From 6ac84c7a5f6d267522bdc872802c8940dcd2adec Mon Sep 17 00:00:00 2001 From: Chris Robinson Date: Mon, 19 Nov 2018 21:04:50 -0800 Subject: Clean up the remaining effect struct member names --- Alc/effects/pshifter.cpp | 138 +++++++++++++++++++++++------------------------ 1 file changed, 69 insertions(+), 69 deletions(-) (limited to 'Alc/effects/pshifter.cpp') diff --git a/Alc/effects/pshifter.cpp b/Alc/effects/pshifter.cpp index 217b021e..ec473678 100644 --- a/Alc/effects/pshifter.cpp +++ b/Alc/effects/pshifter.cpp @@ -119,28 +119,28 @@ inline complex_d polar2rect(const ALphasor &number) struct ALpshifterState final : public ALeffectState { /* Effect parameters */ - ALsizei count; - ALsizei PitchShiftI; - ALfloat PitchShift; - ALfloat FreqPerBin; + ALsizei mCount; + ALsizei mPitchShiftI; + ALfloat mPitchShift; + ALfloat mFreqPerBin; - /*Effects buffers*/ - ALfloat InFIFO[STFT_SIZE]; - ALfloat OutFIFO[STFT_STEP]; - ALdouble LastPhase[STFT_HALF_SIZE+1]; - ALdouble SumPhase[STFT_HALF_SIZE+1]; - ALdouble OutputAccum[STFT_SIZE]; + /* Effects buffers */ + ALfloat mInFIFO[STFT_SIZE]; + ALfloat mOutFIFO[STFT_STEP]; + ALdouble mLastPhase[STFT_HALF_SIZE+1]; + ALdouble mSumPhase[STFT_HALF_SIZE+1]; + ALdouble mOutputAccum[STFT_SIZE]; - complex_d FFTbuffer[STFT_SIZE]; + complex_d mFFTbuffer[STFT_SIZE]; - ALfrequencyDomain Analysis_buffer[STFT_HALF_SIZE+1]; - ALfrequencyDomain Syntesis_buffer[STFT_HALF_SIZE+1]; + ALfrequencyDomain mAnalysis_buffer[STFT_HALF_SIZE+1]; + ALfrequencyDomain mSyntesis_buffer[STFT_HALF_SIZE+1]; - alignas(16) ALfloat BufferOut[BUFFERSIZE]; + alignas(16) ALfloat mBufferOut[BUFFERSIZE]; /* Effect gains for each output channel */ - ALfloat CurrentGains[MAX_OUTPUT_CHANNELS]; - ALfloat TargetGains[MAX_OUTPUT_CHANNELS]; + ALfloat mCurrentGains[MAX_OUTPUT_CHANNELS]; + ALfloat mTargetGains[MAX_OUTPUT_CHANNELS]; }; static ALvoid ALpshifterState_Destruct(ALpshifterState *state); @@ -167,22 +167,22 @@ ALvoid ALpshifterState_Destruct(ALpshifterState *state) ALboolean ALpshifterState_deviceUpdate(ALpshifterState *state, ALCdevice *device) { /* (Re-)initializing parameters and clear the buffers. */ - state->count = FIFO_LATENCY; - state->PitchShiftI = FRACTIONONE; - state->PitchShift = 1.0f; - state->FreqPerBin = device->Frequency / (ALfloat)STFT_SIZE; - - std::fill(std::begin(state->InFIFO), std::end(state->InFIFO), 0.0f); - std::fill(std::begin(state->OutFIFO), std::end(state->OutFIFO), 0.0f); - std::fill(std::begin(state->LastPhase), std::end(state->LastPhase), 0.0); - std::fill(std::begin(state->SumPhase), std::end(state->SumPhase), 0.0); - std::fill(std::begin(state->OutputAccum), std::end(state->OutputAccum), 0.0); - std::fill(std::begin(state->FFTbuffer), std::end(state->FFTbuffer), complex_d{}); - std::fill(std::begin(state->Analysis_buffer), std::end(state->Analysis_buffer), ALfrequencyDomain{}); - std::fill(std::begin(state->Syntesis_buffer), std::end(state->Syntesis_buffer), ALfrequencyDomain{}); - - std::fill(std::begin(state->CurrentGains), std::end(state->CurrentGains), 0.0f); - std::fill(std::begin(state->TargetGains), std::end(state->TargetGains), 0.0f); + state->mCount = FIFO_LATENCY; + state->mPitchShiftI = FRACTIONONE; + state->mPitchShift = 1.0f; + state->mFreqPerBin = device->Frequency / (ALfloat)STFT_SIZE; + + std::fill(std::begin(state->mInFIFO), std::end(state->mInFIFO), 0.0f); + std::fill(std::begin(state->mOutFIFO), std::end(state->mOutFIFO), 0.0f); + std::fill(std::begin(state->mLastPhase), std::end(state->mLastPhase), 0.0); + std::fill(std::begin(state->mSumPhase), std::end(state->mSumPhase), 