/* Copyright (C) 2000 Stefan Westerfeld stefan@space.twc.de This library is free software; you can redistribute it and/or modify it under the terms of the GNU Library General Public License as published by the Free Software Foundation; either version 2 of the License, or (at your option) any later version. This library 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 Library General Public License for more details. You should have received a copy of the GNU Library General Public License along with this library; see the file COPYING.LIB. If not, write to the Free Software Foundation, Inc., 59 Temple Place - Suite 330, Boston, MA 02111-1307, USA. */ #ifdef HAVE_CONFIG_H #include #endif #include #include #include #include #ifdef HAVE_SYS_SELECT_H #include // Needed on some systems. #endif #ifdef HAVE_SYS_SOUNDCARD_H #include #endif #include #include #include #include #include #include #include #include #include #include "debug.h" #include "audiosubsys.h" #include "audioio.h" #define DEFAULT_DEVICE_NAME "/dev/dsp" #undef DEBUG_WAVEFORM #ifdef DEBUG_WAVEFORM #include #endif using namespace std; using namespace Arts; //--- automatic startup class static AudioSubSystemStart aStart; void AudioSubSystemStart::startup() { _instance = new AudioSubSystem(); } void AudioSubSystemStart::shutdown() { delete _instance; } //--- AudioSubSystemPrivate data class Arts::AudioSubSystemPrivate { public: #ifdef DEBUG_WAVEFORM ofstream plotfile; #endif AudioIO *audioIO; string audioIOName; bool audioIOInit; unsigned int adjustDuplexOffsetIndex; int adjustDuplexOffset[4]; int adjustDuplexCount; }; //--- AudioSubSystem implementation AudioSubSystem *AudioSubSystem::the() { return aStart.the(); } const char *AudioSubSystem::error() { return _error.c_str(); } AudioSubSystem::AudioSubSystem() { d = new AudioSubSystemPrivate; #ifdef DEBUG_WAVEFORM d->plotfile.open( "/dev/shm/audiosubsystem.plot" ); #endif d->audioIO = 0; d->audioIOInit = false; _running = false; consumer = 0; producer = 0; fragment_buffer = 0; } AudioSubSystem::~AudioSubSystem() { delete d->audioIO; delete d; } bool AudioSubSystem::attachProducer(ASProducer *producer) { assert(producer); if(this->producer) return false; this->producer = producer; return true; } bool AudioSubSystem::attachConsumer(ASConsumer *consumer) { assert(consumer); if(this->consumer) return false; this->consumer = consumer; return true; } void AudioSubSystem::detachProducer() { assert(producer); producer = 0; if(_running) close(); } void AudioSubSystem::detachConsumer() { assert(consumer); consumer = 0; if(_running) close(); } /* initially creates default AudioIO */ void AudioSubSystem::initAudioIO() { /* auto detect */ if(!d->audioIOInit) { string bestName; int bestValue = 0; arts_debug("autodetecting driver: "); for(int i = 0; i < AudioIO::queryAudioIOCount(); i++) { string name = AudioIO::queryAudioIOParamStr(i, AudioIO::name); AudioIO *aio = AudioIO::createAudioIO(name.c_str()); int value = aio->getParam(AudioIO::autoDetect); arts_debug(" - %s: %d", name.c_str(), value); if(value > bestValue) { bestName = name; bestValue = value; } delete aio; } if(bestValue) { arts_debug("... which means we'll default to %s", bestName.c_str()); audioIO(bestName); } else { arts_debug("... nothing we could use as default found"); } } } void AudioSubSystem::audioIO(const string& audioIO) { if(d->audioIO) delete d->audioIO; d->audioIOName = audioIO; d->audioIO = AudioIO::createAudioIO(audioIO.c_str()); d->audioIOInit = true; } string AudioSubSystem::audioIO() { initAudioIO(); return d->audioIOName; } void AudioSubSystem::deviceName(const string& deviceName) { initAudioIO(); if(!d->audioIO) return; d->audioIO->setParamStr(AudioIO::deviceName, deviceName.c_str()); } string AudioSubSystem::deviceName() { initAudioIO(); if(!d->audioIO) return ""; return d->audioIO->getParamStr(AudioIO::deviceName); } void AudioSubSystem::fragmentCount(int fragmentCount) { initAudioIO(); if(!d->audioIO) return; d->audioIO->setParam(AudioIO::fragmentCount, fragmentCount); } int