/**************************************************************************** ** ** Copyright (C) 2010 Nokia Corporation and/or its subsidiary(-ies). ** All rights reserved. ** Contact: Nokia Corporation (qt-info@nokia.com) ** ** This file is part of the Qt Toolkit. ** ** $QT_BEGIN_LICENSE:LGPL$ ** GNU Lesser General Public License Usage ** This file may be used under the terms of the GNU Lesser General Public ** License version 2.1 as published by the Free Software Foundation and ** appearing in the file LICENSE.LGPL included in the packaging of this ** file. Please review the following information to ensure the GNU Lesser ** General Public License version 2.1 requirements will be met: ** http://www.gnu.org/licenses/old-licenses/lgpl-2.1.html. ** ** In addition, as a special exception, Nokia gives you certain additional ** rights. These rights are described in the Nokia Qt LGPL Exception ** version 1.1, included in the file LGPL_EXCEPTION.txt in this package. ** ** GNU General Public License Usage ** Alternatively, this file may be used under the terms of the GNU General ** Public License version 3.0 as published by the Free Software Foundation ** and appearing in the file LICENSE.GPL included in the packaging of this ** file. Please review the following information to ensure the GNU General ** Public License version 3.0 requirements will be met: ** http://www.gnu.org/copyleft/gpl.html. ** ** Other Usage ** Alternatively, this file may be used in accordance with the terms and ** conditions contained in a signed written agreement between you and Nokia. ** ** ** ** ** ** $QT_END_LICENSE$ ** ****************************************************************************/ #include "qwavedecoder_p.h" #include #include QT_BEGIN_NAMESPACE QWaveDecoder::QWaveDecoder(QIODevice *s, QObject *parent): QIODevice(parent), haveFormat(false), dataSize(0), source(s), state(QWaveDecoder::InitialState), junkToSkip(0), bigEndian(false) { open(QIODevice::ReadOnly | QIODevice::Unbuffered); if (enoughDataAvailable()) QTimer::singleShot(0, this, SLOT(handleData())); else connect(source, SIGNAL(readyRead()), SLOT(handleData())); } QWaveDecoder::~QWaveDecoder() { } QAudioFormat QWaveDecoder::audioFormat() const { return format; } int QWaveDecoder::duration() const { return size() * 1000 / (format.sampleSize() / 8) / format.channels() / format.frequency(); } qint64 QWaveDecoder::size() const { return haveFormat ? dataSize : 0; } bool QWaveDecoder::isSequential() const { return source->isSequential(); } qint64 QWaveDecoder::bytesAvailable() const { return haveFormat ? source->bytesAvailable() : 0; } qint64 QWaveDecoder::readData(char *data, qint64 maxlen) { return haveFormat ? source->read(data, maxlen) : 0; } qint64 QWaveDecoder::writeData(const char *data, qint64 len) { Q_UNUSED(data); Q_UNUSED(len); return -1; } void QWaveDecoder::parsingFailed() { Q_ASSERT(source); source->disconnect(SIGNAL(readyRead()), this, SLOT(handleData())); emit parsingError(); } void QWaveDecoder::handleData() { // As a special "state", if we have junk to skip, we do if (junkToSkip > 0) { discardBytes(junkToSkip); // this also updates junkToSkip // If we couldn't skip all the junk, return if (junkToSkip > 0) { // We might have run out if (source->atEnd()) parsingFailed(); return; } } if (state == QWaveDecoder::InitialState) { if (source->bytesAvailable() < qint64(sizeof(RIFFHeader))) return; RIFFHeader riff; source->read(reinterpret_cast(&riff), sizeof(RIFFHeader)); // RIFF = little endian RIFF, RIFX = big endian RIFF if (((qstrncmp(riff.descriptor.id, "RIFF", 4) != 0) && (qstrncmp(riff.descriptor.id, "RIFX", 4) != 0)) || qstrncmp(riff.type, "WAVE", 4) != 0) { parsingFailed(); return; } else { state = QWaveDecoder::WaitingForFormatState; if (qstrncmp(riff.descriptor.id, "RIFX", 4) == 0) bigEndian = true; else bigEndian = false; } } if (state == QWaveDecoder::WaitingForFormatState) { if (findChunk("fmt ")) { chunk descriptor; peekChunk(&descriptor); if (source->bytesAvailable() < qint64(descriptor.size + sizeof(chunk))) return; WAVEHeader wave; source->read(reinterpret_cast(&wave), sizeof(WAVEHeader)); if (descriptor.size > sizeof(WAVEHeader)) discardBytes(descriptor.size - sizeof(WAVEHeader)); // Swizzle this if (bigEndian) { wave.audioFormat = qFromBigEndian(wave.audioFormat); } if (wave.audioFormat != 0 && wave.audioFormat != 1) { // 32bit wave files have format == 0xFFFE (WAVE_FORMAT_EXTENSIBLE). // but don't support them at the moment. parsingFailed(); return; } else { format.setCodec(QLatin1String("audio/pcm")); if (bigEndian) { int bps = qFromBigEndian(wave.bitsPerSample); format.setSampleType(bps == 8 ? QAudioFormat::UnSignedInt : QAudioFormat::SignedInt); format.setByteOrder(QAudioFormat::BigEndian); format.setFrequency(qFromBigEndian(wave.sampleRate)); format.setSampleSize(bps); format.setChannels(qFromBigEndian(wave.numChannels)); } else { int bps = qFromLittleEndian(wave.bitsPerSample); format.setSampleType(bps == 8 ? QAudioFormat::UnSignedInt : QAudioFormat::SignedInt); format.setByteOrder(QAudioFormat::LittleEndian); format.setFrequency(qFromLittleEndian(wave.sampleRate)); format.setSampleSize(bps); format.setChannels(qFromLittleEndian(wave.numChannels)); } state = QWaveDecoder::WaitingForDataState; } } } if (state == QWaveDecoder::WaitingForDataState) { if (findChunk("data")) { source->disconnect(SIGNAL(readyRead()), this, SLOT(handleData())); chunk descriptor; source->read(reinterpret_cast(&descriptor), sizeof(chunk)); if (bigEndian) descriptor.size = qFromBigEndian(descriptor.size); dataSize = descriptor.size; haveFormat = true; connect(source, SIGNAL(readyRead()), SIGNAL(readyRead())); emit formatKnown(); return; } } // If we hit the end without finding data, it's a parsing error if (source->atEnd()) { parsingFailed(); } } bool QWaveDecoder::enoughDataAvailable() { chunk descriptor; if (!peekChunk(&descriptor)) return false; // This is only called for the RIFF/RIFX header, before bigEndian is set, // so we have to manually swizzle if (qstrncmp(descriptor.id, "RIFX", 4) == 0) descriptor.size = qFromBigEndian(descriptor.size); if (source->bytesAvailable() < qint64(sizeof(chunk) + descriptor.size)) return false; return true; } bool QWaveDecoder::findChunk(const char *chunkId) { chunk descriptor; if (!peekChunk(&descriptor)) return false; if (qstrncmp(descriptor.id, chunkId, 4) == 0) return true; // It's possible that bytes->available() is less than the chunk size // if it's corrupt. junkToSkip = qint64(sizeof(chunk) + descriptor.size); while (source->bytesAvailable() > 0) { // Skip the current amount if (junkToSkip > 0) discardBytes(junkToSkip); // If we still have stuff left, just exit and try again later // since we can't call peekChunk if (junkToSkip > 0) return false; if (!peekChunk(&descriptor)) return false; if (qstrncmp(descriptor.id, chunkId, 4) == 0) return true; } return false; } // Handles endianness bool QWaveDecoder::peekChunk(chunk *pChunk) { if (source->bytesAvailable() < qint64(sizeof(chunk))) return false; source->peek(reinterpret_cast(pChunk), sizeof(chunk)); if (bigEndian) pChunk->size = qFromBigEndian(pChunk->size); return true; } void QWaveDecoder::discardBytes(qint64 numBytes) { // Discards a number of bytes // If the iodevice doesn't have this many bytes in it, // remember how much more junk we have to skip. if (source->isSequential()) { QByteArray r = source->read(qMin(numBytes, qint64(16384))); // uggh, wasted memory, limit to a max of 16k if (r.size() < numBytes) junkToSkip = numBytes - r.size(); else junkToSkip = 0; } else { quint64 origPos = source->pos(); source->seek(source->pos() + numBytes); junkToSkip = origPos + numBytes - source->pos(); } } QT_END_NAMESPACE #include "moc_qwavedecoder_p.cpp"