/* * Fastmix.cpp * ----------- * Purpose: Mixer core for rendering samples, mixing plugins, etc... * Notes : If this is Fastmix.cpp, where is Slowmix.cpp? :) * Authors: Olivier Lapicque * OpenMPT Devs * The OpenMPT source code is released under the BSD license. Read LICENSE for more details. */ // FIXME: // - Playing samples backwards should reverse interpolation LUTs for interpolation modes // with more than two taps since they're not symmetric. We might need separate LUTs // because otherwise we will add tons of branches. // - Loop wraparound works pretty well in general, but not at the start of bidi samples. // - The loop lookahead stuff might still fail for samples with backward loops. #include "stdafx.h" #include "Sndfile.h" #include "MixerLoops.h" #include "MixFuncTable.h" #include "plugins/PlugInterface.h" #include // For FLT_EPSILON #include OPENMPT_NAMESPACE_BEGIN ///////////////////////////////////////////////////////////////////////// struct MixLoopState { const int8 * samplePointer = nullptr; const int8 * lookaheadPointer = nullptr; SmpLength lookaheadStart = 0; uint32 maxSamples = 0; MixLoopState(const ModChannel &chn) { if(chn.pCurrentSample == nullptr) return; UpdateLookaheadPointers(chn); // For platforms that have no fast 64-bit division, precompute this constant // as it won't change during the invocation of CreateStereoMix. SamplePosition increment = chn.increment; if(increment.IsNegative()) increment.Negate(); maxSamples = 16384u / (increment.GetUInt() + 1u); if(maxSamples < 2) maxSamples = 2; } // Calculate offset of loop wrap-around buffer for this sample. void UpdateLookaheadPointers(const ModChannel &chn) { samplePointer = static_cast(chn.pCurrentSample); lookaheadPointer = nullptr; if(!samplePointer) return; if(chn.nLoopEnd < InterpolationMaxLookahead) lookaheadStart = chn.nLoopStart; else lookaheadStart = std::max(chn.nLoopStart, chn.nLoopEnd - InterpolationMaxLookahead); // We only need to apply the loop wrap-around logic if the sample is actually looping and if interpolation is applied. // If there is no interpolation happening, there is no lookahead happening the sample read-out is exact. if(chn.dwFlags[CHN_LOOP] && chn.resamplingMode != SRCMODE_NEAREST) { const bool inSustainLoop = chn.InSustainLoop() && chn.nLoopStart == chn.pModSample->nSustainStart && chn.nLoopEnd == chn.pModSample->nSustainEnd; // Do not enable wraparound magic if we're previewing a custom loop! if(inSustainLoop || chn.nLoopEnd == chn.pModSample->nLoopEnd) { SmpLength lookaheadOffset = 3 * InterpolationMaxLookahead + chn.pModSample->nLength - chn.nLoopEnd; if(inSustainLoop) { lookaheadOffset += 4 * InterpolationMaxLookahead; } lookaheadPointer = samplePointer + lookaheadOffset * chn.pModSample->GetBytesPerSample(); } } } // Returns the buffer length required to render a certain amount of samples, based on the channel's playback speed. static MPT_FORCEINLINE uint32 DistanceToBufferLength(SamplePosition from, SamplePosition to, SamplePosition inc) { return static_cast((to - from - SamplePosition(1)) / inc) + 1; } // Check how many samples can be rendered without encountering loop or sample end, and also update loop position / direction MPT_FORCEINLINE uint32 GetSampleCount(ModChannel &chn, uint32 nSamples, bool ITPingPongMode) const { int32 nLoopStart = chn.dwFlags[CHN_LOOP] ? chn.nLoopStart : 0; SamplePosition nInc = chn.increment; if(nSamples <= 0 || nInc.IsZero() || !chn.nLength || !samplePointer) return 0; // Part 1: Making sure the play position is valid, and if necessary, invert the play direction in case we reached a loop boundary of a ping-pong loop. chn.pCurrentSample = samplePointer; // Under zero ? if (chn.position.GetInt() < nLoopStart) { if (nInc.IsNegative()) { // Invert loop for bidi loops chn.position = SamplePosition(nLoopStart + nLoopStart, 0) - chn.position; if ((chn.position.GetInt() < nLoopStart) || (chn.position.GetUInt() >= (nLoopStart + chn.nLength) / 2)) { chn.position.Set(nLoopStart, 0); } nInc.Negate(); chn.increment = nInc; if(chn.dwFlags[CHN_PINGPONGLOOP]) { chn.dwFlags.reset(CHN_PINGPONGFLAG); // go forward } else { chn.dwFlags.set(CHN_PINGPONGFLAG); chn.position.SetInt(chn.nLength - 1); chn.increment.Negate(); } if(!chn.dwFlags[CHN_LOOP] || chn.position.GetUInt() >= chn.nLength) { chn.position.Set(chn.nLength); return 0; } } else { // We probably didn't hit the loop end yet (first loop), so we do nothing if (chn.position.GetInt() < 0) chn.position.SetInt(0); } } else if (chn.position.GetUInt() >= chn.nLength) { // Past the end if(!chn.dwFlags[CHN_LOOP]) return 0; // not looping -> stop this channel if(chn.dwFlags[CHN_PINGPONGLOOP]) { // Invert loop if (nInc.IsPositive()) { nInc.Negate(); chn.increment = nInc; } chn.dwFlags.set(CHN_PINGPONGFLAG); // adjust loop position SamplePosition invFract = chn.position.GetInvertedFract(); chn.position = SamplePosition(chn.nLength - (chn.position.GetInt() - chn.nLength) - invFract.GetInt(), invFract.GetFract()); if ((chn.position.GetUInt() <= chn.nLoopStart) || (chn.position.GetUInt() >= chn.nLength)) { // Impulse Tracker's software mixer would put a -2 (instead of -1) in the following line (doesn't happen on a GUS) chn.position.SetInt(chn.nLength - std::min(chn.nLength, ITPingPongMode ? SmpLength(2) : SmpLength(1))); } } else { if (nInc.IsNegative()) // This is a bug { nInc.Negate(); chn.increment = nInc; } // Restart at loop start chn.position += SamplePosition(nLoopStart - chn.nLength, 0); MPT_ASSERT(chn.position.GetInt() >= nLoopStart); // Interpolate correctly after wrapping around chn.dwFlags.set(CHN_WRAPPED_LOOP); } } // Part 2: Compute how many samples we can render until we reach the end of sample / loop boundary / etc. SamplePosition nPos = chn.position; // too big increment, and/or too small loop length if (nPos.GetInt() < nLoopStart) { if (nPos.IsNegative() || nInc.IsNegative()) return 0; } if (nPos.IsNegative() || nPos.GetUInt() >= chn.nLength) return 0; uint32 nSmpCount = nSamples; SamplePosition nInv = nInc; if (nInc.IsNegative()) { nInv.Negate(); } LimitMax(nSamples, maxSamples); SamplePosition incSamples = nInc * (nSamples - 1); int32 nPosDest = (nPos + incSamples).GetInt(); const SmpLength nPosInt = nPos.GetUInt(); const bool isAtLoopStart = (nPosInt >= chn.nLoopStart && nPosInt < chn.nLoopStart + InterpolationMaxLookahead); if(!isAtLoopStart) { chn.dwFlags.reset(CHN_WRAPPED_LOOP); } // Loop wrap-around magic. bool checkDest = true; if(lookaheadPointer != nullptr) { if(nPos.GetUInt() >= lookaheadStart) { #if 0 const uint32 oldCount = nSmpCount; // When going backwards - we can only go back up to lookaheadStart. // When going forwards - read through the whole pre-computed wrap-around buffer if possible. // TODO: ProTracker sample swapping needs hard cut at sample end. int32 samplesToRead = nInc.IsNegative() ? (nPosInt - lookaheadStart) //: 2 * InterpolationMaxLookahead - (nPosInt - mixLoopState.lookaheadStart); : (chn.nLoopEnd - nPosInt); //LimitMax(samplesToRead, chn.nLoopEnd - chn.nLoopStart); nSmpCount = SamplesToBufferLength(samplesToRead, chn); Limit(nSmpCount, 1u, oldCount); #else if (nInc.IsNegative()) { nSmpCount = DistanceToBufferLength(SamplePosition(lookaheadStart, 0), nPos, nInv); } else { nSmpCount = DistanceToBufferLength(nPos, SamplePosition(chn.nLoopEnd, 0), nInv); } #endif chn.pCurrentSample = lookaheadPointer; checkDest = false; } else if(chn.dwFlags[CHN_WRAPPED_LOOP] && isAtLoopStart) { // We just restarted the loop, so interpolate correctly after wrapping around nSmpCount = DistanceToBufferLength(nPos, SamplePosition(nLoopStart + InterpolationMaxLookahead, 0), nInv); chn.pCurrentSample = lookaheadPointer + (chn.nLoopEnd - nLoopStart) * chn.pModSample->GetBytesPerSample(); checkDest = false; } else if(nInc.IsPositive() && static_cast(nPosDest) >= lookaheadStart && nSmpCount > 1) { // We shouldn't read that far if we're not using the pre-computed wrap-around buffer. nSmpCount = DistanceToBufferLength(nPos, SamplePosition(lookaheadStart, 0), nInv); checkDest = false; } } if(checkDest) { // Fix up sample count if target position is invalid if (nInc.IsNegative()) { if (nPosDest < nLoopStart) { nSmpCount = DistanceToBufferLength(SamplePosition(nLoopStart, 0), nPos, nInv); } } else { if (nPosDest >= (int32)chn.nLength) { nSmpCount = DistanceToBufferLength(nPos, SamplePosition(chn.nLength, 0), nInv); } } } Limit(nSmpCount, uint32(1u), nSamples); #ifdef MPT_BUILD_DEBUG { SmpLength posDest = (nPos + nInc * (nSmpCount - 1)).GetUInt(); if (posDest < 0 || posDest > chn.nLength) { // We computed an invalid delta! MPT_ASSERT_NOTREACHED(); return 0; } } #endif return nSmpCount; } }; // Render count * number of channels samples void CSoundFile::CreateStereoMix(int count) { mixsample_t *pOfsL, *pOfsR; if(!count) return; // Resetting sound buffer StereoFill(MixSoundBuffer, count, m_dryROfsVol, m_dryLOfsVol); if(m_MixerSettings.gnChannels > 2) StereoFill(MixRearBuffer, count, m_surroundROfsVol, m_surroundLOfsVol); CHANNELINDEX nchmixed = 0; const bool ITPingPongMode = m_playBehaviour[kITPingPongMode]; for(uint32 nChn = 0; nChn < m_nMixChannels; nChn++) { ModChannel &chn = m_PlayState.Chn[m_PlayState.ChnMix[nChn]]; if(!chn.pCurrentSample && !chn.nLOfs && !chn.nROfs) continue; pOfsR = &m_dryROfsVol; pOfsL = &m_dryLOfsVol; uint32 functionNdx = MixFuncTable::ResamplingModeToMixFlags(static_cast(chn.resamplingMode)); if(chn.dwFlags[CHN_16BIT]) functionNdx |= MixFuncTable::ndx16Bit; if(chn.dwFlags[CHN_STEREO]) functionNdx |= MixFuncTable::ndxStereo; #ifndef NO_FILTER if(chn.dwFlags[CHN_FILTER]) functionNdx |= MixFuncTable::ndxFilter; #endif mixsample_t *pbuffer = MixSoundBuffer; #ifndef NO_REVERB if(((m_MixerSettings.DSPMask & SNDDSP_REVERB) && !chn.dwFlags[CHN_NOREVERB]) || chn.dwFlags[CHN_REVERB]) { pbuffer = m_Reverb.GetReverbSendBuffer(count); pOfsR = &m_Reverb.gnRvbROfsVol; pOfsL = &m_Reverb.gnRvbLOfsVol; } #endif if(chn.dwFlags[CHN_SURROUND] && m_MixerSettings.gnChannels > 2) { pbuffer = MixRearBuffer; pOfsR = &m_surroundROfsVol; pOfsL = &m_surroundLOfsVol; } //Look for plugins associated with this implicit tracker channel. #ifndef NO_PLUGINS PLUGINDEX nMixPlugin = GetBestPlugin(m_PlayState.ChnMix[nChn], PrioritiseInstrument, RespectMutes); if ((nMixPlugin > 0) && (nMixPlugin <= MAX_MIXPLUGINS) && m_MixPlugins[nMixPlugin - 1].pMixPlugin != nullptr) { // Render into plugin buffer instead of global buffer SNDMIXPLUGINSTATE &mixState = m_MixPlugins[nMixPlugin - 1].pMixPlugin->m_MixState; if (mixState.pMixBuffer) { pbuffer = mixState.pMixBuffer; pOfsR = &mixState.nVolDecayR; pOfsL = &mixState.nVolDecayL; if (!