// Copyright 2020 The Tint Authors. // // 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 "gmock/gmock.h" #include "src/demangler.h" #include "src/reader/spirv/function.h" #include "src/reader/spirv/parser_impl.h" #include "src/reader/spirv/parser_impl_test_helper.h" #include "src/reader/spirv/spirv_tools_helpers_test.h" namespace tint { namespace reader { namespace spirv { namespace { using ::testing::Eq; using ::testing::HasSubstr; using ::testing::Not; using ::testing::StartsWith; std::string Preamble() { return R"( OpCapability Shader OpCapability Sampled1D OpCapability Image1D OpCapability StorageImageExtendedFormats OpMemoryModel Logical Simple )"; } std::string CommonBasicTypes() { return R"( %void = OpTypeVoid %voidfn = OpTypeFunction %void %float = OpTypeFloat 32 %uint = OpTypeInt 32 0 %int = OpTypeInt 32 1 %int_0 = OpConstant %int 0 %int_1 = OpConstant %int 1 %int_2 = OpConstant %int 2 %int_3 = OpConstant %int 3 %int_4 = OpConstant %int 4 %uint_0 = OpConstant %uint 0 %uint_1 = OpConstant %uint 1 %uint_2 = OpConstant %uint 2 %uint_3 = OpConstant %uint 3 %uint_4 = OpConstant %uint 4 %uint_100 = OpConstant %uint 100 %v2int = OpTypeVector %int 2 %v3int = OpTypeVector %int 3 %v4int = OpTypeVector %int 4 %v2uint = OpTypeVector %uint 2 %v3uint = OpTypeVector %uint 3 %v4uint = OpTypeVector %uint 4 %v2float = OpTypeVector %float 2 %v3float = OpTypeVector %float 3 %v4float = OpTypeVector %float 4 %float_null = OpConstantNull %float %float_1 = OpConstant %float 1 %float_2 = OpConstant %float 2 %float_3 = OpConstant %float 3 %float_4 = OpConstant %float 4 %float_7 = OpConstant %float 7 %v2float_null = OpConstantNull %v2float %v3float_null = OpConstantNull %v3float %v4float_null = OpConstantNull %v4float %the_vi12 = OpConstantComposite %v2int %int_1 %int_2 %the_vi123 = OpConstantComposite %v3int %int_1 %int_2 %int_3 %the_vi1234 = OpConstantComposite %v4int %int_1 %int_2 %int_3 %int_4 %the_vu12 = OpConstantComposite %v2uint %uint_1 %uint_2 %the_vu123 = OpConstantComposite %v3uint %uint_1 %uint_2 %uint_3 %the_vu1234 = OpConstantComposite %v4uint %uint_1 %uint_2 %uint_3 %uint_4 %the_vf12 = OpConstantComposite %v2float %float_1 %float_2 %the_vf123 = OpConstantComposite %v3float %float_1 %float_2 %float_3 %the_vf1234 = OpConstantComposite %v4float %float_1 %float_2 %float_3 %float_4 %depth = OpConstant %float 0.2 )"; } std::string CommonImageTypes() { return R"( ; Define types for all sampler and texture types that can map to WGSL, ; modulo texel formats for storage textures. For now, we limit ; ourselves to 2-channel 32-bit texel formats. ; Because the SPIR-V reader also already generalizes so it can work with ; combined image-samplers, we also test that too. %sampler = OpTypeSampler ; sampled images %f_texture_1d = OpTypeImage %float 1D 0 0 0 1 Unknown %f_texture_1d_array = OpTypeImage %float 1D 0 1 0 1 Unknown %f_texture_2d = OpTypeImage %float 2D 0 0 0 1 Unknown %f_texture_2d_ms = OpTypeImage %float 2D 0 0 1 1 Unknown %f_texture_2d_array = OpTypeImage %float 2D 0 1 0 1 Unknown %f_texture_2d_ms_array = OpTypeImage %float 2D 0 1 1 1 Unknown ; not in WebGPU %f_texture_3d = OpTypeImage %float 3D 0 0 0 1 Unknown %f_texture_cube = OpTypeImage %float Cube 0 0 0 1 Unknown %f_texture_cube_array = OpTypeImage %float Cube 0 1 0 1 Unknown ; storage images %f_storage_1d = OpTypeImage %float 1D 0 0 0 1 Rg32f %f_storage_1d_array = OpTypeImage %float 1D 0 1 0 1 Rg32f %f_storage_2d = OpTypeImage %float 2D 0 0 0 1 Rg32f %f_storage_2d_array = OpTypeImage %float 2D 0 1 0 1 Rg32f %f_storage_3d = OpTypeImage %float 3D 0 0 0 1 Rg32f ; Now all the same, but for unsigned integer sampled type. %u_texture_1d = OpTypeImage %uint 1D 0 0 0 1 Unknown %u_texture_1d_array = OpTypeImage %uint 1D 0 1 0 1 Unknown %u_texture_2d = OpTypeImage %uint 2D 0 0 0 1 Unknown %u_texture_2d_ms = OpTypeImage %uint 2D 0 0 1 1 Unknown %u_texture_2d_array = OpTypeImage %uint 2D 0 1 0 1 Unknown %u_texture_2d_ms_array = OpTypeImage %uint 2D 0 1 1 1 Unknown ; not in WebGPU %u_texture_3d = OpTypeImage %uint 3D 0 0 0 1 Unknown %u_texture_cube = OpTypeImage %uint Cube 0 0 0 1 Unknown %u_texture_cube_array = OpTypeImage %uint Cube 0 1 0 1 Unknown %u_storage_1d = OpTypeImage %uint 1D 0 0 0 1 Rg32ui %u_storage_1d_array = OpTypeImage %uint 1D 0 1 0 1 Rg32ui %u_storage_2d = OpTypeImage %uint 2D 0 0 0 1 Rg32ui %u_storage_2d_array = OpTypeImage %uint 2D 0 1 0 1 Rg32ui %u_storage_3d = OpTypeImage %uint 3D 0 0 0 1 Rg32ui ; Now all the same, but for signed integer sampled type. %i_texture_1d = OpTypeImage %int 1D 0 0 0 1 Unknown %i_texture_1d_array = OpTypeImage %int 1D 0 1 0 1 Unknown %i_texture_2d = OpTypeImage %int 2D 0 0 0 1 Unknown %i_texture_2d_ms = OpTypeImage %int 2D 0 0 1 1 Unknown %i_texture_2d_array = OpTypeImage %int 2D 0 1 0 1 Unknown %i_texture_2d_ms_array = OpTypeImage %int 2D 0 1 1 1 Unknown ; not in WebGPU %i_texture_3d = OpTypeImage %int 3D 0 0 0 1 Unknown %i_texture_cube = OpTypeImage %int Cube 0 0 0 1 Unknown %i_texture_cube_array = OpTypeImage %int Cube 0 1 0 1 Unknown %i_storage_1d = OpTypeImage %int 1D 0 0 0 1 Rg32i %i_storage_1d_array = OpTypeImage %int 1D 0 1 0 1 Rg32i %i_storage_2d = OpTypeImage %int 2D 0 0 0 1 Rg32i %i_storage_2d_array = OpTypeImage %int 2D 0 1 0 1 Rg32i %i_storage_3d = OpTypeImage %int 3D 0 0 0 1 Rg32i ;; Now pointers to each of the above, so we can declare variables for them. %ptr_sampler = OpTypePointer UniformConstant %sampler %ptr_f_texture_1d = OpTypePointer UniformConstant %f_texture_1d %ptr_f_texture_1d_array = OpTypePointer UniformConstant %f_texture_1d_array %ptr_f_texture_2d = OpTypePointer UniformConstant %f_texture_2d %ptr_f_texture_2d_ms = OpTypePointer UniformConstant %f_texture_2d_ms %ptr_f_texture_2d_array = OpTypePointer UniformConstant %f_texture_2d_array %ptr_f_texture_2d_ms_array = OpTypePointer UniformConstant %f_texture_2d_ms_array %ptr_f_texture_3d = OpTypePointer UniformConstant %f_texture_3d %ptr_f_texture_cube = OpTypePointer UniformConstant %f_texture_cube %ptr_f_texture_cube_array = OpTypePointer UniformConstant %f_texture_cube_array ; storage images %ptr_f_storage_1d = OpTypePointer UniformConstant %f_storage_1d %ptr_f_storage_1d_array = OpTypePointer UniformConstant %f_storage_1d_array %ptr_f_storage_2d = OpTypePointer UniformConstant %f_storage_2d %ptr_f_storage_2d_array = OpTypePointer UniformConstant %f_storage_2d_array %ptr_f_storage_3d = OpTypePointer UniformConstant %f_storage_3d ; Now all the same, but for unsigned integer sampled type. %ptr_u_texture_1d = OpTypePointer UniformConstant %u_texture_1d %ptr_u_texture_1d_array = OpTypePointer UniformConstant %u_texture_1d_array %ptr_u_texture_2d = OpTypePointer UniformConstant %u_texture_2d %ptr_u_texture_2d_ms = OpTypePointer UniformConstant %u_texture_2d_ms %ptr_u_texture_2d_array = OpTypePointer UniformConstant %u_texture_2d_array %ptr_u_texture_2d_ms_array = OpTypePointer UniformConstant %u_texture_2d_ms_array %ptr_u_texture_3d = OpTypePointer UniformConstant %u_texture_3d %ptr_u_texture_cube = OpTypePointer UniformConstant %u_texture_cube %ptr_u_texture_cube_array = OpTypePointer UniformConstant %u_texture_cube_array %ptr_u_storage_1d = OpTypePointer UniformConstant %u_storage_1d %ptr_u_storage_1d_array = OpTypePointer UniformConstant %u_storage_1d_array %ptr_u_storage_2d = OpTypePointer UniformConstant %u_storage_2d %ptr_u_storage_2d_array = OpTypePointer UniformConstant %u_storage_2d_array %ptr_u_storage_3d = OpTypePointer UniformConstant %u_storage_3d ; Now all the same, but for signed integer sampled type. %ptr_i_texture_1d = OpTypePointer UniformConstant %i_texture_1d %ptr_i_texture_1d_array = OpTypePointer UniformConstant %i_texture_1d_array %ptr_i_texture_2d = OpTypePointer UniformConstant %i_texture_2d %ptr_i_texture_2d_ms = OpTypePointer UniformConstant %i_texture_2d_ms %ptr_i_texture_2d_array = OpTypePointer UniformConstant %i_texture_2d_array %ptr_i_texture_2d_ms_array = OpTypePointer UniformConstant %i_texture_2d_ms_array %ptr_i_texture_3d = OpTypePointer UniformConstant %i_texture_3d %ptr_i_texture_cube = OpTypePointer UniformConstant %i_texture_cube %ptr_i_texture_cube_array = OpTypePointer UniformConstant %i_texture_cube_array %ptr_i_storage_1d = OpTypePointer UniformConstant %i_storage_1d %ptr_i_storage_1d_array = OpTypePointer UniformConstant %i_storage_1d_array %ptr_i_storage_2d = OpTypePointer UniformConstant %i_storage_2d %ptr_i_storage_2d_array = OpTypePointer UniformConstant %i_storage_2d_array %ptr_i_storage_3d = OpTypePointer UniformConstant %i_storage_3d )"; } std::string CommonTypes() { return CommonBasicTypes() + CommonImageTypes(); } TEST_F(SpvParserTest, GetMemoryObjectDeclarationForHandle_WellFormedButNotAHandle) { const auto assembly = Preamble() + CommonTypes() + R"( %10 = OpConstantNull %ptr_sampler %20 = OpConstantNull %ptr_f_texture_1d )"; auto p = parser(test::Assemble(assembly)); ASSERT_TRUE(p->BuildInternalModule()) << assembly; const auto* sampler = p->GetMemoryObjectDeclarationForHandle(10, false); const auto* image = p->GetMemoryObjectDeclarationForHandle(20, true); EXPECT_EQ(sampler, nullptr); EXPECT_EQ(image, nullptr); EXPECT_TRUE(p->error().empty()); } TEST_F(SpvParserTest, GetMemoryObjectDeclarationForHandle_Variable_Direct) { const auto assembly = Preamble() + CommonTypes() + R"( %10 = OpVariable %ptr_sampler UniformConstant %20 = OpVariable %ptr_f_texture_1d UniformConstant )"; auto p = parser(test::Assemble(assembly)); ASSERT_TRUE(p->BuildInternalModule()); EXPECT_TRUE(p->error().empty()); const auto* sampler = p->GetMemoryObjectDeclarationForHandle(10, false); const auto* image = p->GetMemoryObjectDeclarationForHandle(20, true); ASSERT_TRUE(sampler != nullptr); EXPECT_EQ(sampler->result_id(), 10u); ASSERT_TRUE(image != nullptr); EXPECT_EQ(image->result_id(), 20u); } TEST_F(SpvParserTest, GetMemoryObjectDeclarationForHandle_Variable_AccessChain) { // Show that we would generalize to arrays of handles, even though that // is not supported in WGSL MVP. const auto assembly = Preamble() + CommonTypes() + R"( %sampler_array = OpTypeArray %sampler %uint_100 %image_array = OpTypeArray %f_texture_1d %uint_100 %ptr_sampler_array = OpTypePointer UniformConstant %sampler_array %ptr_image_array = OpTypePointer UniformConstant %image_array %10 = OpVariable %ptr_sampler_array UniformConstant %20 = OpVariable %ptr_image_array UniformConstant %main = OpFunction %void None %voidfn %entry = OpLabel %110 = OpAccessChain %ptr_sampler %10 %uint_1 %120 = OpAccessChain %ptr_f_texture_1d %20 %uint_2 OpReturn OpFunctionEnd )"; auto p = parser(test::Assemble(assembly)); ASSERT_TRUE(p->BuildInternalModule()); EXPECT_TRUE(p->error().empty()); const auto* sampler = p->GetMemoryObjectDeclarationForHandle(110, false); const auto* image = p->GetMemoryObjectDeclarationForHandle(120, true); ASSERT_TRUE(sampler != nullptr); EXPECT_EQ(sampler->result_id(), 10u); ASSERT_TRUE(image != nullptr); EXPECT_EQ(image->result_id(), 20u); } TEST_F(SpvParserTest, GetMemoryObjectDeclarationForHandle_Variable_InBoundsAccessChain) { const auto assembly = Preamble() + CommonTypes() + R"( %sampler_array = OpTypeArray %sampler %uint_100 %image_array = OpTypeArray %f_texture_1d %uint_100 %ptr_sampler_array = OpTypePointer UniformConstant %sampler_array %ptr_image_array = OpTypePointer UniformConstant %image_array %10 = OpVariable %ptr_sampler_array UniformConstant %20 = OpVariable %ptr_image_array UniformConstant %main = OpFunction %void None %voidfn %entry = OpLabel %110 = OpInBoundsAccessChain %ptr_sampler %10 %uint_1 %120 = OpInBoundsAccessChain %ptr_f_texture_1d %20 %uint_2 OpReturn OpFunctionEnd )"; auto p = parser(test::Assemble(assembly)); ASSERT_TRUE(p->BuildInternalModule()); EXPECT_TRUE(p->error().empty()); const auto* sampler = p->GetMemoryObjectDeclarationForHandle(110, false); const auto* image = p->GetMemoryObjectDeclarationForHandle(120, true); ASSERT_TRUE(sampler != nullptr); EXPECT_EQ(sampler->result_id(), 10u); ASSERT_TRUE(image != nullptr); EXPECT_EQ(image->result_id(), 20u); } TEST_F(SpvParserTest, GetMemoryObjectDeclarationForHandle_Variable_PtrAccessChain) { // Show that we would generalize to arrays of handles, even though that // is not supported in WGSL MVP. const auto assembly = Preamble() + CommonTypes() + R"( %sampler_array = OpTypeArray %sampler %uint_100 %image_array = OpTypeArray %f_texture_1d %uint_100 %ptr_sampler_array = OpTypePointer UniformConstant %sampler_array %ptr_image_array = OpTypePointer UniformConstant %image_array %10 = OpVariable %ptr_sampler_array UniformConstant %20 = OpVariable %ptr_image_array UniformConstant %main = OpFunction %void None %voidfn %entry = OpLabel %110 = OpPtrAccessChain %ptr_sampler %10 %uint_1 %uint_1 %120 = OpPtrAccessChain %ptr_f_texture_1d %20 %uint_1 %uint_2 OpReturn OpFunctionEnd )"; auto p = parser(test::Assemble(assembly)); ASSERT_TRUE(p->BuildInternalModule()); EXPECT_TRUE(p->error().empty()); const auto* sampler = p->GetMemoryObjectDeclarationForHandle(110, false); const auto* image = p->GetMemoryObjectDeclarationForHandle(120, true); ASSERT_TRUE(sampler != nullptr); EXPECT_EQ(sampler->result_id(), 10u); ASSERT_TRUE(image != nullptr); EXPECT_EQ(image->result_id(), 20u); } TEST_F(SpvParserTest, GetMemoryObjectDeclarationForHandle_Variable_InBoundsPtrAccessChain) { const auto assembly = Preamble() + CommonTypes() + R"( %sampler_array = OpTypeArray %sampler %uint_100 %image_array = OpTypeArray %f_texture_1d %uint_100 %ptr_sampler_array = OpTypePointer UniformConstant %sampler_array %ptr_image_array = OpTypePointer UniformConstant %image_array %10 = OpVariable %ptr_sampler_array UniformConstant %20 = OpVariable %ptr_image_array UniformConstant %main = OpFunction %void None %voidfn %entry = OpLabel %110 = OpInBoundsPtrAccessChain %ptr_sampler %10 %uint_1 %uint_1 %120 = OpInBoundsPtrAccessChain %ptr_f_texture_1d %20 %uint_1 %uint_2 OpReturn OpFunctionEnd )"; auto p = parser(test::Assemble(assembly)); ASSERT_TRUE(p->BuildInternalModule()); EXPECT_TRUE(p->error().empty()); const auto* sampler = p->GetMemoryObjectDeclarationForHandle(110, false); const auto* image = p->GetMemoryObjectDeclarationForHandle(120, true); ASSERT_TRUE(sampler != nullptr); EXPECT_EQ(sampler->result_id(), 10u); ASSERT_TRUE(image != nullptr); EXPECT_EQ(image->result_id(), 20u); } TEST_F(SpvParserTest, GetMemoryObjectDeclarationForHandle_Variable_CopyObject) { const auto assembly = Preamble() + CommonTypes() + R"( %10 = OpVariable %ptr_sampler UniformConstant %20 = OpVariable %ptr_f_texture_1d UniformConstant %main = OpFunction %void None %voidfn %entry = OpLabel %110 = OpCopyObject %ptr_sampler %10 %120 = OpCopyObject %ptr_f_texture_1d %20 OpReturn OpFunctionEnd )"; auto p = parser(test::Assemble(assembly)); ASSERT_TRUE(p->BuildInternalModule()); EXPECT_TRUE(p->error().empty()); const auto* sampler = p->GetMemoryObjectDeclarationForHandle(110, false); const auto* image = p->GetMemoryObjectDeclarationForHandle(120, true); ASSERT_TRUE(sampler != nullptr); EXPECT_EQ(sampler->result_id(), 10u); ASSERT_TRUE(image != nullptr); EXPECT_EQ(image->result_id(), 20u); } TEST_F(SpvParserTest, GetMemoryObjectDeclarationForHandle_Variable_Load) { const auto assembly = Preamble() + CommonTypes() + R"( %10 = OpVariable %ptr_sampler UniformConstant %20 = OpVariable %ptr_f_texture_1d UniformConstant %main = OpFunction %void None %voidfn %entry = OpLabel %110 = OpLoad %sampler %10 %120 = OpLoad %f_texture_1d %20 OpReturn OpFunctionEnd )"; auto p = parser(test::Assemble(assembly)); ASSERT_TRUE(p->BuildInternalModule()); EXPECT_TRUE(p->error().empty()); const auto* sampler = p->GetMemoryObjectDeclarationForHandle(110, false); const auto* image = p->GetMemoryObjectDeclarationForHandle(120, true); ASSERT_TRUE(sampler != nullptr); EXPECT_EQ(sampler->result_id(), 10u); ASSERT_TRUE(image != nullptr); EXPECT_EQ(image->result_id(), 20u); } TEST_F(SpvParserTest, GetMemoryObjectDeclarationForHandle_Variable_SampledImage) { // Trace through the sampled image instruction, but in two different // directions. const auto assembly = Preamble() + CommonTypes() + R"( %sampled_image_type = OpTypeSampledImage %f_texture_1d %10 = OpVariable %ptr_sampler UniformConstant %20 = OpVariable %ptr_f_texture_1d UniformConstant %main = OpFunction %void None %voidfn %entry = OpLabel %s = OpLoad %sampler %10 %im = OpLoad %f_texture_1d %20 %100 = OpSampledImage %sampled_image_type %im %s OpReturn OpFunctionEnd )"; auto p = parser(test::Assemble(assembly)); ASSERT_TRUE(p->BuildInternalModule()); EXPECT_TRUE(p->error().empty()); const auto* sampler = p->GetMemoryObjectDeclarationForHandle(100, false); const auto* image = p->GetMemoryObjectDeclarationForHandle(100, true); ASSERT_TRUE(sampler != nullptr); EXPECT_EQ(sampler->result_id(), 10u); ASSERT_TRUE(image != nullptr); EXPECT_EQ(image->result_id(), 20u); } TEST_F(SpvParserTest, GetMemoryObjectDeclarationForHandle_Variable_Image) { const auto assembly = Preamble() + CommonTypes() + R"( %sampled_image_type = OpTypeSampledImage %f_texture_1d %10 = OpVariable %ptr_sampler UniformConstant %20 = OpVariable %ptr_f_texture_1d UniformConstant %main = OpFunction %void None %voidfn %entry = OpLabel %s = OpLoad %sampler %10 %im = OpLoad %f_texture_1d %20 %100 = OpSampledImage %sampled_image_type %im %s %200 = OpImage %im %100 OpReturn OpFunctionEnd )"; auto p = parser(test::Assemble(assembly)); ASSERT_TRUE(p->BuildInternalModule()); EXPECT_TRUE(p->error().empty()); const auto* image = p->GetMemoryObjectDeclarationForHandle(200, true); ASSERT_TRUE(image != nullptr); EXPECT_EQ(image->result_id(), 20u); } TEST_F(SpvParserTest, GetMemoryObjectDeclarationForHandle_FuncParam_Direct) { const auto assembly = Preamble() + CommonTypes() + R"( %fty = OpTypeFunction %void %ptr_sampler %ptr_f_texture_1d %func = OpFunction %void None %fty %10 = OpFunctionParameter %ptr_sampler %20 = OpFunctionParameter %ptr_f_texture_1d %entry = OpLabel OpReturn )"; auto p = parser(test::Assemble(assembly)); ASSERT_TRUE(p->BuildInternalModule()); EXPECT_TRUE(p->error().empty()); const auto* sampler = p->GetMemoryObjectDeclarationForHandle(10, false); const auto* image = p->GetMemoryObjectDeclarationForHandle(20, true); ASSERT_TRUE(sampler != nullptr); EXPECT_EQ(sampler->result_id(), 10u); ASSERT_TRUE(image != nullptr); EXPECT_EQ(image->result_id(), 20u); } TEST_F(SpvParserTest, GetMemoryObjectDeclarationForHandle_FuncParam_AccessChain) { // Show that we would generalize to arrays of handles, even though that // is not supported in WGSL MVP. const auto assembly = Preamble() + CommonTypes() + R"( %sampler_array = OpTypeArray %sampler %uint_100 %image_array = OpTypeArray %f_texture_1d %uint_100 %ptr_sampler_array = OpTypePointer UniformConstant %sampler_array %ptr_image_array = OpTypePointer UniformConstant %image_array %fty = OpTypeFunction %void %ptr_sampler_array %ptr_image_array %func = OpFunction %void None %fty %10 = OpFunctionParameter %ptr_sampler_array %20 = OpFunctionParameter %ptr_image_array %entry = OpLabel %110 = OpAccessChain %ptr_sampler %10 %uint_1 %120 = OpAccessChain %ptr_f_texture_1d %20 %uint_2 OpReturn OpFunctionEnd )"; auto p = parser(test::Assemble(assembly)); ASSERT_TRUE(p->BuildInternalModule()); EXPECT_TRUE(p->error().empty()); const auto* sampler = p->GetMemoryObjectDeclarationForHandle(110, false); const auto* image = p->GetMemoryObjectDeclarationForHandle(120, true); ASSERT_TRUE(sampler != nullptr); EXPECT_EQ(sampler->result_id(), 10u); ASSERT_TRUE(image != nullptr); EXPECT_EQ(image->result_id(), 20u); } TEST_F(SpvParserTest, GetMemoryObjectDeclarationForHandle_FuncParam_InBoundsAccessChain) { const auto assembly = Preamble() + CommonTypes() + R"( %sampler_array = OpTypeArray %sampler %uint_100 %image_array = OpTypeArray %f_texture_1d %uint_100 %ptr_sampler_array = OpTypePointer UniformConstant %sampler_array %ptr_image_array = OpTypePointer UniformConstant %image_array %fty = OpTypeFunction %void %ptr_sampler_array %ptr_image_array %func = OpFunction %void None %fty %10 = OpFunctionParameter %ptr_sampler_array %20 = OpFunctionParameter %ptr_image_array %entry = OpLabel %110 = OpInBoundsAccessChain %ptr_sampler %10 %uint_1 %120 = OpInBoundsAccessChain %ptr_f_texture_1d %20 %uint_2 OpReturn OpFunctionEnd )"; auto p = parser(test::Assemble(assembly)); ASSERT_TRUE(p->BuildInternalModule()); EXPECT_TRUE(p->error().empty()); const auto* sampler = p->GetMemoryObjectDeclarationForHandle(110, false); const auto* image = p->GetMemoryObjectDeclarationForHandle(120, true); ASSERT_TRUE(sampler != nullptr); EXPECT_EQ(sampler->result_id(), 10u); ASSERT_TRUE(image != nullptr); EXPECT_EQ(image->result_id(), 20u); } TEST_F(SpvParserTest, GetMemoryObjectDeclarationForHandle_FuncParam_PtrAccessChain) { // Show that we would generalize to arrays of handles, even though that // is not supported in WGSL MVP. const auto assembly = Preamble() + CommonTypes() + R"( %sampler_array = OpTypeArray %sampler %uint_100 %image_array = OpTypeArray %f_texture_1d %uint_100 %ptr_sampler_array = OpTypePointer UniformConstant %sampler_array %ptr_image_array = OpTypePointer UniformConstant %image_array %fty = OpTypeFunction %void %ptr_sampler_array %ptr_image_array %func = OpFunction %void None %fty %10 = OpFunctionParameter %ptr_sampler_array %20 = OpFunctionParameter %ptr_image_array %entry = OpLabel %110 = OpPtrAccessChain %ptr_sampler %10 %uint_1 %uint_1 %120 = OpPtrAccessChain %ptr_f_texture_1d %20 %uint_1 %uint_2 OpReturn OpFunctionEnd )"; auto p = parser(test::Assemble(assembly)); ASSERT_TRUE(p->BuildInternalModule()); EXPECT_TRUE(p->error().empty()); const auto* sampler = p->GetMemoryObjectDeclarationForHandle(110, false); const auto* image = p->GetMemoryObjectDeclarationForHandle(120, true); ASSERT_TRUE(sampler != nullptr); EXPECT_EQ(sampler->result_id(), 10u); ASSERT_TRUE(image != nullptr); EXPECT_EQ(image->result_id(), 20u); } TEST_F(SpvParserTest, GetMemoryObjectDeclarationForHandle_FuncParam_InBoundsPtrAccessChain) { const auto assembly = Preamble() + CommonTypes() + R"( %sampler_array = OpTypeArray %sampler %uint_100 %image_array = OpTypeArray %f_texture_1d %uint_100 %ptr_sampler_array = OpTypePointer UniformConstant %sampler_array %ptr_image_array = OpTypePointer UniformConstant %image_array %fty = OpTypeFunction %void %ptr_sampler_array %ptr_image_array %func = OpFunction %void None %fty %10 = OpFunctionParameter %ptr_sampler_array %20 = OpFunctionParameter %ptr_image_array %entry = OpLabel %110 = OpInBoundsPtrAccessChain %ptr_sampler %10 %uint_1 %uint_1 %120 = OpInBoundsPtrAccessChain %ptr_f_texture_1d %20 %uint_1 %uint_2 OpReturn OpFunctionEnd )"; auto p = parser(test::Assemble(assembly)); ASSERT_TRUE(p->BuildInternalModule()); EXPECT_TRUE(p->error().empty()); const auto* sampler = p->GetMemoryObjectDeclarationForHandle(110, false); const auto* image = p->GetMemoryObjectDeclarationForHandle(120, true); ASSERT_TRUE(sampler != nullptr); EXPECT_EQ(sampler->result_id(), 10u); ASSERT_TRUE(image != nullptr); EXPECT_EQ(image->result_id(), 20u); } TEST_F(SpvParserTest, GetMemoryObjectDeclarationForHandle_FuncParam_CopyObject) { const auto assembly = Preamble() + CommonTypes() + R"( %fty = OpTypeFunction %void %ptr_sampler %ptr_f_texture_1d %func = OpFunction %void None %fty %10 = OpFunctionParameter %ptr_sampler %20 = OpFunctionParameter %ptr_f_texture_1d %entry = OpLabel %110 = OpCopyObject %ptr_sampler %10 %120 = OpCopyObject %ptr_f_texture_1d %20 OpReturn OpFunctionEnd )"; auto p = parser(test::Assemble(assembly)); ASSERT_TRUE(p->BuildInternalModule()); EXPECT_TRUE(p->error().empty()); const auto* sampler = p->GetMemoryObjectDeclarationForHandle(110, false); const auto* image = p->GetMemoryObjectDeclarationForHandle(120, true); ASSERT_TRUE(sampler != nullptr); EXPECT_EQ(sampler->result_id(), 10u); ASSERT_TRUE(image != nullptr); EXPECT_EQ(image->result_id(), 20u); } TEST_F(SpvParserTest, GetMemoryObjectDeclarationForHandle_FuncParam_Load) { const auto assembly = Preamble() + CommonTypes() + R"( %fty = OpTypeFunction %void %ptr_sampler %ptr_f_texture_1d %func = OpFunction %void None %fty %10 = OpFunctionParameter %ptr_sampler %20 = OpFunctionParameter %ptr_f_texture_1d %entry = OpLabel %110 = OpLoad %sampler %10 %120 = OpLoad %f_texture_1d %20 OpReturn OpFunctionEnd )"; auto p = parser(test::Assemble(assembly)); ASSERT_TRUE(p->BuildInternalModule()); EXPECT_TRUE(p->error().empty()); const auto* sampler = p->GetMemoryObjectDeclarationForHandle(110, false); const auto* image = p->GetMemoryObjectDeclarationForHandle(120, true); ASSERT_TRUE(sampler != nullptr); EXPECT_EQ(sampler->result_id(), 10u); ASSERT_TRUE(image != nullptr); EXPECT_EQ(image->result_id(), 20u); } TEST_F(SpvParserTest, GetMemoryObjectDeclarationForHandle_FuncParam_SampledImage) { // Trace through the sampled image instruction, but in two different // directions. const auto assembly = Preamble() + CommonTypes() + R"( %sampled_image_type = OpTypeSampledImage %f_texture_1d %fty = OpTypeFunction %void %ptr_sampler %ptr_f_texture_1d %func = OpFunction %void None %fty %10 = OpFunctionParameter %ptr_sampler %20 = OpFunctionParameter %ptr_f_texture_1d %entry = OpLabel %s = OpLoad %sampler %10 %im = OpLoad %f_texture_1d %20 %100 = OpSampledImage %sampled_image_type %im %s OpReturn OpFunctionEnd )"; auto p = parser(test::Assemble(assembly)); ASSERT_TRUE(p->BuildInternalModule()); EXPECT_TRUE(p->error().empty()); const auto* sampler = p->GetMemoryObjectDeclarationForHandle(100, false); const auto* image = p->GetMemoryObjectDeclarationForHandle(100, true); ASSERT_TRUE(sampler != nullptr); EXPECT_EQ(sampler->result_id(), 10u); ASSERT_TRUE(image != nullptr); EXPECT_EQ(image->result_id(), 20u); } TEST_F(SpvParserTest, GetMemoryObjectDeclarationForHandle_FuncParam_Image) { const auto assembly = Preamble() + CommonTypes() + R"( %sampled_image_type = OpTypeSampledImage %f_texture_1d %fty = OpTypeFunction %void %ptr_sampler %ptr_f_texture_1d %func = OpFunction %void None %fty %10 = OpFunctionParameter %ptr_sampler %20 = OpFunctionParameter %ptr_f_texture_1d %entry = OpLabel %s = OpLoad %sampler %10 %im = OpLoad %f_texture_1d %20 %100 = OpSampledImage %sampled_image_type %im %s %200 = OpImage %im %100 OpReturn OpFunctionEnd )"; auto p = parser(test::Assemble(assembly)); ASSERT_TRUE(p->BuildInternalModule()); EXPECT_TRUE(p->error().empty()); const