boost_1_45_0/libs/spirit/classic/phoenix/example/fundamental/sample10.cpp - nest-learning-thermostat/5.0/boost - Git at Google

 /*=============================================================================
     Phoenix V1.2.1
     Copyright (c) 2001-2003 Joel de Guzman

     Use, modification and distribution is subject to 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)
 ==============================================================================*/
 #include <vector>
 #include <algorithm>
 #include <iostream>

 #define PHOENIX_LIMIT 5
 #include <boost/spirit/include/phoenix1_operators.hpp>
 #include <boost/spirit/include/phoenix1_primitives.hpp>
 #include <boost/spirit/include/phoenix1_composite.hpp>
 #include <boost/spirit/include/phoenix1_special_ops.hpp>
 #include <boost/spirit/include/phoenix1_statements.hpp>
 #include <boost/spirit/include/phoenix1_functions.hpp>

 namespace phoenix {

 ///////////////////////////////////////////////////////////////////////////////
 //
 //  local_tuple
 //
 //      This *is a* tuple like the one we see in TupleT in any actor
 //      base class' eval member function. local_tuple should look and
 //      feel the same as a tupled-args, that's why it is derived from
 //      TupleArgsT. It has an added member, locs which is another tuple
 //      where the local variables will be stored. locs is mutable to
 //      allow read-write access to our locals regardless of
 //      local_tuple's constness (The eval member function accepts it as
 //      a const argument).
 //
 ///////////////////////////////////////////////////////////////////////////////
 template <typename TupleArgsT, typename TupleLocsT>
 struct local_tuple : public TupleArgsT {

     local_tuple(TupleArgsT const& args, TupleLocsT const& locs_)
     :   TupleArgsT(args), locs(locs_) {}

     mutable TupleLocsT locs;
 };

 ///////////////////////////////////////////////////////////////////////////////
 //
 //  local_var_result
 //
 //      This is a return type computer. Given a constant integer N, a
 //      parent index and a tuple, get the Nth local variable type. The
 //      parent index is an integer specifying which parent scope to
 //      access; 0==current scope, 1==parent scope, 2==parent's parent
 //      scope etc.
 //
 //      This is a metaprogram with partial specializations. There is a
 //      general case, a special case for local_tuples and a terminating
 //      special case for local_tuples.
 //
 //      General case: If TupleT is not really a local_tuple, we just return nil_t.
 //
 //      local_tuples case:
 //          Parent index is 0: We get the Nth local variable.
 //          Otherwise: We subclass from local_tuples<N, Parent-1, TupleArgsT>
 //
 ///////////////////////////////////////////////////////////////////////////////
 template <int N, int Parent, typename TupleT>
 struct local_var_result {

     typedef nil_t type;
 };

 //////////////////////////////////
 template <int N, int Parent, typename TupleArgsT, typename TupleLocsT>
 struct local_var_result<N, Parent, local_tuple<TupleArgsT, TupleLocsT> >
 :   public local_var_result<N, Parent-1, TupleArgsT> {};

 //////////////////////////////////
 template <int N, typename TupleArgsT, typename TupleLocsT>
 struct local_var_result<N, 0, local_tuple<TupleArgsT, TupleLocsT> > {

     typedef typename tuple_element<N, TupleLocsT>::type& type;

     static type get(local_tuple<TupleArgsT, TupleLocsT> const& tuple)
     { return tuple.locs[tuple_index<N>()]; }
 };

 ///////////////////////////////////////////////////////////////////////////////
 //
 //  local_var
 //
 //      This class looks so curiously like the argument class. local_var
 //      provides access to the Nth local variable packed in the tuple
 //      duo local_tuple above. Parent specifies the Nth parent scope.
 //      0==current scope, 1==parent scope, 2==parent's parent scope etc.
 //      The member function parent<N>() may be called to provide access
 //      to outer scopes.
 //
 //      Note that the member function eval expects a local_tuple
 //      argument. Otherwise there will be acompile-time error. local_var
 //      primitives only work within the context of a context_composite
 //      (see below).
 //
 //      Provided are some predefined local_var actors for 0..N local
 //      variable access: lvar1..locN.
 //
 ///////////////////////////////////////////////////////////////////////////////
 template <int N, int Parent = 0>
 struct local_var {

     typedef local_var<N, Parent> self_t;

     template <typename TupleT>
     struct result {

         typedef typename local_var_result<N, Parent, TupleT>::type type;
     };

     template <typename TupleT>
     typename actor_result<self_t, TupleT>::type
     eval(TupleT const& tuple) const
     {
         return local_var_result<N, Parent, TupleT>::get(tuple);
     }

     template <int PIndex>
     actor<local_var<N, Parent+PIndex> >
     parent() const
     {
         return local_var<N, Parent+PIndex>();
     }
 };

