Abseil Common Libraries (C++) (grcp 依赖)
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1764 lines
76 KiB
1764 lines
76 KiB
// Copyright 2017 The Abseil Authors. |
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// |
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// Licensed under the Apache License, Version 2.0 (the "License"); |
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// you may not use this file except in compliance with the License. |
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// You may obtain a copy of the License at |
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// |
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// https://www.apache.org/licenses/LICENSE-2.0 |
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// |
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// Unless required by applicable law or agreed to in writing, software |
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// distributed under the License is distributed on an "AS IS" BASIS, |
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// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. |
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// See the License for the specific language governing permissions and |
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// limitations under the License. |
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// |
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// ----------------------------------------------------------------------------- |
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// File: container.h |
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// ----------------------------------------------------------------------------- |
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// |
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// This header file provides Container-based versions of algorithmic functions |
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// within the C++ standard library. The following standard library sets of |
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// functions are covered within this file: |
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// |
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// * Algorithmic <iterator> functions |
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// * Algorithmic <numeric> functions |
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// * <algorithm> functions |
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// |
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// The standard library functions operate on iterator ranges; the functions |
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// within this API operate on containers, though many return iterator ranges. |
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// |
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// All functions within this API are named with a `c_` prefix. Calls such as |
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// `absl::c_xx(container, ...) are equivalent to std:: functions such as |
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// `std::xx(std::begin(cont), std::end(cont), ...)`. Functions that act on |
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// iterators but not conceptually on iterator ranges (e.g. `std::iter_swap`) |
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// have no equivalent here. |
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// |
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// For template parameter and variable naming, `C` indicates the container type |
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// to which the function is applied, `Pred` indicates the predicate object type |
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// to be used by the function and `T` indicates the applicable element type. |
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#ifndef ABSL_ALGORITHM_CONTAINER_H_ |
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#define ABSL_ALGORITHM_CONTAINER_H_ |
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#include <algorithm> |
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#include <cassert> |
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#include <iterator> |
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#include <numeric> |
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#include <type_traits> |
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#include <unordered_map> |
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#include <unordered_set> |
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#include <utility> |
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#include <vector> |
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#include "absl/algorithm/algorithm.h" |
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#include "absl/base/macros.h" |
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#include "absl/meta/type_traits.h" |
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namespace absl { |
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ABSL_NAMESPACE_BEGIN |
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namespace container_algorithm_internal { |
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// NOTE: it is important to defer to ADL lookup for building with C++ modules, |
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// especially for headers like <valarray> which are not visible from this file |
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// but specialize std::begin and std::end. |
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using std::begin; |
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using std::end; |
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// The type of the iterator given by begin(c) (possibly std::begin(c)). |
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// ContainerIter<const vector<T>> gives vector<T>::const_iterator, |
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// while ContainerIter<vector<T>> gives vector<T>::iterator. |
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template <typename C> |
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using ContainerIter = decltype(begin(std::declval<C&>())); |
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// An MSVC bug involving template parameter substitution requires us to use |
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// decltype() here instead of just std::pair. |
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template <typename C1, typename C2> |
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using ContainerIterPairType = |
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decltype(std::make_pair(ContainerIter<C1>(), ContainerIter<C2>())); |
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template <typename C> |
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using ContainerDifferenceType = |
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decltype(std::distance(std::declval<ContainerIter<C>>(), |
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std::declval<ContainerIter<C>>())); |
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template <typename C> |
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using ContainerPointerType = |
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typename std::iterator_traits<ContainerIter<C>>::pointer; |
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// container_algorithm_internal::c_begin and |
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// container_algorithm_internal::c_end are abbreviations for proper ADL |
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// lookup of std::begin and std::end, i.e. |
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// using std::begin; |
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// using std::end; |
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// std::foo(begin(c), end(c)); |
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// becomes |
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// std::foo(container_algorithm_internal::begin(c), |
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// container_algorithm_internal::end(c)); |
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// These are meant for internal use only. |
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template <typename C> |
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ContainerIter<C> c_begin(C& c) { return begin(c); } |
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template <typename C> |
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ContainerIter<C> c_end(C& c) { return end(c); } |
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template <typename T> |
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struct IsUnorderedContainer : std::false_type {}; |
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template <class Key, class T, class Hash, class KeyEqual, class Allocator> |
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struct IsUnorderedContainer< |
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std::unordered_map<Key, T, Hash, KeyEqual, Allocator>> : std::true_type {}; |
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template <class Key, class Hash, class KeyEqual, class Allocator> |
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struct IsUnorderedContainer<std::unordered_set<Key, Hash, KeyEqual, Allocator>> |
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: std::true_type {}; |
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// container_algorithm_internal::c_size. It is meant for internal use only. |
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template <class C> |
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auto c_size(C& c) -> decltype(c.size()) { |
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return c.size(); |
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} |
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template <class T, std::size_t N> |
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constexpr std::size_t c_size(T (&)[N]) { |
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return N; |
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} |
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} // namespace container_algorithm_internal |
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// PUBLIC API |
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//------------------------------------------------------------------------------ |
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// Abseil algorithm.h functions |
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//------------------------------------------------------------------------------ |
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// c_linear_search() |
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// |
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// Container-based version of absl::linear_search() for performing a linear |
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// search within a container. |
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template <typename C, typename EqualityComparable> |
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bool c_linear_search(const C& c, EqualityComparable&& value) { |
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return linear_search(container_algorithm_internal::c_begin(c), |
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container_algorithm_internal::c_end(c), |
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std::forward<EqualityComparable>(value)); |
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} |
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//------------------------------------------------------------------------------ |
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// <iterator> algorithms |
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//------------------------------------------------------------------------------ |
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// c_distance() |
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// |