auto* image = p->GetMemoryObjectDeclarationForHandle(200, true); ASSERT_TRUE(image != nullptr); EXPECT_EQ(image->result_id(), 20u); } // Test RegisterHandleUsage, sampled image cases struct UsageImageAccessCase { std::string inst; std::string expected_sampler_usage; std::string expected_image_usage; }; inline std::ostream& operator<<(std::ostream& out, const UsageImageAccessCase& c) { out << "UsageImageAccessCase(" << c.inst << ", " << c.expected_sampler_usage << ", " << c.expected_image_usage << ")"; return out; } using SpvParserTest_RegisterHandleUsage_SampledImage = SpvParserTestBase<::testing::TestWithParam>; TEST_P(SpvParserTest_RegisterHandleUsage_SampledImage, Variable) { const auto assembly = Preamble() + CommonTypes() + R"( %si_ty = OpTypeSampledImage %f_texture_2d %coords = OpConstantNull %v2float %10 = OpVariable %ptr_sampler UniformConstant %20 = OpVariable %ptr_f_texture_2d UniformConstant %main = OpFunction %void None %voidfn %entry = OpLabel %sam = OpLoad %sampler %10 %im = OpLoad %f_texture_2d %20 %sampled_image = OpSampledImage %si_ty %im %sam )" + GetParam().inst + R"( OpReturn OpFunctionEnd )"; auto p = parser(test::Assemble(assembly)); ASSERT_TRUE(p->BuildInternalModule()); EXPECT_TRUE(p->RegisterHandleUsage()); EXPECT_TRUE(p->error().empty()); Usage su = p->GetHandleUsage(10); Usage iu = p->GetHandleUsage(20); EXPECT_THAT(su.to_str(), Eq(GetParam().expected_sampler_usage)); EXPECT_THAT(iu.to_str(), Eq(GetParam().expected_image_usage)); } TEST_P(SpvParserTest_RegisterHandleUsage_SampledImage, FunctionParam) { const auto assembly = Preamble() + CommonTypes() + R"( %f_ty = OpTypeFunction %void %ptr_sampler %ptr_f_texture_2d %si_ty = OpTypeSampledImage %f_texture_2d %coords = OpConstantNull %v2float %component = OpConstant %uint 1 %10 = OpVariable %ptr_sampler UniformConstant %20 = OpVariable %ptr_f_texture_2d UniformConstant %func = OpFunction %void None %f_ty %110 = OpFunctionParameter %ptr_sampler %120 = OpFunctionParameter %ptr_f_texture_2d %func_entry = OpLabel %sam = OpLoad %sampler %110 %im = OpLoad %f_texture_2d %120 %sampled_image = OpSampledImage %si_ty %im %sam )" + GetParam().inst + R"( OpReturn OpFunctionEnd %main = OpFunction %void None %voidfn %entry = OpLabel %foo = OpFunctionCall %void %func %10 %20 OpReturn OpFunctionEnd )"; auto p = parser(test::Assemble(assembly)); ASSERT_TRUE(p->BuildInternalModule()) << p->error() << assembly << std::endl; EXPECT_TRUE(p->RegisterHandleUsage()) << p->error() << assembly << std::endl; EXPECT_TRUE(p->error().empty()) << p->error() << assembly << std::endl; Usage su = p->GetHandleUsage(10); Usage iu = p->GetHandleUsage(20); EXPECT_THAT(su.to_str(), Eq(GetParam().expected_sampler_usage)); EXPECT_THAT(iu.to_str(), Eq(GetParam().expected_image_usage)); } INSTANTIATE_TEST_SUITE_P( Samples, SpvParserTest_RegisterHandleUsage_SampledImage, ::testing::Values( // OpImageGather UsageImageAccessCase{"%result = OpImageGather " "%v4float %sampled_image %coords %uint_1", "Usage(Sampler( ))", "Usage(Texture( is_sampled ))"}, // OpImageDrefGather UsageImageAccessCase{"%result = OpImageDrefGather " "%v4float %sampled_image %coords %depth", "Usage(Sampler( comparison ))", "Usage(Texture( is_sampled depth ))"}, // Sample the texture. // OpImageSampleImplicitLod UsageImageAccessCase{"%result = OpImageSampleImplicitLod " "%v4float %sampled_image %coords", "Usage(Sampler( ))", "Usage(Texture( is_sampled ))"}, // OpImageSampleExplicitLod UsageImageAccessCase{"%result = OpImageSampleExplicitLod " "%v4float %sampled_image %coords Lod %float_null", "Usage(Sampler( ))", "Usage(Texture( is_sampled ))"}, // OpImageSampleDrefImplicitLod UsageImageAccessCase{"%result = OpImageSampleDrefImplicitLod " "%v4float %sampled_image %coords %depth", "Usage(Sampler( comparison ))", "Usage(Texture( is_sampled depth ))"}, // OpImageSampleDrefExplicitLod UsageImageAccessCase{ "%result = OpImageSampleDrefExplicitLod " "%v4float %sampled_image %coords %depth Lod %float_null", "Usage(Sampler( comparison ))", "Usage(Texture( is_sampled depth ))"}, // Sample the texture, with *Proj* variants, even though WGSL doesn't // support them. // OpImageSampleProjImplicitLod UsageImageAccessCase{"%result = OpImageSampleProjImplicitLod " "%v4float %sampled_image %coords", "Usage(Sampler( ))", "Usage(Texture( is_sampled ))"}, // OpImageSampleProjExplicitLod UsageImageAccessCase{"%result = OpImageSampleProjExplicitLod " "%v4float %sampled_image %coords Lod %float_null", "Usage(Sampler( ))", "Usage(Texture( is_sampled ))"}, // OpImageSampleProjDrefImplicitLod UsageImageAccessCase{"%result = OpImageSampleProjDrefImplicitLod " "%v4float %sampled_image %coords %depth", "Usage(Sampler( comparison ))", "Usage(Texture( is_sampled depth ))"}, // OpImageSampleProjDrefExplicitLod UsageImageAccessCase{ "%result = OpImageSampleProjDrefExplicitLod " "%v4float %sampled_image %coords %depth Lod %float_null", "Usage(Sampler( comparison ))", "Usage(Texture( is_sampled depth ))"}, // OpImageQueryLod UsageImageAccessCase{ "%result = OpImageQueryLod %v2float %sampled_image %coords", "Usage(Sampler( ))", "Usage(Texture( is_sampled ))"})); // Test RegisterHandleUsage, raw image cases. // For these we test the use of an image value directly, and not combined // with the sampler. The image still could be of sampled image type. struct UsageRawImageCase { std::string type; // Example: f_storage_1d or f_texture_1d std::string inst; std::string expected_image_usage; }; inline std::ostream& operator<<(std::ostream& out, const UsageRawImageCase& c) { out << "UsageRawImageCase(" << c.type << ", " << c.inst << ", " << c.expected_image_usage << ")"; return out; } using SpvParserTest_RegisterHandleUsage_RawImage = SpvParserTestBase<::testing::TestWithParam>; TEST_P(SpvParserTest_RegisterHandleUsage_RawImage, Variable) { const auto assembly = Preamble() + CommonTypes() + R"( %20 = OpVariable %ptr_)" + GetParam().type + R"( UniformConstant %main = OpFunction %void None %voidfn %entry = OpLabel %im = OpLoad %)" + GetParam().type + R"( %20 )" + GetParam().inst + R"( OpReturn OpFunctionEnd )"; auto p = parser(test::Assemble(assembly)); ASSERT_TRUE(p->BuildInternalModule()); EXPECT_TRUE(p->RegisterHandleUsage()); EXPECT_TRUE(p->error().empty()); Usage iu = p->GetHandleUsage(20); EXPECT_THAT(iu.to_str(), Eq(GetParam().expected_image_usage)); Usage su = p->GetHandleUsage(20); } TEST_P(SpvParserTest_RegisterHandleUsage_RawImage, FunctionParam) { const auto assembly = Preamble() + CommonTypes() + R"( %f_ty = OpTypeFunction %void %ptr_)" + GetParam().type + R"( %20 = OpVariable %ptr_)" + GetParam().type + R"( UniformConstant %func = OpFunction %void None %f_ty %i_param = OpFunctionParameter %ptr_)" + GetParam().type + R"( %func_entry = OpLabel %im = OpLoad %)" + GetParam().type + R"( %i_param )" + GetParam().inst + R"( OpReturn OpFunctionEnd %main = OpFunction %void None %voidfn %entry = OpLabel %foo = OpFunctionCall %void %func %20 OpReturn OpFunctionEnd )"; auto p = parser(test::Assemble(assembly)); ASSERT_TRUE(p->BuildInternalModule()); EXPECT_TRUE(p->RegisterHandleUsage()); EXPECT_TRUE(p->error().empty()); Usage iu = p->GetHandleUsage(20); EXPECT_THAT(iu.to_str(), Eq(GetParam().expected_image_usage)); } INSTANTIATE_TEST_SUITE_P( Samples, SpvParserTest_RegisterHandleUsage_RawImage, ::testing::Values( // OpImageRead UsageRawImageCase{"f_storage_1d", "%result = OpImageRead %v4float %im %uint_1", "Usage(Texture( read ))"}, // OpImageWrite UsageRawImageCase{"f_storage_1d", "OpImageWrite %im %uint_1 %v4float_null", "Usage(Texture( write ))"}, // OpImageFetch UsageRawImageCase{"f_texture_1d", "%result = OpImageFetch " "%v4float %im %float_null", "Usage(Texture( is_sampled ))"}, // Image queries // OpImageQuerySizeLod // Applies to NonReadable, hence write-only storage UsageRawImageCase{"f_storage_2d", "%result = OpImageQuerySizeLod " "%v2uint %im %uint_1", "Usage(Texture( write ))"}, // OpImageQuerySize // Applies to NonReadable, hence write-only storage UsageRawImageCase{"f_storage_2d", "%result = OpImageQuerySize " "%v2uint %im", "Usage(Texture( write ))"}, // OpImageQueryLevels UsageRawImageCase{"f_texture_2d", "%result = OpImageQueryLevels " "%uint %im", "Usage(Texture( ))"}, // OpImageQuerySamples UsageRawImageCase{"f_texture_2d_ms", "%result = OpImageQuerySamples " "%uint %im", "Usage(Texture( is_sampled ms ))"})); // Test emission of handle variables. // Test emission of variables where we don't have enough clues from their // use in image access instructions in executable code. For these we have // to infer usage from the SPIR-V sampler or image type. struct DeclUnderspecifiedHandleCase { std::string decorations; // SPIR-V decorations std::string inst; // SPIR-V variable declarations std::string var_decl; // WGSL variable declaration }; inline std::ostream& operator<<(std::ostream& out, const DeclUnderspecifiedHandleCase& c) { out << "DeclUnderspecifiedHandleCase(" << c.inst << "\n" << c.var_decl << ")"; return out; } using SpvParserTest_DeclUnderspecifiedHandle = SpvParserTestBase<::testing::TestWithParam>; TEST_P(SpvParserTest_DeclUnderspecifiedHandle, Variable) { const auto assembly = Preamble() + R"( OpDecorate %10 DescriptorSet 0 OpDecorate %10 Binding 0 )" + GetParam().decorations + CommonTypes() + GetParam().inst + R"( %main = OpFunction %void None %voidfn %entry = OpLabel OpReturn OpFunctionEnd )"; auto p = parser(test::Assemble(assembly)); ASSERT_TRUE(p->BuildAndParseInternalModule()) << p->error() << assembly; EXPECT_TRUE(p->error().empty()) << p->error(); const auto module = Demangler().Demangle(p->get_module(), p->get_module().to_str()); EXPECT_THAT(module, HasSubstr(GetParam().var_decl)) << module; } INSTANTIATE_TEST_SUITE_P(Samplers, SpvParserTest_DeclUnderspecifiedHandle, ::testing::Values( DeclUnderspecifiedHandleCase{"", R"( %ptr = OpTypePointer UniformConstant %sampler %10 = OpVariable %ptr UniformConstant )", R"( Variable{ Decorations{ SetDecoration{0} BindingDecoration{0} } x_10 uniform_constant __sampler_sampler })"})); INSTANTIATE_TEST_SUITE_P(Images, SpvParserTest_DeclUnderspecifiedHandle, ::testing::Values( DeclUnderspecifiedHandleCase{"", R"( %10 = OpVariable %ptr_f_texture_1d UniformConstant )", R"( Variable{ Decorations{ SetDecoration{0} BindingDecoration{0} } x_10 uniform_constant __sampled_texture_1d__f32 })"}, DeclUnderspecifiedHandleCase{R"( OpDecorate %10 NonWritable )", R"( %10 = OpVariable %ptr_f_storage_1d UniformConstant )", R"( Variable{ Decorations{ SetDecoration{0} BindingDecoration{0} } x_10 uniform_constant __storage_texture_read_only_1d_rg32float })"}, DeclUnderspecifiedHandleCase{R"( OpDecorate %10 NonReadable )", R"( %10 = OpVariable %ptr_f_storage_1d UniformConstant )", R"( Variable{ Decorations{ SetDecoration{0} BindingDecoration{0} } x_10 uniform_constant __storage_texture_write_only_1d_rg32float })"})); // Test emission of variables when we have image accesses in executable code. struct ImageAccessCase { // SPIR-V image type, excluding result ID and opcode std::string spirv_image_type_details; std::string spirv_image_access; // The provoking image access instruction. std::string var_decl; // WGSL variable declaration std::string texture_builtin; // WGSL texture usage. }; inline std::ostream& operator<<(std::ostream& out, const ImageAccessCase& c) { out << "ImageCase(" << c.spirv_image_type_details << "\n" << c.spirv_image_access << "\n" << c.var_decl << "\n" << c.texture_builtin << ")"; return out; } using SpvParserTest_SampledImageAccessTest = SpvParserTestBase<::testing::TestWithParam>; TEST_P(SpvParserTest_SampledImageAccessTest, Variable) { const auto assembly = Preamble() + R"( OpEntryPoint Fragment %main "main" OpExecutionMode %main OriginUpperLeft OpName %f1 "f1" OpName %vf12 "vf12" OpName %vf123 "vf123" OpName %vf1234 "vf1234" OpName %u1 "u1" OpName %vu12 "vu12" OpName %vu123 "vu123" OpName %vu1234 "vu1234" OpName %i1 "i1" OpName %vi12 "vi12" OpName %vi123 "vi123" OpName %vi1234 "vi1234" OpName %coords1 "coords1" OpName %coords12 "coords12" OpName %coords123 "coords123" OpName %coords1234 "coords1234" OpName %offsets2d "offsets2d" OpName %u_offsets2d "u_offsets2d" OpDecorate %10 DescriptorSet 0 OpDecorate %10 Binding 0 OpDecorate %20 DescriptorSet 2 OpDecorate %20 Binding 1 OpDecorate %30 DescriptorSet 0 OpDecorate %30 Binding 1 )" + CommonBasicTypes() + R"( %sampler = OpTypeSampler %ptr_sampler = OpTypePointer UniformConstant %sampler %im_ty = OpTypeImage )" + GetParam().spirv_image_type_details + R"( %ptr_im_ty = OpTypePointer UniformConstant %im_ty %si_ty = OpTypeSampledImage %im_ty %10 = OpVariable %ptr_sampler UniformConstant %20 = OpVariable %ptr_im_ty UniformConstant %30 = OpVariable %ptr_sampler UniformConstant ; comparison sampler, when needed %main = OpFunction %void None %voidfn %entry = OpLabel %f1 = OpCopyObject %float %float_1 %vf12 = OpCopyObject %v2float %the_vf12 %vf123 = OpCopyObject %v3float %the_vf123 %vf1234 = OpCopyObject %v4float %the_vf1234 %i1 = OpCopyObject %int %int_1 %vi12 = OpCopyObject %v2int %the_vi12 %vi123 = OpCopyObject %v3int %the_vi123 %vi1234 = OpCopyObject %v4int %the_vi1234 %u1 = OpCopyObject %uint %uint_1 %vu12 = OpCopyObject %v2uint %the_vu12 %vu123 = OpCopyObject %v3uint %the_vu123 %vu1234 = OpCopyObject %v4uint %the_vu1234 %coords1 = OpCopyObject %float %float_1 %coords12 = OpCopyObject %v2float %vf12 %coords123 = OpCopyObject %v3float %vf123 %coords1234 = OpCopyObject %v4float %vf1234 %value_offset = OpCompositeConstruct %v2int %int_3 %int_4 %offsets2d = OpCopyObject %v2int %value_offset %u_value_offset = OpCompositeConstruct %v2uint %uint_3 %uint_4 %u_offsets2d = OpCopyObject %v2uint %u_value_offset %sam = OpLoad %sampler %10 %im = OpLoad %im_ty %20 %sampled_image = OpSampledImage %si_ty %im %sam )" + GetParam().spirv_image_access + R"( OpReturn OpFunctionEnd )"; auto p = parser(test::Assemble(assembly)); ASSERT_TRUE(p->BuildAndParseInternalModule()) << p->error() << assembly; EXPECT_TRUE(p->error().empty()) << p->error(); const auto module = Demangler().Demangle(p->get_module(), p->get_module().to_str()); EXPECT_THAT(module, HasSubstr(GetParam().var_decl)) << "DECLARATIONS ARE BAD " << module; EXPECT_THAT(module, HasSubstr(GetParam().texture_builtin)) << "TEXTURE BUILTIN IS BAD " << module << assembly; } // TODO(dneto): Test variable declaration and texture builtins provoked by // use of an image access instruction inside helper function. TEST_P(SpvParserTest_RegisterHandleUsage_SampledImage, DISABLED_FunctionParam) { } INSTANTIATE_TEST_SUITE_P( DISABLED_ImageGather, SpvParserTest_SampledImageAccessTest, ::testing::ValuesIn(std::vector{ // TODO(dneto): OpImageGather // TODO(dneto): OpImageGather with ConstOffset (signed and unsigned) // TODO(dneto): OpImageGather with Offset (signed and unsigned) // TODO(dneto): OpImageGather with Offsets (signed and unsigned) })); INSTANTIATE_TEST_SUITE_P( DISABLED_ImageDrefGather, SpvParserTest_SampledImageAccessTest, ::testing::ValuesIn(std::vector{ // TODO(dneto): OpImageDrefGather // TODO(dneto): OpImageDrefGather with ConstOffset (signed and // unsigned) // TODO(dneto): OpImageDrefGather with Offset (signed and unsigned) // TODO(dneto): OpImageDrefGather with Offsets (signed and unsigned) })); INSTANTIATE_TEST_SUITE_P( ImageSampleImplicitLod, SpvParserTest_SampledImageAccessTest, ::testing::Values( // OpImageSampleImplicitLod ImageAccessCase{"%float 2D 0 0 0 1 Unknown", "%result = OpImageSampleImplicitLod " "%v4float %sampled_image %coords12", R"( Variable{ Decorations{ SetDecoration{0} BindingDecoration{0} } x_10 uniform_constant __sampler_sampler } Variable{ Decorations{ SetDecoration{2} BindingDecoration{1} } x_20 uniform_constant __sampled_texture_2d__f32 })", R"( Call[not set]{ Identifier[not set]{textureSample} ( Identifier[not set]{x_20} Identifier[not set]{x_10} Identifier[not set]{coords12} ) })"}, // OpImageSampleImplicitLod arrayed ImageAccessCase{"%float 2D 0 1 0 1 Unknown", "%result = OpImageSampleImplicitLod " "%v4float %sampled_image %coords123", R"( Variable{ Decorations{ SetDecoration{0} BindingDecoration{0} } x_10 uniform_constant __sampler_sampler } Variable{ Decorations{ SetDecoration{2} BindingDecoration{1} } x_20 uniform_constant __sampled_texture_2d_array__f32 })", R"( Call[not set]{ Identifier[not set]{textureSample} ( Identifier[not set]{x_20} Identifier[not set]{x_10} MemberAccessor[not set]{ Identifier[not set]{coords123} Identifier[not set]{xy} } TypeConstructor[not set]{ __i32 MemberAccessor[not set]{ Identifier[not set]{coords123} Identifier[not set]{z} } } ) })"}, // OpImageSampleImplicitLod with ConstOffset ImageAccessCase{ "%float 2D 0 0 0 1 Unknown", "%result = OpImageSampleImplicitLod " "%v4float %sampled_image %coords12 ConstOffset %offsets2d", R"( Variable{ Decorations{ SetDecoration{0} BindingDecoration{0} } x_10 uniform_constant __sampler_sampler } Variable{ Decorations{ SetDecoration{2} BindingDecoration{1} } x_20 uniform_constant __sampled_texture_2d__f32 })", R"( Call[not set]{ Identifier[not set]{textureSample} ( Identifier[not set]{x_20} Identifier[not set]{x_10} Identifier[not set]{coords12} Identifier[not set]{offsets2d} ) })"}, // OpImageSampleImplicitLod arrayed with ConstOffset ImageAccessCase{ "%float 2D 0 1 0 1 Unknown", "%result = OpImageSampleImplicitLod " "%v4float %sampled_image %coords123 ConstOffset %offsets2d", R"( Variable{ Decorations{ SetDecoration{0} BindingDecoration{0} } x_10 uniform_constant __sampler_sampler } Variable{ Decorations{ SetDecoration{2} BindingDecoration{1} } x_20 uniform_constant __sampled_texture_2d_array__f32 })", R"( Call[not set]{ Identifier[not set]{textureSample} ( Identifier[not set]{x_20} Identifier[not set]{x_10} MemberAccessor[not set]{ Identifier[not set]{coords123} Identifier[not set]{xy} } TypeConstructor[not set]{ __i32 MemberAccessor[not set]{ Identifier[not set]{coords123} Identifier[not set]{z} } } Identifier[not set]{offsets2d} ) })"}, // OpImageSampleImplicitLod with Bias ImageAccessCase{"%float 2D 0 0 0 1 Unknown", "%result = OpImageSampleImplicitLod " "%v4float %sampled_image %coords12 Bias %float_7", R"( Variable{ Decorations{ SetDecoration{0} BindingDecoration{0} } x_10 uniform_constant __sampler_sampler } Variable{ Decorations{ SetDecoration{2} BindingDecoration{1} } x_20 uniform_constant __sampled_texture_2d__f32 })", R"( Call[not set]{ Identifier[not set]{textureSampleBias} ( Identifier[not set]{x_20} Identifier[not set]{x_10} Identifier[not set]{coords12} ScalarConstructor[not set]{7.000000} ) })"}, // OpImageSampleImplicitLod arrayed with Bias ImageAccessCase{"%float 2D 0 1 0 1 Unknown", "%result = OpImageSampleImplicitLod " "%v4float %sampled_image %coords123 Bias %float_7", R"( Variable{ Decorations{ SetDecoration{0} BindingDecoration{0} } x_10 uniform_constant __sampler_sampler } Variable{ Decorations{ SetDecoration{2} BindingDecoration{1} } x_20 uniform_constant __sampled_texture_2d_array__f32 })", R"( Call[not set]{ Identifier[not set]{textureSampleBias} ( Identifier[not set]{x_20} Identifier[not set]{x_10} MemberAccessor[not set]{ Identifier[not set]{coords123} Identifier[not set]{xy} } TypeConstructor[not set]{ __i32 MemberAccessor[not set]{ Identifier[not set]{coords123} Identifier[not set]{z} } } ScalarConstructor[not set]{7.000000} ) })"}, // OpImageSampleImplicitLod with Bias and signed ConstOffset ImageAccessCase{"%float 2D 0 0 0 1 Unknown", "%result = OpImageSampleImplicitLod " "%v4float %sampled_image %coords12 Bias|ConstOffset " "%float_7 %offsets2d", R"( Variable{ Decorations{ SetDecoration{0} BindingDecoration{0} } x_10 uniform_constant __sampler_sampler } Variable{ Decorations{ SetDecoration{2} BindingDecoration{1} } x_20 uniform_constant __sampled_texture_2d__f32 })", R"( Call[not set]{ Identifier[not set]{textureSampleBias} ( Identifier[not set]{x_20} Identifier[not set]{x_10} Identifier[not set]{coords12} ScalarConstructor[not set]{7.000000} Identifier[not set]{offsets2d} ) })"}, // OpImageSampleImplicitLod with Bias and unsigned ConstOffset // Convert ConstOffset to signed ImageAccessCase{"%float 2D 0 0 0 1 Unknown", "%result = OpImageSampleImplicitLod " "%v4float %sampled_image %coords12 Bias|ConstOffset " "%float_7 %u_offsets2d", R"( Variable{ Decorations{ SetDecoration{0} BindingDecoration{0} } x_10 uniform_constant __sampler_sampler } Variable{ Decorations{ SetDecoration{2} BindingDecoration{1} } x_20 uniform_constant __sampled_texture_2d__f32 })", R"( Call[not set]{ Identifier[not set]{textureSampleBias} ( Identifier[not set]{x_20} Identifier[not set]{x_10} Identifier[not set]{coords12} ScalarConstructor[not set]{7.000000} TypeConstructor[not set]{ __vec_2__i32 Identifier[not set]{u_offsets2d} } ) })"}, // OpImageSampleImplicitLod arrayed with Bias ImageAccessCase{"%float 2D 0 1 0 1 Unknown", "%result = OpImageSampleImplicitLod " "%v4float %sampled_image %coords123 Bias|ConstOffset " "%float_7 %offsets2d", R"( Variable{ Decorations{ SetDecoration{0} BindingDecoration{0} } x_10 uniform_constant __sampler_sampler } Variable{ Decorations{ SetDecoration{2} BindingDecoration{1} } x_20 uniform_constant __sampled_texture_2d_array__f32 })", R"( Call[not set]{ Identifier[not set]{textureSampleBias} ( Identifier[not set]{x_20} Identifier[not set]{x_10} MemberAccessor[not set]{ Identifier[not set]{coords123} Identifier[not set]{xy} } TypeConstructor[not set]{ __i32 MemberAccessor[not set]{ Identifier[not set]{coords123} Identifier[not set]{z} } } ScalarConstructor[not set]{7.000000} Identifier[not set]{offsets2d} ) })"})); INSTANTIATE_TEST_SUITE_P( // This test shows the use of a sampled image used with both regular // sampling and depth-refernce sampling. The texture is a depth-texture, // and we use builtins textureSample and textureSampleCompare ImageSampleImplicitLod_BothDrefAndNonDref, SpvParserTest_SampledImageAccessTest, ::testing::Values( // OpImageSampleImplicitLod ImageAccessCase{"%float 2D 0 0 0 1 Unknown", R"( %sam_dref = OpLoad %sampler %30 %sampled_dref_image = OpSampledImage %si_ty %im %sam_dref %200 = OpImageSampleImplicitLod %v4float %sampled_image %coords12 %210 = OpImageSampleDrefImplicitLod %v4float %sampled_dref_image %coords12 %depth )", R"( Variable{ Decorations{ SetDecoration{0} BindingDecoration{0} } x_10 uniform_constant __sampler_sampler } Variable{ Decorations{ SetDecoration{2} BindingDecoration{1} } x_20 uniform_constant __depth_texture_2d } Variable{ Decorations{ SetDecoration{0} BindingDecoration{1} } x_30 uniform_constant __sampler_comparison })", R"( VariableDeclStatement{ VariableConst{ x_200 none __vec_4__f32 { TypeConstructor[not set]{ __vec_4__f32 Call[not set]{ Identifier[not set]{textureSample} ( Identifier[not set]{x_20} Identifier[not set]{x_10} Identifier[not set]{coords12} ) } ScalarConstructor[not set]{0.000000} ScalarConstructor[not set]{0.000000} ScalarConstructor[not set]{0.000000} } } } } VariableDeclStatement{ VariableConst{ x_210 none __vec_4__f32 { TypeConstructor[not set]{ __vec_4__f32 Call[not set]{ Identifier[not set]{textureSampleCompare} ( Identifier[not set]{x_20} Identifier[not set]{x_30} Identifier[not set]{coords12} ScalarConstructor[not set]{0.200000} ) } ScalarConstructor[not set]{0.000000} ScalarConstructor[not set]{0.000000} ScalarConstructor[not set]{0.000000} } } } })"})); INSTANTIATE_TEST_SUITE_P( ImageSampleDrefImplicitLod, SpvParserTest_SampledImageAccessTest, ::testing::Values( // ImageSampleDrefImplicitLod ImageAccessCase{"%float 2D 0 0 0 1 Unknown", "%result = OpImageSampleDrefImplicitLod " "%v4float %sampled_image %coords12 %depth", R"( Variable{ Decorations{ SetDecoration{0} BindingDecoration{0} } x_10 uniform_constant __sampler_comparison } Variable{ Decorations{ SetDecoration{2} BindingDecoration{1} } x_20 uniform_constant __depth_texture_2d })", R"( TypeConstructor[not set]{ __vec_4__f32 Call[not set]{ Identifier[not set]{textureSampleCompare} ( Identifier[not set]{x_20} Identifier[not set]{x_10} Identifier[not set]{coords12} ScalarConstructor[not set]{0.200000} ) } ScalarConstructor[not set]{0.000000} ScalarConstructor[not set]{0.000000} ScalarConstructor[not set]{0.000000} })"}, // ImageSampleDrefImplicitLod - arrayed ImageAccessCase{"%float 2D 0 1 0 1 Unknown", "%result = OpImageSampleDrefImplicitLod " "%v4float %sampled_image %coords123 %depth", R"( Variable{ Decorations{ SetDecoration{0} BindingDecoration{0} } x_10 uniform_constant __sampler_comparison } Variable{ Decorations{ SetDecoration{2} BindingDecoration{1} } x_20 uniform_constant __depth_texture_2d_array })", R"( TypeConstructor[not set]{ __vec_4__f32 Call[not set]{ Identifier[not set]{textureSampleCompare} ( Identifier[not set]{x_20} Identifier[not set]{x_10} MemberAccessor[not set]{ Identifier[not set]{coords123} Identifier[not set]{xy} } TypeConstructor[not set]{ __i32 MemberAccessor[not set]{ Identifier[not set]{coords123} Identifier[not set]{z} } } ScalarConstructor[not set]{0.200000} ) } ScalarConstructor[not set]{0.000000} ScalarConstructor[not set]{0.000000} ScalarConstructor[not set]{0.000000} })"}, // ImageSampleDrefImplicitLod with ConstOffset ImageAccessCase{ "%float 2D 0 0 0 1 Unknown", "%result = OpImageSampleDrefImplicitLod %v4float " "%sampled_image %coords12 %depth ConstOffset %offsets2d", R"( Variable{ Decorations{ SetDecoration{0} BindingDecoration{0} } x_10 uniform_constant __sampler_comparison } Variable{ Decorations{ SetDecoration{2} BindingDecoration{1} } x_20 uniform_constant __depth_texture_2d })", R"( TypeConstructor[not set]{ __vec_4__f32 Call[not set]{ Identifier[not set]{textureSampleCompare} ( Identifier[not set]{x_20} Identifier[not set]{x_10} Identifier[not set]{coords12} ScalarConstructor[not set]{0.200000} Identifier[not set]{offsets2d} ) } ScalarConstructor[not set]{0.000000} ScalarConstructor[not set]{0.000000} ScalarConstructor[not set]{0.000000} })"}, // ImageSampleDrefImplicitLod arrayed with ConstOffset ImageAccessCase{ "%float 2D 0 1 0 1 Unknown", "%result = OpImageSampleDrefImplicitLod %v4float " "%sampled_image %coords123 %depth ConstOffset %offsets2d", R"( Variable{ Decorations{ SetDecoration{0} BindingDecoration{0} } x_10 uniform_constant __sampler_comparison } Variable{ Decorations{ SetDecoration{2} BindingDecoration{1} } x_20 uniform_constant __depth_texture_2d_array })", R"( TypeConstructor[not set]{ __vec_4__f32 