/****************************************************************************** * * Copyright 2009-2016 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 "btif_av" #include "btif_av.h" #include #include #include #include #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 "bt_utils.h" #include "bta/include/bta_api.h" #include "btif/include/btif_a2dp_source.h" #include "btif_a2dp.h" #include "btif_a2dp_audio_interface.h" #include "btif_a2dp_control.h" #include "btif_a2dp_sink.h" #include "btif_av_co.h" #include "btif_profile_queue.h" #include "btif_rc.h" #include "btif_util.h" #include "btu.h" #include "common/state_machine.h" #include "osi/include/allocator.h" #include "osi/include/osi.h" #include "osi/include/properties.h" /***************************************************************************** * Constants & Macros *****************************************************************************/ static const std::string kBtifAvSourceServiceName = "Advanced Audio Source"; static const std::string kBtifAvSinkServiceName = "Advanced Audio Sink"; static constexpr int kDefaultMaxConnectedAudioDevices = 1; static constexpr tBTA_AV_HNDL kBtaHandleUnknown = 0; /***************************************************************************** * Local type definitions *****************************************************************************/ typedef struct { int sample_rate; int channel_count; RawAddress peer_address; } btif_av_sink_config_req_t; /** * BTIF AV events */ typedef enum { /* Reuse BTA_AV_XXX_EVT - No need to redefine them here */ BTIF_AV_CONNECT_REQ_EVT = BTA_AV_MAX_EVT, BTIF_AV_DISCONNECT_REQ_EVT, BTIF_AV_START_STREAM_REQ_EVT, BTIF_AV_STOP_STREAM_REQ_EVT, BTIF_AV_SUSPEND_STREAM_REQ_EVT, BTIF_AV_SINK_CONFIG_REQ_EVT, BTIF_AV_ACL_DISCONNECTED, BTIF_AV_OFFLOAD_START_REQ_EVT, BTIF_AV_AVRCP_OPEN_EVT, BTIF_AV_AVRCP_CLOSE_EVT, BTIF_AV_AVRCP_REMOTE_PLAY_EVT, } btif_av_sm_event_t; class BtifAvEvent { public: BtifAvEvent(uint32_t event, const void* p_data, size_t data_length); BtifAvEvent(const BtifAvEvent& other); BtifAvEvent() = delete; ~BtifAvEvent(); BtifAvEvent& operator=(const BtifAvEvent& other); uint32_t Event() const { return event_; } void* Data() const { return data_; } size_t DataLength() const { return data_length_; } std::string ToString() const; static std::string EventName(uint32_t event); private: void DeepCopy(uint32_t event, const void* p_data, size_t data_length); void DeepFree(); uint32_t event_; void* data_; size_t data_length_; }; class BtifAvPeer; // Should not need dedicated Suspend state as actual actions are no // different than Open state. Suspend flags are needed however to prevent // media task from trying to restart stream during remote Suspend or while // we are in the process of a local Suspend. class BtifAvStateMachine : public bluetooth::common::StateMachine { public: enum { kStateIdle, // AVDTP disconnected kStateOpening, // Opening AVDTP connection kStateOpened, // AVDTP is in OPEN state kStateStarted, // A2DP stream started kStateClosing, // Closing AVDTP connection }; class StateIdle : public State { public: StateIdle(BtifAvStateMachine& sm) : State(sm, kStateIdle), peer_(sm.Peer()) {} void OnEnter() override; void OnExit() override; bool ProcessEvent(uint32_t event, void* p_data) override; private: BtifAvPeer& peer_; }; class StateOpening : public State { public: StateOpening(BtifAvStateMachine& sm) : State(sm, kStateOpening), peer_(sm.Peer()) {} void OnEnter() override; void OnExit() override; bool ProcessEvent(uint32_t event, void* p_data) override; private: BtifAvPeer& peer_; }; class StateOpened : public State { public: StateOpened(BtifAvStateMachine& sm) : State(sm, kStateOpened), peer_(sm.Peer()) {} void OnEnter() override; void OnExit() override; bool ProcessEvent(uint32_t event, void* p_data) override; private: BtifAvPeer& peer_; }; class StateStarted : public State { public: StateStarted(BtifAvStateMachine& sm) : State(sm, kStateStarted), peer_(sm.Peer()) {} void OnEnter() override; void OnExit() override; bool ProcessEvent(uint32_t event, void* p_data) override; private: BtifAvPeer& peer_; }; class StateClosing : public State { public: StateClosing(BtifAvStateMachine& sm) : State(sm, kStateClosing), peer_(sm.Peer()) {} void OnEnter() override; void OnExit() override; bool ProcessEvent(uint32_t event, void* p_data) override; private: BtifAvPeer& peer_; }; BtifAvStateMachine(BtifAvPeer& btif_av_peer) : peer_(btif_av_peer) { state_idle_ = new StateIdle(*this); state_opening_ = new StateOpening(*this); state_opened_ = new StateOpened(*this); state_started_ = new StateStarted(*this); state_closing_ = new StateClosing(*this); AddState(state_idle_); AddState(state_opening_); AddState(state_opened_); AddState(state_started_); AddState(state_closing_); SetInitialState(state_idle_); } BtifAvPeer& Peer() { return peer_; } private: BtifAvPeer& peer_; StateIdle* state_idle_; StateOpening* state_opening_; StateOpened* state_opened_; StateStarted* state_started_; StateClosing* state_closing_; }; class BtifAvPeer { public: enum { kFlagLocalSuspendPending = 0x1, kFlagRemoteSuspend = 0x2, kFlagPendingStart = 0x4, kFlagPendingStop = 0x8, }; static constexpr uint64_t kTimeoutAvOpenOnRcMs = 2 * 1000; // 2s BtifAvPeer(const RawAddress& peer_address, uint8_t peer_sep, tBTA_AV_HNDL bta_handle, uint8_t peer_id); ~BtifAvPeer(); bt_status_t Init(); void Cleanup(); /** * Check whether the peer can be deleted. * * @return true if the pair can be deleted, otherwise false */ bool CanBeDeleted() const; /** * Check whether the peer is the active one. * * @return true if this peer is the active one */ bool IsActivePeer() const { return (PeerAddress() == ActivePeerAddress()); } /** * Get the address of the active peer. * * @return the address of the active peer */ const RawAddress& ActivePeerAddress() const; const RawAddress& PeerAddress() const { return peer_address_; } bool IsSource() const { return (peer_sep_ == AVDT_TSEP_SRC); } bool IsSink() const { return (peer_sep_ == AVDT_TSEP_SNK); } uint8_t PeerSep() const { return peer_sep_; } /** * Get the local device's Service Class UUID * * @return the local device's Service Class UUID: UUID_SERVCLASS_AUDIO_SOURCE * or UUID_SERVCLASS_AUDIO_SINK */ uint16_t LocalUuidServiceClass() const { return (IsSink() ? UUID_SERVCLASS_AUDIO_SOURCE : UUID_SERVCLASS_AUDIO_SINK); } tBTA_AV_HNDL BtaHandle() const { return bta_handle_; } void SetBtaHandle(tBTA_AV_HNDL bta_handle) { bta_handle_ = bta_handle; } uint8_t PeerId() const { return peer_id_; } BtifAvStateMachine& StateMachine() { return state_machine_; } const BtifAvStateMachine& StateMachine() const { return state_machine_; } alarm_t* AvOpenOnRcTimer() { return av_open_on_rc_timer_; } const alarm_t* AvOpenOnRcTimer() const { return av_open_on_rc_timer_; } void SetEdr(tBTA_AV_EDR edr) { edr_ = edr; } bool IsEdr() const { return (edr_ != 0); } bool Is3Mbps() const { return ((edr_ & BTA_AV_EDR_3MBPS) != 0); } bool IsConnected() const; bool IsStreaming() const; bool IsInSilenceMode() const { return is_silenced_; }; void SetSilence(bool silence) { is_silenced_ = silence; }; /** * Check whether any of the flags specified by the bitlags mask is set. * * @param bitflags_mask the bitflags to check * @return true if any of the flags to check is set, otherwise false. */ bool CheckFlags(uint8_t bitflags_mask) const { return ((flags_ & bitflags_mask) != 0); } /** * Set only the flags as specified by the bitflags mask. * * @param bitflags_mask the bitflags to set */ void SetFlags(uint8_t bitflags_mask) { flags_ |= bitflags_mask; } /** * Clear only the flags as specified by the bitflags mask. * * @param bitflags_mask the bitflags to clear */ void ClearFlags(uint8_t bitflags_mask) { flags_ &= ~bitflags_mask; } /** * Clear all flags. */ void ClearAllFlags() { flags_ = 0; } /** * Get a string representation of the flags that are set. */ std::string FlagsToString() const; bool SelfInitiatedConnection() const { return self_initiated_connection_; } void SetSelfInitiatedConnection(bool v) { self_initiated_connection_ = v; } private: const RawAddress peer_address_; const uint8_t peer_sep_; // SEP type of peer device tBTA_AV_HNDL bta_handle_; const uint8_t peer_id_; BtifAvStateMachine state_machine_; alarm_t* av_open_on_rc_timer_; tBTA_AV_EDR edr_; uint8_t flags_; bool self_initiated_connection_; bool is_silenced_; }; class BtifAvSource { public: // The PeerId is used as AppId for BTA_AvRegister() purpose static constexpr uint8_t kPeerIdMin = 0; static constexpr uint8_t kPeerIdMax = BTA_AV_NUM_STRS; BtifAvSource() : callbacks_(nullptr), enabled_(false), a2dp_offload_enabled_(false), max_connected_peers_(kDefaultMaxConnectedAudioDevices) {} ~BtifAvSource(); bt_status_t Init( btav_source_callbacks_t* callbacks, int max_connected_audio_devices, const std::vector& codec_priorities); void Cleanup(); btav_source_callbacks_t* Callbacks() { return callbacks_; } bool Enabled() const { return enabled_; } bool A2dpOffloadEnabled() const { return a2dp_offload_enabled_; } BtifAvPeer* FindPeer(const RawAddress& peer_address); BtifAvPeer* FindPeerByHandle(tBTA_AV_HNDL bta_handle); BtifAvPeer* FindPeerByPeerId(uint8_t peer_id); BtifAvPeer* FindOrCreatePeer(const RawAddress& peer_address, tBTA_AV_HNDL bta_handle); /** * Check whether a connection to a peer is allowed. * The check considers the maximum number of connected peers. * * @param peer_address the peer address to connect to * @return true if connection is allowed, otherwise false */ bool AllowedToConnect(const RawAddress& peer_address) const; /** * Delete a peer. * * @param peer_address the peer to delete * @return true on success, otherwise false */ bool DeletePeer(const RawAddress& peer_address); /** * Delete all peers that have transitioned to Idle state and can be deleted. * If a peer was just created/initialized, then it cannot be deleted yet. */ void DeleteIdlePeers(); /** * Get the active peer. * * @return the active peer */ const RawAddress& ActivePeer() const { return active_peer_; } /** * Check whether peer is silenced * * @param peer_address the peer to check * @return true on silence mode enabled, otherwise false */ bool IsPeerSilenced(const RawAddress& peer_address) { if (peer_address.IsEmpty()) { return false; } BtifAvPeer* peer = FindPeer(peer_address); if (peer == nullptr) { BTIF_TRACE_WARNING("%s: peer is null", __func__); return false; } if (!peer->IsConnected()) { BTIF_TRACE_WARNING("%s: peer is not connected", __func__); return false; } return peer->IsInSilenceMode(); } /** * Set peer silence mode * * @param peer_address the peer to set * @param silence true on enable silence mode, false on disable * @return true on success, otherwise false */ bool SetSilencePeer(const RawAddress& peer_address, const bool silence) { if (peer_address.IsEmpty()) { return false; } LOG_INFO(LOG_TAG, "%s: peer: %s", __PRETTY_FUNCTION__, peer_address.ToString().c_str()); BtifAvPeer* peer = FindPeer(peer_address); if (peer == nullptr) { BTIF_TRACE_WARNING("%s: peer is null", __func__); return false; } if (!peer->IsConnected()) { BTIF_TRACE_WARNING("%s: peer is not connected", __func__); return false; } peer->SetSilence(silence); return true; } /** * Set the active peer. * * @param peer_address the active peer address or RawAddress::kEmpty to * reset the active peer * @return true on success, otherwise false */ bool SetActivePeer(const RawAddress& peer_address, std::promise peer_ready_promise) { LOG(INFO) << __PRETTY_FUNCTION__ << ": peer: " << peer_address; if (active_peer_ == peer_address) { peer_ready_promise.set_value(); return true; // Nothing has changed } if (peer_address.IsEmpty()) { BTIF_TRACE_EVENT("%s: peer address is empty, shutdown the Audio source", __func__); if (!bta_av_co_set_active_peer(peer_address)) { LOG(WARNING) << __func__ << ": unable to set active peer to empty in BtaAvCo"; } btif_a2dp_source_end_session(active_peer_); btif_a2dp_source_shutdown(); active_peer_ = peer_address; peer_ready_promise.set_value(); return true; } BtifAvPeer* peer = FindPeer(peer_address); if (peer != nullptr && !peer->IsConnected()) { LOG(ERROR) << __func__ << ": Error setting " << peer->PeerAddress() << " as active Source peer"; peer_ready_promise.set_value(); return false; } if (!btif_a2dp_source_restart_session(active_peer_, peer_address, std::move(peer_ready_promise))) { // cannot set promise but need to be handled within restart_session return false; } active_peer_ = peer_address; return true; } /** * Update source codec configuration for a peer. * * @param peer_address the address of the peer to update * @param codec_preferences the updated codec preferences */ void UpdateCodecConfig( const RawAddress& peer_address, const std::vector& codec_preferences, std::promise peer_ready_promise) { // Restart the session if the codec for the active peer is updated bool restart_session = ((active_peer_ == peer_address) && !active_peer_.IsEmpty()); if (restart_session) { btif_a2dp_source_end_session(active_peer_); } for (auto cp : codec_preferences) { BTIF_TRACE_DEBUG("%s: codec_preference=%s", __func__, cp.ToString().c_str()); btif_a2dp_source_encoder_user_config_update_req(peer_address, cp); } if (restart_session) { btif_a2dp_source_start_session(active_peer_, std::move(peer_ready_promise)); } else { peer_ready_promise.set_value(); } } const std::map& Peers() const { return peers_; } void RegisterAllBtaHandles(); void DeregisterAllBtaHandles(); void BtaHandleRegistered(uint8_t peer_id, tBTA_AV_HNDL bta_handle); private: void CleanupAllPeers(); btav_source_callbacks_t* callbacks_; bool enabled_; bool a2dp_offload_enabled_; int max_connected_peers_; std::map peers_; std::set silenced_peers_; RawAddress active_peer_; std::map peer_id2bta_handle_; }; class BtifAvSink { public: // The PeerId is used as AppId for BTA_AvRegister() purpose static constexpr uint8_t kPeerIdMin = 0; static constexpr uint8_t kPeerIdMax = BTA_AV_NUM_STRS; BtifAvSink() : callbacks_(nullptr), enabled_(false), max_connected_peers_(kDefaultMaxConnectedAudioDevices) {} ~BtifAvSink(); bt_status_t Init(btav_sink_callbacks_t* callbacks); void Cleanup(); btav_sink_callbacks_t* Callbacks() { return callbacks_; } bool Enabled() const { return enabled_; } BtifAvPeer* FindPeer(const RawAddress& peer_address); BtifAvPeer* FindPeerByHandle(tBTA_AV_HNDL bta_handle); BtifAvPeer* FindPeerByPeerId(uint8_t peer_id); BtifAvPeer* FindOrCreatePeer(const RawAddress& peer_address, tBTA_AV_HNDL bta_handle); /** * Check whether a connection to a peer is allowed. * The check considers the maximum number of connected peers. * * @param peer_address the peer address to connect to * @return true if connection is allowed, otherwise false */ bool AllowedToConnect(const RawAddress& peer_address) const; /** * Delete a peer. * * @param peer_address the peer to delete * @return true on success, otherwise false */ bool DeletePeer(const RawAddress& peer_address); /** * Delete all peers that have transitioned to Idle state and can be deleted. * If a peer was just created/initialized, then it cannot be deleted yet. */ void DeleteIdlePeers(); /** * Get the active peer. * * @return the active peer */ const RawAddress& ActivePeer() const { return active_peer_; } /** * Set the active peer. * * @param peer_address the active peer address or RawAddress::kEmpty to * reset the active peer * @return true on success, otherwise false */ bool SetActivePeer(const RawAddress& peer_address, std::promise peer_ready_promise) { LOG(INFO) << __PRETTY_FUNCTION__ << ": peer: " << peer_address; if (active_peer_ == peer_address) { peer_ready_promise.set_value(); return true; // Nothing has changed } if (peer_address.IsEmpty()) { BTIF_TRACE_EVENT("%s: peer address is empty, shutdown the Audio sink", __func__); if (!bta_av_co_set_active_peer(peer_address)) { LOG(WARNING) << __func__ << ": unable to set active peer to empty in BtaAvCo"; } btif_a2dp_sink_end_session(active_peer_); btif_a2dp_sink_shutdown(); active_peer_ = peer_address; peer_ready_promise.set_value(); return true; } BtifAvPeer* peer = FindPeer(peer_address); if (peer != nullptr && !peer->IsConnected()) { LOG(ERROR) << __func__ << ": Error setting " << peer->PeerAddress() << " as active Sink peer"; peer_ready_promise.set_value(); return false; } if (!btif_a2dp_sink_restart_session(active_peer_, peer_address, std::move(peer_ready_promise))) { // cannot set promise but need to be handled within restart_session return false; } active_peer_ = peer_address; return true; } const std::map& Peers() const { return peers_; } void RegisterAllBtaHandles(); void DeregisterAllBtaHandles(); void BtaHandleRegistered(uint8_t peer_id, tBTA_AV_HNDL bta_handle); private: void CleanupAllPeers(); btav_sink_callbacks_t* callbacks_; bool enabled_; int max_connected_peers_; std::map peers_; RawAddress active_peer_; std::map peer_id2bta_handle_; }; /***************************************************************************** * Static variables *****************************************************************************/ static BtifAvSource btif_av_source; static BtifAvSink btif_av_sink; /* Helper macro to avoid code duplication in the state machine handlers */ #define CHECK_RC_EVENT(e, d) \ case BTA_AV_RC_OPEN_EVT: \ case BTA_AV_RC_BROWSE_OPEN_EVT: \ case BTA_AV_RC_CLOSE_EVT: \ case BTA_AV_RC_BROWSE_CLOSE_EVT: \ case BTA_AV_REMOTE_CMD_EVT: \ case BTA_AV_VENDOR_CMD_EVT: \ case BTA_AV_META_MSG_EVT: \ case BTA_AV_RC_FEAT_EVT: \ case BTA_AV_REMOTE_RSP_EVT: { \ btif_rc_handler(e, d); \ } break; static bt_status_t src_disconnect_sink(const RawAddress& peer_address); static bt_status_t sink_disconnect_src(const RawAddress& peer_address); static void btif_av_source_dispatch_sm_event(const RawAddress& peer_address, btif_av_sm_event_t event); static void btif_av_sink_dispatch_sm_event(const RawAddress& peer_address, btif_av_sm_event_t event); static void btif_av_handle_event(uint8_t peer_sep, const RawAddress& peer_address, tBTA_AV_HNDL bta_handle, const BtifAvEvent& btif_av_event); static void btif_report_connection_state(const RawAddress& peer_address, btav_connection_state_t state); static void btif_report_audio_state(const RawAddress& peer_address, btav_audio_state_t state); static void btif_av_report_sink_audio_config_state( const RawAddress& peer_address, int sample_rate, int channel_count); static void btif_av_source_initiate_av_open_timer_timeout(void* data); static void btif_av_sink_initiate_av_open_timer_timeout(void* data); static void bta_av_sink_media_callback(tBTA_AV_EVT event, tBTA_AV_MEDIA* p_data); static BtifAvPeer* btif_av_source_find_peer(const RawAddress& peer_address) { return btif_av_source.FindPeer(peer_address); } static BtifAvPeer* btif_av_sink_find_peer(const RawAddress& peer_address) { return btif_av_sink.FindPeer(peer_address); } static BtifAvPeer* btif_av_find_peer(const RawAddress& peer_address) { if (btif_av_source.Enabled()) return btif_av_source_find_peer(peer_address); if (btif_av_sink.Enabled()) return btif_av_sink_find_peer(peer_address); return nullptr; } static BtifAvPeer* btif_av_find_active_peer() { if (btif_av_source.Enabled()) return btif_av_source_find_peer(btif_av_source.ActivePeer()); if (btif_av_sink.Enabled()) return btif_av_sink_find_peer(btif_av_sink.ActivePeer()); return nullptr; } /***************************************************************************** * Local helper functions *****************************************************************************/ const char* dump_av_sm_event_name(btif_av_sm_event_t event) { switch ((int)event) { CASE_RETURN_STR(BTA_AV_ENABLE_EVT) CASE_RETURN_STR(BTA_AV_REGISTER_EVT) CASE_RETURN_STR(BTA_AV_OPEN_EVT) CASE_RETURN_STR(BTA_AV_CLOSE_EVT) CASE_RETURN_STR(BTA_AV_START_EVT) CASE_RETURN_STR(BTA_AV_STOP_EVT) CASE_RETURN_STR(BTA_AV_PROTECT_REQ_EVT) CASE_RETURN_STR(BTA_AV_PROTECT_RSP_EVT) CASE_RETURN_STR(BTA_AV_RC_OPEN_EVT) CASE_RETURN_STR(BTA_AV_RC_CLOSE_EVT) CASE_RETURN_STR(BTA_AV_RC_BROWSE_OPEN_EVT) CASE_RETURN_STR(BTA_AV_RC_BROWSE_CLOSE_EVT) CASE_RETURN_STR(BTA_AV_REMOTE_CMD_EVT) CASE_RETURN_STR(BTA_AV_REMOTE_RSP_EVT) CASE_RETURN_STR(BTA_AV_VENDOR_CMD_EVT) CASE_RETURN_STR(BTA_AV_VENDOR_RSP_EVT) CASE_RETURN_STR(BTA_AV_RECONFIG_EVT) CASE_RETURN_STR(BTA_AV_SUSPEND_EVT) CASE_RETURN_STR(BTA_AV_PENDING_EVT) CASE_RETURN_STR(BTA_AV_META_MSG_EVT) CASE_RETURN_STR(BTA_AV_REJECT_EVT) CASE_RETURN_STR(BTA_AV_RC_FEAT_EVT) CASE_RETURN_STR(BTA_AV_OFFLOAD_START_RSP_EVT) CASE_RETURN_STR(BTIF_AV_CONNECT_REQ_EVT) CASE_RETURN_STR(BTIF_AV_DISCONNECT_REQ_EVT) CASE_RETURN_STR(BTIF_AV_START_STREAM_REQ_EVT) CASE_RETURN_STR(BTIF_AV_STOP_STREAM_REQ_EVT) CASE_RETURN_STR(BTIF_AV_SUSPEND_STREAM_REQ_EVT) CASE_RETURN_STR(BTIF_AV_SINK_CONFIG_REQ_EVT) CASE_RETURN_STR(BTIF_AV_ACL_DISCONNECTED) CASE_RETURN_STR(BTIF_AV_OFFLOAD_START_REQ_EVT) CASE_RETURN_STR(BTIF_AV_AVRCP_OPEN_EVT) CASE_RETURN_STR(BTIF_AV_AVRCP_CLOSE_EVT) CASE_RETURN_STR(BTIF_AV_AVRCP_REMOTE_PLAY_EVT) default: return "UNKNOWN_EVENT"; } } BtifAvEvent::BtifAvEvent(uint32_t event, const void* p_data, size_t data_length) : event_(event), data_(nullptr), data_length_(0) { DeepCopy(event, p_data, data_length); } BtifAvEvent::BtifAvEvent(const BtifAvEvent& other) : event_(0), data_(nullptr), data_length_(0) { *this = other; } BtifAvEvent& BtifAvEvent::operator=(const BtifAvEvent& other) { DeepFree(); DeepCopy(other.Event(), other.Data(), other.DataLength()); return *this; } BtifAvEvent::~BtifAvEvent() { DeepFree(); } std::string BtifAvEvent::ToString() const { return BtifAvEvent::EventName(event_); } std::string BtifAvEvent::EventName(uint32_t event) { std::string name = dump_av_sm_event_name((btif_av_sm_event_t)event); std::stringstream ss_value; ss_value << "(0x" << std::hex << event << ")"; return name + ss_value.str(); } void BtifAvEvent::DeepCopy(uint32_t event, const void* p_data, size_t data_length) { event_ = event; data_length_ = data_length; if (data_length == 0) { data_ = nullptr; } else { data_ = osi_malloc(data_length_); memcpy(data_, p_data, data_length); } switch (event) { case BTA_AV_META_MSG_EVT: { CHECK(data_length >= sizeof(tBTA_AV)); const tBTA_AV* av_src = (const tBTA_AV*)p_data; tBTA_AV* av_dest = (tBTA_AV*)data_; if (av_src->meta_msg.p_data && av_src->meta_msg.len) { av_dest->meta_msg.p_data = (uint8_t*)osi_calloc(av_src->meta_msg.len); memcpy(av_dest->meta_msg.p_data, av_src->meta_msg.p_data, av_src->meta_msg.len); } if (av_src->meta_msg.p_msg) { av_dest->meta_msg.p_msg = (tAVRC_MSG*)osi_calloc(sizeof(tAVRC_MSG)); memcpy(av_dest->meta_msg.p_msg, av_src->meta_msg.p_msg, sizeof(tAVRC_MSG)); tAVRC_MSG* p_msg_src = av_src->meta_msg.p_msg; tAVRC_MSG* p_msg_dest = av_dest->meta_msg.p_msg; if ((p_msg_src->hdr.opcode == AVRC_OP_VENDOR) && (p_msg_src->vendor.p_vendor_data && p_msg_src->vendor.vendor_len)) { p_msg_dest->vendor.p_vendor_data = (uint8_t*)osi_calloc(p_msg_src->vendor.vendor_len); memcpy(p_msg_dest->vendor.p_vendor_data, p_msg_src->vendor.p_vendor_data, p_msg_src->vendor.vendor_len); } if ((p_msg_src->hdr.opcode == AVRC_OP_BROWSE) && p_msg_src->browse.p_browse_data && p_msg_src->browse.browse_len) { p_msg_dest->browse.p_browse_data = (uint8_t*)osi_calloc(p_msg_src->browse.browse_len); memcpy(p_msg_dest->browse.p_browse_data, p_msg_src->browse.p_browse_data, p_msg_src->browse.browse_len); } } } break; default: break; } } void BtifAvEvent::DeepFree() { switch (event_) { case BTA_AV_META_MSG_EVT: { tBTA_AV* av = (tBTA_AV*)data_; osi_free_and_reset((void**)&av->meta_msg.p_data); if (av->meta_msg.p_msg) { if (av->meta_msg.p_msg->hdr.opcode == AVRC_OP_VENDOR) { osi_free(av->meta_msg.p_msg->vendor.p_vendor_data); } if (av->meta_msg.p_msg->hdr.opcode == AVRC_OP_BROWSE) { osi_free(av->meta_msg.p_msg->browse.p_browse_data); } osi_free_and_reset((void**)&av->meta_msg.p_msg); } } break; default: break; } osi_free_and_reset((void**)&data_); data_length_ = 0; } BtifAvPeer::BtifAvPeer(const RawAddress& peer_address, uint8_t peer_sep, tBTA_AV_HNDL