Largest and smallest pointer addresses in C

Suppose I have the global variables:

char *min_ptr, *max_ptr;

and the function:

void f(int *p)
{
if(min_ptr > p)
min_ptr = p;
if(max_ptr < p)
max_ptr = p;
}

If C does not guarantee that addresses are stored the same way as unsigned long, I guess I can't initialize my variables as follows:

char *min_ptr = ULONG_MAX, *max_ptr = 0;

How can I initialize min_ptr and max_ptr to the smallest and largest addresses respectively? And is it even valid to use the <, >, <=, or >= operators with pointers?

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What overall problem are you trying to solve? – GManNickG Oct 28 '13 at 0:23
You'd be better off explaining what problem you are trying to solve by comparing pointer values... – John3136 Oct 28 '13 at 0:23
What exactly are you trying to achieve? A function like bool is_pointer_valid(void *p) { return p >= min_ptr && p < max_ptr; } is completely useless since it can't handle gaps in the virtual address space or uninitialized values. – Adam Rosenfield Oct 28 '13 at 0:24
I'm analyzing allocations on the stack. The only pointers I will be passing to f are those on the stack. – user1887231 Oct 28 '13 at 0:27
The stack has gaps, too. (the return addresses and the frame pointers, plus maybe alignment) – wildplasser Oct 28 '13 at 1:15

0 is not a valid address, that's why it's used to represent the null pointer constant. So you can just do:

char * min_ptr = NULL;
char * max_ptr = NULL;

/*  Other stuff  */

void f(int *p) {
if( min_ptr == NULL || min_ptr > p )
min_ptr = p;
if( max_ptr == NULL || max_ptr < p )
max_ptr = p;
}

without messing about with that other stuff.

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Thanks! This is much more elegant and guaranteed to work. – user1887231 Oct 28 '13 at 0:45
@user1887231: No, it's not guaranteed to work. Relational operators on pointers have undefined behavior unless both pointers point into the same object, or just past the end of it. – Keith Thompson Oct 28 '13 at 1:17

Pointer subtraction or pointer comparison using <, <=, >, or >= has undefined behavior unless both pointers point to elements of the same array object, or just past the end of it. (For this purpose, a single object is treated as a single-element array.) The relational operators compare the array indices, and subtraction yields the difference in elements (&arr[5] - &arr[2] == 3, for example).

It's likely to "work" (i.e., give you more or less consistent results) on most systems, though subtraction may still give nonsensical results if there are alignment problems.

You can convert any pointer-to-object value to intptr_t or uintptr_t (defined in <stdint.h>) and back again without loss of information. Since intptr_t and uintptr_t are integer types, subtractions and comparisons on them are well defined -- but that doesn't mean that the comparison means anything with respect to the pointer values. And of course subtraction can overflow.

You can either live with the fact that your code's behavior is not defined by the standard (though it may happen to work on your system), or you can find a different way to solve your problem. For the latter, we might be able to help if you'll tell us what problem you're trying to solve.

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The comparison operators are valid to use.

For the limits, use

INTPTR_MIN
INTPTR_MAX

from stdint.h.

And, FYI, I believe there is a better way to do what you are trying to do.

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The relational operators have defined behavior only for pointers into the same object, or just past the end of it. – Keith Thompson Oct 28 '13 at 1:16
I can compare pointers for two different objects. Also, the transitive property always holds. – Paul Draper Oct 28 '13 at 2:03
You can compare such pointers for equality; the relational operators < <= > >= have undefined behavior. See N1570 section 6.5.8. It may happen to work, but the behavior is not defined by the C standard. – Keith Thompson Oct 28 '13 at 2:28

The header file <stdint.h> in C99 has some useful things defined. uintptr_t is a normal integer type that can contain a pointer. stdint.h defines Maximum and Minimum on all it's types.

So this should work

void *ptr_max = UINTPTR_MAX;

UINTPTR_MIN is not defined as pointer's are unsigned their smallest value is always 0.

Yes you can compare pointers. It's useful in array stuff. Eg checking a array based ring buffer is not full:

// This code has some bugs. Eg, it does not handle wrap arround.
if (ring_buff_back + 1 < ring_buff_front) {...

Note the subtraction on pointers return a ptrdiff_t which is similar to intptr_t.

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<stdint.h> defines both uintptr_t and intptr_t, which are unsigned and signed, respectively. Both are optional. Pointers are neither signed nor unsigned. – Keith Thompson Oct 28 '13 at 1:15