boo/lib/audiodev/AudioVoice.cpp

303 lines
9.9 KiB
C++

#include "AudioVoice.hpp"
#include "AudioVoiceEngine.hpp"
#include "logvisor/logvisor.hpp"
#include <cmath>
namespace boo {
static logvisor::Module Log("boo::AudioVoice");
static AudioMatrixMono DefaultMonoMtx;
static AudioMatrixStereo DefaultStereoMtx;
AudioVoice::AudioVoice(BaseAudioVoiceEngine& root, IAudioVoiceCallback* cb, bool dynamicRate)
: ListNode<AudioVoice, BaseAudioVoiceEngine*, IAudioVoice>(&root), m_cb(cb), m_dynamicRate(dynamicRate) {}
AudioVoice::~AudioVoice() { soxr_delete(m_src); }
AudioVoice*& AudioVoice::_getHeadPtr(BaseAudioVoiceEngine* head) { return head->m_voiceHead; }
std::unique_lock<std::recursive_mutex> AudioVoice::_getHeadLock(BaseAudioVoiceEngine* head) {
return std::unique_lock<std::recursive_mutex>{head->m_dataMutex};
}
void AudioVoice::_setPitchRatio(double ratio, bool slew) {
if (m_dynamicRate) {
m_sampleRatio = ratio * m_sampleRateIn / m_sampleRateOut;
soxr_error_t err = soxr_set_io_ratio(m_src, m_sampleRatio, slew ? m_head->m_5msFrames : 0);
if (err) {
Log.report(logvisor::Fatal, FMT_STRING("unable to set resampler rate: {}"), soxr_strerror(err));
m_setPitchRatio = false;
return;
}
}
m_setPitchRatio = false;
}
void AudioVoice::_midUpdate() {
if (m_resetSampleRate)
_resetSampleRate(m_deferredSampleRate);
if (m_setPitchRatio)
_setPitchRatio(m_pitchRatio, m_slew);
}
void AudioVoice::setPitchRatio(double ratio, bool slew) {
m_setPitchRatio = true;
m_pitchRatio = ratio;
m_slew = slew;
}
void AudioVoice::resetSampleRate(double sampleRate) {
m_resetSampleRate = true;
m_deferredSampleRate = sampleRate;
}
void AudioVoice::start() { m_running = true; }
void AudioVoice::stop() { m_running = false; }
AudioVoiceMono::AudioVoiceMono(BaseAudioVoiceEngine& root, IAudioVoiceCallback* cb, double sampleRate, bool dynamicRate)
: AudioVoice(root, cb, dynamicRate) {
_resetSampleRate(sampleRate);
}
void AudioVoiceMono::_resetSampleRate(double sampleRate) {
soxr_delete(m_src);
double rateOut = m_head->mixInfo().m_sampleRate;
soxr_datatype_t formatOut = m_head->mixInfo().m_sampleFormat;
soxr_io_spec_t ioSpec = soxr_io_spec(SOXR_INT16_I, formatOut);
soxr_quality_spec_t qSpec = soxr_quality_spec(SOXR_20_BITQ, m_dynamicRate ? SOXR_VR : 0);
soxr_error_t err;
m_src = soxr_create(sampleRate, rateOut, 1, &err, &ioSpec, &qSpec, nullptr);
if (err) {
Log.report(logvisor::Fatal, FMT_STRING("unable to create soxr resampler: {}"), soxr_strerror(err));
m_resetSampleRate = false;
return;
}
m_sampleRateIn = sampleRate;
m_sampleRateOut = rateOut;
m_sampleRatio = m_sampleRateIn / m_sampleRateOut;
soxr_set_input_fn(m_src, soxr_input_fn_t(SRCCallback), this, 0);
_setPitchRatio(m_pitchRatio, false);
m_resetSampleRate = false;
}
size_t AudioVoiceMono::SRCCallback(AudioVoiceMono* ctx, int16_t** data, size_t frames) {
std::vector<int16_t>& scratchIn = ctx->m_head->m_scratchIn;
if (scratchIn.size() < frames)
scratchIn.resize(frames);
*data = scratchIn.data();
if (ctx->m_silentOut) {
memset(scratchIn.data(), 0, frames * 2);
return frames;
} else
return ctx->m_cb->supplyAudio(*ctx, frames, scratchIn.data());
}
bool AudioVoiceMono::isSilent() const {
