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463 lines
13 KiB
463 lines
13 KiB
5 years ago
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// Boost Lambda Library -- if.hpp ------------------------------------------
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// Copyright (C) 1999, 2000 Jaakko Jarvi (jaakko.jarvi@cs.utu.fi)
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// Copyright (C) 2000 Gary Powell (powellg@amazon.com)
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// Copyright (C) 2001-2002 Joel de Guzman
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//
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// Distributed under the Boost Software License, Version 1.0. (See
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// accompanying file LICENSE_1_0.txt or copy at
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// http://www.boost.org/LICENSE_1_0.txt)
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//
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// For more information, see www.boost.org
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// --------------------------------------------------------------------------
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#if !defined(BOOST_LAMBDA_IF_HPP)
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#define BOOST_LAMBDA_IF_HPP
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#include "boost/lambda/core.hpp"
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// Arithmetic type promotion needed for if_then_else_return
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#include "boost/lambda/detail/operator_actions.hpp"
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#include "boost/lambda/detail/operator_return_type_traits.hpp"
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namespace boost {
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namespace lambda {
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// -- if control construct actions ----------------------
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class ifthen_action {};
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class ifthenelse_action {};
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class ifthenelsereturn_action {};
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// Specialization for if_then.
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template<class Args>
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class
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lambda_functor_base<ifthen_action, Args> {
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public:
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Args args;
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template <class T> struct sig { typedef void type; };
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public:
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explicit lambda_functor_base(const Args& a) : args(a) {}
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template<class RET, CALL_TEMPLATE_ARGS>
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RET call(CALL_FORMAL_ARGS) const {
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if (detail::select(boost::tuples::get<0>(args), CALL_ACTUAL_ARGS))
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detail::select(boost::tuples::get<1>(args), CALL_ACTUAL_ARGS);
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}
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};
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// If Then
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template <class Arg1, class Arg2>
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inline const
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lambda_functor<
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lambda_functor_base<
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ifthen_action,
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tuple<lambda_functor<Arg1>, lambda_functor<Arg2> >
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>
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>
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if_then(const lambda_functor<Arg1>& a1, const lambda_functor<Arg2>& a2) {
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return
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lambda_functor_base<
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ifthen_action,
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tuple<lambda_functor<Arg1>, lambda_functor<Arg2> >
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>
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( tuple<lambda_functor<Arg1>, lambda_functor<Arg2> >(a1, a2) );
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}
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// Specialization for if_then_else.
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template<class Args>
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class
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lambda_functor_base<ifthenelse_action, Args> {
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public:
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Args args;
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template <class T> struct sig { typedef void type; };
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public:
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explicit lambda_functor_base(const Args& a) : args(a) {}
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template<class RET, CALL_TEMPLATE_ARGS>
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RET call(CALL_FORMAL_ARGS) const {
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if (detail::select(boost::tuples::get<0>(args), CALL_ACTUAL_ARGS))
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detail::select(boost::tuples::get<1>(args), CALL_ACTUAL_ARGS);
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else
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detail::select(boost::tuples::get<2>(args), CALL_ACTUAL_ARGS);
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}
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};
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// If then else
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template <class Arg1, class Arg2, class Arg3>
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inline const
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lambda_functor<
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lambda_functor_base<
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ifthenelse_action,
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tuple<lambda_functor<Arg1>, lambda_functor<Arg2>, lambda_functor<Arg3> >
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>
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>
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if_then_else(const lambda_functor<Arg1>& a1, const lambda_functor<Arg2>& a2,
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const lambda_functor<Arg3>& a3) {
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return
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lambda_functor_base<
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ifthenelse_action,
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tuple<lambda_functor<Arg1>, lambda_functor<Arg2>, lambda_functor<Arg3> >
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>
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(tuple<lambda_functor<Arg1>, lambda_functor<Arg2>, lambda_functor<Arg3> >
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(a1, a2, a3) );
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}
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// Our version of operator?:()
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template <class Arg1, class Arg2, class Arg3>
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inline const
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lambda_functor<
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lambda_functor_base<
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other_action<ifthenelsereturn_action>,
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tuple<lambda_functor<Arg1>,
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typename const_copy_argument<Arg2>::type,
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typename const_copy_argument<Arg3>::type>
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>
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>
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if_then_else_return(const lambda_functor<Arg1>& a1,
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const Arg2 & a2,
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const Arg3 & a3) {
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return
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lambda_functor_base<
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other_action<ifthenelsereturn_action>,
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tuple<lambda_functor<Arg1>,
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typename const_copy_argument<Arg2>::type,
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typename const_copy_argument<Arg3>::type>
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> ( tuple<lambda_functor<Arg1>,
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typename const_copy_argument<Arg2>::type,
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typename const_copy_argument<Arg3>::type> (a1, a2, a3) );
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}
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namespace detail {
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// return type specialization for conditional expression begins -----------
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// start reading below and move upwards
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// PHASE 6:1
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// check if A is conbertible to B and B to A
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template<int Phase, bool AtoB, bool BtoA, bool SameType, class A, class B>
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struct return_type_2_ifthenelsereturn;
