mirror of https://github.com/axmolengine/axmol.git
294 lines
9.8 KiB
C++
294 lines
9.8 KiB
C++
/**
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* OpenAL cross platform audio library
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* Copyright (C) 2013 by Mike Gorchak
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* This library is free software; you can redistribute it and/or
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* modify it under the terms of the GNU Library General Public
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* License as published by the Free Software Foundation; either
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* version 2 of the License, or (at your option) any later version.
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*
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* This library is distributed in the hope that it will be useful,
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* but WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
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* Library General Public License for more details.
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*
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* You should have received a copy of the GNU Library General Public
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* License along with this library; if not, write to the
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* Free Software Foundation, Inc.,
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* 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
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* Or go to http://www.gnu.org/copyleft/lgpl.html
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*/
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#include "config.h"
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#include <algorithm>
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#include <array>
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#include <climits>
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#include <cstdlib>
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#include <iterator>
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#include "alc/effects/base.h"
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#include "almalloc.h"
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#include "alnumbers.h"
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#include "alnumeric.h"
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#include "alspan.h"
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#include "core/bufferline.h"
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#include "core/context.h"
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#include "core/devformat.h"
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#include "core/device.h"
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#include "core/effectslot.h"
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#include "core/mixer.h"
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#include "core/mixer/defs.h"
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#include "core/resampler_limits.h"
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#include "intrusive_ptr.h"
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#include "opthelpers.h"
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#include "vector.h"
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namespace {
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using uint = unsigned int;
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#define MAX_UPDATE_SAMPLES 256
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struct ChorusState final : public EffectState {
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al::vector<float,16> mSampleBuffer;
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uint mOffset{0};
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uint mLfoOffset{0};
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uint mLfoRange{1};
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float mLfoScale{0.0f};
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uint mLfoDisp{0};
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/* Gains for left and right sides */
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struct {
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float Current[MAX_OUTPUT_CHANNELS]{};
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float Target[MAX_OUTPUT_CHANNELS]{};
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} mGains[2];
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/* effect parameters */
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ChorusWaveform mWaveform{};
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int mDelay{0};
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float mDepth{0.0f};
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float mFeedback{0.0f};
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void getTriangleDelays(uint (*delays)[MAX_UPDATE_SAMPLES], const size_t todo);
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void getSinusoidDelays(uint (*delays)[MAX_UPDATE_SAMPLES], const size_t todo);
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void deviceUpdate(const DeviceBase *device, const Buffer &buffer) override;
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void update(const ContextBase *context, const EffectSlot *slot, const EffectProps *props,
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const EffectTarget target) override;
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void process(const size_t samplesToDo, const al::span<const FloatBufferLine> samplesIn,
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const al::span<FloatBufferLine> samplesOut) override;
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DEF_NEWDEL(ChorusState)
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};
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void ChorusState::deviceUpdate(const DeviceBase *Device, const Buffer&)
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{
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constexpr float max_delay{maxf(ChorusMaxDelay, FlangerMaxDelay)};
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const auto frequency = static_cast<float>(Device->Frequency);
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const size_t maxlen{NextPowerOf2(float2uint(max_delay*2.0f*frequency) + 1u)};
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if(maxlen != mSampleBuffer.size())
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al::vector<float,16>(maxlen).swap(mSampleBuffer);
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std::fill(mSampleBuffer.begin(), mSampleBuffer.end(), 0.0f);
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for(auto &e : mGains)
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{
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std::fill(std::begin(e.Current), std::end(e.Current), 0.0f);
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std::fill(std::begin(e.Target), std::end(e.Target), 0.0f);
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}
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}
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void ChorusState::update(const ContextBase *Context, const EffectSlot *Slot,
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const EffectProps *props, const EffectTarget target)
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{
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constexpr int mindelay{(MaxResamplerPadding>>1) << MixerFracBits};
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/* The LFO depth is scaled to be relative to the sample delay. Clamp the
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* delay and depth to allow enough padding for resampling.
