/* * Copyright (c) 2021 The WebRTC project authors. All Rights Reserved. * * Use of this source code is governed by a BSD-style license * that can be found in the LICENSE file in the root of the source * tree. An additional intellectual property rights grant can be found * in the file PATENTS. All contributing project authors may * be found in the AUTHORS file in the root of the source tree. */ // This implementation is borrowed from Chromium. #include "rtc_base/containers/flat_map.h" #include #include #include #include #include "rtc_base/containers/move_only_int.h" #include "test/gmock.h" #include "test/gtest.h" // A flat_map is basically a interface to flat_tree. So several basic // operations are tested to make sure things are set up properly, but the bulk // of the tests are in flat_tree_unittests.cc. using ::testing::ElementsAre; namespace webrtc { namespace { struct Unsortable { int value; }; bool operator==(const Unsortable& lhs, const Unsortable& rhs) { return lhs.value == rhs.value; } bool operator<(const Unsortable& lhs, const Unsortable& rhs) = delete; bool operator<=(const Unsortable& lhs, const Unsortable& rhs) = delete; bool operator>(const Unsortable& lhs, const Unsortable& rhs) = delete; bool operator>=(const Unsortable& lhs, const Unsortable& rhs) = delete; TEST(FlatMap, IncompleteType) { struct A { using Map = flat_map; int data; Map set_with_incomplete_type; Map::iterator it; Map::const_iterator cit; // We do not declare operator< because clang complains that it's unused. }; A a; } TEST(FlatMap, RangeConstructor) { flat_map::value_type input_vals[] = { {1, 1}, {1, 2}, {1, 3}, {2, 1}, {2, 2}, {2, 3}, {3, 1}, {3, 2}, {3, 3}}; flat_map first(std::begin(input_vals), std::end(input_vals)); EXPECT_THAT(first, ElementsAre(std::make_pair(1, 1), std::make_pair(2, 1), std::make_pair(3, 1))); } TEST(FlatMap, MoveConstructor) { using pair = std::pair; flat_map original; original.insert(pair(MoveOnlyInt(1), MoveOnlyInt(1))); original.insert(pair(MoveOnlyInt(2), MoveOnlyInt(2))); original.insert(pair(MoveOnlyInt(3), MoveOnlyInt(3))); original.insert(pair(MoveOnlyInt(4), MoveOnlyInt(4))); flat_map moved(std::move(original)); EXPECT_EQ(1U, moved.count(MoveOnlyInt(1))); EXPECT_EQ(1U, moved.count(MoveOnlyInt(2))); EXPECT_EQ(1U, moved.count(MoveOnlyInt(3))); EXPECT_EQ(1U, moved.count(MoveOnlyInt(4))); } TEST(FlatMap, VectorConstructor) { using IntPair = std::pair; using IntMap = flat_map; std::vector vect{{1, 1}, {1, 2}, {2, 1}}; IntMap map(std::move(vect)); EXPECT_THAT(map, ElementsAre(IntPair(1, 1), IntPair(2, 1))); } TEST(FlatMap, InitializerListConstructor) { flat_map cont( {{1, 1}, {2, 2}, {3, 3}, {4, 4}, {5, 5}, {1, 2}, {10, 10}, {8, 8}}); EXPECT_THAT(cont, ElementsAre(std::make_pair(1, 1), std::make_pair(2, 2), std::make_pair(3, 3), std::make_pair(4, 4), std::make_pair(5, 5), std::make_pair(8, 8), std::make_pair(10, 10))); } TEST(FlatMap, SortedRangeConstructor) { using PairType = std::pair; using MapType = flat_map; MapType::value_type input_vals[] = {{1, {1}}, {2, {1}}, {3, {1}}}; MapType map(sorted_unique, std::begin(input_vals), std::end(input_vals)); EXPECT_THAT( map, ElementsAre(PairType(1, {1}), PairType(2, {1}), PairType(3, {1}))); } TEST(FlatMap, SortedCopyFromVectorConstructor) { using PairType = std::pair; using MapType = flat_map; std::vector vect{{1, {1}}, {2, {1}}}; MapType map(sorted_unique, vect); EXPECT_THAT(map, ElementsAre(PairType(1, {1}), PairType(2, {1}))); } TEST(FlatMap, SortedMoveFromVectorConstructor) { using