/* * SPDX-FileCopyrightText: 2021-2024 Espressif Systems (Shanghai) CO LTD * * SPDX-License-Identifier: Unlicense OR CC0-1.0 */ #include #include #include "freertos/FreeRTOS.h" #include "freertos/task.h" #include "freertos/queue.h" #include "driver/uart.h" #include "esp_log.h" #include "esp_attr.h" #include "uart_driver.h" #include "nimble/hci_common.h" #include "host/ble_hs_mbuf.h" #define TAG "UART_HCI" #define UART_NO (1) #define UART_BUF_SZ (1024) #define UART_TX_PIN (CONFIG_EXAMPLE_HCI_UART_TX_PIN) #define UART_RX_PIN (CONFIG_EXAMPLE_HCI_UART_RX_PIN) #define UART_RTS_PIN (CONFIG_EXAMPLE_HCI_UART_RTS_PIN) #define UART_CTS_PIN (CONFIG_EXAMPLE_HCI_UART_CTS_PIN) #define HCI_H4_ACL (0x02) #define HCI_H4_CMD (0x01) #define HCI_H4_EVT (0x04) #define BLE_HCI_EVENT_HDR_LEN (2) #define BLE_HCI_CMD_HDR_LEN (3) enum { UART_RX_TYPE = 0, UART_RX_LEN, UART_RX_DATA, }; enum { DATA_TYPE_COMMAND = 1, DATA_TYPE_ACL = 2, DATA_TYPE_EVENT = 4 }; TaskHandle_t s_rx_task_hdl; static void IRAM_ATTR hci_uart_rx_task(void *arg) { uint8_t buf[1026]; int len_now_read = -1; uint32_t len_to_read = 1; uint32_t len_total_read = 0; uint8_t rx_st = UART_RX_TYPE; while (1) { len_now_read = uart_read_bytes(UART_NO, &buf[len_total_read], len_to_read, portMAX_DELAY); assert(len_now_read == len_to_read); len_total_read += len_now_read; switch (rx_st) { case UART_RX_TYPE: { assert(buf[0] >= DATA_TYPE_ACL && buf[0] <= DATA_TYPE_EVENT); if (buf[0] == DATA_TYPE_ACL) { len_to_read = 4; } else if (buf[0] == DATA_TYPE_EVENT) { len_to_read = 2; } else { assert(0); } rx_st = UART_RX_LEN; } break; case UART_RX_LEN: { if (buf[0] == DATA_TYPE_ACL) { len_to_read = buf[3] | (buf[4] << 8); } else if (buf[0] == DATA_TYPE_EVENT) { len_to_read = buf[2]; } else { assert(0); } rx_st = UART_RX_DATA; } break; case UART_RX_DATA: { uint8_t *data = buf; int rc; if (data[0] == HCI_H4_EVT) { uint8_t *evbuf; int totlen; totlen = BLE_HCI_EVENT_HDR_LEN + data[2]; assert(totlen <= UINT8_MAX + BLE_HCI_EVENT_HDR_LEN); if (totlen > MYNEWT_VAL(BLE_TRANSPORT_EVT_SIZE)) { ESP_LOGE(TAG, "Received HCI data length at host (%d)" "exceeds maximum configured HCI event buffer size (%d).", totlen, MYNEWT_VAL(BLE_TRANSPORT_EVT_SIZE)); break; } if (data[1] == BLE_HCI_EVCODE_HW_ERROR) { assert(0); } /* Allocate LE Advertising Report Event from lo pool only */ if ((data[1] == BLE_HCI_EVCODE_LE_META) && (data[3] == BLE_HCI_LE_SUBEV_ADV_RPT || data[3] == BLE_HCI_LE_SUBEV_EXT_ADV_RPT)) { evbuf = ble_transport_alloc_evt(1); /* Skip advertising report if we're out of memory */ if (!evbuf) { ESP_LOGE(TAG, "No buffers"); break; } } else { evbuf = ble_transport_alloc_evt(0); assert(evbuf != NULL); } memset(evbuf, 0, sizeof * evbuf); memcpy(evbuf, &data[1], totlen); rc = ble_transport_to_hs_evt(evbuf); assert(rc == 0); } else if (data[0] == HCI_H4_ACL) { struct os_mbuf *m = NULL; m = ble_transport_alloc_acl_from_ll(); if (!m) { ESP_LOGE(TAG, "No buffers"); } if ((rc = os_mbuf_append(m, &data[1], len_total_read - 1)) != 0) { ESP_LOGE(TAG, "%s failed to os_mbuf_append; rc = %d", __func__, rc); os_mbuf_free_chain(m); return; } ble_transport_to_hs_acl(m); } rx_st = UART_RX_TYPE; len_to_read = 1; len_total_read = 0; } break; default: { assert(0); break; } } } vTaskDelete(NULL); } void hci_uart_send(uint8_t *buf, uint16_t len) { uint8_t *p = buf; int len_write = 0; while (len) { len_write = uart_write_bytes(UART_NO, p, len); assert(len_write > 0); len -= len_write; p += len_write; } } void ble_transport_ll_init(void) { } int ble_transport_to_ll_acl_impl(struct os_mbuf *om) { uint8_t buf[OS_MBUF_PKTLEN(om) + 1]; int rc; buf[0] = HCI_H4_ACL; rc = ble_hs_mbuf_to_flat(om, buf + 1, OS_MBUF_PKTLEN(om), NULL); if(rc) { ESP_LOGE(TAG, "Error copying data %d", rc); os_mbuf_free_chain(om); return rc; } hci_uart_send(buf, OS_MBUF_PKTLEN(om) + 1); os_mbuf_free_chain(om); return 0; } int ble_transport_to_ll_cmd_impl(void *buf) { int len = 3 + ((uint8_t *)buf)[2] + 1; uint8_t data[258]; data[0] = HCI_H4_CMD; memcpy(data + 1, buf, len - 1); hci_uart_send(data, len); ble_transport_free(buf); return 0; } void hci_uart_open(void) { uart_config_t uart_config = { .baud_rate = CONFIG_EXAMPLE_HCI_UART_BAUDRATE, .data_bits = UART_DATA_8_BITS, .parity = UART_PARITY_DISABLE, .stop_bits = UART_STOP_BITS_1, .flow_ctrl = CONFIG_EXAMPLE_HCI_UART_FLOW_CTRL, .source_clk = UART_SCLK_DEFAULT, }; int intr_alloc_flags = 0; #if CONFIG_UART_ISR_IN_IRAM intr_alloc_flags = ESP_INTR_FLAG_IRAM; #endif ESP_ERROR_CHECK(uart_driver_install(UART_NO, UART_BUF_SZ * 2, UART_BUF_SZ * 2, 0, NULL, intr_alloc_flags)); ESP_ERROR_CHECK(uart_param_config(UART_NO, &uart_config)); ESP_ERROR_CHECK(uart_set_pin(UART_NO, UART_TX_PIN, UART_RX_PIN, -1, -1)); xTaskCreate(hci_uart_rx_task, "hci_uart_rx_task", 2048, NULL, 12, &s_rx_task_hdl); } void hci_uart_close(void) { if (s_rx_task_hdl) { vTaskDelete(s_rx_task_hdl); } uart_driver_delete(UART_NO); }