/****************************************************************************** * * Copyright 2016 The Android Open Source Project * Copyright 2009-2012 Broadcom Corporation * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at: * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. * ******************************************************************************/ #define LOG_TAG "bt_btif_a2dp_source" #define ATRACE_TAG ATRACE_TAG_AUDIO #include #ifndef OS_GENERIC #include #endif #include #include #include #include #include "audio_a2dp_hw/include/audio_a2dp_hw.h" #include "audio_hal_interface/a2dp_encoding.h" #include "bt_common.h" #include "bta_av_ci.h" #include "btif_a2dp.h" #include "btif_a2dp_audio_interface.h" #include "btif_a2dp_control.h" #include "btif_a2dp_source.h" #include "btif_av.h" #include "btif_av_co.h" #include "btif_util.h" #include "common/message_loop_thread.h" #include "common/metrics.h" #include "common/repeating_timer.h" #include "common/time_util.h" #include "osi/include/fixed_queue.h" #include "osi/include/log.h" #include "osi/include/osi.h" #include "osi/include/wakelock.h" #include "uipc.h" using bluetooth::common::A2dpSessionMetrics; using bluetooth::common::BluetoothMetricsLogger; using bluetooth::common::RepeatingTimer; extern std::unique_ptr a2dp_uipc; /** * The typical runlevel of the tx queue size is ~1 buffer * but due to link flow control or thread preemption in lower * layers we might need to temporarily buffer up data. */ #define MAX_OUTPUT_A2DP_FRAME_QUEUE_SZ (MAX_PCM_FRAME_NUM_PER_TICK * 2) class SchedulingStats { public: SchedulingStats() { Reset(); } void Reset() { total_updates = 0; last_update_us = 0; overdue_scheduling_count = 0; total_overdue_scheduling_delta_us = 0; max_overdue_scheduling_delta_us = 0; premature_scheduling_count = 0; total_premature_scheduling_delta_us = 0; max_premature_scheduling_delta_us = 0; exact_scheduling_count = 0; total_scheduling_time_us = 0; } // Counter for total updates size_t total_updates; // Last update timestamp (in us) uint64_t last_update_us; // Counter for overdue scheduling size_t overdue_scheduling_count; // Accumulated overdue scheduling deviations (in us) uint64_t total_overdue_scheduling_delta_us; // Max. overdue scheduling delta time (in us) uint64_t max_overdue_scheduling_delta_us; // Counter for premature scheduling size_t premature_scheduling_count; // Accumulated premature scheduling deviations (in us) uint64_t total_premature_scheduling_delta_us; // Max. premature scheduling delta time (in us) uint64_t max_premature_scheduling_delta_us; // Counter for exact scheduling size_t exact_scheduling_count; // Accumulated and counted scheduling time (in us) uint64_t total_scheduling_time_us; }; class BtifMediaStats { public: BtifMediaStats() { Reset(); } void Reset() { session_start_us = 0; session_end_us = 0; tx_queue_enqueue_stats.Reset(); tx_queue_dequeue_stats.Reset(); tx_queue_total_frames = 0; tx_queue_max_frames_per_packet = 0; tx_queue_total_queueing_time_us = 0; tx_queue_max_queueing_time_us = 0; tx_queue_total_readbuf_calls = 0; tx_queue_last_readbuf_us = 0; tx_queue_total_flushed_messages = 0; tx_queue_last_flushed_us = 0; tx_queue_total_dropped_messages = 0; tx_queue_max_dropped_messages = 0; tx_queue_dropouts = 0; tx_queue_last_dropouts_us = 0; media_read_total_underflow_bytes = 0; media_read_total_underflow_count = 0; media_read_last_underflow_us = 0; codec_index = -1; } uint64_t session_start_us; uint64_t session_end_us; SchedulingStats tx_queue_enqueue_stats; SchedulingStats tx_queue_dequeue_stats; size_t tx_queue_total_frames; size_t tx_queue_max_frames_per_packet; uint64_t tx_queue_total_queueing_time_us; uint64_t tx_queue_max_queueing_time_us; size_t tx_queue_total_readbuf_calls; uint64_t tx_queue_last_readbuf_us; size_t tx_queue_total_flushed_messages; uint64_t tx_queue_last_flushed_us; size_t tx_queue_total_dropped_messages; size_t tx_queue_max_dropped_messages; size_t tx_queue_dropouts; uint64_t tx_queue_last_dropouts_us; size_t media_read_total_underflow_bytes; size_t media_read_total_underflow_count; uint64_t media_read_last_underflow_us; int codec_index = -1; }; class BtifA2dpSource { public: enum RunState { kStateOff, kStateStartingUp, kStateRunning, kStateShuttingDown }; BtifA2dpSource() : tx_audio_queue(nullptr), tx_flush(false), encoder_interface(nullptr), encoder_interval_ms(0), state_(kStateOff) {} void Reset() { fixed_queue_free(tx_audio_queue, nullptr); tx_audio_queue = nullptr; tx_flush = false; media_alarm.CancelAndWait(); wakelock_release(); encoder_interface = nullptr; encoder_interval_ms = 0; stats.Reset(); accumulated_stats.Reset(); state_ = kStateOff; } BtifA2dpSource::RunState State() const { return state_; } std::string StateStr() const { switch (state_) { case kStateOff: return "STATE_OFF"; case kStateStartingUp: return "STATE_STARTING_UP"; case kStateRunning: return "STATE_RUNNING"; case kStateShuttingDown: return "STATE_SHUTTING_DOWN"; } } void SetState(BtifA2dpSource::RunState state) { state_ = state; } fixed_queue_t* tx_audio_queue; bool tx_flush; /* Discards any outgoing data when true */ RepeatingTimer media_alarm; const tA2DP_ENCODER_INTERFACE* encoder_interface; uint64_t encoder_interval_ms; /* Local copy of the encoder interval */ BtifMediaStats stats; BtifMediaStats accumulated_stats; private: BtifA2dpSource::RunState state_; }; static bluetooth::common::MessageLoopThread btif_a2dp_source_thread( "bt_a2dp_source_worker_thread"); static BtifA2dpSource btif_a2dp_source_cb; static void btif_a2dp_source_init_delayed(void); static void btif_a2dp_source_startup_delayed(void); static