecm [i/o] Handle of the AECM instance. +// @param far_spectrum [in] Absolute value of the farend signal in Q(far_q) +// @param far_q [in] Q-domain of the farend signal +// @param dfa [in] Absolute value of the nearend signal (Q[aecm->dfaQDomain]) +// @param mu [in] NLMS step size. +// @param echoEst [i/o] Estimated echo in Q(far_q+RESOLUTION_CHANNEL16). +// +void WebRtcAecm_UpdateChannel(AecmCore_t * aecm, + const WebRtc_UWord16* far_spectrum, + const WebRtc_Word16 far_q, + const WebRtc_UWord16 * const dfa, + const WebRtc_Word16 mu, + WebRtc_Word32 * echoEst) +{ + + WebRtc_UWord32 tmpU32no1, tmpU32no2; + WebRtc_Word32 tmp32no1, tmp32no2; + WebRtc_Word32 mseStored; + WebRtc_Word32 mseAdapt; + + int i; + + WebRtc_Word16 zerosFar, zerosNum, zerosCh, zerosDfa; + WebRtc_Word16 shiftChFar, shiftNum, shift2ResChan; + WebRtc_Word16 tmp16no1; + WebRtc_Word16 xfaQ, dfaQ; + + // This is the channel estimation algorithm. It is base on NLMS but has a variable step + // length, which was calculated above. + if (mu) + { + for (i = 0; i < PART_LEN1; i++) + { + // Determine norm of channel and farend to make sure we don't get overflow in + // multiplication + zerosCh = WebRtcSpl_NormU32(aecm->channelAdapt32[i]); + zerosFar = WebRtcSpl_NormU32((WebRtc_UWord32)far_spectrum[i]); + if (zerosCh + zerosFar > 31) + { + // Multiplication is safe + tmpU32no1 = WEBRTC_SPL_UMUL_32_16(aecm->channelAdapt32[i], + far_spectrum[i]); + shiftChFar = 0; + } else + { + // We need to shift down before multiplication + shiftChFar = 32 - zerosCh - zerosFar; + tmpU32no1 = WEBRTC_SPL_UMUL_32_16( + WEBRTC_SPL_RSHIFT_W32(aecm->channelAdapt32[i], shiftChFar), + far_spectrum[i]); + } + // Determine Q-domain of numerator + zerosNum = WebRtcSpl_NormU32(tmpU32no1); + if (dfa[i]) + { + zerosDfa = WebRtcSpl_NormU32((WebRtc_UWord32)dfa[i]); + } else + { + zerosDfa = 32; + } + tmp16no1 = zerosDfa - 2 + aecm->dfaNoisyQDomain - + RESOLUTION_CHANNEL32 - far_q + shiftChFar; + if (zerosNum > tmp16no1 + 1) + { + xfaQ = tmp16no1; + dfaQ = zerosDfa - 2; + } else + { + xfaQ = zerosNum - 2; + dfaQ = RESOLUTION_CHANNEL32 + far_q - aecm->dfaNoisyQDomain - + shiftChFar + xfaQ; + } + // Add in the same Q-domain + tmpU32no1 = WEBRTC_SPL_SHIFT_W32(tmpU32no1, xfaQ); + tmpU32no2 = WEBRTC_SPL_SHIFT_W32((WebRtc_UWord32)dfa[i], dfaQ); + tmp32no1 = (WebRtc_Word32)tmpU32no2 - (WebRtc_Word32)tmpU32no1; + zerosNum = WebRtcSpl_NormW32(tmp32no1); + if ((tmp32no1) && (far_spectrum[i] > (CHANNEL_VAD << far_q))) + { + // + // Update is needed + // + // This is what we would like to compute + // + // tmp32no1 = dfa[i] - (aecm->channelAdapt[i] * far_spectrum[i]) + // tmp32norm = (i + 1) + // aecm->channelAdapt[i] += (2^mu) * tmp32no1 + // / (tmp32norm * far_spectrum[i]) + // + + // Make sure we don't get overflow in multiplication. + if (zerosNum + zerosFar > 31) + { + if (tmp32no1 > 0) + { + tmp32no2 = (WebRtc_Word32)WEBRTC_SPL_UMUL_32_16(tmp32no1, + far_spectrum[i]); + } else + { + tmp32no2 = -(WebRtc_Word32)WEBRTC_SPL_UMUL_32_16(-tmp32no1, + far_spectrum[i]); + } + shiftNum = 0; + } else + { + shiftNum = 32 - (zerosNum + zerosFar); + if (tmp32no1 > 0) + { + tmp32no2 = (WebRtc_Word32)WEBRTC_SPL_UMUL_32_16( + WEBRTC_SPL_RSHIFT_W32(tmp32no1, shiftNum), + far_spectrum[i]); + } else + { + tmp32no2 = -(WebRtc_Word32)WEBRTC_SPL_UMUL_32_16( + WEBRTC_SPL_RSHIFT_W32(-tmp32no1, shiftNum), + far_spectrum[i]); + } + } + // Normalize with respect to frequency bin + tmp32no2 = WebRtcSpl_DivW32W16(tmp32no2, i + 1); + // Make sure we are in the right Q-domain + shift2ResChan = shiftNum + shiftChFar - xfaQ - mu - ((30 - zerosFar) << 1); + if (WebRtcSpl_NormW32(tmp32no2) < shift2ResChan) + { + tmp32no2 = WEBRTC_SPL_WORD32_MAX; + } else + { + tmp32no2 = WEBRTC_SPL_SHIFT_W32(tmp32no2, shift2ResChan); + } + aecm->channelAdapt32[i] = WEBRTC_SPL_ADD_SAT_W32(aecm->channelAdapt32[i], + tmp32no2); + if (aecm->channelAdapt32[i] < 0) + { + // We can never have negative channel gain + aecm->channelAdapt32[i] = 0; + } + aecm->channelAdapt16[i] + = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32(aecm->channelAdapt32[i], 16); + } + } + } + // END: Adaptive channel update + + // Determine if we should store or restore the channel + if ((aecm->startupState == 0) & (aecm->currentVADValue)) + { + // During startup we store the channel every block, + // and we recalculate echo estimate + WebRtcAecm_StoreAdaptiveChannel(aecm, far_spectrum, echoEst); + } else + { + if (aecm->farLogEnergy < aecm->farEnergyMSE) + { + aecm->mseChannelCount = 0; + } else + { + aecm->mseChannelCount++; + } + // Enough data for validation. Store channel if we can. + if (aecm->mseChannelCount >= (MIN_MSE_COUNT + 10)) + { + // We have enough data. + // Calculate MSE of "Adapt" and "Stored" versions. + // It is actually not MSE, but average absolute error. + mseStored = 0; + mseAdapt = 0; + for (i = 0; i < MIN_MSE_COUNT; i++) + { + tmp32no1 = ((WebRtc_Word32)aecm->echoStoredLogEnergy[i] + - (WebRtc_Word32)aecm->nearLogEnergy[i]); + tmp32no2 = WEBRTC_SPL_ABS_W32(tmp32no1); + mseStored += tmp32no2; + + tmp32no1 = ((WebRtc_Word32)aecm->echoAdaptLogEnergy[i] + - (WebRtc_Word32)aecm->nearLogEnergy[i]); + tmp32no2 = WEBRTC_SPL_ABS_W32(tmp32no1); + mseAdapt += tmp32no2; + } + if (((mseStored << MSE_RESOLUTION) < (MIN_MSE_DIFF * mseAdapt)) + & ((aecm->mseStoredOld << MSE_RESOLUTION) < (MIN_MSE_DIFF + * aecm->mseAdaptOld))) + { + // The stored channel has a significantly lower MSE than the adaptive one for + // two consecutive calculations. Reset the adaptive channel. + WebRtcAecm_ResetAdaptiveChannel(aecm); + } else if (((MIN_MSE_DIFF * mseStored) > (mseAdapt << MSE_RESOLUTION)) & (mseAdapt + < aecm->mseThreshold) & (aecm->mseAdaptOld < aecm->mseThreshold)) + { + // The adaptive channel has a significantly lower MSE than the stored one. + // The MSE for the adaptive channel has also been low for two consecutive + // calculations. Store the adaptive channel. + WebRtcAecm_StoreAdaptiveChannel(aecm, far_spectrum, echoEst); + + // Update threshold + if (aecm->mseThreshold == WEBRTC_SPL_WORD32_MAX) + { + aecm->mseThreshold = (mseAdapt + aecm->mseAdaptOld); + } else + { + aecm->mseThreshold += WEBRTC_SPL_MUL_16_16_RSFT(mseAdapt + - WEBRTC_SPL_MUL_16_16_RSFT(aecm->mseThreshold, 5, 3), 205, 8); + } + + } + + // Reset counter + aecm->mseChannelCount = 0; + + // Store the MSE values. + aecm->mseStoredOld = mseStored; + aecm->mseAdaptOld = mseAdapt; + } + } + // END: Determine if we should store or reset channel estimate. +} + +// CalcSuppressionGain(...) +// +// This function calculates the suppression gain that is used in the Wiener filter. +// +// +// @param aecm [i/n] Handle of the AECM instance. +// @param supGain [out] (Return value) Suppression gain with which to scale the noise +// level (Q14). +// +// +static WebRtc_Word16 CalcSuppressionGain(AecmCore_t * const aecm) +{ + WebRtc_Word32 tmp32no1; + + WebRtc_Word16 supGain = SUPGAIN_DEFAULT; + WebRtc_Word16 tmp16no1; + WebRtc_Word16 dE = 0; + + // Determine suppression gain used in the Wiener filter. The gain is based on a mix of far + // end energy and echo estimation error. + // Adjust for the far end signal level. A low signal level indicates no far end signal, + // hence we set the suppression gain to 0 + if (!aecm->currentVADValue) + { + supGain = 0; + } else + { + // Adjust for possible double talk. If we have large variations in estimation error we + // likely have double talk (or poor channel). + tmp16no1 = (aecm->nearLogEnergy[0] - aecm->echoStoredLogEnergy[0] - ENERGY_DEV_OFFSET); + dE = WEBRTC_SPL_ABS_W16(tmp16no1); + + if (dE < ENERGY_DEV_TOL) + { + // Likely no double talk. The better estimation, the more we can suppress signal. + // Update counters + if (dE < SUPGAIN_EPC_DT) + { + tmp32no1 = WEBRTC_SPL_MUL_16_16(aecm->supGainErrParamDiffAB, dE); + tmp32no1 += (SUPGAIN_EPC_DT >> 1); + tmp16no1 = (WebRtc_Word16)WebRtcSpl_DivW32W16(tmp32no1, SUPGAIN_EPC_DT); + supGain = aecm->supGainErrParamA - tmp16no1; + } else + { + tmp32no1 = WEBRTC_SPL_MUL_16_16(aecm->supGainErrParamDiffBD, + (ENERGY_DEV_TOL - dE)); + tmp32no1 += ((ENERGY_DEV_TOL - SUPGAIN_EPC_DT) >> 1); + tmp16no1 = (WebRtc_Word16)WebRtcSpl_DivW32W16(tmp32no1, (ENERGY_DEV_TOL + - SUPGAIN_EPC_DT)); + supGain = aecm->supGainErrParamD + tmp16no1; + } + } else + { + // Likely in double talk. Use default value + supGain = aecm->supGainErrParamD; + } + } + + if (supGain > aecm->supGainOld) + { + tmp16no1 = supGain; + } else + { + tmp16no1 = aecm->supGainOld; + } + aecm->supGainOld = supGain; + if (tmp16no1 < aecm->supGain) + { + aecm->supGain += (WebRtc_Word16)((tmp16no1 - aecm->supGain) >> 4); + } else + { + aecm->supGain += (WebRtc_Word16)((tmp16no1 - aecm->supGain) >> 4); + } + + // END: Update suppression gain + + return aecm->supGain; +} + +// Transforms a time domain signal into the frequency domain, outputting the +// complex valued signal, absolute value and sum of absolute values. +// +// time_signal [in] Pointer to time domain signal +// freq_signal_real [out] Pointer to real part of frequency domain array +// freq_signal_imag [out] Pointer to imaginary part of frequency domain +// array +// freq_signal_abs [out] Pointer to absolute value of frequency domain +// array +// freq_signal_sum_abs [out] Pointer to the sum of all absolute values in +// the frequency domain array +// return value The Q-domain of current frequency values +// +static int TimeToFrequencyDomain(const WebRtc_Word16* time_signal, + complex16_t* freq_signal, + WebRtc_UWord16* freq_signal_abs, + WebRtc_UWord32* freq_signal_sum_abs) +{ + int i = 0; + int time_signal_scaling = 0; + + WebRtc_Word32 tmp32no1; + WebRtc_Word32 tmp32no2; + + // In fft_buf, +16 for 32-byte alignment. + WebRtc_Word16 fft_buf[PART_LEN4 + 16]; + WebRtc_Word16 *fft = (WebRtc_Word16 *) (((uintptr_t) fft_buf + 31) & ~31); + + WebRtc_Word16 tmp16no1; + WebRtc_Word16 tmp16no2; +#ifdef AECM_WITH_ABS_APPROX + WebRtc_Word16 max_value = 0; + WebRtc_Word16 min_value = 0; + WebRtc_UWord16 alpha = 0; + WebRtc_UWord16 beta = 0; +#endif + +#ifdef AECM_DYNAMIC_Q + tmp16no1 = WebRtcSpl_MaxAbsValueW16(time_signal, PART_LEN2); + time_signal_scaling = WebRtcSpl_NormW16(tmp16no1); +#endif + + WebRtcAecm_WindowAndFFT(fft, time_signal, freq_signal, time_signal_scaling); + + // Extract imaginary and real part, calculate the magnitude for all frequency bins + freq_signal[0].imag = 0; + freq_signal[PART_LEN].imag = 0; + freq_signal[PART_LEN].real = fft[PART_LEN2]; + freq_signal_abs[0] = (WebRtc_UWord16)WEBRTC_SPL_ABS_W16( + freq_signal[0].real); + freq_signal_abs[PART_LEN] = (WebRtc_UWord16)WEBRTC_SPL_ABS_W16( + freq_signal[PART_LEN].real); + (*freq_signal_sum_abs) = (WebRtc_UWord32)(freq_signal_abs[0]) + + (WebRtc_UWord32)(freq_signal_abs[PART_LEN]); + + for (i = 1; i < PART_LEN; i++) + { + if (freq_signal[i].real == 0) + { + freq_signal_abs[i] = (WebRtc_UWord16)WEBRTC_SPL_ABS_W16( + freq_signal[i].imag); + } + else if (freq_signal[i].imag == 0) + { + freq_signal_abs[i] = (WebRtc_UWord16)WEBRTC_SPL_ABS_W16( + freq_signal[i].real); + } + else + { + // Approximation for magnitude of complex fft output + // magn = sqrt(real^2 + imag^2) + // magn ~= alpha * max(|imag|,|real|) + beta * min(|imag|,|real|) + // + // The parameters alpha and beta are stored in Q15 + +#ifdef AECM_WITH_ABS_APPROX + tmp16no1 = WEBRTC_SPL_ABS_W16(freq_signal[i].real); + tmp16no2 = WEBRTC_SPL_ABS_W16(freq_signal[i].imag); + + if(tmp16no1 > tmp16no2) + { + max_value = tmp16no1; + min_value = tmp16no2; + } else + { + max_value = tmp16no2; + min_value = tmp16no1; + } + + // Magnitude in Q(-6) + if ((max_value >> 2) > min_value) + { + alpha = kAlpha1; + beta = kBeta1; + } else if ((max_value >> 1) > min_value) + { + alpha = kAlpha2; + beta = kBeta2; + } else + { + alpha = kAlpha3; + beta = kBeta3; + } + tmp16no1 = (WebRtc_Word16)WEBRTC_SPL_MUL_16_16_RSFT(max_value, + alpha, + 15); + tmp16no2 = (WebRtc_Word16)WEBRTC_SPL_MUL_16_16_RSFT(min_value, + beta, + 15); + freq_signal_abs[i] = (WebRtc_UWord16)tmp16no1 + + (WebRtc_UWord16)tmp16no2; +#else +#ifdef WEBRTC_ARCH_ARM_V7A + __asm__("smulbb %0, %1, %2" : "=r"(tmp32no1) : "r"(freq_signal[i].real), + "r"(freq_signal[i].real)); + __asm__("smlabb %0, %1, %2, %3" :: "r"(tmp32no2), "r"(freq_signal[i].imag), + "r"(freq_signal[i].imag), "r"(tmp32no1)); +#else + tmp16no1 = WEBRTC_SPL_ABS_W16(freq_signal[i].real); + tmp16no2 = WEBRTC_SPL_ABS_W16(freq_signal[i].imag); + tmp32no1 = WEBRTC_SPL_MUL_16_16(tmp16no1, tmp16no1); + tmp32no2 = WEBRTC_SPL_MUL_16_16(tmp16no2, tmp16no2); + tmp32no2 = WEBRTC_SPL_ADD_SAT_W32(tmp32no1, tmp32no2); +#endif // WEBRTC_ARCH_ARM_V7A + tmp32no1 = WebRtcSpl_SqrtFloor(tmp32no2); + + freq_signal_abs[i] = (WebRtc_UWord16)tmp32no1; +#endif // AECM_WITH_ABS_APPROX + } + (*freq_signal_sum_abs) += (WebRtc_UWord32)freq_signal_abs[i]; + } + + return time_signal_scaling; +} + +int WebRtcAecm_ProcessBlock(AecmCore_t * aecm, + const WebRtc_Word16 * farend, + const WebRtc_Word16 * nearendNoisy, + const WebRtc_Word16 * nearendClean, + WebRtc_Word16 * output) +{ + int i; + + WebRtc_UWord32 xfaSum; + WebRtc_UWord32 dfaNoisySum; + WebRtc_UWord32 dfaCleanSum; + WebRtc_UWord32 echoEst32Gained; + WebRtc_UWord32 tmpU32; + + WebRtc_Word32 tmp32no1; + + WebRtc_UWord16 xfa[PART_LEN1]; + WebRtc_UWord16 dfaNoisy[PART_LEN1]; + WebRtc_UWord16 dfaClean[PART_LEN1]; + WebRtc_UWord16* ptrDfaClean = dfaClean; + const WebRtc_UWord16* far_spectrum_ptr = NULL; + + // 32 byte aligned buffers (with +8 or +16). + // TODO (kma): define fft with complex16_t. + WebRtc_Word16 fft_buf[PART_LEN4 + 2 + 16]; // +2 to make a loop safe. + WebRtc_Word32 echoEst32_buf[PART_LEN1 + 8]; + WebRtc_Word32 dfw_buf[PART_LEN1 + 8]; + WebRtc_Word32 efw_buf[PART_LEN1 + 8]; + + WebRtc_Word16* fft = (WebRtc_Word16*) (((uintptr_t) fft_buf + 31) & ~ 31); + WebRtc_Word32* echoEst32 = (WebRtc_Word32*) (((uintptr_t) echoEst32_buf + 31) & ~ 31); + complex16_t* dfw = (complex16_t*) (((uintptr_t) dfw_buf + 31) & ~ 31); + complex16_t* efw = (complex16_t*) (((uintptr_t) efw_buf + 31) & ~ 31); + + WebRtc_Word16 hnl[PART_LEN1]; + WebRtc_Word16 numPosCoef = 0; + WebRtc_Word16 nlpGain = ONE_Q14; + WebRtc_Word16 delay; + WebRtc_Word16 tmp16no1; + WebRtc_Word16 tmp16no2; + WebRtc_Word16 mu; + WebRtc_Word16 supGain; + WebRtc_Word16 zeros32, zeros16; + WebRtc_Word16 zerosDBufNoisy, zerosDBufClean, zerosXBuf; + WebRtc_Word16 resolutionDiff, qDomainDiff; + + const int kMinPrefBand = 4; + const int kMaxPrefBand = 24; + WebRtc_Word32 avgHnl32 = 0; + +#ifdef ARM_WINM_LOG_ + DWORD temp; + static int flag0 = 0; + __int64 freq, start, end, diff__; + unsigned int milliseconds; +#endif + + // Determine startup state. There are three states: + // (0) the first CONV_LEN blocks + // (1) another CONV_LEN blocks + // (2) the rest + + if (aecm->startupState < 2) + { + aecm->startupState = (aecm->totCount >= CONV_LEN) + (aecm->totCount >= CONV_LEN2); + } + // END: Determine startup state + + // Buffer near and far end signals + memcpy(aecm->xBuf + PART_LEN, farend, sizeof(WebRtc_Word16) * PART_LEN); + memcpy(aecm->dBufNoisy + PART_LEN, nearendNoisy, sizeof(WebRtc_Word16) * PART_LEN); + if (nearendClean != NULL) + { + memcpy(aecm->dBufClean + PART_LEN, nearendClean, sizeof(WebRtc_Word16) * PART_LEN); + } + +#ifdef ARM_WINM_LOG_ + // measure tick start + QueryPerformanceFrequency((LARGE_INTEGER*)&freq); + QueryPerformanceCounter((LARGE_INTEGER*)&start); +#endif + + // Transform far end signal from time domain to frequency domain. + zerosXBuf = TimeToFrequencyDomain(aecm->xBuf, + dfw, + xfa, + &xfaSum); + + // Transform noisy near end signal from time domain to frequency domain. + zerosDBufNoisy = TimeToFrequencyDomain(aecm->dBufNoisy, + dfw, + dfaNoisy, + &dfaNoisySum); + aecm->dfaNoisyQDomainOld = aecm->dfaNoisyQDomain; + aecm->dfaNoisyQDomain = zerosDBufNoisy; + + + if (nearendClean == NULL) + { + ptrDfaClean = dfaNoisy; + aecm->dfaCleanQDomainOld = aecm->dfaNoisyQDomainOld; + aecm->dfaCleanQDomain = aecm->dfaNoisyQDomain; + dfaCleanSum = dfaNoisySum; + } else + { + // Transform clean near end signal from time domain to frequency domain. + zerosDBufClean = TimeToFrequencyDomain(aecm->dBufClean, + dfw, + dfaClean, + &dfaCleanSum); + aecm->dfaCleanQDomainOld = aecm->dfaCleanQDomain; + aecm->dfaCleanQDomain = zerosDBufClean; + } + +#ifdef ARM_WINM_LOG_ + // measure tick end + QueryPerformanceCounter((LARGE_INTEGER*)&end); + diff__ = ((end - start) * 1000) / (freq/1000); + milliseconds = (unsigned int)(diff__ & 0xffffffff); + WriteFile (logFile, &milliseconds, sizeof(unsigned int), &temp, NULL); + // measure tick start + QueryPerformanceCounter((LARGE_INTEGER*)&start); +#endif + + // Get the delay + // Save far-end history and estimate delay + delay = WebRtcAecm_DelayEstimatorProcess(aecm->delay_estimator, + xfa, + dfaNoisy, + PART_LEN1, + zerosXBuf, + aecm->currentVADValue); + if (delay < 0) + { + return -1; + } + + if (aecm->fixedDelay >= 0) + { + // Use fixed delay + delay = aecm->fixedDelay; + } + + aecm->currentDelay = delay; + +#ifdef ARM_WINM_LOG_ + // measure tick end + QueryPerformanceCounter((LARGE_INTEGER*)&end); + diff__ = ((end - start) * 1000) / (freq/1000); + milliseconds = (unsigned int)(diff__ & 0xffffffff); + WriteFile (logFile, &milliseconds, sizeof(unsigned int), &temp, NULL); + // measure tick start + QueryPerformanceCounter((LARGE_INTEGER*)&start); +#endif + // Get aligned far end spectrum + far_spectrum_ptr = WebRtcAecm_GetAlignedFarend(aecm->delay_estimator, + PART_LEN1, + &zerosXBuf); + if (far_spectrum_ptr == NULL) + { + return -1; + } + + // Calculate log(energy) and update energy threshold levels + WebRtcAecm_CalcEnergies(aecm, far_spectrum_ptr, zerosXBuf, dfaNoisySum, echoEst32); + + // Calculate stepsize + mu = WebRtcAecm_CalcStepSize(aecm); + + // Update counters + aecm->totCount++; + + // This is the channel estimation algorithm. + // It is base on NLMS but has a variable step length, which was calculated above. + WebRtcAecm_UpdateChannel(aecm, far_spectrum_ptr, zerosXBuf, dfaNoisy, mu, echoEst32); + supGain = CalcSuppressionGain(aecm); + +#ifdef ARM_WINM_LOG_ + // measure tick end + QueryPerformanceCounter((LARGE_INTEGER*)&end); + diff__ = ((end - start) * 1000) / (freq/1000); + milliseconds = (unsigned int)(diff__ & 0xffffffff); + WriteFile (logFile, &milliseconds, sizeof(unsigned int), &temp, NULL); + // measure tick start + QueryPerformanceCounter((LARGE_INTEGER*)&start); +#endif + + // Calculate Wiener filter hnl[] + for (i = 0; i < PART_LEN1; i++) + { + // Far end signal through channel estimate in Q8 + // How much can we shift right to preserve resolution + tmp32no1 = echoEst32[i] - aecm->echoFilt[i]; + aecm->echoFilt[i] += WEBRTC_SPL_RSHIFT_W32(WEBRTC_SPL_MUL_32_16(tmp32no1, 50), 8); + + zeros32 = WebRtcSpl_NormW32(aecm->echoFilt[i]) + 1; + zeros16 = WebRtcSpl_NormW16(supGain) + 1; + if (zeros32 + zeros16 > 16) + { + // Multiplication is safe + // Result in Q(RESOLUTION_CHANNEL+RESOLUTION_SUPGAIN+aecm->xfaQDomainBuf[diff]) + echoEst32Gained = WEBRTC_SPL_UMUL_32_16((WebRtc_UWord32)aecm->echoFilt[i], + (WebRtc_UWord16)supGain); + resolutionDiff = 14 - RESOLUTION_CHANNEL16 - RESOLUTION_SUPGAIN; + resolutionDiff += (aecm->dfaCleanQDomain - zerosXBuf); + } else + { + tmp16no1 = 17 - zeros32 - zeros16; + resolutionDiff = 14 + tmp16no1 - RESOLUTION_CHANNEL16 - RESOLUTION_SUPGAIN; + resolutionDiff += (aecm->dfaCleanQDomain - zerosXBuf); + if (zeros32 > tmp16no1) + { + echoEst32Gained = WEBRTC_SPL_UMUL_32_16((WebRtc_UWord32)aecm->echoFilt[i], + (WebRtc_UWord16)WEBRTC_SPL_RSHIFT_W16(supGain, + tmp16no1)); // Q-(RESOLUTION_CHANNEL+RESOLUTION_SUPGAIN-16) + } else + { + // Result in Q-(RESOLUTION_CHANNEL+RESOLUTION_SUPGAIN-16) + echoEst32Gained = WEBRTC_SPL_UMUL_32_16( + (WebRtc_UWord32)WEBRTC_SPL_RSHIFT_W32(aecm->echoFilt[i], tmp16no1), + (WebRtc_UWord16)supGain); + } + } + + zeros16 = WebRtcSpl_NormW16(aecm->nearFilt[i]); + if ((zeros16 < (aecm->dfaCleanQDomain - aecm->dfaCleanQDomainOld)) + & (aecm->nearFilt[i])) + { + tmp16no1 = WEBRTC_SPL_SHIFT_W16(aecm->nearFilt[i], zeros16); + qDomainDiff = zeros16 - aecm->dfaCleanQDomain + aecm->dfaCleanQDomainOld; + } else + { + tmp16no1 = WEBRTC_SPL_SHIFT_W16(aecm->nearFilt[i], + aecm->dfaCleanQDomain - aecm->dfaCleanQDomainOld); + qDomainDiff = 0; + } + tmp16no2 = WEBRTC_SPL_SHIFT_W16(ptrDfaClean[i], qDomainDiff); + tmp32no1 = (WebRtc_Word32)(tmp16no2 - tmp16no1); + tmp16no2 = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32(tmp32no1, 4); + tmp16no2 += tmp16no1; + zeros16 = WebRtcSpl_NormW16(tmp16no2); + if ((tmp16no2) & (-qDomainDiff > zeros16)) + { + aecm->nearFilt[i] = WEBRTC_SPL_WORD16_MAX; + } else + { + aecm->nearFilt[i] = WEBRTC_SPL_SHIFT_W16(tmp16no2, -qDomainDiff); + } + + // Wiener filter coefficients, resulting hnl in Q14 + if (echoEst32Gained == 0) + { + hnl[i] = ONE_Q14; + } else if (aecm->nearFilt[i] == 0) + { + hnl[i] = 0; + } else + { + // Multiply the suppression gain + // Rounding + echoEst32Gained += (WebRtc_UWord32)(aecm->nearFilt[i] >> 1); + tmpU32 = WebRtcSpl_DivU32U16(echoEst32Gained, (WebRtc_UWord16)aecm->nearFilt[i]); + + // Current resolution is + // Q-(RESOLUTION_CHANNEL + RESOLUTION_SUPGAIN - max(0, 17 - zeros16 - zeros32)) + // Make sure we are in Q14 + tmp32no1 = (WebRtc_Word32)WEBRTC_SPL_SHIFT_W32(tmpU32, resolutionDiff); + if (tmp32no1 > ONE_Q14) + { + hnl[i] = 0; + } else if (tmp32no1 < 0) + { + hnl[i] = ONE_Q14; + } else + { + // 1-echoEst/dfa + hnl[i] = ONE_Q14 - (WebRtc_Word16)tmp32no1; + if (hnl[i] < 0) + { + hnl[i] = 0; + } + } + } + if (hnl[i]) + { + numPosCoef++; + } + } + // Only in wideband. Prevent the gain in upper band from being larger than + // in lower band. + if (aecm->mult == 2) + { + // TODO(bjornv): Investigate if the scaling of hnl[i] below can cause + // speech distortion in double-talk. + for (i = 0; i < PART_LEN1; i++) + { + hnl[i] = (WebRtc_Word16)WEBRTC_SPL_MUL_16_16_RSFT(hnl[i], hnl[i], 14); + } + + for (i = kMinPrefBand; i <= kMaxPrefBand; i++) + { + avgHnl32 += (WebRtc_Word32)hnl[i]; + } + assert(kMaxPrefBand - kMinPrefBand + 1 > 0); + avgHnl32 /= (kMaxPrefBand - kMinPrefBand + 1); + + for (i = kMaxPrefBand; i < PART_LEN1; i++) + { + if (hnl[i] > (WebRtc_Word16)avgHnl32) + { + hnl[i] = (WebRtc_Word16)avgHnl32; + } + } + } + +#ifdef ARM_WINM_LOG_ + // measure tick end + QueryPerformanceCounter((LARGE_INTEGER*)&end); + diff__ = ((end - start) * 1000) / (freq/1000); + milliseconds = (unsigned int)(diff__ & 0xffffffff); + WriteFile (logFile, &milliseconds, sizeof(unsigned int), &temp, NULL); + // measure tick start + QueryPerformanceCounter((LARGE_INTEGER*)&start); +#endif + + // Calculate NLP gain, result is in Q14 + if (aecm->nlpFlag) + { + for (i = 0; i < PART_LEN1; i++) + { + // Truncate values close to zero and one. + if (hnl[i] > NLP_COMP_HIGH) + { + hnl[i] = ONE_Q14; + } else if (hnl[i] < NLP_COMP_LOW) + { + hnl[i] = 0; + } + + // Remove outliers + if (numPosCoef < 3) + { + nlpGain = 0; + } else + { + nlpGain = ONE_Q14; + } + + // NLP + if ((hnl[i] == ONE_Q14) && (nlpGain == ONE_Q14)) + { + hnl[i] = ONE_Q14; + } else + { + hnl[i] = (WebRtc_Word16)WEBRTC_SPL_MUL_16_16_RSFT(hnl[i], nlpGain, 14); + } + + // multiply with Wiener coefficients + efw[i].real = (WebRtc_Word16)(WEBRTC_SPL_MUL_16_16_RSFT_WITH_ROUND(dfw[i].real, + hnl[i], 14)); + efw[i].imag = (WebRtc_Word16)(WEBRTC_SPL_MUL_16_16_RSFT_WITH_ROUND(dfw[i].imag, + hnl[i], 14)); + } + } + else + { + // multiply with Wiener coefficients + for (i = 0; i < PART_LEN1; i++) + { + efw[i].real = (WebRtc_Word16)(WEBRTC_SPL_MUL_16_16_RSFT_WITH_ROUND(dfw[i].real, + hnl[i], 14)); + efw[i].imag = (WebRtc_Word16)(WEBRTC_SPL_MUL_16_16_RSFT_WITH_ROUND(dfw[i].imag, + hnl[i], 14)); + } + } + + if (aecm->cngMode == AecmTrue) + { + ComfortNoise(aecm, ptrDfaClean, efw, hnl); + } + +#ifdef ARM_WINM_LOG_ + // measure tick end + QueryPerformanceCounter((LARGE_INTEGER*)&end); + diff__ = ((end - start) * 1000) / (freq/1000); + milliseconds = (unsigned int)(diff__ & 0xffffffff); + WriteFile (logFile, &milliseconds, sizeof(unsigned int), &temp, NULL); + // measure tick start + QueryPerformanceCounter((LARGE_INTEGER*)&start); +#endif + + WebRtcAecm_InverseFFTAndWindow(aecm, fft, efw, output, nearendClean); + + return 0; +} + + +// Generate comfort noise and add to output signal. +// +// \param[in] aecm Handle of the AECM instance. +// \param[in] dfa Absolute value of the nearend signal (Q[aecm->dfaQDomain]). +// \param[in,out] outReal Real part of the output signal (Q[aecm->dfaQDomain]). +// \param[in,out] outImag Imaginary part of the output signal (Q[aecm->dfaQDomain]). +// \param[in] lambda Suppression gain with which to scale the noise level (Q14). +// +static void ComfortNoise(AecmCore_t* aecm, + const WebRtc_UWord16* dfa, + complex16_t* out, + const WebRtc_Word16* lambda) +{ + WebRtc_Word16 i; + WebRtc_Word16 tmp16; + WebRtc_Word32 tmp32; + + WebRtc_Word16 randW16[PART_LEN]; + WebRtc_Word16 uReal[PART_LEN1]; + WebRtc_Word16 uImag[PART_LEN1]; + WebRtc_Word32 outLShift32; + WebRtc_Word16 noiseRShift16[PART_LEN1]; + + WebRtc_Word16 shiftFromNearToNoise = kNoiseEstQDomain - aecm->dfaCleanQDomain; + WebRtc_Word16 minTrackShift; + + assert(shiftFromNearToNoise >= 0); + assert(shiftFromNearToNoise < 16); + + if (aecm->noiseEstCtr < 100) + { + // Track the minimum more quickly initially. + aecm->noiseEstCtr++; + minTrackShift = 6; + } else + { + minTrackShift = 9; + } + + // Estimate noise power. + for (i = 0; i < PART_LEN1; i++) + { + + // Shift to the noise domain. + tmp32 = (WebRtc_Word32)dfa[i]; + outLShift32 = WEBRTC_SPL_LSHIFT_W32(tmp32, shiftFromNearToNoise); + + if (outLShift32 < aecm->noiseEst[i]) + { + // Reset "too low" counter + aecm->noiseEstTooLowCtr[i] = 0; + // Track the minimum. + if (aecm->noiseEst[i] < (1 << minTrackShift)) + { + // For small values, decrease noiseEst[i] every + // |kNoiseEstIncCount| block. The regular approach below can not + // go further down due to truncation. + aecm->noiseEstTooHighCtr[i]++; + if (aecm->noiseEstTooHighCtr[i] >= kNoiseEstIncCount) + { + aecm->noiseEst[i]--; + aecm->noiseEstTooHighCtr[i] = 0; // Reset the counter + } + } + else + { + aecm->noiseEst[i] -= ((aecm->noiseEst[i] - outLShift32) >> minTrackShift); + } + } else + { + // Reset "too high" counter + aecm->noiseEstTooHighCtr[i] = 0; + // Ramp slowly upwards until we hit the minimum again. + if ((aecm->noiseEst[i] >> 19) > 0) + { + // Avoid overflow. + // Multiplication with 2049 will cause wrap around. Scale + // down first and then multiply + aecm->noiseEst[i] >>= 11; + aecm->noiseEst[i] *= 2049; + } + else if ((aecm->noiseEst[i] >> 11) > 0) + { + // Large enough for relative increase + aecm->noiseEst[i] *= 2049; + aecm->noiseEst[i] >>= 11; + } + else + { + // Make incremental increases based on size every + // |kNoiseEstIncCount| block + aecm->noiseEstTooLowCtr[i]++; + if (aecm->noiseEstTooLowCtr[i] >= kNoiseEstIncCount) + { + aecm->noiseEst[i] += (aecm->noiseEst[i] >> 9) + 1; + aecm->noiseEstTooLowCtr[i] = 0; // Reset counter + } + } + } + } + + for (i = 0; i < PART_LEN1; i++) + { + tmp32 = WEBRTC_SPL_RSHIFT_W32(aecm->noiseEst[i], shiftFromNearToNoise); + if (tmp32 > 32767) + { + tmp32 = 32767; + aecm->noiseEst[i] = WEBRTC_SPL_LSHIFT_W32(tmp32, shiftFromNearToNoise); + } + noiseRShift16[i] = (WebRtc_Word16)tmp32; + + tmp16 = ONE_Q14 - lambda[i]; + noiseRShift16[i] + = (WebRtc_Word16)WEBRTC_SPL_MUL_16_16_RSFT(tmp16, noiseRShift16[i], 14); + } + + // Generate a uniform random array on [0 2^15-1]. + WebRtcSpl_RandUArray(randW16, PART_LEN, &aecm->seed); + + // Generate noise according to estimated energy. + uReal[0] = 0; // Reject LF noise. + uImag[0] = 0; + for (i = 1; i < PART_LEN1; i++) + { + // Get a random index for the cos and sin tables over [0 359]. + tmp16 = (WebRtc_Word16)WEBRTC_SPL_MUL_16_16_RSFT(359, randW16[i - 1], 15); + + // Tables are in Q13. + uReal[i] = (WebRtc_Word16)WEBRTC_SPL_MUL_16_16_RSFT(noiseRShift16[i], + WebRtcSpl_kCosTable[tmp16], 13); + uImag[i] = (WebRtc_Word16)WEBRTC_SPL_MUL_16_16_RSFT(-noiseRShift16[i], + WebRtcSpl_kSinTable[tmp16], 13); + } + uImag[PART_LEN] = 0; + +#if (!defined ARM_WINM) && (!defined ARM9E_GCC) && (!defined ANDROID_AECOPT) + for (i = 0; i < PART_LEN1; i++) + { + out[i].real = WEBRTC_SPL_ADD_SAT_W16(out[i].real, uReal[i]); + out[i].imag = WEBRTC_SPL_ADD_SAT_W16(out[i].imag, uImag[i]); + } +#else + for (i = 0; i < PART_LEN1 -1; ) + { + out[i].real = WEBRTC_SPL_ADD_SAT_W16(out[i].real, uReal[i]); + out[i].imag = WEBRTC_SPL_ADD_SAT_W16(out[i].imag, uImag[i]); + i++; + + out[i].real = WEBRTC_SPL_ADD_SAT_W16(out[i].real, uReal[i]); + out[i].imag = WEBRTC_SPL_ADD_SAT_W16(out[i].imag, uImag[i]); + i++; + } + out[i].real = WEBRTC_SPL_ADD_SAT_W16(out[i].real, uReal[i]); + out[i].imag = WEBRTC_SPL_ADD_SAT_W16(out[i].imag, uImag[i]); +#endif +} + +void WebRtcAecm_BufferFarFrame(AecmCore_t* const aecm, + const WebRtc_Word16* const farend, + const int farLen) +{ + int writeLen = farLen, writePos = 0; + + // Check if the write position must be wrapped + while (aecm->farBufWritePos + writeLen > FAR_BUF_LEN) + { + // Write to remaining buffer space before wrapping + writeLen = FAR_BUF_LEN - aecm->farBufWritePos; + memcpy(aecm->farBuf + aecm->farBufWritePos, farend + writePos, + sizeof(WebRtc_Word16) * writeLen); + aecm->farBufWritePos = 0; + writePos = writeLen; + writeLen = farLen - writeLen; + } + + memcpy(aecm->farBuf + aecm->farBufWritePos, farend + writePos, + sizeof(WebRtc_Word16) * writeLen); + aecm->farBufWritePos += writeLen; +} + +void WebRtcAecm_FetchFarFrame(AecmCore_t * const aecm, WebRtc_Word16 * const farend, + const int farLen, const int knownDelay) +{ + int readLen = farLen; + int readPos = 0; + int delayChange = knownDelay - aecm->lastKnownDelay; + + aecm->farBufReadPos -= delayChange; + + // Check if delay forces a read position wrap + while (aecm->farBufReadPos < 0) + { + aecm->farBufReadPos += FAR_BUF_LEN; + } + while (aecm->farBufReadPos > FAR_BUF_LEN - 1) + { + aecm->farBufReadPos -= FAR_BUF_LEN; + } + + aecm->lastKnownDelay = knownDelay; + + // Check if read position must be wrapped + while (aecm->farBufReadPos + readLen > FAR_BUF_LEN) + { + + // Read from remaining buffer space before wrapping + readLen = FAR_BUF_LEN - aecm->farBufReadPos; + memcpy(farend + readPos, aecm->farBuf + aecm->farBufReadPos, + sizeof(WebRtc_Word16) * readLen); + aecm->farBufReadPos = 0; + readPos = readLen; + readLen = farLen - readLen; + } + memcpy(farend + readPos, aecm->farBuf + aecm->farBufReadPos, + sizeof(WebRtc_Word16) * readLen); + aecm->farBufReadPos += readLen; +} + +#if !(defined(WEBRTC_ANDROID) && defined(WEBRTC_ARCH_ARM_NEON)) + +void WebRtcAecm_WindowAndFFT(WebRtc_Word16* fft, + const WebRtc_Word16* time_signal, + complex16_t* freq_signal, + int time_signal_scaling) +{ + int i, j; + + memset(fft, 0, sizeof(WebRtc_Word16) * PART_LEN4); + // FFT of signal + for (i = 0, j = 0; i < PART_LEN; i++, j += 2) + { + // Window time domain signal and insert into real part of + // transformation array |fft| + fft[j] = (WebRtc_Word16)WEBRTC_SPL_MUL_16_16_RSFT( + (time_signal[i] << time_signal_scaling), + WebRtcAecm_kSqrtHanning[i], + 14); + fft[PART_LEN2 + j] = (WebRtc_Word16)WEBRTC_SPL_MUL_16_16_RSFT( + (time_signal[i + PART_LEN] << time_signal_scaling), + WebRtcAecm_kSqrtHanning[PART_LEN - i], + 14); + // Inserting zeros in imaginary parts not necessary since we + // initialized the array with all zeros + } + + WebRtcSpl_ComplexBitReverse(fft, PART_LEN_SHIFT); + WebRtcSpl_ComplexFFT(fft, PART_LEN_SHIFT, 1); + + // Take only the first PART_LEN2 samples + for (i = 0, j = 0; j < PART_LEN2; i += 1, j += 2) + { + freq_signal[i].real = fft[j]; + + // The imaginary part has to switch sign + freq_signal[i].imag = - fft[j+1]; + } +} + +void WebRtcAecm_InverseFFTAndWindow(AecmCore_t* aecm, + WebRtc_Word16* fft, + complex16_t* efw, + WebRtc_Word16* output, + const WebRtc_Word16* nearendClean) +{ + int i, j, outCFFT; + WebRtc_Word32 tmp32no1; + + // Synthesis + for (i = 1; i < PART_LEN; i++) + { + j = WEBRTC_SPL_LSHIFT_W32(i, 1); + fft[j] = efw[i].real; + + // mirrored data, even + fft[PART_LEN4 - j] = efw[i].real; + fft[j + 1] = -efw[i].imag; + + //mirrored data, odd + fft[PART_LEN4 - (j - 1)] = efw[i].imag; + } + fft[0] = efw[0].real; + fft[1] = -efw[0].imag; + + fft[PART_LEN2] = efw[PART_LEN].real; + fft[PART_LEN2 + 1] = -efw[PART_LEN].imag; + + // inverse FFT, result should be scaled with outCFFT + WebRtcSpl_ComplexBitReverse(fft, PART_LEN_SHIFT); + outCFFT = WebRtcSpl_ComplexIFFT(fft, PART_LEN_SHIFT, 1); + + //take only the real values and scale with outCFFT + for (i = 0; i < PART_LEN2; i++) + { + j = WEBRTC_SPL_LSHIFT_W32(i, 1); + fft[i] = fft[j]; + } + + for (i = 0; i < PART_LEN; i++) + { + fft[i] = (WebRtc_Word16)WEBRTC_SPL_MUL_16_16_RSFT_WITH_ROUND( + fft[i], + WebRtcAecm_kSqrtHanning[i], + 14); + tmp32no1 = WEBRTC_SPL_SHIFT_W32((WebRtc_Word32)fft[i], + outCFFT - aecm->dfaCleanQDomain); + fft[i] = (WebRtc_Word16)WEBRTC_SPL_SAT(WEBRTC_SPL_WORD16_MAX, + tmp32no1 + aecm->outBuf[i], + WEBRTC_SPL_WORD16_MIN); + output[i] = fft[i]; + + tmp32no1 = WEBRTC_SPL_MUL_16_16_RSFT( + fft[PART_LEN + i], + WebRtcAecm_kSqrtHanning[PART_LEN - i], + 14); + tmp32no1 = WEBRTC_SPL_SHIFT_W32(tmp32no1, + outCFFT - aecm->dfaCleanQDomain); + aecm->outBuf[i] = (WebRtc_Word16)WEBRTC_SPL_SAT( + WEBRTC_SPL_WORD16_MAX, + tmp32no1, + WEBRTC_SPL_WORD16_MIN); + } + +#ifdef ARM_WINM_LOG_ + // measure tick end + QueryPerformanceCounter((LARGE_INTEGER*)&end); + diff__ = ((end - start) * 1000) / (freq/1000); + milliseconds = (unsigned int)(diff__ & 0xffffffff); + WriteFile (logFile, &milliseconds, sizeof(unsigned int), &temp, NULL); +#endif + + // Copy the current block to the old position (aecm->outBuf is shifted elsewhere) + memcpy(aecm->xBuf, aecm->xBuf + PART_LEN, sizeof(WebRtc_Word16) * PART_LEN); + memcpy(aecm->dBufNoisy, aecm->dBufNoisy + PART_LEN, sizeof(WebRtc_Word16) * PART_LEN); + if (nearendClean != NULL) + { + memcpy(aecm->dBufClean, aecm->dBufClean + PART_LEN, sizeof(WebRtc_Word16) * PART_LEN); + } +} + +void WebRtcAecm_CalcLinearEnergies(AecmCore_t* aecm, + const WebRtc_UWord16* far_spectrum, + WebRtc_Word32* echo_est, + WebRtc_UWord32* far_energy, + WebRtc_UWord32* echo_energy_adapt, + WebRtc_UWord32* echo_energy_stored) +{ + int i; + + // Get energy for the delayed far end signal and estimated + // echo using both stored and adapted channels. + for (i = 0; i < PART_LEN1; i++) + { + echo_est[i] = WEBRTC_SPL_MUL_16_U16(aecm->channelStored[i], + far_spectrum[i]); + (*far_energy) += (WebRtc_UWord32)(far_spectrum[i]); + (*echo_energy_adapt) += WEBRTC_SPL_UMUL_16_16(aecm->channelAdapt16[i], + far_spectrum[i]); + (*echo_energy_stored) += (WebRtc_UWord32)echo_est[i]; + } +} + +void WebRtcAecm_StoreAdaptiveChannel(AecmCore_t* aecm, + const WebRtc_UWord16* far_spectrum, + WebRtc_Word32* echo_est) +{ + int i; + + // During startup we store the channel every block. + memcpy(aecm->channelStored, aecm->channelAdapt16, sizeof(WebRtc_Word16) * PART_LEN1); + // Recalculate echo estimate + for (i = 0; i < PART_LEN; i += 4) + { + echo_est[i] = WEBRTC_SPL_MUL_16_U16(aecm->channelStored[i], + far_spectrum[i]); + echo_est[i + 1] = WEBRTC_SPL_MUL_16_U16(aecm->channelStored[i + 1], + far_spectrum[i + 1]); + echo_est[i + 2] = WEBRTC_SPL_MUL_16_U16(aecm->channelStored[i + 2], + far_spectrum[i + 2]); + echo_est[i + 3] = WEBRTC_SPL_MUL_16_U16(aecm->channelStored[i + 3], + far_spectrum[i + 3]); + } + echo_est[i] = WEBRTC_SPL_MUL_16_U16(aecm->channelStored[i], + far_spectrum[i]); +} + +void WebRtcAecm_ResetAdaptiveChannel(AecmCore_t* aecm) +{ + int i; + + // The stored channel has a significantly lower MSE than the adaptive one for + // two consecutive calculations. Reset the adaptive channel. + memcpy(aecm->channelAdapt16, aecm->channelStored, + sizeof(WebRtc_Word16) * PART_LEN1); + // Restore the W32 channel + for (i = 0; i < PART_LEN; i += 4) + { + aecm->channelAdapt32[i] = WEBRTC_SPL_LSHIFT_W32( + (WebRtc_Word32)aecm->channelStored[i], 16); + aecm->channelAdapt32[i + 1] = WEBRTC_SPL_LSHIFT_W32( + (WebRtc_Word32)aecm->channelStored[i + 1], 16); + aecm->channelAdapt32[i + 2] = WEBRTC_SPL_LSHIFT_W32( + (WebRtc_Word32)aecm->channelStored[i + 2], 16); + aecm->channelAdapt32[i + 3] = WEBRTC_SPL_LSHIFT_W32( + (WebRtc_Word32)aecm->channelStored[i + 3], 16); + } + aecm->channelAdapt32[i] = WEBRTC_SPL_LSHIFT_W32((WebRtc_Word32)aecm->channelStored[i], 16); +} + +#endif // !(defined(WEBRTC_ANDROID) && defined(WEBRTC_ARCH_ARM_NEON)) + diff --git a/src/modules/audio_processing/aecm/main/source/aecm_core.h b/src/modules/audio_processing/aecm/main/source/aecm_core.h new file mode 100644 index 0000000..e431c71 --- /dev/null +++ b/src/modules/audio_processing/aecm/main/source/aecm_core.h @@ -0,0 +1,358 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +// Performs echo control (suppression) with fft routines in fixed-point + +#ifndef WEBRTC_MODULES_AUDIO_PROCESSING_AECM_MAIN_SOURCE_AECM_CORE_H_ +#define WEBRTC_MODULES_AUDIO_PROCESSING_AECM_MAIN_SOURCE_AECM_CORE_H_ + +#define AECM_DYNAMIC_Q // turn on/off dynamic Q-domain +//#define AECM_WITH_ABS_APPROX +//#define AECM_SHORT // for 32 sample partition length (otherwise 64) + +#include "typedefs.h" +#include "signal_processing_library.h" + +// Algorithm parameters + +#define FRAME_LEN 80 // Total frame length, 10 ms +#ifdef AECM_SHORT + +#define PART_LEN 32 // Length of partition +#define PART_LEN_SHIFT 6 // Length of (PART_LEN * 2) in base 2 + +#else + +#define PART_LEN 64 // Length of partition +#define PART_LEN_SHIFT 7 // Length of (PART_LEN * 2) in base 2 + +#endif + +#define PART_LEN1 (PART_LEN + 1) // Unique fft coefficients +#define PART_LEN2 (PART_LEN << 1) // Length of partition * 2 +#define PART_LEN4 (PART_LEN << 2) // Length of partition * 4 +#define FAR_BUF_LEN PART_LEN4 // Length of buffers +#define MAX_DELAY 100 + +// Counter parameters +#ifdef AECM_SHORT + +#define CONV_LEN 1024 // Convergence length used at startup +#else + +#define CONV_LEN 512 // Convergence length used at startup +#endif + +#define CONV_LEN2 (CONV_LEN << 1) // Convergence length * 2 used at startup +// Energy parameters +#define MAX_BUF_LEN 64 // History length of energy signals + +#define FAR_ENERGY_MIN 1025 // Lowest Far energy level: At least 2 in energy +#define FAR_ENERGY_DIFF 929 // Allowed difference between max and min + +#define ENERGY_DEV_OFFSET 0 // The energy error offset in Q8 +#define ENERGY_DEV_TOL 400 // The energy estimation tolerance in Q8 +#define FAR_ENERGY_VAD_REGION 230 // Far VAD tolerance region +// Stepsize parameters +#define MU_MIN 10 // Min stepsize 2^-MU_MIN (far end energy dependent) +#define MU_MAX 1 // Max stepsize 2^-MU_MAX (far end energy dependent) +#define MU_DIFF 9 // MU_MIN - MU_MAX +// Channel parameters +#define MIN_MSE_COUNT 20 // Min number of consecutive blocks with enough far end + // energy to compare channel estimates +#define MIN_MSE_DIFF 29 // The ratio between adapted and stored channel to + // accept a new storage (0.8 in Q-MSE_RESOLUTION) +#define MSE_RESOLUTION 5 // MSE parameter resolution +#define RESOLUTION_CHANNEL16 12 // W16 Channel in Q-RESOLUTION_CHANNEL16 +#define RESOLUTION_CHANNEL32 28 // W32 Channel in Q-RESOLUTION_CHANNEL +#define CHANNEL_VAD 16 // Minimum energy in frequency band to update channel +// Suppression gain parameters: SUPGAIN_ parameters in Q-(RESOLUTION_SUPGAIN) +#define RESOLUTION_SUPGAIN 8 // Channel in Q-(RESOLUTION_SUPGAIN) +#define SUPGAIN_DEFAULT (1 << RESOLUTION_SUPGAIN) // Default suppression gain +#define SUPGAIN_ERROR_PARAM_A 3072 // Estimation error parameter (Maximum gain) (8 in Q8) +#define SUPGAIN_ERROR_PARAM_B 1536 // Estimation error parameter (Gain before going down) +#define SUPGAIN_ERROR_PARAM_D SUPGAIN_DEFAULT // Estimation error parameter + // (Should be the same as Default) (1 in Q8) +#define SUPGAIN_EPC_DT 200 // = SUPGAIN_ERROR_PARAM_C * ENERGY_DEV_TOL +// Defines for "check delay estimation" +#define CORR_WIDTH 31 // Number of samples to correlate over. +#define CORR_MAX 16 // Maximum correlation offset +#define CORR_MAX_BUF 63 +#define CORR_DEV 4 +#define CORR_MAX_LEVEL 20 +#define CORR_MAX_LOW 4 +#define CORR_BUF_LEN (CORR_MAX << 1) + 1 +// Note that CORR_WIDTH + 2*CORR_MAX <= MAX_BUF_LEN + +#define ONE_Q14 (1 << 14) + +// NLP defines +#define NLP_COMP_LOW 3277 // 0.2 in Q14 +#define NLP_COMP_HIGH ONE_Q14 // 1 in Q14 + +extern const WebRtc_Word16 WebRtcAecm_kSqrtHanning[]; + +typedef struct { + WebRtc_Word16 real; + WebRtc_Word16 imag; +} complex16_t; + +typedef struct +{ + int farBufWritePos; + int farBufReadPos; + int knownDelay; + int lastKnownDelay; + int firstVAD; // Parameter to control poorly initialized channels + + void *farFrameBuf; + void *nearNoisyFrameBuf; + void *nearCleanFrameBuf; + void *outFrameBuf; + + WebRtc_Word16 farBuf[FAR_BUF_LEN]; + + WebRtc_Word16 mult; + WebRtc_UWord32 seed; + + // Delay estimation variables + void* delay_estimator; + WebRtc_UWord16 currentDelay; + + WebRtc_Word16 nlpFlag; + WebRtc_Word16 fixedDelay; + + WebRtc_UWord32 totCount; + + WebRtc_Word16 dfaCleanQDomain; + WebRtc_Word16 dfaCleanQDomainOld; + WebRtc_Word16 dfaNoisyQDomain; + WebRtc_Word16 dfaNoisyQDomainOld; + + WebRtc_Word16 nearLogEnergy[MAX_BUF_LEN]; + WebRtc_Word16 farLogEnergy; + WebRtc_Word16 echoAdaptLogEnergy[MAX_BUF_LEN]; + WebRtc_Word16 echoStoredLogEnergy[MAX_BUF_LEN]; + + // The extra 16 or 32 bytes in the following buffers are for alignment based Neon code. + // It's designed this way since the current GCC compiler can't align a buffer in 16 or 32 + // byte boundaries properly. + WebRtc_Word16 channelStored_buf[PART_LEN1 + 8]; + WebRtc_Word16 channelAdapt16_buf[PART_LEN1 + 8]; + WebRtc_Word32 channelAdapt32_buf[PART_LEN1 + 8]; + WebRtc_Word16 xBuf_buf[PART_LEN2 + 16]; // farend + WebRtc_Word16 dBufClean_buf[PART_LEN2 + 16]; // nearend + WebRtc_Word16 dBufNoisy_buf[PART_LEN2 + 16]; // nearend + WebRtc_Word16 outBuf_buf[PART_LEN + 8]; + + // Pointers to the above buffers + WebRtc_Word16 *channelStored; + WebRtc_Word16 *channelAdapt16; + WebRtc_Word32 *channelAdapt32; + WebRtc_Word16 *xBuf; + WebRtc_Word16 *dBufClean; + WebRtc_Word16 *dBufNoisy; + WebRtc_Word16 *outBuf; + + WebRtc_Word32 echoFilt[PART_LEN1]; + WebRtc_Word16 nearFilt[PART_LEN1]; + WebRtc_Word32 noiseEst[PART_LEN1]; + int noiseEstTooLowCtr[PART_LEN1]; + int noiseEstTooHighCtr[PART_LEN1]; + WebRtc_Word16 noiseEstCtr; + WebRtc_Word16 cngMode; + + WebRtc_Word32 mseAdaptOld; + WebRtc_Word32 mseStoredOld; + WebRtc_Word32 mseThreshold; + + WebRtc_Word16 farEnergyMin; + WebRtc_Word16 farEnergyMax; + WebRtc_Word16 farEnergyMaxMin; + WebRtc_Word16 farEnergyVAD; + WebRtc_Word16 farEnergyMSE; + WebRtc_Word16 currentVADValue; + WebRtc_Word16 vadUpdateCount; + + WebRtc_Word16 startupState; + WebRtc_Word16 mseChannelCount; + WebRtc_Word16 supGain; + WebRtc_Word16 supGainOld; + + WebRtc_Word16 supGainErrParamA; + WebRtc_Word16 supGainErrParamD; + WebRtc_Word16 supGainErrParamDiffAB; + WebRtc_Word16 supGainErrParamDiffBD; + +#ifdef AEC_DEBUG + FILE *farFile; + FILE *nearFile; + FILE *outFile; +#endif +} AecmCore_t; + +/////////////////////////////////////////////////////////////////////////////////////////////// +// WebRtcAecm_CreateCore(...) +// +// Allocates the memory needed by the AECM. The memory needs to be +// initialized separately using the WebRtcAecm_InitCore() function. +// +// Input: +// - aecm : Instance that should be created +// +// Output: +// - aecm : Created instance +// +// Return value : 0 - Ok +// -1 - Error +// +int WebRtcAecm_CreateCore(AecmCore_t **aecm); + +/////////////////////////////////////////////////////////////////////////////////////////////// +// WebRtcAecm_InitCore(...) +// +// This function initializes the AECM instant created with WebRtcAecm_CreateCore(...) +// Input: +// - aecm : Pointer to the AECM instance +// - samplingFreq : Sampling Frequency +// +// Output: +// - aecm : Initialized instance +// +// Return value : 0 - Ok +// -1 - Error +// +int WebRtcAecm_InitCore(AecmCore_t * const aecm, int samplingFreq); + +/////////////////////////////////////////////////////////////////////////////////////////////// +// WebRtcAecm_FreeCore(...) +// +// This function releases the memory allocated by WebRtcAecm_CreateCore() +// Input: +// - aecm : Pointer to the AECM instance +// +// Return value : 0 - Ok +// -1 - Error +// 11001-11016: Error +// +int WebRtcAecm_FreeCore(AecmCore_t *aecm); + +int WebRtcAecm_Control(AecmCore_t *aecm, int delay, int nlpFlag); + +/////////////////////////////////////////////////////////////////////////////////////////////// +// WebRtcAecm_InitEchoPathCore(...) +// +// This function resets the echo channel adaptation with the specified channel. +// Input: +// - aecm : Pointer to the AECM instance +// - echo_path : Pointer to the data that should initialize the echo path +// +// Output: +// - aecm : Initialized instance +// +void WebRtcAecm_InitEchoPathCore(AecmCore_t* aecm, const WebRtc_Word16* echo_path); + +/////////////////////////////////////////////////////////////////////////////////////////////// +// WebRtcAecm_ProcessFrame(...) +// +// This function processes frames and sends blocks to WebRtcAecm_ProcessBlock(...) +// +// Inputs: +// - aecm : Pointer to the AECM instance +// - farend : In buffer containing one frame of echo signal +// - nearendNoisy : In buffer containing one frame of nearend+echo signal without NS +// - nearendClean : In buffer containing one frame of nearend+echo signal with NS +// +// Output: +// - out : Out buffer, one frame of nearend signal : +// +// +int WebRtcAecm_ProcessFrame(AecmCore_t * aecm, const WebRtc_Word16 * farend, + const WebRtc_Word16 * nearendNoisy, + const WebRtc_Word16 * nearendClean, + WebRtc_Word16 * out); + +/////////////////////////////////////////////////////////////////////////////////////////////// +// WebRtcAecm_ProcessBlock(...) +// +// This function is called for every block within one frame +// This function is called by WebRtcAecm_ProcessFrame(...) +// +// Inputs: +// - aecm : Pointer to the AECM instance +// - farend : In buffer containing one block of echo signal +// - nearendNoisy : In buffer containing one frame of nearend+echo signal without NS +// - nearendClean : In buffer containing one frame of nearend+echo signal with NS +// +// Output: +// - out : Out buffer, one block of nearend signal : +// +// +int WebRtcAecm_ProcessBlock(AecmCore_t * aecm, const WebRtc_Word16 * farend, + const WebRtc_Word16 * nearendNoisy, + const WebRtc_Word16 * noisyClean, + WebRtc_Word16 * out); + +/////////////////////////////////////////////////////////////////////////////////////////////// +// WebRtcAecm_BufferFarFrame() +// +// Inserts a frame of data into farend buffer. +// +// Inputs: +// - aecm : Pointer to the AECM instance +// - farend : In buffer containing one frame of farend signal +// - farLen : Length of frame +// +void WebRtcAecm_BufferFarFrame(AecmCore_t * const aecm, const WebRtc_Word16 * const farend, + const int farLen); + +/////////////////////////////////////////////////////////////////////////////////////////////// +// WebRtcAecm_FetchFarFrame() +// +// Read the farend buffer to account for known delay +// +// Inputs: +// - aecm : Pointer to the AECM instance +// - farend : In buffer containing one frame of farend signal +// - farLen : Length of frame +// - knownDelay : known delay +// +void WebRtcAecm_FetchFarFrame(AecmCore_t * const aecm, WebRtc_Word16 * const farend, + const int farLen, const int knownDelay); + +/////////////////////////////////////////////////////////////////////////////////////////////// +// Some internal functions shared by ARM NEON and generic C code: +// + +void WebRtcAecm_CalcLinearEnergies(AecmCore_t* aecm, + const WebRtc_UWord16* far_spectrum, + WebRtc_Word32* echoEst, + WebRtc_UWord32* far_energy, + WebRtc_UWord32* echo_energy_adapt, + WebRtc_UWord32* echo_energy_stored); + +void WebRtcAecm_StoreAdaptiveChannel(AecmCore_t* aecm, + const WebRtc_UWord16* far_spectrum, + WebRtc_Word32* echo_est); + +void WebRtcAecm_ResetAdaptiveChannel(AecmCore_t *aecm); + +void WebRtcAecm_WindowAndFFT(WebRtc_Word16* fft, + const WebRtc_Word16* time_signal, + complex16_t* freq_signal, + int time_signal_scaling); + +void WebRtcAecm_InverseFFTAndWindow(AecmCore_t* aecm, + WebRtc_Word16* fft, + complex16_t* efw, + WebRtc_Word16* output, + const WebRtc_Word16* nearendClean); + +#endif diff --git a/src/modules/audio_processing/aecm/main/source/aecm_core_neon.c b/src/modules/audio_processing/aecm/main/source/aecm_core_neon.c new file mode 100644 index 0000000..86ced1e --- /dev/null +++ b/src/modules/audio_processing/aecm/main/source/aecm_core_neon.c @@ -0,0 +1,314 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ +#if defined(WEBRTC_ANDROID) && defined(WEBRTC_ARCH_ARM_NEON) + +#include "aecm_core.h" + +#include +#include + + +// Square root of Hanning window in Q14. +static const WebRtc_Word16 kSqrtHanningReversed[] __attribute__ ((aligned (8))) = { + 16384, 16373, 16354, 16325, + 16286, 16237, 16179, 16111, + 16034, 15947, 15851, 15746, + 15631, 15506, 15373, 15231, + 15079, 14918, 14749, 14571, + 14384, 14189, 13985, 13773, + 13553, 13325, 13089, 12845, + 12594, 12335, 12068, 11795, + 11514, 11227, 10933, 10633, + 10326, 10013, 9695, 9370, + 9040, 8705, 8364, 8019, + 7668, 7313, 6954, 6591, + 6224, 5853, 5478, 5101, + 4720, 4337, 3951, 3562, + 3172, 2780, 2386, 1990, + 1594, 1196, 798, 399 +}; + +void WebRtcAecm_WindowAndFFT(WebRtc_Word16* fft, + const WebRtc_Word16* time_signal, + complex16_t* freq_signal, + int time_signal_scaling) +{ + int i, j; + + int16x4_t tmp16x4_scaling = vdup_n_s16(time_signal_scaling); + __asm__("vmov.i16 d21, #0" ::: "d21"); + + for(i = 0, j = 0; i < PART_LEN; i += 4, j += 8) + { + int16x4_t tmp16x4_0; + int16x4_t tmp16x4_1; + int32x4_t tmp32x4_0; + + /* Window near end */ + // fft[j] = (WebRtc_Word16)WEBRTC_SPL_MUL_16_16_RSFT((time_signal[i] + // << time_signal_scaling), WebRtcAecm_kSqrtHanning[i], 14); + __asm__("vld1.16 %P0, [%1, :64]" : "=w"(tmp16x4_0) : "r"(&time_signal[i])); + tmp16x4_0 = vshl_s16(tmp16x4_0, tmp16x4_scaling); + + __asm__("vld1.16 %P0, [%1, :64]" : "=w"(tmp16x4_1) : "r"(&WebRtcAecm_kSqrtHanning[i])); + tmp32x4_0 = vmull_s16(tmp16x4_0, tmp16x4_1); + + __asm__("vshrn.i32 d20, %q0, #14" : : "w"(tmp32x4_0) : "d20"); + __asm__("vst2.16 {d20, d21}, [%0, :128]" : : "r"(&fft[j]) : "q10"); + + // fft[PART_LEN2 + j] = (WebRtc_Word16)WEBRTC_SPL_MUL_16_16_RSFT( + // (time_signal[PART_LEN + i] << time_signal_scaling), + // WebRtcAecm_kSqrtHanning[PART_LEN - i], 14); + __asm__("vld1.16 %P0, [%1, :64]" : "=w"(tmp16x4_0) : "r"(&time_signal[i + PART_LEN])); + tmp16x4_0 = vshl_s16(tmp16x4_0, tmp16x4_scaling); + + __asm__("vld1.16 %P0, [%1, :64]" : "=w"(tmp16x4_1) : "r"(&kSqrtHanningReversed[i])); + tmp32x4_0 = vmull_s16(tmp16x4_0, tmp16x4_1); + + __asm__("vshrn.i32 d20, %q0, #14" : : "w"(tmp32x4_0) : "d20"); + __asm__("vst2.16 {d20, d21}, [%0, :128]" : : "r"(&fft[PART_LEN2 + j]) : "q10"); + } + + WebRtcSpl_ComplexBitReverse(fft, PART_LEN_SHIFT); + WebRtcSpl_ComplexFFT(fft, PART_LEN_SHIFT, 1); + + // Take only the first PART_LEN2 samples, and switch the sign of the imaginary part. + for(i = 0, j = 0; j < PART_LEN2; i += 8, j += 16) + { + __asm__("vld2.16 {d20, d21, d22, d23}, [%0, :256]" : : "r"(&fft[j]) : "q10", "q11"); + __asm__("vneg.s16 d22, d22" : : : "q10"); + __asm__("vneg.s16 d23, d23" : : : "q11"); + __asm__("vst2.16 {d20, d21, d22, d23}, [%0, :256]" : : + "r"(&freq_signal[i].real): "q10", "q11"); + } +} + +void WebRtcAecm_InverseFFTAndWindow(AecmCore_t* aecm, + WebRtc_Word16* fft, + complex16_t* efw, + WebRtc_Word16* output, + const WebRtc_Word16* nearendClean) +{ + int i, j, outCFFT; + WebRtc_Word32 tmp32no1; + + // Synthesis + for(i = 0, j = 0; i < PART_LEN; i += 4, j += 8) + { + // We overwrite two more elements in fft[], but it's ok. + __asm__("vld2.16 {d20, d21}, [%0, :128]" : : "r"(&(efw[i].real)) : "q10"); + __asm__("vmov q11, q10" : : : "q10", "q11"); + + __asm__("vneg.s16 d23, d23" : : : "q11"); + __asm__("vst2.16 {d22, d23}, [%0, :128]" : : "r"(&fft[j]): "q11"); + + __asm__("vrev64.16 q10, q10" : : : "q10"); + __asm__("vst2.16 {d20, d21}, [%0]" : : "r"(&fft[PART_LEN4 - j - 6]): "q10"); + } + + fft[PART_LEN2] = efw[PART_LEN].real; + fft[PART_LEN2 + 1] = -efw[PART_LEN].imag; + + // Inverse FFT, result should be scaled with outCFFT. + WebRtcSpl_ComplexBitReverse(fft, PART_LEN_SHIFT); + outCFFT = WebRtcSpl_ComplexIFFT(fft, PART_LEN_SHIFT, 1); + + // Take only the real values and scale with outCFFT. + for (i = 0, j = 0; i < PART_LEN2; i += 8, j+= 16) + { + __asm__("vld2.16 {d20, d21, d22, d23}, [%0, :256]" : : "r"(&fft[j]) : "q10", "q11"); + __asm__("vst1.16 {d20, d21}, [%0, :128]" : : "r"(&fft[i]): "q10"); + } + + int32x4_t tmp32x4_2; + __asm__("vdup.32 %q0, %1" : "=w"(tmp32x4_2) : "r"((WebRtc_Word32) + (outCFFT - aecm->dfaCleanQDomain))); + for (i = 0; i < PART_LEN; i += 4) + { + int16x4_t tmp16x4_0; + int16x4_t tmp16x4_1; + int32x4_t tmp32x4_0; + int32x4_t tmp32x4_1; + + // fft[i] = (WebRtc_Word16)WEBRTC_SPL_MUL_16_16_RSFT_WITH_ROUND( + // fft[i], WebRtcAecm_kSqrtHanning[i], 14); + __asm__("vld1.16 %P0, [%1, :64]" : "=w"(tmp16x4_0) : "r"(&fft[i])); + __asm__("vld1.16 %P0, [%1, :64]" : "=w"(tmp16x4_1) : "r"(&WebRtcAecm_kSqrtHanning[i])); + __asm__("vmull.s16 %q0, %P1, %P2" : "=w"(tmp32x4_0) : "w"(tmp16x4_0), "w"(tmp16x4_1)); + __asm__("vrshr.s32 %q0, %q1, #14" : "=w"(tmp32x4_0) : "0"(tmp32x4_0)); + + // tmp32no1 = WEBRTC_SPL_SHIFT_W32((WebRtc_Word32)fft[i], + // outCFFT - aecm->dfaCleanQDomain); + __asm__("vshl.s32 %q0, %q1, %q2" : "=w"(tmp32x4_0) : "0"(tmp32x4_0), "w"(tmp32x4_2)); + + // fft[i] = (WebRtc_Word16)WEBRTC_SPL_SAT(WEBRTC_SPL_WORD16_MAX, + // tmp32no1 + outBuf[i], WEBRTC_SPL_WORD16_MIN); + // output[i] = fft[i]; + __asm__("vld1.16 %P0, [%1, :64]" : "=w"(tmp16x4_0) : "r"(&aecm->outBuf[i])); + __asm__("vmovl.s16 %q0, %P1" : "=w"(tmp32x4_1) : "w"(tmp16x4_0)); + __asm__("vadd.i32 %q0, %q1" : : "w"(tmp32x4_0), "w"(tmp32x4_1)); + __asm__("vqshrn.s32 %P0, %q1, #0" : "=w"(tmp16x4_0) : "w"(tmp32x4_0)); + __asm__("vst1.16 %P0, [%1, :64]" : : "w"(tmp16x4_0), "r"(&fft[i])); + __asm__("vst1.16 %P0, [%1, :64]" : : "w"(tmp16x4_0), "r"(&output[i])); + + // tmp32no1 = WEBRTC_SPL_MUL_16_16_RSFT( + // fft[PART_LEN + i], WebRtcAecm_kSqrtHanning[PART_LEN - i], 14); + __asm__("vld1.16 %P0, [%1, :64]" : "=w"(tmp16x4_0) : "r"(&fft[PART_LEN + i])); + __asm__("vld1.16 %P0, [%1, :64]" : "=w"(tmp16x4_1) : "r"(&kSqrtHanningReversed[i])); + __asm__("vmull.s16 %q0, %P1, %P2" : "=w"(tmp32x4_0) : "w"(tmp16x4_0), "w"(tmp16x4_1)); + __asm__("vshr.s32 %q0, %q1, #14" : "=w"(tmp32x4_0) : "0"(tmp32x4_0)); + + // tmp32no1 = WEBRTC_SPL_SHIFT_W32(tmp32no1, outCFFT - aecm->dfaCleanQDomain); + __asm__("vshl.s32 %q0, %q1, %q2" : "=w"(tmp32x4_0) : "0"(tmp32x4_0), "w"(tmp32x4_2)); + // outBuf[i] = (WebRtc_Word16)WEBRTC_SPL_SAT( + // WEBRTC_SPL_WORD16_MAX, tmp32no1, WEBRTC_SPL_WORD16_MIN); + __asm__("vqshrn.s32 %P0, %q1, #0" : "=w"(tmp16x4_0) : "w"(tmp32x4_0)); + __asm__("vst1.16 %P0, [%1, :64]" : : "w"(tmp16x4_0), "r"(&aecm->outBuf[i])); + } + + // Copy the current block to the old position (outBuf is shifted elsewhere). + for (i = 0; i < PART_LEN; i += 16) + { + __asm__("vld1.16 {d20, d21, d22, d23}, [%0, :256]" : : + "r"(&aecm->xBuf[i + PART_LEN]) : "q10"); + __asm__("vst1.16 {d20, d21, d22, d23}, [%0, :256]" : : "r"(&aecm->xBuf[i]): "q10"); + } + for (i = 0; i < PART_LEN; i += 16) + { + __asm__("vld1.16 {d20, d21, d22, d23}, [%0, :256]" : : + "r"(&aecm->dBufNoisy[i + PART_LEN]) : "q10"); + __asm__("vst1.16 {d20, d21, d22, d23}, [%0, :256]" : : + "r"(&aecm->dBufNoisy[i]): "q10"); + } + if (nearendClean != NULL) { + for (i = 0; i < PART_LEN; i += 16) + { + __asm__("vld1.16 {d20, d21, d22, d23}, [%0, :256]" : : + "r"(&aecm->dBufClean[i + PART_LEN]) : "q10"); + __asm__("vst1.16 {d20, d21, d22, d23}, [%0, :256]" : : + "r"(&aecm->dBufClean[i]): "q10"); + } + } +} + +void WebRtcAecm_CalcLinearEnergies(AecmCore_t* aecm, + const WebRtc_UWord16* far_spectrum, + WebRtc_Word32* echo_est, + WebRtc_UWord32* far_energy, + WebRtc_UWord32* echo_energy_adapt, + WebRtc_UWord32* echo_energy_stored) +{ + int i; + + register WebRtc_UWord32 far_energy_r; + register WebRtc_UWord32 echo_energy_stored_r; + register WebRtc_UWord32 echo_energy_adapt_r; + uint32x4_t tmp32x4_0; + + __asm__("vmov.i32 q14, #0" : : : "q14"); // far_energy + __asm__("vmov.i32 q8, #0" : : : "q8"); // echo_energy_stored + __asm__("vmov.i32 q9, #0" : : : "q9"); // echo_energy_adapt + + for(i = 0; i < PART_LEN -7; i += 8) + { + // far_energy += (WebRtc_UWord32)(far_spectrum[i]); + __asm__("vld1.16 {d26, d27}, [%0]" : : "r"(&far_spectrum[i]) : "q13"); + __asm__("vaddw.u16 q14, q14, d26" : : : "q14", "q13"); + __asm__("vaddw.u16 q14, q14, d27" : : : "q14", "q13"); + + // Get estimated echo energies for adaptive channel and stored channel. + // echoEst[i] = WEBRTC_SPL_MUL_16_U16(aecm->channelStored[i], far_spectrum[i]); + __asm__("vld1.16 {d24, d25}, [%0, :128]" : : "r"(&aecm->channelStored[i]) : "q12"); + __asm__("vmull.u16 q10, d26, d24" : : : "q12", "q13", "q10"); + __asm__("vmull.u16 q11, d27, d25" : : : "q12", "q13", "q11"); + __asm__("vst1.32 {d20, d21, d22, d23}, [%0, :256]" : : "r"(&echo_est[i]): + "q10", "q11"); + + // echo_energy_stored += (WebRtc_UWord32)echoEst[i]; + __asm__("vadd.u32 q8, q10" : : : "q10", "q8"); + __asm__("vadd.u32 q8, q11" : : : "q11", "q8"); + + // echo_energy_adapt += WEBRTC_SPL_UMUL_16_16( + // aecm->channelAdapt16[i], far_spectrum[i]); + __asm__("vld1.16 {d24, d25}, [%0, :128]" : : "r"(&aecm->channelAdapt16[i]) : "q12"); + __asm__("vmull.u16 q10, d26, d24" : : : "q12", "q13", "q10"); + __asm__("vmull.u16 q11, d27, d25" : : : "q12", "q13", "q11"); + __asm__("vadd.u32 q9, q10" : : : "q9", "q15"); + __asm__("vadd.u32 q9, q11" : : : "q9", "q11"); + } + + __asm__("vadd.u32 d28, d29" : : : "q14"); + __asm__("vpadd.u32 d28, d28" : : : "q14"); + __asm__("vmov.32 %0, d28[0]" : "=r"(far_energy_r): : "q14"); + + __asm__("vadd.u32 d18, d19" : : : "q9"); + __asm__("vpadd.u32 d18, d18" : : : "q9"); + __asm__("vmov.32 %0, d18[0]" : "=r"(echo_energy_adapt_r): : "q9"); + + __asm__("vadd.u32 d16, d17" : : : "q8"); + __asm__("vpadd.u32 d16, d16" : : : "q8"); + __asm__("vmov.32 %0, d16[0]" : "=r"(echo_energy_stored_r): : "q8"); + + // Get estimated echo energies for adaptive channel and stored channel. + echo_est[i] = WEBRTC_SPL_MUL_16_U16(aecm->channelStored[i], far_spectrum[i]); + *echo_energy_stored = echo_energy_stored_r + (WebRtc_UWord32)echo_est[i]; + *far_energy = far_energy_r + (WebRtc_UWord32)(far_spectrum[i]); + *echo_energy_adapt = echo_energy_adapt_r + WEBRTC_SPL_UMUL_16_16( + aecm->channelAdapt16[i], far_spectrum[i]); +} + +void WebRtcAecm_StoreAdaptiveChannel(AecmCore_t* aecm, + const WebRtc_UWord16* far_spectrum, + WebRtc_Word32* echo_est) +{ + int i; + + // During startup we store the channel every block. + // Recalculate echo estimate. + for(i = 0; i < PART_LEN -7; i += 8) + { + // aecm->channelStored[i] = acem->channelAdapt16[i]; + // echo_est[i] = WEBRTC_SPL_MUL_16_U16(aecm->channelStored[i], far_spectrum[i]); + __asm__("vld1.16 {d26, d27}, [%0]" : : "r"(&far_spectrum[i]) : "q13"); + __asm__("vld1.16 {d24, d25}, [%0, :128]" : : "r"(&aecm->channelAdapt16[i]) : "q12"); + __asm__("vst1.16 {d24, d25}, [%0, :128]" : : "r"(&aecm->channelStored[i]) : "q12"); + __asm__("vmull.u16 q10, d26, d24" : : : "q12", "q13", "q10"); + __asm__("vmull.u16 q11, d27, d25" : : : "q12", "q13", "q11"); + __asm__("vst1.16 {d20, d21, d22, d23}, [%0, :256]" : : + "r"(&echo_est[i]) : "q10", "q11"); + } + aecm->channelStored[i] = aecm->channelAdapt16[i]; + echo_est[i] = WEBRTC_SPL_MUL_16_U16(aecm->channelStored[i], far_spectrum[i]); +} + +void WebRtcAecm_ResetAdaptiveChannel(AecmCore_t* aecm) +{ + int i; + + for(i = 0; i < PART_LEN -7; i += 8) + { + // aecm->channelAdapt16[i] = aecm->channelStored[i]; + // aecm->channelAdapt32[i] = WEBRTC_SPL_LSHIFT_W32((WebRtc_Word32) + // aecm->channelStored[i], 16); + __asm__("vld1.16 {d24, d25}, [%0, :128]" : : + "r"(&aecm->channelStored[i]) : "q12"); + __asm__("vst1.16 {d24, d25}, [%0, :128]" : : + "r"(&aecm->channelAdapt16[i]) : "q12"); + __asm__("vshll.s16 q10, d24, #16" : : : "q12", "q13", "q10"); + __asm__("vshll.s16 q11, d25, #16" : : : "q12", "q13", "q11"); + __asm__("vst1.16 {d20, d21, d22, d23}, [%0, :256]" : : + "r"(&aecm->channelAdapt32[i]): "q10", "q11"); + } + aecm->channelAdapt16[i] = aecm->channelStored[i]; + aecm->channelAdapt32[i] = WEBRTC_SPL_LSHIFT_W32( + (WebRtc_Word32)aecm->channelStored[i], 16); +} + +#endif // #if defined(WEBRTC_ANDROID) && defined(WEBRTC_ARCH_ARM_NEON) diff --git a/src/modules/audio_processing/aecm/main/source/aecm_delay_estimator.c b/src/modules/audio_processing/aecm/main/source/aecm_delay_estimator.c new file mode 100644 index 0000000..2ed9e03 --- /dev/null +++ b/src/modules/audio_processing/aecm/main/source/aecm_delay_estimator.c @@ -0,0 +1,604 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +#include "aecm_delay_estimator.h" + +#include +#include + +#include "signal_processing_library.h" +#include "typedefs.h" + +typedef struct +{ + // Pointers to mean values of spectrum and bit counts + WebRtc_Word32* mean_far_spectrum; + WebRtc_Word32* mean_near_spectrum; + WebRtc_Word32* mean_bit_counts; + + // Arrays only used locally in DelayEstimatorProcess() but whose size + // is determined at run-time. + WebRtc_Word32* bit_counts; + WebRtc_Word32* far_spectrum_32; + WebRtc_Word32* near_spectrum_32; + + // Binary history variables + WebRtc_UWord32* binary_far_history; + + // Far end history variables + WebRtc_UWord16* far_history; + int far_history_position; + WebRtc_Word16* far_q_domains; + + // Delay histogram variables + WebRtc_Word16* delay_histogram; + WebRtc_Word16 vad_counter; + + // Delay memory + int last_delay; + + // Buffer size parameters + int history_size; + int spectrum_size; + +} DelayEstimator_t; + +// Only bit |kBandFirst| through bit |kBandLast| are processed +// |kBandFirst| - |kBandLast| must be < 32 +static const int kBandFirst = 12; +static const int kBandLast = 43; + +static __inline WebRtc_UWord32 SetBit(WebRtc_UWord32 in, + WebRtc_Word32 pos) +{ + WebRtc_UWord32 mask = WEBRTC_SPL_LSHIFT_W32(1, pos); + WebRtc_UWord32 out = (in | mask); + + return out; +} + +// Compares the binary vector |binary_vector| with all rows of the binary +// matrix |binary_matrix| and counts per row the number of times they have the +// same value. +// Input: +// - binary_vector : binary "vector" stored in a long +// - binary_matrix : binary "matrix" stored as a vector of long +// - matrix_size : size of binary "matrix" +// Output: +// - bit_counts : "Vector" stored as a long, containing for each +// row the number of times the matrix row and the +// input vector have the same value +// +static void BitCountComparison(const WebRtc_UWord32 binary_vector, + const WebRtc_UWord32* binary_matrix, + int matrix_size, + WebRtc_Word32* bit_counts) +{ + int n = 0; + WebRtc_UWord32 a = binary_vector; + register WebRtc_UWord32 tmp; + + // compare binary vector |binary_vector| with all rows of the binary matrix + // |binary_matrix| + for (; n < matrix_size; n++) + { + a = (binary_vector ^ binary_matrix[n]); + // Returns bit counts in tmp + tmp = a - ((a >> 1) & 033333333333) - ((a >> 2) & 011111111111); + tmp = ((tmp + (tmp >> 3)) & 030707070707); + tmp = (tmp + (tmp >> 6)); + tmp = (tmp + (tmp >> 12) + (tmp >> 24)) & 077; + + bit_counts[n] = (WebRtc_Word32)tmp; + } +} + +// Computes the binary spectrum by comparing the input |spectrum| with a +// |threshold_spectrum|. +// +// Input: +// - spectrum : Spectrum of which the binary spectrum should +// be calculated. +// - threshold_spectrum : Threshold spectrum with which the input +// spectrum is compared. +// Return: +// - out : Binary spectrum +// +static WebRtc_UWord32 GetBinarySpectrum(WebRtc_Word32* spectrum, + WebRtc_Word32* threshold_spectrum) +{ + int k = kBandFirst; + WebRtc_UWord32 out = 0; + + for (; k <= kBandLast; k++) + { + if (spectrum[k] > threshold_spectrum[k]) + { + out = SetBit(out, k - kBandFirst); + } + } + + return out; +} + +// Calculates the mean recursively. +// +// Input: +// - new_value : new additional value +// - factor : factor for smoothing +// +// Input/Output: +// - mean_value : pointer to the mean value that should be updated +// +static void MeanEstimator(const WebRtc_Word32 new_value, + int factor, + WebRtc_Word32* mean_value) +{ + WebRtc_Word32 mean_new = *mean_value; + WebRtc_Word32 diff = new_value - mean_new; + + // mean_new = mean_value + ((new_value - mean_value) >> factor); + if (diff < 0) + { + diff = -WEBRTC_SPL_RSHIFT_W32(-diff, factor); + } + else + { + diff = WEBRTC_SPL_RSHIFT_W32(diff, factor); + } + mean_new += diff; + + *mean_value = mean_new; +} + +// Moves the pointer to the next entry and inserts new far end spectrum and +// corresponding Q-domain in its buffer. +// +// Input: +// - handle : Pointer to the delay estimation instance +// - far_spectrum : Pointer to the far end spectrum +// - far_q : Q-domain of far end spectrum +// +static void UpdateFarHistory(DelayEstimator_t* self, + WebRtc_UWord16* far_spectrum, + WebRtc_Word16 far_q) +{ + // Get new buffer position + self->far_history_position++; + if (self->far_history_position >= self->history_size) + { + self->far_history_position = 0; + } + // Update Q-domain buffer + self->far_q_domains[self->far_history_position] = far_q; + // Update far end spectrum buffer + memcpy(&(self->far_history[self->far_history_position * self->spectrum_size]), + far_spectrum, + sizeof(WebRtc_UWord16) * self->spectrum_size); +} + +int WebRtcAecm_FreeDelayEstimator(void* handle) +{ + DelayEstimator_t* self = (DelayEstimator_t*)handle; + + if (self == NULL) + { + return -1; + } + + if (self->mean_far_spectrum != NULL) + { + free(self->mean_far_spectrum); + self->mean_far_spectrum = NULL; + } + if (self->mean_near_spectrum != NULL) + { + free(self->mean_near_spectrum); + self->mean_near_spectrum = NULL; + } + if (self->mean_bit_counts != NULL) + { + free(self->mean_bit_counts); + self->mean_bit_counts = NULL; + } + if (self->bit_counts != NULL) + { + free(self->bit_counts); + self->bit_counts = NULL; + } + if (self->far_spectrum_32 != NULL) + { + free(self->far_spectrum_32); + self->far_spectrum_32 = NULL; + } + if (self->near_spectrum_32 != NULL) + { + free(self->near_spectrum_32); + self->near_spectrum_32 = NULL; + } + if (self->far_history != NULL) + { + free(self->far_history); + self->far_history = NULL; + } + if (self->binary_far_history != NULL) + { + free(self->binary_far_history); + self->binary_far_history = NULL; + } + if (self->far_q_domains != NULL) + { + free(self->far_q_domains); + self->far_q_domains = NULL; + } + if (self->delay_histogram != NULL) + { + free(self->delay_histogram); + self->delay_histogram = NULL; + } + + free(self); + + return 0; +} + +int WebRtcAecm_CreateDelayEstimator(void** handle, + int spectrum_size, + int history_size) +{ + DelayEstimator_t *self = NULL; + // Check if the sub band used in the delay estimation is small enough to + // fit in a Word32. + assert(kBandLast - kBandFirst < 32); + if (spectrum_size < kBandLast) + { + return -1; + } + if (history_size < 0) + { + return -1; + } + + self = malloc(sizeof(DelayEstimator_t)); + *handle = self; + if (self == NULL) + { + return -1; + } + + self->mean_far_spectrum = NULL; + self->mean_near_spectrum = NULL; + self->bit_counts = NULL; + self->far_spectrum_32 = NULL; + self->near_spectrum_32 = NULL; + self->far_history = NULL; + self->mean_bit_counts = NULL; + self->binary_far_history = NULL; + self->far_q_domains = NULL; + self->delay_histogram = NULL; + + // Allocate memory for spectrum buffers + self->mean_far_spectrum = malloc(spectrum_size * sizeof(WebRtc_Word32)); + if (self->mean_far_spectrum == NULL) + { + WebRtcAecm_FreeDelayEstimator(self); + self = NULL; + return -1; + } + self->mean_near_spectrum = malloc(spectrum_size * sizeof(WebRtc_Word32)); + if (self->mean_near_spectrum == NULL) + { + WebRtcAecm_FreeDelayEstimator(self); + self = NULL; + return -1; + } + self->mean_bit_counts = malloc(history_size * sizeof(WebRtc_Word32)); + if (self->mean_bit_counts == NULL) + { + WebRtcAecm_FreeDelayEstimator(self); + self = NULL; + return -1; + } + self->bit_counts = malloc(history_size * sizeof(WebRtc_Word32)); + if (self->bit_counts == NULL) + { + WebRtcAecm_FreeDelayEstimator(self); + self = NULL; + return -1; + } + self->far_spectrum_32 = malloc(spectrum_size * sizeof(WebRtc_Word32)); + if (self->far_spectrum_32 == NULL) + { + WebRtcAecm_FreeDelayEstimator(self); + self = NULL; + return -1; + } + self->near_spectrum_32 = malloc(spectrum_size * sizeof(WebRtc_Word32)); + if (self->near_spectrum_32 == NULL) + { + WebRtcAecm_FreeDelayEstimator(self); + self = NULL; + return -1; + } + // Allocate memory for history buffers + self->far_history = malloc(spectrum_size * history_size * + sizeof(WebRtc_UWord16)); + if (self->far_history == NULL) + { + WebRtcAecm_FreeDelayEstimator(self); + self = NULL; + return -1; + } + self->binary_far_history = malloc(history_size * sizeof(WebRtc_UWord32)); + if (self->binary_far_history == NULL) + { + WebRtcAecm_FreeDelayEstimator(self); + self = NULL; + return -1; + } + self->far_q_domains = malloc(history_size * sizeof(WebRtc_Word16)); + if (self->far_q_domains == NULL) + { + WebRtcAecm_FreeDelayEstimator(self); + self = NULL; + return -1; + } + self->delay_histogram = malloc(history_size * sizeof(WebRtc_Word16)); + if (self->delay_histogram == NULL) + { + WebRtcAecm_FreeDelayEstimator(self); + self = NULL; + return -1; + } + + self->spectrum_size = spectrum_size; + self->history_size = history_size; + + return 0; +} + +int WebRtcAecm_InitDelayEstimator(void* handle) +{ + DelayEstimator_t* self = (DelayEstimator_t*)handle; + + if (self == NULL) + { + return -1; + } + // Set averaged far and near end spectra to zero + memset(self->mean_far_spectrum, + 0, + sizeof(WebRtc_Word32) * self->spectrum_size); + memset(self->mean_near_spectrum, + 0, + sizeof(WebRtc_Word32) * self->spectrum_size); + // Set averaged bit counts to zero + memset(self->mean_bit_counts, + 0, + sizeof(WebRtc_Word32) * self->history_size); + memset(self->bit_counts, + 0, + sizeof(WebRtc_Word32) * self->history_size); + memset(self->far_spectrum_32, + 0, + sizeof(WebRtc_Word32) * self->spectrum_size); + memset(self->near_spectrum_32, + 0, + sizeof(WebRtc_Word32) * self->spectrum_size); + // Set far end histories to zero + memset(self->binary_far_history, + 0, + sizeof(WebRtc_UWord32) * self->history_size); + memset(self->far_history, + 0, + sizeof(WebRtc_UWord16) * self->spectrum_size * + self->history_size); + memset(self->far_q_domains, + 0, + sizeof(WebRtc_Word16) * self->history_size); + + self->far_history_position = self->history_size; + // Set delay histogram to zero + memset(self->delay_histogram, + 0, + sizeof(WebRtc_Word16) * self->history_size); + // Set VAD counter to zero + self->vad_counter = 0; + // Set delay memory to zero + self->last_delay = 0; + + return 0; +} + +int WebRtcAecm_DelayEstimatorProcess(void* handle, + WebRtc_UWord16* far_spectrum, + WebRtc_UWord16* near_spectrum, + int spectrum_size, + WebRtc_Word16 far_q, + WebRtc_Word16 vad_value) +{ + DelayEstimator_t* self = (DelayEstimator_t*)handle; + + WebRtc_UWord32 bxspectrum, byspectrum; + + int i; + + WebRtc_Word32 dtmp1; + + WebRtc_Word16 maxHistLvl = 0; + WebRtc_Word16 minpos = -1; + + const int kVadCountThreshold = 25; + const int kMaxHistogram = 600; + + if (self == NULL) + { + return -1; + } + + if (spectrum_size != self->spectrum_size) + { + // Data sizes don't match + return -1; + } + if (far_q > 15) + { + // If far_Q is larger than 15 we can not guarantee no wrap around + return -1; + } + + // Update far end history + UpdateFarHistory(self, far_spectrum, far_q); + // Update the far and near end means + for (i = 0; i < self->spectrum_size; i++) + { + self->far_spectrum_32[i] = (WebRtc_Word32)far_spectrum[i]; + MeanEstimator(self->far_spectrum_32[i], 6, &(self->mean_far_spectrum[i])); + + self->near_spectrum_32[i] = (WebRtc_Word32)near_spectrum[i]; + MeanEstimator(self->near_spectrum_32[i], 6, &(self->mean_near_spectrum[i])); + } + + // Shift binary spectrum history + memmove(&(self->binary_far_history[1]), + &(self->binary_far_history[0]), + (self->history_size - 1) * sizeof(WebRtc_UWord32)); + + // Get binary spectra + bxspectrum = GetBinarySpectrum(self->far_spectrum_32, self->mean_far_spectrum); + byspectrum = GetBinarySpectrum(self->near_spectrum_32, self->mean_near_spectrum); + // Insert new binary spectrum + self->binary_far_history[0] = bxspectrum; + + // Compare with delayed spectra + BitCountComparison(byspectrum, + self->binary_far_history, + self->history_size, + self->bit_counts); + + // Smooth bit count curve + for (i = 0; i < self->history_size; i++) + { + // Update sum + // |bit_counts| is constrained to [0, 32], meaning we can smooth with a + // factor up to 2^26. We use Q9. + dtmp1 = WEBRTC_SPL_LSHIFT_W32(self->bit_counts[i], 9); // Q9 + MeanEstimator(dtmp1, 9, &(self->mean_bit_counts[i])); + } + + // Find minimum position of bit count curve + minpos = WebRtcSpl_MinIndexW32(self->mean_bit_counts, self->history_size); + + // If the farend has been active sufficiently long, begin accumulating a + // histogram of the minimum positions. Search for the maximum bin to + // determine the delay. + if (vad_value == 1) + { + if (self->vad_counter >= kVadCountThreshold) + { + // Increment the histogram at the current minimum position. + if (self->delay_histogram[minpos] < kMaxHistogram) + { + self->delay_histogram[minpos] += 3; + } + +#if (!defined ARM_WINM) && (!defined ARM9E_GCC) && (!defined ANDROID_AECOPT) + // Decrement the entire histogram. + // Select the histogram index corresponding to the maximum bin as + // the delay. + self->last_delay = 0; + for (i = 0; i < self->history_size; i++) + { + if (self->delay_histogram[i] > 0) + { + self->delay_histogram[i]--; + } + if (self->delay_histogram[i] > maxHistLvl) + { + maxHistLvl = self->delay_histogram[i]; + self->last_delay = i; + } + } +#else + self->last_delay = 0; + + for (i = 0; i < self->history_size; i++) + { + WebRtc_Word16 tempVar = self->delay_histogram[i]; + + // Decrement the entire histogram. + if (tempVar > 0) + { + tempVar--; + self->delay_histogram[i] = tempVar; + + // Select the histogram index corresponding to the maximum + // bin as the delay. + if (tempVar > maxHistLvl) + { + maxHistLvl = tempVar; + self->last_delay = i; + } + } + } +#endif + } else + { + self->vad_counter++; + } + } else + { + self->vad_counter = 0; + } + + return self->last_delay; +} + +const WebRtc_UWord16* WebRtcAecm_GetAlignedFarend(void* handle, + int far_spectrum_size, + WebRtc_Word16* far_q) +{ + DelayEstimator_t* self = (DelayEstimator_t*)handle; + int buffer_position = 0; + + if (self == NULL) + { + return NULL; + } + if (far_spectrum_size != self->spectrum_size) + { + return NULL; + } + + // Get buffer position + buffer_position = self->far_history_position - self->last_delay; + if (buffer_position < 0) + { + buffer_position += self->history_size; + } + // Get Q-domain + *far_q = self->far_q_domains[buffer_position]; + // Return far end spectrum + return (self->far_history + (buffer_position * self->spectrum_size)); + +} + +int WebRtcAecm_GetLastDelay(void* handle) +{ + DelayEstimator_t* self = (DelayEstimator_t*)handle; + + if (self == NULL) + { + return -1; + } + + // Return last calculated delay + return self->last_delay; +} diff --git a/src/modules/audio_processing/aecm/main/source/aecm_delay_estimator.h b/src/modules/audio_processing/aecm/main/source/aecm_delay_estimator.h new file mode 100644 index 0000000..5ce57fa --- /dev/null +++ b/src/modules/audio_processing/aecm/main/source/aecm_delay_estimator.h @@ -0,0 +1,112 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +// Performs delay estimation on a block by block basis +// The return value is 0 - OK and -1 - Error, unless otherwise stated. + +#ifndef WEBRTC_MODULES_AUDIO_PROCESSING_AECM_MAIN_SOURCE_AECM_DELAY_ESTIMATOR_H_ +#define WEBRTC_MODULES_AUDIO_PROCESSING_AECM_MAIN_SOURCE_AECM_DELAY_ESTIMATOR_H_ + +#include "typedefs.h" + +// Releases the memory allocated by WebRtcAecm_CreateDelayEstimator(...) +// Input: +// - handle : Pointer to the delay estimation instance +// +int WebRtcAecm_FreeDelayEstimator(void* handle); + +// Allocates the memory needed by the delay estimation. The memory needs to be +// initialized separately using the WebRtcAecm_InitDelayEstimator(...) function. +// +// Input: +// - handle : Instance that should be created +// - spectrum_size : Size of the spectrum used both in far end and near +// end. Used to allocate memory for spectrum specific +// buffers. +// - history_size : Size of the far end history used to estimate the +// delay from. Used to allocate memory for history +// specific buffers. +// +// Output: +// - handle : Created instance +// +int WebRtcAecm_CreateDelayEstimator(void** handle, + int spectrum_size, + int history_size); + +// Initializes the delay estimation instance created with +// WebRtcAecm_CreateDelayEstimator(...) +// Input: +// - handle : Pointer to the delay estimation instance +// +// Output: +// - handle : Initialized instance +// +int WebRtcAecm_InitDelayEstimator(void* handle); + +// Estimates and returns the delay between the far end and near end blocks. +// Input: +// - handle : Pointer to the delay estimation instance +// - far_spectrum : Pointer to the far end spectrum data +// - near_spectrum : Pointer to the near end spectrum data of the current +// block +// - spectrum_size : The size of the data arrays (same for both far and +// near end) +// - far_q : The Q-domain of the far end data +// - vad_value : The VAD decision of the current block +// +// Output: +// - handle : Updated instance +// +// Return value: +// - delay : >= 0 - Calculated delay value +// -1 - Error +// +int WebRtcAecm_DelayEstimatorProcess(void* handle, + WebRtc_UWord16* far_spectrum, + WebRtc_UWord16* near_spectrum, + int spectrum_size, + WebRtc_Word16 far_q, + WebRtc_Word16 vad_value); + +// Returns a pointer to the far end spectrum aligned to current near end +// spectrum. The function WebRtcAecm_DelayEstimatorProcess(...) should +// have been called before WebRtcAecm_GetAlignedFarend(...). Otherwise, you get +// the pointer to the previous frame. The memory is only valid until the next +// call of WebRtcAecm_DelayEstimatorProcess(...). +// +// Inputs: +// - handle : Pointer to the delay estimation instance +// +// Output: +// - far_spectrum_size : Size of far_spectrum allocated by the caller +// - far_q : The Q-domain of the aligned far end spectrum +// +// Return value: +// - far_spectrum : Pointer to the aligned far end spectrum +// NULL - Error +// +const WebRtc_UWord16* WebRtcAecm_GetAlignedFarend(void* handle, + int far_spectrum_size, + WebRtc_Word16* far_q); + +// Returns the last calculated delay updated by the function +// WebRtcAecm_DelayEstimatorProcess(...) +// +// Inputs: +// - handle : Pointer to the delay estimation instance +// +// Return value: +// - delay : >= 0 - Last calculated delay value +// -1 - Error +// +int WebRtcAecm_GetLastDelay(void* handle); + +#endif // WEBRTC_MODULES_AUDIO_PROCESSING_AECM_MAIN_SOURCE_AECM_DELAY_ESTIMATOR_H_ diff --git a/src/modules/audio_processing/aecm/main/source/echo_control_mobile.c b/src/modules/audio_processing/aecm/main/source/echo_control_mobile.c new file mode 100644 index 0000000..dc5c926 --- /dev/null +++ b/src/modules/audio_processing/aecm/main/source/echo_control_mobile.c @@ -0,0 +1,800 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +#include +//#include + +#include "echo_control_mobile.h" +#include "aecm_core.h" +#include "ring_buffer.h" +#ifdef AEC_DEBUG +#include +#endif +#ifdef MAC_IPHONE_PRINT +#include +#include +#elif defined ARM_WINM_LOG +#include "windows.h" +extern HANDLE logFile; +#endif + +#define BUF_SIZE_FRAMES 50 // buffer size (frames) +// Maximum length of resampled signal. Must be an integer multiple of frames +// (ceil(1/(1 + MIN_SKEW)*2) + 1)*FRAME_LEN +// The factor of 2 handles wb, and the + 1 is as a safety margin +#define MAX_RESAMP_LEN (5 * FRAME_LEN) + +static const int kBufSizeSamp = BUF_SIZE_FRAMES * FRAME_LEN; // buffer size (samples) +static const int kSampMsNb = 8; // samples per ms in nb +// Target suppression levels for nlp modes +// log{0.001, 0.00001, 0.00000001} +static const int kInitCheck = 42; + +typedef struct +{ + int sampFreq; + int scSampFreq; + short bufSizeStart; + int knownDelay; + + // Stores the last frame added to the farend buffer + short farendOld[2][FRAME_LEN]; + short initFlag; // indicates if AEC has been initialized + + // Variables used for averaging far end buffer size + short counter; + short sum; + short firstVal; + short checkBufSizeCtr; + + // Variables used for delay shifts + short msInSndCardBuf; + short filtDelay; + int timeForDelayChange; + int ECstartup; + int checkBuffSize; + int delayChange; + short lastDelayDiff; + + WebRtc_Word16 echoMode; + +#ifdef AEC_DEBUG + FILE *bufFile; + FILE *delayFile; + FILE *preCompFile; + FILE *postCompFile; +#endif // AEC_DEBUG + // Structures + void *farendBuf; + + int lastError; + + AecmCore_t *aecmCore; +} aecmob_t; + +// Estimates delay to set the position of the farend buffer read pointer +// (controlled by knownDelay) +static int WebRtcAecm_EstBufDelay(aecmob_t *aecmInst, short msInSndCardBuf); + +// Stuffs the farend buffer if the estimated delay is too large +static int WebRtcAecm_DelayComp(aecmob_t *aecmInst); + +WebRtc_Word32 WebRtcAecm_Create(void **aecmInst) +{ + aecmob_t *aecm; + if (aecmInst == NULL) + { + return -1; + } + + aecm = malloc(sizeof(aecmob_t)); + *aecmInst = aecm; + if (aecm == NULL) + { + return -1; + } + + if (WebRtcAecm_CreateCore(&aecm->aecmCore) == -1) + { + WebRtcAecm_Free(aecm); + aecm = NULL; + return -1; + } + + if (WebRtcApm_CreateBuffer(&aecm->farendBuf, kBufSizeSamp) == -1) + { + WebRtcAecm_Free(aecm); + aecm = NULL; + return -1; + } + + aecm->initFlag = 0; + aecm->lastError = 0; + +#ifdef AEC_DEBUG + aecm->aecmCore->farFile = fopen("aecFar.pcm","wb"); + aecm->aecmCore->nearFile = fopen("aecNear.pcm","wb"); + aecm->aecmCore->outFile = fopen("aecOut.pcm","wb"); + //aecm->aecmCore->outLpFile = fopen("aecOutLp.pcm","wb"); + + aecm->bufFile = fopen("aecBuf.dat", "wb"); + aecm->delayFile = fopen("aecDelay.dat", "wb"); + aecm->preCompFile = fopen("preComp.pcm", "wb"); + aecm->postCompFile = fopen("postComp.pcm", "wb"); +#endif // AEC_DEBUG + return 0; +} + +WebRtc_Word32 WebRtcAecm_Free(void *aecmInst) +{ + aecmob_t *aecm = aecmInst; + + if (aecm == NULL) + { + return -1; + } + +#ifdef AEC_DEBUG + fclose(aecm->aecmCore->farFile); + fclose(aecm->aecmCore->nearFile); + fclose(aecm->aecmCore->outFile); + //fclose(aecm->aecmCore->outLpFile); + + fclose(aecm->bufFile); + fclose(aecm->delayFile); + fclose(aecm->preCompFile); + fclose(aecm->postCompFile); +#endif // AEC_DEBUG + WebRtcAecm_FreeCore(aecm->aecmCore); + WebRtcApm_FreeBuffer(aecm->farendBuf); + free(aecm); + + return 0; +} + +WebRtc_Word32 WebRtcAecm_Init(void *aecmInst, WebRtc_Word32 sampFreq) +{ + aecmob_t *aecm = aecmInst; + AecmConfig aecConfig; + + if (aecm == NULL) + { + return -1; + } + + if (sampFreq != 8000 && sampFreq != 16000) + { + aecm->lastError = AECM_BAD_PARAMETER_ERROR; + return -1; + } + aecm->sampFreq = sampFreq; + + // Initialize AECM core + if (WebRtcAecm_InitCore(aecm->aecmCore, aecm->sampFreq) == -1) + { + aecm->lastError = AECM_UNSPECIFIED_ERROR; + return -1; + } + + // Initialize farend buffer + if (WebRtcApm_InitBuffer(aecm->farendBuf) == -1) + { + aecm->lastError = AECM_UNSPECIFIED_ERROR; + return -1; + } + + aecm->initFlag = kInitCheck; // indicates that initialization has been done + + aecm->delayChange = 1; + + aecm->sum = 0; + aecm->counter = 0; + aecm->checkBuffSize = 1; + aecm->firstVal = 0; + + aecm->ECstartup = 1; + aecm->bufSizeStart = 0; + aecm->checkBufSizeCtr = 0; + aecm->filtDelay = 0; + aecm->timeForDelayChange = 0; + aecm->knownDelay = 0; + aecm->lastDelayDiff = 0; + + memset(&aecm->farendOld[0][0], 0, 160); + + // Default settings. + aecConfig.cngMode = AecmTrue; + aecConfig.echoMode = 3; + + if (WebRtcAecm_set_config(aecm, aecConfig) == -1) + { + aecm->lastError = AECM_UNSPECIFIED_ERROR; + return -1; + } + + return 0; +} + +WebRtc_Word32 WebRtcAecm_BufferFarend(void *aecmInst, const WebRtc_Word16 *farend, + WebRtc_Word16 nrOfSamples) +{ + aecmob_t *aecm = aecmInst; + WebRtc_Word32 retVal = 0; + + if (aecm == NULL) + { + return -1; + } + + if (farend == NULL) + { + aecm->lastError = AECM_NULL_POINTER_ERROR; + return -1; + } + + if (aecm->initFlag != kInitCheck) + { + aecm->lastError = AECM_UNINITIALIZED_ERROR; + return -1; + } + + if (nrOfSamples != 80 && nrOfSamples != 160) + { + aecm->lastError = AECM_BAD_PARAMETER_ERROR; + return -1; + } + + // TODO: Is this really a good idea? + if (!aecm->ECstartup) + { + WebRtcAecm_DelayComp(aecm); + } + + WebRtcApm_WriteBuffer(aecm->farendBuf, farend, nrOfSamples); + + return retVal; +} + +WebRtc_Word32 WebRtcAecm_Process(void *aecmInst, const WebRtc_Word16 *nearendNoisy, + const WebRtc_Word16 *nearendClean, WebRtc_Word16 *out, + WebRtc_Word16 nrOfSamples, WebRtc_Word16 msInSndCardBuf) +{ + aecmob_t *aecm = aecmInst; + WebRtc_Word32 retVal = 0; + short i; + short farend[FRAME_LEN]; + short nmbrOfFilledBuffers; + short nBlocks10ms; + short nFrames; +#ifdef AEC_DEBUG + short msInAECBuf; +#endif + +#ifdef ARM_WINM_LOG + __int64 freq, start, end, diff; + unsigned int milliseconds; + DWORD temp; +#elif defined MAC_IPHONE_PRINT + // double endtime = 0, starttime = 0; + struct timeval starttime; + struct timeval