//------------------------------------------------------
// CAN <==> UART的协议转换器
//
// 程序名称：CAN <---> UART协议转换程序<透明方式>
//
// 作者： LPC
// 创建： 2007-10-09
//
// 说明：
// 1，单片机使用P89C61X2BA
// --晶振11.0592MHZ
// --CAN总线中断使用单片机的中断0，外部有上拉电阻,波特率可以设定
// 2，CAN总线发送采用查询方式，接收采用中断方式
// 3，看门狗复位时间1.2S
// 4，SJA1000晶振8MHZ,Peil模式
// 5，串口中断接收，查询发送，波特率可设置
// 6，×××当串口收到数据后，每8个数一组打包，通过CAN总线发送出去
//
// -----10.16日，重新修改程序完成以下功能-----
// ----此功能已经改为，每收到一帧数据，启动一次CAN传输，传输字节数等于串口收到的数据
// ----串行帧的帧间界定通过当前波特率下传输5个字节为时间间隔，具体为当顺序接收到的任
// 意两个数据，它们之间的时间间隔大于5个字节传送时间，认为这两个数据分属于两个不
// 同的帧
//
// 7，当CAN总线每接收一帧信息后，通过串口发送出去
// -----10.15日，改为可以识别CAN的报文字节长度，即串口只发送CAN报文长度个字节
// 8，看门狗芯片MAX1232CPA，硬件溢出时间1.2S
//
//-------------------------------------------------------

#include "CANCOM.h"

//unsigned char UART_TX_Data[8] = {0,1,2,3,4,5,6,7};
//unsigned char CAN_TX_Data[8] = {0,1,2,3,4,5,6,7};
unsigned char xdata UART_RX_Data[255]; //串口接收到的串行帧
unsigned char xdata CAN_TX_Data[255]; //待发送的数据缓冲区
unsigned char code ACR_ID[4] = {0,0,0,0}; //CAN初始设置验收滤波值
unsigned char code AMR_ID[4] = {0xff,0xff,0xff,0xff};
unsigned char CAN_TX_ID[4] = {0,0,0,0}; //待发送的目标的ID
unsigned char CAN_RX_ID[4] = {0,0,0,0}; //接收到的信息来自何ID
unsigned char CAN_RX_Data[8] = {7,6,5,4,3,2,1,0}; //接受到的数据缓冲
unsigned char code CAN_BTR0[10] ={0xdf,0xcf,0xc7,0xc3,0x43,0xc1,0xc1,0xc0,0xc0,0x80}; unsigned char code CAN_BTR1[10] = {0x7f,0x7f,0x7f,0x7f,0x2f,0x7f,0x4d,0x3e,0x3a,0x23};
// 5K 10K 20K 40K 50K 80K 100K 200K 250K 500K
unsigned char code UART_BTR[4] = {0xe8,0xf4,0xfa};
// 1.2K,2.4K,4.8K

unsigned char CAN_flag; //CAN发送标志位
unsigned char UART_flag; //
unsigned char CAN_ERROR_flag = NOT; //
unsigned char CAN_DataLength = 8; //CAN信息的报文长度
unsigned char UART_DataLength = 0; //串口接收时的当前指示
unsigned char UART_Length = 0; //串口接收区的长度指示
//sbit AAA = P1^4;

void main(void)
{
EA = 0;
System_init(); //系统初始化
Timer_init(); //定时器初始化
Interrupt_init(); //中断
UART_ini();
CAN_init();
Delay(1);
W_WDT();
EA = 1;

//Delay(1);
//UART_Length = 8;
//CAN_Transmit(0);
//UART_Transmit();

while (1)
{
W_WDT();

if (CAN_flag == YES)
{
CAN_flag = NOT;
CAN_Transmit(0);
LED1 = !LED1;
}
else
{
CAN_flag = NOT;
}
/*
if (UART_flag == YES)
{
UART_flag = NOT;
//Delay(50);
UART_Transmit();
//Clear_Buffer(CAN_RX_Data,8);
//LED3 = !LED3;
}
else
{
UART_flag = NOT;
}

