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I am confused about the advantages of using the the




types against simply using const bools in the context of template metaprogramming.

The boost::mpl library clearly prefers the first approach, and defines helper functions like and_, or_ to help manage such bool_. Conditional metafunctions like if_ "take" a bool_ as first (template) argument, but behind the scenes "call" a if_c metafunction wich expects a (const) bool as first (template) argument.

What are the arguments behind this decision?

Thank you in advance for your help!

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3 Answers 3

up vote 11 down vote accepted

Here is a short example, how I use these types every now and then. This example would not be possible, using const bool:

void do_something(boost::mpl::bool_<true>)

void do_something(boost::mpl::bool_<false>)

Call one of these two functions depending on the type of argument:

template<class T>
void doIt(void)

In this case either the first or the second function will be called, depending on the fact if type T is a pointer or not. These types allow you to use function overloading, where it would not be possible using a const bool. With a const bool you would have to decide at runtime, which branch to take. This is specially important if called functions are themselves templates, which would not compile correctly, if they were instantiated for types other than expected, e.g. the first function definition above might contain code, which only compiles for pointers.

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Thank you that's a good example! –  KRao Oct 21 '10 at 13:31
Oh yeah, I forgot about overloading! –  sbi Oct 21 '10 at 13:59
THis is a good answer, but it's much more verbose than necessary. You can write do_something(boost::is_pointer<T>()), which will do the same thing in pretty much the same way. –  Dave Abrahams Nov 28 '11 at 16:46

It's all about creating enough uniformity that the library can provide useful functionality. The MPL protocol is: "all metafunction arguments (and returns) are types." This allows us to write a templates that can operate generically on metafunctions. For example, this template accepts any metafunction (or any metafunction with up to N arguments in C++03):

template <template <class...> class some_metafunction>
struct wrapper;

Once you allow some of the template arguments to be non-types, writing such a wrapper becomes impossible. For a practical example of why we care, this uniformity allows the library to pick apart and evaluate MPL lambda expressions. If metafunction arguments were allowed to be non-types that feature would be unimplementable, because there would be no way to write out all the partial specializations needed to untangle the outer template xxx from its arguments ai in xxx<a1,a2,a3,...>.

A less-interesting, if not less-valid, part of the reason is that many things become less verbose the way we did it in MPL. compare:

and_<mf0<x,y>, mf1<z>, mf2<x,z> >::value


mf0<x,y>::value && mf1<z>::value && mf2<x,z>::value
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I suppose one reason is that bool_<...> are types, and when using them as results of a meta functions, you will never have to stop and think whether your result is a type and you have to do

typedef some_type result;

or a value, which has to be returned as

const static ??? result = some_value;

where you also have to keep track of the type.

Also, I suspect (I haven't worked with Boost.MPL yet) that they both have a result type nested referring to themselves, so that you can write meta functions by just deriving from them:

template< bool b >
struct my_meta_func : bool_<b> {};

and can invoke my_meta_func::result.

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You're right on, only results are always called ::type in MPL. –  Dave Abrahams Nov 28 '11 at 16:47

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