/* Copyright (C) 2001 Paul Davis 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, write to the Free Software Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA. $Id$ */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include extern void store_work_time (int); extern void store_wait_time (int); extern void show_wait_times (); extern void show_work_times (); #undef DEBUG_WAKEUP static void alsa_driver_release_channel_dependent_memory (alsa_driver_t *driver) { if (driver->playback_addr) { free (driver->playback_addr); driver->playback_addr = 0; } if (driver->capture_addr) { free (driver->capture_addr); driver->capture_addr = 0; } if (driver->silent) { free (driver->silent); driver->silent = 0; } if (driver->dither_state) { free (driver->dither_state); driver->dither_state = 0; } } static int alsa_driver_check_capabilities (alsa_driver_t *driver) { return 0; } static int alsa_driver_check_card_type (alsa_driver_t *driver) { int err; snd_ctl_card_info_t *card_info; snd_ctl_card_info_alloca (&card_info); if ((err = snd_ctl_open (&driver->ctl_handle, driver->alsa_name, 0)) < 0) { jack_error ("control open \"%s\" (%s)", driver->alsa_name, snd_strerror(err)); return -1; } if ((err = snd_ctl_card_info(driver->ctl_handle, card_info)) < 0) { jack_error ("control hardware info \"%s\" (%s)", driver->alsa_name, snd_strerror (err)); snd_ctl_close (driver->ctl_handle); return -1; } driver->alsa_driver = strdup(snd_ctl_card_info_get_driver (card_info)); return alsa_driver_check_capabilities (driver); } static int alsa_driver_hammerfall_hardware (alsa_driver_t *driver) { driver->hw = jack_alsa_hammerfall_hw_new (driver); return 0; } static int alsa_driver_hdsp_hardware (alsa_driver_t *driver) { driver->hw = jack_alsa_hdsp_hw_new (driver); return 0; } static int alsa_driver_ice1712_hardware (alsa_driver_t *driver) { driver->hw = jack_alsa_ice1712_hw_new (driver); return 0; } static int alsa_driver_generic_hardware (alsa_driver_t *driver) { driver->hw = jack_alsa_generic_hw_new (driver); return 0; } static int alsa_driver_hw_specific (alsa_driver_t *driver, int hw_monitoring) { int err; if (!strcmp(driver->alsa_driver, "RME9652")) { if ((err = alsa_driver_hammerfall_hardware (driver)) != 0) { return err; } } else if (!strcmp(driver->alsa_driver, "H-DSP")) { if ((err = alsa_driver_hdsp_hardware (driver)) !=0) { return err; } } else if (!strcmp(driver->alsa_driver, "ICE1712")) { if ((err = alsa_driver_ice1712_hardware (driver)) !=0) { return err; } } else { if ((err = alsa_driver_generic_hardware (driver)) != 0) { return err; } } if (driver->hw->capabilities & Cap_HardwareMonitoring) { driver->has_hw_monitoring = TRUE; /* XXX need to ensure that this is really FALSE or TRUE or whatever*/ driver->hw_monitoring = hw_monitoring; } else { driver->has_hw_monitoring = FALSE; driver->hw_monitoring = FALSE; } if (driver->hw->capabilities & Cap_ClockLockReporting) { driver->has_clock_sync_reporting = TRUE; } else { driver->has_clock_sync_reporting = FALSE; } return 0; } static void alsa_driver_setup_io_function_pointers (alsa_driver_t *driver) { switch (driver->sample_bytes) { case 2: if (driver->interleaved) { driver->channel_copy = memcpy_interleave_d16_s16; } else { driver->channel_copy = memcpy_fake; } switch (driver->dither) { case Rectangular: printf("Rectangular dithering at 16 bits\n"); driver->write_via_copy = sample_move_dither_rect_d16_sS; break; case Triangular: printf("Triangular dithering at 16 bits\n"); driver->write_via_copy = sample_move_dither_tri_d16_sS; break; case Shaped: printf("Noise-shaped dithering at 16 bits\n"); driver->write_via_copy = sample_move_dither_shaped_d16_sS; break; default: driver->write_via_copy = sample_move_d16_sS; break; } driver->read_via_copy = sample_move_dS_s16; break; case 4: if (driver->interleaved) { driver->channel_copy = memcpy_interleave_d32_s32; } else { driver->channel_copy = memcpy_fake; } switch (driver->dither) { case Rectangular: printf("Rectangular dithering at 16 bits\n"); driver->write_via_copy = sample_move_dither_rect_d32u24_sS; break; case Triangular: printf("Triangular dithering at 16 bits\n"); driver->write_via_copy = sample_move_dither_tri_d32u24_sS; break; case Shaped: printf("Noise-shaped dithering at 16 bits\n"); driver->write_via_copy = sample_move_dither_shaped_d32u24_sS; break; default: driver->write_via_copy = sample_move_d32u24_sS; break; } driver->read_via_copy = sample_move_dS_s32u24; break; } } static int alsa_driver_configure_stream (alsa_driver_t *driver, const char *stream_name, snd_pcm_t *handle, snd_pcm_hw_params_t *hw_params, snd_pcm_sw_params_t *sw_params, unsigned long *nchns) { int err; if ((err = snd_pcm_hw_params_any (handle, hw_params)) < 0) { jack_error ("ALSA: no playback configurations available (%s)", snd_strerror (err)); return -1; } if ((err = snd_pcm_hw_params_set_periods_integer (handle, hw_params)) < 0) { jack_error ("ALSA: cannot restrict period size to integral value."); return -1; } if ((err = snd_pcm_hw_params_set_access (handle, hw_params, SND_PCM_ACCESS_MMAP_NONINTERLEAVED)) < 0) { if ((err = snd_pcm_hw_params_set_access (handle, hw_params, SND_PCM_ACCESS_MMAP_INTERLEAVED)) < 0) { jack_error ("ALSA: mmap-based access is not possible for the %s " "stream of this audio interface", stream_name); return -1; } } if ((err = snd_pcm_hw_params_set_format (handle, hw_params, SND_PCM_FORMAT_S32)) < 0) { if ((err = snd_pcm_hw_params_set_format (handle, hw_params, SND_PCM_FORMAT_S16)) < 0) { jack_error ("Sorry. The audio interface \"%s\"" "doesn't support either of the two hardware sample formats that jack can use.", driver->alsa_name); return -1; } } if ((err = snd_pcm_hw_params_set_rate_near (handle, hw_params, driver->frame_rate, 0)) < 0) { jack_error ("ALSA: cannot set sample/frame rate to %u for %s", driver->frame_rate, stream_name); return -1; } *nchns = snd_pcm_hw_params_get_channels_max (hw_params); if (*nchns > 1024) { /* the hapless user is an unwitting victim of the "default" ALSA PCM device, which can support up to 16 million channels. since they can't be bothered to set up a proper default device, limit the number of channels for them to a sane default. */ jack_error ("You appear to be using the ALSA software \"plug\" layer, probably\n" "a result of using the \"default\" ALSA device. This is less\n" "efficient than it could be. Consider using a ~/.asoundrc file\n" "to define a hardware audio device rather than using the plug layer\n"); *nchns = 2; } if ((err = snd_pcm_hw_params_set_channels (handle, hw_params, *nchns)) < 0) { jack_error ("ALSA: cannot set channel count to %u for %s", *nchns, stream_name); return -1; } if ((err = snd_pcm_hw_params_set_period_size (handle, hw_params, driver->frames_per_cycle, 0)) < 0) { jack_error ("ALSA: cannot set period size to %u frames for %s", driver->frames_per_cycle, stream_name); return -1; } if ((err = snd_pcm_hw_params_set_periods (handle, hw_params, driver->user_nperiods, 0)) < 0) { jack_error ("ALSA: cannot set number of periods to %u for %s", driver->user_nperiods, stream_name); return -1; } if ((err = snd_pcm_hw_params_set_buffer_size (handle, hw_params, driver->user_nperiods * driver->frames_per_cycle)) < 0) { jack_error ("ALSA: cannot set buffer length to %u for %s", driver->user_nperiods * driver->frames_per_cycle, stream_name); return -1; } if ((err = snd_pcm_hw_params (handle, hw_params)) < 0) { jack_error ("ALSA: cannot set hardware parameters for %s", stream_name); return -1; } snd_pcm_sw_params_current (handle, sw_params); if ((err = snd_pcm_sw_params_set_start_threshold (handle, sw_params, 0U)) < 0) { jack_error ("ALSA: cannot set start mode for %s", stream_name); return -1; } if ((err = snd_pcm_sw_params_set_stop_threshold (handle, sw_params, driver->user_nperiods * driver->frames_per_cycle)) < 0) { jack_error ("ALSA: cannot set stop mode for %s", stream_name); return -1; } if ((err = snd_pcm_sw_params_set_silence_threshold (handle, sw_params, 0)) < 0) { jack_error ("ALSA: cannot set silence threshold for %s", stream_name); return -1; } if ((err = snd_pcm_sw_params_set_silence_size (handle, sw_params, driver->frames_per_cycle * driver->nfragments)) < 0) { jack_error ("ALSA: cannot set silence size for %s", stream_name); return -1; } if ((err = snd_pcm_sw_params_set_avail_min (handle, sw_params, driver->frames_per_cycle)) < 0) { jack_error ("ALSA: cannot set avail min for %s", stream_name); return -1; } if ((err = snd_pcm_sw_params (handle, sw_params)) < 0) { jack_error ("ALSA: cannot set software parameters for %s", stream_name); return -1; } return 0; } static int alsa_driver_set_parameters (alsa_driver_t *driver, jack_nframes_t frames_per_cycle, jack_nframes_t user_nperiods, jack_nframes_t rate) { int p_noninterleaved = 0; int c_noninterleaved = 0; snd_pcm_format_t c_format = 0; snd_pcm_format_t p_format = 0; int dir; unsigned int p_period_size = 0; unsigned int c_period_size = 0; unsigned int p_nfragments = 0; unsigned int c_nfragments = 0; channel_t chn; driver->frame_rate = rate; driver->frames_per_cycle = frames_per_cycle; driver->user_nperiods = user_nperiods; if (driver->capture_handle) { if (alsa_driver_configure_stream (driver, "capture", driver->capture_handle, driver->capture_hw_params, driver->capture_sw_params, &driver->capture_nchannels)) { jack_error ("ALSA: cannot configure capture channel"); return -1; } } if (driver->playback_handle) { if (alsa_driver_configure_stream (driver, "playback", driver->playback_handle, driver->playback_hw_params, driver->playback_sw_params, &driver->playback_nchannels)) { jack_error ("ALSA: cannot configure playback channel"); return -1; } } /* check the fragment size, since thats non-negotiable */ if (driver->playback_handle) { p_period_size = snd_pcm_hw_params_get_period_size (driver->playback_hw_params, &dir); p_nfragments = snd_pcm_hw_params_get_periods (driver->playback_hw_params, &dir); p_format = (snd_pcm_format_t) snd_pcm_hw_params_get_format (driver->playback_hw_params); p_noninterleaved = (snd_pcm_hw_params_get_access (driver->playback_hw_params) == SND_PCM_ACCESS_MMAP_NONINTERLEAVED); if (p_period_size != driver->frames_per_cycle) { jack_error ("alsa_pcm: requested an interrupt every %u frames but got %uc frames for playback", driver->frames_per_cycle,p_period_size); return -1; } } if (driver->capture_handle) { c_period_size = snd_pcm_hw_params_get_period_size (driver->capture_hw_params, &dir); c_nfragments = snd_pcm_hw_params_get_periods (driver->capture_hw_params, &dir); c_format = (snd_pcm_format_t) snd_pcm_hw_params_get_format (driver->capture_hw_params); c_noninterleaved = (snd_pcm_hw_params_get_access (driver->capture_hw_params) == SND_PCM_ACCESS_MMAP_NONINTERLEAVED); if (c_period_size != driver->frames_per_cycle) { jack_error ("alsa_pcm: requested an interrupt every %u frames but got %uc frames for capture", driver->frames_per_cycle,p_period_size); return -1; } } if (driver->capture_handle && driver->playback_handle) { if (p_nfragments != c_nfragments) { jack_error ("alsa_pcm: different period counts for playback and capture!"); return -1; } /* Check that we are using the same sample format on both streams */ if (p_format != c_format) { jack_error ("Sorry. The PCM device \"%s\"" "doesn't support the same sample format for capture and playback." "We cannot use this PCM device.", driver->alsa_name); return -1; } /* check interleave setup */ if (c_noninterleaved != p_noninterleaved) { jack_error ("ALSA: the playback and capture components for this PCM device differ " "in their use of channel interleaving. We cannot use this PCM device."); return -1; } driver->nfragments = c_nfragments; driver->interleaved = !c_noninterleaved; driver->sample_format = c_format; } else if (driver->capture_handle) { driver->nfragments = c_nfragments; driver->interleaved = !c_noninterleaved; driver->sample_format = c_format; } else { driver->nfragments = p_nfragments; driver->interleaved = !p_noninterleaved; driver->sample_format = p_format; } driver->buffer_frames = driver->frames_per_cycle * driver->nfragments; driver->sample_bytes = snd_pcm_format_physical_width (driver->sample_format) / 8; switch (driver->sample_format) { case SND_PCM_FORMAT_S32_LE: case SND_PCM_FORMAT_S16_LE: case SND_PCM_FORMAT_S32_BE: case SND_PCM_FORMAT_S16_BE: break; default: jack_error ("programming error: unhandled format type"); exit (1); } if (driver->interleaved) { driver->interleave_unit = snd_pcm_format_physical_width (driver->sample_format) / 8; driver->playback_interleave_skip = driver->interleave_unit * driver->playback_nchannels; driver->capture_interleave_skip = driver->interleave_unit * driver->capture_nchannels; } else { driver->interleave_unit = 0; /* NOT USED */ driver->playback_interleave_skip = snd_pcm_format_physical_width (driver->sample_format) / 8; driver->capture_interleave_skip = driver->playback_interleave_skip; } if (driver->playback_nchannels > driver->capture_nchannels) { driver->max_nchannels = driver->playback_nchannels; driver->user_nchannels = driver->capture_nchannels; } else { driver->max_nchannels = driver->capture_nchannels; driver->user_nchannels = driver->playback_nchannels; } alsa_driver_setup_io_function_pointers (driver); /* Allocate and initialize structures that rely on the channels counts. */ /* set up the bit pattern that is used to record which channels require action on every cycle. any bits that are not set after the engine's process() call indicate channels that potentially need to be silenced. XXX this is limited to channels. Use a bitset type instead. */ driver->channel_done_bits = 0; if (driver->playback_handle) { driver->playback_addr = (char **) malloc (sizeof (char *) * driver->playback_nchannels); memset (driver->playback_addr, 0, sizeof (char *) * driver->playback_nchannels); driver->silent = (unsigned long *) malloc (sizeof (unsigned long) * driver->playback_nchannels); for (chn = 0; chn < driver->playback_nchannels; chn++) { driver->silent[chn] = 0; } for (chn = 0; chn < driver->playback_nchannels; chn++) { driver->channel_done_bits |= (1<dither_state = (dither_state_t *) calloc ( driver->playback_nchannels, sizeof (dither_state_t)); } if (driver->capture_handle) { driver->capture_addr = (char **) malloc (sizeof (char *) * driver->capture_nchannels); memset (driver->capture_addr, 0, sizeof (char *) * driver->capture_nchannels); } driver->clock_sync_data = (ClockSyncStatus *) malloc (sizeof (ClockSyncStatus) * driver->capture_nchannels > driver->playback_nchannels ? driver->capture_nchannels : driver->playback_nchannels); driver->period_usecs = (((float) driver->frames_per_cycle) / driver->frame_rate) * 1000000.0f; if (driver->engine) { driver->engine->set_buffer_size (driver->engine, driver->frames_per_cycle); } return 0; } static int alsa_driver_reset_parameters (alsa_driver_t *driver, jack_nframes_t frames_per_cycle, jack_nframes_t user_nperiods, jack_nframes_t rate) { /* XXX unregister old ports ? */ alsa_driver_release_channel_dependent_memory (driver); return alsa_driver_set_parameters (driver, frames_per_cycle, user_nperiods, rate); } static int alsa_driver_get_channel_addresses (alsa_driver_t *driver, snd_pcm_uframes_t *capture_avail, snd_pcm_uframes_t *playback_avail, snd_pcm_uframes_t *capture_offset, snd_pcm_uframes_t *playback_offset) { unsigned long err; channel_t chn; if (capture_avail) { if ((err = snd_pcm_mmap_begin (driver->capture_handle, &driver->capture_areas, (snd_pcm_uframes_t *) capture_offset, (snd_pcm_uframes_t *) capture_avail)) < 0) { jack_error ("ALSA-HW: %s: mmap areas info error", driver->alsa_name); return -1; } for (chn = 0; chn < driver->capture_nchannels; chn++) { const snd_pcm_channel_area_t *a = &driver->capture_areas[chn]; driver->capture_addr[chn] = (char *) a->addr + ((a->first + a->step * *capture_offset) / 8); } } if (playback_avail) { if ((err = snd_pcm_mmap_begin (driver->playback_handle, &driver->playback_areas, (snd_pcm_uframes_t *) playback_offset, (snd_pcm_uframes_t *) playback_avail)) < 0) { jack_error ("ALSA-HW: %s: mmap areas info error ", driver->alsa_name); return -1; } for (chn = 0; chn < driver->playback_nchannels; chn++) { const snd_pcm_channel_area_t *a = &driver->playback_areas[chn]; driver->playback_addr[chn] = (char *) a->addr + ((a->first + a->step * *playback_offset) / 8); } } return 0; } static int alsa_driver_audio_start (alsa_driver_t *driver) { int err; snd_pcm_uframes_t poffset, pavail; channel_t chn; driver->poll_last = 0; driver->poll_next = 0; if (driver->playback_handle) { if ((err = snd_pcm_prepare (driver->playback_handle)) < 0) { jack_error ("ALSA-HW: prepare error for playback on \"%s\" (%s)", driver->alsa_name, snd_strerror(err)); return -1; } } if (driver->capture_handle && driver->capture_and_playback_not_synced) { if ((err = snd_pcm_prepare (driver->capture_handle)) < 0) { jack_error ("ALSA-HW: prepare error for capture on \"%s\" (%s)", driver->alsa_name, snd_strerror(err)); return -1; } } if (driver->hw_monitoring) { driver->hw->set_input_monitor_mask (driver->hw, driver->input_monitor_mask); } if (driver->playback_handle) { /* fill playback buffer with zeroes, and mark all fragments as having data. */ pavail = snd_pcm_avail_update (driver->playback_handle); if (pavail != driver->buffer_frames) { jack_error ("ALSA-HW: full buffer not available at start"); return -1; } if (alsa_driver_get_channel_addresses (driver, 0, &pavail, 0, &poffset)) { return -1; } /* XXX this is cheating. ALSA offers no guarantee that we can access the entire buffer at any one time. It works on most hardware tested so far, however, buts its a liability in the long run. I think that alsa-lib may have a better function for doing this here, where the goal is to silence the entire buffer. */ for (chn = 0; chn < driver->playback_nchannels; chn++) { alsa_driver_silence_on_channel (driver, chn, driver->buffer_frames); } snd_pcm_mmap_commit (driver->playback_handle, poffset, driver->buffer_frames); if ((err = snd_pcm_start (driver->playback_handle)) < 0) { jack_error ("could not start playback (%s)", snd_strerror (err)); return -1; } } if (driver->capture_handle && driver->capture_and_playback_not_synced) { if ((err = snd_pcm_start (driver->capture_handle)) < 0) { jack_error ("could not start capture (%s)", snd_strerror (err)); return -1; } } if (driver->hw_monitoring && (driver->input_monitor_mask || driver->all_monitor_in)) { if (driver->all_monitor_in) { driver->hw->set_input_monitor_mask (driver->hw, ~0U); } else { driver->hw->set_input_monitor_mask (driver->hw, driver->input_monitor_mask); } } if (driver->playback_handle) { driver->playback_nfds = snd_pcm_poll_descriptors_count (driver->playback_handle); } else { driver->playback_nfds = 0; } if (driver->capture_handle) { driver->capture_nfds = snd_pcm_poll_descriptors_count (driver->capture_handle); } else { driver->capture_nfds = 0; } if (driver->pfd) free (driver->pfd); driver->pfd = (struct pollfd *) malloc (sizeof (struct pollfd) * (driver->playback_nfds + driver->capture_nfds + 2)); return 0; } static int alsa_driver_audio_stop (alsa_driver_t *driver) { int err; if (driver->playback_handle) { if ((err = snd_pcm_drop (driver->playback_handle)) < 0) { jack_error ("alsa_pcm: channel flush for playback failed (%s)", snd_strerror (err)); return -1; } } if (!driver->playback_handle || driver->capture_and_playback_not_synced) { if (driver->capture_handle) { if ((err = snd_pcm_drop (driver->capture_handle)) < 0) { jack_error ("alsa_pcm: channel flush for capture failed (%s)", snd_strerror (err)); return -1; } } } driver->hw->set_input_monitor_mask (driver->hw, 0); return 0; } static int alsa_driver_xrun_recovery (alsa_driver_t *driver) { snd_pcm_status_t *status; int res; snd_pcm_status_alloca(&status); if (driver->capture_handle) { if ((res = snd_pcm_status(driver->capture_handle, status)) < 0) { jack_error("status error: %s", snd_strerror(res)); } } else { if ((res = snd_pcm_status(driver->playback_handle, status)) < 0) { jack_error("status error: %s", snd_strerror(res)); } } if (snd_pcm_status_get_state(status) == SND_PCM_STATE_XRUN) { struct timeval now, diff, tstamp; gettimeofday(&now, 0); snd_pcm_status_get_trigger_tstamp(status, &tstamp); timersub(&now, &tstamp, &diff); fprintf(stderr, "\n\n**** alsa_pcm: xrun of at least %.3f msecs\n\n", diff.tv_sec * 1000 + diff.tv_usec / 1000.0); } if (alsa_driver_audio_stop (driver) || alsa_driver_audio_start (driver)) { return -1; } return 0; } static void alsa_driver_silence_untouched_channels (alsa_driver_t *driver, jack_nframes_t