Announcing Stack Overflow Documentation

We started with Q&A. Technical documentation is next, and we need your help.

Whether you're a beginner or an experienced developer, you can contribute.

Sign up and start helping → Learn more about Documentation →

Is there a way to write OO-like code in the C programming language?

See also:

Found by searching on "[c] oo".

share|improve this question
thanks for the hint with the square brackets. Didn't know that. – prinzdezibel Feb 7 '09 at 17:58
Yeah, that needs to be made more discoverable or something. I've been trying to frame a good suggestion for uservoice, but its not coming together. – dmckee Feb 7 '09 at 18:01
up vote 30 down vote accepted

The first C++ compiler ("C with classes") would actually generate C code, so that's definitely doable.

Basically, your base class is a struct; derived structs must include the base struct at the first position, so that a pointer to the "derived" struct will also be a valid pointer to the base struct.

typedef struct {
   data member_x;
} base;

typedef struct {
   struct base;
   data member_y;
} derived;

void function_on_base(struct base * a); // here I can pass both pointers to derived and to base

void function_on_derived(struct derived * b); // here I must pass a pointer to the derived class

The functions can be part of the structure as function pointers, so that a syntax like p->call(p) becomes possible, but you still have to explicitly pass a pointer to the struct to the function itself.

share|improve this answer
This doesn't explain how method overriding would work in C. How can you override function_on_base to access derived's memeber_y as you can in C++ polymorphic calls? – John K Oct 30 '12 at 15:50
Overriding is not possible in C. – Patrick Collins Jan 8 '14 at 15:40
This answer is incorrect. Passing a struct derived* to function_on_base will not compile; struct derived* is a different type than struct base* even if the address is correct; however, if you cast the pointer from derived* to base*, it will work (but you'll miss out on compile-time type checking and instead get a crash at runtime). @PatrickCollins Overriding is possible in C: pastebin.com/W5xEytbv – weberc2 Jul 3 '14 at 18:36
@JohnK See above comment. – weberc2 Jul 3 '14 at 18:48
@weberc2 Right you are, I'm not really sure what I was thinking when I wrote that. I might have had "overloading" in mind, which your paste also suggests. – Patrick Collins Jul 4 '14 at 4:03

Common approach is to define struct with pointers to functions. This defines 'methods' which can be called on any type. Subtypes then set their own functions in this common structure, and return it.

For example, in linux kernel, there is struct:

struct inode_operations {
    int (*create) (struct inode *,struct dentry *,int, struct nameidata *);
    struct dentry * (*lookup) (struct inode *,struct dentry *, 
                               struct nameidata *);

Each registered type of filesystem then registers its own functions for create, lookup, and remaining functions. Rest of code can than use generic inode_operations:

struct inode_operations   *i_op;
i_op -> create(...);
share|improve this answer
That's basically how cfront (the original C++ compiler) converted C++ to C that was then compiled with pcc. I learned a lot about how this worked dealing with core files from that mess. – Paul Tomblin Feb 7 '09 at 16:30
Sounds like fun :-) – Peter Štibraný Feb 7 '09 at 18:31

C++ is not that far from C.

Classes are structures with a hidden pointer to a table of function pointers called VTable. The Vtable itself is static. When types point to Vtables with the same structure but where pointers point to other implementation, you get polymorphism.

It is recommended to encapsulate the calls logic in function that take the struct as parameter to avoid code clutter.

You should also encapsulcte structures instantiation and initialisation in functions (this is equivalent to a C++ constructor) and deletion (destructor in C++). These are good practice anyway.

typedef struct
   int (*SomeFunction)(TheClass* this, int i);
   void (*OtherFunction)(TheClass* this, char* c);
} VTable;

typedef struct
   VTable* pVTable;
   int member;

} TheClass;

To call the method:

int CallSomeFunction(TheClass* this, int i)
  (this->SomeFunction)(this, i);
share|improve this answer

I looked at everyone elses' answers and came up with this:

#include <stdio.h>

typedef struct
    int (*get)(void* this);
    void (*set)(void* this, int i);
    int member;

