third_party/abseil-cpp/absl/algorithm/algorithm.h - src - Git at Google

 // Copyright 2017 The Abseil Authors.
 //
 // Licensed under the Apache License, Version 2.0 (the "License");
 // you may not use this file except in compliance with the License.
 // You may obtain a copy of the License at
 //
 //      http://www.apache.org/licenses/LICENSE-2.0
 //
 // Unless required by applicable law or agreed to in writing, software
 // distributed under the License is distributed on an "AS IS" BASIS,
 // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 // See the License for the specific language governing permissions and
 // limitations under the License.
 //
 // -----------------------------------------------------------------------------
 // File: algorithm.h
 // -----------------------------------------------------------------------------
 //
 // This header file contains Google extensions to the standard <algorithm> C++
 // header.

 #ifndef ABSL_ALGORITHM_ALGORITHM_H_
 #define ABSL_ALGORITHM_ALGORITHM_H_

 #include <algorithm>
 #include <iterator>
 #include <type_traits>

 namespace absl {

 namespace algorithm_internal {

 // Performs comparisons with operator==, similar to C++14's `std::equal_to<>`.
 struct EqualTo {
   template <typename T, typename U>
   bool operator()(const T& a, const U& b) const {
     return a == b;
   }
 };

 template <typename InputIter1, typename InputIter2, typename Pred>
 bool EqualImpl(InputIter1 first1, InputIter1 last1, InputIter2 first2,
                InputIter2 last2, Pred pred, std::input_iterator_tag,
                std::input_iterator_tag) {
   while (true) {
     if (first1 == last1) return first2 == last2;
     if (first2 == last2) return false;
     if (!pred(*first1, *first2)) return false;
     ++first1;
     ++first2;
   }
 }

 template <typename InputIter1, typename InputIter2, typename Pred>
 bool EqualImpl(InputIter1 first1, InputIter1 last1, InputIter2 first2,
                InputIter2 last2, Pred&& pred, std::random_access_iterator_tag,
                std::random_access_iterator_tag) {
   return (last1 - first1 == last2 - first2) &&
          std::equal(first1, last1, first2, std::forward<Pred>(pred));
 }

 // When we are using our own internal predicate that just applies operator==, we
 // forward to the non-predicate form of std::equal. This enables an optimization
 // in libstdc++ that can result in std::memcmp being used for integer types.
 template <typename InputIter1, typename InputIter2>
 bool EqualImpl(InputIter1 first1, InputIter1 last1, InputIter2 first2,
                InputIter2 last2, algorithm_internal::EqualTo /* unused */,
                std::random_access_iterator_tag,
                std::random_access_iterator_tag) {
   return (last1 - first1 == last2 - first2) &&
          std::equal(first1, last1, first2);
 }

 template <typename It>
 It RotateImpl(It first, It middle, It last, std::true_type) {
   return std::rotate(first, middle, last);
 }

 template <typename It>
 It RotateImpl(It first, It middle, It last, std::false_type) {
   std::rotate(first, middle, last);
   return std::next(first, std::distance(middle, last));
 }

 }  // namespace algorithm_internal

 // Compares the equality of two ranges specified by pairs of iterators, using
 // the given predicate, returning true iff for each corresponding iterator i1
 // and i2 in the first and second range respectively, pred(*i1, *i2) == true
 //
 // This comparison takes at most min(`last1` - `first1`, `last2` - `first2`)
 // invocations of the predicate. Additionally, if InputIter1 and InputIter2 are
 // both random-access iterators, and `last1` - `first1` != `last2` - `first2`,
 // then the predicate is never invoked and the function returns false.
 //
 // This is a C++11-compatible implementation of C++14 `std::equal`.  See
 // http://en.cppreference.com/w/cpp/algorithm/equal for more information.
 template <typename InputIter1, typename InputIter2, typename Pred>
 bool equal(InputIter1 first1, InputIter1 last1, InputIter2 first2,
            InputIter2 last2, Pred&& pred) {
   return algorithm_internal::EqualImpl(
       first1, last1, first2, last2, std::forward<Pred>(pred),
       typename std::iterator_traits<InputIter1>::iterator_category{},
       typename std::iterator_traits<InputIter2>::iterator_category{});
 }