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// Container-based version of the <iterator> `std::distance()` function to |
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// return the number of elements within a container. |
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template <typename C> |
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container_algorithm_internal::ContainerDifferenceType<const C> c_distance( |
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const C& c) { |
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return std::distance(container_algorithm_internal::c_begin(c), |
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container_algorithm_internal::c_end(c)); |
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} |
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//------------------------------------------------------------------------------ |
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// <algorithm> Non-modifying sequence operations |
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//------------------------------------------------------------------------------ |
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// c_all_of() |
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// |
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// Container-based version of the <algorithm> `std::all_of()` function to |
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// test a condition on all elements within a container. |
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template <typename C, typename Pred> |
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bool c_all_of(const C& c, Pred&& pred) { |
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return std::all_of(container_algorithm_internal::c_begin(c), |
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container_algorithm_internal::c_end(c), |
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std::forward<Pred>(pred)); |
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} |
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// c_any_of() |
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// |
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// Container-based version of the <algorithm> `std::any_of()` function to |
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// test if any element in a container fulfills a condition. |
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template <typename C, typename Pred> |
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bool c_any_of(const C& c, Pred&& pred) { |
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return std::any_of(container_algorithm_internal::c_begin(c), |
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container_algorithm_internal::c_end(c), |
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std::forward<Pred>(pred)); |
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} |
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// c_none_of() |
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// |
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// Container-based version of the <algorithm> `std::none_of()` function to |
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// test if no elements in a container fulfill a condition. |
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template <typename C, typename Pred> |
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bool c_none_of(const C& c, Pred&& pred) { |
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return std::none_of(container_algorithm_internal::c_begin(c), |
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container_algorithm_internal::c_end(c), |
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std::forward<Pred>(pred)); |
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} |
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// c_for_each() |
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// |
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// Container-based version of the <algorithm> `std::for_each()` function to |
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// apply a function to a container's elements. |
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template <typename C, typename Function> |
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decay_t<Function> c_for_each(C&& c, Function&& f) { |
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return std::for_each(container_algorithm_internal::c_begin(c), |
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container_algorithm_internal::c_end(c), |
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std::forward<Function>(f)); |
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} |
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// c_find() |
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// |
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// Container-based version of the <algorithm> `std::find()` function to find |
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// the first element containing the passed value within a container value. |
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template <typename C, typename T> |
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container_algorithm_internal::ContainerIter<C> c_find(C& c, T&& value) { |
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return std::find(container_algorithm_internal::c_begin(c), |
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container_algorithm_internal::c_end(c), |
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std::forward<T>(value)); |
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} |
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// c_find_if() |
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// |
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// Container-based version of the <algorithm> `std::find_if()` function to find |
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// the first element in a container matching the given condition. |
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template <typename C, typename Pred> |
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container_algorithm_internal::ContainerIter<C> c_find_if(C& c, Pred&& pred) { |
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return std::find_if(container_algorithm_internal::c_begin(c), |
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container_algorithm_internal::c_end(c), |
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std::forward<Pred>(pred)); |
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} |
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// c_find_if_not() |
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// |
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// Container-based version of the <algorithm> `std::find_if_not()` function to |
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// find the first element in a container not matching the given condition. |
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template <typename C, typename Pred> |
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container_algorithm_internal::ContainerIter<C> c_find_if_not(C& c, |
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Pred&& pred) { |
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return std::find_if_not(container_algorithm_internal::c_begin(c), |
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container_algorithm_internal::c_end(c), |
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std::forward<Pred>(pred)); |
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} |
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// c_find_end() |
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// |
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// Container-based version of the <algorithm> `std::find_end()` function to |
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// find the last subsequence within a container. |
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template <typename Sequence1, typename Sequence2> |
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container_algorithm_internal::ContainerIter<Sequence1> c_find_end( |
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Sequence1& sequence, Sequence2& subsequence) { |
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return std::find_end(container_algorithm_internal::c_begin(sequence), |
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container_algorithm_internal::c_end(sequence), |
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container_algorithm_internal::c_begin(subsequence), |
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container_algorithm_internal::c_end(subsequence)); |
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} |
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// Overload of c_find_end() for using a predicate evaluation other than `==` as |
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// the function's test condition. |
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template <typename Sequence1, typename Sequence2, typename BinaryPredicate> |
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container_algorithm_internal::ContainerIter<Sequence1> c_find_end( |
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Sequence1& sequence, Sequence2& subsequence, BinaryPredicate&& pred) { |
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return std::find_end(container_algorithm_internal::c_begin(sequence), |
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container_algorithm_internal::c_end(sequence), |
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container_algorithm_internal::c_begin(subsequence), |
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container_algorithm_internal::c_end(subsequence), |
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std::forward<BinaryPredicate>(pred)); |
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} |
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// c_find_first_of() |
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// |
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// Container-based version of the <algorithm> `std::find_first_of()` function to |
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// find the first element within the container that is also within the options |
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// container. |
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template <typename C1, typename C2> |
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container_algorithm_internal::ContainerIter<C1> c_find_first_of(C1& container, |
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C2& options) { |
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return std::find_first_of(container_algorithm_internal::c_begin(container), |
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container_algorithm_internal::c_end(container), |
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container_algorithm_internal::c_begin(options), |
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container_algorithm_internal::c_end(options)); |
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} |
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// Overload of c_find_first_of() for using a predicate evaluation other than |
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// `==` as the function's test condition. |
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template <typename C1, typename C2, typename BinaryPredicate> |
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container_algorithm_internal::ContainerIter<C1> c_find_first_of( |
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C1& container, C2& options, BinaryPredicate&& pred) { |
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return std::find_first_of(container_algorithm_internal::c_begin(container), |
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container_algorithm_internal::c_end(container), |
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container_algorithm_internal::c_begin(options), |
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container_algorithm_internal::c_end(options), |