*/
if ((CAN_ERROR_flag == YES))
{
CAN_ERROR_flag = NOT;
CAN_init();
}
else
{
CAN_ERROR_flag = NOT;
}
}
}
//---------------------------
// 功能：系统设置
// --外部数据存储区访问使能
// --LED指示灯关（1＝on，0＝off）
// --流程控制标志置为无效NOT
// --清空串口，CAN的相关数据缓冲区
//---------------------------
void System_init(void)
{
CKCON = 0x00; //Fosc devide 12
AUXR = 0x00;//0x02; //EXM enable
LED1 = 0; //LED0-3 off 指示灯，共阴接法，1时亮
LED2 = 0;
LED3 = 0;
LED4 = 0;
WDT = 1; //WDT ini

CAN_DataLength = 8;
UART_DataLength = 0;
UART_Length = 0;

CAN_flag = NOT;
CAN_ERROR_flag = NOT;
//UART_flag = NOT;

Clear_Buffer(UART_RX_Data,255);
Clear_Buffer(CAN_TX_Data,255);
Clear_Buffer(CAN_TX_ID,4);
Clear_Buffer(CAN_RX_ID,4);
Clear_Buffer(CAN_RX_Data,8);

/*
CAN_flag = YES;
UART_flag = YES;
*/
}
//-----------------------------
//
// 软件延时（非精确）
// ----内置清看门狗定时器子函数
// 防止多次调用延时过长导致
// 看门狗复位
//
//-----------------------------
void Delay(unsigned char time)
{
unsigned char i;
unsigned int j;

for (i = 0;i < time;i++)
{
W_WDT();
for (j=0;j<30000;j++)
{
}
}
}

//---------------------------------
// 串行口初始化设置
// 方式1，8数据位，一个停止位，无奇偶校验
// 串口中断允许
//------------------------------------
void UART_ini(void)
{
SCON = 0x50; //方式1，波特率可变，8bits，接受允许
PCON&= 0x7F; //SMOD = 0
TMOD |= 0x20; //timer1 mode 2

TL1 = UART_BTR[2]; //| f
//| 波特率＝----------------------
TH1 = UART_BTR[2]; //| 32*2^smod*12*(256-TL1)
TCON |= 0x40; //start

TI = 0;
}

//-----------------------------------------------
//
// 看门狗“喂狗”程序，WDT的一个下降沿触发一次
//
//-----------------------------------------------
void W_WDT(void) //triggle WDT
{
unsigned char i;
WDT = 1;
for (i=0;i<10;i++)
{
}
WDT = 0;
}

//---------------------------------------------------
//
// 中断初始化
//
// ----外部中断0有效，下降沿触发，用于SJA1000产生CAN事件中断
// ----定时器中断，用于判定串口接收的顺序两个字节是否分属两帧
// ----串口中断，RX使用中断，TX未使用
// ----中断优先级暂时未设定
//
//---------------------------------------------------
void Interrupt_init(void)
{
//IP = 0x00;
IT0 = 0x01; //外部0中断沿触发

ET0 = 1; //定时器0中断使能
EX0 = 1; //外部中断使能
ES = 1; //串行中断使能
}

//---------------------------------------------------
//
// 定时中断程序
//
// 一旦中断，说明一帧的接收已经结束，开始启动CAN发送程序
// 把串口接收到的数据准备好给CAN总线发送
// RX_buffer ===> CAN_TX_buffer
//
//---------------------------------------------------
void Timer0_ISR(void) interrupt 1 using 2
{
static unsigned char i;
//unsigned char counter;

//TH0 = temp_TH0;
//TL0 = temp_TL0;

/*counter += 1;
if (counter == 20) //到1S了么？
{
//UART_flag = YES;
}
if (counter == 40) //到2S了么？
{
//CAN_flag = YES;
counter = 0;
}*/
//AAA = !AAA;
TR0 = 0; //定时器关,开始次CAN信息传送

for (i=0;i {
CAN_TX_Data[i] = UART_RX_Data[i];
}
UART_Length = UART_DataLength;
UART_DataLength = 0;
CAN_flag = YES;
}
//---------------------------------------------------------------
//
// 串口中断服务程序
//
// ----只有接收使用
// ----每收一个数重新初始化定时器
//
//----------------------------------------------------------------
void RX_INT(void) interrupt 4 using 3
{
static unsigned char n;

if (RI==1)
{
do
{
RI = 0;
}
while (RI != 0);

