boost/libs/type_traits/doc/has_bit_and.qbk - nest-cam/4320010/boost - Git at Google

 [/
   (C) Copyright 2009-2011  Frederic Bron.
   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).
 ]

 [section:has_bit_and has_bit_and]
    template <class Lhs, class Rhs=Lhs, class Ret=dont_care>
    struct has_bit_and : public __tof {};

 __inherit
 If (i) `lhs` of type `Lhs` and `rhs` of type `Rhs` can be used in expression `lhs&rhs`,
 and (ii) `Ret=dont_care` or the result of expression `lhs&rhs` is convertible to `Ret`
 then inherits from __true_type,
 otherwise inherits from __false_type.

 The default behaviour (`Ret=dont_care`) is to not check for the return value of binary `operator&`.
 If `Ret` is different from the default `dont_care` type, the return value is checked to be convertible to `Ret`.
 Convertible to `Ret` means that the return value of the operator can be used as argument to a function expecting `Ret`:
 ``
 void f(Ret);
 Lhs lhs;
 Rhs rhs;
 f(lhs&rhs); // is valid if has_bit_and<Lhs, Rhs, Ret>::value==true
 ``
 If `Ret=void`, the return type is checked to be exactly `void`.

 __header `#include <boost/type_traits/has_bit_and.hpp>` or `#include <boost/type_traits/has_operator.hpp>` or `#include <boost/type_traits.hpp>`

 __examples

 [:`has_bit_and<Lhs, Rhs, Ret>::value_type` is the type `bool`.]
 [:`has_bit_and<Lhs, Rhs, Ret>::value` is a `bool` integral constant expression.]
 [:`has_bit_and<int>::value` is a `bool` integral constant expression that evaluates to `true`.]
 [:`has_bit_and<long>` inherits from `__true_type`.]

 [:`has_bit_and<int, int, int>` inherits from `__true_type`.]
 [:`has_bit_and<const int, int>` inherits from `__true_type`.]

 [:`has_bit_and<int, double, bool>` inherits from `__false_type`.]
 [:`has_bit_and<int, int, std::string>` inherits from `__false_type`.]


 [*See also:] [link boost_typetraits.category.value_traits.operators Operator Type Traits]

 [*Limitation:]

 * Requires a compiler with working SFINAE.

 [*Known issues:]

 * This trait cannot detect whether binary `operator&` is public or not:
 if `operator&` is defined as a private member of `Lhs` then
 instantiating `has_bit_and<Lhs>` will produce a compiler error.
 For this reason `has_bit_and` cannot be used to determine whether a type has a public `operator&` or not.
 ``
 struct A { private: void operator&(const A&); };
 boost::has_bit_and<A>::value; // error: A::operator&(const A&) is private
 ``

 * There is an issue if the operator exists only for type `A` and `B` is
 convertible to `A`. In this case, the compiler will report an ambiguous overload.
 ``
 struct A { };
 void operator&(const A&, const A&);
 struct B { operator A(); };
 boost::has_bit_and<A>::value; // this is fine
 boost::has_bit_and<B>::value; // error: ambiguous overload
 ``

 * There is an issue when applying this trait to template classes.
 If `operator&` is defined but does not bind for a given template type,
 it is still detected by the trait which returns `true` instead of `false`.
 Example:
 ``
 #include <boost/type_traits/has_bit_and.hpp>
 #include <iostream>

 template <class T>
 struct contains { T data; };

 template <class T>
 bool operator&(const contains<T> &lhs, const contains<T> &rhs) {
 	return f(lhs.data, rhs.data);
 }

 class bad { };
 class good { };
 bool f(const good&, const good&) { }

 int main() {
 	std::cout<<std::boolalpha;
 	// works fine for contains<good>
 	std::cout<<boost::has_bit_and< contains< good > >::value<<'\n'; // true
 	contains<good> g;
 	g&g; // ok
 	// does not work for contains<bad>
 	std::cout<<boost::has_bit_and< contains< bad > >::value<<'\n'; // true, should be false
 	contains<bad> b;
 	b&b; // compile time error
 	return 0;
 }
 ``

