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Added boost header

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This commit is contained in:
Christophe Riccio
2012-01-08 01:26:07 +00:00
parent 9c3faaca40
commit c7d752cdf8
8946 changed files with 1732316 additions and 0 deletions
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1377
test/external/boost/lambda/algorithm.hpp vendored Normal file
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// -- bind.hpp -- Boost Lambda Library --------------------------------------
// Copyright (C) 1999-2001 Jaakko Jarvi (jaakko.jarvi@cs.utu.fi)
// Gary Powell (gwpowell@hotmail.com)
//
// 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)
//
// For more information, see http://www.boost.org
#ifndef BOOST_LAMBDA_BIND_HPP
#define BOOST_LAMBDA_BIND_HPP
#include "boost/lambda/core.hpp"
#include "boost/lambda/detail/bind_functions.hpp"
#endif

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// - casts.hpp -- BLambda Library -------------
//
// Copyright (C) 2000 Gary Powell (powellg@amazon.com)
// Copyright (C) 1999, 2000 Jaakko Jarvi (jaakko.jarvi@cs.utu.fi)
//
// 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)
//
// For more information, see http://www.boost.org
// -----------------------------------------------
#if !defined(BOOST_LAMBDA_CASTS_HPP)
#define BOOST_LAMBDA_CASTS_HPP
#include "boost/lambda/detail/suppress_unused.hpp"
#include "boost/lambda/core.hpp"
#include <typeinfo>
namespace boost {
namespace lambda {
template<class Act, class Args>
struct return_type_N;
template<class T> class cast_action;
template<class T> class static_cast_action;
template<class T> class dynamic_cast_action;
template<class T> class const_cast_action;
template<class T> class reinterpret_cast_action;
class typeid_action;
class sizeof_action;
// Cast actions
template<class T> class cast_action<static_cast_action<T> >
{
public:
template<class RET, class Arg1>
static RET apply(Arg1 &a1) {
return static_cast<RET>(a1);
}
};
template<class T> class cast_action<dynamic_cast_action<T> > {
public:
template<class RET, class Arg1>
static RET apply(Arg1 &a1) {
return dynamic_cast<RET>(a1);
}
};
template<class T> class cast_action<const_cast_action<T> > {
public:
template<class RET, class Arg1>
static RET apply(Arg1 &a1) {
return const_cast<RET>(a1);
}
};
template<class T> class cast_action<reinterpret_cast_action<T> > {
public:
template<class RET, class Arg1>
static RET apply(Arg1 &a1) {
return reinterpret_cast<RET>(a1);
}
};
// typeid action
class typeid_action {
public:
template<class RET, class Arg1>
static RET apply(Arg1 &a1) {
detail::suppress_unused_variable_warnings(a1);
return typeid(a1);
}
};
// sizeof action
class sizeof_action
{
public:
template<class RET, class Arg1>
static RET apply(Arg1 &a1) {
return sizeof(a1);
}
};
// return types of casting lambda_functors (all "T" type.)
template<template <class> class cast_type, class T, class A>
struct return_type_N<cast_action< cast_type<T> >, A> {
typedef T type;
};
// return type of typeid_action
template<class A>
struct return_type_N<typeid_action, A> {
typedef std::type_info const & type;
};
// return type of sizeof_action
template<class A>
struct return_type_N<sizeof_action, A> {
typedef std::size_t type;
};
// the four cast & typeid overloads.
// casts can take ordinary variables (not just lambda functors)
// static_cast
template <class T, class Arg1>
inline const lambda_functor<
lambda_functor_base<
action<1, cast_action<static_cast_action<T> > >,
tuple<typename const_copy_argument <const Arg1>::type>
>
>
ll_static_cast(const Arg1& a1) {
return
lambda_functor_base<
action<1, cast_action<static_cast_action<T> > >,
tuple<typename const_copy_argument <const Arg1>::type>
>
( tuple<typename const_copy_argument <const Arg1>::type>(a1));
}
// dynamic_cast
template <class T, class Arg1>
inline const lambda_functor<
lambda_functor_base<
action<1, cast_action<dynamic_cast_action<T> > >,
tuple<typename const_copy_argument <const Arg1>::type>
>
>
ll_dynamic_cast(const Arg1& a1) {
return
lambda_functor_base<
action<1, cast_action<dynamic_cast_action<T> > >,
tuple<typename const_copy_argument <const Arg1>::type>
>
( tuple<typename const_copy_argument <const Arg1>::type>(a1));
}
// const_cast
template <class T, class Arg1>
inline const lambda_functor<
lambda_functor_base<
action<1, cast_action<const_cast_action<T> > >,
tuple<typename const_copy_argument <const Arg1>::type>
>
>
ll_const_cast(const Arg1& a1) {
return
lambda_functor_base<
action<1, cast_action<const_cast_action<T> > >,
tuple<typename const_copy_argument <const Arg1>::type>
>
( tuple<typename const_copy_argument <const Arg1>::type>(a1));
}
// reinterpret_cast
template <class T, class Arg1>
inline const lambda_functor<
lambda_functor_base<
action<1, cast_action<reinterpret_cast_action<T> > >,
tuple<typename const_copy_argument <const Arg1>::type>
>
>
ll_reinterpret_cast(const Arg1& a1) {
return
lambda_functor_base<
action<1, cast_action<reinterpret_cast_action<T> > >,
tuple<typename const_copy_argument <const Arg1>::type>
>
( tuple<typename const_copy_argument <const Arg1>::type>(a1));
}
// typeid
// can be applied to a normal variable as well (can refer to a polymorphic
// class object)
template <class Arg1>
inline const lambda_functor<
lambda_functor_base<
action<1, typeid_action>,
tuple<typename const_copy_argument <const Arg1>::type>
>
>
ll_typeid(const Arg1& a1) {
return
lambda_functor_base<
action<1, typeid_action>,
tuple<typename const_copy_argument <const Arg1>::type>
>
( tuple<typename const_copy_argument <const Arg1>::type>(a1));
}
// sizeof(expression)
// Always takes a lambda expression (if not, built in sizeof will do)
template <class Arg1>
inline const lambda_functor<
lambda_functor_base<
action<1, sizeof_action>,
tuple<lambda_functor<Arg1> >
>
>
ll_sizeof(const lambda_functor<Arg1>& a1) {
return
lambda_functor_base<
action<1, sizeof_action>,
tuple<lambda_functor<Arg1> >
>
( tuple<lambda_functor<Arg1> >(a1));
}
} // namespace lambda
} // namespace boost
#endif

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/*=============================================================================
Adaptable closures
Phoenix V0.9
Copyright (c) 2001-2002 Joel de Guzman
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)
URL: http://spirit.sourceforge.net/
==============================================================================*/
#ifndef PHOENIX_CLOSURES_HPP
#define PHOENIX_CLOSURES_HPP
///////////////////////////////////////////////////////////////////////////////
#include "boost/lambda/core.hpp"
///////////////////////////////////////////////////////////////////////////////
namespace boost {
namespace lambda {
///////////////////////////////////////////////////////////////////////////////
//
// Adaptable closures
//
// The framework will not be complete without some form of closures
// support. Closures encapsulate a stack frame where local
// variables are created upon entering a function and destructed
// upon exiting. Closures provide an environment for local
// variables to reside. Closures can hold heterogeneous types.
//
// Phoenix closures are true hardware stack based closures. At the
// very least, closures enable true reentrancy in lambda functions.
// A closure provides access to a function stack frame where local
// variables reside. Modeled after Pascal nested stack frames,
// closures can be nested just like nested functions where code in
// inner closures may access local variables from in-scope outer
// closures (accessing inner scopes from outer scopes is an error
// and will cause a run-time assertion failure).
//
// There are three (3) interacting classes:
//
// 1) closure:
//
// At the point of declaration, a closure does not yet create a
// stack frame nor instantiate any variables. A closure declaration
// declares the types and names[note] of the local variables. The
// closure class is meant to be subclassed. It is the
// responsibility of a closure subclass to supply the names for
// each of the local variable in the closure. Example:
//
// struct my_closure : closure<int, string, double> {
//
// member1 num; // names the 1st (int) local variable
// member2 message; // names the 2nd (string) local variable
// member3 real; // names the 3rd (double) local variable
// };
//
// my_closure clos;
//
// Now that we have a closure 'clos', its local variables can be
// accessed lazily using the dot notation. Each qualified local
// variable can be used just like any primitive actor (see
// primitives.hpp). Examples:
//
// clos.num = 30
// clos.message = arg1
// clos.real = clos.num * 1e6
//
// The examples above are lazily evaluated. As usual, these
// expressions return composite actors that will be evaluated
// through a second function call invocation (see operators.hpp).
// Each of the members (clos.xxx) is an actor. As such, applying
// the operator() will reveal its identity:
//
// clos.num() // will return the current value of clos.num
//
// *** [note] Acknowledgement: Juan Carlos Arevalo-Baeza (JCAB)
// introduced and initilally implemented the closure member names
// that uses the dot notation.
//
// 2) closure_member
//
// The named local variables of closure 'clos' above are actually
// closure members. The closure_member class is an actor and
// conforms to its conceptual interface. member1..memberN are
// predefined typedefs that correspond to each of the listed types
// in the closure template parameters.
//
// 3) closure_frame
//
// When a closure member is finally evaluated, it should refer to
// an actual instance of the variable in the hardware stack.
// Without doing so, the process is not complete and the evaluated
// member will result to an assertion failure. Remember that the
// closure is just a declaration. The local variables that a
// closure refers to must still be instantiated.
//
// The closure_frame class does the actual instantiation of the
// local variables and links these variables with the closure and
// all its members. There can be multiple instances of
// closure_frames typically situated in the stack inside a
// function. Each closure_frame instance initiates a stack frame
// with a new set of closure local variables. Example:
//
// void foo()
// {
// closure_frame<my_closure> frame(clos);
// /* do something */
// }
//
// where 'clos' is an instance of our closure 'my_closure' above.
// Take note that the usage above precludes locally declared
// classes. If my_closure is a locally declared type, we can still
// use its self_type as a paramater to closure_frame:
//
// closure_frame<my_closure::self_type> frame(clos);
//
// Upon instantiation, the closure_frame links the local variables
// to the closure. The previous link to another closure_frame
// instance created before is saved. Upon destruction, the
// closure_frame unlinks itself from the closure and relinks the
// preceding closure_frame prior to this instance.
//
// The local variables in the closure 'clos' above is default
// constructed in the stack inside function 'foo'. Once 'foo' is
// exited, all of these local variables are destructed. In some
// cases, default construction is not desirable and we need to
// initialize the local closure variables with some values. This
// can be done by passing in the initializers in a compatible
// tuple. A compatible tuple is one with the same number of
// elements as the destination and where each element from the
// destination can be constructed from each corresponding element
// in the source. Example:
//
// tuple<int, char const*, int> init(123, "Hello", 1000);
// closure_frame<my_closure> frame(clos, init);
//
// Here now, our closure_frame's variables are initialized with
// int: 123, char const*: "Hello" and int: 1000.
//
///////////////////////////////////////////////////////////////////////////////
///////////////////////////////////////////////////////////////////////////////
//
// closure_frame class
//
///////////////////////////////////////////////////////////////////////////////
template <typename ClosureT>
class closure_frame : public ClosureT::tuple_t {
public:
closure_frame(ClosureT& clos)
: ClosureT::tuple_t(), save(clos.frame), frame(clos.frame)
{ clos.frame = this; }
template <typename TupleT>
closure_frame(ClosureT& clos, TupleT const& init)
: ClosureT::tuple_t(init), save(clos.frame), frame(clos.frame)
{ clos.frame = this; }
~closure_frame()
{ frame = save; }
private:
closure_frame(closure_frame const&); // no copy
closure_frame& operator=(closure_frame const&); // no assign
closure_frame* save;
closure_frame*& frame;
};
///////////////////////////////////////////////////////////////////////////////
//
// closure_member class
//
///////////////////////////////////////////////////////////////////////////////
template <int N, typename ClosureT>
class closure_member {
public:
typedef typename ClosureT::tuple_t tuple_t;
closure_member()
: frame(ClosureT::closure_frame_ref()) {}
template <typename TupleT>
struct sig {
typedef typename detail::tuple_element_as_reference<
N, typename ClosureT::tuple_t
>::type type;
};
template <class Ret, class A, class B, class C>
// typename detail::tuple_element_as_reference
// <N, typename ClosureT::tuple_t>::type
Ret
call(A&, B&, C&) const
{
assert(frame);
return boost::tuples::get<N>(*frame);
}
private:
typename ClosureT::closure_frame_t*& frame;
};
///////////////////////////////////////////////////////////////////////////////
//
// closure class
//
///////////////////////////////////////////////////////////////////////////////
template <
typename T0 = null_type,
typename T1 = null_type,
typename T2 = null_type,
typename T3 = null_type,
typename T4 = null_type
>
class closure {
public:
typedef tuple<T0, T1, T2, T3, T4> tuple_t;
typedef closure<T0, T1, T2, T3, T4> self_t;
typedef closure_frame<self_t> closure_frame_t;
closure()
: frame(0) { closure_frame_ref(&frame); }
closure_frame_t& context() { assert(frame); return frame; }
closure_frame_t const& context() const { assert(frame); return frame; }
typedef lambda_functor<closure_member<0, self_t> > member1;
typedef lambda_functor<closure_member<1, self_t> > member2;
typedef lambda_functor<closure_member<2, self_t> > member3;
typedef lambda_functor<closure_member<3, self_t> > member4;
typedef lambda_functor<closure_member<4, self_t> > member5;
private:
closure(closure const&); // no copy
closure& operator=(closure const&); // no assign
template <int N, typename ClosureT>
friend class closure_member;
template <typename ClosureT>
friend class closure_frame;
static closure_frame_t*&
closure_frame_ref(closure_frame_t** frame_ = 0)
{
static closure_frame_t** frame = 0;
if (frame_ != 0)
frame = frame_;
return *frame;
}
closure_frame_t* frame;
};
}}
// namespace
#endif

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// - construct.hpp -- Lambda Library -------------
//
// Copyright (C) 2000 Gary Powell (powellg@amazon.com)
// Copyright (C) 1999, 2000 Jaakko Jarvi (jaakko.jarvi@cs.utu.fi)
//
// 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)
//
// For more information, see http://www.boost.org
//
// -----------------------------------------------
#if !defined(BOOST_LAMBDA_CONSTRUCT_HPP)
#define BOOST_LAMBDA_CONSTRUCT_HPP
#include "boost/type_traits/remove_cv.hpp"
#include "boost/type_traits/is_pointer.hpp"
namespace boost {
namespace lambda {
// constructor is used together with bind. constructor<A> creates a bindable
// function object that passes its arguments forward to a constructor call
// of type A
template<class T> struct constructor {
template <class U> struct sig { typedef T type; };
T operator()() const {
return T();
}
template<class A1>
T operator()(A1& a1) const {
return T(a1);
}
template<class A1, class A2>
T operator()(A1& a1, A2& a2) const {
return T(a1, a2);
}
template<class A1, class A2, class A3>
T operator()(A1& a1, A2& a2, A3& a3) const {
return T(a1, a2, a3);
}
template<class A1, class A2, class A3, class A4>
T operator()(A1& a1, A2& a2, A3& a3, A4& a4) const {
return T(a1, a2, a3, a4);
}
template<class A1, class A2, class A3, class A4, class A5>
T operator()(A1& a1, A2& a2, A3& a3, A4& a4, A5& a5) const {
return T(a1, a2, a3, a4, a5);
}
template<class A1, class A2, class A3, class A4, class A5, class A6>
T operator()(A1& a1, A2& a2, A3& a3, A4& a4, A5& a5, A6& a6) const {
return T(a1, a2, a3, a4, a5, a6);
}
template<class A1, class A2, class A3, class A4, class A5, class A6, class A7>
T operator()(A1& a1, A2& a2, A3& a3, A4& a4, A5& a5, A6& a6, A7& a7) const {
return T(a1, a2, a3, a4, a5, a6, a7);
}
template<class A1, class A2, class A3, class A4, class A5, class A6, class A7, class A8>
T operator()(A1& a1, A2& a2, A3& a3, A4& a4, A5& a5, A6& a6, A7& a7, A8& a8) const {
return T(a1, a2, a3, a4, a5, a6, a7, a8);
}
template<class A1, class A2, class A3, class A4, class A5, class A6, class A7, class A8, class A9>
T operator()(A1& a1, A2& a2, A3& a3, A4& a4, A5& a5, A6& a6, A7& a7, A8& a8, A9& a9) const {
return T(a1, a2, a3, a4, a5, a6, a7, a8, a9);
}
template<class A1, class A2, class A3, class A4, class A5, class A6, class A7, class A8, class A9, class A10>
T operator()(A1& a1, A2& a2, A3& a3, A4& a4, A5& a5, A6& a6, A7& a7, A8& a8, A9& a9, A10& a10) const {
return T(a1, a2, a3, a4, a5, a6, a7, a8, a9, a10);
}
};
namespace detail {
// A standard conforming compiler could disambiguate between
// A1* and A1&, but not all compilers do that, so we need the
// helpers
template <bool IsPointer>
struct destructor_helper {
template<class A1>
static void exec(A1& a1) {
// remove all the qualifiers, not sure whether it is necessary
typedef typename boost::remove_cv<A1>::type plainA1;
a1.~plainA1();
}
};
template <>
struct destructor_helper<true> {
template<class A1>
static void exec(A1* a1) {
typedef typename boost::remove_cv<A1>::type plainA1;
(*a1).~plainA1();
}
};
}
// destructor funtion object
struct destructor {
template <class T> struct sig { typedef void type; };
template<class A1>
void operator()(A1& a1) const {
typedef typename boost::remove_cv<A1>::type plainA1;
detail::destructor_helper<boost::is_pointer<plainA1>::value>::exec(a1);
}
};
// new_ptr is used together with bind.
// note: placement new is not supported
template<class T> struct new_ptr {
template <class U> struct sig { typedef T* type; };
T* operator()() const {
return new T();
}
template<class A1>
T* operator()(A1& a1) const {
return new T(a1);
}
template<class A1, class A2>
T* operator()(A1& a1, A2& a2) const {
return new T(a1, a2);
}
template<class A1, class A2, class A3>
T* operator()(A1& a1, A2& a2, A3& a3) const {
return new T(a1, a2, a3);
}
template<class A1, class A2, class A3, class A4>
T* operator()(A1& a1, A2& a2, A3& a3, A4& a4) const {
return new T(a1, a2, a3, a4);
}
template<class A1, class A2, class A3, class A4, class A5>
T* operator()(A1& a1, A2& a2, A3& a3, A4& a4, A5& a5) const {
return new T(a1, a2, a3, a4, a5);
}
template<class A1, class A2, class A3, class A4, class A5, class A6>
T* operator()(A1& a1, A2& a2, A3& a3, A4& a4, A5& a5, A6& a6) const {
return new T(a1, a2, a3, a4, a5, a6);
}
template<class A1, class A2, class A3, class A4, class A5, class A6, class A7>
T* operator()(A1& a1, A2& a2, A3& a3, A4& a4, A5& a5, A6& a6, A7& a7) const {
return new T(a1, a2, a3, a4, a5, a6, a7);
}
template<class A1, class A2, class A3, class A4, class A5, class A6, class A7, class A8>
T* operator()(A1& a1, A2& a2, A3& a3, A4& a4, A5& a5, A6& a6, A7& a7, A8& a8) const {
return new T(a1, a2, a3, a4, a5, a6, a7, a8);
}
template<class A1, class A2, class A3, class A4, class A5, class A6, class A7, class A8, class A9>
T* operator()(A1& a1, A2& a2, A3& a3, A4& a4, A5& a5, A6& a6, A7& a7, A8& a8, A9& a9) const {
return new T(a1, a2, a3, a4, a5, a6, a7, a8, a9);
}
template<class A1, class A2, class A3, class A4, class A5, class A6, class A7, class A8, class A9, class A10>
T* operator()(A1& a1, A2& a2, A3& a3, A4& a4, A5& a5, A6& a6, A7& a7, A8& a8, A9& a9, A10& a10) const {
return new T(a1, a2, a3, a4, a5, a6, a7, a8, a9, a10);
}
};
// delete_ptr return void
struct delete_ptr {
template <class U> struct sig { typedef void type; };
template <class A1>
void operator()(A1& a1) const {
delete a1;
}
};
// new_array is used together with bind.
template<class T> struct new_array {
template <class U> struct sig { typedef T* type; };
T* operator()(int size) const {
return new T[size];
}
};
// delete_ptr return void
struct delete_array {
template <class U> struct sig { typedef void type; };
template <class A1>
void operator()(A1& a1) const {
delete[] a1;
}
};
} // namespace lambda
} // namespace boost
#endif

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// -- control_structures.hpp -- Boost Lambda Library --------------------------
// Copyright (C) 1999, 2000 Jaakko Jarvi (jaakko.jarvi@cs.utu.fi)
//
// 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)
//
// For more information, see www.boost.org
#ifndef BOOST_LAMBDA_CONTROL_STRUCTURES_HPP
#define BOOST_LAMBDA_CONTROL_STRUCTURES_HPP
#include "boost/lambda/core.hpp"
// Arithmetic type promotion needed for if_then_else_return
#include "boost/lambda/detail/operator_actions.hpp"
#include "boost/lambda/detail/operator_return_type_traits.hpp"
#include "boost/lambda/if.hpp"
#include "boost/lambda/loops.hpp"
#endif

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// -- core.hpp -- Boost Lambda Library -------------------------------------
//
// Copyright (C) 2000 Gary Powell (powellg@amazon.com)
// Copyright (C) 1999, 2000 Jaakko Jarvi (jaakko.jarvi@cs.utu.fi)
//
// 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)
//
// For more information, see www.boost.org
//
// Includes the core of LL, without any real features for client:
//
// tuples, lambda functors, return type deduction templates,
// argument substitution mechanism (select functions)
//
// Some functionality comes as well:
// Assignment and subscript operators, as well as function
// call operator for placeholder variables.
// -------------------------------------------------------------------------
#ifndef BOOST_LAMBDA_CORE_HPP
#define BOOST_LAMBDA_CORE_HPP
#include "boost/type_traits/transform_traits.hpp"
#include "boost/type_traits/cv_traits.hpp"
#include "boost/tuple/tuple.hpp"
// inject some of the tuple names into lambda
namespace boost {
namespace lambda {
using ::boost::tuples::tuple;
using ::boost::tuples::null_type;
} // lambda
} // boost
#include "boost/lambda/detail/lambda_config.hpp"
#include "boost/lambda/detail/lambda_fwd.hpp"
#include "boost/lambda/detail/arity_code.hpp"
#include "boost/lambda/detail/actions.hpp"
#include "boost/lambda/detail/lambda_traits.hpp"
#include "boost/lambda/detail/function_adaptors.hpp"
#include "boost/lambda/detail/return_type_traits.hpp"
#include "boost/lambda/detail/select_functions.hpp"
#include "boost/lambda/detail/lambda_functor_base.hpp"
#include "boost/lambda/detail/lambda_functors.hpp"
#include "boost/lambda/detail/ret.hpp"
namespace boost {
namespace lambda {
namespace {
// These are constants types and need to be initialised
boost::lambda::placeholder1_type free1 = boost::lambda::placeholder1_type();
boost::lambda::placeholder2_type free2 = boost::lambda::placeholder2_type();
boost::lambda::placeholder3_type free3 = boost::lambda::placeholder3_type();
boost::lambda::placeholder1_type& _1 = free1;
boost::lambda::placeholder2_type& _2 = free2;
boost::lambda::placeholder3_type& _3 = free3;
// _1, _2, ... naming scheme by Peter Dimov
} // unnamed
} // lambda
} // boost
#endif //BOOST_LAMBDA_CORE_HPP

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// -- Boost Lambda Library - actions.hpp ----------------------------------
// Copyright (C) 1999, 2000 Jaakko Jarvi (jaakko.jarvi@cs.utu.fi)
//
// 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)
// For more information, see www.boost.org
// ----------------------------------------------------------------
#ifndef BOOST_LAMBDA_ACTIONS_HPP
#define BOOST_LAMBDA_ACTIONS_HPP
namespace boost {
namespace lambda {
template<int Arity, class Act> class action;
// these need to be defined here, since the corresponding lambda
// functions are members of lambda_functor classes
class assignment_action {};
class subscript_action {};
template <class Action> class other_action;
// action for specifying the explicit return type
template <class RET> class explicit_return_type_action {};
// action for preventing the expansion of a lambda expression
struct protect_action {};
// must be defined here, comma is a special case
struct comma_action {};
// actions, for which the existence of protect is checked in return type
// deduction.
template <class Action> struct is_protectable {
BOOST_STATIC_CONSTANT(bool, value = false);
};
// NOTE: comma action is protectable. Other protectable actions
// are listed in operator_actions.hpp
template<> struct is_protectable<other_action<comma_action> > {
BOOST_STATIC_CONSTANT(bool, value = true);
};
namespace detail {
// this type is used in return type deductions to signal that deduction
// did not find a result. It does not necessarily mean an error, it commonly
// means that something else should be tried.
class unspecified {};
}
// function action is a special case: bind functions can be called with
// the return type specialized explicitly e.g. bind<int>(foo);
// If this call syntax is used, the return type is stored in the latter
// argument of function_action template. Otherwise the argument gets the type
// 'unspecified'.
// This argument is only relevant in the return type deduction code
template <int I, class Result_type = detail::unspecified>
class function_action {};
template<class T> class function_action<1, T> {
public:
template<class RET, class A1>
static RET apply(A1& a1) {
return function_adaptor<typename boost::remove_cv<A1>::type>::
template apply<RET>(a1);
}
};
template<class T> class function_action<2, T> {
public:
template<class RET, class A1, class A2>
static RET apply(A1& a1, A2& a2) {
return function_adaptor<typename boost::remove_cv<A1>::type>::
template apply<RET>(a1, a2);
}
};
template<class T> class function_action<3, T> {
public:
template<class RET, class A1, class A2, class A3>
static RET apply(A1& a1, A2& a2, A3& a3) {
return function_adaptor<typename boost::remove_cv<A1>::type>::
template apply<RET>(a1, a2, a3);
}
};
template<class T> class function_action<4, T> {
public:
template<class RET, class A1, class A2, class A3, class A4>
static RET apply(A1& a1, A2& a2, A3& a3, A4& a4) {
return function_adaptor<typename boost::remove_cv<A1>::type>::
template apply<RET>(a1, a2, a3, a4);
}
};
template<class T> class function_action<5, T> {
public:
template<class RET, class A1, class A2, class A3, class A4, class A5>
static RET apply(A1& a1, A2& a2, A3& a3, A4& a4, A5& a5) {
return function_adaptor<typename boost::remove_cv<A1>::type>::
template apply<RET>(a1, a2, a3, a4, a5);
}
};
template<class T> class function_action<6, T> {
public:
template<class RET, class A1, class A2, class A3, class A4, class A5,
class A6>
static RET apply(A1& a1, A2& a2, A3& a3, A4& a4, A5& a5, A6& a6) {
return function_adaptor<typename boost::remove_cv<A1>::type>::
template apply<RET>(a1, a2, a3, a4, a5, a6);
}
};
template<class T> class function_action<7, T> {
public:
template<class RET, class A1, class A2, class A3, class A4, class A5,
class A6, class A7>
static RET apply(A1& a1, A2& a2, A3& a3, A4& a4, A5& a5, A6& a6, A7& a7) {
return function_adaptor<typename boost::remove_cv<A1>::type>::
template apply<RET>(a1, a2, a3, a4, a5, a6, a7);
}
};
template<class T> class function_action<8, T> {
public:
template<class RET, class A1, class A2, class A3, class A4, class A5,
class A6, class A7, class A8>
static RET apply(A1& a1, A2& a2, A3& a3, A4& a4, A5& a5, A6& a6, A7& a7,
A8& a8) {
return function_adaptor<typename boost::remove_cv<A1>::type>::
template apply<RET>(a1, a2, a3, a4, a5, a6, a7, a8);
}
};
template<class T> class function_action<9, T> {
public:
template<class RET, class A1, class A2, class A3, class A4, class A5,
class A6, class A7, class A8, class A9>
static RET apply(A1& a1, A2& a2, A3& a3, A4& a4, A5& a5, A6& a6, A7& a7,
A8& a8, A9& a9) {
return function_adaptor<typename boost::remove_cv<A1>::type>::
template apply<RET>(a1, a2, a3, a4, a5, a6, a7, a8, a9);
}
};
template<class T> class function_action<10, T> {
public:
template<class RET, class A1, class A2, class A3, class A4, class A5,
class A6, class A7, class A8, class A9, class A10>
static RET apply(A1& a1, A2& a2, A3& a3, A4& a4, A5& a5, A6& a6, A7& a7,
A8& a8, A9& a9, A10& a10) {
return function_adaptor<typename boost::remove_cv<A1>::type>::
template apply<RET>(a1, a2, a3, a4, a5, a6, a7, a8, a9, a10);
}
};
} // namespace lambda
} // namespace boost
#endif

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// -- Boost Lambda Library -------------------------------------------------
// Copyright (C) 1999, 2000 Jaakko Jarvi (jaakko.jarvi@cs.utu.fi)
//
// 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)
//
// For more information, see www.boost.org
// --------------------------------------------------
#ifndef BOOST_LAMBDA_ARITY_CODE_HPP
#define BOOST_LAMBDA_ARITY_CODE_HPP
#include "boost/type_traits/cv_traits.hpp"
#include "boost/type_traits/transform_traits.hpp"
namespace boost {
namespace lambda {
// These constants state, whether a lambda_functor instantiation results from
// an expression which contains no placeholders (NONE),
// only free1 placeholders (FIRST),
// free2 placeholders and maybe free1 placeholders (SECOND),
// free3 and maybe free1 and free2 placeholders (THIRD),
// freeE placeholders and maybe free1 and free2 (EXCEPTION).
// RETHROW means, that a rethrow expression is used somewhere in the lambda_functor.
enum { NONE = 0x00, // Notice we are using bits as flags here.
FIRST = 0x01,
SECOND = 0x02,
THIRD = 0x04,
EXCEPTION = 0x08,
RETHROW = 0x10};
template<class T>
struct get_tuple_arity;
namespace detail {
template <class T> struct get_arity_;
} // end detail;
template <class T> struct get_arity {
BOOST_STATIC_CONSTANT(int, value = detail::get_arity_<typename boost::remove_cv<typename boost::remove_reference<T>::type>::type>::value);
};
namespace detail {
template<class T>
struct get_arity_ {
BOOST_STATIC_CONSTANT(int, value = 0);
};
template<class T>
struct get_arity_<lambda_functor<T> > {
BOOST_STATIC_CONSTANT(int, value = get_arity<T>::value);
};
template<class Action, class Args>
struct get_arity_<lambda_functor_base<Action, Args> > {
BOOST_STATIC_CONSTANT(int, value = get_tuple_arity<Args>::value);
};
template<int I>
struct get_arity_<placeholder<I> > {
BOOST_STATIC_CONSTANT(int, value = I);
};
} // detail
template<class T>
struct get_tuple_arity {
BOOST_STATIC_CONSTANT(int, value = get_arity<typename T::head_type>::value | get_tuple_arity<typename T::tail_type>::value);
};
template<>
struct get_tuple_arity<null_type> {
BOOST_STATIC_CONSTANT(int, value = 0);
};
// Does T have placeholder<I> as it's subexpression?
template<class T, int I>
struct has_placeholder {
BOOST_STATIC_CONSTANT(bool, value = (get_arity<T>::value & I) != 0);
};
template<int I, int J>
struct includes_placeholder {
BOOST_STATIC_CONSTANT(bool, value = (J & I) != 0);
};
template<int I, int J>
struct lacks_placeholder {
BOOST_STATIC_CONSTANT(bool, value = ((J & I) == 0));
};
} // namespace lambda
} // namespace boost
#endif