} TheClass;

int Get(void* this)
    TheClass* This = (TheClass*)this;
    return This->member;

void Set(void* this, int i)
    TheClass* This = (TheClass*)this;
    This->member = i;

void init(TheClass* this)
    this->get = &Get;
    this->set = &Set;

int main(int argc, char **argv)
    TheClass name;
    (name.set)(&name, 10);
    printf("%d\n", (name.get)(&name));
    return 0;

I hope that answers some questions.

share|improve this answer
Good example. Would be even better if you had 2 "derived" classes with different init / get / set. "private" members / functions can be done with opaque structs. Naming convention is also important: mylib_someClass_aMethod(this) is a good possibility. – Ciro Santilli 巴拿馬文件 六四事件 法轮功 Apr 29 at 10:33

Appendix B of the article Open Reusable Object Models, by Ian Piumarta and Alessandro Warth of VPRI is an implementation of an Object model in GNU C, about 140 lines of code. It's a fascinating read !

Here's the uncached version of the macro that sends messages to objects, using a GNU extension to C (statement expression):

struct object;

typedef struct object *oop; 
typedef oop *(*method_t)(oop receiver, ...);


#define send(RCV, MSG, ARGS...) ({ \ 
    oop r = (oop)(RCV); \ 
    method_t method = _bind(r, (MSG)); \ 
    method(r, ##ARGS); \ 

In the same doc, have a look at the object, vtable, vtable_delegated and symbol structs, and the _bind and vtable_lookup functions.


share|improve this answer

The file functions fopen, fclose, fread are examples of OO code in C. Instead of the private data in class, they work on the FILE structure which is used to encapsulate the data and the C functions acts as an member class functions. http://www.amazon.com/File-Structures-Object-Oriented-Approach-C/dp/0201874016

share|improve this answer
The title reads now: An Object-Oriented Approach with C++ – prinzdezibel Feb 7 '09 at 16:48
The book pointed to is C++ only. Note: I have a copy and would not recommend it today. If I had one OO recommendation in C to give today it would be C Interfaces and Implementations: Techniques for Creating Reusable Software by David Hanson (amzn.com/0201498413). Absolutely brilliant book and most programmers would do well to understand it, most examples in it are taken from compiler backends so the code is exemplary. – Harry Aug 26 '14 at 17:38

From Wikipedia: In programming languages and type theory, polymorphism (from Greek πολύς, polys, "many, much" and μορφή, morphē, "form, shape") is the provision of a single interface to entities of different types.

So I would say the only way to implement it in C is by using variadic arguments along with some (semi)automatic type info management. For example in C++ you can write (sorry for trivialness):

void add( int& result, int a1, int a2 );
void add( float& result, float a1, float a2 );
void add( double& result, double a1, double a2 );

In C, among other solutions, the best you can do is something like this:

int int_add( int a1, int a2 );
float float_add( float a1, fload a2 );
double double_add( double a1, double a2 );

void add( int typeinfo, void* result, ... );

Then you need:

  1. to implement the "typeinfo" with enums/macros
  2. to implement the latter function with stdarg.h stuff
  3. to say goodbye to C static type checking

I am almost sure that any other implementation of polymorphism should look much like this very one. The above answers, instead, seems to try to address inheritance more than polymorphism!

share|improve this answer
#include <stdio.h>

typedef struct {
    int  x;
    int z;
} base;

typedef struct {
    int y;
    int x;
} derived;

void function_on_base( base * a) // here I can pass both pointers to derived and to base
    printf("Class base [%d]\n",a->x);
    printf("Class base [%d]\n",a->z);
void function_on_derived( derived * b) // here I must pass a pointer to the derived class
    printf("Class derived [%d]\n",b->y);
    printf("Class derived [%d]\n",b->x);

int main()
    derived d;
    base b;
    printf("Teste de poliformismo\n");

    b.x = 2;
    d.y = 1;
    b.z = 3;
    d.x = 4;
    return 0;

The output was:

Class base [3]
Class base [1]
Class base [4]
Class derived [2]
Class derived [3]
Class derived [1]
Class derived [4]

so it works, its a polymorphic code.

UncleZeiv explained about it at the beginning.

share|improve this answer

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.