endtime; + static long int timeused = 0; + static int timecount = 0; +#endif + + if (aecm == NULL) + { + return -1; + } + + if (nearendNoisy == NULL) + { + aecm->lastError = AECM_NULL_POINTER_ERROR; + return -1; + } + + if (out == NULL) + { + aecm->lastError = AECM_NULL_POINTER_ERROR; + return -1; + } + + if (aecm->initFlag != kInitCheck) + { + aecm->lastError = AECM_UNINITIALIZED_ERROR; + return -1; + } + + if (nrOfSamples != 80 && nrOfSamples != 160) + { + aecm->lastError = AECM_BAD_PARAMETER_ERROR; + return -1; + } + + if (msInSndCardBuf < 0) + { + msInSndCardBuf = 0; + aecm->lastError = AECM_BAD_PARAMETER_WARNING; + retVal = -1; + } else if (msInSndCardBuf > 500) + { + msInSndCardBuf = 500; + aecm->lastError = AECM_BAD_PARAMETER_WARNING; + retVal = -1; + } + msInSndCardBuf += 10; + aecm->msInSndCardBuf = msInSndCardBuf; + + nFrames = nrOfSamples / FRAME_LEN; + nBlocks10ms = nFrames / aecm->aecmCore->mult; + + if (aecm->ECstartup) + { + if (nearendClean == NULL) + { + memcpy(out, nearendNoisy, sizeof(short) * nrOfSamples); + } else + { + memcpy(out, nearendClean, sizeof(short) * nrOfSamples); + } + + nmbrOfFilledBuffers = WebRtcApm_get_buffer_size(aecm->farendBuf) / FRAME_LEN; + // The AECM is in the start up mode + // AECM is disabled until the soundcard buffer and farend buffers are OK + + // Mechanism to ensure that the soundcard buffer is reasonably stable. + if (aecm->checkBuffSize) + { + aecm->checkBufSizeCtr++; + // Before we fill up the far end buffer we require the amount of data on the + // sound card to be stable (+/-8 ms) compared to the first value. This + // comparison is made during the following 4 consecutive frames. If it seems + // to be stable then we start to fill up the far end buffer. + + if (aecm->counter == 0) + { + aecm->firstVal = aecm->msInSndCardBuf; + aecm->sum = 0; + } + + if (abs(aecm->firstVal - aecm->msInSndCardBuf) + < WEBRTC_SPL_MAX(0.2 * aecm->msInSndCardBuf, kSampMsNb)) + { + aecm->sum += aecm->msInSndCardBuf; + aecm->counter++; + } else + { + aecm->counter = 0; + } + + if (aecm->counter * nBlocks10ms >= 6) + { + // The farend buffer size is determined in blocks of 80 samples + // Use 75% of the average value of the soundcard buffer + aecm->bufSizeStart + = WEBRTC_SPL_MIN((3 * aecm->sum + * aecm->aecmCore->mult) / (aecm->counter * 40), BUF_SIZE_FRAMES); + // buffersize has now been determined + aecm->checkBuffSize = 0; + } + + if (aecm->checkBufSizeCtr * nBlocks10ms > 50) + { + // for really bad sound cards, don't disable echocanceller for more than 0.5 sec + aecm->bufSizeStart = WEBRTC_SPL_MIN((3 * aecm->msInSndCardBuf + * aecm->aecmCore->mult) / 40, BUF_SIZE_FRAMES); + aecm->checkBuffSize = 0; + } + } + + // if checkBuffSize changed in the if-statement above + if (!aecm->checkBuffSize) + { + // soundcard buffer is now reasonably stable + // When the far end buffer is filled with approximately the same amount of + // data as the amount on the sound card we end the start up phase and start + // to cancel echoes. + + if (nmbrOfFilledBuffers == aecm->bufSizeStart) + { + aecm->ECstartup = 0; // Enable the AECM + } else if (nmbrOfFilledBuffers > aecm->bufSizeStart) + { + WebRtcApm_FlushBuffer( + aecm->farendBuf, + WebRtcApm_get_buffer_size(aecm->farendBuf) + - aecm->bufSizeStart * FRAME_LEN); + aecm->ECstartup = 0; + } + } + + } else + { + // AECM is enabled + + // Note only 1 block supported for nb and 2 blocks for wb + for (i = 0; i < nFrames; i++) + { + nmbrOfFilledBuffers = WebRtcApm_get_buffer_size(aecm->farendBuf) / FRAME_LEN; + + // Check that there is data in the far end buffer + if (nmbrOfFilledBuffers > 0) + { + // Get the next 80 samples from the farend buffer + WebRtcApm_ReadBuffer(aecm->farendBuf, farend, FRAME_LEN); + + // Always store the last frame for use when we run out of data + memcpy(&(aecm->farendOld[i][0]), farend, FRAME_LEN * sizeof(short)); + } else + { + // We have no data so we use the last played frame + memcpy(farend, &(aecm->farendOld[i][0]), FRAME_LEN * sizeof(short)); + } + + // Call buffer delay estimator when all data is extracted, + // i,e. i = 0 for NB and i = 1 for WB + if ((i == 0 && aecm->sampFreq == 8000) || (i == 1 && aecm->sampFreq == 16000)) + { + WebRtcAecm_EstBufDelay(aecm, aecm->msInSndCardBuf); + } + +#ifdef ARM_WINM_LOG + // measure tick start + QueryPerformanceFrequency((LARGE_INTEGER*)&freq); + QueryPerformanceCounter((LARGE_INTEGER*)&start); +#elif defined MAC_IPHONE_PRINT + // starttime = clock()/(double)CLOCKS_PER_SEC; + gettimeofday(&starttime, NULL); +#endif + // Call the AECM + /*WebRtcAecm_ProcessFrame(aecm->aecmCore, farend, &nearend[FRAME_LEN * i], + &out[FRAME_LEN * i], aecm->knownDelay);*/ + if (nearendClean == NULL) + { + if (WebRtcAecm_ProcessFrame(aecm->aecmCore, + farend, + &nearendNoisy[FRAME_LEN * i], + NULL, + &out[FRAME_LEN * i]) == -1) + { + return -1; + } + } else + { + if (WebRtcAecm_ProcessFrame(aecm->aecmCore, + farend, + &nearendNoisy[FRAME_LEN * i], + &nearendClean[FRAME_LEN * i], + &out[FRAME_LEN * i]) == -1) + { + return -1; + } + } + +#ifdef ARM_WINM_LOG + + // measure tick end + QueryPerformanceCounter((LARGE_INTEGER*)&end); + + if(end > start) + { + diff = ((end - start) * 1000) / (freq/1000); + milliseconds = (unsigned int)(diff & 0xffffffff); + WriteFile (logFile, &milliseconds, sizeof(unsigned int), &temp, NULL); + } +#elif defined MAC_IPHONE_PRINT + // endtime = clock()/(double)CLOCKS_PER_SEC; + // printf("%f\n", endtime - starttime); + + gettimeofday(&endtime, NULL); + + if( endtime.tv_usec > starttime.tv_usec) + { + timeused += endtime.tv_usec - starttime.tv_usec; + } else + { + timeused += endtime.tv_usec + 1000000 - starttime.tv_usec; + } + + if(++timecount == 1000) + { + timecount = 0; + printf("AEC: %ld\n", timeused); + timeused = 0; + } +#endif + + } + } + +#ifdef AEC_DEBUG + msInAECBuf = WebRtcApm_get_buffer_size(aecm->farendBuf) / (kSampMsNb*aecm->aecmCore->mult); + fwrite(&msInAECBuf, 2, 1, aecm->bufFile); + fwrite(&(aecm->knownDelay), sizeof(aecm->knownDelay), 1, aecm->delayFile); +#endif + + return retVal; +} + +WebRtc_Word32 WebRtcAecm_set_config(void *aecmInst, AecmConfig config) +{ + aecmob_t *aecm = aecmInst; + + if (aecm == NULL) + { + return -1; + } + + if (aecm->initFlag != kInitCheck) + { + aecm->lastError = AECM_UNINITIALIZED_ERROR; + return -1; + } + + if (config.cngMode != AecmFalse && config.cngMode != AecmTrue) + { + aecm->lastError = AECM_BAD_PARAMETER_ERROR; + return -1; + } + aecm->aecmCore->cngMode = config.cngMode; + + if (config.echoMode < 0 || config.echoMode > 4) + { + aecm->lastError = AECM_BAD_PARAMETER_ERROR; + return -1; + } + aecm->echoMode = config.echoMode; + + if (aecm->echoMode == 0) + { + aecm->aecmCore->supGain = SUPGAIN_DEFAULT >> 3; + aecm->aecmCore->supGainOld = SUPGAIN_DEFAULT >> 3; + aecm->aecmCore->supGainErrParamA = SUPGAIN_ERROR_PARAM_A >> 3; + aecm->aecmCore->supGainErrParamD = SUPGAIN_ERROR_PARAM_D >> 3; + aecm->aecmCore->supGainErrParamDiffAB = (SUPGAIN_ERROR_PARAM_A >> 3) + - (SUPGAIN_ERROR_PARAM_B >> 3); + aecm->aecmCore->supGainErrParamDiffBD = (SUPGAIN_ERROR_PARAM_B >> 3) + - (SUPGAIN_ERROR_PARAM_D >> 3); + } else if (aecm->echoMode == 1) + { + aecm->aecmCore->supGain = SUPGAIN_DEFAULT >> 2; + aecm->aecmCore->supGainOld = SUPGAIN_DEFAULT >> 2; + aecm->aecmCore->supGainErrParamA = SUPGAIN_ERROR_PARAM_A >> 2; + aecm->aecmCore->supGainErrParamD = SUPGAIN_ERROR_PARAM_D >> 2; + aecm->aecmCore->supGainErrParamDiffAB = (SUPGAIN_ERROR_PARAM_A >> 2) + - (SUPGAIN_ERROR_PARAM_B >> 2); + aecm->aecmCore->supGainErrParamDiffBD = (SUPGAIN_ERROR_PARAM_B >> 2) + - (SUPGAIN_ERROR_PARAM_D >> 2); + } else if (aecm->echoMode == 2) + { + aecm->aecmCore->supGain = SUPGAIN_DEFAULT >> 1; + aecm->aecmCore->supGainOld = SUPGAIN_DEFAULT >> 1; + aecm->aecmCore->supGainErrParamA = SUPGAIN_ERROR_PARAM_A >> 1; + aecm->aecmCore->supGainErrParamD = SUPGAIN_ERROR_PARAM_D >> 1; + aecm->aecmCore->supGainErrParamDiffAB = (SUPGAIN_ERROR_PARAM_A >> 1) + - (SUPGAIN_ERROR_PARAM_B >> 1); + aecm->aecmCore->supGainErrParamDiffBD = (SUPGAIN_ERROR_PARAM_B >> 1) + - (SUPGAIN_ERROR_PARAM_D >> 1); + } else if (aecm->echoMode == 3) + { + aecm->aecmCore->supGain = SUPGAIN_DEFAULT; + aecm->aecmCore->supGainOld = SUPGAIN_DEFAULT; + aecm->aecmCore->supGainErrParamA = SUPGAIN_ERROR_PARAM_A; + aecm->aecmCore->supGainErrParamD = SUPGAIN_ERROR_PARAM_D; + aecm->aecmCore->supGainErrParamDiffAB = SUPGAIN_ERROR_PARAM_A - SUPGAIN_ERROR_PARAM_B; + aecm->aecmCore->supGainErrParamDiffBD = SUPGAIN_ERROR_PARAM_B - SUPGAIN_ERROR_PARAM_D; + } else if (aecm->echoMode == 4) + { + aecm->aecmCore->supGain = SUPGAIN_DEFAULT << 1; + aecm->aecmCore->supGainOld = SUPGAIN_DEFAULT << 1; + aecm->aecmCore->supGainErrParamA = SUPGAIN_ERROR_PARAM_A << 1; + aecm->aecmCore->supGainErrParamD = SUPGAIN_ERROR_PARAM_D << 1; + aecm->aecmCore->supGainErrParamDiffAB = (SUPGAIN_ERROR_PARAM_A << 1) + - (SUPGAIN_ERROR_PARAM_B << 1); + aecm->aecmCore->supGainErrParamDiffBD = (SUPGAIN_ERROR_PARAM_B << 1) + - (SUPGAIN_ERROR_PARAM_D << 1); + } + + return 0; +} + +WebRtc_Word32 WebRtcAecm_get_config(void *aecmInst, AecmConfig *config) +{ + aecmob_t *aecm = aecmInst; + + if (aecm == NULL) + { + return -1; + } + + if (config == NULL) + { + aecm->lastError = AECM_NULL_POINTER_ERROR; + return -1; + } + + if (aecm->initFlag != kInitCheck) + { + aecm->lastError = AECM_UNINITIALIZED_ERROR; + return -1; + } + + config->cngMode = aecm->aecmCore->cngMode; + config->echoMode = aecm->echoMode; + + return 0; +} + +WebRtc_Word32 WebRtcAecm_InitEchoPath(void* aecmInst, + const void* echo_path, + size_t size_bytes) +{ + aecmob_t *aecm = aecmInst; + const WebRtc_Word16* echo_path_ptr = echo_path; + + if ((aecm == NULL) || (echo_path == NULL)) + { + aecm->lastError = AECM_NULL_POINTER_ERROR; + return -1; + } + if (size_bytes != WebRtcAecm_echo_path_size_bytes()) + { + // Input channel size does not match the size of AECM + aecm->lastError = AECM_BAD_PARAMETER_ERROR; + return -1; + } + if (aecm->initFlag != kInitCheck) + { + aecm->lastError = AECM_UNINITIALIZED_ERROR; + return -1; + } + + WebRtcAecm_InitEchoPathCore(aecm->aecmCore, echo_path_ptr); + + return 0; +} + +WebRtc_Word32 WebRtcAecm_GetEchoPath(void* aecmInst, + void* echo_path, + size_t size_bytes) +{ + aecmob_t *aecm = aecmInst; + WebRtc_Word16* echo_path_ptr = echo_path; + + if ((aecm == NULL) || (echo_path == NULL)) + { + aecm->lastError = AECM_NULL_POINTER_ERROR; + return -1; + } + if (size_bytes != WebRtcAecm_echo_path_size_bytes()) + { + // Input channel size does not match the size of AECM + aecm->lastError = AECM_BAD_PARAMETER_ERROR; + return -1; + } + if (aecm->initFlag != kInitCheck) + { + aecm->lastError = AECM_UNINITIALIZED_ERROR; + return -1; + } + + memcpy(echo_path_ptr, aecm->aecmCore->channelStored, size_bytes); + return 0; +} + +size_t WebRtcAecm_echo_path_size_bytes() +{ + return (PART_LEN1 * sizeof(WebRtc_Word16)); +} + +WebRtc_Word32 WebRtcAecm_get_version(WebRtc_Word8 *versionStr, WebRtc_Word16 len) +{ + const char version[] = "AECM 1.2.0"; + const short versionLen = (short)strlen(version) + 1; // +1 for null-termination + + if (versionStr == NULL) + { + return -1; + } + + if (versionLen > len) + { + return -1; + } + + strncpy(versionStr, version, versionLen); + return 0; +} + +WebRtc_Word32 WebRtcAecm_get_error_code(void *aecmInst) +{ + aecmob_t *aecm = aecmInst; + + if (aecm == NULL) + { + return -1; + } + + return aecm->lastError; +} + +static int WebRtcAecm_EstBufDelay(aecmob_t *aecm, short msInSndCardBuf) +{ + short delayNew, nSampFar, nSampSndCard; + short diff; + + nSampFar = WebRtcApm_get_buffer_size(aecm->farendBuf); + nSampSndCard = msInSndCardBuf * kSampMsNb * aecm->aecmCore->mult; + + delayNew = nSampSndCard - nSampFar; + + if (delayNew < FRAME_LEN) + { + WebRtcApm_FlushBuffer(aecm->farendBuf, FRAME_LEN); + delayNew += FRAME_LEN; + } + + aecm->filtDelay = WEBRTC_SPL_MAX(0, (8 * aecm->filtDelay + 2 * delayNew) / 10); + + diff = aecm->filtDelay - aecm->knownDelay; + if (diff > 224) + { + if (aecm->lastDelayDiff < 96) + { + aecm->timeForDelayChange = 0; + } else + { + aecm->timeForDelayChange++; + } + } else if (diff < 96 && aecm->knownDelay > 0) + { + if (aecm->lastDelayDiff > 224) + { + aecm->timeForDelayChange = 0; + } else + { + aecm->timeForDelayChange++; + } + } else + { + aecm->timeForDelayChange = 0; + } + aecm->lastDelayDiff = diff; + + if (aecm->timeForDelayChange > 25) + { + aecm->knownDelay = WEBRTC_SPL_MAX((int)aecm->filtDelay - 160, 0); + } + return 0; +} + +static int WebRtcAecm_DelayComp(aecmob_t *aecm) +{ + int nSampFar, nSampSndCard, delayNew, nSampAdd; + const int maxStuffSamp = 10 * FRAME_LEN; + + nSampFar = WebRtcApm_get_buffer_size(aecm->farendBuf); + nSampSndCard = aecm->msInSndCardBuf * kSampMsNb * aecm->aecmCore->mult; + delayNew = nSampSndCard - nSampFar; + + if (delayNew > FAR_BUF_LEN - FRAME_LEN * aecm->aecmCore->mult) + { + // The difference of the buffer sizes is larger than the maximum + // allowed known delay. Compensate by stuffing the buffer. + nSampAdd = (int)(WEBRTC_SPL_MAX(((nSampSndCard >> 1) - nSampFar), + FRAME_LEN)); + nSampAdd = WEBRTC_SPL_MIN(nSampAdd, maxStuffSamp); + + WebRtcApm_StuffBuffer(aecm->farendBuf, nSampAdd); + aecm->delayChange = 1; // the delay needs to be updated + } + + return 0; +} diff --git a/src/modules/audio_processing/agc/main/interface/gain_control.h b/src/modules/audio_processing/agc/main/interface/gain_control.h new file mode 100644 index 0000000..2893331 --- /dev/null +++ b/src/modules/audio_processing/agc/main/interface/gain_control.h @@ -0,0 +1,273 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +#ifndef WEBRTC_MODULES_AUDIO_PROCESSING_AGC_MAIN_INTERFACE_GAIN_CONTROL_H_ +#define WEBRTC_MODULES_AUDIO_PROCESSING_AGC_MAIN_INTERFACE_GAIN_CONTROL_H_ + +#include "typedefs.h" + +// Errors +#define AGC_UNSPECIFIED_ERROR 18000 +#define AGC_UNSUPPORTED_FUNCTION_ERROR 18001 +#define AGC_UNINITIALIZED_ERROR 18002 +#define AGC_NULL_POINTER_ERROR 18003 +#define AGC_BAD_PARAMETER_ERROR 18004 + +// Warnings +#define AGC_BAD_PARAMETER_WARNING 18050 + +enum +{ + kAgcModeUnchanged, + kAgcModeAdaptiveAnalog, + kAgcModeAdaptiveDigital, + kAgcModeFixedDigital +}; + +enum +{ + kAgcFalse = 0, + kAgcTrue +}; + +typedef struct +{ + WebRtc_Word16 targetLevelDbfs; // default 3 (-3 dBOv) + WebRtc_Word16 compressionGaindB; // default 9 dB + WebRtc_UWord8 limiterEnable; // default kAgcTrue (on) +} WebRtcAgc_config_t; + +#if defined(__cplusplus) +extern "C" +{ +#endif + +/* + * This function processes a 10/20ms frame of far-end speech to determine + * if there is active speech. Far-end speech length can be either 10ms or + * 20ms. The length of the input speech vector must be given in samples + * (80/160 when FS=8000, and 160/320 when FS=16000 or FS=32000). + * + * Input: + * - agcInst : AGC instance. + * - inFar : Far-end input speech vector (10 or 20ms) + * - samples : Number of samples in input vector + * + * Return value: + * : 0 - Normal operation. + * : -1 - Error + */ +int WebRtcAgc_AddFarend(void* agcInst, + const WebRtc_Word16* inFar, + WebRtc_Word16 samples); + +/* + * This function processes a 10/20ms frame of microphone speech to determine + * if there is active speech. Microphone speech length can be either 10ms or + * 20ms. The length of the input speech vector must be given in samples + * (80/160 when FS=8000, and 160/320 when FS=16000 or FS=32000). For very low + * input levels, the input signal is increased in level by multiplying and + * overwriting the samples in inMic[]. + * + * This function should be called before any further processing of the + * near-end microphone signal. + * + * Input: + * - agcInst : AGC instance. + * - inMic : Microphone input speech vector (10 or 20 ms) for + * L band + * - inMic_H : Microphone input speech vector (10 or 20 ms) for + * H band + * - samples : Number of samples in input vector + * + * Return value: + * : 0 - Normal operation. + * : -1 - Error + */ +int WebRtcAgc_AddMic(void* agcInst, + WebRtc_Word16* inMic, + WebRtc_Word16* inMic_H, + WebRtc_Word16 samples); + +/* + * This function replaces the analog microphone with a virtual one. + * It is a digital gain applied to the input signal and is used in the + * agcAdaptiveDigital mode where no microphone level is adjustable. + * Microphone speech length can be either 10ms or 20ms. The length of the + * input speech vector must be given in samples (80/160 when FS=8000, and + * 160/320 when FS=16000 or FS=32000). + * + * Input: + * - agcInst : AGC instance. + * - inMic : Microphone input speech vector for (10 or 20 ms) + * L band + * - inMic_H : Microphone input speech vector for (10 or 20 ms) + * H band + * - samples : Number of samples in input vector + * - micLevelIn : Input level of microphone (static) + * + * Output: + * - inMic : Microphone output after processing (L band) + * - inMic_H : Microphone output after processing (H band) + * - micLevelOut : Adjusted microphone level after processing + * + * Return value: + * : 0 - Normal operation. + * : -1 - Error + */ +int WebRtcAgc_VirtualMic(void* agcInst, + WebRtc_Word16* inMic, + WebRtc_Word16* inMic_H, + WebRtc_Word16 samples, + WebRtc_Word32 micLevelIn, + WebRtc_Word32* micLevelOut); + +/* + * This function processes a 10/20ms frame and adjusts (normalizes) the gain + * both analog and digitally. The gain adjustments are done only during + * active periods of speech. The input speech length can be either 10ms or + * 20ms and the output is of the same length. The length of the speech + * vectors must be given in samples (80/160 when FS=8000, and 160/320 when + * FS=16000 or FS=32000). The echo parameter can be used to ensure the AGC will + * not adjust upward in the presence of echo. + * + * This function should be called after processing the near-end microphone + * signal, in any case after any echo cancellation. + * + * Input: + * - agcInst : AGC instance + * - inNear : Near-end input speech vector (10 or 20 ms) for + * L band + * - inNear_H : Near-end input speech vector (10 or 20 ms) for + * H band + * - samples : Number of samples in input/output vector + * - inMicLevel : Current microphone volume level + * - echo : Set to 0 if the signal passed to add_mic is + * almost certainly free of echo; otherwise set + * to 1. If you have no information regarding echo + * set to 0. + * + * Output: + * - outMicLevel : Adjusted microphone volume level + * - out : Gain-adjusted near-end speech vector (L band) + * : May be the same vector as the input. + * - out_H : Gain-adjusted near-end speech vector (H band) + * - saturationWarning : A returned value of 1 indicates a saturation event + * has occurred and the volume cannot be further + * reduced. Otherwise will be set to 0. + * + * Return value: + * : 0 - Normal operation. + * : -1 - Error + */ +int WebRtcAgc_Process(void* agcInst, + const WebRtc_Word16* inNear, + const WebRtc_Word16* inNear_H, + WebRtc_Word16 samples, + WebRtc_Word16* out, + WebRtc_Word16* out_H, + WebRtc_Word32 inMicLevel, + WebRtc_Word32* outMicLevel, + WebRtc_Word16 echo, + WebRtc_UWord8* saturationWarning); + +/* + * This function sets the config parameters (targetLevelDbfs, + * compressionGaindB and limiterEnable). + * + * Input: + * - agcInst : AGC instance + * - config : config struct + * + * Output: + * + * Return value: + * : 0 - Normal operation. + * : -1 - Error + */ +int WebRtcAgc_set_config(void* agcInst, WebRtcAgc_config_t config); + +/* + * This function returns the config parameters (targetLevelDbfs, + * compressionGaindB and limiterEnable). + * + * Input: + * - agcInst : AGC instance + * + * Output: + * - config : config struct + * + * Return value: + * : 0 - Normal operation. + * : -1 - Error + */ +int WebRtcAgc_get_config(void* agcInst, WebRtcAgc_config_t* config); + +/* + * This function creates an AGC instance, which will contain the state + * information for one (duplex) channel. + * + * Return value : AGC instance if successful + * : 0 (i.e., a NULL pointer) if unsuccessful + */ +int WebRtcAgc_Create(void **agcInst); + +/* + * This function frees the AGC instance created at the beginning. + * + * Input: + * - agcInst : AGC instance. + * + * Return value : 0 - Ok + * -1 - Error + */ +int WebRtcAgc_Free(void *agcInst); + +/* + * This function initializes an AGC instance. + * + * Input: + * - agcInst : AGC instance. + * - minLevel : Minimum possible mic level + * - maxLevel : Maximum possible mic level + * - agcMode : 0 - Unchanged + * : 1 - Adaptive Analog Automatic Gain Control -3dBOv + * : 2 - Adaptive Digital Automatic Gain Control -3dBOv + * : 3 - Fixed Digital Gain 0dB + * - fs : Sampling frequency + * + * Return value : 0 - Ok + * -1 - Error + */ +int WebRtcAgc_Init(void *agcInst, + WebRtc_Word32 minLevel, + WebRtc_Word32 maxLevel, + WebRtc_Word16 agcMode, + WebRtc_UWord32 fs); + +/* + * This function returns a text string containing the version. + * + * Input: + * - length : Length of the char array pointed to by version + * Output: + * - version : Pointer to a char array of to which the version + * : string will be copied. + * + * Return value : 0 - OK + * -1 - Error + */ +int WebRtcAgc_Version(WebRtc_Word8 *versionStr, WebRtc_Word16 length); + +#if defined(__cplusplus) +} +#endif + +#endif // WEBRTC_MODULES_AUDIO_PROCESSING_AGC_MAIN_INTERFACE_GAIN_CONTROL_H_ diff --git a/src/modules/audio_processing/agc/main/matlab/getGains.m b/src/modules/audio_processing/agc/main/matlab/getGains.m new file mode 100644 index 0000000..e0234b8 --- /dev/null +++ b/src/modules/audio_processing/agc/main/matlab/getGains.m @@ -0,0 +1,32 @@ +% Outputs a file for testing purposes. +% +% Adjust the following parameters to suit. Their purpose becomes more clear on +% viewing the gain plots. +% MaxGain: Max gain in dB +% MinGain: Min gain at overload (0 dBov) in dB +% CompRatio: Compression ratio, essentially determines the slope of the gain +% function between the max and min gains +% Knee: The smoothness of the transition to max gain (smaller is smoother) +MaxGain = 5; MinGain = 0; CompRatio = 3; Knee = 1; + +% Compute gains +zeros = 0:31; lvl = 2.^(1-zeros); +A = -10*log10(lvl) * (CompRatio - 1) / CompRatio; +B = MaxGain - MinGain; +gains = round(2^16*10.^(0.05 * (MinGain + B * ( log(exp(-Knee*A)+exp(-Knee*B)) - log(1+exp(-Knee*B)) ) / log(1/(1+exp(Knee*B)))))); +fprintf(1, '\t%i, %i, %i, %i,\n', gains); + +% Save gains to file +fid = fopen('gains', 'wb'); +if fid == -1 + error(sprintf('Unable to open file %s', filename)); + return +end +fwrite(fid, gains, 'int32'); +fclose(fid); + +% Plotting +in = 10*log10(lvl); out = 20*log10(gains/65536); +subplot(121); plot(in, out); axis([-60, 0, -5, 30]); grid on; xlabel('Input (dB)'); ylabel('Gain (dB)'); +subplot(122); plot(in, in+out); axis([-60, 0, -60, 10]); grid on; xlabel('Input (dB)'); ylabel('Output (dB)'); +zoom on; diff --git a/src/modules/audio_processing/agc/main/source/agc.gypi b/src/modules/audio_processing/agc/main/source/agc.gypi new file mode 100644 index 0000000..f0642e7 --- /dev/null +++ b/src/modules/audio_processing/agc/main/source/agc.gypi @@ -0,0 +1,40 @@ +# Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. +# +# Use of this source code is governed by a BSD-style license +# that can be found in the LICENSE file in the root of the source +# tree. An additional intellectual property rights grant can be found +# in the file PATENTS. All contributing project authors may +# be found in the AUTHORS file in the root of the source tree. + +{ + 'targets': [ + { + 'target_name': 'agc', + 'type': '<(library)', + 'dependencies': [ + '<(webrtc_root)/common_audio/common_audio.gyp:spl', + ], + 'include_dirs': [ + '../interface', + ], + 'direct_dependent_settings': { + 'include_dirs': [ + '../interface', + ], + }, + 'sources': [ + '../interface/gain_control.h', + 'analog_agc.c', + 'analog_agc.h', + 'digital_agc.c', + 'digital_agc.h', + ], + }, + ], +} + +# Local Variables: +# tab-width:2 +# indent-tabs-mode:nil +# End: +# vim: set expandtab tabstop=2 shiftwidth=2: diff --git a/src/modules/audio_processing/agc/main/source/analog_agc.c b/src/modules/audio_processing/agc/main/source/analog_agc.c new file mode 100644 index 0000000..0c2ccee --- /dev/null +++ b/src/modules/audio_processing/agc/main/source/analog_agc.c @@ -0,0 +1,1709 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +/* analog_agc.c + * + * Using a feedback system, determines an appropriate analog volume level + * given an input signal and current volume level. Targets a conservative + * signal level and is intended for use with a digital AGC to apply + * additional gain. + * + */ + +#include +#include +#ifdef AGC_DEBUG //test log +#include +#endif +#include "analog_agc.h" + +/* The slope of in Q13*/ +static const WebRtc_Word16 kSlope1[8] = {21793, 12517, 7189, 4129, 2372, 1362, 472, 78}; + +/* The offset in Q14 */ +static const WebRtc_Word16 kOffset1[8] = {25395, 23911, 22206, 20737, 19612, 18805, 17951, + 17367}; + +/* The slope of in Q13*/ +static const WebRtc_Word16 kSlope2[8] = {2063, 1731, 1452, 1218, 1021, 857, 597, 337}; + +/* The offset in Q14 */ +static const WebRtc_Word16 kOffset2[8] = {18432, 18379, 18290, 18177, 18052, 17920, 17670, + 17286}; + +static const WebRtc_Word16 kMuteGuardTimeMs = 8000; +static const WebRtc_Word16 kInitCheck = 42; + +/* Default settings if config is not used */ +#define AGC_DEFAULT_TARGET_LEVEL 3 +#define AGC_DEFAULT_COMP_GAIN 9 +/* This is the target level for the analog part in ENV scale. To convert to RMS scale you + * have to add OFFSET_ENV_TO_RMS. + */ +#define ANALOG_TARGET_LEVEL 11 +#define ANALOG_TARGET_LEVEL_2 5 // ANALOG_TARGET_LEVEL / 2 +/* Offset between RMS scale (analog part) and ENV scale (digital part). This value actually + * varies with the FIXED_ANALOG_TARGET_LEVEL, hence we should in the future replace it with + * a table. + */ +#define OFFSET_ENV_TO_RMS 9 +/* The reference input level at which the digital part gives an output of targetLevelDbfs + * (desired level) if we have no compression gain. This level should be set high enough not + * to compress the peaks due to the dynamics. + */ +#define DIGITAL_REF_AT_0_COMP_GAIN 4 +/* Speed of reference level decrease. + */ +#define DIFF_REF_TO_ANALOG 5 + +#ifdef MIC_LEVEL_FEEDBACK +#define NUM_BLOCKS_IN_SAT_BEFORE_CHANGE_TARGET 7 +#endif +/* Size of analog gain table */ +#define GAIN_TBL_LEN 32 +/* Matlab code: + * fprintf(1, '\t%i, %i, %i, %i,\n', round(10.^(linspace(0,10,32)/20) * 2^12)); + */ +/* Q12 */ +static const WebRtc_UWord16 kGainTableAnalog[GAIN_TBL_LEN] = {4096, 4251, 4412, 4579, 4752, + 4932, 5118, 5312, 5513, 5722, 5938, 6163, 6396, 6638, 6889, 7150, 7420, 7701, 7992, + 8295, 8609, 8934, 9273, 9623, 9987, 10365, 10758, 11165, 11587, 12025, 12480, 12953}; + +/* Gain/Suppression tables for virtual Mic (in Q10) */ +static const WebRtc_UWord16 kGainTableVirtualMic[128] = {1052, 1081, 1110, 1141, 1172, 1204, + 1237, 1271, 1305, 1341, 1378, 1416, 1454, 1494, 1535, 1577, 1620, 1664, 1710, 1757, + 1805, 1854, 1905, 1957, 2010, 2065, 2122, 2180, 2239, 2301, 2364, 2428, 2495, 2563, + 2633, 2705, 2779, 2855, 2933, 3013, 3096, 3180, 3267, 3357, 3449, 3543, 3640, 3739, + 3842, 3947, 4055, 4166, 4280, 4397, 4517, 4640, 4767, 4898, 5032, 5169, 5311, 5456, + 5605, 5758, 5916, 6078, 6244, 6415, 6590, 6770, 6956, 7146, 7341, 7542, 7748, 7960, + 8178, 8402, 8631, 8867, 9110, 9359, 9615, 9878, 10148, 10426, 10711, 11004, 11305, + 11614, 11932, 12258, 12593, 12938, 13292, 13655, 14029, 14412, 14807, 15212, 15628, + 16055, 16494, 16945, 17409, 17885, 18374, 18877, 19393, 19923, 20468, 21028, 21603, + 22194, 22801, 23425, 24065, 24724, 25400, 26095, 26808, 27541, 28295, 29069, 29864, + 30681, 31520, 32382}; +static const WebRtc_UWord16 kSuppressionTableVirtualMic[128] = {1024, 1006, 988, 970, 952, + 935, 918, 902, 886, 870, 854, 839, 824, 809, 794, 780, 766, 752, 739, 726, 713, 700, + 687, 675, 663, 651, 639, 628, 616, 605, 594, 584, 573, 563, 553, 543, 533, 524, 514, + 505, 496, 487, 478, 470, 461, 453, 445, 437, 429, 421, 414, 406, 399, 392, 385, 378, + 371, 364, 358, 351, 345, 339, 333, 327, 321, 315, 309, 304, 298, 293, 288, 283, 278, + 273, 268, 263, 258, 254, 249, 244, 240, 236, 232, 227, 223, 219, 215, 211, 208, 204, + 200, 197, 193, 190, 186, 183, 180, 176, 173, 170, 167, 164, 161, 158, 155, 153, 150, + 147, 145, 142, 139, 137, 134, 132, 130, 127, 125, 123, 121, 118, 116, 114, 112, 110, + 108, 106, 104, 102}; + +/* Table for target energy levels. Values in Q(-7) + * Matlab code + * targetLevelTable = fprintf('%d,\t%d,\t%d,\t%d,\n', round((32767*10.^(-(0:63)'/20)).^2*16/2^7) */ + +static const WebRtc_Word32 kTargetLevelTable[64] = {134209536, 106606424, 84680493, 67264106, + 53429779, 42440782, 33711911, 26778323, 21270778, 16895980, 13420954, 10660642, + 8468049, 6726411, 5342978, 4244078, 3371191, 2677832, 2127078, 1689598, 1342095, + 1066064, 846805, 672641, 534298, 424408, 337119, 267783, 212708, 168960, 134210, + 106606, 84680, 67264, 53430, 42441, 33712, 26778, 21271, 16896, 13421, 10661, 8468, + 6726, 5343, 4244, 3371, 2678, 2127, 1690, 1342, 1066, 847, 673, 534, 424, 337, 268, + 213, 169, 134, 107, 85, 67}; + +int WebRtcAgc_AddMic(void *state, WebRtc_Word16 *in_mic, WebRtc_Word16 *in_mic_H, + WebRtc_Word16 samples) +{ + WebRtc_Word32 nrg, max_nrg, sample, tmp32; + WebRtc_Word32 *ptr; + WebRtc_UWord16 targetGainIdx, gain; + WebRtc_Word16 i, n, L, M, subFrames, tmp16, tmp_speech[16]; + Agc_t *stt; + stt = (Agc_t *)state; + + //default/initial values corresponding to 10ms for wb and swb + M = 10; + L = 16; + subFrames = 160; + + if (stt->fs == 8000) + { + if (samples == 80) + { + subFrames = 80; + M = 10; + L = 8; + } else if (samples == 160) + { + subFrames = 80; + M = 20; + L = 8; + } else + { +#ifdef AGC_DEBUG //test log + fprintf(stt->fpt, + "AGC->add_mic, frame %d: Invalid number of samples\n\n", + (stt->fcount + 1)); +#endif + return -1; + } + } else if (stt->fs == 16000) + { + if (samples == 160) + { + subFrames = 160; + M = 10; + L = 16; + } else if (samples == 320) + { + subFrames = 160; + M = 20; + L = 16; + } else + { +#ifdef AGC_DEBUG //test log + fprintf(stt->fpt, + "AGC->add_mic, frame %d: Invalid number of samples\n\n", + (stt->fcount + 1)); +#endif + return -1; + } + } else if (stt->fs == 32000) + { + /* SWB is processed as 160 sample for L and H bands */ + if (samples == 160) + { + subFrames = 160; + M = 10; + L = 16; + } else + { +#ifdef AGC_DEBUG + fprintf(stt->fpt, + "AGC->add_mic, frame %d: Invalid sample rate\n\n", + (stt->fcount + 1)); +#endif + return -1; + } + } + + /* Check for valid pointers based on sampling rate */ + if ((stt->fs == 32000) && (in_mic_H == NULL)) + { + return -1; + } + /* Check for valid pointer for low band */ + if (in_mic == NULL) + { + return -1; + } + + /* apply slowly varying digital gain */ + if (stt->micVol > stt->maxAnalog) + { + /* Q1 */ + tmp16 = (WebRtc_Word16)(stt->micVol - stt->maxAnalog); + tmp32 = WEBRTC_SPL_MUL_16_16(GAIN_TBL_LEN - 1, tmp16); + tmp16 = (WebRtc_Word16)(stt->maxLevel - stt->maxAnalog); + targetGainIdx = (WebRtc_UWord16)WEBRTC_SPL_DIV(tmp32, tmp16); + assert(targetGainIdx < GAIN_TBL_LEN); + + /* Increment through the table towards the target gain. + * If micVol drops below maxAnalog, we allow the gain + * to be dropped immediately. */ + if (stt->gainTableIdx < targetGainIdx) + { + stt->gainTableIdx++; + } else if (stt->gainTableIdx > targetGainIdx) + { + stt->gainTableIdx--; + } + + /* Q12 */ + gain = kGainTableAnalog[stt->gainTableIdx]; + + for (i = 0; i < samples; i++) + { + // For lower band + tmp32 = WEBRTC_SPL_MUL_16_U16(in_mic[i], gain); + sample = WEBRTC_SPL_RSHIFT_W32(tmp32, 12); + if (sample > 32767) + { + in_mic[i] = 32767; + } else if (sample < -32768) + { + in_mic[i] = -32768; + } else + { + in_mic[i] = (WebRtc_Word16)sample; + } + + // For higher band + if (stt->fs == 32000) + { + tmp32 = WEBRTC_SPL_MUL_16_U16(in_mic_H[i], gain); + sample = WEBRTC_SPL_RSHIFT_W32(tmp32, 12); + if (sample > 32767) + { + in_mic_H[i] = 32767; + } else if (sample < -32768) + { + in_mic_H[i] = -32768; + } else + { + in_mic_H[i] = (WebRtc_Word16)sample; + } + } + } + } else + { + stt->gainTableIdx = 0; + } + + /* compute envelope */ + if ((M == 10) && (stt->inQueue > 0)) + { + ptr = stt->env[1]; + } else + { + ptr = stt->env[0]; + } + + for (i = 0; i < M; i++) + { + /* iterate over samples */ + max_nrg = 0; + for (n = 0; n < L; n++) + { + nrg = WEBRTC_SPL_MUL_16_16(in_mic[i * L + n], in_mic[i * L + n]); + if (nrg > max_nrg) + { + max_nrg = nrg; + } + } + ptr[i] = max_nrg; + } + + /* compute energy */ + if ((M == 10) && (stt->inQueue > 0)) + { + ptr = stt->Rxx16w32_array[1]; + } else + { + ptr = stt->Rxx16w32_array[0]; + } + + for (i = 0; i < WEBRTC_SPL_RSHIFT_W16(M, 1); i++) + { + if (stt->fs == 16000) + { + WebRtcSpl_DownsampleBy2(&in_mic[i * 32], 32, tmp_speech, stt->filterState); + } else + { + memcpy(tmp_speech, &in_mic[i * 16], 16 * sizeof(short)); + } + /* Compute energy in blocks of 16 samples */ + ptr[i] = WebRtcSpl_DotProductWithScale(tmp_speech, tmp_speech, 16, 4); + } + + /* update queue information */ + if ((stt->inQueue == 0) && (M == 10)) + { + stt->inQueue = 1; + } else + { + stt->inQueue = 2; + } + + /* call VAD (use low band only) */ + for (i = 0; i < samples; i += subFrames) + { + WebRtcAgc_ProcessVad(&stt->vadMic, &in_mic[i], subFrames); + } + + return 0; +} + +int WebRtcAgc_AddFarend(void *state, const WebRtc_Word16 *in_far, WebRtc_Word16 samples) +{ + WebRtc_Word32 errHandle = 0; + WebRtc_Word16 i, subFrames; + Agc_t *stt; + stt = (Agc_t *)state; + + if (stt == NULL) + { + return -1; + } + + if (stt->fs == 8000) + { + if ((samples != 80) && (samples != 160)) + { +#ifdef AGC_DEBUG //test log + fprintf(stt->fpt, + "AGC->add_far_end, frame %d: Invalid number of samples\n\n", + stt->fcount); +#endif + return -1; + } + subFrames = 80; + } else if (stt->fs == 16000) + { + if ((samples != 160) && (samples != 320)) + { +#ifdef AGC_DEBUG //test log + fprintf(stt->fpt, + "AGC->add_far_end, frame %d: Invalid number of samples\n\n", + stt->fcount); +#endif + return -1; + } + subFrames = 160; + } else if (stt->fs == 32000) + { + if ((samples != 160) && (samples != 320)) + { +#ifdef AGC_DEBUG //test log + fprintf(stt->fpt, + "AGC->add_far_end, frame %d: Invalid number of samples\n\n", + stt->fcount); +#endif + return -1; + } + subFrames = 160; + } else + { +#ifdef AGC_DEBUG //test log + fprintf(stt->fpt, + "AGC->add_far_end, frame %d: Invalid sample rate\n\n", + stt->fcount + 1); +#endif + return -1; + } + + for (i = 0; i < samples; i += subFrames) + { + errHandle += WebRtcAgc_AddFarendToDigital(&stt->digitalAgc, &in_far[i], subFrames); + } + + return errHandle; +} + +int WebRtcAgc_VirtualMic(void *agcInst, WebRtc_Word16 *in_near, WebRtc_Word16 *in_near_H, + WebRtc_Word16 samples, WebRtc_Word32 micLevelIn, + WebRtc_Word32 *micLevelOut) +{ + WebRtc_Word32 tmpFlt, micLevelTmp, gainIdx; + WebRtc_UWord16 gain; + WebRtc_Word16 ii; + Agc_t *stt; + + WebRtc_UWord32 nrg; + WebRtc_Word16 sampleCntr; + WebRtc_UWord32 frameNrg = 0; + WebRtc_UWord32 frameNrgLimit = 5500; + WebRtc_Word16 numZeroCrossing = 0; + const WebRtc_Word16 kZeroCrossingLowLim = 15; + const WebRtc_Word16 kZeroCrossingHighLim = 20; + + stt = (Agc_t *)agcInst; + + /* + * Before applying gain decide if this is a low-level signal. + * The idea is that digital AGC will not adapt to low-level + * signals. + */ + if (stt->fs != 8000) + { + frameNrgLimit = frameNrgLimit << 1; + } + + frameNrg = WEBRTC_SPL_MUL_16_16(in_near[0], in_near[0]); + for (sampleCntr = 1; sampleCntr < samples; sampleCntr++) + { + + // increment frame energy if it is less than the limit + // the correct value of the energy is not important + if (frameNrg < frameNrgLimit) + { + nrg = WEBRTC_SPL_MUL_16_16(in_near[sampleCntr], in_near[sampleCntr]); + frameNrg += nrg; + } + + // Count the zero crossings + numZeroCrossing += ((in_near[sampleCntr] ^ in_near[sampleCntr - 1]) < 0); + } + + if ((frameNrg < 500) || (numZeroCrossing <= 5)) + { + stt->lowLevelSignal = 1; + } else if (numZeroCrossing <= kZeroCrossingLowLim) + { + stt->lowLevelSignal = 0; + } else if (frameNrg <= frameNrgLimit) + { + stt->lowLevelSignal = 1; + } else if (numZeroCrossing >= kZeroCrossingHighLim) + { + stt->lowLevelSignal = 1; + } else + { + stt->lowLevelSignal = 0; + } + + micLevelTmp = WEBRTC_SPL_LSHIFT_W32(micLevelIn, stt->scale); + /* Set desired level */ + gainIdx = stt->micVol; + if (stt->micVol > stt->maxAnalog) + { + gainIdx = stt->maxAnalog; + } + if (micLevelTmp != stt->micRef) + { + /* Something has happened with the physical level, restart. */ + stt->micRef = micLevelTmp; + stt->micVol = 127; + *micLevelOut = 127; + stt->micGainIdx = 127; + gainIdx = 127; + } + /* Pre-process the signal to emulate the microphone level. */ + /* Take one step at a time in the gain table. */ + if (gainIdx > 127) + { + gain = kGainTableVirtualMic[gainIdx - 128]; + } else + { + gain = kSuppressionTableVirtualMic[127 - gainIdx]; + } + for (ii = 0; ii < samples; ii++) + { + tmpFlt = WEBRTC_SPL_RSHIFT_W32(WEBRTC_SPL_MUL_16_U16(in_near[ii], gain), 10); + if (tmpFlt > 32767) + { + tmpFlt = 32767; + gainIdx--; + if (gainIdx >= 127) + { + gain = kGainTableVirtualMic[gainIdx - 127]; + } else + { + gain = kSuppressionTableVirtualMic[127 - gainIdx]; + } + } + if (tmpFlt < -32768) + { + tmpFlt = -32768; + gainIdx--; + if (gainIdx >= 127) + { + gain = kGainTableVirtualMic[gainIdx - 127]; + } else + { + gain = kSuppressionTableVirtualMic[127 - gainIdx]; + } + } + in_near[ii] = (WebRtc_Word16)tmpFlt; + if (stt->fs == 32000) + { + tmpFlt = WEBRTC_SPL_MUL_16_U16(in_near_H[ii], gain); + tmpFlt = WEBRTC_SPL_RSHIFT_W32(tmpFlt, 10); + if (tmpFlt > 32767) + { + tmpFlt = 32767; + } + if (tmpFlt < -32768) + { + tmpFlt = -32768; + } + in_near_H[ii] = (WebRtc_Word16)tmpFlt; + } + } + /* Set the level we (finally) used */ + stt->micGainIdx = gainIdx; +// *micLevelOut = stt->micGainIdx; + *micLevelOut = WEBRTC_SPL_RSHIFT_W32(stt->micGainIdx, stt->scale); + /* Add to Mic as if it was the output from a true microphone */ + if (WebRtcAgc_AddMic(agcInst, in_near, in_near_H, samples) != 0) + { + return -1; + } + return 0; +} + +void WebRtcAgc_UpdateAgcThresholds(Agc_t *stt) +{ + + WebRtc_Word16 tmp16; +#ifdef MIC_LEVEL_FEEDBACK + int zeros; + + if (stt->micLvlSat) + { + /* Lower the analog target level since we have reached its maximum */ + zeros = WebRtcSpl_NormW32(stt->Rxx160_LPw32); + stt->targetIdxOffset = WEBRTC_SPL_RSHIFT_W16((3 * zeros) - stt->targetIdx - 2, 2); + } +#endif + + /* Set analog target level in envelope dBOv scale */ + tmp16 = (DIFF_REF_TO_ANALOG * stt->compressionGaindB) + ANALOG_TARGET_LEVEL_2; + tmp16 = WebRtcSpl_DivW32W16ResW16((WebRtc_Word32)tmp16, ANALOG_TARGET_LEVEL); + stt->analogTarget = DIGITAL_REF_AT_0_COMP_GAIN + tmp16; + if (stt->analogTarget < DIGITAL_REF_AT_0_COMP_GAIN) + { + stt->analogTarget = DIGITAL_REF_AT_0_COMP_GAIN; + } + if (stt->agcMode == kAgcModeFixedDigital) + { + /* Adjust for different parameter interpretation in FixedDigital mode */ + stt->analogTarget = stt->compressionGaindB; + } +#ifdef MIC_LEVEL_FEEDBACK + stt->analogTarget += stt->targetIdxOffset; +#endif + /* Since the offset between RMS and ENV is not constant, we should make this into a + * table, but for now, we'll stick with a constant, tuned for the chosen analog + * target level. + */ + stt->targetIdx = ANALOG_TARGET_LEVEL + OFFSET_ENV_TO_RMS; +#ifdef MIC_LEVEL_FEEDBACK + stt->targetIdx += stt->targetIdxOffset; +#endif + /* Analog adaptation limits */ + /* analogTargetLevel = round((32767*10^(-targetIdx/20))^2*16/2^7) */ + stt->analogTargetLevel = RXX_BUFFER_LEN * kTargetLevelTable[stt->targetIdx]; /* ex. -20 dBov */ + stt->startUpperLimit = RXX_BUFFER_LEN * kTargetLevelTable[stt->targetIdx - 1];/* -19 dBov */ + stt->startLowerLimit = RXX_BUFFER_LEN * kTargetLevelTable[stt->targetIdx + 1];/* -21 dBov */ + stt->upperPrimaryLimit = RXX_BUFFER_LEN * kTargetLevelTable[stt->targetIdx - 2];/* -18 dBov */ + stt->lowerPrimaryLimit = RXX_BUFFER_LEN * kTargetLevelTable[stt->targetIdx + 2];/* -22 dBov */ + stt->upperSecondaryLimit = RXX_BUFFER_LEN * kTargetLevelTable[stt->targetIdx - 5];/* -15 dBov */ + stt->lowerSecondaryLimit = RXX_BUFFER_LEN * kTargetLevelTable[stt->targetIdx + 5];/* -25 dBov */ + stt->upperLimit = stt->startUpperLimit; + stt->lowerLimit = stt->startLowerLimit; +} + +void WebRtcAgc_SaturationCtrl(Agc_t *stt, WebRtc_UWord8 *saturated, WebRtc_Word32 *env) +{ + WebRtc_Word16 i, tmpW16; + + /* Check if the signal is saturated */ + for (i = 0; i < 10; i++) + { + tmpW16 = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32(env[i], 20); + if (tmpW16 > 875) + { + stt->envSum += tmpW16; + } + } + + if (stt->envSum > 25000) + { + *saturated = 1; + stt->envSum = 0; + } + + /* stt->envSum *= 0.99; */ + stt->envSum = (WebRtc_Word16)WEBRTC_SPL_MUL_16_16_RSFT(stt->envSum, + (WebRtc_Word16)32440, 15); +} + +void WebRtcAgc_ZeroCtrl(Agc_t *stt, WebRtc_Word32 *inMicLevel, WebRtc_Word32 *env) +{ + WebRtc_Word16 i; + WebRtc_Word32 tmp32 = 0; + WebRtc_Word32 midVal; + + /* Is the input signal zero? */ + for (i = 0; i < 10; i++) + { + tmp32 += env[i]; + } + + /* Each block is allowed to have a few non-zero + * samples. + */ + if (tmp32 < 500) + { + stt->msZero += 10; + } else + { + stt->msZero = 0; + } + + if (stt->muteGuardMs > 0) + { + stt->muteGuardMs -= 10; + } + + if (stt->msZero > 500) + { + stt->msZero = 0; + + /* Increase microphone level only if it's less than 50% */ + midVal = WEBRTC_SPL_RSHIFT_W32(stt->maxAnalog + stt->minLevel + 1, 1); + if (*inMicLevel < midVal) + { + /* *inMicLevel *= 1.1; */ + tmp32 = WEBRTC_SPL_MUL(1126, *inMicLevel); + *inMicLevel = WEBRTC_SPL_RSHIFT_W32(tmp32, 10); + /* Reduces risk of a muted mic repeatedly triggering excessive levels due + * to zero signal detection. */ + *inMicLevel = WEBRTC_SPL_MIN(*inMicLevel, stt->zeroCtrlMax); + stt->micVol = *inMicLevel; + } + +#ifdef AGC_DEBUG //test log + fprintf(stt->fpt, + "\t\tAGC->zeroCntrl, frame %d: 500 ms under threshold, micVol:\n", + stt->fcount, stt->micVol); +#endif + + stt->activeSpeech = 0; + stt->Rxx16_LPw32Max = 0; + + /* The AGC has a tendency (due to problems with the VAD parameters), to + * vastly increase the volume after a muting event. This timer prevents + * upwards adaptation for a short period. */ + stt->muteGuardMs = kMuteGuardTimeMs; + } +} + +void WebRtcAgc_SpeakerInactiveCtrl(Agc_t *stt) +{ + /* Check if the near end speaker is inactive. + * If that is the case the VAD threshold is + * increased since the VAD speech model gets + * more sensitive to any sound after a long + * silence. + */ + + WebRtc_Word32 tmp32; + WebRtc_Word16 vadThresh; + + if (stt->vadMic.stdLongTerm < 2500) + { + stt->vadThreshold = 1500; + } else + { + vadThresh = kNormalVadThreshold; + if (stt->vadMic.stdLongTerm < 4500) + { + /* Scale between min and max threshold */ + vadThresh += WEBRTC_SPL_RSHIFT_W16(4500 - stt->vadMic.stdLongTerm, 1); + } + + /* stt->vadThreshold = (31 * stt->vadThreshold + vadThresh) / 32; */ + tmp32 = (WebRtc_Word32)vadThresh; + tmp32 += WEBRTC_SPL_MUL_16_16((WebRtc_Word16)31, stt->vadThreshold); + stt->vadThreshold = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32(tmp32, 5); + } +} + +void WebRtcAgc_ExpCurve(WebRtc_Word16 volume, WebRtc_Word16 *index) +{ + // volume in Q14 + // index in [0-7] + /* 8 different curves */ + if (volume > 5243) + { + if (volume > 7864) + { + if (volume > 12124) + { + *index = 7; + } else + { + *index = 6; + } + } else + { + if (volume > 6554) + { + *index = 5; + } else + { + *index = 4; + } + } + } else + { + if (volume > 2621) + { + if (volume > 3932) + { + *index = 3; + } else + { + *index = 2; + } + } else + { + if (volume > 1311) + { + *index = 1; + } else + { + *index = 0; + } + } + } +} + +WebRtc_Word32 WebRtcAgc_ProcessAnalog(void *state, WebRtc_Word32 inMicLevel, + WebRtc_Word32 *outMicLevel, + WebRtc_Word16 vadLogRatio, + WebRtc_Word16 echo, WebRtc_UWord8 *saturationWarning) +{ + WebRtc_UWord32 tmpU32; + WebRtc_Word32 Rxx16w32, tmp32; + WebRtc_Word32 inMicLevelTmp, lastMicVol; + WebRtc_Word16 i; + WebRtc_UWord8 saturated = 0; + Agc_t *stt; + + stt = (Agc_t *)state; + inMicLevelTmp = WEBRTC_SPL_LSHIFT_W32(inMicLevel, stt->scale); + + if (inMicLevelTmp > stt->maxAnalog) + { +#ifdef AGC_DEBUG //test log + fprintf(stt->fpt, "\tAGC->ProcessAnalog, frame %d: micLvl > maxAnalog\n", stt->fcount); +#endif + return -1; + } else if (inMicLevelTmp < stt->minLevel) + { +#ifdef AGC_DEBUG //test log + fprintf(stt->fpt, "\tAGC->ProcessAnalog, frame %d: micLvl < minLevel\n", stt->fcount); +#endif + return -1; + } + + if (stt->firstCall == 0) + { + WebRtc_Word32 tmpVol; + stt->firstCall = 1; + tmp32 = WEBRTC_SPL_RSHIFT_W32((stt->maxLevel - stt->minLevel) * (WebRtc_Word32)51, 9); + tmpVol = (stt->minLevel + tmp32); + + /* If the mic level is very low at start, increase it! */ + if ((inMicLevelTmp < tmpVol) && (stt->agcMode == kAgcModeAdaptiveAnalog)) + { + inMicLevelTmp = tmpVol; + } + stt->micVol = inMicLevelTmp; + } + + /* Set the mic level to the previous output value if there is digital input gain */ + if ((inMicLevelTmp == stt->maxAnalog) && (stt->micVol > stt->maxAnalog)) + { + inMicLevelTmp = stt->micVol; + } + + /* If the mic level was manually changed to a very low value raise it! */ + if ((inMicLevelTmp != stt->micVol) && (inMicLevelTmp < stt->minOutput)) + { + tmp32 = WEBRTC_SPL_RSHIFT_W32((stt->maxLevel - stt->minLevel) * (WebRtc_Word32)51, 9); + inMicLevelTmp = (stt->minLevel + tmp32); + stt->micVol = inMicLevelTmp; +#ifdef MIC_LEVEL_FEEDBACK + //stt->numBlocksMicLvlSat = 0; +#endif +#ifdef AGC_DEBUG //test log + fprintf(stt->fpt, + "\tAGC->ProcessAnalog, frame %d: micLvl < minLevel by manual decrease, raise vol\n", + stt->fcount); +#endif + } + + if (inMicLevelTmp != stt->micVol) + { + // Incoming level mismatch; update our level. + // This could be the case if the volume is changed manually, or if the + // sound device has a low volume resolution. + stt->micVol = inMicLevelTmp; + } + + if (inMicLevelTmp > stt->maxLevel) + { + // Always allow the user to raise the volume above the maxLevel. + stt->maxLevel = inMicLevelTmp; + } + + // Store last value here, after we've taken care of manual updates etc. + lastMicVol = stt->micVol; + + /* Checks if the signal is saturated. Also a check if individual samples + * are larger than 12000 is done. If they are the counter for increasing + * the volume level is set to -100ms + */ + WebRtcAgc_SaturationCtrl(stt, &saturated, stt->env[0]); + + /* The AGC is always allowed to lower the level if the signal is saturated */ + if (saturated == 1) + { + /* Lower the recording level + * Rxx160_LP is adjusted down because it is so slow it could + * cause the AGC to make wrong decisions. */ + /* stt->Rxx160_LPw32 *= 0.875; */ + stt->Rxx160_LPw32 = WEBRTC_SPL_MUL(WEBRTC_SPL_RSHIFT_W32(stt->Rxx160_LPw32, 3), 7); + + stt->zeroCtrlMax = stt->micVol; + + /* stt->micVol *= 0.903; */ + tmp32 = inMicLevelTmp - stt->minLevel; + tmpU32 = WEBRTC_SPL_UMUL(29591, (WebRtc_UWord32)(tmp32)); + stt->micVol = (WebRtc_Word32)WEBRTC_SPL_RSHIFT_U32(tmpU32, 15) + stt->minLevel; + if (stt->micVol > lastMicVol - 2) + { + stt->micVol = lastMicVol - 2; + } + inMicLevelTmp = stt->micVol; + +#ifdef AGC_DEBUG //test log + fprintf(stt->fpt, + "\tAGC->ProcessAnalog, frame %d: saturated, micVol = %d\n", + stt->fcount, stt->micVol); +#endif + + if (stt->micVol < stt->minOutput) + { + *saturationWarning = 1; + } + + /* Reset counter for decrease of volume level to avoid + * decreasing too much. The saturation control can still + * lower the level if needed. */ + stt->msTooHigh = -100; + + /* Enable the control mechanism to ensure that our measure, + * Rxx160_LP, is in the correct range. This must be done since + * the measure is very slow. */ + stt->activeSpeech = 0; + stt->Rxx16_LPw32Max = 0; + + /* Reset to initial values */ + stt->msecSpeechInnerChange = kMsecSpeechInner; + stt->msecSpeechOuterChange = kMsecSpeechOuter; + stt->changeToSlowMode = 0; + + stt->muteGuardMs = 0; + + stt->upperLimit = stt->startUpperLimit; + stt->lowerLimit = stt->startLowerLimit; +#ifdef MIC_LEVEL_FEEDBACK + //stt->numBlocksMicLvlSat = 0; +#endif + } + + /* Check if the input speech is zero. If so the mic volume + * is increased. On some computers the input is zero up as high + * level as 17% */ + WebRtcAgc_ZeroCtrl(stt, &inMicLevelTmp, stt->env[0]); + + /* Check if the near end speaker is inactive. + * If that is the case the VAD threshold is + * increased since the VAD speech model gets + * more sensitive to any sound after a long + * silence. + */ + WebRtcAgc_SpeakerInactiveCtrl(stt); + + for (i = 0; i < 5; i++) + { + /* Computed on blocks of 16 samples */ + + Rxx16w32 = stt->Rxx16w32_array[0][i]; + + /* Rxx160w32 in Q(-7) */ + tmp32 = WEBRTC_SPL_RSHIFT_W32(Rxx16w32 - stt->Rxx16_vectorw32[stt->Rxx16pos], 3); + stt->Rxx160w32 = stt->Rxx160w32 + tmp32; + stt->Rxx16_vectorw32[stt->Rxx16pos] = Rxx16w32; + + /* Circular buffer */ + stt->Rxx16pos++; + if (stt->Rxx16pos == RXX_BUFFER_LEN) + { + stt->Rxx16pos = 0; + } + + /* Rxx16_LPw32 in Q(-4) */ + tmp32 = WEBRTC_SPL_RSHIFT_W32(Rxx16w32 - stt->Rxx16_LPw32, kAlphaShortTerm); + stt->Rxx16_LPw32 = (stt->Rxx16_LPw32) + tmp32; + + if (vadLogRatio > stt->vadThreshold) + { + /* Speech detected! */ + + /* Check if Rxx160_LP is in the correct range. If + * it is too high/low then we set it to the maximum of + * Rxx16_LPw32 during the first 200ms of speech. + */ + if (stt->activeSpeech < 250) + { + stt->activeSpeech += 2; + + if (stt->Rxx16_LPw32 > stt->Rxx16_LPw32Max) + { + stt->Rxx16_LPw32Max = stt->Rxx16_LPw32; + } + } else if (stt->activeSpeech == 250) + { + stt->activeSpeech += 2; + tmp32 = WEBRTC_SPL_RSHIFT_W32(stt->Rxx16_LPw32Max, 3); + stt->Rxx160_LPw32 = WEBRTC_SPL_MUL(tmp32, RXX_BUFFER_LEN); + } + + tmp32 = WEBRTC_SPL_RSHIFT_W32(stt->Rxx160w32 - stt->Rxx160_LPw32, kAlphaLongTerm); + stt->Rxx160_LPw32 = stt->Rxx160_LPw32 + tmp32; + + if (stt->Rxx160_LPw32 > stt->upperSecondaryLimit) + { + stt->msTooHigh += 2; + stt->msTooLow = 0; + stt->changeToSlowMode = 0; + + if (stt->msTooHigh > stt->msecSpeechOuterChange) + { + stt->msTooHigh = 0; + + /* Lower the recording level */ + /* Multiply by 0.828125 which corresponds to decreasing ~0.8dB */ + tmp32 = WEBRTC_SPL_RSHIFT_W32(stt->Rxx160_LPw32, 6); + stt->Rxx160_LPw32 = WEBRTC_SPL_MUL(tmp32, 53); + + /* Reduce the max gain to avoid excessive oscillation + * (but never drop below the maximum analog level). + * stt->maxLevel = (15 * stt->maxLevel + stt->micVol) / 16; + */ + tmp32 = (15 * stt->maxLevel) + stt->micVol; + stt->maxLevel = WEBRTC_SPL_RSHIFT_W32(tmp32, 4); + stt->maxLevel = WEBRTC_SPL_MAX(stt->maxLevel, stt->maxAnalog); + + stt->zeroCtrlMax = stt->micVol; + + /* 0.95 in Q15 */ + tmp32 = inMicLevelTmp - stt->minLevel; + tmpU32 = WEBRTC_SPL_UMUL(31130, (WebRtc_UWord32)(tmp32)); + stt->micVol = (WebRtc_Word32)WEBRTC_SPL_RSHIFT_U32(tmpU32, 15) + stt->minLevel; + if (stt->micVol > lastMicVol - 1) + { + stt->micVol = lastMicVol - 1; + } + inMicLevelTmp = stt->micVol; + + /* Enable the control mechanism to ensure that our measure, + * Rxx160_LP, is in the correct range. + */ + stt->activeSpeech = 0; + stt->Rxx16_LPw32Max = 0; +#ifdef MIC_LEVEL_FEEDBACK + //stt->numBlocksMicLvlSat = 0; +#endif +#ifdef AGC_DEBUG //test log + fprintf(stt->fpt, + "\tAGC->ProcessAnalog, frame %d: measure > 2ndUpperLim, micVol = %d, maxLevel = %d\n", + stt->fcount, stt->micVol, stt->maxLevel); +#endif + } + } else if (stt->Rxx160_LPw32 > stt->upperLimit) + { + stt->msTooHigh += 2; + stt->msTooLow = 0; + stt->changeToSlowMode = 0; + + if (stt->msTooHigh > stt->msecSpeechInnerChange) + { + /* Lower the recording level */ + stt->msTooHigh = 0; + /* Multiply by 0.828125 which corresponds to decreasing ~0.8dB */ + tmp32 = WEBRTC_SPL_RSHIFT_W32(stt->Rxx160_LPw32, 6); + stt->Rxx160_LPw32 = WEBRTC_SPL_MUL(tmp32, 53); + + /* Reduce the max gain to avoid excessive oscillation + * (but never drop below the maximum analog level). + * stt->maxLevel = (15 * stt->maxLevel + stt->micVol) / 16; + */ + tmp32 = (15 * stt->maxLevel) + stt->micVol; + stt->maxLevel = WEBRTC_SPL_RSHIFT_W32(tmp32, 4); + stt->maxLevel = WEBRTC_SPL_MAX(stt->maxLevel, stt->maxAnalog); + + stt->zeroCtrlMax = stt->micVol; + + /* 0.965 in Q15 */ + tmp32 = inMicLevelTmp - stt->minLevel; + tmpU32 = WEBRTC_SPL_UMUL(31621, (WebRtc_UWord32)(inMicLevelTmp - stt->minLevel)); + stt->micVol = (WebRtc_Word32)WEBRTC_SPL_RSHIFT_U32(tmpU32, 15) + stt->minLevel; + if (stt->micVol > lastMicVol - 1) + { + stt->micVol = lastMicVol - 1; + } + inMicLevelTmp = stt->micVol; + +#ifdef MIC_LEVEL_FEEDBACK + //stt->numBlocksMicLvlSat = 0; +#endif +#ifdef AGC_DEBUG //test log + fprintf(stt->fpt, + "\tAGC->ProcessAnalog, frame %d: measure > UpperLim, micVol = %d, maxLevel = %d\n", + stt->fcount, stt->micVol, stt->maxLevel); +#endif + } + } else if (stt->Rxx160_LPw32 < stt->lowerSecondaryLimit) + { + stt->msTooHigh = 0; + stt->changeToSlowMode = 0; + stt->msTooLow += 2; + + if (stt->msTooLow > stt->msecSpeechOuterChange) + { + /* Raise the recording level */ + WebRtc_Word16 index, weightFIX; + WebRtc_Word16 volNormFIX = 16384; // =1 in Q14. + + stt->msTooLow = 0; + + /* Normalize the volume level */ + tmp32 = WEBRTC_SPL_LSHIFT_W32(inMicLevelTmp - stt->minLevel, 14); + if (stt->maxInit != stt->minLevel) + { + volNormFIX = (WebRtc_Word16)WEBRTC_SPL_DIV(tmp32, + (stt->maxInit - stt->minLevel)); + } + + /* Find correct curve */ + WebRtcAgc_ExpCurve(volNormFIX, &index); + + /* Compute weighting factor for the volume increase, 32^(-2*X)/2+1.05 */ + weightFIX = kOffset1[index] + - (WebRtc_Word16)WEBRTC_SPL_MUL_16_16_RSFT(kSlope1[index], + volNormFIX, 13); + + /* stt->Rxx160_LPw32 *= 1.047 [~0.2 dB]; */ + tmp32 = WEBRTC_SPL_RSHIFT_W32(stt->Rxx160_LPw32, 6); + stt->Rxx160_LPw32 = WEBRTC_SPL_MUL(tmp32, 67); + + tmp32 = inMicLevelTmp - stt->minLevel; + tmpU32 = ((WebRtc_UWord32)weightFIX * (WebRtc_UWord32)(inMicLevelTmp - stt->minLevel)); + stt->micVol = (WebRtc_Word32)WEBRTC_SPL_RSHIFT_U32(tmpU32, 14) + stt->minLevel; + if (stt->micVol < lastMicVol + 2) + { + stt->micVol = lastMicVol + 2; + } + + inMicLevelTmp = stt->micVol; + +#ifdef MIC_LEVEL_FEEDBACK + /* Count ms in level saturation */ + //if (stt->micVol > stt->maxAnalog) { + if (stt->micVol > 150) + { + /* mic level is saturated */ + stt->numBlocksMicLvlSat++; + fprintf(stderr, "Sat mic Level: %d\n", stt->numBlocksMicLvlSat); + } +#endif +#ifdef AGC_DEBUG //test log + fprintf(stt->fpt, + "\tAGC->ProcessAnalog, frame %d: measure < 2ndLowerLim, micVol = %d\n", + stt->fcount, stt->micVol); +#endif + } + } else if (stt->Rxx160_LPw32 < stt->lowerLimit) + { + stt->msTooHigh = 0; + stt->changeToSlowMode = 0; + stt->msTooLow += 2; + + if (stt->msTooLow > stt->msecSpeechInnerChange) + { + /* Raise the recording level */ + WebRtc_Word16 index, weightFIX; + WebRtc_Word16 volNormFIX = 16384; // =1 in Q14. + + stt->msTooLow = 0; + + /* Normalize the volume level */ + tmp32 = WEBRTC_SPL_LSHIFT_W32(inMicLevelTmp - stt->minLevel, 14); + if (stt->maxInit != stt->minLevel) + { + volNormFIX = (WebRtc_Word16)WEBRTC_SPL_DIV(tmp32, + (stt->maxInit - stt->minLevel)); + } + + /* Find correct curve */ + WebRtcAgc_ExpCurve(volNormFIX, &index); + + /* Compute weighting factor for the volume increase, (3.^(-2.*X))/8+1 */ + weightFIX = kOffset2[index] + - (WebRtc_Word16)WEBRTC_SPL_MUL_16_16_RSFT(kSlope2[index], + volNormFIX, 13); + + /* stt->Rxx160_LPw32 *= 1.047 [~0.2 dB]; */ + tmp32 = WEBRTC_SPL_RSHIFT_W32(stt->Rxx160_LPw32, 6); + stt->Rxx160_LPw32 = WEBRTC_SPL_MUL(tmp32, 67); + + tmp32 = inMicLevelTmp - stt->minLevel; + tmpU32 = ((WebRtc_UWord32)weightFIX * (WebRtc_UWord32)(inMicLevelTmp - stt->minLevel)); + stt->micVol = (WebRtc_Word32)WEBRTC_SPL_RSHIFT_U32(tmpU32, 14) + stt->minLevel; + if (stt->micVol < lastMicVol + 1) + { + stt->micVol = lastMicVol + 1; + } + + inMicLevelTmp = stt->micVol; + +#ifdef MIC_LEVEL_FEEDBACK + /* Count ms in level saturation */ + //if (stt->micVol > stt->maxAnalog) { + if (stt->micVol > 150) + { + /* mic level is saturated */ + stt->numBlocksMicLvlSat++; + fprintf(stderr, "Sat mic Level: %d\n", stt->numBlocksMicLvlSat); + } +#endif +#ifdef AGC_DEBUG //test log + fprintf(stt->fpt, + "\tAGC->ProcessAnalog, frame %d: measure < LowerLim, micVol = %d\n", + stt->fcount, stt->micVol); +#endif + + } + } else + { + /* The signal is inside the desired range which is: + * lowerLimit < Rxx160_LP/640 < upperLimit + */ + if (stt->changeToSlowMode > 4000) + { + stt->msecSpeechInnerChange = 1000; + stt->msecSpeechOuterChange = 500; + stt->upperLimit = stt->upperPrimaryLimit; + stt->lowerLimit = stt->lowerPrimaryLimit; + } else + { + stt->changeToSlowMode += 2; // in milliseconds + } + stt->msTooLow = 0; + stt->msTooHigh = 0; + + stt->micVol = inMicLevelTmp; + + } +#ifdef MIC_LEVEL_FEEDBACK + if (stt->numBlocksMicLvlSat > NUM_BLOCKS_IN_SAT_BEFORE_CHANGE_TARGET) + { + stt->micLvlSat = 1; + fprintf(stderr, "target before = %d (%d)\n", stt->analogTargetLevel, stt->targetIdx); + WebRtcAgc_UpdateAgcThresholds(stt); + WebRtcAgc_CalculateGainTable(&(stt->digitalAgc.gainTable[0]), + stt->compressionGaindB, stt->targetLevelDbfs, stt->limiterEnable, + stt->analogTarget); + stt->numBlocksMicLvlSat = 0; + stt->micLvlSat = 0; + fprintf(stderr, "target offset = %d\n", stt->targetIdxOffset); + fprintf(stderr, "target after = %d (%d)\n", stt->analogTargetLevel, stt->targetIdx); + } +#endif + } + } + + /* Ensure gain is not increased in presence of echo or after a mute event + * (but allow the zeroCtrl() increase on the frame of a mute detection). + */ + if (echo == 1 || (stt->muteGuardMs > 0 && stt->muteGuardMs < kMuteGuardTimeMs)) + { + if (stt->micVol > lastMicVol) + { + stt->micVol = lastMicVol; + } + } + + /* limit the gain */ + if (stt->micVol > stt->maxLevel) + { + stt->micVol = stt->maxLevel; + } else if (stt->micVol < stt->minOutput) + { + stt->micVol = stt->minOutput; + } + + *outMicLevel = WEBRTC_SPL_RSHIFT_W32(stt->micVol, stt->scale); + if (*outMicLevel > WEBRTC_SPL_RSHIFT_W32(stt->maxAnalog, stt->scale)) + { + *outMicLevel = WEBRTC_SPL_RSHIFT_W32(stt->maxAnalog, stt->scale); + } + + return 0; +} + +int WebRtcAgc_Process(void *agcInst, const WebRtc_Word16 *in_near, + const WebRtc_Word16 *in_near_H, WebRtc_Word16 samples, + WebRtc_Word16 *out, WebRtc_Word16 *out_H, WebRtc_Word32 inMicLevel, + WebRtc_Word32 *outMicLevel, WebRtc_Word16 echo, + WebRtc_UWord8 *saturationWarning) +{ + Agc_t *stt; + WebRtc_Word32 inMicLevelTmp; + WebRtc_Word16 subFrames, i; + WebRtc_UWord8 satWarningTmp = 0; + + stt = (Agc_t *)agcInst; + + // + if (stt == NULL) + { + return -1; + } + // + + + if (stt->fs == 8000) + { + if ((samples != 80) && (samples != 160)) + { +#ifdef AGC_DEBUG //test log + fprintf(stt->fpt, + "AGC->Process, frame %d: Invalid number of samples\n\n", stt->fcount); +#endif + return -1; + } + subFrames = 80; + } else if (stt->fs == 16000) + { + if ((samples != 160) && (samples != 320)) + { +#ifdef AGC_DEBUG //test log + fprintf(stt->fpt, + "AGC->Process, frame %d: Invalid number of samples\n\n", stt->fcount); +#endif + return -1; + } + subFrames = 160; + } else if (stt->fs == 32000) + { + if ((samples != 160) && (samples != 320)) + { +#ifdef AGC_DEBUG //test log + fprintf(stt->fpt, + "AGC->Process, frame %d: Invalid number of samples\n\n", stt->fcount); +#endif + return -1; + } + subFrames = 160; + } else + { +#ifdef AGC_DEBUG// test log + fprintf(stt->fpt, + "AGC->Process, frame %d: Invalid sample rate\n\n", stt->fcount); +#endif + return -1; + } + + /* Check for valid pointers based on sampling rate */ + if (stt->fs == 32000 && in_near_H == NULL) + { + return -1; + } + /* Check for valid pointers for low band */ + if (in_near == NULL) + { + return -1; + } + + *saturationWarning = 0; + //TODO: PUT IN RANGE CHECKING FOR INPUT LEVELS + *outMicLevel = inMicLevel; + inMicLevelTmp = inMicLevel; + + // TODO(andrew): clearly we don't need input and output pointers... + // Change the interface to take a shared input/output. + if (in_near != out) + { + // Only needed if they don't already point to the same place. + memcpy(out, in_near, samples * sizeof(WebRtc_Word16)); + } + if (stt->fs == 32000) + { + if (in_near_H != out_H) + { + memcpy(out_H, in_near_H, samples * sizeof(WebRtc_Word16)); + } + } + +#ifdef AGC_DEBUG//test log + stt->fcount++; +#endif + + for (i = 0; i < samples; i += subFrames) + { + if (WebRtcAgc_ProcessDigital(&stt->digitalAgc, &in_near[i], &in_near_H[i], &out[i], &out_H[i], + stt->fs, stt->lowLevelSignal) == -1) + { +#ifdef AGC_DEBUG//test log + fprintf(stt->fpt, "AGC->Process, frame %d: Error from DigAGC\n\n", stt->fcount); +#endif + return -1; + } + if ((stt->agcMode < kAgcModeFixedDigital) && ((stt->lowLevelSignal == 0) + || (stt->agcMode != kAgcModeAdaptiveDigital))) + { + if (WebRtcAgc_ProcessAnalog(agcInst, inMicLevelTmp, outMicLevel, + stt->vadMic.logRatio, echo, saturationWarning) == -1) + { + return -1; + } + } +#ifdef AGC_DEBUG//test log + fprintf(stt->agcLog, "%5d\t%d\t%d\t%d\n", stt->fcount, inMicLevelTmp, *outMicLevel, stt->maxLevel, stt->micVol); +#endif + + /* update queue */ + if (stt->inQueue > 1) + { + memcpy(stt->env[0], stt->env[1], 10 * sizeof(WebRtc_Word32)); + memcpy(stt->Rxx16w32_array[0], stt->Rxx16w32_array[1], 5 * sizeof(WebRtc_Word32)); + } + + if (stt->inQueue > 0) + { + stt->inQueue--; + } + + /* If 20ms frames are used the input mic level must be updated so that + * the analog AGC does not think that there has been a manual volume + * change. */ + inMicLevelTmp = *outMicLevel; + + /* Store a positive saturation warning. */ + if (*saturationWarning == 1) + { + satWarningTmp = 1; + } + } + + /* Trigger the saturation warning if displayed by any of the frames. */ + *saturationWarning = satWarningTmp; + + return 0; +} + +int WebRtcAgc_set_config(void *agcInst, WebRtcAgc_config_t agcConfig) +{ + Agc_t *stt; + stt = (Agc_t *)agcInst; + + if (stt == NULL) + { + return -1; + } + + if (stt->initFlag != kInitCheck) + { + stt->lastError = AGC_UNINITIALIZED_ERROR; + return -1; + } + + if (agcConfig.limiterEnable != kAgcFalse && agcConfig.limiterEnable != kAgcTrue) + { + stt->lastError = AGC_BAD_PARAMETER_ERROR; + return -1; + } + stt->limiterEnable = agcConfig.limiterEnable; + stt->compressionGaindB = agcConfig.compressionGaindB; + if ((agcConfig.targetLevelDbfs < 0) || (agcConfig.targetLevelDbfs > 31)) + { + stt->lastError = AGC_BAD_PARAMETER_ERROR; + return -1; + } + stt->targetLevelDbfs = agcConfig.targetLevelDbfs; + + if (stt->agcMode == kAgcModeFixedDigital) + { + /* Adjust for different parameter interpretation in FixedDigital mode */ + stt->compressionGaindB += agcConfig.targetLevelDbfs; + } + + /* Update threshold levels for analog adaptation */ + WebRtcAgc_UpdateAgcThresholds(stt); + + /* Recalculate gain table */ + if (WebRtcAgc_CalculateGainTable(&(stt->digitalAgc.gainTable[0]), stt->compressionGaindB, + stt->targetLevelDbfs, stt->limiterEnable, stt->analogTarget) == -1) + { +#ifdef AGC_DEBUG//test log + fprintf(stt->fpt, "AGC->set_config, frame %d: Error from calcGainTable\n\n", stt->fcount); +#endif + return -1; + } + /* Store the config in a WebRtcAgc_config_t */ + stt->usedConfig.compressionGaindB = agcConfig.compressionGaindB; + stt->usedConfig.limiterEnable = agcConfig.limiterEnable; + stt->usedConfig.targetLevelDbfs = agcConfig.targetLevelDbfs; + + return 0; +} + +int WebRtcAgc_get_config(void *agcInst, WebRtcAgc_config_t *config) +{ + Agc_t *stt; + stt = (Agc_t *)agcInst; + + if (stt == NULL) + { + return -1; + } + + if (config == NULL) + { + stt->lastError = AGC_NULL_POINTER_ERROR; + return -1; + } + + if (stt->initFlag != kInitCheck) + { + stt->lastError = AGC_UNINITIALIZED_ERROR; + return -1; + } + + config->limiterEnable = stt->usedConfig.limiterEnable; + config->targetLevelDbfs = stt->usedConfig.targetLevelDbfs; + config->compressionGaindB = stt->usedConfig.compressionGaindB; + + return 0; +} + +int WebRtcAgc_Create(void **agcInst) +{ + Agc_t *stt; + if (agcInst == NULL) + { + return -1; + } + stt = (Agc_t *)malloc(sizeof(Agc_t)); + + *agcInst = stt; + if (stt == NULL) + { + return -1; + } + +#ifdef AGC_DEBUG + stt->fpt = fopen("./agc_test_log.txt", "wt"); + stt->agcLog = fopen("./agc_debug_log.txt", "wt"); + stt->digitalAgc.logFile = fopen("./agc_log.txt", "wt"); +#endif + + stt->initFlag = 0; + stt->lastError = 0; + + return 0; +} + +int WebRtcAgc_Free(void *state) +{ + Agc_t *stt; + + stt = (Agc_t *)state; +#ifdef AGC_DEBUG + fclose(stt->fpt); + fclose(stt->agcLog); + fclose(stt->digitalAgc.logFile); +#endif + free(stt); + + return 0; +} + +/* minLevel - Minimum volume level + * maxLevel - Maximum volume level + */ +int WebRtcAgc_Init(void *agcInst, WebRtc_Word32 minLevel, WebRtc_Word32 maxLevel, + WebRtc_Word16 agcMode, WebRtc_UWord32 fs) +{ + WebRtc_Word32 max_add, tmp32; + WebRtc_Word16 i; + int tmpNorm; + Agc_t *stt; + + /* typecast state pointer */ + stt = (Agc_t *)agcInst; + + if (WebRtcAgc_InitDigital(&stt->digitalAgc, agcMode) != 0) + { + stt->lastError = AGC_UNINITIALIZED_ERROR; + return -1; + } + + /* Analog AGC variables */ + stt->envSum = 0; + + /* mode = 0 - Only saturation protection + * 1 - Analog Automatic Gain Control [-targetLevelDbfs (default -3 dBOv)] + * 2 - Digital Automatic Gain Control [-targetLevelDbfs (default -3 dBOv)] + * 3 - Fixed Digital Gain [compressionGaindB (default 8 dB)] + */ +#ifdef AGC_DEBUG//test log + stt->fcount = 0; + fprintf(stt->fpt, "AGC->Init\n"); +#endif + if (agcMode < kAgcModeUnchanged || agcMode > kAgcModeFixedDigital) + { +#ifdef AGC_DEBUG//test log + fprintf(stt->fpt, "AGC->Init: error, incorrect mode\n\n"); +#endif + return -1; + } + stt->agcMode = agcMode; + stt->fs = fs; + + /* initialize input VAD */ + WebRtcAgc_InitVad(&stt->vadMic); + + /* If the volume range is smaller than 0-256 then + * the levels are shifted up to Q8-domain */ + tmpNorm = WebRtcSpl_NormU32((WebRtc_UWord32)maxLevel); + stt->scale = tmpNorm - 23; + if (stt->scale < 0) + { + stt->scale = 0; + } + // TODO(bjornv): Investigate if we really need to scale up a small range now when we have + // a guard against zero-increments. For now, we do not support scale up (scale = 0). + stt->scale = 0; + maxLevel = WEBRTC_SPL_LSHIFT_W32(maxLevel, stt->scale); + minLevel = WEBRTC_SPL_LSHIFT_W32(minLevel, stt->scale); + + /* Make minLevel and maxLevel static in AdaptiveDigital */ + if (stt->agcMode == kAgcModeAdaptiveDigital) + { + minLevel = 0; + maxLevel = 255; + stt->scale = 0; + } + /* The maximum supplemental volume range is based on a vague idea + * of how much lower the gain will be than the real analog gain. */ + max_add = WEBRTC_SPL_RSHIFT_W32(maxLevel - minLevel, 2); + + /* Minimum/maximum volume level that can be set */ + stt->minLevel = minLevel; + stt->maxAnalog = maxLevel; + stt->maxLevel = maxLevel + max_add; + stt->maxInit = stt->maxLevel; + + stt->zeroCtrlMax = stt->maxAnalog; + + /* Initialize micVol parameter */ + stt->micVol = stt->maxAnalog; + if (stt->agcMode == kAgcModeAdaptiveDigital) + { + stt->micVol = 127; /* Mid-point of mic level */ + } + stt->micRef = stt->micVol; + stt->micGainIdx = 127; +#ifdef MIC_LEVEL_FEEDBACK + stt->numBlocksMicLvlSat = 0; + stt->micLvlSat = 0; +#endif +#ifdef AGC_DEBUG//test log + fprintf(stt->fpt, + "AGC->Init: minLevel = %d, maxAnalog = %d, maxLevel = %d\n", + stt->minLevel, stt->maxAnalog, stt->maxLevel); +#endif + + /* Minimum output volume is 4% higher than the available lowest volume level */ + tmp32 = WEBRTC_SPL_RSHIFT_W32((stt->maxLevel - stt->minLevel) * (WebRtc_Word32)10, 8); + stt->minOutput = (stt->minLevel + tmp32); + + stt->msTooLow = 0; + stt->msTooHigh = 0; + stt->changeToSlowMode = 0; + stt->firstCall = 0; + stt->msZero = 0; + stt->muteGuardMs = 0; + stt->gainTableIdx = 0; + + stt->msecSpeechInnerChange = kMsecSpeechInner; + stt->msecSpeechOuterChange = kMsecSpeechOuter; + + stt->activeSpeech = 0; + stt->Rxx16_LPw32Max = 0; + + stt->vadThreshold = kNormalVadThreshold; + stt->inActive = 0; + + for (i = 0; i < RXX_BUFFER_LEN; i++) + { + stt->Rxx16_vectorw32[i] = (WebRtc_Word32)1000; /* -54dBm0 */ + } + stt->Rxx160w32 = 125 * RXX_BUFFER_LEN; /* (stt->Rxx16_vectorw32[0]>>3) = 125 */ + + stt->Rxx16pos = 0; + stt->Rxx16_LPw32 = (WebRtc_Word32)16284; /* Q(-4) */ + + for (i = 0; i < 5; i++) + { + stt->Rxx16w32_array[0][i] = 0; + } + for (i = 0; i < 20; i++) + { + stt->env[0][i] = 0; + } + stt->inQueue = 0; + +#ifdef MIC_LEVEL_FEEDBACK + stt->targetIdxOffset = 0; +#endif + + WebRtcSpl_MemSetW32(stt->filterState, 0, 8); + + stt->initFlag = kInitCheck; + // Default config settings. + stt->defaultConfig.limiterEnable = kAgcTrue; + stt->defaultConfig.targetLevelDbfs = AGC_DEFAULT_TARGET_LEVEL; + stt->defaultConfig.compressionGaindB = AGC_DEFAULT_COMP_GAIN; + + if (WebRtcAgc_set_config(stt, stt->defaultConfig) == -1) + { + stt->lastError = AGC_UNSPECIFIED_ERROR; + return -1; + } + stt->Rxx160_LPw32 = stt->analogTargetLevel; // Initialize rms value + + stt->lowLevelSignal = 0; + + /* Only positive values are allowed that are not too large */ + if ((minLevel >= maxLevel) || (maxLevel & 0xFC000000)) + { +#ifdef AGC_DEBUG//test log + fprintf(stt->fpt, "minLevel, maxLevel value(s) are invalid\n\n"); +#endif + return -1; + } else + { +#ifdef AGC_DEBUG//test log + fprintf(stt->fpt, "\n"); +#endif + return 0; + } +} + +int WebRtcAgc_Version(WebRtc_Word8 *versionStr, WebRtc_Word16 length) +{ + const WebRtc_Word8 version[] = "AGC 1.7.0"; + const WebRtc_Word16 versionLen = (WebRtc_Word16)strlen(version) + 1; + + if (versionStr == NULL) + { + return -1; + } + + if (versionLen > length) + { + return -1; + } + + strncpy(versionStr, version, versionLen); + return 0; +} diff --git a/src/modules/audio_processing/agc/main/source/analog_agc.h b/src/modules/audio_processing/agc/main/source/analog_agc.h new file mode 100644 index 0000000..b32ac65 --- /dev/null +++ b/src/modules/audio_processing/agc/main/source/analog_agc.h @@ -0,0 +1,133 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +#ifndef WEBRTC_MODULES_AUDIO_PROCESSING_AGC_MAIN_SOURCE_ANALOG_AGC_H_ +#define WEBRTC_MODULES_AUDIO_PROCESSING_AGC_MAIN_SOURCE_ANALOG_AGC_H_ + +#include "typedefs.h" +#include "gain_control.h" +#include "digital_agc.h" + +//#define AGC_DEBUG +//#define MIC_LEVEL_FEEDBACK +#ifdef AGC_DEBUG +#include +#endif + +/* Analog Automatic Gain Control variables: + * Constant declarations (inner limits inside which no changes are done) + * In the beginning the range is narrower to widen as soon as the measure + * 'Rxx160_LP' is inside it. Currently the starting limits are -22.2+/-1dBm0 + * and the final limits -22.2+/-2.5dBm0. These levels makes the speech signal + * go towards -25.4dBm0 (-31.4dBov). Tuned with wbfile-31.4dBov.pcm + * The limits are created by running the AGC with a file having the desired + * signal level and thereafter plotting Rxx160_LP in the dBm0-domain defined + * by out=10*log10(in/260537279.7); Set the target level to the average level + * of our measure Rxx160_LP. Remember that the levels are in blocks of 16 in + * Q(-7). (Example matlab code: round(db2pow(-21.2)*16/2^7) ) + */ +#define RXX_BUFFER_LEN 10 + +static const WebRtc_Word16 kMsecSpeechInner = 520; +static const WebRtc_Word16 kMsecSpeechOuter = 340; + +static const WebRtc_Word16 kNormalVadThreshold = 400; + +static const WebRtc_Word16 kAlphaShortTerm = 6; // 1 >> 6 = 0.0156 +static const WebRtc_Word16 kAlphaLongTerm = 10; // 1 >> 10 = 0.000977 + +typedef struct +{ + // Configurable parameters/variables + WebRtc_UWord32 fs; // Sampling frequency + WebRtc_Word16 compressionGaindB; // Fixed gain level in dB + WebRtc_Word16 targetLevelDbfs; // Target level in -dBfs of envelope (default -3) + WebRtc_Word16 agcMode; // Hard coded mode (adaptAna/adaptDig/fixedDig) + WebRtc_UWord8 limiterEnable; // Enabling limiter (on/off (default off)) + WebRtcAgc_config_t defaultConfig; + WebRtcAgc_config_t usedConfig; + + // General variables + WebRtc_Word16 initFlag; + WebRtc_Word16 lastError; + + // Target level parameters + // Based on the above: analogTargetLevel = round((32767*10^(-22/20))^2*16/2^7) + WebRtc_Word32 analogTargetLevel; // = RXX_BUFFER_LEN * 846805; -22 dBfs + WebRtc_Word32 startUpperLimit; // = RXX_BUFFER_LEN * 1066064; -21 dBfs + WebRtc_Word32 startLowerLimit; // = RXX_BUFFER_LEN * 672641; -23 dBfs + WebRtc_Word32 upperPrimaryLimit; // = RXX_BUFFER_LEN * 1342095; -20 dBfs + WebRtc_Word32 lowerPrimaryLimit; // = RXX_BUFFER_LEN * 534298; -24 dBfs + WebRtc_Word32 upperSecondaryLimit;// = RXX_BUFFER_LEN * 2677832; -17 dBfs + WebRtc_Word32 lowerSecondaryLimit;// = RXX_BUFFER_LEN * 267783; -27 dBfs + WebRtc_UWord16 targetIdx; // Table index for corresponding target level +#ifdef MIC_LEVEL_FEEDBACK + WebRtc_UWord16 targetIdxOffset; // Table index offset for level compensation +#endif + WebRtc_Word16 analogTarget; // Digital reference level in ENV scale + + // Analog AGC specific variables + WebRtc_Word32 filterState[8]; // For downsampling wb to nb + WebRtc_Word32 upperLimit; // Upper limit for mic energy + WebRtc_Word32 lowerLimit; // Lower limit for mic energy + WebRtc_Word32 Rxx160w32; // Average energy for one frame + WebRtc_Word32 Rxx16_LPw32; // Low pass filtered subframe energies + WebRtc_Word32 Rxx160_LPw32; // Low pass filtered frame energies + WebRtc_Word32 Rxx16_LPw32Max; // Keeps track of largest energy subframe + WebRtc_Word32 Rxx16_vectorw32[RXX_BUFFER_LEN];// Array with subframe energies + WebRtc_Word32 Rxx16w32_array[2][5];// Energy values of microphone signal + WebRtc_Word32 env[2][10]; // Envelope values of subframes + + WebRtc_Word16 Rxx16pos; // Current position in the Rxx16_vectorw32 + WebRtc_Word16 envSum; // Filtered scaled envelope in subframes + WebRtc_Word16 vadThreshold; // Threshold for VAD decision + WebRtc_Word16 inActive; // Inactive time in milliseconds + WebRtc_Word16 msTooLow; // Milliseconds of speech at a too low level + WebRtc_Word16 msTooHigh; // Milliseconds of speech at a too high level + WebRtc_Word16 changeToSlowMode; // Change to slow mode after some time at target + WebRtc_Word16 firstCall; // First call to the process-function + WebRtc_Word16 msZero; // Milliseconds of zero input + WebRtc_Word16 msecSpeechOuterChange;// Min ms of speech between volume changes + WebRtc_Word16 msecSpeechInnerChange;// Min ms of speech between volume changes + WebRtc_Word16 activeSpeech; // Milliseconds of active speech + WebRtc_Word16 muteGuardMs; // Counter to prevent mute action + WebRtc_Word16 inQueue; // 10 ms batch indicator + + // Microphone level variables + WebRtc_Word32 micRef; // Remember ref. mic level for virtual mic + WebRtc_UWord16 gainTableIdx; // Current position in virtual gain table + WebRtc_Word32 micGainIdx; // Gain index of mic level to increase slowly + WebRtc_Word32 micVol; // Remember volume between frames + WebRtc_Word32 maxLevel; // Max possible vol level, incl dig gain + WebRtc_Word32 maxAnalog; // Maximum possible analog volume level + WebRtc_Word32 maxInit; // Initial value of "max" + WebRtc_Word32 minLevel; // Minimum possible volume level + WebRtc_Word32 minOutput; // Minimum output volume level + WebRtc_Word32 zeroCtrlMax; // Remember max gain => don't amp low input + + WebRtc_Word16 scale; // Scale factor for internal volume levels +#ifdef MIC_LEVEL_FEEDBACK + WebRtc_Word16 numBlocksMicLvlSat; + WebRtc_UWord8 micLvlSat; +#endif + // Structs for VAD and digital_agc + AgcVad_t vadMic; + DigitalAgc_t digitalAgc; + +#ifdef AGC_DEBUG + FILE* fpt; + FILE* agcLog; + WebRtc_Word32 fcount; +#endif + + WebRtc_Word16 lowLevelSignal; +} Agc_t; + +#endif // WEBRTC_MODULES_AUDIO_PROCESSING_AGC_MAIN_SOURCE_ANALOG_AGC_H_ diff --git a/src/modules/audio_processing/agc/main/source/digital_agc.c b/src/modules/audio_processing/agc/main/source/digital_agc.c new file mode 100644 index 0000000..e303a92 --- /dev/null +++ b/src/modules/audio_processing/agc/main/source/digital_agc.c @@ -0,0 +1,786 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +/* digital_agc.c + * + */ + +#include +#ifdef AGC_DEBUG +#include +#endif +#include "digital_agc.h" +#include "gain_control.h" + +// To generate the gaintable, copy&paste the following lines to a Matlab window: +// MaxGain = 6; MinGain = 0; CompRatio = 3; Knee = 1; +// zeros = 0:31; lvl = 2.^(1-zeros); +// A = -10*log10(lvl) * (CompRatio - 1) / CompRatio; +// B = MaxGain - MinGain; +// gains = round(2^16*10.