As a newcomer to C, I'm confused about when casting a pointer is actually OK.

As I understand, you can pretty much cast any pointer type to any other type, and the compiler will let you do it. For example:

int a = 5;
int* intPtr = &a;
char* charPtr = (char*) intPtr; 

However, in general this invokes undefined behavior (though it happens to work on many platforms). This said, there seem to be some exceptions:

  • you can cast to and from void* freely (?)
  • you can cast to and from char* freely (?)

(at least I've seen it in code...).

So which casts between pointer types are not undefined behaviour in C?


I tried looking into the C standard (section " Pointers", at http://c0x.coding-guidelines.com/ ), but didn't really understand it, apart from the bit about void*.


Just for clarification: I'm explicitly only asking about "normal" pointers, i.e. not about function pointers. I realize that the rules for casting function pointers are very restrictive. As I matter of fact, I've already asked about that :-): What happens if I cast a function pointer, changing the number of parameters

4 Answers 4



  • a T * may be freely converted to a void * and back again (where T * is not a function pointer), and you will get the original pointer.
  • a T * may be freely converted to a U * and back again (where T * and U * are not function pointers), and you will get the original pointer if the alignment requirements are the same. If not, the behaviour is undefined.
  • a function-pointer may be freely converted to any other function-pointer type and back again, and you will get the original pointer.

Note: T * (for non-function-pointers) always satisfies the alignment requirements for char *.

Important: None of these rules says anything about what happens if you convert, say, a T * to a U * and then try to dereference it. That's a whole different area of the standard.

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    In addition to point two, if the alignment requirements are the same, a cast back from U* to T* will compare equal to the original T*. Jan 26, 2011 at 22:03
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    @Oli Charlesworth: About "if the alignment requirements are the same": What is the "alignment requirement", and how am I supposed to know it for a given type? Does the standard say something about it. Is there some operator like alignment, like sizeof?
    – sleske
    Jan 26, 2011 at 22:18
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    @malfy: there's no requirement that alignment be the same as an object's size. An object's size will influence it's alignment requirements, and the alignment of an object will influence the size of the object (in that the size will have to be a multiple of the alignment). But there's nothing that says that an object's size and alignment need to be the same. There are even platforms where alignment isn't a requirement at all. Jan 26, 2011 at 22:29
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    @sleske: A T * (for any non-function T) is guaranteed by design to be correctly aligned for a char *. What's more, the standard guarantees that one is allowed to dereference the char * and access the underlying data (this isn't true for any other destination type). Jan 26, 2011 at 22:35
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    @sleske: Due to the way arrays and object sizes interact (the size of a type is equal to the spacing of that type within an array), required alignment of a type must evenly divide the size of a type. Since the size of char is fixed as 1, the alignment of char cannot be anything else but 1 also.
    – caf
    Jan 27, 2011 at 4:57

Oli Charlesworth's excellent answer lists all cases where casting a pointer to a pointer of a different type gives a well-defined result.

In addition, there are four cases where casting a pointer gives implementation-defined results:

  • You can cast a pointer to an sufficiently large (!) integer type. C99 has the optional types intptr_t and uintptr_t for this purpose. The result is implementation-defined. On platforms that address memory as a contiguous stream of bytes ("linear memory model", used by most modern platforms), it usually returns the numeric value of the memory address the pointer points to, thus simply a byte count. However, not all platforms use a linear memory model, which is why this is implementation-defined :-).
  • Conversely, you can cast an integer to a pointer. If the integer has a type large enough for intptr_t or uintptr_t and was created by casting a pointer, casting it back to the same pointer type will give you back that pointer (which however may no longer be valid). Otherwise the result is implementation-defined. Note that actually dereferencing the pointer (as opposed to just reading its value) may still be UB.
  • You can cast a pointer to any object to char*. Then the result points to the lowest addressed byte of the object, and you can read the remaining bytes of the object by incrementing the pointer, up to the object's size. Of course, which values you actually get is again implementation-defined...
  • You can freely cast null pointers, they'll always stay null pointers regardless of pointer type :-).

Source: C99 standard, sections "Pointers", and "Integer types capable of holding object pointers".

As far as I can tell, all other casts of a pointer to a pointer of a different type are undefined behavior. In particular, if you are not casting to char or a sufficiently large integer type, it may always be UB to cast a pointer to a different pointer type - even without dereferencing it.

This is because the types may have different alignment, and there is no general, portable way to make sure different types have compatible alignment (except for some special cases, such as signed/unsigned integer type pairs).

