/* Copyright (c) 2012 The Chromium OS Authors. All rights reserved. * Use of this source code is governed by a BSD-style license that can be * found in the LICENSE file. */ #ifndef _GNU_SOURCE #define _GNU_SOURCE /* for ppoll and asprintf*/ #endif #include #include #include #include #include #include #include "audio_thread_log.h" #include "cras_audio_thread_monitor.h" #include "cras_config.h" #include "cras_device_monitor.h" #include "cras_fmt_conv.h" #include "cras_iodev.h" #include "cras_rstream.h" #include "cras_server_metrics.h" #include "cras_system_state.h" #include "cras_types.h" #include "cras_util.h" #include "dev_stream.h" #include "audio_thread.h" #include "utlist.h" #define MIN_PROCESS_TIME_US 500 /* 0.5ms - min amount of time to mix/src. */ #define SLEEP_FUZZ_FRAMES 10 /* # to consider "close enough" to sleep frames. */ #define MIN_READ_WAIT_US 2000 /* 2ms */ /* * # to check whether a busyloop event happens */ #define MAX_CONTINUOUS_ZERO_SLEEP_COUNT 2 /* * If the number of continuous zero sleep is equal to this limit, the value * will be recorded immediately. It can ensure all busyloop will be recorded * even if the busyloop does not stop. */ #define MAX_CONTINUOUS_ZERO_SLEEP_METRIC_LIMIT 1000 /* Messages that can be sent from the main context to the audio thread. */ enum AUDIO_THREAD_COMMAND { AUDIO_THREAD_ADD_OPEN_DEV, AUDIO_THREAD_RM_OPEN_DEV, AUDIO_THREAD_IS_DEV_OPEN, AUDIO_THREAD_ADD_STREAM, AUDIO_THREAD_DISCONNECT_STREAM, AUDIO_THREAD_STOP, AUDIO_THREAD_DUMP_THREAD_INFO, AUDIO_THREAD_DRAIN_STREAM, AUDIO_THREAD_CONFIG_GLOBAL_REMIX, AUDIO_THREAD_DEV_START_RAMP, AUDIO_THREAD_REMOVE_CALLBACK, AUDIO_THREAD_AEC_DUMP, }; struct audio_thread_msg { size_t length; enum AUDIO_THREAD_COMMAND id; }; struct audio_thread_config_global_remix { struct audio_thread_msg header; struct cras_fmt_conv *fmt_conv; }; struct audio_thread_open_device_msg { struct audio_thread_msg header; struct cras_iodev *dev; }; struct audio_thread_rm_device_msg { struct audio_thread_msg header; enum CRAS_STREAM_DIRECTION dir; unsigned dev_idx; }; struct audio_thread_rm_callback_msg { struct audio_thread_msg header; int fd; }; struct audio_thread_add_rm_stream_msg { struct audio_thread_msg header; struct cras_rstream *stream; struct cras_iodev **devs; unsigned int num_devs; }; struct audio_thread_dump_debug_info_msg { struct audio_thread_msg header; struct audio_debug_info *info; }; struct audio_thread_dev_start_ramp_msg { struct audio_thread_msg header; unsigned int dev_idx; enum CRAS_IODEV_RAMP_REQUEST request; }; struct audio_thread_aec_dump_msg { struct audio_thread_msg header; cras_stream_id_t stream_id; unsigned int start; /* */ int fd; }; /* Audio thread logging. If atlog is successfully created from cras_shm_setup, * then the fds should have valid value. Or audio thread will fallback to use * calloc to create atlog and leave the fds as -1. */ struct audio_thread_event_log *atlog; char *atlog_name; int atlog_rw_shm_fd; int atlog_ro_shm_fd; static struct iodev_callback_list *iodev_callbacks; struct iodev_callback_list { int fd; int events; enum AUDIO_THREAD_EVENTS_CB_TRIGGER trigger; thread_callback cb; void *cb_data; struct pollfd *pollfd; struct iodev_callback_list *prev, *next; }; void audio_thread_add_events_callback(int fd, thread_callback cb, void *data, int events) { struct iodev_callback_list *iodev_cb; /* Don't add iodev_cb twice */ DL_FOREACH (iodev_callbacks, iodev_cb) if (iodev_cb->fd == fd && iodev_cb->cb_data == data) return; iodev_cb = (struct iodev_callback_list *)calloc(1, sizeof(*iodev_cb)); iodev_cb->fd = fd; iodev_cb->cb = cb; iodev_cb->cb_data = data; iodev_cb->trigger = TRIGGER_POLL; iodev_cb->events = events; DL_APPEND(iodev_callbacks, iodev_cb); } void audio_thread_rm_callback(int fd) { struct iodev_callback_list *iodev_cb; DL_FOREACH (iodev_callbacks, iodev_cb) { if (iodev_cb->fd == fd) { DL_DELETE(iodev_callbacks, iodev_cb); free(iodev_cb); return; } } } void audio_thread_config_events_callback( int fd, enum AUDIO_THREAD_EVENTS_CB_TRIGGER trigger) { struct iodev_callback_list *iodev_cb; DL_FOREACH (iodev_callbacks, iodev_cb) { if (iodev_cb->fd == fd) { iodev_cb->trigger = trigger; return; } } } /* Sends a response (error code) from the audio thread to the main thread. * Indicates that the last message sent to the audio thread has been handled * with an error code of rc. * Args: * thread - thread responding to command. * rc - Result code to send back to the main thread. * Returns: * The number of bytes written to the main thread. */ static int audio_thread_send_response(struct audio_thread *thread, int rc) { return write(thread->to_main_fds[1], &rc, sizeof(rc)); } /* Reads from a file descriptor until all bytes are read. * * Args: * fd - file descriptor to read * buf - the buffer to be written. * count - the number of bytes to read from fd * Returns: * |count| on success, negative error code on failure. */ static int read_until_finished(int fd, void *buf, size_t count) { int nread, count_left = count; while (count_left > 0) { nread = read(fd, (uint8_t *)buf + count - count_left, count_left); if (nread < 0) { if (errno == EINTR) continue; else return nread; } else if (nread == 0) { syslog(LOG_ERR, "Pipe has been closed."); return -EPIPE; } count_left -= nread; } return count; } /* Reads a command from the main thread. Called from the playback/capture * thread. This will read the next available command from the main thread and * put it in buf. * Args: * thread - thread reading the command. * buf - Message is stored here on return. * max_len - maximum length of message to put into buf. * Returns: * 0 on success, negative error code on failure. */ static int audio_thread_read_command(struct audio_thread *thread, uint8_t *buf, size_t max_len) { int to_read, nread, rc; struct audio_thread_msg *msg = (struct audio_thread_msg *)buf; /* Get the length of the message first */ nread = read_until_finished(thread->to_thread_fds[0], buf, sizeof(msg->length)); if (nread < 0) return nread; if (msg->length > max_len) return -ENOMEM; to_read = msg->length - sizeof(msg->length); rc = read_until_finished(thread->to_thread_fds[0], &buf[0] + sizeof(msg->length), to_read); if (rc < 0) return rc; return 0; } /* Builds an initial buffer to avoid an underrun. Adds min_level of latency. */ static void fill_odevs_zeros_min_level(struct cras_iodev *odev) { cras_iodev_fill_odev_zeros(odev, odev->min_buffer_level); } /* Handles messages from main thread to add a new active device. */ static int thread_add_open_dev(struct audio_thread *thread, struct cras_iodev *iodev) { struct open_dev *adev; DL_SEARCH_SCALAR(thread->open_devs[iodev->direction], adev, dev, iodev); if (adev) return -EEXIST; adev = (struct open_dev *)calloc(1, sizeof(*adev)); adev->dev = iodev; /* * Start output devices by padding the output. This avoids a burst of * audio callbacks when the stream starts */ if (iodev->direction == CRAS_STREAM_OUTPUT) fill_odevs_zeros_min_level(iodev); ATLOG(atlog, AUDIO_THREAD_DEV_ADDED, iodev->info.idx, 0, 0); DL_APPEND(thread->open_devs[iodev->direction], adev); return 0; } /* Handles messages from the main thread to remove an active device. */ static int thread_rm_open_dev(struct audio_thread *thread, enum CRAS_STREAM_DIRECTION dir, unsigned int dev_idx) { struct open_dev *adev = dev_io_find_open_dev(thread->open_devs[dir], dev_idx); if (!adev) return -EINVAL; dev_io_rm_open_dev(&thread->open_devs[dir], adev); return 0; } /* * Handles message from the main thread to check if an iodev is in the * open dev list. */ static int thread_is_dev_open(struct audio_thread *thread, struct cras_iodev *iodev) { struct open_dev *adev = dev_io_find_open_dev( thread->open_devs[iodev->direction], iodev->info.idx); return !!adev; } /* * Handles messages from the main thread to start ramping on a device. * Start ramping in audio thread and set mute/unmute * state on device. This should only be done when * device is running with valid streams. * * 1. Mute -> Unmute: Set device unmute state after * ramping is started. * 2. Unmute -> Mute: Set device mute state after * ramping is done. * * The above transition will be handled by cras_iodev_start_ramp. */ static int thread_dev_start_ramp(struct audio_thread *thread, unsigned int dev_idx, enum CRAS_IODEV_RAMP_REQUEST request) { /* Do nothing if device