通信領域經常用到CRC校驗。
這裏把CRC-16的代碼轉發一下。
不過,我推薦一個用於生成各種校驗碼的開源軟件 Fsum frontend
它的開源項目網址是:http://fsumfe.sourceforge.net/
下載其源代碼,可看到各種算法,但不是用c寫的。
該軟件的用處是,可以驗證你的算法。
CRC-16 IBM x 16 + x 15 + x 2 + 1
CRC編碼的原理,網上有很多,簡單的說就是將數據用生成式進行模2除法。
這裏我主要寫一下,查表法的原理。
一、原理:
數據項: <BnBn-1Bn-2Bn-3,...,B3B2B1>
先查表獲得Bn的兩字節餘式,將該餘式的高8位與Bn-1進行模2運算,假定B'n-1,低8位與Bn-2進行模2運算,假定結構爲B'n-2,得到< B'n-1B'n-2Bn-3,...,B3B2B1 >,以此類推,最終獲得兩字節的CRC碼.(參考字節型CRC算法實現一文)
二、實現
以下代碼中中的查表法來自於 Linux-2.6.17,定義法是根據定義編寫的,我使用隨機數對兩種方法進行了比對,結果一致
#include <stdio.h>
#include <stdlib.h>
#include<math.h>
typedef unsigned int u16;
typedef unsigned char u8;
u16 const crc16_table[256] = {
0x0000, 0xC0C1, 0xC181, 0x0140, 0xC301, 0x03C0, 0x0280, 0xC241,
0xC601, 0x06C0, 0x0780, 0xC741, 0x0500, 0xC5C1, 0xC481, 0x0440,
0xCC01, 0x0CC0, 0x0D80, 0xCD41, 0x0F00, 0xCFC1, 0xCE81, 0x0E40,
0x0A00, 0xCAC1, 0xCB81, 0x0B40, 0xC901, 0x09C0, 0x0880, 0xC841,
0xD801, 0x18C0, 0x1980, 0xD941, 0x1B00, 0xDBC1, 0xDA81, 0x1A40,
0x1E00, 0xDEC1, 0xDF81, 0x1F40, 0xDD01, 0x1DC0, 0x1C80, 0xDC41,
0x1400, 0xD4C1, 0xD581, 0x1540, 0xD701, 0x17C0, 0x1680, 0xD641,
0xD201, 0x12C0, 0x1380, 0xD341, 0x1100, 0xD1C1, 0xD081, 0x1040,
0xF001, 0x30C0, 0x3180, 0xF141, 0x3300, 0xF3C1, 0xF281, 0x3240,
0x3600, 0xF6C1, 0xF781, 0x3740, 0xF501, 0x35C0, 0x3480, 0xF441,
0x3C00, 0xFCC1, 0xFD81, 0x3D40, 0xFF01, 0x3FC0, 0x3E80, 0xFE41,
0xFA01, 0x3AC0, 0x3B80, 0xFB41, 0x3900, 0xF9C1, 0xF881, 0x3840,
0x2800, 0xE8C1, 0xE981, 0x2940, 0xEB01, 0x2BC0, 0x2A80, 0xEA41,
0xEE01, 0x2EC0, 0x2F80, 0xEF41, 0x2D00, 0xEDC1, 0xEC81, 0x2C40,
0xE401, 0x24C0, 0x2580, 0xE541, 0x2700, 0xE7C1, 0xE681, 0x2640,
0x2200, 0xE2C1, 0xE381, 0x2340, 0xE101, 0x21C0, 0x2080, 0xE041,
0xA001, 0x60C0, 0x6180, 0xA141, 0x6300, 0xA3C1, 0xA281, 0x6240,
0x6600, 0xA6C1, 0xA781, 0x6740, 0xA501, 0x65C0, 0x6480, 0xA441,
0x6C00, 0xACC1, 0xAD81, 0x6D40, 0xAF01, 0x6FC0, 0x6E80, 0xAE41,
0xAA01, 0x6AC0, 0x6B80, 0xAB41, 0x6900, 0xA9C1, 0xA881, 0x6840,
0x7800, 0xB8C1, 0xB981, 0x7940, 0xBB01, 0x7BC0, 0x7A80, 0xBA41,
0xBE01, 0x7EC0, 0x7F80, 0xBF41, 0x7D00, 0xBDC1, 0xBC81, 0x7C40,
0xB401, 0x74C0, 0x7580, 0xB541, 0x7700, 0xB7C1, 0xB681, 0x7640,
0x7200, 0xB2C1, 0xB381, 0x7340, 0xB101, 0x71C0, 0x7080, 0xB041,
0x5000, 0x90C1, 0x9181, 0x5140, 0x9301, 0x53C0, 0x5280, 0x9241,
0x9601, 0x56C0, 0x5780, 0x9741, 0x5500, 0x95C1, 0x9481, 0x5440,
0x9C01, 0x5CC0, 0x5D80, 0x9D41, 0x5F00, 0x9FC1, 0x9E81, 0x5E40,
0x5A00, 0x9AC1, 0x9B81, 0x5B40, 0x9901, 0x59C0, 0x5880, 0x9841,
0x8801, 0x48C0, 0x4980, 0x8941, 0x4B00, 0x8BC1, 0x8A81, 0x4A40,
0x4E00, 0x8EC1, 0x8F81, 0x4F40, 0x8D01, 0x4DC0, 0x4C80, 0x8C41,
0x4400, 0x84C1, 0x8581, 0x4540, 0x8701, 0x47C0, 0x4680, 0x8641,
0x8201, 0x42C0, 0x4380, 0x8341, 0x4100, 0x81C1, 0x8081, 0x4040
};
static inline u16 crc16_byte(u16 crc, const u8 data)
{
return (crc >> 8) ^ crc16_table[(crc ^ data) & 0xff];
}
/**
* crc16 - compute the CRC-16 for the data buffer
* @crc: previous CRC value
* @buffer: data pointer
* @len: number of bytes in the buffer
*
* Returns the updated CRC value.
*/
u16 crc16(u16 crc, u8 const *buffer, u16 len)
{
while (len--)
crc = crc16_byte(crc, *buffer++);
return crc;
}
/**
* crc16 - compute the CRC-16 for the data buffer according to the definition
* @crc: previous CRC value
* @buffer: data pointer
* @len: number of bytes in the buffer
*
* Returns the updated CRC value.
*/
u16 crc16_calculate(u16 crc,u8 const *buffer,u16 len)
{
u16 i,j;
u8 data;
for ( j = 0; j < len; j++)
{
data= buffer[j];
for ( i = 0; i < 8; i++)
{
crc = ((data ^ (u8)crc) & 1) ? ((crc >> 1) ^ 0xA001) : (crc >> 1);
data>>= 1;
}
}
return crc;
}
int main()
{
u16 crc1,crc2;
u8 test[32] ;
u8 i;
while(1)
{
for(i=0;i<32;i++)
test[i]=rand();
crc1=0;
crc2=0;
// crc=crc16(0,test,6);
crc1=crc16(crc1,test,6);
printf("CRC=%d/n",crc1);
crc2=crc16_calculate(crc2,test,6);
printf("CRC=%d/n",crc2);
if(crc1!=crc2)
break;
}
return 0;
}
本文來自CSDN博客,轉載請標明出處:http://blog.csdn.net/linuxsee/archive/2009/07/16/4353631.aspx