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#include <stdio.h>

int main(){
    unsigned char a[4] = {1, 2, 3, 4};
    int b = *(int *)&a[0];

    printf("%d\n", b);
    return 0;
}

I just cannot understand why the result of b is 0x4030201.

Could someone help me out?

Thanks in advance.

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3  
b is not 0x4030201, did you mean int b = *(int *)&a[0];? –  junjanes Sep 8 '12 at 9:17
1  
Yes, I typed wrongly. Thanks. I have changed it –  Learner Sep 8 '12 at 9:19
    
What you wrote is undefined behaviour. To do it right, you should say: int b; unsigned char * a = (unsigned char *)&b; (And remove your line that declares b.) –  Kerrek SB Sep 8 '12 at 10:36

3 Answers 3

When you tell the compiler to create an array like this:

unsigned char a[4] = {1, 2, 3, 4};

These numbers are put somewhere in memory in following order:

MemoryAddress0: 0x01 -> a[0]
MemoryAddress1: 0x02 -> a[1]
MemoryAddress2: 0x03 -> a[2]
MemoryAddress3: 0x04 -> a[3]

&a[0] is a char pointer with the value of MemoryAddress0 and points a 1 byte value of 0x01

(int*)&a[0] is a casted pointer with the same value of MemoryAddress0 but with int* type this time so it points to four consecutive bytes.

Most machines we use in our daily lives are little endian which means that they store multibyte values in memory from the least significant byte to the most significant one.

When an int* points to a memory of four bytes, the first byte it encounters is the least significant byte and the second byte is the the second least significant and so on.

MemoryAddress0: 0x01 -> 2^0 term
MemoryAddress1: 0x02 -> 2^8 term
MemoryAddress2: 0x03 -> 2^16 term
MemoryAddress3: 0x04 -> 2^24 term

Thus the 4-byte integer value becomes 0x01*2^0 + 0x02*2^8 + 0x03*2^16 + 0x04*2^24 which is equal to 0x04030201.

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Thank you for your detailed explanation... –  Learner Sep 8 '12 at 11:04

You are on a little-endian machine, this means that integers with sizes larger than a byte store the least-significant bytes first.

Note that most architectures these days are little-endian thanks to the common-ness of x86.

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So if I were using a big-endian machine, the result will be 0x1020304? –  Learner Sep 8 '12 at 9:20
1  
@user1592172 yes. –  user529758 Sep 8 '12 at 9:20
1  
Little-Endian machines store the least-significant bytes, not bits, first. Is this a typo? –  trion Sep 8 '12 at 10:51
    
@Learner and it should 0x01020304 if trion is right, which I think he is. –  quantum Sep 9 '12 at 4:09
    
@trion: woops, fixed. –  orlp Sep 9 '12 at 9:09

Because your system is little endian. The first byte in a multi-byte integer is interpreted as the least significant byte in little endian systems.

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Thanks a lot... –  Learner Sep 8 '12 at 9:21

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