399 lines
13 KiB
C
399 lines
13 KiB
C
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/*
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* IntMixer.h
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* ----------
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* Purpose: Fixed point mixer classes
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* Notes : (currently none)
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* Authors: Olivier Lapicque
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* OpenMPT Devs
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* The OpenMPT source code is released under the BSD license. Read LICENSE for more details.
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*/
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#pragma once
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#include "openmpt/all/BuildSettings.hpp"
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#include "Resampler.h"
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#include "MixerInterface.h"
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#include "Paula.h"
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OPENMPT_NAMESPACE_BEGIN
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template<int channelsOut, int channelsIn, typename out, typename in, size_t mixPrecision>
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struct IntToIntTraits : public MixerTraits<channelsOut, channelsIn, out, in>
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{
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typedef MixerTraits<channelsOut, channelsIn, out, in> base_t;
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typedef typename base_t::input_t input_t;
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typedef typename base_t::output_t output_t;
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static MPT_CONSTEXPRINLINE output_t Convert(const input_t x)
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{
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static_assert(std::numeric_limits<input_t>::is_integer, "Input must be integer");
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static_assert(std::numeric_limits<output_t>::is_integer, "Output must be integer");
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static_assert(sizeof(out) * 8 >= mixPrecision, "Mix precision is higher than output type can handle");
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static_assert(sizeof(in) * 8 <= mixPrecision, "Mix precision is lower than input type");
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return static_cast<output_t>(x) * (1<<(mixPrecision - sizeof(in) * 8));
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}
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};
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typedef IntToIntTraits<2, 1, mixsample_t, int8, 16> Int8MToIntS;
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typedef IntToIntTraits<2, 1, mixsample_t, int16, 16> Int16MToIntS;
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typedef IntToIntTraits<2, 2, mixsample_t, int8, 16> Int8SToIntS;
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typedef IntToIntTraits<2, 2, mixsample_t, int16, 16> Int16SToIntS;
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//////////////////////////////////////////////////////////////////////////
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// Interpolation templates
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template<class Traits>
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struct AmigaBlepInterpolation
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{
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SamplePosition subIncrement;
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Paula::State &paula;
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const Paula::BlepArray &WinSincIntegral;
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const int numSteps;
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unsigned int remainingSamples = 0;
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MPT_FORCEINLINE AmigaBlepInterpolation(ModChannel &chn, const CResampler &resampler, unsigned int numSamples)
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: paula{chn.paulaState}
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, WinSincIntegral{resampler.blepTables.GetAmigaTable(resampler.m_Settings.emulateAmiga, chn.dwFlags[CHN_AMIGAFILTER])}
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, numSteps{chn.paulaState.numSteps}
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{
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if(numSteps)
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{
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subIncrement = chn.increment / numSteps;
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// May we read past the start or end of sample if we do partial sample increments?
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// If that's the case, don't apply any sub increments on the source sample if we reached the last output sample
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// Note that this should only happen with notes well outside the Amiga note range, e.g. in software-mixed formats like MED
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const int32 targetPos = (chn.position + chn.increment * numSamples).GetInt();
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if(static_cast<SmpLength>(targetPos) > chn.nLength)
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remainingSamples = numSamples;
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}
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}
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MPT_FORCEINLINE void operator() (typename Traits::outbuf_t &outSample, const typename Traits::input_t * const MPT_RESTRICT inBuffer, const uint32 posLo)
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{
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if(--remainingSamples == 0)
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subIncrement = {};
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SamplePosition pos(0, posLo);
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// First, process steps of full length (one Amiga clock interval)
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for(int step = numSteps; step > 0; step--)
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{
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typename Traits::output_t inSample = 0;
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int32 posInt = pos.GetInt() * Traits::numChannelsIn;
