boost_1_45_0/libs/proto/example/mixed.cpp - nest-learning-thermostat/5.0/boost - Git at Google

 //[ Mixed
 ///////////////////////////////////////////////////////////////////////////////
 //  Copyright 2008 Eric Niebler. 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)
 //
 // This is an example of using BOOST_PROTO_DEFINE_OPERATORS to Protofy
 // expressions using std::vector<> and std::list, non-proto types. It is a port
 // of the Mixed example from PETE.
 // (http://www.codesourcery.com/pooma/download.html).

 #include <list>
 #include <cmath>
 #include <vector>
 #include <complex>
 #include <iostream>
 #include <stdexcept>
 #include <boost/proto/core.hpp>
 #include <boost/proto/debug.hpp>
 #include <boost/proto/context.hpp>
 #include <boost/proto/transform.hpp>
 #include <boost/utility/enable_if.hpp>
 #include <boost/typeof/std/list.hpp>
 #include <boost/typeof/std/vector.hpp>
 #include <boost/typeof/std/complex.hpp>
 #include <boost/type_traits/remove_reference.hpp>
 namespace proto = boost::proto;
 namespace mpl = boost::mpl;
 using proto::_;

 template<typename Expr>
 struct MixedExpr;

 template<typename Iter>
 struct iterator_wrapper
 {
     typedef Iter iterator;

     explicit iterator_wrapper(Iter iter)
       : it(iter)
     {}

     Iter it;
 };

 struct begin : proto::callable
 {
     template<class Sig>
     struct result;

     template<class This, class Cont>
     struct result<This(Cont)>
       : proto::result_of::as_expr<
             iterator_wrapper<typename boost::remove_reference<Cont>::type::const_iterator>
         >
     {};

     template<typename Cont>
     typename result<begin(Cont const &)>::type
     operator ()(Cont const &cont) const
     {
         iterator_wrapper<typename Cont::const_iterator> it(cont.begin());
         return proto::as_expr(it);
     }
 };

 // Here is a grammar that replaces vector and list terminals with their
 // begin iterators
 struct Begin
   : proto::or_<
         proto::when< proto::terminal< std::vector<_, _> >, begin(proto::_value) >
       , proto::when< proto::terminal< std::list<_, _> >, begin(proto::_value) >
       , proto::when< proto::terminal<_> >
       , proto::when< proto::nary_expr<_, proto::vararg<Begin> > >
     >
 {};

 // Here is an evaluation context that dereferences iterator
 // terminals.
 struct DereferenceCtx
 {
     // Unless this is an iterator terminal, use the
     // default evaluation context
     template<typename Expr, typename EnableIf = void>
     struct eval
       : proto::default_eval<Expr, DereferenceCtx const>
     {};

     // Dereference iterator terminals.
     template<typename Expr>
     struct eval<
         Expr
       , typename boost::enable_if<
             proto::matches<Expr, proto::terminal<iterator_wrapper<_> > >
         >::type
     >
     {
         typedef typename proto::result_of::value<Expr>::type IteratorWrapper;
         typedef typename IteratorWrapper::iterator iterator;
         typedef typename std::iterator_traits<iterator>::reference result_type;

         result_type operator ()(Expr &expr, DereferenceCtx const &) const
         {
             return *proto::value(expr).it;
         }
     };
 };

 // Here is an evaluation context that increments iterator
 // terminals.
 struct IncrementCtx
 {
     // Unless this is an iterator terminal, use the
     // default evaluation context
     template<typename Expr, typename EnableIf = void>
     struct eval
       : proto::null_eval<Expr, IncrementCtx const>
     {};

     // advance iterator terminals.
     template<typename Expr>
     struct eval<
         Expr
       , typename boost::enable_if<
             proto::matches<Expr, proto::terminal<iterator_wrapper<_> > >
         >::type
     >
     {
         typedef void result_type;

         result_type operator ()(Expr &expr, IncrementCtx const &) const
         {
             ++proto::value(expr).it;
         }
     };
 };

