/****************************************************************************** * * Copyright (C) 1999-2012 Broadcom Corporation * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at: * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. * ******************************************************************************/ #include #include "alarm.h" #include "thread.h" #include "bt_target.h" #include "bt_trace.h" #include "bt_types.h" #include "allocator.h" #include "btm_api.h" #include "btm_int.h" #include "btu.h" #include "fixed_queue.h" #include "gki.h" #include "hash_map.h" #include "hcimsgs.h" #include "l2c_int.h" #include "osi.h" #if (defined(SDP_INCLUDED) && SDP_INCLUDED == TRUE) #include "sdpint.h" #endif #if (defined(RFCOMM_INCLUDED) && RFCOMM_INCLUDED == TRUE) #include "port_api.h" #include "port_ext.h" #endif #if (defined(GAP_INCLUDED) && GAP_INCLUDED == TRUE) #include "gap_int.h" #endif #if (defined(BNEP_INCLUDED) && BNEP_INCLUDED == TRUE) #include "bnep_int.h" #endif #if (defined(PAN_INCLUDED) && PAN_INCLUDED == TRUE) #include "pan_int.h" #endif #if (defined(HID_HOST_INCLUDED) && HID_HOST_INCLUDED == TRUE ) #include "hidh_int.h" #endif #if (defined(AVDT_INCLUDED) && AVDT_INCLUDED == TRUE) #include "avdt_int.h" #else extern void avdt_rcv_sync_info (BT_HDR *p_buf); #endif #if (defined(MCA_INCLUDED) && MCA_INCLUDED == TRUE) #include "mca_api.h" #include "mca_defs.h" #include "mca_int.h" #endif #if (defined(BTA_INCLUDED) && BTA_INCLUDED == TRUE) #include "bta_sys.h" #endif #if (BLE_INCLUDED == TRUE) #include "gatt_int.h" #if (SMP_INCLUDED == TRUE) #include "smp_int.h" #endif #include "btm_ble_int.h" #endif //#if (defined(BT_APP_DEMO) && BT_APP_DEMO == TRUE) //#include "bt_app_common.h" //#endif extern void BTE_InitStack(void); /* Define BTU storage area */ #if BTU_DYNAMIC_MEMORY == FALSE tBTU_CB btu_cb; #endif static xTaskHandle xBtuTaskHandle; static xQueueHandle xBtuQueue; // Communication queue between btu_task and bta. extern fixed_queue_t *btu_bta_msg_queue; // alarm queue between btu_task and bta extern fixed_queue_t *btu_bta_alarm_queue; // Communication queue between btu_task and hci. extern fixed_queue_t *btu_hci_msg_queue; // General timer queue. extern fixed_queue_t *btu_general_alarm_queue; extern hash_map_t *btu_general_alarm_hash_map; extern pthread_mutex_t btu_general_alarm_lock; // Oneshot timer queue. extern fixed_queue_t *btu_oneshot_alarm_queue; extern hash_map_t *btu_oneshot_alarm_hash_map; extern pthread_mutex_t btu_oneshot_alarm_lock; // l2cap timer queue. extern fixed_queue_t *btu_l2cap_alarm_queue; extern hash_map_t *btu_l2cap_alarm_hash_map; extern pthread_mutex_t btu_l2cap_alarm_lock; extern fixed_queue_t *event_queue; //extern fixed_queue_t *btif_msg_queue; //extern thread_t *bt_workqueue_thread; extern bluedroid_init_done_cb_t bluedroid_init_done_cb; /* Define a function prototype to allow a generic timeout handler */ typedef void (tUSER_TIMEOUT_FUNC) (TIMER_LIST_ENT *p_tle); static void