#include "../util.h" #include "coding.h" /** * IMA ADPCM algorithms (expand one nibble to one sample, based on prev sample/history and step table). * Nibbles are usually grouped in blocks/chunks, with a header, containing 1 or N channels * * All IMAs are mostly the same with these variations: * - interleave: blocks and channels are handled externally (layouts) or internally (mixed channels) * - block header: none (external), normal (4 bytes of history 16b + step 8b + reserved 8b) or others; per channel/global * - expand type: IMA style or variations; low or high nibble first */ static const int ADPCMTable[90] = { 7, 8, 9, 10, 11, 12, 13, 14, 16, 17, 19, 21, 23, 25, 28, 31, 34, 37, 41, 45, 50, 55, 60, 66, 73, 80, 88, 97, 107, 118, 130, 143, 157, 173, 190, 209, 230, 253, 279, 307, 337, 371, 408, 449, 494, 544, 598, 658, 724, 796, 876, 963, 1060, 1166, 1282, 1411, 1552, 1707, 1878, 2066, 2272, 2499, 2749, 3024, 3327, 3660, 4026, 4428, 4871, 5358, 5894, 6484, 7132, 7845, 8630, 9493, 10442, 11487, 12635, 13899, 15289, 16818, 18500, 20350, 22385, 24623, 27086, 29794, 32767, 0 /* garbage value for Ubisoft IMA (see blocked_ubi_sce.c) */ }; static const int IMA_IndexTable[16] = { -1, -1, -1, -1, 2, 4, 6, 8, -1, -1, -1, -1, 2, 4, 6, 8 }; /* Original IMA expansion, using shift+ADDs to avoid MULs (slow back then) */ static void std_ima_expand_nibble(VGMSTREAMCHANNEL * stream, off_t byte_offset, int nibble_shift, int32_t * hist1, int32_t * step_index) { int sample_nibble, sample_decoded, step, delta; /* simplified through math from: * - diff = (code + 1/2) * (step / 4) * > diff = ((step * nibble) + (step / 2)) / 4 * > diff = (step * nibble / 4) + (step / 8) * final diff = [signed] (step / 8) + (step / 4) + (step / 2) + (step) [when code = 4+2+1] */ sample_nibble = (read_8bit(byte_offset,stream->streamfile) >> nibble_shift)&0xf; /* ADPCM code */ sample_decoded = *hist1; /* predictor value */ step = ADPCMTable[*step_index]; /* current step */ delta = step >> 3; if (sample_nibble & 1) delta += step >> 2; if (sample_nibble & 2) delta += step >> 1; if (sample_nibble & 4) delta += step; if (sample_nibble & 8) delta = -delta; sample_decoded += delta; *hist1 = clamp16(sample_decoded); *step_index += IMA_IndexTable[sample_nibble]; if (*step_index < 0) *step_index=0; if (*step_index > 88) *step_index=88; } /* Apple's IMA variation. Exactly the same except it uses 16b history (probably more sensitive to overflow/sign extend?) */ static void std_ima_expand_nibble_16(VGMSTREAMCHANNEL * stream, off_t byte_offset, int nibble_shift, int16_t * hist1, int32_t * step_index) { int sample_nibble, sample_decoded, step, delta; sample_nibble = (read_8bit(byte_offset,stream->streamfile) >> nibble_shift)&0xf; sample_decoded = *hist1; step = ADPCMTable[*step_index]; delta = step >> 3; if (sample_nibble & 1) delta += step >> 2; if (sample_nibble & 2) delta += step >> 1; if (sample_nibble & 4) delta += step; if (sample_nibble & 8) delta = -delta; sample_decoded += delta; *hist1 = clamp16(sample_decoded); /* no need for this, actually */ *step_index += IMA_IndexTable[sample_nibble]; if (*step_index < 0) *step_index=0; if (*step_index > 88) *step_index=88; } /* Original IMA expansion, but using MULs rather than shift+ADDs (faster for newer processors). * There is minor rounding difference between ADD and MUL expansions, noticeable/propagated in non-headered IMAs. */ static void std_ima_expand_nibble_mul(VGMSTREAMCHANNEL * stream, off_t byte_offset, int nibble_shift, int32_t * hist1, int32_t * step_index) { int sample_nibble, sample_decoded, step, delta; /* simplified through math from: * - diff = (code + 1/2) * (step / 4) * > diff = (code + 1/2) * step) / 4) * (2 / 2) * > diff = (code + 1/2) * 2 * step / 8 * final diff = [signed] ((code * 2 + 1) * step) / 8 */ sample_nibble = (read_8bit(byte_offset,stream->streamfile) >> nibble_shift)&0xf; sample_decoded = *hist1; step = ADPCMTable[*step_index]; delta = (sample_nibble & 0x7); delta = ((delta * 2 + 1) * step) >> 3; if (sample_nibble & 8) delta = -delta; sample_decoded += delta; *hist1 = clamp16(sample_decoded); *step_index += IMA_IndexTable[sample_nibble]; if (*step_index < 0) *step_index=0; if (*step_index > 88) *step_index=88; } /* 3DS IMA (Mario Golf, Mario Tennis; maybe other Camelot games) */ static void n3ds_ima_expand_nibble(VGMSTREAMCHANNEL * stream, off_t byte_offset, int nibble_shift, int32_t * hist1, int32_t * step_index) { int sample_nibble, sample_decoded, step, delta; sample_nibble = (read_8bit(byte_offset,stream->streamfile) >> nibble_shift)&0xf; sample_decoded = *hist1; step = ADPCMTable[*step_index]; sample_decoded = sample_decoded << 3; delta = (sample_nibble & 0x07); delta = step * delta * 2 + step; /* custom */ if (sample_nibble & 8) delta = -delta; sample_decoded += delta; sample_decoded = sample_decoded >> 3; *hist1 = clamp16(sample_decoded); *step_index += IMA_IndexTable[sample_nibble]; if (*step_index < 0) *step_index=0; if (*step_index > 88) *step_index=88; } /* The Incredibles PC, updates step_index before doing current sample */ static void snds_ima_expand_nibble(VGMSTREAMCHANNEL * stream, off_t byte_offset, int nibble_shift, int32_t * hist1, int32_t * step_index) { int sample_nibble, sample_decoded, step, delta; sample_nibble = (read_8bit(byte_offset,stream->streamfile) >> nibble_shift)&0xf; sample_decoded = *hist1; *step_index += IMA_IndexTable[sample_nibble]; if (*step_index < 0) *step_index=0; if (*step_index > 88) *step_index=88; step = ADPCMTable[*step_index]; delta = (sample_nibble & 7) * step / 4 + step / 8; /* standard IMA */ if (sample_nibble & 8) delta = -delta; sample_decoded += delta; *hist1 = clamp16(sample_decoded); } /* Omikron: The Nomad Soul, algorithm from the .exe */ static void otns_ima_expand_nibble(VGMSTREAMCHANNEL * stream, off_t byte_offset, int nibble_shift, int32_t * hist1, int32_t * step_index) { int sample_nibble, sample_decoded, step, delta; sample_nibble = (read_8bit(byte_offset,stream->streamfile) >> nibble_shift)&0xf; sample_decoded = *hist1; step = ADPCMTable[*step_index]; delta = 0; if(sample_nibble & 4) delta = step * 4; if(sample_nibble & 2) delta += step * 2; if(sample_nibble & 1) delta += step; delta >>= 2; if (sample_nibble & 8) delta = -delta; sample_decoded += delta; *hist1 = clamp16(sample_decoded); *step_index += IMA_IndexTable[sample_nibble]; if (*step_index < 0) *step_index=0; if (*step_index > 88) *step_index=88; } /* Fairly OddParents (PC) .WV6: minor variation, reverse engineered from the .exe */ static void wv6_ima_expand_nibble(VGMSTREAMCHANNEL * stream, off_t byte_offset, int nibble_shift, int32_t * hist1, int32_t * step_index) { int sample_nibble, sample_decoded, step, delta; sample_nibble = (read_8bit(byte_offset,stream->streamfile) >> nibble_shift)&0xf; sample_decoded = *hist1; step = ADPCMTable[*step_index]; delta = (sample_nibble & 0x7); delta = ((delta * step) >> 3) + ((delta * step) >> 2); if (sample_nibble & 8) delta = -delta; sample_decoded += delta; *hist1 = clamp16(sample_decoded); *step_index += IMA_IndexTable[sample_nibble]; if (*step_index < 0) *step_index=0; if (*step_index > 88) *step_index=88; } /* Lego Racers (PC) .TUN variation, reverse engineered from the .exe */ static void alp_ima_expand_nibble(VGMSTREAMCHANNEL * stream, off_t byte_offset, int nibble_shift, int32_t * hist1, int32_t * step_index) { int sample_nibble, sample_decoded, step, delta; sample_nibble = (read_8bit(byte_offset,stream->streamfile) >> nibble_shift)&0xf; sample_decoded = *hist1; step = ADPCMTable[*step_index]; delta = (sample_nibble & 0x7); delta = (delta * step) >> 2; if (sample_nibble & 8) delta = -delta; sample_decoded += delta; *hist1 = clamp16(sample_decoded); *step_index += IMA_IndexTable[sample_nibble]; if (*step_index < 0) *step_index=0; if (*step_index > 88) *step_index=88; } /* FFTA2 IMA, different hist and sample rounding, reverse engineered from the ROM */ static void ffta2_ima_expand_nibble(VGMSTREAMCHANNEL * stream, off_t byte_offset, int nibble_shift, int32_t * hist1, int32_t * step_index, int16_t *out_sample) { int sample_nibble, sample_decoded, step, delta; sample_nibble = (read_8bit(byte_offset,stream->streamfile) >> nibble_shift)&0xf; /* ADPCM code */ sample_decoded = *hist1; /* predictor value */ step = ADPCMTable[*step_index] * 0x100; /* current step (table in ROM is pre-multiplied though) */ delta = step >> 3; if (sample_nibble & 1) delta += step >> 2; if (sample_nibble & 2) delta += step >> 1; if (sample_nibble & 4) delta += step; if (sample_nibble & 8) delta = -delta; sample_decoded += delta; /* custom clamp16 */ if (sample_decoded > 0x7FFF00) sample_decoded = 0x7FFF00; else if (sample_decoded < -0x800000) sample_decoded = -0x800000; *hist1 = sample_decoded; *out_sample = (short)((sample_decoded + 128) / 256); /* int16 sample rounding, hist is kept as int32 */ *step_index += IMA_IndexTable[sample_nibble]; if (*step_index < 0) *step_index=0; if (*step_index > 88) *step_index=88; } /* Yet another IMA expansion, from the exe */ static void blitz_ima_expand_nibble(VGMSTREAMCHANNEL * stream, off_t byte_offset, int nibble_shift, int32_t * hist1, int32_t * step_index) { int sample_nibble, sample_decoded, step, delta; sample_nibble = (read_8bit(byte_offset,stream->streamfile) >> nibble_shift)&0xf; /* ADPCM code */ sample_decoded = *hist1; /* predictor value */ step = ADPCMTable[*step_index]; /* current step */ /* table has 2 different values, not enough to bother adding the full table */ if (step == 22385) step = 22358; else if (step == 24623) step = 24633; delta = (sample_nibble & 0x07); if (sample_nibble & 8) delta = -delta; delta = (step >> 1) + delta * step; /* custom */ sample_decoded += delta; /* in Zapper somehow the exe tries to clamp hist but actually doesn't (bug? not in Lilo & Stitch), * seems the pcm buffer must be clamped outside though to fix some scratchiness */ *hist1 = sample_decoded;//clamp16(sample_decoded); *step_index += IMA_IndexTable[sample_nibble]; if (*step_index < 0) *step_index=0; if (*step_index > 88) *step_index=88; } static const int CIMAADPCM_INDEX_TABLE[16] = {8, 6, 4, 2, -1, -1, -1, -1, -1, -1, -1, -1, 2, 4, 6, 8}; /* Capcom's MT Framework modified IMA, reverse engineered from the exe */ static void mtf_ima_expand_nibble(VGMSTREAMCHANNEL * stream, off_t byte_offset, int nibble_shift, int32_t * hist1, int32_t * step_index) { int sample_nibble, sample_decoded, step, delta; sample_nibble = (read_8bit(byte_offset,stream->streamfile) >> nibble_shift) & 0xf; sample_decoded = *hist1; step = ADPCMTable[*step_index]; delta = step * (2 * sample_nibble - 15); sample_decoded += delta; *hist1 = sample_decoded; *step_index += CIMAADPCM_INDEX_TABLE[sample_nibble]; if (*step_index < 0) *step_index=0; if (*step_index > 88) *step_index=88; } /* IMA table pre-modified like this: for i=0..89 adpcm = clamp(adpcm[i], 0x1fff) * 4; */ static const int16_t mul_adpcm_table[89] = { 28, 32, 36, 40, 44, 48, 52, 56, 64, 68, 76, 84, 92, 100, 112, 124, 136, 148, 164, 180, 200, 220, 240, 264, 292, 320, 352, 388, 428, 472, 520, 572, 628, 692, 760, 836, 920, 1012, 1116, 1228, 1348, 1484, 1632, 1796, 1976, 2176, 2392, 2632, 2896, 3184, 3504, 3852, 4240, 4664, 5128, 5644, 6208, 6828, 7512, 8264, 9088, 9996, 10996, 12096, 13308, 14640, 16104, 17712, 19484, 21432, 23576, 25936, 28528, 31380, 32764, 32764, 32764, 32764, 32764, 32764, 32764, 32764, 32764, 32764, 32764, 32764, 32764, 32764, 32764 }; /* step table is the same */ /* ops per code, generated like this: for i=0..15 v = 0x800 if (i & 1) v = 0x1800 if (i & 2) v += 0x2000 if (i & 4) v += 0x4000 if (i & 8) v = -v; mul_op_table[i] = v; */ static const int16_t mul_delta_table[16] = { 0x0800, 0x1800, 0x2800, 0x3800, 0x4800, 0x5800, 0x6800, 0x7800, -0x0800,-0x1800,-0x2800,-0x3800,-0x4800,-0x5800,-0x6800,-0x7800 }; /* Crystal Dynamics IMA, reverse engineered from the exe, also info: https://github.com/sephiroth99/MulDeMu */ static void cd_ima_expand_nibble(uint8_t byte, int shift, int32_t* hist1, int32_t* index) { int code, sample, step, delta; /* could do the above table calcs during decode too */ code = (byte >> shift) & 0xf; sample = *hist1; step = mul_adpcm_table[*index]; delta = (int16_t)((step * mul_delta_table[code]) >> 16); sample += delta; *hist1 = clamp16(sample); *index += IMA_IndexTable[code]; if (*index < 0) *index=0; if (*index > 88) *index=88; } /* ************************************ */ /* DVI/IMA */ /* ************************************ */ /* Standard DVI/IMA ADPCM (as in, ADPCM recommended by the IMA using Intel/DVI's implementation). * Configurable: stereo or mono/interleave nibbles, and high or low nibble first. * For vgmstream, low nibble is called "IMA ADPCM" and high nibble is "DVI IMA ADPCM" (same thing though). */ void decode_standard_ima(VGMSTREAMCHANNEL * stream, sample_t * outbuf, int channelspacing, int32_t first_sample, int32_t samples_to_do, int channel, int is_stereo, int is_high_first) { int i, sample_count = 0; int32_t hist1 = stream->adpcm_history1_32; int step_index = stream->adpcm_step_index; /* external interleave */ /* no header (external setup), pre-clamp for wrong values */ if (step_index < 0) step_index=0; if (step_index > 88) step_index=88; /* decode nibbles (layout: varies) */ for (i = first_sample; i < first_sample + samples_to_do; i++, sample_count += channelspacing) { off_t byte_offset = is_stereo ? stream->offset + i : /* stereo: one nibble per channel */ stream->offset + i/2; /* mono: consecutive nibbles */ int nibble_shift = is_high_first ? is_stereo ? (!(channel&1) ? 4:0) : (!(i&1) ? 4:0) : /* even = high, odd = low */ is_stereo ? (!(channel&1) ? 0:4) : (!(i&1) ? 0:4); /* even = low, odd = high */ std_ima_expand_nibble(stream, byte_offset,nibble_shift, &hist1, &step_index); outbuf[sample_count] = (short)(hist1); } stream->adpcm_history1_32 = hist1; stream->adpcm_step_index = step_index; } void decode_mtf_ima(VGMSTREAMCHANNEL * stream, sample_t * outbuf, int channelspacing, int32_t first_sample, int32_t samples_to_do, int channel, int is_stereo) { int i, sample_count = 0; int32_t hist1 = stream->adpcm_history1_32; int step_index = stream->adpcm_step_index; /* external interleave */ /* no header (external setup), pre-clamp for wrong values */ if (step_index < 0) step_index=0; if (step_index > 88) step_index=88; /* decode nibbles (layout: varies) */ for (i = first_sample; i < first_sample + samples_to_do; i++, sample_count += channelspacing) { off_t byte_offset = is_stereo ? stream->offset + i : /* stereo: one nibble per channel */ stream->offset + i/2; /* mono: consecutive nibbles */ int nibble_shift = is_stereo ? ((channel&1) ? 0:4) : ((i&1) ? 0:4); mtf_ima_expand_nibble(stream, byte_offset,nibble_shift, &hist1, &step_index); outbuf[sample_count] = clamp16(hist1 >> 4); } stream->adpcm_history1_32 = hist1; stream->adpcm_step_index = step_index; } void decode_3ds_ima(VGMSTREAMCHANNEL * stream, sample_t * outbuf, int channelspacing, int32_t first_sample, int32_t samples_to_do) { int i, sample_count; int32_t hist1 = stream->adpcm_history1_32; int step_index = stream->adpcm_step_index; //external interleave //no header for (i=first_sample,sample_count=0; ioffset + i/2; int nibble_shift = (i&1?4:0); //low nibble order n3ds_ima_expand_nibble(stream, byte_offset,nibble_shift, &hist1, &step_index); outbuf[sample_count] = (short)(hist1); } stream->adpcm_history1_32 = hist1; stream->adpcm_step_index = step_index; } void decode_snds_ima(VGMSTREAMCHANNEL * stream, sample_t * outbuf, int channelspacing, int32_t first_sample, int32_t samples_to_do, int channel) { int i, sample_count; int32_t hist1 = stream->adpcm_history1_32; int step_index = stream->adpcm_step_index; //external interleave //no header for (i=first_sample,sample_count=0; ioffset + i;//one nibble per channel int nibble_shift = (channel==0?0:4); //high nibble first, based on channel snds_ima_expand_nibble(stream, byte_offset,nibble_shift, &hist1, &step_index); outbuf[sample_count] = (short)(hist1); } stream->adpcm_history1_32 = hist1; stream->adpcm_step_index = step_index; } void decode_otns_ima(VGMSTREAM * vgmstream, VGMSTREAMCHANNEL * stream, sample_t * outbuf, int channelspacing, int32_t first_sample, int32_t samples_to_do, int channel) { int i, sample_count; int32_t hist1 = stream->adpcm_history1_32; int step_index = stream->adpcm_step_index; //internal/byte interleave //no header for (i=first_sample,sample_count=0; ioffset + (vgmstream->channels==1 ? i/2 : i); //one nibble per channel if stereo int nibble_shift = (vgmstream->channels==1) ? //todo simplify (i&1?0:4) : //high nibble first(?) (channel==0?4:0); //low=ch0, high=ch1 (this is correct compared to vids) otns_ima_expand_nibble(stream, byte_offset,nibble_shift, &hist1, &step_index); outbuf[sample_count] = (short)(hist1); } stream->adpcm_history1_32 = hist1; stream->adpcm_step_index = step_index; } /* WV6 IMA, DVI IMA with custom nibble expand */ void decode_wv6_ima(VGMSTREAMCHANNEL * stream, sample_t * outbuf, int channelspacing, int32_t first_sample, int32_t samples_to_do) { int i, sample_count; int32_t hist1 = stream->adpcm_history1_32; int step_index = stream->adpcm_step_index; //external interleave //no header for (i=first_sample,sample_count=0; ioffset + i/2; int nibble_shift = (i&1?0:4); //high nibble first wv6_ima_expand_nibble(stream, byte_offset,nibble_shift, &hist1, &step_index); outbuf[sample_count] = (short)(hist1); } stream->adpcm_history1_32 = hist1; stream->adpcm_step_index = step_index; } /* ALT IMA, DVI IMA with custom nibble expand */ void decode_alp_ima(VGMSTREAMCHANNEL * stream, sample_t * outbuf, int channelspacing, int32_t first_sample, int32_t samples_to_do) { int i, sample_count; int32_t hist1 = stream->adpcm_history1_32; int step_index = stream->adpcm_step_index; //external interleave //no header for (i=first_sample,sample_count=0; ioffset + i/2; int nibble_shift = (i&1?0:4); //high nibble first alp_ima_expand_nibble(stream, byte_offset,nibble_shift, &hist1, &step_index); outbuf[sample_count] = (short)(hist1); } stream->adpcm_history1_32 = hist1; stream->adpcm_step_index = step_index; } /* FFTA2 IMA, DVI IMA with custom nibble expand/rounding */ void decode_ffta2_ima(VGMSTREAMCHANNEL * stream, sample_t * outbuf, int channelspacing, int32_t first_sample, int32_t samples_to_do) { int i, sample_count; int32_t hist1 = stream->adpcm_history1_32; int step_index = stream->adpcm_step_index; int16_t out_sample; //external interleave //no header for (i=first_sample,sample_count=0; ioffset + i/2; int nibble_shift = (i&1?0:4); //high nibble first ffta2_ima_expand_nibble(stream, byte_offset,nibble_shift, &hist1, &step_index, &out_sample); outbuf[sample_count] = out_sample; } stream->adpcm_history1_32 = hist1; stream->adpcm_step_index = step_index; } /* Blitz IMA, IMA with custom nibble expand */ void decode_blitz_ima(VGMSTREAMCHANNEL * stream, sample_t * outbuf, int channelspacing, int32_t first_sample, int32_t samples_to_do) { int i, sample_count; int32_t hist1 = stream->adpcm_history1_32; int step_index = stream->adpcm_step_index; //external interleave //no header for (i=first_sample,sample_count=0; ioffset + i/2; int nibble_shift = (i&1?4:0); //low nibble first blitz_ima_expand_nibble(stream, byte_offset,nibble_shift, &hist1, &step_index); outbuf[sample_count] = (short)clamp16(hist1); } stream->adpcm_history1_32 = hist1; stream->adpcm_step_index = step_index; } /* ************************************ */ /* MS-IMA */ /* ************************************ */ /* IMA with custom frame sizes, header and nibble layout. Outputs an odd number of samples per frame, * so to simplify calcs this decodes full frames, thus hist doesn't need to be mantained. * Officially defined in "Microsoft Multimedia Standards Update" doc (RIFFNEW.pdf). */ void decode_ms_ima(VGMSTREAM* vgmstream, VGMSTREAMCHANNEL* stream, sample_t* outbuf, int channelspacing, int32_t first_sample, int32_t samples_to_do, int channel) { int i, samples_read = 0, samples_done = 0, max_samples; int32_t hist1;// = stream->adpcm_history1_32; int step_index;// = stream->adpcm_step_index; int frame_channels = vgmstream->codec_config ? 1 : vgmstream->channels; /* mono or mch modes */ int frame_channel = vgmstream->codec_config ? 0 : channel; /* internal interleave (configurable size), mixed channels */ int block_samples = ((vgmstream->frame_size - 0x04*frame_channels) * 2 / frame_channels) + 1; first_sample = first_sample % block_samples; /* normal header (hist+step+reserved), per channel */ { //if (first_sample == 0) { off_t header_offset = stream->offset + 0x04*frame_channel; hist1 = read_s16le(header_offset+0x00,stream->streamfile); step_index = read_u8(header_offset+0x02,stream->streamfile); /* 0x03: reserved */ if (step_index < 0) step_index = 0; if (step_index > 88) step_index = 88; /* write header sample (odd samples per block) */ if (samples_read >= first_sample && samples_done < samples_to_do) { outbuf[samples_done * channelspacing] = (short)hist1; samples_done++; } samples_read++; } max_samples = (block_samples - samples_read); if (max_samples > samples_to_do + first_sample - samples_done) max_samples = samples_to_do + first_sample - samples_done; /* for smaller last block */ /* decode nibbles (layout: alternates 4 bytes/4*2 nibbles per channel) */ for (i = 0; i < max_samples; i++) { off_t byte_offset = stream->offset + 0x04*frame_channels + 0x04*frame_channel + 0x04*frame_channels*(i/8) + (i%8)/2; int nibble_shift = (i&1?4:0); /* low nibble first */ std_ima_expand_nibble(stream, byte_offset,nibble_shift, &hist1, &step_index); /* original expand */ if (samples_read >= first_sample && samples_done < samples_to_do) { outbuf[samples_done * channelspacing] = (short)(hist1); samples_done++; } samples_read++; } /* internal interleave: increment offset on complete frame */ if (first_sample + samples_done == block_samples) { stream->offset += vgmstream->frame_size; } //stream->adpcm_history1_32 = hist1; //stream->adpcm_step_index = step_index; } /* Reflection's MS-IMA with custom nibble layout (some info from XA2WAV by Deniz Oezmen) */ void decode_ref_ima(VGMSTREAM * vgmstream, VGMSTREAMCHANNEL * stream, sample_t * outbuf, int channelspacing, int32_t first_sample, int32_t samples_to_do, int channel) { int i, samples_read = 0, samples_done = 0, max_samples; int32_t hist1;// = stream->adpcm_history1_32; int step_index;// = stream->adpcm_step_index; /* internal interleave (configurable size), mixed channels */ int block_channel_size = (vgmstream->interleave_block_size - 0x04*vgmstream->channels) / vgmstream->channels; int block_samples = ((vgmstream->interleave_block_size - 0x04*vgmstream->channels) * 2 / vgmstream->channels) + 1; first_sample = first_sample % block_samples; /* normal header (hist+step+reserved), per channel */ { //if (first_sample == 0) { off_t header_offset = stream->offset + 0x04*channel; hist1 = read_16bitLE(header_offset+0x00,stream->streamfile); step_index = read_8bit(header_offset+0x02,stream->streamfile); if (step_index < 0) step_index = 0; if (step_index > 88) step_index = 88; /* write header sample */ if (samples_read >= first_sample && samples_done < samples_to_do) { outbuf[samples_done * channelspacing] = (short)hist1; samples_done++; } samples_read++; } max_samples = (block_samples - samples_read); if (max_samples > samples_to_do + first_sample - samples_done) max_samples = samples_to_do + first_sample - samples_done; /* for smaller last block */ /* decode nibbles (layout: all nibbles from one channel, then other channels) */ for (i = 0; i < max_samples; i++) { off_t byte_offset = stream->offset + 0x04*vgmstream->channels + block_channel_size*channel + i/2; int nibble_shift = (i&1?4:0); /* low nibble first */ std_ima_expand_nibble(stream, byte_offset,nibble_shift, &hist1, &step_index); if (samples_read >= first_sample && samples_done < samples_to_do) { outbuf[samples_done * channelspacing] = (short)(hist1); samples_done++; } samples_read++; } /* internal interleave: increment offset on complete frame */ if (first_sample + samples_done == block_samples) { stream->offset += vgmstream->interleave_block_size; } //stream->adpcm_history1_32 = hist1; //stream->adpcm_step_index = step_index; } /* ************************************ */ /* XBOX-IMA */ /* ************************************ */ /* MS-IMA with fixed frame size, and outputs an even number of samples per frame (skips last nibble). * Defined in Xbox's SDK. Usable in mono or stereo modes (both suitable for interleaved multichannel). */ void decode_xbox_ima(VGMSTREAMCHANNEL * stream, sample_t * outbuf, int channelspacing, int32_t first_sample, int32_t samples_to_do, int channel, int is_stereo) { int i, frames_in, sample_pos = 0, block_samples, frame_size; int32_t hist1 = stream->adpcm_history1_32; int step_index = stream->adpcm_step_index; off_t frame_offset; /* external interleave (fixed size), stereo/mono */ block_samples = (0x24 - 0x4) * 2; frames_in = first_sample / block_samples; first_sample = first_sample % block_samples; frame_size = is_stereo ? 