/* * Copyright 2014 Google Inc. All rights reserved. * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #include #include "flatbuffers/flatbuffers.h" #include "flatbuffers/idl.h" #include "flatbuffers/minireflect.h" #include "flatbuffers/registry.h" #include "flatbuffers/util.h" // clang-format off #ifdef FLATBUFFERS_CPP98_STL namespace std { using flatbuffers::unique_ptr; } #endif // clang-format on #include "monster_test_generated.h" #include "namespace_test/namespace_test1_generated.h" #include "namespace_test/namespace_test2_generated.h" #include "union_vector/union_vector_generated.h" #include "optional_scalars_generated.h" #if !defined(_MSC_VER) || _MSC_VER >= 1700 # include "monster_extra_generated.h" # include "arrays_test_generated.h" # include "evolution_test/evolution_v1_generated.h" # include "evolution_test/evolution_v2_generated.h" #endif #include "native_type_test_generated.h" #include "test_assert.h" #include "flatbuffers/flexbuffers.h" #include "monster_test_bfbs_generated.h" // Generated using --bfbs-comments --bfbs-builtins --cpp --bfbs-gen-embed // clang-format off // Check that char* and uint8_t* are interoperable types. // The reinterpret_cast<> between the pointers are used to simplify data loading. static_assert(flatbuffers::is_same::value || flatbuffers::is_same::value, "unexpected uint8_t type"); #if defined(FLATBUFFERS_HAS_NEW_STRTOD) && (FLATBUFFERS_HAS_NEW_STRTOD > 0) // Ensure IEEE-754 support if tests of floats with NaN/Inf will run. static_assert(std::numeric_limits::is_iec559 && std::numeric_limits::is_iec559, "IEC-559 (IEEE-754) standard required"); #endif // clang-format on // Shortcuts for the infinity. static const auto infinity_f = std::numeric_limits::infinity(); static const auto infinity_d = std::numeric_limits::infinity(); using namespace MyGame::Example; void FlatBufferBuilderTest(); // Include simple random number generator to ensure results will be the // same cross platform. // http://en.wikipedia.org/wiki/Park%E2%80%93Miller_random_number_generator uint32_t lcg_seed = 48271; uint32_t lcg_rand() { return lcg_seed = (static_cast(lcg_seed) * 279470273UL) % 4294967291UL; } void lcg_reset() { lcg_seed = 48271; } std::string test_data_path = #ifdef BAZEL_TEST_DATA_PATH "../com_github_google_flatbuffers/tests/"; #else "tests/"; #endif // example of how to build up a serialized buffer algorithmically: flatbuffers::DetachedBuffer CreateFlatBufferTest(std::string &buffer) { flatbuffers::FlatBufferBuilder builder; auto vec = Vec3(1, 2, 3, 0, Color_Red, Test(10, 20)); auto name = builder.CreateString("MyMonster"); unsigned char inv_data[] = { 0, 1, 2, 3, 4, 5, 6, 7, 8, 9 }; auto inventory = builder.CreateVector(inv_data, 10); // Alternatively, create the vector first, and fill in data later: // unsigned char *inv_buf = nullptr; // auto inventory = builder.CreateUninitializedVector( // 10, &inv_buf); // memcpy(inv_buf, inv_data, 10); Test tests[] = { Test(10, 20), Test(30, 40) }; auto testv = builder.CreateVectorOfStructs(tests, 2); // clang-format off #ifndef FLATBUFFERS_CPP98_STL // Create a vector of structures from a lambda. auto testv2 = builder.CreateVectorOfStructs( 2, [&](size_t i, Test* s) -> void { *s = tests[i]; }); #else // Create a vector of structures using a plain old C++ function. auto testv2 = builder.CreateVectorOfStructs( 2, [](size_t i, Test* s, void *state) -> void { *s = (reinterpret_cast(state))[i]; }, tests); #endif // FLATBUFFERS_CPP98_STL // clang-format on // create monster with very few fields set: // (same functionality as CreateMonster below, but sets fields manually) flatbuffers::Offset mlocs[3]; auto fred = builder.CreateString("Fred"); auto barney = builder.CreateString("Barney"); auto wilma = builder.CreateString("Wilma"); MonsterBuilder mb1(builder); mb1.add_name(fred); mlocs[0] = mb1.Finish(); MonsterBuilder mb2(builder); mb2.add_name(barney); mb2.add_hp(1000); mlocs[1] = mb2.Finish(); MonsterBuilder mb3(builder); mb3.add_name(wilma); mlocs[2] = mb3.Finish(); // Create an array of strings. Also test string pooling, and lambdas. auto vecofstrings = builder.CreateVector>( 4, [](size_t i, flatbuffers::FlatBufferBuilder *b) -> flatbuffers::Offset { static const char *names[] = { "bob", "fred", "bob", "fred" }; return b->CreateSharedString(names[i]); }, &builder); // Creating vectors of strings in one convenient call. std::vector names2; names2.push_back("jane"); names2.push_back("mary"); auto vecofstrings2 = builder.CreateVectorOfStrings(names2); // Create an array of sorted tables, can be used with binary search when read: auto vecoftables = builder.CreateVectorOfSortedTables(mlocs, 3); // Create an array of sorted structs, // can be used with binary search when read: std::vector abilities; abilities.push_back(Ability(4, 40)); abilities.push_back(Ability(3, 30)); abilities.push_back(Ability(2, 20)); abilities.push_back(Ability(0, 0)); auto vecofstructs = builder.CreateVectorOfSortedStructs(&abilities); flatbuffers::Offset mlocs_stats[1]; auto miss = builder.CreateString("miss"); StatBuilder mb_miss(builder); mb_miss.add_id(miss); mb_miss.add_val(0); mb_miss.add_count(0); // key mlocs_stats[0] = mb_miss.Finish(); auto vec_of_stats = builder.CreateVectorOfSortedTables(mlocs_stats, 1); // Create a nested FlatBuffer. // Nested FlatBuffers are stored in a ubyte vector, which can be convenient // since they can be memcpy'd around much easier than other FlatBuffer // values. They have little overhead compared to storing the table directly. // As a test, create a mostly empty Monster buffer: flatbuffers::FlatBufferBuilder nested_builder; auto nmloc = CreateMonster(nested_builder, nullptr, 0, 0, nested_builder.CreateString("NestedMonster")); FinishMonsterBuffer(nested_builder, nmloc); // Now we can store the buffer in the parent. Note that by default, vectors // are only aligned to their elements or size field, so in this case if the // buffer contains 64-bit elements, they may not be correctly aligned. We fix // that with: builder.ForceVectorAlignment(nested_builder.GetSize(), sizeof(uint8_t), nested_builder.GetBufferMinAlignment()); // If for whatever reason you don't have the nested_builder available, you // can substitute flatbuffers::largest_scalar_t (64-bit) for the alignment, or // the largest force_align value in your schema if you're using it. auto nested_flatbuffer_vector = builder.CreateVector( nested_builder.GetBufferPointer(), nested_builder.GetSize()); // Test a nested FlexBuffer: flexbuffers::Builder flexbuild; flexbuild.Int(1234); flexbuild.Finish(); auto flex = builder.CreateVector(flexbuild.GetBuffer()); // Test vector of enums. Color colors[] = { Color_Blue, Color_Green }; // We use this special creation function because we have an array of // pre-C++11 (enum class) enums whose size likely is int, yet its declared // type in the schema is byte. auto vecofcolors = builder.CreateVectorScalarCast(colors, 2); // shortcut for creating monster with all fields set: auto mloc = CreateMonster( builder, &vec, 150, 80, name, inventory, Color_Blue, Any_Monster, mlocs[1].Union(), // Store a union. testv, vecofstrings, vecoftables, 0, nested_flatbuffer_vector, 0, false, 0, 0, 0, 0, 0, 0, 0, 0, 0, 3.14159f, 3.0f, 0.0f, vecofstrings2, vecofstructs, flex, testv2, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, AnyUniqueAliases_NONE, 0, AnyAmbiguousAliases_NONE, 0, vecofcolors, MyGame::Example::Race_None, 0, vec_of_stats); FinishMonsterBuffer(builder, mloc); // clang-format off #ifdef FLATBUFFERS_TEST_VERBOSE // print byte data for debugging: auto p = builder.GetBufferPointer(); for (flatbuffers::uoffset_t i = 0; i < builder.GetSize(); i++) printf("%d ", p[i]); #endif // clang-format on // return the buffer for the caller to use. auto bufferpointer = reinterpret_cast(builder.GetBufferPointer()); buffer.assign(bufferpointer, bufferpointer + builder.GetSize()); return builder.Release(); } // example of accessing a buffer loaded in memory: void AccessFlatBufferTest(const uint8_t *flatbuf, size_t length, bool pooled = true) { // First, verify the buffers integrity (optional) flatbuffers::Verifier verifier(flatbuf, length); TEST_EQ(VerifyMonsterBuffer(verifier), true); // clang-format off #ifdef FLATBUFFERS_TRACK_VERIFIER_BUFFER_SIZE std::vector test_buff; test_buff.resize(length * 2); std::memcpy(&test_buff[0], flatbuf, length); std::memcpy(&test_buff[length], flatbuf, length); flatbuffers::Verifier verifier1(&test_buff[0], length); TEST_EQ(VerifyMonsterBuffer(verifier1), true); TEST_EQ(verifier1.GetComputedSize(), length); flatbuffers::Verifier verifier2(&test_buff[length], length); TEST_EQ(VerifyMonsterBuffer(verifier2), true); TEST_EQ(verifier2.GetComputedSize(), length); #endif // clang-format on TEST_EQ(strcmp(MonsterIdentifier(), "MONS"), 0); TEST_EQ(MonsterBufferHasIdentifier(flatbuf), true); TEST_EQ(strcmp(MonsterExtension(), "mon"), 0); // Access the buffer from the root. auto monster = GetMonster(flatbuf); TEST_EQ(monster->hp(), 80); TEST_EQ(monster->mana(), 150); // default TEST_EQ_STR(monster->name()->c_str(), "MyMonster"); // Can't access the following field, it is deprecated in the schema, // which means accessors are not generated: // monster.friendly() auto pos = monster->pos(); TEST_NOTNULL(pos); TEST_EQ(pos->z(), 3); TEST_EQ(pos->test3().a(), 10); TEST_EQ(pos->test3().b(), 20); auto inventory = monster->inventory(); TEST_EQ(VectorLength(inventory), 10UL); // Works even if inventory is null. TEST_NOTNULL(inventory); unsigned char inv_data[] = { 0, 1, 2, 3, 4, 5, 6, 7, 8, 9 }; // Check compatibilty of iterators with STL. std::vector inv_vec(inventory->begin(), inventory->end()); int n = 0; for (auto it = inventory->begin(); it != inventory->end(); ++it, ++n) { auto indx = it - inventory->begin(); TEST_EQ(*it, inv_vec.at(indx)); // Use bounds-check. TEST_EQ(*it, inv_data[indx]); } TEST_EQ(n, inv_vec.size()); n = 0; for (auto it = inventory->cbegin(); it != inventory->cend(); ++it, ++n) { auto indx = it - inventory->cbegin(); TEST_EQ(*it, inv_vec.at(indx)); // Use bounds-check. TEST_EQ(*it, inv_data[indx]); } TEST_EQ(n, inv_vec.size()); n = 0; for (auto it = inventory->rbegin(); it != inventory->rend(); ++it, ++n) { auto indx = inventory->rend() - it - 1; TEST_EQ(*it, inv_vec.at(indx)); // Use bounds-check. TEST_EQ(*it, inv_data[indx]); } TEST_EQ(n, inv_vec.size()); n = 0; for (auto it = inventory->crbegin(); it != inventory->crend(); ++it, ++n) { auto indx = inventory->crend() - it - 1; TEST_EQ(*it, inv_vec.at(indx)); // Use bounds-check. TEST_EQ(*it, inv_data[indx]); } TEST_EQ(n, inv_vec.size()); TEST_EQ(monster->color(), Color_Blue); // Example of accessing a union: TEST_EQ(monster->test_type(), Any_Monster); // First make sure which it is. auto monster2 = reinterpret_cast(monster->test()); TEST_NOTNULL(monster2); TEST_EQ_STR(monster2->name()->c_str(), "Fred"); // Example of accessing a vector of strings: auto vecofstrings = monster->testarrayofstring(); TEST_EQ(vecofstrings->size(), 4U); TEST_EQ_STR(vecofstrings->Get(0)->c_str(), "bob"); TEST_EQ_STR(vecofstrings->Get(1)->c_str(), "fred"); if (pooled) { // These should have pointer equality because of string pooling. TEST_EQ(vecofstrings->Get(0)->c_str(), vecofstrings->Get(2)->c_str()); TEST_EQ(vecofstrings->Get(1)->c_str(), vecofstrings->Get(3)->c_str()); } auto vecofstrings2 = monster->testarrayofstring2(); if (vecofstrings2) { TEST_EQ(vecofstrings2->size(), 2U); TEST_EQ_STR(vecofstrings2->Get(0)->c_str(), "jane"); TEST_EQ_STR(vecofstrings2->Get(1)->c_str(), "mary"); } // Example of accessing a vector of tables: auto vecoftables = monster->testarrayoftables(); TEST_EQ(vecoftables->size(), 3U); for (auto it = vecoftables->begin(); it != vecoftables->end(); ++it) { TEST_EQ(strlen(it->name()->c_str()) >= 4, true); } TEST_EQ_STR(vecoftables->Get(0)->name()->c_str(), "Barney"); TEST_EQ(vecoftables->Get(0)->hp(), 1000); TEST_EQ_STR(vecoftables->Get(1)->name()->c_str(), "Fred"); TEST_EQ_STR(vecoftables->Get(2)->name()->c_str(), "Wilma"); TEST_NOTNULL(vecoftables->LookupByKey("Barney")); TEST_NOTNULL(vecoftables->LookupByKey("Fred")); TEST_NOTNULL(vecoftables->LookupByKey("Wilma")); // Test accessing a vector of sorted structs auto vecofstructs = monster->testarrayofsortedstruct(); if (vecofstructs) { // not filled in monster_test.bfbs for (flatbuffers::uoffset_t i = 0; i < vecofstructs->size() - 1; i++) { auto left = vecofstructs->Get(i); auto right = vecofstructs->Get(i + 1); TEST_EQ(true, (left->KeyCompareLessThan(right))); } TEST_NOTNULL(vecofstructs->LookupByKey(0)); // test default value TEST_NOTNULL(vecofstructs->LookupByKey(3)); TEST_EQ(static_cast(nullptr), vecofstructs->LookupByKey(5)); } if (auto vec_of_stat = monster->scalar_key_sorted_tables()) { auto stat_0 = vec_of_stat->LookupByKey(static_cast(0u)); TEST_NOTNULL(stat_0); TEST_NOTNULL(stat_0->id()); TEST_EQ(0, stat_0->count()); TEST_EQ_STR("miss", stat_0->id()->c_str()); } // Test nested FlatBuffers if available: auto nested_buffer = monster->testnestedflatbuffer(); if (nested_buffer) { // nested_buffer is a vector of bytes you can memcpy. However, if you // actually want to access the nested data, this is a convenient // accessor that directly gives you the root table: auto nested_monster = monster->testnestedflatbuffer_nested_root(); TEST_EQ_STR(nested_monster->name()->c_str(), "NestedMonster"); } // Test flexbuffer if available: auto flex = monster->flex(); // flex is a vector of bytes you can memcpy etc. TEST_EQ(flex->size(), 4); // Encoded FlexBuffer bytes. // However, if you actually want to access the nested data, this is a // convenient accessor that directly gives you the root value: TEST_EQ(monster->flex_flexbuffer_root().AsInt16(), 1234); // Test vector of enums: auto colors = monster->vector_of_enums(); if (colors) { TEST_EQ(colors->size(), 2); TEST_EQ(colors->Get(0), Color_Blue); TEST_EQ(colors->Get(1), Color_Green); } // Since Flatbuffers uses explicit mechanisms to override the default // compiler alignment, double check that the compiler indeed obeys them: // (Test consists of a short and byte): TEST_EQ(flatbuffers::AlignOf(), 2UL); TEST_EQ(sizeof(Test), 4UL); const flatbuffers::Vector *tests_array[] = { monster->test4(), monster->test5(), }; for (size_t i = 0; i < sizeof(tests_array) / sizeof(tests_array[0]); ++i) { auto tests = tests_array[i]; TEST_NOTNULL(tests); auto test_0 = tests->Get(0); auto test_1 = tests->Get(1); TEST_EQ(test_0->a(), 10); TEST_EQ(test_0->b(), 20); TEST_EQ(test_1->a(), 30); TEST_EQ(test_1->b(), 40); for (auto it = tests->begin(); it != tests->end(); ++it) { TEST_EQ(it->a() == 10 || it->a() == 30, true); // Just testing iterators. } } // Checking for presence of fields: TEST_EQ(flatbuffers::IsFieldPresent(monster, Monster::VT_HP), true); TEST_EQ(flatbuffers::IsFieldPresent(monster, Monster::VT_MANA), false); // Obtaining a buffer from a root: TEST_EQ(GetBufferStartFromRootPointer(monster), flatbuf); } // Change a FlatBuffer in-place, after it has been constructed. void MutateFlatBuffersTest(uint8_t *flatbuf, std::size_t length) { // Get non-const pointer to root. auto monster = GetMutableMonster(flatbuf); // Each of these tests mutates, then tests, then set back to the original, // so we can test that the buffer in the end still passes our original test. auto hp_ok = monster->mutate_hp(10); TEST_EQ(hp_ok, true); // Field was present. TEST_EQ(monster->hp(), 10); // Mutate to default value auto hp_ok_default = monster->mutate_hp(100); TEST_EQ(hp_ok_default, true); // Field was present. TEST_EQ(monster->hp(), 100); // Test that mutate to default above keeps field valid for further mutations auto hp_ok_2 = monster->mutate_hp(20); TEST_EQ(hp_ok_2, true); TEST_EQ(monster->hp(), 20); monster->mutate_hp(80); // Monster originally at 150 mana (default value) auto mana_default_ok = monster->mutate_mana(150); // Mutate to default value. TEST_EQ(mana_default_ok, true); // Mutation should succeed, because default value. TEST_EQ(monster->mana(), 150); auto mana_ok = monster->mutate_mana(10); TEST_EQ(mana_ok, false); // Field was NOT present, because default value. TEST_EQ(monster->mana(), 150); // Mutate structs. auto pos = monster->mutable_pos(); auto test3 = pos->mutable_test3(); // Struct inside a struct. test3.mutate_a(50); // Struct fields never fail. TEST_EQ(test3.a(), 50); test3.mutate_a(10); // Mutate vectors. auto inventory = monster->mutable_inventory(); inventory->Mutate(9, 100); TEST_EQ(inventory->Get(9), 100); inventory->Mutate(9, 9); auto tables = monster->mutable_testarrayoftables(); auto first = tables->GetMutableObject(0); TEST_EQ(first->hp(), 1000); first->mutate_hp(0); TEST_EQ(first->hp(), 0); first->mutate_hp(1000); // Run the verifier and the regular test to make sure we didn't trample on // anything. AccessFlatBufferTest(flatbuf, length); } // Unpack a FlatBuffer into objects. void ObjectFlatBuffersTest(uint8_t *flatbuf) { // Optional: we can specify resolver and rehasher functions to turn hashed // strings into object pointers and back, to implement remote references // and such. auto resolver = flatbuffers::resolver_function_t( [](void **pointer_adr, flatbuffers::hash_value_t hash) { (void)pointer_adr; (void)hash; // Don't actually do anything, leave variable null. }); auto rehasher = flatbuffers::rehasher_function_t( [](void *pointer) -> flatbuffers::hash_value_t { (void)pointer; return 0; }); // Turn a buffer into C++ objects. auto monster1 = UnPackMonster(flatbuf, &resolver); // Re-serialize the data. flatbuffers::FlatBufferBuilder fbb1; fbb1.Finish(CreateMonster(fbb1, monster1.get(), &rehasher), MonsterIdentifier()); // Unpack again, and re-serialize again. auto monster2 = UnPackMonster(fbb1.GetBufferPointer(), &resolver); flatbuffers::FlatBufferBuilder fbb2; fbb2.Finish(CreateMonster(fbb2, monster2.get(), &rehasher), MonsterIdentifier()); // Now