boo/lib/audiodev/AudioMatrix.cpp

297 lines
9.6 KiB
C++

#include "AudioMatrix.hpp"
#include "AudioVoiceEngine.hpp"
#include <string.h>
namespace boo
{
void AudioMatrixMono::setDefaultMatrixCoefficients(AudioChannelSet acSet)
{
m_curSlewFrame = 0;
m_slewFrames = 0;
memset(&m_coefs, 0, sizeof(m_coefs));
switch (acSet)
{
case AudioChannelSet::Stereo:
case AudioChannelSet::Quad:
m_coefs.v[int(AudioChannel::FrontLeft)] = 1.0;
m_coefs.v[int(AudioChannel::FrontRight)] = 1.0;
break;
case AudioChannelSet::Surround51:
case AudioChannelSet::Surround71:
m_coefs.v[int(AudioChannel::FrontCenter)] = 1.0;
break;
default: break;
}
}
int16_t* AudioMatrixMono::mixMonoSampleData(const AudioVoiceEngineMixInfo& info,
const int16_t* dataIn, int16_t* dataOut, size_t samples)
{
const ChannelMap& chmap = info.m_channelMap;
for (size_t s=0 ; s<samples ; ++s, ++dataIn)
{
if (m_slewFrames && m_curSlewFrame < m_slewFrames)
{
double t = m_curSlewFrame / double(m_slewFrames);
double omt = 1.0 - t;
for (unsigned c=0 ; c<chmap.m_channelCount ; ++c)
{
AudioChannel ch = chmap.m_channels[c];
if (ch != AudioChannel::Unknown)
{
*dataOut = Clamp16(*dataOut + *dataIn * (m_coefs.v[int(ch)] * t + m_oldCoefs.v[int(ch)] * omt));
++dataOut;
}
}
++m_curSlewFrame;
}
else
{
for (unsigned c=0 ; c<chmap.m_channelCount ; ++c)
{
AudioChannel ch = chmap.m_channels[c];
if (ch != AudioChannel::Unknown)
{
*dataOut = Clamp16(*dataOut + *dataIn * m_coefs.v[int(ch)]);
++dataOut;
}
}
}
}
return dataOut;
}
int32_t* AudioMatrixMono::mixMonoSampleData(const AudioVoiceEngineMixInfo& info,
const int32_t* dataIn, int32_t* dataOut, size_t samples)
{
const ChannelMap& chmap = info.m_channelMap;
for (size_t s=0 ; s<samples ; ++s, ++dataIn)
{
if (m_slewFrames && m_curSlewFrame < m_slewFrames)
{
double t = m_curSlewFrame / double(m_slewFrames);
double omt = 1.0 - t;
for (unsigned c=0 ; c<chmap.m_channelCount ; ++c)
{
AudioChannel ch = chmap.m_channels[c];
if (ch != AudioChannel::Unknown)
{
*dataOut = Clamp32(*dataOut + *dataIn * (m_coefs.v[int(ch)] * t + m_oldCoefs.v[int(ch)] * omt));
++dataOut;
}
}
++m_curSlewFrame;
}
else
{
for (unsigned c=0 ; c<chmap.m_channelCount ; ++c)
{
AudioChannel ch = chmap.m_channels[c];
if (ch != AudioChannel::Unknown)
{
*dataOut = Clamp32(*dataOut + *dataIn * m_coefs.v[int(ch)]);
++dataOut;
}
}
}
}
return dataOut;
}
float* AudioMatrixMono::mixMonoSampleData(const AudioVoiceEngineMixInfo& info,
const float* dataIn, float* dataOut, size_t samples)
{
const ChannelMap& chmap = info.m_channelMap;
for (size_t s=0 ; s<samples ; ++s, ++dataIn)
{
if (m_slewFrames && m_curSlewFrame < m_slewFrames)
{
double t = m_curSlewFrame / double(m_slewFrames);
double omt = 1.0 - t;
for (unsigned c=0 ; c<chmap.m_channelCount ; ++c)
{
AudioChannel ch = chmap.m_channels[c];
if (ch != AudioChannel::Unknown)
{
*dataOut = ClampFlt(*dataOut + *dataIn * (m_coefs.v[int(ch)] * t + m_oldCoefs.v[int(ch)] * omt));
++dataOut;
}
}
++m_curSlewFrame;
}
else
{
for (unsigned c=0 ; c<chmap.m_channelCount ; ++c)
{
AudioChannel ch = chmap.m_channels[c];
if (ch != AudioChannel::Unknown)
{
*dataOut = ClampFlt(*dataOut + *dataIn * m_coefs.v[int(ch)]);
++dataOut;
}
}
}
}
return dataOut;
}
void AudioMatrixStereo::setDefaultMatrixCoefficients(AudioChannelSet acSet)
{
m_curSlewFrame = 0;
m_slewFrames = 0;
memset(&m_coefs, 0, sizeof(m_coefs));
