diff options
Diffstat (limited to 'third_party/abseil_cpp/absl/algorithm')
-rw-r--r-- | third_party/abseil_cpp/absl/algorithm/BUILD.bazel | 91 | ||||
-rw-r--r-- | third_party/abseil_cpp/absl/algorithm/CMakeLists.txt | 69 | ||||
-rw-r--r-- | third_party/abseil_cpp/absl/algorithm/algorithm.h | 159 | ||||
-rw-r--r-- | third_party/abseil_cpp/absl/algorithm/algorithm_test.cc | 182 | ||||
-rw-r--r-- | third_party/abseil_cpp/absl/algorithm/container.h | 1728 | ||||
-rw-r--r-- | third_party/abseil_cpp/absl/algorithm/container_test.cc | 1031 | ||||
-rw-r--r-- | third_party/abseil_cpp/absl/algorithm/equal_benchmark.cc | 126 |
7 files changed, 3386 insertions, 0 deletions
diff --git a/third_party/abseil_cpp/absl/algorithm/BUILD.bazel b/third_party/abseil_cpp/absl/algorithm/BUILD.bazel new file mode 100644 index 000000000000..229cd713a206 --- /dev/null +++ b/third_party/abseil_cpp/absl/algorithm/BUILD.bazel @@ -0,0 +1,91 @@ +# +# Copyright 2017 The Abseil Authors. +# +# Licensed under the Apache License, Version 2.0 (the "License"); +# you may not use this file except in compliance with the License. +# You may obtain a copy of the License at +# +# https://www.apache.org/licenses/LICENSE-2.0 +# +# Unless required by applicable law or agreed to in writing, software +# distributed under the License is distributed on an "AS IS" BASIS, +# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. +# See the License for the specific language governing permissions and +# limitations under the License. +# + +load("@rules_cc//cc:defs.bzl", "cc_library", "cc_test") +load( + "//absl:copts/configure_copts.bzl", + "ABSL_DEFAULT_COPTS", + "ABSL_DEFAULT_LINKOPTS", + "ABSL_TEST_COPTS", +) + +package(default_visibility = ["//visibility:public"]) + +licenses(["notice"]) # Apache 2.0 + +cc_library( + name = "algorithm", + hdrs = ["algorithm.h"], + copts = ABSL_DEFAULT_COPTS, + linkopts = ABSL_DEFAULT_LINKOPTS, + deps = [ + "//absl/base:config", + ], +) + +cc_test( + name = "algorithm_test", + size = "small", + srcs = ["algorithm_test.cc"], + copts = ABSL_TEST_COPTS, + linkopts = ABSL_DEFAULT_LINKOPTS, + deps = [ + ":algorithm", + "@com_google_googletest//:gtest_main", + ], +) + +cc_test( + name = "algorithm_benchmark", + srcs = ["equal_benchmark.cc"], + copts = ABSL_TEST_COPTS, + linkopts = ABSL_DEFAULT_LINKOPTS, + tags = ["benchmark"], + deps = [ + ":algorithm", + "//absl/base:core_headers", + "@com_github_google_benchmark//:benchmark_main", + ], +) + +cc_library( + name = "container", + hdrs = [ + "container.h", + ], + copts = ABSL_DEFAULT_COPTS, + linkopts = ABSL_DEFAULT_LINKOPTS, + deps = [ + ":algorithm", + "//absl/base:core_headers", + "//absl/meta:type_traits", + ], +) + +cc_test( + name = "container_test", + srcs = ["container_test.cc"], + copts = ABSL_TEST_COPTS, + linkopts = ABSL_DEFAULT_LINKOPTS, + deps = [ + ":container", + "//absl/base", + "//absl/base:core_headers", + "//absl/memory", + "//absl/types:span", + "@com_google_googletest//:gtest_main", + ], +) diff --git a/third_party/abseil_cpp/absl/algorithm/CMakeLists.txt b/third_party/abseil_cpp/absl/algorithm/CMakeLists.txt new file mode 100644 index 000000000000..56cd0fb85b50 --- /dev/null +++ b/third_party/abseil_cpp/absl/algorithm/CMakeLists.txt @@ -0,0 +1,69 @@ +# +# Copyright 2017 The Abseil Authors. +# +# Licensed under the Apache License, Version 2.0 (the "License"); +# you may not use this file except in compliance with the License. +# You may obtain a copy of the License at +# +# https://www.apache.org/licenses/LICENSE-2.0 +# +# Unless required by applicable law or agreed to in writing, software +# distributed under the License is distributed on an "AS IS" BASIS, +# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. +# See the License for the specific language governing permissions and +# limitations under the License. +# + +absl_cc_library( + NAME + algorithm + HDRS + "algorithm.h" + COPTS + ${ABSL_DEFAULT_COPTS} + DEPS + absl::config + PUBLIC +) + +absl_cc_test( + NAME + algorithm_test + SRCS + "algorithm_test.cc" + COPTS + ${ABSL_TEST_COPTS} + DEPS + absl::algorithm + gmock_main +) + +absl_cc_library( + NAME + algorithm_container + HDRS + "container.h" + COPTS + ${ABSL_DEFAULT_COPTS} + DEPS + absl::algorithm + absl::core_headers + absl::meta + PUBLIC +) + +absl_cc_test( + NAME + container_test + SRCS + "container_test.cc" + COPTS + ${ABSL_TEST_COPTS} + DEPS + absl::algorithm_container + absl::base + absl::core_headers + absl::memory + absl::span + gmock_main +) diff --git a/third_party/abseil_cpp/absl/algorithm/algorithm.h b/third_party/abseil_cpp/absl/algorithm/algorithm.h new file mode 100644 index 000000000000..e9b473387278 --- /dev/null +++ b/third_party/abseil_cpp/absl/algorithm/algorithm.h @@ -0,0 +1,159 @@ +// Copyright 2017 The Abseil Authors. +// +// Licensed under the Apache License, Version 2.0 (the "License"); +// you may not use this file except in compliance with the License. +// You may obtain a copy of the License at +// +// https://www.apache.org/licenses/LICENSE-2.0 +// +// Unless required by applicable law or agreed to in writing, software +// distributed under the License is distributed on an "AS IS" BASIS, +// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. +// See the License for the specific language governing permissions and +// limitations under the License. +// +// ----------------------------------------------------------------------------- +// File: algorithm.h +// ----------------------------------------------------------------------------- +// +// This header file contains Google extensions to the standard <algorithm> C++ +// header. + +#ifndef ABSL_ALGORITHM_ALGORITHM_H_ +#define ABSL_ALGORITHM_ALGORITHM_H_ + +#include <algorithm> +#include <iterator> +#include <type_traits> + +#include "absl/base/config.h" + +namespace absl { +ABSL_NAMESPACE_BEGIN + +namespace algorithm_internal { + +// Performs comparisons with operator==, similar to C++14's `std::equal_to<>`. +struct EqualTo { + template <typename T, typename U> + bool operator()(const T& a, const U& b) const { + return a == b; + } +}; + +template <typename InputIter1, typename InputIter2, typename Pred> +bool EqualImpl(InputIter1 first1, InputIter1 last1, InputIter2 first2, + InputIter2 last2, Pred pred, std::input_iterator_tag, + std::input_iterator_tag) { + while (true) { + if (first1 == last1) return first2 == last2; + if (first2 == last2) return false; + if (!pred(*first1, *first2)) return false; + ++first1; + ++first2; + } +} + +template <typename InputIter1, typename InputIter2, typename Pred> +bool EqualImpl(InputIter1 first1, InputIter1 last1, InputIter2 first2, + InputIter2 last2, Pred&& pred, std::random_access_iterator_tag, + std::random_access_iterator_tag) { + return (last1 - first1 == last2 - first2) && + std::equal(first1, last1, first2, std::forward<Pred>(pred)); +} + +// When we are using our own internal predicate that just applies operator==, we +// forward to the non-predicate form of std::equal. This enables an optimization +// in libstdc++ that can result in std::memcmp being used for integer types. +template <typename InputIter1, typename InputIter2> +bool EqualImpl(InputIter1 first1, InputIter1 last1, InputIter2 first2, + InputIter2 last2, algorithm_internal::EqualTo /* unused */, + std::random_access_iterator_tag, + std::random_access_iterator_tag) { + return (last1 - first1 == last2 - first2) && + std::equal(first1, last1, first2); +} + +template <typename It> +It RotateImpl(It first, It middle, It last, std::true_type) { + return std::rotate(first, middle, last); +} + +template <typename It> +It RotateImpl(It first, It middle, It last, std::false_type) { + std::rotate(first, middle, last); + return std::next(first, std::distance(middle, last)); +} + +} // namespace algorithm_internal + +// equal() +// +// Compares the equality of two ranges specified by pairs of iterators, using +// the given predicate, returning true iff for each corresponding iterator i1 +// and i2 in the first and second range respectively, pred(*i1, *i2) == true +// +// This comparison takes at most min(`last1` - `first1`, `last2` - `first2`) +// invocations of the predicate. Additionally, if InputIter1 and InputIter2 are +// both random-access iterators, and `last1` - `first1` != `last2` - `first2`, +// then the predicate is never invoked and the function returns false. +// +// This is a C++11-compatible implementation of C++14 `std::equal`. See +// https://en.cppreference.com/w/cpp/algorithm/equal for more information. +template <typename InputIter1, typename InputIter2, typename Pred> +bool equal(InputIter1 first1, InputIter1 last1, InputIter2 first2, + InputIter2 last2, Pred&& pred) { + return algorithm_internal::EqualImpl( + first1, last1, first2, last2, std::forward<Pred>(pred), + typename std::iterator_traits<InputIter1>::iterator_category{}, + typename std::iterator_traits<InputIter2>::iterator_category{}); +} + +// Overload of equal() that performs comparison of two ranges specified by pairs +// of iterators using operator==. +template <typename InputIter1, typename InputIter2> +bool equal(InputIter1 first1, InputIter1 last1, InputIter2 first2, + InputIter2 last2) { + return absl::equal(first1, last1, first2, last2, + algorithm_internal::EqualTo{}); +} + +// linear_search() +// +// Performs a linear search for `value` using the iterator `first` up to +// but not including `last`, returning true if [`first`, `last`) contains an +// element equal to `value`. +// +// A linear search is of O(n) complexity