sm64pc/tools/audiofile-0.3.6/libaudiofile/modules/SimpleModule.h

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2020-05-05 12:15:53 +00:00
/*
Audio File Library
Copyright (C) 2010, Michael Pruett <michael@68k.org>
This library is free software; you can redistribute it and/or
modify it under the terms of the GNU Lesser General Public
License as published by the Free Software Foundation; either
version 2.1 of the License, or (at your option) any later version.
This library is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
Lesser General Public License for more details.
You should have received a copy of the GNU Lesser General Public
License along with this library; if not, write to the
Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor,
Boston, MA 02110-1301 USA
*/
#ifndef SIMPLE_MODULE_H
#define SIMPLE_MODULE_H
#include "config.h"
#include "Compiler.h"
#include "Module.h"
#include "byteorder.h"
#include <algorithm>
#include <cassert>
#include <climits>
#include <functional>
class SimpleModule : public Module
{
public:
virtual void runPull() OVERRIDE;
virtual void runPush() OVERRIDE;
virtual void run(Chunk &inChunk, Chunk &outChunk) = 0;
};
struct SwapModule : public SimpleModule
{
public:
virtual const char *name() const OVERRIDE { return "swap"; }
virtual void describe() OVERRIDE
{
m_outChunk->f.byteOrder = m_inChunk->f.byteOrder == AF_BYTEORDER_BIGENDIAN ?
AF_BYTEORDER_LITTLEENDIAN : AF_BYTEORDER_BIGENDIAN;
}
virtual void run(Chunk &inChunk, Chunk &outChunk) OVERRIDE
{
switch (m_inChunk->f.bytesPerSample(false))
{
case 2:
run<2, int16_t>(inChunk, outChunk); break;
case 3:
run<3, char>(inChunk, outChunk); break;
case 4:
run<4, int32_t>(inChunk, outChunk); break;
case 8:
run<8, int64_t>(inChunk, outChunk); break;
default:
assert(false); break;
}
}
private:
template <int N, typename T>
void run(Chunk &inChunk, Chunk &outChunk)
{
int sampleCount = inChunk.f.channelCount * inChunk.frameCount;
runSwap<N, T>(reinterpret_cast<const T *>(inChunk.buffer),
reinterpret_cast<T *>(outChunk.buffer),
sampleCount);
}
template <int N, typename T>
void runSwap(const T *input, T *output, int sampleCount)
{
for (int i=0; i<sampleCount; i++)
output[i] = byteswap(input[i]);
}
};
template <>
inline void SwapModule::runSwap<3, char>(const char *input, char *output, int count)
{
for (int i=0; i<count; i++)
{
output[3*i] = input[3*i+2];
output[3*i+1] = input[3*i+1];
output[3*i+2] = input[3*i];
}
}
template <typename UnaryFunction>
void transform(const void *srcData, void *dstData, size_t count)
{
typedef typename UnaryFunction::argument_type InputType;
typedef typename UnaryFunction::result_type OutputType;
const InputType *src = reinterpret_cast<const InputType *>(srcData);
OutputType *dst = reinterpret_cast<OutputType *>(dstData);
std::transform(src, src + count, dst, UnaryFunction());
}
template <FormatCode>
struct IntTypes;
template <>
struct IntTypes<kInt8> { typedef int8_t SignedType; typedef uint8_t UnsignedType; };
template <>
struct IntTypes<kInt16> { typedef int16_t SignedType; typedef uint16_t UnsignedType; };
template <>
struct IntTypes<kInt24> { typedef int32_t SignedType; typedef uint32_t UnsignedType; };
template <>
struct IntTypes<kInt32> { typedef int32_t SignedType; typedef uint32_t UnsignedType; };
template <FormatCode Format>
struct signConverter
{
typedef typename IntTypes<Format>::SignedType SignedType;
typedef typename IntTypes<Format>::UnsignedType UnsignedType;
static const int kScaleBits = (Format + 1) * CHAR_BIT - 1;
static const int kMinSignedValue = 0-(1U<<kScaleBits);
struct signedToUnsigned : public std::unary_function<SignedType, UnsignedType>
{
UnsignedType operator()(SignedType x) { return x - kMinSignedValue; }
};
struct unsignedToSigned : public std::unary_function<SignedType, UnsignedType>
{
SignedType operator()(UnsignedType x) { return x + kMinSignedValue; }
};
};
class ConvertSign : public SimpleModule
{
public:
ConvertSign(FormatCode format, bool fromSigned) :
m_format(format),
m_fromSigned(fromSigned)
{
}
virtual const char *name() const OVERRIDE { return "sign"; }
virtual void describe() OVERRIDE
{
const int scaleBits = m_inChunk->f.bytesPerSample(false) * CHAR_BIT;
m_outChunk->f.sampleFormat =