we've gone full round-trip, the two buffers should match. auto len1 = fbb1.GetSize(); auto len2 = fbb2.GetSize(); TEST_EQ(len1, len2); TEST_EQ(memcmp(fbb1.GetBufferPointer(), fbb2.GetBufferPointer(), len1), 0); // Test it with the original buffer test to make sure all data survived. AccessFlatBufferTest(fbb2.GetBufferPointer(), len2, false); // Test accessing fields, similar to AccessFlatBufferTest above. TEST_EQ(monster2->hp, 80); TEST_EQ(monster2->mana, 150); // default TEST_EQ_STR(monster2->name.c_str(), "MyMonster"); auto &pos = monster2->pos; TEST_NOTNULL(pos); TEST_EQ(pos->z(), 3); TEST_EQ(pos->test3().a(), 10); TEST_EQ(pos->test3().b(), 20); auto &inventory = monster2->inventory; TEST_EQ(inventory.size(), 10UL); unsigned char inv_data[] = { 0, 1, 2, 3, 4, 5, 6, 7, 8, 9 }; for (auto it = inventory.begin(); it != inventory.end(); ++it) TEST_EQ(*it, inv_data[it - inventory.begin()]); TEST_EQ(monster2->color, Color_Blue); auto monster3 = monster2->test.AsMonster(); TEST_NOTNULL(monster3); TEST_EQ_STR(monster3->name.c_str(), "Fred"); auto &vecofstrings = monster2->testarrayofstring; TEST_EQ(vecofstrings.size(), 4U); TEST_EQ_STR(vecofstrings[0].c_str(), "bob"); TEST_EQ_STR(vecofstrings[1].c_str(), "fred"); auto &vecofstrings2 = monster2->testarrayofstring2; TEST_EQ(vecofstrings2.size(), 2U); TEST_EQ_STR(vecofstrings2[0].c_str(), "jane"); TEST_EQ_STR(vecofstrings2[1].c_str(), "mary"); auto &vecoftables = monster2->testarrayoftables; TEST_EQ(vecoftables.size(), 3U); TEST_EQ_STR(vecoftables[0]->name.c_str(), "Barney"); TEST_EQ(vecoftables[0]->hp, 1000); TEST_EQ_STR(vecoftables[1]->name.c_str(), "Fred"); TEST_EQ_STR(vecoftables[2]->name.c_str(), "Wilma"); auto &tests = monster2->test4; TEST_EQ(tests[0].a(), 10); TEST_EQ(tests[0].b(), 20); TEST_EQ(tests[1].a(), 30); TEST_EQ(tests[1].b(), 40); } // Prefix a FlatBuffer with a size field. void SizePrefixedTest() { // Create size prefixed buffer. flatbuffers::FlatBufferBuilder fbb; FinishSizePrefixedMonsterBuffer( fbb, CreateMonster(fbb, 0, 200, 300, fbb.CreateString("bob"))); // Verify it. flatbuffers::Verifier verifier(fbb.GetBufferPointer(), fbb.GetSize()); TEST_EQ(VerifySizePrefixedMonsterBuffer(verifier), true); // Access it. auto m = GetSizePrefixedMonster(fbb.GetBufferPointer()); TEST_EQ(m->mana(), 200); TEST_EQ(m->hp(), 300); TEST_EQ_STR(m->name()->c_str(), "bob"); } void TriviallyCopyableTest() { // clang-format off #if __GNUG__ && __GNUC__ < 5 TEST_EQ(__has_trivial_copy(Vec3), true); #else #if __cplusplus >= 201103L TEST_EQ(std::is_trivially_copyable::value, true); #endif #endif // clang-format on } // Check stringify of an default enum value to json void JsonDefaultTest() { // load FlatBuffer schema (.fbs) from disk std::string schemafile; TEST_EQ(flatbuffers::LoadFile((test_data_path + "monster_test.fbs").c_str(), false, &schemafile), true); // parse schema first, so we can use it to parse the data after flatbuffers::Parser parser; auto include_test_path = flatbuffers::ConCatPathFileName(test_data_path, "include_test"); const char *include_directories[] = { test_data_path.c_str(), include_test_path.c_str(), nullptr }; TEST_EQ(parser.Parse(schemafile.c_str(), include_directories), true); // create incomplete monster and store to json parser.opts.output_default_scalars_in_json = true; parser.opts.output_enum_identifiers = true; flatbuffers::FlatBufferBuilder builder; auto name = builder.CreateString("default_enum"); MonsterBuilder color_monster(builder); color_monster.add_name(name); FinishMonsterBuffer(builder, color_monster.Finish()); std::string jsongen; auto result = GenerateText(parser, builder.GetBufferPointer(), &jsongen); TEST_EQ(result, true); // default value of the "color" field is Blue TEST_EQ(std::string::npos != jsongen.find("color: \"Blue\""), true); // default value of the "testf" field is 3.14159 TEST_EQ(std::string::npos != jsongen.find("testf: 3.14159"), true); } void JsonEnumsTest() { // load FlatBuffer schema (.fbs) from disk std::string schemafile; TEST_EQ(flatbuffers::LoadFile((test_data_path + "monster_test.fbs").c_str(), false, &schemafile), true); // parse schema first, so we can use it to parse the data after flatbuffers::Parser parser; auto include_test_path = flatbuffers::ConCatPathFileName(test_data_path, "include_test"); const char *include_directories[] = { test_data_path.c_str(), include_test_path.c_str(), nullptr }; parser.opts.output_enum_identifiers = true; TEST_EQ(parser.Parse(schemafile.c_str(), include_directories), true); flatbuffers::FlatBufferBuilder builder; auto name = builder.CreateString("bitflag_enum"); MonsterBuilder color_monster(builder); color_monster.add_name(name); color_monster.add_color(Color(Color_Blue | Color_Red)); FinishMonsterBuffer(builder, color_monster.Finish()); std::string jsongen; auto result = GenerateText(parser, builder.GetBufferPointer(), &jsongen); TEST_EQ(result, true); TEST_EQ(std::string::npos != jsongen.find("color: \"Red Blue\""), true); // Test forward compatibility with 'output_enum_identifiers = true'. // Current Color doesn't have '(1u << 2)' field, let's add it. builder.Clear(); std::string future_json; auto future_name = builder.CreateString("future bitflag_enum"); MonsterBuilder future_color(builder); future_color.add_name(future_name); future_color.add_color( static_cast((1u << 2) | Color_Blue | Color_Red)); FinishMonsterBuffer(builder, future_color.Finish()); result = GenerateText(parser, builder.GetBufferPointer(), &future_json); TEST_EQ(result, true); TEST_EQ(std::string::npos != future_json.find("color: 13"), true); } #if defined(FLATBUFFERS_HAS_NEW_STRTOD) && (FLATBUFFERS_HAS_NEW_STRTOD > 0) // The IEEE-754 quiet_NaN is not simple binary constant. // All binary NaN bit strings have all the bits of the biased exponent field E // set to 1. A quiet NaN bit string should be encoded with the first bit d[1] // of the trailing significand field T being 1 (d[0] is implicit bit). // It is assumed that endianness of floating-point is same as integer. template bool is_quiet_nan_impl(T v) { static_assert(sizeof(T) == sizeof(U), "unexpected"); U b = 0; std::memcpy(&b, &v, sizeof(T)); return ((b & qnan_base) == qnan_base); } # if defined(__mips__) || defined(__hppa__) static bool is_quiet_nan(float v) { return is_quiet_nan_impl(v) || is_quiet_nan_impl(v); } static bool is_quiet_nan(double v) { return is_quiet_nan_impl(v) || is_quiet_nan_impl(v); } # else static bool is_quiet_nan(float v) { return is_quiet_nan_impl(v); } static bool is_quiet_nan(double v) { return is_quiet_nan_impl(v); } # endif void TestMonsterExtraFloats() { TEST_EQ(is_quiet_nan(1.0), false); TEST_EQ(is_quiet_nan(infinity_d), false); TEST_EQ(is_quiet_nan(-infinity_f), false); TEST_EQ(is_quiet_nan(std::numeric_limits::quiet_NaN()), true); TEST_EQ(is_quiet_nan(std::numeric_limits::quiet_NaN()), true); using namespace flatbuffers; using namespace MyGame; // Load FlatBuffer schema (.fbs) from disk. std::string schemafile; TEST_EQ(LoadFile((test_data_path + "monster_extra.fbs").c_str(), false, &schemafile), true); // Parse schema first, so we can use it to parse the data after. Parser parser; auto include_test_path = ConCatPathFileName(test_data_path, "include_test"); const char *include_directories[] = { test_data_path.c_str(), include_test_path.c_str(), nullptr }; TEST_EQ(parser.Parse(schemafile.c_str(), include_directories), true); // Create empty extra and store to json. parser.opts.output_default_scalars_in_json = true; parser.opts.output_enum_identifiers = true; FlatBufferBuilder builder; const auto def_root = MonsterExtraBuilder(builder).Finish(); FinishMonsterExtraBuffer(builder, def_root); const auto def_obj = builder.GetBufferPointer(); const auto def_extra = GetMonsterExtra(def_obj); TEST_NOTNULL(def_extra); TEST_EQ(is_quiet_nan(def_extra->f0()), true); TEST_EQ(is_quiet_nan(def_extra->f1()), true); TEST_EQ(def_extra->f2(), +infinity_f); TEST_EQ(def_extra->f3(), -infinity_f); TEST_EQ(is_quiet_nan(def_extra->d0()), true); TEST_EQ(is_quiet_nan(def_extra->d1()), true); TEST_EQ(def_extra->d2(), +infinity_d); TEST_EQ(def_extra->d3(), -infinity_d); std::string jsongen; auto result = GenerateText(parser, def_obj, &jsongen); TEST_EQ(result, true); // Check expected default values. TEST_EQ(std::string::npos != jsongen.find("f0: nan"), true); TEST_EQ(std::string::npos != jsongen.find("f1: nan"), true); TEST_EQ(std::string::npos != jsongen.find("f2: inf"), true); TEST_EQ(std::string::npos != jsongen.find("f3: -inf"), true); TEST_EQ(std::string::npos != jsongen.find("d0: nan"), true); TEST_EQ(std::string::npos != jsongen.find("d1: nan"), true); TEST_EQ(std::string::npos != jsongen.find("d2: inf"), true); TEST_EQ(std::string::npos != jsongen.find("d3: -inf"), true); // Parse 'mosterdata_extra.json'. const auto extra_base = test_data_path + "monsterdata_extra"; jsongen = ""; TEST_EQ(LoadFile((extra_base + ".json").c_str(), false, &jsongen), true); TEST_EQ(parser.Parse(jsongen.c_str()), true); const auto test_file = parser.builder_.GetBufferPointer(); const auto test_size = parser.builder_.GetSize(); Verifier verifier(test_file, test_size); TEST_ASSERT(VerifyMonsterExtraBuffer(verifier)); const auto extra = GetMonsterExtra(test_file); TEST_NOTNULL(extra); TEST_EQ(is_quiet_nan(extra->f0()), true); TEST_EQ(is_quiet_nan(extra->f1()), true); TEST_EQ(extra->f2(), +infinity_f); TEST_EQ(extra->f3(), -infinity_f); TEST_EQ(is_quiet_nan(extra->d0()), true); TEST_EQ(extra->d1(), +infinity_d); TEST_EQ(extra->d2(), -infinity_d); TEST_EQ(is_quiet_nan(extra->d3()), true); TEST_NOTNULL(extra->fvec()); TEST_EQ(extra->fvec()->size(), 4); TEST_EQ(extra->fvec()->Get(0), 1.0f); TEST_EQ(extra->fvec()->Get(1), -infinity_f); TEST_EQ(extra->fvec()->Get(2), +infinity_f); TEST_EQ(is_quiet_nan(extra->fvec()->Get(3)), true); TEST_NOTNULL(extra->dvec()); TEST_EQ(extra->dvec()->size(), 4); TEST_EQ(extra->dvec()->Get(0), 2.0); TEST_EQ(extra->dvec()->Get(1), +infinity_d); TEST_EQ(extra->dvec()->Get(2), -infinity_d); TEST_EQ(is_quiet_nan(extra->dvec()->Get(3)), true); } #else void TestMonsterExtraFloats() {} #endif // example of parsing text straight into a buffer, and generating // text back from it: void ParseAndGenerateTextTest(bool binary) { // load FlatBuffer schema (.fbs) and JSON from disk std::string schemafile; std::string jsonfile; TEST_EQ(flatbuffers::LoadFile( (test_data_path + "monster_test." + (binary ? "bfbs" : "fbs")) .c_str(), binary, &schemafile), true); TEST_EQ(flatbuffers::LoadFile( (test_data_path + "monsterdata_test.golden").c_str(), false, &jsonfile), true); auto include_test_path = flatbuffers::ConCatPathFileName(test_data_path, "include_test"); const char *include_directories[] = { test_data_path.c_str(), include_test_path.c_str(), nullptr }; // parse schema first, so we can use it to parse the data after flatbuffers::Parser parser; if (binary) { flatbuffers::Verifier verifier( reinterpret_cast(schemafile.c_str()), schemafile.size()); TEST_EQ(reflection::VerifySchemaBuffer(verifier), true); // auto schema = reflection::GetSchema(schemafile.c_str()); TEST_EQ(parser.Deserialize((const uint8_t *)schemafile.c_str(), schemafile.size()), true); } else { TEST_EQ(parser.Parse(schemafile.c_str(), include_directories), true); } TEST_EQ(parser.ParseJson(jsonfile.c_str()), true); // here, parser.builder_ contains a binary buffer that is the parsed data. // First, verify it, just in case: flatbuffers::Verifier verifier(parser.builder_.GetBufferPointer(), parser.builder_.GetSize()); TEST_EQ(VerifyMonsterBuffer(verifier), true); AccessFlatBufferTest(parser.builder_.GetBufferPointer(), parser.builder_.GetSize(), false); // to ensure it is correct, we now generate text back from the binary, // and compare the two: std::string jsongen; auto result = GenerateText(parser, parser.builder_.GetBufferPointer(), &jsongen); TEST_EQ(result, true); TEST_EQ_STR(jsongen.c_str(), jsonfile.c_str()); // We can also do the above using the convenient Registry that knows about // a set of file_identifiers mapped to schemas. flatbuffers::Registry registry; // Make sure schemas can find their includes. registry.AddIncludeDirectory(test_data_path.c_str()); registry.AddIncludeDirectory(include_test_path.c_str()); // Call this with many schemas if possible. registry.Register(MonsterIdentifier(), (test_data_path + "monster_test.fbs").c_str()); // Now we got this set up, we can parse by just specifying the identifier, // the correct schema will be loaded on the fly: auto buf = registry.TextToFlatBuffer(jsonfile.c_str(), MonsterIdentifier()); // If this fails, check registry.lasterror_. TEST_NOTNULL(buf.data()); // Test the buffer, to be sure: AccessFlatBufferTest(buf.data(), buf.size(), false); // We can use the registry to turn this back into text, in this case it // will get the file_identifier from the binary: std::string text; auto ok = registry.FlatBufferToText(buf.data(), buf.size(), &text); // If this fails, check registry.lasterror_. TEST_EQ(ok, true); TEST_EQ_STR(text.c_str(), jsonfile.c_str()); // Generate text for UTF-8 strings without escapes. std::string jsonfile_utf8; TEST_EQ(flatbuffers::LoadFile((test_data_path + "unicode_test.json").c_str(), false, &jsonfile_utf8), true); TEST_EQ(parser.Parse(jsonfile_utf8.c_str(), include_directories), true); // To ensure it is correct, generate utf-8 text back from the binary. std::string jsongen_utf8; // request natural printing for utf-8 strings parser.opts.natural_utf8 = true; parser.opts.strict_json = true; TEST_EQ( GenerateText(parser, parser.builder_.GetBufferPointer(), &jsongen_utf8), true); TEST_EQ_STR(jsongen_utf8.c_str(), jsonfile_utf8.c_str()); } void ReflectionTest(uint8_t *flatbuf, size_t length) { // Load a binary schema. std::string bfbsfile; TEST_EQ(flatbuffers::LoadFile((test_data_path + "monster_test.bfbs").c_str(), true, &bfbsfile), true); // Verify it, just in case: flatbuffers::Verifier verifier( reinterpret_cast(bfbsfile.c_str()), bfbsfile.length()); TEST_EQ(reflection::VerifySchemaBuffer(verifier), true); // Make sure the schema is what we expect it to be. auto &schema = *reflection::GetSchema(bfbsfile.c_str()); auto root_table = schema.root_table(); TEST_EQ_STR(root_table->name()->c_str(), "MyGame.Example.Monster"); auto fields = root_table->fields(); auto hp_field_ptr = fields->LookupByKey("hp"); TEST_NOTNULL(hp_field_ptr); auto &hp_field = *hp_field_ptr; TEST_EQ_STR(hp_field.name()->c_str(), "hp"); TEST_EQ(hp_field.id(), 2); TEST_EQ(hp_field.type()->base_type(), reflection::Short); auto friendly_field_ptr = fields->LookupByKey("friendly"); TEST_NOTNULL(friendly_field_ptr); TEST_NOTNULL(friendly_field_ptr->attributes()); TEST_NOTNULL(friendly_field_ptr->attributes()->LookupByKey("priority")); // Make sure the table index is what we expect it to be. auto pos_field_ptr = fields->LookupByKey("pos"); TEST_NOTNULL(pos_field_ptr); TEST_EQ(pos_field_ptr->type()->base_type(), reflection::Obj); auto pos_table_ptr = schema.objects()->Get(pos_field_ptr->type()->index()); TEST_NOTNULL(pos_table_ptr); TEST_EQ_STR(pos_table_ptr->name()->c_str(), "MyGame.Example.Vec3"); // Test nullability of fields: hp is a 0-default scalar, pos is a struct => // optional, and name is a required string => not optional. TEST_EQ(hp_field.optional(), false); TEST_EQ(pos_field_ptr->optional(), true); TEST_EQ(fields->LookupByKey("name")->optional(), false); // Now use it to dynamically access a buffer. auto &root = *flatbuffers::GetAnyRoot(flatbuf); // Verify the buffer first using reflection based verification TEST_EQ(flatbuffers::Verify(schema, *schema.root_table(), flatbuf, length), true); auto hp = flatbuffers::GetFieldI(root, hp_field); TEST_EQ(hp, 80); // Rather than needing to know the type, we can also get the value of // any field as an int64_t/double/string, regardless of what it actually is. auto hp_int64 = flatbuffers::GetAnyFieldI(root, hp_field); TEST_EQ(hp_int64, 80); auto hp_double = flatbuffers::GetAnyFieldF(root, hp_field); TEST_EQ(hp_double, 80.0); auto hp_string = flatbuffers::GetAnyFieldS(root, hp_field, &schema); TEST_EQ_STR(hp_string.c_str(), "80"); // Get struct field through reflection auto pos_struct = flatbuffers::GetFieldStruct(root, *pos_field_ptr); TEST_NOTNULL(pos_struct); TEST_EQ(flatbuffers::GetAnyFieldF(*pos_struct, *pos_table_ptr->fields()->LookupByKey("z")), 3.0f); auto test3_field = pos_table_ptr->fields()->LookupByKey("test3"); auto test3_struct = flatbuffers::GetFieldStruct(*pos_struct, *test3_field); TEST_NOTNULL(test3_struct); auto test3_object = schema.objects()->Get(test3_field->type()->index()); TEST_EQ(flatbuffers::GetAnyFieldF(*test3_struct, *test3_object->fields()->LookupByKey("a")), 10); // We can also modify it. flatbuffers::SetField(&root, hp_field, 200); hp = flatbuffers::GetFieldI(root, hp_field); TEST_EQ(hp, 200); // We can also set fields generically: flatbuffers::SetAnyFieldI(&root, hp_field, 300); hp_int64 = flatbuffers::GetAnyFieldI(root, hp_field); TEST_EQ(hp_int64, 300); flatbuffers::SetAnyFieldF(&root, hp_field, 300.5); hp_int64 = flatbuffers::GetAnyFieldI(root, hp_field); TEST_EQ(hp_int64, 300); flatbuffers::SetAnyFieldS(&root, hp_field, "300"); hp_int64 = flatbuffers::GetAnyFieldI(root, hp_field); TEST_EQ(hp_int64, 300); // Test buffer is valid after the modifications TEST_EQ(flatbuffers::Verify(schema, *schema.root_table(), flatbuf, length), true); // Reset it, for further tests. flatbuffers::SetField(&root, hp_field, 80); // More advanced functionality: changing the size of items in-line! // First we put the FlatBuffer inside an std::vector. std::vector resizingbuf(flatbuf, flatbuf + length); // Find the field we want to modify. auto &name_field = *fields->LookupByKey("name"); // Get the root. // This time we wrap the result from GetAnyRoot in a smartpointer that // will keep rroot valid as resizingbuf resizes. auto rroot = flatbuffers::piv( flatbuffers::GetAnyRoot(flatbuffers::vector_data(resizingbuf)), resizingbuf); SetString(schema, "totally new string", GetFieldS(**rroot, name_field), &resizingbuf); // Here resizingbuf has changed, but rroot is still valid. TEST_EQ_STR(GetFieldS(**rroot, name_field)->c_str(), "totally new string"); // Now lets extend a vector by 100 elements (10 -> 110). auto &inventory_field = *fields->LookupByKey("inventory"); auto rinventory = flatbuffers::piv( flatbuffers::GetFieldV(**rroot, inventory_field), resizingbuf); flatbuffers::ResizeVector(schema, 110, 50, *rinventory, &resizingbuf); // rinventory still valid, so lets read from it. TEST_EQ(rinventory->Get(10), 50); // For reflection uses not covered already, there is a more powerful way: // we can simply generate whatever object we want to add/modify in a // FlatBuffer of its own, then add that to an existing FlatBuffer: // As an example, let's add a string to an array of strings. // First, find our field: auto &testarrayofstring_field = *fields->LookupByKey("testarrayofstring"); // Find the vector value: auto rtestarrayofstring = flatbuffers::piv( flatbuffers::GetFieldV>( **rroot, testarrayofstring_field), resizingbuf); // It's a vector of 2 strings, to which we add one more, initialized to // offset 0. flatbuffers::ResizeVector>( schema, 3, 0, *rtestarrayofstring, &resizingbuf); // Here we just create a buffer that contans a single string, but this // could also be any complex set of tables and other values. flatbuffers::FlatBufferBuilder stringfbb; stringfbb.Finish(stringfbb.CreateString("hank")); // Add the contents of it to our existing FlatBuffer. // We do this last, so the pointer doesn't get invalidated (since it is // at the end of the buffer): auto string_ptr = flatbuffers::AddFlatBuffer( resizingbuf, stringfbb.GetBufferPointer(), stringfbb.GetSize()); // Finally, set the new value in the vector. rtestarrayofstring->MutateOffset(2, string_ptr); TEST_EQ_STR(rtestarrayofstring->Get(0)->c_str(), "bob"); TEST_EQ_STR(rtestarrayofstring->Get(2)->c_str(), "hank"); // Test integrity of all resize operations above. flatbuffers::Verifier resize_verifier( reinterpret_cast(flatbuffers::vector_data(resizingbuf)), resizingbuf.size()); TEST_EQ(VerifyMonsterBuffer(resize_verifier), true); // Test buffer is valid using reflection as well TEST_EQ(flatbuffers::Verify(schema, *schema.root_table(), flatbuffers::vector_data(resizingbuf), resizingbuf.size()), true); // As an additional test, also set it on the name field. // Note: unlike the name change above, this just overwrites the offset, // rather than changing the string in-place. SetFieldT(*rroot, name_field, string_ptr); TEST_EQ_STR(GetFieldS(**rroot, name_field)->c_str(), "hank"); // Using reflection, rather than mutating binary FlatBuffers, we can also copy // tables and other things out of other FlatBuffers into a FlatBufferBuilder, // either part or whole. flatbuffers::FlatBufferBuilder fbb; auto root_offset = flatbuffers::CopyTable( fbb, schema, *root_table, *flatbuffers::GetAnyRoot(flatbuf), true); fbb.Finish(root_offset, MonsterIdentifier()); // Test that it was copied correctly: AccessFlatBufferTest(fbb.GetBufferPointer(), fbb.GetSize()); // Test buffer is valid using reflection as well TEST_EQ(flatbuffers::Verify(schema, *schema.root_table(), fbb.GetBufferPointer(), fbb.GetSize()), true); } void MiniReflectFlatBuffersTest(uint8_t *flatbuf) { auto s = flatbuffers::FlatBufferToString(flatbuf, Monster::MiniReflectTypeTable()); TEST_EQ_STR( s.c_str(), "{ " "pos: { x: 1.0, y: 2.0, z: 3.0, test1: 0.0, test2: Red, test3: " "{ a: 10, b: 20 } }, " "hp: 80, " "name: \"MyMonster\", " "inventory: [ 0, 1, 2, 3, 4, 5, 6, 7, 8, 9 ], " "test_type: Monster, " "test: { name: \"Fred\" }, " "test4: [ { a: 10, b: 20 }, { a: 30, b: 40 } ], " "testarrayofstring: [ \"bob\", \"fred\", \"bob\", \"fred\" ], " "testarrayoftables: [ { hp: 1000, name: \"Barney\" }, { name: \"Fred\" " "}, " "{ name: \"Wilma\" } ], " // TODO(wvo): should really print this nested buffer correctly. "testnestedflatbuffer: [ 20, 0, 0, 0, 77, 79, 78, 83, 12, 0, 12, 0, 0, " "0, " "4, 0, 6, 0, 8, 0, 12, 0, 0, 0, 0, 0, 0, 0, 4, 0, 0, 0, 13, 0, 0, 0, 78, " "101, 115, 116, 101, 100, 77, 111, 110, 115, 116, 101, 114, 0, 0, 0 ], " "testarrayofstring2: [ \"jane\", \"mary\" ], " "testarrayofsortedstruct: [ { id: 0, distance: 0 }, " "{ id: 2, distance: 20 }, { id: 3, distance: 30 }, " "{ id: 4, distance: 40 } ], " "flex: [ 210, 4, 5, 2 ], " "test5: [ { a: 10, b: 20 }, { a: 30, b: 40 } ], " "vector_of_enums: [ Blue, Green ], " "scalar_key_sorted_tables: [ { id: \"miss\" } ] " "}"); Test test(16, 32); Vec3 vec(1, 2, 3, 1.5, Color_Red, test); flatbuffers::FlatBufferBuilder vec_builder; vec_builder.Finish(vec_builder.CreateStruct(vec)); auto vec_buffer = vec_builder.Release(); auto vec_str = flatbuffers::FlatBufferToString(vec_buffer.data(), Vec3::MiniReflectTypeTable()); TEST_EQ_STR(vec_str.c_str(), "{ x: 1.0, y: 2.0, z: 3.0, test1: 1.5, test2: Red, test3: { a: " "16, b: 32 } }"); } void MiniReflectFixedLengthArrayTest() { // VS10 does not support typed enums, exclude from tests #if !defined(_MSC_VER) || _MSC_VER >= 1700 flatbuffers::FlatBufferBuilder fbb; MyGame::Example::ArrayStruct aStruct(2, 12, 1); auto aTable = MyGame::Example::CreateArrayTable(fbb, &aStruct); fbb.Finish(aTable); auto flatbuf = fbb.Release(); auto s = flatbuffers::FlatBufferToString( flatbuf.data(), MyGame::Example::ArrayTableTypeTable()); TEST_EQ_STR( "{ " "a: { a: 2.0, " "b: [ 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0 ], " "c: 12, " "d: [ { a: [ 0, 0 ], b: A, c: [ A, A ], d: [ 0, 0 ] }, " "{ a: [ 0, 0 ], b: A, c: [ A, A ], d: [ 0, 0 ] } ], " "e: 1, f: [ 0, 0 ] } " "}", s.c_str()); #endif } // Parse a .proto schema, output as .fbs void ParseProtoTest() { // load the .proto and the golden file from disk std::string protofile; std::string goldenfile; std::string goldenunionfile; TEST_EQ( flatbuffers::LoadFile((test_data_path + "prototest/test.proto").c_str(), false, &protofile), true); TEST_EQ( flatbuffers::LoadFile((test_data_path + "prototest/test.golden").c_str(), false, &goldenfile), true); TEST_EQ(flatbuffers::LoadFile( (test_data_path + "prototest/test_union.golden").c_str(), false, &goldenunionfile), true); flatbuffers::IDLOptions opts; opts.include_dependence_headers = false; opts.proto_mode = true; // Parse proto. flatbuffers::Parser parser(opts); auto protopath = test_data_path + "prototest/"; const char *include_directories[] = { protopath.c_str(), nullptr }; TEST_EQ(parser.Parse(protofile.c_str(), include_directories), true); // Generate fbs. auto fbs = flatbuffers::GenerateFBS(parser, "test"); // Ensure generated file is parsable. flatbuffers::Parser parser2; TEST_EQ(parser2.Parse(fbs.c_str(), nullptr), true); TEST_EQ_STR(fbs.c_str(), goldenfile.c_str()); // Parse proto with --oneof-union option. opts.proto_oneof_union = true; flatbuffers::Parser parser3(opts); TEST_EQ(parser3.Parse(protofile.c_str(), include_directories), true); // Generate fbs. auto fbs_union = flatbuffers::GenerateFBS(parser3, "test"); // Ensure generated file is parsable. flatbuffers::Parser parser4; TEST_EQ(parser4.Parse(fbs_union.c_str(), nullptr), true); TEST_EQ_STR(fbs_union.c_str(), goldenunionfile.c_str()); } // Parse a .proto schema, output as .fbs void ParseProtoTestWithSuffix() { // load the .proto and the golden file from disk std::string protofile; std::string goldenfile; std::string goldenunionfile; TEST_EQ( flatbuffers::LoadFile((test_data_path + "prototest/test.proto").c_str(), false, &protofile), true); TEST_EQ(flatbuffers::LoadFile( (test_data_path + "prototest/test_suffix.golden").c_str(), false, &goldenfile), true); TEST_EQ(flatbuffers::LoadFile( (test_data_path + "prototest/test_union_suffix.golden").c_str(), false, &goldenunionfile), true); flatbuffers::IDLOptions opts; opts.include_dependence_headers = false; opts.proto_mode = true; opts.proto_namespace_suffix = "test_namespace_suffix"; // Parse proto. flatbuffers::Parser parser(opts); auto protopath = test_data_path + "prototest/"; const char *include_directories[] = { protopath.c_str(), nullptr }; TEST_EQ(parser.Parse(protofile.c_str(), include_directories), true); // Generate fbs. auto fbs = flatbuffers::GenerateFBS(parser, "test"); // Ensure generated file is parsable. flatbuffers::Parser parser2; TEST_EQ(parser2.Parse(fbs.c_str(), nullptr), true); TEST_EQ_STR(fbs.c_str(), goldenfile.c_str()); // Parse proto with --oneof-union option. opts.proto_oneof_union = true; flatbuffers::Parser parser3(opts); TEST_EQ(parser3.Parse(protofile.c_str(), include_directories), true); // Generate fbs. auto fbs_union = flatbuffers::GenerateFBS(parser3, "test"); // Ensure generated file is parsable. flatbuffers::Parser parser4; TEST_EQ(parser4.Parse(fbs_union.c_str(), nullptr), true); TEST_EQ_STR(fbs_union.c_str(), goldenunionfile.c_str()); } // Parse a .proto schema, output as .fbs void ParseProtoTestWithIncludes() { // load the .proto and the golden file from disk std::string protofile; std::string goldenfile; std::string goldenunionfile; std::string importprotofile; TEST_EQ( flatbuffers::LoadFile((test_data_path + "prototest/test.proto").c_str(), false, &protofile), true); TEST_EQ(flatbuffers::LoadFile( (test_data_path + "prototest/imported.proto").c_str(), false, &importprotofile), true); TEST_EQ(flatbuffers::LoadFile( (test_data_path + "prototest/test_include.golden").c_str(), false, &goldenfile), true); TEST_EQ(flatbuffers::LoadFile( (test_data_path + "prototest/test_union_include.golden").c_str(), false, &goldenunionfile), true); flatbuffers::IDLOptions opts; opts.include_dependence_headers = true; opts.proto_mode = true; // Parse proto. flatbuffers::Parser parser(opts); auto protopath = test_data_path + "prototest/"; const char *include_directories[] = { protopath.c_str(), nullptr }; TEST_EQ(parser.Parse(protofile.c_str(), include_directories), true); // Generate fbs. auto fbs = flatbuffers::GenerateFBS(parser, "test"); // Generate fbs from import.proto flatbuffers::Parser import_parser(opts); TEST_EQ(import_parser.Parse(importprotofile.c_str(), include_directories), true); auto import_fbs = flatbuffers::GenerateFBS(import_parser, "test"); // Ensure generated file is parsable. flatbuffers::Parser parser2; TEST_EQ( parser2.Parse(import_fbs.c_str(), include_directories, "imported.fbs"), true); TEST_EQ(parser2.Parse(fbs.c_str(), nullptr), true); TEST_EQ_STR(fbs.c_str(), goldenfile.c_str()); // Parse proto with --oneof-union option. opts.proto_oneof_union = true; flatbuffers::Parser parser3(opts); TEST_EQ(parser3.Parse(protofile.c_str(), include_directories), true); // Generate fbs. auto fbs_union = flatbuffers::GenerateFBS(parser3, "test"); // Ensure generated file is parsable. flatbuffers::Parser parser4; TEST_EQ(parser4.Parse(import_fbs.c_str(), nullptr, "imported.fbs"), true); TEST_EQ(parser4.Parse(fbs_union.c_str(), nullptr), true); TEST_EQ_STR(fbs_union.c_str(), goldenunionfile.c_str()); } template void CompareTableFieldValue(flatbuffers::Table *table, flatbuffers::voffset_t voffset, T val) { T read = table->GetField(voffset, static_cast(0)); TEST_EQ(read, val); } // Low level stress/fuzz test: serialize/deserialize a variety of // different kinds of data in different combinations void FuzzTest1() { // Values we're testing against: chosen to ensure no bits get chopped // off anywhere, and also be different from eachother. const uint8_t bool_val = true; const int8_t char_val = -127; // 0x81 const uint8_t uchar_val = 0xFF; const int16_t short_val = -32222; // 0x8222; const uint16_t ushort_val = 0xFEEE; const int32_t int_val = 0x83333333; const uint32_t uint_val = 0xFDDDDDDD; const int64_t long_val = 0x8444444444444444LL; const uint64_t ulong_val = 0xFCCCCCCCCCCCCCCCULL; const float float_val = 3.14159f; const double double_val = 3.14159265359; const int test_values_max = 11; const flatbuffers::voffset_t fields_per_object = 4; const int num_fuzz_objects = 10000; // The higher, the more thorough :) flatbuffers::FlatBufferBuilder builder; lcg_reset(); // Keep it deterministic. flatbuffers::uoffset_t objects[num_fuzz_objects]; // Generate num_fuzz_objects random objects each consisting of // fields_per_object fields, each of a random type. for (int i = 0; i < num_fuzz_objects; i++) { auto start = builder.StartTable(); for (flatbuffers::voffset_t f = 0; f < fields_per_object; f++) { int choice = lcg_rand() % test_values_max; auto off = flatbuffers::FieldIndexToOffset(f); switch (choice) { case 0: builder.AddElement(off, bool_val, 0); break; case 1: builder.AddElement(off, char_val, 0); break; case 2: builder.AddElement(off, uchar_val, 0); break; case 3: builder.AddElement(off, short_val, 0); break; case 4: builder.AddElement(off, ushort_val, 0); break; case 5: builder.AddElement(off, int_val, 0); break; case 6: builder.AddElement(off, uint_val, 0); break; case 7: builder.AddElement(off, long_val, 0); break; case 8: builder.AddElement(off, ulong_val, 0); break; case 9: builder.AddElement(off, float_val, 0); break; case 10: builder.AddElement(off, double_val, 0); break; } } objects[i] = builder.EndTable(start); } builder.PreAlign(0); // Align whole buffer. lcg_reset(); // Reset. uint8_t *eob = builder.GetCurrentBufferPointer() + builder.GetSize(); // Test that all objects we generated are readable and return the // expected values. We generate random objects in the same order // so this is deterministic. for (int i = 0; i < num_fuzz_objects; i++) { auto table = reinterpret_cast(eob - objects[i]); for (flatbuffers::voffset_t f = 0; f < fields_per_object; f++) { int choice = lcg_rand() % test_values_max; flatbuffers::voffset_t off = flatbuffers::FieldIndexToOffset(f); switch (choice) { case 0: CompareTableFieldValue(table, off, bool_val); break; case 1: CompareTableFieldValue(table, off, char_val); break; case 2: CompareTableFieldValue(table, off, uchar_val); break; case 3: CompareTableFieldValue(table, off, short_val); break; case 4: CompareTableFieldValue(table, off, ushort_val); break; case 5: CompareTableFieldValue(table, off, int_val); break; case 6: CompareTableFieldValue(table, off, uint_val); break; case 7: CompareTableFieldValue(table, off, long_val); break; case 8: CompareTableFieldValue(table, off, ulong_val); break; case 9: CompareTableFieldValue(table, off, float_val); break; case 10: CompareTableFieldValue(table, off, double_val); break; } } } } // High level stress/fuzz test: generate a big schema and // matching json data in random combinations, then parse both, // generate json back from the binary, and compare with the original. void FuzzTest2() { lcg_reset(); // Keep it deterministic. const int num_definitions = 30; const int num_struct_definitions = 5; // Subset of num_definitions. const int fields_per_definition = 15; const int instances_per_definition = 5; const int deprecation_rate = 10; // 1 in deprecation_rate fields will // be deprecated. std::string schema = "namespace test;\n\n"; struct RndDef { std::string instances[instances_per_definition]; // Since we're generating schema and corresponding data in tandem, // this convenience function adds strings to both at once. static void Add(RndDef (&definitions_l)[num_definitions], std::string &schema_l, const int instances_per_definition_l, const char *schema_add, const char *instance_add, int definition) { schema_l += schema_add; for (int i = 0; i < instances_per_definition_l; i++) definitions_l[definition].instances[i] += instance_add; } }; // clang-format off #define AddToSchemaAndInstances(schema_add, instance_add) \ RndDef::Add(definitions, schema, instances_per_definition, \ schema_add, instance_add, definition) #define Dummy() \ RndDef::Add(definitions, schema, instances_per_definition, \ "byte", "1", definition) // clang-format on RndDef definitions[num_definitions]; // We are going to generate num_definitions, the first // num_struct_definitions will be structs, the rest tables. For each // generate random fields, some of which may be struct/table types // referring to previously generated structs/tables. // Simultanenously, we generate instances_per_definition JSON data // definitions, which will have identical structure to the schema // being generated. We generate multiple instances such that when creating // hierarchy, we get some variety by picking one randomly. for (int definition = 0; definition < num_definitions; definition++) { std::string definition_name = "D" + flatbuffers::NumToString(definition); bool is_struct = definition < num_struct_definitions; AddToSchemaAndInstances( ((is_struct ? "struct " : "table ") + definition_name + " {\n").c_str(), "{\n"); for (int field = 0; field < fields_per_definition; field++) { const bool is_last_field = field == fields_per_definition - 1; // Deprecate 1 in deprecation_rate fields. Only table fields can be // deprecated. // Don't deprecate the last field to avoid dangling commas in JSON. const bool deprecated = !is_struct && !is_last_field && (lcg_rand() % deprecation_rate == 0); std::string field_name = "f" + flatbuffers::NumToString(field); AddToSchemaAndInstances((" " + field_name + ":").c_str(), deprecated ? "" : (field_name + ": ").c_str()); // Pick random type: auto base_type = static_cast( lcg_rand() % (flatbuffers::BASE_TYPE_UNION + 1)); switch (base_type) { case flatbuffers::BASE_TYPE_STRING: if (is_struct) { Dummy(); // No strings in structs. } else { AddToSchemaAndInstances("string", deprecated ? "" : "\"hi\""); } break; case flatbuffers::BASE_TYPE_VECTOR: if (is_struct) { Dummy(); // No vectors in structs. } else { AddToSchemaAndInstances("[ubyte]", deprecated ? "" : "[\n0,\n1,\n255\n]"); } break; case flatbuffers::BASE_TYPE_NONE: case flatbuffers::BASE_TYPE_UTYPE: case flatbuffers::BASE_TYPE_STRUCT: case flatbuffers::BASE_TYPE_UNION: if (definition) { // Pick a random previous definition and random