// Copyright (c) 2010 The Chromium Authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. #include #include "base/scoped_ptr.h" #include "base/string16.h" #include "base/utf_string_conversions.h" #include "base/values.h" #include "testing/gtest/include/gtest/gtest.h" class ValuesTest: public testing::Test { protected: void CompareDictionariesAndCheckResult( const DictionaryValue* dict1, const DictionaryValue* dict2, const char* expected_paths[], size_t expected_paths_count) { std::vector differing_paths; std::vector expected_paths_vector(expected_paths, expected_paths+expected_paths_count); // All comparisons should be commutative, check dict1 against dict2 // and vice-versa. dict1->GetDifferingPaths(dict2, &differing_paths); ASSERT_EQ(expected_paths_count, differing_paths.size()); EXPECT_TRUE(equal(differing_paths.begin(), differing_paths.end(), expected_paths_vector.begin())); dict2->GetDifferingPaths(dict1, &differing_paths); ASSERT_EQ(expected_paths_count, differing_paths.size()); EXPECT_TRUE(equal(differing_paths.begin(), differing_paths.end(), expected_paths_vector.begin())); } }; TEST_F(ValuesTest, Basic) { // Test basic dictionary getting/setting DictionaryValue settings; std::string homepage = "http://google.com"; ASSERT_FALSE(settings.GetString("global.homepage", &homepage)); ASSERT_EQ(std::string("http://google.com"), homepage); ASSERT_FALSE(settings.Get("global", NULL)); settings.Set("global", Value::CreateBooleanValue(true)); ASSERT_TRUE(settings.Get("global", NULL)); settings.SetString("global.homepage", "http://scurvy.com"); ASSERT_TRUE(settings.Get("global", NULL)); homepage = "http://google.com"; ASSERT_TRUE(settings.GetString("global.homepage", &homepage)); ASSERT_EQ(std::string("http://scurvy.com"), homepage); // Test storing a dictionary in a list. ListValue* toolbar_bookmarks; ASSERT_FALSE( settings.GetList("global.toolbar.bookmarks", &toolbar_bookmarks)); toolbar_bookmarks = new ListValue; settings.Set("global.toolbar.bookmarks", toolbar_bookmarks); ASSERT_TRUE(settings.GetList("global.toolbar.bookmarks", &toolbar_bookmarks)); DictionaryValue* new_bookmark = new DictionaryValue; new_bookmark->SetString("name", "Froogle"); new_bookmark->SetString("url", "http://froogle.com"); toolbar_bookmarks->Append(new_bookmark); ListValue* bookmark_list; ASSERT_TRUE(settings.GetList("global.toolbar.bookmarks", &bookmark_list)); DictionaryValue* bookmark; ASSERT_EQ(1U, bookmark_list->GetSize()); ASSERT_TRUE(bookmark_list->GetDictionary(0, &bookmark)); std::string bookmark_name = "Unnamed"; ASSERT_TRUE(bookmark->GetString("name", &bookmark_name)); ASSERT_EQ(std::string("Froogle"), bookmark_name); std::string bookmark_url; ASSERT_TRUE(bookmark->GetString("url", &bookmark_url)); ASSERT_EQ(std::string("http://froogle.com"), bookmark_url); } TEST_F(ValuesTest, List) { scoped_ptr mixed_list(new ListValue()); mixed_list->Set(0, Value::CreateBooleanValue(true)); mixed_list->Set(1, Value::CreateIntegerValue(42)); mixed_list->Set(2, Value::CreateRealValue(88.8)); mixed_list->Set(3, Value::CreateStringValue("foo")); ASSERT_EQ(4u, mixed_list->GetSize()); Value *value = NULL; bool bool_value = false; int int_value = 0; double double_value = 0.0; std::string