which is guaranteed to make at most +// n = (`last` - `first`) comparisons. A linear search over short containers +// may be faster than a binary search, even when the container is sorted. +template <typename InputIterator, typename EqualityComparable> +bool linear_search(InputIterator first, InputIterator last, + const EqualityComparable& value) { + return std::find(first, last, value) != last; +} + +// rotate() +// +// Performs a left rotation on a range of elements (`first`, `last`) such that +// `middle` is now the first element. `rotate()` returns an iterator pointing to +// the first element before rotation. This function is exactly the same as +// `std::rotate`, but fixes a bug in gcc +// <= 4.9 where `std::rotate` returns `void` instead of an iterator. +// +// The complexity of this algorithm is the same as that of `std::rotate`, but if +// `ForwardIterator` is not a random-access iterator, then `absl::rotate` +// performs an additional pass over the range to construct the return value. +template <typename ForwardIterator> +ForwardIterator rotate(ForwardIterator first, ForwardIterator middle, + ForwardIterator last) { + return algorithm_internal::RotateImpl( + first, middle, last, + std::is_same<decltype(std::rotate(first, middle, last)), + ForwardIterator>()); +} + +ABSL_NAMESPACE_END +} // namespace absl + +#endif // ABSL_ALGORITHM_ALGORITHM_H_ diff --git a/third_party/abseil_cpp/absl/algorithm/algorithm_test.cc b/third_party/abseil_cpp/absl/algorithm/algorithm_test.cc new file mode 100644 index 000000000000..81fccb61353e --- /dev/null +++ b/third_party/abseil_cpp/absl/algorithm/algorithm_test.cc @@ -0,0 +1,182 @@ +// Copyright 2017 The Abseil Authors. +// +// Licensed under the Apache License, Version 2.0 (the "License"); +// you may not use this file except in compliance with the License. +// You may obtain a copy of the License at +// +// https://www.apache.org/licenses/LICENSE-2.0 +// +// Unless required by applicable law or agreed to in writing, software +// distributed under the License is distributed on an "AS IS" BASIS, +// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. +// See the License for the specific language governing permissions and +// limitations under the License. + +#include "absl/algorithm/algorithm.h" + +#include <algorithm> +#include <list> +#include <vector> + +#include "gmock/gmock.h" +#include "gtest/gtest.h" + +namespace { + +TEST(EqualTest, DefaultComparisonRandomAccess) { + std::vector<int> v1{1, 2, 3}; + std::vector<int> v2 = v1; + std::vector<int> v3 = {1, 2}; + std::vector<int> v4 = {1, 2, 4}; + + EXPECT_TRUE(absl::equal(v1.begin(), v1.end(), v2.begin(), v2.end())); + EXPECT_FALSE(absl::equal(v1.begin(), v1.end(), v3.begin(), v3.end())); + EXPECT_FALSE(absl::equal(v1.begin(), v1.end(), v4.begin(), v4.end())); +} + +TEST(EqualTest, DefaultComparison) { + std::list<int> lst1{1, 2, 3}; + std::list<int> lst2 = lst1; + std::list<int> lst3{1, 2}; + std::list<int> lst4{1, 2, 4}; + + EXPECT_TRUE(absl::equal(lst1.begin(), lst1.end(), lst2.begin(), lst2.end())); + EXPECT_FALSE(absl::equal(lst1.begin(), lst1.end(), lst3.begin(), lst3.end())); + EXPECT_FALSE(absl::equal(lst1.begin(), lst1.end(), lst4.begin(), lst4.end())); +} + +TEST(EqualTest, EmptyRange) { + std::vector<int> v1{1, 2, 3}; + std::vector<int> empty1; + std::vector<int> empty2; + + EXPECT_FALSE(absl::equal(v1.begin(), v1.end(), empty1.begin(), empty1.end())); + EXPECT_FALSE(absl::equal(empty1.begin(), empty1.end(), v1.begin(), v1.end())); + EXPECT_TRUE( + absl::equal(empty1.begin(), empty1.end(), empty2.begin(), empty2.end())); +} + +TEST(EqualTest, MixedIterTypes) { + std::vector<int> v1{1, 2, 3}; + std::list<int> lst1{v1.begin(), v1.end()}; + std::list<int> lst2{1, 2, 4}; + std::list<int> lst3{1, 2}; + + EXPECT_TRUE(absl::equal(v1.begin(), v1.end(), lst1.begin(), lst1.end())); + EXPECT_FALSE(absl::equal(v1.begin(), v1.end(), lst2.begin(), lst2.end())); + EXPECT_FALSE(absl::equal(v1.begin(), v1.end(), lst3.begin(), lst3.end())); +} + +TEST(EqualTest, MixedValueTypes) { + std::vector<int> v1{1, 2, 3}; + std::vector<char> v2{1, 2, 3}; + std::vector<char> v3{1, 2}; + std::vector<char> v4{1, 2, 4}; + + EXPECT_TRUE(absl::equal(v1.begin(), v1.end(), v2.begin(), v2.end())); + EXPECT_FALSE(absl::equal(v1.begin(), v1.end(), v3.begin(), v3.end())); + EXPECT_FALSE(absl::equal(v1.begin(), v1.end(), v4.begin(), v4.end())); +} + +TEST(EqualTest, WeirdIterators) { + std::vector<bool> v1{true, false}; + std::vector<bool> v2 = v1; + std::vector<bool> v3{true}; + std::vector<bool> v4{true, true, true}; + + EXPECT_TRUE(absl::equal(v1.begin(), v1.end(), v2.begin(), v2.end())); + EXPECT_FALSE(absl::equal(v1.begin(), v1.end(), v3.begin(), v3.end())); + EXPECT_FALSE(absl::equal(v1.begin(), v1.end(), v4.begin(), v4.end())); +} + +TEST(EqualTest, CustomComparison) { + int n[] = {1, 2, 3, 4}; + std::vector<int*> v1{&n[0], &n[1], &n[2]}; + std::vector<int*> v2 = v1; + std::vector<int*> v3{&n[0], &n[1], &n[3]}; + std::vector<int*> v4{&n[0], &n[1]}; + + auto eq = [](int* a, int* b) { return *a == *b; }; + + EXPECT_TRUE(absl::equal(v1.begin(), v1.end(), v2.begin(), v2.end(), eq)); + EXPECT_FALSE(absl::equal(v1.begin(), v1.end(), v3.begin(), v3.end(), eq)); + EXPECT_FALSE(absl::equal(v1.begin(), v1.end(), v4.begin(), v4.end(), eq)); +} + +TEST(EqualTest, MoveOnlyPredicate) { + std::vector<int> v1{1, 2, 3}; + std::vector<int> v2{4, 5, 6}; + + // move-only equality predicate + struct Eq { + Eq() = default; + Eq(Eq &&) = default; + Eq(const Eq &) = delete; + Eq &operator=(const Eq &) = delete; + bool operator()(const int a, const int b) const { return a == b; } + }; + + EXPECT_TRUE(absl::equal(v1.begin(), v1.end(), v1.begin(), v1.end(), Eq())); + EXPECT_FALSE(absl::equal(v1.begin(), v1.end(), v2.begin(), v2.end(), Eq())); +} + +struct CountingTrivialPred { + int* count; + bool operator()(int, int) const { + ++*count; + return true; + } +}; + +TEST(EqualTest, RandomAccessComplexity) { + std::vector<int> v1{1, 1, 3}; + std::vector<int> v2 = v1; + std::vector<int> v3{1, 2}; + + do { + int count = 0; + absl::equal(v1.begin(), v1.end(), v2.begin(), v2.end(), + CountingTrivialPred{&count}); + EXPECT_LE(count, 3); + } while (std::next_permutation(v2.begin(), v2.end())); + + int count = 0; + absl::equal(v1.begin(), v1.end(), v3.begin(), v3.end(), + CountingTrivialPred{&count}); + EXPECT_EQ(count, 0); +} + +class LinearSearchTest : public testing::Test { + protected: + LinearSearchTest() : container_{1, 2, 3} {} + + static bool Is3(int n) { return n == 3; } + static bool Is4(int n) { return n == 4; } + + std::vector<int> container_; +}; + +TEST_F(LinearSearchTest, linear_search) { + EXPECT_TRUE(absl::linear_search(container_.begin(), container_.end(), 3)); + EXPECT_FALSE(absl::linear_search(container_.begin(), container_.end(), 4)); +} + +TEST_F(LinearSearchTest, linear_searchConst) { + const std::vector<int> *const const_container = &container_; + EXPECT_TRUE( + absl::linear_search(const_container->begin(), const_container->end(), 3)); + EXPECT_FALSE( + absl::linear_search(const_container->begin(), const_container->end(), 4)); +} + +TEST(RotateTest, Rotate) { + std::vector<int> v{0, 1, 2, 3, 4}; + EXPECT_EQ(*absl::rotate(v.begin(), v.begin() + 2, v.end()), 0); + EXPECT_THAT(v, testing::ElementsAreArray({2, 3, 4, 0, 1})); + + std::list<int> l{0, 1, 2, 3, 4}; + EXPECT_EQ(*absl::rotate(l.begin(), std::next(l.begin(), 3), l.end()), 0); + EXPECT_THAT(l, testing::ElementsAreArray({3, 4, 0, 1, 2})); +} + +} // namespace diff --git a/third_party/abseil_cpp/absl/algorithm/container.h b/third_party/abseil_cpp/absl/algorithm/container.h new file mode 100644 index 000000000000..2457d78bc241 --- /dev/null +++ b/third_party/abseil_cpp/absl/algorithm/container.h @@ -0,0 +1,1728 @@ +// Copyright 2017 The Abseil Authors. +// +// Licensed under the Apache License, Version 2.0 (the "License"); +// you may not use this file except in compliance with the License. +// You may obtain a copy of the License at +// +// https://www.apache.org/licenses/LICENSE-2.0 +// +// Unless required by applicable law or agreed to in writing, software +// distributed under the License is distributed on an "AS IS" BASIS, +// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. +// See the License for the specific language governing permissions and +// limitations under the License. +// +// ----------------------------------------------------------------------------- +// File: container.h +// ----------------------------------------------------------------------------- +// +// This header file provides Container-based versions of algorithmic functions +// within the C++ standard library. The following standard library sets of +// functions are covered within this file: +// +// * Algorithmic <iterator> functions +// * Algorithmic <numeric> functions +// * <algorithm> functions +// +// The standard library functions operate on iterator ranges; the functions +// within this API operate on containers, though many return iterator ranges. +// +// All functions within this API are named with a `c_` prefix. Calls such as +// `absl::c_xx(container, ...) are equivalent to std:: functions such as +// `std::xx(std::begin(cont), std::end(cont), ...)