mirror of
https://github.com/nillerusr/source-engine.git
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382 lines
9.6 KiB
C++
382 lines
9.6 KiB
C++
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//========= Copyright Valve Corporation, All rights reserved. ============//
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#include <windows.h>
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#include <mmreg.h>
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#include "../toollib/toollib.h"
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#include "tier1/strtools.h"
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#include "resample.h"
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#define clamp(a,b,c) ( (a) > (c) ? (c) : ( (a) < (b) ? (b) : (a) ) )
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const int NUM_COEFFS = 7;
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static const float g_ResampleCoefficients[NUM_COEFFS] =
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{
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0.0457281f, 0.168088f, 0.332501f, 0.504486f, 0.663202f, 0.803781f, 0.933856f
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};
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// generates 1 output sample for 2 input samples
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inline float DecimateSamplePair(float input0, float input1, const float pCoefficients[7], float xState[2], float yState[7] )
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{
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float tmp_0 = xState[0];
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float tmp_1 = xState[1];
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xState[0] = input0;
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xState[1] = input1;
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input0 = (input0 - yState[0]) * pCoefficients[0] + tmp_0;
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input1 = (input1 - yState[1]) * pCoefficients[1] + tmp_1;
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tmp_0 = yState[0];
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tmp_1 = yState[1];
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yState[0] = input0;
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yState[1] = input1;
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input0 = (input0 - yState[2]) * pCoefficients[2] + tmp_0;
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input1 = (input1 - yState[3]) * pCoefficients[3] + tmp_1;
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tmp_0 = yState[2];
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tmp_1 = yState[3];
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yState[2] = input0;
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yState[3] = input1;
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input0 = (input0 - yState[4]) * pCoefficients[4] + tmp_0;
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input1 = (input1 - yState[5]) * pCoefficients[5] + tmp_1;
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tmp_0 = yState[4];
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yState[4] = input0;
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yState[5] = input1;
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input0 = (input0 - yState[6]) * pCoefficients[6] + tmp_0;
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yState[6] = input0;
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return (input0 + input1);
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}
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static void ExtractFloatSamples( float *pOut, const short *pInputBuffer, int sampleCount, int stride )
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{
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for ( int i = 0; i < sampleCount; i++ )
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{
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pOut[i] = pInputBuffer[0] * 1.0f / 32768.0f;
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pInputBuffer += stride;
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}
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}
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static void ExtractShortSamples( short *pOut, const float *pInputBuffer, float scale, int sampleCount, int stride )
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{
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for ( int i = 0; i < sampleCount; i++ )
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{
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int sampleOut = (int)(pInputBuffer[i] * scale);
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sampleOut = clamp( sampleOut, -32768, 32767 );
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pOut[0] = (short)(sampleOut);
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pOut += stride;
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}
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}
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struct decimatestate_t
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{
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float xState[2];
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float yState[7];
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};
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void DecimateSampleBlock( float *pInOut, int sampleCount )
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{
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decimatestate_t block;
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int outCount = sampleCount >> 1;
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int pos = 0;
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memset( &block, 0, sizeof(block) );
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do
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{
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float input0 = pInOut[pos*2+0];
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float input1 = pInOut[pos*2+1];
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pInOut[pos] = DecimateSamplePair( input0, input1, g_ResampleCoefficients, block.xState, block.yState );
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pos++;
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} while( pos < outCount );
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}
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void DecimateSampleRateBy2_16( const short *pInputBuffer, short *pOutputBuffer, int sampleCount, int channelCount )
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{
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float *pTmpBuf = new float[sampleCount];
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for ( int i = 0; i < channelCount; i++ )
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{
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ExtractFloatSamples( pTmpBuf, pInputBuffer+i, sampleCount, channelCount );
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DecimateSampleBlock( pTmpBuf, sampleCount );
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ExtractShortSamples( pOutputBuffer+i, pTmpBuf, 0.5f * 32768.0f, sampleCount>>1, channelCount );
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}
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delete [] pTmpBuf;
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}
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struct adpcmstate_t
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{
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const ADPCMWAVEFORMAT *pFormat;
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const ADPCMCOEFSET *pCoefficients;
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int blockSize;
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};
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static int error_sign_lut[] = { 0, 1, 2, 3, 4, 5, 6, 7, -8, -7, -6, -5, -4, -3, -2, -1 };
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static int error_coefficients_lut[] = { 230, 230, 230, 230, 307, 409, 512, 614, 768, 614, 512, 409, 307, 230, 230, 230 };
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void ParseADPCM( adpcmstate_t &out, const byte *pFormatChunk )
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{
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out.pFormat = (const ADPCMWAVEFORMAT *)pFormatChunk;
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if ( out.pFormat )
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{
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out.pCoefficients = out.pFormat->aCoef;