Call[not set]{ Identifier[not set]{textureSampleCompare} ( Identifier[not set]{x_20} Identifier[not set]{x_10} MemberAccessor[not set]{ Identifier[not set]{coords123} Identifier[not set]{xy} } TypeConstructor[not set]{ __i32 MemberAccessor[not set]{ Identifier[not set]{coords123} Identifier[not set]{z} } } ScalarConstructor[not set]{0.200000} Identifier[not set]{offsets2d} ) } ScalarConstructor[not set]{0.000000} ScalarConstructor[not set]{0.000000} ScalarConstructor[not set]{0.000000} })"})); INSTANTIATE_TEST_SUITE_P( ImageSampleExplicitLod, SpvParserTest_SampledImageAccessTest, ::testing::Values( // OpImageSampleExplicitLod - using Lod ImageAccessCase{"%float 2D 0 0 0 1 Unknown", "%result = OpImageSampleExplicitLod " "%v4float %sampled_image %coords12 Lod %float_null", R"( Variable{ Decorations{ SetDecoration{0} BindingDecoration{0} } x_10 uniform_constant __sampler_sampler } Variable{ Decorations{ SetDecoration{2} BindingDecoration{1} } x_20 uniform_constant __sampled_texture_2d__f32 })", R"( Call[not set]{ Identifier[not set]{textureSampleLevel} ( Identifier[not set]{x_20} Identifier[not set]{x_10} Identifier[not set]{coords12} ScalarConstructor[not set]{0.000000} ) })"}, // OpImageSampleExplicitLod arrayed - using Lod ImageAccessCase{"%float 2D 0 1 0 1 Unknown", "%result = OpImageSampleExplicitLod " "%v4float %sampled_image %coords123 Lod %float_null", R"( Variable{ Decorations{ SetDecoration{0} BindingDecoration{0} } x_10 uniform_constant __sampler_sampler } Variable{ Decorations{ SetDecoration{2} BindingDecoration{1} } x_20 uniform_constant __sampled_texture_2d_array__f32 })", R"( Call[not set]{ Identifier[not set]{textureSampleLevel} ( Identifier[not set]{x_20} Identifier[not set]{x_10} MemberAccessor[not set]{ Identifier[not set]{coords123} Identifier[not set]{xy} } TypeConstructor[not set]{ __i32 MemberAccessor[not set]{ Identifier[not set]{coords123} Identifier[not set]{z} } } ScalarConstructor[not set]{0.000000} ) })"}, // OpImageSampleExplicitLod - using Lod and ConstOffset ImageAccessCase{"%float 2D 0 0 0 1 Unknown", "%result = OpImageSampleExplicitLod " "%v4float %sampled_image %coords12 Lod|ConstOffset " "%float_null %offsets2d", R"( Variable{ Decorations{ SetDecoration{0} BindingDecoration{0} } x_10 uniform_constant __sampler_sampler } Variable{ Decorations{ SetDecoration{2} BindingDecoration{1} } x_20 uniform_constant __sampled_texture_2d__f32 })", R"( Call[not set]{ Identifier[not set]{textureSampleLevel} ( Identifier[not set]{x_20} Identifier[not set]{x_10} Identifier[not set]{coords12} ScalarConstructor[not set]{0.000000} Identifier[not set]{offsets2d} ) })"}, // OpImageSampleExplicitLod - using Lod and unsigned ConstOffset // Convert the ConstOffset operand to signed ImageAccessCase{"%float 2D 0 0 0 1 Unknown", "%result = OpImageSampleExplicitLod " "%v4float %sampled_image %coords12 Lod|ConstOffset " "%float_null %u_offsets2d", R"( Variable{ Decorations{ SetDecoration{0} BindingDecoration{0} } x_10 uniform_constant __sampler_sampler } Variable{ Decorations{ SetDecoration{2} BindingDecoration{1} } x_20 uniform_constant __sampled_texture_2d__f32 })", R"( Call[not set]{ Identifier[not set]{textureSampleLevel} ( Identifier[not set]{x_20} Identifier[not set]{x_10} Identifier[not set]{coords12} ScalarConstructor[not set]{0.000000} TypeConstructor[not set]{ __vec_2__i32 Identifier[not set]{u_offsets2d} } ) })"}, // OpImageSampleExplicitLod arrayed - using Lod and ConstOffset ImageAccessCase{"%float 2D 0 1 0 1 Unknown", "%result = OpImageSampleExplicitLod " "%v4float %sampled_image %coords123 Lod|ConstOffset " "%float_null %offsets2d", R"( Variable{ Decorations{ SetDecoration{0} BindingDecoration{0} } x_10 uniform_constant __sampler_sampler } Variable{ Decorations{ SetDecoration{2} BindingDecoration{1} } x_20 uniform_constant __sampled_texture_2d_array__f32 })", R"( Call[not set]{ Identifier[not set]{textureSampleLevel} ( Identifier[not set]{x_20} Identifier[not set]{x_10} MemberAccessor[not set]{ Identifier[not set]{coords123} Identifier[not set]{xy} } TypeConstructor[not set]{ __i32 MemberAccessor[not set]{ Identifier[not set]{coords123} Identifier[not set]{z} } } ScalarConstructor[not set]{0.000000} Identifier[not set]{offsets2d} ) })"}, // OpImageSampleExplicitLod - using Grad ImageAccessCase{ "%float 2D 0 0 0 1 Unknown", "%result = OpImageSampleExplicitLod " "%v4float %sampled_image %coords12 Grad %float_7 %float_null", R"( Variable{ Decorations{ SetDecoration{0} BindingDecoration{0} } x_10 uniform_constant __sampler_sampler } Variable{ Decorations{ SetDecoration{2} BindingDecoration{1} } x_20 uniform_constant __sampled_texture_2d__f32 })", R"( Call[not set]{ Identifier[not set]{textureSampleGrad} ( Identifier[not set]{x_20} Identifier[not set]{x_10} Identifier[not set]{coords12} ScalarConstructor[not set]{7.000000} ScalarConstructor[not set]{0.000000} ) })"}, // OpImageSampleExplicitLod arrayed - using Grad ImageAccessCase{ "%float 2D 0 1 0 1 Unknown", "%result = OpImageSampleExplicitLod " "%v4float %sampled_image %coords123 Grad %float_7 %float_null", R"( Variable{ Decorations{ SetDecoration{0} BindingDecoration{0} } x_10 uniform_constant __sampler_sampler } Variable{ Decorations{ SetDecoration{2} BindingDecoration{1} } x_20 uniform_constant __sampled_texture_2d_array__f32 })", R"( Call[not set]{ Identifier[not set]{textureSampleGrad} ( Identifier[not set]{x_20} Identifier[not set]{x_10} MemberAccessor[not set]{ Identifier[not set]{coords123} Identifier[not set]{xy} } TypeConstructor[not set]{ __i32 MemberAccessor[not set]{ Identifier[not set]{coords123} Identifier[not set]{z} } } ScalarConstructor[not set]{7.000000} ScalarConstructor[not set]{0.000000} ) })"}, // OpImageSampleExplicitLod - using Grad and ConstOffset ImageAccessCase{"%float 2D 0 0 0 1 Unknown", "%result = OpImageSampleExplicitLod " "%v4float %sampled_image %coords12 Grad|ConstOffset " "%float_7 %float_null %offsets2d", R"( Variable{ Decorations{ SetDecoration{0} BindingDecoration{0} } x_10 uniform_constant __sampler_sampler } Variable{ Decorations{ SetDecoration{2} BindingDecoration{1} } x_20 uniform_constant __sampled_texture_2d__f32 })", R"( Call[not set]{ Identifier[not set]{textureSampleGrad} ( Identifier[not set]{x_20} Identifier[not set]{x_10} Identifier[not set]{coords12} ScalarConstructor[not set]{7.000000} ScalarConstructor[not set]{0.000000} Identifier[not set]{offsets2d} ) })"}, // OpImageSampleExplicitLod - using Grad and unsigned ConstOffset ImageAccessCase{"%float 2D 0 0 0 1 Unknown", "%result = OpImageSampleExplicitLod " "%v4float %sampled_image %coords12 Grad|ConstOffset " "%float_7 %float_null %u_offsets2d", R"( Variable{ Decorations{ SetDecoration{0} BindingDecoration{0} } x_10 uniform_constant __sampler_sampler } Variable{ Decorations{ SetDecoration{2} BindingDecoration{1} } x_20 uniform_constant __sampled_texture_2d__f32 })", R"( Call[not set]{ Identifier[not set]{textureSampleGrad} ( Identifier[not set]{x_20} Identifier[not set]{x_10} Identifier[not set]{coords12} ScalarConstructor[not set]{7.000000} ScalarConstructor[not set]{0.000000} TypeConstructor[not set]{ __vec_2__i32 Identifier[not set]{u_offsets2d} } ) })"}, // OpImageSampleExplicitLod arrayed - using Grad and ConstOffset ImageAccessCase{"%float 2D 0 1 0 1 Unknown", "%result = OpImageSampleExplicitLod " "%v4float %sampled_image %coords123 Grad|ConstOffset " "%float_7 %float_null %offsets2d", R"( Variable{ Decorations{ SetDecoration{0} BindingDecoration{0} } x_10 uniform_constant __sampler_sampler } Variable{ Decorations{ SetDecoration{2} BindingDecoration{1} } x_20 uniform_constant __sampled_texture_2d_array__f32 })", R"( Call[not set]{ Identifier[not set]{textureSampleGrad} ( Identifier[not set]{x_20} Identifier[not set]{x_10} MemberAccessor[not set]{ Identifier[not set]{coords123} Identifier[not set]{xy} } TypeConstructor[not set]{ __i32 MemberAccessor[not set]{ Identifier[not set]{coords123} Identifier[not set]{z} } } ScalarConstructor[not set]{7.000000} ScalarConstructor[not set]{0.000000} Identifier[not set]{offsets2d} ) })"}, // OpImageSampleExplicitLod arrayed - using Grad and unsigned // ConstOffset ImageAccessCase{"%float 2D 0 1 0 1 Unknown", "%result = OpImageSampleExplicitLod " "%v4float %sampled_image %coords123 Grad|ConstOffset " "%float_7 %float_null %u_offsets2d", R"( Variable{ Decorations{ SetDecoration{0} BindingDecoration{0} } x_10 uniform_constant __sampler_sampler } Variable{ Decorations{ SetDecoration{2} BindingDecoration{1} } x_20 uniform_constant __sampled_texture_2d_array__f32 })", R"( Call[not set]{ Identifier[not set]{textureSampleGrad} ( Identifier[not set]{x_20} Identifier[not set]{x_10} MemberAccessor[not set]{ Identifier[not set]{coords123} Identifier[not set]{xy} } TypeConstructor[not set]{ __i32 MemberAccessor[not set]{ Identifier[not set]{coords123} Identifier[not set]{z} } } ScalarConstructor[not set]{7.000000} ScalarConstructor[not set]{0.000000} TypeConstructor[not set]{ __vec_2__i32 Identifier[not set]{u_offsets2d} } ) })"})); // Test crbug.com/378: // In WGSL, sampling from depth texture with explicit level of detail // requires the Lod parameter as an unsigned integer. // This corresponds to SPIR-V OpSampleExplicitLod and WGSL textureSampleLevel. INSTANTIATE_TEST_SUITE_P( ImageSampleExplicitLod_DepthTexture, SpvParserTest_SampledImageAccessTest, ::testing::ValuesIn(std::vector{ // Test a non-depth case. // (This is already tested above in the ImageSampleExplicitLod suite, // but I'm repeating here for the contrast with the depth case.) {"%float 2D 0 0 0 1 Unknown", "%result = OpImageSampleExplicitLod %v4float " "%sampled_image %vf12 Lod %f1", R"( Variable{ Decorations{ SetDecoration{0} BindingDecoration{0} } x_10 uniform_constant __sampler_sampler } Variable{ Decorations{ SetDecoration{2} BindingDecoration{1} } x_20 uniform_constant __sampled_texture_2d__f32 })", R"( Call[not set]{ Identifier[not set]{textureSampleLevel} ( Identifier[not set]{x_20} Identifier[not set]{x_10} Identifier[not set]{vf12} Identifier[not set]{f1} ) })"}, // Test a depth case {"%float 2D 1 0 0 1 Unknown", "%result = OpImageSampleExplicitLod %v4float " "%sampled_image %vf12 Lod %f1", R"( Variable{ Decorations{ SetDecoration{0} BindingDecoration{0} } x_10 uniform_constant __sampler_sampler } Variable{ Decorations{ SetDecoration{2} BindingDecoration{1} } x_20 uniform_constant __depth_texture_2d })", R"( TypeConstructor[not set]{ __vec_4__f32 Call[not set]{ Identifier[not set]{textureSampleLevel} ( Identifier[not set]{x_20} Identifier[not set]{x_10} Identifier[not set]{vf12} TypeConstructor[not set]{ __i32 Identifier[not set]{f1} } ) } ScalarConstructor[not set]{0.000000} ScalarConstructor[not set]{0.000000} ScalarConstructor[not set]{0.000000} })"}})); using SpvParserTest_ImageAccessTest = SpvParserTestBase<::testing::TestWithParam>; TEST_P(SpvParserTest_ImageAccessTest, Variable) { // In this test harness, we only create an image. const auto assembly = Preamble() + R"( OpEntryPoint Fragment %main "main" OpExecutionMode %main OriginUpperLeft OpName %f1 "f1" OpName %vf12 "vf12" OpName %vf123 "vf123" OpName %vf1234 "vf1234" OpName %u1 "u1" OpName %vu12 "vu12" OpName %vu123 "vu123" OpName %vu1234 "vu1234" OpName %i1 "i1" OpName %vi12 "vi12" OpName %vi123 "vi123" OpName %vi1234 "vi1234" OpName %offsets2d "offsets2d" OpDecorate %20 DescriptorSet 2 OpDecorate %20 Binding 1 )" + CommonBasicTypes() + R"( %im_ty = OpTypeImage )" + GetParam().spirv_image_type_details + R"( %ptr_im_ty = OpTypePointer UniformConstant %im_ty %20 = OpVariable %ptr_im_ty UniformConstant %main = OpFunction %void None %voidfn %entry = OpLabel %f1 = OpCopyObject %float %float_1 %vf12 = OpCopyObject %v2float %the_vf12 %vf123 = OpCopyObject %v3float %the_vf123 %vf1234 = OpCopyObject %v4float %the_vf1234 %i1 = OpCopyObject %int %int_1 %vi12 = OpCopyObject %v2int %the_vi12 %vi123 = OpCopyObject %v3int %the_vi123 %vi1234 = OpCopyObject %v4int %the_vi1234 %u1 = OpCopyObject %uint %uint_1 %vu12 = OpCopyObject %v2uint %the_vu12 %vu123 = OpCopyObject %v3uint %the_vu123 %vu1234 = OpCopyObject %v4uint %the_vu1234 %value_offset = OpCompositeConstruct %v2int %int_3 %int_4 %offsets2d = OpCopyObject %v2int %value_offset %im = OpLoad %im_ty %20 )" + GetParam().spirv_image_access + R"( OpReturn OpFunctionEnd )"; auto p = parser(test::Assemble(assembly)); ASSERT_TRUE(p->BuildAndParseInternalModule()) << p->error() << assembly; EXPECT_TRUE(p->error().empty()) << p->error(); const auto module = Demangler().Demangle(p->get_module(), p->get_module().to_str()); EXPECT_THAT(module, HasSubstr(GetParam().var_decl)) << "DECLARATIONS ARE BAD " << module; EXPECT_THAT(module, HasSubstr(GetParam().texture_builtin)) << "TEXTURE BUILTIN IS BAD " << module << assembly; } INSTANTIATE_TEST_SUITE_P( ImageWrite_OptionalParams, SpvParserTest_ImageAccessTest, ::testing::ValuesIn(std::vector{ // OpImageWrite with no extra params {"%float 2D 0 0 0 2 Rgba32f", "OpImageWrite %im %vi12 %vf1234", R"( Variable{ Decorations{ SetDecoration{2} BindingDecoration{1} } x_20 uniform_constant __storage_texture_write_only_2d_rgba32float })", R"(Call[not set]{ Identifier[not