/* * Copyright (c) 2006-2021, RT-Thread Development Team * * SPDX-License-Identifier: Apache-2.0 * * Change Logs: * Date Author Notes * 2021-06-01 KyleChan first version */ #include "board.h" #include "drv_usart_v2.h" #ifdef RT_USING_SERIAL_V2 //#define DRV_DEBUG #define DBG_TAG "drv.usart" #ifdef DRV_DEBUG #define DBG_LVL DBG_LOG #else #define DBG_LVL DBG_INFO #endif /* DRV_DEBUG */ #include #if !defined(BSP_USING_UART1) && !defined(BSP_USING_UART2) && !defined(BSP_USING_UART3) && \ !defined(BSP_USING_UART4) && !defined(BSP_USING_UART5) && !defined(BSP_USING_UART6) && \ !defined(BSP_USING_UART7) && !defined(BSP_USING_UART8) && !defined(BSP_USING_LPUART1) #error "Please define at least one BSP_USING_UARTx" /* this driver can be disabled at menuconfig -> RT-Thread Components -> Device Drivers */ #endif #ifdef RT_SERIAL_USING_DMA static void stm32_dma_config(struct rt_serial_device *serial, rt_ubase_t flag); #endif enum { #ifdef BSP_USING_UART1 UART1_INDEX, #endif #ifdef BSP_USING_UART2 UART2_INDEX, #endif #ifdef BSP_USING_UART3 UART3_INDEX, #endif #ifdef BSP_USING_UART4 UART4_INDEX, #endif #ifdef BSP_USING_UART5 UART5_INDEX, #endif #ifdef BSP_USING_UART6 UART6_INDEX, #endif #ifdef BSP_USING_UART7 UART7_INDEX, #endif #ifdef BSP_USING_UART8 UART8_INDEX, #endif #ifdef BSP_USING_LPUART1 LPUART1_INDEX, #endif }; static struct stm32_uart_config uart_config[] = { #ifdef BSP_USING_UART1 UART1_CONFIG, #endif #ifdef BSP_USING_UART2 UART2_CONFIG, #endif #ifdef BSP_USING_UART3 UART3_CONFIG, #endif #ifdef BSP_USING_UART4 UART4_CONFIG, #endif #ifdef BSP_USING_UART5 UART5_CONFIG, #endif #ifdef BSP_USING_UART6 UART6_CONFIG, #endif #ifdef BSP_USING_UART7 UART7_CONFIG, #endif #ifdef BSP_USING_UART8 UART8_CONFIG, #endif #ifdef BSP_USING_LPUART1 LPUART1_CONFIG, #endif }; static struct stm32_uart uart_obj[sizeof(uart_config) / sizeof(uart_config[0])] = {0}; static rt_err_t stm32_configure(struct rt_serial_device *serial, struct serial_configure *cfg) { struct stm32_uart *uart; RT_ASSERT(serial != RT_NULL); RT_ASSERT(cfg != RT_NULL); uart = rt_container_of(serial, struct stm32_uart, serial); uart->handle.Instance = uart->config->Instance; uart->handle.Init.BaudRate = cfg->baud_rate; uart->handle.Init.Mode = UART_MODE_TX_RX; uart->handle.Init.OverSampling = UART_OVERSAMPLING_16; switch (cfg->data_bits) { case DATA_BITS_8: if (cfg->parity == PARITY_ODD || cfg->parity == PARITY_EVEN) uart->handle.Init.WordLength = UART_WORDLENGTH_9B; else uart->handle.Init.WordLength = UART_WORDLENGTH_8B; break; case DATA_BITS_9: uart->handle.Init.WordLength = UART_WORDLENGTH_9B; break; default: uart->handle.Init.WordLength = UART_WORDLENGTH_8B; break; } switch (cfg->stop_bits) { case STOP_BITS_1: uart->handle.Init.StopBits = UART_STOPBITS_1; break; case STOP_BITS_2: uart->handle.Init.StopBits = UART_STOPBITS_2; break; default: uart->handle.Init.StopBits = UART_STOPBITS_1; break; } switch (cfg->parity) { case PARITY_NONE: uart->handle.Init.Parity = UART_PARITY_NONE; break; case PARITY_ODD: uart->handle.Init.Parity = UART_PARITY_ODD; break; case PARITY_EVEN: uart->handle.Init.Parity = UART_PARITY_EVEN; break; default: uart->handle.Init.Parity = UART_PARITY_NONE; break; } switch (cfg->flowcontrol) { case RT_SERIAL_FLOWCONTROL_NONE: uart->handle.Init.HwFlowCtl = UART_HWCONTROL_NONE; break; case RT_SERIAL_FLOWCONTROL_CTSRTS: uart->handle.Init.HwFlowCtl = UART_HWCONTROL_RTS_CTS; break; default: uart->handle.Init.HwFlowCtl = UART_HWCONTROL_NONE; break; } #ifdef RT_SERIAL_USING_DMA uart->dma_rx.remaining_cnt = serial->config.rx_bufsz; #endif if (HAL_UART_Init(&uart->handle) != HAL_OK) { return -RT_ERROR; } return RT_EOK; } static rt_err_t stm32_control(struct rt_serial_device *serial, int cmd, void *arg) { struct stm32_uart *uart; rt_ubase_t ctrl_arg = (rt_ubase_t)arg; RT_ASSERT(serial != RT_NULL); uart = rt_container_of(serial, struct stm32_uart, serial); if(ctrl_arg & (RT_DEVICE_FLAG_RX_BLOCKING | RT_DEVICE_FLAG_RX_NON_BLOCKING)) { if (uart->uart_dma_flag & RT_DEVICE_FLAG_DMA_RX) ctrl_arg = RT_DEVICE_FLAG_DMA_RX; else ctrl_arg = RT_DEVICE_FLAG_INT_RX; } else if(ctrl_arg & (RT_DEVICE_FLAG_TX_BLOCKING | RT_DEVICE_FLAG_TX_NON_BLOCKING)) { if (uart->uart_dma_flag & RT_DEVICE_FLAG_DMA_TX) ctrl_arg = RT_DEVICE_FLAG_DMA_TX; else ctrl_arg = RT_DEVICE_FLAG_INT_TX; } switch (cmd) { /* disable interrupt */ case RT_DEVICE_CTRL_CLR_INT: NVIC_DisableIRQ(uart->config->irq_type); if (ctrl_arg == RT_DEVICE_FLAG_INT_RX) __HAL_UART_DISABLE_IT(&(uart->handle), UART_IT_RXNE); else if (ctrl_arg == RT_DEVICE_FLAG_INT_TX) __HAL_UART_DISABLE_IT(&(uart->handle), UART_IT_TXE); #ifdef RT_SERIAL_USING_DMA else if (ctrl_arg == RT_DEVICE_FLAG_DMA_RX) { __HAL_UART_DISABLE_IT(&(uart->handle), UART_IT_RXNE); HAL_NVIC_DisableIRQ(uart->config->dma_rx->dma_irq); if (HAL_DMA_Abort(&(uart->dma_rx.handle)) != HAL_OK) { RT_ASSERT(0); } if (HAL_DMA_DeInit(&(uart->dma_rx.handle)) != HAL_OK) { RT_ASSERT(0); } } else if(ctrl_arg == RT_DEVICE_FLAG_DMA_TX) { __HAL_UART_DISABLE_IT(&(uart->handle), UART_IT_TC); HAL_NVIC_DisableIRQ(uart->config->dma_tx->dma_irq); if (HAL_DMA_DeInit(&(uart->dma_tx.handle)) != HAL_OK) { RT_ASSERT(0); } } #endif break; case RT_DEVICE_CTRL_SET_INT: HAL_NVIC_SetPriority(uart->config->irq_type, 1, 0); HAL_NVIC_EnableIRQ(uart->config->irq_type); if (ctrl_arg == RT_DEVICE_FLAG_INT_RX) __HAL_UART_ENABLE_IT(&(uart->handle), UART_IT_RXNE); else if (ctrl_arg == RT_DEVICE_FLAG_INT_TX) __HAL_UART_ENABLE_IT(&(uart->handle), UART_IT_TXE); break; case RT_DEVICE_CTRL_CONFIG: if (ctrl_arg & (RT_DEVICE_FLAG_DMA_RX | RT_DEVICE_FLAG_DMA_TX)) { #ifdef RT_SERIAL_USING_DMA stm32_dma_config(serial, ctrl_arg); #endif } else stm32_control(serial, RT_DEVICE_CTRL_SET_INT, (void *)ctrl_arg); break; case RT_DEVICE_CHECK_OPTMODE: { if (ctrl_arg & RT_DEVICE_FLAG_DMA_TX) return RT_SERIAL_TX_BLOCKING_NO_BUFFER; else return RT_SERIAL_TX_BLOCKING_BUFFER; } case RT_DEVICE_CTRL_CLOSE: if (HAL_UART_DeInit(&(uart->handle)) != HAL_OK ) { RT_ASSERT(0) } break; } return RT_EOK; } static int stm32_putc(struct rt_serial_device *serial, char c) { struct stm32_uart *uart; RT_ASSERT(serial != RT_NULL); uart = rt_container_of(serial, struct stm32_uart, serial); while (__HAL_UART_GET_FLAG(&(uart->handle), UART_FLAG_TC) == RESET); UART_INSTANCE_CLEAR_FUNCTION(&(uart->handle), UART_FLAG_TC); UART_SET_TDR(&uart->handle, c); return 1; } rt_uint32_t stm32_uart_get_mask(rt_uint32_t word_length, rt_uint32_t parity) { rt_uint32_t mask; if (word_length == UART_WORDLENGTH_8B) { if (parity == UART_PARITY_NONE) { mask = 0x00FFU ; } else { mask = 0x007FU ; } } #ifdef UART_WORDLENGTH_9B else if (word_length == UART_WORDLENGTH_9B) { if (parity == UART_PARITY_NONE) { mask = 0x01FFU ; } else { mask = 0x00FFU ; } } #endif #ifdef UART_WORDLENGTH_7B else if (word_length == UART_WORDLENGTH_7B) { if (parity == UART_PARITY_NONE) { mask = 0x007FU ; } else { mask = 0x003FU ; } } else { mask = 0x0000U; } #endif return mask; } static int stm32_getc(struct rt_serial_device *serial) { int ch; struct stm32_uart *uart; RT_ASSERT(serial != RT_NULL); uart = rt_container_of(serial, struct stm32_uart, serial); ch = -1; if (__HAL_UART_GET_FLAG(&(uart->handle), UART_FLAG_RXNE) != RESET) ch = UART_GET_RDR(&uart->handle, stm32_uart_get_mask(uart->handle.Init.WordLength, uart->handle.Init.Parity)); return ch; } static rt_size_t stm32_transmit(struct rt_serial_device *serial, rt_uint8_t *buf, rt_size_t size, rt_uint32_t tx_flag) { struct stm32_uart *uart; RT_ASSERT(serial != RT_NULL); RT_ASSERT(buf != RT_NULL); uart = rt_container_of(serial, struct stm32_uart, serial); if (uart->uart_dma_flag & RT_DEVICE_FLAG_DMA_TX) { HAL_UART_Transmit_DMA(&uart->handle, buf, size); return