/* * Copyright (C) 2014 Freie Universität Berlin * * This file is subject to the terms and conditions of the GNU Lesser General * Public License v2.1. See the file LICENSE in the top level directory for more * details. */ /** * @ingroup cpu_stm32f3 * @{ * * @file * @brief Low-level UART driver implementation * * @author Hauke Petersen * * @} */ #include "cpu.h" #include "periph/uart.h" /** * @brief Allocate memory to store the callback functions. */ static uart_isr_ctx_t uart_config[UART_NUMOF]; static int init_base(uart_t uart, uint32_t baudrate); int uart_init(uart_t uart, uint32_t baudrate, uart_rx_cb_t rx_cb, void *arg) { /* do basic initialization */ int res = init_base(uart, baudrate); if (res != UART_OK) { return res; } /* remember callback addresses */ uart_config[uart].rx_cb = rx_cb; uart_config[uart].arg = arg; /* enable receive interrupt */ switch (uart) { #if UART_0_EN case UART_0: NVIC_EnableIRQ(UART_0_IRQ_CHAN); UART_0_DEV->CR1 |= USART_CR1_RXNEIE; break; #endif #if UART_1_EN case UART_1: NVIC_EnableIRQ(UART_1_IRQ_CHAN); UART_1_DEV->CR1 |= USART_CR1_RXNEIE; break; #endif #if UART_2_EN case UART_2: NVIC_EnableIRQ(UART_2_IRQ_CHAN); UART_2_DEV->CR1 |= USART_CR1_RXNEIE; break; #endif } return UART_OK; } static int init_base(uart_t uart, uint32_t baudrate) { USART_TypeDef *dev = 0; GPIO_TypeDef *port = 0; uint32_t tx_pin = 0; uint32_t rx_pin = 0; uint8_t af = 0; uint32_t clk = 0; uint16_t mantissa; uint8_t fraction; switch (uart) { #if UART_0_EN case UART_0: dev = UART_0_DEV; port = UART_0_PORT; clk = UART_0_CLK; tx_pin = UART_0_TX_PIN; rx_pin = UART_0_RX_PIN; af = UART_0_AF; UART_0_CLKEN(); UART_0_PORT_CLKEN(); break; #endif #if UART_1_EN case UART_1: dev = UART_1_DEV; port = UART_1_PORT; clk = UART_1_CLK; tx_pin = UART_1_TX_PIN; rx_pin = UART_1_RX_PIN; af = UART_1_AF; UART_1_CLKEN(); UART_1_PORT_CLKEN(); break; #endif #if UART_2_EN case UART_2: dev = UART_2_DEV; port = UART_2_PORT; clk = UART_2_CLK; tx_pin = UART_2_TX_PIN; rx_pin = UART_2_RX_PIN; af = UART_2_AF; UART_2_CLKEN(); UART_2_PORT_CLKEN(); break; #endif default: return UART_NODEV; } /* Make sure port and dev are != NULL here, i.e. that the variables are * assigned in all non-returning branches of the switch at the top of this * function. */ assert(port != NULL); assert(dev != NULL); /* uart_configure RX and TX pins, set pin to use alternative function mode */ port->MODER &= ~(3 << (rx_pin * 2) | 3 << (tx_pin * 2)); port->MODER |= 2 << (rx_pin * 2) | 2 << (tx_pin * 2); /* and assign alternative function */ if (rx_pin < 8) { port->AFR[0] &= ~(0xf << (rx_pin * 4)); port->AFR[0] |= af << (rx_pin * 4); } else { port->AFR[1] &= ~(0xf << ((rx_pin - 8) * 4)); port->AFR[1] |= af << ((rx_pin - 8) * 4); } if (tx_pin < 8) { port->AFR[0] &= ~(0xf << (tx_pin * 4)); port->AFR[0] |= af << (tx_pin * 4); } else { port->AFR[1] &= ~(0xf << ((tx_pin - 8) * 4)); port->AFR[1] |= af << ((tx_pin - 8) * 4); } /* uart_configure UART to mode 8N1 with given baudrate */ clk /= baudrate; mantissa = (uint16_t)(clk / 16); fraction = (uint8_t)(clk - (mantissa * 16)); dev->BRR = ((mantissa & 0x0fff) << 4) | (0x0f & fraction); /* enable receive and transmit mode */ dev->CR3 = 0; dev->CR2 = 0; dev->CR1 |= USART_CR1_UE | USART_CR1_TE | USART_CR1_RE; return UART_OK; } void uart_write(uart_t uart, const uint8_t *data, size_t len) { USART_TypeDef *dev = 0; switch (uart) { #if UART_0_EN case UART_0: dev = UART_0_DEV; break; #endif #if UART_1_EN case UART_1: dev = UART_1_DEV; break; #endif #if UART_2_EN case UART_2: dev = UART_2_DEV; break; #endif default: return; } /* Make sure dev is != NULL here, i.e. that the variable is assigned in * all non-returning branches of the switch at the top of this function. */ assert(dev != NULL); for (size_t i = 0; i < len; i++) { while (!(dev->ISR & USART_ISR_TXE)) {} dev->TDR = data[i]; } } static inline void irq_handler(uint8_t uartnum, USART_TypeDef *dev) { if (dev->ISR & USART_ISR_RXNE) { uint8_t data = (uint8_t)dev->RDR; uart_config[uartnum].rx_cb(uart_config[uartnum].arg, data); } else if (dev->ISR & USART_ISR_ORE) { /* do nothing on overrun */ dev->ICR |= USART_ICR_ORECF; } cortexm_isr_end(); } #if UART_0_EN void UART_0_ISR(void) { irq_handler(UART_0, UART_0_DEV); } #endif #if UART_1_EN void UART_1_ISR(void) { irq_handler(UART_1, UART_1_DEV); } #endif #if UART_2_EN void UART_2_ISR(void) { irq_handler(UART_2, UART_2_DEV); } #endif