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std::forward<BinaryPredicate>(pred)); |
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} |
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// c_adjacent_find() |
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// |
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// Container-based version of the <algorithm> `std::adjacent_find()` function to |
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// find equal adjacent elements within a container. |
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template <typename Sequence> |
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container_algorithm_internal::ContainerIter<Sequence> c_adjacent_find( |
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Sequence& sequence) { |
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return std::adjacent_find(container_algorithm_internal::c_begin(sequence), |
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container_algorithm_internal::c_end(sequence)); |
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} |
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// Overload of c_adjacent_find() for using a predicate evaluation other than |
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// `==` as the function's test condition. |
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template <typename Sequence, typename BinaryPredicate> |
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container_algorithm_internal::ContainerIter<Sequence> c_adjacent_find( |
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Sequence& sequence, BinaryPredicate&& pred) { |
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return std::adjacent_find(container_algorithm_internal::c_begin(sequence), |
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container_algorithm_internal::c_end(sequence), |
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std::forward<BinaryPredicate>(pred)); |
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} |
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// c_count() |
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// |
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// Container-based version of the <algorithm> `std::count()` function to count |
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// values that match within a container. |
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template <typename C, typename T> |
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container_algorithm_internal::ContainerDifferenceType<const C> c_count( |
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const C& c, T&& value) { |
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return std::count(container_algorithm_internal::c_begin(c), |
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container_algorithm_internal::c_end(c), |
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std::forward<T>(value)); |
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} |
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// c_count_if() |
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// |
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// Container-based version of the <algorithm> `std::count_if()` function to |
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// count values matching a condition within a container. |
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template <typename C, typename Pred> |
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container_algorithm_internal::ContainerDifferenceType<const C> c_count_if( |
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const C& c, Pred&& pred) { |
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return std::count_if(container_algorithm_internal::c_begin(c), |
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container_algorithm_internal::c_end(c), |
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std::forward<Pred>(pred)); |
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} |
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// c_mismatch() |
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// |
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// Container-based version of the <algorithm> `std::mismatch()` function to |
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// return the first element where two ordered containers differ. Applies `==` to |
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// the first N elements of `c1` and `c2`, where N = min(size(c1), size(c2)). |
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template <typename C1, typename C2> |
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container_algorithm_internal::ContainerIterPairType<C1, C2> |
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c_mismatch(C1& c1, C2& c2) { |
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auto first1 = container_algorithm_internal::c_begin(c1); |
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auto last1 = container_algorithm_internal::c_end(c1); |
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auto first2 = container_algorithm_internal::c_begin(c2); |
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auto last2 = container_algorithm_internal::c_end(c2); |
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for (; first1 != last1 && first2 != last2; ++first1, (void)++first2) { |
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// Negates equality because Cpp17EqualityComparable doesn't require clients |
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// to overload both `operator==` and `operator!=`. |
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if (!(*first1 == *first2)) { |
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break; |
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} |
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} |
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return std::make_pair(first1, first2); |
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} |
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// Overload of c_mismatch() for using a predicate evaluation other than `==` as |
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// the function's test condition. Applies `pred`to the first N elements of `c1` |
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// and `c2`, where N = min(size(c1), size(c2)). |
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template <typename C1, typename C2, typename BinaryPredicate> |
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container_algorithm_internal::ContainerIterPairType<C1, C2> |
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c_mismatch(C1& c1, C2& c2, BinaryPredicate pred) { |
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auto first1 = container_algorithm_internal::c_begin(c1); |
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auto last1 = container_algorithm_internal::c_end(c1); |
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auto first2 = container_algorithm_internal::c_begin(c2); |
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auto last2 = container_algorithm_internal::c_end(c2); |
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for (; first1 != last1 && first2 != last2; ++first1, (void)++first2) { |
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if (!pred(*first1, *first2)) { |
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break; |
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} |
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} |
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return std::make_pair(first1, first2); |
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} |
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// c_equal() |
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// |
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// Container-based version of the <algorithm> `std::equal()` function to |
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// test whether two containers are equal. |
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// |
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// NOTE: the semantics of c_equal() are slightly different than those of |
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// equal(): while the latter iterates over the second container only up to the |
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// size of the first container, c_equal() also checks whether the container |
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// sizes are equal. This better matches expectations about c_equal() based on |
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// its signature. |
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// |
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// Example: |
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// vector v1 = <1, 2, 3>; |
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// vector v2 = <1, 2, 3, 4>; |
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// equal(std::begin(v1), std::end(v1), std::begin(v2)) returns true |
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// c_equal(v1, v2) returns false |
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template <typename C1, typename C2> |
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bool c_equal(const C1& c1, const C2& c2) { |
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return ((container_algorithm_internal::c_size(c1) == |
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container_algorithm_internal::c_size(c2)) && |
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std::equal(container_algorithm_internal::c_begin(c1), |
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container_algorithm_internal::c_end(c1), |
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container_algorithm_internal::c_begin(c2))); |
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} |
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// Overload of c_equal() for using a predicate evaluation other than `==` as |
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// the function's test condition. |
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template <typename C1, typename C2, typename BinaryPredicate> |
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bool c_equal(const C1& c1, const C2& c2, BinaryPredicate&& pred) { |
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return ((container_algorithm_internal::c_size(c1) == |
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container_algorithm_internal::c_size(c2)) && |
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std::equal(container_algorithm_internal::c_begin(c1), |
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container_algorithm_internal::c_end(c1), |
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container_algorithm_internal::c_begin(c2), |
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std::forward<BinaryPredicate>(pred))); |
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} |
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// c_is_permutation() |
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// |
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// Container-based version of the <algorithm> `std::is_permutation()` function |
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// to test whether a container is a permutation of another. |
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template <typename C1, typename C2> |
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bool c_is_permutation(const C1& c1, const C2& c2) { |
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using std::begin; |
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using std::end; |
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return c1.size() == c2.size() && |
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std::is_permutation(begin(c1), end(c1), begin(c2)); |
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} |
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// Overload of c_is_permutation() for using a predicate evaluation other than |
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// `==` as the function's test condition. |
