[/ 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_token_iterator regex_token_iterator] The template class [regex_token_iterator] is an iterator adapter; that is to say it represents a new view of an existing iterator sequence, by enumerating all the occurrences of a regular expression within that sequence, and presenting one or more character sequence for each match found. Each position enumerated by the iterator is a [sub_match] object that represents what matched a particular sub-expression within the regular expression. When class [regex_token_iterator] is used to enumerate a single sub-expression with index -1, then the iterator performs field splitting: that is to say it enumerates one character sequence for each section of the character container sequence that does not match the regular expression specified. template ::value_type, class traits = regex_traits > class regex_token_iterator { public: typedef basic_regex regex_type; typedef sub_match value_type; typedef typename iterator_traits::difference_type difference_type; typedef const value_type* pointer; typedef const value_type& reference; typedef std::forward_iterator_tag iterator_category; ``[link boost_regex.regex_token_iterator.construct1 regex_token_iterator]``(); ``[link boost_regex.regex_token_iterator.construct2 regex_token_iterator]``(BidirectionalIterator a, BidirectionalIterator b, const regex_type& re, int submatch = 0, match_flag_type m = match_default); ``[link boost_regex.regex_token_iterator.construct3 regex_token_iterator]``(BidirectionalIterator a, BidirectionalIterator b, const regex_type& re, const std::vector& submatches, match_flag_type m = match_default); template ``[link boost_regex.regex_token_iterator.construct4 regex_token_iterator]``(BidirectionalIterator a, BidirectionalIterator b, const regex_type& re, const int (&submatches)[N], match_flag_type m = match_default); ``[link boost_regex.regex_token_iterator.construct5 regex_token_iterator]``(const regex_token_iterator&); regex_token_iterator& ``[link boost_regex.regex_token_iterator.assign operator=]``(const regex_token_iterator&); bool ``[link boost_regex.regex_token_iterator.op_eq operator==]``(const regex_token_iterator&)const; bool ``[link boost_regex.regex_token_iterator.op_ne operator!=]``(const regex_token_iterator&)const; const value_type& ``[link boost_regex.regex_token_iterator.op_deref operator*]``()const; const value_type* ``[link boost_regex.regex_token_iterator.op_arrow operator->]``()const; regex_token_iterator& ``[link boost_regex.regex_token_iterator.op_inc1 operator++]``(); regex_token_iterator ``[link boost_regex.regex_token_iterator.op_inc2 operator++]``(int); }; typedef regex_token_iterator cregex_token_iterator; typedef regex_token_iterator sregex_token_iterator; #ifndef BOOST_NO_WREGEX typedef regex_token_iterator wcregex_token_iterator; typedef regex_token_iterator< wsregex_token_iterator; #endif template regex_token_iterator ``[link boost_regex.regex_token_iterator.make make_regex_token_iterator]``( const charT* p, const basic_regex& e, int submatch = 0, regex_constants::match_flag_type m = regex_constants::match_default); template regex_token_iterator::const_iterator, charT, traits> ``[link boost_regex.regex_token_iterator.make make_regex_token_iterator]``( const std::basic_string& p, const basic_regex& e, int submatch = 0, regex_constants::match_flag_type m = regex_constants::match_default); template regex_token_iterator ``[link boost_regex.regex_token_iterator.make make_regex_token_iterator]``( const charT* p, const basic_regex& e, const int (&submatch)[N], regex_constants::match_flag_type m = regex_constants::match_default); template regex_token_iterator::const_iterator, charT, traits> ``[link boost_regex.regex_token_iterator.make make_regex_token_iterator]``( const std::basic_string& p, const basic_regex& e, const int (&submatch)[N], regex_constants::match_flag_type m = regex_constants::match_default); template regex_token_iterator ``[link boost_regex.regex_token_iterator.make make_regex_token_iterator]``( const charT* p, const basic_regex& e, const std::vector& submatch, regex_constants::match_flag_type