 // Performs comparison of two ranges specified by pairs of iterators using
 // operator==.
 template <typename InputIter1, typename InputIter2>
 bool equal(InputIter1 first1, InputIter1 last1, InputIter2 first2,
            InputIter2 last2) {
   return absl::equal(first1, last1, first2, last2,
                      algorithm_internal::EqualTo{});
 }

 // Performs a linear search for `value` using the iterator `first` up to
 // but not including `last`, returning true if [`first`, `last`) contains an
 // element equal to `value`.
 //
 // A linear search is of O(n) complexity which is guaranteed to make at most
 // n = (`last` - `first`) comparisons. A linear search over short containers
 // may be faster than a binary search, even when the container is sorted.
 template <typename InputIterator, typename EqualityComparable>
 bool linear_search(InputIterator first, InputIterator last,
                    const EqualityComparable& value) {
   return std::find(first, last, value) != last;
 }

 // Performs a left rotation on a range of elements (`first`, `last`) such that
 // `middle` is now the first element. `rotate()` returns an iterator pointing to
 // the first element before rotation. This function is exactly the same as
 // `std::rotate`, but fixes a bug in gcc
 // <= 4.9 where `std::rotate` returns `void` instead of an iterator.
 //
 // The complexity of this algorithm is the same as that of `std::rotate`, but if
 // `ForwardIterator` is not a random-access iterator, then `absl::rotate`
 // performs an additional pass over the range to construct the return value.

 template <typename ForwardIterator>
 ForwardIterator rotate(ForwardIterator first, ForwardIterator middle,
                        ForwardIterator last) {
   return algorithm_internal::RotateImpl(
       first, middle, last,
       std::is_same<decltype(std::rotate(first, middle, last)),
                    ForwardIterator>());
 }

 }  // namespace absl

 #endif  // ABSL_ALGORITHM_ALGORITHM_H_
	// Copyright 2017 The Abseil Authors.
	//
	// Licensed under the Apache License, Version 2.0 (the "License");
	// you may not use this file except in compliance with the License.
	// You may obtain a copy of the License at
	//
	// http://www.apache.org/licenses/LICENSE-2.0
	//
	// Unless required by applicable law or agreed to in writing, software
	// distributed under the License is distributed on an "AS IS" BASIS,
	// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	// See the License for the specific language governing permissions and
	// limitations under the License.
	//
	// -----------------------------------------------------------------------------
	// File: algorithm.h
	// -----------------------------------------------------------------------------
	//
	// This header file contains Google extensions to the standard <algorithm> C++
	// header.

	#ifndef ABSL_ALGORITHM_ALGORITHM_H_
	#define ABSL_ALGORITHM_ALGORITHM_H_

	#include <algorithm>
	#include <iterator>
	#include <type_traits>

	namespace absl {

	namespace algorithm_internal {

	// Performs comparisons with operator==, similar to C++14's `std::equal_to<>`.
	struct EqualTo {
	template <typename T, typename U>
	bool operator()(const T& a, const U& b) const {
	return a == b;
	}
	};

	template <typename InputIter1, typename InputIter2, typename Pred>
	bool EqualImpl(InputIter1 first1, InputIter1 last1, InputIter2 first2,
	InputIter2 last2, Pred pred, std::input_iterator_tag,
	std::input_iterator_tag) {
	while (true) {
	if (first1 == last1) return first2 == last2;
	if (first2 == last2) return false;
	if (!pred(first1, first2)) return false;
	++first1;
	++first2;
	}
	}

	template <typename InputIter1, typename InputIter2, typename Pred>
	bool EqualImpl(InputIter1 first1, InputIter1 last1, InputIter2 first2,
	InputIter2 last2, Pred&& pred, std::random_access_iterator_tag,
	std::random_access_iterator_tag) {
	return (last1 - first1 == last2 - first2) &&
	std::equal(first1, last1, first2, std::forward<Pred>(pred));
	}