wasn't already in the active dev list. */ struct cras_iodev *iodev; struct open_dev *adev = dev_io_find_open_dev( thread->open_devs[CRAS_STREAM_OUTPUT], dev_idx); if (!adev) return -EINVAL; iodev = adev->dev; /* * Checks if a device should start ramping for mute/unmute change. * Device must meet all the conditions: * * - Device has ramp support. * - Device is in normal run state, that is, it must be running with valid * streams. * - Device volume, which considers both system volume and adjusted active * node volume, is not zero. If device volume is zero, all the samples are * suppressed to zero and there is no need to ramp. */ if (iodev->ramp && cras_iodev_state(iodev) == CRAS_IODEV_STATE_NORMAL_RUN && !cras_iodev_is_zero_volume(iodev)) return cras_iodev_start_ramp(iodev, request); else return cras_device_monitor_set_device_mute_state( iodev->info.idx); } /* Return non-zero if the stream is attached to any device. */ static int thread_find_stream(struct audio_thread *thread, struct cras_rstream *rstream) { struct open_dev *open_dev; struct dev_stream *s; DL_FOREACH (thread->open_devs[rstream->direction], open_dev) { DL_FOREACH (open_dev->dev->streams, s) { if (s->stream == rstream) return 1; } } return 0; } /* Handles the disconnect_stream message from the main thread. */ static int thread_disconnect_stream(struct audio_thread *thread, struct cras_rstream *stream, struct cras_iodev *dev) { int rc; if (!thread_find_stream(thread, stream)) return 0; rc = dev_io_remove_stream(&thread->open_devs[stream->direction], stream, dev); return rc; } /* Initiates draining of a stream or returns the status of a draining stream. * If the stream has completed draining the thread forfeits ownership and must * never reference it again. Returns the number of milliseconds it will take to * finish draining, a minimum of one ms if any samples remain. */ static int thread_drain_stream_ms_remaining(struct audio_thread *thread, struct cras_rstream *rstream) { int fr_in_buff; struct cras_audio_shm *shm; if (rstream->direction != CRAS_STREAM_OUTPUT) return 0; shm = cras_rstream_shm(rstream); fr_in_buff = cras_shm_get_frames(shm); if (fr_in_buff <= 0) return 0; cras_rstream_set_is_draining(rstream, 1); return 1 + cras_frames_to_ms(fr_in_buff, rstream->format.frame_rate); } /* Handles a request to begin draining and return the amount of time left to * draing a stream. */ static int thread_drain_stream(struct audio_thread *thread, struct cras_rstream *rstream) { int ms_left; if (!thread_find_stream(thread, rstream)) return 0; ms_left = thread_drain_stream_ms_remaining(thread, rstream); if (ms_left == 0) dev_io_remove_stream(&thread->open_devs[rstream->direction], rstream, NULL); return ms_left; } /* Handles the add_stream message from the main thread. */ static int thread_add_stream(struct audio_thread *thread, struct cras_rstream *stream, struct cras_iodev **iodevs, unsigned int num_iodevs) { int rc; rc = dev_io_append_stream(&thread->open_devs[CRAS_STREAM_OUTPUT], &thread->open_devs[CRAS_STREAM_INPUT], stream, iodevs, num_iodevs); if (rc < 0) return rc; return 0; } /* Starts or stops aec dump task. */ static int thread_set_aec_dump(struct audio_thread *thread, cras_stream_id_t stream_id, unsigned int start, int fd) { struct open_dev *idev_list = thread->open_devs[CRAS_STREAM_INPUT]; struct open_dev *adev; struct dev_stream *stream; DL_FOREACH (idev_list, adev) { if (!cras_iodev_is_open(adev->dev)) continue; DL_FOREACH (adev->dev->streams, stream) { if ((stream->stream->apm_list == NULL) || (stream->stream->stream_id != stream_id)) continue; cras_apm_list_set_aec_dump(stream->stream->apm_list, adev->dev, start, fd); } } return 0; } /* Stop the playback thread */ static void terminate_pb_thread() { pthread_exit(0); } static void append_dev_dump_info(struct audio_dev_debug_info *di, struct open_dev *adev) { struct cras_audio_format *fmt = adev->dev->format; struct timespec now, time_since; strncpy(di->dev_name, adev->dev->info.name, sizeof(di->dev_name)); di->buffer_size = adev->dev->buffer_size; di->min_buffer_level = adev->dev->min_buffer_level; di->min_cb_level = adev->dev->min_cb_level; di->max_cb_level = adev->dev->max_cb_level; di->direction = adev->dev->direction; di->num_underruns = cras_iodev_get_num_underruns(adev->dev); di->num_severe_underruns = cras_iodev_get_num_severe_underruns(adev->dev); di->highest_hw_level = adev->dev->highest_hw_level; di->software_gain_scaler = (adev->dev->direction == CRAS_STREAM_INPUT) ? adev->dev->software_gain_scaler : 0.0f; clock_gettime(CLOCK_MONOTONIC_RAW, &now); subtract_timespecs(&now, &adev->dev->open_ts, &time_since); di->runtime_sec = time_since.tv_sec; di->runtime_nsec = time_since.tv_nsec; di->longest_wake_sec = adev->longest_wake.tv_sec; di->longest_wake_nsec = adev->longest_wake.tv_nsec; if (fmt) { di->frame_rate = fmt->frame_rate; di->num_channels = fmt->num_channels; di->est_rate_ratio = cras_iodev_get_est_rate_ratio(adev->dev); } else { di->frame_rate = 0; di->num_channels = 0; di->est_rate_ratio = 0; } } /* Put stream info for the given stream into the info struct. */ static void append_stream_dump_info(struct audio_debug_info *info, struct dev_stream *stream, unsigned int dev_idx, int index) { struct audio_stream_debug_info *si; struct timespec now, time_since; si = &info->streams[index]; si->stream_id = stream->stream->stream_id; si->dev_idx = dev_idx; si->direction = stream->stream->direction; si->stream_type = stream->stream->stream_type; si->client_type = stream->stream->client_type; si->buffer_frames = stream->stream->buffer_frames; si->cb_threshold = stream->stream->cb_threshold; si->frame_rate = stream->stream->format.frame_rate; si->num_channels = stream->stream->format.num_channels; memcpy(si->channel_layout, stream->stream->format.channel_layout, sizeof(si->channel_layout)); si->longest_fetch_sec = stream->stream->longest_fetch_interval.tv_sec; si->longest_fetch_nsec = stream->stream->longest_fetch_interval.tv_nsec; si->num_overruns = cras_shm_num_overruns(stream->stream->shm); si->effects = cras_apm_list_get_effects(stream->stream->apm_list); si->pinned_dev_idx = stream->stream->pinned_dev_idx; si->is_pinned = stream->stream->is_pinned; si->num_missed_cb = stream->stream->num_missed_cb; si->stream_volume = cras_rstream_get_volume_scaler(stream->stream); clock_gettime(CLOCK_MONOTONIC_RAW, &now); subtract_timespecs(&now, &stream->stream->start_ts, &time_since); si->runtime_sec = time_since.tv_sec; si->runtime_nsec = time_since.tv_nsec; } /* Handle a message sent from main thread to the audio thread. * Returns: * Error code when reading or sending message fails. */ static int handle_audio_thread_message(struct audio_thread *thread) { uint8_t buf[256]; struct audio_thread_msg *msg = (struct audio_thread_msg *)buf; int ret = 0; int err; err = audio_thread_read_command(thread, buf, 256); if (err < 0) return err; ATLOG(atlog, AUDIO_THREAD_PB_MSG, msg->id, 0, 0); switch (msg->id) { case AUDIO_THREAD_ADD_STREAM: { struct audio_thread_add_rm_stream_msg *amsg; amsg = (struct audio_thread_add_rm_stream_msg *)msg; ATLOG(atlog, AUDIO_THREAD_WRITE_STREAMS_WAIT, amsg->stream->stream_id, 0, 0); ret = thread_add_stream(thread, amsg->stream, amsg->devs, amsg->num_devs); break; } case AUDIO_THREAD_DISCONNECT_STREAM: { struct audio_thread_add_rm_stream_msg *rmsg; rmsg = (struct audio_thread_add_rm_stream_msg *)msg; ret = thread_disconnect_stream(thread, rmsg->stream, rmsg->devs[0]); break; } case AUDIO_THREAD_ADD_OPEN_DEV: { struct audio_thread_open_device_msg *rmsg; rmsg = (struct audio_thread_open_device_msg *)msg; ret = thread_add_open_dev(thread, rmsg->dev); break; } case AUDIO_THREAD_RM_OPEN_DEV: { struct audio_thread_rm_device_msg *rmsg; rmsg = (struct audio_thread_rm_device_msg *)msg; ret = thread_rm_open_dev(thread, rmsg->dir, rmsg->dev_idx); break; } case AUDIO_THREAD_IS_DEV_OPEN: { struct audio_thread_open_device_msg *rmsg; rmsg = (struct audio_thread_open_device_msg *)msg; ret = thread_is_dev_open(thread, rmsg->dev); break; } case AUDIO_THREAD_STOP: ret = 0; err = audio_thread_send_response(thread, ret); if (err < 0) return err; terminate_pb_thread(); break; case AUDIO_THREAD_DUMP_THREAD_INFO: { struct dev_stream *curr; struct open_dev *adev; struct audio_thread_dump_debug_info_msg *dmsg; struct audio_debug_info *info; unsigned