#include < stdio.h > union
{
long Long; char Char[ sizeof ( long )];
} u; int main() { u.Long = 1 ; if (u.Char[ 0 ] == 1 ) 
{ printf( " Little Endian!\n " );
} else if (u.Char[ sizeof ( long ) - 1 ] == 1 ) { printf( " Big Endian!\n " ); } else { printf( " Unknown Addressing!\n " ); } printf( " Now, Let's look at every byte in the memory!\n " ); for ( int i = 0 ; i < sizeof ( long ); ++ i) { printf( " [%x] = %x\n " , & u.Char, u.Char); } return 0 ;}
很多人认为掌握这个知识是不必要,其实不然.在网络编程中,TCP/IP统一采用big endian方式传送数据,也就是说,假设现在是在一个字节顺序是little endian的机器上传送数据,要求传送的数据是0XCEFABOBO,那么你就要以0XBOBOFACE的顺序在unsigned int中存放这个数据,只有这样才能保证存放的顺序满足TCP/IP的字节顺序要求.很多时候,需要自己编写应用层的协议,字节顺序的概念在这个时候就显得及其的重要了.
下面给出的是在big endian和little endian中相互转换的代码,C语言强大的位操作的能力在这里显示了出来:
#include < stdio.h > const unsigned char SIZE_OF_UNSIGNEDINT = sizeof (unsigned int ); const unsigned char SIZE_OF_UNSIGNEDCHAR = sizeof (unsigned char ); void put_32(unsigned char * cmd, unsigned int data) { int i; for (i = SIZE_OF_UNSIGNEDINT - 1 ; i >= 0 ; -- i) { cmd = data % 256 ; // 或者可以: // cmd = data & 0xFF; data = data >> 8 ; } } unsigned int get_32(unsigned char * cmd) { unsigned int ret; int i; for (ret = 0 , i = SIZE_OF_UNSIGNEDINT - 1 ; i >= 0 ; -- i) { ret = ret << 8 ; ret |= cmd; } return ret;} int main( void ) { unsigned char cmd[SIZE_OF_UNSIGNEDINT]; unsigned int data, ret; unsigned char * p; int i; data = 0x12345678 ; printf( " data = %x\n " , data); // 以字节为单位打印出数据 p = (unsigned char * )( & data); for (i = 0 ; i < SIZE_OF_UNSIGNEDINT; ++ i) { printf( " %x " , * p ++ ); } printf( " \n " ); // 以相反的顺序存放到cmd之中 put_32(cmd, data); for (i = 0 ; i < SIZE_OF_UNSIGNEDINT; ++ i) { printf( " cmd[%d] = %x\n " , i, cmd); } // 再以相反的顺序保存数据到ret中 // 保存之后的ret数值应该与data相同 ret = get_32(cmd); printf( " ret = %x\n " , ret); p = (unsigned char * )( & ret); for (i = 0 ; i < SIZE_OF_UNSIGNEDINT; ++ i) { printf( " %x " , * p ++ ); } printf( " \n " ); return 0 ;} 
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