Eine aufbereitete Darstellung der Quelle

 
     
 
 
Anforderungen  |   Konzepte  |   Entwurf  |   Entwicklung  |   Qualitätssicherung  |   Lebenszyklus  |   Steuerung
 
 
 
 

Benutzer

Quelle  container_test.cc

  Sprache: C
 

// 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 <algorithm>
#include <array>
#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/config.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::IsSubsetOf;
using ::testing::Lt;
using ::testing::Pointee;
using ::testing::SizeIs;
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_ = {123};
  std::list<int> sequence_ = {123};
  std::vector<int> vector_ = {123};
  int array_[3] = {123};
};

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(),
            static_cast<size_t>(absl::c_distance(container_)));
  EXPECT_EQ(sequence_.size(), static_cast<size_t>(absl::c_distance(sequence_)));
  EXPECT_EQ(vector_.size(), static_cast<size_t>(absl::c_distance(vector_)));
  EXPECT_EQ(ABSL_ARRAYSIZE(array_),
            static_cast<size_t>(absl::c_distance(array_)));

  // Works with a temporary argument.
  EXPECT_EQ(vector_.size(),
            static_cast<size_t>(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 = {123};
  std::valarray<int> b = {123};
  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, Contains) {
  EXPECT_TRUE(absl::c_contains(container_, 3));
  EXPECT_FALSE(absl::c_contains(container_, 4));
}

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) {
  // Testing necessary as absl::c_mismatch executes logic.
  {
    auto result = absl::c_mismatch(vector_, sequence_);
    EXPECT_EQ(result.first, vector_.end());
    EXPECT_EQ(result.second, sequence_.end());
  }
  {
    auto result = absl::c_mismatch(sequence_, vector_);
    EXPECT_EQ(result.first, sequence_.end());
    EXPECT_EQ(result.second, vector_.end());
  }

  sequence_.back() = 5;
  {
    auto result = absl::c_mismatch(vector_, sequence_);
    EXPECT_EQ(result.first, std::prev(vector_.end()));
    EXPECT_EQ(result.second, std::prev(sequence_.end()));
  }
  {
    auto result = absl::c_mismatch(sequence_, vector_);
    EXPECT_EQ(result.first, std::prev(sequence_.end()));
    EXPECT_EQ(result.second, std::prev(vector_.end()));
  }

  sequence_.pop_back();
  {
    auto result = absl::c_mismatch(vector_, sequence_);
    EXPECT_EQ(result.first, std::prev(vector_.end()));
    EXPECT_EQ(result.second, sequence_.end());
  }
  {
    auto result = absl::c_mismatch(sequence_, vector_);
    EXPECT_EQ(result.first, sequence_.end());
    EXPECT_EQ(result.second, std::prev(vector_.end()));
  }
  {
    struct NoNotEquals {
      constexpr bool operator==(NoNotEquals) const { return true; }
      constexpr bool operator!=(NoNotEquals) const = delete;
    };
    std::vector<NoNotEquals> first;
    std::list<NoNotEquals> second;

    // Check this still compiles.
    absl::c_mismatch(first, second);
  }
}

TEST_F(NonMutatingTest, MismatchWithPredicate) {
  // Testing necessary as absl::c_mismatch executes logic.
  {
    auto result = absl::c_mismatch(vector_, sequence_, BinPredicate);
    EXPECT_EQ(result.first, vector_.begin());
    EXPECT_EQ(result.second, sequence_.begin());
  }
  {
    auto result = absl::c_mismatch(sequence_, vector_, BinPredicate);
    EXPECT_EQ(result.first, sequence_.begin());
    EXPECT_EQ(result.second, vector_.begin());
  }

  sequence_.front() = 0;
  {
    auto result = absl::c_mismatch(vector_, sequence_, BinPredicate);
    EXPECT_EQ(result.first, vector_.begin());
    EXPECT_EQ(result.second, sequence_.begin());
  }
  {
    auto result = absl::c_mismatch(sequence_, vector_, BinPredicate);
    EXPECT_EQ(result.first, std::next(sequence_.begin()));
    EXPECT_EQ(result.second, std::next(vector_.begin()));
  }

