/*** This file is part of PulseAudio. Copyright 2004-2006 Lennart Poettering Copyright 2006 Pierre Ossman for Cendio AB PulseAudio is free software; you can redistribute it and/or modify it under the terms of the GNU Lesser General Public License as published by the Free Software Foundation; either version 2.1 of the License, or (at your option) any later version. PulseAudio is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU Lesser General Public License along with PulseAudio; if not, write to the Free Software Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA. ***/ #ifdef HAVE_CONFIG_H #include #endif #include #include #include #include #include #include #include #include #include #include #include #include #include #include "sample-util.h" #define PA_SILENCE_MAX (PA_PAGE_SIZE*16) pa_memblock *pa_silence_memblock(pa_memblock* b, const pa_sample_spec *spec) { void *data; pa_assert(b); pa_assert(spec); data = pa_memblock_acquire(b); pa_silence_memory(data, pa_memblock_get_length(b), spec); pa_memblock_release(b); return b; } pa_memchunk* pa_silence_memchunk(pa_memchunk *c, const pa_sample_spec *spec) { void *data; pa_assert(c); pa_assert(c->memblock); pa_assert(spec); data = pa_memblock_acquire(c->memblock); pa_silence_memory((uint8_t*) data+c->index, c->length, spec); pa_memblock_release(c->memblock); return c; } static uint8_t silence_byte(pa_sample_format_t format) { switch (format) { case PA_SAMPLE_U8: return 0x80; case PA_SAMPLE_S16LE: case PA_SAMPLE_S16BE: case PA_SAMPLE_S32LE: case PA_SAMPLE_S32BE: case PA_SAMPLE_FLOAT32LE: case PA_SAMPLE_FLOAT32BE: case PA_SAMPLE_S24LE: case PA_SAMPLE_S24BE: case PA_SAMPLE_S24_32LE: case PA_SAMPLE_S24_32BE: return 0; case PA_SAMPLE_ALAW: return 0xd5; case PA_SAMPLE_ULAW: return 0xff; default: pa_assert_not_reached(); } } void* pa_silence_memory(void *p, size_t length, const pa_sample_spec *spec) { pa_assert(p); pa_assert(length > 0); pa_assert(spec); memset(p, silence_byte(spec->format), length); return p; } #define VOLUME_PADDING 32 static void calc_linear_integer_volume(int32_t linear[], const pa_cvolume *volume) { unsigned channel, nchannels, padding; pa_assert(linear); pa_assert(volume); nchannels = volume->channels; for (channel = 0; channel < nchannels; channel++) linear[channel] = (int32_t) lrint(pa_sw_volume_to_linear(volume->values[channel]) * 0x10000); for (padding = 0; padding < VOLUME_PADDING; padding++, channel++) linear[channel] = linear[padding]; } static void calc_linear_float_volume(float linear[], const pa_cvolume *volume) { unsigned channel, nchannels, padding; pa_assert(linear); pa_assert(volume); nchannels = volume->channels; for (channel = 0; channel < nchannels; channel++) linear[channel] = (float) pa_sw_volume_to_linear(volume->values[channel]); for (padding = 0; padding < VOLUME_PADDING; padding++, channel++) linear[channel] = linear[padding]; } static void calc_linear_integer_stream_volumes(pa_mix_info streams[], unsigned nstreams, const pa_cvolume *volume, const pa_sample_spec *spec) { unsigned k, channel; float