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for(int32 i = 0; i < Traits::numChannelsIn; i++)
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inSample += Traits::Convert(inBuffer[posInt + i]);
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paula.InputSample(static_cast<int16>(inSample / (4 * Traits::numChannelsIn)));
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paula.Clock(Paula::MINIMUM_INTERVAL);
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pos += subIncrement;
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}
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paula.remainder += paula.stepRemainder;
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// Now, process any remaining integer clock amount < MINIMUM_INTERVAL
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uint32 remainClocks = paula.remainder.GetInt();
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if(remainClocks)
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{
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typename Traits::output_t inSample = 0;
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int32 posInt = pos.GetInt() * Traits::numChannelsIn;
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for(int32 i = 0; i < Traits::numChannelsIn; i++)
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inSample += Traits::Convert(inBuffer[posInt + i]);
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paula.InputSample(static_cast<int16>(inSample / (4 * Traits::numChannelsIn)));
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paula.Clock(remainClocks);
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paula.remainder.RemoveInt();
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}
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auto out = paula.OutputSample(WinSincIntegral);
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for(int i = 0; i < Traits::numChannelsOut; i++)
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outSample[i] = out;
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}
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};
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template<class Traits>
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struct LinearInterpolation
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{
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MPT_FORCEINLINE LinearInterpolation(const ModChannel &, const CResampler &, unsigned int) { }
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MPT_FORCEINLINE void operator() (typename Traits::outbuf_t &outSample, const typename Traits::input_t * const MPT_RESTRICT inBuffer, const uint32 posLo)
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{
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static_assert(static_cast<int>(Traits::numChannelsIn) <= static_cast<int>(Traits::numChannelsOut), "Too many input channels");
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const typename Traits::output_t fract = posLo >> 18u;
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for(int i = 0; i < Traits::numChannelsIn; i++)
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{
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typename Traits::output_t srcVol = Traits::Convert(inBuffer[i]);
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typename Traits::output_t destVol = Traits::Convert(inBuffer[i + Traits::numChannelsIn]);
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outSample[i] = srcVol + ((fract * (destVol - srcVol)) / 16384);
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}
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}
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};
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template<class Traits>
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struct FastSincInterpolation
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{
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MPT_FORCEINLINE FastSincInterpolation(const ModChannel &, const CResampler &, unsigned int) { }
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MPT_FORCEINLINE void operator() (typename Traits::outbuf_t &outSample, const typename Traits::input_t * const MPT_RESTRICT inBuffer, const uint32 posLo)
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{
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static_assert(static_cast<int>(Traits::numChannelsIn) <= static_cast<int>(Traits::numChannelsOut), "Too many input channels");
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const int16 *lut = CResampler::FastSincTable + ((posLo >> 22) & 0x3FC);
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for(int i = 0; i < Traits::numChannelsIn; i++)
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{
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outSample[i] =
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(lut[0] * Traits::Convert(inBuffer[i - Traits::numChannelsIn])
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+ lut[1] * Traits::Convert(inBuffer[i])
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+ lut[2] * Traits::Convert(inBuffer[i + Traits::numChannelsIn])
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+ lut[3] * Traits::Convert(inBuffer[i + 2 * Traits::numChannelsIn])) / 16384;
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}
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}
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};
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template<class Traits>
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struct PolyphaseInterpolation
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{
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const SINC_TYPE *sinc;
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MPT_FORCEINLINE PolyphaseInterpolation(const ModChannel &chn, const CResampler &resampler, unsigned int)
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{
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#ifdef MODPLUG_TRACKER
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// Otherwise causes "warning C4100: 'resampler' : unreferenced formal parameter"
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// because all 3 tables are static members.
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// #pragma warning fails with this templated case for unknown reasons.
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MPT_UNREFERENCED_PARAMETER(resampler);
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#endif // MODPLUG_TRACKER
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sinc = (((chn.increment > SamplePosition(0x130000000ll)) || (chn.increment < SamplePosition(-0x130000000ll))) ?
