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/* -*- Mode: C++; tab-width: 2; indent-tabs-mode: nil; c-basic-offset: 2 -*- */
/* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
#if !defined(AudioConverter_h)
#define AudioConverter_h
#include "MediaInfo.h"
// Forward declaration
typedef struct SpeexResamplerState_ SpeexResamplerState;
namespace mozilla {
template <AudioConfig::SampleFormat T> struct AudioDataBufferTypeChooser;
template <> struct AudioDataBufferTypeChooser<AudioConfig::FORMAT_U8>
{ typedef uint8_t Type; };
template <> struct AudioDataBufferTypeChooser<AudioConfig::FORMAT_S16>
{ typedef int16_t Type; };
template <> struct AudioDataBufferTypeChooser<AudioConfig::FORMAT_S24LSB>
{ typedef int32_t Type; };
template <> struct AudioDataBufferTypeChooser<AudioConfig::FORMAT_S24>
{ typedef int32_t Type; };
template <> struct AudioDataBufferTypeChooser<AudioConfig::FORMAT_S32>
{ typedef int32_t Type; };
template <> struct AudioDataBufferTypeChooser<AudioConfig::FORMAT_FLT>
{ typedef float Type; };
// 'Value' is the type used externally to deal with stored value.
// AudioDataBuffer can perform conversion between different SampleFormat content.
template <AudioConfig::SampleFormat Format, typename Value = typename AudioDataBufferTypeChooser<Format>::Type>
class AudioDataBuffer
{
public:
AudioDataBuffer() {}
AudioDataBuffer(Value* aBuffer, size_t aLength)
: mBuffer(aBuffer, aLength)
{}
explicit AudioDataBuffer(const AudioDataBuffer& aOther)
: mBuffer(aOther.mBuffer)
{}
AudioDataBuffer(AudioDataBuffer&& aOther)
: mBuffer(Move(aOther.mBuffer))
{}
template <AudioConfig::SampleFormat OtherFormat, typename OtherValue>
explicit AudioDataBuffer(const AudioDataBuffer<OtherFormat, OtherValue>& other)
{
// TODO: Convert from different type, may use asm routines.
MOZ_CRASH("Conversion not implemented yet");
}
// A u8, s16 and float aligned buffer can only be treated as
// FORMAT_U8, FORMAT_S16 and FORMAT_FLT respectively.
// So allow them as copy and move constructors.
explicit AudioDataBuffer(const AlignedByteBuffer& aBuffer)
: mBuffer(aBuffer)
{
static_assert(Format == AudioConfig::FORMAT_U8,
"Conversion not implemented yet");
}
explicit AudioDataBuffer(const AlignedShortBuffer& aBuffer)
: mBuffer(aBuffer)
{
static_assert(Format == AudioConfig::FORMAT_S16,
"Conversion not implemented yet");
}
explicit AudioDataBuffer(const AlignedFloatBuffer& aBuffer)
: mBuffer(aBuffer)
{
static_assert(Format == AudioConfig::FORMAT_FLT,
"Conversion not implemented yet");
}
explicit AudioDataBuffer(AlignedByteBuffer&& aBuffer)
: mBuffer(Move(aBuffer))
{
static_assert(Format == AudioConfig::FORMAT_U8,
"Conversion not implemented yet");
}
explicit AudioDataBuffer(AlignedShortBuffer&& aBuffer)
: mBuffer(Move(aBuffer))
{
static_assert(Format == AudioConfig::FORMAT_S16,
"Conversion not implemented yet");
}
explicit AudioDataBuffer(AlignedFloatBuffer&& aBuffer)
: mBuffer(Move(aBuffer))
{
static_assert(Format == AudioConfig::FORMAT_FLT,
"Conversion not implemented yet");
}
AudioDataBuffer& operator=(AudioDataBuffer&& aOther)
{
mBuffer = Move(aOther.mBuffer);
return *this;
}
AudioDataBuffer& operator=(const AudioDataBuffer& aOther)
{
mBuffer = aOther.mBuffer;
return *this;
}
Value* Data() const { return mBuffer.Data(); }
size_t Length() const { return mBuffer.Length(); }
size_t Size() const { return mBuffer.Size(); }
AlignedBuffer<Value> Forget()
{
// Correct type -> Just give values as-is.
return Move(mBuffer);
}
private:
AlignedBuffer<Value> mBuffer;
};
typedef AudioDataBuffer<AudioConfig::FORMAT_DEFAULT> AudioSampleBuffer;
class AudioConverter {
public:
AudioConverter(const AudioConfig& aIn, const AudioConfig& aOut);
~AudioConverter();
// Convert the AudioDataBuffer.
// Conversion will be done in place if possible. Otherwise a new buffer will
// be returned.