linear[PA_CHANNELS_MAX + VOLUME_PADDING]; pa_assert(streams); pa_assert(spec); pa_assert(volume); calc_linear_float_volume(linear, volume); for (k = 0; k < nstreams; k++) { for (channel = 0; channel < spec->channels; channel++) { pa_mix_info *m = streams + k; m->linear[channel].i = (int32_t) lrint(pa_sw_volume_to_linear(m->volume.values[channel]) * linear[channel] * 0x10000); } } } static void calc_linear_float_stream_volumes(pa_mix_info streams[], unsigned nstreams, const pa_cvolume *volume, const pa_sample_spec *spec) { unsigned k, channel; float linear[PA_CHANNELS_MAX + VOLUME_PADDING]; pa_assert(streams); pa_assert(spec); pa_assert(volume); calc_linear_float_volume(linear, volume); for (k = 0; k < nstreams; k++) { for (channel = 0; channel < spec->channels; channel++) { pa_mix_info *m = streams + k; m->linear[channel].f = (float) (pa_sw_volume_to_linear(m->volume.values[channel]) * linear[channel]); } } } size_t pa_mix( pa_mix_info streams[], unsigned nstreams, void *data, size_t length, const pa_sample_spec *spec, const pa_cvolume *volume, pa_bool_t mute) { pa_cvolume full_volume; unsigned k; unsigned z; void *end; pa_assert(streams); pa_assert(data); pa_assert(length); pa_assert(spec); if (!volume) volume = pa_cvolume_reset(&full_volume, spec->channels); if (mute || pa_cvolume_is_muted(volume) || nstreams <= 0) { pa_silence_memory(data, length, spec); return length; } for (k = 0; k < nstreams; k++) streams[k].ptr = (uint8_t*) pa_memblock_acquire(streams[k].chunk.memblock) + streams[k].chunk.index; for (z = 0; z < nstreams; z++) if (length > streams[z].chunk.length) length = streams[z].chunk.length; end = (uint8_t*) data + length; switch (spec->format) { case PA_SAMPLE_S16NE:{ unsigned channel = 0; calc_linear_integer_stream_volumes(streams, nstreams, volume, spec); while (data < end) { int32_t sum = 0; unsigned i; for (i = 0; i < nstreams; i++) { pa_mix_info *m = streams + i; int32_t v, lo, hi, cv = m->linear[channel].i; if (PA_LIKELY(cv > 0)) { /* Multiplying the 32bit volume factor with the * 16bit sample might result in an 48bit value. We * want to do without 64 bit integers and hence do * the multiplication independently for the HI and * LO part of the volume. */ hi = cv >> 16; lo = cv & 0xFFFF; v = *((int16_t*) m->ptr); v = ((v * lo) >> 16) + (v * hi); sum += v; } m->ptr = (uint8_t*) m->ptr + sizeof(int16_t); } sum = PA_CLAMP_UNLIKELY(sum, -0x8000, 0x7FFF); *((int16_t*) data) = (int16_t) sum; data = (uint8_t*) data + sizeof(int16_t); if (PA_UNLIKELY(++channel >= spec->channels)) channel = 0; } break; } case PA_SAMPLE_S16RE:{ unsigned channel = 0; calc_linear_integer_stream_volumes(streams, nstreams, volume, spec); while (data < end) { int32_t sum = 0; unsigned i; for (i = 0; i < nstreams; i++) { pa_mix_info *m = streams + i; int32_t v, lo, hi, cv = m->linear[channel].i; if (PA_LIKELY(cv > 0)) { hi = cv >> 16; lo = cv & 0xFFFF; v = PA_INT16_SWAP(*((int16_t*) m->ptr)); v = ((v * lo) >> 16) + (v * hi); sum += v; } m->ptr = (uint8_t*) m->ptr + sizeof(int16_t); } sum = PA_CLAMP_UNLIKELY(sum, -0x8000, 