rt-thread-official/bsp/loongson/ls1bdev/libraries/ls1b_uart.c

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/*
* Copyright (c) 2006-2018, RT-Thread Development Team
*
* SPDX-License-Identifier: Apache-2.0
*
* Change Logs:
* Date Author Notes
* 2021-02-02 michael5hzg@gmail.com adapt to ls1b
*/
// 串口相关源码
#include <stdio.h>
#include <stdarg.h>
#include "ls1b_public.h"
#include "ls1b_regs.h"
#include "ls1b_pin.h"
#include "ls1b_uart.h"
#include "ls1b_clock.h"
#include "ls1b.h"
// 串口线路状态寄存器的位域
#define LS1B_UART_LSR_TE (1 << 6)
#define LS1B_UART_LSR_TFE (1 << 5)
// 打印缓存的大小
#define LS1B_UART_PRINT_BUF_SIZE (256)
// 调试串口信息
ls1b_uart_info_t debug_uart_info = {0};
/*
*
* @UARTx
* @ret
*/
void *uart_get_base(ls1b_uart_t UARTx)
{
void *base = NULL;
switch (UARTx)
{
case LS1B_UART00:
base = (void *)LS1B_UART00_BASE;
break;
case LS1B_UART01:
base = (void *)LS1B_UART01_BASE;
break;
case LS1B_UART1:
base = (void *)LS1B_UART1_BASE;
break;
case LS1B_UART2:
base = (void *)LS1B_UART2_BASE;
break;
case LS1B_UART3:
base = (void *)LS1B_UART3_BASE;
break;
case LS1B_UART4:
base = (void *)LS1B_UART4_BASE;
break;
case LS1B_UART5:
base = (void *)LS1B_UART5_BASE;
break;
case LS1B_UART6:
base = (void *)LS1B_UART6_BASE;
break;
case LS1B_UART7:
base = (void *)LS1B_UART7_BASE;
break;
case LS1B_UART8:
base = (void *)LS1B_UART8_BASE;
break;
case LS1B_UART9:
base = (void *)LS1B_UART9_BASE;
break;
case LS1B_UART10:
base = (void *)LS1B_UART10_BASE;
break;
case LS1B_UART11:
base = (void *)LS1B_UART11_BASE;
break;
default:
break;
}
return base;
}
/*
*
* @uart_info_p
*/
void uart_init(ls1b_uart_info_t *uart_info_p)
{
void *uart_base = uart_get_base(uart_info_p->UARTx);
unsigned long baudrate_div = 0;
// 禁止所有中断
reg_write_8(0, uart_base + LS1B_UART_IER_OFFSET);
// 接收FIFO的中断申请Trigger为14字节清空发送和接收FIFO并复位
reg_write_8(0xc3, uart_base + LS1B_UART_FCR_OFFSET);
// 设置波特率
reg_write_8(0x80, uart_base + LS1B_UART_LCR_OFFSET);
baudrate_div = clk_get_apb_rate() / 16 / uart_info_p->baudrate;
reg_write_8((baudrate_div >> 8) & 0xff, uart_base + LS1B_UART_MSB_OFFSET);
reg_write_8(baudrate_div & 0xff, uart_base + LS1B_UART_LSB_OFFSET);
// 8个数据位1个停止位无校验
reg_write_8(0x03, uart_base + LS1B_UART_LCR_OFFSET);
// 使能接收中断
if (TRUE == uart_info_p->rx_enable)
{
reg_write_8(IER_IRxE|IER_ILE , uart_base + LS1B_UART_IER_OFFSET);
}
return ;
}
/*
* FIFO是否为空
* @uartx
* @ret TRUE or FALSE
*/
BOOL uart_is_transmit_empty(ls1b_uart_t uartx)
{
void *uart_base = uart_get_base(uartx);
unsigned char status = reg_read_8(uart_base + LS1B_UART_LSR_OFFSET);
if (status & (LS1B_UART_LSR_TE | LS1B_UART_LSR_TFE))
{
return TRUE;
}
else
{
return FALSE;
}
}
/*
*
* @uartx
* @ch
*/
void uart_putc(ls1b_uart_t uartx, unsigned char ch)
{
void *uart_base = uart_get_base(uartx);
// 等待
while (FALSE == uart_is_transmit_empty(uartx))
;
// 发送
reg_write_8(ch, uart_base + LS1B_UART_DAT_OFFSET);
return ;
}
/*
*
* @uartx
* @str
*/
void uart_print(ls1b_uart_t uartx, const char *str)
{
while ('\0' != *str) // 判断是否为字符串结束符
{
uart_putc(uartx, *str); // 发送一个字符
str++;
}
return ;
}
/*
* 2
*/
void uart2_init(void)
{
unsigned int tx_gpio = 37;
unsigned int rx_gpio = 36;
// 设置复用
pin_set_remap(tx_gpio, PIN_REMAP_SECOND);
pin_set_remap(rx_gpio, PIN_REMAP_SECOND);
// 初始化相关寄存器
debug_uart_info.UARTx = LS1B_UART2;
debug_uart_info.baudrate = 115200;
debug_uart_info.rx_enable = FALSE; // 调试串口只需要打印(发送)功能,不需要接收功能
uart_init(&debug_uart_info);
return ;
}
/*
* 2
* @str
*/
void uart2_print(const char *str)
{
uart_print(LS1B_UART2, str);
return ;
}
/*
*
* @str
*/
void uart_debug_print(const char *str)
{
uart_print(debug_uart_info.UARTx, str);
return ;
}
/*
*
* @ch
*/
void uart_debug_putc(unsigned char ch)
{
uart_putc(debug_uart_info.UARTx, ch);
return ;
}