boost_1_45_0/libs/xpressive/example/main.cpp - nest-learning-thermostat/5.0/boost - Git at Google

 ///////////////////////////////////////////////////////////////////////////////
 // main.hpp
 //
 //  Copyright 2004 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)

 #include <iostream>
 #include <iomanip>
 #include <boost/xpressive/xpressive.hpp>

 using namespace boost::xpressive;

 ///////////////////////////////////////////////////////////////////////////////
 // Displays nested results to std::cout with indenting
 //
 // Display a tree of nested results
 //
 // Here is a helper class to demonstrate how you might display a tree of nested results:
 struct output_nested_results
 {
     int tabs_;

     output_nested_results(int tabs = 0)
       : tabs_(tabs)
     {
     }

     template< typename BidiIterT >
     void operator ()( match_results< BidiIterT > const &what ) const
     {
         // first, do some indenting
         typedef typename std::iterator_traits< BidiIterT >::value_type char_type;
         char_type space_ch = char_type(' ');
         std::fill_n( std::ostream_iterator<char_type>( std::cout ), tabs_ * 4, space_ch );

         // output the match
         std::cout << what[0] << '\n';

         // output any nested matches
         std::for_each(
             what.nested_results().begin(),
             what.nested_results().end(),
             output_nested_results( tabs_ + 1 ) );
     }
 };

 ///////////////////////////////////////////////////////////////////////////////
 // See if a whole string matches a regex
 //
 // This program outputs the following:
 //
 // hello world!
 // hello
 // world

 void example1()
 {
     std::string hello( "hello world!" );

     sregex rex = sregex::compile( "(\\w+) (\\w+)!" );
     smatch what;

     if( regex_match( hello, what, rex ) )
     {
         std::cout << what[0] << '\n'; // whole match
         std::cout << what[1] << '\n'; // first capture
         std::cout << what[2] << '\n'; // second capture
     }
 }

 ///////////////////////////////////////////////////////////////////////////////
 // See if a string contains a sub-string that matches a regex
 //
 // Notice in this example how we use custom mark_tags to make the pattern
 // more readable. We can use the mark_tags later to index into the match_results<>.
 //
 // This program outputs the following:
 //
 // 5/30/1973
 // 30
 // 5
 // 1973
 // /

 void example2()
 {
     char const *str = "I was born on 5/30/1973 at 7am.";

     // define some custom mark_tags with names more meaningful than s1, s2, etc.
     mark_tag day(1), month(2), year(3), delim(4);

     // this regex finds a date
     cregex date = (month= repeat<1,2>(_d))           // find the month ...
                >> (delim= (set= '/','-'))            // followed by a delimiter ...
                >> (day=   repeat<1,2>(_d)) >> delim  // and a day followed by the same delimiter ...
                >> (year=  repeat<1,2>(_d >> _d));    // and the year.

     cmatch what;

     if( regex_search( str, what, date ) )
     {
         std::cout << what[0]     << '\n'; // whole match
         std::cout << what[day]   << '\n'; // the day
         std::cout << what[month] << '\n'; // the month
         std::cout << what[year]  << '\n'; // the year
         std::cout << what[delim] << '\n'; // the delimiter
     }
 }

 ///////////////////////////////////////////////////////////////////////////////
 // Replace all sub-strings that match a regex
 //
 // The following program finds dates in a string and marks them up with pseudo-HTML.
 //
 // This program outputs the following:
 //
 // I was born on <date>5/30/1973</date> at 7am.

 void example3()
 {
     std::string str( "I was born on 5/30/1973 at 7am." );

     // essentially the same regex as in the previous example, but using a dynamic regex
     sregex date = sregex::compile( "(\\d{1,2})([/-])(\\d{1,2})\\2((?:\\d{2}){1,2})" );

     // As in Perl, $& is a reference to the sub-string that matched the regex
     std::string format( "<date>$&</date>" );

     str = regex_replace( str, date, format );
     std::cout << str << '\n';
 }

 ///////////////////////////////////////////////////////////////////////////////
 // Find all the sub-strings that match a regex and step through them one at a time
 //
 // The following program finds the words in a wide-character string. It uses wsregex_iterator.
 // Notice that dereferencing a wsregex_iterator yields a wsmatch object.
 //
 // This program outputs the following:
 //
 // This
 // is
 // his
 // face

 void example4()
 {
     #ifndef BOOST_XPRESSIVE_NO_WREGEX
     std::wstring str( L"This is his face." );

     // find a whole word
     wsregex token = +alnum;

     wsregex_iterator cur( str.begin(), str.end(), token );
     wsregex_iterator end;

     for( ; cur != end; ++cur )
     {
         wsmatch const &what = *cur;
         std::wcout << what[0] << L'\n';
     }
     #endif
 }