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// Boost Lambda Library -- control_constructs_common.hpp -------------------
// Copyright (C) 1999, 2000 Jaakko Jarvi (jaakko.jarvi@cs.utu.fi)
// Copyright (C) 2000 Gary Powell (powellg@amazon.com)
//
// 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)
//
// For more information, see www.boost.org
// --------------------------------------------------------------------------
#if !defined(BOOST_CONTROL_CONSTRUCTS_COMMON_HPP)
#define BOOST_CONTROL_CONSTRUCTS_COMMON_HPP
namespace boost {
namespace lambda {
// special types of lambda functors, used with control structures
// to guarantee that they are composed correctly.
template<class Tag, class LambdaFunctor>
class tagged_lambda_functor;
template<class Tag, class Args>
class tagged_lambda_functor<Tag, lambda_functor<Args> >
: public lambda_functor<Args>
{
public:
tagged_lambda_functor(const Args& a) : lambda_functor<Args>(a) {}
tagged_lambda_functor(const lambda_functor<Args>& a)
: lambda_functor<Args>(a) {}
// for the no body cases in control structures.
tagged_lambda_functor() : lambda_functor<Args>() {}
};
} // lambda
} // boost
#endif // BOOST_CONTROL_CONSTRUCTS_COMMON_HPP

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// Boost Lambda Library - function_adaptors.hpp ----------------------------
// Copyright (C) 1999, 2000 Jaakko Jarvi (jaakko.jarvi@cs.utu.fi)
//
// 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)
//
// For more information, see www.boost.org
#ifndef BOOST_LAMBDA_FUNCTION_ADAPTORS_HPP
#define BOOST_LAMBDA_FUNCTION_ADAPTORS_HPP
#include "boost/mpl/has_xxx.hpp"
#include "boost/tuple/tuple.hpp"
#include "boost/type_traits/same_traits.hpp"
#include "boost/type_traits/remove_reference.hpp"
#include "boost/type_traits/remove_cv.hpp"
#include "boost/type_traits/add_const.hpp"
#include "boost/type_traits/add_volatile.hpp"
#include "boost/utility/result_of.hpp"
namespace boost {
namespace lambda {
namespace detail {
BOOST_MPL_HAS_XXX_TEMPLATE_DEF(sig)
template<class Tuple>
struct remove_references_from_elements {
typedef typename boost::tuples::cons<
typename boost::remove_reference<typename Tuple::head_type>::type,
typename remove_references_from_elements<typename Tuple::tail_type>::type
> type;
};
template<>
struct remove_references_from_elements<boost::tuples::null_type> {
typedef boost::tuples::null_type type;
};
}
template <class Func> struct function_adaptor {
typedef typename detail::remove_reference_and_cv<Func>::type plainF;
#if !defined(BOOST_NO_RESULT_OF)
// Support functors that use the boost::result_of return type convention.
template<class Tuple, int Length, bool HasSig>
struct result_converter;
template<class Tuple, int Length>
struct result_converter<Tuple, Length, true>
: plainF::template sig<
typename detail::remove_references_from_elements<Tuple>::type
>
{};
template<class Tuple>
struct result_converter<Tuple, 0, false>
: result_of<plainF()>
{};
template<class Tuple>
struct result_converter<Tuple, 1, false>
: result_of<plainF(
typename tuples::element<1, Tuple>::type)
>
{};
template<class Tuple>
struct result_converter<Tuple, 2, false>
: result_of<plainF(
typename tuples::element<1, Tuple>::type,
typename tuples::element<2, Tuple>::type)
>
{};
template<class Tuple>
struct result_converter<Tuple, 3, false>
: result_of<plainF(
typename tuples::element<1, Tuple>::type,
typename tuples::element<2, Tuple>::type,
typename tuples::element<3, Tuple>::type)
>
{};
template<class Tuple>
struct result_converter<Tuple, 4, false>
: result_of<plainF(
typename tuples::element<1, Tuple>::type,
typename tuples::element<2, Tuple>::type,
typename tuples::element<3, Tuple>::type,
typename tuples::element<4, Tuple>::type)
>
{};
template<class Tuple>
struct result_converter<Tuple, 5, false>
: result_of<plainF(
typename tuples::element<1, Tuple>::type,
typename tuples::element<2, Tuple>::type,
typename tuples::element<3, Tuple>::type,
typename tuples::element<4, Tuple>::type,
typename tuples::element<5, Tuple>::type)
>
{};
template<class Tuple>
struct result_converter<Tuple, 6, false>
: result_of<plainF(
typename tuples::element<1, Tuple>::type,
typename tuples::element<2, Tuple>::type,
typename tuples::element<3, Tuple>::type,
typename tuples::element<4, Tuple>::type,
typename tuples::element<5, Tuple>::type,
typename tuples::element<6, Tuple>::type)
>
{};
template<class Tuple>
struct result_converter<Tuple, 7, false>
: result_of<plainF(
typename tuples::element<1, Tuple>::type,
typename tuples::element<2, Tuple>::type,
typename tuples::element<3, Tuple>::type,
typename tuples::element<4, Tuple>::type,
typename tuples::element<5, Tuple>::type,
typename tuples::element<6, Tuple>::type,
typename tuples::element<7, Tuple>::type)
>
{};
template<class Tuple>
struct result_converter<Tuple, 8, false>
: result_of<plainF(
typename tuples::element<1, Tuple>::type,
typename tuples::element<2, Tuple>::type,
typename tuples::element<3, Tuple>::type,
typename tuples::element<4, Tuple>::type,
typename tuples::element<5, Tuple>::type,
typename tuples::element<6, Tuple>::type,
typename tuples::element<7, Tuple>::type,
typename tuples::element<8, Tuple>::type)
>
{};
template<class Tuple>
struct result_converter<Tuple, 9, false>
: result_of<plainF(
typename tuples::element<1, Tuple>::type,
typename tuples::element<2, Tuple>::type,
typename tuples::element<3, Tuple>::type,
typename tuples::element<4, Tuple>::type,
typename tuples::element<5, Tuple>::type,
typename tuples::element<6, Tuple>::type,
typename tuples::element<7, Tuple>::type,
typename tuples::element<8, Tuple>::type,
typename tuples::element<9, Tuple>::type)
>
{};
// we do not know the return type off-hand, we must ask it from Func
// To sig we pass a cons list, where the head is the function object type
// itself (potentially cv-qualified)
// and the tail contains the types of the actual arguments to be passed
// to the function object. The arguments can be cv qualified
// as well.
template <class Args>
struct sig
: result_converter<
Args
, tuples::length<typename Args::tail_type>::value
, detail::has_sig<plainF>::value
>
{};
#else // BOOST_NO_RESULT_OF
template <class Args> class sig {
typedef typename detail::remove_reference_and_cv<Func>::type plainF;
public:
typedef typename plainF::template sig<
typename detail::remove_references_from_elements<Args>::type
>::type type;
};
#endif
template<class RET, class A1>
static RET apply(A1& a1) {
return a1();
}
template<class RET, class A1, class A2>
static RET apply(A1& a1, A2& a2) {
return a1(a2);
}
template<class RET, class A1, class A2, class A3>
static RET apply(A1& a1, A2& a2, A3& a3) {
return a1(a2, a3);
}
template<class RET, class A1, class A2, class A3, class A4>
static RET apply(A1& a1, A2& a2, A3& a3, A4& a4) {
return a1(a2, a3, a4);
}
template<class RET, class A1, class A2, class A3, class A4, class A5>
static RET apply(A1& a1, A2& a2, A3& a3, A4& a4, A5& a5) {
return a1(a2, a3, a4, a5);
}
template<class RET, class A1, class A2, class A3, class A4, class A5, class A6>
static RET apply(A1& a1, A2& a2, A3& a3, A4& a4, A5& a5, A6& a6) {
return a1(a2, a3, a4, a5, a6);
}
template<class RET, class A1, class A2, class A3, class A4, class A5, class A6,
class A7>
static RET apply(A1& a1, A2& a2, A3& a3, A4& a4, A5& a5, A6& a6,
A7& a7) {
return a1(a2, a3, a4, a5, a6, a7);
}
template<class RET, class A1, class A2, class A3, class A4, class A5, class A6,
class A7, class A8>
static RET apply(A1& a1, A2& a2, A3& a3, A4& a4, A5& a5, A6& a6,
A7& a7, A8& a8) {
return a1(a2, a3, a4, a5, a6, a7, a8);
}
template<class RET, class A1, class A2, class A3, class A4, class A5, class A6,
class A7, class A8, class A9>
static RET apply(A1& a1, A2& a2, A3& a3, A4& a4, A5& a5, A6& a6,
A7& a7, A8& a8, A9& a9) {
return a1(a2, a3, a4, a5, a6, a7, a8, a9);
}
template<class RET, class A1, class A2, class A3, class A4, class A5, class A6,
class A7, class A8, class A9, class A10>
static RET apply(A1& a1, A2& a2, A3& a3, A4& a4, A5& a5, A6& a6,
A7& a7, A8& a8, A9& a9, A10& a10) {
return a1(a2, a3, a4, a5, a6, a7, a8, a9, a10);
}
};
template <class Func> struct function_adaptor<const Func>; // error
// -- function adaptors with data member access
template <class Object, class T>
struct function_adaptor<T Object::*> {
// typedef detail::unspecified type;
// T can have qualifiers and can be a reference type
// We get the return type by adding const, if the object through which
// the data member is accessed is const, and finally adding a reference
template<class Args> class sig {
typedef typename boost::tuples::element<1, Args>::type argument_type;
typedef typename boost::remove_reference<
argument_type
>::type unref_type;
typedef typename detail::IF<boost::is_const<unref_type>::value,
typename boost::add_const<T>::type,
T
>::RET properly_consted_return_type;
typedef typename detail::IF<boost::is_volatile<unref_type>::value,
typename boost::add_volatile<properly_consted_return_type>::type,
properly_consted_return_type
>::RET properly_cvd_return_type;
public:
typedef typename detail::IF<boost::is_reference<argument_type>::value,
typename boost::add_reference<properly_cvd_return_type>::type,
typename boost::remove_cv<T>::type
>::RET type;
};
template <class RET>
static RET apply( T Object::*data, Object& o) {
return o.*data;
}
template <class RET>
static RET apply( T Object::*data, const Object& o) {
return o.*data;
}
template <class RET>
static RET apply( T Object::*data, volatile Object& o) {
return o.*data;
}
template <class RET>
static RET apply( T Object::*data, const volatile Object& o) {
return o.*data;
}
template <class RET>
static RET apply( T Object::*data, Object* o) {
return o->*data;
}
template <class RET>
static RET apply( T Object::*data, const Object* o) {
return o->*data;
}
template <class RET>
static RET apply( T Object::*data, volatile Object* o) {
return o->*data;
}
template <class RET>
static RET apply( T Object::*data, const volatile Object* o) {
return o->*data;
}
};
// -- function adaptors with 1 argument apply
template <class Result>
struct function_adaptor<Result (void)> {
template<class T> struct sig { typedef Result type; };
template <class RET>
static Result apply(Result (*func)()) {
return func();
}
};
template <class Result>
struct function_adaptor<Result (*)(void)> {
template<class T> struct sig { typedef Result type; };
template <class RET>
static Result apply(Result (*func)()) {
return func();
}
};
// -- function adaptors with 2 argument apply
template <class Object, class Result>
struct function_adaptor<Result (Object::*)() const> {
template<class T> struct sig { typedef Result type; };
template <class RET>
static Result apply( Result (Object::*func)() const, const Object* o) {
return (o->*func)();
}
template <class RET>
static Result apply( Result (Object::*func)() const, const Object& o) {
return (o.*func)();
}
};
template <class Object, class Result>
struct function_adaptor<Result (Object::*)()> {
template<class T> struct sig { typedef Result type; };
template <class RET>
static Result apply( Result (Object::*func)(), Object* o) {
return (o->*func)();
}
template <class RET>
static Result apply( Result (Object::*func)(), Object& o) {
return (o.*func)();
}
};
template <class Arg1, class Result>
struct function_adaptor<Result (Arg1)> {
template<class T> struct sig { typedef Result type; };
template <class RET, class A1>
static Result apply(Result (*func)(Arg1), A1& a1) {
return func(a1);
}
};
template <class Arg1, class Result>
struct function_adaptor<Result (*)(Arg1)> {
template<class T> struct sig { typedef Result type; };
template <class RET, class A1>
static Result apply(Result (*func)(Arg1), A1& a1) {
return func(a1);
}
};
// -- function adaptors with 3 argument apply
template <class Object, class Arg1, class Result>
struct function_adaptor<Result (Object::*)(Arg1) const> {
template<class T> struct sig { typedef Result type; };
template <class RET, class A1>
static Result apply( Result (Object::*func)(Arg1) const, const Object* o,
A1& a1) {
return (o->*func)(a1);
}
template <class RET, class A1>
static Result apply( Result (Object::*func)(Arg1) const, const Object& o,
A1& a1) {
return (o.*func)(a1);
}
};
template <class Object, class Arg1, class Result>
struct function_adaptor<Result (Object::*)(Arg1)> {
template<class T> struct sig { typedef Result type; };
template <class RET, class A1>
static Result apply( Result (Object::*func)(Arg1), Object* o, A1& a1) {
return (o->*func)(a1);
}
template <class RET, class A1>
static Result apply( Result (Object::*func)(Arg1), Object& o, A1& a1) {
return (o.*func)(a1);
}
};
template <class Arg1, class Arg2, class Result>
struct function_adaptor<Result (Arg1, Arg2)> {
template<class T> struct sig { typedef Result type; };
template <class RET, class A1, class A2>
static Result apply(Result (*func)(Arg1, Arg2), A1& a1, A2& a2) {
return func(a1, a2);
}
};
template <class Arg1, class Arg2, class Result>
struct function_adaptor<Result (*)(Arg1, Arg2)> {
template<class T> struct sig { typedef Result type; };
template <class RET, class A1, class A2>
static Result apply(Result (*func)(Arg1, Arg2), A1& a1, A2& a2) {
return func(a1, a2);
}
};
// -- function adaptors with 4 argument apply
template <class Object, class Arg1, class Arg2, class Result>
struct function_adaptor<Result (Object::*)(Arg1, Arg2) const> {
template<class T> struct sig { typedef Result type; };
template <class RET, class A1, class A2>
static Result apply( Result (Object::*func)(Arg1, Arg2) const, const Object* o, A1& a1, A2& a2) {
return (o->*func)(a1, a2);
}
template <class RET, class A1, class A2>
static Result apply( Result (Object::*func)(Arg1, Arg2) const, const Object& o, A1& a1, A2& a2) {
return (o.*func)(a1, a2);
}
};
template <class Object, class Arg1, class Arg2, class Result>
struct function_adaptor<Result (Object::*)(Arg1, Arg2)> {
template<class T> struct sig { typedef Result type; };
template <class RET, class A1, class A2>
static Result apply( Result (Object::*func)(Arg1, Arg2), Object* o, A1& a1, A2& a2) {
return (o->*func)(a1, a2);
}
template <class RET, class A1, class A2>
static Result apply( Result (Object::*func)(Arg1, Arg2), Object& o, A1& a1, A2& a2) {
return (o.*func)(a1, a2);
}
};
template <class Arg1, class Arg2, class Arg3, class Result>
struct function_adaptor<Result (Arg1, Arg2, Arg3)> {
template<class T> struct sig { typedef Result type; };
template <class RET, class A1, class A2, class A3>
static Result apply(Result (*func)(Arg1, Arg2, Arg3), A1& a1, A2& a2, A3& a3) {
return func(a1, a2, a3);
}
};
template <class Arg1, class Arg2, class Arg3, class Result>
struct function_adaptor<Result (*)(Arg1, Arg2, Arg3)> {
template<class T> struct sig { typedef Result type; };
template <class RET, class A1, class A2, class A3>
static Result apply(Result (*func)(Arg1, Arg2, Arg3), A1& a1, A2& a2, A3& a3) {
return func(a1, a2, a3);
}
};
// -- function adaptors with 5 argument apply
template <class Object, class Arg1, class Arg2, class Arg3, class Result>
struct function_adaptor<Result (Object::*)(Arg1, Arg2, Arg3) const> {
template<class T> struct sig { typedef Result type; };
template <class RET, class A1, class A2, class A3>
static Result apply( Result (Object::*func)(Arg1, Arg2, Arg3) const, const Object* o, A1& a1, A2& a2, A3& a3) {
return (o->*func)(a1, a2, a3);
}
template <class RET, class A1, class A2, class A3>
static Result apply( Result (Object::*func)(Arg1, Arg2, Arg3) const, const Object& o, A1& a1, A2& a2, A3& a3) {
return (o.*func)(a1, a2, a3);
}
};
template <class Object, class Arg1, class Arg2, class Arg3, class Result>
struct function_adaptor<Result (Object::*)(Arg1, Arg2, Arg3)> {
template<class T> struct sig { typedef Result type; };
template <class RET, class A1, class A2, class A3>
static Result apply( Result (Object::*func)(Arg1, Arg2, Arg3), Object* o, A1& a1, A2& a2, A3& a3) {
return (o->*func)(a1, a2, a3);
}
template <class RET, class A1, class A2, class A3>
static Result apply( Result (Object::*func)(Arg1, Arg2, Arg3), Object& o, A1& a1, A2& a2, A3& a3) {
return (o.*func)(a1, a2, a3);
}
};
template <class Arg1, class Arg2, class Arg3, class Arg4, class Result>
struct function_adaptor<Result (Arg1, Arg2, Arg3, Arg4)> {
template<class T> struct sig { typedef Result type; };
template <class RET, class A1, class A2, class A3, class A4>
static Result apply(Result (*func)(Arg1, Arg2, Arg3, Arg4), A1& a1, A2& a2, A3& a3, A4& a4) {
return func(a1, a2, a3, a4);
}
};
template <class Arg1, class Arg2, class Arg3, class Arg4, class Result>
struct function_adaptor<Result (*)(Arg1, Arg2, Arg3, Arg4)> {
template<class T> struct sig { typedef Result type; };
template <class RET, class A1, class A2, class A3, class A4>
static Result apply(Result (*func)(Arg1, Arg2, Arg3, Arg4), A1& a1, A2& a2, A3& a3, A4& a4) {
return func(a1, a2, a3, a4);
}
};
// -- function adaptors with 6 argument apply
template <class Object, class Arg1, class Arg2, class Arg3, class Arg4, class Result>
struct function_adaptor<Result (Object::*)(Arg1, Arg2, Arg3, Arg4) const> {
template<class T> struct sig { typedef Result type; };
template <class RET, class A1, class A2, class A3, class A4>
static Result apply( Result (Object::*func)(Arg1, Arg2, Arg3, Arg4) const, const Object* o, A1& a1, A2& a2, A3& a3, A4& a4) {
return (o->*func)(a1, a2, a3, a4);
}
template <class RET, class A1, class A2, class A3, class A4>
static Result apply( Result (Object::*func)(Arg1, Arg2, Arg3, Arg4) const, const Object& o, A1& a1, A2& a2, A3& a3, A4& a4) {
return (o.*func)(a1, a2, a3, a4);
}
};
template <class Object, class Arg1, class Arg2, class Arg3, class Arg4, class Result>
struct function_adaptor<Result (Object::*)(Arg1, Arg2, Arg3, Arg4)> {
template<class T> struct sig { typedef Result type; };
template <class RET, class A1, class A2, class A3, class A4>
static Result apply( Result (Object::*func)(Arg1, Arg2, Arg3, Arg4), Object* o, A1& a1, A2& a2, A3& a3, A4& a4) {
return (o->*func)(a1, a2, a3, a4);
}
template <class RET, class A1, class A2, class A3, class A4>
static Result apply( Result (Object::*func)(Arg1, Arg2, Arg3, Arg4), Object& o, A1& a1, A2& a2, A3& a3, A4& a4) {
return (o.*func)(a1, a2, a3, a4);
}
};
template <class Arg1, class Arg2, class Arg3, class Arg4, class Arg5, class Result>
struct function_adaptor<Result (Arg1, Arg2, Arg3, Arg4, Arg5)> {
template<class T> struct sig { typedef Result type; };
template <class RET, class A1, class A2, class A3, class A4, class A5>
static Result apply(Result (*func)(Arg1, Arg2, Arg3, Arg4, Arg5), A1& a1, A2& a2, A3& a3, A4& a4, A5& a5) {
return func(a1, a2, a3, a4, a5);
}
};
template <class Arg1, class Arg2, class Arg3, class Arg4, class Arg5, class Result>
struct function_adaptor<Result (*)(Arg1, Arg2, Arg3, Arg4, Arg5)> {
template<class T> struct sig { typedef Result type; };
template <class RET, class A1, class A2, class A3, class A4, class A5>
static Result apply(Result (*func)(Arg1, Arg2, Arg3, Arg4, Arg5), A1& a1, A2& a2, A3& a3, A4& a4, A5& a5) {
return func(a1, a2, a3, a4, a5);
}
};
// -- function adaptors with 7 argument apply
template <class Object, class Arg1, class Arg2, class Arg3, class Arg4, class Arg5, class Result>
struct function_adaptor<Result (Object::*)(Arg1, Arg2, Arg3, Arg4, Arg5) const> {
template<class T> struct sig { typedef Result type; };
template <class RET, class A1, class A2, class A3, class A4, class A5>
static Result apply( Result (Object::*func)(Arg1, Arg2, Arg3, Arg4, Arg5) const, const Object* o, A1& a1, A2& a2, A3& a3, A4& a4, A5& a5) {
return (o->*func)(a1, a2, a3, a4, a5);
}
template <class RET, class A1, class A2, class A3, class A4, class A5>
static Result apply( Result (Object::*func)(Arg1, Arg2, Arg3, Arg4, Arg5) const, const Object& o, A1& a1, A2& a2, A3& a3, A4& a4, A5& a5) {
return (o.*func)(a1, a2, a3, a4, a5);
}
};
template <class Object, class Arg1, class Arg2, class Arg3, class Arg4, class Arg5, class Result>
struct function_adaptor<Result (Object::*)(Arg1, Arg2, Arg3, Arg4, Arg5)> {
template<class T> struct sig { typedef Result type; };
template <class RET, class A1, class A2, class A3, class A4, class A5>
static Result apply( Result (Object::*func)(Arg1, Arg2, Arg3, Arg4, Arg5), Object* o, A1& a1, A2& a2, A3& a3, A4& a4, A5& a5) {
return (o->*func)(a1, a2, a3, a4, a5);
}
template <class RET, class A1, class A2, class A3, class A4, class A5>
static Result apply( Result (Object::*func)(Arg1, Arg2, Arg3, Arg4, Arg5), Object& o, A1& a1, A2& a2, A3& a3, A4& a4, A5& a5) {
return (o.*func)(a1, a2, a3, a4, a5);
}
};
template <class Arg1, class Arg2, class Arg3, class Arg4, class Arg5, class Arg6, class Result>
struct function_adaptor<Result (Arg1, Arg2, Arg3, Arg4, Arg5, Arg6)> {
template<class T> struct sig { typedef Result type; };
template <class RET, class A1, class A2, class A3, class A4, class A5, class A6>
static Result apply(Result (*func)(Arg1, Arg2, Arg3, Arg4, Arg5, Arg6), A1& a1, A2& a2, A3& a3, A4& a4, A5& a5, A6& a6) {
return func(a1, a2, a3, a4, a5, a6);
}
};
template <class Arg1, class Arg2, class Arg3, class Arg4, class Arg5, class Arg6, class Result>
struct function_adaptor<Result (*)(Arg1, Arg2, Arg3, Arg4, Arg5, Arg6)> {
template<class T> struct sig { typedef Result type; };
template <class RET, class A1, class A2, class A3, class A4, class A5, class A6>
static Result apply(Result (*func)(Arg1, Arg2, Arg3, Arg4, Arg5, Arg6), A1& a1, A2& a2, A3& a3, A4& a4, A5& a5, A6& a6) {
return func(a1, a2, a3, a4, a5, a6);
}
};
// -- function adaptors with 8 argument apply
template <class Object, class Arg1, class Arg2, class Arg3, class Arg4, class Arg5, class Arg6, class Result>
struct function_adaptor<Result (Object::*)(Arg1, Arg2, Arg3, Arg4, Arg5, Arg6) const> {
template<class T> struct sig { typedef Result type; };
template <class RET, class A1, class A2, class A3, class A4, class A5, class A6>
static Result apply( Result (Object::*func)(Arg1, Arg2, Arg3, Arg4, Arg5, Arg6) const, const Object* o, A1& a1, A2& a2, A3& a3, A4& a4, A5& a5, A6& a6) {
return (o->*func)(a1, a2, a3, a4, a5, a6);
}
template <class RET, class A1, class A2, class A3, class A4, class A5, class A6>
static Result apply( Result (Object::*func)(Arg1, Arg2, Arg3, Arg4, Arg5, Arg6) const, const Object& o, A1& a1, A2& a2, A3& a3, A4& a4, A5& a5, A6& a6) {
return (o.*func)(a1, a2, a3, a4, a5, a6);
}
};
template <class Object, class Arg1, class Arg2, class Arg3, class Arg4, class Arg5, class Arg6, class Result>
struct function_adaptor<Result (Object::*)(Arg1, Arg2, Arg3, Arg4, Arg5, Arg6)> {
template<class T> struct sig { typedef Result type; };
template <class RET, class A1, class A2, class A3, class A4, class A5, class A6>
static Result apply( Result (Object::*func)(Arg1, Arg2, Arg3, Arg4, Arg5, Arg6), Object* o, A1& a1, A2& a2, A3& a3, A4& a4, A5& a5, A6& a6) {
return (o->*func)(a1, a2, a3, a4, a5, a6);
}
template <class RET, class A1, class A2, class A3, class A4, class A5, class A6>
static Result apply( Result (Object::*func)(Arg1, Arg2, Arg3, Arg4, Arg5, Arg6), Object& o, A1& a1, A2& a2, A3& a3, A4& a4, A5& a5, A6& a6) {
return (o.*func)(a1, a2, a3, a4, a5, a6);
}
};
template <class Arg1, class Arg2, class Arg3, class Arg4, class Arg5, class Arg6, class Arg7, class Result>
struct function_adaptor<Result (Arg1, Arg2, Arg3, Arg4, Arg5, Arg6, Arg7)> {
template<class T> struct sig { typedef Result type; };
template <class RET, class A1, class A2, class A3, class A4, class A5, class A6, class A7>
static Result apply(Result (*func)(Arg1, Arg2, Arg3, Arg4, Arg5, Arg6, Arg7), A1& a1, A2& a2, A3& a3, A4& a4, A5& a5, A6& a6, A7& a7) {
return func(a1, a2, a3, a4, a5, a6, a7);
}
};
template <class Arg1, class Arg2, class Arg3, class Arg4, class Arg5, class Arg6, class Arg7, class Result>
struct function_adaptor<Result (*)(Arg1, Arg2, Arg3, Arg4, Arg5, Arg6, Arg7)> {
template<class T> struct sig { typedef Result type; };
template <class RET, class A1, class A2, class A3, class A4, class A5, class A6, class A7>
static Result apply(Result (*func)(Arg1, Arg2, Arg3, Arg4, Arg5, Arg6, Arg7), A1& a1, A2& a2, A3& a3, A4& a4, A5& a5, A6& a6, A7& a7) {
return func(a1, a2, a3, a4, a5, a6, a7);
}
};
// -- function adaptors with 9 argument apply
template <class Object, class Arg1, class Arg2, class Arg3, class Arg4, class Arg5, class Arg6, class Arg7, class Result>
struct function_adaptor<Result (Object::*)(Arg1, Arg2, Arg3, Arg4, Arg5, Arg6, Arg7) const> {
template<class T> struct sig { typedef Result type; };
template <class RET, class A1, class A2, class A3, class A4, class A5, class A6, class A7>
static Result apply( Result (Object::*func)(Arg1, Arg2, Arg3, Arg4, Arg5, Arg6, Arg7) const, const Object* o, A1& a1, A2& a2, A3& a3, A4& a4, A5& a5, A6& a6, A7& a7) {
return (o->*func)(a1, a2, a3, a4, a5, a6, a7);
}
template <class RET, class A1, class A2, class A3, class A4, class A5, class A6, class A7>
static Result apply( Result (Object::*func)(Arg1, Arg2, Arg3, Arg4, Arg5, Arg6, Arg7) const, const Object& o, A1& a1, A2& a2, A3& a3, A4& a4, A5& a5, A6& a6, A7& a7) {
return (o.*func)(a1, a2, a3, a4, a5, a6, a7);
}
};
template <class Object, class Arg1, class Arg2, class Arg3, class Arg4, class Arg5, class Arg6, class Arg7, class Result>
struct function_adaptor<Result (Object::*)(Arg1, Arg2, Arg3, Arg4, Arg5, Arg6, Arg7)> {
template<class T> struct sig { typedef Result type; };
template <class RET, class A1, class A2, class A3, class A4, class A5, class A6, class A7>
static Result apply( Result (Object::*func)(Arg1, Arg2, Arg3, Arg4, Arg5, Arg6, Arg7), Object* o, A1& a1, A2& a2, A3& a3, A4& a4, A5& a5, A6& a6, A7& a7) {
return (o->*func)(a1, a2, a3, a4, a5, a6, a7);
}
template <class RET, class A1, class A2, class A3, class A4, class A5, class A6, class A7>
static Result apply( Result (Object::*func)(Arg1, Arg2, Arg3, Arg4, Arg5, Arg6, Arg7), Object& o, A1& a1, A2& a2, A3& a3, A4& a4, A5& a5, A6& a6, A7& a7) {
return (o.*func)(a1, a2, a3, a4, a5, a6, a7);
}
};
template <class Arg1, class Arg2, class Arg3, class Arg4, class Arg5, class Arg6, class Arg7, class Arg8, class Result>
struct function_adaptor<Result (Arg1, Arg2, Arg3, Arg4, Arg5, Arg6, Arg7, Arg8)> {
template<class T> struct sig { typedef Result type; };
template <class RET, class A1, class A2, class A3, class A4, class A5, class A6, class A7, class A8>
static Result apply(Result (*func)(Arg1, Arg2, Arg3, Arg4, Arg5, Arg6, Arg7, Arg8), A1& a1, A2& a2, A3& a3, A4& a4, A5& a5, A6& a6, A7& a7, A8& a8) {
return func(a1, a2, a3, a4, a5, a6, a7, a8);
}
};
template <class Arg1, class Arg2, class Arg3, class Arg4, class Arg5, class Arg6, class Arg7, class Arg8, class Result>
struct function_adaptor<Result (*)(Arg1, Arg2, Arg3, Arg4, Arg5, Arg6, Arg7, Arg8)> {
template<class T> struct sig { typedef Result type; };
template <class RET, class A1, class A2, class A3, class A4, class A5, class A6, class A7, class A8>
static Result apply(Result (*func)(Arg1, Arg2, Arg3, Arg4, Arg5, Arg6, Arg7, Arg8), A1& a1, A2& a2, A3& a3, A4& a4, A5& a5, A6& a6, A7& a7, A8& a8) {
return func(a1, a2, a3, a4, a5, a6, a7, a8);
}
};
// -- function adaptors with 10 argument apply
template <class Object, class Arg1, class Arg2, class Arg3, class Arg4, class Arg5, class Arg6, class Arg7, class Arg8, class Result>
struct function_adaptor<Result (Object::*)(Arg1, Arg2, Arg3, Arg4, Arg5, Arg6, Arg7, Arg8) const> {
template<class T> struct sig { typedef Result type; };
template <class RET, class A1, class A2, class A3, class A4, class A5, class A6, class A7, class A8>
static Result apply( Result (Object::*func)(Arg1, Arg2, Arg3, Arg4, Arg5, Arg6, Arg7, Arg8) const, const Object* o, A1& a1, A2& a2, A3& a3, A4& a4, A5& a5, A6& a6, A7& a7, A8& a8) {
return (o->*func)(a1, a2, a3, a4, a5, a6, a7, a8);
}
template <class RET, class A1, class A2, class A3, class A4, class A5, class A6, class A7, class A8>
static Result apply( Result (Object::*func)(Arg1, Arg2, Arg3, Arg4, Arg5, Arg6, Arg7, Arg8) const, const Object& o, A1& a1, A2& a2, A3& a3, A4& a4, A5& a5, A6& a6, A7& a7, A8& a8) {
return (o.*func)(a1, a2, a3, a4, a5, a6, a7, a8);
}
};
template <class Object, class Arg1, class Arg2, class Arg3, class Arg4, class Arg5, class Arg6, class Arg7, class Arg8, class Result>
struct function_adaptor<Result (Object::*)(Arg1, Arg2, Arg3, Arg4, Arg5, Arg6, Arg7, Arg8)> {
template<class T> struct sig { typedef Result type; };
template <class RET, class A1, class A2, class A3, class A4, class A5, class A6, class A7, class A8>
static Result apply( Result (Object::*func)(Arg1, Arg2, Arg3, Arg4, Arg5, Arg6, Arg7, Arg8), Object* o, A1& a1, A2& a2, A3& a3, A4& a4, A5& a5, A6& a6, A7& a7, A8& a8) {
return (o->*func)(a1, a2, a3, a4, a5, a6, a7, a8);
}
template <class RET, class A1, class A2, class A3, class A4, class A5, class A6, class A7, class A8>
static Result apply( Result (Object::*func)(Arg1, Arg2, Arg3, Arg4, Arg5, Arg6, Arg7, Arg8), Object& o, A1& a1, A2& a2, A3& a3, A4& a4, A5& a5, A6& a6, A7& a7, A8& a8) {
return (o.*func)(a1, a2, a3, a4, a5, a6, a7, a8);
}
};
template <class Arg1, class Arg2, class Arg3, class Arg4, class Arg5, class Arg6, class Arg7, class Arg8, class Arg9, class Result>
struct function_adaptor<Result (Arg1, Arg2, Arg3, Arg4, Arg5, Arg6, Arg7, Arg8, Arg9)> {
template<class T> struct sig { typedef Result type; };
template <class RET, class A1, class A2, class A3, class A4, class A5, class A6, class A7, class A8, class A9>
static Result apply(Result (*func)(Arg1, Arg2, Arg3, Arg4, Arg5, Arg6, Arg7, Arg8, Arg9), A1& a1, A2& a2, A3& a3, A4& a4, A5& a5, A6& a6, A7& a7, A8& a8, A9& a9) {
return func(a1, a2, a3, a4, a5, a6, a7, a8, a9);
}
};
template <class Arg1, class Arg2, class Arg3, class Arg4, class Arg5, class Arg6, class Arg7, class Arg8, class Arg9, class Result>
struct function_adaptor<Result (*)(Arg1, Arg2, Arg3, Arg4, Arg5, Arg6, Arg7, Arg8, Arg9)> {
template<class T> struct sig { typedef Result type; };
template <class RET, class A1, class A2, class A3, class A4, class A5, class A6, class A7, class A8, class A9>
static Result apply(Result (*func)(Arg1, Arg2, Arg3, Arg4, Arg5, Arg6, Arg7, Arg8, Arg9), A1& a1, A2& a2, A3& a3, A4& a4, A5& a5, A6& a6, A7& a7, A8& a8, A9& a9) {
return func(a1, a2, a3, a4, a5, a6, a7, a8, a9);
}
};
} // namespace lambda
} // namespace boost
#endif