  sequence_.clear();
  {
    auto result = absl::c_mismatch(vector_, sequence_, BinPredicate);
    EXPECT_EQ(result.first, vector_.begin());
    EXPECT_EQ(result.second, sequence_.end());
  }
  {
    auto result = absl::c_mismatch(sequence_, vector_, BinPredicate);
    EXPECT_EQ(result.first, sequence_.end());
    EXPECT_EQ(result.second, vector_.begin());
  }
}

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 = {123};
  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 = {123};
  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 = {123};
  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 = {123};
  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, ContainsSubrange) {
  EXPECT_TRUE(absl::c_contains_subrange(sequence_, vector_));
  EXPECT_TRUE(absl::c_contains_subrange(vector_, sequence_));
  EXPECT_TRUE(absl::c_contains_subrange(array_, sequence_));
}

TEST_F(NonMutatingTest, ContainsSubrangeWithPredicate) {
  EXPECT_TRUE(absl::c_contains_subrange(sequence_, vector_, Equals));
  EXPECT_TRUE(absl::c_contains_subrange(vector_, sequence_, Equals));
}

TEST_F(NonMutatingTest, SearchN) { absl::c_search_n(sequence_, 31); }

TEST_F(NonMutatingTest, SearchNWithPredicate) {
  absl::c_search_n(sequence_, 31, 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 = {321};
  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_ = {123};
  std::vector<int> output_;
};

TEST_F(NumericMutatingTest, Iota) {
  absl::c_iota(list_, 5);
  std::list<int> expected{567};
  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{12 - 13 - 21000};
  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{12 * 13 * 21000};
  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{11 + 21 + 2 + 31000};
  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{11 * 21 * 2 * 31000};
  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_ = {1234};
  std::list<int> unsorted_ = {2413};
  std::list<int> reversed_ = {4321};
};

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 = {2413};
  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>{135246}, IsOdd));
  EXPECT_FALSE(
      absl::c_is_partitioned(std::vector<int>{123456}, IsOdd));
  EXPECT_FALSE(
      absl::c_is_partitioned(std::vector<int>{246135}, IsOdd));
}

TEST(MutatingTest, Partition) {
  std::vector<int> actual = {12345};
  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 = {12345};
  absl::c_stable_partition(actual, IsOdd);
  EXPECT_THAT(actual, ElementsAre(13524));
}

TEST(MutatingTest, PartitionCopy) {
  const std::vector<int> initial = {12345};
  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(1357));
  EXPECT_THAT(evens, ElementsAre(246));
}

TEST(MutatingTest, PartitionPoint) {
  const std::vector<int> initial = {13524};
  auto middle = absl::c_partition_point(initial, IsOdd);
  EXPECT_EQ(2, *middle);
}

TEST(MutatingTest, CopyMiddle) {
  const std::vector<int> initial = {4, -1, -2, -35};
  const std::list<int> input = {123};
  const std::vector<int> expected = {41235};

  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 = {45};
  const std::list<int> input = {123};
  const std::list<int> expected = {32145};

  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 = {45};
  const std::list<int> input = {123};
  const std::vector<int> expected = {45123};

  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 = {12345};
  const std::vector<int> expected = {12};
  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 = {123};
  std::vector<int> output;
  absl::c_copy_if(input, std::back_inserter(output),
                  [](int i) { return i != 2; });
  EXPECT_THAT(output, ElementsAre(13));
}

