boost/range/algorithm/search_n.hpp
// Copyright Neil Groves 2009. Use, modification and // distribution is subject to 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) // // // For more information, see http://www.boost.org/libs/range/ // #ifndef BOOST_RANGE_ALGORITHM_SEARCH_N_HPP_INCLUDED #define BOOST_RANGE_ALGORITHM_SEARCH_N_HPP_INCLUDED #include <boost/concept_check.hpp> #include <boost/range/begin.hpp> #include <boost/range/end.hpp> #include <boost/range/concepts.hpp> #include <boost/range/detail/range_return.hpp> #include <boost/range/value_type.hpp> #include <iterator> #include <algorithm> namespace boost { namespace range_detail { // Rationale: search_n is implemented rather than delegate to // the standard library implementation because some standard // library implementations are broken eg. MSVC. // search_n forward iterator version template<typename ForwardIterator, typename Integer, typename Value> inline ForwardIterator search_n_impl(ForwardIterator first, ForwardIterator last, Integer count, const Value& value, std::forward_iterator_tag) { first = std::find(first, last, value); while (first != last) { typename std::iterator_traits<ForwardIterator>::difference_type n = count; ForwardIterator i = first; ++i; while (i != last && n != 1 && *i==value) { ++i; --n; } if (n == 1) return first; if (i == last) return last; first = std::find(++i, last, value); } return last; } // search_n random-access iterator version template<typename RandomAccessIterator, typename Integer, typename Value> inline RandomAccessIterator search_n_impl(RandomAccessIterator first, RandomAccessIterator last, Integer count, const Value& value, std::random_access_iterator_tag) { typedef typename std::iterator_traits<RandomAccessIterator>::difference_type difference_t; difference_t tail_size = last - first; const difference_t pattern_size = count; if (tail_size < pattern_size) return last; const difference_t skip_offset = pattern_size - 1; RandomAccessIterator look_ahead = first + skip_offset; tail_size -= pattern_size; while (1) { // look_ahead here is pointing to the last element of the // next possible match while (!(*look_ahead == value)) // skip loop... { if (tail_size < pattern_size) return last; // no match look_ahead += pattern_size; tail_size -= pattern_size; } difference_t remainder = skip_offset; for (RandomAccessIterator back_track = look_ahead - 1; *back_track == value; --back_track) { if (--remainder == 0) { return look_ahead - skip_offset; // matched } } if (remainder > tail_size) return last; // no match look_ahead += remainder; tail_size -= remainder; } return last; } // search_n for forward iterators using a binary predicate // to determine a match template<typename ForwardIterator, typename Integer, typename Value, typename BinaryPredicate> inline ForwardIterator search_n_pred_impl(ForwardIterator first, ForwardIterator last, Integer count, const Value& value, BinaryPredicate pred, std::forward_iterator_tag) { typedef typename std::iterator_traits<ForwardIterator>::difference_type difference_t; while (first != last && !static_cast<bool>(pred(*first, value))) ++first; while (first != last) { difference_t n = count; ForwardIterator i = first; ++i; while (i != last && n != 1 && static_cast<bool>(pred(*i, value))) { ++i; --n; } if (n == 1) return first; if (i == last) return last; first = ++i; while (first != last && !static_cast<bool>(pred(*first, value))) ++first; } return last; } // search_n for random-access iterators using a binary predicate // to determine a match template<typename RandomAccessIterator, typename Integer, typename Value, typename BinaryPredicate> inline RandomAccessIterator search_n_pred_impl(RandomAccessIterator first, RandomAccessIterator last, Integer count, const Value& value, BinaryPredicate pred, std::random_access_iterator_tag) { typedef typename std::iterator_traits<RandomAccessIterator>::difference_type difference_t; difference_t tail_size = last - first; const difference_t pattern_size = count; if (tail_size < pattern_size) return last; const difference_t skip_offset = pattern_size - 1; RandomAccessIterator look_ahead = first + skip_offset; tail_size -= pattern_size; while (1) { // look_ahead points to the last element of the next // possible match while (!static_cast<bool>(pred(*look_ahead, value))) // skip loop { if (tail_size < pattern_size) return last; // no match look_ahead += pattern_size; tail_size -= pattern_size; } difference_t remainder = skip_offset; for (RandomAccessIterator back_track = look_ahead - 1; pred(*back_track, value); --back_track) { if (--remainder == 0) return look_ahead -= skip_offset; // success } if (remainder > tail_size) { return last; // no match } look_ahead += remainder; tail_size -= remainder; } } template<typename ForwardIterator, typename Integer, typename Value> inline ForwardIterator search_n_impl(ForwardIterator first, ForwardIterator last, Integer count, const Value& value) { BOOST_RANGE_CONCEPT_ASSERT((ForwardIteratorConcept<ForwardIterator>)); BOOST_RANGE_CONCEPT_ASSERT((EqualityComparableConcept<Value>)); BOOST_RANGE_CONCEPT_ASSERT((EqualityComparableConcept<typename std::iterator_traits<ForwardIterator>::value_type>)); //BOOST_RANGE_CONCEPT_ASSERT((EqualityComparableConcept2<typename std::iterator_traits<ForwardIterator>::value_type, Value>)); typedef typename std::iterator_traits<ForwardIterator>::iterator_category cat_t; if (count <= 0) return first; if (count == 1) return