In C/C++, addition or subtraction on pointer is defined only if the resulting pointer lies within the original pointed complete object. Moreover, comparison of two pointers can only be performed if the two pointed objects are subobjects of a unique complete object.

What are the reasons of such limitations?

I supposed that segmented memory model (see here §1.2.1) could be one of the reasons but since compilers can actually define a total order on all pointers as demonstrated by this answer, I am doubting this.

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    @oliv a reason could be that more UB enables more optimizations; consider "int x[10];int* py = x + j;", here the compiler could legally make assumptions on the range of j – Massimiliano Janes Dec 3 '17 at 8:48
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    @MassimilianoJanes Given the history of C and the usage of UB for optimization, I think it is very unlikely that optimization potential was the reason for any UB in C. – Sebastian Redl Dec 3 '17 at 8:54
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    In a segmented architecture pa - pb will have more than one correct answer if the address architecture allows the segment address scheme to overlap. – Richard Critten Dec 3 '17 at 11:43
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    @oliv it would help if you(or anybody) could produce a genuine use-case where such relaxed requirements would turn out useful; imho, in order to be fair, such use-case should 1) apply to latest standard, 2) should not have an equivalent, portable solution, and 3) should not rely on any further undefined behavior. Only then, such use-cases could be meaningfully compared against the loss of generality that such decision would entail. – Massimiliano Janes Dec 3 '17 at 16:17
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    @PasserBy Regarding std::less and the builtin operators, there are very good reasons for them to behave differently. For effieciency the builtin comparison operators should be allowed to use the architectures natural comparison instructions and because of things segmented addressing or multiple address spaces it may not be possible to implement a total order of pointers this way. For std::less, a total order is more important than efficiency and it is ok to do extra work to handle memory segments and address spaces. – Johan Dec 4 '17 at 20:51
up vote 7 down vote accepted
+50

There are architectures where program and data spaces are separated, and it's simply impossible to subtract two arbitrary pointers. A pointer to a function or to const static data will be in a completely different address space than a normal variable.

Even if you arbitrarily supplied a ranking between different address spaces, there's a possibility that the diff_t type would need to be a larger size. And the process of comparing or subtracting two pointers would be greatly complicated. That's a bad idea in a language that is designed for speed.

  • I understand thanks to you, that the pointer could not go out of its address space. But why the arithmetic is allowed only within the boundary of an array, why not allowing arithmetic on all the address space? – Oliv Dec 8 '17 at 18:38
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    @Oliv the standard doesn't have any concept of address spaces. It doesn't even assume the existence of a stack and a heap, even though everybody has them. The only way to specify the limitation in a way that makes sense is to do it in terms of an object or array. – Mark Ransom Dec 8 '17 at 19:14
  • Thank you this is exactly what I expected after I read your answer :). – Oliv Dec 8 '17 at 19:16
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    Note: program and data spaces are separated example: Harvard architecture. – chux Dec 8 '17 at 20:14

You only prove that the restriction could be removed - but miss that it would come with a cost (in terms of memory and code) - which was contrary to the goals of C.

Specifically the difference needs to have a type, which is ptrdiff_t, and one would assume it is similar to size_t.

In a segmented memory model you (normally) indirectly have a limitation on the sizes of objects - assuming that the answers in: What's the real size of `size_t`, `uintptr_t`, `intptr_t` and `ptrdiff_t` type on 16-bit systems using segmented addressing mode? are correct.

Thus at least for differences removing that restriction would not only add extra instructions to ensure a total order - for an unimportant corner case (as in other answer), but also spend double the amount of memory for differences etc.

C was designed to be more minimalistic and not to force compiler to spend memory and code on such cases. (In those days memory limitations mattered more.)

Obviously there are also other benefits - like the possibility to detect errors when mixing pointers from different arrays. Similarly as mixing iterators for two different containers is undefined in C++ (with some minor exceptions) - and some debug-implementations detect such errors.

