Following discussion from this question about null pointers in C and C++, I'd like to have the ending question separated here.

If it can be inferred from C and C++ standards (answers can target both standards) that dereferencing a pointer variable whose value is equal to the nullptr (or (void *)0) value is undefined behavior, does it imply that these languages require that a special value in the address space is dead, meaning that it's unusable except for the role of representing nullptr? What if the system has a really useful function or data structure at the same address that's equal to nullptr? Should this never happen because it's a compiler's writer responsibility to figure out a non-conflicting null pointer value for each system the compiler compiles to? Or should the programmer that needs to access such function or data structure be content while programming in "undefined behavior mode" to achieve its intents?

This looks like blurring the lines of the roles of a compiler and a computer system. I would ask whether it's right to do so, but I guess there's no room for this here.

This blog post digs about tackling the problem situation

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    I agree with separating the languages because they are both distinct languages, but the NULL in C++ (with the exception of nullptr) and NULL in C is the same thing so why separate them? Just ask one question to conquer both languages? I don't feel this question is specific to C or C++ but rather applies to both, no? – Brandon Feb 18 '15 at 1:13
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    @Brandon: That's the purview of an answer, not a question. For one thing, nullptr doesn't even exist in C, and the definition of NULL differs between the two languages. Furthermore, there is a ton of wording difference between the two around this topic. If the answers happen to be the same then great, but lumping together two distinct questions about two distinct languages just on the offchance of that is wrong. – Lightness Races in Orbit Feb 18 '15 at 1:15
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    @Brandon: The definitions of a null pointer are very similar in C and in C++. The definition of NULL has a somewhat significant difference. In C, ((void*)0) is a valid definition for NULL; in C++, it's not. That's not relevant to what you're asking, but it illustrates that you shouldn't assume C and C++ are identical in some way. – Keith Thompson Feb 18 '15 at 1:16
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    I don't know what the C and C++ fuss is about. The post clearly asks two questions. One about C and one about C++. No assumption about similarity between C and C++ was made or stated. Do C and C++ [blah blah]? The answer can be C [blah blah] but C++ doesn't [blah blah], or it can be both C and C++ [blah blah]. I don't think there's anything wrong with asking 2 questions in the same post. – thang Feb 18 '15 at 1:21
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    I personally find questions with lots of subquestions annoying and counter productive. and the consensus agrees. As an example, your previous post was even worse, containing multiple questions about multiple languages, and the result was a poor question and answers that failed to answer the problem. I'm not voting to close at this point, I am simply downvoting. – Yakk - Adam Nevraumont Feb 18 '15 at 2:35
up vote 3 down vote accepted

does it imply that these languages require that a special value in the address space is dead, meaning that it's unusable except for the role of representing nullptr?


The compiler needs a special value to represent a null pointer, and must take care that it does not place any object or function at that address, because all pointers to objects and functions are required to compare unequal to the null pointer. The standard library must take similar precautions in its implementation of malloc and friends.

However, if there is something at that address already, something that no strictly conforming program can access, then an implementation is allowed to support dereferencing the null pointer to access it. Dereferencing the null pointer is undefined in standard C, so an implementation can make it do anything it likes, including the obvious.

Both the C and the C++ standards understand the concept of the as-if rule, which basically means that if to valid input, an implementation is indistinguishable from one that conforms to the standard, then it does conform to the standard. The C standard uses a trivial example: Program execution

10 EXAMPLE 2 In executing the fragment

char c1, c2;
/* ... */
c1 = c1 + c2;

the "integer promotions" require that the abstract machine promote the value of each variable to int size and then add the two ints and truncate the sum. Provided the addition of two chars can be done without overflow, or with overflow wrapping silently to produce the correct result, the actual execution need only produce the same result, possibly omitting the promotions.

Now, if c1 and c2's values come from registers, and it's possible to force values outside of char's range into those registers (e.g. by inline assembly), then the fact that the implementation optimises away the integer promotions might be observable. However, since the only way to observe it is through undefined behaviour or implementation extensions, there is no way for any standard code to be affected by this, and an implementation is allowed to do it.