nframes) { channel_t chn; for (chn = 0; chn < driver->playback_nchannels; chn++) { if ((driver->channels_not_done & (1<silent[chn] < driver->buffer_frames) { alsa_driver_silence_on_channel_no_mark (driver, chn, nframes); driver->silent[chn] += nframes; } } } } void alsa_driver_set_clock_sync_status (alsa_driver_t *driver, channel_t chn, ClockSyncStatus status) { driver->clock_sync_data[chn] = status; alsa_driver_clock_sync_notify (driver, chn, status); } static int under_gdb = FALSE; static jack_nframes_t alsa_driver_wait (alsa_driver_t *driver, int extra_fd, int *status, float *delayed_usecs) { snd_pcm_sframes_t avail = 0; snd_pcm_sframes_t capture_avail = 0; snd_pcm_sframes_t playback_avail = 0; int xrun_detected = FALSE; int need_capture; int need_playback; int i; unsigned long long poll_enter, poll_ret; *status = -1; *delayed_usecs = 0; need_capture = driver->capture_handle ? 1 : 0; if (extra_fd >= 0) { need_playback = 0; } else { need_playback = driver->playback_handle ? 1 : 0; } again: while (need_playback || need_capture) { int p_timed_out, c_timed_out; int ci = 0; int nfds; nfds = 0; if (need_playback) { snd_pcm_poll_descriptors (driver->playback_handle, &driver->pfd[0], driver->playback_nfds); nfds += driver->playback_nfds; } if (need_capture) { snd_pcm_poll_descriptors (driver->capture_handle, &driver->pfd[nfds], driver->capture_nfds); ci = nfds; nfds += driver->capture_nfds; } /* ALSA doesn't set POLLERR in some versions of 0.9.X */ for (i = 0; i < nfds; i++) { driver->pfd[i].events |= POLLERR; } if (extra_fd >= 0) { driver->pfd[nfds].fd = extra_fd; driver->pfd[nfds].events = POLLIN|POLLERR|POLLHUP|POLLNVAL; nfds++; } poll_enter = get_cycles (); if (poll (driver->pfd, nfds, (int) floor ((1.5f * driver->period_usecs) / 1000.0f)) < 0) { if (errno == EINTR) { printf ("poll interrupt\n"); // this happens mostly when run // under gdb, or when exiting due to a signal if (under_gdb) { goto again; } *status = -2; return 0; } jack_error ("ALSA: poll call failed (%s)", strerror (errno)); *status = -3; return 0; } poll_ret = get_cycles (); if (extra_fd < 0) { if (driver->poll_next && poll_ret > driver->poll_next) { *delayed_usecs = (float) (poll_ret - driver->poll_next) / driver->cpu_mhz; } driver->poll_last = poll_ret; driver->poll_next = poll_ret + (unsigned long long) floor ((driver->period_usecs * driver->cpu_mhz)); driver->engine->control->current_time.cycles = poll_ret; } #ifdef DEBUG_WAKEUP printf ("%Lu: checked %d fds, %.9f usecs since poll entered\n", poll_ret, nfds, (float) (poll_ret - poll_enter) / driver->cpu_mhz); #endif /* check to see if it was the extra FD that caused us to return from poll */ if (extra_fd >= 0) { if (driver->pfd[nfds-1].revents == 0) { /* we timed out on the extra fd */ *status = -4; return -1; } /* if POLLIN was the only bit set, we're OK */ *status = 0; return (driver->pfd[nfds-1].revents == POLLIN) ? 0 : -1; } p_timed_out = 0; if (need_playback) { for (i = 0; i < driver->playback_nfds; i++) { if (driver->pfd[i].revents & POLLERR) { xrun_detected = TRUE; } if (driver->pfd[i].revents == 0) { p_timed_out++; #ifdef DEBUG_WAKEUP fprintf (stderr, "%Lu playback stream timed out\n", poll_ret); #endif } } if (p_timed_out == 0) { need_playback = 0; #ifdef DEBUG_WAKEUP fprintf (stderr, "%Lu playback stream ready\n", poll_ret); #endif } } c_timed_out = 0; if (need_capture) { for (i = ci; i < nfds; i++) { if (driver->pfd[i].revents & POLLERR) { xrun_detected = TRUE; } if (driver->pfd[i].revents == 0) { c_timed_out++; #ifdef DEBUG_WAKEUP fprintf (stderr, "%Lu capture stream timed out\n", poll_ret); #endif } } if (c_timed_out == 0) { need_capture = 0; #ifdef DEBUG_WAKEUP fprintf (stderr, "%Lu capture stream ready\n", poll_ret); #endif } } if ((p_timed_out && (p_timed_out == driver->playback_nfds)) && (c_timed_out && (c_timed_out == driver->capture_nfds))){ jack_error ("ALSA: poll time out polled for %.6f", ((float) (poll_ret - poll_enter) / driver->cpu_mhz)); *status = -5; return 0; } } if (driver->capture_handle) { if ((capture_avail = snd_pcm_avail_update (driver->capture_handle)) < 0) { if (capture_avail == -EPIPE) { xrun_detected = TRUE; } else { jack_error ("unknown ALSA avail_update return value (%u)", capture_avail); } } } else { capture_avail = INT_MAX; /* odd, but see min() computation below */ } if (driver->playback_handle) { if ((playback_avail = snd_pcm_avail_update (driver->playback_handle)) < 0) { if (playback_avail == -EPIPE) { xrun_detected = TRUE; } else { jack_error ("unknown ALSA avail_update return value (%u)", playback_avail); } } } else { playback_avail = INT_MAX; /* odd, but see min() computation below */ } if (xrun_detected) { *status = alsa_driver_xrun_recovery (driver); return 0; } *status = 0; avail = capture_avail < playback_avail ? capture_avail : playback_avail; #ifdef DEBUG_WAKEUP fprintf (stderr, "wakup complete, avail = %lu, pavail = %lu cavail = %lu\n", avail, playback_avail, capture_avail); #endif /* constrain the available count to the nearest (round down) number of periods. */ return avail - (avail % driver->frames_per_cycle); } static int alsa_driver_process (alsa_driver_t *driver, jack_nframes_t nframes) { snd_pcm_sframes_t contiguous = 0; snd_pcm_sframes_t capture_avail = 0; snd_pcm_sframes_t playback_avail = 0; snd_pcm_uframes_t capture_offset = 0; snd_pcm_uframes_t playback_offset = 0; channel_t chn; JSList *node; jack_engine_t *engine = driver->engine; static int cnt = 0; int engine_ran = 0; cnt++; while (nframes) { if (driver->capture_handle) { if (driver->playback_handle) { /* DUPLEX */ capture_avail = (nframes > driver->frames_per_cycle) ? driver->frames_per_cycle : nframes; playback_avail = (nframes > driver->frames_per_cycle) ? driver->frames_per_cycle : nframes; if (alsa_driver_get_channel_addresses (driver, (snd_pcm_uframes_t *) &capture_avail, (snd_pcm_uframes_t *) &playback_avail, &capture_offset, &playback_offset) < 0) { return -1; } contiguous = capture_avail < playback_avail ? capture_avail : playback_avail; } else { /* CAPTURE ONLY */ capture_avail = (nframes > driver->frames_per_cycle) ? driver->frames_per_cycle : nframes; if (alsa_driver_get_channel_addresses (driver, (snd_pcm_uframes_t *) &capture_avail, (snd_pcm_uframes_t *) 0, &capture_offset, 0) < 0) { return -1; } contiguous = capture_avail; } } else { /* PLAYBACK ONLY */ playback_avail = (nframes > driver->frames_per_cycle) ? driver->frames_per_cycle : nframes; if (alsa_driver_get_channel_addresses (driver, (snd_pcm_uframes_t *) 0, (snd_pcm_uframes_t *) &playback_avail, 0, &playback_offset) < 0) { return -1; } contiguous = playback_avail; } driver->channels_not_done = driver->channel_done_bits; if (engine->process_lock (engine) == 0) { channel_t chn; jack_port_t *port; JSList *node; int ret; if (driver->capture_handle) { for (chn = 0, node = driver->capture_ports; node; node = jack_slist_next (node), chn++) { port = (jack_port_t *) node->data; if (!jack_port_connected (port)) { continue; } alsa_driver_read_from_channel (driver, chn, jack_port_get_buffer (port, nframes), nframes); } snd_pcm_mmap_commit (driver->capture_handle, capture_offset, contiguous); } if (contiguous != driver->frames_per_cycle) { jack_error ("wierd contiguous size %lu", contiguous); } if ((ret = engine->process (engine, contiguous)) != 0) { alsa_driver_audio_stop (driver); if (ret > 0) { engine->post_process (engine); } engine->process_unlock (engine); return ret; } engine_ran = 1; if (driver->playback_handle) { /* now move data from ports to channels */ for (chn = 0, node = driver->playback_ports; node; node = jack_slist_next (node), chn++) { jack_default_audio_sample_t *buf; jack_port_t *port = (jack_port_t *) node->data; if (!jack_port_connected (port)) { continue; } buf = jack_port_get_buffer (port, contiguous); alsa_driver_write_to_channel (driver, chn, buf, contiguous); } } } else { /* oh well, the engine can't run, so we'll just throw away this cycle's data ... */ snd_pcm_mmap_commit (driver->capture_handle, capture_offset, contiguous); } /* Now handle input monitoring */ driver->input_monitor_mask = 0; for (chn = 0, node = driver->capture_ports; node; node = jack_slist_next (node), chn++) { if (((jack_port_t *) node->data)->shared->monitor_requests) { driver->input_monitor_mask |= (1<hw_monitoring) { if (driver->playback_handle) { if (driver->all_monitor_in) { for (chn = 0; chn < driver->playback_nchannels; chn++) { alsa_driver_copy_channel (driver, chn, chn, contiguous); } } else if (driver->input_monitor_mask) { for (chn = 0; chn < driver->playback_nchannels; chn++) { if (driver->input_monitor_mask & (1<hw->input_monitor_mask != driver->input_monitor_mask) && !driver->all_monitor_in) { driver->hw->set_input_monitor_mask (driver->hw, driver->input_monitor_mask); } } if (driver->playback_handle) { if (driver->channels_not_done) { alsa_driver_silence_untouched_channels (driver, contiguous); } snd_pcm_mmap_commit (driver->playback_handle, playback_offset, contiguous); } nframes -= contiguous; } if (engine_ran) { engine->post_process (engine); engine->process_unlock (engine); } return 0; } static void alsa_driver_attach (alsa_driver_t *driver, jack_engine_t *engine) { char buf[32]; channel_t chn; jack_port_t *port; int port_flags; driver->engine = engine; driver->engine->set_buffer_size (engine, driver->frames_per_cycle); driver->engine->set_sample_rate (engine, driver->frame_rate); /* Now become a client of the engine */ if ((driver->client = jack_driver_become_client ("alsa_pcm")) == NULL) { jack_error ("ALSA: cannot become client"); return; } port_flags = JackPortIsOutput|JackPortIsPhysical|JackPortIsTerminal; if (driver->has_hw_monitoring) { port_flags |= JackPortCanMonitor; } for (chn = 0; chn < driver->capture_nchannels; chn++) { snprintf (buf, sizeof(buf) - 1, "capture_%lu", chn+1); if ((port = jack_port_register (driver->client, buf, JACK_DEFAULT_AUDIO_TYPE, port_flags, 0)) == NULL) { jack_error ("ALSA: cannot register port for %s", buf); break; } /* XXX fix this so that it can handle: systemic (external) latency */ jack_port_set_latency (port, driver->frames_per_cycle); driver->capture_ports = jack_slist_append (driver->capture_ports, port); } port_flags = JackPortIsInput|JackPortIsPhysical|JackPortIsTerminal; for (chn = 0; chn < driver->playback_nchannels; chn++) { snprintf (buf, sizeof(buf) - 1, "playback_%lu", chn+1); if ((port = jack_port_register (driver->client, buf, JACK_DEFAULT_AUDIO_TYPE, port_flags, 0)) == NULL) { jack_error ("ALSA: cannot register port for %s", buf); break; } /* XXX fix this so that it can handle: systemic (external) latency */ jack_port_set_latency (port, driver->frames_per_cycle * driver->nfragments); driver->playback_ports = jack_slist_append (driver->playback_ports, port); } jack_activate (driver->client); } static void alsa_driver_detach (alsa_driver_t *driver, jack_engine_t *engine) { JSList *node; if (driver->engine == 0) { return; } for (node = driver->capture_ports; node; node = jack_slist_next (node)) { jack_port_unregister (driver->client, ((jack_port_t *) node->data)); } jack_slist_free (driver->capture_ports); driver->capture_ports = 0; for (node = driver->playback_ports; node; node = jack_slist_next (node)) { jack_port_unregister (driver->client, ((jack_port_t *) node->data)); } jack_slist_free (driver->playback_ports); driver->playback_ports = 0; driver->engine = 0; } static int alsa_driver_change_sample_clock (alsa_driver_t *driver, SampleClockMode mode) { return driver->hw->change_sample_clock (driver->hw, mode); } static void alsa_driver_request_all_monitor_input (alsa_driver_t *driver, int yn) { if (driver->hw_monitoring) { if (yn) { driver->hw->set_input_monitor_mask (driver->hw, ~0U); } else { driver->hw->set_input_monitor_mask (driver->hw, driver->input_monitor_mask); } } driver->all_monitor_in = yn; } static void alsa_driver_set_hw_monitoring (alsa_driver_t *driver, int yn) { if (yn) { driver->hw_monitoring = TRUE; if (driver->all_monitor_in) { driver->hw->set_input_monitor_mask (driver->hw, ~0U); } else { driver->hw->set_input_monitor_mask (driver->hw, driver->input_monitor_mask); } } else { driver->hw_monitoring = FALSE; driver->hw->set_input_monitor_mask (driver->hw, 0); } } static ClockSyncStatus alsa_driver_clock_sync_status (channel_t chn) { return Lock; } static void alsa_driver_delete (alsa_driver_t *driver) { JSList *node; for (node = driver->clock_sync_listeners; node; node = jack_slist_next (node)) { free (node->data); } jack_slist_free (driver->clock_sync_listeners); if (driver->capture_handle) { snd_pcm_close (driver->capture_handle); driver->capture_handle = 0; } if (driver->playback_handle) { snd_pcm_close (driver->playback_handle); driver->capture_handle = 0; } if (driver->capture_hw_params) { snd_pcm_hw_params_free (driver->capture_hw_params); driver->capture_hw_params = 0; } if (driver->playback_hw_params) { snd_pcm_hw_params_free (driver->playback_hw_params); driver->playback_hw_params = 0; } if (driver->capture_sw_params) { snd_pcm_sw_params_free (driver->capture_sw_params); driver->capture_sw_params = 0; } if (driver->playback_sw_params) { snd_pcm_sw_params_free (driver->playback_sw_params); driver->playback_sw_params = 0; } if (driver->pfd) { free (driver->pfd); } if (driver->hw) { driver->hw->release (driver->hw); driver->hw = 0; } free(driver->alsa_name); free(driver->alsa_driver); alsa_driver_release_channel_dependent_memory (driver); free (driver); } static jack_driver_t * alsa_driver_new (char *name, char *alsa_device, jack_nframes_t frames_per_cycle, jack_nframes_t user_nperiods, jack_nframes_t rate, int hw_monitoring, int capturing, int playing, DitherAlgorithm dither) { int err; alsa_driver_t *driver; printf ("creating alsa driver ... %s|%lu|%lu|%lu|%s\n", alsa_device, frames_per_cycle, user_nperiods, rate, hw_monitoring ? "hwmon":"swmon"); driver = (alsa_driver_t *) calloc (1, sizeof (alsa_driver_t)); jack_driver_init ((jack_driver_t *) driver); driver->attach = (JackDriverAttachFunction) alsa_driver_attach; driver->detach = (JackDriverDetachFunction) alsa_driver_detach; driver->wait = (JackDriverWaitFunction) alsa_driver_wait; driver->process = (JackDriverProcessFunction) alsa_driver_process; driver->start = (JackDriverStartFunction) alsa_driver_audio_start; driver->stop = (JackDriverStopFunction) alsa_driver_audio_stop; driver->playback_handle = NULL; driver->capture_handle = NULL; driver->ctl_handle = 0; driver->hw = 0; driver->capture_and_playback_not_synced = FALSE; driver->nfragments = 0; driver->max_nchannels = 0; driver->user_nchannels = 0; driver->playback_nchannels = 0; driver->capture_nchannels = 0; driver->playback_addr = 0; driver->capture_addr = 0; driver->silent = 0; driver->all_monitor_in = FALSE; driver->cpu_mhz = jack_get_mhz(); driver->clock_mode = ClockMaster; /* XXX is it? */ driver->input_monitor_mask = 0; /* XXX is it? */ driver->capture_ports = 0; driver->playback_ports = 0; driver->pfd = 0; driver->playback_nfds = 0; driver->capture_nfds = 0; driver->dither = dither; pthread_mutex_init (&driver->clock_sync_lock, 0); driver->clock_sync_listeners = 0; if (playing) { if ((err = snd_pcm_open (&driver->playback_handle, alsa_device, SND_PCM_STREAM_PLAYBACK, 0)) < 0) { jack_error ("ALSA: Cannot open PCM device %s/%s", name, alsa_device); free (driver); return 0; } } if (capturing) { if ((err = snd_pcm_open (&driver->capture_handle, alsa_device, SND_PCM_STREAM_CAPTURE, 