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Say we have a macro like this

#define FOO(type,name) type name

Which we could use like

FOO(int, int_var);

But not always as simple as that:

FOO(std::map<int, int>, map_var); // error: macro "FOO" passed 3 arguments, but takes just 2

Of course we could do:

 typedef std::map<int, int> map_int_int_t;
 FOO(map_int_int_t, map_var); // OK

which is not as flexible. Plus type incompatibilities have to be dealt with. Any idea how to resolve this with macro ?

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I'm guessing you have to escape characters with a meaning to make them literals. – Jite Dec 12 '12 at 15:04
At least in C++, you can put a typedef anywhere, so I'm not sure why you say it has to be "beforehand". – Vaughn Cato Dec 12 '12 at 15:05
@dmckee But at least in this case the typedef solves it. GCC 4.6 here. – PoP Dec 12 '12 at 15:13

6 Answers 6

up vote 46 down vote accepted

Because angle brackets can also represent (or occur in) the comparison operators <, >, <= and >=, macro expansion can't ignore commas inside angle brackets like it does with the various balanced brackets (), [] and {}. You can enclose the macro argument in parentheses:

FOO((std::map<int, int>), map_var);

The problem is then that the parameter remains parenthesized inside the macro expansion, which prevents it being read as a type in most contexts.

A nice trick to workaround this is that in C++, you can extract a typename from a parenthesized type name using a function type:

template<typename T> struct argument_type;
template<typename T, typename U> struct argument_type<T(U)> { typedef U type; };
#define FOO(t,name) argument_type<void(t)>::type name
FOO((std::map<int, int>), map_var);

Because forming function types ignores extra parentheses, you can use this macro with or without parentheses where the type name doesn't include a comma:

FOO((int), int_var);
FOO(int, int_var2);

In C, of course, this isn't necessary because type names can't contain commas outside parentheses. So, for a cross-language macro you can write:

#ifdef __cplusplus__
template<typename T> struct argument_type;
template<typename T, typename U> struct argument_type<T(U)> { typedef U type; };
#define FOO(t,name) argument_type<void(t)>::type name
#define FOO(t,name) t name
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This is awesome. But how did you find out about this? I've been trying tons of tricks and never even thought that a function type would fix the issue. – William Custode Jul 12 '14 at 12:34
@WilliamCustode as I recall, I'd been studying the grammar of function types and function declarations with reference to the most vexing parse problem, so it was fortuitous that I was aware that redundant parentheses could be applied to a type in that context. – ecatmur Jul 14 '14 at 9:33
I found a problem with this method when working with templates. Let's say the code I wanted was this: template<class KeyType, class ValueType> void SomeFunc(FOO(std::map<KeyType, ValueType>) element) {} If I apply this solution here, the structs behind the macro become dependent types, and the typename prefix is now required on the type. You can add it, but type deduction has been broken, so you now have to manually list the type arguments to call the function. I ended up using temple's method of defining a macro for the comma. It might not look as pretty, but it worked perfectly. – Roger Sanders Oct 1 '14 at 4:30

If you can't use parentheses and you don't like Mike's SINGLE_ARG solution, just define a COMMA:

#define COMMA ,

FOO(std::map<int COMMA int>, map_var);
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#define COMMA wow, you just saved me HOURS of work... why didn't I think of this years ago. Thanks for sharing this idea. This is even allowing me to build macros which setup functions with different argument counts altogether. – moliad Dec 5 '13 at 16:59
Plus 1 for the horror – namezero Feb 8 at 19:05
doesn't work if you want to stringize the argument... – kiw Oct 13 at 14:07
@kiw If you #define STRVX(...) STRV(__VA_ARGS__) and #define STRV(...) # __VA_ARGS__, then std::cout << STRV(type<A COMMA B>) << std::endl; will print type<A COMMA B> and std::cout << STRVX(type<A COMMA B>) << std::endl; will print type<A , B>. (STRV is for "variadic stringify", and STRVX is for "expanded variadic stringify".) – not-a-user Nov 2 at 9:38
@not-a-user yes, but with variadic macros you don't need the COMMA macro in the first place. That's what I ended up with. – kiw Nov 4 at 11:35

If your preprocessor supports variadic macros:

#define SINGLE_ARG(...) __VA_ARGS__
#define FOO(type,name) type name

FOO(SINGLE_ARG(std::map<int, int>), map_var);

Otherwise, it's a bit more tedious:

#define SINGLE_ARG2(A,B) A,B
#define SINGLE_ARG3(A,B,C) A,B,C
// as many as you'll need

FOO(SINGLE_ARG2(std::map<int, int>), map_var);
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Oh, gosh... Why? Why not just enclose in parentheses? – user405725 Dec 12 '12 at 15:09
@VladLazarenko: Because you can't always put arbitrary pieces of code in parentheses. In particular, you can't put parentheses around the type name in a declarator, which is exactly what this argument becomes. – Mike Seymour Dec 12 '12 at 15:11

There are at least two ways to do this. First, you can define a macro that takes multiple arguments:

#define FOO2(type1, type2, name) type1, type2, name

if you do that you may find that you end up defining more macros to handle more arguments.

Second, you can put parentheses around the argument:

#define FOO(type, name) type name
F00((std::map<int, int>) map_var;

if you do that you may find that the extra parentheses screw up the syntax of the result.

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For the first solution, each macro will have to have a different name, since macros don't overload. And for the second, if you're passing in a type name, there's a very good chance that it will be used to declare a variable (or a typedef), so the parentheses will cause problems. – James Kanze Dec 12 '12 at 15:13

This is possible with P99:

#include "p99/p99.h"
#define FOO(...) P99_ALLBUTLAST(__VA_ARGS__) P99_LAST(__VA_ARGS__)

The code above effectively strips only the last comma in the argument list. Check with clang -E (P99 requires a C99 compiler).

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The simple answer is that you can't. This is a side effect of the choice of <...> for template arguments; the < and > also appear in unbalanced contexts so the macro mechanism couldn't be extended to handle them like it handles parentheses. (Some of the committee members had argued for a different token, say (^...^), but they weren't able to convince the majority of the problems using <...>.)

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