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

 /*=============================================================================
     Copyright (c) 2001-2003 Dan Nuffer
     Copyright (c) 2002-2003 Joel de Guzman
     http://spirit.sourceforge.net/

     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)
 =============================================================================*/
 ////////////////////////////////////////////////////////////////////////////
 //
 //  Full calculator example using STL functors
 //  This is discussed in the "Functional" chapter in the Spirit User's Guide.
 //
 //  Ported to Spirit v1.5 from v1.2/1.3 example by Dan Nuffer
 //  [ JDG 9/18/2002 ]
 //
 ////////////////////////////////////////////////////////////////////////////
 #include <boost/spirit/include/classic_core.hpp>
 #include <iostream>
 #include <stack>
 #include <functional>
 #include <string>

 ////////////////////////////////////////////////////////////////////////////
 using namespace std;
 using namespace BOOST_SPIRIT_CLASSIC_NS;

 ////////////////////////////////////////////////////////////////////////////
 //
 //  Semantic actions
 //
 ////////////////////////////////////////////////////////////////////////////
 struct push_int
 {
     push_int(stack<long>& eval_)
     : eval(eval_) {}

     void operator()(char const* str, char const* /*end*/) const
     {
         long n = strtol(str, 0, 10);
         eval.push(n);
         cout << "push\t" << long(n) << endl;
     }

     stack<long>& eval;
 };

 template <typename op>
 struct do_op
 {
     do_op(op const& the_op, stack<long>& eval_)
     : m_op(the_op), eval(eval_) {}

     void operator()(char const*, char const*) const
     {
         long rhs = eval.top();
         eval.pop();
         long lhs = eval.top();
         eval.pop();

         cout << "popped " << lhs << " and " << rhs << " from the stack. ";
         cout << "pushing " << m_op(lhs, rhs) << " onto the stack.\n";
         eval.push(m_op(lhs, rhs));
     }

     op m_op;
     stack<long>& eval;
 };

 template <class op>
 do_op<op>
 make_op(op const& the_op, stack<long>& eval)
 {
     return do_op<op>(the_op, eval);
 }

 struct do_negate
 {
     do_negate(stack<long>& eval_)
     : eval(eval_) {}

     void operator()(char const*, char const*) const
     {
         long lhs = eval.top();
         eval.pop();

         cout << "popped " << lhs << " from the stack. ";
         cout << "pushing " << -lhs << " onto the stack.\n";
         eval.push(-lhs);
     }

     stack<long>& eval;
 };

 ////////////////////////////////////////////////////////////////////////////
 //
 //  Our calculator grammar
 //
 ////////////////////////////////////////////////////////////////////////////
 struct calculator : public grammar<calculator>
 {
     calculator(stack<long>& eval_)
     : eval(eval_) {}

     template <typename ScannerT>
     struct definition
     {
         definition(calculator const& self)
         {
             integer =
                 lexeme_d[ (+digit_p)[push_int(self.eval)] ]
                 ;

             factor =
                     integer
                 |   '(' >> expression >> ')'
                 |   ('-' >> factor)[do_negate(self.eval)]
                 |   ('+' >> factor)
                 ;

             term =
                 factor
                 >> *(   ('*' >> factor)[make_op(multiplies<long>(), self.eval)]
                     |   ('/' >> factor)[make_op(divides<long>(), self.eval)]
                     )
                     ;

             expression =
                 term
                 >> *(  ('+' >> term)[make_op(plus<long>(), self.eval)]
                     |   ('-' >> term)[make_op(minus<long>(), self.eval)]
                     )
                     ;
         }

         rule<ScannerT> expression, term, factor, integer;
         rule<ScannerT> const&
         start() const { return expression; }
     };

     stack<long>& eval;
 };

 ////////////////////////////////////////////////////////////////////////////
 //
 //  Main program
 //
 ////////////////////////////////////////////////////////////////////////////
 int
 main()
 {
     cout << "/////////////////////////////////////////////////////////\n\n";
     cout << "\t\tThe simplest working calculator...\n\n";
     cout << "/////////////////////////////////////////////////////////\n\n";
     cout << "Type an expression...or [q or Q] to quit\n\n";

     stack<long> eval;
     calculator  calc(eval); //  Our parser

     string str;
     while (getline(cin, str))
     {
         if (str.empty() || str[0] == 'q' || str[0] == 'Q')
             break;

         parse_info<> info = parse(str.c_str(), calc, space_p);

         if (info.full)
         {
             cout << "-------------------------\n";
             cout << "Parsing succeeded\n";
             cout << "-------------------------\n";
         }
         else
         {
             cout << "-------------------------\n";
             cout << "Parsing failed\n";
             cout << "stopped at: \": " << info.stop << "\"\n";
             cout << "-------------------------\n";
         }
     }

     cout << "Bye... :-) \n\n";
     return 0;
 }
	/*=============================================================================
	Copyright (c) 2001-2003 Dan Nuffer
	Copyright (c) 2002-2003 Joel de Guzman
	http://spirit.sourceforge.net/

