/* * Copyright (c) 2006-2023, RT-Thread Development Team * * SPDX-License-Identifier: Apache-2.0 * * Change Logs: * Date Author Notes * 2023-09-24 Vandoul first version * 2023-09-27 Vandoul add sci uart */ #include "drv_sci.h" #ifdef BSP_USING_SCI //#define DRV_DEBUG #define DBG_TAG "drv.sci" #ifdef DRV_DEBUG #define DBG_LVL DBG_LOG #else #define DBG_LVL DBG_INFO #endif /* DRV_DEBUG */ #include enum { #ifdef BSP_USING_SCI0 RA_SCI_INDEX0, #endif #ifdef BSP_USING_SCI1 RA_SCI_INDEX1, #endif #ifdef BSP_USING_SCI2 RA_SCI_INDEX2, #endif #ifdef BSP_USING_SCI3 RA_SCI_INDEX3, #endif #ifdef BSP_USING_SCI4 RA_SCI_INDEX4, #endif #ifdef BSP_USING_SCI5 RA_SCI_INDEX5, #endif #ifdef BSP_USING_SCI6 RA_SCI_INDEX6, #endif #ifdef BSP_USING_SCI7 RA_SCI_INDEX7, #endif #ifdef BSP_USING_SCI8 RA_SCI_INDEX8, #endif #ifdef BSP_USING_SCI9 RA_SCI_INDEX9, #endif RA_SCI_INDEX_MAX, }; struct ra_sci_param { const char bus_name[RT_NAME_MAX]; const void *sci_ctrl; const void *sci_cfg; const void *ops; }; #ifdef RT_USING_I2C rt_weak const struct rt_i2c_bus_device_ops sci_ops_i2c; #endif #ifdef RT_USING_SPI rt_weak const struct rt_spi_ops sci_ops_spi; #endif #ifdef RT_USING_UART rt_weak const struct rt_uart_ops sci_ops_uart; #endif struct ra_sci_object { union { #ifdef RT_USING_SPI struct { struct rt_spi_bus sbus; struct rt_spi_configuration *spi_cfg; }; #endif #ifdef RT_USING_I2C struct { struct rt_i2c_bus_device ibus; }; #endif #ifdef RT_USING_UART struct { struct rt_serial_device ubus; }; #endif }; const struct ra_sci_param *param; struct rt_event event; }; #ifndef BIT #define BIT(idx) (1ul << (idx)) #endif #ifndef BITS #define BITS(b,e) ((((uint32_t)-1)<<(b))&(((uint32_t)-1)>>(31-(e)))) #endif #define _TO_STR(_a) #_a #define CONCAT3STR(_a,_b,_c) _TO_STR(_a##_b##_c) #define RA_SCI_EVENT_ABORTED BIT(0) #define RA_SCI_EVENT_RX_COMPLETE BIT(1) #define RA_SCI_EVENT_TX_COMPLETE BIT(2) #define RA_SCI_EVENT_ERROR BIT(3) #define RA_SCI_EVENT_ALL BITS(0,3) #define RA_SCI_HANDLE_ITEM(idx,type,id) {.bus_name=CONCAT3STR(sci,idx,id),.sci_ctrl=&g_sci##idx##_ctrl,.sci_cfg=&g_sci##idx##_cfg,.ops=&sci_ops_##type} const static struct ra_sci_param sci_param[] = { #ifdef BSP_USING_SCI0 #ifdef BSP_USING_SCI0_SPI RA_SCI_HANDLE_ITEM(0, spi, s), #elif defined(BSP_USING_SCI0_I2C) RA_SCI_HANDLE_ITEM(0, i2c, i), #elif defined(BSP_USING_SCI0_UART) RA_SCI_HANDLE_ITEM(0, uart, u), #endif #endif #ifdef BSP_USING_SCI1 #ifdef BSP_USING_SCI1_SPI RA_SCI_HANDLE_ITEM(1, spi, s), #elif defined(BSP_USING_SCI1_I2C) RA_SCI_HANDLE_ITEM(1, i2c, i), #elif defined(BSP_USING_SCI1_UART) RA_SCI_HANDLE_ITEM(1, uart, u), #endif #endif #ifdef BSP_USING_SCI2 #ifdef BSP_USING_SCI2_SPI RA_SCI_HANDLE_ITEM(2, spi, s), #elif defined(BSP_USING_SCI2_I2C) RA_SCI_HANDLE_ITEM(2, i2c, i), #elif defined(BSP_USING_SCI2_UART) RA_SCI_HANDLE_ITEM(2, uart, u), #endif #endif #ifdef BSP_USING_SCI3 #ifdef BSP_USING_SCI3_SPI RA_SCI_HANDLE_ITEM(3, spi, s), #elif defined(BSP_USING_SCI3_I2C) RA_SCI_HANDLE_ITEM(3, i2c, i), #elif