SilentPatch/SilentPatchSA/FLACDecoderSA.cpp

250 lines
7.9 KiB
C++

#include "StdAfxSA.h"
#include "FLACDecoderSA.h"
#include <algorithm>
#include <iterator>
#ifdef _DEBUG
#pragma comment(lib, "libFLAC_static_d.lib")
#else
#pragma comment(lib, "libFLAC_static.lib")
#endif
FLAC__StreamDecoderReadStatus CAEFLACDecoder::read_cb(const FLAC__StreamDecoder* decoder, FLAC__byte buffer[], size_t* bytes, void* client_data)
{
UNREFERENCED_PARAMETER(decoder);
CAEFLACDecoder* pClientData = static_cast<CAEFLACDecoder*>(client_data);
DWORD size = *bytes;
BOOL result = ReadFile(pClientData->GetStream()->GetFile(), buffer, size, &size, nullptr);
*bytes = size;
if ( result == FALSE )
return FLAC__STREAM_DECODER_READ_STATUS_ABORT;
if ( size == 0 )
{
pClientData->m_eof = true;
return FLAC__STREAM_DECODER_READ_STATUS_END_OF_STREAM;
}
pClientData->m_eof = false;
return FLAC__STREAM_DECODER_READ_STATUS_CONTINUE;
}
FLAC__StreamDecoderWriteStatus CAEFLACDecoder::write_cb(const FLAC__StreamDecoder *decoder, const FLAC__Frame *frame, const FLAC__int32 *const buffer[], void *client_data)
{
UNREFERENCED_PARAMETER(decoder);
CAEFLACDecoder* pClientData = static_cast<CAEFLACDecoder*>(client_data);
size_t processedChannels;
// Obtain current sample
assert( frame->header.number_type == FLAC__FRAME_NUMBER_TYPE_SAMPLE_NUMBER );
pClientData->m_currentSample = frame->header.number.sample_number;
processedChannels = std::min<size_t>(2, frame->header.channels);
pClientData->m_curBlockSize = frame->header.blocksize;
pClientData->m_bufferCursor = 0;
if ( pClientData->m_curBlockSize > pClientData->m_maxBlockSize )
{
delete[] pClientData->m_buffer;
pClientData->m_buffer = new FLAC__int32[pClientData->m_curBlockSize * processedChannels];
pClientData->m_maxBlockSize = pClientData->m_curBlockSize;
}
std::copy_n( buffer[0], pClientData->m_curBlockSize, stdext::checked_array_iterator<FLAC__int32*>(pClientData->m_buffer, pClientData->m_curBlockSize) );
if ( processedChannels > 1 )
{
std::copy_n( buffer[1], pClientData->m_curBlockSize, stdext::checked_array_iterator<FLAC__int32*>(pClientData->m_buffer+pClientData->m_curBlockSize, pClientData->m_curBlockSize) );
}
return FLAC__STREAM_DECODER_WRITE_STATUS_CONTINUE;
}
void CAEFLACDecoder::meta_cb(const FLAC__StreamDecoder* decoder, const FLAC__StreamMetadata *metadata, void *client_data)
{
UNREFERENCED_PARAMETER(decoder);
if ( metadata->type == FLAC__METADATA_TYPE_STREAMINFO )
{
// Cache the header
CAEFLACDecoder* pClientData = static_cast<CAEFLACDecoder*>(client_data);
pClientData->m_streamMeta = FLAC__metadata_object_clone(metadata);
assert( pClientData->m_streamMeta != nullptr );
}
}
FLAC__StreamDecoderSeekStatus CAEFLACDecoder::seek_cb(const FLAC__StreamDecoder *decoder, FLAC__uint64 absolute_byte_offset, void *client_data)
{
UNREFERENCED_PARAMETER(decoder);
CAEFLACDecoder* pClientData = static_cast<CAEFLACDecoder*>(client_data);
LARGE_INTEGER li;
li.QuadPart = absolute_byte_offset;
return SetFilePointerEx(pClientData->GetStream()->GetFile(), li, nullptr, FILE_BEGIN) != 0 ? FLAC__STREAM_DECODER_SEEK_STATUS_OK : FLAC__STREAM_DECODER_SEEK_STATUS_ERROR;
}
FLAC__StreamDecoderTellStatus CAEFLACDecoder::tell_cb(const FLAC__StreamDecoder *decoder, FLAC__uint64 *absolute_byte_offset, void *client_data)
{
UNREFERENCED_PARAMETER(decoder);
CAEFLACDecoder* pClientData = static_cast<CAEFLACDecoder*>(client_data);
LARGE_INTEGER li;
li.QuadPart = 0;
BOOL result = SetFilePointerEx(pClientData->GetStream()->GetFile(), li, &li, FILE_CURRENT);
*absolute_byte_offset = li.QuadPart;
return result != 0 ? FLAC__STREAM_DECODER_TELL_STATUS_OK : FLAC__STREAM_DECODER_TELL_STATUS_ERROR;
}
FLAC__StreamDecoderLengthStatus CAEFLACDecoder::length_cb(const FLAC__StreamDecoder *decoder, FLAC__uint64 *stream_length, void *client_data)
{
UNREFERENCED_PARAMETER(decoder);
CAEFLACDecoder* pClientData = static_cast<CAEFLACDecoder*>(client_data);