(mixState.dwFlags & SNDMIXPLUGINSTATE::psfMixReady)) { StereoFill(pbuffer, count, *pOfsR, *pOfsL); mixState.dwFlags |= SNDMIXPLUGINSTATE::psfMixReady; } } } #endif // NO_PLUGINS MixLoopState mixLoopState(chn); //////////////////////////////////////////////////// CHANNELINDEX naddmix = 0; int nsamples = count; // Keep mixing this sample until the buffer is filled. do { uint32 nrampsamples = nsamples; int32 nSmpCount; if(chn.nRampLength > 0) { if (nrampsamples > chn.nRampLength) nrampsamples = chn.nRampLength; } if((nSmpCount = mixLoopState.GetSampleCount(chn, nrampsamples, ITPingPongMode)) <= 0) { // Stopping the channel chn.pCurrentSample = nullptr; chn.nLength = 0; chn.position.Set(0); chn.nRampLength = 0; EndChannelOfs(chn, pbuffer, nsamples); *pOfsR += chn.nROfs; *pOfsL += chn.nLOfs; chn.nROfs = chn.nLOfs = 0; chn.dwFlags.reset(CHN_PINGPONGFLAG); break; } // Should we mix this channel ? if((nchmixed >= m_MixerSettings.m_nMaxMixChannels) // Too many channels || (!chn.nRampLength && !(chn.leftVol | chn.rightVol))) // Channel is completely silent { chn.position += chn.increment * nSmpCount; chn.nROfs = chn.nLOfs = 0; pbuffer += nSmpCount * 2; naddmix = 0; } #ifdef MODPLUG_TRACKER else if(m_SamplePlayLengths != nullptr) { // Detecting the longest play time for each sample for optimization chn.position += chn.increment * nSmpCount; size_t smp = std::distance(static_cast(static_cast::type>(Samples)), chn.pModSample); if(smp < m_SamplePlayLengths->size()) { m_SamplePlayLengths->at(smp) = std::max(m_SamplePlayLengths->at(smp), chn.position.GetUInt()); } } #endif else { // Do mixing mixsample_t *pbufmax = pbuffer + (nSmpCount * 2); chn.nROfs = -*(pbufmax - 2); chn.nLOfs = -*(pbufmax - 1); #ifdef MPT_BUILD_DEBUG SamplePosition targetpos = chn.position + chn.increment * nSmpCount; #endif MixFuncTable::Functions[functionNdx | (chn.nRampLength ? MixFuncTable::ndxRamp : 0)](chn, m_Resampler, pbuffer, nSmpCount); #ifdef MPT_BUILD_DEBUG MPT_ASSERT(chn.position.GetUInt() == targetpos.GetUInt()); #endif chn.nROfs += *(pbufmax - 2); chn.nLOfs += *(pbufmax - 1); pbuffer = pbufmax; naddmix = 1; } nsamples -= nSmpCount; if (chn.nRampLength) { if (chn.nRampLength <= static_cast(nSmpCount)) { // Ramping is done chn.nRampLength = 0; chn.leftVol = chn.newLeftVol; chn.rightVol = chn.newRightVol; chn.rightRamp = chn.leftRamp = 0; if(chn.dwFlags[CHN_NOTEFADE] && !chn.nFadeOutVol) { chn.nLength = 0; chn.pCurrentSample = nullptr; } } else { chn.nRampLength -= nSmpCount; } } const bool pastLoopEnd = chn.position.GetUInt() >= chn.nLoopEnd && chn.dwFlags[CHN_LOOP]; const bool pastSampleEnd = chn.position.GetUInt() >= chn.nLength && !chn.dwFlags[CHN_LOOP] && chn.nLength && !chn.nMasterChn; const bool doSampleSwap = m_playBehaviour[kMODSampleSwap] && chn.nNewIns && chn.nNewIns <= GetNumSamples() && chn.pModSample != &Samples[chn.nNewIns]; if((pastLoopEnd || pastSampleEnd) && doSampleSwap) { // ProTracker compatibility: Instrument changes without a note do not happen instantly, but rather when the sample loop has finished playing. // Test case: PTInstrSwap.mod, PTSwapNoLoop.mod const ModSample &smp = Samples[chn.nNewIns]; chn.pModSample = &smp; chn.pCurrentSample = smp.samplev(); chn.dwFlags = (chn.dwFlags & CHN_CHANNELFLAGS) | smp.uFlags; chn.nLength = smp.uFlags[CHN_LOOP] ? smp.nLoopEnd : 0; // non-looping sample continue in oneshot mode (i.e. they will most probably just play silence) chn.nLoopStart = smp.nLoopStart; chn.nLoopEnd = smp.nLoopEnd; chn.position.SetInt(chn.nLoopStart); mixLoopState.UpdateLookaheadPointers(chn); if(!chn.pCurrentSample) { break; } } else if(pastLoopEnd && !doSampleSwap && m_playBehaviour[kMODOneShotLoops] && chn.nLoopStart == 0) { // ProTracker "oneshot" loops (if loop start is 0, play the whole sample once and then repeat until loop end) chn.position.SetInt(0); chn.nLoopEnd = chn.nLength = chn.pModSample->nLoopEnd; } } while(nsamples > 0); // Restore sample pointer in case it got changed through loop wrap-around chn.pCurrentSample = mixLoopState.samplePointer; nchmixed += naddmix; #ifndef NO_PLUGINS if(naddmix && nMixPlugin > 0 && nMixPlugin <= MAX_MIXPLUGINS && m_MixPlugins[nMixPlugin - 1].pMixPlugin) { m_MixPlugins[nMixPlugin - 1].pMixPlugin->ResetSilence(); } #endif // NO_PLUGINS } m_nMixStat = std::max(m_nMixStat, nchmixed); } void CSoundFile::ProcessPlugins(uint32 nCount) { #ifndef NO_PLUGINS // If any sample channels are active or any plugin has some input, possibly suspended master plugins need to be woken up. bool masterHasInput = (m_nMixStat > 0); #ifdef MPT_INTMIXER const float IntToFloat = m_PlayConfig.getIntToFloat(); const float FloatToInt = m_PlayConfig.getFloatToInt(); #endif // MPT_INTMIXER // Setup float inputs from samples for(PLUGINDEX plug = 0; plug < MAX_MIXPLUGINS; plug++) { SNDMIXPLUGIN &plugin = m_MixPlugins[plug]; if(plugin.pMixPlugin != nullptr && plugin.pMixPlugin->m_MixState.pMixBuffer != nullptr && plugin.pMixPlugin->m_mixBuffer.Ok()) { IMixPlugin *mixPlug = plugin.pMixPlugin; SNDMIXPLUGINSTATE &state = mixPlug->m_MixState; //We should only ever reach this point if the song is playing. if (!mixPlug->IsSongPlaying()) { //Plugin doesn't know it is in a song that is playing; //we must have added it during playback. Initialise it! mixPlug->NotifySongPlaying(true); mixPlug->Resume(); } // Setup float input float *plugInputL = mixPlug->m_mixBuffer.GetInputBuffer(0); float *plugInputR = mixPlug->m_mixBuffer.GetInputBuffer(1); if (state.dwFlags & SNDMIXPLUGINSTATE::psfMixReady) { #ifdef MPT_INTMIXER StereoMixToFloat(state.pMixBuffer, plugInputL, plugInputR, nCount, IntToFloat); #else DeinterleaveStereo(state.pMixBuffer, plugInputL, plugInputR, nCount); #endif // MPT_INTMIXER } else if (state.nVolDecayR || state.nVolDecayL) { StereoFill(state.pMixBuffer, nCount, state.nVolDecayR, state.nVolDecayL); #ifdef MPT_INTMIXER StereoMixToFloat(state.pMixBuffer, plugInputL, plugInputR, nCount, IntToFloat); #else DeinterleaveStereo(state.pMixBuffer, plugInputL, plugInputR, nCount); #endif // MPT_INTMIXER } else { memset(plugInputL, 0, nCount * sizeof(plugInputL[0])); memset(plugInputR, 0, nCount * sizeof(plugInputR[0])); } state.dwFlags &= ~SNDMIXPLUGINSTATE::psfMixReady; if(!plugin.IsMasterEffect() && !(state.dwFlags & SNDMIXPLUGINSTATE::psfSilenceBypass)) { masterHasInput = true; } } } // Convert mix buffer #ifdef MPT_INTMIXER StereoMixToFloat(MixSoundBuffer, MixFloatBuffer[0], MixFloatBuffer[1], nCount, IntToFloat); #else DeinterleaveStereo(MixSoundBuffer, MixFloatBuffer[0], MixFloatBuffer[1], nCount); #endif // MPT_INTMIXER float *pMixL = MixFloatBuffer[0]; float *pMixR = MixFloatBuffer[1]; const bool positionChanged = HasPositionChanged(); // Process Plugins for(PLUGINDEX plug = 0; plug < MAX_MIXPLUGINS; plug++) { SNDMIXPLUGIN &plugin = m_MixPlugins[plug]; if (plugin.pMixPlugin != nullptr && plugin.pMixPlugin->m_MixState.pMixBuffer != nullptr && plugin.pMixPlugin->m_mixBuffer.Ok()) { IMixPlugin *pObject = plugin.pMixPlugin; if(!plugin.IsMasterEffect() && !plugin.pMixPlugin->ShouldProcessSilence() && !