data instance of // that definition. int defref = lcg_rand() % definition; int instance = lcg_rand() % instances_per_definition; AddToSchemaAndInstances( ("D" + flatbuffers::NumToString(defref)).c_str(), deprecated ? "" : definitions[defref].instances[instance].c_str()); } else { // If this is the first definition, we have no definition we can // refer to. Dummy(); } break; case flatbuffers::BASE_TYPE_BOOL: AddToSchemaAndInstances( "bool", deprecated ? "" : (lcg_rand() % 2 ? "true" : "false")); break; case flatbuffers::BASE_TYPE_ARRAY: if (!is_struct) { AddToSchemaAndInstances( "ubyte", deprecated ? "" : "255"); // No fixed-length arrays in tables. } else { AddToSchemaAndInstances("[int:3]", deprecated ? "" : "[\n,\n,\n]"); } break; default: // All the scalar types. schema += flatbuffers::kTypeNames[base_type]; if (!deprecated) { // We want each instance to use its own random value. for (int inst = 0; inst < instances_per_definition; inst++) definitions[definition].instances[inst] += flatbuffers::IsFloat(base_type) ? flatbuffers::NumToString(lcg_rand() % 128) .c_str() : flatbuffers::NumToString(lcg_rand() % 128).c_str(); } } AddToSchemaAndInstances(deprecated ? "(deprecated);\n" : ";\n", deprecated ? "" : is_last_field ? "\n" : ",\n"); } AddToSchemaAndInstances("}\n\n", "}"); } schema += "root_type D" + flatbuffers::NumToString(num_definitions - 1); schema += ";\n"; flatbuffers::Parser parser; // Will not compare against the original if we don't write defaults parser.builder_.ForceDefaults(true); // Parse the schema, parse the generated data, then generate text back // from the binary and compare against the original. TEST_EQ(parser.Parse(schema.c_str()), true); const std::string &json = definitions[num_definitions - 1].instances[0] + "\n"; TEST_EQ(parser.Parse(json.c_str()), true); std::string jsongen; parser.opts.indent_step = 0; auto result = GenerateText(parser, parser.builder_.GetBufferPointer(), &jsongen); TEST_EQ(result, true); if (jsongen != json) { // These strings are larger than a megabyte, so we show the bytes around // the first bytes that are different rather than the whole string. size_t len = std::min(json.length(), jsongen.length()); for (size_t i = 0; i < len; i++) { if (json[i] != jsongen[i]) { i -= std::min(static_cast(10), i); // show some context; size_t end = std::min(len, i + 20); for (; i < end; i++) TEST_OUTPUT_LINE("at %d: found \"%c\", expected \"%c\"\n", static_cast(i), jsongen[i], json[i]); break; } } TEST_NOTNULL(nullptr); //-V501 (this comment supresses CWE-570 warning) } // clang-format off #ifdef FLATBUFFERS_TEST_VERBOSE TEST_OUTPUT_LINE("%dk schema tested with %dk of json\n", static_cast(schema.length() / 1024), static_cast(json.length() / 1024)); #endif // clang-format on } // Test that parser errors are actually generated. void TestError_(const char *src, const char *error_substr, bool strict_json, const char *file, int line, const char *func) { flatbuffers::IDLOptions opts; opts.strict_json = strict_json; flatbuffers::Parser parser(opts); if (parser.Parse(src)) { TestFail("true", "false", ("parser.Parse(\"" + std::string(src) + "\")").c_str(), file, line, func); } else if (!strstr(parser.error_.c_str(), error_substr)) { TestFail(error_substr, parser.error_.c_str(), ("parser.Parse(\"" + std::string(src) + "\")").c_str(), file, line, func); } } void TestError_(const char *src, const char *error_substr, const char *file, int line, const char *func) { TestError_(src, error_substr, false, file, line, func); } #ifdef _WIN32 # define TestError(src, ...) \ TestError_(src, __VA_ARGS__, __FILE__, __LINE__, __FUNCTION__) #else # define TestError(src, ...) \ TestError_(src, __VA_ARGS__, __FILE__, __LINE__, __PRETTY_FUNCTION__) #endif // Test that parsing errors occur as we'd expect. // Also useful for coverage, making sure these paths are run. void ErrorTest() { // In order they appear in idl_parser.cpp TestError("table X { Y:byte; } root_type X; { Y: 999 }", "does not fit"); TestError("\"\0", "illegal"); TestError("\"\\q", "escape code"); TestError("table ///", "documentation"); TestError("@", "illegal"); TestError("table 1", "expecting"); TestError("table X { Y:[[int]]; }", "nested vector"); TestError("table X { Y:1; }", "illegal type"); TestError("table X { Y:int; Y:int; }", "field already"); TestError("table Y {} table X { Y:int; }", "same as table"); TestError("struct X { Y:string; }", "only scalar"); TestError("struct X { a:uint = 42; }", "default values"); TestError("enum Y:byte { Z = 1 } table X { y:Y; }", "not part of enum"); TestError("struct X { Y:int (deprecated); }", "deprecate"); TestError("union Z { X } table X { Y:Z; } root_type X; { Y: {}, A:1 }", "missing type field"); TestError("union Z { X } table X { Y:Z; } root_type X; { Y_type: 99, Y: {", "type id"); TestError("table X { Y:int; } root_type X; { Z:", "unknown field"); TestError("table X { Y:int; } root_type X; { Y:", "string constant", true); TestError("table X { Y:int; } root_type X; { \"Y\":1, }", "string constant", true); TestError( "struct X { Y:int; Z:int; } table W { V:X; } root_type W; " "{ V:{ Y:1 } }", "wrong number"); TestError("enum E:byte { A } table X { Y:E; } root_type X; { Y:U }", "unknown enum value"); TestError("table X { Y:byte; } root_type X; { Y:; }", "starting"); TestError("enum X:byte { Y } enum X {", "enum already"); TestError("enum X:float {}", "underlying"); TestError("enum X:byte { Y, Y }", "value already"); TestError("enum X:byte { Y=2, Z=2 }", "unique"); TestError("table X { Y:int; } table X {", "datatype already"); TestError("struct X (force_align: 7) { Y:int; }", "force_align"); TestError("struct X {}", "size 0"); TestError("{}", "no root"); TestError("table X { Y:byte; } root_type X; { Y:1 } { Y:1 }", "end of file"); TestError("table X { Y:byte; } root_type X; { Y:1 } table Y{ Z:int }", "end of file"); TestError("root_type X;", "unknown root"); TestError("struct X { Y:int; } root_type X;", "a table"); TestError("union X { Y }", "referenced"); TestError("union Z { X } struct X { Y:int; }", "only tables"); TestError("table X { Y:[int]; YLength:int; }", "clash"); TestError("table X { Y:byte; } root_type X; { Y:1, Y:2 }", "more than once"); // float to integer conversion is forbidden TestError("table X { Y:int; } root_type X; { Y:1.0 }", "float"); TestError("table X { Y:bool; } root_type X; { Y:1.0 }", "float"); TestError("enum X:bool { Y = true }", "must be integral"); // Array of non-scalar TestError("table X { x:int; } struct Y { y:[X:2]; }", "may contain only scalar or struct fields"); // Non-snake case field names TestError("table X { Y: int; } root_type Y: {Y:1.0}", "snake_case"); // Complex defaults TestError("table X { y: string = 1; }", "expecting: string"); TestError("table X { y: string = []; }", " Cannot assign token"); TestError("table X { y: [int] = [1]; }", "Expected `]`"); TestError("table X { y: [int] = [; }", "Expected `]`"); TestError("table X { y: [int] = \"\"; }", "type mismatch"); // An identifier can't start from sign (+|-) TestError("table X { -Y: int; } root_type Y: {Y:1.0}", "identifier"); TestError("table X { +Y: int; } root_type Y: {Y:1.0}", "identifier"); } template T TestValue(const char *json, const char *type_name, const char *decls = nullptr) { flatbuffers::Parser parser; parser.builder_.ForceDefaults(true); // return defaults auto check_default = json ? false : true; if (check_default) { parser.opts.output_default_scalars_in_json = true; } // Simple schema. std::string schema = std::string(decls ? decls : "") + "\n" + "table X { y:" + std::string(type_name) + "; } root_type X;"; auto schema_done = parser.Parse(schema.c_str()); TEST_EQ_STR(parser.error_.c_str(), ""); TEST_EQ(schema_done, true); auto done = parser.Parse(check_default ? "{}" : json); TEST_EQ_STR(parser.error_.c_str(), ""); TEST_EQ(done, true); // Check with print. std::string print_back; parser.opts.indent_step = -1; TEST_EQ(GenerateText(parser, parser.builder_.GetBufferPointer(), &print_back), true); // restore value from its default if (check_default) { TEST_EQ(parser.Parse(print_back.c_str()), true); } auto root = flatbuffers::GetRoot( parser.builder_.GetBufferPointer()); return root->GetField(flatbuffers::FieldIndexToOffset(0), 0); } bool FloatCompare(float a, float b) { return fabs(a - b) < 0.001; } // Additional parser testing not covered elsewhere. void ValueTest() { // Test scientific notation numbers. TEST_EQ( FloatCompare(TestValue("{ y:0.0314159e+2 }", "float"), 3.14159f), true); // number in string TEST_EQ(FloatCompare(TestValue("{ y:\"0.0314159e+2\" }", "float"), 3.14159f), true); // Test conversion functions. TEST_EQ(FloatCompare(TestValue("{ y:cos(rad(180)) }", "float"), -1), true); // int embedded to string TEST_EQ(TestValue("{ y:\"-876\" }", "int=-123"), -876); TEST_EQ(TestValue("{ y:\"876\" }", "int=-123"), 876); // Test negative hex constant. TEST_EQ(TestValue("{ y:-0x8ea0 }", "int=-0x8ea0"), -36512); TEST_EQ(TestValue(nullptr, "int=-0x8ea0"), -36512); // positive hex constant TEST_EQ(TestValue("{ y:0x1abcdef }", "int=0x1"), 0x1abcdef); // with optional '+' sign TEST_EQ(TestValue("{ y:+0x1abcdef }", "int=+0x1"), 0x1abcdef); // hex in string TEST_EQ(TestValue("{ y:\"0x1abcdef\" }", "int=+0x1"), 0x1abcdef); // Make sure we do unsigned 64bit correctly. TEST_EQ(TestValue("{ y:12335089644688340133 }", "ulong"), 12335089644688340133ULL); // bool in string TEST_EQ(TestValue("{ y:\"false\" }", "bool=true"), false); TEST_EQ(TestValue("{ y:\"true\" }", "bool=\"true\""), true); TEST_EQ(TestValue("{ y:'false' }", "bool=true"), false); TEST_EQ(TestValue("{ y:'true' }", "bool=\"true\""), true); // check comments before and after json object TEST_EQ(TestValue("/*before*/ { y:1 } /*after*/", "int"), 1); TEST_EQ(TestValue("//before \n { y:1 } //after", "int"), 1); } void NestedListTest() { flatbuffers::Parser parser1; TEST_EQ(parser1.Parse("struct Test { a:short; b:byte; } table T { F:[Test]; }" "root_type T;" "{ F:[ [10,20], [30,40]] }"), true); } void EnumStringsTest() { flatbuffers::Parser parser1; TEST_EQ(parser1.Parse("enum E:byte { A, B, C } table T { F:[E]; }" "root_type T;" "{ F:[ A, B, \"C\", \"A B C\" ] }"), true); flatbuffers::Parser parser2; TEST_EQ(parser2.Parse("enum E:byte { A, B, C } table T { F:[int]; }" "root_type T;" "{ F:[ \"E.C\", \"E.A E.B E.C\" ] }"), true); // unsigned bit_flags flatbuffers::Parser parser3; TEST_EQ( parser3.Parse("enum E:uint16 (bit_flags) { F0, F07=7, F08, F14=14, F15 }" " table T { F: E = \"F15 F08\"; }" "root_type T;"), true); } void EnumNamesTest() { TEST_EQ_STR("Red", EnumNameColor(Color_Red)); TEST_EQ_STR("Green", EnumNameColor(Color_Green)); TEST_EQ_STR("Blue", EnumNameColor(Color_Blue)); // Check that Color to string don't crash while decode a mixture of Colors. // 1) Example::Color enum is enum with unfixed underlying type. // 2) Valid enum range: [0; 2^(ceil(log2(Color_ANY))) - 1]. // Consequence: A value is out of this range will lead to UB (since C++17). // For details see C++17 standard or explanation on the SO: // stackoverflow.com/questions/18195312/what-happens-if-you-static-cast-invalid-value-to-enum-class TEST_EQ_STR("", EnumNameColor(static_cast(0))); TEST_EQ_STR("", EnumNameColor(static_cast(Color_ANY - 1))); TEST_EQ_STR("", EnumNameColor(static_cast(Color_ANY + 1))); } void EnumOutOfRangeTest() { TestError("enum X:byte { Y = 128 }", "enum value does not fit"); TestError("enum X:byte { Y = -129 }", "enum value does not fit"); TestError("enum X:byte { Y = 126, Z0, Z1 }", "enum value does not fit"); TestError("enum X:ubyte { Y = -1 }", "enum value does not fit"); TestError("enum X:ubyte { Y = 256 }", "enum value does not fit"); TestError("enum X:ubyte { Y = 255, Z }", "enum value does not fit"); TestError("table Y{} union X { Y = -1 }", "enum value does not fit"); TestError("table Y{} union X { Y = 256 }", "enum value does not fit"); TestError("table Y{} union X { Y = 255, Z:Y }", "enum value does not fit"); TestError("enum X:int { Y = -2147483649 }", "enum value does not fit"); TestError("enum X:int { Y = 2147483648 }", "enum value does not fit"); TestError("enum X:uint { Y = -1 }", "enum value does not fit"); TestError("enum X:uint { Y = 4294967297 }", "enum value does not fit"); TestError("enum X:long { Y = 9223372036854775808 }", "does not fit"); TestError("enum X:long { Y = 9223372036854775807, Z }", "enum value does not fit"); TestError("enum X:ulong { Y = -1 }", "does not fit"); TestError("enum X:ubyte (bit_flags) { Y=8 }", "bit flag out"); TestError("enum X:byte (bit_flags) { Y=7 }", "must be unsigned"); // -128 // bit_flgs out of range TestError("enum X:ubyte (bit_flags) { Y0,Y1,Y2,Y3,Y4,Y5,Y6,Y7,Y8 }", "out of range"); } void EnumValueTest() { // json: "{ Y:0 }", schema: table X { y: "E"} // 0 in enum (V=0) E then Y=0 is valid. TEST_EQ(TestValue("{ y:0 }", "E", "enum E:int { V }"), 0); TEST_EQ(TestValue("{ y:V }", "E", "enum E:int { V }"), 0); // A default value of Y is 0. TEST_EQ(TestValue("{ }", "E", "enum E:int { V }"), 0); TEST_EQ(TestValue("{ y:5 }", "E=V", "enum E:int { V=5 }"), 5); // Generate json with defaults and check. TEST_EQ(TestValue(nullptr, "E=V", "enum E:int { V=5 }"), 5); // 5 in enum TEST_EQ(TestValue("{ y:5 }", "E", "enum E:int { Z, V=5 }"), 5); TEST_EQ(TestValue("{ y:5 }", "E=V", "enum E:int { Z, V=5 }"), 5); // Generate json with defaults and check. TEST_EQ(TestValue(nullptr, "E", "enum E:int { Z, V=5 }"), 0); TEST_EQ(TestValue(nullptr, "E=V", "enum E:int { Z, V=5 }"), 5); // u84 test TEST_EQ(TestValue(nullptr, "E=V", "enum E:ulong { V = 13835058055282163712 }"), 13835058055282163712ULL); TEST_EQ(TestValue(nullptr, "E=V", "enum E:ulong { V = 18446744073709551615 }"), 18446744073709551615ULL); // Assign non-enum value to enum field. Is it right? TEST_EQ(TestValue("{ y:7 }", "E", "enum E:int { V = 0 }"), 7); // Check that non-ascending values are valid. TEST_EQ(TestValue("{ y:5 }", "E=V", "enum E:int { Z=10, V=5 }"), 5); } void IntegerOutOfRangeTest() { TestError("table T { F:byte; } root_type T; { F:128 }", "constant does not fit"); TestError("table T { F:byte; } root_type T; { F:-129 }", "constant does not fit"); TestError("table T { F:ubyte; } root_type T; { F:256 }", "constant does not fit"); TestError("table T { F:ubyte; } root_type T; { F:-1 }", "constant does not fit"); TestError("table T { F:short; } root_type T; { F:32768 }", "constant does not fit"); TestError("table T { F:short; } root_type T; { F:-32769 }", "constant does not fit"); TestError("table T { F:ushort; } root_type T; { F:65536 }", "constant does not fit"); TestError("table T { F:ushort; } root_type T; { F:-1 }", "constant does not fit"); TestError("table T { F:int; } root_type T; { F:2147483648 }", "constant does not fit"); TestError("table T { F:int; } root_type T; { F:-2147483649 }", "constant does not fit"); TestError("table T { F:uint; } root_type T; { F:4294967296 }", "constant does not fit"); TestError("table T { F:uint; } root_type T; { F:-1 }", "constant does not fit"); // Check fixed width aliases TestError("table X { Y:uint8; } root_type X; { Y: -1 }", "does not fit"); TestError("table X { Y:uint8; } root_type X; { Y: 256 }", "does not fit"); TestError("table X { Y:uint16; } root_type X; { Y: -1 }", "does not fit"); TestError("table X { Y:uint16; } root_type X; { Y: 65536 }", "does not fit"); TestError("table X { Y:uint32; } root_type X; { Y: -1 }", ""); TestError("table X { Y:uint32; } root_type X; { Y: 4294967296 }", "does not fit"); TestError("table X { Y:uint64; } root_type X; { Y: -1 }", ""); TestError("table X { Y:uint64; } root_type X; { Y: -9223372036854775809 }", "does not fit"); TestError("table X { Y:uint64; } root_type X; { Y: 18446744073709551616 }", "does not fit"); TestError("table X { Y:int8; } root_type X; { Y: -129 }", "does not fit"); TestError("table X { Y:int8; } root_type X; { Y: 128 }", "does not fit"); TestError("table X { Y:int16; } root_type X; { Y: -32769 }", "does not fit"); TestError("table X { Y:int16; } root_type X; { Y: 32768 }", "does not fit"); TestError("table X { Y:int32; } root_type X; { Y: -2147483649 }", ""); TestError("table X { Y:int32; } root_type X; { Y: 2147483648 }", "does not fit"); TestError("table X { Y:int64; } root_type X; { Y: -9223372036854775809 }", "does not fit"); TestError("table X { Y:int64; } root_type X; { Y: 9223372036854775808 }", "does not fit"); // check out-of-int64 as int8 TestError("table X { Y:int8; } root_type X; { Y: -9223372036854775809 }", "does not fit"); TestError("table X { Y:int8; } root_type X; { Y: 9223372036854775808 }", "does not fit"); // Check default values TestError("table X { Y:int64=-9223372036854775809; } root_type X; {}", "does not fit"); TestError("table X { Y:int64= 9223372036854775808; } root_type X; {}", "does not fit"); TestError("table X { Y:uint64; } root_type X; { Y: -1 }", ""); TestError("table X { Y:uint64=-9223372036854775809; } root_type X; {}", "does not fit"); TestError("table X { Y:uint64= 18446744073709551616; } root_type X; {}", "does not fit"); } void IntegerBoundaryTest() { // Check numerical compatibility with non-C++ languages. // By the C++ standard, std::numerical_limits::min() == // -9223372036854775807 (-2^63+1) or less* The Flatbuffers grammar and most of // the languages (C#, Java, Rust) expect that minimum values are: -128, // -32768,.., -9223372036854775808. Since C++20, // static_cast(0x8000000000000000ULL) is well-defined two's complement // cast. Therefore -9223372036854775808 should be valid negative value. TEST_EQ(flatbuffers::numeric_limits::min(), -128); TEST_EQ(flatbuffers::numeric_limits::max(), 127); TEST_EQ(flatbuffers::numeric_limits::min(), -32768); TEST_EQ(flatbuffers::numeric_limits::max(), 32767); TEST_EQ(flatbuffers::numeric_limits::min() + 1, -2147483647); TEST_EQ(flatbuffers::numeric_limits::max(), 2147483647ULL); TEST_EQ(flatbuffers::numeric_limits::min() + 