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template <typename C1, typename C2, typename BinaryPredicate> |
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bool c_is_permutation(const C1& c1, const C2& c2, BinaryPredicate&& pred) { |
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using std::begin; |
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using std::end; |
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return c1.size() == c2.size() && |
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std::is_permutation(begin(c1), end(c1), begin(c2), |
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std::forward<BinaryPredicate>(pred)); |
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} |
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// c_search() |
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// |
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// Container-based version of the <algorithm> `std::search()` function to search |
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// a container for a subsequence. |
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template <typename Sequence1, typename Sequence2> |
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container_algorithm_internal::ContainerIter<Sequence1> c_search( |
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Sequence1& sequence, Sequence2& subsequence) { |
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return std::search(container_algorithm_internal::c_begin(sequence), |
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container_algorithm_internal::c_end(sequence), |
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container_algorithm_internal::c_begin(subsequence), |
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container_algorithm_internal::c_end(subsequence)); |
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} |
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// Overload of c_search() for using a predicate evaluation other than |
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// `==` as the function's test condition. |
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template <typename Sequence1, typename Sequence2, typename BinaryPredicate> |
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container_algorithm_internal::ContainerIter<Sequence1> c_search( |
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Sequence1& sequence, Sequence2& subsequence, BinaryPredicate&& pred) { |
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return std::search(container_algorithm_internal::c_begin(sequence), |
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container_algorithm_internal::c_end(sequence), |
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container_algorithm_internal::c_begin(subsequence), |
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container_algorithm_internal::c_end(subsequence), |
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std::forward<BinaryPredicate>(pred)); |
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} |
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// c_search_n() |
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// |
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// Container-based version of the <algorithm> `std::search_n()` function to |
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// search a container for the first sequence of N elements. |
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template <typename Sequence, typename Size, typename T> |
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container_algorithm_internal::ContainerIter<Sequence> c_search_n( |
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Sequence& sequence, Size count, T&& value) { |
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return std::search_n(container_algorithm_internal::c_begin(sequence), |
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container_algorithm_internal::c_end(sequence), count, |
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std::forward<T>(value)); |
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} |
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// Overload of c_search_n() for using a predicate evaluation other than |
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// `==` as the function's test condition. |
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template <typename Sequence, typename Size, typename T, |
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typename BinaryPredicate> |
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container_algorithm_internal::ContainerIter<Sequence> c_search_n( |
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Sequence& sequence, Size count, T&& value, BinaryPredicate&& pred) { |
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return std::search_n(container_algorithm_internal::c_begin(sequence), |
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container_algorithm_internal::c_end(sequence), count, |
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std::forward<T>(value), |
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std::forward<BinaryPredicate>(pred)); |
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} |
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//------------------------------------------------------------------------------ |
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// <algorithm> Modifying sequence operations |
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//------------------------------------------------------------------------------ |
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|
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// c_copy() |
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// |
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// Container-based version of the <algorithm> `std::copy()` function to copy a |
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// container's elements into an iterator. |
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template <typename InputSequence, typename OutputIterator> |
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OutputIterator c_copy(const InputSequence& input, OutputIterator output) { |
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return std::copy(container_algorithm_internal::c_begin(input), |
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container_algorithm_internal::c_end(input), output); |
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} |
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// c_copy_n() |
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// |
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// Container-based version of the <algorithm> `std::copy_n()` function to copy a |
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// container's first N elements into an iterator. |
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template <typename C, typename Size, typename OutputIterator> |
|
OutputIterator c_copy_n(const C& input, Size n, OutputIterator output) { |
|
return std::copy_n(container_algorithm_internal::c_begin(input), n, output); |
|
} |
|
|
|
// c_copy_if() |
|
// |
|
// Container-based version of the <algorithm> `std::copy_if()` function to copy |
|
// a container's elements satisfying some condition into an iterator. |
|
template <typename InputSequence, typename OutputIterator, typename Pred> |
|
OutputIterator c_copy_if(const InputSequence& input, OutputIterator output, |
|
Pred&& pred) { |
|
return std::copy_if(container_algorithm_internal::c_begin(input), |
|
container_algorithm_internal::c_end(input), output, |
|
std::forward<Pred>(pred)); |
|
} |
|
|
|
// c_copy_backward() |
|
// |
|
// Container-based version of the <algorithm> `std::copy_backward()` function to |
|
// copy a container's elements in reverse order into an iterator. |
|
template <typename C, typename BidirectionalIterator> |
|
BidirectionalIterator c_copy_backward(const C& src, |
|
BidirectionalIterator dest) { |
|
return std::copy_backward(container_algorithm_internal::c_begin(src), |
|
container_algorithm_internal::c_end(src), dest); |
|
} |
|
|
|
// c_move() |
|
// |
|
// Container-based version of the <algorithm> `std::move()` function to move |
|
// a container's elements into an iterator. |
|
template <typename C, typename OutputIterator> |
|
OutputIterator c_move(C&& src, OutputIterator dest) { |
|
return std::move(container_algorithm_internal::c_begin(src), |
|
container_algorithm_internal::c_end(src), dest); |
|
} |
|
|
|
// c_move_backward() |
|
// |
|
// Container-based version of the <algorithm> `std::move_backward()` function to |
|
// move a container's elements into an iterator in reverse order. |
|
template <typename C, typename BidirectionalIterator> |
|
BidirectionalIterator c_move_backward(C&& src, BidirectionalIterator dest) { |
|
return std::move_backward(container_algorithm_internal::c_begin(src), |
|
container_algorithm_internal::c_end(src), dest); |
|
} |
|
|
|
// c_swap_ranges() |
|
// |
|
// Container-based version of the <algorithm> `std::swap_ranges()` function to |
|
// swap a container's elements with another container's elements. Swaps the |
|
// first N elements of `c1` and `c2`, where N = min(size(c1), size(c2)). |
|
template <typename C1, typename C2> |
|
container_algorithm_internal::ContainerIter<C2> c_swap_ranges(C1& c1, C2& c2) { |
|
auto first1 = container_algorithm_internal::c_begin(c1); |
|
auto last1 = container_algorithm_internal::c_end(c1); |
|
auto first2 = container_algorithm_internal::c_begin(c2); |
|
auto last2 = container_algorithm_internal::c_end(c2); |
|
|
|
using std::swap; |
|
for (; first1 != last1 && first2 != last2; ++first1, (void)++first2) { |
|
swap(*first1, *first2); |
|
} |
|
return first2; |
|
} |
|
|
|
// c_transform() |
|
// |
|
// Container-based version of the <algorithm> `std::transform()` function to |
|
// transform a container's elements using the unary operation, storing the |
|
// result in an iterator pointing to the last transformed element in the output |
|
// range. |
|
template <typename InputSequence, typename OutputIterator, typename UnaryOp> |
|
OutputIterator c_transform(const InputSequence& input, OutputIterator output, |
|
UnaryOp&& unary_op) { |
|
return std::transform(container_algorithm_internal::c_begin(input), |
|
container_algorithm_internal::c_end(input), output, |
|
std::forward<UnaryOp>(unary_op)); |
|
} |
|
|
|
// Overload of c_transform() for performing a transformation using a binary |
|
// predicate. Applies `binary_op` to the first N elements of `c1` and `c2`, |
|
// where N = min(size(c1), size(c2)). |
|
template <typename InputSequence1, typename InputSequence2, |
|
typename OutputIterator, typename BinaryOp> |
|
OutputIterator c_transform(const InputSequence1& input1, |
|
const InputSequence2& input2, OutputIterator output, |
|
BinaryOp&& binary_op) { |
|
auto first1 = container_algorithm_internal::c_begin(input1); |
|
auto last1 = container_algorithm_internal::c_end(input1); |
|
auto first2 = container_algorithm_internal::c_begin(input2); |
|
auto last2 = container_algorithm_internal::c_end(input2); |
|
for (; first1 != last1 && first2 != last2; |
|
++first1, (void)++first2, ++output) { |
|
*output = binary_op(*first1, *first2); |
|
} |
|
|
|
return output; |
|
} |
|
|
|
// c_replace() |
|
// |
|
// Container-based version of the <algorithm> `std::replace()` function to |
|
// replace a container's elements of some value with a new value. The container |
|
// is modified in place. |
|
template <typename Sequence, typename T> |
|
void c_replace(Sequence& sequence, const T& old_value, const T& new_value) { |
|
std::replace(container_algorithm_internal::c_begin(sequence), |
|
container_algorithm_internal::c_end(sequence), old_value, |
|
new_value); |
|
} |
|
|
|
// c_replace_if() |
|
// |
|
// Container-based version of the <algorithm> `std::replace_if()` function to |
|
// replace a container's elements of some value with a new value based on some |
|
// condition. The container is modified in place. |
|
template <typename C, typename Pred, typename T> |
|
void c_replace_if(C& c, Pred&& pred, T&& new_value) { |
|
std::replace_if(container_algorithm_internal::c_begin(c), |
|