^(0.05 * (MinGain + B * ( log(exp(-Knee*A)+exp(-Knee*B)) - log(1+exp(-Knee*B)) ) / log(1/(1+exp(Knee*B)))))); +// fprintf(1, '\t%i, %i, %i, %i,\n', gains); +// % Matlab code for plotting the gain and input/output level characteristic (copy/paste the following 3 lines): +// in = 10*log10(lvl); out = 20*log10(gains/65536); +// subplot(121); plot(in, out); axis([-30, 0, -5, 20]); grid on; xlabel('Input (dB)'); ylabel('Gain (dB)'); +// subplot(122); plot(in, in+out); axis([-30, 0, -30, 5]); grid on; xlabel('Input (dB)'); ylabel('Output (dB)'); +// zoom on; + +// Generator table for y=log2(1+e^x) in Q8. +static const WebRtc_UWord16 kGenFuncTable[128] = { + 256, 485, 786, 1126, 1484, 1849, 2217, 2586, + 2955, 3324, 3693, 4063, 4432, 4801, 5171, 5540, + 5909, 6279, 6648, 7017, 7387, 7756, 8125, 8495, + 8864, 9233, 9603, 9972, 10341, 10711, 11080, 11449, + 11819, 12188, 12557, 12927, 13296, 13665, 14035, 14404, + 14773, 15143, 15512, 15881, 16251, 16620, 16989, 17359, + 17728, 18097, 18466, 18836, 19205, 19574, 19944, 20313, + 20682, 21052, 21421, 21790, 22160, 22529, 22898, 23268, + 23637, 24006, 24376, 24745, 25114, 25484, 25853, 26222, + 26592, 26961, 27330, 27700, 28069, 28438, 28808, 29177, + 29546, 29916, 30285, 30654, 31024, 31393, 31762, 32132, + 32501, 32870, 33240, 33609, 33978, 34348, 34717, 35086, + 35456, 35825, 36194, 36564, 36933, 37302, 37672, 38041, + 38410, 38780, 39149, 39518, 39888, 40257, 40626, 40996, + 41365, 41734, 42104, 42473, 42842, 43212, 43581, 43950, + 44320, 44689, 45058, 45428, 45797, 46166, 46536, 46905 +}; + +static const WebRtc_Word16 kAvgDecayTime = 250; // frames; < 3000 + +WebRtc_Word32 WebRtcAgc_CalculateGainTable(WebRtc_Word32 *gainTable, // Q16 + WebRtc_Word16 digCompGaindB, // Q0 + WebRtc_Word16 targetLevelDbfs,// Q0 + WebRtc_UWord8 limiterEnable, + WebRtc_Word16 analogTarget) // Q0 +{ + // This function generates the compressor gain table used in the fixed digital part. + WebRtc_UWord32 tmpU32no1, tmpU32no2, absInLevel, logApprox; + WebRtc_Word32 inLevel, limiterLvl; + WebRtc_Word32 tmp32, tmp32no1, tmp32no2, numFIX, den, y32; + const WebRtc_UWord16 kLog10 = 54426; // log2(10) in Q14 + const WebRtc_UWord16 kLog10_2 = 49321; // 10*log10(2) in Q14 + const WebRtc_UWord16 kLogE_1 = 23637; // log2(e) in Q14 + WebRtc_UWord16 constMaxGain; + WebRtc_UWord16 tmpU16, intPart, fracPart; + const WebRtc_Word16 kCompRatio = 3; + const WebRtc_Word16 kSoftLimiterLeft = 1; + WebRtc_Word16 limiterOffset = 0; // Limiter offset + WebRtc_Word16 limiterIdx, limiterLvlX; + WebRtc_Word16 constLinApprox, zeroGainLvl, maxGain, diffGain; + WebRtc_Word16 i, tmp16, tmp16no1; + int zeros, zerosScale; + + // Constants +// kLogE_1 = 23637; // log2(e) in Q14 +// kLog10 = 54426; // log2(10) in Q14 +// kLog10_2 = 49321; // 10*log10(2) in Q14 + + // Calculate maximum digital gain and zero gain level + tmp32no1 = WEBRTC_SPL_MUL_16_16(digCompGaindB - analogTarget, kCompRatio - 1); + tmp16no1 = analogTarget - targetLevelDbfs; + tmp16no1 += WebRtcSpl_DivW32W16ResW16(tmp32no1 + (kCompRatio >> 1), kCompRatio); + maxGain = WEBRTC_SPL_MAX(tmp16no1, (analogTarget - targetLevelDbfs)); + tmp32no1 = WEBRTC_SPL_MUL_16_16(maxGain, kCompRatio); + zeroGainLvl = digCompGaindB; + zeroGainLvl -= WebRtcSpl_DivW32W16ResW16(tmp32no1 + ((kCompRatio - 1) >> 1), + kCompRatio - 1); + if ((digCompGaindB <= analogTarget) && (limiterEnable)) + { + zeroGainLvl += (analogTarget - digCompGaindB + kSoftLimiterLeft); + limiterOffset = 0; + } + + // Calculate the difference between maximum gain and gain at 0dB0v: + // diffGain = maxGain + (compRatio-1)*zeroGainLvl/compRatio + // = (compRatio-1)*digCompGaindB/compRatio + tmp32no1 = WEBRTC_SPL_MUL_16_16(digCompGaindB, kCompRatio - 1); + diffGain = WebRtcSpl_DivW32W16ResW16(tmp32no1 + (kCompRatio >> 1), kCompRatio); + if (diffGain < 0) + { + return -1; + } + + // Calculate the limiter level and index: + // limiterLvlX = analogTarget - limiterOffset + // limiterLvl = targetLevelDbfs + limiterOffset/compRatio + limiterLvlX = analogTarget - limiterOffset; + limiterIdx = 2 + + WebRtcSpl_DivW32W16ResW16(WEBRTC_SPL_LSHIFT_W32((WebRtc_Word32)limiterLvlX, 13), + WEBRTC_SPL_RSHIFT_U16(kLog10_2, 1)); + tmp16no1 = WebRtcSpl_DivW32W16ResW16(limiterOffset + (kCompRatio >> 1), kCompRatio); + limiterLvl = targetLevelDbfs + tmp16no1; + + // Calculate (through table lookup): + // constMaxGain = log2(1+2^(log2(e)*diffGain)); (in Q8) + constMaxGain = kGenFuncTable[diffGain]; // in Q8 + + // Calculate a parameter used to approximate the fractional part of 2^x with a + // piecewise linear function in Q14: + // constLinApprox = round(3/2*(4*(3-2*sqrt(2))/(log(2)^2)-0.5)*2^14); + constLinApprox = 22817; // in Q14 + + // Calculate a denominator used in the exponential part to convert from dB to linear scale: + // den = 20*constMaxGain (in Q8) + den = WEBRTC_SPL_MUL_16_U16(20, constMaxGain); // in Q8 + + for (i = 0; i < 32; i++) + { + // Calculate scaled input level (compressor): + // inLevel = fix((-constLog10_2*(compRatio-1)*(1-i)+fix(compRatio/2))/compRatio) + tmp16 = (WebRtc_Word16)WEBRTC_SPL_MUL_16_16(kCompRatio - 1, i - 1); // Q0 + tmp32 = WEBRTC_SPL_MUL_16_U16(tmp16, kLog10_2) + 1; // Q14 + inLevel = WebRtcSpl_DivW32W16(tmp32, kCompRatio); // Q14 + + // Calculate diffGain-inLevel, to map using the genFuncTable + inLevel = WEBRTC_SPL_LSHIFT_W32((WebRtc_Word32)diffGain, 14) - inLevel; // Q14 + + // Make calculations on abs(inLevel) and compensate for the sign afterwards. + absInLevel = (WebRtc_UWord32)WEBRTC_SPL_ABS_W32(inLevel); // Q14 + + // LUT with interpolation + intPart = (WebRtc_UWord16)WEBRTC_SPL_RSHIFT_U32(absInLevel, 14); + fracPart = (WebRtc_UWord16)(absInLevel & 0x00003FFF); // extract the fractional part + tmpU16 = kGenFuncTable[intPart + 1] - kGenFuncTable[intPart]; // Q8 + tmpU32no1 = WEBRTC_SPL_UMUL_16_16(tmpU16, fracPart); // Q22 + tmpU32no1 += WEBRTC_SPL_LSHIFT_U32((WebRtc_UWord32)kGenFuncTable[intPart], 14); // Q22 + logApprox = WEBRTC_SPL_RSHIFT_U32(tmpU32no1, 8); // Q14 + // Compensate for negative exponent using the relation: + // log2(1 + 2^-x) = log2(1 + 2^x) - x + if (inLevel < 0) + { + zeros = WebRtcSpl_NormU32(absInLevel); + zerosScale = 0; + if (zeros < 15) + { + // Not enough space for multiplication + tmpU32no2 = WEBRTC_SPL_RSHIFT_U32(absInLevel, 15 - zeros); // Q(zeros-1) + tmpU32no2 = WEBRTC_SPL_UMUL_32_16(tmpU32no2, kLogE_1); // Q(zeros+13) + if (zeros < 9) + { + tmpU32no1 = WEBRTC_SPL_RSHIFT_U32(tmpU32no1, 9 - zeros); // Q(zeros+13) + zerosScale = 9 - zeros; + } else + { + tmpU32no2 = WEBRTC_SPL_RSHIFT_U32(tmpU32no2, zeros - 9); // Q22 + } + } else + { + tmpU32no2 = WEBRTC_SPL_UMUL_32_16(absInLevel, kLogE_1); // Q28 + tmpU32no2 = WEBRTC_SPL_RSHIFT_U32(tmpU32no2, 6); // Q22 + } + logApprox = 0; + if (tmpU32no2 < tmpU32no1) + { + logApprox = WEBRTC_SPL_RSHIFT_U32(tmpU32no1 - tmpU32no2, 8 - zerosScale); //Q14 + } + } + numFIX = WEBRTC_SPL_LSHIFT_W32(WEBRTC_SPL_MUL_16_U16(maxGain, constMaxGain), 6); // Q14 + numFIX -= WEBRTC_SPL_MUL_32_16((WebRtc_Word32)logApprox, diffGain); // Q14 + + // Calculate ratio + // Shift numFIX as much as possible + zeros = WebRtcSpl_NormW32(numFIX); + numFIX = WEBRTC_SPL_LSHIFT_W32(numFIX, zeros); // Q(14+zeros) + + // Shift den so we end up in Qy1 + tmp32no1 = WEBRTC_SPL_SHIFT_W32(den, zeros - 8); // Q(zeros) + if (numFIX < 0) + { + numFIX -= WEBRTC_SPL_RSHIFT_W32(tmp32no1, 1); + } else + { + numFIX += WEBRTC_SPL_RSHIFT_W32(tmp32no1, 1); + } + y32 = WEBRTC_SPL_DIV(numFIX, tmp32no1); // in Q14 + if (limiterEnable && (i < limiterIdx)) + { + tmp32 = WEBRTC_SPL_MUL_16_U16(i - 1, kLog10_2); // Q14 + tmp32 -= WEBRTC_SPL_LSHIFT_W32(limiterLvl, 14); // Q14 + y32 = WebRtcSpl_DivW32W16(tmp32 + 10, 20); + } + if (y32 > 39000) + { + tmp32 = WEBRTC_SPL_MUL(y32 >> 1, kLog10) + 4096; // in Q27 + tmp32 = WEBRTC_SPL_RSHIFT_W32(tmp32, 13); // in Q14 + } else + { + tmp32 = WEBRTC_SPL_MUL(y32, kLog10) + 8192; // in Q28 + tmp32 = WEBRTC_SPL_RSHIFT_W32(tmp32, 14); // in Q14 + } + tmp32 += WEBRTC_SPL_LSHIFT_W32(16, 14); // in Q14 (Make sure final output is in Q16) + + // Calculate power + if (tmp32 > 0) + { + intPart = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32(tmp32, 14); + fracPart = (WebRtc_UWord16)(tmp32 & 0x00003FFF); // in Q14 + if (WEBRTC_SPL_RSHIFT_W32(fracPart, 13)) + { + tmp16 = WEBRTC_SPL_LSHIFT_W16(2, 14) - constLinApprox; + tmp32no2 = WEBRTC_SPL_LSHIFT_W32(1, 14) - fracPart; + tmp32no2 = WEBRTC_SPL_MUL_32_16(tmp32no2, tmp16); + tmp32no2 = WEBRTC_SPL_RSHIFT_W32(tmp32no2, 13); + tmp32no2 = WEBRTC_SPL_LSHIFT_W32(1, 14) - tmp32no2; + } else + { + tmp16 = constLinApprox - WEBRTC_SPL_LSHIFT_W16(1, 14); + tmp32no2 = WEBRTC_SPL_MUL_32_16(fracPart, tmp16); + tmp32no2 = WEBRTC_SPL_RSHIFT_W32(tmp32no2, 13); + } + fracPart = (WebRtc_UWord16)tmp32no2; + gainTable[i] = WEBRTC_SPL_LSHIFT_W32(1, intPart) + + WEBRTC_SPL_SHIFT_W32(fracPart, intPart - 14); + } else + { + gainTable[i] = 0; + } + } + + return 0; +} + +WebRtc_Word32 WebRtcAgc_InitDigital(DigitalAgc_t *stt, WebRtc_Word16 agcMode) +{ + + if (agcMode == kAgcModeFixedDigital) + { + // start at minimum to find correct gain faster + stt->capacitorSlow = 0; + } else + { + // start out with 0 dB gain + stt->capacitorSlow = 134217728; // (WebRtc_Word32)(0.125f * 32768.0f * 32768.0f); + } + stt->capacitorFast = 0; + stt->gain = 65536; + stt->gatePrevious = 0; + stt->agcMode = agcMode; +#ifdef AGC_DEBUG + stt->frameCounter = 0; +#endif + + // initialize VADs + WebRtcAgc_InitVad(&stt->vadNearend); + WebRtcAgc_InitVad(&stt->vadFarend); + + return 0; +} + +WebRtc_Word32 WebRtcAgc_AddFarendToDigital(DigitalAgc_t *stt, const WebRtc_Word16 *in_far, + WebRtc_Word16 nrSamples) +{ + // Check for valid pointer + if (&stt->vadFarend == NULL) + { + return -1; + } + + // VAD for far end + WebRtcAgc_ProcessVad(&stt->vadFarend, in_far, nrSamples); + + return 0; +} + +WebRtc_Word32 WebRtcAgc_ProcessDigital(DigitalAgc_t *stt, const WebRtc_Word16 *in_near, + const WebRtc_Word16 *in_near_H, WebRtc_Word16 *out, + WebRtc_Word16 *out_H, WebRtc_UWord32 FS, + WebRtc_Word16 lowlevelSignal) +{ + // array for gains (one value per ms, incl start & end) + WebRtc_Word32 gains[11]; + + WebRtc_Word32 out_tmp, tmp32; + WebRtc_Word32 env[10]; + WebRtc_Word32 nrg, max_nrg; + WebRtc_Word32 cur_level; + WebRtc_Word32 gain32, delta; + WebRtc_Word16 logratio; + WebRtc_Word16 lower_thr, upper_thr; + WebRtc_Word16 zeros, zeros_fast, frac; + WebRtc_Word16 decay; + WebRtc_Word16 gate, gain_adj; + WebRtc_Word16 k, n; + WebRtc_Word16 L, L2; // samples/subframe + + // determine number of samples per ms + if (FS == 8000) + { + L = 8; + L2 = 3; + } else if (FS == 16000) + { + L = 16; + L2 = 4; + } else if (FS == 32000) + { + L = 16; + L2 = 4; + } else + { + return -1; + } + + // TODO(andrew): again, we don't need input and output pointers... + if (in_near != out) + { + // Only needed if they don't already point to the same place. + memcpy(out, in_near, 10 * L * sizeof(WebRtc_Word16)); + } + if (FS == 32000) + { + if (in_near_H != out_H) + { + memcpy(out_H, in_near_H, 10 * L * sizeof(WebRtc_Word16)); + } + } + // VAD for near end + logratio = WebRtcAgc_ProcessVad(&stt->vadNearend, out, L * 10); + + // Account for far end VAD + if (stt->vadFarend.counter > 10) + { + tmp32 = WEBRTC_SPL_MUL_16_16(3, logratio); + logratio = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32(tmp32 - stt->vadFarend.logRatio, 2); + } + + // Determine decay factor depending on VAD + // upper_thr = 1.0f; + // lower_thr = 0.25f; + upper_thr = 1024; // Q10 + lower_thr = 0; // Q10 + if (logratio > upper_thr) + { + // decay = -2^17 / DecayTime; -> -65 + decay = -65; + } else if (logratio < lower_thr) + { + decay = 0; + } else + { + // decay = (WebRtc_Word16)(((lower_thr - logratio) + // * (2^27/(DecayTime*(upper_thr-lower_thr)))) >> 10); + // SUBSTITUTED: 2^27/(DecayTime*(upper_thr-lower_thr)) -> 65 + tmp32 = WEBRTC_SPL_MUL_16_16((lower_thr - logratio), 65); + decay = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32(tmp32, 10); + } + + // adjust decay factor for long silence (detected as low standard deviation) + // This is only done in the adaptive modes + if (stt->agcMode != kAgcModeFixedDigital) + { + if (stt->vadNearend.stdLongTerm < 4000) + { + decay = 0; + } else if (stt->vadNearend.stdLongTerm < 8096) + { + // decay = (WebRtc_Word16)(((stt->vadNearend.stdLongTerm - 4000) * decay) >> 12); + tmp32 = WEBRTC_SPL_MUL_16_16((stt->vadNearend.stdLongTerm - 4000), decay); + decay = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32(tmp32, 12); + } + + if (lowlevelSignal != 0) + { + decay = 0; + } + } +#ifdef AGC_DEBUG + stt->frameCounter++; + fprintf(stt->logFile, "%5.2f\t%d\t%d\t%d\t", (float)(stt->frameCounter) / 100, logratio, decay, stt->vadNearend.stdLongTerm); +#endif + // Find max amplitude per sub frame + // iterate over sub frames + for (k = 0; k < 10; k++) + { + // iterate over samples + max_nrg = 0; + for (n = 0; n < L; n++) + { + nrg = WEBRTC_SPL_MUL_16_16(out[k * L + n], out[k * L + n]); + if (nrg > max_nrg) + { + max_nrg = nrg; + } + } + env[k] = max_nrg; + } + + // Calculate gain per sub frame + gains[0] = stt->gain; + for (k = 0; k < 10; k++) + { + // Fast envelope follower + // decay time = -131000 / -1000 = 131 (ms) + stt->capacitorFast = AGC_SCALEDIFF32(-1000, stt->capacitorFast, stt->capacitorFast); + if (env[k] > stt->capacitorFast) + { + stt->capacitorFast = env[k]; + } + // Slow envelope follower + if (env[k] > stt->capacitorSlow) + { + // increase capacitorSlow + stt->capacitorSlow + = AGC_SCALEDIFF32(500, (env[k] - stt->capacitorSlow), stt->capacitorSlow); + } else + { + // decrease capacitorSlow + stt->capacitorSlow + = AGC_SCALEDIFF32(decay, stt->capacitorSlow, stt->capacitorSlow); + } + + // use maximum of both capacitors as current level + if (stt->capacitorFast > stt->capacitorSlow) + { + cur_level = stt->capacitorFast; + } else + { + cur_level = stt->capacitorSlow; + } + // Translate signal level into gain, using a piecewise linear approximation + // find number of leading zeros + zeros = WebRtcSpl_NormU32((WebRtc_UWord32)cur_level); + if (cur_level == 0) + { + zeros = 31; + } + tmp32 = (WEBRTC_SPL_LSHIFT_W32(cur_level, zeros) & 0x7FFFFFFF); + frac = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32(tmp32, 19); // Q12 + tmp32 = WEBRTC_SPL_MUL((stt->gainTable[zeros-1] - stt->gainTable[zeros]), frac); + gains[k + 1] = stt->gainTable[zeros] + WEBRTC_SPL_RSHIFT_W32(tmp32, 12); +#ifdef AGC_DEBUG + if (k == 0) + { + fprintf(stt->logFile, "%d\t%d\t%d\t%d\t%d\n", env[0], cur_level, stt->capacitorFast, stt->capacitorSlow, zeros); + } +#endif + } + + // Gate processing (lower gain during absence of speech) + zeros = WEBRTC_SPL_LSHIFT_W16(zeros, 9) - WEBRTC_SPL_RSHIFT_W16(frac, 3); + // find number of leading zeros + zeros_fast = WebRtcSpl_NormU32((WebRtc_UWord32)stt->capacitorFast); + if (stt->capacitorFast == 0) + { + zeros_fast = 31; + } + tmp32 = (WEBRTC_SPL_LSHIFT_W32(stt->capacitorFast, zeros_fast) & 0x7FFFFFFF); + zeros_fast = WEBRTC_SPL_LSHIFT_W16(zeros_fast, 9); + zeros_fast -= (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32(tmp32, 22); + + gate = 1000 + zeros_fast - zeros - stt->vadNearend.stdShortTerm; + + if (gate < 0) + { + stt->gatePrevious = 0; + } else + { + tmp32 = WEBRTC_SPL_MUL_16_16(stt->gatePrevious, 7); + gate = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32((WebRtc_Word32)gate + tmp32, 3); + stt->gatePrevious = gate; + } + // gate < 0 -> no gate + // gate > 2500 -> max gate + if (gate > 0) + { + if (gate < 2500) + { + gain_adj = WEBRTC_SPL_RSHIFT_W16(2500 - gate, 5); + } else + { + gain_adj = 0; + } + for (k = 0; k < 10; k++) + { + if ((gains[k + 1] - stt->gainTable[0]) > 8388608) + { + // To prevent wraparound + tmp32 = WEBRTC_SPL_RSHIFT_W32((gains[k+1] - stt->gainTable[0]), 8); + tmp32 = WEBRTC_SPL_MUL(tmp32, (178 + gain_adj)); + } else + { + tmp32 = WEBRTC_SPL_MUL((gains[k+1] - stt->gainTable[0]), (178 + gain_adj)); + tmp32 = WEBRTC_SPL_RSHIFT_W32(tmp32, 8); + } + gains[k + 1] = stt->gainTable[0] + tmp32; + } + } + + // Limit gain to avoid overload distortion + for (k = 0; k < 10; k++) + { + // To prevent wrap around + zeros = 10; + if (gains[k + 1] > 47453132) + { + zeros = 16 - WebRtcSpl_NormW32(gains[k + 1]); + } + gain32 = WEBRTC_SPL_RSHIFT_W32(gains[k+1], zeros) + 1; + gain32 = WEBRTC_SPL_MUL(gain32, gain32); + // check for overflow + while (AGC_MUL32(WEBRTC_SPL_RSHIFT_W32(env[k], 12) + 1, gain32) + > WEBRTC_SPL_SHIFT_W32((WebRtc_Word32)32767, 2 * (1 - zeros + 10))) + { + // multiply by 253/256 ==> -0.1 dB + if (gains[k + 1] > 8388607) + { + // Prevent wrap around + gains[k + 1] = WEBRTC_SPL_MUL(WEBRTC_SPL_RSHIFT_W32(gains[k+1], 8), 253); + } else + { + gains[k + 1] = WEBRTC_SPL_RSHIFT_W32(WEBRTC_SPL_MUL(gains[k+1], 253), 8); + } + gain32 = WEBRTC_SPL_RSHIFT_W32(gains[k+1], zeros) + 1; + gain32 = WEBRTC_SPL_MUL(gain32, gain32); + } + } + // gain reductions should be done 1 ms earlier than gain increases + for (k = 1; k < 10; k++) + { + if (gains[k] > gains[k + 1]) + { + gains[k] = gains[k + 1]; + } + } + // save start gain for next frame + stt->gain = gains[10]; + + // Apply gain + // handle first sub frame separately + delta = WEBRTC_SPL_LSHIFT_W32(gains[1] - gains[0], (4 - L2)); + gain32 = WEBRTC_SPL_LSHIFT_W32(gains[0], 4); + // iterate over samples + for (n = 0; n < L; n++) + { + // For lower band + tmp32 = WEBRTC_SPL_MUL((WebRtc_Word32)out[n], WEBRTC_SPL_RSHIFT_W32(gain32 + 127, 7)); + out_tmp = WEBRTC_SPL_RSHIFT_W32(tmp32 , 16); + if (out_tmp > 4095) + { + out[n] = (WebRtc_Word16)32767; + } else if (out_tmp < -4096) + { + out[n] = (WebRtc_Word16)-32768; + } else + { + tmp32 = WEBRTC_SPL_MUL((WebRtc_Word32)out[n], WEBRTC_SPL_RSHIFT_W32(gain32, 4)); + out[n] = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32(tmp32 , 16); + } + // For higher band + if (FS == 32000) + { + tmp32 = WEBRTC_SPL_MUL((WebRtc_Word32)out_H[n], + WEBRTC_SPL_RSHIFT_W32(gain32 + 127, 7)); + out_tmp = WEBRTC_SPL_RSHIFT_W32(tmp32 , 16); + if (out_tmp > 4095) + { + out_H[n] = (WebRtc_Word16)32767; + } else if (out_tmp < -4096) + { + out_H[n] = (WebRtc_Word16)-32768; + } else + { + tmp32 = WEBRTC_SPL_MUL((WebRtc_Word32)out_H[n], + WEBRTC_SPL_RSHIFT_W32(gain32, 4)); + out_H[n] = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32(tmp32 , 16); + } + } + // + + gain32 += delta; + } + // iterate over subframes + for (k = 1; k < 10; k++) + { + delta = WEBRTC_SPL_LSHIFT_W32(gains[k+1] - gains[k], (4 - L2)); + gain32 = WEBRTC_SPL_LSHIFT_W32(gains[k], 4); + // iterate over samples + for (n = 0; n < L; n++) + { + // For lower band + tmp32 = WEBRTC_SPL_MUL((WebRtc_Word32)out[k * L + n], + WEBRTC_SPL_RSHIFT_W32(gain32, 4)); + out[k * L + n] = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32(tmp32 , 16); + // For higher band + if (FS == 32000) + { + tmp32 = WEBRTC_SPL_MUL((WebRtc_Word32)out_H[k * L + n], + WEBRTC_SPL_RSHIFT_W32(gain32, 4)); + out_H[k * L + n] = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32(tmp32 , 16); + } + gain32 += delta; + } + } + + return 0; +} + +void WebRtcAgc_InitVad(AgcVad_t *state) +{ + WebRtc_Word16 k; + + state->HPstate = 0; // state of high pass filter + state->logRatio = 0; // log( P(active) / P(inactive) ) + // average input level (Q10) + state->meanLongTerm = WEBRTC_SPL_LSHIFT_W16(15, 10); + + // variance of input level (Q8) + state->varianceLongTerm = WEBRTC_SPL_LSHIFT_W32(500, 8); + + state->stdLongTerm = 0; // standard deviation of input level in dB + // short-term average input level (Q10) + state->meanShortTerm = WEBRTC_SPL_LSHIFT_W16(15, 10); + + // short-term variance of input level (Q8) + state->varianceShortTerm = WEBRTC_SPL_LSHIFT_W32(500, 8); + + state->stdShortTerm = 0; // short-term standard deviation of input level in dB + state->counter = 3; // counts updates + for (k = 0; k < 8; k++) + { + // downsampling filter + state->downState[k] = 0; + } +} + +WebRtc_Word16 WebRtcAgc_ProcessVad(AgcVad_t *state, // (i) VAD state + const WebRtc_Word16 *in, // (i) Speech signal + WebRtc_Word16 nrSamples) // (i) number of samples +{ + WebRtc_Word32 out, nrg, tmp32, tmp32b; + WebRtc_UWord16 tmpU16; + WebRtc_Word16 k, subfr, tmp16; + WebRtc_Word16 buf1[8]; + WebRtc_Word16 buf2[4]; + WebRtc_Word16 HPstate; + WebRtc_Word16 zeros, dB; + + // process in 10 sub frames of 1 ms (to save on memory) + nrg = 0; + HPstate = state->HPstate; + for (subfr = 0; subfr < 10; subfr++) + { + // downsample to 4 kHz + if (nrSamples == 160) + { + for (k = 0; k < 8; k++) + { + tmp32 = (WebRtc_Word32)in[2 * k] + (WebRtc_Word32)in[2 * k + 1]; + tmp32 = WEBRTC_SPL_RSHIFT_W32(tmp32, 1); + buf1[k] = (WebRtc_Word16)tmp32; + } + in += 16; + + WebRtcSpl_DownsampleBy2(buf1, 8, buf2, state->downState); + } else + { + WebRtcSpl_DownsampleBy2(in, 8, buf2, state->downState); + in += 8; + } + + // high pass filter and compute energy + for (k = 0; k < 4; k++) + { + out = buf2[k] + HPstate; + tmp32 = WEBRTC_SPL_MUL(600, out); + HPstate = (WebRtc_Word16)(WEBRTC_SPL_RSHIFT_W32(tmp32, 10) - buf2[k]); + tmp32 = WEBRTC_SPL_MUL(out, out); + nrg += WEBRTC_SPL_RSHIFT_W32(tmp32, 6); + } + } + state->HPstate = HPstate; + + // find number of leading zeros + if (!(0xFFFF0000 & nrg)) + { + zeros = 16; + } else + { + zeros = 0; + } + if (!(0xFF000000 & (nrg << zeros))) + { + zeros += 8; + } + if (!(0xF0000000 & (nrg << zeros))) + { + zeros += 4; + } + if (!(0xC0000000 & (nrg << zeros))) + { + zeros += 2; + } + if (!(0x80000000 & (nrg << zeros))) + { + zeros += 1; + } + + // energy level (range {-32..30}) (Q10) + dB = WEBRTC_SPL_LSHIFT_W16(15 - zeros, 11); + + // Update statistics + + if (state->counter < kAvgDecayTime) + { + // decay time = AvgDecTime * 10 ms + state->counter++; + } + + // update short-term estimate of mean energy level (Q10) + tmp32 = (WEBRTC_SPL_MUL_16_16(state->meanShortTerm, 15) + (WebRtc_Word32)dB); + state->meanShortTerm = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32(tmp32, 4); + + // update short-term estimate of variance in energy level (Q8) + tmp32 = WEBRTC_SPL_RSHIFT_W32(WEBRTC_SPL_MUL_16_16(dB, dB), 12); + tmp32 += WEBRTC_SPL_MUL(state->varianceShortTerm, 15); + state->varianceShortTerm = WEBRTC_SPL_RSHIFT_W32(tmp32, 4); + + // update short-term estimate of standard deviation in energy level (Q10) + tmp32 = WEBRTC_SPL_MUL_16_16(state->meanShortTerm, state->meanShortTerm); + tmp32 = WEBRTC_SPL_LSHIFT_W32(state->varianceShortTerm, 12) - tmp32; + state->stdShortTerm = (WebRtc_Word16)WebRtcSpl_Sqrt(tmp32); + + // update long-term estimate of mean energy level (Q10) + tmp32 = WEBRTC_SPL_MUL_16_16(state->meanLongTerm, state->counter) + (WebRtc_Word32)dB; + state->meanLongTerm = WebRtcSpl_DivW32W16ResW16(tmp32, + WEBRTC_SPL_ADD_SAT_W16(state->counter, 1)); + + // update long-term estimate of variance in energy level (Q8) + tmp32 = WEBRTC_SPL_RSHIFT_W32(WEBRTC_SPL_MUL_16_16(dB, dB), 12); + tmp32 += WEBRTC_SPL_MUL(state->varianceLongTerm, state->counter); + state->varianceLongTerm = WebRtcSpl_DivW32W16(tmp32, + WEBRTC_SPL_ADD_SAT_W16(state->counter, 1)); + + // update long-term estimate of standard deviation in energy level (Q10) + tmp32 = WEBRTC_SPL_MUL_16_16(state->meanLongTerm, state->meanLongTerm); + tmp32 = WEBRTC_SPL_LSHIFT_W32(state->varianceLongTerm, 12) - tmp32; + state->stdLongTerm = (WebRtc_Word16)WebRtcSpl_Sqrt(tmp32); + + // update voice activity measure (Q10) + tmp16 = WEBRTC_SPL_LSHIFT_W16(3, 12); + tmp32 = WEBRTC_SPL_MUL_16_16(tmp16, (dB - state->meanLongTerm)); + tmp32 = WebRtcSpl_DivW32W16(tmp32, state->stdLongTerm); + tmpU16 = WEBRTC_SPL_LSHIFT_U16((WebRtc_UWord16)13, 12); + tmp32b = WEBRTC_SPL_MUL_16_U16(state->logRatio, tmpU16); + tmp32 += WEBRTC_SPL_RSHIFT_W32(tmp32b, 10); + + state->logRatio = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32(tmp32, 6); + + // limit + if (state->logRatio > 2048) + { + state->logRatio = 2048; + } + if (state->logRatio < -2048) + { + state->logRatio = -2048; + } + + return state->logRatio; // Q10 +} diff --git a/src/modules/audio_processing/agc/main/source/digital_agc.h b/src/modules/audio_processing/agc/main/source/digital_agc.h new file mode 100644 index 0000000..240b220 --- /dev/null +++ b/src/modules/audio_processing/agc/main/source/digital_agc.h @@ -0,0 +1,76 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +#ifndef WEBRTC_MODULES_AUDIO_PROCESSING_AGC_MAIN_SOURCE_DIGITAL_AGC_H_ +#define WEBRTC_MODULES_AUDIO_PROCESSING_AGC_MAIN_SOURCE_DIGITAL_AGC_H_ + +#ifdef AGC_DEBUG +#include +#endif +#include "typedefs.h" +#include "signal_processing_library.h" + +// the 32 most significant bits of A(19) * B(26) >> 13 +#define AGC_MUL32(A, B) (((B)>>13)*(A) + ( ((0x00001FFF & (B))*(A)) >> 13 )) +// C + the 32 most significant bits of A * B +#define AGC_SCALEDIFF32(A, B, C) ((C) + ((B)>>16)*(A) + ( ((0x0000FFFF & (B))*(A)) >> 16 )) + +typedef struct +{ + WebRtc_Word32 downState[8]; + WebRtc_Word16 HPstate; + WebRtc_Word16 counter; + WebRtc_Word16 logRatio; // log( P(active) / P(inactive) ) (Q10) + WebRtc_Word16 meanLongTerm; // Q10 + WebRtc_Word32 varianceLongTerm; // Q8 + WebRtc_Word16 stdLongTerm; // Q10 + WebRtc_Word16 meanShortTerm; // Q10 + WebRtc_Word32 varianceShortTerm; // Q8 + WebRtc_Word16 stdShortTerm; // Q10 +} AgcVad_t; // total = 54 bytes + +typedef struct +{ + WebRtc_Word32 capacitorSlow; + WebRtc_Word32 capacitorFast; + WebRtc_Word32 gain; + WebRtc_Word32 gainTable[32]; + WebRtc_Word16 gatePrevious; + WebRtc_Word16 agcMode; + AgcVad_t vadNearend; + AgcVad_t vadFarend; +#ifdef AGC_DEBUG + FILE* logFile; + int frameCounter; +#endif +} DigitalAgc_t; + +WebRtc_Word32 WebRtcAgc_InitDigital(DigitalAgc_t *digitalAgcInst, WebRtc_Word16 agcMode); + +WebRtc_Word32 WebRtcAgc_ProcessDigital(DigitalAgc_t *digitalAgcInst, const WebRtc_Word16 *inNear, + const WebRtc_Word16 *inNear_H, WebRtc_Word16 *out, + WebRtc_Word16 *out_H, WebRtc_UWord32 FS, + WebRtc_Word16 lowLevelSignal); + +WebRtc_Word32 WebRtcAgc_AddFarendToDigital(DigitalAgc_t *digitalAgcInst, const WebRtc_Word16 *inFar, + WebRtc_Word16 nrSamples); + +void WebRtcAgc_InitVad(AgcVad_t *vadInst); + +WebRtc_Word16 WebRtcAgc_ProcessVad(AgcVad_t *vadInst, // (i) VAD state + const WebRtc_Word16 *in, // (i) Speech signal + WebRtc_Word16 nrSamples); // (i) number of samples + +WebRtc_Word32 WebRtcAgc_CalculateGainTable(WebRtc_Word32 *gainTable, // Q16 + WebRtc_Word16 compressionGaindB, // Q0 (in dB) + WebRtc_Word16 targetLevelDbfs,// Q0 (in dB) + WebRtc_UWord8 limiterEnable, WebRtc_Word16 analogTarget); + +#endif // WEBRTC_MODULES_AUDIO_PROCESSING_AGC_MAIN_SOURCE_ANALOG_AGC_H_ diff --git a/src/modules/audio_processing/main/apm_tests.gypi b/src/modules/audio_processing/main/apm_tests.gypi new file mode 100644 index 0000000..8c27ff9 --- /dev/null +++ b/src/modules/audio_processing/main/apm_tests.gypi @@ -0,0 +1,107 @@ +# Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. +# +# Use of this source code is governed by a BSD-style license +# that can be found in the LICENSE file in the root of the source +# tree. An additional intellectual property rights grant can be found +# in the file PATENTS. All contributing project authors may +# be found in the AUTHORS file in the root of the source tree. + +{ + 'variables': { + 'protoc_out_dir': '<(SHARED_INTERMEDIATE_DIR)/protoc_out', + 'protoc_out_relpath': 'webrtc/audio_processing', + }, + 'targets': [ + { + 'target_name': 'audioproc_unittest', + 'type': 'executable', + 'conditions': [ + ['prefer_fixed_point==1', { + 'defines': ['WEBRTC_APM_UNIT_TEST_FIXED_PROFILE'], + }, { + 'defines': ['WEBRTC_APM_UNIT_TEST_FLOAT_PROFILE'], + }], + ], + 'dependencies': [ + 'audioproc_unittest_proto', + 'audio_processing', + '<(webrtc_root)/common_audio/common_audio.gyp:spl', + '<(webrtc_root)/system_wrappers/source/system_wrappers.gyp:system_wrappers', + '<(webrtc_root)/../testing/gtest.gyp:gtest', + '<(webrtc_root)/../testing/gtest.gyp:gtest_main', + '<(webrtc_root)/../third_party/protobuf/protobuf.gyp:protobuf_lite', + ], + 'include_dirs': [ + '../../../../testing/gtest/include', + '<(protoc_out_dir)', + ], + 'sources': [ + 'test/unit_test/unit_test.cc', + '<(protoc_out_dir)/<(protoc_out_relpath)/unittest.pb.cc', + '<(protoc_out_dir)/<(protoc_out_relpath)/unittest.pb.h', + ], + }, + { + # Protobuf compiler / generate rule for audioproc_unittest + 'target_name': 'audioproc_unittest_proto', + 'type': 'none', + 'variables': { + 'proto_relpath': + '<(webrtc_root)/modules/audio_processing/main/test/unit_test', + }, + 'sources': [ + '<(proto_relpath)/unittest.proto', + ], + 'rules': [ + { + 'rule_name': 'genproto', + 'extension': 'proto', + 'inputs': [ + '<(PRODUCT_DIR)/<(EXECUTABLE_PREFIX)protoc<(EXECUTABLE_SUFFIX)', + ], + 'outputs': [ + '<(protoc_out_dir)/<(protoc_out_relpath)/<(RULE_INPUT_ROOT).pb.cc', + '<(protoc_out_dir)/<(RULE_INPUT_ROOT).pb.h', + ], + 'action': [ + '<(PRODUCT_DIR)/<(EXECUTABLE_PREFIX)protoc<(EXECUTABLE_SUFFIX)', + '--proto_path=<(proto_relpath)', + '<(proto_relpath)/<(RULE_INPUT_NAME)', + '--cpp_out=<(protoc_out_dir)/<(protoc_out_relpath)', + ], + 'message': 'Generating C++ code from <(RULE_INPUT_PATH)', + }, + ], + 'dependencies': [ + '../../third_party/protobuf/protobuf.gyp:protoc#host', + ], + # This target exports a hard dependency because it generates header + # files. + 'hard_dependency': 1, + }, + { + 'target_name': 'audioproc_process_test', + 'type': 'executable', + 'dependencies': [ + 'audio_processing', + '<(webrtc_root)/system_wrappers/source/system_wrappers.gyp:system_wrappers', + '<(webrtc_root)/../testing/gtest.gyp:gtest', + '<(webrtc_root)/../testing/gtest.gyp:gtest_main', + '<(webrtc_root)/../third_party/protobuf/protobuf.gyp:protobuf_lite', + ], + 'include_dirs': [ + '../../../../testing/gtest/include', + '<(protoc_out_dir)', + ], + 'sources': [ + 'test/process_test/process_test.cc', + ], + }, + ], +} + +# Local Variables: +# tab-width:2 +# indent-tabs-mode:nil +# End: +# vim: set expandtab tabstop=2 shiftwidth=2: diff --git a/src/modules/audio_processing/main/interface/audio_processing.h b/src/modules/audio_processing/main/interface/audio_processing.h new file mode 100644 index 0000000..350ef82 --- /dev/null +++ b/src/modules/audio_processing/main/interface/audio_processing.h @@ -0,0 +1,586 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +#ifndef WEBRTC_MODULES_AUDIO_PROCESSING_MAIN_INTERFACE_AUDIO_PROCESSING_H_ +#define WEBRTC_MODULES_AUDIO_PROCESSING_MAIN_INTERFACE_AUDIO_PROCESSING_H_ + +#include // size_t + +#include "typedefs.h" +#include "module.h" + +namespace webrtc { + +class AudioFrame; +class EchoCancellation; +class EchoControlMobile; +class GainControl; +class HighPassFilter; +class LevelEstimator; +class NoiseSuppression; +class VoiceDetection; + +// The Audio Processing Module (APM) provides a collection of voice processing +// components designed for real-time communications software. +// +// APM operates on two audio streams on a frame-by-frame basis. Frames of the +// primary stream, on which all processing is applied, are passed to +// |ProcessStream()|. Frames of the reverse direction stream, which are used for +// analysis by some components, are passed to |AnalyzeReverseStream()|. On the +// client-side, this will typically be the near-end (capture) and far-end +// (render) streams, respectively. APM should be placed in the signal chain as +// close to the audio hardware abstraction layer (HAL) as possible. +// +// On the server-side, the reverse stream will normally not be used, with +// processing occurring on each incoming stream. +// +// Component interfaces follow a similar pattern and are accessed through +// corresponding getters in APM. All components are disabled at create-time, +// with default settings that are recommended for most situations. New settings +// can be applied without enabling a component. Enabling a component triggers +// memory allocation and initialization to allow it to start processing the +// streams. +// +// Thread safety is provided with the following assumptions to reduce locking +// overhead: +// 1. The stream getters and setters are called from the same thread as +// ProcessStream(). More precisely, stream functions are never called +// concurrently with ProcessStream(). +// 2. Parameter getters are never called concurrently with the corresponding +// setter. +// +// APM accepts only 16-bit linear PCM audio data in frames of 10 ms. Multiple +// channels should be interleaved. +// +// Usage example, omitting error checking: +// AudioProcessing* apm = AudioProcessing::Create(0); +// apm->set_sample_rate_hz(32000); // Super-wideband processing. +// +// // Mono capture and stereo render. +// apm->set_num_channels(1, 1); +// apm->set_num_reverse_channels(2); +// +// apm->high_pass_filter()->Enable(true); +// +// apm->echo_cancellation()->enable_drift_compensation(false); +// apm->echo_cancellation()->Enable(true); +// +// apm->noise_reduction()->set_level(kHighSuppression); +// apm->noise_reduction()->Enable(true); +// +// apm->gain_control()->set_analog_level_limits(0, 255); +// apm->gain_control()->set_mode(kAdaptiveAnalog); +// apm->gain_control()->Enable(true); +// +// apm->voice_detection()->Enable(true); +// +// // Start a voice call... +// +// // ... Render frame arrives bound for the audio HAL ... +// apm->AnalyzeReverseStream(render_frame); +// +// // ... Capture frame arrives from the audio HAL ... +// // Call required set_stream_ functions. +// apm->set_stream_delay_ms(delay_ms); +// apm->gain_control()->set_stream_analog_level(analog_level); +// +// apm->ProcessStream(capture_frame); +// +// // Call required stream_ functions. +// analog_level = apm->gain_control()->stream_analog_level(); +// has_voice = apm->stream_has_voice(); +// +// // Repeate render and capture processing for the duration of the call... +// // Start a new call... +// apm->Initialize(); +// +// // Close the application... +// AudioProcessing::Destroy(apm); +// apm = NULL; +// +class AudioProcessing : public Module { + public: + // Creates a APM instance, with identifier |id|. Use one instance for every + // primary audio stream requiring processing. On the client-side, this would + // typically be one instance for the near-end stream, and additional instances + // for each far-end stream which requires processing. On the server-side, + // this would typically be one instance for every incoming stream. + static AudioProcessing* Create(int id); + + // Destroys a |apm| instance. + static void Destroy(AudioProcessing* apm); + + // Initializes internal states, while retaining all user settings. This + // should be called before beginning to process a new audio stream. However, + // it is not necessary to call before processing the first stream after + // creation. + virtual int Initialize() = 0; + + // Sets the sample |rate| in Hz for both the primary and reverse audio + // streams. 8000, 16000 or 32000 Hz are permitted. + virtual int set_sample_rate_hz(int rate) = 0; + virtual int sample_rate_hz() const = 0; + + // Sets the number of channels for the primary audio stream. Input frames must + // contain a number of channels given by |input_channels|, while output frames + // will be returned with number of channels given by |output_channels|. + virtual int set_num_channels(int input_channels, int output_channels) = 0; + virtual int num_input_channels() const = 0; + virtual int num_output_channels() const = 0; + + // Sets the number of channels for the reverse audio stream. Input frames must + // contain a number of channels given by |channels|. + virtual int set_num_reverse_channels(int channels) = 0; + virtual int num_reverse_channels() const = 0; + + // Processes a 10 ms |frame| of the primary audio stream. On the client-side, + // this is the near-end (or captured) audio. + // + // If needed for enabled functionality, any function with the set_stream_ tag + // must be called prior to processing the current frame. Any getter function + // with the stream_ tag which is needed should be called after processing. + // + // The |_frequencyInHz|, |_audioChannel|, and |_payloadDataLengthInSamples| + // members of |frame| must be valid, and correspond to settings supplied + // to APM. + virtual int ProcessStream(AudioFrame* frame) = 0; + + // Analyzes a 10 ms |frame| of the reverse direction audio stream. The frame + // will not be modified. On the client-side, this is the far-end (or to be + // rendered) audio. + // + // It is only necessary to provide this if echo processing is enabled, as the + // reverse stream forms the echo reference signal. It is recommended, but not + // necessary, to provide if gain control is enabled. On the server-side this + // typically will not be used. If you're not sure what to pass in here, + // chances are you don't need to use it. + // + // The |_frequencyInHz|, |_audioChannel|, and |_payloadDataLengthInSamples| + // members of |frame| must be valid. + // + // TODO(ajm): add const to input; requires an implementation fix. + virtual int AnalyzeReverseStream(AudioFrame* frame) = 0; + + // This must be called if and only if echo processing is enabled. + // + // Sets the |delay| in ms between AnalyzeReverseStream() receiving a far-end + // frame and ProcessStream() receiving a near-end frame containing the + // corresponding echo. On the client-side this can be expressed as + // delay = (t_render - t_analyze) + (t_process - t_capture) + // where, + // - t_analyze is the time a frame is passed to AnalyzeReverseStream() and + // t_render is the time the first sample of the same frame is rendered by + // the audio hardware. + // - t_capture is the time the first sample of a frame is captured by the + // audio hardware and t_pull is the time the same frame is passed to + // ProcessStream(). + virtual int set_stream_delay_ms(int delay) = 0; + virtual int stream_delay_ms() const = 0; + + // Starts recording debugging information to a file specified by |filename|, + // a NULL-terminated string. If there is an ongoing recording, the old file + // will be closed, and recording will continue in the newly specified file. + // An already existing file will be overwritten without warning. + static const int kMaxFilenameSize = 1024; + virtual int StartDebugRecording(const char filename[kMaxFilenameSize]) = 0; + + // Stops recording debugging information, and closes the file. Recording + // cannot be resumed in the same file (without overwriting it). + virtual int StopDebugRecording() = 0; + + // These provide access to the component interfaces and should never return + // NULL. The pointers will be valid for the lifetime of the APM instance. + // The memory for these objects is entirely managed internally. + virtual EchoCancellation* echo_cancellation() const = 0; + virtual EchoControlMobile* echo_control_mobile() const = 0; + virtual GainControl* gain_control() const = 0; + virtual HighPassFilter* high_pass_filter() const = 0; + virtual LevelEstimator* level_estimator() const = 0; + virtual NoiseSuppression* noise_suppression() const = 0; + virtual VoiceDetection* voice_detection() const = 0; + + struct Statistic { + int instant; // Instantaneous value. + int average; // Long-term average. + int maximum; // Long-term maximum. + int minimum; // Long-term minimum. + }; + + // Fatal errors. + enum Errors { + kNoError = 0, + kUnspecifiedError = -1, + kCreationFailedError = -2, + kUnsupportedComponentError = -3, + kUnsupportedFunctionError = -4, + kNullPointerError = -5, + kBadParameterError = -6, + kBadSampleRateError = -7, + kBadDataLengthError = -8, + kBadNumberChannelsError = -9, + kFileError = -10, + kStreamParameterNotSetError = -11, + kNotEnabledError = -12 + }; + + // Warnings are non-fatal. + enum Warnings { + // This results when a set_stream_ parameter is out of range. Processing + // will continue, but the parameter may have been truncated. + kBadStreamParameterWarning = -13, + }; + + // Inherited from Module. + virtual WebRtc_Word32 TimeUntilNextProcess() { return -1; }; + virtual WebRtc_Word32 Process() { return -1; }; + + protected: + virtual ~AudioProcessing() {}; +}; + +// The acoustic echo cancellation (AEC) component provides better performance +// than AECM but also requires more processing power and is dependent on delay +// stability and reporting accuracy. As such it is well-suited and recommended +// for PC and IP phone applications. +// +// Not recommended to be enabled on the server-side. +class EchoCancellation { + public: + // EchoCancellation and EchoControlMobile may not be enabled simultaneously. + // Enabling one will disable the other. + virtual int Enable(bool enable) = 0; + virtual bool is_enabled() const = 0; + + // Differences in clock speed on the primary and reverse streams can impact + // the AEC performance. On the client-side, this could be seen when different + // render and capture devices are used, particularly with webcams. + // + // This enables a compensation mechanism, and requires that + // |set_device_sample_rate_hz()| and |set_stream_drift_samples()| be called. + virtual int enable_drift_compensation(bool enable) = 0; + virtual bool is_drift_compensation_enabled() const = 0; + + // Provides the sampling rate of the audio devices. It is assumed the render + // and capture devices use the same nominal sample rate. Required if and only + // if drift compensation is enabled. + virtual int set_device_sample_rate_hz(int rate) = 0; + virtual int device_sample_rate_hz() const = 0; + + // Sets the difference between the number of samples rendered and captured by + // the audio devices since the last call to |ProcessStream()|. Must be called + // if and only if drift compensation is enabled, prior to |ProcessStream()|. + virtual int set_stream_drift_samples(int drift) = 0; + virtual int stream_drift_samples() const = 0; + + enum SuppressionLevel { + kLowSuppression, + kModerateSuppression, + kHighSuppression + }; + + // Sets the aggressiveness of the suppressor. A higher level trades off + // double-talk performance for increased echo suppression. + virtual int set_suppression_level(SuppressionLevel level) = 0; + virtual SuppressionLevel suppression_level() const = 0; + + // Returns false if the current frame almost certainly contains no echo + // and true if it _might_ contain echo. + virtual bool stream_has_echo() const = 0; + + // Enables the computation of various echo metrics. These are obtained + // through |GetMetrics()|. + virtual int enable_metrics(bool enable) = 0; + virtual bool are_metrics_enabled() const = 0; + + // Each statistic is reported in dB. + // P_far: Far-end (render) signal power. + // P_echo: Near-end (capture) echo signal power. + // P_out: Signal power at the output of the AEC. + // P_a: Internal signal power at the point before the AEC's non-linear + // processor. + struct Metrics { + // RERL = ERL + ERLE + AudioProcessing::Statistic residual_echo_return_loss; + + // ERL = 10log_10(P_far / P_echo) + AudioProcessing::Statistic echo_return_loss; + + // ERLE = 10log_10(P_echo / P_out) + AudioProcessing::Statistic echo_return_loss_enhancement; + + // (Pre non-linear processing suppression) A_NLP = 10log_10(P_echo / P_a) + AudioProcessing::Statistic a_nlp; + }; + + // TODO(ajm): discuss the metrics update period. + virtual int GetMetrics(Metrics* metrics) = 0; + + protected: + virtual ~EchoCancellation() {}; +}; + +// The acoustic echo control for mobile (AECM) component is a low complexity +// robust option intended for use on mobile devices. +// +// Not recommended to be enabled on the server-side. +class EchoControlMobile { + public: + // EchoCancellation and EchoControlMobile may not be enabled simultaneously. + // Enabling one will disable the other. + virtual int Enable(bool enable) = 0; + virtual bool is_enabled() const = 0; + + // Recommended settings for particular audio routes. In general, the louder + // the echo is expected to be, the higher this value should be set. The + // preferred setting may vary from device to device. + enum RoutingMode { + kQuietEarpieceOrHeadset, + kEarpiece, + kLoudEarpiece, + kSpeakerphone, + kLoudSpeakerphone + }; + + // Sets echo control appropriate for the audio routing |mode| on the device. + // It can and should be updated during a call if the audio routing changes. + virtual int set_routing_mode(RoutingMode mode) = 0; + virtual RoutingMode routing_mode() const = 0; + + // Comfort noise replaces suppressed background noise to maintain a + // consistent signal level. + virtual int enable_comfort_noise(bool enable) = 0; + virtual bool is_comfort_noise_enabled() const = 0; + + // A typical use case is to initialize the component with an echo path from a + // previous call. The echo path is retrieved using |GetEchoPath()|, typically + // at the end of a call. The data can then be stored for later use as an + // initializer before the next call, using |SetEchoPath()|. + // + // Controlling the echo path this way requires the data |size_bytes| to match + // the internal echo path size. This size can be acquired using + // |echo_path_size_bytes()|. |SetEchoPath()| causes an entire reset, worth + // noting if it is to be called during an ongoing call. + // + // It is possible that version incompatibilities may result in a stored echo + // path of the incorrect size. In this case, the stored path should be + // discarded. + virtual int SetEchoPath(const void* echo_path, size_t size_bytes) = 0; + virtual int GetEchoPath(void* echo_path, size_t size_bytes) const = 0; + + // The returned path size is guaranteed not to change for the lifetime of + // the application. + static size_t echo_path_size_bytes(); + + protected: + virtual ~EchoControlMobile() {}; +}; + +// The automatic gain control (AGC) component brings the signal to an +// appropriate range. This is done by applying a digital gain directly and, in +// the analog mode, prescribing an analog gain to be applied at the audio HAL. +// +// Recommended to be enabled on the client-side. +class GainControl { + public: + virtual int Enable(bool enable) = 0; + virtual bool is_enabled() const = 0; + + // When an analog mode is set, this must be called prior to |ProcessStream()| + // to pass the current analog level from the audio HAL. Must be within the + // range provided to |set_analog_level_limits()|. + virtual int set_stream_analog_level(int level) = 0; + + // When an analog mode is set, this should be called after |ProcessStream()| + // to obtain the recommended new analog level for the audio HAL. It is the + // users responsibility to apply this level. + virtual int stream_analog_level() = 0; + + enum Mode { + // Adaptive mode intended for use if an analog volume control is available + // on the capture device. It will require the user to provide coupling + // between the OS mixer controls and AGC through the |stream_analog_level()| + // functions. + // + // It consists of an analog gain prescription for the audio device and a + // digital compression stage. + kAdaptiveAnalog, + + // Adaptive mode intended for situations in which an analog volume control + // is unavailable. It operates in a similar fashion to the adaptive analog + // mode, but with scaling instead applied in the digital domain. As with + // the analog mode, it additionally uses a digital compression stage. + kAdaptiveDigital, + + // Fixed mode which enables only the digital compression stage also used by + // the two adaptive modes. + // + // It is distinguished from the adaptive modes by considering only a + // short time-window of the input signal. It applies a fixed gain through + // most of the input level range, and compresses (gradually reduces gain + // with increasing level) the input signal at higher levels. This mode is + // preferred on embedded devices where the capture signal level is + // predictable, so that a known gain can be applied. + kFixedDigital + }; + + virtual int set_mode(Mode mode) = 0; + virtual Mode mode() const = 0; + + // Sets the target peak |level| (or envelope) of the AGC in dBFs (decibels + // from digital full-scale). The convention is to use positive values. For + // instance, passing in a value of 3 corresponds to -3 dBFs, or a target + // level 3 dB below full-scale. Limited to [0, 31]. + // + // TODO(ajm): use a negative value here instead, if/when VoE will similarly + // update its interface. + virtual int set_target_level_dbfs(int level) = 0; + virtual int target_level_dbfs() const = 0; + + // Sets the maximum |gain| the digital compression stage may apply, in dB. A + // higher number corresponds to greater compression, while a value of 0 will + // leave the signal uncompressed. Limited to [0, 90]. + virtual int set_compression_gain_db(int gain) = 0; + virtual int compression_gain_db() const = 0; + + // When enabled, the compression stage will hard limit the signal to the + // target level. Otherwise, the signal will be compressed but not limited + // above the target level. + virtual int enable_limiter(bool enable) = 0; + virtual bool is_limiter_enabled() const = 0; + + // Sets the |minimum| and |maximum| analog levels of the audio capture device. + // Must be set if and only if an analog mode is used. Limited to [0, 65535]. + virtual int set_analog_level_limits(int minimum, + int maximum) = 0; + virtual int analog_level_minimum() const = 0; + virtual int analog_level_maximum() const = 0; + + // Returns true if the AGC has detected a saturation event (period where the + // signal reaches digital full-scale) in the current frame and the analog + // level cannot be reduced. + // + // This could be used as an indicator to reduce or disable analog mic gain at + // the audio HAL. + virtual bool stream_is_saturated() const = 0; + + protected: + virtual ~GainControl() {}; +}; + +// A filtering component which removes DC offset and low-frequency noise. +// Recommended to be enabled on the client-side. +class HighPassFilter { + public: + virtual int Enable(bool enable) = 0; + virtual bool is_enabled() const = 0; + + protected: + virtual ~HighPassFilter() {}; +}; + +// An estimation component used to retrieve level metrics. +class LevelEstimator { + public: + virtual int Enable(bool enable) = 0; + virtual bool is_enabled() const = 0; + + // The metrics are reported in dBFs calculated as: + // Level = 10log_10(P_s / P_max) [dBFs], where + // P_s is the signal power and P_max is the maximum possible (or peak) + // power. With 16-bit signals, P_max = (2^15)^2. + struct Metrics { + AudioProcessing::Statistic signal; // Overall signal level. + AudioProcessing::Statistic speech; // Speech level. + AudioProcessing::Statistic noise; // Noise level. + }; + + virtual int GetMetrics(Metrics* metrics, Metrics* reverse_metrics) = 0; + + //virtual int enable_noise_warning(bool enable) = 0; + //bool is_noise_warning_enabled() const = 0; + //virtual bool stream_has_high_noise() const = 0; + + protected: + virtual ~LevelEstimator() {}; +}; + +// The noise suppression (NS) component attempts to remove noise while +// retaining speech. Recommended to be enabled on the client-side. +// +// Recommended to be enabled on the client-side. +class NoiseSuppression { + public: + virtual int Enable(bool enable) = 0; + virtual bool is_enabled() const = 0; + + // Determines the aggressiveness of the suppression. Increasing the level + // will reduce the noise level at the expense of a higher speech distortion. + enum Level { + kLow, + kModerate, + kHigh, + kVeryHigh + }; + + virtual int set_level(Level level) = 0; + virtual Level level() const = 0; + + protected: + virtual ~NoiseSuppression() {}; +}; + +// The voice activity detection (VAD) component analyzes the stream to +// determine if voice is present. A facility is also provided to pass in an +// external VAD decision. +class VoiceDetection { + public: + virtual int Enable(bool enable) = 0; + virtual bool is_enabled() const = 0; + + // Returns true if voice is detected in the current frame. Should be called + // after |ProcessStream()|. + virtual bool stream_has_voice() const = 0; + + // Some of the APM functionality requires a VAD decision. In the case that + // a decision is externally available for the current frame, it can be passed + // in here, before |ProcessStream()| is called. + // + // VoiceDetection does _not_ need to be enabled to use this. If it happens to + // be enabled, detection will be skipped for any frame in which an external + // VAD decision is provided. + virtual int set_stream_has_voice(bool has_voice) = 0; + + // Specifies the likelihood that a frame will be declared to contain voice. + // A higher value makes it more likely that speech will not be clipped, at + // the expense of more noise being detected as voice. + enum Likelihood { + kVeryLowLikelihood, + kLowLikelihood, + kModerateLikelihood, + kHighLikelihood + }; + + virtual int set_likelihood(Likelihood likelihood) = 0; + virtual Likelihood likelihood() const = 0; + + // Sets the |size| of the frames in ms on which the VAD will operate. Larger + // frames will improve detection accuracy, but reduce the frequency of + // updates. + // + // This does not impact the size of frames passed to |ProcessStream()|. + virtual int set_frame_size_ms(int size) = 0; + virtual int frame_size_ms() const = 0; + + protected: + virtual ~VoiceDetection() {}; +}; +} // namespace webrtc + +#endif // WEBRTC_MODULES_AUDIO_PROCESSING_MAIN_INTERFACE_AUDIO_PROCESSING_H_ diff --git a/src/modules/audio_processing/main/source/apm.gypi b/src/modules/audio_processing/main/source/apm.gypi new file mode 100644 index 0000000..5cac671 --- /dev/null +++ b/src/modules/audio_processing/main/source/apm.gypi @@ -0,0 +1,136 @@ +# Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. +# +# Use of this source code is governed by a BSD-style license +# that can be found in the LICENSE file in the root of the source +# tree. An additional intellectual property rights grant can be found +# in the file PATENTS. All contributing project authors may +# be found in the AUTHORS file in the root of the source tree. + +{ + 'variables': { + 'protoc_out_dir': '<(SHARED_INTERMEDIATE_DIR)/protoc_out', + 'protoc_out_relpath': 'webrtc/audio_processing', + }, + 'targets': [ + { + 'target_name': 'audio_processing', + 'type': '<(library)', + 'conditions': [ + ['prefer_fixed_point==1', { + 'dependencies': ['ns_fix'], + 'defines': ['WEBRTC_NS_FIXED'], + }, { + 'dependencies': ['ns'], + 'defines': ['WEBRTC_NS_FLOAT'], + }], + ['build_with_chromium==1', { + 'dependencies': [ + '../../protobuf/protobuf.gyp:protobuf_lite', + ], + }, { + 'dependencies': [ + '../../third_party/protobuf/protobuf.gyp:protobuf_lite', + ], + }], + ], + 'dependencies': [ + 'debug_proto', + 'aec', + 'aecm', + 'agc', + '<(webrtc_root)/common_audio/common_audio.gyp:spl', + '<(webrtc_root)/common_audio/common_audio.gyp:vad', + '<(webrtc_root)/system_wrappers/source/system_wrappers.gyp:system_wrappers', + ], + 'include_dirs': [ + '../interface', + '../../../interface', + '<(protoc_out_dir)', + ], + 'direct_dependent_settings': { + 'include_dirs': [ + '../interface', + '../../../interface', + ], + }, + 'sources': [ + '../interface/audio_processing.h', + 'audio_buffer.cc', + 'audio_buffer.h', + 'audio_processing_impl.cc', + 'audio_processing_impl.h', + 'echo_cancellation_impl.cc', + 'echo_cancellation_impl.h', + 'echo_control_mobile_impl.cc', + 'echo_control_mobile_impl.h', + 'gain_control_impl.cc', + 'gain_control_impl.h', + 'high_pass_filter_impl.cc', + 'high_pass_filter_impl.h', + 'level_estimator_impl.cc', + 'level_estimator_impl.h', + 'noise_suppression_impl.cc', + 'noise_suppression_impl.h', + 'splitting_filter.cc', + 'splitting_filter.h', + 'processing_component.cc', + 'processing_component.h', + 'voice_detection_impl.cc', + 'voice_detection_impl.h', + '<(protoc_out_dir)/<(protoc_out_relpath)/debug.pb.cc', + '<(protoc_out_dir)/<(protoc_out_relpath)/debug.pb.h', + ], + }, + { + # Protobuf compiler / generate rule for audio_processing + 'target_name': 'debug_proto', + 'type': 'none', + 'variables': { + 'proto_relpath': 'audio_processing/main/source/', + }, + 'sources': [ + '<(proto_relpath)/debug.proto', + ], + 'rules': [ + { + 'rule_name': 'genproto', + 'extension': 'proto', + 'inputs': [ + '<(PRODUCT_DIR)/<(EXECUTABLE_PREFIX)protoc<(EXECUTABLE_SUFFIX)', + ], + 'outputs': [ + '<(protoc_out_dir)/<(protoc_out_relpath)/<(RULE_INPUT_ROOT).pb.cc', + '<(protoc_out_dir)/<(protoc_out_relpath)/<(RULE_INPUT_ROOT).pb.h', + ], + 'action': [ + '<(PRODUCT_DIR)/<(EXECUTABLE_PREFIX)protoc<(EXECUTABLE_SUFFIX)', + '--proto_path=<(proto_relpath)', + '<(proto_relpath)/<(RULE_INPUT_NAME)', + '--cpp_out=<(protoc_out_dir)/<(protoc_out_relpath)', + ], + 'message': 'Generating C++ code from <(RULE_INPUT_PATH)', + }, + ], + 'conditions': [ + ['build_with_chromium==1', { + 'dependencies': [ + '../../protobuf/protobuf.gyp:protoc#host', + ], + }, { + 'dependencies': [ + '../../third_party/protobuf/protobuf.gyp:protoc#host', + ], + }], + ], + # This target exports a hard dependency because it generates header + # files. + 'hard_dependency': 1, + }, + ], +} + +# Local Variables: +# tab-width:2 +# indent-tabs-mode:nil +# End: +# vim: set expandtab tabstop=2 shiftwidth=2: diff --git a/src/modules/audio_processing/main/source/audio_buffer.cc b/src/modules/audio_processing/main/source/audio_buffer.cc new file mode 100644 index 0000000..6b20fce --- /dev/null +++ b/src/modules/audio_processing/main/source/audio_buffer.cc @@ -0,0 +1,278 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +#include "audio_buffer.h" + +#include "module_common_types.h" + +namespace webrtc { +namespace { + +enum { + kSamplesPer8kHzChannel = 80, + kSamplesPer16kHzChannel = 160, + kSamplesPer32kHzChannel = 320 +}; + +void StereoToMono(const WebRtc_Word16* left, const WebRtc_Word16* right, + WebRtc_Word16* out, int samples_per_channel) { + WebRtc_Word32 data_int32 = 0; + for (int i = 0; i < samples_per_channel; i++) { + data_int32 = (left[i] + right[i]) >> 1; + if (data_int32 > 32767) { + data_int32 = 32767; + } else if (data_int32 < -32768) { + data_int32 = -32768; + } + + out[i] = static_cast(data_int32); + } +} +} // namespace + +struct AudioChannel { + AudioChannel() { + memset(data, 0, sizeof(data)); + } + + WebRtc_Word16 data[kSamplesPer32kHzChannel]; +}; + +struct SplitAudioChannel { + SplitAudioChannel() { + memset(low_pass_data, 0, sizeof(low_pass_data)); + memset(high_pass_data, 0, sizeof(high_pass_data)); + memset(analysis_filter_state1, 0, sizeof(analysis_filter_state1)); + memset(analysis_filter_state2, 0, sizeof(analysis_filter_state2)); + memset(synthesis_filter_state1, 0, sizeof(synthesis_filter_state1)); + memset(synthesis_filter_state2, 0, sizeof(synthesis_filter_state2)); + } + + WebRtc_Word16 low_pass_data[kSamplesPer16kHzChannel]; + WebRtc_Word16 high_pass_data[kSamplesPer16kHzChannel]; + + WebRtc_Word32 analysis_filter_state1[6]; + WebRtc_Word32 analysis_filter_state2[6]; + WebRtc_Word32 synthesis_filter_state1[6]; + WebRtc_Word32 synthesis_filter_state2[6]; +}; + +// TODO(am): check range of input parameters? +AudioBuffer::AudioBuffer(WebRtc_Word32 max_num_channels, + WebRtc_Word32 samples_per_channel) + : max_num_channels_(max_num_channels), + num_channels_(0), + num_mixed_channels_(0), + num_mixed_low_pass_channels_(0), + samples_per_channel_(samples_per_channel), + samples_per_split_channel_(samples_per_channel), + reference_copied_(false), + data_(NULL), + channels_(NULL), + split_channels_(NULL), + mixed_low_pass_channels_(NULL), + low_pass_reference_channels_(NULL) { + if (max_num_channels_ > 1) { + channels_ = new AudioChannel[max_num_channels_]; + mixed_low_pass_channels_ = new AudioChannel[max_num_channels_]; + } + low_pass_reference_channels_ = new AudioChannel[max_num_channels_]; + + if (samples_per_channel_ == kSamplesPer32kHzChannel) { + split_channels_ = new SplitAudioChannel[max_num_channels_]; + samples_per_split_channel_ = kSamplesPer16kHzChannel; + } +} + +AudioBuffer::~AudioBuffer() { + if (channels_ != NULL) { + delete [] channels_; + } + + if (mixed_low_pass_channels_ != NULL) { + delete [] mixed_low_pass_channels_; + } + + if (low_pass_reference_channels_ != NULL) { + delete [] low_pass_reference_channels_; + } + + if (split_channels_ != NULL) { + delete [] split_channels_; + } +} + +WebRtc_Word16* AudioBuffer::data(WebRtc_Word32 channel) const { + assert(channel >= 0 && channel < num_channels_); + if (data_ != NULL) { + return data_; + } + + return channels_[channel].data; +} + +WebRtc_Word16* AudioBuffer::low_pass_split_data(WebRtc_Word32 channel) const { + assert(channel >= 0 && channel < num_channels_); + if (split_channels_ == NULL) { + return data(channel); + } + + return split_channels_[channel].low_pass_data; +} + +WebRtc_Word16* AudioBuffer::high_pass_split_data(WebRtc_Word32 channel) const { + assert(channel >= 0 && channel < num_channels_); + if (split_channels_ == NULL) { + return NULL; + } + + return split_channels_[channel].high_pass_data; +} + +WebRtc_Word16* AudioBuffer::mixed_low_pass_data(WebRtc_Word32 channel) const { + assert(channel >= 0 && channel < num_mixed_low_pass_channels_); + + return mixed_low_pass_channels_[channel].data; +} + +WebRtc_Word16* AudioBuffer::low_pass_reference(WebRtc_Word32 channel) const { + assert(channel >= 0 && channel < num_channels_); + if (!reference_copied_) { + return NULL; + } + + return low_pass_reference_channels_[channel].data; +} + +WebRtc_Word32* AudioBuffer::analysis_filter_state1(WebRtc_Word32 channel) const { + assert(channel >= 0 && channel < num_channels_); + return split_channels_[channel].analysis_filter_state1; +} + +WebRtc_Word32* AudioBuffer::analysis_filter_state2(WebRtc_Word32 channel) const { + assert(channel >= 0 && channel < num_channels_); + return split_channels_[channel].analysis_filter_state2; +} + +WebRtc_Word32* AudioBuffer::synthesis_filter_state1(WebRtc_Word32 channel) const { + assert(channel >= 0 && channel < num_channels_); + return split_channels_[channel].synthesis_filter_state1; +} + +WebRtc_Word32* AudioBuffer::synthesis_filter_state2(WebRtc_Word32 channel) const { + assert(channel >= 0 && channel < num_channels_); + return split_channels_[channel].synthesis_filter_state2; +} + +WebRtc_Word32 AudioBuffer::num_channels() const { + return num_channels_; +} + +WebRtc_Word32 AudioBuffer::samples_per_channel() const { + return samples_per_channel_; +} + +WebRtc_Word32 AudioBuffer::samples_per_split_channel() const { + return samples_per_split_channel_; +} + +// TODO(ajm): Do deinterleaving and mixing in one step? +void AudioBuffer::DeinterleaveFrom(AudioFrame* audioFrame) { + assert(audioFrame->_audioChannel <= max_num_channels_); + assert(audioFrame->_payloadDataLengthInSamples == samples_per_channel_); + + num_channels_ = audioFrame->_audioChannel; + num_mixed_channels_ = 0; + num_mixed_low_pass_channels_ = 0; + reference_copied_ = false; + + if (num_channels_ == 1) { + // We can get away with a pointer assignment in this case. + data_ = audioFrame->_payloadData; + return; + } + + for (int i = 0; i < num_channels_; i++) { + WebRtc_Word16* deinterleaved = channels_[i].data; + WebRtc_Word16* interleaved = audioFrame->_payloadData; + WebRtc_Word32 interleaved_idx = i; + for (int j = 0; j < samples_per_channel_; j++) { + deinterleaved[j] = interleaved[interleaved_idx]; + interleaved_idx += num_channels_; + } + } +} + +void AudioBuffer::InterleaveTo(AudioFrame* audioFrame) const { + assert(audioFrame->_audioChannel == num_channels_); + assert(audioFrame->_payloadDataLengthInSamples == samples_per_channel_); + + if (num_channels_ == 1) { + if (num_mixed_channels_ == 1) { + memcpy(audioFrame->_payloadData, + channels_[0].data, + sizeof(WebRtc_Word16) * samples_per_channel_); + } else { + // These should point to the same buffer in this case. + assert(data_ == audioFrame->_payloadData); + } + + return; + } + + for (int i = 0; i < num_channels_; i++) { + WebRtc_Word16* deinterleaved = channels_[i].data; + WebRtc_Word16* interleaved = audioFrame->_payloadData; + WebRtc_Word32 interleaved_idx = i; + for (int j = 0; j < samples_per_channel_; j++) { + interleaved[interleaved_idx] = deinterleaved[j]; + interleaved_idx += num_channels_; + } + } +} + +// TODO(ajm): would be good to support the no-mix case with pointer assignment. +// TODO(ajm): handle mixing to multiple channels? +void AudioBuffer::Mix(WebRtc_Word32 num_mixed_channels) { + // We currently only support the stereo to mono case. + assert(num_channels_ == 2); + assert(num_mixed_channels == 1); + + StereoToMono(channels_[0].data, + channels_[1].data, + channels_[0].data, + samples_per_channel_); + + num_channels_ = num_mixed_channels; + num_mixed_channels_ = num_mixed_channels; +} + +void AudioBuffer::CopyAndMixLowPass(WebRtc_Word32 num_mixed_channels) { + // We currently only support the stereo to mono case. + assert(num_channels_ == 2); + assert(num_mixed_channels == 1); + + StereoToMono(low_pass_split_data(0), + low_pass_split_data(1), + mixed_low_pass_channels_[0].data, + samples_per_split_channel_); + + num_mixed_low_pass_channels_ = num_mixed_channels; +} + +void AudioBuffer::CopyLowPassToReference() { + reference_copied_ = true; + for (int i = 0; i < num_channels_; i++) { + memcpy(low_pass_reference_channels_[i].data, + low_pass_split_data(i), + sizeof(WebRtc_Word16) * samples_per_split_channel_); + } +} +} // namespace webrtc diff --git a/src/modules/audio_processing/main/source/audio_buffer.h b/src/modules/audio_processing/main/source/audio_buffer.h new file mode 100644 index 0000000..15f850b --- /dev/null +++ b/src/modules/audio_processing/main/source/audio_buffer.h @@ -0,0 +1,68 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +#ifndef WEBRTC_MODULES_AUDIO_PROCESSING_MAIN_SOURCE_AUDIO_BUFFER_H_ +#define WEBRTC_MODULES_AUDIO_PROCESSING_MAIN_SOURCE_AUDIO_BUFFER_H_ + +#include "typedefs.h" + + +namespace webrtc { + +struct AudioChannel; +struct SplitAudioChannel; +class AudioFrame; + +class AudioBuffer { + public: + AudioBuffer(WebRtc_Word32 max_num_channels, WebRtc_Word32 samples_per_channel); + virtual ~AudioBuffer(); + + WebRtc_Word32 num_channels() const; + WebRtc_Word32 samples_per_channel() const; + WebRtc_Word32 samples_per_split_channel() const; + + WebRtc_Word16* data(WebRtc_Word32 channel) const; + WebRtc_Word16* low_pass_split_data(WebRtc_Word32 channel) const; + WebRtc_Word16* high_pass_split_data(WebRtc_Word32 channel) const; + WebRtc_Word16* mixed_low_pass_data(WebRtc_Word32 channel) const; + WebRtc_Word16* low_pass_reference(WebRtc_Word32 channel) const; + + WebRtc_Word32* analysis_filter_state1(WebRtc_Word32 channel) const; + WebRtc_Word32* analysis_filter_state2(WebRtc_Word32 channel) const; + WebRtc_Word32* synthesis_filter_state1(WebRtc_Word32 channel) const; + WebRtc_Word32* synthesis_filter_state2(WebRtc_Word32 channel) const; + + void DeinterleaveFrom(AudioFrame* audioFrame); + void InterleaveTo(AudioFrame* audioFrame) const; + void Mix(WebRtc_Word32 num_mixed_channels); + void CopyAndMixLowPass(WebRtc_Word32 num_mixed_channels); + void CopyLowPassToReference(); + + private: + const WebRtc_Word32 max_num_channels_; + WebRtc_Word32 num_channels_; + WebRtc_Word32 num_mixed_channels_; + WebRtc_Word32 num_mixed_low_pass_channels_; + const WebRtc_Word32 samples_per_channel_; + WebRtc_Word32 samples_per_split_channel_; + bool reference_copied_; + + WebRtc_Word16* data_; + // TODO(ajm): Prefer to make these vectors if permitted... + AudioChannel* channels_; + SplitAudioChannel* split_channels_; + // TODO(ajm): improve this, we don't need the full 32 kHz space here. + AudioChannel* mixed_low_pass_channels_; + AudioChannel* low_pass_reference_channels_; +}; +} // namespace webrtc + +#endif // WEBRTC_MODULES_AUDIO_PROCESSING_MAIN_SOURCE_AUDIO_BUFFER_H_ diff --git a/src/modules/audio_processing/main/source/audio_processing_impl.cc b/src/modules/audio_processing/main/source/audio_processing_impl.cc new file mode 100644 index 0000000..b1464e1 --- /dev/null +++ b/src/modules/audio_processing/main/source/audio_processing_impl.cc @@ -0,0 +1,651 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +#include "audio_processing_impl.h" + +#include + +#include "audio_buffer.h" +#include "critical_section_wrapper.h" +#include "echo_cancellation_impl.h" +#include "echo_control_mobile_impl.h" +#include "file_wrapper.h" +#include "high_pass_filter_impl.h" +#include "gain_control_impl.h" +#include "level_estimator_impl.h" +#include "module_common_types.h" +#include "noise_suppression_impl.h" +#include "processing_component.h" +#include "splitting_filter.h" +#include "voice_detection_impl.h" +#ifdef WEBRTC_ANDROID +#include "external/webrtc/src/modules/audio_processing/main/source/debug.pb.h" +#else +#include "webrtc/audio_processing/debug.pb.h" +#endif + +namespace webrtc { +AudioProcessing* AudioProcessing::Create(int id) { + /*WEBRTC_TRACE(webrtc::kTraceModuleCall, + webrtc::kTraceAudioProcessing, + id, + "AudioProcessing::Create()");*/ + + AudioProcessingImpl* apm = new AudioProcessingImpl(id); + if (apm->Initialize() != kNoError) { + delete apm; + apm = NULL; + } + + return apm; +} + +void AudioProcessing::Destroy(AudioProcessing* apm) { + delete static_cast(apm); +} + +AudioProcessingImpl::AudioProcessingImpl(int id) + : id_(id), + echo_cancellation_(NULL), + echo_control_mobile_(NULL), + gain_control_(NULL), + high_pass_filter_(NULL), + level_estimator_(NULL), + noise_suppression_(NULL), + voice_detection_(NULL), + debug_file_(FileWrapper::Create()), + event_msg_(new audioproc::Event()), + crit_(CriticalSectionWrapper::CreateCriticalSection()), + render_audio_(NULL), + capture_audio_(NULL), + sample_rate_hz_(kSampleRate16kHz), + split_sample_rate_hz_(kSampleRate16kHz), + samples_per_channel_(sample_rate_hz_ / 100), + stream_delay_ms_(0), + was_stream_delay_set_(false), + num_reverse_channels_(1), + num_input_channels_(1), + num_output_channels_(1) { + + echo_cancellation_ = new EchoCancellationImpl(this); + component_list_.push_back(echo_cancellation_); + + echo_control_mobile_ = new EchoControlMobileImpl(this); + component_list_.push_back(echo_control_mobile_); + + gain_control_ = new GainControlImpl(this); + component_list_.push_back(gain_control_); + + high_pass_filter_ = new HighPassFilterImpl(this); + component_list_.push_back(high_pass_filter_); + + level_estimator_ = new LevelEstimatorImpl(this); + component_list_.push_back(level_estimator_); + + noise_suppression_ = new NoiseSuppressionImpl(this); + component_list_.push_back(noise_suppression_); + + voice_detection_ = new VoiceDetectionImpl(this); + component_list_.push_back(voice_detection_); +} + +AudioProcessingImpl::~AudioProcessingImpl() { + while (!component_list_.empty()) { + ProcessingComponent* component = component_list_.front(); + component->Destroy(); + delete component; + component_list_.pop_front(); + } + + if (debug_file_->Open()) { + debug_file_->CloseFile(); + } + delete debug_file_; + debug_file_ = NULL; + + delete event_msg_; + event_msg_ = NULL; + + delete crit_; + crit_ = NULL; + + if (render_audio_) { + delete render_audio_; + render_audio_ = NULL; + } + + if (capture_audio_) { + delete capture_audio_; + capture_audio_ = NULL; + } +} + +CriticalSectionWrapper* AudioProcessingImpl::crit() const { + return crit_; +} + +int AudioProcessingImpl::split_sample_rate_hz() const { + return split_sample_rate_hz_; +} + +int AudioProcessingImpl::Initialize() { + CriticalSectionScoped crit_scoped(*crit_); + return InitializeLocked(); +} + +int AudioProcessingImpl::InitializeLocked() { + if (render_audio_ != NULL) { + delete render_audio_; + render_audio_ = NULL; + } + + if (capture_audio_ != NULL) { + delete capture_audio_; + capture_audio_ = NULL; + } + + render_audio_ = new AudioBuffer(num_reverse_channels_, + samples_per_channel_); + capture_audio_ = new AudioBuffer(num_input_channels_, + samples_per_channel_); + + was_stream_delay_set_ = false; + + // Initialize all components. + std::list::iterator it; + for (it = component_list_.begin(); it != component_list_.end(); it++) { + int err = (*it)->Initialize(); + if (err != kNoError) { + return err; + } + } + + if (debug_file_->Open()) { + int err = WriteInitMessage(); + if (err != kNoError) { + return err; + } + } + + return kNoError; +} + +int AudioProcessingImpl::set_sample_rate_hz(int rate) { + CriticalSectionScoped crit_scoped(*crit_); + if (rate != kSampleRate8kHz && + rate != kSampleRate16kHz && + rate != kSampleRate32kHz) { + return kBadParameterError; + } + + sample_rate_hz_ = rate; + samples_per_channel_ = rate / 100; + + if (sample_rate_hz_ == kSampleRate32kHz) { + split_sample_rate_hz_ = kSampleRate16kHz; + } else { + split_sample_rate_hz_ = sample_rate_hz_; + } + + return InitializeLocked(); +} + +int AudioProcessingImpl::sample_rate_hz() const { + return sample_rate_hz_; +} + +int AudioProcessingImpl::set_num_reverse_channels(int channels) { + CriticalSectionScoped crit_scoped(*crit_); + // Only stereo supported currently. + if (channels > 2 || channels < 1) { + return kBadParameterError; + } + + num_reverse_channels_ = channels; + + return InitializeLocked(); +} + +int AudioProcessingImpl::num_reverse_channels() const { + return num_reverse_channels_; +} + +int AudioProcessingImpl::set_num_channels( + int input_channels, + int output_channels) { + CriticalSectionScoped crit_scoped(*crit_); + if (output_channels > input_channels) { + return kBadParameterError; + } + + // Only stereo supported currently. + if (input_channels > 2 || input_channels < 1) { + return kBadParameterError; + } + + if (output_channels > 2 || output_channels < 1) { + return kBadParameterError; + } + + num_input_channels_ = input_channels; + num_output_channels_ = output_channels; + + return InitializeLocked(); +} + +int AudioProcessingImpl::num_input_channels() const { + return num_input_channels_; +} + +int AudioProcessingImpl::num_output_channels() const { + return num_output_channels_; +} + +int AudioProcessingImpl::ProcessStream(AudioFrame* frame) { + CriticalSectionScoped crit_scoped(*crit_); + int err = kNoError; + + if (frame == NULL) { + return kNullPointerError; + } + + if (frame->_frequencyInHz != sample_rate_hz_) { + return kBadSampleRateError; + } + + if (frame->_audioChannel != num_input_channels_) { + return kBadNumberChannelsError; + } + + if (frame->_payloadDataLengthInSamples != samples_per_channel_) { + return kBadDataLengthError; + } + + if (debug_file_->Open()) { + event_msg_->set_type(audioproc::Event::STREAM); + audioproc::Stream* msg = event_msg_->mutable_stream(); + const size_t data_size = sizeof(WebRtc_Word16) * + frame->_payloadDataLengthInSamples * + frame->_audioChannel; + msg->set_input_data(frame->_payloadData, data_size); + msg->set_delay(stream_delay_ms_); + msg->set_drift(echo_cancellation_->stream_drift_samples()); + msg->set_level(gain_control_->stream_analog_level()); + } + + capture_audio_->DeinterleaveFrom(frame); + + // TODO(ajm): experiment with mixing and AEC placement. + if (num_output_channels_ < num_input_channels_) { + capture_audio_->Mix(num_output_channels_); + + frame->_audioChannel = num_output_channels_; + } + + if (sample_rate_hz_ == kSampleRate32kHz) { + for (int i = 0; i < num_input_channels_; i++) { + // Split into a low and high band. + SplittingFilterAnalysis(capture_audio_->data(i), + capture_audio_->low_pass_split_data(i), + capture_audio_->high_pass_split_data(i), + capture_audio_->analysis_filter_state1(i), + capture_audio_->analysis_filter_state2(i)); + } + } + + err = high_pass_filter_->ProcessCaptureAudio(capture_audio_); + if (err != kNoError) { + return err; + } + + err = gain_control_->AnalyzeCaptureAudio(capture_audio_); + if (err != kNoError) { + return err; + } + + err = echo_cancellation_->ProcessCaptureAudio(capture_audio_); + if (err != kNoError) { + return err; + } + + if (echo_control_mobile_->is_enabled() && + noise_suppression_->is_enabled()) { + capture_audio_->CopyLowPassToReference(); + } + + err = noise_suppression_->ProcessCaptureAudio(capture_audio_); + if (err != kNoError) { + return err; + } + + err = echo_control_mobile_->ProcessCaptureAudio(capture_audio_); + if (err != kNoError) { + return err; + } + + err = voice_detection_->ProcessCaptureAudio(capture_audio_); + if (err != kNoError) { + return err; + } + + err = gain_control_->ProcessCaptureAudio(capture_audio_); + if (err != kNoError) { + return err; + } + + //err = level_estimator_->ProcessCaptureAudio(capture_audio_); + //if (err != kNoError) { + // return err; + //} + + if (sample_rate_hz_ == kSampleRate32kHz) { + for (int i = 0; i < num_output_channels_; i++) { + // Recombine low and high bands. + SplittingFilterSynthesis(capture_audio_->low_pass_split_data(i), + capture_audio_->high_pass_split_data(i), + capture_audio_->data(i), + capture_audio_->synthesis_filter_state1(i), + capture_audio_->synthesis_filter_state2(i)); + } + } + + capture_audio_->InterleaveTo(frame); + + if (debug_file_->Open()) { + audioproc::Stream* msg = event_msg_->mutable_stream(); + const size_t data_size = sizeof(WebRtc_Word16) * + frame->_payloadDataLengthInSamples * + frame->_audioChannel; + msg->set_output_data(frame->_payloadData, data_size); + err = WriteMessageToDebugFile(); + if (err != kNoError) { + return err; + } + } + + return kNoError; +} + +int AudioProcessingImpl::AnalyzeReverseStream(AudioFrame* frame) { + CriticalSectionScoped crit_scoped(*crit_); + int err = kNoError; + + if (frame == NULL) { + return kNullPointerError; + } + + if (frame->_frequencyInHz != sample_rate_hz_) { + return kBadSampleRateError; + } + + if (frame->_audioChannel != num_reverse_channels_) { + return kBadNumberChannelsError; + } + + if (frame->_payloadDataLengthInSamples != samples_per_channel_) { + return kBadDataLengthError; + } + + if (debug_file_->Open()) { + event_msg_->set_type(audioproc::Event::REVERSE_STREAM); + audioproc::ReverseStream* msg = event_msg_->mutable_reverse_stream(); + const size_t data_size = sizeof(WebRtc_Word16) * + frame->_payloadDataLengthInSamples * + frame->_audioChannel; + msg->set_data(frame->_payloadData, data_size); + err = WriteMessageToDebugFile(); + if (err != kNoError) { + return err; + } + } + + render_audio_->DeinterleaveFrom(frame); + + // TODO(ajm): turn the splitting filter into a component? + if (sample_rate_hz_ == kSampleRate32kHz) { + for (int i = 0; i < num_reverse_channels_; i++) { + // Split into low and high band. + SplittingFilterAnalysis(render_audio_->data(i), + render_audio_->low_pass_split_data(i), + render_audio_->high_pass_split_data(i), + render_audio_->analysis_filter_state1(i), + render_audio_->analysis_filter_state2(i)); + } + } + + // TODO(ajm): warnings possible from components? + err = echo_cancellation_->ProcessRenderAudio(render_audio_); + if (err != kNoError) { + return err; + } + + err = echo_control_mobile_->ProcessRenderAudio(render_audio_); + if (err != kNoError) { + return err; + } + + err = gain_control_->ProcessRenderAudio(render_audio_); + if (err != kNoError) { + return err; + } + + //err = level_estimator_->AnalyzeReverseStream(render_audio_); + //if (err != kNoError) { + // return err; + //} + + was_stream_delay_set_ = false; + return err; // TODO(ajm): this is for returning warnings; necessary? +} + +int AudioProcessingImpl::set_stream_delay_ms(int delay) { + was_stream_delay_set_ = true; + if (delay < 0) { + return kBadParameterError; + } + + // TODO(ajm): the max is rather arbitrarily chosen; investigate. + if (delay > 500) { + stream_delay_ms_ = 500; + return kBadStreamParameterWarning; + } + + stream_delay_ms_ = delay; + return kNoError; +} + +int AudioProcessingImpl::stream_delay_ms() const { + return stream_delay_ms_; +} + +bool AudioProcessingImpl::was_stream_delay_set() const { + return was_stream_delay_set_; +} + +int AudioProcessingImpl::StartDebugRecording( + const char filename[AudioProcessing::kMaxFilenameSize]) { + CriticalSectionScoped crit_scoped(*crit_); + assert(kMaxFilenameSize == FileWrapper::kMaxFileNameSize); + + if (filename == NULL) { + return kNullPointerError; + } + + // Stop any ongoing recording. + if (debug_file_->Open()) { + if (debug_file_->CloseFile() == -1) { + return kFileError; + } + } + + if (debug_file_->OpenFile(filename, false) == -1) { + debug_file_->CloseFile(); + return kFileError; + } + + int err = WriteInitMessage(); + if (err != kNoError) { + return err; + } + + return kNoError; +} + +int AudioProcessingImpl::StopDebugRecording() { + CriticalSectionScoped crit_scoped(*crit_); + // We just return if recording hasn't started. + if (debug_file_->Open()) { + if (debug_file_->CloseFile() == -1) { + return kFileError; + } + } + + return kNoError; +} + +EchoCancellation* AudioProcessingImpl::echo_cancellation() const { + return echo_cancellation_; +} + +EchoControlMobile* AudioProcessingImpl::echo_control_mobile() const { + return echo_control_mobile_; +} + +GainControl* AudioProcessingImpl::gain_control() const { + return gain_control_; +} + +HighPassFilter* AudioProcessingImpl::high_pass_filter() const { + return high_pass_filter_; +} + +LevelEstimator* AudioProcessingImpl::level_estimator() const { + return level_estimator_; +} + +NoiseSuppression* AudioProcessingImpl::noise_suppression() const { + return noise_suppression_; +} + +VoiceDetection* AudioProcessingImpl::voice_detection() const { + return voice_detection_; +} + +WebRtc_Word32 AudioProcessingImpl::Version(WebRtc_Word8* version, + WebRtc_UWord32& bytes_remaining, WebRtc_UWord32& position) const { + if (version == NULL) { + /*WEBRTC_TRACE(webrtc::kTraceError, + webrtc::kTraceAudioProcessing, + -1, + "Null version pointer");*/ + return kNullPointerError; + } + memset(&version[position], 0, bytes_remaining); + + char my_version[] = "AudioProcessing 1.0.0"; + // Includes null termination. + WebRtc_UWord32 length = static_cast(strlen(my_version)); + if (bytes_remaining < length) { + /*WEBRTC_TRACE(webrtc::kTraceError, + webrtc::kTraceAudioProcessing, + -1, + "Buffer of insufficient length");*/ + return kBadParameterError; + } + memcpy(&version[position], my_version, length); + bytes_remaining -= length; + position += length; + + std::list::const_iterator it; + for (it = component_list_.begin(); it != component_list_.end(); it++) { + char component_version[256]; + strcpy(component_version, "\n"); + int err = (*it)->get_version(&component_version[1], + sizeof(component_version) - 1); + if (err != kNoError) { + return err; + } + if (strncmp(&component_version[1], "\0", 1) == 0) { + // Assume empty if first byte is NULL. + continue; + } + + length = static_cast(strlen(component_version)); + if (bytes_remaining < length) { + /*WEBRTC_TRACE(webrtc::kTraceError, + webrtc::kTraceAudioProcessing, + -1, + "Buffer of insufficient length");*/ + return kBadParameterError; + } + memcpy(&version[position], component_version, length); + bytes_remaining -= length; + position += length; + } + + return kNoError; +} + +WebRtc_Word32 AudioProcessingImpl::ChangeUniqueId(const WebRtc_Word32 id) { + CriticalSectionScoped crit_scoped(*crit_); + /*WEBRTC_TRACE(webrtc::kTraceModuleCall, + webrtc::kTraceAudioProcessing, + id_, + "ChangeUniqueId(new id = %d)", + id);*/ + id_ = id; + + return kNoError; +} + +int AudioProcessingImpl::WriteMessageToDebugFile() { + int32_t size = event_msg_->ByteSize(); + if (size <= 0) { + return kUnspecifiedError; + } +#if defined(WEBRTC_BIG_ENDIAN) + // TODO(ajm): Use little-endian "on the wire". For the moment, we can be + // pretty safe in assuming little-endian. +#endif + + if (!event_msg_->SerializeToString(&event_str_)) { + return kUnspecifiedError; + } + + // Write message preceded by its size. + if (!debug_file_->Write(&size, sizeof(int32_t))) { + return kFileError; + } + if (!debug_file_->Write(event_str_.data(), event_str_.length())) { + return kFileError; + } + + event_msg_->Clear(); + + return 0; +} + +int AudioProcessingImpl::WriteInitMessage() { + event_msg_->set_type(audioproc::Event::INIT); + audioproc::Init* msg = event_msg_->mutable_init(); + msg->set_sample_rate(sample_rate_hz_); + msg->set_device_sample_rate(echo_cancellation_->device_sample_rate_hz()); + msg->set_num_input_channels(num_input_channels_); + msg->set_num_output_channels(num_output_channels_); + msg->set_num_reverse_channels(num_reverse_channels_); + + int err = WriteMessageToDebugFile(); + if (err != kNoError) { + return err; + } + + return kNoError; +} +} // namespace webrtc diff --git a/src/modules/audio_processing/main/source/audio_processing_impl.h b/src/modules/audio_processing/main/source/audio_processing_impl.h new file mode 100644 index 0000000..fc35937 --- /dev/null +++ b/src/modules/audio_processing/main/source/audio_processing_impl.h @@ -0,0 +1,117 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +#ifndef WEBRTC_MODULES_AUDIO_PROCESSING_MAIN_SOURCE_AUDIO_PROCESSING_IMPL_H_ +#define WEBRTC_MODULES_AUDIO_PROCESSING_MAIN_SOURCE_AUDIO_PROCESSING_IMPL_H_ + +#include +#include + +#include "audio_processing.h" + +namespace webrtc { +namespace audioproc { +class Event; +} // audioproc +class AudioBuffer; +class CriticalSectionWrapper; +class EchoCancellationImpl; +class EchoControlMobileImpl; +class FileWrapper; +class GainControlImpl; +class HighPassFilterImpl; +class LevelEstimatorImpl; +class NoiseSuppressionImpl; +class ProcessingComponent; +class VoiceDetectionImpl; + +class AudioProcessingImpl : public AudioProcessing { + public: + enum { + kSampleRate8kHz = 8000, + kSampleRate16kHz = 16000, + kSampleRate32kHz = 32000 + }; + + explicit AudioProcessingImpl(int id); + virtual ~AudioProcessingImpl(); + + CriticalSectionWrapper* crit() const; + + int split_sample_rate_hz() const; + bool was_stream_delay_set() const; + + // AudioProcessing methods. + virtual int Initialize(); + virtual int InitializeLocked(); + virtual int set_sample_rate_hz(int rate); + virtual int sample_rate_hz() const; + virtual int set_num_channels(int input_channels, int output_channels); + virtual int num_input_channels() const; + virtual int num_output_channels() const; + virtual int set_num_reverse_channels(int channels); + virtual int num_reverse_channels() const; + virtual int ProcessStream(AudioFrame* frame); + virtual int AnalyzeReverseStream(AudioFrame* frame); + virtual int set_stream_delay_ms(int delay); + virtual int stream_delay_ms() const; + virtual int StartDebugRecording(const char filename[kMaxFilenameSize]); + virtual int StopDebugRecording(); + virtual EchoCancellation* echo_cancellation() const; + virtual EchoControlMobile* echo_control_mobile() const; + virtual GainControl* gain_control() const; + virtual HighPassFilter* high_pass_filter() const; + virtual LevelEstimator* level_estimator() const; + virtual NoiseSuppression* noise_suppression() const; + virtual VoiceDetection* voice_detection() const; + + // Module methods. + virtual WebRtc_Word32 Version(WebRtc_Word8* version, + WebRtc_UWord32& remainingBufferInBytes, + WebRtc_UWord32& position) const; + virtual WebRtc_Word32 ChangeUniqueId(const WebRtc_Word32 id); + + private: + int WriteMessageToDebugFile(); + int WriteInitMessage(); + + int id_; + + EchoCancellationImpl* echo_cancellation_; + EchoControlMobileImpl* echo_control_mobile_; + GainControlImpl* gain_control_; + HighPassFilterImpl* high_pass_filter_; + LevelEstimatorImpl* level_estimator_; + NoiseSuppressionImpl* noise_suppression_; + VoiceDetectionImpl* voice_detection_; + + std::list component_list_; + + FileWrapper* debug_file_; + audioproc::Event* event_msg_; // Protobuf message. + std::string event_str_; // Memory for protobuf serialization. + CriticalSectionWrapper* crit_; + + AudioBuffer* render_audio_; + AudioBuffer* capture_audio_; + + int sample_rate_hz_; + int split_sample_rate_hz_; + int samples_per_channel_; + int stream_delay_ms_; + bool was_stream_delay_set_; + + int num_reverse_channels_; + int num_input_channels_; + int num_output_channels_; +}; +} // namespace webrtc + +#endif // WEBRTC_MODULES_AUDIO_PROCESSING_MAIN_SOURCE_AUDIO_PROCESSING_IMPL_H_ diff --git a/src/modules/audio_processing/main/source/debug.proto b/src/modules/audio_processing/main/source/debug.proto new file mode 100644 index 0000000..4b3a163 --- /dev/null +++ b/src/modules/audio_processing/main/source/debug.proto @@ -0,0 +1,37 @@ +syntax = "proto2"; +option optimize_for = LITE_RUNTIME; +package webrtc.audioproc; + +message Init { + optional int32 sample_rate = 1; + optional int32 device_sample_rate = 2; + optional int32 num_input_channels = 3; + optional int32 num_output_channels = 4; + optional int32 num_reverse_channels = 5; +} + +message ReverseStream { + optional bytes data = 1; +} + +message Stream { + optional bytes input_data = 1; + optional bytes output_data = 2; + optional int32 delay = 3; + optional sint32 drift = 4; + optional int32 level = 5; +} + +message Event { + enum Type { + INIT = 0; + REVERSE_STREAM = 1; + STREAM = 2; + } + + required Type type = 1; + + optional Init init = 2; + optional ReverseStream reverse_stream = 3; + optional Stream stream = 4; +} diff --git a/src/modules/audio_processing/main/source/echo_cancellation_impl.cc b/src/modules/audio_processing/main/source/echo_cancellation_impl.cc new file mode 100644 index 0000000..886d5f1 --- /dev/null +++ b/src/modules/audio_processing/main/source/echo_cancellation_impl.cc @@ -0,0 +1,348 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +#include "echo_cancellation_impl.h" + +#include +#include + +#include "critical_section_wrapper.h" +#include "echo_cancellation.h" + +#include "audio_processing_impl.h" +#include "audio_buffer.h" + +namespace webrtc { + +typedef void Handle; + +namespace { +WebRtc_Word16 MapSetting(EchoCancellation::SuppressionLevel level) { + switch (level) { + case EchoCancellation::kLowSuppression: + return kAecNlpConservative; + case EchoCancellation::kModerateSuppression: + return kAecNlpModerate; + case EchoCancellation::kHighSuppression: + return kAecNlpAggressive; + default: + return -1; + } +} + +int MapError(int err) { + switch (err) { + case AEC_UNSUPPORTED_FUNCTION_ERROR: + return AudioProcessing::kUnsupportedFunctionError; + break; + case AEC_BAD_PARAMETER_ERROR: + return AudioProcessing::kBadParameterError; + break; + case AEC_BAD_PARAMETER_WARNING: + return AudioProcessing::kBadStreamParameterWarning; + break; + default: + // AEC_UNSPECIFIED_ERROR + // AEC_UNINITIALIZED_ERROR + // AEC_NULL_POINTER_ERROR + return AudioProcessing::kUnspecifiedError; + } +} +} // namespace + +EchoCancellationImpl::EchoCancellationImpl(const AudioProcessingImpl* apm) + : ProcessingComponent(apm), + apm_(apm), + drift_compensation_enabled_(false), + metrics_enabled_(false), + suppression_level_(kModerateSuppression), + device_sample_rate_hz_(48000), + stream_drift_samples_(0), + was_stream_drift_set_(false), + stream_has_echo_(false) {} + +EchoCancellationImpl::~EchoCancellationImpl() {} + +int EchoCancellationImpl::ProcessRenderAudio(const AudioBuffer* audio) { + if (!is_component_enabled()) { + return apm_->kNoError; + } + + assert(audio->samples_per_split_channel() <= 160); + assert(audio->num_channels() == apm_->num_reverse_channels()); + + int err = apm_->kNoError; + + // The ordering convention must be followed to pass to the correct AEC. + size_t handle_index = 0; + for (int i = 0; i < apm_->num_output_channels(); i++) { + for (int j = 0; j < audio->num_channels(); j++) { + Handle* my_handle = static_cast(handle(handle_index)); + err = WebRtcAec_BufferFarend( + my_handle, + audio->low_pass_split_data(j), + static_cast(audio->samples_per_split_channel())); + + if (err != apm_->kNoError) { + return GetHandleError(my_handle); // TODO(ajm): warning possible? + } + + handle_index++; + } + } + + return apm_->kNoError; +} + +int EchoCancellationImpl::ProcessCaptureAudio(AudioBuffer* audio) { + if (!is_component_enabled()) { + return apm_->kNoError; + } + + if (!apm_->was_stream_delay_set()) { + return apm_->kStreamParameterNotSetError; + } + + if (drift_compensation_enabled_ && !was_stream_drift_set_) { + return apm_->kStreamParameterNotSetError; + } + + assert(audio->samples_per_split_channel() <= 160); + assert(audio->num_channels() == apm_->num_output_channels()); + + int err = apm_->kNoError; + + // The ordering convention must be followed to pass to the correct AEC. + size_t handle_index = 0; + stream_has_echo_ = false; + for (int i = 0; i < audio->num_channels(); i++) { + for (int j = 0; j < apm_->num_reverse_channels(); j++) { + Handle* my_handle = handle(handle_index); + err = WebRtcAec_Process( + my_handle, + audio->low_pass_split_data(i), + audio->high_pass_split_data(i), + audio->low_pass_split_data(i), + audio->high_pass_split_data(i), + static_cast(audio->samples_per_split_channel()), + apm_->stream_delay_ms(), + stream_drift_samples_); + + if (err != apm_->kNoError) { + err = GetHandleError(my_handle); + // TODO(ajm): Figure out how to return warnings properly. + if (err != apm_->kBadStreamParameterWarning) { + return err; + } + } + + WebRtc_Word16 status = 0; + err = WebRtcAec_get_echo_status(my_handle, &status); + if (err != apm_->kNoError) { + return GetHandleError(my_handle); + } + + if (status == 1) { + stream_has_echo_ = true; + } + + handle_index++; + } + } + + was_stream_drift_set_ = false; + return apm_->kNoError; +} + +int EchoCancellationImpl::Enable(bool enable) { + CriticalSectionScoped crit_scoped(*apm_->crit()); + // Ensure AEC and AECM are not both enabled. + if (enable && apm_->echo_control_mobile()->is_enabled()) { + return apm_->kBadParameterError; + } + + return EnableComponent(enable); +} + +bool EchoCancellationImpl::is_enabled() const { + return is_component_enabled(); +} + +int EchoCancellationImpl::set_suppression_level(SuppressionLevel level) { + CriticalSectionScoped crit_scoped(*apm_->crit()); + if (MapSetting(level) == -1) { + return apm_->kBadParameterError; + } + + suppression_level_ = level; + return Configure(); +} + +EchoCancellation::SuppressionLevel EchoCancellationImpl::suppression_level() + const { + return suppression_level_; +} + +int EchoCancellationImpl::enable_drift_compensation(bool enable) { + CriticalSectionScoped crit_scoped(*apm_->crit()); + drift_compensation_enabled_ = enable; + return Configure(); +} + +bool EchoCancellationImpl::is_drift_compensation_enabled() const { + return drift_compensation_enabled_; +} + +int EchoCancellationImpl::set_device_sample_rate_hz(int rate) { + CriticalSectionScoped crit_scoped(*apm_->crit()); + if (rate < 8000 || rate > 96000) { + return apm_->kBadParameterError; + } + + device_sample_rate_hz_ = rate; + return Initialize(); +} + +int EchoCancellationImpl::device_sample_rate_hz() const { + return device_sample_rate_hz_; +} + +int EchoCancellationImpl::set_stream_drift_samples(int drift) { + was_stream_drift_set_ = true; + stream_drift_samples_ = drift; + return apm_->kNoError; +} + +int EchoCancellationImpl::stream_drift_samples() const { + return stream_drift_samples_; +} + +int EchoCancellationImpl::enable_metrics(bool enable) { + CriticalSectionScoped crit_scoped(*apm_->crit()); + metrics_enabled_ = enable; + return Configure(); +} + +bool EchoCancellationImpl::are_metrics_enabled() const { + return metrics_enabled_; +} + +// TODO(ajm): we currently just use the metrics from the first AEC. Think more +// aboue the best way to extend this to multi-channel. +int EchoCancellationImpl::GetMetrics(Metrics* metrics) { + CriticalSectionScoped