The C standard specifies:

A pointer to void shall have the same representation and alignment requirements as a pointer to a character type. Similarly, pointers to qualified or unqualified versions of compatible types shall have the same representation and alignment requirements. All pointers to structure types shall have the same representation and alignment requirements as each other. All pointers to union types shall have the same representation and alignment requirements as each other. Pointers to other types need not have the same representation or alignment requirements.

i.e. sizeof(int*) is not necessarily equal to sizeof(char*) - but sizeof(struct A*) is necessarily equal to sizeof(struct B*).

What is the rationale behind this requirement? As I understand it the rationale behind differing sizes for basic types is to support use cases like near/far/huge pointers (edit: as was pointed out in comments and in the accepted answer, this is not the rationale) - but doesn't this same rationale apply to structs in different locations in memory?

  • 11
    I believe it is because of opaque pointers. The compiler needs to allocate a pointer without knowing the actual struct internals.
    – Eugene Sh.
    Aug 9 '21 at 20:16
  • 2
    It would be impossible to write type-erased interfaces without this, and forward declarations of structs moot, severely constraining the programmer.
    – SergeyA
    Aug 9 '21 at 20:19
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    @SergeyA Why would it be impossible to write type-erased interfaces? Functions like qsort work just fine on types that don't have the same-pointer-size restriction. Aug 9 '21 at 20:29
  • 1
    You can use a pointer to struct (or union) before the relevant struct (or union) is defined. struct node { struct node *next; /* struct node undefined here, but next is ok */ ... };
    – pmg
    Aug 9 '21 at 20:34
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    The rationale for differing sizes is not near/far pointers: those require an extension to standard C anyway. It's pointers to words vs pointers to bytes on architectures where individual bytes can't be accessed directly, only words, so a pointer to a byte is a word pointer plus some extra information indicating which part of the word the pointer points to. (Also data and code pointers can have different size, which is a little less exotic.) Aug 9 '21 at 20:38

The answer is very simple: struct and union types can be declared as opaque types, ie: without an actual definition of the struct or union details. If the representation of pointers was different depending on the structures' details, how would the compiler determine what representation to use for opaque pointers appearing as arguments, return values, or even just reading from or storing them to memory.

The natural consequence of the ability to manipulate opaque pointer types is all such pointers must have the same representation. Note however that pointers to struct and pointers to union may have a different representation, as well as pointers to basic types such as char, int, double...

Another distinction regarding pointer representation is between pointers to data and pointers to functions, which may have a different size. Such a difference is more common in current architectures, albeit still rare outside operating system and device driver space. 64-bit for function pointers seems a waste as 4GB should be amply sufficient for code space, but modern architectures take advantage of this extra space to store pointer signatures to harden code against malicious attacks. Another use is to take advantage of hardware that ignores some of the pointer bits (eg: x86_64 ignores the top 16 bits) to store type information or to use NaN values unmodified as pointers.

Furthermore, the near/far/huge pointer attributes from legacy 16 bit code were not correctly addressed by this remark in the C Standard as all pointers could be near, far or huge. Yet the distinction between code pointers and data pointers in mixed model code was covered by it and seems still current on some OSes.

Finally, Posix mandates that all pointers have the same size and representation so mixed model code should quickly become a historical curiosity.

It is arguable that architectures where the representation is different for different data types are vanishingly rare nowadays and it be high time to clean up the standard and remove this option. The main objection is support for architectures where the addressable units are large words and 8-bit bytes are addressed using extra information, making char * and void * larger than regular pointers. Yet such architectures make pointer arithmetics very cumbersome and are quite rare too (I personally have never seen one).