TEST(MutatingTest, CopyBackward) {
  std::vector<int> actual = {12345};
  std::vector<int> expected = {12123};
  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 = {246};
  std::vector<int> evens = {135};
  absl::c_swap_ranges(odds, evens);
  EXPECT_THAT(odds, ElementsAre(135));
  EXPECT_THAT(evens, ElementsAre(246));

  odds.pop_back();
  absl::c_swap_ranges(odds, evens);
  EXPECT_THAT(odds, ElementsAre(24));
  EXPECT_THAT(evens, ElementsAre(136));

  absl::c_swap_ranges(evens, odds);
  EXPECT_THAT(odds, ElementsAre(13));
  EXPECT_THAT(evens, ElementsAre(246));
}

TEST_F(NonMutatingTest, Transform) {
  std::vector<int> x{024}, 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, -47}), y);

  y = {130};
  end = absl::c_transform(x, y, back_inserter(z), std::plus<int>());
  EXPECT_EQ(std::vector<int>({154}), z);
  *end = 7;
  EXPECT_EQ(std::vector<int>({1547}), z);

  z.clear();
  y.pop_back();
  end = absl::c_transform(x, y, std::back_inserter(z), std::plus<int>());
  EXPECT_EQ(std::vector<int>({15}), z);
  *end = 7;
  EXPECT_EQ(std::vector<int>({157}), z);

  z.clear();
  std::swap(x, y);
  end = absl::c_transform(x, y, std::back_inserter(z), std::plus<int>());
  EXPECT_EQ(std::vector<int>({15}), z);
  *end = 7;
  EXPECT_EQ(std::vector<int>({157}), z);
}

TEST(MutatingTest, Replace) {
  const std::vector<int> initial = {123145};
  const std::vector<int> expected = {423445};

  std::vector<int> test_vector = initial;
  absl::c_replace(test_vector, 14);
  EXPECT_EQ(expected, test_vector);

  std::list<int> test_list(initial.begin(), initial.end());
  absl::c_replace(test_list, 14);
  EXPECT_EQ(std::list<int>(expected.begin(), expected.end()), test_list);
}

TEST(MutatingTest, ReplaceIf) {
  std::vector<int> actual = {12345};
  const std::vector<int> expected = {02040};

  absl::c_replace_if(actual, IsOdd, 0);
  EXPECT_EQ(expected, actual);
}

TEST(MutatingTest, ReplaceCopy) {
  const std::vector<int> initial = {123145};
  const std::vector<int> expected = {423445};

  std::vector<int> actual;
  absl::c_replace_copy(initial, back_inserter(actual), 14);
  EXPECT_EQ(expected, actual);
}

TEST(MutatingTest, Sort) {
  std::vector<int> test_vector = {2314};
  absl::c_sort(test_vector);
  EXPECT_THAT(test_vector, ElementsAre(1234));
}

TEST(MutatingTest, SortWithPredicate) {
  std::vector<int> test_vector = {2314};
  absl::c_sort(test_vector, std::greater<int>());
  EXPECT_THAT(test_vector, ElementsAre(4321));
}

// 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 = {{11}, {21}, {20}, {10}, {22}};
  absl::c_stable_sort(test_vector);
  EXPECT_THAT(test_vector,
              ElementsAre(IsElement(11), IsElement(10), IsElement(21),
                          IsElement(20), IsElement(22)));
}

TEST(MutatingTest, StableSortWithPredicate) {
  std::vector<Element> test_vector = {{11}, {21}, {20}, {10}, {22}};
  absl::c_stable_sort(test_vector, [](const Element& e1, const Element& e2) {
    return e2 < e1;
  });
  EXPECT_THAT(test_vector,
              ElementsAre(IsElement(21), IsElement(20), IsElement(22),
                          IsElement(11), IsElement(10)));
}

TEST(MutatingTest, ReplaceCopyIf) {
  const std::vector<int> initial = {12345};
  const std::vector<int> expected = {02040};

  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(11111));
}

TEST(MutatingTest, FillN) {
  std::vector<int> actual(50);
  absl::c_fill_n(actual, 21);
  EXPECT_THAT(actual, ElementsAre(11000));
}