defined(BSP_USING_SCI3_UART) RA_SCI_HANDLE_ITEM(3, uart, u), #endif #endif #ifdef BSP_USING_SCI4 #ifdef BSP_USING_SCI4_SPI RA_SCI_HANDLE_ITEM(4, spi, s), #elif defined(BSP_USING_SCI4_I2C) RA_SCI_HANDLE_ITEM(4, i2c, i), #elif defined(BSP_USING_SCI4_UART) RA_SCI_HANDLE_ITEM(4, uart, u), #endif #endif #ifdef BSP_USING_SCI5 #ifdef BSP_USING_SCI5_SPI RA_SCI_HANDLE_ITEM(5, spi, s), #elif defined(BSP_USING_SCI5_I2C) RA_SCI_HANDLE_ITEM(5, i2c, i), #elif defined(BSP_USING_SCI5_UART) RA_SCI_HANDLE_ITEM(5, uart, u), #endif #endif #ifdef BSP_USING_SCI6 #ifdef BSP_USING_SCI6_SPI RA_SCI_HANDLE_ITEM(6, spi, s), #elif defined(BSP_USING_SCI6_I2C) RA_SCI_HANDLE_ITEM(6, i2c, i), #elif defined(BSP_USING_SCI6_UART) RA_SCI_HANDLE_ITEM(6, uart, u), #endif #endif #ifdef BSP_USING_SCI7 #ifdef BSP_USING_SCI7_SPI RA_SCI_HANDLE_ITEM(7, spi, s), #elif defined(BSP_USING_SCI7_I2C) RA_SCI_HANDLE_ITEM(7, i2c, i), #elif defined(BSP_USING_SCI7_UART) RA_SCI_HANDLE_ITEM(7, uart, u), #endif #endif #ifdef BSP_USING_SCI8 #ifdef BSP_USING_SCI8_SPI RA_SCI_HANDLE_ITEM(8, spi, s), #elif defined(BSP_USING_SCI8_I2C) RA_SCI_HANDLE_ITEM(8, i2c, i), #elif defined(BSP_USING_SCI8_UART) RA_SCI_HANDLE_ITEM(8, uart, u), #endif #endif #ifdef BSP_USING_SCI9 #ifdef BSP_USING_SCI9_SPI RA_SCI_HANDLE_ITEM(9, spi, s), #elif defined(BSP_USING_SCI9_I2C) RA_SCI_HANDLE_ITEM(9, i2c, i), #elif defined(BSP_USING_SCI9_UART) RA_SCI_HANDLE_ITEM(9, uart, u), #endif #endif }; static struct ra_sci_object sci_obj[RA_SCI_INDEX_MAX] = {0}; rt_used static rt_err_t ra_wait_complete(struct ra_sci_object *obj) { rt_uint32_t event = 0; if (RT_EOK != rt_event_recv(&obj->event, RA_SCI_EVENT_ALL, RT_EVENT_FLAG_OR | RT_EVENT_FLAG_CLEAR, (rt_int32_t)rt_tick_from_millisecond(400), &event)) { return -RT_ETIMEOUT; } if ((event & (RA_SCI_EVENT_ABORTED | RA_SCI_EVENT_ERROR)) == 0) { return RT_EOK; } return -RT_ERROR; } /** * @brief SCI UART * @defgroup SCI_UART * @{ */ #ifdef BSP_USING_SCIn_UART const static int uart_buff_size[][2] = { #ifdef BSP_USING_SCI0_UART {BSP_SCI0_UART_RX_BUFSIZE, BSP_SCI0_UART_TX_BUFSIZE}, #endif #ifdef BSP_USING_SCI1_UART {BSP_SCI1_UART_RX_BUFSIZE, BSP_SCI1_UART_TX_BUFSIZE}, #endif #ifdef BSP_USING_SCI2_UART {BSP_SCI2_UART_RX_BUFSIZE, BSP_SCI2_UART_TX_BUFSIZE}, #endif #ifdef BSP_USING_SCI3_UART {BSP_SCI3_UART_RX_BUFSIZE, BSP_SCI3_UART_TX_BUFSIZE}, #endif #ifdef BSP_USING_SCI4_UART {BSP_SCI4_UART_RX_BUFSIZE, BSP_SCI4_UART_TX_BUFSIZE}, #endif #ifdef BSP_USING_SCI5_UART {BSP_SCI5_UART_RX_BUFSIZE, BSP_SCI5_UART_TX_BUFSIZE}, #endif #ifdef BSP_USING_SCI6_UART {BSP_SCI6_UART_RX_BUFSIZE, BSP_SCI6_UART_TX_BUFSIZE}, #endif #ifdef BSP_USING_SCI7_UART {BSP_SCI7_UART_RX_BUFSIZE, BSP_SCI7_UART_TX_BUFSIZE}, #endif #ifdef BSP_USING_SCI8_UART {BSP_SCI8_UART_RX_BUFSIZE, BSP_SCI8_UART_TX_BUFSIZE}, #endif #ifdef BSP_USING_SCI9_UART {BSP_SCI9_UART_RX_BUFSIZE, BSP_SCI9_UART_TX_BUFSIZE}, #endif {0, 0}, }; void sci_uart_irq_callback(uart_callback_args_t *p_args) { rt_interrupt_enter(); if (NULL != p_args) { struct ra_sci_object *obj = (struct ra_sci_object *)p_args->p_context; RT_ASSERT(obj != RT_NULL); if (UART_EVENT_RX_CHAR == p_args->event) { struct rt_serial_device *serial = &obj->ubus; struct rt_serial_rx_fifo *rx_fifo; rx_fifo = (struct rt_serial_rx_fifo *) serial->serial_rx; RT_ASSERT(rx_fifo != RT_NULL); rt_ringbuffer_putchar(&(rx_fifo->rb), (rt_uint8_t)p_args->data); rt_hw_serial_isr(serial, RT_SERIAL_EVENT_RX_IND); } } rt_interrupt_leave(); } static rt_err_t ra_uart_configure(struct rt_serial_device *serial, struct serial_configure *cfg) { struct ra_sci_object *obj; const struct ra_sci_param *param; RT_ASSERT(serial != RT_NULL); RT_ASSERT(cfg != RT_NULL); fsp_err_t err = FSP_SUCCESS; obj = rt_container_of(serial, struct ra_sci_object, ubus); param = obj->param; RT_ASSERT(param != RT_NULL); err = R_SCI_UART_Open((uart_ctrl_t *const)param->sci_ctrl, (uart_cfg_t *const)param->sci_cfg); if (FSP_SUCCESS != err) { return -RT_ERROR; } err = R_SCI_UART_CallbackSet((uart_ctrl_t *const)param->sci_ctrl, sci_uart_irq_callback, obj, NULL); if (FSP_SUCCESS != err) { //LOG_W("R_SCI_UART_CallbackSet API failed,%d", err); } return RT_EOK; } static rt_err_t ra_uart_control(struct rt_serial_device *serial, int cmd, void *arg) { return RT_EOK; } static int ra_uart_putc(struct rt_serial_device *serial, char c) { struct ra_sci_object *obj; const struct ra_sci_param *param; RT_ASSERT(serial != RT_NULL); obj = rt_container_of(serial, struct ra_sci_object, ubus); param = obj->param; RT_ASSERT(param != RT_NULL); sci_uart_instance_ctrl_t *p_ctrl = (sci_uart_instance_ctrl_t *)param->sci_ctrl; p_ctrl->p_reg->TDR = c; while ((p_ctrl->p_reg->SSR_b.TEND) == 0); return RT_EOK; } static int ra_uart_getc(struct rt_serial_device *serial) { return RT_EOK; } static rt_ssize_t ra_uart_transmit(struct rt_serial_device *serial, rt_uint8_t *buf, rt_size_t size, rt_uint32_t tx_flag) { RT_ASSERT(serial != RT_NULL); RT_ASSERT(buf != RT_NULL); return 0; } const struct rt_uart_ops sci_ops_uart = { .configure = ra_uart_configure, .control = ra_uart_control, .putc = ra_uart_putc, .getc = ra_uart_getc, .transmit = ra_uart_transmit, }; #else void sci_uart_irq_callback(uart_callback_args_t *p_args) { } #endif /** * @} */ /** * @brief SCI I2C * @defgroup SCI_I2C * @{ */ #ifdef BSP_USING_SCIn_I2C void sci_i2c_irq_callback(i2c_master_callback_args_t *p_args) { rt_interrupt_enter(); if (NULL != p_args) { /* capture callback event for validating the i2c transfer event*/ struct ra_sci_object *obj = (struct ra_sci_object *)p_args->p_context; uint32_t event = 0; RT_ASSERT(obj != RT_NULL); switch (p_args->event) { case I2C_MASTER_EVENT_ABORTED: event |= RA_SCI_EVENT_ABORTED; break; case I2C_MASTER_EVENT_RX_COMPLETE: event |= RA_SCI_EVENT_RX_COMPLETE; break; case I2C_MASTER_EVENT_TX_COMPLETE: event |= RA_SCI_EVENT_TX_COMPLETE; break; } rt_event_send(&obj->event, event); LOG_D("event:%x", p_args->event); } rt_interrupt_leave(); LOG_D("p_args:%p", p_args); } static