104
test/external/boost/lambda/detail/is_instance_of.hpp vendored Normal file
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@@ -0,0 +1,104 @@
// Boost Lambda Library - is_instance_of.hpp ---------------------
// Copyright (C) 2001 Jaakko Jarvi (jaakko.jarvi@cs.utu.fi)
//
// 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)
//
// For more information, see www.boost.org
// ---------------------------------------------------------------
#ifndef BOOST_LAMBDA_IS_INSTANCE_OF
#define BOOST_LAMBDA_IS_INSTANCE_OF
#include "boost/config.hpp" // for BOOST_STATIC_CONSTANT
#include "boost/type_traits/conversion_traits.hpp" // for is_convertible
#include "boost/preprocessor/enum_shifted_params.hpp"
#include "boost/preprocessor/repeat_2nd.hpp"
// is_instance_of --------------------------------
//
// is_instance_of_n<A, B>::value is true, if type A is
// an instantiation of a template B, or A derives from an instantiation
// of template B
//
// n is the number of template arguments for B
//
// Example:
// is_instance_of_2<std::istream, basic_stream>::value == true
// The original implementation was somewhat different, with different versions
// for different compilers. However, there was still a problem
// with gcc.3.0.2 and 3.0.3 compilers, which didn't think regard
// is_instance_of_N<...>::value was a constant.
// John Maddock suggested the way around this problem by building
// is_instance_of templates using boost::is_convertible.
// Now we only have one version of is_instance_of templates, which delagate
// all the nasty compiler tricks to is_convertible.
#define BOOST_LAMBDA_CLASS(z, N,A) BOOST_PP_COMMA_IF(N) class
#define BOOST_LAMBDA_CLASS_ARG(z, N,A) BOOST_PP_COMMA_IF(N) class A##N
#define BOOST_LAMBDA_ARG(z, N,A) BOOST_PP_COMMA_IF(N) A##N
#define BOOST_LAMBDA_CLASS_LIST(n, NAME) BOOST_PP_REPEAT(n, BOOST_LAMBDA_CLASS, NAME)
#define BOOST_LAMBDA_CLASS_ARG_LIST(n, NAME) BOOST_PP_REPEAT(n, BOOST_LAMBDA_CLASS_ARG, NAME)
#define BOOST_LAMBDA_ARG_LIST(n, NAME) BOOST_PP_REPEAT(n, BOOST_LAMBDA_ARG, NAME)
namespace boost {
namespace lambda {
#define BOOST_LAMBDA_IS_INSTANCE_OF_TEMPLATE(INDEX) \
\
namespace detail { \
\
template <template<BOOST_LAMBDA_CLASS_LIST(INDEX,T)> class F> \
struct BOOST_PP_CAT(conversion_tester_,INDEX) { \
template<BOOST_LAMBDA_CLASS_ARG_LIST(INDEX,A)> \
BOOST_PP_CAT(conversion_tester_,INDEX) \
(const F<BOOST_LAMBDA_ARG_LIST(INDEX,A)>&); \
}; \
\
} /* end detail */ \
\
template <class From, template <BOOST_LAMBDA_CLASS_LIST(INDEX,T)> class To> \
struct BOOST_PP_CAT(is_instance_of_,INDEX) \
{ \
private: \
typedef ::boost::is_convertible< \
From, \
BOOST_PP_CAT(detail::conversion_tester_,INDEX)<To> \
> helper_type; \
\
public: \
BOOST_STATIC_CONSTANT(bool, value = helper_type::value); \
};
#define BOOST_LAMBDA_HELPER(z, N, A) BOOST_LAMBDA_IS_INSTANCE_OF_TEMPLATE( BOOST_PP_INC(N) )
// Generate the traits for 1-4 argument templates
BOOST_PP_REPEAT_2ND(4,BOOST_LAMBDA_HELPER,FOO)
#undef BOOST_LAMBDA_HELPER
#undef BOOST_LAMBDA_IS_INSTANCE_OF_TEMPLATE
#undef BOOST_LAMBDA_CLASS
#undef BOOST_LAMBDA_ARG
#undef BOOST_LAMBDA_CLASS_ARG
#undef BOOST_LAMBDA_CLASS_LIST
#undef BOOST_LAMBDA_ARG_LIST
#undef BOOST_LAMBDA_CLASS_ARG_LIST
} // lambda
} // boost
#endif

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test/external/boost/lambda/detail/lambda_config.hpp vendored Normal file
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// Boost Lambda Library - lambda_config.hpp ------------------------------
// Copyright (C) 1999, 2000 Jaakko Jarvi (jaakko.jarvi@cs.utu.fi)
//
// 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)
//
// For more information, see www.boost.org
// ---------------------------------------------------------------
#ifndef BOOST_LAMBDA_LAMBDA_CONFIG_HPP
#define BOOST_LAMBDA_LAMBDA_CONFIG_HPP
// add to boost/config.hpp
// for now
# if defined __GNUC__
# if (__GNUC__ == 3 && __GNUC_MINOR__ >= 4)
# define BOOST_REF_TO_FUNC_CONFLICTS_WITH_REF_TO_T
# define BOOST_LAMBDA_INCORRECT_BIND_OVERLOADING
# endif
# if (__GNUC__ == 2 && __GNUC_MINOR__ <= 97)
# define BOOST_NO_TEMPLATED_STREAMS
# define BOOST_LAMBDA_INCORRECT_BIND_OVERLOADING
# endif
# if (__GNUC__ == 2 && __GNUC_MINOR__ <= 95)
# define BOOST_LAMBDA_FAILS_IN_TEMPLATE_KEYWORD_AFTER_SCOPE_OPER
# endif
# endif // __GNUC__
#if defined __KCC
#define BOOST_NO_FDECL_TEMPLATES_AS_TEMPLATE_TEMPLATE_PARAMS
#endif // __KCC
#endif

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// Boost Lambda Library lambda_functor_base.hpp -----------------------------
//
// Copyright (C) 1999, 2000 Jaakko Jarvi (jaakko.jarvi@cs.utu.fi)
//
// 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)
//
// For more information, see www.boost.org
// ------------------------------------------------------------
#ifndef BOOST_LAMBDA_LAMBDA_FUNCTOR_BASE_HPP
#define BOOST_LAMBDA_LAMBDA_FUNCTOR_BASE_HPP
#include "boost/type_traits/add_reference.hpp"
#include "boost/type_traits/add_const.hpp"
#include "boost/type_traits/remove_const.hpp"
#include "boost/lambda/detail/lambda_fwd.hpp"
#include "boost/lambda/detail/lambda_traits.hpp"
namespace boost {
namespace lambda {
#if BOOST_WORKAROUND(BOOST_MSVC, >= 1400)
#pragma warning(push)
#pragma warning(disable:4512) //assignment operator could not be generated
#endif
// for return type deductions we wrap bound argument to this class,
// which fulfils the base class contract for lambda_functors
template <class T>
class identity {
T elem;
public:
typedef T element_t;
// take all parameters as const references. Note that non-const references
// stay as they are.
typedef typename boost::add_reference<
typename boost::add_const<T>::type
>::type par_t;
explicit identity(par_t t) : elem(t) {}
template <typename SigArgs>
struct sig { typedef typename boost::remove_const<element_t>::type type; };
template<class RET, CALL_TEMPLATE_ARGS>
RET call(CALL_FORMAL_ARGS) const { CALL_USE_ARGS; return elem; }
};
#if BOOST_WORKAROUND(BOOST_MSVC, >= 1400)
#pragma warning(pop)
#endif
template <class T>
inline lambda_functor<identity<T&> > var(T& t) { return identity<T&>(t); }
// for lambda functors, var is an identity operator. It was forbidden
// at some point, but we might want to var something that can be a
// non-lambda functor or a lambda functor.
template <class T>
lambda_functor<T> var(const lambda_functor<T>& t) { return t; }
template <class T> struct var_type {
typedef lambda_functor<identity<T&> > type;
};
template <class T>
inline
lambda_functor<identity<typename bound_argument_conversion<const T>::type> >
constant(const T& t) {
return identity<typename bound_argument_conversion<const T>::type>(t);
}
template <class T>
lambda_functor<T> constant(const lambda_functor<T>& t) { return t; }
template <class T> struct constant_type {
typedef
lambda_functor<
identity<typename bound_argument_conversion<const T>::type>
> type;
};
template <class T>
inline lambda_functor<identity<const T&> > constant_ref(const T& t) {
return identity<const T&>(t);
}
template <class T>
lambda_functor<T> constant_ref(const lambda_functor<T>& t) { return t; }
template <class T> struct constant_ref_type {
typedef
lambda_functor<identity<const T&> > type;
};
// as_lambda_functor turns any types to lambda functors
// non-lambda_functors will be bound argument types
template <class T>
struct as_lambda_functor {
typedef typename
detail::remove_reference_and_cv<T>::type plain_T;
typedef typename
detail::IF<is_lambda_functor<plain_T>::value,
plain_T,
lambda_functor<
identity<typename bound_argument_conversion<T>::type>
>
>::RET type;
};
// turns arbitrary objects into lambda functors
template <class T>
inline
lambda_functor<identity<typename bound_argument_conversion<const T>::type> >
to_lambda_functor(const T& t) {
return identity<typename bound_argument_conversion<const T>::type>(t);
}
template <class T>
inline lambda_functor<T>
to_lambda_functor(const lambda_functor<T>& t) {
return t;
}
namespace detail {
// In a call constify_rvals<T>::go(x)
// x should be of type T. If T is a non-reference type, do
// returns x as const reference.
// Otherwise the type doesn't change.
// The purpose of this class is to avoid
// 'cannot bind temporaries to non-const references' errors.
template <class T> struct constify_rvals {
template<class U>
static inline const U& go(const U& u) { return u; }
};
template <class T> struct constify_rvals<T&> {
template<class U>
static inline U& go(U& u) { return u; }
};
// check whether one of the elements of a tuple (cons list) is of type
// null_type. Needed, because the compiler goes ahead and instantiates
// sig template for nullary case even if the nullary operator() is not
// called
template <class T> struct is_null_type
{ BOOST_STATIC_CONSTANT(bool, value = false); };
template <> struct is_null_type<null_type>
{ BOOST_STATIC_CONSTANT(bool, value = true); };
template<class Tuple> struct has_null_type {
BOOST_STATIC_CONSTANT(bool, value = (is_null_type<typename Tuple::head_type>::value || has_null_type<typename Tuple::tail_type>::value));
};
template<> struct has_null_type<null_type> {
BOOST_STATIC_CONSTANT(bool, value = false);
};
// helpers -------------------
template<class Args, class SigArgs>
class deduce_argument_types_ {
typedef typename as_lambda_functor<typename Args::head_type>::type lf_t;
typedef typename lf_t::inherited::template sig<SigArgs>::type el_t;
public:
typedef
boost::tuples::cons<
el_t,
typename deduce_argument_types_<typename Args::tail_type, SigArgs>::type
> type;
};
template<class SigArgs>
class deduce_argument_types_<null_type, SigArgs> {
public:
typedef null_type type;
};
// // note that tuples cannot have plain function types as elements.
// // Hence, all other types will be non-const, except references to
// // functions.
// template <class T> struct remove_reference_except_from_functions {
// typedef typename boost::remove_reference<T>::type t;
// typedef typename detail::IF<boost::is_function<t>::value, T, t>::RET type;
// };
template<class Args, class SigArgs>
class deduce_non_ref_argument_types_ {
typedef typename as_lambda_functor<typename Args::head_type>::type lf_t;
typedef typename lf_t::inherited::template sig<SigArgs>::type el_t;
public:
typedef
boost::tuples::cons<
// typename detail::remove_reference_except_from_functions<el_t>::type,
typename boost::remove_reference<el_t>::type,
typename deduce_non_ref_argument_types_<typename Args::tail_type, SigArgs>::type
> type;
};
template<class SigArgs>
class deduce_non_ref_argument_types_<null_type, SigArgs> {
public:
typedef null_type type;
};
// -------------
// take stored Args and Open Args, and return a const list with
// deduced elements (real return types)
template<class Args, class SigArgs>
class deduce_argument_types {
typedef typename deduce_argument_types_<Args, SigArgs>::type t1;
public:
typedef typename detail::IF<
has_null_type<t1>::value, null_type, t1
>::RET type;
};
// take stored Args and Open Args, and return a const list with
// deduced elements (references are stripped from the element types)
template<class Args, class SigArgs>
class deduce_non_ref_argument_types {
typedef typename deduce_non_ref_argument_types_<Args, SigArgs>::type t1;
public:
typedef typename detail::IF<
has_null_type<t1>::value, null_type, t1
>::RET type;
};
template <int N, class Args, class SigArgs>
struct nth_return_type_sig {
typedef typename
as_lambda_functor<
typename boost::tuples::element<N, Args>::type
// typename tuple_element_as_reference<N, Args>::type
>::type lf_type;
typedef typename lf_type::inherited::template sig<SigArgs>::type type;
};
template<int N, class Tuple> struct element_or_null {
typedef typename boost::tuples::element<N, Tuple>::type type;
};
template<int N> struct element_or_null<N, null_type> {
typedef null_type type;
};
} // end detail
// -- lambda_functor base ---------------------
// the explicit_return_type_action case -----------------------------------
template<class RET, class Args>
class lambda_functor_base<explicit_return_type_action<RET>, Args>
{
public:
Args args;
typedef RET result_type;
explicit lambda_functor_base(const Args& a) : args(a) {}
template <class SigArgs> struct sig { typedef RET type; };
template<class RET_, CALL_TEMPLATE_ARGS>
RET call(CALL_FORMAL_ARGS) const
{
return detail::constify_rvals<RET>::go(
detail::r_select<RET>::go(boost::tuples::get<0>(args), CALL_ACTUAL_ARGS));
}
};
// the protect_action case -----------------------------------
template<class Args>
class lambda_functor_base<protect_action, Args>
{
public:
Args args;
public:
explicit lambda_functor_base(const Args& a) : args(a) {}
template<class RET, CALL_TEMPLATE_ARGS>
RET call(CALL_FORMAL_ARGS) const
{
CALL_USE_ARGS;
return boost::tuples::get<0>(args);
}
template<class SigArgs> struct sig {
// typedef typename detail::tuple_element_as_reference<0, SigArgs>::type type;
typedef typename boost::tuples::element<0, Args>::type type;
};
};
// Do nothing --------------------------------------------------------
class do_nothing_action {};
template<class Args>
class lambda_functor_base<do_nothing_action, Args> {
// Args args;
public:
// explicit lambda_functor_base(const Args& a) {}
lambda_functor_base() {}
template<class RET, CALL_TEMPLATE_ARGS> RET call(CALL_FORMAL_ARGS) const {
return CALL_USE_ARGS;
}
template<class SigArgs> struct sig { typedef void type; };
};
// These specializations provide a shorter notation to define actions.
// These lambda_functor_base instances take care of the recursive evaluation
// of the arguments and pass the evaluated arguments to the apply function
// of an action class. To make action X work with these classes, one must
// instantiate the lambda_functor_base as:
// lambda_functor_base<action<ARITY, X>, Args>
// Where ARITY is the arity of the apply function in X
// The return type is queried as:
// return_type_N<X, EvaluatedArgumentTypes>::type
// for which there must be a specialization.
// Function actions, casts, throws,... all go via these classes.
template<class Act, class Args>
class lambda_functor_base<action<0, Act>, Args>
{
public:
// Args args; not needed
explicit lambda_functor_base(const Args& /*a*/) {}
template<class SigArgs> struct sig {
typedef typename return_type_N<Act, null_type>::type type;
};
template<class RET, CALL_TEMPLATE_ARGS>
RET call(CALL_FORMAL_ARGS) const {
CALL_USE_ARGS;
return Act::template apply<RET>();
}
};
#if defined BOOST_LAMBDA_LAMBDA_FUNCTOR_BASE_FIRST_PART
#error "Multiple defines of BOOST_LAMBDA_LAMBDA_FUNCTOR_BASE_FIRST_PART"
#endif
#define BOOST_LAMBDA_LAMBDA_FUNCTOR_BASE_FIRST_PART(ARITY) \
template<class Act, class Args> \
class lambda_functor_base<action<ARITY, Act>, Args> \
{ \
public: \
Args args; \
\
explicit lambda_functor_base(const Args& a) : args(a) {} \
\
template<class SigArgs> struct sig { \
typedef typename \
detail::deduce_argument_types<Args, SigArgs>::type rets_t; \
public: \
typedef typename \
return_type_N_prot<Act, rets_t>::type type; \
}; \
\
\
template<class RET, CALL_TEMPLATE_ARGS> \
RET call(CALL_FORMAL_ARGS) const { \
using boost::tuples::get; \
using detail::constify_rvals; \
using detail::r_select; \
using detail::element_or_null; \
using detail::deduce_argument_types;
BOOST_LAMBDA_LAMBDA_FUNCTOR_BASE_FIRST_PART(1)
typedef typename
deduce_argument_types<Args, tuple<CALL_REFERENCE_TYPES> >::type rets_t;
typedef typename element_or_null<0, rets_t>::type rt0;
return Act::template apply<RET>(
constify_rvals<rt0>::go(r_select<rt0>::go(get<0>(args), CALL_ACTUAL_ARGS))
);
}
};
BOOST_LAMBDA_LAMBDA_FUNCTOR_BASE_FIRST_PART(2)
typedef typename
deduce_argument_types<Args, tuple<CALL_REFERENCE_TYPES> >::type rets_t;
typedef typename element_or_null<0, rets_t>::type rt0;
typedef typename element_or_null<1, rets_t>::type rt1;
return Act::template apply<RET>(
constify_rvals<rt0>::go(r_select<rt0>::go(get<0>(args), CALL_ACTUAL_ARGS)),
constify_rvals<rt1>::go(r_select<rt1>::go(get<1>(args), CALL_ACTUAL_ARGS))
);
}
};
BOOST_LAMBDA_LAMBDA_FUNCTOR_BASE_FIRST_PART(3)
typedef typename
deduce_argument_types<Args, tuple<CALL_REFERENCE_TYPES> >::type rets_t;
typedef typename element_or_null<0, rets_t>::type rt0;
typedef typename element_or_null<1, rets_t>::type rt1;
typedef typename element_or_null<2, rets_t>::type rt2;
return Act::template apply<RET>(
constify_rvals<rt0>::go(r_select<rt0>::go(get<0>(args), CALL_ACTUAL_ARGS)),
constify_rvals<rt1>::go(r_select<rt1>::go(get<1>(args), CALL_ACTUAL_ARGS)),
constify_rvals<rt2>::go(r_select<rt2>::go(get<2>(args), CALL_ACTUAL_ARGS))
);
}
};
BOOST_LAMBDA_LAMBDA_FUNCTOR_BASE_FIRST_PART(4)
typedef typename
deduce_argument_types<Args, tuple<CALL_REFERENCE_TYPES> >::type rets_t;
typedef typename element_or_null<0, rets_t>::type rt0;
typedef typename element_or_null<1, rets_t>::type rt1;
typedef typename element_or_null<2, rets_t>::type rt2;
typedef typename element_or_null<3, rets_t>::type rt3;
return Act::template apply<RET>(
constify_rvals<rt0>::go(r_select<rt0>::go(get<0>(args), CALL_ACTUAL_ARGS)),
constify_rvals<rt1>::go(r_select<rt1>::go(get<1>(args), CALL_ACTUAL_ARGS)),
constify_rvals<rt2>::go(r_select<rt2>::go(get<2>(args), CALL_ACTUAL_ARGS)),
constify_rvals<rt3>::go(r_select<rt3>::go(get<3>(args), CALL_ACTUAL_ARGS))
);
}
};
BOOST_LAMBDA_LAMBDA_FUNCTOR_BASE_FIRST_PART(5)
typedef typename
deduce_argument_types<Args, tuple<CALL_REFERENCE_TYPES> >::type rets_t;
typedef typename element_or_null<0, rets_t>::type rt0;
typedef typename element_or_null<1, rets_t>::type rt1;
typedef typename element_or_null<2, rets_t>::type rt2;
typedef typename element_or_null<3, rets_t>::type rt3;
typedef typename element_or_null<4, rets_t>::type rt4;
return Act::template apply<RET>(
constify_rvals<rt0>::go(r_select<rt0>::go(get<0>(args), CALL_ACTUAL_ARGS)),
constify_rvals<rt1>::go(r_select<rt1>::go(get<1>(args), CALL_ACTUAL_ARGS)),
constify_rvals<rt2>::go(r_select<rt2>::go(get<2>(args), CALL_ACTUAL_ARGS)),
constify_rvals<rt3>::go(r_select<rt3>::go(get<3>(args), CALL_ACTUAL_ARGS)),
constify_rvals<rt4>::go(r_select<rt4>::go(get<4>(args), CALL_ACTUAL_ARGS))
);
}
};
BOOST_LAMBDA_LAMBDA_FUNCTOR_BASE_FIRST_PART(6)
typedef typename
deduce_argument_types<Args, tuple<CALL_REFERENCE_TYPES> >::type rets_t;
typedef typename element_or_null<0, rets_t>::type rt0;
typedef typename element_or_null<1, rets_t>::type rt1;
typedef typename element_or_null<2, rets_t>::type rt2;
typedef typename element_or_null<3, rets_t>::type rt3;
typedef typename element_or_null<4, rets_t>::type rt4;
typedef typename element_or_null<5, rets_t>::type rt5;
return Act::template apply<RET>(
constify_rvals<rt0>::go(r_select<rt0>::go(get<0>(args), CALL_ACTUAL_ARGS)),
constify_rvals<rt1>::go(r_select<rt1>::go(get<1>(args), CALL_ACTUAL_ARGS)),
constify_rvals<rt2>::go(r_select<rt2>::go(get<2>(args), CALL_ACTUAL_ARGS)),
constify_rvals<rt3>::go(r_select<rt3>::go(get<3>(args), CALL_ACTUAL_ARGS)),
constify_rvals<rt4>::go(r_select<rt4>::go(get<4>(args), CALL_ACTUAL_ARGS)),
constify_rvals<rt5>::go(r_select<rt5>::go(get<5>(args), CALL_ACTUAL_ARGS))
);
}
};
BOOST_LAMBDA_LAMBDA_FUNCTOR_BASE_FIRST_PART(7)
typedef typename
deduce_argument_types<Args, tuple<CALL_REFERENCE_TYPES> >::type rets_t;
typedef typename element_or_null<0, rets_t>::type rt0;
typedef typename element_or_null<1, rets_t>::type rt1;
typedef typename element_or_null<2, rets_t>::type rt2;
typedef typename element_or_null<3, rets_t>::type rt3;
typedef typename element_or_null<4, rets_t>::type rt4;
typedef typename element_or_null<5, rets_t>::type rt5;
typedef typename element_or_null<6, rets_t>::type rt6;
return Act::template apply<RET>(
constify_rvals<rt0>::go(r_select<rt0>::go(get<0>(args), CALL_ACTUAL_ARGS)),
constify_rvals<rt1>::go(r_select<rt1>::go(get<1>(args), CALL_ACTUAL_ARGS)),
constify_rvals<rt2>::go(r_select<rt2>::go(get<2>(args), CALL_ACTUAL_ARGS)),
constify_rvals<rt3>::go(r_select<rt3>::go(get<3>(args), CALL_ACTUAL_ARGS)),
constify_rvals<rt4>::go(r_select<rt4>::go(get<4>(args), CALL_ACTUAL_ARGS)),
constify_rvals<rt5>::go(r_select<rt5>::go(get<5>(args), CALL_ACTUAL_ARGS)),
constify_rvals<rt6>::go(r_select<rt6>::go(get<6>(args), CALL_ACTUAL_ARGS))
);
}
};
BOOST_LAMBDA_LAMBDA_FUNCTOR_BASE_FIRST_PART(8)
typedef typename
deduce_argument_types<Args, tuple<CALL_REFERENCE_TYPES> >::type rets_t;
typedef typename element_or_null<0, rets_t>::type rt0;
typedef typename element_or_null<1, rets_t>::type rt1;
typedef typename element_or_null<2, rets_t>::type rt2;
typedef typename element_or_null<3, rets_t>::type rt3;
typedef typename element_or_null<4, rets_t>::type rt4;
typedef typename element_or_null<5, rets_t>::type rt5;
typedef typename element_or_null<6, rets_t>::type rt6;
typedef typename element_or_null<7, rets_t>::type rt7;
return Act::template apply<RET>(
constify_rvals<rt0>::go(r_select<rt0>::go(get<0>(args), CALL_ACTUAL_ARGS)),
constify_rvals<rt1>::go(r_select<rt1>::go(get<1>(args), CALL_ACTUAL_ARGS)),
constify_rvals<rt2>::go(r_select<rt2>::go(get<2>(args), CALL_ACTUAL_ARGS)),
constify_rvals<rt3>::go(r_select<rt3>::go(get<3>(args), CALL_ACTUAL_ARGS)),
constify_rvals<rt4>::go(r_select<rt4>::go(get<4>(args), CALL_ACTUAL_ARGS)),
constify_rvals<rt5>::go(r_select<rt5>::go(get<5>(args), CALL_ACTUAL_ARGS)),
constify_rvals<rt6>::go(r_select<rt6>::go(get<6>(args), CALL_ACTUAL_ARGS)),
constify_rvals<rt7>::go(r_select<rt7>::go(get<7>(args), CALL_ACTUAL_ARGS))
);
}
};
BOOST_LAMBDA_LAMBDA_FUNCTOR_BASE_FIRST_PART(9)
typedef typename
deduce_argument_types<Args, tuple<CALL_REFERENCE_TYPES> >::type rets_t;
typedef typename element_or_null<0, rets_t>::type rt0;
typedef typename element_or_null<1, rets_t>::type rt1;
typedef typename element_or_null<2, rets_t>::type rt2;
typedef typename element_or_null<3, rets_t>::type rt3;
typedef typename element_or_null<4, rets_t>::type rt4;
typedef typename element_or_null<5, rets_t>::type rt5;
typedef typename element_or_null<6, rets_t>::type rt6;
typedef typename element_or_null<7, rets_t>::type rt7;
typedef typename element_or_null<8, rets_t>::type rt8;
return Act::template apply<RET>(
constify_rvals<rt0>::go(r_select<rt0>::go(get<0>(args), CALL_ACTUAL_ARGS)),
constify_rvals<rt1>::go(r_select<rt1>::go(get<1>(args), CALL_ACTUAL_ARGS)),
constify_rvals<rt2>::go(r_select<rt2>::go(get<2>(args), CALL_ACTUAL_ARGS)),
constify_rvals<rt3>::go(r_select<rt3>::go(get<3>(args), CALL_ACTUAL_ARGS)),
constify_rvals<rt4>::go(r_select<rt4>::go(get<4>(args), CALL_ACTUAL_ARGS)),
constify_rvals<rt5>::go(r_select<rt5>::go(get<5>(args), CALL_ACTUAL_ARGS)),
constify_rvals<rt6>::go(r_select<rt6>::go(get<6>(args), CALL_ACTUAL_ARGS)),
constify_rvals<rt7>::go(r_select<rt7>::go(get<7>(args), CALL_ACTUAL_ARGS)),
constify_rvals<rt8>::go(r_select<rt8>::go(get<8>(args), CALL_ACTUAL_ARGS))
);
}
};
BOOST_LAMBDA_LAMBDA_FUNCTOR_BASE_FIRST_PART(10)
typedef typename
deduce_argument_types<Args, tuple<CALL_REFERENCE_TYPES> >::type rets_t;
typedef typename element_or_null<0, rets_t>::type rt0;
typedef typename element_or_null<1, rets_t>::type rt1;
typedef typename element_or_null<2, rets_t>::type rt2;
typedef typename element_or_null<3, rets_t>::type rt3;
typedef typename element_or_null<4, rets_t>::type rt4;
typedef typename element_or_null<5, rets_t>::type rt5;
typedef typename element_or_null<6, rets_t>::type rt6;
typedef typename element_or_null<7, rets_t>::type rt7;
typedef typename element_or_null<8, rets_t>::type rt8;
typedef typename element_or_null<9, rets_t>::type rt9;
return Act::template apply<RET>(
constify_rvals<rt0>::go(r_select<rt0>::go(get<0>(args), CALL_ACTUAL_ARGS)),
constify_rvals<rt1>::go(r_select<rt1>::go(get<1>(args), CALL_ACTUAL_ARGS)),
constify_rvals<rt2>::go(r_select<rt2>::go(get<2>(args), CALL_ACTUAL_ARGS)),
constify_rvals<rt3>::go(r_select<rt3>::go(get<3>(args), CALL_ACTUAL_ARGS)),
constify_rvals<rt4>::go(r_select<rt4>::go(get<4>(args), CALL_ACTUAL_ARGS)),
constify_rvals<rt5>::go(r_select<rt5>::go(get<5>(args), CALL_ACTUAL_ARGS)),
constify_rvals<rt6>::go(r_select<rt6>::go(get<6>(args), CALL_ACTUAL_ARGS)),
constify_rvals<rt7>::go(r_select<rt7>::go(get<7>(args), CALL_ACTUAL_ARGS)),
constify_rvals<rt8>::go(r_select<rt8>::go(get<8>(args), CALL_ACTUAL_ARGS)),
constify_rvals<rt9>::go(r_select<rt9>::go(get<9>(args), CALL_ACTUAL_ARGS))
);
}
};
#undef BOOST_LAMBDA_LAMBDA_FUNCTOR_BASE_FIRST_PART
} // namespace lambda
} // namespace boost
#endif

