Is the behaviour of this code well defined?

#include <stdio.h>
#include <stdint.h>

int main(void)
    void *ptr = (char *)0x01;
    size_t val;

    ptr = (char *)ptr + 1;
    val = (size_t)(uintptr_t)ptr;

    printf("%zu\n", val);
    return 0;

I mean, can we assign some fixed number to a pointer and increment it even if it is pointing to some random address? (I know that you can not dereference it)

  • 25
    @Dan - Hardly a test of code validity. Plenty of code with undefined behavior "compiles and runs". Jun 28, 2018 at 12:50
  • 37
    @Dan - What part of "undefined" is not clear? Undefined doesn't mean "unexpected results". It can appear to work just fine for years. That's the problem. Jun 28, 2018 at 12:56
  • 28
    @Dan Considering the print statement, it should print the value 2. That's the well-defined behaviour check right there. I'll get right to the point: that statement of yours demonstrates a complete lack of understanding of "undefined behavior". "I ran it and it even emitted the output I expected" most certainly does not preclude undefined behavior. Jun 28, 2018 at 13:03
  • 11
    @Dan In other words, Undefined Behavior roughly means that the spec doesn't specify what should happen. In fact, IIRC the spec defines that any program with undefined behavior can compile to whatever the compiler wants since it's undefined. That includes both "compiles perfectly to the instructions you expected/wanted", but also "compiles into code that just prints 2", and also "fails to compile". Something doing what you expect can still be undefined behavior.
    – Delioth
    Jun 28, 2018 at 14:25
  • 8
    @Dan: Among the behaviors that fall under the description of undefined behavior is "do exactly what you expect when you're testing, and then do something else entirely when you're doing something important and/or have convinced yourself that this can never be the cause of the bugs you're finding".
    – user1084944
    Jun 28, 2018 at 14:36

5 Answers 5


The assignment:

void *ptr = (char *)0x01;

Is implementation defined behavior because it is converting an integer to a pointer. This is detailed in section of the C standard regarding Pointers:

5 An integer may be converted to any pointer type. Except as previously specified, the result is implementation-defined, might not be correctly aligned, might not point to an entity of the referenced type, and might be a trap representation.

As for the subsequent pointer arithmetic:

ptr = (char *)ptr + 1;

This is dependent on a few things.

First, the current value of ptr may be a trap representation as per above. If it is, the behavior is undefined.

Next is the question of whether 0x1 points to a valid object. Adding a pointer and an integer is only valid if both the pointer operand and the result point to elements of an array object (a single object counts as an array of size 1) or one element past the array object. This is detailed in section 6.5.6:

7 For the purposes of these operators, a pointer to an object that is not an element of an array behaves the same as a pointer to the first element of an array of length one with the type of the object as its element type

8 When an expression that has integer type is added to or subtracted from a pointer, the result has the type of the pointer operand. If the pointer operand points to an element of an array object, and the array is large enough, the result points to an element offset from the original element such that the difference of the subscripts of the resulting and original array elements equals the integer expression. In other words, if the expression P points to the i-th element of an array object, the expressions (P)+N (equivalently, N+(P) ) and (P)-N (where N has the value n ) point to, respectively, the i+n-th and i−n-th elements of the array object, provided they exist. Moreover, if the expression P points to the last element of an array object, the expression (P)+1 points one past the last element of the array object, and if the expression Q points one past the last element of an array object, the expression (Q)-1 points to the last element of the array object. If both the pointer operand and the result point to elements of the same array object, or one past the last element of the array object, the evaluation shall not produce an overflow; otherwise, the behavior is undefined. If the result points one past the last element of the array object, it shall not be used as the operand of a unary * operator that is evaluated.

On a hosted implementation the value 0x1 almost certainly does not point to a valid object, in which case the addition is undefined. An embedded implementation could however support setting pointers to specific values, and if so it could be the case that 0x1 does in fact point to a valid object. If so, the behavior is well defined, otherwise it is undefined.

  • 1
    I was wondering about that section in 6.5.6 and how it applies to this case. if (char *)ptr is considered to be pointing to the first element of a 1-element array, then would (char *)ptr + 1 not be pointing one past the last element of a 1-element array? Jun 28, 2018 at 13:16
  • 2
    Your quote of p8 would be relevant if the OP didn't add +1. But... There's p7 to consider. Jun 28, 2018 at 13:17
  • 2
    I think the pointer arithmetic is implementation defined because: The assignment is implementation defined. If the implementation results in a pointer to inside a char array then ptr + 1 is well defined. On the other hand if the implementation returns e.g. a trap then it is UB. Jun 28, 2018 at 14:20
  • 3
    @GoswinvonBrederlow: I don't think implementation defined behavior is allowed to be undefined. But I know what you're trying to say -- whether or not the addition is undefined behavior depends on implementation defined choices.
    – user1084944
    Jun 28, 2018 at 14:31
  • 2
    Strictly speaking, couldn't this be well-defined on a specific implementation? i.e. if (int *)0x01 was defined by my fictional implementation WeirdC to point to a valid char array, would that make the rest valid as well, albeit only on WeirdC? I ask because this is relevant for e.g. embedded development, where you might well be using pointers to some given integer value to modify data.
    – anon
    Jun 28, 2018 at 17:15

No, the behaviour of this program is undefined. Once an undefined construct is reached in a program, any future behaviour is undefined. Paradoxically, any past behaviour is undefined too.

