/* Copyright (C) 2005-2009 Michel de Boer 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, see . */ #include "audio_device.h" #include #include #include #include #include #include #include "sys_settings.h" #include "translator.h" #include "log.h" #include "userintf.h" #include "util.h" #include "audits/memman.h" #ifdef HAVE_LIBASOUND #include #endif #ifdef HAVE_JACK #include #endif t_audio_io* t_audio_io::open(const t_audio_device& dev, bool playback, bool capture, bool blocking, int channels, t_audio_sampleformat format, int sample_rate, bool short_latency) { t_audio_io* aio; if(dev.type == t_audio_device::OSS) { aio = new t_oss_io(); MEMMAN_NEW(aio); #ifdef HAVE_LIBASOUND } else if (dev.type == t_audio_device::ALSA) { aio = new t_alsa_io(); MEMMAN_NEW(aio); #endif #ifdef HAVE_JACK } elseif (dev.type == t_audio_device::JACK) { aio = new t_jack_io(); MEMMAN_NEW(aio); #endif } else { string msg("Audio device not implemented"); log_file->write_report(msg, "t_audio_io::open", LOG_NORMAL, LOG_CRITICAL); return 0; } if (aio->open(dev.device, playback, capture, blocking, channels, format, sample_rate, short_latency)) { return aio; } else { string msg("Open audio device failed"); log_file->write_report(msg, "t_audio_io::open", LOG_NORMAL, LOG_CRITICAL); MEMMAN_DELETE(aio); delete aio; return 0L; } } bool t_audio_io::validate(const t_audio_device& dev, bool playback, bool capture) { t_audio_io *aio = open(dev, playback, capture, false, 1, SAMPLEFORMAT_S16, 8000, true); if (aio) { MEMMAN_DELETE(aio); delete aio; return true; } return false; } t_audio_io::~t_audio_io() {} int t_audio_io::get_sample_rate(void) const { return _sample_rate; } bool t_audio_io::open(const string& device, bool playback, bool capture, bool blocking, int channels, t_audio_sampleformat format, int sample_rate, bool short_latency) { _sample_rate = sample_rate; return true; } t_oss_io::t_oss_io() : fd(-1), play_buffersize(0), rec_buffersize(0) { } t_oss_io::~t_oss_io() { if (fd > 0) { int arg = 0; ioctl(fd, SNDCTL_DSP_RESET, &arg); close(fd); } fd = -1; } bool t_oss_io::open(const string& device, bool playback, bool capture, bool blocking, int channels, t_audio_sampleformat format, int sample_rate, bool short_latency) { t_audio_io::open(device, playback, capture, blocking, channels, format, sample_rate, short_latency); int mode = 0; int status; log_file->write_header("t_oss_io::open", LOG_NORMAL); log_file->write_raw("Opening OSS device: "); log_file->write_raw(device); log_file->write_endl(); if (playback) log_file->write_raw("play\n"); if (capture) log_file->write_raw("capture\n"); log_file->write_footer(); assert (playback || capture); if (playback && capture) mode |= O_RDWR; else if (playback) mode |= O_WRONLY; else if (capture) mode |= O_RDONLY; // On some systems opening the audio devices blocks if another // process or thread has opened it already. To prevent a deadlock // first try to open the device in non-blocking mode. // If the device is still open by another twinkle thread then that // is a bug, but this way at least non deadlock is caused. if(blocking) { fd = ::open(device.c_str(), mode | O_NONBLOCK); if (fd == -1) { string msg("OSS audio device open failed: "); msg += get_error_str(errno); log_file->write_report(msg, "t_oss_io::open", LOG_NORMAL, LOG_CRITICAL); return false; } else { close(fd); fd = -1; } } else mode |= O_NONBLOCK; fd = ::open(device.c_str(), mode); if (fd < 0) { string msg("OSS audio device open failed: "); msg += get_error_str(errno); log_file->write_report(msg, "t_oss_io::open", LOG_NORMAL, LOG_CRITICAL); return false; } // Full duplex if (playback && capture) { status = ioctl(fd, SNDCTL_DSP_SETDUPLEX, 0); if (status == -1) { string msg("SNDCTL_DSP_SETDUPLEX ioctl failed: "); msg += get_error_str(errno); log_file->write_report(msg, "t_oss_io::open", LOG_NORMAL, LOG_CRITICAL); ui->cb_display_msg(TRANSLATE("Sound card cannot be set to full duplex."), MSG_CRITICAL); close(fd); return false; } } // Set fragment size int arg; if (short_latency) { switch (sys_config->get_oss_fragment_size()) { case 16: arg = 0x00ff0004; // 255 buffers of 2^4 bytes each break; case 32: arg = 0x00ff0005; // 255 buffers of 2^5 bytes each break; case 64: arg = 0x00ff0006; // 255 buffers of 2^5 bytes each break; case 128: arg = 0x00ff0007; // 255 buffers of 2^7 bytes each break; case 256: arg = 0x00ff0008; // 255 buffers of 2^8 bytes each break; default: arg = 0x00ff0007; // 255 buffers of 2^7 bytes each } } else { arg = 0x00ff000a; // 255 buffers of 2^10 bytes each } status = ioctl(fd, SNDCTL_DSP_SETFRAGMENT, &arg); if (status == -1) { string msg("SNDCTL_DSP_FRAGMENT ioctl failed: "); msg += get_error_str(errno); log_file->write_report(msg, "t_oss_io::open", LOG_NORMAL, LOG_CRITICAL); ui->cb_display_msg(TRANSLATE("Cannot set buffer size on sound card."), MSG_CRITICAL); close(fd); return false; } // Channels arg = channels; status = ioctl(fd, SNDCTL_DSP_CHANNELS, &arg); if (status == -1) { string msg("SNDCTL_DSP_CHANNELS ioctl failed: "); msg += get_error_str(errno); log_file->write_report(msg, "t_oss_io::open", LOG_NORMAL, LOG_CRITICAL); msg = TRANSLATE("Sound card cannot be set to %1 channels."); msg = replace_first(msg, "%1", int2str(channels)); ui->cb_display_msg(msg, MSG_CRITICAL); return false; } if (arg != channels) { log_file->write_report("Unable to set channels", "t_oss_io::open", LOG_NORMAL, LOG_CRITICAL); string msg = "Sound card cannot be set to "; msg = TRANSLATE("Sound card cannot be set to %1 channels."); msg = replace_first(msg, "%1", int2str(channels)); ui->cb_display_msg(msg, MSG_CRITICAL); return false; } // Sample format int fmt; switch (format) { case SAMPLEFORMAT_S16: #ifdef WORDS_BIGENDIAN fmt = AFMT_S16_BE; #else fmt = AFMT_S16_LE; #endif break; case SAMPLEFORMAT_U16: #ifdef WORDS_BIGENDIAN fmt = AFMT_U16_BE; #else fmt = AFMT_U16_LE; #endif break; case SAMPLEFORMAT_S8: fmt = AFMT_S8; break; case SAMPLEFORMAT_U8: fmt = AFMT_U8; break; default: fmt = 0; // fail } arg = fmt; status = ioctl(fd, SNDCTL_DSP_SETFMT, &arg); if (status == -1) { string msg("SNDCTL_DSP_SETFMT ioctl failed: "); msg += get_error_str(errno); log_file->write_report(msg, "t_oss_io::open", LOG_NORMAL, LOG_CRITICAL); ui->cb_display_msg(TRANSLATE("Cannot set sound card to 16 bits recording."), MSG_CRITICAL); return false; } arg = fmt; status = ioctl(fd, SOUND_PCM_WRITE_BITS, &arg); if (status == -1) { string msg("SOUND_PCM_WRITE_BITS ioctl failed: "); msg += get_error_str(errno); log_file->write_report(msg, "t_oss_io::open", LOG_NORMAL, LOG_CRITICAL); ui->cb_display_msg(TRANSLATE("Cannot set sound card to 16 bits playing."), MSG_CRITICAL); return false; } // Sample rate arg = sample_rate; status = ioctl(fd, SNDCTL_DSP_SPEED, &arg); if (status == -1) { string msg("SNDCTL_DSP_SPEED ioctl failed: "); msg += get_error_str(errno); log_file->write_report(msg, "t_oss_io::open", LOG_NORMAL, LOG_CRITICAL); msg = TRANSLATE("Cannot set sound card sample rate to %1"); msg = replace_first(msg, "%1", int2str(sample_rate)); ui->cb_display_msg(msg, MSG_CRITICAL); return false; } play_buffersize = rec_buffersize = 0; if (playback) play_buffersize = get_buffer_space(false); if (capture) rec_buffersize = get_buffer_space(true); return true; } void t_oss_io::enable(bool enable_playback, bool enable_recording) { int arg, status; arg = enable_recording ? PCM_ENABLE_INPUT : 0; arg |= enable_playback ? PCM_ENABLE_OUTPUT : 0; status = ioctl(fd, SNDCTL_DSP_SETTRIGGER, &arg); if (status == -1) { string msg("SNDCTL_DSP_SETTRIGGER ioctl failed: "); msg += get_error_str(errno); log_file->write_report(msg, "t_oss_io::enable", LOG_NORMAL, LOG_CRITICAL); } } void t_oss_io::flush(bool playback_buffer, bool recording_buffer) { for (int i = 0; i < 2; i++) { // i == 0: flush playback buffer, 1: flush recording buffer if (i == 0 && playback_buffer || i == 1 && recording_buffer) { int skip_bytes = ( (i==0) ? play_buffersize : rec_buffersize) - get_buffer_space(i == 1); if(skip_bytes <= 0) continue; unsigned char *trash = new unsigned char[skip_bytes]; MEMMAN_NEW_ARRAY(trash); read(trash, skip_bytes); MEMMAN_DELETE_ARRAY(trash); delete [] trash; } } } int t_oss_io::get_buffer_space(bool is_recording_buffer) { audio_buf_info dsp_info; int status = ioctl(fd, is_recording_buffer ? SNDCTL_DSP_GETISPACE : SNDCTL_DSP_GETOSPACE, &dsp_info); if (status == -1) return 0; return dsp_info.bytes; } int t_oss_io::get_buffer_size(bool is_recording_buffer) { if (is_recording_buffer) return rec_buffersize; else return play_buffersize; } bool t_oss_io::play_buffer_underrun(void) { return get_buffer_space(false) >= get_buffer_size(false); } int t_oss_io::read(unsigned char* buf, int len) { return ::read(fd, buf, len); } int t_oss_io::write(const unsigned char* buf, int len) { return ::write(fd, buf, len); } #ifdef HAVE_LIBASOUND t_alsa_io::t_alsa_io() : pcm_play_ptr(0), pcm_rec_ptr(0), play_framesize(1), rec_framesize(1), play_buffersize(0), rec_buffersize(0) { } t_alsa_io::~t_alsa_io() { if (pcm_play_ptr) { log_file->write_header("t_alsa_io::~t_alsa_io", LOG_NORMAL, LOG_DEBUG); log_file->write_raw("snd_pcm_close, handle = "); log_file->write_raw(ptr2str(pcm_play_ptr)); log_file->write_endl(); log_file->write_footer(); // Without the snd_pcm_hw_free, snd_pcm_close sometimes fails. snd_pcm_hw_free(pcm_play_ptr); snd_pcm_close(pcm_play_ptr); pcm_play_ptr = 0; } if (pcm_rec_ptr) { log_file->write_header("t_alsa_io::~t_alsa_io", LOG_NORMAL, LOG_DEBUG); log_file->write_raw("snd_pcm_close, handle = "); log_file->write_raw(ptr2str(pcm_rec_ptr)); log_file->write_endl(); log_file->write_footer(); snd_pcm_hw_free(pcm_rec_ptr); snd_pcm_close(pcm_rec_ptr); pcm_rec_ptr = 0; } } bool t_alsa_io::open(const string& device, bool playback, bool capture, bool blocking, int channels, t_audio_sampleformat format, int sample_rate, bool short_latency) { t_audio_io::open(device, playback, capture, blocking, channels, format, sample_rate, short_latency); int mode = 0; string msg; this->short_latency = short_latency; const char* dev = device.c_str(); if(dev[0] == 0) dev = "default"; log_file->write_header("t_alsa_io::open", LOG_NORMAL); log_file->write_raw("Opening ALSA device: "); log_file->write_raw(dev); log_file->write_endl(); if (playback) log_file->write_raw("play\n"); if (capture) log_file->write_raw("capture\n"); log_file->write_footer(); if (playback && capture) { // Full duplex: Perform the operation in two steps if (!open(device, true, false, blocking, channels, format, sample_rate, short_latency)) return false; if (!open(device, false, true, blocking, channels, format, sample_rate, short_latency)) return false; return true; } snd_pcm_t* pcm_ptr; #define HANDLE_ALSA_ERROR(func) string msg(func); msg += " failed: "; msg += snd_strerror(err); \ log_file->write_report(msg, "t_alsa_io::open", LOG_NORMAL, LOG_CRITICAL); msg = TRANSLATE("Opening ALSA driver failed") + ": " + msg; \ ui->cb_display_msg(msg, MSG_CRITICAL); if(pcm_ptr) snd_pcm_close(pcm_ptr); return false; if (!blocking) mode = SND_PCM_NONBLOCK; int err = snd_pcm_open(&pcm_ptr, dev, playback ? SND_PCM_STREAM_PLAYBACK : SND_PCM_STREAM_CAPTURE, mode); if (err < 0) { string msg("snd_pcm_open failed: "); msg += snd_strerror(err); log_file->write_report(msg, "t_alsa_io::open", LOG_NORMAL, LOG_CRITICAL); msg = "Cannot open ALSA driver for PCM "; if (playback) { msg = TRANSLATE("Cannot open ALSA driver for PCM playback"); } else { msg = TRANSLATE("Cannot open ALSA driver for PCM capture"); } msg += ": "; msg += snd_strerror(err); ui->cb_display_msg(msg, MSG_CRITICAL); return false; } log_file->write_header("t_alsa_io::open", LOG_NORMAL, LOG_DEBUG); log_file->write_raw("snd_pcm_open succeeded, handle = "); log_file->write_raw(ptr2str(pcm_ptr)); log_file->write_endl(); log_file->write_footer(); snd_pcm_hw_params_t *hw_params; snd_pcm_sw_params_t *sw_params; // Set HW params if ((err = snd_pcm_hw_params_malloc (&hw_params)) < 0) { HANDLE_ALSA_ERROR("snd_pcm_hw_params_malloc"); } MEMMAN_NEW(hw_params); if ((err = snd_pcm_hw_params_any (pcm_ptr, hw_params)) < 0) { HANDLE_ALSA_ERROR("snd_pcm_hw_params_any"); } if ((err = snd_pcm_hw_params_set_access (pcm_ptr, hw_params, SND_PCM_ACCESS_RW_INTERLEAVED)) < 0) { HANDLE_ALSA_ERROR("snd_pcm_hw_params_set_access"); } snd_pcm_format_t fmt; int sample_bits; switch (format) { case SAMPLEFORMAT_S16: #ifdef WORDS_BIGENDIAN fmt = SND_PCM_FORMAT_S16_BE; #else fmt = SND_PCM_FORMAT_S16_LE; #endif sample_bits = 16; break; case SAMPLEFORMAT_U16: #ifdef WORDS_BIGENDIAN fmt = SND_PCM_FORMAT_U16_BE; #else fmt = SND_PCM_FORMAT_U16_LE; #endif sample_bits = 16; break; case SAMPLEFORMAT_S8: fmt = SND_PCM_FORMAT_S8; sample_bits = 8; break; case SAMPLEFORMAT_U8: fmt = SND_PCM_FORMAT_U8; sample_bits = 8; break; default: {HANDLE_ALSA_ERROR("invalid sample format");} } if ((err = snd_pcm_hw_params_set_format (pcm_ptr, hw_params, fmt)) < 0) { string s("snd_pcm_hw_params_set_format("); s += int2str(fmt); s += ")"; HANDLE_ALSA_ERROR(s); } // Some sound cards do not support the exact sample rate specified in the // wav files. Still we first try to set the exact sample rate instead of // specifying the 3rd parameter as -1 to choose an approximate. // For some reason on my first sound card that supports the exact rate, // I get mono sound when the -1 parameter is specified. if ((err = snd_pcm_hw_params_set_rate (pcm_ptr, hw_params, sample_rate, 0)) < 0) { msg = "Cannot set soundcard to exact sample rate of "; msg += int2str(sample_rate); msg += ".