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*/
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const DeviceBase *device{Context->mDevice};
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const auto frequency = static_cast<float>(device->Frequency);
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mWaveform = props->Chorus.Waveform;
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mDelay = maxi(float2int(props->Chorus.Delay*frequency*MixerFracOne + 0.5f), mindelay);
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mDepth = minf(props->Chorus.Depth * static_cast<float>(mDelay),
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static_cast<float>(mDelay - mindelay));
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mFeedback = props->Chorus.Feedback;
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/* Gains for left and right sides */
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const auto lcoeffs = CalcDirectionCoeffs({-1.0f, 0.0f, 0.0f}, 0.0f);
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const auto rcoeffs = CalcDirectionCoeffs({ 1.0f, 0.0f, 0.0f}, 0.0f);
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mOutTarget = target.Main->Buffer;
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ComputePanGains(target.Main, lcoeffs.data(), Slot->Gain, mGains[0].Target);
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ComputePanGains(target.Main, rcoeffs.data(), Slot->Gain, mGains[1].Target);
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float rate{props->Chorus.Rate};
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if(!(rate > 0.0f))
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{
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mLfoOffset = 0;
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mLfoRange = 1;
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mLfoScale = 0.0f;
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mLfoDisp = 0;
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}
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else
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{
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/* Calculate LFO coefficient (number of samples per cycle). Limit the
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* max range to avoid overflow when calculating the displacement.
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*/
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uint lfo_range{float2uint(minf(frequency/rate + 0.5f, float{INT_MAX/360 - 180}))};
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mLfoOffset = mLfoOffset * lfo_range / mLfoRange;
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mLfoRange = lfo_range;
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switch(mWaveform)
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{
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case ChorusWaveform::Triangle:
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mLfoScale = 4.0f / static_cast<float>(mLfoRange);
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break;
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case ChorusWaveform::Sinusoid:
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mLfoScale = al::numbers::pi_v<float>*2.0f / static_cast<float>(mLfoRange);
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break;
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}
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/* Calculate lfo phase displacement */
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int phase{props->Chorus.Phase};
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if(phase < 0) phase = 360 + phase;
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mLfoDisp = (mLfoRange*static_cast<uint>(phase) + 180) / 360;
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}
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}
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void ChorusState::getTriangleDelays(uint (*delays)[MAX_UPDATE_SAMPLES], const size_t todo)
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{
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const uint lfo_range{mLfoRange};
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const float lfo_scale{mLfoScale};
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const float depth{mDepth};
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const int delay{mDelay};
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ASSUME(lfo_range > 0);
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ASSUME(todo > 0);
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uint offset{mLfoOffset};
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auto gen_lfo = [&offset,lfo_range,lfo_scale,depth,delay]() -> uint
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{
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offset = (offset+1)%lfo_range;
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const float offset_norm{static_cast<float>(offset) * lfo_scale};
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return static_cast<uint>(fastf2i((1.0f-std::abs(2.0f-offset_norm)) * depth) + delay);
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};
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std::generate_n(delays[0], todo, gen_lfo);
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offset = (mLfoOffset+mLfoDisp) % lfo_range;
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std::generate_n(delays[1], todo, gen_lfo);
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mLfoOffset = static_cast<uint>(mLfoOffset+todo) % lfo_range;
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}
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void ChorusState::getSinusoidDelays(uint (*delays)[MAX_UPDATE_SAMPLES], const size_t todo)
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{
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const uint lfo_range{mLfoRange};
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const float lfo_scale{mLfoScale};
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const float depth{mDepth};
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const int delay{mDelay};
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ASSUME(lfo_range > 0);
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ASSUME(todo > 0);
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uint offset{mLfoOffset};
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auto gen_lfo = [&offset,lfo_range,lfo_scale,depth,delay]() -> uint
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{
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offset = (offset+1)%lfo_range;
