added CAST5, CAST6, RC5 and RC6

[arm-crypto-lib.git] / test_src / uart_i.c

/* uart_i.c */
/*
    This file is part of the OpenARMWare.
    Copyright (C) 2010 Daniel Otte (daniel.otte@rub.de)

    This program is free software: you can redistribute it and/or modify
    it under the terms of the GNU General Public License as published by
    the Free Software Foundation, either version 3 of the License, or
    (at your option) any later version.

    This program is distributed in the hope that it will be useful,
    but WITHOUT ANY WARRANTY; without even the implied warranty of
    MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
    GNU General Public License for more details.

    You should have received a copy of the GNU General Public License
    along with this program.  If not, see <http://www.gnu.org/licenses/>.
*/

#include <stdint.h>
#include "sysclock.h"
#include "hw_regs.h"
#include "hw_uart_regs.h"
#include "uart_defines.h"
#include "circularbytebuffer.h"
#include "uart_lowlevel.h"

static const
uint32_t uart_base[] = { UART0_BASE, UART1_BASE, UART2_BASE };

static const
uint32_t gpio_base[] =
        { GPIOA_BASE, GPIOB_BASE, GPIOC_BASE, GPIOD_BASE,
          GPIOE_BASE, GPIOF_BASE, GPIOG_BASE, GPIOH_BASE,
          GPIOJ_BASE,
        };

static const
uint8_t uart_tx_gpio[] = { GPIOA, GPIOD, GPIOG };
static const
uint8_t uart_rx_gpio[] = { GPIOA, GPIOD, GPIOG };
static const
uint8_t uart_tx_pin[] = { 1, 1, 1 };
static const
uint8_t uart_rx_pin[] = { 0, 0, 0 };
static const
uint8_t uart_tx_pctl[] = {1, 5, 1};
static const
uint8_t uart_rx_pctl[] = {1, 5, 1};
static const
uint8_t uart_isr_vector[] = {5, 6, 33};

static const
uint32_t uart_rx_buffersize[] = {128, 128, 128};
static const
uint32_t uart_tx_buffersize[] = {256, 256, 256};
static
uint8_t uart_swflowctrl_en[] = {0, 0, 0};
static
uint8_t uart_swflowctrl_halt[] = {0, 0, 0};

static
circularbytebuffer_t uart_rx_buffer[3];
static
circularbytebuffer_t uart_tx_buffer[3];


static
void uart_tx_isr(uint8_t uartno);
static
void uart_rx_isr(uint8_t uartno);

void uart0_isr(void){
        if(HW_REG(UART0_BASE+UARTMIS_OFFSET)&_BV(UART_TXMIS)){
//              HW_REG(uart_base[0]+UARTDR_OFFSET) = 'X';
                uart_tx_isr(UART_0);
        }
        if(HW_REG(UART0_BASE+UARTMIS_OFFSET)&_BV(UART_RXMIS)){
                uart_rx_isr(UART_0);
        }
}

static
void uart_tx_isr(uint8_t uartno){
        uint32_t tmp;
        tmp = circularbytebuffer_cnt(&(uart_tx_buffer[uartno]));
        while(tmp-- && (!(HW_REG(uart_base[uartno]+UARTFR_OFFSET)&_BV(UART_TXFF)))
                  && !(uart_swflowctrl_en[uartno] && uart_swflowctrl_halt[uartno])){
                HW_REG(uart_base[uartno]+UARTDR_OFFSET)
                                = (uint32_t)circularbytebuffer_get_fifo(&(uart_tx_buffer[uartno]));
        }
        HW_REG(uart_base[uartno]+UARTICR_OFFSET) |= _BV(UART_TXIC);
}

static
void uart_rx_isr(uint8_t uartno){
        uint8_t c;
        while(!HW_REG(uart_base[uartno]+UARTFR_OFFSET)&_BV(UART_RXFE)){
                c = HW_REG(uart_base[uartno]+UARTDR_OFFSET);
                if(uart_swflowctrl_en[uartno]){
                        circularbytebuffer_append(c, &(uart_rx_buffer[uartno]));
                }else{
                        if(c==UART_XON_CHAR){
                                uart_swflowctrl_halt[uartno] = 0;
                        }else{
                                if(c==UART_XOFF_CHAR){
                                        uart_swflowctrl_halt[uartno] = 1;
                                }else{
                                        circularbytebuffer_append(c, &(uart_rx_buffer[uartno]));
                                }
                        }
                }
        }
        HW_REG(uart_base[uartno]+UARTICR_OFFSET) |= _BV(UART_RXIC);
}

void calc_baud_values(uint32_t baudrate, uint16_t* intdivider, uint8_t* fracdivider, uint8_t* highspeed){
        uint32_t tmp;
        uint32_t uart_freq;
        uart_freq = sysclk_get_freq();
        *highspeed = (baudrate*16>uart_freq)?1:0;
        tmp = (uint64_t)uart_freq*128/((*highspeed?8:16)*baudrate);
        tmp++;
        tmp>>=1;
        *fracdivider = (uint8_t)(tmp&0x3f);
        *intdivider = tmp>>6;
}

