// Protocol Buffers - Google's data interchange format // Copyright 2023 Google LLC. All rights reserved. // // Use of this source code is governed by a BSD-style // license that can be found in the LICENSE file or at // https://developers.google.com/open-source/licenses/bsd #include #include #include #include #include #include #include #include "google/protobuf/test_messages_proto3.upb.h" #include "upb/base/status.hpp" #include "upb/base/string_view.h" #include "upb/base/upcast.h" #include "upb/json/decode.h" #include "upb/json/encode.h" #include "upb/mem/arena.h" #include "upb/mem/arena.hpp" #include "upb/message/array.h" #include "upb/message/map.h" #include "upb/message/message.h" #include "upb/message/test.upb.h" #include "upb/message/test.upb_minitable.h" #include "upb/message/test.upbdefs.h" #include "upb/message/value.h" #include "upb/mini_table/extension_registry.h" #include "upb/mini_table/field.h" #include "upb/mini_table/message.h" #include "upb/reflection/def.h" #include "upb/reflection/def.hpp" #include "upb/reflection/message.h" #include "upb/test/fuzz_util.h" #include "upb/wire/decode.h" #include "upb/wire/encode.h" // begin:google_only // #include "testing/fuzzing/fuzztest.h" // end:google_only void VerifyMessage(const upb_test_TestExtensions* ext_msg) { EXPECT_TRUE(upb_test_TestExtensions_has_optional_int32_ext(ext_msg)); // EXPECT_FALSE(upb_test_TestExtensions_Nested_has_optional_int32_ext(ext_msg)); EXPECT_TRUE(upb_test_has_optional_msg_ext(ext_msg)); EXPECT_EQ(123, upb_test_TestExtensions_optional_int32_ext(ext_msg)); const protobuf_test_messages_proto3_TestAllTypesProto3* ext_submsg = upb_test_optional_msg_ext(ext_msg); EXPECT_TRUE(ext_submsg != nullptr); EXPECT_EQ(456, protobuf_test_messages_proto3_TestAllTypesProto3_optional_int32( ext_submsg)); } TEST(MessageTest, Extensions) { upb::Arena arena; upb_test_TestExtensions* ext_msg = upb_test_TestExtensions_new(arena.ptr()); EXPECT_FALSE(upb_test_TestExtensions_has_optional_int32_ext(ext_msg)); // EXPECT_FALSE(upb_test_TestExtensions_Nested_has_optional_int32_ext(ext_msg)); EXPECT_FALSE(upb_test_has_optional_msg_ext(ext_msg)); upb::DefPool defpool; upb::MessageDefPtr m(upb_test_TestExtensions_getmsgdef(defpool.ptr())); EXPECT_TRUE(m.ptr() != nullptr); std::string json = R"json( { "[upb_test.TestExtensions.optional_int32_ext]": 123, "[upb_test.TestExtensions.Nested.repeated_int32_ext]": [2, 4, 6], "[upb_test.optional_msg_ext]": {"optional_int32": 456} } )json"; upb::Status status; EXPECT_TRUE(upb_JsonDecode(json.data(), json.size(), UPB_UPCAST(ext_msg), m.ptr(), defpool.ptr(), 0, arena.ptr(), status.ptr())) << status.error_message(); VerifyMessage(ext_msg); // Test round-trip through binary format. size_t size; char* serialized = upb_test_TestExtensions_serialize(ext_msg, arena.ptr(), &size); ASSERT_TRUE(serialized != nullptr); ASSERT_GE(size, 0); upb_test_TestExtensions* ext_msg2 = upb_test_TestExtensions_parse_ex( serialized, size, upb_DefPool_ExtensionRegistry(defpool.ptr()), 0, arena.ptr()); VerifyMessage(ext_msg2); // Test round-trip through JSON format. size_t json_size = upb_JsonEncode(UPB_UPCAST(ext_msg), m.ptr(), defpool.ptr(), 0, nullptr, 0, status.ptr()); char* json_buf = static_cast(upb_Arena_Malloc(arena.ptr(), json_size + 1)); upb_JsonEncode(UPB_UPCAST(ext_msg), m.ptr(), defpool.ptr(), 0, json_buf, json_size + 1, status.ptr()); upb_test_TestExtensions* ext_msg3 = upb_test_TestExtensions_new(arena.ptr()); EXPECT_TRUE(upb_JsonDecode(json_buf, json_size, UPB_UPCAST(ext_msg3), m.ptr(), defpool.ptr(), 0, arena.ptr(), status.ptr())) << status.error_message(); VerifyMessage(ext_msg3); // Test setters and mutable accessors upb_test_TestExtensions* ext_msg4 = upb_test_TestExtensions_new(arena.ptr()); upb_test_TestExtensions_set_optional_int32_ext(ext_msg4, 123, arena.ptr()); protobuf_test_messages_proto3_TestAllTypesProto3_set_optional_int32( upb_test_mutable_optional_msg_ext(ext_msg4, arena.ptr()), 456); VerifyMessage(ext_msg4); } void VerifyMessageSet(const upb_test_TestMessageSet* mset_msg) { ASSERT_TRUE(mset_msg != nullptr); bool has = upb_test_MessageSetMember_has_message_set_extension(mset_msg); EXPECT_TRUE(has); if (!has) return; const upb_test_MessageSetMember* member = upb_test_MessageSetMember_message_set_extension(mset_msg); EXPECT_TRUE(member != nullptr); EXPECT_TRUE(upb_test_MessageSetMember_has_optional_int32(member)); EXPECT_EQ(234, upb_test_MessageSetMember_optional_int32(member)); } TEST(MessageTest, MessageSet) { upb::Arena arena; upb_test_TestMessageSet* ext_msg = upb_test_TestMessageSet_new(arena.ptr()); EXPECT_FALSE(upb_test_MessageSetMember_has_message_set_extension(ext_msg)); upb::DefPool defpool; upb::MessageDefPtr m(upb_test_TestMessageSet_getmsgdef(defpool.ptr())); EXPECT_TRUE(m.ptr() != nullptr); std::string json = R"json( { "[upb_test.MessageSetMember]": {"optional_int32": 234} } )json"; upb::Status status; EXPECT_TRUE(upb_JsonDecode(json.data(), json.size(), UPB_UPCAST(ext_msg), m.ptr(), defpool.ptr(), 0, arena.ptr(), status.ptr())) << status.error_message(); VerifyMessageSet(ext_msg); // Test round-trip through binary format. size_t size; char* serialized = upb_test_TestMessageSet_serialize(ext_msg, arena.ptr(), &size); ASSERT_TRUE(serialized != nullptr); ASSERT_GE(size, 0); upb_test_TestMessageSet* ext_msg2 = upb_test_TestMessageSet_parse_ex( serialized, size, upb_DefPool_ExtensionRegistry(defpool.ptr()), 0, arena.ptr()); VerifyMessageSet(ext_msg2); // Test round-trip through JSON format. size_t json_size = upb_JsonEncode(UPB_UPCAST(ext_msg), m.ptr(), defpool.ptr(), 0, nullptr, 0, status.ptr()); char* json_buf = static_cast(upb_Arena_Malloc(arena.ptr(), json_size + 1)); upb_JsonEncode(UPB_UPCAST(ext_msg), m.ptr(), defpool.ptr(), 0, json_buf, json_size + 1, status.ptr()); upb_test_TestMessageSet* ext_msg3 = upb_test_TestMessageSet_new(arena.ptr()); EXPECT_TRUE(upb_JsonDecode(json_buf, json_size, UPB_UPCAST(ext_msg3), m.ptr(), defpool.ptr(), 0, arena.ptr(), status.ptr())) << status.error_message(); VerifyMessageSet(ext_msg3); } TEST(MessageTest, UnknownMessageSet) { static const char data[] = "ABCDE"; upb_StringView data_view = upb_StringView_FromString(data); upb::Arena arena; upb_test_FakeMessageSet* fake = upb_test_FakeMessageSet_new(arena.ptr()); // Add a MessageSet item that is unknown (there is no matching extension in // the .proto file) upb_test_FakeMessageSet_Item* item = upb_test_FakeMessageSet_add_item(fake, arena.ptr()); upb_test_FakeMessageSet_Item_set_type_id(item, 12345); upb_test_FakeMessageSet_Item_set_message(item, data_view); // Set unknown fields inside the message set to test that we can skip them. upb_test_FakeMessageSet_Item_set_unknown_varint(item, 12345678); upb_test_FakeMessageSet_Item_set_unknown_fixed32(item, 12345678); upb_test_FakeMessageSet_Item_set_unknown_fixed64(item, 