mirror of
https://github.com/mpv-player/mpv
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4bbefcad28
git-svn-id: svn://svn.mplayerhq.hu/mplayer/trunk@4002 b3059339-0415-0410-9bf9-f77b7e298cf2
455 lines
10 KiB
C
455 lines
10 KiB
C
/*
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Unified ADPCM Decoder for MPlayer
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This file is in charge of decoding all of the various ADPCM data
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formats that various entities have created. Details about the data
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formats can be found here:
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http://www.pcisys.net/~melanson/codecs/
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(C) 2001 Mike Melanson
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*/
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#include "config.h"
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#include "bswap.h"
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#include "adpcm.h"
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#define BE_16(x) (be2me_16(*(unsigned short *)(x)))
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#define BE_32(x) (be2me_32(*(unsigned int *)(x)))
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#define LE_16(x) (le2me_16(*(unsigned short *)(x)))
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#define LE_32(x) (le2me_32(*(unsigned int *)(x)))
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// pertinent tables
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static int adpcm_step[89] =
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{
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7, 8, 9, 10, 11, 12, 13, 14, 16, 17,
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19, 21, 23, 25, 28, 31, 34, 37, 41, 45,
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50, 55, 60, 66, 73, 80, 88, 97, 107, 118,
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130, 143, 157, 173, 190, 209, 230, 253, 279, 307,
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337, 371, 408, 449, 494, 544, 598, 658, 724, 796,
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876, 963, 1060, 1166, 1282, 1411, 1552, 1707, 1878, 2066,
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2272, 2499, 2749, 3024, 3327, 3660, 4026, 4428, 4871, 5358,
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5894, 6484, 7132, 7845, 8630, 9493, 10442, 11487, 12635, 13899,
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15289, 16818, 18500, 20350, 22385, 24623, 27086, 29794, 32767
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};
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static int adpcm_index[16] =
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{
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-1, -1, -1, -1, 2, 4, 6, 8,
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-1, -1, -1, -1, 2, 4, 6, 8
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};
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static int ms_adapt_table[] =
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{
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230, 230, 230, 230, 307, 409, 512, 614,
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768, 614, 512, 409, 307, 230, 230, 230
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};
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static int ms_adapt_coeff1[] =
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{
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256, 512, 0, 192, 240, 460, 392
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};
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static int ms_adapt_coeff2[] =
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{
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0, -256, 0, 64, 0, -208, -232
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};
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// useful macros
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// clamp a number between 0 and 88
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#define CLAMP_0_TO_88(x) if (x < 0) x = 0; else if (x > 88) x = 88;
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// clamp a number within a signed 16-bit range
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#define CLAMP_S16(x) if (x < -32768) x = -32768; \
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else if (x > 32767) x = 32767;
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// clamp a number above 16
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#define CLAMP_ABOVE_16(x) if (x < 16) x = 16;
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// sign extend a 16-bit value
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#define SE_16BIT(x) if (x & 0x8000) x -= 0x10000;
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// sign extend a 4-bit value
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#define SE_4BIT(x) if (x & 0x8) x -= 0x10;
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void decode_nibbles(unsigned short *output,
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int output_size, int channels,
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int predictor_l, int index_l,
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int predictor_r, int index_r)
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{
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int step[2];
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int predictor[2];
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int index[2];
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int diff;
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int i;
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int sign;
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int delta;
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int channel_number = 0;
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step[0] = adpcm_step[index_l];
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step[1] = adpcm_step[index_r];
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predictor[0] = predictor_l;
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predictor[1] = predictor_r;
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index[0] = index_l;
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index[1] = index_r;
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for (i = 0; i < output_size; i++)
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{
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delta = output[i];
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index[channel_number] += adpcm_index[delta];
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CLAMP_0_TO_88(index[channel_number]);
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sign = delta & 8;
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delta = delta & 7;
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diff = step[channel_number] >> 3;
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if (delta & 4) diff += step[channel_number];
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if (delta & 2) diff += step[channel_number] >> 1;
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if (delta & 1) diff += step[channel_number] >> 2;
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if (sign)
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predictor[channel_number] -= diff;
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else
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predictor[channel_number] += diff;
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CLAMP_S16(predictor[channel_number]);
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output[i] = predictor[channel_number];
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step[channel_number] = adpcm_step[index[channel_number]];
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// toggle channel
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channel_number ^= channels - 1;
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}
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}
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int ima_adpcm_decode_block(unsigned short *output, unsigned char *input,
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int channels)
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{
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int initial_predictor_l = 0;
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int initial_predictor_r = 0;
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int initial_index_l = 0;
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int initial_index_r = 0;
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int i;
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initial_predictor_l = BE_16(&input[0]);
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initial_index_l = initial_predictor_l;
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// mask, sign-extend, and clamp the predictor portion
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initial_predictor_l &= 0xFF80;
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SE_16BIT(initial_predictor_l);
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CLAMP_S16(initial_predictor_l);
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// mask and clamp the index portion
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initial_index_l &= 0x7F;
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CLAMP_0_TO_88(initial_index_l);
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// handle stereo
