// 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/json/json_reader.h" #include #include #include #include #include "base/base_paths.h" #include "base/features.h" #include "base/files/file_util.h" #include "base/logging.h" #include "base/path_service.h" #include "base/rust_buildflags.h" #include "base/strings/stringprintf.h" #include "base/strings/utf_string_conversions.h" #include "base/test/gmock_expected_support.h" #include "base/test/metrics/histogram_tester.h" #include "base/test/scoped_feature_list.h" #include "base/values.h" #include "build/build_config.h" #include "testing/gmock/include/gmock/gmock.h" #include "testing/gtest/include/gtest/gtest.h" namespace { // MSan will do a better job detecting over-read errors if the input is not // nul-terminated on the heap. This will copy |input| to a new buffer owned by // |owner|, returning a std::string_view to |owner|. std::string_view MakeNotNullTerminatedInput(const char* input, std::unique_ptr* owner) { size_t str_len = strlen(input); owner->reset(new char[str_len]); memcpy(owner->get(), input, str_len); return std::string_view(owner->get(), str_len); } } // namespace namespace base { class JSONReaderTest : public testing::TestWithParam { public: void SetUp() override { feature_list_.InitWithFeatureState(base::features::kUseRustJsonParser, using_rust_); } protected: bool using_rust_ = GetParam(); base::test::ScopedFeatureList feature_list_; }; TEST_P(JSONReaderTest, Whitespace) { std::optional root = JSONReader::Read(" null "); ASSERT_TRUE(root); EXPECT_TRUE(root->is_none()); } TEST_P(JSONReaderTest, InvalidString) { // These are invalid because they do not represent a JSON value, // see https://tools.ietf.org/rfc/rfc8259.txt EXPECT_FALSE(JSONReader::Read("")); EXPECT_FALSE(JSONReader::Read("nu")); } TEST_P(JSONReaderTest, SimpleBool) { #if BUILDFLAG(BUILD_RUST_JSON_READER) base::HistogramTester histograms; #endif // BUILDFLAG(BUILD_RUST_JSON_READER) std::optional root = JSONReader::Read("true "); ASSERT_TRUE(root); EXPECT_TRUE(root->is_bool()); #if BUILDFLAG(BUILD_RUST_JSON_READER) histograms.ExpectTotalCount("Security.JSONParser.ParsingTime", 1); #endif // BUILDFLAG(BUILD_RUST_JSON_READER) } TEST_P(JSONReaderTest, EmbeddedComments) { std::optional root = JSONReader::Read("/* comment */null"); ASSERT_TRUE(root); EXPECT_TRUE(root->is_none()); root = JSONReader::Read("40 /* comment */"); ASSERT_TRUE(root); EXPECT_TRUE(root->is_int()); root = JSONReader::Read("true // comment"); ASSERT_TRUE(root); EXPECT_TRUE(root->is_bool()); // Comments in different contexts. root = JSONReader::Read("{ \"cheese\": 3\n\n // Here's a comment\n}"); ASSERT_TRUE(root); EXPECT_TRUE(root->is_dict()); root = JSONReader::Read("{ \"cheese\": 3// Here's a comment\n}"); ASSERT_TRUE(root); EXPECT_TRUE(root->is_dict()); // Multiple comment markers. root = JSONReader::Read( "{ \"cheese\": 3// Here's a comment // and another\n}"); ASSERT_TRUE(root); EXPECT_TRUE(root->is_dict()); root = JSONReader::Read("/* comment */\"sample string\""); ASSERT_TRUE(root); ASSERT_TRUE(root->is_string()); EXPECT_EQ("sample string", root->GetString()); root = JSONReader::Read("[1, /* comment, 2 ] */ \n 3]"); ASSERT_TRUE(root); Value::List* list = root->GetIfList(); ASSERT_TRUE(list); ASSERT_EQ(2u, list->size()); ASSERT_TRUE((*list)[0].is_int()); EXPECT_EQ(1, (*list)[0].GetInt()); ASSERT_TRUE((*list)[1].is_int()); EXPECT_EQ(3, (*list)[1].GetInt()); root = JSONReader::Read("[1, /*a*/2, 3]"); ASSERT_TRUE(root); list = root->GetIfList(); ASSERT_TRUE(list); EXPECT_EQ(3u, (*list).size()); root = JSONReader::Read("/* comment **/42"); ASSERT_TRUE(root); ASSERT_TRUE(root->is_int()); EXPECT_EQ(42, root->GetInt()); root = JSONReader::Read( "/* comment **/\n" "// */ 43\n" "44"); ASSERT_TRUE(root); EXPECT_TRUE(root->is_int()); EXPECT_EQ(44, root->GetInt()); // At one point, this parsed successfully as the value three. EXPECT_FALSE(JSONReader::Read("/33")); } TEST_P(JSONReaderTest, Ints) { std::optional root = JSONReader::Read("43"); ASSERT_TRUE(root); ASSERT_TRUE(root->is_int()); EXPECT_EQ(43, root->GetInt()); } TEST_P(JSONReaderTest, NonDecimalNumbers) { // According to RFC 8259, oct, hex, and leading zeros are invalid JSON. EXPECT_FALSE(JSONReader::Read("043")); EXPECT_FALSE(JSONReader::Read("0x43")); EXPECT_FALSE(JSONReader::Read("00")); } TEST_P(JSONReaderTest, NumberZero) { // Test 0 (which needs to be special cased because of the leading zero // clause). std::optional root = JSONReader::Read("0"); ASSERT_TRUE(root); ASSERT_TRUE(root->is_int()); EXPECT_EQ(0, root->GetInt()); } TEST_P(JSONReaderTest, LargeIntPromotion) { // Numbers