\nThe card will choose a lower approximate rate."; log_file->write_report(msg, "t_alsa_io::open", LOG_NORMAL, LOG_WARNING); if ((err = snd_pcm_hw_params_set_rate (pcm_ptr, hw_params, sample_rate, -1)) < 0) { string s("snd_pcm_hw_params_set_rate("); s += int2str(sample_rate); s += ")"; HANDLE_ALSA_ERROR(s); } } // Read back card rate for reporting in the log file. unsigned int card_rate; int card_dir; snd_pcm_hw_params_get_rate(hw_params, &card_rate, &card_dir); if ((err = snd_pcm_hw_params_set_channels (pcm_ptr, hw_params, channels)) < 0) { string s("snd_pcm_hw_params_set_channels("); s += int2str(channels); s += ")"; HANDLE_ALSA_ERROR(s); } // Note: The buffersize is in FRAMES, not BYTES (one frame = sizeof(sample) * channels) snd_pcm_uframes_t buffersize; unsigned int periods = 8; // Double buffering // Set the size of one period in samples if (short_latency) { if (playback) { buffersize = sys_config->get_alsa_play_period_size(); } else { buffersize = sys_config->get_alsa_capture_period_size(); } } else { buffersize = 1024; } if ((err = snd_pcm_hw_params_set_period_size_near (pcm_ptr, hw_params, &buffersize, nullptr)) < 0) { HANDLE_ALSA_ERROR("snd_pcm_hw_params_set_period_size_near"); } // The number of periods determines the ALSA application buffer size. // This size must be larger than the jitter buffer. // TODO: use some more sophisticated algorithm here: read back the period // size and calculate the number of periods needed (only in the // short latency case)? if (buffersize <= 64) { periods *= 8; } else if (buffersize <= 256) { periods *= 4; } if ((err = snd_pcm_hw_params_set_periods(pcm_ptr, hw_params, periods, 1)) < 0) { if ((err = snd_pcm_hw_params_set_periods_near(pcm_ptr, hw_params, &periods, nullptr)) < 0) { HANDLE_ALSA_ERROR("snd_pcm_hw_params_set_periods"); } } if ((err = snd_pcm_hw_params (pcm_ptr, hw_params)) < 0) { HANDLE_ALSA_ERROR("snd_pcm_hw_params"); } // Find out if the sound card supports pause functionality can_pause = (snd_pcm_hw_params_can_pause(hw_params) == 1); MEMMAN_DELETE(hw_params); snd_pcm_hw_params_free(hw_params); // Set SW params if ((err = snd_pcm_sw_params_malloc(&sw_params)) < 0) { HANDLE_ALSA_ERROR("snd_pcm_sw_params_malloc"); } MEMMAN_NEW(sw_params); if ((err = snd_pcm_sw_params_current (pcm_ptr, sw_params)) < 0) { HANDLE_ALSA_ERROR("snd_pcm_sw_params_current"); } if ((err = snd_pcm_sw_params (pcm_ptr, sw_params)) < 0) { HANDLE_ALSA_ERROR("snd_pcm_sw_params"); } MEMMAN_DELETE(sw_params); snd_pcm_sw_params_free(sw_params); if ((err = snd_pcm_prepare (pcm_ptr)) < 0) { HANDLE_ALSA_ERROR("snd_pcm_prepare"); } if (playback) { pcm_play_ptr = pcm_ptr; play_framesize = (sample_bits / 8) * channels; play_buffersize = (int)buffersize * periods * play_framesize; play_periods = periods; log_file->write_header("t_alsa_io::open", LOG_NORMAL, LOG_DEBUG); log_file->write_raw("ALSA playback buffer settings.\n"); log_file->write_raw("Rate = "); log_file->write_raw(card_rate); log_file->write_raw(" frames/sec\n"); log_file->write_raw("Frame size = "); log_file->write_raw(play_framesize); log_file->write_raw(" bytes\n"); log_file->write_raw("Periods = "); log_file->write_raw(play_periods); log_file->write_endl(); log_file->write_raw("Period size = "); log_file->write_raw(buffersize * play_framesize); log_file->write_raw(" bytes\n"); log_file->write_raw("Buffer size = "); log_file->write_raw(play_buffersize); log_file->write_raw(" bytes\n"); log_file->write_raw("Can pause: "); log_file->write_bool(can_pause); log_file->write_endl(); log_file->write_footer(); } else { // Since audio_rx checks buffer before reading, start manually if ((err = snd_pcm_start(pcm_ptr)) < 0) { HANDLE_ALSA_ERROR("snd_pcm_start"); } pcm_rec_ptr = pcm_ptr; rec_framesize = (sample_bits / 8) * channels; rec_buffersize = (int)buffersize * periods * rec_framesize; rec_periods = periods; // HACK: snd_pcm_delay seems not to work for the dsnoop device. // This code determines