0x24*2 : 0x24; frame_offset = stream->offset + frame_size*frames_in; /* normal header (hist+step+reserved), stereo/mono */ if (first_sample == 0) { off_t header_offset = is_stereo ? frame_offset + 0x04*(channel % 2) : frame_offset + 0x00; hist1 = read_16bitLE(header_offset+0x00,stream->streamfile); step_index = read_8bit(header_offset+0x02,stream->streamfile); if (step_index < 0) step_index=0; if (step_index > 88) step_index=88; /* write header sample (even samples per block, skips last nibble) */ outbuf[sample_pos] = (short)(hist1); sample_pos += channelspacing; first_sample += 1; samples_to_do -= 1; } /* decode nibbles (layout: straight in mono or 4 bytes per channel in stereo) */ for (i = first_sample; i < first_sample + samples_to_do; i++) { off_t byte_offset = is_stereo ? frame_offset + 0x04*2 + 0x04*(channel % 2) + 0x04*2*((i-1)/8) + ((i-1)%8)/2 : frame_offset + 0x04 + (i-1)/2; int nibble_shift = (!((i-1)&1) ? 0:4); /* low first */ /* must skip last nibble per spec, rarely needed though (ex. Gauntlet Dark Legacy) */ if (i < block_samples) { std_ima_expand_nibble(stream, byte_offset,nibble_shift, &hist1, &step_index); outbuf[sample_pos] = (short)(hist1); sample_pos += channelspacing; } } stream->adpcm_history1_32 = hist1; stream->adpcm_step_index = step_index; } /* Multichannel XBOX-IMA ADPCM, with all channels mixed in the same block (equivalent to multichannel MS-IMA; seen in .rsd XADP). */ void decode_xbox_ima_mch(VGMSTREAMCHANNEL * stream, sample_t * outbuf, int channelspacing, int32_t first_sample, int32_t samples_to_do, int channel) { int i, sample_count = 0, num_frame; int32_t hist1 = stream->adpcm_history1_32; int step_index = stream->adpcm_step_index; /* external interleave (fixed size), multichannel */ int block_samples = (0x24 - 0x4) * 2; num_frame = first_sample / block_samples; first_sample = first_sample % block_samples; /* normal header (hist+step+reserved), multichannel */ if (first_sample == 0) { off_t header_offset = stream->offset + 0x24*channelspacing*num_frame + 0x04*channel; hist1 = read_16bitLE(header_offset+0x00,stream->streamfile); step_index = read_8bit(header_offset+0x02,stream->streamfile); if (step_index < 0) step_index=0; if (step_index > 88) step_index=88; /* write header sample (even samples per block, skips last nibble) */ outbuf[sample_count] = (short)(hist1); sample_count += channelspacing; first_sample += 1; samples_to_do -= 1; } /* decode nibbles (layout: alternates 4 bytes/4*2 nibbles per channel) */ for (i = first_sample; i < first_sample + samples_to_do; i++) { off_t byte_offset = (stream->offset + 0x24*channelspacing*num_frame + 0x04*channelspacing) + 0x04*channel + 0x04*channelspacing*((i-1)/8) + ((i-1)%8)/2; int nibble_shift = ((i-1)&1?4:0); /* low nibble first */ /* must skip last nibble per spec, rarely needed though */ if (i < block_samples) { std_ima_expand_nibble(stream, byte_offset,nibble_shift, &hist1, &step_index); outbuf[sample_count] = (short)(hist1); sample_count += channelspacing; } } stream->adpcm_history1_32 = hist1; stream->adpcm_step_index = step_index; } /* Similar to MS-IMA with even number of samples, header sample is not written (setup only). * Apparently clamps to -32767 unlike standard's -32768 (probably not noticeable). * Info here: http://problemkaputt.de/gbatek.htm#dssoundnotes */ void decode_nds_ima(VGMSTREAMCHANNEL * stream, sample_t * outbuf, int channelspacing, int32_t first_sample, int32_t samples_to_do) { int i, sample_count; int32_t hist1 = stream->adpcm_history1_32; int step_index = stream->adpcm_step_index; /* external interleave (configurable size), mono */ /* normal header (hist+step+reserved), single channel */ if (first_sample == 0) { off_t header_offset = stream->offset; hist1 = read_16bitLE(header_offset,stream->streamfile); step_index = read_16bitLE(header_offset+2,stream->streamfile); if (step_index < 0) step_index=0; /* probably pre-adjusted */ if (step_index > 88) step_index=88; } /* decode nibbles (layout: all nibbles from the channel) */ for (i=first_sample,sample_count=0; ioffset + 0x04 + i/2; int nibble_shift = (i&1?4:0); /* low nibble first */ //todo waveform has minor deviations using known expands std_ima_expand_nibble(stream, byte_offset,nibble_shift, &hist1, &step_index); outbuf[sample_count] = (short)(hist1); } stream->adpcm_history1_32 = hist1; stream->adpcm_step_index = step_index; } void decode_dat4_ima(VGMSTREAMCHANNEL * stream, sample_t * outbuf, int channelspacing, int32_t first_sample, int32_t samples_to_do) { int i, sample_count; int32_t hist1 = stream->adpcm_history1_16;//todo unneeded 16? int step_index = stream->adpcm_step_index; //external interleave //normal header if (first_sample == 0) { off_t header_offset = stream->offset; hist1 = read_16bitLE(header_offset,stream->streamfile); step_index = read_8bit(header_offset+2,stream->streamfile); //todo clip step_index? } for (i=first_sample,sample_count=0; ioffset + 4 + i/2; int nibble_shift = (i&1?0:4); //high nibble first std_ima_expand_nibble(stream, byte_offset,nibble_shift, &hist1, &step_index); outbuf[sample_count] = (short)(hist1); } stream->adpcm_history1_16 = hist1; stream->adpcm_step_index = step_index; } void decode_rad_ima(VGMSTREAM * vgmstream,VGMSTREAMCHANNEL * stream, sample_t * outbuf, int channelspacing, int32_t first_sample, int32_t samples_to_do,int channel) { int i, sample_count; int32_t hist1 = stream->adpcm_history1_32; int step_index = stream->adpcm_step_index; //internal interleave (configurable size), mixed channels (4 byte per ch) int block_samples = (vgmstream->interleave_block_size - 4*vgmstream->channels) * 2 / vgmstream->channels; first_sample = first_sample % block_samples; //inverted header (per channel) if (first_sample == 0) { off_t header_offset = stream->offset + 4*channel; step_index = read_16bitLE(header_offset,stream->streamfile); hist1 = read_16bitLE(header_offset+2,stream->streamfile); if (step_index < 0) step_index=0; if (step_index > 88) step_index=88; } for (i=first_sample,sample_count=0; ioffset + 4*vgmstream->channels + channel + i/2*vgmstream->channels; int nibble_shift = (i&1?4:0); //low nibble first std_ima_expand_nibble(stream, byte_offset,nibble_shift, &hist1, &step_index); outbuf[sample_count] = (short)(hist1); } //internal interleave: increment offset on complete frame if (i == block_samples) stream->offset += vgmstream->interleave_block_size; stream->adpcm_history1_32 = hist1; stream->adpcm_step_index = step_index; } void decode_rad_ima_mono(VGMSTREAMCHANNEL * stream, sample_t * outbuf, int channelspacing, int32_t first_sample, int32_t samples_to_do) { int i, sample_count; int32_t hist1 = stream->adpcm_history1_32; int step_index = stream->adpcm_step_index; //semi-external interleave? int block_samples = 0x14 * 2; first_sample = first_sample % block_samples; //inverted header if (first_sample == 0) { off_t header_offset = stream->offset; step_index = read_16bitLE(header_offset,stream->streamfile); hist1 = read_16bitLE(header_offset+2,stream->streamfile); if (step_index < 0) step_index=0; if (step_index > 88) step_index=88; } for (i=first_sample,sample_count=0; ioffset + 4 + i/2; int nibble_shift = (i&1?4:0); //low nibble first std_ima_expand_nibble(stream, byte_offset,nibble_shift, &hist1, &step_index); outbuf[sample_count] = (short)(hist1); } stream->adpcm_history1_32 = hist1; stream->adpcm_step_index = step_index; } /* Apple's IMA4, a.k.a QuickTime IMA. 2 byte header and header sample is not written (setup only). */ void decode_apple_ima4(VGMSTREAMCHANNEL * stream, sample_t * outbuf, int channelspacing, int32_t first_sample, int32_t samples_to_do) { int i, sample_count, num_frame; int16_t hist1 = stream->adpcm_history1_16;//todo unneeded 16? int step_index = stream->adpcm_step_index; //external interleave int block_samples = (0x22 - 0x2) * 2; num_frame = first_sample / block_samples; first_sample = first_sample % block_samples; //2-byte header if (first_sample == 0) { off_t header_offset = stream->offset + 0x22*num_frame; hist1 = (int16_t)((uint16_t)read_16bitBE(header_offset,stream->streamfile) & 0xff80); step_index = read_8bit(header_offset+1,stream->streamfile) & 0x7f; if (step_index < 0) step_index=0; if (step_index > 88) step_index=88; } for (i=first_sample,sample_count=0; ioffset + 0x22*num_frame + 0x2) + i/2; int nibble_shift = (i&1?4:0); //low nibble first std_ima_expand_nibble_16(stream, byte_offset,nibble_shift, &hist1, &step_index); outbuf[sample_count] = (short)(hist1); } stream->adpcm_history1_16 = hist1; stream->adpcm_step_index = step_index; } /* XBOX-IMA with modified data layout */ void decode_fsb_ima(VGMSTREAM * vgmstream, VGMSTREAMCHANNEL * stream, sample_t * outbuf, int channelspacing, int32_t first_sample, int32_t samples_to_do,int channel) { int i, sample_count = 0; int32_t hist1 = stream->adpcm_history1_32; int step_index = stream->adpcm_step_index; /* internal interleave (configurable size), mixed channels */ int block_samples = (0x24 - 0x4) * 2; first_sample = first_sample % block_samples; /* interleaved header (all hist per channel + all step_index+reserved per channel) */ if (first_sample == 0) { off_t hist_offset = stream->offset + 0x02*channel + 0x00; off_t step_offset = stream->offset + 0x02*channel + 0x02*vgmstream->channels; hist1 = read_16bitLE(hist_offset,stream->streamfile); step_index = read_8bit(step_offset,stream->streamfile); if (step_index < 0) step_index=0; if (step_index > 88) step_index=88; /* write header sample (even samples per block, skips last nibble) */ outbuf[sample_count] = (short)(hist1); sample_count += channelspacing; first_sample += 1; samples_to_do -= 1; } /* decode nibbles (layout: 2 bytes/2*2 nibbles per channel) */ for (i = first_sample; i < first_sample + samples_to_do; i++) { off_t byte_offset = stream->offset + 0x04*vgmstream->channels + 0x02*channel + (i-1)/4*2*vgmstream->channels + ((i-1)%4)/2; int nibble_shift = ((i-1)&1?4:0); /* low nibble first */ /* must skip last nibble per official decoder, probably not needed though */ if (i < block_samples) { std_ima_expand_nibble(stream, byte_offset,nibble_shift, &hist1, &step_index); outbuf[sample_count] = (short)(hist1); sample_count += channelspacing; } } /* internal interleave: increment offset on complete frame */ if (i == block_samples) { stream->offset += 0x24*vgmstream->channels; } stream->adpcm_history1_32 = hist1; stream->adpcm_step_index = step_index; } /* mono XBOX-IMA with header endianness and alt nibble expand (verified vs AK test demos) */ void decode_wwise_ima(VGMSTREAM* vgmstream, VGMSTREAMCHANNEL* stream, sample_t* outbuf, int channelspacing, int32_t first_sample, int32_t samples_to_do) { int i, sample_count = 0, num_frame; int32_t hist1 = stream->adpcm_history1_32; int step_index = stream->adpcm_step_index; /* external interleave (fixed size), mono */ int block_samples = (0x24 - 0x4) * 2; num_frame = first_sample / block_samples; first_sample = first_sample % block_samples; /* normal header (hist+step+reserved), single channel */ if (first_sample == 0) { int16_t (*read_16bit)(off_t,STREAMFILE*) = vgmstream->codec_endian ? read_16bitBE : read_16bitLE; off_t header_offset = stream->offset + 0x24*num_frame; hist1 = read_16bit(header_offset,stream->streamfile); step_index = read_8bit(header_offset+2,stream->streamfile); if (step_index < 0) step_index=0; if (step_index > 88) step_index=88; /* write header sample (even samples per block, skips last nibble) */ outbuf[sample_count] = (short)(hist1); sample_count += channelspacing; first_sample += 1; samples_to_do -= 1; } /* decode nibbles (layout: all nibbles from one channel) */ for (i = first_sample; i < first_sample + samples_to_do; i++) { off_t byte_offset = (stream->offset + 0x24*num_frame + 0x4) + (i-1)/2; int nibble_shift = ((i-1)&1?4:0); /* low nibble first */ /* must skip last nibble like other XBOX-IMAs, often needed (ex. Bayonetta 2 sfx) */ if (i < block_samples) { std_ima_expand_nibble_mul(stream, byte_offset,nibble_shift, &hist1, &step_index); outbuf[sample_count] = (short)(hist1); sample_count += channelspacing; } } stream->adpcm_history1_32 = hist1; stream->adpcm_step_index = step_index; } /* MS-IMA with possibly the XBOX-IMA model of even number of samples per block (more tests are needed) */ void decode_awc_ima(VGMSTREAMCHANNEL * stream, sample_t * outbuf, int channelspacing, int32_t first_sample, int32_t samples_to_do) { int i, sample_count; int32_t hist1 = stream->adpcm_history1_32; int step_index = stream->adpcm_step_index; //internal interleave, mono int block_samples = (0x800 - 4) * 2; first_sample = first_sample % block_samples; //inverted header if (first_sample == 0) { off_t header_offset = stream->offset; step_index = read_16bitLE(header_offset,stream->streamfile); hist1 = read_16bitLE(header_offset+2,stream->streamfile); if (step_index < 0) step_index=0; if (step_index > 88) step_index=88; } for (i=first_sample,sample_count=0; ioffset + 4 + i/2; int nibble_shift = (i&1?4:0); //low nibble first std_ima_expand_nibble(stream, byte_offset,nibble_shift, &hist1, &step_index); outbuf[sample_count] = (short)(hist1); } //internal interleave: increment offset on complete frame if (i == block_samples) stream->offset += 0x800; stream->adpcm_history1_32 = hist1; stream->adpcm_step_index = step_index; } /* DVI stereo/mono with some mini header and sample output */ void decode_ubi_ima(VGMSTREAMCHANNEL * stream, sample_t * outbuf, int channelspacing, int32_t first_sample, int32_t samples_to_do, int channel) { int i, sample_count = 0; int32_t hist1 = stream->adpcm_history1_32; int step_index = stream->adpcm_step_index; //internal interleave //header in the beginning of the stream if (stream->channel_start_offset == stream->offset) { int version, big_endian, header_samples, max_samples_to_do; int16_t (*read_16bit)(off_t,STREAMFILE*) = NULL; off_t offset = stream->offset; /* header fields mostly unknown (vary a lot or look like flags, tool version?, 0x08: stereo flag?) */ version = read_8bit(offset + 0x00, stream->streamfile); big_endian = version < 5; read_16bit = big_endian ? read_16bitBE : read_16bitLE; header_samples = read_16bit(offset + 0x0E, stream->streamfile); /* always 10 (per channel) */ hist1 = read_16bit(offset + 0x10 + channel*0x04,stream->streamfile); step_index = read_8bit(offset + 0x12 + channel*0x04,stream->streamfile); offset += 0x10 + 0x08; if (version >= 3) offset += 0x04; if (version >= 6) /* later BAOs */ offset += 0x08; /* write PCM samples, must be written to match header's num_samples (hist mustn't) */ max_samples_to_do = ((samples_to_do > header_samples) ? header_samples : samples_to_do); for (i = first_sample; i < max_samples_to_do; i++, sample_count += channelspacing) { outbuf[sample_count] = read_16bit(offset + channel*sizeof(sample) + i*channelspacing*sizeof(sample),stream->streamfile); first_sample++; samples_to_do--; } /* header done */ if (i == header_samples) { stream->offset = offset + header_samples*channelspacing*sizeof(sample); } } first_sample -= 10; //todo fix hack (needed to adjust nibble offset below) if (step_index < 0) step_index = 0; if (step_index > 88) step_index = 88; for (i = first_sample; i < first_sample + samples_to_do; i++, sample_count += channelspacing) { off_t byte_offset = channelspacing == 1 ? stream->offset + i/2 : /* mono mode */ stream->offset + i; /* stereo mode */ int nibble_shift = channelspacing == 1 ? (!(i%2) ? 4:0) : /* mono mode (high first) */ (channel==0 ? 4:0); /* stereo mode (high=L,low=R) */ std_ima_expand_nibble_mul(stream, byte_offset,nibble_shift, &hist1, &step_index); outbuf[sample_count] = (short)(hist1); /* all samples are written */ } stream->adpcm_history1_32 = hist1; stream->adpcm_step_index = step_index; } /* standard IMA but with a tweak for Ubi's encoder bug with step index (see blocked_ubi_sce.c) */ void decode_ubi_sce_ima(VGMSTREAMCHANNEL * stream, sample_t * outbuf, int channelspacing, int32_t first_sample, int32_t samples_to_do, int channel) { int i, sample_count = 0; int32_t hist1 = stream->adpcm_history1_32; int step_index = stream->adpcm_step_index; //internal interleave if (step_index < 0) step_index = 0; if (step_index > 89) step_index = 89; for (i = first_sample; i < first_sample + samples_to_do; i++, sample_count += channelspacing) { off_t byte_offset = channelspacing == 1 ? stream->offset + i/2 : /* mono mode */ stream->offset + i; /* stereo mode */ int nibble_shift = channelspacing == 1 ? (!(i%2) ? 4:0) : /* mono mode (high first) */ (channel==0 ? 