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I'm trying this pointer trick and I can't figure out how to fix it, I'm running g++ 4.6 on ubuntu 12.04 64-bit. Check out this code below:

int arr[5];
arr[3] = 50;
((short*) arr)[6] = 2;
cout << arr[3] << endl;

The logic is: since short is 2 bytes, int is 4 bytes, I want to change the first 2 bytes in arr[3], while keeping the value of the second 2 bytes as 50. So I'm just messing with the bit pattern. Unfortunately, sizeof(int*) and sizeof(short*) are both 8 bytes. Is there a type cast that returns a pointer of size 2 bytes?

Update:

I realized that the question is poorly written, so I'll fix that: The output from cout << arr[3] << endl; I'm getting is 2. The output I would like to get is neither 2 nor 50, but rather a large number, indicating that the left part of the int bit pattern has been changed, while the right part (the second 2-bits) of the int stored in arr[3] is still unchanged.

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You are manipulating bits of integers, not of pointers. Size of pointers is irrelevant. Your problem lies elsewhere. –  n.m. Feb 27 '13 at 6:22
    
Remember the [] operator is doing a deference. ((short*) arr)[6] is a short sized value. –  shf301 Feb 27 '13 at 6:23
    
I agree with you, but it's the only explanation I can think of for why it's not working :s –  naxchange Feb 27 '13 at 6:23
    
@naxchange: What "isn't working" about it? What is the behavior you are seeing, and what is the behavior you are expecting instead? –  Billy ONeal Feb 27 '13 at 6:25
    
You're going to run into byte swapping and endianness issues if you try to manipulate data this way. –  Tuxdude Feb 27 '13 at 6:27

6 Answers 6

up vote 5 down vote accepted

sizeof(int*) and sizeof(short*) are both going to be the same -- as will sizeof(void*) -- you're asking for the size of a pointer, not the size of the thing the pointer points to.

Use sizeof(int) or sizeof(short) instead.


Now, as for your code snippet, you are making assumptions about the endianness of the machine on which you're running. The "first" part of the int on a given platform may be the bytes with higher address, or the bytes with lower address.

For instance, your memory block may be laid out like this. Let's say the least significant byte has index zero, and the most significant byte has index one. On a big endian architecture an int may look like this:

 <------------- 4 bytes --------------->
+---------+---------+---------+---------+
| int:3   | int:2   | int:1   | int:0   |
| short:1 | short:0 | short:1 | short:0 |
+---------+---------+---------+---------+

Notice how the first short in the int -- which in your case would have been ((short*) arr)[6] -- contains the most significant bits of the int, not the least significant. So if you overwrite ((short*) arr)[6], you are overwriting the most significant bits of arr[3], which appears to be what you wanted. But x64 is not a big endian machine.

On a little endian architecture, you would see this instead:

 <------------- 4 bytes --------------->
+---------+---------+---------+---------+
| int:0   | int:1   | int:2   | int:3   |
| short:0 | short:1 | short:0 | short:1 |
+---------+---------+---------+---------+

leading to the opposite behavior -- ((short*) arr)[6] would be the least significant bits of arr[3], and ((short*) arr)[7] would be the most significant.


Here's what my machine happens to do -- your machine may be different:

C:\Users\Billy\Desktop>type example.cpp
#include <iostream>

int main()
{
        std::cout << "Size of int is " << sizeof(int) << " and size of short is "
                  << sizeof(short) << std::endl;

        int arr[5];
        arr[3] = 50;
        ((short*) arr)[6] = 2;
        std::cout << arr[3] << std::endl;
        ((short*) arr)[7] = 2;
        std::cout << arr[3] << std::endl;
}


C:\Users\Billy\Desktop>cl /W4 /EHsc /nologo example.cpp && example.exe
example.cpp
Size of int is 4 and size of short is 2
2
131074
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The question doesn't imply a need for sizeof(int) or ...short... - just a concern that the indexing wouldn't work as intended. –  Tony D Feb 27 '13 at 6:21
    
@TonyD: The question is a bit poorly written. The only question I see in this question (that is, ending with a ?) is discussing sizeof(int*) and sizeof(short*). Beyond that the OP hasn't been very clear about the behavior he is seeing versus the behavior he expects. –  Billy ONeal Feb 27 '13 at 6:23
    
So, can I conclude that ((short*) arr)[7] = 2; would resolve what I'm looking for? –  naxchange Feb 27 '13 at 6:40
    
Yes, yes it does. Thanks a million! –  naxchange Feb 27 '13 at 6:40
    
@naxchange: Yeah. Sorry, I off by one error'd all of the place there. –  Billy ONeal Feb 27 '13 at 6:44

Your problem is due to endianness. Intel CPU's are little endian meaning that the first byte of an int is stored in the the first address. Let me how you can example:

Let's assume that arr[3] is at address 10:

Then arr[3] = 50; Writes the following to memory

10:   0x32
11:   0x00
12:   0x00
13:   0x00

And ((short*) arr)[6] = 2; writes the following to memory

10:  0x02
11:  0x00
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1  
+1 -- but anyone who stores an int at a non-aligned address should be shot :) –  Billy ONeal Feb 27 '13 at 6:50

When you index a pointer, it adds the index multiplied by the size of the pointed-to type. So, you don't need a 2-byte pointer.

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I agree with you, but it's not working when I run it –  naxchange Feb 27 '13 at 6:23

You are making a lot of assumptions which might not hold water. Also what does the sizeof pointers have to do with the problem at hand?

Why not just use bit masks:

arr[3] |= (top_2_bytes << 16);

This should set the upper 16 bytes without disturbing the lower 16. (You may get into signed/unsigned dramas)

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Said all the above, the standard prohibits doing such things: Setting a variable through a pointer to another type is calling undefined behaviour. If you know how your machine works (sizes of int and short, endianness, ...) and you know how your compiler (is likely to) translate your code, then you might get away with it. Does for neat parlor tricks, and spectacular explosions when the machine/compiler/phase of the moon change.

If it wins any performance, the win will be minimal, and it could even be a net loss (one compiler long ago I fiddled with, playing the "I can implement this loop better than the compiler, I know exactly what goes on here" generated much worse code for my `label: ... if() goto label; than the exact same written natively as a loop: My "smart" code confused the compiler, its "pattern for loops" did not apply).

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You wouldn't want your actual pointer to be of size two bytes; this would mean that it could only access ~16k of memory addresses. However, using a cast, as you are, to a short *, will let you access the memory every two bytes (since the compiler will view the array as an array of shorts, not of ints).

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