// Copyright 2012 The Chromium Authors // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. #include "base/values.h" #include #include #include #include #include #include #include #include #include #include #include "base/bits.h" #include "base/containers/adapters.h" #include "base/containers/contains.h" #include "base/strings/string_piece.h" #include "base/strings/utf_string_conversions.h" #include "base/test/gtest_util.h" #include "build/build_config.h" #include "testing/gmock/include/gmock/gmock.h" #include "testing/gtest/include/gtest/gtest.h" #if BUILDFLAG(ENABLE_BASE_TRACING) #include #include "third_party/perfetto/include/perfetto/test/traced_value_test_support.h" // no-presubmit-check nogncheck #endif // BUILDFLAG(ENABLE_BASE_TRACING) namespace base { #ifdef NDEBUG // `Value` should have a (relatively) small size to avoid creating excess // overhead, e.g. for lists of values that are all ints. // // This test is limited to NDEBUG builds, since some containers may require // extra storage for supporting debug checks for things like iterators. TEST(ValuesTest, SizeOfValue) { #if defined(__GLIBCXX__) // libstdc++ std::string takes already 4 machine words, so the absl::variant // takes 5 constexpr size_t kExpectedSize = 5 * sizeof(void*); #else // !defined(__GLIBCXX__) // libc++'s std::string and std::vector both take 3 machine words. An // additional word is used by absl::variant for the type index. constexpr size_t kExpectedSize = 4 * sizeof(void*); #endif // defined(__GLIBCXX__) // Use std::integral_constant so the compiler error message includes the // evaluated size. In future versions of clang, it should be possible to // simplify this to an equality comparison (i.e. newer clangs print out // "comparison reduces to '(1 == 2)'"). static_assert(std::is_same_v, std::integral_constant>, "base::Value has an unexpected size!"); } #endif TEST(ValuesTest, TestNothrow) { static_assert(std::is_nothrow_move_constructible_v, "IsNothrowMoveConstructible"); static_assert(std::is_nothrow_default_constructible_v, "IsNothrowDefaultConstructible"); static_assert(std::is_nothrow_constructible_v, "IsNothrowMoveConstructibleFromString"); static_assert(std::is_nothrow_constructible_v, "IsNothrowMoveConstructibleFromBlob"); static_assert(std::is_nothrow_move_assignable_v, "IsNothrowMoveAssignable"); } TEST(ValuesTest, EmptyValue) { Value value; EXPECT_EQ(Value::Type::NONE, value.type()); EXPECT_EQ(std::nullopt, value.GetIfBool()); EXPECT_EQ(std::nullopt, value.GetIfInt()); EXPECT_EQ(std::nullopt, value.GetIfDouble()); EXPECT_EQ(nullptr, value.GetIfString()); EXPECT_EQ(nullptr, value.GetIfBlob()); } // Group of tests for the value constructors. TEST(ValuesTest, ConstructBool) { Value true_value(true); EXPECT_EQ(Value::Type::BOOLEAN, true_value.type()); EXPECT_THAT(true_value.GetIfBool(), testing::Optional(true)); EXPECT_TRUE(true_value.GetBool()); Value false_value(false); EXPECT_EQ(Value::Type::BOOLEAN, false_value.type()); EXPECT_THAT(false_value.GetIfBool(), testing::Optional(false)); EXPECT_FALSE(false_value.GetBool()); } TEST(ValuesTest, ConstructFromPtrs) { static_assert(!std::is_constructible_v, ""); static_assert(!std::is_constructible_v, ""); static_assert(!std::is_constructible_v, ""); static_assert(!std::is_constructible_v, ""); static_assert(std::is_constructible_v, ""); static_assert(std::is_constructible_v, ""); static_assert(std::is_constructible_v, ""); static_assert(std::is_constructible_v, ""); } TEST(ValuesTest, ConstructInt) { Value value(-37); EXPECT_EQ(Value::Type::INTEGER, value.type()); EXPECT_THAT(value.GetIfInt(), testing::Optional(-37)); EXPECT_EQ(-37, value.GetInt()); EXPECT_THAT(value.GetIfDouble(), testing::Optional(-37.0)); EXPECT_EQ(-37.0, value.GetDouble()); } TEST(ValuesTest, ConstructDouble) { Value value(-4.655); EXPECT_EQ(Value::Type::DOUBLE, value.type()); EXPECT_THAT(value.GetIfDouble(), testing::Optional(-4.655)); EXPECT_EQ(-4.655, value.GetDouble()); } TEST(ValuesTest, ConstructStringFromConstCharPtr) { const char* str = "foobar"; Value value(str); EXPECT_EQ(Value::Type::STRING, value.type()); EXPECT_THAT(value.GetIfString(), testing::Pointee(std::string("foobar"))); EXPECT_EQ("foobar", value.GetString()); } TEST(ValuesTest, ConstructStringFromStringPiece) { std::string str = "foobar"; Value value{StringPiece(str)}; EXPECT_EQ(Value::Type::STRING, value.type()); EXPECT_THAT(value.GetIfString(), testing::Pointee(std::string("foobar"))); EXPECT_EQ("foobar", value.GetString()); } TEST(ValuesTest, ConstructStringFromStdStringRRef) { std::string str = "foobar"; Value value(std::move(str)); EXPECT_EQ(Value::Type::STRING, value.type()); EXPECT_THAT(value.GetIfString(), testing::Pointee(std::string("foobar"))); EXPECT_EQ("foobar", value.GetString()); } TEST(ValuesTest, ConstructStringFromConstChar16Ptr) { std::u16string str = u"foobar"; Value value(str.c_str()); EXPECT_EQ(Value::Type::STRING, value.type()); EXPECT_THAT(value.GetIfString(), testing::Pointee(std::string("foobar"))); EXPECT_EQ("foobar", value.GetString()); } TEST(ValuesTest, ConstructStringFromStringPiece16) { std::u16string str = u"foobar"; Value value{StringPiece16(str)}; EXPECT_EQ(Value::Type::STRING, value.type()); EXPECT_THAT(value.GetIfString(), testing::Pointee(std::string("foobar"))); EXPECT_EQ("foobar", value.GetString()); } TEST(ValuesTest, ConstructBinary) { Value::BlobStorage blob = {0xF, 0x0, 0x0, 0xB, 0xA, 0x2}; Value value(blob); EXPECT_EQ(Value::Type::BINARY, value.type()); EXPECT_THAT(value.GetIfBlob(), testing::Pointee(blob)); EXPECT_EQ(blob, value.GetBlob()); } TEST(ValuesTest, ConstructDict) { Value::Dict value; EXPECT_EQ(Value::Type::DICT, Value(std::move(value)).type()); } TEST(ValuesTest, ConstructDictFromValueDict) { Value::Dict dict; dict.Set("foo", "bar"); { Value value(dict.Clone()); EXPECT_EQ(Value::Type::DICT, value.type()); EXPECT_TRUE(value.GetIfDict()); EXPECT_TRUE(value.GetDict().FindString("foo")); EXPECT_EQ("bar", *value.GetDict().FindString("foo")); } dict.Set("foo", "baz"); { Value value(std::move(dict)); EXPECT_EQ(Value::Type::DICT, value.type()); EXPECT_TRUE(value.GetIfDict()); EXPECT_TRUE(value.GetDict().FindString("foo")); EXPECT_EQ("baz", *value.GetDict().FindString("foo")); } } TEST(ValuesTest, ConstructList) { Value value(Value::List{}); EXPECT_EQ(Value::Type::LIST, value.type()); } TEST(ValuesTest, UseTestingEachOnValueList) { Value::List list; list.Append(true); list.Append(true); // This will only work if `Value::List::value_type` is defined. EXPECT_THAT(list, testing::Each(testing::ResultOf( [](const Value& value) { return value.GetBool(); }, testing::Eq(true)))); } TEST(ValuesTest, ConstructListFromValueList) { Value::List list; list.Append("foo"); { Value value(list.Clone()); EXPECT_EQ(Value::Type::LIST, value.type()); EXPECT_EQ(1u, value.GetList().size()); EXPECT_EQ(Value::Type::STRING, value.GetList()[0].type()); EXPECT_EQ("foo", value.GetList()[0].GetString()); } list.back() = base::Value("bar"); { Value value(std::move(list)); EXPECT_EQ(Value::Type::LIST, value.type()); EXPECT_EQ(1u, value.GetList().size()); EXPECT_EQ(Value::Type::STRING, value.GetList()[0].type()); EXPECT_EQ("bar", value.GetList()[0].GetString()); } } TEST(ValuesTest, HardenTests) { Value value; ASSERT_EQ(value.type(), Value::Type::NONE); EXPECT_DEATH_IF_SUPPORTED(value.GetBool(), ""); EXPECT_DEATH_IF_SUPPORTED(value.GetInt(), ""); EXPECT_DEATH_IF_SUPPORTED(value.GetDouble(), ""); EXPECT_DEATH_IF_SUPPORTED(value.GetString(), ""); EXPECT_DEATH_IF_SUPPORTED(value.GetBlob(), ""); } // Group of tests for the copy constructors and copy-assigmnent. For equality // checks comparisons of the interesting