mirror of https://github.com/axmolengine/axmol.git
248 lines
8.1 KiB
C++
248 lines
8.1 KiB
C++
/**
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* OpenAL cross platform audio library
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* Copyright (C) 2018 by Raul Herraiz.
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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 <cmath>
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#include <complex>
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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 "alcomplex.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 "intrusive_ptr.h"
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namespace {
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using uint = unsigned int;
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using complex_d = std::complex<double>;
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#define HIL_SIZE 1024
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#define OVERSAMP (1<<2)
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#define HIL_STEP (HIL_SIZE / OVERSAMP)
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#define FIFO_LATENCY (HIL_STEP * (OVERSAMP-1))
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/* Define a Hann window, used to filter the HIL input and output. */
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std::array<double,HIL_SIZE> InitHannWindow()
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{
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std::array<double,HIL_SIZE> ret;
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/* Create lookup table of the Hann window for the desired size, i.e. HIL_SIZE */
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for(size_t i{0};i < HIL_SIZE>>1;i++)
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{
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constexpr double scale{al::numbers::pi / double{HIL_SIZE}};
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const double val{std::sin(static_cast<double>(i+1) * scale)};
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ret[i] = ret[HIL_SIZE-1-i] = val * val;
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}
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return ret;
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}
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alignas(16) const std::array<double,HIL_SIZE> HannWindow = InitHannWindow();
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struct FshifterState final : public EffectState {
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/* Effect parameters */
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size_t mCount{};
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size_t mPos{};
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uint mPhaseStep[2]{};
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uint mPhase[2]{};
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double mSign[2]{};
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/* Effects buffers */
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double mInFIFO[HIL_SIZE]{};
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complex_d mOutFIFO[HIL_STEP]{};
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complex_d mOutputAccum[HIL_SIZE]{};
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complex_d mAnalytic[HIL_SIZE]{};
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complex_d mOutdata[BufferLineSize]{};
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alignas(16) float mBufferOut[BufferLineSize]{};
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/* Effect gains for each output channel */
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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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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(FshifterState)
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};
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void FshifterState::deviceUpdate(const DeviceBase*, const Buffer&)
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{
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/* (Re-)initializing parameters and clear the buffers. */
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mCount = 0;
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mPos = FIFO_LATENCY;
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std::fill(std::begin(mPhaseStep), std::end(mPhaseStep), 0u);
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std::fill(std::begin(mPhase), std::end(mPhase), 0u);
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std::fill(std::begin(mSign), std::end(mSign), 1.0);
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std::fill(std::begin(mInFIFO), std::end(mInFIFO), 0.0);
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std::fill(std::begin(mOutFIFO), std::end(mOutFIFO), complex_d{});
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std::fill(std::begin(mOutputAccum), std::end(mOutputAccum), complex_d{});
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std::fill(std::begin(mAnalytic), std::end(mAnalytic), complex_d{});
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for(auto &gain : mGains)
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{
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std::fill(std::begin(gain.Current), std::end(gain.Current), 0.0f);
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std::fill(std::begin(gain.Target), std::end(gain.Target), 0.0f);
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}
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}
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void FshifterState::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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const DeviceBase *device{context->mDevice};
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const float step{props->Fshifter.Frequency / static_cast<float>(device->Frequency)};
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mPhaseStep[0] = mPhaseStep[1] = fastf2u(minf(step, 1.0f) * MixerFracOne);
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switch(props->Fshifter.LeftDirection)
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{
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case FShifterDirection::Down:
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mSign[0] = -1.0;
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break;
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case FShifterDirection::Up:
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mSign[0] = 1.0;
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break;
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case FShifterDirection::Off:
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mPhase[0] = 0;
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mPhaseStep[0] = 0;
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break;
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}
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switch(props->Fshifter.RightDirection)
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{
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case FShifterDirection::Down:
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mSign[1] = -1.0;
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break;
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case FShifterDirection::Up:
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mSign[1] = 1.0;
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break;
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case FShifterDirection::Off:
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mPhase[1] = 0;
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mPhaseStep[1] = 0;
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break;
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}
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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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}
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void FshifterState::process(const size_t samplesToDo, const al::span<const FloatBufferLine> samplesIn, const al::span<FloatBufferLine> samplesOut)
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{
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for(size_t base{0u};base < samplesToDo;)
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{
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size_t todo{minz(HIL_STEP-mCount, samplesToDo-base)};
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/* Fill FIFO buffer with samples data */
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const size_t pos{mPos};
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size_t count{mCount};
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do {
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mInFIFO[pos+count] = samplesIn[0][base];
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mOutdata[base] = mOutFIFO[count];
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++base; ++count;
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} while(--todo);
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mCount = count;
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/* Check whether FIFO buffer is filled */
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if(mCount < HIL_STEP) break;
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mCount = 0;
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mPos = (mPos+HIL_STEP) & (HIL_SIZE-1);
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/* Real signal windowing and store in Analytic buffer */
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for(size_t src{mPos}, k{0u};src < HIL_SIZE;++src,++k)
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mAnalytic[k] = mInFIFO[src]*HannWindow[k];
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for(size_t src{0u}, k{HIL_SIZE-mPos};src < mPos;++src,++k)
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mAnalytic[k] = mInFIFO[src]*HannWindow[k];
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/* Processing signal by Discrete Hilbert Transform (analytical signal). */
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complex_hilbert(mAnalytic);
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/* Windowing and add to output accumulator */
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for(size_t dst{mPos}, k{0u};dst < HIL_SIZE;++dst,++k)
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mOutputAccum[dst] += 2.0/OVERSAMP*HannWindow[k]*mAnalytic[k];
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for(size_t dst{0u}, k{HIL_SIZE-mPos};dst < mPos;++dst,++k)
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mOutputAccum[dst] += 2.0/OVERSAMP*HannWindow[k]*mAnalytic[k];
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/* Copy out the accumulated result, then clear for the next iteration. */
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std::copy_n(mOutputAccum + mPos, HIL_STEP, mOutFIFO);
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std::fill_n(mOutputAccum + mPos, HIL_STEP, complex_d{});
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}
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/* Process frequency shifter using the analytic signal obtained. */
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float *RESTRICT BufferOut{mBufferOut};
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for(int c{0};c < 2;++c)
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{
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const uint phase_step{mPhaseStep[c]};
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uint phase_idx{mPhase[c]};
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for(size_t k{0};k < samplesToDo;++k)
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{
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const double phase{phase_idx * (al::numbers::pi*2.0 / MixerFracOne)};
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BufferOut[k] = static_cast<float>(mOutdata[k].real()*std::cos(phase) +
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mOutdata[k].imag()*std::sin(phase)*mSign[c]);
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phase_idx += phase_step;
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phase_idx &= MixerFracMask;
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}
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mPhase[c] = phase_idx;
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/* Now, mix the processed sound data to the output. */
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MixSamples({BufferOut, samplesToDo}, samplesOut, mGains[c].Current, mGains[c].Target,
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maxz(samplesToDo, 512), 0);
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}
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}
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struct FshifterStateFactory final : public EffectStateFactory {
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al::intrusive_ptr<EffectState> create() override
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{ return al::intrusive_ptr<EffectState>{new FshifterState{}}; }
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};
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} // namespace
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EffectStateFactory *FshifterStateFactory_getFactory()
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{
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static FshifterStateFactory FshifterFactory{};
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return &FshifterFactory;
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}
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