  • 1
    C does work just fine with tagged pointer types, where some bits of the pointer are used for type checking by the hardware. I've used that one a lot :) Aug 9 '21 at 20:56
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    3) I have used a nonconforming compiler that had sizeof(char *) be 2 but sizeof(const char *) be 3. It was about as annoying as it sounds.
    – Joshua
    Aug 9 '21 at 21:06
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    @Joshua: That's fine, your struct probably has a size of 2 and alignment of 1, but a pointer to such a struct has the same size and alignment as any other struct pointer.
    – chqrlie
    Aug 9 '21 at 21:06
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    @CraigEstey: Some Microchip processor. RAM was only 32k but ROM was bigger than 64k and const char * could point into ROM.
    – Joshua
    Aug 9 '21 at 21:09
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    "Posix mandates ... should quickly become a historical curiosity." POSIX shows no sign of taking significant marketshare in the embedded space that accounts for the vast majority of devices programmed in C.
    – Ben Voigt
    Aug 10 '21 at 15:06

In the C language invented by Dennis Ritchie, when a C compiler encountered a definition for struct foo *p; it would have no need to care about whether or how the structure was defined unless or until a program used pointer arithmetic or the -> operator. Otherwise, it could simply record that p was a pointer to a structure with tag foo without having to know or care about if, where, or how such a structure might be defined. The Standard adds an odd little wrinkle which sometimes makes structure pointers with matching tags incompatible, but the issue remains that a compiler must be able to process a declaration of a pointer-to-structure type, as well as basic assignments between such pointers, in cases where it might not know the contents of a structure.

Note that on platforms where pointers to objects with arbitrary alignment may be larger than pointers to objects that are known to have int alignment, a compiler might sensibly specify that all structures have int alignment even if they only contain character members. Further, compilers for such platforms might decide to process pointers to unions in such a way as to allow a pointer to any object--even a character--to be converted into a pointer to any union containing such an object, and used to access that object within the union. This may require that pointers to union objects be the size of a byte pointer, rather than a smaller int pointer.

Note that in pre-standard compilers, if two structures contained matching members, a function that accepted a void* and converted it into one structure type would have been expected to be usable to operate on both types interchangeably. Unfortunately, the Standard allows compilers to assume that code will never do such a thing, and provides no means for programmers to indicate when two structures should be usable interchangeably.

  • I think the standard (even C89) does provide for that, for any structures which have the same initial members (if all members from start to the ones you wish to access in both structs are not common, you have not told the compiler to align those members properly): one, you can put the common members into a single struct definition, and use that struct as the first member of any other struct that should be usable interchangeably; two, you can put the structs into a union, and access the common initial members of each struct through either of those struct members of the union.
    – mtraceur
    Nov 29 '21 at 6:06
  • @mtraceur: Given declarations struct {int x;} *p1; struct {int x;} *p2; and code p1->x = 1; p2->x=2; return p1->x;, the aliasing optimization logic in both clang nor gcc will (unless disabled with -fno-strict-aliasing) generate code that unconditionally returns 1.
    – supercat
    Nov 29 '21 at 15:40
  • We're going to need to get more specific. I'm not seeing the same result. When I compile a file containing just int f(struct {int x;} *p1, struct {int x;} *p2) { p1->x = 1; p2->x = 2; return p1->x; } with clang -c -Os -std=c89 -pedantic (same result with -O3 instead of -Os, and with c17 instead of c89), f turns into the following machine instructions on this ARMv8/AArch64 machine I'm on right now: mov w8, #0x1, mov w9, #0x2, str w8, [x0], str w9, [x1], ldr w0, [x0], ret.
    – mtraceur
    Nov 29 '21 at 18:35
  • Same result on an x86-64 machine I just tried it on with Clang. However, I went to reproduce it on godbolt and on godbolt I see what you're reporting with latest GCC (but not with latest Clang). I am willing to believe that GCC is technically correct here, but this is still all somewhat besides the point, because that's not what I had in mind when I said the standard provides a way to do this.
    – mtraceur
    Nov 29 '21 at 18:57
  • What I had in mind is that the standard provides several ways to explicitly tell the compiler "I intend for these two struct types to have common layout/members (at least at the beginning) and I intend for this function to operate on any struct with this common layout".
    – mtraceur
    Nov 29 '21 at 19:03

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