12345678); upb_test_FakeMessageSet_Item_set_unknown_bytes(item, data_view); upb_test_FakeMessageSet_Item_mutable_unknowngroup(item, arena.ptr()); // Round trip through a true MessageSet where this item_id is unknown. size_t size; char* serialized = upb_test_FakeMessageSet_serialize(fake, arena.ptr(), &size); ASSERT_TRUE(serialized != nullptr); ASSERT_GE(size, 0); upb::DefPool defpool; upb::MessageDefPtr m(upb_test_TestMessageSet_getmsgdef(defpool.ptr())); EXPECT_TRUE(m.ptr() != nullptr); upb_test_TestMessageSet* message_set = upb_test_TestMessageSet_parse_ex( serialized, size, upb_DefPool_ExtensionRegistry(defpool.ptr()), 0, arena.ptr()); ASSERT_TRUE(message_set != nullptr); char* serialized2 = upb_test_TestMessageSet_serialize(message_set, arena.ptr(), &size); ASSERT_TRUE(serialized2 != nullptr); ASSERT_GE(size, 0); // Parse back into a fake MessageSet and verify that the unknown MessageSet // item was preserved in full (both type_id and message). upb_test_FakeMessageSet* fake2 = upb_test_FakeMessageSet_parse(serialized2, size, arena.ptr()); ASSERT_TRUE(fake2 != nullptr); const upb_test_FakeMessageSet_Item* const* items = upb_test_FakeMessageSet_item(fake2, &size); ASSERT_EQ(1, size); EXPECT_EQ(12345, upb_test_FakeMessageSet_Item_type_id(items[0])); EXPECT_TRUE(upb_StringView_IsEqual( data_view, upb_test_FakeMessageSet_Item_message(items[0]))); // The non-MessageSet unknown fields should have been discarded. EXPECT_FALSE(upb_test_FakeMessageSet_Item_has_unknown_varint(items[0])); EXPECT_FALSE(upb_test_FakeMessageSet_Item_has_unknown_fixed32(items[0])); EXPECT_FALSE(upb_test_FakeMessageSet_Item_has_unknown_fixed64(items[0])); EXPECT_FALSE(upb_test_FakeMessageSet_Item_has_unknown_bytes(items[0])); EXPECT_FALSE(upb_test_FakeMessageSet_Item_has_unknowngroup(items[0])); } TEST(MessageTest, Proto2Enum) { upb::Arena arena; upb_test_Proto2FakeEnumMessage* fake_msg = upb_test_Proto2FakeEnumMessage_new(arena.ptr()); upb_test_Proto2FakeEnumMessage_set_optional_enum(fake_msg, 999); int32_t* vals = upb_test_Proto2FakeEnumMessage_resize_repeated_enum( fake_msg, 6, arena.ptr()); vals[0] = upb_test_Proto2EnumMessage_ZERO; vals[1] = 7; // Unknown small. vals[2] = upb_test_Proto2EnumMessage_SMALL; vals[3] = 888; // Unknown large. vals[4] = upb_test_Proto2EnumMessage_LARGE; vals[5] = upb_test_Proto2EnumMessage_NEGATIVE; vals = upb_test_Proto2FakeEnumMessage_resize_packed_enum(fake_msg, 6, arena.ptr()); vals[0] = upb_test_Proto2EnumMessage_ZERO; vals[1] = 7; // Unknown small. vals[2] = upb_test_Proto2EnumMessage_SMALL; vals[3] = 888; // Unknown large. vals[4] = upb_test_Proto2EnumMessage_LARGE; vals[5] = upb_test_Proto2EnumMessage_NEGATIVE; size_t size; char* pb = upb_test_Proto2FakeEnumMessage_serialize(fake_msg, arena.ptr(), &size); // Parsing as enums puts unknown values into unknown fields. upb_test_Proto2EnumMessage* enum_msg = upb_test_Proto2EnumMessage_parse(pb, size, arena.ptr()); ASSERT_TRUE(enum_msg != nullptr); EXPECT_EQ(false, upb_test_Proto2EnumMessage_has_optional_enum(enum_msg)); const int32_t* vals_const = upb_test_Proto2EnumMessage_repeated_enum(enum_msg, &size); EXPECT_EQ(4, size); // Two unknown values moved to the unknown field set. // Parsing back into the fake message shows the original data, except the // repeated enum is rearranged. pb = upb_test_Proto2EnumMessage_serialize(enum_msg, arena.ptr(), &size); upb_test_Proto2FakeEnumMessage* fake_msg2 = upb_test_Proto2FakeEnumMessage_parse(pb, size, arena.ptr()); ASSERT_TRUE(fake_msg2 != nullptr); EXPECT_EQ(true, upb_test_Proto2FakeEnumMessage_has_optional_enum(fake_msg2)); EXPECT_EQ(999, upb_test_Proto2FakeEnumMessage_optional_enum(fake_msg2)); int32_t expected[] = { upb_test_Proto2EnumMessage_ZERO, upb_test_Proto2EnumMessage_SMALL, upb_test_Proto2EnumMessage_LARGE, upb_test_Proto2EnumMessage_NEGATIVE, 7, 888, }; vals_const = upb_test_Proto2FakeEnumMessage_repeated_enum(fake_msg2, &size); EXPECT_EQ(6, size); EXPECT_THAT(std::vector(vals_const, vals_const + size), ::testing::ElementsAreArray(expected)); vals_const = upb_test_Proto2FakeEnumMessage_packed_enum(fake_msg2, &size); EXPECT_EQ(6, size); EXPECT_THAT(std::vector(vals_const, vals_const + size), ::testing::ElementsAreArray(expected)); } TEST(MessageTest, TestBadUTF8) { upb::Arena arena; std::string serialized("r\x03\xed\xa0\x81"); EXPECT_EQ(nullptr, protobuf_test_messages_proto3_TestAllTypesProto3_parse( serialized.data(), serialized.size(), arena.ptr())); } TEST(MessageTest, DecodeRequiredFieldsTopLevelMessage) { upb::Arena arena; upb_test_TestRequiredFields* test_msg; upb_test_EmptyMessage* empty_msg; // Succeeds, because we did not request required field checks. test_msg = upb_test_TestRequiredFields_parse(nullptr, 0, arena.ptr()); EXPECT_NE(nullptr, test_msg); // Fails, because required fields are missing. EXPECT_EQ(kUpb_DecodeStatus_MissingRequired, upb_Decode(nullptr, 0, UPB_UPCAST(test_msg), &upb_0test__TestRequiredFields_msg_init, nullptr, kUpb_DecodeOption_CheckRequired, arena.ptr())); upb_test_TestRequiredFields_set_required_int32(test_msg, 1); size_t size; char* serialized = upb_test_TestRequiredFields_serialize(test_msg, arena.ptr(), &size); ASSERT_TRUE(serialized != nullptr); EXPECT_NE(0, size); // Fails, but the code path is slightly different because the serialized // payload is not empty. EXPECT_EQ(kUpb_DecodeStatus_MissingRequired, upb_Decode(serialized, size, UPB_UPCAST(test_msg), &upb_0test__TestRequiredFields_msg_init, nullptr, kUpb_DecodeOption_CheckRequired, arena.ptr())); empty_msg = upb_test_EmptyMessage_new(arena.ptr()); upb_test_TestRequiredFields_set_required_int32(test_msg, 1); upb_test_TestRequiredFields_set_required_int64(test_msg, 2); upb_test_TestRequiredFields_set_required_message(test_msg, empty_msg); // Succeeds, because required fields are present (though not in the input). EXPECT_EQ(kUpb_DecodeStatus_Ok, upb_Decode(nullptr, 0, UPB_UPCAST(test_msg), &upb_0test__TestRequiredFields_msg_init, nullptr, kUpb_DecodeOption_CheckRequired, arena.ptr())); // Serialize a complete payload. serialized = upb_test_TestRequiredFields_serialize(test_msg, arena.ptr(), &size); ASSERT_TRUE(serialized != nullptr); EXPECT_NE(0, size); upb_test_TestRequiredFields* test_msg2 = upb_test_TestRequiredFields_parse_ex( serialized, size, nullptr, kUpb_DecodeOption_CheckRequired, arena.ptr()); EXPECT_NE(nullptr, test_msg2); // When we add an incomplete sub-message, this is not flagged by the parser. // This makes parser checking unsuitable for MergeFrom(). upb_test_TestRequiredFields_set_optional_message( test_msg2, upb_test_TestRequiredFields_new(arena.ptr())); EXPECT_EQ(kUpb_DecodeStatus_Ok, upb_Decode(serialized, size, UPB_UPCAST(test_msg2), &upb_0test__TestRequiredFields_msg_init, nullptr, kUpb_DecodeOption_CheckRequired, arena.ptr())); } TEST(MessageTest, DecodeRequiredFieldsSubMessage) { upb::Arena