The result of void *ptr = (char*)0x01; is implementation-defined, due in part to the fact that a char can have a trap representation.

But the behaviour of the ensuing pointer arithmetic in the statement ptr = (char *)ptr + 1; is undefined. This is because pointer arithmetic is only valid within arrays including one past the end of the array. For this purpose an object is an array of length one.

  • Comments are not for extended discussion; this conversation has been moved to chat.
    – user3956566
    Jun 29, 2018 at 19:24

Yes, the code is well-defined as implementation-defined. It is not undefined. See ISO/IEC 9899:2011 []/5 and note 67.

The C language was originally created as a system programming language. Systems programming required manipulating memory-mapped hardware, requiring that you would stuff hard-coded addresses into pointers, sometimes increment those pointers, and read and write data from and to the resulting address. To that end, assigning and integer to a pointer and manipulating that pointer using arithmetic is well defined by the language. By making it implementation-defined, what the language allows is that all kinds of things can happen: from the classic halt-and-catch-fire to raising a bus error when trying to dereference an odd address.

The difference between undefined behaviour and implementation-defined behaviour is basically undefined behaviour means "don't do that, we don't know what will happen" and implementation-defined behaviour means "it's OK to go ahead and do that, it's up to you to know what will happen."

  • 2
    “manipulating that pointer using arithmetic is well defined by the language” — citation needed. Jun 28, 2018 at 16:44
  • 4
    The language standard specifically defines that pointer arithmetic is only valid within the bounds of an object
    – M.M
    Jun 28, 2018 at 21:12
  • 2
    I think it's pretty clear that this is UB in the C standard (because of typically creating a pointer outside the bounds of any object), but many implementations will define the behaviour of pointers in more cases than the C standard does. e.g. if you don't dereference them, on many implementations it is safe to create pointers that don't point inside any object. Jun 29, 2018 at 3:21
  • @PeterCordes: The Standard makes no attempt to mandate that all implementations be suitable for low-level systems programming, nor does it in any way imply that it's possible to have a quality implementation that is suitable for low-level or systems programming without it supporting behaviors beyond those mandated by the Standard (and which might not be processed predictably by implementations that aren't suitable for systems programming).
    – supercat
    Jun 29, 2018 at 16:20

It is undefined behavior.

From N1570 (emphasis added):

An integer may be converted to any pointer type. Except as previously specified, the result is implementation-defined, might not be correctly aligned, might not point to an entity of the referenced type, and might be a trap representation.

If the value is a trap representation, reading it is undefined behavior:

Certain object representations need not represent a value of the object type. If the stored value of an object has such a representation and is read by an lvalue expression that does not have character type, the behavior is undefined. If such a representation is produced by a side effect that modifies all or any part of the object by an lvalue expression that does not have character type, the behavior is undefined.) Such a representation is called a trap representation.


An identifier is a primary expression, provided it has been declared as designating an object (in which case it is an lvalue) or a function (in which case it is a function designator).

Therefore, the line void *ptr = (char *)0x01; is already potentially undefined behavior, on an implementation where (char*)0x01 or (void*)(char*)0x01 is a trap representation. The left-hand side is an lvalue expression that does not have character type and reads a trap representation.

On some hardware, loading an invalid pointer into a machine register could crash the program, so this was a forced move by the standards committee.

  • 1
    So far as I can tell, even on platforms where loading an invalid pointer into a machine register could trigger a trap, the statement int *p = (int*)someValue; would have defined behavior provided nothing tries to use the pointer in p, regardless of whether the expression yields a valid pointer. Were that not the case, the construct would always invoke Undefined Behavior, since--precisely as with UB--the behavior would be behave usefully on implementations that choose to specify useful behavior, and behave unpredictably on implementations that don't.
    – supercat
    Jun 29, 2018 at 20:50
  • @supercat It looks to me that, on a machine where (char*)0x01 were a trap representation, ptr in the expression void *ptr = (char*)0x01; is a lvalue expression that reads that value and does not have character type, which is stated to be UB? If not, the next line that uses ptr definitely is. Am I misunderstanding?
    – Davislor
    Jun 29, 2018 at 21:58
  • The line which uses reads ptr and casts it to uintptr_t would invoke UB if (char*)1 were a trap representation. The presence within an expression of an lvalue that holds a trap representation, however, only invokes UB in cases where the lvalue is evaluated. In the declaration void *ptr = (char*)0x01; however, there is no lvalue, and if the declaration and store were split off as in void *ptr; ptr = (char*)0x01; the statement after the declaration would contain the lvalue ptr, but would write to that lvalue without evaluating it.
    – supercat
    Jul 5, 2018 at 19:11
  • @supercat I quote the section of the (draft) standard that says an identifier is a lvalue, and for a lvalue (such as ptr) whose type is not a character type (such as void*) to read a trap representation is already UB. So, a compiler would be permitted to emit a machine instruction to read the invalid bit pattern into an address or segment register, on a CPU where that would cause a hardware trap. If you interpret the standard differently, then we can still agree that the increment is UB in this case?
    – Davislor
    Jul 5, 2018 at 19:25
  • @supercat And that’s a reasonable behavior characteristic of many environments. Many architectures, including x86 with segment registers in protected mode, have trap representations for pointers, and the expected behavior of an int-to-pointer conversion could well be to load that exact bit pattern and shoot yourself in the foot.
    – Davislor
    Jul 5, 2018 at 19:38

