/** * OpenAL cross platform audio library * Copyright (C) 1999-2007 by authors. * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Library General Public * License as published by the Free Software Foundation; either * version 2 of the License, or (at your option) any later version. * * This library 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 * Library General Public License for more details. * * You should have received a copy of the GNU Library General Public * License along with this library; if not, write to the * Free Software Foundation, Inc., * 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA. * Or go to http://www.gnu.org/copyleft/lgpl.html */ #include "config.h" #include "voice.h" #include #include #include #include #include #include #include #include #include #include #include #include "alcmain.h" #include "albyte.h" #include "alconfig.h" #include "alcontext.h" #include "alnumeric.h" #include "aloptional.h" #include "alspan.h" #include "alstring.h" #include "alu.h" #include "async_event.h" #include "buffer_storage.h" #include "core/devformat.h" #include "core/filters/biquad.h" #include "core/filters/nfc.h" #include "core/filters/splitter.h" #include "core/fmt_traits.h" #include "core/logging.h" #include "core/mixer/defs.h" #include "core/mixer/hrtfdefs.h" #include "cpu_caps.h" #include "hrtf.h" #include "inprogext.h" #include "opthelpers.h" #include "ringbuffer.h" #include "threads.h" #include "vector.h" #include "voice_change.h" struct CTag; #ifdef HAVE_SSE struct SSETag; #endif #ifdef HAVE_NEON struct NEONTag; #endif struct CopyTag; Resampler ResamplerDefault{Resampler::Linear}; MixerFunc MixSamples{Mix_}; namespace { using HrtfMixerFunc = void(*)(const float *InSamples, float2 *AccumSamples, const uint IrSize, const MixHrtfFilter *hrtfparams, const size_t BufferSize); using HrtfMixerBlendFunc = void(*)(const float *InSamples, float2 *AccumSamples, const uint IrSize, const HrtfFilter *oldparams, const MixHrtfFilter *newparams, const size_t BufferSize); HrtfMixerFunc MixHrtfSamples{MixHrtf_}; HrtfMixerBlendFunc MixHrtfBlendSamples{MixHrtfBlend_}; inline MixerFunc SelectMixer() { #ifdef HAVE_NEON if((CPUCapFlags&CPU_CAP_NEON)) return Mix_; #endif #ifdef HAVE_SSE if((CPUCapFlags&CPU_CAP_SSE)) return Mix_; #endif return Mix_; } inline HrtfMixerFunc SelectHrtfMixer() { #ifdef HAVE_NEON if((CPUCapFlags&CPU_CAP_NEON)) return MixHrtf_; #endif #ifdef HAVE_SSE if((CPUCapFlags&CPU_CAP_SSE)) return MixHrtf_; #endif return MixHrtf_; } inline HrtfMixerBlendFunc SelectHrtfBlendMixer() { #ifdef HAVE_NEON if((CPUCapFlags&CPU_CAP_NEON)) return MixHrtfBlend_; #endif #ifdef HAVE_SSE if((CPUCapFlags&CPU_CAP_SSE)) return MixHrtfBlend_; #endif return MixHrtfBlend_; } } // namespace void aluInitMixer() { if(auto resopt = ConfigValueStr(nullptr, nullptr, "resampler")) { struct ResamplerEntry { const char name[16]; const Resampler resampler; }; constexpr ResamplerEntry ResamplerList[]{ { "none", Resampler::Point }, { "point", Resampler::Point }, { "linear", Resampler::Linear }, { "cubic", Resampler::Cubic }, { "bsinc12", Resampler::BSinc12 }, { "fast_bsinc12", Resampler::FastBSinc12 }, { "bsinc24", Resampler::BSinc24 }, { "fast_bsinc24", Resampler::FastBSinc24 }, }; const char *str{resopt->c_str()}; if(al::strcasecmp(str, "bsinc") == 0) { WARN("Resampler option \"%s\" is deprecated, using bsinc12\n", str); str = "bsinc12"; } else if(al::strcasecmp(str, "sinc4") == 0 || al::strcasecmp(str, "sinc8") == 0) { WARN("Resampler option \"%s\" is deprecated, using cubic\n", str); str = "cubic"; } auto iter = std::find_if(std::begin(ResamplerList), std::end(ResamplerList), [str](const ResamplerEntry &entry) -> bool { return