/* Copyright (C) 2014 Paul Brossier This file is part of aubio. aubio is free software: you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation, either version 3 of the License, or (at your option) any later version. aubio is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with aubio. If not, see . */ #include "aubio_priv.h" #ifdef HAVE_WAVREAD #include "fvec.h" #include "fmat.h" #include "source_wavread.h" #include #define AUBIO_WAVREAD_BUFSIZE 1024 #define SHORT_TO_FLOAT(x) (smpl_t)(x * 3.0517578125e-05) struct _aubio_source_wavread_t { uint_t hop_size; uint_t samplerate; uint_t channels; // some data about the file char_t *path; uint_t input_samplerate; uint_t input_channels; // internal stuff FILE *fid; uint_t read_samples; uint_t blockalign; uint_t bitspersample; uint_t read_index; uint_t eof; uint_t duration; size_t seek_start; unsigned char *short_output; fmat_t *output; }; static unsigned int read_little_endian (unsigned char *buf, unsigned int length); static unsigned int read_little_endian (unsigned char *buf, unsigned int length) { uint_t i, ret = 0; for (i = 0; i < length; i++) { ret += buf[i] << (i * 8); } return ret; } aubio_source_wavread_t * new_aubio_source_wavread(const char_t * path, uint_t samplerate, uint_t hop_size) { aubio_source_wavread_t * s = AUBIO_NEW(aubio_source_wavread_t); size_t bytes_read = 0, bytes_junk = 0, bytes_expected = 44; unsigned char buf[5] = "\0"; unsigned int format, channels, sr, byterate, blockalign, duration, bitspersample;//, data_size; if (path == NULL) { AUBIO_ERR("source_wavread: Aborted opening null path\n"); goto beach; } if ((sint_t)samplerate < 0) { AUBIO_ERR("source_wavread: Can not open %s with samplerate %d\n", path, samplerate); goto beach; } if ((sint_t)hop_size <= 0) { AUBIO_ERR("source_wavread: Can not open %s with hop_size %d\n", path, hop_size); goto beach; } if (s->path) AUBIO_FREE(s->path); s->path = AUBIO_ARRAY(char_t, strnlen(path, PATH_MAX) + 1); strncpy(s->path, path, strnlen(path, PATH_MAX) + 1); s->samplerate = samplerate; s->hop_size = hop_size; s->fid = fopen((const char *)path, "rb"); if (!s->fid) { AUBIO_ERR("source_wavread: Failed opening %s (System error: %s)\n", s->path, strerror(errno)); goto beach; } // ChunkID bytes_read += fread(buf, 1, 4, s->fid); buf[4] = '\0'; if ( strcmp((const char *)buf, "RIFF") != 0 ) { AUBIO_ERR("source_wavread: Failed opening %s (could not find RIFF header)\n", s->path); goto beach; } // ChunkSize bytes_read += fread(buf, 1, 4, s->fid); // Format bytes_read += fread(buf, 1, 4, s->fid); buf[4] = '\0'; if ( strcmp((const char *)buf, "WAVE") != 0 ) { AUBIO_ERR("source_wavread: Failed opening %s (wrong format in RIFF header)\n", s->path); goto beach; } // Subchunk1ID bytes_read += fread(buf, 1, 4, s->fid); buf[4] = '\0'; // check if we have a JUNK Chunk if ( strcmp((const char *)buf, "JUNK") == 0 ) { bytes_junk = fread(buf, 1, 4, s->fid); buf[4] = '\0'; bytes_junk += read_little_endian(buf, 4); if (fseek(s->fid, bytes_read + bytes_junk, SEEK_SET) != 0) { AUBIO_ERR("source_wavread: Failed opening %s (could not seek past JUNK Chunk: %s)\n", s->path, strerror(errno)); goto beach; } bytes_read += bytes_junk; bytes_expected += bytes_junk + 4; // now really read the fmt chunk bytes_read += fread(buf, 1, 4, s->fid); buf[4] = '\0'; } // get the fmt chunk if ( strcmp((const char *)buf, "fmt ") != 0 ) { AUBIO_ERR("source_wavread: Failed opening %s (could not find 'fmt ' in RIFF header)\n", s->path); goto beach; } // Subchunk1Size bytes_read += fread(buf, 1, 4, s->fid); format = read_little_endian(buf, 4); if ( format != 16 ) { // TODO accept format 18 AUBIO_ERR("source_wavread: Failed opening %s (not encoded with PCM)\n", s->path); goto beach; } if ( buf[1] || buf[2] | buf[3] ) { AUBIO_ERR("source_wavread: Failed opening %s (Subchunk1Size should be 0)\n", s->path); goto beach; } // AudioFormat bytes_read += fread(buf, 1, 2, s->fid); if ( buf[0] != 1 || buf[1] != 0) { AUBIO_ERR("source_wavread: Failed opening %s (AudioFormat should be PCM)\n", s->path); goto beach; } // NumChannels bytes_read += fread(buf, 1, 2, s->fid); channels = read_little_endian(buf, 2); // SampleRate bytes_read += fread(buf, 1, 4, s->fid); sr = read_little_endian(buf, 4); // ByteRate bytes_read += fread(buf, 1, 4, s->fid); byterate = read_little_endian(buf, 4); // BlockAlign bytes_read += fread(buf, 1, 2, s->fid); blockalign = read_little_endian(buf, 2); // BitsPerSample bytes_read += fread(buf, 1, 2, s->fid); bitspersample = read_little_endian(buf, 2); #if 0 if ( bitspersample != 16 ) { AUBIO_ERR("source_wavread: can not process %dbit file %s\n", bitspersample, s->path); goto beach; } #endif if ( byterate * 8 != sr * channels * bitspersample ) { AUBIO_ERR("source_wavread: Failed opening %s (wrong byterate)\n", s->path); goto beach; } if ( blockalign * 8 != channels * bitspersample ) { AUBIO_ERR("source_wavread: Failed opening %s (wrong blockalign)\n", s->path); goto beach; } s->input_samplerate = sr; s->input_channels = channels; #if 0 AUBIO_DBG("channels %d\n", channels); AUBIO_DBG("sr %d\n", sr); AUBIO_DBG("byterate %d\n", byterate); AUBIO_DBG("blockalign %d\n", blockalign); AUBIO_DBG("bitspersample %d\n", bitspersample); AUBIO_DBG("found %d channels in %s\n", s->input_channels, s->path); AUBIO_DBG("found %d samplerate in %s\n", s->input_samplerate, s->path); #endif if (samplerate == 0) { s->samplerate = s->input_samplerate; } else if (samplerate != s->input_samplerate) { AUBIO_ERR("source_wavread: can not resample %s from %d to %dHz\n", s->path, s->input_samplerate, samplerate); goto beach; } // Subchunk2ID bytes_read += fread(buf, 1, 4, s->fid); buf[4] = '\0'; while ( strcmp((const char *)buf, "data") != 0 ) { if (feof(s->fid) || ferror(s->fid)) { AUBIO_ERR("source_wavread: no data RIFF header found in %s\n", s->path); goto beach; } bytes_junk = fread(buf, 1, 4, s->fid); buf[4] = '\0'; bytes_junk += read_little_endian(buf, 4); if (fseek(s->fid, bytes_read + bytes_junk, SEEK_SET) != 0) { AUBIO_ERR("source_wavread: could not seek past unknown chunk in %s (%s)\n", s->path, strerror(errno)); goto beach; } bytes_read += bytes_junk; bytes_expected += bytes_junk+ 4; bytes_read += fread(buf, 1, 4, s->fid); buf[4] = '\0'; } // Subchunk2Size bytes_read += fread(buf, 1, 4, s->fid); duration = read_little_endian(buf, 4) / blockalign; //data_size = buf[0] + (buf[1] << 8) + (buf[2] << 16) + (buf[3] << 24); //AUBIO_MSG("found %d frames in %s\n", 8 * data_size / bitspersample / channels, s->path); // check the total number of bytes read is correct if ( bytes_read != bytes_expected ) { #ifndef HAVE_WIN_HACKS AUBIO_ERR("source_wavread: short read (%zd instead of %zd) in %s\n", bytes_read, bytes_expected, s->path); #else // mingw does not know about %zd... AUBIO_ERR("source_wavread: short read (%d instead of %d) in %s\n", (int)bytes_read, (int)bytes_expected, s->path); #endif goto beach; } s->seek_start = bytes_read; s->output = new_fmat(s->input_channels, AUBIO_WAVREAD_BUFSIZE); s->blockalign= blockalign; s->bitspersample = bitspersample; s->duration = duration; s->short_output = (unsigned char *)calloc(s->blockalign, AUBIO_WAVREAD_BUFSIZE); s->read_index = 0; s->read_samples = 0; s->eof = 0; return s; beach: //AUBIO_ERR("source_wavread: can not read %s at samplerate %dHz with a hop_size of %d\n", // s->path, s->samplerate, s->hop_size); del_aubio_source_wavread(s); return NULL; } void aubio_source_wavread_readframe(aubio_source_wavread_t *s, uint_t *wavread_read); void aubio_source_wavread_readframe(aubio_source_wavread_t *s, uint_t *wavread_read) { unsigned char *short_ptr = s->short_output; size_t read = fread(short_ptr, s->blockalign, AUBIO_WAVREAD_BUFSIZE, s->fid); uint_t i, j, b, bitspersample = s->bitspersample; uint_t wrap_at = (1 << ( bitspersample - 1 ) ); uint_t wrap_with = (1 << bitspersample); smpl_t scaler = 1. / wrap_at; int signed_val = 0; unsigned int unsigned_val = 0; for (j = 0; j < read; j++) { for (i = 0; i < s->input_channels; i++) { unsigned_val = 0; for (b = 0; b < bitspersample; b+=8 ) { unsigned_val += *(short_ptr) << b; short_ptr++; } signed_val = unsigned_val; // FIXME why does 8 bit conversion maps [0;255] to [-128;127] // instead of [0;127] to [0;127] and [128;255] to [-128;-1] if (bitspersample == 8) signed_val -= wrap_at; else if (unsigned_val >= wrap_at) signed_val = unsigned_val - wrap_with; s->output->data[i][j] = signed_val * scaler; } } *wavread_read = read; if (read == 0) s->eof = 1; } void aubio_source_wavread_do(aubio_source_wavread_t * s, fvec_t * read_data, uint_t * read){ uint_t i, j; uint_t end = 0; uint_t total_wrote = 0; while (total_wrote < s->hop_size) { end = MIN(s->read_samples - s->read_index, s->hop_size - total_wrote); for (i = 0; i < end; i++) { read_data->data[i + total_wrote] = 0; for (j = 0; j < s->input_channels; j++ ) { read_data->data[i + total_wrote] += s->output->data[j][i + s->read_index]; } read_data->data[i + total_wrote] /= (smpl_t)(s->input_channels); } total_wrote += end; if (total_wrote < s->hop_size) { uint_t wavread_read = 0; aubio_source_wavread_readframe(s, &wavread_read); s->read_samples = wavread_read; s->read_index = 0; if (s->eof) { break; } } else { s->read_index += end; } } if (total_wrote < s->hop_size) { for (i = end; i < s->hop_size; i++) { read_data->data[i] = 0.; } } *read = total_wrote; } void aubio_source_wavread_do_multi(aubio_source_wavread_t * s, fmat_t * read_data, uint_t * read){ uint_t i,j; uint_t end = 0; uint_t total_wrote = 0; while (total_wrote < s->hop_size) { end = MIN(s->read_samples - s->read_index, s->hop_size - total_wrote); for (j = 0; j < read_data->height; j++) { for (i = 0; i < end; i++) { read_data->data[j][i + total_wrote] = s->output->data[j][i]; } } total_wrote += end; if (total_wrote < s->hop_size) { uint_t wavread_read = 0; aubio_source_wavread_readframe(s, &wavread_read); s->read_samples = wavread_read; s->read_index = 0; if (s->eof) { break; } } else { s->read_index += end; } } if (total_wrote < s->hop_size) { for (j = 0; j < read_data->height; j++) { for (i = end; i < s->hop_size; i++) { read_data->data[j][i] = 0.; } } } *read = total_wrote; } uint_t aubio_source_wavread_get_samplerate(aubio_source_wavread_t * s) { return s->samplerate; } uint_t aubio_source_wavread_get_channels(aubio_source_wavread_t * s) { return s->input_channels; } uint_t aubio_source_wavread_seek (aubio_source_wavread_t * s, uint_t pos) { uint_t ret = 0; if ((sint_t)pos < 0) { return AUBIO_FAIL; } ret = fseek(s->fid, s->seek_start + pos * s->blockalign, SEEK_SET); if (ret != 0) { AUBIO_ERR("source_wavread: could not seek %s at %d (%s)\n", s->path, pos, strerror(errno)); return AUBIO_FAIL; } // reset some values s->eof = 0; s->read_index = 0; return AUBIO_OK; } uint_t aubio_source_wavread_get_duration (const aubio_source_wavread_t * s) { if (s && s->duration) { return s->duration; } return 0; } uint_t aubio_source_wavread_close (aubio_source_wavread_t * s) { if (!s->fid) { return AUBIO_FAIL; } if (fclose(s->fid)) { AUBIO_ERR("source_wavread: could not close %s (%s)\n", s->path, strerror(errno)); return AUBIO_FAIL; } s->fid = NULL; return AUBIO_OK; } void del_aubio_source_wavread(aubio_source_wavread_t * s) { if (!s) return; aubio_source_wavread_close(s); if (s->short_output) AUBIO_FREE(s->short_output); if (s->output) del_fmat(s->output); if (s->path) AUBIO_FREE(s->path); AUBIO_FREE(s); } #endif /* HAVE_WAVREAD */