0)) < 0) { snd_pcm_close (driver->playback_handle); jack_error ("ALSA: Cannot open PCM device %s", name); free (driver); return 0; } } driver->alsa_name = strdup (alsa_device); if (alsa_driver_check_card_type (driver)) { if (driver->capture_handle) { snd_pcm_close (driver->capture_handle); } if (driver->playback_handle) { snd_pcm_close (driver->playback_handle); } free (driver); return 0; } driver->playback_hw_params = 0; driver->capture_hw_params = 0; driver->playback_sw_params = 0; driver->capture_sw_params = 0; if (driver->playback_handle) { if ((err = snd_pcm_hw_params_malloc (&driver->playback_hw_params)) < 0) { jack_error ("ALSA: could no allocate playback hw params structure"); alsa_driver_delete (driver); return 0; } if ((err = snd_pcm_sw_params_malloc (&driver->playback_sw_params)) < 0) { jack_error ("ALSA: could no allocate playback sw params structure"); alsa_driver_delete (driver); return 0; } } if (driver->capture_handle) { if ((err = snd_pcm_hw_params_malloc (&driver->capture_hw_params)) < 0) { jack_error ("ALSA: could no allocate capture hw params structure"); alsa_driver_delete (driver); return 0; } if ((err = snd_pcm_sw_params_malloc (&driver->capture_sw_params)) < 0) { jack_error ("ALSA: could no allocate capture sw params structure"); alsa_driver_delete (driver); return 0; } } if (alsa_driver_set_parameters (driver, frames_per_cycle, user_nperiods, rate)) { alsa_driver_delete (driver); return 0; } driver->capture_and_playback_not_synced = FALSE; if (driver->capture_handle && driver->playback_handle) { if (snd_pcm_link (driver->capture_handle, driver->playback_handle) != 0) { driver->capture_and_playback_not_synced = TRUE; } } alsa_driver_hw_specific (driver, hw_monitoring); return (jack_driver_t *) driver; } int alsa_driver_listen_for_clock_sync_status (alsa_driver_t *driver, ClockSyncListenerFunction func, void *arg) { ClockSyncListener *csl; csl = (ClockSyncListener *) malloc (sizeof (ClockSyncListener)); csl->function = func; csl->arg = arg; csl->id = driver->next_clock_sync_listener_id++; pthread_mutex_lock (&driver->clock_sync_lock); driver->clock_sync_listeners = jack_slist_prepend (driver->clock_sync_listeners, csl); pthread_mutex_unlock (&driver->clock_sync_lock); return csl->id; } int alsa_driver_stop_listening_to_clock_sync_status (alsa_driver_t *driver, int which) { JSList *node; int ret = -1; pthread_mutex_lock (&driver->clock_sync_lock); for (node = driver->clock_sync_listeners; node; node = jack_slist_next (node)) { if (((ClockSyncListener *) node->data)->id == which) { driver->clock_sync_listeners = jack_slist_remove_link (driver->clock_sync_listeners, node); free (node->data); jack_slist_free_1 (node); ret = 0; break; } } pthread_mutex_unlock (&driver->clock_sync_lock); return ret; } void alsa_driver_clock_sync_notify (alsa_driver_t *driver, channel_t chn, ClockSyncStatus status) { JSList *node; pthread_mutex_lock (&driver->clock_sync_lock); for (node = driver->clock_sync_listeners; node; node = jack_slist_next (node)) { ClockSyncListener *csl = (ClockSyncListener *) node->data; csl->function (chn, status, csl->arg); } pthread_mutex_unlock (&driver->clock_sync_lock); } /* DRIVER "PLUGIN" INTERFACE */ static void alsa_usage () { fprintf (stderr, "\ alsa PCM driver args: -d alsa-pcm-name (default: default) -r sample-rate (default: 48kHz) -p frames-per-period (default: 1024) -n periods-per-hardware-buffer (default: 2) -H (use hardware monitoring if available, default: no) -D (duplex, default: yes) -C (capture, default: duplex) -P (playback, default: duplex) -z[r|t|s|-] (dither, rect|tri|shaped|off, default: off) "); } jack_driver_t * driver_initialize (int argc, char **argv) { jack_nframes_t srate = 48000; jack_nframes_t frames_per_interrupt = 1024; unsigned long user_nperiods = 2; char *pcm_name = "default"; int hw_monitoring = FALSE; int capture = FALSE; int playback = FALSE; DitherAlgorithm dither = None; int i; /* grrrr ... getopt() cannot be called in more than one "loop" per process instance. ridiculous, but true. why isn't there a getopt_reinitialize() function? */ for (i = 1; i < argc; i++) { if (argv[i][0] == '-') { switch (argv[i][1]) { case 'D': capture = TRUE; playback = TRUE; break; case 'C': capture = TRUE; break; case 'P': playback = TRUE; break; case 'd': pcm_name = argv[i+1]; i++; break; case 'n': user_nperiods = atoi (argv[i+1]); i++; break; case 'r': srate = atoi (argv[i+1]); i++; break; case 'p': frames_per_interrupt = atoi (argv[i+1]); i++; break; case 'H': hw_monitoring = 1; break; case 'z': switch (argv[i][2]) { case '-': dither = None; break; case 'r': dither = Rectangular; break; case 's': dither = Shaped; break; case 't': default: dither = Triangular; break; } break; default: alsa_usage (); return NULL; } } else { alsa_usage (); return NULL; } } /* duplex is the default */ if (!capture && !playback) { capture = TRUE; playback = TRUE; } return alsa_driver_new ("alsa_pcm", pcm_name, frames_per_interrupt, user_nperiods, srate, hw_monitoring, capture, playback, dither); } void driver_finish (jack_driver_t *driver) { alsa_driver_delete ((alsa_driver_t *) driver); }