bta_handle, uint8_t peer_id) : peer_address_(peer_address), peer_sep_(peer_sep), bta_handle_(bta_handle), peer_id_(peer_id), state_machine_(*this), av_open_on_rc_timer_(nullptr), edr_(0), flags_(0), self_initiated_connection_(false) {} BtifAvPeer::~BtifAvPeer() { alarm_free(av_open_on_rc_timer_); } std::string BtifAvPeer::FlagsToString() const { std::string result; if (flags_ & BtifAvPeer::kFlagLocalSuspendPending) { if (!result.empty()) result += "|"; result += "LOCAL_SUSPEND_PENDING"; } if (flags_ & BtifAvPeer::kFlagRemoteSuspend) { if (!result.empty()) result += "|"; result += "REMOTE_SUSPEND"; } if (flags_ & BtifAvPeer::kFlagPendingStart) { if (!result.empty()) result += "|"; result += "PENDING_START"; } if (flags_ & BtifAvPeer::kFlagPendingStop) { if (!result.empty()) result += "|"; result += "PENDING_STOP"; } if (result.empty()) result = "None"; return base::StringPrintf("0x%x(%s)", flags_, result.c_str()); } bt_status_t BtifAvPeer::Init() { alarm_free(av_open_on_rc_timer_); av_open_on_rc_timer_ = alarm_new("btif_av_peer.av_open_on_rc_timer"); is_silenced_ = false; state_machine_.Start(); return BT_STATUS_SUCCESS; } void BtifAvPeer::Cleanup() { state_machine_.Quit(); alarm_free(av_open_on_rc_timer_); av_open_on_rc_timer_ = nullptr; } bool BtifAvPeer::CanBeDeleted() const { return ( (state_machine_.StateId() == BtifAvStateMachine::kStateIdle) && (state_machine_.PreviousStateId() != BtifAvStateMachine::kStateInvalid)); } const RawAddress& BtifAvPeer::ActivePeerAddress() const { if (IsSource()) { return btif_av_sink.ActivePeer(); } if (IsSink()) { return btif_av_source.ActivePeer(); } LOG(FATAL) << __PRETTY_FUNCTION__ << ": A2DP peer " << PeerAddress() << " is neither Source nor Sink"; return RawAddress::kEmpty; } bool BtifAvPeer::IsConnected() const { int state = state_machine_.StateId(); return ((state == BtifAvStateMachine::kStateOpened) || (state == BtifAvStateMachine::kStateStarted)); } bool BtifAvPeer::IsStreaming() const { int state = state_machine_.StateId(); return (state == BtifAvStateMachine::kStateStarted); } BtifAvSource::~BtifAvSource() { CleanupAllPeers(); } bt_status_t BtifAvSource::Init( btav_source_callbacks_t* callbacks, int max_connected_audio_devices, const std::vector& codec_priorities) { LOG_INFO(LOG_TAG, "%s: max_connected_audio_devices=%d", __PRETTY_FUNCTION__, max_connected_audio_devices); if (enabled_) return BT_STATUS_SUCCESS; CleanupAllPeers(); max_connected_peers_ = max_connected_audio_devices; /* A2DP OFFLOAD */ char value_sup[PROPERTY_VALUE_MAX] = {'\0'}; char value_dis[PROPERTY_VALUE_MAX] = {'\0'}; osi_property_get("ro.bluetooth.a2dp_offload.supported", value_sup, "false"); osi_property_get("persist.bluetooth.a2dp_offload.disabled", value_dis, "false"); a2dp_offload_enabled_ = (strcmp(value_sup, "true") == 0) && (strcmp(value_dis, "false") == 0); BTIF_TRACE_DEBUG("a2dp_offload.enable = %d", a2dp_offload_enabled_); callbacks_ = callbacks; bta_av_co_init(codec_priorities); if (!btif_a2dp_source_init()) { return BT_STATUS_FAIL; } btif_enable_service(BTA_A2DP_SOURCE_SERVICE_ID); enabled_ = true; return BT_STATUS_SUCCESS; } void BtifAvSource::Cleanup() { LOG_INFO(LOG_TAG, "%s", __PRETTY_FUNCTION__); if (!enabled_) return; btif_queue_cleanup(UUID_SERVCLASS_AUDIO_SOURCE); std::promise peer_ready_promise; do_in_main_thread( FROM_HERE, base::BindOnce(base::IgnoreResult(&BtifAvSource::SetActivePeer), base::Unretained(&btif_av_source), RawAddress::kEmpty, std::move(peer_ready_promise))); do_in_main_thread(FROM_HERE, base::Bind(&btif_a2dp_source_cleanup)); btif_disable_service(BTA_A2DP_SOURCE_SERVICE_ID); CleanupAllPeers(); callbacks_ = nullptr; enabled_ = false; } BtifAvPeer* BtifAvSource::FindPeer(const RawAddress& peer_address) { auto it = peers_.find(peer_address); if (it != peers_.end()) return it->second; return nullptr; } BtifAvPeer* BtifAvSource::FindPeerByHandle(tBTA_AV_HNDL bta_handle) { for (auto it : peers_) { BtifAvPeer* peer = it.second; if (peer->BtaHandle() == bta_handle) { return peer; } } return nullptr; } BtifAvPeer* BtifAvSource::FindPeerByPeerId(uint8_t peer_id) { for (auto it : peers_) { BtifAvPeer* peer = it.second; if (peer->PeerId() == peer_id) { return peer; } } return nullptr; } BtifAvPeer* BtifAvSource::FindOrCreatePeer(const RawAddress& peer_address, tBTA_AV_HNDL bta_handle) { BTIF_TRACE_DEBUG("%s: peer_address=%s bta_handle=0x%x", __PRETTY_FUNCTION__, peer_address.ToString().c_str(), bta_handle); BtifAvPeer* peer = FindPeer(peer_address); if (peer != nullptr) return peer; // Find next availabie Peer ID to use uint8_t peer_id; for (peer_id = kPeerIdMin; peer_id < kPeerIdMax; peer_id++) { if (FindPeerByPeerId(peer_id) == nullptr) break; } if (peer_id == kPeerIdMax) { BTIF_TRACE_ERROR( "%s: Cannot create peer for peer_address=%s : " "cannot allocate unique Peer ID", __PRETTY_FUNCTION__, peer_address.ToString().c_str()); return nullptr; } // Get the BTA Handle (if known) if (bta_handle == kBtaHandleUnknown) { auto it = peer_id2bta_handle_.find(peer_id); if (it != peer_id2bta_handle_.end()) { bta_handle = it->second; } } LOG_INFO(LOG_TAG, "%s: Create peer: peer_address=%s bta_handle=0x%x peer_id=%d", __PRETTY_FUNCTION__, peer_address.ToString().c_str(), bta_handle, peer_id); peer = new BtifAvPeer(peer_address, AVDT_TSEP_SNK, bta_handle, peer_id); peers_.insert(std::make_pair(peer_address, peer)); peer->Init(); return peer; } bool BtifAvSource::AllowedToConnect(const RawAddress& peer_address) const { int connected = 0; // Count peers that are in the process of connecting or already connected for (auto it : peers_) { const BtifAvPeer* peer = it.second; switch (peer->StateMachine().StateId()) { case BtifAvStateMachine::kStateOpening: case BtifAvStateMachine::kStateOpened: case BtifAvStateMachine::kStateStarted: if (peer->PeerAddress() == peer_address) { return true; // Already connected or accounted for } connected++; break; default: break; } } return (connected < max_connected_peers_); } bool BtifAvSource::DeletePeer(const RawAddress& peer_address) { auto it = peers_.find(peer_address); if (it == peers_.end()) return false; BtifAvPeer* peer = it->second; peer->Cleanup(); peers_.erase(it); delete peer; return true; } void BtifAvSource::DeleteIdlePeers() { for (auto it = peers_.begin(); it != peers_.end();) { BtifAvPeer* peer = it->second; auto prev_it = it++; if (!peer->CanBeDeleted()) continue; LOG_INFO(LOG_TAG, "%s: Deleting idle peer: %s bta_handle=0x%x", __func__, peer->PeerAddress().ToString().c_str(), peer->BtaHandle()); peer->Cleanup(); peers_.erase(prev_it); delete peer; } } void BtifAvSource::CleanupAllPeers() { while (!peers_.empty()) { auto it = peers_.begin(); BtifAvPeer* peer = it->second; peer->Cleanup(); peers_.erase(it); delete peer; } } void BtifAvSource::RegisterAllBtaHandles() { for (int peer_id = kPeerIdMin; peer_id < kPeerIdMax; peer_id++) { BTA_AvRegister(BTA_AV_CHNL_AUDIO, kBtifAvSourceServiceName.c_str(), peer_id, nullptr, UUID_SERVCLASS_AUDIO_SOURCE); } } void BtifAvSource::DeregisterAllBtaHandles() { for (auto it : peer_id2bta_handle_) { tBTA_AV_HNDL bta_handle = it.second; BTA_AvDeregister(bta_handle); } peer_id2bta_handle_.clear(); } void BtifAvSource::BtaHandleRegistered(uint8_t peer_id, tBTA_AV_HNDL bta_handle) { peer_id2bta_handle_.insert(std::make_pair(peer_id, bta_handle)); // Set the BTA Handle for the Peer (if exists) BtifAvPeer* peer = FindPeerByPeerId(peer_id); if (peer != nullptr) { peer->SetBtaHandle(bta_handle); } } BtifAvSink::~BtifAvSink() { CleanupAllPeers(); } bt_status_t BtifAvSink::Init(btav_sink_callbacks_t* callbacks) { LOG_INFO(LOG_TAG, "%s", __PRETTY_FUNCTION__); if (enabled_) return BT_STATUS_SUCCESS; CleanupAllPeers(); max_connected_peers_ = kDefaultMaxConnectedAudioDevices; callbacks_ = callbacks; std::vector codec_priorities; // Default priorities bta_av_co_init(codec_priorities); if (!btif_a2dp_sink_init()) { return BT_STATUS_FAIL; } btif_enable_service(BTA_A2DP_SINK_SERVICE_ID); enabled_ = true; return BT_STATUS_SUCCESS; } void BtifAvSink::Cleanup() { LOG_INFO(LOG_TAG, "%s", __PRETTY_FUNCTION__); if (!enabled_) return; btif_queue_cleanup(UUID_SERVCLASS_AUDIO_SINK); std::promise peer_ready_promise; do_in_main_thread( FROM_HERE, base::BindOnce(base::IgnoreResult(&BtifAvSink::SetActivePeer), base::Unretained(&btif_av_sink), RawAddress::kEmpty, std::move(peer_ready_promise))); do_in_main_thread(FROM_HERE, base::Bind(&btif_a2dp_sink_cleanup)); btif_disable_service(BTA_A2DP_SINK_SERVICE_ID); CleanupAllPeers(); callbacks_ = nullptr; enabled_ = false; } BtifAvPeer* BtifAvSink::FindPeer(const RawAddress& peer_address) { auto it = peers_.find(peer_address); if (it != peers_.end()) return it->second; return nullptr; } BtifAvPeer* BtifAvSink::FindPeerByHandle(tBTA_AV_HNDL bta_handle) { for (auto it : peers_) { BtifAvPeer* peer = it.second; if (peer->BtaHandle() == bta_handle) { return peer; } } return nullptr; } BtifAvPeer* BtifAvSink::FindPeerByPeerId(uint8_t peer_id) { for (auto it : peers_) { BtifAvPeer* peer = it.second; if (peer->PeerId() == peer_id) { return peer; } } return nullptr; } BtifAvPeer* BtifAvSink::FindOrCreatePeer(const RawAddress& peer_address, tBTA_AV_HNDL bta_handle) { BTIF_TRACE_DEBUG("%s: peer_address=%s bta_handle=0x%x", __PRETTY_FUNCTION__, peer_address.ToString().c_str(), bta_handle); BtifAvPeer* peer = FindPeer(peer_address); if (peer != nullptr) return peer; // Find next availabie Peer ID to use uint8_t peer_id; for (peer_id = kPeerIdMin; peer_id < kPeerIdMax; peer_id++) { if (FindPeerByPeerId(peer_id) == nullptr) break; } if (peer_id == kPeerIdMax) { BTIF_TRACE_ERROR( "%s: Cannot create peer for peer_address=%s : " "cannot allocate unique Peer ID", __PRETTY_FUNCTION__, peer_address.ToString().c_str()); return nullptr; } // Get the BTA Handle (if known) if (bta_handle == kBtaHandleUnknown) { auto it = peer_id2bta_handle_.find(peer_id); if (it != peer_id2bta_handle_.end()) { bta_handle = it->second; } } LOG_INFO(LOG_TAG, "%s: Create peer: peer_address=%s bta_handle=0x%x peer_id=%d", __PRETTY_FUNCTION__, peer_address.ToString().c_str(), bta_handle, peer_id); peer = new BtifAvPeer(peer_address, AVDT_TSEP_SRC, bta_handle, peer_id); peers_.insert(std::make_pair(peer_address, peer)); peer->Init(); if (active_peer_.IsEmpty()) { active_peer_ = peer_address; } return peer; } bool BtifAvSink::AllowedToConnect(const RawAddress& peer_address) const { int connected = 0; // Count peers that are in the process of connecting or already connected for (auto it : peers_) { const BtifAvPeer* peer = it.second; switch (peer->StateMachine().StateId()) { case BtifAvStateMachine::kStateOpening: case BtifAvStateMachine::kStateOpened: case BtifAvStateMachine::kStateStarted: if (peer->PeerAddress() == peer_address) { return true; // Already connected or accounted for } connected++; break; default: break; } } return (connected < max_connected_peers_); } bool BtifAvSink::DeletePeer(const RawAddress& peer_address) { auto it = peers_.find(peer_address); if (it == peers_.end()) return false; BtifAvPeer* peer = it->second; peer->Cleanup(); peers_.erase(it); delete peer; return true; } void BtifAvSink::DeleteIdlePeers() { for (auto it = peers_.begin(); it != peers_.end();) { BtifAvPeer* peer = it->second; auto prev_it = it++; if (!peer->CanBeDeleted()) continue; LOG_INFO(LOG_TAG, "%s: Deleting idle peer: %s bta_handle=0x%x", __func__, peer->PeerAddress().ToString().c_str(), peer->BtaHandle()); peer->Cleanup(); peers_.erase(prev_it); delete peer; } } void BtifAvSink::CleanupAllPeers() { while (!peers_.empty()) { auto it = peers_.begin(); BtifAvPeer* peer = it->second; peer->Cleanup(); peers_.erase(it); delete peer; } } void BtifAvSink::RegisterAllBtaHandles() { for (int peer_id = kPeerIdMin; peer_id < kPeerIdMax; peer_id++) { BTA_AvRegister(BTA_AV_CHNL_AUDIO, kBtifAvSinkServiceName.c_str(), peer_id, bta_av_sink_media_callback, UUID_SERVCLASS_AUDIO_SINK); } } void BtifAvSink::DeregisterAllBtaHandles() { for (auto it : peer_id2bta_handle_) { tBTA_AV_HNDL bta_handle = it.second; BTA_AvDeregister(bta_handle); } peer_id2bta_handle_.clear(); } void BtifAvSink::BtaHandleRegistered(uint8_t peer_id, tBTA_AV_HNDL bta_handle) { peer_id2bta_handle_.insert(std::make_pair(peer_id, bta_handle)); // Set the BTA Handle for the Peer (if exists) BtifAvPeer* peer = FindPeerByPeerId(peer_id); if (peer != nullptr) { peer->SetBtaHandle(bta_handle); } } void BtifAvStateMachine::StateIdle::OnEnter() { BTIF_TRACE_DEBUG("%s: Peer %s", __PRETTY_FUNCTION__, peer_.PeerAddress().ToString().c_str()); peer_.SetEdr(0); peer_.ClearAllFlags(); // Stop A2DP if this is the active peer if (peer_.IsActivePeer() || peer_.ActivePeerAddress().IsEmpty()) { btif_a2dp_on_idle(); } // Reset the active peer if this was the active peer and // the Idle state was reentered if (peer_.IsActivePeer() && peer_.CanBeDeleted()) { std::promise peer_ready_promise; if (peer_.IsSink()) { btif_av_source.SetActivePeer(RawAddress::kEmpty, std::move(peer_ready_promise)); } else if (peer_.IsSource()) { btif_av_sink.SetActivePeer(RawAddress::kEmpty, std::move(peer_ready_promise)); } } // Delete peers that are re-entering the Idle state if (peer_.IsSink()) { do_in_main_thread(FROM_HERE, base::Bind(&BtifAvSource::DeleteIdlePeers, base::Unretained(&btif_av_source))); } else if (peer_.IsSource()) { do_in_main_thread(FROM_HERE, base::Bind(&BtifAvSink::DeleteIdlePeers, base::Unretained(&btif_av_sink))); } } void BtifAvStateMachine::StateIdle::OnExit() { BTIF_TRACE_DEBUG("%s: Peer %s", __PRETTY_FUNCTION__, peer_.PeerAddress().ToString().c_str()); } bool BtifAvStateMachine::StateIdle::ProcessEvent(uint32_t event, void* p_data) { BTIF_TRACE_DEBUG("%s: Peer %s : event=%s flags=%s active_peer=%s", __PRETTY_FUNCTION__, peer_.PeerAddress().ToString().c_str(), BtifAvEvent::EventName(event).c_str(), peer_.FlagsToString().c_str(), logbool(peer_.IsActivePeer()).c_str()); switch (event) { case BTA_AV_ENABLE_EVT: break; case BTIF_AV_STOP_STREAM_REQ_EVT: case BTIF_AV_SUSPEND_STREAM_REQ_EVT: case BTIF_AV_ACL_DISCONNECTED: // Ignore. Just re-enter Idle so the peer can be deleted peer_.StateMachine().TransitionTo(BtifAvStateMachine::kStateIdle); break; case BTIF_AV_DISCONNECT_REQ_EVT: if (peer_.BtaHandle() != kBtaHandleUnknown) { BTA_AvClose(peer_.BtaHandle()); if (peer_.IsSource()) { BTA_AvCloseRc(peer_.BtaHandle()); } } // Re-enter Idle so the peer can be deleted peer_.StateMachine().TransitionTo(BtifAvStateMachine::kStateIdle); break; case BTIF_AV_CONNECT_REQ_EVT: case BTA_AV_PENDING_EVT: { bool can_connect = true; peer_.SetSelfInitiatedConnection(event == BTIF_AV_CONNECT_REQ_EVT); // Check whether connection is allowed if (peer_.IsSink()) { can_connect = btif_av_source.AllowedToConnect(peer_.PeerAddress()); if (!can_connect) src_disconnect_sink(peer_.PeerAddress()); } else if (peer_.IsSource()) { can_connect = btif_av_sink.AllowedToConnect(peer_.PeerAddress()); if (!can_connect) sink_disconnect_src(peer_.PeerAddress()); } if (!can_connect) { BTIF_TRACE_ERROR( "%s: Cannot connect to peer %s: too many connected " "peers", __PRETTY_FUNCTION__, peer_.PeerAddress().ToString().c_str()); if (peer_.SelfInitiatedConnection()) { btif_queue_advance(); } break; } BTA_AvOpen(peer_.PeerAddress(), peer_.BtaHandle(), true, BTA_SEC_AUTHENTICATE, peer_.LocalUuidServiceClass()); peer_.StateMachine().TransitionTo(BtifAvStateMachine::kStateOpening); } break; case BTIF_AV_AVRCP_OPEN_EVT: case BTA_AV_RC_OPEN_EVT: { // IOP_FIX: Jabra 620 only does AVRCP Open without AV Open whenever it // connects. So as per the AV WP, an AVRCP connection cannot exist // without an AV connection. Therefore, we initiate an AV connection // if an RC_OPEN_EVT is received when we are in AV_CLOSED state. // We initiate the AV connection after a small 3s timeout to avoid any // collisions from the headsets, as some headsets initiate the AVRCP // connection first and then immediately initiate the AV connection // // TODO: We may need to do this only on an AVRCP Play. FixMe BTIF_TRACE_WARNING("%s: Peer %s : event=%s received without AV", __PRETTY_FUNCTION__, peer_.PeerAddress().ToString().c_str(), BtifAvEvent::EventName(event).c_str()); bool can_connect = true; // Check whether connection is allowed if (peer_.IsSink()) { can_connect = btif_av_source.AllowedToConnect(peer_.PeerAddress()); if (!can_connect) src_disconnect_sink(peer_.PeerAddress()); } else if (peer_.IsSource()) { can_connect = btif_av_sink.AllowedToConnect(peer_.PeerAddress()); if (!can_connect) sink_disconnect_src(peer_.PeerAddress()); } if (!can_connect) { BTIF_TRACE_ERROR( "%s: Cannot connect to peer %s: too many connected " "peers", __PRETTY_FUNCTION__, peer_.PeerAddress().ToString().c_str()); break; } if (btif_av_source.Enabled()) { alarm_set_on_mloop( peer_.AvOpenOnRcTimer(), BtifAvPeer::kTimeoutAvOpenOnRcMs, btif_av_source_initiate_av_open_timer_timeout, &peer_); } else if (btif_av_sink.Enabled()) { alarm_set_on_mloop(peer_.AvOpenOnRcTimer(), BtifAvPeer::kTimeoutAvOpenOnRcMs, btif_av_sink_initiate_av_open_timer_timeout, &peer_); } if (event == BTA_AV_RC_OPEN_EVT) { btif_rc_handler(event, (tBTA_AV*)p_data); } } break; case BTA_AV_RC_BROWSE_OPEN_EVT: btif_rc_handler(event, (tBTA_AV*)p_data); break; // In case Signalling channel is not down and remote started Streaming // Procedure, we have to handle Config and Open event in Idle state. // We hit these scenarios while running PTS test case for AVRCP Controller. case BTIF_AV_SINK_CONFIG_REQ_EVT: { const btif_av_sink_config_req_t* p_config_req = static_cast(p_data); btif_av_report_sink_audio_config_state(p_config_req->peer_address, p_config_req->sample_rate, p_config_req->channel_count); } break; case BTA_AV_OPEN_EVT: { tBTA_AV* p_bta_data = (tBTA_AV*)p_data; btav_connection_state_t state; int av_state; tBTA_AV_STATUS status = p_bta_data->open.status; bool can_connect = true; LOG_INFO( LOG_TAG, "%s: Peer %s : event=%s flags=%s status=%d(%s) edr=0x%x", __PRETTY_FUNCTION__, peer_.PeerAddress().ToString().c_str(), BtifAvEvent::EventName(event).c_str(), peer_.FlagsToString().c_str(), status, (status == BTA_AV_SUCCESS) ? "SUCCESS" : "FAILED", p_bta_data->open.edr); if (p_bta_data->open.status == BTA_AV_SUCCESS) { state = BTAV_CONNECTION_STATE_CONNECTED; av_state = BtifAvStateMachine::kStateOpened; peer_.SetEdr(p_bta_data->open.edr); CHECK(peer_.PeerSep() == p_bta_data->open.sep); // Check whether connection is allowed if (peer_.IsSink()) { can_connect = btif_av_source.AllowedToConnect(peer_.PeerAddress()); if (!can_connect) src_disconnect_sink(peer_.PeerAddress()); } else if (peer_.IsSource()) { can_connect = btif_av_sink.AllowedToConnect(peer_.PeerAddress()); if (!can_connect) sink_disconnect_src(peer_.PeerAddress()); } } else { state = BTAV_CONNECTION_STATE_DISCONNECTED; av_state = BtifAvStateMachine::kStateIdle; } if (!can_connect) { BTIF_TRACE_ERROR( "%s: Cannot connect to peer %s: too many connected " "peers", __PRETTY_FUNCTION__, peer_.PeerAddress().ToString().c_str()); } else { // Report the connection state to the application btif_report_connection_state(peer_.PeerAddress(), state); // Change state to Open/Idle based on the status peer_.StateMachine().TransitionTo(av_state); if (peer_.IsSink()) { // If queued PLAY command, send it now btif_rc_check_handle_pending_play( p_bta_data->open.bd_addr, (p_bta_data->open.status == BTA_AV_SUCCESS)); } else if (peer_.IsSource() && (p_bta_data->open.status == BTA_AV_SUCCESS)) { // Bring up AVRCP connection as well BTA_AvOpenRc(peer_.BtaHandle()); } } btif_queue_advance(); } break; case BTA_AV_REMOTE_CMD_EVT: case BTA_AV_VENDOR_CMD_EVT: case BTA_AV_META_MSG_EVT: case BTA_AV_RC_FEAT_EVT: case BTA_AV_REMOTE_RSP_EVT: btif_rc_handler(event, (tBTA_AV*)p_data); break; case BTIF_AV_AVRCP_CLOSE_EVT: case BTA_AV_RC_CLOSE_EVT: { BTIF_TRACE_DEBUG("%s: Peer %s : event=%s : Stopping AV timer", __PRETTY_FUNCTION__, peer_.PeerAddress().ToString().c_str(), BtifAvEvent::EventName(event).c_str()); alarm_cancel(peer_.AvOpenOnRcTimer()); if (event == BTA_AV_RC_CLOSE_EVT) { btif_rc_handler(event, (tBTA_AV*)p_data); } } break; case BTIF_AV_OFFLOAD_START_REQ_EVT: BTIF_TRACE_ERROR("%s: Peer %s : event=%s: stream is not Opened", __PRETTY_FUNCTION__, peer_.PeerAddress().ToString().c_str(), BtifAvEvent::EventName(event).c_str()); btif_a2dp_on_offload_started(peer_.PeerAddress(), BTA_AV_FAIL); break; default: BTIF_TRACE_WARNING("%s: Peer %s : Unhandled event=%s", __PRETTY_FUNCTION__, peer_.PeerAddress().ToString().c_str(), BtifAvEvent::EventName(event).c_str()); return false; } return true; } void BtifAvStateMachine::StateOpening::OnEnter() { BTIF_TRACE_DEBUG("%s: Peer %s", __PRETTY_FUNCTION__, peer_.PeerAddress().ToString().c_str()); // Inform the application that we are entering connecting state btif_report_connection_state(peer_.PeerAddress(), BTAV_CONNECTION_STATE_CONNECTING); } void BtifAvStateMachine::StateOpening::OnExit() { BTIF_TRACE_DEBUG("%s: Peer %s", __PRETTY_FUNCTION__, peer_.PeerAddress().ToString().c_str()); } bool BtifAvStateMachine::StateOpening::ProcessEvent(uint32_t event, void* p_data) { BTIF_TRACE_DEBUG("%s: Peer %s : event=%s flags=%s active_peer=%s", __PRETTY_FUNCTION__, peer_.PeerAddress().ToString().c_str(), BtifAvEvent::EventName(event).c_str(), peer_.FlagsToString().c_str(), logbool(peer_.IsActivePeer()).c_str()); switch (event) { case BTIF_AV_STOP_STREAM_REQ_EVT: case BTIF_AV_SUSPEND_STREAM_REQ_EVT: break; // Ignore case BTIF_AV_ACL_DISCONNECTED: // ACL Disconnected needs to be handled only in Opening state, because // it is in an intermediate state. In other states we can handle // incoming/outgoing connect/disconnect requests. BTIF_TRACE_WARNING( "%s: Peer %s : event=%s: transitioning to Idle due to ACL Disconnect", __PRETTY_FUNCTION__, peer_.PeerAddress().ToString().c_str(), BtifAvEvent::EventName(event).c_str()); btif_report_connection_state(peer_.PeerAddress(), BTAV_CONNECTION_STATE_DISCONNECTED); peer_.StateMachine().TransitionTo(BtifAvStateMachine::kStateIdle); if (peer_.SelfInitiatedConnection()) { btif_queue_advance(); } break; case BTA_AV_REJECT_EVT: BTIF_TRACE_WARNING("%s: Peer %s : event=%s flags=%s", __PRETTY_FUNCTION__, peer_.PeerAddress().ToString().c_str(), BtifAvEvent::EventName(event).c_str(), peer_.FlagsToString().c_str()); btif_report_connection_state(peer_.PeerAddress(), BTAV_CONNECTION_STATE_DISCONNECTED); peer_.StateMachine().TransitionTo(BtifAvStateMachine::kStateIdle); if (peer_.SelfInitiatedConnection()) { btif_queue_advance(); } break; case BTA_AV_OPEN_EVT: { tBTA_AV* p_bta_data = (tBTA_AV*)p_data; btav_connection_state_t state; int av_state; tBTA_AV_STATUS status = p_bta_data->open.status; LOG_INFO( LOG_TAG, "%s: Peer %s : event=%s flags=%s status=%d(%s) edr=0x%x", __PRETTY_FUNCTION__, peer_.PeerAddress().ToString().c_str(), BtifAvEvent::EventName(event).c_str(), peer_.FlagsToString().c_str(), status, (status == BTA_AV_SUCCESS) ? "SUCCESS" : "FAILED", p_bta_data->open.edr); if (p_bta_data->open.status == BTA_AV_SUCCESS) { state = BTAV_CONNECTION_STATE_CONNECTED; av_state = BtifAvStateMachine::kStateOpened; peer_.SetEdr(p_bta_data->open.edr); CHECK(peer_.PeerSep() == p_bta_data->open.sep); } else { if (btif_rc_is_connected_peer(peer_.PeerAddress())) { // Disconnect the AVRCP connection, in case the A2DP connectiton // failed for any reason. BTIF_TRACE_WARNING("%s: Peer %s : Disconnecting AVRCP", __PRETTY_FUNCTION__, peer_.PeerAddress().ToString().c_str()); uint8_t peer_handle = btif_rc_get_connected_peer_handle(peer_.PeerAddress()); if (peer_handle != BTRC_HANDLE_NONE) { BTA_AvCloseRc(peer_handle); } } state = BTAV_CONNECTION_STATE_DISCONNECTED; av_state = BtifAvStateMachine::kStateIdle; } // Report the connection state to the application btif_report_connection_state(peer_.PeerAddress(), state); // Change state to Open/Idle based on the status peer_.StateMachine().TransitionTo(av_state); if (peer_.IsSink()) { // If queued PLAY command, send it now