/*** This file is part of PulseAudio. Copyright 2010 Intel Corporation Contributor: Pierre-Louis Bossart Copyright 2012 Niels Ole Salscheider 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, see . ***/ #ifdef HAVE_CONFIG_H #include #endif #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "module-virtual-surround-sink-symdef.h" PA_MODULE_AUTHOR("Niels Ole Salscheider"); PA_MODULE_DESCRIPTION(_("Virtual surround sink")); PA_MODULE_VERSION(PACKAGE_VERSION); PA_MODULE_LOAD_ONCE(false); PA_MODULE_USAGE( _("sink_name= " "sink_properties= " "master= " "format= " "rate= " "channels= " "channel_map= " "use_volume_sharing= " "force_flat_volume= " "hrir=/path/to/left_hrir.wav " )); #define MEMBLOCKQ_MAXLENGTH (16*1024*1024) struct userdata { pa_module *module; /* FIXME: Uncomment this and take "autoloaded" as a modarg if this is a filter */ /* bool autoloaded; */ pa_sink *sink; pa_sink_input *sink_input; pa_memblockq *memblockq; bool auto_desc; unsigned channels; unsigned hrir_channels; unsigned fs, sink_fs; unsigned *mapping_left; unsigned *mapping_right; unsigned hrir_samples; float *hrir_data; float *input_buffer; int input_buffer_offset; }; static const char* const valid_modargs[] = { "sink_name", "sink_properties", "master", "format", "rate", "channels", "channel_map", "use_volume_sharing", "force_flat_volume", "hrir", NULL }; /* Called from I/O thread context */ static int sink_process_msg_cb(pa_msgobject *o, int code, void *data, int64_t offset, pa_memchunk *chunk) { struct userdata *u = PA_SINK(o)->userdata; switch (code) { case PA_SINK_MESSAGE_GET_LATENCY: /* The sink is _put() before the sink input is, so let's * make sure we don't access it in that time. Also, the * sink input is first shut down, the sink second. */ if (!PA_SINK_IS_LINKED(u->sink->thread_info.state) || !PA_SINK_INPUT_IS_LINKED(u->sink_input->thread_info.state)) { *((pa_usec_t*) data) = 0; return 0; } *((pa_usec_t*) data) = /* Get the latency of the master sink */ pa_sink_get_latency_within_thread(u->sink_input->sink) + /* Add the latency internal to our sink input on top */ pa_bytes_to_usec(pa_memblockq_get_length(u->sink_input->thread_info.render_memblockq), &u->sink_input->sink->sample_spec); return 0; } return pa_sink_process_msg(o, code, data, offset, chunk); } /* Called from main context */ static int sink_set_state_cb(pa_sink *s, pa_sink_state_t state) { struct userdata *u; pa_sink_assert_ref(s); pa_assert_se(u = s->userdata); if (!PA_SINK_IS_LINKED(state) || !PA_SINK_INPUT_IS_LINKED(pa_sink_input_get_state(u->sink_input))) return 0; pa_sink_input_cork(u->sink_input, state == PA_SINK_SUSPENDED); return 0; } /* Called from I/O thread context */ static void sink_request_rewind_cb(pa_sink *s) { struct userdata *u; pa_sink_assert_ref(s); pa_assert_se(u = s->userdata); if (!PA_SINK_IS_LINKED(u->sink->thread_info.state) || !PA_SINK_INPUT_IS_LINKED(u->sink_input->thread_info.state)) return; /* Just hand this one over to the master sink */ pa_sink_input_request_rewind(u->sink_input, s->thread_info.rewind_nbytes + pa_memblockq_get_length(u->memblockq), true, false, false); } /* Called from I/O thread context */ static void sink_update_requested_latency_cb(pa_sink *s) { struct userdata *u; pa_sink_assert_ref(s); pa_assert_se(u = s->userdata); if (!PA_SINK_IS_LINKED(u->sink->thread_info.state) || !PA_SINK_INPUT_IS_LINKED(u->sink_input->thread_info.state)) return; /* Just hand this one over to the master sink */ pa_sink_input_set_requested_latency_within_thread( u->sink_input, pa_sink_get_requested_latency_within_thread(s)); } /* Called from main context */ static void sink_set_volume_cb(pa_sink *s) { struct userdata *u; pa_sink_assert_ref(s); pa_assert_se(u = s->userdata); if (!PA_SINK_IS_LINKED(pa_sink_get_state(s)) || !PA_SINK_INPUT_IS_LINKED(pa_sink_input_get_state(u->sink_input))) return; pa_sink_input_set_volume(u->sink_input, &s->real_volume, s->save_volume, true); } /* Called from main context */ static void sink_set_mute_cb(pa_sink *s) { struct userdata *u; pa_sink_assert_ref(s); pa_assert_se(u = s->userdata); if (!PA_SINK_IS_LINKED(pa_sink_get_state(s)) || !PA_SINK_INPUT_IS_LINKED(pa_sink_input_get_state(u->sink_input))) return; pa_sink_input_set_mute(u->sink_input, s->muted, s->save_muted); } /* Called from I/O thread context */ static int sink_input_pop_cb(pa_sink_input *i, size_t nbytes, pa_memchunk *chunk) { struct userdata *u; float *src, *dst; unsigned n; pa_memchunk tchunk; unsigned j, k, l; float sum_right, sum_left; float current_sample; pa_sink_input_assert_ref(i); pa_assert(chunk); pa_assert_se(u = i->userdata); /* Hmm, process any rewind request that might be queued up */ pa_sink_process_rewind(u->sink, 0); while (pa_memblockq_peek(u->memblockq, &tchunk) < 0) { pa_memchunk nchunk; pa_sink_render(u->sink, nbytes * u->sink_fs / u->fs, &nchunk); pa_memblockq_push(u->memblockq, &nchunk); pa_memblock_unref(nchunk.memblock); } tchunk.length = PA_MIN(nbytes * u->sink_fs / u->fs, tchunk.length); pa_assert(tchunk.length > 0); n = (unsigned) (tchunk.length / u->sink_fs); pa_assert(n > 0); chunk->index = 0; chunk->length = n * u->fs; chunk->memblock = pa_memblock_new(i->sink->core->mempool, chunk->length); pa_memblockq_drop(u->memblockq, n * u->sink_fs); src = pa_memblock_acquire_chunk(&tchunk); dst = pa_memblock_acquire(chunk->memblock); for (l = 0; l < n; l++) { memcpy(((char*) u->input_buffer) + u->input_buffer_offset * u->sink_fs, ((char *) src) + l * u->sink_fs, u->sink_fs); sum_right = 0; sum_left = 0; /* fold the input buffer with the impulse response */ for (j = 0; j < u->hrir_samples; j++) { for (k = 0; k < u->channels; k++) { current_sample = u->input_buffer[((u->input_buffer_offset + j) % u->hrir_samples) * u->channels + k]; sum_left += current_sample * u->hrir_data[j * u->hrir_channels + u->mapping_left[k]]; sum_right += current_sample * u->hrir_data[j * u->hrir_channels + u->mapping_right[k]]; } } dst[2 * l] = PA_CLAMP_UNLIKELY(sum_left, -1.0f, 1.0f); dst[2 * l + 1] = PA_CLAMP_UNLIKELY(sum_right, -1.0f, 1.0f); u->input_buffer_offset--; if (u->input_buffer_offset < 0) u->input_buffer_offset += u->hrir_samples; } pa_memblock_release(tchunk.memblock); pa_memblock_release(chunk->memblock); pa_memblock_unref(tchunk.memblock); return 0; } /* Called from I/O thread context */ static void sink_input_process_rewind_cb(pa_sink_input *i, size_t nbytes) { struct userdata *u; size_t amount = 0; pa_sink_input_assert_ref(i); pa_assert_se(u = i->userdata); if (u->sink->thread_info.rewind_nbytes > 0) { size_t max_rewrite; max_rewrite = nbytes * u->sink_fs / u->fs + pa_memblockq_get_length(u->memblockq); amount = PA_MIN(u->sink->thread_info.rewind_nbytes * u->sink_fs / u->fs, max_rewrite); u->sink->thread_info.rewind_nbytes = 0; if (amount > 0) { pa_memblockq_seek(u->memblockq, - (int64_t) amount, PA_SEEK_RELATIVE, true); /* Reset the input buffer */ memset(u->input_buffer, 0, u->hrir_samples * u->sink_fs); u->input_buffer_offset = 