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// Boost Lambda Library - lambda_functors.hpp -------------------------------
// Copyright (C) 1999, 2000 Jaakko Jarvi (jaakko.jarvi@cs.utu.fi)
//
// 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)
//
// For more information, see http://www.boost.org
// ------------------------------------------------
#ifndef BOOST_LAMBDA_LAMBDA_FUNCTORS_HPP
#define BOOST_LAMBDA_LAMBDA_FUNCTORS_HPP
#include <boost/config.hpp>
#include <boost/detail/workaround.hpp>
#if BOOST_WORKAROUND(BOOST_MSVC, == 1310)
#include <boost/mpl/or.hpp>
#include <boost/utility/enable_if.hpp>
#include <boost/type_traits/is_array.hpp>
#define BOOST_LAMBDA_DISABLE_IF_ARRAY1(A1, R1)\
typename lazy_disable_if<is_array<A1>, typename R1 >::type
#define BOOST_LAMBDA_DISABLE_IF_ARRAY2(A1, A2, R1, R2) \
typename lazy_disable_if<mpl::or_<is_array<A1>, is_array<A2> >, typename R1, R2 >::type
#define BOOST_LAMBDA_DISABLE_IF_ARRAY3(A1, A2, A3, R1, R2, R3) \
typename lazy_disable_if<mpl::or_<is_array<A1>, is_array<A2>, is_array<A3> >, typename R1, R2, R3 >::type
#else
#define BOOST_LAMBDA_DISABLE_IF_ARRAY1(A1, R1) typename R1::type
#define BOOST_LAMBDA_DISABLE_IF_ARRAY2(A1, A2, R1, R2) typename R1, R2::type
#define BOOST_LAMBDA_DISABLE_IF_ARRAY3(A1, A2, A3, R1, R2, R3) typename R1, R2, R3::type
#endif
namespace boost {
namespace lambda {
// -- lambda_functor --------------------------------------------
// --------------------------------------------------------------
//inline const null_type const_null_type() { return null_type(); }
namespace detail {
namespace {
static const null_type constant_null_type = null_type();
} // unnamed
} // detail
class unused {};
#define cnull_type() detail::constant_null_type
// -- free variables types --------------------------------------------------
// helper to work around the case where the nullary return type deduction
// is always performed, even though the functor is not nullary
namespace detail {
template<int N, class Tuple> struct get_element_or_null_type {
typedef typename
detail::tuple_element_as_reference<N, Tuple>::type type;
};
template<int N> struct get_element_or_null_type<N, null_type> {
typedef null_type type;
};
}
template <int I> struct placeholder;
template<> struct placeholder<FIRST> {
template<class SigArgs> struct sig {
typedef typename detail::get_element_or_null_type<0, SigArgs>::type type;
};
template<class RET, CALL_TEMPLATE_ARGS>
RET call(CALL_FORMAL_ARGS) const {
BOOST_STATIC_ASSERT(boost::is_reference<RET>::value);
CALL_USE_ARGS; // does nothing, prevents warnings for unused args
return a;
}
};
template<> struct placeholder<SECOND> {
template<class SigArgs> struct sig {
typedef typename detail::get_element_or_null_type<1, SigArgs>::type type;
};
template<class RET, CALL_TEMPLATE_ARGS>
RET call(CALL_FORMAL_ARGS) const { CALL_USE_ARGS; return b; }
};
template<> struct placeholder<THIRD> {
template<class SigArgs> struct sig {
typedef typename detail::get_element_or_null_type<2, SigArgs>::type type;
};
template<class RET, CALL_TEMPLATE_ARGS>
RET call(CALL_FORMAL_ARGS) const { CALL_USE_ARGS; return c; }
};
template<> struct placeholder<EXCEPTION> {
template<class SigArgs> struct sig {
typedef typename detail::get_element_or_null_type<3, SigArgs>::type type;
};
template<class RET, CALL_TEMPLATE_ARGS>
RET call(CALL_FORMAL_ARGS) const { CALL_USE_ARGS; return env; }
};
typedef const lambda_functor<placeholder<FIRST> > placeholder1_type;
typedef const lambda_functor<placeholder<SECOND> > placeholder2_type;
typedef const lambda_functor<placeholder<THIRD> > placeholder3_type;
///////////////////////////////////////////////////////////////////////////////
// free variables are lambda_functors. This is to allow uniform handling with
// other lambda_functors.
// -------------------------------------------------------------------
#if BOOST_WORKAROUND(BOOST_MSVC, >= 1400)
#pragma warning(push)
#pragma warning(disable:4512) //assignment operator could not be generated
#endif
// -- lambda_functor NONE ------------------------------------------------
template <class T>
class lambda_functor : public T
{
BOOST_STATIC_CONSTANT(int, arity_bits = get_arity<T>::value);
public:
typedef T inherited;
lambda_functor() {}
lambda_functor(const lambda_functor& l) : inherited(l) {}
lambda_functor(const T& t) : inherited(t) {}
template <class SigArgs> struct sig {
typedef typename inherited::template
sig<typename SigArgs::tail_type>::type type;
};
// Note that this return type deduction template is instantiated, even
// if the nullary
// operator() is not called at all. One must make sure that it does not fail.
typedef typename
inherited::template sig<null_type>::type
nullary_return_type;
// Support for boost::result_of.
template <class Sig> struct result;
template <class F>
struct result<F()> {
typedef nullary_return_type type;
};
template <class F, class A>
struct result<F(A)> {
typedef typename sig<tuple<F, A> >::type type;
};
template <class F, class A, class B>
struct result<F(A, B)> {
typedef typename sig<tuple<F, A, B> >::type type;
};
template <class F, class A, class B, class C>
struct result<F(A, B, C)> {
typedef typename sig<tuple<F, A, B, C> >::type type;
};
nullary_return_type operator()() const {
return inherited::template
call<nullary_return_type>
(cnull_type(), cnull_type(), cnull_type(), cnull_type());
}
template<class A>
typename inherited::template sig<tuple<A&> >::type
operator()(A& a) const {
return inherited::template call<
typename inherited::template sig<tuple<A&> >::type
>(a, cnull_type(), cnull_type(), cnull_type());
}
template<class A>
BOOST_LAMBDA_DISABLE_IF_ARRAY1(A, inherited::template sig<tuple<A const&> >)
operator()(A const& a) const {
return inherited::template call<
typename inherited::template sig<tuple<A const&> >::type
>(a, cnull_type(), cnull_type(), cnull_type());
}
template<class A, class B>
typename inherited::template sig<tuple<A&, B&> >::type
operator()(A& a, B& b) const {
return inherited::template call<
typename inherited::template sig<tuple<A&, B&> >::type
>(a, b, cnull_type(), cnull_type());
}
template<class A, class B>
BOOST_LAMBDA_DISABLE_IF_ARRAY2(A, B, inherited::template sig<tuple<A const&, B&> >)
operator()(A const& a, B& b) const {
return inherited::template call<
typename inherited::template sig<tuple<A const&, B&> >::type
>(a, b, cnull_type(), cnull_type());
}
template<class A, class B>
BOOST_LAMBDA_DISABLE_IF_ARRAY2(A, B, inherited::template sig<tuple<A&, B const&> >)
operator()(A& a, B const& b) const {
return inherited::template call<
typename inherited::template sig<tuple<A&, B const&> >::type
>(a, b, cnull_type(), cnull_type());
}
template<class A, class B>
BOOST_LAMBDA_DISABLE_IF_ARRAY2(A, B, inherited::template sig<tuple<A const&, B const&> >)
operator()(A const& a, B const& b) const {
return inherited::template call<
typename inherited::template sig<tuple<A const&, B const&> >::type
>(a, b, cnull_type(), cnull_type());
}
template<class A, class B, class C>
typename inherited::template sig<tuple<A&, B&, C&> >::type
operator()(A& a, B& b, C& c) const
{
return inherited::template call<
typename inherited::template sig<tuple<A&, B&, C&> >::type
>(a, b, c, cnull_type());
}
template<class A, class B, class C>
BOOST_LAMBDA_DISABLE_IF_ARRAY3(A, B, C, inherited::template sig<tuple<A const&, B const&, C const&> >)
operator()(A const& a, B const& b, C const& c) const
{
return inherited::template call<
typename inherited::template sig<tuple<A const&, B const&, C const&> >::type
>(a, b, c, cnull_type());
}
// for internal calls with env
template<CALL_TEMPLATE_ARGS>
typename inherited::template sig<tuple<CALL_REFERENCE_TYPES> >::type
internal_call(CALL_FORMAL_ARGS) const {
return inherited::template
call<typename inherited::template
sig<tuple<CALL_REFERENCE_TYPES> >::type>(CALL_ACTUAL_ARGS);
}
template<class A>
const lambda_functor<lambda_functor_base<
other_action<assignment_action>,
boost::tuple<lambda_functor,
typename const_copy_argument <const A>::type> > >
operator=(const A& a) const {
return lambda_functor_base<
other_action<assignment_action>,
boost::tuple<lambda_functor,
typename const_copy_argument <const A>::type> >
( boost::tuple<lambda_functor,
typename const_copy_argument <const A>::type>(*this, a) );
}
template<class A>
const lambda_functor<lambda_functor_base<
other_action<subscript_action>,
boost::tuple<lambda_functor,
typename const_copy_argument <const A>::type> > >
operator[](const A& a) const {
return lambda_functor_base<
other_action<subscript_action>,
boost::tuple<lambda_functor,
typename const_copy_argument <const A>::type> >
( boost::tuple<lambda_functor,
typename const_copy_argument <const A>::type>(*this, a ) );
}
};
#if BOOST_WORKAROUND(BOOST_MSVC, >= 1400)
#pragma warning(pop)
#endif
} // namespace lambda
} // namespace boost
// is_placeholder
#include <boost/is_placeholder.hpp>
namespace boost
{
template<> struct is_placeholder< lambda::lambda_functor< lambda::placeholder<lambda::FIRST> > >
{
enum _vt { value = 1 };
};
template<> struct is_placeholder< lambda::lambda_functor< lambda::placeholder<lambda::SECOND> > >
{
enum _vt { value = 2 };
};
template<> struct is_placeholder< lambda::lambda_functor< lambda::placeholder<lambda::THIRD> > >
{
enum _vt { value = 3 };
};
} // namespace boost
#endif

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// lambda_fwd.hpp - Boost Lambda Library -------------------------------
// Copyright (C) 1999, 2000 Jaakko Jarvi (jaakko.jarvi@cs.utu.fi)
//
// 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)
//
// For more information, see www.boost.org
// -------------------------------------------------------
#ifndef BOOST_LAMBDA_FWD_HPP
#define BOOST_LAMBDA_FWD_HPP
namespace boost {
namespace lambda {
namespace detail {
template<class T> struct generate_error;
}
// -- placeholders --------------------------------------------
template <int I> struct placeholder;
// function_adaptors
template <class Func>
struct function_adaptor;
template <int I, class Act> class action;
template <class Base>
class lambda_functor;
template <class Act, class Args>
class lambda_functor_base;
} // namespace lambda
} // namespace boost
// #define CALL_TEMPLATE_ARGS class A, class Env
// #define CALL_FORMAL_ARGS A& a, Env& env
// #define CALL_ACTUAL_ARGS a, env
// #define CALL_ACTUAL_ARGS_NO_ENV a
// #define CALL_REFERENCE_TYPES A&, Env&
// #define CALL_PLAIN_TYPES A, Env
#define CALL_TEMPLATE_ARGS class A, class B, class C, class Env
#define CALL_FORMAL_ARGS A& a, B& b, C& c, Env& env
#define CALL_ACTUAL_ARGS a, b, c, env
#define CALL_ACTUAL_ARGS_NO_ENV a, b, c
#define CALL_REFERENCE_TYPES A&, B&, C&, Env&
#define CALL_PLAIN_TYPES A, B, C, Env
namespace boost {
namespace lambda {
namespace detail {
template<class A1, class A2, class A3, class A4>
void do_nothing(A1&, A2&, A3&, A4&) {}
} // detail
} // lambda
} // boost
// prevent the warnings from unused arguments
#define CALL_USE_ARGS \
::boost::lambda::detail::do_nothing(a, b, c, env)
#endif

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// - lambda_traits.hpp --- Boost Lambda Library ----------------------------
//
// Copyright (C) 1999, 2000 Jaakko Jarvi (jaakko.jarvi@cs.utu.fi)
//
// 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)
//
// For more information, see www.boost.org
// -------------------------------------------------------------------------
#ifndef BOOST_LAMBDA_LAMBDA_TRAITS_HPP
#define BOOST_LAMBDA_LAMBDA_TRAITS_HPP
#include "boost/type_traits/transform_traits.hpp"
#include "boost/type_traits/cv_traits.hpp"
#include "boost/type_traits/function_traits.hpp"
#include "boost/type_traits/object_traits.hpp"
#include "boost/tuple/tuple.hpp"
namespace boost {
namespace lambda {
// -- if construct ------------------------------------------------
// Proposed by Krzysztof Czarnecki and Ulrich Eisenecker
namespace detail {
template <bool If, class Then, class Else> struct IF { typedef Then RET; };
template <class Then, class Else> struct IF<false, Then, Else> {
typedef Else RET;
};
// An if construct that doesn't instantiate the non-matching template:
// Called as:
// IF_type<condition, A, B>::type
// The matching template must define the typeded 'type'
// I.e. A::type if condition is true, B::type if condition is false
// Idea from Vesa Karvonen (from C&E as well I guess)
template<class T>
struct IF_type_
{
typedef typename T::type type;
};
template<bool C, class T, class E>
struct IF_type
{
typedef typename
IF_type_<typename IF<C, T, E>::RET >::type type;
};
// helper that can be used to give typedef T to some type
template <class T> struct identity_mapping { typedef T type; };
// An if construct for finding an integral constant 'value'
// Does not instantiate the non-matching branch
// Called as IF_value<condition, A, B>::value
// If condition is true A::value must be defined, otherwise B::value
template<class T>
struct IF_value_
{
BOOST_STATIC_CONSTANT(int, value = T::value);
};
template<bool C, class T, class E>
struct IF_value
{
BOOST_STATIC_CONSTANT(int, value = (IF_value_<typename IF<C, T, E>::RET>::value));
};
// --------------------------------------------------------------
// removes reference from other than function types:
template<class T> class remove_reference_if_valid
{
typedef typename boost::remove_reference<T>::type plainT;
public:
typedef typename IF<
boost::is_function<plainT>::value,
T,
plainT
>::RET type;
};
template<class T> struct remove_reference_and_cv {
typedef typename boost::remove_cv<
typename boost::remove_reference<T>::type
>::type type;
};
// returns a reference to the element of tuple T
template<int N, class T> struct tuple_element_as_reference {
typedef typename
boost::tuples::access_traits<
typename boost::tuples::element<N, T>::type
>::non_const_type type;
};
// returns the cv and reverence stripped type of a tuple element
template<int N, class T> struct tuple_element_stripped {
typedef typename
remove_reference_and_cv<
typename boost::tuples::element<N, T>::type
>::type type;
};
// is_lambda_functor -------------------------------------------------
template <class T> struct is_lambda_functor_ {
BOOST_STATIC_CONSTANT(bool, value = false);
};
template <class Arg> struct is_lambda_functor_<lambda_functor<Arg> > {
BOOST_STATIC_CONSTANT(bool, value = true);
};
} // end detail
template <class T> struct is_lambda_functor {
BOOST_STATIC_CONSTANT(bool,
value =
detail::is_lambda_functor_<
typename detail::remove_reference_and_cv<T>::type
>::value);
};
namespace detail {
// -- parameter_traits_ ---------------------------------------------
// An internal parameter type traits class that respects
// the reference_wrapper class.
// The conversions performed are:
// references -> compile_time_error
// T1 -> T2,
// reference_wrapper<T> -> T&
// const array -> ref to const array
// array -> ref to array
// function -> ref to function
// ------------------------------------------------------------------------
template<class T1, class T2>
struct parameter_traits_ {
typedef T2 type;
};
// Do not instantiate with reference types
template<class T, class Any> struct parameter_traits_<T&, Any> {
typedef typename
generate_error<T&>::
parameter_traits_class_instantiated_with_reference_type type;
};
// Arrays can't be stored as plain types; convert them to references
template<class T, int n, class Any> struct parameter_traits_<T[n], Any> {
typedef T (&type)[n];
};
template<class T, int n, class Any>
struct parameter_traits_<const T[n], Any> {
typedef const T (&type)[n];
};
template<class T, int n, class Any>
struct parameter_traits_<volatile T[n], Any> {
typedef volatile T (&type)[n];
};
template<class T, int n, class Any>
struct parameter_traits_<const volatile T[n], Any> {
typedef const volatile T (&type)[n];
};
template<class T, class Any>
struct parameter_traits_<boost::reference_wrapper<T>, Any >{
typedef T& type;
};
template<class T, class Any>
struct parameter_traits_<const boost::reference_wrapper<T>, Any >{
typedef T& type;
};
template<class T, class Any>
struct parameter_traits_<volatile boost::reference_wrapper<T>, Any >{
typedef T& type;
};
template<class T, class Any>
struct parameter_traits_<const volatile boost::reference_wrapper<T>, Any >{
typedef T& type;
};
template<class Any>
struct parameter_traits_<void, Any> {
typedef void type;
};
template<class Arg, class Any>
struct parameter_traits_<lambda_functor<Arg>, Any > {
typedef lambda_functor<Arg> type;
};
template<class Arg, class Any>
struct parameter_traits_<const lambda_functor<Arg>, Any > {
typedef lambda_functor<Arg> type;
};
// Are the volatile versions needed?
template<class Arg, class Any>
struct parameter_traits_<volatile lambda_functor<Arg>, Any > {
typedef lambda_functor<Arg> type;
};
template<class Arg, class Any>
struct parameter_traits_<const volatile lambda_functor<Arg>, Any > {
typedef lambda_functor<Arg> type;
};
} // end namespace detail
// ------------------------------------------------------------------------
// traits classes for lambda expressions (bind functions, operators ...)
// must be instantiated with non-reference types
// The default is const plain type -------------------------
// const T -> const T,
// T -> const T,
// references -> compile_time_error
// reference_wrapper<T> -> T&
// array -> const ref array
template<class T>
struct const_copy_argument {
typedef typename
detail::parameter_traits_<
T,
typename detail::IF<boost::is_function<T>::value, T&, const T>::RET
>::type type;
};
// T may be a function type. Without the IF test, const would be added
// to a function type, which is illegal.
// all arrays are converted to const.
// This traits template is used for 'const T&' parameter passing
// and thus the knowledge of the potential
// non-constness of an actual argument is lost.
template<class T, int n> struct const_copy_argument <T[n]> {
typedef const T (&type)[n];
};
template<class T, int n> struct const_copy_argument <volatile T[n]> {
typedef const volatile T (&type)[n];
};
template<class T>
struct const_copy_argument<T&> {};
// do not instantiate with references
// typedef typename detail::generate_error<T&>::references_not_allowed type;
template<>
struct const_copy_argument<void> {
typedef void type;
};
// Does the same as const_copy_argument, but passes references through as such
template<class T>
struct bound_argument_conversion {
typedef typename const_copy_argument<T>::type type;
};
template<class T>
struct bound_argument_conversion<T&> {
typedef T& type;
};
// The default is non-const reference -------------------------
// const T -> const T&,
// T -> T&,
// references -> compile_time_error
// reference_wrapper<T> -> T&
template<class T>
struct reference_argument {
typedef typename detail::parameter_traits_<T, T&>::type type;
};
template<class T>
struct reference_argument<T&> {
typedef typename detail::generate_error<T&>::references_not_allowed type;
};
template<class Arg>
struct reference_argument<lambda_functor<Arg> > {
typedef lambda_functor<Arg> type;
};
template<class Arg>
struct reference_argument<const lambda_functor<Arg> > {
typedef lambda_functor<Arg> type;
};
// Are the volatile versions needed?
template<class Arg>
struct reference_argument<volatile lambda_functor<Arg> > {
typedef lambda_functor<Arg> type;
};
template<class Arg>
struct reference_argument<const volatile lambda_functor<Arg> > {
typedef lambda_functor<Arg> type;
};
template<>
struct reference_argument<void> {
typedef void type;
};
namespace detail {
// Array to pointer conversion
template <class T>
struct array_to_pointer {
typedef T type;
};
template <class T, int N>
struct array_to_pointer <const T[N]> {
typedef const T* type;
};
template <class T, int N>
struct array_to_pointer <T[N]> {
typedef T* type;
};
template <class T, int N>
struct array_to_pointer <const T (&) [N]> {
typedef const T* type;
};
template <class T, int N>
struct array_to_pointer <T (&) [N]> {
typedef T* type;
};
// ---------------------------------------------------------------------------
// The call_traits for bind
// Respects the reference_wrapper class.
// These templates are used outside of bind functions as well.
// the bind_tuple_mapper provides a shorter notation for default
// bound argument storing semantics, if all arguments are treated
// uniformly.
// from template<class T> foo(const T& t) : bind_traits<const T>::type
// from template<class T> foo(T& t) : bind_traits<T>::type
// Conversions:
// T -> const T,
// cv T -> cv T,
// T& -> T&
// reference_wrapper<T> -> T&
// const reference_wrapper<T> -> T&
// array -> const ref array
// make bound arguments const, this is a deliberate design choice, the
// purpose is to prevent side effects to bound arguments that are stored
// as copies
template<class T>
struct bind_traits {
typedef const T type;
};
template<class T>
struct bind_traits<T&> {
typedef T& type;
};
// null_types are an exception, we always want to store them as non const
// so that other templates can assume that null_type is always without const
template<>
struct bind_traits<null_type> {
typedef null_type type;
};
// the bind_tuple_mapper, bind_type_generators may
// introduce const to null_type
template<>
struct bind_traits<const null_type> {
typedef null_type type;
};
// Arrays can't be stored as plain types; convert them to references.
// All arrays are converted to const. This is because bind takes its
// parameters as const T& and thus the knowledge of the potential
// non-constness of actual argument is lost.
template<class T, int n> struct bind_traits <T[n]> {
typedef const T (&type)[n];
};
template<class T, int n>
struct bind_traits<const T[n]> {
typedef const T (&type)[n];
};
template<class T, int n> struct bind_traits<volatile T[n]> {
typedef const volatile T (&type)[n];
};
template<class T, int n>
struct bind_traits<const volatile T[n]> {
typedef const volatile T (&type)[n];
};
template<class R>
struct bind_traits<R()> {
typedef R(&type)();
};
template<class R, class Arg1>
struct bind_traits<R(Arg1)> {
typedef R(&type)(Arg1);
};
template<class R, class Arg1, class Arg2>
struct bind_traits<R(Arg1, Arg2)> {
typedef R(&type)(Arg1, Arg2);
};
template<class R, class Arg1, class Arg2, class Arg3>
struct bind_traits<R(Arg1, Arg2, Arg3)> {
typedef R(&type)(Arg1, Arg2, Arg3);
};
template<class R, class Arg1, class Arg2, class Arg3, class Arg4>
struct bind_traits<R(Arg1, Arg2, Arg3, Arg4)> {
typedef R(&type)(Arg1, Arg2, Arg3, Arg4);
};
template<class R, class Arg1, class Arg2, class Arg3, class Arg4, class Arg5>
struct bind_traits<R(Arg1, Arg2, Arg3, Arg4, Arg5)> {
typedef R(&type)(Arg1, Arg2, Arg3, Arg4, Arg5);
};
template<class R, class Arg1, class Arg2, class Arg3, class Arg4, class Arg5, class Arg6>
struct bind_traits<R(Arg1, Arg2, Arg3, Arg4, Arg5, Arg6)> {
typedef R(&type)(Arg1, Arg2, Arg3, Arg4, Arg5, Arg6);
};
template<class R, class Arg1, class Arg2, class Arg3, class Arg4, class Arg5, class Arg6, class Arg7>
struct bind_traits<R(Arg1, Arg2, Arg3, Arg4, Arg5, Arg6, Arg7)> {
typedef R(&type)(Arg1, Arg2, Arg3, Arg4, Arg5, Arg6, Arg7);
};
template<class R, class Arg1, class Arg2, class Arg3, class Arg4, class Arg5, class Arg6, class Arg7, class Arg8>
struct bind_traits<R(Arg1, Arg2, Arg3, Arg4, Arg5, Arg6, Arg7, Arg8)> {
typedef R(&type)(Arg1, Arg2, Arg3, Arg4, Arg5, Arg6, Arg7, Arg8);
};
template<class R, class Arg1, class Arg2, class Arg3, class Arg4, class Arg5, class Arg6, class Arg7, class Arg8, class Arg9>
struct bind_traits<R(Arg1, Arg2, Arg3, Arg4, Arg5, Arg6, Arg7, Arg8, Arg9)> {
typedef R(&type)(Arg1, Arg2, Arg3, Arg4, Arg5, Arg6, Arg7, Arg8, Arg9);
};
template<class T>
struct bind_traits<reference_wrapper<T> >{
typedef T& type;
};
template<class T>
struct bind_traits<const reference_wrapper<T> >{
typedef T& type;
};
template<>
struct bind_traits<void> {
typedef void type;
};
template <
class T0 = null_type, class T1 = null_type, class T2 = null_type,
class T3 = null_type, class T4 = null_type, class T5 = null_type,
class T6 = null_type, class T7 = null_type, class T8 = null_type,
class T9 = null_type
>
struct bind_tuple_mapper {
typedef
tuple<typename bind_traits<T0>::type,
typename bind_traits<T1>::type,
typename bind_traits<T2>::type,
typename bind_traits<T3>::type,
typename bind_traits<T4>::type,
typename bind_traits<T5>::type,
typename bind_traits<T6>::type,
typename bind_traits<T7>::type,
typename bind_traits<T8>::type,
typename bind_traits<T9>::type> type;
};
// bind_traits, except map const T& -> const T
// this is needed e.g. in currying. Const reference arguments can
// refer to temporaries, so it is not safe to store them as references.
template <class T> struct remove_const_reference {
typedef typename bind_traits<T>::type type;
};
template <class T> struct remove_const_reference<const T&> {
typedef const T type;
};
// maps the bind argument types to the resulting lambda functor type
template <
class T0 = null_type, class T1 = null_type, class T2 = null_type,
class T3 = null_type, class T4 = null_type, class T5 = null_type,
class T6 = null_type, class T7 = null_type, class T8 = null_type,
class T9 = null_type
>
class bind_type_generator {
typedef typename
detail::bind_tuple_mapper<
T0, T1, T2, T3, T4, T5, T6, T7, T8, T9
>::type args_t;
BOOST_STATIC_CONSTANT(int, nof_elems = boost::tuples::length<args_t>::value);
typedef
action<
nof_elems,
function_action<nof_elems>
> action_type;
public:
typedef
lambda_functor<
lambda_functor_base<
action_type,
args_t
>
> type;
};
} // detail
template <class T> inline const T& make_const(const T& t) { return t; }
} // end of namespace lambda
} // end of namespace boost
#endif // BOOST_LAMBDA_TRAITS_HPP