//UART_RX_Data[UART_DataLength++] = SBUF;
n = SBUF;
UART_Send_Byte(n);

TH0 = temp_TH0;
TL0 = temp_TL0;
TR0 = 1; //启动数据间隔定时，判断是否分属两帧
}
else
{
//TX
}
}
//---------------------------------------------------------------
//
// 串口发送单字节程序
//
//----------------------------------------------------------------
void UART_Send_Byte(unsigned char Data)
{
SBUF = Data;
while (TI == 0) //等待发送完毕
{
}
TI = 0;
}

//---------------------------------------------------------------
//
// 初始化定时器程序
//
// ----定时器0方式1，定时器1方式2留给串口
//
//----------------------------------------------------------------
void Timer_init(void)
{
TMOD |= 0x01; //使用定时器0－方式1

TH0 = temp_TH0;
TL0 = temp_TL0;
//TR0 = 1; //这里不打开定时器
}

void CAN_init(void)
{

EA = 0;
MOD_CAN1 |= 0x08; //单滤波方式
do
{
MOD_CAN1 |= 0x01; //request to reset mode
}
while ((MOD_CAN1&0x01) != 0x01);

CDR_CAN1 = 0xc8; //选择PeliCAN模式，使用输入比较器，clk_out关闭
IER_CAN1 = 0x01; //允许发送中断，其他中断禁能

ACR0_CAN1 = ACR_ID[0];
ACR1_CAN1 = ACR_ID[1];
ACR2_CAN1 = ACR_ID[2];
ACR3_CAN1 = ACR_ID[3];
AMR0_CAN1 = AMR_ID[0];
AMR1_CAN1 = AMR_ID[1];
AMR2_CAN1 = AMR_ID[2];
AMR3_CAN1 = AMR_ID[3];

//ECC_CAN1 = 0;
//TXERR_CAN1 = 0;
//RBSA_CAN1 = 0;

BTR0_CAN1 = CAN_BTR0[0];
BTR1_CAN1 = CAN_BTR1[0];
OCR_CAN1 = 0xaa; //normal output

W_WDT();
do
{
MOD_CAN1 &= 0xfe;
}
while ((MOD_CAN1&0x01) != 0x00);
EA = 1;
}

//-----------------------------------
//
// 串口发送一帧接受到的CAN数据
//
// ----长度1－8，根据接收到的CAN信息来确定
//
//-----------------------------------
void UART_Transmit(void) //using 0
{
unsigned char i;

LED3 = !LED3;
for (i=0;i {
UART_Send_Byte(CAN_RX_Data[i]);
}
}
//-----------------------------------
//
// CAN发送接受到的一帧串口数据
//
// ----最大长度255，根据接收到的串口信息的
// 个数来确定
// ----按每依次8个数据作为一个CAN帧的报文部分
// 不足8个或超过8的倍数的部分按实际个数作
// 为CAN报文
// ----FarmeType = 1为扩展帧，FarmeType = 0为
// 标准帧
//-----------------------------------
void CAN_Transmit(bit FarmeType)
{

unsigned char i;
unsigned char m;
unsigned char can_status;
unsigned char xdata *pointer;


if (FarmeType == 0) //标准帧
{
for (m=0;m<(UART_Length/8);m++)
{
W_WDT();
do //发送缓冲区空么？
{
can_status = SR_CAN1;
}
while ((can_status&0x04) != 0x04);

TXFrameInfo1 = 0x00 + 0x08;
pointer = &TXID1;
for (i=0;i<2;i++)
{
*(pointer++) = CAN_TX_ID[i];
}

pointer = &TXID3;
for (i=0;i<8;i++)
{
*(pointer++) = CAN_TX_Data[i+8*m];
}
CMR_CAN1 = Request_TX;
W_WDT();
}

if ((UART_Length%8) != 0)
{
W_WDT();
do //发送缓冲区空么？
{
can_status = SR_CAN1;
}
while ((can_status&0x04) != 0x04);
TXFrameInfo1 = 0x00 + UART_Length%8;
pointer = &TXID1;
for (i=0;i<2;i++)
{
*(pointer++) = CAN_TX_ID[i];
}

pointer = &TXID3;
for (i=0;i<(UART_Length%8);i++)
{
*(pointer++) = CAN_TX_Data[i+8*(UART_Length/8)];
}
CMR_CAN1 = Request_TX;
W_WDT();
}
else
{
}
}
else //扩展帧
{
for (m=0;m<(UART_Length/8);m++)
{
W_WDT();
do //发送缓冲区空么？
{
can_status = SR_CAN1;
}
while ((can_status&0x04) != 0x04);