 ///////////////////////////////////////////////////////////////////////////////
 // Split a string into tokens that each match a regex
 //
 // The following program finds race times in a string and displays first the minutes
 // and then the seconds. It uses regex_token_iterator<>.
 //
 // This program outputs the following:
 //
 // 4
 // 40
 // 3
 // 35
 // 2
 // 32

 void example5()
 {
     std::string str( "Eric: 4:40, Karl: 3:35, Francesca: 2:32" );

     // find a race time
     sregex time = sregex::compile( "(\\d):(\\d\\d)" );

     // for each match, the token iterator should first take the value of
     // the first marked sub-expression followed by the value of the second
     // marked sub-expression
     int const subs[] = { 1, 2 };

     sregex_token_iterator cur( str.begin(), str.end(), time, subs );
     sregex_token_iterator end;

     for( ; cur != end; ++cur )
     {
         std::cout << *cur << '\n';
     }
 }

 ///////////////////////////////////////////////////////////////////////////////
 // Split a string using a regex as a delimiter
 //
 // The following program takes some text that has been marked up with html and strips
 // out the mark-up. It uses a regex that matches an HTML tag and a regex_token_iterator<>
 // that returns the parts of the string that do not match the regex.
 //
 // This program outputs the following:
 //
 // {Now }{is the time }{for all good men}{ to come to the aid of their}{ country.}

 void example6()
 {
     std::string str( "Now <bold>is the time <i>for all good men</i> to come to the aid of their</bold> country." );

     // find a HTML tag
     sregex html = '<' >> optional('/') >> +_w >> '>';

     // the -1 below directs the token iterator to display the parts of
     // the string that did NOT match the regular expression.
     sregex_token_iterator cur( str.begin(), str.end(), html, -1 );
     sregex_token_iterator end;

     for( ; cur != end; ++cur )
     {
         std::cout << '{' << *cur << '}';
     }
     std::cout << '\n';
 }

 ///////////////////////////////////////////////////////////////////////////////
 // main
 int main()
 {
     std::cout << "\n\nExample 1:\n\n";
     example1();

     std::cout << "\n\nExample 2:\n\n";
     example2();

     std::cout << "\n\nExample 3:\n\n";
     example3();

     std::cout << "\n\nExample 4:\n\n";
     example4();

     std::cout << "\n\nExample 5:\n\n";
     example5();

     std::cout << "\n\nExample 6:\n\n";
     example6();

     std::cout << "\n\n" << std::flush;

     return 0;
 }
	///////////////////////////////////////////////////////////////////////////////
	// main.hpp
	//
	// Copyright 2004 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)

	#include <iostream>
	#include <iomanip>
	#include <boost/xpressive/xpressive.hpp>

	using namespace boost::xpressive;

	///////////////////////////////////////////////////////////////////////////////
	// Displays nested results to std::cout with indenting
	//
	// Display a tree of nested results
	//
	// Here is a helper class to demonstrate how you might display a tree of nested results:
	struct output_nested_results
	{
	int tabs_;

	output_nested_results(int tabs = 0)
	: tabs_(tabs)
	{
	}

	template< typename BidiIterT >
	void operator ()( match_results< BidiIterT > const &what ) const
	{
	// first, do some indenting
	typedef typename std::iterator_traits< BidiIterT >::value_type char_type;
	char_type space_ch = char_type(' ');
	std::fill_n( std::ostream_iterator<char_type>( std::cout ), tabs_ * 4, space_ch );

	// output the match
	std::cout << what[0] << '\n';

	// output any nested matches
	std::for_each(
	what.nested_results().begin(),
	what.nested_results().end(),
	output_nested_results( tabs_ + 1 ) );
	}
	};

	///////////////////////////////////////////////////////////////////////////////
	// See if a whole string matches a regex
	//
	// This program outputs the following:
	//
	// hello world!
	// hello
	// world

	void example1()
	{
	std::string hello( "hello world!" );

	sregex rex = sregex::compile( "(\\w+) (\\w+)!" );
	smatch what;

	if( regex_match( hello, what, rex ) )
	{
	std::cout << what[0] << '\n'; // whole match
	std::cout << what[1] << '\n'; // first capture
	std::cout << what[2] << '\n'; // second capture
	}
	}

	///////////////////////////////////////////////////////////////////////////////
	// See if a string contains a sub-string that matches a regex
	//
	// Notice in this example how we use custom mark_tags to make the pattern
	// more readable. We can use the mark_tags later to index into the match_results<>.
	//
	// This program outputs the following:
	//
	// 5/30/1973
	// 30
	// 5
	// 1973
	// /

	void example2()
	{
	char const *str = "I was born on 5/30/1973 at 7am.";

	// define some custom mark_tags with names more meaningful than s1, s2, etc.
	mark_tag day(1), month(2), year(3), delim(4);