container_algorithm_internal::c_end(c), |
|
std::forward<Pred>(pred), std::forward<T>(new_value)); |
|
} |
|
|
|
// c_replace_copy() |
|
// |
|
// Container-based version of the <algorithm> `std::replace_copy()` function to |
|
// replace a container's elements of some value with a new value and return the |
|
// results within an iterator. |
|
template <typename C, typename OutputIterator, typename T> |
|
OutputIterator c_replace_copy(const C& c, OutputIterator result, T&& old_value, |
|
T&& new_value) { |
|
return std::replace_copy(container_algorithm_internal::c_begin(c), |
|
container_algorithm_internal::c_end(c), result, |
|
std::forward<T>(old_value), |
|
std::forward<T>(new_value)); |
|
} |
|
|
|
// c_replace_copy_if() |
|
// |
|
// Container-based version of the <algorithm> `std::replace_copy_if()` function |
|
// to replace a container's elements of some value with a new value based on |
|
// some condition, and return the results within an iterator. |
|
template <typename C, typename OutputIterator, typename Pred, typename T> |
|
OutputIterator c_replace_copy_if(const C& c, OutputIterator result, Pred&& pred, |
|
T&& new_value) { |
|
return std::replace_copy_if(container_algorithm_internal::c_begin(c), |
|
container_algorithm_internal::c_end(c), result, |
|
std::forward<Pred>(pred), |
|
std::forward<T>(new_value)); |
|
} |
|
|
|
// c_fill() |
|
// |
|
// Container-based version of the <algorithm> `std::fill()` function to fill a |
|
// container with some value. |
|
template <typename C, typename T> |
|
void c_fill(C& c, T&& value) { |
|
std::fill(container_algorithm_internal::c_begin(c), |
|
container_algorithm_internal::c_end(c), std::forward<T>(value)); |
|
} |
|
|
|
// c_fill_n() |
|
// |
|
// Container-based version of the <algorithm> `std::fill_n()` function to fill |
|
// the first N elements in a container with some value. |
|
template <typename C, typename Size, typename T> |
|
void c_fill_n(C& c, Size n, T&& value) { |
|
std::fill_n(container_algorithm_internal::c_begin(c), n, |
|
std::forward<T>(value)); |
|
} |
|
|
|
// c_generate() |
|
// |
|
// Container-based version of the <algorithm> `std::generate()` function to |
|
// assign a container's elements to the values provided by the given generator. |
|
template <typename C, typename Generator> |
|
void c_generate(C& c, Generator&& gen) { |
|
std::generate(container_algorithm_internal::c_begin(c), |
|
container_algorithm_internal::c_end(c), |
|
std::forward<Generator>(gen)); |
|
} |
|
|
|
// c_generate_n() |
|
// |
|
// Container-based version of the <algorithm> `std::generate_n()` function to |
|
// assign a container's first N elements to the values provided by the given |
|
// generator. |
|
template <typename C, typename Size, typename Generator> |
|
container_algorithm_internal::ContainerIter<C> c_generate_n(C& c, Size n, |
|
Generator&& gen) { |
|
return std::generate_n(container_algorithm_internal::c_begin(c), n, |
|
std::forward<Generator>(gen)); |
|
} |
|
|
|
// Note: `c_xx()` <algorithm> container versions for `remove()`, `remove_if()`, |
|
// and `unique()` are omitted, because it's not clear whether or not such |
|
// functions should call erase on their supplied sequences afterwards. Either |
|
// behavior would be surprising for a different set of users. |
|
|
|
// c_remove_copy() |
|
// |
|
// Container-based version of the <algorithm> `std::remove_copy()` function to |
|
// copy a container's elements while removing any elements matching the given |
|
// `value`. |
|
template <typename C, typename OutputIterator, typename T> |
|
OutputIterator c_remove_copy(const C& c, OutputIterator result, T&& value) { |
|
return std::remove_copy(container_algorithm_internal::c_begin(c), |
|
container_algorithm_internal::c_end(c), result, |
|
std::forward<T>(value)); |
|
} |
|
|
|
// c_remove_copy_if() |
|
// |
|
// Container-based version of the <algorithm> `std::remove_copy_if()` function |
|
// to copy a container's elements while removing any elements matching the given |
|
// condition. |
|
template <typename C, typename OutputIterator, typename Pred> |
|
OutputIterator c_remove_copy_if(const C& c, OutputIterator result, |
|
Pred&& pred) { |
|
return std::remove_copy_if(container_algorithm_internal::c_begin(c), |
|
container_algorithm_internal::c_end(c), result, |
|
std::forward<Pred>(pred)); |
|
} |
|
|
|
// c_unique_copy() |
|
// |
|
// Container-based version of the <algorithm> `std::unique_copy()` function to |
|
// copy a container's elements while removing any elements containing duplicate |
|
// values. |
|
template <typename C, typename OutputIterator> |
|
OutputIterator c_unique_copy(const C& c, OutputIterator result) { |
|
return std::unique_copy(container_algorithm_internal::c_begin(c), |
|
container_algorithm_internal::c_end(c), result); |
|
} |
|
|
|
// Overload of c_unique_copy() for using a predicate evaluation other than |
|
// `==` for comparing uniqueness of the element values. |
|
template <typename C, typename OutputIterator, typename BinaryPredicate> |
|
OutputIterator c_unique_copy(const C& c, OutputIterator result, |
|
BinaryPredicate&& pred) { |
|
return std::unique_copy(container_algorithm_internal::c_begin(c), |
|
container_algorithm_internal::c_end(c), result, |
|
std::forward<BinaryPredicate>(pred)); |
|
} |
|
|
|
// c_reverse() |
|
// |
|
// Container-based version of the <algorithm> `std::reverse()` function to |
|
// reverse a container's elements. |
|
template <typename Sequence> |
|
void c_reverse(Sequence& sequence) { |
|
std::reverse(container_algorithm_internal::c_begin(sequence), |
|
container_algorithm_internal::c_end(sequence)); |
|
} |
|
|
|
// c_reverse_copy() |
|
// |
|
// Container-based version of the <algorithm> `std::reverse()` function to |
|
// reverse a container's elements and write them to an iterator range. |
|
template <typename C, typename OutputIterator> |
|
OutputIterator c_reverse_copy(const C& sequence, OutputIterator result) { |
|
return std::reverse_copy(container_algorithm_internal::c_begin(sequence), |
|
container_algorithm_internal::c_end(sequence), |
|
result); |
|
} |
|
|
|
// c_rotate() |
|
// |
|
// Container-based version of the <algorithm> `std::rotate()` function to |
|
// shift a container's elements leftward such that the `middle` element becomes |
|
// the first element in the container. |
|
template <typename C, |
|
typename Iterator = container_algorithm_internal::ContainerIter<C>> |
|
Iterator c_rotate(C& sequence, Iterator middle) { |
|
return absl::rotate(container_algorithm_internal::c_begin(sequence), middle, |
|
container_algorithm_internal::c_end(sequence)); |
|
} |
|
|
|
// c_rotate_copy() |
|
// |
|
// Container-based version of the <algorithm> `std::rotate_copy()` function to |
|
// shift a container's elements leftward such that the `middle` element becomes |
|
// the first element in a new iterator range. |
|
template <typename C, typename OutputIterator> |
|
OutputIterator c_rotate_copy( |
|
const C& sequence, |
|
container_algorithm_internal::ContainerIter<const C> middle, |
|
OutputIterator result) { |
|
return std::rotate_copy(container_algorithm_internal::c_begin(sequence), |
|
middle, container_algorithm_internal::c_end(sequence), |
|
result); |
|
} |
|
|
|
// c_shuffle() |
|
// |
|
// Container-based version of the <algorithm> `std::shuffle()` function to |
|
// randomly shuffle elements within the container using a `gen()` uniform random |
|
// number generator. |
|
template <typename RandomAccessContainer, typename UniformRandomBitGenerator> |
|
void c_shuffle(RandomAccessContainer& c, UniformRandomBitGenerator&& gen) { |
|
std::shuffle(container_algorithm_internal::c_begin(c), |
|
container_algorithm_internal::c_end(c), |
|
std::forward<UniformRandomBitGenerator>(gen)); |
|
} |
|
|
|
//------------------------------------------------------------------------------ |
|
// <algorithm> Partition functions |
|
//------------------------------------------------------------------------------ |
|
|
|
// c_is_partitioned() |
|
// |
|
// Container-based version of the <algorithm> `std::is_partitioned()` function |
|
// to test whether all elements in the container for which `pred` returns `true` |
|
// precede those for which `pred` is `false`. |
|
template <typename C, typename Pred> |
|
bool c_is_partitioned(const C& c, Pred&& pred) { |
|
return std::is_partitioned(container_algorithm_internal::c_begin(c), |
|
container_algorithm_internal::c_end(c), |
|
std::forward<Pred>(pred)); |
|
} |
|
|
|
// c_partition() |
|
// |
|
// Container-based version of the <algorithm> `std::partition()` function |
|
// to rearrange all elements in a container in such a way that all elements for |
|
// which `pred` returns `true` precede all those for which it returns `false`, |
|
// returning an iterator to the first element of the second group. |
|
template <typename C, typename Pred> |
|
container_algorithm_internal::ContainerIter<C> c_partition(C& c, Pred&& pred) { |
|
return std::partition(container_algorithm_internal::c_begin(c), |
|
container_algorithm_internal::c_end(c), |
|
std::forward<Pred>(pred)); |
|
} |
|
|
|
// c_stable_partition() |
|
// |
|
// Container-based version of the <algorithm> `std::stable_partition()` function |
|
// to rearrange all elements in a container in such a way that all elements for |
|
// which `pred` returns `true` precede all those for which it returns `false`, |
|
// preserving the relative ordering between the two groups. The function returns |
|
// an iterator to the first element of the second group. |
|
template <typename C, typename Pred> |
|
container_algorithm_internal::ContainerIter<C> c_stable_partition(C& c, |
|
Pred&& pred) { |
|
return std::stable_partition(container_algorithm_internal::c_begin(c), |
|
container_algorithm_internal::c_end(c), |
|
std::forward<Pred>(pred)); |
|
} |
|
|
|
// c_partition_copy() |
|
// |
|
// Container-based version of the <algorithm> `std::partition_copy()` function |
|
// to partition a container's elements and return them into two iterators: one |
|
// for which `pred` returns `true`, and one for which `pred` returns `false.` |
|
|
|
template <typename C, typename OutputIterator1, typename OutputIterator2, |
|
typename Pred> |
|
std::pair<OutputIterator1, OutputIterator2> c_partition_copy( |
|
const C& c, OutputIterator1 out_true, OutputIterator2 out_false, |
|
Pred&& pred) { |
|
return std::partition_copy(container_algorithm_internal::c_begin(c), |
|
container_algorithm_internal::c_end(c), out_true, |
|
out_false, std::forward<Pred>(pred)); |
|
} |
|
|
|
// c_partition_point() |
|
// |
|
// Container-based version of the <algorithm> `std::partition_point()` function |
|
// to return the first element of an already partitioned container for which |
|
// the given `pred` is not `true`. |
|
template <typename C, typename Pred> |
|
container_algorithm_internal::ContainerIter<C> c_partition_point(C& c, |
|
Pred&& pred) { |
|
return std::partition_point(container_algorithm_internal::c_begin(c), |
|
container_algorithm_internal::c_end(c), |
|
std::forward<Pred>(pred)); |
|
} |
|
|
|
//------------------------------------------------------------------------------ |
|
// <algorithm> Sorting functions |
|
//------------------------------------------------------------------------------ |
|
|
|
// c_sort() |
|
// |
|
// Container-based version of the <algorithm> `std::sort()` function |
|
// to sort elements in ascending order of their values. |
|
template <typename C> |
|
void c_sort(C& c) { |
|
std::sort(container_algorithm_internal::c_begin(c), |
|
container_algorithm_internal::c_end(c)); |
|
} |
|
|
|
// Overload of c_sort() for performing a `comp` comparison other than the |
|
// default `operator<`. |
|
template <typename C, typename Compare> |
|
void c_sort(C& c, Compare&& comp) { |
|
std::sort(container_algorithm_internal::c_begin(c), |
|
container_algorithm_internal::c_end(c), |
|
std::forward<Compare>(comp)); |
|
} |
|
|
|
// c_stable_sort() |
|
// |
|
// Container-based version of the <algorithm> `std::stable_sort()` function |
|
// to sort elements in ascending order of their values, preserving the order |
|
// of equivalents. |
|
template <typename C> |
|
void c_stable_sort(C& c) { |
|
std::stable_sort(container_algorithm_internal::c_begin(c), |
|
container_algorithm_internal::c_end(c)); |
|
} |
|
|
|