al::strcasecmp(str, entry.name) == 0; }); if(iter == std::end(ResamplerList)) ERR("Invalid resampler: %s\n", str); else ResamplerDefault = iter->resampler; } MixSamples = SelectMixer(); MixHrtfBlendSamples = SelectHrtfBlendMixer(); MixHrtfSamples = SelectHrtfMixer(); } namespace { void SendSourceStoppedEvent(ALCcontext *context, uint id) { RingBuffer *ring{context->mAsyncEvents.get()}; auto evt_vec = ring->getWriteVector(); if(evt_vec.first.len < 1) return; AsyncEvent *evt{::new(evt_vec.first.buf) AsyncEvent{EventType_SourceStateChange}}; evt->u.srcstate.id = id; evt->u.srcstate.state = VChangeState::Stop; ring->writeAdvance(1); } const float *DoFilters(BiquadFilter &lpfilter, BiquadFilter &hpfilter, float *dst, const al::span src, int type) { switch(type) { case AF_None: lpfilter.clear(); hpfilter.clear(); break; case AF_LowPass: lpfilter.process(src, dst); hpfilter.clear(); return dst; case AF_HighPass: lpfilter.clear(); hpfilter.process(src, dst); return dst; case AF_BandPass: DualBiquad{lpfilter, hpfilter}.process(src, dst); return dst; } return src.data(); } void LoadSamples(float *RESTRICT dst, const al::byte *src, const size_t srcstep, FmtType srctype, const size_t samples) noexcept { #define HANDLE_FMT(T) case T: al::LoadSampleArray(dst, src, srcstep, samples); break switch(srctype) { HANDLE_FMT(FmtUByte); HANDLE_FMT(FmtShort); HANDLE_FMT(FmtFloat); HANDLE_FMT(FmtDouble); HANDLE_FMT(FmtMulaw); HANDLE_FMT(FmtAlaw); } #undef HANDLE_FMT } float *LoadBufferStatic(BufferlistItem *BufferListItem, BufferlistItem *&BufferLoopItem, const size_t NumChannels, const size_t SampleSize, const size_t chan, size_t DataPosInt, al::span SrcBuffer) { const BufferStorage &Buffer = *BufferListItem->mBuffer; const uint LoopStart{Buffer.mLoopStart}; const uint LoopEnd{Buffer.mLoopEnd}; ASSUME(LoopEnd > LoopStart); /* If current pos is beyond the loop range, do not loop */ if(!BufferLoopItem || DataPosInt >= LoopEnd) { BufferLoopItem = nullptr; /* Load what's left to play from the buffer */ const size_t DataRem{minz(SrcBuffer.size(), Buffer.mSampleLen-DataPosInt)}; const al::byte *Data{Buffer.mData.data()}; Data += (DataPosInt*NumChannels + chan)*SampleSize; LoadSamples(SrcBuffer.data(), Data, NumChannels, Buffer.mType, DataRem); SrcBuffer = SrcBuffer.subspan(DataRem); } else { /* Load what's left of this loop iteration */ const size_t DataRem{minz(SrcBuffer.size(), LoopEnd-DataPosInt)}; const al::byte *Data{Buffer.mData.data()}; Data += (DataPosInt*NumChannels + chan)*SampleSize; LoadSamples(SrcBuffer.data(), Data, NumChannels, Buffer.mType, DataRem); SrcBuffer = SrcBuffer.subspan(DataRem); /* Load any repeats of the loop we can to fill the buffer. */ const auto LoopSize = static_cast(LoopEnd - LoopStart); while(!SrcBuffer.empty()) { const size_t DataSize{minz(SrcBuffer.size(), LoopSize)}; Data = Buffer.mData.data() + (LoopStart*NumChannels + chan)*SampleSize; LoadSamples(SrcBuffer.data(), Data, NumChannels, Buffer.mType, DataSize); SrcBuffer = SrcBuffer.subspan(DataSize); } } return SrcBuffer.begin(); } float *LoadBufferCallback(BufferlistItem *BufferListItem, const size_t NumChannels, const size_t SampleSize, const size_t chan, size_t NumCallbackSamples, al::span SrcBuffer) { const BufferStorage &Buffer = *BufferListItem->mBuffer; /* Load what's left to play from the buffer */ const size_t DataRem{minz(SrcBuffer.size(), NumCallbackSamples)}; const al::byte *Data{Buffer.mData.data() + chan*SampleSize}; LoadSamples(SrcBuffer.data(), Data, NumChannels, Buffer.mType, DataRem); SrcBuffer = SrcBuffer.subspan(DataRem); return SrcBuffer.begin(); } float *LoadBufferQueue(BufferlistItem *BufferListItem, BufferlistItem *BufferLoopItem, const size_t NumChannels, const size_t SampleSize, const size_t chan, size_t DataPosInt, al::span SrcBuffer) { /* Crawl the buffer queue to fill in the temp buffer */ while(BufferListItem && !SrcBuffer.empty()) { BufferStorage *Buffer{BufferListItem->mBuffer}; if(!