TEST(MutatingTest, Generate) {
  std::vector<int> actual(5);
  int x = 0;
  absl::c_generate(actual, [&x]() { return ++x; });
  EXPECT_THAT(actual, ElementsAre(12345));
}

TEST(MutatingTest, GenerateN) {
  std::vector<int> actual(50);
  int x = 0;
  absl::c_generate_n(actual, 3, [&x]() { return ++x; });
  EXPECT_THAT(actual, ElementsAre(12300));
}

TEST(MutatingTest, RemoveCopy) {
  std::vector<int> actual;
  absl::c_remove_copy(std::vector<int>{123}, back_inserter(actual), 2);
  EXPECT_THAT(actual, ElementsAre(13));
}

TEST(MutatingTest, RemoveCopyIf) {
  std::vector<int> actual;
  absl::c_remove_copy_if(std::vector<int>{123}, back_inserter(actual),
                         IsOdd);
  EXPECT_THAT(actual, ElementsAre(2));
}

TEST(MutatingTest, UniqueCopy) {
  std::vector<int> actual;
  absl::c_unique_copy(std::vector<int>{1222332},
                      back_inserter(actual));
  EXPECT_THAT(actual, ElementsAre(1232));
}

TEST(MutatingTest, UniqueCopyWithPredicate) {
  std::vector<int> actual;
  absl::c_unique_copy(std::vector<int>{123, -1, -2, -31},
                      back_inserter(actual),
                      [](int x, int y) { return (x < 0) == (y < 0); });
  EXPECT_THAT(actual, ElementsAre(1, -11));
}

TEST(MutatingTest, Reverse) {
  std::vector<int> test_vector = {1234};
  absl::c_reverse(test_vector);
  EXPECT_THAT(test_vector, ElementsAre(4321));

  std::list<int> test_list = {1234};
  absl::c_reverse(test_list);
  EXPECT_THAT(test_list, ElementsAre(4321));
}

TEST(MutatingTest, ReverseCopy) {
  std::vector<int> actual;
  absl::c_reverse_copy(std::vector<int>{1234}, back_inserter(actual));
  EXPECT_THAT(actual, ElementsAre(4321));
}

TEST(MutatingTest, Rotate) {
  std::vector<int> actual = {1234};
  auto it = absl::c_rotate(actual, actual.begin() + 2);
  EXPECT_THAT(actual, testing::ElementsAreArray({3412}));
  EXPECT_EQ(*it, 1);
}

TEST(MutatingTest, RotateCopy) {
  std::vector<int> initial = {1234};
  std::vector<int> actual;
  auto end =
      absl::c_rotate_copy(initial, initial.begin() + 2, back_inserter(actual));
  *end = 5;
  EXPECT_THAT(actual, ElementsAre(34125));
}

template <typename T>
T RandomlySeededPrng() {
  std::random_device rdev;
  std::seed_seq::result_type data[T::state_size];
  std::generate_n(data, T::state_size, std::ref(rdev));
  std::seed_seq prng_seed(data, data + T::state_size);
  return T(prng_seed);
}

TEST(MutatingTest, Shuffle) {
  std::vector<int> actual = {12345};
  absl::c_shuffle(actual, RandomlySeededPrng<std::mt19937_64>());
  EXPECT_THAT(actual, UnorderedElementsAre(12345));
}

TEST(MutatingTest, Sample) {
  std::vector<int> actual;
  absl::c_sample(std::vector<int>{12345}, std::back_inserter(actual), 3,
                 RandomlySeededPrng<std::mt19937_64>());
  EXPECT_THAT(actual, IsSubsetOf({12345}));
  EXPECT_THAT(actual, SizeIs(3));
}

TEST(MutatingTest, PartialSort) {
  std::vector<int> sequence{53420};
  absl::c_partial_sort(sequence, sequence.begin() + 2);
  EXPECT_THAT(absl::MakeSpan(sequence.data(), 2), ElementsAre(03));
  absl::c_partial_sort(sequence, sequence.begin() + 2, std::greater<int>());
  EXPECT_THAT(absl::MakeSpan(sequence.data(), 2), ElementsAre(425));
}

