boost/algorithm/is_palindrome.hpp
/* Copyright (c) Alexander Zaitsev <zamazan4ik@gmail.com>, 2016 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/ for latest version. */ /// \file is_palindrome.hpp /// \brief Checks the input sequence on palindrome. /// \author Alexander Zaitsev #ifndef BOOST_ALGORITHM_IS_PALINDROME_HPP #define BOOST_ALGORITHM_IS_PALINDROME_HPP #include <iterator> #include <functional> #include <cstring> #include <boost/range/begin.hpp> #include <boost/range/end.hpp> namespace boost { namespace algorithm { /// \fn is_palindrome ( BidirectionalIterator begin, BidirectionalIterator end, Predicate p ) /// \return true if the entire sequence is palindrome /// /// \param begin The start of the input sequence /// \param end One past the end of the input sequence /// \param p A predicate used to compare the values. /// /// \note This function will return true for empty sequences and for palindromes. /// For other sequences function will return false. /// Complexity: O(N). template <typename BidirectionalIterator, typename Predicate> bool is_palindrome(BidirectionalIterator begin, BidirectionalIterator end, Predicate p) { if(begin == end) { return true; } --end; while(begin != end) { if(!p(*begin, *end)) { return false; } ++begin; if(begin == end) { break; } --end; } return true; } /// \fn is_palindrome ( BidirectionalIterator begin, BidirectionalIterator end ) /// \return true if the entire sequence is palindrome /// /// \param begin The start of the input sequence /// \param end One past the end of the input sequence /// /// \note This function will return true for empty sequences and for palindromes. /// For other sequences function will return false. /// Complexity: O(N). template <typename BidirectionalIterator> bool is_palindrome(BidirectionalIterator begin, BidirectionalIterator end) { return is_palindrome(begin, end, std::equal_to<typename std::iterator_traits<BidirectionalIterator>::value_type> ()); } /// \fn is_palindrome ( const R& range ) /// \return true if the entire sequence is palindrome /// /// \param range The range to be tested. /// /// \note This function will return true for empty sequences and for palindromes. /// For other sequences function will return false. /// Complexity: O(N). template <typename R> bool is_palindrome(const R& range) { return is_palindrome(boost::begin(range), boost::end(range)); } /// \fn is_palindrome ( const R& range, Predicate p ) /// \return true if the entire sequence is palindrome /// /// \param range The range to be tested. /// \param p A predicate used to compare the values. /// /// \note This function will return true for empty sequences and for palindromes. /// For other sequences function will return false. /// Complexity: O(N). template <typename R, typename Predicate> bool is_palindrome(const R& range, Predicate p) { return is_palindrome(boost::begin(range), boost::end(range), p); } /// \fn is_palindrome ( const char* str ) /// \return true if the entire sequence is palindrome /// /// \param str C-string to be tested. /// /// \note This function will return true for empty sequences and for palindromes. /// For other sequences function will return false. /// Complexity: O(N). bool is_palindrome(const char* str) { if(!str) return true; return is_palindrome(str, str + strlen(str)); } /// \fn is_palindrome ( const char* str, Predicate p ) /// \return true if the entire sequence is palindrome /// /// \param str C-string to be tested. /// \param p A predicate used to compare the values. /// /// \note This function will return true for empty sequences and for palindromes. /// For other sequences function will return false. /// Complexity: O(N). template<typename Predicate> bool is_palindrome(const char* str, Predicate p) { if(!str) return true; return is_palindrome(str, str + strlen(str), p); } }} #endif // BOOST_ALGORITHM_IS_PALINDROME_HPP