I have a piece of memory I am "guarding", defined by

typedef unsigned char byte;

byte * guardArea;
size_t guardSize;

byte * guardArea = getGuardArea();
size_t guardSize = getGuardSize();

An acceptable implementation for the sake of this would be:

size_t glGuardSize = 1024; /* protect an area of 1kb */
byte * getGuardArea()
{
     return malloc( glGuardSize );
}
size_t getGuardSize()
{
     return glGuardSize;
}

Can the following snippet return true for any pointer (from a different malloc, from the stack etc)?

if ( ptr >= guardArea && ptr < (guardArea + guardSize)) {
     return true;
}

The standard states that:

  • values within the area will return true. (When ptr was a member, all acts correctly.)

  • pointers will be distinct (a == b only if they are the same).

  • all addresses within the byte array can be accessed by incrementing the base.
  • any pointer can be converted to and from a char *, without damage.

So I can't understand how the result could be true for any pointer from a different object (as it would break the distinct rule for one of the pointers within the area).

Edit:

What is the use case?

The ability to detect whether a pointer is within a region is really important, at some point code is written

if (  isInMyAreaOfInterest( unknownPointer ) ) {
    doMySpecialThing( unknownPointer );
} else {
    doSomethingElse( unknownPointer );
}

I think the language needs to support the developer by making such constructs simple and obvious, and our interpretation of the standard, is that the developer needs to cast to int. Due to the "undefined behavior" of pointer comparisons of distinct objects.

I was hoping for some clarity of why I can't do what I would like (my snippet), as all the posts on SO I found say that the standard claims undefined behavior, without any explanation, or examples of why the standard is better than how I would like it to work.

At the moment, we have a rule, we are neither understanding why the rule exists, or questioning if the rule is helping us

Example posts:

SO: checking if a pointer is in a malloced area

SO: C compare pointers

  • It actually depends on the implementation of getGuardArea() and getGuardSize();. As long as you don't elaborate more, this question cannot be answered. – Jabberwocky Aug 26 '16 at 7:34
  • 1
    Just for curiosity, what is the use case? – wasthishelpful Aug 26 '16 at 7:35
  • 1
    I still don't get your problem. If you get some memory with malloc, you can be sure that block of memory won't be assigned again (unless malloc on your system is awfully broken). Conceptually your snippet works. What's the problem? The casting of pointers? Can you link to any of these posts that talk about UB? – Fabio Turati Aug 26 '16 at 7:54
  • So I can't understand how the result could be true for any pointer from a different object. The premise of the question is wrong. If two pointers to different objects are compared using relational operator then this results in undefined behavior. The result isn't false or true, instead anything is allowed to happen, as it is undefined behavior, explained here:stackoverflow.com/a/4105123/4082723 – 2501 Aug 26 '16 at 7:58
  • 1
    @Lundin: There is no real-world reason why compilers written by non-obtuse programmers for modern linear-address machines should not interpret relational operators as defining a consistent non-overlapping ordering among all data pointers. Unfortunately, compiler behavior which would for decades have been correctly recognized as obtuse is today regarded as fashionable. – supercat Aug 26 '16 at 20:46
up vote 32 down vote accepted

It is still possible for an allocation to generate a pointer that satisfies the condition despite the pointer not pointing into the region. This will happen, for example, on an 80286 in protected mode, which is used by Windows 3.x in Standard mode and OS/2 1.x.

In this system, pointers are 32-bit values, split into two 16-bit parts, traditionally written as XXXX:YYYY. The first 16-bit part (XXXX) is the "selector", which chooses a bank of 64KB. The second 16-bit part (YYYY) is the "offset", which chooses a byte within that 64KB bank. (It's more complicated than this, but let's just leave it at that for the purpose of this discussion.)

Memory blocks larger than 64KB are broken up into 64KB chunks. To move from one chunk to the next, you add 8 to the selector. For example, the byte after 0101:FFFF is 0109:0000.

But why do you add 8 to move to the next selector? Why not just increment the selector? Because the bottom three bits of the selector are used for other things.

In particular, the bottom bit of the selector is used to choose the selector table. (Let's ignore bits 1 and 2 since they are not relevant to the discussion. Assume for convenience that they are always zero.)