if snd_pcm is working. As the capture // device just started, it should return zero or a small number. // So if it returns that more than half of the buffer is filled // already, it seems broken. rec_delay_broken = false; if (get_buffer_space(true) > rec_buffersize / 2) { rec_delay_broken = true; log_file->write_report( "snd_pcm_delay does not work for capture buffer.", "t_alsa_io::open", LOG_NORMAL, LOG_DEBUG); } log_file->write_header("t_alsa_io::open", LOG_NORMAL, LOG_DEBUG); log_file->write_raw("ALSA capture buffer settings.\n"); log_file->write_raw("Rate = "); log_file->write_raw(card_rate); log_file->write_raw(" frames/sec\n"); log_file->write_raw("Frame size = "); log_file->write_raw(rec_framesize); log_file->write_raw(" bytes\n"); log_file->write_raw("Periods = "); log_file->write_raw(rec_periods); log_file->write_endl(); log_file->write_raw("Period size = "); log_file->write_raw(buffersize * rec_framesize); log_file->write_raw(" bytes\n"); log_file->write_raw("Buffer size = "); log_file->write_raw(rec_buffersize); log_file->write_raw(" bytes\n"); log_file->write_raw("Can pause: "); log_file->write_bool(can_pause); log_file->write_endl(); log_file->write_footer(); } return true; #undef HANDLE_ALSA_ERROR } void t_alsa_io::enable(bool enable_playback, bool enable_recording) { if (!can_pause) return; if (pcm_play_ptr) { snd_pcm_pause(pcm_play_ptr, (int)enable_playback); } if (pcm_rec_ptr) { snd_pcm_pause(pcm_rec_ptr, (int)enable_recording); } } void t_alsa_io::flush(bool playback_buffer, bool recording_buffer) { if (playback_buffer && pcm_play_ptr) { // snd_pcm_reset(pcm_play_ptr); snd_pcm_drop(pcm_play_ptr); snd_pcm_prepare(pcm_play_ptr); snd_pcm_start(pcm_play_ptr); } if (recording_buffer && pcm_rec_ptr) { // For some obscure reason snd_pcm_reset causes the CPU // load to rise to 99.9% when playing and capturing is // done on the same sound card. // Therefor snd_pcm_reset is replaced by functions to // stop the card, drop samples and start again. // snd_pcm_reset(pcm_rec_ptr); snd_pcm_drop(pcm_rec_ptr); snd_pcm_prepare(pcm_rec_ptr); snd_pcm_start(pcm_rec_ptr); } } int t_alsa_io::get_buffer_space(bool is_recording_buffer) { int rv; int err; snd_pcm_sframes_t delay; snd_pcm_status_t* status; snd_pcm_status_alloca(&status); if(is_recording_buffer) { if(!pcm_rec_ptr) return 0; // This does not work as snd_pcm_status_get_avail_max does not return // accurate results. // snd_pcm_status(pcm_rec_ptr, status); // rv = rec_framesize * snd_pcm_status_get_avail_max(status); snd_pcm_hwsync(pcm_rec_ptr); if ((err = snd_pcm_delay(pcm_rec_ptr, &delay)) < 0) { string msg = "snd_pcm_delay for capture buffer failed: "; msg += snd_strerror(err); log_file->write_report(msg, "t_alsa_io::get_buffer_space", LOG_NORMAL, LOG_DEBUG); delay = 0; snd_pcm_prepare(pcm_rec_ptr); } if (rec_delay_broken) { rv = 0; // there is no way to get an accurate number } else { rv = int(delay * rec_framesize); } if (rv > rec_buffersize) { rv = rec_buffersize; // capture buffer overrun snd_pcm_prepare(pcm_rec_ptr); } } else { if(!pcm_play_ptr) return 0; snd_pcm_status(pcm_play_ptr, status); rv = play_framesize * snd_pcm_status_get_avail_max(status); if (rv > play_buffersize) { rv = play_buffersize; // playback buffer underrun snd_pcm_prepare(pcm_play_ptr); } } return rv; } int t_alsa_io::get_buffer_size(bool is_recording_buffer) { if (is_recording_buffer) return rec_buffersize; else return play_buffersize; } bool t_alsa_io::play_buffer_underrun(void) { if (!pcm_play_ptr) return false; return snd_pcm_state(pcm_play_ptr) == SND_PCM_STATE_XRUN; } int t_alsa_io::read(unsigned char* buf, int len) { string msg; if (!pcm_rec_ptr) { log_file->write_report("Illegal pcm_rec_prt.", "t_alsa_io::read", LOG_NORMAL, LOG_CRITICAL); return -1; } int len_frames = len / rec_framesize; int read_frames = 0; for(;;) { int read = snd_pcm_readi(pcm_rec_ptr, buf, len_frames); if (read == -EPIPE) { msg = "Capture buffer overrun."; log_file->write_report(msg, "t_alsa_io::read", LOG_NORMAL, LOG_DEBUG); snd_pcm_prepare(pcm_rec_ptr); snd_pcm_start(pcm_rec_ptr); continue; } else if (read <= 0) { msg = "PCM read error: "; msg += snd_strerror(read); log_file->write_report(msg, "t_alsa_io::read", LOG_NORMAL, LOG_DEBUG); return -1; } else if (read < len_frames) { buf += rec_framesize * read; len_frames -= read; read_frames += read; continue; } return (read_frames + read) * rec_framesize; } } int t_alsa_io::write(const unsigned char* buf, int len) { int len_frames = len / play_framesize; int frames_written = 0; string msg; for (;;) { if(!pcm_play_ptr) return -1; int written = snd_pcm_writei(pcm_play_ptr, buf, len_frames); if (written == -EPIPE) { msg = "Playback buffer underrun."; log_file->write_report(msg, "t_alsa_io::write", LOG_NORMAL, LOG_DEBUG); snd_pcm_prepare(pcm_play_ptr); continue; } else if (written == -EINVAL) { msg = "Invalid argument passed to snd_pcm_writei: "; msg += snd_strerror(written); log_file->write_report(msg, "t_alsa_io::write", LOG_NORMAL, LOG_DEBUG); } else if (written < 0) { msg = "PCM write error: "; msg += snd_strerror(written); log_file->write_report(msg, "t_alsa_io::write", LOG_NORMAL, LOG_DEBUG); return -1; } else if (written < len_frames) { buf += written * play_framesize; len_frames -= written; frames_written += written; continue; } return (frames_written + written) * play_framesize; } } // This function fills the specified list with ALSA hardware soundcards found on the system. // It uses plughw:xx instead of hw:xx for specifiers, because hw:xx are not practical to // use (e.g. they require a resampler/channel mixer in the application). // playback indicates if a list with playback or capture devices should be created. void alsa_fill_soundcards(list& l, bool playback) { int err = 0; int card = -1, device = -1; snd_ctl_t *handle; snd_ctl_card_info_t *info; snd_pcm_info_t *pcminfo; snd_ctl_card_info_alloca(&info); snd_pcm_info_alloca(&pcminfo); for (;;) { err = snd_card_next(&card); if (err < 0 || card < 0) break; if (card >= 0) { string name = "hw:"; name += int2str(card); if ((err = snd_ctl_open(&handle, name.c_str(), 0)) < 0) continue; if ((err = snd_ctl_card_info(handle, info)) < 0) { snd_ctl_close(handle); continue; } const char *card_name = snd_ctl_card_info_get_name(info); for (;;) { err = snd_ctl_pcm_next_device(handle, &device); if (err < 0 || device < 0) break; snd_pcm_info_set_device(pcminfo, device); snd_pcm_info_set_subdevice(pcminfo, 0); if (playback) { snd_pcm_info_set_stream(pcminfo, SND_PCM_STREAM_PLAYBACK); } else { snd_pcm_info_set_stream(pcminfo, SND_PCM_STREAM_CAPTURE); } if ((err = snd_ctl_pcm_info(handle, pcminfo)) < 0) continue; t_audio_device dev; dev.device = string("plughw:") + int2str(card) + string(",") + int2str(device); dev.name = string(card_name) + " ("; dev.name += snd_pcm_info_get_name(pcminfo); dev.name += ")"; dev.type = t_audio_device::ALSA; l.push_back(dev); } snd_ctl_close(handle); } } } // endif ifdef HAVE_LIBASOUND #endif