uint8_t uart_init(uint8_t uartno, uint32_t baudrate, uint8_t databits, uint8_t paraty, uint8_t stopbits){
        return uart_init_flow(uartno, baudrate, databits, paraty, stopbits, 0);
}

uint8_t uart_init_flow(uint8_t uartno, uint32_t baudrate, uint8_t databits, uint8_t paraty, uint8_t stopbits, uint8_t flowctrl){
        uint32_t tmp;
        if(databits>=5){
                databits-=5;
        }
        if(uartno>UART_MAX){
                return UART_ERROR_WRONG_UART;
        }
        if(databits>UART_DATABITS_8){
                return UART_ERROR_WRONG_DATABITS;
        }
        if(paraty>UART_PARATY_SPACE){
                return UART_ERROR_WRONG_PARATY;
        }
        if(stopbits>UART_STOPBITS_TWO){
                return UART_ERROR_WRONG_STOPBITS;
        }
        if(0==circularbytebuffer_init(uart_rx_buffersize[uartno], &(uart_rx_buffer[uartno]))){
                return UART_ERROR_RX_BUFFER_INIT;
        }
        if(0==circularbytebuffer_init(uart_tx_buffersize[uartno], &(uart_tx_buffer[uartno]))){
                return UART_ERROR_TX_BUFFER_INIT;
        }
        /* enable clock for uart */
        HW_REG(SYSCTL_BASE+RCGC1_OFFSET) |= _BV(uartno);
        /* enable clock for gpio*/
        HW_REG(SYSCTL_BASE+RCGC2_OFFSET) |= _BV(uart_rx_gpio[uartno]) | _BV(uart_tx_gpio[uartno]);
    HW_REG(SYSCTL_BASE+RCGC2_OFFSET) |= 1;

    HW_REG(gpio_base[uart_rx_gpio[uartno]] + GPIO_ODR_OFFSET) &= ~_BV(uart_rx_pin[uartno]); /* open drain */
    HW_REG(gpio_base[uart_tx_gpio[uartno]] + GPIO_ODR_OFFSET) &= ~_BV(uart_tx_pin[uartno]); /* open drain */
    HW_REG(gpio_base[uart_rx_gpio[uartno]] + GPIO_PUR_OFFSET) &= ~_BV(uart_rx_pin[uartno]); /* pull-up */
    HW_REG(gpio_base[uart_tx_gpio[uartno]] + GPIO_PUR_OFFSET) &= ~_BV(uart_tx_pin[uartno]); /* pull-up */
    HW_REG(gpio_base[uart_rx_gpio[uartno]] + GPIO_PDR_OFFSET) &= ~_BV(uart_rx_pin[uartno]); /* pull-down*/
    HW_REG(gpio_base[uart_tx_gpio[uartno]] + GPIO_PDR_OFFSET) &= ~_BV(uart_tx_pin[uartno]); /* pull-down*/
    HW_REG(gpio_base[uart_rx_gpio[uartno]] + GPIO_DEN_OFFSET) |=  _BV(uart_rx_pin[uartno]); /* digital enable */
    HW_REG(gpio_base[uart_tx_gpio[uartno]] + GPIO_DEN_OFFSET) |=  _BV(uart_tx_pin[uartno]); /* digital enable */

        /* switch to alternate function for rx */
        HW_REG(gpio_base[uart_rx_gpio[uartno]]+GPIO_AFSEL_OFFSET) |= _BV(uart_rx_pin[uartno]);
         /* switch to alternate function for tx */
        HW_REG(gpio_base[uart_tx_gpio[uartno]]+GPIO_AFSEL_OFFSET) |= _BV(uart_tx_pin[uartno]);
        /* switch multiplexer to uart for rx */
        HW_REG(gpio_base[uart_rx_gpio[uartno]]+GPIO_PCTL_OFFSET) &= ~(0x0f<<(uart_rx_pin[uartno]*4));
        HW_REG(gpio_base[uart_rx_gpio[uartno]]+GPIO_PCTL_OFFSET) |= ((uart_rx_pctl[uartno])<<(uart_rx_pin[uartno]*4));
        /* switch multiplexer to uart for tx */
        HW_REG(gpio_base[uart_tx_gpio[uartno]]+GPIO_PCTL_OFFSET) &= ~(0x0f<<(uart_tx_pin[uartno]*4));
        HW_REG(gpio_base[uart_tx_gpio[uartno]]+GPIO_PCTL_OFFSET) |= ((uart_tx_pctl[uartno])<<(uart_tx_pin[uartno]*4));
        /* set pins to be 2mA */
        HW_REG(gpio_base[uart_rx_gpio[uartno]]+GPIO_DR2R_OFFSET) |= _BV(uart_rx_pin[uartno]);
        HW_REG(gpio_base[uart_tx_gpio[uartno]]+GPIO_DR2R_OFFSET) |= _BV(uart_tx_pin[uartno]);
        /* configure rx pin as input */
        HW_REG(gpio_base[uart_rx_gpio[uartno]]+GPIO_DIR_OFFSET) &= ~_BV(uart_rx_pin[uartno]);
        /* configure tx pin as output */
        HW_REG(gpio_base[uart_tx_gpio[uartno]]+GPIO_DIR_OFFSET) |= _BV(uart_tx_pin[uartno]);