0; } } pa_sink_process_rewind(u->sink, amount); pa_memblockq_rewind(u->memblockq, nbytes * u->sink_fs / u->fs); } /* Called from I/O thread context */ static void sink_input_update_max_rewind_cb(pa_sink_input *i, size_t nbytes) { struct userdata *u; pa_sink_input_assert_ref(i); pa_assert_se(u = i->userdata); /* FIXME: Too small max_rewind: * https://bugs.freedesktop.org/show_bug.cgi?id=53709 */ pa_memblockq_set_maxrewind(u->memblockq, nbytes * u->sink_fs / u->fs); pa_sink_set_max_rewind_within_thread(u->sink, nbytes * u->sink_fs / u->fs); } /* Called from I/O thread context */ static void sink_input_update_max_request_cb(pa_sink_input *i, size_t nbytes) { struct userdata *u; pa_sink_input_assert_ref(i); pa_assert_se(u = i->userdata); pa_sink_set_max_request_within_thread(u->sink, nbytes * u->sink_fs / u->fs); } /* Called from I/O thread context */ static void sink_input_update_sink_latency_range_cb(pa_sink_input *i) { struct userdata *u; pa_sink_input_assert_ref(i); pa_assert_se(u = i->userdata); pa_sink_set_latency_range_within_thread(u->sink, i->sink->thread_info.min_latency, i->sink->thread_info.max_latency); } /* Called from I/O thread context */ static void sink_input_update_sink_fixed_latency_cb(pa_sink_input *i) { struct userdata *u; pa_sink_input_assert_ref(i); pa_assert_se(u = i->userdata); pa_sink_set_fixed_latency_within_thread(u->sink, i->sink->thread_info.fixed_latency); } /* Called from I/O thread context */ static void sink_input_detach_cb(pa_sink_input *i) { struct userdata *u; pa_sink_input_assert_ref(i); pa_assert_se(u = i->userdata); pa_sink_detach_within_thread(u->sink); pa_sink_set_rtpoll(u->sink, NULL); } /* Called from I/O thread context */ static void sink_input_attach_cb(pa_sink_input *i) { struct userdata *u; pa_sink_input_assert_ref(i); pa_assert_se(u = i->userdata); pa_sink_set_rtpoll(u->sink, i->sink->thread_info.rtpoll); pa_sink_set_latency_range_within_thread(u->sink, i->sink->thread_info.min_latency, i->sink->thread_info.max_latency); pa_sink_set_fixed_latency_within_thread(u->sink, i->sink->thread_info.fixed_latency); pa_sink_set_max_request_within_thread(u->sink, pa_sink_input_get_max_request(i) * u->sink_fs / u->fs); /* FIXME: Too small max_rewind: * https://bugs.freedesktop.org/show_bug.cgi?id=53709 */ pa_sink_set_max_rewind_within_thread(u->sink, pa_sink_input_get_max_rewind(i) * u->sink_fs / u->fs); pa_sink_attach_within_thread(u->sink); } /* Called from main context */ static void sink_input_kill_cb(pa_sink_input *i) { struct userdata *u; pa_sink_input_assert_ref(i); pa_assert_se(u = i->userdata); /* The order here matters! We first kill the sink input, followed * by the sink. That means the sink callbacks must be protected * against an unconnected sink input! */ pa_sink_input_unlink(u->sink_input); pa_sink_unlink(u->sink); pa_sink_input_unref(u->sink_input); u->sink_input = NULL; pa_sink_unref(u->sink); u->sink = NULL; pa_module_unload_request(u->module, true); } /* Called from IO thread context */ static void sink_input_state_change_cb(pa_sink_input *i, pa_sink_input_state_t state) { struct userdata *u; pa_sink_input_assert_ref(i); pa_assert_se(u = i->userdata); /* If we are added for the first time, ask for a rewinding so that * we are heard right-away. */ if (PA_SINK_INPUT_IS_LINKED(state) && i->thread_info.state == PA_SINK_INPUT_INIT) { pa_log_debug("Requesting rewind due to state change."); pa_sink_input_request_rewind(i, 0, false, true, true); } } /* Called from main context */ static void sink_input_moving_cb(pa_sink_input *i, pa_sink *dest) { struct userdata *u; pa_sink_input_assert_ref(i); pa_assert_se(u = i->userdata); if (dest) { pa_sink_set_asyncmsgq(u->sink, dest->asyncmsgq); pa_sink_update_flags(u->sink, PA_SINK_LATENCY|PA_SINK_DYNAMIC_LATENCY, dest->flags); } else pa_sink_set_asyncmsgq(u->sink, NULL); if (u->auto_desc && dest) { const char *z; pa_proplist *pl; pl = pa_proplist_new(); z = pa_proplist_gets(dest->proplist, PA_PROP_DEVICE_DESCRIPTION); pa_proplist_setf(pl, PA_PROP_DEVICE_DESCRIPTION, "Virtual Surround Sink %s on %s", pa_proplist_gets(u->sink->proplist, "device.vsurroundsink.name"), z ? z : dest->name); pa_sink_update_proplist(u->sink, PA_UPDATE_REPLACE, pl); pa_proplist_free(pl); } } /* Called from main context */ static void sink_input_volume_changed_cb(pa_sink_input *i) { struct userdata *u; pa_sink_input_assert_ref(i); pa_assert_se(u = i->userdata); pa_sink_volume_changed(u->sink, &i->volume); } /* Called from main context */ static void sink_input_mute_changed_cb(pa_sink_input *i) { struct userdata *u; pa_sink_input_assert_ref(i); pa_assert_se(u = i->userdata); pa_sink_mute_changed(u->sink, i->muted); } static pa_channel_position_t mirror_channel(pa_channel_position_t channel) { switch (channel) { case PA_CHANNEL_POSITION_FRONT_LEFT: return PA_CHANNEL_POSITION_FRONT_RIGHT; case PA_CHANNEL_POSITION_FRONT_RIGHT: return PA_CHANNEL_POSITION_FRONT_LEFT; case PA_CHANNEL_POSITION_REAR_LEFT: return PA_CHANNEL_POSITION_REAR_RIGHT; case PA_CHANNEL_POSITION_REAR_RIGHT: return PA_CHANNEL_POSITION_REAR_LEFT; case PA_CHANNEL_POSITION_SIDE_LEFT: return PA_CHANNEL_POSITION_SIDE_RIGHT; case PA_CHANNEL_POSITION_SIDE_RIGHT: return PA_CHANNEL_POSITION_SIDE_LEFT; case PA_CHANNEL_POSITION_FRONT_LEFT_OF_CENTER: return PA_CHANNEL_POSITION_FRONT_RIGHT_OF_CENTER; case PA_CHANNEL_POSITION_FRONT_RIGHT_OF_CENTER: return PA_CHANNEL_POSITION_FRONT_LEFT_OF_CENTER; case PA_CHANNEL_POSITION_TOP_FRONT_LEFT: return PA_CHANNEL_POSITION_TOP_FRONT_RIGHT; case PA_CHANNEL_POSITION_TOP_FRONT_RIGHT: return PA_CHANNEL_POSITION_TOP_FRONT_LEFT; case PA_CHANNEL_POSITION_TOP_REAR_LEFT: return PA_CHANNEL_POSITION_TOP_REAR_RIGHT; case PA_CHANNEL_POSITION_TOP_REAR_RIGHT: return PA_CHANNEL_POSITION_TOP_REAR_LEFT; default: return channel; } } static void normalize_hrir(struct userdata *u) { /* normalize hrir to avoid audible clipping * * The following heuristic tries to avoid audible clipping. It cannot avoid * clipping in the worst case though, because the scaling factor would * become too large resulting in a too quiet signal. * The idea of the heuristic is to avoid clipping when a single click is * played back on all channels. The scaling factor describes the additional * factor that is necessary to avoid clipping for "normal" signals. * * This algorithm doesn't pretend to be perfect, it's just something that * appears to work (not too quiet, no audible clipping) on the material that * it has been tested on. If you find a real-world example where this * algorithm results in audible clipping, please write a patch that adjusts * the scaling factor constants or improves the algorithm (or if you can't * write a patch, at least report the problem to the PulseAudio mailing list * or bug tracker). */ const float scaling_factor = 2.5; float hrir_sum, hrir_max; unsigned i, j; hrir_max = 0; for (i = 0; i < u->hrir_samples; i++) { hrir_sum = 0; for (j = 0; j < u->hrir_channels; j++) hrir_sum += fabs(u->hrir_data[i * u->hrir_channels + j]); if (hrir_sum > hrir_max) hrir_max = hrir_sum; } for (i = 0; i < u->hrir_samples; i++) { for (j = 0; j < u->hrir_channels; j++) u->hrir_data[i * u->hrir_channels + j] /= hrir_max * scaling_factor; } } int pa__init(pa_module*m) { struct userdata *u; pa_sample_spec ss, sink_input_ss; pa_channel_map map, sink_input_map; pa_modargs *ma; pa_sink *master=NULL; pa_sink_input_new_data sink_input_data; pa_sink_new_data sink_data; bool use_volume_sharing = true; bool force_flat_volume = false; pa_memchunk silence; const char *hrir_file; unsigned i, j, found_channel_left, found_channel_right; float *hrir_data; pa_sample_spec hrir_ss; pa_channel_map hrir_map; pa_sample_spec hrir_temp_ss; pa_memchunk hrir_temp_chunk, hrir_temp_chunk_resampled; pa_resampler *resampler; size_t hrir_copied_length, hrir_total_length; hrir_temp_chunk.memblock = NULL; hrir_temp_chunk_resampled.memblock = NULL; pa_assert(m); if (!(ma = pa_modargs_new(m->argument, valid_modargs))) { pa_log("Failed to parse module arguments."); goto fail; } if (!(master = pa_namereg_get(m->core, pa_modargs_get_value(ma, "master", NULL), PA_NAMEREG_SINK))) { pa_log("Master sink not found"); goto fail; } pa_assert(master); u = pa_xnew0(struct userdata, 1); u->module = m; m->userdata = u; /* Initialize hrir and input buffer */ /* this is the hrir file for the left ear! */ if (!(hrir_file = pa_modargs_get_value(ma, "hrir", NULL))) { pa_log("The mandatory 'hrir' module argument is missing."); goto fail; } if (pa_sound_file_load(master->core->mempool, hrir_file, &hrir_temp_ss, &hrir_map, &hrir_temp_chunk, NULL) < 0) { pa_log("Cannot load hrir file."); goto fail; } /* sample spec / map of hrir */ hrir_ss.format = PA_SAMPLE_FLOAT32; hrir_ss.rate = master->sample_spec.rate; hrir_ss.channels = hrir_temp_ss.channels; /* sample spec of sink */ ss = hrir_ss; map = hrir_map; if (pa_modargs_get_sample_spec_and_channel_map(ma, &ss, &map, PA_CHANNEL_MAP_DEFAULT) < 0) { pa_log("Invalid sample format specification or channel map"); goto fail; } ss.format = PA_SAMPLE_FLOAT32; hrir_ss.rate = ss.rate; u->channels = ss.channels; if (pa_modargs_get_value_boolean(ma, "use_volume_sharing", &use_volume_sharing) < 0) { pa_log("use_volume_sharing= expects a boolean argument"); goto fail; } if (pa_modargs_get_value_boolean(ma, "force_flat_volume", &force_flat_volume) < 0) { pa_log("force_flat_volume= expects a boolean argument"); goto fail; } if (use_volume_sharing && force_flat_volume) { pa_log("Flat volume can't be forced when using volume sharing."); goto fail; } /* sample spec / map of sink input */ pa_channel_map_init_stereo(&sink_input_map); sink_input_ss.channels = 2; sink_input_ss.format = PA_SAMPLE_FLOAT32; sink_input_ss.rate = ss.rate; u->sink_fs = pa_frame_size(&ss); u->fs = pa_frame_size(&sink_input_ss); /* Create sink */ pa_sink_new_data_init(&sink_data); sink_data.driver = __FILE__; sink_data.module = m; if (!(sink_data.name = pa_xstrdup(pa_modargs_get_value(ma, "sink_name", NULL)))) sink_data.name = pa_sprintf_malloc("%s.vsurroundsink", master->name); pa_sink_new_data_set_sample_spec(&sink_data, &ss); pa_sink_new_data_set_channel_map(&sink_data, &map); pa_proplist_sets(sink_data.proplist, PA_PROP_DEVICE_MASTER_DEVICE, master->name); pa_proplist_sets(sink_data.proplist, PA_PROP_DEVICE_CLASS, "filter"); pa_proplist_sets(sink_data.proplist, "device.vsurroundsink.name", sink_data.name); if (pa_modargs_get_proplist(ma, "sink_properties", sink_data.proplist, PA_UPDATE_REPLACE) < 0) { pa_log("Invalid properties"); pa_sink_new_data_done(&sink_data); goto