m = regex_constants::match_default); template regex_token_iterator< typename std::basic_string::const_iterator, charT, traits> ``[link boost_regex.regex_token_iterator.make make_regex_token_iterator]``( const std::basic_string& p, const basic_regex& e, const std::vector& submatch, regex_constants::match_flag_type m = regex_constants::match_default); [h4 Description] [#boost_regex.regex_token_iterator.construct1] regex_token_iterator(); [*Effects]: constructs an end of sequence iterator. [#boost_regex.regex_token_iterator.construct2] regex_token_iterator(BidirectionalIterator a, BidirectionalIterator b, const regex_type& re, int submatch = 0, match_flag_type m = match_default); [*Preconditions]: `!re.empty()`. Object /re/ shall exist for the lifetime of the iterator constructed from it. [*Effects]: constructs a [regex_token_iterator] that will enumerate one string for each regular expression match of the expression /re/ found within the sequence \[a,b), using match flags /m/ (see [match_flag_type]). The string enumerated is the sub-expression /submatch/ for each match found; if /submatch/ is -1, then enumerates all the text sequences that did not match the expression /re/ (that is to performs field splitting). [*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). [#boost_regex.regex_token_iterator.construct3] regex_token_iterator(BidirectionalIterator a, BidirectionalIterator b, const regex_type& re, const std::vector& submatches, match_flag_type m = match_default); [*Preconditions]: `submatches.size() && !re.empty()`. Object /re/ shall exist for the lifetime of the iterator constructed from it. [*Effects]: constructs a [regex_token_iterator] that will enumerate `submatches.size()` strings for each regular expression match of the expression /re/ found within the sequence \[a,b), using match flags /m/ (see [match_flag_type]). For each match found one string will be enumerated for each sub-expression index contained within submatches vector; if `submatches[0]` is -1, then the first string enumerated for each match will be all of the text from end of the last match to the start of the current match, in addition there will be one extra string enumerated when no more matches can be found: from the end of the last match found, to the end of the underlying sequence. [*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). [#boost_regex.regex_token_iterator.construct4] template regex_token_iterator(BidirectionalIterator a, BidirectionalIterator b, const regex_type& re, const int (&submatches)[R], match_flag_type m = match_default); [*Preconditions]: `!re.empty()`. Object /re/ shall exist for the lifetime of the iterator constructed from it. [*Effects]: constructs a [regex_token_iterator] that will enumerate /R/ strings for each regular expression match of the expression /re/ found within the sequence \[a,b), using match flags /m/ (see [match_flag_type]). For each match found one string will be enumerated for each sub-expression index contained within the /submatches/ array; if `submatches[0]` is -1, then the first string enumerated for each match will be all of the text from end of the last match to the start of the current match, in addition there will be one extra string enumerated when no more matches can be found: from the end of the last match found, to the end of the underlying sequence. [*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). [#boost_regex.regex_token_iterator.construct5] regex_token_iterator(const regex_token_iterator& that); [*Effects]: constructs a copy of `that`. [*Postconditions]: `*this == that`. [#boost_regex.regex_token_iterator.assign] regex_token_iterator& operator=(const regex_token_iterator& that); [*Effects]: sets `*this` to be equal to `that`. [*Postconditions]: `*this == that`. [#boost_regex.regex_token_iterator.op_eq] bool operator==(const regex_token_iterator&)const; [*Effects]: returns true if `*this` is the same position as `that`. [#boost_regex.regex_token_iterator.op_ne] bool operator!=(const regex_token_iterator&)const; [*Effects]: returns `!