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How to trigger a warning when a certain function is called (not compiled)?

If we write:
void foo() {
#warning "Danger Will Robinson!"
}
we'll get a warning when compiling foo(). Now, What I want to do is for the compilation not to emit a warning, but for a warning to be emitted if foo() is called.
Is that possible, using g++ and/or clang++?
Note: This question is somewhat similar to this one, about marking functions as "deprecated" (a-la C++14's [[deprecated]] attribute). However, it's a different semantic. I do not want people to get the notion that my function is deprecated, but rather get a custom warning.

C++11 added _Pragma, which is like #pragma but macros can expand to it. So, you can make a macro, that expands to this warning and the function:
#include <cstdio>
void foo() {
std::puts("foo is called!");
}
#define foo(...) _Pragma("message \"Danger Will Robinson!\"") \
foo(__VA_ARGS__)
int main() {
foo();
}
The main issue with this approach is that it will not respect overloads and warn on any function with the name foo.

A suggestion from #StoryTeller in the comments, which works - partially - in GCC:
__attribute__ ((warning ("Danger Will Robinson!")))
void foo() { }
int bar() {
const int x = 123;
foo();
return x;
}
Why "partially"? As #StoryTeller says:
Dead code elimination can remove the warning should the call be on the eliminated branch
Have look at This GodBolt example: When you enable optimizations so that the function is inlined - the warning attribute is ignored.

C++: cleanest practice to write an empty function body [duplicate]

I have a cross platform application and in a few of my functions not all the values passed to functions are utilised. Hence I get a warning from GCC telling me that there are unused variables.
What would be the best way of coding around the warning?
An #ifdef around the function?
#ifdef _MSC_VER
void ProcessOps::sendToExternalApp(QString sAppName, QString sImagePath, qreal qrLeft, qreal qrTop, qreal qrWidth, qreal qrHeight)
#else
void ProcessOps::sendToExternalApp(QString sAppName, QString sImagePath, qreal /*qrLeft*/, qreal /*qrTop*/, qreal /*qrWidth*/, qreal /*qrHeight*/)
#endif
{
This is so ugly but seems like the way the compiler would prefer.
Or do I assign zero to the variable at the end of the function? (which I hate because it's altering something in the program flow to silence a compiler warning).
Is there a correct way?

You can put it in "(void)var;" expression (does nothing) so that a compiler sees it is used. This is portable between compilers.
E.g.
void foo(int param1, int param2)
{
(void)param2;
bar(param1);
}
Or,
#define UNUSED(expr) do { (void)(expr); } while (0)
...
void foo(int param1, int param2)
{
UNUSED(param2);
bar(param1);
}

In GCC and Clang you can use the __attribute__((unused)) preprocessor directive to achieve your goal.
For example:
int foo (__attribute__((unused)) int bar) {
return 0;
}

C++17 now provides the [[maybe_unused]] attribute.
http://en.cppreference.com/w/cpp/language/attributes
Quite nice and standard.

C++17 Update
In C++17 we gain the attribute [[maybe_unused]] which is covered in [dcl.attr.unused]
The attribute-token maybe_unused indicates that a name or entity is possibly intentionally unused. It shall
appear at most once in each attribute-list and no attribute-argument-clause shall be present.
...
Example:
[[maybe_unused]] void f([[maybe_unused]] bool thing1,
[[maybe_unused]] bool thing2) {
[[maybe_unused]] bool b = thing1 && thing2;
assert(b);
}
Implementations should not warn that b is unused, whether or not NDEBUG is defined. —end example ]
For the following example:
int foo ( int bar) {
bool unused_bool ;
return 0;
}
Both clang and gcc generate a diagnostic using -Wall -Wextra for both bar and unused_bool (See it live).
While adding [[maybe_unused]] silences the diagnostics:
int foo ([[maybe_unused]] int bar) {
[[maybe_unused]] bool unused_bool ;
return 0;
}
see it live.
Before C++17
In C++11 an alternative form of the UNUSED macro could be formed using a lambda expression(via Ben Deane) with an capture of the unused variable:
#define UNUSED(x) [&x]{}()
The immediate invocation of the lambda expression should be optimized away, given the following example:
int foo (int bar) {
UNUSED(bar) ;
return 0;
}
we can see in godbolt that the call is optimized away:
foo(int):
xorl %eax, %eax
ret

Your current solution is best - comment out the parameter name if you don't use it. That applies to all compilers, so you don't have to use the pre-processor to do it specially for GCC.

