/* * Copyright (C) 2023 Adrien Gesta-Fline * * This file is part of libAAF. * * This program 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 2 of the License, or * (at your option) any later version. * * This program 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 this program; if not, write to the Free Software Foundation, Inc., * 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA. */ #include #include #include #include #include #include "aaf/RIFFParser.h" #define debug(...) \ _dbg (dbg, NULL, DEBUG_SRC_ID_AAF_IFACE, VERB_DEBUG, __VA_ARGS__) #define warning(...) \ _dbg (dbg, NULL, DEBUG_SRC_ID_AAF_IFACE, VERB_WARNING, __VA_ARGS__) #define error(...) \ _dbg (dbg, NULL, DEBUG_SRC_ID_AAF_IFACE, VERB_ERROR, __VA_ARGS__) #define BE2LE32(val) \ (((val >> 24) & 0xff) | ((val << 8) & 0xff0000) | ((val >> 8) & 0xff00) | ((val << 24) & 0xff000000)) #define BE2LE16(val) \ ((val << 8) | (val >> 8)) static uint32_t beExtended2leUint32 (const unsigned char numx[10]); int riff_writeWavFileHeader (FILE* fp, struct wavFmtChunk* wavFmt, struct wavBextChunk* wavBext, uint32_t audioDataSize, struct dbg* dbg) { (void)dbg; uint32_t filesize = (4 /* WAVE */) + sizeof (struct wavFmtChunk) + ((wavBext) ? sizeof (struct wavBextChunk) : 0) + (8 /*data chunk header*/) + audioDataSize; size_t writtenBytes = fwrite ("RIFF", sizeof (unsigned char), 4, fp); if (writtenBytes < 4) { return -1; } writtenBytes = fwrite (&filesize, sizeof (uint32_t), 1, fp); if (writtenBytes < 1) { return -1; } writtenBytes = fwrite ("WAVE", sizeof (unsigned char), 4, fp); if (writtenBytes < 4) { return -1; } wavFmt->ckid[0] = 'f'; wavFmt->ckid[1] = 'm'; wavFmt->ckid[2] = 't'; wavFmt->ckid[3] = ' '; wavFmt->cksz = sizeof (struct wavFmtChunk) - sizeof (struct riffChunk); wavFmt->format_tag = 1; /* PCM */ wavFmt->avg_bytes_per_sec = wavFmt->samples_per_sec * wavFmt->channels * wavFmt->bits_per_sample / 8; wavFmt->block_align = wavFmt->channels * wavFmt->bits_per_sample / 8; writtenBytes = fwrite ((unsigned char*)wavFmt, sizeof (unsigned char), sizeof (struct wavFmtChunk), fp); if (writtenBytes < sizeof (struct wavFmtChunk)) { return -1; } if (wavBext) { wavBext->ckid[0] = 'b'; wavBext->ckid[1] = 'e'; wavBext->ckid[2] = 'x'; wavBext->ckid[3] = 't'; wavBext->cksz = sizeof (struct wavBextChunk) - sizeof (struct riffChunk); wavBext->version = 1; writtenBytes = fwrite ((unsigned char*)wavBext, sizeof (unsigned char), sizeof (struct wavBextChunk), fp); if (writtenBytes < sizeof (struct wavBextChunk)) { return -1; } } writtenBytes = fwrite ("data", sizeof (unsigned char), 4, fp); if (writtenBytes < 4) { return -1; } writtenBytes = fwrite (&audioDataSize, sizeof (uint32_t), 1, fp); if (writtenBytes < 1) { return -1; } return 0; } int riff_parseAudioFile (struct RIFFAudioFile* RIFFAudioFile, enum RIFF_PARSER_FLAGS flags, size_t (*readerCallback) (unsigned char*, size_t, size_t, void*, void*, void*), void* user1, void* user2, void* user3, struct