(*this == that)`. [#boost_regex.regex_token_iterator.op_deref] const value_type& operator*()const; [*Effects]: returns the current character sequence being enumerated. [#boost_regex.regex_token_iterator.op_arrow] const value_type* operator->()const; [*Effects]: returns `&(*this)`. [#boost_regex.regex_token_iterator.op_inc1] regex_token_iterator& operator++(); [*Effects]: Moves on to the next character sequence to be enumerated. [*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). [*Returns]: `*this`. [#boost_regex.regex_token_iterator.op_inc2] regex_token_iterator& operator++(int); [*Effects]: constructs a copy result of `*this`, then calls `++(*this)`. [*Returns]: result. [#boost_regex.regex_token_iterator.make] template regex_token_iterator make_regex_token_iterator( const charT* p, const basic_regex& e, int submatch = 0, regex_constants::match_flag_type m = regex_constants::match_default); template regex_token_iterator::const_iterator, charT, traits> make_regex_token_iterator( const std::basic_string& p, const basic_regex& e, int submatch = 0, regex_constants::match_flag_type m = regex_constants::match_default); template regex_token_iterator make_regex_token_iterator( const charT* p, const basic_regex& e, const int (&submatch)[N], regex_constants::match_flag_type m = regex_constants::match_default); template regex_token_iterator< typename std::basic_string::const_iterator, charT, traits> make_regex_token_iterator( const std::basic_string& p, const basic_regex& e, const int (&submatch)[N], regex_constants::match_flag_type m = regex_constants::match_default); template regex_token_iterator make_regex_token_iterator( const charT* p, const basic_regex& e, const std::vector& submatch, regex_constants::match_flag_type m = regex_constants::match_default); template regex_token_iterator< typename std::basic_string::const_iterator, charT, traits> make_regex_token_iterator( const std::basic_string& p, const basic_regex& e, const std::vector& submatch, regex_constants::match_flag_type m = regex_constants::match_default); [*Effects]: returns a [regex_token_iterator] that enumerates one [sub_match] for each value in /submatch/ for each occurrence of regular expression /e/ in string /p/, matched using [match_flag_type] /m/. [h4 Examples] The following example takes a string and splits it into a series of tokens: #include #include using namespace std; int main(int argc) { string s; do{ if(argc == 1) { cout << "Enter text to split (or \"quit\" to exit): "; getline(cin, s); if(s == "quit") break; } else s = "This is a string of tokens"; boost::regex re("\\s+"); boost::sregex_token_iterator i(s.begin(), s.end(), re, -1); boost::sregex_token_iterator j; unsigned count = 0; while(i != j) { cout << *i++ << endl; count++; } cout << "There were " << count << " tokens found." << endl; }while(argc == 1); return 0; } The following example takes a html file and outputs a list of all the linked files: #include #include #include #include boost::regex e("<\\s*A\\s+[^>]*href\\s*=\\s*\"([^\"]*)\"", boost::regex::normal | boost::regbase::icase); void load_file(std::string& s, std::istream& is) { s.erase(); // // attempt to grow string buffer to match file size, // this doesn't always work... s.reserve(is.rdbuf()->in_avail()); char c; while(is.get(c)) { // use logarithmic growth strategy, in case // in_avail (above) returned zero: if(s.capacity() == s.size()) s.reserve(s.capacity() * 3); s.append(1, c); } } int main(int argc, char** argv) { std::string s; int i; for(i = 1; i < argc; ++i) { std::cout << "Findings URL's in " << argv[i] << ":" << std::endl; s.erase(); std::ifstream is(argv[i]); load_file(s, is); boost::sregex_token_iterator i(s.begin(), s.end(), e, 1); boost::sregex_token_iterator j; while(i != j) { std::cout << *i++ << std::endl; } } // // alternative method: // test the array-literal constructor, and split out the whole // match as well as $1.... // for(i = 1; i < argc; ++i) { std::cout << "Findings URL's in " << argv[i] << ":" << std::endl; s.erase(); std::ifstream is(argv[i]); load_file(s, is); const int subs[] = {1, 0,}; boost::sregex_token_iterator i(s.begin(), s.end(), e, subs); boost::sregex_token_iterator j; while(i != j) { std::cout << *i++ << std::endl; } } return 0; } [endsect]