fields are done instead of relying on // Equals being correct. TEST(ValuesTest, CopyBool) { Value true_value(true); Value copied_true_value(true_value.Clone()); EXPECT_EQ(true_value.type(), copied_true_value.type()); EXPECT_EQ(true_value.GetBool(), copied_true_value.GetBool()); Value false_value(false); Value copied_false_value(false_value.Clone()); EXPECT_EQ(false_value.type(), copied_false_value.type()); EXPECT_EQ(false_value.GetBool(), copied_false_value.GetBool()); Value blank; blank = true_value.Clone(); EXPECT_EQ(true_value.type(), blank.type()); EXPECT_EQ(true_value.GetBool(), blank.GetBool()); blank = false_value.Clone(); EXPECT_EQ(false_value.type(), blank.type()); EXPECT_EQ(false_value.GetBool(), blank.GetBool()); } TEST(ValuesTest, CopyInt) { Value value(74); Value copied_value(value.Clone()); EXPECT_EQ(value.type(), copied_value.type()); EXPECT_EQ(value.GetInt(), copied_value.GetInt()); Value blank; blank = value.Clone(); EXPECT_EQ(value.type(), blank.type()); EXPECT_EQ(value.GetInt(), blank.GetInt()); } TEST(ValuesTest, CopyDouble) { Value value(74.896); Value copied_value(value.Clone()); EXPECT_EQ(value.type(), copied_value.type()); EXPECT_EQ(value.GetDouble(), copied_value.GetDouble()); Value blank; blank = value.Clone(); EXPECT_EQ(value.type(), blank.type()); EXPECT_EQ(value.GetDouble(), blank.GetDouble()); } TEST(ValuesTest, CopyString) { Value value("foobar"); Value copied_value(value.Clone()); EXPECT_EQ(value.type(), copied_value.type()); EXPECT_EQ(value.GetString(), copied_value.GetString()); Value blank; blank = value.Clone(); EXPECT_EQ(value.type(), blank.type()); EXPECT_EQ(value.GetString(), blank.GetString()); } TEST(ValuesTest, CopyBinary) { Value value(Value::BlobStorage({0xF, 0x0, 0x0, 0xB, 0xA, 0x2})); Value copied_value(value.Clone()); EXPECT_EQ(value.type(), copied_value.type()); EXPECT_EQ(value.GetBlob(), copied_value.GetBlob()); Value blank; blank = value.Clone(); EXPECT_EQ(value.type(), blank.type()); EXPECT_EQ(value.GetBlob(), blank.GetBlob()); } TEST(ValuesTest, CopyDictionary) { Value::Dict dict; dict.Set("Int", 123); Value value(std::move(dict)); Value copied_value(value.Clone()); EXPECT_EQ(value, copied_value); Value blank; blank = value.Clone(); EXPECT_EQ(value, blank); } TEST(ValuesTest, CopyList) { Value::List list; list.Append(123); Value value(std::move(list)); Value copied_value(value.Clone()); EXPECT_EQ(value, copied_value); Value blank; blank = value.Clone(); EXPECT_EQ(value, blank); } // Group of tests for the move constructors and move-assigmnent. TEST(ValuesTest, MoveBool) { Value true_value(true); Value moved_true_value(std::move(true_value)); EXPECT_EQ(Value::Type::BOOLEAN, moved_true_value.type()); EXPECT_TRUE(moved_true_value.GetBool()); Value false_value(false); Value moved_false_value(std::move(false_value)); EXPECT_EQ(Value::Type::BOOLEAN, moved_false_value.type()); EXPECT_FALSE(moved_false_value.GetBool()); Value blank; blank = Value(true); EXPECT_EQ(Value::Type::BOOLEAN, blank.type()); EXPECT_TRUE(blank.GetBool()); blank = Value(false); EXPECT_EQ(Value::Type::BOOLEAN, blank.type()); EXPECT_FALSE(blank.GetBool()); } TEST(ValuesTest, MoveInt) { Value value(74); Value moved_value(std::move(value)); EXPECT_EQ(Value::Type::INTEGER, moved_value.type()); EXPECT_EQ(74, moved_value.GetInt()); Value blank; blank = Value(47); EXPECT_EQ(Value::Type::INTEGER, blank.type()); EXPECT_EQ(47, blank.GetInt()); } TEST(ValuesTest, MoveDouble) { Value value(74.896); Value moved_value(std::move(value)); EXPECT_EQ(Value::Type::DOUBLE, moved_value.type()); EXPECT_EQ(74.896, moved_value.GetDouble()); Value blank; blank = Value(654.38); EXPECT_EQ(Value::Type::DOUBLE, blank.type()); EXPECT_EQ(654.38, blank.GetDouble()); } TEST(ValuesTest, MoveString) { Value value("foobar"); Value moved_value(std::move(value)); EXPECT_EQ(Value::Type::STRING, moved_value.type()); EXPECT_EQ("foobar", moved_value.GetString()); Value blank; blank = Value("foobar"); EXPECT_EQ(Value::Type::STRING, blank.type()); EXPECT_EQ("foobar", blank.GetString()); } TEST(ValuesTest, MoveBinary) { const Value::BlobStorage buffer = {0xF, 0x0, 0x0, 0xB, 0xA, 0x2}; Value value(buffer); Value moved_value(std::move(value)); EXPECT_EQ(Value::Type::BINARY, moved_value.type()); EXPECT_EQ(buffer, moved_value.GetBlob()); Value blank; blank = Value(buffer); EXPECT_EQ(Value::Type::BINARY, blank.type()); EXPECT_EQ(buffer, blank.GetBlob()); } TEST(ValuesTest, MoveConstructDictionary) { Value::Dict dict; dict.Set("Int", 123); Value value(std::move(dict)); Value moved_value(std::move(value)); EXPECT_EQ(Value::Type::DICT, moved_value.type()); EXPECT_EQ(123, moved_value.GetDict().Find("Int")->GetInt()); } TEST(ValuesTest, MoveAssignDictionary) { Value::Dict dict; dict.Set("Int", 123); Value blank; blank = Value(std::move(dict)); EXPECT_EQ(Value::Type::DICT, blank.type()); EXPECT_EQ(123, blank.GetDict().Find("Int")->GetInt()); } TEST(ValuesTest, ConstructDictWithIterators) { std::vector> values; values.emplace_back(std::make_pair("Int", 123)); Value blank; blank = Value(Value::Dict(std::make_move_iterator(values.begin()), std::make_move_iterator(values.end()))); EXPECT_EQ(Value::Type::DICT, blank.type()); EXPECT_EQ(123, blank.GetDict().Find("Int")->GetInt()); } TEST(ValuesTest, MoveList) { Value::List list; list.Append(123); Value value(list.Clone()); Value moved_value(std::move(value)); EXPECT_EQ(Value::Type::LIST, moved_value.type()); EXPECT_EQ(123, moved_value.GetList().back().GetInt()); Value blank; blank = Value(std::move(list)); EXPECT_EQ(Value::Type::LIST, blank.type()); EXPECT_EQ(123, blank.GetList().back().GetInt()); } TEST(ValuesTest, Append) { Value::List list; list.Append(true); EXPECT_TRUE(list.back().is_bool()); list.Append(123); EXPECT_TRUE(list.back().is_int()); list.Append(3.14); EXPECT_TRUE(list.back().is_double()); std::string str = "foo"; list.Append(str.c_str()); EXPECT_TRUE(list.back().is_string()); list.Append(StringPiece(str)); EXPECT_TRUE(list.back().is_string()); list.Append(std::move(str)); EXPECT_TRUE(list.back().is_string()); std::u16string str16 = u"bar"; list.Append(str16.c_str()); EXPECT_TRUE(list.back().is_string()); list.Append(base::StringPiece16(str16)); EXPECT_TRUE(list.back().is_string()); list.Append(Value()); EXPECT_TRUE(list.back().is_none()); list.Append(Value::Dict()); EXPECT_TRUE(list.back().is_dict()); list.Append(Value::List()); EXPECT_TRUE(list.back().is_list()); } TEST(ValuesTest, ListInsert) { Value::List list; const Value::List& const_list = list; auto iter = list.Insert(list.end(), Value(true)); EXPECT_TRUE(list.begin() == iter); EXPECT_EQ(*iter, true); iter = list.Insert(const_list.begin(), Value(123)); EXPECT_TRUE(const_list.begin() == iter); EXPECT_EQ(*iter, 123); iter = list.Insert(list.begin() + 1, Value("Hello world!")); EXPECT_TRUE(list.begin() + 1 == iter); EXPECT_EQ(*iter, "Hello world!"); } TEST(ValuesTest, ListResize) { auto list = base::Value::List().Append("Hello world!"); EXPECT_EQ(list.size(), 1U); list.resize(2); // Adds an empty entry to the back to match the size. EXPECT_EQ(list.size(), 2U); EXPECT_TRUE(list[0].is_string()); EXPECT_TRUE(list[1].is_none()); list.resize(1); // Shrinks the list and kicks the new entry out. EXPECT_EQ(list.size(), 1U); EXPECT_TRUE(list[0].is_string()); list.resize(0); // Removes the remaining entry too. EXPECT_EQ(list.size(), 0U); } TEST(ValuesTest, ReverseIter) { Value::List list; const Value::List& const_list = list; list.Append(Value(true)); list.Append(Value(123)); list.Append(Value("Hello world!")); auto iter = list.rbegin(); EXPECT_TRUE(const_list.rbegin() == iter); EXPECT_EQ(*iter, "Hello world!"); ++iter; EXPECT_EQ(*iter, 