The Standard does not require that implementations process integer-to-pointer conversions in a meaningful fashion for any particular integer values, or even for any possible integer values other than Null Pointer Constants. The only thing it guarantees about such conversions is that a program which stores the result of such a conversion directly into an object of suitable pointer type and does nothing with it except examine the bytes of that object will, at worst, see Unspecified values. While the behavior of converting an integer to a pointer is Implementation-Defined, nothing would forbid any implementation (no matter what it actually does with such conversions!) from specifying that some (or even all) of the bytes of the representation having Unspecified values, and specifying that some (or even all) integer values may behave as though they yield trap representations.

The only reasons the Standard says anything at all about integer-to-pointer conversions are that:

  1. In some implementations, the construct is meaningful, and some programs for those implementations require it.

  2. The authors of the Standard did not like the idea of a construct that was used on some implementations would represent a constraint violation on others.

  3. It would have been odd for the Standard to describe a construct but then specify that it has Undefined Behavior in all cases.

Personally, I think the Standard should have allowed implementations to treat integer-to-pointer conversions as constraint violations if they don't define any situations where they would be useful, rather than require that compilers accept the meaningless code, but that wasn't the philosophy at the time.

I think it would be simplest to simply say that any operation involving integer-to-pointer conversions with anything other than intptr_t or uintptr_t values received from pointer-to-integer conversions invokes Undefined Behavior, but then note that it is common for quality implementations intended for low-level programming to process Undefined Behavior "in a documented manner characteristic of the environment". The Standard doesn't specify when implementations should process programs that invoke UB in that fashion but instead treats it as a Quality of Implementation issue.

If an implementation specifies that integer-to-pointer conversions operate in a fashion that would define the behavior of

char *p = (char*)1;

as equivalent to "char p = (char)2;", then the implementation should be expected to work that way. On the other hand, an implementation could define the behavior of integer-to-pointer conversion in such a way that even:

char *p = (char*)1;
char *q = p;  // Not doing any arithmetic here--just a simple assignment

would release nasal demons. On most platforms, a compiler where arithmetic on pointers produced by integer-to-pointer conversions behaved oddly would not be viewed as a high-quality implementation suitable for low-level programming. A programmer that is not intending to target any other kind of implementations could thus expect such constructs to behave usefully on compilers for which the code was suitable, even though the Standard does not require it.

  • 1
    @M.M: In what cases is the act of storing a trap representation yield UB? The Standard specifically says that the action yields a pointer that may be a trap representation, rather than saying that the action may invoke UB. If the cast itself could invoke UB, that would of course allow it to yield a trap representation, but saying so would be meaningless since the cast would be allowed to do anything else whatsoever. Note that "might" is rather vague as to whether it is granting permission to the implementation to do something other than yield a pointer to a valid object, or...
    – supercat
    Jul 1, 2018 at 18:29
  • 1
    ...is giving permission to the programmer to form such a pointer without invoking UB, provided that the pointer isn't actually used in an invalid way [and, as noted, I know of nothing to suggest that the act of storing anything into a legitimate object of a particular type using an lvalue of that type might do anything other than alter the stored value in that object].
    – supercat
    Jul 1, 2018 at 18:32
  • 1
    @M.M: Of course, the authors of the Standard don't make much effort to handle actions which would have meaningful and necessary on some platforms and application fields, but not others. Occasionally, they say such actions should have defined behavior even on platforms/fields where they would serve no purpose. More often, they invoke UB even on platforms/fields where it's meaningful and necessary. If quality implementations for such platforms can be expected to process them in a fashion characteristic of the environment regardless of what the Standard mandates...
    – supercat
    Jul 1, 2018 at 19:06
  • 1
    ...it shouldn't really matter whether the Standard defines such behaviors or not. The only reason any of these issues pose problems is that some compiler writers have become more interested in identifying cases that can be regarded as invoking UB than in cases where platforms would have useful characteristic behaviors which programmers might benefit from or rely upon.
    – supercat
    Jul 1, 2018 at 19:07
  • 1
    @Davislor: Even when round-tripping, the Standard imposes no requirements about what happens if code does anything with the resulting pointer other than compare it for equality with other pointers. Obviously a quality implementation should be able to offer behavioral guarantees in many such cases, but the Standard doesn't require it.
    – supercat
    Jul 5, 2018 at 19:42

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