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// number of bytes for samples
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out.blockSize = ((out.pFormat->wSamplesPerBlock - 2) * out.pFormat->wfx.nChannels ) / 2;
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// size of channel header
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out.blockSize += 7 * out.pFormat->wfx.nChannels;
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}
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}
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void DecompressBlockMono( const adpcmstate_t &state, short *pOut, const char *pIn, int count )
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{
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int pred = *pIn++;
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int co1 = state.pCoefficients[pred].iCoef1;
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int co2 = state.pCoefficients[pred].iCoef2;
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// read initial delta
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int delta = *((short *)pIn);
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pIn += 2;
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// read initial samples for prediction
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int samp1 = *((short *)pIn);
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pIn += 2;
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int samp2 = *((short *)pIn);
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pIn += 2;
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// write out the initial samples (stored in reverse order)
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*pOut++ = (short)samp2;
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*pOut++ = (short)samp1;
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// subtract the 2 samples in the header
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count -= 2;
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// this is a toggle to read nibbles, first nibble is high
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int high = 1;
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int error, sample=0;
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// now process the block
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while ( count )
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{
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// read the error nibble from the input stream
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if ( high )
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{
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sample = (unsigned char) (*pIn++);
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// high nibble
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error = sample >> 4;
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// cache low nibble for next read
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sample = sample & 0xf;
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// Next read is from cache, not stream
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high = 0;
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}
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else
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{
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// stored in previous read (low nibble)
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error = sample;
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// next read is from stream
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high = 1;
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}
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// convert to signed with LUT
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int errorSign = error_sign_lut[error];
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// interpolate the new sample
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int predSample = (samp1 * co1) + (samp2 * co2);
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// coefficients are fixed point 8-bit, so shift back to 16-bit integer
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predSample >>= 8;
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// Add in current error estimate
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predSample += (errorSign * delta);
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// Correct error estimate
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delta = (delta * error_coefficients_lut[error]) >> 8;
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// Clamp error estimate
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if ( delta < 16 )
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delta = 16;
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// clamp
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if ( predSample > 32767L )
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predSample = 32767L;
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else if ( predSample < -32768L )
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predSample = -32768L;
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// output
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*pOut++ = (short)predSample;
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// move samples over
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samp2 = samp1;
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samp1 = predSample;
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count--;
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}
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}
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//-----------------------------------------------------------------------------
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// Purpose: Decode a single block of stereo ADPCM audio
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// Input : *pOut - 16-bit output buffer
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// *pIn - ADPCM encoded block data
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// count - number of sample pairs to decode
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//-----------------------------------------------------------------------------
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void DecompressBlockStereo( const adpcmstate_t &state, short *pOut, const char *pIn, int count )
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{
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int pred[2], co1[2], co2[2];
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int i;
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for ( i = 0; i < 2; i++ )
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{
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pred[i] = *pIn++;
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co1[i] = state.pCoefficients[pred[i]].iCoef1;
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co2[i] = state.pCoefficients[pred[i]].iCoef2;
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}
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int delta[2], samp1[2], samp2[2];
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for ( i = 0; i < 2; i++, pIn += 2 )
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{
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// read initial delta
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delta[i] = *((short *)pIn);
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}
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// read initial samples for prediction
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for ( i = 0; i < 2; i++, pIn += 2 )
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{
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samp1[i] = *((short *)pIn);
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}
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for ( i = 0; i < 2; i++, pIn += 2 )
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{
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samp2[i] = *((short *)pIn);
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}
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// write out the initial samples (stored in reverse order)
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*pOut++ = (short)samp2[0]; // left
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*pOut++ = (short)samp2[1]; // right
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*pOut++ = (short)samp1[0]; // left
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*pOut++ = (short)samp1[1]; // right