if (m_sendMatrices.size()) {
for (auto& mtx : m_sendMatrices)
if (!mtx.second.isSilent())
return false;
return true;
} else {
return DefaultMonoMtx.isSilent();
}
}
template <typename T>
size_t AudioVoiceMono::_pumpAndMix(size_t frames) {
auto& scratchPre = m_head->_getScratchPre<T>();
if (scratchPre.size() < frames)
scratchPre.resize(frames + 2);
auto& scratchPost = m_head->_getScratchPost<T>();
if (scratchPost.size() < frames)
scratchPost.resize(frames + 2);
double dt = frames / m_sampleRateOut;
m_cb->preSupplyAudio(*this, dt);
_midUpdate();
if (isSilent()) {
int16_t* dummy;
SRCCallback(this, &dummy, size_t(std::ceil(frames * m_sampleRatio)));
return 0;
}
size_t oDone = soxr_output(m_src, scratchPre.data(), frames);
if (oDone) {
if (m_sendMatrices.size()) {
for (auto& mtx : m_sendMatrices) {
AudioSubmix& smx = *reinterpret_cast<AudioSubmix*>(mtx.first);
m_cb->routeAudio(oDone, 1, dt, smx.m_busId, scratchPre.data(), scratchPost.data());
mtx.second.mixMonoSampleData(m_head->clientMixInfo(), scratchPost.data(), smx._getMergeBuf<T>(oDone), oDone);
}
} else {
AudioSubmix& smx = *m_head->m_mainSubmix;
m_cb->routeAudio(oDone, 1, dt, m_head->m_mainSubmix->m_busId, scratchPre.data(), scratchPost.data());
DefaultMonoMtx.mixMonoSampleData(m_head->clientMixInfo(), scratchPost.data(), smx._getMergeBuf<T>(oDone), oDone);
}
}
return oDone;
}
void AudioVoiceMono::resetChannelLevels() {
m_head->m_submixesDirty = true;
m_sendMatrices.clear();
}
void AudioVoiceMono::setMonoChannelLevels(IAudioSubmix* submix, const float coefs[8], bool slew) {
if (!submix)
submix = m_head->m_mainSubmix.get();
auto search = m_sendMatrices.find(submix);
if (search == m_sendMatrices.cend())
search = m_sendMatrices.emplace(submix, AudioMatrixMono{}).first;
search->second.setMatrixCoefficients(coefs, slew ? m_head->m_5msFrames : 0);
}
void AudioVoiceMono::setStereoChannelLevels(IAudioSubmix* submix, const float coefs[8][2], bool slew) {
float newCoefs[8] = {coefs[0][0], coefs[1][0], coefs[2][0], coefs[3][0],
coefs[4][0], coefs[5][0], coefs[6][0], coefs[7][0]};
if (!submix)
submix = m_head->m_mainSubmix.get();
auto search = m_sendMatrices.find(submix);
if (search == m_sendMatrices.cend())
search = m_sendMatrices.emplace(submix, AudioMatrixMono{}).first;
search->second.setMatrixCoefficients(newCoefs, slew ? m_head->m_5msFrames : 0);
}
AudioVoiceStereo::AudioVoiceStereo(BaseAudioVoiceEngine& root, IAudioVoiceCallback* cb, double sampleRate,
bool dynamicRate)
: AudioVoice(root, cb, dynamicRate) {
_resetSampleRate(sampleRate);
}
void AudioVoiceStereo::_resetSampleRate(double sampleRate) {
soxr_delete(m_src);
double rateOut = m_head->mixInfo().m_sampleRate;
soxr_datatype_t formatOut = m_head->mixInfo().m_sampleFormat;
soxr_io_spec_t ioSpec = soxr_io_spec(SOXR_INT16_I, formatOut);
soxr_quality_spec_t qSpec = soxr_quality_spec(SOXR_20_BITQ, m_dynamicRate ? SOXR_VR : 0);
soxr_error_t err;
m_src = soxr_create(sampleRate, rateOut, 2, &err, &ioSpec, &qSpec, nullptr);
if (!m_src) {
Log.report(logvisor::Fatal, FMT_STRING("unable to create soxr resampler: {}"), soxr_strerror(err));
m_resetSampleRate = false;
return;
}
m_sampleRateIn = sampleRate;
