boost_1_45_0/libs/regex/doc/regex_search.qbk - nest-learning-thermostat/5.0/boost - Git at Google

 [/
   Copyright 2006-2007 John Maddock.
   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).
 ]


 [section:regex_search regex_search]

    #include <boost/regex.hpp>

 The algorithm [regex_search] will search a range denoted by a pair of
 bidirectional-iterators for a given regular expression. The algorithm
 uses various heuristics to reduce the search time by only checking
 for a match if a match could conceivably start at that position. The
 algorithm is defined as follows:

    template <class BidirectionalIterator,
             class Allocator, class charT, class traits>
    bool regex_search(BidirectionalIterator first, BidirectionalIterator last,
                      match_results<BidirectionalIterator, Allocator>& m,
                      const basic_regex<charT, traits>& e,
                      match_flag_type flags = match_default);

    template <class ST, class SA,
             class Allocator, class charT, class traits>
    bool regex_search(const basic_string<charT, ST, SA>& s,
                      match_results<
                         typename basic_string<charT, ST,SA>::const_iterator,
                         Allocator>& m,
                      const basic_regex<charT, traits>& e,
                      match_flag_type flags = match_default);

    template<class charT, class Allocator, class traits>
    bool regex_search(const charT* str,
                      match_results<const charT*, Allocator>& m,
                      const basic_regex<charT, traits>& e,
                      match_flag_type flags = match_default);

    template <class BidirectionalIterator, class charT, class traits>
    bool regex_search(BidirectionalIterator first, BidirectionalIterator last,
                      const basic_regex<charT, traits>& e,
                      match_flag_type flags = match_default);

    template <class charT, class traits>
    bool regex_search(const charT* str,
                      const basic_regex<charT, traits>& e,
                      match_flag_type flags = match_default);

    template<class ST, class SA, class charT, class traits>
    bool regex_search(const basic_string<charT, ST, SA>& s,
                      const basic_regex<charT, traits>& e,
                      match_flag_type flags = match_default);

 [h4 Description]

    template <class BidirectionalIterator, class Allocator, class charT, class traits>
    bool regex_search(BidirectionalIterator first, BidirectionalIterator last,
                      match_results<BidirectionalIterator, Allocator>& m,
                      const basic_regex<charT, traits>& e,
                      match_flag_type flags = match_default);

 [*Requires]: Type BidirectionalIterator meets the requirements of a Bidirectional Iterator (24.1.4).

 [*Effects]: Determines whether there is some sub-sequence within \[first,last)
 that matches the regular expression /e/, parameter /flags/ is used to control
 how the expression is matched against the character sequence. Returns
 true if such a sequence exists, false otherwise.

 [*Throws]: `std::runtime_error` if the complexity of matching the expression
 against an N character string begins to exceed O(N[super 2]), or if the
 program runs out of stack space while matching the expression (if Boost.Regex is
 configured in recursive mode), or if the matcher exhausts its permitted
 memory allocation (if Boost.Regex is configured in non-recursive mode).

 [*Postconditions]: If the function returns false, then the effect on
 parameter /m/ is undefined, otherwise the effects on parameter /m/
 are given in the table:

 [table
 [[Element][Value]]
 [[`m.size()`][`e.mark_count()`]]
 [[`m.empty()`][`false`]]
 [[`m.prefix().first`][`first`]]
 [[`m.prefix().last`][`m[0].first`]]
 [[`m.prefix().matched`][`m.prefix().first != m.prefix().second`]]
 [[`m.suffix().first`][`m[0].second`]]
 [[`m.suffix().last`][`last`]]
 [[`m.suffix().matched`][`m.suffix().first != m.suffix().second`]]
 [[`m[0].first`][The start of the sequence of characters that matched the regular expression]]
 [[`m[0].second`][The end of the sequence of characters that matched the regular expression]]
 [[`m[0].matched`][true if a full match was found, and false if it was a partial match (found as a result of the match_partial flag being set).]]
 [[`m[n].first`][For all integers `n < m.size()`, the start of the sequence that
       matched sub-expression /n/. Alternatively, if sub-expression /n/ did not
       participate in the match, then last.]]
 [[`m[n].second`][For all integers `n < m.size()`, the end of the sequence that
       matched sub-expression /n/. Alternatively, if sub-expression /n/ did not
       participate in the match, then `last`.]]
 [[`m[n].matched`][For all integers `n < m.size()`, true if sub-expression /n/
       participated in the match, false otherwise.]]
 ]