AudioSubSystem::fragmentCount() { initAudioIO(); if(!d->audioIO) return 0; return d->audioIO->getParam(AudioIO::fragmentCount); } void AudioSubSystem::fragmentSize(int fragmentSize) { initAudioIO(); if(!d->audioIO) return; d->audioIO->setParam(AudioIO::fragmentSize, fragmentSize); } int AudioSubSystem::fragmentSize() { initAudioIO(); if(!d->audioIO) return 0; return d->audioIO->getParam(AudioIO::fragmentSize); } void AudioSubSystem::samplingRate(int samplingRate) { initAudioIO(); if(!d->audioIO) return; d->audioIO->setParam(AudioIO::samplingRate, samplingRate); } int AudioSubSystem::samplingRate() { initAudioIO(); if(!d->audioIO) return 0; return d->audioIO->getParam(AudioIO::samplingRate); } void AudioSubSystem::channels(int channels) { initAudioIO(); if(!d->audioIO) return; d->audioIO->setParam(AudioIO::channels, channels); } int AudioSubSystem::channels() { initAudioIO(); if(!d->audioIO) return 0; return d->audioIO->getParam(AudioIO::channels); } void AudioSubSystem::format(int format) { initAudioIO(); if(!d->audioIO) return; d->audioIO->setParam(AudioIO::format, format); } int AudioSubSystem::format() { initAudioIO(); if(!d->audioIO) return 0; return d->audioIO->getParam(AudioIO::format); } int AudioSubSystem::bits() { int _format = format(); arts_assert(_format == 0 || _format == 8 || _format == 16 || _format == 17 || _format == 32); return (_format & (32 | 16 | 8)); } void AudioSubSystem::fullDuplex(bool fullDuplex) { initAudioIO(); if(!d->audioIO) return; int direction = fullDuplex?3:2; d->audioIO->setParam(AudioIO::direction, direction); } bool AudioSubSystem::fullDuplex() { initAudioIO(); if(!d->audioIO) return false; return d->audioIO->getParam(AudioIO::direction) == 3; } int AudioSubSystem::selectReadFD() { initAudioIO(); if(!d->audioIO) return false; return d->audioIO->getParam(AudioIO::selectReadFD); } int AudioSubSystem::selectWriteFD() { initAudioIO(); if(!d->audioIO) return false; return d->audioIO->getParam(AudioIO::selectWriteFD); } bool AudioSubSystem::check() { bool ok = open(); if(ok) close(); return ok; } bool AudioSubSystem::open() { assert(!_running); initAudioIO(); if(!d->audioIO) { if(d->audioIOName.empty()) _error = "couldn't auto detect which audio I/O method to use"; else _error = "unable to select '"+d->audioIOName+"' style audio I/O"; return false; } if(d->audioIO->open()) { _running = true; _fragmentSize = d->audioIO->getParam(AudioIO::fragmentSize); _fragmentCount = d->audioIO->getParam(AudioIO::fragmentCount); // allocate global buffer to do I/O assert(fragment_buffer == 0); fragment_buffer = new char[_fragmentSize]; d->adjustDuplexCount = 0; return true; } else { _error = d->audioIO->getParamStr(AudioIO::lastError); return false; } } void AudioSubSystem::close() { assert(_running); assert(d->audioIO); d->audioIO->close(); wBuffer.clear(); rBuffer.clear(); _running = false; if(fragment_buffer) { delete[] fragment_buffer; fragment_buffer = 0; } } bool AudioSubSystem::running() { return _running; } void AudioSubSystem::handleIO(int type) { assert(d->audioIO); if(type & ioRead) { int len = d->audioIO->read(fragment_buffer,_fragmentSize); if(len > 0) { if(rBuffer.size() < _fragmentSize * _fragmentCount * bits() / 8 * channels()) { rBuffer.write(len,fragment_buffer); #ifdef DEBUG_WAVEFORM float * end = (float *)(fragment_buffer + len); float * floatbuffer = (float *)fragment_buffer; while(floatbuffer < end) { d->plotfile << *floatbuffer++ << "\n"; ++floatbuffer; } #endif } else { arts_debug( "AudioSubSystem: rBuffer is too full" ); } } } if(type & ioWrite) { /* * make sure that we have a fragment full of data at least */ Rewrite: while(wBuffer.size() < _fragmentSize) { long wbsz = wBuffer.size(); producer->needMore(); if(wbsz == wBuffer.size()) { /* * Even though we asked the client to supply more * data, he didn't give us more. So we can't supply * output data as well. Bad luck. Might produce a * buffer underrun - but we can't help here. */ arts_info("full duplex: no more data available (underrun)"); return; } } /* * look how much we really can write