 // A grammar which matches all the assignment operators,
 // so we can easily disable them.
 struct AssignOps
   : proto::switch_<struct AssignOpsCases>
 {};

 // Here are the cases used by the switch_ above.
 struct AssignOpsCases
 {
     template<typename Tag, int D = 0> struct case_  : proto::not_<_> {};

     template<int D> struct case_< proto::tag::plus_assign, D >         : _ {};
     template<int D> struct case_< proto::tag::minus_assign, D >        : _ {};
     template<int D> struct case_< proto::tag::multiplies_assign, D >   : _ {};
     template<int D> struct case_< proto::tag::divides_assign, D >      : _ {};
     template<int D> struct case_< proto::tag::modulus_assign, D >      : _ {};
     template<int D> struct case_< proto::tag::shift_left_assign, D >   : _ {};
     template<int D> struct case_< proto::tag::shift_right_assign, D >  : _ {};
     template<int D> struct case_< proto::tag::bitwise_and_assign, D >  : _ {};
     template<int D> struct case_< proto::tag::bitwise_or_assign, D >   : _ {};
     template<int D> struct case_< proto::tag::bitwise_xor_assign, D >  : _ {};
 };

 // An expression conforms to the MixedGrammar if it is a terminal or some
 // op that is not an assignment op. (Assignment will be handled specially.)
 struct MixedGrammar
   : proto::or_<
         proto::terminal<_>
       , proto::and_<
             proto::nary_expr<_, proto::vararg<MixedGrammar> >
           , proto::not_<AssignOps>
         >
     >
 {};

 // Expressions in the MixedDomain will be wrapped in MixedExpr<>
 // and must conform to the MixedGrammar
 struct MixedDomain
   : proto::domain<proto::generator<MixedExpr>, MixedGrammar>
 {};

 // Here is MixedExpr, a wrapper for expression types in the MixedDomain.
 template<typename Expr>
 struct MixedExpr
   : proto::extends<Expr, MixedExpr<Expr>, MixedDomain>
 {
     explicit MixedExpr(Expr const &expr)
       : proto::extends<Expr, MixedExpr<Expr>, MixedDomain>(expr)
     {}
 private:
     // hide this:
     using proto::extends<Expr, MixedExpr<Expr>, MixedDomain>::operator [];
 };

 // Define a trait type for detecting vector and list terminals, to
 // be used by the BOOST_PROTO_DEFINE_OPERATORS macro below.
 template<typename T>
 struct IsMixed
   : mpl::false_
 {};

 template<typename T, typename A>
 struct IsMixed<std::list<T, A> >
   : mpl::true_
 {};

 template<typename T, typename A>
 struct IsMixed<std::vector<T, A> >
   : mpl::true_
 {};

 namespace MixedOps
 {
     // This defines all the overloads to make expressions involving
     // std::vector to build expression templates.
     BOOST_PROTO_DEFINE_OPERATORS(IsMixed, MixedDomain)

     struct assign_op
     {
         template<typename T, typename U>
         void operator ()(T &t, U const &u) const
         {
             t = u;
         }
     };

     struct plus_assign_op
     {
         template<typename T, typename U>
         void operator ()(T &t, U const &u) const
         {
             t += u;
         }
     };

     struct minus_assign_op
     {
         template<typename T, typename U>
         void operator ()(T &t, U const &u) const
         {
             t -= u;
         }
     };

     struct sin_
     {
         template<typename Sig>
         struct result;

         template<typename This, typename Arg>
         struct result<This(Arg)>
           : boost::remove_const<typename boost::remove_reference<Arg>::type>
         {};

         template<typename Arg>
         Arg operator ()(Arg const &a) const
         {
             return std::sin(a);
         }
     };