This is the same logic that applies to getting useful results when dereferencing null pointers: there are only two ways to see, from code, that there is something meaningful at that particular address: getting a null pointer from an evaluation that is guaranteed to produce a pointer to an object, or by just trying it. The former is what I mentioned the compiler and standard library must take care of. The latter is not something that can affect a valid standard program.

A well-known example is the interrupt vector table on DOS implementations, which resides at address zero. It is typically accessed simply by dereferencing a null pointer. The C and C++ standards don't, shouldn't and cannot cover access to the interrupt vector table. They do not define such behaviour, but they do not restrict access to it either. Implementations should be and are allowed to provide extensions to access it.

  • The other obvious example besides the interrupt table is main() itself. You can't legally form a pointer to that, so &main == nullptr may evaluate to true on a hypothetical implementation. – MSalters Feb 18 '15 at 16:26
  • @MSalters Only in C++, though. C does allow you to take a pointer to that. And C++ requires binary compatibility with a conforming C99 implementation in its extern "C" support, so any representation of null pointers that doesn't work for C also can't work for C++. But, I suppose a C++ compiled program could have a different address for main than a C compiled program would. – hvd Feb 18 '15 at 16:29
  • IIRC, that binary compatibility is limited, and in particular main would still need to be compiled as C++ because C99's startup code cannot be expected to call C++ constructors before main is entered. Which BTW is closely related to the reason C++ doesn't allow main to be recursively called, on reasonable implementations that would rerun global ctors. – MSalters Feb 18 '15 at 16:38
  • @MSalters Yep, and that's something that really does happen on Cygwin, which is easy to see if C++ code defines main, and C code contains an external declaration of main to call it. Valid code cannot do this, of course. – hvd Feb 18 '15 at 16:43
  • I've removed yours as correct answer because… – pepper_chico Jan 19 '17 at 15:37

That depends on what is meant by the phrase "address space". The C standard uses the phrase informally, but doesn't define what it means.

For each pointer type, there must be a value (the null pointer) that compares unequal to a pointer to any object or function. That means, for example, that if a pointer type is 32 bits wide, then there can be at most 232-1 valid non-null values of that type. There could be fewer than that if some addresses have more than one representation, or if not all representations correspond to valid addresses.

So if you define the "address space" to cover 2N distinct addresses, where N is the width in bits of a pointer, then yes, one of those values must be reserved as the null pointer value.

On the other hand, if the "address space" is narrower than that (for example, typical 64-bit systems can't actually access 264 distinct memory locations), then the value reserved as the null pointer can easily be outside the "address space".

Some things to note:

  • The representation of a null pointer may or may not be all-bits-zero.
  • Not all pointer types are necessarily the same size.
  • Not all pointer types necessarily use the same representation for a null pointer.

On most modern implementations, all pointer types are the same size, and all represent a null pointer as all-bits-zero, but there are valid reasons to, for example, make function pointers wider than object pointers, or make void* wider than int*, or use a representation other than all-bits-zero for the null pointer.

This answer is based on the C standard. Most of it also applies to C++. (One difference is that C++ has pointer-to-member types, which are typically wider than ordinary pointers.)

  • I come with this question from experience not only regarding a big OS, what about some microcontrollers for example, or other rather well used systems, where the OEM does put a function/data lying at address 0 (or any) while the available C compiler of such platform may make a mess of a pointer of such value because it's the value of a null pointer. – pepper_chico Feb 18 '15 at 1:55
  • @pepper_chico: The same answer applies. Some address value must be reserved as a null pointer. That value needn't necessarily be 0x00000000, but it often is. – Keith Thompson Feb 18 '15 at 2:02
  • This, from the point of view of the C and C++ compiler implementers that must take care for which and each system it's compiling for. This is to me quite weird, turn the language less portable, but anyway, if it's the way it's, ¯_ツ_¯ – pepper_chico Feb 18 '15 at 2:08
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    @pepper_chico: It doesn't harm portability as long as you write portable code. Well-written code doesn't care how a null pointer is represented. – Keith Thompson Feb 18 '15 at 2:09
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    @pepper_chico, I don't get your point about compiler implementation details making the language less portable. Of course the compiler isn't portable--that's it's job, to convert portable programs into non-portable machine-specific assembly. The compiler should know every little quirk of every different machine. It's job is to know that so the application programmer doesn't have to. – Lee Daniel Crocker Feb 18 '15 at 16:58

does it imply that these languages require that a special value in the address space is dead, meaning that it's unusable except for the role of representing nullptr?


