// (C) Copyright Gennadiy Rozental 2001. // 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) // See http://www.boost.org/libs/test for the library home page. // /// @file /// Addition to STL algorithms // *************************************************************************** #ifndef BOOST_TEST_UTILS_ALGORITHM_HPP #define BOOST_TEST_UTILS_ALGORITHM_HPP // STL #include #include // std::find #include // std::bind1st #include //____________________________________________________________________________// namespace boost { namespace unit_test { namespace utils { /// @brief this algorithm search through two collections for first mismatch position that get returned as a pair /// of iterators, first pointing to the mismatch position in first collection, second iterator in second one /// /// @param first1 - first collection begin iterator /// @param last1 - first collection end iterator /// @param first2 - second collection begin iterator /// @param last2 - second collection end iterator template inline std::pair mismatch( InputIter1 first1, InputIter1 last1, InputIter2 first2, InputIter2 last2 ) { while( first1 != last1 && first2 != last2 && *first1 == *first2 ) { ++first1; ++first2; } return std::pair(first1, first2); } //____________________________________________________________________________// /// @brief this algorithm search through two collections for first mismatch position that get returned as a pair /// of iterators, first pointing to the mismatch position in first collection, second iterator in second one. This algorithms /// uses supplied predicate for collection elements comparison /// /// @param first1 - first collection begin iterator /// @param last1 - first collection end iterator /// @param first2 - second collection begin iterator /// @param last2 - second collection end iterator /// @param pred - predicate to be used for search template inline std::pair mismatch( InputIter1 first1, InputIter1 last1, InputIter2 first2, InputIter2 last2, Predicate pred ) { while( first1 != last1 && first2 != last2 && pred( *first1, *first2 ) ) { ++first1; ++first2; } return std::pair(first1, first2); } //____________________________________________________________________________// /// @brief this algorithm search through first collection for first element that does not belong a second one /// /// @param first1 - first collection begin iterator /// @param last1 - first collection end iterator /// @param first2 - second collection begin iterator /// @param last2 - second collection end iterator template inline ForwardIterator1 find_first_not_of( ForwardIterator1 first1, ForwardIterator1 last1, ForwardIterator2 first2, ForwardIterator2 last2 ) { while( first1 != last1 ) { if( std::find( first2, last2, *first1 ) == last2 ) break; ++first1; } return first1; } //____________________________________________________________________________// /// @brief this algorithm search through first collection for first element that does not satisfy binary /// predicate in conjunction will any element in second collection /// /// @param first1 - first collection begin iterator /// @param last1 - first collection end iterator /// @param first2 - second collection begin iterator /// @param last2 - second collection end iterator /// @param pred - predicate to be used for search template inline ForwardIterator1 find_first_not_of( ForwardIterator1 first1, ForwardIterator1 last1, ForwardIterator2 first2, ForwardIterator2 last2, Predicate pred ) { while( first1 != last1 ) { if( std::find_if( first2, last2, std::bind1st( pred, *first1 ) ) == last2 ) break; ++first1; } return first1; } //____________________________________________________________________________// /// @brief this algorithm search through first collection for last element that belongs to a second one /// /// @param first1 - first collection begin iterator /// @param last1 - first collection end iterator /// @param first2 - second collection begin iterator /// @param last2 - second collection end iterator template inline BidirectionalIterator1 find_last_of( BidirectionalIterator1 first1, BidirectionalIterator1 last1, ForwardIterator2 first2, ForwardIterator2 last2 ) { if( first1 == last1 || first2 == last2 ) return last1; BidirectionalIterator1 it1 = last1; while( --it1 != first1 && std::find( first2, last2, *it1 ) == last2 ) {} return it1 == first1 && std::find( first2, last2, *it1 ) == last2 ? last1 : it1; } //____________________________________________________________________________// /// @brief this algorithm search through first collection for last element that satisfy binary /// predicate in conjunction will at least one element in second collection /// /// @param first1 - first collection begin iterator /// @param last1 - first collection end iterator /// @param first2 - second collection begin iterator /// @param last2 - second collection end iterator /// @param pred - predicate to be used for search template inline BidirectionalIterator1 find_last_of( BidirectionalIterator1 first1, BidirectionalIterator1 last1, ForwardIterator2 first2, ForwardIterator2 last2, Predicate pred ) { if( first1 == last1 || first2 == last2 ) return last1; BidirectionalIterator1 it1 = last1; while( --it1 != first1 && std::find_if( first2, last2, std::bind1st( pred, *it1 ) ) == last2 ) {} return it1 == first1 && std::find_if( first2, last2, std::bind1st( pred, *it1 ) ) == last2 ? last1 : it1; } //____________________________________________________________________________// /// @brief this algorithm search through first collection for last element that does not belong to a second one /// /// @param first1 - first collection begin iterator /// @param last1 - first collection end iterator /// @param first2 - second collection begin iterator /// @param last2 - second collection end iterator template inline BidirectionalIterator1 find_last_not_of( BidirectionalIterator1 first1, BidirectionalIterator1 last1, ForwardIterator2 first2, ForwardIterator2 last2 ) { if( first1 == last1 || first2 == last2 ) return last1; BidirectionalIterator1 it1 = last1; while( --it1 != first1 && std::find( first2, last2, *it1 ) != last2 ) {} return it1 == first1 && std::find( first2, last2, *it1 ) != last2 ? last1 : it1; } //____________________________________________________________________________// /// @brief this algorithm search through first collection for last element that does not satisfy binary /// predicate in conjunction will any element in second collection /// /// @param first1 - first collection begin iterator /// @param last1 - first collection end iterator /// @param first2 - second collection begin iterator /// @param last2 - second collection end iterator /// @param pred - predicate to be used for search template inline BidirectionalIterator1 find_last_not_of( BidirectionalIterator1 first1, BidirectionalIterator1 last1, ForwardIterator2 first2, ForwardIterator2 last2, Predicate pred ) { if( first1 == last1 || first2 == last2 ) return last1; BidirectionalIterator1 it1 = last1; while( --it1 != first1 && std::find_if( first2, last2, std::bind1st( pred, *it1 ) ) != last2 ) {} return it1 == first1 && std::find_if( first2, last2, std::bind1st( pred, *it1 ) ) == last2 ? last1 : it1; } //____________________________________________________________________________// /// @brief This algorithm replaces all occurrences of a set of substrings by another substrings /// /// @param str - string of operation /// @param first1 - iterator to the beginning of the substrings to replace /// @param last1 - iterator to the end of the substrings to replace /// @param first2 - iterator to the beginning of the substrings to replace with /// @param last2 - iterator to the end of the substrings to replace with template inline StringClass replace_all_occurrences_of( StringClass str, ForwardIterator first1, ForwardIterator last1, ForwardIterator first2, ForwardIterator last2) { for(; first1 != last1 && first2 != last2; ++first1, ++first2) { std::size_t found = str.find( *first1 ); while( found != StringClass::npos ) { str.replace(found, first1->size(), *first2 ); found = str.find( *first1, found + first2->size() ); } } return str; } /// @brief This algorithm replaces all occurrences of a string with basic wildcards /// with another (optionally containing wildcards as well). /// /// @param str - string to transform /// @param it_string_to_find - iterator to the beginning of the substrings to replace /// @param it_string_to_find_end - iterator to the end of the substrings to replace /// @param it_string_to_replace - iterator to the beginning of the substrings to replace with /// @param it_string_to_replace_end - iterator to the end of the substrings to replace with /// /// The wildcard is the symbol '*'. Only a unique wildcard per string is supported. The replacement /// string may also contain a wildcard, in which case it is considered as a placeholder to the content /// of the wildcard in the source string. /// Example: /// - In order to replace the occurrences of @c 'time=\"some-variable-value\"' to a constant string, /// one may use @c 'time=\"*\"' as the string to search for, and 'time=\"0.0\"' as the replacement string. /// - In order to replace the occurrences of 'file.cpp(XX)' per 'file.cpp:XX', where XX is a variable to keep, /// on may use @c 'file.cpp(*)' as the string to search for, and 'file.cpp:*' as the replacement string. template inline StringClass replace_all_occurrences_with_wildcards( StringClass str, ForwardIterator it_string_to_find, ForwardIterator it_string_to_find_end, ForwardIterator it_string_to_replace, ForwardIterator it_string_to_replace_end) { for(; it_string_to_find != it_string_to_find_end && it_string_to_replace != it_string_to_replace_end; ++it_string_to_find, ++ it_string_to_replace) { std::size_t wildcard_pos = it_string_to_find->find("*"); if(wildcard_pos == StringClass::npos) { ForwardIterator it_to_find_current_end(it_string_to_find); ForwardIterator it_to_replace_current_end(it_string_to_replace); str = replace_all_occurrences_of( str, it_string_to_find, ++it_to_find_current_end, it_string_to_replace, ++it_to_replace_current_end); continue; } std::size_t wildcard_pos_replace = it_string_to_replace->find("*"); std::size_t found_begin = str.find( it_string_to_find->substr(0, wildcard_pos) ); while( found_begin != StringClass::npos ) { std::size_t found_end = str.find(it_string_to_find->substr(wildcard_pos+1), found_begin + wildcard_pos + 1); // to simplify if( found_end != StringClass::npos ) { if( wildcard_pos_replace == StringClass::npos ) { StringClass replace_content = *it_string_to_replace; str.replace( found_begin, found_end + (it_string_to_find->size() - wildcard_pos - 1 ) - found_begin, replace_content); } else { StringClass replace_content = it_string_to_replace->substr(0, wildcard_pos_replace) + str.substr(found_begin + wildcard_pos, found_end - found_begin - wildcard_pos) + it_string_to_replace->substr(wildcard_pos_replace+1) ; str.replace( found_begin, found_end + (it_string_to_find->size() - wildcard_pos - 1 ) - found_begin, replace_content); } } // may adapt the restart to the replacement and be more efficient found_begin = str.find( it_string_to_find->substr(0, wildcard_pos), found_begin + 1 ); } } return str; } } // namespace utils } // namespace unit_test } // namespace boost #include #endif // BOOST_TEST_UTILS_ALGORITHM_HPP