     template<typename A>
     typename proto::result_of::make_expr<
         proto::tag::function
       , MixedDomain
       , sin_ const
       , A const &
     >::type sin(A const &a)
     {
         return proto::make_expr<proto::tag::function, MixedDomain>(sin_(), boost::ref(a));
     }

     template<typename FwdIter, typename Expr, typename Op>
     void evaluate(FwdIter begin, FwdIter end, Expr const &expr, Op op)
     {
         IncrementCtx const inc = {};
         DereferenceCtx const deref = {};
         typename boost::result_of<Begin(Expr const &)>::type expr2 = Begin()(expr);
         for(; begin != end; ++begin)
         {
             op(*begin, proto::eval(expr2, deref));
             proto::eval(expr2, inc);
         }
     }

     // Add-assign to a vector from some expression.
     template<typename T, typename A, typename Expr>
     std::vector<T, A> &assign(std::vector<T, A> &arr, Expr const &expr)
     {
         evaluate(arr.begin(), arr.end(), proto::as_expr<MixedDomain>(expr), assign_op());
         return arr;
     }

     // Add-assign to a list from some expression.
     template<typename T, typename A, typename Expr>
     std::list<T, A> &assign(std::list<T, A> &arr, Expr const &expr)
     {
         evaluate(arr.begin(), arr.end(), proto::as_expr<MixedDomain>(expr), assign_op());
         return arr;
     }

     // Add-assign to a vector from some expression.
     template<typename T, typename A, typename Expr>
     std::vector<T, A> &operator +=(std::vector<T, A> &arr, Expr const &expr)
     {
         evaluate(arr.begin(), arr.end(), proto::as_expr<MixedDomain>(expr), plus_assign_op());
         return arr;
     }

     // Add-assign to a list from some expression.
     template<typename T, typename A, typename Expr>
     std::list<T, A> &operator +=(std::list<T, A> &arr, Expr const &expr)
     {
         evaluate(arr.begin(), arr.end(), proto::as_expr<MixedDomain>(expr), plus_assign_op());
         return arr;
     }

     // Minus-assign to a vector from some expression.
     template<typename T, typename A, typename Expr>
     std::vector<T, A> &operator -=(std::vector<T, A> &arr, Expr const &expr)
     {
         evaluate(arr.begin(), arr.end(), proto::as_expr<MixedDomain>(expr), minus_assign_op());
         return arr;
     }

     // Minus-assign to a list from some expression.
     template<typename T, typename A, typename Expr>
     std::list<T, A> &operator -=(std::list<T, A> &arr, Expr const &expr)
     {
         evaluate(arr.begin(), arr.end(), proto::as_expr<MixedDomain>(expr), minus_assign_op());
         return arr;
     }
 }

 int main()
 {
     using namespace MixedOps;

     int n = 10;
     std::vector<int> a,b,c,d;
     std::list<double> e;
     std::list<std::complex<double> > f;

     int i;
     for(i = 0;i < n; ++i)
     {
         a.push_back(i);
         b.push_back(2*i);
         c.push_back(3*i);
         d.push_back(i);
         e.push_back(0.0);
         f.push_back(std::complex<double>(1.0, 1.0));
     }

     MixedOps::assign(b, 2);
     MixedOps::assign(d, a + b * c);
     a += if_else(d < 30, b, c);

     MixedOps::assign(e, c);
     e += e - 4 / (c + 1);

     f -= sin(0.1 * e * std::complex<double>(0.2, 1.2));

     std::list<double>::const_iterator ei = e.begin();
     std::list<std::complex<double> >::const_iterator fi = f.begin();
     for (i = 0; i < n; ++i)
     {
         std::cout
             << "a(" << i << ") = " << a[i]
             << " b(" << i << ") = " << b[i]
             << " c(" << i << ") = " << c[i]
             << " d(" << i << ") = " << d[i]
             << " e(" << i << ") = " << *ei++
             << " f(" << i << ") = " << *fi++
             << std::endl;
     }
 }
 //]
	//[ Mixed
	///////////////////////////////////////////////////////////////////////////////
	// Copyright 2008 Eric Niebler. 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)
	//
	// This is an example of using BOOST_PROTO_DEFINE_OPERATORS to Protofy
	// expressions using std::vector<> and std::list, non-proto types. It is a port
	// of the Mixed example from PETE.
	// (http://www.codesourcery.com/pooma/download.html).

