libs/type_erasure/example/associated.cpp
// Boost.TypeErasure library // // Copyright 2012 Steven Watanabe // // Distributed under the Boost Software License Version 1.0. (See // accompanying file LICENSE_1_0.txt or copy at // http://www.boost.org/LICENSE_1_0.txt) // // $Id$ #include <boost/type_erasure/any.hpp> #include <boost/type_erasure/any_cast.hpp> #include <boost/type_erasure/builtin.hpp> #include <boost/type_erasure/operators.hpp> #include <boost/type_erasure/deduced.hpp> #include <boost/type_erasure/same_type.hpp> #include <boost/pointee.hpp> #include <boost/mpl/vector.hpp> #include <iostream> namespace mpl = boost::mpl; using namespace boost::type_erasure; //[associated1 /*` Associated types such as `typename T::value_type` or `typename std::iterator_traits<T>::reference` are quite common in template programming. Boost.TypeErasure handles them using the __deduced template. __deduced is just like an ordinary __placeholder, except that the type that it binds to is determined by calling a metafunction and does not need to be specified explicitly. For example, we can define a concept for holding an iterator, raw pointer, or smart pointer as follows. First, we define a metafunction called `pointee` defining the associated type. */ template<class T> struct pointee { typedef typename mpl::eval_if<is_placeholder<T>, mpl::identity<void>, boost::pointee<T> >::type type; }; /*` Note that we can't just use `boost::pointee`, because this metafunction needs to be safe to instantiate with placeholders. It doesn't matter what it returns as long as it doesn't give an error. (The library never tries to instantiate it with a placeholder, but argument dependent lookup can cause spurious instantiations.) */ template<class T = _self> struct pointer : mpl::vector< copy_constructible<T>, dereferenceable<deduced<pointee<T> >&, T> > { // provide a typedef for convenience typedef deduced<pointee<T> > element_type; }; //] void associated2() { //[associated2 /*` Now the Concept of `x` uses two placeholders, `_self` and `pointer<>::element_type`. When we construct `x`, with an `int*`, `pointer<>::element_type` is deduced as `pointee<int*>::type` which is `int`. Thus, dereferencing `x` returns an __any that contains an `int`. */ int i = 10; any< mpl::vector< pointer<>, typeid_<pointer<>::element_type> > > x(&i); int j = any_cast<int>(*x); // j == i //] } void associated3() { //[associated3 /*` Sometimes we want to require that the associated type be a specific type. This can be solved using the __same_type concept. Here we create an any that can hold any pointer whose element type is `int`. */ int i = 10; any< mpl::vector< pointer<>, same_type<pointer<>::element_type, int> > > x(&i); std::cout << *x << std::endl; // prints 10 /*` Using __same_type like this effectively causes the library to replace all uses of `pointer<>::element_type` with `int` and validate that it is always bound to `int`. Thus, dereferencing `x` now returns an `int`. */ //] } void associated4() { //[associated4 /*` __same_type can also be used for two placeholders. This allows us to use a simple name instead of writing out an associated type over and over. */ int i = 10; any< mpl::vector< pointer<>, same_type<pointer<>::element_type, _a>, typeid_<_a>, copy_constructible<_a>, addable<_a>, ostreamable<std::ostream, _a> > > x(&i); std::cout << (*x + *x) << std::endl; // prints 20 //] } //[associated //` (For the source of the examples in this section see //` [@boost:/libs/type_erasure/example/associated.cpp associated.cpp]) //` [associated1] //` [associated2] //` [associated3] //` [associated4] //]