`. Functions that act on +// iterators but not conceptually on iterator ranges (e.g. `std::iter_swap`) +// have no equivalent here. +// +// For template parameter and variable naming, `C` indicates the container type +// to which the function is applied, `Pred` indicates the predicate object type +// to be used by the function and `T` indicates the applicable element type. + +#ifndef ABSL_ALGORITHM_CONTAINER_H_ +#define ABSL_ALGORITHM_CONTAINER_H_ + +#include <algorithm> +#include <cassert> +#include <iterator> +#include <numeric> +#include <type_traits> +#include <unordered_map> +#include <unordered_set> +#include <utility> +#include <vector> + +#include "absl/algorithm/algorithm.h" +#include "absl/base/macros.h" +#include "absl/meta/type_traits.h" + +namespace absl { +ABSL_NAMESPACE_BEGIN +namespace container_algorithm_internal { + +// NOTE: it is important to defer to ADL lookup for building with C++ modules, +// especially for headers like <valarray> which are not visible from this file +// but specialize std::begin and std::end. +using std::begin; +using std::end; + +// The type of the iterator given by begin(c) (possibly std::begin(c)). +// ContainerIter<const vector<T>> gives vector<T>::const_iterator, +// while ContainerIter<vector<T>> gives vector<T>::iterator. +template <typename C> +using ContainerIter = decltype(begin(std::declval<C&>())); + +// An MSVC bug involving template parameter substitution requires us to use +// decltype() here instead of just std::pair. +template <typename C1, typename C2> +using ContainerIterPairType = + decltype(std::make_pair(ContainerIter<C1>(), ContainerIter<C2>())); + +template <typename C> +using ContainerDifferenceType = + decltype(std::distance(std::declval<ContainerIter<C>>(), + std::declval<ContainerIter<C>>())); + +template <typename C> +using ContainerPointerType = + typename std::iterator_traits<ContainerIter<C>>::pointer; + +// container_algorithm_internal::c_begin and +// container_algorithm_internal::c_end are abbreviations for proper ADL +// lookup of std::begin and std::end, i.e. +// using std::begin; +// using std::end; +// std::foo(begin(c), end(c); +// becomes +// std::foo(container_algorithm_internal::begin(c), +// container_algorithm_internal::end(c)); +// These are meant for internal use only. + +template <typename C> +ContainerIter<C> c_begin(C& c) { return begin(c); } + +template <typename C> +ContainerIter<C> c_end(C& c) { return end(c); } + +template <typename T> +struct IsUnorderedContainer : std::false_type {}; + +template <class Key, class T, class Hash, class KeyEqual, class Allocator> +struct IsUnorderedContainer< + std::unordered_map<Key, T, Hash, KeyEqual, Allocator>> : std::true_type {}; + +template <class Key, class Hash, class KeyEqual, class Allocator> +struct IsUnorderedContainer<std::unordered_set<Key, Hash, KeyEqual, Allocator>> + : std::true_type {}; + +// container_algorithm_internal::c_size. It is meant for internal use only. + +template <class C> +auto c_size(C& c) -> decltype(c.size()) { + return c.size(); +} + +template <class T, std::size_t N> +constexpr std::size_t c_size(T (&)[N]) { + return N; +} + +} // namespace container_algorithm_internal + +// PUBLIC API + +//------------------------------------------------------------------------------ +// Abseil algorithm.h functions +//------------------------------------------------------------------------------ + +// c_linear_search() +// +// Container-based version of absl::linear_search() for performing a linear +// search within a container. +template <typename C, typename EqualityComparable> +bool c_linear_search(const C& c, EqualityComparable&& value) { + return linear_search(container_algorithm_internal::c_begin(c), + container_algorithm_internal::c_end(c), + std::forward<EqualityComparable>(value)); +} + +//------------------------------------------------------------------------------ +// <iterator> algorithms +//------------------------------------------------------------------------------ + +// c_distance() +// +// Container-based version of the <iterator> `std::distance()` function to +// return the number of elements within a container. +template <typename C> +container_algorithm_internal::ContainerDifferenceType<const C> c_distance( + const C& c) { + return std::distance(container_algorithm_internal::c_begin(c), + container_algorithm_internal::c_end(c)); +} + +//------------------------------------------------------------------------------ +// <algorithm> Non-modifying sequence operations +//------------------------------------------------------------------------------ + +// c_all_of() +// +// Container-based version of the <algorithm> `std::all_of()` function to +// test a condition on all elements within a container. +template <typename C, typename Pred> +bool c_all_of(const C& c, Pred&& pred) { + return std::all_of(container_algorithm_internal::c_begin(c), + container_algorithm_internal::c_end(c), + std::forward<Pred>(pred)); +} + +// c_any_of() +// +// Container-based version of the <algorithm> `std::any_of()` function to +// test if any element in a container fulfills a condition. +template <typename C, typename Pred> +bool c_any_of(const C& c, Pred&& pred) { + return std::any_of(container_algorithm_internal::c_begin(c), + container_algorithm_internal::c_end(c), + std::forward<Pred>(pred)); +} + +// c_none_of() +// +// Container-based version of the <algorithm> `std::none_of()` function to +// test if no elements in a container fulfil a condition. +template <typename C, typename Pred> +bool c_none_of(const C& c, Pred&& pred) { + return std::none_of(container_algorithm_internal::c_begin(c), + container_algorithm_internal::c_end(c), + std::forward<Pred>(pred)); +} + +// c_for_each() +// +// Container-based version of the <algorithm> `std::for_each()` function to +// apply a function to a container's elements. +template <typename C, typename Function> +decay_t<Function> c_for_each(C&& c, Function&& f) { + return std::for_each(container_algorithm_internal::c_begin(c), + container_algorithm_internal::c_end(c), + std::forward<Function>(f)); +} + +// c_find() +// +// Container-based version of the <algorithm> `std::find()` function to find +// the first element containing the passed value within a container value. +template <typename C, typename T> +container_algorithm_internal::ContainerIter<C> c_find(C& c, T&& value) { + return std::find(container_algorithm_internal::c_begin(c), + container_algorithm_internal::c_end(c), + std::forward<T>(value)); +} + +// c_find_if() +// +// Container-based version of the <algorithm> `std::find_if()` function to find +// the first element in a container matching the given condition. +template <typename C, typename Pred> +container_algorithm_internal::ContainerIter<C> c_find_if(C& c, Pred&& pred) { + return std::find_if(container_algorithm_internal::c_begin(c), + container_algorithm_internal::c_end(c), + std::forward<Pred>(pred)); +} + +// c_find_if_not() +// +// Container-based version of the <algorithm> `std::find_if_not()` function to +// find the first element in a container not matching the given condition. +template <typename C, typename Pred> +container_algorithm_internal::ContainerIter<C> c_find_if_not(C& c, + Pred&& pred) { + return std::find_if_not(container_algorithm_internal::c_begin(c), + container_algorithm_internal::c_end(c), + std::forward<Pred>(pred)); +} + +// c_find_end() +// +// Container-based version of the <algorithm> `std::find_end()` function to +// find the last subsequence within a container. +template <typename Sequence1, typename Sequence2> +container_algorithm_internal::ContainerIter<Sequence1> c_find_end( + Sequence1& sequence, Sequence2& subsequence) { + return std::find_end(container_algorithm_internal::c_begin(sequence), + container_algorithm_internal::c_end(sequence), + container_algorithm_internal::c_begin(subsequence), + container_algorithm_internal::c_end(subsequence)); +} + +// Overload of c_find_end() for using a predicate evaluation other than `==` as +// the function's test condition. +template <typename Sequence1, typename Sequence2, typename BinaryPredicate> +container_algorithm_internal::ContainerIter<Sequence1> c_find_end( + Sequence1& sequence, Sequence2& subsequence, BinaryPredicate&& pred) { + return std::find_end(container_algorithm_internal::c_begin(sequence), + container_algorithm_internal::c_end(sequence), + container_algorithm_internal::c_begin(subsequence), + container_algorithm_internal::c_end(subsequence), + std::forward<BinaryPredicate>(pred)); +} + +// c_find_first_of() +// +// Container-based version of the <algorithm> `std::find_first_of()` function to +// find the first element within the container that is also within the options +// container. +template <typename C1, typename C2> +container_algorithm_internal::ContainerIter<C1> c_find_first_of(C1& container, + C2& options) { + return std::find_first_of(container_algorithm_internal::c_begin(container), + container_algorithm_internal::c_end(container), + container_algorithm_internal::c_begin(options), + container_algorithm_internal::c_end(options)); +} + +// Overload of c_find_first_of() for using a predicate evaluation other than +// `==` as the function's test condition. +template <typename C1, typename C2, typename BinaryPredicate> +container_algorithm_internal::ContainerIter<C1> c_find_first_of( + C1& container, C2& options, BinaryPredicate&& pred) { + return std::find_first_of(container_algorithm_internal::c_begin(container), + container_algorithm_internal::c_end(container), + container_algorithm_internal::c_begin(options), + container_algorithm_internal::c_end(options), + std::forward<BinaryPredicate>(pred)); +} + +// c_adjacent_find() +// +// Container-based version of the <algorithm> `std::adjacent_find()` function