123); ++iter; EXPECT_EQ(*iter, true); ++iter; EXPECT_TRUE(list.rend() == iter); EXPECT_TRUE(const_list.rend() == iter); } // Test all three behaviors of EnsureDict() (Create a new dict where no // matchining values exist, return an existing dict, create a dict overwriting // a value of another type). TEST(ValuesTest, DictEnsureDict) { Value::Dict root; // This call should create a new nested dictionary. Value::Dict* foo_dict = root.EnsureDict("foo"); EXPECT_TRUE(foo_dict->empty()); foo_dict->Set("a", "b"); // This call should retrieve the dictionary created above, rather than // creating a new one. std::string* a_string = root.EnsureDict("foo")->FindString("a"); ASSERT_NE(nullptr, a_string); EXPECT_EQ(*a_string, "b"); // Use EnsureDict() to overwrite an existing non-dictionary value. root.Set("bar", 3); Value::Dict* bar_dict = root.EnsureDict("bar"); EXPECT_TRUE(bar_dict->empty()); bar_dict->Set("b", "c"); // Test that the above call created a "bar" entry. bar_dict = root.FindDict("bar"); ASSERT_NE(nullptr, bar_dict); std::string* b_string = bar_dict->FindString("b"); ASSERT_NE(nullptr, b_string); EXPECT_EQ(*b_string, "c"); } // Test all three behaviors of EnsureList() (Create a new list where no // matchining value exists, return an existing list, create a list overwriting // a value of another type). TEST(ValuesTest, DictEnsureList) { Value::Dict root; // This call should create a new list. Value::List* foo_list = root.EnsureList("foo"); EXPECT_TRUE(foo_list->empty()); foo_list->Append("a"); // This call should retrieve the list created above, rather than creating a // new one. foo_list = root.EnsureList("foo"); ASSERT_EQ(1u, foo_list->size()); EXPECT_EQ((*foo_list)[0], Value("a")); // Use EnsureList() to overwrite an existing non-list value. root.Set("bar", 3); Value::List* bar_list = root.EnsureList("bar"); EXPECT_TRUE(bar_list->empty()); bar_list->Append("b"); // Test that the above call created a "bar" entry. bar_list = root.FindList("bar"); ASSERT_NE(nullptr, bar_list); ASSERT_EQ(1u, bar_list->size()); EXPECT_EQ((*bar_list)[0], Value("b")); } // TODO(dcheng): Add more tests directly exercising the updated dictionary and // list APIs. For now, most of the updated APIs are tested indirectly via the // legacy APIs that are largely backed by the updated APIs. TEST(ValuesTest, DictFindByDottedPath) { Value::Dict dict; EXPECT_EQ(nullptr, dict.FindByDottedPath("a.b.c")); Value::Dict& a_dict = dict.Set("a", Value::Dict())->GetDict(); EXPECT_EQ(nullptr, dict.FindByDottedPath("a.b.c")); Value::Dict& b_dict = a_dict.Set("b", Value::Dict())->GetDict(); EXPECT_EQ(nullptr, dict.FindByDottedPath("a.b.c")); b_dict.Set("c", true); const Value* value = dict.FindByDottedPath("a.b.c"); ASSERT_NE(nullptr, value); EXPECT_TRUE(value->GetBool()); } TEST(ValuesTest, DictSetByDottedPath) { Value::Dict dict; Value* c = dict.SetByDottedPath("a.b.c", Value()); ASSERT_TRUE(c); Value::Dict* a = dict.FindDict("a"); ASSERT_TRUE(a); EXPECT_EQ(1U, a->size()); Value::Dict* b = a->FindDict("b"); ASSERT_TRUE(b); EXPECT_EQ(1U, b->size()); EXPECT_EQ(c, b->Find("c")); } TEST(ValuesTest, RvalueDictSetByDottedPath) { Value::Dict dict = Value::Dict() .SetByDottedPath("nested.dictionary.null", Value()) .SetByDottedPath("nested.dictionary.bool", false) .SetByDottedPath("nested.dictionary.int", 42) .SetByDottedPath("nested.dictionary.double", 1.2) .SetByDottedPath("nested.dictionary.string", "value") .SetByDottedPath("nested.dictionary.u16-string", u"u16-value") .SetByDottedPath("nested.dictionary.std-string", std::string("std-value")) .SetByDottedPath("nested.dictionary.blob", Value::BlobStorage({1, 2})) .SetByDottedPath("nested.dictionary.list", Value::List().Append("value in list")) .SetByDottedPath("nested.dictionary.dict", Value::Dict().Set("key", "value")); Value::Dict expected = Value::Dict() // .Set("nested", base::Value::Dict() // .Set("dictionary", base::Value::Dict() .Set("null", Value()) .Set("bool", false) .Set("int", 42) .Set("double", 1.2) .Set("string", "value") .Set("u16-string", u"u16-value") .Set("std-string", std::string("std-value")) .Set("blob", Value::BlobStorage({1, 2})) .Set("list", Value::List().Append("value in list")) .Set("dict", Value::Dict().Set("key", "value")))); EXPECT_EQ(dict, expected); } TEST(ValuesTest, DictSetWithDottedKey) { Value::Dict dict; Value* abc = dict.Set("a.b.c", Value()); ASSERT_TRUE(abc); EXPECT_FALSE(dict.FindByDottedPath("a")); EXPECT_FALSE(dict.FindByDottedPath("a.b")); EXPECT_FALSE(dict.FindByDottedPath("a.b.c")); EXPECT_EQ(abc, dict.Find("a.b.c")); } TEST(ValuesTest, ListFront) { Value::List list; const Value::List& const_list = list; list.Append(1); list.Append(2); list.Append(3); EXPECT_EQ(Value(1), list.front()); EXPECT_EQ(Value(1), const_list.front()); } TEST(ValuesTest, ListFrontWhenEmpty) { Value::List list; const Value::List& const_list = list; EXPECT_CHECK_DEATH(list.front()); EXPECT_CHECK_DEATH(const_list.front()); } TEST(ValuesTest, ListBack) { Value::List list; const Value::List& const_list = list; list.Append(1); list.Append(2); list.Append(3); EXPECT_EQ(Value(3), list.back()); EXPECT_EQ(Value(3), const_list.back()); } TEST(ValuesTest, ListBackWhenEmpty) { Value::List list; const Value::List& const_list = list; EXPECT_CHECK_DEATH(list.back()); EXPECT_CHECK_DEATH(const_list.back()); } TEST(ValuesTest, ListErase) { Value::List list; list.Append(1); list.Append(2); list.Append(3); auto next_it = list.erase(list.begin() + 1); ASSERT_EQ(2u, list.size()); EXPECT_EQ(list[0], Value(1)); EXPECT_EQ(list[1], Value(3)); EXPECT_EQ(*next_it, Value(3)); EXPECT_EQ(next_it + 1, list.end()); } TEST(ValuesTest, ListEraseRange) { Value::List list; list.Append(1); list.Append(2); list.Append(3); list.Append(4); auto next_it = list.erase(list.begin() + 1, list.begin() + 3); ASSERT_EQ(2u, list.size()); EXPECT_EQ(list[0], Value(1)); EXPECT_EQ(list[1], Value(4)); EXPECT_EQ(*next_it, Value(4)); EXPECT_EQ(next_it + 1, list.end()); next_it = list.erase(list.begin() + 1, list.begin() + 1); ASSERT_EQ(2u, list.size()); EXPECT_EQ(list[0], Value(1)); EXPECT_EQ(list[1], Value(4)); EXPECT_EQ(*next_it, Value(4)); EXPECT_EQ(next_it + 1, list.end()); next_it = list.erase(list.begin() + 1, list.end()); ASSERT_EQ(1u, list.size()); EXPECT_EQ(list[0], Value(1)); EXPECT_EQ(next_it, list.end()); list.clear(); next_it = list.erase(list.begin(), list.begin()); ASSERT_EQ(0u, list.size()); EXPECT_EQ(next_it, list.begin()); EXPECT_EQ(next_it, list.end()); } TEST(ValuesTest, ListEraseValue) { Value::List list; list.Append(1); list.Append(2); list.Append(2); list.Append(3); EXPECT_EQ(2u, list.EraseValue(Value(2))); EXPECT_EQ(2u, list.size()); EXPECT_EQ(1, list[0]); EXPECT_EQ(3, list[1]); EXPECT_EQ(1u, list.EraseValue(Value(1))); EXPECT_EQ(1u, list.size()); EXPECT_EQ(3, list[0]); EXPECT_EQ(1u, list.EraseValue(Value(3))); EXPECT_TRUE(list.empty()); EXPECT_EQ(0u, list.EraseValue(Value(3))); } TEST(ValuesTest, ListEraseIf) { Value::List list; list.Append(1); list.Append(2); list.Append(2); list.Append(3); EXPECT_EQ(3u, list.EraseIf([](const auto& val) { return val >= Value(2); })); EXPECT_EQ(1u, list.size()); EXPECT_EQ(1, list[0]); EXPECT_EQ(1u, list.EraseIf([](const auto& val) { return true; })); EXPECT_TRUE(list.empty()); EXPECT_EQ(0u, list.EraseIf([](const auto& val) { return true; })); } TEST(ValuesTest, ClearList) { Value::List list; list.Append(1); list.Append(2); list.Append(3); EXPECT_EQ(3u, list.size()); EXPECT_FALSE(list.empty()); list.clear(); EXPECT_EQ(0u, list.size()); EXPECT_TRUE(list.empty()); // list.clear() should be idempotent. list.clear(); EXPECT_EQ(0u, list.size()); EXPECT_TRUE(list.empty()); } TEST(ValuesTest, FindKey) { Value::Dict