arena; upb_test_TestRequiredFields* test_msg = upb_test_TestRequiredFields_new(arena.ptr()); upb_test_SubMessageHasRequired* sub_msg = upb_test_SubMessageHasRequired_new(arena.ptr()); upb_test_EmptyMessage* empty_msg = upb_test_EmptyMessage_new(arena.ptr()); upb_test_SubMessageHasRequired_set_optional_message(sub_msg, test_msg); size_t size; char* serialized = upb_test_SubMessageHasRequired_serialize(sub_msg, arena.ptr(), &size); EXPECT_NE(0, size); // No parse error when parsing normally. EXPECT_NE(nullptr, upb_test_SubMessageHasRequired_parse(serialized, size, arena.ptr())); // Parse error when verifying required fields, due to incomplete sub-message. EXPECT_EQ(nullptr, upb_test_SubMessageHasRequired_parse_ex( serialized, size, nullptr, kUpb_DecodeOption_CheckRequired, arena.ptr())); upb_test_TestRequiredFields_set_required_int32(test_msg, 1); upb_test_TestRequiredFields_set_required_int64(test_msg, 2); upb_test_TestRequiredFields_set_required_message(test_msg, empty_msg); serialized = upb_test_SubMessageHasRequired_serialize(sub_msg, arena.ptr(), &size); EXPECT_NE(0, size); // No parse error; sub-message now is complete. EXPECT_NE(nullptr, upb_test_SubMessageHasRequired_parse_ex( serialized, size, nullptr, kUpb_DecodeOption_CheckRequired, arena.ptr())); } TEST(MessageTest, EncodeRequiredFields) { upb::Arena arena; upb_test_TestRequiredFields* test_msg = upb_test_TestRequiredFields_new(arena.ptr()); // Succeeds, we didn't ask for required field checking. size_t size; char* serialized = upb_test_TestRequiredFields_serialize_ex(test_msg, 0, arena.ptr(), &size); ASSERT_TRUE(serialized != nullptr); EXPECT_EQ(size, 0); // Fails, we asked for required field checking but the required field is // missing. serialized = upb_test_TestRequiredFields_serialize_ex( test_msg, kUpb_EncodeOption_CheckRequired, arena.ptr(), &size); ASSERT_TRUE(serialized == nullptr); // Fails, some required fields are present but not others. upb_test_TestRequiredFields_set_required_int32(test_msg, 1); serialized = upb_test_TestRequiredFields_serialize_ex( test_msg, kUpb_EncodeOption_CheckRequired, arena.ptr(), &size); ASSERT_TRUE(serialized == nullptr); // Succeeds, all required fields are set. upb_test_EmptyMessage* empty_msg = upb_test_EmptyMessage_new(arena.ptr()); upb_test_TestRequiredFields_set_required_int64(test_msg, 2); upb_test_TestRequiredFields_set_required_message(test_msg, empty_msg); serialized = upb_test_TestRequiredFields_serialize_ex( test_msg, kUpb_EncodeOption_CheckRequired, arena.ptr(), &size); ASSERT_TRUE(serialized != nullptr); } TEST(MessageTest, MaxRequiredFields) { upb::Arena arena; upb_test_TestMaxRequiredFields* test_msg = upb_test_TestMaxRequiredFields_new(arena.ptr()); // Fails, we asked for required field checking but the required field is // missing. size_t size; char* serialized = upb_test_TestMaxRequiredFields_serialize_ex( test_msg, kUpb_EncodeOption_CheckRequired, arena.ptr(), &size); ASSERT_TRUE(serialized == nullptr); upb::DefPool defpool; upb::MessageDefPtr m(upb_test_TestMaxRequiredFields_getmsgdef(defpool.ptr())); upb_MessageValue val; val.int32_val = 1; for (int i = 1; i <= 61; i++) { upb::FieldDefPtr f = m.FindFieldByNumber(i); ASSERT_TRUE(f); upb_Message_SetFieldByDef(UPB_UPCAST(test_msg), f.ptr(), val, arena.ptr()); } // Fails, field 63 still isn't set. serialized = upb_test_TestMaxRequiredFields_serialize_ex( test_msg, kUpb_EncodeOption_CheckRequired, arena.ptr(), &size); ASSERT_TRUE(serialized == nullptr); // Succeeds, all required fields are set. upb::FieldDefPtr f = m.FindFieldByNumber(62); ASSERT_TRUE(f); upb_Message_SetFieldByDef(UPB_UPCAST(test_msg), f.ptr(), val, arena.ptr()); serialized = upb_test_TestMaxRequiredFields_serialize_ex( test_msg, kUpb_EncodeOption_CheckRequired, arena.ptr(), &size); ASSERT_TRUE(serialized != nullptr); } TEST(MessageTest, MapField) { upb::Arena arena; upb_test_TestMapFieldExtra* test_msg_extra = upb_test_TestMapFieldExtra_new(arena.ptr()); ASSERT_TRUE(upb_test_TestMapFieldExtra_map_field_set( test_msg_extra, 0, upb_test_TestMapFieldExtra_THREE, arena.ptr())); size_t size; char* serialized = upb_test_TestMapFieldExtra_serialize_ex( test_msg_extra, 0, arena.ptr(), &size); ASSERT_NE(nullptr, serialized); ASSERT_NE(0, size); upb_test_TestMapField* test_msg = upb_test_TestMapField_parse(serialized, size, arena.ptr()); ASSERT_NE(nullptr, test_msg); ASSERT_FALSE(upb_test_TestMapField_map_field_get(test_msg, 0, nullptr)); serialized = upb_test_TestMapField_serialize_ex(test_msg, 0, arena.ptr(), &size); ASSERT_NE(0, size); // parse into second instance upb_test_TestMapFieldExtra* test_msg_extra2 = upb_test_TestMapFieldExtra_parse(serialized, size, arena.ptr()); ASSERT_TRUE( upb_test_TestMapFieldExtra_map_field_get(test_msg_extra2, 0, nullptr)); } TEST(MessageTest, Freeze) { const upb_MiniTable* m = &upb_0test__TestFreeze_msg_init; upb::Arena arena; { upb_test_TestFreeze* raw = upb_test_TestFreeze_new(arena.ptr()); upb_Message* msg = UPB_UPCAST(raw); ASSERT_FALSE(upb_Message_IsFrozen(msg)); upb_Message_Freeze(msg, m); ASSERT_TRUE(upb_Message_IsFrozen(msg)); } { upb_test_TestFreeze* raw = upb_test_TestFreeze_new(arena.ptr()); upb_Message* msg = UPB_UPCAST(raw); size_t size; upb_Array* arr = _upb_test_TestFreeze_array_int_mutable_upb_array( raw, &size, arena.ptr()); ASSERT_NE(arr, nullptr); ASSERT_EQ(size, 0); ASSERT_FALSE(upb_Array_IsFrozen(arr)); upb_Map* map = _upb_test_TestFreeze_map_int_mutable_upb_map(raw, arena.ptr()); ASSERT_NE(map, nullptr); ASSERT_FALSE(upb_Map_IsFrozen(map)); upb_test_TestFreeze* nest = upb_test_TestFreeze_new(arena.ptr()); upb_test_set_nest(raw, nest, arena.ptr()); ASSERT_FALSE(upb_Message_IsFrozen(UPB_UPCAST(nest))); upb_Message_Freeze(msg, m); ASSERT_TRUE(upb_Message_IsFrozen(msg)); ASSERT_TRUE(upb_Array_IsFrozen(arr)); ASSERT_TRUE(upb_Map_IsFrozen(map)); ASSERT_TRUE(upb_Message_IsFrozen(UPB_UPCAST(nest))); } { upb_test_TestFreeze* raw = upb_test_TestFreeze_new(arena.ptr()); upb_Message* msg = UPB_UPCAST(raw); size_t size; upb_Array* arr = _upb_test_TestFreeze_array_int_mutable_upb_array( raw, &size, arena.ptr()); ASSERT_NE(arr, nullptr); ASSERT_EQ(size, 0); ASSERT_FALSE(upb_Array_IsFrozen(arr)); upb_Map* map = _upb_test_TestFreeze_map_int_mutable_upb_map(raw, arena.ptr()); ASSERT_NE(map, nullptr); ASSERT_FALSE(upb_Map_IsFrozen(map)); upb_test_TestFreeze* nest = upb_test_TestFreeze_new(arena.ptr()); upb_test_set_nest(raw, nest, arena.ptr()); ASSERT_FALSE(upb_Message_IsFrozen(UPB_UPCAST(nest))); upb_Message_Freeze(UPB_UPCAST(nest), m); ASSERT_FALSE(upb_Message_IsFrozen(msg)); ASSERT_FALSE(upb_Array_IsFrozen(arr)); ASSERT_FALSE(upb_Map_IsFrozen(map)); ASSERT_TRUE(upb_Message_IsFrozen(UPB_UPCAST(nest))); const upb_MiniTableField* fa = upb_MiniTable_FindFieldByNumber(m, 20); const upb_MiniTable* ma = upb_MiniTable_SubMessage(m, fa); upb_Array_Freeze(arr, ma); ASSERT_FALSE(upb_Message_IsFrozen(msg)); ASSERT_TRUE(upb_Array_IsFrozen(arr)); ASSERT_FALSE(upb_Map_IsFrozen(map)); ASSERT_TRUE(upb_Message_IsFrozen(UPB_UPCAST(nest))); const upb_MiniTableField* fm = upb_MiniTable_FindFieldByNumber(m, 10); const upb_MiniTable* mm = upb_MiniTable_SubMessage(m, fm); upb_Map_Freeze(map, mm); ASSERT_FALSE(upb_Message_IsFrozen(msg)); ASSERT_TRUE(upb_Array_IsFrozen(arr)); ASSERT_TRUE(upb_Map_IsFrozen(map)); ASSERT_TRUE(upb_Message_IsFrozen(UPB_UPCAST(nest))); } } // begin:google_only // // static void DecodeEncodeArbitrarySchemaAndPayload( // const upb::fuzz::MiniTableFuzzInput& input, std::string_view proto_payload, // int decode_options, int encode_options) { // // Lexan does not have setenv // #ifndef _MSC_VER // setenv("FUZZTEST_STACK_LIMIT", "262144", 1); // #endif // // The value of 80 used here is empirical and intended to roughly represent // // the tiny 64K stack size used by the test framework. We still see the // // occasional stack overflow at 90, so far 80 has worked 100% of the time. // decode_options = upb_Decode_LimitDepth(decode_options, 80); // encode_options = upb_Encode_LimitDepth(encode_options, 80); // // upb::Arena arena; // upb_ExtensionRegistry* exts; // const upb_MiniTable* mini_table = // upb::fuzz::BuildMiniTable(input, &exts, arena.ptr()); // if (!mini_table) return; // upb_Message* msg = upb_Message_New(mini_table, arena.ptr()); // upb_Decode(proto_payload.data(), proto_payload.size(), msg, mini_table, exts, // decode_options, arena.ptr()); // char* ptr; // size_t size; // upb_Encode(msg, mini_table, encode_options, arena.ptr(), &ptr, &size); // } // FUZZ_TEST(FuzzTest, DecodeEncodeArbitrarySchemaAndPayload); // // TEST(FuzzTest, DecodeUnknownProto2EnumExtension) { // DecodeEncodeArbitrarySchemaAndPayload( // {{"\256\354Rt\216\3271\234", "\243\243\267\207\336gV\366w"}, // {"z"}, // "}\212\304d\371\363\341\2329\325B\264\377?\215\223\201\201\226y\201%" // "\321\363\255;", // {}}, // "\010", -724543908, -591643538); // } // // TEST(FuzzTest, DecodeExtensionEnsurePresenceInitialized) { // DecodeEncodeArbitrarySchemaAndPayload( // {{"\031", "S", "\364", "", "", "j", "\303", "", "\224", "\277"}, // {}, // "_C-\236$*)C0C>", // {4041515984, 2147483647, 1929379871, 0, 3715937258, 4294967295}}, // "\010\002", 342248070, -806315555); // } // // TEST(FuzzTest, DecodeExtendMessageSetWithNonMessage) { // DecodeEncodeArbitrarySchemaAndPayload( // {{"\n"}, {""}, ".\244", {}}, "\013\032\005\212a#\365\336\020\001\226", // 14803219, 670718349); // } // // TEST(FuzzTest, DecodeExtendMessageSetWithNonMessage2) { // DecodeEncodeArbitrarySchemaAndPayload({{"\n", "G", "\n", "\274", ""}, // {"", "\030"}, // "_@", // {4294967295, 2147483647}}, // std::string("\013\032\000\220", 4), // 279975758, 1647495141); // } // // TEST(FuzzTest, DecodeExtendMessageSetWithNonMessage3) { // DecodeEncodeArbitrarySchemaAndPayload( // {{"\n"}, {"B", ""}, "\212:b", {11141121}}, // "\013\032\004\357;7\363\020\001\346\240\200\201\271", 399842149, // -452966025); // } // // TEST(FuzzTest, DecodeExtendMessageSetWithNonMessage4) { // DecodeEncodeArbitrarySchemaAndPayload( // {{"\n", "3\340", "\354"}, {}, "B}G", {4294967295, 4082331310}}, // "\013\032\004\244B\331\255\020\001\220\224\243\350\t", -561523015, // 