TEST(MutatingTest, PartialSortCopy) {
  const std::vector<int> initial = {53420};
  std::vector<int> actual(2);
  absl::c_partial_sort_copy(initial, actual);
  EXPECT_THAT(actual, ElementsAre(03));
  absl::c_partial_sort_copy(initial, actual, std::greater<int>());
  EXPECT_THAT(actual, ElementsAre(425));
}

TEST(MutatingTest, Merge) {
  std::vector<int> actual;
  absl::c_merge(std::vector<int>{135}, std::vector<int>{24},
                back_inserter(actual));
  EXPECT_THAT(actual, ElementsAre(12345));
}

TEST(MutatingTest, MergeWithComparator) {
  std::vector<int> actual;
  absl::c_merge(std::vector<int>{531}, std::vector<int>{42},
                back_inserter(actual), std::greater<int>());
  EXPECT_THAT(actual, ElementsAre(54321));
}

TEST(MutatingTest, InplaceMerge) {
  std::vector<int> actual = {13524};
  absl::c_inplace_merge(actual, actual.begin() + 3);
  EXPECT_THAT(actual, ElementsAre(12345));
}

TEST(MutatingTest, InplaceMergeWithComparator) {
  std::vector<int> actual = {53142};
  absl::c_inplace_merge(actual, actual.begin() + 3, std::greater<int>());
  EXPECT_THAT(actual, ElementsAre(54321));
}

class SetOperationsTest : public testing::Test {
 protected:
  std::vector<int> a_ = {123};
  std::vector<int> b_ = {135};

  std::vector<int> a_reversed_ = {321};
  std::vector<int> b_reversed_ = {531};
};

TEST_F(SetOperationsTest, SetUnion) {
  std::vector<int> actual;
  absl::c_set_union(a_, b_, back_inserter(actual));
  EXPECT_THAT(actual, ElementsAre(1235));
}

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(5321));
}

TEST_F(SetOperationsTest, SetIntersection) {
  std::vector<int> actual;
  absl::c_set_intersection(a_, b_, back_inserter(actual));
  EXPECT_THAT(actual, ElementsAre(13));
}

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(31));
}

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(25));
}

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(52));
}

TEST(HeapOperationsTest, WithoutComparator) {
  std::vector<int> heap = {123};
  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(1234));
  EXPECT_FALSE(absl::c_is_heap(heap));
}

TEST(HeapOperationsTest, WithComparator) {
  using greater = std::greater<int>;
  std::vector<int> heap = {321};
  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(3210));
  EXPECT_FALSE(absl::c_is_heap(heap, greater()));
}

TEST(MutatingTest, PermutationOperations) {
  std::vector<int> initial = {1234};
  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);
}

#if defined(ABSL_INTERNAL_CPLUSPLUS_LANG) && \
    ABSL_INTERNAL_CPLUSPLUS_LANG >= 201703L

TEST(ConstexprTest, Distance) {
  // Works at compile time with constexpr containers.
  static_assert(absl::c_distance(std::array<int3>()) == 3);
}

TEST(ConstexprTest, MinElement) {
  constexpr std::array<int3> kArray = {123};
  static_assert(*absl::c_min_element(kArray) == 1);
}

TEST(ConstexprTest, MinElementWithPredicate) {
  constexpr std::array<int3> kArray = {123};
  static_assert(*absl::c_min_element(kArray, std::greater<int>()) == 3);
}

TEST(ConstexprTest, MaxElement) {
  constexpr std::array<int3> kArray = {123};
  static_assert(*absl::c_max_element(kArray) == 3);
}

TEST(ConstexprTest, MaxElementWithPredicate) {
  constexpr std::array<int3> kArray = {123};
  static_assert(*absl::c_max_element(kArray, std::greater<int>()) == 1);
}

