/****************************************************************************** * * Copyright (C) 2014 Google, Inc. * * 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 "common/bt_defs.h" #include "common/bt_trace.h" #include "stack/bt_types.h" #include "osi/fixed_queue.h" #include "hci/hci_hal.h" #include "hci/hci_internals.h" #include "hci/hci_layer.h" #include "osi/thread.h" #include "esp_bt.h" #include "stack/hcimsgs.h" #define HCI_H4_TASK_PINNED_TO_CORE (TASK_PINNED_TO_CORE) #define HCI_H4_TASK_STACK_SIZE (2048 + BT_TASK_EXTRA_STACK_SIZE) #define HCI_H4_TASK_PRIO (configMAX_PRIORITIES - 4) #define HCI_H4_TASK_NAME "hciH4T" #define HCI_H4_QUEUE_LEN 1 #if (C2H_FLOW_CONTROL_INCLUDED == TRUE) #include "l2c_int.h" #endif ///C2H_FLOW_CONTROL_INCLUDED == TRUE #include "stack/hcimsgs.h" #define HCI_HAL_SERIAL_BUFFER_SIZE 1026 #define HCI_BLE_EVENT 0x3e #define PACKET_TYPE_TO_INBOUND_INDEX(type) ((type) - 2) #define PACKET_TYPE_TO_INDEX(type) ((type) - 1) extern bool BTU_check_queue_is_congest(void); static const uint8_t preamble_sizes[] = { HCI_COMMAND_PREAMBLE_SIZE, HCI_ACL_PREAMBLE_SIZE, HCI_SCO_PREAMBLE_SIZE, HCI_EVENT_PREAMBLE_SIZE }; static const uint16_t outbound_event_types[] = { MSG_HC_TO_STACK_HCI_ERR, MSG_HC_TO_STACK_HCI_ACL, MSG_HC_TO_STACK_HCI_SCO, MSG_HC_TO_STACK_HCI_EVT }; typedef struct { size_t buffer_size; fixed_queue_t *rx_q; uint16_t adv_free_num; } hci_hal_env_t; static hci_hal_env_t hci_hal_env; static const hci_hal_t interface; static const hci_hal_callbacks_t *callbacks; static const esp_vhci_host_callback_t vhci_host_cb; static osi_thread_t *hci_h4_thread; static void host_send_pkt_available_cb(void); static int host_recv_pkt_cb(uint8_t *data, uint16_t len); static void hci_hal_h4_rx_handler(void *arg); static void event_uart_has_bytes(fixed_queue_t *queue); static void hci_hal_env_init( size_t buffer_size, size_t max_buffer_count) { assert(buffer_size > 0); assert(max_buffer_count > 0); hci_hal_env.buffer_size = buffer_size; hci_hal_env.adv_free_num = 0; hci_hal_env.rx_q = fixed_queue_new(max_buffer_count); if (hci_hal_env.rx_q) { fixed_queue_register_dequeue(hci_hal_env.rx_q, event_uart_has_bytes); } else { HCI_TRACE_ERROR("%s unable to create rx queue.\n", __func__); } return; } static void hci_hal_env_deinit(void) { fixed_queue_free(hci_hal_env.rx_q, osi_free_func); hci_hal_env.rx_q = NULL; } static bool hal_open(const hci_hal_callbacks_t *upper_callbacks) { assert(upper_callbacks != NULL); callbacks = upper_callbacks; #if (BLE_ADV_REPORT_FLOW_CONTROL == TRUE) hci_hal_env_init(HCI_HAL_SERIAL_BUFFER_SIZE, BLE_ADV_REPORT_FLOW_CONTROL_NUM + L2CAP_HOST_FC_ACL_BUFS + QUEUE_SIZE_MAX); // adv flow control num + ACL flow control num + hci cmd numeber #else hci_hal_env_init(HCI_HAL_SERIAL_BUFFER_SIZE, QUEUE_SIZE_MAX); #endif hci_h4_thread = osi_thread_create(HCI_H4_TASK_NAME, HCI_H4_TASK_STACK_SIZE, HCI_H4_TASK_PRIO, HCI_H4_TASK_PINNED_TO_CORE, 1); if (hci_h4_thread == NULL) { return false; } //register