that overflow ints should succeed, being internally promoted to // storage as doubles std::optional root = JSONReader::Read("2147483648"); ASSERT_TRUE(root); EXPECT_TRUE(root->is_double()); EXPECT_DOUBLE_EQ(2147483648.0, root->GetDouble()); root = JSONReader::Read("-2147483649"); ASSERT_TRUE(root); EXPECT_TRUE(root->is_double()); EXPECT_DOUBLE_EQ(-2147483649.0, root->GetDouble()); } TEST_P(JSONReaderTest, LargerIntIsLossy) { // Parse LONG_MAX as a JSON number (not a JSON string). The result of the // parse is a base::Value, either a (32-bit) int or a (64-bit) double. // LONG_MAX would overflow an int and can only be approximated by a double. // In this case, parsing is lossy. const char* etc807 = "9223372036854775807"; const char* etc808 = "9223372036854775808.000000"; std::optional root = JSONReader::Read(etc807); ASSERT_TRUE(root); ASSERT_FALSE(root->is_int()); ASSERT_TRUE(root->is_double()); // We use StringPrintf instead of NumberToString, because the NumberToString // function does not let you specify the precision, and its default output, // "9.223372036854776e+18", isn't precise enough to see the lossiness. EXPECT_EQ(std::string(etc808), StringPrintf("%f", root->GetDouble())); } TEST_P(JSONReaderTest, Doubles) { std::optional root = JSONReader::Read("43.1"); ASSERT_TRUE(root); EXPECT_TRUE(root->is_double()); EXPECT_DOUBLE_EQ(43.1, root->GetDouble()); root = JSONReader::Read("4.3e-1"); ASSERT_TRUE(root); EXPECT_TRUE(root->is_double()); EXPECT_DOUBLE_EQ(.43, root->GetDouble()); root = JSONReader::Read("2.1e0"); ASSERT_TRUE(root); EXPECT_TRUE(root->is_double()); EXPECT_DOUBLE_EQ(2.1, root->GetDouble()); root = JSONReader::Read("2.1e+0001"); ASSERT_TRUE(root); EXPECT_TRUE(root->is_double()); EXPECT_DOUBLE_EQ(21.0, root->GetDouble()); root = JSONReader::Read("0.01"); ASSERT_TRUE(root); EXPECT_TRUE(root->is_double()); EXPECT_DOUBLE_EQ(0.01, root->GetDouble()); root = JSONReader::Read("1.00"); ASSERT_TRUE(root); EXPECT_TRUE(root->is_double()); EXPECT_DOUBLE_EQ(1.0, root->GetDouble()); // Some "parse to float64" implementations find this one tricky. // https://github.com/serde-rs/json/issues/707 root = JSONReader::Read("122.416294033786585"); ASSERT_TRUE(root); EXPECT_TRUE(root->is_double()); EXPECT_DOUBLE_EQ(122.416294033786585, root->GetDouble()); // This is syntaxtically valid, but out of range of a double. auto value = JSONReader::ReadAndReturnValueWithError("1e1000", JSON_PARSE_RFC); ASSERT_FALSE(value.has_value()); } TEST_P(JSONReaderTest, FractionalNumbers) { // Fractional parts must have a digit before and after the decimal point. EXPECT_FALSE(JSONReader::Read("1.")); EXPECT_FALSE(JSONReader::Read(".1")); EXPECT_FALSE(JSONReader::Read("1.e10")); } TEST_P(JSONReaderTest, ExponentialNumbers) { // Exponent must have a digit following the 'e'. EXPECT_FALSE(JSONReader::Read("1e")); EXPECT_FALSE(JSONReader::Read("1E")); EXPECT_FALSE(JSONReader::Read("1e1.")); EXPECT_FALSE(JSONReader::Read("1e1.0")); } TEST_P(JSONReaderTest, InvalidInfNAN) { // The largest finite double is roughly 1.8e308. EXPECT_FALSE(JSONReader::Read("1e1000")); EXPECT_FALSE(JSONReader::Read("-1e1000")); EXPECT_FALSE(JSONReader::Read("NaN")); EXPECT_FALSE(JSONReader::Read("nan")); EXPECT_FALSE(JSONReader::Read("inf")); } TEST_P(JSONReaderTest, InvalidNumbers) { EXPECT_TRUE(JSONReader::Read("4.3")); EXPECT_FALSE(JSONReader::Read("4.")); EXPECT_FALSE(JSONReader::Read("4.3.1")); EXPECT_FALSE(JSONReader::Read("4e3.1")); EXPECT_FALSE(JSONReader::Read("4.a")); EXPECT_FALSE(JSONReader::Read("42a")); } TEST_P(JSONReaderTest, Zeroes) { std::optional root = JSONReader::Read("0"); ASSERT_TRUE(root); EXPECT_TRUE(root->is_int()); EXPECT_DOUBLE_EQ(0, root->GetInt()); root = JSONReader::Read("0.0"); ASSERT_TRUE(root); EXPECT_TRUE(root->is_double()); EXPECT_DOUBLE_EQ(0.0, root->GetDouble()); EXPECT_FALSE(std::signbit(root->GetDouble())); root = JSONReader::Read("-0"); ASSERT_TRUE(root); EXPECT_TRUE(root->is_double()); EXPECT_DOUBLE_EQ(0.0, root->GetDouble()); EXPECT_TRUE(std::signbit(root->GetDouble())); root = JSONReader::Read("-0.0"); ASSERT_TRUE(root); EXPECT_TRUE(root->is_double()); EXPECT_DOUBLE_EQ(-0.0, root->GetDouble()); EXPECT_TRUE(std::signbit(root->GetDouble())); } TEST_P(JSONReaderTest, SimpleString) { std::optional root = JSONReader::Read("\"hello world\""); ASSERT_TRUE(root); ASSERT_TRUE(root->is_string()); EXPECT_EQ("hello world", root->GetString()); } TEST_P(JSONReaderTest, EmptyString) { std::optional root = JSONReader::Read("\"\""); ASSERT_TRUE(root); ASSERT_TRUE(root->is_string()); EXPECT_EQ("", root->GetString()); } TEST_P(JSONReaderTest, BasicStringEscapes) { std::optional