crit_scoped(*apm_->crit()); + if (metrics == NULL) { + return apm_->kNullPointerError; + } + + if (!is_component_enabled() || !metrics_enabled_) { + return apm_->kNotEnabledError; + } + + AecMetrics my_metrics; + memset(&my_metrics, 0, sizeof(my_metrics)); + memset(metrics, 0, sizeof(Metrics)); + + Handle* my_handle = static_cast(handle(0)); + int err = WebRtcAec_GetMetrics(my_handle, &my_metrics); + if (err != apm_->kNoError) { + return GetHandleError(my_handle); + } + + metrics->residual_echo_return_loss.instant = my_metrics.rerl.instant; + metrics->residual_echo_return_loss.average = my_metrics.rerl.average; + metrics->residual_echo_return_loss.maximum = my_metrics.rerl.max; + metrics->residual_echo_return_loss.minimum = my_metrics.rerl.min; + + metrics->echo_return_loss.instant = my_metrics.erl.instant; + metrics->echo_return_loss.average = my_metrics.erl.average; + metrics->echo_return_loss.maximum = my_metrics.erl.max; + metrics->echo_return_loss.minimum = my_metrics.erl.min; + + metrics->echo_return_loss_enhancement.instant = my_metrics.erle.instant; + metrics->echo_return_loss_enhancement.average = my_metrics.erle.average; + metrics->echo_return_loss_enhancement.maximum = my_metrics.erle.max; + metrics->echo_return_loss_enhancement.minimum = my_metrics.erle.min; + + metrics->a_nlp.instant = my_metrics.aNlp.instant; + metrics->a_nlp.average = my_metrics.aNlp.average; + metrics->a_nlp.maximum = my_metrics.aNlp.max; + metrics->a_nlp.minimum = my_metrics.aNlp.min; + + return apm_->kNoError; +} + +bool EchoCancellationImpl::stream_has_echo() const { + return stream_has_echo_; +} + +int EchoCancellationImpl::Initialize() { + int err = ProcessingComponent::Initialize(); + if (err != apm_->kNoError || !is_component_enabled()) { + return err; + } + + was_stream_drift_set_ = false; + + return apm_->kNoError; +} + +int EchoCancellationImpl::get_version(char* version, + int version_len_bytes) const { + if (WebRtcAec_get_version(version, version_len_bytes) != 0) { + return apm_->kBadParameterError; + } + + return apm_->kNoError; +} + +void* EchoCancellationImpl::CreateHandle() const { + Handle* handle = NULL; + if (WebRtcAec_Create(&handle) != apm_->kNoError) { + handle = NULL; + } else { + assert(handle != NULL); + } + + return handle; +} + +int EchoCancellationImpl::DestroyHandle(void* handle) const { + assert(handle != NULL); + return WebRtcAec_Free(static_cast(handle)); +} + +int EchoCancellationImpl::InitializeHandle(void* handle) const { + assert(handle != NULL); + return WebRtcAec_Init(static_cast(handle), + apm_->sample_rate_hz(), + device_sample_rate_hz_); +} + +int EchoCancellationImpl::ConfigureHandle(void* handle) const { + assert(handle != NULL); + AecConfig config; + config.metricsMode = metrics_enabled_; + config.nlpMode = MapSetting(suppression_level_); + config.skewMode = drift_compensation_enabled_; + + return WebRtcAec_set_config(static_cast(handle), config); +} + +int EchoCancellationImpl::num_handles_required() const { + return apm_->num_output_channels() * + apm_->num_reverse_channels(); +} + +int EchoCancellationImpl::GetHandleError(void* handle) const { + assert(handle != NULL); + return MapError(WebRtcAec_get_error_code(static_cast(handle))); +} +} // namespace webrtc diff --git a/src/modules/audio_processing/main/source/echo_cancellation_impl.h b/src/modules/audio_processing/main/source/echo_cancellation_impl.h new file mode 100644 index 0000000..071c18f --- /dev/null +++ b/src/modules/audio_processing/main/source/echo_cancellation_impl.h @@ -0,0 +1,72 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +#ifndef WEBRTC_MODULES_AUDIO_PROCESSING_MAIN_SOURCE_ECHO_CANCELLATION_IMPL_H_ +#define WEBRTC_MODULES_AUDIO_PROCESSING_MAIN_SOURCE_ECHO_CANCELLATION_IMPL_H_ + +#include "audio_processing.h" +#include "processing_component.h" + +namespace webrtc { +class AudioProcessingImpl; +class AudioBuffer; + +class EchoCancellationImpl : public EchoCancellation, + public ProcessingComponent { + public: + explicit EchoCancellationImpl(const AudioProcessingImpl* apm); + virtual ~EchoCancellationImpl(); + + int ProcessRenderAudio(const AudioBuffer* audio); + int ProcessCaptureAudio(AudioBuffer* audio); + + // EchoCancellation implementation. + virtual bool is_enabled() const; + virtual int device_sample_rate_hz() const; + virtual int stream_drift_samples() const; + + // ProcessingComponent implementation. + virtual int Initialize(); + virtual int get_version(char* version, int version_len_bytes) const; + + private: + // EchoCancellation implementation. + virtual int Enable(bool enable); + virtual int enable_drift_compensation(bool enable); + virtual bool is_drift_compensation_enabled() const; + virtual int set_device_sample_rate_hz(int rate); + virtual int set_stream_drift_samples(int drift); + virtual int set_suppression_level(SuppressionLevel level); + virtual SuppressionLevel suppression_level() const; + virtual int enable_metrics(bool enable); + virtual bool are_metrics_enabled() const; + virtual bool stream_has_echo() const; + virtual int GetMetrics(Metrics* metrics); + + // ProcessingComponent implementation. + virtual void* CreateHandle() const; + virtual int InitializeHandle(void* handle) const; + virtual int ConfigureHandle(void* handle) const; + virtual int DestroyHandle(void* handle) const; + virtual int num_handles_required() const; + virtual int GetHandleError(void* handle) const; + + const AudioProcessingImpl* apm_; + bool drift_compensation_enabled_; + bool metrics_enabled_; + SuppressionLevel suppression_level_; + int device_sample_rate_hz_; + int stream_drift_samples_; + bool was_stream_drift_set_; + bool stream_has_echo_; +}; +} // namespace webrtc + +#endif // WEBRTC_MODULES_AUDIO_PROCESSING_MAIN_SOURCE_ECHO_CANCELLATION_IMPL_H_ diff --git a/src/modules/audio_processing/main/source/echo_control_mobile_impl.cc b/src/modules/audio_processing/main/source/echo_control_mobile_impl.cc new file mode 100644 index 0000000..ff15255 --- /dev/null +++ b/src/modules/audio_processing/main/source/echo_control_mobile_impl.cc @@ -0,0 +1,309 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +#include "echo_control_mobile_impl.h" + +#include +#include + +#include "critical_section_wrapper.h" +#include "echo_control_mobile.h" + +#include "audio_processing_impl.h" +#include "audio_buffer.h" + +namespace webrtc { + +typedef void Handle; + +namespace { +WebRtc_Word16 MapSetting(EchoControlMobile::RoutingMode mode) { + switch (mode) { + case EchoControlMobile::kQuietEarpieceOrHeadset: + return 0; + case EchoControlMobile::kEarpiece: + return 1; + case EchoControlMobile::kLoudEarpiece: + return 2; + case EchoControlMobile::kSpeakerphone: + return 3; + case EchoControlMobile::kLoudSpeakerphone: + return 4; + default: + return -1; + } +} + +int MapError(int err) { + switch (err) { + case AECM_UNSUPPORTED_FUNCTION_ERROR: + return AudioProcessing::kUnsupportedFunctionError; + case AECM_NULL_POINTER_ERROR: + return AudioProcessing::kNullPointerError; + case AECM_BAD_PARAMETER_ERROR: + return AudioProcessing::kBadParameterError; + case AECM_BAD_PARAMETER_WARNING: + return AudioProcessing::kBadStreamParameterWarning; + default: + // AECM_UNSPECIFIED_ERROR + // AECM_UNINITIALIZED_ERROR + return AudioProcessing::kUnspecifiedError; + } +} +} // namespace + +size_t EchoControlMobile::echo_path_size_bytes() { + return WebRtcAecm_echo_path_size_bytes(); +} + +EchoControlMobileImpl::EchoControlMobileImpl(const AudioProcessingImpl* apm) + : ProcessingComponent(apm), + apm_(apm), + routing_mode_(kSpeakerphone), + comfort_noise_enabled_(true), + external_echo_path_(NULL) {} + +EchoControlMobileImpl::~EchoControlMobileImpl() { + if (external_echo_path_ != NULL) { + delete [] external_echo_path_; + external_echo_path_ = NULL; + } +} + +int EchoControlMobileImpl::ProcessRenderAudio(const AudioBuffer* audio) { + if (!is_component_enabled()) { + return apm_->kNoError; + } + + assert(audio->samples_per_split_channel() <= 160); + assert(audio->num_channels() == apm_->num_reverse_channels()); + + int err = apm_->kNoError; + + // The ordering convention must be followed to pass to the correct AECM. + size_t handle_index = 0; + for (int i = 0; i < apm_->num_output_channels(); i++) { + for (int j = 0; j < audio->num_channels(); j++) { + Handle* my_handle = static_cast(handle(handle_index)); + err = WebRtcAecm_BufferFarend( + my_handle, + audio->low_pass_split_data(j), + static_cast(audio->samples_per_split_channel())); + + if (err != apm_->kNoError) { + return GetHandleError(my_handle); // TODO(ajm): warning possible? + } + + handle_index++; + } + } + + return apm_->kNoError; +} + +int EchoControlMobileImpl::ProcessCaptureAudio(AudioBuffer* audio) { + if (!is_component_enabled()) { + return apm_->kNoError; + } + + if (!apm_->was_stream_delay_set()) { + return apm_->kStreamParameterNotSetError; + } + + assert(audio->samples_per_split_channel() <= 160); + assert(audio->num_channels() == apm_->num_output_channels()); + + int err = apm_->kNoError; + + // The ordering convention must be followed to pass to the correct AECM. + size_t handle_index = 0; + for (int i = 0; i < audio->num_channels(); i++) { + // TODO(ajm): improve how this works, possibly inside AECM. + // This is kind of hacked up. + WebRtc_Word16* noisy = audio->low_pass_reference(i); + WebRtc_Word16* clean = audio->low_pass_split_data(i); + if (noisy == NULL) { + noisy = clean; + clean = NULL; + } + for (int j = 0; j < apm_->num_reverse_channels(); j++) { + Handle* my_handle = static_cast(handle(handle_index)); + err = WebRtcAecm_Process( + my_handle, + noisy, + clean, + audio->low_pass_split_data(i), + static_cast(audio->samples_per_split_channel()), + apm_->stream_delay_ms()); + + if (err != apm_->kNoError) { + return GetHandleError(my_handle); // TODO(ajm): warning possible? + } + + handle_index++; + } + } + + return apm_->kNoError; +} + +int EchoControlMobileImpl::Enable(bool enable) { + CriticalSectionScoped crit_scoped(*apm_->crit()); + // Ensure AEC and AECM are not both enabled. + if (enable && apm_->echo_cancellation()->is_enabled()) { + return apm_->kBadParameterError; + } + + return EnableComponent(enable); +} + +bool EchoControlMobileImpl::is_enabled() const { + return is_component_enabled(); +} + +int EchoControlMobileImpl::set_routing_mode(RoutingMode mode) { + CriticalSectionScoped crit_scoped(*apm_->crit()); + if (MapSetting(mode) == -1) { + return apm_->kBadParameterError; + } + + routing_mode_ = mode; + return Configure(); +} + +EchoControlMobile::RoutingMode EchoControlMobileImpl::routing_mode() + const { + return routing_mode_; +} + +int EchoControlMobileImpl::enable_comfort_noise(bool enable) { + CriticalSectionScoped crit_scoped(*apm_->crit()); + comfort_noise_enabled_ = enable; + return Configure(); +} + +bool EchoControlMobileImpl::is_comfort_noise_enabled() const { + return comfort_noise_enabled_; +} + +int EchoControlMobileImpl::SetEchoPath(const void* echo_path, + size_t size_bytes) { + CriticalSectionScoped crit_scoped(*apm_->crit()); + if (echo_path == NULL) { + return apm_->kNullPointerError; + } + if (size_bytes != echo_path_size_bytes()) { + // Size mismatch + return apm_->kBadParameterError; + } + + if (external_echo_path_ == NULL) { + external_echo_path_ = new unsigned char[size_bytes]; + } + memcpy(external_echo_path_, echo_path, size_bytes); + + return Initialize(); +} + +int EchoControlMobileImpl::GetEchoPath(void* echo_path, + size_t size_bytes) const { + CriticalSectionScoped crit_scoped(*apm_->crit()); + if (echo_path == NULL) { + return apm_->kNullPointerError; + } + if (size_bytes != echo_path_size_bytes()) { + // Size mismatch + return apm_->kBadParameterError; + } + if (!is_component_enabled()) { + return apm_->kNotEnabledError; + } + + // Get the echo path from the first channel + Handle* my_handle = static_cast(handle(0)); + if (WebRtcAecm_GetEchoPath(my_handle, echo_path, size_bytes) != 0) { + return GetHandleError(my_handle); + } + + return apm_->kNoError; +} + +int EchoControlMobileImpl::Initialize() { + if (!is_component_enabled()) { + return apm_->kNoError; + } + + if (apm_->sample_rate_hz() == apm_->kSampleRate32kHz) { + // AECM doesn't support super-wideband. + return apm_->kBadSampleRateError; + } + + return ProcessingComponent::Initialize(); +} + +int EchoControlMobileImpl::get_version(char* version, + int version_len_bytes) const { + if (WebRtcAecm_get_version(version, version_len_bytes) != 0) { + return apm_->kBadParameterError; + } + + return apm_->kNoError; +} + +void* EchoControlMobileImpl::CreateHandle() const { + Handle* handle = NULL; + if (WebRtcAecm_Create(&handle) != apm_->kNoError) { + handle = NULL; + } else { + assert(handle != NULL); + } + + return handle; +} + +int EchoControlMobileImpl::DestroyHandle(void* handle) const { + return WebRtcAecm_Free(static_cast(handle)); +} + +int EchoControlMobileImpl::InitializeHandle(void* handle) const { + assert(handle != NULL); + Handle* my_handle = static_cast(handle); + if (WebRtcAecm_Init(my_handle, apm_->sample_rate_hz()) != 0) { + return GetHandleError(my_handle); + } + if (external_echo_path_ != NULL) { + if (WebRtcAecm_InitEchoPath(my_handle, + external_echo_path_, + echo_path_size_bytes()) != 0) { + return GetHandleError(my_handle); + } + } + + return apm_->kNoError; +} + +int EchoControlMobileImpl::ConfigureHandle(void* handle) const { + AecmConfig config; + config.cngMode = comfort_noise_enabled_; + config.echoMode = MapSetting(routing_mode_); + + return WebRtcAecm_set_config(static_cast(handle), config); +} + +int EchoControlMobileImpl::num_handles_required() const { + return apm_->num_output_channels() * + apm_->num_reverse_channels(); +} + +int EchoControlMobileImpl::GetHandleError(void* handle) const { + assert(handle != NULL); + return MapError(WebRtcAecm_get_error_code(static_cast(handle))); +} +} // namespace webrtc diff --git a/src/modules/audio_processing/main/source/echo_control_mobile_impl.h b/src/modules/audio_processing/main/source/echo_control_mobile_impl.h new file mode 100644 index 0000000..6314e66 --- /dev/null +++ b/src/modules/audio_processing/main/source/echo_control_mobile_impl.h @@ -0,0 +1,62 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +#ifndef WEBRTC_MODULES_AUDIO_PROCESSING_MAIN_SOURCE_ECHO_CONTROL_MOBILE_IMPL_H_ +#define WEBRTC_MODULES_AUDIO_PROCESSING_MAIN_SOURCE_ECHO_CONTROL_MOBILE_IMPL_H_ + +#include "audio_processing.h" +#include "processing_component.h" + +namespace webrtc { +class AudioProcessingImpl; +class AudioBuffer; + +class EchoControlMobileImpl : public EchoControlMobile, + public ProcessingComponent { + public: + explicit EchoControlMobileImpl(const AudioProcessingImpl* apm); + virtual ~EchoControlMobileImpl(); + + int ProcessRenderAudio(const AudioBuffer* audio); + int ProcessCaptureAudio(AudioBuffer* audio); + + // EchoControlMobile implementation. + virtual bool is_enabled() const; + + // ProcessingComponent implementation. + virtual int Initialize(); + virtual int get_version(char* version, int version_len_bytes) const; + + private: + // EchoControlMobile implementation. + virtual int Enable(bool enable); + virtual int set_routing_mode(RoutingMode mode); + virtual RoutingMode routing_mode() const; + virtual int enable_comfort_noise(bool enable); + virtual bool is_comfort_noise_enabled() const; + virtual int SetEchoPath(const void* echo_path, size_t size_bytes); + virtual int GetEchoPath(void* echo_path, size_t size_bytes) const; + + // ProcessingComponent implementation. + virtual void* CreateHandle() const; + virtual int InitializeHandle(void* handle) const; + virtual int ConfigureHandle(void* handle) const; + virtual int DestroyHandle(void* handle) const; + virtual int num_handles_required() const; + virtual int GetHandleError(void* handle) const; + + const AudioProcessingImpl* apm_; + RoutingMode routing_mode_; + bool comfort_noise_enabled_; + unsigned char* external_echo_path_; +}; +} // namespace webrtc + +#endif // WEBRTC_MODULES_AUDIO_PROCESSING_MAIN_SOURCE_ECHO_CONTROL_MOBILE_IMPL_H_ diff --git a/src/modules/audio_processing/main/source/gain_control_impl.cc b/src/modules/audio_processing/main/source/gain_control_impl.cc new file mode 100644 index 0000000..dc3e565 --- /dev/null +++ b/src/modules/audio_processing/main/source/gain_control_impl.cc @@ -0,0 +1,391 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +#include "gain_control_impl.h" + +#include + +#include "critical_section_wrapper.h" +#include "gain_control.h" + +#include "audio_processing_impl.h" +#include "audio_buffer.h" + +namespace webrtc { + +typedef void Handle; + +/*template +class GainControlHandle : public ComponentHandle { + public: + GainControlHandle(); + virtual ~GainControlHandle(); + + virtual int Create(); + virtual T* ptr() const; + + private: + T* handle; +};*/ + +namespace { +WebRtc_Word16 MapSetting(GainControl::Mode mode) { + switch (mode) { + case GainControl::kAdaptiveAnalog: + return kAgcModeAdaptiveAnalog; + break; + case GainControl::kAdaptiveDigital: + return kAgcModeAdaptiveDigital; + break; + case GainControl::kFixedDigital: + return kAgcModeFixedDigital; + break; + default: + return -1; + } +} +} // namespace + +GainControlImpl::GainControlImpl(const AudioProcessingImpl* apm) + : ProcessingComponent(apm), + apm_(apm), + mode_(kAdaptiveAnalog), + minimum_capture_level_(0), + maximum_capture_level_(255), + limiter_enabled_(true), + target_level_dbfs_(3), + compression_gain_db_(9), + analog_capture_level_(0), + was_analog_level_set_(false), + stream_is_saturated_(false) {} + +GainControlImpl::~GainControlImpl() {} + +int GainControlImpl::ProcessRenderAudio(AudioBuffer* audio) { + if (!is_component_enabled()) { + return apm_->kNoError; + } + + assert(audio->samples_per_split_channel() <= 160); + + WebRtc_Word16* mixed_data = audio->low_pass_split_data(0); + if (audio->num_channels() > 1) { + audio->CopyAndMixLowPass(1); + mixed_data = audio->mixed_low_pass_data(0); + } + + for (int i = 0; i < num_handles(); i++) { + Handle* my_handle = static_cast(handle(i)); + int err = WebRtcAgc_AddFarend( + my_handle, + mixed_data, + static_cast(audio->samples_per_split_channel())); + + if (err != apm_->kNoError) { + return GetHandleError(my_handle); + } + } + + return apm_->kNoError; +} + +int GainControlImpl::AnalyzeCaptureAudio(AudioBuffer* audio) { + if (!is_component_enabled()) { + return apm_->kNoError; + } + + assert(audio->samples_per_split_channel() <= 160); + assert(audio->num_channels() == num_handles()); + + int err = apm_->kNoError; + + if (mode_ == kAdaptiveAnalog) { + for (int i = 0; i < num_handles(); i++) { + Handle* my_handle = static_cast(handle(i)); + err = WebRtcAgc_AddMic( + my_handle, + audio->low_pass_split_data(i), + audio->high_pass_split_data(i), + static_cast(audio->samples_per_split_channel())); + + if (err != apm_->kNoError) { + return GetHandleError(my_handle); + } + } + } else if (mode_ == kAdaptiveDigital) { + + for (int i = 0; i < num_handles(); i++) { + Handle* my_handle = static_cast(handle(i)); + WebRtc_Word32 capture_level_out = 0; + + err = WebRtcAgc_VirtualMic( + my_handle, + audio->low_pass_split_data(i), + audio->high_pass_split_data(i), + static_cast(audio->samples_per_split_channel()), + //capture_levels_[i], + analog_capture_level_, + &capture_level_out); + + capture_levels_[i] = capture_level_out; + + if (err != apm_->kNoError) { + return GetHandleError(my_handle); + } + + } + } + + return apm_->kNoError; +} + +int GainControlImpl::ProcessCaptureAudio(AudioBuffer* audio) { + if (!is_component_enabled()) { + return apm_->kNoError; + } + + if (mode_ == kAdaptiveAnalog && !was_analog_level_set_) { + return apm_->kStreamParameterNotSetError; + } + + assert(audio->samples_per_split_channel() <= 160); + assert(audio->num_channels() == num_handles()); + + stream_is_saturated_ = false; + for (int i = 0; i < num_handles(); i++) { + Handle* my_handle = static_cast(handle(i)); + WebRtc_Word32 capture_level_out = 0; + WebRtc_UWord8 saturation_warning = 0; + + int err = WebRtcAgc_Process( + my_handle, + audio->low_pass_split_data(i), + audio->high_pass_split_data(i), + static_cast(audio->samples_per_split_channel()), + audio->low_pass_split_data(i), + audio->high_pass_split_data(i), + capture_levels_[i], + &capture_level_out, + apm_->echo_cancellation()->stream_has_echo(), + &saturation_warning); + + if (err != apm_->kNoError) { + return GetHandleError(my_handle); + } + + capture_levels_[i] = capture_level_out; + if (saturation_warning == 1) { + stream_is_saturated_ = true; + } + } + + if (mode_ == kAdaptiveAnalog) { + // Take the analog level to be the average across the handles. + analog_capture_level_ = 0; + for (int i = 0; i < num_handles(); i++) { + analog_capture_level_ += capture_levels_[i]; + } + + analog_capture_level_ /= num_handles(); + } + + was_analog_level_set_ = false; + return apm_->kNoError; +} + +// TODO(ajm): ensure this is called under kAdaptiveAnalog. +int GainControlImpl::set_stream_analog_level(int level) { + was_analog_level_set_ = true; + if (level < minimum_capture_level_ || level > maximum_capture_level_) { + return apm_->kBadParameterError; + } + + if (mode_ == kAdaptiveAnalog) { + if (level != analog_capture_level_) { + // The analog level has been changed; update our internal levels. + capture_levels_.assign(num_handles(), level); + } + } + analog_capture_level_ = level; + + return apm_->kNoError; +} + +int GainControlImpl::stream_analog_level() { + // TODO(ajm): enable this assertion? + //assert(mode_ == kAdaptiveAnalog); + + return analog_capture_level_; +} + +int GainControlImpl::Enable(bool enable) { + CriticalSectionScoped crit_scoped(*apm_->crit()); + return EnableComponent(enable); +} + +bool GainControlImpl::is_enabled() const { + return is_component_enabled(); +} + +int GainControlImpl::set_mode(Mode mode) { + CriticalSectionScoped crit_scoped(*apm_->crit()); + if (MapSetting(mode) == -1) { + return apm_->kBadParameterError; + } + + mode_ = mode; + return Initialize(); +} + +GainControl::Mode GainControlImpl::mode() const { + return mode_; +} + +int GainControlImpl::set_analog_level_limits(int minimum, + int maximum) { + CriticalSectionScoped crit_scoped(*apm_->crit()); + if (minimum < 0) { + return apm_->kBadParameterError; + } + + if (maximum > 65535) { + return apm_->kBadParameterError; + } + + if (maximum < minimum) { + return apm_->kBadParameterError; + } + + minimum_capture_level_ = minimum; + maximum_capture_level_ = maximum; + + return Initialize(); +} + +int GainControlImpl::analog_level_minimum() const { + return minimum_capture_level_; +} + +int GainControlImpl::analog_level_maximum() const { + return maximum_capture_level_; +} + +bool GainControlImpl::stream_is_saturated() const { + return stream_is_saturated_; +} + +int GainControlImpl::set_target_level_dbfs(int level) { + CriticalSectionScoped crit_scoped(*apm_->crit()); + if (level > 31 || level < 0) { + return apm_->kBadParameterError; + } + + target_level_dbfs_ = level; + return Configure(); +} + +int GainControlImpl::target_level_dbfs() const { + return target_level_dbfs_; +} + +int GainControlImpl::set_compression_gain_db(int gain) { + CriticalSectionScoped crit_scoped(*apm_->crit()); + if (gain < 0 || gain > 90) { + return apm_->kBadParameterError; + } + + compression_gain_db_ = gain; + return Configure(); +} + +int GainControlImpl::compression_gain_db() const { + return compression_gain_db_; +} + +int GainControlImpl::enable_limiter(bool enable) { + CriticalSectionScoped crit_scoped(*apm_->crit()); + limiter_enabled_ = enable; + return Configure(); +} + +bool GainControlImpl::is_limiter_enabled() const { + return limiter_enabled_; +} + +int GainControlImpl::Initialize() { + int err = ProcessingComponent::Initialize(); + if (err != apm_->kNoError || !is_component_enabled()) { + return err; + } + + analog_capture_level_ = + (maximum_capture_level_ - minimum_capture_level_) >> 1; + capture_levels_.assign(num_handles(), analog_capture_level_); + was_analog_level_set_ = false; + + return apm_->kNoError; +} + +int GainControlImpl::get_version(char* version, int version_len_bytes) const { + if (WebRtcAgc_Version(version, version_len_bytes) != 0) { + return apm_->kBadParameterError; + } + + return apm_->kNoError; +} + +void* GainControlImpl::CreateHandle() const { + Handle* handle = NULL; + if (WebRtcAgc_Create(&handle) != apm_->kNoError) { + handle = NULL; + } else { + assert(handle != NULL); + } + + return handle; +} + +int GainControlImpl::DestroyHandle(void* handle) const { + return WebRtcAgc_Free(static_cast(handle)); +} + +int GainControlImpl::InitializeHandle(void* handle) const { + return WebRtcAgc_Init(static_cast(handle), + minimum_capture_level_, + maximum_capture_level_, + MapSetting(mode_), + apm_->sample_rate_hz()); +} + +int GainControlImpl::ConfigureHandle(void* handle) const { + WebRtcAgc_config_t config; + // TODO(ajm): Flip the sign here (since AGC expects a positive value) if we + // change the interface. + //assert(target_level_dbfs_ <= 0); + //config.targetLevelDbfs = static_cast(-target_level_dbfs_); + config.targetLevelDbfs = static_cast(target_level_dbfs_); + config.compressionGaindB = + static_cast(compression_gain_db_); + config.limiterEnable = limiter_enabled_; + + return WebRtcAgc_set_config(static_cast(handle), config); +} + +int GainControlImpl::num_handles_required() const { + return apm_->num_output_channels(); +} + +int GainControlImpl::GetHandleError(void* handle) const { + // The AGC has no get_error() function. + // (Despite listing errors in its interface...) + assert(handle != NULL); + return apm_->kUnspecifiedError; +} +} // namespace webrtc diff --git a/src/modules/audio_processing/main/source/gain_control_impl.h b/src/modules/audio_processing/main/source/gain_control_impl.h new file mode 100644 index 0000000..7b6987e --- /dev/null +++ b/src/modules/audio_processing/main/source/gain_control_impl.h @@ -0,0 +1,80 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +#ifndef WEBRTC_MODULES_AUDIO_PROCESSING_MAIN_SOURCE_GAIN_CONTROL_IMPL_H_ +#define WEBRTC_MODULES_AUDIO_PROCESSING_MAIN_SOURCE_GAIN_CONTROL_IMPL_H_ + +#include + +#include "audio_processing.h" +#include "processing_component.h" + +namespace webrtc { +class AudioProcessingImpl; +class AudioBuffer; + +class GainControlImpl : public GainControl, + public ProcessingComponent { + public: + explicit GainControlImpl(const AudioProcessingImpl* apm); + virtual ~GainControlImpl(); + + int ProcessRenderAudio(AudioBuffer* audio); + int AnalyzeCaptureAudio(AudioBuffer* audio); + int ProcessCaptureAudio(AudioBuffer* audio); + + // ProcessingComponent implementation. + virtual int Initialize(); + virtual int get_version(char* version, int version_len_bytes) const; + + // GainControl implementation. + virtual bool is_enabled() const; + virtual int stream_analog_level(); + + private: + // GainControl implementation. + virtual int Enable(bool enable); + virtual int set_stream_analog_level(int level); + virtual int set_mode(Mode mode); + virtual Mode mode() const; + virtual int set_target_level_dbfs(int level); + virtual int target_level_dbfs() const; + virtual int set_compression_gain_db(int gain); + virtual int compression_gain_db() const; + virtual int enable_limiter(bool enable); + virtual bool is_limiter_enabled() const; + virtual int set_analog_level_limits(int minimum, int maximum); + virtual int analog_level_minimum() const; + virtual int analog_level_maximum() const; + virtual bool stream_is_saturated() const; + + // ProcessingComponent implementation. + virtual void* CreateHandle() const; + virtual int InitializeHandle(void* handle) const; + virtual int ConfigureHandle(void* handle) const; + virtual int DestroyHandle(void* handle) const; + virtual int num_handles_required() const; + virtual int GetHandleError(void* handle) const; + + const AudioProcessingImpl* apm_; + Mode mode_; + int minimum_capture_level_; + int maximum_capture_level_; + bool limiter_enabled_; + int target_level_dbfs_; + int compression_gain_db_; + std::vector capture_levels_; + int analog_capture_level_; + bool was_analog_level_set_; + bool stream_is_saturated_; +}; +} // namespace webrtc + +#endif // WEBRTC_MODULES_AUDIO_PROCESSING_MAIN_SOURCE_GAIN_CONTROL_IMPL_H_ diff --git a/src/modules/audio_processing/main/source/high_pass_filter_impl.cc b/src/modules/audio_processing/main/source/high_pass_filter_impl.cc new file mode 100644 index 0000000..fa6d5d5 --- /dev/null +++ b/src/modules/audio_processing/main/source/high_pass_filter_impl.cc @@ -0,0 +1,180 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +#include "high_pass_filter_impl.h" + +#include + +#include "critical_section_wrapper.h" +#include "typedefs.h" +#include "signal_processing_library.h" + +#include "audio_processing_impl.h" +#include "audio_buffer.h" + +namespace webrtc { +namespace { +const WebRtc_Word16 kFilterCoefficients8kHz[5] = + {3798, -7596, 3798, 7807, -3733}; + +const WebRtc_Word16 kFilterCoefficients[5] = + {4012, -8024, 4012, 8002, -3913}; + +struct FilterState { + WebRtc_Word16 y[4]; + WebRtc_Word16 x[2]; + const WebRtc_Word16* ba; +}; + +int InitializeFilter(FilterState* hpf, int sample_rate_hz) { + assert(hpf != NULL); + + if (sample_rate_hz == AudioProcessingImpl::kSampleRate8kHz) { + hpf->ba = kFilterCoefficients8kHz; + } else { + hpf->ba = kFilterCoefficients; + } + + WebRtcSpl_MemSetW16(hpf->x, 0, 2); + WebRtcSpl_MemSetW16(hpf->y, 0, 4); + + return AudioProcessing::kNoError; +} + +int Filter(FilterState* hpf, WebRtc_Word16* data, int length) { + assert(hpf != NULL); + + WebRtc_Word32 tmp_int32 = 0; + WebRtc_Word16* y = hpf->y; + WebRtc_Word16* x = hpf->x; + const WebRtc_Word16* ba = hpf->ba; + + for (int i = 0; i < length; i++) { + // y[i] = b[0] * x[i] + b[1] * x[i-1] + b[2] * x[i-2] + // + -a[1] * y[i-1] + -a[2] * y[i-2]; + + tmp_int32 = + WEBRTC_SPL_MUL_16_16(y[1], ba[3]); // -a[1] * y[i-1] (low part) + tmp_int32 += + WEBRTC_SPL_MUL_16_16(y[3], ba[4]); // -a[2] * y[i-2] (low part) + tmp_int32 = (tmp_int32 >> 15); + tmp_int32 += + WEBRTC_SPL_MUL_16_16(y[0], ba[3]); // -a[1] * y[i-1] (high part) + tmp_int32 += + WEBRTC_SPL_MUL_16_16(y[2], ba[4]); // -a[2] * y[i-2] (high part) + tmp_int32 = (tmp_int32 << 1); + + tmp_int32 += WEBRTC_SPL_MUL_16_16(data[i], ba[0]); // b[0]*x[0] + tmp_int32 += WEBRTC_SPL_MUL_16_16(x[0], ba[1]); // b[1]*x[i-1] + tmp_int32 += WEBRTC_SPL_MUL_16_16(x[1], ba[2]); // b[2]*x[i-2] + + // Update state (input part) + x[1] = x[0]; + x[0] = data[i]; + + // Update state (filtered part) + y[2] = y[0]; + y[3] = y[1]; + y[0] = static_cast(tmp_int32 >> 13); + y[1] = static_cast((tmp_int32 - + WEBRTC_SPL_LSHIFT_W32(static_cast(y[0]), 13)) << 2); + + // Rounding in Q12, i.e. add 2^11 + tmp_int32 += 2048; + + // Saturate (to 2^27) so that the HP filtered signal does not overflow + tmp_int32 = WEBRTC_SPL_SAT(static_cast(134217727), + tmp_int32, + static_cast(-134217728)); + + // Convert back to Q0 and use rounding + data[i] = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32(tmp_int32, 12); + + } + + return AudioProcessing::kNoError; +} +} // namespace + +typedef FilterState Handle; + +HighPassFilterImpl::HighPassFilterImpl(const AudioProcessingImpl* apm) + : ProcessingComponent(apm), + apm_(apm) {} + +HighPassFilterImpl::~HighPassFilterImpl() {} + +int HighPassFilterImpl::ProcessCaptureAudio(AudioBuffer* audio) { + int err = apm_->kNoError; + + if (!is_component_enabled()) { + return apm_->kNoError; + } + + assert(audio->samples_per_split_channel() <= 160); + + for (int i = 0; i < num_handles(); i++) { + Handle* my_handle = static_cast(handle(i)); + err = Filter(my_handle, + audio->low_pass_split_data(i), + audio->samples_per_split_channel()); + + if (err != apm_->kNoError) { + return GetHandleError(my_handle); + } + } + + return apm_->kNoError; +} + +int HighPassFilterImpl::Enable(bool enable) { + CriticalSectionScoped crit_scoped(*apm_->crit()); + return EnableComponent(enable); +} + +bool HighPassFilterImpl::is_enabled() const { + return is_component_enabled(); +} + +int HighPassFilterImpl::get_version(char* version, + int version_len_bytes) const { + // An empty string is used to indicate no version information. + memset(version, 0, version_len_bytes); + return apm_->kNoError; +} + +void* HighPassFilterImpl::CreateHandle() const { + return new FilterState; +} + +int HighPassFilterImpl::DestroyHandle(void* handle) const { + delete static_cast(handle); + return apm_->kNoError; +} + +int HighPassFilterImpl::InitializeHandle(void* handle) const { + return InitializeFilter(static_cast(handle), + apm_->sample_rate_hz()); +} + +int HighPassFilterImpl::ConfigureHandle(void* /*handle*/) const { + return apm_->kNoError; // Not configurable. +} + +int HighPassFilterImpl::num_handles_required() const { + return apm_->num_output_channels(); +} + +int HighPassFilterImpl::GetHandleError(void* handle) const { + // The component has no detailed errors. + assert(handle != NULL); + return apm_->kUnspecifiedError; +} +} // namespace webrtc diff --git a/src/modules/audio_processing/main/source/high_pass_filter_impl.h b/src/modules/audio_processing/main/source/high_pass_filter_impl.h new file mode 100644 index 0000000..4c23754 --- /dev/null +++ b/src/modules/audio_processing/main/source/high_pass_filter_impl.h @@ -0,0 +1,51 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +#ifndef WEBRTC_MODULES_AUDIO_PROCESSING_MAIN_SOURCE_HIGH_PASS_FILTER_IMPL_H_ +#define WEBRTC_MODULES_AUDIO_PROCESSING_MAIN_SOURCE_HIGH_PASS_FILTER_IMPL_H_ + +#include "audio_processing.h" +#include "processing_component.h" + +namespace webrtc { +class AudioProcessingImpl; +class AudioBuffer; + +class HighPassFilterImpl : public HighPassFilter, + public ProcessingComponent { + public: + explicit HighPassFilterImpl(const AudioProcessingImpl* apm); + virtual ~HighPassFilterImpl(); + + int ProcessCaptureAudio(AudioBuffer* audio); + + // HighPassFilter implementation. + virtual bool is_enabled() const; + + // ProcessingComponent implementation. + virtual int get_version(char* version, int version_len_bytes) const; + + private: + // HighPassFilter implementation. + virtual int Enable(bool enable); + + // ProcessingComponent implementation. + virtual void* CreateHandle() const; + virtual int InitializeHandle(void* handle) const; + virtual int ConfigureHandle(void* handle) const; + virtual int DestroyHandle(void* handle) const; + virtual int num_handles_required() const; + virtual int GetHandleError(void* handle) const; + + const AudioProcessingImpl* apm_; +}; +} // namespace webrtc + +#endif // WEBRTC_MODULES_AUDIO_PROCESSING_MAIN_SOURCE_HIGH_PASS_FILTER_IMPL_H_ diff --git a/src/modules/audio_processing/main/source/level_estimator_impl.cc b/src/modules/audio_processing/main/source/level_estimator_impl.cc new file mode 100644 index 0000000..799a962 --- /dev/null +++ b/src/modules/audio_processing/main/source/level_estimator_impl.cc @@ -0,0 +1,182 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +#include "level_estimator_impl.h" + +#include +#include + +#include "critical_section_wrapper.h" + +#include "audio_processing_impl.h" +#include "audio_buffer.h" + +// TODO(ajm): implement the underlying level estimator component. + +namespace webrtc { + +typedef void Handle; + +namespace { +/*int EstimateLevel(AudioBuffer* audio, Handle* my_handle) { + assert(audio->samples_per_split_channel() <= 160); + + WebRtc_Word16* mixed_data = audio->low_pass_split_data(0); + if (audio->num_channels() > 1) { + audio->CopyAndMixLowPass(1); + mixed_data = audio->mixed_low_pass_data(0); + } + + int err = UpdateLvlEst(my_handle, + mixed_data, + audio->samples_per_split_channel()); + if (err != AudioProcessing::kNoError) { + return GetHandleError(my_handle); + } + + return AudioProcessing::kNoError; +} + +int GetMetricsLocal(Handle* my_handle, LevelEstimator::Metrics* metrics) { + level_t levels; + memset(&levels, 0, sizeof(levels)); + + int err = ExportLevels(my_handle, &levels, 2); + if (err != AudioProcessing::kNoError) { + return err; + } + metrics->signal.instant = levels.instant; + metrics->signal.average = levels.average; + metrics->signal.maximum = levels.max; + metrics->signal.minimum = levels.min; + + err = ExportLevels(my_handle, &levels, 1); + if (err != AudioProcessing::kNoError) { + return err; + } + metrics->speech.instant = levels.instant; + metrics->speech.average = levels.average; + metrics->speech.maximum = levels.max; + metrics->speech.minimum = levels.min; + + err = ExportLevels(my_handle, &levels, 0); + if (err != AudioProcessing::kNoError) { + return err; + } + metrics->noise.instant = levels.instant; + metrics->noise.average = levels.average; + metrics->noise.maximum = levels.max; + metrics->noise.minimum = levels.min; + + return AudioProcessing::kNoError; +}*/ +} // namespace + +LevelEstimatorImpl::LevelEstimatorImpl(const AudioProcessingImpl* apm) + : ProcessingComponent(apm), + apm_(apm) {} + +LevelEstimatorImpl::~LevelEstimatorImpl() {} + +int LevelEstimatorImpl::AnalyzeReverseStream(AudioBuffer* /*audio*/) { + return apm_->kUnsupportedComponentError; + /*if (!is_component_enabled()) { + return apm_->kNoError; + } + + return EstimateLevel(audio, static_cast(handle(1)));*/ +} + +int LevelEstimatorImpl::ProcessCaptureAudio(AudioBuffer* /*audio*/) { + return apm_->kUnsupportedComponentError; + /*if (!is_component_enabled()) { + return apm_->kNoError; + } + + return EstimateLevel(audio, static_cast(handle(0)));*/ +} + +int LevelEstimatorImpl::Enable(bool /*enable*/) { + CriticalSectionScoped crit_scoped(*apm_->crit()); + return apm_->kUnsupportedComponentError; + //return EnableComponent(enable); +} + +bool LevelEstimatorImpl::is_enabled() const { + return is_component_enabled(); +} + +int LevelEstimatorImpl::GetMetrics(LevelEstimator::Metrics* /*metrics*/, + LevelEstimator::Metrics* /*reverse_metrics*/) { + return apm_->kUnsupportedComponentError; + /*if (!is_component_enabled()) { + return apm_->kNotEnabledError; + } + + int err = GetMetricsLocal(static_cast(handle(0)), metrics); + if (err != apm_->kNoError) { + return err; + } + + err = GetMetricsLocal(static_cast(handle(1)), reverse_metrics); + if (err != apm_->kNoError) { + return err; + } + + return apm_->kNoError;*/ +} + +int LevelEstimatorImpl::get_version(char* version, + int version_len_bytes) const { + // An empty string is used to indicate no version information. + memset(version, 0, version_len_bytes); + return apm_->kNoError; +} + +void* LevelEstimatorImpl::CreateHandle() const { + Handle* handle = NULL; + /*if (CreateLvlEst(&handle) != apm_->kNoError) { + handle = NULL; + } else { + assert(handle != NULL); + }*/ + + return handle; +} + +int LevelEstimatorImpl::DestroyHandle(void* /*handle*/) const { + return apm_->kUnsupportedComponentError; + //return FreeLvlEst(static_cast(handle)); +} + +int LevelEstimatorImpl::InitializeHandle(void* /*handle*/) const { + return apm_->kUnsupportedComponentError; + /*const double kIntervalSeconds = 1.5; + return InitLvlEst(static_cast(handle), + apm_->sample_rate_hz(), + kIntervalSeconds);*/ +} + +int LevelEstimatorImpl::ConfigureHandle(void* /*handle*/) const { + return apm_->kUnsupportedComponentError; + //return apm_->kNoError; +} + +int LevelEstimatorImpl::num_handles_required() const { + return apm_->kUnsupportedComponentError; + //return 2; +} + +int LevelEstimatorImpl::GetHandleError(void* handle) const { + // The component has no detailed errors. + assert(handle != NULL); + return apm_->kUnspecifiedError; +} +} // namespace webrtc diff --git a/src/modules/audio_processing/main/source/level_estimator_impl.h b/src/modules/audio_processing/main/source/level_estimator_impl.h new file mode 100644 index 0000000..1515722 --- /dev/null +++ b/src/modules/audio_processing/main/source/level_estimator_impl.h @@ -0,0 +1,53 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +#ifndef WEBRTC_MODULES_AUDIO_PROCESSING_MAIN_SOURCE_LEVEL_ESTIMATOR_IMPL_H_ +#define WEBRTC_MODULES_AUDIO_PROCESSING_MAIN_SOURCE_LEVEL_ESTIMATOR_IMPL_H_ + +#include "audio_processing.h" +#include "processing_component.h" + +namespace webrtc { +class AudioProcessingImpl; +class AudioBuffer; + +class LevelEstimatorImpl : public LevelEstimator, + public ProcessingComponent { + public: + explicit LevelEstimatorImpl(const AudioProcessingImpl* apm); + virtual ~LevelEstimatorImpl(); + + int AnalyzeReverseStream(AudioBuffer* audio); + int ProcessCaptureAudio(AudioBuffer* audio); + + // LevelEstimator implementation. + virtual bool is_enabled() const; + + // ProcessingComponent implementation. + virtual int get_version(char* version, int version_len_bytes) const; + + private: + // LevelEstimator implementation. + virtual int Enable(bool enable); + virtual int GetMetrics(Metrics* metrics, Metrics* reverse_metrics); + + // ProcessingComponent implementation. + virtual void* CreateHandle() const; + virtual int InitializeHandle(void* handle) const; + virtual int ConfigureHandle(void* handle) const; + virtual int DestroyHandle(void* handle) const; + virtual int num_handles_required() const; + virtual int GetHandleError(void* handle) const; + + const AudioProcessingImpl* apm_; +}; +} // namespace webrtc + +#endif // WEBRTC_MODULES_AUDIO_PROCESSING_MAIN_SOURCE_LEVEL_ESTIMATOR_IMPL_H_ diff --git a/src/modules/audio_processing/main/source/noise_suppression_impl.cc b/src/modules/audio_processing/main/source/noise_suppression_impl.cc new file mode 100644 index 0000000..f899f35 --- /dev/null +++ b/src/modules/audio_processing/main/source/noise_suppression_impl.cc @@ -0,0 +1,179 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +#include "noise_suppression_impl.h" + +#include + +#include "critical_section_wrapper.h" +#if defined(WEBRTC_NS_FLOAT) +#include "noise_suppression.h" +#elif defined(WEBRTC_NS_FIXED) +#include "noise_suppression_x.h" +#endif + +#include "audio_processing_impl.h" +#include "audio_buffer.h" + +namespace webrtc { + +#if defined(WEBRTC_NS_FLOAT) +typedef NsHandle Handle; +#elif defined(WEBRTC_NS_FIXED) +typedef NsxHandle Handle; +#endif + +namespace { +int MapSetting(NoiseSuppression::Level level) { + switch (level) { + case NoiseSuppression::kLow: + return 0; + case NoiseSuppression::kModerate: + return 1; + case NoiseSuppression::kHigh: + return 2; + case NoiseSuppression::kVeryHigh: + return 3; + default: + return -1; + } +} +} // namespace + +NoiseSuppressionImpl::NoiseSuppressionImpl(const AudioProcessingImpl* apm) + : ProcessingComponent(apm), + apm_(apm), + level_(kModerate) {} + +NoiseSuppressionImpl::~NoiseSuppressionImpl() {} + +int NoiseSuppressionImpl::ProcessCaptureAudio(AudioBuffer* audio) { + int err = apm_->kNoError; + + if (!is_component_enabled()) { + return apm_->kNoError; + } + assert(audio->samples_per_split_channel() <= 160); + assert(audio->num_channels() == num_handles()); + + for (int i = 0; i < num_handles(); i++) { + Handle* my_handle = static_cast(handle(i)); +#if defined(WEBRTC_NS_FLOAT) + err = WebRtcNs_Process(static_cast(handle(i)), + audio->low_pass_split_data(i), + audio->high_pass_split_data(i), + audio->low_pass_split_data(i), + audio->high_pass_split_data(i)); +#elif defined(WEBRTC_NS_FIXED) + err = WebRtcNsx_Process(static_cast(handle(i)), + audio->low_pass_split_data(i), + audio->high_pass_split_data(i), + audio->low_pass_split_data(i), + audio->high_pass_split_data(i)); +#endif + + if (err != apm_->kNoError) { + return GetHandleError(my_handle); + } + } + + return apm_->kNoError; +} + +int NoiseSuppressionImpl::Enable(bool enable) { + CriticalSectionScoped crit_scoped(*apm_->crit()); + return EnableComponent(enable); +} + +bool NoiseSuppressionImpl::is_enabled() const { + return is_component_enabled(); +} + +int NoiseSuppressionImpl::set_level(Level level) { + CriticalSectionScoped crit_scoped(*apm_->crit()); + if (MapSetting(level) == -1) { + return apm_->kBadParameterError; + } + + level_ = level; + return Configure(); +} + +NoiseSuppression::Level NoiseSuppressionImpl::level() const { + return level_; +} + +int NoiseSuppressionImpl::get_version(char* version, + int version_len_bytes) const { +#if defined(WEBRTC_NS_FLOAT) + if (WebRtcNs_get_version(version, version_len_bytes) != 0) +#elif defined(WEBRTC_NS_FIXED) + if (WebRtcNsx_get_version(version, version_len_bytes) != 0) +#endif + { + return apm_->kBadParameterError; + } + + return apm_->kNoError; +} + +void* NoiseSuppressionImpl::CreateHandle() const { + Handle* handle = NULL; +#if defined(WEBRTC_NS_FLOAT) + if (WebRtcNs_Create(&handle) != apm_->kNoError) +#elif defined(WEBRTC_NS_FIXED) + if (WebRtcNsx_Create(&handle) != apm_->kNoError) +#endif + { + handle = NULL; + } else { + assert(handle != NULL); + } + + return handle; +} + +int NoiseSuppressionImpl::DestroyHandle(void* handle) const { +#if defined(WEBRTC_NS_FLOAT) + return WebRtcNs_Free(static_cast(handle)); +#elif defined(WEBRTC_NS_FIXED) + return WebRtcNsx_Free(static_cast(handle)); +#endif +} + +int NoiseSuppressionImpl::InitializeHandle(void* handle) const { +#if defined(WEBRTC_NS_FLOAT) + return WebRtcNs_Init(static_cast(handle), apm_->sample_rate_hz()); +#elif defined(WEBRTC_NS_FIXED) + return WebRtcNsx_Init(static_cast(handle), apm_->sample_rate_hz()); +#endif +} + +int NoiseSuppressionImpl::ConfigureHandle(void* handle) const { +#if defined(WEBRTC_NS_FLOAT) + return WebRtcNs_set_policy(static_cast(handle), + MapSetting(level_)); +#elif defined(WEBRTC_NS_FIXED) + return WebRtcNsx_set_policy(static_cast(handle), + MapSetting(level_)); +#endif +} + +int NoiseSuppressionImpl::num_handles_required() const { + return apm_->num_output_channels(); +} + +int NoiseSuppressionImpl::GetHandleError(void* handle) const { + // The NS has no get_error() function. + assert(handle != NULL); + return apm_->kUnspecifiedError; +} +} // namespace webrtc + diff --git a/src/modules/audio_processing/main/source/noise_suppression_impl.h b/src/modules/audio_processing/main/source/noise_suppression_impl.h new file mode 100644 index 0000000..c9ff9b3 --- /dev/null +++ b/src/modules/audio_processing/main/source/noise_suppression_impl.h @@ -0,0 +1,54 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +#ifndef WEBRTC_MODULES_AUDIO_PROCESSING_MAIN_SOURCE_NOISE_SUPPRESSION_IMPL_H_ +#define WEBRTC_MODULES_AUDIO_PROCESSING_MAIN_SOURCE_NOISE_SUPPRESSION_IMPL_H_ + +#include "audio_processing.h" +#include "processing_component.h" + +namespace webrtc { +class AudioProcessingImpl; +class AudioBuffer; + +class NoiseSuppressionImpl : public NoiseSuppression, + public ProcessingComponent { + public: + explicit NoiseSuppressionImpl(const AudioProcessingImpl* apm); + virtual ~NoiseSuppressionImpl(); + + int ProcessCaptureAudio(AudioBuffer* audio); + + // NoiseSuppression implementation. + virtual bool is_enabled() const; + + // ProcessingComponent implementation. + virtual int get_version(char* version, int version_len_bytes) const; + + private: + // NoiseSuppression implementation. + virtual int Enable(bool enable); + virtual int set_level(Level level); + virtual Level level() const; + + // ProcessingComponent implementation. + virtual void* CreateHandle() const; + virtual int InitializeHandle(void* handle) const; + virtual int ConfigureHandle(void* handle) const; + virtual int DestroyHandle(void* handle) const; + virtual int num_handles_required() const; + virtual int GetHandleError(void* handle) const; + + const AudioProcessingImpl* apm_; + Level level_; +}; +} // namespace webrtc + +#endif // WEBRTC_MODULES_AUDIO_PROCESSING_MAIN_SOURCE_NOISE_SUPPRESSION_IMPL_H_ diff --git a/src/modules/audio_processing/main/source/processing_component.cc b/src/modules/audio_processing/main/source/processing_component.cc new file mode 100644 index 0000000..9ac1257 --- /dev/null +++ b/src/modules/audio_processing/main/source/processing_component.cc @@ -0,0 +1,112 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +#include "processing_component.h" + +#include + +#include "audio_processing_impl.h" + +namespace webrtc { + +ProcessingComponent::ProcessingComponent(const AudioProcessingImpl* apm) + : apm_(apm), + initialized_(false), + enabled_(false), + num_handles_(0) {} + +ProcessingComponent::~ProcessingComponent() { + assert(initialized_ == false); +} + +int ProcessingComponent::Destroy() { + while (!handles_.empty()) { + DestroyHandle(handles_.back()); + handles_.pop_back(); + } + initialized_ = false; + + return apm_->kNoError; +} + +int ProcessingComponent::EnableComponent(bool enable) { + if (enable && !enabled_) { + enabled_ = enable; // Must be set before Initialize() is called. + + int err = Initialize(); + if (err != apm_->kNoError) { + enabled_ = false; + return err; + } + } else { + enabled_ = enable; + } + + return apm_->kNoError; +} + +bool ProcessingComponent::is_component_enabled() const { + return enabled_; +} + +void* ProcessingComponent::handle(int index) const { + assert(index < num_handles_); + return handles_[index]; +} + +int ProcessingComponent::num_handles() const { + return num_handles_; +} + +int ProcessingComponent::Initialize() { + if (!enabled_) { + return apm_->kNoError; + } + + num_handles_ = num_handles_required(); + if (num_handles_ > static_cast(handles_.size())) { + handles_.resize(num_handles_, NULL); + } + + assert(static_cast(handles_.size()) >= num_handles_); + for (int i = 0; i < num_handles_; i++) { + if (handles_[i] == NULL) { + handles_[i] = CreateHandle(); + if (handles_[i] == NULL) { + return apm_->kCreationFailedError; + } + } + + int err = InitializeHandle(handles_[i]); + if (err != apm_->kNoError) { + return GetHandleError(handles_[i]); + } + } + + initialized_ = true; + return Configure(); +} + +int ProcessingComponent::Configure() { + if (!initialized_) { + return apm_->kNoError; + } + + assert(static_cast(handles_.size()) >= num_handles_); + for (int i = 0; i < num_handles_; i++) { + int err = ConfigureHandle(handles_[i]); + if (err != apm_->kNoError) { + return GetHandleError(handles_[i]); + } + } + + return apm_->kNoError; +} +} // namespace webrtc diff --git a/src/modules/audio_processing/main/source/processing_component.h b/src/modules/audio_processing/main/source/processing_component.h new file mode 100644 index 0000000..3d8a02b --- /dev/null +++ b/src/modules/audio_processing/main/source/processing_component.h @@ -0,0 +1,63 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +#ifndef WEBRTC_MODULES_AUDIO_PROCESSING_MAIN_SOURCE_PROCESSING_COMPONENT_H_ +#define WEBRTC_MODULES_AUDIO_PROCESSING_MAIN_SOURCE_PROCESSING_COMPONENT_H_ + +#include + +#include "audio_processing.h" + +namespace webrtc { +class AudioProcessingImpl; + +/*template +class ComponentHandle { + public: + ComponentHandle(); + virtual ~ComponentHandle(); + + virtual int Create() = 0; + virtual T* ptr() const = 0; +};*/ + +class ProcessingComponent { + public: + explicit ProcessingComponent(const AudioProcessingImpl* apm); + virtual ~ProcessingComponent(); + + virtual int Initialize(); + virtual int Destroy(); + virtual int get_version(char* version, int version_len_bytes) const = 0; + + protected: + virtual int Configure(); + int EnableComponent(bool enable); + bool is_component_enabled() const; + void* handle(int index) const; + int num_handles() const; + + private: + virtual void* CreateHandle() const = 0; + virtual int InitializeHandle(void* handle) const = 0; + virtual int ConfigureHandle(void* handle) const = 0; + virtual int DestroyHandle(void* handle) const = 0; + virtual int num_handles_required() const = 0; + virtual int GetHandleError(void* handle) const = 0; + + const AudioProcessingImpl* apm_; + std::vector handles_; + bool initialized_; + bool enabled_; + int num_handles_; +}; +} // namespace webrtc + +#endif // WEBRTC_MODULES_AUDIO_PROCESSING_MAIN_SOURCE_PROCESSING_COMPONENT_H__ diff --git a/src/modules/audio_processing/main/source/splitting_filter.cc b/src/modules/audio_processing/main/source/splitting_filter.cc new file mode 100644 index 0000000..1526141 --- /dev/null +++ b/src/modules/audio_processing/main/source/splitting_filter.cc @@ -0,0 +1,33 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +#include "splitting_filter.h" +#include "signal_processing_library.h" + +namespace webrtc { + +void SplittingFilterAnalysis(const WebRtc_Word16* in_data, + WebRtc_Word16* low_band, + WebRtc_Word16* high_band, + WebRtc_Word32* filter_state1, + WebRtc_Word32* filter_state2) +{ + WebRtcSpl_AnalysisQMF(in_data, low_band, high_band, filter_state1, filter_state2); +} + +void SplittingFilterSynthesis(const WebRtc_Word16* low_band, + const WebRtc_Word16* high_band, + WebRtc_Word16* out_data, + WebRtc_Word32* filt_state1, + WebRtc_Word32* filt_state2) +{ + WebRtcSpl_SynthesisQMF(low_band, high_band, out_data, filt_state1, filt_state2); +} +} // namespace webrtc diff --git a/src/modules/audio_processing/main/source/splitting_filter.h b/src/modules/audio_processing/main/source/splitting_filter.h new file mode 100644 index 0000000..661bfb2 --- /dev/null +++ b/src/modules/audio_processing/main/source/splitting_filter.h @@ -0,0 +1,63 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +#ifndef WEBRTC_MODULES_AUDIO_PROCESSING_MAIN_SOURCE_SPLITTING_FILTER_H_ +#define WEBRTC_MODULES_AUDIO_PROCESSING_MAIN_SOURCE_SPLITTING_FILTER_H_ + +#include "typedefs.h" +#include "signal_processing_library.h" + +namespace webrtc { +/* + * SplittingFilterbank_analysisQMF(...) + * + * Splits a super-wb signal into two subbands: 0-8 kHz and 8-16 kHz. + * + * Input: + * - in_data : super-wb audio signal + * + * Input & Output: + * - filt_state1: Filter state for first all-pass filter + * - filt_state2: Filter state for second all-pass filter + * + * Output: + * - low_band : The signal from the 0-4 kHz band + * - high_band : The signal from the 4-8 kHz band + */ +void SplittingFilterAnalysis(const WebRtc_Word16* in_data, + WebRtc_Word16* low_band, + WebRtc_Word16* high_band, + WebRtc_Word32* filt_state1, + WebRtc_Word32* filt_state2); + +/* + * SplittingFilterbank_synthesisQMF(...) + * + * Combines the two subbands (0-8 and 8-16 kHz) into a super-wb signal. + * + * Input: + * - low_band : The signal with the 0-8 kHz band + * - high_band : The signal with the 8-16 kHz band + * + * Input & Output: + * - filt_state1: Filter state for first all-pass filter + * - filt_state2: Filter state for second all-pass filter + * + * Output: + * - out_data : super-wb speech signal + */ +void SplittingFilterSynthesis(const WebRtc_Word16* low_band, + const WebRtc_Word16* high_band, + WebRtc_Word16* out_data, + WebRtc_Word32* filt_state1, + WebRtc_Word32* filt_state2); +} // namespace webrtc + +#endif // WEBRTC_MODULES_AUDIO_PROCESSING_MAIN_SOURCE_SPLITTING_FILTER_H_ diff --git a/src/modules/audio_processing/main/source/voice_detection_impl.cc b/src/modules/audio_processing/main/source/voice_detection_impl.cc new file mode 100644 index 0000000..3eb446e --- /dev/null +++ b/src/modules/audio_processing/main/source/voice_detection_impl.cc @@ -0,0 +1,202 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +#include "voice_detection_impl.h" + +#include + +#include "critical_section_wrapper.h" +#include "webrtc_vad.h" + +#include "audio_processing_impl.h" +#include "audio_buffer.h" + +namespace webrtc { + +typedef VadInst Handle; + +namespace { +WebRtc_Word16 MapSetting(VoiceDetection::Likelihood likelihood) { + switch (likelihood) { + case VoiceDetection::kVeryLowLikelihood: + return 3; + break; + case VoiceDetection::kLowLikelihood: + return 2; + break; + case VoiceDetection::kModerateLikelihood: + return 1; + break; + case VoiceDetection::kHighLikelihood: + return 0; + break; + default: + return -1; + } +} +} // namespace + + +VoiceDetectionImpl::VoiceDetectionImpl(const AudioProcessingImpl* apm) + : ProcessingComponent(apm), + apm_(apm), + stream_has_voice_(false), + using_external_vad_(false), + likelihood_(kLowLikelihood), + frame_size_ms_(10), + frame_size_samples_(0) {} + +VoiceDetectionImpl::~VoiceDetectionImpl() {} + +int VoiceDetectionImpl::ProcessCaptureAudio(AudioBuffer* audio) { + if (!is_component_enabled()) { + return apm_->kNoError; + } + + if (using_external_vad_) { + using_external_vad_ = false; + return apm_->kNoError; + } + assert(audio->samples_per_split_channel() <= 160); + + WebRtc_Word16* mixed_data = audio->low_pass_split_data(0); + if (audio->num_channels() > 1) { + audio->CopyAndMixLowPass(1); + mixed_data = audio->mixed_low_pass_data(0); + } + + // TODO(ajm): concatenate data in frame buffer here. + + int vad_ret_val; + vad_ret_val = WebRtcVad_Process(static_cast(handle(0)), + apm_->split_sample_rate_hz(), + mixed_data, + frame_size_samples_); + + if (vad_ret_val == 0) { + stream_has_voice_ = false; + } else if (vad_ret_val == 1) { + stream_has_voice_ = true; + } else { + return apm_->kUnspecifiedError; + } + + return apm_->kNoError; +} + +int VoiceDetectionImpl::Enable(bool enable) { + CriticalSectionScoped crit_scoped(*apm_->crit()); + return EnableComponent(enable); +} + +bool VoiceDetectionImpl::is_enabled() const { + return is_component_enabled(); +} + +int VoiceDetectionImpl::set_stream_has_voice(bool has_voice) { + using_external_vad_ = true; + stream_has_voice_ = has_voice; + return apm_->kNoError; +} + +bool VoiceDetectionImpl::stream_has_voice() const { + // TODO(ajm): enable this assertion? + //assert(using_external_vad_ || is_component_enabled()); + return stream_has_voice_; +} + +int VoiceDetectionImpl::set_likelihood(VoiceDetection::Likelihood likelihood) { + CriticalSectionScoped crit_scoped(*apm_->crit()); + if (MapSetting(likelihood) == -1) { + return apm_->kBadParameterError; + } + + likelihood_ = likelihood; + return Configure(); +} + +VoiceDetection::Likelihood VoiceDetectionImpl::likelihood() const { + return likelihood_; +} + +int VoiceDetectionImpl::set_frame_size_ms(int size) { + CriticalSectionScoped crit_scoped(*apm_->crit()); + assert(size == 10); // TODO(ajm): remove when supported. + if (size != 10 && + size != 20 && + size != 30) { + return apm_->kBadParameterError; + } + + frame_size_ms_ = size; + + return Initialize(); +} + +int VoiceDetectionImpl::frame_size_ms() const { + return frame_size_ms_; +} + +int VoiceDetectionImpl::Initialize() { + int err = ProcessingComponent::Initialize(); + if (err != apm_->kNoError || !is_component_enabled()) { + return err; + } + + using_external_vad_ = false; + frame_size_samples_ = frame_size_ms_ * (apm_->split_sample_rate_hz() / 1000); + // TODO(ajm): intialize frame buffer here. + + return apm_->kNoError; +} + +int VoiceDetectionImpl::get_version(char* version, + int version_len_bytes) const { + if (WebRtcVad_get_version(version, version_len_bytes) != 0) { + return apm_->kBadParameterError; + } + + return apm_->kNoError; +} + +void* VoiceDetectionImpl::CreateHandle() const { + Handle* handle = NULL; + if (WebRtcVad_Create(&handle) != apm_->kNoError) { + handle = NULL; + } else { + assert(handle != NULL); + } + + return handle; +} + +int VoiceDetectionImpl::DestroyHandle(void* handle) const { + return WebRtcVad_Free(static_cast(handle)); +} + +int VoiceDetectionImpl::InitializeHandle(void* handle) const { + return WebRtcVad_Init(static_cast(handle)); +} + +int VoiceDetectionImpl::ConfigureHandle(void* handle) const { + return WebRtcVad_set_mode(static_cast(handle), + MapSetting(likelihood_)); +} + +int VoiceDetectionImpl::num_handles_required() const { + return 1; +} + +int VoiceDetectionImpl::GetHandleError(void* handle) const { + // The VAD has no get_error() function. + assert(handle != NULL); + return apm_->kUnspecifiedError; +} +} // namespace webrtc diff --git a/src/modules/audio_processing/main/source/voice_detection_impl.h b/src/modules/audio_processing/main/source/voice_detection_impl.h new file mode 100644 index 0000000..ef212d1 --- /dev/null +++ b/src/modules/audio_processing/main/source/voice_detection_impl.h @@ -0,0 +1,63 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +#ifndef WEBRTC_MODULES_AUDIO_PROCESSING_MAIN_SOURCE_VOICE_DETECTION_IMPL_H_ +#define WEBRTC_MODULES_AUDIO_PROCESSING_MAIN_SOURCE_VOICE_DETECTION_IMPL_H_ + +#include "audio_processing.h" +#include "processing_component.h" + +namespace webrtc { +class AudioProcessingImpl; +class AudioBuffer; + +class VoiceDetectionImpl : public VoiceDetection, + public ProcessingComponent { + public: + explicit VoiceDetectionImpl(const AudioProcessingImpl* apm); + virtual ~VoiceDetectionImpl(); + + int ProcessCaptureAudio(AudioBuffer* audio); + + // VoiceDetection implementation. + virtual bool is_enabled() const; + + // ProcessingComponent implementation. + virtual int Initialize(); + virtual int get_version(char* version, int version_len_bytes) const; + + private: + // VoiceDetection implementation. + virtual int Enable(bool enable); + virtual int set_stream_has_voice(bool has_voice); + virtual bool stream_has_voice() const; + virtual int set_likelihood(Likelihood likelihood); + virtual Likelihood likelihood() const; + virtual int set_frame_size_ms(int size); + virtual int frame_size_ms() const; + + // ProcessingComponent implementation. + virtual void* CreateHandle() const; + virtual int InitializeHandle(void* handle) const; + virtual int ConfigureHandle(void* handle) const; + virtual int DestroyHandle(void* handle) const; + virtual int num_handles_required() const; + virtual int GetHandleError(void* handle) const; + + const AudioProcessingImpl* apm_; + bool stream_has_voice_; + bool using_external_vad_; + Likelihood likelihood_; + int frame_size_ms_; + int frame_size_samples_; +}; +} // namespace webrtc + +#endif // WEBRTC_MODULES_AUDIO_PROCESSING_MAIN_SOURCE_VOICE_DETECTION_IMPL_H_ diff --git a/src/modules/audio_processing/main/test/android/apmtest/AndroidManifest.xml b/src/modules/audio_processing/main/test/android/apmtest/AndroidManifest.xml new file mode 100644 index 0000000..c6063b3 --- /dev/null +++ b/src/modules/audio_processing/main/test/android/apmtest/AndroidManifest.xml @@ -0,0 +1,30 @@ + + + + + + + + + + + + + + + + + + + + + + + diff --git a/src/modules/audio_processing/main/test/android/apmtest/default.properties b/src/modules/audio_processing/main/test/android/apmtest/default.properties new file mode 100644 index 0000000..9a2c9f6 --- /dev/null +++ b/src/modules/audio_processing/main/test/android/apmtest/default.properties @@ -0,0 +1,11 @@ +# This file is automatically generated by Android Tools. +# Do not modify this file -- YOUR CHANGES WILL BE ERASED! +# +# This file must be checked in Version Control Systems. +# +# To customize properties used by the Ant build system use, +# "build.properties", and override values to adapt the script to your +# project structure. + +# Project target. +target=android-9 diff --git a/src/modules/audio_processing/main/test/android/apmtest/jni/Application.mk b/src/modules/audio_processing/main/test/android/apmtest/jni/Application.mk new file mode 100644 index 0000000..22d188e --- /dev/null +++ b/src/modules/audio_processing/main/test/android/apmtest/jni/Application.mk @@ -0,0 +1 @@ +APP_PLATFORM := android-9 diff --git a/src/modules/audio_processing/main/test/android/apmtest/jni/main.c b/src/modules/audio_processing/main/test/android/apmtest/jni/main.c new file mode 100644 index 0000000..2e19635 --- /dev/null +++ b/src/modules/audio_processing/main/test/android/apmtest/jni/main.c @@ -0,0 +1,307 @@ +/* + * Copyright (C) 2010 The Android Open Source Project + * + * Licensed under the Apache License, Version 2.0 (the "License"); + * you may not use this file except in compliance with the License. + * You may obtain a copy of the License at + * + * http://www.apache.org/licenses/LICENSE-2.0 + * + * Unless required by applicable law or agreed to in writing, software + * distributed under the License is distributed on an "AS IS" BASIS, + * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. + * See the License for the specific language governing permissions and + * limitations under the License. + * + */ + +//BEGIN_INCLUDE(all) +#include +#include + +#include +#include + +#include +#include +#include + +#define LOGI(...) ((void)__android_log_print(ANDROID_LOG_INFO, "native-activity", __VA_ARGS__)) +#define LOGW(...) ((void)__android_log_print(ANDROID_LOG_WARN, "native-activity", __VA_ARGS__)) + +/** + * Our saved state data. + */ +struct saved_state { + float angle; + int32_t x; + int32_t y; +}; + +/** + * Shared state for our app. + */ +struct engine { + struct android_app* app; + + ASensorManager* sensorManager; + const ASensor* accelerometerSensor; + ASensorEventQueue* sensorEventQueue; + + int animating; + EGLDisplay display; + EGLSurface surface; + EGLContext context; + int32_t width; + int32_t height; + struct saved_state state; +}; + +/** + * Initialize an EGL context for the current display. + */ +static int engine_init_display(struct engine* engine) { + // initialize OpenGL ES and EGL + + /* + * Here specify the attributes of the desired configuration. + * Below, we select an EGLConfig with at least 8 bits per color + * component compatible with on-screen windows + */ + const EGLint attribs[] = { + EGL_SURFACE_TYPE, EGL_WINDOW_BIT, + EGL_BLUE_SIZE, 8, + EGL_GREEN_SIZE, 8, + EGL_RED_SIZE, 8, + EGL_NONE + }; + EGLint w, h, dummy, format; + EGLint numConfigs; + EGLConfig config; + EGLSurface surface; + EGLContext context; + + EGLDisplay display = eglGetDisplay(EGL_DEFAULT_DISPLAY); + + eglInitialize(display, 0, 0); + + /* Here, the application chooses the configuration it desires. In this + * sample, we have a very simplified selection process, where we pick + * the first EGLConfig that matches our criteria */ + eglChooseConfig(display, attribs, &config, 1, &numConfigs); + + /* EGL_NATIVE_VISUAL_ID is an attribute of the EGLConfig that is + * guaranteed to be accepted by ANativeWindow_setBuffersGeometry(). + * As soon as we picked a EGLConfig, we can safely reconfigure the + * ANativeWindow buffers to match, using EGL_NATIVE_VISUAL_ID. */ + eglGetConfigAttrib(display, config, EGL_NATIVE_VISUAL_ID, &format); + + ANativeWindow_setBuffersGeometry(engine->app->window, 0, 0, format); + + surface = eglCreateWindowSurface(display, config, engine->app->window, NULL); + context = eglCreateContext(display, config, NULL, NULL); + + if (eglMakeCurrent(display, surface, surface, context) == EGL_FALSE) { + LOGW("Unable to eglMakeCurrent"); + return -1; + } + + eglQuerySurface(display, surface, EGL_WIDTH, &w); + eglQuerySurface(display, surface, EGL_HEIGHT, &h); + + engine->display = display; + engine->context = context; + engine->surface = surface; + engine->width = w; + engine->height = h; + engine->state.angle = 0; + + // Initialize GL state. + glHint(GL_PERSPECTIVE_CORRECTION_HINT, GL_FASTEST); + glEnable(GL_CULL_FACE); + glShadeModel(GL_SMOOTH); + glDisable(GL_DEPTH_TEST); + + return 0; +} + +/** + * Just the current frame in the display. + */ +static void engine_draw_frame(struct engine* engine) { + if (engine->display == NULL) { + // No display. + return; + } + + // Just fill the screen with a color. + glClearColor(((float)engine->state.x)/engine->width, engine->state.angle, + ((float)engine->state.y)/engine->height, 1); + glClear(GL_COLOR_BUFFER_BIT); + + eglSwapBuffers(engine->display, engine->surface); +} + +/** + * Tear down the EGL context currently associated with the display. + */ +static void engine_term_display(struct engine* engine) { + if (engine->display != EGL_NO_DISPLAY) { + eglMakeCurrent(engine->display, EGL_NO_SURFACE, EGL_NO_SURFACE, EGL_NO_CONTEXT); + if (engine->context != EGL_NO_CONTEXT) { + eglDestroyContext(engine->display, engine->context); + } + if (engine->surface != EGL_NO_SURFACE) { + eglDestroySurface(engine->display, engine->surface); + } + eglTerminate(engine->display); + } + engine->animating = 0; + engine->display = EGL_NO_DISPLAY; + engine->context = EGL_NO_CONTEXT; + engine->surface = EGL_NO_SURFACE; +} + +/** + * Process the next input event. + */ +static int32_t engine_handle_input(struct android_app* app, AInputEvent* event) { + struct engine* engine = (struct engine*)app->userData; + if (AInputEvent_getType(event) == AINPUT_EVENT_TYPE_MOTION) { + engine->animating = 1; + engine->state.x = AMotionEvent_getX(event, 0); + engine->state.y = AMotionEvent_getY(event, 0); + return 1; + } + return 0; +} + +/** + * Process the next main command. + */ +static void engine_handle_cmd(struct android_app* app, int32_t cmd) { + struct engine* engine = (struct engine*)app->userData; + switch (cmd) { + case APP_CMD_SAVE_STATE: + // The system has asked us to save our current state. Do so. + engine->app->savedState = malloc(sizeof(struct saved_state)); + *((struct saved_state*)engine->app->savedState) = engine->state; + engine->app->savedStateSize = sizeof(struct saved_state); + break; + case APP_CMD_INIT_WINDOW: + // The window is being shown, get it ready. + if (engine->app->window != NULL) { + engine_init_display(engine); + engine_draw_frame(engine); + } + break; + case APP_CMD_TERM_WINDOW: + // The window is being hidden or closed, clean it up. + engine_term_display(engine); + break; + case APP_CMD_GAINED_FOCUS: + // When our app gains focus, we start monitoring the accelerometer. + if (engine->accelerometerSensor != NULL) { + ASensorEventQueue_enableSensor(engine->sensorEventQueue, + engine->accelerometerSensor); + // We'd like to get 60 events per second (in us). + ASensorEventQueue_setEventRate(engine->sensorEventQueue, + engine->accelerometerSensor, (1000L/60)*1000); + } + break; + case APP_CMD_LOST_FOCUS: + // When our app loses focus, we stop monitoring the accelerometer. + // This is to avoid consuming battery while not being used. + if (engine->accelerometerSensor != NULL) { + ASensorEventQueue_disableSensor(engine->sensorEventQueue, + engine->accelerometerSensor); + } + // Also stop animating. + engine->animating = 0; + engine_draw_frame(engine); + break; + } +} + +/** + * This is the main entry point of a native application that is using + * android_native_app_glue. It runs in its own thread, with its own + * event loop for receiving input events and doing other things. + */ +void android_main(struct android_app* state) { + struct engine engine; + + // Make sure glue isn't stripped. + app_dummy(); + + memset(&engine, 0, sizeof(engine)); + state->userData = &engine; + state->onAppCmd = engine_handle_cmd; + state->onInputEvent = engine_handle_input; + engine.app = state; + + // Prepare to monitor accelerometer + engine.sensorManager = ASensorManager_getInstance(); + engine.accelerometerSensor = ASensorManager_getDefaultSensor(engine.sensorManager, + ASENSOR_TYPE_ACCELEROMETER); + engine.sensorEventQueue = ASensorManager_createEventQueue(engine.sensorManager, + state->looper, LOOPER_ID_USER, NULL, NULL); + + if (state->savedState != NULL) { + // We are starting with a previous saved state; restore from it. + engine.state = *(struct saved_state*)state->savedState; + } + + // loop waiting for stuff to do. + + while (1) { + // Read all pending events. + int ident; + int events; + struct android_poll_source* source; + + // If not animating, we will block forever waiting for events. + // If animating, we loop until all events are read, then continue + // to draw the next frame of animation. + while ((ident=ALooper_pollAll(engine.animating ? 0 : -1, NULL, &events, + (void**)&source)) >= 0) { + + // Process this event. + if (source != NULL) { + source->process(state, source); + } + + // If a sensor has data, process it now. + if (ident == LOOPER_ID_USER) { + if (engine.accelerometerSensor != NULL) { + ASensorEvent event; + while (ASensorEventQueue_getEvents(engine.sensorEventQueue, + &event, 1) > 0) { + LOGI("accelerometer: x=%f y=%f z=%f", + event.acceleration.x, event.acceleration.y, + event.acceleration.z); + } + } + } + + // Check if we are exiting. + if (state->destroyRequested != 0) { + engine_term_display(&engine); + return; + } + } + + if (engine.animating) { + // Done with events; draw next animation frame. + engine.state.angle += .01f; + if (engine.state.angle > 1) { + engine.state.angle = 0; + } + + // Drawing is throttled to the screen update rate, so there + // is no need to do timing here. + engine_draw_frame(&engine); + } + } +} +//END_INCLUDE(all) diff --git a/src/modules/audio_processing/main/test/android/apmtest/res/values/strings.xml b/src/modules/audio_processing/main/test/android/apmtest/res/values/strings.xml new file mode 100644 index 0000000..d0bd0f3 --- /dev/null +++ b/src/modules/audio_processing/main/test/android/apmtest/res/values/strings.xml @@ -0,0 +1,4 @@ + + + apmtest + diff --git a/src/modules/audio_processing/main/test/process_test/apmtest.m b/src/modules/audio_processing/main/test/process_test/apmtest.m new file mode 100644 index 0000000..3172cd1 --- /dev/null +++ b/src/modules/audio_processing/main/test/process_test/apmtest.m @@ -0,0 +1,355 @@ +function apmtest(task, testname, filepath, casenumber, legacy) +%APMTEST is a tool to process APM file sets and easily display the output. +% APMTEST(TASK, TESTNAME, CASENUMBER) performs one of several TASKs: +% 'test' Processes the files to produce test output. +% 'list' Prints a list of cases in the test set, preceded by their +% CASENUMBERs. +% 'show' Uses spclab to show the test case specified by the +% CASENUMBER parameter. +% +% using a set of test files determined by TESTNAME: +% 'all' All tests. +% 'apm' The standard APM test set (default). +% 'apmm' The mobile APM test set. +% 'aec' The AEC test set. +% 'aecm' The AECM test set. +% 'agc' The AGC test set. +% 'ns' The NS test set. +% 'vad' The VAD test set. +% +% FILEPATH specifies the path to the test data files. +% +% CASENUMBER can be used to select a single test case. Omit CASENUMBER, +% or set to zero, to use all test cases. +% + +if nargin < 5 || isempty(legacy) + % Set to true to run old VQE recordings. + legacy = false; +end + +if nargin < 4 || isempty(casenumber) + casenumber = 0; +end + +if nargin < 3 || isempty(filepath) + filepath = 'data/'; +end + +if nargin < 2 || isempty(testname) + testname = 'all'; +end + +if nargin < 1 || isempty(task) + task = 'test'; +end + +if ~strcmp(task, 'test') && ~strcmp(task, 'list') && ~strcmp(task, 'show') + error(['TASK ' task ' is not recognized']); +end + +if casenumber == 0 && strcmp(task, 'show') + error(['CASENUMBER must be specified for TASK ' task]); +end + +inpath = [filepath 'input/']; +outpath = [filepath 'output/']; +refpath = [filepath 'reference/']; + +if strcmp(testname, 'all') + tests = {'apm','apmm','aec','aecm','agc','ns','vad'}; +else + tests = {testname}; +end + +if legacy + progname = './test'; +else + progname = './process_test'; +end + +global farFile; +global nearFile; +global eventFile; +global delayFile; +global driftFile; + +if legacy + farFile = 'vqeFar.pcm'; + nearFile = 'vqeNear.pcm'; + eventFile = 'vqeEvent.dat'; + delayFile = 'vqeBuf.dat'; + driftFile = 'vqeDrift.dat'; +else + farFile = 'apm_far.pcm'; + nearFile = 'apm_near.pcm'; + eventFile = 'apm_event.dat'; + delayFile = 'apm_delay.dat'; + driftFile = 'apm_drift.dat'; +end + +simulateMode = false; +nErr = 0; +nCases = 0; +for i=1:length(tests) + simulateMode = false; + + if strcmp(tests{i}, 'apm') + testdir = ['apm/']; + outfile = ['out']; + if legacy + opt = ['-ec 1 -agc 2 -nc 2 -vad 3']; + else + opt = ['--no_progress -hpf' ... + ' -aec --drift_compensation -agc --fixed_digital' ... + ' -ns --ns_moderate -vad']; + end + + elseif strcmp(tests{i}, 'apm-swb') + simulateMode = true; + testdir = ['apm-swb/']; + outfile = ['out']; + if legacy + opt = ['-fs 32000 -ec 1 -agc 2 -nc 2']; + else + opt = ['--no_progress -fs 32000 -hpf' ... + ' -aec --drift_compensation -agc --adaptive_digital' ... + ' -ns --ns_moderate -vad']; + end + elseif strcmp(tests{i}, 'apmm') + testdir = ['apmm/']; + outfile = ['out']; + opt = ['-aec --drift_compensation -agc --fixed_digital -hpf -ns ' ... + '--ns_moderate']; + + else + error(['TESTNAME ' tests{i} ' is not recognized']); + end + + inpathtest = [inpath testdir]; + outpathtest = [outpath testdir]; + refpathtest = [refpath testdir]; + + if ~exist(inpathtest,'dir') + error(['Input directory ' inpathtest ' does not exist']); + end + + if ~exist(refpathtest,'dir') + warning(['Reference directory ' refpathtest ' does not exist']); + end + + [status, errMsg] = mkdir(outpathtest); + if (status == 0) + error(errMsg); + end + + [nErr, nCases] = recurseDir(inpathtest, outpathtest, refpathtest, outfile, ... + progname, opt, simulateMode, nErr, nCases, task, casenumber, legacy); + + if strcmp(task, 'test') || strcmp(task, 'show') + system(['rm ' farFile]); + system(['rm ' nearFile]); + if simulateMode == false + system(['rm ' eventFile]); + system(['rm ' delayFile]); + system(['rm ' driftFile]); + end + end +end + +if ~strcmp(task, 'list') + if nErr == 0 + fprintf(1, '\nAll files are bit-exact to reference\n', nErr); + else + fprintf(1, '\n%d files are NOT bit-exact to reference\n', nErr); + end +end + + +function [nErrOut, nCases] = recurseDir(inpath, outpath, refpath, ... + outfile, progname, opt, simulateMode, nErr, nCases, task, casenumber, ... + legacy) + +global farFile; +global nearFile; +global eventFile; +global delayFile; +global driftFile; + +dirs = dir(inpath); +nDirs = 0; +nErrOut = nErr; +for i=3:length(dirs) % skip . and .. + nDirs = nDirs + dirs(i).isdir; +end + + +if nDirs == 0 + nCases = nCases + 1; + + if casenumber == nCases || casenumber == 0 + + if strcmp(task, 'list') + fprintf([num2str(nCases) '. ' outfile '\n']) + else + vadoutfile = ['vad_' outfile '.dat']; + outfile = [outfile '.pcm']; + + % Check for VAD test + vadTest = 0; + if ~isempty(findstr(opt, '-vad')) + vadTest = 1; + if legacy + opt = [opt ' ' outpath vadoutfile]; + else + opt = [opt ' --vad_out_file ' outpath vadoutfile]; + end + end + + if exist([inpath 'vqeFar.pcm']) + system(['ln -s -f ' inpath 'vqeFar.pcm ' farFile]); + elseif exist([inpath 'apm_far.pcm']) + system(['ln -s -f ' inpath 'apm_far.pcm ' farFile]); + end + + if exist([inpath 'vqeNear.pcm']) + system(['ln -s -f ' inpath 'vqeNear.pcm ' nearFile]); + elseif exist([inpath 'apm_near.pcm']) + system(['ln -s -f ' inpath 'apm_near.pcm ' nearFile]); + end + + if exist([inpath 'vqeEvent.dat']) + system(['ln -s -f ' inpath 'vqeEvent.dat ' eventFile]); + elseif exist([inpath 'apm_event.dat']) + system(['ln -s -f ' inpath 'apm_event.dat ' eventFile]); + end + + if exist([inpath 'vqeBuf.dat']) + system(['ln -s -f ' inpath 'vqeBuf.dat ' delayFile]); + elseif exist([inpath 'apm_delay.dat']) + system(['ln -s -f ' inpath 'apm_delay.dat ' delayFile]); + end + + if exist([inpath 'vqeSkew.dat']) + system(['ln -s -f ' inpath 'vqeSkew.dat ' driftFile]); + elseif exist([inpath 'vqeDrift.dat']) + system(['ln -s -f ' inpath 'vqeDrift.dat ' driftFile]); + elseif exist([inpath 'apm_drift.dat']) + system(['ln -s -f ' inpath 'apm_drift.dat ' driftFile]); + end + + if simulateMode == false + command = [progname ' -o ' outpath outfile ' ' opt]; + else + if legacy + inputCmd = [' -in ' nearFile]; + else + inputCmd = [' -i ' nearFile]; + end + + if exist([farFile]) + if legacy + inputCmd = [' -if ' farFile inputCmd]; + else + inputCmd = [' -ir ' farFile inputCmd]; + end + end + command = [progname inputCmd ' -o ' outpath outfile ' ' opt]; + end + % This prevents MATLAB from using its own C libraries. + shellcmd = ['bash -c "unset LD_LIBRARY_PATH;']; + fprintf([command '\n']); + [status, result] = system([shellcmd command '"']); + fprintf(result); + + fprintf(['Reference file: ' refpath outfile '\n']); + + if vadTest == 1 + equal_to_ref = are_files_equal([outpath vadoutfile], ... + [refpath vadoutfile], ... + 'int8'); + if ~equal_to_ref + nErr = nErr + 1; + end + end + + [equal_to_ref, diffvector] = are_files_equal([outpath outfile], ... + [refpath outfile], ... + 'int16'); + if ~equal_to_ref + nErr = nErr + 1; + end + + if strcmp(task, 'show') + % Assume the last init gives the sample rate of interest. + str_idx = strfind(result, 'Sample rate:'); + fs = str2num(result(str_idx(end) + 13:str_idx(end) + 17)); + fprintf('Using %d Hz\n', fs); + + if exist([farFile]) + spclab(fs, farFile, nearFile, [refpath outfile], ... + [outpath outfile], diffvector); + %spclab(fs, diffvector); + else + spclab(fs, nearFile, [refpath outfile], [outpath outfile], ... + diffvector); + %spclab(fs, diffvector); + end + end + end + end +else + + for i=3:length(dirs) + if dirs(i).isdir + [nErr, nCases] = recurseDir([inpath dirs(i).name '/'], outpath, ... + refpath,[outfile '_' dirs(i).name], progname, opt, ... + simulateMode, nErr, nCases, task, casenumber, legacy); + end + end +end +nErrOut = nErr; + +function [are_equal, diffvector] = ... + are_files_equal(newfile, reffile, precision, diffvector) + +are_equal = false; +diffvector = 0; +if ~exist(newfile,'file') + warning(['Output file ' newfile ' does not exist']); + return +end + +if ~exist(reffile,'file') + warning(['Reference file ' reffile ' does not exist']); + return +end + +fid = fopen(newfile,'rb'); +new = fread(fid,inf,precision); +fclose(fid); + +fid = fopen(reffile,'rb'); +ref = fread(fid,inf,precision); +fclose(fid); + +if length(new) ~= length(ref) + warning('Reference is not the same length as output'); + minlength = min(length(new), length(ref)); + new = new(1:minlength); + ref = ref(1:minlength); +end +diffvector = new - ref; + +if isequal(new, ref) + fprintf([newfile ' is bit-exact to reference\n']); + are_equal = true; +else + if isempty(new) + warning([newfile ' is empty']); + return + end + snr = snrseg(new,ref,80); + fprintf('\n'); + are_equal = false; +end diff --git a/src/modules/audio_processing/main/test/process_test/process_test.cc b/src/modules/audio_processing/main/test/process_test/process_test.cc new file mode 100644 index 0000000..f6b6d69 --- /dev/null +++ b/src/modules/audio_processing/main/test/process_test/process_test.cc @@ -0,0 +1,897 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +#include +#include +#ifdef WEBRTC_ANDROID +#include +#endif + +#include "gtest/gtest.h" + +#include "audio_processing.h" +#include "cpu_features_wrapper.h" +#include "module_common_types.h" +#include "tick_util.h" +#ifdef WEBRTC_ANDROID +#include "external/webrtc/src/modules/audio_processing/main/source/debug.pb.h" +#else +#include "webrtc/audio_processing/debug.pb.h" +#endif + +using webrtc::AudioFrame; +using webrtc::AudioProcessing; +using webrtc::GainControl; +using webrtc::NoiseSuppression; +using webrtc::TickInterval; +using webrtc::TickTime; +using webrtc::audioproc::Event; +using webrtc::audioproc::Init; +using webrtc::audioproc::ReverseStream; +using webrtc::audioproc::Stream; + +namespace { +// Returns true on success, false on error or end-of-file. +bool ReadMessageFromFile(FILE* file, + ::google::protobuf::MessageLite* msg) { + // The "wire format" for the size is little-endian. + // Assume process_test is running on a little-endian machine. + int32_t size; + if (fread(&size, sizeof(int32_t), 1, file) != 1) { + return false; + } + if (size <= 0) { + return false; + } + size_t usize = static_cast(size); + + char array[usize]; + if (fread(array, sizeof(char), usize, file) != usize) { + return false; + } + + msg->Clear(); + return msg->ParseFromArray(array, usize); +} + +void usage() { + printf( + "Usage: process_test [options] [-pb PROTOBUF_FILE]\n" + " [-ir REVERSE_FILE] [-i PRIMARY_FILE] [-o OUT_FILE]\n"); + printf( + "process_test is a test application for AudioProcessing.\n\n" + "When a protobuf debug file is available, specify it with -pb.\n" + "Alternately, when -ir or -i is used, the specified files will be\n" + "processed directly in a simulation mode. Otherwise the full set of\n" + "legacy test files is expected to be present in the working directory.\n"); + printf("\n"); + printf("Options\n"); + printf("General configuration (only used for the simulation mode):\n"); + printf(" -fs SAMPLE_RATE_HZ\n"); + printf(" -ch CHANNELS_IN CHANNELS_OUT\n"); + printf(" -rch REVERSE_CHANNELS\n"); + printf("\n"); + printf("Component configuration:\n"); + printf( + "All components are disabled by default. Each block below begins with a\n" + "flag to enable the component with default settings. The subsequent flags\n" + "in the block are used to provide configuration settings.\n"); + printf("\n -aec Echo cancellation\n"); + printf(" --drift_compensation\n"); + printf(" --no_drift_compensation\n"); + printf("\n -aecm Echo control mobile\n"); + printf(" --aecm_echo_path_in_file FILE\n"); + printf(" --aecm_echo_path_out_file FILE\n"); + printf("\n -agc Gain control\n"); + printf(" --analog\n"); + printf(" --adaptive_digital\n"); + printf(" --fixed_digital\n"); + printf(" --target_level LEVEL\n"); + printf(" --compression_gain GAIN\n"); + printf(" --limiter\n"); + printf(" --no_limiter\n"); + printf("\n -hpf High pass filter\n"); + printf("\n -ns Noise suppression\n"); + printf(" --ns_low\n"); + printf(" --ns_moderate\n"); + printf(" --ns_high\n"); + printf(" --ns_very_high\n"); + printf("\n -vad Voice activity detection\n"); + printf(" --vad_out_file FILE\n"); + printf("\n"); + printf("Modifiers:\n"); + printf(" --perf Measure performance.\n"); + printf(" --quiet Suppress text output.\n"); + printf(" --no_progress Suppress progress.\n"); + printf(" --version Print version information and exit.\n"); +} + +// void function for gtest. +void void_main(int argc, char* argv[]) { + if (argc > 1 && strcmp(argv[1], "--help") == 0) { + usage(); + return; + } + + if (argc < 2) { + printf("Did you mean to run without arguments?\n"); + printf("Try `process_test --help' for more information.