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Differential D2716 Diff 9122 extern/audaspace/src/fx/BinauralReader.cpp

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extern/audaspace/src/fx/BinauralReader.cpp

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/*******************************************************************************
* Copyright 2015-2016 Juan Francisco Crespo Galán
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
******************************************************************************/
#include "fx/BinauralReader.h"
#include "Exception.h"
#include <cstring>
#include <cstdlib>
#include <algorithm>
#define NUM_OUTCHANNELS 2
#define NUM_CONVOLVERS 4
#define CROSSFADE_SAMPLES 1024
AUD_NAMESPACE_BEGIN
BinauralReader::BinauralReader(std::shared_ptr<IReader> reader, std::shared_ptr<HRTF> hrtfs, std::shared_ptr<Source> source, std::shared_ptr<ThreadPool> threadPool, std::shared_ptr<FFTPlan> plan) :
m_reader(reader), m_hrtfs(hrtfs), m_source(source), m_N(plan->getSize()), m_threadPool(threadPool), m_position(0), m_eosReader(false), m_eosTail(false), m_transition(false), m_transPos(CROSSFADE_SAMPLES*NUM_OUTCHANNELS)
{
if(m_hrtfs->isEmpty())
AUD_THROW(StateException, "The provided HRTF object is empty");
if(m_reader->getSpecs().channels != 1)
AUD_THROW(StateException, "The sound must have only one channel");
if(m_reader->getSpecs().rate != m_hrtfs->getSpecs().rate)
AUD_THROW(StateException, "The sound and the HRTFs must have the same rate");
m_M = m_L = m_N / 2;
m_RealAzimuth = m_Azimuth = m_source->getAzimuth();
m_RealElevation = m_Elevation = m_source->getElevation();
auto irs = m_hrtfs->getImpulseResponse(m_RealAzimuth, m_RealElevation);
for(unsigned int i = 0; i < NUM_CONVOLVERS; i++)
if(i%NUM_OUTCHANNELS==0)
m_convolvers.push_back(std::unique_ptr<Convolver>(new Convolver(irs.first->getChannel(0), irs.first->getLength(), m_threadPool, plan)));
else
m_convolvers.push_back(std::unique_ptr<Convolver>(new Convolver(irs.second->getChannel(0), irs.second->getLength(), m_threadPool, plan)));
m_futures.resize(NUM_CONVOLVERS);
m_outBuffer = (sample_t*)std::malloc(m_L*NUM_OUTCHANNELS*sizeof(sample_t));
m_eOutBufLen = m_outBufLen = m_outBufferPos = m_L * NUM_OUTCHANNELS;
m_inBuffer = (sample_t*)std::malloc(m_L * sizeof(sample_t));
for(int i = 0; i < NUM_CONVOLVERS; i++)
m_vecOut.push_back((sample_t*)std::calloc(m_L, sizeof(sample_t)));
}
BinauralReader::~BinauralReader()
{
std::free(m_outBuffer);
std::free(m_inBuffer);
for(int i = 0; i < m_vecOut.size(); i++)
std::free(m_vecOut[i]);
}
bool BinauralReader::isSeekable() const
{
return m_reader->isSeekable();
}
void BinauralReader::seek(int position)
{
m_position = position;
m_reader->seek(position);
for(int i = 0; i < NUM_CONVOLVERS; i++)
m_convolvers[i]->reset();
m_eosTail = false;
m_eosReader = false;
m_outBufferPos = m_eOutBufLen = m_outBufLen;
m_transition = false;
m_transPos = CROSSFADE_SAMPLES*NUM_OUTCHANNELS;
}
int BinauralReader::getLength() const
{
return m_reader->getLength();
}
int BinauralReader::getPosition() const
{
return m_position;
}
Specs BinauralReader::getSpecs() const
{
Specs specs = m_reader->getSpecs();
specs.channels = CHANNELS_STEREO;
return specs;
}
void BinauralReader::read(int& length, bool& eos, sample_t* buffer)
{
int samples = 0;
int iteration = 0;
if(length <= 0)
{
length = 0;
eos = (m_eosTail && m_outBufferPos >= m_eOutBufLen);
return;
}
eos = false;
int writePos = 0;
do
{
int bufRest = m_eOutBufLen - m_outBufferPos;
