mirror of https://github.com/axmolengine/axmol.git
440 lines
15 KiB
C++
440 lines
15 KiB
C++
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#include "config.h"
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#include "mastering.h"
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#include <algorithm>
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#include <cmath>
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#include <cstddef>
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#include <functional>
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#include <iterator>
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#include <limits>
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#include <new>
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#include "almalloc.h"
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#include "alnumeric.h"
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#include "alspan.h"
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#include "opthelpers.h"
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/* These structures assume BufferLineSize is a power of 2. */
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static_assert((BufferLineSize & (BufferLineSize-1)) == 0, "BufferLineSize is not a power of 2");
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struct SlidingHold {
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alignas(16) float mValues[BufferLineSize];
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uint mExpiries[BufferLineSize];
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uint mLowerIndex;
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uint mUpperIndex;
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uint mLength;
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};
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namespace {
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using namespace std::placeholders;
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/* This sliding hold follows the input level with an instant attack and a
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* fixed duration hold before an instant release to the next highest level.
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* It is a sliding window maximum (descending maxima) implementation based on
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* Richard Harter's ascending minima algorithm available at:
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*
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* http://www.richardhartersworld.com/cri/2001/slidingmin.html
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*/
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float UpdateSlidingHold(SlidingHold *Hold, const uint i, const float in)
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{
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static constexpr uint mask{BufferLineSize - 1};
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const uint length{Hold->mLength};
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float (&values)[BufferLineSize] = Hold->mValues;
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uint (&expiries)[BufferLineSize] = Hold->mExpiries;
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uint lowerIndex{Hold->mLowerIndex};
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uint upperIndex{Hold->mUpperIndex};
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if(i >= expiries[upperIndex])
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upperIndex = (upperIndex + 1) & mask;
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if(in >= values[upperIndex])
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{
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values[upperIndex] = in;
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expiries[upperIndex] = i + length;
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lowerIndex = upperIndex;
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}
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else
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{
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do {
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do {
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if(!(in >= values[lowerIndex]))
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goto found_place;
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} while(lowerIndex--);
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lowerIndex = mask;
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} while(true);
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found_place:
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lowerIndex = (lowerIndex + 1) & mask;
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values[lowerIndex] = in;
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expiries[lowerIndex] = i + length;
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}
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Hold->mLowerIndex = lowerIndex;
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Hold->mUpperIndex = upperIndex;
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return values[upperIndex];
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}
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void ShiftSlidingHold(SlidingHold *Hold, const uint n)
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{
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auto exp_begin = std::begin(Hold->mExpiries) + Hold->mUpperIndex;
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auto exp_last = std::begin(Hold->mExpiries) + Hold->mLowerIndex;
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if(exp_last-exp_begin < 0)
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{
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std::transform(exp_begin, std::end(Hold->mExpiries), exp_begin,
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[n](uint e){ return e - n; });
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exp_begin = std::begin(Hold->mExpiries);
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}
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std::transform(exp_begin, exp_last+1, exp_begin, [n](uint e){ return e - n; });
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}
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/* Multichannel compression is linked via the absolute maximum of all
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* channels.
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*/
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void LinkChannels(Compressor *Comp, const uint SamplesToDo, const FloatBufferLine *OutBuffer)
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{
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const size_t numChans{Comp->mNumChans};
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ASSUME(SamplesToDo > 0);
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ASSUME(numChans > 0);
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auto side_begin = std::begin(Comp->mSideChain) + Comp->mLookAhead;
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std::fill(side_begin, side_begin+SamplesToDo, 0.0f);
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auto fill_max = [SamplesToDo,side_begin](const FloatBufferLine &input) -> void
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{
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const float *RESTRICT buffer{al::assume_aligned<16>(input.data())};
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auto max_abs = std::bind(maxf, _1, std::bind(static_cast<float(&)(float)>(std::fabs), _2));
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std::transform(side_begin, side_begin+SamplesToDo, buffer, side_begin, max_abs);
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};
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std::for_each(OutBuffer, OutBuffer+numChans, fill_max);
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}
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/* This calculates the squared crest factor of the control signal for the
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* basic automation of the attack/release times. As suggested by the paper,
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* it uses an instantaneous squared peak detector and a squared RMS detector
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* both with 200ms release times.