TEST(ConstexprTest, MinMaxElement) {
  static constexpr std::array<int3> kArray = {123};
  constexpr auto kMinMaxPair = absl::c_minmax_element(kArray);
  static_assert(*kMinMaxPair.first == 1);
  static_assert(*kMinMaxPair.second == 3);
}

TEST(ConstexprTest, MinMaxElementWithPredicate) {
  static constexpr std::array<int3> kArray = {123};
  constexpr auto kMinMaxPair =
      absl::c_minmax_element(kArray, std::greater<int>());
  static_assert(*kMinMaxPair.first == 3);
  static_assert(*kMinMaxPair.second == 1);
}
#endif  // defined(ABSL_INTERNAL_CPLUSPLUS_LANG) &&
        //  ABSL_INTERNAL_CPLUSPLUS_LANG >= 201703L

#if defined(ABSL_INTERNAL_CPLUSPLUS_LANG) && \
    ABSL_INTERNAL_CPLUSPLUS_LANG >= 202002L

TEST(ConstexprTest, LinearSearch) {
  static constexpr std::array<int3> kArray = {123};
  static_assert(absl::c_linear_search(kArray, 3));
  static_assert(!absl::c_linear_search(kArray, 4));
}

TEST(ConstexprTest, AllOf) {
  static constexpr std::array<int3> kArray = {123};
  static_assert(!absl::c_all_of(kArray, [](int x) { return x > 1; }));
  static_assert(absl::c_all_of(kArray, [](int x) { return x > 0; }));
}

TEST(ConstexprTest, AnyOf) {
  static constexpr std::array<int3> kArray = {123};
  static_assert(absl::c_any_of(kArray, [](int x) { return x > 2; }));
  static_assert(!absl::c_any_of(kArray, [](int x) { return x > 5; }));
}

TEST(ConstexprTest, NoneOf) {
  static constexpr std::array<int3> kArray = {123};
  static_assert(!absl::c_none_of(kArray, [](int x) { return x > 2; }));
  static_assert(absl::c_none_of(kArray, [](int x) { return x > 5; }));
}

TEST(ConstexprTest, ForEach) {
  static constexpr std::array<int3> kArray = [] {
    std::array<int3> array = {123};
    absl::c_for_each(array, [](int& x) { x += 1; });
    return array;
  }();
  static_assert(kArray == std::array{234});
}

TEST(ConstexprTest, Find) {
  static constexpr std::array<int3> kArray = {123};
  static_assert(absl::c_find(kArray, 1) == kArray.begin());
  static_assert(absl::c_find(kArray, 4) == kArray.end());
}

TEST(ConstexprTest, Contains) {
  static constexpr std::array<int3> kArray = {123};
  static_assert(absl::c_contains(kArray, 1));
  static_assert(!absl::c_contains(kArray, 4));
}

TEST(ConstexprTest, FindIf) {
  static constexpr std::array<int3> kArray = {123};
  static_assert(absl::c_find_if(kArray, [](int x) { return x > 2; }) ==
                kArray.begin() + 2);
  static_assert(absl::c_find_if(kArray, [](int x) { return x > 5; }) ==
                kArray.end());
}

TEST(ConstexprTest, FindIfNot) {
  static constexpr std::array<int3> kArray = {123};
  static_assert(absl::c_find_if_not(kArray, [](int x) { return x > 1; }) ==
                kArray.begin());
  static_assert(absl::c_find_if_not(kArray, [](int x) { return x > 0; }) ==
                kArray.end());
}

TEST(ConstexprTest, FindEnd) {
  static constexpr std::array<int5> kHaystack = {12323};
  static constexpr std::array<int2> kNeedle = {23};
  static_assert(absl::c_find_end(kHaystack, kNeedle) == kHaystack.begin() + 3);
}

TEST(ConstexprTest, FindFirstOf) {
  static constexpr std::array<int3> kArray = {123};
  static_assert(absl::c_find_first_of(kArray, kArray) == kArray.begin());
}

