/* * Squeezelite for esp32 * * (c) Sebastien 2019 * Philippe G. 2019, philippe_44@outlook.com * * This software is released under the MIT License. * https://opensource.org/licenses/MIT * */ #include "platform_config.h" #include "squeezelite.h" #include "bt_app_sink.h" #include "raop_sink.h" #include #define LOCK_O mutex_lock(outputbuf->mutex) #define UNLOCK_O mutex_unlock(outputbuf->mutex) #define LOCK_D mutex_lock(decode.mutex); #define UNLOCK_D mutex_unlock(decode.mutex); enum { DECODE_BT = 1, DECODE_RAOP }; extern struct outputstate output; extern struct decodestate decode; extern struct buffer *outputbuf; // this is the only system-wide loglevel variable extern log_level loglevel; static bool enable_bt_sink; static bool enable_airplay; #define RAOP_OUTPUT_SIZE (((RAOP_SAMPLE_RATE * BYTES_PER_FRAME * 2 * 120) / 100) & ~BYTES_PER_FRAME) #define SYNC_WIN_SLOW 32 #define SYNC_WIN_CHECK 8 #define SYNC_WIN_FAST 2 static raop_event_t raop_state; static EXT_RAM_ATTR struct { bool enabled; int sum, count, win, errors[SYNC_WIN_SLOW]; s32_t len; u32_t start_time, playtime; } raop_sync; /**************************************************************************************** * Common sink data handler */ static void sink_data_handler(const uint8_t *data, uint32_t len) { size_t bytes, space; int wait = 5; // would be better to lock output, but really, it does not matter if (!output.external) { LOG_SDEBUG("Cannot use external sink while LMS is controlling player"); return; } // there will always be room at some point while (len) { LOCK_O; bytes = min(_buf_space(outputbuf), _buf_cont_write(outputbuf)) / (BYTES_PER_FRAME / 4); bytes = min(len, bytes); #if BYTES_PER_FRAME == 4 memcpy(outputbuf->writep, data, bytes); #else { s16_t *iptr = (s16_t*) data; ISAMPLE_T *optr = (ISAMPLE_T *) outputbuf->writep; size_t n = bytes / 2; while (n--) *optr++ = *iptr++ << 16; } #endif _buf_inc_writep(outputbuf, bytes * BYTES_PER_FRAME / 4); space = _buf_space(outputbuf); len -= bytes; data += bytes; UNLOCK_O; // allow i2s to empty the buffer if needed if (len && !space && wait--) usleep(20000); } if (!wait) { LOG_WARN("Waited too long, dropping frames"); } } /**************************************************************************************** * BT sink command handler */ static bool bt_sink_cmd_handler(bt_sink_cmd_t cmd, va_list args) { // don't LOCK_O as there is always a chance that LMS takes control later anyway if (output.external != DECODE_BT && output.state > OUTPUT_STOPPED) { LOG_WARN("Cannot use BT sink while LMS/AirPlay is controlling player"); return false; } LOCK_D; if (cmd != BT_SINK_VOLUME) LOCK_O; switch(cmd) { case BT_SINK_AUDIO_STARTED: output.next_sample_rate = output.current_sample_rate = va_arg(args, u32_t); output.external = DECODE_BT; output.state = OUTPUT_STOPPED; output.frames_played = 0; _buf_flush(outputbuf); if (decode.state != DECODE_STOPPED) decode.state = DECODE_ERROR; LOG_INFO("BT sink started"); break; case BT_SINK_AUDIO_STOPPED: if (output.external == DECODE_BT) { if (output.state > OUTPUT_STOPPED) output.state = OUTPUT_STOPPED; output.stop_time = gettime_ms(); LOG_INFO("BT sink stopped"); } break; case BT_SINK_PLAY: output.state = OUTPUT_RUNNING; LOG_INFO("BT playing"); break; case BT_SINK_STOP: _buf_flush(outputbuf); output.state = OUTPUT_STOPPED; output.stop_time = gettime_ms(); LOG_INFO("BT stopped"); break; case BT_SINK_PAUSE: output.stop_time = gettime_ms(); LOG_INFO("BT paused, just silence"); break; case BT_SINK_RATE: output.next_sample_rate = output.current_sample_rate = va_arg(args, u32_t); LOG_INFO("Setting BT sample rate %u", output.next_sample_rate); break; case BT_SINK_VOLUME: { u32_t volume = va_arg(args, u32_t); volume = 65536 * powf(volume / 128.0f, 3); set_volume(volume, volume); break; default: break; } } if (cmd != BT_SINK_VOLUME) UNLOCK_O; UNLOCK_D; return true; } /**************************************************************************************** * raop sink data handler */ static void raop_sink_data_handler(const uint8_t *data, uint32_t len, u32_t playtime) { raop_sync.playtime = playtime; raop_sync.len = len; sink_data_handler(data, len); } /**************************************************************************************** * AirPlay sink command handler */ static bool raop_sink_cmd_handler(raop_event_t event, va_list args) { // don't LOCK_O as there is always a chance that LMS takes control later anyway if (output.external != DECODE_RAOP && output.state > OUTPUT_STOPPED) { LOG_WARN("Cannot use Airplay sink while LMS/BT is controlling player"); return false; } LOCK_D; if (event != RAOP_VOLUME) LOCK_O; // this is async, so player might have been deleted switch (event) { case RAOP_TIMING: { if (!raop_sync.enabled || output.state != OUTPUT_RUNNING || output.frames_played_dmp < output.device_frames) break; u32_t ms, now = gettime_ms(); u32_t level = _buf_used(outputbuf); int error; // in how many ms will the most recent block play ms = (((s32_t)(level - raop_sync.len) / BYTES_PER_FRAME + output.device_frames + output.frames_in_process) * 10) / (RAOP_SAMPLE_RATE / 100) - (s32_t) (now - output.updated); // when outputbuf is empty, it means we have a network black-out or something error = level ? (raop_sync.playtime - now) - ms : 0; if (loglevel == lDEBUG || !level) { LOG_INFO("head local:%d, remote:%d (delta:%d)", ms, raop_sync.playtime - now, error); LOG_INFO("obuf:%u, sync_len:%u, devframes:%u, inproc:%u", _buf_used(outputbuf), raop_sync.len, output.device_frames, output.frames_in_process); } // calculate sum, error and update sliding window raop_sync.errors[raop_sync.count++ % raop_sync.win] = error; raop_sync.sum += error; error = raop_sync.sum / min(raop_sync.count, raop_sync.win); // wait till we have enough data or there is a strong deviation if ((raop_sync.count >= raop_sync.win && abs(error) > 10) || (raop_sync.count >= SYNC_WIN_CHECK && abs(error) > 100)) { if (error < 0) { output.skip_frames = -(error * RAOP_SAMPLE_RATE) / 1000; output.state = OUTPUT_SKIP_FRAMES; LOG_INFO("skipping %u frames (count:%d)", output.skip_frames, raop_sync.count); } else { output.pause_frames = (error * RAOP_SAMPLE_RATE) / 1000; output.state = OUTPUT_PAUSE_FRAMES; LOG_INFO("pausing for %u frames (count: %d)", output.pause_frames, raop_sync.count); } raop_sync.sum = raop_sync.count = 0; memset(raop_sync.errors, 0, sizeof(raop_sync.errors)); } // move to normal mode if possible if (raop_sync.win == 1) { raop_sync.win = SYNC_WIN_FAST; LOG_INFO("backend played %u, desired %u, (delta:%d)", ms, raop_sync.playtime - now, error); } else if (raop_sync.win == SYNC_WIN_FAST && raop_sync.count >= SYNC_WIN_FAST && abs(error) < 10) { raop_sync.win = SYNC_WIN_SLOW; LOG_INFO("switching to slow sync mode %u", raop_sync.win); } break; } case RAOP_SETUP: // we need a fair bit of space for RTP process _buf_resize(outputbuf, RAOP_OUTPUT_SIZE); output.frames_played = 0; output.external = DECODE_RAOP; output.state = OUTPUT_STOPPED; if (decode.state != DECODE_STOPPED) decode.state = DECODE_ERROR; LOG_INFO("resizing buffer %u", outputbuf->size); break; case RAOP_STREAM: LOG_INFO("Stream", NULL); raop_state = event; raop_sync.win = 1; raop_sync.sum = raop_sync.count = 0; memset(raop_sync.errors, 0, sizeof(raop_sync.errors)); raop_sync.enabled = !strcasestr(output.device, "BT"); output.next_sample_rate = output.current_sample_rate = RAOP_SAMPLE_RATE; break; case RAOP_STOP: case RAOP_FLUSH: if (event == RAOP_FLUSH) { LOG_INFO("Flush", NULL); } else { LOG_INFO("Stop", NULL); } raop_state = event; _buf_flush(outputbuf); if (output.state > OUTPUT_STOPPED) output.state = OUTPUT_STOPPED; output.frames_played = 0; output.stop_time = gettime_ms(); break; case RAOP_PLAY: { LOG_INFO("Play", NULL); if (raop_state != RAOP_PLAY) { output.state = OUTPUT_START_AT; output.start_at = va_arg(args, u32_t); raop_sync.start_time = output.start_at; LOG_INFO("Starting at %u (in %d ms)", output.start_at, output.start_at - gettime_ms()); } raop_state = event; break; } case RAOP_VOLUME: { float volume = va_arg(args, double); LOG_INFO("Volume[0..1] %0.4f", volume); volume = 65536 * powf(volume, 3); set_volume(volume, volume); break; } default: break; } if (event != RAOP_VOLUME) UNLOCK_O; UNLOCK_D; return true; } /**************************************************************************************** * We provide the generic codec register option */ void register_external(void) { char *p; if ((p = config_alloc_get(NVS_TYPE_STR, "enable_bt_sink")) != NULL) { enable_bt_sink = strcmp(p,"1") == 0 || strcasecmp(p,"y") == 0; free(p); } if ((p = config_alloc_get(NVS_TYPE_STR, "enable_airplay")) != NULL) { enable_airplay = strcmp(p,"1") == 0 || strcasecmp(p,"y") == 0; free(p); } if (!strcasestr(output.device, "BT ") ) { if(enable_bt_sink){ bt_sink_init(bt_sink_cmd_handler, sink_data_handler); LOG_INFO("Initializing BT sink"); } } else { LOG_WARN("Cannot be a BT sink and source"); } if (enable_airplay){ raop_sink_init(raop_sink_cmd_handler, raop_sink_data_handler); LOG_INFO("Initializing AirPlay sink"); } } void deregister_external(void) { if (!strcasestr(output.device, "BT ") && enable_bt_sink) { LOG_INFO("Stopping BT sink"); bt_sink_deinit(); } if (enable_airplay){ LOG_INFO("Stopping AirPlay sink"); raop_sink_deinit(); } } void decode_restore(int external) { switch (external) { case DECODE_BT: bt_disconnect(); break; case DECODE_RAOP: raop_disconnect(); raop_state = RAOP_STOP; break; } }