TXFrameInfo1 = 0x80 + 0x08;
pointer = &TXID1;
for (i=0;i<4;i++)
{
*(pointer++) = CAN_TX_ID[i];
}

pointer = &TXDATA1;
for (i=0;i<8;i++)
{
*(pointer++) = CAN_TX_Data[i+8*m];
}
CMR_CAN1 = Request_TX;
W_WDT();
}

if ((UART_Length%8) != 0)
{
W_WDT();
do //发送缓冲区空么？
{
can_status = SR_CAN1;
}
while ((can_status&0x04) != 0x04);
TXFrameInfo1 = 0x80 + UART_Length%8;
pointer = &TXID1;
for (i=0;i<4;i++)
{
*(pointer++) = CAN_TX_ID[i];
}

pointer = &TXDATA1;
for (i=0;i<(UART_Length%8);i++)
{
*(pointer++) = CAN_TX_Data[i+8*(UART_Length/8)];
}
CMR_CAN1 = Request_TX;
W_WDT();
}
else
{
}
}

UART_Length = 0;

}

//-----------------------------------
//
// CAN接收中断服务程序
//
// ----判断是否是RX中断，如果是
// 把接受到的CAN信息通过串行口发送出去
// ----其他的中断说明CAN总线出现错误或脱离
//
//-----------------------------------
void CAN_ISR(void) interrupt 0 using 1
{
unsigned char can_int;

EA = 0;

can_int = IR_CAN1;
if ((can_int&0x01) == 0x01) //接收中断
{
CAN_Receive();
CMR_CAN1 |= ReleaseRXBuf;
}
else
{
CAN_ERROR_flag = YES; //其他中断，暂时未用
}

//UART_flag = YES;
//CAN_flag = YES;
UART_Transmit();

EA = 1;
}

//-----------------------------------
//
// CAN接收数据函数
//
// ----根据接受到的帧信息，按不同的长度存储
// 报文数据
//
//-----------------------------------
void CAN_Receive(void) using 1
{
unsigned char i;
unsigned char xdata *pointer;
unsigned char Info;

Info = RXFrameInfo1;

if ((Info&0x80) == 0) //standard Frame
{
//CAN_RX_ID[0] = RXID1;
//CAN_RX_ID[1] = RXID2;

CAN_DataLength = Info&0x0f;
pointer = &RXID3;
for (i=0;i {
CAN_RX_Data[i] = *(pointer++);
}
for (;i<8;i++)
{
CAN_RX_Data[i] = 0x00;
}
}
else //Ex Frame
{
//CAN_RX_ID[0] = RXID1;
//CAN_RX_ID[1] = RXID2;
//CAN_RX_ID[2] = RXID3;
//CAN_RX_ID[3] = RXID4;
CAN_DataLength = Info&0x0f;
pointer = &RXDATA1;
for (i=0;i {
CAN_RX_Data[i] = *(pointer++);
//pointer += 1;
}
for (;i<8;i++)
{
CAN_RX_Data[i] = 0x00;
}
}
}
//-----------------------------------
//
// 清0缓冲区
//
// ----pointer,指向待清0 的缓冲区首地址
// ----length 清0 的长度
//-----------------------------------
void Clear_Buffer(unsigned char *pointer,unsigned char length)
{
unsigned char i;