	// this regex finds a date
	cregex date = (month= repeat<1,2>(_d)) // find the month ...
	>> (delim= (set= '/','-')) // followed by a delimiter ...
	>> (day= repeat<1,2>(_d)) >> delim // and a day followed by the same delimiter ...
	>> (year= repeat<1,2>(_d >> _d)); // and the year.

	cmatch what;

	if( regex_search( str, what, date ) )
	{
	std::cout << what[0] << '\n'; // whole match
	std::cout << what[day] << '\n'; // the day
	std::cout << what[month] << '\n'; // the month
	std::cout << what[year] << '\n'; // the year
	std::cout << what[delim] << '\n'; // the delimiter
	}
	}

	///////////////////////////////////////////////////////////////////////////////
	// Replace all sub-strings that match a regex
	//
	// The following program finds dates in a string and marks them up with pseudo-HTML.
	//
	// This program outputs the following:
	//
	// I was born on <date>5/30/1973</date> at 7am.

	void example3()
	{
	std::string str( "I was born on 5/30/1973 at 7am." );

	// essentially the same regex as in the previous example, but using a dynamic regex
	sregex date = sregex::compile( "(\\d{1,2})([/-])(\\d{1,2})\\2((?:\\d{2}){1,2})" );

	// As in Perl, $& is a reference to the sub-string that matched the regex
	std::string format( "<date>$&</date>" );

	str = regex_replace( str, date, format );
	std::cout << str << '\n';
	}

	///////////////////////////////////////////////////////////////////////////////
	// Find all the sub-strings that match a regex and step through them one at a time
	//
	// The following program finds the words in a wide-character string. It uses wsregex_iterator.
	// Notice that dereferencing a wsregex_iterator yields a wsmatch object.
	//
	// This program outputs the following:
	//
	// This
	// is
	// his
	// face

	void example4()
	{
	#ifndef BOOST_XPRESSIVE_NO_WREGEX
	std::wstring str( L"This is his face." );

	// find a whole word
	wsregex token = +alnum;

	wsregex_iterator cur( str.begin(), str.end(), token );
	wsregex_iterator end;

	for( ; cur != end; ++cur )
	{
	wsmatch const &what = *cur;
	std::wcout << what[0] << L'\n';
	}
	#endif
	}

	///////////////////////////////////////////////////////////////////////////////
	// Split a string into tokens that each match a regex
	//
	// The following program finds race times in a string and displays first the minutes
	// and then the seconds. It uses regex_token_iterator<>.
	//
	// This program outputs the following:
	//
	// 4
	// 40
	// 3
	// 35
	// 2
	// 32

	void example5()
	{
	std::string str( "Eric: 4:40, Karl: 3:35, Francesca: 2:32" );

	// find a race time
	sregex time = sregex::compile( "(\\d):(\\d\\d)" );

	// for each match, the token iterator should first take the value of
	// the first marked sub-expression followed by the value of the second
	// marked sub-expression
	int const subs[] = { 1, 2 };

	sregex_token_iterator cur( str.begin(), str.end(), time, subs );
	sregex_token_iterator end;

	for( ; cur != end; ++cur )
	{
	std::cout << *cur << '\n';
	}
	}

	///////////////////////////////////////////////////////////////////////////////
	// Split a string using a regex as a delimiter
	//
	// The following program takes some text that has been marked up with html and strips
	// out the mark-up. It uses a regex that matches an HTML tag and a regex_token_iterator<>
	// that returns the parts of the string that do not match the regex.
	//
	// This program outputs the following:
	//
	// {Now }{is the time }{for all good men}{ to come to the aid of their}{ country.}

	void example6()
	{
	std::string str( "Now <bold>is the time <i>for all good men</i> to come to the aid of their</bold> country." );

	// find a HTML tag
	sregex html = '<' >> optional('/') >> +_w >> '>';

	// the -1 below directs the token iterator to display the parts of
	// the string that did NOT match the regular expression.
	sregex_token_iterator cur( str.begin(), str.end(), html, -1 );
	sregex_token_iterator end;

	for( ; cur != end; ++cur )
	{
	std::cout << '{' << *cur << '}';
	}
	std::cout << '\n';
	}

	///////////////////////////////////////////////////////////////////////////////
	// main
	int main()
	{
	std::cout << "\n\nExample 1:\n\n";
	example1();

	std::cout << "\n\nExample 2:\n\n";
	example2();

	std::cout << "\n\nExample 3:\n\n";
	example3();

	std::cout << "\n\nExample 4:\n\n";
	example4();

	std::cout << "\n\nExample 5:\n\n";
	example5();

	std::cout << "\n\nExample 6:\n\n";
	example6();

	std::cout << "\n\n" << std::flush;

	return 0;
	}