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if (channels > 1)
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{
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initial_predictor_r = BE_16(&input[IMA_ADPCM_BLOCK_SIZE]);
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initial_index_r = initial_predictor_r;
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// mask, sign-extend, and clamp the predictor portion
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initial_predictor_r &= 0xFF80;
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SE_16BIT(initial_predictor_r);
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CLAMP_S16(initial_predictor_r);
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// mask and clamp the index portion
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initial_index_r &= 0x7F;
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CLAMP_0_TO_88(initial_index_r);
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}
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// break apart all of the nibbles in the block
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if (channels == 1)
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for (i = 0; i < IMA_ADPCM_SAMPLES_PER_BLOCK / 2; i++)
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{
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output[i * 2 + 0] = input[2 + i] & 0x0F;
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output[i * 2 + 1] = input[2 + i] >> 4;
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}
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else
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for (i = 0; i < IMA_ADPCM_SAMPLES_PER_BLOCK / 2 * 2; i++)
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{
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output[i * 4 + 0] = input[2 + i] & 0x0F;
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output[i * 4 + 1] = input[2 + IMA_ADPCM_BLOCK_SIZE + i] & 0x0F;
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output[i * 4 + 2] = input[2 + i] >> 4;
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output[i * 4 + 3] = input[2 + IMA_ADPCM_BLOCK_SIZE + i] >> 4;
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}
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decode_nibbles(output,
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IMA_ADPCM_SAMPLES_PER_BLOCK * channels, channels,
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initial_predictor_l, initial_index_l,
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initial_predictor_r, initial_index_r);
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return IMA_ADPCM_SAMPLES_PER_BLOCK * channels;
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}
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int ms_adpcm_decode_block(unsigned short *output, unsigned char *input,
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int channels, int block_size)
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{
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int current_channel = 0;
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int idelta[2];
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int sample1[2];
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int sample2[2];
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int coeff1[2];
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int coeff2[2];
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int stream_ptr = 0;
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int out_ptr = 0;
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int upper_nibble = 1;
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int nibble;
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int snibble; // signed nibble
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int predictor;
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// fetch the header information, in stereo if both channels are present
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coeff1[0] = ms_adapt_coeff1[input[stream_ptr]];
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coeff2[0] = ms_adapt_coeff2[input[stream_ptr]];
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stream_ptr++;
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if (channels == 2)
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{
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coeff1[1] = ms_adapt_coeff1[input[stream_ptr]];
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coeff2[1] = ms_adapt_coeff2[input[stream_ptr]];
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stream_ptr++;
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}
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idelta[0] = LE_16(&input[stream_ptr]);
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stream_ptr += 2;
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SE_16BIT(idelta[0]);
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if (channels == 2)
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{
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idelta[1] = LE_16(&input[stream_ptr]);
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stream_ptr += 2;
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SE_16BIT(idelta[1]);
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}
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sample1[0] = LE_16(&input[stream_ptr]);
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stream_ptr += 2;
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SE_16BIT(sample1[0]);
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if (channels == 2)
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{
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sample1[1] = LE_16(&input[stream_ptr]);
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stream_ptr += 2;
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SE_16BIT(sample1[1]);
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}
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sample2[0] = LE_16(&input[stream_ptr]);
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stream_ptr += 2;
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SE_16BIT(sample2[0]);
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if (channels == 2)
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{
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sample2[1] = LE_16(&input[stream_ptr]);
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stream_ptr += 2;
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SE_16BIT(sample2[1]);
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}
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while (stream_ptr < block_size)
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{
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// get the next nibble
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if (upper_nibble)
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nibble = snibble = input[stream_ptr] >> 4;
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else
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nibble = snibble = input[stream_ptr++] & 0x0F;
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upper_nibble ^= 1;
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SE_4BIT(snibble);
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predictor = (
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((sample1[current_channel] * coeff1[current_channel]) +
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(sample2[current_channel] * coeff2[current_channel])) / 256) +
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(snibble * idelta[current_channel]);
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CLAMP_S16(predictor);
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sample2[current_channel] = sample1[current_channel];
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sample1[current_channel] = predictor;
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output[out_ptr++] = predictor;
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// compute the next adaptive scale factor (a.k.a. the variable idelta)
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idelta[current_channel] =
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(ms_adapt_table[nibble] * idelta[current_channel]) / 256;
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CLAMP_ABOVE_16(idelta[current_channel]);
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// toggle the channel
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current_channel ^= channels - 1;
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}
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return (block_size - (MS_ADPCM_PREAMBLE_SIZE * channels)) * 2;
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}
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// note: This decoder assumes the format 0x61 data always comes in
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// mono flavor
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int fox61_adpcm_decode_block(unsigned short *output, unsigned char *input)
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{
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int i;
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int predictor;
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int index;
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// the first predictor value goes straight to the output
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predictor = output[0] = LE_16(&input[0]);
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SE_16BIT(predictor);
