ttss_sop/source/msp/UART4.C

//////////////////////////////////////////////////////////////////////////  
/// 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uart4 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_uart4_Init
						uart4_IRQHandler
						    	L0_Usend_uc------UserDef
-----------------------------------------------------------------------------------------
********************************************************************************/
#include "uart4.h"

//#define _USE_485

static volatile Ts_uart_send_buf idata ts_uart_send_shop;
//TP_Handler_X s_uart4_at_rec;
//TP_Handler_X s_uart4_tcp_rec; 
TP_Handler_X s_uart4_rec;
TS_PH3_ccmodbus s_uart4_ack;

//#define FOSC 11059200L          //系统频率
//#define BAUD4 115200             //串口波特率
void L0_uart4_init(void)//115200bps@11.0592MHz
{
	#if(MainFre_11M == D_sys_MainFre)
#if 0
    S4CON = 0x50;               //8位可变波特率
    T4L = (65536 - (FOSC/4/BAUD4));   //设置波特率重装值
    T4H = (65536 - (FOSC/4/BAUD4))>>8;
    T4T3M |= 0x20;              //定时器4为1T模式
    T4T3M |= 0x80;              //定时器4开始计时
#else
	S4CON = 0x10;		//8位数据,可变波特率
	S4CON |= 0x40;		//串口4选择定时器4为波特率发生器
	T4T3M |= 0x20;		//定时器4时钟为Fosc,即1T
	T4L = 0xE8;		//设定定时初值
	T4H = 0xFF;		//设定定时初值
	T4T3M |= 0x80;		//启动定时器4
#endif
	
	
#elif (MainFre_22M == D_sys_MainFre)	//115200bps@22.1184MHz
	S4CON = 0x10;		//8位数据,可变波特率
	S4CON |= 0x40;		//串口4选择定时器4为波特率发生器
	T4T3M |= 0x20;		//定时器4时钟为Fosc,即1T
	T4L = 0xD0;		//设定定时初值
	T4H = 0xFF;		//设定定时初值
	T4T3M |= 0x80;		//启动定时器4
#endif
}

void L0_uart4_buf_init(void)
{						
	ts_uart[uNum4].p = &ts_uart_send_shop;
	ts_uart[uNum4].p->now = 0;
	ts_uart[uNum4].p->ok = D_ready;
	ts_uart[uNum4].t = &s_uart4_rec;
	ts_uart[uNum4].t->head_0 = D_CMD_Filter1_ff;
	ts_uart[uNum4].t->head_1 = D_CMD_Filter2_fe;
	ts_uart[uNum4].t->head = 0;
	ts_uart[uNum4].t->ok = 0;
	ts_uart[uNum4].tp_handler = L1_s2b_PH3;
	ts_uart[uNum4].ack = (U8*)&s_uart4_ack;
	
	//s_uart4_tcp_rec.head_0 = D_CMD_Filter1_ff;
	//s_uart4_tcp_rec.head_1 = D_CMD_Filter2_fe;
	//s_uart4_tcp_rec.head = 0;
	//s_uart4_tcp_rec.ok = 0;
	L0_uart4_init();
	D_uart4_ES_INT(1); //打开串口中断
	
#if (D_UART4_485_TYPE != TYPE_485_NONE)
	D_UART4_485_RX() //默认处于接收状态
#endif
}

void L0_uart4_sendArray(U8 * buf, U16 len)
{
#if (D_UART4_485_TYPE != TYPE_485_NONE)
	D_UART4_485_TX() //切换到输出状态
#endif
	L0_uartN_sendArray(uNum4,buf,len);
}

/*************************************************
UART 中断
*************************************************/

#define D_SERVE_uart4   interrupt 18
void INTERRUPT_uart4(void)  D_SERVE_uart4// using 2
{
#if 1
	//NOP();	NOP();	NOP();
	if(L0_uart4_IntRI())					//如果是U0接收中断	
	{
		L0_uart4_IntRIClear(); 				//清除接收中断标志
		ts_uart[uNum4].t->reg = L0_uartN_get(uNum4);
		ts_uart[uNum4].tp_handler(ts_uart[uNum4].t);
	}
	if(L0_uart4_IntTI())					//如果是U0发送中断
	{
		L0_uart4_IntTIClear(); 				//清除发送中断标志
		if(ts_uart[uNum4].p->max != ts_uart[uNum4].p->now)
		{
			L0_uartN_set(uNum4,ts_uart[uNum4].p->p[ts_uart[uNum4].p->now]);
			ts_uart[uNum4].p->now ++;
		}
		else
		{
			ts_uart[uNum4].p->ok = D_ready;
			ts_uart[uNum4].p->max = 0;
			ts_uart[uNum4].p->now = 0;//可以发送下一个数据
#if (D_UART4_485_TYPE != TYPE_485_NONE)
			D_UART4_485_RX() //切换到接收状态
#endif

		}
	}
	//NOP();	NOP();	NOP();
#endif
}
v0.1 4 years ago			`//////////////////////////////////////////////////////////////////////////`
			`/// 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uart4 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_uart4_Init`
			`uart4_IRQHandler`
			`L0_Usend_uc------UserDef`
			`-----------------------------------------------------------------------------------------`
			`********************************************************************************/`
			`#include "uart4.h"`