// Overload of c_stable_sort() for performing a `comp` comparison other than the |
|
// default `operator<`. |
|
template <typename C, typename Compare> |
|
void c_stable_sort(C& c, Compare&& comp) { |
|
std::stable_sort(container_algorithm_internal::c_begin(c), |
|
container_algorithm_internal::c_end(c), |
|
std::forward<Compare>(comp)); |
|
} |
|
|
|
// c_is_sorted() |
|
// |
|
// Container-based version of the <algorithm> `std::is_sorted()` function |
|
// to evaluate whether the given container is sorted in ascending order. |
|
template <typename C> |
|
bool c_is_sorted(const C& c) { |
|
return std::is_sorted(container_algorithm_internal::c_begin(c), |
|
container_algorithm_internal::c_end(c)); |
|
} |
|
|
|
// c_is_sorted() overload for performing a `comp` comparison other than the |
|
// default `operator<`. |
|
template <typename C, typename Compare> |
|
bool c_is_sorted(const C& c, Compare&& comp) { |
|
return std::is_sorted(container_algorithm_internal::c_begin(c), |
|
container_algorithm_internal::c_end(c), |
|
std::forward<Compare>(comp)); |
|
} |
|
|
|
// c_partial_sort() |
|
// |
|
// Container-based version of the <algorithm> `std::partial_sort()` function |
|
// to rearrange elements within a container such that elements before `middle` |
|
// are sorted in ascending order. |
|
template <typename RandomAccessContainer> |
|
void c_partial_sort( |
|
RandomAccessContainer& sequence, |
|
container_algorithm_internal::ContainerIter<RandomAccessContainer> middle) { |
|
std::partial_sort(container_algorithm_internal::c_begin(sequence), middle, |
|
container_algorithm_internal::c_end(sequence)); |
|
} |
|
|
|
// Overload of c_partial_sort() for performing a `comp` comparison other than |
|
// the default `operator<`. |
|
template <typename RandomAccessContainer, typename Compare> |
|
void c_partial_sort( |
|
RandomAccessContainer& sequence, |
|
container_algorithm_internal::ContainerIter<RandomAccessContainer> middle, |
|
Compare&& comp) { |
|
std::partial_sort(container_algorithm_internal::c_begin(sequence), middle, |
|
container_algorithm_internal::c_end(sequence), |
|
std::forward<Compare>(comp)); |
|
} |
|
|
|
// c_partial_sort_copy() |
|
// |
|
// Container-based version of the <algorithm> `std::partial_sort_copy()` |
|
// function to sort the elements in the given range `result` within the larger |
|
// `sequence` in ascending order (and using `result` as the output parameter). |
|
// At most min(result.last - result.first, sequence.last - sequence.first) |
|
// elements from the sequence will be stored in the result. |
|
template <typename C, typename RandomAccessContainer> |
|
container_algorithm_internal::ContainerIter<RandomAccessContainer> |
|
c_partial_sort_copy(const C& sequence, RandomAccessContainer& result) { |
|
return std::partial_sort_copy(container_algorithm_internal::c_begin(sequence), |
|
container_algorithm_internal::c_end(sequence), |
|
container_algorithm_internal::c_begin(result), |
|
container_algorithm_internal::c_end(result)); |
|
} |
|
|
|
// Overload of c_partial_sort_copy() for performing a `comp` comparison other |
|
// than the default `operator<`. |
|
template <typename C, typename RandomAccessContainer, typename Compare> |
|
container_algorithm_internal::ContainerIter<RandomAccessContainer> |
|
c_partial_sort_copy(const C& sequence, RandomAccessContainer& result, |
|
Compare&& comp) { |
|
return std::partial_sort_copy(container_algorithm_internal::c_begin(sequence), |
|
container_algorithm_internal::c_end(sequence), |
|
container_algorithm_internal::c_begin(result), |
|
container_algorithm_internal::c_end(result), |
|
std::forward<Compare>(comp)); |
|
} |
|
|
|
// c_is_sorted_until() |
|
// |
|
// Container-based version of the <algorithm> `std::is_sorted_until()` function |
|
// to return the first element within a container that is not sorted in |
|
// ascending order as an iterator. |
|
template <typename C> |
|
container_algorithm_internal::ContainerIter<C> c_is_sorted_until(C& c) { |
|
return std::is_sorted_until(container_algorithm_internal::c_begin(c), |
|
container_algorithm_internal::c_end(c)); |
|
} |
|
|
|
// Overload of c_is_sorted_until() for performing a `comp` comparison other than |
|
// the default `operator<`. |
|
template <typename C, typename Compare> |
|
container_algorithm_internal::ContainerIter<C> c_is_sorted_until( |
|
C& c, Compare&& comp) { |
|
return std::is_sorted_until(container_algorithm_internal::c_begin(c), |
|
container_algorithm_internal::c_end(c), |
|
std::forward<Compare>(comp)); |
|
} |
|
|
|
// c_nth_element() |
|
// |
|
// Container-based version of the <algorithm> `std::nth_element()` function |
|
// to rearrange the elements within a container such that the `nth` element |
|
// would be in that position in an ordered sequence; other elements may be in |
|
// any order, except that all preceding `nth` will be less than that element, |
|
// and all following `nth` will be greater than that element. |
|
template <typename RandomAccessContainer> |
|
void c_nth_element( |
|
RandomAccessContainer& sequence, |
|
container_algorithm_internal::ContainerIter<RandomAccessContainer> nth) { |
|
std::nth_element(container_algorithm_internal::c_begin(sequence), nth, |
|
container_algorithm_internal::c_end(sequence)); |
|
} |
|
|
|
// Overload of c_nth_element() for performing a `comp` comparison other than |
|
// the default `operator<`. |
|
template <typename RandomAccessContainer, typename Compare> |
|
void c_nth_element( |
|
RandomAccessContainer& sequence, |
|
container_algorithm_internal::ContainerIter<RandomAccessContainer> nth, |
|
Compare&& comp) { |
|
std::nth_element(container_algorithm_internal::c_begin(sequence), nth, |
|
container_algorithm_internal::c_end(sequence), |
|
std::forward<Compare>(comp)); |
|
} |
|
|
|
//------------------------------------------------------------------------------ |
|
// <algorithm> Binary Search |
|
//------------------------------------------------------------------------------ |
|
|
|
// c_lower_bound() |
|
// |
|
// Container-based version of the <algorithm> `std::lower_bound()` function |
|
// to return an iterator pointing to the first element in a sorted container |
|
// which does not compare less than `value`. |
|
template <typename Sequence, typename T> |
|
container_algorithm_internal::ContainerIter<Sequence> c_lower_bound( |
|
Sequence& sequence, T&& value) { |
|
return std::lower_bound(container_algorithm_internal::c_begin(sequence), |
|
container_algorithm_internal::c_end(sequence), |
|
std::forward<T>(value)); |
|
} |
|
|
|
// Overload of c_lower_bound() for performing a `comp` comparison other than |
|
// the default `operator<`. |
|
template <typename Sequence, typename T, typename Compare> |
|
container_algorithm_internal::ContainerIter<Sequence> c_lower_bound( |
|
Sequence& sequence, T&& value, Compare&& comp) { |
|
return std::lower_bound(container_algorithm_internal::c_begin(sequence), |
|
container_algorithm_internal::c_end(sequence), |
|
std::forward<T>(value), std::forward<Compare>(comp)); |
|
} |
|
|
|
// c_upper_bound() |
|
// |
|
// Container-based version of the <algorithm> `std::upper_bound()` function |
|
// to return an iterator pointing to the first element in a sorted container |
|
// which is greater than `value`. |
|
template <typename Sequence, typename T> |
|
container_algorithm_internal::ContainerIter<Sequence> c_upper_bound( |
|
Sequence& sequence, T&& value) { |
|
return std::upper_bound(container_algorithm_internal::c_begin(sequence), |
|
container_algorithm_internal::c_end(sequence), |
|
std::forward<T>(value)); |
|
} |
|
|
|
// Overload of c_upper_bound() for performing a `comp` comparison other than |
|
// the default `operator<`. |
|
template <typename Sequence, typename T, typename Compare> |
|
container_algorithm_internal::ContainerIter<Sequence> c_upper_bound( |
|
Sequence& sequence, T&& value, Compare&& comp) { |
|
return std::upper_bound(container_algorithm_internal::c_begin(sequence), |
|
container_algorithm_internal::c_end(sequence), |
|
std::forward<T>(value), std::forward<Compare>(comp)); |
|
} |
|
|
|
// c_equal_range() |
|
// |
|
// Container-based version of the <algorithm> `std::equal_range()` function |
|
// to return an iterator pair pointing to the first and last elements in a |
|
// sorted container which compare equal to `value`. |
|
template <typename Sequence, typename T> |
|
container_algorithm_internal::ContainerIterPairType<Sequence, Sequence> |
|
c_equal_range(Sequence& sequence, T&& value) { |
|
return std::equal_range(container_algorithm_internal::c_begin(sequence), |
|
container_algorithm_internal::c_end(sequence), |
|
std::forward<T>(value)); |
|
} |
|
|
|
// Overload of c_equal_range() for performing a `comp` comparison other than |
|
// the default `operator<`. |
|
template <typename Sequence, typename T, typename Compare> |
|
container_algorithm_internal::ContainerIterPairType<Sequence, Sequence> |
|
c_equal_range(Sequence& sequence, T&& value, Compare&& comp) { |
|
return std::equal_range(container_algorithm_internal::c_begin(sequence), |
|
container_algorithm_internal::c_end(sequence), |
|
std::forward<T>(value), std::forward<Compare>(comp)); |
|
} |
|
|
|
// c_binary_search() |
|
// |
|
// Container-based version of the <algorithm> `std::binary_search()` function |
|
// to test if any element in the sorted container contains a value equivalent to |
|
// 'value'. |
|
template <typename Sequence, typename T> |
|
bool c_binary_search(Sequence&& sequence, T&& value) { |
|
return std::binary_search(container_algorithm_internal::c_begin(sequence), |
|
container_algorithm_internal::c_end(sequence), |
|
std::forward<T>(value)); |
|
} |
|
|
|
// Overload of c_binary_search() for performing a `comp` comparison other than |
|
// the default `operator<`. |
|
template <typename Sequence, typename T, typename Compare> |
|
bool c_binary_search(Sequence&& sequence, T&& value, Compare&& comp) { |
|
return std::binary_search(container_algorithm_internal::c_begin(sequence), |
|
container_algorithm_internal::c_end(sequence), |
|
std::forward<T>(value), |
|
std::forward<Compare>(comp)); |
|
} |
|
|
|
//------------------------------------------------------------------------------ |
|
// <algorithm> Merge functions |
|
//------------------------------------------------------------------------------ |
|
|
|
// c_merge() |
|
// |
|
// Container-based version of the <algorithm> `std::merge()` function |
|
// to merge two sorted containers into a single sorted iterator. |
|
template <typename C1, typename C2, typename OutputIterator> |
|
OutputIterator c_merge(const C1& c1, const C2& c2, OutputIterator result) { |
|
return std::merge(container_algorithm_internal::c_begin(c1), |
|
container_algorithm_internal::c_end(c1), |
|
container_algorithm_internal::c_begin(c2), |
|
container_algorithm_internal::c_end(c2), result); |
|
} |
|
|
|
// Overload of c_merge() for performing a `comp` comparison other than |
|
// the default `operator<`. |
|
template <typename C1, typename C2, typename OutputIterator, typename Compare> |
|
OutputIterator c_merge(const C1& c1, const C2& c2, OutputIterator result, |
|
Compare&& comp) { |
|
return std::merge(container_algorithm_internal::c_begin(c1), |
|
container_algorithm_internal::c_end(c1), |
|
container_algorithm_internal::c_begin(c2), |
|
container_algorithm_internal::c_end(c2), result, |
|
std::forward<Compare>(comp)); |
|
} |
|
|
|
// c_inplace_merge() |
|
// |
|
// Container-based version of the <algorithm> `std::inplace_merge()` function |
|
// to merge a supplied iterator `middle` into a container. |
|
template <typename C> |
|
void c_inplace_merge(C& c, |
|
container_algorithm_internal::ContainerIter<C> middle) { |
|
std::inplace_merge(container_algorithm_internal::c_begin(c), middle, |
|
container_algorithm_internal::c_end(c)); |
|
} |
|
|
|
// Overload of c_inplace_merge() for performing a merge using a `comp` other |
|
// than `operator<`. |
|
template <typename C, typename Compare> |
|
void c_inplace_merge(C& c, |
|
container_algorithm_internal::ContainerIter<C> middle, |
|
Compare&& comp) { |
|
std::inplace_merge(container_algorithm_internal::c_begin(c), middle, |
|
container_algorithm_internal::c_end(c), |
|
std::forward<Compare>(comp)); |
|
} |
|
|
|
// c_includes() |
|
// |
|
// Container-based version of the <algorithm> `std::includes()` function |
|