PairType = std::pair; using MapType = flat_map; std::vector vect{{1, {1}}, {2, {1}}}; MapType map(sorted_unique, std::move(vect)); EXPECT_THAT(map, ElementsAre(PairType(1, {1}), PairType(2, {1}))); } TEST(FlatMap, SortedInitializerListConstructor) { using PairType = std::pair; flat_map map( sorted_unique, {{1, {1}}, {2, {2}}, {3, {3}}, {4, {4}}, {5, {5}}, {8, {8}}, {10, {10}}}); EXPECT_THAT(map, ElementsAre(PairType(1, {1}), PairType(2, {2}), PairType(3, {3}), PairType(4, {4}), PairType(5, {5}), PairType(8, {8}), PairType(10, {10}))); } TEST(FlatMap, InitializerListAssignment) { flat_map cont; cont = {{1, 1}, {2, 2}}; EXPECT_THAT(cont, ElementsAre(std::make_pair(1, 1), std::make_pair(2, 2))); } TEST(FlatMap, InsertFindSize) { flat_map s; s.insert(std::make_pair(1, 1)); s.insert(std::make_pair(1, 1)); s.insert(std::make_pair(2, 2)); EXPECT_EQ(2u, s.size()); EXPECT_EQ(std::make_pair(1, 1), *s.find(1)); EXPECT_EQ(std::make_pair(2, 2), *s.find(2)); EXPECT_EQ(s.end(), s.find(7)); } TEST(FlatMap, CopySwap) { flat_map original; original.insert({1, 1}); original.insert({2, 2}); EXPECT_THAT(original, ElementsAre(std::make_pair(1, 1), std::make_pair(2, 2))); flat_map copy(original); EXPECT_THAT(copy, ElementsAre(std::make_pair(1, 1), std::make_pair(2, 2))); copy.erase(copy.begin()); copy.insert({10, 10}); EXPECT_THAT(copy, ElementsAre(std::make_pair(2, 2), std::make_pair(10, 10))); original.swap(copy); EXPECT_THAT(original, ElementsAre(std::make_pair(2, 2), std::make_pair(10, 10))); EXPECT_THAT(copy, ElementsAre(std::make_pair(1, 1), std::make_pair(2, 2))); } // operator[](const Key&) TEST(FlatMap, SubscriptConstKey) { flat_map m; // Default construct elements that don't exist yet. int& s = m["a"]; EXPECT_EQ(0, s); EXPECT_EQ(1u, m.size()); // The returned mapped reference should refer into the map. s = 22; EXPECT_EQ(22, m["a"]); // Overwrite existing elements. m["a"] = 44; EXPECT_EQ(44, m["a"]); } // operator[](Key&&) TEST(FlatMap, SubscriptMoveOnlyKey) { flat_map m; // Default construct elements that don't exist yet. int& s = m[MoveOnlyInt(1)]; EXPECT_EQ(0, s); EXPECT_EQ(1u, m.size()); // The returned mapped reference should refer into the map. s = 22; EXPECT_EQ(22, m[MoveOnlyInt(1)]); // Overwrite existing elements. m[MoveOnlyInt(1)] = 44; EXPECT_EQ(44, m[MoveOnlyInt(1)]); } // Mapped& at(const Key&) // const Mapped& at(const Key&) const TEST(FlatMap, AtFunction) { flat_map m = {{1, "a"}, {2, "b"}}; // Basic Usage. EXPECT_EQ("a", m.at(1)); EXPECT_EQ("b", m.at(2)); // Const reference works. const std::string& const_ref = std::as_const(m).at(1); EXPECT_EQ("a", const_ref); // Reference works, can operate on the string. m.at(1)[0] = 'x'; EXPECT_EQ("x", m.at(1)); // Out-of-bounds will CHECK. EXPECT_DEATH_IF_SUPPORTED(m.at(-1), ""); EXPECT_DEATH_IF_SUPPORTED({ m.at(-1)[0] = 'z'; }, ""); // Heterogeneous look-up works. flat_map m2 = {{"a", 1}, {"b", 2}}; EXPECT_EQ(1, m2.at(absl::string_view("a"))); EXPECT_EQ(2, std::as_const(m2).at(absl::string_view("b"))); } // insert_or_assign(K&&, M&&) TEST(FlatMap, InsertOrAssignMoveOnlyKey) { flat_map m; // Initial insertion should return an iterator to the element and set the // second pair member to `true`. The inserted key and value should be moved // from. MoveOnlyInt key(1); MoveOnlyInt val(22); auto result = m.insert_or_assign(std::move(key), std::move(val)); EXPECT_EQ(1, result.first->first.data()); EXPECT_EQ(22, result.first->second.data()); EXPECT_TRUE(result.second); EXPECT_EQ(1u, m.size()); EXPECT_EQ(0, key.data()); // moved from EXPECT_EQ(0, val.data()); // moved from // Second call with same key should result in an assignment, overwriting the // old value. Assignment should be indicated by setting the second pair member // to `false`. Only the inserted value should be moved from, the key should be // left intact. key = MoveOnlyInt(1); val = MoveOnlyInt(44); result = m.insert_or_assign(std::move(key), std::move(val)); EXPECT_EQ(1, result.first->first.data()); EXPECT_EQ(44, result.first->second.data()); EXPECT_FALSE(result.second); EXPECT_EQ(1u, m.size()); EXPECT_EQ(1, key.data()); // not moved from EXPECT_EQ(0, val.data()); // moved from // Check that random insertion results in sorted range. flat_map map; for (int i : {3, 1, 5, 6, 8, 7, 0, 9, 4, 2}) { map.insert_or_assign(MoveOnlyInt(i), i); EXPECT_TRUE(absl::c_is_sorted(map)); } } // insert_or_assign(const_iterator hint, K&&, M&&) TEST(FlatMap, InsertOrAssignMoveOnlyKeyWithHint) { flat_map m; // Initial insertion should return an iterator to the element. The inserted // key and value should be moved from. MoveOnlyInt key(1); MoveOnlyInt val(22); auto result = m.insert_or_assign(m.end(), std::move(key), std::move(val)); EXPECT_EQ(1, result->first.data()); EXPECT_EQ(22, result->second.data()); EXPECT_EQ(1u, m.size()); EXPECT_EQ(0, key.data()); // moved from EXPECT_EQ(0, val.data()); // moved from // Second call with same key should result in an assignment, overwriting the // old value. Only the inserted value should be moved from, the key should be // left intact. key = MoveOnlyInt(1); val = MoveOnlyInt(44); result = m.insert_or_assign(m.end(), std::move(key), std::move(val)); EXPECT_EQ(1, result->first.data()); EXPECT_EQ(44, result->second.data()); EXPECT_EQ(1u, m.size()); EXPECT_EQ(1, key.data()); // not moved from EXPECT_EQ(0, val.data()); // moved from // Check that random insertion results in sorted range. flat_map map; for (int i : {3, 1, 5, 6, 8, 7, 0, 9, 4, 2}) { map.insert_or_assign(map.end(), MoveOnlyInt(i), i); EXPECT_TRUE(absl::c_is_sorted(map)); } } // try_emplace(K&&, Args&&...) TEST(FlatMap, TryEmplaceMoveOnlyKey) { flat_map> m; // Trying to emplace into an empty map should succeed. Insertion should return // an iterator to the element and set the second pair member to `true`. The // inserted key and value should be moved from. MoveOnlyInt key(1); MoveOnlyInt val1(22); MoveOnlyInt val2(44); // Test piecewise construction of mapped_type. auto result = m.try_emplace(std::move(key), std::move(val1), std::move(val2)); EXPECT_EQ(1, result.first->first.data()); EXPECT_EQ(22, result.first->second.first.data()); EXPECT_EQ(44, result.first->second.second.data()); EXPECT_TRUE(result.second); EXPECT_EQ(1u, m.size()); EXPECT_EQ(0, key.data()); // moved from EXPECT_EQ(0, val1.data()); // moved from EXPECT_EQ(0, val2.data()); // moved from // Second call with same key should result in a no-op, returning an iterator // to the existing element and returning false as the second pair member. // Key and values that were attempted to be inserted should be left intact. key = MoveOnlyInt(1); auto paired_val = std::make_pair(MoveOnlyInt(33), MoveOnlyInt(55)); // Test construction of mapped_type from pair. result = m.try_emplace(std::move(key), std::move(paired_val)); EXPECT_EQ(1, result.first->first.data()); EXPECT_EQ(22, result.first->second.first.data()); EXPECT_EQ(44, result.first->second.second.data()); EXPECT_FALSE(result.second); EXPECT_EQ(1u, m.size()); EXPECT_EQ(1, key.data()); // not