for (i=0;i {
*(pointer++) = 0x00;
}
}

另外头文件为：

#ifndef _CANCOM_H
#define _CANCOM_H

#define CS1_SJA1000 0x7f00 //SJA1000 Pin /CS ----> P2.7,low level active

#define MOD_CAN1 XBYTE[CS1_SJA1000+0] //Peli
#define CMR_CAN1 XBYTE[CS1_SJA1000+1] //command
#define SR_CAN1 XBYTE[CS1_SJA1000+2] //state
#define IR_CAN1 XBYTE[CS1_SJA1000+3] //interrupt
#define IER_CAN1 XBYTE[CS1_SJA1000+4] //interrupt enable //Peli
#define BTR0_CAN1 XBYTE[CS1_SJA1000+6] //bus timing0
#define BTR1_CAN1 XBYTE[CS1_SJA1000+7] //bus timing1
#define OCR_CAN1 XBYTE[CS1_SJA1000+8]
#define TEST_CAN1 XBYTE[CS1_SJA1000+9]
#define ECC_CAN1 XBYTE[CS1_SJA1000+12] //error catch
#define EWLR_CAN1 XBYTE[CS1_SJA1000+13] //error warning limit
#define RXERR_CAN1 XBYTE[CS1_SJA1000+14] //
#define TXERR_CAN1 XBYTE[CS1_SJA1000+15]
#define ACR0_CAN1 XBYTE[CS1_SJA1000+16]
#define ACR1_CAN1 XBYTE[CS1_SJA1000+17]
#define ACR2_CAN1 XBYTE[CS1_SJA1000+18]
#define ACR3_CAN1 XBYTE[CS1_SJA1000+19]
#define AMR0_CAN1 XBYTE[CS1_SJA1000+20]
#define AMR1_CAN1 XBYTE[CS1_SJA1000+21]
#define AMR2_CAN1 XBYTE[CS1_SJA1000+22]
#define AMR3_CAN1 XBYTE[CS1_SJA1000+23]
#define RBSA_CAN1 XBYTE[CS1_SJA1000+30] //beginning of receive
#define CDR_CAN1 XBYTE[CS1_SJA1000+31] //clock devide

#define TXFrameInfo1 XBYTE[CS1_SJA1000+16]
#define TXID1 XBYTE[CS1_SJA1000+17]
#define TXID2 XBYTE[CS1_SJA1000+18]
#define TXID3 XBYTE[CS1_SJA1000+19]
#define TXID4 XBYTE[CS1_SJA1000+20]
#define TXDATA1 XBYTE[CS1_SJA1000+21]
#define TXDATA2 XBYTE[CS1_SJA1000+22]
#define TXDATA3 XBYTE[CS1_SJA1000+23]
#define TXDATA4 XBYTE[CS1_SJA1000+24]
#define TXDATA5 XBYTE[CS1_SJA1000+25]
#define TXDATA6 XBYTE[CS1_SJA1000+26]
#define TXDATA7 XBYTE[CS1_SJA1000+27]
#define TXDATA8 XBYTE[CS1_SJA1000+28]

#define RXFrameInfo1 XBYTE[CS1_SJA1000+16]
#define RXID1 XBYTE[CS1_SJA1000+17]
#define RXID2 XBYTE[CS1_SJA1000+18]
#define RXID3 XBYTE[CS1_SJA1000+19]
#define RXID4 XBYTE[CS1_SJA1000+20]
#define RXDATA1 XBYTE[CS1_SJA1000+21]
#define RXDATA2 XBYTE[CS1_SJA1000+22]
#define RXDATA3 XBYTE[CS1_SJA1000+23]
#define RXDATA4 XBYTE[CS1_SJA1000+24]
#define RXDATA5 XBYTE[CS1_SJA1000+25]
#define RXDATA6 XBYTE[CS1_SJA1000+26]
#define RXDATA7 XBYTE[CS1_SJA1000+27]
#define RXDATA8 XBYTE[CS1_SJA1000+28]

#define GoToRESET 0x01
#define ReleaseRXBuf 0x04
#define Request_TX 0x01

#define NOT 0
#define YES 1
//4800bps 5bits 1.04mS
#define TIME_MS 1
#define temp_TH0 (0 - 922*TIME_MS)/256
#define temp_TL0 (0 - 922*TIME_MS)%256

sbit LED1 = P1^2;
sbit LED2 = P1^3;
sbit LED3 = P1^5;
sbit LED4 = P1^4;
sbit WDT = P3^4;

void System_init(void);
void Delay(unsigned char time);
void W_WDT(void);
void Interrupt_init(void);
void CAN_init(void);
//void CAN_Transmit(unsigned char Farmeinfo);
void CAN_Transmit(bit FarmeType);
void CAN_Receive(void);
void Timer_init(void);
void UART_ini(void);
void UART_Send_Byte(unsigned char Data);
void UART_Transmit(void);
void Clear_Buffer(unsigned char *pointer,unsigned char length);

#endif

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