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// subtract the 2 samples in the header
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count -= 2;
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// this is a toggle to read nibbles, first nibble is high
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int high = 1;
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int error, sample=0;
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// now process the block
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while ( count )
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{
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for ( i = 0; i < 2; i++ )
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{
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// read the error nibble from the input stream
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if ( high )
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{
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sample = (unsigned char) (*pIn++);
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// high nibble
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error = sample >> 4;
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// cache low nibble for next read
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sample = sample & 0xf;
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// Next read is from cache, not stream
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high = 0;
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}
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else
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{
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// stored in previous read (low nibble)
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error = sample;
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// next read is from stream
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high = 1;
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}
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// convert to signed with LUT
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int errorSign = error_sign_lut[error];
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// interpolate the new sample
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int predSample = (samp1[i] * co1[i]) + (samp2[i] * co2[i]);
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// coefficients are fixed point 8-bit, so shift back to 16-bit integer
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predSample >>= 8;
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// Add in current error estimate
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predSample += (errorSign * delta[i]);
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// Correct error estimate
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delta[i] = (delta[i] * error_coefficients_lut[error]) >> 8;
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// Clamp error estimate
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if ( delta[i] < 16 )
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delta[i] = 16;
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// clamp
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if ( predSample > 32767L )
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predSample = 32767L;
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else if ( predSample < -32768L )
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predSample = -32768L;
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// output
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*pOut++ = (short)predSample;
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// move samples over
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samp2[i] = samp1[i];
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samp1[i] = predSample;
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}
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count--;
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}
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}
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int ADPCMSampleCountShortBlock( const adpcmstate_t &state, int shortBlockSize )
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{
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if ( shortBlockSize < 8 )
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return 0;
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int sampleCount = state.pFormat->wSamplesPerBlock;
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// short block?, fixup sample count (2 samples per byte, divided by number of channels per sample set)
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sampleCount -= ((state.blockSize - shortBlockSize) * 2) / state.pFormat->wfx.nChannels;
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return sampleCount;
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}
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int ADPCMSampleCount( const byte *pFormatChunk, const byte *pDataChunk, int dataSize )
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{
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adpcmstate_t state;
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ParseADPCM( state, pFormatChunk );
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int numBlocks = dataSize / state.blockSize;
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int mod = dataSize % state.blockSize;
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return numBlocks * state.pFormat->wSamplesPerBlock + ADPCMSampleCountShortBlock(state, mod);
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}
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void DecompressADPCMSamples( const byte *pFormatChunk, const byte *pDataChunk, int dataSize, short *pOutputBuffer )
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{
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adpcmstate_t state;
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ParseADPCM( state, pFormatChunk );
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while ( dataSize > 0 )
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{
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int block = dataSize;
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int sampleCount = state.pFormat->wSamplesPerBlock;
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if ( block > state.blockSize )
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{
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block = state.blockSize;
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}
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else
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{
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sampleCount = ADPCMSampleCountShortBlock( state, block );
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}
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if ( state.pFormat->wfx.nChannels == 1 )
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{
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DecompressBlockMono( state, pOutputBuffer, (const char *)pDataChunk, sampleCount );
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}
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else
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{
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DecompressBlockStereo( state, pOutputBuffer, (const char *)pDataChunk, sampleCount );
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}
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pOutputBuffer += sampleCount * state.pFormat->wfx.nChannels;
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dataSize -= block;
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pDataChunk += block;
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}
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}
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void Convert8To16( const byte *pInputBuffer, short *pOutputBuffer, int sampleCount, int channelCount )
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{
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for ( int i = 0; i < sampleCount*channelCount; i++ )
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{
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unsigned short signedSample = (byte)((int)((unsigned)pInputBuffer[i]) - 128);
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pOutputBuffer[i] = (short) (signedSample | (signedSample<<8));
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}
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}
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