An even cleaner way is to just comment out variable names:
int main(int /* argc */, char const** /* argv */) {
return 0;
}

gcc doesn't flag these warnings by default. This warning must have been turned on either explicitly by passing -Wunused-parameter to the compiler or implicitly by passing -Wall -Wextra (or possibly some other combination of flags).
Unused parameter warnings can simply be suppressed by passing -Wno-unused-parameter to the compiler, but note that this disabling flag must come after any possible enabling flags for this warning in the compiler command line, so that it can take effect.

A coworker just pointed me to this nice little macro here
For ease I'll include the macro below.
#ifdef UNUSED
#elif defined(__GNUC__)
# define UNUSED(x) UNUSED_ ## x __attribute__((unused))
#elif defined(__LCLINT__)
# define UNUSED(x) /*#unused#*/ x
#else
# define UNUSED(x) x
#endif
void dcc_mon_siginfo_handler(int UNUSED(whatsig))

macro-less and portable way to declare one or more parameters as unused:
template <typename... Args> inline void unused(Args&&...) {}
int main(int argc, char* argv[])
{
unused(argc, argv);
return 0;
}

Using preprocessor directives is considered evil most of the time. Ideally you want to avoid them like the Pest. Remember that making the compiler understand your code is easy, allowing other programmers to understand your code is much harder. A few dozen cases like this here and there makes it very hard to read for yourself later or for others right now.
One way might be to put your parameters together into some sort of argument class. You could then use only a subset of the variables (equivalent to your assigning 0 really) or having different specializations of that argument class for each platform. This might however not be worth it, you need to analyze whether it would fit.
If you can read impossible templates, you might find advanced tips in the "Exceptional C++" book. If the people who would read your code could get their skillset to encompass the crazy stuff taught in that book, then you would have beautiful code which can also be easily read. The compiler would also be well aware of what you are doing (instead of hiding everything by preprocessing)

I have seen this instead of the (void)param2 way of silencing the warning:
void foo(int param1, int param2)
{
std::ignore = param2;
bar(param1);
}
Looks like this was added in C++11

Lol! I dont think there is another question on SO that reveal all the heretics corrupted by Chaos better that this one!
With all due respect to C++17 there is a clear guideline in C++ Core Guidelines. AFAIR, back in 2009 this option was available as well as today. And if somebody says it is considered as a bug in Doxygen then there is a bug in Doxygen

First off the warning is generated by the variable definition in the source file not the header file. The header can stay pristine and should, since you might be using something like doxygen to generate the API-documentation.
I will assume that you have completely different implementation in source files. In these cases you can either comment out the offending parameter or just write the parameter.
Example:
func(int a, int b)
{
b;
foo(a);
}
This might seem cryptic, so defined a macro like UNUSED. The way MFC did it is:
#ifdef _DEBUG
#define UNUSED(x)
#else
#define UNUSED(x) x
#endif
Like this you see the warning still in debug builds, might be helpful.

Is it not safe to always comment out parameter names? If it's not you can do something like
#ifdef _MSC_VER
# define P_(n) n
#else
# define P_(n)
#endif
void ProcessOps::sendToExternalApp(
QString sAppName, QString sImagePath,
qreal P_(qrLeft), qreal P_(qrTop), qreal P_(qrWidth), qreal P_(qrHeight))
It's a bit less ugly.

Using an UNREFERENCED_PARAMETER(p) could work. I know it is defined in WinNT.h for Windows systems and can easily be defined for gcc as well (if it doesn't already have it).
UNREFERENCED PARAMETER(p) is defined as
#define UNREFERENCED_PARAMETER(P) (P)
in WinNT.h.