There are two selector tables, the Global Selector Table (for memory shared across all processes) and the Local Selector Table (for memory private to a single process). Therefore, the selectors available for process private memory are 0001, 0009, 0011, 0019, etc. Meanwhile, the selectors available for global memory are 0008, 0010, 0018, 0020, etc. (Selector 0000 is reserved.)

Okay, now we can set up our counter-example. Suppose guardArea = 0101:0000 and guardSize = 0x00020000. This means that the guarded addresses are 0101:0000 through 0101:FFFF and 0109:0000 through 0109:FFFF. Furthermore, guardArea + guardSize = 0111:0000.

Meanwhile, suppose there is some global memory that happens to be allocated at 0108:0000. This is a global memory allocation because the selector is an even number.

Observe that the global memory allocation is not part of the guarded region, but its pointer value does satisfy the numeric inequality 0101:0000 <= 0108:0000 < 0111:0000.

Bonus chatter: Even on CPU architectures with a flat memory model, the test can fail. Modern compilers take advantage of undefined behavior and optimize accordingly. If they see a relational comparison between pointers, they are permitted to assume that the pointers point into the same array (or one past the last element of that array). Specifically, the only pointers that can legally be compared with guardArea are the ones of the form guardArea, guardArea+1, guardArea+2, ..., guardArea + guardSize. For all of these pointers, the condition ptr >= guardArea is true and can therefore be optimized out, reducing your test to

if (ptr < (guardArea + guardSize))

which will now be satisfied for pointers that are numerically less than guardArea.

Moral of the story: This code is not safe, not even on flat architectures.

But all is not lost: The pointer-to-integer conversion is implementation-defined, which means that your implementation must document how it works. If your implementation defines the pointer-to-integer conversion as producing the numeric value of the pointer, and you know that you are on a flat architecture, then what you can do is compare integers rather than pointers. Integer comparisons are not constrained in the same way that pointer comparisons are.

if ((uintptr_t)ptr >= (uintptr_t)guardArea &&
    (uintptr_t)ptr < (uintptr_t)guardArea + (uintptr_t)guardSize)
  • 5
    @Lundin The question did not say "Assume I am not on an icky processor." See also the bonus chatter, which demonstrates that this code is unsafe even on a modern flat architecture. – Raymond Chen Aug 26 '16 at 8:20
  • 6
    The "Bonus chatter" portion of this answer perfectly illustrates a major flaw in contemporary (2016) optimizing compilers. If the programmer writes if (ptr>=guardArea && ptr<(guardArea + guardSize)) and the compiler silently drops the first condition, then that compiler is seriously broken. Detecting undefined behavior is not an opportunity for optimization, it is an opportunity to issue a diagnostic. – user3386109 Aug 26 '16 at 18:44
  • 1
    @user3386109 On the other hand, sometimes you want the optimization. E.g. bool inRange(char*p,char*start, int length){return p>=start && p<start+length); int array[80]; void stuff(){char*p = findSomething(array, 80); /* stop if not found */ if (!p) return; /* if in first half */ if (inRange(p, array, 40)) { ... } /* if in second half */ if (inRange(p, array+40, 40)) { ... } }. In this case, you want to optimize out the first half of the check when checking the first half of the array, and you would be annoyed if the compiler spit out a diagnostic. – Raymond Chen Aug 26 '16 at 19:56
  • 6
    @user3386109 I should give up trying to come up with specific examples. The point is that inlining, loop unrolling, constant propagation, template expansion, and many other compiler transformations can expose valid optimization opportunities that you would want the compiler to exploit. – Raymond Chen Aug 27 '16 at 3:36
  • 1
    @YuhongBao I know, but I simplified the architecture for the purpose of discussion. Whether the LDT bit is 0, 1, or 2 is immaterial. – Raymond Chen Sep 27 '17 at 23:21

Yes.

void foo(void) {}
void(*a) = foo;
void *b = malloc(69);
uintptr_t ua = a, ub = b;

ua and ub are in fact permitted to have the same value. This occurred frequently on segmented systems (like MS-DOS) which might put code and data in separate segments.

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