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I have a question regarding using intptr_t vs. long int. I've observed that incrementing memory addresses (e.g. via manual pointer arithmetic) differs by data type. For instance incrementing a char pointer adds 1 to the memory address, whereas incrementing an int pointer adds 4, 8 for a double, 16 for a long double, etc...

At first I did something like this:

char myChar, *pChar;
float myFloat, *pFloat;

pChar = &myChar;
pFloat = &myFloat;

printf( "pChar:  %d\n", ( int )pChar );
printf( "pFloat: %d\n", ( int )pFloat );


printf( "and then after incrementing,:\n\n" );
printf( "pChar:  %d\n", (int)pChar );
printf( "pFloat:    %d\n", (int)pFloat );

which compiled and executed just fine, but XCode gave me warnings for my typecasting: "Cast from pointer to integer of different size."

After some googling and binging (is the latter a word yet?), I saw some people recommend using intptr_t:

#include <stdint.h>


printf( "pChar:  %ld\n", ( intptr_t )pChar );
printf( "pFloat: %ld\n", ( intptr_t )pFloat );

which indeed resolves the errors. So, I thought, from now on, I should use intptr_t for typecasting pointers... But then after some fidgeting, I found that I could solve the problem by just replacing int with long int:

printf( "pChar:  %ld\n", ( long int )pChar );
printf( "pFloat: %ld\n", ( long int )pFloat );

So my question is, why is intptr_t useful, and when should it used? It seems superfluous in this instance. Clearly, the memory addresses for myChar and myFloat were just too big to fit in an int... so typecasting them to long ints solved the problem.

Is it that sometimes memory addresses are too big for long int as well? Now that I think about it, I guess that's possible if you have > 4GB of RAM, in which case memory addresses could exceed 2^32 - 1 (max value for unsigned long ints...) but C was created long before that was imaginable, right? Or were they that prescient?


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Yes, binging is a word, which originally meant to indulge in an activity, especially eating, to excess. – ack Jul 4 '14 at 17:13
up vote 22 down vote accepted

Here's the thing: on some platforms, int is the right size, but on others, long is the right size. How do you know which one is the one you should use? You don't. One might be right, but the standard makes no guarantees about which one it would be (if it is either). So the standard provides a type that is defined to be the correct size, regardless of what platform you're on. Where before you had to write:

  typedef long intptr;
  typedef int intptr;

Now you just write:

#include <stdint.h>

And it covers so many more cases. Imagine specializing the snippet above for every single platform your code runs on.

share|improve this answer
Hmm, thanks for the clarification. What if you just used long all the time? Wouldn't long work with shorter addresses as well? Does the extra memory allocation for longs vs ints significantly affect performance? – grisaitis Jun 13 '11 at 4:22
@caravaggisto - Nope. long is only guaranteed to be 32 bits, and may not work on a 64-bit platform. You could always use long long, but that doesn't exist before C99. I doubt the allocation matters much. It's more a problem of correctness. – Chris Lutz Jun 13 '11 at 4:27
Right, I see what you're saying with the 64-bit case. I was wondering, if you're only considering 32-bit systems, it seems like long would work on all, while int would not where 'long is the right size' as you discuss in your initial answer. – grisaitis Jun 13 '11 at 4:33
That is, if you're on a system that has int length addresses, long would presumably work as well, no? It seems to be an issue of address lengths fitting within the range of a given data type. – grisaitis Jun 13 '11 at 4:36
@R..: Often an API which provides a callback function, or a messaging API like the Windows message pump, will have an integer data field or two that can be passed around. Your program may need to stuff a pointer into a DWORD or an int because that is all that is available in the API. – Zan Lynx Sep 5 '12 at 15:41

intptr_t is a new invention, created after 64-bit and even 128-bit memory addresses were imagined.

If you ever need to cast a pointer into an integer type, always use intptr_t. Doing anything else will cause unnecessary problems for people who need to port your code in the future.

It took a long time to iron out all of the bugs with this in programs like Mozilla/Firefox when people wanted to compile it on 64-bit Linux.

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Thanks for the useful answer, Zan. Wasn't aware of that with Firefox. Sounds pretty bad. – grisaitis Jun 13 '11 at 4:28
It would be better to use uintptr_t. Signed types are messy and surely make no sense with pointers... – R.. Jun 13 '11 at 5:10
Good call. Everything I see written about uintptr_t is in the context of c++ and the inttypes.h library. looks like it's in stdint.h, too, though. any difference? – grisaitis Jun 13 '11 at 5:30
Nevermind, that last bit was a dumb question. :) – grisaitis Jun 14 '11 at 18:59
@user10607: It is available from C99 onwards. That's more than a decade. So unless you're using an ancient compiler like TurboC or a very exotic platform with no int to hold a pointer, it will be available ;) – MestreLion Feb 17 '15 at 6:13

First, intptr_t is only for data pointers (not functions) and is not guaranteed to exist.

Then, no, you shouldn't use it for the purpose of printing. The %p is for that. You just have to cast your pointer to (void*) and there you go.

It is also no good for arithmetic / accessing individual bytes. Cast to (unsigned char*) instead.

intptr_t is really for the rare occasions that you have to interpret pointers as integers (which they really aren't). Don't that if you mustn't.

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thanks. What are pointers, then, if not (binary) integers? Thank you for your time. – grisaitis Jun 14 '11 at 16:57
@caravaggisto, this depends a lot on the architecture. Some architectures have segmented memory, so an address is composed of two parts. Just simple integer addition might for example not always give you a valid address. Arithmetic on unsigned char will do, provided you allocated a chunk that is large enough. – Jens Gustedt Jun 14 '11 at 18:17

You could make your life easier by using the p conversion specifier:

printf("%p\n", (void *)foo);

Also, the portable way to print a variable of type (u)intptr_t is to use the PRI*PTR macros from inttypes.h; the following is equivalent to using p on my platform (32-bit):

printf("%08" PRIxPTR "\n", (uintptr_t)(void *)foo);

The casts to void * are necessary for full portability, but can be omitted on platforms with uniform pointer representations.

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Although this probably should have been a comment to the question. – ecerulm Jun 18 '15 at 19:48

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