string_value; ASSERT_FALSE(mixed_list->Get(4, &value)); ASSERT_FALSE(mixed_list->GetInteger(0, &int_value)); ASSERT_EQ(0, int_value); ASSERT_FALSE(mixed_list->GetReal(1, &double_value)); ASSERT_EQ(0.0, double_value); ASSERT_FALSE(mixed_list->GetString(2, &string_value)); ASSERT_EQ("", string_value); ASSERT_FALSE(mixed_list->GetBoolean(3, &bool_value)); ASSERT_EQ(false, bool_value); ASSERT_TRUE(mixed_list->GetBoolean(0, &bool_value)); ASSERT_EQ(true, bool_value); ASSERT_TRUE(mixed_list->GetInteger(1, &int_value)); ASSERT_EQ(42, int_value); ASSERT_TRUE(mixed_list->GetReal(2, &double_value)); ASSERT_EQ(88.8, double_value); ASSERT_TRUE(mixed_list->GetString(3, &string_value)); ASSERT_EQ("foo", string_value); } TEST_F(ValuesTest, BinaryValue) { char* buffer = NULL; // Passing a null buffer pointer doesn't yield a BinaryValue scoped_ptr binary(BinaryValue::Create(buffer, 0)); ASSERT_FALSE(binary.get()); // If you want to represent an empty binary value, use a zero-length buffer. buffer = new char[1]; ASSERT_TRUE(buffer); binary.reset(BinaryValue::Create(buffer, 0)); ASSERT_TRUE(binary.get()); ASSERT_TRUE(binary->GetBuffer()); ASSERT_EQ(buffer, binary->GetBuffer()); ASSERT_EQ(0U, binary->GetSize()); // Test the common case of a non-empty buffer buffer = new char[15]; binary.reset(BinaryValue::Create(buffer, 15)); ASSERT_TRUE(binary.get()); ASSERT_TRUE(binary->GetBuffer()); ASSERT_EQ(buffer, binary->GetBuffer()); ASSERT_EQ(15U, binary->GetSize()); char stack_buffer[42]; memset(stack_buffer, '!', 42); binary.reset(BinaryValue::CreateWithCopiedBuffer(stack_buffer, 42)); ASSERT_TRUE(binary.get()); ASSERT_TRUE(binary->GetBuffer()); ASSERT_NE(stack_buffer, binary->GetBuffer()); ASSERT_EQ(42U, binary->GetSize()); ASSERT_EQ(0, memcmp(stack_buffer, binary->GetBuffer(), binary->GetSize())); } TEST_F(ValuesTest, StringValue) { // Test overloaded CreateStringValue. scoped_ptr narrow_value(Value::CreateStringValue("narrow")); ASSERT_TRUE(narrow_value.get()); ASSERT_TRUE(narrow_value->IsType(Value::TYPE_STRING)); scoped_ptr utf16_value( Value::CreateStringValue(ASCIIToUTF16("utf16"))); ASSERT_TRUE(utf16_value.get()); ASSERT_TRUE(utf16_value->IsType(Value::TYPE_STRING)); // Test overloaded GetString. std::string narrow = "http://google.com"; string16 utf16 = ASCIIToUTF16("http://google.com"); ASSERT_TRUE(narrow_value->GetAsString(&narrow)); ASSERT_TRUE(narrow_value->GetAsString(&utf16)); ASSERT_EQ(std::string("narrow"), narrow); ASSERT_EQ(ASCIIToUTF16("narrow"), utf16); ASSERT_TRUE(utf16_value->GetAsString(&narrow)); ASSERT_TRUE(utf16_value->GetAsString(&utf16)); ASSERT_EQ(std::string("utf16"), narrow); ASSERT_EQ(ASCIIToUTF16("utf16"), utf16); } // This is a Value object that allows us to tell if it's been // properly deleted by modifying the value of external flag on destruction. class DeletionTestValue : public Value { public: explicit DeletionTestValue(bool* deletion_flag) : Value(TYPE_NULL) { Init(deletion_flag); // Separate function so that we can use ASSERT_* } void Init(bool* deletion_flag) { ASSERT_TRUE(deletion_flag); deletion_flag_ = deletion_flag; *deletion_flag_ = false; } ~DeletionTestValue() { *deletion_flag_ = true; } private: bool* deletion_flag_; }; TEST_F(ValuesTest, ListDeletion) { bool deletion_flag = true; { ListValue list; list.Append(new DeletionTestValue(&deletion_flag)); EXPECT_FALSE(deletion_flag); } EXPECT_TRUE(deletion_flag); { ListValue list; list.Append(new