737
test/external/boost/lambda/detail/member_ptr.hpp vendored Normal file
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@@ -0,0 +1,737 @@
// Boost Lambda Library -- member_ptr.hpp ---------------------
// Copyright (C) 1999, 2000 Jaakko Jarvi (jaakko.jarvi@cs.utu.fi)
// Copyright (C) 2000 Gary Powell (gary.powell@sierra.com)
//
// 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)
//
// For more information, see www.boost.org
// --------------------------------------------------------------------------
#if !defined(BOOST_LAMBDA_MEMBER_PTR_HPP)
#define BOOST_LAMBDA_MEMBER_PTR_HPP
namespace boost {
namespace lambda {
class member_pointer_action {};
namespace detail {
// the boost type_traits member_pointer traits are not enough,
// need to know more details.
template<class T>
struct member_pointer {
typedef typename boost::add_reference<T>::type type;
typedef detail::unspecified class_type;
typedef detail::unspecified qualified_class_type;
BOOST_STATIC_CONSTANT(bool, is_data_member = false);
BOOST_STATIC_CONSTANT(bool, is_function_member = false);
};
template<class T, class U>
struct member_pointer<T U::*> {
typedef typename boost::add_reference<T>::type type;
typedef U class_type;
typedef U qualified_class_type;
BOOST_STATIC_CONSTANT(bool, is_data_member = true);
BOOST_STATIC_CONSTANT(bool, is_function_member = false);
};
template<class T, class U>
struct member_pointer<const T U::*> {
typedef typename boost::add_reference<const T>::type type;
typedef U class_type;
typedef const U qualified_class_type;
BOOST_STATIC_CONSTANT(bool, is_data_member = true);
BOOST_STATIC_CONSTANT(bool, is_function_member = false);
};
template<class T, class U>
struct member_pointer<volatile T U::*> {
typedef typename boost::add_reference<volatile T>::type type;
typedef U class_type;
typedef volatile U qualified_class_type;
BOOST_STATIC_CONSTANT(bool, is_data_member = true);
BOOST_STATIC_CONSTANT(bool, is_function_member = false);
};
template<class T, class U>
struct member_pointer<const volatile T U::*> {
typedef typename boost::add_reference<const volatile T>::type type;
typedef U class_type;
typedef const volatile U qualified_class_type;
BOOST_STATIC_CONSTANT(bool, is_data_member = true);
BOOST_STATIC_CONSTANT(bool, is_function_member = false);
};
// -- nonconst member functions --
template<class T, class U>
struct member_pointer<T (U::*)()> {
typedef T type;
typedef U class_type;
typedef U qualified_class_type;
BOOST_STATIC_CONSTANT(bool, is_data_member = false);
BOOST_STATIC_CONSTANT(bool, is_function_member = true);
};
template<class T, class U, class A1>
struct member_pointer<T (U::*)(A1)> {
typedef T type;
typedef U class_type;
typedef U qualified_class_type;
BOOST_STATIC_CONSTANT(bool, is_data_member = false);
BOOST_STATIC_CONSTANT(bool, is_function_member = true);
};
template<class T, class U, class A1, class A2>
struct member_pointer<T (U::*)(A1, A2)> {
typedef T type;
typedef U class_type;
typedef U qualified_class_type;
BOOST_STATIC_CONSTANT(bool, is_data_member = false);
BOOST_STATIC_CONSTANT(bool, is_function_member = true);
};
template<class T, class U, class A1, class A2, class A3>
struct member_pointer<T (U::*)(A1, A2, A3)> {
typedef T type;
typedef U class_type;
typedef U qualified_class_type;
BOOST_STATIC_CONSTANT(bool, is_data_member = false);
BOOST_STATIC_CONSTANT(bool, is_function_member = true);
};
template<class T, class U, class A1, class A2, class A3, class A4>
struct member_pointer<T (U::*)(A1, A2, A3, A4)> {
typedef T type;
typedef U class_type;
typedef U qualified_class_type;
BOOST_STATIC_CONSTANT(bool, is_data_member = false);
BOOST_STATIC_CONSTANT(bool, is_function_member = true);
};
template<class T, class U, class A1, class A2, class A3, class A4, class A5>
struct member_pointer<T (U::*)(A1, A2, A3, A4, A5)> {
typedef T type;
typedef U class_type;
typedef U qualified_class_type;
BOOST_STATIC_CONSTANT(bool, is_data_member = false);
BOOST_STATIC_CONSTANT(bool, is_function_member = true);
};
template<class T, class U, class A1, class A2, class A3, class A4, class A5,
class A6>
struct member_pointer<T (U::*)(A1, A2, A3, A4, A5, A6)> {
typedef T type;
typedef U class_type;
typedef U qualified_class_type;
BOOST_STATIC_CONSTANT(bool, is_data_member = false);
BOOST_STATIC_CONSTANT(bool, is_function_member = true);
};
template<class T, class U, class A1, class A2, class A3, class A4, class A5,
class A6, class A7>
struct member_pointer<T (U::*)(A1, A2, A3, A4, A5, A6, A7)> {
typedef T type;
typedef U class_type;
typedef U qualified_class_type;
BOOST_STATIC_CONSTANT(bool, is_data_member = false);
BOOST_STATIC_CONSTANT(bool, is_function_member = true);
};
template<class T, class U, class A1, class A2, class A3, class A4, class A5,
class A6, class A7, class A8>
struct member_pointer<T (U::*)(A1, A2, A3, A4, A5, A6, A7, A8)> {
typedef T type;
typedef U class_type;
typedef U qualified_class_type;
BOOST_STATIC_CONSTANT(bool, is_data_member = false);
BOOST_STATIC_CONSTANT(bool, is_function_member = true);
};
template<class T, class U, class A1, class A2, class A3, class A4, class A5,
class A6, class A7, class A8, class A9>
struct member_pointer<T (U::*)(A1, A2, A3, A4, A5, A6, A7, A8, A9)> {
typedef T type;
typedef U class_type;
typedef U qualified_class_type;
BOOST_STATIC_CONSTANT(bool, is_data_member = false);
BOOST_STATIC_CONSTANT(bool, is_function_member = true);
};
// -- const member functions --
template<class T, class U>
struct member_pointer<T (U::*)() const> {
typedef T type;
typedef U class_type;
typedef const U qualified_class_type;
BOOST_STATIC_CONSTANT(bool, is_data_member = false);
BOOST_STATIC_CONSTANT(bool, is_function_member = true);
};
template<class T, class U, class A1>
struct member_pointer<T (U::*)(A1) const> {
typedef T type;
typedef U class_type;
typedef const U qualified_class_type;
BOOST_STATIC_CONSTANT(bool, is_data_member = false);
BOOST_STATIC_CONSTANT(bool, is_function_member = true);
};
template<class T, class U, class A1, class A2>
struct member_pointer<T (U::*)(A1, A2) const> {
typedef T type;
typedef U class_type;
typedef const U qualified_class_type;
BOOST_STATIC_CONSTANT(bool, is_data_member = false);
BOOST_STATIC_CONSTANT(bool, is_function_member = true);
};
template<class T, class U, class A1, class A2, class A3>
struct member_pointer<T (U::*)(A1, A2, A3) const> {
typedef T type;
typedef U class_type;
typedef const U qualified_class_type;
BOOST_STATIC_CONSTANT(bool, is_data_member = false);
BOOST_STATIC_CONSTANT(bool, is_function_member = true);
};
template<class T, class U, class A1, class A2, class A3, class A4>
struct member_pointer<T (U::*)(A1, A2, A3, A4) const> {
typedef T type;
typedef U class_type;
typedef const U qualified_class_type;
BOOST_STATIC_CONSTANT(bool, is_data_member = false);
BOOST_STATIC_CONSTANT(bool, is_function_member = true);
};
template<class T, class U, class A1, class A2, class A3, class A4, class A5>
struct member_pointer<T (U::*)(A1, A2, A3, A4, A5) const> {
typedef T type;
typedef U class_type;
typedef const U qualified_class_type;
BOOST_STATIC_CONSTANT(bool, is_data_member = false);
BOOST_STATIC_CONSTANT(bool, is_function_member = true);
};
template<class T, class U, class A1, class A2, class A3, class A4, class A5,
class A6>
struct member_pointer<T (U::*)(A1, A2, A3, A4, A5, A6) const> {
typedef T type;
typedef U class_type;
typedef const U qualified_class_type;
BOOST_STATIC_CONSTANT(bool, is_data_member = false);
BOOST_STATIC_CONSTANT(bool, is_function_member = true);
};
template<class T, class U, class A1, class A2, class A3, class A4, class A5,
class A6, class A7>
struct member_pointer<T (U::*)(A1, A2, A3, A4, A5, A6, A7) const> {
typedef T type;
typedef U class_type;
typedef const U qualified_class_type;
BOOST_STATIC_CONSTANT(bool, is_data_member = false);
BOOST_STATIC_CONSTANT(bool, is_function_member = true);
};
template<class T, class U, class A1, class A2, class A3, class A4, class A5,
class A6, class A7, class A8>
struct member_pointer<T (U::*)(A1, A2, A3, A4, A5, A6, A7, A8) const> {
typedef T type;
typedef U class_type;
typedef const U qualified_class_type;
BOOST_STATIC_CONSTANT(bool, is_data_member = false);
BOOST_STATIC_CONSTANT(bool, is_function_member = true);
};
template<class T, class U, class A1, class A2, class A3, class A4, class A5,
class A6, class A7, class A8, class A9>
struct member_pointer<T (U::*)(A1, A2, A3, A4, A5, A6, A7, A8, A9) const> {
typedef T type;
typedef U class_type;
typedef const U qualified_class_type;
BOOST_STATIC_CONSTANT(bool, is_data_member = false);
BOOST_STATIC_CONSTANT(bool, is_function_member = true);
};
// -- volatile --
template<class T, class U>
struct member_pointer<T (U::*)() volatile> {
typedef T type;
typedef U class_type;
typedef volatile U qualified_class_type;
BOOST_STATIC_CONSTANT(bool, is_data_member = false);
BOOST_STATIC_CONSTANT(bool, is_function_member = true);
};
template<class T, class U, class A1>
struct member_pointer<T (U::*)(A1) volatile> {
typedef T type;
typedef U class_type;
typedef volatile U qualified_class_type;
BOOST_STATIC_CONSTANT(bool, is_data_member = false);
BOOST_STATIC_CONSTANT(bool, is_function_member = true);
};
template<class T, class U, class A1, class A2>
struct member_pointer<T (U::*)(A1, A2) volatile> {
typedef T type;
typedef U class_type;
typedef volatile U qualified_class_type;
BOOST_STATIC_CONSTANT(bool, is_data_member = false);
BOOST_STATIC_CONSTANT(bool, is_function_member = true);
};
template<class T, class U, class A1, class A2, class A3>
struct member_pointer<T (U::*)(A1, A2, A3) volatile> {
typedef T type;
typedef U class_type;
typedef volatile U qualified_class_type;
BOOST_STATIC_CONSTANT(bool, is_data_member = false);
BOOST_STATIC_CONSTANT(bool, is_function_member = true);
};
template<class T, class U, class A1, class A2, class A3, class A4>
struct member_pointer<T (U::*)(A1, A2, A3, A4) volatile> {
typedef T type;
typedef U class_type;
typedef volatile U qualified_class_type;
BOOST_STATIC_CONSTANT(bool, is_data_member = false);
BOOST_STATIC_CONSTANT(bool, is_function_member = true);
};
template<class T, class U, class A1, class A2, class A3, class A4, class A5>
struct member_pointer<T (U::*)(A1, A2, A3, A4, A5) volatile> {
typedef T type;
typedef U class_type;
typedef volatile U qualified_class_type;
BOOST_STATIC_CONSTANT(bool, is_data_member = false);
BOOST_STATIC_CONSTANT(bool, is_function_member = true);
};
template<class T, class U, class A1, class A2, class A3, class A4, class A5,
class A6>
struct member_pointer<T (U::*)(A1, A2, A3, A4, A5, A6) volatile> {
typedef T type;
typedef U class_type;
typedef volatile U qualified_class_type;
BOOST_STATIC_CONSTANT(bool, is_data_member = false);
BOOST_STATIC_CONSTANT(bool, is_function_member = true);
};
template<class T, class U, class A1, class A2, class A3, class A4, class A5,
class A6, class A7>
struct member_pointer<T (U::*)(A1, A2, A3, A4, A5, A6, A7) volatile> {
typedef T type;
typedef U class_type;
typedef volatile U qualified_class_type;
BOOST_STATIC_CONSTANT(bool, is_data_member = false);
BOOST_STATIC_CONSTANT(bool, is_function_member = true);
};
template<class T, class U, class A1, class A2, class A3, class A4, class A5,
class A6, class A7, class A8>
struct member_pointer<T (U::*)(A1, A2, A3, A4, A5, A6, A7, A8) volatile> {
typedef T type;
typedef U class_type;
typedef volatile U qualified_class_type;
BOOST_STATIC_CONSTANT(bool, is_data_member = false);
BOOST_STATIC_CONSTANT(bool, is_function_member = true);
};
template<class T, class U, class A1, class A2, class A3, class A4, class A5,
class A6, class A7, class A8, class A9>
struct member_pointer<T (U::*)(A1, A2, A3, A4, A5, A6, A7, A8, A9) volatile> {
typedef T type;
typedef U class_type;
typedef volatile U qualified_class_type;
BOOST_STATIC_CONSTANT(bool, is_data_member = false);
BOOST_STATIC_CONSTANT(bool, is_function_member = true);
};
// -- const volatile
template<class T, class U>
struct member_pointer<T (U::*)() const volatile> {
typedef T type;
typedef U class_type;
typedef const volatile U qualified_class_type;
BOOST_STATIC_CONSTANT(bool, is_data_member = false);
BOOST_STATIC_CONSTANT(bool, is_function_member = true);
};
template<class T, class U, class A1>
struct member_pointer<T (U::*)(A1) const volatile> {
typedef T type;
typedef U class_type;
typedef const volatile U qualified_class_type;
BOOST_STATIC_CONSTANT(bool, is_data_member = false);
BOOST_STATIC_CONSTANT(bool, is_function_member = true);
};
template<class T, class U, class A1, class A2>
struct member_pointer<T (U::*)(A1, A2) const volatile> {
typedef T type;
typedef U class_type;
typedef const volatile U qualified_class_type;
BOOST_STATIC_CONSTANT(bool, is_data_member = false);
BOOST_STATIC_CONSTANT(bool, is_function_member = true);
};
template<class T, class U, class A1, class A2, class A3>
struct member_pointer<T (U::*)(A1, A2, A3) const volatile> {
typedef T type;
typedef U class_type;
typedef const volatile U qualified_class_type;
BOOST_STATIC_CONSTANT(bool, is_data_member = false);
BOOST_STATIC_CONSTANT(bool, is_function_member = true);
};
template<class T, class U, class A1, class A2, class A3, class A4>
struct member_pointer<T (U::*)(A1, A2, A3, A4) const volatile> {
typedef T type;
typedef U class_type;
typedef const volatile U qualified_class_type;
};
template<class T, class U, class A1, class A2, class A3, class A4, class A5>
struct member_pointer<T (U::*)(A1, A2, A3, A4, A5) const volatile> {
typedef T type;
typedef U class_type;
typedef const volatile U qualified_class_type;
BOOST_STATIC_CONSTANT(bool, is_data_member = false);
BOOST_STATIC_CONSTANT(bool, is_function_member = true);
};
template<class T, class U, class A1, class A2, class A3, class A4, class A5,
class A6>
struct member_pointer<T (U::*)(A1, A2, A3, A4, A5, A6) const volatile> {
typedef T type;
typedef U class_type;
typedef const volatile U qualified_class_type;
BOOST_STATIC_CONSTANT(bool, is_data_member = false);
BOOST_STATIC_CONSTANT(bool, is_function_member = true);
};
template<class T, class U, class A1, class A2, class A3, class A4, class A5,
class A6, class A7>
struct member_pointer<T (U::*)(A1, A2, A3, A4, A5, A6, A7) const volatile> {
typedef T type;
typedef U class_type;
typedef const volatile U qualified_class_type;
BOOST_STATIC_CONSTANT(bool, is_data_member = false);
BOOST_STATIC_CONSTANT(bool, is_function_member = true);
};
template<class T, class U, class A1, class A2, class A3, class A4, class A5,
class A6, class A7, class A8>
struct member_pointer<T (U::*)(A1, A2, A3, A4, A5, A6, A7, A8) const volatile> {
typedef T type;
typedef U class_type;
typedef const volatile U qualified_class_type;
BOOST_STATIC_CONSTANT(bool, is_data_member = false);
BOOST_STATIC_CONSTANT(bool, is_function_member = true);
};
template<class T, class U, class A1, class A2, class A3, class A4, class A5,
class A6, class A7, class A8, class A9>
struct member_pointer<T (U::*)(A1, A2, A3, A4, A5, A6, A7, A8, A9) const volatile> {
typedef T type;
typedef U class_type;
typedef const volatile U qualified_class_type;
BOOST_STATIC_CONSTANT(bool, is_data_member = false);
BOOST_STATIC_CONSTANT(bool, is_function_member = true);
};
} // detail
namespace detail {
// this class holds a pointer to a member function and the object.
// when called, it just calls the member function with the parameters
// provided
// It would have been possible to use existing lambda_functors to represent
// a bound member function like this, but to have a separate template is
// safer, since now this functor doesn't mix and match with lambda_functors
// only thing you can do with this is to call it
// note that previously instantiated classes
// (other_action<member_pointer_action> and member_pointer_action_helper
// guarantee, that A and B are
// such types, that for objects a and b of corresponding types, a->*b leads
// to the builtin ->* to be called. So types that would end in a call to
// a user defined ->* do not create a member_pointer_caller object.
template<class RET, class A, class B>
class member_pointer_caller {
A a; B b;
public:
member_pointer_caller(const A& aa, const B& bb) : a(aa), b(bb) {}
RET operator()() const { return (a->*b)(); }
template<class A1>
RET operator()(const A1& a1) const { return (a->*b)(a1); }
template<class A1, class A2>
RET operator()(const A1& a1, const A2& a2) const { return (a->*b)(a1, a2); }
template<class A1, class A2, class A3>
RET operator()(const A1& a1, const A2& a2, const A3& a3) const {
return (a->*b)(a1, a2, a3);
}
template<class A1, class A2, class A3, class A4>
RET operator()(const A1& a1, const A2& a2, const A3& a3,
const A4& a4) const {
return (a->*b)(a1, a2, a3, a4);
}
template<class A1, class A2, class A3, class A4, class A5>
RET operator()(const A1& a1, const A2& a2, const A3& a3, const A4& a4,
const A5& a5) const {
return (a->*b)(a1, a2, a3, a4, a5);
}
template<class A1, class A2, class A3, class A4, class A5, class A6>
RET operator()(const A1& a1, const A2& a2, const A3& a3, const A4& a4,
const A5& a5, const A6& a6) const {
return (a->*b)(a1, a2, a3, a4, a5, a6);
}
template<class A1, class A2, class A3, class A4, class A5, class A6,
class A7>
RET operator()(const A1& a1, const A2& a2, const A3& a3, const A4& a4,
const A5& a5, const A6& a6, const A7& a7) const {
return (a->*b)(a1, a2, a3, a4, a5, a6, a7);
}
template<class A1, class A2, class A3, class A4, class A5, class A6,
class A7, class A8>
RET operator()(const A1& a1, const A2& a2, const A3& a3, const A4& a4,
const A5& a5, const A6& a6, const A7& a7,
const A8& a8) const {
return (a->*b)(a1, a2, a3, a4, a5, a6, a7, a8);
}
template<class A1, class A2, class A3, class A4, class A5, class A6,
class A7, class A8, class A9>
RET operator()(const A1& a1, const A2& a2, const A3& a3, const A4& a4,
const A5& a5, const A6& a6, const A7& a7,
const A8& a8, const A9& a9) const {
return (a->*b)(a1, a2, a3, a4, a5, a6, a7, a8, a9);
}
};
// helper templates for return type deduction and action classes
// different cases for data member, function member, neither
// true-true case
template <bool Is_data_member, bool Is_function_member>
struct member_pointer_action_helper;
// cannot be both, no body provided
// data member case
// this means, that B is a data member and A is a pointer type,
// so either built-in ->* should be called, or there is an error
template <>
struct member_pointer_action_helper<true, false> {
public:
template<class RET, class A, class B>
static RET apply(A& a, B& b) {
return a->*b;
}
template<class A, class B>
struct return_type {
private:
typedef typename detail::remove_reference_and_cv<B>::type plainB;
typedef typename detail::member_pointer<plainB>::type type0;
// we remove the reference now, as we may have to add cv:s
typedef typename boost::remove_reference<type0>::type type1;
// A is a reference to pointer
// remove the top level cv qualifiers and reference
typedef typename
detail::remove_reference_and_cv<A>::type non_ref_A;
// A is a pointer type, so take the type pointed to
typedef typename ::boost::remove_pointer<non_ref_A>::type non_pointer_A;
public:
// For non-reference types, we must add const and/or volatile if
// the pointer type has these qualifiers
// If the member is a reference, these do not have any effect
// (cv T == T if T is a reference type)
typedef typename detail::IF<
::boost::is_const<non_pointer_A>::value,
typename ::boost::add_const<type1>::type,
type1
>::RET type2;
typedef typename detail::IF<
::boost::is_volatile<non_pointer_A>::value,
typename ::boost::add_volatile<type2>::type,
type2
>::RET type3;
// add reference back
typedef typename ::boost::add_reference<type3>::type type;
};
};
// neither case
template <>
struct member_pointer_action_helper<false, false> {
public:
template<class RET, class A, class B>
static RET apply(A& a, B& b) {
// not a built in member pointer operator, just call ->*
return a->*b;
}
// an overloaded member pointer operators, user should have specified
// the return type
// At this point we know that there is no matching specialization for
// return_type_2, so try return_type_2_plain
template<class A, class B>
struct return_type {
typedef typename plain_return_type_2<
other_action<member_pointer_action>, A, B
>::type type;
};
};
// member pointer function case
// This is a built in ->* call for a member function,
// the only thing that you can do with that, is to give it some arguments
// note, it is guaranteed that A is a pointer type, and thus it cannot
// be a call to overloaded ->*
template <>
struct member_pointer_action_helper<false, true> {
public:
template<class RET, class A, class B>
static RET apply(A& a, B& b) {
typedef typename ::boost::remove_cv<B>::type plainB;
typedef typename detail::member_pointer<plainB>::type ret_t;
typedef typename ::boost::remove_cv<A>::type plainA;
// we always strip cv:s to
// make the two routes (calling and type deduction)
// to give the same results (and the const does not make any functional
// difference)
return detail::member_pointer_caller<ret_t, plainA, plainB>(a, b);
}
template<class A, class B>
struct return_type {
typedef typename detail::remove_reference_and_cv<B>::type plainB;
typedef typename detail::member_pointer<plainB>::type ret_t;
typedef typename detail::remove_reference_and_cv<A>::type plainA;
typedef detail::member_pointer_caller<ret_t, plainA, plainB> type;
};
};
} // detail
template<> class other_action<member_pointer_action> {
public:
template<class RET, class A, class B>
static RET apply(A& a, B& b) {
typedef typename
::boost::remove_cv<B>::type plainB;
return detail::member_pointer_action_helper<
boost::is_pointer<A>::value &&
detail::member_pointer<plainB>::is_data_member,
boost::is_pointer<A>::value &&
detail::member_pointer<plainB>::is_function_member
>::template apply<RET>(a, b);
}
};
// return type deduction --
// If the right argument is a pointer to data member,
// and the left argument is of compatible pointer to class type
// return type is a reference to the data member type
// if right argument is a pointer to a member function, and the left
// argument is of a compatible type, the return type is a
// member_pointer_caller (see above)
// Otherwise, return type deduction fails. There is either an error,
// or the user is trying to call an overloaded ->*
// In such a case either ret<> must be used, or a return_type_2 user
// defined specialization must be provided
template<class A, class B>
struct return_type_2<other_action<member_pointer_action>, A, B> {
private:
typedef typename
detail::remove_reference_and_cv<B>::type plainB;
public:
typedef typename
detail::member_pointer_action_helper<
detail::member_pointer<plainB>::is_data_member,
detail::member_pointer<plainB>::is_function_member
>::template return_type<A, B>::type type;
};
// this is the way the generic lambda_functor_base functions instantiate
// return type deduction. We turn it into return_type_2, so that the
// user can provide specializations on that level.
template<class Args>
struct return_type_N<other_action<member_pointer_action>, Args> {
typedef typename boost::tuples::element<0, Args>::type A;
typedef typename boost::tuples::element<1, Args>::type B;
typedef typename
return_type_2<other_action<member_pointer_action>,
typename boost::remove_reference<A>::type,
typename boost::remove_reference<B>::type
>::type type;
};
template<class Arg1, class Arg2>
inline const
lambda_functor<
lambda_functor_base<
action<2, other_action<member_pointer_action> >,
tuple<lambda_functor<Arg1>, typename const_copy_argument<Arg2>::type>
>
>
operator->*(const lambda_functor<Arg1>& a1, const Arg2& a2)
{
return
lambda_functor_base<
action<2, other_action<member_pointer_action> >,
tuple<lambda_functor<Arg1>, typename const_copy_argument<Arg2>::type>
>
(tuple<lambda_functor<Arg1>,
typename const_copy_argument<Arg2>::type>(a1, a2));
}
template<class Arg1, class Arg2>
inline const
lambda_functor<
lambda_functor_base<
action<2, other_action<member_pointer_action> >,
tuple<lambda_functor<Arg1>, lambda_functor<Arg2> >
>
>
operator->*(const lambda_functor<Arg1>& a1, const lambda_functor<Arg2>& a2)
{
return
lambda_functor_base<
action<2, other_action<member_pointer_action> >,
tuple<lambda_functor<Arg1>, lambda_functor<Arg2> >
>
(tuple<lambda_functor<Arg1>, lambda_functor<Arg2> >(a1, a2));
}
template<class Arg1, class Arg2>
inline const
lambda_functor<
lambda_functor_base<
action<2, other_action<member_pointer_action> >,
tuple<typename const_copy_argument<Arg1>::type, lambda_functor<Arg2> >
>
>
operator->*(const Arg1& a1, const lambda_functor<Arg2>& a2)
{
return
lambda_functor_base<
action<2, other_action<member_pointer_action> >,
tuple<typename const_copy_argument<Arg1>::type, lambda_functor<Arg2> >
>
(tuple<typename const_copy_argument<Arg1>::type,
lambda_functor<Arg2> >(a1, a2));
}
} // namespace lambda
} // namespace boost
#endif

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// -- operator_actions.hpp - Boost Lambda Library ----------------------
// Copyright (C) 1999, 2000 Jaakko Jarvi (jaakko.jarvi@cs.utu.fi)
//
// 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)
// For more information, see http://lambda.cs.utu.fi
#ifndef BOOST_LAMBDA_OPERATOR_ACTIONS_HPP
#define BOOST_LAMBDA_OPERATOR_ACTIONS_HPP
namespace boost {
namespace lambda {
// -- artihmetic ----------------------
class plus_action {};
class minus_action {};
class multiply_action {};
class divide_action {};
class remainder_action {};
// -- bitwise -------------------
class leftshift_action {};
class rightshift_action {};
class xor_action {};
// -- bitwise/logical -------------------
class and_action {};
class or_action {};
class not_action {};
// -- relational -------------------------
class less_action {};
class greater_action {};
class lessorequal_action {};
class greaterorequal_action {};
class equal_action {};
class notequal_action {};
// -- increment/decrement ------------------------------
class increment_action {};
class decrement_action {};
// -- void return ------------------------------
// -- other ------------------------------
class addressof_action {};
// class comma_action {}; // defined in actions.hpp
class contentsof_action {};
// class member_pointer_action {}; (defined in member_ptr.hpp)
// -- actioun group templates --------------------
template <class Action> class arithmetic_action;
template <class Action> class bitwise_action;
template <class Action> class logical_action;
template <class Action> class relational_action;
template <class Action> class arithmetic_assignment_action;
template <class Action> class bitwise_assignment_action;
template <class Action> class unary_arithmetic_action;
template <class Action> class pre_increment_decrement_action;
template <class Action> class post_increment_decrement_action;
// ---------------------------------------------------------
// actions, for which the existence of protect is checked in return type
// deduction.
template <class Act> struct is_protectable<arithmetic_action<Act> > {
BOOST_STATIC_CONSTANT(bool, value = true);
};
template <class Act> struct is_protectable<bitwise_action<Act> > {
BOOST_STATIC_CONSTANT(bool, value = true);
};
template <class Act> struct is_protectable<logical_action<Act> > {
BOOST_STATIC_CONSTANT(bool, value = true);
};
template <class Act> struct is_protectable<relational_action<Act> > {
BOOST_STATIC_CONSTANT(bool, value = true);
};
template <class Act>
struct is_protectable<arithmetic_assignment_action<Act> > {
BOOST_STATIC_CONSTANT(bool, value = true);
};
template <class Act> struct is_protectable<bitwise_assignment_action<Act> > {
BOOST_STATIC_CONSTANT(bool, value = true);
};
template <class Act> struct is_protectable<unary_arithmetic_action<Act> > {
BOOST_STATIC_CONSTANT(bool, value = true);
};
template <class Act>
struct is_protectable<pre_increment_decrement_action<Act> > {
BOOST_STATIC_CONSTANT(bool, value = true);
};
template <class Act> struct
is_protectable<post_increment_decrement_action<Act> > {
BOOST_STATIC_CONSTANT(bool, value = true);
};
template <> struct is_protectable<other_action<addressof_action> > {
BOOST_STATIC_CONSTANT(bool, value = true);
};
template <> struct is_protectable<other_action<contentsof_action> > {
BOOST_STATIC_CONSTANT(bool, value = true);
};
template<> struct is_protectable<other_action<subscript_action> > {
BOOST_STATIC_CONSTANT(bool, value = true);
};
template<> struct is_protectable<other_action<assignment_action> > {
BOOST_STATIC_CONSTANT(bool, value = true);
};
// NOTE: comma action is also protectable, but the specialization is
// in actions.hpp
} // namespace lambda
} // namespace boost
#endif

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// Boost Lambda Library - operator_lambda_func_base.hpp -----------------
//
// Copyright (C) 1999, 2000 Jaakko Jarvi (jaakko.jarvi@cs.utu.fi)
//
// 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)
//
// For more information, see www.boost.org
// ------------------------------------------------------------
#ifndef BOOST_LAMBDA_OPERATOR_LAMBDA_FUNC_BASE_HPP
#define BOOST_LAMBDA_OPERATOR_LAMBDA_FUNC_BASE_HPP
namespace boost {
namespace lambda {
// These operators cannot be implemented as apply functions of action
// templates
// Specialization for comma.
template<class Args>
class lambda_functor_base<other_action<comma_action>, Args> {
public:
Args args;
public:
explicit lambda_functor_base(const Args& a) : args(a) {}
template<class RET, CALL_TEMPLATE_ARGS>
RET call(CALL_FORMAL_ARGS) const {
return detail::select(boost::tuples::get<0>(args), CALL_ACTUAL_ARGS),
detail::select(boost::tuples::get<1>(args), CALL_ACTUAL_ARGS);
}
template<class SigArgs> struct sig {
private:
typedef typename
detail::deduce_argument_types<Args, SigArgs>::type rets_t;
public:
typedef typename return_type_2_comma< // comma needs special handling
typename detail::element_or_null<0, rets_t>::type,
typename detail::element_or_null<1, rets_t>::type
>::type type;
};
};
namespace detail {
// helper traits to make the expression shorter, takes binary action
// bound argument tuple, open argument tuple and gives the return type
template<class Action, class Bound, class Open> class binary_rt {
private:
typedef typename
detail::deduce_argument_types<Bound, Open>::type rets_t;
public:
typedef typename return_type_2_prot<
Action,
typename detail::element_or_null<0, rets_t>::type,
typename detail::element_or_null<1, rets_t>::type
>::type type;
};
// same for unary actions
template<class Action, class Bound, class Open> class unary_rt {
private:
typedef typename
detail::deduce_argument_types<Bound, Open>::type rets_t;
public:
typedef typename return_type_1_prot<
Action,
typename detail::element_or_null<0, rets_t>::type
>::type type;
};
} // end detail
// Specialization for logical and (to preserve shortcircuiting)
// this could be done with a macro as the others, code used to be different
template<class Args>
class lambda_functor_base<logical_action<and_action>, Args> {
public:
Args args;
public:
explicit lambda_functor_base(const Args& a) : args(a) {}
template<class RET, CALL_TEMPLATE_ARGS>
RET call(CALL_FORMAL_ARGS) const {
return detail::select(boost::tuples::get<0>(args), CALL_ACTUAL_ARGS) &&
detail::select(boost::tuples::get<1>(args), CALL_ACTUAL_ARGS);
}
template<class SigArgs> struct sig {
typedef typename
detail::binary_rt<logical_action<and_action>, Args, SigArgs>::type type;
};
};
// Specialization for logical or (to preserve shortcircuiting)
// this could be done with a macro as the others, code used to be different
template<class Args>
class lambda_functor_base<logical_action< or_action>, Args> {
public:
Args args;
public:
explicit lambda_functor_base(const Args& a) : args(a) {}
template<class RET, CALL_TEMPLATE_ARGS>
RET call(CALL_FORMAL_ARGS) const {
return detail::select(boost::tuples::get<0>(args), CALL_ACTUAL_ARGS) ||
detail::select(boost::tuples::get<1>(args), CALL_ACTUAL_ARGS);
}
template<class SigArgs> struct sig {
typedef typename
detail::binary_rt<logical_action<or_action>, Args, SigArgs>::type type;
};
};
// Specialization for subscript
template<class Args>
class lambda_functor_base<other_action<subscript_action>, Args> {
public:
Args args;
public:
explicit lambda_functor_base(const Args& a) : args(a) {}
template<class RET, CALL_TEMPLATE_ARGS>
RET call(CALL_FORMAL_ARGS) const {
return detail::select(boost::tuples::get<0>(args), CALL_ACTUAL_ARGS)
[detail::select(boost::tuples::get<1>(args), CALL_ACTUAL_ARGS)];
}
template<class SigArgs> struct sig {
typedef typename
detail::binary_rt<other_action<subscript_action>, Args, SigArgs>::type
type;
};
};
#define BOOST_LAMBDA_BINARY_ACTION(SYMBOL, ACTION_CLASS) \
template<class Args> \
class lambda_functor_base<ACTION_CLASS, Args> { \
public: \
Args args; \
public: \
explicit lambda_functor_base(const Args& a) : args(a) {} \
\
template<class RET, CALL_TEMPLATE_ARGS> \
RET call(CALL_FORMAL_ARGS) const { \
return detail::select(boost::tuples::get<0>(args), CALL_ACTUAL_ARGS) \
SYMBOL \
detail::select(boost::tuples::get<1>(args), CALL_ACTUAL_ARGS); \
} \
template<class SigArgs> struct sig { \
typedef typename \
detail::binary_rt<ACTION_CLASS, Args, SigArgs>::type type; \
}; \
};
#define BOOST_LAMBDA_PREFIX_UNARY_ACTION(SYMBOL, ACTION_CLASS) \
template<class Args> \
class lambda_functor_base<ACTION_CLASS, Args> { \
public: \
Args args; \
public: \
explicit lambda_functor_base(const Args& a) : args(a) {} \
\
template<class RET, CALL_TEMPLATE_ARGS> \
RET call(CALL_FORMAL_ARGS) const { \
return SYMBOL \
detail::select(boost::tuples::get<0>(args), CALL_ACTUAL_ARGS); \
} \
template<class SigArgs> struct sig { \
typedef typename \
detail::unary_rt<ACTION_CLASS, Args, SigArgs>::type type; \
}; \
};
#define BOOST_LAMBDA_POSTFIX_UNARY_ACTION(SYMBOL, ACTION_CLASS) \
template<class Args> \
class lambda_functor_base<ACTION_CLASS, Args> { \
public: \
Args args; \
public: \
explicit lambda_functor_base(const Args& a) : args(a) {} \
\
template<class RET, CALL_TEMPLATE_ARGS> \
RET call(CALL_FORMAL_ARGS) const { \
return \
detail::select(boost::tuples::get<0>(args), CALL_ACTUAL_ARGS) SYMBOL; \
} \
template<class SigArgs> struct sig { \
typedef typename \
detail::unary_rt<ACTION_CLASS, Args, SigArgs>::type type; \
}; \
};
BOOST_LAMBDA_BINARY_ACTION(+,arithmetic_action<plus_action>)
BOOST_LAMBDA_BINARY_ACTION(-,arithmetic_action<minus_action>)
BOOST_LAMBDA_BINARY_ACTION(*,arithmetic_action<multiply_action>)
BOOST_LAMBDA_BINARY_ACTION(/,arithmetic_action<divide_action>)
BOOST_LAMBDA_BINARY_ACTION(%,arithmetic_action<remainder_action>)
BOOST_LAMBDA_BINARY_ACTION(<<,bitwise_action<leftshift_action>)
BOOST_LAMBDA_BINARY_ACTION(>>,bitwise_action<rightshift_action>)
BOOST_LAMBDA_BINARY_ACTION(&,bitwise_action<and_action>)
BOOST_LAMBDA_BINARY_ACTION(|,bitwise_action<or_action>)
BOOST_LAMBDA_BINARY_ACTION(^,bitwise_action<xor_action>)
BOOST_LAMBDA_BINARY_ACTION(<,relational_action<less_action>)
BOOST_LAMBDA_BINARY_ACTION(>,relational_action<greater_action>)
BOOST_LAMBDA_BINARY_ACTION(<=,relational_action<lessorequal_action>)
BOOST_LAMBDA_BINARY_ACTION(>=,relational_action<greaterorequal_action>)
BOOST_LAMBDA_BINARY_ACTION(==,relational_action<equal_action>)
BOOST_LAMBDA_BINARY_ACTION(!=,relational_action<notequal_action>)
BOOST_LAMBDA_BINARY_ACTION(+=,arithmetic_assignment_action<plus_action>)
BOOST_LAMBDA_BINARY_ACTION(-=,arithmetic_assignment_action<minus_action>)
BOOST_LAMBDA_BINARY_ACTION(*=,arithmetic_assignment_action<multiply_action>)
BOOST_LAMBDA_BINARY_ACTION(/=,arithmetic_assignment_action<divide_action>)
BOOST_LAMBDA_BINARY_ACTION(%=,arithmetic_assignment_action<remainder_action>)
BOOST_LAMBDA_BINARY_ACTION(<<=,bitwise_assignment_action<leftshift_action>)
BOOST_LAMBDA_BINARY_ACTION(>>=,bitwise_assignment_action<rightshift_action>)
BOOST_LAMBDA_BINARY_ACTION(&=,bitwise_assignment_action<and_action>)
BOOST_LAMBDA_BINARY_ACTION(|=,bitwise_assignment_action<or_action>)
BOOST_LAMBDA_BINARY_ACTION(^=,bitwise_assignment_action<xor_action>)
BOOST_LAMBDA_BINARY_ACTION(=,other_action< assignment_action>)
BOOST_LAMBDA_PREFIX_UNARY_ACTION(+, unary_arithmetic_action<plus_action>)
BOOST_LAMBDA_PREFIX_UNARY_ACTION(-, unary_arithmetic_action<minus_action>)
BOOST_LAMBDA_PREFIX_UNARY_ACTION(~, bitwise_action<not_action>)
BOOST_LAMBDA_PREFIX_UNARY_ACTION(!, logical_action<not_action>)
BOOST_LAMBDA_PREFIX_UNARY_ACTION(++, pre_increment_decrement_action<increment_action>)
BOOST_LAMBDA_PREFIX_UNARY_ACTION(--, pre_increment_decrement_action<decrement_action>)
BOOST_LAMBDA_PREFIX_UNARY_ACTION(&,other_action<addressof_action>)
BOOST_LAMBDA_PREFIX_UNARY_ACTION(*,other_action<contentsof_action>)
BOOST_LAMBDA_POSTFIX_UNARY_ACTION(++, post_increment_decrement_action<increment_action>)
BOOST_LAMBDA_POSTFIX_UNARY_ACTION(--, post_increment_decrement_action<decrement_action>)
#undef BOOST_LAMBDA_POSTFIX_UNARY_ACTION
#undef BOOST_LAMBDA_PREFIX_UNARY_ACTION
#undef BOOST_LAMBDA_BINARY_ACTION
} // namespace lambda
} // namespace boost
#endif