dict; dict.Set("foo", "bar"); Value value(std::move(dict)); EXPECT_NE(nullptr, value.GetDict().Find("foo")); EXPECT_EQ(nullptr, value.GetDict().Find("baz")); } TEST(ValuesTest, FindKeyChangeValue) { Value::Dict dict; dict.Set("foo", "bar"); Value* found = dict.Find("foo"); ASSERT_NE(nullptr, found); EXPECT_EQ("bar", found->GetString()); *found = Value(123); EXPECT_EQ(123, dict.Find("foo")->GetInt()); } TEST(ValuesTest, FindKeyConst) { Value::Dict dict; dict.Set("foo", "bar"); const Value value(std::move(dict)); EXPECT_NE(nullptr, value.GetDict().Find("foo")); EXPECT_EQ(nullptr, value.GetDict().Find("baz")); } TEST(ValuesTest, FindBoolKey) { Value::Dict dict; dict.Set("null", Value()); dict.Set("bool", false); dict.Set("int", 0); dict.Set("double", 0.0); dict.Set("string", std::string()); dict.Set("blob", Value(Value::BlobStorage())); dict.Set("list", Value::List()); dict.Set("dict", Value::Dict()); EXPECT_EQ(std::nullopt, dict.FindBool("null")); EXPECT_NE(std::nullopt, dict.FindBool("bool")); EXPECT_EQ(std::nullopt, dict.FindBool("int")); EXPECT_EQ(std::nullopt, dict.FindBool("double")); EXPECT_EQ(std::nullopt, dict.FindBool("string")); EXPECT_EQ(std::nullopt, dict.FindBool("blob")); EXPECT_EQ(std::nullopt, dict.FindBool("list")); EXPECT_EQ(std::nullopt, dict.FindBool("dict")); } TEST(ValuesTest, FindIntKey) { Value::Dict dict; dict.Set("null", Value()); dict.Set("bool", false); dict.Set("int", 0); dict.Set("double", 0.0); dict.Set("string", std::string()); dict.Set("blob", Value(Value::BlobStorage())); dict.Set("list", Value::List()); dict.Set("dict", Value::Dict()); EXPECT_EQ(std::nullopt, dict.FindInt("null")); EXPECT_EQ(std::nullopt, dict.FindInt("bool")); EXPECT_NE(std::nullopt, dict.FindInt("int")); EXPECT_EQ(std::nullopt, dict.FindInt("double")); EXPECT_EQ(std::nullopt, dict.FindInt("string")); EXPECT_EQ(std::nullopt, dict.FindInt("blob")); EXPECT_EQ(std::nullopt, dict.FindInt("list")); EXPECT_EQ(std::nullopt, dict.FindInt("dict")); } TEST(ValuesTest, FindStringKey) { Value::Dict dict; dict.Set("null", Value()); dict.Set("bool", false); dict.Set("int", 0); dict.Set("double", 0.0); dict.Set("string", std::string()); dict.Set("blob", Value(Value::BlobStorage())); dict.Set("list", Value::List()); dict.Set("dict", Value::Dict()); EXPECT_EQ(nullptr, dict.FindString("null")); EXPECT_EQ(nullptr, dict.FindString("bool")); EXPECT_EQ(nullptr, dict.FindString("int")); EXPECT_EQ(nullptr, dict.FindString("double")); EXPECT_NE(nullptr, dict.FindString("string")); EXPECT_EQ(nullptr, dict.FindString("blob")); EXPECT_EQ(nullptr, dict.FindString("list")); EXPECT_EQ(nullptr, dict.FindString("dict")); } TEST(ValuesTest, MutableFindStringKey) { Value::Dict dict; dict.Set("string", "foo"); *(dict.FindString("string")) = "bar"; Value::Dict expected_dict; expected_dict.Set("string", "bar"); EXPECT_EQ(expected_dict, dict); Value value(std::move(dict)); Value expected_value(std::move(expected_dict)); EXPECT_EQ(expected_value, value); } TEST(ValuesTest, FindDictKey) { Value::Dict dict; dict.Set("null", Value()); dict.Set("bool", false); dict.Set("int", 0); dict.Set("double", 0.0); dict.Set("string", std::string()); dict.Set("blob", Value(Value::BlobStorage())); dict.Set("list", Value::List()); dict.Set("dict", Value::Dict()); EXPECT_EQ(nullptr, dict.FindDict("null")); EXPECT_EQ(nullptr, dict.FindDict("bool")); EXPECT_EQ(nullptr, dict.FindDict("int")); EXPECT_EQ(nullptr, dict.FindDict("double")); EXPECT_EQ(nullptr, dict.FindDict("string")); EXPECT_EQ(nullptr, dict.FindDict("blob")); EXPECT_EQ(nullptr, dict.FindDict("list")); EXPECT_NE(nullptr, dict.FindDict("dict")); } TEST(ValuesTest, FindListKey) { Value::Dict dict; dict.Set("null", Value()); dict.Set("bool", false); dict.Set("int", 0); dict.Set("double", 0.0); dict.Set("string", std::string()); dict.Set("blob", Value(Value::BlobStorage())); dict.Set("list", Value::List()); dict.Set("dict", Value::Dict()); EXPECT_EQ(nullptr, dict.FindList("null")); EXPECT_EQ(nullptr, dict.FindList("bool")); EXPECT_EQ(nullptr, dict.FindList("int")); EXPECT_EQ(nullptr, dict.FindList("double")); EXPECT_EQ(nullptr, dict.FindList("string")); EXPECT_EQ(nullptr, dict.FindList("blob")); EXPECT_NE(nullptr, dict.FindList("list")); EXPECT_EQ(nullptr, dict.FindList("dict")); } TEST(ValuesTest, FindBlob) { Value::Dict dict; dict.Set("null", Value()); dict.Set("bool", false); dict.Set("int", 0); dict.Set("double", 0.0); dict.Set("string", std::string()); dict.Set("blob", Value(Value::BlobStorage())); dict.Set("list", Value::List()); dict.Set("dict", Value::Dict()); EXPECT_EQ(nullptr, dict.FindBlob("null")); EXPECT_EQ(nullptr, dict.FindBlob("bool")); EXPECT_EQ(nullptr, dict.FindBlob("int")); EXPECT_EQ(nullptr, dict.FindBlob("double")); EXPECT_EQ(nullptr, dict.FindBlob("string")); EXPECT_NE(nullptr, dict.FindBlob("blob")); EXPECT_EQ(nullptr, dict.FindBlob("list")); EXPECT_EQ(nullptr, dict.FindBlob("dict")); } TEST(ValuesTest, SetKey) { Value::Dict dict; dict.Set("null", Value()); dict.Set("bool", false); dict.Set("int", 0); dict.Set("double", 0.0); dict.Set("string", std::string()); dict.Set("blob", Value(Value::BlobStorage())); dict.Set("list", Value::List()); dict.Set("dict", Value::Dict()); Value::Dict dict2; dict2.Set(StringPiece("null"), Value(Value::Type::NONE)); dict2.Set(StringPiece("bool"), Value(Value::Type::BOOLEAN)); dict2.Set(std::string("int"), Value(Value::Type::INTEGER)); dict2.Set(std::string("double"), Value(Value::Type::DOUBLE)); dict2.Set(std::string("string"), Value(Value::Type::STRING)); dict2.Set("blob", Value(Value::Type::BINARY)); dict2.Set("list", Value(Value::Type::LIST)); dict2.Set("dict", Value(Value::Type::DICT)); EXPECT_EQ(dict, dict2); EXPECT_EQ(Value(std::move(dict)), Value(std::move(dict2))); } TEST(ValuesTest, SetBoolKey) { std::optional value; Value::Dict dict; dict.Set("true_key", true); dict.Set("false_key", false); value = dict.FindBool("true_key"); ASSERT_TRUE(value); ASSERT_TRUE(*value); value = dict.FindBool("false_key"); ASSERT_TRUE(value); ASSERT_FALSE(*value); value = dict.FindBool("missing_key"); ASSERT_FALSE(value); } TEST(ValuesTest, SetIntKey) { std::optional value; Value::Dict dict; dict.Set("one_key", 1); dict.Set("minus_one_key", -1); value = dict.FindInt("one_key"); ASSERT_TRUE(value); ASSERT_EQ(1, *value); value = dict.FindInt("minus_one_key"); ASSERT_TRUE(value); ASSERT_EQ(-1, *value); value = dict.FindInt("missing_key"); ASSERT_FALSE(value); } TEST(ValuesTest, SetDoubleKey) { Value::Dict dict; dict.Set("one_key", 1.0); dict.Set("minus_one_key", -1.0); dict.Set("pi_key", 3.1415); const Value* value; value = dict.Find("one_key"); ASSERT_TRUE(value); EXPECT_TRUE(value->is_double()); EXPECT_EQ(1.0, value->GetDouble()); value = dict.Find("minus_one_key"); ASSERT_TRUE(value); EXPECT_TRUE(value->is_double()); EXPECT_EQ(-1.0, value->GetDouble()); value = dict.Find("pi_key"); ASSERT_TRUE(value); EXPECT_TRUE(value->is_double()); EXPECT_EQ(3.1415, value->GetDouble()); } TEST(ValuesTest, SetStringKey) { Value::Dict dict; dict.Set("one_key", "one"); dict.Set("hello_key", "hello world"); std::string movable_value("movable_value"); dict.Set("movable_key", std::move(movable_value)); ASSERT_TRUE(movable_value.empty()); const std::string* value; value = dict.FindString("one_key"); ASSERT_TRUE(value); ASSERT_EQ("one", *value); value = dict.FindString("hello_key"); ASSERT_TRUE(value); ASSERT_EQ("hello world", *value); value = dict.FindString("movable_key"); ASSERT_TRUE(value); ASSERT_EQ("movable_value", *value); value = dict.FindString("missing_key"); ASSERT_FALSE(value); } TEST(ValuesTest, RvalueSet) { Value::Dict dict = Value::Dict() .Set("null", Value()) .Set("bool", false) .Set("int", 42) .Set("double", 1.2) .Set("string", "value") .Set("u16-string", u"u16-value") .Set("std-string", std::string("std-value")) .Set("blob", Value::BlobStorage({1, 2})) .Set("list", Value::List().Append("value in list")) .Set("dict", Value::Dict().Set("key", "value")); Value::Dict expected; expected.Set("null", Value()); expected.Set("bool", false); expected.Set("int", 42); expected.Set("double", 1.2); expected.Set("string", "value"); expected.Set("u16-string", u"u16-value"); expected.Set("std-string", std::string("std-value")); expected.Set("blob", Value::BlobStorage({1, 2})); Value::List nested_list; nested_list.Append("value in list"); expected.Set("list", std::move(nested_list)); Value::Dict nested_dict; nested_dict.Set("key", "value"); expected.Set("dict", std::move(nested_dict)); EXPECT_EQ(dict, expected); } TEST(ValuesTest, FindPath) { // Construct a dictionary path {root}.foo.bar = 123 Value::Dict foo; foo.Set("bar", Value(123)); Value::Dict root; root.Set("foo", std::move(foo)); // Double key, second not found. Value* found = root.FindByDottedPath("foo.notfound"); EXPECT_FALSE(found); // Double key, found. found = root.FindByDottedPath("foo.bar"); EXPECT_TRUE(found); EXPECT_TRUE(found->is_int()); EXPECT_EQ(123, found->GetInt()); } TEST(ValuesTest, SetByDottedPath) { Value::Dict root; Value* inserted = root.SetByDottedPath("one.two", Value(123)); Value* found = root.FindByDottedPath("one.two"); ASSERT_TRUE(found); EXPECT_EQ(found->type(), Value::Type::INTEGER); EXPECT_EQ(inserted, found); EXPECT_EQ(123, found->GetInt()); inserted = root.SetByDottedPath("foo.bar", Value(123)); found = root.FindByDottedPath("foo.bar"); ASSERT_TRUE(found); EXPECT_EQ(found->type(), Value::Type::INTEGER); EXPECT_EQ(inserted, found); EXPECT_EQ(123, found->GetInt()); // Overwrite with a different value. root.SetByDottedPath("foo.bar", Value("hello")); found = root.FindByDottedPath("foo.bar"); ASSERT_TRUE(found); EXPECT_EQ(found->type(), Value::Type::STRING); EXPECT_EQ("hello", found->GetString()); // Can't change existing non-dictionary keys to dictionaries. found = root.SetByDottedPath("foo.bar.baz", Value(123)); EXPECT_FALSE(found); } TEST(ValuesTest, SetBoolPath) { Value::Dict root; Value* inserted = root.SetByDottedPath("foo.bar", true); Value* found = root.FindByDottedPath("foo.bar"); ASSERT_TRUE(found); EXPECT_EQ(inserted, found); ASSERT_TRUE(found->is_bool()); EXPECT_TRUE(found->GetBool()); // Overwrite with a different value. root.SetByDottedPath("foo.bar", false); found = root.FindByDottedPath("foo.bar"); ASSERT_TRUE(found); ASSERT_TRUE(found->is_bool()); EXPECT_FALSE(found->GetBool()); // Can't change existing non-dictionary keys. ASSERT_FALSE(root.SetByDottedPath("foo.bar.zoo", true)); } TEST(ValuesTest, SetIntPath) { Value::Dict root; Value* inserted = root.SetByDottedPath("foo.bar", 123); Value* found = root.FindByDottedPath("foo.bar"); ASSERT_TRUE(found); EXPECT_EQ(inserted, found); ASSERT_TRUE(found->is_int()); EXPECT_EQ(123, found->GetInt()); // Overwrite with a different value. root.SetByDottedPath("foo.bar", 234); found = root.FindByDottedPath("foo.bar"); ASSERT_TRUE(found); ASSERT_TRUE(found->is_int()); EXPECT_EQ(234, found->GetInt()); // Can't change existing non-dictionary keys. ASSERT_FALSE(root.SetByDottedPath("foo.bar.zoo", 567)); } TEST(ValuesTest, SetDoublePath) { Value::Dict root; Value* inserted = root.SetByDottedPath("foo.bar", 1.23); Value* found = root.FindByDottedPath("foo.bar"); ASSERT_TRUE(found); EXPECT_EQ(inserted, found); ASSERT_TRUE(found->is_double()); EXPECT_EQ(1.23, found->GetDouble()); // Overwrite with a different value. root.SetByDottedPath("foo.bar", 2.34); found = root.FindByDottedPath("foo.bar"); ASSERT_TRUE(found); ASSERT_TRUE(found->is_double()); EXPECT_EQ(2.34, found->GetDouble()); // Can't change existing non-dictionary keys. ASSERT_FALSE(root.SetByDottedPath("foo.bar.zoo", 5.67)); } TEST(ValuesTest, SetStringPath) { Value::Dict root; Value* inserted = root.SetByDottedPath("foo.bar", "hello world"); Value* found = root.FindByDottedPath("foo.bar"); ASSERT_TRUE(found); EXPECT_EQ(inserted, found); ASSERT_TRUE(found->is_string()); EXPECT_EQ("hello world", found->GetString()); // Overwrite with a different value. root.SetByDottedPath("foo.bar", "bonjour monde"); found = root.FindByDottedPath("foo.bar"); ASSERT_TRUE(found); ASSERT_TRUE(found->is_string()); EXPECT_EQ("bonjour monde", found->GetString()); ASSERT_TRUE(root.SetByDottedPath("foo.bar", StringPiece("rah rah"))); ASSERT_TRUE(root.SetByDottedPath("foo.bar", std::string("temp string"))); ASSERT_TRUE(root.SetByDottedPath("foo.bar", u"temp string")); // Can't change existing non-dictionary keys. ASSERT_FALSE(root.SetByDottedPath("foo.bar.zoo", "ola mundo")); } TEST(ValuesTest, Remove) { Value::Dict root; root.Set("one", Value(123)); // Removal of missing key should fail. EXPECT_FALSE(root.Remove("two")); // Removal of existing key should succeed. EXPECT_TRUE(root.Remove("one")); // Second removal of previously existing key should fail. EXPECT_FALSE(root.Remove("one")); } TEST(ValuesTest, Extract) { Value::Dict root; root.Set("one", Value(123)); // Extraction of missing key should fail. EXPECT_EQ(std::nullopt, root.Extract("two")); // Extraction of existing key should succeed. EXPECT_EQ(Value(123), root.Extract("one")); // Second extraction of previously existing key should fail. EXPECT_EQ(std::nullopt, root.Extract("one")); } TEST(ValuesTest, RemoveByDottedPath) { Value::Dict root; root.SetByDottedPath("one.two.three", Value(123)); // Removal of missing key should fail. EXPECT_FALSE(root.RemoveByDottedPath("one.two.four")); // Removal of existing key should succeed. EXPECT_TRUE(root.RemoveByDottedPath("one.two.three")); // Second removal of previously existing key should fail. EXPECT_FALSE(root.RemoveByDottedPath("one.two.three")); // Intermediate empty dictionaries should be cleared. EXPECT_EQ(nullptr, root.Find("one")); root.SetByDottedPath("one.two.three", Value(123)); root.SetByDottedPath("one.two.four", Value(124)); EXPECT_TRUE(root.RemoveByDottedPath("one.two.three")); // Intermediate non-empty dictionaries should be kept. EXPECT_NE(nullptr, root.Find("one")); EXPECT_NE(nullptr, root.FindByDottedPath("one.two")); EXPECT_NE(nullptr, root.FindByDottedPath("one.two.four")); } TEST(ValuesTest, ExtractByDottedPath) { Value::Dict root; root.SetByDottedPath("one.two.three", Value(123)); // Extraction of missing key should fail. EXPECT_EQ(std::nullopt, root.ExtractByDottedPath("one.two.four")); // Extraction of existing key should succeed. EXPECT_EQ(Value(123), root.ExtractByDottedPath("one.two.three")); // Second extraction of previously existing key should fail. EXPECT_EQ(std::nullopt, root.ExtractByDottedPath("one.two.three")); // Intermediate empty dictionaries should be cleared. EXPECT_EQ(nullptr, root.Find("one")); root.SetByDottedPath("one.two.three", Value(123)); root.SetByDottedPath("one.two.four", Value(124)); EXPECT_EQ(Value(123), root.ExtractByDottedPath("one.two.three")); // Intermediate non-empty dictionaries should be kept. EXPECT_NE(nullptr, root.Find("one")); EXPECT_NE(nullptr, root.FindByDottedPath("one.two")); EXPECT_NE(nullptr, root.FindByDottedPath("one.two.four")); } TEST(ValuesTest, Basic) { // Test basic dictionary getting/setting Value::Dict settings; ASSERT_FALSE(settings.FindByDottedPath("global.homepage")); ASSERT_FALSE(settings.Find("global")); settings.Set("global", Value(true)); ASSERT_TRUE(settings.Find("global")); settings.Remove("global"); settings.SetByDottedPath("global.homepage", Value("http://scurvy.com")); ASSERT_TRUE(settings.Find("global")); const