m_fromSigned ? AF_SAMPFMT_UNSIGNED : AF_SAMPFMT_TWOSCOMP;
double shift = -(1 << (scaleBits - 1));
if (m_fromSigned)
shift = -shift;
m_outChunk->f.pcm.intercept += shift;
m_outChunk->f.pcm.minClip += shift;
m_outChunk->f.pcm.maxClip += shift;
}
virtual void run(Chunk &input, Chunk &output) OVERRIDE
{
size_t count = input.frameCount * m_inChunk->f.channelCount;
if (m_fromSigned)
convertSignedToUnsigned(input.buffer, output.buffer, count);
else
convertUnsignedToSigned(input.buffer, output.buffer, count);
}
private:
FormatCode m_format;
bool m_fromSigned;
template <FormatCode Format>
static void convertSignedToUnsigned(const void *src, void *dst, size_t count)
{
transform<typename signConverter<Format>::signedToUnsigned>(src, dst, count);
}
void convertSignedToUnsigned(const void *src, void *dst, size_t count)
{
switch (m_format)
{
case kInt8:
convertSignedToUnsigned<kInt8>(src, dst, count);
break;
case kInt16:
convertSignedToUnsigned<kInt16>(src, dst, count);
break;
case kInt24:
convertSignedToUnsigned<kInt24>(src, dst, count);
break;
case kInt32:
convertSignedToUnsigned<kInt32>(src, dst, count);
break;
default:
assert(false);
}
}
template <FormatCode Format>
static void convertUnsignedToSigned(const void *src, void *dst, size_t count)
{
transform<typename signConverter<Format>::unsignedToSigned>(src, dst, count);
}
void convertUnsignedToSigned(const void *src, void *dst, size_t count)
{
switch (m_format)
{
case kInt8:
convertUnsignedToSigned<kInt8>(src, dst, count);
break;
case kInt16:
convertUnsignedToSigned<kInt16>(src, dst, count);
break;
case kInt24:
convertUnsignedToSigned<kInt24>(src, dst, count);
break;
case kInt32:
convertUnsignedToSigned<kInt32>(src, dst, count);
break;
default:
assert(false);
}
}
};
struct Expand3To4Module : public SimpleModule
{
public:
Expand3To4Module(bool isSigned) : m_isSigned(isSigned)
{
}
virtual const char *name() const OVERRIDE { return "expand3to4"; }
virtual void describe() OVERRIDE
{
m_outChunk->f.packed = false;
}
virtual void run(Chunk &inChunk, Chunk &outChunk) OVERRIDE
{
int count = inChunk.f.channelCount * inChunk.frameCount;
if (m_isSigned)
run<int32_t>(reinterpret_cast<const uint8_t *>(inChunk.buffer),
reinterpret_cast<int32_t *>(outChunk.buffer),
count);
else
run<uint32_t>(reinterpret_cast<const uint8_t *>(inChunk.buffer),
reinterpret_cast<uint32_t *>(outChunk.buffer),
count);
}
private:
bool m_isSigned;
template <typename T>
void run(const uint8_t *input, T *output, int sampleCount)
{
for (int i=0; i<sampleCount; i++)
{
T t =
#ifdef WORDS_BIGENDIAN
(input[3*i] << 24) |
(input[3*i+1] << 16) |
input[3*i+2] << 8;
#else
(input[3*i+2] << 24) |
(input[3*i+1] << 16) |
input[3*i] << 8;
#endif
output[i] = t >> 8;
}
}
};
struct Compress4To3Module : public SimpleModule
{
public:
Compress4To3Module(bool isSigned) : m_isSigned(isSigned)
{
}
virtual const char *name() const OVERRIDE { return "compress4to3"; }
virtual void describe() OVERRIDE
{
m_outChunk->f.packed = true;
}
virtual void run(Chunk &inChunk, Chunk &outChunk) OVERRIDE
{
int count = inChunk.f.channelCount * inChunk.frameCount;
if (m_isSigned)
run<int32_t>(inChunk.buffer, outChunk.buffer, count);
else
run<uint32_t>(inChunk.buffer, outChunk.buffer, count);
}
private:
bool m_isSigned;
template <typename T>
void run(const void *input, void *output, int count)
{
const T *in = reinterpret_cast<const T *>(input);
uint8_t *out = reinterpret_cast<uint8_t *>(output);
for (int i=0; i<count; i++)
{
uint8_t c0, c1, c2;
extract3(in[i], c0, c1, c2);
out[3*i] = c0;
out[3*i+1] = c1;
out[3*i+2] = c2;
}
}
template <typename T>
void extract3(T in, uint8_t &c0, uint8_t &c1, uint8_t &c2)
{
#ifdef WORDS_BIGENDIAN
c0 = (in >> 16) & 0xff;
c1 = (in >> 8) & 0xff;
c2 = in & 0xff;
#else
c2 = (in >> 16) & 0xff;
c1 = (in >> 8) & 0xff;
c0 = in & 0xff;
#endif
}
};
template <typename Arg, typename Result>
struct intToFloat : public std::unary_function<Arg, Result>
{
Result operator()(Arg x) const { return x; }
};
struct ConvertIntToFloat : public SimpleModule
{
ConvertIntToFloat(FormatCode inFormat, FormatCode outFormat) :
m_inFormat(inFormat), m_outFormat(outFormat)
{
}
virtual const char *name() const OVERRIDE { return "intToFloat"; }
virtual void describe() OVERRIDE
{
m_outChunk->f.sampleFormat = m_outFormat == kDouble ?
