/*************************************************************************** * __________ __ ___. * Open \______ \ ____ ____ | | _\_ |__ _______ ___ * Source | _// _ \_/ ___\| |/ /| __ \ / _ \ \/ / * Jukebox | | ( <_> ) \___| < | \_\ ( <_> > < < * Firmware |____|_ /\____/ \___ >__|_ \|___ /\____/__/\_ \ * \/ \/ \/ \/ \/ * * Copyright (C) 2012 Dominik Riebeling * * All files in this archive are subject to the GNU General Public License. * See the file COPYING in the source tree root for full license agreement. * * This software is distributed on an "AS IS" basis, WITHOUT WARRANTY OF ANY * KIND, either express or implied. * ****************************************************************************/ #include #include "encoderlame.h" #include "rbsettings.h" #include "lame/lame.h" /** Resolve a symbol from loaded library. */ #define SYMBOLRESOLVE(symbol, type) \ do { m_##symbol = (type)lib->resolve(#symbol); \ if(!m_##symbol) return; \ qDebug() << "[EncoderLame] Resolved symbol " #symbol; } \ while(0) EncoderLame::EncoderLame(QObject *parent) : EncoderBase(parent) { m_symbolsResolved = false; lib = new QLibrary("libmp3lame", this); SYMBOLRESOLVE(get_lame_short_version, const char* (*)()); SYMBOLRESOLVE(lame_set_out_samplerate, int (*)(lame_global_flags*, int)); SYMBOLRESOLVE(lame_set_in_samplerate, int (*)(lame_global_flags*, int)); SYMBOLRESOLVE(lame_set_num_channels, int (*)(lame_global_flags*, int)); SYMBOLRESOLVE(lame_set_scale, int (*)(lame_global_flags*, float)); SYMBOLRESOLVE(lame_set_mode, int (*)(lame_global_flags*, MPEG_mode)); SYMBOLRESOLVE(lame_set_VBR, int (*)(lame_global_flags*, vbr_mode)); SYMBOLRESOLVE(lame_set_VBR_quality, int (*)(lame_global_flags*, float)); SYMBOLRESOLVE(lame_set_VBR_max_bitrate_kbps, int (*)(lame_global_flags*, int)); SYMBOLRESOLVE(lame_set_bWriteVbrTag, int (*)(lame_global_flags*, int)); SYMBOLRESOLVE(lame_init, lame_global_flags* (*)()); SYMBOLRESOLVE(lame_init_params, int (*)(lame_global_flags*)); SYMBOLRESOLVE(lame_encode_buffer, int (*)(lame_global_flags*, short int*, short int*, int, unsigned char*, int)); SYMBOLRESOLVE(lame_encode_flush, int (*)(lame_global_flags*, unsigned char*, int)); SYMBOLRESOLVE(lame_close, int (*)(lame_global_flags*)); qDebug() << "[EncoderLame] libmp3lame loaded:" << lib->isLoaded(); m_encoderVolume = RbSettings::subValue("lame", RbSettings::EncoderVolume).toDouble(); m_encoderQuality = RbSettings::subValue("lame", RbSettings::EncoderQuality).toDouble(); m_symbolsResolved = true; } void EncoderLame::generateSettings() { // no settings for now. // show lame version. if(m_symbolsResolved) { double quality = RbSettings::subValue("lame", RbSettings::EncoderQuality).toDouble(); // default quality is 0.999. if(quality < 0) { quality = 0.99; } insertSetting(LAMEVERSION, new EncTtsSetting(this, EncTtsSetting::eREADONLYSTRING, tr("LAME"), QString(m_get_lame_short_version()))); insertSetting(VOLUME, new EncTtsSetting(this, EncTtsSetting::eDOUBLE, tr("Volume"), RbSettings::subValue("lame", RbSettings::EncoderVolume).toDouble(), 0.0, 1.0)); insertSetting(QUALITY, new EncTtsSetting(this, EncTtsSetting::eDOUBLE, tr("Quality"), quality, 0.0, 1.0)); } else { insertSetting(LAMEVERSION, new EncTtsSetting(this, EncTtsSetting::eREADONLYSTRING, tr("LAME"), tr("Could not find libmp3lame!"))); } } void EncoderLame::saveSettings() { if(m_symbolsResolved) { RbSettings::setSubValue("lame", RbSettings::EncoderVolume, getSetting(VOLUME)->current().toDouble()); RbSettings::setSubValue("lame", RbSettings::EncoderQuality, getSetting(QUALITY)->current().toDouble()); m_encoderVolume = RbSettings::subValue("lame", RbSettings::EncoderVolume).toDouble(); m_encoderQuality = RbSettings::subValue("lame", RbSettings::EncoderQuality).toDouble(); } } bool EncoderLame::start() { if(!m_symbolsResolved) { return false; } // try to get config from settings return true; } bool EncoderLame::encode(QString input,QString output) { qDebug() << "[EncoderLame] Encoding" << QDir::cleanPath(input); if(!m_symbolsResolved) { qDebug() << "[EncoderLame] Symbols not successfully resolved, cannot run!"; return false; } QFile fin(input); QFile fout(output); // initialize encoder lame_global_flags *gfp; unsigned char header[12]; unsigned char chunkheader[8]; unsigned int datalength = 0; unsigned int channels = 0; unsigned int samplerate = 0; unsigned int samplesize = 0; int num_samples = 0; int ret; unsigned char* mp3buf; int mp3buflen; short int* wavbuf; int wavbuflen; gfp = m_lame_init(); m_lame_set_out_samplerate(gfp, 12000); // resample to 12kHz // scale input volume m_lame_set_scale(gfp, m_encoderVolume); m_lame_set_mode(gfp, MONO); // mono output mode m_lame_set_VBR(gfp, vbr_default); // enable default VBR mode // VBR quality m_lame_set_VBR_quality(gfp, m_encoderQuality); m_lame_set_VBR_max_bitrate_kbps(gfp, 