\n\n"); + } + + AudioProcessing* apm = AudioProcessing::Create(0); + ASSERT_TRUE(apm != NULL); + + WebRtc_Word8 version[1024]; + WebRtc_UWord32 version_bytes_remaining = sizeof(version); + WebRtc_UWord32 version_position = 0; + + const char* pb_filename = NULL; + const char* far_filename = NULL; + const char* near_filename = NULL; + const char* out_filename = NULL; + const char* vad_out_filename = NULL; + const char* aecm_echo_path_in_filename = NULL; + const char* aecm_echo_path_out_filename = NULL; + + int32_t sample_rate_hz = 16000; + int32_t device_sample_rate_hz = 16000; + + int num_capture_input_channels = 1; + int num_capture_output_channels = 1; + int num_render_channels = 1; + + int samples_per_channel = sample_rate_hz / 100; + + bool simulating = false; + bool perf_testing = false; + bool verbose = true; + bool progress = true; + //bool interleaved = true; + + for (int i = 1; i < argc; i++) { + if (strcmp(argv[i], "-pb") == 0) { + i++; + ASSERT_LT(i, argc) << "Specify protobuf filename after -pb"; + pb_filename = argv[i]; + + } else if (strcmp(argv[i], "-ir") == 0) { + i++; + ASSERT_LT(i, argc) << "Specify filename after -ir"; + far_filename = argv[i]; + simulating = true; + + } else if (strcmp(argv[i], "-i") == 0) { + i++; + ASSERT_LT(i, argc) << "Specify filename after -i"; + near_filename = argv[i]; + simulating = true; + + } else if (strcmp(argv[i], "-o") == 0) { + i++; + ASSERT_LT(i, argc) << "Specify filename after -o"; + out_filename = argv[i]; + + } else if (strcmp(argv[i], "-fs") == 0) { + i++; + ASSERT_LT(i, argc) << "Specify sample rate after -fs"; + ASSERT_EQ(1, sscanf(argv[i], "%d", &sample_rate_hz)); + samples_per_channel = sample_rate_hz / 100; + + ASSERT_EQ(apm->kNoError, + apm->set_sample_rate_hz(sample_rate_hz)); + + } else if (strcmp(argv[i], "-ch") == 0) { + i++; + ASSERT_LT(i + 1, argc) << "Specify number of channels after -ch"; + ASSERT_EQ(1, sscanf(argv[i], "%d", &num_capture_input_channels)); + i++; + ASSERT_EQ(1, sscanf(argv[i], "%d", &num_capture_output_channels)); + + ASSERT_EQ(apm->kNoError, + apm->set_num_channels(num_capture_input_channels, + num_capture_output_channels)); + + } else if (strcmp(argv[i], "-rch") == 0) { + i++; + ASSERT_LT(i, argc) << "Specify number of channels after -rch"; + ASSERT_EQ(1, sscanf(argv[i], "%d", &num_render_channels)); + + ASSERT_EQ(apm->kNoError, + apm->set_num_reverse_channels(num_render_channels)); + + } else if (strcmp(argv[i], "-aec") == 0) { + ASSERT_EQ(apm->kNoError, apm->echo_cancellation()->Enable(true)); + + } else if (strcmp(argv[i], "-noasm") == 0) { + WebRtc_GetCPUInfo = WebRtc_GetCPUInfoNoASM; + + } else if (strcmp(argv[i], "--drift_compensation") == 0) { + ASSERT_EQ(apm->kNoError, apm->echo_cancellation()->Enable(true)); + // TODO(ajm): this is enabled in the VQE test app by default. Investigate + // why it can give better performance despite passing zeros. + ASSERT_EQ(apm->kNoError, + apm->echo_cancellation()->enable_drift_compensation(true)); + } else if (strcmp(argv[i], "--no_drift_compensation") == 0) { + ASSERT_EQ(apm->kNoError, apm->echo_cancellation()->Enable(true)); + ASSERT_EQ(apm->kNoError, + apm->echo_cancellation()->enable_drift_compensation(false)); + + } else if (strcmp(argv[i], "-aecm") == 0) { + ASSERT_EQ(apm->kNoError, apm->echo_control_mobile()->Enable(true)); + + } else if (strcmp(argv[i], "--aecm_echo_path_in_file") == 0) { + i++; + ASSERT_LT(i, argc) << "Specify filename after --aecm_echo_path_in_file"; + aecm_echo_path_in_filename = argv[i]; + + } else if (strcmp(argv[i], "--aecm_echo_path_out_file") == 0) { + i++; + ASSERT_LT(i, argc) << "Specify filename after --aecm_echo_path_out_file"; + aecm_echo_path_out_filename = argv[i]; + + } else if (strcmp(argv[i], "-agc") == 0) { + ASSERT_EQ(apm->kNoError, apm->gain_control()->Enable(true)); + + } else if (strcmp(argv[i], "--analog") == 0) { + ASSERT_EQ(apm->kNoError, apm->gain_control()->Enable(true)); + ASSERT_EQ(apm->kNoError, + apm->gain_control()->set_mode(GainControl::kAdaptiveAnalog)); + + } else if (strcmp(argv[i], "--adaptive_digital") == 0) { + ASSERT_EQ(apm->kNoError, apm->gain_control()->Enable(true)); + ASSERT_EQ(apm->kNoError, + apm->gain_control()->set_mode(GainControl::kAdaptiveDigital)); + + } else if (strcmp(argv[i], "--fixed_digital") == 0) { + ASSERT_EQ(apm->kNoError, apm->gain_control()->Enable(true)); + ASSERT_EQ(apm->kNoError, + apm->gain_control()->set_mode(GainControl::kFixedDigital)); + + } else if (strcmp(argv[i], "--target_level") == 0) { + i++; + int level; + ASSERT_EQ(1, sscanf(argv[i], "%d", &level)); + + ASSERT_EQ(apm->kNoError, apm->gain_control()->Enable(true)); + ASSERT_EQ(apm->kNoError, + apm->gain_control()->set_target_level_dbfs(level)); + + } else if (strcmp(argv[i], "--compression_gain") == 0) { + i++; + int gain; + ASSERT_EQ(1, sscanf(argv[i], "%d", &gain)); + + ASSERT_EQ(apm->kNoError, apm->gain_control()->Enable(true)); + ASSERT_EQ(apm->kNoError, + apm->gain_control()->set_compression_gain_db(gain)); + + } else if (strcmp(argv[i], "--limiter") == 0) { + ASSERT_EQ(apm->kNoError, apm->gain_control()->Enable(true)); + ASSERT_EQ(apm->kNoError, + apm->gain_control()->enable_limiter(true)); + + } else if (strcmp(argv[i], "--no_limiter") == 0) { + ASSERT_EQ(apm->kNoError, apm->gain_control()->Enable(true)); + ASSERT_EQ(apm->kNoError, + apm->gain_control()->enable_limiter(false)); + + } else if (strcmp(argv[i], "-hpf") == 0) { + ASSERT_EQ(apm->kNoError, apm->high_pass_filter()->Enable(true)); + + } else if (strcmp(argv[i], "-ns") == 0) { + ASSERT_EQ(apm->kNoError, apm->noise_suppression()->Enable(true)); + + } else if (strcmp(argv[i], "--ns_low") == 0) { + ASSERT_EQ(apm->kNoError, apm->noise_suppression()->Enable(true)); + ASSERT_EQ(apm->kNoError, + apm->noise_suppression()->set_level(NoiseSuppression::kLow)); + + } else if (strcmp(argv[i], "--ns_moderate") == 0) { + ASSERT_EQ(apm->kNoError, apm->noise_suppression()->Enable(true)); + ASSERT_EQ(apm->kNoError, + apm->noise_suppression()->set_level(NoiseSuppression::kModerate)); + + } else if (strcmp(argv[i], "--ns_high") == 0) { + ASSERT_EQ(apm->kNoError, apm->noise_suppression()->Enable(true)); + ASSERT_EQ(apm->kNoError, + apm->noise_suppression()->set_level(NoiseSuppression::kHigh)); + + } else if (strcmp(argv[i], "--ns_very_high") == 0) { + ASSERT_EQ(apm->kNoError, apm->noise_suppression()->Enable(true)); + ASSERT_EQ(apm->kNoError, + apm->noise_suppression()->set_level(NoiseSuppression::kVeryHigh)); + + } else if (strcmp(argv[i], "-vad") == 0) { + ASSERT_EQ(apm->kNoError, apm->voice_detection()->Enable(true)); + + } else if (strcmp(argv[i], "--vad_out_file") == 0) { + i++; + ASSERT_LT(i, argc) << "Specify filename after --vad_out_file"; + vad_out_filename = argv[i]; + + } else if (strcmp(argv[i], "--perf") == 0) { + perf_testing = true; + + } else if (strcmp(argv[i], "--quiet") == 0) { + verbose = false; + progress = false; + + } else if (strcmp(argv[i], "--no_progress") == 0) { + progress = false; + + } else if (strcmp(argv[i], "--version") == 0) { + ASSERT_EQ(apm->kNoError, apm->Version(version, + version_bytes_remaining, + version_position)); + printf("%s\n", version); + return; + + } else if (strcmp(argv[i], "--debug_recording") == 0) { + i++; + ASSERT_LT(i, argc) << "Specify filename after --debug_recording"; + ASSERT_EQ(apm->kNoError, apm->StartDebugRecording(argv[i])); + } else { + FAIL() << "Unrecognized argument " << argv[i]; + } + } + // If we're reading a protobuf file, ensure a simulation hasn't also + // been requested (which makes no sense...) + ASSERT_FALSE(pb_filename && simulating); + + if (verbose) { + printf("Sample rate: %d Hz\n", sample_rate_hz); + printf("Primary channels: %d (in), %d (out)\n", + num_capture_input_channels, + num_capture_output_channels); + printf("Reverse channels: %d \n", num_render_channels); + } + + const char far_file_default[] = "apm_far.pcm"; + const char near_file_default[] = "apm_near.pcm"; + const char out_file_default[] = "out.pcm"; + const char event_filename[] = "apm_event.dat"; + const char delay_filename[] = "apm_delay.dat"; + const char drift_filename[] = "apm_drift.dat"; + const char vad_file_default[] = "vad_out.dat"; + + if (!simulating) { + far_filename = far_file_default; + near_filename = near_file_default; + } + + if (!out_filename) { + out_filename = out_file_default; + } + + if (!vad_out_filename) { + vad_out_filename = vad_file_default; + } + + FILE* pb_file = NULL; + FILE* far_file = NULL; + FILE* near_file = NULL; + FILE* out_file = NULL; + FILE* event_file = NULL; + FILE* delay_file = NULL; + FILE* drift_file = NULL; + FILE* vad_out_file = NULL; + FILE* aecm_echo_path_in_file = NULL; + FILE* aecm_echo_path_out_file = NULL; + + if (pb_filename) { + pb_file = fopen(pb_filename, "rb"); + ASSERT_TRUE(NULL != pb_file) << "Unable to open protobuf file " + << pb_filename; + } else { + if (far_filename) { + far_file = fopen(far_filename, "rb"); + ASSERT_TRUE(NULL != far_file) << "Unable to open far-end audio file " + << far_filename; + } + + near_file = fopen(near_filename, "rb"); + ASSERT_TRUE(NULL != near_file) << "Unable to open near-end audio file " + << near_filename; + if (!simulating) { + event_file = fopen(event_filename, "rb"); + ASSERT_TRUE(NULL != event_file) << "Unable to open event file " + << event_filename; + + delay_file = fopen(delay_filename, "rb"); + ASSERT_TRUE(NULL != delay_file) << "Unable to open buffer file " + << delay_filename; + + drift_file = fopen(drift_filename, "rb"); + ASSERT_TRUE(NULL != drift_file) << "Unable to open drift file " + << drift_filename; + } + } + + out_file = fopen(out_filename, "wb"); + ASSERT_TRUE(NULL != out_file) << "Unable to open output audio file " + << out_filename; + + int near_size_samples = 0; + if (pb_file) { + struct stat st; + stat(pb_filename, &st); + // Crude estimate, but should be good enough. + near_size_samples = st.st_size / 3 / sizeof(int16_t); + } else { + struct stat st; + stat(near_filename, &st); + near_size_samples = st.st_size / sizeof(int16_t); + } + + if (apm->voice_detection()->is_enabled()) { + vad_out_file = fopen(vad_out_filename, "wb"); + ASSERT_TRUE(NULL != vad_out_file) << "Unable to open VAD output file " + << vad_out_file; + } + + if (aecm_echo_path_in_filename != NULL) { + aecm_echo_path_in_file = fopen(aecm_echo_path_in_filename, "rb"); + ASSERT_TRUE(NULL != aecm_echo_path_in_file) << "Unable to open file " + << aecm_echo_path_in_filename; + + const size_t path_size = + apm->echo_control_mobile()->echo_path_size_bytes(); + unsigned char echo_path[path_size]; + ASSERT_EQ(path_size, fread(echo_path, + sizeof(unsigned char), + path_size, + aecm_echo_path_in_file)); + EXPECT_EQ(apm->kNoError, + apm->echo_control_mobile()->SetEchoPath(echo_path, path_size)); + fclose(aecm_echo_path_in_file); + aecm_echo_path_in_file = NULL; + } + + if (aecm_echo_path_out_filename != NULL) { + aecm_echo_path_out_file = fopen(aecm_echo_path_out_filename, "wb"); + ASSERT_TRUE(NULL != aecm_echo_path_out_file) << "Unable to open file " + << aecm_echo_path_out_filename; + } + + enum Events { + kInitializeEvent, + kRenderEvent, + kCaptureEvent, + kResetEventDeprecated + }; + int16_t event = 0; + size_t read_count = 0; + int reverse_count = 0; + int primary_count = 0; + int near_read_samples = 0; + TickInterval acc_ticks; + + AudioFrame far_frame; + far_frame._frequencyInHz = sample_rate_hz; + + AudioFrame near_frame; + near_frame._frequencyInHz = sample_rate_hz; + + int delay_ms = 0; + int drift_samples = 0; + int capture_level = 127; + int8_t stream_has_voice = 0; + + TickTime t0 = TickTime::Now(); + TickTime t1 = t0; + WebRtc_Word64 max_time_us = 0; + WebRtc_Word64 max_time_reverse_us = 0; + WebRtc_Word64 min_time_us = 1e6; + WebRtc_Word64 min_time_reverse_us = 1e6; + + // TODO(ajm): Ideally we would refactor this block into separate functions, + // but for now we want to share the variables. + if (pb_file) { + Event event_msg; + while (ReadMessageFromFile(pb_file, &event_msg)) { + std::ostringstream trace_stream; + trace_stream << "Processed frames: " << reverse_count << " (reverse), " + << primary_count << " (primary)"; + SCOPED_TRACE(trace_stream.str()); + + if (event_msg.type() == Event::INIT) { + ASSERT_TRUE(event_msg.has_init()); + const Init msg = event_msg.init(); + + ASSERT_TRUE(msg.has_sample_rate()); + ASSERT_EQ(apm->kNoError, + apm->set_sample_rate_hz(msg.sample_rate())); + + ASSERT_TRUE(msg.has_device_sample_rate()); + ASSERT_EQ(apm->kNoError, + apm->echo_cancellation()->set_device_sample_rate_hz( + msg.device_sample_rate())); + + ASSERT_TRUE(msg.has_num_input_channels()); + ASSERT_TRUE(msg.has_num_output_channels()); + ASSERT_EQ(apm->kNoError, + apm->set_num_channels(msg.num_input_channels(), + msg.num_output_channels())); + + ASSERT_TRUE(msg.has_num_reverse_channels()); + ASSERT_EQ(apm->kNoError, + apm->set_num_reverse_channels(msg.num_reverse_channels())); + + samples_per_channel = msg.sample_rate() / 100; + far_frame._frequencyInHz = msg.sample_rate(); + far_frame._payloadDataLengthInSamples = + msg.num_reverse_channels() * samples_per_channel; + near_frame._frequencyInHz = msg.sample_rate(); + + if (verbose) { + printf("Init at frame: %d (primary), %d (reverse)\n", + primary_count, reverse_count); + printf(" Sample rate: %d Hz\n", sample_rate_hz); + } + + } else if (event_msg.type() == Event::REVERSE_STREAM) { + ASSERT_TRUE(event_msg.has_reverse_stream()); + const ReverseStream msg = event_msg.reverse_stream(); + reverse_count++; + + ASSERT_TRUE(msg.has_data()); + ASSERT_EQ(sizeof(int16_t) * far_frame._payloadDataLengthInSamples, + msg.data().size()); + memcpy(far_frame._payloadData, msg.data().data(), msg.data().size()); + + if (perf_testing) { + t0 = TickTime::Now(); + } + + ASSERT_EQ(apm->kNoError, + apm->AnalyzeReverseStream(&far_frame)); + + if (perf_testing) { + t1 = TickTime::Now(); + TickInterval tick_diff = t1 - t0; + acc_ticks += tick_diff; + if (tick_diff.Microseconds() > max_time_reverse_us) { + max_time_reverse_us = tick_diff.Microseconds(); + } + if (tick_diff.Microseconds() < min_time_reverse_us) { + min_time_reverse_us = tick_diff.Microseconds(); + } + } + + } else if (event_msg.type() == Event::STREAM) { + ASSERT_TRUE(event_msg.has_stream()); + const Stream msg = event_msg.stream(); + primary_count++; + + near_frame._audioChannel = apm->num_input_channels(); + near_frame._payloadDataLengthInSamples = + apm->num_input_channels() * samples_per_channel; + + ASSERT_TRUE(msg.has_input_data()); + ASSERT_EQ(sizeof(int16_t) * near_frame._payloadDataLengthInSamples, + msg.input_data().size()); + memcpy(near_frame._payloadData, + msg.input_data().data(), + msg.input_data().size()); + + near_read_samples += near_frame._payloadDataLengthInSamples; + if (progress && primary_count % 100 == 0) { + printf("%.0f%% complete\r", + (near_read_samples * 100.0) / near_size_samples); + fflush(stdout); + } + + if (perf_testing) { + t0 = TickTime::Now(); + } + + ASSERT_EQ(apm->kNoError, + apm->gain_control()->set_stream_analog_level(msg.level())); + ASSERT_EQ(apm->kNoError, + apm->set_stream_delay_ms(msg.delay())); + ASSERT_EQ(apm->kNoError, + apm->echo_cancellation()->set_stream_drift_samples(msg.drift())); + + int err = apm->ProcessStream(&near_frame); + if (err == apm->kBadStreamParameterWarning) { + printf("Bad parameter warning. %s\n", trace_stream.str().c_str()); + } + ASSERT_TRUE(err == apm->kNoError || + err == apm->kBadStreamParameterWarning); + + capture_level = apm->gain_control()->stream_analog_level(); + + stream_has_voice = + static_cast(apm->voice_detection()->stream_has_voice()); + if (vad_out_file != NULL) { + ASSERT_EQ(1u, fwrite(&stream_has_voice, + sizeof(stream_has_voice), + 1, + vad_out_file)); + } + + if (apm->gain_control()->mode() != GainControl::kAdaptiveAnalog) { + ASSERT_EQ(msg.level(), capture_level); + } + + if (perf_testing) { + t1 = TickTime::Now(); + TickInterval tick_diff = t1 - t0; + acc_ticks += tick_diff; + if (tick_diff.Microseconds() > max_time_us) { + max_time_us = tick_diff.Microseconds(); + } + if (tick_diff.Microseconds() < min_time_us) { + min_time_us = tick_diff.Microseconds(); + } + } + + ASSERT_EQ(near_frame._payloadDataLengthInSamples, + fwrite(near_frame._payloadData, + sizeof(int16_t), + near_frame._payloadDataLengthInSamples, + out_file)); + } + } + + ASSERT_TRUE(feof(pb_file)); + printf("100%% complete\r"); + + } else { + while (simulating || feof(event_file) == 0) { + std::ostringstream trace_stream; + trace_stream << "Processed frames: " << reverse_count << " (reverse), " + << primary_count << " (primary)"; + SCOPED_TRACE(trace_stream.str()); + + if (simulating) { + if (far_file == NULL) { + event = kCaptureEvent; + } else { + if (event == kRenderEvent) { + event = kCaptureEvent; + } else { + event = kRenderEvent; + } + } + } else { + read_count = fread(&event, sizeof(event), 1, event_file); + if (read_count != 1) { + break; + } + } + + if (event == kInitializeEvent || event == kResetEventDeprecated) { + ASSERT_EQ(1u, + fread(&sample_rate_hz, sizeof(sample_rate_hz), 1, event_file)); + samples_per_channel = sample_rate_hz / 100; + + ASSERT_EQ(1u, + fread(&device_sample_rate_hz, + sizeof(device_sample_rate_hz), + 1, + event_file)); + + ASSERT_EQ(apm->kNoError, + apm->set_sample_rate_hz(sample_rate_hz)); + + ASSERT_EQ(apm->kNoError, + apm->echo_cancellation()->set_device_sample_rate_hz( + device_sample_rate_hz)); + + far_frame._frequencyInHz = sample_rate_hz; + near_frame._frequencyInHz = sample_rate_hz; + + if (verbose) { + printf("Init at frame: %d (primary), %d (reverse)\n", + primary_count, reverse_count); + printf(" Sample rate: %d Hz\n", sample_rate_hz); + } + + } else if (event == kRenderEvent) { + reverse_count++; + far_frame._audioChannel = num_render_channels; + far_frame._payloadDataLengthInSamples = + num_render_channels * samples_per_channel; + + read_count = fread(far_frame._payloadData, + sizeof(WebRtc_Word16), + far_frame._payloadDataLengthInSamples, + far_file); + + if (simulating) { + if (read_count != far_frame._payloadDataLengthInSamples) { + break; // This is expected. + } + } else { + ASSERT_EQ(read_count, + far_frame._payloadDataLengthInSamples); + } + + if (perf_testing) { + t0 = TickTime::Now(); + } + + ASSERT_EQ(apm->kNoError, + apm->AnalyzeReverseStream(&far_frame)); + + if (perf_testing) { + t1 = TickTime::Now(); + TickInterval tick_diff = t1 - t0; + acc_ticks += tick_diff; + if (tick_diff.Microseconds() > max_time_reverse_us) { + max_time_reverse_us = tick_diff.Microseconds(); + } + if (tick_diff.Microseconds() < min_time_reverse_us) { + min_time_reverse_us = tick_diff.Microseconds(); + } + } + + } else if (event == kCaptureEvent) { + primary_count++; + near_frame._audioChannel = num_capture_input_channels; + near_frame._payloadDataLengthInSamples = + num_capture_input_channels * samples_per_channel; + + read_count = fread(near_frame._payloadData, + sizeof(WebRtc_Word16), + near_frame._payloadDataLengthInSamples, + near_file); + + near_read_samples += read_count; + if (progress && primary_count % 100 == 0) { + printf("%.0f%% complete\r", + (near_read_samples * 100.0) / near_size_samples); + fflush(stdout); + } + if (simulating) { + if (read_count != near_frame._payloadDataLengthInSamples) { + break; // This is expected. + } + + delay_ms = 0; + drift_samples = 0; + } else { + ASSERT_EQ(read_count, + near_frame._payloadDataLengthInSamples); + + // TODO(ajm): sizeof(delay_ms) for current files? + ASSERT_EQ(1u, + fread(&delay_ms, 2, 1, delay_file)); + ASSERT_EQ(1u, + fread(&drift_samples, sizeof(drift_samples), 1, drift_file)); + } + + if (perf_testing) { + t0 = TickTime::Now(); + } + + // TODO(ajm): fake an analog gain while simulating. + + int capture_level_in = capture_level; + ASSERT_EQ(apm->kNoError, + apm->gain_control()->set_stream_analog_level(capture_level)); + ASSERT_EQ(apm->kNoError, + apm->set_stream_delay_ms(delay_ms)); + ASSERT_EQ(apm->kNoError, + apm->echo_cancellation()->set_stream_drift_samples(drift_samples)); + + int err = apm->ProcessStream(&near_frame); + if (err == apm->kBadStreamParameterWarning) { + printf("Bad parameter warning. %s\n", trace_stream.str().c_str()); + } + ASSERT_TRUE(err == apm->kNoError || + err == apm->kBadStreamParameterWarning); + + capture_level = apm->gain_control()->stream_analog_level(); + + stream_has_voice = + static_cast(apm->voice_detection()->stream_has_voice()); + if (vad_out_file != NULL) { + ASSERT_EQ(1u, fwrite(&stream_has_voice, + sizeof(stream_has_voice), + 1, + vad_out_file)); + } + + if (apm->gain_control()->mode() != GainControl::kAdaptiveAnalog) { + ASSERT_EQ(capture_level_in, capture_level); + } + + if (perf_testing) { + t1 = TickTime::Now(); + TickInterval tick_diff = t1 - t0; + acc_ticks += tick_diff; + if (tick_diff.Microseconds() > max_time_us) { + max_time_us = tick_diff.Microseconds(); + } + if (tick_diff.Microseconds() < min_time_us) { + min_time_us = tick_diff.Microseconds(); + } + } + + ASSERT_EQ(near_frame._payloadDataLengthInSamples, + fwrite(near_frame._payloadData, + sizeof(WebRtc_Word16), + near_frame._payloadDataLengthInSamples, + out_file)); + } + else { + FAIL() << "Event " << event << " is unrecognized"; + } + } + } + + if (aecm_echo_path_out_file != NULL) { + const size_t path_size = + apm->echo_control_mobile()->echo_path_size_bytes(); + unsigned char echo_path[path_size]; + apm->echo_control_mobile()->GetEchoPath(echo_path, path_size); + ASSERT_EQ(path_size, fwrite(echo_path, + sizeof(unsigned char), + path_size, + aecm_echo_path_out_file)); + fclose(aecm_echo_path_out_file); + aecm_echo_path_out_file = NULL; + } + + if (verbose) { + printf("\nProcessed frames: %d (primary), %d (reverse)\n", + primary_count, reverse_count); + } + + if (!pb_file) { + int8_t temp_int8; + if (far_file) { + read_count = fread(&temp_int8, sizeof(temp_int8), 1, far_file); + EXPECT_NE(0, feof(far_file)) << "Far-end file not fully processed"; + } + + read_count = fread(&temp_int8, sizeof(temp_int8), 1, near_file); + EXPECT_NE(0, feof(near_file)) << "Near-end file not fully processed"; + + if (!simulating) { + read_count = fread(&temp_int8, sizeof(temp_int8), 1, event_file); + EXPECT_NE(0, feof(event_file)) << "Event file not fully processed"; + read_count = fread(&temp_int8, sizeof(temp_int8), 1, delay_file); + EXPECT_NE(0, feof(delay_file)) << "Delay file not fully processed"; + read_count = fread(&temp_int8, sizeof(temp_int8), 1, drift_file); + EXPECT_NE(0, feof(drift_file)) << "Drift file not fully processed"; + } + } + + if (perf_testing) { + if (primary_count > 0) { + WebRtc_Word64 exec_time = acc_ticks.Milliseconds(); + printf("\nTotal time: %.3f s, file time: %.2f s\n", + exec_time * 0.001, primary_count * 0.01); + printf("Time per frame: %.3f ms (average), %.3f ms (max)," + " %.3f ms (min)\n", + (exec_time * 1.0) / primary_count, + (max_time_us + max_time_reverse_us) / 1000.0, + (min_time_us + min_time_reverse_us) / 1000.0); + } else { + printf("Warning: no capture frames\n"); + } + } + + AudioProcessing::Destroy(apm); + apm = NULL; +} +} // namespace + +int main(int argc, char* argv[]) +{ + void_main(argc, argv); + + // Optional, but removes memory leak noise from Valgrind. + google::protobuf::ShutdownProtobufLibrary(); + return 0; +} diff --git a/src/modules/audio_processing/main/test/unit_test/unit_test.cc b/src/modules/audio_processing/main/test/unit_test/unit_test.cc new file mode 100644 index 0000000..0563fdf --- /dev/null +++ b/src/modules/audio_processing/main/test/unit_test/unit_test.cc @@ -0,0 +1,1008 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +#include + +#include + +#include "audio_processing.h" +#include "event_wrapper.h" +#include "module_common_types.h" +#include "signal_processing_library.h" +#include "thread_wrapper.h" +#include "trace.h" +#ifdef WEBRTC_ANDROID +#include "external/webrtc/src/modules/audio_processing/main/test/unit_test/unittest.pb.h" +#else +#include "webrtc/audio_processing/unittest.pb.h" +#endif + +using webrtc::AudioProcessing; +using webrtc::AudioFrame; +using webrtc::GainControl; +using webrtc::NoiseSuppression; +using webrtc::EchoCancellation; +using webrtc::EventWrapper; +using webrtc::Trace; +using webrtc::LevelEstimator; +using webrtc::EchoCancellation; +using webrtc::EchoControlMobile; +using webrtc::VoiceDetection; + +namespace { +// When false, this will compare the output data with the results stored to +// file. This is the typical case. When the file should be updated, it can +// be set to true with the command-line switch --write_output_data. +bool write_output_data = false; + +#if defined(WEBRTC_APM_UNIT_TEST_FIXED_PROFILE) +const char kOutputFileName[] = "output_data_fixed.pb"; +#elif defined(WEBRTC_APM_UNIT_TEST_FLOAT_PROFILE) +const char kOutputFileName[] = "output_data_float.pb"; +#endif + +class ApmEnvironment : public ::testing::Environment { + public: + virtual void SetUp() { + Trace::CreateTrace(); + ASSERT_EQ(0, Trace::SetTraceFile("apm_trace.txt")); + } + + virtual void TearDown() { + Trace::ReturnTrace(); + } +}; + +class ApmTest : public ::testing::Test { + protected: + ApmTest(); + virtual void SetUp(); + virtual void TearDown(); + + webrtc::AudioProcessing* apm_; + webrtc::AudioFrame* frame_; + webrtc::AudioFrame* revframe_; + FILE* far_file_; + FILE* near_file_; +}; + +ApmTest::ApmTest() + : apm_(NULL), + frame_(NULL), + revframe_(NULL), + far_file_(NULL), + near_file_(NULL) {} + +void ApmTest::SetUp() { + apm_ = AudioProcessing::Create(0); + ASSERT_TRUE(apm_ != NULL); + + frame_ = new AudioFrame(); + revframe_ = new AudioFrame(); + + ASSERT_EQ(apm_->kNoError, apm_->set_sample_rate_hz(32000)); + ASSERT_EQ(apm_->kNoError, apm_->set_num_channels(2, 2)); + ASSERT_EQ(apm_->kNoError, apm_->set_num_reverse_channels(2)); + + frame_->_payloadDataLengthInSamples = 320; + frame_->_audioChannel = 2; + frame_->_frequencyInHz = 32000; + revframe_->_payloadDataLengthInSamples = 320; + revframe_->_audioChannel = 2; + revframe_->_frequencyInHz = 32000; + + far_file_ = fopen("aec_far.pcm", "rb"); + ASSERT_TRUE(far_file_ != NULL) << "Could not open input file aec_far.pcm\n"; + near_file_ = fopen("aec_near.pcm", "rb"); + ASSERT_TRUE(near_file_ != NULL) << "Could not open input file aec_near.pcm\n"; +} + +void ApmTest::TearDown() { + if (frame_) { + delete frame_; + } + frame_ = NULL; + + if (revframe_) { + delete revframe_; + } + revframe_ = NULL; + + if (far_file_) { + ASSERT_EQ(0, fclose(far_file_)); + } + far_file_ = NULL; + + if (near_file_) { + ASSERT_EQ(0, fclose(near_file_)); + } + near_file_ = NULL; + + if (apm_ != NULL) { + AudioProcessing::Destroy(apm_); + } + apm_ = NULL; +} + +void MixStereoToMono(const WebRtc_Word16* stereo, + WebRtc_Word16* mono, + int num_samples) { + for (int i = 0; i < num_samples; i++) { + int int32 = (static_cast(stereo[i * 2]) + + static_cast(stereo[i * 2 + 1])) >> 1; + mono[i] = static_cast(int32); + } +} + +template +T MaxValue(T a, T b) { + return a > b ? a : b; +} + +template +T AbsValue(T a) { + return a > 0 ? a : -a; +} + +WebRtc_Word16 MaxAudioFrame(const AudioFrame& frame) { + const int length = frame._payloadDataLengthInSamples * frame._audioChannel; + WebRtc_Word16 max = AbsValue(frame._payloadData[0]); + for (int i = 1; i < length; i++) { + max = MaxValue(max, AbsValue(frame._payloadData[i])); + } + + return max; +} + +void TestStats(const AudioProcessing::Statistic& test, + const webrtc::audioproc::Test::Statistic& reference) { + EXPECT_EQ(reference.instant(), test.instant); + EXPECT_EQ(reference.average(), test.average); + EXPECT_EQ(reference.maximum(), test.maximum); + EXPECT_EQ(reference.minimum(), test.minimum); +} + +void WriteStatsMessage(const AudioProcessing::Statistic& output, + webrtc::audioproc::Test::Statistic* message) { + message->set_instant(output.instant); + message->set_average(output.average); + message->set_maximum(output.maximum); + message->set_minimum(output.minimum); +} + +void WriteMessageLiteToFile(const char* filename, + const ::google::protobuf::MessageLite& message) { + assert(filename != NULL); + + FILE* file = fopen(filename, "wb"); + ASSERT_TRUE(file != NULL) << "Could not open " << filename; + int size = message.ByteSize(); + ASSERT_GT(size, 0); + unsigned char* array = new unsigned char[size]; + ASSERT_TRUE(message.SerializeToArray(array, size)); + + ASSERT_EQ(1u, fwrite(&size, sizeof(int), 1, file)); + ASSERT_EQ(static_cast(size), + fwrite(array, sizeof(unsigned char), size, file)); + + delete [] array; + fclose(file); +} + +void ReadMessageLiteFromFile(const char* filename, + ::google::protobuf::MessageLite* message) { + assert(filename != NULL); + assert(message != NULL); + + FILE* file = fopen(filename, "rb"); + ASSERT_TRUE(file != NULL) << "Could not open " << filename; + int size = 0; + ASSERT_EQ(1u, fread(&size, sizeof(int), 1, file)); + ASSERT_GT(size, 0); + unsigned char* array = new unsigned char[size]; + ASSERT_EQ(static_cast(size), + fread(array, sizeof(unsigned char), size, file)); + + ASSERT_TRUE(message->ParseFromArray(array, size)); + + delete [] array; + fclose(file); +} + +struct ThreadData { + ThreadData(int thread_num_, AudioProcessing* ap_) + : thread_num(thread_num_), + error(false), + ap(ap_) {} + int thread_num; + bool error; + AudioProcessing* ap; +}; + +// Don't use GTest here; non-thread-safe on Windows (as of 1.5.0). +bool DeadlockProc(void* thread_object) { + ThreadData* thread_data = static_cast(thread_object); + AudioProcessing* ap = thread_data->ap; + int err = ap->kNoError; + + AudioFrame primary_frame; + AudioFrame reverse_frame; + primary_frame._payloadDataLengthInSamples = 320; + primary_frame._audioChannel = 2; + primary_frame._frequencyInHz = 32000; + reverse_frame._payloadDataLengthInSamples = 320; + reverse_frame._audioChannel = 2; + reverse_frame._frequencyInHz = 32000; + + ap->echo_cancellation()->Enable(true); + ap->gain_control()->Enable(true); + ap->high_pass_filter()->Enable(true); + ap->level_estimator()->Enable(true); + ap->noise_suppression()->Enable(true); + ap->voice_detection()->Enable(true); + + if (thread_data->thread_num % 2 == 0) { + err = ap->AnalyzeReverseStream(&reverse_frame); + if (err != ap->kNoError) { + printf("Error in AnalyzeReverseStream(): %d\n", err); + thread_data->error = true; + return false; + } + } + + if (thread_data->thread_num % 2 == 1) { + ap->set_stream_delay_ms(0); + ap->echo_cancellation()->set_stream_drift_samples(0); + ap->gain_control()->set_stream_analog_level(0); + err = ap->ProcessStream(&primary_frame); + if (err == ap->kStreamParameterNotSetError) { + printf("Expected kStreamParameterNotSetError in ProcessStream(): %d\n", + err); + } else if (err != ap->kNoError) { + printf("Error in ProcessStream(): %d\n", err); + thread_data->error = true; + return false; + } + ap->gain_control()->stream_analog_level(); + } + + EventWrapper* event = EventWrapper::Create(); + event->Wait(1); + delete event; + event = NULL; + + return true; +} + +/*TEST_F(ApmTest, Deadlock) { + const int num_threads = 16; + std::vector threads(num_threads); + std::vector thread_data(num_threads); + + ASSERT_EQ(apm_->kNoError, apm_->set_sample_rate_hz(32000)); + ASSERT_EQ(apm_->kNoError, apm_->set_num_channels(2, 2)); + ASSERT_EQ(apm_->kNoError, apm_->set_num_reverse_channels(2)); + + for (int i = 0; i < num_threads; i++) { + thread_data[i] = new ThreadData(i, apm_); + threads[i] = ThreadWrapper::CreateThread(DeadlockProc, + thread_data[i], + kNormalPriority, + 0); + ASSERT_TRUE(threads[i] != NULL); + unsigned int thread_id = 0; + threads[i]->Start(thread_id); + } + + EventWrapper* event = EventWrapper::Create(); + ASSERT_EQ(kEventTimeout, event->Wait(5000)); + delete event; + event = NULL; + + for (int i = 0; i < num_threads; i++) { + // This will return false if the thread has deadlocked. + ASSERT_TRUE(threads[i]->Stop()); + ASSERT_FALSE(thread_data[i]->error); + delete threads[i]; + threads[i] = NULL; + delete thread_data[i]; + thread_data[i] = NULL; + } +}*/ + +TEST_F(ApmTest, StreamParameters) { + // No errors when the components are disabled. + EXPECT_EQ(apm_->kNoError, + apm_->ProcessStream(frame_)); + + // Missing agc level + EXPECT_EQ(apm_->kNoError, apm_->Initialize()); + EXPECT_EQ(apm_->kNoError, apm_->gain_control()->Enable(true)); + EXPECT_EQ(apm_->kStreamParameterNotSetError, + apm_->ProcessStream(frame_)); + EXPECT_EQ(apm_->kNoError, apm_->set_stream_delay_ms(100)); + EXPECT_EQ(apm_->kNoError, + apm_->echo_cancellation()->set_stream_drift_samples(0)); + EXPECT_EQ(apm_->kStreamParameterNotSetError, + apm_->ProcessStream(frame_)); + EXPECT_EQ(apm_->kNoError, apm_->gain_control()->Enable(false)); + + // Missing delay + EXPECT_EQ(apm_->kNoError, apm_->Initialize()); + EXPECT_EQ(apm_->kNoError, apm_->echo_cancellation()->Enable(true)); + EXPECT_EQ(apm_->kStreamParameterNotSetError, + apm_->ProcessStream(frame_)); + EXPECT_EQ(apm_->kNoError, apm_->gain_control()->Enable(true)); + EXPECT_EQ(apm_->kNoError, + apm_->echo_cancellation()->set_stream_drift_samples(0)); + EXPECT_EQ(apm_->kNoError, + apm_->gain_control()->set_stream_analog_level(127)); + EXPECT_EQ(apm_->kStreamParameterNotSetError, + apm_->ProcessStream(frame_)); + EXPECT_EQ(apm_->kNoError, apm_->gain_control()->Enable(false)); + + // Missing drift + EXPECT_EQ(apm_->kNoError, apm_->Initialize()); + EXPECT_EQ(apm_->kNoError, + apm_->echo_cancellation()->enable_drift_compensation(true)); + EXPECT_EQ(apm_->kStreamParameterNotSetError, + apm_->ProcessStream(frame_)); + EXPECT_EQ(apm_->kNoError, apm_->gain_control()->Enable(true)); + EXPECT_EQ(apm_->kNoError, apm_->set_stream_delay_ms(100)); + EXPECT_EQ(apm_->kNoError, + apm_->gain_control()->set_stream_analog_level(127)); + EXPECT_EQ(apm_->kStreamParameterNotSetError, + apm_->ProcessStream(frame_)); + + // No stream parameters + EXPECT_EQ(apm_->kNoError, apm_->Initialize()); + EXPECT_EQ(apm_->kNoError, + apm_->AnalyzeReverseStream(revframe_)); + EXPECT_EQ(apm_->kStreamParameterNotSetError, + apm_->ProcessStream(frame_)); + + // All there + EXPECT_EQ(apm_->kNoError, apm_->gain_control()->Enable(true)); + EXPECT_EQ(apm_->kNoError, apm_->Initialize()); + EXPECT_EQ(apm_->kNoError, apm_->set_stream_delay_ms(100)); + EXPECT_EQ(apm_->kNoError, + apm_->echo_cancellation()->set_stream_drift_samples(0)); + EXPECT_EQ(apm_->kNoError, + apm_->gain_control()->set_stream_analog_level(127)); + EXPECT_EQ(apm_->kNoError, apm_->ProcessStream(frame_)); +} + +TEST_F(ApmTest, Channels) { + // Testing number of invalid channels + EXPECT_EQ(apm_->kBadParameterError, apm_->set_num_channels(0, 1)); + EXPECT_EQ(apm_->kBadParameterError, apm_->set_num_channels(1, 0)); + EXPECT_EQ(apm_->kBadParameterError, apm_->set_num_channels(3, 1)); + EXPECT_EQ(apm_->kBadParameterError, apm_->set_num_channels(1, 3)); + EXPECT_EQ(apm_->kBadParameterError, apm_->set_num_reverse_channels(0)); + EXPECT_EQ(apm_->kBadParameterError, apm_->set_num_reverse_channels(3)); + // Testing number of valid channels + for (int i = 1; i < 3; i++) { + for (int j = 1; j < 3; j++) { + if (j > i) { + EXPECT_EQ(apm_->kBadParameterError, apm_->set_num_channels(i, j)); + } else { + EXPECT_EQ(apm_->kNoError, apm_->set_num_channels(i, j)); + EXPECT_EQ(j, apm_->num_output_channels()); + } + } + EXPECT_EQ(i, apm_->num_input_channels()); + EXPECT_EQ(apm_->kNoError, apm_->set_num_reverse_channels(i)); + EXPECT_EQ(i, apm_->num_reverse_channels()); + } +} + +TEST_F(ApmTest, SampleRates) { + // Testing invalid sample rates + EXPECT_EQ(apm_->kBadParameterError, apm_->set_sample_rate_hz(10000)); + // Testing valid sample rates + int fs[] = {8000, 16000, 32000}; + for (size_t i = 0; i < sizeof(fs) / sizeof(*fs); i++) { + EXPECT_EQ(apm_->kNoError, apm_->set_sample_rate_hz(fs[i])); + EXPECT_EQ(fs[i], apm_->sample_rate_hz()); + } +} + +TEST_F(ApmTest, Process) { + GOOGLE_PROTOBUF_VERIFY_VERSION; + webrtc::audioproc::OutputData output_data; + + if (!write_output_data) { + ReadMessageLiteFromFile(kOutputFileName, &output_data); + } else { + // We don't have a file; add the required tests to the protobuf. + // TODO(ajm): vary the output channels as well? + const int channels[] = {1, 2}; + const size_t channels_size = sizeof(channels) / sizeof(*channels); +#if defined(WEBRTC_APM_UNIT_TEST_FIXED_PROFILE) + // AECM doesn't support super-wb. + const int sample_rates[] = {8000, 16000}; +#elif defined(WEBRTC_APM_UNIT_TEST_FLOAT_PROFILE) + const int sample_rates[] = {8000, 16000, 32000}; +#endif + const size_t sample_rates_size = sizeof(sample_rates) / sizeof(*sample_rates); + for (size_t i = 0; i < channels_size; i++) { + for (size_t j = 0; j < channels_size; j++) { + for (size_t k = 0; k < sample_rates_size; k++) { + webrtc::audioproc::Test* test = output_data.add_test(); + test->set_num_reverse_channels(channels[i]); + test->set_num_input_channels(channels[j]); + test->set_num_output_channels(channels[j]); + test->set_sample_rate(sample_rates[k]); + } + } + } + } + +#if defined(WEBRTC_APM_UNIT_TEST_FIXED_PROFILE) + EXPECT_EQ(apm_->kNoError, apm_->set_sample_rate_hz(16000)); + EXPECT_EQ(apm_->kNoError, apm_->echo_control_mobile()->Enable(true)); + + EXPECT_EQ(apm_->kNoError, + apm_->gain_control()->set_mode(GainControl::kAdaptiveDigital)); + EXPECT_EQ(apm_->kNoError, apm_->gain_control()->Enable(true)); +#elif defined(WEBRTC_APM_UNIT_TEST_FLOAT_PROFILE) + EXPECT_EQ(apm_->kNoError, + apm_->echo_cancellation()->enable_drift_compensation(true)); + EXPECT_EQ(apm_->kNoError, + apm_->echo_cancellation()->enable_metrics(true)); + EXPECT_EQ(apm_->kNoError, apm_->echo_cancellation()->Enable(true)); + + EXPECT_EQ(apm_->kNoError, + apm_->gain_control()->set_mode(GainControl::kAdaptiveAnalog)); + EXPECT_EQ(apm_->kNoError, + apm_->gain_control()->set_analog_level_limits(0, 255)); + EXPECT_EQ(apm_->kNoError, apm_->gain_control()->Enable(true)); +#endif + + EXPECT_EQ(apm_->kNoError, + apm_->high_pass_filter()->Enable(true)); + + //EXPECT_EQ(apm_->kNoError, + // apm_->level_estimator()->Enable(true)); + + EXPECT_EQ(apm_->kNoError, + apm_->noise_suppression()->Enable(true)); + + EXPECT_EQ(apm_->kNoError, + apm_->voice_detection()->Enable(true)); + + for (int i = 0; i < output_data.test_size(); i++) { + printf("Running test %d of %d...\n", i + 1, output_data.test_size()); + + webrtc::audioproc::Test* test = output_data.mutable_test(i); + const int num_samples = test->sample_rate() / 100; + revframe_->_payloadDataLengthInSamples = num_samples; + revframe_->_audioChannel = test->num_reverse_channels(); + revframe_->_frequencyInHz = test->sample_rate(); + frame_->_payloadDataLengthInSamples = num_samples; + frame_->_audioChannel = test->num_input_channels(); + frame_->_frequencyInHz = test->sample_rate(); + + EXPECT_EQ(apm_->kNoError, apm_->Initialize()); + ASSERT_EQ(apm_->kNoError, apm_->set_sample_rate_hz(test->sample_rate())); + ASSERT_EQ(apm_->kNoError, apm_->set_num_channels(frame_->_audioChannel, + frame_->_audioChannel)); + ASSERT_EQ(apm_->kNoError, + apm_->set_num_reverse_channels(revframe_->_audioChannel)); + + int frame_count = 0; + int has_echo_count = 0; + int has_voice_count = 0; + int is_saturated_count = 0; + int analog_level = 127; + int analog_level_average = 0; + int max_output_average = 0; + + while (1) { + WebRtc_Word16 temp_data[640]; + + // Read far-end frame + size_t read_count = fread(temp_data, + sizeof(WebRtc_Word16), + num_samples * 2, + far_file_); + if (read_count != static_cast(num_samples * 2)) { + // Check that the file really ended. + ASSERT_NE(0, feof(far_file_)); + break; // This is expected. + } + + if (revframe_->_audioChannel == 1) { + MixStereoToMono(temp_data, revframe_->_payloadData, + revframe_->_payloadDataLengthInSamples); + } else { + memcpy(revframe_->_payloadData, + &temp_data[0], + sizeof(WebRtc_Word16) * read_count); + } + + EXPECT_EQ(apm_->kNoError, + apm_->AnalyzeReverseStream(revframe_)); + + EXPECT_EQ(apm_->kNoError, apm_->set_stream_delay_ms(0)); + EXPECT_EQ(apm_->kNoError, + apm_->echo_cancellation()->set_stream_drift_samples(0)); + EXPECT_EQ(apm_->kNoError, + apm_->gain_control()->set_stream_analog_level(analog_level)); + + // Read near-end frame + read_count = fread(temp_data, + sizeof(WebRtc_Word16), + num_samples * 2, + near_file_); + if (read_count != static_cast(num_samples * 2)) { + // Check that the file really ended. + ASSERT_NE(0, feof(near_file_)); + break; // This is expected. + } + + if (frame_->_audioChannel == 1) { + MixStereoToMono(temp_data, frame_->_payloadData, num_samples); + } else { + memcpy(frame_->_payloadData, + &temp_data[0], + sizeof(WebRtc_Word16) * read_count); + } + + EXPECT_EQ(apm_->kNoError, apm_->ProcessStream(frame_)); + + max_output_average += MaxAudioFrame(*frame_); + + if (apm_->echo_cancellation()->stream_has_echo()) { + has_echo_count++; + } + + analog_level = apm_->gain_control()->stream_analog_level(); + analog_level_average += analog_level; + if (apm_->gain_control()->stream_is_saturated()) { + is_saturated_count++; + } + if (apm_->voice_detection()->stream_has_voice()) { + has_voice_count++; + } + + frame_count++; + } + max_output_average /= frame_count; + analog_level_average /= frame_count; + + //LevelEstimator::Metrics far_metrics; + //LevelEstimator::Metrics near_metrics; + //EXPECT_EQ(apm_->kNoError, + // apm_->level_estimator()->GetMetrics(&near_metrics, + +#if defined(WEBRTC_APM_UNIT_TEST_FLOAT_PROFILE) + EchoCancellation::Metrics echo_metrics; + EXPECT_EQ(apm_->kNoError, + apm_->echo_cancellation()->GetMetrics(&echo_metrics)); +#endif + + if (!write_output_data) { + EXPECT_EQ(test->has_echo_count(), has_echo_count); + EXPECT_EQ(test->has_voice_count(), has_voice_count); + EXPECT_EQ(test->is_saturated_count(), is_saturated_count); + + EXPECT_EQ(test->analog_level_average(), analog_level_average); + EXPECT_EQ(test->max_output_average(), max_output_average); + +#if defined(WEBRTC_APM_UNIT_TEST_FLOAT_PROFILE) + webrtc::audioproc::Test::EchoMetrics reference = + test->echo_metrics(); + TestStats(echo_metrics.residual_echo_return_loss, + reference.residual_echo_return_loss()); + TestStats(echo_metrics.echo_return_loss, + reference.echo_return_loss()); + TestStats(echo_metrics.echo_return_loss_enhancement, + reference.echo_return_loss_enhancement()); + TestStats(echo_metrics.a_nlp, + reference.a_nlp()); +#endif + } else { + test->set_has_echo_count(has_echo_count); + test->set_has_voice_count(has_voice_count); + test->set_is_saturated_count(is_saturated_count); + + test->set_analog_level_average(analog_level_average); + test->set_max_output_average(max_output_average); + +#if defined(WEBRTC_APM_UNIT_TEST_FLOAT_PROFILE) + webrtc::audioproc::Test::EchoMetrics* message = + test->mutable_echo_metrics(); + WriteStatsMessage(echo_metrics.residual_echo_return_loss, + message->mutable_residual_echo_return_loss()); + WriteStatsMessage(echo_metrics.echo_return_loss, + message->mutable_echo_return_loss()); + WriteStatsMessage(echo_metrics.echo_return_loss_enhancement, + message->mutable_echo_return_loss_enhancement()); + WriteStatsMessage(echo_metrics.a_nlp, + message->mutable_a_nlp()); +#endif + } + + rewind(far_file_); + rewind(near_file_); + } + + if (write_output_data) { + WriteMessageLiteToFile(kOutputFileName, output_data); + } +} + +TEST_F(ApmTest, EchoCancellation) { + EXPECT_EQ(apm_->kNoError, + apm_->echo_cancellation()->enable_drift_compensation(true)); + EXPECT_TRUE(apm_->echo_cancellation()->is_drift_compensation_enabled()); + EXPECT_EQ(apm_->kNoError, + apm_->echo_cancellation()->enable_drift_compensation(false)); + EXPECT_FALSE(apm_->echo_cancellation()->is_drift_compensation_enabled()); + + EXPECT_EQ(apm_->kBadParameterError, + apm_->echo_cancellation()->set_device_sample_rate_hz(4000)); + EXPECT_EQ(apm_->kBadParameterError, + apm_->echo_cancellation()->set_device_sample_rate_hz(100000)); + + int rate[] = {16000, 44100, 48000}; + for (size_t i = 0; i < sizeof(rate)/sizeof(*rate); i++) { + EXPECT_EQ(apm_->kNoError, + apm_->echo_cancellation()->set_device_sample_rate_hz(rate[i])); + EXPECT_EQ(rate[i], + apm_->echo_cancellation()->device_sample_rate_hz()); + } + + EXPECT_EQ(apm_->kBadParameterError, + apm_->echo_cancellation()->set_suppression_level( + static_cast(-1))); + + EXPECT_EQ(apm_->kBadParameterError, + apm_->echo_cancellation()->set_suppression_level( + static_cast(4))); + + EchoCancellation::SuppressionLevel level[] = { + EchoCancellation::kLowSuppression, + EchoCancellation::kModerateSuppression, + EchoCancellation::kHighSuppression, + }; + for (size_t i = 0; i < sizeof(level)/sizeof(*level); i++) { + EXPECT_EQ(apm_->kNoError, + apm_->echo_cancellation()->set_suppression_level(level[i])); + EXPECT_EQ(level[i], + apm_->echo_cancellation()->suppression_level()); + } + + EchoCancellation::Metrics metrics; + EXPECT_EQ(apm_->kNotEnabledError, + apm_->echo_cancellation()->GetMetrics(&metrics)); + + EXPECT_EQ(apm_->kNoError, + apm_->echo_cancellation()->enable_metrics(true)); + EXPECT_TRUE(apm_->echo_cancellation()->are_metrics_enabled()); + EXPECT_EQ(apm_->kNoError, + apm_->echo_cancellation()->enable_metrics(false)); + EXPECT_FALSE(apm_->echo_cancellation()->are_metrics_enabled()); + + EXPECT_EQ(apm_->kNoError, apm_->echo_cancellation()->Enable(true)); + EXPECT_TRUE(apm_->echo_cancellation()->is_enabled()); + EXPECT_EQ(apm_->kNoError, apm_->echo_cancellation()->Enable(false)); + EXPECT_FALSE(apm_->echo_cancellation()->is_enabled()); +} + +TEST_F(ApmTest, EchoControlMobile) { + // AECM won't use super-wideband. + EXPECT_EQ(apm_->kNoError, apm_->set_sample_rate_hz(32000)); + EXPECT_EQ(apm_->kBadSampleRateError, apm_->echo_control_mobile()->Enable(true)); + EXPECT_EQ(apm_->kNoError, apm_->set_sample_rate_hz(16000)); + // Turn AECM on (and AEC off) + EXPECT_EQ(apm_->kNoError, apm_->echo_control_mobile()->Enable(true)); + EXPECT_TRUE(apm_->echo_control_mobile()->is_enabled()); + + EXPECT_EQ(apm_->kBadParameterError, + apm_->echo_control_mobile()->set_routing_mode( + static_cast(-1))); + EXPECT_EQ(apm_->kBadParameterError, + apm_->echo_control_mobile()->set_routing_mode( + static_cast(5))); + + // Toggle routing modes + EchoControlMobile::RoutingMode mode[] = { + EchoControlMobile::kQuietEarpieceOrHeadset, + EchoControlMobile::kEarpiece, + EchoControlMobile::kLoudEarpiece, + EchoControlMobile::kSpeakerphone, + EchoControlMobile::kLoudSpeakerphone, + }; + for (size_t i = 0; i < sizeof(mode)/sizeof(*mode); i++) { + EXPECT_EQ(apm_->kNoError, + apm_->echo_control_mobile()->set_routing_mode(mode[i])); + EXPECT_EQ(mode[i], + apm_->echo_control_mobile()->routing_mode()); + } + // Turn comfort noise off/on + EXPECT_EQ(apm_->kNoError, + apm_->echo_control_mobile()->enable_comfort_noise(false)); + EXPECT_FALSE(apm_->echo_control_mobile()->is_comfort_noise_enabled()); + EXPECT_EQ(apm_->kNoError, + apm_->echo_control_mobile()->enable_comfort_noise(true)); + EXPECT_TRUE(apm_->echo_control_mobile()->is_comfort_noise_enabled()); + // Set and get echo path + const size_t echo_path_size = + apm_->echo_control_mobile()->echo_path_size_bytes(); + unsigned char echo_path_in[echo_path_size]; + unsigned char echo_path_out[echo_path_size]; + EXPECT_EQ(apm_->kNullPointerError, + apm_->echo_control_mobile()->SetEchoPath(NULL, echo_path_size)); + EXPECT_EQ(apm_->kNullPointerError, + apm_->echo_control_mobile()->GetEchoPath(NULL, echo_path_size)); + EXPECT_EQ(apm_->kBadParameterError, + apm_->echo_control_mobile()->GetEchoPath(echo_path_out, 1)); + EXPECT_EQ(apm_->kNoError, + apm_->echo_control_mobile()->GetEchoPath(echo_path_out, + echo_path_size)); + for (size_t i = 0; i < echo_path_size; i++) { + echo_path_in[i] = echo_path_out[i] + 1; + } + EXPECT_EQ(apm_->kBadParameterError, + apm_->echo_control_mobile()->SetEchoPath(echo_path_in, 1)); + EXPECT_EQ(apm_->kNoError, + apm_->echo_control_mobile()->SetEchoPath(echo_path_in, echo_path_size)); + EXPECT_EQ(apm_->kNoError, + apm_->echo_control_mobile()->GetEchoPath(echo_path_out, echo_path_size)); + for (size_t i = 0; i < echo_path_size; i++) { + EXPECT_EQ(echo_path_in[i], echo_path_out[i]); + } + // Turn AECM off + EXPECT_EQ(apm_->kNoError, apm_->echo_control_mobile()->Enable(false)); + EXPECT_FALSE(apm_->echo_control_mobile()->is_enabled()); +} + +TEST_F(ApmTest, GainControl) { + // Testing gain modes + EXPECT_EQ(apm_->kBadParameterError, + apm_->gain_control()->set_mode(static_cast(-1))); + + EXPECT_EQ(apm_->kBadParameterError, + apm_->gain_control()->set_mode(static_cast(3))); + + EXPECT_EQ(apm_->kNoError, + apm_->gain_control()->set_mode( + apm_->gain_control()->mode())); + + GainControl::Mode mode[] = { + GainControl::kAdaptiveAnalog, + GainControl::kAdaptiveDigital, + GainControl::kFixedDigital + }; + for (size_t i = 0; i < sizeof(mode)/sizeof(*mode); i++) { + EXPECT_EQ(apm_->kNoError, + apm_->gain_control()->set_mode(mode[i])); + EXPECT_EQ(mode[i], apm_->gain_control()->mode()); + } + // Testing invalid target levels + EXPECT_EQ(apm_->kBadParameterError, + apm_->gain_control()->set_target_level_dbfs(-3)); + EXPECT_EQ(apm_->kBadParameterError, + apm_->gain_control()->set_target_level_dbfs(-40)); + // Testing valid target levels + EXPECT_EQ(apm_->kNoError, + apm_->gain_control()->set_target_level_dbfs( + apm_->gain_control()->target_level_dbfs())); + + int level_dbfs[] = {0, 6, 31}; + for (size_t i = 0; i < sizeof(level_dbfs)/sizeof(*level_dbfs); i++) { + EXPECT_EQ(apm_->kNoError, + apm_->gain_control()->set_target_level_dbfs(level_dbfs[i])); + EXPECT_EQ(level_dbfs[i], apm_->gain_control()->target_level_dbfs()); + } + + // Testing invalid compression gains + EXPECT_EQ(apm_->kBadParameterError, + apm_->gain_control()->set_compression_gain_db(-1)); + EXPECT_EQ(apm_->kBadParameterError, + apm_->gain_control()->set_compression_gain_db(100)); + + // Testing valid compression gains + EXPECT_EQ(apm_->kNoError, + apm_->gain_control()->set_compression_gain_db( + apm_->gain_control()->compression_gain_db())); + + int gain_db[] = {0, 10, 90}; + for (size_t i = 0; i < sizeof(gain_db)/sizeof(*gain_db); i++) { + EXPECT_EQ(apm_->kNoError, + apm_->gain_control()->set_compression_gain_db(gain_db[i])); + EXPECT_EQ(gain_db[i], apm_->gain_control()->compression_gain_db()); + } + + // Testing limiter off/on + EXPECT_EQ(apm_->kNoError, apm_->gain_control()->enable_limiter(false)); + EXPECT_FALSE(apm_->gain_control()->is_limiter_enabled()); + EXPECT_EQ(apm_->kNoError, apm_->gain_control()->enable_limiter(true)); + EXPECT_TRUE(apm_->gain_control()->is_limiter_enabled()); + + // Testing invalid level limits + EXPECT_EQ(apm_->kBadParameterError, + apm_->gain_control()->set_analog_level_limits(-1, 512)); + EXPECT_EQ(apm_->kBadParameterError, + apm_->gain_control()->set_analog_level_limits(100000, 512)); + EXPECT_EQ(apm_->kBadParameterError, + apm_->gain_control()->set_analog_level_limits(512, -1)); + EXPECT_EQ(apm_->kBadParameterError, + apm_->gain_control()->set_analog_level_limits(512, 100000)); + EXPECT_EQ(apm_->kBadParameterError, + apm_->gain_control()->set_analog_level_limits(512, 255)); + + // Testing valid level limits + EXPECT_EQ(apm_->kNoError, + apm_->gain_control()->set_analog_level_limits( + apm_->gain_control()->analog_level_minimum(), + apm_->gain_control()->analog_level_maximum())); + + int min_level[] = {0, 255, 1024}; + for (size_t i = 0; i < sizeof(min_level)/sizeof(*min_level); i++) { + EXPECT_EQ(apm_->kNoError, + apm_->gain_control()->set_analog_level_limits(min_level[i], 1024)); + EXPECT_EQ(min_level[i], apm_->gain_control()->analog_level_minimum()); + } + + int max_level[] = {0, 1024, 65535}; + for (size_t i = 0; i < sizeof(min_level)/sizeof(*min_level); i++) { + EXPECT_EQ(apm_->kNoError, + apm_->gain_control()->set_analog_level_limits(0, max_level[i])); + EXPECT_EQ(max_level[i], apm_->gain_control()->analog_level_maximum()); + } + + // TODO(ajm): stream_is_saturated() and stream_analog_level() + + // Turn AGC off + EXPECT_EQ(apm_->kNoError, apm_->gain_control()->Enable(false)); + EXPECT_FALSE(apm_->gain_control()->is_enabled()); +} + +TEST_F(ApmTest, NoiseSuppression) { + // Tesing invalid suppression levels + EXPECT_EQ(apm_->kBadParameterError, + apm_->noise_suppression()->set_level( + static_cast(-1))); + + EXPECT_EQ(apm_->kBadParameterError, + apm_->noise_suppression()->set_level( + static_cast(5))); + + // Tesing valid suppression levels + NoiseSuppression::Level level[] = { + NoiseSuppression::kLow, + NoiseSuppression::kModerate, + NoiseSuppression::kHigh, + NoiseSuppression::kVeryHigh + }; + for (size_t i = 0; i < sizeof(level)/sizeof(*level); i++) { + EXPECT_EQ(apm_->kNoError, + apm_->noise_suppression()->set_level(level[i])); + EXPECT_EQ(level[i], apm_->noise_suppression()->level()); + } + + // Turing NS on/off + EXPECT_EQ(apm_->kNoError, apm_->noise_suppression()->Enable(true)); + EXPECT_TRUE(apm_->noise_suppression()->is_enabled()); + EXPECT_EQ(apm_->kNoError, apm_->noise_suppression()->Enable(false)); + EXPECT_FALSE(apm_->noise_suppression()->is_enabled()); +} + +TEST_F(ApmTest, HighPassFilter) { + // Turing HP filter on/off + EXPECT_EQ(apm_->kNoError, apm_->high_pass_filter()->Enable(true)); + EXPECT_TRUE(apm_->high_pass_filter()->is_enabled()); + EXPECT_EQ(apm_->kNoError, apm_->high_pass_filter()->Enable(false)); + EXPECT_FALSE(apm_->high_pass_filter()->is_enabled()); +} + +TEST_F(ApmTest, LevelEstimator) { + // Turing Level estimator on/off + EXPECT_EQ(apm_->kUnsupportedComponentError, + apm_->level_estimator()->Enable(true)); + EXPECT_FALSE(apm_->level_estimator()->is_enabled()); + EXPECT_EQ(apm_->kUnsupportedComponentError, + apm_->level_estimator()->Enable(false)); + EXPECT_FALSE(apm_->level_estimator()->is_enabled()); +} + +TEST_F(ApmTest, VoiceDetection) { + // Test external VAD + EXPECT_EQ(apm_->kNoError, + apm_->voice_detection()->set_stream_has_voice(true)); + EXPECT_TRUE(apm_->voice_detection()->stream_has_voice()); + EXPECT_EQ(apm_->kNoError, + apm_->voice_detection()->set_stream_has_voice(false)); + EXPECT_FALSE(apm_->voice_detection()->stream_has_voice()); + + // Tesing invalid likelihoods + EXPECT_EQ(apm_->kBadParameterError, + apm_->voice_detection()->set_likelihood( + static_cast(-1))); + + EXPECT_EQ(apm_->kBadParameterError, + apm_->voice_detection()->set_likelihood( + static_cast(5))); + + // Tesing valid likelihoods + VoiceDetection::Likelihood likelihood[] = { + VoiceDetection::kVeryLowLikelihood, + VoiceDetection::kLowLikelihood, + VoiceDetection::kModerateLikelihood, + VoiceDetection::kHighLikelihood + }; + for (size_t i = 0; i < sizeof(likelihood)/sizeof(*likelihood); i++) { + EXPECT_EQ(apm_->kNoError, + apm_->voice_detection()->set_likelihood(likelihood[i])); + EXPECT_EQ(likelihood[i], apm_->voice_detection()->likelihood()); + } + + /* TODO(bjornv): Enable once VAD supports other frame lengths than 10 ms + // Tesing invalid frame sizes + EXPECT_EQ(apm_->kBadParameterError, + apm_->voice_detection()->set_frame_size_ms(12)); + + // Tesing valid frame sizes + for (int i = 10; i <= 30; i += 10) { + EXPECT_EQ(apm_->kNoError, + apm_->voice_detection()->set_frame_size_ms(i)); + EXPECT_EQ(i, apm_->voice_detection()->frame_size_ms()); + } + */ + + // Turing VAD on/off + EXPECT_EQ(apm_->kNoError, apm_->voice_detection()->Enable(true)); + EXPECT_TRUE(apm_->voice_detection()->is_enabled()); + EXPECT_EQ(apm_->kNoError, apm_->voice_detection()->Enable(false)); + EXPECT_FALSE(apm_->voice_detection()->is_enabled()); + + // TODO(bjornv): Add tests for streamed voice; stream_has_voice() +} + +// Below are some ideas for tests from VPM. + +/*TEST_F(VideoProcessingModuleTest, GetVersionTest) +{ +} + +TEST_F(VideoProcessingModuleTest, HandleNullBuffer) +{ +} + +TEST_F(VideoProcessingModuleTest, HandleBadSize) +{ +} + +TEST_F(VideoProcessingModuleTest, IdenticalResultsAfterReset) +{ +} +*/ +} // namespace + +int main(int argc, char** argv) { + ::testing::InitGoogleTest(&argc, argv); + ApmEnvironment* env = new ApmEnvironment; // GTest takes ownership. + ::testing::AddGlobalTestEnvironment(env); + + for (int i = 1; i < argc; i++) { + if (strcmp(argv[i], "--write_output_data") == 0) { + write_output_data = true; + } + } + + int err = RUN_ALL_TESTS(); + + // Optional, but removes memory leak noise from Valgrind. + google::protobuf::ShutdownProtobufLibrary(); + return err; +} diff --git a/src/modules/audio_processing/main/test/unit_test/unittest.proto b/src/modules/audio_processing/main/test/unit_test/unittest.proto new file mode 100644 index 0000000..3dde02b --- /dev/null +++ b/src/modules/audio_processing/main/test/unit_test/unittest.proto @@ -0,0 +1,43 @@ +syntax = "proto2"; +option optimize_for = LITE_RUNTIME; +package webrtc.audioproc; + +message Test { + optional int32 num_reverse_channels = 1; + optional int32 num_input_channels = 2; + optional int32 num_output_channels = 3; + optional int32 sample_rate = 4; + + message Frame { + } + + repeated Frame frame = 5; + + optional int32 analog_level_average = 6; + optional int32 max_output_average = 7; + + optional int32 has_echo_count = 8; + optional int32 has_voice_count = 9; + optional int32 is_saturated_count = 10; + + message Statistic { + optional int32 instant = 1; + optional int32 average = 2; + optional int32 maximum = 3; + optional int32 minimum = 4; + } + + message EchoMetrics { + optional Statistic residual_echo_return_loss = 1; + optional Statistic echo_return_loss = 2; + optional Statistic echo_return_loss_enhancement = 3; + optional Statistic a_nlp = 4; + } + + optional EchoMetrics echo_metrics = 11; +} + +message OutputData { + repeated Test test = 1; +} + diff --git a/src/modules/audio_processing/ns/main/interface/noise_suppression.h b/src/modules/audio_processing/ns/main/interface/noise_suppression.h new file mode 100644 index 0000000..f28a10a --- /dev/null +++ b/src/modules/audio_processing/ns/main/interface/noise_suppression.h @@ -0,0 +1,124 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +#ifndef WEBRTC_MODULES_AUDIO_PROCESSING_NS_MAIN_INTERFACE_NOISE_SUPPRESSION_H_ +#define WEBRTC_MODULES_AUDIO_PROCESSING_NS_MAIN_INTERFACE_NOISE_SUPPRESSION_H_ + +#include "typedefs.h" + +typedef struct NsHandleT NsHandle; + +#ifdef __cplusplus +extern "C" { +#endif + +/* + * This function returns the version number of the code. + * + * Input: + * - version : Pointer to a character array where the version + * info is stored. + * - length : Length of version. + * + * Return value : 0 - Ok + * -1 - Error (probably length is not sufficient) + */ +int WebRtcNs_get_version(char *version, short length); + + +/* + * This function creates an instance to the noise reduction structure + * + * Input: + * - NS_inst : Pointer to noise reduction instance that should be + * created + * + * Output: + * - NS_inst : Pointer to created noise reduction instance + * + * Return value : 0 - Ok + * -1 - Error + */ +int WebRtcNs_Create(NsHandle **NS_inst); + + +/* + * This function frees the dynamic memory of a specified Noise Reduction + * instance. + * + * Input: + * - NS_inst : Pointer to NS instance that should be freed + * + * Return value : 0 - Ok + * -1 - Error + */ +int WebRtcNs_Free(NsHandle *NS_inst); + + +/* + * This function initializes a NS instance + * + * Input: + * - NS_inst : Instance that should be initialized + * - fs : sampling frequency + * + * Output: + * - NS_inst : Initialized instance + * + * Return value : 0 - Ok + * -1 - Error + */ +int WebRtcNs_Init(NsHandle *NS_inst, WebRtc_UWord32 fs); + +/* + * This changes the aggressiveness of the noise suppression method. + * + * Input: + * - NS_inst : Instance that should be initialized + * - mode : 0: Mild, 1: Medium , 2: Aggressive + * + * Output: + * - NS_inst : Initialized instance + * + * Return value : 0 - Ok + * -1 - Error + */ +int WebRtcNs_set_policy(NsHandle *NS_inst, int mode); + + +/* + * This functions does Noise Suppression for the inserted speech frame. The + * input and output signals should always be 10ms (80 or 160 samples). + * + * Input + * - NS_inst : NS Instance. Needs to be initiated before call. + * - spframe : Pointer to speech frame buffer for L band + * - spframe_H : Pointer to speech frame buffer for H band + * - fs : sampling frequency + * + * Output: + * - NS_inst : Updated NS instance + * - outframe : Pointer to output frame for L band + * - outframe_H : Pointer to output frame for H band + * + * Return value : 0 - OK + * -1 - Error + */ +int WebRtcNs_Process(NsHandle *NS_inst, + short *spframe, + short *spframe_H, + short *outframe, + short *outframe_H); + +#ifdef __cplusplus +} +#endif + +#endif // WEBRTC_MODULES_AUDIO_PROCESSING_NS_MAIN_INTERFACE_NOISE_SUPPRESSION_H_ diff --git a/src/modules/audio_processing/ns/main/interface/noise_suppression_x.h b/src/modules/audio_processing/ns/main/interface/noise_suppression_x.h new file mode 100644 index 0000000..35fea2f --- /dev/null +++ b/src/modules/audio_processing/ns/main/interface/noise_suppression_x.h @@ -0,0 +1,123 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +#ifndef WEBRTC_MODULES_AUDIO_PROCESSING_NS_MAIN_INTERFACE_NOISE_SUPPRESSION_X_H_ +#define WEBRTC_MODULES_AUDIO_PROCESSING_NS_MAIN_INTERFACE_NOISE_SUPPRESSION_X_H_ + +#include "signal_processing_library.h" + +typedef struct NsxHandleT NsxHandle; + +#ifdef __cplusplus +extern "C" { +#endif + +/* + * This function returns the version number of the code. + * + * Input: + * - version : Pointer to a character array where the version + * info is stored. + * - length : Length of version. + * + * Return value : 0 - Ok + * -1 - Error (probably length is not sufficient) + */ +int WebRtcNsx_get_version(char *version, short length); + + +/* + * This function creates an instance to the noise reduction structure + * + * Input: + * - nsxInst : Pointer to noise reduction instance that should be + * created + * + * Output: + * - nsxInst : Pointer to created noise reduction instance + * + * Return value : 0 - Ok + * -1 - Error + */ +int WebRtcNsx_Create(NsxHandle **nsxInst); + + +/* + * This function frees the dynamic memory of a specified Noise Suppression + * instance. + * + * Input: + * - nsxInst : Pointer to NS instance that should be freed + * + * Return value : 0 - Ok + * -1 - Error + */ +int WebRtcNsx_Free(NsxHandle *nsxInst); + + +/* + * This function initializes a NS instance + * + * Input: + * - nsxInst : Instance that should be initialized + * - fs : sampling frequency + * + * Output: + * - nsxInst : Initialized instance + * + * Return value : 0 - Ok + * -1 - Error + */ +int WebRtcNsx_Init(NsxHandle *nsxInst, WebRtc_UWord32 fs); + +/* + * This changes the aggressiveness of the noise suppression method. + * + * Input: + * - nsxInst : Instance that should be initialized + * - mode : 0: Mild, 1: Medium , 2: Aggressive + * + * Output: + * - nsxInst : Initialized instance + * + * Return value : 0 - Ok + * -1 - Error + */ +int WebRtcNsx_set_policy(NsxHandle *nsxInst, int mode); + +/* + * This functions does noise suppression for the inserted speech frame. The + * input and output signals should always be 10ms (80 or 160 samples). + * + * Input + * - nsxInst : NSx instance. Needs to be initiated before call. + * - speechFrame : Pointer to speech frame buffer for L band + * - speechFrameHB : Pointer to speech frame buffer for H band + * - fs : sampling frequency + * + * Output: + * - nsxInst : Updated NSx instance + * - outFrame : Pointer to output frame for L band + * - outFrameHB : Pointer to output frame for H band + * + * Return value : 0 - OK + * -1 - Error + */ +int WebRtcNsx_Process(NsxHandle *nsxInst, + short *speechFrame, + short *speechFrameHB, + short *outFrame, + short *outFrameHB); + +#ifdef __cplusplus +} +#endif + +#endif // WEBRTC_MODULES_AUDIO_PROCESSING_NS_MAIN_INTERFACE_NOISE_SUPPRESSION_X_H_ diff --git a/src/modules/audio_processing/ns/main/source/defines.h b/src/modules/audio_processing/ns/main/source/defines.h new file mode 100644 index 0000000..d253967 --- /dev/null +++ b/src/modules/audio_processing/ns/main/source/defines.h @@ -0,0 +1,53 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +#ifndef WEBRTC_MODULES_AUDIO_PROCESSING_NS_MAIN_SOURCE_DEFINES_H_ +#define WEBRTC_MODULES_AUDIO_PROCESSING_NS_MAIN_SOURCE_DEFINES_H_ + +//#define PROCESS_FLOW_0 // Use the traditional method. +//#define PROCESS_FLOW_1 // Use traditional with DD estimate of prior SNR. +#define PROCESS_FLOW_2 // Use the new method of speech/noise classification. + +#define BLOCKL_MAX 160 // max processing block length: 160 +#define ANAL_BLOCKL_MAX 256 // max analysis block length: 256 +#define HALF_ANAL_BLOCKL 129 // half max analysis block length + 1 + +#define QUANTILE (float)0.25 + +#define SIMULT 3 +#define END_STARTUP_LONG 200 +#define END_STARTUP_SHORT 50 +#define FACTOR (float)40.0 +#define WIDTH (float)0.01 + +#define SMOOTH (float)0.75 // filter smoothing +// Length of fft work arrays. +#define IP_LENGTH (ANAL_BLOCKL_MAX >> 1) // must be at least ceil(2 + sqrt(ANAL_BLOCKL_MAX/2)) +#define W_LENGTH (ANAL_BLOCKL_MAX >> 1) + +//PARAMETERS FOR NEW METHOD +#define DD_PR_SNR (float)0.98 // DD update of prior SNR +#define LRT_TAVG (float)0.50 // tavg parameter for LRT (previously 0.90) +#define SPECT_FL_TAVG (float)0.30 // tavg parameter for spectral flatness measure +#define SPECT_DIFF_TAVG (float)0.30 // tavg parameter for spectral difference measure +#define PRIOR_UPDATE (float)0.10 // update parameter of prior model +#define NOISE_UPDATE (float)0.90 // update parameter for noise +#define SPEECH_UPDATE (float)0.99 // update parameter when likely speech +#define WIDTH_PR_MAP (float)4.0 // width parameter in sigmoid map for prior model +#define LRT_FEATURE_THR (float)0.5 // default threshold for LRT feature +#define SF_FEATURE_THR (float)0.5 // default threshold for Spectral Flatness feature +#define SD_FEATURE_THR (float)0.5 // default threshold for Spectral Difference feature +#define PROB_RANGE (float)0.20 // probability threshold for noise state in + // speech/noise likelihood +#define HIST_PAR_EST 1000 // histogram size for estimation of parameters +#define GAMMA_PAUSE (float)0.05 // update for conservative noise estimate +// +#define B_LIM (float)0.5 // threshold in final energy gain factor calculation +#endif // WEBRTC_MODULES_AUDIO_PROCESSING_NS_MAIN_SOURCE_DEFINES_H_ diff --git a/src/modules/audio_processing/ns/main/source/noise_suppression.c b/src/modules/audio_processing/ns/main/source/noise_suppression.c new file mode 100644 index 0000000..aed10b1 --- /dev/null +++ b/src/modules/audio_processing/ns/main/source/noise_suppression.c @@ -0,0 +1,69 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +#include +#include + +#include "noise_suppression.h" +#include "ns_core.h" +#include "defines.h" + +int WebRtcNs_get_version(char *versionStr, short length) +{ + const char version[] = "NS 2.2.0"; + const short versionLen = (short)strlen(version) + 1; // +1 for null-termination + + if (versionStr == NULL) { + return -1; + } + + if (versionLen > length) { + return -1; + } + + strncpy(versionStr, version, versionLen); + + return 0; +} + +int WebRtcNs_Create(NsHandle **NS_inst) +{ + *NS_inst = (NsHandle*) malloc(sizeof(NSinst_t)); + if (*NS_inst!=NULL) { + (*(NSinst_t**)NS_inst)->initFlag=0; + return 0; + } else { + return -1; + } + +} + +int WebRtcNs_Free(NsHandle *NS_inst) +{ + free(NS_inst); + return 0; +} + + +int WebRtcNs_Init(NsHandle *NS_inst, WebRtc_UWord32 fs) +{ + return WebRtcNs_InitCore((NSinst_t*) NS_inst, fs); +} + +int WebRtcNs_set_policy(NsHandle *NS_inst, int mode) +{ + return WebRtcNs_set_policy_core((NSinst_t*) NS_inst, mode); +} + + +int WebRtcNs_Process(NsHandle *NS_inst, short *spframe, short *spframe_H, short *outframe, short *outframe_H) +{ + return WebRtcNs_ProcessCore((NSinst_t*) NS_inst, spframe, spframe_H, outframe, outframe_H); +} diff --git a/src/modules/audio_processing/ns/main/source/noise_suppression_x.c b/src/modules/audio_processing/ns/main/source/noise_suppression_x.c new file mode 100644 index 0000000..f1ad730 --- /dev/null +++ b/src/modules/audio_processing/ns/main/source/noise_suppression_x.c @@ -0,0 +1,74 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +#include +#include + +#include "noise_suppression_x.h" +#include "nsx_core.h" +#include "nsx_defines.h" + +int WebRtcNsx_get_version(char *versionStr, short length) +{ + const char version[] = "NS\t3.1.0"; + const short versionLen = (short)strlen(version) + 1; // +1 for null-termination + + if (versionStr == NULL) + { + return -1; + } + + if (versionLen > length) + { + return -1; + } + + strncpy(versionStr, version, versionLen); + + return 0; +} + +int WebRtcNsx_Create(NsxHandle **nsxInst) +{ + *nsxInst = (NsxHandle*)malloc(sizeof(NsxInst_t)); + if (*nsxInst != NULL) + { + (*(NsxInst_t**)nsxInst)->initFlag = 0; + return 0; + } else + { + return -1; + } + +} + +int WebRtcNsx_Free(NsxHandle *nsxInst) +{ + free(nsxInst); + return 0; +} + +int WebRtcNsx_Init(NsxHandle *nsxInst, WebRtc_UWord32 fs) +{ + return WebRtcNsx_InitCore((NsxInst_t*)nsxInst, fs); +} + +int WebRtcNsx_set_policy(NsxHandle *nsxInst, int mode) +{ + return WebRtcNsx_set_policy_core((NsxInst_t*)nsxInst, mode); +} + +int WebRtcNsx_Process(NsxHandle *nsxInst, short *speechFrame, short *speechFrameHB, + short *outFrame, short *outFrameHB) +{ + return WebRtcNsx_ProcessCore((NsxInst_t*)nsxInst, speechFrame, speechFrameHB, outFrame, + outFrameHB); +} + diff --git a/src/modules/audio_processing/ns/main/source/ns.gypi b/src/modules/audio_processing/ns/main/source/ns.gypi new file mode 100644 index 0000000..9bdbcb9 --- /dev/null +++ b/src/modules/audio_processing/ns/main/source/ns.gypi @@ -0,0 +1,64 @@ +# Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. +# +# Use of this source code is governed by a BSD-style license +# that can be found in the LICENSE file in the root of the source +# tree. An additional intellectual property rights grant can be found +# in the file PATENTS. All contributing project authors may +# be found in the AUTHORS file in the root of the source tree. + +{ + 'targets': [ + { + 'target_name': 'ns', + 'type': '<(library)', + 'dependencies': [ + '<(webrtc_root)/common_audio/common_audio.gyp:spl', + 'apm_util' + ], + 'include_dirs': [ + '../interface', + ], + 'direct_dependent_settings': { + 'include_dirs': [ + '../interface', + ], + }, + 'sources': [ + '../interface/noise_suppression.h', + 'noise_suppression.c', + 'windows_private.h', + 'defines.h', + 'ns_core.c', + 'ns_core.h', + ], + }, + { + 'target_name': 'ns_fix', + 'type': '<(library)', + 'dependencies': [ + '<(webrtc_root)/common_audio/common_audio.gyp:spl', + ], + 'include_dirs': [ + '../interface', + ], + 'direct_dependent_settings': { + 'include_dirs': [ + '../interface', + ], + }, + 'sources': [ + '../interface/noise_suppression_x.h', + 'noise_suppression_x.c', + 'nsx_defines.h', + 'nsx_core.c', + 'nsx_core.h', + ], + }, + ], +} + +# Local Variables: +# tab-width:2 +# indent-tabs-mode:nil +# End: +# vim: set expandtab tabstop=2 shiftwidth=2: diff --git a/src/modules/audio_processing/ns/main/source/ns_core.c b/src/modules/audio_processing/ns/main/source/ns_core.c new file mode 100644 index 0000000..10a1b83 --- /dev/null +++ b/src/modules/audio_processing/ns/main/source/ns_core.c @@ -0,0 +1,1500 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +#include +#include +//#include +#include +#include "noise_suppression.h" +#include "ns_core.h" +#include "windows_private.h" +#include "fft4g.h" +#include "signal_processing_library.h" + +// Set Feature Extraction Parameters +void WebRtcNs_set_feature_extraction_parameters(NSinst_t *inst) +{ + //bin size of histogram + inst->featureExtractionParams.binSizeLrt = (float)0.1; + inst->featureExtractionParams.binSizeSpecFlat = (float)0.05; + inst->featureExtractionParams.binSizeSpecDiff = (float)0.1; + + //range of histogram over which lrt threshold is computed + inst->featureExtractionParams.rangeAvgHistLrt = (float)1.0; + + //scale parameters: multiply dominant peaks of the histograms by scale factor to obtain + // thresholds for prior model + inst->featureExtractionParams.factor1ModelPars = (float)1.20; //for lrt and spectral diff + inst->featureExtractionParams.factor2ModelPars = (float)0.9; //for spectral_flatness: + // used when noise is flatter than speech + + //peak limit for spectral flatness (varies between 0 and 1) + inst->featureExtractionParams.thresPosSpecFlat = (float)0.6; + + //limit on spacing of two highest peaks in histogram: spacing determined by bin size + inst->featureExtractionParams.limitPeakSpacingSpecFlat = 2 + * inst->featureExtractionParams.binSizeSpecFlat; + inst->featureExtractionParams.limitPeakSpacingSpecDiff = 2 + * inst->featureExtractionParams.binSizeSpecDiff; + + //limit on relevance of second peak: + inst->featureExtractionParams.limitPeakWeightsSpecFlat = (float)0.5; + inst->featureExtractionParams.limitPeakWeightsSpecDiff = (float)0.5; + + // fluctuation limit of lrt feature + inst->featureExtractionParams.thresFluctLrt = (float)0.05; + + //limit on the max and min values for the feature thresholds + inst->featureExtractionParams.maxLrt = (float)1.0; + inst->featureExtractionParams.minLrt = (float)0.20; + + inst->featureExtractionParams.maxSpecFlat = (float)0.95; + inst->featureExtractionParams.minSpecFlat = (float)0.10; + + inst->featureExtractionParams.maxSpecDiff = (float)1.0; + inst->featureExtractionParams.minSpecDiff = (float)0.16; + + //criteria of weight of histogram peak to accept/reject feature + inst->featureExtractionParams.thresWeightSpecFlat = (int)(0.3 + * (inst->modelUpdatePars[1])); //for spectral flatness + inst->featureExtractionParams.thresWeightSpecDiff = (int)(0.3 + * (inst->modelUpdatePars[1])); //for spectral difference +} + +// Initialize state +int WebRtcNs_InitCore(NSinst_t *inst, WebRtc_UWord32 fs) +{ + int i; + //We only support 10ms frames + + //check for valid pointer + if (inst == NULL) + { + return -1; + } + + // Initialization of struct + if (fs == 8000 || fs == 16000 || fs == 32000) + { + inst->fs = fs; + } + else + { + return -1; + } + inst->windShift = 0; + if (fs == 8000) + { + // We only support 10ms frames + inst->blockLen = 80; + inst->blockLen10ms = 80; + inst->anaLen = 128; + inst->window = kBlocks80w128; + inst->outLen = 0; + } + else if (fs == 16000) + { + // We only support 10ms frames + inst->blockLen = 160; + inst->blockLen10ms = 160; + inst->anaLen = 256; + inst->window = kBlocks160w256; + inst->outLen = 0; + } + else if (fs==32000) + { + // We only support 10ms frames + inst->blockLen = 160; + inst->blockLen10ms = 160; + inst->anaLen = 256; + inst->window = kBlocks160w256; + inst->outLen = 0; + } + inst->magnLen = inst->anaLen / 2 + 1; // Number of frequency bins + + // Initialize fft work arrays. + inst->ip[0] = 0; // Setting this triggers initialization. + memset(inst->dataBuf, 0, sizeof(float) * ANAL_BLOCKL_MAX); + rdft(inst->anaLen, 1, inst->dataBuf, inst->ip, inst->wfft); + + memset(inst->dataBuf, 0, sizeof(float) * ANAL_BLOCKL_MAX); + memset(inst->syntBuf, 0, sizeof(float) * ANAL_BLOCKL_MAX); + + //for HB processing + memset(inst->dataBufHB, 0, sizeof(float) * ANAL_BLOCKL_MAX); + + //for quantile noise estimation + memset(inst->quantile, 0, sizeof(float) * HALF_ANAL_BLOCKL); + for (i = 0; i < SIMULT * HALF_ANAL_BLOCKL; i++) + { + inst->lquantile[i] = (float)8.0; + inst->density[i] = (float)0.3; + } + + for (i = 0; i < SIMULT; i++) + { + inst->counter[i] = (int)floor((float)(END_STARTUP_LONG * (i + 1)) / (float)SIMULT); + } + + inst->updates = 0; + + // Wiener filter initialization + for (i = 0; i < HALF_ANAL_BLOCKL; i++) + { + inst->smooth[i] = (float)1.0; + } + + // Set the aggressiveness: default + inst->aggrMode = 0; + + //initialize variables for new method + inst->priorSpeechProb = (float)0.5; //prior prob for speech/noise + for (i = 0; i < HALF_ANAL_BLOCKL; i++) + { + inst->magnPrev[i] = (float)0.0; //previous mag spectrum + inst->noisePrev[i] = (float)0.0; //previous noise-spectrum + inst->logLrtTimeAvg[i] = LRT_FEATURE_THR; //smooth LR ratio (same as threshold) + inst->magnAvgPause[i] = (float)0.0; //conservative noise spectrum estimate + inst->speechProbHB[i] = (float)0.0; //for estimation of HB in second pass + inst->initMagnEst[i] = (float)0.0; //initial average mag spectrum + } + + //feature quantities + inst->featureData[0] = SF_FEATURE_THR; //spectral flatness (start on threshold) + inst->featureData[1] = (float)0.0; //spectral entropy: not used in this version + inst->featureData[2] = (float)0.0; //spectral variance: not used in this version + inst->featureData[3] = LRT_FEATURE_THR; //average lrt factor (start on threshold) + inst->featureData[4] = SF_FEATURE_THR; //spectral template diff (start on threshold) + inst->featureData[5] = (float)0.0; //normalization for spectral-diff + inst->featureData[6] = (float)0.0; //window time-average of input magnitude spectrum + + //histogram quantities: used to estimate/update thresholds for features + for (i = 0; i < HIST_PAR_EST; i++) + { + inst->histLrt[i] = 0; + inst->histSpecFlat[i] = 0; + inst->histSpecDiff[i] = 0; + } + + inst->blockInd = -1; //frame counter + inst->priorModelPars[0] = LRT_FEATURE_THR; //default threshold for lrt feature + inst->priorModelPars[1] = (float)0.5; //threshold for spectral flatness: + // determined on-line + inst->priorModelPars[2] = (float)1.0; //sgn_map par for spectral measure: + // 1 for flatness measure + inst->priorModelPars[3] = (float)0.5; //threshold for template-difference feature: + // determined on-line + inst->priorModelPars[4] = (float)1.0; //default weighting parameter for lrt feature + inst->priorModelPars[5] = (float)0.0; //default weighting parameter for + // spectral flatness feature + inst->priorModelPars[6] = (float)0.0; //default weighting parameter for + // spectral difference feature + + inst->modelUpdatePars[0] = 2; //update flag for parameters: + // 0 no update, 1=update once, 2=update every window + inst->modelUpdatePars[1] = 500; //window for update + inst->modelUpdatePars[2] = 0; //counter for update of conservative noise spectrum + //counter if the feature thresholds are updated during the sequence + inst->modelUpdatePars[3] = inst->modelUpdatePars[1]; + + inst->signalEnergy = 0.0; + inst->sumMagn = 0.0; + inst->whiteNoiseLevel = 0.0; + inst->pinkNoiseNumerator = 0.0; + inst->pinkNoiseExp = 0.0; + + WebRtcNs_set_feature_extraction_parameters(inst); // Set feature configuration + + //default mode + WebRtcNs_set_policy_core(inst, 0); + + + memset(inst->outBuf, 0, sizeof(float) * 3 * BLOCKL_MAX); + + inst->initFlag = 1; + return 0; +} + +int WebRtcNs_set_policy_core(NSinst_t *inst, int mode) +{ + // allow for modes:0,1,2,3 + if (mode < 0 || mode > 3) + { + return (-1); + } + + inst->aggrMode = mode; + if (mode == 0) + { + inst->overdrive = (float)1.0; + inst->denoiseBound = (float)0.5; + inst->gainmap = 0; + } + else if (mode == 1) + { + //inst->overdrive = (float)1.25; + inst->overdrive = (float)1.0; + inst->denoiseBound = (float)0.25; + inst->gainmap = 1; + } + else if (mode == 2) + { + //inst->overdrive = (float)1.25; + inst->overdrive = (float)1.1; + inst->denoiseBound = (float)0.125; + inst->gainmap = 1; + } + else if (mode == 3) + { + //inst->overdrive = (float)1.30; + inst->overdrive = (float)1.25; + inst->denoiseBound = (float)0.09; + inst->gainmap = 1; + } + return 0; +} + +// Estimate noise +void WebRtcNs_NoiseEstimation(NSinst_t *inst, float *magn, float *noise) +{ + int i, s, offset; + float lmagn[HALF_ANAL_BLOCKL], delta; + + if (inst->updates < END_STARTUP_LONG) + { + inst->updates++; + } + + for (i = 0; i < inst->magnLen; i++) + { + lmagn[i] = (float)log(magn[i]); + } + + // loop over simultaneous estimates + for (s = 0; s < SIMULT; s++) + { + offset = s * inst->magnLen; + + // newquantest(...) + for (i = 0; i < inst->magnLen; i++) + { + // compute delta + if (inst->density[offset + i] > 1.0) + { + delta = FACTOR * (float)1.0 / inst->density[offset + i]; + } + else + { + delta = FACTOR; + } + + // update log quantile estimate + if (lmagn[i] > inst->lquantile[offset + i]) + { + inst->lquantile[offset + i] += QUANTILE * delta + / (float)(inst->counter[s] + 1); + } + else + { + inst->lquantile[offset + i] -= ((float)1.0 - QUANTILE) * delta + / (float)(inst->counter[s] + 1); + } + + // update density estimate + if (fabs(lmagn[i] - inst->lquantile[offset + i]) < WIDTH) + { + inst->density[offset + i] = ((float)inst->counter[s] * inst->density[offset + + i] + (float)1.0 / ((float)2.0 * WIDTH)) / (float)(inst->counter[s] + + 1); + } + } // end loop over magnitude spectrum + + if (inst->counter[s] >= END_STARTUP_LONG) + { + inst->counter[s] = 0; + if (inst->updates >= END_STARTUP_LONG) + { + for (i = 0; i < inst->magnLen; i++) + { + inst->quantile[i] = (float)exp(inst->lquantile[offset + i]); + } + } + } + + inst->counter[s]++; + } // end loop over simultaneous estimates + + // Sequentially update the noise during startup + if (inst->updates < END_STARTUP_LONG) + { + // Use the last "s" to get noise during startup that differ from zero. + for (i = 0; i < inst->magnLen; i++) + { + inst->quantile[i] = (float)exp(inst->lquantile[offset + i]); + } + } + + for (i = 0; i < inst->magnLen; i++) + { + noise[i] = inst->quantile[i]; + } +} + +// Extract thresholds for feature parameters +// histograms are computed over some window_size (given by inst->modelUpdatePars[1]) +// thresholds and weights are extracted every window +// flag 0 means update histogram only, flag 1 means compute the thresholds/weights +// threshold and weights are returned in: inst->priorModelPars +void WebRtcNs_FeatureParameterExtraction(NSinst_t *inst, int flag) +{ + int i, useFeatureSpecFlat, useFeatureSpecDiff, numHistLrt; + int maxPeak1, maxPeak2; + int weightPeak1SpecFlat, weightPeak2SpecFlat, weightPeak1SpecDiff, weightPeak2SpecDiff; + + float binMid, featureSum; + float posPeak1SpecFlat, posPeak2SpecFlat, posPeak1SpecDiff, posPeak2SpecDiff; + float fluctLrt, avgHistLrt, avgSquareHistLrt, avgHistLrtCompl; + + //3 features: lrt, flatness, difference + //lrt_feature = inst->featureData[3]; + //flat_feature = inst->featureData[0]; + //diff_feature = inst->featureData[4]; + + //update histograms + if (flag == 0) + { + // LRT + if ((inst->featureData[3] < HIST_PAR_EST * inst->featureExtractionParams.binSizeLrt) + && (inst->featureData[3] >= 0.0)) + { + i = (int)(inst->featureData[3] / inst->featureExtractionParams.binSizeLrt); + inst->histLrt[i]++; + } + // Spectral flatness + if ((inst->featureData[0] < HIST_PAR_EST + * inst->featureExtractionParams.binSizeSpecFlat) + && (inst->featureData[0] >= 0.0)) + { + i = (int)(inst->featureData[0] / inst->featureExtractionParams.binSizeSpecFlat); + inst->histSpecFlat[i]++; + } + // Spectral difference + if ((inst->featureData[4] < HIST_PAR_EST + * inst->featureExtractionParams.binSizeSpecDiff) + && (inst->featureData[4] >= 0.0)) + { + i = (int)(inst->featureData[4] / inst->featureExtractionParams.binSizeSpecDiff); + inst->histSpecDiff[i]++; + } + } + + // extract parameters for speech/noise probability + if (flag == 1) + { + //lrt feature: compute the average over inst->featureExtractionParams.rangeAvgHistLrt + avgHistLrt = 0.0; + avgHistLrtCompl = 0.0; + avgSquareHistLrt = 0.0; + numHistLrt = 0; + for (i = 0; i < HIST_PAR_EST; i++) + { + binMid = ((float)i + (float)0.5) * inst->featureExtractionParams.binSizeLrt; + if (binMid <= inst->featureExtractionParams.rangeAvgHistLrt) + { + avgHistLrt += inst->histLrt[i] * binMid; + numHistLrt += inst->histLrt[i]; + } + avgSquareHistLrt += inst->histLrt[i] * binMid * binMid; + avgHistLrtCompl += inst->histLrt[i] * binMid; + } + if (numHistLrt > 0) + { + avgHistLrt = avgHistLrt / ((float)numHistLrt); + } + avgHistLrtCompl = avgHistLrtCompl / ((float)inst->modelUpdatePars[1]); + avgSquareHistLrt = avgSquareHistLrt / ((float)inst->modelUpdatePars[1]); + fluctLrt = avgSquareHistLrt - avgHistLrt * avgHistLrtCompl; + // get threshold for lrt feature: + if (fluctLrt < inst->featureExtractionParams.thresFluctLrt) + { + //very low fluct, so likely noise + inst->priorModelPars[0] = inst->featureExtractionParams.maxLrt; + } + else + { + inst->priorModelPars[0] = inst->featureExtractionParams.factor1ModelPars + * avgHistLrt; + // check if value is within min/max range + if (inst->priorModelPars[0] < inst->featureExtractionParams.minLrt) + { + inst->priorModelPars[0] = inst->featureExtractionParams.minLrt; + } + if (inst->priorModelPars[0] > inst->featureExtractionParams.maxLrt) + { + inst->priorModelPars[0] = inst->featureExtractionParams.maxLrt; + } + } + // done with lrt feature + + // + // for spectral flatness and spectral difference: compute the main peaks of histogram + maxPeak1 = 0; + maxPeak2 = 0; + posPeak1SpecFlat = 0.0; + posPeak2SpecFlat = 0.0; + weightPeak1SpecFlat = 0; + weightPeak2SpecFlat = 0; + + // peaks for flatness + for (i = 0; i < HIST_PAR_EST; i++) + { + binMid = ((float)i + (float)0.5) * inst->featureExtractionParams.binSizeSpecFlat; + if (inst->histSpecFlat[i] > maxPeak1) + { + // Found new "first" peak + maxPeak2 = maxPeak1; + weightPeak2SpecFlat = weightPeak1SpecFlat; + posPeak2SpecFlat = posPeak1SpecFlat; + + maxPeak1 = inst->histSpecFlat[i]; + weightPeak1SpecFlat = inst->histSpecFlat[i]; + posPeak1SpecFlat = binMid; + } + else if (inst->histSpecFlat[i] > maxPeak2) + { + // Found new "second" peak + maxPeak2 = inst->histSpecFlat[i]; + weightPeak2SpecFlat = inst->histSpecFlat[i]; + posPeak2SpecFlat = binMid; + } + } + + //compute two peaks for spectral difference + maxPeak1 = 0; + maxPeak2 = 0; + posPeak1SpecDiff = 0.0; + posPeak2SpecDiff = 0.0; + weightPeak1SpecDiff = 0; + weightPeak2SpecDiff = 0; + // peaks for spectral difference + for (i = 0; i < HIST_PAR_EST; i++) + { + binMid = ((float)i + (float)0.5) * inst->featureExtractionParams.binSizeSpecDiff; + if (inst->histSpecDiff[i] > maxPeak1) + { + // Found new "first" peak + maxPeak2 = maxPeak1; + weightPeak2SpecDiff = weightPeak1SpecDiff; + posPeak2SpecDiff = posPeak1SpecDiff; + + maxPeak1 = inst->histSpecDiff[i]; + weightPeak1SpecDiff = inst->histSpecDiff[i]; + posPeak1SpecDiff = binMid; + } + else if (inst->histSpecDiff[i] > maxPeak2) + { + // Found new "second" peak + maxPeak2 = inst->histSpecDiff[i]; + weightPeak2SpecDiff = inst->histSpecDiff[i]; + posPeak2SpecDiff = binMid; + } + } + + // for spectrum flatness feature + useFeatureSpecFlat = 1; + // merge the two peaks if they are close + if ((fabs(posPeak2SpecFlat - posPeak1SpecFlat) + < inst->featureExtractionParams.limitPeakSpacingSpecFlat) + && (weightPeak2SpecFlat + > inst->featureExtractionParams.limitPeakWeightsSpecFlat + * weightPeak1SpecFlat)) + { + weightPeak1SpecFlat += weightPeak2SpecFlat; + posPeak1SpecFlat = (float)0.5 * (posPeak1SpecFlat + posPeak2SpecFlat); + } + //reject if weight of peaks is not large enough, or peak value too small + if (weightPeak1SpecFlat < inst->featureExtractionParams.thresWeightSpecFlat + || posPeak1SpecFlat < inst->featureExtractionParams.thresPosSpecFlat) + { + useFeatureSpecFlat = 0; + } + // if selected, get the threshold + if (useFeatureSpecFlat == 1) + { + // compute the threshold + inst->priorModelPars[1] = inst->featureExtractionParams.factor2ModelPars + * posPeak1SpecFlat; + //check if value is within min/max range + if (inst->priorModelPars[1] < inst->featureExtractionParams.minSpecFlat) + { + inst->priorModelPars[1] = inst->featureExtractionParams.minSpecFlat; + } + if (inst->priorModelPars[1] > inst->featureExtractionParams.maxSpecFlat) + { + inst->priorModelPars[1] = inst->featureExtractionParams.maxSpecFlat; + } + } + // done with flatness feature + + // for template feature + useFeatureSpecDiff = 1; + // merge the two peaks if they are close + if ((fabs(posPeak2SpecDiff - posPeak1SpecDiff) + < inst->featureExtractionParams.limitPeakSpacingSpecDiff) + && (weightPeak2SpecDiff + > inst->featureExtractionParams.limitPeakWeightsSpecDiff + * weightPeak1SpecDiff)) + { + weightPeak1SpecDiff += weightPeak2SpecDiff; + posPeak1SpecDiff = (float)0.5 * (posPeak1SpecDiff + posPeak2SpecDiff); + } + // get the threshold value + inst->priorModelPars[3] = inst->featureExtractionParams.factor1ModelPars + * posPeak1SpecDiff; + //reject if weight of peaks is not large enough + if (weightPeak1SpecDiff < inst->featureExtractionParams.thresWeightSpecDiff) + { + useFeatureSpecDiff = 0; + } + //check if value is within min/max range + if (inst->priorModelPars[3] < inst->featureExtractionParams.minSpecDiff) + { + inst->priorModelPars[3] = inst->featureExtractionParams.minSpecDiff; + } + if (inst->priorModelPars[3] > inst->featureExtractionParams.maxSpecDiff) + { + inst->priorModelPars[3] = inst->featureExtractionParams.maxSpecDiff; + } + // done with spectral difference feature + + // don't use template feature if fluctuation of lrt feature is very low: + // most likely just noise state + if (fluctLrt < inst->featureExtractionParams.thresFluctLrt) + { + useFeatureSpecDiff = 0; + } + + // select the weights between the features + // inst->priorModelPars[4] is weight for lrt: always selected + // inst->priorModelPars[5] is weight for spectral flatness + // inst->priorModelPars[6] is weight for spectral difference + featureSum = (float)(1 + useFeatureSpecFlat + useFeatureSpecDiff); + inst->priorModelPars[4] = (float)1.0 / featureSum; + inst->priorModelPars[5] = ((float)useFeatureSpecFlat) / featureSum; + inst->priorModelPars[6] = ((float)useFeatureSpecDiff) / featureSum; + + // set hists to zero for next update + if (inst->modelUpdatePars[0] >= 1) + { + for (i = 0; i < HIST_PAR_EST; i++) + { + inst->histLrt[i] = 0; + inst->histSpecFlat[i] = 0; + inst->histSpecDiff[i] = 0; + } + } + } // end of flag == 1 +} + +// Compute spectral flatness on input spectrum +// magnIn is the magnitude spectrum +// spectral flatness is returned in inst->featureData[0] +void WebRtcNs_ComputeSpectralFlatness(NSinst_t *inst, float *magnIn) +{ + int i; + int shiftLP = 1; //option to remove first bin(s) from spectral measures + float avgSpectralFlatnessNum, avgSpectralFlatnessDen, spectralTmp; + + // comute spectral measures + // for flatness + avgSpectralFlatnessNum = 0.0; + avgSpectralFlatnessDen = inst->sumMagn; + for (i = 0; i < shiftLP; i++) + { + avgSpectralFlatnessDen -= magnIn[i]; + } + // compute log of ratio of the geometric to arithmetic mean: check for log(0) case + for (i = shiftLP; i < inst->magnLen; i++) + { + if (magnIn[i] > 0.0) + { + avgSpectralFlatnessNum += (float)log(magnIn[i]); + } + else + { + inst->featureData[0] -= SPECT_FL_TAVG * inst->featureData[0]; + return; + } + } + //normalize + avgSpectralFlatnessDen = avgSpectralFlatnessDen / inst->magnLen; + avgSpectralFlatnessNum = avgSpectralFlatnessNum / inst->magnLen; + + //ratio and inverse log: check for case of log(0) + spectralTmp = (float)exp(avgSpectralFlatnessNum) / avgSpectralFlatnessDen; + + //time-avg update of spectral flatness feature + inst->featureData[0] += SPECT_FL_TAVG * (spectralTmp - inst->featureData[0]); + // done with flatness feature +} + +// Compute the difference measure between input spectrum and a template/learned noise spectrum +// magnIn is the input spectrum +// the reference/template spectrum is inst->magnAvgPause[i] +// returns (normalized) spectral difference in inst->featureData[4] +void WebRtcNs_ComputeSpectralDifference(NSinst_t *inst, float *magnIn) +{ + // avgDiffNormMagn = var(magnIn) - cov(magnIn, magnAvgPause)^2 / var(magnAvgPause) + int i; + float avgPause, avgMagn, covMagnPause, varPause, varMagn, avgDiffNormMagn; + + avgPause = 0.0; + avgMagn = inst->sumMagn; + // compute average quantities + for (i = 0; i < inst->magnLen; i++) + { + //conservative smooth noise spectrum from pause frames + avgPause += inst->magnAvgPause[i]; + } + avgPause = avgPause / ((float)inst->magnLen); + avgMagn = avgMagn / ((float)inst->magnLen); + + covMagnPause = 0.0; + varPause = 0.0; + varMagn = 0.0; + // compute variance and covariance quantities + for (i = 0; i < inst->magnLen; i++) + { + covMagnPause += (magnIn[i] - avgMagn) * (inst->magnAvgPause[i] - avgPause); + varPause += (inst->magnAvgPause[i] - avgPause) * (inst->magnAvgPause[i] - avgPause); + varMagn += (magnIn[i] - avgMagn) * (magnIn[i] - avgMagn); + } + covMagnPause = covMagnPause / ((float)inst->magnLen); + varPause = varPause / ((float)inst->magnLen); + varMagn = varMagn / ((float)inst->magnLen); + // update of average magnitude spectrum + inst->featureData[6] += inst->signalEnergy; + + avgDiffNormMagn = varMagn - (covMagnPause * covMagnPause) / (varPause + (float)0.0001); + // normalize and compute time-avg update of difference feature + avgDiffNormMagn = (float)(avgDiffNormMagn / (inst->featureData[5] + (float)0.0001)); + inst->featureData[4] += SPECT_DIFF_TAVG * (avgDiffNormMagn - inst->featureData[4]); +} + +// Compute speech/noise probability +// speech/noise probability is returned in: probSpeechFinal +//magn is the input magnitude spectrum +//noise is the noise spectrum +//snrLocPrior is the prior snr for each freq. +//snr loc_post is the post snr for each freq. +void WebRtcNs_SpeechNoiseProb(NSinst_t *inst, float *probSpeechFinal, float *snrLocPrior, + float *snrLocPost) +{ + int i, sgnMap; + float invLrt, gainPrior, indPrior; + float logLrtTimeAvgKsum, besselTmp; + float indicator0, indicator1, indicator2; + float tmpFloat1, tmpFloat2; + float weightIndPrior0, weightIndPrior1, weightIndPrior2; + float threshPrior0, threshPrior1, threshPrior2; + float widthPrior, widthPrior0, widthPrior1, widthPrior2; + + widthPrior0 = WIDTH_PR_MAP; + widthPrior1 = (float)2.0 * WIDTH_PR_MAP; //width for pause region: + // lower range, so increase width in tanh map + widthPrior2 = (float)2.0 * WIDTH_PR_MAP; //for spectral-difference measure + + //threshold parameters for features + threshPrior0 = inst->priorModelPars[0]; + threshPrior1 = inst->priorModelPars[1]; + threshPrior2 = inst->priorModelPars[3]; + + //sign for flatness feature + sgnMap = (int)(inst->priorModelPars[2]); + + //weight parameters for features + weightIndPrior0 = inst->priorModelPars[4]; + weightIndPrior1 = inst->priorModelPars[5]; + weightIndPrior2 = inst->priorModelPars[6]; + + // compute feature based on average LR factor + // this is the average over all frequencies of the smooth log lrt + logLrtTimeAvgKsum = 0.0; + for (i = 0; i < inst->magnLen; i++) + { + tmpFloat1 = (float)1.0 + (float)2.0 * snrLocPrior[i]; + tmpFloat2 = (float)2.0 * snrLocPrior[i] / (tmpFloat1 + (float)0.0001); + besselTmp = (snrLocPost[i] + (float)1.0) * tmpFloat2; + inst->logLrtTimeAvg[i] += LRT_TAVG * (besselTmp - (float)log(tmpFloat1) + - inst->logLrtTimeAvg[i]); + logLrtTimeAvgKsum += inst->logLrtTimeAvg[i]; + } + logLrtTimeAvgKsum = (float)logLrtTimeAvgKsum / (inst->magnLen); + inst->featureData[3] = logLrtTimeAvgKsum; + // done with computation of LR factor + + // + //compute the indicator functions + // + + // average lrt feature + widthPrior = widthPrior0; + //use larger width in tanh map for pause regions + if (logLrtTimeAvgKsum < threshPrior0) + { + widthPrior = widthPrior1; + } + // compute indicator function: sigmoid map + indicator0 = (float)0.5 * ((float)tanh(widthPrior * (logLrtTimeAvgKsum - threshPrior0)) + + (float)1.0); + + //spectral flatness feature + tmpFloat1 = inst->featureData[0]; + widthPrior = widthPrior0; + //use larger width in tanh map for pause regions + if (sgnMap == 1 && (tmpFloat1 > threshPrior1)) + { + widthPrior = widthPrior1; + } + if (sgnMap == -1 && (tmpFloat1 < threshPrior1)) + { + widthPrior = widthPrior1; + } + // compute indicator function: sigmoid map + indicator1 = (float)0.5 * ((float)tanh( + (float)sgnMap * widthPrior * (threshPrior1 + - tmpFloat1)) + (float)1.0); + + //for template spectrum-difference + tmpFloat1 = inst->featureData[4]; + widthPrior = widthPrior0; + //use larger width in tanh map for pause regions + if (tmpFloat1 < threshPrior2) + { + widthPrior = widthPrior2; + } + // compute indicator function: sigmoid map + indicator2 = (float)0.5 * ((float)tanh(widthPrior * (tmpFloat1 - threshPrior2)) + + (float)1.0); + + //combine the indicator function with the feature weights + indPrior = weightIndPrior0 * indicator0 + weightIndPrior1 * indicator1 + weightIndPrior2 + * indicator2; + // done with computing indicator function + + //compute the prior probability + inst->priorSpeechProb += PRIOR_UPDATE * (indPrior - inst->priorSpeechProb); + // make sure probabilities are within range: keep floor to 0.01 + if (inst->priorSpeechProb > 1.0) + { + inst->priorSpeechProb = (float)1.0; + } + if (inst->priorSpeechProb < 0.01) + { + inst->priorSpeechProb = (float)0.01; + } + + //final speech probability: combine prior model with LR factor: + gainPrior = ((float)1.0 - inst->priorSpeechProb) / (inst->priorSpeechProb + (float)0.0001); + for (i = 0; i < inst->magnLen; i++) + { + invLrt = (float)exp(-inst->logLrtTimeAvg[i]); + invLrt = (float)gainPrior * invLrt; + probSpeechFinal[i] = (float)1.0 / ((float)1.0 + invLrt); + } +} + +int WebRtcNs_ProcessCore(NSinst_t *inst, + short *speechFrame, + short *speechFrameHB, + short *outFrame, + short *outFrameHB) +{ + // main routine for noise reduction + + int flagHB = 0; + int i; + const int kStartBand = 5; // Skip first frequency bins during estimation. + int updateParsFlag; + + float energy1, energy2, gain, factor, factor1, factor2; + float signalEnergy, sumMagn; + float snrPrior, currentEstimateStsa; + float tmpFloat1, tmpFloat2, tmpFloat3, probSpeech, probNonSpeech; + float gammaNoiseTmp, gammaNoiseOld; + float noiseUpdateTmp, fTmp, dTmp; + float fin[BLOCKL_MAX], fout[BLOCKL_MAX]; + float winData[ANAL_BLOCKL_MAX]; + float magn[HALF_ANAL_BLOCKL], noise[HALF_ANAL_BLOCKL]; + float theFilter[HALF_ANAL_BLOCKL], theFilterTmp[HALF_ANAL_BLOCKL]; + float snrLocPost[HALF_ANAL_BLOCKL], snrLocPrior[HALF_ANAL_BLOCKL]; + float probSpeechFinal[HALF_ANAL_BLOCKL], previousEstimateStsa[HALF_ANAL_BLOCKL]; + float real[ANAL_BLOCKL_MAX], imag[HALF_ANAL_BLOCKL]; + // Variables during startup + float sum_log_i = 0.0; + float sum_log_i_square = 0.0; + float sum_log_magn = 0.0; + float sum_log_i_log_magn = 0.0; + float parametric_noise = 0.0; + float parametric_exp = 0.0; + float parametric_num = 0.0; + + // SWB variables + int deltaBweHB = 1; + int deltaGainHB = 1; + float decayBweHB = 1.0; + float gainMapParHB = 1.0; + float gainTimeDomainHB = 1.0; + float avgProbSpeechHB, avgProbSpeechHBTmp, avgFilterGainHB, gainModHB; + + // Check that initiation has been done + if (inst->initFlag != 1) + { + return (-1); + } + // Check for valid pointers based on sampling rate + if (inst->fs == 32000) + { + if (speechFrameHB == NULL) + { + return -1; + } + flagHB = 1; + // range for averaging low band quantities for H band gain + deltaBweHB = (int)inst->magnLen / 4; + deltaGainHB = deltaBweHB; + } + // + updateParsFlag = inst->modelUpdatePars[0]; + // + + //for LB do all processing + // convert to float + for (i = 0; i < inst->blockLen10ms; i++) + { + fin[i] = (float)speechFrame[i]; + } + // update analysis buffer for L band + memcpy(inst->dataBuf, inst->dataBuf + inst->blockLen10ms, + sizeof(float) * (inst->anaLen - inst->blockLen10ms)); + memcpy(inst->dataBuf + inst->anaLen - inst->blockLen10ms, fin, + sizeof(float) * inst->blockLen10ms); + + if (flagHB == 1) + { + // convert to float + for (i = 0; i < inst->blockLen10ms; i++) + { + fin[i] = (float)speechFrameHB[i]; + } + // update analysis buffer for H band + memcpy(inst->dataBufHB, inst->dataBufHB + inst->blockLen10ms, + sizeof(float) * (inst->anaLen - inst->blockLen10ms)); + memcpy(inst->dataBufHB + inst->anaLen - inst->blockLen10ms, fin, + sizeof(float) * inst->blockLen10ms); + } + + // check if processing needed + if (inst->outLen == 0) + { + // windowing + energy1 = 0.0; + for (i = 0; i < inst->anaLen; i++) + { + winData[i] = inst->window[i] * inst->dataBuf[i]; + energy1 += winData[i] * winData[i]; + } + if (energy1 == 0.0) + { + // synthesize the special case of zero input + // we want to avoid updating statistics in this case: + // Updating feature statistics when we have zeros only will cause thresholds to + // move towards zero signal situations. This in turn has the effect that once the + // signal is "turned on" (non-zero values) everything will be treated as speech + // and there is no noise suppression effect. Depending on the duration of the + // inactive signal it takes a considerable amount of time for the system to learn + // what is noise and what is speech. + + // read out fully processed segment + for (i = inst->windShift; i < inst->blockLen + inst->windShift; i++) + { + fout[i - inst->windShift] = inst->syntBuf[i]; + } + // update synthesis buffer + memcpy(inst->syntBuf, inst->syntBuf + inst->blockLen, + sizeof(float) * (inst->anaLen - inst->blockLen)); + memset(inst->syntBuf + inst->anaLen - inst->blockLen, 0, + sizeof(float) * inst->blockLen); + + // out buffer + inst->outLen = inst->blockLen - inst->blockLen10ms; + if (inst->blockLen > inst->blockLen10ms) + { + for (i = 0; i < inst->outLen; i++) + { + inst->outBuf[i] = fout[i + inst->blockLen10ms]; + } + } + // convert to short + for (i = 0; i < inst->blockLen10ms; i++) + { + dTmp = fout[i]; + if (dTmp < WEBRTC_SPL_WORD16_MIN) + { + dTmp = WEBRTC_SPL_WORD16_MIN; + } + else if (dTmp > WEBRTC_SPL_WORD16_MAX) + { + dTmp = WEBRTC_SPL_WORD16_MAX; + } + outFrame[i] = (short)dTmp; + } + + // for time-domain gain of HB + if (flagHB == 1) + { + for (i = 0; i < inst->blockLen10ms; i++) + { + dTmp = inst->dataBufHB[i]; + if (dTmp < WEBRTC_SPL_WORD16_MIN) + { + dTmp = WEBRTC_SPL_WORD16_MIN; + } + else if (dTmp > WEBRTC_SPL_WORD16_MAX) + { + dTmp = WEBRTC_SPL_WORD16_MAX; + } + outFrameHB[i] = (short)dTmp; + } + } // end of H band gain computation + // + return 0; + } + + // + inst->blockInd++; // Update the block index only when we process a block. + // FFT + rdft(inst->anaLen, 1, winData, inst->ip, inst->wfft); + + imag[0] = 0; + real[0] = winData[0]; + magn[0] = (float)(fabs(real[0]) + 1.0f); + imag[inst->magnLen - 1] = 0; + real[inst->magnLen - 1] = winData[1]; + magn[inst->magnLen - 1] = (float)(fabs(real[inst->magnLen - 1]) + 1.0f); + signalEnergy = (float)(real[0] * real[0]) + (float)(real[inst->magnLen - 1] + * real[inst->magnLen - 1]); + sumMagn = magn[0] + magn[inst->magnLen - 1]; + if (inst->blockInd < END_STARTUP_SHORT) + { + inst->initMagnEst[0] += magn[0]; + inst->initMagnEst[inst->magnLen - 1] += magn[inst->magnLen - 1]; + tmpFloat2 = log((float)(inst->magnLen - 1)); + sum_log_i = tmpFloat2; + sum_log_i_square = tmpFloat2 * tmpFloat2; + tmpFloat1 = log(magn[inst->magnLen - 1]); + sum_log_magn = tmpFloat1; + sum_log_i_log_magn = tmpFloat2 * tmpFloat1; + } + for (i = 1; i < inst->magnLen - 1; i++) + { + real[i] = winData[2 * i]; + imag[i] = winData[2 * i + 1]; + // magnitude spectrum + fTmp = real[i] * real[i]; + fTmp += imag[i] * imag[i]; + signalEnergy += fTmp; + magn[i] = ((float)sqrt(fTmp)) + 1.0f; + sumMagn += magn[i]; + if (inst->blockInd < END_STARTUP_SHORT) + { + inst->initMagnEst[i] += magn[i]; + if (i >= kStartBand) + { + tmpFloat2 = log((float)i); + sum_log_i += tmpFloat2; + sum_log_i_square += tmpFloat2 * tmpFloat2; + tmpFloat1 = log(magn[i]); + sum_log_magn += tmpFloat1; + sum_log_i_log_magn += tmpFloat2 * tmpFloat1; + } + } + } + signalEnergy = signalEnergy / ((float)inst->magnLen); + inst->signalEnergy = signalEnergy; + inst->sumMagn = sumMagn; + + //compute spectral flatness on input spectrum + WebRtcNs_ComputeSpectralFlatness(inst, magn); + // quantile noise estimate + WebRtcNs_NoiseEstimation(inst, magn, noise); + //compute simplified noise model during startup + if (inst->blockInd < END_STARTUP_SHORT) + { + // Estimate White noise + inst->whiteNoiseLevel += sumMagn / ((float)inst->magnLen) * inst->overdrive; + // Estimate Pink noise parameters + tmpFloat1 = sum_log_i_square * ((float)(inst->magnLen - kStartBand)); + tmpFloat1 -= (sum_log_i * sum_log_i); + tmpFloat2 = (sum_log_i_square * sum_log_magn - sum_log_i * sum_log_i_log_magn); + tmpFloat3 = tmpFloat2 / tmpFloat1; + // Constrain the estimated spectrum to be positive + if (tmpFloat3 < 0.0f) + { + tmpFloat3 = 0.0f; + } + inst->pinkNoiseNumerator += tmpFloat3; + tmpFloat2 = (sum_log_i * sum_log_magn); + tmpFloat2 -= ((float)(inst->magnLen - kStartBand)) * sum_log_i_log_magn; + tmpFloat3 = tmpFloat2 / tmpFloat1; + // Constrain the pink noise power to be in the interval [0, 1]; + if (tmpFloat3 < 0.0f) + { + tmpFloat3 = 0.0f; + } + if (tmpFloat3 > 1.0f) + { + tmpFloat3 = 1.0f; + } + inst->pinkNoiseExp += tmpFloat3; + + // Calculate frequency independent parts of parametric noise estimate. + if (inst->pinkNoiseExp == 0.0f) + { + // Use white noise estimate + parametric_noise = inst->whiteNoiseLevel; + } + else + { + // Use pink noise estimate + parametric_num = exp(inst->pinkNoiseNumerator / (float)(inst->blockInd + 1)); + parametric_num *= (float)(inst->blockInd + 1); + parametric_exp = inst->pinkNoiseExp / (float)(inst->blockInd + 1); + parametric_noise = parametric_num / pow((float)kStartBand, parametric_exp); + } + for (i = 0; i < inst->magnLen; i++) + { + // Estimate the background noise using the white and pink noise parameters + if ((inst->pinkNoiseExp > 0.0f) && (i >= kStartBand)) + { + // Use pink noise estimate + parametric_noise = parametric_num / pow((float)i, parametric_exp); + } + theFilterTmp[i] = (inst->initMagnEst[i] - inst->overdrive * parametric_noise); + theFilterTmp[i] /= (inst->initMagnEst[i] + (float)0.0001); + // Weight quantile noise with modeled noise + noise[i] *= (inst->blockInd); + tmpFloat2 = parametric_noise * (END_STARTUP_SHORT - inst->blockInd); + noise[i] += (tmpFloat2 / (float)(inst->blockInd + 1)); + noise[i] /= END_STARTUP_SHORT; + } + } + //compute average signal during END_STARTUP_LONG time: + // used to normalize spectral difference measure + if (inst->blockInd < END_STARTUP_LONG) + { + inst->featureData[5] *= inst->blockInd; + inst->featureData[5] += signalEnergy; + inst->featureData[5] /= (inst->blockInd + 1); + } + +#ifdef PROCESS_FLOW_0 + if (inst->blockInd > END_STARTUP_LONG) + { + //option: average the quantile noise: for check with AEC2 + for (i = 0; i < inst->magnLen; i++) + { + noise[i] = (float)0.6 * inst->noisePrev[i] + (float)0.4 * noise[i]; + } + for (i = 0; i < inst->magnLen; i++) + { + // Wiener with over sub-substraction: + theFilter[i] = (magn[i] - inst->overdrive * noise[i]) / (magn[i] + (float)0.0001); + } + } +#else + //start processing at frames == converged+1 + // + // STEP 1: compute prior and post snr based on quantile noise est + // + + // compute DD estimate of prior SNR: needed for new method + for (i = 0; i < inst->magnLen; i++) + { + // post snr + snrLocPost[i] = (float)0.0; + if (magn[i] > noise[i]) + { + snrLocPost[i] = magn[i] / (noise[i] + (float)0.0001) - (float)1.0; + } + // previous post snr + // previous estimate: based on previous frame with gain filter + previousEstimateStsa[i] = inst->magnPrev[i] / (inst->noisePrev[i] + (float)0.0001) + * (inst->smooth[i]); + // DD estimate is sum of two terms: current estimate and previous estimate + // directed decision update of snrPrior + snrLocPrior[i] = DD_PR_SNR * previousEstimateStsa[i] + ((float)1.0 - DD_PR_SNR) + * snrLocPost[i]; + // post and prior snr needed for step 2 + } // end of loop over freqs +#ifdef PROCESS_FLOW_1 + for (i = 0; i < inst->magnLen; i++) + { + // gain filter + tmpFloat1 = inst->overdrive + snrLocPrior[i]; + tmpFloat2 = (float)snrLocPrior[i] / tmpFloat1; + theFilter[i] = (float)tmpFloat2; + } // end of loop over freqs +#endif + // done with step 1: dd computation of prior and post snr + + // + //STEP 2: compute speech/noise likelihood + // +#ifdef PROCESS_FLOW_2 + // compute difference of input spectrum with learned/estimated noise spectrum + WebRtcNs_ComputeSpectralDifference(inst, magn); + // compute histograms for parameter decisions (thresholds and weights for features) + // parameters are extracted once every window time (=inst->modelUpdatePars[1]) + if (updateParsFlag >= 1) + { + // counter update + inst->modelUpdatePars[3]--; + // update histogram + if (inst->modelUpdatePars[3] > 0) + { + WebRtcNs_FeatureParameterExtraction(inst, 0); + } + // compute model parameters + if (inst->modelUpdatePars[3] == 0) + { + WebRtcNs_FeatureParameterExtraction(inst, 1); + inst->modelUpdatePars[3] = inst->modelUpdatePars[1]; + // if wish to update only once, set flag to zero + if (updateParsFlag == 1) + { + inst->modelUpdatePars[0] = 0; + } + else + { + // update every window: + // get normalization for spectral difference for next window estimate + inst->featureData[6] = inst->featureData[6] + / ((float)inst->modelUpdatePars[1]); + inst->featureData[5] = (float)0.5 * (inst->featureData[6] + + inst->featureData[5]); + inst->featureData[6] = (float)0.0; + } + } + } + // compute speech/noise probability + WebRtcNs_SpeechNoiseProb(inst, probSpeechFinal, snrLocPrior, snrLocPost); + // time-avg parameter for noise update + gammaNoiseTmp = NOISE_UPDATE; + for (i = 0; i < inst->magnLen; i++) + { + probSpeech = probSpeechFinal[i]; + probNonSpeech = (float)1.0 - probSpeech; + // temporary noise update: + // use it for speech frames if update value is less than previous + noiseUpdateTmp = gammaNoiseTmp * inst->noisePrev[i] + ((float)1.0 - gammaNoiseTmp) + * (probNonSpeech * magn[i] + probSpeech * inst->noisePrev[i]); + // + // time-constant based on speech/noise state + gammaNoiseOld = gammaNoiseTmp; + gammaNoiseTmp = NOISE_UPDATE; + // increase gamma (i.e., less noise update) for frame likely to be speech + if (probSpeech > PROB_RANGE) + { + gammaNoiseTmp = SPEECH_UPDATE; + } + // conservative noise update + if (probSpeech < PROB_RANGE) + { + inst->magnAvgPause[i] += GAMMA_PAUSE * (magn[i] - inst->magnAvgPause[i]); + } + // noise update + if (gammaNoiseTmp == gammaNoiseOld) + { + noise[i] = noiseUpdateTmp; + } + else + { + noise[i] = gammaNoiseTmp * inst->noisePrev[i] + ((float)1.0 - gammaNoiseTmp) + * (probNonSpeech * magn[i] + probSpeech * inst->noisePrev[i]); + // allow for noise update downwards: + // if noise update decreases the noise, it is safe, so allow it to happen + if (noiseUpdateTmp < noise[i]) + { + noise[i] = noiseUpdateTmp; + } + } + } // end of freq loop + // done with step 2: noise update + + // + // STEP 3: compute dd update of prior snr and post snr based on new noise estimate + // + for (i = 0; i < inst->magnLen; i++) + { + // post and prior snr + currentEstimateStsa = (float)0.0; + if (magn[i] > noise[i]) + { + currentEstimateStsa = magn[i] / (noise[i] + (float)0.0001) - (float)1.0; + } + // DD estimate is sume of two terms: current estimate and previous estimate + // directed decision update of snrPrior + snrPrior = DD_PR_SNR * previousEstimateStsa[i] + ((float)1.0 - DD_PR_SNR) + * currentEstimateStsa; + // gain filter + tmpFloat1 = inst->overdrive + snrPrior; + tmpFloat2 = (float)snrPrior / tmpFloat1; + theFilter[i] = (float)tmpFloat2; + } // end of loop over freqs + // done with step3 +#endif +#endif + + for (i = 0; i < inst->magnLen; i++) + { + // flooring bottom + if (theFilter[i] < inst->denoiseBound) + { + theFilter[i] = inst->denoiseBound; + } + // flooring top + if (theFilter[i] > (float)1.0) + { + theFilter[i] = 1.0; + } + if (inst->blockInd < END_STARTUP_SHORT) + { + // flooring bottom + if (theFilterTmp[i] < inst->denoiseBound) + { + theFilterTmp[i] = inst->denoiseBound; + } + // flooring top + if (theFilterTmp[i] > (float)1.0) + { + theFilterTmp[i] = 1.0; + } + // Weight the two suppression filters + theFilter[i] *= (inst->blockInd); + theFilterTmp[i] *= (END_STARTUP_SHORT - inst->blockInd); + theFilter[i] += theFilterTmp[i]; + theFilter[i] /= (END_STARTUP_SHORT); + } + // smoothing +#ifdef PROCESS_FLOW_0 + inst->smooth[i] *= SMOOTH; // value set to 0.7 in define.h file + inst->smooth[i] += ((float)1.0 - SMOOTH) * theFilter[i]; +#else + inst->smooth[i] = theFilter[i]; +#endif + real[i] *= inst->smooth[i]; + imag[i] *= inst->smooth[i]; + } + // keep track of noise and magn spectrum for next frame + for (i = 0; i < inst->magnLen; i++) + { + inst->noisePrev[i] = noise[i]; + inst->magnPrev[i] = magn[i]; + } + // back to time domain + winData[0] = real[0]; + winData[1] = real[inst->magnLen - 1]; + for (i = 1; i < inst->magnLen - 1; i++) + { + winData[2 * i] = real[i]; + winData[2 * i + 1] = imag[i]; + } + rdft(inst->anaLen, -1, winData, inst->ip, inst->wfft); + + for (i = 0; i < inst->anaLen; i++) + { + real[i] = 2.0f * winData[i] / inst->anaLen; // fft scaling + } + + //scale factor: only do it after END_STARTUP_LONG time + factor = (float)1.0; + if (inst->gainmap == 1 && inst->blockInd > END_STARTUP_LONG) + { + factor1 = (float)1.0; + factor2 = (float)1.0; + + energy2 = 0.0; + for (i = 0; i < inst->anaLen;i++) + { + energy2 += (float)real[i] * (float)real[i]; + } + gain = (float)sqrt(energy2 / (energy1 + (float)1.0)); + +#ifdef PROCESS_FLOW_2 + // scaling for new version + if (gain > B_LIM) + { + factor1 = (float)1.0 + (float)1.3 * (gain - B_LIM); + if (gain * factor1 > (float)1.0) + { + factor1 = (float)1.0 / gain; + } + } + if (gain < B_LIM) + { + //don't reduce scale too much for pause regions: + // attenuation here should be controlled by flooring + if (gain <= inst->denoiseBound) + { + gain = inst->denoiseBound; + } + factor2 = (float)1.0 - (float)0.3 * (B_LIM - gain); + } + //combine both scales with speech/noise prob: + // note prior (priorSpeechProb) is not frequency dependent + factor = inst->priorSpeechProb * factor1 + ((float)1.0 - inst->priorSpeechProb) + * factor2; +#else + if (gain > B_LIM) + { + factor = (float)1.0 + (float)1.3 * (gain - B_LIM); + } + else + { + factor = (float)1.0 + (float)2.0 * (gain - B_LIM); + } + if (gain * factor > (float)1.0) + { + factor = (float)1.0 / gain; + } +#endif + } // out of inst->gainmap==1 + + // synthesis + for (i = 0; i < inst->anaLen; i++) + { + inst->syntBuf[i] += factor * inst->window[i] * (float)real[i]; + } + // read out fully processed segment + for (i = inst->windShift; i < inst->blockLen + inst->windShift; i++) + { + fout[i - inst->windShift] = inst->syntBuf[i]; + } + // update synthesis buffer + memcpy(inst->syntBuf, inst->syntBuf + inst->blockLen, + sizeof(float) * (inst->anaLen - inst->blockLen)); + memset(inst->syntBuf + inst->anaLen - inst->blockLen, 0, + sizeof(float) * inst->blockLen); + + // out buffer + inst->outLen = inst->blockLen - inst->blockLen10ms; + if (inst->blockLen > inst->blockLen10ms) + { + for (i = 0; i < inst->outLen; i++) + { + inst->outBuf[i] = fout[i + inst->blockLen10ms]; + } + } + } // end of if out.len==0 + else + { + for (i = 0; i < inst->blockLen10ms; i++) + { + fout[i] = inst->outBuf[i]; + } + memcpy(inst->outBuf, inst->outBuf + inst->blockLen10ms, + sizeof(float) * (inst->outLen - inst->blockLen10ms)); + memset(inst->outBuf + inst->outLen - inst->blockLen10ms, 0, + sizeof(float) * inst->blockLen10ms); + inst->outLen -= inst->blockLen10ms; + } + + // convert to short + for (i = 0; i < inst->blockLen10ms; i++) + { + dTmp = fout[i]; + if (dTmp < WEBRTC_SPL_WORD16_MIN) + { + dTmp = WEBRTC_SPL_WORD16_MIN; + } + else if (dTmp > WEBRTC_SPL_WORD16_MAX) + { + dTmp = WEBRTC_SPL_WORD16_MAX; + } + outFrame[i] = (short)dTmp; + } + + // for time-domain gain of HB + if (flagHB == 1) + { + for (i = 0; i < inst->magnLen; i++) + { + inst->speechProbHB[i] = probSpeechFinal[i]; + } + if (inst->blockInd > END_STARTUP_LONG) + { + // average speech prob from low band + // avg over second half (i.e., 4->8kHz) of freq. spectrum + avgProbSpeechHB = 0.0; + for (i = inst->magnLen - deltaBweHB - 1; i < inst->magnLen - 1; i++) + { + avgProbSpeechHB += inst->speechProbHB[i]; + } + avgProbSpeechHB = avgProbSpeechHB / ((float)deltaBweHB); + // average filter gain from low band + // average over second half (i.e., 4->8kHz) of freq. spectrum + avgFilterGainHB = 0.0; + for (i = inst->magnLen - deltaGainHB - 1; i < inst->magnLen - 1; i++) + { + avgFilterGainHB += inst->smooth[i]; + } + avgFilterGainHB = avgFilterGainHB / ((float)(deltaGainHB)); + avgProbSpeechHBTmp = (float)2.0 * avgProbSpeechHB - (float)1.0; + // gain based on speech prob: + gainModHB = (float)0.5 * ((float)1.0 + (float)tanh(gainMapParHB * avgProbSpeechHBTmp)); + //combine gain with low band gain + gainTimeDomainHB = (float)0.5 * gainModHB + (float)0.5 * avgFilterGainHB; + if (avgProbSpeechHB >= (float)0.5) + { + gainTimeDomainHB = (float)0.25 * gainModHB + (float)0.75 * avgFilterGainHB; + } + gainTimeDomainHB = gainTimeDomainHB * decayBweHB; + } // end of converged + //make sure gain is within flooring range + // flooring bottom + if (gainTimeDomainHB < inst->denoiseBound) + { + gainTimeDomainHB = inst->denoiseBound; + } + // flooring top + if (gainTimeDomainHB > (float)1.0) + { + gainTimeDomainHB = 1.0; + } + //apply gain + for (i = 0; i < inst->blockLen10ms; i++) + { + dTmp = gainTimeDomainHB * inst->dataBufHB[i]; + if (dTmp < WEBRTC_SPL_WORD16_MIN) + { + dTmp = WEBRTC_SPL_WORD16_MIN; + } + else if (dTmp > WEBRTC_SPL_WORD16_MAX) + { + dTmp = WEBRTC_SPL_WORD16_MAX; + } + outFrameHB[i] = (short)dTmp; + } + } // end of H band gain computation + // + + return 0; +} diff --git a/src/modules/audio_processing/ns/main/source/ns_core.h b/src/modules/audio_processing/ns/main/source/ns_core.h new file mode 100644 index 0000000..f72e22b --- /dev/null +++ b/src/modules/audio_processing/ns/main/source/ns_core.h @@ -0,0 +1,179 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +#ifndef WEBRTC_MODULES_AUDIO_PROCESSING_NS_MAIN_SOURCE_NS_CORE_H_ +#define WEBRTC_MODULES_AUDIO_PROCESSING_NS_MAIN_SOURCE_NS_CORE_H_ + +#include "defines.h" + +typedef struct NSParaExtract_t_ { + + //bin size of histogram + float binSizeLrt; + float binSizeSpecFlat; + float binSizeSpecDiff; + //range of histogram over which lrt threshold is computed + float rangeAvgHistLrt; + //scale parameters: multiply dominant peaks of the histograms by scale factor to obtain + //thresholds for prior model + float factor1ModelPars; //for lrt and spectral difference + float factor2ModelPars; //for spectral_flatness: used when noise is flatter than speech + //peak limit for spectral flatness (varies between 0 and 1) + float thresPosSpecFlat; + //limit on spacing of two highest peaks in histogram: spacing determined by bin size + float limitPeakSpacingSpecFlat; + float limitPeakSpacingSpecDiff; + //limit on relevance of second peak: + float limitPeakWeightsSpecFlat; + float limitPeakWeightsSpecDiff; + //limit on fluctuation of lrt feature + float thresFluctLrt; + //limit on the max and min values for the feature thresholds + float maxLrt; + float minLrt; + float maxSpecFlat; + float minSpecFlat; + float maxSpecDiff; + float minSpecDiff; + //criteria of weight of histogram peak to accept/reject feature + int thresWeightSpecFlat; + int thresWeightSpecDiff; + +} NSParaExtract_t; + +typedef struct NSinst_t_ { + + WebRtc_UWord32 fs; + int blockLen; + int blockLen10ms; + int windShift; + int outLen; + int anaLen; + int magnLen; + int aggrMode; + const float* window; + float dataBuf[ANAL_BLOCKL_MAX]; + float syntBuf[ANAL_BLOCKL_MAX]; + float outBuf[3 * BLOCKL_MAX]; + + int initFlag; + // parameters for quantile noise estimation + float density[SIMULT * HALF_ANAL_BLOCKL]; + float lquantile[SIMULT * HALF_ANAL_BLOCKL]; + float quantile[HALF_ANAL_BLOCKL]; + int counter[SIMULT]; + int updates; + // parameters for Wiener filter + float smooth[HALF_ANAL_BLOCKL]; + float overdrive; + float denoiseBound; + int gainmap; + // fft work arrays. + int ip[IP_LENGTH]; + float wfft[W_LENGTH]; + + // parameters for new method: some not needed, will reduce/cleanup later + WebRtc_Word32 blockInd; //frame index counter + int modelUpdatePars[4]; //parameters for updating or estimating + // thresholds/weights for prior model + float priorModelPars[7]; //parameters for prior model + float noisePrev[HALF_ANAL_BLOCKL]; //noise spectrum from previous frame + float magnPrev[HALF_ANAL_BLOCKL]; //magnitude spectrum of previous frame + float logLrtTimeAvg[HALF_ANAL_BLOCKL]; //log lrt factor with time-smoothing + float priorSpeechProb; //prior speech/noise probability + float featureData[7]; //data for features + float magnAvgPause[HALF_ANAL_BLOCKL]; //conservative noise spectrum estimate + float signalEnergy; //energy of magn + float sumMagn; //sum of magn + float whiteNoiseLevel; //initial noise estimate + float initMagnEst[HALF_ANAL_BLOCKL]; //initial magnitude spectrum estimate + float pinkNoiseNumerator; //pink noise parameter: numerator + float pinkNoiseExp; //pink noise parameter: power of freq + NSParaExtract_t featureExtractionParams; //parameters for feature extraction + //histograms for parameter estimation + int histLrt[HIST_PAR_EST]; + int histSpecFlat[HIST_PAR_EST]; + int histSpecDiff[HIST_PAR_EST]; + //quantities for high band estimate + float speechProbHB[HALF_ANAL_BLOCKL]; //final speech/noise prob: prior + LRT + float dataBufHB[ANAL_BLOCKL_MAX]; //buffering data for HB + +} NSinst_t; + + +#ifdef __cplusplus +extern "C" { +#endif + +/**************************************************************************** + * WebRtcNs_InitCore(...) + * + * This function initializes a noise suppression instance + * + * Input: + * - inst : Instance that should be initialized + * - fs : Sampling frequency + * + * Output: + * - inst : Initialized instance + * + * Return value : 0 - Ok + * -1 - Error + */ +int WebRtcNs_InitCore(NSinst_t *inst, WebRtc_UWord32 fs); + +/**************************************************************************** + * WebRtcNs_set_policy_core(...) + * + * This changes the aggressiveness of the noise suppression method. + * + * Input: + * - inst : Instance that should be initialized + * - mode : 0: Mild (6 dB), 1: Medium (10 dB), 2: Aggressive (15 dB) + * + * Output: + * - NS_inst : Initialized instance + * + * Return value : 0 - Ok + * -1 - Error + */ +int WebRtcNs_set_policy_core(NSinst_t *inst, int mode); + +/**************************************************************************** + * WebRtcNs_ProcessCore + * + * Do noise suppression. + * + * Input: + * - inst : Instance that should be initialized + * - inFrameLow : Input speech frame for lower band + * - inFrameHigh : Input speech frame for higher band + * + * Output: + * - inst : Updated instance + * - outFrameLow : Output speech frame for lower band + * - outFrameHigh : Output speech frame for higher band + * + * Return value : 0 - OK + * -1 - Error + */ + + +int WebRtcNs_ProcessCore(NSinst_t *inst, + short *inFrameLow, + short *inFrameHigh, + short *outFrameLow, + short *outFrameHigh); + + +#ifdef __cplusplus +} +#endif +#endif // WEBRTC_MODULES_AUDIO_PROCESSING_NS_MAIN_SOURCE_NS_CORE_H_ diff --git a/src/modules/audio_processing/ns/main/source/nsx_core.c b/src/modules/audio_processing/ns/main/source/nsx_core.c new file mode 100644 index 0000000..f499cbe --- /dev/null +++ b/src/modules/audio_processing/ns/main/source/nsx_core.c @@ -0,0 +1,2494 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +#include "noise_suppression_x.h" + +#include +#include +#include +#include + +#include "nsx_core.h" + +// Skip first frequency bins during estimation. (0 <= value < 64) +static const int kStartBand = 5; + +// Rounding +static const WebRtc_Word16 kRoundTable[16] = {0, 1, 2, 4, 8, 16, 32, 64, 128, 256, 512, 1024, + 2048, 4096, 8192, 16384}; + +// Constants to compensate for shifting signal log(2^shifts). +const WebRtc_Word16 WebRtcNsx_kLogTable[9] = {0, 177, 355, 532, 710, 887, 1065, 1242, 1420}; + +const WebRtc_Word16 WebRtcNsx_kCounterDiv[201] = {32767, 16384, 10923, 8192, 6554, 5461, 4681, + 4096, 3641, 3277, 2979, 2731, 2521, 2341, 2185, 2048, 1928, 1820, 1725, 1638, 1560, + 1489, 1425, 1365, 1311, 1260, 1214, 1170, 1130, 1092, 1057, 1024, 993, 964, 936, 910, + 886, 862, 840, 819, 799, 780, 762, 745, 728, 712, 697, 683, 669, 655, 643, 630, 618, + 607, 596, 585, 575, 565, 555, 546, 537, 529, 520, 512, 504, 496, 489, 482, 475, 468, + 462, 455, 449, 443, 437, 431, 426, 420, 415, 410, 405, 400, 395, 390, 386, 381, 377, + 372, 368, 364, 360, 356, 352, 349, 345, 341, 338, 334, 331, 328, 324, 321, 318, 315, + 312, 309, 306, 303, 301, 298, 295, 293, 290, 287, 285, 282, 280, 278, 275, 273, 271, + 269, 266, 264, 262, 260, 258, 256, 254, 252, 250, 248, 246, 245, 243, 241, 239, 237, + 236, 234, 232, 231, 229, 228, 226, 224, 223, 221, 220, 218, 217, 216, 214, 213, 211, + 210, 209, 207, 206, 205, 204, 202, 201, 200, 199, 197, 196, 195, 194, 193, 192, 191, + 189, 188, 187, 186, 185, 184, 183, 182, 181, 180, 179, 178, 177, 176, 175, 174, 173, + 172, 172, 171, 170, 169, 168, 167, 166, 165, 165, 164, 163}; + +const WebRtc_Word16 WebRtcNsx_kLogTableFrac[256] = { + 0, 1, 3, 4, 6, 7, 9, 10, 11, 13, 14, 16, 17, 18, 20, 21, + 22, 24, 25, 26, 28, 29, 30, 32, 33, 34, 36, 37, 38, 40, 41, 42, + 44, 45, 46, 47, 49, 50, 51, 52, 54, 55, 56, 57, 59, 60, 61, 62, + 63, 65, 66, 67, 68, 69, 71, 72, 73, 74, 75, 77, 78, 79, 80, 81, + 82, 84, 85, 86, 87, 88, 89, 90, 92, 93, 94, 95, 96, 97, 98, 99, + 100, 102, 103, 104, 105, 106, 107, 108, 109, 110, 111, 112, 113, 114, 116, 117, + 118, 119, 120, 121, 122, 123, 124, 125, 126, 127, 128, 129, 130, 131, 132, 133, + 134, 135, 136, 137, 138, 139, 140, 141, 142, 143, 144, 145, 146, 147, 148, 149, + 150, 151, 152, 153, 154, 155, 155, 156, 157, 158, 159, 160, 161, 162, 163, 164, + 165, 166, 167, 168, 169, 169, 170, 171, 172, 173, 174, 175, 176, 177, 178, 178, + 179, 180, 181, 182, 183, 184, 185, 185, 186, 187, 188, 189, 190, 191, 192, 192, + 193, 194, 195, 196, 197, 198, 198, 199, 200, 201, 202, 203, 203, 204, 205, 206, + 207, 208, 208, 209, 210, 211, 212, 212, 213, 214, 215, 216, 216, 217, 218, 219, + 220, 220, 221, 222, 223, 224, 224, 225, 226, 227, 228, 228, 229, 230, 231, 231, + 232, 233, 234, 234, 235, 236, 237, 238, 238, 239, 240, 241, 241, 242, 243, 244, + 244, 245, 246, 247, 247, 248, 249, 249, 250, 251, 252, 252, 253, 254, 255, 255 +}; + +static const WebRtc_Word16 kPowTableFrac[1024] = { + 0, 1, 1, 2, 3, 3, 4, 5, + 6, 6, 7, 8, 8, 9, 10, 10, + 11, 12, 13, 13, 14, 15, 15, 16, + 17, 17, 18, 19, 20, 20, 21, 22, + 22, 23, 24, 25, 25, 26, 27, 27, + 28, 29, 30, 30, 31, 32, 32, 33, + 34, 35, 35, 36, 37, 37, 38, 39, + 40, 40, 41, 42, 42, 43, 44, 45, + 45, 46, 47, 48, 48, 49, 50, 50, + 51, 52, 53, 53, 54, 55, 56, 56, + 57, 58, 58, 59, 60, 61, 61, 62, + 63, 64, 64, 65, 66, 67, 67, 68, + 69, 69, 70, 71, 72, 72, 73, 74, + 75, 75, 76, 77, 78, 78, 79, 80, + 81, 81, 82, 83, 84, 84, 85, 86, + 87, 87, 88, 89, 90, 90, 91, 92, + 93, 93, 94, 95, 96, 96, 97, 98, + 99, 100, 100, 101, 102, 103, 103, 104, + 105, 106, 106, 107, 108, 109, 109, 110, + 111, 112, 113, 113, 114, 115, 116, 116, + 117, 118, 119, 119, 120, 121, 122, 123, + 123, 124, 125, 126, 126, 127, 128, 129, + 130, 130, 131, 132, 133, 133, 134, 135, + 136, 137, 137, 138, 139, 140, 141, 141, + 142, 143, 144, 144, 145, 146, 147, 148, + 148, 149, 150, 151, 152, 152, 153, 154, + 155, 156, 156, 157, 158, 159, 160, 160, + 161, 162, 163, 164, 164, 165, 166, 167, + 168, 168, 169, 170, 171, 172, 173, 173, + 174, 175, 176, 177, 177, 178, 179, 180, + 181, 181, 182, 183, 184, 185, 186, 186, + 187, 188, 189, 190, 190, 191, 192, 193, + 194, 195, 195, 196, 197, 198, 199, 200, + 200, 201, 202, 203, 204, 205, 205, 206, + 207, 208, 209, 210, 210, 211, 212, 213, + 214, 215, 215, 216, 217, 218, 219, 220, + 220, 221, 222, 223, 224, 225, 225, 226, + 227, 228, 229, 230, 231, 231, 232, 233, + 234, 235, 236, 237, 237, 238, 239, 240, + 241, 242, 243, 243, 244, 245, 246, 247, + 248, 249, 249, 250, 251, 252, 253, 254, + 255, 255, 256, 257, 258, 259, 260, 261, + 262, 262, 263, 264, 265, 266, 267, 268, + 268, 269, 270, 271, 272, 273, 274, 275, + 276, 276, 277, 278, 279, 280, 281, 282, + 283, 283, 284, 285, 286, 287, 288, 289, + 290, 291, 291, 292, 293, 294, 295, 296, + 297, 298, 299, 299, 300, 301, 302, 303, + 304, 305, 306, 307, 308, 308, 309, 310, + 311, 312, 313, 314, 315, 316, 317, 318, + 318, 319, 320, 321, 322, 323, 324, 325, + 326, 327, 328, 328, 329, 330, 331, 332, + 333, 334, 335, 336, 337, 338, 339, 339, + 340, 341, 342, 343, 344, 345, 346, 347, + 348, 349, 350, 351, 352, 352, 353, 354, + 355, 356, 357, 358, 359, 360, 361, 362, + 363, 364, 365, 366, 367, 367, 368, 369, + 370, 371, 372, 373, 374, 375, 376, 377, + 378, 379, 380, 381, 382, 383, 384, 385, + 385, 386, 387, 388, 389, 390, 391, 392, + 393, 394, 395, 396, 397, 398, 399, 400, + 401, 402, 403, 404, 405, 406, 407, 408, + 409, 410, 410, 411, 412, 413, 414, 415, + 416, 417, 418, 419, 420, 421, 422, 423, + 424, 425, 426, 427, 428, 429, 430, 431, + 432, 433, 434, 435, 436, 437, 438, 439, + 440, 441, 442, 443, 444, 445, 446, 447, + 448, 449, 450, 451, 452, 453, 454, 455, + 456, 457, 458, 459, 460, 461, 462, 463, + 464, 465, 466, 467, 468, 469, 470, 471, + 472, 473, 474, 475, 476, 477, 478, 479, + 480, 481, 482, 483, 484, 485, 486, 487, + 488, 489, 490, 491, 492, 493, 494, 495, + 496, 498, 499, 500, 501, 502, 503, 504, + 505, 506, 507, 508, 509, 510, 511, 512, + 513, 514, 515, 516, 517, 518, 519, 520, + 521, 522, 523, 525, 526, 527, 528, 529, + 530, 531, 532, 533, 534, 535, 536, 537, + 538, 539, 540, 541, 542, 544, 545, 546, + 547, 548, 549, 550, 551, 552, 553, 554, + 555, 556, 557, 558, 560, 561, 562, 563, + 564, 565, 566, 567, 568, 569, 570, 571, + 572, 574, 575, 576, 577, 578, 579, 580, + 581, 582, 583, 584, 585, 587, 588, 589, + 590, 591, 592, 593, 594, 595, 596, 597, + 599, 600, 601, 602, 603, 604, 605, 606, + 607, 608, 610, 611, 612, 613, 614, 615, + 616, 617, 618, 620, 621, 622, 623, 624, + 625, 626, 627, 628, 630, 631, 632, 633, + 634, 635, 636, 637, 639, 640, 641, 642, + 643, 644, 645, 646, 648, 649, 650, 651, + 652, 653, 654, 656, 657, 658, 659, 660, + 661, 662, 664, 665, 666, 667, 668, 669, + 670, 672, 673, 674, 675, 676, 677, 678, + 680, 681, 682, 683, 684, 685, 687, 688, + 689, 690, 691, 692, 693, 695, 696, 697, + 698, 699, 700, 702, 703, 704, 705, 706, + 708, 709, 710, 711, 712, 713, 715, 716, + 717, 718, 719, 720, 722, 723, 724, 725, + 726, 728, 729, 730, 731, 732, 733, 735, + 736, 737, 738, 739, 741, 742, 743, 744, + 745, 747, 748, 749, 750, 751, 753, 754, + 755, 756, 757, 759, 760, 761, 762, 763, + 765, 766, 767, 768, 770, 771, 772, 773, + 774, 776, 777, 778, 779, 780, 782, 783, + 784, 785, 787, 788, 789, 790, 792, 793, + 794, 795, 796, 798, 799, 800, 801, 803, + 804, 805, 806, 808, 809, 810, 811, 813, + 814, 815, 816, 818, 819, 820, 821, 823, + 824, 825, 826, 828, 829, 830, 831, 833, + 834, 835, 836, 838, 839, 840, 841, 843, + 844, 845, 846, 848, 849, 850, 851, 853, + 854, 855, 857, 858, 859, 860, 862, 863, + 864, 866, 867, 868, 869, 871, 872, 873, + 874, 876, 877, 878, 880, 881, 882, 883, + 885, 886, 887, 889, 890, 891, 893, 894, + 895, 896, 898, 899, 900, 902, 903, 904, + 906, 907, 908, 909, 911, 912, 913, 915, + 916, 917, 919, 920, 921, 923, 924, 925, + 927, 928, 929, 931, 932, 933, 935, 936, + 937, 938, 940, 941, 942, 944, 945, 946, + 948, 949, 950, 952, 953, 955, 956, 957, + 959, 960, 961, 963, 964, 965, 967, 968, + 969, 971, 972, 973, 975, 976, 977, 979, + 980, 981, 983, 984, 986, 987, 988, 990, + 991, 992, 994, 995, 996, 998, 999, 1001, + 1002, 1003, 1005, 1006, 1007, 1009, 1010, 1012, + 1013, 1014, 1016, 1017, 1018, 1020, 1021, 1023 +}; + +static const WebRtc_Word16 kIndicatorTable[17] = {0, 2017, 3809, 5227, 6258, 6963, 7424, 7718, + 7901, 8014, 8084, 8126, 8152, 8168, 8177, 8183, 8187}; + +// hybrib Hanning & flat window +static const WebRtc_Word16 kBlocks80w128x[128] = { + 0, 536, 1072, 1606, 2139, 2669, 3196, 3720, 4240, 4756, 5266, + 5771, 6270, 6762, 7246, 7723, 8192, 8652, 9102, 9543, 9974, 10394, + 10803, 11200, 11585, 11958, 12318, 12665, 12998, 13318, 13623, 13913, 14189, + 14449, 14694, 14924, 15137, 15334, 15515, 15679, 15826, 15956, 16069, 16165, + 16244, 16305, 16349, 16375, 16384, 16384, 16384, 16384, 16384, 16384, 16384, + 16384, 16384, 16384, 16384, 16384, 16384, 16384, 16384, 16384, 16384, 16384, + 16384, 16384, 16384, 16384, 16384, 16384, 16384, 16384, 16384, 16384, 16384, + 16384, 16384, 16384, 16384, 16375, 16349, 16305, 16244, 16165, 16069, 15956, + 15826, 15679, 15515, 15334, 15137, 14924, 14694, 14449, 14189, 13913, 13623, + 13318, 12998, 12665, 12318, 11958, 11585, 11200, 10803, 10394, 9974, 9543, + 9102, 8652, 8192, 7723, 7246, 6762, 6270, 5771, 5266, 4756, 4240, + 3720, 3196, 2669, 2139, 1606, 1072, 536 +}; + +// hybrib Hanning & flat window +static const WebRtc_Word16 kBlocks160w256x[256] = { + 0, 268, 536, 804, 1072, 1339, 1606, 1872, + 2139, 2404, 2669, 2933, 3196, 3459, 3720, 3981, + 4240, 4499, 4756, 5012, 5266, 5520, 5771, 6021, + 6270, 6517, 6762, 7005, 7246, 7486, 7723, 7959, + 8192, 8423, 8652, 8878, 9102, 9324, 9543, 9760, + 9974, 10185, 10394, 10600, 10803, 11003, 11200, 11394, +11585, 11773, 11958, 12140, 12318, 12493, 12665, 12833, +12998, 13160, 13318, 13472, 13623, 13770, 13913, 14053, +14189, 14321, 14449, 14574, 14694, 14811, 14924, 15032, +15137, 15237, 15334, 15426, 15515, 15599, 15679, 15754, +15826, 15893, 15956, 16015, 16069, 16119, 16165, 16207, +16244, 16277, 16305, 16329, 16349, 16364, 16375, 16382, +16384, 16384, 16384, 16384, 16384, 16384, 16384, 16384, +16384, 16384, 16384, 16384, 16384, 16384, 16384, 16384, +16384, 16384, 16384, 16384, 16384, 16384, 16384, 16384, +16384, 16384, 16384, 16384, 16384, 16384, 16384, 16384, +16384, 16384, 16384, 16384, 16384, 16384, 16384, 16384, +16384, 16384, 16384, 16384, 16384, 16384, 16384, 16384, +16384, 16384, 16384, 16384, 16384, 16384, 16384, 16384, +16384, 16384, 16384, 16384, 16384, 16384, 16384, 16384, +16384, 16382, 16375, 16364, 16349, 16329, 16305, 16277, +16244, 16207, 16165, 16119, 16069, 16015, 15956, 15893, +15826, 15754, 15679, 15599, 15515, 15426, 15334, 15237, +15137, 15032, 14924, 14811, 14694, 14574, 14449, 14321, +14189, 14053, 13913, 13770, 13623, 13472, 13318, 13160, +12998, 12833, 12665, 12493, 12318, 12140, 11958, 11773, +11585, 11394, 11200, 11003, 10803, 10600, 10394, 10185, + 9974, 9760, 9543, 9324, 9102, 8878, 8652, 8423, + 8192, 7959, 7723, 7486, 7246, 7005, 6762, 6517, + 6270, 6021, 5771, 5520, 5266, 5012, 4756, 4499, + 4240, 3981, 3720, 3459, 3196, 2933, 2669, 2404, + 2139, 1872, 1606, 1339, 1072, 804, 536, 268 +}; + +// Gain factor table: Input value in Q8 and output value in Q13 +static const WebRtc_Word16 kFactor1Table[257] = { + 8192, 8192, 8192, 8192, 8192, 8192, 8192, + 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, + 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, + 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, + 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, + 8192, 8192, 8233, 8274, 8315, 8355, 8396, 8436, 8475, 8515, 8554, 8592, 8631, 8669, + 8707, 8745, 8783, 8820, 8857, 8894, 8931, 8967, 9003, 9039, 9075, 9111, 9146, 9181, + 9216, 9251, 9286, 9320, 9354, 9388, 9422, 9456, 9489, 9523, 9556, 9589, 9622, 9655, + 9687, 9719, 9752, 9784, 9816, 9848, 9879, 9911, 9942, 9973, 10004, 10035, 10066, + 10097, 10128, 10158, 10188, 10218, 10249, 10279, 10308, 10338, 10368, 10397, 10426, + 10456, 10485, 10514, 10543, 10572, 10600, 10629, 10657, 10686, 10714, 10742, 10770, + 10798, 10826, 10854, 10882, 10847, 10810, 10774, 10737, 10701, 10666, 10631, 10596, + 10562, 10527, 10494, 10460, 10427, 10394, 10362, 10329, 10297, 10266, 10235, 10203, + 10173, 10142, 10112, 10082, 10052, 10023, 9994, 9965, 9936, 9908, 9879, 9851, 9824, + 9796, 9769, 9742, 9715, 9689, 9662, 9636, 9610, 9584, 9559, 9534, 9508, 9484, 9459, + 9434, 9410, 9386, 9362, 9338, 9314, 9291, 9268, 9245, 9222, 9199, 9176, 9154, 9132, + 9110, 9088, 9066, 9044, 9023, 9002, 8980, 8959, 8939, 8918, 8897, 8877, 8857, 8836, + 8816, 8796, 8777, 8757, 8738, 8718, 8699, 8680, 8661, 8642, 8623, 8605, 8586, 8568, + 8550, 8532, 8514, 8496, 8478, 8460, 8443, 8425, 8408, 8391, 8373, 8356, 8339, 8323, + 8306, 8289, 8273, 8256, 8240, 8224, 8208, 8192 +}; + +// Gain factor table: Input value in Q8 and output value in Q13 +static const WebRtc_Word16 kFactor2Aggressiveness1[257] = { + 7577, 7577, 7577, 7577, 7577, 7577, + 7577, 7577, 7577, 7577, 7577, 7577, 7577, 7577, 7577, 7577, 7577, 7596, 7614, 7632, + 7650, 7667, 7683, 7699, 7715, 7731, 7746, 7761, 7775, 7790, 7804, 7818, 7832, 7845, + 7858, 7871, 7884, 7897, 7910, 7922, 7934, 7946, 7958, 7970, 7982, 7993, 8004, 8016, + 8027, 8038, 8049, 8060, 8070, 8081, 8091, 8102, 8112, 8122, 8132, 8143, 8152, 8162, + 8172, 8182, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, + 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, + 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, + 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, + 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, + 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, + 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, + 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, + 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, + 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, + 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, + 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, + 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, + 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192 +}; + +// Gain factor table: Input value in Q8 and output value in Q13 +static const WebRtc_Word16 kFactor2Aggressiveness2[257] = { + 7270, 7270, 7270, 7270, 7270, 7306, + 7339, 7369, 7397, 7424, 7448, 7472, 7495, 7517, 7537, 7558, 7577, 7596, 7614, 7632, + 7650, 7667, 7683, 7699, 7715, 7731, 7746, 7761, 7775, 7790, 7804, 7818, 7832, 7845, + 7858, 7871, 7884, 7897, 7910, 7922, 7934, 7946, 7958, 7970, 7982, 7993, 8004, 8016, + 8027, 8038, 8049, 8060, 8070, 8081, 8091, 8102, 8112, 8122, 8132, 8143, 8152, 8162, + 8172, 8182, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, + 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, + 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, + 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, + 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, + 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, + 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, + 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, + 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, + 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, + 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, + 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, + 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, + 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192 +}; + +// Gain factor table: Input value in Q8 and output value in Q13 +static const WebRtc_Word16 kFactor2Aggressiveness3[257] = { + 7184, 7184, 7184, 7229, 7270, 7306, + 7339, 7369, 7397, 7424, 7448, 7472, 7495, 7517, 7537, 7558, 7577, 7596, 7614, 7632, + 7650, 7667, 7683, 7699, 7715, 7731, 7746, 7761, 7775, 7790, 7804, 7818, 7832, 7845, + 7858, 7871, 7884, 7897, 7910, 7922, 7934, 7946, 7958, 7970, 7982, 7993, 8004, 8016, + 8027, 8038, 8049, 8060, 8070, 8081, 8091, 8102, 8112, 8122, 8132, 8143, 8152, 8162, + 8172, 8182, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, + 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, + 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, + 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, + 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, + 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, + 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, + 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, + 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, + 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, + 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, + 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, + 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, + 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192, 8192 +}; + +// sum of log2(i) from table index to inst->anaLen2 in Q5 +// Note that the first table value is invalid, since log2(0) = -infinity +static const WebRtc_Word16 kSumLogIndex[66] = { + 0, 22917, 22917, 22885, 22834, 22770, 22696, 22613, + 22524, 22428, 22326, 22220, 22109, 21994, 21876, 21754, + 21629, 21501, 21370, 21237, 21101, 20963, 20822, 20679, + 20535, 20388, 20239, 20089, 19937, 19783, 19628, 19470, + 19312, 19152, 18991, 18828, 18664, 18498, 18331, 18164, + 17994, 17824, 17653, 17480, 17306, 17132, 16956, 16779, + 16602, 16423, 16243, 16063, 15881, 15699, 15515, 15331, + 15146, 14960, 14774, 14586, 14398, 14209, 14019, 13829, + 13637, 13445 +}; + +// sum of log2(i)^2 from table index to inst->anaLen2 in Q2 +// Note that the first table value is invalid, since log2(0) = -infinity +static const WebRtc_Word16 kSumSquareLogIndex[66] = { + 0, 16959, 16959, 16955, 16945, 16929, 16908, 16881, + 16850, 16814, 16773, 16729, 16681, 16630, 16575, 16517, + 16456, 16392, 16325, 16256, 16184, 16109, 16032, 15952, + 15870, 15786, 15700, 15612, 15521, 15429, 15334, 15238, + 15140, 15040, 14938, 14834, 14729, 14622, 14514, 14404, + 14292, 14179, 14064, 13947, 13830, 13710, 13590, 13468, + 13344, 13220, 13094, 12966, 12837, 12707, 12576, 12444, + 12310, 12175, 12039, 11902, 11763, 11624, 11483, 11341, + 11198, 11054 +}; + +// log2(table index) in Q12 +// Note that the first table value is invalid, since log2(0) = -infinity +static const WebRtc_Word16 kLogIndex[129] = { + 0, 0, 4096, 6492, 8192, 9511, 10588, 11499, + 12288, 12984, 13607, 14170, 14684, 15157, 15595, 16003, + 16384, 16742, 17080, 17400, 17703, 17991, 18266, 18529, + 18780, 19021, 19253, 19476, 19691, 19898, 20099, 20292, + 20480, 20662, 20838, 21010, 21176, 21338, 21496, 21649, + 21799, 21945, 22087, 22226, 22362, 22495, 22625, 22752, + 22876, 22998, 23117, 23234, 23349, 23462, 23572, 23680, + 23787, 23892, 23994, 24095, 24195, 24292, 24388, 24483, + 24576, 24668, 24758, 24847, 24934, 25021, 25106, 25189, + 25272, 25354, 25434, 25513, 25592, 25669, 25745, 25820, + 25895, 25968, 26041, 26112, 26183, 26253, 26322, 26390, + 26458, 26525, 26591, 26656, 26721, 26784, 26848, 26910, + 26972, 27033, 27094, 27154, 27213, 27272, 27330, 27388, + 27445, 27502, 27558, 27613, 27668, 27722, 27776, 27830, + 27883, 27935, 27988, 28039, 28090, 28141, 28191, 28241, + 28291, 28340, 28388, 28437, 28484, 28532, 28579, 28626, + 28672 +}; + +// determinant of estimation matrix in Q0 corresponding to the log2 tables above +// Note that the first table value is invalid, since log2(0) = -infinity +static const WebRtc_Word16 kDeterminantEstMatrix[66] = { + 0, 29814, 25574, 22640, 20351, 18469, 16873, 15491, + 14277, 13199, 12233, 11362, 10571, 9851, 9192, 8587, + 8030, 7515, 7038, 6596, 6186, 5804, 5448, 5115, + 4805, 4514, 4242, 3988, 3749, 3524, 3314, 3116, + 2930, 2755, 2590, 2435, 2289, 2152, 2022, 1900, + 1785, 1677, 1575, 1478, 1388, 1302, 1221, 1145, + 1073, 1005, 942, 881, 825, 771, 721, 674, + 629, 587, 547, 510, 475, 442, 411, 382, + 355, 330 +}; + +void WebRtcNsx_UpdateNoiseEstimate(NsxInst_t *inst, int offset) +{ + WebRtc_Word32 tmp32no1 = 0; + WebRtc_Word32 tmp32no2 = 0; + + WebRtc_Word16 tmp16no1 = 0; + WebRtc_Word16 tmp16no2 = 0; + WebRtc_Word16 exp2Const = 11819; // Q13 + + int i = 0; + + tmp16no2 = WebRtcSpl_MaxValueW16(inst->noiseEstLogQuantile + offset, inst->magnLen); + inst->qNoise = 14 + - (int)WEBRTC_SPL_MUL_16_16_RSFT_WITH_ROUND(exp2Const, tmp16no2, 21); + for (i = 0; i < inst->magnLen; i++) + { + // inst->quantile[i]=exp(inst->lquantile[offset+i]); + // in Q21 + tmp32no2 = WEBRTC_SPL_MUL_16_16(exp2Const, inst->noiseEstLogQuantile[offset + i]); + tmp32no1 = (0x00200000 | (tmp32no2 & 0x001FFFFF)); + tmp16no1 = -(WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32(tmp32no2, 21); + tmp16no1 += 21;// shift 21 to get result in Q0 + tmp16no1 -= (WebRtc_Word16)inst->qNoise; //shift to get result in Q(qNoise) + if (tmp16no1 > 0) + { + inst->noiseEstQuantile[i] = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32(tmp32no1 + + kRoundTable[tmp16no1], tmp16no1); + } + else + { + inst->noiseEstQuantile[i] = (WebRtc_Word16)WEBRTC_SPL_LSHIFT_W32(tmp32no1, + -tmp16no1); + } + } +} + +void WebRtcNsx_CalcParametricNoiseEstimate(NsxInst_t *inst, + WebRtc_Word16 pink_noise_exp_avg, + WebRtc_Word32 pink_noise_num_avg, + int freq_index, + WebRtc_UWord32 *noise_estimate, + WebRtc_UWord32 *noise_estimate_avg) +{ + WebRtc_Word32 tmp32no1 = 0; + WebRtc_Word32 tmp32no2 = 0; + + WebRtc_Word16 int_part = 0; + WebRtc_Word16 frac_part = 0; + + // Use pink noise estimate + // noise_estimate = 2^(pinkNoiseNumerator + pinkNoiseExp * log2(j)) + assert(freq_index > 0); + tmp32no2 = WEBRTC_SPL_MUL_16_16(pink_noise_exp_avg, kLogIndex[freq_index]); // Q26 + tmp32no2 = WEBRTC_SPL_RSHIFT_W32(tmp32no2, 15); // Q11 + tmp32no1 = pink_noise_num_avg - tmp32no2; // Q11 + + // Calculate output: 2^tmp32no1 + // Output in Q(minNorm-stages) + tmp32no1 += WEBRTC_SPL_LSHIFT_W32((WebRtc_Word32)(inst->minNorm - inst->stages), 11); + if (tmp32no1 > 0) + { + int_part = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32(tmp32no1, 11); + frac_part = (WebRtc_Word16)(tmp32no1 & 0x000007ff); // Q11 + // Piecewise linear approximation of 'b' in + // 2^(int_part+frac_part) = 2^int_part * (1 + b) + // 'b' is given in Q11 and below stored in frac_part. + if (WEBRTC_SPL_RSHIFT_W32(frac_part, 10)) + { + // Upper fractional part + tmp32no2 = WEBRTC_SPL_MUL_32_16(2048 - frac_part, 1244); // Q21 + tmp32no2 = 2048 - WEBRTC_SPL_RSHIFT_W32(tmp32no2, 10); + } + else + { + // Lower fractional part + tmp32no2 = WEBRTC_SPL_RSHIFT_W32(WEBRTC_SPL_MUL_32_16(frac_part, 804), 10); + } + // Shift fractional part to Q(minNorm-stages) + tmp32no2 = WEBRTC_SPL_SHIFT_W32(tmp32no2, int_part - 11); + *noise_estimate_avg = WEBRTC_SPL_LSHIFT_U32(1, int_part) + (WebRtc_UWord32)tmp32no2; + // Scale up to initMagnEst, which is not block averaged + *noise_estimate = (*noise_estimate_avg) * (WebRtc_UWord32)(inst->blockIndex + 1); + } +} + +// Initialize state +WebRtc_Word32 WebRtcNsx_InitCore(NsxInst_t *inst, WebRtc_UWord32 fs) +{ + int i; + + //check for valid pointer + if (inst == NULL) + { + return -1; + } + // + + // Initialization of struct + if (fs == 8000 || fs == 16000 || fs == 32000) + { + inst->fs = fs; + } else + { + return -1; + } + + if (fs == 8000) + { + inst->blockLen10ms = 80; + inst->anaLen = 128; + inst->stages = 7; + inst->window = kBlocks80w128x; + inst->thresholdLogLrt = 131072; //default threshold for LRT feature + inst->maxLrt = 0x0040000; + inst->minLrt = 52429; + } else if (fs == 16000) + { + inst->blockLen10ms = 160; + inst->anaLen = 256; + inst->stages = 8; + inst->window = kBlocks160w256x; + inst->thresholdLogLrt = 212644; //default threshold for LRT feature + inst->maxLrt = 0x0080000; + inst->minLrt = 104858; + } else if (fs == 32000) + { + inst->blockLen10ms = 160; + inst->anaLen = 256; + inst->stages = 8; + inst->window = kBlocks160w256x; + inst->thresholdLogLrt = 212644; //default threshold for LRT feature + inst->maxLrt = 0x0080000; + inst->minLrt = 104858; + } + inst->anaLen2 = WEBRTC_SPL_RSHIFT_W16(inst->anaLen, 1); + inst->magnLen = inst->anaLen2 + 1; + + WebRtcSpl_ZerosArrayW16(inst->analysisBuffer, ANAL_BLOCKL_MAX); + WebRtcSpl_ZerosArrayW16(inst->synthesisBuffer, ANAL_BLOCKL_MAX); + + // for HB processing + WebRtcSpl_ZerosArrayW16(inst->dataBufHBFX, ANAL_BLOCKL_MAX); + // for quantile noise estimation + WebRtcSpl_ZerosArrayW16(inst->noiseEstQuantile, HALF_ANAL_BLOCKL); + for (i = 0; i < SIMULT * HALF_ANAL_BLOCKL; i++) + { + inst->noiseEstLogQuantile[i] = 2048; // Q8 + inst->noiseEstDensity[i] = 153; // Q9 + } + for (i = 0; i < SIMULT; i++) + { + inst->noiseEstCounter[i] = (WebRtc_Word16)(END_STARTUP_LONG * (i + 1)) / SIMULT; + } + + // Initialize suppression filter with ones + WebRtcSpl_MemSetW16((WebRtc_Word16*)inst->noiseSupFilter, 16384, HALF_ANAL_BLOCKL); + + // Set the aggressiveness: default + inst->aggrMode = 0; + + //initialize variables for new method + inst->priorNonSpeechProb = 8192; // Q14(0.5) prior probability for speech/noise + for (i = 0; i < HALF_ANAL_BLOCKL; i++) + { + inst->prevMagnU16[i] = 0; + inst->prevNoiseU32[i] = 0; //previous noise-spectrum + inst->logLrtTimeAvgW32[i] = 0; //smooth LR ratio + inst->avgMagnPause[i] = 0; //conservative noise spectrum estimate + inst->initMagnEst[i] = 0; //initial average magnitude spectrum + } + + //feature quantities + inst->thresholdSpecDiff = 50; //threshold for difference feature: determined on-line + inst->thresholdSpecFlat = 20480; //threshold for flatness: determined on-line + inst->featureLogLrt = inst->thresholdLogLrt; //average LRT factor (= threshold) + inst->featureSpecFlat = inst->thresholdSpecFlat; //spectral flatness (= threshold) + inst->featureSpecDiff = inst->thresholdSpecDiff; //spectral difference (= threshold) + inst->weightLogLrt = 6; //default weighting par for LRT feature + inst->weightSpecFlat = 0; //default weighting par for spectral flatness feature + inst->weightSpecDiff = 0; //default weighting par for spectral difference feature + + inst->curAvgMagnEnergy = 0; //window time-average of input magnitude spectrum + inst->timeAvgMagnEnergy = 0; //normalization for spectral difference + inst->timeAvgMagnEnergyTmp = 0; //normalization for spectral difference + + //histogram quantities: used to estimate/update thresholds for features + WebRtcSpl_ZerosArrayW16(inst->histLrt, HIST_PAR_EST); + WebRtcSpl_ZerosArrayW16(inst->histSpecDiff, HIST_PAR_EST); + WebRtcSpl_ZerosArrayW16(inst->histSpecFlat, HIST_PAR_EST); + + inst->blockIndex = -1; //frame counter + + //inst->modelUpdate = 500; //window for update + inst->modelUpdate = (1 << STAT_UPDATES); //window for update + inst->cntThresUpdate = 0; //counter feature thresholds updates + + inst->sumMagn = 0; + inst->magnEnergy = 0; + inst->prevQMagn = 0; + inst->qNoise = 0; + inst->prevQNoise = 0; + + inst->energyIn = 0; + inst->scaleEnergyIn = 0; + + inst->whiteNoiseLevel = 0; + inst->pinkNoiseNumerator = 0; + inst->pinkNoiseExp = 0; + inst->minNorm = 15; // Start with full scale + inst->zeroInputSignal = 0; + + //default mode + WebRtcNsx_set_policy_core(inst, 0); + +#ifdef NS_FILEDEBUG + inst->infile=fopen("indebug.pcm","wb"); + inst->outfile=fopen("outdebug.pcm","wb"); + inst->file1=fopen("file1.pcm","wb"); + inst->file2=fopen("file2.pcm","wb"); + inst->file3=fopen("file3.pcm","wb"); + inst->file4=fopen("file4.pcm","wb"); + inst->file5=fopen("file5.pcm","wb"); +#endif + + inst->initFlag = 1; + + return 0; +} + +int WebRtcNsx_set_policy_core(NsxInst_t *inst, int mode) +{ + // allow for modes:0,1,2,3 + if (mode < 0 || mode > 3) + { + return -1; + } + + inst->aggrMode = mode; + if (mode == 0) + { + inst->overdrive = 256; // Q8(1.0) + inst->denoiseBound = 8192; // Q14(0.5) + inst->gainMap = 0; // No gain compensation + } else if (mode == 1) + { + inst->overdrive = 256; // Q8(1.0) + inst->denoiseBound = 4096; // Q14(0.25) + inst->factor2Table = kFactor2Aggressiveness1; + inst->gainMap = 1; + } else if (mode == 2) + { + inst->overdrive = 282; // ~= Q8(1.1) + inst->denoiseBound = 2048; // Q14(0.125) + inst->factor2Table = kFactor2Aggressiveness2; + inst->gainMap = 1; + } else if (mode == 3) + { + inst->overdrive = 320; // Q8(1.25) + inst->denoiseBound = 1475; // ~= Q14(0.09) + inst->factor2Table = kFactor2Aggressiveness3; + inst->gainMap = 1; + } + return 0; +} + +#if !(defined(WEBRTC_ARCH_ARM_NEON) && defined(WEBRTC_ANDROID)) +void WebRtcNsx_NoiseEstimation(NsxInst_t *inst, WebRtc_UWord16 *magn, WebRtc_UWord32 *noise, + WebRtc_Word16 *qNoise) +{ + WebRtc_Word32 numerator; + + WebRtc_Word16 lmagn[HALF_ANAL_BLOCKL], counter, countDiv, countProd, delta, zeros, frac; + WebRtc_Word16 log2, tabind, logval, tmp16, tmp16no1, tmp16no2; + WebRtc_Word16 log2Const = 22713; // Q15 + WebRtc_Word16 widthFactor = 21845; + + int i, s, offset; + + numerator = FACTOR_Q16; + + tabind = inst->stages - inst->normData; + if (tabind < 0) + { + logval = -WebRtcNsx_kLogTable[-tabind]; + } else + { + logval = WebRtcNsx_kLogTable[tabind]; + } + + // lmagn(i)=log(magn(i))=log(2)*log2(magn(i)) + // magn is in Q(-stages), and the real lmagn values are: + // real_lmagn(i)=log(magn(i)*2^stages)=log(magn(i))+log(2^stages) + // lmagn in Q8 + for (i = 0; i < inst->magnLen; i++) + { + if (magn[i]) + { + zeros = WebRtcSpl_NormU32((WebRtc_UWord32)magn[i]); + frac = (WebRtc_Word16)((((WebRtc_UWord32)magn[i] << zeros) & 0x7FFFFFFF) >> 23); + // log2(magn(i)) + log2 = (WebRtc_Word16)(((31 - zeros) << 8) + WebRtcNsx_kLogTableFrac[frac]); + // log2(magn(i))*log(2) + lmagn[i] = (WebRtc_Word16)WEBRTC_SPL_MUL_16_16_RSFT(log2, log2Const, 15); + // + log(2^stages) + lmagn[i] += logval; + } else + { + lmagn[i] = logval;//0; + } + } + + // loop over simultaneous estimates + for (s = 0; s < SIMULT; s++) + { + offset = s * inst->magnLen; + + // Get counter values from state + counter = inst->noiseEstCounter[s]; + countDiv = WebRtcNsx_kCounterDiv[counter]; + countProd = (WebRtc_Word16)WEBRTC_SPL_MUL_16_16(counter, countDiv); + + // quant_est(...) + for (i = 0; i < inst->magnLen; i++) + { + // compute delta + if (inst->noiseEstDensity[offset + i] > 512) + { + delta = WebRtcSpl_DivW32W16ResW16(numerator, + inst->noiseEstDensity[offset + i]); + } else + { + delta = FACTOR_Q7; + } + + // update log quantile estimate + tmp16 = (WebRtc_Word16)WEBRTC_SPL_MUL_16_16_RSFT(delta, countDiv, 14); + if (lmagn[i] > inst->noiseEstLogQuantile[offset + i]) + { + // +=QUANTILE*delta/(inst->counter[s]+1) QUANTILE=0.25, =1 in Q2 + // CounterDiv=1/inst->counter[s] in Q15 + tmp16 += 2; + tmp16no1 = WEBRTC_SPL_RSHIFT_W16(tmp16, 2); + inst->noiseEstLogQuantile[offset + i] += tmp16no1; + } else + { + tmp16 += 1; + tmp16no1 = WEBRTC_SPL_RSHIFT_W16(tmp16, 1); + // *(1-QUANTILE), in Q2 QUANTILE=0.25, 1-0.25=0.75=3 in Q2 + tmp16no2 = (WebRtc_Word16)WEBRTC_SPL_MUL_16_16_RSFT(tmp16no1, 3, 1); + inst->noiseEstLogQuantile[offset + i] -= tmp16no2; + } + + // update density estimate + if (WEBRTC_SPL_ABS_W16(lmagn[i] - inst->noiseEstLogQuantile[offset + i]) + < WIDTH_Q8) + { + tmp16no1 = (WebRtc_Word16)WEBRTC_SPL_MUL_16_16_RSFT_WITH_ROUND( + inst->noiseEstDensity[offset + i], countProd, 15); + tmp16no2 = (WebRtc_Word16)WEBRTC_SPL_MUL_16_16_RSFT_WITH_ROUND(widthFactor, + countDiv, 15); + inst->noiseEstDensity[offset + i] = tmp16no1 + tmp16no2; + } + } // end loop over magnitude spectrum + + if (counter >= END_STARTUP_LONG) + { + inst->noiseEstCounter[s] = 0; + if (inst->blockIndex >= END_STARTUP_LONG) + { + WebRtcNsx_UpdateNoiseEstimate(inst, offset); + } + } + inst->noiseEstCounter[s]++; + + } // end loop over simultaneous estimates + + // Sequentially update the noise during startup + if (inst->blockIndex < END_STARTUP_LONG) + { + WebRtcNsx_UpdateNoiseEstimate(inst, offset); + } + + for (i = 0; i < inst->magnLen; i++) + { + noise[i] = (WebRtc_UWord32)(inst->noiseEstQuantile[i]); // Q(qNoise) + } + (*qNoise) = (WebRtc_Word16)inst->qNoise; +} +#endif // !(defined(WEBRTC_ARCH_ARM_NEON) && defined(WEBRTC_ANDROID)) + +// Extract thresholds for feature parameters +// histograms are computed over some window_size (given by window_pars) +// thresholds and weights are extracted every window +// flag 0 means update histogram only, flag 1 means compute the thresholds/weights +// threshold and weights are returned in: inst->priorModelPars +void WebRtcNsx_FeatureParameterExtraction(NsxInst_t *inst, int flag) +{ + WebRtc_UWord32 tmpU32; + WebRtc_UWord32 histIndex; + WebRtc_UWord32 posPeak1SpecFlatFX, posPeak2SpecFlatFX; + WebRtc_UWord32 posPeak1SpecDiffFX, posPeak2SpecDiffFX; + + WebRtc_Word32 tmp32; + WebRtc_Word32 fluctLrtFX, thresFluctLrtFX; + WebRtc_Word32 avgHistLrtFX, avgSquareHistLrtFX, avgHistLrtComplFX; + + WebRtc_Word16 j; + WebRtc_Word16 numHistLrt; + + int i; + int useFeatureSpecFlat, useFeatureSpecDiff, featureSum; + int maxPeak1, maxPeak2; + int weightPeak1SpecFlat, weightPeak2SpecFlat; + int weightPeak1SpecDiff, weightPeak2SpecDiff; + + //update histograms + if (!flag) + { + // LRT + // Type casting to UWord32 is safe since negative values will not be wrapped to larger + // values than HIST_PAR_EST + histIndex = (WebRtc_UWord32)(inst->featureLogLrt); + if (histIndex < HIST_PAR_EST) + { + inst->histLrt[histIndex]++; + } + // Spectral flatness + // (inst->featureSpecFlat*20)>>10 = (inst->featureSpecFlat*5)>>8 + histIndex = WEBRTC_SPL_RSHIFT_U32(inst->featureSpecFlat * 5, 8); + if (histIndex < HIST_PAR_EST) + { + inst->histSpecFlat[histIndex]++; + } + // Spectral difference + histIndex = HIST_PAR_EST; + if (inst->timeAvgMagnEnergy) + { + // Guard against division by zero + // If timeAvgMagnEnergy == 0 we have no normalizing statistics and therefore can't + // update the histogram + histIndex = WEBRTC_SPL_UDIV((inst->featureSpecDiff * 5) >> inst->stages, + inst->timeAvgMagnEnergy); + } + if (histIndex < HIST_PAR_EST) + { + inst->histSpecDiff[histIndex]++; + } + } + + // extract parameters for speech/noise probability + if (flag) + { + useFeatureSpecDiff = 1; + //for LRT feature: + // compute the average over inst->featureExtractionParams.rangeAvgHistLrt + avgHistLrtFX = 0; + avgSquareHistLrtFX = 0; + numHistLrt = 0; + for (i = 0; i < BIN_SIZE_LRT; i++) + { + j = (2 * i + 1); + tmp32 = WEBRTC_SPL_MUL_16_16(inst->histLrt[i], j); + avgHistLrtFX += tmp32; + numHistLrt += inst->histLrt[i]; + avgSquareHistLrtFX += WEBRTC_SPL_MUL_32_16(tmp32, j); + } + avgHistLrtComplFX = avgHistLrtFX; + for (; i < HIST_PAR_EST; i++) + { + j = (2 * i + 1); + tmp32 = WEBRTC_SPL_MUL_16_16(inst->histLrt[i], j); + avgHistLrtComplFX += tmp32; + avgSquareHistLrtFX += WEBRTC_SPL_MUL_32_16(tmp32, j); + } + fluctLrtFX = WEBRTC_SPL_MUL(avgSquareHistLrtFX, numHistLrt); + fluctLrtFX -= WEBRTC_SPL_MUL(avgHistLrtFX, avgHistLrtComplFX); + thresFluctLrtFX = THRES_FLUCT_LRT * numHistLrt; + // get threshold for LRT feature: + tmpU32 = (FACTOR_1_LRT_DIFF * (WebRtc_UWord32)avgHistLrtFX); + if ((fluctLrtFX < thresFluctLrtFX) || (numHistLrt == 0) || (tmpU32 + > (WebRtc_UWord32)(100 * numHistLrt))) + { + inst->thresholdLogLrt = inst->maxLrt; //very low fluctuation, so likely noise + } else + { + tmp32 = (WebRtc_Word32)((tmpU32 << (9 + inst->stages)) / numHistLrt / 25); + // check if value is within min/max range + inst->thresholdLogLrt = WEBRTC_SPL_SAT(inst->maxLrt, tmp32, inst->minLrt); + } + if (fluctLrtFX < thresFluctLrtFX) + { + // Do not use difference feature if fluctuation of LRT feature is very low: + // most likely just noise state + useFeatureSpecDiff = 0; + } + + // for spectral flatness and spectral difference: compute the main peaks of histogram + maxPeak1 = 0; + maxPeak2 = 0; + posPeak1SpecFlatFX = 0; + posPeak2SpecFlatFX = 0; + weightPeak1SpecFlat = 0; + weightPeak2SpecFlat = 0; + + // peaks for flatness + for (i = 0; i < HIST_PAR_EST; i++) + { + if (inst->histSpecFlat[i] > maxPeak1) + { + // Found new "first" peak + maxPeak2 = maxPeak1; + weightPeak2SpecFlat = weightPeak1SpecFlat; + posPeak2SpecFlatFX = posPeak1SpecFlatFX; + + maxPeak1 = inst->histSpecFlat[i]; + weightPeak1SpecFlat = inst->histSpecFlat[i]; + posPeak1SpecFlatFX = (WebRtc_UWord32)(2 * i + 1); + } else if (inst->histSpecFlat[i] > maxPeak2) + { + // Found new "second" peak + maxPeak2 = inst->histSpecFlat[i]; + weightPeak2SpecFlat = inst->histSpecFlat[i]; + posPeak2SpecFlatFX = (WebRtc_UWord32)(2 * i + 1); + } + } + + // for spectral flatness feature + useFeatureSpecFlat = 1; + // merge the two peaks if they are close + if ((posPeak1SpecFlatFX - posPeak2SpecFlatFX < LIM_PEAK_SPACE_FLAT_DIFF) + && (weightPeak2SpecFlat * LIM_PEAK_WEIGHT_FLAT_DIFF > weightPeak1SpecFlat)) + { + weightPeak1SpecFlat += weightPeak2SpecFlat; + posPeak1SpecFlatFX = (posPeak1SpecFlatFX + posPeak2SpecFlatFX) >> 1; + } + //reject if weight of peaks is not large enough, or peak value too small + if (weightPeak1SpecFlat < THRES_WEIGHT_FLAT_DIFF || posPeak1SpecFlatFX + < THRES_PEAK_FLAT) + { + useFeatureSpecFlat = 0; + } else // if selected, get the threshold + { + // compute the threshold and check if value is within min/max range + inst->thresholdSpecFlat = WEBRTC_SPL_SAT(MAX_FLAT_Q10, FACTOR_2_FLAT_Q10 + * posPeak1SpecFlatFX, MIN_FLAT_Q10); //Q10 + } + // done with flatness feature + + if (useFeatureSpecDiff) + { + //compute two peaks for spectral difference + maxPeak1 = 0; + maxPeak2 = 0; + posPeak1SpecDiffFX = 0; + posPeak2SpecDiffFX = 0; + weightPeak1SpecDiff = 0; + weightPeak2SpecDiff = 0; + // peaks for spectral difference + for (i = 0; i < HIST_PAR_EST; i++) + { + if (inst->histSpecDiff[i] > maxPeak1) + { + // Found new "first" peak + maxPeak2 = maxPeak1; + weightPeak2SpecDiff = weightPeak1SpecDiff; + posPeak2SpecDiffFX = posPeak1SpecDiffFX; + + maxPeak1 = inst->histSpecDiff[i]; + weightPeak1SpecDiff = inst->histSpecDiff[i]; + posPeak1SpecDiffFX = (WebRtc_UWord32)(2 * i + 1); + } else if (inst->histSpecDiff[i] > maxPeak2) + { + // Found new "second" peak + maxPeak2 = inst->histSpecDiff[i]; + weightPeak2SpecDiff = inst->histSpecDiff[i]; + posPeak2SpecDiffFX = (WebRtc_UWord32)(2 * i + 1); + } + } + + // merge the two peaks if they are close + if ((posPeak1SpecDiffFX - posPeak2SpecDiffFX < LIM_PEAK_SPACE_FLAT_DIFF) + && (weightPeak2SpecDiff * LIM_PEAK_WEIGHT_FLAT_DIFF > weightPeak1SpecDiff)) + { + weightPeak1SpecDiff += weightPeak2SpecDiff; + posPeak1SpecDiffFX = (posPeak1SpecDiffFX + posPeak2SpecDiffFX) >> 1; + } + // get the threshold value and check if value is within min/max range + inst->thresholdSpecDiff = WEBRTC_SPL_SAT(MAX_DIFF, FACTOR_1_LRT_DIFF + * posPeak1SpecDiffFX, MIN_DIFF); //5x bigger + //reject if weight of peaks is not large enough + if (weightPeak1SpecDiff < THRES_WEIGHT_FLAT_DIFF) + { + useFeatureSpecDiff = 0; + } + // done with spectral difference feature + } + + // select the weights between the features + // inst->priorModelPars[4] is weight for LRT: always selected + featureSum = 6 / (1 + useFeatureSpecFlat + useFeatureSpecDiff); + inst->weightLogLrt = featureSum; + inst->weightSpecFlat = useFeatureSpecFlat * featureSum; + inst->weightSpecDiff = useFeatureSpecDiff * featureSum; + + // set histograms to zero for next update + WebRtcSpl_ZerosArrayW16(inst->histLrt, HIST_PAR_EST); + WebRtcSpl_ZerosArrayW16(inst->histSpecDiff, HIST_PAR_EST); + WebRtcSpl_ZerosArrayW16(inst->histSpecFlat, HIST_PAR_EST); + } // end of flag == 1 +} + + +// Compute spectral flatness on input spectrum +// magn is the magnitude spectrum +// spectral flatness is returned in inst->featureSpecFlat +void WebRtcNsx_ComputeSpectralFlatness(NsxInst_t *inst, WebRtc_UWord16 *magn) +{ + WebRtc_UWord32 tmpU32; + WebRtc_UWord32 avgSpectralFlatnessNum, avgSpectralFlatnessDen; + + WebRtc_Word32 tmp32; + WebRtc_Word32 currentSpectralFlatness, logCurSpectralFlatness; + + WebRtc_Word16 zeros, frac, intPart; + + int i; + + // for flatness + avgSpectralFlatnessNum = 0; + avgSpectralFlatnessDen = inst->sumMagn - (WebRtc_UWord32)magn[0]; // Q(normData-stages) + + // compute log of ratio of the geometric to arithmetic mean: check for log(0) case + // flatness = exp( sum(log(magn[i]))/N - log(sum(magn[i])/N) ) + // = exp( sum(log(magn[i]))/N ) * N / sum(magn[i]) + // = 2^( sum(log2(magn[i]))/N - (log2(sum(magn[i])) - log2(N)) ) [This is used] + for (i = 1; i < inst->magnLen; i++) + { + // First bin is excluded from spectrum measures. Number of bins is now a power of 2 + if (magn[i]) + { + zeros = WebRtcSpl_NormU32((WebRtc_UWord32)magn[i]); + frac = (WebRtc_Word16)(((WebRtc_UWord32)((WebRtc_UWord32)(magn[i]) << zeros) + & 0x7FFFFFFF) >> 23); + // log2(magn(i)) + tmpU32 = (WebRtc_UWord32)(((31 - zeros) << 8) + + WebRtcNsx_kLogTableFrac[frac]); // Q8 + avgSpectralFlatnessNum += tmpU32; // Q8 + } else + { + //if at least one frequency component is zero, treat separately + tmpU32 = WEBRTC_SPL_UMUL_32_16(inst->featureSpecFlat, SPECT_FLAT_TAVG_Q14); // Q24 + inst->featureSpecFlat -= WEBRTC_SPL_RSHIFT_U32(tmpU32, 14); // Q10 + return; + } + } + //ratio and inverse log: check for case of log(0) + zeros = WebRtcSpl_NormU32(avgSpectralFlatnessDen); + frac = (WebRtc_Word16)(((avgSpectralFlatnessDen << zeros) & 0x7FFFFFFF) >> 23); + // log2(avgSpectralFlatnessDen) + tmp32 = (WebRtc_Word32)(((31 - zeros) << 8) + WebRtcNsx_kLogTableFrac[frac]); // Q8 + logCurSpectralFlatness = (WebRtc_Word32)avgSpectralFlatnessNum; + logCurSpectralFlatness += ((WebRtc_Word32)(inst->stages - 1) << (inst->stages + 7)); // Q(8+stages-1) + logCurSpectralFlatness -= (tmp32 << (inst->stages - 1)); + logCurSpectralFlatness = WEBRTC_SPL_LSHIFT_W32(logCurSpectralFlatness, 10 - inst->stages); // Q17 + tmp32 = (WebRtc_Word32)(0x00020000 | (WEBRTC_SPL_ABS_W32(logCurSpectralFlatness) + & 0x0001FFFF)); //Q17 + intPart = -(WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32(logCurSpectralFlatness, 17); + intPart += 7; // Shift 7 to get the output in Q10 (from Q17 = -17+10) + if (intPart > 0) + { + currentSpectralFlatness = WEBRTC_SPL_RSHIFT_W32(tmp32, intPart); + } else + { + currentSpectralFlatness = WEBRTC_SPL_LSHIFT_W32(tmp32, -intPart); + } + + //time average update of spectral flatness feature + tmp32 = currentSpectralFlatness - (WebRtc_Word32)inst->featureSpecFlat; // Q10 + tmp32 = WEBRTC_SPL_MUL_32_16(SPECT_FLAT_TAVG_Q14, tmp32); // Q24 + inst->featureSpecFlat = (WebRtc_UWord32)((WebRtc_Word32)inst->featureSpecFlat + + WEBRTC_SPL_RSHIFT_W32(tmp32, 14)); // Q10 + // done with flatness feature +} + + +// Compute the difference measure between input spectrum and a template/learned noise spectrum +// magn_tmp is the input spectrum +// the reference/template spectrum is inst->magn_avg_pause[i] +// returns (normalized) spectral difference in inst->featureSpecDiff +void WebRtcNsx_ComputeSpectralDifference(NsxInst_t *inst, WebRtc_UWord16 *magnIn) +{ + // This is to be calculated: + // avgDiffNormMagn = var(magnIn) - cov(magnIn, magnAvgPause)^2 / var(magnAvgPause) + + WebRtc_UWord32 tmpU32no1, tmpU32no2; + WebRtc_UWord32 varMagnUFX, varPauseUFX, avgDiffNormMagnUFX; + + WebRtc_Word32 tmp32no1, tmp32no2; + WebRtc_Word32 avgPauseFX, avgMagnFX, covMagnPauseFX; + WebRtc_Word32 maxPause, minPause; + + WebRtc_Word16 tmp16no1; + + int i, norm32, nShifts; + + avgPauseFX = 0; + maxPause = 0; + minPause = inst->avgMagnPause[0]; // Q(prevQMagn) + // compute average quantities + for (i = 0; i < inst->magnLen; i++) + { + // Compute mean of magn_pause + avgPauseFX += inst->avgMagnPause[i]; // in Q(prevQMagn) + maxPause = WEBRTC_SPL_MAX(maxPause, inst->avgMagnPause[i]); + minPause = WEBRTC_SPL_MIN(minPause, inst->avgMagnPause[i]); + } + // normalize by replacing div of "inst->magnLen" with "inst->stages-1" shifts + avgPauseFX = WEBRTC_SPL_RSHIFT_W32(avgPauseFX, inst->stages - 1); + avgMagnFX = (WebRtc_Word32)WEBRTC_SPL_RSHIFT_U32(inst->sumMagn, inst->stages - 1); + // Largest possible deviation in magnPause for (co)var calculations + tmp32no1 = WEBRTC_SPL_MAX(maxPause - avgPauseFX, avgPauseFX - minPause); + // Get number of shifts to make sure we don't get wrap around in varPause + nShifts = WEBRTC_SPL_MAX(0, 10 + inst->stages - WebRtcSpl_NormW32(tmp32no1)); + + varMagnUFX = 0; + varPauseUFX = 0; + covMagnPauseFX = 0; + for (i = 0; i < inst->magnLen; i++) + { + // Compute var and cov of magn and magn_pause + tmp16no1 = (WebRtc_Word16)((WebRtc_Word32)magnIn[i] - avgMagnFX); + tmp32no2 = inst->avgMagnPause[i] - avgPauseFX; + varMagnUFX += (WebRtc_UWord32)WEBRTC_SPL_MUL_16_16(tmp16no1, tmp16no1); // Q(2*qMagn) + tmp32no1 = WEBRTC_SPL_MUL_32_16(tmp32no2, tmp16no1); // Q(prevQMagn+qMagn) + covMagnPauseFX += tmp32no1; // Q(prevQMagn+qMagn) + tmp32no1 = WEBRTC_SPL_RSHIFT_W32(tmp32no2, nShifts); // Q(prevQMagn-minPause) + varPauseUFX += (WebRtc_UWord32)WEBRTC_SPL_MUL(tmp32no1, tmp32no1); // Q(2*(prevQMagn-minPause)) + } + //update of average magnitude spectrum: Q(-2*stages) and averaging replaced by shifts + inst->curAvgMagnEnergy += WEBRTC_SPL_RSHIFT_U32(inst->magnEnergy, 2 * inst->normData + + inst->stages - 1); + + avgDiffNormMagnUFX = varMagnUFX; // Q(2*qMagn) + if ((varPauseUFX) && (covMagnPauseFX)) + { + tmpU32no1 = (WebRtc_UWord32)WEBRTC_SPL_ABS_W32(covMagnPauseFX); // Q(prevQMagn+qMagn) + norm32 = WebRtcSpl_NormU32(tmpU32no1) - 16; + if (norm32 > 0) + { + tmpU32no1 = WEBRTC_SPL_LSHIFT_U32(tmpU32no1, norm32); // Q(prevQMagn+qMagn+norm32) + } else + { + tmpU32no1 = WEBRTC_SPL_RSHIFT_U32(tmpU32no1, -norm32); // Q(prevQMagn+qMagn+norm32) + } + tmpU32no2 = WEBRTC_SPL_UMUL(tmpU32no1, tmpU32no1); // Q(2*(prevQMagn+qMagn-norm32)) + + nShifts += norm32; + nShifts <<= 1; + if (nShifts < 0) + { + varPauseUFX >>= (-nShifts); // Q(2*(qMagn+norm32+minPause)) + nShifts = 0; + } + tmpU32no1 = WEBRTC_SPL_UDIV(tmpU32no2, varPauseUFX); // Q(2*(qMagn+norm32-16+minPause)) + tmpU32no1 = WEBRTC_SPL_RSHIFT_U32(tmpU32no1, nShifts); + + avgDiffNormMagnUFX -= WEBRTC_SPL_MIN(avgDiffNormMagnUFX, tmpU32no1); // Q(2*qMagn) + } + //normalize and compute time average update of difference feature + tmpU32no1 = WEBRTC_SPL_RSHIFT_U32(avgDiffNormMagnUFX, 2 * inst->normData); + if (inst->featureSpecDiff > tmpU32no1) + { + tmpU32no2 = WEBRTC_SPL_UMUL_32_16(inst->featureSpecDiff - tmpU32no1, + SPECT_DIFF_TAVG_Q8); // Q(8-2*stages) + inst->featureSpecDiff -= WEBRTC_SPL_RSHIFT_U32(tmpU32no2, 8); // Q(-2*stages) + } else + { + tmpU32no2 = WEBRTC_SPL_UMUL_32_16(tmpU32no1 - inst->featureSpecDiff, + SPECT_DIFF_TAVG_Q8); // Q(8-2*stages) + inst->featureSpecDiff += WEBRTC_SPL_RSHIFT_U32(tmpU32no2, 8); // Q(-2*stages) + } +} + +// Compute speech/noise probability +// speech/noise probability is returned in: probSpeechFinal +//snrLocPrior is the prior SNR for each frequency (in Q11) +//snrLocPost is the post SNR for each frequency (in Q11) +void WebRtcNsx_SpeechNoiseProb(NsxInst_t *inst, WebRtc_UWord16 *nonSpeechProbFinal, + WebRtc_UWord32 *priorLocSnr, WebRtc_UWord32 *postLocSnr) +{ + WebRtc_UWord32 zeros, num, den, tmpU32no1, tmpU32no2, tmpU32no3; + + WebRtc_Word32 invLrtFX, indPriorFX, tmp32, tmp32no1, tmp32no2, besselTmpFX32; + WebRtc_Word32 frac32, logTmp; + WebRtc_Word32 logLrtTimeAvgKsumFX; + + WebRtc_Word16 indPriorFX16; + WebRtc_Word16 tmp16, tmp16no1, tmp16no2, tmpIndFX, tableIndex, frac, intPart; + + int i, normTmp, normTmp2, nShifts; + + // compute feature based on average LR factor + // this is the average over all frequencies of the smooth log LRT + logLrtTimeAvgKsumFX = 0; + for (i = 0; i < inst->magnLen; i++) + { + besselTmpFX32 = (WebRtc_Word32)postLocSnr[i]; // Q11 + normTmp = WebRtcSpl_NormU32(postLocSnr[i]); + num = WEBRTC_SPL_LSHIFT_U32(postLocSnr[i], normTmp); // Q(11+normTmp) + if (normTmp > 10) + { + den = WEBRTC_SPL_LSHIFT_U32(priorLocSnr[i], normTmp - 11); // Q(normTmp) + } else + { + den = WEBRTC_SPL_RSHIFT_U32(priorLocSnr[i], 11 - normTmp); // Q(normTmp) + } + besselTmpFX32 -= WEBRTC_SPL_UDIV(num, den); // Q11 + + // inst->logLrtTimeAvg[i] += LRT_TAVG * (besselTmp - log(snrLocPrior) - inst->logLrtTimeAvg[i]); + // Here, LRT_TAVG = 0.5 + zeros = WebRtcSpl_NormU32(priorLocSnr[i]); + frac32 = (WebRtc_Word32)(((priorLocSnr[i] << zeros) & 0x7FFFFFFF) >> 19); + tmp32 = WEBRTC_SPL_MUL(frac32, frac32); + tmp32 = WEBRTC_SPL_RSHIFT_W32(WEBRTC_SPL_MUL(tmp32, -43), 19); + tmp32 += WEBRTC_SPL_MUL_16_16_RSFT((WebRtc_Word16)frac32, 5412, 12); + frac32 = tmp32 + 37; + // tmp32 = log2(priorLocSnr[i]) + tmp32 = (WebRtc_Word32)(((31 - zeros) << 12) + frac32) - (11 << 12); // Q12 + logTmp = WEBRTC_SPL_RSHIFT_W32(WEBRTC_SPL_MUL_32_16(tmp32, 178), 8); // log2(priorLocSnr[i])*log(2) + tmp32no1 = WEBRTC_SPL_RSHIFT_W32(logTmp + inst->logLrtTimeAvgW32[i], 1); // Q12 + inst->logLrtTimeAvgW32[i] += (besselTmpFX32 - tmp32no1); // Q12 + + logLrtTimeAvgKsumFX += inst->logLrtTimeAvgW32[i]; // Q12 + } + inst->featureLogLrt = WEBRTC_SPL_RSHIFT_W32(logLrtTimeAvgKsumFX * 5, inst->stages + 10); // 5 = BIN_SIZE_LRT / 2 + // done with computation of LR factor + + // + //compute the indicator functions + // + + // average LRT feature + // FLOAT code + // indicator0 = 0.5 * (tanh(widthPrior * (logLrtTimeAvgKsum - threshPrior0)) + 1.0); + tmpIndFX = 16384; // Q14(1.0) + tmp32no1 = logLrtTimeAvgKsumFX - inst->thresholdLogLrt; // Q12 + nShifts = 7 - inst->stages; // WIDTH_PR_MAP_SHIFT - inst->stages + 5; + //use larger width in tanh map for pause regions + if (tmp32no1 < 0) + { + tmpIndFX = 0; + tmp32no1 = -tmp32no1; + //widthPrior = widthPrior * 2.0; + nShifts++; + } + tmp32no1 = WEBRTC_SPL_SHIFT_W32(tmp32no1, nShifts); // Q14 + // compute indicator function: sigmoid map + tableIndex = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32(tmp32no1, 