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.
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 allow 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.
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.
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;
}
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.
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.
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
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.
#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.
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.
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);
...
The C++ Programming Language (3rd Edition) gives three examples:
sizeof('a'), as #Adam Rosenfield mentioned;
// comments being used to create hidden code:
int f(int a, int b)
{
return a //* blah */ b
;
}
Structures etc. hiding stuff in out scopes, as in your example.
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));
}
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.
#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.
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.
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
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.
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;
}
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++.
Related
I am now studying C++ 11 and getting confused by value category of expressions in C++ 11. According to terminology the Lvalue is the top-left point of the W, that is iM (or i-m sometimes) meaning that "has identity but cannot be moved from". This really makes me confused. Please consider the example below:
#include <iostream>
int main()
{
int a = 0, b = 1, c = 2;
a = std::move(b = c);
std::cout << a << '\n';
}
This example compiled well.
We all know that the assignment b = c is an Lvalue then what do they mean by 'cannot be moved from'? Please give examples that can clearly illustrate this!
Thanks!
Roughly speaking:
an lvalue has identity because you can take its address
int x;
&x; // ok
an lvalue cannot be moved from because it cannot be used as an argument to move constructor/assignment
struct Foo
{
Foo(Foo&); // 0
Foo(Foo&&); // 1
};
Foo x;
Foo y{x}; // calls 0, not 1
in the example above, x is an lvalue: the copy constructor is invoked. If you want to move from x, you need to make it an rvalue: this is why you must use std::move(x) to cast it to an rvalue reference.
Foo y{std::move(x)}; // calls 1
In your example std::move(b = c) is an rvalue, as std::move is literally just a static_cast to an rvalue reference.
In frama-C when I load my source file it does pre processing and does automatic error correction like "automatic typecast " as shown below (int is typecasted to float).
Now how can I see all the changes made after preprocessing.
Is there any method or log file or warning message which shows all the changes made by frama-c.!
This is my Source code:
int main() {
int a, b;
printf("Input two integers to divide\n");
scanf("%d%d", &a, &b);
printf("%d/%d = %.2f\n", a, b, a/(float)b);
}
This is my frama-C preprocessed code:
extern int (/* missing proto */ printf)();
extern int (/* missing proto */ scanf)();
int main(void) {
int a;
int b;
int __retres;
printf("Input two integers to divide\n");
scanf("%d%d", &a, &b);
printf("%d/%d = %.2f\n", a, b, (float)a/(float)b);
__retres =0;
return (__retres);
}
Frama-C's API proposes a certain number of hooks that will be triggered for difference cases of normalization. Note that it does not perform "automatic error correction". The transformations that are done do not alter the semantics of the program.
These hooks are located in cil/src/frontc/cabs2cil.mli For instance, you find there:
val typeForInsertedCast:
(Cil_types.exp -> Cil_types.typ -> Cil_types.typ -> Cil_types.typ) ref
typeForInsertedCast e t1 t2 is called when an expression e of type t1 must be implicitely converted to type t2 (in the conditions described by the section 6.3 of the C standard about implicit conversions). By providing your own function here via a plugin, you can track all implicit conversions that happen in your program.
A tutorial on writing Frama-C plugins is available in the user manual (requires OCaml knowledge).
if TStruct is packed, then this code ends with Str.D == 0x00223344 (not 0x11223344). Why? ARM GCC 4.7
#include <string.h>
typedef struct {
unsigned char B;
unsigned int D;
} __attribute__ ((packed)) TStruct;
volatile TStruct Str;
int main( void) {
memset((void *)&Str, 0, sizeof(Str));
Str.D = 0x11223344;
if(Str.D != 0x11223344) {
return 1;
}
return 0;
}
I guess your problem has nothing to do with unaligned access, but with structure definition. int is not necessarily 32 bit long. According to the C standard, int is at least 16 bit long, and char is at least 8 bits long.
My guess is, Your compiler optimizes TStruct so it looks like this:
struct {
unsigned char B : 8;
unsigned int D : 24;
} ...;
When you are assigning 0x11223344 to Str.D, than according to the C standard, the compiler must only make sure that at least 16 bits (0x3344) are written to Str.D. You didn't specify that Str.D is 32 bit long, only that it is at least 16 bits long.
Your compiler may also arrange the struct like this:
struct {
unsigned char B : 16;
unsigned int D : 16;
} ...;
B is at least 8 bits long, and D is at least 16 bits long, all ok.
Probably, what you want to do, is:
#include <stdint.h>
typedef struct {
uint8_t B;
uint32_t D;
} __attribute__((packed)) TStruct;
That way You can ensure a 32-bit value 0x11223344 properly writes to Str.D. It is a good idea to use size constrained types for __packed structs.
As for unaligned access of a member inside a struct, the compiler should take care of it. If a compiler knows the structure definition, then when you are accessing Str.D it should take care of any unaligned access and bit/byte operations.
I realised gcc and g++ handle differently for the following codes:
#include <stdio.h>
int main(void)
{
int a = 0;
int& b = a;
return 0;
}
gcc returns "parse error before &", while no error is returned by g++.
I once encountered an interview mentioned C and C++ compilers handles differently for int& b.
That's because & has no meaning in a C type declaration - in C++, it means the variable will be a reference, but those do not exist in C.
In other words, int& b = a; simply isn't valid C code.
I would like to know, when two integers are multiplied and result is typecast to short and assigned to short, what will the compiler resolves it to? Below is the code snippet
int a=1,b=2,c;
short x=3,y=4,z;
int p;
short q;
int main()
{
c = a*b; /* Mul two ints and assign to int
[compiler resolves this to __mulsi3()] */
z = x*y; /* Mul two short and assign to short
[compiler resolves this to __mulhi3()] */
p = (x*y); /* Mul two short and assign to int
[compiler resolves this to __mulsi3()] */
q =(short)(a*b); /* Mul two ints typecast to short and assign to short
[compiler resolves this to __mulhi3()] */
return 0;
}
Here in the case for q =(short)(a*b);, first two ints multiplication should be performed (using __mulsi3()) and then assign it to short. But it's not the case here, compiler type casts both a and b to short and then calls __mulhi3().
I would like to know how can I change in gcc source code [which file], so that i can achieve my above requirements.
The compiler can analyse the code and see that as you covert the result immediately to a short the mutiplication can be done as short multiplication without affecting the result. This is exactly the same as case two of your example.
As the result is the same you don't need to worry about which multiplication function is used.