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The C preprocessor is justifiably feared and shunned by the C++ community. In-lined functions, consts and templates are usually a safer and superior alternative to a #define.

The following macro:

#define SUCCEEDED(hr) ((HRESULT)(hr) >= 0)

is in no way superior to the type safe:

inline bool succeeded(int hr) { return hr >= 0; }

But macros do have their place, please list the uses you find for macros that you can't do without the preprocessor.

Please put each use-cases in a seperate answer so it can be voted up and if you know of how to achieve one of the answers without the preprosessor point out how in that answer's comments.

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38 Answers 38

If you have a list of fields that get used for a bunch of things, e.g. defining a structure, serializing that structure to/from some binary format, doing database inserts, etc, then you can (recursively!) use the preprocessor to avoid ever repeating your field list.

This is admittedly hideous. But maybe sometimes better than updating a long list of fields in multiple places? I've used this technique exactly once, and it was quite helpful that one time.

Of course the same general idea is used extensively in languages with proper reflection -- just instrospect the class and operate on each field in turn. Doing it in the C preprocessor is fragile, illegible, and not always portable. So I mention it with some trepidation. Nonetheless, here it is...

(EDIT: I see now that this is similar to what @Andrew Johnson said on 9/18; however the idea of recursively including the same file takes the idea a bit further.)

// file foo.h, defines class Foo and various members on it without ever repeating the
// list of fields.

#if defined( FIELD_LIST )
   // here's the actual list of fields in the class.  If FIELD_LIST is defined, we're at
   // the 3rd level of inclusion and somebody wants to actually use the field list.  In order
   // to do so, they will have defined the macros STRING and INT before including us.
   STRING( fooString )
   INT( barInt )   
#else // defined( FIELD_LIST )

#if !defined(FOO_H)
#define FOO_H

#define DEFINE_STRUCT
// recursively include this same file to define class Foo
#include "foo.h"
#undef DEFINE_STRUCT

#define DEFINE_CLEAR
// recursively include this same file to define method Foo::clear
#include "foo.h"
#undef DEFINE_CLEAR

// etc ... many more interesting examples like serialization

#else // defined(FOO_H)
// from here on, we know that FOO_H was defined, in other words we're at the second level of
// recursive inclusion, and the file is being used to make some particular
// use of the field list, for example defining the class or a single method of it

#if defined( DEFINE_STRUCT )
#define STRING(a)  std::string a;
#define INT(a)     long a;
   class Foo
   {
      public:
#define FIELD_LIST
// recursively include the same file (for the third time!) to get fields
// This is going to translate into:
//    std::string fooString;
//    int barInt;
#include "foo.h"
#endif

      void clear();
   };
#undef STRING
#undef INT
#endif // defined(DEFINE_STRUCT)


#if defined( DEFINE_ZERO )
#define STRING(a) a = "";
#define INT(a) a = 0;
#define FIELD_LIST
   void Foo::clear()
   {
// recursively include the same file (for the third time!) to get fields.
// This is going to translate into:
//    fooString="";
//    barInt=0;
#include "foo.h"
#undef STRING
#undef int
   }
#endif // defined( DEFINE_ZERO )

// etc...


#endif // end else clause for defined( FOO_H )

#endif // end else clause for defined( FIELD_LIST )
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I've used the preprocesser to calculate fixed-point numbers from floating point values used in embedded systems that cannot use floating point in the compiled code. It's handy to have all of your math in Real World Units and not have to think about them in fixed-point.

Example:

// TICKS_PER_UNIT is defined in floating point to allow the conversions to compute during compile-time.
#define TICKS_PER_UNIT  1024.0


// NOTE: The TICKS_PER_x_MS will produce constants in the preprocessor.  The (long) cast will
//       guarantee there are no floating point values in the embedded code and will produce a warning
//       if the constant is larger than the data type being stored to.
//       Adding 0.5 sec to the calculation forces rounding instead of truncation.
#define TICKS_PER_1_MS( ms ) (long)( ( ( ms * TICKS_PER_UNIT ) / 1000 ) + 0.5 )
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1  
This can be done with an inlined function –  Motti Aug 19 '09 at 7:01

You need a macros for resource identifiers in Visual Studio as the resource compiler only understands them (i.e., it doesn't work with const or enum).

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Can you implement this as an inline function?

#define my_free(x) do { free(x); x = NULL; } while (0)
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11  
template<class T> inline void destroy(T*& p) { delete p; p = 0; } –  KTC Sep 19 '08 at 4:48

You can enable additional logging in a debug build and disable it for a release build without the overhead of a Boolean check. So, instead of:

void Log::trace(const char *pszMsg) {
    if (!bDebugBuild) {
        return;
    }
    // Do the logging
}

...

log.trace("Inside MyFunction");

You can have:

#ifdef _DEBUG
#define LOG_TRACE log.trace
#else
#define LOG_TRACE void
#endif

...

LOG_TRACE("Inside MyFunction");

When _DEBUG is not defined, this will not generate any code at all. Your program will run faster and the text for the trace logging won't be compiled into your executable.

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1  
One can achieve similar effect by playing with templates. –  Sergey Skoblikov Nov 28 '08 at 17:11
1  
inline void LogTrace(const char*) { if(DEBUG) doTrace(); } should be optimized away in release builds. –  Motti Jun 15 '09 at 18:35

I once took a C++ application full of macros that took 45 minutes to build, replaced the macros with inline functions, and got the build down to less than 15 minutes.

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#define COLUMNS(A,B) [(B) - (A) + 1]

struct 
{
    firstName COLUMNS(  1,  30);
    lastName  COLUMNS( 31,  60);
    address1  COLUMNS( 61,  90);
    address2  COLUMNS( 91, 120);
    city      COLUMNS(121, 150);
};
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Often times I end up with code like:

int SomeAPICallbackMethod(long a, long b, SomeCrazyClass c, long d, string e, string f, long double yx) { ... }
int AnotherCallback(long a, long b, SomeCrazyClass c, long d, string e, string f, long double yx) { ... }
int YetAnotherCallback(long a, long b, SomeCrazyClass c, long d, string e, string f, long double yx) { ... }

In some cases I'll use the following to make my life easier:

#define APIARGS long a, long b, SomeCrazyClass c, long d, string e, string f, long double yx
int SomeAPICallbackMethod(APIARGS) { ... }

It comes with the caveat of really hiding the variable names, which can be an issue in larger systems, so this isn't always the right thing to do, only sometimes.

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6  
In that situation, you might be better off making a CallbackArg structure. –  Josh Matthews Sep 19 '08 at 4:24

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