m_sampleRateOut = rateOut;
m_sampleRatio = m_sampleRateIn / m_sampleRateOut;
soxr_set_input_fn(m_src, soxr_input_fn_t(SRCCallback), this, 0);
_setPitchRatio(m_pitchRatio, false);
m_resetSampleRate = false;
}
size_t AudioVoiceStereo::SRCCallback(AudioVoiceStereo* ctx, int16_t** data, size_t frames) {
std::vector<int16_t>& scratchIn = ctx->m_head->m_scratchIn;
size_t samples = frames * 2;
if (scratchIn.size() < samples)
scratchIn.resize(samples);
*data = scratchIn.data();
if (ctx->m_silentOut) {
memset(scratchIn.data(), 0, samples * 2);
return frames;
} else
return ctx->m_cb->supplyAudio(*ctx, frames, scratchIn.data());
}
bool AudioVoiceStereo::isSilent() const {
if (m_sendMatrices.size()) {
for (auto& mtx : m_sendMatrices)
if (!mtx.second.isSilent())
return false;
return true;
} else {
return DefaultStereoMtx.isSilent();
}
}
template <typename T>
size_t AudioVoiceStereo::_pumpAndMix(size_t frames) {
size_t samples = frames * 2;
auto& scratchPre = m_head->_getScratchPre<T>();
if (scratchPre.size() < samples)
scratchPre.resize(samples + 4);
auto& scratchPost = m_head->_getScratchPost<T>();
if (scratchPost.size() < samples)
scratchPost.resize(samples + 4);
double dt = frames / m_sampleRateOut;
m_cb->preSupplyAudio(*this, dt);
_midUpdate();
if (isSilent()) {
int16_t* dummy;
SRCCallback(this, &dummy, size_t(std::ceil(frames * m_sampleRatio)));
return 0;
}
size_t oDone = soxr_output(m_src, scratchPre.data(), frames);
if (oDone) {
if (m_sendMatrices.size()) {
for (auto& mtx : m_sendMatrices) {
AudioSubmix& smx = *reinterpret_cast<AudioSubmix*>(mtx.first);
m_cb->routeAudio(oDone, 2, dt, smx.m_busId, scratchPre.data(), scratchPost.data());
mtx.second.mixStereoSampleData(m_head->clientMixInfo(), scratchPost.data(), smx._getMergeBuf<T>(oDone), oDone);
}
} else {
AudioSubmix& smx = *m_head->m_mainSubmix;
m_cb->routeAudio(oDone, 2, dt, m_head->m_mainSubmix->m_busId, scratchPre.data(), scratchPost.data());
DefaultStereoMtx.mixStereoSampleData(m_head->clientMixInfo(), scratchPost.data(), smx._getMergeBuf<T>(oDone),
oDone);
}
}
return oDone;
}
void AudioVoiceStereo::resetChannelLevels() {
m_head->m_submixesDirty = true;
m_sendMatrices.clear();
}
void AudioVoiceStereo::setMonoChannelLevels(IAudioSubmix* submix, const float coefs[8], bool slew) {
float newCoefs[8][2] = {{coefs[0], coefs[0]}, {coefs[1], coefs[1]}, {coefs[2], coefs[2]}, {coefs[3], coefs[3]},
{coefs[4], coefs[4]}, {coefs[5], coefs[5]}, {coefs[6], coefs[6]}, {coefs[7], coefs[7]}};
if (!submix)
submix = m_head->m_mainSubmix.get();
auto search = m_sendMatrices.find(submix);
if (search == m_sendMatrices.cend())
search = m_sendMatrices.emplace(submix, AudioMatrixStereo{}).first;
search->second.setMatrixCoefficients(newCoefs, slew ? m_head->m_5msFrames : 0);
}
void AudioVoiceStereo::setStereoChannelLevels(IAudioSubmix* submix, const float coefs[8][2], bool slew) {
if (!submix)
submix = m_head->m_mainSubmix.get();
auto search = m_sendMatrices.find(submix);
if (search == m_sendMatrices.cend())
search = m_sendMatrices.emplace(submix, AudioMatrixStereo{}).first;
search->second.setMatrixCoefficients(coefs, slew ? m_head->m_5msFrames : 0);
}
} // namespace boo