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const float offset_norm{static_cast<float>(offset) * lfo_scale};
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return static_cast<uint>(fastf2i(std::sin(offset_norm)*depth) + delay);
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};
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std::generate_n(delays[0], todo, gen_lfo);
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offset = (mLfoOffset+mLfoDisp) % lfo_range;
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std::generate_n(delays[1], todo, gen_lfo);
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mLfoOffset = static_cast<uint>(mLfoOffset+todo) % lfo_range;
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}
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void ChorusState::process(const size_t samplesToDo, const al::span<const FloatBufferLine> samplesIn, const al::span<FloatBufferLine> samplesOut)
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{
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const size_t bufmask{mSampleBuffer.size()-1};
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const float feedback{mFeedback};
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const uint avgdelay{(static_cast<uint>(mDelay) + (MixerFracOne>>1)) >> MixerFracBits};
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float *RESTRICT delaybuf{mSampleBuffer.data()};
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uint offset{mOffset};
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for(size_t base{0u};base < samplesToDo;)
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{
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const size_t todo{minz(MAX_UPDATE_SAMPLES, samplesToDo-base)};
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uint moddelays[2][MAX_UPDATE_SAMPLES];
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if(mWaveform == ChorusWaveform::Sinusoid)
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getSinusoidDelays(moddelays, todo);
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else /*if(mWaveform == ChorusWaveform::Triangle)*/
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getTriangleDelays(moddelays, todo);
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alignas(16) float temps[2][MAX_UPDATE_SAMPLES];
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for(size_t i{0u};i < todo;++i)
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{
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// Feed the buffer's input first (necessary for delays < 1).
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delaybuf[offset&bufmask] = samplesIn[0][base+i];
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// Tap for the left output.
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uint delay{offset - (moddelays[0][i]>>MixerFracBits)};
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float mu{static_cast<float>(moddelays[0][i]&MixerFracMask) * (1.0f/MixerFracOne)};
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temps[0][i] = cubic(delaybuf[(delay+1) & bufmask], delaybuf[(delay ) & bufmask],
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delaybuf[(delay-1) & bufmask], delaybuf[(delay-2) & bufmask], mu);
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// Tap for the right output.
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delay = offset - (moddelays[1][i]>>MixerFracBits);
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mu = static_cast<float>(moddelays[1][i]&MixerFracMask) * (1.0f/MixerFracOne);
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temps[1][i] = cubic(delaybuf[(delay+1) & bufmask], delaybuf[(delay ) & bufmask],
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delaybuf[(delay-1) & bufmask], delaybuf[(delay-2) & bufmask], mu);
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// Accumulate feedback from the average delay of the taps.
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delaybuf[offset&bufmask] += delaybuf[(offset-avgdelay) & bufmask] * feedback;
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++offset;
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}
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for(size_t c{0};c < 2;++c)
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MixSamples({temps[c], todo}, samplesOut, mGains[c].Current, mGains[c].Target,
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samplesToDo-base, base);
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base += todo;
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}
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mOffset = offset;
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}
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struct ChorusStateFactory final : public EffectStateFactory {
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al::intrusive_ptr<EffectState> create() override
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{ return al::intrusive_ptr<EffectState>{new ChorusState{}}; }
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};
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/* Flanger is basically a chorus with a really short delay. They can both use
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* the same processing functions, so piggyback flanger on the chorus functions.
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*/
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struct FlangerStateFactory final : public EffectStateFactory {
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al::intrusive_ptr<EffectState> create() override
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{ return al::intrusive_ptr<EffectState>{new ChorusState{}}; }
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};
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} // namespace
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EffectStateFactory *ChorusStateFactory_getFactory()
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{
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static ChorusStateFactory ChorusFactory{};
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return &ChorusFactory;
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}
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EffectStateFactory *FlangerStateFactory_getFactory()
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{
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static FlangerStateFactory FlangerFactory{};
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return &FlangerFactory;
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}
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