void btif_a2dp_source_start_session_delayed( const RawAddress& peer_address, std::promise start_session_promise); static void btif_a2dp_source_end_session_delayed( const RawAddress& peer_address); static void btif_a2dp_source_shutdown_delayed(void); static void btif_a2dp_source_cleanup_delayed(void); static void btif_a2dp_source_audio_tx_start_event(void); static void btif_a2dp_source_audio_tx_stop_event(void); static void btif_a2dp_source_audio_tx_flush_event(void); // Set up the A2DP Source codec, and prepare the encoder. // The peer address is |peer_addr|. // This function should be called prior to starting A2DP streaming. static void btif_a2dp_source_setup_codec(const RawAddress& peer_addr); static void btif_a2dp_source_setup_codec_delayed( const RawAddress& peer_address); static void btif_a2dp_source_encoder_user_config_update_event( const RawAddress& peer_address, const btav_a2dp_codec_config_t& codec_user_config); static void btif_a2dp_source_audio_feeding_update_event( const btav_a2dp_codec_config_t& codec_audio_config); static bool btif_a2dp_source_audio_tx_flush_req(void); static void btif_a2dp_source_audio_handle_timer(void); static uint32_t btif_a2dp_source_read_callback(uint8_t* p_buf, uint32_t len); static bool btif_a2dp_source_enqueue_callback(BT_HDR* p_buf, size_t frames_n, uint32_t bytes_read); static void log_tstamps_us(const char* comment, uint64_t timestamp_us); static void update_scheduling_stats(SchedulingStats* stats, uint64_t now_us, uint64_t expected_delta); // Update the A2DP Source related metrics. // This function should be called before collecting the metrics. static void btif_a2dp_source_update_metrics(void); static void btm_read_rssi_cb(void* data); static void btm_read_failed_contact_counter_cb(void* data); static void btm_read_automatic_flush_timeout_cb(void* data); static void btm_read_tx_power_cb(void* data); void btif_a2dp_source_accumulate_scheduling_stats(SchedulingStats* src, SchedulingStats* dst) { dst->total_updates += src->total_updates; dst->last_update_us = src->last_update_us; dst->overdue_scheduling_count += src->overdue_scheduling_count; dst->total_overdue_scheduling_delta_us += src->total_overdue_scheduling_delta_us; dst->max_overdue_scheduling_delta_us = std::max(dst->max_overdue_scheduling_delta_us, src->max_overdue_scheduling_delta_us); dst->premature_scheduling_count += src->premature_scheduling_count; dst->total_premature_scheduling_delta_us += src->total_premature_scheduling_delta_us; dst->max_premature_scheduling_delta_us = std::max(dst->max_premature_scheduling_delta_us, src->max_premature_scheduling_delta_us); dst->exact_scheduling_count += src->exact_scheduling_count; dst->total_scheduling_time_us += src->total_scheduling_time_us; } void btif_a2dp_source_accumulate_stats(BtifMediaStats* src, BtifMediaStats* dst) { dst->tx_queue_total_frames += src->tx_queue_total_frames; dst->tx_queue_max_frames_per_packet = std::max( dst->tx_queue_max_frames_per_packet, src->tx_queue_max_frames_per_packet); dst->tx_queue_total_queueing_time_us += src->tx_queue_total_queueing_time_us; dst->tx_queue_max_queueing_time_us = std::max( dst->tx_queue_max_queueing_time_us, src->tx_queue_max_queueing_time_us); dst->tx_queue_total_readbuf_calls += src->tx_queue_total_readbuf_calls; dst->tx_queue_last_readbuf_us = src->tx_queue_last_readbuf_us; dst->tx_queue_total_flushed_messages += src->tx_queue_total_flushed_messages; dst->tx_queue_last_flushed_us = src->tx_queue_last_flushed_us; dst->tx_queue_total_dropped_messages += src->tx_queue_total_dropped_messages; dst->tx_queue_max_dropped_messages = std::max( dst->tx_queue_max_dropped_messages, src->tx_queue_max_dropped_messages); dst->tx_queue_dropouts += src->tx_queue_dropouts; dst->tx_queue_last_dropouts_us = src->tx_queue_last_dropouts_us; dst->media_read_total_underflow_bytes += src->media_read_total_underflow_bytes; dst->media_read_total_underflow_count += src->media_read_total_underflow_count; dst->media_read_last_underflow_us = src->media_read_last_underflow_us; if (dst->codec_index < 0) dst->codec_index = src->codec_index; btif_a2dp_source_accumulate_scheduling_stats(&src->tx_queue_enqueue_stats, &dst->tx_queue_enqueue_stats); btif_a2dp_source_accumulate_scheduling_stats(&src->tx_queue_dequeue_stats, &dst->tx_queue_dequeue_stats); src->Reset(); } bool btif_a2dp_source_init(void) { LOG_INFO(LOG_TAG, "%s", __func__); // Start A2DP Source media task btif_a2dp_source_thread.StartUp(); btif_a2dp_source_thread.DoInThread( FROM_HERE, base::Bind(&btif_a2dp_source_init_delayed)); return true; } static void btif_a2dp_source_init_delayed(void) { LOG_INFO(LOG_TAG, "%s", __func__); // Nothing to do } bool btif_a2dp_source_startup(void) { LOG_INFO(LOG_TAG, "%s: state=%s", __func__, btif_a2dp_source_cb.StateStr().c_str()); if (btif_a2dp_source_cb.State() != BtifA2dpSource::kStateOff) { LOG_ERROR(LOG_TAG, "%s: A2DP Source media task already running", __func__); return false; } btif_a2dp_source_cb.Reset(); btif_a2dp_source_cb.SetState(BtifA2dpSource::kStateStartingUp); btif_a2dp_source_cb.tx_audio_queue = fixed_queue_new(SIZE_MAX); // Schedule the rest of the operations btif_a2dp_source_thread.DoInThread( FROM_HERE, base::Bind(&btif_a2dp_source_startup_delayed)); return true; } static void btif_a2dp_source_startup_delayed() { LOG_INFO(LOG_TAG, "%s: state=%s", __func__, btif_a2dp_source_cb.StateStr().c_str()); if (!btif_a2dp_source_thread.EnableRealTimeScheduling()) { LOG(FATAL) << __func__ << ": unable to enable real time scheduling"; } if (!bluetooth::audio::a2dp::init(&btif_a2dp_source_thread)) { if (btif_av_is_a2dp_offload_enabled()) { LOG(WARNING) << __func__ << ": Using BluetoothA2dp HAL"; } else { LOG(WARNING) << __func__ << ": Using legacy HAL"; btif_a2dp_control_init(); } } btif_a2dp_source_cb.SetState(BtifA2dpSource::kStateRunning); } bool btif_a2dp_source_start_session(const RawAddress& peer_address, std::promise peer_ready_promise) { LOG(INFO) << __func__ << ": peer_address=" << peer_address << " state=" << btif_a2dp_source_cb.StateStr(); btif_a2dp_source_setup_codec(peer_address); if (btif_a2dp_source_thread.DoInThread( FROM_HERE, base::BindOnce(&btif_a2dp_source_start_session_delayed, peer_address, std::move(peer_ready_promise)))) { return true; } else { // cannot set promise but triggers crash LOG(FATAL) << __func__ << ": peer_address=" << peer_address << " state=" << btif_a2dp_source_cb.StateStr() << " fails to context switch"; return false; } } static void btif_a2dp_source_start_session_delayed( const RawAddress& peer_address, std::promise peer_ready_promise) { LOG(INFO) << __func__ << ": peer_address=" << peer_address << " state=" << btif_a2dp_source_cb.StateStr(); if (btif_a2dp_source_cb.State() != BtifA2dpSource::kStateRunning) { LOG(ERROR) << __func__ << ": A2DP Source media task is not running"; peer_ready_promise.set_value(); return; } if (bluetooth::audio::a2dp::is_hal_2_0_enabled()) { bluetooth::audio::a2dp::start_session(); BluetoothMetricsLogger::GetInstance()->LogBluetoothSessionStart( bluetooth::common::CONNECTION_TECHNOLOGY_TYPE_BREDR, 0); } else if (btif_av_is_a2dp_offload_enabled()) { btif_a2dp_audio_interface_start_session(); } else { BluetoothMetricsLogger::GetInstance()->LogBluetoothSessionStart( bluetooth::common::CONNECTION_TECHNOLOGY_TYPE_BREDR, 0); } peer_ready_promise.set_value(); } bool btif_a2dp_source_restart_session(const RawAddress& old_peer_address, const RawAddress& new_peer_address, std::promise peer_ready_promise) { bool is_streaming = btif_a2dp_source_cb.media_alarm.IsScheduled(); LOG(INFO) << __func__ << ": old_peer_address=" << old_peer_address << " new_peer_address=" << new_peer_address << " is_streaming=" << logbool(is_streaming) << " state=" << btif_a2dp_source_cb.StateStr(); CHECK(!new_peer_address.IsEmpty()); // Must stop first the audio streaming if (is_streaming) { btif_a2dp_source_stop_audio_req(); } // If the old active peer was valid, end the old session. // Otherwise, time to startup the A2DP Source processing. if (!old_peer_address.IsEmpty()) { btif_a2dp_source_end_session(old_peer_address); } else { btif_a2dp_source_startup(); } // Start the session. // If audio was streaming before, start audio streaming as well. btif_a2dp_source_start_session(new_peer_address, std::move(peer_ready_promise)); if (is_streaming) { btif_a2dp_source_start_audio_req(); } return true; } bool btif_a2dp_source_end_session(const RawAddress& peer_address) { LOG_INFO(LOG_TAG, "%s: peer_address=%s state=%s", __func__, peer_address.ToString().c_str(), btif_a2dp_source_cb.StateStr().c_str()); btif_a2dp_source_thread.DoInThread( FROM_HERE, base::Bind(&btif_a2dp_source_end_session_delayed, peer_address)); return true; } static void btif_a2dp_source_end_session_delayed( const RawAddress& peer_address) { LOG_INFO(LOG_TAG, "%s: peer_address=%s state=%s", __func__, peer_address.ToString().c_str(), btif_a2dp_source_cb.StateStr().c_str()); if ((btif_a2dp_source_cb.State() == BtifA2dpSource::kStateRunning) || (btif_a2dp_source_cb.State() == BtifA2dpSource::kStateShuttingDown)) { btif_av_stream_stop(peer_address); } else { LOG_ERROR(LOG_TAG, "%s: A2DP Source media task is not running", __func__); } if (bluetooth::audio::a2dp::is_hal_2_0_enabled()) { bluetooth::audio::a2dp::end_session(); BluetoothMetricsLogger::GetInstance()->LogBluetoothSessionEnd( bluetooth::common::DISCONNECT_REASON_UNKNOWN, 0); } else if (btif_av_is_a2dp_offload_enabled()) { btif_a2dp_audio_interface_end_session(); } else { BluetoothMetricsLogger::GetInstance()->LogBluetoothSessionEnd( bluetooth::common::DISCONNECT_REASON_UNKNOWN, 0); } } void btif_a2dp_source_shutdown(void) { LOG_INFO(LOG_TAG, "%s: state=%s", __func__, btif_a2dp_source_cb.StateStr().c_str()); if ((btif_a2dp_source_cb.State() == BtifA2dpSource::kStateOff) || (btif_a2dp_source_cb.State() == BtifA2dpSource::kStateShuttingDown)) { return; } /* Make sure no channels are restarted while shutting down */ btif_a2dp_source_cb.SetState(BtifA2dpSource::kStateShuttingDown); btif_a2dp_source_thread.DoInThread( FROM_HERE, base::Bind(&btif_a2dp_source_shutdown_delayed)); } static void btif_a2dp_source_shutdown_delayed(void) { LOG_INFO(LOG_TAG, "%s: state=%s", __func__, btif_a2dp_source_cb.StateStr().c_str()); // Stop the timer btif_a2dp_source_cb.media_alarm.CancelAndWait(); wakelock_release(); if (bluetooth::audio::a2dp::is_hal_2_0_enabled()) { bluetooth::audio::a2dp::cleanup(); } else if (btif_av_is_a2dp_offload_enabled()) { btif_a2dp_audio_interface_end_session(); } else { btif_a2dp_control_cleanup(); } fixed_queue_free(btif_a2dp_source_cb.tx_audio_queue, nullptr); btif_a2dp_source_cb.tx_audio_queue = nullptr; btif_a2dp_source_cb.SetState(BtifA2dpSource::kStateOff); } void btif_a2dp_source_cleanup(void) { LOG_INFO(LOG_TAG, "%s: state=%s", __func__, btif_a2dp_source_cb.StateStr().c_str()); // Make sure the source is shutdown btif_a2dp_source_shutdown(); btif_a2dp_source_thread.DoInThread( FROM_HERE, base::Bind(&btif_a2dp_source_cleanup_delayed)); // Exit the thread btif_a2dp_source_thread.ShutDown(); } static void btif_a2dp_source_cleanup_delayed(void) { LOG_INFO(LOG_TAG, "%s: state=%s", __func__, btif_a2dp_source_cb.StateStr().c_str()); // Nothing to do } bool