 * `volatile` qualifier is not properly handled and would lead to undefined behavior

 [endsect]
	[/
	(C) Copyright 2009-2011 Frederic Bron.
	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).
	]

	[section:has_bit_and has_bit_and]
	template <class Lhs, class Rhs=Lhs, class Ret=dont_care>
	struct has_bit_and : public __tof {};

	__inherit
	If (i) `lhs` of type `Lhs` and `rhs` of type `Rhs` can be used in expression `lhs&rhs`,
	and (ii) `Ret=dont_care` or the result of expression `lhs&rhs` is convertible to `Ret`
	then inherits from __true_type,
	otherwise inherits from __false_type.

	The default behaviour (`Ret=dont_care`) is to not check for the return value of binary `operator&`.
	If `Ret` is different from the default `dont_care` type, the return value is checked to be convertible to `Ret`.
	Convertible to `Ret` means that the return value of the operator can be used as argument to a function expecting `Ret`:
	``
	void f(Ret);
	Lhs lhs;
	Rhs rhs;
	f(lhs&rhs); // is valid if has_bit_and<Lhs, Rhs, Ret>::value==true
	``
	If `Ret=void`, the return type is checked to be exactly `void`.

	__header `#include <boost/type_traits/has_bit_and.hpp>` or `#include <boost/type_traits/has_operator.hpp>` or `#include <boost/type_traits.hpp>`

	__examples

	[:`has_bit_and<Lhs, Rhs, Ret>::value_type` is the type `bool`.]
	[:`has_bit_and<Lhs, Rhs, Ret>::value` is a `bool` integral constant expression.]
	[:`has_bit_and<int>::value` is a `bool` integral constant expression that evaluates to `true`.]
	[:`has_bit_and<long>` inherits from `__true_type`.]

	[:`has_bit_and<int, int, int>` inherits from `__true_type`.]
	[:`has_bit_and<const int, int>` inherits from `__true_type`.]

	[:`has_bit_and<int, double, bool>` inherits from `__false_type`.]
	[:`has_bit_and<int, int, std::string>` inherits from `__false_type`.]


	[*See also:] [link boost_typetraits.category.value_traits.operators Operator Type Traits]

	[*Limitation:]

	* Requires a compiler with working SFINAE.

	[*Known issues:]

	* This trait cannot detect whether binary `operator&` is public or not:
	if `operator&` is defined as a private member of `Lhs` then
	instantiating `has_bit_and<Lhs>` will produce a compiler error.
	For this reason `has_bit_and` cannot be used to determine whether a type has a public `operator&` or not.
	``
	struct A { private: void operator&(const A&); };
	boost::has_bit_and<A>::value; // error: A::operator&(const A&) is private
	``

	* There is an issue if the operator exists only for type `A` and `B` is
	convertible to `A`. In this case, the compiler will report an ambiguous overload.
	``
	struct A { };
	void operator&(const A&, const A&);
	struct B { operator A(); };
	boost::has_bit_and<A>::value; // this is fine
	boost::has_bit_and<B>::value; // error: ambiguous overload
	``

	* There is an issue when applying this trait to template classes.
	If `operator&` is defined but does not bind for a given template type,
	it is still detected by the trait which returns `true` instead of `false`.
	Example:
	``
	#include <boost/type_traits/has_bit_and.hpp>
	#include <iostream>

	template <class T>
	struct contains { T data; };

	template <class T>
	bool operator&(const contains<T> &lhs, const contains<T> &rhs) {
	return f(lhs.data, rhs.data);
	}

	class bad { };
	class good { };
	bool f(const good&, const good&) { }

	int main() {
	std::cout<<std::boolalpha;
	// works fine for contains<good>
	std::cout<<boost::has_bit_and< contains< good > >::value<<'\n'; // true
	contains<good> g;
	g&g; // ok
	// does not work for contains<bad>
	std::cout<<boost::has_bit_and< contains< bad > >::value<<'\n'; // true, should be false
	contains<bad> b;
	b&b; // compile time error
	return 0;
	}
	``

	* `volatile` qualifier is not properly handled and would lead to undefined behavior

	[endsect]