 //////////////////////////////////
 namespace locals {

     actor<local_var<0> > const result   = local_var<0>();
     actor<local_var<1> > const lvar1    = local_var<1>();
     actor<local_var<2> > const lvar2    = local_var<2>();
     actor<local_var<3> > const lvar3    = local_var<3>();
     actor<local_var<4> > const lvar4    = local_var<4>();
 }


 ///////////////////////////////////////////////////////////////////////////////
 template <int N, int Parent, typename TupleT>
 struct local_func_result {

     typedef nil_t type;
 };

 //////////////////////////////////
 template <int N, int Parent, typename TupleArgsT, typename TupleLocsT>
 struct local_func_result<N, Parent, local_tuple<TupleArgsT, TupleLocsT> >
 :   public local_func_result<N, Parent-1, TupleArgsT> {};

 //////////////////////////////////
 template <int N, typename TupleArgsT, typename TupleLocsT>
 struct local_func_result<N, 0, local_tuple<TupleArgsT, TupleLocsT> > {

     typedef typename actor_result<
         typename tuple_element<N, TupleLocsT>::type,
         local_tuple<TupleArgsT, TupleLocsT>
     >::type type;

     template <typename ArgsT>
     static type eval(local_tuple<ArgsT, TupleLocsT> const& tuple)
     { return tuple.locs[tuple_index<N>()].eval(tuple); }
 };


 template <
     int N, int Parent,
     typename A0 = nil_t,
     typename A1 = nil_t,
     typename A2 = nil_t,
     typename A3 = nil_t,
     typename A4 = nil_t
 >
 struct local_function_actor;

 //////////////////////////////////
 template <int N, int Parent>
 struct local_function_base {

     template <typename TupleT>
     struct result {

         typedef typename local_func_result<N, Parent, TupleT>::type type;
     };
 };

 //////////////////////////////////
 template <int N, int Parent>
 struct local_function_actor<N, Parent, nil_t, nil_t, nil_t, nil_t, nil_t>
 :   public local_function_base<N, Parent> {

     template <typename TupleArgsT, typename TupleLocsT>
     typename local_func_result<
         N, Parent, local_tuple<TupleArgsT, TupleLocsT> >::type
     eval(local_tuple<TupleArgsT, TupleLocsT> const& args) const
     {
         typedef local_tuple<TupleArgsT, TupleLocsT> local_tuple_t;
         typedef tuple<> tuple_t;
         tuple_t local_args;

         local_tuple<tuple_t, TupleLocsT> local_context(local_args, args.locs);
         return local_func_result<
             N, Parent, local_tuple_t>
         ::eval(local_context);
     }
 };

 //////////////////////////////////
 template <int N, int Parent,
     typename A0>
 struct local_function_actor<N, Parent, A0, nil_t, nil_t, nil_t, nil_t>
 :   public local_function_base<N, Parent> {

     local_function_actor(
         A0 const& _0)
     :   a0(_0) {}

     template <typename TupleArgsT, typename TupleLocsT>
     typename local_func_result<
         N, Parent, local_tuple<TupleArgsT, TupleLocsT> >::type
     eval(local_tuple<TupleArgsT, TupleLocsT> const& args) const
     {
         typedef local_tuple<TupleArgsT, TupleLocsT> local_tuple_t;
         typename actor_result<A0, local_tuple_t>::type r0 = a0.eval(args);

         typedef tuple<
             typename actor_result<A0, local_tuple_t>::type
         > tuple_t;
         tuple_t local_args(r0);

         local_tuple<tuple_t, TupleLocsT> local_context(local_args, args.locs);
         return local_func_result<
             N, Parent, local_tuple_t>
         ::eval(local_context);
     }