// to test whether a sorted container `c1` entirely contains another sorted |
|
// container `c2`. |
|
template <typename C1, typename C2> |
|
bool c_includes(const C1& c1, const C2& c2) { |
|
return std::includes(container_algorithm_internal::c_begin(c1), |
|
container_algorithm_internal::c_end(c1), |
|
container_algorithm_internal::c_begin(c2), |
|
container_algorithm_internal::c_end(c2)); |
|
} |
|
|
|
// Overload of c_includes() for performing a merge using a `comp` other than |
|
// `operator<`. |
|
template <typename C1, typename C2, typename Compare> |
|
bool c_includes(const C1& c1, const C2& c2, Compare&& comp) { |
|
return std::includes(container_algorithm_internal::c_begin(c1), |
|
container_algorithm_internal::c_end(c1), |
|
container_algorithm_internal::c_begin(c2), |
|
container_algorithm_internal::c_end(c2), |
|
std::forward<Compare>(comp)); |
|
} |
|
|
|
// c_set_union() |
|
// |
|
// Container-based version of the <algorithm> `std::set_union()` function |
|
// to return an iterator containing the union of two containers; duplicate |
|
// values are not copied into the output. |
|
template <typename C1, typename C2, typename OutputIterator, |
|
typename = typename std::enable_if< |
|
!container_algorithm_internal::IsUnorderedContainer<C1>::value, |
|
void>::type, |
|
typename = typename std::enable_if< |
|
!container_algorithm_internal::IsUnorderedContainer<C2>::value, |
|
void>::type> |
|
OutputIterator c_set_union(const C1& c1, const C2& c2, OutputIterator output) { |
|
return std::set_union(container_algorithm_internal::c_begin(c1), |
|
container_algorithm_internal::c_end(c1), |
|
container_algorithm_internal::c_begin(c2), |
|
container_algorithm_internal::c_end(c2), output); |
|
} |
|
|
|
// Overload of c_set_union() for performing a merge using a `comp` other than |
|
// `operator<`. |
|
template <typename C1, typename C2, typename OutputIterator, typename Compare, |
|
typename = typename std::enable_if< |
|
!container_algorithm_internal::IsUnorderedContainer<C1>::value, |
|
void>::type, |
|
typename = typename std::enable_if< |
|
!container_algorithm_internal::IsUnorderedContainer<C2>::value, |
|
void>::type> |
|
OutputIterator c_set_union(const C1& c1, const C2& c2, OutputIterator output, |
|
Compare&& comp) { |
|
return std::set_union(container_algorithm_internal::c_begin(c1), |
|
container_algorithm_internal::c_end(c1), |
|
container_algorithm_internal::c_begin(c2), |
|
container_algorithm_internal::c_end(c2), output, |
|
std::forward<Compare>(comp)); |
|
} |
|
|
|
// c_set_intersection() |
|
// |
|
// Container-based version of the <algorithm> `std::set_intersection()` function |
|
// to return an iterator containing the intersection of two containers. |
|
template <typename C1, typename C2, typename OutputIterator, |
|
typename = typename std::enable_if< |
|
!container_algorithm_internal::IsUnorderedContainer<C1>::value, |
|
void>::type, |
|
typename = typename std::enable_if< |
|
!container_algorithm_internal::IsUnorderedContainer<C2>::value, |
|
void>::type> |
|
OutputIterator c_set_intersection(const C1& c1, const C2& c2, |
|
OutputIterator output) { |
|
return std::set_intersection(container_algorithm_internal::c_begin(c1), |
|
container_algorithm_internal::c_end(c1), |
|
container_algorithm_internal::c_begin(c2), |
|
container_algorithm_internal::c_end(c2), output); |
|
} |
|
|
|
// Overload of c_set_intersection() for performing a merge using a `comp` other |
|
// than `operator<`. |
|
template <typename C1, typename C2, typename OutputIterator, typename Compare, |
|
typename = typename std::enable_if< |
|
!container_algorithm_internal::IsUnorderedContainer<C1>::value, |
|
void>::type, |
|
typename = typename std::enable_if< |
|
!container_algorithm_internal::IsUnorderedContainer<C2>::value, |
|
void>::type> |
|
OutputIterator c_set_intersection(const C1& c1, const C2& c2, |
|
OutputIterator output, Compare&& comp) { |
|
return std::set_intersection(container_algorithm_internal::c_begin(c1), |
|
container_algorithm_internal::c_end(c1), |
|
container_algorithm_internal::c_begin(c2), |
|
container_algorithm_internal::c_end(c2), output, |
|
std::forward<Compare>(comp)); |
|
} |
|
|
|
// c_set_difference() |
|
// |
|
// Container-based version of the <algorithm> `std::set_difference()` function |
|
// to return an iterator containing elements present in the first container but |
|
// not in the second. |
|
template <typename C1, typename C2, typename OutputIterator, |
|
typename = typename std::enable_if< |
|
!container_algorithm_internal::IsUnorderedContainer<C1>::value, |
|
void>::type, |
|
typename = typename std::enable_if< |
|
!container_algorithm_internal::IsUnorderedContainer<C2>::value, |
|
void>::type> |
|
OutputIterator c_set_difference(const C1& c1, const C2& c2, |
|
OutputIterator output) { |
|
return std::set_difference(container_algorithm_internal::c_begin(c1), |
|
container_algorithm_internal::c_end(c1), |
|
container_algorithm_internal::c_begin(c2), |
|
container_algorithm_internal::c_end(c2), output); |
|
} |
|
|
|
// Overload of c_set_difference() for performing a merge using a `comp` other |
|
// than `operator<`. |
|
template <typename C1, typename C2, typename OutputIterator, typename Compare, |
|
typename = typename std::enable_if< |
|
!container_algorithm_internal::IsUnorderedContainer<C1>::value, |
|
void>::type, |
|
typename = typename std::enable_if< |
|
!container_algorithm_internal::IsUnorderedContainer<C2>::value, |
|
void>::type> |
|
OutputIterator c_set_difference(const C1& c1, const C2& c2, |
|
OutputIterator output, Compare&& comp) { |
|
return std::set_difference(container_algorithm_internal::c_begin(c1), |
|
container_algorithm_internal::c_end(c1), |
|
container_algorithm_internal::c_begin(c2), |
|
container_algorithm_internal::c_end(c2), output, |
|
std::forward<Compare>(comp)); |
|
} |
|
|
|
// c_set_symmetric_difference() |
|
// |
|
// Container-based version of the <algorithm> `std::set_symmetric_difference()` |
|
// function to return an iterator containing elements present in either one |
|
// container or the other, but not both. |
|
template <typename C1, typename C2, typename OutputIterator, |
|
typename = typename std::enable_if< |
|
!container_algorithm_internal::IsUnorderedContainer<C1>::value, |
|
void>::type, |
|
typename = typename std::enable_if< |
|
!container_algorithm_internal::IsUnorderedContainer<C2>::value, |
|
void>::type> |
|
OutputIterator c_set_symmetric_difference(const C1& c1, const C2& c2, |
|
OutputIterator output) { |
|
return std::set_symmetric_difference( |
|
container_algorithm_internal::c_begin(c1), |
|
container_algorithm_internal::c_end(c1), |
|
container_algorithm_internal::c_begin(c2), |
|
container_algorithm_internal::c_end(c2), output); |
|
} |
|
|
|
// Overload of c_set_symmetric_difference() for performing a merge using a |
|
// `comp` other than `operator<`. |
|
template <typename C1, typename C2, typename OutputIterator, typename Compare, |
|
typename = typename std::enable_if< |
|
!container_algorithm_internal::IsUnorderedContainer<C1>::value, |
|
void>::type, |
|
typename = typename std::enable_if< |
|
!container_algorithm_internal::IsUnorderedContainer<C2>::value, |
|
void>::type> |
|
OutputIterator c_set_symmetric_difference(const C1& c1, const C2& c2, |
|
OutputIterator output, |
|
Compare&& comp) { |
|
return std::set_symmetric_difference( |
|
container_algorithm_internal::c_begin(c1), |
|
container_algorithm_internal::c_end(c1), |
|
container_algorithm_internal::c_begin(c2), |
|
container_algorithm_internal::c_end(c2), output, |
|
std::forward<Compare>(comp)); |
|
} |
|
|
|
//------------------------------------------------------------------------------ |
|
// <algorithm> Heap functions |
|
//------------------------------------------------------------------------------ |
|
|
|
// c_push_heap() |
|
// |
|
// Container-based version of the <algorithm> `std::push_heap()` function |
|
// to push a value onto a container heap. |
|
template <typename RandomAccessContainer> |
|
void c_push_heap(RandomAccessContainer& sequence) { |
|
std::push_heap(container_algorithm_internal::c_begin(sequence), |
|
container_algorithm_internal::c_end(sequence)); |
|
} |
|
|
|
// Overload of c_push_heap() for performing a push operation on a heap using a |
|
// `comp` other than `operator<`. |
|
template <typename RandomAccessContainer, typename Compare> |
|
void c_push_heap(RandomAccessContainer& sequence, Compare&& comp) { |
|
std::push_heap(container_algorithm_internal::c_begin(sequence), |
|
container_algorithm_internal::c_end(sequence), |
|
std::forward<Compare>(comp)); |
|
} |
|
|
|
// c_pop_heap() |
|
// |
|
// Container-based version of the <algorithm> `std::pop_heap()` function |
|
// to pop a value from a heap container. |
|
template <typename RandomAccessContainer> |
|
void c_pop_heap(RandomAccessContainer& sequence) { |
|
std::pop_heap(container_algorithm_internal::c_begin(sequence), |
|
container_algorithm_internal::c_end(sequence)); |
|
} |
|
|
|
// Overload of c_pop_heap() for performing a pop operation on a heap using a |
|
// `comp` other than `operator<`. |
|
template <typename RandomAccessContainer, typename Compare> |
|
void c_pop_heap(RandomAccessContainer& sequence, Compare&& comp) { |
|
std::pop_heap(container_algorithm_internal::c_begin(sequence), |
|
container_algorithm_internal::c_end(sequence), |
|
std::forward<Compare>(comp)); |
|
} |
|
|
|
// c_make_heap() |
|
// |
|
// Container-based version of the <algorithm> `std::make_heap()` function |
|
// to make a container a heap. |
|
template <typename RandomAccessContainer> |
|
void c_make_heap(RandomAccessContainer& sequence) { |
|
std::make_heap(container_algorithm_internal::c_begin(sequence), |
|
container_algorithm_internal::c_end(sequence)); |
|
} |
|
|
|
// Overload of c_make_heap() for performing heap comparisons using a |
|
// `comp` other than `operator<` |
|
template <typename RandomAccessContainer, typename Compare> |
|
void c_make_heap(RandomAccessContainer& sequence, Compare&& comp) { |
|
std::make_heap(container_algorithm_internal::c_begin(sequence), |
|
container_algorithm_internal::c_end(sequence), |
|
std::forward<Compare>(comp)); |
|
} |
|
|
|
// c_sort_heap() |
|
// |
|
// Container-based version of the <algorithm> `std::sort_heap()` function |
|
// to sort a heap into ascending order (after which it is no longer a heap). |
|
template <typename RandomAccessContainer> |
|
void c_sort_heap(RandomAccessContainer& sequence) { |
|
std::sort_heap(container_algorithm_internal::c_begin(sequence), |
|
container_algorithm_internal::c_end(sequence)); |
|
} |
|
|
|
// Overload of c_sort_heap() for performing heap comparisons using a |
|
// `comp` other than `operator<` |
|
template <typename RandomAccessContainer, typename Compare> |
|
void c_sort_heap(RandomAccessContainer& sequence, Compare&& comp) { |
|
std::sort_heap(container_algorithm_internal::c_begin(sequence), |
|
container_algorithm_internal::c_end(sequence), |
|
std::forward<Compare>(comp)); |
|
} |
|
|
|
// c_is_heap() |
|
// |
|
// Container-based version of the <algorithm> `std::is_heap()` function |
|
// to check whether the given container is a heap. |
|
template <typename RandomAccessContainer> |
|
bool c_is_heap(const RandomAccessContainer& sequence) { |
|
return std::is_heap(container_algorithm_internal::c_begin(sequence), |
|
container_algorithm_internal::c_end(sequence)); |
|
} |
|
|
|
// Overload of c_is_heap() for performing heap comparisons using a |
|
// `comp` other than `operator<` |
|
template <typename RandomAccessContainer, typename Compare> |
|
bool c_is_heap(const RandomAccessContainer& sequence, Compare&& comp) { |
|
return std::is_heap(container_algorithm_internal::c_begin(sequence), |
|
container_algorithm_internal::c_end(sequence), |
|
std::forward<Compare>(comp)); |
|
} |
|
|
|
// c_is_heap_until() |
|
// |
|
// Container-based version of the <algorithm> `std::is_heap_until()` function |
|
// to find the first element in a given container which is not in heap order. |
|
template <typename RandomAccessContainer> |
|
container_algorithm_internal::ContainerIter<RandomAccessContainer> |
|
c_is_heap_until(RandomAccessContainer& sequence) { |
|
return std::is_heap_until(container_algorithm_internal::c_begin(sequence), |
|
container_algorithm_internal::c_end(sequence)); |
|
} |
|
|
|
// Overload of c_is_heap_until() for performing heap comparisons using a |