    template <class charT, class Allocator, class traits>
    bool regex_search(const charT* str, match_results<const charT*, Allocator>& m,
                      const basic_regex<charT, traits>& e,
                      match_flag_type flags = match_default);

 [*Effects]: Returns the result of `regex_search(str, str + char_traits<charT>::length(str), m, e, flags)`.

    template <class ST, class SA, class Allocator, class charT,
             class traits>
    bool regex_search(const basic_string<charT, ST, SA>& s,
                      match_results<typename basic_string<charT, ST, SA>::const_iterator, Allocator>& m,
                      const basic_regex<charT, traits>& e,
                      match_flag_type flags = match_default);

 [*Effects]: Returns the result of `regex_search(s.begin(), s.end(), m, e, flags)`.

    template <class iterator, class charT, class traits>
    bool regex_search(iterator first, iterator last,
                      const basic_regex<charT, traits>& e,
                      match_flag_type flags = match_default);

 [*Effects]: Behaves "as if" by constructing an instance of
 `match_results<BidirectionalIterator> what`, and then returning the result of
 `regex_search(first, last, what, e, flags)`.

    template <class charT, class traits>
    bool regex_search(const charT* str
                      const basic_regex<charT, traits>& e,
                      match_flag_type flags = match_default);

 [*Effects]: Returns the result of `regex_search(str, str + char_traits<charT>::length(str), e, flags)`.

    template <class ST, class SA, class charT, class traits>
    bool regex_search(const basic_string<charT, ST, SA>& s,
                      const basic_regex<charT, traits>& e,
                      match_flag_type flags = match_default);

 [*Effects]: Returns the result of `regex_search(s.begin(), s.end(), e, flags)`.

 [h4 Examples]

 The following example, takes the contents of a file in the form of a string,
 and searches for all the C++ class declarations in the file. The code will
 work regardless of the way that `std::string` is implemented, for example it
 could easily be modified to work with the SGI rope class, which uses a
 non-contiguous storage strategy.

    #include <string>
    #include <map>
    #include <boost/regex.hpp>

    // purpose:
    // takes the contents of a file in the form of a string
    // and searches for all the C++ class definitions, storing
    // their locations in a map of strings/int's
    typedef std::map<std::string, int, std::less<std::string> > map_type;

    boost::regex expression(
       "^(template[[:space:]]*<[^;:{]+>[[:space:]]*)?"
       "(class|struct)[[:space:]]*"
       "(\\<\\w+\\>([[:blank:]]*\\([^)]*\\))?"
       "[[:space:]]*)*(\\<\\w*\\>)[[:space:]]*"
       "(<[^;:{]+>[[:space:]]*)?(\\{|:[^;\\{()]*\\{)");

    void IndexClasses(map_type& m, const std::string& file)
    {
       std::string::const_iterator start, end;
       start = file.begin();
       end = file.end();
          boost::match_results<std::string::const_iterator> what;
       boost::match_flag_type flags = boost::match_default;
       while(regex_search(start, end, what, expression, flags))
       {
          // what[0] contains the whole string
          // what[5] contains the class name.
          // what[6] contains the template specialisation if any.
          // add class name and position to map:
          m[std::string(what[5].first, what[5].second)
                + std::string(what[6].first, what[6].second)]
             = what[5].first - file.begin();
          // update search position:
          start = what[0].second;
          // update flags:
          flags |= boost::match_prev_avail;
          flags |= boost::match_not_bob;
       }
    }