DeletionTestValue(&deletion_flag)); EXPECT_FALSE(deletion_flag); list.Clear(); EXPECT_TRUE(deletion_flag); } { ListValue list; list.Append(new DeletionTestValue(&deletion_flag)); EXPECT_FALSE(deletion_flag); EXPECT_TRUE(list.Set(0, Value::CreateNullValue())); EXPECT_TRUE(deletion_flag); } } TEST_F(ValuesTest, ListRemoval) { bool deletion_flag = true; Value* removed_item = NULL; { ListValue list; list.Append(new DeletionTestValue(&deletion_flag)); EXPECT_FALSE(deletion_flag); EXPECT_EQ(1U, list.GetSize()); EXPECT_FALSE(list.Remove(std::numeric_limits::max(), &removed_item)); EXPECT_FALSE(list.Remove(1, &removed_item)); EXPECT_TRUE(list.Remove(0, &removed_item)); ASSERT_TRUE(removed_item); EXPECT_EQ(0U, list.GetSize()); } EXPECT_FALSE(deletion_flag); delete removed_item; removed_item = NULL; EXPECT_TRUE(deletion_flag); { ListValue list; list.Append(new DeletionTestValue(&deletion_flag)); EXPECT_FALSE(deletion_flag); EXPECT_TRUE(list.Remove(0, NULL)); EXPECT_TRUE(deletion_flag); EXPECT_EQ(0U, list.GetSize()); } { ListValue list; DeletionTestValue* value = new DeletionTestValue(&deletion_flag); list.Append(value); EXPECT_FALSE(deletion_flag); EXPECT_EQ(0, list.Remove(*value)); EXPECT_TRUE(deletion_flag); EXPECT_EQ(0U, list.GetSize()); } } TEST_F(ValuesTest, DictionaryDeletion) { std::string key = "test"; bool deletion_flag = true; { DictionaryValue dict; dict.Set(key, new DeletionTestValue(&deletion_flag)); EXPECT_FALSE(deletion_flag); } EXPECT_TRUE(deletion_flag); { DictionaryValue dict; dict.Set(key, new DeletionTestValue(&deletion_flag)); EXPECT_FALSE(deletion_flag); dict.Clear(); EXPECT_TRUE(deletion_flag); } { DictionaryValue dict; dict.Set(key, new DeletionTestValue(&deletion_flag)); EXPECT_FALSE(deletion_flag); dict.Set(key, Value::CreateNullValue()); EXPECT_TRUE(deletion_flag); } } TEST_F(ValuesTest, DictionaryRemoval) { std::string key = "test"; bool deletion_flag = true; Value* removed_item = NULL; { DictionaryValue dict; dict.Set(key, new DeletionTestValue(&deletion_flag)); EXPECT_FALSE(deletion_flag); EXPECT_TRUE(dict.HasKey(key)); EXPECT_FALSE(dict.Remove("absent key", &removed_item)); EXPECT_TRUE(dict.Remove(key, &removed_item)); EXPECT_FALSE(dict.HasKey(key)); ASSERT_TRUE(removed_item); } EXPECT_FALSE(deletion_flag); delete removed_item; removed_item = NULL; EXPECT_TRUE(deletion_flag); { DictionaryValue dict; dict.Set(key, new DeletionTestValue(&deletion_flag)); EXPECT_FALSE(deletion_flag); EXPECT_TRUE(dict.HasKey(key)); EXPECT_TRUE(dict.Remove(key, NULL)); EXPECT_TRUE(deletion_flag); EXPECT_FALSE(dict.HasKey(key)); } } TEST_F(ValuesTest, DictionaryWithoutPathExpansion) { DictionaryValue dict; dict.Set("this.is.expanded", Value::CreateNullValue()); dict.SetWithoutPathExpansion("this.isnt.expanded", Value::CreateNullValue()); EXPECT_FALSE(dict.HasKey("this.is.expanded")); EXPECT_TRUE(dict.HasKey("this")); Value* value1; EXPECT_TRUE(dict.Get("this", &value1)); DictionaryValue* value2; ASSERT_TRUE(dict.GetDictionaryWithoutPathExpansion("this", &value2)); EXPECT_EQ(value1, value2); EXPECT_EQ(1U, value2->size()); EXPECT_TRUE(dict.HasKey("this.isnt.expanded")); Value* value3; EXPECT_FALSE(dict.Get("this.isnt.expanded", &value3)); Value* value4; ASSERT_TRUE(dict.GetWithoutPathExpansion("this.isnt.expanded", &value4)); EXPECT_EQ(Value::TYPE_NULL, value4->GetType()); } TEST_F(ValuesTest, DeepCopy) { DictionaryValue original_dict; Value* original_null = Value::CreateNullValue(); original_dict.Set("null", original_null); Value* original_bool = Value::CreateBooleanValue(true); original_dict.Set("bool", original_bool); Value* original_int = Value::CreateIntegerValue(42); original_dict.Set("int", original_int); Value* original_real = Value::CreateRealValue(3.14); original_dict.Set("real", original_real); Value* original_string = Value::CreateStringValue("hello"); original_dict.Set("string", original_string); Value* original_string16 = Value::CreateStringValue(ASCIIToUTF16("hello16")); original_dict.Set("string16", original_string16); char* original_buffer = new char[42]; memset(original_buffer, '!', 42); BinaryValue* original_binary = Value::CreateBinaryValue(original_buffer, 42); original_dict.Set("binary", original_binary); ListValue* original_list = new ListValue(); Value* original_list_element_0 = Value::CreateIntegerValue(0); original_list->Append(original_list_element_0); Value* original_list_element_1 = Value::CreateIntegerValue(1); original_list->Append(original_list_element_1); original_dict.Set("list", original_list); scoped_ptr copy_dict( static_cast(original_dict.DeepCopy())); ASSERT_TRUE(copy_dict.get()); ASSERT_NE(copy_dict.get(), &original_dict); Value* copy_null = NULL; ASSERT_TRUE(copy_dict->Get("null", ©_null)); ASSERT_TRUE(copy_null); ASSERT_NE(copy_null, original_null); ASSERT_TRUE(copy_null->IsType(Value::TYPE_NULL)); Value* copy_bool = NULL; ASSERT_TRUE(copy_dict->Get("bool", ©_bool)); ASSERT_TRUE(copy_bool); ASSERT_NE(copy_bool, original_bool); ASSERT_TRUE(copy_bool->IsType(Value::TYPE_BOOLEAN)); bool copy_bool_value = false; ASSERT_TRUE(copy_bool->GetAsBoolean(©_bool_value)); ASSERT_TRUE(copy_bool_value); Value* copy_int = NULL; ASSERT_TRUE(copy_dict->Get("int", ©_int)); ASSERT_TRUE(copy_int); ASSERT_NE(copy_int, original_int); ASSERT_TRUE(copy_int->IsType(Value::TYPE_INTEGER)); int copy_int_value = 0; ASSERT_TRUE(copy_int->GetAsInteger(©_int_value)); ASSERT_EQ(42, copy_int_value); Value* copy_real = NULL; ASSERT_TRUE(copy_dict->Get("real", ©_real)); ASSERT_TRUE(copy_real); ASSERT_NE(copy_real, original_real); ASSERT_TRUE(copy_real->IsType(Value::TYPE_REAL)); double copy_real_value = 0; ASSERT_TRUE(copy_real->GetAsReal(©_real_value)); ASSERT_EQ(3.14, copy_real_value); Value* copy_string = NULL; ASSERT_TRUE(copy_dict->Get("string", ©_string)); ASSERT_TRUE(copy_string); ASSERT_NE(copy_string, original_string); ASSERT_TRUE(copy_string->IsType(Value::TYPE_STRING)); std::string copy_string_value; string16 copy_string16_value; ASSERT_TRUE(copy_string->GetAsString(©_string_value)); ASSERT_TRUE(copy_string->GetAsString(©_string16_value)); ASSERT_EQ(std::string("hello"), copy_string_value); ASSERT_EQ(ASCIIToUTF16("hello"), copy_string16_value); Value* copy_string16 = NULL; ASSERT_TRUE(copy_dict->Get("string16", ©_string16)); ASSERT_TRUE(copy_string16); ASSERT_NE(copy_string16, original_string16); ASSERT_TRUE(copy_string16->IsType(Value::TYPE_STRING)); ASSERT_TRUE(copy_string16->GetAsString(©_string_value)); ASSERT_TRUE(copy_string16->GetAsString(©_string16_value)); ASSERT_EQ(std::string("hello16"), copy_string_value); ASSERT_EQ(ASCIIToUTF16("hello16"), copy_string16_value); Value* copy_binary = NULL; ASSERT_TRUE(copy_dict->Get("binary", ©_binary)); ASSERT_TRUE(copy_binary); ASSERT_NE(copy_binary, original_binary); ASSERT_TRUE(copy_binary->IsType(Value::TYPE_BINARY)); ASSERT_NE(original_binary->GetBuffer(), static_cast(copy_binary)->GetBuffer()); ASSERT_EQ(original_binary->GetSize(), static_cast(copy_binary)->GetSize()); ASSERT_EQ(0, memcmp(original_binary->GetBuffer(), static_cast(copy_binary)->GetBuffer(), original_binary->GetSize())); Value* copy_value = NULL; ASSERT_TRUE(copy_dict->Get("list", ©_value)); ASSERT_TRUE(copy_value); ASSERT_NE(copy_value, original_list); ASSERT_TRUE(copy_value->IsType(Value::TYPE_LIST)); ListValue* copy_list = static_cast(copy_value); ASSERT_EQ(2U, copy_list->GetSize()); Value* copy_list_element_0; ASSERT_TRUE(copy_list->Get(0, ©_list_element_0)); ASSERT_TRUE(copy_list_element_0); ASSERT_NE(copy_list_element_0, original_list_element_0); int copy_list_element_0_value; ASSERT_TRUE(copy_list_element_0->GetAsInteger(©_list_element_0_value)); ASSERT_EQ(0, copy_list_element_0_value); Value* copy_list_element_1; ASSERT_TRUE(copy_list->Get(1, ©_list_element_1)); ASSERT_TRUE(copy_list_element_1); ASSERT_NE(copy_list_element_1, original_list_element_1); int copy_list_element_1_value; ASSERT_TRUE(copy_list_element_1->GetAsInteger(©_list_element_1_value)); ASSERT_EQ(1, copy_list_element_1_value); } TEST_F(ValuesTest, Equals) { Value* null1 = Value::CreateNullValue(); Value* null2 = Value::CreateNullValue(); EXPECT_NE(null1, null2); EXPECT_TRUE(null1->Equals(null2)); Value* boolean = Value::CreateBooleanValue(false); EXPECT_FALSE(null1->Equals(boolean)); delete null1; delete null2; delete boolean; DictionaryValue dv; dv.SetBoolean("a", false); dv.SetInteger("b", 2); dv.SetReal("c", 2.5); dv.SetString("d1", "string"); dv.SetString("d2", ASCIIToUTF16("http://google.com")); dv.Set("e", Value::CreateNullValue()); scoped_ptr copy; copy.reset(static_cast(dv.DeepCopy())); EXPECT_TRUE(dv.Equals(copy.get())); ListValue* list = new ListValue; list->Append(Value::CreateNullValue()); list->Append(new DictionaryValue); dv.Set("f", list); EXPECT_FALSE(dv.Equals(copy.get())); copy->Set("f", list->DeepCopy()); EXPECT_TRUE(dv.Equals(copy.get())); list->Append(Value::CreateBooleanValue(true)); EXPECT_FALSE(dv.Equals(copy.get())); // Check if Equals detects differences in only the keys. copy.reset(static_cast(dv.DeepCopy())); EXPECT_TRUE(dv.Equals(copy.get())); copy->Remove("a", NULL); copy->SetBoolean("aa", false); EXPECT_FALSE(dv.Equals(copy.get())); } TEST_F(ValuesTest, RemoveEmptyChildren) { scoped_ptr root(new DictionaryValue); // Remove empty lists and dictionaries. root->Set("empty_dict", new DictionaryValue); root->Set("empty_list", new ListValue); root->SetWithoutPathExpansion("a.b.c.d.e", new DictionaryValue); root.reset(root->DeepCopyWithoutEmptyChildren()); EXPECT_TRUE(root->empty()); // Make sure we don't prune too much. root->SetBoolean("bool", true); root->Set("empty_dict", new DictionaryValue); root->SetString("empty_string", ""); root.reset(root->DeepCopyWithoutEmptyChildren()); EXPECT_EQ(2U, root->size()); // Should do nothing. root.reset(root->DeepCopyWithoutEmptyChildren()); EXPECT_EQ(2U, root->size()); // Nested test cases. These should all reduce back to the bool and string // set above. { root->Set("a.b.c.d.e", new DictionaryValue); root.reset(root->DeepCopyWithoutEmptyChildren()); EXPECT_EQ(2U, root->size()); } { DictionaryValue* inner = new