24

I know it is an integer type that can be cast to/from pointer without loss of data, but why would I ever want to do this? What advantage does having an integer type have over void* for holding the pointer and THE_REAL_TYPE* for pointer arithmetic?

EDIT
The question marked as "already been asked" doesn't answer this. The question there is if using intptr_t as a general replacment for void* is a good idea, and the answers there seem to be "don't use intptr_t", so my question is still valid: What would be a good use case for intptr_t?

  • See also: stackoverflow.com/questions/6326338/… – i_am_jorf Jan 28 '16 at 20:20
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    Try writing memory management code of an OS without a safe type. – too honest for this site Jan 28 '16 at 20:39
  • Nominate for re-open as listed dupe answer "Is it a good idea to use intptr_t as a general-purpose storage", which is close to this post, but not quite. – chux Jan 28 '16 at 21:03
  • In my experience its main use is for tidying up legacy code that assumed casting an int to void * and back again later was a valid technique – M.M Jan 28 '16 at 21:35
  • Note: The post essential also applies to uintptr_t. – chux Jan 28 '16 at 21:48
15

The primary reason, you cannot do bitwise operation on a void *, but you can do the same on a intptr_t.

On many occassion, where you need to perform bitwise operation on an address, you can use intptr_t.

However, for bitwise operations, best approach is to use the unsigned counterpart, uintptr_t.

As mentioned in the other answer by @chux, pointer comparison is another important aspect.

Also, FWIW, as per C11 standard, §7.20.1.4,

These types are optional.

  • 4
    For bit-wise operations, I'd very much prefer an unsigned type, ie std::uintptr_t. I must admit that I still have to encounter a use-case for the signed version. – 5gon12eder Jan 28 '16 at 20:25
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    @5gon12eder: I fully agree, but I know at least one platform which used actually signed memory space. Acknowledged, Transputers are not very up-to-date now, but C also targets more exotic platforms. FYI: That was related to the instruction set and how literals & instructions were composed. Quite interesting subject which shows there once were quite interesting architectures beyond the current quite boring (from the instruction set) ones. – too honest for this site Jan 28 '16 at 20:43
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    Pointer types does not guarantee +1 actually increase the value by 1. void * does not have operator + although gcc supports it as an extension. Even with sizeof(char) (by standard) and sizeof(void) (by gcc extension) guaranteed to equal to 1, adding 1 to char * or void * still does not guarantee increasing their numerical value by 1: examples are non-byte addressable machines( lower bits of pointers are always 0s). So intptr_t also makes +/- safer. – user3528438 Jan 28 '16 at 21:23
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    @user3528438 Why would you want to increase the pointer by any number that it not a multiple of the size of the thing it points to? – Baruch Jan 28 '16 at 21:29
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    @baruch an example: you might want to generate a pointer that's correctly aligned for int, so you could take some other pointer and increase it to the next multiple of sizeof(int). (or alignof(int)) – M.M Jan 28 '16 at 21:38
7

What is the use of intptr_t?

Example use: order comparing.
Comparing pointers for equality is not a problem.
Other compare operations like >, <= may be UB. C11dr §6.5.8/5 Relational operators.
So convert to intptr_t first.

[Edit] New example: Sort an array of pointers by pointer value.

int ptr_cmp(const void *a, const void *b) {
  intptr_t ia = (intptr) (*((void **) a));
  intptr_t ib = (intptr) (*((void **) b));
  return (ia > ib) - (ia < ib);
}

void *a[N];
...
qsort(a, sizeof a/sizeof a[0], sizeof a[0], ptr_cmp);

[Former example] Example use: Test if a pointer is of an array of pointers.

#define N  10
char special[N][1];

// UB as testing order of pointer, not of the same array, is UB.
int test_special1(char *candidate) {
  return (candidate >= special[0]) && (candidate <= special[N-1]);
}

// OK - integer compare
int test_special2(char *candidate) {
  intptr_t ca = (intptr_t) candidate;
  intptr_t mn = (intptr_t) special[0];
  intptr_t mx = (intptr_t) special[N-1];
  return (ca >= mn) && (ca <= mx);
}

As commented by @M.M, the above code may not work as intended. But at least it is not UB. - just non-portably functionality. I was hoping to use this to solve this problem.

  • 1
    note that this is not guaranteed to work – M.M Jan 28 '16 at 21:15
  • 1
    @M.M I took a shot. What might not work about it? Sequence of special[0]..special[N-1] might not match the intptr_t versions? or do you see another pitfall? – chux Jan 28 '16 at 21:18
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    Yes, the intptr_t values need not have the same ordering as the pointers in the range being tested. Although it is quite likely that they would. – M.M Jan 28 '16 at 21:21
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    If comparing to pointers from different memory allocations is UB and not guaranteed to work, I don't see how casting them to an integer first would make it work any better. – Baruch Jan 28 '16 at 21:33
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    @M.M Unless you're writing the nuclear missile launch control system – Lightness Races in Orbit Feb 23 at 13:22
6

The uintptr_t type is very useful when writing memory management code. That kind of code wants to talk to its clients in terms of generic pointers (void *), but internally do all kinds of arithmetic on addresses.

You can do some of the same things by operating in terms of char *, but not everything, and the result looks like pre-Ansi C.

Not all memory management code uses uintptr_t - as an example, the BSD kernel code defines a vm_offset_t with similar properties. But if you are writing e.g. a debug malloc package, why invent your own type?

It's also helpful when you have %p available in your printf, and are writing code that needs to print pointer sized integral variables in hex on a variety of architectures.

I find intptr_t rather less useful, except possibly as a way station when casting, to avoid the dread warning about changing signedness and integer size in the same cast. (Writing portable code that passes -Wall -Werror on all relevant architectures can be a bit of a struggle.)

6

There's also a semantic consideration.

A void* is supposed to point to something. Despite modern practicality, a pointer is not a memory address. Okay, it usually/probably/always(!) holds one, but it's not a number. It's a pointer. It refers to a thing.

A intptr_t does not. It's an integer value, that is safe to convert to/from a pointer so you can use it for antique APIs, packing it into a pthread function argument, things like that.

That's why you can do more numbery and bitty things on an intptr_t than you can on a void*, and why you should be self-documenting by using the proper type for the job.

Ultimately, almost everything could be an integer (remember, your computer works on numbers!). Pointers could have been integers. But they're not. They're pointers, because they are meant for different use. And, theoretically, they could be something other than numbers.

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