root = JSONReader::Read("\" \\\"\\\\\\/\\b\\f\\n\\r\\t\""); ASSERT_TRUE(root); ASSERT_TRUE(root->is_string()); EXPECT_EQ(" \"\\/\b\f\n\r\t", root->GetString()); } TEST_P(JSONReaderTest, UnicodeEscapes) { // Test hex and unicode escapes including the null character. std::optional root = JSONReader::Read("\"\\x41\\xFF\\x00\\u1234\\u0000\""); ASSERT_TRUE(root); ASSERT_TRUE(root->is_string()); const std::string& str_val = root->GetString(); EXPECT_EQ(std::wstring(L"A\x00FF\0\x1234\0", 5), UTF8ToWide(str_val)); // The contents of a Unicode escape may only be four hex chars. Previously the // parser accepted things like "0x01" and "0X01". EXPECT_FALSE(JSONReader::Read("\"\\u0x12\"")); // Surrogate pairs are allowed in JSON. EXPECT_TRUE(JSONReader::Read("\"\\uD834\\uDD1E\"")); // U+1D11E } TEST_P(JSONReaderTest, InvalidStrings) { EXPECT_FALSE(JSONReader::Read("\"no closing quote")); EXPECT_FALSE(JSONReader::Read("\"\\z invalid escape char\"")); EXPECT_FALSE(JSONReader::Read("\"\\xAQ invalid hex code\"")); EXPECT_FALSE(JSONReader::Read("not enough hex chars\\x1\"")); EXPECT_FALSE(JSONReader::Read("\"not enough escape chars\\u123\"")); EXPECT_FALSE(JSONReader::Read("\"extra backslash at end of input\\\"")); } TEST_P(JSONReaderTest, BasicArray) { std::optional root = JSONReader::Read("[true, false, null]"); ASSERT_TRUE(root); Value::List* list = root->GetIfList(); ASSERT_TRUE(list); EXPECT_EQ(3U, list->size()); // Test with trailing comma. Should be parsed the same as above. std::optional root2 = JSONReader::Read("[true, false, null, ]", JSON_ALLOW_TRAILING_COMMAS); ASSERT_TRUE(root2); EXPECT_EQ(*list, *root2); } TEST_P(JSONReaderTest, EmptyArray) { std::optional value = JSONReader::Read("[]"); ASSERT_TRUE(value); Value::List* list = value->GetIfList(); ASSERT_TRUE(list); EXPECT_TRUE(list->empty()); } TEST_P(JSONReaderTest, CompleteArray) { std::optional value = JSONReader::Read("[\"a\", 3, 4.56, null]"); ASSERT_TRUE(value); Value::List* list = value->GetIfList(); ASSERT_TRUE(list); EXPECT_EQ(4U, list->size()); } TEST_P(JSONReaderTest, NestedArrays) { std::optional value = JSONReader::Read( "[[true], [], {\"smell\": \"nice\",\"taste\": \"yummy\" }, [false, [], " "[null]], null]"); ASSERT_TRUE(value); Value::List* list = value->GetIfList(); ASSERT_TRUE(list); EXPECT_EQ(5U, list->size()); // Lots of trailing commas. std::optional root2 = JSONReader::Read( "[[true], [], {\"smell\": \"nice\",\"taste\": \"yummy\" }, [false, [], " "[null, ] , ], null,]", JSON_ALLOW_TRAILING_COMMAS); ASSERT_TRUE(root2); EXPECT_EQ(*list, *root2); } TEST_P(JSONReaderTest, InvalidArrays) { // Missing close brace. EXPECT_FALSE(JSONReader::Read("[[true], [], [false, [], [null]], null")); // Too many commas. EXPECT_FALSE(JSONReader::Read("[true,, null]")); EXPECT_FALSE(JSONReader::Read("[true,, null]", JSON_ALLOW_TRAILING_COMMAS)); // No commas. EXPECT_FALSE(JSONReader::Read("[true null]")); // Trailing comma. EXPECT_FALSE(JSONReader::Read("[true,]")); } TEST_P(JSONReaderTest, ArrayTrailingComma) { // Valid if we set |allow_trailing_comma| to true. std::optional value = JSONReader::Read("[true,]", JSON_ALLOW_TRAILING_COMMAS); ASSERT_TRUE(value); Value::List* list = value->GetIfList(); ASSERT_TRUE(list); ASSERT_EQ(1U, list->size()); const Value& value1 = (*list)[0]; ASSERT_TRUE(value1.is_bool()); EXPECT_TRUE(value1.GetBool()); } TEST_P(JSONReaderTest, ArrayTrailingCommaNoEmptyElements) { // Don't allow empty elements, even if |allow_trailing_comma| is // true. EXPECT_FALSE(JSONReader::Read("[,]", JSON_ALLOW_TRAILING_COMMAS)); EXPECT_FALSE(JSONReader::Read("[true,,]", JSON_ALLOW_TRAILING_COMMAS)); EXPECT_FALSE(JSONReader::Read("[,true,]", JSON_ALLOW_TRAILING_COMMAS)); EXPECT_FALSE(JSONReader::Read("[true,,false]", JSON_ALLOW_TRAILING_COMMAS)); } TEST_P(JSONReaderTest, EmptyDictionary) { std::optional dict_val = JSONReader::Read("{}"); ASSERT_TRUE(dict_val); ASSERT_TRUE(dict_val->is_dict()); } TEST_P(JSONReaderTest, CompleteDictionary) { std::optional root1 = JSONReader::Read( "{\"number\":9.87654321, \"null\":null , \"\\x53\" : \"str\", \"bool\": " "false, \"more\": {} }"); ASSERT_TRUE(root1); const Value::Dict* root1_dict = root1->GetIfDict(); ASSERT_TRUE(root1_dict); auto double_val = root1_dict->FindDouble("number"); ASSERT_TRUE(double_val); EXPECT_DOUBLE_EQ(9.87654321, *double_val); const Value* null_val = root1_dict->Find("null"); ASSERT_TRUE(null_val); EXPECT_TRUE(null_val->is_none()); const std::string* str_val = root1_dict->FindString("S"); ASSERT_TRUE(str_val); EXPECT_EQ("str", *str_val); auto