     A0 a0; //  actors
 };

 namespace impl {

     template <
         int N, int Parent,
         typename T0 = nil_t,
         typename T1 = nil_t,
         typename T2 = nil_t,
         typename T3 = nil_t,
         typename T4 = nil_t
     >
     struct make_local_function_actor {

         typedef local_function_actor<
             N, Parent,
             typename as_actor<T0>::type,
             typename as_actor<T1>::type,
             typename as_actor<T2>::type,
             typename as_actor<T3>::type,
             typename as_actor<T4>::type
         > composite_type;

         typedef actor<composite_type> type;
     };
 }


 template <int N, int Parent = 0>
 struct local_function {

     actor<local_function_actor<N, Parent> >
     operator()() const
     {
         return local_function_actor<N, Parent>();
     }

     template <typename T0>
     typename impl::make_local_function_actor<N, Parent, T0>::type
     operator()(T0 const& _0) const
     {
         return impl::make_local_function_actor<N, Parent, T0>::composite_type(_0);
     }

     template <int PIndex>
     local_function<N, Parent+PIndex>
     parent() const
     {
         return local_function<N, Parent+PIndex>();
     }
 };

 //////////////////////////////////
 namespace locals {

     local_function<1> const lfun1     = local_function<1>();
     local_function<2> const lfun2     = local_function<2>();
     local_function<3> const lfun3     = local_function<3>();
     local_function<4> const lfun4     = local_function<4>();
 }


 ///////////////////////////////////////////////////////////////////////////////
 //
 //  context_composite
 //
 //      This class encapsulates an actor and some local variable
 //      initializers packed in a tuple.
 //
 //      context_composite is just like a proxy and delegates the actual
 //      evaluation to the actor. The actor does the actual work. In the
 //      eval member function, before invoking the embedded actor's eval
 //      member function, we first stuff an instance of our locals and
 //      bundle both 'args' and 'locals' in a local_tuple. This
 //      local_tuple instance is created in the stack initializing it
 //      with our locals member. We then pass this local_tuple instance
 //      as an argument to the actor's eval member function.
 //
 ///////////////////////////////////////////////////////////////////////////////
 template <typename ActorT, typename LocsT>
 struct context_composite {

     typedef context_composite<ActorT, LocsT> self_t;

     template <typename TupleT>
     struct result { typedef typename tuple_element<0, LocsT>::type type; };

     context_composite(ActorT const& actor_, LocsT const& locals_)
     :   actor(actor_), locals(locals_) {}

     template <typename TupleT>
     typename tuple_element<0, LocsT>::type
     eval(TupleT const& args) const
     {
         local_tuple<TupleT, LocsT>  local_context(args, locals);
         actor.eval(local_context);
         return local_context.locs[tuple_index<0>()];
     }

     ActorT actor;
     LocsT locals;
 };

 ///////////////////////////////////////////////////////////////////////////////
 //
 //  context_gen
 //
 //      At construction time, this class is given some local var-
 //      initializers packed in a tuple. We just store this for later.
 //      The operator[] of this class creates the actual context_composite
 //      given an actor. This is responsible for the construct
 //      context<types>[actor].
 //
 ///////////////////////////////////////////////////////////////////////////////
 template <typename LocsT>
 struct context_gen {

     context_gen(LocsT const& locals_)
     :   locals(locals_) {}

     template <typename ActorT>
     actor<context_composite<typename as_actor<ActorT>::type, LocsT> >
     operator[](ActorT const& actor)
     {
         return context_composite<typename as_actor<ActorT>::type, LocsT>
             (as_actor<ActorT>::convert(actor), locals);
     }

     LocsT locals;
 };

 ///////////////////////////////////////////////////////////////////////////////
 //
 //    Front end generator functions. These generators are overloaded for
 //    1..N local variables. context<T0,... TN>(i0,...iN) generate
 //    context_gen objects (see above).
 //
 ///////////////////////////////////////////////////////////////////////////////
 template <typename T0>
 inline context_gen<tuple<T0> >
 context()
 {
     typedef tuple<T0> tuple_t;
     return context_gen<tuple_t>(tuple_t(T0()));
 }

 //////////////////////////////////
 template <typename T0, typename T1>
 inline context_gen<tuple<T0, T1> >
 context(
     T1 const& _1 = T1()
 )
 {
     typedef tuple<T0, T1> tuple_t;
     return context_gen<tuple_t>(tuple_t(T0(), _1));
 }

 //////////////////////////////////
 template <typename T0, typename T1, typename T2>
 inline context_gen<tuple<T0, T1, T2> >
 context(
     T1 const& _1 = T1(),
     T2 const& _2 = T2()
 )
 {
     typedef tuple<T0, T1, T2> tuple_t;
     return context_gen<tuple_t>(tuple_t(T0(), _1, _2));
 }

