/******************************************************************//** * @file drv_usart.c * @brief USART driver of RT-Thread RTOS for EFM32 * COPYRIGHT (C) 2011, RT-Thread Development Team * @author onelife * @version 0.4 beta ********************************************************************** * @section License * The license and distribution terms for this file may be found in the file LICENSE in this * distribution or at http://www.rt-thread.org/license/LICENSE ********************************************************************** * @section Change Logs * Date Author Notes * 2010-12-22 onelife Initial creation for EFM32 * 2011-01-17 onelife Merge with serial.c * * @section Change Logs of serial.c * 2009-02-05 Bernard first version * 2009-10-25 Bernard fix rt_serial_read bug when there is no data in the buffer. * 2010-03-29 Bernard cleanup code. *********************************************************************/ /******************************************************************//** * @addtogroup efm32 * @{ *********************************************************************/ /* Includes -------------------------------------------------------------------*/ #include "board.h" #include "hdl_interrupt.h" #include "drv_usart.h" /* Private typedef -------------------------------------------------------------*/ /* Private define --------------------------------------------------------------*/ /* Private macro --------------------------------------------------------------*/ /* Private variables ------------------------------------------------------------*/ #ifdef RT_USING_USART0 #if (RT_USING_USART0 > 3) #error "The location number range of usart is 0~3" #endif struct rt_device usart0_device; #endif #ifdef RT_USING_USART1 #if (RT_USING_USART1 > 3) #error "The location number range of usart is 0~3" #endif struct rt_device usart1_device; #endif #ifdef RT_USING_USART2 #if (RT_USING_USART2 > 3) #error "The location number range of usart is 0~3" #endif struct rt_device usart2_device; #endif /* Private function prototypes ---------------------------------------------------*/ /* Private functions ------------------------------------------------------------*/ /******************************************************************//** * @brief * Initialize USART device * * @details * * @note * * @param[in] dev * Pointer to device descriptor * * @return * Error code *********************************************************************/ static rt_err_t rt_usart_init (rt_device_t dev) { struct efm32_usart_device_t *usart; usart = (struct efm32_usart_device_t *)(dev->user_data); if (!(dev->flag & RT_DEVICE_FLAG_ACTIVATED)) { if (dev->flag & RT_DEVICE_FLAG_DMA_TX) { struct efm32_usart_dma_mode_t *dma_tx; dma_tx = (struct efm32_usart_dma_mode_t *)(usart->tx_mode); usart->state |= USART_STATE_RX_BUSY; } if (dev->flag & RT_DEVICE_FLAG_INT_RX) { struct efm32_usart_int_mode_t *int_rx; int_rx = (struct efm32_usart_int_mode_t *)(usart->rx_mode); int_rx->data_ptr = RT_NULL; } /* Enable USART */ USART_Enable(usart->usart_device, usartEnable); dev->flag |= RT_DEVICE_FLAG_ACTIVATED; } return RT_EOK; } /******************************************************************//** * @brief * Open USART device * * @details * * @note * * @param[in] dev * Pointer to device descriptor * * @param[in] oflag * Device open flag * * @return * Error code *********************************************************************/ static rt_err_t rt_usart_open(rt_device_t