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// if A can be converted to B and vice versa -> ambiguous
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template<int Phase, class A, class B>
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struct return_type_2_ifthenelsereturn<Phase, true, true, false, A, B> {
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typedef
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detail::return_type_deduction_failure<return_type_2_ifthenelsereturn> type;
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// ambiguous type in conditional expression
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};
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// if A can be converted to B and vice versa and are of same type
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template<int Phase, class A, class B>
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struct return_type_2_ifthenelsereturn<Phase, true, true, true, A, B> {
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typedef A type;
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};
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// A can be converted to B
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template<int Phase, class A, class B>
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struct return_type_2_ifthenelsereturn<Phase, true, false, false, A, B> {
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typedef B type;
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};
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// B can be converted to A
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template<int Phase, class A, class B>
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struct return_type_2_ifthenelsereturn<Phase, false, true, false, A, B> {
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typedef A type;
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};
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// neither can be converted. Then we drop the potential references, and
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// try again
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template<class A, class B>
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struct return_type_2_ifthenelsereturn<1, false, false, false, A, B> {
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// it is safe to add const, since the result will be an rvalue and thus
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// const anyway. The const are needed eg. if the types
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// are 'const int*' and 'void *'. The remaining type should be 'const void*'
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typedef const typename boost::remove_reference<A>::type plainA;
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typedef const typename boost::remove_reference<B>::type plainB;
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// TODO: Add support for volatile ?
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typedef typename
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return_type_2_ifthenelsereturn<
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2,
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boost::is_convertible<plainA,plainB>::value,
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boost::is_convertible<plainB,plainA>::value,
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boost::is_same<plainA,plainB>::value,
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plainA,
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plainB>::type type;
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};
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// PHASE 6:2
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template<class A, class B>
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struct return_type_2_ifthenelsereturn<2, false, false, false, A, B> {
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typedef
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detail::return_type_deduction_failure<return_type_2_ifthenelsereturn> type;
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// types_do_not_match_in_conditional_expression
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};
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// PHASE 5: now we know that types are not arithmetic.
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template<class A, class B>
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struct non_numeric_types {
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typedef typename
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return_type_2_ifthenelsereturn<
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1, // phase 1
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is_convertible<A,B>::value,
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is_convertible<B,A>::value,
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is_same<A,B>::value,
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A,
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B>::type type;
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};
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// PHASE 4 :
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// the base case covers arithmetic types with differing promote codes
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// use the type deduction of arithmetic_actions
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template<int CodeA, int CodeB, class A, class B>
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struct arithmetic_or_not {
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typedef typename
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return_type_2<arithmetic_action<plus_action>, A, B>::type type;
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// plus_action is just a random pick, has to be a concrete instance
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};
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// this case covers the case of artihmetic types with the same promote codes.
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// non numeric deduction is used since e.g. integral promotion is not
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// performed with operator ?:
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template<int CodeA, class A, class B>
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struct arithmetic_or_not<CodeA, CodeA, A, B> {
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typedef typename non_numeric_types<A, B>::type type;
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};
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// if either A or B has promote code -1 it is not an arithmetic type
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template<class A, class B>
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struct arithmetic_or_not <-1, -1, A, B> {
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typedef typename non_numeric_types<A, B>::type type;
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};
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template<int CodeB, class A, class B>
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struct arithmetic_or_not <-1, CodeB, A, B> {
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typedef typename non_numeric_types<A, B>::type type;
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};
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template<int CodeA, class A, class B>
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struct arithmetic_or_not <CodeA, -1, A, B> {
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typedef typename non_numeric_types<A, B>::type type;
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};
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// PHASE 3 : Are the types same?
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// No, check if they are arithmetic or not
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template <class A, class B>
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struct same_or_not {
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typedef typename detail::remove_reference_and_cv<A>::type plainA;
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typedef typename detail::remove_reference_and_cv<B>::type plainB;
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typedef typename
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arithmetic_or_not<
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detail::promote_code<plainA>::value,
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detail::promote_code<plainB>::value,
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A,
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B>::type type;
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};
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// Yes, clear.
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template <class A> struct same_or_not<A, A> {
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typedef A type;
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};
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} // detail
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// PHASE 2 : Perform first the potential array_to_pointer conversion
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template<class A, class B>
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struct return_type_2<other_action<ifthenelsereturn_action>, A, B> {
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typedef typename detail::array_to_pointer<A>::type A1;
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typedef typename detail::array_to_pointer<B>::type B1;
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typedef typename
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boost::add_const<typename detail::same_or_not<A1, B1>::type>::type type;
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};
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// PHASE 1 : Deduction is based on the second and third operand
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// return type specialization for conditional expression ends -----------
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// Specialization of lambda_functor_base for if_then_else_return.