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*/
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void CrestDetector(Compressor *Comp, const uint SamplesToDo)
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{
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const float a_crest{Comp->mCrestCoeff};
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float y2_peak{Comp->mLastPeakSq};
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float y2_rms{Comp->mLastRmsSq};
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ASSUME(SamplesToDo > 0);
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auto calc_crest = [&y2_rms,&y2_peak,a_crest](const float x_abs) noexcept -> float
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{
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const float x2{clampf(x_abs * x_abs, 0.000001f, 1000000.0f)};
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y2_peak = maxf(x2, lerpf(x2, y2_peak, a_crest));
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y2_rms = lerpf(x2, y2_rms, a_crest);
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return y2_peak / y2_rms;
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};
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auto side_begin = std::begin(Comp->mSideChain) + Comp->mLookAhead;
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std::transform(side_begin, side_begin+SamplesToDo, std::begin(Comp->mCrestFactor), calc_crest);
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Comp->mLastPeakSq = y2_peak;
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Comp->mLastRmsSq = y2_rms;
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}
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/* The side-chain starts with a simple peak detector (based on the absolute
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* value of the incoming signal) and performs most of its operations in the
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* log domain.
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*/
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void PeakDetector(Compressor *Comp, const uint SamplesToDo)
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{
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ASSUME(SamplesToDo > 0);
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/* Clamp the minimum amplitude to near-zero and convert to logarithm. */
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auto side_begin = std::begin(Comp->mSideChain) + Comp->mLookAhead;
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std::transform(side_begin, side_begin+SamplesToDo, side_begin,
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[](float s) { return std::log(maxf(0.000001f, s)); });
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}
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/* An optional hold can be used to extend the peak detector so it can more
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* solidly detect fast transients. This is best used when operating as a
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* limiter.
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*/
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void PeakHoldDetector(Compressor *Comp, const uint SamplesToDo)
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{
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ASSUME(SamplesToDo > 0);
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SlidingHold *hold{Comp->mHold};
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uint i{0};
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auto detect_peak = [&i,hold](const float x_abs) -> float
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{
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const float x_G{std::log(maxf(0.000001f, x_abs))};
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return UpdateSlidingHold(hold, i++, x_G);
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};
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auto side_begin = std::begin(Comp->mSideChain) + Comp->mLookAhead;
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std::transform(side_begin, side_begin+SamplesToDo, side_begin, detect_peak);
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ShiftSlidingHold(hold, SamplesToDo);
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}
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/* This is the heart of the feed-forward compressor. It operates in the log
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* domain (to better match human hearing) and can apply some basic automation
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* to knee width, attack/release times, make-up/post gain, and clipping
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* reduction.
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*/
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void GainCompressor(Compressor *Comp, const uint SamplesToDo)
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{
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const bool autoKnee{Comp->mAuto.Knee};
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const bool autoAttack{Comp->mAuto.Attack};
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const bool autoRelease{Comp->mAuto.Release};
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const bool autoPostGain{Comp->mAuto.PostGain};
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const bool autoDeclip{Comp->mAuto.Declip};
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const uint lookAhead{Comp->mLookAhead};
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const float threshold{Comp->mThreshold};
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const float slope{Comp->mSlope};
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const float attack{Comp->mAttack};
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const float release{Comp->mRelease};
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const float c_est{Comp->mGainEstimate};
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const float a_adp{Comp->mAdaptCoeff};
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const float *crestFactor{Comp->mCrestFactor};
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float postGain{Comp->mPostGain};
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float knee{Comp->mKnee};
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float t_att{attack};
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float t_rel{release - attack};
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float a_att{std::exp(-1.0f / t_att)};
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float a_rel{std::exp(-1.0f / t_rel)};
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float y_1{Comp->mLastRelease};
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float y_L{Comp->mLastAttack};
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float c_dev{Comp->mLastGainDev};
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ASSUME(SamplesToDo > 0);
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for(float &sideChain : al::span<float>{Comp->mSideChain, SamplesToDo})
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{
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if(autoKnee)
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knee = maxf(0.0f, 2.5f * (c_dev + c_est));
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const float knee_h{0.5f * knee};
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/* This is the gain computer. It applies a static compression curve
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* to the control signal.
