/* -*- c-basic-offset: 4 indent-tabs-mode: nil -*- vi:set ts=8 sts=4 sw=4: */ /* Rosegarden A sequencer and musical notation editor. Copyright 2000-2011 the Rosegarden development team. See the AUTHORS file for more details. 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. See the file COPYING included with this distribution for more information. */ #include "RIFFAudioFile.h" #include "base/RealTime.h" #include "base/Profiler.h" #include "misc/Strings.h" using std::cout; using std::cerr; using std::endl; //#define DEBUG_RIFF namespace Rosegarden { RIFFAudioFile::RIFFAudioFile(unsigned int id, const std::string &name, const QString &fileName): AudioFile(id, name, fileName), m_subFormat(PCM), m_bytesPerSecond(0), m_bytesPerFrame(0) {} RIFFAudioFile::RIFFAudioFile(const QString &fileName, unsigned int channels = 1, unsigned int sampleRate = 48000, unsigned int bytesPerSecond = 6000, unsigned int bytesPerFrame = 2, unsigned int bitsPerSample = 16): AudioFile(0, "", fileName) { m_bitsPerSample = bitsPerSample; m_sampleRate = sampleRate; m_bytesPerSecond = bytesPerSecond; m_bytesPerFrame = bytesPerFrame; m_channels = channels; if (bitsPerSample == 16) m_subFormat = PCM; else if (bitsPerSample == 32) m_subFormat = FLOAT; else throw(BadSoundFileException(m_fileName, qstrtostr(QObject::tr("Rosegarden currently only supports 16 or 32-bit PCM or IEEE floating-point RIFF files for writing")))); } RIFFAudioFile::~RIFFAudioFile() {} // Show some stats on this file // void RIFFAudioFile::printStats() { cout << "filename : " << m_fileName << endl << "channels : " << m_channels << endl << "sample rate : " << m_sampleRate << endl << "bytes per second : " << m_bytesPerSecond << endl << "bits per sample : " << m_bitsPerSample << endl << "bytes per frame : " << m_bytesPerFrame << endl << "file length : " << m_fileSize << " bytes" << endl << endl; } bool RIFFAudioFile::appendSamples(const std::string &buffer) { /* if (m_outFile == 0 || m_type != WAV) return false; */ // write out putBytes(m_outFile, buffer); return true; } bool RIFFAudioFile::appendSamples(const char *buf, unsigned int frames) { putBytes(m_outFile, buf, frames * m_bytesPerFrame); return true; } // scan on from a descriptor position bool RIFFAudioFile::scanForward(std::ifstream *file, const RealTime &time) { // sanity if (file == 0) return false; unsigned int totalSamples = m_sampleRate * time.sec + ( ( m_sampleRate * time.usec() ) / 1000000 ); unsigned int totalBytes = totalSamples * m_bytesPerFrame; m_loseBuffer = true; // do the seek file->seekg(totalBytes, std::ios::cur); if (file->eof()) return false; return true; } bool RIFFAudioFile::scanForward(const RealTime &time) { if (*m_inFile) return scanForward(m_inFile, time); else return false; } bool RIFFAudioFile::scanTo(const RealTime &time) { if (*m_inFile) return scanTo(m_inFile, time); else return false; } bool RIFFAudioFile::scanTo(std::ifstream *file, const RealTime &time) { // sanity if (file == 0) return false; // whatever we do here we invalidate the read buffer // m_loseBuffer = true; file->clear(); // seek past header - don't hardcode this - use the file format // spec to get header length and then scoot to that. // file->seekg(16, std::ios::beg); unsigned int lengthOfFormat = 0; try { lengthOfFormat = getIntegerFromLittleEndian(getBytes(file, 4)); file->seekg(lengthOfFormat, std::ios::cur); // check we've got data chunk start std::string chunkName; int chunkLength = 0; while ((chunkName = getBytes(file, 4)) != "data") { if (file->eof()) { std::cerr << "RIFFAudioFile::scanTo(): failed to find data " << std::endl; return false; } //#ifdef DEBUG_RIFF std::cerr << "RIFFAudioFile::scanTo(): skipping chunk: " << chunkName << std::endl; //#endif