639

C and C++ have many differences, and not all valid C code is valid C++ code.
(By "valid" I mean standard code with defined behavior, i.e. not implementation-specific/undefined/etc.)

Is there any scenario in which a piece of code valid in both C and C++ would produce different behavior when compiled with a standard compiler in each language?

To make it a reasonable/useful comparison (I'm trying to learn something practically useful, not to try to find obvious loopholes in the question), let's assume:

  • Nothing preprocessor-related (which means no hacks with #ifdef __cplusplus, pragmas, etc.)
  • Anything implementation-defined is the same in both languages (e.g. numeric limits, etc.)
  • We're comparing reasonably recent versions of each standard (e.g. say, C++98 and C90 or later)
    If the versions matter, then please mention which versions of each produce different behavior.
  • 10
    By the way, it can be useful to program in a dialect which is C and C++ at the same time. I've done this in the past and one one current project: the TXR language. Interestingly, the developers of the Lua language did the same thing, and they call this dialect "Clean C". You get the benefit of better compile time checking and possibly additional useful diagnostics from C++ compilers, yet retain the C portability. – Kaz Oct 15 '12 at 7:59
  • 9
    I merged the older question into this question since this has more views and upvoted answers. This is still an example of a non-constructive question, but it's quite borderline since yes, it does teach SO users something. I'm closing it as not constructive only to reflect the state of the question before the merge. Feel free to disagree and re-open. – George Stocker Oct 16 '12 at 0:37
  • 11
    Voting to reopen as I think it can be objectively answered with a "yes" followed by an example (as proved below). I think it is constructive in that people can learn relevant behaviour from it. – Anders Abel Oct 16 '12 at 15:39
  • 6
    @AndersAbel The pure number of answers, all of which are correct, demonstrates unambiguously that it remains a make-a-list question. There was no way you could have asked this question without getting a list. – dmckee Oct 16 '12 at 22:19
  • 2
    @dmckee For what it's worth, I agree with you. However, the C++ tag people are... Shall we say... feisty. – George Stocker Oct 17 '12 at 1:19

19 Answers 19

378

The following, valid in C and C++, is going to (most likely) result in different values in i in C and C++:

int i = sizeof('a');

See Size of character ('a') in C/C++ for an explanation of the difference.

Another one from this article:

#include <stdio.h>

int  sz = 80;

int main(void)
{
    struct sz { char c; };

    int val = sizeof(sz);      // sizeof(int) in C,
                               // sizeof(struct sz) in C++
    printf("%d\n", val);
    return 0;
}
  • 7
    Definitely wasn't expecting this one! I was hoping for something a little more dramatic but this is still useful, thanks. :) +1 – Mehrdad Oct 14 '12 at 23:58
  • 15
    +1 the second example is a good one for the fact that C++ doesn't require struct before struct names. – Seth Carnegie Oct 15 '12 at 0:31
  • 1
    @Andrey I thought the same a while ago and tested it and it worked on GCC 4.7.1 without the std, contrary to my expectation. Is that a bug in GCC? – Seth Carnegie Oct 16 '12 at 19:35
  • 3
    @SethCarnegie: A non-conforming program need not fail to work, but it is not guaranteed to work either. – Andrey Vihrov Oct 16 '12 at 21:35
  • 3
    struct sz { int i[2];}; would mean that C and C++ have to produce different values. (Whereas a DSP with sizeof(int) == 1, could produce the same value). – Martin Bonner Jan 9 '17 at 13:52
458

Here is an example that takes advantage of the difference between function calls and object declarations in C and C++, as well as the fact that C90 allows the calling of undeclared functions:

#include <stdio.h>

struct f { int x; };

int main() {
    f();
}

int f() {
    return printf("hello");
}

In C++ this will print nothing because a temporary f is created and destroyed, but in C90 it will print hello because functions can be called without having been declared.

In case you were wondering about the name f being used twice, the C and C++ standards explicitly allows this, and to make an object you have to say struct f to disambiguate if you want the structure, or leave off struct if you want the function.