size; } stm32_control(serial, RT_DEVICE_CTRL_SET_INT, (void *)tx_flag); return size; } #ifdef RT_SERIAL_USING_DMA static void dma_recv_isr(struct rt_serial_device *serial, rt_uint8_t isr_flag) { struct stm32_uart *uart; rt_size_t recv_len, counter; RT_ASSERT(serial != RT_NULL); uart = rt_container_of(serial, struct stm32_uart, serial); recv_len = 0; counter = __HAL_DMA_GET_COUNTER(&(uart->dma_rx.handle)); if (counter <= uart->dma_rx.remaining_cnt) recv_len = uart->dma_rx.remaining_cnt - counter; else recv_len = serial->config.rx_bufsz + uart->dma_rx.remaining_cnt - counter; if (recv_len) { #if defined (__DCACHE_PRESENT) && (__DCACHE_PRESENT == 1U) struct rt_serial_rx_fifo *rx_fifo = (struct rt_serial_rx_fifo *) serial->serial_rx; SCB_InvalidateDCache_by_Addr((uint32_t *)rx_fifo->buffer, serial->config.rx_bufsz); #endif uart->dma_rx.remaining_cnt = counter; rt_hw_serial_isr(serial, RT_SERIAL_EVENT_RX_DMADONE | (recv_len << 8)); } } #endif /* RT_SERIAL_USING_DMA */ /** * Uart common interrupt process. This need add to uart ISR. * * @param serial serial device */ static void uart_isr(struct rt_serial_device *serial) { struct stm32_uart *uart; RT_ASSERT(serial != RT_NULL); uart = rt_container_of(serial, struct stm32_uart, serial); /* If the Read data register is not empty and the RXNE interrupt is enabled (RDR) */ if ((__HAL_UART_GET_FLAG(&(uart->handle), UART_FLAG_RXNE) != RESET) && (__HAL_UART_GET_IT_SOURCE(&(uart->handle), UART_IT_RXNE) != RESET)) { 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), UART_GET_RDR(&uart->handle, stm32_uart_get_mask(uart->handle.Init.WordLength, uart->handle.Init.Parity))); rt_hw_serial_isr(serial, RT_SERIAL_EVENT_RX_IND); } /* If the Transmit data register is empty and the TXE interrupt enable is enabled (TDR) */ else if ((__HAL_UART_GET_FLAG(&(uart->handle), UART_FLAG_TXE) != RESET) && (__HAL_UART_GET_IT_SOURCE(&(uart->handle), UART_IT_TXE)) != RESET) { struct rt_serial_tx_fifo *tx_fifo; tx_fifo = (struct rt_serial_tx_fifo *) serial->serial_tx; RT_ASSERT(tx_fifo != RT_NULL); rt_uint8_t put_char = 0; if (rt_ringbuffer_getchar(&(tx_fifo->rb), &put_char)) { UART_SET_TDR(&uart->handle, put_char); } else { __HAL_UART_DISABLE_IT(&(uart->handle), UART_IT_TXE); __HAL_UART_ENABLE_IT(&(uart->handle), UART_IT_TC); } } else if (__HAL_UART_GET_FLAG(&(uart->handle), UART_FLAG_TC) && (__HAL_UART_GET_IT_SOURCE(&(uart->handle), UART_IT_TC) != RESET)) { if (uart->uart_dma_flag & RT_DEVICE_FLAG_DMA_TX) { /* The HAL_UART_TxCpltCallback will be triggered */ HAL_UART_IRQHandler(&(uart->handle)); } else { /* Transmission complete interrupt disable ( CR1 Register) */ __HAL_UART_DISABLE_IT(&(uart->handle), UART_IT_TC); rt_hw_serial_isr(serial, RT_SERIAL_EVENT_TX_DONE); } /* Clear Transmission complete interrupt flag ( ISR Register ) */ UART_INSTANCE_CLEAR_FUNCTION(&(uart->handle), UART_FLAG_TC); } #ifdef RT_SERIAL_USING_DMA else if ((uart->uart_dma_flag) && (__HAL_UART_GET_FLAG(&(uart->handle), UART_FLAG_IDLE) != RESET) && (__HAL_UART_GET_IT_SOURCE(&(uart->handle), UART_IT_IDLE) != RESET)) { dma_recv_isr(serial, UART_RX_DMA_IT_IDLE_FLAG); __HAL_UART_CLEAR_IDLEFLAG(&uart->handle); } #endif else { if (__HAL_UART_GET_FLAG(&(uart->handle), UART_FLAG_ORE) != RESET) { LOG_E("(%s) serial device Overrun error!", serial->parent.parent.name); __HAL_UART_CLEAR_OREFLAG(&uart->handle); } if (__HAL_UART_GET_FLAG(&(uart->handle), UART_FLAG_NE) != RESET) { __HAL_UART_CLEAR_NEFLAG(&uart->handle); } if (__HAL_UART_GET_FLAG(&(uart->handle), UART_FLAG_FE) != RESET) { __HAL_UART_CLEAR_FEFLAG(&uart->handle); } if (__HAL_UART_GET_FLAG(&(uart->handle), UART_FLAG_PE) != RESET) { __HAL_UART_CLEAR_PEFLAG(&uart->handle); } #if !defined(SOC_SERIES_STM32L4) && !defined(SOC_SERIES_STM32WL) && !defined(SOC_SERIES_STM32F7) && !defined(SOC_SERIES_STM32F0) \ && !defined(SOC_SERIES_STM32L0) && !defined(SOC_SERIES_STM32G0) && !defined(SOC_SERIES_STM32H7) \ && !defined(SOC_SERIES_STM32G4) && !defined(SOC_SERIES_STM32MP1) && !defined(SOC_SERIES_STM32WB) if (__HAL_UART_GET_FLAG(&(uart->handle), UART_FLAG_LBD) != RESET) { UART_INSTANCE_CLEAR_FUNCTION(&(uart->handle), UART_FLAG_LBD); } #endif if (__HAL_UART_GET_FLAG(&(uart->handle), UART_FLAG_CTS) != RESET) { UART_INSTANCE_CLEAR_FUNCTION(&(uart->handle), UART_FLAG_CTS); } if (__HAL_UART_GET_FLAG(&(uart->handle), UART_FLAG_TXE) != RESET) { UART_INSTANCE_CLEAR_FUNCTION(&(uart->handle), UART_FLAG_TXE); } if (__HAL_UART_GET_FLAG(&(uart->handle), UART_FLAG_TC) != RESET) { UART_INSTANCE_CLEAR_FUNCTION(&(uart->handle), UART_FLAG_TC); } if (__HAL_UART_GET_FLAG(&(uart->handle), UART_FLAG_RXNE) != RESET) { UART_INSTANCE_CLEAR_FUNCTION(&(uart->handle), UART_FLAG_RXNE); } } } #if defined(BSP_USING_UART1) void USART1_IRQHandler(void) { /* enter interrupt */ rt_interrupt_enter(); uart_isr(&(uart_obj[UART1_INDEX].serial)); /* leave interrupt */ rt_interrupt_leave(); } #if defined(RT_SERIAL_USING_DMA) && defined(BSP_UART1_RX_USING_DMA) void UART1_DMA_RX_IRQHandler(void) { /* enter interrupt */ rt_interrupt_enter(); HAL_DMA_IRQHandler(&uart_obj[UART1_INDEX].dma_rx.handle); /* leave interrupt */ rt_interrupt_leave(); } #endif /* defined(RT_SERIAL_USING_DMA) && defined(BSP_UART1_RX_USING_DMA) */ #if defined(RT_SERIAL_USING_DMA) && defined(BSP_UART1_TX_USING_DMA) void UART1_DMA_TX_IRQHandler(void) { /* enter interrupt */ rt_interrupt_enter(); HAL_DMA_IRQHandler(&uart_obj[UART1_INDEX].dma_tx.handle); /* leave interrupt */ rt_interrupt_leave(); } #endif /* defined(RT_SERIAL_USING_DMA) && defined(BSP_UART1_TX_USING_DMA) */ #endif /* BSP_USING_UART1 */ #if defined(BSP_USING_UART2) void USART2_IRQHandler(void) { /* enter interrupt */ rt_interrupt_enter(); uart_isr(&(uart_obj[UART2_INDEX].serial)); /* leave interrupt */ rt_interrupt_leave(); } #if defined(RT_SERIAL_USING_DMA) && defined(BSP_UART2_RX_USING_DMA) void UART2_DMA_RX_IRQHandler(void) { /* enter interrupt */ rt_interrupt_enter(); HAL_DMA_IRQHandler(&uart_obj[UART2_INDEX].dma_rx.handle); /* leave interrupt */ rt_interrupt_leave(); } #endif /* defined(RT_SERIAL_USING_DMA) && defined(BSP_UART2_RX_USING_DMA) */ #if defined(RT_SERIAL_USING_DMA) && defined(BSP_UART2_TX_USING_DMA) void UART2_DMA_TX_IRQHandler(void) { /* enter interrupt */ rt_interrupt_enter(); HAL_DMA_IRQHandler(&uart_obj[UART2_INDEX].dma_tx.handle); /* leave interrupt */ rt_interrupt_leave(); } #endif /* defined(RT_SERIAL_USING_DMA) && defined(BSP_UART2_TX_USING_DMA) */ #endif /* BSP_USING_UART2 */ #if defined(BSP_USING_UART3) void USART3_IRQHandler(void) { /* enter interrupt */ rt_interrupt_enter(); uart_isr(&(uart_obj[UART3_INDEX].serial)); /* leave interrupt */ rt_interrupt_leave(); } #if defined(RT_SERIAL_USING_DMA) && defined(BSP_UART3_RX_USING_DMA) void UART3_DMA_RX_IRQHandler(void) { /* enter interrupt */ rt_interrupt_enter(); HAL_DMA_IRQHandler(&uart_obj[UART3_INDEX].dma_rx.handle); /* leave interrupt */ rt_interrupt_leave(); } #endif /* defined(BSP_UART_USING_DMA_RX) && defined(BSP_UART3_RX_USING_DMA) */ #if defined(RT_SERIAL_USING_DMA) && defined(BSP_UART3_TX_USING_DMA) void UART3_DMA_TX_IRQHandler(void) { /* enter interrupt */ rt_interrupt_enter(); HAL_DMA_IRQHandler(&uart_obj[UART3_INDEX].dma_tx.handle); /* leave interrupt */ rt_interrupt_leave(); } #endif /* defined(BSP_UART_USING_DMA_TX) && defined(BSP_UART3_TX_USING_DMA) */ #endif /* BSP_USING_UART3*/ #if defined(BSP_USING_UART4) void UART4_IRQHandler(void) { /* enter interrupt */ rt_interrupt_enter(); uart_isr(&(uart_obj[UART4_INDEX].serial)); /* leave interrupt */ rt_interrupt_leave(); } #if defined(RT_SERIAL_USING_DMA) && defined(BSP_UART4_RX_USING_DMA) void UART4_DMA_RX_IRQHandler(void) { /* enter interrupt */ rt_interrupt_enter(); HAL_DMA_IRQHandler(&uart_obj[UART4_INDEX].dma_rx.handle); /* leave interrupt */ rt_interrupt_leave(); } #endif /* defined(BSP_UART_USING_DMA_RX) && defined(BSP_UART4_RX_USING_DMA) */ #if defined(RT_SERIAL_USING_DMA) && defined(BSP_UART4_TX_USING_DMA) void UART4_DMA_TX_IRQHandler(void) { /* enter interrupt */ rt_interrupt_enter(); HAL_DMA_IRQHandler(&uart_obj[UART4_INDEX].dma_tx.handle); /* leave interrupt */ rt_interrupt_leave(); } #endif /* defined(BSP_UART_USING_DMA_TX) && defined(BSP_UART4_TX_USING_DMA) */ #endif /* BSP_USING_UART4*/ #if defined(BSP_USING_UART5) void UART5_IRQHandler(void) { /* enter interrupt */ rt_interrupt_enter(); uart_isr(&(uart_obj[UART5_INDEX].serial)); /* leave interrupt */ rt_interrupt_leave(); } #if defined(RT_SERIAL_USING_DMA) && defined(BSP_UART5_RX_USING_DMA) void UART5_DMA_RX_IRQHandler(void) { /* enter interrupt */ rt_interrupt_enter(); HAL_DMA_IRQHandler(&uart_obj[UART5_INDEX].dma_rx.handle); /* leave interrupt */ rt_interrupt_leave(); } #endif /* defined(RT_SERIAL_USING_DMA) && defined(BSP_UART5_RX_USING_DMA) */ #if defined(RT_SERIAL_USING_DMA) && defined(BSP_UART5_TX_USING_DMA) void UART5_DMA_TX_IRQHandler(void) { /* enter interrupt */ rt_interrupt_enter(); HAL_DMA_IRQHandler(&uart_obj[UART5_INDEX].dma_tx.handle); /* leave interrupt */ rt_interrupt_leave(); } #endif /* defined(RT_SERIAL_USING_DMA) && defined(BSP_UART5_TX_USING_DMA) */ #endif /* BSP_USING_UART5*/ #if defined(BSP_USING_UART6) void USART6_IRQHandler(void) { /* enter interrupt */ rt_interrupt_enter(); uart_isr(&(uart_obj[UART6_INDEX].serial)); /* leave interrupt */ rt_interrupt_leave(); } #if defined(RT_SERIAL_USING_DMA) && defined(BSP_UART6_RX_USING_DMA) void UART6_DMA_RX_IRQHandler(void) { /* enter interrupt */ rt_interrupt_enter(); HAL_DMA_IRQHandler(&uart_obj[UART6_INDEX].dma_rx.handle); /* leave interrupt */ rt_interrupt_leave(); } #endif /* defined(RT_SERIAL_USING_DMA) && defined(BSP_UART6_RX_USING_DMA) */ #if defined(RT_SERIAL_USING_DMA) && defined(BSP_UART6_TX_USING_DMA) void UART6_DMA_TX_IRQHandler(void) { /* enter interrupt */ rt_interrupt_enter(); HAL_DMA_IRQHandler(&uart_obj[UART6_INDEX].dma_tx.handle); /* leave interrupt */ rt_interrupt_leave(); } #endif /* defined(RT_SERIAL_USING_DMA) && defined(BSP_UART6_TX_USING_DMA) */ #endif /* BSP_USING_UART6*/ #if defined(BSP_USING_UART7) void UART7_IRQHandler(void) { /* enter interrupt */ rt_interrupt_enter(); uart_isr(&(uart_obj[UART7_INDEX].serial)); /* leave interrupt */ rt_interrupt_leave(); } #if defined(RT_SERIAL_USING_DMA) && defined(BSP_UART7_RX_USING_DMA) void UART7_DMA_RX_IRQHandler(void) { /* enter interrupt */ rt_interrupt_enter(); HAL_DMA_IRQHandler(&uart_obj[UART7_INDEX].dma_rx.handle); /* leave interrupt */ rt_interrupt_leave(); } #endif /* defined(RT_SERIAL_USING_DMA) && defined(BSP_UART7_RX_USING_DMA) */ #if defined(RT_SERIAL_USING_DMA) && defined(BSP_UART7_TX_USING_DMA) void UART7_DMA_TX_IRQHandler(void) { /* enter interrupt */ rt_interrupt_enter(); HAL_DMA_IRQHandler(&uart_obj[UART7_INDEX].dma_tx.handle); /* leave interrupt */ rt_interrupt_leave(); } #endif /* defined(RT_SERIAL_USING_DMA) && defined(BSP_UART7_TX_USING_DMA) */ #endif /* BSP_USING_UART7*/ #if defined(BSP_USING_UART8) void UART8_IRQHandler(void) { /* enter interrupt */ rt_interrupt_enter(); uart_isr(&(uart_obj[UART8_INDEX].serial)); /* leave interrupt */ rt_interrupt_leave(); } #if defined(RT_SERIAL_USING_DMA) && defined(BSP_UART8_RX_USING_DMA) void UART8_DMA_RX_IRQHandler(void) { /* enter interrupt */ rt_interrupt_enter(); HAL_DMA_IRQHandler(&uart_obj[UART8_INDEX].dma_rx.handle); /* leave interrupt */ rt_interrupt_leave(); } #endif /* defined(RT_SERIAL_USING_DMA) && defined(BSP_UART8_RX_USING_DMA) */ #if defined(RT_SERIAL_USING_DMA) && defined(BSP_UART8_TX_USING_DMA) void