This answer comes with an interesting statement - "on machines where int* is smaller than a char*". (let's exclude pointers to functions)

Is it possible for pointers to different types to have different sizes? Why would this be useful?

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    This may be useful: stackoverflow.com/questions/12006854/… Apr 5, 2013 at 11:23
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    @KirilKirov that is interesting (I guess I immediately excluded function pointers from my train of thought). Good info! Apr 5, 2013 at 11:27
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    @KirilKirov I was lazy enough not to check your link, but it seems that after all, my answer is redundant -.-
    – user529758
    Apr 5, 2013 at 11:29
  • If I'm not wrong, there are very specific platforms, where char* and int* have different sizes. It's been a while, since I read about this, but if I remember correctly - this is very rare and is more relevant for some embedded systems. Apr 5, 2013 at 11:29
  • All answers mentioned the size is not guaranteed. But uintptr_t is fixed size for all pointer types!?
    – masoud
    Apr 5, 2013 at 11:40

5 Answers 5


Yes, it's entirely possible. On some machines, a pointer to a byte contains two values: A pointer to the WORD address of the memory word containing the byte, and a "byte index" that gives the position of the byte within the word. E.g. on a 32-bit machine, the "byte index" is 0..3.

This would require more storage space than a "int *", which is just a pointer to the relevant word.

  • Indeed. One could even imagine some kind of weird machine where different data is stored in different memory banks entirely, each addressed in their own way. Apr 5, 2013 at 11:28
  • Can you please name such machines, Mats? Apr 5, 2013 at 11:29
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    @MartinVidner: I just invented one in my mind for you. Apr 5, 2013 at 11:29
  • Alpha processors before EV56, as per my quick googling, doesn't support "byte addressing" - each memory read/write has to be an entire machine word, and bytes "swizzled" out of their location with some sort of shift operations. Apr 5, 2013 at 11:31
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    8086 segmented memory model. Near pointers 16-bit, far pointers 20/32 bit. Apr 5, 2013 at 11:32

On word addressed machines a char* might need to contain part-word info, making it larger than an int*.

The standard allows this, not to rule out implementations on such hardware (even though that is even more rare now than when C89 was designed).

  • Linked your answer here do you know of other cases where char* has a different size than int*? Mar 13, 2015 at 15:40

The tag means that you are asking about C++ and its compliant implementations, not some specific physical machine.

I'd have to quote the entire standard in order to prove it, but the simple fact is that it makes no guarantees on the result of sizeof(T*) for any T, and (as a corollary) no guarantees that sizeof(T1*) == sizeof(T2*) for any T1 and T2).

  • I am. In absence of something else, I guess the only the size of char and unsigned char are guaranteed would do. Apr 5, 2013 at 11:36
  • @LuchianGrigore: Sure, as long as you mention that there are other contraints on some types. Apr 5, 2013 at 12:04
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    "An object of type cv void* shall have the same representation and alignment requirements as cv char*"
    – PlasmaHH
    Oct 7, 2013 at 11:52
  • @PlasmaHH Good find :) Oct 7, 2013 at 12:15
  • Another guarantee is that "Pointers to cv-qualified and cv-unqualified versions of layout-compatible types shall have the same value representation and alignment requirements". In C, all pointers to struct type must have same r&a but C++ doesn't appear to have that rule.
    – M.M
    Nov 5, 2015 at 20:05

Yes, pointers aren't guaranteed to have the same size, although on most modern architectures they are, in practice.

One point where this can be useful is when one concerns data vs. function pointers. Historically, function pointers (that are used to essentially jump to certain parts in the executable code) needed so-called "far pointers" which are wider than data pointers.


I can imagine a machine where it makes sense to assume that the memory needs for int arrays are going to be far less than the memory needs for char arrays.

One may specify, for instance, that an implementation is not going to use more than 10 dynamically allocated integers, but is free to allocate many char arrays. In this case, one byte may suffice for an int*, while a char* needs to be four bytes or more.

That's a theoretical vision.

  • More than 256 dynamically allocated integers, even, if one byte is enough. Apr 5, 2013 at 11:33
  • I wanted to mention 4 bits pointers, but I thought that was over the top :)
    – xtofl
    Apr 5, 2013 at 11:34

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