 [endsect]
	[/
	Copyright 2006-2007 John Maddock.
	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).
	]


	[section:regex_search regex_search]

	#include <boost/regex.hpp>

	The algorithm [regex_search] will search a range denoted by a pair of
	bidirectional-iterators for a given regular expression. The algorithm
	uses various heuristics to reduce the search time by only checking
	for a match if a match could conceivably start at that position. The
	algorithm is defined as follows:

	template <class BidirectionalIterator,
	class Allocator, class charT, class traits>
	bool regex_search(BidirectionalIterator first, BidirectionalIterator last,
	match_results<BidirectionalIterator, Allocator>& m,
	const basic_regex<charT, traits>& e,
	match_flag_type flags = match_default);

	template <class ST, class SA,
	class Allocator, class charT, class traits>
	bool regex_search(const basic_string<charT, ST, SA>& s,
	match_results<
	typename basic_string<charT, ST,SA>::const_iterator,
	Allocator>& m,
	const basic_regex<charT, traits>& e,
	match_flag_type flags = match_default);

	template<class charT, class Allocator, class traits>
	bool regex_search(const charT* str,
	match_results<const charT*, Allocator>& m,
	const basic_regex<charT, traits>& e,
	match_flag_type flags = match_default);

	template <class BidirectionalIterator, class charT, class traits>
	bool regex_search(BidirectionalIterator first, BidirectionalIterator last,
	const basic_regex<charT, traits>& e,
	match_flag_type flags = match_default);

	template <class charT, class traits>
	bool regex_search(const charT* str,
	const basic_regex<charT, traits>& e,
	match_flag_type flags = match_default);

	template<class ST, class SA, class charT, class traits>
	bool regex_search(const basic_string<charT, ST, SA>& s,
	const basic_regex<charT, traits>& e,
	match_flag_type flags = match_default);

	[h4 Description]

	template <class BidirectionalIterator, class Allocator, class charT, class traits>
	bool regex_search(BidirectionalIterator first, BidirectionalIterator last,
	match_results<BidirectionalIterator, Allocator>& m,
	const basic_regex<charT, traits>& e,
	match_flag_type flags = match_default);

	[*Requires]: Type BidirectionalIterator meets the requirements of a Bidirectional Iterator (24.1.4).

	[*Effects]: Determines whether there is some sub-sequence within \[first,last)
	that matches the regular expression /e/, parameter /flags/ is used to control
	how the expression is matched against the character sequence. Returns
	true if such a sequence exists, false otherwise.

	[*Throws]: `std::runtime_error` if the complexity of matching the expression
	against an N character string begins to exceed O(N[super 2]), or if the
	program runs out of stack space while matching the expression (if Boost.Regex is
	configured in recursive mode), or if the matcher exhausts its permitted
	memory allocation (if Boost.Regex is configured in non-recursive mode).

	[*Postconditions]: If the function returns false, then the effect on
	parameter /m/ is undefined, otherwise the effects on parameter /m/
	are given in the table:

	[table
	[[Element][Value]]
	[[`m.size()`][`e.mark_count()`]]
	[[`m.empty()`][`false`]]
	[[`m.prefix().first`][`first`]]
	[[`m.prefix().last`][`m[0].first`]]
	[[`m.prefix().matched`][`m.prefix().first != m.prefix().second`]]
	[[`m.suffix().first`][`m[0].second`]]
	[[`m.suffix().last`][`last`]]
	[[`m.suffix().matched`][`m.suffix().first != m.suffix().second`]]
	[[`m[0].first`][The start of the sequence of characters that matched the regular expression]]
	[[`m[0].second`][The end of the sequence of characters that matched the regular expression]]
	[[`m[0].matched`][true if a full match was found, and false if it was a partial match (found as a result of the match_partial flag being set).]]
	[[`m[n].first`][For all integers `n < m.size()`, the start of the sequence that
	matched sub-expression /n/. Alternatively, if sub-expression /n/ did not
	participate in the match, then last.]]
	[[`m[n].second`][For all integers `n < m.size()`, the end of the sequence that
	matched sub-expression /n/. Alternatively, if sub-expression /n/ did not
	participate in the match, then `last`.]]
	[[`m[n].matched`][For all integers `n < m.size()`, true if sub-expression /n/
	participated in the match, false otherwise.]]
	]

