See Also: part 1, part 2, part 3, part 4 and part 5.

This post is a departure from what most of the others are like. I am most certainly not going to be using this “trick” I just learned.

Background

Recently in my day job, I was doing a code review and came across something that was most certainly not legal C code. In fact, I was confident that line wouldn’t even compile without issuing a warning. Yet, the developer said he did not see a warning about it.

The bit of code was supposed to be calling a function that returns a populated structure. Consider this silly example:

#include <stdio.h>

// typedefs
typedef struct {
    unsigned int major;
    unsigned int minor;
    unsigned int patch;
} VersionStruct;

// prototypes
VersionStruct GetVersion (void);

// main
int main()
{
    VersionStruct foo;
    
    foo = GetVersion ();
    
    printf ("Version %u.%u.%u\n", foo.major, foo.minor, foo.patch);

    return 0;
}

// functions
VersionStruct GetVersion ()
{
    VersionStruct ver;
    
    ver.major = 1;
    ver.minor = 0;
    ver.patch = 42;
    
    return ver;
}

But in the code, the call to the function was incomplete. There was no return variable, and even had “void” inside the parens. It looked something like this:

int main()
{
    VersionStruct GetVersion (void);

    return 0;
}

I took one look at that and said “no way that’s working.” But there had been no compiler warning.

So off I went to the Online GDB Compiler to type up a quick example.

And it built without warning.

Well, maybe the default is to ignore this warning… So I added “-Wall” and “-Wextra” to the build flags. That should catch it :)

And it built without warning.

“How can this work? It looks like a prototype in the middle of a function!” I asked.

Yes, Virginia. You can have inline prototypes.

A brief bit of searching told me that, yes, inline prototypes were a thing.

This should give a compiler warning:

#include <stdio.h>

int main()
{
    function ();

    return 0;
}

void function (void)
{
    printf ("Inside function.\n");
}

When I built that, I received two compiler warnings:

main.c: At top level:
main.c:10:6: warning: conflicting types for ‘function’; have ‘void(void)’
   10 | void function (void)
      |      ^~~~~~~~
main.c:5:5: note: previous implicit declaration of ‘function’ with type ‘void(void)’
    5 |     function ();
      |     ^~~~~~~~

The first warning is not about the missing prototype, but about “conflicting types”. In C, a function without a prototype is assumed to be a function that returns an int.

Had I made function like this…

int function (void)
{
    printf ("Inside function.\n");
    return 0;
}

…I’d see only one, but different, warning:

main.c: In function ‘main’:
main.c:5:5: warning: implicit declaration of function ‘function’ [-Wimplicit-function-declaration]
    5 |     function ();
      |     ^~~~~~~~

For the first example, the compiler makes an assumption about what this function should be, then finds code using it the wrong way. It warns me that I am not using it like the implied prototype says it should be used. Sorta.

For the next, my function matches the implied prototype, so those warnings go away, but a real “implicit declaration” warning is given.

Going back to the original “void” code, I can add an inline prototype in main() to make these all go away:

#include <stdio.h>

int main()
{
    void function(void); // Inline prototype?
    
    function ();

    return 0;
}

void function (void)
{
    printf ("Inside function.\n");
}

I had no idea that was allowed.

I have no idea why one would do that. BUT, I suppose if you wanted to get to one function without an include file with a prototype for it, you could just stick that right before you call the function…

But Why would you want to do that?

I learned this is possible. I do not think I want to ever do this. Am I missing some great benefit for being able to have a prototype inside a function like this? Is there some “clean code” recommendation that might actually say this is useful?

“It wouldn’t be in there if it didn’t have a reason.”

Let me know what you know in the comments. Until next time…

In the previous installment, I rambled on about the difference of “char *line;” and “char line[];”. The first is a “pointer to char(s)” and the second is “an array of char(s)”. But, when you pass them into a function, they both are treated as a pointer to those chars.

One “benefit” of using “line[]” was that you could use sizeof(line) on it and get the byte count of the array. This is faster than using strlen().

But if you pass it into a function, all you have is a pointer so strlen() is what you have to use.

While you can’t pass an “array of char” into a function as an array of char, you can pass a structure that contains an “array of char” and sizeof() will work on that:

#include <stdio.h>
#include <stdlib.h> // for EXIT_SUCCESS
#include <string.h>
typedef struct
{
    char buffer[80];
} MyStruct;
void function (MyStruct test)
{
    printf ("sizeof(test.buffer) = %zu\n", sizeof(test.buffer));
}
int main(void)
{
    MyStruct test;
    
    strncpy (test.buffer, "This is a test", sizeof(test.buffer));
    
    function (test);
    return EXIT_SUCCESS;
}

You may notice that was passing a copy of the structure in, but stay with me for a moment.

If you have a function that is supposed to copy data into a buffer:

#define VERSION_STRING "1.0.42b-alpha"
void GetVersion (char *buffer)
{
    if (NULL != buffer)
    {
        strcpy (buffer, VERSION_STRING);
    }
}

…you can easily have a buffer overrun problem if the function writes more data than is available in the caller’s buffer. Because of this potential problem, I add a size parameter to such functions:

void GetVersion (char *buffer, size_t bufferSize)
{
    if (NULL != buffer)
    {
        // Copy up to bufferSize bytes.
        strncpy (buffer, VERSION_STRING, bufferSize);
    }
}

As long as the caller passes the correct parameters, this is safe:

char buffer[20];
GetVersion (buffer, 20);

But the caller could still screw up:

char buffer[20];
GetVersion (buffer, 200); // oops, one too many zeros

But if you use a structure, it is impossible for the caller to mess it up (though, of course, they could mess up the structure on their side before calling your function). The compiler type checking will flag if the wrong data type is passed in. The “buffer” will always be the “buffer.” No chance of a “bad pointer” or “buffer overrun” crashing the program.