1LL, -9223372036854775807LL); TEST_EQ(flatbuffers::numeric_limits::max(), 9223372036854775807ULL); TEST_EQ(flatbuffers::numeric_limits::max(), 255); TEST_EQ(flatbuffers::numeric_limits::max(), 65535); TEST_EQ(flatbuffers::numeric_limits::max(), 4294967295ULL); TEST_EQ(flatbuffers::numeric_limits::max(), 18446744073709551615ULL); TEST_EQ(TestValue("{ y:127 }", "byte"), 127); TEST_EQ(TestValue("{ y:-128 }", "byte"), -128); TEST_EQ(TestValue("{ y:255 }", "ubyte"), 255); TEST_EQ(TestValue("{ y:0 }", "ubyte"), 0); TEST_EQ(TestValue("{ y:32767 }", "short"), 32767); TEST_EQ(TestValue("{ y:-32768 }", "short"), -32768); TEST_EQ(TestValue("{ y:65535 }", "ushort"), 65535); TEST_EQ(TestValue("{ y:0 }", "ushort"), 0); TEST_EQ(TestValue("{ y:2147483647 }", "int"), 2147483647); TEST_EQ(TestValue("{ y:-2147483648 }", "int") + 1, -2147483647); TEST_EQ(TestValue("{ y:4294967295 }", "uint"), 4294967295); TEST_EQ(TestValue("{ y:0 }", "uint"), 0); TEST_EQ(TestValue("{ y:9223372036854775807 }", "long"), 9223372036854775807LL); TEST_EQ(TestValue("{ y:-9223372036854775808 }", "long") + 1LL, -9223372036854775807LL); TEST_EQ(TestValue("{ y:18446744073709551615 }", "ulong"), 18446744073709551615ULL); TEST_EQ(TestValue("{ y:0 }", "ulong"), 0); TEST_EQ(TestValue("{ y: 18446744073709551615 }", "uint64"), 18446744073709551615ULL); // check that the default works TEST_EQ(TestValue(nullptr, "uint64 = 18446744073709551615"), 18446744073709551615ULL); } void ValidFloatTest() { // check rounding to infinity TEST_EQ(TestValue("{ y:+3.4029e+38 }", "float"), +infinity_f); TEST_EQ(TestValue("{ y:-3.4029e+38 }", "float"), -infinity_f); TEST_EQ(TestValue("{ y:+1.7977e+308 }", "double"), +infinity_d); TEST_EQ(TestValue("{ y:-1.7977e+308 }", "double"), -infinity_d); TEST_EQ( FloatCompare(TestValue("{ y:0.0314159e+2 }", "float"), 3.14159f), true); // float in string TEST_EQ(FloatCompare(TestValue("{ y:\" 0.0314159e+2 \" }", "float"), 3.14159f), true); TEST_EQ(TestValue("{ y:1 }", "float"), 1.0f); TEST_EQ(TestValue("{ y:1.0 }", "float"), 1.0f); TEST_EQ(TestValue("{ y:1. }", "float"), 1.0f); TEST_EQ(TestValue("{ y:+1. }", "float"), 1.0f); TEST_EQ(TestValue("{ y:-1. }", "float"), -1.0f); TEST_EQ(TestValue("{ y:1.e0 }", "float"), 1.0f); TEST_EQ(TestValue("{ y:1.e+0 }", "float"), 1.0f); TEST_EQ(TestValue("{ y:1.e-0 }", "float"), 1.0f); TEST_EQ(TestValue("{ y:0.125 }", "float"), 0.125f); TEST_EQ(TestValue("{ y:.125 }", "float"), 0.125f); TEST_EQ(TestValue("{ y:-.125 }", "float"), -0.125f); TEST_EQ(TestValue("{ y:+.125 }", "float"), +0.125f); TEST_EQ(TestValue("{ y:5 }", "float"), 5.0f); TEST_EQ(TestValue("{ y:\"5\" }", "float"), 5.0f); #if defined(FLATBUFFERS_HAS_NEW_STRTOD) && (FLATBUFFERS_HAS_NEW_STRTOD > 0) // Old MSVC versions may have problem with this check. // https://www.exploringbinary.com/visual-c-plus-plus-strtod-still-broken/ TEST_EQ(TestValue("{ y:6.9294956446009195e15 }", "double"), 6929495644600920.0); // check nan's TEST_EQ(std::isnan(TestValue("{ y:nan }", "double")), true); TEST_EQ(std::isnan(TestValue("{ y:nan }", "float")), true); TEST_EQ(std::isnan(TestValue("{ y:\"nan\" }", "float")), true); TEST_EQ(std::isnan(TestValue("{ y:\"+nan\" }", "float")), true); TEST_EQ(std::isnan(TestValue("{ y:\"-nan\" }", "float")), true); TEST_EQ(std::isnan(TestValue("{ y:+nan }", "float")), true); TEST_EQ(std::isnan(TestValue("{ y:-nan }", "float")), true); TEST_EQ(std::isnan(TestValue(nullptr, "float=nan")), true); TEST_EQ(std::isnan(TestValue(nullptr, "float=-nan")), true); // check inf TEST_EQ(TestValue("{ y:inf }", "float"), infinity_f); TEST_EQ(TestValue("{ y:\"inf\" }", "float"), infinity_f); TEST_EQ(TestValue("{ y:\"-inf\" }", "float"), -infinity_f); TEST_EQ(TestValue("{ y:\"+inf\" }", "float"), infinity_f); TEST_EQ(TestValue("{ y:+inf }", "float"), infinity_f); TEST_EQ(TestValue("{ y:-inf }", "float"), -infinity_f); TEST_EQ(TestValue(nullptr, "float=inf"), infinity_f); TEST_EQ(TestValue(nullptr, "float=-inf"), -infinity_f); TestValue( "{ y: [0.2, .2, 1.0, -1.0, -2., 2., 1e0, -1e0, 1.0e0, -1.0e0, -3.e2, " "3.0e2] }", "[double]"); TestValue( "{ y: [0.2, .2, 1.0, -1.0, -2., 2., 1e0, -1e0, 1.0e0, -1.0e0, -3.e2, " "3.0e2] }", "[float]"); // Test binary format of float point. // https://en.cppreference.com/w/cpp/language/floating_literal // 0x11.12p-1 = (1*16^1 + 2*16^0 + 3*16^-1 + 4*16^-2) * 2^-1 = TEST_EQ(TestValue("{ y:0x12.34p-1 }", "double"), 9.1015625); // hex fraction 1.2 (decimal 1.125) scaled by 2^3, that is 9.0 TEST_EQ(TestValue("{ y:-0x0.2p0 }", "float"), -0.125f); TEST_EQ(TestValue("{ y:-0x.2p1 }", "float"), -0.25f); TEST_EQ(TestValue("{ y:0x1.2p3 }", "float"), 9.0f); TEST_EQ(TestValue("{ y:0x10.1p0 }", "float"), 16.0625f); TEST_EQ(TestValue("{ y:0x1.2p3 }", "double"), 9.0); TEST_EQ(TestValue("{ y:0x10.1p0 }", "double"), 16.0625); TEST_EQ(TestValue("{ y:0xC.68p+2 }", "double"), 49.625); TestValue("{ y: [0x20.4ep1, +0x20.4ep1, -0x20.4ep1] }", "[double]"); TestValue("{ y: [0x20.4ep1, +0x20.4ep1, -0x20.4ep1] }", "[float]"); #else // FLATBUFFERS_HAS_NEW_STRTOD TEST_OUTPUT_LINE("FLATBUFFERS_HAS_NEW_STRTOD tests skipped"); #endif // !FLATBUFFERS_HAS_NEW_STRTOD } void InvalidFloatTest() { auto invalid_msg = "invalid number"; auto comma_msg = "expecting: ,"; TestError("table T { F:float; } root_type T; { F:1,0 }", ""); TestError("table T { F:float; } root_type T; { F:. }", ""); TestError("table T { F:float; } root_type T; { F:- }", invalid_msg); TestError("table T { F:float; } root_type T; { F:+ }", invalid_msg); TestError("table T { F:float; } root_type T; { F:-. }", invalid_msg); TestError("table T { F:float; } root_type T; { F:+. }", invalid_msg); TestError("table T { F:float; } root_type T; { F:.e }", ""); TestError("table T { F:float; } root_type T; { F:-e }", invalid_msg); TestError("table T { F:float; } root_type T; { F:+e }", invalid_msg); TestError("table T { F:float; } root_type T; { F:-.e }", invalid_msg); TestError("table T { F:float; } root_type T; { F:+.e }", invalid_msg); TestError("table T { F:float; } root_type T; { F:-e1 }", invalid_msg); TestError("table T { F:float; } root_type T; { F:+e1 }", invalid_msg); TestError("table T { F:float; } root_type T; { F:1.0e+ }", invalid_msg); TestError("table T { F:float; } root_type T; { F:1.0e- }", invalid_msg); // exponent pP is mandatory for hex-float TestError("table T { F:float; } root_type T; { F:0x0 }", invalid_msg); TestError("table T { F:float; } root_type T; { F:-0x. }", invalid_msg); TestError("table T { F:float; } root_type T; { F:0x. }", invalid_msg); TestError("table T { F:float; } root_type T; { F:0Xe }", invalid_msg); TestError("table T { F:float; } root_type T; { F:\"0Xe\" }", invalid_msg); TestError("table T { F:float; } root_type T; { F:\"nan(1)\" }", invalid_msg); // eE not exponent in hex-float! TestError("table T { F:float; } root_type T; { F:0x0.0e+ }", invalid_msg); TestError("table T { F:float; } root_type T; { F:0x0.0e- }", invalid_msg); TestError("table T { F:float; } root_type T; { F:0x0.0p }", invalid_msg); TestError("table T { F:float; } root_type T; { F:0x0.0p+ }", invalid_msg); TestError("table T { F:float; } root_type T; { F:0x0.0p- }", invalid_msg); TestError("table T { F:float; } root_type T; { F:0x0.0pa1 }", invalid_msg); TestError("table T { F:float; } root_type T; { F:0x0.0e+ }", invalid_msg); TestError("table T { F:float; } root_type T; { F:0x0.0e- }", invalid_msg); TestError("table T { F:float; } root_type T; { F:0x0.0e+0 }", invalid_msg); TestError("table T { F:float; } root_type T; { F:0x0.0e-0 }", invalid_msg); TestError("table T { F:float; } root_type T; { F:0x0.0ep+ }", invalid_msg); TestError("table T { F:float; } root_type T; { F:0x0.0ep- }", invalid_msg); TestError("table T { F:float; } root_type T; { F:1.2.3 }", invalid_msg); TestError("table T { F:float; } root_type T; { F:1.2.e3 }", invalid_msg); TestError("table T { F:float; } root_type T; { F:1.2e.3 }", invalid_msg); TestError("table T { F:float; } root_type T; { F:1.2e0.3 }", invalid_msg); TestError("table T { F:float; } root_type T; { F:1.2e3. }", invalid_msg); TestError("table T { F:float; } root_type T; { F:1.2e3.0 }", invalid_msg); TestError("table T { F:float; } root_type T; { F:+-1.0 }", invalid_msg); TestError("table T { F:float; } root_type T; { F:1.0e+-1 }", invalid_msg); TestError("table T { F:float; } root_type T; { F:\"1.0e+-1\" }", invalid_msg); TestError("table T { F:float; } root_type T; { F:1.e0e }", comma_msg); TestError("table T { F:float; } root_type T; { F:0x1.p0e }", comma_msg); TestError("table T { F:float; } root_type T; { F:\" 0x10 \" }", invalid_msg); // floats in string TestError("table T { F:float; } root_type T; { F:\"1,2.\" }", invalid_msg); TestError("table T { F:float; } root_type T; { F:\"1.2e3.\" }", invalid_msg); TestError("table T { F:float; } root_type T; { F:\"0x1.p0e\" }", invalid_msg); TestError("table T { F:float; } root_type T; { F:\"0x1.0\" }", invalid_msg); TestError("table T { F:float; } root_type T; { F:\" 0x1.0\" }", invalid_msg); TestError("table T { F:float; } root_type T; { F:\"+ 0\" }", invalid_msg); // disable escapes for "number-in-string" TestError("table T { F:float; } root_type T; { F:\"\\f1.2e3.\" }", "invalid"); TestError("table T { F:float; } root_type T; { F:\"\\t1.2e3.\" }", "invalid"); TestError("table T { F:float; } root_type T; { F:\"\\n1.2e3.\" }", "invalid"); TestError("table T { F:float; } root_type T; { F:\"\\r1.2e3.\" }", "invalid"); TestError("table T { F:float; } root_type T; { F:\"4\\x005\" }", "invalid"); TestError("table T { F:float; } root_type T; { F:\"\'12\'\" }", invalid_msg); // null is not a number constant! TestError("table T { F:float; } root_type T; { F:\"null\" }", invalid_msg); TestError("table T { F:float; } root_type T; { F:null }", invalid_msg); } void GenerateTableTextTest() { std::string schemafile; std::string jsonfile; bool ok = flatbuffers::LoadFile((test_data_path + "monster_test.fbs").c_str(), false, &schemafile) && flatbuffers::LoadFile((test_data_path + "monsterdata_test.json").c_str(), false, &jsonfile); TEST_EQ(ok, true); auto include_test_path = flatbuffers::ConCatPathFileName(test_data_path, "include_test"); const char *include_directories[] = { test_data_path.c_str(), include_test_path.c_str(), nullptr }; flatbuffers::IDLOptions opt; opt.indent_step = -1; flatbuffers::Parser parser(opt); ok = parser.Parse(schemafile.c_str(), include_directories) && parser.Parse(jsonfile.c_str(), include_directories); TEST_EQ(ok, true); // Test root table const Monster *monster = GetMonster(parser.builder_.GetBufferPointer()); const auto abilities = monster->testarrayofsortedstruct(); TEST_EQ(abilities->size(), 3); TEST_EQ(abilities->Get(0)->id(), 0); TEST_EQ(abilities->Get(0)->distance(), 45); TEST_EQ(abilities->Get(1)->id(), 1); TEST_EQ(abilities->Get(1)->distance(), 21); TEST_EQ(abilities->Get(2)->id(), 5); TEST_EQ(abilities->Get(2)->distance(), 12); std::string jsongen; auto result = GenerateTextFromTable(parser, monster, "MyGame.Example.Monster", &jsongen); TEST_EQ(result, true); // Test sub table const Vec3 *pos = monster->pos(); jsongen.clear(); result = GenerateTextFromTable(parser, pos, "MyGame.Example.Vec3", &jsongen); TEST_EQ(result, true); TEST_EQ_STR( jsongen.c_str(), "{x: 1.0,y: 2.0,z: 3.0,test1: 3.0,test2: \"Green\",test3: {a: 5,b: 6}}"); const Test &test3 = pos->test3(); jsongen.clear(); result = GenerateTextFromTable(parser, &test3, "MyGame.Example.Test", &jsongen); TEST_EQ(result, true); TEST_EQ_STR(jsongen.c_str(), "{a: 5,b: 6}"); const Test *test4 = monster->test4()->Get(0); jsongen.clear(); result = GenerateTextFromTable(parser, test4, "MyGame.Example.Test", &jsongen); TEST_EQ(result, true); TEST_EQ_STR(jsongen.c_str(), "{a: 10,b: 20}"); } template void NumericUtilsTestInteger(const char *lower, const char *upper) { T x; TEST_EQ(flatbuffers::StringToNumber("1q", &x), false); TEST_EQ(x, 0); TEST_EQ(flatbuffers::StringToNumber(upper, &x), false); TEST_EQ(x, flatbuffers::numeric_limits::max()); TEST_EQ(flatbuffers::StringToNumber(lower, &x), false); auto expval = flatbuffers::is_unsigned::value ? flatbuffers::numeric_limits::max() : flatbuffers::numeric_limits::lowest(); TEST_EQ(x, expval); } template void NumericUtilsTestFloat(const char *lower, const char *upper) { T f; TEST_EQ(flatbuffers::StringToNumber("", &f), false); TEST_EQ(flatbuffers::StringToNumber("1q", &f), false); TEST_EQ(f, 0); TEST_EQ(flatbuffers::StringToNumber(upper, &f), true); TEST_EQ(f, +flatbuffers::numeric_limits::infinity()); TEST_EQ(flatbuffers::StringToNumber(lower, &f), true); TEST_EQ(f, -flatbuffers::numeric_limits::infinity()); } void NumericUtilsTest() { NumericUtilsTestInteger("-1", "18446744073709551616"); NumericUtilsTestInteger("-1", "256"); NumericUtilsTestInteger("-9223372036854775809", "9223372036854775808"); NumericUtilsTestInteger("-129", "128"); NumericUtilsTestFloat("-3.4029e+38", "+3.4029e+38"); NumericUtilsTestFloat("-1.7977e+308", "+1.7977e+308"); } void IsAsciiUtilsTest() { char c = -128; for (int cnt = 0; cnt < 256; cnt++) { auto alpha = (('a' <= c) && (c <= 'z')) || (('A' <= c) && (c <= 'Z')); auto dec = (('0' <= c) && (c <= '9')); auto hex = (('a' <= c) && (c <= 'f')) || (('A' <= c) && (c <= 'F')); TEST_EQ(flatbuffers::is_alpha(c), alpha); TEST_EQ(flatbuffers::is_alnum(c), alpha || dec); TEST_EQ(flatbuffers::is_digit(c), dec); TEST_EQ(flatbuffers::is_xdigit(c), dec || hex); c += 1; } } void UnicodeTest() { flatbuffers::Parser parser; // Without setting allow_non_utf8 = true, we treat \x sequences as byte // sequences which are then validated as UTF-8. TEST_EQ(parser.Parse("table T { F:string; }" "root_type T;" "{ F:\"\\u20AC\\u00A2\\u30E6\\u30FC\\u30B6\\u30FC" "\\u5225\\u30B5\\u30A4\\u30C8\\xE2\\x82\\xAC\\u0080\\uD8" "3D\\uDE0E\" }"), true); std::string jsongen; parser.opts.indent_step = -1; auto result = GenerateText(parser, parser.builder_.GetBufferPointer(), &jsongen); TEST_EQ(result, true); TEST_EQ_STR(jsongen.c_str(), "{F: \"\\u20AC\\u00A2\\u30E6\\u30FC\\u30B6\\u30FC" "\\u5225\\u30B5\\u30A4\\u30C8\\u20AC\\u0080\\uD83D\\uDE0E\"}"); } void UnicodeTestAllowNonUTF8() { flatbuffers::Parser parser; parser.opts.allow_non_utf8 = true; TEST_EQ( parser.Parse( "table T { F:string; }" "root_type T;" "{ F:\"\\u20AC\\u00A2\\u30E6\\u30FC\\u30B6\\u30FC" "\\u5225\\u30B5\\u30A4\\u30C8\\x01\\x80\\u0080\\uD83D\\uDE0E\" }"), true); std::string jsongen; parser.opts.indent_step = -1; auto result = GenerateText(parser, parser.builder_.GetBufferPointer(), &jsongen); TEST_EQ(result, true); TEST_EQ_STR( jsongen.c_str(), "{F: \"\\u20AC\\u00A2\\u30E6\\u30FC\\u30B6\\u30FC" "\\u5225\\u30B5\\u30A4\\u30C8\\u0001\\x80\\u0080\\uD83D\\uDE0E\"}"); } void UnicodeTestGenerateTextFailsOnNonUTF8() { flatbuffers::Parser parser; // Allow non-UTF-8 initially to model what happens when we load a binary // flatbuffer from disk which contains non-UTF-8 strings. parser.opts.allow_non_utf8 = true; TEST_EQ( parser.Parse( "table T { F:string; }" "root_type T;" "{ F:\"\\u20AC\\u00A2\\u30E6\\u30FC\\u30B6\\u30FC" "\\u5225\\u30B5\\u30A4\\u30C8\\x01\\x80\\u0080\\uD83D\\uDE0E\" }"), true); std::string jsongen; parser.opts.indent_step = -1; // Now, disallow non-UTF-8 (the default behavior) so GenerateText indicates // failure. parser.opts.allow_non_utf8 = false; auto result = GenerateText(parser, parser.builder_.GetBufferPointer(), &jsongen); TEST_EQ(result, false); } void UnicodeSurrogatesTest() { flatbuffers::Parser parser; TEST_EQ(parser.Parse("table T { F:string (id: 0); }" "root_type T;" "{ F:\"\\uD83D\\uDCA9\"}"), true); auto root = flatbuffers::GetRoot( parser.builder_.GetBufferPointer()); auto string = root->GetPointer( flatbuffers::FieldIndexToOffset(0)); TEST_EQ_STR(string->c_str(), "\xF0\x9F\x92\xA9"); } void UnicodeInvalidSurrogatesTest() { TestError( "table T { F:string; }" "root_type T;" "{ F:\"\\uD800\"}", "unpaired high surrogate"); TestError( "table T { F:string; }" "root_type T;" "{ F:\"\\uD800abcd\"}", "unpaired high surrogate"); TestError( "table T { F:string; }" "root_type T;" "{ F:\"\\uD800\\n\"}", "unpaired high surrogate"); TestError( "table T { F:string; }" "root_type T;" "{ F:\"\\uD800\\uD800\"}", "multiple high surrogates"); TestError( "table T { F:string; }" "root_type T;" "{ F:\"\\uDC00\"}", "unpaired low surrogate"); } void InvalidUTF8Test() { // "1 byte" pattern, under min length of 2 bytes TestError( "table T { F:string; }" "root_type T;" "{ F:\"\x80\"}", "illegal UTF-8 sequence"); // 2 byte pattern, string too short TestError( "table T { F:string; }" "root_type T;" "{ F:\"\xDF\"}", "illegal UTF-8 sequence"); // 3 byte pattern, string too short TestError( "table T { F:string; }" "root_type T;" "{ F:\"\xEF\xBF\"}", "illegal UTF-8 sequence"); // 4 byte pattern, string too short TestError( "table T { F:string; }" "root_type T;" "{ F:\"\xF7\xBF\xBF\"}", "illegal UTF-8 sequence"); // "5 byte" pattern, string too short TestError( "table T { F:string; }" "root_type T;" "{ F:\"\xFB\xBF\xBF\xBF\"}", "illegal UTF-8 sequence"); // "6 byte" pattern, string too short TestError( "table T { F:string; }" "root_type T;" "{ F:\"\xFD\xBF\xBF\xBF\xBF\"}", "illegal UTF-8 sequence"); // "7 byte" pattern, string too short TestError( "table T { F:string; }" "root_type T;" "{ F:\"\xFE\xBF\xBF\xBF\xBF\xBF\"}", "illegal UTF-8 sequence"); // "5 byte" pattern, over max length of 4 bytes TestError( "table T { F:string; }" "root_type T;" "{ F:\"\xFB\xBF\xBF\xBF\xBF\"}", "illegal UTF-8 sequence"); // "6 byte" pattern, over max length of 4 bytes TestError( "table T { F:string; }" "root_type T;" "{ F:\"\xFD\xBF\xBF\xBF\xBF\xBF\"}", "illegal UTF-8 sequence"); // "7 byte" pattern, over max length of 4 bytes TestError( "table T { F:string; }" "root_type T;" "{ F:\"\xFE\xBF\xBF\xBF\xBF\xBF\xBF\"}", "illegal UTF-8 sequence"); // Three invalid encodings for U+000A (\n, aka NEWLINE) TestError( "table T { F:string; }" "root_type T;" "{ F:\"\xC0\x8A\"}", "illegal UTF-8 sequence"); TestError( "table T { F:string; }" "root_type T;" "{ F:\"\xE0\x80\x8A\"}", "illegal UTF-8 sequence"); TestError( "table T { F:string; }" "root_type T;" "{ F:\"\xF0\x80\x80\x8A\"}", "illegal UTF-8 sequence"); // Two invalid encodings for U+00A9 (COPYRIGHT SYMBOL) TestError( "table T { F:string; }" "root_type T;" "{ F:\"\xE0\x81\xA9\"}", "illegal UTF-8 sequence"); TestError( "table T { F:string; }" "root_type T;" "{ F:\"\xF0\x80\x81\xA9\"}", "illegal UTF-8 sequence"); // Invalid encoding for U+20AC (EURO SYMBOL) TestError( "table T { F:string; }" "root_type T;" "{ F:\"\xF0\x82\x82\xAC\"}", "illegal UTF-8 sequence"); // UTF-16 surrogate values between U+D800 and U+DFFF cannot be encoded in // UTF-8 TestError( "table T { F:string; }" "root_type T;" // U+10400 "encoded" as U+D801 U+DC00 "{ F:\"\xED\xA0\x81\xED\xB0\x80\"}", "illegal UTF-8 sequence"); // Check independence of identifier from locale. std::string locale_ident; locale_ident += "table T { F"; locale_ident += static_cast(-32); // unsigned 0xE0 locale_ident += " :string; }"; locale_ident += "root_type T;"; locale_ident += "{}"; TestError(locale_ident.c_str(), ""); } void UnknownFieldsTest() { flatbuffers::IDLOptions opts; opts.skip_unexpected_fields_in_json = true; flatbuffers::Parser parser(opts); TEST_EQ(parser.Parse("table T { str:string; i:int;}" "root_type T;" "{ str:\"test\"," "unknown_string:\"test\"," "\"unknown_string\":\"test\"," "unknown_int:10," "unknown_float:1.0," "unknown_array: [ 1, 2, 3, 4]," "unknown_object: { i: 10 }," "\"unknown_object\": { \"i\": 10 }," "i:10}"), true); std::string jsongen; parser.opts.indent_step = -1; auto result = GenerateText(parser, parser.builder_.GetBufferPointer(), &jsongen); TEST_EQ(result, true); TEST_EQ_STR(jsongen.c_str(), "{str: \"test\",i: 10}"); } void ParseUnionTest() { // Unions must be parseable with the type field following the object. flatbuffers::Parser parser; TEST_EQ(parser.Parse("table T { A:int; }" "union U { T }" "table V { X:U; }" "root_type V;" "{ X:{ A:1 }, X_type: T }"), true); // Unions must be parsable with prefixed namespace. flatbuffers::Parser parser2; TEST_EQ(parser2.Parse("namespace N; table A {} namespace; union U { N.A }" "table B { e:U; } root_type B;" "{ e_type: N_A, e: {} }"), true); } void InvalidNestedFlatbufferTest() { // First, load and parse FlatBuffer schema (.fbs) std::string schemafile; TEST_EQ(flatbuffers::LoadFile((test_data_path + "monster_test.fbs").c_str(), false, &schemafile), true); auto include_test_path = flatbuffers::ConCatPathFileName(test_data_path, "include_test"); const char *include_directories[] = { test_data_path.c_str(), include_test_path.c_str(), nullptr }; flatbuffers::Parser parser1; TEST_EQ(parser1.Parse(schemafile.c_str(), include_directories), true); // "color" inside nested flatbuffer contains invalid enum value TEST_EQ(parser1.Parse("{ name: \"Bender\", testnestedflatbuffer: { name: " "\"Leela\", color: \"nonexistent\"}}"), false); } void EvolutionTest() { // VS10 does not support typed enums, exclude from tests #if !defined(_MSC_VER) || _MSC_VER >= 1700 const int NUM_VERSIONS = 2; std::string schemas[NUM_VERSIONS]; std::string jsonfiles[NUM_VERSIONS]; std::vector binaries[NUM_VERSIONS]; flatbuffers::IDLOptions idl_opts; idl_opts.lang_to_generate |= flatbuffers::IDLOptions::kBinary; flatbuffers::Parser parser(idl_opts); // Load all the schema versions and their associated data. for (int i = 0; i < NUM_VERSIONS; ++i) { std::string schema = test_data_path + "evolution_test/evolution_v" + flatbuffers::NumToString(i + 1) + ".fbs"; TEST_ASSERT(flatbuffers::LoadFile(schema.c_str(), false, &schemas[i])); std::string json = test_data_path + "evolution_test/evolution_v" + flatbuffers::NumToString(i + 1) + ".json"; TEST_ASSERT(flatbuffers::LoadFile(json.c_str(), false, &jsonfiles[i])); TEST_ASSERT(parser.Parse(schemas[i].c_str())); TEST_ASSERT(parser.Parse(jsonfiles[i].c_str())); auto bufLen = parser.builder_.GetSize(); auto buf = parser.builder_.GetBufferPointer(); binaries[i].reserve(bufLen); std::copy(buf, buf + bufLen, std::back_inserter(binaries[i])); } // Assert that all the verifiers for the different schema versions properly // verify any version data. for (int i = 0; i < NUM_VERSIONS; ++i) { flatbuffers::Verifier verifier(&binaries[i].front(), binaries[i].size()); TEST_ASSERT(Evolution::V1::VerifyRootBuffer(verifier)); TEST_ASSERT(Evolution::V2::VerifyRootBuffer(verifier)); } // Test backwards compatibility by reading old data with an evolved schema. auto root_v1_viewed_from_v2 = Evolution::V2::GetRoot(&binaries[0].front()); // field 'k' is new in version 2, so it should be null. TEST_ASSERT(nullptr == root_v1_viewed_from_v2->k()); // field 'l' is new in version 2 with a default of 56. TEST_EQ(root_v1_viewed_from_v2->l(), 56); // field 'c' of 'TableA' is new in version 2, so it should be null. TEST_ASSERT(nullptr == root_v1_viewed_from_v2->e()->c()); // 'TableC' was added to field 'c' union in version 2, so it should be null. TEST_ASSERT(nullptr == root_v1_viewed_from_v2->c_as_TableC()); // The field 'c' union should be of type 'TableB' regardless of schema version TEST_ASSERT(root_v1_viewed_from_v2->c_type() == Evolution::V2::Union::TableB); // The field 'f' was renamed to 'ff' in version 2, it should still be // readable. TEST_EQ(root_v1_viewed_from_v2->ff()->a(), 16); // Test forwards compatibility by reading new data with an old schema. auto root_v2_viewed_from_v1 = Evolution::V1::GetRoot(&binaries[1].front()); // The field 'c' union in version 2 is a new table (index = 3) and should // still be accessible, but not interpretable. TEST_EQ(static_cast(root_v2_viewed_from_v1->c_type()), 3); TEST_NOTNULL(root_v2_viewed_from_v1->c()); // The field 'd' enum in verison 2 has new members and should still be // accessible, but not interpretable. TEST_EQ(static_cast(root_v2_viewed_from_v1->d()), 3); // The field 'a' in version 2 is deprecated and should return the default // value (0) instead of the value stored in the in the buffer (42). TEST_EQ(root_v2_viewed_from_v1->a(), 0); // The field 'ff' was originally named 'f' in version 1, it should still be // readable. TEST_EQ(root_v2_viewed_from_v1->f()->a(), 35); #endif } void UnionDeprecationTest() { const int NUM_VERSIONS = 2; std::string schemas[NUM_VERSIONS]; std::string jsonfiles[NUM_VERSIONS]; std::vector binaries[NUM_VERSIONS]; flatbuffers::IDLOptions idl_opts; idl_opts.lang_to_generate |= flatbuffers::IDLOptions::kBinary; flatbuffers::Parser parser(idl_opts); // Load all the schema versions and their associated data. for (int i = 0; i < NUM_VERSIONS; ++i) { std::string schema = test_data_path + "evolution_test/evolution_v" + flatbuffers::NumToString(i + 1) + ".fbs"; TEST_ASSERT(flatbuffers::LoadFile(schema.c_str(), false, &schemas[i])); std::string json = test_data_path + "evolution_test/evolution_v" + flatbuffers::NumToString(i + 1) + ".json"; TEST_ASSERT(flatbuffers::LoadFile(json.c_str(), false, &jsonfiles[i])); TEST_ASSERT(parser.Parse(schemas[i].c_str())); TEST_ASSERT(parser.Parse(jsonfiles[i].c_str())); auto bufLen = parser.builder_.GetSize(); auto buf = parser.builder_.GetBufferPointer(); binaries[i].reserve(bufLen); std::copy(buf, buf + bufLen, std::back_inserter(binaries[i])); } auto v2 = parser.LookupStruct("Evolution.V2.Root"); TEST_NOTNULL(v2); auto j_type_field = v2->fields.Lookup("j_type"); TEST_NOTNULL(j_type_field); TEST_ASSERT(j_type_field->deprecated); } void UnionVectorTest() { // load FlatBuffer fbs schema and json. std::string schemafile, jsonfile; TEST_EQ(flatbuffers::LoadFile( (test_data_path + "union_vector/union_vector.fbs").c_str(), false, &schemafile), true); TEST_EQ(flatbuffers::LoadFile( (test_data_path + "union_vector/union_vector.json").c_str(), false, &jsonfile), true); // parse schema. flatbuffers::IDLOptions idl_opts; idl_opts.lang_to_generate |= flatbuffers::IDLOptions::kBinary; flatbuffers::Parser parser(idl_opts); TEST_EQ(parser.Parse(schemafile.c_str()), true); flatbuffers::FlatBufferBuilder fbb; // union types. std::vector types; types.push_back(static_cast(Character_Belle)); types.push_back(static_cast(Character_MuLan)); types.push_back(static_cast(Character_BookFan)); types.push_back(static_cast(Character_Other)); types.push_back(static_cast(Character_Unused)); // union values. std::vector> characters; characters.push_back(fbb.CreateStruct(BookReader(/*books_read=*/7)).Union()); characters.push_back(CreateAttacker(fbb, /*sword_attack_damage=*/5).Union()); characters.push_back(fbb.CreateStruct(BookReader(/*books_read=*/2)).Union()); characters.push_back(fbb.CreateString("Other").Union()); characters.push_back(fbb.CreateString("Unused").Union()); // create Movie. const auto movie_offset = CreateMovie(fbb, Character_Rapunzel, fbb.CreateStruct(Rapunzel(/*hair_length=*/6)).Union(), fbb.CreateVector(types), fbb.CreateVector(characters)); FinishMovieBuffer(fbb, movie_offset); flatbuffers::Verifier verifier(fbb.GetBufferPointer(), fbb.GetSize()); TEST_EQ(VerifyMovieBuffer(verifier), true); auto flat_movie = GetMovie(fbb.GetBufferPointer()); auto TestMovie = [](const Movie *movie) { TEST_EQ(movie->main_character_type() == Character_Rapunzel, true); auto cts = movie->characters_type(); TEST_EQ(movie->characters_type()->size(), 5); TEST_EQ(cts->GetEnum(0) == Character_Belle, true); TEST_EQ(cts->GetEnum(1) == Character_MuLan, true); TEST_EQ(cts->GetEnum(2) == Character_BookFan, true); TEST_EQ(cts->GetEnum(3) == Character_Other, true); TEST_EQ(cts->GetEnum(4) == Character_Unused, true); auto rapunzel = movie->main_character_as_Rapunzel(); TEST_NOTNULL(rapunzel); TEST_EQ(rapunzel->hair_length(), 6); auto cs = movie->characters(); TEST_EQ(cs->size(), 5); auto belle = cs->GetAs(0); TEST_EQ(belle->books_read(), 7); auto mu_lan = cs->GetAs(1); TEST_EQ(mu_lan->sword_attack_damage(), 5); auto book_fan = cs->GetAs(2); TEST_EQ(book_fan->books_read(), 2); auto other = cs->GetAsString(3); TEST_EQ_STR(other->c_str(), "Other"); auto unused = cs->GetAsString(4); TEST_EQ_STR(unused->c_str(), "Unused"); }; TestMovie(flat_movie); // Also test the JSON we loaded above. TEST_EQ(parser.Parse(jsonfile.c_str()), true); auto jbuf = parser.builder_.GetBufferPointer(); flatbuffers::Verifier jverifier(jbuf, parser.builder_.GetSize()); TEST_EQ(VerifyMovieBuffer(jverifier), true); TestMovie(GetMovie(jbuf)); auto movie_object = flat_movie->UnPack(); TEST_EQ(movie_object->main_character.AsRapunzel()->hair_length(), 6); TEST_EQ(movie_object->characters[0].AsBelle()->books_read(), 7); TEST_EQ(movie_object->characters[1].AsMuLan()->sword_attack_damage, 5); TEST_EQ(movie_object->characters[2].AsBookFan()->books_read(), 2); TEST_EQ_STR(movie_object->characters[3].AsOther()->c_str(), "Other"); TEST_EQ_STR(movie_object->characters[4].AsUnused()->c_str(), "Unused"); fbb.Clear(); fbb.Finish(Movie::Pack(fbb, movie_object)); delete movie_object; auto repacked_movie = GetMovie(fbb.GetBufferPointer()); TestMovie(repacked_movie); // Generate text using mini-reflection. auto s = flatbuffers::FlatBufferToString(fbb.GetBufferPointer(), MovieTypeTable()); TEST_EQ_STR( s.c_str(), "{ main_character_type: Rapunzel, main_character: { hair_length: 6 }, " "characters_type: [ Belle, MuLan, BookFan, Other, Unused ], " "characters: [ { books_read: 7 }, { sword_attack_damage: 5 }, " "{ books_read: 2 }, \"Other\", \"Unused\" ] }"); flatbuffers::ToStringVisitor visitor("\n", true, " "); IterateFlatBuffer(fbb.GetBufferPointer(), MovieTypeTable(), &visitor); TEST_EQ_STR(visitor.s.c_str(), "{\n" " \"main_character_type\": \"Rapunzel\",\n" " \"main_character\": {\n" " \"hair_length\": 6\n" " },\n" " \"characters_type\": [\n" " \"Belle\",\n" " \"MuLan\",\n" " \"BookFan\",\n" " \"Other\",\n" " \"Unused\"\n" " ],\n" " \"characters\": [\n" " {\n" " \"books_read\": 7\n" " },\n" " {\n" " \"sword_attack_damage\": 5\n" " },\n" " {\n" " \"books_read\": 2\n" " },\n" " \"Other\",\n" " \"Unused\"\n" " ]\n" "}"); // Generate text using parsed schema. std::string jsongen; auto result = GenerateText(parser, fbb.GetBufferPointer(), &jsongen); TEST_EQ(result, true); TEST_EQ_STR(jsongen.c_str(), "{\n" " main_character_type: \"Rapunzel\",\n" " main_character: {\n" " hair_length: 6\n" " },\n" " characters_type: [\n" " \"Belle\",\n" " \"MuLan\",\n" " \"BookFan\",\n" " \"Other\",\n" " \"Unused\"\n" " ],\n" " characters: [\n" " {\n" " books_read: 7\n" " },\n" " {\n" " sword_attack_damage: 5\n" " },\n" " {\n" " books_read: 2\n" " },\n" " \"Other\",\n" " \"Unused\"\n" " ]\n" "}\n"); // Simple test with reflection. parser.Serialize(); auto schema = reflection::GetSchema(parser.builder_.GetBufferPointer()); auto ok = flatbuffers::Verify(*schema, *schema->root_table(), fbb.GetBufferPointer(), fbb.GetSize()); TEST_EQ(ok, true); flatbuffers::Parser parser2(idl_opts); TEST_EQ(parser2.Parse("struct Bool { b:bool; }" "union Any { Bool }" "table Root { a:Any; }" "root_type Root;"), true); TEST_EQ(parser2.Parse("{a_type:Bool,a:{b:true}}"), true); } void ConformTest() { flatbuffers::Parser parser; TEST_EQ(parser.Parse("table T { A:int; } enum E:byte { A }"), true); auto test_conform = [](flatbuffers::Parser &parser1, const char *test, const char *expected_err) { flatbuffers::Parser parser2; TEST_EQ(parser2.Parse(test), true); auto err = parser2.ConformTo(parser1); TEST_NOTNULL(strstr(err.c_str(), expected_err)); }; test_conform(parser, "table T { A:byte; }", "types differ for field"); test_conform(parser, "table T { B:int; A:int; }", "offsets differ for field"); test_conform(parser, "table T { A:int = 1; }", "defaults differ for field"); test_conform(parser, "table T { B:float; }", "field renamed to different type"); test_conform(parser, "enum E:byte { B, A }", "values differ for enum"); } void ParseProtoBufAsciiTest() { // We can put the parser in a mode where it will accept JSON that looks more // like Protobuf ASCII, for users that have data in that format. // This uses no "" for field names (which we already support by default, // omits `,`, `:` before `{` and a couple of other features. flatbuffers::Parser parser; parser.opts.protobuf_ascii_alike = true; TEST_EQ( parser.Parse("table S { B:int; } table T { A:[int]; C:S; } root_type T;"), true); TEST_EQ(parser.Parse("{ A [1 2] C { B:2 }}"), true); // Similarly, in text output, it should omit these. std::string text; auto ok = flatbuffers::GenerateText( parser, parser.builder_.GetBufferPointer(), &text); TEST_EQ(ok, true); TEST_EQ_STR(text.c_str(), "{\n A [\n 1\n 2\n ]\n C {\n B: 2\n }\n}\n"); } void FlexBuffersTest() { flexbuffers::Builder slb(512, flexbuffers::BUILDER_FLAG_SHARE_KEYS_AND_STRINGS); // Write the equivalent of: // { vec: [ -100, "Fred", 4.0, false ], bar: [ 1, 2, 3 ], bar3: [ 1, 2, 3 ], // foo: 100, bool: true, mymap: { foo: "Fred" } } // clang-format off #ifndef FLATBUFFERS_CPP98_STL // It's possible to do this without std::function support as well. slb.Map([&]() { slb.Vector("vec", [&]() { slb += -100; // Equivalent to slb.Add(-100) or slb.Int(-100); slb += "Fred"; slb.IndirectFloat(4.0f); auto i_f = slb.LastValue(); uint8_t blob[] = { 77 }; slb.Blob(blob, 1); slb += false; slb.ReuseValue(i_f); }); int ints[] = { 1, 2, 3 }; slb.Vector("bar", ints, 3); slb.FixedTypedVector("bar3", ints, 3); bool bools[] = {true, false, true, false}; slb.Vector("bools", bools, 4); slb.Bool("bool", true); slb.Double("foo", 100); slb.Map("mymap", [&]() { slb.String("foo", "Fred"); // Testing key and string reuse. }); }); slb.Finish(); #else // It's possible to do this without std::function support as well. slb.Map([](flexbuffers::Builder& slb2) { slb2.Vector("vec", [](flexbuffers::Builder& slb3) { slb3 += -100; // Equivalent to slb.Add(-100) or slb.Int(-100); slb3 += "Fred"; slb3.IndirectFloat(4.0f); auto i_f = slb3.LastValue(); uint8_t blob[] = { 77 }; slb3.Blob(blob, 1); slb3 += false; slb3.ReuseValue(i_f); }, slb2); int ints[] = { 1, 2, 3 }; slb2.Vector("bar", ints, 3); slb2.FixedTypedVector("bar3", ints, 3); slb2.Bool("bool", true); slb2.Double("foo", 100); slb2.Map("mymap", [](flexbuffers::Builder& slb3) { slb3.String("foo", "Fred"); // Testing key and string reuse. }, slb2); }, slb); slb.Finish(); #endif // FLATBUFFERS_CPP98_STL #ifdef FLATBUFFERS_TEST_VERBOSE for (size_t i = 0; i < slb.GetBuffer().size(); i++) printf("%d ", flatbuffers::vector_data(slb.GetBuffer())[i]); printf("\n"); #endif // clang-format on auto map = flexbuffers::GetRoot(slb.GetBuffer()).AsMap(); TEST_EQ(map.size(), 7); auto vec = map["vec"].AsVector(); TEST_EQ(vec.size(), 6); TEST_EQ(vec[0].AsInt64(), -100); TEST_EQ_STR(vec[1].AsString().c_str(), "Fred"); TEST_EQ(vec[1].AsInt64(), 0); // Number parsing failed. TEST_EQ(vec[2].AsDouble(), 4.0); TEST_EQ(vec[2].AsString().IsTheEmptyString(), true); // Wrong Type. TEST_EQ_STR(vec[2].AsString().c_str(), ""); // This still works though. TEST_EQ_STR(vec[2].ToString().c_str(), "4.0"); // Or have it converted. // Few tests for templated version of As. TEST_EQ(vec[0].As(), -100); TEST_EQ_STR(vec[1].As().c_str(), "Fred"); TEST_EQ(vec[1].As(), 0); // Number parsing failed. TEST_EQ(vec[2].As(), 4.0); // Test that the blob can be accessed. TEST_EQ(vec[3].IsBlob(), true); auto blob = vec[3].AsBlob(); TEST_EQ(blob.size(), 1); TEST_EQ(blob.data()[0], 77); TEST_EQ(vec[4].IsBool(), true); // Check if type is a bool TEST_EQ(vec[4].AsBool(), false); // Check if value is false TEST_EQ(vec[5].AsDouble(), 4.0); // This is shared with vec[2] ! auto tvec = map["bar"].AsTypedVector(); TEST_EQ(tvec.size(), 3); TEST_EQ(tvec[2].AsInt8(), 3); auto tvec3 = map["bar3"].AsFixedTypedVector(); TEST_EQ(tvec3.size(), 3); TEST_EQ(tvec3[2].AsInt8(), 3); TEST_EQ(map["bool"].AsBool(), true); auto tvecb = map["bools"].AsTypedVector(); TEST_EQ(tvecb.ElementType(), flexbuffers::FBT_BOOL); TEST_EQ(map["foo"].AsUInt8(), 100); TEST_EQ(map["unknown"].IsNull(), true); auto mymap = map["mymap"].AsMap(); // These should be equal by pointer equality, since key and value are shared. TEST_EQ(mymap.Keys()[0].AsKey(), map.Keys()[4].AsKey()); TEST_EQ(mymap.Values()[0].AsString().c_str(), vec[1].AsString().c_str()); // We can mutate values in the buffer. TEST_EQ(vec[0].MutateInt(-99), true); TEST_EQ(vec[0].AsInt64(), -99); TEST_EQ(vec[1].MutateString("John"), true); // Size must match. TEST_EQ_STR(vec[1].AsString().c_str(), "John"); TEST_EQ(vec[1].MutateString("Alfred"), false); // Too long. TEST_EQ(vec[2].MutateFloat(2.0f), true); TEST_EQ(vec[2].AsFloat(), 2.0f); TEST_EQ(vec[2].MutateFloat(3.14159), false); // Double does not fit in float. TEST_EQ(vec[4].AsBool(), false); // Is false before change TEST_EQ(vec[4].MutateBool(true), true); // Can change a bool TEST_EQ(vec[4].AsBool(), true); // Changed bool is now true // Parse from JSON: flatbuffers::Parser parser; slb.Clear(); auto jsontest = "{ a: [ 123, 456.0 ], b: \"hello\", c: true, d: false }"; TEST_EQ(parser.ParseFlexBuffer(jsontest, nullptr, &slb), true); auto jroot = flexbuffers::GetRoot(slb.GetBuffer()); auto jmap = jroot.AsMap(); auto jvec = jmap["a"].AsVector(); TEST_EQ(jvec[0].AsInt64(), 123); TEST_EQ(jvec[1].AsDouble(), 456.0); TEST_EQ_STR(jmap["b"].AsString().c_str(), "hello"); TEST_EQ(jmap["c"].IsBool(), true); // Parsed correctly to a bool TEST_EQ(jmap["c"].AsBool(), true); // Parsed correctly to true TEST_EQ(jmap["d"].IsBool(), true); // Parsed correctly to a bool TEST_EQ(jmap["d"].AsBool(), false); // Parsed correctly to false // And from FlexBuffer back to JSON: auto jsonback = jroot.ToString(); TEST_EQ_STR(jsontest, jsonback.c_str()); slb.Clear(); slb.Vector([&]() { for (int i = 0; i < 130; ++i) slb.Add(static_cast(255)); slb.Vector([&]() { for (int i = 0; i < 130; ++i) slb.Add(static_cast(255)); slb.Vector([] {}); }); }); slb.Finish(); TEST_EQ(slb.GetSize(), 664); } void FlexBuffersFloatingPointTest() { #if defined(FLATBUFFERS_HAS_NEW_STRTOD) && (FLATBUFFERS_HAS_NEW_STRTOD > 0) flexbuffers::Builder slb(512, flexbuffers::BUILDER_FLAG_SHARE_KEYS_AND_STRINGS); // Parse floating-point values from JSON: flatbuffers::Parser parser; slb.Clear(); auto jsontest = "{ a: [1.0, nan, inf, infinity, -inf, +inf, -infinity, 8.0] }"; TEST_EQ(parser.ParseFlexBuffer(jsontest, nullptr, &slb), true); auto jroot = flexbuffers::GetRoot(slb.GetBuffer()); auto jmap = jroot.AsMap(); auto jvec = jmap["a"].AsVector(); TEST_EQ(8, jvec.size()); TEST_EQ(1.0, jvec[0].AsDouble()); TEST_ASSERT(is_quiet_nan(jvec[1].AsDouble())); TEST_EQ(infinity_d, jvec[2].AsDouble()); TEST_EQ(infinity_d, jvec[3].AsDouble()); TEST_EQ(-infinity_d, jvec[4].AsDouble()); TEST_EQ(+infinity_d, jvec[5].AsDouble()); TEST_EQ(-infinity_d, jvec[6].AsDouble()); TEST_EQ(8.0, jvec[7].AsDouble()); #endif } void FlexBuffersDeprecatedTest() { // FlexBuffers as originally designed had a flaw involving the // FBT_VECTOR_STRING datatype, and this test documents/tests the fix for it. // Discussion: https://github.com/google/flatbuffers/issues/5627 flexbuffers::Builder slb; // FBT_VECTOR_* are "typed vectors" where all elements are of the same type. // Problem is, when storing FBT_STRING elements, it relies on that type to // get the bit-width for the size field of the string, which in this case // isn't present, and instead defaults to 8-bit. This means that any strings // stored inside such a vector, when accessed thru the old API that returns // a String reference, will appear to be truncated if the string stored is // actually >=256 bytes. std::string test_data(300, 'A'); auto start = slb.StartVector(); // This one will have a 16-bit size field. slb.String(test_data); // This one will have an 8-bit size field. slb.String("hello"); // We're asking this to be serialized as a typed vector (true), but not // fixed size (false). The type will be FBT_VECTOR_STRING with a bit-width // of whatever the offsets in the vector need, the bit-widths of the strings // are not stored(!) <- the actual design flaw. // Note that even in the fixed code, we continue to serialize the elements of // FBT_VECTOR_STRING as FBT_STRING, since there may be old code out there // reading new data that we want to continue to function. // Thus, FBT_VECTOR_STRING, while deprecated, will always be represented the // same way, the fix lies on the reading side. slb.EndVector(start, true, false); slb.Finish(); // So now lets read this data back. // For existing data, since we have no way of knowing what the actual // bit-width of the size field of the string is, we are going to ignore this // field, and instead treat these strings as FBT_KEY (null-terminated), so we // can deal with strings of arbitrary length. This of course truncates strings // with embedded nulls, but we think that that is preferrable over truncating // strings >= 256 bytes. auto vec = flexbuffers::GetRoot(slb.GetBuffer()).AsTypedVector(); // Even though this was serialized as FBT_VECTOR_STRING, it is read as // FBT_VECTOR_KEY: TEST_EQ(vec.ElementType(), flexbuffers::FBT_KEY); // Access the long string. Previously, this would return a string of size 1, // since it would read the high-byte of the 16-bit length. // This should now correctly test the full 300 bytes, using AsKey(): TEST_EQ_STR(vec[0].AsKey(), test_data.c_str()); // Old code that called AsString will continue to work, as the String // accessor objects now use a cached size that can come from a key as well. TEST_EQ_STR(vec[0].AsString().c_str(), test_data.c_str()); // Short strings work as before: TEST_EQ_STR(vec[1].AsKey(), "hello"); TEST_EQ_STR(vec[1].AsString().c_str(), "hello"); // So, while existing code and data mostly "just work" with the fixes applied // to AsTypedVector and AsString, what do you do going forward? // Code accessing existing data doesn't necessarily need to change, though // you could consider using AsKey instead of AsString for a) documenting // that you are accessing keys, or b) a speedup if you don't actually use // the string size. // For new data, or data that doesn't need to be backwards compatible, // instead serialize as FBT_VECTOR (call EndVector with typed = false, then // read elements with AsString), or, for maximum compactness, use // FBT_VECTOR_KEY (call slb.Key above instead, read with AsKey or AsString). } void TypeAliasesTest() { flatbuffers::FlatBufferBuilder builder; builder.Finish(CreateTypeAliases( builder, flatbuffers::numeric_limits::min(), flatbuffers::numeric_limits::max(), flatbuffers::numeric_limits::min(), flatbuffers::numeric_limits::max(), flatbuffers::numeric_limits::min(), flatbuffers::numeric_limits::max(), flatbuffers::numeric_limits::min(), flatbuffers::numeric_limits::max(), 2.3f, 2.3)); auto p = builder.GetBufferPointer(); auto ta = flatbuffers::GetRoot(p); TEST_EQ(ta->i8(), flatbuffers::numeric_limits::min()); TEST_EQ(ta->u8(), flatbuffers::numeric_limits::max()); TEST_EQ(ta->i16(), flatbuffers::numeric_limits::min()); TEST_EQ(ta->u16(), flatbuffers::numeric_limits::max()); TEST_EQ(ta->i32(), flatbuffers::numeric_limits::min()); TEST_EQ(ta->u32(), flatbuffers::numeric_limits::max()); TEST_EQ(ta->i64(), flatbuffers::numeric_limits::min()); TEST_EQ(ta->u64(), flatbuffers::numeric_limits::max()); TEST_EQ(ta->f32(), 2.3f); TEST_EQ(ta->f64(), 2.3); using namespace flatbuffers; // is_same static_assert(is_samei8()), int8_t>::value, "invalid type"); static_assert(is_samei16()), int16_t>::value, "invalid type"); static_assert(is_samei32()), int32_t>::value, "invalid type"); static_assert(is_samei64()), int64_t>::value, "invalid type"); static_assert(is_sameu8()), uint8_t>::value, "invalid type"); static_assert(is_sameu16()), uint16_t>::value, "invalid type"); static_assert(is_sameu32()), uint32_t>::value, "invalid type"); static_assert(is_sameu64()), uint64_t>::value, "invalid type"); static_assert(is_samef32()), float>::value, "invalid type"); static_assert(is_samef64()), double>::value, "invalid type"); } void EndianSwapTest() { TEST_EQ(flatbuffers::EndianSwap(static_cast(0x1234)), 0x3412); TEST_EQ(flatbuffers::EndianSwap(static_cast(0x12345678)), 0x78563412); TEST_EQ(flatbuffers::EndianSwap(static_cast(0x1234567890ABCDEF)), 0xEFCDAB9078563412); TEST_EQ(flatbuffers::EndianSwap(flatbuffers::EndianSwap(3.14f)), 3.14f); } void UninitializedVectorTest() { flatbuffers::FlatBufferBuilder builder; Test *buf = nullptr; auto vector_offset = builder.CreateUninitializedVectorOfStructs(2, &buf); TEST_NOTNULL(buf); buf[0] = Test(10, 20); buf[1] = Test(30, 40); auto required_name = builder.CreateString("myMonster"); auto monster_builder = MonsterBuilder(builder); monster_builder.add_name( required_name); // required field mandated for monster. monster_builder.add_test4(vector_offset); builder.Finish(monster_builder.Finish()); auto p = builder.GetBufferPointer(); auto uvt = flatbuffers::GetRoot(p); TEST_NOTNULL(uvt); auto vec = uvt->test4(); TEST_NOTNULL(vec); auto test_0 = vec->Get(0); auto test_1 = vec->Get(1); TEST_EQ(test_0->a(), 10); TEST_EQ(test_0->b(), 20); TEST_EQ(test_1->a(), 30); TEST_EQ(test_1->b(), 40); } void EqualOperatorTest() { MonsterT a; MonsterT b; TEST_EQ(b == a, true); TEST_EQ(b != a, false); b.mana = 33; TEST_EQ(b == a, false); TEST_EQ(b != a, true); b.mana = 150; TEST_EQ(b == a, true); TEST_EQ(b != a, false); b.inventory.push_back(3); TEST_EQ(b == a, false); TEST_EQ(b != a, true); b.inventory.clear(); TEST_EQ(b == a, true); TEST_EQ(b != a, false); b.test.type = Any_Monster; TEST_EQ(b == a, false); TEST_EQ(b != a, true); } // For testing any binaries, e.g. from fuzzing. void LoadVerifyBinaryTest() { std::string binary; if (flatbuffers::LoadFile( (test_data_path + "fuzzer/your-filename-here").c_str(), true, &binary)) { flatbuffers::Verifier verifier( reinterpret_cast(binary.data()), binary.size()); TEST_EQ(VerifyMonsterBuffer(verifier), true); } } void CreateSharedStringTest() { flatbuffers::FlatBufferBuilder builder; const auto one1 = builder.CreateSharedString("one"); const auto two = builder.CreateSharedString("two"); const auto one2 = builder.CreateSharedString("one"); TEST_EQ(one1.o, one2.o); const auto onetwo = builder.CreateSharedString("onetwo"); TEST_EQ(onetwo.o != one1.o, true); TEST_EQ(onetwo.o != two.o, true); // Support for embedded nulls const char chars_b[] = { 'a', '\0', 'b' }; const char chars_c[] = { 'a', '\0', 'c' }; const auto null_b1 = builder.CreateSharedString(chars_b, sizeof(chars_b)); const auto null_c = builder.CreateSharedString(chars_c, sizeof(chars_c)); const auto null_b2 = builder.CreateSharedString(chars_b, sizeof(chars_b)); TEST_EQ(null_b1.o != null_c.o, true); // Issue#5058 repro TEST_EQ(null_b1.o, null_b2.o); // Put the strings into an array for round trip verification. const flatbuffers::Offset array[7] = { one1, two, one2, onetwo, null_b1, null_c, null_b2 }; const auto vector_offset = builder.CreateVector(array, flatbuffers::uoffset_t(7)); MonsterBuilder monster_builder(builder); monster_builder.add_name(two); monster_builder.add_testarrayofstring(vector_offset); builder.Finish(monster_builder.Finish()); // Read the Monster back. const auto *monster = flatbuffers::GetRoot(builder.GetBufferPointer()); TEST_EQ_STR(monster->name()->c_str(), "two"); const auto *testarrayofstring = monster->testarrayofstring(); TEST_EQ(testarrayofstring->size(), flatbuffers::uoffset_t(7)); const auto &a = *testarrayofstring; TEST_EQ_STR(a[0]->c_str(), "one"); TEST_EQ_STR(a[1]->c_str(), "two"); TEST_EQ_STR(a[2]->c_str(), "one"); TEST_EQ_STR(a[3]->c_str(), "onetwo"); TEST_EQ(a[4]->str(), (std::string(chars_b, sizeof(chars_b)))); TEST_EQ(a[5]->str(), (std::string(chars_c, sizeof(chars_c)))); TEST_EQ(a[6]->str(), (std::string(chars_b, sizeof(chars_b)))); // Make sure String::operator< works, too, since it is related to // StringOffsetCompare. TEST_EQ((*a[0]) < (*a[1]), true); TEST_EQ((*a[1]) < (*a[0]), false); TEST_EQ((*a[1]) < (*a[2]), false); TEST_EQ((*a[2]) < (*a[1]), true); TEST_EQ((*a[4]) < (*a[3]), true); TEST_EQ((*a[5]) < (*a[4]), false); TEST_EQ((*a[5]) < (*a[4]), false); TEST_EQ((*a[6]) < (*a[5]), true); } #if !defined(FLATBUFFERS_SPAN_MINIMAL) void FlatbuffersSpanTest() { // Compile-time checking of non-const [] to const [] conversions. using flatbuffers::internal::is_span_convertable; (void)is_span_convertable::type(123); (void)is_span_convertable::type(123); (void)is_span_convertable::type(123); (void)is_span_convertable::type(123); (void)is_span_convertable::type(123); (void)is_span_convertable::type(123); (void)is_span_convertable::type(123); using flatbuffers::span; span c1; TEST_EQ(c1.size(), 0); span c2; TEST_EQ(c2.size(), 0); span c3; TEST_EQ(c3.size(), 0); TEST_ASSERT(c1.empty() && c2.empty() && c3.empty()); int i_data7[7] = { 0, 1, 2, 3, 4, 5, 6 }; span i1(&i_data7[0], 7); span i2(i1); // make dynamic from static TEST_EQ(i1.size(), 7); TEST_EQ(i1.empty(), false); TEST_EQ(i1.size(), i2.size()); TEST_EQ(i1.data(), i_data7); TEST_EQ(i1[2], 2); // Make const span from a non-const one. span i3(i1); // Construct from a C-array. span i4(i_data7); span i5(i_data7); span i6(i_data7); span i7(i_data7); TEST_EQ(i7.size(), 7); // Check construction from a const array. const int i_cdata5[5] = { 4, 3, 2, 1, 0 }; span i8(i_cdata5); span i9(i_cdata5); TEST_EQ(i9.size(), 5); // Construction from a (ptr, size) pair. span i10(i_data7, 7); span i11(i_data7, 7); TEST_EQ(i11.size(), 7); span i12(i_cdata5, 5); span i13(i_cdata5, 5); TEST_EQ(i13.size(), 5); // Construction from std::array. std::array i_arr6 = { { 0, 1, 2, 3, 4, 5 } }; span i14(i_arr6); span i15(i_arr6); span i16(i_arr6); span i17(i_arr6); TEST_EQ(i17.size(), 6); const std::array i_carr8 = { { 0, 1, 2, 3, 4, 5, 6, 7 } }; span i18(i_carr8); span i19(i_carr8); TEST_EQ(i18.size(), 8); TEST_EQ(i19.size(), 8); TEST_EQ(i19[7], 7); // Check compatibility with flatbuffers::Array. int fbs_int3_underlaying[3] = { 0 }; int fbs_int3_data[3] = { 1, 2, 3 }; auto &fbs_int3 = flatbuffers::CastToArray(fbs_int3_underlaying); fbs_int3.CopyFromSpan(fbs_int3_data); TEST_EQ(fbs_int3.Get(1), 2); const int fbs_cint3_data[3] = { 2, 3, 4 }; fbs_int3.CopyFromSpan(fbs_cint3_data); TEST_EQ(fbs_int3.Get(1), 3); // Check with Array enum class Dummy : uint16_t { Zero = 0, One, Two }; Dummy fbs_dummy3_underlaying[3] = {}; Dummy fbs_dummy3_data[3] = { Dummy::One, Dummy::Two, Dummy::Two }; auto &fbs_dummy3 = flatbuffers::CastToArray(fbs_dummy3_underlaying); fbs_dummy3.CopyFromSpan(fbs_dummy3_data); TEST_EQ(fbs_dummy3.Get(1), Dummy::Two); } #else void FlatbuffersSpanTest() {} #endif void FixedLengthArrayTest() { // VS10 does not support typed enums, exclude from tests #if !defined(_MSC_VER) || _MSC_VER >= 1700 // Generate an ArrayTable containing one ArrayStruct. flatbuffers::FlatBufferBuilder fbb; MyGame::Example::NestedStruct nStruct0(MyGame::Example::TestEnum::B); TEST_NOTNULL(nStruct0.mutable_a()); nStruct0.mutable_a()->Mutate(0, 1); nStruct0.mutable_a()->Mutate(1, 2); TEST_NOTNULL(nStruct0.mutable_c()); nStruct0.mutable_c()->Mutate(0, MyGame::Example::TestEnum::C); nStruct0.mutable_c()->Mutate(1, MyGame::Example::TestEnum::A); TEST_NOTNULL(nStruct0.mutable_d()); nStruct0.mutable_d()->Mutate(0, flatbuffers::numeric_limits::max()); nStruct0.mutable_d()->Mutate(1, flatbuffers::numeric_limits::min()); MyGame::Example::NestedStruct nStruct1(MyGame::Example::TestEnum::C); TEST_NOTNULL(nStruct1.mutable_a()); nStruct1.mutable_a()->Mutate(0, 3); nStruct1.mutable_a()->Mutate(1, 4); TEST_NOTNULL(nStruct1.mutable_c()); nStruct1.mutable_c()->Mutate(0, MyGame::Example::TestEnum::C); nStruct1.mutable_c()->Mutate(1, MyGame::Example::TestEnum::A); TEST_NOTNULL(nStruct1.mutable_d()); nStruct1.mutable_d()->Mutate(0, flatbuffers::numeric_limits::min()); nStruct1.mutable_d()->Mutate(1, flatbuffers::numeric_limits::max()); MyGame::Example::ArrayStruct aStruct(2, 12, 1); TEST_NOTNULL(aStruct.b()); TEST_NOTNULL(aStruct.mutable_b()); TEST_NOTNULL(aStruct.mutable_d()); TEST_NOTNULL(aStruct.mutable_f()); for (int i = 0; i < aStruct.b()->size(); i++) aStruct.mutable_b()->Mutate(i, i + 1); aStruct.mutable_d()->Mutate(0, nStruct0); aStruct.mutable_d()->Mutate(1, nStruct1); auto aTable = MyGame::Example::CreateArrayTable(fbb, &aStruct); MyGame::Example::FinishArrayTableBuffer(fbb, aTable); // Verify correctness of the ArrayTable. flatbuffers::Verifier verifier(fbb.GetBufferPointer(), fbb.GetSize()); MyGame::Example::VerifyArrayTableBuffer(verifier); auto p = MyGame::Example::GetMutableArrayTable(fbb.GetBufferPointer()); auto mArStruct = p->mutable_a(); TEST_NOTNULL(mArStruct); TEST_NOTNULL(mArStruct->b()); TEST_NOTNULL(mArStruct->d()); TEST_NOTNULL(mArStruct->f()); TEST_NOTNULL(mArStruct->mutable_b()); TEST_NOTNULL(mArStruct->mutable_d()); TEST_NOTNULL(mArStruct->mutable_f()); mArStruct->mutable_b()->Mutate(14, -14); TEST_EQ(mArStruct->a(), 2); TEST_EQ(mArStruct->b()->size(), 15); TEST_EQ(mArStruct->b()->Get(aStruct.b()->size() - 1), -14); TEST_EQ(mArStruct->c(), 12); TEST_NOTNULL(mArStruct->d()->Get(0)); TEST_NOTNULL(mArStruct->d()->Get(0)->a()); TEST_EQ(mArStruct->d()->Get(0)->a()->Get(0), 1); TEST_EQ(mArStruct->d()->Get(0)->a()->Get(1), 2); TEST_NOTNULL(mArStruct->d()->Get(1)); TEST_NOTNULL(mArStruct->d()->Get(1)->a()); TEST_EQ(mArStruct->d()->Get(1)->a()->Get(0), 3); TEST_EQ(mArStruct->d()->Get(1)->a()->Get(1), 4); TEST_NOTNULL(mArStruct->mutable_d()->GetMutablePointer(1)); TEST_NOTNULL(mArStruct->mutable_d()->GetMutablePointer(1)->mutable_a()); mArStruct->mutable_d()->GetMutablePointer(1)->mutable_a()->Mutate(1, 