btif_rc_check_handle_pending_play( p_bta_data->open.bd_addr, (p_bta_data->open.status == BTA_AV_SUCCESS)); } else if (peer_.IsSource() && (p_bta_data->open.status == BTA_AV_SUCCESS)) { // Bring up AVRCP connection as well BTA_AvOpenRc(peer_.BtaHandle()); } if (peer_.SelfInitiatedConnection()) { btif_queue_advance(); } } break; case BTIF_AV_SINK_CONFIG_REQ_EVT: { const btif_av_sink_config_req_t* p_config_req = static_cast(p_data); if (peer_.IsSource()) { btif_av_report_sink_audio_config_state(p_config_req->peer_address, p_config_req->sample_rate, p_config_req->channel_count); } } break; case BTIF_AV_CONNECT_REQ_EVT: { // The device has moved already to Opening, hence don't report the // connection state. BTIF_TRACE_WARNING( "%s: Peer %s : event=%s : device is already connecting, " "ignore Connect request", __PRETTY_FUNCTION__, peer_.PeerAddress().ToString().c_str(), BtifAvEvent::EventName(event).c_str()); btif_queue_advance(); } break; case BTA_AV_PENDING_EVT: { // The device has moved already to Opening, hence don't report the // connection state. BTIF_TRACE_WARNING( "%s: Peer %s : event=%s : device is already connecting, " "ignore incoming request", __PRETTY_FUNCTION__, peer_.PeerAddress().ToString().c_str(), BtifAvEvent::EventName(event).c_str()); } break; case BTIF_AV_OFFLOAD_START_REQ_EVT: BTIF_TRACE_ERROR("%s: Peer %s : event=%s: stream is not Opened", __PRETTY_FUNCTION__, peer_.PeerAddress().ToString().c_str(), BtifAvEvent::EventName(event).c_str()); btif_a2dp_on_offload_started(peer_.PeerAddress(), BTA_AV_FAIL); break; case BTA_AV_CLOSE_EVT: btif_a2dp_on_stopped(nullptr); btif_report_connection_state(peer_.PeerAddress(), BTAV_CONNECTION_STATE_DISCONNECTED); peer_.StateMachine().TransitionTo(BtifAvStateMachine::kStateIdle); if (peer_.SelfInitiatedConnection()) { btif_queue_advance(); } break; case BTIF_AV_DISCONNECT_REQ_EVT: BTA_AvClose(peer_.BtaHandle()); btif_report_connection_state(peer_.PeerAddress(), BTAV_CONNECTION_STATE_DISCONNECTED); peer_.StateMachine().TransitionTo(BtifAvStateMachine::kStateIdle); if (peer_.SelfInitiatedConnection()) { btif_queue_advance(); } break; CHECK_RC_EVENT(event, (tBTA_AV*)p_data); default: BTIF_TRACE_WARNING("%s: Peer %s : Unhandled event=%s", __PRETTY_FUNCTION__, peer_.PeerAddress().ToString().c_str(), BtifAvEvent::EventName(event).c_str()); return false; } return true; } void BtifAvStateMachine::StateOpened::OnEnter() { BTIF_TRACE_DEBUG("%s: Peer %s", __PRETTY_FUNCTION__, peer_.PeerAddress().ToString().c_str()); peer_.ClearFlags(BtifAvPeer::kFlagLocalSuspendPending | BtifAvPeer::kFlagPendingStart | BtifAvPeer::kFlagPendingStop); // Set the active peer if the first connected device. // NOTE: This should be done only if we are A2DP Sink, because the A2DP Sink // implementation in Java doesn't support active devices (yet). // For A2DP Source, the setting of the Active device is done by the // ActiveDeviceManager in Java. if (peer_.IsSource() && btif_av_sink.ActivePeer().IsEmpty()) { std::promise peer_ready_promise; if (!btif_av_sink.SetActivePeer(peer_.PeerAddress(), std::move(peer_ready_promise))) { BTIF_TRACE_ERROR("%s: Error setting %s as active Source peer", __func__, peer_.PeerAddress().ToString().c_str()); } } } void BtifAvStateMachine::StateOpened::OnExit() { BTIF_TRACE_DEBUG("%s: Peer %s", __PRETTY_FUNCTION__, peer_.PeerAddress().ToString().c_str()); peer_.ClearFlags(BtifAvPeer::kFlagPendingStart); } bool BtifAvStateMachine::StateOpened::ProcessEvent(uint32_t event, void* p_data) { tBTA_AV* p_av = (tBTA_AV*)p_data; BTIF_TRACE_DEBUG("%s: Peer %s : event=%s flags=%s active_peer=%s", __PRETTY_FUNCTION__, peer_.PeerAddress().ToString().c_str(), BtifAvEvent::EventName(event).c_str(), peer_.FlagsToString().c_str(), logbool(peer_.IsActivePeer()).c_str()); if ((event == BTA_AV_REMOTE_CMD_EVT) && peer_.CheckFlags(BtifAvPeer::kFlagRemoteSuspend) && (p_av->remote_cmd.rc_id == AVRC_ID_PLAY)) { BTIF_TRACE_EVENT("%s: Peer %s : Resetting remote suspend flag on RC PLAY", __PRETTY_FUNCTION__, peer_.PeerAddress().ToString().c_str()); peer_.ClearFlags(BtifAvPeer::kFlagRemoteSuspend); } switch (event) { case BTIF_AV_STOP_STREAM_REQ_EVT: case BTIF_AV_SUSPEND_STREAM_REQ_EVT: case BTIF_AV_ACL_DISCONNECTED: break; // Ignore case BTIF_AV_START_STREAM_REQ_EVT: LOG_INFO(LOG_TAG, "%s: Peer %s : event=%s flags=%s", __PRETTY_FUNCTION__, peer_.PeerAddress().ToString().c_str(), BtifAvEvent::EventName(event).c_str(), peer_.FlagsToString().c_str()); BTA_AvStart(peer_.BtaHandle()); peer_.SetFlags(BtifAvPeer::kFlagPendingStart); break; case BTA_AV_START_EVT: { LOG_INFO(LOG_TAG, "%s: Peer %s : event=%s status=%d suspending=%d " "initiator=%d flags=%s", __PRETTY_FUNCTION__, peer_.PeerAddress().ToString().c_str(), BtifAvEvent::EventName(event).c_str(), p_av->start.status, p_av->start.suspending, p_av->start.initiator, peer_.FlagsToString().c_str()); if ((p_av->start.status == BTA_SUCCESS) && p_av->start.suspending) return true; // If remote tries to start A2DP when DUT is A2DP Source, then Suspend. // If A2DP is Sink and call is active, then disconnect the AVDTP channel. bool should_suspend = false; if (peer_.IsSink() && !peer_.CheckFlags(BtifAvPeer::kFlagPendingStart | BtifAvPeer::kFlagRemoteSuspend)) { LOG(WARNING) << __PRETTY_FUNCTION__ << ": Peer " << peer_.PeerAddress() << " : trigger Suspend as remote initiated"; should_suspend = true; } // If peer is A2DP Source, do ACK commands to audio HAL and start media task if (peer_.IsSink() && btif_a2dp_on_started(peer_.PeerAddress(), &p_av->start)) { // Only clear pending flag after acknowledgement peer_.ClearFlags(BtifAvPeer::kFlagPendingStart); } // Remain in Open state if status failed if (p_av->start.status != BTA_AV_SUCCESS) return false; if (peer_.IsSource() && peer_.IsActivePeer()) { // Remove flush state, ready for streaming btif_a2dp_sink_set_rx_flush(false); } if (should_suspend) { btif_av_source_dispatch_sm_event(peer_.PeerAddress(), BTIF_AV_SUSPEND_STREAM_REQ_EVT); } peer_.StateMachine().TransitionTo(BtifAvStateMachine::kStateStarted); } break; case BTIF_AV_DISCONNECT_REQ_EVT: BTA_AvClose(peer_.BtaHandle()); if (peer_.IsSource()) { BTA_AvCloseRc(peer_.BtaHandle()); } // Inform the application that we are disconnecting btif_report_connection_state(peer_.PeerAddress(), BTAV_CONNECTION_STATE_DISCONNECTING); // Wait in closing state until fully closed peer_.StateMachine().TransitionTo(BtifAvStateMachine::kStateClosing); break; case BTA_AV_CLOSE_EVT: // AVDTP link is closed if (peer_.IsActivePeer()) { btif_a2dp_on_stopped(nullptr); } // Change state to Idle, send acknowledgement if start is pending if (peer_.CheckFlags(BtifAvPeer::kFlagPendingStart)) { BTIF_TRACE_WARNING("%s: Peer %s : failed pending start request", __PRETTY_FUNCTION__, peer_.PeerAddress().ToString().c_str()); btif_a2dp_command_ack(A2DP_CTRL_ACK_FAILURE); // Pending start flag will be cleared when exit current state } // Inform the application that we are disconnected btif_report_connection_state(peer_.PeerAddress(), BTAV_CONNECTION_STATE_DISCONNECTED); peer_.StateMachine().TransitionTo(BtifAvStateMachine::kStateIdle); break; case BTA_AV_RECONFIG_EVT: if (peer_.CheckFlags(BtifAvPeer::kFlagPendingStart) && (p_av->reconfig.status == BTA_AV_SUCCESS)) { LOG_INFO(LOG_TAG, "%s : Peer %s : Reconfig done - calling BTA_AvStart()", __PRETTY_FUNCTION__, peer_.PeerAddress().ToString().c_str()); BTA_AvStart(peer_.BtaHandle()); } else if (peer_.CheckFlags(BtifAvPeer::kFlagPendingStart)) { BTIF_TRACE_WARNING("%s: Peer %s : failed reconfiguration", __PRETTY_FUNCTION__, peer_.PeerAddress().ToString().c_str()); peer_.ClearFlags(BtifAvPeer::kFlagPendingStart); btif_a2dp_command_ack(A2DP_CTRL_ACK_FAILURE); } break; case BTIF_AV_CONNECT_REQ_EVT: { BTIF_TRACE_WARNING("%s: Peer %s : Ignore %s for same device", __PRETTY_FUNCTION__, peer_.PeerAddress().ToString().c_str(), BtifAvEvent::EventName(event).c_str()); btif_queue_advance(); } break; case BTIF_AV_OFFLOAD_START_REQ_EVT: BTIF_TRACE_ERROR("%s: Peer %s : event=%s: stream is not Opened", __PRETTY_FUNCTION__, peer_.PeerAddress().ToString().c_str(), BtifAvEvent::EventName(event).c_str()); btif_a2dp_on_offload_started(peer_.PeerAddress(), BTA_AV_FAIL); break; case BTIF_AV_AVRCP_REMOTE_PLAY_EVT: if (peer_.CheckFlags(BtifAvPeer::kFlagRemoteSuspend)) { BTIF_TRACE_EVENT( "%s: Peer %s : Resetting remote suspend flag on RC PLAY", __PRETTY_FUNCTION__, peer_.PeerAddress().ToString().c_str()); peer_.ClearFlags(BtifAvPeer::kFlagRemoteSuspend); } break; CHECK_RC_EVENT(event, (tBTA_AV*)p_data); default: BTIF_TRACE_WARNING("%s: Peer %s : Unhandled event=%s", __PRETTY_FUNCTION__, peer_.PeerAddress().ToString().c_str(), BtifAvEvent::EventName(event).c_str()); return false; } return true; } void BtifAvStateMachine::StateStarted::OnEnter() { BTIF_TRACE_DEBUG("%s: Peer %s", __PRETTY_FUNCTION__, peer_.PeerAddress().ToString().c_str()); // We are again in started state, clear any remote suspend flags peer_.ClearFlags(BtifAvPeer::kFlagRemoteSuspend); // Report that we have entered the Streaming stage. Usually, this should // be followed by focus grant. See update_audio_focus_state() btif_report_audio_state(peer_.PeerAddress(), BTAV_AUDIO_STATE_STARTED); } void BtifAvStateMachine::StateStarted::OnExit() { BTIF_TRACE_DEBUG("%s: Peer %s", __PRETTY_FUNCTION__, peer_.PeerAddress().ToString().c_str()); } bool BtifAvStateMachine::StateStarted::ProcessEvent(uint32_t event, void* p_data) { tBTA_AV* p_av = (tBTA_AV*)p_data; BTIF_TRACE_DEBUG("%s: Peer %s : event=%s flags=%s active_peer=%s", __PRETTY_FUNCTION__, peer_.PeerAddress().ToString().c_str(), BtifAvEvent::EventName(event).c_str(), peer_.FlagsToString().c_str(), logbool(peer_.IsActivePeer()).c_str()); switch (event) { case BTIF_AV_ACL_DISCONNECTED: break; // Ignore case BTIF_AV_START_STREAM_REQ_EVT: LOG_INFO(LOG_TAG, "%s: Peer %s : event=%s flags=%s", __PRETTY_FUNCTION__, peer_.PeerAddress().ToString().c_str(), BtifAvEvent::EventName(event).c_str(), peer_.FlagsToString().c_str()); // We were started remotely, just ACK back the local request if (peer_.IsSink()) btif_a2dp_on_started(peer_.PeerAddress(), nullptr); break; // FIXME -- use suspend = true always to work around issue with BTA AV case BTIF_AV_STOP_STREAM_REQ_EVT: case BTIF_AV_SUSPEND_STREAM_REQ_EVT: LOG_INFO(LOG_TAG, "%s: Peer %s : event=%s flags=%s", __PRETTY_FUNCTION__, peer_.PeerAddress().ToString().c_str(), BtifAvEvent::EventName(event).c_str(), peer_.FlagsToString().c_str()); // Set pending flag to ensure the BTIF task is not trying to restart // the stream while suspend is in progress. peer_.SetFlags(BtifAvPeer::kFlagLocalSuspendPending); // If we were remotely suspended but suspend locally, local suspend // always overrides. peer_.ClearFlags(BtifAvPeer::kFlagRemoteSuspend); if (peer_.IsSink()) { // Immediately stop transmission of frames while suspend is pending if (peer_.IsActivePeer()) { if (event == BTIF_AV_STOP_STREAM_REQ_EVT) { btif_a2dp_on_stopped(nullptr); } else { // (event == BTIF_AV_SUSPEND_STREAM_REQ_EVT) btif_a2dp_source_set_tx_flush(true); } } } else if (peer_.IsSource()) { btif_a2dp_on_stopped(nullptr); } BTA_AvStop(peer_.BtaHandle(), true); break; case BTIF_AV_DISCONNECT_REQ_EVT: LOG_INFO(LOG_TAG, "%s: Peer %s : event=%s flags=%s", __PRETTY_FUNCTION__, peer_.PeerAddress().ToString().c_str(), BtifAvEvent::EventName(event).c_str(), peer_.FlagsToString().c_str()); // Request AVDTP to close BTA_AvClose(peer_.BtaHandle()); if (peer_.IsSource()) { BTA_AvCloseRc(peer_.BtaHandle()); } // Inform the application that we are disconnecting btif_report_connection_state(peer_.PeerAddress(), BTAV_CONNECTION_STATE_DISCONNECTING); // Wait in closing state until fully closed peer_.StateMachine().TransitionTo(BtifAvStateMachine::kStateClosing); break; case BTA_AV_SUSPEND_EVT: { LOG_INFO(LOG_TAG, "%s: Peer %s : event=%s status=%d initiator=%d flags=%s", __PRETTY_FUNCTION__, peer_.PeerAddress().ToString().c_str(), BtifAvEvent::EventName(event).c_str(), p_av->suspend.status, p_av->suspend.initiator, peer_.FlagsToString().c_str()); // A2DP