	#include <list>
	#include <cmath>
	#include <vector>
	#include <complex>
	#include <iostream>
	#include <stdexcept>
	#include <boost/proto/core.hpp>
	#include <boost/proto/debug.hpp>
	#include <boost/proto/context.hpp>
	#include <boost/proto/transform.hpp>
	#include <boost/utility/enable_if.hpp>
	#include <boost/typeof/std/list.hpp>
	#include <boost/typeof/std/vector.hpp>
	#include <boost/typeof/std/complex.hpp>
	#include <boost/type_traits/remove_reference.hpp>
	namespace proto = boost::proto;
	namespace mpl = boost::mpl;
	using proto::_;

	template<typename Expr>
	struct MixedExpr;

	template<typename Iter>
	struct iterator_wrapper
	{
	typedef Iter iterator;

	explicit iterator_wrapper(Iter iter)
	: it(iter)
	{}

	Iter it;
	};

	struct begin : proto::callable
	{
	template<class Sig>
	struct result;

	template<class This, class Cont>
	struct result<This(Cont)>
	: proto::result_of::as_expr<
	iterator_wrapper<typename boost::remove_reference<Cont>::type::const_iterator>
	>
	{};

	template<typename Cont>
	typename result<begin(Cont const &)>::type
	operator ()(Cont const &cont) const
	{
	iterator_wrapper<typename Cont::const_iterator> it(cont.begin());
	return proto::as_expr(it);
	}
	};

	// Here is a grammar that replaces vector and list terminals with their
	// begin iterators
	struct Begin
	: proto::or_<
	proto::when< proto::terminal< std::vector<_, _> >, begin(proto::_value) >
	, proto::when< proto::terminal< std::list<_, _> >, begin(proto::_value) >
	, proto::when< proto::terminal<_> >
	, proto::when< proto::nary_expr<_, proto::vararg<Begin> > >
	>
	{};

	// Here is an evaluation context that dereferences iterator
	// terminals.
	struct DereferenceCtx
	{
	// Unless this is an iterator terminal, use the
	// default evaluation context
	template<typename Expr, typename EnableIf = void>
	struct eval
	: proto::default_eval<Expr, DereferenceCtx const>
	{};

	// Dereference iterator terminals.
	template<typename Expr>
	struct eval<
	Expr
	, typename boost::enable_if<
	proto::matches<Expr, proto::terminal<iterator_wrapper<_> > >
	>::type
	>
	{
	typedef typename proto::result_of::value<Expr>::type IteratorWrapper;
	typedef typename IteratorWrapper::iterator iterator;
	typedef typename std::iterator_traits<iterator>::reference result_type;

	result_type operator ()(Expr &expr, DereferenceCtx const &) const
	{
	return *proto::value(expr).it;
	}
	};
	};

	// Here is an evaluation context that increments iterator
	// terminals.
	struct IncrementCtx
	{
	// Unless this is an iterator terminal, use the
	// default evaluation context
	template<typename Expr, typename EnableIf = void>
	struct eval
	: proto::null_eval<Expr, IncrementCtx const>
	{};

	// advance iterator terminals.
	template<typename Expr>
	struct eval<
	Expr
	, typename boost::enable_if<
	proto::matches<Expr, proto::terminal<iterator_wrapper<_> > >
	>::type
	>
	{
	typedef void result_type;

	result_type operator ()(Expr &expr, IncrementCtx const &) const
	{
	++proto::value(expr).it;
	}
	};
	};