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// operator_return_type_traits.hpp -- Boost Lambda Library ------------------
// Copyright (C) 1999, 2000 Jaakko Jarvi (jaakko.jarvi@cs.utu.fi)
//
// 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)
//
// For more information, see www.boost.org
#ifndef BOOST_LAMBDA_OPERATOR_RETURN_TYPE_TRAITS_HPP
#define BOOST_LAMBDA_OPERATOR_RETURN_TYPE_TRAITS_HPP
#include "boost/lambda/detail/is_instance_of.hpp"
#include "boost/type_traits/same_traits.hpp"
#include "boost/indirect_reference.hpp"
#include "boost/detail/container_fwd.hpp"
#include <cstddef> // needed for the ptrdiff_t
#include <iosfwd> // for istream and ostream
#include <iterator> // needed for operator&
namespace boost {
namespace lambda {
namespace detail {
// -- general helper templates for type deduction ------------------
// Much of the type deduction code for standard arithmetic types from Gary Powell
template <class A> struct promote_code { static const int value = -1; };
// this means that a code is not defined for A
// -- the next 5 types are needed in if_then_else_return
// the promotion order is not important, but they must have distinct values.
template <> struct promote_code<bool> { static const int value = 10; };
template <> struct promote_code<char> { static const int value = 20; };
template <> struct promote_code<unsigned char> { static const int value = 30; };
template <> struct promote_code<signed char> { static const int value = 40; };
template <> struct promote_code<short int> { static const int value = 50; };
// ----------
template <> struct promote_code<int> { static const int value = 100; };
template <> struct promote_code<unsigned int> { static const int value = 200; };
template <> struct promote_code<long> { static const int value = 300; };
template <> struct promote_code<unsigned long> { static const int value = 400; };
template <> struct promote_code<float> { static const int value = 500; };
template <> struct promote_code<double> { static const int value = 600; };
template <> struct promote_code<long double> { static const int value = 700; };
// TODO: wchar_t
// forward delcaration of complex.
} // namespace detail
} // namespace lambda
} // namespace boost
namespace boost {
namespace lambda {
namespace detail {
template <> struct promote_code< std::complex<float> > { static const int value = 800; };
template <> struct promote_code< std::complex<double> > { static const int value = 900; };
template <> struct promote_code< std::complex<long double> > { static const int value = 1000; };
// -- int promotion -------------------------------------------
template <class T> struct promote_to_int { typedef T type; };
template <> struct promote_to_int<bool> { typedef int type; };
template <> struct promote_to_int<char> { typedef int type; };
template <> struct promote_to_int<unsigned char> { typedef int type; };
template <> struct promote_to_int<signed char> { typedef int type; };
template <> struct promote_to_int<short int> { typedef int type; };
// The unsigned short int promotion rule is this:
// unsigned short int to signed int if a signed int can hold all values
// of unsigned short int, otherwise go to unsigned int.
template <> struct promote_to_int<unsigned short int>
{
typedef
detail::IF<sizeof(int) <= sizeof(unsigned short int),
// I had the logic reversed but ">" messes up the parsing.
unsigned int,
int>::RET type;
};
// TODO: think, should there be default behaviour for non-standard types?
} // namespace detail
// ------------------------------------------
// Unary actions ----------------------------
// ------------------------------------------
template<class Act, class A>
struct plain_return_type_1 {
typedef detail::unspecified type;
};
template<class Act, class A>
struct plain_return_type_1<unary_arithmetic_action<Act>, A> {
typedef A type;
};
template<class Act, class A>
struct return_type_1<unary_arithmetic_action<Act>, A> {
typedef
typename plain_return_type_1<
unary_arithmetic_action<Act>,
typename detail::remove_reference_and_cv<A>::type
>::type type;
};
template<class A>
struct plain_return_type_1<bitwise_action<not_action>, A> {
typedef A type;
};
// bitwise not, operator~()
template<class A> struct return_type_1<bitwise_action<not_action>, A> {
typedef
typename plain_return_type_1<
bitwise_action<not_action>,
typename detail::remove_reference_and_cv<A>::type
>::type type;
};
// prefix increment and decrement operators return
// their argument by default as a non-const reference
template<class Act, class A>
struct plain_return_type_1<pre_increment_decrement_action<Act>, A> {
typedef A& type;
};
template<class Act, class A>
struct return_type_1<pre_increment_decrement_action<Act>, A> {
typedef
typename plain_return_type_1<
pre_increment_decrement_action<Act>,
typename detail::remove_reference_and_cv<A>::type
>::type type;
};
// post decrement just returns the same plain type.
template<class Act, class A>
struct plain_return_type_1<post_increment_decrement_action<Act>, A> {
typedef A type;
};
template<class Act, class A>
struct return_type_1<post_increment_decrement_action<Act>, A>
{
typedef
typename plain_return_type_1<
post_increment_decrement_action<Act>,
typename detail::remove_reference_and_cv<A>::type
>::type type;
};
// logical not, operator!()
template<class A>
struct plain_return_type_1<logical_action<not_action>, A> {
typedef bool type;
};
template<class A>
struct return_type_1<logical_action<not_action>, A> {
typedef
typename plain_return_type_1<
logical_action<not_action>,
typename detail::remove_reference_and_cv<A>::type
>::type type;
};
// address of action ---------------------------------------
template<class A>
struct return_type_1<other_action<addressof_action>, A> {
typedef
typename plain_return_type_1<
other_action<addressof_action>,
typename detail::remove_reference_and_cv<A>::type
>::type type1;
// If no user defined specialization for A, then return the
// cv qualified pointer to A
typedef typename detail::IF<
boost::is_same<type1, detail::unspecified>::value,
typename boost::remove_reference<A>::type*,
type1
>::RET type;
};
// contentsof action ------------------------------------
// TODO: this deduction may lead to fail directly,
// (if A has no specialization for iterator_traits and has no
// typedef A::reference.
// There is no easy way around this, cause there doesn't seem to be a way
// to test whether a class is an iterator or not.
// The default works with std::iterators.
namespace detail {
// A is a nonreference type
template <class A> struct contentsof_type {
typedef typename boost::indirect_reference<A>::type type;
};
// this is since the nullary () in lambda_functor is always instantiated
template <> struct contentsof_type<null_type> {
typedef detail::unspecified type;
};
template <class A> struct contentsof_type<const A> {
typedef typename contentsof_type<A>::type type;
};
template <class A> struct contentsof_type<volatile A> {
typedef typename contentsof_type<A>::type type;
};
template <class A> struct contentsof_type<const volatile A> {
typedef typename contentsof_type<A>::type type;
};
// standard iterator traits should take care of the pointer types
// but just to be on the safe side, we have the specializations here:
// these work even if A is cv-qualified.
template <class A> struct contentsof_type<A*> {
typedef A& type;
};
template <class A> struct contentsof_type<A* const> {
typedef A& type;
};
template <class A> struct contentsof_type<A* volatile> {
typedef A& type;
};
template <class A> struct contentsof_type<A* const volatile> {
typedef A& type;
};
template<class A, int N> struct contentsof_type<A[N]> {
typedef A& type;
};
template<class A, int N> struct contentsof_type<const A[N]> {
typedef const A& type;
};
template<class A, int N> struct contentsof_type<volatile A[N]> {
typedef volatile A& type;
};
template<class A, int N> struct contentsof_type<const volatile A[N]> {
typedef const volatile A& type;
};
} // end detail
template<class A>
struct return_type_1<other_action<contentsof_action>, A> {
typedef
typename plain_return_type_1<
other_action<contentsof_action>,
typename detail::remove_reference_and_cv<A>::type
>::type type1;
// If no user defined specialization for A, then return the
// cv qualified pointer to A
typedef typename
detail::IF_type<
boost::is_same<type1, detail::unspecified>::value,
detail::contentsof_type<
typename boost::remove_reference<A>::type
>,
detail::identity_mapping<type1>
>::type type;
};
// ------------------------------------------------------------------
// binary actions ---------------------------------------------------
// ------------------------------------------------------------------
// here the default case is: no user defined versions:
template <class Act, class A, class B>
struct plain_return_type_2 {
typedef detail::unspecified type;
};
namespace detail {
// error classes
class illegal_pointer_arithmetic{};
// pointer arithmetic type deductions ----------------------
// value = false means that this is not a pointer arithmetic case
// value = true means, that this can be a pointer arithmetic case, but not necessarily is
// This means, that for user defined operators for pointer types, say for some operator+(X, *Y),
// the deductions must be coded at an earliel level (return_type_2).
template<class Act, class A, class B>
struct pointer_arithmetic_traits { static const bool value = false; };
template<class A, class B>
struct pointer_arithmetic_traits<plus_action, A, B> {
typedef typename
array_to_pointer<typename boost::remove_reference<A>::type>::type AP;
typedef typename
array_to_pointer<typename boost::remove_reference<B>::type>::type BP;
static const bool is_pointer_A = boost::is_pointer<AP>::value;
static const bool is_pointer_B = boost::is_pointer<BP>::value;
static const bool value = is_pointer_A || is_pointer_B;
// can't add two pointers.
// note, that we do not check wether the other type is valid for
// addition with a pointer.
// the compiler will catch it in the apply function
typedef typename
detail::IF<
is_pointer_A && is_pointer_B,
detail::return_type_deduction_failure<
detail::illegal_pointer_arithmetic
>,
typename detail::IF<is_pointer_A, AP, BP>::RET
>::RET type;
};
template<class A, class B>
struct pointer_arithmetic_traits<minus_action, A, B> {
typedef typename
array_to_pointer<typename boost::remove_reference<A>::type>::type AP;
typedef typename
array_to_pointer<typename boost::remove_reference<B>::type>::type BP;
static const bool is_pointer_A = boost::is_pointer<AP>::value;
static const bool is_pointer_B = boost::is_pointer<BP>::value;
static const bool value = is_pointer_A || is_pointer_B;
static const bool same_pointer_type =
is_pointer_A && is_pointer_B &&
boost::is_same<
typename boost::remove_const<
typename boost::remove_pointer<
typename boost::remove_const<AP>::type
>::type
>::type,
typename boost::remove_const<
typename boost::remove_pointer<
typename boost::remove_const<BP>::type
>::type
>::type
>::value;
// ptr - ptr has type ptrdiff_t
// note, that we do not check if, in ptr - B, B is
// valid for subtraction with a pointer.
// the compiler will catch it in the apply function
typedef typename
detail::IF<
same_pointer_type, const std::ptrdiff_t,
typename detail::IF<
is_pointer_A,
AP,
detail::return_type_deduction_failure<detail::illegal_pointer_arithmetic>
>::RET
>::RET type;
};
} // namespace detail
// -- arithmetic actions ---------------------------------------------
namespace detail {
template<bool is_pointer_arithmetic, class Act, class A, class B>
struct return_type_2_arithmetic_phase_1;
template<class A, class B> struct return_type_2_arithmetic_phase_2;
template<class A, class B> struct return_type_2_arithmetic_phase_3;
} // namespace detail
// drop any qualifiers from the argument types within arithmetic_action
template<class A, class B, class Act>
struct return_type_2<arithmetic_action<Act>, A, B>
{
typedef typename detail::remove_reference_and_cv<A>::type plain_A;
typedef typename detail::remove_reference_and_cv<B>::type plain_B;
typedef typename
plain_return_type_2<arithmetic_action<Act>, plain_A, plain_B>::type type1;
// if user defined return type, do not enter the whole arithmetic deductions
typedef typename
detail::IF_type<
boost::is_same<type1, detail::unspecified>::value,
detail::return_type_2_arithmetic_phase_1<
detail::pointer_arithmetic_traits<Act, A, B>::value, Act, A, B
>,
plain_return_type_2<arithmetic_action<Act>, plain_A, plain_B>
>::type type;
};
namespace detail {
// perform integral promotion, no pointer arithmetic
template<bool is_pointer_arithmetic, class Act, class A, class B>
struct return_type_2_arithmetic_phase_1
{
typedef typename
return_type_2_arithmetic_phase_2<
typename remove_reference_and_cv<A>::type,
typename remove_reference_and_cv<B>::type
>::type type;
};
// pointer_arithmetic
template<class Act, class A, class B>
struct return_type_2_arithmetic_phase_1<true, Act, A, B>
{
typedef typename
pointer_arithmetic_traits<Act, A, B>::type type;
};
template<class A, class B>
struct return_type_2_arithmetic_phase_2 {
typedef typename
return_type_2_arithmetic_phase_3<
typename promote_to_int<A>::type,
typename promote_to_int<B>::type
>::type type;
};
// specialization for unsigned int.
// We only have to do these two specialization because the value promotion will
// take care of the other cases.
// The unsigned int promotion rule is this:
// unsigned int to long if a long can hold all values of unsigned int,
// otherwise go to unsigned long.
// struct so I don't have to type this twice.
struct promotion_of_unsigned_int
{
typedef
detail::IF<sizeof(long) <= sizeof(unsigned int),
unsigned long,
long>::RET type;
};
template<>
struct return_type_2_arithmetic_phase_2<unsigned int, long>
{
typedef promotion_of_unsigned_int::type type;
};
template<>
struct return_type_2_arithmetic_phase_2<long, unsigned int>
{
typedef promotion_of_unsigned_int::type type;
};
template<class A, class B> struct return_type_2_arithmetic_phase_3 {
enum { promote_code_A_value = promote_code<A>::value,
promote_code_B_value = promote_code<B>::value }; // enums for KCC
typedef typename
detail::IF<
promote_code_A_value == -1 || promote_code_B_value == -1,
detail::return_type_deduction_failure<return_type_2_arithmetic_phase_3>,
typename detail::IF<
((int)promote_code_A_value > (int)promote_code_B_value),
A,
B
>::RET
>::RET type;
};
} // namespace detail
// -- bitwise actions -------------------------------------------
// note: for integral types deuduction is similar to arithmetic actions.
// drop any qualifiers from the argument types within arithmetic action
template<class A, class B, class Act>
struct return_type_2<bitwise_action<Act>, A, B>
{
typedef typename detail::remove_reference_and_cv<A>::type plain_A;
typedef typename detail::remove_reference_and_cv<B>::type plain_B;
typedef typename
plain_return_type_2<bitwise_action<Act>, plain_A, plain_B>::type type1;
// if user defined return type, do not enter type deductions
typedef typename
detail::IF_type<
boost::is_same<type1, detail::unspecified>::value,
return_type_2<arithmetic_action<plus_action>, A, B>,
plain_return_type_2<bitwise_action<Act>, plain_A, plain_B>
>::type type;
// plus_action is just a random pick, has to be a concrete instance
// TODO: This check is only valid for built-in types, overloaded types might
// accept floating point operators
// bitwise operators not defined for floating point types
// these test are not strictly needed here, since the error will be caught in
// the apply function
BOOST_STATIC_ASSERT(!(boost::is_float<plain_A>::value && boost::is_float<plain_B>::value));
};
namespace detail {
#ifdef BOOST_NO_TEMPLATED_STREAMS
template<class A, class B>
struct leftshift_type {
typedef typename detail::IF<
boost::is_convertible<
typename boost::remove_reference<A>::type*,
std::ostream*
>::value,
std::ostream&,
typename detail::remove_reference_and_cv<A>::type
>::RET type;
};
template<class A, class B>
struct rightshift_type {
typedef typename detail::IF<
boost::is_convertible<
typename boost::remove_reference<A>::type*,
std::istream*
>::value,
std::istream&,
typename detail::remove_reference_and_cv<A>::type
>::RET type;
};
#else
template <class T> struct get_ostream_type {
typedef std::basic_ostream<typename T::char_type,
typename T::traits_type>& type;
};
template <class T> struct get_istream_type {
typedef std::basic_istream<typename T::char_type,
typename T::traits_type>& type;
};
template<class A, class B>
struct leftshift_type {
private:
typedef typename boost::remove_reference<A>::type plainA;
public:
typedef typename detail::IF_type<
is_instance_of_2<plainA, std::basic_ostream>::value,
get_ostream_type<plainA>, //reference to the stream
detail::remove_reference_and_cv<A>
>::type type;
};
template<class A, class B>
struct rightshift_type {
private:
typedef typename boost::remove_reference<A>::type plainA;
public:
typedef typename detail::IF_type<
is_instance_of_2<plainA, std::basic_istream>::value,
get_istream_type<plainA>, //reference to the stream
detail::remove_reference_and_cv<A>
>::type type;
};
#endif
} // end detail
// ostream
template<class A, class B>
struct return_type_2<bitwise_action<leftshift_action>, A, B>
{
typedef typename detail::remove_reference_and_cv<A>::type plain_A;
typedef typename detail::remove_reference_and_cv<B>::type plain_B;
typedef typename
plain_return_type_2<bitwise_action<leftshift_action>, plain_A, plain_B>::type type1;
// if user defined return type, do not enter type deductions
typedef typename
detail::IF_type<
boost::is_same<type1, detail::unspecified>::value,
detail::leftshift_type<A, B>,
plain_return_type_2<bitwise_action<leftshift_action>, plain_A, plain_B>
>::type type;
};
// istream
template<class A, class B>
struct return_type_2<bitwise_action<rightshift_action>, A, B>
{
typedef typename detail::remove_reference_and_cv<A>::type plain_A;
typedef typename detail::remove_reference_and_cv<B>::type plain_B;
typedef typename
plain_return_type_2<bitwise_action<rightshift_action>, plain_A, plain_B>::type type1;
// if user defined return type, do not enter type deductions
typedef typename
detail::IF_type<
boost::is_same<type1, detail::unspecified>::value,
detail::rightshift_type<A, B>,
plain_return_type_2<bitwise_action<rightshift_action>, plain_A, plain_B>
>::type type;
};
// -- logical actions ----------------------------------------
// always bool
// NOTE: this may not be true for some weird user-defined types,
template<class A, class B, class Act>
struct plain_return_type_2<logical_action<Act>, A, B> {
typedef bool type;
};
template<class A, class B, class Act>
struct return_type_2<logical_action<Act>, A, B> {
typedef typename detail::remove_reference_and_cv<A>::type plain_A;
typedef typename detail::remove_reference_and_cv<B>::type plain_B;
typedef typename
plain_return_type_2<logical_action<Act>, plain_A, plain_B>::type type;
};
// -- relational actions ----------------------------------------
// always bool
// NOTE: this may not be true for some weird user-defined types,
template<class A, class B, class Act>
struct plain_return_type_2<relational_action<Act>, A, B> {
typedef bool type;
};
template<class A, class B, class Act>
struct return_type_2<relational_action<Act>, A, B> {
typedef typename detail::remove_reference_and_cv<A>::type plain_A;
typedef typename detail::remove_reference_and_cv<B>::type plain_B;
typedef typename
plain_return_type_2<relational_action<Act>, plain_A, plain_B>::type type;
};
// Assingment actions -----------------------------------------------
// return type is the type of the first argument as reference
// note that cv-qualifiers are preserved.
// Yes, assignment operator can be const!
// NOTE: this may not be true for some weird user-defined types,
template<class A, class B, class Act>
struct return_type_2<arithmetic_assignment_action<Act>, A, B> {
typedef typename detail::remove_reference_and_cv<A>::type plain_A;
typedef typename detail::remove_reference_and_cv<B>::type plain_B;
typedef typename
plain_return_type_2<
arithmetic_assignment_action<Act>, plain_A, plain_B
>::type type1;
typedef typename
detail::IF<
boost::is_same<type1, detail::unspecified>::value,
typename boost::add_reference<A>::type,
type1
>::RET type;
};
template<class A, class B, class Act>
struct return_type_2<bitwise_assignment_action<Act>, A, B> {
typedef typename detail::remove_reference_and_cv<A>::type plain_A;
typedef typename detail::remove_reference_and_cv<B>::type plain_B;
typedef typename
plain_return_type_2<
bitwise_assignment_action<Act>, plain_A, plain_B
>::type type1;
typedef typename
detail::IF<
boost::is_same<type1, detail::unspecified>::value,
typename boost::add_reference<A>::type,
type1
>::RET type;
};
template<class A, class B>
struct return_type_2<other_action<assignment_action>, A, B> {
typedef typename detail::remove_reference_and_cv<A>::type plain_A;
typedef typename detail::remove_reference_and_cv<B>::type plain_B;
typedef typename
plain_return_type_2<
other_action<assignment_action>, plain_A, plain_B
>::type type1;
typedef typename
detail::IF<
boost::is_same<type1, detail::unspecified>::value,
typename boost::add_reference<A>::type,
type1
>::RET type;
};
// -- other actions ----------------------------------------
// comma action ----------------------------------
// Note: this may not be true for some weird user-defined types,
// NOTE! This only tries the plain_return_type_2 layer and gives
// detail::unspecified as default. If no such specialization is found, the
// type rule in the spcecialization of the return_type_2_prot is used
// to give the type of the right argument (which can be a reference too)
// (The built in operator, can return a l- or rvalue).
template<class A, class B>
struct return_type_2<other_action<comma_action>, A, B> {
typedef typename detail::remove_reference_and_cv<A>::type plain_A;
typedef typename detail::remove_reference_and_cv<B>::type plain_B;
typedef typename
plain_return_type_2<
other_action<comma_action>, plain_A, plain_B
>::type type;
};
// subscript action -----------------------------------------------
namespace detail {
// A and B are nonreference types
template <class A, class B> struct subscript_type {
typedef detail::unspecified type;
};
template <class A, class B> struct subscript_type<A*, B> {
typedef A& type;
};
template <class A, class B> struct subscript_type<A* const, B> {
typedef A& type;
};
template <class A, class B> struct subscript_type<A* volatile, B> {
typedef A& type;
};
template <class A, class B> struct subscript_type<A* const volatile, B> {
typedef A& type;
};
template<class A, class B, int N> struct subscript_type<A[N], B> {
typedef A& type;
};
// these 3 specializations are needed to make gcc <3 happy
template<class A, class B, int N> struct subscript_type<const A[N], B> {
typedef const A& type;
};
template<class A, class B, int N> struct subscript_type<volatile A[N], B> {
typedef volatile A& type;
};
template<class A, class B, int N> struct subscript_type<const volatile A[N], B> {
typedef const volatile A& type;
};
} // end detail
template<class A, class B>
struct return_type_2<other_action<subscript_action>, A, B> {
typedef typename detail::remove_reference_and_cv<A>::type plain_A;
typedef typename detail::remove_reference_and_cv<B>::type plain_B;
typedef typename boost::remove_reference<A>::type nonref_A;
typedef typename boost::remove_reference<B>::type nonref_B;
typedef typename
plain_return_type_2<
other_action<subscript_action>, plain_A, plain_B
>::type type1;
typedef typename
detail::IF_type<
boost::is_same<type1, detail::unspecified>::value,
detail::subscript_type<nonref_A, nonref_B>,
plain_return_type_2<other_action<subscript_action>, plain_A, plain_B>
>::type type;
};
template<class Key, class T, class Cmp, class Allocator, class B>
struct plain_return_type_2<other_action<subscript_action>, std::map<Key, T, Cmp, Allocator>, B> {
typedef T& type;
// T == std::map<Key, T, Cmp, Allocator>::mapped_type;
};
template<class Key, class T, class Cmp, class Allocator, class B>
struct plain_return_type_2<other_action<subscript_action>, std::multimap<Key, T, Cmp, Allocator>, B> {
typedef T& type;
// T == std::map<Key, T, Cmp, Allocator>::mapped_type;
};
// deque
template<class T, class Allocator, class B>
struct plain_return_type_2<other_action<subscript_action>, std::deque<T, Allocator>, B> {
typedef typename std::deque<T, Allocator>::reference type;
};
template<class T, class Allocator, class B>
struct plain_return_type_2<other_action<subscript_action>, const std::deque<T, Allocator>, B> {
typedef typename std::deque<T, Allocator>::const_reference type;
};
// vector
template<class T, class Allocator, class B>
struct plain_return_type_2<other_action<subscript_action>, std::vector<T, Allocator>, B> {
typedef typename std::vector<T, Allocator>::reference type;
};
template<class T, class Allocator, class B>
struct plain_return_type_2<other_action<subscript_action>, const std::vector<T, Allocator>, B> {
typedef typename std::vector<T, Allocator>::const_reference type;
};
// basic_string
template<class Char, class Traits, class Allocator, class B>
struct plain_return_type_2<other_action<subscript_action>, std::basic_string<Char, Traits, Allocator>, B> {
typedef typename std::basic_string<Char, Traits, Allocator>::reference type;
};
template<class Char, class Traits, class Allocator, class B>
struct plain_return_type_2<other_action<subscript_action>, const std::basic_string<Char, Traits, Allocator>, B> {
typedef typename std::basic_string<Char, Traits, Allocator>::const_reference type;
};
template<class Char, class Traits, class Allocator>
struct plain_return_type_2<arithmetic_action<plus_action>,
std::basic_string<Char, Traits, Allocator>,
std::basic_string<Char, Traits, Allocator> > {
typedef std::basic_string<Char, Traits, Allocator> type;
};
template<class Char, class Traits, class Allocator>
struct plain_return_type_2<arithmetic_action<plus_action>,
const Char*,
std::basic_string<Char, Traits, Allocator> > {
typedef std::basic_string<Char, Traits, Allocator> type;
};
template<class Char, class Traits, class Allocator>
struct plain_return_type_2<arithmetic_action<plus_action>,
std::basic_string<Char, Traits, Allocator>,
const Char*> {
typedef std::basic_string<Char, Traits, Allocator> type;
};
template<class Char, class Traits, class Allocator, std::size_t N>
struct plain_return_type_2<arithmetic_action<plus_action>,
Char[N],
std::basic_string<Char, Traits, Allocator> > {
typedef std::basic_string<Char, Traits, Allocator> type;
};
template<class Char, class Traits, class Allocator, std::size_t N>
struct plain_return_type_2<arithmetic_action<plus_action>,
std::basic_string<Char, Traits, Allocator>,
Char[N]> {
typedef std::basic_string<Char, Traits, Allocator> type;
};
} // namespace lambda
} // namespace boost
#endif

