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The C standard allows pointers to different types to have different sizes, e.g. sizeof(char*) != sizeof(int*) is permitted. It does, however, require that if a pointer is converted to a void* and then back to its original type, it must compare as equal to its original value. Therefore, it follows logically that sizeof(void*) >= sizeof(T*) for all types T, correct?

On most common platforms in use today (x86, PPC, ARM, and 64-bit variants, etc.), the size of all pointers equals the native register size (4 or 8 bytes), regardless of the pointed-to type. Are there any esoteric or embedded platforms where pointers to different types might have different sizes? I'm specifically asking about data pointers, although I'd also be interested to know if there are platforms where function pointers have unusual sizes.

I'm definitely not asking about C++'s pointer-to-members and pointer-to-member-functions. Those take on unusual sizes on common platforms, and can even vary within one platform, depending on the properties of the pointer-to class (non-polymorphic, single inheritance, multiple inheritance, virtual inheritance, or incomplete type).

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Curious, what section of the standard allows for the different pointer sizes? Would you mind posting that section –  JaredPar May 27 '09 at 14:37
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Nit-pick: the "native integral type" in C has to be int, which is rarely 64-bit even on 64-bit platforms, AFAIK. In other words, LP64 is more common than ILP64. –  unwind May 27 '09 at 14:41
    
@JaredPar: I'm not exactly sure where it says so in the standard, but this page lysator.liu.se/c/rat/d9.html#4-9-6-1 makes mention of it, regarding the %p fprintf format specifier. @unwind: s/native integer size/native register size/ –  Adam Rosenfield May 27 '09 at 14:46
    
I would like to know if there is N for which the following holds: sizeof(anypointer) <= N*sizeof(int). Fo instance, if I assume that an int is no more than N=4 times smaller than a pointer, what are the odds that this assumption is wrong? –  Giovanni Funchal Aug 17 '09 at 18:45
    
Minor observation: The size of all struct X * pointers is the same. The reason is that you can forward declare a struct, e.g. struct X; and then put a pointer to it in another struct, struct Y { struct X *x; }; and the compiler can still know how much space struct Y requires, without knowing anything about struct X. –  Shahbaz Jan 13 at 18:50

7 Answers 7

up vote 32 down vote accepted

Answer from the C FAQ:

The Prime 50 series used segment 07777, offset 0 for the null pointer, at least for PL/I. Later models used segment 0, offset 0 for null pointers in C, necessitating new instructions such as TCNP (Test C Null Pointer), evidently as a sop to all the extant poorly-written C code which made incorrect assumptions. Older, word-addressed Prime machines were also notorious for requiring larger byte pointers (char *'s) than word pointers (int *'s).

The Eclipse MV series from Data General has three architecturally supported pointer formats (word, byte, and bit pointers), two of which are used by C compilers: byte pointers for char * and void *, and word pointers for everything else. For historical reasons during the evolution of the 32-bit MV line from the 16-bit Nova line, word pointers and byte pointers had the offset, indirection, and ring protection bits in different places in the word. Passing a mismatched pointer format to a function resulted in protection faults. Eventually, the MV C compiler added many compatibility options to try to deal with code that had pointer type mismatch errors.

Some Honeywell-Bull mainframes use the bit pattern 06000 for (internal) null pointers.

The CDC Cyber 180 Series has 48-bit pointers consisting of a ring, segment, and offset. Most users (in ring 11) have null pointers of 0xB00000000000. It was common on old CDC ones-complement machines to use an all-one-bits word as a special flag for all kinds of data, including invalid addresses.

The old HP 3000 series uses a different addressing scheme for byte addresses than for word addresses; like several of the machines above it therefore uses different representations for char * and void * pointers than for other pointers.

The Symbolics Lisp Machine, a tagged architecture, does not even have conventional numeric pointers; it uses the pair (basically a nonexistent handle) as a C null pointer.

Depending on the ``memory model'' in use, 8086-family processors (PC compatibles) may use 16-bit data pointers and 32-bit function pointers, or vice versa.

Some 64-bit Cray machines represent int * in the lower 48 bits of a word; char * additionally uses some of the upper 16 bits to indicate a byte address within a word.

Additional links: A message from Chris Torek with more details about some of these machines.

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+1 Why is this not the accepted answer?.. –  dcow Jun 30 '12 at 16:38
    
@David Cowden Suspect this answer was written 4 months after the accepted one. Since the OP asked for an example and got it - that answer was accepted. This post, certainly more complete, deserved its high vote rating. Maybe highly rated non-accepted answers deserve a community "accept override"? That sounds like a "meta" question though. –  chux Oct 10 '13 at 22:52
    
@chux probably better to just notify the asker that a response to their question has vastly surpassed the accepted answer and let them reconsider. Ultimately it's up to the asker to determine which response best answers their question. I simply commented to underscore the fact that I very much enjoy this answer (= –  dcow Oct 11 '13 at 0:13
    
@chux that's what the 'Populist' badge is for. stackoverflow.com/help/badges/62/populist –  Aric TenEyck Dec 24 '13 at 19:52

Back in the golden years of DOS, 8088s and segmented memory, it was common to specify a "memory model" in which e.g. all code would fit into 64k (one segment) but data could span multiple segments; this meant that a function pointer would be 2 bytes, a data pointer, 4 bytes. Not sure if anybody is still programming for machines of that kind, maybe some still survive in embedded uses.

