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int main(){
   short a=1;         // #1
   char *p=(char*)&a;
   *(p)=1;            // #2
   cout << a << endl; // Output: 1
   *(p+1)=2;          // #3
   cout << a << endl; // Output: 513

From my understanding, the output should be as shown in the picture below, 257 and then 258.
Is there any reason I got different result when I run the program above ?

enter image description here

Update: I know this is Undefined behavior, but still, does this mean that the decimal to binary conversion is not done as usual: right to left, but instead is done left to right for example:

binary(a)=1000 0000 | 0000 0000

so *(p)=1; will make binary(a)=1000 0000 | 0000 0000 which is 1 in decimal
and *(p+1)=2; will make binary(a)=1000 0000 | 0100 0000 which is 513
which exactly the output of the program.

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@BenjaminLindley rather – user529758 Dec 8 '12 at 20:01
@BenjaminLindley (Of course. But when I'm saying this very same thing, I am always being talked off...) – user529758 Dec 8 '12 at 20:04
@H2CO3, That's life right there.… – chris Dec 8 '12 at 20:06
Note that the endianness affects the order of bytes within a multi-byte type. It does not necessarily affect the bit order within a byte. But that's not detectable since you can't address anything smaller than a byte. But other than that, yes, your interpretation is correct. – Benjamin Lindley Dec 8 '12 at 20:22

2 Answers 2

up vote 3 down vote accepted

What happens here is due to the fact that we have a 2-byte short in a little endian CPU architecture. The standard does not require that the architecture be LE, so in any case this program can generate a number of different results when run on different systems.

A short here is laid out in memory with the least significant byte (LSB) first:

         Memory addresses ------>
            LSB          MSB

         0000 0000   0000 0000

p points at the LSB and sets is to 1:

         0000 0001   0000 0000

The result when interpreted as a short is LSB + 256 * MSB, i.e. 1 + 0 * 256 = 1

p then points at the MSB (which is on the next memory address) and sets is to 2:

         0000 0001   0000 0010

Result when interpreted as a short: 1 + 2 * 256 = 513

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so for example right shift operator will move the 1 in LSB to the right and the 1 in MSB to the left, so cout << (a>>1); will print out 0000 0000 0000 0001 which is 256. is this correct ? – AlexDan Dec 8 '12 at 20:26
@AlexDan: No, not correct. Left and right bit shifting is well defined, portable behavior. (1>>1) == 0. Regardless of the endianness of your system. – Benjamin Lindley Dec 8 '12 at 20:45

Is there any reason I got different result when I run the program above ?

Yes. Language-agnostic answer: because this program invokes undefined behavior. Answer considering what might have happened actually: your system has different endianness than that you think it has.

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