vhci host cb if (esp_vhci_host_register_callback(&vhci_host_cb) != ESP_OK) { return false; } return true; } static void hal_close() { hci_hal_env_deinit(); osi_thread_free(hci_h4_thread); hci_h4_thread = NULL; } /** * Function: transmit_data -TX data to low-layer * It is ported from Bluedroid source code, so it is not * needed to use write() to send data. * TODO: Just use firmware API to send data. */ static uint16_t transmit_data(serial_data_type_t type, uint8_t *data, uint16_t length) { uint8_t previous_byte; assert(data != NULL); assert(length > 0); if (type < DATA_TYPE_COMMAND || type > DATA_TYPE_SCO) { HCI_TRACE_ERROR("%s invalid data type: %d", __func__, type); return 0; } // Write the signal byte right before the data --data; previous_byte = *data; *(data) = type; ++length; BTTRC_DUMP_BUFFER("Transmit Pkt", data, length); // TX Data to target esp_vhci_host_send_packet(data, length); // Be nice and restore the old value of that byte *(data) = previous_byte; return length - 1; } // Internal functions static void hci_hal_h4_rx_handler(void *arg) { fixed_queue_process(hci_hal_env.rx_q); } bool hci_hal_h4_task_post(osi_thread_blocking_t blocking) { return osi_thread_post(hci_h4_thread, hci_hal_h4_rx_handler, NULL, 0, blocking); } #if (C2H_FLOW_CONTROL_INCLUDED == TRUE) static void hci_packet_complete(BT_HDR *packet){ uint8_t type, num_handle; uint16_t handle; uint16_t handles[MAX_L2CAP_LINKS + 4]; uint16_t num_packets[MAX_L2CAP_LINKS + 4]; uint8_t *stream = packet->data + packet->offset; tL2C_LCB *p_lcb = NULL; STREAM_TO_UINT8(type, stream); if (type == DATA_TYPE_ACL/* || type == DATA_TYPE_SCO*/) { STREAM_TO_UINT16(handle, stream); handle = handle & HCI_DATA_HANDLE_MASK; p_lcb = l2cu_find_lcb_by_handle(handle); if (p_lcb) { p_lcb->completed_packets++; } if (esp_vhci_host_check_send_available()){ num_handle = l2cu_find_completed_packets(handles, num_packets); if (num_handle > 0){ btsnd_hcic_host_num_xmitted_pkts (num_handle, handles, num_packets); } } else { //Send HCI_Host_Number_of_Completed_Packets next time. } } } #endif ///C2H_FLOW_CONTROL_INCLUDED == TRUE bool host_recv_adv_packet(BT_HDR *packet) { assert(packet); if(packet->data[0] == DATA_TYPE_EVENT && packet->data[1] == HCI_BLE_EVENT) { if(packet->data[3] == HCI_BLE_ADV_PKT_RPT_EVT #if (BLE_ADV_REPORT_FLOW_CONTROL == TRUE) || packet->data[3] == HCI_BLE_ADV_DISCARD_REPORT_EVT #endif ) { return true; } } return false; } #if (BLE_ADV_REPORT_FLOW_CONTROL == TRUE) static void hci_update_adv_report_flow_control(BT_HDR *packet) { // this is adv packet if(host_recv_adv_packet(packet)) { // update adv free number hci_hal_env.adv_free_num ++; if (esp_vhci_host_check_send_available()){ // send hci cmd btsnd_hcic_ble_update_adv_report_flow_control(hci_hal_env.adv_free_num); hci_hal_env.adv_free_num = 0; } else { //do nothing } } } #endif static void hci_hal_h4_hdl_rx_packet(BT_HDR *packet) { uint8_t type, hdr_size; uint16_t length; uint8_t *stream = packet->data + packet->offset; if (!packet) { return; } #if (C2H_FLOW_CONTROL_INCLUDED == TRUE) hci_packet_complete(packet); #endif ///C2H_FLOW_CONTROL_INCLUDED == TRUE STREAM_TO_UINT8(type, stream); packet->offset++; packet->len--; if (type == HCI_BLE_EVENT) { #if (!CONFIG_BT_STACK_NO_LOG) uint8_t len = 0; STREAM_TO_UINT8(len, stream); #endif HCI_TRACE_ERROR("Workround stream corrupted during LE SCAN: pkt_len=%d ble_event_len=%d\n", packet->len, len); osi_free(packet); return; } if (type < DATA_TYPE_ACL || type > DATA_TYPE_EVENT) { HCI_TRACE_ERROR("%s Unknown HCI message type. Dropping this byte 0x%x," " min %x, max %x\n", __func__, type, DATA_TYPE_ACL, DATA_TYPE_EVENT); osi_free(packet); return; } hdr_size = preamble_sizes[type - 1]; if (packet->len < hdr_size) { HCI_TRACE_ERROR("Wrong packet length type=%d pkt_len=%d hdr_len=%d", type, packet->len, hdr_size); osi_free(packet); return; } if (type == DATA_TYPE_ACL) { stream += hdr_size - 2; STREAM_TO_UINT16(length, stream); } else { stream += hdr_size - 1; STREAM_TO_UINT8(length, stream); } if ((length + hdr_size) != packet->len) { HCI_TRACE_ERROR("Wrong packet length type=%d hdr_len=%d pd_len=%d " "pkt_len=%d", type, hdr_size, length, packet->len); osi_free(packet); return; } #if (BLE_ADV_REPORT_FLOW_CONTROL == TRUE) hci_update_adv_report_flow_control(packet); #endif #if SCAN_QUEUE_CONGEST_CHECK if(BTU_check_queue_is_congest() && host_recv_adv_packet(packet)) { HCI_TRACE_ERROR("BtuQueue is congested"); osi_free(packet); return; } #endif packet->event = outbound_event_types[PACKET_TYPE_TO_INDEX(type)]; callbacks->packet_ready(packet); } static void event_uart_has_bytes(fixed_queue_t *queue) { BT_HDR *packet; while (!fixed_queue_is_empty(queue)) { packet = fixed_queue_dequeue(queue); hci_hal_h4_hdl_rx_packet(packet); } } static void host_send_pkt_available_cb(void) { //Controller rx cache buffer is ready for receiving new host packet //Just Call Host main thread task to process pending packets. hci_host_task_post(OSI_THREAD_BLOCKING); } static int host_recv_pkt_cb(uint8_t *data, uint16_t len) { //Target has packet to host, malloc new buffer for packet BT_HDR *pkt; size_t pkt_size; if (hci_hal_env.rx_q == NULL) { return 0; } pkt_size = BT_HDR_SIZE + len; pkt = (BT_HDR *) osi_calloc(pkt_size); //pkt = (BT_HDR *)hci_hal_env.allocator->alloc(pkt_size); if (!pkt) { HCI_TRACE_ERROR("%s couldn't aquire memory for inbound data buffer.\n", __func__); return -1; } pkt->offset = 0; pkt->len = len; pkt->layer_specific = 0; memcpy(pkt->data, data, len); fixed_queue_enqueue(hci_hal_env.rx_q, pkt); hci_hal_h4_task_post(OSI_THREAD_NON_BLOCKING); BTTRC_DUMP_BUFFER("Recv Pkt", pkt->data, len); return 0; } static const esp_vhci_host_callback_t vhci_host_cb = { .notify_host_send_available = host_send_pkt_available_cb, .notify_host_recv = host_recv_pkt_cb, }; static const hci_hal_t interface = { hal_open, hal_close, transmit_data, }; const hci_hal_t *hci_hal_h4_get_interface() { return &interface; }