DictionaryValue; root->Set("dict_with_emtpy_children", inner); inner->Set("empty_dict", new DictionaryValue); inner->Set("empty_list", new ListValue); root.reset(root->DeepCopyWithoutEmptyChildren()); EXPECT_EQ(2U, root->size()); } { ListValue* inner = new ListValue; root->Set("list_with_empty_children", inner); inner->Append(new DictionaryValue); inner->Append(new ListValue); root.reset(root->DeepCopyWithoutEmptyChildren()); EXPECT_EQ(2U, root->size()); } // Nested with siblings. { ListValue* inner = new ListValue; root->Set("list_with_empty_children", inner); inner->Append(new DictionaryValue); inner->Append(new ListValue); DictionaryValue* inner2 = new DictionaryValue; root->Set("dict_with_empty_children", inner2); inner2->Set("empty_dict", new DictionaryValue); inner2->Set("empty_list", new ListValue); root.reset(root->DeepCopyWithoutEmptyChildren()); EXPECT_EQ(2U, root->size()); } // Make sure nested values don't get pruned. { ListValue* inner = new ListValue; root->Set("list_with_empty_children", inner); ListValue* inner2 = new ListValue; inner->Append(new DictionaryValue); inner->Append(inner2); inner2->Append(Value::CreateStringValue("hello")); root.reset(root->DeepCopyWithoutEmptyChildren()); EXPECT_EQ(3U, root->size()); EXPECT_TRUE(root->GetList("list_with_empty_children", &inner)); EXPECT_EQ(1U, inner->GetSize()); // Dictionary was pruned. EXPECT_TRUE(inner->GetList(0, &inner2)); EXPECT_EQ(1U, inner2->GetSize()); } } TEST_F(ValuesTest, MergeDictionary) { scoped_ptr base(new DictionaryValue); base->SetString("base_key", "base_key_value_base"); base->SetString("collide_key", "collide_key_value_base"); DictionaryValue* base_sub_dict = new DictionaryValue; base_sub_dict->SetString("sub_base_key", "sub_base_key_value_base"); base_sub_dict->SetString("sub_collide_key", "sub_collide_key_value_base"); base->Set("sub_dict_key", base_sub_dict); scoped_ptr merge(new DictionaryValue); merge->SetString("merge_key", "merge_key_value_merge"); merge->SetString("collide_key", "collide_key_value_merge"); DictionaryValue* merge_sub_dict = new DictionaryValue; merge_sub_dict->SetString("sub_merge_key", "sub_merge_key_value_merge"); merge_sub_dict->SetString("sub_collide_key", "sub_collide_key_value_merge"); merge->Set("sub_dict_key", merge_sub_dict); base->MergeDictionary(merge.get()); EXPECT_EQ(4U, base->size()); std::string base_key_value; EXPECT_TRUE(base->GetString("base_key", &base_key_value)); EXPECT_EQ("base_key_value_base", base_key_value); // Base value preserved. std::string collide_key_value; EXPECT_TRUE(base->GetString("collide_key", &collide_key_value)); EXPECT_EQ("collide_key_value_merge", collide_key_value); // Replaced. std::string merge_key_value; EXPECT_TRUE(base->GetString("merge_key", &merge_key_value)); EXPECT_EQ("merge_key_value_merge", merge_key_value); // Merged in. DictionaryValue* res_sub_dict; EXPECT_TRUE(base->GetDictionary("sub_dict_key", &res_sub_dict)); EXPECT_EQ(3U, res_sub_dict->size()); std::string sub_base_key_value; EXPECT_TRUE(res_sub_dict->GetString("sub_base_key", &sub_base_key_value)); EXPECT_EQ("sub_base_key_value_base", sub_base_key_value); // Preserved. std::string sub_collide_key_value; EXPECT_TRUE(res_sub_dict->GetString("sub_collide_key", &sub_collide_key_value)); EXPECT_EQ("sub_collide_key_value_merge", sub_collide_key_value); // Replaced. std::string