			`//#define _USE_485`

			`static volatile Ts_uart_send_buf idata ts_uart_send_shop;`
			`//TP_Handler_X s_uart4_at_rec;`
			`//TP_Handler_X s_uart4_tcp_rec;`
			`TP_Handler_X s_uart4_rec;`
			`TS_PH3_ccmodbus s_uart4_ack;`

			`//#define FOSC 11059200L //系统频率`
			`//#define BAUD4 115200 //串口波特率`
			`void L0_uart4_init(void)//115200bps@11.0592MHz`
			`{`
			`#if(MainFre_11M == D_sys_MainFre)`
			`#if 0`
			`S4CON = 0x50; //8位可变波特率`
			`T4L = (65536 - (FOSC/4/BAUD4)); //设置波特率重装值`
			`T4H = (65536 - (FOSC/4/BAUD4))>>8;`
			`T4T3M \|= 0x20; //定时器4为1T模式`
			`T4T3M \|= 0x80; //定时器4开始计时`
			`#else`
			`S4CON = 0x10; //8位数据,可变波特率`
			`S4CON \|= 0x40; //串口4选择定时器4为波特率发生器`
			`T4T3M \|= 0x20; //定时器4时钟为Fosc,即1T`
			`T4L = 0xE8; //设定定时初值`
			`T4H = 0xFF; //设定定时初值`
			`T4T3M \|= 0x80; //启动定时器4`
			`#endif`


			`#elif (MainFre_22M == D_sys_MainFre) //115200bps@22.1184MHz`
			`S4CON = 0x10; //8位数据,可变波特率`
			`S4CON \|= 0x40; //串口4选择定时器4为波特率发生器`
			`T4T3M \|= 0x20; //定时器4时钟为Fosc,即1T`
			`T4L = 0xD0; //设定定时初值`
			`T4H = 0xFF; //设定定时初值`
			`T4T3M \|= 0x80; //启动定时器4`
			`#endif`
			`}`

			`void L0_uart4_buf_init(void)`
			`{`
			`ts_uart[uNum4].p = &ts_uart_send_shop;`
			`ts_uart[uNum4].p->now = 0;`
			`ts_uart[uNum4].p->ok = D_ready;`
			`ts_uart[uNum4].t = &s_uart4_rec;`
			`ts_uart[uNum4].t->head_0 = D_CMD_Filter1_ff;`
			`ts_uart[uNum4].t->head_1 = D_CMD_Filter2_fe;`
			`ts_uart[uNum4].t->head = 0;`
			`ts_uart[uNum4].t->ok = 0;`
			`ts_uart[uNum4].tp_handler = L1_s2b_PH3;`
			`ts_uart[uNum4].ack = (U8*)&s_uart4_ack;`

			`//s_uart4_tcp_rec.head_0 = D_CMD_Filter1_ff;`
			`//s_uart4_tcp_rec.head_1 = D_CMD_Filter2_fe;`
			`//s_uart4_tcp_rec.head = 0;`
			`//s_uart4_tcp_rec.ok = 0;`
			`L0_uart4_init();`
			`D_uart4_ES_INT(1); //打开串口中断`

			`#if (D_UART4_485_TYPE != TYPE_485_NONE)`
			`D_UART4_485_RX() //默认处于接收状态`
			`#endif`
			`}`

			`void L0_uart4_sendArray(U8 * buf, U16 len)`
			`{`
			`#if (D_UART4_485_TYPE != TYPE_485_NONE)`
			`D_UART4_485_TX() //切换到输出状态`
			`#endif`
			`L0_uartN_sendArray(uNum4,buf,len);`
			`}`

			`/*************************************************`
			`UART 中断`
			`*************************************************/`

			`#define D_SERVE_uart4 interrupt 18`
			`void INTERRUPT_uart4(void) D_SERVE_uart4// using 2`
			`{`
			`#if 1`
			`//NOP(); NOP(); NOP();`
			`if(L0_uart4_IntRI()) //如果是U0接收中断`
			`{`
			`L0_uart4_IntRIClear(); //清除接收中断标志`
			`ts_uart[uNum4].t->reg = L0_uartN_get(uNum4);`
			`ts_uart[uNum4].tp_handler(ts_uart[uNum4].t);`
			`}`
			`if(L0_uart4_IntTI()) //如果是U0发送中断`
			`{`
			`L0_uart4_IntTIClear(); //清除发送中断标志`
			`if(ts_uart[uNum4].p->max != ts_uart[uNum4].p->now)`
			`{`
			`L0_uartN_set(uNum4,ts_uart[uNum4].p->p[ts_uart[uNum4].p->now]);`
			`ts_uart[uNum4].p->now ++;`
			`}`
			`else`
			`{`
			`ts_uart[uNum4].p->ok = D_ready;`
			`ts_uart[uNum4].p->max = 0;`
			`ts_uart[uNum4].p->now = 0;//可以发送下一个数据`
			`#if (D_UART4_485_TYPE != TYPE_485_NONE)`
			`D_UART4_485_RX() //切换到接收状态`
			`#endif`

			`}`
			`}`
			`//NOP(); NOP(); NOP();`
			`#endif`
			`}`