AF_SAMPFMT_DOUBLE : AF_SAMPFMT_FLOAT;
m_outChunk->f.sampleWidth = m_outFormat == kDouble ? 64 : 32;
}
virtual void run(Chunk &inChunk, Chunk &outChunk) OVERRIDE
{
const void *src = inChunk.buffer;
void *dst = outChunk.buffer;
int count = inChunk.frameCount * inChunk.f.channelCount;
if (m_outFormat == kFloat)
{
switch (m_inFormat)
{
case kInt8:
run<int8_t, float>(src, dst, count); break;
case kInt16:
run<int16_t, float>(src, dst, count); break;
case kInt24:
case kInt32:
run<int32_t, float>(src, dst, count); break;
default:
assert(false);
}
}
else if (m_outFormat == kDouble)
{
switch (m_inFormat)
{
case kInt8:
run<int8_t, double>(src, dst, count); break;
case kInt16:
run<int16_t, double>(src, dst, count); break;
case kInt24:
case kInt32:
run<int32_t, double>(src, dst, count); break;
default:
assert(false);
}
}
}
private:
FormatCode m_inFormat, m_outFormat;
template <typename Arg, typename Result>
static void run(const void *src, void *dst, int count)
{
transform<intToFloat<Arg, Result> >(src, dst, count);
}
};
template <typename Arg, typename Result, unsigned shift>
struct lshift : public std::unary_function<Arg, Result>
{
Result operator()(const Arg &x) const { return x << shift; }
};
template <typename Arg, typename Result, unsigned shift>
struct rshift : public std::unary_function<Arg, Result>
{
Result operator()(const Arg &x) const { return x >> shift; }
};
struct ConvertInt : public SimpleModule
{
ConvertInt(FormatCode inFormat, FormatCode outFormat) :
m_inFormat(inFormat),
m_outFormat(outFormat)
{
assert(isInteger(m_inFormat));
assert(isInteger(m_outFormat));
}
virtual const char *name() const OVERRIDE { return "convertInt"; }
virtual void describe() OVERRIDE
{
getDefaultPCMMapping(m_outChunk->f.sampleWidth,
m_outChunk->f.pcm.slope,
m_outChunk->f.pcm.intercept,
m_outChunk->f.pcm.minClip,
m_outChunk->f.pcm.maxClip);
}
virtual void run(Chunk &inChunk, Chunk &outChunk) OVERRIDE
{
const void *src = inChunk.buffer;
void *dst = outChunk.buffer;
size_t count = inChunk.frameCount * inChunk.f.channelCount;
#define MASK(N, M) (((N)<<3) | (M))
#define HANDLE(N, M) \
case MASK(N, M): convertInt<N, M>(src, dst, count); break;
switch (MASK(m_inFormat, m_outFormat))
{
HANDLE(kInt8, kInt16)
HANDLE(kInt8, kInt24)
HANDLE(kInt8, kInt32)
HANDLE(kInt16, kInt8)
HANDLE(kInt16, kInt24)
HANDLE(kInt16, kInt32)
HANDLE(kInt24, kInt8)
HANDLE(kInt24, kInt16)
HANDLE(kInt24, kInt32)
HANDLE(kInt32, kInt8)
HANDLE(kInt32, kInt16)
HANDLE(kInt32, kInt24)
}
#undef MASK
#undef HANDLE
}
private:
FormatCode m_inFormat, m_outFormat;
void getDefaultPCMMapping(int &bits, double &slope, double &intercept,
double &minClip, double &maxClip)
{
bits = (m_outFormat + 1) * CHAR_BIT;
slope = (1LL << (bits - 1));
intercept = 0;
minClip = -(1 << (bits - 1));
maxClip = (1LL << (bits - 1)) - 1;
}
static bool isInteger(FormatCode code)
{
return code >= kInt8 && code <= kInt32;
}
template <FormatCode Input, FormatCode Output, bool = (Input > Output)>
struct shift;
template <FormatCode Input, FormatCode Output>
struct shift<Input, Output, true> :
public rshift<typename IntTypes<Input>::SignedType,
typename IntTypes<Output>::SignedType,
(Input - Output) * CHAR_BIT>
{
};
template <FormatCode Input, FormatCode Output>
struct shift<Input, Output, false> :
public lshift<typename IntTypes<Input>::SignedType,