(plugin.pMixPlugin->m_MixState.dwFlags & SNDMIXPLUGINSTATE::psfHasInput)) { // If plugin has no inputs and isn't a master plugin, we shouldn't let it process silence if possible. // I have yet to encounter a VST plugin which actually sets this flag. bool hasInput = false; for(PLUGINDEX inPlug = 0; inPlug < plug; inPlug++) { if(m_MixPlugins[inPlug].GetOutputPlugin() == plug) { hasInput = true; break; } } if(!hasInput) { continue; } } bool isMasterMix = false; float *plugInputL = pObject->m_mixBuffer.GetInputBuffer(0); float *plugInputR = pObject->m_mixBuffer.GetInputBuffer(1); if (pMixL == plugInputL) { isMasterMix = true; pMixL = MixFloatBuffer[0]; pMixR = MixFloatBuffer[1]; } SNDMIXPLUGINSTATE &state = plugin.pMixPlugin->m_MixState; float *pOutL = pMixL; float *pOutR = pMixR; if (!plugin.IsOutputToMaster()) { PLUGINDEX nOutput = plugin.GetOutputPlugin(); if(nOutput > plug && nOutput < MAX_MIXPLUGINS && m_MixPlugins[nOutput].pMixPlugin != nullptr) { IMixPlugin *outPlugin = m_MixPlugins[nOutput].pMixPlugin; if(!(state.dwFlags & SNDMIXPLUGINSTATE::psfSilenceBypass)) outPlugin->ResetSilence(); if(outPlugin->m_mixBuffer.Ok()) { pOutL = outPlugin->m_mixBuffer.GetInputBuffer(0); pOutR = outPlugin->m_mixBuffer.GetInputBuffer(1); } } } /* if (plugin.multiRouting) { int nOutput=0; for (int nOutput=0; nOutput < plugin.nOutputs / 2; nOutput++) { destinationPlug = plugin.multiRoutingDestinations[nOutput]; pOutState = m_MixPlugins[destinationPlug].pMixState; pOutputs[2 * nOutput] = plugInputL; pOutputs[2 * (nOutput + 1)] = plugInputR; } }*/ if (plugin.IsMasterEffect()) { if (!isMasterMix) { float *pInL = plugInputL; float *pInR = plugInputR; for (uint32 i=0; iResetSilence(); SNDMIXPLUGIN *chain = &plugin; PLUGINDEX out = chain->GetOutputPlugin(), prevOut = plug; while(out > prevOut && out < MAX_MIXPLUGINS) { chain = &m_MixPlugins[out]; prevOut = out; out = chain->GetOutputPlugin(); if(chain->pMixPlugin) { chain->pMixPlugin->ResetSilence(); } } } } if(plugin.IsBypassed() || (plugin.IsAutoSuspendable() && (state.dwFlags & SNDMIXPLUGINSTATE::psfSilenceBypass))) { const float * const pInL = plugInputL; const float * const pInR = plugInputR; for (uint32 i=0; iPositionChanged(); pObject->Process(pOutL, pOutR, nCount); state.inputSilenceCount += nCount; if(plugin.IsAutoSuspendable() && pObject->GetNumOutputChannels() > 0 && state.inputSilenceCount >= m_MixerSettings.gdwMixingFreq * 4) { bool isSilent = true; for(uint32 i = 0; i < nCount; i++) { if(pOutL[i] >= FLT_EPSILON || pOutL[i] <= -FLT_EPSILON || pOutR[i] >= FLT_EPSILON || pOutR[i] <= -FLT_EPSILON) { isSilent = false; break; } } if(isSilent) { state.dwFlags |= SNDMIXPLUGINSTATE::psfSilenceBypass; } else { state.inputSilenceCount = 0; } } } state.dwFlags &= ~SNDMIXPLUGINSTATE::psfHasInput; } } #ifdef MPT_INTMIXER FloatToStereoMix(pMixL, pMixR, MixSoundBuffer, nCount, FloatToInt); #else InterleaveStereo(pMixL, pMixR, MixSoundBuffer, nCount); #endif // MPT_INTMIXER #else MPT_UNREFERENCED_PARAMETER(nCount); #endif // NO_PLUGINS } OPENMPT_NAMESPACE_END