  • 5
    Strictly speaking under C this will not compile, because the declaration of "int f()" is after the definition of "int main()" :) – Sogartar Oct 15 '12 at 11:11
  • 14
    @Sogartar, really? codepad.org/STSQlUhh C99 compilers will give you a warning, but they'll still let you compile it. – jrajav Oct 15 '12 at 11:29
  • 21
    @Sogartar in C functions are allowed to be implicitly declared. – Alex B Oct 15 '12 at 11:48
  • 8
    @AlexB Not in C99 and C11. – user529758 Jan 19 '14 at 22:25
  • 3
    @jrajav Those are not C99 compilers, then. A C99 compiler detects undeclared identifiers as a syntax error. A compiler that doesn't do that is either a C89 compiler, or a pre-standard or another kind of non-conformant compiler. – user529758 Jan 19 '14 at 22:26
417

For C++ vs. C90, there's at least one way to get different behavior that's not implementation defined. C90 doesn't have single-line comments. With a little care, we can use that to create an expression with entirely different results in C90 and in C++.

int a = 10 //* comment */ 2 
        + 3;

In C++, everything from the // to the end of the line is a comment, so this works out as:

int a = 10 + 3;

Since C90 doesn't have single-line comments, only the /* comment */ is a comment. The first / and the 2 are both parts of the initialization, so it comes out to:

int a = 10 / 2 + 3;

So, a correct C++ compiler will give 13, but a strictly correct C90 compiler 8. Of course, I just picked arbitrary numbers here -- you can use other numbers as you see fit.

  • 31
    WHOA this is mind-blowing!! Of all possible things I would never have thought comments could be used to change behavior haha. +1 – Mehrdad Oct 15 '12 at 6:06
  • 85
    even without the 2, it would read as 10 / + 3 which is valid (unary +). – Benoit Oct 15 '12 at 7:44
  • 12
    Now for fun, modify it so that C and C++ both calculate different arithmetic expressions the evaluate to the same result. – Ryan Thompson Oct 15 '12 at 9:59
  • 21
    @RyanThompson Trivial. s/2/1/ – sehe Oct 15 '12 at 11:53
  • 3
    @Mehrdad Am I wrong or comments are preprocessor-related? They should thus be excluded as a possible answer from your question! ;-) – Ale Oct 7 '14 at 23:08
169

C90 vs. C++11 (int vs. double):

#include <stdio.h>

int main()
{
  auto j = 1.5;
  printf("%d", (int)sizeof(j));
  return 0;
}

In C auto means local variable. In C90 it's ok to omit variable or function type. It defaults to int. In C++11 auto means something completely different, it tells the compiler to infer the type of the variable from the value used to initialize it.

  • 9
    C90 has auto? – Seth Carnegie Oct 15 '12 at 1:45
  • 6
    Yes: tigcc.ticalc.org/doc/keywords.html#auto – detunized Oct 15 '12 at 1:47
  • 19
    @SethCarnegie: Yeah, it's a storage class; it's what happens by default when you omit it, so no one used it, and they changed its meaning. I think it's int by default. This is clever! +1 – Mehrdad Oct 15 '12 at 1:48
  • 22
    @KeithThompson Ah, I guess you mean the inferred int. Still, in the real world, where there is tons of legacy code and the market leader still hasn't implemented C99 and has no intent to do so, talk of "an obsolete version of C" is absurd. – Jim Balter Oct 15 '12 at 2:42
  • 7
    "Every variable MUST have an explicit storage class. Yours truly, upper management." – btown Oct 15 '12 at 15:28
114

Another example that I haven't seen mentioned yet, this one highlighting a preprocessor difference:

#include <stdio.h>
int main()
{
#if true
    printf("true!\n");
#else
    printf("false!\n");
#endif
    return 0;
}

This prints "false" in C and "true" in C++ - In C, any undefined macro evaluates to 0. In C++, there's 1 exception: "true" evaluates to 1.

  • 2
    Interesting. Does anyone know the rationale behind this change? – antred Sep 2 '14 at 11:50
  • 2
    because "true" is a key word/valid value, so it is evaluated to true like any "true value" (so like any positive integer). You can still do #define true false to print "false" in C++ too ;) – GameDeveloper Nov 30 '14 at 10:45
  • 19
    #define true false ಠ_ಠ – Bryan Boettcher Dec 1 '14 at 21:25
  • 2
    @DarioOO won't such redefinition result in UB? – Ruslan May 7 '15 at 11:51
  • 3
    @DarioOO: Yes, you are wrong. Re-definition of keywords is not allowed, punishment left to fate (UB). The preprocessor being a separate phase of compilation not withstanding. – Deduplicator Jun 20 '15 at 12:45
102

Per C++11 standard:

a. The comma operator performs lvalue-to-rvalue conversion in C but not C++:

   char arr[100];
   int s = sizeof(0, arr);       // The comma operator is used.