std::string* homepage = settings.FindStringByDottedPath("global.homepage"); ASSERT_TRUE(homepage); ASSERT_EQ(std::string("http://scurvy.com"), *homepage); // Test storing a dictionary in a list. ASSERT_FALSE(settings.FindByDottedPath("global.toolbar.bookmarks")); Value::List new_toolbar_bookmarks; settings.SetByDottedPath("global.toolbar.bookmarks", std::move(new_toolbar_bookmarks)); Value::List* toolbar_bookmarks = settings.FindListByDottedPath("global.toolbar.bookmarks"); ASSERT_TRUE(toolbar_bookmarks); Value::Dict new_bookmark; new_bookmark.Set("name", Value("Froogle")); new_bookmark.Set("url", Value("http://froogle.com")); toolbar_bookmarks->Append(std::move(new_bookmark)); Value* bookmark_list = settings.FindByDottedPath("global.toolbar.bookmarks"); ASSERT_TRUE(bookmark_list); ASSERT_EQ(1U, bookmark_list->GetList().size()); Value* bookmark = &bookmark_list->GetList()[0]; ASSERT_TRUE(bookmark); ASSERT_TRUE(bookmark->is_dict()); const std::string* bookmark_name = bookmark->GetDict().FindString("name"); ASSERT_TRUE(bookmark_name); ASSERT_EQ(std::string("Froogle"), *bookmark_name); const std::string* bookmark_url = bookmark->GetDict().FindString("url"); ASSERT_TRUE(bookmark_url); ASSERT_EQ(std::string("http://froogle.com"), *bookmark_url); } TEST(ValuesTest, List) { Value::List mixed_list; mixed_list.Append(true); mixed_list.Append(42); mixed_list.Append(88.8); mixed_list.Append("foo"); ASSERT_EQ(4u, mixed_list.size()); EXPECT_EQ(true, mixed_list[0]); EXPECT_EQ(42, mixed_list[1]); EXPECT_EQ(88.8, mixed_list[2]); EXPECT_EQ("foo", mixed_list[3]); // Try searching in the mixed list. ASSERT_TRUE(Contains(mixed_list, 42)); ASSERT_FALSE(Contains(mixed_list, false)); } TEST(ValuesTest, RvalueAppend) { Value::List list = Value::List() .Append(Value()) .Append(false) .Append(42) .Append(1.2) .Append("value") .Append(u"u16-value") .Append(std::string("std-value")) .Append(Value::BlobStorage({1, 2})) .Append(Value::List().Append("value in list")) .Append(Value::Dict().Set("key", "value")); Value::List expected; expected.Append(Value()); expected.Append(false); expected.Append(42); expected.Append(1.2); expected.Append("value"); expected.Append(u"u16-value"); expected.Append(std::string("std-value")); expected.Append(Value::BlobStorage({1, 2})); Value::List nested_list; nested_list.Append("value in list"); expected.Append(std::move(nested_list)); Value::Dict nested_dict; nested_dict.Set("key", "value"); expected.Append(std::move(nested_dict)); EXPECT_EQ(list, expected); } TEST(ValuesTest, ListWithCapacity) { Value::List list_with_capacity = Value::List::with_capacity(3).Append(true).Append(42).Append(88.8); ASSERT_EQ(3u, list_with_capacity.size()); } TEST(ValuesTest, BinaryValue) { // Default constructor creates a BinaryValue with a buffer of size 0. Value binary(Value::Type::BINARY); ASSERT_TRUE(binary.GetBlob().empty()); // Test the common case of a non-empty buffer Value::BlobStorage buffer(15); uint8_t* original_buffer = buffer.data(); binary = Value(std::move(buffer)); ASSERT_TRUE(binary.GetBlob().data()); ASSERT_EQ(original_buffer, binary.GetBlob().data()); ASSERT_EQ(15U, binary.GetBlob().size()); char stack_buffer[42]; memset(stack_buffer, '!', 42); binary = Value(Value::BlobStorage(stack_buffer, stack_buffer + 42)); ASSERT_TRUE(binary.GetBlob().data()); ASSERT_NE(stack_buffer, reinterpret_cast(binary.GetBlob().data())); ASSERT_EQ(42U, binary.GetBlob().size()); ASSERT_EQ(0, memcmp(stack_buffer, binary.GetBlob().data(), binary.GetBlob().size())); } TEST(ValuesTest, StringValue) { // Test overloaded StringValue constructor. std::unique_ptr narrow_value(new Value("narrow")); ASSERT_TRUE(narrow_value.get()); ASSERT_TRUE(narrow_value->is_string()); std::unique_ptr utf16_value(new Value(u"utf16")); ASSERT_TRUE(utf16_value.get()); ASSERT_TRUE(utf16_value->is_string()); ASSERT_TRUE(narrow_value->is_string()); ASSERT_EQ(std::string("narrow"), narrow_value->GetString()); ASSERT_TRUE(utf16_value->is_string()); ASSERT_EQ(std::string("utf16"), utf16_value->GetString()); } TEST(ValuesTest, DictionaryDeletion) { std::string key = "test"; Value::Dict dict; dict.Set(key, Value()); EXPECT_FALSE(dict.empty()); EXPECT_EQ(1U, dict.size()); dict.clear(); EXPECT_TRUE(dict.empty()); EXPECT_TRUE(dict.empty()); EXPECT_EQ(0U, dict.size()); } TEST(ValuesTest, DictionarySetReturnsPointer) { { Value::Dict dict; Value* blank_ptr = dict.Set("foo.bar", Value()); EXPECT_EQ(Value::Type::NONE, blank_ptr->type()); } { Value::Dict dict; Value* blank_ptr = dict.Set("foo.bar", Value()); EXPECT_EQ(Value::Type::NONE, blank_ptr->type()); } { Value::Dict dict; Value* int_ptr = dict.Set("foo.bar", 42); EXPECT_EQ(Value::Type::INTEGER, int_ptr->type()); EXPECT_EQ(42, int_ptr->GetInt()); } { Value::Dict dict; Value* string_ptr = dict.Set("foo.bar", "foo"); EXPECT_EQ(Value::Type::STRING, string_ptr->type()); EXPECT_EQ("foo", string_ptr->GetString()); } { Value::Dict dict; Value* string16_ptr = dict.Set("foo.bar", u"baz"); EXPECT_EQ(Value::Type::STRING, string16_ptr->type()); EXPECT_EQ("baz", string16_ptr->GetString()); } { Value::Dict dict; Value* dict_ptr = dict.Set("foo.bar", Value::Dict()); EXPECT_EQ(Value::Type::DICT, dict_ptr->type()); } { Value::Dict dict; Value* list_ptr = dict.Set("foo.bar", Value::List()); EXPECT_EQ(Value::Type::LIST, list_ptr->type()); } } TEST(ValuesTest, Clone) { Value original_null; Value original_bool(true); Value original_int(42); Value original_double(3.14); Value original_string("hello"); Value original_string16(u"hello16"); Value original_binary(Value::BlobStorage(42, '!')); Value::List list; list.Append(0); list.Append(1); Value original_list(std::move(list)); Value original_dict(Value::Dict() .Set("null", original_null.Clone()) .Set("bool", original_bool.Clone()) .Set("int", original_int.Clone()) .Set("double", original_double.Clone()) .Set("string", original_string.Clone()) .Set("string16", original_string16.Clone()) .Set("binary", original_binary.Clone()) .Set("list", original_list.Clone())); Value copy_value = original_dict.Clone(); const Value::Dict& copy_dict = copy_value.GetDict(); EXPECT_EQ(original_dict, copy_dict); EXPECT_EQ(original_null, *copy_dict.Find("null")); EXPECT_EQ(original_bool, *copy_dict.Find("bool")); EXPECT_EQ(original_int, *copy_dict.Find("int")); EXPECT_EQ(original_double, *copy_dict.Find("double")); EXPECT_EQ(original_string, *copy_dict.Find("string")); EXPECT_EQ(original_string16, *copy_dict.Find("string16")); EXPECT_EQ(original_binary, *copy_dict.Find("binary")); EXPECT_EQ(original_list, *copy_dict.Find("list")); } TEST(ValuesTest, TakeString) { Value value("foo"); std::string taken = std::move(value).TakeString(); EXPECT_EQ(taken, "foo"); } // Check that the value can still be used after `TakeString()` was called, as // long as a new value was assigned to it. TEST(ValuesTest, PopulateAfterTakeString) { Value value("foo"); std::string taken = std::move(value).TakeString(); value = Value(false); EXPECT_EQ(value, Value(false)); } TEST(ValuesTest, TakeDict) { Value::Dict dict; dict.Set("foo", 123); Value value(std::move(dict)); Value clone = value.Clone(); Value::Dict taken = std::move(value).TakeDict(); EXPECT_EQ(taken, clone); } // Check that the value can still be used after `TakeDict()` was called, as long // as a new value was assigned to it. TEST(ValuesTest, PopulateAfterTakeDict) { Value::Dict dict; dict.Set("foo", 123); Value value(std::move(dict)); Value::Dict taken = std::move(value).TakeDict(); value = Value(false); EXPECT_EQ(value, Value(false)); } TEST(ValuesTest, TakeList) { Value::List list; list.Append(true); list.Append(123); Value value(std::move(list)); Value