RT-Thread中的串口DMA分析


這里分析一下RT-Thread中串口DMA方式的實現,以供做新處理器串口支持時的參考。

背景

在如今的芯片性能和外設強大功能的情況下,串口不實現DMA/中斷方式操作,我認為在實際項目中基本是不可接受的,但遺憾的是,rt-thread現有支持的實現中,基本上沒有支持串口的DMA,文檔也沒有關於串口DMA支持相關的說明,這里以STM32實現為背景,梳理一下串口DMA的實現流程,以供新處理器實現時以作參考。

DMA接收准備

啟用DMA接收,需要在打開設備的時候做一些處理,入口函數為rt_device_open()。主體實現是:

rt_err_t rt_device_open(rt_device_t dev, rt_uint16_t oflag) { ...... result = device_init(dev); ...... result = device_open(dev, oflag); ...... } 

device_init()就是rt_serial_init()函數,其主要是調用configure()函數,

static rt_err_t rt_serial_init(struct rt_device *dev) { ...... if (serial->ops->configure) result = serial->ops->configure(serial, &serial->config); ...... } 

在stm32下,其configure()函數是stm32_configure(),其根據設備打開參數,配置STM32外設的寄存器。包括波特率、校驗等串口工作參數。

device_open()函數就是rt_serial_open()函數,其主要實現是:

static rt_err_t rt_serial_open(struct rt_device *dev, rt_uint16_t oflag) { ...... #ifdef RT_SERIAL_USING_DMA else if (oflag & RT_DEVICE_FLAG_DMA_RX) { if (serial->config.bufsz == 0) { struct rt_serial_rx_dma* rx_dma; rx_dma = (struct rt_serial_rx_dma*) rt_malloc (sizeof(struct rt_serial_rx_dma)); RT_ASSERT(rx_dma != RT_NULL); rx_dma->activated = RT_FALSE; serial->serial_rx = rx_dma; } else { struct rt_serial_rx_fifo* rx_fifo; rx_fifo = (struct rt_serial_rx_fifo*) rt_malloc (sizeof(struct rt_serial_rx_fifo) + serial->config.bufsz); RT_ASSERT(rx_fifo != RT_NULL); rx_fifo->buffer = (rt_uint8_t*) (rx_fifo + 1); rt_memset(rx_fifo->buffer, 0, serial->config.bufsz); rx_fifo->put_index = 0; rx_fifo->get_index = 0; rx_fifo->is_full = RT_FALSE; serial->serial_rx = rx_fifo; /* configure fifo address and length to low level device */ serial->ops->control(serial, RT_DEVICE_CTRL_CONFIG, (void *) RT_DEVICE_FLAG_DMA_RX); } dev->open_flag |= RT_DEVICE_FLAG_DMA_RX; } #endif /* RT_SERIAL_USING_DMA */ ...... #ifdef RT_SERIAL_USING_DMA else if (oflag & RT_DEVICE_FLAG_DMA_TX) { struct rt_serial_tx_dma* tx_dma; tx_dma = (struct rt_serial_tx_dma*) rt_malloc (sizeof(struct rt_serial_tx_dma)); RT_ASSERT(tx_dma != RT_NULL); tx_dma->activated = RT_FALSE; rt_data_queue_init(&(tx_dma->data_queue), 8, 4, RT_NULL); serial->serial_tx = tx_dma; dev->open_flag |= RT_DEVICE_FLAG_DMA_TX; /* configure low level device */ serial->ops->control(serial, RT_DEVICE_CTRL_CONFIG, (void *)RT_DEVICE_FLAG_DMA_TX); } #endif /* RT_SERIAL_USING_DMA */ ...... } 

可見,其主要工作是為DMA接收准備FIFO緩沖區;為DMA發送准備發送數據緩沖隊列,但是好像STM32中斷並沒有用到發送數據緩沖。

DMA配置數據來源是rt_hw_usart_init()函數,缺省的配置參數由宏RT_SERIAL_CONFIG_DEFAULT決定, 這里決定了缺省的接收緩沖區參數是64字節,通訊缺省參數是:115200,8N1。