UART8_DMA_TX_IRQHandler(void) { /* enter interrupt */ rt_interrupt_enter(); HAL_DMA_IRQHandler(&uart_obj[UART8_INDEX].dma_tx.handle); /* leave interrupt */ rt_interrupt_leave(); } #endif /* defined(RT_SERIAL_USING_DMA) && defined(BSP_UART8_TX_USING_DMA) */ #endif /* BSP_USING_UART8*/ #if defined(BSP_USING_LPUART1) void LPUART1_IRQHandler(void) { /* enter interrupt */ rt_interrupt_enter(); uart_isr(&(uart_obj[LPUART1_INDEX].serial)); /* leave interrupt */ rt_interrupt_leave(); } #if defined(RT_SERIAL_USING_DMA) && defined(BSP_LPUART1_RX_USING_DMA) void LPUART1_DMA_RX_IRQHandler(void) { /* enter interrupt */ rt_interrupt_enter(); HAL_DMA_IRQHandler(&uart_obj[LPUART1_INDEX].dma_rx.handle); /* leave interrupt */ rt_interrupt_leave(); } #endif /* defined(RT_SERIAL_USING_DMA) && defined(BSP_LPUART1_RX_USING_DMA) */ #endif /* BSP_USING_LPUART1*/ static void stm32_uart_get_config(void) { struct serial_configure config = RT_SERIAL_CONFIG_DEFAULT; #ifdef BSP_USING_UART1 uart_obj[UART1_INDEX].serial.config = config; uart_obj[UART1_INDEX].uart_dma_flag = 0; uart_obj[UART1_INDEX].serial.config.rx_bufsz = BSP_UART1_RX_BUFSIZE; uart_obj[UART1_INDEX].serial.config.tx_bufsz = BSP_UART1_TX_BUFSIZE; #ifdef BSP_UART1_RX_USING_DMA uart_obj[UART1_INDEX].uart_dma_flag |= RT_DEVICE_FLAG_DMA_RX; static struct dma_config uart1_dma_rx = UART1_DMA_RX_CONFIG; uart_config[UART1_INDEX].dma_rx = &uart1_dma_rx; #endif #ifdef BSP_UART1_TX_USING_DMA uart_obj[UART1_INDEX].uart_dma_flag |= RT_DEVICE_FLAG_DMA_TX; static struct dma_config uart1_dma_tx = UART1_DMA_TX_CONFIG; uart_config[UART1_INDEX].dma_tx = &uart1_dma_tx; #endif #endif #ifdef BSP_USING_UART2 uart_obj[UART2_INDEX].serial.config = config; uart_obj[UART2_INDEX].uart_dma_flag = 0; uart_obj[UART2_INDEX].serial.config.rx_bufsz = BSP_UART2_RX_BUFSIZE; uart_obj[UART2_INDEX].serial.config.tx_bufsz = BSP_UART2_TX_BUFSIZE; #ifdef BSP_UART2_RX_USING_DMA uart_obj[UART2_INDEX].uart_dma_flag |= RT_DEVICE_FLAG_DMA_RX; static struct dma_config uart2_dma_rx = UART2_DMA_RX_CONFIG; uart_config[UART2_INDEX].dma_rx = &uart2_dma_rx; #endif #ifdef BSP_UART2_TX_USING_DMA uart_obj[UART2_INDEX].uart_dma_flag |= RT_DEVICE_FLAG_DMA_TX; static struct dma_config uart2_dma_tx = UART2_DMA_TX_CONFIG; uart_config[UART2_INDEX].dma_tx = &uart2_dma_tx; #endif #endif #ifdef BSP_USING_UART3 uart_obj[UART3_INDEX].serial.config = config; uart_obj[UART3_INDEX].uart_dma_flag = 0; uart_obj[UART3_INDEX].serial.config.rx_bufsz = BSP_UART3_RX_BUFSIZE; uart_obj[UART3_INDEX].serial.config.tx_bufsz = BSP_UART3_TX_BUFSIZE; #ifdef BSP_UART3_RX_USING_DMA uart_obj[UART3_INDEX].uart_dma_flag |= RT_DEVICE_FLAG_DMA_RX; static struct dma_config uart3_dma_rx = UART3_DMA_RX_CONFIG; uart_config[UART3_INDEX].dma_rx = &uart3_dma_rx; #endif #ifdef BSP_UART3_TX_USING_DMA uart_obj[UART3_INDEX].uart_dma_flag |= RT_DEVICE_FLAG_DMA_TX; static struct dma_config uart3_dma_tx = UART3_DMA_TX_CONFIG; uart_config[UART3_INDEX].dma_tx = &uart3_dma_tx; #endif #endif #ifdef BSP_USING_UART4 uart_obj[UART4_INDEX].serial.config = config; uart_obj[UART4_INDEX].uart_dma_flag = 0; uart_obj[UART4_INDEX].serial.config.rx_bufsz = BSP_UART4_RX_BUFSIZE; uart_obj[UART4_INDEX].serial.config.tx_bufsz = BSP_UART4_TX_BUFSIZE; #ifdef BSP_UART4_RX_USING_DMA uart_obj[UART4_INDEX].uart_dma_flag |= RT_DEVICE_FLAG_DMA_RX; static struct dma_config uart4_dma_rx = UART4_DMA_RX_CONFIG; uart_config[UART4_INDEX].dma_rx = &uart4_dma_rx; #endif #ifdef BSP_UART4_TX_USING_DMA uart_obj[UART4_INDEX].uart_dma_flag |= RT_DEVICE_FLAG_DMA_TX; static struct dma_config uart4_dma_tx = UART4_DMA_TX_CONFIG; uart_config[UART4_INDEX].dma_tx = &uart4_dma_tx; #endif #ifdef BSP_USING_UART5 uart_obj[UART5_INDEX].serial.config = config; uart_obj[UART5_INDEX].uart_dma_flag = 0; uart_obj[UART5_INDEX].serial.config.rx_bufsz = BSP_UART5_RX_BUFSIZE; uart_obj[UART5_INDEX].serial.config.tx_bufsz = BSP_UART5_TX_BUFSIZE; #ifdef BSP_UART5_RX_USING_DMA uart_obj[UART5_INDEX].uart_dma_flag |= RT_DEVICE_FLAG_DMA_RX; static struct dma_config uart5_dma_rx = UART5_DMA_RX_CONFIG; uart_config[UART5_INDEX].dma_rx = &uart5_dma_rx; #endif #ifdef BSP_UART5_TX_USING_DMA uart_obj[UART5_INDEX].uart_dma_flag |= RT_DEVICE_FLAG_DMA_TX; static struct dma_config uart5_dma_tx = UART5_DMA_TX_CONFIG; uart_config[UART5_INDEX].dma_tx = &uart5_dma_tx; #endif #endif #endif } #ifdef RT_SERIAL_USING_DMA static void stm32_dma_config(struct rt_serial_device *serial, rt_ubase_t flag) { struct rt_serial_rx_fifo *rx_fifo; DMA_HandleTypeDef *DMA_Handle; struct dma_config *dma_config; struct stm32_uart *uart; RT_ASSERT(serial != RT_NULL); RT_ASSERT(flag == RT_DEVICE_FLAG_DMA_TX || flag == RT_DEVICE_FLAG_DMA_RX); uart = rt_container_of(serial, struct stm32_uart, serial); if (RT_DEVICE_FLAG_DMA_RX == flag) { DMA_Handle = &uart->dma_rx.handle; dma_config = uart->config->dma_rx; } else /* RT_DEVICE_FLAG_DMA_TX == flag */ { DMA_Handle = &uart->dma_tx.handle; dma_config = uart->config->dma_tx; } LOG_D("%s dma config start", uart->config->name); { rt_uint32_t tmpreg = 0x00U; #if defined(SOC_SERIES_STM32F1) || defined(SOC_SERIES_STM32F0) || defined(SOC_SERIES_STM32G0) \ || defined(SOC_SERIES_STM32L0) /* enable DMA clock && Delay after an RCC peripheral clock enabling*/ SET_BIT(RCC->AHBENR, dma_config->dma_rcc); tmpreg = READ_BIT(RCC->AHBENR, dma_config->dma_rcc); #elif defined(SOC_SERIES_STM32F4) || defined(SOC_SERIES_STM32F7) || defined(SOC_SERIES_STM32L4) || defined(SOC_SERIES_STM32WL) \ || defined(SOC_SERIES_STM32G4)|| defined(SOC_SERIES_STM32H7) || defined(SOC_SERIES_STM32WB) /* enable DMA clock && Delay after an RCC peripheral clock enabling*/ SET_BIT(RCC->AHB1ENR, dma_config->dma_rcc); tmpreg = READ_BIT(RCC->AHB1ENR, dma_config->dma_rcc); #elif defined(SOC_SERIES_STM32MP1) /* enable DMA clock && Delay after an RCC peripheral clock enabling*/ SET_BIT(RCC->MP_AHB2ENSETR, dma_config->dma_rcc); tmpreg = READ_BIT(RCC->MP_AHB2ENSETR, dma_config->dma_rcc); #endif #if defined(DMAMUX1) && (defined(SOC_SERIES_STM32L4) || defined(SOC_SERIES_STM32WL) || defined(SOC_SERIES_STM32G4) || defined(SOC_SERIES_STM32WB)) /* enable DMAMUX clock for L4+ and G4 */ __HAL_RCC_DMAMUX1_CLK_ENABLE(); #elif defined(SOC_SERIES_STM32MP1) __HAL_RCC_DMAMUX_CLK_ENABLE(); #endif UNUSED(tmpreg); /* To avoid compiler warnings */ } if (RT_DEVICE_FLAG_DMA_RX == flag) { __HAL_LINKDMA(&(uart->handle), hdmarx, uart->dma_rx.handle); } else if (RT_DEVICE_FLAG_DMA_TX == flag) { __HAL_LINKDMA(&(uart->handle), hdmatx, uart->dma_tx.handle); } #if defined(SOC_SERIES_STM32F1) || defined(SOC_SERIES_STM32F0) || defined(SOC_SERIES_STM32L0) DMA_Handle->Instance = dma_config->Instance; #elif defined(SOC_SERIES_STM32F4) || defined(SOC_SERIES_STM32F7) DMA_Handle->Instance = dma_config->Instance; DMA_Handle->Init.Channel = dma_config->channel; #elif defined(SOC_SERIES_STM32L4) || defined(SOC_SERIES_STM32WL) || defined(SOC_SERIES_STM32G0) || defined(SOC_SERIES_STM32G4) || defined(SOC_SERIES_STM32WB)\ || defined(SOC_SERIES_STM32H7) || defined(SOC_SERIES_STM32MP1) DMA_Handle->Instance = dma_config->Instance; DMA_Handle->Init.Request = dma_config->request; #endif DMA_Handle->Init.PeriphInc = DMA_PINC_DISABLE; DMA_Handle->Init.MemInc = DMA_MINC_ENABLE; DMA_Handle->Init.PeriphDataAlignment = DMA_PDATAALIGN_BYTE; DMA_Handle->Init.MemDataAlignment = DMA_MDATAALIGN_BYTE; if (RT_DEVICE_FLAG_DMA_RX == flag) { DMA_Handle->Init.Direction = DMA_PERIPH_TO_MEMORY; DMA_Handle->Init.Mode = DMA_CIRCULAR; } else if (RT_DEVICE_FLAG_DMA_TX == flag) { DMA_Handle->Init.Direction = DMA_MEMORY_TO_PERIPH; DMA_Handle->Init.Mode = DMA_NORMAL; } DMA_Handle->Init.Priority = DMA_PRIORITY_MEDIUM; #if