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template<class Args>
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class
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lambda_functor_base<other_action<ifthenelsereturn_action>, Args> {
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public:
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Args args;
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template <class SigArgs> struct sig {
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private:
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typedef typename detail::nth_return_type_sig<1, Args, SigArgs>::type ret1;
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typedef typename detail::nth_return_type_sig<2, Args, SigArgs>::type ret2;
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public:
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typedef typename return_type_2<
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other_action<ifthenelsereturn_action>, ret1, ret2
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>::type type;
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};
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public:
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explicit lambda_functor_base(const Args& a) : args(a) {}
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template<class RET, CALL_TEMPLATE_ARGS>
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RET call(CALL_FORMAL_ARGS) const {
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return (detail::select(boost::tuples::get<0>(args), CALL_ACTUAL_ARGS)) ?
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detail::select(boost::tuples::get<1>(args), CALL_ACTUAL_ARGS)
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:
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detail::select(boost::tuples::get<2>(args), CALL_ACTUAL_ARGS);
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}
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};
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// The code below is from Joel de Guzman, some name changes etc.
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// has been made.
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///////////////////////////////////////////////////////////////////////////////
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//
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// if_then_else_composite
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//
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// This composite has two (2) forms:
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//
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// if_(condition)
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// [
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// statement
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// ]
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//
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// and
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//
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// if_(condition)
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// [
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// true_statement
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// ]
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// .else_
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// [
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// false_statement
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// ]
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//
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// where condition is an lambda_functor that evaluates to bool. If condition
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// is true, the true_statement (again an lambda_functor) is executed
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// otherwise, the false_statement (another lambda_functor) is executed. The
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// result type of this is void. Note the trailing underscore after
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// if_ and the leading dot and the trailing underscore before
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// and after .else_.
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//
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///////////////////////////////////////////////////////////////////////////////
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template <typename CondT, typename ThenT, typename ElseT>
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struct if_then_else_composite {
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typedef if_then_else_composite<CondT, ThenT, ElseT> self_t;
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template <class SigArgs>
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struct sig { typedef void type; };
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if_then_else_composite(
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CondT const& cond_,
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ThenT const& then_,
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ElseT const& else__)
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: cond(cond_), then(then_), else_(else__) {}
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template <class Ret, CALL_TEMPLATE_ARGS>
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Ret call(CALL_FORMAL_ARGS) const
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{
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if (cond.internal_call(CALL_ACTUAL_ARGS))
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then.internal_call(CALL_ACTUAL_ARGS);
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else
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else_.internal_call(CALL_ACTUAL_ARGS);
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}
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CondT cond; ThenT then; ElseT else_; // lambda_functors
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};
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//////////////////////////////////
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template <typename CondT, typename ThenT>
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struct else_gen {
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else_gen(CondT const& cond_, ThenT const& then_)
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: cond(cond_), then(then_) {}
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template <typename ElseT>
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lambda_functor<if_then_else_composite<CondT, ThenT,
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typename as_lambda_functor<ElseT>::type> >
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operator[](ElseT const& else_)
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{
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typedef if_then_else_composite<CondT, ThenT,
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typename as_lambda_functor<ElseT>::type>
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result;
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return result(cond, then, to_lambda_functor(else_));
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}
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CondT cond; ThenT then;
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};
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//////////////////////////////////
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template <typename CondT, typename ThenT>
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struct if_then_composite {
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template <class SigArgs>
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struct sig { typedef void type; };
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if_then_composite(CondT const& cond_, ThenT const& then_)
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: cond(cond_), then(then_), else_(cond, then) {}
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template <class Ret, CALL_TEMPLATE_ARGS>
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Ret call(CALL_FORMAL_ARGS) const
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{
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if (cond.internal_call(CALL_ACTUAL_ARGS))
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then.internal_call(CALL_ACTUAL_ARGS);
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}
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CondT cond; ThenT then; // lambda_functors
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else_gen<CondT, ThenT> else_;
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};
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//////////////////////////////////
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template <typename CondT>
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struct if_gen {
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if_gen(CondT const& cond_)
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: cond(cond_) {}
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template <typename ThenT>
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lambda_functor<if_then_composite<
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typename as_lambda_functor<CondT>::type,
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typename as_lambda_functor<ThenT>::type> >
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operator[](ThenT const& then) const
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{
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typedef if_then_composite<
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typename as_lambda_functor<CondT>::type,
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typename as_lambda_functor<ThenT>::type>
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result;
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|
||
|
return result(
|
||
|
to_lambda_functor(cond),
|
||
|
to_lambda_functor(then));
|
||
|
}
|
||
|
|
||
|
CondT cond;
|
||
|
};
|
||
|
|
||
|
//////////////////////////////////
|
||
|
template <typename CondT>
|
||
|
inline if_gen<CondT>
|
||
|
if_(CondT const& cond)
|
||
|
{
|
||
|
return if_gen<CondT>(cond);
|
||
|
}
|
||
|
|
||
|
|
||
|
|
||
|
} // lambda
|
||
|
} // boost
|
||
|
|
||
|
#endif // BOOST_LAMBDA_IF_HPP
|
||
|
|
||
|
|