bool_val = root1_dict->FindBool("bool"); ASSERT_TRUE(bool_val); ASSERT_FALSE(*bool_val); std::optional root2 = JSONReader::Read( "{\"number\":9.87654321, \"null\":null , \"\\x53\" : \"str\", \"bool\": " "false, \"more\": {},}", JSON_PARSE_CHROMIUM_EXTENSIONS | JSON_ALLOW_TRAILING_COMMAS); ASSERT_TRUE(root2); Value::Dict* root2_dict = root2->GetIfDict(); ASSERT_TRUE(root2_dict); EXPECT_EQ(*root1_dict, *root2_dict); // Test newline equivalence. root2 = JSONReader::Read( "{\n" " \"number\":9.87654321,\n" " \"null\":null,\n" " \"\\x53\":\"str\",\n" " \"bool\": false,\n" " \"more\": {},\n" "}\n", JSON_PARSE_CHROMIUM_EXTENSIONS | JSON_ALLOW_TRAILING_COMMAS); ASSERT_TRUE(root2); root2_dict = root2->GetIfDict(); ASSERT_TRUE(root2); EXPECT_EQ(*root1_dict, *root2_dict); root2 = JSONReader::Read( "{\r\n" " \"number\":9.87654321,\r\n" " \"null\":null,\r\n" " \"\\x53\":\"str\",\r\n" " \"bool\": false,\r\n" " \"more\": {},\r\n" "}\r\n", JSON_PARSE_CHROMIUM_EXTENSIONS | JSON_ALLOW_TRAILING_COMMAS); ASSERT_TRUE(root2); root2_dict = root2->GetIfDict(); ASSERT_TRUE(root2_dict); EXPECT_EQ(*root1_dict, *root2_dict); } TEST_P(JSONReaderTest, NestedDictionaries) { std::optional root1 = JSONReader::Read( "{\"inner\":{\"array\":[true, 3, 4.56, null]},\"false\":false,\"d\":{}}"); ASSERT_TRUE(root1); const base::Value::Dict* root1_dict = root1->GetIfDict(); ASSERT_TRUE(root1_dict); const Value::Dict* inner_dict = root1_dict->FindDict("inner"); ASSERT_TRUE(inner_dict); const Value::List* inner_array = inner_dict->FindList("array"); ASSERT_TRUE(inner_array); EXPECT_EQ(4U, inner_array->size()); auto bool_value = root1_dict->FindBool("false"); ASSERT_TRUE(bool_value); EXPECT_FALSE(*bool_value); inner_dict = root1_dict->FindDict("d"); EXPECT_TRUE(inner_dict); std::optional root2 = JSONReader::Read( "{\"inner\": {\"array\":[true, 3, 4.56, null] , " "},\"false\":false,\"d\":{},}", JSON_ALLOW_TRAILING_COMMAS); ASSERT_TRUE(root2); EXPECT_EQ(*root1_dict, *root2); } TEST_P(JSONReaderTest, DictionaryKeysWithPeriods) { std::optional root = JSONReader::Read("{\"a.b\":3,\"c\":2,\"d.e.f\":{\"g.h.i.j\":1}}"); ASSERT_TRUE(root); Value::Dict* root_dict = root->GetIfDict(); ASSERT_TRUE(root_dict); auto integer_value = root_dict->FindInt("a.b"); ASSERT_TRUE(integer_value); EXPECT_EQ(3, *integer_value); integer_value = root_dict->FindInt("c"); ASSERT_TRUE(integer_value); EXPECT_EQ(2, *integer_value); const Value::Dict* inner_dict = root_dict->FindDict("d.e.f"); ASSERT_TRUE(inner_dict); EXPECT_EQ(1U, inner_dict->size()); integer_value = inner_dict->FindInt("g.h.i.j"); ASSERT_TRUE(integer_value); EXPECT_EQ(1, *integer_value); root = JSONReader::Read("{\"a\":{\"b\":2},\"a.b\":1}"); ASSERT_TRUE(root); root_dict = root->GetIfDict(); ASSERT_TRUE(root_dict); const Value* integer_path_value = root_dict->FindByDottedPath("a.b"); ASSERT_TRUE(integer_path_value); EXPECT_EQ(2, integer_path_value->GetInt()); integer_value = root_dict->FindInt("a.b"); ASSERT_TRUE(integer_value); EXPECT_EQ(1, *integer_value); } TEST_P(JSONReaderTest, DuplicateKeys) { std::optional root = JSONReader::Read("{\"x\":1,\"x\":2,\"y\":3}"); ASSERT_TRUE(root); const Value::Dict* root_dict = root->GetIfDict(); ASSERT_TRUE(root_dict); auto integer_value = root_dict->FindInt("x"); ASSERT_TRUE(integer_value); EXPECT_EQ(2, *integer_value); } TEST_P(JSONReaderTest, InvalidDictionaries) { // No closing brace. EXPECT_FALSE(JSONReader::Read("{\"a\": true")); // Keys must be quoted strings. EXPECT_FALSE(JSONReader::Read("{foo:true}")); EXPECT_FALSE(JSONReader::Read("{1234: false}")); EXPECT_FALSE(JSONReader::Read("{:false}")); EXPECT_FALSE(JSONReader::Read("{ , }")); // Trailing comma. EXPECT_FALSE(JSONReader::Read("{\"a\":true,}")); // Too many commas. EXPECT_FALSE(JSONReader::Read("{\"a\":true,,\"b\":false}")); EXPECT_FALSE(JSONReader::Read("{\"a\":true,,\"b\":false}", JSON_ALLOW_TRAILING_COMMAS)); // No separator. EXPECT_FALSE(JSONReader::Read("{\"a\" \"b\"}")); // Lone comma. EXPECT_FALSE(JSONReader::Read("{,}")); EXPECT_FALSE(JSONReader::Read("{,}", JSON_ALLOW_TRAILING_COMMAS)); EXPECT_FALSE(JSONReader::Read("{\"a\":true,,}", JSON_ALLOW_TRAILING_COMMAS)); EXPECT_FALSE(JSONReader::Read("{,\"a\":true}", JSON_ALLOW_TRAILING_COMMAS)); EXPECT_FALSE(JSONReader::Read("{\"a\":true,,\"b\":false}", JSON_ALLOW_TRAILING_COMMAS)); } TEST_P(JSONReaderTest, StackOverflow) { std::string evil(1000000, '['); evil.append(std::string(1000000, ']')); EXPECT_FALSE(JSONReader::Read(evil)); // A few thousand adjacent lists is fine. std::string not_evil("["); not_evil.reserve(15010); for (int i = 0; i < 