14); + if ((tableIndex < 16) && (tableIndex >= 0)) + { + tmp16no2 = kIndicatorTable[tableIndex]; + tmp16no1 = kIndicatorTable[tableIndex + 1] - kIndicatorTable[tableIndex]; + frac = (WebRtc_Word16)(tmp32no1 & 0x00003fff); // Q14 + tmp16no2 += (WebRtc_Word16)WEBRTC_SPL_MUL_16_16_RSFT(tmp16no1, frac, 14); + if (tmpIndFX == 0) + { + tmpIndFX = 8192 - tmp16no2; // Q14 + } else + { + tmpIndFX = 8192 + tmp16no2; // Q14 + } + } + indPriorFX = WEBRTC_SPL_MUL_16_16(inst->weightLogLrt, tmpIndFX); // 6*Q14 + + //spectral flatness feature + if (inst->weightSpecFlat) + { + tmpU32no1 = WEBRTC_SPL_UMUL(inst->featureSpecFlat, 400); // Q10 + tmpIndFX = 16384; // Q14(1.0) + //use larger width in tanh map for pause regions + tmpU32no2 = inst->thresholdSpecFlat - tmpU32no1; //Q10 + nShifts = 4; + if (inst->thresholdSpecFlat < tmpU32no1) + { + tmpIndFX = 0; + tmpU32no2 = tmpU32no1 - inst->thresholdSpecFlat; + //widthPrior = widthPrior * 2.0; + nShifts++; + } + tmp32no1 = (WebRtc_Word32)WebRtcSpl_DivU32U16(WEBRTC_SPL_LSHIFT_U32(tmpU32no2, + nShifts), 25); //Q14 + tmpU32no1 = WebRtcSpl_DivU32U16(WEBRTC_SPL_LSHIFT_U32(tmpU32no2, nShifts), 25); //Q14 + // compute indicator function: sigmoid map + // FLOAT code + // indicator1 = 0.5 * (tanh(sgnMap * widthPrior * (threshPrior1 - tmpFloat1)) + 1.0); + tableIndex = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_U32(tmpU32no1, 14); + if (tableIndex < 16) + { + tmp16no2 = kIndicatorTable[tableIndex]; + tmp16no1 = kIndicatorTable[tableIndex + 1] - kIndicatorTable[tableIndex]; + frac = (WebRtc_Word16)(tmpU32no1 & 0x00003fff); // Q14 + tmp16no2 += (WebRtc_Word16)WEBRTC_SPL_MUL_16_16_RSFT(tmp16no1, frac, 14); + if (tmpIndFX) + { + tmpIndFX = 8192 + tmp16no2; // Q14 + } else + { + tmpIndFX = 8192 - tmp16no2; // Q14 + } + } + indPriorFX += WEBRTC_SPL_MUL_16_16(inst->weightSpecFlat, tmpIndFX); // 6*Q14 + } + + //for template spectral-difference + if (inst->weightSpecDiff) + { + tmpU32no1 = 0; + if (inst->featureSpecDiff) + { + normTmp = WEBRTC_SPL_MIN(20 - inst->stages, + WebRtcSpl_NormU32(inst->featureSpecDiff)); + tmpU32no1 = WEBRTC_SPL_LSHIFT_U32(inst->featureSpecDiff, normTmp); // Q(normTmp-2*stages) + tmpU32no2 = WEBRTC_SPL_RSHIFT_U32(inst->timeAvgMagnEnergy, 20 - inst->stages + - normTmp); + if (tmpU32no2) + { + tmpU32no1 = WEBRTC_SPL_UDIV(tmpU32no1, tmpU32no2); // Q14?? Q(20 - inst->stages) + } else + { + tmpU32no1 = (WebRtc_UWord32)(0x7fffffff); + } + } + tmpU32no3 = WEBRTC_SPL_UDIV(WEBRTC_SPL_LSHIFT_U32(inst->thresholdSpecDiff, 17), 25); + tmpU32no2 = tmpU32no1 - tmpU32no3; + nShifts = 1; + tmpIndFX = 16384; // Q14(1.0) + //use larger width in tanh map for pause regions + if (tmpU32no2 & 0x80000000) + { + tmpIndFX = 0; + tmpU32no2 = tmpU32no3 - tmpU32no1; + //widthPrior = widthPrior * 2.0; + nShifts--; + } + tmpU32no1 = WEBRTC_SPL_RSHIFT_U32(tmpU32no2, nShifts); + // compute indicator function: sigmoid map + /* FLOAT code + indicator2 = 0.5 * (tanh(widthPrior * (tmpFloat1 - threshPrior2)) + 1.0); + */ + tableIndex = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_U32(tmpU32no1, 14); + if (tableIndex < 16) + { + tmp16no2 = kIndicatorTable[tableIndex]; + tmp16no1 = kIndicatorTable[tableIndex + 1] - kIndicatorTable[tableIndex]; + frac = (WebRtc_Word16)(tmpU32no1 & 0x00003fff); // Q14 + tmp16no2 += (WebRtc_Word16)WEBRTC_SPL_MUL_16_16_RSFT_WITH_ROUND(tmp16no1, frac, + 14); + if (tmpIndFX) + { + tmpIndFX = 8192 + tmp16no2; + } else + { + tmpIndFX = 8192 - tmp16no2; + } + } + indPriorFX += WEBRTC_SPL_MUL_16_16(inst->weightSpecDiff, tmpIndFX); // 6*Q14 + } + + //combine the indicator function with the feature weights + // FLOAT code + // indPrior = 1 - (weightIndPrior0 * indicator0 + weightIndPrior1 * indicator1 + weightIndPrior2 * indicator2); + indPriorFX16 = WebRtcSpl_DivW32W16ResW16(98307 - indPriorFX, 6); // Q14 + // done with computing indicator function + + //compute the prior probability + // FLOAT code + // inst->priorNonSpeechProb += PRIOR_UPDATE * (indPriorNonSpeech - inst->priorNonSpeechProb); + tmp16 = indPriorFX16 - inst->priorNonSpeechProb; // Q14 + inst->priorNonSpeechProb += (WebRtc_Word16)WEBRTC_SPL_MUL_16_16_RSFT(PRIOR_UPDATE_Q14, + tmp16, 14); // Q14 + + //final speech probability: combine prior model with LR factor: + for (i = 0; i < inst->magnLen; i++) + { + // FLOAT code + // invLrt = exp(inst->logLrtTimeAvg[i]); + // invLrt = inst->priorSpeechProb * invLrt; + // nonSpeechProbFinal[i] = (1.0 - inst->priorSpeechProb) / (1.0 - inst->priorSpeechProb + invLrt); + // invLrt = (1.0 - inst->priorNonSpeechProb) * invLrt; + // nonSpeechProbFinal[i] = inst->priorNonSpeechProb / (inst->priorNonSpeechProb + invLrt); + nonSpeechProbFinal[i] = 0; // Q8 + if ((inst->logLrtTimeAvgW32[i] < 65300) && (inst->priorNonSpeechProb > 0)) + { + tmp32no1 = WEBRTC_SPL_RSHIFT_W32(WEBRTC_SPL_MUL(inst->logLrtTimeAvgW32[i], 23637), + 14); // Q12 + intPart = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_W32(tmp32no1, 12); + if (intPart < -8) + { + intPart = -8; + } + frac = (WebRtc_Word16)(tmp32no1 & 0x00000fff); // Q12 + // Quadratic approximation of 2^frac + tmp32no2 = WEBRTC_SPL_RSHIFT_W32(frac * frac * 44, 19); // Q12 + tmp32no2 += WEBRTC_SPL_MUL_16_16_RSFT(frac, 84, 7); // Q12 + invLrtFX = WEBRTC_SPL_LSHIFT_W32(1, 8 + intPart) + + WEBRTC_SPL_SHIFT_W32(tmp32no2, intPart - 4); // Q8 + + normTmp = WebRtcSpl_NormW32(invLrtFX); + normTmp2 = WebRtcSpl_NormW16((16384 - inst->priorNonSpeechProb)); + if (normTmp + normTmp2 < 15) + { + invLrtFX = WEBRTC_SPL_RSHIFT_W32(invLrtFX, 15 - normTmp2 - normTmp); // Q(normTmp+normTmp2-7) + tmp32no1 = WEBRTC_SPL_MUL_32_16(invLrtFX, (16384 - inst->priorNonSpeechProb)); // Q(normTmp+normTmp2+7) + invLrtFX = WEBRTC_SPL_SHIFT_W32(tmp32no1, 7 - normTmp - normTmp2); // Q14 + } else + { + tmp32no1 = WEBRTC_SPL_MUL_32_16(invLrtFX, (16384 - inst->priorNonSpeechProb)); // Q22 + invLrtFX = WEBRTC_SPL_RSHIFT_W32(tmp32no1, 8); // Q14 + } + + tmp32no1 = WEBRTC_SPL_LSHIFT_W32((WebRtc_Word32)inst->priorNonSpeechProb, 8); // Q22 + nonSpeechProbFinal[i] = (WebRtc_UWord16)WEBRTC_SPL_DIV(tmp32no1, + (WebRtc_Word32)inst->priorNonSpeechProb + + invLrtFX); // Q8 + if (7 - normTmp - normTmp2 > 0) + { + nonSpeechProbFinal[i] = 0; // Q8 + } + } + } +} + +// Transform input (speechFrame) to frequency domain magnitude (magnU16) +void WebRtcNsx_DataAnalysis(NsxInst_t *inst, short *speechFrame, WebRtc_UWord16 *magnU16) +{ + + WebRtc_UWord32 tmpU32no1, tmpU32no2; + + WebRtc_Word32 tmp_1_w32 = 0; + WebRtc_Word32 tmp_2_w32 = 0; + WebRtc_Word32 sum_log_magn = 0; + WebRtc_Word32 sum_log_i_log_magn = 0; + + WebRtc_UWord16 sum_log_magn_u16 = 0; + WebRtc_UWord16 tmp_u16 = 0; + + WebRtc_Word16 sum_log_i = 0; + WebRtc_Word16 sum_log_i_square = 0; + WebRtc_Word16 frac = 0; + WebRtc_Word16 log2 = 0; + WebRtc_Word16 matrix_determinant = 0; + WebRtc_Word16 winData[ANAL_BLOCKL_MAX], maxWinData; + WebRtc_Word16 realImag[ANAL_BLOCKL_MAX << 1]; + + int i, j; + int outCFFT; + int zeros; + int net_norm = 0; + int right_shifts_in_magnU16 = 0; + int right_shifts_in_initMagnEst = 0; + + // For lower band do all processing + // update analysis buffer for L band + WEBRTC_SPL_MEMCPY_W16(inst->analysisBuffer, inst->analysisBuffer + inst->blockLen10ms, + inst->anaLen - inst->blockLen10ms); + WEBRTC_SPL_MEMCPY_W16(inst->analysisBuffer + inst->anaLen - inst->blockLen10ms, + speechFrame, inst->blockLen10ms); + + // Window data before FFT + for (i = 0; i < inst->anaLen; i++) + { + winData[i] = (WebRtc_Word16)WEBRTC_SPL_MUL_16_16_RSFT_WITH_ROUND(inst->window[i], + inst->analysisBuffer[i], + 14); // Q0 + } + // Get input energy + inst->energyIn = WebRtcSpl_Energy(winData, (int)inst->anaLen, &(inst->scaleEnergyIn)); + + // Reset zero input flag + inst->zeroInputSignal = 0; + // Acquire norm for winData + maxWinData = WebRtcSpl_MaxAbsValueW16(winData, inst->anaLen); + inst->normData = WebRtcSpl_NormW16(maxWinData); + if (maxWinData == 0) + { + // Treat zero input separately. + inst->zeroInputSignal = 1; + return; + } + + // Determine the net normalization in the frequency domain + net_norm = inst->stages - inst->normData; + // Track lowest normalization factor and use it to prevent wrap around in shifting + right_shifts_in_magnU16 = inst->normData - inst->minNorm; + right_shifts_in_initMagnEst = WEBRTC_SPL_MAX(-right_shifts_in_magnU16, 0); + inst->minNorm -= right_shifts_in_initMagnEst; + right_shifts_in_magnU16 = WEBRTC_SPL_MAX(right_shifts_in_magnU16, 0); + + // create realImag as winData interleaved with zeros (= imag. part), normalize it + for (i = 0; i < inst->anaLen; i++) + { + j = WEBRTC_SPL_LSHIFT_W16(i, 1); + realImag[j] = WEBRTC_SPL_LSHIFT_W16(winData[i], inst->normData); // Q(normData) + realImag[j + 1] = 0; // Insert zeros in imaginary part + } + + // bit-reverse position of elements in array and FFT the array + WebRtcSpl_ComplexBitReverse(realImag, inst->stages); // Q(normData-stages) + outCFFT = WebRtcSpl_ComplexFFT(realImag, inst->stages, 1); + + inst->imag[0] = 0; // Q(normData-stages) + inst->imag[inst->anaLen2] = 0; + inst->real[0] = realImag[0]; // Q(normData-stages) + inst->real[inst->anaLen2] = realImag[inst->anaLen]; + // Q(2*(normData-stages)) + inst->magnEnergy = (WebRtc_UWord32)WEBRTC_SPL_MUL_16_16(inst->real[0], inst->real[0]); + inst->magnEnergy += (WebRtc_UWord32)WEBRTC_SPL_MUL_16_16(inst->real[inst->anaLen2], + inst->real[inst->anaLen2]); + magnU16[0] = (WebRtc_UWord16)WEBRTC_SPL_ABS_W16(inst->real[0]); // Q(normData-stages) + magnU16[inst->anaLen2] = (WebRtc_UWord16)WEBRTC_SPL_ABS_W16(inst->real[inst->anaLen2]); + inst->sumMagn = (WebRtc_UWord32)magnU16[0]; // Q(normData-stages) + inst->sumMagn += (WebRtc_UWord32)magnU16[inst->anaLen2]; + + // Gather information during startup for noise parameter estimation + if (inst->blockIndex < END_STARTUP_SHORT) + { + // Switch initMagnEst to Q(minNorm-stages) + inst->initMagnEst[0] = WEBRTC_SPL_RSHIFT_U32(inst->initMagnEst[0], + right_shifts_in_initMagnEst); + inst->initMagnEst[inst->anaLen2] = + WEBRTC_SPL_RSHIFT_U32(inst->initMagnEst[inst->anaLen2], + right_shifts_in_initMagnEst); // Q(minNorm-stages) + + // Shift magnU16 to same domain as initMagnEst + tmpU32no1 = WEBRTC_SPL_RSHIFT_W32((WebRtc_UWord32)magnU16[0], + right_shifts_in_magnU16); // Q(minNorm-stages) + tmpU32no2 = WEBRTC_SPL_RSHIFT_W32((WebRtc_UWord32)magnU16[inst->anaLen2], + right_shifts_in_magnU16); // Q(minNorm-stages) + + // Update initMagnEst + inst->initMagnEst[0] += tmpU32no1; // Q(minNorm-stages) + inst->initMagnEst[inst->anaLen2] += tmpU32no2; // Q(minNorm-stages) + + log2 = 0; + if (magnU16[inst->anaLen2]) + { + // Calculate log2(magnU16[inst->anaLen2]) + zeros = WebRtcSpl_NormU32((WebRtc_UWord32)magnU16[inst->anaLen2]); + frac = (WebRtc_Word16)((((WebRtc_UWord32)magnU16[inst->anaLen2] << zeros) & + 0x7FFFFFFF) >> 23); // Q8 + // log2(magnU16(i)) in Q8 + log2 = (WebRtc_Word16)(((31 - zeros) << 8) + WebRtcNsx_kLogTableFrac[frac]); + } + + sum_log_magn = (WebRtc_Word32)log2; // Q8 + // sum_log_i_log_magn in Q17 + sum_log_i_log_magn = (WEBRTC_SPL_MUL_16_16(kLogIndex[inst->anaLen2], log2) >> 3); + } + + for (i = 1; i < inst->anaLen2; i++) + { + j = WEBRTC_SPL_LSHIFT_W16(i, 1); + inst->real[i] = realImag[j]; + inst->imag[i] = -realImag[j + 1]; + // magnitude spectrum + // energy in Q(2*(normData-stages)) + tmpU32no1 = (WebRtc_UWord32)WEBRTC_SPL_MUL_16_16(realImag[j], realImag[j]); + tmpU32no1 += (WebRtc_UWord32)WEBRTC_SPL_MUL_16_16(realImag[j + 1], realImag[j + 1]); + inst->magnEnergy += tmpU32no1; // Q(2*(normData-stages)) + + magnU16[i] = (WebRtc_UWord16)WebRtcSpl_Sqrt(tmpU32no1); // Q(normData-stages) + inst->sumMagn += (WebRtc_UWord32)magnU16[i]; // Q(normData-stages) + if (inst->blockIndex < END_STARTUP_SHORT) + { + // Switch initMagnEst to Q(minNorm-stages) + inst->initMagnEst[i] = WEBRTC_SPL_RSHIFT_U32(inst->initMagnEst[i], + right_shifts_in_initMagnEst); + + // Shift magnU16 to same domain as initMagnEst, i.e., Q(minNorm-stages) + tmpU32no1 = WEBRTC_SPL_RSHIFT_W32((WebRtc_UWord32)magnU16[i], + right_shifts_in_magnU16); + // Update initMagnEst + inst->initMagnEst[i] += tmpU32no1; // Q(minNorm-stages) + + if (i >= kStartBand) + { + // For pink noise estimation. Collect data neglecting lower frequency band + log2 = 0; + if (magnU16[i]) + { + zeros = WebRtcSpl_NormU32((WebRtc_UWord32)magnU16[i]); + frac = (WebRtc_Word16)((((WebRtc_UWord32)magnU16[i] << zeros) & + 0x7FFFFFFF) >> 23); + // log2(magnU16(i)) in Q8 + log2 = (WebRtc_Word16)(((31 - zeros) << 8) + + WebRtcNsx_kLogTableFrac[frac]); + } + sum_log_magn += (WebRtc_Word32)log2; // Q8 + // sum_log_i_log_magn in Q17 + sum_log_i_log_magn += (WEBRTC_SPL_MUL_16_16(kLogIndex[i], log2) >> 3); + } + } + } + + //compute simplified noise model during startup + if (inst->blockIndex < END_STARTUP_SHORT) + { + // Estimate White noise + // Switch whiteNoiseLevel to Q(minNorm-stages) + inst->whiteNoiseLevel = WEBRTC_SPL_RSHIFT_U32(inst->whiteNoiseLevel, + right_shifts_in_initMagnEst); + + // Update the average magnitude spectrum, used as noise estimate. + tmpU32no1 = WEBRTC_SPL_UMUL_32_16(inst->sumMagn, inst->overdrive); + tmpU32no1 = WEBRTC_SPL_RSHIFT_U32(tmpU32no1, inst->stages + 8); + + // Replacing division above with 'stages' shifts + // Shift to same Q-domain as whiteNoiseLevel + tmpU32no1 = WEBRTC_SPL_RSHIFT_U32(tmpU32no1, right_shifts_in_magnU16); + // This operation is safe from wrap around as long as END_STARTUP_SHORT < 128 + assert(END_STARTUP_SHORT < 128); + inst->whiteNoiseLevel += tmpU32no1; // Q(minNorm-stages) + + // Estimate Pink noise parameters + // Denominator used in both parameter estimates. + // The value is only dependent on the size of the frequency band (kStartBand) + // and to reduce computational complexity stored in a table (kDeterminantEstMatrix[]) + matrix_determinant = kDeterminantEstMatrix[kStartBand]; // Q0 + sum_log_i = kSumLogIndex[kStartBand]; // Q5 + sum_log_i_square = kSumSquareLogIndex[kStartBand]; // Q2 + if (inst->fs == 8000) + { + // Adjust values to shorter blocks in narrow band. + tmp_1_w32 = (WebRtc_Word32)matrix_determinant; + tmp_1_w32 += WEBRTC_SPL_MUL_16_16_RSFT(kSumLogIndex[65], sum_log_i, 9); + tmp_1_w32 -= WEBRTC_SPL_MUL_16_16_RSFT(kSumLogIndex[65], kSumLogIndex[65], 10); + tmp_1_w32 -= WEBRTC_SPL_LSHIFT_W32((WebRtc_Word32)sum_log_i_square, 4); + tmp_1_w32 -= WEBRTC_SPL_MUL_16_16_RSFT((WebRtc_Word16)(inst->magnLen + - kStartBand), kSumSquareLogIndex[65], 2); + matrix_determinant = (WebRtc_Word16)tmp_1_w32; + sum_log_i -= kSumLogIndex[65]; // Q5 + sum_log_i_square -= kSumSquareLogIndex[65]; // Q2 + } + + // Necessary number of shifts to fit sum_log_magn in a word16 + zeros = 16 - WebRtcSpl_NormW32(sum_log_magn); + if (zeros < 0) + { + zeros = 0; + } + tmp_1_w32 = WEBRTC_SPL_LSHIFT_W32(sum_log_magn, 1); // Q9 + sum_log_magn_u16 = (WebRtc_UWord16)WEBRTC_SPL_RSHIFT_W32(tmp_1_w32, zeros);//Q(9-zeros) + + // Calculate and update pinkNoiseNumerator. Result in Q11. + tmp_2_w32 = WEBRTC_SPL_MUL_16_U16(sum_log_i_square, sum_log_magn_u16); // Q(11-zeros) + tmpU32no1 = WEBRTC_SPL_RSHIFT_U32((WebRtc_UWord32)sum_log_i_log_magn, 12); // Q5 + + // Shift the largest value of sum_log_i and tmp32no3 before multiplication + tmp_u16 = WEBRTC_SPL_LSHIFT_U16((WebRtc_UWord16)sum_log_i, 1); // Q6 + if ((WebRtc_UWord32)sum_log_i > tmpU32no1) + { + tmp_u16 = WEBRTC_SPL_RSHIFT_U16(tmp_u16, zeros); + } + else + { + tmpU32no1 = WEBRTC_SPL_RSHIFT_U32(tmpU32no1, zeros); + } + tmp_2_w32 -= (WebRtc_Word32)WEBRTC_SPL_UMUL_32_16(tmpU32no1, tmp_u16); // Q(11-zeros) + matrix_determinant = WEBRTC_SPL_RSHIFT_W16(matrix_determinant, zeros); // Q(-zeros) + tmp_2_w32 = WebRtcSpl_DivW32W16(tmp_2_w32, matrix_determinant); // Q11 + tmp_2_w32 += WEBRTC_SPL_LSHIFT_W32((WebRtc_Word32)net_norm, 11); // Q11 + if (tmp_2_w32 < 0) + { + tmp_2_w32 = 0; + } + inst->pinkNoiseNumerator += tmp_2_w32; // Q11 + + // Calculate and update pinkNoiseExp. Result in Q14. + tmp_2_w32 = WEBRTC_SPL_MUL_16_U16(sum_log_i, sum_log_magn_u16); // Q(14-zeros) + tmp_1_w32 = WEBRTC_SPL_RSHIFT_W32(sum_log_i_log_magn, 3 + zeros); + tmp_1_w32 = WEBRTC_SPL_MUL((WebRtc_Word32)(inst->magnLen - kStartBand), + tmp_1_w32); + tmp_2_w32 -= tmp_1_w32; // Q(14-zeros) + if (tmp_2_w32 > 0) + { + // If the exponential parameter is negative force it to zero, which means a + // flat spectrum. + tmp_1_w32 = WebRtcSpl_DivW32W16(tmp_2_w32, matrix_determinant); // Q14 + inst->pinkNoiseExp += WEBRTC_SPL_SAT(16384, tmp_1_w32, 0); // Q14 + } + } +} + +void WebRtcNsx_DataSynthesis(NsxInst_t *inst, short *outFrame) +{ + WebRtc_Word32 tmp32no1; + WebRtc_Word32 energyOut; + + WebRtc_Word16 realImag[ANAL_BLOCKL_MAX << 1]; + WebRtc_Word16 tmp16no1, tmp16no2; + WebRtc_Word16 energyRatio; + WebRtc_Word16 gainFactor, gainFactor1, gainFactor2; + + int i, j; + int outCIFFT; + int scaleEnergyOut = 0; + + if (inst->zeroInputSignal) + { + // synthesize the special case of zero input + // read out fully processed segment + for (i = 0; i < inst->blockLen10ms; i++) + { + outFrame[i] = inst->synthesisBuffer[i]; // Q0 + } + // update synthesis buffer + WEBRTC_SPL_MEMCPY_W16(inst->synthesisBuffer, + inst->synthesisBuffer + inst->blockLen10ms, + inst->anaLen - inst->blockLen10ms); + WebRtcSpl_ZerosArrayW16(inst->synthesisBuffer + inst->anaLen - inst->blockLen10ms, + inst->blockLen10ms); + return; + } + // Filter the data in the frequency domain + for (i = 0; i < inst->magnLen; i++) + { + inst->real[i] = (WebRtc_Word16)WEBRTC_SPL_MUL_16_16_RSFT(inst->real[i], + (WebRtc_Word16)(inst->noiseSupFilter[i]), 14); // Q(normData-stages) + inst->imag[i] = (WebRtc_Word16)WEBRTC_SPL_MUL_16_16_RSFT(inst->imag[i], + (WebRtc_Word16)(inst->noiseSupFilter[i]), 14); // Q(normData-stages) + } + // back to time domain + // Create spectrum + realImag[0] = inst->real[0]; + realImag[1] = -inst->imag[0]; + for (i = 1; i < inst->anaLen2; i++) + { + j = WEBRTC_SPL_LSHIFT_W16(i, 1); + tmp16no1 = (inst->anaLen << 1) - j; + realImag[j] = inst->real[i]; + realImag[j + 1] = -inst->imag[i]; + realImag[tmp16no1] = inst->real[i]; + realImag[tmp16no1 + 1] = inst->imag[i]; + } + realImag[inst->anaLen] = inst->real[inst->anaLen2]; + realImag[inst->anaLen + 1] = -inst->imag[inst->anaLen2]; + + // bit-reverse position of elements in array and IFFT it + WebRtcSpl_ComplexBitReverse(realImag, inst->stages); + outCIFFT = WebRtcSpl_ComplexIFFT(realImag, inst->stages, 1); + + for (i = 0; i < inst->anaLen; i++) + { + j = WEBRTC_SPL_LSHIFT_W16(i, 1); + tmp32no1 = WEBRTC_SPL_SHIFT_W32((WebRtc_Word32)realImag[j], outCIFFT - inst->normData); + inst->real[i] = (WebRtc_Word16)WEBRTC_SPL_SAT(WEBRTC_SPL_WORD16_MAX, tmp32no1, + WEBRTC_SPL_WORD16_MIN); + } + + //scale factor: only do it after END_STARTUP_LONG time + gainFactor = 8192; // 8192 = Q13(1.0) + if (inst->gainMap == 1 && + inst->blockIndex > END_STARTUP_LONG && + inst->energyIn > 0) + { + energyOut = WebRtcSpl_Energy(inst->real, (int)inst->anaLen, &scaleEnergyOut); // Q(-scaleEnergyOut) + if (scaleEnergyOut == 0 && !(energyOut & 0x7f800000)) + { + energyOut = WEBRTC_SPL_SHIFT_W32(energyOut, 8 + scaleEnergyOut + - inst->scaleEnergyIn); + } else + { + inst->energyIn = WEBRTC_SPL_RSHIFT_W32(inst->energyIn, 8 + scaleEnergyOut + - inst->scaleEnergyIn); // Q(-8-scaleEnergyOut) + } + + assert(inst->energyIn > 0); + energyRatio = (WebRtc_Word16)WEBRTC_SPL_DIV(energyOut + + WEBRTC_SPL_RSHIFT_W32(inst->energyIn, 1), inst->energyIn); // Q8 + + // // original FLOAT code + // if (gain > blim) { + // factor1=1.0+1.3*(gain-blim); + // if (gain*factor1 > 1.0) { // FLOAT + // factor1 = 1.0/gain; // FLOAT + // } + // } + // else { + // factor1=1.0; // FLOAT + // } + // + // if (gain > blim) { + // factor2=1.0; //FLOAT + // } + // else { + // //don't reduce scale too much for pause regions: attenuation here should be controlled by flooring + // factor2=1.0-0.3*(blim-gain); // FLOAT + // if (gain <= inst->denoiseBound) { + // factor2=1.0-0.3*(blim-inst->denoiseBound); // FLOAT + // } + // } + + // all done in lookup tables now + gainFactor1 = kFactor1Table[energyRatio]; // Q8 + gainFactor2 = inst->factor2Table[energyRatio]; // Q8 + + //combine both scales with speech/noise prob: note prior (priorSpeechProb) is not frequency dependent + + // factor = inst->priorSpeechProb*factor1 + (1.0-inst->priorSpeechProb)*factor2; // original code + tmp16no1 = (WebRtc_Word16)WEBRTC_SPL_MUL_16_16_RSFT(16384 - inst->priorNonSpeechProb, + gainFactor1, 14); // Q13 16384 = Q14(1.0) + tmp16no2 = (WebRtc_Word16)WEBRTC_SPL_MUL_16_16_RSFT(inst->priorNonSpeechProb, + gainFactor2, 14); // Q13; + gainFactor = tmp16no1 + tmp16no2; // Q13 + } // out of flag_gain_map==1 + + // synthesis + for (i = 0; i < inst->anaLen; i++) + { + tmp16no1 = (WebRtc_Word16)WEBRTC_SPL_MUL_16_16_RSFT_WITH_ROUND(inst->window[i], + inst->real[i], 14); // Q0, window in Q14 + tmp32no1 = WEBRTC_SPL_MUL_16_16_RSFT_WITH_ROUND(tmp16no1, gainFactor, 13); // Q0 + // Down shift with rounding + tmp16no2 = (WebRtc_Word16)WEBRTC_SPL_SAT(WEBRTC_SPL_WORD16_MAX, tmp32no1, + WEBRTC_SPL_WORD16_MIN); // Q0 + inst->synthesisBuffer[i] = WEBRTC_SPL_ADD_SAT_W16(inst->synthesisBuffer[i], tmp16no2); // Q0 + } + + // read out fully processed segment + for (i = 0; i < inst->blockLen10ms; i++) + { + outFrame[i] = inst->synthesisBuffer[i]; // Q0 + } + // update synthesis buffer + WEBRTC_SPL_MEMCPY_W16(inst->synthesisBuffer, inst->synthesisBuffer + inst->blockLen10ms, + inst->anaLen - inst->blockLen10ms); + WebRtcSpl_ZerosArrayW16(inst->synthesisBuffer + inst->anaLen - inst->blockLen10ms, + inst->blockLen10ms); +} + +int WebRtcNsx_ProcessCore(NsxInst_t *inst, short *speechFrame, short *speechFrameHB, + short *outFrame, short *outFrameHB) +{ + // main routine for noise suppression + + WebRtc_UWord32 tmpU32no1, tmpU32no2, tmpU32no3; + WebRtc_UWord32 satMax, maxNoiseU32; + WebRtc_UWord32 tmpMagnU32, tmpNoiseU32; + WebRtc_UWord32 nearMagnEst; + WebRtc_UWord32 noiseUpdateU32; + WebRtc_UWord32 noiseU32[HALF_ANAL_BLOCKL]; + WebRtc_UWord32 postLocSnr[HALF_ANAL_BLOCKL]; + WebRtc_UWord32 priorLocSnr[HALF_ANAL_BLOCKL]; + WebRtc_UWord32 prevNearSnr[HALF_ANAL_BLOCKL]; + WebRtc_UWord32 curNearSnr; + WebRtc_UWord32 priorSnr; + WebRtc_UWord32 noise_estimate = 0; + WebRtc_UWord32 noise_estimate_avg = 0; + WebRtc_UWord32 numerator = 0; + + WebRtc_Word32 tmp32no1, tmp32no2; + WebRtc_Word32 pink_noise_num_avg = 0; + + WebRtc_UWord16 tmpU16no1; + WebRtc_UWord16 magnU16[HALF_ANAL_BLOCKL]; + WebRtc_UWord16 prevNoiseU16[HALF_ANAL_BLOCKL]; + WebRtc_UWord16 nonSpeechProbFinal[HALF_ANAL_BLOCKL]; + WebRtc_UWord16 gammaNoise, prevGammaNoise; + WebRtc_UWord16 noiseSupFilterTmp[HALF_ANAL_BLOCKL]; + + WebRtc_Word16 qMagn, qNoise; + WebRtc_Word16 avgProbSpeechHB, gainModHB, avgFilterGainHB, gainTimeDomainHB; + WebRtc_Word16 pink_noise_exp_avg = 0; + + int i; + int nShifts, postShifts; + int norm32no1, norm32no2; + int flag, sign; + int q_domain_to_use = 0; + +#ifdef NS_FILEDEBUG + fwrite(spframe, sizeof(short), inst->blockLen10ms, inst->infile); +#endif + + // Check that initialization has been done + if (inst->initFlag != 1) + { + return -1; + } + // Check for valid pointers based on sampling rate + if ((inst->fs == 32000) && (speechFrameHB == NULL)) + { + return -1; + } + + // Store speechFrame and transform to frequency domain + WebRtcNsx_DataAnalysis(inst, speechFrame, magnU16); + + if (inst->zeroInputSignal) + { + WebRtcNsx_DataSynthesis(inst, outFrame); + + if (inst->fs == 32000) + { + // update analysis buffer for H band + // append new data to buffer FX + WEBRTC_SPL_MEMCPY_W16(inst->dataBufHBFX, inst->dataBufHBFX + inst->blockLen10ms, + inst->anaLen - inst->blockLen10ms); + WEBRTC_SPL_MEMCPY_W16(inst->dataBufHBFX + inst->anaLen - inst->blockLen10ms, + speechFrameHB, inst->blockLen10ms); + for (i = 0; i < inst->blockLen10ms; i++) + { + outFrameHB[i] = inst->dataBufHBFX[i]; // Q0 + } + } // end of H band gain computation + return 0; + } + + // Update block index when we have something to process + inst->blockIndex++; + // + + // Norm of magn + qMagn = inst->normData - inst->stages; + + // Compute spectral flatness on input spectrum + WebRtcNsx_ComputeSpectralFlatness(inst, magnU16); + + // quantile noise estimate + WebRtcNsx_NoiseEstimation(inst, magnU16, noiseU32, &qNoise); + + //noise estimate from previous frame + for (i = 0; i < inst->magnLen; i++) + { + prevNoiseU16[i] = (WebRtc_UWord16)WEBRTC_SPL_RSHIFT_U32(inst->prevNoiseU32[i], 11); // Q(prevQNoise) + } + + if (inst->blockIndex < END_STARTUP_SHORT) + { + // Noise Q-domain to be used later; see description at end of section. + q_domain_to_use = WEBRTC_SPL_MIN((int)qNoise, inst->minNorm - inst->stages); + + // Calculate frequency independent parts in parametric noise estimate and calculate + // the estimate for the lower frequency band (same values for all frequency bins) + if (inst->pinkNoiseExp) + { + pink_noise_exp_avg = (WebRtc_Word16)WebRtcSpl_DivW32W16(inst->pinkNoiseExp, + (WebRtc_Word16)(inst->blockIndex + 1)); // Q14 + pink_noise_num_avg = WebRtcSpl_DivW32W16(inst->pinkNoiseNumerator, + (WebRtc_Word16)(inst->blockIndex + 1)); // Q11 + WebRtcNsx_CalcParametricNoiseEstimate(inst, + pink_noise_exp_avg, + pink_noise_num_avg, + kStartBand, + &noise_estimate, + &noise_estimate_avg); + } + else + { + // Use white noise estimate if we have poor pink noise parameter estimates + noise_estimate = inst->whiteNoiseLevel; // Q(minNorm-stages) + noise_estimate_avg = noise_estimate / (inst->blockIndex + 1); // Q(minNorm-stages) + } + for (i = 0; i < inst->magnLen; i++) + { + // Estimate the background noise using the pink noise parameters if permitted + if ((inst->pinkNoiseExp) && (i >= kStartBand)) + { + // Reset noise_estimate + noise_estimate = 0; + noise_estimate_avg = 0; + // Calculate the parametric noise estimate for current frequency bin + WebRtcNsx_CalcParametricNoiseEstimate(inst, + pink_noise_exp_avg, + pink_noise_num_avg, + i, + &noise_estimate, + &noise_estimate_avg); + } + // Calculate parametric Wiener filter + noiseSupFilterTmp[i] = inst->denoiseBound; + if (inst->initMagnEst[i]) + { + // numerator = (initMagnEst - noise_estimate * overdrive) + // Result in Q(8+minNorm-stages) + tmpU32no1 = WEBRTC_SPL_UMUL_32_16(noise_estimate, inst->overdrive); + numerator = WEBRTC_SPL_LSHIFT_U32(inst->initMagnEst[i], 8); + if (numerator > tmpU32no1) + { + // Suppression filter coefficient larger than zero, so calculate. + numerator -= tmpU32no1; + + // Determine number of left shifts in numerator for best accuracy after + // division + nShifts = WebRtcSpl_NormU32(numerator); + nShifts = WEBRTC_SPL_SAT(6, nShifts, 0); + + // Shift numerator to Q(nShifts+8+minNorm-stages) + numerator = WEBRTC_SPL_LSHIFT_U32(numerator, nShifts); + + // Shift denominator to Q(nShifts-6+minNorm-stages) + tmpU32no1 = WEBRTC_SPL_RSHIFT_U32(inst->initMagnEst[i], 6 - nShifts); + tmpU32no2 = WEBRTC_SPL_UDIV(numerator, tmpU32no1); // Q14 + noiseSupFilterTmp[i] = (WebRtc_UWord16)WEBRTC_SPL_SAT(16384, tmpU32no2, + (WebRtc_UWord32)(inst->denoiseBound)); // Q14 + } + } + // Weight quantile noise 'noiseU32' with modeled noise 'noise_estimate_avg' + // 'noiseU32 is in Q(qNoise) and 'noise_estimate' in Q(minNorm-stages) + // To guarantee that we do not get wrap around when shifting to the same domain + // we use the lowest one. Furthermore, we need to save 6 bits for the weighting. + // 'noise_estimate_avg' can handle this operation by construction, but 'noiseU32' + // may not. + + // Shift 'noiseU32' to 'q_domain_to_use' + tmpU32no1 = WEBRTC_SPL_RSHIFT_U32(noiseU32[i], (int)qNoise - q_domain_to_use); + // Shift 'noise_estimate_avg' to 'q_domain_to_use' + tmpU32no2 = WEBRTC_SPL_RSHIFT_U32(noise_estimate_avg, inst->minNorm - inst->stages + - q_domain_to_use); + // Make a simple check to see if we have enough room for weighting 'tmpU32no1' + // without wrap around + nShifts = 0; + if (tmpU32no1 & 0xfc000000) { + tmpU32no1 = WEBRTC_SPL_RSHIFT_U32(tmpU32no1, 6); + tmpU32no2 = WEBRTC_SPL_RSHIFT_U32(tmpU32no2, 6); + nShifts = 6; + } + // Add them together and divide by startup length + noiseU32[i] = WebRtcSpl_DivU32U16(tmpU32no1 + tmpU32no2, END_STARTUP_SHORT); + // Shift back if necessary + noiseU32[i] = WEBRTC_SPL_LSHIFT_U32(noiseU32[i], nShifts); + } + // Update new Q-domain for 'noiseU32' + qNoise = q_domain_to_use; + } + // compute average signal during END_STARTUP_LONG time: + // used to normalize spectral difference measure + if (inst->blockIndex < END_STARTUP_LONG) + { + // substituting division with shift ending up in Q(-2*stages) + inst->timeAvgMagnEnergyTmp + += WEBRTC_SPL_RSHIFT_U32(inst->magnEnergy, + 2 * inst->normData + inst->stages - 1); + inst->timeAvgMagnEnergy = WebRtcSpl_DivU32U16(inst->timeAvgMagnEnergyTmp, + inst->blockIndex + 1); + } + + //start processing at frames == converged+1 + // STEP 1: compute prior and post SNR based on quantile noise estimates + + // compute direct decision (DD) estimate of prior SNR: needed for new method + satMax = (WebRtc_UWord32)1048575;// Largest possible value without getting overflow despite shifting 12 steps + postShifts = 6 + qMagn - qNoise; + nShifts = 5 - inst->prevQMagn + inst->prevQNoise; + for (i = 0; i < inst->magnLen; i++) + { + // FLOAT: + // post SNR + // postLocSnr[i] = 0.0; + // if (magn[i] > noise[i]) + // { + // postLocSnr[i] = magn[i] / (noise[i] + 0.0001); + // } + // // previous post SNR + // // previous estimate: based on previous frame with gain filter (smooth is previous filter) + // + // prevNearSnr[i] = inst->prevMagnU16[i] / (inst->noisePrev[i] + 0.0001) * (inst->smooth[i]); + // + // // DD estimate is sum of two terms: current estimate and previous estimate + // // directed decision update of priorSnr (or we actually store [2*priorSnr+1]) + // + // priorLocSnr[i] = DD_PR_SNR * prevNearSnr[i] + (1.0 - DD_PR_SNR) * (postLocSnr[i] - 1.0); + + // calculate post SNR: output in Q11 + postLocSnr[i] = 2048; // 1.0 in Q11 + tmpU32no1 = WEBRTC_SPL_LSHIFT_U32((WebRtc_UWord32)magnU16[i], 6); // Q(6+qMagn) + if (postShifts < 0) + { + tmpU32no2 = WEBRTC_SPL_RSHIFT_U32(noiseU32[i], -postShifts); // Q(6+qMagn) + } else + { + tmpU32no2 = WEBRTC_SPL_LSHIFT_U32(noiseU32[i], postShifts); // Q(6+qMagn) + } + if (tmpU32no1 > tmpU32no2) + { + // Current magnitude larger than noise + tmpU32no1 = WEBRTC_SPL_LSHIFT_U32(tmpU32no1, 11); // Q(17+qMagn) + if (tmpU32no2) + { + tmpU32no1 = WEBRTC_SPL_UDIV(tmpU32no1, tmpU32no2); // Q11 + postLocSnr[i] = WEBRTC_SPL_MIN(satMax, tmpU32no1); // Q11 + } else + { + postLocSnr[i] = satMax; + } + } + + // calculate prevNearSnr[i] and save for later instead of recalculating it later + nearMagnEst = WEBRTC_SPL_UMUL_16_16(inst->prevMagnU16[i], inst->noiseSupFilter[i]); // Q(prevQMagn+14) + tmpU32no1 = WEBRTC_SPL_LSHIFT_U32(nearMagnEst, 3); // Q(prevQMagn+17) + tmpU32no2 = WEBRTC_SPL_RSHIFT_U32(inst->prevNoiseU32[i], nShifts); // Q(prevQMagn+6) + + if (tmpU32no2) + { + tmpU32no1 = WEBRTC_SPL_DIV(tmpU32no1, tmpU32no2); // Q11 + tmpU32no1 = WEBRTC_SPL_MIN(satMax, tmpU32no1); // Q11 + } else + { + tmpU32no1 = satMax; // Q11 + } + prevNearSnr[i] = tmpU32no1; // Q11 + + //directed decision update of priorSnr + tmpU32no1 = WEBRTC_SPL_UMUL_32_16(prevNearSnr[i], DD_PR_SNR_Q11); // Q22 + tmpU32no2 = WEBRTC_SPL_UMUL_32_16(postLocSnr[i] - 2048, ONE_MINUS_DD_PR_SNR_Q11); // Q22 + priorSnr = tmpU32no1 + tmpU32no2 + 512; // Q22 (added 512 for rounding) + // priorLocSnr = 1 + 2*priorSnr + priorLocSnr[i] = 2048 + WEBRTC_SPL_RSHIFT_U32(priorSnr, 10); // Q11 + } // end of loop over frequencies + // done with step 1: DD computation of prior and post SNR + + // STEP 2: compute speech/noise likelihood + + //compute difference of input spectrum with learned/estimated noise spectrum + WebRtcNsx_ComputeSpectralDifference(inst, magnU16); + //compute histograms for determination of parameters (thresholds and weights for features) + //parameters are extracted once every window time (=inst->modelUpdate) + //counter update + inst->cntThresUpdate++; + flag = (int)(inst->cntThresUpdate == inst->modelUpdate); + //update histogram + WebRtcNsx_FeatureParameterExtraction(inst, flag); + //compute model parameters + if (flag) + { + inst->cntThresUpdate = 0; // Reset counter + //update every window: + // get normalization for spectral difference for next window estimate + + // Shift to Q(-2*stages) + inst->curAvgMagnEnergy = WEBRTC_SPL_RSHIFT_U32(inst->curAvgMagnEnergy, STAT_UPDATES); + + tmpU32no1 = (inst->curAvgMagnEnergy + inst->timeAvgMagnEnergy + 1) >> 1; //Q(-2*stages) + // Update featureSpecDiff + if ((tmpU32no1 != inst->timeAvgMagnEnergy) && (inst->featureSpecDiff)) + { + norm32no1 = 0; + tmpU32no3 = tmpU32no1; + while (0xFFFF0000 & tmpU32no3) + { + tmpU32no3 >>= 1; + norm32no1++; + } + tmpU32no2 = inst->featureSpecDiff; + while (0xFFFF0000 & tmpU32no2) + { + tmpU32no2 >>= 1; + norm32no1++; + } + tmpU32no3 = WEBRTC_SPL_UMUL(tmpU32no3, tmpU32no2); + tmpU32no3 = WEBRTC_SPL_UDIV(tmpU32no3, inst->timeAvgMagnEnergy); + if (WebRtcSpl_NormU32(tmpU32no3) < norm32no1) + { + inst->featureSpecDiff = 0x007FFFFF; + } else + { + inst->featureSpecDiff = WEBRTC_SPL_MIN(0x007FFFFF, + WEBRTC_SPL_LSHIFT_U32(tmpU32no3, norm32no1)); + } + } + + inst->timeAvgMagnEnergy = tmpU32no1; // Q(-2*stages) + inst->curAvgMagnEnergy = 0; + } + + //compute speech/noise probability + WebRtcNsx_SpeechNoiseProb(inst, nonSpeechProbFinal, priorLocSnr, postLocSnr); + + //time-avg parameter for noise update + gammaNoise = NOISE_UPDATE_Q8; // Q8 + + maxNoiseU32 = 0; + postShifts = inst->prevQNoise - qMagn; + nShifts = inst->prevQMagn - qMagn; + for (i = 0; i < inst->magnLen; i++) + { + // temporary noise update: use it for speech frames if update value is less than previous + // the formula has been rewritten into: + // noiseUpdate = noisePrev[i] + (1 - gammaNoise) * nonSpeechProb * (magn[i] - noisePrev[i]) + + if (postShifts < 0) + { + tmpU32no2 = WEBRTC_SPL_RSHIFT_U32(magnU16[i], -postShifts); // Q(prevQNoise) + } else + { + tmpU32no2 = WEBRTC_SPL_LSHIFT_U32(magnU16[i], postShifts); // Q(prevQNoise) + } + if (prevNoiseU16[i] > tmpU32no2) + { + sign = -1; + tmpU32no1 = prevNoiseU16[i] - tmpU32no2; + } else + { + sign = 1; + tmpU32no1 = tmpU32no2 - prevNoiseU16[i]; + } + noiseUpdateU32 = inst->prevNoiseU32[i]; // Q(prevQNoise+11) + tmpU32no3 = 0; + if ((tmpU32no1) && (nonSpeechProbFinal[i])) + { + // This value will be used later, if gammaNoise changes + tmpU32no3 = WEBRTC_SPL_UMUL_32_16(tmpU32no1, nonSpeechProbFinal[i]); // Q(prevQNoise+8) + if (0x7c000000 & tmpU32no3) + { + // Shifting required before multiplication + tmpU32no2 + = WEBRTC_SPL_UMUL_32_16(WEBRTC_SPL_RSHIFT_U32(tmpU32no3, 5), gammaNoise); // Q(prevQNoise+11) + } else + { + // We can do shifting after multiplication + tmpU32no2 + = WEBRTC_SPL_RSHIFT_U32(WEBRTC_SPL_UMUL_32_16(tmpU32no3, gammaNoise), 5); // Q(prevQNoise+11) + } + if (sign > 0) + { + noiseUpdateU32 += tmpU32no2; // Q(prevQNoise+11) + } else + { + // This operation is safe. We can never get wrap around, since worst + // case scenario means magnU16 = 0 + noiseUpdateU32 -= tmpU32no2; // Q(prevQNoise+11) + } + } + + //increase gamma (i.e., less noise update) for frame likely to be speech + prevGammaNoise = gammaNoise; + gammaNoise = NOISE_UPDATE_Q8; + //time-constant based on speech/noise state + //increase gamma (i.e., less noise update) for frames likely to be speech + if (nonSpeechProbFinal[i] < ONE_MINUS_PROB_RANGE_Q8) + { + gammaNoise = GAMMA_NOISE_TRANS_AND_SPEECH_Q8; + } + + if (prevGammaNoise != gammaNoise) + { + // new noise update + // this line is the same as above, only that the result is stored in a different variable and the gammaNoise + // has changed + // + // noiseUpdate = noisePrev[i] + (1 - gammaNoise) * nonSpeechProb * (magn[i] - noisePrev[i]) + + if (0x7c000000 & tmpU32no3) + { + // Shifting required before multiplication + tmpU32no2 + = WEBRTC_SPL_UMUL_32_16(WEBRTC_SPL_RSHIFT_U32(tmpU32no3, 5), gammaNoise); // Q(prevQNoise+11) + } else + { + // We can do shifting after multiplication + tmpU32no2 + = WEBRTC_SPL_RSHIFT_U32(WEBRTC_SPL_UMUL_32_16(tmpU32no3, gammaNoise), 5); // Q(prevQNoise+11) + } + if (sign > 0) + { + tmpU32no1 = inst->prevNoiseU32[i] + tmpU32no2; // Q(prevQNoise+11) + } else + { + tmpU32no1 = inst->prevNoiseU32[i] - tmpU32no2; // Q(prevQNoise+11) + } + if (noiseUpdateU32 > tmpU32no1) + { + noiseUpdateU32 = tmpU32no1; // Q(prevQNoise+11) + } + } + noiseU32[i] = noiseUpdateU32; // Q(prevQNoise+11) + if (noiseUpdateU32 > maxNoiseU32) + { + maxNoiseU32 = noiseUpdateU32; + } + + // conservative noise update + // // original FLOAT code + // if (prob_speech < PROB_RANGE) { + // inst->avgMagnPause[i] = inst->avgMagnPause[i] + (1.0 - gamma_pause)*(magn[i] - inst->avgMagnPause[i]); + // } + + tmp32no2 = WEBRTC_SPL_SHIFT_W32(inst->avgMagnPause[i], -nShifts); + if (nonSpeechProbFinal[i] > ONE_MINUS_PROB_RANGE_Q8) + { + if (nShifts < 0) + { + tmp32no1 = (WebRtc_Word32)magnU16[i] - tmp32no2; // Q(qMagn) + tmp32no1 = WEBRTC_SPL_MUL_32_16(tmp32no1, ONE_MINUS_GAMMA_PAUSE_Q8); // Q(8+prevQMagn+nShifts) + tmp32no1 = WEBRTC_SPL_RSHIFT_W32(tmp32no1 + 128, 8); // Q(qMagn) + } else + { + tmp32no1 = WEBRTC_SPL_LSHIFT_W32((WebRtc_Word32)magnU16[i], nShifts) + - inst->avgMagnPause[i]; // Q(qMagn+nShifts) + tmp32no1 = WEBRTC_SPL_MUL_32_16(tmp32no1, ONE_MINUS_GAMMA_PAUSE_Q8); // Q(8+prevQMagn+nShifts) + tmp32no1 = WEBRTC_SPL_RSHIFT_W32(tmp32no1 + (128 << nShifts), 8 + nShifts); // Q(qMagn) + } + tmp32no2 += tmp32no1; // Q(qMagn) + } + inst->avgMagnPause[i] = tmp32no2; + } // end of frequency loop + + norm32no1 = WebRtcSpl_NormU32(maxNoiseU32); + qNoise = inst->prevQNoise + norm32no1 - 5; + // done with step 2: noise update + + // STEP 3: compute dd update of prior snr and post snr based on new noise estimate + nShifts = inst->prevQNoise + 11 - qMagn; + for (i = 0; i < inst->magnLen; i++) + { + // FLOAT code + // // post and prior SNR + // curNearSnr = 0.0; + // if (magn[i] > noise[i]) + // { + // curNearSnr = magn[i] / (noise[i] + 0.0001) - 1.0; + // } + // // DD estimate is sum of two terms: current estimate and previous estimate + // // directed decision update of snrPrior + // snrPrior = DD_PR_SNR * prevNearSnr[i] + (1.0 - DD_PR_SNR) * curNearSnr; + // // gain filter + // tmpFloat1 = inst->overdrive + snrPrior; + // tmpFloat2 = snrPrior / tmpFloat1; + // theFilter[i] = tmpFloat2; + + // calculate curNearSnr again, this is necessary because a new noise estimate has been made since then. for the original + curNearSnr = 0; // Q11 + if (nShifts < 0) + { + // This case is equivalent with magn < noise which implies curNearSnr = 0; + tmpMagnU32 = (WebRtc_UWord32)magnU16[i]; // Q(qMagn) + tmpNoiseU32 = WEBRTC_SPL_LSHIFT_U32(noiseU32[i], -nShifts); // Q(qMagn) + } else if (nShifts > 17) + { + tmpMagnU32 = WEBRTC_SPL_LSHIFT_U32(magnU16[i], 17); // Q(qMagn+17) + tmpNoiseU32 = WEBRTC_SPL_RSHIFT_U32(noiseU32[i], nShifts - 17); // Q(qMagn+17) + } else + { + tmpMagnU32 = WEBRTC_SPL_LSHIFT_U32((WebRtc_UWord32)magnU16[i], nShifts); // Q(qNoise_prev+11) + tmpNoiseU32 = noiseU32[i]; // Q(qNoise_prev+11) + } + if (tmpMagnU32 > tmpNoiseU32) + { + tmpU32no1 = tmpMagnU32 - tmpNoiseU32; // Q(qCur) + norm32no2 = WEBRTC_SPL_MIN(11, WebRtcSpl_NormU32(tmpU32no1)); + tmpU32no1 = WEBRTC_SPL_LSHIFT_U32(tmpU32no1, norm32no2); // Q(qCur+norm32no2) + tmpU32no2 = WEBRTC_SPL_RSHIFT_U32(tmpNoiseU32, 11 - norm32no2); // Q(qCur+norm32no2-11) + if (tmpU32no2) + { + tmpU32no1 = WEBRTC_SPL_UDIV(tmpU32no1, tmpU32no2); // Q11 + } + curNearSnr = WEBRTC_SPL_MIN(satMax, tmpU32no1); // Q11 + } + + //directed decision update of priorSnr + // FLOAT + // priorSnr = DD_PR_SNR * prevNearSnr + (1.0-DD_PR_SNR) * curNearSnr; + + tmpU32no1 = WEBRTC_SPL_UMUL_32_16(prevNearSnr[i], DD_PR_SNR_Q11); // Q22 + tmpU32no2 = WEBRTC_SPL_UMUL_32_16(curNearSnr, ONE_MINUS_DD_PR_SNR_Q11); // Q22 + priorSnr = tmpU32no1 + tmpU32no2; // Q22 + + //gain filter + tmpU32no1 = (WebRtc_UWord32)(inst->overdrive) + + WEBRTC_SPL_RSHIFT_U32(priorSnr + 8192, 14); // Q8 + tmpU16no1 = (WebRtc_UWord16)WEBRTC_SPL_UDIV(priorSnr + (tmpU32no1 >> 1), tmpU32no1); // Q14 + inst->noiseSupFilter[i] = WEBRTC_SPL_SAT(16384, tmpU16no1, inst->denoiseBound); // 16384 = Q14(1.0) // Q14 + + // Weight in the parametric Wiener filter during startup + if (inst->blockIndex < END_STARTUP_SHORT) + { + // Weight the two suppression filters + tmpU32no1 = WEBRTC_SPL_UMUL_16_16(inst->noiseSupFilter[i], + (WebRtc_UWord16)inst->blockIndex); + tmpU32no2 = WEBRTC_SPL_UMUL_16_16(noiseSupFilterTmp[i], + (WebRtc_UWord16)(END_STARTUP_SHORT + - inst->blockIndex)); + tmpU32no1 += tmpU32no2; + inst->noiseSupFilter[i] = (WebRtc_UWord16)WebRtcSpl_DivU32U16(tmpU32no1, + END_STARTUP_SHORT); + } + } // end of loop over frequencies + //done with step3 + + // save noise and magnitude spectrum for next frame + inst->prevQNoise = qNoise; + inst->prevQMagn = qMagn; + if (norm32no1 > 5) + { + for (i = 0; i < inst->magnLen; i++) + { + inst->prevNoiseU32[i] = WEBRTC_SPL_LSHIFT_U32(noiseU32[i], norm32no1 - 5); // Q(qNoise+11) + inst->prevMagnU16[i] = magnU16[i]; // Q(qMagn) + } + } else + { + for (i = 0; i < inst->magnLen; i++) + { + inst->prevNoiseU32[i] = WEBRTC_SPL_RSHIFT_U32(noiseU32[i], 5 - norm32no1); // Q(qNoise+11) + inst->prevMagnU16[i] = magnU16[i]; // Q(qMagn) + } + } + + WebRtcNsx_DataSynthesis(inst, outFrame); +#ifdef NS_FILEDEBUG + fwrite(outframe, sizeof(short), inst->blockLen10ms, inst->outfile); +#endif + + //for H band: + // only update data buffer, then apply time-domain gain is applied derived from L band + if (inst->fs == 32000) + { + // update analysis buffer for H band + // append new data to buffer FX + WEBRTC_SPL_MEMCPY_W16(inst->dataBufHBFX, inst->dataBufHBFX + inst->blockLen10ms, inst->anaLen - inst->blockLen10ms); + WEBRTC_SPL_MEMCPY_W16(inst->dataBufHBFX + inst->anaLen - inst->blockLen10ms, speechFrameHB, inst->blockLen10ms); + // range for averaging low band quantities for H band gain + + gainTimeDomainHB = 16384; // 16384 = Q14(1.0) + //average speech prob from low band + //average filter gain from low band + //avg over second half (i.e., 4->8kHz) of freq. spectrum + tmpU32no1 = 0; // Q12 + tmpU16no1 = 0; // Q8 + for (i = inst->anaLen2 - (inst->anaLen2 >> 2); i < inst->anaLen2; i++) + { + tmpU16no1 += nonSpeechProbFinal[i]; // Q8 + tmpU32no1 += (WebRtc_UWord32)(inst->noiseSupFilter[i]); // Q14 + } + avgProbSpeechHB = (WebRtc_Word16)(4096 + - WEBRTC_SPL_RSHIFT_U16(tmpU16no1, inst->stages - 7)); // Q12 + avgFilterGainHB = (WebRtc_Word16)WEBRTC_SPL_RSHIFT_U32(tmpU32no1, inst->stages - 3); // Q14 + + // // original FLOAT code + // // gain based on speech probability: + // avg_prob_speech_tt=(float)2.0*avg_prob_speech-(float)1.0; + // gain_mod=(float)0.5*((float)1.0+(float)tanh(avg_prob_speech_tt)); // between 0 and 1 + + // gain based on speech probability: + // original expression: "0.5 * (1 + tanh(2x-1))" + // avgProbSpeechHB has been anyway saturated to a value between 0 and 1 so the other cases don't have to be dealt with + // avgProbSpeechHB and gainModHB are in Q12, 3607 = Q12(0.880615234375) which is a zero point of + // |0.5 * (1 + tanh(2x-1)) - x| - |0.5 * (1 + tanh(2x-1)) - 0.880615234375| meaning that from that point the error of approximating + // the expression with f(x) = x would be greater than the error of approximating the expression with f(x) = 0.880615234375 + // error: "|0.5 * (1 + tanh(2x-1)) - x| from x=0 to 0.880615234375" -> http://www.wolframalpha.com/input/?i=|0.5+*+(1+%2B+tanh(2x-1))+-+x|+from+x%3D0+to+0.880615234375 + // and: "|0.5 * (1 + tanh(2x-1)) - 0.880615234375| from x=0.880615234375 to 1" -> http://www.wolframalpha.com/input/?i=+|0.5+*+(1+%2B+tanh(2x-1))+-+0.880615234375|+from+x%3D0.880615234375+to+1 + gainModHB = WEBRTC_SPL_MIN(avgProbSpeechHB, 3607); + + // // original FLOAT code + // //combine gain with low band gain + // if (avg_prob_speech < (float)0.5) { + // gain_time_domain_HB=(float)0.5*gain_mod+(float)0.5*avg_filter_gain; + // } + // else { + // gain_time_domain_HB=(float)0.25*gain_mod+(float)0.75*avg_filter_gain; + // } + + + //combine gain with low band gain + if (avgProbSpeechHB < 2048) + { // 2048 = Q12(0.5) + // the next two lines in float are "gain_time_domain = 0.5 * gain_mod + 0.5 * avg_filter_gain"; Q2(0.5) = 2 equals one left shift + gainTimeDomainHB = (gainModHB << 1) + (avgFilterGainHB >> 1); // Q14 + } else + { + // "gain_time_domain = 0.25 * gain_mod + 0.75 * agv_filter_gain;" + gainTimeDomainHB = (WebRtc_Word16)WEBRTC_SPL_MUL_16_16_RSFT(3, avgFilterGainHB, 2); // 3 = Q2(0.75); Q14 + gainTimeDomainHB += gainModHB; // Q14 + } + //make sure gain is within flooring range + gainTimeDomainHB + = WEBRTC_SPL_SAT(16384, gainTimeDomainHB, (WebRtc_Word16)(inst->denoiseBound)); // 16384 = Q14(1.0) + + + //apply gain + for (i = 0; i < inst->blockLen10ms; i++) + { + outFrameHB[i] + = (WebRtc_Word16)WEBRTC_SPL_MUL_16_16_RSFT(gainTimeDomainHB, inst->dataBufHBFX[i], 14); // Q0 + } + } // end of H band gain computation + + return 0; +} diff --git a/src/modules/audio_processing/ns/main/source/nsx_core.h b/src/modules/audio_processing/ns/main/source/nsx_core.h new file mode 100644 index 0000000..54a236f --- /dev/null +++ b/src/modules/audio_processing/ns/main/source/nsx_core.h @@ -0,0 +1,181 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +#ifndef WEBRTC_MODULES_AUDIO_PROCESSING_NS_MAIN_SOURCE_NSX_CORE_H_ +#define WEBRTC_MODULES_AUDIO_PROCESSING_NS_MAIN_SOURCE_NSX_CORE_H_ + +#include "typedefs.h" +#include "signal_processing_library.h" + +#include "nsx_defines.h" + +#ifdef NS_FILEDEBUG +#include +#endif + +typedef struct NsxInst_t_ +{ + WebRtc_UWord32 fs; + + const WebRtc_Word16* window; + WebRtc_Word16 analysisBuffer[ANAL_BLOCKL_MAX]; + WebRtc_Word16 synthesisBuffer[ANAL_BLOCKL_MAX]; + WebRtc_UWord16 noiseSupFilter[HALF_ANAL_BLOCKL]; + WebRtc_UWord16 overdrive; /* Q8 */ + WebRtc_UWord16 denoiseBound; /* Q14 */ + const WebRtc_Word16* factor2Table; + WebRtc_Word16 noiseEstLogQuantile[SIMULT * HALF_ANAL_BLOCKL]; + WebRtc_Word16 noiseEstDensity[SIMULT * HALF_ANAL_BLOCKL]; + WebRtc_Word16 noiseEstCounter[SIMULT]; + WebRtc_Word16 noiseEstQuantile[HALF_ANAL_BLOCKL]; + + WebRtc_Word16 anaLen; + int anaLen2; + int magnLen; + int aggrMode; + int stages; + int initFlag; + int gainMap; + + WebRtc_Word32 maxLrt; + WebRtc_Word32 minLrt; + WebRtc_Word32 logLrtTimeAvgW32[HALF_ANAL_BLOCKL]; //log lrt factor with time-smoothing in Q8 + WebRtc_Word32 featureLogLrt; + WebRtc_Word32 thresholdLogLrt; + WebRtc_Word16 weightLogLrt; + + WebRtc_UWord32 featureSpecDiff; + WebRtc_UWord32 thresholdSpecDiff; + WebRtc_Word16 weightSpecDiff; + + WebRtc_UWord32 featureSpecFlat; + WebRtc_UWord32 thresholdSpecFlat; + WebRtc_Word16 weightSpecFlat; + + WebRtc_Word32 avgMagnPause[HALF_ANAL_BLOCKL]; //conservative estimate of noise spectrum + WebRtc_UWord32 magnEnergy; + WebRtc_UWord32 sumMagn; + WebRtc_UWord32 curAvgMagnEnergy; + WebRtc_UWord32 timeAvgMagnEnergy; + WebRtc_UWord32 timeAvgMagnEnergyTmp; + + WebRtc_UWord32 whiteNoiseLevel; //initial noise estimate + WebRtc_UWord32 initMagnEst[HALF_ANAL_BLOCKL];//initial magnitude spectrum estimate + WebRtc_Word32 pinkNoiseNumerator; //pink noise parameter: numerator + WebRtc_Word32 pinkNoiseExp; //pink noise parameter: power of freq + int minNorm; //smallest normalization factor + int zeroInputSignal; //zero input signal flag + + WebRtc_UWord32 prevNoiseU32[HALF_ANAL_BLOCKL]; //noise spectrum from previous frame + WebRtc_UWord16 prevMagnU16[HALF_ANAL_BLOCKL]; //magnitude spectrum from previous frame + WebRtc_Word16 priorNonSpeechProb; //prior speech/noise probability // Q14 + + int blockIndex; //frame index counter + int modelUpdate; //parameter for updating or estimating thresholds/weights for prior model + int cntThresUpdate; + + //histograms for parameter estimation + WebRtc_Word16 histLrt[HIST_PAR_EST]; + WebRtc_Word16 histSpecFlat[HIST_PAR_EST]; + WebRtc_Word16 histSpecDiff[HIST_PAR_EST]; + + //quantities for high band estimate + WebRtc_Word16 dataBufHBFX[ANAL_BLOCKL_MAX]; /* Q0 */ + + int qNoise; + int prevQNoise; + int prevQMagn; + int blockLen10ms; + + WebRtc_Word16 real[ANAL_BLOCKL_MAX]; + WebRtc_Word16 imag[ANAL_BLOCKL_MAX]; + WebRtc_Word32 energyIn; + int scaleEnergyIn; + int normData; + +} NsxInst_t; + +#ifdef __cplusplus +extern "C" +{ +#endif + +/**************************************************************************** + * WebRtcNsx_InitCore(...) + * + * This function initializes a noise suppression instance + * + * Input: + * - inst : Instance that should be initialized + * - fs : Sampling frequency + * + * Output: + * - inst : Initialized instance + * + * Return value : 0 - Ok + * -1 - Error + */ +WebRtc_Word32 WebRtcNsx_InitCore(NsxInst_t *inst, WebRtc_UWord32 fs); + +/**************************************************************************** + * WebRtcNsx_set_policy_core(...) + * + * This changes the aggressiveness of the noise suppression method. + * + * Input: + * - inst : Instance that should be initialized + * - mode : 0: Mild (6 dB), 1: Medium (10 dB), 2: Aggressive (15 dB) + * + * Output: + * - NS_inst : Initialized instance + * + * Return value : 0 - Ok + * -1 - Error + */ +int WebRtcNsx_set_policy_core(NsxInst_t *inst, int mode); + +/**************************************************************************** + * WebRtcNsx_ProcessCore + * + * Do noise suppression. + * + * Input: + * - inst : Instance that should be initialized + * - inFrameLow : Input speech frame for lower band + * - inFrameHigh : Input speech frame for higher band + * + * Output: + * - inst : Updated instance + * - outFrameLow : Output speech frame for lower band + * - outFrameHigh : Output speech frame for higher band + * + * Return value : 0 - OK + * -1 - Error + */ +int WebRtcNsx_ProcessCore(NsxInst_t *inst, short *inFrameLow, short *inFrameHigh, + short *outFrameLow, short *outFrameHigh); + +/**************************************************************************** + * Internal functions and variable declarations shared with optimized code. + */ +void WebRtcNsx_UpdateNoiseEstimate(NsxInst_t *inst, int offset); + +void WebRtcNsx_NoiseEstimation(NsxInst_t *inst, WebRtc_UWord16 *magn, WebRtc_UWord32 *noise, + WebRtc_Word16 *qNoise); + +extern const WebRtc_Word16 WebRtcNsx_kLogTable[9]; +extern const WebRtc_Word16 WebRtcNsx_kLogTableFrac[256]; +extern const WebRtc_Word16 WebRtcNsx_kCounterDiv[201]; + +#ifdef __cplusplus +} +#endif + +#endif // WEBRTC_MODULES_AUDIO_PROCESSING_NS_MAIN_SOURCE_NSX_CORE_H_ diff --git a/src/modules/audio_processing/ns/main/source/nsx_core_neon.c b/src/modules/audio_processing/ns/main/source/nsx_core_neon.c new file mode 100644 index 0000000..e0da82c --- /dev/null +++ b/src/modules/audio_processing/ns/main/source/nsx_core_neon.c @@ -0,0 +1,225 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +#if defined(WEBRTC_ARCH_ARM_NEON) && defined(WEBRTC_ANDROID) + +#include "nsx_core.h" +#include + +void WebRtcNsx_NoiseEstimation(NsxInst_t *inst, WebRtc_UWord16 *magn, WebRtc_UWord32 *noise, + WebRtc_Word16 *qNoise) +{ + WebRtc_Word32 numerator; + + WebRtc_Word16 lmagn[HALF_ANAL_BLOCKL], counter, countDiv, countProd, delta, zeros, frac; + WebRtc_Word16 log2, tabind, logval, tmp16, tmp16no1, tmp16no2; + WebRtc_Word16 log2Const = 22713; + WebRtc_Word16 widthFactor = 21845; + + int i, s, offset; + + numerator = FACTOR_Q16; + + tabind = inst->stages - inst->normData; + if (tabind < 0) + { + logval = -WebRtcNsx_kLogTable[-tabind]; + } else + { + logval = WebRtcNsx_kLogTable[tabind]; + } + + // lmagn(i)=log(magn(i))=log(2)*log2(magn(i)) + // magn is in Q(-stages), and the real lmagn values are: + // real_lmagn(i)=log(magn(i)*2^stages)=log(magn(i))+log(2^stages) + // lmagn in Q8 + for (i = 0; i < inst->magnLen; i++) + { + if (magn[i]) + { + zeros = WebRtcSpl_NormU32((WebRtc_UWord32)magn[i]); + frac = (WebRtc_Word16)((((WebRtc_UWord32)magn[i] << zeros) & 0x7FFFFFFF) >> 23); + // log2(magn(i)) + log2 = (WebRtc_Word16)(((31 - zeros) << 8) + WebRtcNsx_kLogTableFrac[frac]); + // log2(magn(i))*log(2) + lmagn[i] = (WebRtc_Word16)WEBRTC_SPL_MUL_16_16_RSFT(log2, log2Const, 15); + // + log(2^stages) + lmagn[i] += logval; + } else + { + lmagn[i] = logval; + } + } + + int16x4_t Q3_16x4 = vdup_n_s16(3); + int16x8_t WIDTHQ8_16x8 = vdupq_n_s16(WIDTH_Q8); + int16x8_t WIDTHFACTOR_16x8 = vdupq_n_s16(widthFactor); + + // Loop over simultaneous estimates + for (s = 0; s < SIMULT; s++) + { + offset = s * inst->magnLen; + + // Get counter values from state + counter = inst->noiseEstCounter[s]; + countDiv = WebRtcNsx_kCounterDiv[counter]; + countProd = (WebRtc_Word16)WEBRTC_SPL_MUL_16_16(counter, countDiv); + + // quant_est(...) + WebRtc_Word16 delta_[8]; + int16x4_t tmp16x4_0; + int16x4_t tmp16x4_1; + int16x4_t countDiv_16x4 = vdup_n_s16(countDiv); + int16x8_t countProd_16x8 = vdupq_n_s16(countProd); + int16x8_t tmp16x8_0 = vdupq_n_s16(countDiv); + int16x8_t prod16x8 = vqrdmulhq_s16(WIDTHFACTOR_16x8, tmp16x8_0); + int16x8_t tmp16x8_1; + int16x8_t tmp16x8_2; + int16x8_t tmp16x8_3; + int16x8_t tmp16x8_4; + int16x8_t tmp16x8_5; + int32x4_t tmp32x4; + + for (i = 0; i < inst->magnLen - 7; i += 8) { + // compute delta + tmp16x8_0 = vdupq_n_s16(FACTOR_Q7); + vst1q_s16(delta_, tmp16x8_0); + int j; + for (j = 0; j < 8; j++) { + if (inst->noiseEstDensity[offset + i + j] > 512) + delta_[j] = WebRtcSpl_DivW32W16ResW16(numerator, + inst->noiseEstDensity[offset + i + j]); + } + + // Update log quantile estimate + + // tmp16 = (WebRtc_Word16)WEBRTC_SPL_MUL_16_16_RSFT(delta, countDiv, 14); + tmp32x4 = vmull_s16(vld1_s16(&delta_[0]), countDiv_16x4); + tmp16x4_1 = vshrn_n_s32(tmp32x4, 14); + tmp32x4 = vmull_s16(vld1_s16(&delta_[4]), countDiv_16x4); + tmp16x4_0 = vshrn_n_s32(tmp32x4, 14); + tmp16x8_0 = vcombine_s16(tmp16x4_1, tmp16x4_0); // Keep for several lines. + + // prepare for the "if" branch + // tmp16 += 2; + // tmp16_1 = (Word16)(tmp16>>2); + tmp16x8_1 = vrshrq_n_s16(tmp16x8_0, 2); + + // inst->noiseEstLogQuantile[offset+i] + tmp16_1; + tmp16x8_2 = vld1q_s16(&inst->noiseEstLogQuantile[offset + i]); // Keep + tmp16x8_1 = vaddq_s16(tmp16x8_2, tmp16x8_1); // Keep for several lines + + // Prepare for the "else" branch + // tmp16 += 1; + // tmp16_1 = (Word16)(tmp16>>1); + tmp16x8_0 = vrshrq_n_s16(tmp16x8_0, 1); + + // tmp16_2 = (Word16)WEBRTC_SPL_MUL_16_16_RSFT(tmp16_1,3,1); + tmp32x4 = vmull_s16(vget_low_s16(tmp16x8_0), Q3_16x4); + tmp16x4_1 = vshrn_n_s32(tmp32x4, 1); + + // tmp16_2 = (Word16)WEBRTC_SPL_MUL_16_16_RSFT(tmp16_1,3,1); + tmp32x4 = vmull_s16(vget_high_s16(tmp16x8_0), Q3_16x4); + tmp16x4_0 = vshrn_n_s32(tmp32x4, 1); + + // inst->noiseEstLogQuantile[offset + i] - tmp16_2; + tmp16x8_0 = vcombine_s16(tmp16x4_1, tmp16x4_0); // keep + tmp16x8_0 = vsubq_s16(tmp16x8_2, tmp16x8_0); + + // Do the if-else branches: + tmp16x8_3 = vld1q_s16(&lmagn[i]); // keep for several lines + tmp16x8_5 = vsubq_s16(tmp16x8_3, tmp16x8_2); + __asm__("vcgt.s16 %q0, %q1, #0"::"w"(tmp16x8_4), "w"(tmp16x8_5)); + __asm__("vbit %q0, %q1, %q2"::"w"(tmp16x8_2), "w"(tmp16x8_1), "w"(tmp16x8_4)); + __asm__("vbif %q0, %q1, %q2"::"w"(tmp16x8_2), "w"(tmp16x8_0), "w"(tmp16x8_4)); + vst1q_s16(&inst->noiseEstLogQuantile[offset + i], tmp16x8_2); + + // Update density estimate + // tmp16_1 + tmp16_2 + tmp16x8_1 = vld1q_s16(&inst->noiseEstDensity[offset + i]); + tmp16x8_0 = vqrdmulhq_s16(tmp16x8_1, countProd_16x8); + tmp16x8_0 = vaddq_s16(tmp16x8_0, prod16x8); + + // lmagn[i] - inst->noiseEstLogQuantile[offset + i] + tmp16x8_3 = vsubq_s16(tmp16x8_3, tmp16x8_2); + tmp16x8_3 = vabsq_s16(tmp16x8_3); + tmp16x8_4 = vcgtq_s16(WIDTHQ8_16x8, tmp16x8_3); + __asm__("vbit %q0, %q1, %q2"::"w"(tmp16x8_1), "w"(tmp16x8_0), "w"(tmp16x8_4)); + vst1q_s16(&inst->noiseEstDensity[offset + i], tmp16x8_1); + } // End loop over magnitude spectrum + + for (; i < inst->magnLen; i++) + { + // compute delta + if (inst->noiseEstDensity[offset + i] > 512) + { + delta = WebRtcSpl_DivW32W16ResW16(numerator, + inst->noiseEstDensity[offset + i]); + } else + { + delta = FACTOR_Q7; + } + + // update log quantile estimate + tmp16 = (WebRtc_Word16)WEBRTC_SPL_MUL_16_16_RSFT(delta, countDiv, 14); + if (lmagn[i] > inst->noiseEstLogQuantile[offset + i]) + { + // +=QUANTILE*delta/(inst->counter[s]+1) QUANTILE=0.25, =1 in Q2 + // CounterDiv=1/inst->counter[s] in Q15 + tmp16 += 2; + tmp16no1 = WEBRTC_SPL_RSHIFT_W16(tmp16, 2); + inst->noiseEstLogQuantile[offset + i] += tmp16no1; + } else + { + tmp16 += 1; + tmp16no1 = WEBRTC_SPL_RSHIFT_W16(tmp16, 1); + // *(1-QUANTILE), in Q2 QUANTILE=0.25, 1-0.25=0.75=3 in Q2 + tmp16no2 = (WebRtc_Word16)WEBRTC_SPL_MUL_16_16_RSFT(tmp16no1, 3, 1); + inst->noiseEstLogQuantile[offset + i] -= tmp16no2; + } + + // update density estimate + if (WEBRTC_SPL_ABS_W16(lmagn[i] - inst->noiseEstLogQuantile[offset + i]) + < WIDTH_Q8) + { + tmp16no1 = (WebRtc_Word16)WEBRTC_SPL_MUL_16_16_RSFT_WITH_ROUND( + inst->noiseEstDensity[offset + i], countProd, 15); + tmp16no2 = (WebRtc_Word16)WEBRTC_SPL_MUL_16_16_RSFT_WITH_ROUND(widthFactor, + countDiv, 15); + inst->noiseEstDensity[offset + i] = tmp16no1 + tmp16no2; + } + } // end loop over magnitude spectrum + + if (counter >= END_STARTUP_LONG) + { + inst->noiseEstCounter[s] = 0; + if (inst->blockIndex >= END_STARTUP_LONG) + { + WebRtcNsx_UpdateNoiseEstimate(inst, offset); + } + } + inst->noiseEstCounter[s]++; + + } // end loop over simultaneous estimates + + // Sequentially update the noise during startup + if (inst->blockIndex < END_STARTUP_LONG) + { + WebRtcNsx_UpdateNoiseEstimate(inst, offset); + } + + for (i = 0; i < inst->magnLen; i++) + { + noise[i] = (WebRtc_UWord32)(inst->noiseEstQuantile[i]); // Q(qNoise) + } + (*qNoise) = (WebRtc_Word16)inst->qNoise; +} + +#endif // defined(WEBRTC_ARCH_ARM_NEON) && defined(WEBRTC_ANDROID) diff --git a/src/modules/audio_processing/ns/main/source/nsx_defines.h b/src/modules/audio_processing/ns/main/source/nsx_defines.h new file mode 100644 index 0000000..58796b9 --- /dev/null +++ b/src/modules/audio_processing/ns/main/source/nsx_defines.h @@ -0,0 +1,58 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +#ifndef WEBRTC_MODULES_AUDIO_PROCESSING_NS_MAIN_SOURCE_NSX_DEFINES_H_ +#define WEBRTC_MODULES_AUDIO_PROCESSING_NS_MAIN_SOURCE_NSX_DEFINES_H_ + +#define ANAL_BLOCKL_MAX 256 // max analysis block length +#define HALF_ANAL_BLOCKL 129 // half max analysis block length + 1 +#define SIMULT 3 +#define END_STARTUP_LONG 200 +#define END_STARTUP_SHORT 50 +#define FACTOR_Q16 (WebRtc_Word32)2621440 // 40 in Q16 +#define FACTOR_Q7 (WebRtc_Word16)5120 // 40 in Q7 +#define WIDTH_Q8 3 // 0.01 in Q8 (or 25 ) +//PARAMETERS FOR NEW METHOD +#define DD_PR_SNR_Q11 2007 // ~= Q11(0.98) DD update of prior SNR +#define ONE_MINUS_DD_PR_SNR_Q11 41 // DD update of prior SNR +#define SPECT_FLAT_TAVG_Q14 4915 // (0.30) tavg parameter for spectral flatness measure +#define SPECT_DIFF_TAVG_Q8 77 // (0.30) tavg parameter for spectral flatness measure +#define PRIOR_UPDATE_Q14 1638 // Q14(0.1) update parameter of prior model +#define NOISE_UPDATE_Q8 26 // 26 ~= Q8(0.1) update parameter for noise +// probability threshold for noise state in speech/noise likelihood +#define ONE_MINUS_PROB_RANGE_Q8 205 // 205 ~= Q8(0.8) +#define HIST_PAR_EST 1000 // histogram size for estimation of parameters +//FEATURE EXTRACTION CONFIG +//bin size of histogram +#define BIN_SIZE_LRT 10 +//scale parameters: multiply dominant peaks of the histograms by scale factor to obtain +// thresholds for prior model +#define FACTOR_1_LRT_DIFF 6 //for LRT and spectral difference (5 times bigger) +//for spectral_flatness: used when noise is flatter than speech (10 times bigger) +#define FACTOR_2_FLAT_Q10 922 +//peak limit for spectral flatness (varies between 0 and 1) +#define THRES_PEAK_FLAT 24 // * 2 * BIN_SIZE_FLAT_FX +//limit on spacing of two highest peaks in histogram: spacing determined by bin size +#define LIM_PEAK_SPACE_FLAT_DIFF 4 // * 2 * BIN_SIZE_DIFF_FX +//limit on relevance of second peak: +#define LIM_PEAK_WEIGHT_FLAT_DIFF 2 +#define THRES_FLUCT_LRT 10240 //=20 * inst->modelUpdate; fluctuation limit of LRT feat. +//limit on the max and min values for the feature thresholds +#define MAX_FLAT_Q10 38912 // * 2 * BIN_SIZE_FLAT_FX +#define MIN_FLAT_Q10 4096 // * 2 * BIN_SIZE_FLAT_FX +#define MAX_DIFF 100 // * 2 * BIN_SIZE_DIFF_FX +#define MIN_DIFF 16 // * 2 * BIN_SIZE_DIFF_FX +//criteria of weight of histogram peak to accept/reject feature +#define THRES_WEIGHT_FLAT_DIFF 154//(int)(0.3*(inst->modelUpdate)) for flatness and difference +// +#define STAT_UPDATES 9 // Update every 512 = 1 << 9 block +#define ONE_MINUS_GAMMA_PAUSE_Q8 13 // ~= Q8(0.05) update for conservative noise estimate +#define GAMMA_NOISE_TRANS_AND_SPEECH_Q8 3 // ~= Q8(0.01) update for transition and noise region +#endif // WEBRTC_MODULES_AUDIO_PROCESSING_NS_MAIN_SOURCE_NSX_DEFINES_H_ diff --git a/src/modules/audio_processing/ns/main/source/windows_private.h b/src/modules/audio_processing/ns/main/source/windows_private.h new file mode 100644 index 0000000..8f9006e --- /dev/null +++ b/src/modules/audio_processing/ns/main/source/windows_private.h @@ -0,0 +1,573 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +#ifndef WEBRTC_MODULES_AUDIO_PROCESSING_NS_MAIN_SOURCE_WINDOWS_PRIVATE_H_ +#define WEBRTC_MODULES_AUDIO_PROCESSING_NS_MAIN_SOURCE_WINDOWS_PRIVATE_H_ + +// Hanning window for 4ms 16kHz +static const float kHanning64w128[128] = { +0.00000000000000f, 0.02454122852291f, 0.04906767432742f, +0.07356456359967f, 0.09801714032956f, 0.12241067519922f, +0.14673047445536f, 0.17096188876030f, 0.19509032201613f, +0.21910124015687f, 0.24298017990326f, 0.26671275747490f, +0.29028467725446f, 0.31368174039889f, 0.33688985339222f, +0.35989503653499f, 0.38268343236509f, 0.40524131400499f, +0.42755509343028f, 0.44961132965461f, 0.47139673682600f, +0.49289819222978f, 0.51410274419322f, 0.53499761988710f, +0.55557023301960f, 0.57580819141785f, 0.59569930449243f, +0.61523159058063f, 0.63439328416365f, 0.65317284295378f, +0.67155895484702f, 0.68954054473707f, 0.70710678118655f, +0.72424708295147f, 0.74095112535496f, 0.75720884650648f, +0.77301045336274f, 0.78834642762661f, 0.80320753148064f, +0.81758481315158f, 0.83146961230255f, 0.84485356524971f, +0.85772861000027f, 0.87008699110871f, 0.88192126434835f, +0.89322430119552f, 0.90398929312344f, 0.91420975570353f, +0.92387953251129f, 0.93299279883474f, 0.94154406518302f, +0.94952818059304f, 0.95694033573221f, 0.96377606579544f, +0.97003125319454f, 0.97570213003853f, 0.98078528040323f, +0.98527764238894f, 0.98917650996478f, 0.99247953459871f, +0.99518472667220f, 0.99729045667869f, 0.99879545620517f, +0.99969881869620f, 1.00000000000000f, +0.99969881869620f, 0.99879545620517f, 0.99729045667869f, +0.99518472667220f, 0.99247953459871f, 0.98917650996478f, +0.98527764238894f, 0.98078528040323f, 0.97570213003853f, +0.97003125319454f, 0.96377606579544f, 0.95694033573221f, +0.94952818059304f, 0.94154406518302f, 0.93299279883474f, +0.92387953251129f, 0.91420975570353f, 0.90398929312344f, +0.89322430119552f, 0.88192126434835f, 0.87008699110871f, +0.85772861000027f, 0.84485356524971f, 0.83146961230255f, +0.81758481315158f, 0.80320753148064f, 0.78834642762661f, +0.77301045336274f, 0.75720884650648f, 0.74095112535496f, +0.72424708295147f, 0.70710678118655f, 0.68954054473707f, +0.67155895484702f, 0.65317284295378f, 0.63439328416365f, +0.61523159058063f, 0.59569930449243f, 0.57580819141785f, +0.55557023301960f, 0.53499761988710f, 0.51410274419322f, +0.49289819222978f, 0.47139673682600f, 0.44961132965461f, +0.42755509343028f, 0.40524131400499f, 0.38268343236509f, +0.35989503653499f, 0.33688985339222f, 0.31368174039889f, +0.29028467725446f, 0.26671275747490f, 0.24298017990326f, +0.21910124015687f, 0.19509032201613f, 0.17096188876030f, +0.14673047445536f, 0.12241067519922f, 0.09801714032956f, +0.07356456359967f, 0.04906767432742f, 0.02454122852291f +}; + + + +// hybrib Hanning & flat window +static const float kBlocks80w128[128] = { +(float)0.00000000, (float)0.03271908, (float)0.06540313, (float)0.09801714, (float)0.13052619, +(float)0.16289547, (float)0.19509032, (float)0.22707626, (float)0.25881905, (float)0.29028468, +(float)0.32143947, (float)0.35225005, (float)0.38268343, (float)0.41270703, (float)0.44228869, +(float)0.47139674, (float)0.50000000, (float)0.52806785, (float)0.55557023, (float)0.58247770, +(float)0.60876143, (float)0.63439328, (float)0.65934582, (float)0.68359230, (float)0.70710678, +(float)0.72986407, (float)0.75183981, (float)0.77301045, (float)0.79335334, (float)0.81284668, +(float)0.83146961, (float)0.84920218, (float)0.86602540, (float)0.88192126, (float)0.89687274, +(float)0.91086382, (float)0.92387953, (float)0.93590593, (float)0.94693013, (float)0.95694034, +(float)0.96592583, (float)0.97387698, (float)0.98078528, (float)0.98664333, (float)0.99144486, +(float)0.99518473, (float)0.99785892, (float)0.99946459, (float)1.00000000, (float)1.00000000, +(float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, +(float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, +(float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, +(float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, +(float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, +(float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, +(float)1.00000000, (float)0.99946459, (float)0.99785892, (float)0.99518473, (float)0.99144486, +(float)0.98664333, (float)0.98078528, (float)0.97387698, (float)0.96592583, (float)0.95694034, +(float)0.94693013, (float)0.93590593, (float)0.92387953, (float)0.91086382, (float)0.89687274, +(float)0.88192126, (float)0.86602540, (float)0.84920218, (float)0.83146961, (float)0.81284668, +(float)0.79335334, (float)0.77301045, (float)0.75183981, (float)0.72986407, (float)0.70710678, +(float)0.68359230, (float)0.65934582, (float)0.63439328, (float)0.60876143, (float)0.58247770, +(float)0.55557023, (float)0.52806785, (float)0.50000000, (float)0.47139674, (float)0.44228869, +(float)0.41270703, (float)0.38268343, (float)0.35225005, (float)0.32143947, (float)0.29028468, +(float)0.25881905, (float)0.22707626, (float)0.19509032, (float)0.16289547, (float)0.13052619, +(float)0.09801714, (float)0.06540313, (float)0.03271908 +}; + +// hybrib Hanning & flat window +static const float kBlocks160w256[256] = { +(float)0.00000000, (float)0.01636173, (float)0.03271908, (float)0.04906767, (float)0.06540313, +(float)0.08172107, (float)0.09801714, (float)0.11428696, (float)0.13052619, (float)0.14673047, +(float)0.16289547, (float)0.17901686, (float)0.19509032, (float)0.21111155, (float)0.22707626, +(float)0.24298018, (float)0.25881905, (float)0.27458862, (float)0.29028468, (float)0.30590302, +(float)0.32143947, (float)0.33688985, (float)0.35225005, (float)0.36751594, (float)0.38268343, +(float)0.39774847, (float)0.41270703, (float)0.42755509, (float)0.44228869, (float)0.45690388, +(float)0.47139674, (float)0.48576339, (float)0.50000000, (float)0.51410274, (float)0.52806785, +(float)0.54189158, (float)0.55557023, (float)0.56910015, (float)0.58247770, (float)0.59569930, +(float)0.60876143, (float)0.62166057, (float)0.63439328, (float)0.64695615, (float)0.65934582, +(float)0.67155895, (float)0.68359230, (float)0.69544264, (float)0.70710678, (float)0.71858162, +(float)0.72986407, (float)0.74095113, (float)0.75183981, (float)0.76252720, (float)0.77301045, +(float)0.78328675, (float)0.79335334, (float)0.80320753, (float)0.81284668, (float)0.82226822, +(float)0.83146961, (float)0.84044840, (float)0.84920218, (float)0.85772861, (float)0.86602540, +(float)0.87409034, (float)0.88192126, (float)0.88951608, (float)0.89687274, (float)0.90398929, +(float)0.91086382, (float)0.91749450, (float)0.92387953, (float)0.93001722, (float)0.93590593, +(float)0.94154407, (float)0.94693013, (float)0.95206268, (float)0.95694034, (float)0.96156180, +(float)0.96592583, (float)0.97003125, (float)0.97387698, (float)0.97746197, (float)0.98078528, +(float)0.98384601, (float)0.98664333, (float)0.98917651, (float)0.99144486, (float)0.99344778, +(float)0.99518473, (float)0.99665524, (float)0.99785892, (float)0.99879546, (float)0.99946459, +(float)0.99986614, (float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, +(float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, +(float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, +(float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, +(float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, +(float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, +(float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, +(float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, +(float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, +(float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, +(float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, +(float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, +(float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, +(float)1.00000000, (float)0.99986614, (float)0.99946459, (float)0.99879546, (float)0.99785892, +(float)0.99665524, (float)0.99518473, (float)0.99344778, (float)0.99144486, (float)0.98917651, +(float)0.98664333, (float)0.98384601, (float)0.98078528, (float)0.97746197, (float)0.97387698, +(float)0.97003125, (float)0.96592583, (float)0.96156180, (float)0.95694034, (float)0.95206268, +(float)0.94693013, (float)0.94154407, (float)0.93590593, (float)0.93001722, (float)0.92387953, +(float)0.91749450, (float)0.91086382, (float)0.90398929, (float)0.89687274, (float)0.88951608, +(float)0.88192126, (float)0.87409034, (float)0.86602540, (float)0.85772861, (float)0.84920218, +(float)0.84044840, (float)0.83146961, (float)0.82226822, (float)0.81284668, (float)0.80320753, +(float)0.79335334, (float)0.78328675, (float)0.77301045, (float)0.76252720, (float)0.75183981, +(float)0.74095113, (float)0.72986407, (float)0.71858162, (float)0.70710678, (float)0.69544264, +(float)0.68359230, (float)0.67155895, (float)0.65934582, (float)0.64695615, (float)0.63439328, +(float)0.62166057, (float)0.60876143, (float)0.59569930, (float)0.58247770, (float)0.56910015, +(float)0.55557023, (float)0.54189158, (float)0.52806785, (float)0.51410274, (float)0.50000000, +(float)0.48576339, (float)0.47139674, (float)0.45690388, (float)0.44228869, (float)0.42755509, +(float)0.41270703, (float)0.39774847, (float)0.38268343, (float)0.36751594, (float)0.35225005, +(float)0.33688985, (float)0.32143947, (float)0.30590302, (float)0.29028468, (float)0.27458862, +(float)0.25881905, (float)0.24298018, (float)0.22707626, (float)0.21111155, (float)0.19509032, +(float)0.17901686, (float)0.16289547, (float)0.14673047, (float)0.13052619, (float)0.11428696, +(float)0.09801714, (float)0.08172107, (float)0.06540313, (float)0.04906767, (float)0.03271908, +(float)0.01636173 +}; + +// hybrib Hanning & flat window: for 20ms +static const float kBlocks320w512[512] = { +(float)0.00000000, (float)0.00818114, (float)0.01636173, (float)0.02454123, (float)0.03271908, +(float)0.04089475, (float)0.04906767, (float)0.05723732, (float)0.06540313, (float)0.07356456, +(float)0.08172107, (float)0.08987211, (float)0.09801714, (float)0.10615561, (float)0.11428696, +(float)0.12241068, (float)0.13052619, (float)0.13863297, (float)0.14673047, (float)0.15481816, +(float)0.16289547, (float)0.17096189, (float)0.17901686, (float)0.18705985, (float)0.19509032, +(float)0.20310773, (float)0.21111155, (float)0.21910124, (float)0.22707626, (float)0.23503609, +(float)0.24298018, (float)0.25090801, (float)0.25881905, (float)0.26671276, (float)0.27458862, +(float)0.28244610, (float)0.29028468, (float)0.29810383, (float)0.30590302, (float)0.31368174, +(float)0.32143947, (float)0.32917568, (float)0.33688985, (float)0.34458148, (float)0.35225005, +(float)0.35989504, (float)0.36751594, (float)0.37511224, (float)0.38268343, (float)0.39022901, +(float)0.39774847, (float)0.40524131, (float)0.41270703, (float)0.42014512, (float)0.42755509, +(float)0.43493645, (float)0.44228869, (float)0.44961133, (float)0.45690388, (float)0.46416584, +(float)0.47139674, (float)0.47859608, (float)0.48576339, (float)0.49289819, (float)0.50000000, +(float)0.50706834, (float)0.51410274, (float)0.52110274, (float)0.52806785, (float)0.53499762, +(float)0.54189158, (float)0.54874927, (float)0.55557023, (float)0.56235401, (float)0.56910015, +(float)0.57580819, (float)0.58247770, (float)0.58910822, (float)0.59569930, (float)0.60225052, +(float)0.60876143, (float)0.61523159, (float)0.62166057, (float)0.62804795, (float)0.63439328, +(float)0.64069616, (float)0.64695615, (float)0.65317284, (float)0.65934582, (float)0.66547466, +(float)0.67155895, (float)0.67759830, (float)0.68359230, (float)0.68954054, (float)0.69544264, +(float)0.70129818, (float)0.70710678, (float)0.71286806, (float)0.71858162, (float)0.72424708, +(float)0.72986407, (float)0.73543221, (float)0.74095113, (float)0.74642045, (float)0.75183981, +(float)0.75720885, (float)0.76252720, (float)0.76779452, (float)0.77301045, (float)0.77817464, +(float)0.78328675, (float)0.78834643, (float)0.79335334, (float)0.79830715, (float)0.80320753, +(float)0.80805415, (float)0.81284668, (float)0.81758481, (float)0.82226822, (float)0.82689659, +(float)0.83146961, (float)0.83598698, (float)0.84044840, (float)0.84485357, (float)0.84920218, +(float)0.85349396, (float)0.85772861, (float)0.86190585, (float)0.86602540, (float)0.87008699, +(float)0.87409034, (float)0.87803519, (float)0.88192126, (float)0.88574831, (float)0.88951608, +(float)0.89322430, (float)0.89687274, (float)0.90046115, (float)0.90398929, (float)0.90745693, +(float)0.91086382, (float)0.91420976, (float)0.91749450, (float)0.92071783, (float)0.92387953, +(float)0.92697940, (float)0.93001722, (float)0.93299280, (float)0.93590593, (float)0.93875641, +(float)0.94154407, (float)0.94426870, (float)0.94693013, (float)0.94952818, (float)0.95206268, +(float)0.95453345, (float)0.95694034, (float)0.95928317, (float)0.96156180, (float)0.96377607, +(float)0.96592583, (float)0.96801094, (float)0.97003125, (float)0.97198664, (float)0.97387698, +(float)0.97570213, (float)0.97746197, (float)0.97915640, (float)0.98078528, (float)0.98234852, +(float)0.98384601, (float)0.98527764, (float)0.98664333, (float)0.98794298, (float)0.98917651, +(float)0.99034383, (float)0.99144486, (float)0.99247953, (float)0.99344778, (float)0.99434953, +(float)0.99518473, (float)0.99595331, (float)0.99665524, (float)0.99729046, (float)0.99785892, +(float)0.99836060, (float)0.99879546, (float)0.99916346, (float)0.99946459, (float)0.99969882, +(float)0.99986614, (float)0.99996653, (float)1.00000000, (float)1.00000000, (float)1.00000000, +(float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, +(float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, +(float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, +(float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, +(float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, +(float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, +(float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, +(float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, +(float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, +(float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, +(float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, +(float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, +(float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, +(float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, +(float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, +(float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, +(float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, +(float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, +(float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, +(float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, +(float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, +(float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, +(float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, +(float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, +(float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, (float)1.00000000, +(float)1.00000000, (float)0.99996653, (float)0.99986614, (float)0.99969882, (float)0.99946459, +(float)0.99916346, (float)0.99879546, (float)0.99836060, (float)0.99785892, (float)0.99729046, +(float)0.99665524, (float)0.99595331, (float)0.99518473, (float)0.99434953, (float)0.99344778, +(float)0.99247953, (float)0.99144486, (float)0.99034383, (float)0.98917651, (float)0.98794298, +(float)0.98664333, (float)0.98527764, (float)0.98384601, (float)0.98234852, (float)0.98078528, +(float)0.97915640, (float)0.97746197, (float)0.97570213, (float)0.97387698, (float)0.97198664, +(float)0.97003125, (float)0.96801094, (float)0.96592583, (float)0.96377607, (float)0.96156180, +(float)0.95928317, (float)0.95694034, (float)0.95453345, (float)0.95206268, (float)0.94952818, +(float)0.94693013, (float)0.94426870, (float)0.94154407, (float)0.93875641, (float)0.93590593, +(float)0.93299280, (float)0.93001722, (float)0.92697940, (float)0.92387953, (float)0.92071783, +(float)0.91749450, (float)0.91420976, (float)0.91086382, (float)0.90745693, (float)0.90398929, +(float)0.90046115, (float)0.89687274, (float)0.89322430, (float)0.88951608, (float)0.88574831, +(float)0.88192126, (float)0.87803519, (float)0.87409034, (float)0.87008699, (float)0.86602540, +(float)0.86190585, (float)0.85772861, (float)0.85349396, (float)0.84920218, (float)0.84485357, +(float)0.84044840, (float)0.83598698, (float)0.83146961, (float)0.82689659, (float)0.82226822, +(float)0.81758481, (float)0.81284668, (float)0.80805415, (float)0.80320753, (float)0.79830715, +(float)0.79335334, (float)0.78834643, (float)0.78328675, (float)0.77817464, (float)0.77301045, +(float)0.76779452, (float)0.76252720, (float)0.75720885, (float)0.75183981, (float)0.74642045, +(float)0.74095113, (float)0.73543221, (float)0.72986407, (float)0.72424708, (float)0.71858162, +(float)0.71286806, (float)0.70710678, (float)0.70129818, (float)0.69544264, (float)0.68954054, +(float)0.68359230, (float)0.67759830, (float)0.67155895, (float)0.66547466, (float)0.65934582, +(float)0.65317284, (float)0.64695615, (float)0.64069616, (float)0.63439328, (float)0.62804795, +(float)0.62166057, (float)0.61523159, (float)0.60876143, (float)0.60225052, (float)0.59569930, +(float)0.58910822, (float)0.58247770, (float)0.57580819, (float)0.56910015, (float)0.56235401, +(float)0.55557023, (float)0.54874927, (float)0.54189158, (float)0.53499762, (float)0.52806785, +(float)0.52110274, (float)0.51410274, (float)0.50706834, (float)0.50000000, (float)0.49289819, +(float)0.48576339, (float)0.47859608, (float)0.47139674, (float)0.46416584, (float)0.45690388, +(float)0.44961133, (float)0.44228869, (float)0.43493645, (float)0.42755509, (float)0.42014512, +(float)0.41270703, (float)0.40524131, (float)0.39774847, (float)0.39022901, (float)0.38268343, +(float)0.37511224, (float)0.36751594, (float)0.35989504, (float)0.35225005, (float)0.34458148, +(float)0.33688985, (float)0.32917568, (float)0.32143947, (float)0.31368174, (float)0.30590302, +(float)0.29810383, (float)0.29028468, (float)0.28244610, (float)0.27458862, (float)0.26671276, +(float)0.25881905, (float)0.25090801, (float)0.24298018, (float)0.23503609, (float)0.22707626, +(float)0.21910124, (float)0.21111155, (float)0.20310773, (float)0.19509032, (float)0.18705985, +(float)0.17901686, (float)0.17096189, (float)0.16289547, (float)0.15481816, (float)0.14673047, +(float)0.13863297, (float)0.13052619, (float)0.12241068, (float)0.11428696, (float)0.10615561, +(float)0.09801714, (float)0.08987211, (float)0.08172107, (float)0.07356456, (float)0.06540313, +(float)0.05723732, (float)0.04906767, (float)0.04089475, (float)0.03271908, (float)0.02454123, +(float)0.01636173, (float)0.00818114 +}; + + +// Hanning window: for 15ms at 16kHz with symmetric zeros +static const float kBlocks240w512[512] = { +(float)0.00000000, (float)0.00000000, (float)0.00000000, (float)0.00000000, (float)0.00000000, +(float)0.00000000, (float)0.00000000, (float)0.00000000, (float)0.00000000, (float)0.00000000, +(float)0.00000000, (float)0.00000000, (float)0.00000000, (float)0.00000000, (float)0.00000000, +(float)0.00000000, (float)0.00000000, (float)0.00654494, (float)0.01308960, (float)0.01963369, +(float)0.02617695, (float)0.03271908, (float)0.03925982, (float)0.04579887, (float)0.05233596, +(float)0.05887080, (float)0.06540313, (float)0.07193266, (float)0.07845910, (float)0.08498218, +(float)0.09150162, (float)0.09801714, (float)0.10452846, (float)0.11103531, (float)0.11753740, +(float)0.12403446, (float)0.13052620, (float)0.13701233, (float)0.14349262, (float)0.14996676, +(float)0.15643448, (float)0.16289547, (float)0.16934951, (float)0.17579629, (float)0.18223552, +(float)0.18866697, (float)0.19509032, (float)0.20150533, (float)0.20791170, (float)0.21430916, +(float)0.22069745, (float)0.22707628, (float)0.23344538, (float)0.23980446, (float)0.24615330, +(float)0.25249159, (float)0.25881904, (float)0.26513544, (float)0.27144045, (float)0.27773386, +(float)0.28401536, (float)0.29028466, (float)0.29654160, (float)0.30278578, (float)0.30901700, +(float)0.31523499, (float)0.32143945, (float)0.32763019, (float)0.33380687, (float)0.33996925, +(float)0.34611708, (float)0.35225007, (float)0.35836795, (float)0.36447051, (float)0.37055743, +(float)0.37662852, (float)0.38268346, (float)0.38872197, (float)0.39474389, (float)0.40074885, +(float)0.40673664, (float)0.41270703, (float)0.41865975, (float)0.42459452, (float)0.43051112, +(float)0.43640924, (float)0.44228873, (float)0.44814920, (float)0.45399052, (float)0.45981237, +(float)0.46561453, (float)0.47139674, (float)0.47715878, (float)0.48290035, (float)0.48862126, +(float)0.49432120, (float)0.50000000, (float)0.50565743, (float)0.51129311, (float)0.51690692, +(float)0.52249855, (float)0.52806789, (float)0.53361452, (float)0.53913832, (float)0.54463905, +(float)0.55011642, (float)0.55557024, (float)0.56100029, (float)0.56640625, (float)0.57178795, +(float)0.57714522, (float)0.58247769, (float)0.58778524, (float)0.59306765, (float)0.59832460, +(float)0.60355598, (float)0.60876143, (float)0.61394083, (float)0.61909395, (float)0.62422055, +(float)0.62932038, (float)0.63439333, (float)0.63943899, (float)0.64445734, (float)0.64944810, +(float)0.65441096, (float)0.65934587, (float)0.66425246, (float)0.66913062, (float)0.67398012, +(float)0.67880076, (float)0.68359232, (float)0.68835455, (float)0.69308740, (float)0.69779050, +(float)0.70246369, (float)0.70710677, (float)0.71171963, (float)0.71630198, (float)0.72085363, +(float)0.72537440, (float)0.72986406, (float)0.73432255, (float)0.73874950, (float)0.74314487, +(float)0.74750835, (float)0.75183982, (float)0.75613910, (float)0.76040596, (float)0.76464027, +(float)0.76884186, (float)0.77301043, (float)0.77714598, (float)0.78124821, (float)0.78531694, +(float)0.78935206, (float)0.79335338, (float)0.79732066, (float)0.80125386, (float)0.80515265, +(float)0.80901700, (float)0.81284672, (float)0.81664157, (float)0.82040149, (float)0.82412618, +(float)0.82781565, (float)0.83146966, (float)0.83508795, (float)0.83867061, (float)0.84221727, +(float)0.84572780, (float)0.84920216, (float)0.85264021, (float)0.85604161, (float)0.85940641, +(float)0.86273444, (float)0.86602545, (float)0.86927933, (float)0.87249607, (float)0.87567532, +(float)0.87881714, (float)0.88192129, (float)0.88498765, (float)0.88801610, (float)0.89100653, +(float)0.89395881, (float)0.89687276, (float)0.89974827, (float)0.90258533, (float)0.90538365, +(float)0.90814316, (float)0.91086388, (float)0.91354549, (float)0.91618794, (float)0.91879123, +(float)0.92135513, (float)0.92387950, (float)0.92636442, (float)0.92880958, (float)0.93121493, +(float)0.93358046, (float)0.93590593, (float)0.93819135, (float)0.94043654, (float)0.94264150, +(float)0.94480604, (float)0.94693011, (float)0.94901365, (float)0.95105654, (float)0.95305866, +(float)0.95501995, (float)0.95694035, (float)0.95881975, (float)0.96065807, (float)0.96245527, +(float)0.96421117, (float)0.96592581, (float)0.96759909, (float)0.96923089, (float)0.97082120, +(float)0.97236991, (float)0.97387701, (float)0.97534233, (float)0.97676587, (float)0.97814763, +(float)0.97948742, (float)0.98078531, (float)0.98204112, (float)0.98325491, (float)0.98442656, +(float)0.98555607, (float)0.98664331, (float)0.98768836, (float)0.98869103, (float)0.98965138, +(float)0.99056935, (float)0.99144489, (float)0.99227792, (float)0.99306846, (float)0.99381649, +(float)0.99452192, (float)0.99518472, (float)0.99580491, (float)0.99638247, (float)0.99691731, +(float)0.99740952, (float)0.99785894, (float)0.99826562, (float)0.99862951, (float)0.99895066, +(float)0.99922901, (float)0.99946457, (float)0.99965733, (float)0.99980724, (float)0.99991435, +(float)0.99997860, (float)1.00000000, (float)0.99997860, (float)0.99991435, (float)0.99980724, +(float)0.99965733, (float)0.99946457, (float)0.99922901, (float)0.99895066, (float)0.99862951, +(float)0.99826562, (float)0.99785894, (float)0.99740946, (float)0.99691731, (float)0.99638247, +(float)0.99580491, (float)0.99518472, (float)0.99452192, (float)0.99381644, (float)0.99306846, +(float)0.99227792, (float)0.99144489, (float)0.99056935, (float)0.98965138, (float)0.98869103, +(float)0.98768836, (float)0.98664331, (float)0.98555607, (float)0.98442656, (float)0.98325491, +(float)0.98204112, (float)0.98078525, (float)0.97948742, (float)0.97814757, (float)0.97676587, +(float)0.97534227, (float)0.97387695, (float)0.97236991, (float)0.97082120, (float)0.96923089, +(float)0.96759909, (float)0.96592581, (float)0.96421117, (float)0.96245521, (float)0.96065807, +(float)0.95881969, (float)0.95694029, (float)0.95501995, (float)0.95305860, (float)0.95105648, +(float)0.94901365, (float)0.94693011, (float)0.94480604, (float)0.94264150, (float)0.94043654, +(float)0.93819129, (float)0.93590593, (float)0.93358046, (float)0.93121493, (float)0.92880952, +(float)0.92636436, (float)0.92387950, (float)0.92135507, (float)0.91879123, (float)0.91618794, +(float)0.91354543, (float)0.91086382, (float)0.90814310, (float)0.90538365, (float)0.90258527, +(float)0.89974827, (float)0.89687276, (float)0.89395875, (float)0.89100647, (float)0.88801610, +(float)0.88498759, (float)0.88192123, (float)0.87881714, (float)0.87567532, (float)0.87249595, +(float)0.86927933, (float)0.86602539, (float)0.86273432, (float)0.85940641, (float)0.85604161, +(float)0.85264009, (float)0.84920216, (float)0.84572780, (float)0.84221715, (float)0.83867055, +(float)0.83508795, (float)0.83146954, (float)0.82781565, (float)0.82412612, (float)0.82040137, +(float)0.81664157, (float)0.81284660, (float)0.80901700, (float)0.80515265, (float)0.80125374, +(float)0.79732066, (float)0.79335332, (float)0.78935200, (float)0.78531694, (float)0.78124815, +(float)0.77714586, (float)0.77301049, (float)0.76884180, (float)0.76464021, (float)0.76040596, +(float)0.75613904, (float)0.75183970, (float)0.74750835, (float)0.74314481, (float)0.73874938, +(float)0.73432249, (float)0.72986400, (float)0.72537428, (float)0.72085363, (float)0.71630186, +(float)0.71171951, (float)0.70710677, (float)0.70246363, (float)0.69779032, (float)0.69308734, +(float)0.68835449, (float)0.68359220, (float)0.67880070, (float)0.67398006, (float)0.66913044, +(float)0.66425240, (float)0.65934575, (float)0.65441096, (float)0.64944804, (float)0.64445722, +(float)0.63943905, (float)0.63439327, (float)0.62932026, (float)0.62422055, (float)0.61909389, +(float)0.61394072, (float)0.60876143, (float)0.60355592, (float)0.59832448, (float)0.59306765, +(float)0.58778518, (float)0.58247757, (float)0.57714522, (float)0.57178789, (float)0.56640613, +(float)0.56100023, (float)0.55557019, (float)0.55011630, (float)0.54463905, (float)0.53913826, +(float)0.53361434, (float)0.52806783, (float)0.52249849, (float)0.51690674, (float)0.51129305, +(float)0.50565726, (float)0.50000006, (float)0.49432117, (float)0.48862115, (float)0.48290038, +(float)0.47715873, (float)0.47139663, (float)0.46561456, (float)0.45981231, (float)0.45399037, +(float)0.44814920, (float)0.44228864, (float)0.43640912, (float)0.43051112, (float)0.42459446, +(float)0.41865960, (float)0.41270703, (float)0.40673658, (float)0.40074870, (float)0.39474386, +(float)0.38872188, (float)0.38268328, (float)0.37662849, (float)0.37055734, (float)0.36447033, +(float)0.35836792, (float)0.35224995, (float)0.34611690, (float)0.33996922, (float)0.33380675, +(float)0.32763001, (float)0.32143945, (float)0.31523487, (float)0.30901679, (float)0.30278572, +(float)0.29654145, (float)0.29028472, (float)0.28401530, (float)0.27773371, (float)0.27144048, +(float)0.26513538, (float)0.25881892, (float)0.25249159, (float)0.24615324, (float)0.23980433, +(float)0.23344538, (float)0.22707619, (float)0.22069728, (float)0.21430916, (float)0.20791161, +(float)0.20150517, (float)0.19509031, (float)0.18866688, (float)0.18223536, (float)0.17579627, +(float)0.16934940, (float)0.16289529, (float)0.15643445, (float)0.14996666, (float)0.14349243, +(float)0.13701232, (float)0.13052608, (float)0.12403426, (float)0.11753736, (float)0.11103519, +(float)0.10452849, (float)0.09801710, (float)0.09150149, (float)0.08498220, (float)0.07845904, +(float)0.07193252, (float)0.06540315, (float)0.05887074, (float)0.05233581, (float)0.04579888, +(float)0.03925974, (float)0.03271893, (float)0.02617695, (float)0.01963361, (float)0.01308943, +(float)0.00654493, (float)0.00000000, (float)0.00000000, (float)0.00000000, (float)0.00000000, +(float)0.00000000, (float)0.00000000, (float)0.00000000, (float)0.00000000, (float)0.00000000, +(float)0.00000000, (float)0.00000000, (float)0.00000000, (float)0.00000000, (float)0.00000000, +(float)0.00000000, (float)0.00000000 +}; + + +// Hanning window: for 30ms with 1024 fft with symmetric zeros at 16kHz +static const float kBlocks480w1024[1024] = { +(float)0.00000000, (float)0.00000000, (float)0.00000000, (float)0.00000000, (float)0.00000000, +(float)0.00000000, (float)0.00000000, (float)0.00000000, (float)0.00000000, (float)0.00000000, +(float)0.00000000, (float)0.00000000, (float)0.00000000, (float)0.00000000, (float)0.00000000, +(float)0.00000000, (float)0.00000000, (float)0.00000000, (float)0.00000000, (float)0.00000000, +(float)0.00000000, (float)0.00000000, (float)0.00000000, (float)0.00000000, (float)0.00000000, +(float)0.00000000, (float)0.00000000, (float)0.00000000, (float)0.00000000, (float)0.00000000, +(float)0.00000000, (float)0.00000000, (float)0.00000000, (float)0.00327249, (float)0.00654494, +(float)0.00981732, (float)0.01308960, (float)0.01636173, (float)0.01963369, (float)0.02290544, +(float)0.02617695, (float)0.02944817, (float)0.03271908, (float)0.03598964, (float)0.03925982, +(float)0.04252957, (float)0.04579887, (float)0.04906768, (float)0.05233596, (float)0.05560368, +(float)0.05887080, (float)0.06213730, (float)0.06540313, (float)0.06866825, (float)0.07193266, +(float)0.07519628, (float)0.07845910, (float)0.08172107, (float)0.08498218, (float)0.08824237, +(float)0.09150162, (float)0.09475989, (float)0.09801714, (float)0.10127335, (float)0.10452846, +(float)0.10778246, (float)0.11103531, (float)0.11428697, (float)0.11753740, (float)0.12078657, +(float)0.12403446, (float)0.12728101, (float)0.13052620, (float)0.13376999, (float)0.13701233, +(float)0.14025325, (float)0.14349262, (float)0.14673047, (float)0.14996676, (float)0.15320145, +(float)0.15643448, 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+(float)0.08824220, (float)0.08498220, (float)0.08172106, (float)0.07845904, (float)0.07519618, +(float)0.07193252, (float)0.06866808, (float)0.06540315, (float)0.06213728, (float)0.05887074, +(float)0.05560357, (float)0.05233581, (float)0.04906749, (float)0.04579888, (float)0.04252954, +(float)0.03925974, (float)0.03598953, (float)0.03271893, (float)0.02944798, (float)0.02617695, +(float)0.02290541, (float)0.01963361, (float)0.01636161, (float)0.01308943, (float)0.00981712, +(float)0.00654493, (float)0.00327244, (float)0.00000000, (float)0.00000000, (float)0.00000000, +(float)0.00000000, (float)0.00000000, (float)0.00000000, (float)0.00000000, (float)0.00000000, +(float)0.00000000, (float)0.00000000, (float)0.00000000, (float)0.00000000, (float)0.00000000, +(float)0.00000000, (float)0.00000000, (float)0.00000000, (float)0.00000000, (float)0.00000000, +(float)0.00000000, (float)0.00000000, (float)0.00000000, (float)0.00000000, (float)0.00000000, +(float)0.00000000, (float)0.00000000, (float)0.00000000, (float)0.00000000, (float)0.00000000, +(float)0.00000000, (float)0.00000000, (float)0.00000000, (float)0.00000000}; + +#endif // WEBRTC_MODULES_AUDIO_PROCESSING_NS_MAIN_SOURCE_WINDOWS_PRIVATE_H_ diff --git a/src/modules/audio_processing/utility/fft4g.c b/src/modules/audio_processing/utility/fft4g.c new file mode 100644 index 0000000..9a84368 --- /dev/null +++ b/src/modules/audio_processing/utility/fft4g.c @@ -0,0 +1,1356 @@ +/* + * http://www.kurims.kyoto-u.ac.jp/~ooura/fft.html + * Copyright Takuya OOURA, 1996-2001 + * + * You may use, copy, modify and distribute this code for any purpose (include + * commercial use) and without fee. Please refer to this package when you modify + * this code. + * + * Changes: + * Trivial type modifications by the WebRTC authors. + */ + +/* +Fast Fourier/Cosine/Sine Transform + dimension :one + data length :power of 2 + decimation :frequency + radix :4, 2 + data :inplace + table :use +functions + cdft: Complex Discrete Fourier Transform + rdft: Real Discrete Fourier Transform + ddct: Discrete Cosine Transform + ddst: Discrete Sine Transform + dfct: Cosine Transform of RDFT (Real Symmetric DFT) + dfst: Sine Transform of RDFT (Real Anti-symmetric DFT) +function prototypes + void cdft(int, int, float *, int *, float *); + void rdft(int, int, float *, int *, float *); + void ddct(int, int, float *, int *, float *); + void ddst(int, int, float *, int *, float *); + void dfct(int, float *, float *, int *, float *); + void dfst(int, float *, float *, int *, float *); + + +-------- Complex DFT (Discrete Fourier Transform) -------- + [definition] + + X[k] = sum_j=0^n-1 x[j]*exp(2*pi*i*j*k/n), 0<=k + X[k] = sum_j=0^n-1 x[j]*exp(-2*pi*i*j*k/n), 0<=k + ip[0] = 0; // first time only + cdft(2*n, 1, a, ip, w); + + ip[0] = 0; // first time only + cdft(2*n, -1, a, ip, w); + [parameters] + 2*n :data length (int) + n >= 1, n = power of 2 + a[0...2*n-1] :input/output data (float *) + input data + a[2*j] = Re(x[j]), + a[2*j+1] = Im(x[j]), 0<=j= 2+sqrt(n) + strictly, + length of ip >= + 2+(1<<(int)(log(n+0.5)/log(2))/2). + ip[0],ip[1] are pointers of the cos/sin table. + w[0...n/2-1] :cos/sin table (float *) + w[],ip[] are initialized if ip[0] == 0. + [remark] + Inverse of + cdft(2*n, -1, a, ip, w); + is + cdft(2*n, 1, a, ip, w); + for (j = 0; j <= 2 * n - 1; j++) { + a[j] *= 1.0 / n; + } + . + + +-------- Real DFT / Inverse of Real DFT -------- + [definition] + RDFT + R[k] = sum_j=0^n-1 a[j]*cos(2*pi*j*k/n), 0<=k<=n/2 + I[k] = sum_j=0^n-1 a[j]*sin(2*pi*j*k/n), 0 IRDFT (excluding scale) + a[k] = (R[0] + R[n/2]*cos(pi*k))/2 + + sum_j=1^n/2-1 R[j]*cos(2*pi*j*k/n) + + sum_j=1^n/2-1 I[j]*sin(2*pi*j*k/n), 0<=k + ip[0] = 0; // first time only + rdft(n, 1, a, ip, w); + + ip[0] = 0; // first time only + rdft(n, -1, a, ip, w); + [parameters] + n :data length (int) + n >= 2, n = power of 2 + a[0...n-1] :input/output data (float *) + + output data + a[2*k] = R[k], 0<=k + input data + a[2*j] = R[j], 0<=j= 2+sqrt(n/2) + strictly, + length of ip >= + 2+(1<<(int)(log(n/2+0.5)/log(2))/2). + ip[0],ip[1] are pointers of the cos/sin table. + w[0...n/2-1] :cos/sin table (float *) + w[],ip[] are initialized if ip[0] == 0. + [remark] + Inverse of + rdft(n, 1, a, ip, w); + is + rdft(n, -1, a, ip, w); + for (j = 0; j <= n - 1; j++) { + a[j] *= 2.0 / n; + } + . + + +-------- DCT (Discrete Cosine Transform) / Inverse of DCT -------- + [definition] + IDCT (excluding scale) + C[k] = sum_j=0^n-1 a[j]*cos(pi*j*(k+1/2)/n), 0<=k DCT + C[k] = sum_j=0^n-1 a[j]*cos(pi*(j+1/2)*k/n), 0<=k + ip[0] = 0; // first time only + ddct(n, 1, a, ip, w); + + ip[0] = 0; // first time only + ddct(n, -1, a, ip, w); + [parameters] + n :data length (int) + n >= 2, n = power of 2 + a[0...n-1] :input/output data (float *) + output data + a[k] = C[k], 0<=k= 2+sqrt(n/2) + strictly, + length of ip >= + 2+(1<<(int)(log(n/2+0.5)/log(2))/2). + ip[0],ip[1] are pointers of the cos/sin table. + w[0...n*5/4-1] :cos/sin table (float *) + w[],ip[] are initialized if ip[0] == 0. + [remark] + Inverse of + ddct(n, -1, a, ip, w); + is + a[0] *= 0.5; + ddct(n, 1, a, ip, w); + for (j = 0; j <= n - 1; j++) { + a[j] *= 2.0 / n; + } + . + + +-------- DST (Discrete Sine Transform) / Inverse of DST -------- + [definition] + IDST (excluding scale) + S[k] = sum_j=1^n A[j]*sin(pi*j*(k+1/2)/n), 0<=k DST + S[k] = sum_j=0^n-1 a[j]*sin(pi*(j+1/2)*k/n), 0 + ip[0] = 0; // first time only + ddst(n, 1, a, ip, w); + + ip[0] = 0; // first time only + ddst(n, -1, a, ip, w); + [parameters] + n :data length (int) + n >= 2, n = power of 2 + a[0...n-1] :input/output data (float *) + + input data + a[j] = A[j], 0 + output data + a[k] = S[k], 0= 2+sqrt(n/2) + strictly, + length of ip >= + 2+(1<<(int)(log(n/2+0.5)/log(2))/2). + ip[0],ip[1] are pointers of the cos/sin table. + w[0...n*5/4-1] :cos/sin table (float *) + w[],ip[] are initialized if ip[0] == 0. + [remark] + Inverse of + ddst(n, -1, a, ip, w); + is + a[0] *= 0.5; + ddst(n, 1, a, ip, w); + for (j = 0; j <= n - 1; j++) { + a[j] *= 2.0 / n; + } + . + + +-------- Cosine Transform of RDFT (Real Symmetric DFT) -------- + [definition] + C[k] = sum_j=0^n a[j]*cos(pi*j*k/n), 0<=k<=n + [usage] + ip[0] = 0; // first time only + dfct(n, a, t, ip, w); + [parameters] + n :data length - 1 (int) + n >= 2, n = power of 2 + a[0...n] :input/output data (float *) + output data + a[k] = C[k], 0<=k<=n + t[0...n/2] :work area (float *) + ip[0...