// Providing an empty buffer and resampling is expected, the resampler
// will be drained.
template <AudioConfig::SampleFormat Format, typename Value>
AudioDataBuffer<Format, Value> Process(AudioDataBuffer<Format, Value>&& aBuffer)
{
MOZ_DIAGNOSTIC_ASSERT(mIn.Format() == mOut.Format() && mIn.Format() == Format);
AudioDataBuffer<Format, Value> buffer = Move(aBuffer);
if (CanWorkInPlace()) {
size_t frames = SamplesInToFrames(buffer.Length());
frames = ProcessInternal(buffer.Data(), buffer.Data(), frames);
if (frames && mIn.Rate() != mOut.Rate()) {
frames = ResampleAudio(buffer.Data(), buffer.Data(), frames);
}
AlignedBuffer<Value> temp = buffer.Forget();
temp.SetLength(FramesOutToSamples(frames));
return AudioDataBuffer<Format, Value>(Move(temp));;
}
return Process(buffer);
}
template <AudioConfig::SampleFormat Format, typename Value>
AudioDataBuffer<Format, Value> Process(const AudioDataBuffer<Format, Value>& aBuffer)
{
MOZ_DIAGNOSTIC_ASSERT(mIn.Format() == mOut.Format() && mIn.Format() == Format);
// Perform the downmixing / reordering in temporary buffer.
size_t frames = SamplesInToFrames(aBuffer.Length());
AlignedBuffer<Value> temp1;
if (!temp1.SetLength(FramesOutToSamples(frames))) {
return AudioDataBuffer<Format, Value>(Move(temp1));
}
frames = ProcessInternal(temp1.Data(), aBuffer.Data(), frames);
if (mIn.Rate() == mOut.Rate()) {
MOZ_ALWAYS_TRUE(temp1.SetLength(FramesOutToSamples(frames)));
return AudioDataBuffer<Format, Value>(Move(temp1));
}
// At this point, temp1 contains the buffer reordered and downmixed.
// If we are downsampling we can re-use it.
AlignedBuffer<Value>* outputBuffer = &temp1;
AlignedBuffer<Value> temp2;
if (!frames || mOut.Rate() > mIn.Rate()) {
// We are upsampling or about to drain, we can't work in place.
// Allocate another temporary buffer where the upsampling will occur.
if (!temp2.SetLength(FramesOutToSamples(ResampleRecipientFrames(frames)))) {
return AudioDataBuffer<Format, Value>(Move(temp2));
}
outputBuffer = &temp2;
}
if (!frames) {
frames = DrainResampler(outputBuffer->Data());
} else {
frames = ResampleAudio(outputBuffer->Data(), temp1.Data(), frames);
}
MOZ_ALWAYS_TRUE(outputBuffer->SetLength(FramesOutToSamples(frames)));
return AudioDataBuffer<Format, Value>(Move(*outputBuffer));
}
// Attempt to convert the AudioDataBuffer in place.
// Will return 0 if the conversion wasn't possible.
template <typename Value>
size_t Process(Value* aBuffer, size_t aFrames)
{
MOZ_DIAGNOSTIC_ASSERT(mIn.Format() == mOut.Format());
if (!CanWorkInPlace()) {
return 0;
}
size_t frames = ProcessInternal(aBuffer, aBuffer, aFrames);
if (frames && mIn.Rate() != mOut.Rate()) {
frames = ResampleAudio(aBuffer, aBuffer, aFrames);
}
return frames;
}
bool CanWorkInPlace() const;
bool CanReorderAudio() const
{
return mIn.Layout().MappingTable(mOut.Layout());
}
const AudioConfig& InputConfig() const { return mIn; }
const AudioConfig& OutputConfig() const { return mOut; }
private:
const AudioConfig mIn;
const AudioConfig mOut;
uint8_t mChannelOrderMap[MAX_AUDIO_CHANNELS];
/**
* ProcessInternal
* Parameters:
* aOut : destination buffer where converted samples will be copied
* aIn : source buffer
* aSamples: number of frames in source buffer
*
* Return Value: number of frames converted or 0 if error
*/
size_t ProcessInternal(void* aOut, const void* aIn, size_t aFrames);
void ReOrderInterleavedChannels(void* aOut, const void* aIn, size_t aFrames) const;
size_t DownmixAudio(void* aOut, const void* aIn, size_t aFrames) const;
size_t UpmixAudio(void* aOut, const void* aIn, size_t aFrames) const;
size_t FramesOutToSamples(size_t aFrames) const;
size_t SamplesInToFrames(size_t aSamples) const;
size_t FramesOutToBytes(size_t aFrames) const;
// Resampler context.
SpeexResamplerState* mResampler;
size_t ResampleAudio(void* aOut, const void* aIn, size_t aFrames);
size_t ResampleRecipientFrames(size_t aFrames) const;
void RecreateResampler();
size_t DrainResampler(void* aOut);
};
} // namespace mozilla
#endif /* AudioConverter_h */
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