to +// find equal adjacent elements within a container. +template <typename Sequence> +container_algorithm_internal::ContainerIter<Sequence> c_adjacent_find( + Sequence& sequence) { + return std::adjacent_find(container_algorithm_internal::c_begin(sequence), + container_algorithm_internal::c_end(sequence)); +} + +// Overload of c_adjacent_find() for using a predicate evaluation other than +// `==` as the function's test condition. +template <typename Sequence, typename BinaryPredicate> +container_algorithm_internal::ContainerIter<Sequence> c_adjacent_find( + Sequence& sequence, BinaryPredicate&& pred) { + return std::adjacent_find(container_algorithm_internal::c_begin(sequence), + container_algorithm_internal::c_end(sequence), + std::forward<BinaryPredicate>(pred)); +} + +// c_count() +// +// Container-based version of the <algorithm> `std::count()` function to count +// values that match within a container. +template <typename C, typename T> +container_algorithm_internal::ContainerDifferenceType<const C> c_count( + const C& c, T&& value) { + return std::count(container_algorithm_internal::c_begin(c), + container_algorithm_internal::c_end(c), + std::forward<T>(value)); +} + +// c_count_if() +// +// Container-based version of the <algorithm> `std::count_if()` function to +// count values matching a condition within a container. +template <typename C, typename Pred> +container_algorithm_internal::ContainerDifferenceType<const C> c_count_if( + const C& c, Pred&& pred) { + return std::count_if(container_algorithm_internal::c_begin(c), + container_algorithm_internal::c_end(c), + std::forward<Pred>(pred)); +} + +// c_mismatch() +// +// Container-based version of the <algorithm> `std::mismatch()` function to +// return the first element where two ordered containers differ. +template <typename C1, typename C2> +container_algorithm_internal::ContainerIterPairType<C1, C2> +c_mismatch(C1& c1, C2& c2) { + return std::mismatch(container_algorithm_internal::c_begin(c1), + container_algorithm_internal::c_end(c1), + container_algorithm_internal::c_begin(c2)); +} + +// Overload of c_mismatch() for using a predicate evaluation other than `==` as +// the function's test condition. +template <typename C1, typename C2, typename BinaryPredicate> +container_algorithm_internal::ContainerIterPairType<C1, C2> +c_mismatch(C1& c1, C2& c2, BinaryPredicate&& pred) { + return std::mismatch(container_algorithm_internal::c_begin(c1), + container_algorithm_internal::c_end(c1), + container_algorithm_internal::c_begin(c2), + std::forward<BinaryPredicate>(pred)); +} + +// c_equal() +// +// Container-based version of the <algorithm> `std::equal()` function to +// test whether two containers are equal. +// +// NOTE: the semantics of c_equal() are slightly different than those of +// equal(): while the latter iterates over the second container only up to the +// size of the first container, c_equal() also checks whether the container +// sizes are equal. This better matches expectations about c_equal() based on +// its signature. +// +// Example: +// vector v1 = <1, 2, 3>; +// vector v2 = <1, 2, 3, 4>; +// equal(std::begin(v1), std::end(v1), std::begin(v2)) returns true +// c_equal(v1, v2) returns false + +template <typename C1, typename C2> +bool c_equal(const C1& c1, const C2& c2) { + return ((container_algorithm_internal::c_size(c1) == + container_algorithm_internal::c_size(c2)) && + std::equal(container_algorithm_internal::c_begin(c1), + container_algorithm_internal::c_end(c1), + container_algorithm_internal::c_begin(c2))); +} + +// Overload of c_equal() for using a predicate evaluation other than `==` as +// the function's test condition. +template <typename C1, typename C2, typename BinaryPredicate> +bool c_equal(const C1& c1, const C2& c2, BinaryPredicate&& pred) { + return ((container_algorithm_internal::c_size(c1) == + container_algorithm_internal::c_size(c2)) && + std::equal(container_algorithm_internal::c_begin(c1), + container_algorithm_internal::c_end(c1), + container_algorithm_internal::c_begin(c2), + std::forward<BinaryPredicate>(pred))); +} + +// c_is_permutation() +// +// Container-based version of the <algorithm> `std::is_permutation()` function +// to test whether a container is a permutation of another. +template <typename C1, typename C2> +bool c_is_permutation(const C1& c1, const C2& c2) { + using std::begin; + using std::end; + return c1.size() == c2.size() && + std::is_permutation(begin(c1), end(c1), begin(c2)); +} + +// Overload of c_is_permutation() for using a predicate evaluation other than +// `==` as the function's test condition. +template <typename C1, typename C2, typename BinaryPredicate> +bool c_is_permutation(const C1& c1, const C2& c2, BinaryPredicate&& pred) { + using std::begin; + using std::end; + return c1.size() == c2.size() && + std::is_permutation(begin(c1), end(c1), begin(c2), + std::forward<BinaryPredicate>(pred)); +} + +// c_search() +// +// Container-based version of the <algorithm> `std::search()` function to search +// a container for a subsequence. +template <typename Sequence1, typename Sequence2> +container_algorithm_internal::ContainerIter<Sequence1> c_search( + Sequence1& sequence, Sequence2& subsequence) { + return std::search(container_algorithm_internal::c_begin(sequence), + container_algorithm_internal::c_end(sequence), + container_algorithm_internal::c_begin(subsequence), + container_algorithm_internal::c_end(subsequence)); +} + +// Overload of c_search() for using a predicate evaluation other than +// `==` as the function's test condition. +template <typename Sequence1, typename Sequence2, typename BinaryPredicate> +container_algorithm_internal::ContainerIter<Sequence1> c_search( + Sequence1& sequence, Sequence2& subsequence, BinaryPredicate&& pred) { + return std::search(container_algorithm_internal::c_begin(sequence), + container_algorithm_internal::c_end(sequence), + container_algorithm_internal::c_begin(subsequence), + container_algorithm_internal::c_end(subsequence), + std::forward<BinaryPredicate>(pred)); +} + +// c_search_n() +// +// Container-based version of the <algorithm> `std::search_n()` function to +// search a container for the first sequence of N elements. +template <typename Sequence, typename Size, typename T> +container_algorithm_internal::ContainerIter<Sequence> c_search_n( + Sequence& sequence, Size count, T&& value) { + return std::search_n(container_algorithm_internal::c_begin(sequence), + container_algorithm_internal::c_end(sequence), count, + std::forward<T>(value)); +} + +// Overload of c_search_n() for using a predicate evaluation other than +// `==` as the function's test condition. +template <typename Sequence, typename Size, typename T, + typename BinaryPredicate> +container_algorithm_internal::ContainerIter<Sequence> c_search_n( + Sequence& sequence, Size count, T&& value, BinaryPredicate&& pred) { + return std::search_n(container_algorithm_internal::c_begin(sequence), + container_algorithm_internal::c_end(sequence), count, + std::forward<T>(value), + std::forward<BinaryPredicate>(pred)); +} + +//------------------------------------------------------------------------------ +// <algorithm> Modifying sequence operations +//------------------------------------------------------------------------------ + +// c_copy() +// +// Container-based version of the <algorithm> `std::copy()` function to copy a +// container's elements into an iterator. +template <typename InputSequence, typename OutputIterator> +OutputIterator c_copy(const InputSequence& input, OutputIterator output) { + return std::copy(container_algorithm_internal::c_begin(input), + container_algorithm_internal::c_end(input), output); +} + +// c_copy_n() +// +// Container-based version of the <algorithm> `std::copy_n()` function to copy a +// container's first N elements into an iterator. +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. +template <typename C1, typename C2> +container_algorithm_internal::ContainerIter<C2> c_swap_ranges(C1& c1, C2& c2) { + return std::swap_ranges(container_algorithm_internal::c_begin(c1), + container_algorithm_internal::c_end(c1), + container_algorithm_internal::c_begin(c2)); +} + +// 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. +template <typename InputSequence1, typename InputSequence2, + typename OutputIterator, typename BinaryOp> +OutputIterator c_transform(const InputSequence1& input1, + const InputSequence2& input2, OutputIterator output, + BinaryOp&& binary_op) { + return std::transform(container_algorithm_internal::c_begin(input1), + container_algorithm_internal::c_end(input1), + container_algorithm_internal::c_begin(input2), output, + std::forward<BinaryOp>(binary_op)); +} + +// 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_ diff --git a/third_party/abseil_cpp/absl/algorithm/container_test.cc b/third_party/abseil_cpp/absl/algorithm/container_test.cc new file mode 100644 index 000000000000..0a4abe946272 --- /dev/null +++ b/third_party/abseil_cpp/absl/algorithm/container_test.cc @@ -0,0 +1,1031 @@ +// Copyright 2017 The Abseil Authors. +// +// Licensed under the Apache License, Version 2.0 (the "License"); +// you may not use this file except in compliance with the License. +// You may obtain a copy of the License at +// +// https://www.apache.org/licenses/LICENSE-2.0 +// +// Unless required by applicable law or agreed to in writing, software +// distributed under the License is distributed on an "AS IS" BASIS, +// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. +// See