  • So there is a limitation due to the difference type. But why limiting to the size of the complete object in which is originaly pointing the pointer? – Oliv Dec 8 '17 at 18:32
  • @Oliv Because there are systems that can have different kinds or segments of memory, where pointers into one kind of memory looks entirely different from the other kinds of memory, and there does not exist an good way to compare pointers to different kinds of memory - at least not without adding huge cost to every kind of pointer comparison (i.e. each comparison would need to first figure out what kind of memory it is and then carry that information alongside all pointers). So, not all systems provide a flat address space where the memory address is a simple unique number. – nos Dec 8 '17 at 18:42
  • @nos The information is carried somehow because without it, it would be impossible to dereference a pointer. For example, a function declared void f(int* p) should in any case be able to derefence p. So a int* must hold all the information (address space, segment, relative address). Or maybe, far and huge pointer had different types? – Oliv Dec 8 '17 at 19:00
  • Don't forget banked memory (en.wikipedia.org/wiki/Bank_switching)... banked architectures were popular back when C was being invented. Pointers in different banks simply can not be compared with each other in any sane manner. I've seen bank pages as small as 512 (two-byte) words (C would never work on such) and as large as 8K (two byte) words which did support compilers. Likely larger banks were out there but I never used them. – Gilbert Dec 9 '17 at 13:32
  • @Oliv, far and huge pointers were different types (or different type-prefixes or...). Comparing them would for me be similar to comparing map::iterator and vector::iterator (and not only between iterators from different vectors). Defining a total order would be possible for such cases, but in more than 99.99% of cases it is a mistake and detecting that is more helpful. – Hans Olsson Dec 12 '17 at 10:57

The reason is to keep the possibility to generate reasonable code. This applies to systems with a flat memory model as well as to systems with more complex memory models. If you forbid the (not very useful) corner cases like adding or subtracting out of arrays and demanding a total order on pointers between objects you can skip a lot of overhead in the generated code.

The limitations imposed by the standard allows the compiler to make assumptions on pointer arithmetic and use this to improve quality of the code. It covers both computing things statically in the compiler instead of at runtime and choosing which instrutions and addressing modes to use. As an example, consider a program with two pointers p1 and p2. If the compiler can derive that they point to different data objects it can safely assume that any no operation based on following p1 will ever affect the object pointed to by p2. This allows the compiler to reorder loads and stores based on p1 without consider loads and stores based on p2 and the other way around.

  • With flat memory model, I believe there are just no overhead. On segmented memory model, because compilers know to which segment belongs each pointer at compile time, they can generate the optimal code for pointers on the same segment and less optimal for pointers not belonging to the same segment. Could you develop on the "a lot of overhead"? – Oliv Dec 8 '17 at 11:30
  • @oliv This is not true in general, even with a flat memory model the ub-rules allows the compiler to make assumptions on pointer arithmetic and by that improve the quality of the code. It relates both to computing things statically in the compiler instead of at runtime and to which instructions to choose. – Johan Dec 8 '17 at 12:05
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    @Johan: can you give an example? – geza Dec 8 '17 at 12:32
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    @geza: As a simple example, consider int foo[10],bar[10],x; ... if (bar[0]) foo[x]++; return bar[0];. Should a compiler have to reload bar[0] after incrementing foo[x] to allow for the possibility that foo+x == bar? – supercat Dec 8 '17 at 20:56
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    But the compilers are going to assume that these two expressions may alias in almost all cases. Think about a function that take as argument two pointer to the same type, if you do not want the compiler to alias the expression above, you need to declare one "restrict". The only situation where compilers can infer that these two expressions are not aliading is when the compiler can deduce the original array of these pointers, that is when the arrays are declared in the direct context of these expressions. So this rule just do not help! – Oliv Dec 12 '17 at 22:38

The rationale is that some architectures have segmented memory, and pointers to different objects may point at different memory segments. The difference between the two pointers would then not necessarily be something meaningful.

This goes back all the way to pre-standard C. The C rationale doesn't mention this explicitly, but it hints at this being the reason, if we look where it explains the rationale why using a negative array index is undefined behavior (C99 rationale 5.10 6.5.6, emphasis mine):

In the case of p-1, on the other hand, an entire object would have to be allocated prior to the array of objects that p traverses, so decrement loops that run off the bottom of an array can fail. This restriction allows segmented architectures, for instance, to place objects at the start of a range of addressable memory.