(Buffer && DataPosInt < Buffer->mSampleLen)) { if(Buffer) DataPosInt -= Buffer->mSampleLen; BufferListItem = BufferListItem->mNext.load(std::memory_order_acquire); if(!BufferListItem) BufferListItem = BufferLoopItem; continue; } const size_t DataSize{minz(SrcBuffer.size(), Buffer->mSampleLen-DataPosInt)}; const al::byte *Data{Buffer->mData.data()}; Data += (DataPosInt*NumChannels + chan)*SampleSize; LoadSamples(SrcBuffer.data(), Data, NumChannels, Buffer->mType, DataSize); SrcBuffer = SrcBuffer.subspan(DataSize); if(SrcBuffer.empty()) break; DataPosInt = 0; BufferListItem = BufferListItem->mNext.load(std::memory_order_acquire); if(!BufferListItem) BufferListItem = BufferLoopItem; } return SrcBuffer.begin(); } void DoHrtfMix(const float *samples, const uint DstBufferSize, DirectParams &parms, const float TargetGain, const uint Counter, uint OutPos, const uint IrSize, ALCdevice *Device) { auto &HrtfSamples = Device->HrtfSourceData; /* Source HRTF mixing needs to include the direct delay so it remains * aligned with the direct mix's HRTF filtering. */ float2 *AccumSamples{Device->HrtfAccumData + HRTF_DIRECT_DELAY}; /* Copy the HRTF history and new input samples into a temp buffer. */ auto src_iter = std::copy(parms.Hrtf.History.begin(), parms.Hrtf.History.end(), std::begin(HrtfSamples)); std::copy_n(samples, DstBufferSize, src_iter); /* Copy the last used samples back into the history buffer for later. */ std::copy_n(std::begin(HrtfSamples) + DstBufferSize, parms.Hrtf.History.size(), parms.Hrtf.History.begin()); /* If fading and this is the first mixing pass, fade between the IRs. */ uint fademix{0u}; if(Counter && OutPos == 0) { fademix = minu(DstBufferSize, Counter); float gain{TargetGain}; /* The new coefficients need to fade in completely since they're * replacing the old ones. To keep the gain fading consistent, * interpolate between the old and new target gains given how much of * the fade time this mix handles. */ if(Counter > fademix) { const float a{static_cast(fademix) / static_cast(Counter)}; gain = lerp(parms.Hrtf.Old.Gain, TargetGain, a); } MixHrtfFilter hrtfparams; hrtfparams.Coeffs = &parms.Hrtf.Target.Coeffs; hrtfparams.Delay = parms.Hrtf.Target.Delay; hrtfparams.Gain = 0.0f; hrtfparams.GainStep = gain / static_cast(fademix); MixHrtfBlendSamples(HrtfSamples, AccumSamples+OutPos, IrSize, &parms.Hrtf.Old, &hrtfparams, fademix); /* Update the old parameters with the result. */ parms.Hrtf.Old = parms.Hrtf.Target; parms.Hrtf.Old.Gain = gain; OutPos += fademix; } if(fademix < DstBufferSize) { const uint todo{DstBufferSize - fademix}; float gain{TargetGain}; /* Interpolate the target gain if the gain fading lasts longer than * this mix. */ if(Counter > DstBufferSize) { const float a{static_cast(todo) / static_cast(Counter-fademix)}; gain = lerp(parms.Hrtf.Old.Gain, TargetGain, a); } MixHrtfFilter hrtfparams; hrtfparams.Coeffs = &parms.Hrtf.Target.Coeffs; hrtfparams.Delay = parms.Hrtf.Target.Delay; hrtfparams.Gain = parms.Hrtf.Old.Gain; hrtfparams.GainStep = (gain - parms.Hrtf.Old.Gain) / static_cast(todo); MixHrtfSamples(HrtfSamples+fademix, AccumSamples+OutPos, IrSize, &hrtfparams, todo); /* Store the now-current gain for next time. */ parms.Hrtf.Old.Gain = gain; } } void DoNfcMix(const al::span samples, FloatBufferLine *OutBuffer, DirectParams &parms, const float *TargetGains, const uint Counter, const uint OutPos, ALCdevice *Device) { using FilterProc = void (NfcFilter::*)(const al::span, float*); static constexpr FilterProc NfcProcess[MaxAmbiOrder+1]{ nullptr, &NfcFilter::process1, &NfcFilter::process2, &NfcFilter::process3}; float *CurrentGains{parms.Gains.Current.data()}; MixSamples(samples, {OutBuffer, 1u}, CurrentGains, TargetGains, Counter, OutPos); ++OutBuffer; ++CurrentGains; ++TargetGains; const al::span nfcsamples{Device->NfcSampleData, samples.size()}; size_t order{1}; while(const size_t chancount{Device->NumChannelsPerOrder[order]}) { (parms.NFCtrlFilter.