yunweiban_NB/source/msp/UART1.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	&= ~BIT1;							   //p5.1输出TXD
//P5_DIR	|= BIT0;							   //p5.0输入RXD
//P5_SEL0 &= ~(BIT0 +BIT1);					   //设置P5.0  P5.1为UART0 RXD TXD 
//P5_SEL1 |= BIT0 +BIT1;

/*****************************************************************************
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_protocol_ 的公共协议包(关键的结构体)的声明------struct _s_protocol_
 							void L1_uart_2buf(struct _s_protocol_ *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 "uart0.h"	
struct _s_protocol_ s_at0; 


struct _s_send_buf_ s_send_pool;
struct _s_send_buf_ s_send_bath;
U8 L0_uart0_get(void){return SBUF;}

//#define D_uart_baudrate(X)	PCON |= U0BRD;	(256 - s_sys_para.sys_clock * (1 + 1) / (32 * X))

sbit led =P0^4;
void L0_uart0_init(void)
{
	//UART初始化
	PCON &= 0x7F;		//波特率不倍速
	SCON = 0x50;		//8位数据,可变波特率

	
//	AUXR |= 0x40;		//定时器1时钟为Fosc,即1T  去掉为9600
	AUXR &= 0xFE;		//串口1选择定时器1为波特率发生器

	//  0  1  0  1  
	// b7 b6 5 4 , 3 2 1 0
	//      0
	TMOD &= 0x0F;		//清除定时器1模式位
	TMOD |= 0x20;		//设定定时器1为8位自动重装方式
	TL1 = 0xFD;		//设定定时初值
	TH1 = 0xFD;		//设定定时器重装值
	ET1 = 0;		//禁止定时器1中断
	TR1 = 1;		//启动定时器1

	//L0_uart0_IntTIClear();
	//L0_uart0_IntSendStart();
	L0_uart0_IntSendOver();
	TI = 0;
	ES = 1;										 //打开串口中断 
	s_send_bath.p = s_send_bath.buf;
}


void L0_uart0_uc(U8 ww)
{
	s_send_bath.max = 1;
	s_send_bath.buf[0] = ww;
	s_send_bath.p = s_send_bath.buf;
	L0_uart0_sendbuf();
}


void L0_uart0_0d0a(void)
{
	s_send_bath.max = 2;
	s_send_bath.buf[0] = 0x0d;
	s_send_bath.buf[1] = 0x0a;
	s_send_bath.p = s_send_bath.buf;
	L0_uart0_sendbuf();
}
		//		L0_uart0_uc(cguHex2Char[D_uc_low(s->sec)][0]);
void L0_uart0_uchex(U8 ww)
{
	s_send_bath.max = 2;
	s_send_bath.buf[0] = cguHex2Char[D_uc_low(ww)][1];
	s_send_bath.buf[1] = cguHex2Char[D_uc_high(ww)][1];
	s_send_bath.p = s_send_bath.buf;
	L0_uart0_sendbuf();
}
void L0_uart0_ulhex(vU32 ww)
{
	U_U32 ultemp;
	ultemp.dWord = ww;	
	L0_uart0_uchex(ultemp.BYTE4.byte0);	
	L0_uart0_uchex(ultemp.BYTE4.byte1);
	L0_uart0_uchex(ultemp.BYTE4.byte2);
	L0_uart0_uchex(ultemp.BYTE4.byte3);		
}
#define D_SERVE_UART   interrupt 4



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

void INTERRUPT_UART(void)  D_SERVE_UART// using 2
{
	D_51_REG_ES(0);
//------------------------------------------------
	if(L0_uart0_IntRI())					//如果是U0接收中断	
	{L0_uart0_IntRIClear(); 				//清除接收中断标志
		//L1_uart_2buf(&s_at0);
		L1_uart_2strbuf(&s_at0);
		//D_led_D2_REV();
	}
//------------------------------------------------
	else
	{
		if(L0_uart0_IntTI())				//如果是U0发送中断
		{L0_uart0_IntTIClear();			//清除发送中断标志
			if(s_send_pool.max != s_send_pool.now)
			{
				L0_uart0_set(s_send_pool.buf[s_send_pool.now]);
				s_send_pool.now ++;
			}else
			{	
				s_send_pool.max = 0;s_send_pool.now = 0;
				L0_uart0_IntSendOver();		//可以发送下一个数据
			}
		}
	}	
	D_51_REG_ES(1);
}

#define D_task_uart0_0  0x10
#define D_task_uart0_buf_send  0x11
#define D_task_uart0_buf_pre  0x12
#define D_task_uart0_buf_over  0x13


//U8 packagea[] = "AT+CIPSEND=251\r\n";

void L0_uart0_sendstr(U8 *str)
{
	//L0_uart0_sendbuf(str,strlen(str));
	s_send_bath.max = strlen(str);
	s_send_bath.p = str;
	L0_uart0_sendbuf();
}


//  发送buf数组 中的0----(num-1)
void L0_uart0_sendbuf(void)
{	
	unsigned char n = 0;
	//s_send_bath.max = 1;
	//s_send_bath.0 = 1;
	//s_send_bath.buf[0] = ww;
	/// s_send_bath.buf  s_send_bath.max 已经在调用前写入
	if(s_send_bath.max>= D_send_buf_max)
	{
				s_send_bath.max = 3;
	}
	ES = 0;
	if(L0_uart0_SendIntFree())
	{///  上次的已经发送完毕了,或者第一次开始
	/// (s_send_pool.now == s_send_pool.max = 0 buf中为空)
		for(n = 0;n < s_send_bath.max; n++)
		{
			s_send_pool.buf[n] = s_send_bath.p[n]; 
		}
		//s_send_pool.now = 0;
		s_send_pool.max = s_send_bath.max;
		L0_uart0_IntTIClear();
		L0_uart0_IntSendStart();
		s_send_pool.now = 1;
		L0_uart0_set(s_send_pool.buf[0]);
	}else
	{// 需要插入
		///  [0]--?--[pool.now]--?--[pool.max-1].......................................
		///  [0]--?--[pool.now]--?--[pool.max]+[bath.0]--?---[bath.max-1].............
		for(n = 0;n < s_send_bath.max; n++)
		{
			s_send_pool.buf[s_send_pool.max] = s_send_bath.p[n];
			s_send_pool.max ++;
			if(s_send_pool.max >= D_send_buf_max)
			{
				s_send_pool.max = D_send_buf_max;
			}
		}
	}
	ES = 1;
}