int num_streams = 0; unsigned int num_devs = 0; ret = 0; dmsg = (struct audio_thread_dump_debug_info_msg *)msg; info = dmsg->info; /* Go through all open devices. */ DL_FOREACH (thread->open_devs[CRAS_STREAM_OUTPUT], adev) { append_dev_dump_info(&info->devs[num_devs], adev); if (++num_devs == MAX_DEBUG_DEVS) break; DL_FOREACH (adev->dev->streams, curr) { if (num_streams == MAX_DEBUG_STREAMS) break; append_stream_dump_info(info, curr, adev->dev->info.idx, num_streams++); } } DL_FOREACH (thread->open_devs[CRAS_STREAM_INPUT], adev) { if (num_devs == MAX_DEBUG_DEVS) break; append_dev_dump_info(&info->devs[num_devs], adev); DL_FOREACH (adev->dev->streams, curr) { if (num_streams == MAX_DEBUG_STREAMS) break; append_stream_dump_info(info, curr, adev->dev->info.idx, num_streams++); } ++num_devs; } info->num_devs = num_devs; info->num_streams = num_streams; memcpy(&info->log, atlog, sizeof(info->log)); break; } case AUDIO_THREAD_DRAIN_STREAM: { struct audio_thread_add_rm_stream_msg *rmsg; rmsg = (struct audio_thread_add_rm_stream_msg *)msg; ret = thread_drain_stream(thread, rmsg->stream); break; } case AUDIO_THREAD_REMOVE_CALLBACK: { struct audio_thread_rm_callback_msg *rmsg; rmsg = (struct audio_thread_rm_callback_msg *)msg; audio_thread_rm_callback(rmsg->fd); break; } case AUDIO_THREAD_CONFIG_GLOBAL_REMIX: { struct audio_thread_config_global_remix *rmsg; void *rsp; /* Respond the pointer to the old remix converter, so it can be * freed later in main thread. */ rsp = (void *)thread->remix_converter; rmsg = (struct audio_thread_config_global_remix *)msg; thread->remix_converter = rmsg->fmt_conv; return write(thread->to_main_fds[1], &rsp, sizeof(rsp)); } case AUDIO_THREAD_DEV_START_RAMP: { struct audio_thread_dev_start_ramp_msg *rmsg; rmsg = (struct audio_thread_dev_start_ramp_msg *)msg; ret = thread_dev_start_ramp(thread, rmsg->dev_idx, rmsg->request); break; } case AUDIO_THREAD_AEC_DUMP: { struct audio_thread_aec_dump_msg *rmsg; rmsg = (struct audio_thread_aec_dump_msg *)msg; ret = thread_set_aec_dump(thread, rmsg->stream_id, rmsg->start, rmsg->fd); break; } default: ret = -EINVAL; break; } err = audio_thread_send_response(thread, ret); if (err < 0) return err; return 0; } /* Returns the number of active streams plus the number of active devices. */ static int fill_next_sleep_interval(struct audio_thread *thread, struct timespec *ts) { struct timespec min_ts; struct timespec now; int ret; ts->tv_sec = 0; ts->tv_nsec = 0; /* Limit the sleep time to 20 seconds. */ min_ts.tv_sec = 20; min_ts.tv_nsec = 0; clock_gettime(CLOCK_MONOTONIC_RAW, &now); add_timespecs(&min_ts, &now); ret = dev_io_next_output_wake(&thread->open_devs[CRAS_STREAM_OUTPUT], &min_ts); ret += dev_io_next_input_wake(&thread->open_devs[CRAS_STREAM_INPUT], &min_ts); if (timespec_after(&min_ts, &now)) subtract_timespecs(&min_ts, &now, ts); return ret; } static struct pollfd *add_pollfd(struct audio_thread *thread, int fd, int events) { thread->pollfds[thread->num_pollfds].fd = fd; thread->pollfds[thread->num_pollfds].events = events; thread->num_pollfds++; if (thread->num_pollfds >= thread->pollfds_size) { thread->pollfds_size *= 2; thread->pollfds = (struct pollfd *)realloc( thread->pollfds, sizeof(*thread->pollfds) * thread->pollfds_size); return NULL; } return &thread->pollfds[thread->num_pollfds - 1]; } static int continuous_zero_sleep_count = 0; static unsigned busyloop_count = 0; /* * Logs the number of busyloop during one audio thread running state * (wait_ts != NULL). */ static void log_busyloop(struct timespec *wait_ts) { static struct timespec start_time; static bool started = false; struct timespec diff, now; /* If wait_ts is NULL, there is no stream running. */ if (wait_ts && !started) { started = true; busyloop_count = 0; clock_gettime(CLOCK_MONOTONIC_RAW, &start_time); } else if (!wait_ts && started) { started = false; clock_gettime(CLOCK_MONOTONIC_RAW, &now); subtract_timespecs(&now, &start_time, &diff); cras_server_metrics_busyloop(&diff, busyloop_count); } } static void check_busyloop(struct timespec *wait_ts) { if (wait_ts->tv_sec == 0 && wait_ts->tv_nsec == 0) { continuous_zero_sleep_count++; if (continuous_zero_sleep_count == MAX_CONTINUOUS_ZERO_SLEEP_COUNT) { busyloop_count++; cras_audio_thread_event_busyloop(); } if (continuous_zero_sleep_count == MAX_CONTINUOUS_ZERO_SLEEP_METRIC_LIMIT) cras_server_metrics_busyloop_length( continuous_zero_sleep_count); } else { if (continuous_zero_sleep_count >= MAX_CONTINUOUS_ZERO_SLEEP_COUNT && continuous_zero_sleep_count < MAX_CONTINUOUS_ZERO_SLEEP_METRIC_LIMIT) cras_server_metrics_busyloop_length( continuous_zero_sleep_count); continuous_zero_sleep_count = 0; } } /* For playback, fill the audio buffer when needed, for capture, pull out * samples when they are ready. * This thread will attempt to run at a high priority to allow for low latency * streams. This thread sleeps while the device plays back or captures audio, * it will wake up as little as it can while avoiding xruns. It can also be * woken by sending it a message using the "audio_thread_post_message" function. */ static void *audio_io_thread(void *arg) { struct audio_thread *thread = (struct audio_thread *)arg; struct open_dev *adev; struct dev_stream *curr; struct timespec ts; int msg_fd; int rc; msg_fd = thread->to_thread_fds[0]; /* Attempt to get realtime scheduling */ if (cras_set_rt_scheduling(CRAS_SERVER_RT_THREAD_PRIORITY) == 0) cras_set_thread_priority(CRAS_SERVER_RT_THREAD_PRIORITY); thread->pollfds[0].fd = msg_fd; thread->pollfds[0].events = POLLIN; while (1) { struct timespec *wait_ts; struct iodev_callback_list *iodev_cb; int non_empty; wait_ts = NULL; thread->num_pollfds = 1; /* device opened */ dev_io_run(&thread->open_devs[CRAS_STREAM_OUTPUT], &thread->open_devs[CRAS_STREAM_INPUT], thread->remix_converter); non_empty = dev_io_check_non_empty_state_transition( thread->open_devs[CRAS_STREAM_OUTPUT]); if (fill_next_sleep_interval(thread, &ts)) wait_ts = &ts; restart_poll_loop: thread->num_pollfds = 1; DL_FOREACH (iodev_callbacks, iodev_cb) { if (iodev_cb->trigger != TRIGGER_POLL) { iodev_cb->pollfd = NULL; continue; } iodev_cb->pollfd = add_pollfd(thread, iodev_cb->fd, iodev_cb->events); if (!iodev_cb->pollfd) goto restart_poll_loop; } /* TODO(dgreid) - once per rstream not per dev_stream */ DL_FOREACH (thread->open_devs[CRAS_STREAM_OUTPUT], adev) { DL_FOREACH (adev->dev->streams, curr) { int fd = dev_stream_poll_stream_fd(curr); if (fd < 0) continue; if (!add_pollfd(thread, fd, POLLIN)) goto restart_poll_loop; } } DL_FOREACH (thread->open_devs[CRAS_STREAM_INPUT], adev) { DL_FOREACH (adev->dev->streams, curr) { int fd = dev_stream_poll_stream_fd(curr); if (fd < 0) continue; if (!add_pollfd(thread, fd, POLLIN)) goto restart_poll_loop; } } log_busyloop(wait_ts); ATLOG(atlog, AUDIO_THREAD_SLEEP, wait_ts ? wait_ts->tv_sec : 0, wait_ts ? wait_ts->tv_nsec : 0, non_empty); if (wait_ts) check_busyloop(wait_ts); /* Sync atlog with shared memory. */ __sync_synchronize(); atlog->sync_write_pos = atlog->write_pos; rc = ppoll(thread->pollfds, thread->num_pollfds, wait_ts, NULL); ATLOG(atlog, AUDIO_THREAD_WAKE, rc, 0, 0); /* Handle callbacks registered by TRIGGER_WAKEUP */ DL_FOREACH (iodev_callbacks, iodev_cb) { if (iodev_cb->trigger == TRIGGER_WAKEUP) { ATLOG(atlog, AUDIO_THREAD_IODEV_CB, 0, 0, 0); iodev_cb->cb(iodev_cb->cb_data, 0); } } /* If there's no pollfd ready to handle. */ if (rc <= 0) continue; if (thread->pollfds[0].revents & POLLIN) { rc = handle_audio_thread_message(thread); if (rc < 0) syslog(LOG_ERR, "handle message %d", rc); } DL_FOREACH (iodev_callbacks, iodev_cb) { if (iodev_cb->pollfd && iodev_cb->pollfd->revents & iodev_cb->events) { ATLOG(atlog, AUDIO_THREAD_IODEV_CB, iodev_cb->pollfd->revents, iodev_cb->events, 0); iodev_cb->cb(iodev_cb->cb_data, iodev_cb->pollfd->revents); } } } return NULL; } /* Write a message to the playback thread and wait for an ack, This keeps these * operations synchronous for the main server thread. For instance when the * RM_STREAM message is sent, the stream can be deleted after the function * returns. Making this synchronous also allows the thread to return an error * code that can be handled by the caller. * Args: * thread - thread to receive message. * msg - The message to send. * Returns: * A return code from the message handler