0x7FFF); *((int16_t*) data) = PA_INT16_SWAP((int16_t) sum); data = (uint8_t*) data + sizeof(int16_t); if (PA_UNLIKELY(++channel >= spec->channels)) channel = 0; } break; } case PA_SAMPLE_S32NE:{ unsigned channel = 0; calc_linear_integer_stream_volumes(streams, nstreams, volume, spec); while (data < end) { int64_t sum = 0; unsigned i; for (i = 0; i < nstreams; i++) { pa_mix_info *m = streams + i; int32_t cv = m->linear[channel].i; int64_t v; if (PA_LIKELY(cv > 0)) { v = *((int32_t*) m->ptr); v = (v * cv) >> 16; sum += v; } m->ptr = (uint8_t*) m->ptr + sizeof(int32_t); } sum = PA_CLAMP_UNLIKELY(sum, -0x80000000LL, 0x7FFFFFFFLL); *((int32_t*) data) = (int32_t) sum; data = (uint8_t*) data + sizeof(int32_t); if (PA_UNLIKELY(++channel >= spec->channels)) channel = 0; } break; } case PA_SAMPLE_S32RE:{ unsigned channel = 0; calc_linear_integer_stream_volumes(streams, nstreams, volume, spec); while (data < end) { int64_t sum = 0; unsigned i; for (i = 0; i < nstreams; i++) { pa_mix_info *m = streams + i; int32_t cv = m->linear[channel].i; int64_t v; if (PA_LIKELY(cv > 0)) { v = PA_INT32_SWAP(*((int32_t*) m->ptr)); v = (v * cv) >> 16; sum += v; } m->ptr = (uint8_t*) m->ptr + sizeof(int32_t); } sum = PA_CLAMP_UNLIKELY(sum, -0x80000000LL, 0x7FFFFFFFLL); *((int32_t*) data) = PA_INT32_SWAP((int32_t) sum); data = (uint8_t*) data + sizeof(int32_t); if (PA_UNLIKELY(++channel >= spec->channels)) channel = 0; } break; } case PA_SAMPLE_S24NE: { unsigned channel = 0; calc_linear_integer_stream_volumes(streams, nstreams, volume, spec); while (data < end) { int64_t sum = 0; unsigned i; for (i = 0; i < nstreams; i++) { pa_mix_info *m = streams + i; int32_t cv = m->linear[channel].i; int64_t v; if (PA_LIKELY(cv > 0)) { v = (int32_t) (PA_READ24NE(m->ptr) << 8); v = (v * cv) >> 16; sum += v; } m->ptr = (uint8_t*) m->ptr + 3; } sum = PA_CLAMP_UNLIKELY(sum, -0x80000000LL, 0x7FFFFFFFLL); PA_WRITE24NE(data, ((uint32_t) sum) >> 8); data = (uint8_t*) data + 3; if (PA_UNLIKELY(++channel >= spec->channels)) channel = 0; } break; } case PA_SAMPLE_S24RE: { unsigned channel = 0; calc_linear_integer_stream_volumes(streams, nstreams, volume, spec); while (data < end) { int64_t sum = 0; unsigned i; for (i = 0; i < nstreams; i++) { pa_mix_info *m = streams + i; int32_t cv = m->linear[channel].i; int64_t v; if (PA_LIKELY(cv > 0)) { v = (int32_t) (PA_READ24RE(m->ptr) << 8); v = (v * cv) >> 16; sum += v; } m->ptr = (uint8_t*) m->ptr + 3; } sum = PA_CLAMP_UNLIKELY(sum, -0x80000000LL, 0x7FFFFFFFLL); PA_WRITE24RE(data, ((uint32_t) sum) >> 8); data = (uint8_t*) data + 3; if (PA_UNLIKELY(++channel >= spec->channels)) channel = 0; } break; } case PA_SAMPLE_S24_32NE: { unsigned channel = 0; calc_linear_integer_stream_volumes(streams, nstreams, volume, spec); while (data < end) { int64_t sum = 0; unsigned i; for (i = 0; i < nstreams; i++) { pa_mix_info *m = streams + i; int32_t cv = m->linear[channel].i; int64_t v; if (PA_LIKELY(cv > 0)) { v = (int32_t) (*((uint32_t*)m->ptr) << 8); v = (v * cv) >> 16; sum += v; } m->ptr = (uint8_t*) m->ptr + sizeof(int32_t); } sum = PA_CLAMP_UNLIKELY(sum, -0x80000000LL, 0x7FFFFFFFLL); *((uint32_t*) data) = ((uint32_t) (int32_t) sum) >> 8; data = (uint8_t*) data + sizeof(uint32_t); if (PA_UNLIKELY(++channel >= spec->channels)) channel = 0; } break; } case PA_SAMPLE_S24_32RE: { unsigned channel = 0; calc_linear_integer_stream_volumes(streams, nstreams, volume, spec); while (data < end) { int64_t sum = 0; unsigned i; for (i = 0; i < nstreams; i++) { pa_mix_info *m = streams + i; int32_t cv = m->linear[channel].i; int64_t v; if (PA_LIKELY(cv > 0)) { v = (int32_t) (PA_UINT32_SWAP(*((uint32_t*) m->ptr)) << 8); v = (v * cv) >> 16; sum += v; } m->ptr = (uint8_t*) m->ptr + 3; } sum = PA_CLAMP_UNLIKELY(sum, -0x80000000LL, 0x7FFFFFFFLL); *((uint32_t*) data) = PA_INT32_SWAP(((uint32_t) (int32_t) sum) >> 8); data = (uint8_t*) data + sizeof(uint32_t); if (PA_UNLIKELY(++channel >= spec->channels)) channel = 0; } break; } case PA_SAMPLE_U8: { unsigned channel = 0; calc_linear_integer_stream_volumes(streams, nstreams, volume, spec); while (data < end) { int32_t sum = 0; unsigned i; for (i = 0; i < nstreams; i++) { pa_mix_info *m = streams + i; int32_t v, cv = m->linear[channel].i; if (PA_LIKELY(cv > 0)) { v = (int32_t) *((uint8_t*) m->ptr) - 0x80; v = (v * cv) >> 16; sum += v; } m->ptr = (uint8_t*) m->ptr + 1; } sum = PA_CLAMP_UNLIKELY(sum, -0x80, 0x7F); *((uint8_t*) data) = (uint8_t) (sum + 0x80); data = (uint8_t*) data + 1; if (PA_UNLIKELY(++channel >= spec->channels)) channel = 0; } break; } case PA_SAMPLE_ULAW: { unsigned channel = 0; calc_linear_integer_stream_volumes(streams, nstreams, volume, spec); while (data < end) { int32_t sum = 0; unsigned i; for (i = 0; i < nstreams; i++) { pa_mix_info *m = streams + i; int32_t v, hi, lo, cv = m->linear[channel].i; if (PA_LIKELY(cv > 0)) { hi = cv >> 16; lo = cv & 0xFFFF; v = (int32_t) st_ulaw2linear16(*((uint8_t*) m->ptr)); v = ((v * lo) >> 16) + (v * hi); sum += v; } m->ptr = (uint8_t*) m->ptr + 1; } sum = PA_CLAMP_UNLIKELY(sum, -0x8000, 0x7FFF); *((uint8_t*) data) = (uint8_t) st_14linear2ulaw((int16_t) sum >> 2); data = (uint8_t*) data + 1; if (PA_UNLIKELY(++channel >= spec->channels)) channel = 0; } break; } case PA_SAMPLE_ALAW: { unsigned channel = 0; calc_linear_integer_stream_volumes(streams, nstreams, volume, spec); while (data < end) { int32_t sum = 0; unsigned i; for (i = 0; i < nstreams; i++) { pa_mix_info *m = streams + i; int32_t v, hi, lo, cv = m->linear[channel].i; if (PA_LIKELY(cv > 0)) { hi = cv >> 16; lo = cv & 0xFFFF; v = (int32_t) st_alaw2linear16(*((uint8_t*) m->ptr)); v = ((v * lo) >> 16) + (v * hi); sum += v; } m->ptr = (uint8_t*) m->ptr + 1; } sum = PA_CLAMP_UNLIKELY(sum, -0x8000, 0x7FFF); *((uint8_t*) data) = (uint8_t) st_13linear2alaw((int16_t) sum >> 3); data = (uint8_t*) data + 1; if (PA_UNLIKELY(++channel >= spec->channels)) channel = 0; } break; } case PA_SAMPLE_FLOAT32NE: { unsigned channel = 0; calc_linear_float_stream_volumes(streams, nstreams, volume, spec); while (data < end) { float sum = 0; unsigned i; for (i = 0; i < nstreams; i++) { pa_mix_info *m = streams + i; float v, cv = m->linear[channel].f; if (PA_LIKELY(cv > 0)) { v = *((float*) m->ptr); v *= cv; sum += v; } m->ptr = (uint8_t*) m->ptr + sizeof(float); } *((float*) data) = sum; data = (uint8_t*) data + sizeof(float); if (PA_UNLIKELY(++channel >= spec->channels)) channel = 0; } break; } case PA_SAMPLE_FLOAT32RE: { unsigned channel = 0; calc_linear_float_stream_volumes(streams, nstreams, volume, spec); while (data < end) { float sum = 0; unsigned i; for (i = 0; i < nstreams; i++) { pa_mix_info *m = streams + i; float v, cv = m->linear[channel].f; if (PA_LIKELY(cv > 0)) { v = PA_FLOAT32_SWAP(*(float*) m->ptr); v *= cv; sum += v; } m->ptr = (uint8_t*) m->ptr + sizeof(float); } *((float*) data) = PA_FLOAT32_SWAP(sum); data = (uint8_t*) data + sizeof(float); if (PA_UNLIKELY(++channel >= spec->channels)) channel = 0; } break; } default: pa_log_error("Unable to mix audio data of format %s.", pa_sample_format_to_string(spec->format)); pa_assert_not_reached(); } for (k = 0; k < nstreams; k++) pa_memblock_release(streams[k].chunk.memblock); return length; } typedef union { float f; uint32_t i; } volume_val; typedef void (*pa_calc_volume_func_t) (void *volumes, const pa_cvolume *volume); static const pa_calc_volume_func_t calc_volume_table[] = { [PA_SAMPLE_U8] = (pa_calc_volume_func_t) calc_linear_integer_volume, [PA_SAMPLE_ALAW] = (pa_calc_volume_func_t) calc_linear_integer_volume, [PA_SAMPLE_ULAW] = (pa_calc_volume_func_t) calc_linear_integer_volume, [PA_SAMPLE_S16LE] = (pa_calc_volume_func_t) calc_linear_integer_volume, [PA_SAMPLE_S16BE] = (pa_calc_volume_func_t) calc_linear_integer_volume, [PA_SAMPLE_FLOAT32LE] = (pa_calc_volume_func_t) calc_linear_float_volume, [PA_SAMPLE_FLOAT32BE] = (pa_calc_volume_func_t) calc_linear_float_volume, [PA_SAMPLE_S32LE] = (pa_calc_volume_func_t) calc_linear_integer_volume, [PA_SAMPLE_S32BE] = (pa_calc_volume_func_t) calc_linear_integer_volume, [PA_SAMPLE_S24LE] = (pa_calc_volume_func_t) calc_linear_integer_volume, [PA_SAMPLE_S24BE] = (pa_calc_volume_func_t) calc_linear_integer_volume, [PA_SAMPLE_S24_32LE] = (pa_calc_volume_func_t) calc_linear_integer_volume, [PA_SAMPLE_S24_32BE] = (pa_calc_volume_func_t) calc_linear_integer_volume }; void pa_volume_memchunk( pa_memchunk*c, const pa_sample_spec *spec, const pa_cvolume *volume) { void *ptr; volume_val linear[PA_CHANNELS_MAX + VOLUME_PADDING]; pa_do_volume_func_t do_volume; pa_assert(c); pa_assert(spec); pa_assert(pa_sample_spec_valid(spec)); pa_assert(pa_frame_aligned(c->length, spec)); pa_assert(volume); if (pa_memblock_is_silence(c->memblock)) return; if (pa_cvolume_channels_equal_to(volume, PA_VOLUME_NORM)) return; if (pa_cvolume_channels_equal_to(volume, PA_VOLUME_MUTED)) { pa_silence_memchunk(c, spec); return; } do_volume = pa_get_volume_func(spec->format); pa_assert(do_volume); calc_volume_table[spec->format] ((void *)linear, volume); ptr = (uint8_t*) pa_memblock_acquire(c->memblock) + c->index; do_volume (ptr, (void *)linear, spec->channels, c->length); pa_memblock_release(c->memblock); } size_t