TEST(ConstexprTest, AdjacentFind) {
  static constexpr std::array<int4> kArray = {1223};
  static_assert(absl::c_adjacent_find(kArray) == kArray.begin() + 1);
}

TEST(ConstexprTest, AdjacentFindWithPredicate) {
  static constexpr std::array<int3> kArray = {123};
  static_assert(absl::c_adjacent_find(kArray, std::less<int>()) ==
                kArray.begin());
}

TEST(ConstexprTest, Count) {
  static constexpr std::array<int3> kArray = {123};
  static_assert(absl::c_count(kArray, 1) == 1);
  static_assert(absl::c_count(kArray, 2) == 1);
  static_assert(absl::c_count(kArray, 3) == 1);
  static_assert(absl::c_count(kArray, 4) == 0);
}

TEST(ConstexprTest, CountIf) {
  static constexpr std::array<int3> kArray = {123};
  static_assert(absl::c_count_if(kArray, [](int x) { return x > 0; }) == 3);
  static_assert(absl::c_count_if(kArray, [](int x) { return x > 1; }) == 2);
}

TEST(ConstexprTest, Mismatch) {
  static constexpr std::array<int3> kArray1 = {123};
  static constexpr std::array<int3> kArray2 = {123};
  static constexpr std::array<int3> kArray3 = {234};
  static_assert(absl::c_mismatch(kArray1, kArray2) ==
                std::pair{kArray1.end(), kArray2.end()});
  static_assert(absl::c_mismatch(kArray1, kArray3) ==
                std::pair{kArray1.begin(), kArray3.begin()});
}

TEST(ConstexprTest, MismatchWithPredicate) {
  static constexpr std::array<int3> kArray1 = {123};
  static constexpr std::array<int3> kArray2 = {123};
  static constexpr std::array<int3> kArray3 = {234};
  static_assert(absl::c_mismatch(kArray1, kArray2, std::not_equal_to<int>()) ==
                std::pair{kArray1.begin(), kArray2.begin()});
  static_assert(absl::c_mismatch(kArray1, kArray3, std::not_equal_to<int>()) ==
                std::pair{kArray1.end(), kArray3.end()});
}

TEST(ConstexprTest, Equal) {
  static constexpr std::array<int3> kArray1 = {123};
  static constexpr std::array<int3> kArray2 = {123};
  static constexpr std::array<int3> kArray3 = {234};
  static_assert(absl::c_equal(kArray1, kArray2));
  static_assert(!absl::c_equal(kArray1, kArray3));
}

TEST(ConstexprTest, EqualWithPredicate) {
  static constexpr std::array<int3> kArray1 = {123};
  static constexpr std::array<int3> kArray2 = {123};
  static constexpr std::array<int3> kArray3 = {234};
  static_assert(!absl::c_equal(kArray1, kArray2, std::not_equal_to<int>()));
  static_assert(absl::c_equal(kArray1, kArray3, std::not_equal_to<int>()));
}

TEST(ConstexprTest, IsPermutation) {
  static constexpr std::array<int3> kArray1 = {123};
  static constexpr std::array<int3> kArray2 = {321};
  static constexpr std::array<int3> kArray3 = {234};
  static_assert(absl::c_is_permutation(kArray1, kArray2));
  static_assert(!absl::c_is_permutation(kArray1, kArray3));
}

TEST(ConstexprTest, IsPermutationWithPredicate) {
  static constexpr std::array<int3> kArray1 = {123};
  static constexpr std::array<int3> kArray2 = {321};
  static constexpr std::array<int3> kArray3 = {234};
  static_assert(absl::c_is_permutation(kArray1, kArray2, std::equal_to<int>()));
  static_assert(
      !absl::c_is_permutation(kArray1, kArray3, std::equal_to<int>()));
}