btif_a2dp_source_media_task_is_running(void) { return (btif_a2dp_source_cb.State() == BtifA2dpSource::kStateRunning); } bool btif_a2dp_source_media_task_is_shutting_down(void) { return (btif_a2dp_source_cb.State() == BtifA2dpSource::kStateShuttingDown); } bool btif_a2dp_source_is_streaming(void) { return btif_a2dp_source_cb.media_alarm.IsScheduled(); } static void btif_a2dp_source_setup_codec(const RawAddress& peer_address) { LOG_INFO(LOG_TAG, "%s: peer_address=%s state=%s", __func__, peer_address.ToString().c_str(), btif_a2dp_source_cb.StateStr().c_str()); // Check to make sure the platform has 8 bits/byte since // we're using that in frame size calculations now. CHECK(CHAR_BIT == 8); btif_a2dp_source_audio_tx_flush_req(); btif_a2dp_source_thread.DoInThread( FROM_HERE, base::Bind(&btif_a2dp_source_setup_codec_delayed, peer_address)); } static void btif_a2dp_source_setup_codec_delayed( const RawAddress& peer_address) { LOG_INFO(LOG_TAG, "%s: peer_address=%s state=%s", __func__, peer_address.ToString().c_str(), btif_a2dp_source_cb.StateStr().c_str()); tA2DP_ENCODER_INIT_PEER_PARAMS peer_params; bta_av_co_get_peer_params(peer_address, &peer_params); if (!bta_av_co_set_active_peer(peer_address)) { LOG_ERROR(LOG_TAG, "%s: Cannot stream audio: cannot set active peer to %s", __func__, peer_address.ToString().c_str()); return; } btif_a2dp_source_cb.encoder_interface = bta_av_co_get_encoder_interface(); if (btif_a2dp_source_cb.encoder_interface == nullptr) { LOG_ERROR(LOG_TAG, "%s: Cannot stream audio: no source encoder interface", __func__); return; } A2dpCodecConfig* a2dp_codec_config = bta_av_get_a2dp_current_codec(); if (a2dp_codec_config == nullptr) { LOG_ERROR(LOG_TAG, "%s: Cannot stream audio: current codec is not set", __func__); return; } btif_a2dp_source_cb.encoder_interface->encoder_init( &peer_params, a2dp_codec_config, btif_a2dp_source_read_callback, btif_a2dp_source_enqueue_callback); // Save a local copy of the encoder_interval_ms btif_a2dp_source_cb.encoder_interval_ms = btif_a2dp_source_cb.encoder_interface->get_encoder_interval_ms(); if (bluetooth::audio::a2dp::is_hal_2_0_enabled()) { bluetooth::audio::a2dp::setup_codec(); } } void btif_a2dp_source_start_audio_req(void) { LOG_INFO(LOG_TAG, "%s: state=%s", __func__, btif_a2dp_source_cb.StateStr().c_str()); btif_a2dp_source_thread.DoInThread( FROM_HERE, base::Bind(&btif_a2dp_source_audio_tx_start_event)); } void btif_a2dp_source_stop_audio_req(void) { LOG_INFO(LOG_TAG, "%s: state=%s", __func__, btif_a2dp_source_cb.StateStr().c_str()); btif_a2dp_source_thread.DoInThread( FROM_HERE, base::Bind(&btif_a2dp_source_audio_tx_stop_event)); } void btif_a2dp_source_encoder_user_config_update_req( const RawAddress& peer_address, const btav_a2dp_codec_config_t& codec_user_config) { LOG_INFO(LOG_TAG, "%s: peer_address=%s state=%s", __func__, peer_address.ToString().c_str(), btif_a2dp_source_cb.StateStr().c_str()); btif_a2dp_source_thread.DoInThread( FROM_HERE, base::Bind(&btif_a2dp_source_encoder_user_config_update_event, peer_address, codec_user_config)); } static void btif_a2dp_source_encoder_user_config_update_event( const RawAddress& peer_address, const btav_a2dp_codec_config_t& codec_user_config) { LOG_INFO(LOG_TAG, "%s: peer_address=%s state=%s", __func__, peer_address.ToString().c_str(), btif_a2dp_source_cb.StateStr().c_str()); if (!bta_av_co_set_codec_user_config(peer_address, codec_user_config)) { LOG_ERROR(LOG_TAG, "%s: cannot update codec user configuration", __func__); } } void btif_a2dp_source_feeding_update_req( const btav_a2dp_codec_config_t& codec_audio_config) { LOG_INFO(LOG_TAG, "%s: state=%s", __func__, btif_a2dp_source_cb.StateStr().c_str()); btif_a2dp_source_thread.DoInThread( FROM_HERE, base::Bind(&btif_a2dp_source_audio_feeding_update_event, codec_audio_config)); } static void btif_a2dp_source_audio_feeding_update_event( const btav_a2dp_codec_config_t& codec_audio_config) { LOG_INFO(LOG_TAG, "%s: state=%s", __func__, btif_a2dp_source_cb.StateStr().c_str()); if (!bta_av_co_set_codec_audio_config(codec_audio_config)) { LOG_ERROR(LOG_TAG, "%s: cannot update codec audio feeding parameters", __func__); } } void btif_a2dp_source_on_idle(void) { LOG_INFO(LOG_TAG, "%s: state=%s", __func__, btif_a2dp_source_cb.StateStr().c_str()); if (btif_a2dp_source_cb.State() == BtifA2dpSource::kStateOff) return; /* Make sure media task is stopped */ btif_a2dp_source_stop_audio_req(); } void btif_a2dp_source_on_stopped(tBTA_AV_SUSPEND* p_av_suspend) { LOG_INFO(LOG_TAG, "%s: state=%s", __func__, btif_a2dp_source_cb.StateStr().c_str()); if (btif_a2dp_source_cb.State() == BtifA2dpSource::kStateOff) return; /* allow using this api for other than suspend */ if (p_av_suspend != nullptr) { if (p_av_suspend->status != BTA_AV_SUCCESS) { LOG_ERROR(LOG_TAG, "%s: A2DP stop request failed: status=%d", __func__, p_av_suspend->status); if (p_av_suspend->initiator) { LOG_WARN(LOG_TAG, "%s: A2DP stop request failed: status=%d", __func__, p_av_suspend->status); if (bluetooth::audio::a2dp::is_hal_2_0_enabled()) { bluetooth::audio::a2dp::ack_stream_suspended(A2DP_CTRL_ACK_FAILURE); } else { btif_a2dp_command_ack(A2DP_CTRL_ACK_FAILURE); } } return; } } if (btif_av_is_a2dp_offload_enabled()) { bluetooth::audio::a2dp::ack_stream_suspended(A2DP_CTRL_ACK_SUCCESS); return; } /* ensure tx frames are immediately suspended */ btif_a2dp_source_cb.tx_flush = true; /* request to stop media task */ btif_a2dp_source_audio_tx_flush_req(); btif_a2dp_source_stop_audio_req(); /* once stream is fully stopped we will ack back */ } void btif_a2dp_source_on_suspended(tBTA_AV_SUSPEND* p_av_suspend) { LOG_INFO(LOG_TAG, "%s: state=%s", __func__, btif_a2dp_source_cb.StateStr().c_str()); if (btif_a2dp_source_cb.State() == BtifA2dpSource::kStateOff) return; /* check for status failures */ if (p_av_suspend->status != BTA_AV_SUCCESS) { if (p_av_suspend->initiator) { LOG_WARN(LOG_TAG, "%s: A2DP suspend request failed: status=%d", __func__, p_av_suspend->status); if (bluetooth::audio::a2dp::is_hal_2_0_enabled()) { bluetooth::audio::a2dp::ack_stream_suspended(A2DP_CTRL_ACK_FAILURE); } else { btif_a2dp_command_ack(A2DP_CTRL_ACK_FAILURE); } } } if (btif_av_is_a2dp_offload_enabled()) { bluetooth::audio::a2dp::ack_stream_suspended(A2DP_CTRL_ACK_SUCCESS); return; } /* once stream is fully stopped we will ack back */ /* ensure tx frames are immediately flushed */ btif_a2dp_source_cb.tx_flush = true; /* stop timer tick */ btif_a2dp_source_stop_audio_req(); } /* when true media task discards any tx frames */ void btif_a2dp_source_set_tx_flush(bool enable) { LOG_INFO(LOG_TAG, "%s: enable=%s state=%s", __func__, (enable) ? "true" : "false", btif_a2dp_source_cb.StateStr().c_str()); btif_a2dp_source_cb.tx_flush = enable; } static void btif_a2dp_source_audio_tx_start_event(void) { LOG_INFO(LOG_TAG, "%s: media_alarm is %srunning, streaming %s state=%s", __func__, btif_a2dp_source_cb.media_alarm.IsScheduled() ? "" : "not ", btif_a2dp_source_is_streaming() ? "true" : "false", btif_a2dp_source_cb.StateStr().c_str()); if (btif_av_is_a2dp_offload_enabled()) return; /* Reset the media feeding state */ CHECK(btif_a2dp_source_cb.encoder_interface != nullptr); btif_a2dp_source_cb.encoder_interface->feeding_reset(); APPL_TRACE_EVENT( "%s: starting timer %" PRIu64 " ms", __func__, btif_a2dp_source_cb.encoder_interface->get_encoder_interval_ms()); wakelock_acquire(); btif_a2dp_source_cb.media_alarm.SchedulePeriodic( btif_a2dp_source_thread.GetWeakPtr(), FROM_HERE, base::Bind(&btif_a2dp_source_audio_handle_timer), base::TimeDelta::FromMilliseconds( btif_a2dp_source_cb.encoder_interface->get_encoder_interval_ms())); btif_a2dp_source_cb.stats.Reset(); // Assign session_start_us to 1 when // bluetooth::common::time_get_os_boottime_us() is 0 to indicate // btif_a2dp_source_start_audio_req() has been called btif_a2dp_source_cb.stats.session_start_us = bluetooth::common::time_get_os_boottime_us(); if (btif_a2dp_source_cb.stats.session_start_us == 0) { btif_a2dp_source_cb.stats.session_start_us = 1; } btif_a2dp_source_cb.stats.session_end_us = 0; A2dpCodecConfig* codec_config = bta_av_get_a2dp_current_codec(); if (codec_config != nullptr) { btif_a2dp_source_cb.stats.codec_index = codec_config->codecIndex(); } } static void btif_a2dp_source_audio_tx_stop_event(void) { LOG_INFO(LOG_TAG, "%s: media_alarm is %srunning, streaming %s state=%s", __func__, btif_a2dp_source_cb.media_alarm.IsScheduled() ? "" : "not ", btif_a2dp_source_is_streaming() ? "true" : "false", btif_a2dp_source_cb.StateStr().c_str()); if (btif_av_is_a2dp_offload_enabled()) return; btif_a2dp_source_cb.stats.session_end_us = bluetooth::common::time_get_os_boottime_us(); btif_a2dp_source_update_metrics(); btif_a2dp_source_accumulate_stats(&btif_a2dp_source_cb.stats, &btif_a2dp_source_cb.accumulated_stats); uint8_t p_buf[AUDIO_STREAM_OUTPUT_BUFFER_SZ * 2]; uint16_t event; // Keep track of audio data still left in the pipe if (bluetooth::audio::a2dp::is_hal_2_0_enabled()) { btif_a2dp_control_log_bytes_read( bluetooth::audio::a2dp::read(p_buf, sizeof(p_buf))); } else if (a2dp_uipc != nullptr) { btif_a2dp_control_log_bytes_read(UIPC_Read(*a2dp_uipc, UIPC_CH_ID_AV_AUDIO, &event, p_buf, sizeof(p_buf))); } /* Stop the timer first */ btif_a2dp_source_cb.media_alarm.CancelAndWait(); wakelock_release(); if (bluetooth::audio::a2dp::is_hal_2_0_enabled()) { bluetooth::audio::a2dp::ack_stream_suspended(A2DP_CTRL_ACK_SUCCESS); } else if (a2dp_uipc != nullptr) { UIPC_Close(*a2dp_uipc, UIPC_CH_ID_AV_AUDIO); /* * Try to send acknowldegment once the media stream is * stopped. This will make sure that the A2DP HAL layer is * un-blocked on wait for acknowledgment for the sent command. * This resolves a corner cases AVDTP SUSPEND collision * when the DUT and the remote device issue SUSPEND simultaneously * and due to the processing of the SUSPEND request from the remote, * the media path is torn down. If the A2DP HAL happens to wait * for ACK for the initiated SUSPEND, it would never receive it casuing * a block/wait. Due to this acknowledgement, the A2DP HAL is guranteed * to get the ACK for any pending command in such cases. */ btif_a2dp_command_ack(A2DP_CTRL_ACK_SUCCESS); } /* audio engine stopped, reset tx suspended flag */ btif_a2dp_source_cb.tx_flush = false; /* Reset the media feeding state */ if (btif_a2dp_source_cb.encoder_interface != nullptr) btif_a2dp_source_cb.encoder_interface->feeding_reset(); } static void btif_a2dp_source_audio_handle_timer(void) { if (btif_av_is_a2dp_offload_enabled()) return; uint64_t timestamp_us = bluetooth::common::time_get_os_boottime_us(); log_tstamps_us("A2DP Source tx timer", timestamp_us); if (!btif_a2dp_source_cb.media_alarm.IsScheduled()) { LOG_ERROR(LOG_TAG, "%s: ERROR Media task Scheduled after Suspend", __func__); return; } CHECK(btif_a2dp_source_cb.encoder_interface != nullptr); size_t transmit_queue_length = fixed_queue_length(btif_a2dp_source_cb.tx_audio_queue); #ifndef OS_GENERIC ATRACE_INT("btif TX queue", transmit_queue_length); #endif if (btif_a2dp_source_cb.encoder_interface->set_transmit_queue_length != nullptr) { btif_a2dp_source_cb.encoder_interface->set_transmit_queue_length( transmit_queue_length); } btif_a2dp_source_cb.encoder_interface->send_frames(timestamp_us); bta_av_ci_src_data_ready(BTA_AV_CHNL_AUDIO); update_scheduling_stats(&btif_a2dp_source_cb.stats.tx_queue_enqueue_stats, timestamp_us, btif_a2dp_source_cb.encoder_interval_ms * 1000); } static uint32_t btif_a2dp_source_read_callback(uint8_t* p_buf, uint32_t len) { uint16_t event; uint32_t bytes_read = 0; if (bluetooth::audio::a2dp::is_hal_2_0_enabled()) { bytes_read = bluetooth::audio::a2dp::read(p_buf, len); } else if (a2dp_uipc != nullptr) { bytes_read = UIPC_Read(*a2dp_uipc, UIPC_CH_ID_AV_AUDIO, &event, p_buf, len); } if (bytes_read < len) { LOG_WARN(LOG_TAG, "%s: UNDERFLOW: ONLY READ %d BYTES OUT OF %d", __func__, bytes_read, len); btif_a2dp_source_cb.stats.media_read_total_underflow_bytes += (len - bytes_read); btif_a2dp_source_cb.stats.media_read_total_underflow_count++; btif_a2dp_source_cb.stats.media_read_last_underflow_us = bluetooth::common::time_get_os_boottime_us(); bluetooth::common::LogA2dpAudioUnderrunEvent( btif_av_source_active_peer(), btif_a2dp_source_cb.encoder_interval_ms, len - bytes_read); } return bytes_read; } static bool btif_a2dp_source_enqueue_callback(BT_HDR* p_buf, size_t frames_n, uint32_t bytes_read) { uint64_t now_us = bluetooth::common::time_get_os_boottime_us(); btif_a2dp_control_log_bytes_read(bytes_read); /* Check if timer was stopped (media task stopped) */ if (!btif_a2dp_source_cb.media_alarm.IsScheduled()) { osi_free(p_buf); return false; } /* Check if the transmission queue has been flushed */ if (btif_a2dp_source_cb.tx_flush) { LOG_VERBOSE(LOG_TAG, "%s: tx suspended, discarded frame", __func__); btif_a2dp_source_cb.stats.tx_queue_total_flushed_messages += fixed_queue_length(btif_a2dp_source_cb.tx_audio_queue); btif_a2dp_source_cb.stats.tx_queue_last_flushed_us = now_us; fixed_queue_flush(btif_a2dp_source_cb.tx_audio_queue, osi_free); osi_free(p_buf); return false; } // Check for TX queue overflow // TODO: Using frames_n here is probably wrong: should be "+ 1" instead. if (fixed_queue_length(btif_a2dp_source_cb.tx_audio_queue) + frames_n > MAX_OUTPUT_A2DP_FRAME_QUEUE_SZ) { LOG_WARN(LOG_TAG, "%s: TX queue buffer size now=%u adding=%u max=%d", __func__, (uint32_t)fixed_queue_length(btif_a2dp_source_cb.tx_audio_queue), (uint32_t)frames_n, MAX_OUTPUT_A2DP_FRAME_QUEUE_SZ); // Keep track of drop-outs btif_a2dp_source_cb.stats.tx_queue_dropouts++; btif_a2dp_source_cb.stats.tx_queue_last_dropouts_us = now_us; // Flush all queued buffers size_t drop_n = fixed_queue_length(btif_a2dp_source_cb.tx_audio_queue); btif_a2dp_source_cb.stats.tx_queue_max_dropped_messages = std::max( drop_n, btif_a2dp_source_cb.stats.tx_queue_max_dropped_messages); int num_dropped_encoded_bytes = 0; int num_dropped_encoded_frames = 0; while (fixed_queue_length(btif_a2dp_source_cb.tx_audio_queue)) { btif_a2dp_source_cb.stats.tx_queue_total_dropped_messages++; void* p_data = fixed_queue_try_dequeue(btif_a2dp_source_cb.tx_audio_queue); if (p_data != nullptr) { auto p_dropped_buf = static_cast(p_data); num_dropped_encoded_bytes += p_dropped_buf->len; num_dropped_encoded_frames += p_dropped_buf->layer_specific; osi_free(p_data); } } bluetooth::common::LogA2dpAudioOverrunEvent( btif_av_source_active_peer(), drop_n, btif_a2dp_source_cb.encoder_interval_ms, num_dropped_encoded_frames, num_dropped_encoded_bytes); // Request additional debug info if we had to flush buffers RawAddress peer_bda = btif_av_source_active_peer(); tBTM_STATUS status = BTM_ReadRSSI(peer_bda, btm_read_rssi_cb); if (status != BTM_CMD_STARTED) { LOG_WARN(LOG_TAG, "%s: Cannot read RSSI: status %d", __func__, status); } status = BTM_ReadFailedContactCounter(peer_bda, btm_read_failed_contact_counter_cb); if (status != BTM_CMD_STARTED) { LOG_WARN(LOG_TAG, "%s: Cannot read Failed Contact Counter: status %d", __func__, status); } status = BTM_ReadAutomaticFlushTimeout(peer_bda, btm_read_automatic_flush_timeout_cb); if (status != BTM_CMD_STARTED) { LOG_WARN(LOG_TAG, "%s: Cannot read Automatic Flush Timeout: status %d", __func__, status); } status = BTM_ReadTxPower(peer_bda, BT_TRANSPORT_BR_EDR, btm_read_tx_power_cb); if (status != BTM_CMD_STARTED) { LOG_WARN(LOG_TAG, "%s: Cannot read Tx Power: status %d", __func__, status); } } /* Update the statistics */ btif_a2dp_source_cb.stats.tx_queue_total_frames += frames_n; btif_a2dp_source_cb.stats.tx_queue_max_frames_per_packet = std::max( frames_n, btif_a2dp_source_cb.stats.tx_queue_max_frames_per_packet); CHECK(btif_a2dp_source_cb.encoder_interface != nullptr); fixed_queue_enqueue(btif_a2dp_source_cb.tx_audio_queue, p_buf); return true; } static void btif_a2dp_source_audio_tx_flush_event(void) { /* Flush all enqueued audio buffers (encoded) */ LOG_INFO(LOG_TAG, "%s: state=%s", __func__, btif_a2dp_source_cb.StateStr().c_str()); if (btif_av_is_a2dp_offload_enabled()) return; if (btif_a2dp_source_cb.encoder_interface != nullptr) btif_a2dp_source_cb.encoder_interface->feeding_flush(); btif_a2dp_source_cb.stats.tx_queue_total_flushed_messages += fixed_queue_length(btif_a2dp_source_cb.tx_audio_queue); btif_a2dp_source_cb.stats.tx_queue_last_flushed_us = bluetooth::common::time_get_os_boottime_us(); fixed_queue_flush(btif_a2dp_source_cb.tx_audio_queue, osi_free); if (!bluetooth::audio::a2dp::is_hal_2_0_enabled() && a2dp_uipc != nullptr) { UIPC_Ioctl(*a2dp_uipc, UIPC_CH_ID_AV_AUDIO, UIPC_REQ_RX_FLUSH, nullptr); } } static bool btif_a2dp_source_audio_tx_flush_req(void) { LOG_INFO(LOG_TAG, "%s: state=%s", __func__, btif_a2dp_source_cb.StateStr().c_str()); btif_a2dp_source_thread.DoInThread( FROM_HERE, base::Bind(&btif_a2dp_source_audio_tx_flush_event)); return true; } BT_HDR* btif_a2dp_source_audio_readbuf(void) { uint64_t