btu_l2cap_alarm_process(TIMER_LIST_ENT *p_tle); static void btu_general_alarm_process(TIMER_LIST_ENT *p_tle); static void btu_hci_msg_process(BT_HDR *p_msg); #if (defined(BTA_INCLUDED) && BTA_INCLUDED == TRUE) static void btu_bta_alarm_process(TIMER_LIST_ENT *p_tle); #endif void btu_hci_msg_ready(fixed_queue_t *queue) { BT_HDR *p_msg; while (!fixed_queue_is_empty(queue)) { p_msg = (BT_HDR *)fixed_queue_dequeue(queue); btu_hci_msg_process(p_msg); } } void btu_general_alarm_ready(fixed_queue_t *queue) { TIMER_LIST_ENT *p_tle; while (!fixed_queue_is_empty(queue)) { p_tle = (TIMER_LIST_ENT *)fixed_queue_dequeue(queue); btu_general_alarm_process(p_tle); } } void btu_oneshot_alarm_ready(fixed_queue_t *queue) { TIMER_LIST_ENT *p_tle; while (!fixed_queue_is_empty(queue)) { p_tle = (TIMER_LIST_ENT *)fixed_queue_dequeue(queue); btu_general_alarm_process(p_tle); switch (p_tle->event) { #if (defined(BLE_INCLUDED) && BLE_INCLUDED == TRUE) case BTU_TTYPE_BLE_RANDOM_ADDR: btm_ble_timeout(p_tle); break; #endif case BTU_TTYPE_USER_FUNC: { tUSER_TIMEOUT_FUNC *p_uf = (tUSER_TIMEOUT_FUNC *)p_tle->param; (*p_uf)(p_tle); } break; default: // FAIL LOG_ERROR("Received unexpected oneshot timer event:0x%x\n", p_tle->event); break; } } } void btu_l2cap_alarm_ready(fixed_queue_t *queue) { TIMER_LIST_ENT *p_tle; while (!fixed_queue_is_empty(queue)) { p_tle = (TIMER_LIST_ENT *)fixed_queue_dequeue(queue); btu_l2cap_alarm_process(p_tle); } } #if (defined(BTA_INCLUDED) && BTA_INCLUDED == TRUE) void btu_bta_msg_ready(fixed_queue_t *queue) { BT_HDR *p_msg; while (!fixed_queue_is_empty(queue)) { p_msg = (BT_HDR *)fixed_queue_dequeue(queue); bta_sys_event(p_msg); } } void btu_bta_alarm_ready(fixed_queue_t *queue) { TIMER_LIST_ENT *p_tle; while (!fixed_queue_is_empty(queue)) { p_tle = (TIMER_LIST_ENT *)fixed_queue_dequeue(queue); btu_bta_alarm_process(p_tle); } } #endif static void btu_hci_msg_process(BT_HDR *p_msg) { /* Determine the input message type. */ switch (p_msg->event & BT_EVT_MASK) { case BTU_POST_TO_TASK_NO_GOOD_HORRIBLE_HACK: // TODO(zachoverflow): remove this ((post_to_task_hack_t *)(&p_msg->data[0]))->callback(p_msg); break; case BT_EVT_TO_BTU_HCI_ACL: /* All Acl Data goes to L2CAP */ l2c_rcv_acl_data (p_msg); break; case BT_EVT_TO_BTU_L2C_SEG_XMIT: /* L2CAP segment transmit complete */ l2c_link_segments_xmitted (p_msg); break; case BT_EVT_TO_BTU_HCI_SCO: #if BTM_SCO_INCLUDED == TRUE btm_route_sco_data (p_msg); break; #endif case BT_EVT_TO_BTU_HCI_EVT: btu_hcif_process_event ((UINT8)(p_msg->event & BT_SUB_EVT_MASK), p_msg); GKI_freebuf(p_msg); #if (defined(HCILP_INCLUDED) && HCILP_INCLUDED == TRUE) /* If host receives events which it doesn't response to, */ /* host should start idle timer to enter sleep mode. */ btu_check_bt_sleep (); #endif break; case BT_EVT_TO_BTU_HCI_CMD: btu_hcif_send_cmd ((UINT8)(p_msg->event & BT_SUB_EVT_MASK), p_msg); break; default:; int i = 0; uint16_t mask = (UINT16) (p_msg->event & BT_EVT_MASK); BOOLEAN handled = FALSE; for (; !handled && i < BTU_MAX_REG_EVENT; i++) { if (btu_cb.event_reg[i].event_cb == NULL) continue; if (mask == btu_cb.event_reg[i].event_range) { if (btu_cb.event_reg[i].event_cb) { btu_cb.event_reg[i].event_cb(p_msg); handled = TRUE; } } } if (handled == FALSE) GKI_freebuf (p_msg); break; } } #if (defined(BTA_INCLUDED) && BTA_INCLUDED == TRUE) static void btu_bta_alarm_process(TIMER_LIST_ENT *p_tle) { // call timer callback if (p_tle->p_cback) { (*p_tle->p_cback)(p_tle); } else if (p_tle->event) { BT_HDR *p_msg; if ((p_msg = (BT_HDR *) GKI_getbuf(sizeof(BT_HDR))) != NULL) { p_msg->event = p_tle->event; p_msg->layer_specific = 0; //GKI_freebuf(p_msg); bta_sys_sendmsg(p_msg); } } } #endif /***************************************************************************** ** ** Function btu_task_thread_handler ** ** Description Process BTU Task Thread. ******************************************************************************/ static void btu_task_thread_handler(void *arg) { //ke_event_clear(KE_EVENT_BTU_TASK_THREAD); TaskEvt_t *e; for (;;) { if (pdTRUE == xQueueReceive(xBtuQueue, &e, (portTickType)portMAX_DELAY)) { if (e->sig == 0xff) { fixed_queue_process(btu_hci_msg_queue); #if (defined(BTA_INCLUDED) && BTA_INCLUDED == TRUE) fixed_queue_process(btu_bta_msg_queue); fixed_queue_process(btu_bta_alarm_queue); #endif fixed_queue_process(btu_general_alarm_queue); fixed_queue_process(btu_oneshot_alarm_queue); fixed_queue_process(btu_l2cap_alarm_queue); } } osi_free(e); } } void btu_task_post(void) { TaskEvt_t *evt = (TaskEvt_t *)osi_malloc(sizeof(TaskEvt_t)); if (evt == NULL) return; evt->sig = 0xff; evt->par = 0; if (xQueueSend(xBtuQueue, &evt, 10/portTICK_RATE_MS) != pdTRUE) { ets_printf("xBtuQueue failed\n"); } } void btu_task_start_up(void) { // ke_event_callback_set(KE_EVENT_BTU_TASK_THREAD, &btu_task_thread_handler); xBtuQueue = xQueueCreate(30, sizeof(void *)); xTaskCreate(btu_task_thread_handler, "BtuT", 8192, NULL, configMAX_PRIORITIES - 1, &xBtuTaskHandle); #if (defined(BTA_INCLUDED) && BTA_INCLUDED == TRUE) fixed_queue_register_dequeue(btu_bta_msg_queue, btu_bta_msg_ready); #endif fixed_queue_register_dequeue(btu_hci_msg_queue, btu_hci_msg_ready); fixed_queue_register_dequeue(btu_general_alarm_queue, btu_general_alarm_ready); fixed_queue_register_dequeue(btu_oneshot_alarm_queue, btu_oneshot_alarm_ready); fixed_queue_register_dequeue(btu_l2cap_alarm_queue, btu_l2cap_alarm_ready); /* Initialize the mandatory core stack control blocks (BTU, BTM, L2CAP, and SDP) */ btu_init_core(); /* Initialize any optional stack components */ BTE_InitStack(); #if (defined(BTA_INCLUDED) && BTA_INCLUDED == TRUE) bta_sys_init(); #endif // Inform the bt jni thread initialization is ok. // btif_transfer_context(btif_init_ok, 0, NULL, 0, NULL); #if(defined(BT_APP_DEMO) && BT_APP_DEMO == TRUE) if (bluedroid_init_done_cb) bluedroid_init_done_cb(); #endif } void