int writeLength = std::min((length*NUM_OUTCHANNELS) - writePos, m_eOutBufLen + bufRest);
if(bufRest < writeLength || (m_eOutBufLen == 0 && m_eosTail))
{
if(bufRest > 0)
std::memcpy(buffer + writePos, m_outBuffer + m_outBufferPos, bufRest*sizeof(sample_t));
if(!m_eosTail)
{
int n = NUM_OUTCHANNELS;
if(m_transition)
n = NUM_CONVOLVERS;
else if(checkSource())
n = NUM_CONVOLVERS;
loadBuffer(n);
int len = std::min(std::abs(writeLength - bufRest), m_eOutBufLen);
std::memcpy(buffer + writePos + bufRest, m_outBuffer, len*sizeof(sample_t));
samples += len;
m_outBufferPos = len;
writeLength = std::min((length*NUM_OUTCHANNELS) - writePos, m_eOutBufLen + bufRest);
}
else
{
m_outBufferPos += bufRest;
length = (writePos+bufRest) / NUM_OUTCHANNELS;
eos = true;
return;
}
}
else
{
std::memcpy(buffer + writePos, m_outBuffer + m_outBufferPos, writeLength*sizeof(sample_t));
m_outBufferPos += writeLength;
}
writePos += writeLength;
iteration++;
} while(writePos < length*NUM_OUTCHANNELS);
m_position += length;
}
bool BinauralReader::checkSource()
{
if((m_Azimuth != m_source->getAzimuth() || m_Elevation != m_source->getElevation()) && (!m_eosReader && !m_eosTail))
{
float az = m_Azimuth = m_source->getAzimuth();
float el = m_Elevation = m_source->getElevation();
auto irs = m_hrtfs->getImpulseResponse(az, el);
if(az != m_RealAzimuth || el != m_RealElevation)
{
m_RealAzimuth = az;
m_RealElevation = el;
for(int i = 0; i < NUM_OUTCHANNELS; i++)
{
auto temp = std::move(m_convolvers[i]);
m_convolvers[i] = std::move(m_convolvers[i + NUM_OUTCHANNELS]);
m_convolvers[i + NUM_OUTCHANNELS] = std::move(temp);
}
for(int i = 0; i < NUM_OUTCHANNELS; i++)
if(i%NUM_OUTCHANNELS == 0)
m_convolvers[i]->setImpulseResponse(irs.first->getChannel(0));
else
m_convolvers[i]->setImpulseResponse(irs.second->getChannel(0));
m_transPos = CROSSFADE_SAMPLES*NUM_OUTCHANNELS;
m_transition = true;
return true;
}
}
return false;
}
void BinauralReader::loadBuffer(int nConvolvers)
{
m_lastLengthIn = m_L;
m_reader->read(m_lastLengthIn, m_eosReader, m_inBuffer);
if(!m_eosReader || m_lastLengthIn > 0)
{
int len = m_lastLengthIn;
for(int i = 0; i < nConvolvers; i++)
m_futures[i] = m_threadPool->enqueue(&BinauralReader::threadFunction, this, i, true);
for(int i = 0; i < nConvolvers; i++)
len = m_futures[i].get();
joinByChannel(0, len, nConvolvers);
m_eOutBufLen = len*NUM_OUTCHANNELS;
}
else if(!m_eosTail)
{
int len = m_lastLengthIn = m_L;
for(int i = 0; i < nConvolvers; i++)
m_futures[i] = m_threadPool->enqueue(&BinauralReader::threadFunction, this, i, false);
for(int i = 0; i < nConvolvers; i++)
len = m_futures[i].get();
joinByChannel(0, len, nConvolvers);
m_eOutBufLen = len*NUM_OUTCHANNELS;
}
}
void BinauralReader::joinByChannel(int start, int len, int nConvolvers)
{
int k = 0;
float vol = 0;
const int l = CROSSFADE_SAMPLES*NUM_OUTCHANNELS;
for(int i = 0; i < len*NUM_OUTCHANNELS; i += NUM_OUTCHANNELS)
{
if(m_transition)
{
vol = (m_transPos - i) / (float)l;
if(vol > 1.0f)
vol = 1.0f;
else if(vol < 0.0f)
vol = 0.0f;
}
for(int j = 0; j < NUM_OUTCHANNELS; j++)
m_outBuffer[i + j + start] = ((m_vecOut[j][k] * (1.0f - vol)) + (m_vecOut[j + NUM_OUTCHANNELS][k] * vol))*m_source->getVolume();
k++;
}
if(m_transition)
{
m_transPos -= len*NUM_OUTCHANNELS;
if(m_transPos <= 0)
{
m_transition = false;
m_transPos = l;
}
}
}
int BinauralReader::threadFunction(int id, bool input)
{
int l = m_lastLengthIn;
if(input)
m_convolvers[id]->getNext(m_inBuffer, m_vecOut[id], l, m_eosTail);
else
m_convolvers[id]->getNext(nullptr, m_vecOut[id], l, m_eosTail);
return l;
}
AUD_NAMESPACE_END