defined(SOC_SERIES_STM32F4) || defined(SOC_SERIES_STM32F7) || defined(SOC_SERIES_STM32H7) || defined(SOC_SERIES_STM32MP1) DMA_Handle->Init.FIFOMode = DMA_FIFOMODE_DISABLE; #endif if (HAL_DMA_DeInit(DMA_Handle) != HAL_OK) { RT_ASSERT(0); } if (HAL_DMA_Init(DMA_Handle) != HAL_OK) { RT_ASSERT(0); } /* enable interrupt */ if (flag == RT_DEVICE_FLAG_DMA_RX) { rx_fifo = (struct rt_serial_rx_fifo *)serial->serial_rx; RT_ASSERT(rx_fifo != RT_NULL); /* Start DMA transfer */ if (HAL_UART_Receive_DMA(&(uart->handle), rx_fifo->buffer, serial->config.rx_bufsz) != HAL_OK) { /* Transfer error in reception process */ RT_ASSERT(0); } CLEAR_BIT(uart->handle.Instance->CR3, USART_CR3_EIE); __HAL_UART_ENABLE_IT(&(uart->handle), UART_IT_IDLE); } /* DMA irq should set in DMA TX mode, or HAL_UART_TxCpltCallback function will not be called */ HAL_NVIC_SetPriority(dma_config->dma_irq, 0, 0); HAL_NVIC_EnableIRQ(dma_config->dma_irq); HAL_NVIC_SetPriority(uart->config->irq_type, 1, 0); HAL_NVIC_EnableIRQ(uart->config->irq_type); LOG_D("%s dma %s instance: %x", uart->config->name, flag == RT_DEVICE_FLAG_DMA_RX ? "RX" : "TX", DMA_Handle->Instance); LOG_D("%s dma config done", uart->config->name); } /** * @brief UART error callbacks * @param huart: UART handle * @note This example shows a simple way to report transfer error, and you can * add your own implementation. * @retval None */ void HAL_UART_ErrorCallback(UART_HandleTypeDef *huart) { RT_ASSERT(huart != NULL); struct stm32_uart *uart = (struct stm32_uart *)huart; LOG_D("%s: %s %d\n", __FUNCTION__, uart->config->name, huart->ErrorCode); UNUSED(uart); } /** * @brief Rx Transfer completed callback * @param huart: UART handle * @note This example shows a simple way to report end of DMA Rx transfer, and * you can add your own implementation. * @retval None */ void HAL_UART_RxCpltCallback(UART_HandleTypeDef *huart) { struct stm32_uart *uart; RT_ASSERT(huart != NULL); uart = (struct stm32_uart *)huart; dma_recv_isr(&uart->serial, UART_RX_DMA_IT_TC_FLAG); } /** * @brief Rx Half transfer completed callback * @param huart: UART handle * @note This example shows a simple way to report end of DMA Rx Half transfer, * and you can add your own implementation. * @retval None */ void HAL_UART_RxHalfCpltCallback(UART_HandleTypeDef *huart) { struct stm32_uart *uart; RT_ASSERT(huart != NULL); uart = (struct stm32_uart *)huart; dma_recv_isr(&uart->serial, UART_RX_DMA_IT_HT_FLAG); } /** * @brief HAL_UART_TxCpltCallback * @param huart: UART handle * @note This callback can be called by two functions, first in UART_EndTransmit_IT when * UART Tx complete and second in UART_DMATransmitCplt function in DMA Circular mode. * @retval None */ void HAL_UART_TxCpltCallback(UART_HandleTypeDef *huart) { struct stm32_uart *uart; struct rt_serial_device *serial; rt_size_t trans_total_index; rt_base_t level; RT_ASSERT(huart != NULL); uart = (struct stm32_uart *)huart; serial = &uart->serial; RT_ASSERT(serial != RT_NULL); level = rt_hw_interrupt_disable(); trans_total_index = __HAL_DMA_GET_COUNTER(&(uart->dma_tx.handle)); rt_hw_interrupt_enable(level); if (trans_total_index) return; rt_hw_serial_isr(serial, RT_SERIAL_EVENT_TX_DMADONE); } #endif /* RT_SERIAL_USING_DMA */ static const struct rt_uart_ops stm32_uart_ops = { .configure = stm32_configure, .control = stm32_control, .putc = stm32_putc, .getc = stm32_getc, .transmit = stm32_transmit }; int rt_hw_usart_init(void) { rt_err_t result = 0; rt_size_t obj_num = sizeof(uart_obj) / sizeof(struct stm32_uart); stm32_uart_get_config(); for (int i = 0; i < obj_num; i++) { /* init UART object */ uart_obj[i].config = &uart_config[i]; uart_obj[i].serial.ops = &stm32_uart_ops; /* register UART device */ result = rt_hw_serial_register(&uart_obj[i].serial, uart_obj[i].config->name, RT_DEVICE_FLAG_RDWR, NULL); RT_ASSERT(result == RT_EOK); } return result; } #endif /* RT_USING_SERIAL_V2 */