 //////////////////////////////////
 template <typename T0, typename T1, typename T2, typename T3>
 inline context_gen<tuple<T0, T1, T2, T3> >
 context(
     T1 const& _1 = T1(),
     T2 const& _2 = T2(),
     T3 const& _3 = T3()
 )
 {
     typedef tuple<T0, T1, T2, T3> tuple_t;
     return context_gen<tuple_t>(tuple_t(T0(), _1, _2, _3));
 }

 //////////////////////////////////
 template <typename T0, typename T1, typename T2, typename T3, typename T4>
 inline context_gen<tuple<T0, T1, T2, T3, T4> >
 context(
     T1 const& _1 = T1(),
     T2 const& _2 = T2(),
     T3 const& _3 = T3(),
     T4 const& _4 = T4()
 )
 {
     typedef tuple<T0, T1, T2, T3, T4> tuple_t;
     return context_gen<tuple_t>(tuple_t(T0(), _1, _2, _3, _4));
 }


 ///////////////////////////////////////////////////////////////////////////////
 }

 //////////////////////////////////
 using namespace std;
 using namespace phoenix;
 using namespace phoenix::locals;

 //////////////////////////////////
 int
 main()
 {
     int _10 = 10;

 #ifndef __BORLANDC__

     context<nil_t>
     (
         1000,                   //  lvar1: local int variable
         cout << arg1 << '\n',   //  lfun2: local function w/ 1 argument (arg1)
         lvar1 * 2,              //  lfun3: local function that accesses local variable lvar1
         lfun2(2 * arg1)         //  lfun4: local function that calls local function lfun2
     )
     [
         lfun2(arg1 + 2000),
         lfun2(val(5000) * 2),
         lfun2(lvar1 + lfun3()),
         lfun4(val(55)),
         cout << lvar1 << '\n',
         cout << lfun3() << '\n',
         cout << val("bye bye\n")
     ]

     (_10);

 #else   //  Borland does not like local variables w/ local functions
         //  we can have local variables (see sample 7..9) *OR*
         //  local functions (this: sample 10) but not both
         //  Sigh... Borland :-{

     context<nil_t>
     (
         12345,
         cout << arg1 << '\n'
     )
     [
         lfun2(arg1 + 687),
         lfun2(val(9999) * 2),
         cout << val("bye bye\n")
     ]

     (_10);

 #endif

     return 0;
 }
	/*=============================================================================
	Phoenix V1.2.1
	Copyright (c) 2001-2003 Joel de Guzman

	Use, modification and distribution is subject to 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)
	==============================================================================*/
	#include <vector>
	#include <algorithm>
	#include <iostream>

	#define PHOENIX_LIMIT 5
	#include <boost/spirit/include/phoenix1_operators.hpp>
	#include <boost/spirit/include/phoenix1_primitives.hpp>
	#include <boost/spirit/include/phoenix1_composite.hpp>
	#include <boost/spirit/include/phoenix1_special_ops.hpp>
	#include <boost/spirit/include/phoenix1_statements.hpp>
	#include <boost/spirit/include/phoenix1_functions.hpp>

	namespace phoenix {

	///////////////////////////////////////////////////////////////////////////////
	//
	// local_tuple
	//
	// This is a tuple like the one we see in TupleT in any actor
	// base class' eval member function. local_tuple should look and
	// feel the same as a tupled-args, that's why it is derived from
	// TupleArgsT. It has an added member, locs which is another tuple
	// where the local variables will be stored. locs is mutable to
	// allow read-write access to our locals regardless of
	// local_tuple's constness (The eval member function accepts it as
	// a const argument).
	//
	///////////////////////////////////////////////////////////////////////////////
	template <typename TupleArgsT, typename TupleLocsT>
	struct local_tuple : public TupleArgsT {

	local_tuple(TupleArgsT const& args, TupleLocsT const& locs_)
	: TupleArgsT(args), locs(locs_) {}

	mutable TupleLocsT locs;
	};