the License for the specific language governing permissions and +// limitations under the License. + +#include "absl/algorithm/container.h" + +#include <functional> +#include <initializer_list> +#include <iterator> +#include <list> +#include <memory> +#include <ostream> +#include <random> +#include <set> +#include <unordered_set> +#include <utility> +#include <valarray> +#include <vector> + +#include "gmock/gmock.h" +#include "gtest/gtest.h" +#include "absl/base/casts.h" +#include "absl/base/macros.h" +#include "absl/memory/memory.h" +#include "absl/types/span.h" + +namespace { + +using ::testing::Each; +using ::testing::ElementsAre; +using ::testing::Gt; +using ::testing::IsNull; +using ::testing::Lt; +using ::testing::Pointee; +using ::testing::Truly; +using ::testing::UnorderedElementsAre; + +// Most of these tests just check that the code compiles, not that it +// does the right thing. That's fine since the functions just forward +// to the STL implementation. +class NonMutatingTest : public testing::Test { + protected: + std::unordered_set<int> container_ = {1, 2, 3}; + std::list<int> sequence_ = {1, 2, 3}; + std::vector<int> vector_ = {1, 2, 3}; + int array_[3] = {1, 2, 3}; +}; + +struct AccumulateCalls { + void operator()(int value) { + calls.push_back(value); + } + std::vector<int> calls; +}; + +bool Predicate(int value) { return value < 3; } +bool BinPredicate(int v1, int v2) { return v1 < v2; } +bool Equals(int v1, int v2) { return v1 == v2; } +bool IsOdd(int x) { return x % 2 != 0; } + + +TEST_F(NonMutatingTest, Distance) { + EXPECT_EQ(container_.size(), absl::c_distance(container_)); + EXPECT_EQ(sequence_.size(), absl::c_distance(sequence_)); + EXPECT_EQ(vector_.size(), absl::c_distance(vector_)); + EXPECT_EQ(ABSL_ARRAYSIZE(array_), absl::c_distance(array_)); + + // Works with a temporary argument. + EXPECT_EQ(vector_.size(), absl::c_distance(std::vector<int>(vector_))); +} + +TEST_F(NonMutatingTest, Distance_OverloadedBeginEnd) { + // Works with classes which have custom ADL-selected overloads of std::begin + // and std::end. + std::initializer_list<int> a = {1, 2, 3}; + std::valarray<int> b = {1, 2, 3}; + EXPECT_EQ(3, absl::c_distance(a)); + EXPECT_EQ(3, absl::c_distance(b)); + + // It is assumed that other c_* functions use the same mechanism for + // ADL-selecting begin/end overloads. +} + +TEST_F(NonMutatingTest, ForEach) { + AccumulateCalls c = absl::c_for_each(container_, AccumulateCalls()); + // Don't rely on the unordered_set's order. + std::sort(c.calls.begin(), c.calls.end()); + EXPECT_EQ(vector_, c.calls); + + // Works with temporary container, too. + AccumulateCalls c2 = + absl::c_for_each(std::unordered_set<int>(container_), AccumulateCalls()); + std::sort(c2.calls.begin(), c2.calls.end()); + EXPECT_EQ(vector_, c2.calls); +} + +TEST_F(NonMutatingTest, FindReturnsCorrectType) { + auto it = absl::c_find(container_, 3); + EXPECT_EQ(3, *it); + absl::c_find(absl::implicit_cast<const std::list<int>&>(sequence_), 3); +} + +TEST_F(NonMutatingTest, FindIf) { absl::c_find_if(container_, Predicate); } + +TEST_F(NonMutatingTest, FindIfNot) { + absl::c_find_if_not(container_, Predicate); +} + +TEST_F(NonMutatingTest, FindEnd) { + absl::c_find_end(sequence_, vector_); + absl::c_find_end(vector_, sequence_); +} + +TEST_F(NonMutatingTest, FindEndWithPredicate) { + absl::c_find_end(sequence_, vector_, BinPredicate); + absl::c_find_end(vector_, sequence_, BinPredicate); +} + +TEST_F(NonMutatingTest, FindFirstOf) { + absl::c_find_first_of(container_, sequence_); + absl::c_find_first_of(sequence_, container_); +} + +TEST_F(NonMutatingTest, FindFirstOfWithPredicate) { + absl::c_find_first_of(container_, sequence_, BinPredicate); + absl::c_find_first_of(sequence_, container_, BinPredicate); +} + +TEST_F(NonMutatingTest, AdjacentFind) { absl::c_adjacent_find(sequence_); } + +TEST_F(NonMutatingTest, AdjacentFindWithPredicate) { + absl::c_adjacent_find(sequence_, BinPredicate); +} + +TEST_F(NonMutatingTest, Count) { EXPECT_EQ(1, absl::c_count(container_, 3)); } + +TEST_F(NonMutatingTest, CountIf) { + EXPECT_EQ(2, absl::c_count_if(container_, Predicate)); + const std::unordered_set<int>& const_container = container_; + EXPECT_EQ(2, absl::c_count_if(const_container, Predicate)); +} + +TEST_F(NonMutatingTest, Mismatch) { + absl::c_mismatch(container_, sequence_); + absl::c_mismatch(sequence_, container_); +} + +TEST_F(NonMutatingTest, MismatchWithPredicate) { + absl::c_mismatch(container_, sequence_, BinPredicate); + absl::c_mismatch(sequence_, container_, BinPredicate); +} + +TEST_F(NonMutatingTest, Equal) { + EXPECT_TRUE(absl::c_equal(vector_, sequence_)); + EXPECT_TRUE(absl::c_equal(sequence_, vector_)); + EXPECT_TRUE(absl::c_equal(sequence_, array_)); + EXPECT_TRUE(absl::c_equal(array_, vector_)); + + // Test that behavior appropriately differs from that of equal(). + std::vector<int> vector_plus = {1, 2, 3}; + vector_plus.push_back(4); + EXPECT_FALSE(absl::c_equal(vector_plus, sequence_)); + EXPECT_FALSE(absl::c_equal(sequence_, vector_plus)); + EXPECT_FALSE(absl::c_equal(array_, vector_plus)); +} + +TEST_F(NonMutatingTest, EqualWithPredicate) { + EXPECT_TRUE(absl::c_equal(vector_, sequence_, Equals)); + EXPECT_TRUE(absl::c_equal(sequence_, vector_, Equals)); + EXPECT_TRUE(absl::c_equal(array_, sequence_, Equals)); + EXPECT_TRUE(absl::c_equal(vector_, array_, Equals)); + + // Test that behavior appropriately differs from that of equal(). + std::vector<int> vector_plus = {1, 2, 3}; + vector_plus.push_back(4); + EXPECT_FALSE(absl::c_equal(vector_plus, sequence_, Equals)); + EXPECT_FALSE(absl::c_equal(sequence_, vector_plus, Equals)); + EXPECT_FALSE(absl::c_equal(vector_plus, array_, Equals)); +} + +TEST_F(NonMutatingTest, IsPermutation) { + auto vector_permut_ = vector_; + std::next_permutation(vector_permut_.begin(), vector_permut_.end()); + EXPECT_TRUE(absl::c_is_permutation(vector_permut_, sequence_)); + EXPECT_TRUE(absl::c_is_permutation(sequence_, vector_permut_)); + + // Test that behavior appropriately differs from that of is_permutation(). + std::vector<int> vector_plus = {1, 2, 3}; + vector_plus.push_back(4); + EXPECT_FALSE(absl::c_is_permutation(vector_plus, sequence_)); + EXPECT_FALSE(absl::c_is_permutation(sequence_, vector_plus)); +} + +TEST_F(NonMutatingTest, IsPermutationWithPredicate) { + auto vector_permut_ = vector_; + std::next_permutation(vector_permut_.begin(), vector_permut_.end()); + EXPECT_TRUE(absl::c_is_permutation(vector_permut_, sequence_, Equals)); + EXPECT_TRUE(absl::c_is_permutation(sequence_, vector_permut_, Equals)); + + // Test that behavior appropriately differs from that of is_permutation(). + std::vector<int> vector_plus = {1, 2, 3}; + vector_plus.push_back(4); + EXPECT_FALSE(absl::c_is_permutation(vector_plus, sequence_, Equals)); + EXPECT_FALSE(absl::c_is_permutation(sequence_, vector_plus, Equals)); +} + +TEST_F(NonMutatingTest, Search) { + absl::c_search(sequence_, vector_); + absl::c_search(vector_, sequence_); + absl::c_search(array_, sequence_); +} + +TEST_F(NonMutatingTest, SearchWithPredicate) { + absl::c_search(sequence_, vector_, BinPredicate); + absl::c_search(vector_, sequence_, BinPredicate); +} + +TEST_F(NonMutatingTest, SearchN) { absl::c_search_n(sequence_, 3, 1); } + +TEST_F(NonMutatingTest, SearchNWithPredicate) { + absl::c_search_n(sequence_, 3, 1, BinPredicate); +} + +TEST_F(NonMutatingTest, LowerBound) { + std::list<int>::iterator i = absl::c_lower_bound(sequence_, 3); + ASSERT_TRUE(i != sequence_.end()); + EXPECT_EQ(2, std::distance(sequence_.begin(), i)); + EXPECT_EQ(3, *i); +} + +TEST_F(NonMutatingTest, LowerBoundWithPredicate) { + std::vector<int> v(vector_); + std::sort(v.begin(), v.end(), std::greater<int>()); + std::vector<int>::iterator i = absl::c_lower_bound(v, 3, std::greater<int>()); + EXPECT_TRUE(i == v.begin()); + EXPECT_EQ(3, *i); +} + +TEST_F(NonMutatingTest, UpperBound) { + std::list<int>::iterator i = absl::c_upper_bound(sequence_, 1); + ASSERT_TRUE(i != sequence_.end()); + EXPECT_EQ(1, std::distance(sequence_.begin(), i)); + EXPECT_EQ(2, *i); +} + +TEST_F(NonMutatingTest, UpperBoundWithPredicate) { + std::vector<int> v(vector_); + std::sort(v.begin(), v.end(), std::greater<int>()); + std::vector<int>::iterator i = absl::c_upper_bound(v, 1, std::greater<int>()); + EXPECT_EQ(3, i - v.begin()); + EXPECT_TRUE(i == v.end()); +} + +TEST_F(NonMutatingTest, EqualRange) { + std::pair<std::list<int>::iterator, std::list<int>::iterator> p = + absl::c_equal_range(sequence_, 2); + EXPECT_EQ(1, std::distance(sequence_.begin(), p.first)); + EXPECT_EQ(2, std::distance(sequence_.begin(), p.second)); +} + +TEST_F(NonMutatingTest, EqualRangeArray) { + auto p = absl::c_equal_range(array_, 2); + EXPECT_EQ(1, std::distance(std::begin(array_), p.first)); + EXPECT_EQ(2, std::distance(std::begin(array_), p.second)); +} + +TEST_F(NonMutatingTest, EqualRangeWithPredicate) { + std::vector<int> v(vector_); + std::sort(v.begin(), v.end(), std::greater<int>()); + std::pair<std::vector<int>::iterator, std::vector<int>::iterator> p = + absl::c_equal_range(v, 2, std::greater<int>()); + EXPECT_EQ(1, std::distance(v.begin(), p.first)); + EXPECT_EQ(2, std::distance(v.begin(), p.second)); +} + +TEST_F(NonMutatingTest, BinarySearch) { + EXPECT_TRUE(absl::c_binary_search(vector_, 2)); + EXPECT_TRUE(absl::c_binary_search(std::vector<int>(vector_), 2)); +} + +TEST_F(NonMutatingTest, BinarySearchWithPredicate) { + std::vector<int> v(vector_); + std::sort(v.begin(), v.end(), std::greater<int>()); + EXPECT_TRUE(absl::c_binary_search(v, 