typename IntTypes<Output>::SignedType,
(Output - Input) * CHAR_BIT>
{
};
template <FormatCode Input, FormatCode Output>
static void convertInt(const void *src, void *dst, int count)
{
transform<shift<Input, Output> >(src, dst, count);
}
};
template <typename Arg, typename Result>
struct floatToFloat : public std::unary_function<Arg, Result>
{
Result operator()(Arg x) const { return x; }
};
struct ConvertFloat : public SimpleModule
{
ConvertFloat(FormatCode inFormat, FormatCode outFormat) :
m_inFormat(inFormat), m_outFormat(outFormat)
{
assert((m_inFormat == kFloat && m_outFormat == kDouble) ||
(m_inFormat == kDouble && m_outFormat == kFloat));
}
virtual const char *name() const OVERRIDE { return "convertFloat"; }
virtual void describe() OVERRIDE
{
switch (m_outFormat)
{
case kFloat:
m_outChunk->f.sampleFormat = AF_SAMPFMT_FLOAT;
m_outChunk->f.sampleWidth = 32;
break;
case kDouble:
m_outChunk->f.sampleFormat = AF_SAMPFMT_DOUBLE;
m_outChunk->f.sampleWidth = 64;
break;
default:
assert(false);
}
}
virtual void run(Chunk &inChunk, Chunk &outChunk) OVERRIDE
{
const void *src = inChunk.buffer;
void *dst = outChunk.buffer;
size_t count = inChunk.frameCount * inChunk.f.channelCount;
switch (m_outFormat)
{
case kFloat:
transform<floatToFloat<double, float> >(src, dst, count);
break;
case kDouble:
transform<floatToFloat<float, double> >(src, dst, count);
break;
default:
assert(false);
}
}
private:
FormatCode m_inFormat, m_outFormat;
};
struct Clip : public SimpleModule
{
Clip(FormatCode format, const PCMInfo &outputMapping) :
m_format(format),
m_outputMapping(outputMapping)
{
}
virtual const char *name() const OVERRIDE { return "clip"; }
virtual void describe() OVERRIDE
{
m_outChunk->f.pcm = m_outputMapping;
}
virtual void run(Chunk &inChunk, Chunk &outChunk) OVERRIDE
{
const void *src = inChunk.buffer;
void *dst = outChunk.buffer;
int count = inChunk.frameCount * inChunk.f.channelCount;
switch (m_format)
{
case kInt8:
run<int8_t>(src, dst, count); break;
case kInt16:
run<int16_t>(src, dst, count); break;
case kInt24:
case kInt32:
run<int32_t>(src, dst, count); break;
case kFloat:
run<float>(src, dst, count); break;
case kDouble:
run<double>(src, dst, count); break;
default:
assert(false);
}
}
private:
FormatCode m_format;
PCMInfo m_outputMapping;
template <typename T>
void run(const void *srcData, void *dstData, int count)
{
const T minValue = m_outputMapping.minClip;
const T maxValue = m_outputMapping.maxClip;
const T *src = reinterpret_cast<const T *>(srcData);
T *dst = reinterpret_cast<T *>(dstData);
for (int i=0; i<count; i++)
{
T t = src[i];
t = std::min(t, maxValue);
t = std::max(t, minValue);
dst[i] = t;
}
}
};
struct ConvertFloatToIntClip : public SimpleModule
{
ConvertFloatToIntClip(FormatCode inputFormat, FormatCode outputFormat,
const PCMInfo &inputMapping, const PCMInfo &outputMapping) :
m_inputFormat(inputFormat),
m_outputFormat(outputFormat),
m_inputMapping(inputMapping),
m_outputMapping(outputMapping)
{
assert(m_inputFormat == kFloat || m_inputFormat == kDouble);
assert(m_outputFormat == kInt8 ||
m_outputFormat == kInt16 ||
m_outputFormat == kInt24 ||
m_outputFormat == kInt32);
}
virtual const char *name() const OVERRIDE { return "convertPCMMapping"; }
virtual void describe() OVERRIDE
{
