C语言版CRC-16系列校验算法_crc16校验-CSDN博客
参考的这篇文章的,基本上是把他的超过来了
CRC(循环冗余校验)在线计算_ip33.com
1. CRC16常见几个标准的算法
RC16常见的标准有以下几种,被用在各个规范中,其算法原理基本一致,就是在数据的输入和输出有所差异,下边把这些标准的差异列出,并给出C语言的算法实现。
CRC16_CCITT:多项式x16+x12+x5+1(0x1021),初始值0x0000,低位在前,高位在后,结果与0x0000异或
CRC16_CCITT_FALSE:多项式x16+x12+x5+1(0x1021),初始值0xFFFF,低位在后,高位在前,结果与0x0000异或
CRC16_XMODEM:多项式x16+x12+x5+1(0x1021),初始值0x0000,低位在后,高位在前,结果与0x0000异或
CRC16_X25:多项式x16+x12+x5+1(0x1021),初始值0x0000,低位在前,高位在后,结果与0xFFFF异或
CRC16_MODBUS:多项式x16+x15+x5+1(0x8005),初始值0xFFFF,低位在前,高位在后,结果与0x0000异或
CRC16_IBM:多项式x16+x15+x5+1(0x8005),初始值0x0000,低位在前,高位在后,结果与0x0000异或
CRC16_MAXIM:多项式x16+x15+x5+1(0x8005),初始值0x0000,低位在前,高位在后,结果与0xFFFF异或
CRC16_USB:多项式x16+x15+x5+1(0x8005),初始值0xFFFF,低位在前,高位在后,结果与0xFFFF异或
2、CRC16的算法原理及程序
根据CRC16的标准选择初值CRCIn的值。
将数据的第一个字节与CRCIn高8位异或。
判断最高位,若该位为 0 左移一位,若为 1 左移一位再与多项式Hex码异或。
重复3直至8位全部移位计算结束。
重复将所有输入数据操作完成以上步骤,所得16位数即16位CRC校验码。
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| void InvertUint8(unsigned char *DesBuf, unsigned char *SrcBuf)
{
int i;
unsigned char temp = 0;
for(i = 0; i < 8; i++)
{
if(SrcBuf[0] & (1 << i))
{
temp |= 1<<(7-i);
}
}
DesBuf[0] = temp;
}
void InvertUint16(unsigned short *DesBuf, unsigned short *SrcBuf)
{
int i;
unsigned short temp = 0;
for(i = 0; i < 16; i++)
{
if(SrcBuf[0] & (1 << i))
{
temp |= 1<<(15 - i);
}
}
DesBuf[0] = temp;
}
unsigned short CRC16_CCITT(unsigned char *puchMsg, unsigned int usDataLen)
{
unsigned short wCRCin = 0x0000;
unsigned short wCPoly = 0x1021;
unsigned char wChar = 0;
while (usDataLen--)
{
wChar = *(puchMsg++);
InvertUint8(&wChar, &wChar);
wCRCin ^= (wChar << 8);
for(int i = 0; i < 8; i++)
{
if(wCRCin & 0x8000)
{
wCRCin = (wCRCin << 1) ^ wCPoly;
}
else
{
wCRCin = wCRCin << 1;
}
}
}
InvertUint16(&wCRCin, &wCRCin);
return (wCRCin) ;
}
unsigned short CRC16_CCITT_FALSE(unsigned char *puchMsg, unsigned int usDataLen)
{
unsigned short wCRCin = 0xFFFF;
unsigned short wCPoly = 0x1021;
unsigned char wChar = 0;
while (usDataLen--)
{
wChar = *(puchMsg++);
wCRCin ^= (wChar << 8);
for(int i = 0; i < 8; i++)
{
if(wCRCin & 0x8000)
{
wCRCin = (wCRCin << 1) ^ wCPoly;
}
else
{
wCRCin = wCRCin << 1;
}
}
}
return (wCRCin) ;
}
unsigned short CRC16_XMODEM(unsigned char *puchMsg, unsigned int usDataLen)
{
unsigned short wCRCin = 0x0000;
unsigned short wCPoly = 0x1021;
unsigned char wChar = 0;
while (usDataLen--)
{
wChar = *(puchMsg++);
wCRCin ^= (wChar << 8);