	///////////////////////////////////////////////////////////////////////////////
	//
	// local_var_result
	//
	// This is a return type computer. Given a constant integer N, a
	// parent index and a tuple, get the Nth local variable type. The
	// parent index is an integer specifying which parent scope to
	// access; 0==current scope, 1==parent scope, 2==parent's parent
	// scope etc.
	//
	// This is a metaprogram with partial specializations. There is a
	// general case, a special case for local_tuples and a terminating
	// special case for local_tuples.
	//
	// General case: If TupleT is not really a local_tuple, we just return nil_t.
	//
	// local_tuples case:
	// Parent index is 0: We get the Nth local variable.
	// Otherwise: We subclass from local_tuples<N, Parent-1, TupleArgsT>
	//
	///////////////////////////////////////////////////////////////////////////////
	template <int N, int Parent, typename TupleT>
	struct local_var_result {

	typedef nil_t type;
	};

	//////////////////////////////////
	template <int N, int Parent, typename TupleArgsT, typename TupleLocsT>
	struct local_var_result<N, Parent, local_tuple<TupleArgsT, TupleLocsT> >
	: public local_var_result<N, Parent-1, TupleArgsT> {};

	//////////////////////////////////
	template <int N, typename TupleArgsT, typename TupleLocsT>
	struct local_var_result<N, 0, local_tuple<TupleArgsT, TupleLocsT> > {

	typedef typename tuple_element<N, TupleLocsT>::type& type;

	static type get(local_tuple<TupleArgsT, TupleLocsT> const& tuple)
	{ return tuple.locs[tuple_index<N>()]; }
	};

	///////////////////////////////////////////////////////////////////////////////
	//
	// local_var
	//
	// This class looks so curiously like the argument class. local_var
	// provides access to the Nth local variable packed in the tuple
	// duo local_tuple above. Parent specifies the Nth parent scope.
	// 0==current scope, 1==parent scope, 2==parent's parent scope etc.
	// The member function parent<N>() may be called to provide access
	// to outer scopes.
	//
	// Note that the member function eval expects a local_tuple
	// argument. Otherwise there will be acompile-time error. local_var
	// primitives only work within the context of a context_composite
	// (see below).
	//
	// Provided are some predefined local_var actors for 0..N local
	// variable access: lvar1..locN.
	//
	///////////////////////////////////////////////////////////////////////////////
	template <int N, int Parent = 0>
	struct local_var {

	typedef local_var<N, Parent> self_t;

	template <typename TupleT>
	struct result {

	typedef typename local_var_result<N, Parent, TupleT>::type type;
	};

	template <typename TupleT>
	typename actor_result<self_t, TupleT>::type
	eval(TupleT const& tuple) const
	{
	return local_var_result<N, Parent, TupleT>::get(tuple);
	}

	template <int PIndex>
	actor<local_var<N, Parent+PIndex> >
	parent() const
	{
	return local_var<N, Parent+PIndex>();
	}
	};

	//////////////////////////////////
	namespace locals {

	actor<local_var<0> > const result = local_var<0>();
	actor<local_var<1> > const lvar1 = local_var<1>();
	actor<local_var<2> > const lvar2 = local_var<2>();
	actor<local_var<3> > const lvar3 = local_var<3>();
	actor<local_var<4> > const lvar4 = local_var<4>();
	}









	///////////////////////////////////////////////////////////////////////////////
	template <int N, int Parent, typename TupleT>
	struct local_func_result {

	typedef nil_t type;
	};

	//////////////////////////////////
	template <int N, int Parent, typename TupleArgsT, typename TupleLocsT>
	struct local_func_result<N, Parent, local_tuple<TupleArgsT, TupleLocsT> >
	: public local_func_result<N, Parent-1, TupleArgsT> {};

	//////////////////////////////////
	template <int N, typename TupleArgsT, typename TupleLocsT>
	struct local_func_result<N, 0, local_tuple<TupleArgsT, TupleLocsT> > {

	typedef typename actor_result<
	typename tuple_element<N, TupleLocsT>::type,
	local_tuple<TupleArgsT, TupleLocsT>
	>::type type;

	template <typename ArgsT>
	static type eval(local_tuple<ArgsT, TupleLocsT> const& tuple)
	{ return tuple.locs[tuple_index<N>()].eval(tuple); }
	};








	template <
	int N, int Parent,
	typename A0 = nil_t,
	typename A1 = nil_t,
	typename A2 = nil_t,
	typename A3 = nil_t,
	typename A4 = nil_t
	>
	struct local_function_actor;

	//////////////////////////////////
	template <int N, int Parent>
	struct local_function_base {

	template <typename TupleT>
	struct result {

	typedef typename local_func_result<N, Parent, TupleT>::type type;
	};
	};