2, std::greater<int>())); + EXPECT_TRUE( + absl::c_binary_search(std::vector<int>(v), 2, std::greater<int>())); +} + +TEST_F(NonMutatingTest, MinElement) { + std::list<int>::iterator i = absl::c_min_element(sequence_); + ASSERT_TRUE(i != sequence_.end()); + EXPECT_EQ(*i, 1); +} + +TEST_F(NonMutatingTest, MinElementWithPredicate) { + std::list<int>::iterator i = + absl::c_min_element(sequence_, std::greater<int>()); + ASSERT_TRUE(i != sequence_.end()); + EXPECT_EQ(*i, 3); +} + +TEST_F(NonMutatingTest, MaxElement) { + std::list<int>::iterator i = absl::c_max_element(sequence_); + ASSERT_TRUE(i != sequence_.end()); + EXPECT_EQ(*i, 3); +} + +TEST_F(NonMutatingTest, MaxElementWithPredicate) { + std::list<int>::iterator i = + absl::c_max_element(sequence_, std::greater<int>()); + ASSERT_TRUE(i != sequence_.end()); + EXPECT_EQ(*i, 1); +} + +TEST_F(NonMutatingTest, LexicographicalCompare) { + EXPECT_FALSE(absl::c_lexicographical_compare(sequence_, sequence_)); + + std::vector<int> v; + v.push_back(1); + v.push_back(2); + v.push_back(4); + + EXPECT_TRUE(absl::c_lexicographical_compare(sequence_, v)); + EXPECT_TRUE(absl::c_lexicographical_compare(std::list<int>(sequence_), v)); +} + +TEST_F(NonMutatingTest, LexicographicalCopmareWithPredicate) { + EXPECT_FALSE(absl::c_lexicographical_compare(sequence_, sequence_, + std::greater<int>())); + + std::vector<int> v; + v.push_back(1); + v.push_back(2); + v.push_back(4); + + EXPECT_TRUE( + absl::c_lexicographical_compare(v, sequence_, std::greater<int>())); + EXPECT_TRUE(absl::c_lexicographical_compare( + std::vector<int>(v), std::list<int>(sequence_), std::greater<int>())); +} + +TEST_F(NonMutatingTest, Includes) { + std::set<int> s(vector_.begin(), vector_.end()); + s.insert(4); + EXPECT_TRUE(absl::c_includes(s, vector_)); +} + +TEST_F(NonMutatingTest, IncludesWithPredicate) { + std::vector<int> v = {3, 2, 1}; + std::set<int, std::greater<int>> s(v.begin(), v.end()); + s.insert(4); + EXPECT_TRUE(absl::c_includes(s, v, std::greater<int>())); +} + +class NumericMutatingTest : public testing::Test { + protected: + std::list<int> list_ = {1, 2, 3}; + std::vector<int> output_; +}; + +TEST_F(NumericMutatingTest, Iota) { + absl::c_iota(list_, 5); + std::list<int> expected{5, 6, 7}; + EXPECT_EQ(list_, expected); +} + +TEST_F(NonMutatingTest, Accumulate) { + EXPECT_EQ(absl::c_accumulate(sequence_, 4), 1 + 2 + 3 + 4); +} + +TEST_F(NonMutatingTest, AccumulateWithBinaryOp) { + EXPECT_EQ(absl::c_accumulate(sequence_, 4, std::multiplies<int>()), + 1 * 2 * 3 * 4); +} + +TEST_F(NonMutatingTest, AccumulateLvalueInit) { + int lvalue = 4; + EXPECT_EQ(absl::c_accumulate(sequence_, lvalue), 1 + 2 + 3 + 4); +} + +TEST_F(NonMutatingTest, AccumulateWithBinaryOpLvalueInit) { + int lvalue = 4; + EXPECT_EQ(absl::c_accumulate(sequence_, lvalue, std::multiplies<int>()), + 1 * 2 * 3 * 4); +} + +TEST_F(NonMutatingTest, InnerProduct) { + EXPECT_EQ(absl::c_inner_product(sequence_, vector_, 1000), + 1000 + 1 * 1 + 2 * 2 + 3 * 3); +} + +TEST_F(NonMutatingTest, InnerProductWithBinaryOps) { + EXPECT_EQ(absl::c_inner_product(sequence_, vector_, 10, + std::multiplies<int>(), std::plus<int>()), + 10 * (1 + 1) * (2 + 2) * (3 + 3)); +} + +TEST_F(NonMutatingTest, InnerProductLvalueInit) { + int lvalue = 1000; + EXPECT_EQ(absl::c_inner_product(sequence_, vector_, lvalue), + 1000 + 1 * 1 + 2 * 2 + 3 * 3); +} + +TEST_F(NonMutatingTest, InnerProductWithBinaryOpsLvalueInit) { + int lvalue = 10; + EXPECT_EQ(absl::c_inner_product(sequence_, vector_, lvalue, + std::multiplies<int>(), std::plus<int>()), + 10 * (1 + 1) * (2 + 2) * (3 + 3)); +} + +TEST_F(NumericMutatingTest, AdjacentDifference) { + auto last = absl::c_adjacent_difference(list_, std::back_inserter(output_)); + *last = 1000; + std::vector<int> expected{1, 2 - 1, 3 - 2, 1000}; + EXPECT_EQ(output_, expected); +} + +TEST_F(NumericMutatingTest, AdjacentDifferenceWithBinaryOp) { + auto last = absl::c_adjacent_difference(list_, std::back_inserter(output_), + std::multiplies<int>()); + *last = 1000; + std::vector<int> expected{1, 2 * 1, 3 * 2, 1000}; + EXPECT_EQ(output_, expected); +} + +TEST_F(NumericMutatingTest, PartialSum) { + auto last = absl::c_partial_sum(list_, std::back_inserter(output_)); + *last = 1000; + std::vector<int> expected{1, 1 + 2, 1 + 2 + 3, 1000}; + EXPECT_EQ(output_, expected); +} + +TEST_F(NumericMutatingTest, PartialSumWithBinaryOp) { + auto last = absl::c_partial_sum(list_, std::back_inserter(output_), + std::multiplies<int>()); + *last = 1000; + std::vector<int> expected{1, 1 * 2, 1 * 2 * 3, 1000}; + EXPECT_EQ(output_, expected); +} + +TEST_F(NonMutatingTest, LinearSearch) { + EXPECT_TRUE(absl::c_linear_search(container_, 3)); + EXPECT_FALSE(absl::c_linear_search(container_, 4)); +} + +TEST_F(NonMutatingTest, AllOf) { + const std::vector<int>& v = vector_; + EXPECT_FALSE(absl::c_all_of(v, [](int x) { return x > 1; })); + EXPECT_TRUE(absl::c_all_of(v, [](int x) { return x > 0; })); +} + +TEST_F(NonMutatingTest, AnyOf) { + const std::vector<int>& v = vector_; + EXPECT_TRUE(absl::c_any_of(v, [](int x) { return x > 2; })); + EXPECT_FALSE(absl::c_any_of(v, [](int x) { return x > 5; })); +} + +TEST_F(NonMutatingTest, NoneOf) { + const std::vector<int>& v = vector_; + EXPECT_FALSE(absl::c_none_of(v, [](int x) { return x > 2; })); + EXPECT_TRUE(absl::c_none_of(v, [](int x) { return x > 5; })); +} + +TEST_F(NonMutatingTest, MinMaxElementLess) { + std::pair<std::vector<int>::const_iterator, std::vector<int>::const_iterator> + p = absl::c_minmax_element(vector_, std::less<int>()); + EXPECT_TRUE(p.first == vector_.begin()); + EXPECT_TRUE(p.second == vector_.begin() + 2); +} + +TEST_F(NonMutatingTest, MinMaxElementGreater) { + std::pair<std::vector<int>::const_iterator, std::vector<int>::const_iterator> + p = absl::c_minmax_element(vector_, std::greater<int>()); + EXPECT_TRUE(p.first == vector_.begin() + 2); + EXPECT_TRUE(p.second == vector_.begin()); +} + +TEST_F(NonMutatingTest, MinMaxElementNoPredicate) { + std::pair<std::vector<int>::const_iterator, std::vector<int>::const_iterator> + p = absl::c_minmax_element(vector_); + EXPECT_TRUE(p.first == vector_.begin()); + EXPECT_TRUE(p.second == vector_.begin() + 2); +} + +class SortingTest : public testing::Test { + protected: + std::list<int> sorted_ = {1, 2, 3, 4}; + std::list<int> unsorted_ = {2, 4, 1, 3}; + std::list<int> reversed_ = {4, 3, 2, 1}; +}; + +TEST_F(SortingTest, IsSorted) { + EXPECT_TRUE(absl::c_is_sorted(sorted_)); + EXPECT_FALSE(absl::c_is_sorted(unsorted_)); + EXPECT_FALSE(absl::c_is_sorted(reversed_)); +} + +TEST_F(SortingTest, IsSortedWithPredicate) { + EXPECT_FALSE(absl::c_is_sorted(sorted_, std::greater<int>())); + EXPECT_FALSE(absl::c_is_sorted(unsorted_, std::greater<int>())); + EXPECT_TRUE(absl::c_is_sorted(reversed_, std::greater<int>())); +} + +TEST_F(SortingTest, IsSortedUntil) { + EXPECT_EQ(1, *absl::c_is_sorted_until(unsorted_)); + EXPECT_EQ(4, *absl::c_is_sorted_until(unsorted_, std::greater<int>())); +} + +TEST_F(SortingTest, NthElement) { + std::vector<int> unsorted = {2, 4, 1, 3}; + absl::c_nth_element(unsorted, unsorted.begin() + 2); + EXPECT_THAT(unsorted, + ElementsAre(Lt(3), Lt(3), 3, Gt(3))); + absl::c_nth_element(unsorted, unsorted.begin() + 2, std::greater<int>()); + EXPECT_THAT(unsorted, + ElementsAre(Gt(2), Gt(2), 2, Lt(2))); +} + +TEST(MutatingTest, IsPartitioned) { + EXPECT_TRUE( + absl::c_is_partitioned(std::vector<int>{1, 3, 5, 2, 4, 6}, IsOdd)); + EXPECT_FALSE( + absl::c_is_partitioned(std::vector<int>{1, 2, 3, 4, 5, 6}, IsOdd)); + EXPECT_FALSE( + absl::c_is_partitioned(std::vector<int>{2, 4, 6, 1, 3, 5}, IsOdd)); +} + +TEST(MutatingTest, Partition) { + std::vector<int> actual = {1, 2, 3, 4, 5}; + absl::c_partition(actual, IsOdd); + EXPECT_THAT(actual, Truly([](const std::vector<int>& c) { + return absl::c_is_partitioned(c, IsOdd); + })); +} + +TEST(MutatingTest, StablePartition) { + std::vector<int> actual = {1, 2, 3, 4, 5}; + absl::c_stable_partition(actual, IsOdd); + EXPECT_THAT(actual, ElementsAre(1, 3, 5, 2, 4)); +} + +TEST(MutatingTest, PartitionCopy) { + const std::vector<int> initial = {1, 2, 3, 4, 5}; + std::vector<int> odds, evens; + auto ends = absl::c_partition_copy(initial, back_inserter(odds), + back_inserter(evens), IsOdd); + *ends.first = 7; + *ends.second = 6; + EXPECT_THAT(odds, ElementsAre(1, 3, 5, 7)); + EXPECT_THAT(evens, ElementsAre(2, 4, 6)); +} + +TEST(MutatingTest, PartitionPoint) { + const std::vector<int> initial = {1, 3, 5, 2, 4}; + auto middle = absl::c_partition_point(initial, IsOdd); + EXPECT_EQ(2, *middle); +} + +TEST(MutatingTest, CopyMiddle) { + const std::vector<int> initial = {4, -1, -2, -3, 5}; + const std::list<int> input = {1, 2, 3}; + const std::vector<int> expected = {4, 1, 2, 3, 5}; + + std::list<int> test_list(initial.begin(), initial.end()); + absl::c_copy(input, ++test_list.begin()); + EXPECT_EQ(std::list<int>(expected.begin(), expected.end()), test_list); + + std::vector<int> test_vector = initial; + absl::c_copy(input, test_vector.begin() + 1); + EXPECT_EQ(expected, test_vector); +} + +TEST(MutatingTest, CopyFrontInserter) { + const std::list<int> initial = {4, 5}; + const std::list<int> input = {1, 2, 3}; + const std::list<int> expected = {3, 2, 1, 4, 5}; + + std::list<int> test_list = initial; + absl::c_copy(input, std::front_inserter(test_list)); + EXPECT_EQ(expected, test_list); +} + +TEST(MutatingTest, CopyBackInserter) { + const std::vector<int> initial = {4, 5}; + const std::list<int> input = {1, 2, 3}; + const std::vector<int> expected = {4, 5, 1, 2, 3}; + + std::list<int> test_list(initial.begin(), initial.end()); + absl::c_copy(input, std::back_inserter(test_list)); + EXPECT_EQ(std::list<int>(expected.begin(), expected.end()), test_list); + + std::vector<int> test_vector = initial; + absl::c_copy(input, std::back_inserter(test_vector)); + EXPECT_EQ(expected, test_vector); +} + +TEST(MutatingTest, CopyN) { + const std::vector<int> initial = {1, 2, 3, 4, 5}; + const std::vector<int> expected = {1, 2}; + std::vector<int> actual; + absl::c_copy_n(initial, 2, back_inserter(actual)); + EXPECT_EQ(expected, actual); +} + +TEST(MutatingTest, CopyIf) { + const std::list<int> input = {1, 2, 3}; + std::vector<int> output; + absl::c_copy_if(input, std::back_inserter(output), + [](int i) { return i != 2; }); + EXPECT_THAT(output, ElementsAre(1, 3)); +} + +TEST(MutatingTest, CopyBackward) { + std::vector<int> actual = {1, 2, 3, 4, 5}; + std::vector<int> expected = {1, 2, 1, 2, 3}; + absl::c_copy_backward(absl::MakeSpan(actual.data(), 3), actual.end()); + EXPECT_EQ(expected, actual); +} + +TEST(MutatingTest, Move) { + std::vector<std::unique_ptr<int>> src; + src.emplace_back(absl::make_unique<int>(1)); + src.emplace_back(absl::make_unique<int>(2)); + src.emplace_back(absl::make_unique<int>(3)); + src.emplace_back(absl::make_unique<int>(4)); + src.emplace_back(absl::make_unique<int>(5)); + + std::vector<std::unique_ptr<int>> dest = {}; + absl::c_move(src, std::back_inserter(dest)); + EXPECT_THAT(src, Each(IsNull())); + EXPECT_THAT(dest, ElementsAre(Pointee(1), Pointee(2), Pointee(3), Pointee(4), + Pointee(5))); +} + +TEST(MutatingTest, MoveBackward) { + std::vector<std::unique_ptr<int>> actual; + actual.emplace_back(absl::make_unique<int>(1)); + actual.emplace_back(absl::make_unique<int>(2)); + actual.emplace_back(absl::make_unique<int>(3)); + actual.emplace_back(absl::make_unique<int>(4)); + actual.emplace_back(absl::make_unique<int>(5)); + auto subrange = absl::MakeSpan(actual.data(), 3); + absl::c_move_backward(subrange, actual.end()); + EXPECT_THAT(actual, ElementsAre(IsNull(), IsNull(), Pointee(1), Pointee(2), + Pointee(3))); +} + +TEST(MutatingTest, MoveWithRvalue) { + auto MakeRValueSrc = [] { + std::vector<std::unique_ptr<int>> src; + src.emplace_back(absl::make_unique<int>(1)); + src.emplace_back(absl::make_unique<int>(2)); + src.emplace_back(absl::make_unique<int>(3)); + return src; + }; + + std::vector<std::unique_ptr<int>> dest = MakeRValueSrc(); + absl::c_move(MakeRValueSrc(), std::back_inserter(dest)); + EXPECT_THAT(dest, ElementsAre(Pointee(1), Pointee(2), Pointee(3), Pointee(1), + Pointee(2), Pointee(3))); +} + +TEST(MutatingTest, SwapRanges) { + std::vector<int> odds = {2, 4, 6}; + std::vector<int> evens = {1, 3, 5}; + absl::c_swap_ranges(odds, evens); + EXPECT_THAT(odds, ElementsAre(1, 3, 5)); + EXPECT_THAT(evens, ElementsAre(2, 4, 6)); +} + +TEST_F(NonMutatingTest, Transform) { + std::vector<int> x{0, 2, 4}, y, z; + auto end = absl::c_transform(x, back_inserter(y), std::negate<int>()); + EXPECT_EQ(std::vector<int>({0, -2, -4}), y); + *end = 7; + EXPECT_EQ(std::vector<int>({0, -2, -4, 7}), y); + + y = {1, 3, 0}; + end = absl::c_transform(x, y, back_inserter(z), std::plus<int>()); + EXPECT_EQ(std::vector<int>({1, 5, 4}), z); + *end = 7; + EXPECT_EQ(std::vector<int>({1, 5, 4, 7}), z); +} + +TEST(MutatingTest, Replace) { + const std::vector<int> initial = {1, 2, 3, 1, 4, 5}; + const std::vector<int> expected = {4, 2, 3, 4, 4, 5}; + + std::vector<int> test_vector = initial; + absl::c_replace(test_vector, 1, 4); + EXPECT_EQ(expected, test_vector); + + std::list<int> test_list(initial.begin(), initial.end()); + absl::c_replace(test_list, 1, 4); + EXPECT_EQ(std::list<int>(expected.begin(), expected.end()), test_list); +} + +TEST(MutatingTest, ReplaceIf) { + std::vector<int> actual = {1, 2, 3, 4, 5}; + const std::vector<int> expected = {0, 2, 0, 4, 0}; + + absl::c_replace_if(actual, IsOdd, 0); + EXPECT_EQ(expected, actual); +} + +TEST(MutatingTest, ReplaceCopy) { + const std::vector<int> initial = {1, 2, 3, 1, 4, 5}; + const std::vector<int> expected = {4, 2, 3, 4, 4, 5}; + + std::vector<int> actual; + absl::c_replace_copy(initial, back_inserter(actual), 1, 4); + EXPECT_EQ(expected, actual); +} + +TEST(MutatingTest, Sort) { + std::vector<int> test_vector = {2, 3, 1, 4}; + absl::c_sort(test_vector); + EXPECT_THAT(test_vector, ElementsAre(1, 2, 3, 4)); +} + +TEST(MutatingTest, SortWithPredicate) { + std::vector<int> test_vector = {2, 3, 1, 4}; + absl::c_sort(test_vector, std::greater<int>()); + EXPECT_THAT(test_vector, ElementsAre(4, 3, 2, 1)); +} + +// For absl::c_stable_sort tests. Needs an operator< that does not cover all +// fields so that the test can check the sort preserves order of equal elements. +struct Element { + int key; + int value; + friend bool operator<(const Element& e1, const Element& e2) { + return e1.key < e2.key; + } + // Make gmock print useful diagnostics. + friend std::ostream& operator<<(std::ostream& o, const Element& e) { + return o << "{" << e.key << ", " << e.value << "}"; + } +}; + +MATCHER_P2(IsElement, key, value, "") { + return arg.key == key && arg.value == value; +} + +TEST(MutatingTest, StableSort) { + std::vector<Element> test_vector = {{1, 1}, {2, 1}, {2, 0}, {1, 0}, {2, 2}}; + absl::c_stable_sort(test_vector); + EXPECT_THAT( + test_vector, + ElementsAre(IsElement(1, 1), IsElement(1, 0), IsElement(2, 1), + IsElement(2, 0), IsElement(2, 2))); +} + +TEST(MutatingTest, StableSortWithPredicate) { + std::vector<Element> test_vector = {{1, 1}, {2, 1}, {2, 0}, {1, 0}, {2, 2}}; + absl::c_stable_sort(test_vector, [](const Element& e1, const Element& e2) { + return e2 < e1; + }); + EXPECT_THAT( + test_vector, + ElementsAre(IsElement(2, 1), IsElement(2, 0), IsElement(2, 2), + IsElement(1, 1), IsElement(1, 0))); +} + +TEST(MutatingTest, ReplaceCopyIf) { + const std::vector<int> initial = {1, 2, 3, 4, 5}; + const std::vector<int> expected = {0, 2, 0, 4, 0}; + + std::vector<int> actual; + absl::c_replace_copy_if(initial, back_inserter(actual), IsOdd, 0); + EXPECT_EQ(expected, actual); +} + +TEST(MutatingTest, Fill) { + std::vector<int> actual(5); + absl::c_fill(actual, 1); + EXPECT_THAT(actual, ElementsAre(1, 1, 1, 1, 1)); +} + +TEST(MutatingTest, FillN) { + std::vector<int> actual(5, 0); + absl::c_fill_n(actual, 2, 1); + EXPECT_THAT(actual, ElementsAre(1, 1, 0, 0, 0)); +} + +TEST(MutatingTest, Generate) { + std::vector<int> actual(5); + int x = 0; + absl::c_generate(actual, [&x]() { return ++x; }); + EXPECT_THAT(actual, ElementsAre(1, 2, 3, 4, 5)); +} + +TEST(MutatingTest, GenerateN) { + std::vector<int> actual(5, 0); + int x = 0; + absl::c_generate_n(actual, 3, [&x]() { return ++x; }); + EXPECT_THAT(actual, ElementsAre(1, 2, 3, 0, 0)); +} + +TEST(MutatingTest, RemoveCopy) { + std::vector<int> actual; + absl::c_remove_copy(std::vector<int>{1, 2, 3}, back_inserter(actual), 2); + EXPECT_THAT(actual, ElementsAre(1, 3)); +} + +TEST(MutatingTest, RemoveCopyIf) { + std::vector<int> actual; + absl::c_remove_copy_if(std::vector<int>{1, 2, 3}, back_inserter(actual), + IsOdd); + EXPECT_THAT(actual, ElementsAre(2)); +} + +TEST(MutatingTest, UniqueCopy) { + std::vector<int> actual; + absl::c_unique_copy(std::vector<int>{1, 2, 2, 2, 3, 3, 2}, + back_inserter(actual)); + EXPECT_THAT(actual, ElementsAre(1, 2, 3, 2)); +} + +TEST(MutatingTest, UniqueCopyWithPredicate) { + std::vector<int> actual; + absl::c_unique_copy(std::vector<int>{1, 2, 3, -1, -2, -3, 1}, + back_inserter(actual), + [](int x, int y) { return (x < 0) == (y < 0); }); + EXPECT_THAT(actual, ElementsAre(1, -1, 1)); +} + +TEST(MutatingTest, Reverse) { + std::vector<int> test_vector = {1, 2, 3, 4}; + absl::c_reverse(test_vector); + EXPECT_THAT(test_vector, ElementsAre(4, 3, 2, 1)); + + std::list<int> test_list = {1, 2, 3, 4}; + absl::c_reverse(test_list); + EXPECT_THAT(test_list, ElementsAre(4, 3, 2, 1)); +} + +TEST(MutatingTest, ReverseCopy) { + std::vector<int> actual; + absl::c_reverse_copy(std::vector<int>{1, 2, 3, 4}, back_inserter(actual)); + EXPECT_THAT(actual, ElementsAre(4, 3, 2, 1)); +} + +TEST(MutatingTest, Rotate) { + std::vector<int> actual = {1, 2, 3, 4}; + auto it = absl::c_rotate(actual, actual.begin() + 2); + EXPECT_THAT(actual, testing::ElementsAreArray({3, 4, 1, 2})); + EXPECT_EQ(*it, 1); +} + +TEST(MutatingTest, RotateCopy) { + std::vector<int> initial = {1, 2, 3, 4}; + std::vector<int> actual; + auto end = + absl::c_rotate_copy(initial, initial.begin() + 2, back_inserter(actual)); + *end = 5; + EXPECT_THAT(actual, ElementsAre(3, 4, 1, 2, 5)); +} + +TEST(MutatingTest, Shuffle) { + std::vector<int> actual = {1, 2, 3, 4, 5}; + absl::c_shuffle(actual, std::random_device()); + EXPECT_THAT(actual, UnorderedElementsAre(1, 2, 3, 4, 5)); +} + +TEST(MutatingTest, PartialSort) { + std::vector<int> sequence{5, 3, 42, 0}; + absl::c_partial_sort(sequence, sequence.begin() + 2); + EXPECT_THAT(absl::MakeSpan(sequence.data(), 2), ElementsAre(0, 3)); + absl::c_partial_sort(sequence, sequence.begin() + 2, std::greater<int>()); + EXPECT_THAT(absl::MakeSpan(sequence.data(), 2), ElementsAre(42, 5)); +} + +TEST(MutatingTest, PartialSortCopy) { + const std::vector<int> initial = {5, 3, 42, 0}; + std::vector<int> actual(2); + absl::c_partial_sort_copy(initial, actual); + EXPECT_THAT(actual, ElementsAre(0, 3)); + absl::c_partial_sort_copy(initial, actual, std::greater<int>()); + EXPECT_THAT(actual, ElementsAre(42, 