*NfcProcess[order])(samples, nfcsamples.data()); MixSamples(nfcsamples, {OutBuffer, chancount}, CurrentGains, TargetGains, Counter, OutPos); OutBuffer += chancount; CurrentGains += chancount; TargetGains += chancount; if(++order == MaxAmbiOrder+1) break; } } } // namespace void Voice::mix(const State vstate, ALCcontext *Context, const uint SamplesToDo) { static constexpr std::array SilentTarget{}; ASSUME(SamplesToDo > 0); /* Get voice info */ uint DataPosInt{mPosition.load(std::memory_order_relaxed)}; uint DataPosFrac{mPositionFrac.load(std::memory_order_relaxed)}; BufferlistItem *BufferListItem{mCurrentBuffer.load(std::memory_order_relaxed)}; BufferlistItem *BufferLoopItem{mLoopBuffer.load(std::memory_order_relaxed)}; const uint SampleSize{mSampleSize}; const uint increment{mStep}; if UNLIKELY(increment < 1) { /* If the voice is supposed to be stopping but can't be mixed, just * stop it before bailing. */ if(vstate == Stopping) mPlayState.store(Stopped, std::memory_order_release); return; } ASSUME(SampleSize > 0); const size_t FrameSize{mChans.size() * SampleSize}; ASSUME(FrameSize > 0); ALCdevice *Device{Context->mDevice.get()}; const uint NumSends{Device->NumAuxSends}; const uint IrSize{Device->mIrSize}; ResamplerFunc Resample{(increment == MixerFracOne && DataPosFrac == 0) ? Resample_ : mResampler}; uint Counter{(mFlags&VoiceIsFading) ? SamplesToDo : 0}; if(!Counter) { /* No fading, just overwrite the old/current params. */ for(auto &chandata : mChans) { { DirectParams &parms = chandata.mDryParams; if(!(mFlags&VoiceHasHrtf)) parms.Gains.Current = parms.Gains.Target; else parms.Hrtf.Old = parms.Hrtf.Target; } for(uint send{0};send < NumSends;++send) { if(mSend[send].Buffer.empty()) continue; SendParams &parms = chandata.mWetParams[send]; parms.Gains.Current = parms.Gains.Target; } } } uint buffers_done{0u}; uint OutPos{0u}; do { /* Figure out how many buffer samples will be needed */ uint DstBufferSize{SamplesToDo - OutPos}; uint SrcBufferSize; if(increment <= MixerFracOne) { /* Calculate the last written dst sample pos. */ uint64_t DataSize64{DstBufferSize - 1}; /* Calculate the last read src sample pos. */ DataSize64 = (DataSize64*increment + DataPosFrac) >> MixerFracBits; /* +1 to get the src sample count, include padding. */ DataSize64 += 1 + MaxResamplerPadding; /* Result is guaranteed to be <= BufferLineSize+MaxResamplerPadding * since we won't use more src samples than dst samples+padding. */ SrcBufferSize = static_cast(DataSize64); } else { uint64_t DataSize64{DstBufferSize}; /* Calculate the end src sample pos, include padding. */ DataSize64 = (DataSize64*increment + DataPosFrac) >> MixerFracBits; DataSize64 += MaxResamplerPadding; if(DataSize64 <= BufferLineSize + MaxResamplerPadding) SrcBufferSize = static_cast(DataSize64); else { /* If the source size got saturated, we can't fill the desired * dst size. Figure out how many samples we can actually mix. */ SrcBufferSize = BufferLineSize + MaxResamplerPadding; DataSize64 = SrcBufferSize - MaxResamplerPadding; DataSize64 = ((DataSize64<(DataSize64) & ~3u; } } } if((mFlags&(VoiceIsCallback|VoiceCallbackStopped)) == VoiceIsCallback && BufferListItem) { BufferStorage *buffer{BufferListItem->mBuffer}; /* Exclude resampler pre-padding from the needed size. */ const uint toLoad{SrcBufferSize - (MaxResamplerPadding>>1)}; if(toLoad > mNumCallbackSamples) { const size_t byteOffset{mNumCallbackSamples*FrameSize}; const size_t needBytes{toLoad*FrameSize - byteOffset}; const int gotBytes{buffer->mCallback(buffer->mUserData, &buffer->mData[byteOffset], static_cast(needBytes))}; if(gotBytes < 1) mFlags |= VoiceCallbackStopped; else if(static_cast(gotBytes) < needBytes) { mFlags |= VoiceCallbackStopped; mNumCallbackSamples += static_cast(static_cast(gotBytes) / FrameSize); } else mNumCallbackSamples = toLoad; } } ASSUME(DstBufferSize > 0); for(auto &chandata : mChans) { const size_t num_chans{mChans.size()}; const auto chan = static_cast(std::distance(mChans.data(), std::addressof(chandata))); const al::span SrcData{Device->SourceData, SrcBufferSize}; /* Load the previous samples into the source data first, then load * what we can from the buffer queue. */ auto srciter = std::copy_n(chandata.mPrevSamples.begin(), MaxResamplerPadding>>1, SrcData.begin()); if UNLIKELY(!BufferListItem) srciter = std::copy(chandata.mPrevSamples.begin()+(MaxResamplerPadding>>1), chandata.mPrevSamples.end(), srciter); else if((mFlags&VoiceIsStatic)) srciter = LoadBufferStatic(BufferListItem, BufferLoopItem, num_chans, SampleSize, chan, DataPosInt, {srciter, SrcData.end()}); else if((mFlags&VoiceIsCallback)) srciter = LoadBufferCallback(BufferListItem, num_chans, SampleSize, chan, mNumCallbackSamples, {srciter, SrcData.end()}); else srciter = LoadBufferQueue(BufferListItem, BufferLoopItem, num_chans, SampleSize, chan, DataPosInt, {srciter, SrcData.end()}); if UNLIKELY(srciter != SrcData.end()) { /* If the source buffer wasn't filled, copy the last sample for * the remaining buffer. Ideally it should have ended with * silence, but if not the gain fading should help avoid clicks * from sudden amplitude changes. */ const float sample{*(srciter-1)}; std::fill(srciter, SrcData.end(), sample); } /* Store the last source samples used for next time. */ std::copy_n(&SrcData[(increment*DstBufferSize + DataPosFrac)>>MixerFracBits], chandata.mPrevSamples.size(), chandata.mPrevSamples.begin()); /* Resample, then apply ambisonic upsampling as needed. */ const float *ResampledData{Resample(&mResampleState, &SrcData[MaxResamplerPadding>>1], DataPosFrac, increment, {Device->ResampledData, DstBufferSize})}; if((mFlags&VoiceIsAmbisonic)) { const float hfscale{chandata.mAmbiScale}; /* Beware the evil const_cast. It's safe since it's pointing to * either SourceData or ResampledData (both non-const), but the * resample method takes the source as const float* and may * return it without copying to output, making it currently * unavoidable. */ const al::span samples{const_cast(ResampledData), DstBufferSize}; chandata.mAmbiSplitter.processHfScale(samples, hfscale); } /* Now filter and mix to the appropriate outputs. */ float (&FilterBuf)[BufferLineSize] = Device->FilteredData; { DirectParams &parms = chandata.mDryParams; const float *samples{DoFilters(parms.LowPass, parms.HighPass, FilterBuf, {ResampledData, DstBufferSize}, mDirect.FilterType)}; if((mFlags&VoiceHasHrtf)) { const float TargetGain{UNLIKELY(vstate == Stopping) ? 