uart.c

/*
 * Copyright (C) 2014-2016 Freie Universität Berlin
 *               2015 Jan Wagner <mail@jwagner.eu>
 *
 *
 * 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_nrf5x_common
 * @{
 *
 * @file
 * @brief       Implementation of the peripheral UART interface
 *
 * @author      Christian Kühling <kuehling@zedat.fu-berlin.de>
 * @author      Timo Ziegler <timo.ziegler@fu-berlin.de>
 * @author      Hauke Petersen <hauke.petersen@fu-berlin.de>
 * @author      Jan Wagner <mail@jwagner.eu>
 *
 * @}
 */

#include <stdint.h>

#include "cpu.h"
#include "sched.h"
#include "thread.h"
#include "periph/uart.h"
#include "periph_cpu.h"
#include "periph_conf.h"


/**
 * @brief Allocate memory for the interrupt context
 */
static uart_isr_ctx_t uart_config;

int uart_init(uart_t uart, uint32_t baudrate, uart_rx_cb_t rx_cb, void *arg)
{
    if (uart != 0) {
        return -1;
    }

    /* remember callback addresses and argument */
    uart_config.rx_cb = rx_cb;
    uart_config.arg = arg;

#ifdef CPU_FAM_NRF51
   /* power on the UART device */
    NRF_UART0->POWER = 1;
#endif
    /* reset configuration registers */
    NRF_UART0->CONFIG = 0;
    /* configure RX/TX pin modes */
    GPIO_BASE->DIRSET = (1 << UART_PIN_TX);
    GPIO_BASE->DIRCLR = (1 << UART_PIN_RX);
    /* configure UART pins to use */
    NRF_UART0->PSELTXD = UART_PIN_TX;
    NRF_UART0->PSELRXD = UART_PIN_RX;
    /* enable HW-flow control if defined */
#if UART_HWFLOWCTRL
    /* set pin mode for RTS and CTS pins */
    GPIO_BASE->DIRSET = (1 << UART_PIN_RTS);
    GPIO_BASE->DIRCLR = (1 << UART_PIN_CTS);
    /* configure RTS and CTS pins to use */
    NRF_UART0->PSELRTS = UART_PIN_RTS;
    NRF_UART0->PSELCTS = UART_PIN_CTS;
    NRF_UART0->CONFIG |= UART_CONFIG_HWFC_Msk;  /* enable HW flow control */
#else
    NRF_UART0->PSELRTS = 0xffffffff;            /* pin disconnected */
    NRF_UART0->PSELCTS = 0xffffffff;            /* pin disconnected */
#endif

    /* select baudrate */
    switch (baudrate) {
        case 1200:
            NRF_UART0->BAUDRATE = UART_BAUDRATE_BAUDRATE_Baud1200;
            break;
        case 2400:
            NRF_UART0->BAUDRATE = UART_BAUDRATE_BAUDRATE_Baud2400;
            break;
        case 4800:
            NRF_UART0->BAUDRATE = UART_BAUDRATE_BAUDRATE_Baud4800;
            break;
        case 9600:
            NRF_UART0->BAUDRATE = UART_BAUDRATE_BAUDRATE_Baud9600;
            break;
        case 14400:
            NRF_UART0->BAUDRATE = UART_BAUDRATE_BAUDRATE_Baud14400;
            break;
        case 19200:
            NRF_UART0->BAUDRATE = UART_BAUDRATE_BAUDRATE_Baud19200;
            break;
        case 28800:
            NRF_UART0->BAUDRATE = UART_BAUDRATE_BAUDRATE_Baud28800;
            break;
        case 38400:
            NRF_UART0->BAUDRATE = UART_BAUDRATE_BAUDRATE_Baud38400;
            break;
        case 57600:
            NRF_UART0->BAUDRATE = UART_BAUDRATE_BAUDRATE_Baud57600;
            break;
        case 76800:
            NRF_UART0->BAUDRATE = UART_BAUDRATE_BAUDRATE_Baud76800;
            break;
        case 115200:
            NRF_UART0->BAUDRATE = UART_BAUDRATE_BAUDRATE_Baud115200;
            break;
        case 230400:
            NRF_UART0->BAUDRATE = UART_BAUDRATE_BAUDRATE_Baud230400;
            break;
        case 250000:
            NRF_UART0->BAUDRATE = UART_BAUDRATE_BAUDRATE_Baud250000;
            break;
        case 460800:
            NRF_UART0->BAUDRATE = UART_BAUDRATE_BAUDRATE_Baud460800;
            break;
        case 921600:
            NRF_UART0->BAUDRATE = UART_BAUDRATE_BAUDRATE_Baud921600;
            break;
        default:
            return -2;
    }

    /* enable the UART device */
    NRF_UART0->ENABLE = UART_ENABLE_ENABLE_Enabled;
    /* enable TX and RX */
    NRF_UART0->TASKS_STARTTX = 1;
    NRF_UART0->TASKS_STARTRX = 1;
    /* enable global and receiving interrupt */
    NVIC_EnableIRQ(UART_IRQN);
    NRF_UART0->INTENSET = UART_INTENSET_RXDRDY_Msk;
    return 0;
}

void uart_write(uart_t uart, const uint8_t *data, size_t len)
{
    if (uart == 0) {
        for (size_t i = 0; i < len; i++) {
            /* write data into transmit register */
            NRF_UART0->TXD = data[i];
            /* wait for any transmission to be done */
            while (NRF_UART0->EVENTS_TXDRDY == 0) {}
            /* reset ready flag */
            NRF_UART0->EVENTS_TXDRDY = 0;
        }
    }
}

void uart_poweron(uart_t uart)
{
    (void)uart;
    NRF_UART0->TASKS_STARTRX = 1;
    NRF_UART0->TASKS_STARTTX = 1;
}

void uart_poweroff(uart_t uart)
{
    (void)uart;
    NRF_UART0->TASKS_SUSPEND;
}

void isr_uart0(void)
{
    if (NRF_UART0->EVENTS_RXDRDY == 1) {
        NRF_UART0->EVENTS_RXDRDY = 0;
        uint8_t byte = (uint8_t)(NRF_UART0->RXD & 0xff);
        uart_config.rx_cb(uart_config.arg, byte);
    }
    if (sched_context_switch_request) {
        thread_yield();
    }
}