moved from EXPECT_EQ(33, paired_val.first.data()); // not moved from EXPECT_EQ(55, paired_val.second.data()); // not moved from // Check that random insertion results in sorted range. flat_map map; for (int i : {3, 1, 5, 6, 8, 7, 0, 9, 4, 2}) { map.try_emplace(MoveOnlyInt(i), i); EXPECT_TRUE(absl::c_is_sorted(map)); } } // try_emplace(const_iterator hint, K&&, Args&&...) TEST(FlatMap, TryEmplaceMoveOnlyKeyWithHint) { flat_map> m; // Trying to emplace into an empty map should succeed. Insertion should return // an iterator to the element. The inserted key and value should be moved // from. MoveOnlyInt key(1); MoveOnlyInt val1(22); MoveOnlyInt val2(44); // Test piecewise construction of mapped_type. auto result = m.try_emplace(m.end(), std::move(key), std::move(val1), std::move(val2)); EXPECT_EQ(1, result->first.data()); EXPECT_EQ(22, result->second.first.data()); EXPECT_EQ(44, result->second.second.data()); EXPECT_EQ(1u, m.size()); EXPECT_EQ(0, key.data()); // moved from EXPECT_EQ(0, val1.data()); // moved from EXPECT_EQ(0, val2.data()); // moved from // Second call with same key should result in a no-op, returning an iterator // to the existing element. Key and values that were attempted to be inserted // should be left intact. key = MoveOnlyInt(1); val1 = MoveOnlyInt(33); val2 = MoveOnlyInt(55); auto paired_val = std::make_pair(MoveOnlyInt(33), MoveOnlyInt(55)); // Test construction of mapped_type from pair. result = m.try_emplace(m.end(), std::move(key), std::move(paired_val)); EXPECT_EQ(1, result->first.data()); EXPECT_EQ(22, result->second.first.data()); EXPECT_EQ(44, result->second.second.data()); EXPECT_EQ(1u, m.size()); EXPECT_EQ(1, key.data()); // not moved from EXPECT_EQ(33, paired_val.first.data()); // not moved from EXPECT_EQ(55, paired_val.second.data()); // not moved from // Check that random insertion results in sorted range. flat_map map; for (int i : {3, 1, 5, 6, 8, 7, 0, 9, 4, 2}) { map.try_emplace(map.end(), MoveOnlyInt(i), i); EXPECT_TRUE(absl::c_is_sorted(map)); } } TEST(FlatMap, UsingTransparentCompare) { using ExplicitInt = MoveOnlyInt; flat_map m; const auto& m1 = m; int x = 0; // Check if we can use lookup functions without converting to key_type. // Correctness is checked in flat_tree tests. m.count(x); m1.count(x); m.find(x); m1.find(x); m.equal_range(x); m1.equal_range(x); m.lower_bound(x); m1.lower_bound(x); m.upper_bound(x); m1.upper_bound(x); m.erase(x); // Check if we broke overload resolution. m.emplace(ExplicitInt(0), 0); m.emplace(ExplicitInt(1), 0); m.erase(m.begin()); m.erase(m.cbegin()); } TEST(FlatMap, SupportsEraseIf) { flat_map m; m.insert(std::make_pair(MoveOnlyInt(1), MoveOnlyInt(1))); m.insert(std::make_pair(MoveOnlyInt(2), MoveOnlyInt(2))); m.insert(std::make_pair(MoveOnlyInt(3), MoveOnlyInt(3))); m.insert(std::make_pair(MoveOnlyInt(4), MoveOnlyInt(4))); m.insert(std::make_pair(MoveOnlyInt(5), MoveOnlyInt(5))); EraseIf(m, [to_be_removed = MoveOnlyInt(2)]( const std::pair& e) { return e.first == to_be_removed; }); EXPECT_EQ(m.size(), 4u); ASSERT_TRUE(m.find(MoveOnlyInt(1)) != m.end()); ASSERT_FALSE(m.find(MoveOnlyInt(2)) != m.end()); ASSERT_TRUE(m.find(MoveOnlyInt(3)) != m.end()); ASSERT_TRUE(m.find(MoveOnlyInt(4)) != m.end()); ASSERT_TRUE(m.find(MoveOnlyInt(5)) != m.end()); } } // namespace } // namespace webrtc