370
test/external/boost/lambda/detail/operators.hpp vendored Normal file
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@@ -0,0 +1,370 @@
// Boost Lambda Library - operators.hpp --------------------------------------
// Copyright (C) 1999, 2000 Jaakko Jarvi (jaakko.jarvi@cs.utu.fi)
//
// 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)
//
// For more information, see www.boost.org
// ---------------------------------------------------------------
#ifndef BOOST_LAMBDA_OPERATORS_HPP
#define BOOST_LAMBDA_OPERATORS_HPP
#include "boost/lambda/detail/is_instance_of.hpp"
namespace boost {
namespace lambda {
#if defined BOOST_LAMBDA_BE1
#error "Multiple defines of BOOST_LAMBDA_BE1"
#endif
// For all BOOSTA_LAMBDA_BE* macros:
// CONSTA must be either 'A' or 'const A'
// CONSTB must be either 'B' or 'const B'
// It is stupid to have the names A and B as macro arguments, but it avoids
// the need to pass in emtpy macro arguments, which gives warnings on some
// compilers
#define BOOST_LAMBDA_BE1(OPER_NAME, ACTION, CONSTA, CONSTB, CONVERSION) \
template<class Arg, class B> \
inline const \
lambda_functor< \
lambda_functor_base< \
ACTION, \
tuple<lambda_functor<Arg>, typename const_copy_argument <CONSTB>::type> \
> \
> \
OPER_NAME (const lambda_functor<Arg>& a, CONSTB& b) { \
return \
lambda_functor_base< \
ACTION, \
tuple<lambda_functor<Arg>, typename const_copy_argument <CONSTB>::type>\
> \
(tuple<lambda_functor<Arg>, typename const_copy_argument <CONSTB>::type>(a, b)); \
}
#if defined BOOST_LAMBDA_BE2
#error "Multiple defines of BOOST_LAMBDA_BE2"
#endif
#define BOOST_LAMBDA_BE2(OPER_NAME, ACTION, CONSTA, CONSTB, CONVERSION) \
template<class A, class Arg> \
inline const \
lambda_functor< \
lambda_functor_base< \
ACTION, \
tuple<typename CONVERSION <CONSTA>::type, lambda_functor<Arg> > \
> \
> \
OPER_NAME (CONSTA& a, const lambda_functor<Arg>& b) { \
return \
lambda_functor_base< \
ACTION, \
tuple<typename CONVERSION <CONSTA>::type, lambda_functor<Arg> > \
> \
(tuple<typename CONVERSION <CONSTA>::type, lambda_functor<Arg> >(a, b)); \
}
#if defined BOOST_LAMBDA_BE3
#error "Multiple defines of BOOST_LAMBDA_BE3"
#endif
#define BOOST_LAMBDA_BE3(OPER_NAME, ACTION, CONSTA, CONSTB, CONVERSION) \
template<class ArgA, class ArgB> \
inline const \
lambda_functor< \
lambda_functor_base< \
ACTION, \
tuple<lambda_functor<ArgA>, lambda_functor<ArgB> > \
> \
> \
OPER_NAME (const lambda_functor<ArgA>& a, const lambda_functor<ArgB>& b) { \
return \
lambda_functor_base< \
ACTION, \
tuple<lambda_functor<ArgA>, lambda_functor<ArgB> > \
> \
(tuple<lambda_functor<ArgA>, lambda_functor<ArgB> >(a, b)); \
}
#if defined BOOST_LAMBDA_BE
#error "Multiple defines of BOOST_LAMBDA_BE"
#endif
#define BOOST_LAMBDA_BE(OPER_NAME, ACTION, CONSTA, CONSTB, CONST_CONVERSION) \
BOOST_LAMBDA_BE1(OPER_NAME, ACTION, CONSTA, CONSTB, CONST_CONVERSION) \
BOOST_LAMBDA_BE2(OPER_NAME, ACTION, CONSTA, CONSTB, CONST_CONVERSION) \
BOOST_LAMBDA_BE3(OPER_NAME, ACTION, CONSTA, CONSTB, CONST_CONVERSION)
#define BOOST_LAMBDA_EMPTY()
BOOST_LAMBDA_BE(operator+, arithmetic_action<plus_action>, const A, const B, const_copy_argument)
BOOST_LAMBDA_BE(operator-, arithmetic_action<minus_action>, const A, const B, const_copy_argument)
BOOST_LAMBDA_BE(operator*, arithmetic_action<multiply_action>, const A, const B, const_copy_argument)
BOOST_LAMBDA_BE(operator/, arithmetic_action<divide_action>, const A, const B, const_copy_argument)
BOOST_LAMBDA_BE(operator%, arithmetic_action<remainder_action>, const A, const B, const_copy_argument)
BOOST_LAMBDA_BE(operator<<, bitwise_action<leftshift_action>, const A, const B, const_copy_argument)
BOOST_LAMBDA_BE(operator>>, bitwise_action<rightshift_action>, const A, const B, const_copy_argument)
BOOST_LAMBDA_BE(operator&, bitwise_action<and_action>, const A, const B, const_copy_argument)
BOOST_LAMBDA_BE(operator|, bitwise_action<or_action>, const A, const B, const_copy_argument)
BOOST_LAMBDA_BE(operator^, bitwise_action<xor_action>, const A, const B, const_copy_argument)
BOOST_LAMBDA_BE(operator&&, logical_action<and_action>, const A, const B, const_copy_argument)
BOOST_LAMBDA_BE(operator||, logical_action<or_action>, const A, const B, const_copy_argument)
BOOST_LAMBDA_BE(operator<, relational_action<less_action>, const A, const B, const_copy_argument)
BOOST_LAMBDA_BE(operator>, relational_action<greater_action>, const A, const B, const_copy_argument)
BOOST_LAMBDA_BE(operator<=, relational_action<lessorequal_action>, const A, const B, const_copy_argument)
BOOST_LAMBDA_BE(operator>=, relational_action<greaterorequal_action>, const A, const B, const_copy_argument)
BOOST_LAMBDA_BE(operator==, relational_action<equal_action>, const A, const B, const_copy_argument)
BOOST_LAMBDA_BE(operator!=, relational_action<notequal_action>, const A, const B, const_copy_argument)
BOOST_LAMBDA_BE(operator+=, arithmetic_assignment_action<plus_action>, A, const B, reference_argument)
BOOST_LAMBDA_BE(operator-=, arithmetic_assignment_action<minus_action>, A, const B, reference_argument)
BOOST_LAMBDA_BE(operator*=, arithmetic_assignment_action<multiply_action>, A, const B, reference_argument)
BOOST_LAMBDA_BE(operator/=, arithmetic_assignment_action<divide_action>, A, const B, reference_argument)
BOOST_LAMBDA_BE(operator%=, arithmetic_assignment_action<remainder_action>, A, const B, reference_argument)
BOOST_LAMBDA_BE(operator<<=, bitwise_assignment_action<leftshift_action>, A, const B, reference_argument)
BOOST_LAMBDA_BE(operator>>=, bitwise_assignment_action<rightshift_action>, A, const B, reference_argument)
BOOST_LAMBDA_BE(operator&=, bitwise_assignment_action<and_action>, A, const B, reference_argument)
BOOST_LAMBDA_BE(operator|=, bitwise_assignment_action<or_action>, A, const B, reference_argument)
BOOST_LAMBDA_BE(operator^=, bitwise_assignment_action<xor_action>, A, const B, reference_argument)
// A special trick for comma operator for correct preprocessing
#if defined BOOST_LAMBDA_COMMA_OPERATOR_NAME
#error "Multiple defines of BOOST_LAMBDA_COMMA_OPERATOR_NAME"
#endif
#define BOOST_LAMBDA_COMMA_OPERATOR_NAME operator,
BOOST_LAMBDA_BE1(BOOST_LAMBDA_COMMA_OPERATOR_NAME, other_action<comma_action>, const A, const B, const_copy_argument)
BOOST_LAMBDA_BE2(BOOST_LAMBDA_COMMA_OPERATOR_NAME, other_action<comma_action>, const A, const B, const_copy_argument)
BOOST_LAMBDA_BE3(BOOST_LAMBDA_COMMA_OPERATOR_NAME, other_action<comma_action>, const A, const B, const_copy_argument)
namespace detail {
// special cases for ostream& << Any and istream& >> Any ---------------
// the actual stream classes may vary and thus a specialisation for,
// say ostream& does not match (the general case above is chosen).
// Therefore we specialise for non-const reference:
// if the left argument is a stream, we store the stream as reference
// if it is something else, we store a const plain by default
// Note that the overloading is const vs. non-const first argument
#ifdef BOOST_NO_TEMPLATED_STREAMS
template<class T> struct convert_ostream_to_ref_others_to_c_plain_by_default {
typedef typename detail::IF<
boost::is_convertible<T*, std::ostream*>::value,
T&,
typename const_copy_argument <T>::type
>::RET type;
};
template<class T> struct convert_istream_to_ref_others_to_c_plain_by_default {
typedef typename detail::IF<
boost::is_convertible<T*, std::istream*>::value,
T&,
typename const_copy_argument <T>::type
>::RET type;
};
#else
template<class T> struct convert_ostream_to_ref_others_to_c_plain_by_default {
typedef typename detail::IF<
is_instance_of_2<
T, std::basic_ostream
>::value,
T&,
typename const_copy_argument <T>::type
>::RET type;
};
template<class T> struct convert_istream_to_ref_others_to_c_plain_by_default {
typedef typename detail::IF<
is_instance_of_2<
T, std::basic_istream
>::value,
T&,
typename const_copy_argument <T>::type
>::RET type;
};
#endif
} // detail
BOOST_LAMBDA_BE2(operator<<, bitwise_action< leftshift_action>, A, const B, detail::convert_ostream_to_ref_others_to_c_plain_by_default)
BOOST_LAMBDA_BE2(operator>>, bitwise_action< rightshift_action>, A, const B, detail::convert_istream_to_ref_others_to_c_plain_by_default)
// special case for io_manipulators.
// function references cannot be given as arguments to lambda operator
// expressions in general. With << and >> the use of manipulators is
// so common, that specializations are provided to make them work.
template<class Arg, class Ret, class ManipArg>
inline const
lambda_functor<
lambda_functor_base<
bitwise_action<leftshift_action>,
tuple<lambda_functor<Arg>, Ret(&)(ManipArg)>
>
>
operator<<(const lambda_functor<Arg>& a, Ret(&b)(ManipArg))
{
return
lambda_functor_base<
bitwise_action<leftshift_action>,
tuple<lambda_functor<Arg>, Ret(&)(ManipArg)>
>
( tuple<lambda_functor<Arg>, Ret(&)(ManipArg)>(a, b) );
}
template<class Arg, class Ret, class ManipArg>
inline const
lambda_functor<
lambda_functor_base<
bitwise_action<rightshift_action>,
tuple<lambda_functor<Arg>, Ret(&)(ManipArg)>
>
>
operator>>(const lambda_functor<Arg>& a, Ret(&b)(ManipArg))
{
return
lambda_functor_base<
bitwise_action<rightshift_action>,
tuple<lambda_functor<Arg>, Ret(&)(ManipArg)>
>
( tuple<lambda_functor<Arg>, Ret(&)(ManipArg)>(a, b) );
}
// (+ and -) take their arguments as const references.
// This has consquences with pointer artihmetic
// E.g int a[]; ... *a = 1 works but not *(a+1) = 1.
// the result of a+1 would be const
// To make the latter work too,
// non-const arrays are taken as non-const and stored as non-const as well.
#if defined BOOST_LAMBDA_PTR_ARITHMETIC_E1
#error "Multiple defines of BOOST_LAMBDA_PTR_ARITHMETIC_E1"
#endif
#define BOOST_LAMBDA_PTR_ARITHMETIC_E1(OPER_NAME, ACTION, CONSTB) \
template<class Arg, int N, class B> \
inline const \
lambda_functor< \
lambda_functor_base<ACTION, tuple<lambda_functor<Arg>, CONSTB(&)[N]> > \
> \
OPER_NAME (const lambda_functor<Arg>& a, CONSTB(&b)[N]) \
{ \
return \
lambda_functor_base<ACTION, tuple<lambda_functor<Arg>, CONSTB(&)[N]> > \
(tuple<lambda_functor<Arg>, CONSTB(&)[N]>(a, b)); \
}
#if defined BOOST_LAMBDA_PTR_ARITHMETIC_E2
#error "Multiple defines of BOOST_LAMBDA_PTR_ARITHMETIC_E2"
#endif
#define BOOST_LAMBDA_PTR_ARITHMETIC_E2(OPER_NAME, ACTION, CONSTA) \
template<int N, class A, class Arg> \
inline const \
lambda_functor< \
lambda_functor_base<ACTION, tuple<CONSTA(&)[N], lambda_functor<Arg> > > \
> \
OPER_NAME (CONSTA(&a)[N], const lambda_functor<Arg>& b) \
{ \
return \
lambda_functor_base<ACTION, tuple<CONSTA(&)[N], lambda_functor<Arg> > > \
(tuple<CONSTA(&)[N], lambda_functor<Arg> >(a, b)); \
}
BOOST_LAMBDA_PTR_ARITHMETIC_E1(operator+, arithmetic_action<plus_action>, B)
BOOST_LAMBDA_PTR_ARITHMETIC_E2(operator+, arithmetic_action<plus_action>, A)
BOOST_LAMBDA_PTR_ARITHMETIC_E1(operator+, arithmetic_action<plus_action>,const B)
BOOST_LAMBDA_PTR_ARITHMETIC_E2(operator+, arithmetic_action<plus_action>,const A)
//BOOST_LAMBDA_PTR_ARITHMETIC_E1(operator-, arithmetic_action<minus_action>)
// This is not needed, since the result of ptr-ptr is an rvalue anyway
BOOST_LAMBDA_PTR_ARITHMETIC_E2(operator-, arithmetic_action<minus_action>, A)
BOOST_LAMBDA_PTR_ARITHMETIC_E2(operator-, arithmetic_action<minus_action>, const A)
#undef BOOST_LAMBDA_BE1
#undef BOOST_LAMBDA_BE2
#undef BOOST_LAMBDA_BE3
#undef BOOST_LAMBDA_BE
#undef BOOST_LAMBDA_COMMA_OPERATOR_NAME
#undef BOOST_LAMBDA_PTR_ARITHMETIC_E1
#undef BOOST_LAMBDA_PTR_ARITHMETIC_E2
// ---------------------------------------------------------------------
// unary operators -----------------------------------------------------
// ---------------------------------------------------------------------
#if defined BOOST_LAMBDA_UE
#error "Multiple defines of BOOST_LAMBDA_UE"
#endif
#define BOOST_LAMBDA_UE(OPER_NAME, ACTION) \
template<class Arg> \
inline const \
lambda_functor<lambda_functor_base<ACTION, tuple<lambda_functor<Arg> > > > \
OPER_NAME (const lambda_functor<Arg>& a) \
{ \
return \
lambda_functor_base<ACTION, tuple<lambda_functor<Arg> > > \
( tuple<lambda_functor<Arg> >(a) ); \
}
BOOST_LAMBDA_UE(operator+, unary_arithmetic_action<plus_action>)
BOOST_LAMBDA_UE(operator-, unary_arithmetic_action<minus_action>)
BOOST_LAMBDA_UE(operator~, bitwise_action<not_action>)
BOOST_LAMBDA_UE(operator!, logical_action<not_action>)
BOOST_LAMBDA_UE(operator++, pre_increment_decrement_action<increment_action>)
BOOST_LAMBDA_UE(operator--, pre_increment_decrement_action<decrement_action>)
BOOST_LAMBDA_UE(operator*, other_action<contentsof_action>)
BOOST_LAMBDA_UE(operator&, other_action<addressof_action>)
#if defined BOOST_LAMBDA_POSTFIX_UE
#error "Multiple defines of BOOST_LAMBDA_POSTFIX_UE"
#endif
#define BOOST_LAMBDA_POSTFIX_UE(OPER_NAME, ACTION) \
template<class Arg> \
inline const \
lambda_functor<lambda_functor_base<ACTION, tuple<lambda_functor<Arg> > > > \
OPER_NAME (const lambda_functor<Arg>& a, int) \
{ \
return \
lambda_functor_base<ACTION, tuple<lambda_functor<Arg> > > \
( tuple<lambda_functor<Arg> >(a) ); \
}
BOOST_LAMBDA_POSTFIX_UE(operator++, post_increment_decrement_action<increment_action>)
BOOST_LAMBDA_POSTFIX_UE(operator--, post_increment_decrement_action<decrement_action>)
#undef BOOST_LAMBDA_UE
#undef BOOST_LAMBDA_POSTFIX_UE
} // namespace lambda
} // namespace boost
#endif

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// Boost Lambda Library ret.hpp -----------------------------------------
// Copyright (C) 1999, 2000 Jaakko Jarvi (jaakko.jarvi@cs.utu.fi)
//
// 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)
//
// For more information, see www.boost.org
#ifndef BOOST_LAMBDA_RET_HPP
#define BOOST_LAMBDA_RET_HPP
namespace boost {
namespace lambda {
// TODO:
// Add specializations for function references for ret, protect and unlambda
// e.g void foo(); unlambda(foo); fails, as it would add a const qualifier
// for a function type.
// on the other hand unlambda(*foo) does work
// -- ret -------------------------
// the explicit return type template
// TODO: It'd be nice to make ret a nop for other than lambda functors
// but causes an ambiguiyty with gcc (not with KCC), check what is the
// right interpretation.
// // ret for others than lambda functors has no effect
// template <class U, class T>
// inline const T& ret(const T& t) { return t; }
template<class RET, class Arg>
inline const
lambda_functor<
lambda_functor_base<
explicit_return_type_action<RET>,
tuple<lambda_functor<Arg> >
>
>
ret(const lambda_functor<Arg>& a1)
{
return
lambda_functor_base<
explicit_return_type_action<RET>,
tuple<lambda_functor<Arg> >
>
(tuple<lambda_functor<Arg> >(a1));
}
// protect ------------------
// protecting others than lambda functors has no effect
template <class T>
inline const T& protect(const T& t) { return t; }
template<class Arg>
inline const
lambda_functor<
lambda_functor_base<
protect_action,
tuple<lambda_functor<Arg> >
>
>
protect(const lambda_functor<Arg>& a1)
{
return
lambda_functor_base<
protect_action,
tuple<lambda_functor<Arg> >
>
(tuple<lambda_functor<Arg> >(a1));
}
// -------------------------------------------------------------------
// Hides the lambda functorness of a lambda functor.
// After this, the functor is immune to argument substitution, etc.
// This can be used, e.g. to make it safe to pass lambda functors as
// arguments to functions, which might use them as target functions
// note, unlambda and protect are different things. Protect hides the lambda
// functor for one application, unlambda for good.
template <class LambdaFunctor>
class non_lambda_functor
{
LambdaFunctor lf;
public:
// This functor defines the result_type typedef.
// The result type must be deducible without knowing the arguments
template <class SigArgs> struct sig {
typedef typename
LambdaFunctor::inherited::
template sig<typename SigArgs::tail_type>::type type;
};
explicit non_lambda_functor(const LambdaFunctor& a) : lf(a) {}
typename LambdaFunctor::nullary_return_type
operator()() const {
return lf.template
call<typename LambdaFunctor::nullary_return_type>
(cnull_type(), cnull_type(), cnull_type(), cnull_type());
}
template<class A>
typename sig<tuple<const non_lambda_functor, A&> >::type
operator()(A& a) const {
return lf.template call<typename sig<tuple<const non_lambda_functor, A&> >::type >(a, cnull_type(), cnull_type(), cnull_type());
}
template<class A, class B>
typename sig<tuple<const non_lambda_functor, A&, B&> >::type
operator()(A& a, B& b) const {
return lf.template call<typename sig<tuple<const non_lambda_functor, A&, B&> >::type >(a, b, cnull_type(), cnull_type());
}
template<class A, class B, class C>
typename sig<tuple<const non_lambda_functor, A&, B&, C&> >::type
operator()(A& a, B& b, C& c) const {
return lf.template call<typename sig<tuple<const non_lambda_functor, A&, B&, C&> >::type>(a, b, c, cnull_type());
}
};
template <class Arg>
inline const Arg& unlambda(const Arg& a) { return a; }
template <class Arg>
inline const non_lambda_functor<lambda_functor<Arg> >
unlambda(const lambda_functor<Arg>& a)
{
return non_lambda_functor<lambda_functor<Arg> >(a);
}
// Due to a language restriction, lambda functors cannot be made to
// accept non-const rvalue arguments. Usually iterators do not return
// temporaries, but sometimes they do. That's why a workaround is provided.
// Note, that this potentially breaks const correctness, so be careful!
// any lambda functor can be turned into a const_incorrect_lambda_functor
// The operator() takes arguments as consts and then casts constness
// away. So this breaks const correctness!!! but is a necessary workaround
// in some cases due to language limitations.
// Note, that this is not a lambda_functor anymore, so it can not be used
// as a sub lambda expression.
template <class LambdaFunctor>
struct const_incorrect_lambda_functor {
LambdaFunctor lf;
public:
explicit const_incorrect_lambda_functor(const LambdaFunctor& a) : lf(a) {}
template <class SigArgs> struct sig {
typedef typename
LambdaFunctor::inherited::template
sig<typename SigArgs::tail_type>::type type;
};
// The nullary case is not needed (no arguments, no parameter type problems)
template<class A>
typename sig<tuple<const const_incorrect_lambda_functor, A&> >::type
operator()(const A& a) const {
return lf.template call<typename sig<tuple<const const_incorrect_lambda_functor, A&> >::type >(const_cast<A&>(a), cnull_type(), cnull_type(), cnull_type());
}
template<class A, class B>
typename sig<tuple<const const_incorrect_lambda_functor, A&, B&> >::type
operator()(const A& a, const B& b) const {
return lf.template call<typename sig<tuple<const const_incorrect_lambda_functor, A&, B&> >::type >(const_cast<A&>(a), const_cast<B&>(b), cnull_type(), cnull_type());
}
template<class A, class B, class C>
typename sig<tuple<const const_incorrect_lambda_functor, A&, B&, C&> >::type
operator()(const A& a, const B& b, const C& c) const {
return lf.template call<typename sig<tuple<const const_incorrect_lambda_functor, A&, B&, C&> >::type>(const_cast<A&>(a), const_cast<B&>(b), const_cast<C&>(c), cnull_type());
}
};
// ------------------------------------------------------------------------
// any lambda functor can be turned into a const_parameter_lambda_functor
// The operator() takes arguments as const.
// This is useful if lambda functors are called with non-const rvalues.
// Note, that this is not a lambda_functor anymore, so it can not be used
// as a sub lambda expression.
template <class LambdaFunctor>
struct const_parameter_lambda_functor {
LambdaFunctor lf;
public:
explicit const_parameter_lambda_functor(const LambdaFunctor& a) : lf(a) {}
template <class SigArgs> struct sig {
typedef typename
LambdaFunctor::inherited::template
sig<typename SigArgs::tail_type>::type type;
};
// The nullary case is not needed: no arguments, no constness problems.
template<class A>
typename sig<tuple<const const_parameter_lambda_functor, const A&> >::type
operator()(const A& a) const {
return lf.template call<typename sig<tuple<const const_parameter_lambda_functor, const A&> >::type >(a, cnull_type(), cnull_type(), cnull_type());
}
template<class A, class B>
typename sig<tuple<const const_parameter_lambda_functor, const A&, const B&> >::type
operator()(const A& a, const B& b) const {
return lf.template call<typename sig<tuple<const const_parameter_lambda_functor, const A&, const B&> >::type >(a, b, cnull_type(), cnull_type());
}
template<class A, class B, class C>
typename sig<tuple<const const_parameter_lambda_functor, const A&, const B&, const C&>
>::type
operator()(const A& a, const B& b, const C& c) const {
return lf.template call<typename sig<tuple<const const_parameter_lambda_functor, const A&, const B&, const C&> >::type>(a, b, c, cnull_type());
}
};
template <class Arg>
inline const const_incorrect_lambda_functor<lambda_functor<Arg> >
break_const(const lambda_functor<Arg>& lf)
{
return const_incorrect_lambda_functor<lambda_functor<Arg> >(lf);
}
template <class Arg>
inline const const_parameter_lambda_functor<lambda_functor<Arg> >
const_parameters(const lambda_functor<Arg>& lf)
{
return const_parameter_lambda_functor<lambda_functor<Arg> >(lf);
}
// make void ------------------------------------------------
// make_void( x ) turns a lambda functor x with some return type y into
// another lambda functor, which has a void return type
// when called, the original return type is discarded
// we use this action. The action class will be called, which means that
// the wrapped lambda functor is evaluated, but we just don't do anything
// with the result.
struct voidifier_action {
template<class Ret, class A> static void apply(A&) {}
};
template<class Args> struct return_type_N<voidifier_action, Args> {
typedef void type;
};
template<class Arg1>
inline const
lambda_functor<
lambda_functor_base<
action<1, voidifier_action>,
tuple<lambda_functor<Arg1> >
>
>
make_void(const lambda_functor<Arg1>& a1) {
return
lambda_functor_base<
action<1, voidifier_action>,
tuple<lambda_functor<Arg1> >
>
(tuple<lambda_functor<Arg1> > (a1));
}
// for non-lambda functors, make_void does nothing
// (the argument gets evaluated immediately)
template<class Arg1>
inline const
lambda_functor<
lambda_functor_base<do_nothing_action, null_type>
>
make_void(const Arg1& a1) {
return
lambda_functor_base<do_nothing_action, null_type>();
}
// std_functor -----------------------------------------------------
// The STL uses the result_type typedef as the convention to let binders know
// the return type of a function object.
// LL uses the sig template.
// To let LL know that the function object has the result_type typedef
// defined, it can be wrapped with the std_functor function.
// Just inherit form the template parameter (the standard functor),
// and provide a sig template. So we have a class which is still the
// same functor + the sig template.
template<class T>
struct result_type_to_sig : public T {
template<class Args> struct sig { typedef typename T::result_type type; };
result_type_to_sig(const T& t) : T(t) {}
};
template<class F>
inline result_type_to_sig<F> std_functor(const F& f) { return f; }
} // namespace lambda
} // namespace boost
#endif

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// return_type_traits.hpp -- Boost Lambda Library ---------------------------
// Copyright (C) 1999, 2000 Jaakko Jarvi (jaakko.jarvi@cs.utu.fi)
//
// 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)
//
// For more information, see www.boost.org
#ifndef BOOST_LAMBDA_RETURN_TYPE_TRAITS_HPP
#define BOOST_LAMBDA_RETURN_TYPE_TRAITS_HPP
#include "boost/mpl/has_xxx.hpp"
#include <cstddef> // needed for the ptrdiff_t
namespace boost {
namespace lambda {
using ::boost::type_traits::ice_and;
using ::boost::type_traits::ice_or;
using ::boost::type_traits::ice_not;
// Much of the type deduction code for standard arithmetic types
// from Gary Powell
// different arities:
template <class Act, class A1> struct return_type_1; // 1-ary actions
template <class Act, class A1, class A2> struct return_type_2; // 2-ary
template <class Act, class Args> struct return_type_N; // >3- ary
template <class Act, class A1> struct return_type_1_prot;
template <class Act, class A1, class A2> struct return_type_2_prot; // 2-ary
template <class Act, class A1> struct return_type_N_prot; // >3-ary
namespace detail {
template<class> class return_type_deduction_failure {};
// In some cases return type deduction should fail (an invalid lambda
// expression). Sometimes the lambda expression can be ok, the return type
// just is not deducible (user defined operators). Then return type deduction
// should never be entered at all, and the use of ret<> does this.
// However, for nullary lambda functors, return type deduction is always
// entered, and there seems to be no way around this.
// (the return type is part of the prototype of the non-template
// operator()(). The prototype is instantiated, even though the body
// is not.)
// So, in the case the return type deduction should fail, it should not
// fail directly, but rather result in a valid but wrong return type,
// causing a compile time error only if the function is really called.
} // end detail
// return_type_X_prot classes --------------------------------------------
// These classes are the first layer that gets instantiated from the
// lambda_functor_base sig templates. It will check whether
// the action is protectable and one of arguments is "protected" or its
// evaluation will otherwise result in another lambda functor.
// If this is a case, the result type will be another lambda functor.
// The arguments are always non-reference types, except for comma action
// where the right argument can be a reference too. This is because it
// matters (in the builtin case) whether the argument is an lvalue or
// rvalue: int i; i, 1 -> rvalue; 1, i -> lvalue
template <class Act, class A> struct return_type_1_prot {
public:
typedef typename
detail::IF<
// is_protectable<Act>::value && is_lambda_functor<A>::value,
ice_and<is_protectable<Act>::value, is_lambda_functor<A>::value>::value,
lambda_functor<
lambda_functor_base<
Act,
tuple<typename detail::remove_reference_and_cv<A>::type>
>
>,
typename return_type_1<Act, A>::type
>::RET type;
};
// take care of the unavoidable instantiation for nullary case
template<class Act> struct return_type_1_prot<Act, null_type> {
typedef null_type type;
};
// Unary actions (result from unary operators)
// do not have a default return type.
template<class Act, class A> struct return_type_1 {
typedef typename
detail::return_type_deduction_failure<return_type_1> type;
};
namespace detail {
template <class T>
class protect_conversion {
typedef typename boost::remove_reference<T>::type non_ref_T;
public:
// add const to rvalues, so that all rvalues are stored as const in
// the args tuple
typedef typename detail::IF_type<
// boost::is_reference<T>::value && !boost::is_const<non_ref_T>::value,
ice_and<boost::is_reference<T>::value,
ice_not<boost::is_const<non_ref_T>::value>::value>::value,
detail::identity_mapping<T>,
const_copy_argument<non_ref_T> // handles funtion and array
>::type type; // types correctly
};
} // end detail
template <class Act, class A, class B> struct return_type_2_prot {
// experimental feature
// We may have a lambda functor as a result type of a subexpression
// (if protect) has been used.
// Thus, if one of the parameter types is a lambda functor, the result
// is a lambda functor as well.
// We need to make a conservative choise here.
// The resulting lambda functor stores all const reference arguments as
// const copies. References to non-const are stored as such.
// So if the source of the argument is a const open argument, a bound
// argument stored as a const reference, or a function returning a
// const reference, that information is lost. There is no way of
// telling apart 'real const references' from just 'LL internal
// const references' (or it would be really hard)
// The return type is a subclass of lambda_functor, which has a converting
// copy constructor. It can copy any lambda functor, that has the same
// action type and code, and a copy compatible argument tuple.
typedef typename boost::remove_reference<A>::type non_ref_A;
typedef typename boost::remove_reference<B>::type non_ref_B;
typedef typename
detail::IF<
// is_protectable<Act>::value &&
// (is_lambda_functor<A>::value || is_lambda_functor<B>::value),
ice_and<is_protectable<Act>::value,
ice_or<is_lambda_functor<A>::value,
is_lambda_functor<B>::value>::value>::value,
lambda_functor<
lambda_functor_base<
Act,
tuple<typename detail::protect_conversion<A>::type,
typename detail::protect_conversion<B>::type>
>
>,
typename return_type_2<Act, non_ref_A, non_ref_B>::type
>::RET type;
};
// take care of the unavoidable instantiation for nullary case
template<class Act> struct return_type_2_prot<Act, null_type, null_type> {
typedef null_type type;
};
// take care of the unavoidable instantiation for nullary case
template<class Act, class Other> struct return_type_2_prot<Act, Other, null_type> {
typedef null_type type;
};
// take care of the unavoidable instantiation for nullary case
template<class Act, class Other> struct return_type_2_prot<Act, null_type, Other> {
typedef null_type type;
};
// comma is a special case, as the user defined operator can return
// an lvalue (reference) too, hence it must be handled at this level.
template<class A, class B>
struct return_type_2_comma
{
typedef typename boost::remove_reference<A>::type non_ref_A;
typedef typename boost::remove_reference<B>::type non_ref_B;
typedef typename
detail::IF<
// is_protectable<other_action<comma_action> >::value && // it is protectable
// (is_lambda_functor<A>::value || is_lambda_functor<B>::value),
ice_and<is_protectable<other_action<comma_action> >::value, // it is protectable
ice_or<is_lambda_functor<A>::value,
is_lambda_functor<B>::value>::value>::value,
lambda_functor<
lambda_functor_base<
other_action<comma_action>,
tuple<typename detail::protect_conversion<A>::type,
typename detail::protect_conversion<B>::type>
>
>,
typename
return_type_2<other_action<comma_action>, non_ref_A, non_ref_B>::type
>::RET type1;
// if no user defined return_type_2 (or plain_return_type_2) specialization
// matches, then return the righthand argument
typedef typename
detail::IF<
boost::is_same<type1, detail::unspecified>::value,
B,
type1
>::RET type;
};
// currently there are no protectable actions with > 2 args
template<class Act, class Args> struct return_type_N_prot {
typedef typename return_type_N<Act, Args>::type type;
};
// take care of the unavoidable instantiation for nullary case
template<class Act> struct return_type_N_prot<Act, null_type> {
typedef null_type type;
};
// handle different kind of actions ------------------------
// use the return type given in the bind invocation as bind<Ret>(...)
template<int I, class Args, class Ret>
struct return_type_N<function_action<I, Ret>, Args> {
typedef Ret type;
};
// ::result_type support
namespace detail
{
BOOST_MPL_HAS_XXX_TRAIT_DEF(result_type)
template<class F> struct get_result_type
{
typedef typename F::result_type type;
};
template<class F, class A> struct get_sig
{
typedef typename function_adaptor<F>::template sig<A>::type type;
};
} // namespace detail
// Ret is detail::unspecified, so try to deduce return type
template<int I, class Args>
struct return_type_N<function_action<I, detail::unspecified>, Args > {
// in the case of function action, the first element in Args is
// some type of function
typedef typename Args::head_type Func;
typedef typename detail::remove_reference_and_cv<Func>::type plain_Func;
public:
// pass the function to function_adaptor, and get the return type from
// that
typedef typename detail::IF<
detail::has_result_type<plain_Func>::value,
detail::get_result_type<plain_Func>,
detail::get_sig<plain_Func, Args>
>::RET::type type;
};
} // namespace lambda
} // namespace boost
#endif

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// -- select_functions.hpp -- Boost Lambda Library --------------------------
// Copyright (C) 1999, 2000 Jaakko Jarvi (jaakko.jarvi@cs.utu.fi)
//
// 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)
//
// For more information, see http://www.boost.org
#ifndef BOOST_LAMBDA_SELECT_FUNCTIONS_HPP
#define BOOST_LAMBDA_SELECT_FUNCTIONS_HPP
namespace boost {
namespace lambda {
namespace detail {
// select functions -------------------------------
template<class Any, CALL_TEMPLATE_ARGS>
inline Any& select(Any& any, CALL_FORMAL_ARGS) { CALL_USE_ARGS; return any; }
template<class Arg, CALL_TEMPLATE_ARGS>
inline typename Arg::template sig<tuple<CALL_REFERENCE_TYPES> >::type
select ( const lambda_functor<Arg>& op, CALL_FORMAL_ARGS ) {
return op.template call<
typename Arg::template sig<tuple<CALL_REFERENCE_TYPES> >::type
>(CALL_ACTUAL_ARGS);
}
template<class Arg, CALL_TEMPLATE_ARGS>
inline typename Arg::template sig<tuple<CALL_REFERENCE_TYPES> >::type
select ( lambda_functor<Arg>& op, CALL_FORMAL_ARGS) {
return op.template call<
typename Arg::template sig<tuple<CALL_REFERENCE_TYPES> >::type
>(CALL_ACTUAL_ARGS);
}
// ------------------------------------------------------------------------
// select functions where the return type is explicitly given
// Note: on many functions, this return type is just discarded.
// The select functions are inside a class template, and the return type
// is a class template argument.
// The first implementation used function templates with an explicitly
// specified template parameter.
// However, this resulted in ambiguous calls (at least with gcc 2.95.2
// and edg 2.44). Not sure whether the compilers were right or wrong.
template<class RET> struct r_select {
// Any == RET
template<class Any, CALL_TEMPLATE_ARGS>
static
inline RET go (Any& any, CALL_FORMAL_ARGS) { CALL_USE_ARGS; return any; }
template<class Arg, CALL_TEMPLATE_ARGS>
static
inline RET go (const lambda_functor<Arg>& op, CALL_FORMAL_ARGS ) {
return op.template call<RET>(CALL_ACTUAL_ARGS);
}
template<class Arg, CALL_TEMPLATE_ARGS>
static
inline RET go (lambda_functor<Arg>& op, CALL_FORMAL_ARGS ) {
return op.template call<RET>(CALL_ACTUAL_ARGS);
}
};
} // namespace detail
} // namespace lambda
} // namespace boost
#endif