chunkLength = getIntegerFromLittleEndian(getBytes(file, 4)); if (chunkLength < 0) { std::cerr << "RIFFAudioFile::scanTo(): negative chunk length " << chunkLength << " for chunk " << chunkName << std::endl; return false; } file->seekg(chunkLength, std::ios::cur); } // get the length of the data chunk, and scan past it as a side-effect chunkLength = getIntegerFromLittleEndian(getBytes(file, 4)); #ifdef DEBUG_RIFF std::cout << "RIFFAudioFile::scanTo() - data chunk size = " << chunkLength << std::endl; #endif } catch (BadSoundFileException s) { #ifdef DEBUG_RIFF std::cerr << "RIFFAudioFile::scanTo - EXCEPTION - \"" << s.getMessage() << "\"" << std::endl; #endif return false; } // Ok, we're past all the header information in the data chunk. // Now, how much do we scan forward? // size_t totalFrames = size_t(RealTime::realTime2Frame(time, m_sampleRate)); unsigned int totalBytes = totalFrames * m_bytesPerFrame; // When using seekg we have to keep an eye on the boundaries ourselves // if (totalBytes > m_fileSize - (lengthOfFormat + 16 + 8)) { #ifdef DEBUG_RIFF std::cerr << "RIFFAudioFile::scanTo() - attempting to move past end of " << "data block" << std::endl; #endif return false; } #ifdef DEBUG_RIFF std::cout << "RIFFAudioFile::scanTo - seeking to " << time << " (" << totalBytes << " bytes from current " << file->tellg() << ")" << std::endl; #endif file->seekg(totalBytes, std::ios::cur); return true; } // Get a certain number of sample frames - a frame is a set // of samples (all channels) for a given sample quanta. // // For example, getting one frame of 16-bit stereo will return // four bytes of data (two per channel). // // std::string RIFFAudioFile::getSampleFrames(std::ifstream *file, unsigned int frames) { // sanity if (file == 0) return std::string(""); // Bytes per sample already takes into account the number // of channels we're using // long totalBytes = frames * m_bytesPerFrame; try { return getBytes(file, totalBytes); } catch (BadSoundFileException s) { return ""; } } unsigned int RIFFAudioFile::getSampleFrames(std::ifstream *file, char *buf, unsigned int frames) { if (file == 0) return 0; try { return getBytes(file, buf, frames * m_bytesPerFrame) / m_bytesPerFrame; } catch (BadSoundFileException s) { return 0; } } std::string RIFFAudioFile::getSampleFrames(unsigned int frames) { if (*m_inFile) { return getSampleFrames(m_inFile, frames); } else { return std::string(""); } } // Return a slice of frames over a time period // std::string RIFFAudioFile::getSampleFrameSlice(std::ifstream *file, const RealTime &time) { // sanity if (file == 0) return std::string(""); long totalFrames = RealTime::realTime2Frame(time, m_sampleRate); long totalBytes = totalFrames * m_bytesPerFrame; try { return getBytes(file, totalBytes); } catch (BadSoundFileException s) { return ""; } } std::string RIFFAudioFile::getSampleFrameSlice(const RealTime &time) { if (*m_inFile) { return getSampleFrameSlice(m_inFile, time); } else { return std::string(""); } } RealTime RIFFAudioFile::getLength() { // Fixed header size = 44 but prove by getting it from the file too // unsigned int headerLength = 44; if (m_inFile) { m_inFile->seekg(16, std::ios::beg); headerLength = getIntegerFromLittleEndian(getBytes(m_inFile, 4)); m_inFile->seekg(headerLength, std::ios::cur); headerLength += (16 + 8); } if (!m_bytesPerFrame || !m_sampleRate) return RealTime::zeroTime; double frames = (m_fileSize - headerLength) / m_bytesPerFrame; double seconds = frames / ((double)m_sampleRate); int secs = int(seconds); int nsecs = int((seconds - secs) * 1000000000.0); return RealTime(secs, nsecs); } // The RIFF file format chunk defines our internal meta data. // // Courtesy of: // http://www.technology.niagarac.on.ca/courses/comp630/WavFileFormat.html // // 'The WAV file itself consists of three "chunks" of information: // The RIFF chunk which identifies the file as a WAV file, The FORMAT // chunk which identifies parameters such as sample rate and the DATA // chunk which contains the actual data (samples).' // // void RIFFAudioFile::readFormatChunk() { if (m_inFile == 0) return ; m_loseBuffer = true; // seek to beginning m_inFile->seekg(0, std::ios::beg); // get the header string // std::string hS = getBytes(36); // Look for the RIFF identifier and bomb out if we don't find it // if (hS.compare(0, 4, AUDIO_RIFF_ID) != 0) { #ifdef DEBUG_RIFF std::cerr << "RIFFAudioFile::readFormatChunk - " << "can't find RIFF identifier\n"; #endif throw(BadSoundFileException(m_fileName, qstrtostr(QObject::tr("Can't find RIFF identifier")))); } // Look for the WAV identifier // if (hS.compare(8, 4, AUDIO_WAVE_ID) != 0) { #ifdef DEBUG_RIFF std::cerr << "Can't find WAV identifier\n"; #endif throw(BadSoundFileException(m_fileName, qstrtostr(QObject::tr("Can't find WAV identifier")))); } // Look for the FORMAT identifier - note that this doesn't actually // have to be in the first chunk we come across, but for the moment // this is the only place we check for it because I'm lazy. // // if (hS.compare(12, 4, AUDIO_FORMAT_ID) != 0) { #ifdef DEBUG_RIFF std::cerr << "Can't find FORMAT identifier\n"; #endif throw(BadSoundFileException(m_fileName, qstrtostr(QObject::tr("Can't find FORMAT identifier")))); } // Little endian conversion of length bytes into file length // (add on eight for RIFF id and length field and compare to // real file size). // unsigned int length = getIntegerFromLittleEndian(hS.substr(4, 4)) + 8; if (length != m_fileSize) { std::cerr << "WARNING: RIFFAudioFile: incorrect length (" << length << ", file size is " << m_fileSize << "), ignoring" << std::endl; length = m_fileSize; } // Check the format length // unsigned int lengthOfFormat = getIntegerFromLittleEndian(hS.substr(16, 4)); // Make sure we step to the end of the format chunk ignoring the // tail if it exists // if (lengthOfFormat > 0x10) { #ifdef DEBUG_RIFF std::cerr << "RIFFAudioFile::readFormatChunk - " << "extended Format Chunk (" << lengthOfFormat << ")" << std::endl; #endif // ignore any overlapping bytes m_inFile->seekg(lengthOfFormat - 0x10, std::ios::cur); } else if (lengthOfFormat < 0x10) { #ifdef DEBUG_RIFF std::cerr << "RIFFAudioFile::readFormatChunk - " << "truncated Format Chunk (" << lengthOfFormat << ")" << std::endl; #endif m_inFile->seekg(lengthOfFormat - 0x10, std::ios::cur); //throw(BadSoundFileException(m_fileName, "Format chunk too short")); } // Check sub format - we support PCM or IEEE floating point. // unsigned int subFormat = getIntegerFromLittleEndian(hS.substr(20, 2)); if (subFormat == 0x01) { m_subFormat = PCM; } else if (subFormat == 0x03) { m_subFormat = FLOAT; } else { throw(BadSoundFileException(m_fileName, qstrtostr(QObject::tr("Rosegarden currently only supports PCM or IEEE floating-point RIFF files")))); } // We seem to have a good looking .WAV file - extract the // sample information and populate this locally // unsigned int channelNumbers = getIntegerFromLittleEndian(hS.substr(22, 2)); switch (channelNumbers) { case 0x01: case 0x02: m_channels = channelNumbers; break; default: { throw(BadSoundFileException(m_fileName, qstrtostr(QObject::tr("Unsupported number of channels")))); } break; } // Now the rest of the information // m_sampleRate = getIntegerFromLittleEndian(hS.substr(24, 4)); m_bytesPerSecond = getIntegerFromLittleEndian(hS.substr(28, 4)); m_bytesPerFrame = getIntegerFromLittleEndian(hS.substr(32, 2)); m_bitsPerSample = getIntegerFromLittleEndian(hS.substr(34, 