In C++ the value of this expression will be 100 and in C this will be sizeof(char*).

b. In C++ the type of enumerator is its enum. In C the type of enumerator is int.

   enum E { a, b, c };
   sizeof(a) == sizeof(int);     // In C
   sizeof(a) == sizeof(E);       // In C++

This means that sizeof(int) may not be equal to sizeof(E).

c. In C++ a function declared with empty params list takes no arguments. In C empty params list mean that the number and type of function params is unknown.

   int f();           // int f(void) in C++
                      // int f(*unknown*) in C
  • The first one is also implementation-defined like Alexey's. But +1. – Seth Carnegie Oct 15 '12 at 1:00
  • 1
    @Seth, All material above is taken directly from Annex C.1 of the C++11 standard. – Kirill Kobelev Oct 15 '12 at 1:13
  • Yes but it is still implementation-defined. sizeof(char*) could be 100 in which case the first example would produce the same observable behaviour in C and C++ (i.e. though the method of obtaining s would be different, s would end up being 100). The OP mentioned that this type of implementation-defined behaviour was fine as he was just wanting to avoid language-lawyer answers, so the first one is fine by his exception. But the second one is good in any case. – Seth Carnegie Oct 15 '12 at 1:31
  • 3
    There is an easy fix -- just change the example to: char arr[sizeof(char*)+1]; int s = sizeof(0, arr); – Mankarse Oct 15 '12 at 11:49
  • 3
    To avoid implementation-defined differences, you could also use void *arr[100]. In this case an element is the same size as a pointer to the same element, so as long as there are 2 or more elements, the array must be larger than the address of its first element. – finnw Oct 15 '12 at 12:48
51

This program prints 1 in C++ and 0 in C:

#include <stdio.h>
#include <stdlib.h>

int main(void)
{
    int d = (int)(abs(0.6) + 0.5);
    printf("%d", d);
    return 0;
}

This happens because there is double abs(double) overload in C++, so abs(0.6) returns 0.6 while in C it returns 0 because of implicit double-to-int conversion before invoking int abs(int). In C, you have to use fabs to work with double.

  • 5
    had to debug code of someone else with that issue. Oh How I loved that. Anyway your program is printing 0 in C++ too. C++ have to use the header "cmath" see comparison first one returnin 0 ideone.com/0tQB2G 2nd one returning 1 ideone.com/SLeANo – GameDeveloper Nov 30 '14 at 11:00
  • Glad/sorry to hear that I'm not the only who find this difference via debugging. Just tested in VS2013, an empty with only file with this content will output 1 if extension is .cpp, and 0 if extension is .c. Looks like <math.h> is included indirectly in VS. – Pavel Chikulaev Dec 2 '14 at 3:05
  • And looks like in VS C++, <math.h> includes C++ stuff into global namespace, where as for GCC it is not. Unsure which is standard behavior however. – Pavel Chikulaev Dec 2 '14 at 3:21
  • no it is not, but lot of users would not be able to compile code written for visual studio if they don't add missing includes;) and even worse, there's the chance users won't get compile errors but strange numerical behaviour due to that non standard behaviour (which could be disabled from options but is enabled by default) – GameDeveloper Dec 2 '14 at 13:43
  • 1
    A secondary issue is that although the C++ standard does appear to say that including <math.h> also includes the additional overloads; in practice it turns out that all the major compilers don't include those overloads unless the form <cmath> is used. – M.M May 9 '16 at 4:25
37

Another sizeof trap: boolean expressions.

#include <stdio.h>
int main() {
    printf("%d\n", (int)sizeof !0);
}

It equals to sizeof(int) in C, because the expression is of type int, but is typically 1 in C++ (though it's not required to be). In practice they are almost always different.

  • 6
    One ! should be enough for a bool. – Alexey Frunze Oct 15 '12 at 14:15
  • 2
    !! is the int to boolean conversion operator :) – EvilTeach Apr 19 '17 at 16:41
  • 1
    sizeof(0) is 4 in both C and C++ because 0 is an integer rvalue. sizeof(!0) is 4 in C and 1 in C++. Logical NOT operates on operands of type bool. If the int value is 0 it is implicitly converted to false (a bool rvalue), then it is flipped, resulting in true. Both true and false are bool rvalues in C++ and the sizeof(bool) is 1. However in C !0 evaluates to 1, which is an rvalue of type int. C programming language has no bool data type by default. – Galaxy Jun 21 '18 at 22:24
36
#include <stdio.h>

int main(void)
{
    printf("%d\n", (int)sizeof('a'));
    return 0;
}

In C, this prints whatever the value of sizeof(int) is on the current system, which is typically 4 in most systems commonly in use today.

In C++, this must print 1.