in the thread. */ static int audio_thread_post_message(struct audio_thread *thread, struct audio_thread_msg *msg) { int err, rsp; err = write(thread->to_thread_fds[1], msg, msg->length); if (err < 0) { syslog(LOG_ERR, "Failed to post message to thread."); return err; } /* Synchronous action, wait for response. */ err = read_until_finished(thread->to_main_fds[0], &rsp, sizeof(rsp)); if (err < 0) { syslog(LOG_ERR, "Failed to read reply from thread."); return err; } return rsp; } static void init_open_device_msg(struct audio_thread_open_device_msg *msg, enum AUDIO_THREAD_COMMAND id, struct cras_iodev *dev) { memset(msg, 0, sizeof(*msg)); msg->header.id = id; msg->header.length = sizeof(*msg); msg->dev = dev; } static void init_rm_device_msg(struct audio_thread_rm_device_msg *msg, enum CRAS_STREAM_DIRECTION dir, unsigned int dev_idx) { memset(msg, 0, sizeof(*msg)); msg->header.id = AUDIO_THREAD_RM_OPEN_DEV; msg->header.length = sizeof(*msg); msg->dir = dir; msg->dev_idx = dev_idx; } static void init_add_rm_stream_msg(struct audio_thread_add_rm_stream_msg *msg, enum AUDIO_THREAD_COMMAND id, struct cras_rstream *stream, struct cras_iodev **devs, unsigned int num_devs) { memset(msg, 0, sizeof(*msg)); msg->header.id = id; msg->header.length = sizeof(*msg); msg->stream = stream; msg->devs = devs; msg->num_devs = num_devs; } static void init_dump_debug_info_msg(struct audio_thread_dump_debug_info_msg *msg, struct audio_debug_info *info) { memset(msg, 0, sizeof(*msg)); msg->header.id = AUDIO_THREAD_DUMP_THREAD_INFO; msg->header.length = sizeof(*msg); msg->info = info; } static void init_config_global_remix_msg(struct audio_thread_config_global_remix *msg) { memset(msg, 0, sizeof(*msg)); msg->header.id = AUDIO_THREAD_CONFIG_GLOBAL_REMIX; msg->header.length = sizeof(*msg); } static void init_device_start_ramp_msg(struct audio_thread_dev_start_ramp_msg *msg, enum AUDIO_THREAD_COMMAND id, unsigned int dev_idx, enum CRAS_IODEV_RAMP_REQUEST request) { memset(msg, 0, sizeof(*msg)); msg->header.id = id; msg->header.length = sizeof(*msg); msg->dev_idx = dev_idx; msg->request = request; } /* Exported Interface */ int audio_thread_event_log_shm_fd() { return atlog_ro_shm_fd; } int audio_thread_add_stream(struct audio_thread *thread, struct cras_rstream *stream, struct cras_iodev **devs, unsigned int num_devs) { struct audio_thread_add_rm_stream_msg msg; assert(thread && stream); if (!thread->started) return -EINVAL; init_add_rm_stream_msg(&msg, AUDIO_THREAD_ADD_STREAM, stream, devs, num_devs); return audio_thread_post_message(thread, &msg.header); } int audio_thread_disconnect_stream(struct audio_thread *thread, struct cras_rstream *stream, struct cras_iodev *dev) { struct audio_thread_add_rm_stream_msg msg; assert(thread && stream); init_add_rm_stream_msg(&msg, AUDIO_THREAD_DISCONNECT_STREAM, stream, &dev, 0); return audio_thread_post_message(thread, &msg.header); } int audio_thread_drain_stream(struct audio_thread *thread, struct cras_rstream *stream) { struct audio_thread_add_rm_stream_msg msg; assert(thread && stream); init_add_rm_stream_msg(&msg, AUDIO_THREAD_DRAIN_STREAM, stream, NULL, 0); return audio_thread_post_message(thread, &msg.header); } int audio_thread_dump_thread_info(struct audio_thread *thread, struct audio_debug_info *info) { struct audio_thread_dump_debug_info_msg msg; init_dump_debug_info_msg(&msg, info); return audio_thread_post_message(thread, &msg.header); } int audio_thread_set_aec_dump(struct audio_thread *thread, cras_stream_id_t stream_id, unsigned int start, int fd) { struct audio_thread_aec_dump_msg msg; memset(&msg, 0, sizeof(msg)); msg.header.id = AUDIO_THREAD_AEC_DUMP; msg.header.length = sizeof(msg); msg.stream_id = stream_id; msg.start = start; msg.fd = fd; return audio_thread_post_message(thread, &msg.header); } int audio_thread_rm_callback_sync(struct audio_thread *thread, int fd) { struct audio_thread_rm_callback_msg msg; memset(&msg, 0, sizeof(msg)); msg.header.id = AUDIO_THREAD_REMOVE_CALLBACK; msg.header.length = sizeof(msg); msg.fd = fd; return audio_thread_post_message(thread, &msg.header); } int audio_thread_config_global_remix(struct audio_thread *thread, unsigned