	template <class charT, class Allocator, class traits>
	bool regex_search(const charT* str, match_results<const charT*, Allocator>& m,
	const basic_regex<charT, traits>& e,
	match_flag_type flags = match_default);

	[*Effects]: Returns the result of `regex_search(str, str + char_traits<charT>::length(str), m, e, flags)`.

	template <class ST, class SA, class Allocator, class charT,
	class traits>
	bool regex_search(const basic_string<charT, ST, SA>& s,
	match_results<typename basic_string<charT, ST, SA>::const_iterator, Allocator>& m,
	const basic_regex<charT, traits>& e,
	match_flag_type flags = match_default);

	[*Effects]: Returns the result of `regex_search(s.begin(), s.end(), m, e, flags)`.

	template <class iterator, class charT, class traits>
	bool regex_search(iterator first, iterator last,
	const basic_regex<charT, traits>& e,
	match_flag_type flags = match_default);

	[*Effects]: Behaves "as if" by constructing an instance of
	`match_results<BidirectionalIterator> what`, and then returning the result of
	`regex_search(first, last, what, e, flags)`.

	template <class charT, class traits>
	bool regex_search(const charT* str
	const basic_regex<charT, traits>& e,
	match_flag_type flags = match_default);

	[*Effects]: Returns the result of `regex_search(str, str + char_traits<charT>::length(str), e, flags)`.

	template <class ST, class SA, class charT, class traits>
	bool regex_search(const basic_string<charT, ST, SA>& s,
	const basic_regex<charT, traits>& e,
	match_flag_type flags = match_default);

	[*Effects]: Returns the result of `regex_search(s.begin(), s.end(), e, flags)`.

	[h4 Examples]

	The following example, takes the contents of a file in the form of a string,
	and searches for all the C++ class declarations in the file. The code will
	work regardless of the way that `std::string` is implemented, for example it
	could easily be modified to work with the SGI rope class, which uses a
	non-contiguous storage strategy.

	#include <string>
	#include <map>
	#include <boost/regex.hpp>

	// purpose:
	// takes the contents of a file in the form of a string
	// and searches for all the C++ class definitions, storing
	// their locations in a map of strings/int's
	typedef std::map<std::string, int, std::less<std::string> > map_type;

	boost::regex expression(
	"^(template[[:space:]]<[^;:{]+>[[:space:]])?"
	"(class\|struct)[[:space:]]*"
	"(\\<\\w+\\>([[:blank:]]\\([^)]\\))?"
	"[[:space:]])(\\<\\w\\>)[[:space:]]"
	"(<[^;:{]+>[[:space:]])?(\\{\|:[^;\\{()]\\{)");

	void IndexClasses(map_type& m, const std::string& file)
	{
	std::string::const_iterator start, end;
	start = file.begin();
	end = file.end();
	boost::match_results<std::string::const_iterator> what;
	boost::match_flag_type flags = boost::match_default;
	while(regex_search(start, end, what, expression, flags))
	{
	// what[0] contains the whole string
	// what[5] contains the class name.
	// what[6] contains the template specialisation if any.
	// add class name and position to map:
	m[std::string(what[5].first, what[5].second)
	+ std::string(what[6].first, what[6].second)]
	= what[5].first - file.begin();
	// update search position:
	start = what[0].second;
	// update flags:
	flags \|= boost::match_prev_avail;
	flags \|= boost::match_not_bob;
	}
	}

	[endsect]