1683327312); // } // // TEST(FuzzTest, DecodeExtendMessageSetWithNonMessage5) { // DecodeEncodeArbitrarySchemaAndPayload( // {{"\n"}, {""}, "kB", {0}}, // "x\203\251\006\013\032\002S\376\010\273\'\020\014\365\207\244\234", // -696925610, -654590577); // } // // TEST(FuzzTest, ExtendMessageSetWithEmptyExtension) { // DecodeEncodeArbitrarySchemaAndPayload({{"\n"}, {}, "_", {}}, std::string(), 0, // 0); // } // // TEST(FuzzTest, DecodeEncodeArbitrarySchemaAndPayloadRegression) { // DecodeEncodeArbitrarySchemaAndPayload( // {{"\320", "\320", "\320", "\320", "\320", "%2%%%%%"}, // {"", "", "", "", "", "", "", "", "", "", "", "", // "", "", "", "", "", "", "", "", "", "", ""}, // "\226\226\226\226\226\226\350\351\350\350\350\350\350\350\350\314", // {4026531839}}, // std::string("\n\n\n\n\272\n======@@%%%%%%%%%%%%%%%@@@((" // "qqqqqqqq5555555555qqqqqffq((((((((((((\335@@>" // "\ru\360ncppppxxxxxxxxx\025\025\025xxxxxppppppp<=" // "\2165\275\275\315\217\361\010\t\000\016\013in\n\n\n\256\263", // 130), // 901979906, 65537); // } // // // This test encodes a map field with extra cruft. // TEST(FuzzTest, DecodeEncodeArbitrarySchemaAndPayloadRegressionInvalidMap) { // DecodeEncodeArbitrarySchemaAndPayload({{"%%%%///////"}, {}, "", {}}, // std::string("\035|", 2), 65536, 3); // } // // // This test found a case where presence was unset for a mini table field. // TEST(FuzzTest, DecodeEncodeArbitrarySchemaAndPayloadRegressionMsan) { // DecodeEncodeArbitrarySchemaAndPayload({{"%-#^#"}, {}, "", {}}, std::string(), // -1960166338, 16809991); // } // // // This test encodes a map containing a msg wrapping another, empty msg. // TEST(FuzzTest, DecodeEncodeArbitrarySchemaAndPayloadRegressionMapMap) { // DecodeEncodeArbitrarySchemaAndPayload( // {{"%#G"}, {}, "", {}}, std::string("\022\002\022\000", 4), 0, 0); // } // // TEST(FuzzTest, GroupMap) { // // Groups should not be allowed as maps, but we previously failed to prevent // // this. // DecodeEncodeArbitrarySchemaAndPayload( // {.mini_descriptors = {"$$FF$", "%-C"}, // .enum_mini_descriptors = {}, // .extensions = "", // .links = {1}}, // std::string( // "\023\020\030\233\000\204\330\372#\000`" // "a\000\000\001\000\000\000ccccccc\030s\273sssssssss\030\030\030\030" // "\030\030\030\030\215\215\215\215\215\215\215\215\030\030\232\253\253" // "\232*\334\227\273\231\207\373\t\0051\305\265\335\224\226"), // 0, 0); // } // // TEST(FuzzTest, MapUnknownFieldSpanBuffers) { // DecodeEncodeArbitrarySchemaAndPayload( // {{"$ 3", "%# "}, {}, "", {1}}, // std::string( // "\"\002\010\000\000\000\000\000\000\000\000\000\000\000\000\000\000", // 17), // 0, 0); // } // // // Another test for mismatched submsg types. // TEST(FuzzTest, DecodeEncodeArbitrarySchemaAndPayloadRegression22) { // DecodeEncodeArbitrarySchemaAndPayload( // {{"$2222222222222222222222", "%,&"}, {}, "", {1}}, // std::string("\035\170\170\170\051\263\001\030\000\035\357\357\340\021\035" // "\025\331\035\035\035\035\035\035\035\035", // 25), // 0, 0); // } // // TEST(FuzzTest, ExtensionWithoutExt) { // DecodeEncodeArbitrarySchemaAndPayload({{"$ 3", "", "%#F"}, {}, "", {2, 1}}, // std::string("\022\002\010\000", 4), 0, // 0); // } // // TEST(FuzzTest, MapFieldVerify) { // DecodeEncodeArbitrarySchemaAndPayload({{"% ^!"}, {}, "", {}}, "", 0, 0); // } // // TEST(FuzzTest, TooManyRequiredFields) { // DecodeEncodeArbitrarySchemaAndPayload( // {{"$ N N N N N N N N N N N N N N N N N N N N N N N N N N N N N N N N N N " // "N N N N N N N N N N N N N N N N N N N N N N N N N N N N N N N"}, // {}, // "", // {}}, // "", 0, 4); // } // // end:google_only