	// A grammar which matches all the assignment operators,
	// so we can easily disable them.
	struct AssignOps
	: proto::switch_<struct AssignOpsCases>
	{};

	// Here are the cases used by the switch_ above.
	struct AssignOpsCases
	{
	template<typename Tag, int D = 0> struct case_ : proto::not_<_> {};

	template<int D> struct case_< proto::tag::plus_assign, D > : _ {};
	template<int D> struct case_< proto::tag::minus_assign, D > : _ {};
	template<int D> struct case_< proto::tag::multiplies_assign, D > : _ {};
	template<int D> struct case_< proto::tag::divides_assign, D > : _ {};
	template<int D> struct case_< proto::tag::modulus_assign, D > : _ {};
	template<int D> struct case_< proto::tag::shift_left_assign, D > : _ {};
	template<int D> struct case_< proto::tag::shift_right_assign, D > : _ {};
	template<int D> struct case_< proto::tag::bitwise_and_assign, D > : _ {};
	template<int D> struct case_< proto::tag::bitwise_or_assign, D > : _ {};
	template<int D> struct case_< proto::tag::bitwise_xor_assign, D > : _ {};
	};

	// An expression conforms to the MixedGrammar if it is a terminal or some
	// op that is not an assignment op. (Assignment will be handled specially.)
	struct MixedGrammar
	: proto::or_<
	proto::terminal<_>
	, proto::and_<
	proto::nary_expr<_, proto::vararg<MixedGrammar> >
	, proto::not_<AssignOps>
	>
	>
	{};

	// Expressions in the MixedDomain will be wrapped in MixedExpr<>
	// and must conform to the MixedGrammar
	struct MixedDomain
	: proto::domain<proto::generator<MixedExpr>, MixedGrammar>
	{};

	// Here is MixedExpr, a wrapper for expression types in the MixedDomain.
	template<typename Expr>
	struct MixedExpr
	: proto::extends<Expr, MixedExpr<Expr>, MixedDomain>
	{
	explicit MixedExpr(Expr const &expr)
	: proto::extends<Expr, MixedExpr<Expr>, MixedDomain>(expr)
	{}
	private:
	// hide this:
	using proto::extends<Expr, MixedExpr<Expr>, MixedDomain>::operator [];
	};

	// Define a trait type for detecting vector and list terminals, to
	// be used by the BOOST_PROTO_DEFINE_OPERATORS macro below.
	template<typename T>
	struct IsMixed
	: mpl::false_
	{};

	template<typename T, typename A>
	struct IsMixed<std::list<T, A> >
	: mpl::true_
	{};

	template<typename T, typename A>
	struct IsMixed<std::vector<T, A> >
	: mpl::true_
	{};

	namespace MixedOps
	{
	// This defines all the overloads to make expressions involving
	// std::vector to build expression templates.
	BOOST_PROTO_DEFINE_OPERATORS(IsMixed, MixedDomain)

	struct assign_op
	{
	template<typename T, typename U>
	void operator ()(T &t, U const &u) const
	{
	t = u;
	}
	};

	struct plus_assign_op
	{
	template<typename T, typename U>
	void operator ()(T &t, U const &u) const
	{
	t += u;
	}
	};

	struct minus_assign_op
	{
	template<typename T, typename U>
	void operator ()(T &t, U const &u) const
	{
	t -= u;
	}
	};

	struct sin_
	{
	template<typename Sig>
	struct result;

	template<typename This, typename Arg>
	struct result<This(Arg)>
	: boost::remove_const<typename boost::remove_reference<Arg>::type>
	{};

	template<typename Arg>
	Arg operator ()(Arg const &a) const
	{
	return std::sin(a);
	}
	};

