// Copyright (c) 2016 Google Inc. // // 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 #include #include "gmock/gmock.h" #include "gtest/gtest.h" #include "spirv-tools/optimizer.hpp" #include "spirv/1.1/spirv.h" namespace spvtools { namespace { using ::testing::ContainerEq; using ::testing::HasSubstr; // Return a string that contains the minimum instructions needed to form // a valid module. Other instructions can be appended to this string. std::string Header() { return R"(OpCapability Shader OpCapability Linkage OpMemoryModel Logical GLSL450 )"; } // When we assemble with a target environment of SPIR-V 1.1, we expect // the following in the module header version word. const uint32_t kExpectedSpvVersion = 0x10100; TEST(CppInterface, SuccessfulRoundTrip) { const std::string input_text = "%2 = OpSizeOf %1 %3\n"; SpirvTools t(SPV_ENV_UNIVERSAL_1_1); std::vector binary; EXPECT_TRUE(t.Assemble(input_text, &binary)); EXPECT_TRUE(binary.size() > 5u); EXPECT_EQ(SpvMagicNumber, binary[0]); EXPECT_EQ(kExpectedSpvVersion, binary[1]); // This cannot pass validation since %1 is not defined. t.SetMessageConsumer([](spv_message_level_t level, const char* source, const spv_position_t& position, const char* message) { EXPECT_EQ(SPV_MSG_ERROR, level); EXPECT_STREQ("input", source); EXPECT_EQ(0u, position.line); EXPECT_EQ(0u, position.column); EXPECT_EQ(1u, position.index); EXPECT_STREQ("ID 1[%1] has not been defined\n %2 = OpSizeOf %1 %3\n", message); }); EXPECT_FALSE(t.Validate(binary)); std::string output_text; EXPECT_TRUE(t.Disassemble(binary, &output_text)); EXPECT_EQ(input_text, output_text); } TEST(CppInterface, AssembleEmptyModule) { std::vector binary(10, 42); SpirvTools t(SPV_ENV_UNIVERSAL_1_1); EXPECT_TRUE(t.Assemble("", &binary)); // We only have the header. EXPECT_EQ(5u, binary.size()); EXPECT_EQ(SpvMagicNumber, binary[0]); EXPECT_EQ(kExpectedSpvVersion, binary[1]); } TEST(CppInterface, AssembleOverloads) { const std::string input_text = "%2 = OpSizeOf %1 %3\n"; SpirvTools t(SPV_ENV_UNIVERSAL_1_1); { std::vector binary; EXPECT_TRUE(t.Assemble(input_text, &binary)); EXPECT_TRUE(binary.size() > 5u); EXPECT_EQ(SpvMagicNumber, binary[0]); EXPECT_EQ(kExpectedSpvVersion, binary[1]); } { std::vector binary; EXPECT_TRUE(t.Assemble(input_text.data(), input_text.size(), &binary)); EXPECT_TRUE(binary.size() > 5u); EXPECT_EQ(SpvMagicNumber, binary[0]); EXPECT_EQ(kExpectedSpvVersion, binary[1]); } { // Ignore the last newline. std::vector binary; EXPECT_TRUE(t.Assemble(input_text.data(), input_text.size() - 1, &binary)); EXPECT_TRUE(binary.size() > 5u); EXPECT_EQ(SpvMagicNumber, binary[0]); EXPECT_EQ(kExpectedSpvVersion, binary[1]); } } TEST(CppInterface, DisassembleEmptyModule) { std::string text(10, 'x'); SpirvTools t(SPV_ENV_UNIVERSAL_1_1); int invocation_count = 0; t.SetMessageConsumer( [&invocation_count](spv_message_level_t level, const char* source, const spv_position_t& position, const