26

In a C++ project, including .h files of C source files will cause many errors because of different standards between C and C++.
How to use C source files in a C++ project (or in main.cpp)?

10
  • 6
    Compile the C source with a C compiler; compile the C++ source with a C++ compiler; (preferably, write the main() function in C++); link the program with a C++ compiler. Dec 4 '12 at 1:15
  • 1
    can you elabourate on what you tried and what were the errors?
    – Karthik T
    Dec 4 '12 at 1:15
  • 2
    Incompatibilities are few and far between. You're going to have to "fix" the C files to be C++ compatible if you want to use them in a C++ compiler or you can link the C object files separately. The only problem I've encountered personally is C's implicit conversion from void* to any other pointer type.
    – Ed S.
    Dec 4 '12 at 1:15
  • Actually, it shouldn't give you problems since C++ recognizes standard C. The best practice is to correct the name of your libraries following the pattern: <stdio.h> becomes <cstdio>. But it shouldn't be a problem
    – gibertoni
    Dec 4 '12 at 1:16
  • 1
    @KuramaYoko There are many perfectly legal (even idomatic) constructs in c that will throw a error in a c++ compiler. Even int *i = malloc(sizeof(int) * 10); is illegal in c++. So is any code that uses class as a variable name or uses c99 dynamic arrays or or or... Dec 4 '12 at 1:18
40

For the maximum reliability:

  • Compile the C source with a C compiler.
  • Compile the C++ source with a C++ compiler
  • Preferably, write the main() function in C++.
  • Link the program with a C++ compiler.

Make sure that the C headers are either themselves aware of C++ or that the C++ code includes the C headers inside an extern "C" { ... } block.

Either (C header file cheader.h):

#ifndef CHEADER_H_INCLUDED
#define CHEADER_H_INCLUDED

#ifdef __cplusplus
extern "C" {
#endif

...main contents of header...

#ifdef __cplusplus
}
#endif

#endif /* CHEADER_H_INCLUDED */ 

or (C++ source code):

extern "C" {
#include "cheader.h"
}

Modern C style is very close to the common subset of the C and C++ languages. However, arbitrary C code is not C++ code for any of a very large number of reasons, and simply calling the C source files C++ source files (by changing the extension, or simply by compiling with the C++ compiler) is not guaranteed to be successful. In general, it is easier to compile C as C and C++ as C++ and then link the resulting object files with the C++ compiler (to ensure the correct support libraries are invoked).

However, if the MSVC compiler is saying that programs using MFC have to be written solely in C++ (MFC requires C++ compilation (use a .cpp suffix) is the reported error), then you may have no choice but to ensure that your C code is compilable as C++ code. That means you'll have to cast the return values from malloc() et al; you have to worry about other places where you do not use a cast to convert a void * into some other pointer type; you have to worry about sizeof('a') == 4 in C and sizeof('a') == 1 in C++; you have to ensure that every function is declared before it is used; you have to ensure your C code does not use any C++ keywords (typename, class in particular; also inline sometimes — but the complete list is quite large).

In some circles, you'd have to worry about the use of features in C99 that are not in C++2003 or C++2011, such as flexible array members, designated initializers, compound literals, variable-length arrays, and so on. However, if the C code is for MSVC, then that probably isn't going to be a problem; those features are not supported by the MSVC C compiler (it only supports C89, not C99).

FWIW: I have a script to hunt down C++ keywords. It contains the following comment:

# http://en.cppreference.com/w/cpp/keywords
# plus JL annotations
# and                               C (<iso646.h>)
# and_eq                            C (<iso646.h>)
# alignas (C++11 feature)
# alignof (C++11 feature)
# asm                               C (core)
# auto(1)                           C (core)
# bitand                            C (<iso646.h>)
# bitor                             C (<iso646.h>)
# bool                              C99 (<stdbool.h>)
# break                             C (core)
# case                              C (core)
# catch
# char                              C (core)
# char16_t (C++11 feature)
# char32_t (C++11 feature)
# class
# compl                             C (<iso646.h>)
# const                             C (core)
# constexpr (C++11 feature)
# const_cast
# continue                          C (core)
# decltype (C++11 feature)
# default(1)                        C (core)
# delete(1)
# double                            C (core)
# dynamic_cast
# else                              C (core)
# enum                              C (core)
# explicit
# export
# extern                            C (core)
# false                             C99 (<stdbool.h>)
# float                             C (core)
# for                               C (core)
# friend
# goto                              C (core)
# if                                C (core)
# inline                            C (core)
# int                               C (core)
# long                              C (core)
# mutable
# namespace
# new
# noexcept (C++11 feature)
# not                               C (<iso646.h>)
# not_eq                            C (<iso646.h>)
# nullptr (C++11 feature)
# operator
# or                                C (<iso646.h>)
# or_eq                             C (<iso646.h>)
# private
# protected
# public
# register                          C (core)
# reinterpret_cast
# return                            C (core)
# short                             C (core)
# signed                            C (core)
# sizeof                            C (core)
# static                            C (core)
# static_assert (C++11 feature)
# static_cast
# struct                            C (core)
# switch                            C (core)
# template
# this
# thread_local (C++11 feature)
# throw
# true                              C99 (<stdbool.h>)
# try
# typedef                           C (core)
# typeid
# typename
# union                             C (core)
# unsigned                          C (core)
# using(1)
# virtual
# void                              C (core)
# volatile                          C (core)
# wchar_t                           C (core)
# while                             C (core)
# xor                               C (<iso646.h>)
# xor_eq                            C (<iso646.h>)

The (1) suffixes is a footnote at CPP Reference:

  • (1) — meaning changed in C++11
3
9

Minimal runnable C from C++ example

Calling C from C++ is pretty easy: each C function only has one possible non-mangled symbol, so no extra work is required.

main.cpp

#include <cassert>

#include "c.h"

int main() {
    assert(f() == 1);
}

c.h

#ifndef C_H
#define C_H

/* This ifdef allows the header to be used from both C and C++. */
#ifdef __cplusplus
extern "C" {
#endif
int f();
#ifdef __cplusplus
}
#endif

#endif

c.c

#include "c.h"

int f() { return 1; }

Run:

g++ -c -o main.o -std=c++98 main.cpp
gcc -c -o c.o -std=c89 c.c
g++ -o main.out main.o c.o
./main.out

I have explained extern "C" in more detail at: What is the effect of extern "C" in C++?

Example on GitHub.

Minimal runnable C++ from C example

Calling C++ from is a bit harder: we have to manually create non-mangled versions of each function we want to expose.

Here we illustrate how to expose C++ function overloads to C.

main.c

#include <assert.h>

#include "cpp.h"

int main(void) {
    assert(f_int(1) == 2);
    assert(f_float(1.0) == 3);
    return 0;
}

cpp.h

#ifndef CPP_H
#define CPP_H

#ifdef __cplusplus
// C cannot see these overloaded prototypes, or else it would get confused.
int f(int i);
int f(float i);
extern "C" {
#endif
int f_int(int i);
int f_float(float i);
#ifdef __cplusplus
}
#endif

#endif

cpp.cpp

#include "cpp.h"

int f(int i) {
    return i + 1;
}

int f(float i) {
    return i + 2;
}

int f_int(int i) {
    return f(i);
}

int f_float(float i) {
    return f(i);
}

Run:

gcc -c -o main.o -std=c89 -Wextra main.c
g++ -c -o cpp.o -std=c++98 cpp.cpp
g++ -o main.out main.o cpp.o
./main.out

Example on GitHub.

2

C++ preaches "backwards compatibility" to C source, so an option would be to copy the C source onto a .cpp file and build. Now C++ is not COMPLETELY backwards compatible, so you might need to change some things around in the C source, but generally it should build with minimal errors. Just make sure you include the C library's that the .c uses(considering your compiler supports C also)

#include <stdio.h>
#include <string.h>
//so on
0

if you are just using the source code and not some precompiled libraries, in most of the cases you could just rename the .c file to a .cpp file

3
  • But some global variables defined in .h of c files will cause many errors, and more other errors.
    – Al2O3
    Dec 4 '12 at 1:20
  • that is why I said in most of the cases, but you are right... global variables are not a good practice anyway hehehe
    – Salchi13
    Dec 4 '12 at 1:28
  • Renaming .c files works only if the C code is crap: It requires that the C is actually within the common subset of C and C++, which is not the case for good C code. For instance, there is a very good reason for C programmers to not cast the result of malloc(), C++ forces the cast. C has true multidimensional dynamic arrays, C++ has not. There are some more things that good C code does which is not allowed in C++, these are just two examples out of the top of my head. Aug 18 '18 at 22:16

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

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