without blocking */ int space = d->audioIO->getParam(AudioIO::canWrite); int can_write = min(space, _fragmentSize); if(can_write > 0) { /* * ok, so write it (as we checked that our buffer has enough data * to do so and the soundcardbuffer has enough data to handle this * write, nothing can go wrong here) */ int rSize = wBuffer.read(can_write,fragment_buffer); assert(rSize == can_write); int len = d->audioIO->write(fragment_buffer,can_write); if(len != can_write) arts_fatal("AudioSubSystem::handleIO: write failed\n" "len = %d, can_write = %d, errno = %d (%s)\n\n" "This might be a sound hardware/driver specific problem" " (see aRts FAQ)",len,can_write,errno,strerror(errno)); if(fullDuplex()) { /* * if we're running full duplex, here is a good place to check * for full duplex drift */ d->adjustDuplexCount += can_write; if(d->adjustDuplexCount > samplingRate()) { adjustDuplexBuffers(); d->adjustDuplexCount = 0; } } } // If we can write a fragment more, then do so right now: if (space >= _fragmentSize*2) goto Rewrite; } assert((type & ioExcept) == 0); } void AudioSubSystem::read(void *buffer, int size) { /* if not enough data can be read, produce some */ while(rBuffer.size() < size) adjustInputBuffer(1); /* finally, just take the data out of the input buffer */ int rSize = rBuffer.read(size,buffer); assert(rSize == size); } void AudioSubSystem::write(void *buffer, int size) { wBuffer.write(size,buffer); } float AudioSubSystem::outputDelay() { int fsize = _fragmentSize; int fcount = _fragmentCount; if(fsize > 0 && fcount > 0) // not all AudioIO classes need to support this { double hardwareBuffer = fsize * fcount; double freeOutputSpace = d->audioIO->getParam(AudioIO::canWrite); double playSpeed = channels() * samplingRate() * (bits() / 8); return (hardwareBuffer - freeOutputSpace) / playSpeed; } else return 0.0; } void AudioSubSystem::adjustDuplexBuffers() { int fsize = _fragmentSize; int fcount = _fragmentCount; if(fsize > 0 && fcount > 0) // not all AudioIO classes need to support this { int bound = 2; //max(fcount/2, 1); int optimalOffset = fsize * (fcount + bound); int minOffset = fsize * fcount; int maxOffset = fsize * (fcount + 2 * bound); int canRead = d->audioIO->getParam(AudioIO::canRead); if(canRead < 0) { arts_warning("AudioSubSystem::adjustDuplexBuffers: canRead < 0?"); canRead = 0; } int canWrite = d->audioIO->getParam(AudioIO::canWrite); if(canWrite < 0) { arts_warning("AudioSubSystem::adjustDuplexBuffers: canWrite < 0?"); canWrite = 0; } int currentOffset = rBuffer.size() + wBuffer.size() + canRead + max((fsize * fcount) - canWrite, 0); d->adjustDuplexOffset[d->adjustDuplexOffsetIndex++ & 3] = currentOffset; if(d->adjustDuplexOffsetIndex <= 4) return; int avgOffset; avgOffset = d->adjustDuplexOffset[0] + d->adjustDuplexOffset[1] + d->adjustDuplexOffset[2] + d->adjustDuplexOffset[3]; avgOffset /= 4; /* printf("offset: %d avg %d min %d opt %d max %d\r", currentOffset, avgOffset, minOffset, optimalOffset, maxOffset); fflush(stdout); */ if(minOffset <= avgOffset && avgOffset <= maxOffset) return; d->adjustDuplexOffsetIndex = 0; int adjust = (optimalOffset - currentOffset) / _fragmentSize; arts_debug("AudioSubSystem::adjustDuplexBuffers(%d)", adjust); } } void AudioSubSystem::adjustInputBuffer(int count) { if(format() == 8) { memset( fragment_buffer, 0x80, _fragmentSize ); } else { memset( fragment_buffer, 0, _fragmentSize ); } while(count > 0 && rBuffer.size() < _fragmentSize * _fragmentCount * 4) { rBuffer.write(_fragmentSize, fragment_buffer); #ifdef DEBUG_WAVEFORM float * end = (float *)(fragment_buffer + _fragmentSize); float * floatbuffer = (float *)fragment_buffer; while(floatbuffer < end) { d->plotfile << *floatbuffer++ << "\n"; ++floatbuffer; } #endif count--; } while(count < 0 && rBuffer.size() >= _fragmentSize) { rBuffer.read(_fragmentSize, fragment_buffer); count++; } } void AudioSubSystem::emergencyCleanup() { if(producer || consumer) { fprintf(stderr, "AudioSubSystem::emergencyCleanup\n"); if(producer) detachProducer(); if(consumer) detachConsumer(); } }