clone = value.Clone(); Value::List taken = std::move(value).TakeList(); EXPECT_EQ(taken, clone); } // Check that the value can still be used after `TakeList()` was called, as long // as a new value was assigned to it. TEST(ValuesTest, PopulateAfterTakeList) { Value::List list; list.Append("hello"); Value value(std::move(list)); Value::List taken = std::move(value).TakeList(); value = Value(false); EXPECT_EQ(value, Value(false)); } TEST(ValuesTest, SpecializedEquals) { std::vector values; values.emplace_back(false); values.emplace_back(true); values.emplace_back(0); values.emplace_back(1); values.emplace_back(1.0); values.emplace_back(2.0); values.emplace_back("hello"); values.emplace_back("world"); base::Value::Dict dict; dict.Set("hello", "world"); values.emplace_back(std::move(dict)); base::Value::Dict dict2; dict2.Set("world", "hello"); values.emplace_back(std::move(dict2)); base::Value::List list; list.Append("hello"); list.Append("world"); values.emplace_back(std::move(list)); base::Value::List list2; list2.Append("world"); list2.Append("hello"); values.emplace_back(std::move(list2)); for (const Value& outer_value : values) { for (const Value& inner_value : values) { SCOPED_TRACE(::testing::Message() << "Outer: " << outer_value << "Inner: " << inner_value); const bool should_be_equal = &outer_value == &inner_value; if (should_be_equal) { EXPECT_EQ(outer_value, inner_value); EXPECT_EQ(inner_value, outer_value); EXPECT_FALSE(outer_value != inner_value); EXPECT_FALSE(inner_value != outer_value); } else { EXPECT_NE(outer_value, inner_value); EXPECT_NE(inner_value, outer_value); EXPECT_FALSE(outer_value == inner_value); EXPECT_FALSE(inner_value == outer_value); } // Also test the various overloads for operator== against concrete // subtypes. outer_value.Visit([&](const auto& outer_member) { using T = std::decay_t; if constexpr (!std::is_same_v && !std::is_same_v) { if (should_be_equal) { EXPECT_EQ(outer_member, inner_value); EXPECT_EQ(inner_value, outer_member); EXPECT_FALSE(outer_member != inner_value); EXPECT_FALSE(inner_value != outer_member); } else { EXPECT_NE(outer_member, inner_value); EXPECT_NE(inner_value, outer_member); EXPECT_FALSE(outer_member == inner_value); EXPECT_FALSE(inner_value == outer_member); } } }); } // A copy of a Value should also compare equal to itself. Value copied_value = outer_value.Clone(); EXPECT_EQ(outer_value, copied_value); EXPECT_EQ(copied_value, outer_value); EXPECT_FALSE(outer_value != copied_value); EXPECT_FALSE(copied_value != outer_value); } } // Test that a literal string comparison does not end up using the bool (!!) // overload. TEST(ValuesTest, LiteralStringEquals) { EXPECT_EQ("hello world", base::Value("hello world")); EXPECT_EQ(base::Value("hello world"), "hello world"); EXPECT_NE("hello world", base::Value(true)); EXPECT_NE(base::Value(true), "hello world"); } TEST(ValuesTest, Equals) { auto null1 = std::make_unique(); auto null2 = std::make_unique(); EXPECT_NE(null1.get(), null2.get()); EXPECT_EQ(*null1, *null2); Value boolean(false); EXPECT_NE(*null1, boolean); Value::Dict dv; dv.Set("a", false); dv.Set("b", 2); dv.Set("c", 2.5); dv.Set("d1", "string"); dv.Set("d2", u"http://google.com"); dv.Set("e", Value()); Value::Dict copy = dv.Clone(); EXPECT_EQ(dv, copy); Value::List list; list.Append(Value()); list.Append(Value(Value::Type::DICT)); Value::List list_copy(list.Clone()); Value* list_weak = dv.Set("f", std::move(list)); EXPECT_NE(dv, copy); copy.Set("f", std::move(list_copy)); EXPECT_EQ(dv, copy); list_weak->GetList().Append(true); EXPECT_NE(dv, copy); // Check if Equals detects differences in only the keys. copy = dv.Clone(); EXPECT_EQ(dv, copy); copy.Remove("a"); copy.Set("aa", false); EXPECT_NE(dv, copy); } TEST(ValuesTest, Comparisons) { // Test None Values. Value null1; Value null2; EXPECT_EQ(null1, null2); EXPECT_FALSE(null1 != null2); EXPECT_FALSE(null1 < null2); EXPECT_FALSE(null1 > null2); EXPECT_LE(null1, null2); EXPECT_GE(null1, null2); // Test Bool Values. Value bool1(false); Value bool2(true); EXPECT_FALSE(bool1 == bool2); EXPECT_NE(bool1, bool2); EXPECT_LT(bool1, bool2); EXPECT_FALSE(bool1 > bool2); EXPECT_LE(bool1, bool2); EXPECT_FALSE(bool1 >= bool2); // Test Int Values. Value int1(1); Value int2(2); EXPECT_FALSE(int1 == int2); EXPECT_NE(int1, int2); EXPECT_LT(int1, int2); EXPECT_FALSE(int1 > int2); EXPECT_LE(int1, int2); EXPECT_FALSE(int1 >= int2); // Test Double Values. Value double1(1.0); Value double2(2.0); EXPECT_FALSE(double1 == double2); EXPECT_NE(double1, double2); EXPECT_LT(double1, double2); EXPECT_FALSE(double1 > double2); EXPECT_LE(double1, double2); EXPECT_FALSE(double1 >= double2); // Test String Values. Value string1("1"); Value string2("2"); EXPECT_FALSE(string1 == string2); EXPECT_NE(string1, string2); EXPECT_LT(string1, string2); EXPECT_FALSE(string1 > string2); EXPECT_LE(string1, string2); EXPECT_FALSE(string1 >= string2); // Test Binary Values. Value binary1(Value::BlobStorage{0x01}); Value binary2(Value::BlobStorage{0x02}); EXPECT_FALSE(binary1 == binary2); EXPECT_NE(binary1, binary2); EXPECT_LT(binary1, binary2); EXPECT_FALSE(binary1 > binary2); EXPECT_LE(binary1, binary2); EXPECT_FALSE(binary1 >= binary2); // Test Empty List Values. Value::List null_list1; Value::List null_list2; EXPECT_EQ(null_list1, null_list2); EXPECT_FALSE(null_list1 != null_list2); EXPECT_FALSE(null_list1 < null_list2); EXPECT_FALSE(null_list1 > null_list2); EXPECT_LE(null_list1, null_list2); EXPECT_GE(null_list1, null_list2); // Test Non Empty List Values. Value::List int_list1; Value::List int_list2; int_list1.Append(1); int_list2.Append(2); EXPECT_FALSE(int_list1 == int_list2); EXPECT_NE(int_list1, int_list2); EXPECT_LT(int_list1, int_list2); EXPECT_FALSE(int_list1 > int_list2); EXPECT_LE(int_list1, int_list2); EXPECT_FALSE(int_list1 >= int_list2); // Test Empty Dict Values. Value::Dict null_dict1; Value::Dict null_dict2; EXPECT_EQ(null_dict1, null_dict2); EXPECT_FALSE(null_dict1 != null_dict2); EXPECT_FALSE(null_dict1 < null_dict2); EXPECT_FALSE(null_dict1 > null_dict2); EXPECT_LE(null_dict1, null_dict2); EXPECT_GE(null_dict1, null_dict2); // Test Non Empty Dict Values. Value::Dict int_dict1; Value::Dict int_dict2; int_dict1.Set("key", 1); int_dict2.Set("key", 2); EXPECT_FALSE(int_dict1 == int_dict2); EXPECT_NE(int_dict1, int_dict2); EXPECT_LT(int_dict1, int_dict2); EXPECT_FALSE(int_dict1 > int_dict2); EXPECT_LE(int_dict1, int_dict2); EXPECT_FALSE(int_dict1 >= int_dict2); // Test Values of different types. std::vector values; values.emplace_back(std::move(null1)); values.emplace_back(std::move(bool1)); values.emplace_back(std::move(int1)); values.emplace_back(std::move(double1)); values.emplace_back(std::move(string1)); values.emplace_back(std::move(binary1)); values.emplace_back(std::move(int_dict1)); values.emplace_back(std::move(int_list1)); for (size_t i = 0; i < values.size(); ++i) { for (size_t j = i + 1; j < values.size(); ++j) { EXPECT_FALSE(values[i] == values[j]); EXPECT_NE(values[i], values[j]); EXPECT_LT(values[i], values[j]); EXPECT_FALSE(values[i] > values[j]); EXPECT_LE(values[i], values[j]); EXPECT_FALSE(values[i] >= values[j]); } } } TEST(ValuesTest, Merge) { Value::Dict base; base.Set("base_key", "base_key_value_base"); base.Set("collide_key", "collide_key_value_base"); Value::Dict base_sub_dict; base_sub_dict.Set("sub_base_key", "sub_base_key_value_base"); base_sub_dict.Set("sub_collide_key", "sub_collide_key_value_base"); base.Set("sub_dict_key", std::move(base_sub_dict)); Value::Dict merge; merge.Set("merge_key", "merge_key_value_merge"); merge.Set("collide_key", "collide_key_value_merge"); Value::Dict