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They are not that uncommon in the embedded world. DOS is still used a lot. –  Nils Pipenbrinck Mar 10 '10 at 13:07
    
@Nils, I recently (well after I'd posted this) interviewed a new grad (EE) and his main assembly experience (from embedded uses, of course) turned out to be with Intel 8051 and Freescale 6811 -- 8-bit descendants of CPUs I studied at college in the '70s (!), and even then we hankered for more powerful ones such as Zilog Z80. So 8088 and DOS would be a big step up there...! –  Alex Martelli Mar 10 '10 at 15:08

Not quite what you're asking, but back in the 16-bit DOS/Windows days, you did have the distinction between a pointer and a far-pointer, the latter being 32-bits.

I might have the syntax wrong...

int *pInt = malloc(sizeof(int));
int far *fpInt = _fmalloc(sizeof(int));

printf("pInt: %d, fpInt: %d\n", sizeof(pInt), sizeof(fpInt));

Output:

pInt: 2, fpInt 4

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Bah, I completely forgot about near and far pointers. I was aware of their existence, but when I was writing this question, they totally slipped my mind. –  Adam Rosenfield May 27 '09 at 14:47
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Is 16bit DOS supposed to be an example with a standard conforming compiler? –  sellibitze Oct 10 '10 at 20:15

One could easily imagine a Harvard architecture machine having different sizes for function pointers and all other pointers. Don't know of an example...

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Harvard Architecture used often in embedded processors (PIC) in 2013. –  chux Oct 10 '13 at 22:55
    
Yes, Harvard architectures show up in a lot of embedded chips. But do you know of one that implements function-pointers that are a different size than the other pointers on the same platform? –  dmckee Oct 10 '13 at 23:15
    
PIC16 (CCS compiler) used a goofy 9-10 bit RAM (1-2 bit page reg and 8-bit offset.) Cumbersome to even memcpy(). Non-volatile data is stuck in ROM (I think 14-16 bit even address pointing to 1 byte) and used a special memcpy()/strcpy(). Functions are hard to get/use via a function pointer, also have the 14-16 bit address into a half 14-bit instruction word, so address must be even. Sure I've gotten this story messed up as I use a PIC24 much more often and let the compiler deal with addresses knowing, I, the coder, must not wily-nilly mix pointer types. –  chux Oct 10 '13 at 23:53

Therefore, it follows logically that sizeof(void*) >= sizeof(T*) for all types T, correct?

That doesn't necessarily follow, since sizeof is about the storage representation, and not all bit-patterns have to be valid values. I think you could write a conformant implementation where sizeof(int*) == 8, sizeof(void*) == 4, but there are no more than 2^32 possible values for an int*. Not sure why you'd want to.

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It depends on your definition of "logically" ;v) –  Potatoswatter Aug 19 '10 at 9:27
    
How could malloc() be used to allocate, and then assign, an int*? Also, did you mean "There are no more than 2^32 possible values for an int*" or "for an int"? –  smci Dec 2 '11 at 20:28
    
@smci: I meant for an int*. The point is that provided there are no more than 2^32 legal values for an int* then it doesn't matter what the size of int* is, or which values are the legal ones, the implementation can still implement conversion from int* to a 4-byte void* and back again. You can allocate and then assign an int* using malloc as follows: int **ppint = malloc(sizeof(*ppint)); *ppint = 0;. But I don't see what that has to do with either the question or my answer. –  Steve Jessop Dec 4 '11 at 1:24
    
But you were talking about the case sizeof(int*) == 8. I guess you meant "8 bytes, but with the high 4 bytes zero-padded". That's not really the general case sizeof(int*) == 8 –  smci Dec 6 '11 at 0:56
    
Right, it could be the high bytes that are padding. It could be some other bytes. The distribution of used and unused values could be very complex. As I said, I can't think of any good reasons to actually implement that, but I'm not talking about the general case, I'm talking about whether or not something "follows logically". The general case is that sizeof(T*) is the same for all object types T. –  Steve Jessop Dec 6 '11 at 9:44

Near and far pointers are still used on some embedded microcontrollers with paged flash or RAM, to allow you to point to data in the same page (near pointer), or another page (far pointer, which is larger because it includes page information).

For example, Freescale's HCS12 microcontroller uses a 16-bit Von Neumann architecture, which means that no address can be more than 16 bits. Because of the limitation this would put on the amount of code space available, there is an 8-bit page register.

So to point to data in the same code page, you just specify the 16-bit address; this is a near pointer.

To point to data in another code page, you have to include both the 8-bit page number and the 16-bit address within that page, resulting in a 24-bit far pointer.

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It is possible that the size of pointers to data differs from pointers to functions for example. It is common for this to occur in microprocessor for embedded system. Harvard architecture machines like dmckee mentioned makes this easy to happen.

It turns out that it makes gcc backends a pain to develop! :)

Edit: I can't go into the details of the specific machine I am talking about but let me add why Harvard machines make this easy to happen. The Harvard architecture has different storage and pathways to instructions and data, therefore if the bus for the instructions is 'larger' than the one for data, you're bound to have a function pointer whose size is bigger than a pointer to data!

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