char* message) { ++invocation_count; EXPECT_EQ(SPV_MSG_ERROR, level); EXPECT_STREQ("input", source); EXPECT_EQ(0u, position.line); EXPECT_EQ(0u, position.column); EXPECT_EQ(0u, position.index); EXPECT_STREQ("Missing module.", message); }); EXPECT_FALSE(t.Disassemble({}, &text)); EXPECT_EQ("xxxxxxxxxx", text); // The original string is unmodified. EXPECT_EQ(1, invocation_count); } TEST(CppInterface, DisassembleOverloads) { const std::string input_text = "%2 = OpSizeOf %1 %3\n"; SpirvTools t(SPV_ENV_UNIVERSAL_1_1); std::vector binary; EXPECT_TRUE(t.Assemble(input_text, &binary)); { std::string output_text; EXPECT_TRUE(t.Disassemble(binary, &output_text)); EXPECT_EQ(input_text, output_text); } { std::string output_text; EXPECT_TRUE(t.Disassemble(binary.data(), binary.size(), &output_text)); EXPECT_EQ(input_text, output_text); } } TEST(CppInterface, SuccessfulValidation) { SpirvTools t(SPV_ENV_UNIVERSAL_1_1); int invocation_count = 0; t.SetMessageConsumer([&invocation_count](spv_message_level_t, const char*, const spv_position_t&, const char*) { ++invocation_count; }); std::vector binary; EXPECT_TRUE(t.Assemble(Header(), &binary)); EXPECT_TRUE(t.Validate(binary)); EXPECT_EQ(0, invocation_count); } TEST(CppInterface, ValidateOverloads) { SpirvTools t(SPV_ENV_UNIVERSAL_1_1); std::vector binary; EXPECT_TRUE(t.Assemble(Header(), &binary)); { EXPECT_TRUE(t.Validate(binary)); } { EXPECT_TRUE(t.Validate(binary.data(), binary.size())); } } TEST(CppInterface, ValidateEmptyModule) { SpirvTools t(SPV_ENV_UNIVERSAL_1_1); int invocation_count = 0; t.SetMessageConsumer( [&invocation_count](spv_message_level_t level, const char* source, const spv_position_t& position, const char* message) { ++invocation_count; EXPECT_EQ(SPV_MSG_ERROR, level); EXPECT_STREQ("input", source); EXPECT_EQ(0u, position.line); EXPECT_EQ(0u, position.column); EXPECT_EQ(0u, position.index); EXPECT_STREQ("Invalid SPIR-V magic number.", message); }); EXPECT_FALSE(t.Validate({})); EXPECT_EQ(1, invocation_count); } // Returns the assembly for a SPIR-V module with a struct declaration // with the given number of members. std::string MakeModuleHavingStruct(int num_members) { std::stringstream os; os << Header(); os << R"(%1 = OpTypeInt 32 0 %2 = OpTypeStruct)"; for (int i = 0; i < num_members; i++) os << " %1"; return os.str(); } TEST(CppInterface, ValidateWithOptionsPass) { SpirvTools t(SPV_ENV_UNIVERSAL_1_1); std::vector binary; EXPECT_TRUE(t.Assemble(MakeModuleHavingStruct(10), &binary)); const ValidatorOptions opts; EXPECT_TRUE(t.Validate(binary.data(), binary.size(), opts)); } TEST(CppInterface, ValidateWithOptionsFail) { SpirvTools t(SPV_ENV_UNIVERSAL_1_1); std::vector binary; EXPECT_TRUE(t.Assemble(MakeModuleHavingStruct(10), &binary)); ValidatorOptions opts; opts.SetUniversalLimit(spv_validator_limit_max_struct_members, 9); std::stringstream os; t.SetMessageConsumer([&os](spv_message_level_t, const char*, const spv_position_t&, const char* message) { os << message; }); EXPECT_FALSE(t.Validate(binary.data(), binary.size(), opts)); EXPECT_THAT( os.str(), HasSubstr( "Number of OpTypeStruct members (10) has exceeded the limit (9)")); } // Checks