C has requirements for null pointer that make it different to object pointers:

(C11, "[...] If a null pointer constant is converted to a pointer type, the resulting pointer, called a null pointer, is guaranteed to compare unequal to a pointer to any object or function."

What if the system has a really useful function or data structure at the same address that's equal to nullptr? Should this never happen because it's a compiler writer responsibility to figure out a non-conflicting null pointer value for each system the compiler compiles to?

The New C Standard by Derek M. Jones provides the following commentary on implementations:

All bits zero is a convenient execution-time representation of the null pointer constant for many implementations because it is invariably the lowest address in storage. (The INMOS Transputer[632] had a signed address space, which placed zero in the middle.) Although there may be program bootstrap information at this location, it is unlikely that any objects or functions will be placed here. Many operating systems leave this storage location unused because experience has shown that program faults sometimes cause values to be written into the location specified by the null pointer constant (the more developer-oriented environments try to raise an exception when that location is accessed).

Another implementation technique, when the host environment does not include address zero as part of a processes address space, is to create an object (sometimes called _ _null) as part of the standard library. All references to the null pointer constant refer to this object, whose address will compare unequal to any other object or function.

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    As pointed out correctly by KT, there is no requirement whatsoever that pointer values represent the address space at all, so to say that they require a "dead spot in the address space" is mistaken. – Lee Daniel Crocker Feb 18 '15 at 16:32
  • @LeeDanielCrocker My answer covers the general case but of course if your pointer width is larger than the available address space, no "dead spot" is required because the "dead spot" can anyway be set at an address outside the available address space. – ouah Feb 18 '15 at 16:53
  • It's interesting to learn about implementation techniques for this, thanks. – pepper_chico Feb 18 '15 at 23:33

Yes, that's precisely what it means.

[C++11: 4.10/1]: [..] A null pointer constant can be converted to a pointer type; the result is the null pointer value of that type and is distinguishable from every other value of object pointer or function pointer type. [..]

The null pointer value doesn't need to be 0x00000000, but it does need to be unique; there's no other way to make this rule work.

It's certainly not the only rule of the abstract machine that implicitly emplaces strict limitations upon practical implementations.

What if the OS puts a really useful function or data structure at the same address that's equal to nullptr?

The OS won't do that but it can be exploited.

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    @BWG: Not in a well-defined fashion, no. You are not [compliantly] permitted to decrement a pointer past the beginning of the object to which it points. It is a myth that simply won't die that you can just assign anything you like to a pointer! Unless you're wondering about within an array, pointer arithmetic is mostly UB. Of course in practice you can probably get your compiler to make it happen. Again, though, remember that neither nullptr nor (void*)0 needs to be actually 0x00000000. – Lightness Races in Orbit Feb 18 '15 at 1:00
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    i worked on a machine where ffffffff was null. It was a shock to me to see 0 as null. 0 seems a poor choice since every machine (real or virtual) has a an address 0 but most (or many) dont have an address FFFFFFFF so making fffffffff 'reserved' is less invasive – pm100 Feb 18 '15 at 1:07
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    The standard may be being clear that (int *)(void *)0 and variations are UB, but not so clear about *ptr, whether ptr is equal to (void *)0 or not. Previously I got quotations addressing this specifically, which means this difference of context in expressions is meaningful in some sense. – pepper_chico Feb 18 '15 at 1:14
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    @Brandon: No. The ! doesn't compare against a verbatim 0x00000000 in memory; pointers aren't integers. They are pointers! In fact, the standard says explicitly that converting a pointer to bool results in false iff the pointer holds the null pointer value. It doesn't really matter what that value is. (This, along with the special case that integer 0 is a null pointer constant regardless of how it'll be represented as a pointer in memory, means that this apparent oddity is rendered largely transparent to you in every way that matters.) – Lightness Races in Orbit Feb 18 '15 at 1:37
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    @Brandon: while (!p) is equivalent to while (p == 0), which by definition compares p to a null pointer. 0 is a null pointer constant, which is converted to a null pointer value. If a null pointer's representation is not all-bits-zero, the conversion is non-trivial. – Keith Thompson Feb 18 '15 at 1:37

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