TEST(ConstexprTest, Search) {
  static constexpr std::array<int3> kArray1 = {123};
  static constexpr std::array<int3> kArray2 = {123};
  static constexpr std::array<int3> kArray3 = {234};
  static_assert(absl::c_search(kArray1, kArray2) == kArray1.begin());
  static_assert(absl::c_search(kArray1, kArray3) == kArray1.end());
}

TEST(ConstexprTest, SearchWithPredicate) {
  static constexpr std::array<int3> kArray1 = {123};
  static constexpr std::array<int3> kArray2 = {123};
  static constexpr std::array<int3> kArray3 = {234};
  static_assert(absl::c_search(kArray1, kArray2, std::not_equal_to<int>()) ==
                kArray1.end());
  static_assert(absl::c_search(kArray1, kArray3, std::not_equal_to<int>()) ==
                kArray1.begin());
}

TEST(ConstexprTest, ContainsSubrange) {
  static constexpr std::array<int3> kArray1 = {123};
  static constexpr std::array<int3> kArray2 = {123};
  static constexpr std::array<int3> kArray3 = {234};
  static_assert(absl::c_contains_subrange(kArray1, kArray2));
  static_assert(!absl::c_contains_subrange(kArray1, kArray3));
}

TEST(ConstexprTest, ContainsSubrangeWithPredicate) {
  static constexpr std::array<int3> kArray1 = {123};
  static constexpr std::array<int3> kArray2 = {123};
  static constexpr std::array<int3> kArray3 = {234};
  static_assert(
      !absl::c_contains_subrange(kArray1, kArray2, std::not_equal_to<>()));
  static_assert(
      absl::c_contains_subrange(kArray1, kArray3, std::not_equal_to<>()));
}

TEST(ConstexprTest, SearchN) {
  static constexpr std::array<int4> kArray = {1223};
  static_assert(absl::c_search_n(kArray, 11) == kArray.begin());
  static_assert(absl::c_search_n(kArray, 22) == kArray.begin() + 1);
  static_assert(absl::c_search_n(kArray, 14) == kArray.end());
}

TEST(ConstexprTest, SearchNWithPredicate) {
  static constexpr std::array<int4> kArray = {1223};
  static_assert(absl::c_search_n(kArray, 11, std::not_equal_to<int>()) ==
                kArray.begin() + 1);
  static_assert(absl::c_search_n(kArray, 22, std::not_equal_to<int>()) ==
                kArray.end());
  static_assert(absl::c_search_n(kArray, 14, std::not_equal_to<int>()) ==
                kArray.begin());
}

#endif  // defined(ABSL_INTERNAL_CPLUSPLUS_LANG) &&
        //  ABSL_INTERNAL_CPLUSPLUS_LANG >= 202002L

}  // namespace

Messung V0.5 in Prozent
C=85 H=100 G=92

¤ Dauer der Verarbeitung: 0.18 Sekunden  (vorverarbeitet am  2026-06-05) ¤

*© Formatika GbR, Deutschland






Wurzel

Suchen

PVS Prover

Isabelle Prover

NIST Cobol Testsuite

Cephes Mathematical Library

Vienna Development Method

Haftungshinweis

Die Informationen auf dieser Webseite wurden nach bestem Wissen sorgfältig zusammengestellt. Es wird jedoch weder Vollständigkeit, noch Richtigkeit, noch Qualität der bereit gestellten Informationen zugesichert.

Bemerkung:

Die farbliche Syntaxdarstellung und die Messung sind noch experimentell.






                                                                                                                                                                                                                                                                                                                                                                                                     


Neuigkeiten

     Aktuelles
     Motto des Tages

Software

     Quellcodebibliothek
     Eigene Quellcodes
     Fremde Quellcodes
     Suchen

Aktivitäten

     Artikel über Sicherheit
     Anleitung zur Aktivierung von SSL

Muße

     Gedichte
     Musik
     Bilder

Jenseits des Üblichen ....
    

Besucherstatistik

Besucherstatistik