std::find(first, last, value); return range_detail::search_n_impl(first, last, count, value, cat_t()); } template<typename ForwardIterator, typename Integer, typename Value, typename BinaryPredicate> inline ForwardIterator search_n_pred_impl(ForwardIterator first, ForwardIterator last, Integer count, const Value& value, BinaryPredicate pred) { BOOST_RANGE_CONCEPT_ASSERT((ForwardIteratorConcept<ForwardIterator>)); BOOST_RANGE_CONCEPT_ASSERT(( BinaryPredicateConcept< BinaryPredicate, typename std::iterator_traits<ForwardIterator>::value_type, Value> )); typedef typename std::iterator_traits<ForwardIterator>::iterator_category cat_t; if (count <= 0) return first; if (count == 1) { while (first != last && !static_cast<bool>(pred(*first, value))) ++first; return first; } return range_detail::search_n_pred_impl(first, last, count, value, pred, cat_t()); } } // namespace range_detail namespace range { /// \brief template function search /// /// range-based version of the search std algorithm /// /// \pre ForwardRange is a model of the ForwardRangeConcept /// \pre Integer is an integral type /// \pre Value is a model of the EqualityComparableConcept /// \pre ForwardRange's value type is a model of the EqualityComparableConcept /// \pre Object's of ForwardRange's value type can be compared for equality with Objects of type Value template< class ForwardRange, class Integer, class Value > inline BOOST_DEDUCED_TYPENAME range_iterator<ForwardRange>::type search_n(ForwardRange& rng, Integer count, const Value& value) { BOOST_RANGE_CONCEPT_ASSERT((ForwardRangeConcept<ForwardRange>)); return range_detail::search_n_impl(boost::begin(rng),boost::end(rng), count, value); } /// \overload template< class ForwardRange, class Integer, class Value > inline BOOST_DEDUCED_TYPENAME range_iterator<const ForwardRange>::type search_n(const ForwardRange& rng, Integer count, const Value& value) { BOOST_RANGE_CONCEPT_ASSERT((ForwardRangeConcept<const ForwardRange>)); return range_detail::search_n_impl(boost::begin(rng), boost::end(rng), count, value); } /// \overload template< class ForwardRange, class Integer, class Value, class BinaryPredicate > inline BOOST_DEDUCED_TYPENAME range_iterator<ForwardRange>::type search_n(ForwardRange& rng, Integer count, const Value& value, BinaryPredicate binary_pred) { BOOST_RANGE_CONCEPT_ASSERT((ForwardRangeConcept<ForwardRange>)); BOOST_RANGE_CONCEPT_ASSERT((BinaryPredicateConcept<BinaryPredicate, BOOST_DEDUCED_TYPENAME range_value<ForwardRange>::type, const Value&>)); return range_detail::search_n_pred_impl(boost::begin(rng), boost::end(rng), count, value, binary_pred); } /// \overload template< class ForwardRange, class Integer, class Value, class BinaryPredicate > inline BOOST_DEDUCED_TYPENAME range_iterator<const ForwardRange>::type search_n(const ForwardRange& rng, Integer count, const Value& value, BinaryPredicate binary_pred) { BOOST_RANGE_CONCEPT_ASSERT((ForwardRangeConcept<const ForwardRange>)); BOOST_RANGE_CONCEPT_ASSERT((BinaryPredicateConcept<BinaryPredicate, BOOST_DEDUCED_TYPENAME range_value<const ForwardRange>::type, const Value&>)); return range_detail::search_n_pred_impl(boost::begin(rng), boost::end(rng), count, value, binary_pred); } // range_return overloads /// \overload template< range_return_value re, class ForwardRange, class Integer, class Value > inline BOOST_DEDUCED_TYPENAME range_return<ForwardRange,re>::type search_n(ForwardRange& rng, Integer count, const Value& value) { BOOST_RANGE_CONCEPT_ASSERT((ForwardRangeConcept<ForwardRange>)); return range_return<ForwardRange,re>:: pack(range_detail::search_n_impl(boost::begin(rng),boost::end(rng), count, value), rng); } /// \overload template< range_return_value re, class ForwardRange, class Integer, class Value > inline BOOST_DEDUCED_TYPENAME range_return<const ForwardRange,re>::type search_n(const ForwardRange& rng, Integer count, const Value& value) { BOOST_RANGE_CONCEPT_ASSERT((ForwardRangeConcept<const ForwardRange>)); return range_return<const ForwardRange,re>:: pack(range_detail::search_n_impl(boost::begin(rng), boost::end(rng), count, value), rng); } /// \overload template< range_return_value re, class ForwardRange, class Integer, class Value, class BinaryPredicate > inline BOOST_DEDUCED_TYPENAME range_return<ForwardRange,re>::type search_n(ForwardRange& rng, Integer count, const Value& value, BinaryPredicate pred) { BOOST_RANGE_CONCEPT_ASSERT((ForwardRangeConcept<ForwardRange>)); BOOST_RANGE_CONCEPT_ASSERT((BinaryPredicateConcept<BinaryPredicate, BOOST_DEDUCED_TYPENAME range_value<ForwardRange>::type, const Value&>)); return range_return<ForwardRange,re>:: pack(range_detail::search_n_pred_impl(boost::begin(rng), boost::end(rng), count, value, pred), rng); } /// \overload template< range_return_value re, class ForwardRange, class Integer, class Value, class BinaryPredicate > inline BOOST_DEDUCED_TYPENAME range_return<const ForwardRange,re>::type search_n(const ForwardRange& rng, Integer count, const Value& value, BinaryPredicate pred) { BOOST_RANGE_CONCEPT_ASSERT((ForwardRangeConcept<const ForwardRange>)); BOOST_RANGE_CONCEPT_ASSERT((BinaryPredicateConcept<BinaryPredicate, BOOST_DEDUCED_TYPENAME range_value<const ForwardRange>::type, const Value&>)); return range_return<const ForwardRange,re>:: pack(range_detail::search_n_pred_impl(boost::begin(rng), boost::end(rng), count, value, pred), rng); } } // namespace range using range::search_n; } // namespace boost #endif // include guard