4:0); /* stereo mode (high=L,low=R) */ std_ima_expand_nibble(stream, byte_offset,nibble_shift, &hist1, &step_index); outbuf[sample_count] = (short)(hist1); /* all samples are written */ } stream->adpcm_history1_32 = hist1; stream->adpcm_step_index = step_index; } /* IMA with variable frame formats controlled by the block layout. The original code uses * tables mapping all standard IMA combinations (to optimize calculations), but decodes the same. * Based on HCS's and Nisto's reverse engineering in h4m_audio_decode. */ void decode_h4m_ima(VGMSTREAMCHANNEL * stream, sample_t * outbuf, int channelspacing, int32_t first_sample, int32_t samples_to_do, int channel, uint16_t frame_format) { int i, samples_done = 0; int32_t hist1 = stream->adpcm_history1_32; int step_index = stream->adpcm_step_index; size_t header_size; int is_stereo = (channelspacing > 1); /* external interleave (blocked, should call 1 frame) */ /* custom header, per channel */ if (first_sample == 0) { int channel_pos = is_stereo ? (1 - channel) : channel; /* R hist goes first */ switch(frame_format) { case 1: /* combined hist+index */ hist1 = read_16bitBE(stream->offset + 0x02*channel_pos + 0x00,stream->streamfile) & 0xFFFFFF80; step_index = (uint8_t)read_8bit(stream->offset + 0x02*channel_pos + 0x01,stream->streamfile) & 0x7f; break; case 3: /* separate hist+index */ hist1 = read_16bitBE(stream->offset + 0x03*channel_pos + 0x00,stream->streamfile); step_index = (uint8_t)read_8bit(stream->offset + 0x03*channel_pos + 0x02,stream->streamfile); break; case 2: /* no hist/index (continues from previous frame) */ default: break; } /* write header sample (last nibble is skipped) */ if (frame_format == 1 || frame_format == 3) { outbuf[samples_done * channelspacing] = (short)hist1; samples_done++; samples_to_do--; } /* clamp corrupted data just in case */ if (step_index < 0) step_index = 0; if (step_index > 88) step_index = 88; } else { /* offset adjust for header sample */ if (frame_format == 1 || frame_format == 3) { first_sample--; } } /* offset adjust */ switch(frame_format) { case 1: header_size = (channelspacing*0x02); break; case 3: header_size = (channelspacing*0x03); break; default: header_size = 0; break; } /* decode block nibbles */ for (i = first_sample; i < first_sample + samples_to_do; i++) { off_t byte_offset = is_stereo ? stream->offset + header_size + i : /* stereo: one nibble per channel */ stream->offset + header_size + i/2; /* mono: consecutive nibbles */ int nibble_shift = is_stereo ? (!(channel&1) ? 0:4) : /* stereo: L=low, R=high */ (!(i&1) ? 0:4); /* mono: low first */ std_ima_expand_nibble(stream, byte_offset,nibble_shift, &hist1, &step_index); outbuf[samples_done * channelspacing] = (short)(hist1); samples_done++; } stream->adpcm_history1_32 = hist1; stream->adpcm_step_index = step_index; } /* test... */ static inline int _clamp_s32(int value, int min, int max) { if (value < min) return min; else if (value > max) return max; else return value; } /* Crystal Dynamics IMA. Original code uses mind-bending intrinsics, so this may not be fully accurate. * Has another table with delta_table MMX combos, and uses header sample (first nibble is always 0). */ void decode_cd_ima(VGMSTREAMCHANNEL* stream, sample_t* outbuf, int channelspacing, int32_t first_sample, int32_t samples_to_do) { uint8_t frame[0x24] = {0}; int i, frames_in, sample_pos = 0, block_samples, frame_size; int32_t hist1 = stream->adpcm_history1_32; int step_index = stream->adpcm_step_index; off_t frame_offset; /* external interleave (fixed size), mono */ frame_size = 0x24; block_samples = (frame_size - 0x4) * 2; frames_in = first_sample / block_samples; first_sample = first_sample % block_samples; frame_offset = stream->offset + frame_size * frames_in; read_streamfile(frame, frame_offset, frame_size, stream->streamfile); /* ignore EOF errors */ /* normal header (hist+step+reserved), mono */ if (first_sample == 0) { hist1 = get_s16le(frame + 0x00); step_index = get_u8(frame + 0x02); step_index = _clamp_s32(step_index, 0, 88); /* write header sample (even samples per block, skips first nibble) */ outbuf[sample_pos] = (short)(hist1); sample_pos += channelspacing; first_sample += 1; samples_to_do -= 1; } /* decode nibbles (layout: straight in mono) */ for (i = first_sample; i < first_sample + samples_to_do; i++) { int pos = 0x04 + (i/2); int shift = (i&1 ? 4:0); /* low first, but first low nibble is skipped */ cd_ima_expand_nibble(frame[pos], shift, &hist1, &step_index); outbuf[sample_pos] = (short)(hist1); sample_pos += channelspacing; } stream->adpcm_history1_32 = hist1; stream->adpcm_step_index = step_index; } /* ************************************************************* */ size_t ima_bytes_to_samples(size_t bytes, int channels) { if (channels <= 0) return 0; /* 2 samples per byte (2 nibbles) in stereo or mono config */ return bytes * 2 / channels; } size_t ms_ima_bytes_to_samples(size_t bytes, int block_align, int channels) { if (block_align <= 0 || channels <= 0) return 0; /* MS-IMA blocks have a 4 byte header per channel; 2 samples per byte (2 nibbles) */ return (bytes / block_align) * ((block_align - 0x04*channels) * 2 / channels + 1) + ((bytes % block_align) ? (((bytes % block_align) - 0x04*channels) * 2 / channels + 1) : 0); } size_t xbox_ima_bytes_to_samples(size_t bytes, int channels) { int mod; int block_align = 0x24 * channels; if (channels <= 0) return 0; mod = bytes % block_align; /* XBOX IMA blocks have a 4 byte header per channel; 2 samples per byte (2 nibbles) */ return (bytes / block_align) * (block_align - 4 * channels) * 2 / channels + ((mod > 0 && mod > 0x04*channels) ? (mod - 0x04*channels) * 2 / channels : 0); /* unlikely (encoder aligns) */ } size_t dat4_ima_bytes_to_samples(size_t bytes, int channels) { int block_align = 0x20 * channels; if (channels <= 0) return 0; /* DAT4 IMA blocks have a 4 byte header per channel; 2 samples per byte (2 nibbles) */ return (bytes / block_align) * (block_align - 4 * channels) * 2 / channels + ((bytes % block_align) ? ((bytes % block_align) - 4 * channels) * 2 / channels : 0); /* unlikely (encoder aligns) */ } size_t apple_ima4_bytes_to_samples(size_t bytes, int channels) { int block_align = 0x22 * channels; if (channels <= 0) return 0; return (bytes / block_align) * (block_align - 0x02*channels) * 2 / channels + ((bytes % block_align) ? ((bytes % block_align) - 0x02*channels) * 2 / channels : 0); } /* test XBOX-ADPCM frames for correctness */ int xbox_check_format(STREAMFILE* sf, uint32_t offset, uint32_t max, int channels) { off_t max_offset = offset + max; int ch; if (max_offset > get_streamfile_size(sf)) max_offset = get_streamfile_size(sf); if (!channels) return 0; while (offset < max_offset) { for (ch = 0; ch < channels; ch++) { uint16_t step = read_u16le(offset + 0x04 * ch + 0x02,sf); if (step > 88) return 0; } offset += 0x24 * channels; } return 1; }