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(((chn.increment > SamplePosition(0x180000000ll)) || (chn.increment < SamplePosition(-0x180000000ll))) ? resampler.gDownsample2x : resampler.gDownsample13x) : resampler.gKaiserSinc);
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}
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MPT_FORCEINLINE void operator() (typename Traits::outbuf_t &outSample, const typename Traits::input_t * const MPT_RESTRICT inBuffer, const uint32 posLo)
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{
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static_assert(static_cast<int>(Traits::numChannelsIn) <= static_cast<int>(Traits::numChannelsOut), "Too many input channels");
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const SINC_TYPE *lut = sinc + ((posLo >> (32 - SINC_PHASES_BITS)) & SINC_MASK) * SINC_WIDTH;
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for(int i = 0; i < Traits::numChannelsIn; i++)
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{
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outSample[i] =
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(lut[0] * Traits::Convert(inBuffer[i - 3 * Traits::numChannelsIn])
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+ lut[1] * Traits::Convert(inBuffer[i - 2 * Traits::numChannelsIn])
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+ lut[2] * Traits::Convert(inBuffer[i - Traits::numChannelsIn])
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+ lut[3] * Traits::Convert(inBuffer[i])
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+ lut[4] * Traits::Convert(inBuffer[i + Traits::numChannelsIn])
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+ lut[5] * Traits::Convert(inBuffer[i + 2 * Traits::numChannelsIn])
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+ lut[6] * Traits::Convert(inBuffer[i + 3 * Traits::numChannelsIn])
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+ lut[7] * Traits::Convert(inBuffer[i + 4 * Traits::numChannelsIn])) / (1 << SINC_QUANTSHIFT);
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}
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}
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};
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template<class Traits>
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struct FIRFilterInterpolation
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{
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const int16 *WFIRlut;
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MPT_FORCEINLINE FIRFilterInterpolation(const ModChannel &, const CResampler &resampler, unsigned int)
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{
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WFIRlut = resampler.m_WindowedFIR.lut;
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}
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MPT_FORCEINLINE void operator() (typename Traits::outbuf_t &outSample, const typename Traits::input_t * const MPT_RESTRICT inBuffer, const uint32 posLo)
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{
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static_assert(static_cast<int>(Traits::numChannelsIn) <= static_cast<int>(Traits::numChannelsOut), "Too many input channels");
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const int16 * const lut = WFIRlut + ((((posLo >> 16) + WFIR_FRACHALVE) >> WFIR_FRACSHIFT) & WFIR_FRACMASK);
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for(int i = 0; i < Traits::numChannelsIn; i++)
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{
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typename Traits::output_t vol1 =
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(lut[0] * Traits::Convert(inBuffer[i - 3 * Traits::numChannelsIn]))
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+ (lut[1] * Traits::Convert(inBuffer[i - 2 * Traits::numChannelsIn]))
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+ (lut[2] * Traits::Convert(inBuffer[i - Traits::numChannelsIn]))
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+ (lut[3] * Traits::Convert(inBuffer[i]));
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typename Traits::output_t vol2 =
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(lut[4] * Traits::Convert(inBuffer[i + 1 * Traits::numChannelsIn]))
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+ (lut[5] * Traits::Convert(inBuffer[i + 2 * Traits::numChannelsIn]))
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+ (lut[6] * Traits::Convert(inBuffer[i + 3 * Traits::numChannelsIn]))
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+ (lut[7] * Traits::Convert(inBuffer[i + 4 * Traits::numChannelsIn]));
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outSample[i] = ((vol1 / 2) + (vol2 / 2)) / (1 << (WFIR_16BITSHIFT - 1));
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}
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}
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};
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//////////////////////////////////////////////////////////////////////////
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// Mixing templates (add sample to stereo mix)
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template<class Traits>
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struct NoRamp
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{
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typename Traits::output_t lVol, rVol;
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MPT_FORCEINLINE NoRamp(const ModChannel &chn)
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{
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lVol = chn.leftVol;
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rVol = chn.rightVol;
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}
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};
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struct Ramp
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{
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ModChannel &channel;
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int32 lRamp, rRamp;
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MPT_FORCEINLINE Ramp(ModChannel &chn)
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: channel{chn}
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{
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lRamp = chn.rampLeftVol;
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rRamp = chn.rampRightVol;
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}
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MPT_FORCEINLINE ~Ramp()
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{
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channel.rampLeftVol = lRamp; channel.leftVol = lRamp >> VOLUMERAMPPRECISION;
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channel.rampRightVol = rRamp; channel.rightVol = rRamp >> VOLUMERAMPPRECISION;
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}
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};
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// Legacy optimization: If chn.nLeftVol == chn.nRightVol, save one multiplication instruction
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template<class Traits>
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struct MixMonoFastNoRamp : public NoRamp<Traits>
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{
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typedef NoRamp<Traits> base_t;
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MPT_FORCEINLINE void operator() (const typename Traits::outbuf_t &outSample, const ModChannel &, typename Traits::output_t * const MPT_RESTRICT outBuffer)
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{
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typename Traits::output_t vol = outSample[0] * base_t::lVol;
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for(int i = 0; i < Traits::numChannelsOut; i++)
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{
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outBuffer[i] += vol;
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}