5); TEST_EQ(5, mArStruct->d()->Get(1)->a()->Get(1)); TEST_EQ(MyGame::Example::TestEnum::B, mArStruct->d()->Get(0)->b()); TEST_NOTNULL(mArStruct->d()->Get(0)->c()); TEST_EQ(MyGame::Example::TestEnum::C, mArStruct->d()->Get(0)->c()->Get(0)); TEST_EQ(MyGame::Example::TestEnum::A, mArStruct->d()->Get(0)->c()->Get(1)); TEST_EQ(flatbuffers::numeric_limits::max(), mArStruct->d()->Get(0)->d()->Get(0)); TEST_EQ(flatbuffers::numeric_limits::min(), mArStruct->d()->Get(0)->d()->Get(1)); TEST_EQ(MyGame::Example::TestEnum::C, mArStruct->d()->Get(1)->b()); TEST_NOTNULL(mArStruct->d()->Get(1)->c()); TEST_EQ(MyGame::Example::TestEnum::C, mArStruct->d()->Get(1)->c()->Get(0)); TEST_EQ(MyGame::Example::TestEnum::A, mArStruct->d()->Get(1)->c()->Get(1)); TEST_EQ(flatbuffers::numeric_limits::min(), mArStruct->d()->Get(1)->d()->Get(0)); TEST_EQ(flatbuffers::numeric_limits::max(), mArStruct->d()->Get(1)->d()->Get(1)); for (int i = 0; i < mArStruct->b()->size() - 1; i++) TEST_EQ(mArStruct->b()->Get(i), i + 1); // Check alignment TEST_EQ(0, reinterpret_cast(mArStruct->d()) % 8); TEST_EQ(0, reinterpret_cast(mArStruct->f()) % 8); // Check if default constructor set all memory zero const size_t arr_size = sizeof(MyGame::Example::ArrayStruct); char non_zero_memory[arr_size]; // set memory chunk of size ArrayStruct to 1's std::memset(static_cast(non_zero_memory), 1, arr_size); // after placement-new it should be all 0's # if defined(_MSC_VER) && defined(_DEBUG) # undef new # endif MyGame::Example::ArrayStruct *ap = new (non_zero_memory) MyGame::Example::ArrayStruct; # if defined(_MSC_VER) && defined(_DEBUG) # define new DEBUG_NEW # endif (void)ap; for (size_t i = 0; i < arr_size; ++i) { TEST_EQ(non_zero_memory[i], 0); } #endif } #if !defined(FLATBUFFERS_SPAN_MINIMAL) && \ (!defined(_MSC_VER) || _MSC_VER >= 1700) void FixedLengthArrayConstructorTest() { const int32_t nested_a[2] = { 1, 2 }; MyGame::Example::TestEnum nested_c[2] = { MyGame::Example::TestEnum::A, MyGame::Example::TestEnum::B }; const int64_t int64_2[2] = { -2, -1 }; std::array init_d = { { MyGame::Example::NestedStruct(nested_a, MyGame::Example::TestEnum::B, nested_c, int64_2), MyGame::Example::NestedStruct(nested_a, MyGame::Example::TestEnum::A, nested_c, std::array{ { 12, 13 } }) } }; MyGame::Example::ArrayStruct arr_struct( 8.125, std::array{ { 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15 } }, -17, init_d, 10, int64_2); TEST_EQ(arr_struct.a(), 8.125); TEST_EQ(arr_struct.b()->Get(2), 3); TEST_EQ(arr_struct.c(), -17); TEST_NOTNULL(arr_struct.d()); const auto &arr_d_0 = *arr_struct.d()->Get(0); TEST_EQ(arr_d_0.a()->Get(0), 1); TEST_EQ(arr_d_0.a()->Get(1), 2); TEST_EQ(arr_d_0.b(), MyGame::Example::TestEnum::B); TEST_EQ(arr_d_0.c()->Get(0), MyGame::Example::TestEnum::A); TEST_EQ(arr_d_0.c()->Get(1), MyGame::Example::TestEnum::B); TEST_EQ(arr_d_0.d()->Get(0), -2); TEST_EQ(arr_d_0.d()->Get(1), -1); const auto &arr_d_1 = *arr_struct.d()->Get(1); TEST_EQ(arr_d_1.a()->Get(0), 1); TEST_EQ(arr_d_1.a()->Get(1), 2); TEST_EQ(arr_d_1.b(), MyGame::Example::TestEnum::A); TEST_EQ(arr_d_1.c()->Get(0), MyGame::Example::TestEnum::A); TEST_EQ(arr_d_1.c()->Get(1), MyGame::Example::TestEnum::B); TEST_EQ(arr_d_1.d()->Get(0), 12); TEST_EQ(arr_d_1.d()->Get(1), 13); TEST_EQ(arr_struct.e(), 10); TEST_EQ(arr_struct.f()->Get(0), -2); TEST_EQ(arr_struct.f()->Get(1), -1); } #else void FixedLengthArrayConstructorTest() {} #endif void NativeTypeTest() { const int N = 3; Geometry::ApplicationDataT src_data; src_data.vectors.reserve(N); src_data.vectors_alt.reserve(N); for (int i = 0; i < N; ++i) { src_data.vectors.push_back( Native::Vector3D(10 * i + 0.1f, 10 * i + 0.2f, 10 * i + 0.3f)); src_data.vectors_alt.push_back( Native::Vector3D(20 * i + 0.1f, 20 * i + 0.2f, 20 * i + 0.3f)); } flatbuffers::FlatBufferBuilder fbb; fbb.Finish(Geometry::ApplicationData::Pack(fbb, &src_data)); auto dstDataT = Geometry::UnPackApplicationData(fbb.GetBufferPointer()); for (int i = 0; i < N; ++i) { const Native::Vector3D &v = dstDataT->vectors[i]; TEST_EQ(v.x, 10 * i + 0.1f); TEST_EQ(v.y, 10 * i + 0.2f); TEST_EQ(v.z, 10 * i + 0.3f); const Native::Vector3D &v2 = dstDataT->vectors_alt[i]; TEST_EQ(v2.x, 20 * i + 0.1f); TEST_EQ(v2.y, 20 * i + 0.2f); TEST_EQ(v2.z, 20 * i + 0.3f); } } void FixedLengthArrayJsonTest(bool binary) { // VS10 does not support typed enums, exclude from tests #if !defined(_MSC_VER) || _MSC_VER >= 1700 // load FlatBuffer schema (.fbs) and JSON from disk std::string schemafile; std::string jsonfile; TEST_EQ( flatbuffers::LoadFile( (test_data_path + "arrays_test." + (binary ? "bfbs" : "fbs")).c_str(), binary, &schemafile), true); TEST_EQ(flatbuffers::LoadFile((test_data_path + "arrays_test.golden").c_str(), false, &jsonfile), true); // parse schema first, so we can use it to parse the data after flatbuffers::Parser parserOrg, parserGen; if (binary) { flatbuffers::Verifier verifier( reinterpret_cast(schemafile.c_str()), schemafile.size()); TEST_EQ(reflection::VerifySchemaBuffer(verifier), true); TEST_EQ(parserOrg.Deserialize((const uint8_t *)schemafile.c_str(), schemafile.size()), true); TEST_EQ(parserGen.Deserialize((const uint8_t *)schemafile.c_str(), schemafile.size()), true); } else { TEST_EQ(parserOrg.Parse(schemafile.c_str()), true); TEST_EQ(parserGen.Parse(schemafile.c_str()), true); } TEST_EQ(parserOrg.Parse(jsonfile.c_str()), true); // First, verify it, just in case: flatbuffers::Verifier verifierOrg(parserOrg.builder_.GetBufferPointer(), parserOrg.builder_.GetSize()); TEST_EQ(VerifyArrayTableBuffer(verifierOrg), true); // Export to JSON std::string jsonGen; TEST_EQ( GenerateText(parserOrg, parserOrg.builder_.GetBufferPointer(), &jsonGen), true); // Import from JSON TEST_EQ(parserGen.Parse(jsonGen.c_str()), true); // Verify buffer from generated JSON flatbuffers::Verifier verifierGen(parserGen.builder_.GetBufferPointer(), parserGen.builder_.GetSize()); TEST_EQ(VerifyArrayTableBuffer(verifierGen), true); // Compare generated buffer to original TEST_EQ(parserOrg.builder_.GetSize(), parserGen.builder_.GetSize()); TEST_EQ(std::memcmp(parserOrg.builder_.GetBufferPointer(), parserGen.builder_.GetBufferPointer(), parserOrg.builder_.GetSize()), 0); #else (void)binary; #endif } void TestEmbeddedBinarySchema() { // load JSON from disk std::string jsonfile; TEST_EQ(flatbuffers::LoadFile( (test_data_path + "monsterdata_test.golden").c_str(), false, &jsonfile), true); // parse schema first, so we can use it to parse the data after flatbuffers::Parser parserOrg, parserGen; flatbuffers::Verifier verifier(MyGame::Example::MonsterBinarySchema::data(), MyGame::Example::MonsterBinarySchema::size()); TEST_EQ(reflection::VerifySchemaBuffer(verifier), true); TEST_EQ(parserOrg.Deserialize(MyGame::Example::MonsterBinarySchema::data(), MyGame::Example::MonsterBinarySchema::size()), true); TEST_EQ(parserGen.Deserialize(MyGame::Example::MonsterBinarySchema::data(), MyGame::Example::MonsterBinarySchema::size()), true); TEST_EQ(parserOrg.Parse(jsonfile.c_str()), true); // First, verify it, just in case: flatbuffers::Verifier verifierOrg(parserOrg.builder_.GetBufferPointer(), parserOrg.builder_.GetSize()); TEST_EQ(VerifyMonsterBuffer(verifierOrg), true); // Export to JSON std::string jsonGen; TEST_EQ( GenerateText(parserOrg, parserOrg.builder_.GetBufferPointer(), &jsonGen), true); // Import from JSON TEST_EQ(parserGen.Parse(jsonGen.c_str()), true); // Verify buffer from generated JSON flatbuffers::Verifier verifierGen(parserGen.builder_.GetBufferPointer(), parserGen.builder_.GetSize()); TEST_EQ(VerifyMonsterBuffer(verifierGen), true); // Compare generated buffer to original TEST_EQ(parserOrg.builder_.GetSize(), parserGen.builder_.GetSize()); TEST_EQ(std::memcmp(parserOrg.builder_.GetBufferPointer(), parserGen.builder_.GetBufferPointer(), parserOrg.builder_.GetSize()), 0); } void StringVectorDefaultsTest() { std::vector schemas; schemas.push_back("table Monster { mana: string = \"\"; }"); schemas.push_back("table Monster { mana: string = \"mystr\"; }"); schemas.push_back("table Monster { mana: string = \" \"; }"); schemas.push_back("table Monster { mana: [int] = []; }"); schemas.push_back("table Monster { mana: [uint] = [ ]; }"); schemas.push_back("table Monster { mana: [byte] = [\t\t\n]; }"); schemas.push_back("enum E:int{}table Monster{mana:[E]=[];}"); for (auto s = schemas.begin(); s < schemas.end(); s++) { flatbuffers::Parser parser; TEST_ASSERT(parser.Parse(s->c_str())); const auto *mana = parser.structs_.Lookup("Monster")->fields.Lookup("mana"); TEST_EQ(mana->IsDefault(), true); } } void OptionalScalarsTest() { // Simple schemas and a "has optional scalar" sentinal. std::vector schemas; schemas.push_back("table Monster { mana : int; }"); schemas.push_back("table Monster { mana : int = 42; }"); schemas.push_back("table Monster { mana : int = null; }"); schemas.push_back("table Monster { mana : long; }"); schemas.push_back("table Monster { mana : long = 42; }"); schemas.push_back("table Monster { mana : long = null; }"); schemas.push_back("table Monster { mana : float; }"); schemas.push_back("table Monster { mana : float = 42; }"); schemas.push_back("table Monster { mana : float = null; }"); schemas.push_back("table Monster { mana : double; }"); schemas.push_back("table Monster { mana : double = 42; }"); schemas.push_back("table Monster { mana : double = null; }"); schemas.push_back("table Monster { mana : bool; }"); schemas.push_back("table Monster { mana : bool = 42; }"); schemas.push_back("table Monster { mana : bool = null; }"); schemas.push_back( "enum Enum: int {A=0, B=1} " "table Monster { mana : Enum; }"); schemas.push_back( "enum Enum: int {A=0, B=1} " "table Monster { mana : Enum = B; }"); schemas.push_back( "enum Enum: int {A=0, B=1} " "table Monster { mana : Enum = null; }"); // Check the FieldDef is correctly set. for (auto schema = schemas.begin(); schema < schemas.end(); schema++) { const bool has_null = schema->find("null") != std::string::npos; flatbuffers::Parser parser; TEST_ASSERT(parser.Parse(schema->c_str())); const auto *mana = parser.structs_.Lookup("Monster")->fields.Lookup("mana"); TEST_EQ(mana->IsOptional(), has_null); } // Test if nullable scalars are allowed for each language. for (unsigned lang = 1; lang < flatbuffers::IDLOptions::kMAX; lang <<= 1) { flatbuffers::IDLOptions opts; opts.lang_to_generate = lang; if (false == flatbuffers::Parser::SupportsOptionalScalars(opts)) { continue; } for (auto schema = schemas.begin(); schema < schemas.end(); schema++) { flatbuffers::Parser parser(opts); auto done = parser.Parse(schema->c_str()); TEST_EQ_STR(parser.error_.c_str(), ""); TEST_ASSERT(done); } } // test C++ nullable flatbuffers::FlatBufferBuilder fbb; FinishScalarStuffBuffer( fbb, optional_scalars::CreateScalarStuff(fbb, 1, static_cast(2))); auto opts = optional_scalars::GetMutableScalarStuff(fbb.GetBufferPointer()); TEST_ASSERT(!opts->maybe_bool()); TEST_ASSERT(!opts->maybe_f32().has_value()); TEST_ASSERT(opts->maybe_i8().has_value()); TEST_EQ(opts->maybe_i8().value(), 2); TEST_ASSERT(opts->mutate_maybe_i8(3)); TEST_ASSERT(opts->maybe_i8().has_value()); TEST_EQ(opts->maybe_i8().value(), 3); TEST_ASSERT(!opts->mutate_maybe_i16(-10)); optional_scalars::ScalarStuffT obj; TEST_ASSERT(!obj.maybe_bool); TEST_ASSERT(!obj.maybe_f32.has_value()); opts->UnPackTo(&obj); TEST_ASSERT(!obj.maybe_bool); TEST_ASSERT(!obj.maybe_f32.has_value()); TEST_ASSERT(obj.maybe_i8.has_value() && obj.maybe_i8.value() == 3); TEST_ASSERT(obj.maybe_i8 && *obj.maybe_i8 == 3); obj.maybe_i32 = -1; obj.maybe_enum = optional_scalars::OptionalByte_Two; fbb.Clear(); FinishScalarStuffBuffer(fbb, optional_scalars::ScalarStuff::Pack(fbb, &obj)); opts = optional_scalars::GetMutableScalarStuff(fbb.GetBufferPointer()); TEST_ASSERT(opts->maybe_i8().has_value()); TEST_EQ(opts->maybe_i8().value(), 3); TEST_ASSERT(opts->maybe_i32().has_value()); TEST_EQ(opts->maybe_i32().value(), -1); TEST_EQ(opts->maybe_enum().value(), optional_scalars::OptionalByte_Two); TEST_ASSERT(opts->maybe_i32() == flatbuffers::Optional(-1)); } void ParseFlexbuffersFromJsonWithNullTest() { // Test nulls are handled appropriately through flexbuffers to exercise other // code paths of ParseSingleValue in the optional scalars change. // TODO(cneo): Json -> Flatbuffers test once some language can generate code // with optional scalars. { char json[] = "{\"opt_field\": 123 }"; flatbuffers::Parser parser; flexbuffers::Builder flexbuild; parser.ParseFlexBuffer(json, nullptr, &flexbuild); auto root = flexbuffers::GetRoot(flexbuild.GetBuffer()); TEST_EQ(root.AsMap()["opt_field"].AsInt64(), 123); } { char json[] = "{\"opt_field\": 123.4 }"; flatbuffers::Parser parser; flexbuffers::Builder flexbuild; parser.ParseFlexBuffer(json, nullptr, &flexbuild); auto root = flexbuffers::GetRoot(flexbuild.GetBuffer()); TEST_EQ(root.AsMap()["opt_field"].AsDouble(), 123.4); } { char json[] = "{\"opt_field\": null }"; flatbuffers::Parser parser; flexbuffers::Builder flexbuild; parser.ParseFlexBuffer(json, nullptr, &flexbuild); auto root = flexbuffers::GetRoot(flexbuild.GetBuffer()); TEST_ASSERT(!root.AsMap().IsTheEmptyMap()); TEST_ASSERT(root.AsMap()["opt_field"].IsNull()); TEST_EQ(root.ToString(), std::string("{ opt_field: null }")); } } void FieldIdentifierTest() { using flatbuffers::Parser; TEST_EQ(true, Parser().Parse("table T{ f: int (id:0); }")); // non-integer `id` should be rejected TEST_EQ(false, Parser().Parse("table T{ f: int (id:text); }")); TEST_EQ(false, Parser().Parse("table T{ f: int (id:\"text\"); }")); TEST_EQ(false, Parser().Parse("table T{ f: int (id:0text); }")); TEST_EQ(false, Parser().Parse("table T{ f: int (id:1.0); }")); TEST_EQ(false, Parser().Parse("table T{ f: int (id:-1); g: int (id:0); }")); TEST_EQ(false, Parser().Parse("table T{ f: int (id:129496726); }")); // A unuion filed occupys two ids: enumerator + pointer (offset). TEST_EQ(false, Parser().Parse("union X{} table T{ u: X(id:0); table F{x:int;\n}")); // Positive tests for unions TEST_EQ(true, Parser().Parse("union X{} table T{ u: X (id:1); }")); TEST_EQ(true, Parser().Parse("union X{} table T{ u: X; }")); // Test using 'inf' and 'nan' words both as identifiers and as default values. TEST_EQ(true, Parser().Parse("table T{ nan: string; }")); TEST_EQ(true, Parser().Parse("table T{ inf: string; }")); #if defined(FLATBUFFERS_HAS_NEW_STRTOD) && (FLATBUFFERS_HAS_NEW_STRTOD > 0) TEST_EQ(true, Parser().Parse("table T{ inf: float = inf; }")); TEST_EQ(true, Parser().Parse("table T{ nan: float = inf; }")); #endif } void ParseIncorrectMonsterJsonTest() { std::string schemafile; TEST_EQ(flatbuffers::LoadFile((test_data_path + "monster_test.bfbs").c_str(), true, &schemafile), true); flatbuffers::Parser parser; flatbuffers::Verifier verifier( reinterpret_cast(schemafile.c_str()), schemafile.size()); TEST_EQ(reflection::VerifySchemaBuffer(verifier), true); TEST_EQ(parser.Deserialize((const uint8_t *)schemafile.c_str(), schemafile.size()), true); TEST_EQ(parser.ParseJson("{name:\"monster\"}"), true); TEST_EQ(parser.ParseJson(""), false); TEST_EQ(parser.ParseJson("{name: 1}"), false); TEST_EQ(parser.ParseJson("{name:+1}"), false); TEST_EQ(parser.ParseJson("{name:-1}"), false); TEST_EQ(parser.ParseJson("{name:-f}"), false); TEST_EQ(parser.ParseJson("{name:+f}"), false); } int FlatBufferTests() { // clang-format off // Run our various test suites: std::string rawbuf; auto flatbuf1 = CreateFlatBufferTest(rawbuf); #if !defined(FLATBUFFERS_CPP98_STL) auto flatbuf = std::move(flatbuf1); // Test move assignment. #else auto &flatbuf = flatbuf1; #endif // !defined(FLATBUFFERS_CPP98_STL) TriviallyCopyableTest(); AccessFlatBufferTest(reinterpret_cast(rawbuf.c_str()), rawbuf.length()); AccessFlatBufferTest(flatbuf.data(), flatbuf.size()); MutateFlatBuffersTest(flatbuf.data(), flatbuf.size()); ObjectFlatBuffersTest(flatbuf.data()); MiniReflectFlatBuffersTest(flatbuf.data()); MiniReflectFixedLengthArrayTest(); SizePrefixedTest(); #ifndef FLATBUFFERS_NO_FILE_TESTS #ifdef FLATBUFFERS_TEST_PATH_PREFIX test_data_path = FLATBUFFERS_STRING(FLATBUFFERS_TEST_PATH_PREFIX) + test_data_path; #endif ParseAndGenerateTextTest(false); ParseAndGenerateTextTest(true); FixedLengthArrayJsonTest(false); FixedLengthArrayJsonTest(true); ReflectionTest(flatbuf.data(), flatbuf.size()); ParseProtoTest(); ParseProtoTestWithSuffix(); ParseProtoTestWithIncludes(); EvolutionTest(); UnionDeprecationTest(); UnionVectorTest(); LoadVerifyBinaryTest(); GenerateTableTextTest(); TestEmbeddedBinarySchema(); #endif // clang-format on FuzzTest1(); FuzzTest2(); ErrorTest(); ValueTest(); EnumValueTest(); EnumStringsTest(); EnumNamesTest(); EnumOutOfRangeTest(); IntegerOutOfRangeTest(); IntegerBoundaryTest(); UnicodeTest(); UnicodeTestAllowNonUTF8(); UnicodeTestGenerateTextFailsOnNonUTF8(); UnicodeSurrogatesTest(); UnicodeInvalidSurrogatesTest(); InvalidUTF8Test(); UnknownFieldsTest(); ParseUnionTest(); InvalidNestedFlatbufferTest(); ConformTest(); ParseProtoBufAsciiTest(); TypeAliasesTest(); EndianSwapTest(); CreateSharedStringTest(); JsonDefaultTest(); JsonEnumsTest(); FlexBuffersTest(); FlexBuffersDeprecatedTest(); UninitializedVectorTest(); EqualOperatorTest(); NumericUtilsTest(); IsAsciiUtilsTest(); ValidFloatTest(); InvalidFloatTest(); TestMonsterExtraFloats(); FixedLengthArrayTest(); NativeTypeTest(); OptionalScalarsTest(); ParseFlexbuffersFromJsonWithNullTest(); FlatbuffersSpanTest(); FixedLengthArrayConstructorTest(); FieldIdentifierTest(); StringVectorDefaultsTest(); ParseIncorrectMonsterJsonTest(); FlexBuffersFloatingPointTest(); return 0; } int main(int /*argc*/, const char * /*argv*/[]) { InitTestEngine(); std::string req_locale; if (flatbuffers::ReadEnvironmentVariable("FLATBUFFERS_TEST_LOCALE", &req_locale)) { TEST_OUTPUT_LINE("The environment variable FLATBUFFERS_TEST_LOCALE=%s", req_locale.c_str()); req_locale = flatbuffers::RemoveStringQuotes(req_locale); std::string the_locale; TEST_ASSERT_FUNC( flatbuffers::SetGlobalTestLocale(req_locale.c_str(), &the_locale)); TEST_OUTPUT_LINE("The global C-locale changed: %s", the_locale.c_str()); } FlatBufferTests(); FlatBufferBuilderTest(); if (!testing_fails) { TEST_OUTPUT_LINE("ALL TESTS PASSED"); } else { TEST_OUTPUT_LINE("%d FAILED TESTS", testing_fails); } return CloseTestEngine(); }