        /* disable uart */
        HW_REG(uart_base[uartno]+UARTCTL_OFFSET) &= ~_BV(UART_UARTEN);
        /* set baudrate parameters */
        uint8_t highspeed;
        calc_baud_values(baudrate,
                                 (uint16_t*)&HW_REG(uart_base[uartno]+UARTIBRD_OFFSET),
                                 (uint8_t*)&HW_REG(uart_base[uartno]+UARTFBRD_OFFSET),
                                 &highspeed);
        /* wait until uart is no longer busy */
        while(HW_REG(uart_base[uartno]+UARTFR_OFFSET)&_BV(UART_BUSY))
                ;
        /* flush FIFOs */
        HW_REG(uart_base[uartno]+UARTLCRH_OFFSET) &= ~_BV(UART_FEN);
        /* set line parameters (bits, paraty, stopbits*/
        tmp = HW_REG(uart_base[uartno]+UARTLCRH_OFFSET);
        tmp &= ~0xff;
        tmp |= (paraty==UART_PARATY_MARK||paraty==UART_PARATY_SPACE)?_BV(7):0; /* set flag for mark or space paraty*/
        tmp |= databits<<5;
        tmp |= _BV(UART_FEN); /* enable FIFOs */
        tmp |= (stopbits==UART_STOPBITS_TWO)?_BV(3):0;
        tmp |= (paraty==UART_PARATY_EVEN || paraty==UART_PARATY_MARK)?_BV(2):0;
        tmp |= (paraty!=UART_PARATY_NONE)?_BV(1):0;
        HW_REG(uart_base[uartno]+UARTLCRH_OFFSET) = tmp;
        /* set the highspeed bit accordingly */
        if(highspeed){
                HW_REG(uart_base[uartno]+UARTCTL_OFFSET) |= _BV(UART_HSE);
        } else {
                HW_REG(uart_base[uartno]+UARTCTL_OFFSET) &= ~_BV(UART_HSE);
        }
        /* set flow control */
        if(flowctrl==UART_FLOWCTRL_SOFT){
                uart_swflowctrl_en[uartno] = 1;
                uart_swflowctrl_halt[uartno] = 0;
        }else{
                uart_swflowctrl_en[uartno] = 0;
        }
        /* uart interrupt enable */
        HW_REG(uart_base[uartno]+UARTIM_OFFSET) |= _BV(UART_TXIM) | _BV(UART_RXIM);
        HW_REG(ISR_ENABLE_VECTOR+uart_isr_vector[uartno]/32) |=
                        _BV(uart_isr_vector[uartno]%32);

        HW_REG(uart_base[uartno]+UARTCTL_OFFSET) |= _BV(UART_EOT);
        HW_REG(uart_base[uartno]+UARTFR_OFFSET) = 0;
        HW_REG(uart_base[uartno]+UARTCTL_OFFSET) |= _BV(UART_RXE) | _BV(UART_TXE);
        HW_REG(uart_base[uartno]+UARTCTL_OFFSET) |= _BV(UART_UARTEN);

        return UART_ERROR_OK;
}


void uart_putc(uint8_t uartno, uint8_t byte){
        if(uartno>UART_MAX){
                return;
        }
        /* wait while buffer is full */
        while(circularbytebuffer_cnt(&(uart_tx_buffer[uartno]))==uart_tx_buffersize[uartno]){
        }
        if(circularbytebuffer_cnt(&(uart_tx_buffer[uartno]))>0){
                circularbytebuffer_append(byte, &(uart_tx_buffer[uartno]));
                return;
        }
        /* if we have a full uart, append to buffer */
        if(HW_REG(uart_base[uartno]+UARTFR_OFFSET)&_BV(UART_TXFF)){
                circularbytebuffer_append(byte, &(uart_tx_buffer[uartno]));
                return;
        }
        HW_REG(uart_base[uartno]+UARTDR_OFFSET) = (uint32_t)byte;
}

uint16_t uart_getc(uint8_t uartno){
        if(uartno>UART_MAX){
                return 0xffff;
        }
        if(circularbytebuffer_cnt(&(uart_rx_buffer[uartno]))){
                return circularbytebuffer_get_fifo(&(uart_rx_buffer[uartno]));
        }
        /* wait while the FIFO is empty */
        while(HW_REG(uart_base[uartno]+UARTFR_OFFSET)&_BV(UART_RXFE))
                ;
        return (uint16_t)HW_REG(uart_base[uartno]+UARTDR_OFFSET);
}

uint32_t uart_dataavail(uint8_t uartno){
        if(uartno>UART_MAX){
                return 0;
        }
        /* wait while the FIFO is empty */
        if(circularbytebuffer_cnt(&(uart_rx_buffer[uartno]))){
                return 1;
        }
        return(HW_REG(uart_base[uartno]+UARTFR_OFFSET)&_BV(UART_RXFE))?0:1;
}