	//////////////////////////////////
	template <int N, int Parent>
	struct local_function_actor<N, Parent, nil_t, nil_t, nil_t, nil_t, nil_t>
	: public local_function_base<N, Parent> {

	template <typename TupleArgsT, typename TupleLocsT>
	typename local_func_result<
	N, Parent, local_tuple<TupleArgsT, TupleLocsT> >::type
	eval(local_tuple<TupleArgsT, TupleLocsT> const& args) const
	{
	typedef local_tuple<TupleArgsT, TupleLocsT> local_tuple_t;
	typedef tuple<> tuple_t;
	tuple_t local_args;

	local_tuple<tuple_t, TupleLocsT> local_context(local_args, args.locs);
	return local_func_result<
	N, Parent, local_tuple_t>
	::eval(local_context);
	}
	};

	//////////////////////////////////
	template <int N, int Parent,
	typename A0>
	struct local_function_actor<N, Parent, A0, nil_t, nil_t, nil_t, nil_t>
	: public local_function_base<N, Parent> {

	local_function_actor(
	A0 const& _0)
	: a0(_0) {}

	template <typename TupleArgsT, typename TupleLocsT>
	typename local_func_result<
	N, Parent, local_tuple<TupleArgsT, TupleLocsT> >::type
	eval(local_tuple<TupleArgsT, TupleLocsT> const& args) const
	{
	typedef local_tuple<TupleArgsT, TupleLocsT> local_tuple_t;
	typename actor_result<A0, local_tuple_t>::type r0 = a0.eval(args);

	typedef tuple<
	typename actor_result<A0, local_tuple_t>::type
	> tuple_t;
	tuple_t local_args(r0);

	local_tuple<tuple_t, TupleLocsT> local_context(local_args, args.locs);
	return local_func_result<
	N, Parent, local_tuple_t>
	::eval(local_context);
	}

	A0 a0; // actors
	};

	namespace impl {

	template <
	int N, int Parent,
	typename T0 = nil_t,
	typename T1 = nil_t,
	typename T2 = nil_t,
	typename T3 = nil_t,
	typename T4 = nil_t
	>
	struct make_local_function_actor {

	typedef local_function_actor<
	N, Parent,
	typename as_actor<T0>::type,
	typename as_actor<T1>::type,
	typename as_actor<T2>::type,
	typename as_actor<T3>::type,
	typename as_actor<T4>::type
	> composite_type;

	typedef actor<composite_type> type;
	};
	}



	template <int N, int Parent = 0>
	struct local_function {

	actor<local_function_actor<N, Parent> >
	operator()() const
	{
	return local_function_actor<N, Parent>();
	}

	template <typename T0>
	typename impl::make_local_function_actor<N, Parent, T0>::type
	operator()(T0 const& _0) const
	{
	return impl::make_local_function_actor<N, Parent, T0>::composite_type(_0);
	}

	template <int PIndex>
	local_function<N, Parent+PIndex>
	parent() const
	{
	return local_function<N, Parent+PIndex>();
	}
	};

	//////////////////////////////////
	namespace locals {

	local_function<1> const lfun1 = local_function<1>();
	local_function<2> const lfun2 = local_function<2>();
	local_function<3> const lfun3 = local_function<3>();
	local_function<4> const lfun4 = local_function<4>();
	}






	///////////////////////////////////////////////////////////////////////////////
	//
	// context_composite
	//
	// This class encapsulates an actor and some local variable
	// initializers packed in a tuple.
	//
	// context_composite is just like a proxy and delegates the actual
	// evaluation to the actor. The actor does the actual work. In the
	// eval member function, before invoking the embedded actor's eval
	// member function, we first stuff an instance of our locals and
	// bundle both 'args' and 'locals' in a local_tuple. This
	// local_tuple instance is created in the stack initializing it
	// with our locals member. We then pass this local_tuple instance
	// as an argument to the actor's eval member function.
	//
	///////////////////////////////////////////////////////////////////////////////
	template <typename ActorT, typename LocsT>
	struct context_composite {

	typedef context_composite<ActorT, LocsT> self_t;

	template <typename TupleT>
	struct result { typedef typename tuple_element<0, LocsT>::type type; };

	context_composite(ActorT const& actor_, LocsT const& locals_)
	: actor(actor_), locals(locals_) {}

	template <typename TupleT>
	typename tuple_element<0, LocsT>::type
	eval(TupleT const& args) const
	{
	local_tuple<TupleT, LocsT> local_context(args, locals);
	actor.eval(local_context);
	return local_context.locs[tuple_index<0>()];
	}