5000; ++i) not_evil.append("[],"); not_evil.append("[]]"); std::optional value = JSONReader::Read(not_evil); ASSERT_TRUE(value); Value::List* list = value->GetIfList(); ASSERT_TRUE(list); EXPECT_EQ(5001U, list->size()); } TEST_P(JSONReaderTest, UTF8Input) { std::optional root = JSONReader::Read("\"\xe7\xbd\x91\xe9\xa1\xb5\""); ASSERT_TRUE(root); ASSERT_TRUE(root->is_string()); const std::string& str_val = root->GetString(); EXPECT_EQ(L"\x7f51\x9875", UTF8ToWide(str_val)); root = JSONReader::Read("{\"path\": \"/tmp/\xc3\xa0\xc3\xa8\xc3\xb2.png\"}"); ASSERT_TRUE(root); const Value::Dict* root_dict = root->GetIfDict(); ASSERT_TRUE(root_dict); const std::string* maybe_string = root_dict->FindString("path"); ASSERT_TRUE(maybe_string); EXPECT_EQ("/tmp/\xC3\xA0\xC3\xA8\xC3\xB2.png", *maybe_string); // JSON can encode non-characters. const char* const noncharacters[] = { "\"\xEF\xB7\x90\"", // U+FDD0 "\"\xEF\xB7\x9F\"", // U+FDDF "\"\xEF\xB7\xAF\"", // U+FDEF "\"\xEF\xBF\xBE\"", // U+FFFE "\"\xEF\xBF\xBF\"", // U+FFFF "\"\xF0\x9F\xBF\xBE\"", // U+01FFFE "\"\xF0\x9F\xBF\xBF\"", // U+01FFFF "\"\xF0\xAF\xBF\xBE\"", // U+02FFFE "\"\xF0\xAF\xBF\xBF\"", // U+02FFFF "\"\xF0\xBF\xBF\xBE\"", // U+03FFFE "\"\xF0\xBF\xBF\xBF\"", // U+03FFFF "\"\xF1\x8F\xBF\xBE\"", // U+04FFFE "\"\xF1\x8F\xBF\xBF\"", // U+04FFFF "\"\xF1\x9F\xBF\xBE\"", // U+05FFFE "\"\xF1\x9F\xBF\xBF\"", // U+05FFFF "\"\xF1\xAF\xBF\xBE\"", // U+06FFFE "\"\xF1\xAF\xBF\xBF\"", // U+06FFFF "\"\xF1\xBF\xBF\xBE\"", // U+07FFFE "\"\xF1\xBF\xBF\xBF\"", // U+07FFFF "\"\xF2\x8F\xBF\xBE\"", // U+08FFFE "\"\xF2\x8F\xBF\xBF\"", // U+08FFFF "\"\xF2\x9F\xBF\xBE\"", // U+09FFFE "\"\xF2\x9F\xBF\xBF\"", // U+09FFFF "\"\xF2\xAF\xBF\xBE\"", // U+0AFFFE "\"\xF2\xAF\xBF\xBF\"", // U+0AFFFF "\"\xF2\xBF\xBF\xBE\"", // U+0BFFFE "\"\xF2\xBF\xBF\xBF\"", // U+0BFFFF "\"\xF3\x8F\xBF\xBE\"", // U+0CFFFE "\"\xF3\x8F\xBF\xBF\"", // U+0CFFFF "\"\xF3\x9F\xBF\xBE\"", // U+0DFFFE "\"\xF3\x9F\xBF\xBF\"", // U+0DFFFF "\"\xF3\xAF\xBF\xBE\"", // U+0EFFFE "\"\xF3\xAF\xBF\xBF\"", // U+0EFFFF "\"\xF3\xBF\xBF\xBE\"", // U+0FFFFE "\"\xF3\xBF\xBF\xBF\"", // U+0FFFFF "\"\xF4\x8F\xBF\xBE\"", // U+10FFFE "\"\xF4\x8F\xBF\xBF\"", // U+10FFFF }; for (auto* noncharacter : noncharacters) { root = JSONReader::Read(noncharacter); ASSERT_TRUE(root); ASSERT_TRUE(root->is_string()); EXPECT_EQ(std::string(noncharacter + 1, strlen(noncharacter) - 2), root->GetString()); } } TEST_P(JSONReaderTest, InvalidUTF8Input) { EXPECT_FALSE(JSONReader::Read("\"345\xb0\xa1\xb0\xa2\"")); EXPECT_FALSE(JSONReader::Read("\"123\xc0\x81\"")); EXPECT_FALSE(JSONReader::Read("\"abc\xc0\xae\"")); } TEST_P(JSONReaderTest, UTF16Escapes) { std::optional root = JSONReader::Read("\"\\u20ac3,14\""); ASSERT_TRUE(root); ASSERT_TRUE(root->is_string()); EXPECT_EQ( "\xe2\x82\xac" "3,14", root->GetString()); root = JSONReader::Read("\"\\ud83d\\udca9\\ud83d\\udc6c\""); ASSERT_TRUE(root); ASSERT_TRUE(root->is_string()); EXPECT_EQ("\xf0\x9f\x92\xa9\xf0\x9f\x91\xac", root->GetString()); } TEST_P(JSONReaderTest, InvalidUTF16Escapes) { const char* const cases[] = { "\"\\u123\"", // Invalid scalar. "\"\\ud83d\"", // Invalid scalar. "\"\\u$%@!\"", // Invalid scalar. "\"\\uzz89\"", // Invalid scalar. "\"\\ud83d\\udca\"", // Invalid lower surrogate. "\"\\ud83d\\ud83d\"", // Invalid lower surrogate. "\"\\ud83d\\uaaaZ\"", // Invalid lower surrogate. "\"\\ud83foo\"", // No lower surrogate. "\"\\ud83d\\foo\"", // No lower surrogate. "\"\\ud83\\foo\"", // Invalid upper surrogate. "\"\\ud83d\\u1\"", // No lower surrogate. "\"\\ud83\\u1\"", // Invalid upper surrogate. }; std::optional root; for (auto* i : cases) { root = JSONReader::Read(i); EXPECT_FALSE(root) << i; } } TEST_P(JSONReaderTest, LiteralRoots) { std::optional root = JSONReader::Read("null"); ASSERT_TRUE(root); EXPECT_TRUE(root->is_none()); root = JSONReader::Read("true"); ASSERT_TRUE(root); ASSERT_TRUE(root->is_bool()); EXPECT_TRUE(root->GetBool()); root = JSONReader::Read("10"); ASSERT_TRUE(root); ASSERT_TRUE(root->is_int()); EXPECT_EQ(10, root->GetInt()); root = JSONReader::Read("\"root\""); ASSERT_TRUE(root); ASSERT_TRUE(root->is_string()); EXPECT_EQ("root", root->GetString()); } TEST_P(JSONReaderTest, ReadFromFile) { FilePath path; ASSERT_TRUE(PathService::Get(base::DIR_TEST_DATA, &path)); path = path.AppendASCII("json"); ASSERT_TRUE(base::PathExists(path)); std::string input; ASSERT_TRUE(ReadFileToString(path.AppendASCII("bom_feff.json"), &input)); EXPECT_THAT( JSONReader::ReadAndReturnValueWithError(input), base::test::ValueIs(::testing::Property(&base::Value::is_dict, true))); } // Tests that the root