  • 3
    Yes, I was actually familiar with this trick, being that 'c' is an int in C, and a char in C++, but it's still good to have it listed here. – Sean Feb 23 '09 at 23:29
  • 8
    That would make an interesting interview question - especially for people that put c/c++ expert on their CVs – Martin Beckett Feb 23 '09 at 23:32
  • 2
    Kind of underhanded though. The whole purpose of sizeof is so you don't need to know exactly how large a type is. – Dana the Sane Feb 23 '09 at 23:37
  • 13
    In C the value is implementation defined and 1 is a possibility. (In C++ it has to print 1 as stated.) – Windows programmer Feb 24 '09 at 0:06
  • 2
    Actually it has undefined behavior in both cases. %d is not the right format specifier for size_t. – R.. Feb 27 '14 at 20:49
25

The C++ Programming Language (3rd Edition) gives three examples:

  1. sizeof('a'), as @Adam Rosenfield mentioned;

  2. // comments being used to create hidden code:

    int f(int a, int b)
    {
        return a //* blah */ b
            ;
    }
    
  3. Structures etc. hiding stuff in out scopes, as in your example.

24

An old chestnut that depends on the C compiler, not recognizing C++ end-of-line comments...

...
int a = 4 //* */ 2
        +2;
printf("%i\n",a);
...
  • 5
    So, that's only in C89 compilers, not modern ones... – Jonathan Leffler Feb 24 '09 at 0:20
20

Another one listed by the C++ Standard:

#include <stdio.h>

int x[1];
int main(void) {
    struct x { int a[2]; };
    /* size of the array in C */
    /* size of the struct in C++ */
    printf("%d\n", (int)sizeof(x)); 
}
  • so you get padding differences ? – v.oddou Feb 18 '16 at 7:36
  • ah sorry i got it, there is another x at the top. i thought you said "the array a". – v.oddou Feb 18 '16 at 7:37
20

Inline functions in C default to external scope where as those in C++ do not.

Compiling the following two files together would print the "I am inline" in case of GNU C but nothing for C++.

File 1

#include <stdio.h>

struct fun{};

int main()
{
    fun();  // In C, this calls the inline function from file 2 where as in C++
            // this would create a variable of struct fun
    return 0;
}

File 2

#include <stdio.h>
inline void fun(void)
{
    printf("I am inline\n");
} 

Also, C++ implicitly treats any const global as static unless it is explicitly declared extern, unlike C in which extern is the default.

  • I really don't think so. Probably you have missed the point. It's not about definition of struct st which is merely used to make the code valid c++. The point is that it highlights different behavior of inline functions in c vs c++. Same applies to extern. None of these is discussed in any of the solutions. – fayyazkl Oct 15 '12 at 16:01
  • 2
    What is the different behavior of inline functions and extern that is demonstrated here? – Seth Carnegie Oct 15 '12 at 16:10
  • It is written pretty clearly. "Inline functions in c default to external scope where as those in c++ are not (code shows that). Also C++ implicitly treats any const global as file scope unless it is explicitly declared extern, unlike C in which extern is the default. A similar example can be created for that". I am puzzled - Is it not understandable? – fayyazkl Oct 15 '12 at 16:12
  • 10
    @fayyazkl The behaviour shown is only because of the difference of lookup (struct fun vs fn) and has nothing to do whether the function is inline. The result is identical if you remove inline qualifier. – Alex B Oct 15 '12 at 23:36
  • 3
    In ISO C this program is ill formed: inline was not added until C99, but in C99 fun() may not be called without a prototype in scope. So I assume this answer only applies to GNU C. – M.M May 9 '16 at 4:28
16
struct abort
{
    int x;
};

int main()
{
    abort();
    return 0;
}

Returns with exit code of 0 in C++, or 3 in C.

This trick could probably be used to do something more interesting, but I couldn't think of a good way of creating a constructor that would be palatable to C. I tried making a similarly boring example with the copy constructor, that would let an argument be passed, albeit in a rather non-portable fashion:

struct exit
{
    int x;
};

int main()
{
    struct exit code;
    code.x=1;

    exit(code);

    return 0;
}

VC++ 2005 refused to compile that in C++ mode, though, complaining about how "exit code" was redefined. (I think this is a compiler bug, unless I've suddenly forgotten how to program.) It exited with a process exit code of 1 when compiled as C though.

  • Your second example using exit, doesn't compile on gcc or g++, unfortunately. It's a good idea, though. – Sean Feb 24 '09 at 2:55
  • 1
    exit(code) is a valid declaration of a variable code of type exit, apparently. (See "most vexing parse", which is a different but similar issue). – immibis Mar 25 '15 at 8:57
15
#include <stdio.h>

struct A {
    double a[32];
};

int main() {
    struct B {
        struct A {
            short a, b;
        } a;
    };
    printf("%d\n", sizeof(struct A));
    return 0;
}

This program prints 128 (32 * sizeof(double)) when compiled using a C++ compiler and 4 when compiled using a C compiler.