Use compiler's flag, e.g. flag for GCC:
-Wno-unused-variable

In C++11, this is the solution I'm using:
template<typename... Ts> inline void Unreferenced(Ts&&...) {}
int Foo(int bar)
{
Unreferenced(bar);
return 0;
}
int Foo2(int bar1, int bar2)
{
Unreferenced(bar1, bar2);
return 0;
}
Verified to be portable (at least on modern msvc, clang and gcc) and not producing extra code when optimizations are enabled.
With no optimization, the extra function call is performed and references to the parameters are copied to the stack, but there are no macros involved.
If the extra code is an issue, you can use this declaration instead:
(decltype(Unreferenced(bar1, bar2)))0;
but at that point, a macro provides better readability:
#define UNREFERENCED(...) { (decltype(Unreferenced(__VA_ARGS__)))0; }

This works well but requires C++11
template <typename ...Args>
void unused(Args&& ...args)
{
(void)(sizeof...(args));
}

You can use __unused to tell the compiler that variable might not be used.
- (void)myMethod:(__unused NSObject *)theObject
{
// there will be no warning about `theObject`, because you wrote `__unused`
__unused int theInt = 0;
// there will be no warning, but you are still able to use `theInt` in the future
}

I found most of the presented answers work for local unused variable only, and will cause compile error for unused static global variable.
Another macro needed to suppress the warning of unused static global variable.
template <typename T>
const T* UNUSED_VARIABLE(const T& dummy) {
return &dummy;
}
#define UNUSED_GLOBAL_VARIABLE(x) namespace {\
const auto dummy = UNUSED_VARIABLE(x);\
}
static int a = 0;
UNUSED_GLOBAL_VARIABLE(a);
int main ()
{
int b = 3;
UNUSED_VARIABLE(b);
return 0;
}
This works because no warning will be reported for non-static global variable in anonymous namespace.
C++ 11 is required though
g++ -Wall -O3 -std=c++11 test.cpp

void func(void *aux UNUSED)
{
return;
}
smth like that, in that case if u dont use aux it wont warn u

I don't see your problem with the warning. Document it in the method/function header that compiler xy will issue a (correct) warning here, but that theses variables are needed for platform z.
The warning is correct, no need to turn it off. It does not invalidate the program - but it should be documented, that there is a reason.

what does this macro mean ? #define UNUSED(x) ((x)=(x))

what does this macro mean ? I just find the following macro in source files:
#define UNUSED(x) ((x)=(x))

It is probably there to suppress compiler warnings of unused variables/arguments to functions. You could also use this:
// C++ only
void some_func(int /*x*/)
Or
// C and C++
void some_func(int x)
{
(void)x;
}
Or your compiler may support a flag to do so, but these are portable and won't skip over valid warnings.

Use it to get rid of any compiler warning referring an unused variable.

Some compilers issue a warning about unused variables - variables that are defined but never referenced. Sometimes you have code that references a variable only under some conditional ifdefs (only on some platforms or only in debug) and it is inconvenient to duplicate those conditions at the point the variable is defined. A macro like this can be used to suppress the unused variable warning in such cases.

It silence the compiler from complaining that a variable is not used.
Other ways to do it :
completely remove the variable : void foo( int )
out comment the variable : void foo( int /* value */ )
use that macro : void foo( int value ){ UNUSED(value); }

Is it possible to write these pure_assert and const_assert macros?

The GCC __attribute__((pure)) and __attribute__((const)) allow functions to be declared as non–side-effecting and referentially transparent, respectively; let's say I want to write pure_assert and const_assert macros, whose argument must be an expression of the appropriate level of strictness, that is:
assert(oops_a_side_effect());
Silently results in different behaviours in debug and release, but:
pure_assert(oops_a_side_effect());
const_assert(oops_read_a_global());
Would be a compile-time error, at least in debug builds. For what I should hope are obvious reasons, you can't just create a pure_assert_impl declared __attribute__((pure)) and have the macro expand to it. So is it possible to write these macros?

Does gcc enforce that pure and const functions cannot call non-pure or non-const functions, respectively? If so, you could define a properly attributed function template which takes a function pointer as a template parameter, and let the macro expand to an invocation of that function template. I assume you need to support functions that take parameters, this would work better with C++0x variadic templates or lambdas.

gcc does not enforce purity or referential transparency in any way. These attributes are just hints for the optimiser. So the answer is no.