for(int i = 0; i < 8; i++)
{
if(wCRCin & 0x8000)
{
wCRCin = (wCRCin << 1) ^ wCPoly;
}
else
{
wCRCin = wCRCin << 1;
}
}
}
return (wCRCin) ;
}
unsigned short CRC16_X25(unsigned char *puchMsg, unsigned int usDataLen)
{
unsigned short wCRCin = 0xFFFF;
unsigned short wCPoly = 0x1021;
unsigned char wChar = 0;
while (usDataLen--)
{
wChar = *(puchMsg++);
InvertUint8(&wChar, &wChar);
wCRCin ^= (wChar << 8);
for(int i = 0;i < 8;i++)
{
if(wCRCin & 0x8000)
{
wCRCin = (wCRCin << 1) ^ wCPoly;
}
else
{
wCRCin = wCRCin << 1;
}
}
}
InvertUint16(&wCRCin, &wCRCin);
return (wCRCin^0xFFFF) ;
}
unsigned short CRC16_MODBUS(unsigned char *puchMsg, unsigned int usDataLen)
{
unsigned short wCRCin = 0xFFFF;
unsigned short wCPoly = 0x8005;
unsigned char wChar = 0;
while (usDataLen--)
{
wChar = *(puchMsg++);
InvertUint8(&wChar, &wChar);
wCRCin ^= (wChar << 8);
for(int i = 0; i < 8; i++)
{
if(wCRCin & 0x8000)
{
wCRCin = (wCRCin << 1) ^ wCPoly;
}
else
{
wCRCin = wCRCin << 1;
}
}
}
InvertUint16(&wCRCin, &wCRCin);
return (wCRCin) ;
}
unsigned short CRC16_IBM(unsigned char *puchMsg, unsigned int usDataLen)
{
unsigned short wCRCin = 0x0000;
unsigned short wCPoly = 0x8005;
unsigned char wChar = 0;
while (usDataLen--)
{
wChar = *(puchMsg++);
InvertUint8(&wChar, &wChar);
wCRCin ^= (wChar << 8);
for(int i = 0; i < 8; i++)
{
if(wCRCin & 0x8000)
{
wCRCin = (wCRCin << 1) ^ wCPoly;
}
else
{
wCRCin = wCRCin << 1;
}
}
}
InvertUint16(&wCRCin,&wCRCin);
return (wCRCin) ;
}
unsigned short CRC16_MAXIM(unsigned char *puchMsg, unsigned int usDataLen)
{
unsigned short wCRCin = 0x0000;
unsigned short wCPoly = 0x8005;
unsigned char wChar = 0;
while (usDataLen--)
{
wChar = *(puchMsg++);
InvertUint8(&wChar, &wChar);
wCRCin ^= (wChar << 8);
for(int i = 0; i < 8; i++)
{
if(wCRCin & 0x8000)
{
wCRCin = (wCRCin << 1) ^ wCPoly;
}
else
{
wCRCin = wCRCin << 1;
}
}
}
InvertUint16(&wCRCin, &wCRCin);
return (wCRCin^0xFFFF) ;
}
unsigned short CRC16_USB(unsigned char *puchMsg, unsigned int usDataLen)
{
unsigned short wCRCin = 0xFFFF;
unsigned short wCPoly = 0x8005;
unsigned char wChar = 0;
while (usDataLen--)
{
wChar = *(puchMsg++);
InvertUint8(&wChar, &wChar);
wCRCin ^= (wChar << 8);
for(int i = 0; i < 8; i++)
{
if(wCRCin & 0x8000)
{
wCRCin = (wCRCin << 1) ^ wCPoly;
}
else
{
wCRCin = wCRCin << 1;
}
}
}
InvertUint16(&wCRCin, &wCRCin);
return (wCRCin^0xFFFF) ;
}
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