//[ VirtualMember
// 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 example demonstrates how to use BOOST_PROTO_EXTENDS_MEMBERS()
// to add "virtual" data members to expressions within a domain. For
// instance, with Phoenix you can create a lambda expression such as
//
// if_(_1 > 0)[ std::cout << _2 ].else_[ std::cout << _3 ]
//
// In the above expression, "else_" is a so-called virtual data member
// of the expression "if_(_1 > 0)[ std::cout << _2 ]". This example
// shows how to implement the ".else_" syntax with Proto.
//
// ****WARNING****WARNING****WARNING****WARNING****WARNING****WARNING****
// * The virtual data member feature is experimental and can change at *
// * any time. Use it at your own risk. *
// **********************************************************************
#if defined(_MSC_VER) && _MSC_VER == 1310
#error "Sorry, this example doesn\'t work with MSVC 7.1"
#endif
#include <iostream>
#include <boost/config.hpp>
#include <boost/detail/workaround.hpp>
#include <boost/mpl/eval_if.hpp>
#include <boost/mpl/min_max.hpp>
#include <boost/mpl/next_prior.hpp>
#include <boost/fusion/include/at.hpp>
#include <boost/fusion/include/vector.hpp>
#include <boost/typeof/std/ostream.hpp>
#include <boost/proto/proto.hpp>
namespace mpl = boost::mpl;
namespace proto = boost::proto;
namespace fusion = boost::fusion;
using proto::_;
namespace mini_lambda
{
// A callable PolymorphicFunctionObject that wraps
// fusion::at()
struct at : proto::callable
{
template<class Sig>
struct result;
template<class This, class Vector, class N>
struct result<This(Vector, N)>
: fusion::result_of::at<
typename boost::remove_reference<Vector>::type
, typename boost::remove_reference<N>::type
>
{};
template<class Vector, class N>
typename fusion::result_of::at<Vector const, N>::type
operator()(Vector const &vector, N) const
{
return fusion::at<N>(vector);
}
};
// An MPL IntegralConstant
template<class N>
struct placeholder
{
typedef N type;
typedef typename N::tag tag;
typedef typename N::next next;
typedef typename N::prior prior;
typedef typename N::value_type value_type;
static const value_type value = N::value;
};
// Some keyword types for our lambda DSEL
namespace keyword
{
struct if_ {};
struct else_ {};
struct do_ {};
struct while_ {};
struct try_ {};
struct catch_ {};
}
// Forward declaration for the mini-lambda grammar
struct grammar;
// A callable PolymorphicFunctionObject that evaluates
// if/then/else expressions.
struct eval_if_else : proto::callable
{
typedef void result_type;
template<typename If, typename Then, typename Else, typename Args>
void operator()(If const &if_, Then const &then_, Else const &else_, Args const &args) const
{
if(grammar()(if_, 0, args))
{
grammar()(then_, 0, args);
}
else
{
grammar()(else_, 0, args);
}
}
};
// Forward declaration for the mini-lambda expression wrapper
template<class E>
struct expression;
// The grammar for mini-lambda expressions with transforms for
// evaluating the lambda expression.
struct grammar
: proto::or_<
// When evaluating a placeholder, use the placeholder
// to index into the "data" parameter, which is a fusion
// vector containing the arguments to the lambda expression.
proto::when<
proto::terminal<placeholder<_> >
, at(proto::_data, proto::_value)
>
// When evaluating if/then/else expressions of the form
// "if_( E0 )[ E1 ].else_[ E2 ]", pass E0, E1 and E2 to
// eval_if_else along with the "data" parameter. Note the
// use of proto::member<> to match binary expressions like
// "X.Y" where "Y" is a virtual data member.