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*/
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const float x_over{std::addressof(sideChain)[lookAhead] - threshold};
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const float y_G{
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(x_over <= -knee_h) ? 0.0f :
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(std::fabs(x_over) < knee_h) ? (x_over + knee_h) * (x_over + knee_h) / (2.0f * knee) :
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x_over};
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const float y2_crest{*(crestFactor++)};
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if(autoAttack)
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{
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t_att = 2.0f*attack/y2_crest;
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a_att = std::exp(-1.0f / t_att);
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}
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if(autoRelease)
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{
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t_rel = 2.0f*release/y2_crest - t_att;
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a_rel = std::exp(-1.0f / t_rel);
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}
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/* Gain smoothing (ballistics) is done via a smooth decoupled peak
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* detector. The attack time is subtracted from the release time
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* above to compensate for the chained operating mode.
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*/
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const float x_L{-slope * y_G};
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y_1 = maxf(x_L, lerpf(x_L, y_1, a_rel));
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y_L = lerpf(y_1, y_L, a_att);
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/* Knee width and make-up gain automation make use of a smoothed
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* measurement of deviation between the control signal and estimate.
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* The estimate is also used to bias the measurement to hot-start its
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* average.
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*/
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c_dev = lerpf(-(y_L+c_est), c_dev, a_adp);
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if(autoPostGain)
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{
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/* Clipping reduction is only viable when make-up gain is being
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* automated. It modifies the deviation to further attenuate the
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* control signal when clipping is detected. The adaptation time
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* is sufficiently long enough to suppress further clipping at the
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* same output level.
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*/
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if(autoDeclip)
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c_dev = maxf(c_dev, sideChain - y_L - threshold - c_est);
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postGain = -(c_dev + c_est);
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}
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sideChain = std::exp(postGain - y_L);
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}
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Comp->mLastRelease = y_1;
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Comp->mLastAttack = y_L;
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Comp->mLastGainDev = c_dev;
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}
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/* Combined with the hold time, a look-ahead delay can improve handling of
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* fast transients by allowing the envelope time to converge prior to
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* reaching the offending impulse. This is best used when operating as a
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* limiter.
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*/
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void SignalDelay(Compressor *Comp, const uint SamplesToDo, FloatBufferLine *OutBuffer)
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{
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const size_t numChans{Comp->mNumChans};
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const uint lookAhead{Comp->mLookAhead};
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ASSUME(SamplesToDo > 0);
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ASSUME(numChans > 0);
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ASSUME(lookAhead > 0);
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for(size_t c{0};c < numChans;c++)
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{
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float *inout{al::assume_aligned<16>(OutBuffer[c].data())};
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float *delaybuf{al::assume_aligned<16>(Comp->mDelay[c].data())};
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auto inout_end = inout + SamplesToDo;
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if(SamplesToDo >= lookAhead) LIKELY
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{
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auto delay_end = std::rotate(inout, inout_end - lookAhead, inout_end);
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std::swap_ranges(inout, delay_end, delaybuf);
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}
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else
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{
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auto delay_start = std::swap_ranges(inout, inout_end, delaybuf);
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std::rotate(delaybuf, delay_start, delaybuf + lookAhead);
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}
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}
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}
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} // namespace
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std::unique_ptr<Compressor> Compressor::Create(const size_t NumChans, const float SampleRate,
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const bool AutoKnee, const bool AutoAttack, const bool AutoRelease, const bool AutoPostGain,
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const bool AutoDeclip, const float LookAheadTime, const float HoldTime, const float PreGainDb,
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const float PostGainDb, const float ThresholdDb, const float Ratio, const float KneeDb,
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const float AttackTime, const float ReleaseTime)
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{
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const auto lookAhead = static_cast<uint>(
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clampf(std::round(LookAheadTime*SampleRate), 0.0f, BufferLineSize-1));
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const auto hold = static_cast<uint>(
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clampf(std::round(HoldTime*SampleRate), 0.0f, BufferLineSize-1));
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size_t size{sizeof(Compressor)};
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if(lookAhead > 0)
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{
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size += sizeof(*Compressor::mDelay) * NumChans;
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/* The sliding hold implementation doesn't handle a length of 1. A 1-
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* sample hold is useless anyway, it would only ever give back what was
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* just given to it.