5)); +} + +TEST(MutatingTest, Merge) { + std::vector<int> actual; + absl::c_merge(std::vector<int>{1, 3, 5}, std::vector<int>{2, 4}, + back_inserter(actual)); + EXPECT_THAT(actual, ElementsAre(1, 2, 3, 4, 5)); +} + +TEST(MutatingTest, MergeWithComparator) { + std::vector<int> actual; + absl::c_merge(std::vector<int>{5, 3, 1}, std::vector<int>{4, 2}, + back_inserter(actual), std::greater<int>()); + EXPECT_THAT(actual, ElementsAre(5, 4, 3, 2, 1)); +} + +TEST(MutatingTest, InplaceMerge) { + std::vector<int> actual = {1, 3, 5, 2, 4}; + absl::c_inplace_merge(actual, actual.begin() + 3); + EXPECT_THAT(actual, ElementsAre(1, 2, 3, 4, 5)); +} + +TEST(MutatingTest, InplaceMergeWithComparator) { + std::vector<int> actual = {5, 3, 1, 4, 2}; + absl::c_inplace_merge(actual, actual.begin() + 3, std::greater<int>()); + EXPECT_THAT(actual, ElementsAre(5, 4, 3, 2, 1)); +} + +class SetOperationsTest : public testing::Test { + protected: + std::vector<int> a_ = {1, 2, 3}; + std::vector<int> b_ = {1, 3, 5}; + + std::vector<int> a_reversed_ = {3, 2, 1}; + std::vector<int> b_reversed_ = {5, 3, 1}; +}; + +TEST_F(SetOperationsTest, SetUnion) { + std::vector<int> actual; + absl::c_set_union(a_, b_, back_inserter(actual)); + EXPECT_THAT(actual, ElementsAre(1, 2, 3, 5)); +} + +TEST_F(SetOperationsTest, SetUnionWithComparator) { + std::vector<int> actual; + absl::c_set_union(a_reversed_, b_reversed_, back_inserter(actual), + std::greater<int>()); + EXPECT_THAT(actual, ElementsAre(5, 3, 2, 1)); +} + +TEST_F(SetOperationsTest, SetIntersection) { + std::vector<int> actual; + absl::c_set_intersection(a_, b_, back_inserter(actual)); + EXPECT_THAT(actual, ElementsAre(1, 3)); +} + +TEST_F(SetOperationsTest, SetIntersectionWithComparator) { + std::vector<int> actual; + absl::c_set_intersection(a_reversed_, b_reversed_, back_inserter(actual), + std::greater<int>()); + EXPECT_THAT(actual, ElementsAre(3, 1)); +} + +TEST_F(SetOperationsTest, SetDifference) { + std::vector<int> actual; + absl::c_set_difference(a_, b_, back_inserter(actual)); + EXPECT_THAT(actual, ElementsAre(2)); +} + +TEST_F(SetOperationsTest, SetDifferenceWithComparator) { + std::vector<int> actual; + absl::c_set_difference(a_reversed_, b_reversed_, back_inserter(actual), + std::greater<int>()); + EXPECT_THAT(actual, ElementsAre(2)); +} + +TEST_F(SetOperationsTest, SetSymmetricDifference) { + std::vector<int> actual; + absl::c_set_symmetric_difference(a_, b_, back_inserter(actual)); + EXPECT_THAT(actual, ElementsAre(2, 5)); +} + +TEST_F(SetOperationsTest, SetSymmetricDifferenceWithComparator) { + std::vector<int> actual; + absl::c_set_symmetric_difference(a_reversed_, b_reversed_, + back_inserter(actual), std::greater<int>()); + EXPECT_THAT(actual, ElementsAre(5, 2)); +} + +TEST(HeapOperationsTest, WithoutComparator) { + std::vector<int> heap = {1, 2, 3}; + EXPECT_FALSE(absl::c_is_heap(heap)); + absl::c_make_heap(heap); + EXPECT_TRUE(absl::c_is_heap(heap)); + heap.push_back(4); + EXPECT_EQ(3, absl::c_is_heap_until(heap) - heap.begin()); + absl::c_push_heap(heap); + EXPECT_EQ(4, heap[0]); + absl::c_pop_heap(heap); + EXPECT_EQ(4, heap[3]); + absl::c_make_heap(heap); + absl::c_sort_heap(heap); + EXPECT_THAT(heap, ElementsAre(1, 2, 3, 4)); + EXPECT_FALSE(absl::c_is_heap(heap)); +} + +TEST(HeapOperationsTest, WithComparator) { + using greater = std::greater<int>; + std::vector<int> heap = {3, 2, 1}; + EXPECT_FALSE(absl::c_is_heap(heap, greater())); + absl::c_make_heap(heap, greater()); + EXPECT_TRUE(absl::c_is_heap(heap, greater())); + heap.push_back(0); + EXPECT_EQ(3, absl::c_is_heap_until(heap, greater()) - heap.begin()); + absl::c_push_heap(heap, greater()); + EXPECT_EQ(0, heap[0]); + absl::c_pop_heap(heap, greater()); + EXPECT_EQ(0, heap[3]); + absl::c_make_heap(heap, greater()); + absl::c_sort_heap(heap, greater()); + EXPECT_THAT(heap, ElementsAre(3, 2, 1, 0)); + EXPECT_FALSE(absl::c_is_heap(heap, greater())); +} + +TEST(MutatingTest, PermutationOperations) { + std::vector<int> initial = {1, 2, 3, 4}; + std::vector<int> permuted = initial; + + absl::c_next_permutation(permuted); + EXPECT_TRUE(absl::c_is_permutation(initial, permuted)); + EXPECT_TRUE(absl::c_is_permutation(initial, permuted, std::equal_to<int>())); + + std::vector<int> permuted2 = initial; + absl::c_prev_permutation(permuted2, std::greater<int>()); + EXPECT_EQ(permuted, permuted2); + + absl::c_prev_permutation(permuted); + EXPECT_EQ(initial, permuted); +} + +} // namespace diff --git a/third_party/abseil_cpp/absl/algorithm/equal_benchmark.cc b/third_party/abseil_cpp/absl/algorithm/equal_benchmark.cc new file mode 100644 index 000000000000..7bf62c9a7f56 --- /dev/null +++ b/third_party/abseil_cpp/absl/algorithm/equal_benchmark.cc @@ -0,0 +1,126 @@ +// Copyright 2017 The Abseil Authors. +// +// Licensed under the Apache License, Version 2.0 (the "License"); +// you may not use this file except in compliance with the License. +// You may obtain a copy of the License at +// +// https://www.apache.org/licenses/LICENSE-2.0 +// +// Unless required by applicable law or agreed to in writing, software +// distributed under the License is distributed on an "AS IS" BASIS, +// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. +// See the License for the specific language governing permissions and +// limitations under the License. + +#include <cstdint> +#include <cstring> + +#include "benchmark/benchmark.h" +#include "absl/algorithm/algorithm.h" + +namespace { + +// The range of sequence sizes to benchmark. +constexpr int kMinBenchmarkSize = 1024; +constexpr int kMaxBenchmarkSize = 8 * 1024 * 1024; + +// A user-defined type for use in equality benchmarks. Note that we expect +// std::memcmp to win for this type: libstdc++'s std::equal only defers to +// memcmp for integral types. This is because it is not straightforward to +// guarantee that std::memcmp would produce a result "as-if" compared by +// operator== for other types (example gotchas: NaN floats, structs with +// padding). +struct EightBits { + explicit EightBits(int /* unused */) : data(0) {} + bool operator==(const EightBits& rhs) const { return data == rhs.data; } + uint8_t data; +}; + +template <typename T> +void BM_absl_equal_benchmark(benchmark::State& state) { + std::vector<T> xs(state.range(0), T(0)); + std::vector<T> ys = xs; + while (state.KeepRunning()) { + const bool same = absl::equal(xs.begin(), xs.end(), ys.begin(), ys.end()); + benchmark::DoNotOptimize(same); + } +} + +template <typename T> +void BM_std_equal_benchmark(benchmark::State& state) { + std::vector<T> xs(state.range(0), T(0)); + std::vector<T> ys = xs; + while (state.KeepRunning()) { + const bool same = std::equal(xs.begin(), xs.end(), ys.begin()); + benchmark::DoNotOptimize(same); + } +} + +template <typename T> +void BM_memcmp_benchmark(benchmark::State& state) { + std::vector<T> xs(state.range(0), T(0)); + std::vector<T> ys = xs; + while (state.KeepRunning()) { + const bool same = + std::memcmp(xs.data(), ys.data(), xs.size() * sizeof(T)) == 0; + benchmark::DoNotOptimize(same); + } +} + +// The expectation is that the compiler should be able to elide the equality +// comparison altogether for sufficiently simple types. +template <typename T> +void BM_absl_equal_self_benchmark(benchmark::State& state) { + std::vector<T> xs(state.range(0), T(0)); + while (state.KeepRunning()) { + const bool same = absl::equal(xs.begin(), xs.end(), xs.begin(), xs.end()); + benchmark::DoNotOptimize(same); + } +} + +BENCHMARK_TEMPLATE(BM_absl_equal_benchmark, uint8_t) + ->Range(kMinBenchmarkSize, kMaxBenchmarkSize); +BENCHMARK_TEMPLATE(BM_std_equal_benchmark, uint8_t) + ->Range(kMinBenchmarkSize, kMaxBenchmarkSize); +BENCHMARK_TEMPLATE(BM_memcmp_benchmark, uint8_t) + ->Range(kMinBenchmarkSize, kMaxBenchmarkSize); +BENCHMARK_TEMPLATE(BM_absl_equal_self_benchmark, uint8_t) + ->Range(kMinBenchmarkSize, kMaxBenchmarkSize); + +BENCHMARK_TEMPLATE(BM_absl_equal_benchmark, uint16_t) + ->Range(kMinBenchmarkSize, kMaxBenchmarkSize); +BENCHMARK_TEMPLATE(BM_std_equal_benchmark, uint16_t) + ->Range(kMinBenchmarkSize, kMaxBenchmarkSize); +BENCHMARK_TEMPLATE(BM_memcmp_benchmark, uint16_t) + ->Range(kMinBenchmarkSize, kMaxBenchmarkSize); +BENCHMARK_TEMPLATE(BM_absl_equal_self_benchmark, uint16_t) + ->Range(kMinBenchmarkSize, kMaxBenchmarkSize); + +BENCHMARK_TEMPLATE(BM_absl_equal_benchmark, uint32_t) + ->Range(kMinBenchmarkSize, kMaxBenchmarkSize); +BENCHMARK_TEMPLATE(BM_std_equal_benchmark, uint32_t) + ->Range(kMinBenchmarkSize, kMaxBenchmarkSize); +BENCHMARK_TEMPLATE(BM_memcmp_benchmark, uint32_t) + ->Range(kMinBenchmarkSize, kMaxBenchmarkSize); +BENCHMARK_TEMPLATE(BM_absl_equal_self_benchmark, uint32_t) + ->Range(kMinBenchmarkSize, kMaxBenchmarkSize); + +BENCHMARK_TEMPLATE(BM_absl_equal_benchmark, uint64_t) + ->Range(kMinBenchmarkSize, kMaxBenchmarkSize); +BENCHMARK_TEMPLATE(BM_std_equal_benchmark, uint64_t) + ->Range(kMinBenchmarkSize, kMaxBenchmarkSize); +BENCHMARK_TEMPLATE(BM_memcmp_benchmark, uint64_t) + ->Range(kMinBenchmarkSize, kMaxBenchmarkSize); +BENCHMARK_TEMPLATE(BM_absl_equal_self_benchmark, uint64_t) + ->Range(kMinBenchmarkSize, kMaxBenchmarkSize); + +BENCHMARK_TEMPLATE(BM_absl_equal_benchmark, EightBits) + ->Range(kMinBenchmarkSize, kMaxBenchmarkSize); +BENCHMARK_TEMPLATE(BM_std_equal_benchmark, EightBits) + ->Range(kMinBenchmarkSize, kMaxBenchmarkSize); +BENCHMARK_TEMPLATE(BM_memcmp_benchmark, EightBits) + ->Range(kMinBenchmarkSize, kMaxBenchmarkSize); +BENCHMARK_TEMPLATE(BM_absl_equal_self_benchmark, EightBits) + ->Range(kMinBenchmarkSize, kMaxBenchmarkSize); + +} // namespace |