int num_channels, const float *coefficient) { int err; int identity_remix = 1; unsigned int i, j; struct audio_thread_config_global_remix msg; void *rsp; init_config_global_remix_msg(&msg); /* Check if the coefficients represent an identity matrix for remix * conversion, which means no remix at all. If so then leave the * converter as NULL. */ for (i = 0; i < num_channels; i++) { if (coefficient[i * num_channels + i] != 1.0f) { identity_remix = 0; break; } for (j = i + 1; j < num_channels; j++) { if (coefficient[i * num_channels + j] != 0 || coefficient[j * num_channels + i] != 0) { identity_remix = 0; break; } } } if (!identity_remix) { msg.fmt_conv = cras_channel_remix_conv_create(num_channels, coefficient); if (NULL == msg.fmt_conv) return -ENOMEM; } err = write(thread->to_thread_fds[1], &msg, msg.header.length); if (err < 0) { syslog(LOG_ERR, "Failed to post message to thread."); return err; } /* Synchronous action, wait for response. */ err = read_until_finished(thread->to_main_fds[0], &rsp, sizeof(rsp)); if (err < 0) { syslog(LOG_ERR, "Failed to read reply from thread."); return err; } if (rsp) cras_fmt_conv_destroy((struct cras_fmt_conv **)&rsp); return 0; } struct audio_thread *audio_thread_create() { int rc; struct audio_thread *thread; thread = (struct audio_thread *)calloc(1, sizeof(*thread)); if (!thread) return NULL; thread->to_thread_fds[0] = -1; thread->to_thread_fds[1] = -1; thread->to_main_fds[0] = -1; thread->to_main_fds[1] = -1; /* Two way pipes for communication with the device's audio thread. */ rc = pipe(thread->to_thread_fds); if (rc < 0) { syslog(LOG_ERR, "Failed to pipe"); free(thread); return NULL; } rc = pipe(thread->to_main_fds); if (rc < 0) { syslog(LOG_ERR, "Failed to pipe"); free(thread); return NULL; } if (asprintf(&atlog_name, "/ATlog-%d", getpid()) < 0) { syslog(LOG_ERR, "Failed to generate ATlog name."); exit(-1); } atlog = audio_thread_event_log_init(atlog_name); thread->pollfds_size = 32; thread->pollfds = (struct pollfd *)malloc(sizeof(*thread->pollfds) * thread->pollfds_size); return thread; } int audio_thread_add_open_dev(struct audio_thread *thread, struct cras_iodev *dev) { struct audio_thread_open_device_msg msg; assert(thread && dev); if (!thread->started) return -EINVAL; init_open_device_msg(&msg, AUDIO_THREAD_ADD_OPEN_DEV, dev); return audio_thread_post_message(thread, &msg.header); } int audio_thread_rm_open_dev(struct audio_thread *thread, enum CRAS_STREAM_DIRECTION dir, unsigned int dev_idx) { struct audio_thread_rm_device_msg msg; assert(thread); if (!thread->started) return -EINVAL; init_rm_device_msg(&msg, dir, dev_idx); return audio_thread_post_message(thread, &msg.header); } int audio_thread_is_dev_open(struct audio_thread *thread, struct cras_iodev *dev) { struct audio_thread_open_device_msg msg; if (!dev) return 0; init_open_device_msg(&msg, AUDIO_THREAD_IS_DEV_OPEN, dev); return audio_thread_post_message(thread, &msg.header); } int audio_thread_dev_start_ramp(struct audio_thread *thread, unsigned int dev_idx, enum CRAS_IODEV_RAMP_REQUEST request) { struct audio_thread_dev_start_ramp_msg msg; assert(thread); if (!thread->started) return -EINVAL; init_device_start_ramp_msg(&msg, AUDIO_THREAD_DEV_START_RAMP, dev_idx, request); return audio_thread_post_message(thread, &msg.header); } int audio_thread_start(struct audio_thread *thread) { int rc; rc = pthread_create(&thread->tid, NULL, audio_io_thread, thread); if (rc) { syslog(LOG_ERR, "Failed pthread_create"); return rc; } thread->started = 1; return 0; } void audio_thread_destroy(struct audio_thread *thread) { if (thread->started) { struct audio_thread_msg msg; msg.id = AUDIO_THREAD_STOP; msg.length = sizeof(msg); audio_thread_post_message(thread, &msg); pthread_join(thread->tid, NULL); } free(thread->pollfds); audio_thread_event_log_deinit(atlog, atlog_name); free(atlog_name); if (thread->to_thread_fds[0] != -1) { close(thread->to_thread_fds[0]); close(thread->to_thread_fds[1]); } if (thread->to_main_fds[0] != -1) { close(thread->to_main_fds[0]); close(thread->to_main_fds[1]); } if (thread->remix_converter) cras_fmt_conv_destroy(&thread->remix_converter); free(thread); }