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ttss_sop/source/msp/UART2.c

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//////////////////////////////////////////////////////////////////////////
/// COPYRIGHT NOTICE
/// Copyright (c) 2015, 传控科技
/// All rights reserved.
///
/// @file main.c
/// @brief main app
///
///(本文件实现的功能的详述)
///
/// @version 1.1 CCsens technology
/// @author CC
/// @date 20150102
///
///
/// 修订说明:最初版本
/// Modified by:
/// Modified date:
/// Version:
/// Descriptions:
// 20160413 CC-ACC-VH02
// 连接至 J22 RXD0 TXD0
//P5_DIR &= ~BITN1; //p5.1输出TXD
//P5_DIR |= BITN0; //p5.0输入RXD
//P5_SEL0 &= ~(BITN0 +BITN1); //设置P5.0 P5.1为UART0 RXD TXD
//P5_SEL1 |= BITN0 +BITN1;
/*****************************************************************************
update by cc @201700110
针对多串口 和 单一串口 有区别 每个串口是独立的还是分开的有讲究 程序是复杂的还是软件应用简单是
个需要平衡的事情.
clib/clib.c:
公用的函数 和硬件无关
放置串行模式(串口等其他通讯总线类的输出)输出的函数,
一些覆盖模式输出的(lcd等固屏输出的)的也可使用
void Lc_print(void (*L0pf_send_uc)(char ww), char *dat,...)
-----------------------------------------------------------------------------------------
uartcom/Uprotocol2app
协议到应用
为了适应不同的通讯协议需要不同的uart口来对应 和应用相关
typedef struct _ts_lcm_pro_; 应用协议包的定义? LCM的协议------------
L3_UARTcom0_exp_protocol 解析应用协议
-----------------------------------------------------------------------------------------
uartcom/urec2protocol: 接收到的数据放入到指向特定协议的缓存中,和协议的格式有关 一般分为 标头式或者标尾式
公用的串口通讯定义
struct _s_uart_rec_ 的公共协议包(关键的结构体)的声明------struct _s_uart_rec_
void L1_uart_2buf(struct _s_uart_rec_ *p)串行数据保存到指向特定协议的缓冲中
--------------------------------------------------------------------------------------------
msp/uartx.c 底层代码 和cpu相关 缓存发送也放在里面
L0_UART0_Init
UART0_IRQHandler
L0_Usend_uc------UserDef
-----------------------------------------------------------------------------------------
********************************************************************************/
#include "uart2.h"
#include "../app/common.h"
//发送缓冲区
static volatile Ts_uart_send_buf idata ts_uart_send_buf;
//接收缓冲区最多存放16个字符,这个值尽量小,但要大于实际处理协议的缓冲区大小
static U8 uart2_recv_buf[16];
Ts_uart_recv_buf ts_uart2_recv_buf;
void L0_uart2_init(void)
{
#if(MainFre_11M == D_sys_MainFre) //115200bps@11.0592MHz
S2CON = 0x50; //8位数据,可变波特率
AUXR |= 0x04; //定时器2时钟为Fosc,即1T
T2L = 0xE8; //设定定时初值
T2H = 0xFF; //设定定时初值
AUXR |= 0x10; //启动定时器2
#elif (MainFre_22M == D_sys_MainFre) //115200bps@22.1184MHz
S2CON = 0x50; //8位数据,可变波特率
AUXR |= 0x04; //定时器2时钟为Fosc,即1T
T2L = 0xD0; //设定定时初值
T2H = 0xFF; //设定定时初值
AUXR |= 0x10; //启动定时器2
#endif
}
void L0_uart2_buf_init(void)
{
ts_uart[uNum2].p = &ts_uart_send_buf;
ts_uart[uNum2].p->now = 0;
ts_uart[uNum2].p->ok = D_ready;
ts_uart[uNum2].t = &ts_uart_recv_buf;
ts_uart[uNum2].t->buf = uart2_recv_buf;
ts_uart[uNum2].t->head_0 = D_CMD_Filter1_ff;
ts_uart[uNum2].t->head_1 = D_CMD_Filter2_fe;
ts_uart[uNum2].t->head = 0;
ts_uart[uNum2].t->ok = 0;
ts_uart[uNum2].tp_handler = L1_s2b_PH3;
L0_uart2_init();
D_uart2_ES_INT(1); //打开串口中断
#if (D_UART2_485_TYPE != TYPE_485_NONE)
D_UART2_485_RX() //默认处于接收状态
#endif
}
void L0_uart2_sendArray(U8 * buf, U16 len)
{
#if (D_UART2_485_TYPE != TYPE_485_NONE)
D_UART2_485_TX() //切换到输出状态
#endif
L0_uartN_sendArray(uNum2,buf,len);
}
/*************************************************
UART 中断
*************************************************/
#define D_SERVE_uart2 interrupt 8
void INTERRUPT_uart2(void) D_SERVE_uart2// using 2
{
//NOP(); NOP(); NOP();
if(L0_uart2_IntRI()) //如果是U2接收中断
{
L0_uart2_IntRIClear(); //清除接收中断标志
ts_uart[uNum2].t->reg = L0_uartN_get(uNum2);
ts_uart[uNum2].tp_handler(ts_uart[uNum2].t));
}
if(L0_uart2_IntTI()) //如果是U0发送中断
{
L0_uart2_IntTIClear(); //清除发送中断标志
if(ts_uart[uNum2].p->max != ts_uart[uNum2].p->now)
{
L0_uartN_set(uNum2,ts_uart[uNum2].p->p[ts_uart[uNum2].p->now]);
ts_uart[uNum2].p->now ++;
}
else
{
ts_uart[uNum2].p->ok = D_ready;
ts_uart[uNum2].p->max = 0;
ts_uart[uNum2].p->now = 0;//可以发送下一个数据
#if (D_UART2_485_TYPE != TYPE_485_NONE)
D_UART2_485_RX() //切换到接收状态
#endif
}
}
//NOP(); NOP(); NOP();
}