dbg* dbg) { struct riffChunk chunk; struct riffHeaderChunk riff; memset (RIFFAudioFile, 0x00, sizeof (struct RIFFAudioFile)); size_t bytesRead = readerCallback ((unsigned char*)&riff, 0, sizeof (riff), user1, user2, user3); if (bytesRead < sizeof (riff)) { error ("Could not read file header"); return -1; } int be = 0; /* big endian */ if (riff.format[0] == 'A' && riff.format[1] == 'I' && riff.format[2] == 'F' && riff.format[3] == 'F') { be = 1; riff.cksz = BE2LE32 (riff.cksz); } else if (riff.format[0] == 'A' && riff.format[1] == 'I' && riff.format[2] == 'F' && riff.format[3] == 'C') { be = 1; riff.cksz = BE2LE32 (riff.cksz); } else if (riff.format[0] == 'W' && riff.format[1] == 'A' && riff.format[2] == 'V' && riff.format[3] == 'E') { be = 0; } else { error ("File is not a valid RIFF/WAVE or RIFF/AIFF : Missing format identifier"); return -1; } size_t filesize = riff.cksz + sizeof (chunk); size_t pos = sizeof (struct riffHeaderChunk); while (pos < filesize) { bytesRead = readerCallback ((unsigned char*)&chunk, pos, sizeof (chunk), user1, user2, user3); if (bytesRead < sizeof (chunk)) { error ("Could not read chunk \"%.4s\" @ %" PRIu64 " (%" PRIu64 " bytes returned)", chunk.ckid, pos, bytesRead); break; } if (be) { chunk.cksz = BE2LE32 (chunk.cksz); } debug ("Got chunk \"%.4s\" (%u bytes) @ %" PRIu64 " (%" PRIu64 " bytes returned)", chunk.ckid, chunk.cksz, pos, bytesRead); if (!be) { /* WAVE */ if (chunk.ckid[0] == 'f' && chunk.ckid[1] == 'm' && chunk.ckid[2] == 't' && chunk.ckid[3] == ' ') { struct wavFmtChunk wavFmtChunk; bytesRead = readerCallback ((unsigned char*)&wavFmtChunk, pos, sizeof (wavFmtChunk), user1, user2, user3); if (bytesRead < sizeof (wavFmtChunk)) { error ("Could not read chunk \"%.4s\" content @ %" PRIu64 " (%" PRIu64 " bytes returned)", chunk.ckid, pos, bytesRead); break; } RIFFAudioFile->channels = wavFmtChunk.channels; RIFFAudioFile->sampleSize = wavFmtChunk.bits_per_sample; RIFFAudioFile->sampleRate = wavFmtChunk.samples_per_sec; if (flags & RIFF_PARSE_ONLY_HEADER) { return 0; } } else if (chunk.ckid[0] == 'd' && chunk.ckid[1] == 'a' && chunk.ckid[2] == 't' && chunk.ckid[3] == 'a') { if (RIFFAudioFile->channels > 0 && RIFFAudioFile->sampleSize > 0) { RIFFAudioFile->sampleCount = chunk.cksz / RIFFAudioFile->channels / (RIFFAudioFile->sampleSize / 8); } if (flags & RIFF_PARSE_AAF_SUMMARY) { return 0; } } } else { /* AIFF */ if (chunk.ckid[0] == 'C' && chunk.ckid[1] == 'O' && chunk.ckid[2] == 'M' && chunk.ckid[3] == 'M') { struct aiffCOMMChunk aiffCOMMChunk; bytesRead = readerCallback ((unsigned char*)&aiffCOMMChunk, pos, sizeof (aiffCOMMChunk), user1, user2, user3); if (bytesRead < sizeof (aiffCOMMChunk)) { error ("Could not read chunk \"%.4s\" content @ %" PRIu64 " (%" PRIu64 " bytes returned)", chunk.ckid, pos, bytesRead); break; } RIFFAudioFile->channels = BE2LE16 (aiffCOMMChunk.numChannels); RIFFAudioFile->sampleSize = BE2LE16 (aiffCOMMChunk.sampleSize); RIFFAudioFile->sampleRate = beExtended2leUint32 (aiffCOMMChunk.sampleRate); RIFFAudioFile->sampleCount = BE2LE32 (aiffCOMMChunk.numSampleFrames); if (flags & RIFF_PARSE_ONLY_HEADER) { return 0; } } else if (chunk.ckid[0] == 'S' && chunk.ckid[1] == 'S' && chunk.ckid[2] == 'N' && chunk.ckid[3] == 'D') { /* * Samplecount should be already set with numSampleFrames in COMM chunk. * However in AAF (AIFCDescriptor::Summary), numSampleFrames is often null, * so we must extract samplecount out of SSND chunk, like we do with wav DATA chunk. */ uint64_t sampleCount = chunk.cksz / RIFFAudioFile->channels / (RIFFAudioFile->sampleSize / 8); if (RIFFAudioFile->sampleCount > 0 && RIFFAudioFile->sampleCount != sampleCount) { debug ("Sample count retrieved from COMM chunk (%" PRIu64 ") does not match SSND chunk (%" PRIu64 ")", RIFFAudioFile->sampleCount, sampleCount); } RIFFAudioFile->sampleCount = sampleCount; if (flags & RIFF_PARSE_AAF_SUMMARY) { return 0; } } } pos += chunk.cksz + sizeof (chunk); } return 0; } static uint32_t beExtended2leUint32 (const unsigned char numx[10]) { /* * https://stackoverflow.com/a/18854415/16400184 */ unsigned char x[10]; /* be -> le */ x[0] = numx[9]; x[1] = numx[8]; x[2] = numx[7]; x[3] = numx[6]; x[4] = numx[5]; x[5] = numx[4]; x[6] = numx[3]; x[7] = numx[2]; x[8] = numx[1]; x[9] = numx[0]; int exponent = (((x[9] << 8) | x[8]) & 0x7FFF); uint64_t mantissa = ((uint64_t)x[7] << 56) | ((uint64_t)x[6] << 48) | ((uint64_t)x[5] << 40) | ((uint64_t)x[4] << 32) | ((uint64_t)x[3] << 24) | ((uint64_t)x[2] << 16) | ((uint64_t)x[1] << 8) | (uint64_t)x[0]; unsigned char d[8] = { 0 }; double result; d[7] = x[9] & 0x80; /* Set sign. */ if ((exponent == 0x7FFF) || (exponent == 0)) { /* Infinite, NaN or denormal */ if (exponent == 0x7FFF) { /* Infinite or NaN */ d[7] |= 0x7F; d[6] = 0xF0; } else { /* Otherwise it's denormal. It cannot be represented as double. Translate as singed zero. */ memcpy (&result, d, 8); return result; } } else { /* Normal number. */ exponent = exponent - 0x3FFF + 0x03FF; /*< exponent for double precision. */ if (exponent <= -52) { /*< Too small to represent. Translate as (signed) zero. */ memcpy (&result, d, 8); return result; } else if (exponent < 0) { /* Denormal, exponent bits are already zero here. */ } else if (exponent >= 0x7FF) { /*< Too large to represent. Translate as infinite. */ d[7] |= 0x7F; d[6] = 0xF0; memset (d, 0x00, 6); memcpy (&result, d, 8); return result; } else { /* Representable number */ d[7] |= (exponent & 0x7F0) >> 4; d[6] |= (exponent & 0xF) << 4; } } /* Translate mantissa. */ mantissa >>= 11; if (exponent < 0) { /* Denormal, further shifting is required here. */ mantissa >>= (-exponent + 1); } d[0] = mantissa & 0xFF; d[1] = (mantissa >> 8) & 0xFF; d[2] = (mantissa >> 16) & 0xFF; d[3] = (mantissa >> 24) & 0xFF; d[4] = (mantissa >> 32) & 0xFF; d[5] = (mantissa >> 40) & 0xFF; d[6] |= (mantissa >> 48) & 0x0F; memcpy (&result, d, 8); return (uint32_t)result; }