	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)
	=============================================================================*/
	////////////////////////////////////////////////////////////////////////////
	//
	// Full calculator example using STL functors
	// This is discussed in the "Functional" chapter in the Spirit User's Guide.
	//
	// Ported to Spirit v1.5 from v1.2/1.3 example by Dan Nuffer
	// [ JDG 9/18/2002 ]
	//
	////////////////////////////////////////////////////////////////////////////
	#include <boost/spirit/include/classic_core.hpp>
	#include <iostream>
	#include <stack>
	#include <functional>
	#include <string>

	////////////////////////////////////////////////////////////////////////////
	using namespace std;
	using namespace BOOST_SPIRIT_CLASSIC_NS;

	////////////////////////////////////////////////////////////////////////////
	//
	// Semantic actions
	//
	////////////////////////////////////////////////////////////////////////////
	struct push_int
	{
	push_int(stack<long>& eval_)
	: eval(eval_) {}

	void operator()(char const* str, char const* /end/) const
	{
	long n = strtol(str, 0, 10);
	eval.push(n);
	cout << "push\t" << long(n) << endl;
	}

	stack<long>& eval;
	};

	template <typename op>
	struct do_op
	{
	do_op(op const& the_op, stack<long>& eval_)
	: m_op(the_op), eval(eval_) {}

	void operator()(char const, char const) const
	{
	long rhs = eval.top();
	eval.pop();
	long lhs = eval.top();
	eval.pop();

	cout << "popped " << lhs << " and " << rhs << " from the stack. ";
	cout << "pushing " << m_op(lhs, rhs) << " onto the stack.\n";
	eval.push(m_op(lhs, rhs));
	}

	op m_op;
	stack<long>& eval;
	};

	template <class op>
	do_op<op>
	make_op(op const& the_op, stack<long>& eval)
	{
	return do_op<op>(the_op, eval);
	}

	struct do_negate
	{
	do_negate(stack<long>& eval_)
	: eval(eval_) {}

	void operator()(char const, char const) const
	{
	long lhs = eval.top();
	eval.pop();

	cout << "popped " << lhs << " from the stack. ";
	cout << "pushing " << -lhs << " onto the stack.\n";
	eval.push(-lhs);
	}

	stack<long>& eval;
	};

	////////////////////////////////////////////////////////////////////////////
	//
	// Our calculator grammar
	//
	////////////////////////////////////////////////////////////////////////////
	struct calculator : public grammar<calculator>
	{
	calculator(stack<long>& eval_)
	: eval(eval_) {}

	template <typename ScannerT>
	struct definition
	{
	definition(calculator const& self)
	{
	integer =
	lexeme_d[ (+digit_p)[push_int(self.eval)] ]
	;

	factor =
	integer
	\| '(' >> expression >> ')'
	\| ('-' >> factor)[do_negate(self.eval)]
	\| ('+' >> factor)
	;

	term =
	factor
	>> ( ('' >> factor)[make_op(multiplies<long>(), self.eval)]
	\| ('/' >> factor)[make_op(divides<long>(), self.eval)]
	)
	;

	expression =
	term
	>> *( ('+' >> term)[make_op(plus<long>(), self.eval)]
	\| ('-' >> term)[make_op(minus<long>(), self.eval)]
	)
	;
	}

	rule<ScannerT> expression, term, factor, integer;
	rule<ScannerT> const&
	start() const { return expression; }
	};

	stack<long>& eval;
	};

	////////////////////////////////////////////////////////////////////////////
	//
	// Main program
	//
	////////////////////////////////////////////////////////////////////////////
	int
	main()
	{
	cout << "/////////////////////////////////////////////////////////\n\n";
	cout << "\t\tThe simplest working calculator...\n\n";
	cout << "/////////////////////////////////////////////////////////\n\n";
	cout << "Type an expression...or [q or Q] to quit\n\n";

	stack<long> eval;
	calculator calc(eval); // Our parser

	string str;
	while (getline(cin, str))
	{
	if (str.empty() \|\| str[0] == 'q' \|\| str[0] == 'Q')
	break;

	parse_info<> info = parse(str.c_str(), calc, space_p);

	if (info.full)
	{
	cout << "-------------------------\n";
	cout << "Parsing succeeded\n";
	cout << "-------------------------\n";
	}
	else
	{
	cout << "-------------------------\n";
	cout << "Parsing failed\n";
	cout << "stopped at: \": " << info.stop << "\"\n";
	cout << "-------------------------\n";
	}
	}

	cout << "Bye... :-) \n\n";
	return 0;
	}