that after running the given optimizer |opt| on the given |original| // source code, we can get the given |optimized| source code. void CheckOptimization(const std::string& original, const std::string& optimized, const Optimizer& opt) { SpirvTools t(SPV_ENV_UNIVERSAL_1_1); std::vector original_binary; ASSERT_TRUE(t.Assemble(original, &original_binary)); std::vector optimized_binary; EXPECT_TRUE(opt.Run(original_binary.data(), original_binary.size(), &optimized_binary)); std::string optimized_text; EXPECT_TRUE(t.Disassemble(optimized_binary, &optimized_text)); EXPECT_EQ(optimized, optimized_text); } TEST(CppInterface, OptimizeEmptyModule) { SpirvTools t(SPV_ENV_UNIVERSAL_1_1); std::vector binary; EXPECT_TRUE(t.Assemble("", &binary)); Optimizer o(SPV_ENV_UNIVERSAL_1_1); o.RegisterPass(CreateStripDebugInfoPass()); // Fails to validate. EXPECT_FALSE(o.Run(binary.data(), binary.size(), &binary)); } TEST(CppInterface, OptimizeModifiedModule) { Optimizer o(SPV_ENV_UNIVERSAL_1_1); o.RegisterPass(CreateStripDebugInfoPass()); CheckOptimization(Header() + "OpSource GLSL 450", Header(), o); } TEST(CppInterface, OptimizeMulitplePasses) { std::string original_text = Header() + "OpSource GLSL 450 " "OpDecorate %true SpecId 1 " "%bool = OpTypeBool " "%true = OpSpecConstantTrue %bool"; Optimizer o(SPV_ENV_UNIVERSAL_1_1); o.RegisterPass(CreateStripDebugInfoPass()) .RegisterPass(CreateFreezeSpecConstantValuePass()); std::string expected_text = Header() + "%bool = OpTypeBool\n" "%true = OpConstantTrue %bool\n"; CheckOptimization(original_text, expected_text, o); } TEST(CppInterface, OptimizeDoNothingWithPassToken) { CreateFreezeSpecConstantValuePass(); auto token = CreateUnifyConstantPass(); } TEST(CppInterface, OptimizeReassignPassToken) { auto token = CreateNullPass(); token = CreateStripDebugInfoPass(); CheckOptimization( Header() + "OpSource GLSL 450", Header(), Optimizer(SPV_ENV_UNIVERSAL_1_1).RegisterPass(std::move(token))); } TEST(CppInterface, OptimizeMoveConstructPassToken) { auto token1 = CreateStripDebugInfoPass(); Optimizer::PassToken token2(std::move(token1)); CheckOptimization( Header() + "OpSource GLSL 450", Header(), Optimizer(SPV_ENV_UNIVERSAL_1_1).RegisterPass(std::move(token2))); } TEST(CppInterface, OptimizeMoveAssignPassToken) { auto token1 = CreateStripDebugInfoPass(); auto token2 = CreateNullPass(); token2 = std::move(token1); CheckOptimization( Header() + "OpSource GLSL 450", Header(), Optimizer(SPV_ENV_UNIVERSAL_1_1).RegisterPass(std::move(token2))); } TEST(CppInterface, OptimizeSameAddressForOriginalOptimizedBinary) { SpirvTools t(SPV_ENV_UNIVERSAL_1_1); std::vector binary; ASSERT_TRUE(t.Assemble(Header() + "OpSource GLSL 450", &binary)); EXPECT_TRUE(Optimizer(SPV_ENV_UNIVERSAL_1_1) .RegisterPass(CreateStripDebugInfoPass()) .Run(binary.data(), binary.size(), &binary)); std::string optimized_text; EXPECT_TRUE(t.Disassemble(binary, &optimized_text)); EXPECT_EQ(Header(), optimized_text); } // TODO(antiagainst): tests for SetMessageConsumer(). } // namespace } // namespace spvtools