rt_ssize_t ra_i2c_mst_xfer(struct rt_i2c_bus_device *bus, struct rt_i2c_msg msgs[], rt_uint32_t num) { rt_size_t i; RT_ASSERT(bus != RT_NULL); struct ra_sci_object *obj = rt_container_of(bus, struct ra_sci_object, ibus); const struct ra_sci_param *param = obj->param; i2c_master_ctrl_t *master_ctrl = (i2c_master_ctrl_t *)param->sci_ctrl; int err = FSP_SUCCESS; bool restart = false; for (i = 0; i < num; i++) { struct rt_i2c_msg *msg = &msgs[i]; if (msg->flags & RT_I2C_NO_STOP) { restart = true; } else { restart = false; } if (msg->flags & RT_I2C_ADDR_10BIT) { //LOG_E("10Bit not support"); //break; #ifdef SOC_SERIES_R7FA8M85 R_SCI_B_I2C_SlaveAddressSet(master_ctrl, msg->addr, I2C_MASTER_ADDR_MODE_10BIT); #else R_SCI_I2C_SlaveAddressSet(master_ctrl, msg->addr, I2C_MASTER_ADDR_MODE_10BIT); #endif } else { //master_ctrl->slave = msg->addr; #ifdef SOC_SERIES_R7FA8M85 R_SCI_B_I2C_SlaveAddressSet(master_ctrl, msg->addr, I2C_MASTER_ADDR_MODE_7BIT); #else R_SCI_I2C_SlaveAddressSet(master_ctrl, msg->addr, I2C_MASTER_ADDR_MODE_7BIT); #endif } if (msg->flags & RT_I2C_RD) { #ifdef SOC_SERIES_R7FA8M85 err = R_SCI_B_I2C_Read(master_ctrl, msg->buf, msg->len, restart); #else err = R_SCI_I2C_Read(master_ctrl, msg->buf, msg->len, restart); #endif } else { #ifdef SOC_SERIES_R7FA8M85 err = R_SCI_B_I2C_Write(master_ctrl, msg->buf, msg->len, restart); #else err = R_SCI_I2C_Write(master_ctrl, msg->buf, msg->len, restart); #endif } if (FSP_SUCCESS == err) { /* handle error */ err = ra_wait_complete(obj); if (RT_EOK != err) { //LOG_E("POWER_CTL reg I2C write failed,%d,%d", err, i); break; } } /* handle error */ else { /* Write API returns itself is not successful */ LOG_E("R_IIC_MASTER_Write/Read API failed,%d", i); break; } } return (rt_ssize_t)i; } const struct rt_i2c_bus_device_ops sci_ops_i2c = { .master_xfer = ra_i2c_mst_xfer, .slave_xfer = RT_NULL, .i2c_bus_control = RT_NULL }; #endif /** * @} */ /** * @brief SCI SPI * @defgroup SCI_SPI * @{ */ #ifdef BSP_USING_SCIn_SPI void sci_spi_irq_callback(spi_callback_args_t *p_args) { rt_interrupt_enter(); if (NULL != p_args) { /* capture callback event for validating the i2c transfer event*/ struct ra_sci_object *obj = (struct ra_sci_object *)p_args->p_context; uint32_t event = 0; switch (p_args->event) { case SPI_EVENT_ERR_MODE_FAULT : case SPI_EVENT_ERR_READ_OVERFLOW: case SPI_EVENT_ERR_PARITY : case SPI_EVENT_ERR_OVERRUN : case SPI_EVENT_ERR_FRAMING : case SPI_EVENT_ERR_MODE_UNDERRUN: event |= RA_SCI_EVENT_ERROR; break; case SPI_EVENT_TRANSFER_ABORTED : event |= RA_SCI_EVENT_ABORTED; break; case SPI_EVENT_TRANSFER_COMPLETE: event |= RA_SCI_EVENT_TX_COMPLETE; break; } rt_event_send(&obj->event, event); LOG_D("event:%x", p_args->event); } rt_interrupt_leave(); LOG_D("p_args:%p", p_args); } static spi_bit_width_t ra_width_shift(rt_uint8_t data_width) { spi_bit_width_t bit_width = SPI_BIT_WIDTH_8_BITS; if (data_width == 1) bit_width = SPI_BIT_WIDTH_8_BITS; else if (data_width == 2) bit_width = SPI_BIT_WIDTH_16_BITS; else if (data_width == 4) bit_width = SPI_BIT_WIDTH_32_BITS; return bit_width; } static rt_err_t ra_write_message(struct rt_spi_device *device, const void *send_buf, const rt_size_t len) { RT_ASSERT(device != NULL); RT_ASSERT(send_buf != NULL); RT_ASSERT(len > 0); rt_err_t err = RT_EOK; struct ra_sci_object *obj = rt_container_of(device->bus, struct ra_sci_object, sbus); const struct ra_sci_param *param = obj->param; spi_bit_width_t bit_width = ra_width_shift(obj->spi_cfg->data_width); /**< send msessage */ err = R_SCI_SPI_Write((spi_ctrl_t *)param->sci_ctrl, send_buf, len, bit_width); if (RT_EOK != err) { LOG_E("%s write failed. %d", param->bus_name, err); return -RT_ERROR; } /* Wait for SPI_EVENT_TRANSFER_COMPLETE callback event. */ ra_wait_complete(obj); return len; } static rt_err_t ra_read_message(struct rt_spi_device *device, void *recv_buf, const rt_size_t len) { RT_ASSERT(device != NULL); RT_ASSERT(recv_buf != NULL); RT_ASSERT(len > 0); rt_err_t err = RT_EOK; struct ra_sci_object *obj = rt_container_of(device->bus, struct ra_sci_object, sbus); const struct ra_sci_param *param = obj->param; spi_bit_width_t bit_width = ra_width_shift(obj->spi_cfg->data_width); /**< receive message */ err = R_SCI_SPI_Read((spi_ctrl_t *)param->sci_ctrl, recv_buf, len, bit_width); if (RT_EOK != err) { LOG_E("%s write failed. %d", param->bus_name, err); return -RT_ERROR; } /* Wait for SPI_EVENT_TRANSFER_COMPLETE callback event. */ ra_wait_complete(obj); return len; } static rt_err_t ra_write_read_message(struct rt_spi_device *device, struct rt_spi_message *message) { RT_ASSERT(device != NULL); RT_ASSERT(message != NULL); RT_ASSERT(message->length > 0); rt_err_t err = RT_EOK; struct ra_sci_object *obj = rt_container_of(device->bus, struct ra_sci_object, sbus); const struct ra_sci_param *param = obj->param; spi_bit_width_t bit_width = ra_width_shift(obj->spi_cfg->data_width); /**< write and receive message */ err = R_SCI_SPI_WriteRead((spi_ctrl_t *)param->sci_ctrl, message->send_buf, message->recv_buf, message->length, bit_width); if (RT_EOK != err) { LOG_E("%s write and read failed. %d", param->bus_name, err); return -RT_ERROR; } /* Wait for SPI_EVENT_TRANSFER_COMPLETE callback event. */ ra_wait_complete(obj); return message->length; } /**< init spi TODO : MSB does not support modification */ static rt_err_t ra_hw_spi_configure(struct rt_spi_device *device, struct rt_spi_configuration *configuration) { RT_ASSERT(device != NULL); RT_ASSERT(configuration != NULL); rt_err_t err = RT_EOK; struct ra_sci_object *obj = rt_container_of(device->bus, struct ra_sci_object, sbus); const struct ra_sci_param *param = obj->param; const spi_cfg_t *cfg = (const spi_cfg_t *)param->sci_cfg; /**< data_width : 1 -> 8 bits , 2 -> 16 bits, 4 -> 32 bits, default 32 bits*/ rt_uint8_t data_width = configuration->data_width / 8; RT_ASSERT(data_width == 1 || data_width == 2 || data_width == 4); configuration->data_width = configuration->data_width / 8; obj->spi_cfg = configuration; sci_spi_extended_cfg_t *cfg_ext = (sci_spi_extended_cfg_t *)cfg->p_extend; /**< Configure Select Line */ rt_pin_write(device->cs_pin, PIN_HIGH); /**< config bitrate */ R_SCI_SPI_CalculateBitrate(obj->spi_cfg->max_hz, &cfg_ext->clk_div, false); /**< init */ err = R_SCI_SPI_Open((spi_ctrl_t *)param->sci_ctrl, cfg); /* handle error */ if (err == FSP_ERR_IN_USE) { R_SCI_SPI_Close((spi_ctrl_t *)param->sci_ctrl); err = R_SCI_SPI_Open((spi_ctrl_t *)param->sci_ctrl, cfg); } if (RT_EOK != err) { LOG_E("%s init failed. %d", param->bus_name, err); return -RT_ERROR; } err = R_SCI_SPI_CallbackSet((spi_ctrl_t *)param->sci_ctrl, sci_spi_irq_callback, obj, NULL); if (FSP_SUCCESS != err) { LOG_E("R_SCI_I2C_CallbackSet API failed,%d", err); } return RT_EOK; } static rt_ssize_t ra_spixfer(struct rt_spi_device *device, struct rt_spi_message *message) { RT_ASSERT(device != RT_NULL); RT_ASSERT(device->bus != RT_NULL); RT_ASSERT(message != RT_NULL); rt_err_t err = RT_EOK; if (message->cs_take && !(device->config.mode & RT_SPI_NO_CS) && (device->cs_pin != PIN_NONE)) { if (device->config.mode & RT_SPI_CS_HIGH) rt_pin_write(device->cs_pin, PIN_HIGH); else rt_pin_write(device->cs_pin, PIN_LOW); } if (message->length > 0) { if (message->send_buf == RT_NULL && message->recv_buf != RT_NULL) { /**< receive message */ err = ra_read_message(device, (void *)message->recv_buf, (const rt_size_t)message->length); } else if (message->send_buf != RT_NULL && message->recv_buf == RT_NULL) { /**< send message */ err = ra_write_message(device, (const void *)message->send_buf, (const rt_size_t)message->length); } else if (message->send_buf != RT_NULL && message->recv_buf != RT_NULL) { /**< send and receive message */ err = ra_write_read_message(device, message); } } if (message->cs_release && !(device->config.mode & RT_SPI_NO_CS) && (device->cs_pin != PIN_NONE)) { if (device->config.mode & RT_SPI_CS_HIGH) rt_pin_write(device->cs_pin, PIN_LOW); else rt_pin_write(device->cs_pin, PIN_HIGH); } return err; } const struct rt_spi_ops sci_ops_spi = { .configure = ra_hw_spi_configure, .xfer = ra_spixfer, }; #endif /** * @} */ static int ra_hw_sci_init(void) { for (rt_uint8_t idx = 0; idx < RA_SCI_INDEX_MAX; idx++) { struct ra_sci_object *obj = &sci_obj[idx]; const struct ra_sci_param *param = &sci_param[idx]; obj->param = param; rt_err_t err; #ifdef BSP_USING_SCIn_SPI if ((uint32_t)param->ops == (uint32_t)&sci_ops_spi) { /**< register spi bus */ err = rt_spi_bus_register(&obj->sbus, param->bus_name, param->ops); if (RT_EOK != err) { LOG_E("bus %s register failed. %d", param->bus_name, err); return -RT_ERROR; } } else #endif #ifdef BSP_USING_SCIn_I2C if ((uint32_t)param->ops == (uint32_t)&sci_ops_i2c) { obj->ibus.ops = param->ops; obj->ibus.priv = 0; /* opening IIC master module */ #ifdef SOC_SERIES_R7FA8M85 err = R_SCI_B_I2C_Open((i2c_master_ctrl_t *)param->sci_ctrl, param->sci_cfg); #else err = R_SCI_I2C_Open((i2c_master_ctrl_t *)param->sci_ctrl, param->sci_cfg); #endif if (err != FSP_SUCCESS) { LOG_E("R_IIC_MASTER_Open API failed,%d", err); continue; } #ifdef SOC_SERIES_R7FA8M85 err = R_SCI_B_I2C_CallbackSet((i2c_master_ctrl_t *)param->sci_ctrl, sci_i2c_irq_callback, obj, NULL); #else err = R_SCI_I2C_CallbackSet((i2c_master_ctrl_t *)param->sci_ctrl, sci_i2c_irq_callback, obj, NULL); #endif /* handle error */ if (FSP_SUCCESS != err) { LOG_E("R_SCI_I2C_CallbackSet API failed,%d", err); continue; } err = rt_i2c_bus_device_register(&obj->ibus, param->bus_name); if (RT_EOK != err) { LOG_E("i2c bus %s register failed,%d", param->bus_name, err); continue; } } else #endif #ifdef BSP_USING_SCIn_UART if ((uint32_t)param->ops == (uint32_t)&sci_ops_uart) { if (rt_device_find(param->bus_name) != RT_NULL) { continue; } struct rt_serial_device *serial = &obj->ubus; obj->ubus.ops = param->ops; serial->config.rx_bufsz = uart_buff_size[bufsz_idx][0]; serial->config.tx_bufsz = uart_buff_size[bufsz_idx][1]; bufsz_idx ++; err = rt_hw_serial_register(serial, param->bus_name, RT_DEVICE_FLAG_RDWR, RT_NULL); if (RT_EOK != err) { LOG_E("uart %s register failed,%d", param->bus_name, err); continue; } } #endif { } if (RT_EOK != rt_event_init(&obj->event, param->bus_name, RT_IPC_FLAG_PRIO)) { LOG_E("sci event init fail!"); return -RT_ERROR; } } return RT_EOK; } INIT_BOARD_EXPORT(ra_hw_sci_init); #ifdef BSP_USING_SCIn_UART rt_weak int rt_hw_usart_init(void) { int bufsz_idx = 0; for (rt_uint8_t idx = 0; idx < RA_SCI_INDEX_MAX; idx++) { struct ra_sci_object *obj = &sci_obj[idx]; const struct ra_sci_param *param = &sci_param[idx]; obj->param = param; rt_err_t err; if ((uint32_t)param->ops == (uint32_t)&sci_ops_uart) { if (rt_device_find(param->bus_name) != RT_NULL) { continue; } struct rt_serial_device *serial = &obj->ubus; obj->ubus.ops = param->ops; serial->config.rx_bufsz = uart_buff_size[bufsz_idx][0]; serial->config.tx_bufsz = uart_buff_size[bufsz_idx][1]; bufsz_idx ++; err = rt_hw_serial_register(serial, param->bus_name, RT_DEVICE_FLAG_RDWR, RT_NULL); if (RT_EOK != err) { continue; } if (RT_EOK != rt_event_init(&obj->event, param->bus_name, RT_IPC_FLAG_PRIO)) { return -RT_ERROR; } } } return RT_EOK; } #endif /** * Attach the spi device to SPI bus, this function must be used after initialization. */ #ifdef BSP_USING_SCIn_SPI rt_err_t drv_sci_spi_device_attach(const char *bus_name, const char *device_name, rt_base_t cs_pin) { RT_ASSERT(bus_name != RT_NULL); RT_ASSERT(device_name != RT_NULL); rt_err_t result; struct rt_spi_device *spi_device; /* attach the device to spi bus*/ spi_device = (struct rt_spi_device *)rt_malloc(sizeof(struct rt_spi_device)); RT_ASSERT(spi_device != RT_NULL); result = rt_spi_bus_attach_device_cspin(spi_device, device_name, bus_name, cs_pin, RT_NULL); if (result != RT_EOK) { LOG_E("%s attach to %s faild, %d\n", device_name, bus_name, result); } LOG_D("%s attach to %s done", device_name, bus_name); return result; } #endif #endif /* BSP_USING_SCI */