2)); if (m_subFormat == PCM) { if (m_bitsPerSample != 8 && m_bitsPerSample != 16 && m_bitsPerSample != 24) { throw BadSoundFileException(QObject::tr("Rosegarden currently only supports 8-, 16- or 24-bit PCM in RIFF files")); } } else if (m_subFormat == FLOAT) { if (m_bitsPerSample != 32) { throw BadSoundFileException(QObject::tr("Rosegarden currently only supports 32-bit floating-point in RIFF files")); } } // printStats(); } // Write out the format chunk from our internal data // void RIFFAudioFile::writeFormatChunk() { if (m_outFile == 0 || m_type != WAV) return ; std::string outString; // RIFF type is all we support for the moment outString += AUDIO_RIFF_ID; // Now write the total length of the file minus these first 8 bytes. // We won't know this until we've finished recording the file. // outString += "0000"; // WAV file is all we support // outString += AUDIO_WAVE_ID; // Begin the format chunk outString += AUDIO_FORMAT_ID; // length //cout << "LENGTH = " << getLittleEndianFromInteger(0x10, 4) << endl; outString += getLittleEndianFromInteger(0x10, 4); // 1 for PCM, 3 for float if (m_subFormat == PCM) { outString += getLittleEndianFromInteger(0x01, 2); } else { outString += getLittleEndianFromInteger(0x03, 2); } // channel outString += getLittleEndianFromInteger(m_channels, 2); // sample rate outString += getLittleEndianFromInteger(m_sampleRate, 4); // bytes per second outString += getLittleEndianFromInteger(m_bytesPerSecond, 4); // bytes per sample outString += getLittleEndianFromInteger(m_bytesPerFrame, 2); // bits per sample outString += getLittleEndianFromInteger(m_bitsPerSample, 2); // Now mark the beginning of the "data" chunk and leave the file // open for writing. outString += "data"; // length of data to follow - again needs to be written after // we've completed the file. // outString += "0000"; // write out // putBytes(m_outFile, outString); } AudioFileType RIFFAudioFile::identifySubType(const QString &filename) { std::ifstream *testFile = new std::ifstream(filename, std::ios::in | std::ios::binary); if (!(*testFile)) return UNKNOWN; std::string hS; unsigned int numberOfBytes = 36; char *bytes = new char[numberOfBytes]; testFile->read(bytes, numberOfBytes); for (unsigned int i = 0; i < numberOfBytes; i++) hS += (unsigned char)bytes[i]; AudioFileType type = UNKNOWN; // Test for BWF first because it's an extension of a plain WAV // if (hS.compare(0, 4, AUDIO_RIFF_ID) == 0 && hS.compare(8, 4, AUDIO_WAVE_ID) == 0 && hS.compare(12, 4, AUDIO_BWF_ID) == 0) { type = BWF; } // Now for a WAV else if (hS.compare(0, 4, AUDIO_RIFF_ID) == 0 && hS.compare(8, 4, AUDIO_WAVE_ID) == 0) { type = WAV; } else type = UNKNOWN; testFile->close(); delete [] bytes; return type; } float RIFFAudioFile::convertBytesToSample(const unsigned char *ubuf) { switch (getBitsPerSample()) { case 8: { // WAV stores 8-bit samples unsigned, other sizes signed. return (float)(ubuf[0] - 128.0) / 128.0; } case 16: { // Two's complement little-endian 16-bit integer. // We convert endianness (if necessary) but assume 16-bit short. unsigned char b2 = ubuf[0]; unsigned char b1 = ubuf[1]; unsigned int bits = (b1 << 8) + b2; return (float)(short(bits)) / 32768.0; } case 24: { // Two's complement little-endian 24-bit integer. // Again, convert endianness but assume 32-bit int. unsigned char b3 = ubuf[0]; unsigned char b2 = ubuf[1]; unsigned char b1 = ubuf[2]; // Rotate 8 bits too far in order to get the sign bit // in the right place; this gives us a 32-bit value, // hence the larger float divisor unsigned int bits = (b1 << 24) + (b2 << 16) + (b3 << 8); return (float)(int(bits)) / 2147483648.0; } case 32: { // IEEE floating point return *(float *)ubuf; } default: return 0.0f; } } }