0.0); + std::fill(std::begin(state->mOutputAccum), std::end(state->mOutputAccum), 0.0); + std::fill(std::begin(state->mFFTbuffer), std::end(state->mFFTbuffer), complex_d{}); + std::fill(std::begin(state->mAnalysis_buffer), std::end(state->mAnalysis_buffer), ALfrequencyDomain{}); + std::fill(std::begin(state->mSyntesis_buffer), std::end(state->mSyntesis_buffer), ALfrequencyDomain{}); + + std::fill(std::begin(state->mCurrentGains), std::end(state->mCurrentGains), 0.0f); + std::fill(std::begin(state->mTargetGains), std::end(state->mTargetGains), 0.0f); return AL_TRUE; } @@ -196,11 +196,11 @@ ALvoid ALpshifterState_update(ALpshifterState *state, const ALCcontext *context, pitch = std::pow(2.0f, (ALfloat)(props->Pshifter.CoarseTune*100 + props->Pshifter.FineTune) / 1200.0f ); - state->PitchShiftI = fastf2i(pitch*FRACTIONONE); - state->PitchShift = state->PitchShiftI * (1.0f/FRACTIONONE); + state->mPitchShiftI = fastf2i(pitch*FRACTIONONE); + state->mPitchShift = state->mPitchShiftI * (1.0f/FRACTIONONE); CalcAngleCoeffs(0.0f, 0.0f, 0.0f, coeffs); - ComputePanGains(&device->Dry, coeffs, slot->Params.Gain, state->TargetGains); + ComputePanGains(&device->Dry, coeffs, slot->Params.Gain, state->mTargetGains); } ALvoid ALpshifterState_process(ALpshifterState *state, ALsizei SamplesToDo, const ALfloat (*RESTRICT SamplesIn)[BUFFERSIZE], ALfloat (*RESTRICT SamplesOut)[BUFFERSIZE], ALsizei NumChannels) @@ -210,16 +210,16 @@ ALvoid ALpshifterState_process(ALpshifterState *state, ALsizei SamplesToDo, cons */ static constexpr ALdouble expected{M_PI*2.0 / OVERSAMP}; - const ALdouble freq_per_bin{state->FreqPerBin}; - ALfloat *RESTRICT bufferOut{state->BufferOut}; - ALsizei count{state->count}; + const ALdouble freq_per_bin{state->mFreqPerBin}; + ALfloat *RESTRICT bufferOut{state->mBufferOut}; + ALsizei count{state->mCount}; for(ALsizei i{0};i < SamplesToDo;) { do { /* Fill FIFO buffer with samples data */ - state->InFIFO[count] = SamplesIn[0][i]; - bufferOut[i] = state->OutFIFO[count - FIFO_LATENCY]; + state->mInFIFO[count] = SamplesIn[0][i]; + bufferOut[i] = state->mOutFIFO[count - FIFO_LATENCY]; count++; } while(++i < SamplesToDo && count < STFT_SIZE); @@ -231,13 +231,13 @@ ALvoid ALpshifterState_process(ALpshifterState *state, ALsizei SamplesToDo, cons /* Real signal windowing and store in FFTbuffer */ for(ALsizei k{0};k < STFT_SIZE;k++) { - state->FFTbuffer[k].real(state->InFIFO[k] * HannWindow[k]); - state->FFTbuffer[k].imag(0.0); + state->mFFTbuffer[k].real(state->mInFIFO[k] * HannWindow[k]); + state->mFFTbuffer[k].imag(0.0); } /* ANALYSIS */ /* Apply FFT to FFTbuffer data */ - complex_fft(state->FFTbuffer, STFT_SIZE, -1.0); + complex_fft(state->mFFTbuffer, STFT_SIZE, -1.0); /* Analyze the obtained data. Since the real FFT is symmetric, only * STFT_HALF_SIZE+1 samples are needed. @@ -245,10 +245,10 @@ ALvoid ALpshifterState_process(ALpshifterState *state, ALsizei SamplesToDo, cons for(ALsizei k{0};k < STFT_HALF_SIZE+1;k++) { /* Compute amplitude and phase */ - ALphasor component{rect2polar(state->FFTbuffer[k])}; + ALphasor component{rect2polar(state->mFFTbuffer[k])}; /* Compute phase difference and subtract expected phase difference */ - double tmp{(component.Phase - state->LastPhase[k]) - k*expected}; + double tmp{(component.Phase - state->mLastPhase[k]) - k*expected}; /* Map delta phase into +/- Pi interval */ int qpd{double2int(tmp / M_PI)}; @@ -261,29 +261,29 @@ ALvoid ALpshifterState_process(ALpshifterState *state, ALsizei SamplesToDo, cons * for maintain the gain (because half of bins are used) and store * amplitude and true frequency in analysis buffer. */ - state->Analysis_buffer[k].Amplitude = 2.0 * component.Amplitude; - state->Analysis_buffer[k].Frequency = (k + tmp) * freq_per_bin; + state->mAnalysis_buffer[k].Amplitude = 2.0 * component.Amplitude; + state->mAnalysis_buffer[k].Frequency = (k + tmp) * freq_per_bin; /* Store actual phase[k] for the calculations in the next frame*/ - state->LastPhase[k] = component.Phase; + state->mLastPhase[k] = component.Phase; } /* PROCESSING */ /* pitch shifting */ for(ALsizei k{0};k < STFT_HALF_SIZE+1;k++) { - state->Syntesis_buffer[k].Amplitude = 0.0; - state->Syntesis_buffer[k].Frequency = 0.0; + state->mSyntesis_buffer[k].Amplitude = 0.0; + state->mSyntesis_buffer[k].Frequency = 0.0; } for(ALsizei k{0};k < STFT_HALF_SIZE+1;k++) { - ALsizei j{(k*state->PitchShiftI) >> FRACTIONBITS}; + ALsizei j{(k*state->mPitchShiftI) >> FRACTIONBITS}; if(j >= STFT_HALF_SIZE+1) break; - state->Syntesis_buffer[j].Amplitude += state->Analysis_buffer[k].Amplitude; - state->Syntesis_buffer[j].Frequency = state->Analysis_buffer[k].Frequency * - state->PitchShift; + state->mSyntesis_buffer[j].Amplitude += state->mAnalysis_buffer[k].Amplitude; + state->mSyntesis_buffer[j].Frequency = state->mAnalysis_buffer[k].Frequency * + state->mPitchShift; } /* SYNTHESIS */ @@ -294,41 +294,41 @@ ALvoid ALpshifterState_process(ALpshifterState *state, ALsizei SamplesToDo, cons ALdouble tmp; /* Compute bin deviation from scaled freq */ - tmp = state->Syntesis_buffer[k].Frequency/freq_per_bin - k; + tmp = state->mSyntesis_buffer[k].Frequency/freq_per_bin - k; /* Calculate actual delta phase and accumulate it to get bin phase */ - state->SumPhase[k] += (k + tmp) * expected; + state->mSumPhase[k] += (k + tmp) * expected; - component.Amplitude = state->Syntesis_buffer[k].Amplitude; - component.Phase = state->SumPhase[k]; + component.Amplitude = state->mSyntesis_buffer[k].Amplitude; + component.Phase = state->mSumPhase[k]; /* Compute phasor component to cartesian complex number and storage it into FFTbuffer*/ - state->FFTbuffer[k] = polar2rect(component); + state->mFFTbuffer[k] = polar2rect(component); } /* zero negative frequencies for recontruct a real signal */ for(ALsizei k{STFT_HALF_SIZE+1};k < STFT_SIZE;k++) - state->FFTbuffer[k] = complex_d{}; + state->mFFTbuffer[k] = complex_d{}; /* Apply iFFT to buffer data */ - complex_fft(state->FFTbuffer, STFT_SIZE, 1.0); + complex_fft(state->mFFTbuffer, STFT_SIZE, 1.0); /* Windowing and add to output */ for(ALsizei k{0};k < STFT_SIZE;k++) - state->OutputAccum[k] += HannWindow[k] * state->FFTbuffer[k].real() / - (0.5 * STFT_HALF_SIZE * OVERSAMP); + state->mOutputAccum[k] += HannWindow[k] * state->mFFTbuffer[k].real() / + (0.5 * STFT_HALF_SIZE * OVERSAMP); /* Shift accumulator, input & output FIFO */ ALsizei j, k; - for(k = 0;k < STFT_STEP;k++) state->OutFIFO[k] = (ALfloat)state->OutputAccum[k]; - for(j = 0;k < STFT_SIZE;k++,j++) state->OutputAccum[j] = state->OutputAccum[k]; - for(;j < STFT_SIZE;j++) state->OutputAccum[j] = 0.0; + for(k = 0;k < STFT_STEP;k++) state->mOutFIFO[k] = (ALfloat)state->mOutputAccum[k]; + for(j = 0;k < STFT_SIZE;k++,j++) state->mOutputAccum[j] = state->mOutputAccum[k]; + for(;j < STFT_SIZE;j++) state->mOutputAccum[j] = 0.0; for(k = 0;k < FIFO_LATENCY;k++) - state->InFIFO[k] = state->InFIFO[k+STFT_STEP]; + state->mInFIFO[k] = state->mInFIFO[k+STFT_STEP]; } - state->count = count; + state->mCount = count; /* Now, mix the processed sound data to the output. */ - MixSamples(bufferOut, NumChannels, SamplesOut, state->CurrentGains, state->TargetGains, + MixSamples(bufferOut, NumChannels, SamplesOut, state->mCurrentGains, state->mTargetGains, maxi(SamplesToDo, 512), 0, SamplesToDo); } -- cgit v1.2.3