	template<typename A>
	typename proto::result_of::make_expr<
	proto::tag::function
	, MixedDomain
	, sin_ const
	, A const &
	>::type sin(A const &a)
	{
	return proto::make_expr<proto::tag::function, MixedDomain>(sin_(), boost::ref(a));
	}

	template<typename FwdIter, typename Expr, typename Op>
	void evaluate(FwdIter begin, FwdIter end, Expr const &expr, Op op)
	{
	IncrementCtx const inc = {};
	DereferenceCtx const deref = {};
	typename boost::result_of<Begin(Expr const &)>::type expr2 = Begin()(expr);
	for(; begin != end; ++begin)
	{
	op(*begin, proto::eval(expr2, deref));
	proto::eval(expr2, inc);
	}
	}

	// Add-assign to a vector from some expression.
	template<typename T, typename A, typename Expr>
	std::vector<T, A> &assign(std::vector<T, A> &arr, Expr const &expr)
	{
	evaluate(arr.begin(), arr.end(), proto::as_expr<MixedDomain>(expr), assign_op());
	return arr;
	}

	// Add-assign to a list from some expression.
	template<typename T, typename A, typename Expr>
	std::list<T, A> &assign(std::list<T, A> &arr, Expr const &expr)
	{
	evaluate(arr.begin(), arr.end(), proto::as_expr<MixedDomain>(expr), assign_op());
	return arr;
	}

	// Add-assign to a vector from some expression.
	template<typename T, typename A, typename Expr>
	std::vector<T, A> &operator +=(std::vector<T, A> &arr, Expr const &expr)
	{
	evaluate(arr.begin(), arr.end(), proto::as_expr<MixedDomain>(expr), plus_assign_op());
	return arr;
	}

	// Add-assign to a list from some expression.
	template<typename T, typename A, typename Expr>
	std::list<T, A> &operator +=(std::list<T, A> &arr, Expr const &expr)
	{
	evaluate(arr.begin(), arr.end(), proto::as_expr<MixedDomain>(expr), plus_assign_op());
	return arr;
	}

	// Minus-assign to a vector from some expression.
	template<typename T, typename A, typename Expr>
	std::vector<T, A> &operator -=(std::vector<T, A> &arr, Expr const &expr)
	{
	evaluate(arr.begin(), arr.end(), proto::as_expr<MixedDomain>(expr), minus_assign_op());
	return arr;
	}

	// Minus-assign to a list from some expression.
	template<typename T, typename A, typename Expr>
	std::list<T, A> &operator -=(std::list<T, A> &arr, Expr const &expr)
	{
	evaluate(arr.begin(), arr.end(), proto::as_expr<MixedDomain>(expr), minus_assign_op());
	return arr;
	}
	}

	int main()
	{
	using namespace MixedOps;

	int n = 10;
	std::vector<int> a,b,c,d;
	std::list<double> e;
	std::list<std::complex<double> > f;

	int i;
	for(i = 0;i < n; ++i)
	{
	a.push_back(i);
	b.push_back(2*i);
	c.push_back(3*i);
	d.push_back(i);
	e.push_back(0.0);
	f.push_back(std::complex<double>(1.0, 1.0));
	}

	MixedOps::assign(b, 2);
	MixedOps::assign(d, a + b * c);
	a += if_else(d < 30, b, c);

	MixedOps::assign(e, c);
	e += e - 4 / (c + 1);

	f -= sin(0.1 * e * std::complex<double>(0.2, 1.2));

	std::list<double>::const_iterator ei = e.begin();
	std::list<std::complex<double> >::const_iterator fi = f.begin();
	for (i = 0; i < n; ++i)
	{
	std::cout
	<< "a(" << i << ") = " << a[i]
	<< " b(" << i << ") = " << b[i]
	<< " c(" << i << ") = " << c[i]
	<< " d(" << i << ") = " << d[i]
	<< " e(" << i << ") = " << *ei++
	<< " f(" << i << ") = " << *fi++
	<< std::endl;
	}
	}
	//]