sub_merge_key_value; EXPECT_TRUE(res_sub_dict->GetString("sub_merge_key", &sub_merge_key_value)); EXPECT_EQ("sub_merge_key_value_merge", sub_merge_key_value); // Merged in. } TEST_F(ValuesTest, GetDifferingPaths) { scoped_ptr dict1(new DictionaryValue()); scoped_ptr dict2(new DictionaryValue()); std::vector differing_paths; // Test comparing empty dictionaries. dict1->GetDifferingPaths(dict2.get(), &differing_paths); EXPECT_EQ(differing_paths.size(), 0UL); // Compare an empty dictionary with various non-empty dictionaries. static const char* expected_paths1[] = { "segment1" }; dict1->SetString("segment1", "value1"); CompareDictionariesAndCheckResult(dict1.get(), dict2.get(), expected_paths1, arraysize(expected_paths1)); static const char* expected_paths2[] = { "segment1", "segment2", "segment2.segment3" }; dict1->SetString("segment2.segment3", "value2"); CompareDictionariesAndCheckResult(dict1.get(), dict2.get(), expected_paths2, arraysize(expected_paths2)); static const char* expected_paths3[] = { "segment1", "segment2", "segment2.segment3", "segment4", "segment4.segment5" }; dict1->SetString("segment4.segment5", "value3"); CompareDictionariesAndCheckResult(dict1.get(), dict2.get(), expected_paths3, arraysize(expected_paths3)); // Now various tests with two populated dictionaries. static const char* expected_paths4[] = { "segment1", "segment2", "segment2.segment3", "segment4", "segment4.segment5" }; dict2->Set("segment2", new DictionaryValue()); CompareDictionariesAndCheckResult(dict1.get(), dict2.get(), expected_paths4, arraysize(expected_paths4)); static const char* expected_paths5[] = { "segment1", "segment4", "segment4.segment5" }; dict2->SetString("segment2.segment3", "value2"); CompareDictionariesAndCheckResult(dict1.get(), dict2.get(), expected_paths5, arraysize(expected_paths5)); dict2->SetBoolean("segment2.segment3", true); CompareDictionariesAndCheckResult(dict1.get(), dict2.get(), expected_paths4, arraysize(expected_paths4)); // Test two identical dictionaries. dict2.reset(static_cast(dict1->DeepCopy())); dict2->GetDifferingPaths(dict1.get(), &differing_paths); EXPECT_EQ(differing_paths.size(), 0UL); // Test a deep dictionary structure. static const char* expected_paths6[] = { "s1", "s1.s2", "s1.s2.s3", "s1.s2.s3.s4", "s1.s2.s3.s4.s5" }; dict1.reset(new DictionaryValue()); dict2.reset(new DictionaryValue()); dict1->Set("s1.s2.s3.s4.s5", new DictionaryValue()); CompareDictionariesAndCheckResult(dict1.get(), dict2.get(), expected_paths6, arraysize(expected_paths6)); // Make sure disjoint dictionaries generate the right differing path list. static const char* expected_paths7[] = { "a", "b", "c", "d" }; dict1.reset(new DictionaryValue()); dict1->SetBoolean("a", true); dict1->SetBoolean("c", true); dict2.reset(new DictionaryValue()); dict1->SetBoolean("b", true); dict1->SetBoolean("d", true); CompareDictionariesAndCheckResult(dict1.get(), dict2.get(), expected_paths7, arraysize(expected_paths7)); // For code coverage completeness. Make sure that all branches // that were not covered are executed. static const char* expected_paths8[] = { "s1", "s1.s2" }; dict1.reset(new DictionaryValue()); dict1->Set("s1.s2", new DictionaryValue()); dict2.reset(new DictionaryValue()); dict2->SetInteger("s1", 1); CompareDictionariesAndCheckResult(dict1.get(), dict2.get(), expected_paths8, arraysize(expected_paths8)); }