I doubt that there's a really good solution for this, but I've found a possibility for something like const_assert(), which appears to work with the two versions of gcc I have readily to hand (4.1.2 and 4.4.4).
#include <assert.h>
extern void dummy_void_function(void);
#define const_assert(x) \
assert(__builtin_choose_expr(__builtin_constant_p((x) == (x)), \
(x), dummy_void_function()))
extern int function(void);
extern int __attribute__((pure)) pure_function(void);
extern int __attribute__((const)) const_function(void);
extern int global;
extern volatile int volatile_global;
void test(int arg)
{
/* These cause compile-time errors: */
const_assert(function() == 0);
const_assert(pure_function() == 0);
const_assert(volatile_global == 0);
/* These don't: */
const_assert(const_function() == 0);
const_assert(arg == 0);
const_assert(global == 0);
}
This is really checking whether the expression (x) == (x) is regarded as a compile-time constant by the compiler, and creating brokenness if it's not. The "good" cases effectively become assert(x); and the bad ones generate compile-time errors:
$ gcc -c const_assert.c
const_assert.c: In function 'test':
const_assert.c:18: error: void value not ignored as it ought to be
const_assert.c:19: error: void value not ignored as it ought to be
const_assert.c:20: error: void value not ignored as it ought to be
However, with optimisation enabled, it still produces errors in the expected cases, but one of them is a bit odd:
$ gcc -O -c const_assert.c
const_assert.c: In function 'test':
const_assert.c:18: error: void value not ignored as it ought to be
const_assert.c:19: error: first argument to '__builtin_choose_expr' not a constant
const_assert.c:20: error: void value not ignored as it ought to be
...you'd expect the result of __builtin_constant_p() to be regarded as a constant by definition! So I'm not sure that I would really trust this for real code...
(And I don't have any good ideas right now for pure_assert()!)

Tough luck, I'm afraid. Macros are expanded by the preprocessor, even before the compiler starts looking at the code.
What maybe could be a solution, is to let the assert test expression be evaluated regardless of release or debug mode, however let the result be tested only in debug mode.

C++ expected type specifier error

I am trying to write a wrapper function to figure out who is calling a specific function. So in .h file I added the following: (and implementation in the .cc file)
extern int foo(/*some arguments*/);
extern void call_log(const char*file,const char*function,const int line,const char*args);
#define foo(...) (call_log(__FILE__, __FUNCTION__, __LINE__, "" #__VA_ARGS__), foo(__VA_ARGS__))
However, I get the following error:
error: expected a type specifier
(call_log(__FILE__, __FUNCTION__, __LINE__, "" #__VA_ARGS__),foo(__VA_ARGS__)
Assume that the foo function is called with some parameters and returns an int.
the compiler is gcc 3.4
Thanks
EDIT
removed "." and extra spaced, yet problem still there. Can anyone see what can cause it. Also notice that I am using variadic macros -- supported by my compiler (c99)
Edit 2
Just to get the claims about my illegal use of some c/c++ constructs. The following code below works, and I am trying to adapt it to my current (above function)
#include <stdio.h>
int funcA( int a, int b ){ return a+b; }
// instrumentation
void call_log(const char*file,const char*function,const int line,const char*args){
printf("file:%s line: %i function: %s args: %s\n",file,line,function,args);
}
#define funcA(...) \
(call_log(__FILE__, __FUNCTION__, __LINE__, "" #__VA_ARGS__), funcA(__VA_ARGS__))
// testing
void funcB()
{
funcA(7,8);
}
int main(void){
int x = funcA(1,2)+
funcA(3,4);
printf( "x: %i (==10)\n", x );
funcA(5,6);
funcB();
}
Edit 3
As litb pointed out, the problem is, in fact, due to macro substitutions. I also noticed that foo is not only a function call but also used as ptr->foo[] in some cases. Any ides how to resolve this sort of issues, without breaking more code

The best way to find out what's wrong would be to make the compiler show the preprocessed code. You can then easier spot the problem in the offending line.

If I'm not mistaken I believe you have a number of syntax errors in the definition and declaration of call_log.
In the definition I am pretty sure you need a space between the const char* and the variable name. ie...
extern void call_log(const char* file,const char* function,const int line,const char* args);
In addition, in the declaration, I don't think you can append #__VA_ARGS__ to "" in the manner you are doing. The macro will resolved this as:
(call_log(file_name, function_name, line_#, "" arg1, arg2...), foo(args[])
which is not a valid function call. On a side-note you are also missing a semicolon after the macro definition.
Finally, I do not see a reference to foo(args) in your macro definition; It's possible I'm missing some context but you may wish to look at that as well.
Hope this helps...
CJ