of a JSON object can be deleted safely while its // children outlive it. TEST_P(JSONReaderTest, StringOptimizations) { Value dict_literal_0; Value dict_literal_1; Value dict_string_0; Value dict_string_1; Value list_value_0; Value list_value_1; { std::optional root = JSONReader::Read( "{" " \"test\": {" " \"foo\": true," " \"bar\": 3.14," " \"baz\": \"bat\"," " \"moo\": \"cow\"" " }," " \"list\": [" " \"a\"," " \"b\"" " ]" "}", JSON_PARSE_RFC); ASSERT_TRUE(root); Value::Dict* root_dict = root->GetIfDict(); ASSERT_TRUE(root_dict); Value::Dict* dict = root_dict->FindDict("test"); ASSERT_TRUE(dict); Value::List* list = root_dict->FindList("list"); ASSERT_TRUE(list); Value* to_move = dict->Find("foo"); ASSERT_TRUE(to_move); dict_literal_0 = std::move(*to_move); to_move = dict->Find("bar"); ASSERT_TRUE(to_move); dict_literal_1 = std::move(*to_move); to_move = dict->Find("baz"); ASSERT_TRUE(to_move); dict_string_0 = std::move(*to_move); to_move = dict->Find("moo"); ASSERT_TRUE(to_move); dict_string_1 = std::move(*to_move); ASSERT_TRUE(dict->Remove("foo")); ASSERT_TRUE(dict->Remove("bar")); ASSERT_TRUE(dict->Remove("baz")); ASSERT_TRUE(dict->Remove("moo")); ASSERT_EQ(2u, list->size()); list_value_0 = std::move((*list)[0]); list_value_1 = std::move((*list)[1]); list->clear(); } ASSERT_TRUE(dict_literal_0.is_bool()); EXPECT_TRUE(dict_literal_0.GetBool()); ASSERT_TRUE(dict_literal_1.is_double()); EXPECT_EQ(3.14, dict_literal_1.GetDouble()); ASSERT_TRUE(dict_string_0.is_string()); EXPECT_EQ("bat", dict_string_0.GetString()); ASSERT_TRUE(dict_string_1.is_string()); EXPECT_EQ("cow", dict_string_1.GetString()); ASSERT_TRUE(list_value_0.is_string()); EXPECT_EQ("a", list_value_0.GetString()); ASSERT_TRUE(list_value_1.is_string()); EXPECT_EQ("b", list_value_1.GetString()); } // A smattering of invalid JSON designed to test specific portions of the // parser implementation against buffer overflow. Best run with DCHECKs so // that the one in NextChar fires. TEST_P(JSONReaderTest, InvalidSanity) { const char* const kInvalidJson[] = { "/* test *", "{\"foo\"", "{\"foo\":", " [", "\"\\u123g\"", "{\n\"eh:\n}", }; for (size_t i = 0; i < std::size(kInvalidJson); ++i) { LOG(INFO) << "Sanity test " << i << ": <" << kInvalidJson[i] << ">"; auto root = JSONReader::ReadAndReturnValueWithError(kInvalidJson[i]); EXPECT_FALSE(root.has_value()); EXPECT_NE("", root.error().message); } } TEST_P(JSONReaderTest, IllegalTrailingNull) { const char json[] = {'"', 'n', 'u', 'l', 'l', '"', '\0'}; std::string json_string(json, sizeof(json)); auto root = JSONReader::ReadAndReturnValueWithError(json_string); EXPECT_FALSE(root.has_value()); EXPECT_NE("", root.error().message); } TEST_P(JSONReaderTest, ASCIIControlCodes) { // A literal NUL byte or a literal new line, in a JSON string, should be // rejected. RFC 8259 section 7 says "the characters that MUST be escaped // [include]... the control characters (U+0000 through U+001F)". // // Currently, we accept \r and \n in JSON strings because they are widely used // and somewhat useful (especially when nesting JSON messages), but reject all // other control characters. { const char json[] = "\"a\rn\nc\""; auto root = JSONReader::Read(json); ASSERT_TRUE(root); ASSERT_TRUE(root->is_string()); EXPECT_EQ(5u, root->GetString().length()); } { // Replace the \r with a disallowed \f, and require parsing to fail: const char json[] = "\"a\fn\nc\""; auto root = JSONReader::ReadAndReturnValueWithError(json); EXPECT_FALSE(root.has_value()); EXPECT_NE("", root.error().message); } } TEST_P(JSONReaderTest, MaxNesting) { std::string json(R"({"outer": { "inner": {"foo": true}}})"); EXPECT_FALSE(JSONReader::Read(json, JSON_PARSE_RFC, 3)); EXPECT_TRUE(JSONReader::Read(json, JSON_PARSE_RFC, 4)); } TEST_P(JSONReaderTest, Decode4ByteUtf8Char) { // kUtf8Data contains a 4 byte unicode character (a smiley!) that JSONReader // should be able to handle. The UTF-8 encoding of U+1F607 SMILING FACE WITH // HALO is "\xF0\x9F\x98\x87". const char kUtf8Data[] = "[\"😇\",[],[],[],{\"google:suggesttype\":[]}]"; std::optional root = JSONReader::Read(kUtf8Data, JSON_PARSE_RFC); ASSERT_TRUE(root); Value::List* list = root->GetIfList(); ASSERT_TRUE(list); ASSERT_EQ(5u, list->size()); ASSERT_TRUE((*list)[0].is_string()); EXPECT_EQ("\xF0\x9F\x98\x87", (*list)[0].GetString()); } TEST_P(JSONReaderTest, DecodeUnicodeNonCharacter) { // Tests Unicode code points (encoded as escaped UTF-16) that are not valid // characters. EXPECT_TRUE(JSONReader::Read("[\"\\uFDD0\"]")); // U+FDD0 EXPECT_TRUE(JSONReader::Read("[\"\\uFDDF\"]")); // U+FDDF