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index = input[2];
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// unpack the nibbles
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for (i = 4; i < FOX61_ADPCM_BLOCK_SIZE; i++)
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{
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output[1 + (i - 4) * 2 + 0] = (input[i] >> 4) & 0x0F;
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output[1 + (i - 4) * 2 + 1] = input[i] & 0x0F;
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}
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decode_nibbles(&output[1], FOX61_ADPCM_SAMPLES_PER_BLOCK - 1, 1,
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predictor, index,
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0, 0);
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return FOX61_ADPCM_SAMPLES_PER_BLOCK;
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}
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// note: This decoder assumes the format 0x62 data always comes in
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// stereo flavor
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int fox62_adpcm_decode_block(unsigned short *output, unsigned char *input)
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{
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int pred1;
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int pred2;
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int index1;
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int index2;
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int in_ptr = 0x10;
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int out_ptr = 0;
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int flag1 = 0;
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int flag2 = 1;
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int sum;
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unsigned char last_byte = 0;
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unsigned char nibble;
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// ADPCM work variables
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int sign;
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int delta;
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int step;
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int diff;
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pred1 = LE_16(&input[10]);
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pred2 = LE_16(&input[12]);
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SE_16BIT(pred1);
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SE_16BIT(pred2);
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sum = pred2;
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index1 = input[14];
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index2 = input[15];
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while (in_ptr < 2048)
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{
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if (flag2)
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{
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last_byte = input[in_ptr++];
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nibble = last_byte & 0x0F;
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step = adpcm_step[index1];
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sign = nibble & 8;
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delta = nibble & 7;
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diff = step >> 3;
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if (delta & 4) diff += step;
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if (delta & 2) diff += step >> 1;
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if (delta & 1) diff += step >> 2;
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if (sign)
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pred1 -= diff;
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else
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pred1 += diff;
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CLAMP_S16(pred1);
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index1 += adpcm_index[nibble];
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CLAMP_0_TO_88(index1);
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if (flag1)
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flag2 = 0;
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else
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{
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nibble = (last_byte >> 4) & 0x0F;
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step = adpcm_step[index2];
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sign = nibble & 8;
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delta = nibble & 7;
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diff = step >> 3;
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if (delta & 4) diff += step;
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if (delta & 2) diff += step >> 1;
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if (delta & 1) diff += step >> 2;
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if (sign)
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pred2 -= diff;
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else
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pred2 += diff;
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CLAMP_S16(pred2);
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index2 += adpcm_index[nibble];
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CLAMP_0_TO_88(index2);
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sum = (sum + pred2) / 2;
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}
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output[out_ptr++] = pred1 + sum;
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output[out_ptr++] = pred1 - sum;
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flag1 ^= 1;
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if (in_ptr >= 2048)
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break;
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}
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else
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{
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nibble = (last_byte >> 4) & 0x0F;
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step = adpcm_step[index1];
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sign = nibble & 8;
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delta = nibble & 7;
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diff = step >> 3;
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if (delta & 4) diff += step;
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if (delta & 2) diff += step >> 1;
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if (delta & 1) diff += step >> 2;
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if (sign)
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pred1 -= diff;
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else
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pred1 += diff;
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CLAMP_S16(pred1);
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index1 += adpcm_index[nibble];
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CLAMP_0_TO_88(index1);
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if (flag1)
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flag2 = 1;
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else
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{
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last_byte = input[in_ptr++];
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nibble = last_byte & 0x0F;
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step = adpcm_step[index2];
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sign = nibble & 8;
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delta = nibble & 7;
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diff = step >> 3;
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if (delta & 4) diff += step;
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if (delta & 2) diff += step >> 1;
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if (delta & 1) diff += step >> 2;
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if (sign)
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pred2 -= diff;
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else
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pred2 += diff;
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CLAMP_S16(pred2);
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index2 += adpcm_index[nibble];
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CLAMP_0_TO_88(index2);
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sum = (sum + pred2) / 2;
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}
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output[out_ptr++] = pred1 + sum;
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output[out_ptr++] = pred1 - sum;
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flag1 ^= 1;
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if (in_ptr >= 2048)
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break;
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}
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}
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return out_ptr;
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}
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