|
// `comp` other than `operator<` |
|
template <typename RandomAccessContainer, typename Compare> |
|
container_algorithm_internal::ContainerIter<RandomAccessContainer> |
|
c_is_heap_until(RandomAccessContainer& sequence, Compare&& comp) { |
|
return std::is_heap_until(container_algorithm_internal::c_begin(sequence), |
|
container_algorithm_internal::c_end(sequence), |
|
std::forward<Compare>(comp)); |
|
} |
|
|
|
//------------------------------------------------------------------------------ |
|
// <algorithm> Min/max |
|
//------------------------------------------------------------------------------ |
|
|
|
// c_min_element() |
|
// |
|
// Container-based version of the <algorithm> `std::min_element()` function |
|
// to return an iterator pointing to the element with the smallest value, using |
|
// `operator<` to make the comparisons. |
|
template <typename Sequence> |
|
container_algorithm_internal::ContainerIter<Sequence> c_min_element( |
|
Sequence& sequence) { |
|
return std::min_element(container_algorithm_internal::c_begin(sequence), |
|
container_algorithm_internal::c_end(sequence)); |
|
} |
|
|
|
// Overload of c_min_element() for performing a `comp` comparison other than |
|
// `operator<`. |
|
template <typename Sequence, typename Compare> |
|
container_algorithm_internal::ContainerIter<Sequence> c_min_element( |
|
Sequence& sequence, Compare&& comp) { |
|
return std::min_element(container_algorithm_internal::c_begin(sequence), |
|
container_algorithm_internal::c_end(sequence), |
|
std::forward<Compare>(comp)); |
|
} |
|
|
|
// c_max_element() |
|
// |
|
// Container-based version of the <algorithm> `std::max_element()` function |
|
// to return an iterator pointing to the element with the largest value, using |
|
// `operator<` to make the comparisons. |
|
template <typename Sequence> |
|
container_algorithm_internal::ContainerIter<Sequence> c_max_element( |
|
Sequence& sequence) { |
|
return std::max_element(container_algorithm_internal::c_begin(sequence), |
|
container_algorithm_internal::c_end(sequence)); |
|
} |
|
|
|
// Overload of c_max_element() for performing a `comp` comparison other than |
|
// `operator<`. |
|
template <typename Sequence, typename Compare> |
|
container_algorithm_internal::ContainerIter<Sequence> c_max_element( |
|
Sequence& sequence, Compare&& comp) { |
|
return std::max_element(container_algorithm_internal::c_begin(sequence), |
|
container_algorithm_internal::c_end(sequence), |
|
std::forward<Compare>(comp)); |
|
} |
|
|
|
// c_minmax_element() |
|
// |
|
// Container-based version of the <algorithm> `std::minmax_element()` function |
|
// to return a pair of iterators pointing to the elements containing the |
|
// smallest and largest values, respectively, using `operator<` to make the |
|
// comparisons. |
|
template <typename C> |
|
container_algorithm_internal::ContainerIterPairType<C, C> |
|
c_minmax_element(C& c) { |
|
return std::minmax_element(container_algorithm_internal::c_begin(c), |
|
container_algorithm_internal::c_end(c)); |
|
} |
|
|
|
// Overload of c_minmax_element() for performing `comp` comparisons other than |
|
// `operator<`. |
|
template <typename C, typename Compare> |
|
container_algorithm_internal::ContainerIterPairType<C, C> |
|
c_minmax_element(C& c, Compare&& comp) { |
|
return std::minmax_element(container_algorithm_internal::c_begin(c), |
|
container_algorithm_internal::c_end(c), |
|
std::forward<Compare>(comp)); |
|
} |
|
|
|
//------------------------------------------------------------------------------ |
|
// <algorithm> Lexicographical Comparisons |
|
//------------------------------------------------------------------------------ |
|
|
|
// c_lexicographical_compare() |
|
// |
|
// Container-based version of the <algorithm> `std::lexicographical_compare()` |
|
// function to lexicographically compare (e.g. sort words alphabetically) two |
|
// container sequences. The comparison is performed using `operator<`. Note |
|
// that capital letters ("A-Z") have ASCII values less than lowercase letters |
|
// ("a-z"). |
|
template <typename Sequence1, typename Sequence2> |
|
bool c_lexicographical_compare(Sequence1&& sequence1, Sequence2&& sequence2) { |
|
return std::lexicographical_compare( |
|
container_algorithm_internal::c_begin(sequence1), |
|
container_algorithm_internal::c_end(sequence1), |
|
container_algorithm_internal::c_begin(sequence2), |
|
container_algorithm_internal::c_end(sequence2)); |
|
} |
|
|
|
// Overload of c_lexicographical_compare() for performing a lexicographical |
|
// comparison using a `comp` operator instead of `operator<`. |
|
template <typename Sequence1, typename Sequence2, typename Compare> |
|
bool c_lexicographical_compare(Sequence1&& sequence1, Sequence2&& sequence2, |
|
Compare&& comp) { |
|
return std::lexicographical_compare( |
|
container_algorithm_internal::c_begin(sequence1), |
|
container_algorithm_internal::c_end(sequence1), |
|
container_algorithm_internal::c_begin(sequence2), |
|
container_algorithm_internal::c_end(sequence2), |
|
std::forward<Compare>(comp)); |
|
} |
|
|
|
// c_next_permutation() |
|
// |
|
// Container-based version of the <algorithm> `std::next_permutation()` function |
|
// to rearrange a container's elements into the next lexicographically greater |
|
// permutation. |
|
template <typename C> |
|
bool c_next_permutation(C& c) { |
|
return std::next_permutation(container_algorithm_internal::c_begin(c), |
|
container_algorithm_internal::c_end(c)); |
|
} |
|
|
|
// Overload of c_next_permutation() for performing a lexicographical |
|
// comparison using a `comp` operator instead of `operator<`. |
|
template <typename C, typename Compare> |
|
bool c_next_permutation(C& c, Compare&& comp) { |
|
return std::next_permutation(container_algorithm_internal::c_begin(c), |
|
container_algorithm_internal::c_end(c), |
|
std::forward<Compare>(comp)); |
|
} |
|
|
|
// c_prev_permutation() |
|
// |
|
// Container-based version of the <algorithm> `std::prev_permutation()` function |
|
// to rearrange a container's elements into the next lexicographically lesser |
|
// permutation. |
|
template <typename C> |
|
bool c_prev_permutation(C& c) { |
|
return std::prev_permutation(container_algorithm_internal::c_begin(c), |
|
container_algorithm_internal::c_end(c)); |
|
} |
|
|
|
// Overload of c_prev_permutation() for performing a lexicographical |
|
// comparison using a `comp` operator instead of `operator<`. |
|
template <typename C, typename Compare> |
|
bool c_prev_permutation(C& c, Compare&& comp) { |
|
return std::prev_permutation(container_algorithm_internal::c_begin(c), |
|
container_algorithm_internal::c_end(c), |
|
std::forward<Compare>(comp)); |
|
} |
|
|
|
//------------------------------------------------------------------------------ |
|
// <numeric> algorithms |
|
//------------------------------------------------------------------------------ |
|
|
|
// c_iota() |
|
// |
|
// Container-based version of the <algorithm> `std::iota()` function |
|
// to compute successive values of `value`, as if incremented with `++value` |
|
// after each element is written. and write them to the container. |
|
template <typename Sequence, typename T> |
|
void c_iota(Sequence& sequence, T&& value) { |
|
std::iota(container_algorithm_internal::c_begin(sequence), |
|
container_algorithm_internal::c_end(sequence), |
|
std::forward<T>(value)); |
|
} |
|
// c_accumulate() |
|
// |
|
// Container-based version of the <algorithm> `std::accumulate()` function |
|
// to accumulate the element values of a container to `init` and return that |
|
// accumulation by value. |
|
// |
|
// Note: Due to a language technicality this function has return type |
|
// absl::decay_t<T>. As a user of this function you can casually read |
|
// this as "returns T by value" and assume it does the right thing. |
|
template <typename Sequence, typename T> |
|
decay_t<T> c_accumulate(const Sequence& sequence, T&& init) { |
|
return std::accumulate(container_algorithm_internal::c_begin(sequence), |
|
container_algorithm_internal::c_end(sequence), |
|
std::forward<T>(init)); |
|
} |
|
|
|
// Overload of c_accumulate() for using a binary operations other than |
|
// addition for computing the accumulation. |
|
template <typename Sequence, typename T, typename BinaryOp> |
|
decay_t<T> c_accumulate(const Sequence& sequence, T&& init, |
|
BinaryOp&& binary_op) { |
|
return std::accumulate(container_algorithm_internal::c_begin(sequence), |
|
container_algorithm_internal::c_end(sequence), |
|
std::forward<T>(init), |
|
std::forward<BinaryOp>(binary_op)); |
|
} |
|
|
|
// c_inner_product() |
|
// |
|
// Container-based version of the <algorithm> `std::inner_product()` function |
|
// to compute the cumulative inner product of container element pairs. |
|
// |
|
// Note: Due to a language technicality this function has return type |
|
// absl::decay_t<T>. As a user of this function you can casually read |
|
// this as "returns T by value" and assume it does the right thing. |
|
template <typename Sequence1, typename Sequence2, typename T> |
|
decay_t<T> c_inner_product(const Sequence1& factors1, const Sequence2& factors2, |
|
T&& sum) { |
|
return std::inner_product(container_algorithm_internal::c_begin(factors1), |
|
container_algorithm_internal::c_end(factors1), |
|
container_algorithm_internal::c_begin(factors2), |
|
std::forward<T>(sum)); |
|
} |
|
|
|
// Overload of c_inner_product() for using binary operations other than |
|
// `operator+` (for computing the accumulation) and `operator*` (for computing |
|
// the product between the two container's element pair). |
|
template <typename Sequence1, typename Sequence2, typename T, |
|
typename BinaryOp1, typename BinaryOp2> |
|
decay_t<T> c_inner_product(const Sequence1& factors1, const Sequence2& factors2, |
|
T&& sum, BinaryOp1&& op1, BinaryOp2&& op2) { |
|
return std::inner_product(container_algorithm_internal::c_begin(factors1), |
|
container_algorithm_internal::c_end(factors1), |
|
container_algorithm_internal::c_begin(factors2), |
|
std::forward<T>(sum), std::forward<BinaryOp1>(op1), |
|
std::forward<BinaryOp2>(op2)); |
|
} |
|
|
|
// c_adjacent_difference() |
|
// |
|
// Container-based version of the <algorithm> `std::adjacent_difference()` |
|
// function to compute the difference between each element and the one preceding |
|
// it and write it to an iterator. |
|
template <typename InputSequence, typename OutputIt> |
|
OutputIt c_adjacent_difference(const InputSequence& input, |
|
OutputIt output_first) { |
|
return std::adjacent_difference(container_algorithm_internal::c_begin(input), |
|
container_algorithm_internal::c_end(input), |
|
output_first); |
|
} |
|
|
|
// Overload of c_adjacent_difference() for using a binary operation other than |
|
// subtraction to compute the adjacent difference. |
|
template <typename InputSequence, typename OutputIt, typename BinaryOp> |
|
OutputIt c_adjacent_difference(const InputSequence& input, |
|
OutputIt output_first, BinaryOp&& op) { |
|
return std::adjacent_difference(container_algorithm_internal::c_begin(input), |
|
container_algorithm_internal::c_end(input), |
|
output_first, std::forward<BinaryOp>(op)); |
|
} |
|
|
|
// c_partial_sum() |
|
// |
|
// Container-based version of the <algorithm> `std::partial_sum()` function |
|
// to compute the partial sum of the elements in a sequence and write them |
|
// to an iterator. The partial sum is the sum of all element values so far in |
|
// the sequence. |
|
template <typename InputSequence, typename OutputIt> |
|
OutputIt c_partial_sum(const InputSequence& input, OutputIt output_first) { |
|
return std::partial_sum(container_algorithm_internal::c_begin(input), |
|
container_algorithm_internal::c_end(input), |
|
output_first); |
|
} |
|
|
|
// Overload of c_partial_sum() for using a binary operation other than addition |
|
// to compute the "partial sum". |
|
template <typename InputSequence, typename OutputIt, typename BinaryOp> |
|
OutputIt c_partial_sum(const InputSequence& input, OutputIt output_first, |
|
BinaryOp&& op) { |
|
return std::partial_sum(container_algorithm_internal::c_begin(input), |
|
container_algorithm_internal::c_end(input), |
|
output_first, std::forward<BinaryOp>(op)); |
|
} |
|
|
|
ABSL_NAMESPACE_END |
|
} // namespace absl |
|
|
|
#endif // ABSL_ALGORITHM_CONTAINER_H_
|
|
|