, proto::when<
proto::subscript<
proto::member<
proto::subscript<
proto::function<
proto::terminal<keyword::if_>
, grammar
>
, grammar
>
, proto::terminal<keyword::else_>
>
, grammar
>
, eval_if_else(
proto::_right(proto::_left(proto::_left(proto::_left)))
, proto::_right(proto::_left(proto::_left))
, proto::_right
, proto::_data
)
>
, proto::otherwise<
proto::_default<grammar>
>
>
{};
// Define the mini-lambda domain, in which all expressions are
// wrapped in mini_lambda::expression.
struct domain
: proto::domain<proto::pod_generator<expression> >
{};
// A simple transform for computing the arity of
// a lambda expression.
struct arity_of
: proto::or_<
proto::when<
proto::terminal< placeholder<_> >
, mpl::next<proto::_value>()
>
, proto::when<
proto::terminal<_>
, mpl::int_<0>()
>
, proto::otherwise<
proto::fold<
_
, mpl::int_<0>()
, mpl::max<arity_of, proto::_state>()
>
>
>
{};
// Here is the mini-lambda expression wrapper. It serves two purposes:
// 1) To define operator() overloads that evaluate the lambda expression, and
// 2) To define virtual data members like "else_" so that we can write
// expressions like "if_(X)[Y].else_[Z]".
template<class E>
struct expression
{
BOOST_PROTO_BASIC_EXTENDS(E, expression<E>, domain)
BOOST_PROTO_EXTENDS_ASSIGN()
BOOST_PROTO_EXTENDS_SUBSCRIPT()
// Use BOOST_PROTO_EXTENDS_MEMBERS() to define "virtual"
// data members that all expressions in the mini-lambda
// domain will have. They can be used to create expressions
// like "if_(x)[y].else_[z]" and "do_[y].while_(z)".
BOOST_PROTO_EXTENDS_MEMBERS(
((keyword::else_, else_))
((keyword::while_, while_))
((keyword::catch_, catch_))
)
// Calculate the arity of this lambda expression
static int const arity = boost::result_of<arity_of(E)>::type::value;
// Define overloads of operator() that evaluate the lambda
// expression for up to 3 arguments.
// Don't try to compute the return type of the lambda if
// it isn't nullary.
typename mpl::eval_if_c<
0 != arity
, mpl::identity<void>
, boost::result_of<grammar(
E const &
, int const &
, fusion::vector<> &
)>
>::type
operator()() const
{
BOOST_MPL_ASSERT_RELATION(arity, ==, 0);
fusion::vector<> args;
return grammar()(proto_base(), 0, args);
}
#define BOOST_PROTO_LOCAL_MACRO( \
N, typename_A, A_const_ref, A_const_ref_a, a \
) \
template<typename_A(N)> \
typename boost::result_of<grammar( \
E const & \
, int const & \
, fusion::vector<A_const_ref(N)> & \
)>::type \
operator ()(A_const_ref_a(N)) const \
{ \
BOOST_MPL_ASSERT_RELATION(arity, <=, N); \
fusion::vector<A_const_ref(N)> args(a(N)); \
return grammar()(proto_base(), 0, args); \
}
// Repeats BOOST_PROTO_LOCAL_MACRO macro for N=1 to 3
// inclusive (because there are only 3 placeholders)
#define BOOST_PROTO_LOCAL_a BOOST_PROTO_a
#define BOOST_PROTO_LOCAL_LIMITS (1, 3)
#include BOOST_PROTO_LOCAL_ITERATE()
};
namespace placeholders
{
typedef placeholder<mpl::int_<0> > _1_t;
typedef placeholder<mpl::int_<1> > _2_t;
typedef placeholder<mpl::int_<2> > _3_t;
// Define some placeholders
expression<proto::terminal<_1_t>::type> const _1 = {{{}}};
expression<proto::terminal<_2_t>::type> const _2 = {{{}}};
expression<proto::terminal<_3_t>::type> const _3 = {{{}}};
// Define the if_() statement
template<typename E>
typename proto::result_of::make_expr<proto::tag::function, domain
, keyword::if_
, E const &
>::type const
if_(E const &e)
{
return proto::make_expr<proto::tag::function, domain>(
keyword::if_()
, boost::ref(e)
);
}
}
using placeholders::if_;
}
int main()
{
using namespace mini_lambda::placeholders;
// OK, we can create if/then/else lambda expressions
// and evaluate them.
if_(_1 > 0)
[
std::cout << _2 << '\n'
]
.else_
[
std::cout << _3 << '\n'
]
(-42, "positive", "non-positive");
// Even though all expressions in the mini-lambda
// domain have members named else_, while_, and catch_,
// they all occupy the same byte in the expression.
BOOST_MPL_ASSERT_RELATION(sizeof(_1), ==, 2);
return 0;
}
//]
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