0.0f : parms.Hrtf.Target.Gain}; DoHrtfMix(samples, DstBufferSize, parms, TargetGain, Counter, OutPos, IrSize, Device); } else if((mFlags&VoiceHasNfc)) { const float *TargetGains{UNLIKELY(vstate == Stopping) ? SilentTarget.data() : parms.Gains.Target.data()}; DoNfcMix({samples, DstBufferSize}, mDirect.Buffer.data(), parms, TargetGains, Counter, OutPos, Device); } else { const float *TargetGains{UNLIKELY(vstate == Stopping) ? SilentTarget.data() : parms.Gains.Target.data()}; MixSamples({samples, DstBufferSize}, mDirect.Buffer, parms.Gains.Current.data(), TargetGains, Counter, OutPos); } } for(uint send{0};send < NumSends;++send) { if(mSend[send].Buffer.empty()) continue; SendParams &parms = chandata.mWetParams[send]; const float *samples{DoFilters(parms.LowPass, parms.HighPass, FilterBuf, {ResampledData, DstBufferSize}, mSend[send].FilterType)}; const float *TargetGains{UNLIKELY(vstate == Stopping) ? SilentTarget.data() : parms.Gains.Target.data()}; MixSamples({samples, DstBufferSize}, mSend[send].Buffer, parms.Gains.Current.data(), TargetGains, Counter, OutPos); } } /* Update positions */ DataPosFrac += increment*DstBufferSize; const uint SrcSamplesDone{DataPosFrac>>MixerFracBits}; DataPosInt += SrcSamplesDone; DataPosFrac &= MixerFracMask; OutPos += DstBufferSize; Counter = maxu(DstBufferSize, Counter) - DstBufferSize; if UNLIKELY(!BufferListItem) { /* Do nothing extra when there's no buffers. */ } else if((mFlags&VoiceIsStatic)) { if(BufferLoopItem) { /* Handle looping static source */ const BufferStorage &Buffer = *BufferListItem->mBuffer; const uint LoopStart{Buffer.mLoopStart}; const uint LoopEnd{Buffer.mLoopEnd}; if(DataPosInt >= LoopEnd) { assert(LoopEnd > LoopStart); DataPosInt = ((DataPosInt-LoopStart)%(LoopEnd-LoopStart)) + LoopStart; } } else { /* Handle non-looping static source */ if(DataPosInt >= BufferListItem->mSampleLen) { BufferListItem = nullptr; break; } } } else if((mFlags&VoiceIsCallback)) { BufferStorage &buffer = *BufferListItem->mBuffer; if(SrcSamplesDone < mNumCallbackSamples) { const size_t byteOffset{SrcSamplesDone*FrameSize}; const size_t byteEnd{mNumCallbackSamples*FrameSize}; al::byte *data{buffer.mData.data()}; std::copy(data+byteOffset, data+byteEnd, data); mNumCallbackSamples -= SrcSamplesDone; } else { BufferListItem = nullptr; mNumCallbackSamples = 0; } } else { /* Handle streaming source */ do { if(BufferListItem->mSampleLen > DataPosInt) break; DataPosInt -= BufferListItem->mSampleLen; ++buffers_done; BufferListItem = BufferListItem->mNext.load(std::memory_order_relaxed); if(!BufferListItem) BufferListItem = BufferLoopItem; } while(BufferListItem); } } while(OutPos < SamplesToDo); mFlags |= VoiceIsFading; /* Don't update positions and buffers if we were stopping. */ if UNLIKELY(vstate == Stopping) { mPlayState.store(Stopped, std::memory_order_release); return; } /* Capture the source ID in case it's reset for stopping. */ const uint SourceID{mSourceID.load(std::memory_order_relaxed)}; /* Update voice info */ mPosition.store(DataPosInt, std::memory_order_relaxed); mPositionFrac.store(DataPosFrac, std::memory_order_relaxed); mCurrentBuffer.store(BufferListItem, std::memory_order_relaxed); if(!BufferListItem) { mLoopBuffer.store(nullptr, std::memory_order_relaxed); mSourceID.store(0u, std::memory_order_relaxed); } std::atomic_thread_fence(std::memory_order_release); /* Send any events now, after the position/buffer info was updated. */ const uint enabledevt{Context->mEnabledEvts.load(std::memory_order_acquire)}; if(buffers_done > 0 && (enabledevt&EventType_BufferCompleted)) { RingBuffer *ring{Context->mAsyncEvents.get()}; auto evt_vec = ring->getWriteVector(); if(evt_vec.first.len > 0) { AsyncEvent *evt{::new(evt_vec.first.buf) AsyncEvent{EventType_BufferCompleted}}; evt->u.bufcomp.id = SourceID; evt->u.bufcomp.count = buffers_done; ring->writeAdvance(1); } } if(!BufferListItem) { /* If the voice just ended, set it to Stopping so the next render * ensures any residual noise fades to 0 amplitude. */ mPlayState.store(Stopping, std::memory_order_release); if((enabledevt&EventType_SourceStateChange)) SendSourceStoppedEvent(Context, SourceID); } }