m_outChunk->f.sampleFormat = AF_SAMPFMT_TWOSCOMP;
m_outChunk->f.sampleWidth = (m_outputFormat + 1) * CHAR_BIT;
m_outChunk->f.pcm = m_outputMapping;
}
virtual void run(Chunk &inChunk, Chunk &outChunk) OVERRIDE
{
const void *src = inChunk.buffer;
void *dst = outChunk.buffer;
int count = inChunk.frameCount * inChunk.f.channelCount;
if (m_inputFormat == kFloat)
{
switch (m_outputFormat)
{
case kInt8:
run<float, int8_t>(src, dst, count); break;
case kInt16:
run<float, int16_t>(src, dst, count); break;
case kInt24:
case kInt32:
run<float, int32_t>(src, dst, count); break;
default:
assert(false);
}
}
else if (m_inputFormat == kDouble)
{
switch (m_outputFormat)
{
case kInt8:
run<double, int8_t>(src, dst, count); break;
case kInt16:
run<double, int16_t>(src, dst, count); break;
case kInt24:
case kInt32:
run<double, int32_t>(src, dst, count); break;
default:
assert(false);
}
}
}
private:
FormatCode m_inputFormat, m_outputFormat;
PCMInfo m_inputMapping, m_outputMapping;
template <typename Input, typename Output>
void run(const void *srcData, void *dstData, int count)
{
const Input *src = reinterpret_cast<const Input *>(srcData);
Output *dst = reinterpret_cast<Output *>(dstData);
double m = m_outputMapping.slope / m_inputMapping.slope;
double b = m_outputMapping.intercept - m * m_inputMapping.intercept;
double minValue = m_outputMapping.minClip;
double maxValue = m_outputMapping.maxClip;
for (int i=0; i<count; i++)
{
double t = m * src[i] + b;
t = std::min(t, maxValue);
t = std::max(t, minValue);
dst[i] = static_cast<Output>(t);
}
}
};
struct ApplyChannelMatrix : public SimpleModule
{
public:
ApplyChannelMatrix(FormatCode format, bool isReading,
int inChannels, int outChannels,
double minClip, double maxClip, const double *matrix);
virtual ~ApplyChannelMatrix();
virtual const char *name() const OVERRIDE;
virtual void describe() OVERRIDE;
virtual void run(Chunk &inChunk, Chunk &outChunk) OVERRIDE;
private:
FormatCode m_format;
int m_inChannels, m_outChannels;
double m_minClip, m_maxClip;
double *m_matrix;
void initDefaultMatrix();
template <typename T>
void run(const void *input, void *output, int frameCount);
};
struct Transform : public SimpleModule
{
public:
Transform(FormatCode format,
const PCMInfo &inputMapping,
const PCMInfo &outputMapping) :
m_format(format),
m_inputMapping(inputMapping),
m_outputMapping(outputMapping)
{
assert(m_format == kFloat || m_format == kDouble);
}
virtual const char *name() const OVERRIDE { return "transform"; }
virtual void describe() OVERRIDE
{
m_outChunk->f.pcm = m_outputMapping;
}
virtual void run(Chunk &inChunk, Chunk &outChunk) OVERRIDE
{
int count = inChunk.frameCount * inChunk.f.channelCount;
if (m_format == kFloat)
run<float>(inChunk.buffer, outChunk.buffer, count);
else if (m_format == kDouble)
run<double>(inChunk.buffer, outChunk.buffer, count);
else
assert(false);
}
private:
FormatCode m_format;
PCMInfo m_inputMapping, m_outputMapping;
template <typename T>
void run(const void *srcData, void *dstData, int count)
{
const T *src = reinterpret_cast<const T *>(srcData);
T *dst = reinterpret_cast<T *>(dstData);
double m = m_outputMapping.slope / m_inputMapping.slope;
double b = m_outputMapping.intercept - m * m_inputMapping.intercept;
for (int i=0; i<count; i++)
dst[i] = m * src[i] + b;
}
};
#endif // SIMPLE_MODULE_H