pa_frame_align(size_t l, const pa_sample_spec *ss) { size_t fs; pa_assert(ss); fs = pa_frame_size(ss); return (l/fs) * fs; } pa_bool_t pa_frame_aligned(size_t l, const pa_sample_spec *ss) { size_t fs; pa_assert(ss); fs = pa_frame_size(ss); return l % fs == 0; } void pa_interleave(const void *src[], unsigned channels, void *dst, size_t ss, unsigned n) { unsigned c; size_t fs; pa_assert(src); pa_assert(channels > 0); pa_assert(dst); pa_assert(ss > 0); pa_assert(n > 0); fs = ss * channels; for (c = 0; c < channels; c++) { unsigned j; void *d; const void *s; s = src[c]; d = (uint8_t*) dst + c * ss; for (j = 0; j < n; j ++) { memcpy(d, s, (int) ss); s = (uint8_t*) s + ss; d = (uint8_t*) d + fs; } } } void pa_deinterleave(const void *src, void *dst[], unsigned channels, size_t ss, unsigned n) { size_t fs; unsigned c; pa_assert(src); pa_assert(dst); pa_assert(channels > 0); pa_assert(ss > 0); pa_assert(n > 0); fs = ss * channels; for (c = 0; c < channels; c++) { unsigned j; const void *s; void *d; s = (uint8_t*) src + c * ss; d = dst[c]; for (j = 0; j < n; j ++) { memcpy(d, s, (int) ss); s = (uint8_t*) s + fs; d = (uint8_t*) d + ss; } } } static pa_memblock *silence_memblock_new(pa_mempool *pool, uint8_t c) { pa_memblock *b; size_t length; void *data; pa_assert(pool); length = PA_MIN(pa_mempool_block_size_max(pool), PA_SILENCE_MAX); b = pa_memblock_new(pool, length); data = pa_memblock_acquire(b); memset(data, c, length); pa_memblock_release(b); pa_memblock_set_is_silence(b, TRUE); return b; } void pa_silence_cache_init(pa_silence_cache *cache) { pa_assert(cache); memset(cache, 0, sizeof(pa_silence_cache)); } void pa_silence_cache_done(pa_silence_cache *cache) { pa_sample_format_t f; pa_assert(cache); for (f = 0; f < PA_SAMPLE_MAX; f++) if (cache->blocks[f]) pa_memblock_unref(cache->blocks[f]); memset(cache, 0, sizeof(pa_silence_cache)); } pa_memchunk* pa_silence_memchunk_get(pa_silence_cache *cache, pa_mempool *pool, pa_memchunk* ret, const pa_sample_spec *spec, size_t length) { pa_memblock *b; size_t l; pa_assert(cache); pa_assert(pa_sample_spec_valid(spec)); if (!(b = cache->blocks[spec->format])) switch (spec->format) { case PA_SAMPLE_U8: cache->blocks[PA_SAMPLE_U8] = b = silence_memblock_new(pool, 0x80); break; case PA_SAMPLE_S16LE: case PA_SAMPLE_S16BE: case PA_SAMPLE_S32LE: case PA_SAMPLE_S32BE: case PA_SAMPLE_S24LE: case PA_SAMPLE_S24BE: case PA_SAMPLE_S24_32LE: case PA_SAMPLE_S24_32BE: case PA_SAMPLE_FLOAT32LE: case PA_SAMPLE_FLOAT32BE: cache->blocks[PA_SAMPLE_S16LE] = b = silence_memblock_new(pool, 0); cache->blocks[PA_SAMPLE_S16BE] = pa_memblock_ref(b); cache->blocks[PA_SAMPLE_S32LE] = pa_memblock_ref(b); cache->blocks[PA_SAMPLE_S32BE] = pa_memblock_ref(b); cache->blocks[PA_SAMPLE_S24LE] = pa_memblock_ref(b); cache->blocks[PA_SAMPLE_S24BE] = pa_memblock_ref(b); cache->blocks[PA_SAMPLE_S24_32LE] = pa_memblock_ref(b); cache->blocks[PA_SAMPLE_S24_32BE] = pa_memblock_ref(b); cache->blocks[PA_SAMPLE_FLOAT32LE] = pa_memblock_ref(b); cache->blocks[PA_SAMPLE_FLOAT32BE] = pa_memblock_ref(b); break; case