64); // maximum bitrate 64kbps m_lame_set_bWriteVbrTag(gfp, 0); // disable LAME tag. if(!fin.open(QIODevice::ReadOnly)) { qDebug() << "[EncoderLame] Could not open input file" << input; return false; } // read RIFF header fin.read((char*)header, 12); if(memcmp("RIFF", header, 4) != 0) { qDebug() << "[EncoderLame] RIFF header not found!" << header[0] << header[1] << header[2] << header[3]; fin.close(); return false; } if(memcmp("WAVE", &header[8], 4) != 0) { qDebug() << "[EncoderLame] WAVE FOURCC not found!" << header[8] << header[9] << header[10] << header[11]; fin.close(); return false; } // search for fmt chunk do { // read fmt fin.read((char*)chunkheader, 8); int chunkdatalen = chunkheader[4] | chunkheader[5]<<8 | chunkheader[6]<<16 | chunkheader[7]<<24; if(memcmp("fmt ", chunkheader, 4) == 0) { // fmt found, read rest of chunk. // NOTE: This code ignores the format tag value. // Ideally this should be checked as well. However, rbspeex doesn't // check the format tag either when reading wave files, so if // problems arise we should notice pretty soon. Furthermore, the // input format used should be known. In case some TTS uses a // different wave encoding some time this needs to get adjusted. if(chunkdatalen < 16) { qDebug() << "fmt chunk too small!"; } else { unsigned char *buf = new unsigned char[chunkdatalen]; fin.read((char*)buf, chunkdatalen); channels = buf[2] | buf[3]<<8; samplerate = buf[4] | buf[5]<<8 | buf[6]<<16 | buf[7]<<24; samplesize = buf[14] | buf[15]<<8; delete[] buf; } } // read data else if(memcmp("data", chunkheader, 4) == 0) { datalength = chunkdatalen; break; } else { // unknown chunk, just skip its data. qDebug() << "[EncoderLame] unknown chunk, skipping." << chunkheader[0] << chunkheader[1] << chunkheader[2] << chunkheader[3]; fin.seek(fin.pos() + chunkdatalen); } } while(!fin.atEnd()); // check format if(channels == 0 || samplerate == 0 || samplesize == 0 || datalength == 0) { qDebug() << "[EncoderLame] invalid format. Channels:" << channels << "Samplerate:" << samplerate << "Samplesize:" << samplesize << "Data chunk length:" << datalength; fin.close(); return false; } num_samples = (datalength / channels / (samplesize/8)); // set input format values m_lame_set_in_samplerate(gfp, samplerate); m_lame_set_num_channels(gfp, channels); // initialize encoder. ret = m_lame_init_params(gfp); if(ret != 0) { qDebug() << "[EncoderLame] lame_init_params() failed with" << ret; fin.close(); return false; } // we're dealing with rather small files here (100kB-ish), so don't care // about the possible output size and simply allocate the same number of // bytes the input file has. This wastes space but should be ok. // Put an upper limit of 8MiB. if(datalength > 8*1024*1024) { qDebug() << "[EncoderLame] Input file too large:" << datalength; fin.close(); return false; } mp3buflen = datalength; wavbuflen = datalength; mp3buf = new unsigned char[mp3buflen]; wavbuf = new short int[wavbuflen]; #if defined(Q_OS_MACX) // handle byte order -- the host might not be LE. if(samplesize == 8) { // no need to convert. fin.read((char*)wavbuf, wavbuflen); } else if(samplesize == 16) { // read LE 16bit words. Since the input format is either mono or // interleaved there's no need to care for that. unsigned int pos = 0; char word[2]; while(pos < datalength) { fin.read(word, 2); wavbuf[pos++] = (word[0]&0xff) | ((word[1]<<8)&0xff00); } } else { qDebug() << "[EncoderLame] Unknown samplesize:" << samplesize; fin.close(); delete[] mp3buf; delete[] wavbuf; return false; } #else // all systems but OS X are considered LE. fin.read((char*)wavbuf, wavbuflen); #endif fin.close(); // encode data. fout.open(QIODevice::ReadWrite); ret = m_lame_encode_buffer(gfp, wavbuf, wavbuf, num_samples, mp3buf, mp3buflen); if(ret < 0) { qDebug() << "[EncoderLame] Error during encoding:" << ret; } if(fout.write((char*)mp3buf, ret) != (unsigned int)ret) { qDebug() << "[EncoderLame] Writing mp3 data failed!" << ret; fout.close(); delete[] mp3buf; delete[] wavbuf; return false; } // flush remaining data ret = m_lame_encode_flush(gfp, mp3buf, mp3buflen); if(fout.write((char*)mp3buf, ret) != (unsigned int)ret) { qDebug() << "[EncoderLame] Writing final mp3 data failed!"; fout.close(); delete[] mp3buf; delete[] wavbuf; return false; } // shut down encoder and clean up. m_lame_close(gfp); fout.close(); delete[] mp3buf; delete[] wavbuf; return true; } /** Check if the current configuration is usable. * Since we're loading a library dynamically in the constructor test if that * succeeded. Otherwise the "configuration" is not usable, even though the * problem is not necessarily related to configuration values set by the user. */ bool EncoderLame::configOk() { return (lib->isLoaded() && m_symbolsResolved); }