This is because C does not have the notion of scope resolution. In C structures contained in other structures get put into the scope of the outer structure.

  • This one is interesting! (I think you mean 32*sizeof(double) rather than 32 though :)) – user1354557 Feb 18 '16 at 14:45
  • Oh yes, ofcourse. Fixing it now. :) – wefwefa3 Feb 18 '16 at 16:22
  • 3
    note that you're getting UB by printing size_t with %d – phuclv Aug 8 '18 at 3:31
7

Don't forget the distinction between the C and C++ global namespaces. Suppose you have a foo.cpp

#include <cstdio>

void foo(int r)
{
  printf("I am C++\n");
}

and a foo2.c

#include <stdio.h>

void foo(int r)
{
  printf("I am C\n");
}

Now suppose you have a main.c and main.cpp which both look like this:

extern void foo(int);

int main(void)
{
  foo(1);
  return 0;
}

When compiled as C++, it will use the symbol in the C++ global namespace; in C it will use the C one:

$ diff main.cpp main.c
$ gcc -o test main.cpp foo.cpp foo2.c
$ ./test 
I am C++
$ gcc -o test main.c foo.cpp foo2.c
$ ./test 
I am C
  • You mean the linkage specification? – Mehrdad Oct 17 '14 at 9:31
  • name mangling. C++ names have prefixes and suffixes while C not – GameDeveloper Nov 30 '14 at 10:53
  • Name mangling is not a part of the C++ specification. Is it prohibited in C? – skyking Aug 21 '15 at 7:25
  • 4
    This is undefined behaviour (multiple definition of foo). There are not separate "global namespaces". – M.M May 9 '16 at 3:49
3
int main(void) {
    const int dim = 5; 
    int array[dim];
}

This is rather peculiar in that it is valid in C++ and in C99, C11, and C17 (though optional in C11, C17); but not valid in C89.

In C99+ it creates a variable-length array, which has its own peculiarities over normal arrays, as it has a runtime type instead of compile-time type, and sizeof array is not an integer constant expression in C. In C++ the type is wholly static.


If you try to add an initializer here:

int main(void) {
    const int dim = 5; 
    int array[dim] = {0};
}

is valid C++ but not C, because variable-length arrays cannot have an initializer.

1

This concerns lvalues and rvalues in C and C++.

In the C programming language, both the pre-increment and the post-increment operators return rvalues, not lvalues. This means that they cannot be on the left side of the = assignment operator. Both these statements will give a compiler error in C:

int a = 5;
a++ = 2;  /* error: lvalue required as left operand of assignment */
++a = 2;  /* error: lvalue required as left operand of assignment */

In C++ however, the pre-increment operator returns an lvalue, while the post-increment operator returns an rvalue. It means that an expression with the pre-increment operator can be placed on the left side of the = assignment operator!

int a = 5;
a++ = 2;  // error: lvalue required as left operand of assignment
++a = 2;  // No error: a gets assigned to 2!

Now why is this so? The post-increment increments the variable, and it returns the variable as it was before the increment happened. This is actually just an rvalue. The former value of the variable a is copied into a register as a temporary, and then a is incremented. But the former value of a is returned by the expression, it is an rvalue. It no longer represents the current content of the variable.

The pre-increment first increments the variable, and then it returns the variable as it became after the increment happened. In this case, we do not need to store the old value of the variable into a temporary register. We just retrieve the new value of the variable after it has been incremented. So the pre-increment returns an lvalue, it returns the variable a itself. We can use assign this lvalue to something else, it is like the following statement. This is an implicit conversion of lvalue into rvalue.

int x = a;
int x = ++a;

Since the pre-increment returns an lvalue, we can also assign something to it. The following two statements are identical. In the second assignment, first a is incremented, then its new value is overwritten with 2.

int a;
a = 2;
++a = 2;  // Valid in C++.
  • 2
    There's no "valid in C" here. – o11c Nov 27 '18 at 6:25
0

Empty structures have size 0 in C and 1 in C++:

#include <stdio.h>

typedef struct {} Foo;

int main()
{
    printf("%zd\n", sizeof(Foo));
    return 0;
}
  • 1
    No, the difference is that C does not have empty structures, except as a compiler extension, i.e. this code does not match "is valid in both C and C++" – Antti Haapala Nov 27 '18 at 5:56

protected by Ashwini Chaudhary Oct 27 '12 at 22:55

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