dev, rt_uint16_t oflag) { RT_ASSERT(dev != RT_NULL); struct efm32_usart_device_t *usart; IRQn_Type rxIrq; usart = (struct efm32_usart_device_t *)(dev->user_data); //if (usart->state & USART_STATE_CONSOLE) { /* Allocate new RX buffer */ struct efm32_usart_int_mode_t *int_mode; int_mode = (struct efm32_usart_int_mode_t *)(usart->rx_mode); if ((int_mode->data_ptr = rt_malloc(SERIAL_RX_BUFFER_SIZE)) == RT_NULL) { rt_kprintf("no memory for serial RX buffer\n"); return -RT_ENOMEM; } rt_memset(int_mode->data_ptr, 0, SERIAL_RX_BUFFER_SIZE); int_mode->data_size = SERIAL_RX_BUFFER_SIZE; int_mode->read_index = 0; int_mode->save_index = 0; } /* Enable TX/RX interrupt */ switch (usart->unit) { case 0: rxIrq = USART0_RX_IRQn; break; case 1: rxIrq = USART1_RX_IRQn; break; case 2: rxIrq = USART2_RX_IRQn; break; } /* Enable RX interrupts */ usart->usart_device->IEN = USART_IEN_RXDATAV; usart->usart_device->IFC = _USART_IFC_MASK; /* Enable IRQ */ if (oflag != RT_DEVICE_OFLAG_WRONLY) { NVIC_ClearPendingIRQ(rxIrq); NVIC_SetPriority(rxIrq, EFM32_IRQ_PRI_DEFAULT); NVIC_EnableIRQ(rxIrq); } if (oflag != RT_DEVICE_OFLAG_RDONLY) { /* DMA IRQ is enabled by DMA_Init() */ NVIC_SetPriority(DMA_IRQn, EFM32_IRQ_PRI_DEFAULT); } #ifdef RT_USART_DEBUG rt_kprintf("USART%d: Open with flag %x\n", usart->unit, oflag); #endif return RT_EOK; } /******************************************************************//** * @brief * Close USART device * * @details * * @note * * @param[in] dev * Pointer to device descriptor * * @return * Error code *********************************************************************/ static rt_err_t rt_usart_close(rt_device_t dev) { struct efm32_usart_int_mode_t *int_rx; int_rx = (struct efm32_usart_int_mode_t *)\ (((struct efm32_usart_device_t *)(dev->user_data))->rx_mode); rt_free(int_rx->data_ptr); int_rx->data_ptr = RT_NULL; return RT_EOK; } /******************************************************************//** * @brief * Read from USART device * * @details * * @note * * @param[in] dev * Pointer to device descriptor * * @param[in] pos * Offset * * @param[in] buffer * Poniter to the buffer * * @param[in] size * Buffer size in byte * * @return * Error code *********************************************************************/ static rt_size_t rt_usart_read ( rt_device_t dev, rt_off_t pos, void* buffer, rt_size_t size) { rt_uint8_t* ptr; rt_err_t err_code; ptr = buffer; err_code = RT_EOK; if (dev->flag & RT_DEVICE_FLAG_INT_RX) { /* interrupt mode Rx */ while (size) { rt_base_t level; struct efm32_usart_int_mode_t *int_rx; int_rx = (struct efm32_usart_int_mode_t *)\ (((struct efm32_usart_device_t *)(dev->user_data))->rx_mode); /* disable interrupt */ level = rt_hw_interrupt_disable(); if (int_rx->read_index != int_rx->save_index) { /* read a character */ *ptr++ = int_rx->data_ptr[int_rx->read_index]; size--; /* move to next position */ int_rx->read_index ++; if (int_rx->read_index >= SERIAL_RX_BUFFER_SIZE) { int_rx->read_index = 0; } } else { /* set error code */ err_code = -RT_EEMPTY; /* enable interrupt */ rt_hw_interrupt_enable(level); break; } /* enable interrupt */ rt_hw_interrupt_enable(level); } } else { /* polling mode */ USART_TypeDef *usart_device; RT_ASSERT(buffer != RT_NULL); usart_device = ((struct efm32_usart_device_t *)(dev->user_data))->usart_device; while ((rt_uint32_t)ptr - (rt_uint32_t)buffer < size) { while (usart_device->STATUS & USART_STATUS_RXDATAV) { *ptr = usart_device->RXDATA & 0xff; ptr ++; } } } /* set error code */ rt_set_errno(err_code); return (rt_uint32_t)ptr - (rt_uint32_t)buffer; } /******************************************************************//** * @brief * Write to USART device * * @details * * @note * * @param[in] dev * Pointer to device descriptor * * @param[in] pos * Offset * * @param[in] buffer * Poniter to the buffer * * @param[in] size * Buffer size in byte * * @return * Error code *********************************************************************/ static rt_size_t rt_usart_write ( rt_device_t dev, rt_off_t pos, const void* buffer, rt_size_t size) { rt_err_t err_code; rt_size_t write_size; struct efm32_usart_device_t* usart; err_code = RT_EOK; write_size = 0; usart = (struct efm32_usart_device_t*)(dev->user_data); if (dev->flag & RT_DEVICE_FLAG_DMA_TX) { /* DMA mode Tx */ struct efm32_usart_dma_mode_t *dma_tx; if (dev->flag & RT_DEVICE_FLAG_STREAM) { *((rt_uint8_t *)buffer + size++) = '\r'; *((rt_uint8_t *)buffer + size) = 0x0; } dma_tx = (struct efm32_usart_dma_mode_t *)(usart->tx_mode); dma_tx->data_ptr = (rt_uint32_t *)buffer; dma_tx->data_size = size; usart->state |= USART_STATE_TX_BUSY; DMA_ActivateBasic( dma_tx->dma_channel, true, false, (void *)&(usart->usart_device->TXDATA), buffer, size - 1); /* Wait, otherwise the TX buffer is overwrite */ if (usart->state & USART_STATE_CONSOLE) { while(usart->state & USART_STATE_TX_BUSY); } else { while(usart->state & USART_STATE_TX_BUSY) { rt_thread_sleep(USART_WAIT_TIME_TX); } } write_size = size; } else { /* polling mode */ rt_uint8_t* ptr = (rt_uint8_t*)buffer; if (dev->flag & RT_DEVICE_FLAG_STREAM) { /* stream mode */ while (size) { if (*ptr == '\n') { while (!(usart->usart_device->STATUS & USART_STATUS_TXBL)); usart->usart_device->TXDATA = '\r'; } while (!(usart->usart_device->STATUS & USART_STATUS_TXBL)); usart->usart_device->TXDATA = (rt_uint32_t)*ptr; ++ptr; --size; } } else { /* write data directly */ while (size) { while (!(usart->usart_device->STATUS & USART_STATUS_TXBL)); usart->usart_device->TXDATA = (rt_uint32_t)*ptr; ++ptr; --size; } } write_size = (rt_size_t)ptr - (rt_size_t)buffer; } /* set error code */ rt_set_errno(err_code); return write_size; } /******************************************************************//** * @brief * Configure USART device * * @details * * @note * * @param[in] dev * Pointer to device descriptor * * @param[in] cmd * IIC control command * * @param[in] args * Arguments * * @return * Error code *********************************************************************/ static rt_err_t rt_usart_control ( rt_device_t dev, rt_uint8_t cmd, void *args) { RT_ASSERT(dev != RT_NULL); struct efm32_usart_device_t *usart; usart = (struct efm32_usart_device_t *)(dev->user_data); switch (cmd) { case RT_DEVICE_CTRL_SUSPEND: /* Suspend device */ dev->flag |= RT_DEVICE_FLAG_SUSPENDED; USART_Enable(usart->usart_device, usartDisable); break; case RT_DEVICE_CTRL_RESUME: /* Resume device */ dev->flag &= ~RT_DEVICE_FLAG_SUSPENDED; USART_Enable(usart->usart_device, usartEnable); break; case RT_DEVICE_CTRL_USART_RBUFFER: /* Set RX buffer */ { struct efm32_usart_int_mode_t *int_rx; rt_uint8_t size; int_rx = (struct efm32_usart_int_mode_t *)(usart->rx_mode); size = (rt_uint8_t)((rt_uint32_t)args & 0xFFUL); /* Free previous RX buffer */ if (int_rx->data_ptr != RT_NULL) { if (size == 0) { /* Free RX buffer */ rt_free(int_rx->data_ptr); int_rx->data_ptr = RT_NULL; } else if (size != int_rx->data_size) { /* Re-allocate RX buffer */ if ((int_rx->data_ptr = rt_realloc(int_rx->data_ptr, size)) \ == RT_NULL) { rt_kprintf("no memory for usart rx buffer\n"); return -RT_ENOMEM; } //rt_memset(int_rx->data_ptr, 0, size); //TODO } } else { /* Allocate new RX buffer */ if ((int_rx->data_ptr = rt_malloc(size)) == RT_NULL) { rt_kprintf("no memory for usart rx buffer\n"); return -RT_ENOMEM; } } int_rx->data_size = size; int_rx->read_index = 0; int_rx->save_index = 0; } break; } return RT_EOK; } /******************************************************************//** * @brief * USART RX data valid interrupt handler * * @details * * @note * * @param[in] dev * Pointer to device descriptor *********************************************************************/ void rt_hw_usart_rx_isr(rt_device_t dev) { struct efm32_usart_device_t *usart; struct efm32_usart_int_mode_t *int_rx; /* interrupt mode receive */ RT_ASSERT(dev->flag & RT_DEVICE_FLAG_INT_RX); usart = (struct efm32_usart_device_t *)(dev->user_data); int_rx = (struct efm32_usart_int_mode_t *)(usart->rx_mode); RT_ASSERT(int_rx->data_ptr != RT_NULL); /* Set status */ usart->state |= USART_STATE_RX_BUSY; /* save on rx buffer */ while (usart->usart_device->STATUS & USART_STATUS_RXDATAV) { rt_base_t level; /* disable interrupt */ level = rt_hw_interrupt_disable(); /* save character */ int_rx->data_ptr[int_rx->save_index] = \ (rt_uint8_t)(usart->usart_device->RXDATA & 0xFFUL); int_rx->save_index ++; if (int_rx->save_index >= SERIAL_RX_BUFFER_SIZE) int_rx->save_index = 0; /* if the next position is read index, discard this 'read char' */ if (int_rx->save_index == int_rx->read_index) { int_rx->read_index ++; if (int_rx->read_index >= SERIAL_RX_BUFFER_SIZE) { int_rx->read_index = 0; } } /* enable interrupt */ rt_hw_interrupt_enable(level); } /* invoke callback */ if (dev->rx_indicate != RT_NULL) { rt_size_t rx_length; /* get rx length */ rx_length = int_rx->read_index > int_rx->save_index ? SERIAL_RX_BUFFER_SIZE - int_rx->read_index + int_rx->save_index : \ int_rx->save_index - int_rx->read_index; dev->rx_indicate(dev, rx_length); } } /******************************************************************//** * @brief * DMA for USART TX interrupt handler * * @details * * @note * * @param[in] dev * Pointer to device descriptor *********************************************************************/ void rt_hw_usart_dma_tx_isr(rt_device_t dev) { /* DMA mode receive */ struct efm32_usart_device_t *usart; struct efm32_usart_dma_mode_t *dma_tx; RT_ASSERT(dev->flag & RT_DEVICE_FLAG_DMA_TX); usart = (struct efm32_usart_device_t *)(dev->user_data); dma_tx = (struct efm32_usart_dma_mode_t *)(usart->tx_mode); /* invoke call to notify tx complete */ if (dev->tx_complete != RT_NULL) { dev->tx_complete(dev, dma_tx->data_ptr); } /* Set status */ usart->state &= ~(rt_uint32_t)USART_STATE_TX_BUSY; } /******************************************************************//** * @brief * Register USART device * * @details * * @note * * @param[in] device * Pointer to device descriptor * * @param[in] name * Device name * * @param[in] flag * Configuration flags * * @param[in] usart * Pointer to USART device descriptor * * @return * Error code *********************************************************************/ rt_err_t rt_hw_usart_register( rt_device_t device, const char *name, rt_uint32_t flag, struct efm32_usart_device_t *usart) { RT_ASSERT(device != RT_NULL); if ((flag & RT_DEVICE_FLAG_DMA_RX) || (flag & RT_DEVICE_FLAG_INT_TX)) { RT_ASSERT(0); } device->type = RT_Device_Class_Char; device->rx_indicate = RT_NULL; device->tx_complete = RT_NULL; device->init = rt_usart_init; device->open = rt_usart_open; device->close = rt_usart_close; device->read = rt_usart_read; device->write = rt_usart_write; device->control = rt_usart_control; device->user_data = usart; /* register a character device */ return rt_device_register(device, name, RT_DEVICE_FLAG_RDWR | flag); } /******************************************************************//** * @brief * Initialize the specified USART unit * * @details * * @note * * @param[in] device * Pointer to device descriptor * * @param[in] unitNumber * Unit number * * @param[in] location * Pin location number * * @param[in] flag * Configuration flag * * @param[in] dmaChannel * DMA channel number for TX * * @param[in] console * Indicate if using as console * * @return * Pointer to USART device *********************************************************************/ static struct efm32_usart_device_t *rt_hw_usart_unit_init( rt_device_t device, rt_uint8_t unitNumber, rt_uint8_t location, rt_uint32_t flag, rt_uint32_t dmaChannel, rt_bool_t console) { struct efm32_usart_device_t *usart; struct efm32_usart_dma_mode_t *dma_mode; CMU_Clock_TypeDef usartClock; rt_uint32_t txDmaSelect; USART_InitAsync_TypeDef init; efm32_irq_hook_init_t hook; /* Allocate device */ usart = rt_malloc(sizeof(struct efm32_usart_device_t)); if (usart == RT_NULL) { rt_kprintf("no memory for USART driver\n"); return usart; } usart->unit = unitNumber; if (console == true) { usart->state = USART_STATE_CONSOLE; } else { usart->state = 0; } usart->tx_mode = RT_NULL; usart->rx_mode = RT_NULL; /* Allocate TX */ dma_mode = RT_NULL; if (flag & RT_DEVICE_FLAG_DMA_TX) { usart->tx_mode = dma_mode = rt_malloc(sizeof(struct efm32_usart_dma_mode_t)); if (dma_mode == RT_NULL) { rt_kprintf("no memory for USART TX by DMA\n"); rt_free(usart->rx_mode); rt_free(usart); usart = RT_NULL; return usart; } dma_mode->dma_channel = dmaChannel; } /* Allocate RX */ if (flag & RT_DEVICE_FLAG_INT_RX) { usart->rx_mode = rt_malloc(sizeof(struct efm32_usart_int_mode_t)); if (usart->rx_mode == RT_NULL) { rt_kprintf("no memory for USART RX by interrupt\n"); rt_free(usart->tx_mode); rt_free(usart); usart = RT_NULL; return usart; } } /* Initialization */ switch (unitNumber) { case 0: usart->usart_device = USART0; usartClock = (CMU_Clock_TypeDef)cmuClock_USART0; txDmaSelect = DMAREQ_USART0_TXBL; break; case 1: usart->usart_device = USART1; usartClock = (CMU_Clock_TypeDef)cmuClock_USART1; txDmaSelect = DMAREQ_USART1_TXBL; break; case 2: usart->usart_device = USART2; usartClock = (CMU_Clock_TypeDef)cmuClock_USART2; txDmaSelect = DMAREQ_USART2_TXBL; break; } /* Enable USART clock */ CMU_ClockEnable(usartClock, true); /* Reset */ USART_Reset(usart->usart_device); /* Config GPIO */ GPIO_PinModeSet( (GPIO_Port_TypeDef)AF_PORT(AF_USART_TX(unitNumber), location), AF_PIN(AF_USART_TX(unitNumber), location), gpioModePushPull, 0); GPIO_PinModeSet( (GPIO_Port_TypeDef)AF_PORT(AF_USART_RX(unitNumber), location), AF_PIN(AF_USART_RX(unitNumber), location), gpioModeInputPull, 1); /* Config interrupt and NVIC */ if (flag & RT_DEVICE_FLAG_INT_RX) { hook.type = efm32_irq_type_usart; hook.unit = unitNumber * 2 + 1; hook.cbFunc = rt_hw_usart_rx_isr; hook.userPtr = device; efm32_irq_hook_register(&hook); } /* Config DMA */ if (flag & RT_DEVICE_FLAG_DMA_TX) { DMA_CB_TypeDef *callback; DMA_CfgChannel_TypeDef chnlCfg; DMA_CfgDescr_TypeDef descrCfg; hook.type = efm32_irq_type_dma; hook.unit = dmaChannel; hook.cbFunc = rt_hw_usart_dma_tx_isr; hook.userPtr = device; efm32_irq_hook_register(&hook); callback = (DMA_CB_TypeDef *)rt_malloc(sizeof(DMA_CB_TypeDef)); callback->cbFunc = DMA_IRQHandler_All; callback->userPtr = RT_NULL; callback->primary = 0; /* Setting up DMA channel */ chnlCfg.highPri = false; /* Can't use with peripherals */ chnlCfg.enableInt = true; /* Interrupt for callback function */ chnlCfg.select = txDmaSelect; chnlCfg.cb = callback; DMA_CfgChannel(dmaChannel, &chnlCfg); /* Setting up DMA channel descriptor */ descrCfg.dstInc = dmaDataIncNone; descrCfg.srcInc = dmaDataInc1; descrCfg.size = dmaDataSize1; descrCfg.arbRate = dmaArbitrate1; descrCfg.hprot = 0; DMA_CfgDescr(dmaChannel, true, &descrCfg); } /* Enable RX and TX pins and set location */ usart->usart_device->ROUTE = USART_ROUTE_RXPEN | USART_ROUTE_TXPEN | \ (location << _USART_ROUTE_LOCATION_SHIFT); /* Init specified USART unit */ init.enable = usartEnable; init.refFreq = 0; init.baudrate = UART_BAUDRATE; init.oversampling = USART_CTRL_OVS_X4; init.databits = USART_FRAME_DATABITS_EIGHT; init.parity = USART_FRAME_PARITY_NONE; init.stopbits = USART_FRAME_STOPBITS_ONE; USART_InitAsync(usart->usart_device, &init); /* Clear RX/TX buffers */ usart->usart_device->CMD = USART_CMD_CLEARRX | USART_CMD_CLEARTX; return usart; } /******************************************************************//** * @brief * Initialize all USART module related hardware and register USART device to kernel * * @details * * @note *********************************************************************/ void rt_hw_usart_init(void) { struct efm32_usart_device_t *usart; rt_uint32_t flag; rt_bool_t console; /* Register usart0 */ #ifdef RT_USING_USART0 flag = RT_DEVICE_FLAG_RDWR; #if (RT_CONSOLE_DEVICE == 0x0UL) console = true; flag |= RT_DEVICE_FLAG_STREAM; #else console = false; #endif #ifdef RT_USART0_USING_DMA RT_ASSERT(RT_USART0_USING_DMA < DMA_CHAN_COUNT); flag |= RT_DEVICE_FLAG_DMA_TX; #else #define RT_USART0_USING_DMA EFM32_NO_DATA #endif flag |= RT_DEVICE_FLAG_INT_RX; usart = rt_hw_usart_unit_init( &usart0_device, 0, RT_USING_USART0, flag, RT_USART0_USING_DMA, console); rt_hw_usart_register(&usart0_device, RT_USART0_NAME, flag, usart); #endif /* Register usart1 */ #ifdef RT_USING_USART1 flag = RT_DEVICE_FLAG_RDWR; #if (RT_CONSOLE_DEVICE == 0x1UL) console = true; flag |= RT_DEVICE_FLAG_STREAM; #else console = false; #endif #ifdef RT_USART1_USING_DMA RT_ASSERT(RT_USART1_USING_DMA < DMA_CHAN_COUNT); flag |= RT_DEVICE_FLAG_DMA_TX; #else #define RT_USART1_USING_DMA EFM32_NO_DATA #endif flag |= RT_DEVICE_FLAG_INT_RX; usart = rt_hw_usart_unit_init( &usart1_device, 1, RT_USING_USART1, flag, RT_USART1_USING_DMA, console); rt_hw_usart_register(&usart1_device, RT_USART1_NAME, flag, usart); #endif /* Register usart2 */ #ifdef RT_USING_USART2 flag = RT_DEVICE_FLAG_RDWR; #if (RT_CONSOLE_DEVICE == 0x2UL) console = true; flag |= RT_DEVICE_FLAG_STREAM; #else console = false; #endif #ifdef RT_USART2_USING_DMA RT_ASSERT(RT_USART2_USING_DMA < DMA_CHAN_COUNT); flag |= RT_DEVICE_FLAG_DMA_TX; #else #define RT_USART2_USING_DMA EFM32_NO_DATA #endif flag |= RT_DEVICE_FLAG_INT_RX; usart = rt_hw_usart_unit_init( &usart2_device, 2, RT_USING_USART2, flag, RT_USART2_USING_DMA, console); rt_hw_usart_register(&usart2_device, RT_USART2_NAME, flag, usart); #endif } /******************************************************************//** * @} *********************************************************************/