#include "qtprivate.h" #include "quicktime.h" #include "funcprotos.h" #include "wmx2.h" typedef struct { /* During decoding the work_buffer contains the most recently read chunk. */ /* During encoding the work_buffer contains interlaced overflow samples */ /* from the last chunk written. */ int16_t *write_buffer; unsigned char *read_buffer; /* Temporary buffer for drive reads. */ /* Starting information for all channels during encoding a chunk. */ int *last_samples, *last_indexes; long chunk; /* Number of chunk in work buffer */ int buffer_channel; /* Channel of work buffer */ /* Number of samples in largest chunk read. */ /* Number of samples plus overflow in largest chunk write, interlaced. */ long write_size; /* Size of write buffer. */ long read_size; /* Size of read buffer. */ } quicktime_wmx2_codec_t; static int quicktime_wmx2_step[89] = { 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 }; static int quicktime_wmx2_index[16] = { -1, -1, -1, -1, 2, 4, 6, 8, -1, -1, -1, -1, 2, 4, 6, 8 }; /* ================================== private for wmx2 */ #define HEADER_SIZE 3 static int wmx2_decode_sample(int *predictor, int *nibble, int *index, int *step) { int difference, sign; /* Get new index value */ *index += quicktime_wmx2_index[*nibble]; if(*index < 0) *index = 0; else if(*index > 88) *index = 88; /* Get sign and magnitude from *nibble */ sign = *nibble & 8; *nibble = *nibble & 7; /* Get difference */ difference = *step >> 3; if(*nibble & 4) difference += *step; if(*nibble & 2) difference += *step >> 1; if(*nibble & 1) difference += *step >> 2; /* Predict value */ if(sign) *predictor -= difference; else *predictor += difference; if(*predictor > 32767) *predictor = 32767; else if(*predictor < -32768) *predictor = -32768; /* Update the step value */ *step = quicktime_wmx2_step[*index]; return 0; } static int wmx2_decode_block(quicktime_audio_map_t *atrack, int16_t *output, unsigned char *input, int samples) { int predictor, index, step; int nibble, nibble_count; int16_t *output_end = output + samples; /* Get the chunk header */ predictor = *input++ << 8; predictor |= *input++; if(predictor & 0x8000) predictor -= 0x10000; index = *input++; if(index > 88) index = 88; /*printf("input %d %d\n", predictor, index); */ step = quicktime_wmx2_step[index]; /* Read the input buffer sequentially, one nibble at a time */ nibble_count = 0; while(output < output_end) { nibble = nibble_count ? (*input++ >> 4) & 0x0f : *input & 0x0f; wmx2_decode_sample(&predictor, &nibble, &index, &step); *output++ = predictor; nibble_count ^= 1; } return 0; } static int wmx2_encode_sample(int *last_sample, int *last_index, int *nibble, int next_sample) { int difference, new_difference, mask, step; difference = next_sample - *last_sample; *nibble = 0; step = quicktime_wmx2_step[*last_index]; new_difference = step >> 3; if(difference < 0) { *nibble = 8; difference = -difference; } mask = 4; while(mask) { if(difference >= step) { *nibble |= mask; difference -= step; new_difference += step; } step >>= 1; mask >>= 1; } if(*nibble & 8) *last_sample -= new_difference; else *last_sample += new_difference; if(*last_sample > 32767) *last_sample = 32767; else if(*last_sample < -32767) *last_sample = -32767; *last_index += quicktime_wmx2_index[*nibble]; if(*last_index < 0) *last_index = 0; else if(*last_index > 88) *last_index= 88; return 0; } static int wmx2_encode_block(quicktime_audio_map_t *atrack, unsigned char *output, int16_t *input, int step, int channel, int samples) { quicktime_wmx2_codec_t *codec = ((quicktime_codec_t*)atrack->codec)->priv; int i, nibble_count = 0, nibble, header; /* Get a fake starting sample */ header = codec->last_samples[channel]; /*printf("output %d %d\n", header, codec->last_indexes[channel]); */ /* Force rounding. */ /* if(header < 0x7fc0) header += 0x40; */ /* header &= 0xff80; */ if(header < 0) header += 0x10000; *output++ = (header & 0xff00) >> 8; *output++ = (header & 0xff); *output++ = (codec->last_indexes[channel] & 0x7f); for(i = 0; i < samples; i++) { wmx2_encode_sample(&(codec->last_samples[channel]), &(codec->last_indexes[channel]), &nibble, *input); if(nibble_count) *output++ |= (nibble << 4); else *output = nibble; input += step; nibble_count ^= 1; } return 0; } /* Convert the number of samples in a chunk into the number of bytes in that */ /* chunk. The number of samples in a chunk should end on a block boundary. */ static long wmx2_samples_to_bytes(long samples, int channels) { long bytes = samples / 2; if(bytes * 2 < samples) bytes++; bytes *= channels; bytes += HEADER_SIZE * channels; return bytes; } /* Decode the chunk into the work buffer */ static int wmx2_decode_chunk(quicktime_t *file, int track, long chunk, int channel) { int j, result; long chunk_samples, chunk_bytes; unsigned char *block_ptr; quicktime_trak_t *trak = file->atracks[track].track; quicktime_wmx2_codec_t *codec = ((quicktime_codec_t*)file->atracks[track].codec)->priv; /* Get the byte count to read. */ chunk_samples = quicktime_chunk_samples(trak, chunk); chunk_bytes = wmx2_samples_to_bytes(chunk_samples, file->atracks[track].channels); /* Get the buffer to read into. */ if(codec->write_buffer && codec->write_size < chunk_samples) { free(codec->write_buffer); codec->write_buffer = 0; } if(!codec->write_buffer) { codec->write_size = chunk_samples; codec->write_buffer = malloc(sizeof(int16_t) * codec->write_size); } if(codec->read_buffer && codec->read_size < chunk_bytes) { free(codec->read_buffer); codec->read_buffer = 0; } if(!codec->read_buffer) { codec->read_size = chunk_bytes; codec->read_buffer = malloc(codec->read_size); } /* codec->work_size now holds the number of samples in the last chunk */ /* codec->read_size now holds number of bytes in the last read buffer */ /* Read the entire chunk regardless of where the desired sample range starts. */ result = quicktime_read_chunk(file, (char*)codec->read_buffer, track, chunk, 0, chunk_bytes); /* Now decode the chunk, one block at a time, until the total samples in the chunk */ /* is reached. */ if(!result) { block_ptr = codec->read_buffer; for(j = 0; j < file->atracks[track].channels; j++) { if(j == channel) wmx2_decode_block(&(file->atracks[track]), codec->write_buffer, block_ptr, chunk_samples); block_ptr += chunk_bytes / file->atracks[track].channels; } } codec->buffer_channel = channel; codec->chunk = chunk; return result; } /* =================================== public for wmx2 */ static int decode(quicktime_t *file, int16_t *output_i, float *output_f, long samples, int track, int channel) { int result = 0; long chunk, chunk_sample, chunk_samples; long i, chunk_start, chunk_end; quicktime_trak_t *trak = file->atracks[track].track; quicktime_wmx2_codec_t *codec = ((quicktime_codec_t*)file->atracks[track].codec)->priv; /* Get the first chunk with this routine and then increase the chunk number. */ quicktime_chunk_of_sample(&chunk_sample, &chunk, trak, file->atracks[track].current_position); /* Read chunks until the output is full. */ for(i = 0; i < samples && !result; ) { /* Get chunk we're on. */ chunk_samples = quicktime_chunk_samples(trak, chunk); if(!codec->write_buffer || codec->chunk != chunk || codec->buffer_channel != channel) { /* read a new chunk if necessary */ result = wmx2_decode_chunk(file, track, chunk, channel); } /* Get boundaries from the chunk */ chunk_start = 0; if(chunk_sample < file->atracks[track].current_position) chunk_start = file->atracks[track].current_position - chunk_sample; chunk_end = chunk_samples; if(chunk_sample + chunk_end > file->atracks[track].current_position + samples) chunk_end = file->atracks[track].current_position + samples - chunk_sample; /* Read from the chunk */ if(output_i) { while(chunk_start < chunk_end) { output_i[i++] = codec->write_buffer[chunk_start++]; } } else