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// Boost Lambda Library suppress_unused.hpp -----------------------------
//
// Copyright (C) 2009 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)
//
// For more information, see www.boost.org
// ------------------------------------------------------------
#ifndef BOOST_LAMBDA_SUPRESS_UNUSED_HPP
#define BOOST_LAMBDA_SUPRESS_UNUSED_HPP
namespace boost {
namespace lambda {
namespace detail {
template<class T>
inline void suppress_unused_variable_warnings(const T&) {}
}
}
}
#endif

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

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// -- lambda.hpp -- Boost Lambda Library -----------------------------------
// Copyright (C) 1999, 2000 Jaakko Jarvi (jaakko.jarvi@cs.utu.fi)
//
// 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)
//
// For more information, see http://lambda.cs.utu.fi
#ifndef BOOST_LAMBDA_LAMBDA_HPP
#define BOOST_LAMBDA_LAMBDA_HPP
#include "boost/lambda/core.hpp"
#ifdef BOOST_NO_FDECL_TEMPLATES_AS_TEMPLATE_TEMPLATE_PARAMS
#include <istream>
#include <ostream>
#endif
#include "boost/lambda/detail/operator_actions.hpp"
#include "boost/lambda/detail/operator_lambda_func_base.hpp"
#include "boost/lambda/detail/operator_return_type_traits.hpp"
#include "boost/lambda/detail/operators.hpp"
#ifndef BOOST_LAMBDA_FAILS_IN_TEMPLATE_KEYWORD_AFTER_SCOPE_OPER
// sorry, member ptr does not work with gcc2.95
#include "boost/lambda/detail/member_ptr.hpp"
#endif
#endif

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// Boost Lambda Library -- loops.hpp ----------------------------------------
// Copyright (C) 1999, 2000 Jaakko Jarvi (jaakko.jarvi@cs.utu.fi)
// Copyright (C) 2000 Gary Powell (powellg@amazon.com)
// Copyright (c) 2001-2002 Joel de Guzman
//
// 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)
//
// For more information, see www.boost.org
// --------------------------------------------------------------------------
#if !defined(BOOST_LAMBDA_LOOPS_HPP)
#define BOOST_LAMBDA_LOOPS_HPP
#include "boost/lambda/core.hpp"
namespace boost {
namespace lambda {
// -- loop control structure actions ----------------------
class forloop_action {};
class forloop_no_body_action {};
class whileloop_action {};
class whileloop_no_body_action {};
class dowhileloop_action {};
class dowhileloop_no_body_action {};
// For loop
template <class Arg1, class Arg2, class Arg3, class Arg4>
inline const
lambda_functor<
lambda_functor_base<
forloop_action,
tuple<lambda_functor<Arg1>, lambda_functor<Arg2>,
lambda_functor<Arg3>, lambda_functor<Arg4> >
>
>
for_loop(const lambda_functor<Arg1>& a1, const lambda_functor<Arg2>& a2,
const lambda_functor<Arg3>& a3, const lambda_functor<Arg4>& a4) {
return
lambda_functor_base<
forloop_action,
tuple<lambda_functor<Arg1>, lambda_functor<Arg2>,
lambda_functor<Arg3>, lambda_functor<Arg4> >
>
( tuple<lambda_functor<Arg1>, lambda_functor<Arg2>,
lambda_functor<Arg3>, lambda_functor<Arg4> >(a1, a2, a3, a4)
);
}
// No body case.
template <class Arg1, class Arg2, class Arg3>
inline const
lambda_functor<
lambda_functor_base<
forloop_no_body_action,
tuple<lambda_functor<Arg1>, lambda_functor<Arg2>, lambda_functor<Arg3> >
>
>
for_loop(const lambda_functor<Arg1>& a1, const lambda_functor<Arg2>& a2,
const lambda_functor<Arg3>& a3) {
return
lambda_functor_base<
forloop_no_body_action,
tuple<lambda_functor<Arg1>, lambda_functor<Arg2>,
lambda_functor<Arg3> >
>
( tuple<lambda_functor<Arg1>, lambda_functor<Arg2>,
lambda_functor<Arg3> >(a1, a2, a3) );
}
// While loop
template <class Arg1, class Arg2>
inline const
lambda_functor<
lambda_functor_base<
whileloop_action,
tuple<lambda_functor<Arg1>, lambda_functor<Arg2> >
>
>
while_loop(const lambda_functor<Arg1>& a1, const lambda_functor<Arg2>& a2) {
return
lambda_functor_base<
whileloop_action,
tuple<lambda_functor<Arg1>, lambda_functor<Arg2> >
>
( tuple<lambda_functor<Arg1>, lambda_functor<Arg2> >(a1, a2));
}
// No body case.
template <class Arg1>
inline const
lambda_functor<
lambda_functor_base<
whileloop_no_body_action,
tuple<lambda_functor<Arg1> >
>
>
while_loop(const lambda_functor<Arg1>& a1) {
return
lambda_functor_base<
whileloop_no_body_action,
tuple<lambda_functor<Arg1> >
>
( tuple<lambda_functor<Arg1> >(a1) );
}
// Do While loop
template <class Arg1, class Arg2>
inline const
lambda_functor<
lambda_functor_base<
dowhileloop_action,
tuple<lambda_functor<Arg1>, lambda_functor<Arg2> >
>
>
do_while_loop(const lambda_functor<Arg1>& a1, const lambda_functor<Arg2>& a2) {
return
lambda_functor_base<
dowhileloop_action,
tuple<lambda_functor<Arg1>, lambda_functor<Arg2> >
>
( tuple<lambda_functor<Arg1>, lambda_functor<Arg2> >(a1, a2));
}
// No body case.
template <class Arg1>
inline const
lambda_functor<
lambda_functor_base<
dowhileloop_no_body_action,
tuple<lambda_functor<Arg1> >
>
>
do_while_loop(const lambda_functor<Arg1>& a1) {
return
lambda_functor_base<
dowhileloop_no_body_action,
tuple<lambda_functor<Arg1> >
>
( tuple<lambda_functor<Arg1> >(a1));
}
// Control loop lambda_functor_base specializations.
// Specialization for for_loop.
template<class Args>
class
lambda_functor_base<forloop_action, Args> {
public:
Args args;
template <class T> struct sig { typedef void type; };
public:
explicit lambda_functor_base(const Args& a) : args(a) {}
template<class RET, CALL_TEMPLATE_ARGS>
RET call(CALL_FORMAL_ARGS) const {
for(detail::select(boost::tuples::get<0>(args), CALL_ACTUAL_ARGS);
detail::select(boost::tuples::get<1>(args), CALL_ACTUAL_ARGS);
detail::select(boost::tuples::get<2>(args), CALL_ACTUAL_ARGS))
detail::select(boost::tuples::get<3>(args), CALL_ACTUAL_ARGS);
}
};
// No body case
template<class Args>
class
lambda_functor_base<forloop_no_body_action, Args> {
public:
Args args;
template <class T> struct sig { typedef void type; };
public:
explicit lambda_functor_base(const Args& a) : args(a) {}
template<class RET, CALL_TEMPLATE_ARGS>
RET call(CALL_FORMAL_ARGS) const {
for(detail::select(boost::tuples::get<0>(args), CALL_ACTUAL_ARGS);
detail::select(boost::tuples::get<1>(args), CALL_ACTUAL_ARGS);
detail::select(boost::tuples::get<2>(args), CALL_ACTUAL_ARGS)) {}
}
};
// Specialization for while_loop.
template<class Args>
class
lambda_functor_base<whileloop_action, Args> {
public:
Args args;
template <class T> struct sig { typedef void type; };
public:
explicit lambda_functor_base(const Args& a) : args(a) {}
template<class RET, CALL_TEMPLATE_ARGS>
RET call(CALL_FORMAL_ARGS) const {
while(detail::select(boost::tuples::get<0>(args), CALL_ACTUAL_ARGS))
detail::select(boost::tuples::get<1>(args), CALL_ACTUAL_ARGS);
}
};
// No body case
template<class Args>
class
lambda_functor_base<whileloop_no_body_action, Args> {
public:
Args args;
template <class T> struct sig { typedef void type; };
public:
explicit lambda_functor_base(const Args& a) : args(a) {}
template<class RET, CALL_TEMPLATE_ARGS>
RET call(CALL_FORMAL_ARGS) const {
while(detail::select(boost::tuples::get<0>(args), CALL_ACTUAL_ARGS)) {}
}
};
// Specialization for do_while_loop.
// Note that the first argument is the condition.
template<class Args>
class
lambda_functor_base<dowhileloop_action, Args> {
public:
Args args;
template <class T> struct sig { typedef void type; };
public:
explicit lambda_functor_base(const Args& a) : args(a) {}
template<class RET, CALL_TEMPLATE_ARGS>
RET call(CALL_FORMAL_ARGS) const {
do {
detail::select(boost::tuples::get<1>(args), CALL_ACTUAL_ARGS);
} while (detail::select(boost::tuples::get<0>(args), CALL_ACTUAL_ARGS) );
}
};
// No body case
template<class Args>
class
lambda_functor_base<dowhileloop_no_body_action, Args> {
public:
Args args;
template <class T> struct sig { typedef void type; };
public:
explicit lambda_functor_base(const Args& a) : args(a) {}
template<class RET, CALL_TEMPLATE_ARGS>
RET call(CALL_FORMAL_ARGS) const {
do {} while (detail::select(boost::tuples::get<0>(args), CALL_ACTUAL_ARGS) );
}
};
// The code below is from Joel de Guzman, some name changes etc.
// has been made.
///////////////////////////////////////////////////////////////////////////////
//
// while_composite
//
// This composite has the form:
//
// while_(condition)
// [
// statement
// ]
//
// While the condition (an lambda_functor) evaluates to true, statement
// (another lambda_functor) is executed. The result type of this is void.
// Note the trailing underscore after while_.
//
///////////////////////////////////////////////////////////////////////////////
template <typename CondT, typename DoT>
struct while_composite {
typedef while_composite<CondT, DoT> self_t;
template <class SigArgs>
struct sig { typedef void type; };
while_composite(CondT const& cond_, DoT const& do__)
: cond(cond_), do_(do__) {}
template <class Ret, CALL_TEMPLATE_ARGS>
Ret call(CALL_FORMAL_ARGS) const
{
while (cond.internal_call(CALL_ACTUAL_ARGS))
do_.internal_call(CALL_ACTUAL_ARGS);
}
CondT cond;
DoT do_;
};
//////////////////////////////////
template <typename CondT>
struct while_gen {
while_gen(CondT const& cond_)
: cond(cond_) {}
template <typename DoT>
lambda_functor<while_composite<
typename as_lambda_functor<CondT>::type,
typename as_lambda_functor<DoT>::type> >
operator[](DoT const& do_) const
{
typedef while_composite<
typename as_lambda_functor<CondT>::type,
typename as_lambda_functor<DoT>::type>
result;
return result(
to_lambda_functor(cond),
to_lambda_functor(do_));
}
CondT cond;
};
//////////////////////////////////
template <typename CondT>
inline while_gen<CondT>
while_(CondT const& cond)
{
return while_gen<CondT>(cond);
}
///////////////////////////////////////////////////////////////////////////////
//
// do_composite
//
// This composite has the form:
//
// do_
// [
// statement
// ]
// .while_(condition)
//
// While the condition (an lambda_functor) evaluates to true, statement
// (another lambda_functor) is executed. The statement is executed at least
// once. The result type of this is void. Note the trailing
// underscore after do_ and the the leading dot and the trailing
// underscore before and after .while_.
//
///////////////////////////////////////////////////////////////////////////////
template <typename DoT, typename CondT>
struct do_composite {
typedef do_composite<DoT, CondT> self_t;
template <class SigArgs>
struct sig { typedef void type; };
do_composite(DoT const& do__, CondT const& cond_)
: do_(do__), cond(cond_) {}
template <class Ret, CALL_TEMPLATE_ARGS>
Ret call(CALL_FORMAL_ARGS) const
{
do
do_.internal_call(CALL_ACTUAL_ARGS);
while (cond.internal_call(CALL_ACTUAL_ARGS));
}
DoT do_;
CondT cond;
};
////////////////////////////////////
template <typename DoT>
struct do_gen2 {
do_gen2(DoT const& do__)
: do_(do__) {}
template <typename CondT>
lambda_functor<do_composite<
typename as_lambda_functor<DoT>::type,
typename as_lambda_functor<CondT>::type> >
while_(CondT const& cond) const
{
typedef do_composite<
typename as_lambda_functor<DoT>::type,
typename as_lambda_functor<CondT>::type>
result;
return result(
to_lambda_functor(do_),
to_lambda_functor(cond));
}
DoT do_;
};
////////////////////////////////////
struct do_gen {
template <typename DoT>
do_gen2<DoT>
operator[](DoT const& do_) const
{
return do_gen2<DoT>(do_);
}
};
do_gen const do_ = do_gen();
///////////////////////////////////////////////////////////////////////////////
//
// for_composite
//
// This statement has the form:
//
// for_(init, condition, step)
// [
// statement
// ]
//
// Where init, condition, step and statement are all lambda_functors. init
// is executed once before entering the for-loop. The for-loop
// exits once condition evaluates to false. At each loop iteration,
// step and statement is called. The result of this statement is
// void. Note the trailing underscore after for_.
//
///////////////////////////////////////////////////////////////////////////////
template <typename InitT, typename CondT, typename StepT, typename DoT>
struct for_composite {
template <class SigArgs>
struct sig { typedef void type; };
for_composite(
InitT const& init_,
CondT const& cond_,
StepT const& step_,
DoT const& do__)
: init(init_), cond(cond_), step(step_), do_(do__) {}
template <class Ret, CALL_TEMPLATE_ARGS>
Ret
call(CALL_FORMAL_ARGS) const
{
for (init.internal_call(CALL_ACTUAL_ARGS); cond.internal_call(CALL_ACTUAL_ARGS); step.internal_call(CALL_ACTUAL_ARGS))
do_.internal_call(CALL_ACTUAL_ARGS);
}
InitT init; CondT cond; StepT step; DoT do_; // lambda_functors
};
//////////////////////////////////
template <typename InitT, typename CondT, typename StepT>
struct for_gen {
for_gen(
InitT const& init_,
CondT const& cond_,
StepT const& step_)
: init(init_), cond(cond_), step(step_) {}
template <typename DoT>
lambda_functor<for_composite<
typename as_lambda_functor<InitT>::type,
typename as_lambda_functor<CondT>::type,
typename as_lambda_functor<StepT>::type,
typename as_lambda_functor<DoT>::type> >
operator[](DoT const& do_) const
{
typedef for_composite<
typename as_lambda_functor<InitT>::type,
typename as_lambda_functor<CondT>::type,
typename as_lambda_functor<StepT>::type,
typename as_lambda_functor<DoT>::type>
result;
return result(
to_lambda_functor(init),
to_lambda_functor(cond),
to_lambda_functor(step),
to_lambda_functor(do_));
}
InitT init; CondT cond; StepT step;
};
//////////////////////////////////
template <typename InitT, typename CondT, typename StepT>
inline for_gen<InitT, CondT, StepT>
for_(InitT const& init, CondT const& cond, StepT const& step)
{
return for_gen<InitT, CondT, StepT>(init, cond, step);
}
} // lambda
} // boost
#endif // BOOST_LAMBDA_LOOPS_HPP

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// -- numeric.hpp -- Boost Lambda Library -----------------------------------
// Copyright (C) 2002 Jaakko Jarvi (jaakko.jarvi@cs.utu.fi)
// Copyright (C) 2002 Gary Powell (gwpowell@hotmail.com)
//
// 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)
//
// For more information, see http://www.boost.org
#ifndef BOOST_LAMBDA_NUMERIC_HPP
#define BOOST_LAMBDA_NUMERIC_HPP
#include "boost/lambda/core.hpp"
#include <numeric>
namespace boost {
namespace lambda {
namespace ll {
// accumulate ---------------------------------
struct accumulate {
template <class Args>
struct sig {
typedef typename boost::remove_const<
typename boost::tuples::element<3, Args>::type
>::type type;
};
template <class A, class B, class C>
C
operator()(A a, B b, C c) const
{ return ::std::accumulate(a, b, c); }
template <class A, class B, class C, class D>
C
operator()(A a, B b, C c, D d) const
{ return ::std::accumulate(a, b, c, d); }
};
// inner_product ---------------------------------
struct inner_product {
template <class Args>
struct sig {
typedef typename boost::remove_const<
typename boost::tuples::element<4, Args>::type
>::type type;
};
template <class A, class B, class C, class D>
D
operator()(A a, B b, C c, D d) const
{ return ::std::inner_product(a, b, c, d); }
template <class A, class B, class C, class D, class E, class F>
D
operator()(A a, B b, C c, D d, E e, F f) const
{ return ::std::inner_product(a, b, c, d, e, f); }
};
// partial_sum ---------------------------------
struct partial_sum {
template <class Args>
struct sig {
typedef typename boost::remove_const<
typename boost::tuples::element<3, Args>::type
>::type type;
};
template <class A, class B, class C>
C
operator()(A a, B b, C c) const
{ return ::std::partial_sum(a, b, c); }
template <class A, class B, class C, class D>
C
operator()(A a, B b, C c, D d) const
{ return ::std::partial_sum(a, b, c, d); }
};
// adjacent_difference ---------------------------------
struct adjacent_difference {
template <class Args>
struct sig {
typedef typename boost::remove_const<
typename boost::tuples::element<3, Args>::type
>::type type;
};
template <class A, class B, class C>
C
operator()(A a, B b, C c) const
{ return ::std::adjacent_difference(a, b, c); }
template <class A, class B, class C, class D>
C
operator()(A a, B b, C c, D d) const
{ return ::std::adjacent_difference(a, b, c, d); }
};
} // end of ll namespace
} // end of lambda namespace
} // end of boost namespace
#endif

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// Boost Lambda Library -- switch.hpp -----------------------------------
//
// Copyright (C) 2000 Gary Powell (powellg@amazon.com)
// Copyright (C) 1999, 2000 Jaakko Jarvi (jaakko.jarvi@cs.utu.fi)
//
// 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)
//
// For more information, see www.boost.org
// --------------------------------------------------------------------------
#if !defined(BOOST_LAMBDA_SWITCH_HPP)
#define BOOST_LAMBDA_SWITCH_HPP
#include "boost/lambda/core.hpp"
#include "boost/lambda/detail/control_constructs_common.hpp"
#include "boost/preprocessor/enum_shifted_params.hpp"
#include "boost/preprocessor/repeat_2nd.hpp"
#include "boost/preprocessor/tuple.hpp"
namespace boost {
namespace lambda {
// Switch actions
template <int N, class Switch1 = null_type, class Switch2 = null_type,
class Switch3 = null_type, class Switch4 = null_type,
class Switch5 = null_type, class Switch6 = null_type,
class Switch7 = null_type, class Switch8 = null_type,
class Switch9 = null_type>
struct switch_action {};
namespace detail {
// templates to represent special lambda functors for the cases in
// switch statements
template <int Value> struct case_label {};
struct default_label {};
template<class Type> struct switch_case_tag {};
// a normal case is represented as:
// tagged_lambda_functor<switch_case_tag<case_label<N> > >, LambdaFunctor>
// the default case as:
// tagged_lambda_functor<switch_case_tag<default_label> >, LambdaFunctor>
} // end detail
/// create switch_case_tag tagged_lambda_functors
template <int CaseValue, class Arg>
inline const
tagged_lambda_functor<
detail::switch_case_tag<detail::case_label<CaseValue> >,
lambda_functor<Arg>
>
case_statement(const lambda_functor<Arg>& a) {
return
tagged_lambda_functor<
detail::switch_case_tag<detail::case_label<CaseValue> >,
lambda_functor<Arg>
>(a);
}
// No case body case.
template <int CaseValue>
inline const
tagged_lambda_functor<
detail::switch_case_tag<detail::case_label<CaseValue> >,
lambda_functor<
lambda_functor_base<
do_nothing_action,
null_type
>
>
>
case_statement() {
return
tagged_lambda_functor<
detail::switch_case_tag<detail::case_label<CaseValue> >,
lambda_functor<
lambda_functor_base<
do_nothing_action,
null_type
>
>
> () ;
}
// default label
template <class Arg>
inline const
tagged_lambda_functor<
detail::switch_case_tag<detail::default_label>,
lambda_functor<Arg>
>
default_statement(const lambda_functor<Arg>& a) {
return
tagged_lambda_functor<
detail::switch_case_tag<detail::default_label>,
lambda_functor<Arg>
>(a);
}
// default lable, no case body case.
inline const
tagged_lambda_functor<
detail::switch_case_tag<detail::default_label>,
lambda_functor<
lambda_functor_base<
do_nothing_action,
null_type
>
>
>
default_statement() {
return
lambda_functor_base<
do_nothing_action,
null_type
> () ;
}
// Specializations for lambda_functor_base of case_statement -----------------
// 0 case type:
// useless (just the condition part) but provided for completeness.
template<class Args>
class
lambda_functor_base<
switch_action<1>,
Args
>
{
public:
Args args;
template <class SigArgs> struct sig { typedef void type; };
public:
explicit lambda_functor_base(const Args& a) : args(a) {}
template<class RET, CALL_TEMPLATE_ARGS>
RET call(CALL_FORMAL_ARGS) const {
detail::select(::boost::tuples::get<1>(args), CALL_ACTUAL_ARGS);
}
};
// 1 case type:
// template<class Args, int Case1>
// class
// lambda_functor_base<
// action<
// 2,
// return_void_action<switch_action<detail::case_label<Case1> > >
// >,
// Args
// >
// {
// Args args;
// public:
// explicit lambda_functor_base(const Args& a) : args(a) {}
// template<class RET, class A, class B, class C>
// RET call(A& a, B& b, C& c) const {
// switch( detail::select(::boost::tuples::get<0>(args), a, b, c) )
// {
// case Case1:
// detail::select(::boost::tuples::get<1>(args), a, b, c);
// break;
// }
// }
// };
// switch with default being the sole label - doesn't make much sense but
// it is there for completeness
// template<class Args>
// class
// lambda_functor_base<
// action<
// 2,
// return_void_action<switch_action<detail::default_label> >
// >,
// Args
// >
// {
// Args args;
// public:
// explicit lambda_functor_base(const Args& a) : args(a) {}
//
// template<class RET, class A, class B, class C>
// RET call(A& a, B& b, C& c) const {
// switch( detail::select(::boost::tuples::get<0>(args), a, b, c) )
// {
// default:
// detail::select(::boost::tuples::get<1>(args), a, b, c);
// break;
// }
// }
// };
// // 2 case type:
// The different specializations are generated with Vesa Karvonen's
// preprocessor library.
// This is just a comment to show what the generated classes look like
// template<class Args, int Case1, int Case2>
// class
// lambda_functor_base<
// action<3,
// return_void_action<
// switch_action<
// detail::case_label<Case1>,
// detail::case_label<Case2>
// >
// >
// >,
// Args
// >
// {
// Args args;
// public:
// explicit lambda_functor_base(const Args& a) : args(a) {}
// template<class RET, class A, class B, class C>
// RET call(A& a, B& b, C& c) const {
// switch( detail::select(::boost::tuples::get<0>(args), a, b, c) )
// {
// case Case1:
// detail::select(::boost::tuples::get<1>(args), a, b, c);
// break;
// case Case2:
// detail::select(::boost::tuples::get<2>(args), a, b, c);
// break;
// }
// }
// };
// template<class Args, int Case1>
// class
// lambda_functor_base<
// action<3,
// return_void_action<
// switch_action<
// detail::case_label<Case1>,
// detail::default_label
// >
// >
// >,
// Args
// >
// {
// Args args;
// public:
// explicit lambda_functor_base(const Args& a) : args(a) {}
// template<class RET, class A, class B, class C>
// RET call(A& a, B& b, C& c) const {
// switch( detail::select(::boost::tuples::get<0>(args), a, b, c) )
// {
// case Case1:
// detail::select(::boost::tuples::get<1>(args), a, b, c);
// break;
// default:
// detail::select(::boost::tuples::get<2>(args), a, b, c);
// break;
// }
// }
// };
// -------------------------
// Some helper preprocessor macros ---------------------------------
// BOOST_LAMBDA_A_I_LIST(N, X) is a list of form X0, X1, ..., XN
// BOOST_LAMBDA_A_I_B_LIST(N, X, Y) is a list of form X0 Y, X1 Y, ..., XN Y
#define BOOST_LAMBDA_A_I(z, i, A) \
BOOST_PP_COMMA_IF(i) BOOST_PP_CAT(A,i)
#define BOOST_LAMBDA_A_I_B(z, i, T) \
BOOST_PP_COMMA_IF(i) BOOST_PP_CAT(BOOST_PP_TUPLE_ELEM(2,0,T),i) BOOST_PP_TUPLE_ELEM(2,1,T)
#define BOOST_LAMBDA_A_I_LIST(i, A) \
BOOST_PP_REPEAT(i,BOOST_LAMBDA_A_I, A)
#define BOOST_LAMBDA_A_I_B_LIST(i, A, B) \
BOOST_PP_REPEAT(i,BOOST_LAMBDA_A_I_B, (A,B))
// Switch related macros -------------------------------------------
#define BOOST_LAMBDA_SWITCH_CASE_BLOCK(z, N, A) \
case Case##N: \
detail::select(::boost::tuples::get<BOOST_PP_INC(N)>(args), CALL_ACTUAL_ARGS); \
break;
#define BOOST_LAMBDA_SWITCH_CASE_BLOCK_LIST(N) \
BOOST_PP_REPEAT(N, BOOST_LAMBDA_SWITCH_CASE_BLOCK, FOO)
// 2 case type:
#define BOOST_LAMBDA_SWITCH_NO_DEFAULT_CASE(N) \
template<class Args, BOOST_LAMBDA_A_I_LIST(N, int Case)> \
class \
lambda_functor_base< \
switch_action<BOOST_PP_INC(N), \
BOOST_LAMBDA_A_I_B_LIST(N, detail::case_label<Case,>) \
>, \
Args \
> \
{ \
public: \
Args args; \
template <class SigArgs> struct sig { typedef void type; }; \
public: \
explicit lambda_functor_base(const Args& a) : args(a) {} \
\
template<class RET, CALL_TEMPLATE_ARGS> \
RET call(CALL_FORMAL_ARGS) const { \
switch( detail::select(::boost::tuples::get<0>(args), CALL_ACTUAL_ARGS) ) \
{ \
BOOST_LAMBDA_SWITCH_CASE_BLOCK_LIST(N) \
} \
} \
};
#define BOOST_LAMBDA_SWITCH_WITH_DEFAULT_CASE(N) \
template< \
class Args BOOST_PP_COMMA_IF(BOOST_PP_DEC(N)) \
BOOST_LAMBDA_A_I_LIST(BOOST_PP_DEC(N), int Case) \
> \
class \
lambda_functor_base< \
switch_action<BOOST_PP_INC(N), \
BOOST_LAMBDA_A_I_B_LIST(BOOST_PP_DEC(N), \
detail::case_label<Case, >) \
BOOST_PP_COMMA_IF(BOOST_PP_DEC(N)) \
detail::default_label \
>, \
Args \
> \
{ \
public: \
Args args; \
template <class SigArgs> struct sig { typedef void type; }; \
public: \
explicit lambda_functor_base(const Args& a) : args(a) {} \
\
template<class RET, CALL_TEMPLATE_ARGS> \
RET call(CALL_FORMAL_ARGS) const { \
switch( detail::select(::boost::tuples::get<0>(args), CALL_ACTUAL_ARGS) ) \
{ \
BOOST_LAMBDA_SWITCH_CASE_BLOCK_LIST(BOOST_PP_DEC(N)) \
default: \
detail::select(::boost::tuples::get<N>(args), CALL_ACTUAL_ARGS); \
break; \
} \
} \
};
// switch_statement bind functions -------------------------------------
// The zero argument case, for completeness sake
inline const
lambda_functor<
lambda_functor_base<
do_nothing_action,
null_type
>
>
switch_statement() {
return
lambda_functor_base<
do_nothing_action,
null_type
>
();
}
// 1 argument case, this is useless as well, just the condition part
template <class TestArg>
inline const
lambda_functor<
lambda_functor_base<
switch_action<1>,
tuple<lambda_functor<TestArg> >
>
>
switch_statement(const lambda_functor<TestArg>& a1) {
return
lambda_functor_base<
switch_action<1>,
tuple< lambda_functor<TestArg> >
>
( tuple<lambda_functor<TestArg> >(a1));
}
#define HELPER(z, N, FOO) \
BOOST_PP_COMMA_IF(N) \
BOOST_PP_CAT( \
const tagged_lambda_functor<detail::switch_case_tag<TagData, \
N>) \
BOOST_PP_COMMA() Arg##N>& a##N
#define HELPER_LIST(N) BOOST_PP_REPEAT(N, HELPER, FOO)
#define BOOST_LAMBDA_SWITCH_STATEMENT(N) \
template <class TestArg, \
BOOST_LAMBDA_A_I_LIST(N, class TagData), \
BOOST_LAMBDA_A_I_LIST(N, class Arg)> \
inline const \
lambda_functor< \
lambda_functor_base< \
switch_action<BOOST_PP_INC(N), \
BOOST_LAMBDA_A_I_LIST(N, TagData) \
>, \
tuple<lambda_functor<TestArg>, BOOST_LAMBDA_A_I_LIST(N, Arg)> \
> \
> \
switch_statement( \
const lambda_functor<TestArg>& ta, \
HELPER_LIST(N) \
) \
{ \
return \
lambda_functor_base< \
switch_action<BOOST_PP_INC(N), \
BOOST_LAMBDA_A_I_LIST(N, TagData) \
>, \
tuple<lambda_functor<TestArg>, BOOST_LAMBDA_A_I_LIST(N, Arg)> \
> \
( tuple<lambda_functor<TestArg>, BOOST_LAMBDA_A_I_LIST(N, Arg)> \
(ta, BOOST_LAMBDA_A_I_LIST(N, a) )); \
}
// Here's the actual generation
#define BOOST_LAMBDA_SWITCH(N) \
BOOST_LAMBDA_SWITCH_NO_DEFAULT_CASE(N) \
BOOST_LAMBDA_SWITCH_WITH_DEFAULT_CASE(N)
// Use this to avoid case 0, these macros work only from case 1 upwards
#define BOOST_LAMBDA_SWITCH_HELPER(z, N, A) \
BOOST_LAMBDA_SWITCH( BOOST_PP_INC(N) )
// Use this to avoid cases 0 and 1, these macros work only from case 2 upwards
#define BOOST_LAMBDA_SWITCH_STATEMENT_HELPER(z, N, A) \
BOOST_LAMBDA_SWITCH_STATEMENT(BOOST_PP_INC(N))
#ifdef BOOST_MSVC
#pragma warning(push)
#pragma warning(disable:4065)
#endif
// up to 9 cases supported (counting default:)
BOOST_PP_REPEAT_2ND(9,BOOST_LAMBDA_SWITCH_HELPER,FOO)
BOOST_PP_REPEAT_2ND(9,BOOST_LAMBDA_SWITCH_STATEMENT_HELPER,FOO)
#ifdef BOOST_MSVC
#pragma warning(pop)
#endif
} // namespace lambda
} // namespace boost
#undef HELPER
#undef HELPER_LIST
#undef BOOST_LAMBDA_SWITCH_HELPER
#undef BOOST_LAMBDA_SWITCH
#undef BOOST_LAMBDA_SWITCH_NO_DEFAULT_CASE
#undef BOOST_LAMBDA_SWITCH_WITH_DEFAULT_CASE
#undef BOOST_LAMBDA_SWITCH_CASE_BLOCK
#undef BOOST_LAMBDA_SWITCH_CASE_BLOCK_LIST
#undef BOOST_LAMBDA_SWITCH_STATEMENT
#undef BOOST_LAMBDA_SWITCH_STATEMENT_HELPER
#endif