now_us = bluetooth::common::time_get_os_boottime_us(); BT_HDR* p_buf = (BT_HDR*)fixed_queue_try_dequeue(btif_a2dp_source_cb.tx_audio_queue); btif_a2dp_source_cb.stats.tx_queue_total_readbuf_calls++; btif_a2dp_source_cb.stats.tx_queue_last_readbuf_us = now_us; if (p_buf != nullptr) { // Update the statistics update_scheduling_stats(&btif_a2dp_source_cb.stats.tx_queue_dequeue_stats, now_us, btif_a2dp_source_cb.encoder_interval_ms * 1000); } return p_buf; } static void log_tstamps_us(const char* comment, uint64_t timestamp_us) { static uint64_t prev_us = 0; APPL_TRACE_DEBUG("%s: [%s] ts %08" PRIu64 ", diff : %08" PRIu64 ", queue sz %zu", __func__, comment, timestamp_us, timestamp_us - prev_us, fixed_queue_length(btif_a2dp_source_cb.tx_audio_queue)); prev_us = timestamp_us; } static void update_scheduling_stats(SchedulingStats* stats, uint64_t now_us, uint64_t expected_delta) { uint64_t last_us = stats->last_update_us; stats->total_updates++; stats->last_update_us = now_us; if (last_us == 0) return; // First update: expected delta doesn't apply uint64_t deadline_us = last_us + expected_delta; if (deadline_us < now_us) { // Overdue scheduling uint64_t delta_us = now_us - deadline_us; // Ignore extreme outliers if (delta_us < 10 * expected_delta) { stats->max_overdue_scheduling_delta_us = std::max(delta_us, stats->max_overdue_scheduling_delta_us); stats->total_overdue_scheduling_delta_us += delta_us; stats->overdue_scheduling_count++; stats->total_scheduling_time_us += now_us - last_us; } } else if (deadline_us > now_us) { // Premature scheduling uint64_t delta_us = deadline_us - now_us; // Ignore extreme outliers if (delta_us < 10 * expected_delta) { stats->max_premature_scheduling_delta_us = std::max(delta_us, stats->max_premature_scheduling_delta_us); stats->total_premature_scheduling_delta_us += delta_us; stats->premature_scheduling_count++; stats->total_scheduling_time_us += now_us - last_us; } } else { // On-time scheduling stats->exact_scheduling_count++; stats->total_scheduling_time_us += now_us - last_us; } } void btif_a2dp_source_debug_dump(int fd) { btif_a2dp_source_accumulate_stats(&btif_a2dp_source_cb.stats, &btif_a2dp_source_cb.accumulated_stats); uint64_t now_us = bluetooth::common::time_get_os_boottime_us(); BtifMediaStats* accumulated_stats = &btif_a2dp_source_cb.accumulated_stats; SchedulingStats* enqueue_stats = &accumulated_stats->tx_queue_enqueue_stats; SchedulingStats* dequeue_stats = &accumulated_stats->tx_queue_dequeue_stats; size_t ave_size; uint64_t ave_time_us; dprintf(fd, "\nA2DP State:\n"); dprintf(fd, " TxQueue:\n"); dprintf(fd, " Counts (enqueue/dequeue/readbuf) : %zu / " "%zu / %zu\n", enqueue_stats->total_updates, dequeue_stats->total_updates, accumulated_stats->tx_queue_total_readbuf_calls); dprintf( fd, " Last update time ago in ms (enqueue/dequeue/readbuf) : %llu / %llu " "/ %llu\n", (enqueue_stats->last_update_us > 0) ? (unsigned long long)(now_us - enqueue_stats->last_update_us) / 1000 : 0, (dequeue_stats->last_update_us > 0) ? (unsigned long long)(now_us - dequeue_stats->last_update_us) / 1000 : 0, (accumulated_stats->tx_queue_last_readbuf_us > 0) ? (unsigned long long)(now_us - accumulated_stats->tx_queue_last_readbuf_us) / 1000 : 0); ave_size = 0; if (enqueue_stats->total_updates != 0) ave_size = accumulated_stats->tx_queue_total_frames / enqueue_stats->total_updates; dprintf(fd, " Frames per packet (total/max/ave) : %zu / " "%zu / %zu\n", accumulated_stats->tx_queue_total_frames, accumulated_stats->tx_queue_max_frames_per_packet, ave_size); dprintf(fd, " Counts (flushed/dropped/dropouts) : %zu / " "%zu / %zu\n", accumulated_stats->tx_queue_total_flushed_messages, accumulated_stats->tx_queue_total_dropped_messages, accumulated_stats->tx_queue_dropouts); dprintf(fd, " Counts (max dropped) : %zu\n", accumulated_stats->tx_queue_max_dropped_messages); dprintf( fd, " Last update time ago in ms (flushed/dropped) : %llu / " "%llu\n", (accumulated_stats->tx_queue_last_flushed_us > 0) ? (unsigned long long)(now_us - accumulated_stats->tx_queue_last_flushed_us) / 1000 : 0, (accumulated_stats->tx_queue_last_dropouts_us > 0) ? (unsigned long long)(now_us - accumulated_stats->tx_queue_last_dropouts_us) / 1000 : 0); dprintf(fd, " Counts (underflow) : %zu\n", accumulated_stats->media_read_total_underflow_count); dprintf(fd, " Bytes (underflow) : %zu\n", accumulated_stats->media_read_total_underflow_bytes); dprintf(fd, " Last update time ago in ms (underflow) : %llu\n", (accumulated_stats->media_read_last_underflow_us > 0) ? (unsigned long long)(now_us - accumulated_stats ->media_read_last_underflow_us) / 1000 : 0); // // TxQueue enqueue stats // dprintf( fd, " Enqueue deviation counts (overdue/premature) : %zu / %zu\n", enqueue_stats->overdue_scheduling_count, enqueue_stats->premature_scheduling_count); ave_time_us = 0; if (enqueue_stats->overdue_scheduling_count != 0) { ave_time_us = enqueue_stats->total_overdue_scheduling_delta_us / enqueue_stats->overdue_scheduling_count; } dprintf( fd, " Enqueue overdue scheduling time in ms (total/max/ave) : %llu / %llu " "/ %llu\n", (unsigned long long)enqueue_stats->total_overdue_scheduling_delta_us / 1000, (unsigned long long)enqueue_stats->max_overdue_scheduling_delta_us / 1000, (unsigned long long)ave_time_us / 1000); ave_time_us = 0; if (enqueue_stats->premature_scheduling_count != 0) { ave_time_us = enqueue_stats->total_premature_scheduling_delta_us / enqueue_stats->premature_scheduling_count; } dprintf( fd, " Enqueue premature scheduling time in ms (total/max/ave) : %llu / %llu " "/ %llu\n", (unsigned long