LARGE_INTEGER li;
BOOL bResult = GetFileSizeEx(pClientData->GetStream()->GetFile(), &li);
*stream_length = li.QuadPart;
return bResult ? FLAC__STREAM_DECODER_LENGTH_STATUS_OK: FLAC__STREAM_DECODER_LENGTH_STATUS_ERROR;
}
FLAC__bool CAEFLACDecoder::eof_cb(const FLAC__StreamDecoder* decoder, void* client_data)
{
UNREFERENCED_PARAMETER(decoder);
CAEFLACDecoder* pClientData = static_cast<CAEFLACDecoder*>(client_data);
return pClientData->m_eof;
}
void CAEFLACDecoder::error_cb(const FLAC__StreamDecoder* decoder, FLAC__StreamDecoderErrorStatus status, void* client_data)
{
// Not implemented
UNREFERENCED_PARAMETER(decoder);
UNREFERENCED_PARAMETER(status);
UNREFERENCED_PARAMETER(client_data);
}
bool CAEFLACDecoder::Initialise()
{
m_FLACdecoder = FLAC__stream_decoder_new();
assert( m_FLACdecoder != nullptr );
if ( m_FLACdecoder == nullptr )
return false;
if ( FLAC__stream_decoder_init_stream(m_FLACdecoder, read_cb, seek_cb, tell_cb, length_cb, eof_cb, write_cb, meta_cb, error_cb, this) != FLAC__STREAM_DECODER_INIT_STATUS_OK )
return false;
if ( FLAC__stream_decoder_process_until_end_of_metadata(m_FLACdecoder) == false )
return false;
if ( m_streamMeta == nullptr )
return false;
m_eof = false;
return m_streamMeta->data.stream_info.sample_rate <= 48000 && (m_streamMeta->data.stream_info.bits_per_sample == 8 || m_streamMeta->data.stream_info.bits_per_sample == 16 || m_streamMeta->data.stream_info.bits_per_sample == 24);
}
uint32_t CAEFLACDecoder::FillBuffer(void* pBuf, uint32_t nLen)
{
uint32_t samplesToDecode = nLen / (2 * sizeof(int16_t));
uint32_t bytesDecoded = 0;
int16_t* outputBuffer = static_cast<int16_t*>(pBuf);
FLAC__int32* inputBuffer[] = { m_buffer+m_bufferCursor, m_buffer+m_bufferCursor+m_curBlockSize };
const uint32_t sampleWidth = m_streamMeta->data.stream_info.bits_per_sample;
const bool stereo = m_streamMeta->data.stream_info.channels > 1;
while ( bytesDecoded < nLen )
{
if ( m_bufferCursor >= m_curBlockSize )
{
// New FLAC frame needed
if ( FLAC__stream_decoder_get_state(m_FLACdecoder) == FLAC__STREAM_DECODER_END_OF_STREAM )
break;
FLAC__stream_decoder_process_single(m_FLACdecoder);
inputBuffer[0] = m_buffer;
inputBuffer[1] = m_buffer+m_curBlockSize;
}
size_t samplesThisIteration = std::min( m_curBlockSize-m_bufferCursor, samplesToDecode );
if ( sampleWidth == 8 )
{
if ( stereo )
{
for ( size_t i = 0; i < samplesThisIteration; ++i )
{
outputBuffer[0] = int16_t(*inputBuffer[0]++ << 8);
outputBuffer[1] = int16_t(*inputBuffer[1]++ << 8);
outputBuffer += 2;
}
}
else
{
for ( size_t i = 0; i < samplesThisIteration; ++i )
{
outputBuffer[0] = outputBuffer[1] = int16_t(*inputBuffer[0]++ << 8);
outputBuffer += 2;
}
}
}
else if ( sampleWidth == 24 )
{
// 24-bit
if ( stereo )
{
for ( size_t i = 0; i < samplesThisIteration; ++i )
{
outputBuffer[0] = int16_t(*inputBuffer[0]++ >> 8);
outputBuffer[1] = int16_t(*inputBuffer[1]++ >> 8);
outputBuffer += 2;
}
}
else
{
for ( size_t i = 0; i < samplesThisIteration; ++i )
{
outputBuffer[0] = outputBuffer[1] = int16_t(*inputBuffer[0]++ >> 8);
outputBuffer += 2;
}
}
}
else
{
if ( stereo )
{
for ( size_t i = 0; i < samplesThisIteration; ++i )
{
outputBuffer[0] = int16_t(*inputBuffer[0]++);
outputBuffer[1] = int16_t(*inputBuffer[1]++);
outputBuffer += 2;
}
}
else
{
for ( size_t i = 0; i < samplesThisIteration; ++i )
{
outputBuffer[0] = outputBuffer[1] = int16_t(*inputBuffer[0]++);
outputBuffer += 2;
}
}
}
m_currentSample += samplesThisIteration;
m_bufferCursor += samplesThisIteration;
samplesToDecode -= samplesThisIteration;
bytesDecoded += samplesThisIteration * 2 * sizeof(int16_t);
}
return bytesDecoded;
}
CAEFLACDecoder::~CAEFLACDecoder()
{
if ( m_FLACdecoder != nullptr )
{
FLAC__stream_decoder_finish(m_FLACdecoder);
FLAC__stream_decoder_delete(m_FLACdecoder);
if ( m_streamMeta != nullptr )
FLAC__metadata_object_delete(m_streamMeta);
}
delete[] m_buffer;
}