suspended, stop A2DP encoder/decoder until resumed btif_a2dp_on_suspended(&p_av->suspend); // If not successful, remain in current state if (p_av->suspend.status != BTA_AV_SUCCESS) { peer_.ClearFlags(BtifAvPeer::kFlagLocalSuspendPending); if (peer_.IsSink() && peer_.IsActivePeer()) { // Suspend failed, reset back tx flush state btif_a2dp_source_set_tx_flush(false); } return false; } btav_audio_state_t state = BTAV_AUDIO_STATE_REMOTE_SUSPEND; if (p_av->suspend.initiator != true) { // Remote suspend, notify HAL and await audioflinger to // suspend/stop stream. // // Set remote suspend flag to block media task from restarting // stream only if we did not already initiate a local suspend. if (!peer_.CheckFlags(BtifAvPeer::kFlagLocalSuspendPending)) peer_.SetFlags(BtifAvPeer::kFlagRemoteSuspend); } else { state = BTAV_AUDIO_STATE_STOPPED; } // Suspend completed, clear pending status peer_.ClearFlags(BtifAvPeer::kFlagLocalSuspendPending); btif_report_audio_state(peer_.PeerAddress(), state); peer_.StateMachine().TransitionTo(BtifAvStateMachine::kStateOpened); } break; case BTA_AV_STOP_EVT: LOG_INFO(LOG_TAG, "%s: Peer %s : event=%s flags=%s", __PRETTY_FUNCTION__, peer_.PeerAddress().ToString().c_str(), BtifAvEvent::EventName(event).c_str(), peer_.FlagsToString().c_str()); peer_.SetFlags(BtifAvPeer::kFlagPendingStop); peer_.ClearFlags(BtifAvPeer::kFlagLocalSuspendPending); btif_a2dp_on_stopped(&p_av->suspend); btif_report_audio_state(peer_.PeerAddress(), BTAV_AUDIO_STATE_STOPPED); // If stop was successful, change state to Open if (p_av->suspend.status == BTA_AV_SUCCESS) peer_.StateMachine().TransitionTo(BtifAvStateMachine::kStateOpened); break; case BTA_AV_CLOSE_EVT: LOG_INFO(LOG_TAG, "%s: Peer %s : event=%s flags=%s", __PRETTY_FUNCTION__, peer_.PeerAddress().ToString().c_str(), BtifAvEvent::EventName(event).c_str(), peer_.FlagsToString().c_str()); peer_.SetFlags(BtifAvPeer::kFlagPendingStop); // AVDTP link is closed if (peer_.IsActivePeer()) { btif_a2dp_on_stopped(nullptr); } // Inform the application that we are disconnected btif_report_connection_state(peer_.PeerAddress(), BTAV_CONNECTION_STATE_DISCONNECTED); peer_.StateMachine().TransitionTo(BtifAvStateMachine::kStateIdle); break; case BTIF_AV_OFFLOAD_START_REQ_EVT: BTA_AvOffloadStart(peer_.BtaHandle()); break; case BTA_AV_OFFLOAD_START_RSP_EVT: btif_a2dp_on_offload_started(peer_.PeerAddress(), p_av->status); break; CHECK_RC_EVENT(event, (tBTA_AV*)p_data); default: BTIF_TRACE_WARNING("%s: Peer %s : Unhandled event=%s", __PRETTY_FUNCTION__, peer_.PeerAddress().ToString().c_str(), BtifAvEvent::EventName(event).c_str()); return false; } return true; } void BtifAvStateMachine::StateClosing::OnEnter() { BTIF_TRACE_DEBUG("%s: Peer %s", __PRETTY_FUNCTION__, peer_.PeerAddress().ToString().c_str()); if (peer_.IsActivePeer()) { if (peer_.IsSink()) { // Immediately stop transmission of frames btif_a2dp_source_set_tx_flush(true); // Wait for Audio Flinger to stop A2DP } else if (peer_.IsSource()) { btif_a2dp_sink_set_rx_flush(true); } } } void BtifAvStateMachine::StateClosing::OnExit() { BTIF_TRACE_DEBUG("%s: Peer %s", __PRETTY_FUNCTION__, peer_.PeerAddress().ToString().c_str()); } bool BtifAvStateMachine::StateClosing::ProcessEvent(uint32_t event, void* p_data) { BTIF_TRACE_DEBUG("%s: Peer %s : event=%s flags=%s active_peer=%s", __PRETTY_FUNCTION__, peer_.PeerAddress().ToString().c_str(), BtifAvEvent::EventName(event).c_str(), peer_.FlagsToString().c_str(), logbool(peer_.IsActivePeer()).c_str()); switch (event) { case BTIF_AV_SUSPEND_STREAM_REQ_EVT: case BTIF_AV_ACL_DISCONNECTED: break; // Ignore case BTA_AV_STOP_EVT: case BTIF_AV_STOP_STREAM_REQ_EVT: if (peer_.IsActivePeer()) { btif_a2dp_on_stopped(nullptr); } break; case BTA_AV_CLOSE_EVT: // Inform the application that we are disconnecting btif_report_connection_state(peer_.PeerAddress(), BTAV_CONNECTION_STATE_DISCONNECTED); peer_.StateMachine().TransitionTo(BtifAvStateMachine::kStateIdle); break; // Handle the RC_CLOSE event for the cleanup case BTA_AV_RC_CLOSE_EVT: btif_rc_handler(event, (tBTA_AV*)p_data); break; // Handle the RC_BROWSE_CLOSE event for testing case BTA_AV_RC_BROWSE_CLOSE_EVT: btif_rc_handler(event, (tBTA_AV*)p_data); break; case BTIF_AV_OFFLOAD_START_REQ_EVT: BTIF_TRACE_ERROR("%s: Peer %s : event=%s: stream is not Opened", __PRETTY_FUNCTION__, peer_.PeerAddress().ToString().c_str(), BtifAvEvent::EventName(event).c_str()); btif_a2dp_on_offload_started(peer_.PeerAddress(), BTA_AV_FAIL); break; default: BTIF_TRACE_WARNING("%s: Peer %s : Unhandled event=%s", __PRETTY_FUNCTION__, peer_.PeerAddress().ToString().c_str(), BtifAvEvent::EventName(event).c_str()); return false; } return true; } /** * Timer to trigger AV Open on the Source if the remote Sink device establishes * AVRCP connection without AV connection. The timer is needed to interoperate * with headsets that do establish AV after AVRCP connection. */ static void btif_av_source_initiate_av_open_timer_timeout(void* data) { BtifAvPeer* peer = (BtifAvPeer*)data; BTIF_TRACE_DEBUG("%s: Peer %s", __func__, peer->PeerAddress().ToString().c_str()); // Check if AVRCP is connected to the peer if (!btif_rc_is_connected_peer(peer->PeerAddress())) { BTIF_TRACE_ERROR("%s: AVRCP peer %s is not connected", __func__, peer->PeerAddress().ToString().c_str()); return; } // Connect to the AVRCP peer if (btif_av_source.Enabled() && btif_av_source.FindPeer(peer->PeerAddress()) == peer) { BTIF_TRACE_DEBUG("%s: Connecting to AVRCP peer %s", __func__, peer->PeerAddress().ToString().c_str()); btif_av_source_dispatch_sm_event(peer->PeerAddress(), BTIF_AV_CONNECT_REQ_EVT); } } /** * Timer to trigger AV Open on the Sink if the remote Source device establishes * AVRCP connection without AV connection. */ static void btif_av_sink_initiate_av_open_timer_timeout(void* data) { BtifAvPeer* peer = (BtifAvPeer*)data; BTIF_TRACE_DEBUG("%s: Peer %s", __func__, peer->PeerAddress().ToString().c_str()); // Check if AVRCP is connected to the peer if (!btif_rc_is_connected_peer(peer->PeerAddress())) { BTIF_TRACE_ERROR("%s: AVRCP peer %s is not connected", __func__, peer->PeerAddress().ToString().c_str()); return; } // Connect to the AVRCP peer if (btif_av_sink.Enabled() && btif_av_sink.FindPeer(peer->PeerAddress()) == peer) { BTIF_TRACE_DEBUG("%s: Connecting to AVRCP peer %s", __func__, peer->PeerAddress().ToString().c_str()); btif_av_sink_dispatch_sm_event(peer->PeerAddress(), BTIF_AV_CONNECT_REQ_EVT); } } /** * Report the A2DP connection state * * @param peer_address the peer address * @param state the connection state */ static void btif_report_connection_state(const RawAddress& peer_address, btav_connection_state_t state) { LOG_INFO(LOG_TAG, "%s: peer_address=%s state=%d", __func__, peer_address.ToString().c_str(), state); if (btif_av_source.Enabled()) { do_in_jni_thread(FROM_HERE, base::Bind(btif_av_source.Callbacks()->connection_state_cb, peer_address, state)); } else if (btif_av_sink.Enabled()) { do_in_jni_thread(FROM_HERE, base::Bind(btif_av_sink.Callbacks()->connection_state_cb, peer_address, state)); } } /** * Report the audio state of the A2DP connection. * The state is updated when either the remote ends starts streaming * (Started state) or whenever it transitions out of Started state * (to Opened or Streaming state). * * @param peer_address the peer address * @param state the audio state */ static void btif_report_audio_state(const RawAddress& peer_address, btav_audio_state_t state) { LOG_INFO(LOG_TAG, "%s: peer_address=%s state=%d", __func__, peer_address.ToString().c_str(), state); if (btif_av_source.Enabled()) { do_in_jni_thread(FROM_HERE, base::Bind(btif_av_source.Callbacks()->audio_state_cb, peer_address, state)); } else if (btif_av_sink.Enabled()) { do_in_jni_thread(FROM_HERE, base::Bind(btif_av_sink.Callbacks()->audio_state_cb, peer_address, state)); } } void btif_av_report_source_codec_state( const RawAddress& peer_address, const btav_a2dp_codec_config_t& codec_config, const std::vector& codecs_local_capabilities, const std::vector& codecs_selectable_capabilities) { BTIF_TRACE_EVENT("%s: peer_address=%s", __func__, peer_address.ToString().c_str()); if (btif_av_source.Enabled()) { do_in_jni_thread( FROM_HERE, base::Bind(btif_av_source.Callbacks()->audio_config_cb, peer_address, codec_config, codecs_local_capabilities, codecs_selectable_capabilities)); } } /** * Report the audio config state of the A2DP Sink connection. * * @param peer_address the peer address * @param sample_rate the sample rate (in samples per second) * @param channel_count the channel count (1 for Mono, 2 for Stereo) */ static void btif_av_report_sink_audio_config_state( const RawAddress& peer_address, int sample_rate, int channel_count) { LOG_INFO(LOG_TAG, "%s: Peer %s : sample_rate=%d channel_count=%d", __func__, peer_address.ToString().c_str(), sample_rate, channel_count); if (btif_av_sink.Enabled()) { do_in_jni_thread(FROM_HERE, base::Bind(btif_av_sink.Callbacks()->audio_config_cb, peer_address, sample_rate, channel_count)); } } /** * Process BTIF or BTA AV or BTA AVRCP events. The processing is done on the * JNI thread. * * @param peer_sep the corresponding peer's SEP: AVDT_TSEP_SRC if the peer * is A2DP Source, or AVDT_TSEP_SNK if the peer is A2DP Sink. * @param peer_address the peer address if known, otherwise RawAddress::kEmpty * @param bta_handle the BTA handle for the peer if known, otherwise * kBtaHandleUnknown * @param btif_av_event the corresponding event */ static void btif_av_handle_event(uint8_t peer_sep, const RawAddress& peer_address, tBTA_AV_HNDL bta_handle, const BtifAvEvent& btif_av_event) { BtifAvPeer* peer = nullptr; BTIF_TRACE_EVENT("%s: peer_sep=%s (%d) peer_address=%s handle=0x%x event=%s", __func__, (peer_sep == AVDT_TSEP_SRC) ? "Source" : "Sink", peer_sep, peer_address.ToString().c_str(), bta_handle, btif_av_event.ToString().c_str()); // Find the peer if (peer_address != RawAddress::kEmpty) { if (peer_sep == AVDT_TSEP_SNK) { peer = btif_av_source.FindOrCreatePeer(peer_address, bta_handle); } else if (peer_sep == AVDT_TSEP_SRC) { peer = btif_av_sink.FindOrCreatePeer(peer_address, bta_handle); } } else if (bta_handle != kBtaHandleUnknown) { if (peer_sep == AVDT_TSEP_SNK) { peer = btif_av_source.FindPeerByHandle(bta_handle); } else if (peer_sep == AVDT_TSEP_SRC) { peer = btif_av_sink.FindPeerByHandle(bta_handle); } } if (peer == nullptr) { BTIF_TRACE_ERROR( "%s: Cannot find or create %s peer for peer_address=%s handle=0x%x : " "event dropped: %s", __func__, (peer_sep == AVDT_TSEP_SRC) ? "Source" : "Sink", peer_address.ToString().c_str(), bta_handle, btif_av_event.ToString().c_str()); return; } peer->StateMachine().ProcessEvent(btif_av_event.Event(), btif_av_event.Data()); } /** * Process BTA AV or BTA AVRCP events. The processing is done on the JNI * thread. * * @param peer_sep the corresponding peer's SEP: AVDT_TSEP_SRC if the peer * is A2DP Source, or AVDT_TSEP_SNK if the peer is A2DP Sink. * @param btif_av_event the corresponding event */ static void btif_av_handle_bta_av_event(uint8_t peer_sep, const BtifAvEvent& btif_av_event) { RawAddress peer_address = RawAddress::kEmpty; tBTA_AV_HNDL bta_handle = kBtaHandleUnknown; tBTA_AV_EVT event = btif_av_event.Event(); tBTA_AV* p_data = (tBTA_AV*)btif_av_event.Data(); BTIF_TRACE_DEBUG("%s: peer_sep=%s (%d) event=%s", __func__, (peer_sep == AVDT_TSEP_SRC) ? "Source" : "Sink", peer_sep, btif_av_event.ToString().c_str()); switch (event) { case BTA_AV_ENABLE_EVT: { const tBTA_AV_ENABLE& enable = p_data->enable; BTIF_TRACE_DEBUG("%s: features=0x%x", __func__, enable.features); return; // Nothing to do } case BTA_AV_REGISTER_EVT: { const tBTA_AV_REGISTER& registr = p_data->registr; bta_handle = registr.hndl; uint8_t peer_id = registr.app_id; // The PeerId is used as AppId BTIF_TRACE_DEBUG("%s: handle=0x%x app_id=%d", __func__, bta_handle, registr.app_id); if (peer_sep == AVDT_TSEP_SNK) { btif_av_source.BtaHandleRegistered(peer_id, bta_handle); } else if (peer_sep == AVDT_TSEP_SRC) { btif_av_sink.BtaHandleRegistered(peer_id, bta_handle); } return; // Nothing else to do } case BTA_AV_OPEN_EVT: { const tBTA_AV_OPEN& open = p_data->open; peer_address = open.bd_addr; bta_handle = open.hndl; break; } case BTA_AV_CLOSE_EVT: { const tBTA_AV_CLOSE& close = p_data->close; bta_handle = close.hndl; break; } case BTA_AV_START_EVT: { const tBTA_AV_START& start = p_data->start; bta_handle = start.hndl; break; } case BTA_AV_SUSPEND_EVT: case BTA_AV_STOP_EVT: { const tBTA_AV_SUSPEND& suspend = p_data->suspend; bta_handle = suspend.hndl; break; } case BTA_AV_PROTECT_REQ_EVT: { const tBTA_AV_PROTECT_REQ& protect_req = p_data->protect_req; bta_handle = protect_req.hndl; break; } case BTA_AV_PROTECT_RSP_EVT: { const tBTA_AV_PROTECT_RSP& protect_rsp = p_data->protect_rsp; bta_handle = protect_rsp.hndl; break; } case BTA_AV_RC_OPEN_EVT: { const tBTA_AV_RC_OPEN& rc_open = p_data->rc_open; peer_address = rc_open.peer_addr; break; } case BTA_AV_RC_CLOSE_EVT: { const tBTA_AV_RC_CLOSE& rc_close = p_data->rc_close; peer_address = rc_close.peer_addr; break; } case BTA_AV_RC_BROWSE_OPEN_EVT: { const tBTA_AV_RC_BROWSE_OPEN& rc_browse_open = p_data->rc_browse_open; peer_address = rc_browse_open.peer_addr; break; } case BTA_AV_RC_BROWSE_CLOSE_EVT: { const tBTA_AV_RC_BROWSE_CLOSE& rc_browse_close = p_data->rc_browse_close; peer_address = rc_browse_close.peer_addr; break; } case BTA_AV_REMOTE_CMD_EVT: case BTA_AV_REMOTE_RSP_EVT: case BTA_AV_VENDOR_CMD_EVT: case BTA_AV_VENDOR_RSP_EVT: case BTA_AV_META_MSG_EVT: case BTA_AV_OFFLOAD_START_RSP_EVT: { // TODO: Might be wrong - this code will be removed once those // events are received from the AVRCP module. if (peer_sep == AVDT_TSEP_SNK) { peer_address = btif_av_source.ActivePeer(); } else if (peer_sep == AVDT_TSEP_SRC) { peer_address = btif_av_sink.ActivePeer(); } break; } case BTA_AV_RECONFIG_EVT: { const tBTA_AV_RECONFIG& reconfig = p_data->reconfig; bta_handle = reconfig.hndl; break; } case BTA_AV_PENDING_EVT: { const tBTA_AV_PEND& pend = p_data->pend; peer_address = pend.bd_addr; break; } case BTA_AV_REJECT_EVT: { const tBTA_AV_REJECT& reject = p_data->reject; peer_address = reject.bd_addr; bta_handle = reject.hndl; break; } case BTA_AV_RC_FEAT_EVT: { const tBTA_AV_RC_FEAT& rc_feat = p_data->rc_feat; peer_address = rc_feat.peer_addr; break; } } BTIF_TRACE_DEBUG("%s: peer_address=%s handle=0x%x", __func__, peer_address.ToString().c_str(), bta_handle); btif_av_handle_event(peer_sep, peer_address, bta_handle, btif_av_event); } static void bta_av_source_callback(tBTA_AV_EVT event, tBTA_AV* p_data) { BtifAvEvent btif_av_event(event, p_data, sizeof(tBTA_AV)); BTIF_TRACE_EVENT("%s: event=%s", __func__, btif_av_event.ToString().c_str()); do_in_main_thread(FROM_HERE, base::Bind(&btif_av_handle_bta_av_event, AVDT_TSEP_SNK /* peer_sep */, btif_av_event)); } static void bta_av_sink_callback(tBTA_AV_EVT event, tBTA_AV* p_data) { BtifAvEvent btif_av_event(event, p_data, sizeof(tBTA_AV)); do_in_main_thread(FROM_HERE, base::Bind(&btif_av_handle_bta_av_event, AVDT_TSEP_SRC /* peer_sep */, btif_av_event)); } // TODO: All processing should be done on the JNI thread static void bta_av_sink_media_callback(tBTA_AV_EVT event, tBTA_AV_MEDIA* p_data) { BTIF_TRACE_EVENT("%s: event=%d", __func__, event); switch (event) { case BTA_AV_SINK_MEDIA_DATA_EVT: { BtifAvPeer* peer = btif_av_sink_find_peer(btif_av_sink.ActivePeer()); if (peer != nullptr) { int state = peer->StateMachine().StateId(); if ((state == BtifAvStateMachine::kStateStarted) || (state == BtifAvStateMachine::kStateOpened)) { uint8_t queue_len = btif_a2dp_sink_enqueue_buf((BT_HDR*)p_data); BTIF_TRACE_DEBUG("%s: Packets in Sink queue %d", __func__, queue_len); } } break; } case BTA_AV_SINK_MEDIA_CFG_EVT: { btif_av_sink_config_req_t config_req; // Update the codec info of the A2DP Sink decoder btif_a2dp_sink_update_decoder((uint8_t*)(p_data->avk_config.codec_info)); config_req.sample_rate = A2DP_GetTrackSampleRate(p_data->avk_config.codec_info); if (config_req.sample_rate == -1) { APPL_TRACE_ERROR("%s: Cannot get the track frequency", __func__); break; } config_req.channel_count = A2DP_GetTrackChannelCount(p_data->avk_config.codec_info); if (config_req.channel_count == -1) { APPL_TRACE_ERROR("%s: Cannot get the channel count", __func__); break; } config_req.peer_address = p_data->avk_config.bd_addr; BtifAvEvent btif_av_event(BTIF_AV_SINK_CONFIG_REQ_EVT, &config_req, sizeof(config_req)); do_in_main_thread(FROM_HERE, base::Bind(&btif_av_handle_event, AVDT_TSEP_SRC, // peer_sep config_req.peer_address, kBtaHandleUnknown, btif_av_event)); break; } default: break; } } // Initializes the AV interface for source mode static bt_status_t init_src( btav_source_callbacks_t* callbacks, int max_connected_audio_devices, std::vector codec_priorities) { BTIF_TRACE_EVENT("%s", __func__); return btif_av_source.Init(callbacks, max_connected_audio_devices, codec_priorities); } // Initializes the AV interface for sink mode static bt_status_t init_sink(btav_sink_callbacks_t* callbacks) { BTIF_TRACE_EVENT("%s", __func__); return btif_av_sink.Init(callbacks); } // Updates the final focus state reported by components calling this module static void update_audio_focus_state(int state) { BTIF_TRACE_DEBUG("%s: state=%d", __func__, state); btif_a2dp_sink_set_focus_state_req((btif_a2dp_sink_focus_state_t)state); } // Updates the track gain (used for ducking). static void update_audio_track_gain(float gain) { BTIF_TRACE_DEBUG("%s: gain=%f", __func__, gain); btif_a2dp_sink_set_audio_track_gain(gain); } // Establishes the AV signalling channel with the remote headset static bt_status_t connect_int(RawAddress* peer_address, uint16_t uuid) { BTIF_TRACE_EVENT("%s: peer_address=%s uuid=0x%x", __func__, peer_address->ToString().c_str(), uuid); BtifAvPeer* peer = nullptr; if (uuid == UUID_SERVCLASS_AUDIO_SOURCE) { peer = btif_av_source.FindOrCreatePeer(*peer_address, kBtaHandleUnknown); if (peer == nullptr) { return BT_STATUS_FAIL; } } else if (uuid == UUID_SERVCLASS_AUDIO_SINK) { peer = btif_av_sink.FindOrCreatePeer(*peer_address, kBtaHandleUnknown); if (peer == nullptr) { return BT_STATUS_FAIL; } } peer->StateMachine().ProcessEvent(BTIF_AV_CONNECT_REQ_EVT, nullptr); return BT_STATUS_SUCCESS; } static void set_source_silence_peer_int(const RawAddress& peer_address, bool silence) { BTIF_TRACE_EVENT("%s: peer_address=%s, silence=%s", __func__, peer_address.ToString().c_str(), silence ? "true" : "false"); if (!btif_av_source.SetSilencePeer(peer_address, silence)) { BTIF_TRACE_ERROR("%s: Error setting silence state to %s", __func__, peer_address.ToString().c_str()); } } // Set the active peer static void set_active_peer_int(uint8_t peer_sep, const RawAddress& peer_address, std::promise peer_ready_promise) { BTIF_TRACE_EVENT("%s: peer_sep=%s (%d) peer_address=%s", __func__, (peer_sep == AVDT_TSEP_SRC) ? "Source" : "Sink", peer_sep, peer_address.ToString().c_str()); BtifAvPeer* peer = nullptr; if (peer_sep == AVDT_TSEP_SNK) { if (!btif_av_source.SetActivePeer(peer_address, std::move(peer_ready_promise))) { BTIF_TRACE_ERROR("%s: Error setting %s as active Sink peer", __func__, peer_address.ToString().c_str()); } return; } if (peer_sep == AVDT_TSEP_SRC) { if (!btif_av_sink.SetActivePeer(peer_address, std::move(peer_ready_promise))) { BTIF_TRACE_ERROR("%s: Error setting %s as active Source peer", __func__, peer_address.ToString().c_str()); } return; } // If reached here, we could not set the active peer BTIF_TRACE_ERROR("%s: Cannot set active %s peer to %s: peer not %s", __func__, (peer_sep == AVDT_TSEP_SRC) ? "Source" : "Sink", peer_address.ToString().c_str(), (peer == nullptr) ? "found" : "connected"); peer_ready_promise.set_value(); } static bt_status_t src_connect_sink(const RawAddress& peer_address) { BTIF_TRACE_EVENT("%s: Peer %s", __func__, peer_address.ToString().c_str()); if (!btif_av_source.Enabled()) { BTIF_TRACE_WARNING("%s: BTIF AV Source is not enabled", __func__); return BT_STATUS_NOT_READY; } RawAddress peer_address_copy(peer_address); return btif_queue_connect(UUID_SERVCLASS_AUDIO_SOURCE, &peer_address_copy, connect_int); } static bt_status_t sink_connect_src(const RawAddress& peer_address) { LOG_INFO(LOG_TAG, "%s: Peer %s", __func__, peer_address.ToString().c_str()); if (!btif_av_sink.Enabled()) { BTIF_TRACE_WARNING("%s: BTIF AV Sink is not enabled", __func__); return BT_STATUS_NOT_READY; } RawAddress peer_address_copy(peer_address); return btif_queue_connect(UUID_SERVCLASS_AUDIO_SINK, &peer_address_copy, connect_int); } static bt_status_t src_disconnect_sink(const RawAddress& peer_address) { LOG_INFO(LOG_TAG, "%s: Peer %s", __func__, peer_address.ToString().c_str()); if (!btif_av_source.Enabled()) { BTIF_TRACE_WARNING("%s: BTIF AV Source is not enabled", __func__); return BT_STATUS_NOT_READY; } BtifAvEvent btif_av_event(BTIF_AV_DISCONNECT_REQ_EVT, &peer_address, sizeof(peer_address)); return do_in_main_thread( FROM_HERE, base::Bind(&btif_av_handle_event, AVDT_TSEP_SNK, // peer_sep peer_address, kBtaHandleUnknown, btif_av_event)); } static bt_status_t sink_disconnect_src(const RawAddress& peer_address) { LOG_INFO(LOG_TAG, "%s: Peer %s", __func__, peer_address.ToString().c_str()); if (!btif_av_sink.Enabled()) { BTIF_TRACE_WARNING("%s: BTIF AV Sink is not enabled", __func__); return BT_STATUS_NOT_READY; } BtifAvEvent btif_av_event(BTIF_AV_DISCONNECT_REQ_EVT, &peer_address, sizeof(peer_address)); return do_in_main_thread( FROM_HERE, base::Bind(&btif_av_handle_event, AVDT_TSEP_SRC, // peer_sep peer_address, kBtaHandleUnknown, btif_av_event)); } static bt_status_t src_set_silence_sink(const RawAddress& peer_address, bool silence) { BTIF_TRACE_EVENT("%s: Peer %s", __func__, peer_address.ToString().c_str()); if (!btif_av_source.Enabled()) { BTIF_TRACE_WARNING("%s: BTIF AV Source is not enabled", __func__); return BT_STATUS_NOT_READY; } return do_in_main_thread(FROM_HERE, base::Bind(&set_source_silence_peer_int, peer_address, silence)); } static bt_status_t src_set_active_sink(const RawAddress& peer_address) { BTIF_TRACE_EVENT("%s: Peer %s", __func__, peer_address.ToString().c_str()); if (!btif_av_source.Enabled()) { LOG(WARNING) << __func__ << ": BTIF AV Source is not enabled"; return BT_STATUS_NOT_READY; } std::promise peer_ready_promise; std::future peer_ready_future = peer_ready_promise.get_future(); bt_status_t status = do_in_main_thread( FROM_HERE, base::BindOnce(&set_active_peer_int, AVDT_TSEP_SNK, // peer_sep peer_address, std::move(peer_ready_promise))); if (status == BT_STATUS_SUCCESS) { peer_ready_future.wait(); } else { LOG(WARNING) << __func__ << ": BTIF AV Source fails to change peer"; } return status; } static bt_status_t codec_config_src( const RawAddress& peer_address, std::vector codec_preferences) { BTIF_TRACE_EVENT("%s", __func__); if (!btif_av_source.Enabled()) { LOG(WARNING) << __func__ << ": BTIF AV Source is not enabled"; return BT_STATUS_NOT_READY; } std::promise peer_ready_promise; std::future peer_ready_future = peer_ready_promise.get_future(); bt_status_t status = do_in_main_thread( FROM_HERE, base::BindOnce(&BtifAvSource::UpdateCodecConfig, base::Unretained(&btif_av_source), peer_address, codec_preferences, std::move(peer_ready_promise))); if (status == BT_STATUS_SUCCESS) { peer_ready_future.wait(); } else { LOG(WARNING) << __func__ << ": BTIF AV Source fails to config codec"; } return status; } static void cleanup_src(void) { BTIF_TRACE_EVENT("%s", __func__); do_in_main_thread(FROM_HERE, base::Bind(&BtifAvSource::Cleanup, base::Unretained(&btif_av_source))); } static void cleanup_sink(void) { BTIF_TRACE_EVENT("%s", __func__); do_in_main_thread(FROM_HERE, base::Bind(&BtifAvSink::Cleanup, base::Unretained(&btif_av_sink))); } static const btav_source_interface_t bt_av_src_interface = { sizeof(btav_source_interface_t), init_src, src_connect_sink, src_disconnect_sink, src_set_silence_sink, src_set_active_sink, codec_config_src, cleanup_src, }; static