	ActorT actor;
	LocsT locals;
	};

	///////////////////////////////////////////////////////////////////////////////
	//
	// context_gen
	//
	// At construction time, this class is given some local var-
	// initializers packed in a tuple. We just store this for later.
	// The operator[] of this class creates the actual context_composite
	// given an actor. This is responsible for the construct
	// context<types>[actor].
	//
	///////////////////////////////////////////////////////////////////////////////
	template <typename LocsT>
	struct context_gen {

	context_gen(LocsT const& locals_)
	: locals(locals_) {}

	template <typename ActorT>
	actor<context_composite<typename as_actor<ActorT>::type, LocsT> >
	operator[](ActorT const& actor)
	{
	return context_composite<typename as_actor<ActorT>::type, LocsT>
	(as_actor<ActorT>::convert(actor), locals);
	}

	LocsT locals;
	};

	///////////////////////////////////////////////////////////////////////////////
	//
	// Front end generator functions. These generators are overloaded for
	// 1..N local variables. context<T0,... TN>(i0,...iN) generate
	// context_gen objects (see above).
	//
	///////////////////////////////////////////////////////////////////////////////
	template <typename T0>
	inline context_gen<tuple<T0> >
	context()
	{
	typedef tuple<T0> tuple_t;
	return context_gen<tuple_t>(tuple_t(T0()));
	}

	//////////////////////////////////
	template <typename T0, typename T1>
	inline context_gen<tuple<T0, T1> >
	context(
	T1 const& _1 = T1()
	)
	{
	typedef tuple<T0, T1> tuple_t;
	return context_gen<tuple_t>(tuple_t(T0(), _1));
	}

	//////////////////////////////////
	template <typename T0, typename T1, typename T2>
	inline context_gen<tuple<T0, T1, T2> >
	context(
	T1 const& _1 = T1(),
	T2 const& _2 = T2()
	)
	{
	typedef tuple<T0, T1, T2> tuple_t;
	return context_gen<tuple_t>(tuple_t(T0(), _1, _2));
	}

	//////////////////////////////////
	template <typename T0, typename T1, typename T2, typename T3>
	inline context_gen<tuple<T0, T1, T2, T3> >
	context(
	T1 const& _1 = T1(),
	T2 const& _2 = T2(),
	T3 const& _3 = T3()
	)
	{
	typedef tuple<T0, T1, T2, T3> tuple_t;
	return context_gen<tuple_t>(tuple_t(T0(), _1, _2, _3));
	}

	//////////////////////////////////
	template <typename T0, typename T1, typename T2, typename T3, typename T4>
	inline context_gen<tuple<T0, T1, T2, T3, T4> >
	context(
	T1 const& _1 = T1(),
	T2 const& _2 = T2(),
	T3 const& _3 = T3(),
	T4 const& _4 = T4()
	)
	{
	typedef tuple<T0, T1, T2, T3, T4> tuple_t;
	return context_gen<tuple_t>(tuple_t(T0(), _1, _2, _3, _4));
	}












	///////////////////////////////////////////////////////////////////////////////
	}

	//////////////////////////////////
	using namespace std;
	using namespace phoenix;
	using namespace phoenix::locals;

	//////////////////////////////////
	int
	main()
	{
	int _10 = 10;

	#ifndef __BORLANDC__

	context<nil_t>
	(
	1000, // lvar1: local int variable
	cout << arg1 << '\n', // lfun2: local function w/ 1 argument (arg1)
	lvar1 * 2, // lfun3: local function that accesses local variable lvar1
	lfun2(2 * arg1) // lfun4: local function that calls local function lfun2
	)
	[
	lfun2(arg1 + 2000),
	lfun2(val(5000) * 2),
	lfun2(lvar1 + lfun3()),
	lfun4(val(55)),
	cout << lvar1 << '\n',
	cout << lfun3() << '\n',
	cout << val("bye bye\n")
	]

	(_10);

	#else // Borland does not like local variables w/ local functions
	// we can have local variables (see sample 7..9) OR
	// local functions (this: sample 10) but not both
	// Sigh... Borland :-{

	context<nil_t>
	(
	12345,
	cout << arg1 << '\n'
	)
	[
	lfun2(arg1 + 687),
	lfun2(val(9999) * 2),
	cout << val("bye bye\n")
	]

	(_10);

	#endif

	return 0;
	}