set]{textureStore} ( Identifier[not set]{x_20} Identifier[not set]{vi12} Identifier[not set]{vf1234} ) })"}})); INSTANTIATE_TEST_SUITE_P( // SPIR-V's texel parameter is a 4-element vector with the component // type matching the sampled type. WGSL's texel parameter might be // scalar or vector, depending on the number of channels in the texture. ImageWrite_ConvertTexelOperand_Arity, SpvParserTest_ImageAccessTest, ::testing::ValuesIn(std::vector{ // Source 1 component, dest 1 component {"%float 2D 0 0 0 2 R32f", "OpImageWrite %im %vi12 %f1", R"( Variable{ Decorations{ SetDecoration{2} BindingDecoration{1} } x_20 uniform_constant __storage_texture_write_only_2d_r32float })", R"(Call[not set]{ Identifier[not set]{textureStore} ( Identifier[not set]{x_20} Identifier[not set]{vi12} Identifier[not set]{f1} ) })"}, // Source 2 component, dest 1 component {"%float 2D 0 0 0 2 R32f", "OpImageWrite %im %vi12 %vf12", R"( Variable{ Decorations{ SetDecoration{2} BindingDecoration{1} } x_20 uniform_constant __storage_texture_write_only_2d_r32float })", R"(Call[not set]{ Identifier[not set]{textureStore} ( Identifier[not set]{x_20} Identifier[not set]{vi12} MemberAccessor[not set]{ Identifier[not set]{vf12} Identifier[not set]{x} } ) })"}, // Source 3 component, dest 1 component {"%float 2D 0 0 0 2 R32f", "OpImageWrite %im %vi12 %vf123", R"( Variable{ Decorations{ SetDecoration{2} BindingDecoration{1} } x_20 uniform_constant __storage_texture_write_only_2d_r32float })", R"(Call[not set]{ Identifier[not set]{textureStore} ( Identifier[not set]{x_20} Identifier[not set]{vi12} MemberAccessor[not set]{ Identifier[not set]{vf123} Identifier[not set]{x} } ) })"}, // Source 4 component, dest 1 component {"%float 2D 0 0 0 2 R32f", "OpImageWrite %im %vi12 %vf1234", R"( Variable{ Decorations{ SetDecoration{2} BindingDecoration{1} } x_20 uniform_constant __storage_texture_write_only_2d_r32float })", R"(Call[not set]{ Identifier[not set]{textureStore} ( Identifier[not set]{x_20} Identifier[not set]{vi12} MemberAccessor[not set]{ Identifier[not set]{vf1234} Identifier[not set]{x} } ) })"}, // Source 2 component, dest 2 component {"%float 2D 0 0 0 2 Rg32f", "OpImageWrite %im %vi12 %vf12", R"( Variable{ Decorations{ SetDecoration{2} BindingDecoration{1} } x_20 uniform_constant __storage_texture_write_only_2d_rg32float })", R"(Call[not set]{ Identifier[not set]{textureStore} ( Identifier[not set]{x_20} Identifier[not set]{vi12} Identifier[not set]{vf12} ) })"}, // Source 3 component, dest 2 component {"%float 2D 0 0 0 2 Rg32f", "OpImageWrite %im %vi12 %vf123", R"( Variable{ Decorations{ SetDecoration{2} BindingDecoration{1} } x_20 uniform_constant __storage_texture_write_only_2d_rg32float })", R"(Call[not set]{ Identifier[not set]{textureStore} ( Identifier[not set]{x_20} Identifier[not set]{vi12} MemberAccessor[not set]{ Identifier[not set]{vf123} Identifier[not set]{xy} } ) })"}, // Source 4 component, dest 2 component {"%float 2D 0 0 0 2 Rg32f", "OpImageWrite %im %vi12 %vf1234", R"( Variable{ Decorations{ SetDecoration{2} BindingDecoration{1} } x_20 uniform_constant __storage_texture_write_only_2d_rg32float })", R"(Call[not set]{ Identifier[not set]{textureStore} ( Identifier[not set]{x_20} Identifier[not set]{vi12} MemberAccessor[not set]{ Identifier[not set]{vf1234} Identifier[not set]{xy} } ) })"}, // WGSL does not support 3-component storage textures. // Source 4 component, dest 4 component {"%float 2D 0 0 0 2 Rgba32f", "OpImageWrite %im %vi12 %vf1234", R"( Variable{ Decorations{ SetDecoration{2} BindingDecoration{1} } x_20 uniform_constant __storage_texture_write_only_2d_rgba32float })", R"(Call[not set]{ Identifier[not set]{textureStore} ( Identifier[not set]{x_20} Identifier[not set]{vi12} Identifier[not set]{vf1234} ) })"}})); TEST_F(SpvParserTest, ImageWrite_TooFewSrcTexelComponents_1_vs_4) { const auto assembly = Preamble() + R"( OpEntryPoint Fragment %main "main" OpExecutionMode %main OriginUpperLeft OpName %f1 "f1" OpName %coords12 "coords12" OpDecorate %20 DescriptorSet 2 OpDecorate %20 Binding 1 )" + CommonBasicTypes() + R"( %im_ty = OpTypeImage %void 2D 0 0 0 2 Rgba32f %ptr_im_ty = OpTypePointer UniformConstant %im_ty %20 = OpVariable %ptr_im_ty UniformConstant %main = OpFunction %void None %voidfn %entry = OpLabel %f1 = OpCopyObject %float %float_1 %coords12 = OpCopyObject %v2float %the_vf12 %im = OpLoad %im_ty %20 OpImageWrite %im %coords12 %f1 OpReturn OpFunctionEnd )"; auto p = parser(test::Assemble(assembly)); EXPECT_FALSE(p->BuildAndParseInternalModule()); EXPECT_THAT(p->error(), Eq("texel has too few components for storage texture: 1 provided " "but 4 required, in: OpImageWrite %52 %3 %2")) << p->error(); } TEST_F(SpvParserTest, ImageWrite_ThreeComponentStorageTexture_IsError) { // SPIR-V doesn't allow a 3-element storage texture format. const auto assembly = Preamble() + R"( OpEntryPoint Fragment %main "main" OpExecutionMode %main OriginUpperLeft OpName %vf123 "vf123" OpName %coords12 "coords12" OpDecorate %20 DescriptorSet 2 OpDecorate %20 Binding 1 )" + CommonBasicTypes() + R"( %im_ty = OpTypeImage %void 2D 0 0 0 2 Rgb32f %ptr_im_ty = OpTypePointer UniformConstant %im_ty %20 = OpVariable %ptr_im_ty UniformConstant %main = OpFunction %void None %voidfn %entry = OpLabel %vf123 = OpCopyObject %v3float %the_vf123 %coords12 = OpCopyObject %v2float %the_vf12 %im = OpLoad %im_ty %20 OpImageWrite %im %coords12 %vf123 OpReturn OpFunctionEnd )"; auto error = test::AssembleFailure(assembly); EXPECT_THAT(error, HasSubstr("Invalid image format 'Rgb32f'")); } TEST_F(SpvParserTest, ImageWrite_FloatDest_IntegralSrc_IsError) { const auto assembly = Preamble() + R"( OpEntryPoint Fragment %main "main" OpExecutionMode %main OriginUpperLeft OpName %coords12 "coords12" OpDecorate %20 DescriptorSet 2 OpDecorate %20 Binding 1 )" + CommonBasicTypes() + R"( %im_ty = OpTypeImage %void 2D 0 0 0 2 R32f %ptr_im_ty = OpTypePointer UniformConstant %im_ty %20 = OpVariable %ptr_im_ty UniformConstant %main = OpFunction %void None %voidfn %entry = OpLabel %f1 = OpCopyObject %float %float_1 %coords12 = OpCopyObject %v2float %the_vf12 %im = OpLoad %im_ty %20 OpImageWrite %im %coords12 %uint_0 OpReturn OpFunctionEnd )"; auto p = parser(test::Assemble(assembly)); EXPECT_FALSE(p->BuildAndParseInternalModule()); EXPECT_THAT(p->error(), Eq("can only write float or float vector to a storage image with " "floating texel format: OpImageWrite %52 %2 %13")) << p->error(); } TEST_F(SpvParserTest, ImageWrite_IntegralDest_FloatSrc_IsError) { const auto assembly = Preamble() + R"( OpEntryPoint Fragment %main "main" OpExecutionMode %main OriginUpperLeft OpName %coords12 "coords12" OpDecorate %20 DescriptorSet 2 OpDecorate %20 Binding 1 )" + CommonBasicTypes() + R"( %im_ty = OpTypeImage %void 2D 0 0 0 2 R32ui %ptr_im_ty = OpTypePointer UniformConstant %im_ty %20 = OpVariable %ptr_im_ty UniformConstant %main = OpFunction %void None %voidfn %entry = OpLabel %f1 = OpCopyObject %float %float_1 %coords12 = OpCopyObject %v2float %f1 %im = OpLoad %im_ty %20 OpImageWrite %im %coords12 %f1 OpReturn OpFunctionEnd )"; auto p = parser(test::Assemble(assembly)); EXPECT_FALSE(p->BuildAndParseInternalModule()); EXPECT_THAT(p->error(), Eq("float or float vector can only be written to a storage image " "with floating texel format: OpImageWrite %52 %2 %51")) << p->error(); } INSTANTIATE_TEST_SUITE_P( // Convert texel values when the sampled type of the texture is of the // wrong signedness: // unsigned int channel type -> signed int sampled texture // signed int channel type -> unsigned int sampled texture // (It is already a SPIR-V validation rule that floating point texels // must already be used with textures of floating point sampled types) ImageWrite_ConvertTexelOperand_Signedness, SpvParserTest_ImageAccessTest, ::testing::ValuesIn(std::vector{ // Sampled type is unsigned int, texel is unsigned int {"%uint 2D 0 0 0 2 Rgba32ui", "OpImageWrite %im %vi12 %vu1234", R"( Variable{ Decorations{ SetDecoration{2} BindingDecoration{1} } x_20 uniform_constant __storage_texture_write_only_2d_rgba32uint })", R"(Call[not set]{ Identifier[not set]{textureStore} ( Identifier[not set]{x_20} Identifier[not set]{vi12} Identifier[not set]{vu1234} ) })"}, // Sampled type is unsigned int, texel is signed int {"%uint 2D 0 0 0 2 Rgba32ui", "OpImageWrite %im %vi12 %vi1234", R"( Variable{ Decorations{ SetDecoration{2} BindingDecoration{1} } x_20 uniform_constant __storage_texture_write_only_2d_rgba32uint })", R"(Call[not set]{ Identifier[not set]{textureStore} ( Identifier[not set]{x_20} Identifier[not set]{vi12} Bitcast[not set]<__vec_4__u32>{ Identifier[not set]{vi1234} } ) })"}, // Sampled type is signed int, texel is unsigned int {"%int 2D 0 0 0 2 Rgba32i", "OpImageWrite %im %vi12 %vu1234", R"( Variable{ Decorations{ SetDecoration{2} BindingDecoration{1} } x_20 uniform_constant __storage_texture_write_only_2d_rgba32sint })", R"(Call[not set]{ Identifier[not set]{textureStore} ( Identifier[not set]{x_20} Identifier[not set]{vi12} Bitcast[not set]<__vec_4__i32>{ Identifier[not set]{vu1234} } ) })"}, // Sampled type is signed int, texel is signed int {"%int 2D 0 0 0 2 Rgba32i", "OpImageWrite %im %vi12 %vi1234", R"( Variable{ Decorations{ SetDecoration{2} BindingDecoration{1} } x_20 uniform_constant __storage_texture_write_only_2d_rgba32sint })", R"(Call[not set]{ Identifier[not set]{textureStore} ( Identifier[not set]{x_20} Identifier[not set]{vi12} Identifier[not set]{vi1234} ) })"}})); INSTANTIATE_TEST_SUITE_P( ImageRead_OptionalParams, SpvParserTest_ImageAccessTest, ::testing::ValuesIn(std::vector{ // OpImageRead with no extra params {"%float 2D 0 0 0 2 Rgba32f", "%99 = OpImageRead %v4float %im %vi12", R"(Variable{ Decorations{ SetDecoration{2} BindingDecoration{1} } x_20 uniform_constant __storage_texture_read_only_2d_rgba32float })", R"(VariableDeclStatement{ VariableConst{ x_99 none __vec_4__f32 { Call[not set]{ Identifier[not set]{textureLoad} ( Identifier[not set]{x_20} Identifier[not set]{vi12} ) } } } })"}})); INSTANTIATE_TEST_SUITE_P( ImageFetch_OptionalParams, SpvParserTest_ImageAccessTest, ::testing::ValuesIn(std::vector{ // OpImageFetch with no extra params {"%float 2D 0 0 0 1 Unknown", "%99 = OpImageFetch %v4float %im %vi12", R"(Variable{ Decorations{ SetDecoration{2} BindingDecoration{1} } x_20 uniform_constant __sampled_texture_2d__f32 })", R"(VariableDeclStatement{ VariableConst{ x_99 none __vec_4__f32 { Call[not set]{ Identifier[not set]{textureLoad} ( Identifier[not set]{x_20} Identifier[not set]{vi12} ) } } } })"}, // OpImageFetch with explicit level {"%float 2D 0 0 0 1 Unknown", "%99 = OpImageFetch %v4float %im %vi12 Lod %int_3", R"(Variable{ Decorations{ SetDecoration{2} BindingDecoration{1} } x_20 uniform_constant __sampled_texture_2d__f32 })", R"(VariableDeclStatement{ VariableConst{ x_99 none __vec_4__f32 { Call[not set]{ Identifier[not set]{textureLoad} ( Identifier[not set]{x_20} Identifier[not set]{vi12} ScalarConstructor[not set]{3} ) } } } })"}})); INSTANTIATE_TEST_SUITE_P( ImageFetch_Multisampled, SpvParserTest_ImageAccessTest, ::testing::ValuesIn(std::vector{ // SPIR-V requires a Sample image operand when operating on a // multisampled image. // ImageFetch non-arrayed {"%float 2D 0 0 1 1 Unknown", "%99 = OpImageFetch %v4float %im %vi12 Sample %i1", R"(Variable{ Decorations{ SetDecoration{2} BindingDecoration{1} } x_20 uniform_constant __multisampled_texture_2d__f32 })", R"(VariableDeclStatement{ VariableConst{ x_99 none __vec_4__f32 { Call[not set]{ Identifier[not set]{textureLoad} ( Identifier[not set]{x_20} Identifier[not set]{vi12} Identifier[not set]{i1} ) } } } })"}, // ImageFetch arrayed {"%float 2D 0 1 1 1 Unknown", "%99 = OpImageFetch %v4float %im %vi123 Sample %i1", R"(Variable{ Decorations{ SetDecoration{2} BindingDecoration{1} } x_20 uniform_constant __multisampled_texture_2d_array__f32 })", R"(VariableDeclStatement{ VariableConst{ x_99 none __vec_4__f32 { Call[not set]{ Identifier[not set]{textureLoad} ( Identifier[not set]{x_20} MemberAccessor[not set]{ Identifier[not set]{vi123} Identifier[not set]{xy} } MemberAccessor[not set]{ Identifier[not set]{vi123} Identifier[not set]{z} } Identifier[not set]{i1} ) } } } })"}})); INSTANTIATE_TEST_SUITE_P( ImageFetch_Multisampled_ConvertSampleOperand, SpvParserTest_ImageAccessTest, ::testing::ValuesIn(std::vector{ {"%float 2D 0 0 1 1 Unknown", "%99 = OpImageFetch %v4float %im %vi12 Sample %u1", R"(Variable{ Decorations{ SetDecoration{2} BindingDecoration{1} } x_20 uniform_constant __multisampled_texture_2d__f32 })", R"(VariableDeclStatement{ VariableConst{ x_99 none __vec_4__f32 { Call[not set]{ Identifier[not set]{textureLoad} ( Identifier[not set]{x_20} Identifier[not set]{vi12} TypeConstructor[not set]{ __i32 Identifier[not set]{u1} } ) } } } })"}})); INSTANTIATE_TEST_SUITE_P( ConvertResultSignedness, SpvParserTest_SampledImageAccessTest, ::testing::ValuesIn(std::vector{ // Valid SPIR-V only has: // float scalar sampled type vs. floating result // integral scalar sampled type vs. integral result // Any of the sampling, reading, or fetching use the same codepath. // We'll test with: // OpImageFetch // OpImageRead // OpImageSampleImplicitLod - representative of sampling // // OpImageRead // // OpImageFetch requires no conversion, float -> v4float {"%float 2D 0 0 0 1 Unknown", "%99 = OpImageFetch %v4float %im %vi12", R"(Variable{ Decorations{ SetDecoration{2} BindingDecoration{1} } x_20 uniform_constant __sampled_texture_2d__f32 })", R"(VariableDeclStatement{ VariableConst{ x_99 none __vec_4__f32 { Call[not set]{ Identifier[not set]{textureLoad} ( Identifier[not set]{x_20} Identifier[not set]{vi12} ) } } } })"}, // OpImageFetch requires no conversion, uint -> v4uint {"%uint 2D 0 0 0 1 Unknown", "%99 = OpImageFetch %v4uint %im %vi12", R"(Variable{ Decorations{ SetDecoration{2} BindingDecoration{1} } x_20 uniform_constant __sampled_texture_2d__u32 })", R"(VariableDeclStatement{ VariableConst{ x_99 none __vec_4__u32 { Call[not set]{ Identifier[not set]{textureLoad} ( Identifier[not set]{x_20} Identifier[not set]{vi12} ) } } } })"}, // OpImageFetch requires conversion, uint -> v4int {"%uint 2D 0 0 0 1 Unknown", "%99 = OpImageFetch %v4int %im %vi12", R"(Variable{ Decorations{ SetDecoration{2} BindingDecoration{1} } x_20 uniform_constant __sampled_texture_2d__u32 })", R"(VariableDeclStatement{ VariableConst{ x_99 none __vec_4__i32 { Bitcast[not set]<__vec_4__i32>{ Call[not set]{ Identifier[not set]{textureLoad} ( Identifier[not set]{x_20} Identifier[not set]{vi12} ) } } } } })"}, // OpImageFetch requires no conversion, int -> v4int {"%int 2D 0 0 0 1 Unknown", "%99 = OpImageFetch %v4int %im %vi12", R"(Variable{ Decorations{ SetDecoration{2} BindingDecoration{1} } x_20 uniform_constant __sampled_texture_2d__i32 })", R"(VariableDeclStatement{ VariableConst{ x_99 none __vec_4__i32 { Call[not set]{ Identifier[not set]{textureLoad} ( Identifier[not set]{x_20} Identifier[not set]{vi12} ) } } } })"}, // OpImageFetch requires conversion, int -> v4uint {"%int 2D 0 0 0 1 Unknown", "%99 = OpImageFetch %v4uint %im %vi12", R"(Variable{ Decorations{ SetDecoration{2} BindingDecoration{1} } x_20 uniform_constant __sampled_texture_2d__i32 })", R"(VariableDeclStatement{ VariableConst{ x_99 none __vec_4__u32 { Bitcast[not set]<__vec_4__u32>{ Call[not set]{ Identifier[not set]{textureLoad} ( Identifier[not set]{x_20} Identifier[not set]{vi12} ) } } } } })"}, // // OpImageRead // // OpImageRead requires no conversion, float -> v4float {"%float 2D 0 0 0 1 Rgba32f", "%99 = OpImageRead %v4float %im %vi12", R"(Variable{ Decorations{ SetDecoration{2} BindingDecoration{1} } x_20 uniform_constant __storage_texture_read_only_2d_rgba32float })", R"(VariableDeclStatement{ VariableConst{ x_99 none __vec_4__f32 { Call[not set]{ Identifier[not set]{textureLoad} ( Identifier[not set]{x_20} Identifier[not set]{vi12} ) } } } })"}, // OpImageRead requires no conversion, uint -> v4uint {"%uint 2D 0 0 0 1 Rgba32ui", "%99 = OpImageRead %v4uint %im %vi12", R"(Variable{ Decorations{ SetDecoration{2} BindingDecoration{1} } x_20 uniform_constant __storage_texture_read_only_2d_rgba32uint })", R"(VariableDeclStatement{ VariableConst{ x_99 none __vec_4__u32 { Call[not set]{ Identifier[not set]{textureLoad} ( Identifier[not set]{x_20} Identifier[not set]{vi12} ) } } } })"}, // OpImageRead requires conversion, uint -> v4int {"%uint 2D 0 0 0 1 Rgba32ui", "%99 = OpImageRead %v4int %im %vi12", R"(Variable{ Decorations{ SetDecoration{2} BindingDecoration{1} } x_20 uniform_constant __storage_texture_read_only_2d_rgba32uint })", R"(VariableDeclStatement{ VariableConst{ x_99 none __vec_4__i32 { Bitcast[not set]<__vec_4__i32>{ Call[not set]{ Identifier[not set]{textureLoad} ( Identifier[not set]{x_20} Identifier[not set]{vi12} ) } } } } })"}, // OpImageRead requires no conversion, int -> v4int {"%int 2D 0 0 0 1 Rgba32i", "%99 = OpImageRead %v4int %im %vi12", R"(Variable{ Decorations{ SetDecoration{2} BindingDecoration{1} } x_20 uniform_constant __storage_texture_read_only_2d_rgba32sint })", R"(VariableDeclStatement{ VariableConst{ x_99 none __vec_4__i32 { Call[not set]{ Identifier[not set]{textureLoad} ( Identifier[not set]{x_20} Identifier[not set]{vi12} ) } } } })"}, // OpImageRead requires conversion, int -> v4uint {"%int 2D 0 0 0 1 Rgba32i", "%99 = OpImageRead %v4uint %im %vi12", R"(Variable{ Decorations{ SetDecoration{2} BindingDecoration{1} } x_20 uniform_constant __storage_texture_read_only_2d_rgba32sint })", R"(VariableDeclStatement{ VariableConst{ x_99 none __vec_4__u32 { Bitcast[not set]<__vec_4__u32>{ Call[not set]{ Identifier[not set]{textureLoad} ( Identifier[not set]{x_20} Identifier[not set]{vi12} ) } } } } })"}, // // Sampling operations, using OpImageSampleImplicitLod as an example. // WGSL sampling operations only work on textures with a float sampled // component. So we can only test the float -> float (non-conversion) // case. // OpImageSampleImplicitLod requires no conversion, float -> v4float {"%float 2D 0 0 0 1 Unknown", "%99 = OpImageSampleImplicitLod %v4float %sampled_image %vf12", R"( Variable{ Decorations{ SetDecoration{0} BindingDecoration{0} } x_10 uniform_constant __sampler_sampler } Variable{ Decorations{ SetDecoration{2} BindingDecoration{1} } x_20 uniform_constant __sampled_texture_2d__f32 })", R"(VariableDeclStatement{ VariableConst{ x_99 none __vec_4__f32 { Call[not set]{ Identifier[not set]{textureSample} ( Identifier[not set]{x_20} Identifier[not set]{x_10} Identifier[not set]{vf12} ) } } } })"}})); struct ImageCoordsCase { // SPIR-V image type, excluding result ID and opcode std::string spirv_image_type_details; std::string spirv_image_access; std::string expected_error; std::vector expected_expressions; }; inline std::ostream& operator<<(std::ostream& out, const ImageCoordsCase& c) { out << "ImageAccessCase(" << c.spirv_image_type_details << "\n" << c.spirv_image_access << "\n"; for (auto e : c.expected_expressions) { out << e << ","; } out << ")" << std::endl; return out; } using SpvParserTest_ImageCoordsTest = SpvParserTestBase<::testing::TestWithParam>; TEST_P(SpvParserTest_ImageCoordsTest, MakeCoordinateOperandsForImageAccess) { const auto assembly = Preamble() + R"( OpEntryPoint Fragment %100 "main" OpExecutionMode %100 OriginUpperLeft OpName %float_var "float_var" OpName %ptr_float "ptr_float" OpName %i1 "i1" OpName %vi12 "vi12" OpName %vi123 "vi123" OpName %vi1234 "vi1234" OpName %u1 "u1" OpName %vu12 "vu12" OpName %vu123 "vu123" OpName %vu1234 "vu1234" OpName %f1 "f1" OpName %vf12 "vf12" OpName %vf123 "vf123" OpName %vf1234 "vf1234" OpDecorate %10 DescriptorSet 0 OpDecorate %10 Binding 0 OpDecorate %20 DescriptorSet 2 OpDecorate %20 Binding 1 OpDecorate %30 DescriptorSet 0 OpDecorate %30 Binding 1 )" + CommonBasicTypes() + R"( %sampler = OpTypeSampler %ptr_sampler = OpTypePointer UniformConstant %sampler %im_ty = OpTypeImage )" + GetParam().spirv_image_type_details + R"( %ptr_im_ty = OpTypePointer UniformConstant %im_ty %si_ty = OpTypeSampledImage %im_ty %ptr_float = OpTypePointer Function %float %10 = OpVariable %ptr_sampler UniformConstant %20 = OpVariable %ptr_im_ty UniformConstant %30 = OpVariable %ptr_sampler UniformConstant ; comparison sampler, when needed %100 = OpFunction %void None %voidfn %entry = OpLabel %float_var = OpVariable %ptr_float Function %i1 = OpCopyObject %int %int_1 %vi12 = OpCopyObject %v2int %the_vi12 %vi123 = OpCopyObject %v3int %the_vi123 %vi1234 = OpCopyObject %v4int %the_vi1234 %u1 = OpCopyObject %uint %uint_1 %vu12 = OpCopyObject %v2uint %the_vu12 %vu123 = OpCopyObject %v3uint %the_vu123 %vu1234 = OpCopyObject %v4uint %the_vu1234 %f1 = OpCopyObject %float %float_1 %vf12 = OpCopyObject %v2float %the_vf12 %vf123 = OpCopyObject %v3float %the_vf123 %vf1234 = OpCopyObject %v4float %the_vf1234 %sam = OpLoad %sampler %10 %im = OpLoad %im_ty %20 %sampled_image = OpSampledImage %si_ty %im %sam )" + GetParam().spirv_image_access + R"( ; Use an anchor for the cases when the image access doesn't have a result ID. %1000 = OpCopyObject %uint %uint_0 OpReturn OpFunctionEnd )"; auto p = parser(test::Assemble(assembly)); if (!p->BuildAndParseInternalModule()) { EXPECT_THAT(p->error(), StartsWith(GetParam().expected_error)) << assembly; } else { EXPECT_TRUE(p->error().empty()) << p->error(); FunctionEmitter fe(p.get(), *spirv_function(p.get(), 100)); // We actually have to generate the module to cache expressions for the // result IDs, particularly the OpCopyObject fe.Emit(); const spvtools::opt::Instruction* anchor = p->GetInstructionForTest(1000); ASSERT_NE(anchor, nullptr); const spvtools::opt::Instruction& image_access = *(anchor->PreviousNode()); ast::ExpressionList result = fe.MakeCoordinateOperandsForImageAccess(image_access); if (GetParam().expected_error.empty()) { EXPECT_TRUE(fe.success()) << p->error(); EXPECT_TRUE(p->error().empty()); std::vector result_strings; for (auto* expr : result) { ASSERT_NE(expr, nullptr); result_strings.push_back( Demangler().Demangle(p->get_module(), expr->str())); } EXPECT_THAT(result_strings, ::testing::ContainerEq(GetParam().expected_expressions)); } else { EXPECT_FALSE(fe.success()); EXPECT_THAT(p->error(), Eq(GetParam().expected_error)); EXPECT_TRUE(result.empty()); } } } INSTANTIATE_TEST_SUITE_P(Good_1D, SpvParserTest_ImageCoordsTest, ::testing::ValuesIn(std::vector{ {"%float 1D 0 0 0 1 Unknown", "%result = OpImageSampleImplicitLod %v4float " "%sampled_image %f1", "", {"Identifier[not set]{f1}\n"}}, {"%float 1D 0 0 0 1 Unknown", "%result = OpImageSampleImplicitLod %v4float " "%sampled_image %vf12", // one excess arg "", {R"(MemberAccessor[not set]{ Identifier[not set]{vf12} Identifier[not set]{x} } )"}}, {"%float 1D 0 0 0 1 Unknown", "%result = OpImageSampleImplicitLod %v4float " "%sampled_image %vf123", // two excess args "", {R"(MemberAccessor[not set]{ Identifier[not set]{vf123} Identifier[not set]{x} } )"}}, {"%float 1D 0 0 0 1 Unknown", "%result = OpImageSampleImplicitLod %v4float " "%sampled_image %vf1234", // three excess args "", {R"(MemberAccessor[not set]{ Identifier[not set]{vf1234} Identifier[not set]{x} } )"}}})); INSTANTIATE_TEST_SUITE_P(Good_1DArray, SpvParserTest_ImageCoordsTest, ::testing::ValuesIn(std::vector{ {"%float 1D 0 1 0 1 Unknown", "%result = OpImageSampleImplicitLod %v4float " "%sampled_image %vf12", "", { R"(MemberAccessor[not set]{ Identifier[not set]{vf12} Identifier[not set]{x} } )", R"(TypeConstructor[not set]{ __i32 MemberAccessor[not set]{ Identifier[not set]{vf12} Identifier[not set]{y} } } )"}}, {"%float 1D 0 1 0 1 Unknown", "%result = OpImageSampleImplicitLod %v4float " "%sampled_image %vf123", // one excess arg "", { R"(MemberAccessor[not set]{ Identifier[not set]{vf123} Identifier[not set]{x} } )", R"(TypeConstructor[not set]{ __i32 MemberAccessor[not set]{ Identifier[not set]{vf123} Identifier[not set]{y} } } )"}}, {"%float 1D 0 1 0 1 Unknown", "%result = OpImageSampleImplicitLod %v4float " "%sampled_image %vf1234", // two excess args "", { R"(MemberAccessor[not set]{ Identifier[not set]{vf1234} Identifier[not set]{x} } )", R"(TypeConstructor[not set]{ __i32 MemberAccessor[not set]{ Identifier[not set]{vf1234} Identifier[not set]{y} } } )"}}})); INSTANTIATE_TEST_SUITE_P(Good_2D, SpvParserTest_ImageCoordsTest, ::testing::ValuesIn(std::vector{ {"%float 2D 0 0 0 1 Unknown", "%result = OpImageSampleImplicitLod %v4float " "%sampled_image %vf12", "", {"Identifier[not set]{vf12}\n"}}, {"%float 2D 0 0 0 1 Unknown", "%result = OpImageSampleImplicitLod %v4float " "%sampled_image %vf123", // one excess arg "", {R"(MemberAccessor[not set]{ Identifier[not set]{vf123} Identifier[not set]{xy} } )"}}, {"%float 2D 0 0 0 1 Unknown", "%result = OpImageSampleImplicitLod %v4float " "%sampled_image %vf1234", // two excess args "", {R"(MemberAccessor[not set]{ Identifier[not set]{vf1234} Identifier[not set]{xy} } )"}}})); INSTANTIATE_TEST_SUITE_P(Good_2DArray, SpvParserTest_ImageCoordsTest, ::testing::ValuesIn(std::vector{ {"%float 2D 0 1 0 1 Unknown", "%result = OpImageSampleImplicitLod %v4float " "%sampled_image %vf123", "", { R"(MemberAccessor[not set]{ Identifier[not set]{vf123} Identifier[not set]{xy} } )", R"(TypeConstructor[not set]{ __i32 MemberAccessor[not set]{ Identifier[not set]{vf123} Identifier[not set]{z} } } )"}}, {"%float 2D 0 1 0 1 Unknown", "%result = OpImageSampleImplicitLod %v4float " "%sampled_image %vf1234", // one excess arg "", { R"(MemberAccessor[not set]{ Identifier[not set]{vf1234} Identifier[not set]{xy} } )", R"(TypeConstructor[not set]{ __i32 MemberAccessor[not set]{ Identifier[not set]{vf1234} Identifier[not set]{z} } } )"}}})); INSTANTIATE_TEST_SUITE_P(Good_3D, SpvParserTest_ImageCoordsTest, ::testing::ValuesIn(std::vector{ {"%float 3D 0 0 0 1 Unknown", "%result = OpImageSampleImplicitLod " "%v4float " "%sampled_image %vf123", "", {"Identifier[not set]{vf123}\n"}}, {"%float 3D 0 0 0 1 Unknown", "%result = OpImageSampleImplicitLod " "%v4float " "%sampled_image %vf1234", // one excess // arg "", {R"(MemberAccessor[not set]{ Identifier[not set]{vf1234} Identifier[not set]{xyz} } )"}}})); INSTANTIATE_TEST_SUITE_P(Good_Cube, SpvParserTest_ImageCoordsTest, ::testing::ValuesIn(std::vector{ {"%float Cube 0 0 0 1 Unknown", "%result = OpImageSampleImplicitLod " "%v4float " "%sampled_image %vf123", "", {"Identifier[not set]{vf123}\n"}}, {"%float Cube 0 0 0 1 Unknown", "%result = OpImageSampleImplicitLod " "%v4float " "%sampled_image %vf1234", // one excess // arg "", {R"(MemberAccessor[not set]{ Identifier[not set]{vf1234} Identifier[not set]{xyz} } )"}}})); INSTANTIATE_TEST_SUITE_P(Good_CubeArray, SpvParserTest_ImageCoordsTest, ::testing::ValuesIn(std::vector{ {"%float Cube 0 1 0 1 Unknown", "%result = OpImageSampleImplicitLod " "%v4float " "%sampled_image %vf1234", "", {R"(MemberAccessor[not set]{ Identifier[not set]{vf1234} Identifier[not set]{xyz} } )", R"(TypeConstructor[not set]{ __i32 MemberAccessor[not set]{ Identifier[not set]{vf1234} Identifier[not set]{w} } } )"}}})); INSTANTIATE_TEST_SUITE_P( PreserveFloatCoords_NonArrayed, // In SPIR-V, sampling and dref sampling operations use floating point // coordinates. Prove that we preserve floating point-ness. // Test across all such instructions. SpvParserTest_ImageCoordsTest, ::testing::ValuesIn(std::vector{ // Scalar cases {"%float 1D 0 0 0 1 Unknown", "%result = OpImageSampleImplicitLod %v4float %sampled_image %f1", "", {"Identifier[not set]{f1}\n"}}, {"%float 1D 0 0 0 1 Unknown", "%result = OpImageSampleExplicitLod %v4float %sampled_image %f1 Lod " "%f1", "", {"Identifier[not set]{f1}\n"}}, // WGSL does not support depth textures with 1D coordinates // Vector cases {"%float 2D 0 0 0 1 Unknown", "%result = OpImageSampleImplicitLod %v4float %sampled_image %vf12", "", {"Identifier[not set]{vf12}\n"}}, {"%float 2D 0 0 0 1 Unknown", "%result = OpImageSampleExplicitLod %v4float %sampled_image %vf12 Lod " "%f1", "", {"Identifier[not set]{vf12}\n"}}, {"%float 2D 1 0 0 1 Unknown", "%result = OpImageSampleDrefImplicitLod %v4float %sampled_image %vf12 " "%depth", "", {"Identifier[not set]{vf12}\n"}}, {"%float 2D 1 0 0 1 Unknown", "%result = OpImageSampleDrefExplicitLod %v4float %sampled_image %vf12 " "%depth Lod %f1", "", {"Identifier[not set]{vf12}\n"}}, })); INSTANTIATE_TEST_SUITE_P( PreserveFloatCoords_Arrayed, // In SPIR-V, sampling and dref sampling operations use floating point // coordinates. Prove that we preserve floating point-ness of the // coordinate part, but convert the array index to signed integer. Test // across all such instructions. SpvParserTest_ImageCoordsTest, ::testing::ValuesIn(std::vector{ {"%float 2D 0 1 0 1 Unknown", "%result = OpImageSampleImplicitLod %v4float %sampled_image %vf123", "", { R"(MemberAccessor[not set]{ Identifier[not set]{vf123} Identifier[not set]{xy} } )", R"(TypeConstructor[not set]{ __i32 MemberAccessor[not set]{ Identifier[not set]{vf123} Identifier[not set]{z} } } )"}}, {"%float 2D 0 1 0 1 Unknown", "%result = OpImageSampleExplicitLod %v4float %sampled_image %vf123 " "Lod %f1", "", { R"(MemberAccessor[not set]{ Identifier[not set]{vf123} Identifier[not set]{xy} } )", R"(TypeConstructor[not set]{ __i32 MemberAccessor[not set]{ Identifier[not set]{vf123} Identifier[not set]{z} } } )"}}, {"%float 2D 1 1 0 1 Unknown", "%result = OpImageSampleDrefImplicitLod %v4float %sampled_image " "%vf123 %depth", "", { R"(MemberAccessor[not set]{ Identifier[not set]{vf123} Identifier[not set]{xy} } )", R"(TypeConstructor[not set]{ __i32 MemberAccessor[not set]{ Identifier[not set]{vf123} Identifier[not set]{z} } } )"}}, {"%float 2D 1 1 0 1 Unknown", "%result = OpImageSampleDrefExplicitLod %v4float %sampled_image " "%vf123 %depth Lod %f1", "", { R"(MemberAccessor[not set]{ Identifier[not set]{vf123} Identifier[not set]{xy} } )", R"(TypeConstructor[not set]{ __i32 MemberAccessor[not set]{ Identifier[not set]{vf123} Identifier[not set]{z} } } )"}}})); INSTANTIATE_TEST_SUITE_P( PreserveIntCoords_NonArrayed, // In SPIR-V, image read, fetch, and write use integer coordinates. // Prove that we preserve signed integer coordinates. SpvParserTest_ImageCoordsTest, ::testing::ValuesIn(std::vector{ // Scalar cases {"%float 1D 0 0 0 1 Unknown", "%result = OpImageFetch %float %im %i1", "", {"Identifier[not set]{i1}\n"}}, {"%float 1D 0 0 0 2 R32f", "%result = OpImageRead %float %im %i1", "", {"Identifier[not set]{i1}\n"}}, {"%float 1D 0 0 0 2 R32f", "OpImageWrite %im %i1 %float_1", "", {"Identifier[not set]{i1}\n"}}, // Vector cases {"%float 2D 0 0 0 1 Unknown", "%result = OpImageFetch %float %im %vi12", "", {"Identifier[not set]{vi12}\n"}}, {"%float 2D 0 0 0 2 R32f", "%result = OpImageRead %float %im %vi12", "", {"Identifier[not set]{vi12}\n"}}, {"%float 2D 0 0 0 2 R32f", "OpImageWrite %im %vi12 %float_1", "", {"Identifier[not set]{vi12}\n"}}})); INSTANTIATE_TEST_SUITE_P( PreserveIntCoords_Arrayed, // In SPIR-V, image read, fetch, and write use integer coordinates. // Prove that we preserve signed integer coordinates. SpvParserTest_ImageCoordsTest, ::testing::ValuesIn(std::vector{ {"%float 2D 0 1 0 1 Unknown", "%result = OpImageFetch %float %im %vi123", "", { R"(MemberAccessor[not set]{ Identifier[not set]{vi123} Identifier[not set]{xy} } )", R"(MemberAccessor[not set]{ Identifier[not set]{vi123} Identifier[not set]{z} } )"}}, {"%float 2D 0 1 0 2 R32f", "%result = OpImageRead %float %im %vi123", "", { R"(MemberAccessor[not set]{ Identifier[not set]{vi123} Identifier[not set]{xy} } )", R"(MemberAccessor[not set]{ Identifier[not set]{vi123} Identifier[not set]{z} } )"}}, {"%float 2D 0 1 0 2 R32f", "OpImageWrite %im %vi123 %float_1", "", { R"(MemberAccessor[not set]{ Identifier[not set]{vi123} Identifier[not set]{xy} } )", R"(MemberAccessor[not set]{ Identifier[not set]{vi123} Identifier[not set]{z} } )"}}})); INSTANTIATE_TEST_SUITE_P( ConvertUintCoords_NonArrayed, // In SPIR-V, image read, fetch, and write use integer coordinates. // Prove that we convert unsigned integer coordinates to signed. SpvParserTest_ImageCoordsTest, ::testing::ValuesIn(std::vector{ // Scalar cases {"%float 1D 0 0 0 1 Unknown", "%result = OpImageFetch %float %im %u1", "", {R"(TypeConstructor[not set]{ __i32 Identifier[not set]{u1} } )"}}, {"%float 1D 0 0 0 2 R32f", "%result = OpImageRead %float %im %u1", "", {R"(TypeConstructor[not set]{ __i32 Identifier[not set]{u1} } )"}}, {"%float 1D 0 0 0 2 R32f", "OpImageWrite %im %u1 %float_1", "", {R"(TypeConstructor[not set]{ __i32 Identifier[not set]{u1} } )"}}, // Vector cases {"%float 2D 0 0 0 1 Unknown", "%result = OpImageFetch %float %im %vu12", "", {R"(TypeConstructor[not set]{ __vec_2__i32 Identifier[not set]{vu12} } )"}}, {"%float 2D 0 0 0 2 R32f", "%result = OpImageRead %float %im %vu12", "", {R"(TypeConstructor[not set]{ __vec_2__i32 Identifier[not set]{vu12} } )"}}, {"%float 2D 0 0 0 2 R32f", "OpImageWrite %im %vu12 %float_1", "", {R"(TypeConstructor[not set]{ __vec_2__i32 Identifier[not set]{vu12} } )"}}})); INSTANTIATE_TEST_SUITE_P( ConvertUintCoords_Arrayed, // In SPIR-V, image read, fetch, and write use integer coordinates. // Prove that we convert unsigned integer coordinates to signed. SpvParserTest_ImageCoordsTest, ::testing::ValuesIn(std::vector{ {"%float 2D 0 1 0 1 Unknown", "%result = OpImageFetch %float %im %vu123", "", { R"(TypeConstructor[not set]{ __vec_2__i32 MemberAccessor[not set]{ Identifier[not set]{vu123} Identifier[not set]{xy} } } )", R"(TypeConstructor[not set]{ __i32 MemberAccessor[not set]{ Identifier[not set]{vu123} Identifier[not set]{z} } } )"}}, {"%float 2D 0 1 0 2 R32f", "%result = OpImageRead %float %im %vu123", "", { R"(TypeConstructor[not set]{ __vec_2__i32 MemberAccessor[not set]{ Identifier[not set]{vu123} Identifier[not set]{xy} } } )", R"(TypeConstructor[not set]{ __i32 MemberAccessor[not set]{ Identifier[not set]{vu123} Identifier[not set]{z} } } )"}}, {"%float 2D 0 1 0 2 R32f", "OpImageWrite %im %vu123 %float_1", "", { R"(TypeConstructor[not set]{ __vec_2__i32 MemberAccessor[not set]{ Identifier[not set]{vu123} Identifier[not set]{xy} } } )", R"(TypeConstructor[not set]{ __i32 MemberAccessor[not set]{ Identifier[not set]{vu123} Identifier[not set]{z} } } )"}}})); INSTANTIATE_TEST_SUITE_P( BadInstructions, SpvParserTest_ImageCoordsTest, ::testing::ValuesIn(std::vector{ {"%float 1D 0 0 0 1 Unknown", "OpNop", "internal error: not an image access " "instruction: OpNop", {}}, {"%float 1D 0 0 0 1 Unknown", "%50 = OpCopyObject %float %float_1", "internal error: couldn't find image for " "%50 = OpCopyObject %18 %44", {}}, {"%float 1D 0 0 0 1 Unknown", "OpStore %float_var %float_1", "invalid type for image or sampler " "variable or function parameter: %1 = OpVariable %2 Function", {}}, // An example with a missing coordinate // won't assemble, so we skip it. })); INSTANTIATE_TEST_SUITE_P( Bad_Coordinate, SpvParserTest_ImageCoordsTest, ::testing::ValuesIn(std::vector{ {"%float 1D 0 0 0 1 Unknown", "%result = OpImageSampleImplicitLod " // bad type for coordinate: not a number "%v4float %sampled_image %float_var", "bad or unsupported coordinate type for image access: %71 = " "OpImageSampleImplicitLod %42 %70 %1", {}}, {"%float 1D 0 1 0 1 Unknown", // 1DArray "%result = OpImageSampleImplicitLod " // 1 component, but need 2 "%v4float %sampled_image %f1", "image access required 2 coordinate components, but only 1 provided, " "in: %71 = OpImageSampleImplicitLod %42 %70 %12", {}}, {"%float 2D 0 0 0 1 Unknown", // 2D "%result = OpImageSampleImplicitLod " // 1 component, but need 2 "%v4float %sampled_image %f1", "image access required 2 coordinate components, but only 1 provided, " "in: %71 = OpImageSampleImplicitLod %42 %70 %12", {}}, {"%float 2D 0 1 0 1 Unknown", // 2DArray "%result = OpImageSampleImplicitLod " // 2 component, but need 3 "%v4float %sampled_image %vf12", "image access required 3 coordinate components, but only 2 provided, " "in: %71 = OpImageSampleImplicitLod %42 %70 %13", {}}, {"%float 3D 0 0 0 1 Unknown", // 3D "%result = OpImageSampleImplicitLod " // 2 components, but need 3 "%v4float %sampled_image %vf12", "image access required 3 coordinate components, but only 2 provided, " "in: %71 = OpImageSampleImplicitLod %42 %70 %13", {}}, })); INSTANTIATE_TEST_SUITE_P( SampleNonFloatTexture_IsError, SpvParserTest_ImageCoordsTest, ::testing::ValuesIn(std::vector{ // ImageSampleImplicitLod {"%uint 2D 0 0 0 1 Unknown", "%result = OpImageSampleImplicitLod %v4uint %sampled_image %vf12", "sampled image must have float component type", {}}, {"%int 2D 0 0 0 1 Unknown", "%result = OpImageSampleImplicitLod %v4int %sampled_image %vf12", "sampled image must have float component type", {}}, // ImageSampleExplicitLod {"%uint 2D 0 0 0 1 Unknown", "%result = OpImageSampleExplicitLod %v4uint %sampled_image %vf12 " "Lod %f1", "sampled image must have float component type", {}}, {"%int 2D 0 0 0 1 Unknown", "%result = OpImageSampleExplicitLod %v4int %sampled_image %vf12 " "Lod %f1", "sampled image must have float component type", {}}, // ImageSampleDrefImplicitLod {"%uint 2D 0 0 0 1 Unknown", "%result = OpImageSampleDrefImplicitLod %v4uint %sampled_image %vf12 " "%f1", "sampled image must have float component type", {}}, {"%int 2D 0 0 0 1 Unknown", "%result = OpImageSampleDrefImplicitLod %v4int %sampled_image %vf12 " "%f1", "sampled image must have float component type", {}}, // ImageSampleDrefExplicitLod {"%uint 2D 0 0 0 1 Unknown", "%result = OpImageSampleDrefExplicitLod %v4uint %sampled_image %vf12 " "%f1 Lod %f1", "sampled image must have float component type", {}}, {"%int 2D 0 0 0 1 Unknown", "%result = OpImageSampleDrefExplicitLod %v4int %sampled_image %vf12 " "%f1 Lod %f1", "sampled image must have float component type", {}}})); INSTANTIATE_TEST_SUITE_P( ConstOffset_BadInstruction_Errors, SpvParserTest_ImageCoordsTest, ::testing::ValuesIn(std::vector{ // ImageFetch {"%uint 2D 0 0 0 1 Unknown", "%result = OpImageFetch %v4uint %sampled_image %vf12 ConstOffset " "%the_vu12", "ConstOffset is only permitted for sampling operations: ", {}}, // ImageRead {"%uint 2D 0 0 0 2 Rgba32ui", "%result = OpImageRead %v4uint %im %vu12 ConstOffset %the_vu12", "ConstOffset is only permitted for sampling operations: ", {}}, // ImageWrite {"%uint 2D 0 0 0 2 Rgba32ui", "OpImageWrite %im %vu12 %vu1234 ConstOffset %the_vu12", "ConstOffset is only permitted for sampling operations: ", {}} // TODO(dneto): Gather // TODO(dneto): DrefGather })); INSTANTIATE_TEST_SUITE_P( ConstOffset_BadDim_Errors, SpvParserTest_ImageCoordsTest, ::testing::ValuesIn(std::vector{ // 1D {"%uint 1D 0 0 0 1 Unknown", "%result = OpImageSampleImplicitLod %v4float %sampled_image %vf1234 " "ConstOffset %the_vu12", "ConstOffset is only permitted for 2D, 2D Arrayed, and 3D textures: ", {}}, // 1D Array {"%uint 1D 0 1 0 1 Unknown", "%result = OpImageSampleImplicitLod %v4float %sampled_image %vf1234 " "ConstOffset %the_vu12", "ConstOffset is only permitted for 2D, 2D Arrayed, and 3D textures: ", {}}, // Cube {"%uint Cube 0 0 0 1 Unknown", "%result = OpImageSampleImplicitLod %v4float %sampled_image %vf1234 " "ConstOffset %the_vu12", "ConstOffset is only permitted for 2D, 2D Arrayed, and 3D textures: ", {}}, // Cube Array {"%uint Cube 0 1 0 1 Unknown", "%result = OpImageSampleImplicitLod %v4float %sampled_image %vf1234 " "ConstOffset %the_vu12", "ConstOffset is only permitted for 2D, 2D Arrayed, and 3D textures: ", {}}})); } // namespace } // namespace spirv } // namespace reader } // namespace tint