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}
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};
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template<class Traits>
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struct MixMonoNoRamp : public NoRamp<Traits>
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{
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typedef NoRamp<Traits> base_t;
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MPT_FORCEINLINE void operator() (const typename Traits::outbuf_t &outSample, const ModChannel &, typename Traits::output_t * const MPT_RESTRICT outBuffer)
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{
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outBuffer[0] += outSample[0] * base_t::lVol;
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outBuffer[1] += outSample[0] * base_t::rVol;
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}
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};
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template<class Traits>
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struct MixMonoRamp : public Ramp
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{
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MPT_FORCEINLINE void operator() (const typename Traits::outbuf_t &outSample, const ModChannel &chn, typename Traits::output_t * const MPT_RESTRICT outBuffer)
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{
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lRamp += chn.leftRamp;
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rRamp += chn.rightRamp;
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outBuffer[0] += outSample[0] * (lRamp >> VOLUMERAMPPRECISION);
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outBuffer[1] += outSample[0] * (rRamp >> VOLUMERAMPPRECISION);
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}
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};
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template<class Traits>
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struct MixStereoNoRamp : public NoRamp<Traits>
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{
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typedef NoRamp<Traits> base_t;
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MPT_FORCEINLINE void operator() (const typename Traits::outbuf_t &outSample, const ModChannel &, typename Traits::output_t * const MPT_RESTRICT outBuffer)
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{
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outBuffer[0] += outSample[0] * base_t::lVol;
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outBuffer[1] += outSample[1] * base_t::rVol;
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}
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};
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template<class Traits>
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struct MixStereoRamp : public Ramp
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{
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MPT_FORCEINLINE void operator() (const typename Traits::outbuf_t &outSample, const ModChannel &chn, typename Traits::output_t * const MPT_RESTRICT outBuffer)
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{
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lRamp += chn.leftRamp;
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rRamp += chn.rightRamp;
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outBuffer[0] += outSample[0] * (lRamp >> VOLUMERAMPPRECISION);
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outBuffer[1] += outSample[1] * (rRamp >> VOLUMERAMPPRECISION);
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}
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};
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//////////////////////////////////////////////////////////////////////////
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// Filter templates
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template<class Traits>
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struct NoFilter
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{
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MPT_FORCEINLINE NoFilter(const ModChannel &) { }
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MPT_FORCEINLINE void operator() (const typename Traits::outbuf_t &, const ModChannel &) { }
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};
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// Resonant filter
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template<class Traits>
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struct ResonantFilter
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{
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ModChannel &channel;
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// Filter history
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typename Traits::output_t fy[Traits::numChannelsIn][2];
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MPT_FORCEINLINE ResonantFilter(ModChannel &chn)
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: channel{chn}
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{
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for(int i = 0; i < Traits::numChannelsIn; i++)
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{
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fy[i][0] = chn.nFilter_Y[i][0];
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fy[i][1] = chn.nFilter_Y[i][1];
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}
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}
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MPT_FORCEINLINE ~ResonantFilter()
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{
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for(int i = 0; i < Traits::numChannelsIn; i++)
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{
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channel.nFilter_Y[i][0] = fy[i][0];
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channel.nFilter_Y[i][1] = fy[i][1];
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}
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}
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// To avoid a precision loss in the state variables especially with quiet samples at low cutoff and high mix rate, we pre-amplify the sample.
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#define MIXING_FILTER_PREAMP 256
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// Filter values are clipped to double the input range
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#define ClipFilter(x) Clamp<typename Traits::output_t, typename Traits::output_t>(x, int16_min * 2 * MIXING_FILTER_PREAMP, int16_max * 2 * MIXING_FILTER_PREAMP)
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MPT_FORCEINLINE void operator() (typename Traits::outbuf_t &outSample, const ModChannel &chn)
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{
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static_assert(static_cast<int>(Traits::numChannelsIn) <= static_cast<int>(Traits::numChannelsOut), "Too many input channels");
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||
|
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||
|
for(int i = 0; i < Traits::numChannelsIn; i++)
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||
|
{
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||
|
const auto inputAmp = outSample[i] * MIXING_FILTER_PREAMP;
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||
|
typename Traits::output_t val = static_cast<typename Traits::output_t>(mpt::rshift_signed(
|
||
|
Util::mul32to64(inputAmp, chn.nFilter_A0) +
|
||
|
Util::mul32to64(ClipFilter(fy[i][0]), chn.nFilter_B0) +
|
||
|
Util::mul32to64(ClipFilter(fy[i][1]), chn.nFilter_B1) +
|
||
|
(1 << (MIXING_FILTER_PRECISION - 1)), MIXING_FILTER_PRECISION));
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||
|
fy[i][1] = fy[i][0];
|
||
|
fy[i][0] = val - (inputAmp & chn.nFilter_HP);
|
||
|
outSample[i] = val / MIXING_FILTER_PREAMP;
|
||
|
}
|
||
|
}
|
||
|
|
||
|
#undef ClipFilter
|
||
|
};
|
||
|
|
||
|
|
||
|
OPENMPT_NAMESPACE_END
|