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*/
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if(hold > 1)
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size += sizeof(*Compressor::mHold);
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}
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auto Comp = CompressorPtr{al::construct_at(static_cast<Compressor*>(al_calloc(16, size)))};
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Comp->mNumChans = NumChans;
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Comp->mAuto.Knee = AutoKnee;
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Comp->mAuto.Attack = AutoAttack;
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Comp->mAuto.Release = AutoRelease;
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Comp->mAuto.PostGain = AutoPostGain;
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Comp->mAuto.Declip = AutoPostGain && AutoDeclip;
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Comp->mLookAhead = lookAhead;
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Comp->mPreGain = std::pow(10.0f, PreGainDb / 20.0f);
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Comp->mPostGain = PostGainDb * std::log(10.0f) / 20.0f;
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Comp->mThreshold = ThresholdDb * std::log(10.0f) / 20.0f;
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Comp->mSlope = 1.0f / maxf(1.0f, Ratio) - 1.0f;
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Comp->mKnee = maxf(0.0f, KneeDb * std::log(10.0f) / 20.0f);
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Comp->mAttack = maxf(1.0f, AttackTime * SampleRate);
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Comp->mRelease = maxf(1.0f, ReleaseTime * SampleRate);
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/* Knee width automation actually treats the compressor as a limiter. By
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* varying the knee width, it can effectively be seen as applying
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* compression over a wide range of ratios.
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*/
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if(AutoKnee)
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Comp->mSlope = -1.0f;
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if(lookAhead > 0)
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{
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if(hold > 1)
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{
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Comp->mHold = al::construct_at(reinterpret_cast<SlidingHold*>(Comp.get() + 1));
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Comp->mHold->mValues[0] = -std::numeric_limits<float>::infinity();
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Comp->mHold->mExpiries[0] = hold;
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Comp->mHold->mLength = hold;
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Comp->mDelay = reinterpret_cast<FloatBufferLine*>(Comp->mHold + 1);
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}
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else
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Comp->mDelay = reinterpret_cast<FloatBufferLine*>(Comp.get() + 1);
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std::uninitialized_fill_n(Comp->mDelay, NumChans, FloatBufferLine{});
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}
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Comp->mCrestCoeff = std::exp(-1.0f / (0.200f * SampleRate)); // 200ms
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Comp->mGainEstimate = Comp->mThreshold * -0.5f * Comp->mSlope;
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Comp->mAdaptCoeff = std::exp(-1.0f / (2.0f * SampleRate)); // 2s
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return Comp;
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}
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Compressor::~Compressor()
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{
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if(mHold)
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std::destroy_at(mHold);
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mHold = nullptr;
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if(mDelay)
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std::destroy_n(mDelay, mNumChans);
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mDelay = nullptr;
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}
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void Compressor::process(const uint SamplesToDo, FloatBufferLine *OutBuffer)
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{
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const size_t numChans{mNumChans};
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ASSUME(SamplesToDo > 0);
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ASSUME(numChans > 0);
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const float preGain{mPreGain};
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if(preGain != 1.0f)
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{
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auto apply_gain = [SamplesToDo,preGain](FloatBufferLine &input) noexcept -> void
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{
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float *buffer{al::assume_aligned<16>(input.data())};
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std::transform(buffer, buffer+SamplesToDo, buffer,
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[preGain](float s) { return s * preGain; });
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};
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std::for_each(OutBuffer, OutBuffer+numChans, apply_gain);
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}
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LinkChannels(this, SamplesToDo, OutBuffer);
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if(mAuto.Attack || mAuto.Release)
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CrestDetector(this, SamplesToDo);
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if(mHold)
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PeakHoldDetector(this, SamplesToDo);
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else
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PeakDetector(this, SamplesToDo);
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GainCompressor(this, SamplesToDo);
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if(mDelay)
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SignalDelay(this, SamplesToDo, OutBuffer);
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const float (&sideChain)[BufferLineSize*2] = mSideChain;
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auto apply_comp = [SamplesToDo,&sideChain](FloatBufferLine &input) noexcept -> void
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{
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float *buffer{al::assume_aligned<16>(input.data())};
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const float *gains{al::assume_aligned<16>(&sideChain[0])};
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std::transform(gains, gains+SamplesToDo, buffer, buffer,
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[](float g, float s) { return g * s; });
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};
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std::for_each(OutBuffer, OutBuffer+numChans, apply_comp);
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auto side_begin = std::begin(mSideChain) + SamplesToDo;
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std::copy(side_begin, side_begin+mLookAhead, std::begin(mSideChain));
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}
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