  • Almost, so why if they had allowed p-1 (without allowing its deferencement) segmented architecture would not habe been allowed to place an object at the start of a range of addressable memory? – Oliv Dec 8 '17 at 17:58
  • @Oliv • I'm speculating, but maybe because decrementing C008:0000 becomes C008:FFF0 (for an array of something that takes 16-bytes per something), and that wrap-around would be tricky to handle (i.e., necessitating extra code, slower speed). Are segmented architectures still around? – Eljay Dec 11 '17 at 20:58
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    @Eljay: On an 8086 real mode compiler, subtracting one from 0xC008:0 would yield 0xC008:0xFFFF. Bizarrely enough, this behavior is actually very useful, since it means that objects larger than 32K can be handled using 16-bit arithmetic. A pointer to a 50,000-byte object will have a segment part that is less than 15536. If one tries to add 40,000 to it, that value will get converted to -25536 by integer wraparound, but adding -25536 to a pointer whose segment part is less than 15536 will add 40000 to the segment part. – supercat Jul 11 at 21:48

Since the C standard intends to cover the majority of processor architectures, it should also cover this one: Imagine an architecture (I know one, but wouldn't name it) where pointers are not just plain numbers, but are like structures or "descriptors". Such a structure contains information about the object it points into (its virtual address and size) and the offset within it. Adding or subtracting a pointer produces a new structure with only the offset field adjusted; producing a structure with the offset greater than the size of the object is hardware prohibited. There are other restrictions (such as how the initial descriptor is produced or what are the other ways to modify it), but they are not relevant to the topic.

In most cases where the Stanadrd classifies an action as invoking Undefined Behavior, it has done so because:

  1. There might be platforms where defining the behavior would be expensive. Segmented architectures could behave weirdly if code tries to do pointer arithmetic that extends beyond object boundaries, and some compilers may evaluate p > q by testing the sign of q-p.

  2. There are some kinds of programming where defining the behavior would be useless. Many kinds of code can get by just fine without relying upon forms of pointer addition, subtraction, or relational comparison beyond those given by the Standard.

  3. People writing compilers for various purposes should be capable of recognizing cases where quality compilers intended for such purposes should behave predictably, and handling such cases when appropriate, whether or not the Standard compels them to do so.

Both #1 and #2 are very low bars, and #3 was thought to be a "gimme". Although it has become fashionable for compiler writers to show off their cleverness by finding ways of breaking code whose behavior was defined by quality implementations intended for low-level programming, I don't think the authors of the Standard expected compiler writers to perceive a huge difference between actions which were required to behave predictably, versus those where nearly all quality implementations were expected to behave identically, but where there it might conceivably be useful to let some arcane implementations do something else.

I would like to answer this by inverting the question. Instead of asking why pointer addition and most of the arithmetic operations are not allowed, why do pointers allow only adding or subtracting an integer, post and pre increment and decrement and comparison (or subtraction) of pointers pointing to the same array? It is to do with the logical consequence of the arithmetic operation. Adding/subtracting an integer n to a pointer p gives me the address of nth element from the currently pointed element either in the forward or reverse direction. Similarly, subtracting p1 and p2 pointing to the same array gives me the count of elements between the two pointers. The fact (or design) that the pointer arithmetic operations are defined consistent with the type of variable it is pointing to is a real stroke of genius. Any operation other than the permitted ones defies programming or philosophically logical reasoning and therefore is not allowed.

  • Actualy, my question originate on the fact that these rules does not allow to implement an efficient vector, or a colony without UB. Unfortunatly, we use pointer to identify memory location too. – Oliv Dec 10 '17 at 21:21
  • @oliv What do you mean by "colony" in this context? – zwol Dec 11 '17 at 15:46
  • @zwol like the one of boost or plf. – Oliv Dec 11 '17 at 16:17
  • @oliv I don't know what that is, and searches do not bring it up. Do you have a specific URL for the thing you're talking about? – zwol Dec 11 '17 at 16:25
  • @zwol indeed google need these 3 words to find related results (boost cpp colony), it need to understand that you are making a search in the "coder" context. – Oliv Dec 12 '17 at 9:46

(Please do not upvote) This is a summary of the answer, and the reason why I choosed the Mark Ransom answer's, and to make this post: the answer is its post + its following comment.

The question was What are the reasons of such limitations (that pointer arithmetic and comparison must fall on a unique complete object)?

Ransom's comment+answer summary: since there is no concept of address space, the only possiblity to constrain pointer arithmetic to fall inside an address space was to constrain it on an object.

Krazy Glew comment's provides also a sociological oriented answer.

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