fail; } if ((u->auto_desc = !pa_proplist_contains(sink_data.proplist, PA_PROP_DEVICE_DESCRIPTION))) { const char *z; z = pa_proplist_gets(master->proplist, PA_PROP_DEVICE_DESCRIPTION); pa_proplist_setf(sink_data.proplist, PA_PROP_DEVICE_DESCRIPTION, "Virtual Surround Sink %s on %s", sink_data.name, z ? z : master->name); } u->sink = pa_sink_new(m->core, &sink_data, (master->flags & (PA_SINK_LATENCY|PA_SINK_DYNAMIC_LATENCY)) | (use_volume_sharing ? PA_SINK_SHARE_VOLUME_WITH_MASTER : 0)); pa_sink_new_data_done(&sink_data); if (!u->sink) { pa_log("Failed to create sink."); goto fail; } u->sink->parent.process_msg = sink_process_msg_cb; u->sink->set_state = sink_set_state_cb; u->sink->update_requested_latency = sink_update_requested_latency_cb; u->sink->request_rewind = sink_request_rewind_cb; pa_sink_set_set_mute_callback(u->sink, sink_set_mute_cb); if (!use_volume_sharing) { pa_sink_set_set_volume_callback(u->sink, sink_set_volume_cb); pa_sink_enable_decibel_volume(u->sink, true); } /* Normally this flag would be enabled automatically be we can force it. */ if (force_flat_volume) u->sink->flags |= PA_SINK_FLAT_VOLUME; u->sink->userdata = u; pa_sink_set_asyncmsgq(u->sink, master->asyncmsgq); /* Create sink input */ pa_sink_input_new_data_init(&sink_input_data); sink_input_data.driver = __FILE__; sink_input_data.module = m; pa_sink_input_new_data_set_sink(&sink_input_data, master, false); sink_input_data.origin_sink = u->sink; pa_proplist_setf(sink_input_data.proplist, PA_PROP_MEDIA_NAME, "Virtual Surround Sink Stream from %s", pa_proplist_gets(u->sink->proplist, PA_PROP_DEVICE_DESCRIPTION)); pa_proplist_sets(sink_input_data.proplist, PA_PROP_MEDIA_ROLE, "filter"); pa_sink_input_new_data_set_sample_spec(&sink_input_data, &sink_input_ss); pa_sink_input_new_data_set_channel_map(&sink_input_data, &sink_input_map); pa_sink_input_new(&u->sink_input, m->core, &sink_input_data); pa_sink_input_new_data_done(&sink_input_data); if (!u->sink_input) goto fail; u->sink_input->pop = sink_input_pop_cb; u->sink_input->process_rewind = sink_input_process_rewind_cb; u->sink_input->update_max_rewind = sink_input_update_max_rewind_cb; u->sink_input->update_max_request = sink_input_update_max_request_cb; u->sink_input->update_sink_latency_range = sink_input_update_sink_latency_range_cb; u->sink_input->update_sink_fixed_latency = sink_input_update_sink_fixed_latency_cb; u->sink_input->kill = sink_input_kill_cb; u->sink_input->attach = sink_input_attach_cb; u->sink_input->detach = sink_input_detach_cb; u->sink_input->state_change = sink_input_state_change_cb; u->sink_input->moving = sink_input_moving_cb; u->sink_input->volume_changed = use_volume_sharing ? NULL : sink_input_volume_changed_cb; u->sink_input->mute_changed = sink_input_mute_changed_cb; u->sink_input->userdata = u; u->sink->input_to_master = u->sink_input; pa_sink_input_get_silence(u->sink_input, &silence); u->memblockq = pa_memblockq_new("module-virtual-surround-sink memblockq", 0, MEMBLOCKQ_MAXLENGTH, 0, &sink_input_ss, 1, 1, 0, &silence); pa_memblock_unref(silence.memblock); /* resample hrir */ resampler = pa_resampler_new(u->sink->core->mempool, &hrir_temp_ss, &hrir_map, &hrir_ss, &hrir_map, u->sink->core->lfe_crossover_freq, PA_RESAMPLER_SRC_SINC_BEST_QUALITY, PA_RESAMPLER_NO_REMAP); u->hrir_samples = hrir_temp_chunk.length / pa_frame_size(&hrir_temp_ss) * hrir_ss.rate / hrir_temp_ss.rate; if (u->hrir_samples > 64) { u->hrir_samples = 64; pa_log("The (resampled) hrir contains more than 64 samples. Only the first 64 samples will be used to limit processor usage."); } hrir_total_length = u->hrir_samples * pa_frame_size(&hrir_ss); u->hrir_channels = hrir_ss.channels; u->hrir_data = (float *) pa_xmalloc(hrir_total_length); hrir_copied_length = 0; /* add silence to the hrir until we get enough samples out of the resampler */ while (hrir_copied_length < hrir_total_length) { pa_resampler_run(resampler, &hrir_temp_chunk, &hrir_temp_chunk_resampled); if (hrir_temp_chunk.memblock != hrir_temp_chunk_resampled.memblock) { /* Silence input block */ pa_silence_memblock(hrir_temp_chunk.memblock, &hrir_temp_ss); } if (hrir_temp_chunk_resampled.memblock) { /* Copy hrir data */ hrir_data = (float *) pa_memblock_acquire(hrir_temp_chunk_resampled.memblock); if (hrir_total_length - hrir_copied_length >= hrir_temp_chunk_resampled.length) { memcpy(u->hrir_data + hrir_copied_length, hrir_data, hrir_temp_chunk_resampled.length); hrir_copied_length += hrir_temp_chunk_resampled.length; } else { memcpy(u->hrir_data + hrir_copied_length, hrir_data, hrir_total_length - hrir_copied_length); hrir_copied_length = hrir_total_length; } pa_memblock_release(hrir_temp_chunk_resampled.memblock); pa_memblock_unref(hrir_temp_chunk_resampled.memblock); hrir_temp_chunk_resampled.memblock = NULL; } } pa_resampler_free(resampler); pa_memblock_unref(hrir_temp_chunk.memblock); hrir_temp_chunk.memblock = NULL; if (hrir_map.channels < map.channels) { pa_log("hrir file does not have enough channels!"); goto fail; } normalize_hrir(u); /* create mapping between hrir and input */ u->mapping_left = (unsigned *) pa_xnew0(unsigned, u->channels); u->mapping_right = (unsigned *) pa_xnew0(unsigned, u->channels); for (i = 0; i < map.channels; i++) { found_channel_left = 0; found_channel_right = 0; for (j = 0; j < hrir_map.channels; j++) { if (hrir_map.map[j] == map.map[i]) { u->mapping_left[i] = j; found_channel_left = 1; } if (hrir_map.map[j] == mirror_channel(map.map[i])) { u->mapping_right[i] = j; found_channel_right = 1; } } if (!found_channel_left) { pa_log("Cannot find mapping for channel %s", pa_channel_position_to_string(map.map[i])); goto fail; } if (!found_channel_right) { pa_log("Cannot find mapping for channel %s", pa_channel_position_to_string(mirror_channel(map.map[i]))); goto fail; } } u->input_buffer = pa_xmalloc0(u->hrir_samples * u->sink_fs); u->input_buffer_offset = 0; pa_sink_put(u->sink); pa_sink_input_put(u->sink_input); pa_modargs_free(ma); return 0; fail: if (hrir_temp_chunk.memblock) pa_memblock_unref(hrir_temp_chunk.memblock); if (hrir_temp_chunk_resampled.memblock) pa_memblock_unref(hrir_temp_chunk_resampled.memblock); if (ma) pa_modargs_free(ma); pa__done(m); return -1; } int pa__get_n_used(pa_module *m) { struct userdata *u; pa_assert(m); pa_assert_se(u = m->userdata); return pa_sink_linked_by(u->sink); } void pa__done(pa_module*m) { struct userdata *u; pa_assert(m); if (!(u = m->userdata)) return; /* See comments in sink_input_kill_cb() above regarding * destruction order! */ if (u->sink_input) pa_sink_input_unlink(u->sink_input); if (u->sink) pa_sink_unlink(u->sink); if (u->sink_input) pa_sink_input_unref(u->sink_input); if (u->sink) pa_sink_unref(u->sink); if (u->memblockq) pa_memblockq_free(u->memblockq); if (u->hrir_data) pa_xfree(u->hrir_data); if (u->input_buffer) pa_xfree(u->input_buffer); if (u->mapping_left) pa_xfree(u->mapping_left); if (u->mapping_right) pa_xfree(u->mapping_right); pa_xfree(u); }