*] :work area for bit reversal (int *) + length of ip >= 2+sqrt(n/4) + strictly, + length of ip >= + 2+(1<<(int)(log(n/4+0.5)/log(2))/2). + ip[0],ip[1] are pointers of the cos/sin table. + w[0...n*5/8-1] :cos/sin table (float *) + w[],ip[] are initialized if ip[0] == 0. + [remark] + Inverse of + a[0] *= 0.5; + a[n] *= 0.5; + dfct(n, a, t, ip, w); + is + a[0] *= 0.5; + a[n] *= 0.5; + dfct(n, a, t, ip, w); + for (j = 0; j <= n; j++) { + a[j] *= 2.0 / n; + } + . + + +-------- Sine Transform of RDFT (Real Anti-symmetric DFT) -------- + [definition] + S[k] = sum_j=1^n-1 a[j]*sin(pi*j*k/n), 0= 2, n = power of 2 + a[0...n-1] :input/output data (float *) + output data + a[k] = S[k], 0= 2+sqrt(n/4) + strictly, + length of ip >= + 2+(1<<(int)(log(n/4+0.5)/log(2))/2). + ip[0],ip[1] are pointers of the cos/sin table. + w[0...n*5/8-1] :cos/sin table (float *) + w[],ip[] are initialized if ip[0] == 0. + [remark] + Inverse of + dfst(n, a, t, ip, w); + is + dfst(n, a, t, ip, w); + for (j = 1; j <= n - 1; j++) { + a[j] *= 2.0 / n; + } + . + + +Appendix : + The cos/sin table is recalculated when the larger table required. + w[] and ip[] are compatible with all routines. +*/ + +void cdft(int n, int isgn, float *a, int *ip, float *w) +{ + void makewt(int nw, int *ip, float *w); + void bitrv2(int n, int *ip, float *a); + void bitrv2conj(int n, int *ip, float *a); + void cftfsub(int n, float *a, float *w); + void cftbsub(int n, float *a, float *w); + + if (n > (ip[0] << 2)) { + makewt(n >> 2, ip, w); + } + if (n > 4) { + if (isgn >= 0) { + bitrv2(n, ip + 2, a); + cftfsub(n, a, w); + } else { + bitrv2conj(n, ip + 2, a); + cftbsub(n, a, w); + } + } else if (n == 4) { + cftfsub(n, a, w); + } +} + + +void rdft(int n, int isgn, float *a, int *ip, float *w) +{ + void makewt(int nw, int *ip, float *w); + void makect(int nc, int *ip, float *c); + void bitrv2(int n, int *ip, float *a); + void cftfsub(int n, float *a, float *w); + void cftbsub(int n, float *a, float *w); + void rftfsub(int n, float *a, int nc, float *c); + void rftbsub(int n, float *a, int nc, float *c); + int nw, nc; + float xi; + + nw = ip[0]; + if (n > (nw << 2)) { + nw = n >> 2; + makewt(nw, ip, w); + } + nc = ip[1]; + if (n > (nc << 2)) { + nc = n >> 2; + makect(nc, ip, w + nw); + } + if (isgn >= 0) { + if (n > 4) { + bitrv2(n, ip + 2, a); + cftfsub(n, a, w); + rftfsub(n, a, nc, w + nw); + } else if (n == 4) { + cftfsub(n, a, w); + } + xi = a[0] - a[1]; + a[0] += a[1]; + a[1] = xi; + } else { + a[1] = 0.5f * (a[0] - a[1]); + a[0] -= a[1]; + if (n > 4) { + rftbsub(n, a, nc, w + nw); + bitrv2(n, ip + 2, a); + cftbsub(n, a, w); + } else if (n == 4) { + cftfsub(n, a, w); + } + } +} + + +void ddct(int n, int isgn, float *a, int *ip, float *w) +{ + void makewt(int nw, int *ip, float *w); + void makect(int nc, int *ip, float *c); + void bitrv2(int n, int *ip, float *a); + void cftfsub(int n, float *a, float *w); + void cftbsub(int n, float *a, float *w); + void rftfsub(int n, float *a, int nc, float *c); + void rftbsub(int n, float *a, int nc, float *c); + void dctsub(int n, float *a, int nc, float *c); + int j, nw, nc; + float xr; + + nw = ip[0]; + if (n > (nw << 2)) { + nw = n >> 2; + makewt(nw, ip, w); + } + nc = ip[1]; + if (n > nc) { + nc = n; + makect(nc, ip, w + nw); + } + if (isgn < 0) { + xr = a[n - 1]; + for (j = n - 2; j >= 2; j -= 2) { + a[j + 1] = a[j] - a[j - 1]; + a[j] += a[j - 1]; + } + a[1] = a[0] - xr; + a[0] += xr; + if (n > 4) { + rftbsub(n, a, nc, w + nw); + bitrv2(n, ip + 2, a); + cftbsub(n, a, w); + } else if (n == 4) { + cftfsub(n, a, w); + } + } + dctsub(n, a, nc, w + nw); + if (isgn >= 0) { + if (n > 4) { + bitrv2(n, ip + 2, a); + cftfsub(n, a, w); + rftfsub(n, a, nc, w + nw); + } else if (n == 4) { + cftfsub(n, a, w); + } + xr = a[0] - a[1]; + a[0] += a[1]; + for (j = 2; j < n; j += 2) { + a[j - 1] = a[j] - a[j + 1]; + a[j] += a[j + 1]; + } + a[n - 1] = xr; + } +} + + +void ddst(int n, int isgn, float *a, int *ip, float *w) +{ + void makewt(int nw, int *ip, float *w); + void makect(int nc, int *ip, float *c); + void bitrv2(int n, int *ip, float *a); + void cftfsub(int n, float *a, float *w); + void cftbsub(int n, float *a, float *w); + void rftfsub(int n, float *a, int nc, float *c); + void rftbsub(int n, float *a, int nc, float *c); + void dstsub(int n, float *a, int nc, float *c); + int j, nw, nc; + float xr; + + nw = ip[0]; + if (n > (nw << 2)) { + nw = n >> 2; + makewt(nw, ip, w); + } + nc = ip[1]; + if (n > nc) { + nc = n; + makect(nc, ip, w + nw); + } + if (isgn < 0) { + xr = a[n - 1]; + for (j = n - 2; j >= 2; j -= 2) { + a[j + 1] = -a[j] - a[j - 1]; + a[j] -= a[j - 1]; + } + a[1] = a[0] + xr; + a[0] -= xr; + if (n > 4) { + rftbsub(n, a, nc, w + nw); + bitrv2(n, ip + 2, a); + cftbsub(n, a, w); + } else if (n == 4) { + cftfsub(n, a, w); + } + } + dstsub(n, a, nc, w + nw); + if (isgn >= 0) { + if (n > 4) { + bitrv2(n, ip + 2, a); + cftfsub(n, a, w); + rftfsub(n, a, nc, w + nw); + } else if (n == 4) { + cftfsub(n, a, w); + } + xr = a[0] - a[1]; + a[0] += a[1]; + for (j = 2; j < n; j += 2) { + a[j - 1] = -a[j] - a[j + 1]; + a[j] -= a[j + 1]; + } + a[n - 1] = -xr; + } +} + + +void dfct(int n, float *a, float *t, int *ip, float *w) +{ + void makewt(int nw, int *ip, float *w); + void makect(int nc, int *ip, float *c); + void bitrv2(int n, int *ip, float *a); + void cftfsub(int n, float *a, float *w); + void rftfsub(int n, float *a, int nc, float *c); + void dctsub(int n, float *a, int nc, float *c); + int j, k, l, m, mh, nw, nc; + float xr, xi, yr, yi; + + nw = ip[0]; + if (n > (nw << 3)) { + nw = n >> 3; + makewt(nw, ip, w); + } + nc = ip[1]; + if (n > (nc << 1)) { + nc = n >> 1; + makect(nc, ip, w + nw); + } + m = n >> 1; + yi = a[m]; + xi = a[0] + a[n]; + a[0] -= a[n]; + t[0] = xi - yi; + t[m] = xi + yi; + if (n > 2) { + mh = m >> 1; + for (j = 1; j < mh; j++) { + k = m - j; + xr = a[j] - a[n - j]; + xi = a[j] + a[n - j]; + yr = a[k] - a[n - k]; + yi = a[k] + a[n - k]; + a[j] = xr; + a[k] = yr; + t[j] = xi - yi; + t[k] = xi + yi; + } + t[mh] = a[mh] + a[n - mh]; + a[mh] -= a[n - mh]; + dctsub(m, a, nc, w + nw); + if (m > 4) { + bitrv2(m, ip + 2, a); + cftfsub(m, a, w); + rftfsub(m, a, nc, w + nw); + } else if (m == 4) { + cftfsub(m, a, w); + } + a[n - 1] = a[0] - a[1]; + a[1] = a[0] + a[1]; + for (j = m - 2; j >= 2; j -= 2) { + a[2 * j + 1] = a[j] + a[j + 1]; + a[2 * j - 1] = a[j] - a[j + 1]; + } + l = 2; + m = mh; + while (m >= 2) { + dctsub(m, t, nc, w + nw); + if (m > 4) { + bitrv2(m, ip + 2, t); + cftfsub(m, t, w); + rftfsub(m, t, nc, w + nw); + } else if (m == 4) { + cftfsub(m, t, w); + } + a[n - l] = t[0] - t[1]; + a[l] = t[0] + t[1]; + k = 0; + for (j = 2; j < m; j += 2) { + k += l << 2; + a[k - l] = t[j] - t[j + 1]; + a[k + l] = t[j] + t[j + 1]; + } + l <<= 1; + mh = m >> 1; + for (j = 0; j < mh; j++) { + k = m - j; + t[j] = t[m + k] - t[m + j]; + t[k] = t[m + k] + t[m + j]; + } + t[mh] = t[m + mh]; + m = mh; + } + a[l] = t[0]; + a[n] = t[2] - t[1]; + a[0] = t[2] + t[1]; + } else { + a[1] = a[0]; + a[2] = t[0]; + a[0] = t[1]; + } +} + + +void dfst(int n, float *a, float *t, int *ip, float *w) +{ + void makewt(int nw, int *ip, float *w); + void makect(int nc, int *ip, float *c); + void bitrv2(int n, int *ip, float *a); + void cftfsub(int n, float *a, float *w); + void rftfsub(int n, float *a, int nc, float *c); + void dstsub(int n, float *a, int nc, float *c); + int j, k, l, m, mh, nw, nc; + float xr, xi, yr, yi; + + nw = ip[0]; + if (n > (nw << 3)) { + nw = n >> 3; + makewt(nw, ip, w); + } + nc = ip[1]; + if (n > (nc << 1)) { + nc = n >> 1; + makect(nc, ip, w + nw); + } + if (n > 2) { + m = n >> 1; + mh = m >> 1; + for (j = 1; j < mh; j++) { + k = m - j; + xr = a[j] + a[n - j]; + xi = a[j] - a[n - j]; + yr = a[k] + a[n - k]; + yi = a[k] - a[n - k]; + a[j] = xr; + a[k] = yr; + t[j] = xi + yi; + t[k] = xi - yi; + } + t[0] = a[mh] - a[n - mh]; + a[mh] += a[n - mh]; + a[0] = a[m]; + dstsub(m, a, nc, w + nw); + if (m > 4) { + bitrv2(m, ip + 2, a); + cftfsub(m, a, w); + rftfsub(m, a, nc, w + nw); + } else if (m == 4) { + cftfsub(m, a, w); + } + a[n - 1] = a[1] - a[0]; + a[1] = a[0] + a[1]; + for (j = m - 2; j >= 2; j -= 2) { + a[2 * j + 1] = a[j] - a[j + 1]; + a[2 * j - 1] = -a[j] - a[j + 1]; + } + l = 2; + m = mh; + while (m >= 2) { + dstsub(m, t, nc, w + nw); + if (m > 4) { + bitrv2(m, ip + 2, t); + cftfsub(m, t, w); + rftfsub(m, t, nc, w + nw); + } else if (m == 4) { + cftfsub(m, t, w); + } + a[n - l] = t[1] - t[0]; + a[l] = t[0] + t[1]; + k = 0; + for (j = 2; j < m; j += 2) { + k += l << 2; + a[k - l] = -t[j] - t[j + 1]; + a[k + l] = t[j] - t[j + 1]; + } + l <<= 1; + mh = m >> 1; + for (j = 1; j < mh; j++) { + k = m - j; + t[j] = t[m + k] + t[m + j]; + t[k] = t[m + k] - t[m + j]; + } + t[0] = t[m + mh]; + m = mh; + } + a[l] = t[0]; + } + a[0] = 0; +} + + +/* -------- initializing routines -------- */ + + +#include + +void makewt(int nw, int *ip, float *w) +{ + void bitrv2(int n, int *ip, float *a); + int j, nwh; + float delta, x, y; + + ip[0] = nw; + ip[1] = 1; + if (nw > 2) { + nwh = nw >> 1; + delta = (float)atan(1.0f) / nwh; + w[0] = 1; + w[1] = 0; + w[nwh] = (float)cos(delta * nwh); + w[nwh + 1] = w[nwh]; + if (nwh > 2) { + for (j = 2; j < nwh; j += 2) { + x = (float)cos(delta * j); + y = (float)sin(delta * j); + w[j] = x; + w[j + 1] = y; + w[nw - j] = y; + w[nw - j + 1] = x; + } + bitrv2(nw, ip + 2, w); + } + } +} + + +void makect(int nc, int *ip, float *c) +{ + int j, nch; + float delta; + + ip[1] = nc; + if (nc > 1) { + nch = nc >> 1; + delta = (float)atan(1.0f) / nch; + c[0] = (float)cos(delta * nch); + c[nch] = 0.5f * c[0]; + for (j = 1; j < nch; j++) { + c[j] = 0.5f * (float)cos(delta * j); + c[nc - j] = 0.5f * (float)sin(delta * j); + } + } +} + + +/* -------- child routines -------- */ + + +void bitrv2(int n, int *ip, float *a) +{ + int j, j1, k, k1, l, m, m2; + float xr, xi, yr, yi; + + ip[0] = 0; + l = n; + m = 1; + while ((m << 3) < l) { + l >>= 1; + for (j = 0; j < m; j++) { + ip[m + j] = ip[j] + l; + } + m <<= 1; + } + m2 = 2 * m; + if ((m << 3) == l) { + for (k = 0; k < m; k++) { + for (j = 0; j < k; j++) { + j1 = 2 * j + ip[k]; + k1 = 2 * k + ip[j]; + xr = a[j1]; + xi = a[j1 + 1]; + yr = a[k1]; + yi = a[k1 + 1]; + a[j1] = yr; + a[j1 + 1] = yi; + a[k1] = xr; + a[k1 + 1] = xi; + j1 += m2; + k1 += 2 * m2; + xr = a[j1]; + xi = a[j1 + 1]; + yr = a[k1]; + yi = a[k1 + 1]; + a[j1] = yr; + a[j1 + 1] = yi; + a[k1] = xr; + a[k1 + 1] = xi; + j1 += m2; + k1 -= m2; + xr = a[j1]; + xi = a[j1 + 1]; + yr = a[k1]; + yi = a[k1 + 1]; + a[j1] = yr; + a[j1 + 1] = yi; + a[k1] = xr; + a[k1 + 1] = xi; + j1 += m2; + k1 += 2 * m2; + xr = a[j1]; + xi = a[j1 + 1]; + yr = a[k1]; + yi = a[k1 + 1]; + a[j1] = yr; + a[j1 + 1] = yi; + a[k1] = xr; + a[k1 + 1] = xi; + } + j1 = 2 * k + m2 + ip[k]; + k1 = j1 + m2; + xr = a[j1]; + xi = a[j1 + 1]; + yr = a[k1]; + yi = a[k1 + 1]; + a[j1] = yr; + a[j1 + 1] = yi; + a[k1] = xr; + a[k1 + 1] = xi; + } + } else { + for (k = 1; k < m; k++) { + for (j = 0; j < k; j++) { + j1 = 2 * j + ip[k]; + k1 = 2 * k + ip[j]; + xr = a[j1]; + xi = a[j1 + 1]; + yr = a[k1]; + yi = a[k1 + 1]; + a[j1] = yr; + a[j1 + 1] = yi; + a[k1] = xr; + a[k1 + 1] = xi; + j1 += m2; + k1 += m2; + xr = a[j1]; + xi = a[j1 + 1]; + yr = a[k1]; + yi = a[k1 + 1]; + a[j1] = yr; + a[j1 + 1] = yi; + a[k1] = xr; + a[k1 + 1] = xi; + } + } + } +} + + +void bitrv2conj(int n, int *ip, float *a) +{ + int j, j1, k, k1, l, m, m2; + float xr, xi, yr, yi; + + ip[0] = 0; + l = n; + m = 1; + while ((m << 3) < l) { + l >>= 1; + for (j = 0; j < m; j++) { + ip[m + j] = ip[j] + l; + } + m <<= 1; + } + m2 = 2 * m; + if ((m << 3) == l) { + for (k = 0; k < m; k++) { + for (j = 0; j < k; j++) { + j1 = 2 * j + ip[k]; + k1 = 2 * k + ip[j]; + xr = a[j1]; + xi = -a[j1 + 1]; + yr = a[k1]; + yi = -a[k1 + 1]; + a[j1] = yr; + a[j1 + 1] = yi; + a[k1] = xr; + a[k1 + 1] = xi; + j1 += m2; + k1 += 2 * m2; + xr = a[j1]; + xi = -a[j1 + 1]; + yr = a[k1]; + yi = -a[k1 + 1]; + a[j1] = yr; + a[j1 + 1] = yi; + a[k1] = xr; + a[k1 + 1] = xi; + j1 += m2; + k1 -= m2; + xr = a[j1]; + xi = -a[j1 + 1]; + yr = a[k1]; + yi = -a[k1 + 1]; + a[j1] = yr; + a[j1 + 1] = yi; + a[k1] = xr; + a[k1 + 1] = xi; + j1 += m2; + k1 += 2 * m2; + xr = a[j1]; + xi = -a[j1 + 1]; + yr = a[k1]; + yi = -a[k1 + 1]; + a[j1] = yr; + a[j1 + 1] = yi; + a[k1] = xr; + a[k1 + 1] = xi; + } + k1 = 2 * k + ip[k]; + a[k1 + 1] = -a[k1 + 1]; + j1 = k1 + m2; + k1 = j1 + m2; + xr = a[j1]; + xi = -a[j1 + 1]; + yr = a[k1]; + yi = -a[k1 + 1]; + a[j1] = yr; + a[j1 + 1] = yi; + a[k1] = xr; + a[k1 + 1] = xi; + k1 += m2; + a[k1 + 1] = -a[k1 + 1]; + } + } else { + a[1] = -a[1]; + a[m2 + 1] = -a[m2 + 1]; + for (k = 1; k < m; k++) { + for (j = 0; j < k; j++) { + j1 = 2 * j + ip[k]; + k1 = 2 * k + ip[j]; + xr = a[j1]; + xi = -a[j1 + 1]; + yr = a[k1]; + yi = -a[k1 + 1]; + a[j1] = yr; + a[j1 + 1] = yi; + a[k1] = xr; + a[k1 + 1] = xi; + j1 += m2; + k1 += m2; + xr = a[j1]; + xi = -a[j1 + 1]; + yr = a[k1]; + yi = -a[k1 + 1]; + a[j1] = yr; + a[j1 + 1] = yi; + a[k1] = xr; + a[k1 + 1] = xi; + } + k1 = 2 * k + ip[k]; + a[k1 + 1] = -a[k1 + 1]; + a[k1 + m2 + 1] = -a[k1 + m2 + 1]; + } + } +} + + +void cftfsub(int n, float *a, float *w) +{ + void cft1st(int n, float *a, float *w); + void cftmdl(int n, int l, float *a, float *w); + int j, j1, j2, j3, l; + float x0r, x0i, x1r, x1i, x2r, x2i, x3r, x3i; + + l = 2; + if (n > 8) { + cft1st(n, a, w); + l = 8; + while ((l << 2) < n) { + cftmdl(n, l, a, w); + l <<= 2; + } + } + if ((l << 2) == n) { + for (j = 0; j < l; j += 2) { + j1 = j + l; + j2 = j1 + l; + j3 = j2 + l; + x0r = a[j] + a[j1]; + x0i = a[j + 1] + a[j1 + 1]; + x1r = a[j] - a[j1]; + x1i = a[j + 1] - a[j1 + 1]; + x2r = a[j2] + a[j3]; + x2i = a[j2 + 1] + a[j3 + 1]; + x3r = a[j2] - a[j3]; + x3i = a[j2 + 1] - a[j3 + 1]; + a[j] = x0r + x2r; + a[j + 1] = x0i + x2i; + a[j2] = x0r - x2r; + a[j2 + 1] = x0i - x2i; + a[j1] = x1r - x3i; + a[j1 + 1] = x1i + x3r; + a[j3] = x1r + x3i; + a[j3 + 1] = x1i - x3r; + } + } else { + for (j = 0; j < l; j += 2) { + j1 = j + l; + x0r = a[j] - a[j1]; + x0i = a[j + 1] - a[j1 + 1]; + a[j] += a[j1]; + a[j + 1] += a[j1 + 1]; + a[j1] = x0r; + a[j1 + 1] = x0i; + } + } +} + + +void cftbsub(int n, float *a, float *w) +{ + void cft1st(int n, float *a, float *w); + void cftmdl(int n, int l, float *a, float *w); + int j, j1, j2, j3, l; + float x0r, x0i, x1r, x1i, x2r, x2i, x3r, x3i; + + l = 2; + if (n > 8) { + cft1st(n, a, w); + l = 8; + while ((l << 2) < n) { + cftmdl(n, l, a, w); + l <<= 2; + } + } + if ((l << 2) == n) { + for (j = 0; j < l; j += 2) { + j1 = j + l; + j2 = j1 + l; + j3 = j2 + l; + x0r = a[j] + a[j1]; + x0i = -a[j + 1] - a[j1 + 1]; + x1r = a[j] - a[j1]; + x1i = -a[j + 1] + a[j1 + 1]; + x2r = a[j2] + a[j3]; + x2i = a[j2 + 1] + a[j3 + 1]; + x3r = a[j2] - a[j3]; + x3i = a[j2 + 1] - a[j3 + 1]; + a[j] = x0r + x2r; + a[j + 1] = x0i - x2i; + a[j2] = x0r - x2r; + a[j2 + 1] = x0i + x2i; + a[j1] = x1r - x3i; + a[j1 + 1] = x1i - x3r; + a[j3] = x1r + x3i; + a[j3 + 1] = x1i + x3r; + } + } else { + for (j = 0; j < l; j += 2) { + j1 = j + l; + x0r = a[j] - a[j1]; + x0i = -a[j + 1] + a[j1 + 1]; + a[j] += a[j1]; + a[j + 1] = -a[j + 1] - a[j1 + 1]; + a[j1] = x0r; + a[j1 + 1] = x0i; + } + } +} + + +void cft1st(int n, float *a, float *w) +{ + int j, k1, k2; + float wk1r, wk1i, wk2r, wk2i, wk3r, wk3i; + float x0r, x0i, x1r, x1i, x2r, x2i, x3r, x3i; + + x0r = a[0] + a[2]; + x0i = a[1] + a[3]; + x1r = a[0] - a[2]; + x1i = a[1] - a[3]; + x2r = a[4] + a[6]; + x2i = a[5] + a[7]; + x3r = a[4] - a[6]; + x3i = a[5] - a[7]; + a[0] = x0r + x2r; + a[1] = x0i + x2i; + a[4] = x0r - x2r; + a[5] = x0i - x2i; + a[2] = x1r - x3i; + a[3] = x1i + x3r; + a[6] = x1r + x3i; + a[7] = x1i - x3r; + wk1r = w[2]; + x0r = a[8] + a[10]; + x0i = a[9] + a[11]; + x1r = a[8] - a[10]; + x1i = a[9] - a[11]; + x2r = a[12] + a[14]; + x2i = a[13] + a[15]; + x3r = a[12] - a[14]; + x3i = a[13] - a[15]; + a[8] = x0r + x2r; + a[9] = x0i + x2i; + a[12] = x2i - x0i; + a[13] = x0r - x2r; + x0r = x1r - x3i; + x0i = x1i + x3r; + a[10] = wk1r * (x0r - x0i); + a[11] = wk1r * (x0r + x0i); + x0r = x3i + x1r; + x0i = x3r - x1i; + a[14] = wk1r * (x0i - x0r); + a[15] = wk1r * (x0i + x0r); + k1 = 0; + for (j = 16; j < n; j += 16) { + k1 += 2; + k2 = 2 * k1; + wk2r = w[k1]; + wk2i = w[k1 + 1]; + wk1r = w[k2]; + wk1i = w[k2 + 1]; + wk3r = wk1r - 2 * wk2i * wk1i; + wk3i = 2 * wk2i * wk1r - wk1i; + x0r = a[j] + a[j + 2]; + x0i = a[j + 1] + a[j + 3]; + x1r = a[j] - a[j + 2]; + x1i = a[j + 1] - a[j + 3]; + x2r = a[j + 4] + a[j + 6]; + x2i = a[j + 5] + a[j + 7]; + x3r = a[j + 4] - a[j + 6]; + x3i = a[j + 5] - a[j + 7]; + a[j] = x0r + x2r; + a[j + 1] = x0i + x2i; + x0r -= x2r; + x0i -= x2i; + a[j + 4] = wk2r * x0r - wk2i * x0i; + a[j + 5] = wk2r * x0i + wk2i * x0r; + x0r = x1r - x3i; + x0i = x1i + x3r; + a[j + 2] = wk1r * x0r - wk1i * x0i; + a[j + 3] = wk1r * x0i + wk1i * x0r; + x0r = x1r + x3i; + x0i = x1i - x3r; + a[j + 6] = wk3r * x0r - wk3i * x0i; + a[j + 7] = wk3r * x0i + wk3i * x0r; + wk1r = w[k2 + 2]; + wk1i = w[k2 + 3]; + wk3r = wk1r - 2 * wk2r * wk1i; + wk3i = 2 * wk2r * wk1r - wk1i; + x0r = a[j + 8] + a[j + 10]; + x0i = a[j + 9] + a[j + 11]; + x1r = a[j + 8] - a[j + 10]; + x1i = a[j + 9] - a[j + 11]; + x2r = a[j + 12] + a[j + 14]; + x2i = a[j + 13] + a[j + 15]; + x3r = a[j + 12] - a[j + 14]; + x3i = a[j + 13] - a[j + 15]; + a[j + 8] = x0r + x2r; + a[j + 9] = x0i + x2i; + x0r -= x2r; + x0i -= x2i; + a[j + 12] = -wk2i * x0r - wk2r * x0i; + a[j + 13] = -wk2i * x0i + wk2r * x0r; + x0r = x1r - x3i; + x0i = x1i + x3r; + a[j + 10] = wk1r * x0r - wk1i * x0i; + a[j + 11] = wk1r * x0i + wk1i * x0r; + x0r = x1r + x3i; + x0i = x1i - x3r; + a[j + 14] = wk3r * x0r - wk3i * x0i; + a[j + 15] = wk3r * x0i + wk3i * x0r; + } +} + + +void cftmdl(int n, int l, float *a, float *w) +{ + int j, j1, j2, j3, k, k1, k2, m, m2; + float wk1r, wk1i, wk2r, wk2i, wk3r, wk3i; + float x0r, x0i, x1r, x1i, x2r, x2i, x3r, x3i; + + m = l << 2; + for (j = 0; j < l; j += 2) { + j1 = j + l; + j2 = j1 + l; + j3 = j2 + l; + x0r = a[j] + a[j1]; + x0i = a[j + 1] + a[j1 + 1]; + x1r = a[j] - a[j1]; + x1i = a[j + 1] - a[j1 + 1]; + x2r = a[j2] + a[j3]; + x2i = a[j2 + 1] + a[j3 + 1]; + x3r = a[j2] - a[j3]; + x3i = a[j2 + 1] - a[j3 + 1]; + a[j] = x0r + x2r; + a[j + 1] = x0i + x2i; + a[j2] = x0r - x2r; + a[j2 + 1] = x0i - x2i; + a[j1] = x1r - x3i; + a[j1 + 1] = x1i + x3r; + a[j3] = x1r + x3i; + a[j3 + 1] = x1i - x3r; + } + wk1r = w[2]; + for (j = m; j < l + m; j += 2) { + j1 = j + l; + j2 = j1 + l; + j3 = j2 + l; + x0r = a[j] + a[j1]; + x0i = a[j + 1] + a[j1 + 1]; + x1r = a[j] - a[j1]; + x1i = a[j + 1] - a[j1 + 1]; + x2r = a[j2] + a[j3]; + x2i = a[j2 + 1] + a[j3 + 1]; + x3r = a[j2] - a[j3]; + x3i = a[j2 + 1] - a[j3 + 1]; + a[j] = x0r + x2r; + a[j + 1] = x0i + x2i; + a[j2] = x2i - x0i; + a[j2 + 1] = x0r - x2r; + x0r = x1r - x3i; + x0i = x1i + x3r; + a[j1] = wk1r * (x0r - x0i); + a[j1 + 1] = wk1r * (x0r + x0i); + x0r = x3i + x1r; + x0i = x3r - x1i; + a[j3] = wk1r * (x0i - x0r); + a[j3 + 1] = wk1r * (x0i + x0r); + } + k1 = 0; + m2 = 2 * m; + for (k = m2; k < n; k += m2) { + k1 += 2; + k2 = 2 * k1; + wk2r = w[k1]; + wk2i = w[k1 + 1]; + wk1r = w[k2]; + wk1i = w[k2 + 1]; + wk3r = wk1r - 2 * wk2i * wk1i; + wk3i = 2 * wk2i * wk1r - wk1i; + for (j = k; j < l + k; j += 2) { + j1 = j + l; + j2 = j1 + l; + j3 = j2 + l; + x0r = a[j] + a[j1]; + x0i = a[j + 1] + a[j1 + 1]; + x1r = a[j] - a[j1]; + x1i = a[j + 1] - a[j1 + 1]; + x2r = a[j2] + a[j3]; + x2i = a[j2 + 1] + a[j3 + 1]; + x3r = a[j2] - a[j3]; + x3i = a[j2 + 1] - a[j3 + 1]; + a[j] = x0r + x2r; + a[j + 1] = x0i + x2i; + x0r -= x2r; + x0i -= x2i; + a[j2] = wk2r * x0r - wk2i * x0i; + a[j2 + 1] = wk2r * x0i + wk2i * x0r; + x0r = x1r - x3i; + x0i = x1i + x3r; + a[j1] = wk1r * x0r - wk1i * x0i; + a[j1 + 1] = wk1r * x0i + wk1i * x0r; + x0r = x1r + x3i; + x0i = x1i - x3r; + a[j3] = wk3r * x0r - wk3i * x0i; + a[j3 + 1] = wk3r * x0i + wk3i * x0r; + } + wk1r = w[k2 + 2]; + wk1i = w[k2 + 3]; + wk3r = wk1r - 2 * wk2r * wk1i; + wk3i = 2 * wk2r * wk1r - wk1i; + for (j = k + m; j < l + (k + m); j += 2) { + j1 = j + l; + j2 = j1 + l; + j3 = j2 + l; + x0r = a[j] + a[j1]; + x0i = a[j + 1] + a[j1 + 1]; + x1r = a[j] - a[j1]; + x1i = a[j + 1] - a[j1 + 1]; + x2r = a[j2] + a[j3]; + x2i = a[j2 + 1] + a[j3 + 1]; + x3r = a[j2] - a[j3]; + x3i = a[j2 + 1] - a[j3 + 1]; + a[j] = x0r + x2r; + a[j + 1] = x0i + x2i; + x0r -= x2r; + x0i -= x2i; + a[j2] = -wk2i * x0r - wk2r * x0i; + a[j2 + 1] = -wk2i * x0i + wk2r * x0r; + x0r = x1r - x3i; + x0i = x1i + x3r; + a[j1] = wk1r * x0r - wk1i * x0i; + a[j1 + 1] = wk1r * x0i + wk1i * x0r; + x0r = x1r + x3i; + x0i = x1i - x3r; + a[j3] = wk3r * x0r - wk3i * x0i; + a[j3 + 1] = wk3r * x0i + wk3i * x0r; + } + } +} + + +void rftfsub(int n, float *a, int nc, float *c) +{ + int j, k, kk, ks, m; + float wkr, wki, xr, xi, yr, yi; + + m = n >> 1; + ks = 2 * nc / m; + kk = 0; + for (j = 2; j < m; j += 2) { + k = n - j; + kk += ks; + wkr = 0.5f - c[nc - kk]; + wki = c[kk]; + xr = a[j] - a[k]; + xi = a[j + 1] + a[k + 1]; + yr = wkr * xr - wki * xi; + yi = wkr * xi + wki * xr; + a[j] -= yr; + a[j + 1] -= yi; + a[k] += yr; + a[k + 1] -= yi; + } +} + + +void rftbsub(int n, float *a, int nc, float *c) +{ + int j, k, kk, ks, m; + float wkr, wki, xr, xi, yr, yi; + + a[1] = -a[1]; + m = n >> 1; + ks = 2 * nc / m; + kk = 0; + for (j = 2; j < m; j += 2) { + k = n - j; + kk += ks; + wkr = 0.5f - c[nc - kk]; + wki = c[kk]; + xr = a[j] - a[k]; + xi = a[j + 1] + a[k + 1]; + yr = wkr * xr + wki * xi; + yi = wkr * xi - wki * xr; + a[j] -= yr; + a[j + 1] = yi - a[j + 1]; + a[k] += yr; + a[k + 1] = yi - a[k + 1]; + } + a[m + 1] = -a[m + 1]; +} + + +void dctsub(int n, float *a, int nc, float *c) +{ + int j, k, kk, ks, m; + float wkr, wki, xr; + + m = n >> 1; + ks = nc / n; + kk = 0; + for (j = 1; j < m; j++) { + k = n - j; + kk += ks; + wkr = c[kk] - c[nc - kk]; + wki = c[kk] + c[nc - kk]; + xr = wki * a[j] - wkr * a[k]; + a[j] = wkr * a[j] + wki * a[k]; + a[k] = xr; + } + a[m] *= c[0]; +} + + +void dstsub(int n, float *a, int nc, float *c) +{ + int j, k, kk, ks, m; + float wkr, wki, xr; + + m = n >> 1; + ks = nc / n; + kk = 0; + for (j = 1; j < m; j++) { + k = n - j; + kk += ks; + wkr = c[kk] - c[nc - kk]; + wki = c[kk] + c[nc - kk]; + xr = wki * a[k] - wkr * a[j]; + a[k] = wkr * a[k] + wki * a[j]; + a[j] = xr; + } + a[m] *= c[0]; +} + diff --git a/src/modules/audio_processing/utility/fft4g.h b/src/modules/audio_processing/utility/fft4g.h new file mode 100644 index 0000000..373ff14 --- /dev/null +++ b/src/modules/audio_processing/utility/fft4g.h @@ -0,0 +1,18 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +#ifndef WEBRTC_MODULES_AUDIO_PROCESSING_UTILITY_FFT4G_H_ +#define WEBRTC_MODULES_AUDIO_PROCESSING_UTILITY_FFT4G_H_ + +void rdft(int, int, float *, int *, float *); +void cdft(int, int, float *, int *, float *); + +#endif + diff --git a/src/modules/audio_processing/utility/ring_buffer.c b/src/modules/audio_processing/utility/ring_buffer.c new file mode 100644 index 0000000..ea2e354 --- /dev/null +++ b/src/modules/audio_processing/utility/ring_buffer.c @@ -0,0 +1,239 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +/* + * Provides a generic ring buffer that can be written to and read from with + * arbitrarily sized blocks. The AEC uses this for several different tasks. + */ + +#include +#include +#include "ring_buffer.h" + +typedef struct { + int readPos; + int writePos; + int size; + char rwWrap; + bufdata_t *data; +} buf_t; + +enum {SAME_WRAP, DIFF_WRAP}; + +int WebRtcApm_CreateBuffer(void **bufInst, int size) +{ + buf_t *buf = NULL; + + if (size < 0) { + return -1; + } + + buf = malloc(sizeof(buf_t)); + *bufInst = buf; + if (buf == NULL) { + return -1; + } + + buf->data = malloc(size*sizeof(bufdata_t)); + if (buf->data == NULL) { + free(buf); + buf = NULL; + return -1; + } + + buf->size = size; + return 0; +} + +int WebRtcApm_InitBuffer(void *bufInst) +{ + buf_t *buf = (buf_t*)bufInst; + + buf->readPos = 0; + buf->writePos = 0; + buf->rwWrap = SAME_WRAP; + + // Initialize buffer to zeros + memset(buf->data, 0, sizeof(bufdata_t)*buf->size); + + return 0; +} + +int WebRtcApm_FreeBuffer(void *bufInst) +{ + buf_t *buf = (buf_t*)bufInst; + + if (buf == NULL) { + return -1; + } + + free(buf->data); + free(buf); + + return 0; +} + +int WebRtcApm_ReadBuffer(void *bufInst, bufdata_t *data, int size) +{ + buf_t *buf = (buf_t*)bufInst; + int n = 0, margin = 0; + + if (size <= 0 || size > buf->size) { + return -1; + } + + n = size; + if (buf->rwWrap == DIFF_WRAP) { + margin = buf->size - buf->readPos; + if (n > margin) { + buf->rwWrap = SAME_WRAP; + memcpy(data, buf->data + buf->readPos, + sizeof(bufdata_t)*margin); + buf->readPos = 0; + n = size - margin; + } + else { + memcpy(data, buf->data + buf->readPos, + sizeof(bufdata_t)*n); + buf->readPos += n; + return n; + } + } + + if (buf->rwWrap == SAME_WRAP) { + margin = buf->writePos - buf->readPos; + if (margin > n) + margin = n; + memcpy(data + size - n, buf->data + buf->readPos, + sizeof(bufdata_t)*margin); + buf->readPos += margin; + n -= margin; + } + + return size - n; +} + +int WebRtcApm_WriteBuffer(void *bufInst, const bufdata_t *data, int size) +{ + buf_t *buf = (buf_t*)bufInst; + int n = 0, margin = 0; + + if (size < 0 || size > buf->size) { + return -1; + } + + n = size; + if (buf->rwWrap == SAME_WRAP) { + margin = buf->size - buf->writePos; + if (n > margin) { + buf->rwWrap = DIFF_WRAP; + memcpy(buf->data + buf->writePos, data, + sizeof(bufdata_t)*margin); + buf->writePos = 0; + n = size - margin; + } + else { + memcpy(buf->data + buf->writePos, data, + sizeof(bufdata_t)*n); + buf->writePos += n; + return n; + } + } + + if (buf->rwWrap == DIFF_WRAP) { + margin = buf->readPos - buf->writePos; + if (margin > n) + margin = n; + memcpy(buf->data + buf->writePos, data + size - n, + sizeof(bufdata_t)*margin); + buf->writePos += margin; + n -= margin; + } + + return size - n; +} + +int WebRtcApm_FlushBuffer(void *bufInst, int size) +{ + buf_t *buf = (buf_t*)bufInst; + int n = 0, margin = 0; + + if (size <= 0 || size > buf->size) { + return -1; + } + + n = size; + if (buf->rwWrap == DIFF_WRAP) { + margin = buf->size - buf->readPos; + if (n > margin) { + buf->rwWrap = SAME_WRAP; + buf->readPos = 0; + n = size - margin; + } + else { + buf->readPos += n; + return n; + } + } + + if (buf->rwWrap == SAME_WRAP) { + margin = buf->writePos - buf->readPos; + if (margin > n) + margin = n; + buf->readPos += margin; + n -= margin; + } + + return size - n; +} + +int WebRtcApm_StuffBuffer(void *bufInst, int size) +{ + buf_t *buf = (buf_t*)bufInst; + int n = 0, margin = 0; + + if (size <= 0 || size > buf->size) { + return -1; + } + + n = size; + if (buf->rwWrap == SAME_WRAP) { + margin = buf->readPos; + if (n > margin) { + buf->rwWrap = DIFF_WRAP; + buf->readPos = buf->size - 1; + n -= margin + 1; + } + else { + buf->readPos -= n; + return n; + } + } + + if (buf->rwWrap == DIFF_WRAP) { + margin = buf->readPos - buf->writePos; + if (margin > n) + margin = n; + buf->readPos -= margin; + n -= margin; + } + + return size - n; +} + +int WebRtcApm_get_buffer_size(const void *bufInst) +{ + const buf_t *buf = (buf_t*)bufInst; + + if (buf->rwWrap == SAME_WRAP) + return buf->writePos - buf->readPos; + else + return buf->size - buf->readPos + buf->writePos; +} diff --git a/src/modules/audio_processing/utility/ring_buffer.h b/src/modules/audio_processing/utility/ring_buffer.h new file mode 100644 index 0000000..0fd261d --- /dev/null +++ b/src/modules/audio_processing/utility/ring_buffer.h @@ -0,0 +1,41 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +/* + * Specifies the interface for the AEC generic buffer. + */ + +#ifndef WEBRTC_MODULES_AUDIO_PROCESSING_UTILITY_RING_BUFFER_H_ +#define WEBRTC_MODULES_AUDIO_PROCESSING_UTILITY_RING_BUFFER_H_ + +// Determines buffer datatype +typedef short bufdata_t; + +// Unless otherwise specified, functions return 0 on success and -1 on error +int WebRtcApm_CreateBuffer(void **bufInst, int size); +int WebRtcApm_InitBuffer(void *bufInst); +int WebRtcApm_FreeBuffer(void *bufInst); + +// Returns number of samples read +int WebRtcApm_ReadBuffer(void *bufInst, bufdata_t *data, int size); + +// Returns number of samples written +int WebRtcApm_WriteBuffer(void *bufInst, const bufdata_t *data, int size); + +// Returns number of samples flushed +int WebRtcApm_FlushBuffer(void *bufInst, int size); + +// Returns number of samples stuffed +int WebRtcApm_StuffBuffer(void *bufInst, int size); + +// Returns number of samples in buffer +int WebRtcApm_get_buffer_size(const void *bufInst); + +#endif // WEBRTC_MODULES_AUDIO_PROCESSING_UTILITY_RING_BUFFER_H_ diff --git a/src/modules/audio_processing/utility/util.gypi b/src/modules/audio_processing/utility/util.gypi new file mode 100644 index 0000000..331de4b --- /dev/null +++ b/src/modules/audio_processing/utility/util.gypi @@ -0,0 +1,33 @@ +# Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. +# +# Use of this source code is governed by a BSD-style license +# that can be found in the LICENSE file in the root of the source +# tree. An additional intellectual property rights grant can be found +# in the file PATENTS. All contributing project authors may +# be found in the AUTHORS file in the root of the source tree. + +{ + 'targets': [ + { + 'target_name': 'apm_util', + 'type': '<(library)', + 'direct_dependent_settings': { + 'include_dirs': [ + '.', + ], + }, + 'sources': [ + 'ring_buffer.c', + 'ring_buffer.h', + 'fft4g.c', + 'fft4g.h', + ], + }, + ], +} + +# Local Variables: +# tab-width:2 +# indent-tabs-mode:nil +# End: +# vim: set expandtab tabstop=2 shiftwidth=2: diff --git a/src/modules/interface/module.h b/src/modules/interface/module.h new file mode 100644 index 0000000..aae9322 --- /dev/null +++ b/src/modules/interface/module.h @@ -0,0 +1,70 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +#ifndef MODULES_INTERFACE_MODULE_H_ +#define MODULES_INTERFACE_MODULE_H_ + +#include + +#include "typedefs.h" + +namespace webrtc { + +class Module { + public: + // Returns version of the module and its components. + virtual int32_t Version(char* version, + uint32_t& remaining_buffer_in_bytes, + uint32_t& position) const = 0; + + // Change the unique identifier of this object. + virtual int32_t ChangeUniqueId(const int32_t id) = 0; + + // Returns the number of milliseconds until the module want a worker + // thread to call Process. + virtual int32_t TimeUntilNextProcess() = 0; + + // Process any pending tasks such as timeouts. + virtual int32_t Process() = 0; + + protected: + virtual ~Module() {} +}; + +// Reference counted version of the module interface. +class RefCountedModule : public Module { + public: + // Increase the reference count by one. + // Returns the incremented reference count. + // TODO(perkj): Make this pure virtual when Chromium have implemented + // reference counting ADM and Video capture module. + virtual int32_t AddRef() { + assert(!"Not implemented."); + return 1; + } + + // Decrease the reference count by one. + // Returns the decreased reference count. + // Returns 0 if the last reference was just released. + // When the reference count reach 0 the object will self-destruct. + // TODO(perkj): Make this pure virtual when Chromium have implemented + // reference counting ADM and Video capture module. + virtual int32_t Release() { + assert(!"Not implemented."); + return 1; + } + + protected: + virtual ~RefCountedModule() {} +}; + +} // namespace webrtc + +#endif // MODULES_INTERFACE_MODULE_H_ diff --git a/src/modules/interface/module_common_types.h b/src/modules/interface/module_common_types.h new file mode 100644 index 0000000..6e35a9d --- /dev/null +++ b/src/modules/interface/module_common_types.h @@ -0,0 +1,1029 @@ +#ifndef MODULE_COMMON_TYPES_H +#define MODULE_COMMON_TYPES_H + +#include // memcpy +#include + +#include "typedefs.h" +#include "common_types.h" + +#ifdef _WIN32 + #pragma warning(disable:4351) // remove warning "new behavior: elements of array + // 'array' will be default initialized" +#endif + +namespace webrtc +{ +struct RTPHeader +{ + bool markerBit; + WebRtc_UWord8 payloadType; + WebRtc_UWord16 sequenceNumber; + WebRtc_UWord32 timestamp; + WebRtc_UWord32 ssrc; + WebRtc_UWord8 numCSRCs; + WebRtc_UWord32 arrOfCSRCs[kRtpCsrcSize]; + WebRtc_UWord8 paddingLength; + WebRtc_UWord16 headerLength; +}; + +struct RTPAudioHeader +{ + WebRtc_UWord8 numEnergy; // number of valid entries in arrOfEnergy + WebRtc_UWord8 arrOfEnergy[kRtpCsrcSize]; // one energy byte (0-9) per channel + bool isCNG; // is this CNG + WebRtc_UWord8 channel; // number of channels 2 = stereo +}; + +struct RTPVideoHeaderH263 +{ + void InitRTPVideoHeaderH263() {}; + bool independentlyDecodable; // H.263-1998 if no P bit it's not independently decodable + bool bits; // H.263 mode B, Xor the lasy byte of previus packet with the + // first byte of this packet +}; +enum {kNoPictureId = -1}; +enum {kNoTl0PicIdx = -1}; +enum {kNoTemporalIdx = -1}; +struct RTPVideoHeaderVP8 +{ + void InitRTPVideoHeaderVP8() + { + nonReference = false; + pictureId = kNoPictureId; + tl0PicIdx = kNoTl0PicIdx; + temporalIdx = kNoTemporalIdx; + partitionId = 0; + beginningOfPartition = false; + } + + bool nonReference; // Frame is discardable. + WebRtc_Word16 pictureId; // Picture ID index, 15 bits; + // kNoPictureId if PictureID does not exist. + WebRtc_Word16 tl0PicIdx; // TL0PIC_IDX, 8 bits; + // kNoTl0PicIdx means no value provided. + WebRtc_Word8 temporalIdx; // Temporal layer index, or kNoTemporalIdx. + int partitionId; // VP8 partition ID + bool beginningOfPartition; // True if this packet is the first + // in a VP8 partition. Otherwise false +}; +union RTPVideoTypeHeader +{ + RTPVideoHeaderH263 H263; + RTPVideoHeaderVP8 VP8; +}; + +enum RTPVideoCodecTypes +{ + kRTPVideoGeneric = 0, + kRTPVideoH263 = 1, + kRTPVideoMPEG4 = 5, + kRTPVideoVP8 = 8, + kRTPVideoNoVideo = 10, + kRTPVideoFEC = 11, + kRTPVideoI420 = 12 +}; +struct RTPVideoHeader +{ + WebRtc_UWord16 width; // size + WebRtc_UWord16 height; + + bool isFirstPacket; // first packet in frame + RTPVideoCodecTypes codec; + RTPVideoTypeHeader codecHeader; +}; +union RTPTypeHeader +{ + RTPAudioHeader Audio; + RTPVideoHeader Video; +}; + +struct WebRtcRTPHeader +{ + RTPHeader header; + FrameType frameType; + RTPTypeHeader type; +}; + +class RTPFragmentationHeader +{ +public: + RTPFragmentationHeader() : + fragmentationVectorSize(0), + fragmentationOffset(NULL), + fragmentationLength(NULL), + fragmentationTimeDiff(NULL), + fragmentationPlType(NULL) + {}; + + ~RTPFragmentationHeader() + { + delete [] fragmentationOffset; + delete [] fragmentationLength; + delete [] fragmentationTimeDiff; + delete [] fragmentationPlType; + } + + RTPFragmentationHeader& operator=(const RTPFragmentationHeader& header) + { + if(this == &header) + { + return *this; + } + + if(header.fragmentationVectorSize != fragmentationVectorSize) + { + // new size of vectors + + // delete old + delete [] fragmentationOffset; + fragmentationOffset = NULL; + delete [] fragmentationLength; + fragmentationLength = NULL; + delete [] fragmentationTimeDiff; + fragmentationTimeDiff = NULL; + delete [] fragmentationPlType; + fragmentationPlType = NULL; + + if(header.fragmentationVectorSize > 0) + { + // allocate new + if(header.fragmentationOffset) + { + fragmentationOffset = new WebRtc_UWord32[header.fragmentationVectorSize]; + } + if(header.fragmentationLength) + { + fragmentationLength = new WebRtc_UWord32[header.fragmentationVectorSize]; + } + if(header.fragmentationTimeDiff) + { + fragmentationTimeDiff = new WebRtc_UWord16[header.fragmentationVectorSize]; + } + if(header.fragmentationPlType) + { + fragmentationPlType = new WebRtc_UWord8[header.fragmentationVectorSize]; + } + } + // set new size + fragmentationVectorSize = header.fragmentationVectorSize; + } + + if(header.fragmentationVectorSize > 0) + { + // copy values + if(header.fragmentationOffset) + { + memcpy(fragmentationOffset, header.fragmentationOffset, + header.fragmentationVectorSize * sizeof(WebRtc_UWord32)); + } + if(header.fragmentationLength) + { + memcpy(fragmentationLength, header.fragmentationLength, + header.fragmentationVectorSize * sizeof(WebRtc_UWord32)); + } + if(header.fragmentationTimeDiff) + { + memcpy(fragmentationTimeDiff, header.fragmentationTimeDiff, + header.fragmentationVectorSize * sizeof(WebRtc_UWord16)); + } + if(header.fragmentationPlType) + { + memcpy(fragmentationPlType, header.fragmentationPlType, + header.fragmentationVectorSize * sizeof(WebRtc_UWord8)); + } + } + return *this; + } + void VerifyAndAllocateFragmentationHeader( const WebRtc_UWord16 size) + { + if( fragmentationVectorSize < size) + { + WebRtc_UWord16 oldVectorSize = fragmentationVectorSize; + { + // offset + WebRtc_UWord32* oldOffsets = fragmentationOffset; + fragmentationOffset = new WebRtc_UWord32[size]; + memset(fragmentationOffset+oldVectorSize, 0, + sizeof(WebRtc_UWord32)*(size-oldVectorSize)); + // copy old values + memcpy(fragmentationOffset,oldOffsets, sizeof(WebRtc_UWord32) * oldVectorSize); + delete[] oldOffsets; + } + // length + { + WebRtc_UWord32* oldLengths = fragmentationLength; + fragmentationLength = new WebRtc_UWord32[size]; + memset(fragmentationLength+oldVectorSize, 0, + sizeof(WebRtc_UWord32) * (size- oldVectorSize)); + memcpy(fragmentationLength, oldLengths, + sizeof(WebRtc_UWord32) * oldVectorSize); + delete[] oldLengths; + } + // time diff + { + WebRtc_UWord16* oldTimeDiffs = fragmentationTimeDiff; + fragmentationTimeDiff = new WebRtc_UWord16[size]; + memset(fragmentationTimeDiff+oldVectorSize, 0, + sizeof(WebRtc_UWord16) * (size- oldVectorSize)); + memcpy(fragmentationTimeDiff, oldTimeDiffs, + sizeof(WebRtc_UWord16) * oldVectorSize); + delete[] oldTimeDiffs; + } + // payload type + { + WebRtc_UWord8* oldTimePlTypes = fragmentationPlType; + fragmentationPlType = new WebRtc_UWord8[size]; + memset(fragmentationPlType+oldVectorSize, 0, + sizeof(WebRtc_UWord8) * (size- oldVectorSize)); + memcpy(fragmentationPlType, oldTimePlTypes, + sizeof(WebRtc_UWord8) * oldVectorSize); + delete[] oldTimePlTypes; + } + fragmentationVectorSize = size; + } + } + + WebRtc_UWord16 fragmentationVectorSize; // Number of fragmentations + WebRtc_UWord32* fragmentationOffset; // Offset of pointer to data for each fragm. + WebRtc_UWord32* fragmentationLength; // Data size for each fragmentation + WebRtc_UWord16* fragmentationTimeDiff; // Timestamp difference relative "now" for + // each fragmentation + WebRtc_UWord8* fragmentationPlType; // Payload type of each fragmentation +}; + +struct RTCPVoIPMetric +{ + // RFC 3611 4.7 + WebRtc_UWord8 lossRate; + WebRtc_UWord8 discardRate; + WebRtc_UWord8 burstDensity; + WebRtc_UWord8 gapDensity; + WebRtc_UWord16 burstDuration; + WebRtc_UWord16 gapDuration; + WebRtc_UWord16 roundTripDelay; + WebRtc_UWord16 endSystemDelay; + WebRtc_UWord8 signalLevel; + WebRtc_UWord8 noiseLevel; + WebRtc_UWord8 RERL; + WebRtc_UWord8 Gmin; + WebRtc_UWord8 Rfactor; + WebRtc_UWord8 extRfactor; + WebRtc_UWord8 MOSLQ; + WebRtc_UWord8 MOSCQ; + WebRtc_UWord8 RXconfig; + WebRtc_UWord16 JBnominal; + WebRtc_UWord16 JBmax; + WebRtc_UWord16 JBabsMax; +}; + +// class describing a complete, or parts of an encoded frame. +class EncodedVideoData +{ +public: + EncodedVideoData() : + completeFrame(false), + missingFrame(false), + payloadData(NULL), + payloadSize(0), + bufferSize(0) + {}; + + EncodedVideoData(const EncodedVideoData& data) + { + payloadType = data.payloadType; + timeStamp = data.timeStamp; + renderTimeMs = data.renderTimeMs; + encodedWidth = data.encodedWidth; + encodedHeight = data.encodedHeight; + completeFrame = data.completeFrame; + missingFrame = data.missingFrame; + payloadSize = data.payloadSize; + fragmentationHeader = data.fragmentationHeader; + frameType = data.frameType; + codec = data.codec; + if (data.payloadSize > 0) + { + payloadData = new WebRtc_UWord8[data.payloadSize]; + memcpy(payloadData, data.payloadData, data.payloadSize); + } + else + { + payloadData = NULL; + } + } + + + ~EncodedVideoData() + { + delete [] payloadData; + }; + + EncodedVideoData& operator=(const EncodedVideoData& data) + { + if (this == &data) + { + return *this; + } + payloadType = data.payloadType; + timeStamp = data.timeStamp; + renderTimeMs = data.renderTimeMs; + encodedWidth = data.encodedWidth; + encodedHeight = data.encodedHeight; + completeFrame = data.completeFrame; + missingFrame = data.missingFrame; + payloadSize = data.payloadSize; + fragmentationHeader = data.fragmentationHeader; + frameType = data.frameType; + codec = data.codec; + if (data.payloadSize > 0) + { + delete [] payloadData; + payloadData = new WebRtc_UWord8[data.payloadSize]; + memcpy(payloadData, data.payloadData, data.payloadSize); + bufferSize = data.payloadSize; + } + return *this; + }; + void VerifyAndAllocate( const WebRtc_UWord32 size) + { + if (bufferSize < size) + { + WebRtc_UWord8* oldPayload = payloadData; + payloadData = new WebRtc_UWord8[size]; + memcpy(payloadData, oldPayload, sizeof(WebRtc_UWord8) * payloadSize); + + bufferSize = size; + delete[] oldPayload; + } + } + + WebRtc_UWord8 payloadType; + WebRtc_UWord32 timeStamp; + WebRtc_Word64 renderTimeMs; + WebRtc_UWord32 encodedWidth; + WebRtc_UWord32 encodedHeight; + bool completeFrame; + bool missingFrame; + WebRtc_UWord8* payloadData; + WebRtc_UWord32 payloadSize; + WebRtc_UWord32 bufferSize; + RTPFragmentationHeader fragmentationHeader; + FrameType frameType; + VideoCodecType codec; +}; + +// Video Content Metrics +struct VideoContentMetrics +{ + VideoContentMetrics(): motionMagnitudeNZ(0), sizeZeroMotion(0), spatialPredErr(0), + spatialPredErrH(0), spatialPredErrV(0), motionPredErr(0), + motionHorizontalness(0), motionClusterDistortion(0), + nativeWidth(0), nativeHeight(0), contentChange(false) { } + void Reset(){ motionMagnitudeNZ = 0; sizeZeroMotion = 0; spatialPredErr = 0; + spatialPredErrH = 0; spatialPredErrV = 0; motionPredErr = 0; + motionHorizontalness = 0; motionClusterDistortion = 0; + nativeWidth = 0; nativeHeight = 0; contentChange = false; } + + float motionMagnitudeNZ; + float sizeZeroMotion; + float spatialPredErr; + float spatialPredErrH; + float spatialPredErrV; + float motionPredErr; + float motionHorizontalness; + float motionClusterDistortion; + WebRtc_UWord32 nativeWidth; + WebRtc_UWord32 nativeHeight; + WebRtc_UWord32 nativeFrameRate; + bool contentChange; +}; + +/************************************************* + * + * VideoFrame class + * + * The VideoFrame class allows storing and + * handling of video frames. + * + * + *************************************************/ +class VideoFrame +{ +public: + VideoFrame(); + ~VideoFrame(); + /** + * Verifies that current allocated buffer size is larger than or equal to the input size. + * If the current buffer size is smaller, a new allocation is made and the old buffer data + * is copied to the new buffer. + * Buffer size is updated to minimumSize. + */ + WebRtc_Word32 VerifyAndAllocate(const WebRtc_UWord32 minimumSize); + /** + * Update length of data buffer in frame. Function verifies that new length is less or + * equal to allocated size. + */ + WebRtc_Word32 SetLength(const WebRtc_UWord32 newLength); + /* + * Swap buffer and size data + */ + WebRtc_Word32 Swap(WebRtc_UWord8*& newMemory, + WebRtc_UWord32& newLength, + WebRtc_UWord32& newSize); + /* + * Swap buffer and size data + */ + WebRtc_Word32 SwapFrame(VideoFrame& videoFrame); + /** + * Copy buffer: If newLength is bigger than allocated size, a new buffer of size length + * is allocated. + */ + WebRtc_Word32 CopyFrame(const VideoFrame& videoFrame); + /** + * Copy buffer: If newLength is bigger than allocated size, a new buffer of size length + * is allocated. + */ + WebRtc_Word32 CopyFrame(WebRtc_UWord32 length, const WebRtc_UWord8* sourceBuffer); + /** + * Delete VideoFrame and resets members to zero + */ + void Free(); + /** + * Set frame timestamp (90kHz) + */ + void SetTimeStamp(const WebRtc_UWord32 timeStamp) {_timeStamp = timeStamp;} + /** + * Get pointer to frame buffer + */ + WebRtc_UWord8* Buffer() const {return _buffer;} + + WebRtc_UWord8*& Buffer() {return _buffer;} + + /** + * Get allocated buffer size + */ + WebRtc_UWord32 Size() const {return _bufferSize;} + /** + * Get frame length + */ + WebRtc_UWord32 Length() const {return _bufferLength;} + /** + * Get frame timestamp (90kHz) + */ + WebRtc_UWord32 TimeStamp() const {return _timeStamp;} + /** + * Get frame width + */ + WebRtc_UWord32 Width() const {return _width;} + /** + * Get frame height + */ + WebRtc_UWord32 Height() const {return _height;} + /** + * Set frame width + */ + void SetWidth(const WebRtc_UWord32 width) {_width = width;} + /** + * Set frame height + */ + void SetHeight(const WebRtc_UWord32 height) {_height = height;} + /** + * Set render time in miliseconds + */ + void SetRenderTime(const WebRtc_Word64 renderTimeMs) {_renderTimeMs = renderTimeMs;} + /** + * Get render time in miliseconds + */ + WebRtc_Word64 RenderTimeMs() const {return _renderTimeMs;} + +private: + void Set(WebRtc_UWord8* buffer, + WebRtc_UWord32 size, + WebRtc_UWord32 length, + WebRtc_UWord32 timeStamp); + + WebRtc_UWord8* _buffer; // Pointer to frame buffer + WebRtc_UWord32 _bufferSize; // Allocated buffer size + WebRtc_UWord32 _bufferLength; // Length (in bytes) of buffer + WebRtc_UWord32 _timeStamp; // Timestamp of frame (90kHz) + WebRtc_UWord32 _width; + WebRtc_UWord32 _height; + WebRtc_Word64 _renderTimeMs; +}; // end of VideoFrame class declaration + +// inline implementation of VideoFrame class: +inline +VideoFrame::VideoFrame(): + _buffer(0), + _bufferSize(0), + _bufferLength(0), + _timeStamp(0), + _width(0), + _height(0), + _renderTimeMs(0) +{ + // +} +inline +VideoFrame::~VideoFrame() +{ + if(_buffer) + { + delete [] _buffer; + _buffer = NULL; + } +} + + +inline +WebRtc_Word32 +VideoFrame::VerifyAndAllocate(const WebRtc_UWord32 minimumSize) +{ + if (minimumSize < 1) + { + return -1; + } + if(minimumSize > _bufferSize) + { + // create buffer of sufficient size + WebRtc_UWord8* newBufferBuffer = new WebRtc_UWord8[minimumSize]; + if(_buffer) + { + // copy old data + memcpy(newBufferBuffer, _buffer, _bufferSize); + delete [] _buffer; + } + _buffer = newBufferBuffer; + _bufferSize = minimumSize; + } + return 0; +} + +inline +WebRtc_Word32 +VideoFrame::SetLength(const WebRtc_UWord32 newLength) +{ + if (newLength >_bufferSize ) + { // can't accomodate new value + return -1; + } + _bufferLength = newLength; + return 0; +} + +inline +WebRtc_Word32 +VideoFrame::SwapFrame(VideoFrame& videoFrame) +{ + WebRtc_UWord32 tmpTimeStamp = _timeStamp; + WebRtc_UWord32 tmpWidth = _width; + WebRtc_UWord32 tmpHeight = _height; + WebRtc_Word64 tmpRenderTime = _renderTimeMs; + + _timeStamp = videoFrame._timeStamp; + _width = videoFrame._width; + _height = videoFrame._height; + _renderTimeMs = videoFrame._renderTimeMs; + + videoFrame._timeStamp = tmpTimeStamp; + videoFrame._width = tmpWidth; + videoFrame._height = tmpHeight; + videoFrame._renderTimeMs = tmpRenderTime; + + return Swap(videoFrame._buffer, videoFrame._bufferLength, videoFrame._bufferSize); +} + +inline +WebRtc_Word32 +VideoFrame::Swap(WebRtc_UWord8*& newMemory, WebRtc_UWord32& newLength, WebRtc_UWord32& newSize) +{ + WebRtc_UWord8* tmpBuffer = _buffer; + WebRtc_UWord32 tmpLength = _bufferLength; + WebRtc_UWord32 tmpSize = _bufferSize; + _buffer = newMemory; + _bufferLength = newLength; + _bufferSize = newSize; + newMemory = tmpBuffer; + newLength = tmpLength; + newSize = tmpSize; + return 0; +} + +inline +WebRtc_Word32 +VideoFrame::CopyFrame(WebRtc_UWord32 length, const WebRtc_UWord8* sourceBuffer) +{ + if (length > _bufferSize) + { + WebRtc_Word32 ret = VerifyAndAllocate(length); + if (ret < 0) + { + return ret; + } + } + memcpy(_buffer, sourceBuffer, length); + _bufferLength = length; + return 0; +} + +inline +WebRtc_Word32 +VideoFrame::CopyFrame(const VideoFrame& videoFrame) +{ + if(CopyFrame(videoFrame.Length(), videoFrame.Buffer()) != 0) + { + return -1; + } + _timeStamp = videoFrame._timeStamp; + _width = videoFrame._width; + _height = videoFrame._height; + _renderTimeMs = videoFrame._renderTimeMs; + return 0; +} + +inline +void +VideoFrame::Free() +{ + _timeStamp = 0; + _bufferLength = 0; + _bufferSize = 0; + _height = 0; + _width = 0; + _renderTimeMs = 0; + + if(_buffer) + { + delete [] _buffer; + _buffer = NULL; + } +} + + +/************************************************* + * + * AudioFrame class + * + * The AudioFrame class holds up to 60 ms wideband + * audio. It allows for adding and subtracting frames + * while keeping track of the resulting states. + * + * Note + * - The +operator assume that you would never add + * exact opposite frames when deciding the resulting + * state. To do this use the -operator. + * + * - _audioChannel of 1 indicated mono, and 2 + * indicates stereo. + * + * - _payloadDataLengthInSamples is the number of + * samples per channel. Therefore, the total + * number of samples in _payloadData is + * (_payloadDataLengthInSamples * _audioChannel). + * + * - Stereo data is stored in interleaved fashion + * starting with the left channel. + * + *************************************************/ +class AudioFrame +{ +public: + enum{kMaxAudioFrameSizeSamples = 3840}; // stereo 32KHz 60ms 2*32*60 + + enum VADActivity + { + kVadActive = 0, + kVadPassive = 1, + kVadUnknown = 2 + }; + enum SpeechType + { + kNormalSpeech = 0, + kPLC = 1, + kCNG = 2, + kPLCCNG = 3, + kUndefined = 4 + }; + + AudioFrame(); + virtual ~AudioFrame(); + + WebRtc_Word32 UpdateFrame( + const WebRtc_Word32 id, + const WebRtc_UWord32 timeStamp, + const WebRtc_Word16* payloadData, + const WebRtc_UWord16 payloadDataLengthInSamples, + const int frequencyInHz, + const SpeechType speechType, + const VADActivity vadActivity, + const WebRtc_UWord8 audioChannel = 1, + const WebRtc_Word32 volume = -1, + const WebRtc_Word32 energy = -1); + + AudioFrame& Append(const AudioFrame& rhs); + + void Mute() const; + + AudioFrame& operator=(const AudioFrame& rhs); + AudioFrame& operator>>=(const WebRtc_Word32 rhs); + AudioFrame& operator+=(const AudioFrame& rhs); + AudioFrame& operator-=(const AudioFrame& rhs); + + WebRtc_Word32 _id; + WebRtc_UWord32 _timeStamp; + + // Supporting Stereo, stereo samples are interleaved + mutable WebRtc_Word16 _payloadData[kMaxAudioFrameSizeSamples]; + WebRtc_UWord16 _payloadDataLengthInSamples; + int _frequencyInHz; + WebRtc_UWord8 _audioChannel; + SpeechType _speechType; + VADActivity _vadActivity; + + WebRtc_UWord32 _energy; + WebRtc_Word32 _volume; +}; + +inline +AudioFrame::AudioFrame() + : + _id(-1), + _timeStamp(0), + _payloadData(), + _payloadDataLengthInSamples(0), + _frequencyInHz(0), + _audioChannel(1), + _speechType(kUndefined), + _vadActivity(kVadUnknown), + _energy(0xffffffff), + _volume(0xffffffff) +{ +} + +inline +AudioFrame::~AudioFrame() +{ +} + +inline +WebRtc_Word32 +AudioFrame::UpdateFrame( + const WebRtc_Word32 id, + const WebRtc_UWord32 timeStamp, + const WebRtc_Word16* payloadData, + const WebRtc_UWord16 payloadDataLengthInSamples, + const int frequencyInHz, + const SpeechType speechType, + const VADActivity vadActivity, + const WebRtc_UWord8 audioChannel, + const WebRtc_Word32 volume, + const WebRtc_Word32 energy) +{ + _id = id; + _timeStamp = timeStamp; + _frequencyInHz = frequencyInHz; + _speechType = speechType; + _vadActivity = vadActivity; + _volume = volume; + _audioChannel = audioChannel; + _energy = energy; + + if((payloadDataLengthInSamples > kMaxAudioFrameSizeSamples) || + (audioChannel > 2) || (audioChannel < 1)) + { + _payloadDataLengthInSamples = 0; + return -1; + } + _payloadDataLengthInSamples = payloadDataLengthInSamples; + if(payloadData != NULL) + { + memcpy(_payloadData, payloadData, sizeof(WebRtc_Word16) * + payloadDataLengthInSamples * _audioChannel); + } + else + { + memset(_payloadData,0,sizeof(WebRtc_Word16) * + payloadDataLengthInSamples * _audioChannel); + } + return 0; +} + +inline +void +AudioFrame::Mute() const +{ + memset(_payloadData, 0, _payloadDataLengthInSamples * sizeof(WebRtc_Word16)); +} + +inline +AudioFrame& +AudioFrame::operator=(const AudioFrame& rhs) +{ + // Sanity Check + if((rhs._payloadDataLengthInSamples > kMaxAudioFrameSizeSamples) || + (rhs._audioChannel > 2) || + (rhs._audioChannel < 1)) + { + return *this; + } + if(this == &rhs) + { + return *this; + } + _id = rhs._id; + _timeStamp = rhs._timeStamp; + _frequencyInHz = rhs._frequencyInHz; + _speechType = rhs._speechType; + _vadActivity = rhs._vadActivity; + _volume = rhs._volume; + _audioChannel = rhs._audioChannel; + _energy = rhs._energy; + + _payloadDataLengthInSamples = rhs._payloadDataLengthInSamples; + memcpy(_payloadData, rhs._payloadData, + sizeof(WebRtc_Word16) * rhs._payloadDataLengthInSamples * _audioChannel); + + return *this; +} + +inline +AudioFrame& +AudioFrame::operator>>=(const WebRtc_Word32 rhs) +{ + assert((_audioChannel > 0) && (_audioChannel < 3)); + if((_audioChannel > 2) || + (_audioChannel < 1)) + { + return *this; + } + for(WebRtc_UWord16 i = 0; i < _payloadDataLengthInSamples * _audioChannel; i++) + { + _payloadData[i] = WebRtc_Word16(_payloadData[i] >> rhs); + } + return *this; +} + +inline +AudioFrame& +AudioFrame::Append(const AudioFrame& rhs) +{ + // Sanity check + assert((_audioChannel > 0) && (_audioChannel < 3)); + if((_audioChannel > 2) || + (_audioChannel < 1)) + { + return *this; + } + if(_audioChannel != rhs._audioChannel) + { + return *this; + } + if((_vadActivity == kVadActive) || + rhs._vadActivity == kVadActive) + { + _vadActivity = kVadActive; + } + else if((_vadActivity == kVadUnknown) || + rhs._vadActivity == kVadUnknown) + { + _vadActivity = kVadUnknown; + } + if(_speechType != rhs._speechType) + { + _speechType = kUndefined; + } + + WebRtc_UWord16 offset = _payloadDataLengthInSamples * _audioChannel; + for(WebRtc_UWord16 i = 0; + i < rhs._payloadDataLengthInSamples * rhs._audioChannel; + i++) + { + _payloadData[offset+i] = rhs._payloadData[i]; + } + _payloadDataLengthInSamples += rhs._payloadDataLengthInSamples; + return *this; +} + +// merge vectors +inline +AudioFrame& +AudioFrame::operator+=(const AudioFrame& rhs) +{ + // Sanity check + assert((_audioChannel > 0) && (_audioChannel < 3)); + if((_audioChannel > 2) || + (_audioChannel < 1)) + { + return *this; + } + if(_audioChannel != rhs._audioChannel) + { + return *this; + } + bool noPrevData = false; + if(_payloadDataLengthInSamples != rhs._payloadDataLengthInSamples) + { + if(_payloadDataLengthInSamples == 0) + { + // special case we have no data to start with + _payloadDataLengthInSamples = rhs._payloadDataLengthInSamples; + noPrevData = true; + } else + { + return *this; + } + } + + if((_vadActivity == kVadActive) || + rhs._vadActivity == kVadActive) + { + _vadActivity = kVadActive; + } + else if((_vadActivity == kVadUnknown) || + rhs._vadActivity == kVadUnknown) + { + _vadActivity = kVadUnknown; + } + + if(_speechType != rhs._speechType) + { + _speechType = kUndefined; + } + + if(noPrevData) + { + memcpy(_payloadData, rhs._payloadData, + sizeof(WebRtc_Word16) * rhs._payloadDataLengthInSamples * _audioChannel); + } else + { + // IMPROVEMENT this can be done very fast in assembly + for(WebRtc_UWord16 i = 0; i < _payloadDataLengthInSamples * _audioChannel; i++) + { + WebRtc_Word32 wrapGuard = (WebRtc_Word32)_payloadData[i] + + (WebRtc_Word32)rhs._payloadData[i]; + if(wrapGuard < -32768) + { + _payloadData[i] = -32768; + }else if(wrapGuard > 32767) + { + _payloadData[i] = 32767; + }else + { + _payloadData[i] = (WebRtc_Word16)wrapGuard; + } + } + } + _energy = 0xffffffff; + _volume = 0xffffffff; + return *this; +} + +inline +AudioFrame& +AudioFrame::operator-=(const AudioFrame& rhs) +{ + // Sanity check + assert((_audioChannel > 0) && (_audioChannel < 3)); + if((_audioChannel > 2)|| + (_audioChannel < 1)) + { + return *this; + } + if((_payloadDataLengthInSamples != rhs._payloadDataLengthInSamples) || + (_audioChannel != rhs._audioChannel)) + { + return *this; + } + if((_vadActivity != kVadPassive) || + rhs._vadActivity != kVadPassive) + { + _vadActivity = kVadUnknown; + } + _speechType = kUndefined; + + for(WebRtc_UWord16 i = 0; i < _payloadDataLengthInSamples * _audioChannel; i++) + { + WebRtc_Word32 wrapGuard = (WebRtc_Word32)_payloadData[i] - + (WebRtc_Word32)rhs._payloadData[i]; + if(wrapGuard < -32768) + { + _payloadData[i] = -32768; + } + else if(wrapGuard > 32767) + { + _payloadData[i] = 32767; + } + else + { + _payloadData[i] = (WebRtc_Word16)wrapGuard; + } + } + _energy = 0xffffffff; + _volume = 0xffffffff; + return *this; +} + +} // namespace webrtc + +#endif // MODULE_COMMON_TYPES_H diff --git a/src/system_wrappers/OWNERS b/src/system_wrappers/OWNERS new file mode 100644 index 0000000..4091a93 --- /dev/null +++ b/src/system_wrappers/OWNERS @@ -0,0 +1,7 @@ +henrike@webrtc.org +pwestin@webrtc.org +perkj@webrtc.org +henrika@webrtc.org +henrikg@webrtc.org +mflodman@webrtc.org +niklas.enbom@webrtc.org \ No newline at end of file diff --git a/src/system_wrappers/interface/cpu_features_wrapper.h b/src/system_wrappers/interface/cpu_features_wrapper.h new file mode 100644 index 0000000..5d8a828 --- /dev/null +++ b/src/system_wrappers/interface/cpu_features_wrapper.h @@ -0,0 +1,34 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +#ifndef WEBRTC_SYSTEM_WRAPPERS_INTERFACE_CPU_FEATURES_WRAPPER_H_ +#define WEBRTC_SYSTEM_WRAPPERS_INTERFACE_CPU_FEATURES_WRAPPER_H_ + +#if defined(__cplusplus) || defined(c_plusplus) +extern "C" { +#endif + +// list of features. +typedef enum { + kSSE2, + kSSE3 +} CPUFeature; + +typedef int (*WebRtc_CPUInfo)(CPUFeature feature); +// returns true if the CPU supports the feature. +extern WebRtc_CPUInfo WebRtc_GetCPUInfo; +// No CPU feature is available => straight C path. +extern WebRtc_CPUInfo WebRtc_GetCPUInfoNoASM; + +#if defined(__cplusplus) || defined(c_plusplus) +} // extern "C" +#endif + +#endif // WEBRTC_SYSTEM_WRAPPERS_INTERFACE_CPU_FEATURES_WRAPPER_H_ diff --git a/src/system_wrappers/interface/critical_section_wrapper.h b/src/system_wrappers/interface/critical_section_wrapper.h new file mode 100644 index 0000000..ad31497 --- /dev/null +++ b/src/system_wrappers/interface/critical_section_wrapper.h @@ -0,0 +1,66 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +#ifndef WEBRTC_SYSTEM_WRAPPERS_INTERFACE_CRITICAL_SECTION_WRAPPER_H_ +#define WEBRTC_SYSTEM_WRAPPERS_INTERFACE_CRITICAL_SECTION_WRAPPER_H_ + +// If the critical section is heavily contended it may be beneficial to use +// read/write locks instead. + +#include "common_types.h" + +namespace webrtc { +class CriticalSectionWrapper +{ +public: + // Factory method, constructor disabled + static CriticalSectionWrapper* CreateCriticalSection(); + + virtual ~CriticalSectionWrapper() {} + + // Tries to grab lock, beginning of a critical section. Will wait for the + // lock to become available if the grab failed. + virtual void Enter() = 0; + + // Returns a grabbed lock, end of critical section. + virtual void Leave() = 0; +}; + +// RAII extension of the critical section. Prevents Enter/Leave missmatches and +// provides more compact critical section syntax. +class CriticalSectionScoped +{ +public: + CriticalSectionScoped(CriticalSectionWrapper& critsec) + : + _ptrCritSec(&critsec) + { + _ptrCritSec->Enter(); + } + + ~CriticalSectionScoped() + { + if (_ptrCritSec) + { + Leave(); + } + } + +private: + void Leave() + { + _ptrCritSec->Leave(); + _ptrCritSec = 0; + } + + CriticalSectionWrapper* _ptrCritSec; +}; +} // namespace webrtc +#endif // WEBRTC_SYSTEM_WRAPPERS_INTERFACE_CRITICAL_SECTION_WRAPPER_H_ diff --git a/src/system_wrappers/source/cpu_features.cc b/src/system_wrappers/source/cpu_features.cc new file mode 100644 index 0000000..41a86e3 --- /dev/null +++ b/src/system_wrappers/source/cpu_features.cc @@ -0,0 +1,74 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +// Parts of this file derived from Chromium's base/cpu.cc. + +#include "cpu_features_wrapper.h" + +#include "typedefs.h" + +#if defined(WEBRTC_ARCH_X86_FAMILY) +#if defined(_MSC_VER) +#include +#endif +#endif + +// No CPU feature is available => straight C path. +int GetCPUInfoNoASM(CPUFeature feature) { + (void)feature; + return 0; +} + +#if defined(WEBRTC_ARCH_X86_FAMILY) +#ifndef _MSC_VER +// Intrinsic for "cpuid". +#if defined(__pic__) && defined(__i386__) +static inline void __cpuid(int cpu_info[4], int info_type) { + __asm__ volatile ( + "mov %%ebx, %%edi\n" + "cpuid\n" + "xchg %%edi, %%ebx\n" + : "=a"(cpu_info[0]), "=D"(cpu_info[1]), "=c"(cpu_info[2]), "=d"(cpu_info[3]) + : "a"(info_type)); +} +#else +static inline void __cpuid(int cpu_info[4], int info_type) { + __asm__ volatile ( + "cpuid\n" + : "=a"(cpu_info[0]), "=b"(cpu_info[1]), "=c"(cpu_info[2]), "=d"(cpu_info[3]) + : "a"(info_type)); +} +#endif +#endif // _MSC_VER +#endif // WEBRTC_ARCH_X86_FAMILY + +#if defined(WEBRTC_ARCH_X86_FAMILY) +// Actual feature detection for x86. +static int GetCPUInfo(CPUFeature feature) { + int cpu_info[4]; + __cpuid(cpu_info, 1); + if (feature == kSSE2) { + return 0 != (cpu_info[3] & 0x04000000); + } + if (feature == kSSE3) { + return 0 != (cpu_info[2] & 0x00000001); + } + return 0; +} +#else +// Default to straight C for other platforms. +static int GetCPUInfo(CPUFeature feature) { + (void)feature; + return 0; +} +#endif + +WebRtc_CPUInfo WebRtc_GetCPUInfo = GetCPUInfo; +WebRtc_CPUInfo WebRtc_GetCPUInfoNoASM = GetCPUInfoNoASM; diff --git a/src/system_wrappers/source/critical_section.cc b/src/system_wrappers/source/critical_section.cc new file mode 100644 index 0000000..413f889 --- /dev/null +++ b/src/system_wrappers/source/critical_section.cc @@ -0,0 +1,27 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +#if defined(_WIN32) + #include + #include "critical_section_windows.h" +#else + #include "critical_section_posix.h" +#endif + +namespace webrtc { +CriticalSectionWrapper* CriticalSectionWrapper::CreateCriticalSection() +{ +#ifdef _WIN32 + return new CriticalSectionWindows(); +#else + return new CriticalSectionPosix(); +#endif +} +} // namespace webrtc diff --git a/src/system_wrappers/source/critical_section_posix.cc b/src/system_wrappers/source/critical_section_posix.cc new file mode 100644 index 0000000..b499b9f --- /dev/null +++ b/src/system_wrappers/source/critical_section_posix.cc @@ -0,0 +1,38 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +#include "critical_section_posix.h" + +namespace webrtc { +CriticalSectionPosix::CriticalSectionPosix() +{ + pthread_mutexattr_t attr; + pthread_mutexattr_init(&attr); + pthread_mutexattr_settype(&attr, PTHREAD_MUTEX_RECURSIVE); + pthread_mutex_init(&_mutex, &attr); +} + +CriticalSectionPosix::~CriticalSectionPosix() +{ + pthread_mutex_destroy(&_mutex); +} + +void +CriticalSectionPosix::Enter() +{ + pthread_mutex_lock(&_mutex); +} + +void +CriticalSectionPosix::Leave() +{ + pthread_mutex_unlock(&_mutex); +} +} // namespace webrtc diff --git a/src/system_wrappers/source/critical_section_posix.h b/src/system_wrappers/source/critical_section_posix.h new file mode 100644 index 0000000..40b7dc9 --- /dev/null +++ b/src/system_wrappers/source/critical_section_posix.h @@ -0,0 +1,35 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +#ifndef WEBRTC_SYSTEM_WRAPPERS_SOURCE_CRITICAL_SECTION_POSIX_H_ +#define WEBRTC_SYSTEM_WRAPPERS_SOURCE_CRITICAL_SECTION_POSIX_H_ + +#include "critical_section_wrapper.h" + +#include + +namespace webrtc { +class CriticalSectionPosix : public CriticalSectionWrapper +{ +public: + CriticalSectionPosix(); + + virtual ~CriticalSectionPosix(); + + virtual void Enter(); + virtual void Leave(); + +private: + pthread_mutex_t _mutex; + friend class ConditionVariablePosix; +}; +} // namespace webrtc + +#endif // WEBRTC_SYSTEM_WRAPPERS_SOURCE_CRITICAL_SECTION_POSIX_H_ diff --git a/src/system_wrappers/source/critical_section_windows.cc b/src/system_wrappers/source/critical_section_windows.cc new file mode 100644 index 0000000..1ca5751 --- /dev/null +++ b/src/system_wrappers/source/critical_section_windows.cc @@ -0,0 +1,35 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +#include "critical_section_windows.h" + +namespace webrtc { +CriticalSectionWindows::CriticalSectionWindows() +{ + InitializeCriticalSection(&crit); +} + +CriticalSectionWindows::~CriticalSectionWindows() +{ + DeleteCriticalSection(&crit); +} + +void +CriticalSectionWindows::Enter() +{ + EnterCriticalSection(&crit); +} + +void +CriticalSectionWindows::Leave() +{ + LeaveCriticalSection(&crit); +} +} // namespace webrtc diff --git a/src/system_wrappers/source/critical_section_windows.h b/src/system_wrappers/source/critical_section_windows.h new file mode 100644 index 0000000..9556fa9 --- /dev/null +++ b/src/system_wrappers/source/critical_section_windows.h @@ -0,0 +1,36 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +#ifndef WEBRTC_SYSTEM_WRAPPERS_SOURCE_CRITICAL_SECTION_WINDOWS_H_ +#define WEBRTC_SYSTEM_WRAPPERS_SOURCE_CRITICAL_SECTION_WINDOWS_H_ + +#include "typedefs.h" +#include "critical_section_wrapper.h" +#include + +namespace webrtc { +class CriticalSectionWindows : public CriticalSectionWrapper +{ +public: + CriticalSectionWindows(); + + virtual ~CriticalSectionWindows(); + + virtual void Enter(); + virtual void Leave(); + +private: + CRITICAL_SECTION crit; + + friend class ConditionVariableWindows; +}; +} // namespace webrtc + +#endif // WEBRTC_SYSTEM_WRAPPERS_SOURCE_CRITICAL_SECTION_WINDOWS_H_ diff --git a/src/system_wrappers/source/system_wrappers.gyp b/src/system_wrappers/source/system_wrappers.gyp new file mode 100644 index 0000000..c3e98ea --- /dev/null +++ b/src/system_wrappers/source/system_wrappers.gyp @@ -0,0 +1,167 @@ +# Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. +# +# Use of this source code is governed by a BSD-style license +# that can be found in the LICENSE file in the root of the source +# tree. An additional intellectual property rights grant can be found +# in the file PATENTS. All contributing project authors may +# be found in the AUTHORS file in the root of the source tree. + +# TODO: Rename files to use *_linux.cpp etc. names, to automatically include relevant files. Remove conditions section. + +{ + 'includes': [ + '../../common_settings.gypi', # Common settings + ], + 'targets': [ + { + 'target_name': 'system_wrappers', + 'type': '<(library)', + 'include_dirs': [ + 'spreadsortlib', + '../interface', + ], + 'direct_dependent_settings': { + 'include_dirs': [ + '../interface', + ], + }, + 'sources': [ + '../interface/aligned_malloc.h', + '../interface/atomic32_wrapper.h', + '../interface/condition_variable_wrapper.h', + '../interface/cpu_wrapper.h', + '../interface/cpu_features_wrapper.h', + '../interface/critical_section_wrapper.h', + '../interface/data_log.h', + '../interface/data_log_impl.h', + '../interface/event_wrapper.h', + '../interface/file_wrapper.h', + '../interface/fix_interlocked_exchange_pointer_windows.h', + '../interface/list_wrapper.h', + '../interface/map_wrapper.h', + '../interface/ref_count.h', + '../interface/rw_lock_wrapper.h', + '../interface/scoped_ptr.h', + '../interface/scoped_refptr.h', + '../interface/sort.h', + '../interface/thread_wrapper.h', + '../interface/tick_util.h', + '../interface/trace.h', + 'aligned_malloc.cc', + 'atomic32.cc', + 'atomic32_linux.h', + 'atomic32_mac.h', + 'atomic32_windows.h', + 'condition_variable.cc', + 'condition_variable_posix.h', + 'condition_variable_windows.h', + 'cpu.cc', + 'cpu_linux.h', + 'cpu_mac.h', + 'cpu_windows.h', + 'cpu_features.cc', + 'critical_section.cc', + 'critical_section_posix.h', + 'critical_section_windows.h', + 'event.cc', + 'event_posix.h', + 'event_windows.h', + 'file_impl.cc', + 'file_impl.h', + 'list_no_stl.cc', + 'map.cc', + 'rw_lock.cc', + 'rw_lock_posix.h', + 'rw_lock_windows.h', + 'sort.cc', + 'thread.cc', + 'thread_posix.h', + 'thread_windows.h', + 'thread_windows_set_name.h', + 'trace_impl.cc', + 'trace_impl.h', + 'trace_posix.h', + 'trace_windows.h', + ], + 'conditions': [ + ['os_posix==1', { + 'sources': [ + 'condition_variable_posix.cc', + 'critical_section_posix.cc', + 'event_posix.cc', + 'rw_lock_posix.cc', + 'thread_posix.cc', + 'trace_posix.cc', + ], + }], + ['enable_data_logging==1', { + 'sources': [ + 'data_log.cc', + ], + },{ + 'sources': [ + 'data_log_dummy.cc', + ], + },], + ['OS=="linux"', { + 'sources': [ + 'cpu_linux.cc', + ], + 'link_settings': { + 'libraries': [ + '-lrt', + ], + }, + }], + ['OS=="mac"', { + 'sources': [ + 'cpu_mac.cc', + ], + 'link_settings': { + 'libraries': [ + '$(SDKROOT)/System/Library/Frameworks/ApplicationServices.framework', + ], + }, + }], + ['OS=="win"', { + 'sources': [ + 'condition_variable_windows.cc', + 'cpu_windows.cc', + 'critical_section_windows.cc', + 'event_windows.cc', + 'rw_lock_windows.cc', + 'thread_windows.cc', + 'trace_windows.cc', + ], + 'link_settings': { + 'libraries': [ + '-lwinmm.lib', + ], + }, + }], + ] # conditions + }, + ], # targets + 'conditions': [ + ['build_with_chromium==0', { + 'targets': [ + { + 'target_name': 'system_wrappersTest', + 'type': 'executable', + 'dependencies': [ + 'system_wrappers' + ], + 'sources': [ + '../test/Test.cpp', + ], + }, + ], # targets + }], # build_with_chromium + ], # conditions +} + +# Local Variables: +# tab-width:2 +# indent-tabs-mode:nil +# End: +# vim: set expandtab tabstop=2 shiftwidth=2: diff --git a/src/typedefs.h b/src/typedefs.h new file mode 100644 index 0000000..6620550 --- /dev/null +++ b/src/typedefs.h @@ -0,0 +1,140 @@ +/* + * Copyright (c) 2011 The WebRTC project authors. All Rights Reserved. + * + * Use of this source code is governed by a BSD-style license + * that can be found in the LICENSE file in the root of the source + * tree. An additional intellectual property rights grant can be found + * in the file PATENTS. All contributing project authors may + * be found in the AUTHORS file in the root of the source tree. + */ + +// This file contains platform-specific typedefs and defines. + +#ifndef WEBRTC_TYPEDEFS_H_ +#define WEBRTC_TYPEDEFS_H_ + +// Reserved words definitions +#define WEBRTC_EXTERN extern +#define G_CONST const +#define WEBRTC_INLINE extern __inline + +// Define WebRTC preprocessor identifiers based on the current build platform. +// TODO(ajm): Clean these up. We can probably remove everything in this block. +// - TARGET_MAC_INTEL and TARGET_MAC aren't used anywhere. +// - In the few places where TARGET_PC is used, it should be replaced by +// something more specific. +// - Do we really support PowerPC? Probably not. Remove WEBRTC_MAC_INTEL +// from build/common.gypi as well. +#if defined(WIN32) + // Windows & Windows Mobile + #if !defined(WEBRTC_TARGET_PC) + #define WEBRTC_TARGET_PC + #endif +#elif defined(__APPLE__) + // Mac OS X + #if defined(__LITTLE_ENDIAN__ ) //TODO: is this used? + #if !defined(WEBRTC_TARGET_MAC_INTEL) + #define WEBRTC_TARGET_MAC_INTEL + #endif + #else + #if !defined(WEBRTC_TARGET_MAC) + #define WEBRTC_TARGET_MAC + #endif + #endif +#else + // Linux etc. + #if !defined(WEBRTC_TARGET_PC) + #define WEBRTC_TARGET_PC + #endif +#endif + +// Derived from Chromium's build/build_config.h +// Processor architecture detection. For more info on what's defined, see: +// http://msdn.microsoft.com/en-us/library/b0084kay.aspx +// http://www.agner.org/optimize/calling_conventions.pdf +// or with gcc, run: "echo | gcc -E -dM -" +// TODO(ajm): replace WEBRTC_LITTLE_ENDIAN with WEBRTC_ARCH_LITTLE_ENDIAN? +#if defined(_M_X64) || defined(__x86_64__) +#define WEBRTC_ARCH_X86_FAMILY +#define WEBRTC_ARCH_X86_64 +#define WEBRTC_ARCH_64_BITS +#define WEBRTC_ARCH_LITTLE_ENDIAN +#elif defined(_M_IX86) || defined(__i386__) +#define WEBRTC_ARCH_X86_FAMILY +#define WEBRTC_ARCH_X86 +#define WEBRTC_ARCH_32_BITS +#define WEBRTC_ARCH_LITTLE_ENDIAN +#elif defined(__ARMEL__) +// TODO(ajm): Chromium uses the two commented defines. Should we switch? +#define WEBRTC_ARCH_ARM +//#define WEBRTC_ARCH_ARM_FAMILY +//#define WEBRTC_ARCH_ARMEL +#define WEBRTC_ARCH_32_BITS +#define WEBRTC_ARCH_LITTLE_ENDIAN +#else +#error Please add support for your architecture in typedefs.h +#endif + +// TODO(ajm): SSE2 is disabled on Windows for the moment, because AEC +// optimization is broken. Enable it as soon as AEC is fixed. +//#if defined(__SSE2__) || defined(_MSC_VER) +#if defined(__SSE2__) +#define WEBRTC_USE_SSE2 +#endif + +#if defined(WEBRTC_TARGET_PC) + +#if !defined(_MSC_VER) + #include +#else + // Define C99 equivalent types. + // Since MSVC doesn't include these headers, we have to write our own + // version to provide a compatibility layer between MSVC and the WebRTC + // headers. + typedef signed char int8_t; + typedef signed short int16_t; + typedef signed int int32_t; + typedef signed long long int64_t; + typedef unsigned char uint8_t; + typedef unsigned short uint16_t; + typedef unsigned int uint32_t; + typedef unsigned long long uint64_t; +#endif + +#if defined(WIN32) + typedef __int64 WebRtc_Word64; + typedef unsigned __int64 WebRtc_UWord64; +#else + typedef int64_t WebRtc_Word64; + typedef uint64_t WebRtc_UWord64; +#endif + typedef int32_t WebRtc_Word32; + typedef uint32_t WebRtc_UWord32; + typedef int16_t WebRtc_Word16; + typedef uint16_t WebRtc_UWord16; + typedef char WebRtc_Word8; + typedef uint8_t WebRtc_UWord8; + + // Define endian for the platform + #define WEBRTC_LITTLE_ENDIAN + +#elif defined(WEBRTC_TARGET_MAC_INTEL) + #include + + typedef int64_t WebRtc_Word64; + typedef uint64_t WebRtc_UWord64; + typedef int32_t WebRtc_Word32; + typedef uint32_t WebRtc_UWord32; + typedef int16_t WebRtc_Word16; + typedef char WebRtc_Word8; + typedef uint16_t WebRtc_UWord16; + typedef uint8_t WebRtc_UWord8; + + // Define endian for the platform + #define WEBRTC_LITTLE_ENDIAN + +#else + #error "No platform defined for WebRTC type definitions (typedefs.h)" +#endif + +#endif // WEBRTC_TYPEDEFS_H_ -- cgit v1.2.3