long)enqueue_stats->total_premature_scheduling_delta_us / 1000, (unsigned long long)enqueue_stats->max_premature_scheduling_delta_us / 1000, (unsigned long long)ave_time_us / 1000); // // TxQueue dequeue stats // dprintf( fd, " Dequeue deviation counts (overdue/premature) : %zu / %zu\n", dequeue_stats->overdue_scheduling_count, dequeue_stats->premature_scheduling_count); ave_time_us = 0; if (dequeue_stats->overdue_scheduling_count != 0) { ave_time_us = dequeue_stats->total_overdue_scheduling_delta_us / dequeue_stats->overdue_scheduling_count; } dprintf( fd, " Dequeue overdue scheduling time in ms (total/max/ave) : %llu / %llu " "/ %llu\n", (unsigned long long)dequeue_stats->total_overdue_scheduling_delta_us / 1000, (unsigned long long)dequeue_stats->max_overdue_scheduling_delta_us / 1000, (unsigned long long)ave_time_us / 1000); ave_time_us = 0; if (dequeue_stats->premature_scheduling_count != 0) { ave_time_us = dequeue_stats->total_premature_scheduling_delta_us / dequeue_stats->premature_scheduling_count; } dprintf( fd, " Dequeue premature scheduling time in ms (total/max/ave) : %llu / %llu " "/ %llu\n", (unsigned long long)dequeue_stats->total_premature_scheduling_delta_us / 1000, (unsigned long long)dequeue_stats->max_premature_scheduling_delta_us / 1000, (unsigned long long)ave_time_us / 1000); } static void btif_a2dp_source_update_metrics(void) { BtifMediaStats stats = btif_a2dp_source_cb.stats; SchedulingStats enqueue_stats = stats.tx_queue_enqueue_stats; A2dpSessionMetrics metrics; metrics.codec_index = stats.codec_index; metrics.is_a2dp_offload = btif_av_is_a2dp_offload_enabled(); // session_start_us is 0 when btif_a2dp_source_start_audio_req() is not called // mark the metric duration as invalid (-1) in this case if (stats.session_start_us != 0) { int64_t session_end_us = stats.session_end_us == 0 ? bluetooth::common::time_get_os_boottime_us() : stats.session_end_us; if (static_cast(session_end_us) > stats.session_start_us) { metrics.audio_duration_ms = (session_end_us - stats.session_start_us) / 1000; } } if (enqueue_stats.total_updates > 1) { metrics.media_timer_min_ms = btif_a2dp_source_cb.encoder_interval_ms - (enqueue_stats.max_premature_scheduling_delta_us / 1000); metrics.media_timer_max_ms = btif_a2dp_source_cb.encoder_interval_ms + (enqueue_stats.max_overdue_scheduling_delta_us / 1000); metrics.total_scheduling_count = enqueue_stats.overdue_scheduling_count + enqueue_stats.premature_scheduling_count + enqueue_stats.exact_scheduling_count; if (metrics.total_scheduling_count > 0) { metrics.media_timer_avg_ms = enqueue_stats.total_scheduling_time_us / (1000 * metrics.total_scheduling_count); } metrics.buffer_overruns_max_count = stats.tx_queue_max_dropped_messages; metrics.buffer_overruns_total = stats.tx_queue_total_dropped_messages; metrics.buffer_underruns_count = stats.media_read_total_underflow_count; metrics.buffer_underruns_average = 0; if (metrics.buffer_underruns_count > 0) { metrics.buffer_underruns_average = stats.media_read_total_underflow_bytes / metrics.buffer_underruns_count; } } BluetoothMetricsLogger::GetInstance()->LogA2dpSession(metrics); } static void btm_read_rssi_cb(void* data) { if (data == nullptr) { LOG_ERROR(LOG_TAG, "%s: Read RSSI request timed out", __func__); return; } tBTM_RSSI_RESULT* result = (tBTM_RSSI_RESULT*)data; if (result->status != BTM_SUCCESS) { LOG_ERROR(LOG_TAG, "%s: unable to read remote RSSI (status %d)", __func__, result->status); return; } bluetooth::common::LogReadRssiResult( result->rem_bda, bluetooth::common::kUnknownConnectionHandle, result->hci_status, result->rssi); LOG_WARN(LOG_TAG, "%s: device: %s, rssi: %d", __func__, result->rem_bda.ToString().c_str(), result->rssi); } static void btm_read_failed_contact_counter_cb(void* data) { if (data == nullptr) { LOG_ERROR(LOG_TAG, "%s: Read Failed Contact Counter request timed out", __func__); return; } tBTM_FAILED_CONTACT_COUNTER_RESULT* result = (tBTM_FAILED_CONTACT_COUNTER_RESULT*)data; if (result->status != BTM_SUCCESS) { LOG_ERROR(LOG_TAG, "%s: unable to read Failed Contact Counter (status %d)", __func__, result->status); return; } bluetooth::common::LogReadFailedContactCounterResult( result->rem_bda, bluetooth::common::kUnknownConnectionHandle, result->hci_status, result->failed_contact_counter); LOG_WARN(LOG_TAG, "%s: device: %s, Failed Contact Counter: %u", __func__, result->rem_bda.ToString().c_str(), result->failed_contact_counter); } static void btm_read_automatic_flush_timeout_cb(void* data) { if (data == nullptr) { LOG_ERROR(LOG_TAG, "%s: Read Automatic Flush Timeout request timed out", __func__); return; } tBTM_AUTOMATIC_FLUSH_TIMEOUT_RESULT* result = (tBTM_AUTOMATIC_FLUSH_TIMEOUT_RESULT*)data; if (result->status != BTM_SUCCESS) { LOG_ERROR(LOG_TAG, "%s: unable to read Automatic Flush Timeout (status %d)", __func__, result->status); return; } LOG_WARN(LOG_TAG, "%s: device: %s, Automatic Flush Timeout: %u", __func__, result->rem_bda.ToString().c_str(), result->automatic_flush_timeout); } static void btm_read_tx_power_cb(void* data) { if (data == nullptr) { LOG_ERROR(LOG_TAG, "%s: Read Tx Power request timed out", __func__); return; } tBTM_TX_POWER_RESULT* result = (tBTM_TX_POWER_RESULT*)data; if (result->status != BTM_SUCCESS) { LOG_ERROR(LOG_TAG, "%s: unable to read Tx Power (status %d)", __func__, result->status); return; } bluetooth::common::LogReadTxPowerLevelResult( result->rem_bda, bluetooth::common::kUnknownConnectionHandle, result->hci_status, result->tx_power); LOG_WARN(LOG_TAG, "%s: device: %s, Tx Power: %d", __func__, result->rem_bda.ToString().c_str(), result->tx_power); }