btu_task_shut_down(void) { fixed_queue_unregister_dequeue(btu_hci_msg_queue); fixed_queue_unregister_dequeue(btu_general_alarm_queue); fixed_queue_unregister_dequeue(btu_oneshot_alarm_queue); fixed_queue_unregister_dequeue(btu_l2cap_alarm_queue); #if (defined(BTA_INCLUDED) && BTA_INCLUDED == TRUE) fixed_queue_unregister_dequeue(btu_bta_msg_queue); bta_sys_free(); #endif btu_free_core(); vTaskDelete(xBtuTaskHandle); vQueueDelete(xBtuQueue); } /******************************************************************************* ** ** Function btu_start_timer ** ** Description Start a timer for the specified amount of time. ** NOTE: The timeout resolution is in SECONDS! (Even ** though the timer structure field is ticks) ** ** Returns void ** *******************************************************************************/ static void btu_general_alarm_process(TIMER_LIST_ENT *p_tle) { assert(p_tle != NULL); switch (p_tle->event) { case BTU_TTYPE_BTM_DEV_CTL: btm_dev_timeout(p_tle); break; case BTU_TTYPE_L2CAP_LINK: case BTU_TTYPE_L2CAP_CHNL: case BTU_TTYPE_L2CAP_HOLD: case BTU_TTYPE_L2CAP_INFO: case BTU_TTYPE_L2CAP_FCR_ACK: l2c_process_timeout (p_tle); break; #if (defined(SDP_INCLUDED) && SDP_INCLUDED == TRUE) case BTU_TTYPE_SDP: sdp_conn_timeout ((tCONN_CB *)p_tle->param); break; #endif case BTU_TTYPE_BTM_RMT_NAME: btm_inq_rmt_name_failed(); break; #if (defined(RFCOMM_INCLUDED) && RFCOMM_INCLUDED == TRUE) case BTU_TTYPE_RFCOMM_MFC: case BTU_TTYPE_RFCOMM_PORT: rfcomm_process_timeout (p_tle); break; #endif #if ((defined(BNEP_INCLUDED) && BNEP_INCLUDED == TRUE)) case BTU_TTYPE_BNEP: bnep_process_timeout(p_tle); break; #endif #if (defined(AVDT_INCLUDED) && AVDT_INCLUDED == TRUE) case BTU_TTYPE_AVDT_CCB_RET: case BTU_TTYPE_AVDT_CCB_RSP: case BTU_TTYPE_AVDT_CCB_IDLE: case BTU_TTYPE_AVDT_SCB_TC: avdt_process_timeout(p_tle); break; #endif #if (defined(HID_HOST_INCLUDED) && HID_HOST_INCLUDED == TRUE) case BTU_TTYPE_HID_HOST_REPAGE_TO : hidh_proc_repage_timeout(p_tle); break; #endif #if (defined(BLE_INCLUDED) && BLE_INCLUDED == TRUE) case BTU_TTYPE_BLE_INQUIRY: case BTU_TTYPE_BLE_GAP_LIM_DISC: case BTU_TTYPE_BLE_RANDOM_ADDR: case BTU_TTYPE_BLE_GAP_FAST_ADV: case BTU_TTYPE_BLE_OBSERVE: btm_ble_timeout(p_tle); break; case BTU_TTYPE_ATT_WAIT_FOR_RSP: gatt_rsp_timeout(p_tle); break; case BTU_TTYPE_ATT_WAIT_FOR_IND_ACK: gatt_ind_ack_timeout(p_tle); break; #if (defined(SMP_INCLUDED) && SMP_INCLUDED == TRUE) case BTU_TTYPE_SMP_PAIRING_CMD: smp_rsp_timeout(p_tle); break; #endif #endif #if (MCA_INCLUDED == TRUE) case BTU_TTYPE_MCA_CCB_RSP: mca_process_timeout(p_tle); break; #endif case BTU_TTYPE_USER_FUNC: { tUSER_TIMEOUT_FUNC *p_uf = (tUSER_TIMEOUT_FUNC *)p_tle->param; (*p_uf)(p_tle); } break; default:; int i = 0; BOOLEAN handled = FALSE; for (; !handled && i < BTU_MAX_REG_TIMER; i++) { if (btu_cb.timer_reg[i].timer_cb == NULL) continue; if (btu_cb.timer_reg[i].p_tle == p_tle) { btu_cb.timer_reg[i].timer_cb(p_tle); handled = TRUE; } } break; } } void btu_general_alarm_cb(void *data) { assert(data != NULL); TIMER_LIST_ENT *p_tle = (TIMER_LIST_ENT *)data; fixed_queue_enqueue(btu_general_alarm_queue, p_tle); //ke_event_set(KE_EVENT_BTU_TASK_THREAD); btu_task_post(); } void btu_start_timer(TIMER_LIST_ENT *p_tle, UINT16 type, UINT32 timeout_sec) { osi_alarm_t *alarm = NULL; assert(p_tle != NULL); // Get the alarm for the timer list entry. pthread_mutex_lock(&btu_general_alarm_lock); if (!hash_map_has_key(btu_general_alarm_hash_map, p_tle)) { alarm = osi_alarm_new("btu_gen", btu_general_alarm_cb, (void *)p_tle, 0); hash_map_set(btu_general_alarm_hash_map, p_tle, alarm); } pthread_mutex_unlock(&btu_general_alarm_lock); alarm = hash_map_get(btu_general_alarm_hash_map, p_tle); if (alarm == NULL) { LOG_ERROR("%s Unable to create alarm", __func__); return; } osi_alarm_cancel(alarm); p_tle->event = type; // NOTE: This value is in seconds but stored in a ticks field. p_tle->ticks = timeout_sec; p_tle->in_use = TRUE; osi_alarm_set(alarm, (period_ms_t)(timeout_sec * 1000)); } /******************************************************************************* ** ** Function btu_stop_timer ** ** Description Stop a timer. ** ** Returns void ** *******************************************************************************/ void btu_stop_timer(TIMER_LIST_ENT *p_tle) { assert(p_tle != NULL); if (p_tle->in_use == FALSE) return; p_tle->in_use = FALSE; // Get the alarm for the timer list entry. osi_alarm_t *alarm = hash_map_get(btu_general_alarm_hash_map, p_tle); if (alarm == NULL) { LOG_WARN("%s Unable to find expected alarm in hashmap", __func__); return; } osi_alarm_cancel(alarm); } #if defined(QUICK_TIMER_TICKS_PER_SEC) && (QUICK_TIMER_TICKS_PER_SEC > 0) /******************************************************************************* ** ** Function btu_start_quick_timer ** ** Description Start a timer for the specified amount of time in ticks. ** ** Returns void ** *******************************************************************************/ static void btu_l2cap_alarm_process(TIMER_LIST_ENT *p_tle) { assert(p_tle != NULL); switch (p_tle->event) { case BTU_TTYPE_L2CAP_CHNL: /* monitor or retransmission timer */ case BTU_TTYPE_L2CAP_FCR_ACK: /* ack timer */ l2c_process_timeout (p_tle); break; default: break; } } static void btu_l2cap_alarm_cb(void *data) { assert(data != NULL); TIMER_LIST_ENT *p_tle = (TIMER_LIST_ENT *)data; fixed_queue_enqueue(btu_l2cap_alarm_queue, p_tle); //ke_event_set(KE_EVENT_BTU_TASK_THREAD); btu_task_post(); } void btu_start_quick_timer(TIMER_LIST_ENT *p_tle, UINT16 type, UINT32 timeout_ticks) { osi_alarm_t *alarm = NULL; assert(p_tle != NULL); // Get the alarm for the timer list entry. pthread_mutex_lock(&btu_l2cap_alarm_lock); if (!hash_map_has_key(btu_l2cap_alarm_hash_map, p_tle)) { alarm = osi_alarm_new("btu_l2cap", btu_l2cap_alarm_cb, (void *)p_tle, 0); hash_map_set(btu_l2cap_alarm_hash_map, p_tle, (void *)alarm); } pthread_mutex_unlock(&btu_l2cap_alarm_lock); alarm = hash_map_get(btu_l2cap_alarm_hash_map, p_tle); if (alarm == NULL) { LOG_ERROR("%s Unable to create