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Suppose I have this in list.h:

typedef struct list_t list_t;
typedef struct list_iter_t list_iter_t;
list_iter_t iterator(list_t *list);

and then define them in list.c:

typedef struct node_t {
    ...
} node_t;

struct list_iter_t {
    node_t *current;
    // this contains info on whether the iterator has reached the end, etc.
    char danger;
};

struct list_t {
    ...
}

list_iter_t iterator(list_t *list) {
    list_iter_t iter;
    ...
    return iter;
}

Is there anything I can do aside from including the struct declaration in the header file so that in some file test.c I can have:

#include "list.h"

void foo(list_t *list) {
    list_iter_t = iterator(list);
    ...
}

Like maybe tell the compiler the storage size of list_iter_t somehow? It's inconvenient to have to use a pointer (not because it's a pointer, but for other reasons), but at the same time I would like to hide the implementation details as much as possible.

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1  
Are you asking if you can declare variable whose type is incomplete? You can't. –  Kerrek SB Sep 2 '11 at 1:53
3  
No there isn't. You can't declare an incomplete type. Also, your typedefs are wrong. They should be typedef struct list_t list_t; typedef struct list_iter_t list_iter_t;. Think about it this way, if what you ask for were possible, there would be no such thing as an opaque type in C. Someone tries to hide the innards of a struct from you by giving you only a header containing a forward declaration and a library that goes along with it, you could simply declare an instance in your code and use it. –  Praetorian Sep 2 '11 at 1:56
    
Okay thanks. (The absence of "struct" in the typedef was a typo.) –  Nick Sep 2 '11 at 2:05

3 Answers 3

up vote 3 down vote accepted

The succinct answer is "No".

The way you tell the compiler the size of a struct is by telling it the details of how the struct is structured. If you want to allocate an object, rather than a pointer to the object, the compiler must know the complete type of the object. You also can't access the members of a structure via a pointer to the structure if the type is incomplete. That is, the compiler must know the offset and type of the member to generate the correct code to access someptr->member (as well as to allocate somevalue or access somevalue.member).

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It is possible to tell the compiler the size of the structure, using a dummy definition like:

struct node_t {
    char dummy[sizeof(struct { ... })];
};

(with the proper definition instead available to the implementation file).

Formally this causes undefined behaviour; it is likely to somewhat work in practice, though.

You are probably best off just including the proper structure definition though, and leaving a comment to the effect that code should simply not touch the internal members.

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How about having the "real" file use a union of the fake type and a real structure? –  supercat Sep 16 '13 at 0:45
    
To clarify: if a header file has union {unsigned long data[50];} FOO; and the .C file has union {unsigned long data[50]; REAL_STRUCTURE dat;} FOO;, would behavior be defined provided that the size and alignment requirements of dat were no bigger than those of data? –  supercat Sep 16 '13 at 15:59
    
@supercat: No, that would be just as undefined - for two unions declared in different translation units to be compatible types there has to be a one-to-one correspondence between members. –  caf Sep 17 '13 at 0:46
    
If the union includes both a type which forces alignment, and an unsigned char[], would a pointer to one union's unsigned char[] be valid as a pointer to the other union [I think it would have to be valid as a pointer to the other union's unsigned char[], and I think a pointer to that union's unsigned char[] would be valid as a pointer to that union]. –  supercat Sep 17 '13 at 14:45
    
@supercat: No, you can't just cast any pointer to unsigned char to a pointer to a union even if that union contains an unsigned char member. If you're not convinced maybe you should ask this as a new question so it can get some more eyes. –  caf Sep 18 '13 at 1:53

You can forward declare structs in your header file, but within the header file, you must restrict yourself to using pointers or references to those structs. This is because, as other people have pointed out, the compiler doesn't know the size of the struct until it is fully defined.

So you will have to change your header slightly like so:

typedef struct list_struct list_t;              // forward declare list_t as some struct

typedef struct list_iter_struct list_iter_t;    // forward declare list_iter_t

list_iter_t* iterator(list_t* list);            // delcare a function using pointers to opaque types

I find it best to use a different name for the struct (e.g. list_struct) and the typedef (list_t). This helps you to keep the concepts separated in your mind.

As I mentioned earlier: in the header file, you can only have pointers or references to the typedefs.

list_iter_t* iterator (list_t *list);    // pointer to opaque type is OK
list_iter_t* iterator2(list_t &list);    // reference to opaque type is OK too
list_iter_t  iterator3(list_t *list);    // will not compile, list_iter_t is of unknown size

In your implementation file, you fill in the details for your structs. Using your example, I figure it might look something like this:

// this is the node_struct structure, completely hidden to the outside world
struct node_struct {
    int                 age;
    char                name[100];
    struct node_struct *next;
};

// this is the structure of the list_struct which was forward declared in the header file.
struct list_struct {
    node_t  *first;
    node_t  *last;
};

// this is the structure of the list_iter_struct which was forward declared in the header file.
struct list_iter_struct {
    node_t  *first;
    node_t  *current;
    bool     danger;
};

// this is the implementation of the iterator() function which returns a pointer to a list_iter_t
// given a pointer to a list_t.
list_iter_t* iterator(list_t* list)
{
    list_iter_t* iter = (list_iter_t*)malloc(sizeof(list_iter_t));

    iter->first = list->first;
    iter->current = list->first;
    iter->danger = false;

    return iter;
}
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The question wasn't about C++. –  alk Sep 19 at 18:58

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