	// When we are using our own internal predicate that just applies operator==, we
	// forward to the non-predicate form of std::equal. This enables an optimization
	// in libstdc++ that can result in std::memcmp being used for integer types.
	template <typename InputIter1, typename InputIter2>
	bool EqualImpl(InputIter1 first1, InputIter1 last1, InputIter2 first2,
	InputIter2 last2, algorithm_internal::EqualTo /* unused */,
	std::random_access_iterator_tag,
	std::random_access_iterator_tag) {
	return (last1 - first1 == last2 - first2) &&
	std::equal(first1, last1, first2);
	}

	template <typename It>
	It RotateImpl(It first, It middle, It last, std::true_type) {
	return std::rotate(first, middle, last);
	}

	template <typename It>
	It RotateImpl(It first, It middle, It last, std::false_type) {
	std::rotate(first, middle, last);
	return std::next(first, std::distance(middle, last));
	}

	} // namespace algorithm_internal

	// Compares the equality of two ranges specified by pairs of iterators, using
	// the given predicate, returning true iff for each corresponding iterator i1
	// and i2 in the first and second range respectively, pred(i1, i2) == true
	//
	// This comparison takes at most min(`last1` - `first1`, `last2` - `first2`)
	// invocations of the predicate. Additionally, if InputIter1 and InputIter2 are
	// both random-access iterators, and `last1` - `first1` != `last2` - `first2`,
	// then the predicate is never invoked and the function returns false.
	//
	// This is a C++11-compatible implementation of C++14 `std::equal`. See
	// http://en.cppreference.com/w/cpp/algorithm/equal for more information.
	template <typename InputIter1, typename InputIter2, typename Pred>
	bool equal(InputIter1 first1, InputIter1 last1, InputIter2 first2,
	InputIter2 last2, Pred&& pred) {
	return algorithm_internal::EqualImpl(
	first1, last1, first2, last2, std::forward<Pred>(pred),
	typename std::iterator_traits<InputIter1>::iterator_category{},
	typename std::iterator_traits<InputIter2>::iterator_category{});
	}

	// Performs comparison of two ranges specified by pairs of iterators using
	// operator==.
	template <typename InputIter1, typename InputIter2>
	bool equal(InputIter1 first1, InputIter1 last1, InputIter2 first2,
	InputIter2 last2) {
	return absl::equal(first1, last1, first2, last2,
	algorithm_internal::EqualTo{});
	}

	// Performs a linear search for `value` using the iterator `first` up to
	// but not including `last`, returning true if [`first`, `last`) contains an
	// element equal to `value`.
	//
	// A linear search is of O(n) complexity which is guaranteed to make at most
	// n = (`last` - `first`) comparisons. A linear search over short containers
	// may be faster than a binary search, even when the container is sorted.
	template <typename InputIterator, typename EqualityComparable>
	bool linear_search(InputIterator first, InputIterator last,
	const EqualityComparable& value) {
	return std::find(first, last, value) != last;
	}

	// Performs a left rotation on a range of elements (`first`, `last`) such that
	// `middle` is now the first element. `rotate()` returns an iterator pointing to
	// the first element before rotation. This function is exactly the same as
	// `std::rotate`, but fixes a bug in gcc
	// <= 4.9 where `std::rotate` returns `void` instead of an iterator.
	//
	// The complexity of this algorithm is the same as that of `std::rotate`, but if
	// `ForwardIterator` is not a random-access iterator, then `absl::rotate`
	// performs an additional pass over the range to construct the return value.

	template <typename ForwardIterator>
	ForwardIterator rotate(ForwardIterator first, ForwardIterator middle,
	ForwardIterator last) {
	return algorithm_internal::RotateImpl(
	first, middle, last,
	std::is_same<decltype(std::rotate(first, middle, last)),
	ForwardIterator>());
	}

	} // namespace absl

	#endif // ABSL_ALGORITHM_ALGORITHM_H_