alarm", __func__); return; } osi_alarm_cancel(alarm); p_tle->event = type; p_tle->ticks = timeout_ticks; p_tle->in_use = TRUE; // The quick timer ticks are 100ms long. osi_alarm_set(alarm, (period_ms_t)(timeout_ticks * 100)); } /******************************************************************************* ** ** Function btu_stop_quick_timer ** ** Description Stop a timer. ** ** Returns void ** *******************************************************************************/ void btu_stop_quick_timer(TIMER_LIST_ENT *p_tle) { assert(p_tle != NULL); if (p_tle->in_use == FALSE) return; p_tle->in_use = FALSE; // Get the alarm for the timer list entry. osi_alarm_t *alarm = hash_map_get(btu_l2cap_alarm_hash_map, p_tle); if (alarm == NULL) { LOG_WARN("%s Unable to find expected alarm in hashmap", __func__); return; } osi_alarm_cancel(alarm); } #endif /* defined(QUICK_TIMER_TICKS_PER_SEC) && (QUICK_TIMER_TICKS_PER_SEC > 0) */ void btu_oneshot_alarm_cb(void *data) { assert(data != NULL); TIMER_LIST_ENT *p_tle = (TIMER_LIST_ENT *)data; btu_stop_timer_oneshot(p_tle); fixed_queue_enqueue(btu_oneshot_alarm_queue, p_tle); //ke_event_set(KE_EVENT_BTU_TASK_THREAD); btu_task_post(); } /* * Starts a oneshot timer with a timeout in seconds. */ void btu_start_timer_oneshot(TIMER_LIST_ENT *p_tle, UINT16 type, UINT32 timeout_sec) { osi_alarm_t *alarm = NULL; assert(p_tle != NULL); // Get the alarm for the timer list entry. pthread_mutex_lock(&btu_oneshot_alarm_lock); if (!hash_map_has_key(btu_oneshot_alarm_hash_map, p_tle)) { alarm = osi_alarm_new("btu_oneshot", btu_oneshot_alarm_cb, (void *)p_tle, 0); hash_map_set(btu_oneshot_alarm_hash_map, p_tle, alarm); } pthread_mutex_unlock(&btu_oneshot_alarm_lock); alarm = hash_map_get(btu_oneshot_alarm_hash_map, p_tle); if (alarm == NULL) { LOG_ERROR("%s Unable to create alarm", __func__); return; } osi_alarm_cancel(alarm); p_tle->event = type; p_tle->in_use = TRUE; // NOTE: This value is in seconds but stored in a ticks field. p_tle->ticks = timeout_sec; osi_alarm_set(alarm, (period_ms_t)(timeout_sec * 1000)); } void btu_stop_timer_oneshot(TIMER_LIST_ENT *p_tle) { assert(p_tle != NULL); if (p_tle->in_use == FALSE) return; p_tle->in_use = FALSE; // Get the alarm for the timer list entry. osi_alarm_t *alarm = hash_map_get(btu_oneshot_alarm_hash_map, p_tle); if (alarm == NULL) { LOG_WARN("%s Unable to find expected alarm in hashmap", __func__); return; } osi_alarm_cancel(alarm); } #if (defined(HCILP_INCLUDED) && HCILP_INCLUDED == TRUE) /******************************************************************************* ** ** Function btu_check_bt_sleep ** ** Description This function is called to check if controller can go to sleep. ** ** Returns void ** *******************************************************************************/ void btu_check_bt_sleep (void) { // TODO(zachoverflow) take pending commands into account? if (l2cb.controller_xmit_window == l2cb.num_lm_acl_bufs) { bte_main_lpm_allow_bt_device_sleep(); } } #endif