PA_SAMPLE_ALAW: cache->blocks[PA_SAMPLE_ALAW] = b = silence_memblock_new(pool, 0xd5); break; case PA_SAMPLE_ULAW: cache->blocks[PA_SAMPLE_ULAW] = b = silence_memblock_new(pool, 0xff); break; default: pa_assert_not_reached(); } pa_assert(b); ret->memblock = pa_memblock_ref(b); l = pa_memblock_get_length(b); if (length > l || length == 0) length = l; ret->length = pa_frame_align(length, spec); ret->index = 0; return ret; } void pa_sample_clamp(pa_sample_format_t format, void *dst, size_t dstr, const void *src, size_t sstr, unsigned n) { const float *s; float *d; s = src; d = dst; if (format == PA_SAMPLE_FLOAT32NE) { for (; n > 0; n--) { float f; f = *s; *d = PA_CLAMP_UNLIKELY(f, -1.0f, 1.0f); s = (const float*) ((const uint8_t*) s + sstr); d = (float*) ((uint8_t*) d + dstr); } } else { pa_assert(format == PA_SAMPLE_FLOAT32RE); for (; n > 0; n--) { float f; f = PA_FLOAT32_SWAP(*s); f = PA_CLAMP_UNLIKELY(f, -1.0f, 1.0f); *d = PA_FLOAT32_SWAP(f); s = (const float*) ((const uint8_t*) s + sstr); d = (float*) ((uint8_t*) d + dstr); } } } /* Similar to pa_bytes_to_usec() but rounds up, not down */ pa_usec_t pa_bytes_to_usec_round_up(uint64_t length, const pa_sample_spec *spec) { size_t fs; pa_usec_t usec; pa_assert(spec); fs = pa_frame_size(spec); length = (length + fs - 1) / fs; usec = (pa_usec_t) length * PA_USEC_PER_SEC; return (usec + spec->rate - 1) / spec->rate; } /* Similar to pa_usec_to_bytes() but rounds up, not down */ size_t pa_usec_to_bytes_round_up(pa_usec_t t, const pa_sample_spec *spec) { uint64_t u; pa_assert(spec); u = (uint64_t) t * (uint64_t) spec->rate; u = (u + PA_USEC_PER_SEC - 1) / PA_USEC_PER_SEC; u *= pa_frame_size(spec); return (size_t) u; } void pa_memchunk_dump_to_file(pa_memchunk *c, const char *fn) { FILE *f; void *p; pa_assert(c); pa_assert(fn); /* Only for debugging purposes */ f = pa_fopen_cloexec(fn, "a"); if (!f) { pa_log_warn("Failed to open '%s': %s", fn, pa_cstrerror(errno)); return; } p = pa_memblock_acquire(c->memblock); if (fwrite((uint8_t*) p + c->index, 1, c->length, f) != c->length) pa_log_warn("Failed to write to '%s': %s", fn, pa_cstrerror(errno)); pa_memblock_release(c->memblock); fclose(f); } static void calc_sine(float *f, size_t l, double freq) { size_t i; l /= sizeof(float); for (i = 0; i < l; i++) *(f++) = (float) 0.5f * sin((double) i*M_PI*2*freq / (double) l); } void pa_memchunk_sine(pa_memchunk *c, pa_mempool *pool, unsigned rate, unsigned freq) { size_t l; unsigned gcd, n; void *p; pa_memchunk_reset(c); gcd = pa_gcd(rate, freq); n = rate / gcd; l = pa_mempool_block_size_max(pool) / sizeof(float); l /= n; if (l <= 0) l = 1; l *= n; c->length = l * sizeof(float); c->memblock = pa_memblock_new(pool, c->length); p = pa_memblock_acquire(c->memblock); calc_sine(p, c->length, freq * l / rate); pa_memblock_release(c->memblock); } size_t pa_convert_size(size_t size, const pa_sample_spec *from, const pa_sample_spec *to) { pa_usec_t usec; pa_assert(from); pa_assert(to); usec = pa_bytes_to_usec_round_up(size, from); return pa_usec_to_bytes_round_up(usec, to); }