merge_sub_dict; merge_sub_dict.Set("sub_merge_key", "sub_merge_key_value_merge"); merge_sub_dict.Set("sub_collide_key", "sub_collide_key_value_merge"); merge.Set("sub_dict_key", std::move(merge_sub_dict)); base.Merge(std::move(merge)); EXPECT_EQ(4U, base.size()); const std::string* base_key_value = base.FindString("base_key"); ASSERT_TRUE(base_key_value); EXPECT_EQ("base_key_value_base", *base_key_value); // Base value preserved. const std::string* collide_key_value = base.FindString("collide_key"); ASSERT_TRUE(collide_key_value); EXPECT_EQ("collide_key_value_merge", *collide_key_value); // Replaced. const std::string* merge_key_value = base.FindString("merge_key"); ASSERT_TRUE(merge_key_value); EXPECT_EQ("merge_key_value_merge", *merge_key_value); // Merged in. Value::Dict* res_sub_dict = base.FindDict("sub_dict_key"); ASSERT_TRUE(res_sub_dict); EXPECT_EQ(3U, res_sub_dict->size()); const std::string* sub_base_key_value = res_sub_dict->FindString("sub_base_key"); ASSERT_TRUE(sub_base_key_value); EXPECT_EQ("sub_base_key_value_base", *sub_base_key_value); // Preserved. const std::string* sub_collide_key_value = res_sub_dict->FindString("sub_collide_key"); ASSERT_TRUE(sub_collide_key_value); EXPECT_EQ("sub_collide_key_value_merge", *sub_collide_key_value); // Replaced. const std::string* sub_merge_key_value = res_sub_dict->FindString("sub_merge_key"); ASSERT_TRUE(sub_merge_key_value); EXPECT_EQ("sub_merge_key_value_merge", *sub_merge_key_value); // Merged in. } TEST(ValuesTest, DictionaryIterator) { Value::Dict dict; for (Value::Dict::iterator it = dict.begin(); it != dict.end(); ++it) { ADD_FAILURE(); } Value value1("value1"); dict.Set("key1", value1.Clone()); bool seen1 = false; for (Value::Dict::iterator it = dict.begin(); it != dict.end(); ++it) { EXPECT_FALSE(seen1); EXPECT_EQ("key1", it->first); EXPECT_EQ(value1, it->second); seen1 = true; } EXPECT_TRUE(seen1); Value value2("value2"); dict.Set("key2", value2.Clone()); bool seen2 = seen1 = false; for (Value::Dict::iterator it = dict.begin(); it != dict.end(); ++it) { if (it->first == "key1") { EXPECT_FALSE(seen1); EXPECT_EQ(value1, it->second); seen1 = true; } else if (it->first == "key2") { EXPECT_FALSE(seen2); EXPECT_EQ(value2, it->second); seen2 = true; } else { ADD_FAILURE(); } } EXPECT_TRUE(seen1); EXPECT_TRUE(seen2); } TEST(ValuesTest, MutatingCopiedPairsInDictMutatesUnderlyingValues) { Value::Dict dict; dict.Set("key", Value("initial value")); // Because the non-const dict iterates over // pairs, it's possible to alter iterated-over values in place even when // "copying" the key-value pair: for (auto kv : dict) { kv.second.GetString() = "replacement"; } std::string* found = dict.FindString("key"); ASSERT_TRUE(found); EXPECT_EQ(*found, "replacement"); } TEST(ValuesTest, StdDictionaryIterator) { Value::Dict dict; for (auto it = dict.begin(); it != dict.end(); ++it) { ADD_FAILURE(); } Value value1("value1"); dict.Set("key1", value1.Clone()); bool seen1 = false; for (auto it : dict) { EXPECT_FALSE(seen1); EXPECT_EQ("key1", it.first); EXPECT_EQ(value1, it.second); seen1 = true; } EXPECT_TRUE(seen1); Value value2("value2"); dict.Set("key2", value2.Clone()); bool seen2 = seen1 = false; for (auto it : dict) { if (it.first == "key1") { EXPECT_FALSE(seen1); EXPECT_EQ(value1, it.second); seen1 = true; } else if (it.first == "key2") { EXPECT_FALSE(seen2); EXPECT_EQ(value2, it.second); seen2 = true; } else { ADD_FAILURE(); } } EXPECT_TRUE(seen1); EXPECT_TRUE(seen2); } TEST(ValuesTest, SelfSwap) { base::Value test(1); std::swap(test, test); EXPECT_EQ(1, test.GetInt()); } TEST(ValuesTest, FromToUniquePtrValue) { std::unique_ptr dict = std::make_unique(Value::Type::DICT); dict->GetDict().Set("name", "Froogle"); dict->GetDict().Set("url", "http://froogle.com"); Value dict_copy = dict->Clone(); Value dict_converted = Value::FromUniquePtrValue(std::move(dict)); EXPECT_EQ(dict_copy, dict_converted); std::unique_ptr val = Value::ToUniquePtrValue(std::move(dict_converted)); EXPECT_EQ(dict_copy, *val); } TEST(ValuesTest, MutableFindStringPath) { Value::Dict dict; dict.SetByDottedPath("foo.bar", "value"); *(dict.FindStringByDottedPath("foo.bar")) = "new_value"; Value::Dict expected_dict; expected_dict.SetByDottedPath("foo.bar", "new_value"); EXPECT_EQ(expected_dict, dict); } TEST(ValuesTest, MutableGetString) { Value value("value"); value.GetString() = "new_value"; EXPECT_EQ("new_value", value.GetString()); } #if BUILDFLAG(ENABLE_BASE_TRACING) TEST(ValuesTest, TracingSupport) { EXPECT_EQ(perfetto::TracedValueToString(Value(false)), "false"); EXPECT_EQ(perfetto::TracedValueToString(Value(1)), "1"); EXPECT_EQ(perfetto::TracedValueToString(Value(1.5)), "1.5"); EXPECT_EQ(perfetto::TracedValueToString(Value("value")), "value"); EXPECT_EQ(perfetto::TracedValueToString(Value(Value::Type::NONE)), ""); { Value::List list; EXPECT_EQ(perfetto::TracedValueToString(list), "{}"); list.Append(2); list.Append(3); EXPECT_EQ(perfetto::TracedValueToString(list), "[2,3]"); EXPECT_EQ(perfetto::TracedValueToString(Value(std::move(list))), "[2,3]"); } { Value::Dict dict; EXPECT_EQ(perfetto::TracedValueToString(dict), "{}"); dict.Set("key", "value"); EXPECT_EQ(perfetto::TracedValueToString(dict), "{key:value}"); EXPECT_EQ(perfetto::TracedValueToString(Value(std::move(dict))), "{key:value}"); } } #endif // BUILDFLAG(ENABLE_BASE_TRACING) TEST(ValueViewTest, BasicConstruction) { { ValueView v = true; EXPECT_EQ(true, absl::get(v.data_view_for_test())); } { ValueView v = 25; EXPECT_EQ(25, absl::get(v.data_view_for_test())); } { ValueView v = 3.14; EXPECT_DOUBLE_EQ(3.14, absl::get( v.data_view_for_test())); } { ValueView v = StringPiece("hello world"); EXPECT_EQ("hello world", absl::get(v.data_view_for_test())); } { ValueView v = "hello world"; EXPECT_EQ("hello world", absl::get(v.data_view_for_test())); } { std::string str = "hello world"; ValueView v = str; EXPECT_EQ("hello world", absl::get(v.data_view_for_test())); } { Value::Dict dict; dict.Set("hello", "world"); ValueView v = dict; EXPECT_EQ(dict, absl::get>( v.data_view_for_test())); } { Value::List list; list.Append("hello"); list.Append("world"); ValueView v = list; EXPECT_EQ(list, absl::get>( v.data_view_for_test())); } } TEST(ValueViewTest, ValueConstruction) { { Value val(true); ValueView v = val; EXPECT_EQ(true, absl::get(v.data_view_for_test())); } { Value val(25); ValueView v = val; EXPECT_EQ(25, absl::get(v.data_view_for_test())); } { Value val(3.14); ValueView v = val; EXPECT_DOUBLE_EQ(3.14, absl::get( v.data_view_for_test())); } { Value val("hello world"); ValueView v = val; EXPECT_EQ("hello world", absl::get(v.data_view_for_test())); } { Value::Dict dict; dict.Set("hello", "world"); Value val(dict.Clone()); ValueView v = val; EXPECT_EQ(dict, absl::get>( v.data_view_for_test())); } { Value::List list; list.Append("hello"); list.Append("world"); Value val(list.Clone()); ValueView v = val; EXPECT_EQ(list, absl::get>( v.data_view_for_test())); } } TEST(ValueViewTest, ToValue) { { Value val(true); Value to_val = ValueView(val).ToValue(); EXPECT_EQ(val, to_val); } { Value val(25); Value to_val = ValueView(val).ToValue(); EXPECT_EQ(val, to_val); } { Value val(3.14); Value to_val = ValueView(val).ToValue(); EXPECT_EQ(val, to_val); } { Value val("hello world"); Value to_val = ValueView(val).ToValue(); EXPECT_EQ(val, to_val); } { Value::Dict dict; dict.Set("hello", "world"); Value val(dict.Clone()); Value to_val = ValueView(val).ToValue(); EXPECT_EQ(val, to_val); } { Value::List list; list.Append("hello"); list.Append("world"); Value val(list.Clone()); Value to_val = ValueView(val).ToValue(); EXPECT_EQ(val, to_val); } } } // namespace base