EXPECT_TRUE(JSONReader::Read("[\"\\uFDEF\"]")); // U+FDEF EXPECT_TRUE(JSONReader::Read("[\"\\uFFFE\"]")); // U+FFFE EXPECT_TRUE(JSONReader::Read("[\"\\uFFFF\"]")); // U+FFFF EXPECT_TRUE(JSONReader::Read("[\"\\uD83F\\uDFFE\"]")); // U+01FFFE EXPECT_TRUE(JSONReader::Read("[\"\\uD83F\\uDFFF\"]")); // U+01FFFF EXPECT_TRUE(JSONReader::Read("[\"\\uD87F\\uDFFE\"]")); // U+02FFFE EXPECT_TRUE(JSONReader::Read("[\"\\uD87F\\uDFFF\"]")); // U+02FFFF EXPECT_TRUE(JSONReader::Read("[\"\\uD8BF\\uDFFE\"]")); // U+03FFFE EXPECT_TRUE(JSONReader::Read("[\"\\uD8BF\\uDFFF\"]")); // U+03FFFF EXPECT_TRUE(JSONReader::Read("[\"\\uD8FF\\uDFFE\"]")); // U+04FFFE EXPECT_TRUE(JSONReader::Read("[\"\\uD8FF\\uDFFF\"]")); // U+04FFFF EXPECT_TRUE(JSONReader::Read("[\"\\uD93F\\uDFFE\"]")); // U+05FFFE EXPECT_TRUE(JSONReader::Read("[\"\\uD93F\\uDFFF\"]")); // U+05FFFF EXPECT_TRUE(JSONReader::Read("[\"\\uD97F\\uDFFE\"]")); // U+06FFFE EXPECT_TRUE(JSONReader::Read("[\"\\uD97F\\uDFFF\"]")); // U+06FFFF EXPECT_TRUE(JSONReader::Read("[\"\\uD9BF\\uDFFE\"]")); // U+07FFFE EXPECT_TRUE(JSONReader::Read("[\"\\uD9BF\\uDFFF\"]")); // U+07FFFF EXPECT_TRUE(JSONReader::Read("[\"\\uD9FF\\uDFFE\"]")); // U+08FFFE EXPECT_TRUE(JSONReader::Read("[\"\\uD9FF\\uDFFF\"]")); // U+08FFFF EXPECT_TRUE(JSONReader::Read("[\"\\uDA3F\\uDFFE\"]")); // U+09FFFE EXPECT_TRUE(JSONReader::Read("[\"\\uDA3F\\uDFFF\"]")); // U+09FFFF EXPECT_TRUE(JSONReader::Read("[\"\\uDA7F\\uDFFE\"]")); // U+0AFFFE EXPECT_TRUE(JSONReader::Read("[\"\\uDA7F\\uDFFF\"]")); // U+0AFFFF EXPECT_TRUE(JSONReader::Read("[\"\\uDABF\\uDFFE\"]")); // U+0BFFFE EXPECT_TRUE(JSONReader::Read("[\"\\uDABF\\uDFFF\"]")); // U+0BFFFF EXPECT_TRUE(JSONReader::Read("[\"\\uDAFF\\uDFFE\"]")); // U+0CFFFE EXPECT_TRUE(JSONReader::Read("[\"\\uDAFF\\uDFFF\"]")); // U+0CFFFF EXPECT_TRUE(JSONReader::Read("[\"\\uDB3F\\uDFFE\"]")); // U+0DFFFE EXPECT_TRUE(JSONReader::Read("[\"\\uDB3F\\uDFFF\"]")); // U+0DFFFF EXPECT_TRUE(JSONReader::Read("[\"\\uDB7F\\uDFFE\"]")); // U+0EFFFE EXPECT_TRUE(JSONReader::Read("[\"\\uDB7F\\uDFFF\"]")); // U+0EFFFF EXPECT_TRUE(JSONReader::Read("[\"\\uDBBF\\uDFFE\"]")); // U+0FFFFE EXPECT_TRUE(JSONReader::Read("[\"\\uDBBF\\uDFFF\"]")); // U+0FFFFF EXPECT_TRUE(JSONReader::Read("[\"\\uDBFF\\uDFFE\"]")); // U+10FFFE EXPECT_TRUE(JSONReader::Read("[\"\\uDBFF\\uDFFF\"]")); // U+10FFFF } TEST_P(JSONReaderTest, DecodeNegativeEscapeSequence) { EXPECT_FALSE(JSONReader::Read("[\"\\x-A\"]")); EXPECT_FALSE(JSONReader::Read("[\"\\u-00A\"]")); } // Verifies invalid code points are replaced. TEST_P(JSONReaderTest, ReplaceInvalidCharacters) { // U+D800 is a lone high surrogate. const std::string invalid_high = "\"\xED\xA0\x80\""; std::optional value = JSONReader::Read(invalid_high, JSON_REPLACE_INVALID_CHARACTERS); ASSERT_TRUE(value); ASSERT_TRUE(value->is_string()); // Expect three U+FFFD (one for each UTF-8 byte in the invalid code point). EXPECT_EQ("\xEF\xBF\xBD\xEF\xBF\xBD\xEF\xBF\xBD", value->GetString()); // U+DFFF is a lone low surrogate. const std::string invalid_low = "\"\xED\xBF\xBF\""; value = JSONReader::Read(invalid_low, JSON_REPLACE_INVALID_CHARACTERS); ASSERT_TRUE(value); ASSERT_TRUE(value->is_string()); // Expect three U+FFFD (one for each UTF-8 byte in the invalid code point). EXPECT_EQ("\xEF\xBF\xBD\xEF\xBF\xBD\xEF\xBF\xBD", value->GetString()); } TEST_P(JSONReaderTest, ReplaceInvalidUTF16EscapeSequence) { // U+D800 is a lone high surrogate. const std::string invalid_high = "\"_\\uD800_\""; std::optional value = JSONReader::Read(invalid_high, JSON_REPLACE_INVALID_CHARACTERS); ASSERT_TRUE(value); ASSERT_TRUE(value->is_string()); EXPECT_EQ("_\xEF\xBF\xBD_", value->GetString()); // U+DFFF is a lone low surrogate. const std::string invalid_low = "\"_\\uDFFF_\""; value = JSONReader::Read(invalid_low, JSON_REPLACE_INVALID_CHARACTERS); ASSERT_TRUE(value); ASSERT_TRUE(value->is_string()); EXPECT_EQ("_\xEF\xBF\xBD_", value->GetString()); } TEST_P(JSONReaderTest, ParseNumberErrors) { const struct { const char* input; bool parse_success; double value; } kCases[] = { // clang-format off {"1", true, 1}, {"2.", false, 0}, {"42", true, 42}, {"6e", false, 0}, {"43e2", true, 4300}, {"43e-", false, 0}, {"9e-3", true, 0.009}, {"2e+", false, 0}, {"2e+2", true, 200}, // clang-format on }; for (unsigned int i = 0; i < std::size(kCases); ++i) { auto test_case = kCases[i]; SCOPED_TRACE(StringPrintf("case %u: \"%s\"", i, test_case.input)); std::unique_ptr input_owner; std::string_view input = MakeNotNullTerminatedInput(test_case.input, &input_owner); std::optional result = JSONReader::Read(input); EXPECT_EQ(test_case.parse_success, result.has_value()); if (!result) continue; ASSERT_TRUE(result->is_double() || result->is_int()); EXPECT_EQ(test_case.value, result->GetDouble()); } } TEST_P(JSONReaderTest, UnterminatedInputs) { const char* const kCases[] = { // clang-format off "/", "//", "/*", "\"xxxxxx", "\"", "{ ", "[\t", "tru", "fals", "nul", "\"\\x", "\"\\x2", "\"\\u123", "\"\\uD803\\u", "\"\\", "\"\\/", // clang-format on }; for (unsigned int i = 0; i < std::size(kCases); ++i) { auto* test_case = kCases[i]; SCOPED_TRACE(StringPrintf("case %u: \"%s\"", i, test_case)); std::unique_ptr input_owner; std::string_view input = MakeNotNullTerminatedInput(test_case, &input_owner); EXPECT_FALSE(JSONReader::Read(input)); } } TEST_P(JSONReaderTest, LineColumnCounting) { const struct { const char* input; int error_line; int error_column; } kCases[] = { // For all but the "q_is_not_etc" case, the error (indicated by ^ in the // comments) is seeing a digit when expecting ',' or ']'. { // Line and column counts are 1-based, not 0-based. "q_is_not_the_start_of_any_valid_JSON_token", 1, 1, }, { "[2,4,6 8", // -----^ 1, 8, }, { "[2,4,6\t8", // ------^ 1, 8, }, { "[2,4,6\n8", // ------^ 2, 1, }, { "[\n0,\n1,\n2,\n3,4,5,6 7,\n8,\n9\n]", // ---------------------^ 5, 9, }, { // Same as the previous example, but with "\r\n"s instead of "\n"s. "[\r\n0,\r\n1,\r\n2,\r\n3,4,5,6 7,\r\n8,\r\n9\r\n]", // -----------------------------^ 5, 9, }, // The JSON spec forbids unescaped ASCII control characters (including // line breaks) within a string, but our implementation is more lenient. { "[\"3\n1\" 4", // --------^ 2, 4, }, { "[\"3\r\n1\" 4", // ----------^ 2, 4, }, }; for (unsigned int i = 0; i < std::size(kCases); ++i) { auto test_case = kCases[i]; SCOPED_TRACE(StringPrintf("case %u: \"%s\"", i, test_case.input)); auto root = JSONReader::ReadAndReturnValueWithError( test_case.input, JSON_PARSE_RFC | JSON_ALLOW_NEWLINES_IN_STRINGS); EXPECT_FALSE(root.has_value()); EXPECT_EQ(test_case.error_line, root.error().line); EXPECT_EQ(test_case.error_column, root.error().column); } } TEST_P(JSONReaderTest, ChromiumExtensions) { // All of these cases should parse with JSON_PARSE_CHROMIUM_EXTENSIONS but // fail with JSON_PARSE_RFC. const struct { // The JSON input. const char* input; // What JSON_* option permits this extension. int option; } kCases[] = { {"{ /* comment */ \"foo\": 3 }", JSON_ALLOW_COMMENTS}, {"{ // comment\n \"foo\": 3 }", JSON_ALLOW_COMMENTS}, {"[\"\\xAB\"]", JSON_ALLOW_X_ESCAPES}, {"[\"\n\"]", JSON_ALLOW_NEWLINES_IN_STRINGS}, {"[\"\r\"]", JSON_ALLOW_NEWLINES_IN_STRINGS}, }; for (size_t i = 0; i < std::size(kCases); ++i) { SCOPED_TRACE(testing::Message() << "case " << i); const auto& test_case = kCases[i]; auto result = JSONReader::ReadAndReturnValueWithError(test_case.input, JSON_PARSE_RFC); EXPECT_FALSE(result.has_value()); result = JSONReader::ReadAndReturnValueWithError( test_case.input, JSON_PARSE_RFC | test_case.option); EXPECT_TRUE(result.has_value()); result = JSONReader::ReadAndReturnValueWithError( test_case.input, JSON_PARSE_CHROMIUM_EXTENSIONS); EXPECT_TRUE(result.has_value()); result = JSONReader::ReadAndReturnValueWithError( test_case.input, JSON_PARSE_CHROMIUM_EXTENSIONS & ~test_case.option); EXPECT_FALSE(result.has_value()); } } // For every control character, place it unescaped in a string and ensure that: // a) It doesn't parse with JSON_PARSE_RFC // b) It doesn't parse with JSON_PARSE_CHROMIUM_EXTENSIONS // c) It does parse with JSON_ALLOW_CONTROL_CHARS TEST_P(JSONReaderTest, UnescapedControls) { std::string input = "\"foo\""; // ECMA-404 (JSON standard) section 9: characters from 0x00 to 0x1f must be // escaped. for (char c = 0x00; c <= 0x1f; c++) { input[1] = c; auto result = JSONReader::Read(input, JSON_PARSE_RFC); EXPECT_FALSE(result.has_value()); bool should_parse_with_extensions = (c == '\r' || c == '\n'); result = JSONReader::Read(input, JSON_PARSE_CHROMIUM_EXTENSIONS); EXPECT_EQ(should_parse_with_extensions, result.has_value()); result = JSONReader::Read(input, JSON_ALLOW_CONTROL_CHARS); ASSERT_TRUE(result.has_value()); ASSERT_TRUE(result->is_string()); EXPECT_EQ(result->GetString().length(), input.length() - 2); EXPECT_EQ(result->GetString()[0], c); } } TEST_P(JSONReaderTest, UsingRust) { ASSERT_EQ(JSONReader::UsingRust(), using_rust_); } INSTANTIATE_TEST_SUITE_P(All, JSONReaderTest, #if BUILDFLAG(BUILD_RUST_JSON_READER) testing::Bool(), #else // BUILDFLAG(BUILD_RUST_JSON_READER) testing::Values(false), #endif // BUILDFLAG(BUILD_RUST_JSON_READER) [](const testing::TestParamInfo& info) { return info.param ? "Rust" : "Cpp"; }); } // namespace base