const btav_sink_interface_t bt_av_sink_interface = { sizeof(btav_sink_interface_t), init_sink, sink_connect_src, sink_disconnect_src, cleanup_sink, update_audio_focus_state, update_audio_track_gain, }; RawAddress btif_av_source_active_peer(void) { return btif_av_source.ActivePeer(); } RawAddress btif_av_sink_active_peer(void) { return btif_av_sink.ActivePeer(); } bool btif_av_is_sink_enabled(void) { return btif_av_sink.Enabled(); } void btif_av_stream_start(void) { LOG_INFO(LOG_TAG, "%s", __func__); btif_av_source_dispatch_sm_event(btif_av_source_active_peer(), BTIF_AV_START_STREAM_REQ_EVT); } void btif_av_stream_stop(const RawAddress& peer_address) { LOG_INFO(LOG_TAG, "%s peer %s", __func__, peer_address.ToString().c_str()); if (!peer_address.IsEmpty()) { btif_av_source_dispatch_sm_event(peer_address, BTIF_AV_STOP_STREAM_REQ_EVT); return; } // The active peer might have changed and we might be in the process // of reconfiguring the stream. We need to stop the appopriate peer(s). for (auto it : btif_av_source.Peers()) { const BtifAvPeer* peer = it.second; btif_av_source_dispatch_sm_event(peer->PeerAddress(), BTIF_AV_STOP_STREAM_REQ_EVT); } } void btif_av_stream_suspend(void) { LOG_INFO(LOG_TAG, "%s", __func__); // The active peer might have changed and we might be in the process // of reconfiguring the stream. We need to suspend the appropriate peer(s). for (auto it : btif_av_source.Peers()) { const BtifAvPeer* peer = it.second; btif_av_source_dispatch_sm_event(peer->PeerAddress(), BTIF_AV_SUSPEND_STREAM_REQ_EVT); } } void btif_av_stream_start_offload(void) { LOG_INFO(LOG_TAG, "%s", __func__); btif_av_source_dispatch_sm_event(btif_av_source_active_peer(), BTIF_AV_OFFLOAD_START_REQ_EVT); } void btif_av_src_disconnect_sink(const RawAddress& peer_address) { LOG_INFO(LOG_TAG, "%s: peer %s", __func__, peer_address.ToString().c_str()); src_disconnect_sink(peer_address); } bool btif_av_stream_ready(void) { // Make sure the main adapter is enabled if (btif_is_enabled() == 0) { BTIF_TRACE_EVENT("%s: Main adapter is not enabled", __func__); return false; } BtifAvPeer* peer = btif_av_find_active_peer(); if (peer == nullptr) { BTIF_TRACE_WARNING("%s: No active peer found", __func__); return false; } int state = peer->StateMachine().StateId(); LOG_INFO(LOG_TAG, "%s: Peer %s : state=%d, flags=%s", __func__, peer->PeerAddress().ToString().c_str(), state, peer->FlagsToString().c_str()); // check if we are remotely suspended or stop is pending if (peer->CheckFlags(BtifAvPeer::kFlagRemoteSuspend | BtifAvPeer::kFlagPendingStop)) { return false; } return (state == BtifAvStateMachine::kStateOpened); } bool btif_av_stream_started_ready(void) { BtifAvPeer* peer = btif_av_find_active_peer(); if (peer == nullptr) { BTIF_TRACE_WARNING("%s: No active peer found", __func__); return false; } int state = peer->StateMachine().StateId(); bool ready = false; if (peer->CheckFlags(BtifAvPeer::kFlagLocalSuspendPending | BtifAvPeer::kFlagRemoteSuspend | BtifAvPeer::kFlagPendingStop)) { // Disallow media task to start if we have pending actions ready = false; } else { ready = (state == BtifAvStateMachine::kStateStarted); } LOG_INFO(LOG_TAG, "%s: Peer %s : state=%d flags=%s ready=%d", __func__, peer->PeerAddress().ToString().c_str(), state, peer->FlagsToString().c_str(), ready); return ready; } static void btif_av_source_dispatch_sm_event(const RawAddress& peer_address, btif_av_sm_event_t event) { BtifAvEvent btif_av_event(event, nullptr, 0); BTIF_TRACE_EVENT("%s: peer_address=%s event=%s", __func__, peer_address.ToString().c_str(), btif_av_event.ToString().c_str()); do_in_main_thread(FROM_HERE, base::Bind(&btif_av_handle_event, AVDT_TSEP_SNK, // peer_sep peer_address, kBtaHandleUnknown, btif_av_event)); } static void btif_av_sink_dispatch_sm_event(const RawAddress& peer_address, btif_av_sm_event_t event) { BtifAvEvent btif_av_event(event, nullptr, 0); BTIF_TRACE_EVENT("%s: peer_address=%s event=%s", __func__, peer_address.ToString().c_str(), btif_av_event.ToString().c_str()); do_in_main_thread(FROM_HERE, base::Bind(&btif_av_handle_event, AVDT_TSEP_SRC, // peer_sep peer_address, kBtaHandleUnknown, btif_av_event)); } bt_status_t btif_av_source_execute_service(bool enable) { BTIF_TRACE_EVENT("%s: Source service: %s", __func__, (enable) ? "enable" : "disable"); if (enable) { // TODO: Removed BTA_SEC_AUTHORIZE since the Java/App does not // handle this request in order to allow incoming connections to succeed. // We need to put this back once support for this is added. // Added BTA_AV_FEAT_NO_SCO_SSPD - this ensures that the BTA does not // auto-suspend av streaming on AG events(SCO or Call). The suspend shall // be initiated by the app/audioflinger layers. // Support for browsing for SDP record should work only if we enable BROWSE // while registering. tBTA_AV_FEAT features = BTA_AV_FEAT_RCTG | BTA_AV_FEAT_METADATA | BTA_AV_FEAT_VENDOR | BTA_AV_FEAT_NO_SCO_SSPD; if (delay_reporting_enabled()) { features |= BTA_AV_FEAT_DELAY_RPT; } #if (AVRC_ADV_CTRL_INCLUDED == TRUE) features |= BTA_AV_FEAT_RCCT | BTA_AV_FEAT_ADV_CTRL | BTA_AV_FEAT_BROWSE; #endif BTA_AvEnable(BTA_SEC_AUTHENTICATE, features, bta_av_source_callback); btif_av_source.RegisterAllBtaHandles(); return BT_STATUS_SUCCESS; } // Disable the service btif_av_source.DeregisterAllBtaHandles(); BTA_AvDisable(); return BT_STATUS_SUCCESS; } bt_status_t btif_av_sink_execute_service(bool enable) { BTIF_TRACE_EVENT("%s: Sink service: %s", __func__, (enable) ? "enable" : "disable"); if (enable) { // Added BTA_AV_FEAT_NO_SCO_SSPD - this ensures that the BTA does not // auto-suspend AV streaming on AG events (SCO or Call). The suspend shall // be initiated by the app/audioflinger layers. tBTA_AV_FEAT features = BTA_AV_FEAT_NO_SCO_SSPD | BTA_AV_FEAT_RCCT | BTA_AV_FEAT_METADATA | BTA_AV_FEAT_VENDOR | BTA_AV_FEAT_ADV_CTRL | BTA_AV_FEAT_RCTG | BTA_AV_FEAT_BROWSE; BTA_AvEnable(BTA_SEC_AUTHENTICATE, features, bta_av_sink_callback); btif_av_sink.RegisterAllBtaHandles(); return BT_STATUS_SUCCESS; } // Disable the service btif_av_sink.DeregisterAllBtaHandles(); BTA_AvDisable(); return BT_STATUS_SUCCESS; } // Get the AV callback interface for A2DP source profile const btav_source_interface_t* btif_av_get_src_interface(void) { BTIF_TRACE_EVENT("%s", __func__); return &bt_av_src_interface; } // Get the AV callback interface for A2DP sink profile const btav_sink_interface_t* btif_av_get_sink_interface(void) { BTIF_TRACE_EVENT("%s", __func__); return &bt_av_sink_interface; } bool btif_av_is_connected(void) { BtifAvPeer* peer = btif_av_find_active_peer(); if (peer == nullptr) { BTIF_TRACE_WARNING("%s: No active peer found", __func__); return false; } bool connected = peer->IsConnected(); BTIF_TRACE_DEBUG("%s: Peer %s is %s", __func__, peer->PeerAddress().ToString().c_str(), (connected) ? "connected" : "not connected"); return connected; } uint8_t btif_av_get_peer_sep(void) { BtifAvPeer* peer = btif_av_find_active_peer(); if (peer == nullptr) { BTIF_TRACE_WARNING("%s: No active peer found", __func__); return AVDT_TSEP_SNK; } uint8_t peer_sep = peer->PeerSep(); BTIF_TRACE_DEBUG("%s: Peer %s SEP is %s (%d)", __func__, peer->PeerAddress().ToString().c_str(), (peer_sep == AVDT_TSEP_SRC) ? "Source" : "Sink", peer_sep); return peer_sep; } void btif_av_clear_remote_suspend_flag(void) { BtifAvPeer* peer = btif_av_find_active_peer(); if (peer == nullptr) { BTIF_TRACE_WARNING("%s: No active peer found", __func__); return; } BTIF_TRACE_DEBUG("%s: Peer %s : flags=%s are cleared", __func__, peer->PeerAddress().ToString().c_str(), peer->FlagsToString().c_str()); peer->ClearFlags(BtifAvPeer::kFlagRemoteSuspend); } bool btif_av_is_peer_edr(const RawAddress& peer_address) { BtifAvPeer* peer = btif_av_find_peer(peer_address); if (peer == nullptr) { BTIF_TRACE_WARNING("%s: No peer found for peer_address=%s", __func__, peer_address.ToString().c_str()); return false; } if (!peer->IsConnected()) { BTIF_TRACE_WARNING("%s: Peer %s is not connected", __func__, peer_address.ToString().c_str()); return false; } bool is_edr = peer->IsEdr(); BTIF_TRACE_DEBUG("%s: Peer %s : is_edr=%d", __func__, peer_address.ToString().c_str(), is_edr); return is_edr; } bool btif_av_peer_supports_3mbps(const RawAddress& peer_address) { BtifAvPeer* peer = btif_av_find_peer(peer_address); if (peer == nullptr) { BTIF_TRACE_WARNING("%s: No peer found for peer_address=%s", __func__, peer_address.ToString().c_str()); return false; } bool is3mbps = peer->Is3Mbps(); bool is_connected = peer->IsConnected(); BTIF_TRACE_DEBUG("%s: Peer %s : connected=%d, edr_3mbps=%d", __func__, peer_address.ToString().c_str(), is_connected, is3mbps); return (is_connected && is3mbps); } void btif_av_acl_disconnected(const RawAddress& peer_address) { // Inform the application that ACL is disconnected and move to idle state LOG_INFO(LOG_TAG, "%s: Peer %s : ACL Disconnected", __func__, peer_address.ToString().c_str()); if (btif_av_source.Enabled()) { btif_av_source_dispatch_sm_event(peer_address, BTIF_AV_ACL_DISCONNECTED); } else if (btif_av_sink.Enabled()) { btif_av_sink_dispatch_sm_event(peer_address, BTIF_AV_ACL_DISCONNECTED); } } static void btif_debug_av_peer_dump(int fd, const BtifAvPeer& peer) { std::string state_str; int state = peer.StateMachine().StateId(); switch (state) { case BtifAvStateMachine::kStateIdle: state_str = "Idle"; break; case BtifAvStateMachine::kStateOpening: state_str = "Opening"; break; case BtifAvStateMachine::kStateOpened: state_str = "Opened"; break; case BtifAvStateMachine::kStateStarted: state_str = "Started"; break; case BtifAvStateMachine::kStateClosing: state_str = "Closing"; break; default: state_str = "Unknown(" + std::to_string(state) + ")"; break; } dprintf(fd, " Peer: %s\n", peer.PeerAddress().ToString().c_str()); dprintf(fd, " Connected: %s\n", peer.IsConnected() ? "true" : "false"); dprintf(fd, " Streaming: %s\n", peer.IsStreaming() ? "true" : "false"); dprintf(fd, " SEP: %d(%s)\n", peer.PeerSep(), (peer.IsSource()) ? "Source" : "Sink"); dprintf(fd, " State Machine: %s\n", state_str.c_str()); dprintf(fd, " Flags: %s\n", peer.FlagsToString().c_str()); dprintf(fd, " OpenOnRcTimer: %s\n", alarm_is_scheduled(peer.AvOpenOnRcTimer()) ? "Scheduled" : "Not scheduled"); dprintf(fd, " BTA Handle: 0x%x\n", peer.BtaHandle()); dprintf(fd, " Peer ID: %d\n", peer.PeerId()); dprintf(fd, " EDR: %s\n", peer.IsEdr() ? "true" : "false"); dprintf(fd, " Support 3Mbps: %s\n", peer.Is3Mbps() ? "true" : "false"); dprintf(fd, " Self Initiated Connection: %s\n", peer.SelfInitiatedConnection() ? "true" : "false"); } static void btif_debug_av_source_dump(int fd) { bool enabled = btif_av_source.Enabled(); dprintf(fd, "\nA2DP Source State: %s\n", (enabled) ? "Enabled" : "Disabled"); if (!enabled) return; dprintf(fd, " Active peer: %s\n", btif_av_source.ActivePeer().ToString().c_str()); for (auto it : btif_av_source.Peers()) { const BtifAvPeer* peer = it.second; btif_debug_av_peer_dump(fd, *peer); } } static void btif_debug_av_sink_dump(int fd) { bool enabled = btif_av_sink.Enabled(); dprintf(fd, "\nA2DP Sink State: %s\n", (enabled) ? "Enabled" : "Disabled"); if (!enabled) return; dprintf(fd, " Active peer: %s\n", btif_av_sink.ActivePeer().ToString().c_str()); dprintf(fd, " Peers:\n"); for (auto it : btif_av_sink.Peers()) { const BtifAvPeer* peer = it.second; btif_debug_av_peer_dump(fd, *peer); } } void btif_debug_av_dump(int fd) { btif_debug_av_source_dump(fd); btif_debug_av_sink_dump(fd); } void btif_av_set_audio_delay(uint16_t delay) { btif_a2dp_control_set_audio_delay(delay); bluetooth::audio::a2dp::set_remote_delay(delay); } void btif_av_reset_audio_delay(void) { btif_a2dp_control_reset_audio_delay(); } bool btif_av_is_a2dp_offload_enabled() { return btif_av_source.A2dpOffloadEnabled(); } bool btif_av_is_peer_silenced(const RawAddress& peer_address) { return btif_av_source.IsPeerSilenced(peer_address); }