if(output_f) { while(chunk_start < chunk_end) { output_f[i++] = (float)codec->write_buffer[chunk_start++] / 32767; } } chunk++; chunk_sample += chunk_samples; } return result; } static int encode(quicktime_t *file, int16_t **input_i, float **input_f, int track, long samples) { int result = 0; long i, j, step; long chunk_bytes; quicktime_audio_map_t *track_map = &(file->atracks[track]); quicktime_wmx2_codec_t *codec = ((quicktime_codec_t*)track_map->codec)->priv; quicktime_trak_t *trak = track_map->track; int16_t *input_ptr; unsigned char *output_ptr; quicktime_atom_t chunk_atom; /* Get buffer sizes */ if(codec->write_buffer && codec->write_size < samples * track_map->channels) { /* Create new buffer */ long new_size = samples * track_map->channels; int16_t *new_buffer = malloc(sizeof(int16_t) * new_size); /* Swap pointers. */ free(codec->write_buffer); codec->write_buffer = new_buffer; codec->write_size = new_size; } else if(!codec->write_buffer) { /* No buffer in the first place. */ codec->write_size = samples * track_map->channels; codec->write_buffer = malloc(sizeof(int16_t) * codec->write_size); } /* Get output size */ chunk_bytes = wmx2_samples_to_bytes(samples, track_map->channels); if(codec->read_buffer && codec->read_size < chunk_bytes) { free(codec->read_buffer); codec->read_buffer = 0; } if(!codec->read_buffer) { codec->read_buffer = malloc(chunk_bytes); codec->read_size = chunk_bytes; } if(!codec->last_samples) { codec->last_samples = malloc(sizeof(int) * track_map->channels); for(i = 0; i < track_map->channels; i++) { codec->last_samples[i] = 0; } } if(!codec->last_indexes) { codec->last_indexes = malloc(sizeof(int) * track_map->channels); for(i = 0; i < track_map->channels; i++) { codec->last_indexes[i] = 0; } } /* Arm the input buffer */ step = track_map->channels; for(j = 0; j < track_map->channels; j++) { input_ptr = codec->write_buffer + j; if(input_i) { for(i = 0; i < samples; i++) { *input_ptr = input_i[j][i]; input_ptr += step; } } else if(input_f) { for(i = 0; i < samples; i++) { *input_ptr = (int16_t)(input_f[j][i] * 32767); input_ptr += step; } } } /* Encode from the input buffer to the read_buffer. */ input_ptr = codec->write_buffer; output_ptr = codec->read_buffer; for(j = 0; j < track_map->channels; j++) { wmx2_encode_block(track_map, output_ptr, input_ptr + j, track_map->channels, j, samples); output_ptr += chunk_bytes / track_map->channels; } if(samples) { //int offset = quicktime_position(file); quicktime_write_chunk_header(file, trak, &chunk_atom); result = !quicktime_write_data(file, (char*)codec->read_buffer, chunk_bytes); quicktime_write_chunk_footer(file, trak, track_map->current_chunk, &chunk_atom, 1); track_map->current_chunk++; } return result; } static void delete_codec(quicktime_audio_map_t *atrack) { quicktime_wmx2_codec_t *codec = ((quicktime_codec_t*)atrack->codec)->priv; if(codec->write_buffer) free(codec->write_buffer); if(codec->read_buffer) free(codec->read_buffer); if(codec->last_samples) free(codec->last_samples); if(codec->last_indexes) free(codec->last_indexes); codec->last_samples = 0; codec->last_indexes = 0; codec->read_buffer = 0; codec->write_buffer = 0; codec->chunk = 0; codec->buffer_channel = 0; /* Channel of work buffer */ codec->write_size = 0; /* Size of work buffer */ codec->read_size = 0; free(codec); } void quicktime_init_codec_wmx2(quicktime_audio_map_t *atrack) { quicktime_codec_t *codec_base = (quicktime_codec_t*)atrack->codec; /* Init public items */ codec_base->priv = calloc(1, sizeof(quicktime_wmx2_codec_t)); codec_base->delete_acodec = delete_codec; codec_base->decode_video = 0; codec_base->encode_video = 0; codec_base->decode_audio = decode; codec_base->encode_audio = encode; codec_base->fourcc = QUICKTIME_WMX2; codec_base->title = "IMA4 on steroids"; codec_base->desc = "IMA4 on steroids. (Not standardized)"; codec_base->wav_id = 0x11; }