switch (acSet)
{
case AudioChannelSet::Stereo:
case AudioChannelSet::Quad:
m_coefs.v[int(AudioChannel::FrontLeft)][0] = 1.0;
m_coefs.v[int(AudioChannel::FrontRight)][1] = 1.0;
break;
case AudioChannelSet::Surround51:
case AudioChannelSet::Surround71:
m_coefs.v[int(AudioChannel::FrontLeft)][0] = 1.0;
m_coefs.v[int(AudioChannel::FrontRight)][1] = 1.0;
break;
default: break;
}
}
int16_t* AudioMatrixStereo::mixStereoSampleData(const AudioVoiceEngineMixInfo& info,
const int16_t* dataIn, int16_t* dataOut, size_t frames)
{
const ChannelMap& chmap = info.m_channelMap;
for (size_t f=0 ; f<frames ; ++f, dataIn += 2)
{
if (m_slewFrames && m_curSlewFrame < m_slewFrames)
{
double t = m_curSlewFrame / double(m_slewFrames);
double omt = 1.0 - t;
for (unsigned c=0 ; c<chmap.m_channelCount ; ++c)
{
AudioChannel ch = chmap.m_channels[c];
if (ch != AudioChannel::Unknown)
{
*dataOut = Clamp16(*dataOut +
*dataIn * (m_coefs.v[int(ch)][0] * t + m_oldCoefs.v[int(ch)][0] * omt) +
*dataIn * (m_coefs.v[int(ch)][1] * t + m_oldCoefs.v[int(ch)][1] * omt));
++dataOut;
}
}
++m_curSlewFrame;
}
else
{
for (unsigned c=0 ; c<chmap.m_channelCount ; ++c)
{
AudioChannel ch = chmap.m_channels[c];
if (ch != AudioChannel::Unknown)
{
*dataOut = Clamp16(*dataOut +
dataIn[0] * m_coefs.v[int(ch)][0] +
dataIn[1] * m_coefs.v[int(ch)][1]);
++dataOut;
}
}
}
}
return dataOut;
}
int32_t* AudioMatrixStereo::mixStereoSampleData(const AudioVoiceEngineMixInfo& info,
const int32_t* dataIn, int32_t* dataOut, size_t frames)
{
const ChannelMap& chmap = info.m_channelMap;
for (size_t f=0 ; f<frames ; ++f, dataIn += 2)
{
if (m_slewFrames && m_curSlewFrame < m_slewFrames)
{
double t = m_curSlewFrame / double(m_slewFrames);
double omt = 1.0 - t;
for (unsigned c=0 ; c<chmap.m_channelCount ; ++c)
{
AudioChannel ch = chmap.m_channels[c];
if (ch != AudioChannel::Unknown)
{
*dataOut = Clamp32(*dataOut +
*dataIn * (m_coefs.v[int(ch)][0] * t + m_oldCoefs.v[int(ch)][0] * omt) +
*dataIn * (m_coefs.v[int(ch)][1] * t + m_oldCoefs.v[int(ch)][1] * omt));
++dataOut;
}
}
++m_curSlewFrame;
}
else
{
for (unsigned c=0 ; c<chmap.m_channelCount ; ++c)
{
AudioChannel ch = chmap.m_channels[c];
if (ch != AudioChannel::Unknown)
{
*dataOut = Clamp32(*dataOut +
dataIn[0] * m_coefs.v[int(ch)][0] +
dataIn[1] * m_coefs.v[int(ch)][1]);
++dataOut;
}
}
}
}
return dataOut;
}
float* AudioMatrixStereo::mixStereoSampleData(const AudioVoiceEngineMixInfo& info,
const float* dataIn, float* dataOut, size_t frames)
{
const ChannelMap& chmap = info.m_channelMap;
for (size_t f=0 ; f<frames ; ++f, dataIn += 2)
{
if (m_slewFrames && m_curSlewFrame < m_slewFrames)
{
double t = m_curSlewFrame / double(m_slewFrames);
double omt = 1.0 - t;
for (unsigned c=0 ; c<chmap.m_channelCount ; ++c)
{
AudioChannel ch = chmap.m_channels[c];
if (ch != AudioChannel::Unknown)
{
*dataOut = ClampFlt(*dataOut +
*dataIn * (m_coefs.v[int(ch)][0] * t + m_oldCoefs.v[int(ch)][0] * omt) +
*dataIn * (m_coefs.v[int(ch)][1] * t + m_oldCoefs.v[int(ch)][1] * omt));
++dataOut;
}
}
++m_curSlewFrame;
}
else
{
for (unsigned c=0 ; c<chmap.m_channelCount ; ++c)
{
AudioChannel ch = chmap.m_channels[c];
if (ch != AudioChannel::Unknown)
{
*dataOut = ClampFlt(*dataOut +
dataIn[0] * m_coefs.v[int(ch)][0] +
dataIn[1] * m_coefs.v[int(ch)][1]);
++dataOut;
}
}
}
}
return dataOut;
}
}