  • I think it might be better to start with the second point (conversion from pointer to integer) and then specify that if a pointer-to-integer conversion has ever yielded a particular integer value, and the object identified by the pointer at the of the conversion yielded that value is still valid, then casting that particular integer value to a pointer is defined by the standard to yield a pointer equivalent to the original. I don't think implementations are required to promise any behaviors beyond that.
    – supercat
    May 6, 2015 at 23:17
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    @supercat: Thanks for the suggestion. Actually, I think C99 is even stricter: The roundtrip pointer->int->pointer is only guaranteed to give back the same pointer if the integer type used is `(u)intptr_t´ (C99, "Integer types capable of holding object pointers") - you can't just use any sufficiently large int type. I edited my post.
    – sleske
    May 8, 2015 at 14:57
  • If type intptr_t exists [its existence is optional] then an integer type is capable of holding all the values which intptr_t could hold, I would expect a conversion from a pointer to that type would be processed as equivalent to a conversion to intptr_t followed by a conversion to that other type. Such behavior (the fact that any size integer can be coerced to any other) would be the only basis for unsigned short x = somePointer; having any meaning on machines where unsigned short can't hold a pointer.
    – supercat
    May 8, 2015 at 15:05
  • As it is, while I can't see much use for short x=somePointer; it's meaning is established by the standard. Given short x1=p1,x2=p2; int result = (x1==x2);, the result would be the same as would be computed by uintptr_t u1=p1,u2=p2; int result = ((short)u1==(short)u2);.
    – supercat
    May 8, 2015 at 15:08
  • @supercat: Yes, that seems correct. I edited again :-). Hope my text is right now.
    – sleske
    May 8, 2015 at 15:13

Generally, if as usual nowadays the pointers themselves have the same alignment properties, the problem is not the cast itself, but whether or not you may access the data through the pointer.

Casting any type T* to void* and back is guaranteed for any object type T: this is guaranteed to give you exactly the same pointer back. void* is the catch all object pointer type.

For other casts between object types there is no guarantee, accessing an object through such a pointer may cause all sorts of problems, such as alignments (bus error), trap representations of integers. Different pointer types are not even guaranteed to have the same width, so theoretically you might even loose information.

One cast that should always work, though, is to (unsigned char*). Through such a pointer you may then investigate the individual bytes of your object.

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    Note that casting from one pointer type to another pointer type might result in undefined behavior even if you don't attempt to dereference the pointer (if the pointer would be of an incorrect alignment for the destination type). Jan 26, 2011 at 22:35
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    There's no need for the (void *) in (unsigned char *)(void *). Jan 27, 2011 at 0:10
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    @sleske: no, not always. The case of casting to character type pointers is explicitly foreseen in the standard. As far as I am able to read this through the lines accessing through a pointer of different type is only UB if the target memory can not be interpreted as a valid object of the target type. Since this can never happen for unsigned char this is ok. (I find the standard particularly unclear about alignment issues, do they mean the alignment of the pointer type, or of the pointed-to type?) Jan 27, 2011 at 16:07
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    @sleske: I didn't say char I said unsigned char. For signed char (and so for char if it is signed) this is special because of the possible problems with trap representations for the type. But by definition in the standard unsigned char never has trap representations or padding bits, and so accessing the individual bytes as unsigned char is always well defined and there is no room for interpretation. Access through unsigned char to the components of an object is foreseen as such at several places of the standard. Jan 27, 2011 at 16:22
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    @Jens Gusted: Yes, that's correct (sorry about the signed/unsigned thing, my mistake). My point is that while you certainly can access the components of an object as bytes by casting to unsigned char*, the values you get for the components are implementation-defined. You can cast e.g. double* to char*, but the values you get by dereferencing the result will depend on the platform's represenation of FP values (hence implementation-defined). Or am I missing something?
    – sleske
    Jan 27, 2011 at 16:38

The authors of the Standard made no attempt to weigh the costs and benefits of supporting conversions among most combinations of pointer types on platforms where such support would be expensive, since:

  1. Most platforms where such conversions would be expensive would likely have been obscure ones the authors of the Standard didn't know about.

  2. People using such platforms would be better placed than the authors of the Standard with the costs and benefits of such support.

If some particular platform uses a different representation for int* and double*, I think the Standard would deliberately allow for the possibility that e.g. round-drip conversion from double* to int* and back to double* would work consistently but conversions from int* to double* and back to int* might fail.

I don't think the authors of the Standard intended that such operations might fail on platforms where such conversions cost nothing. They described the Spirit of C in the charter and rationale documents as including the principle "Don't prevent [or needlessly obstruct] the programmer from doing what needs to be done." Given that principle, there would be no need for the Standard to mandate that implementations process actions in a way that helps programmers accomplish what they need to do in cases where doing so would cost nothing, since implementations that make a bona fide effort to uphold the Spirit of C will behave in such fashion with or without a mandate.

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