To allow the buffer inside the structure to be modified, pass it in by reference:

#include <stdio.h>
#include <stdlib.h> // for EXIT_SUCCESS
#include <string.h>
#define VERSION_STRING "1.0.42b-alpha"
typedef struct
{
    char buffer[80];
} MyStruct;
void GetVersion (MyStruct *test)
{
    strncpy (test->buffer, VERSION_STRING, sizeof(test->buffer));
}
int main(void)
{
    MyStruct test;
    
    GetVersion (&test);
    
    printf ("Version: %s\n", test.buffer);
    return EXIT_SUCCESS;
}

Using this approach, you can safely pass a “buffer” into functions and they can get the sizeof() the buffer to ensure they do not overwrite anything.

But wait, there’s more…

It is pretty easy for a function to get out of control if you are trying to get back more than one thing. If you just want an “int”, that’s easy…

int GetCounter ()
{
    static int s_count = 0;
    return s_count++;
}

But if you wanted to get the major, minor, patch and build version, you end up passing in ints by reference to get something like this:

void GetVersion (int *major, int *minor, int *patch, int *build)
{
   if (NULL != major)
   {
      *major = MAJOR_VERSION;
   }
   if (NULL != minor)
   {
      *major = MINOR_VERSION;
   }
   if (NULL != patch)
   {
      *major = PATCH_VERSION;
   }
   if (NULL != build)
   {
      *major = BUILD_VERSION;
   }
}

Of course, anytime pointers are involved, the caller could pass in the wrong pointer and things could get screwed up. Plus, look at all those NULL checks to make sure the pointer isn’t 0. (This does not help if the pointer is pointing to some random location in memory.)

#include <stdio.h>
#include <stdlib.h> // for EXIT_SUCCESS
#define MAJOR_VERSION 1
#define MINOR_VERSION 0
#define PATCH_VERSION 0
#define BUILD_VERSION 42
typedef struct
{
    int major;
    int minor;
    int patch;
    int build;
} VersionStruct;
VersionStruct GetVersion ()
{
    VersionStruct ver;
    
    ver.major = MAJOR_VERSION;
    ver.minor = MINOR_VERSION;
    ver.patch = PATCH_VERSION;
    ver.build = BUILD_VERSION;
    
    return ver;
}
int main(void)
{
    VersionStruct ver;
    
    ver = GetVersion ();
    
    printf ("Version: %u.%u.%u.%u\n",
        ver.major, ver.minor, ver.patch, ver.build);
    return EXIT_SUCCESS;
}

If you are concerned about overhead of passing structures, you can pass them by reference (pointer) and the compiler should still catch if a wrong pointer type is passed in:

#include <stdio.h>
#include <stdlib.h> // for EXIT_SUCCESS
#define MAJOR_VERSION 1
#define MINOR_VERSION 0
#define PATCH_VERSION 0
#define BUILD_VERSION 42
typedef struct
{
    int major;
    int minor;
    int patch;
    int build;
} VersionStruct;
void GetVersion (VersionStruct *ver)
{
    if (NULL != ver)
    {
        ver->major = MAJOR_VERSION;
        ver->minor = MINOR_VERSION;
        ver->patch = PATCH_VERSION;
        ver->build = BUILD_VERSION;
    }
}
int main(void)
{
    VersionStruct ver;
    
    GetVersion (&ver);
    
    printf ("Version: %u.%u.%u.%u\n",
        ver.major, ver.minor, ver.patch, ver.build);
    return EXIT_SUCCESS;
}

However, when dealing with pointers, there is always some risk. While the compiler will catch passing in the wrong structure pointer, there are still ways the caller can screw it up. For instance, void pointers:

int main(void)
{
    void *nothing = (void*)0x1234;
    
    GetVersion (nothing);
    return EXIT_SUCCESS;
}

Yep. Crash.

...Program finished with exit code 139
Press ENTER to exit console.

Give someone access to a function in your DLL and they might find a way to crash the program as simply as using a void pointer.

It is a bit trickier when you pass the full structure:

typedef struct
{
    int x;
} BogusStruct;
int main(void)
{
    BogusStruct ver;
    
    ver = GetVersion ();
    
    return EXIT_SUCCESS;
}

Compiler don’t like:

main.c: In function ‘main’:
main.c:38:11: error: incompatible types when assigning to type ‘BogusStruct’ from type ‘VersionStruct’
   38 |     ver = GetVersion ();
      |           ^~~~~~~~~~
main.c:36:17: warning: variable ‘ver’ set but not used [-Wunused-but-set-variable]
   36 |     BogusStruct ver;
      |                 ^~~

And you can’t really cast a return value like this:

int main(void)
{
    BogusStruct ver;
    
    (VersionStruct)ver = GetVersion ();
    
    return EXIT_SUCCESS;
}

Compiler don’t like:

main.c: In function ‘main’:
main.c:38:5: error: conversion to non-scalar type requested
   38 |     (VersionStruct)ver = GetVersion ();
      |     ^

Though maybe you could cast it if it was passed in as a parameter:

void ShowVersion (VersionStruct ver)
{
    printf ("Version: %u.%u.%u.%u\n",
    ver.major, ver.minor, ver.patch, ver.build);
}
int main(void)
{
    BogusStruct ver;
    
    ShowVersion ((VersionStruct)ver);
    
    return EXIT_SUCCESS;
}

Compiler still don’t like:

main.c: In function ‘main’:
main.c:44:5: error: conversion to non-scalar type requested
   44 |     ShowVersion ((VersionStruct)ver);
      |     ^~~~~~~~~~~

Hmm. Is there a way to screw this up? Let me know in the comments.

Until then…