#define RT_SERIAL_RB_BUFSZ 64 

DMA接收

DMA接收我們從DMA中斷開始分析,DMA接收中斷服務函數為UARTn_DMA_RX_IRQHandler(),其調用HAL庫的DMA處理函數HAL_DMA_IRQHandler(),該函數調用回調函數HAL_UART_RxCpltCallback()或HAL_UART_RxHalfCpltCallback(),這兩個函數進入真正的中斷服務處理函數dma_isr(struct rt_serial_device *),主體代碼如下:

static void dma_isr(struct rt_serial_device *serial) { ...... /* 如果是DMA-RX中斷 */ if ((__HAL_DMA_GET_IT_SOURCE(&(uart->dma_rx.handle), DMA_IT_TC) != RESET) || (__HAL_DMA_GET_IT_SOURCE(&(uart->dma_rx.handle), DMA_IT_HT) != RESET)) { level = rt_hw_interrupt_disable(); /* 得到本次接收到的數據量 */ recv_total_index = serial->config.bufsz - __HAL_DMA_GET_COUNTER(&(uart->dma_rx.handle)); if (recv_total_index == 0) { /* 這一句代碼,是什么意思? */ recv_len = serial->config.bufsz - uart->dma_rx.last_index; } else { /* 減去以前接收到的數據量,得到本次接收到的數據數量 */ recv_len = recv_total_index - uart->dma_rx.last_index; } /* 更新接收歷史數據量 */ uart->dma_rx.last_index = recv_total_index; rt_hw_interrupt_enable(level); if (recv_len) { /* 如果有新數據,調用serial設備模塊的通用處理 */ rt_hw_serial_isr(serial, RT_SERIAL_EVENT_RX_DMADONE | (recv_len << 8)); } } } 

在serial模塊的函數rt_hw_serial_isr()中,主體代碼是:

void rt_hw_serial_isr(struct rt_serial_device *serial, int event) { ...... case RT_SERIAL_EVENT_RX_DMADONE: { int length; rt_base_t level; /* get DMA rx length */ length = (event & (~0xff)) >> 8; if (serial->config.bufsz == 0) { /* 這個case的處理邏輯不知道怎么應用,看起來STM32實現並沒有處理這個case */ struct rt_serial_rx_dma* rx_dma; rx_dma = (struct rt_serial_rx_dma*) serial->serial_rx; RT_ASSERT(rx_dma != RT_NULL); RT_ASSERT(serial->parent.rx_indicate != RT_NULL); serial->parent.rx_indicate(&(serial->parent), length); rx_dma->activated = RT_FALSE; } else { /* disable interrupt */ level = rt_hw_interrupt_disable(); /* update fifo put index, 將數據放入接收緩沖區 */ rt_dma_recv_update_put_index(serial, length); /* calculate received total length, 更新緩沖區信息 */ length = rt_dma_calc_recved_len(serial); /* enable interrupt */ rt_hw_interrupt_enable(level); /* invoke callback, 通知上層,有新數據到達 */ if (serial->parent.rx_indicate != RT_NULL) { serial->parent.rx_indicate(&(serial->parent), length); } } break; } ...... } 

上層接到通知后,讀取函數最終調用驅動讀函數rt_serial_read()函數,在DMA的條件下,調用_serial_dma_rx()從緩沖區讀取數據。其代碼為:

static rt_size_t rt_serial_read(struct rt_device *dev, rt_off_t pos, void *buffer, rt_size_t size) { ...... else if (dev->open_flag & RT_DEVICE_FLAG_DMA_RX) { return _serial_dma_rx(serial, (rt_uint8_t *)buffer, size); } ...... } 

DMA發送

DMA發送從驅動寫函數rt_serial_write()開始,在DMA的條件下,調用_serial_dma_tx(),_serial_dma_tx()再調用操作的DMA發送函數發送數據,代碼為:

static rt_size_t rt_serial_write(struct rt_device *dev, rt_off_t pos, const void *buffer, rt_size_t size) { ...... else if (dev->open_flag & RT_DEVICE_FLAG_DMA_TX) { return _serial_dma_tx(serial, (const rt_uint8_t *)buffer, size); } ...... } 
rt_inline int _serial_dma_tx(struct rt_serial_device *serial, const rt_uint8_t *data, int length) { ...... /* make a DMA transfer */ serial->ops->dma_transmit(serial, (rt_uint8_t *)data, length, RT_SERIAL_DMA_TX); ...... } 

STM32的dma_transmit()實現函數是stm32_dma_transmit(),其實現就是簡單調用HAL_UART_Transmit_DMA(),代碼為:

static rt_size_t stm32_dma_transmit(struct rt_serial_device *serial, rt_uint8_t *buf, rt_size_t size, int direction) { ...... if (HAL_UART_Transmit_DMA(&uart->handle, buf, size) == HAL_OK) ...... } 

實現非常簡單。

 
 
 
 
 


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