src/tint/writer/spirv/builder_entry_point_test.cc - dawn - Git at Google

 // Copyright 2021 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 <memory>

 #include "gtest/gtest.h"
 #include "src/tint/ast/address_space.h"
 #include "src/tint/ast/builtin_attribute.h"
 #include "src/tint/ast/builtin_value.h"
 #include "src/tint/ast/location_attribute.h"
 #include "src/tint/ast/return_statement.h"
 #include "src/tint/ast/stage_attribute.h"
 #include "src/tint/ast/variable.h"
 #include "src/tint/program.h"
 #include "src/tint/sem/f32.h"
 #include "src/tint/sem/vector.h"
 #include "src/tint/writer/spirv/builder.h"
 #include "src/tint/writer/spirv/spv_dump.h"
 #include "src/tint/writer/spirv/test_helper.h"

 using namespace tint::number_suffixes;  // NOLINT

 namespace tint::writer::spirv {
 namespace {

 using BuilderTest = TestHelper;

 TEST_F(BuilderTest, EntryPoint_Parameters) {
     // @fragment
     // fn frag_main(@builtin(position) coord : vec4<f32>,
     //              @location(1) loc1 : f32) {
     //   var col : f32 = (coord.x * loc1);
     // }
     auto* coord = Param("coord", ty.vec4<f32>(),
                         utils::Vector{
                             Builtin(ast::BuiltinValue::kPosition),
                         });
     auto* loc1 = Param("loc1", ty.f32(),
                        utils::Vector{
                            Location(1_u),
                        });
     auto* mul = Mul(Expr(MemberAccessor("coord", "x")), Expr("loc1"));
     auto* col = Var("col", ty.f32(), mul);
     Func("frag_main", utils::Vector{coord, loc1}, ty.void_(), utils::Vector{WrapInStatement(col)},
          utils::Vector{
              Stage(ast::PipelineStage::kFragment),
          });

     spirv::Builder& b = SanitizeAndBuild();

     ASSERT_TRUE(b.Build());

     // Test that "coord" and "loc1" get hoisted out to global variables with the
     // Input address space, retaining their decorations.
     EXPECT_EQ(DumpBuilder(b), R"(OpCapability Shader
 OpMemoryModel Logical GLSL450
 OpEntryPoint Fragment %19 "frag_main" %1 %5
 OpExecutionMode %19 OriginUpperLeft
 OpName %1 "coord_1"
 OpName %5 "loc1_1"
 OpName %9 "frag_main_inner"
 OpName %10 "coord"
 OpName %11 "loc1"
 OpName %15 "col"
 OpName %19 "frag_main"
 OpDecorate %1 BuiltIn FragCoord
 OpDecorate %5 Location 1
 %4 = OpTypeFloat 32
 %3 = OpTypeVector %4 4
 %2 = OpTypePointer Input %3
 %1 = OpVariable %2 Input
 %6 = OpTypePointer Input %4
 %5 = OpVariable %6 Input
 %8 = OpTypeVoid
 %7 = OpTypeFunction %8 %3 %4
 %16 = OpTypePointer Function %4
 %17 = OpConstantNull %4
 %18 = OpTypeFunction %8
 %9 = OpFunction %8 None %7
 %10 = OpFunctionParameter %3
 %11 = OpFunctionParameter %4
 %12 = OpLabel
 %15 = OpVariable %16 Function %17
 %13 = OpCompositeExtract %4 %10 0
 %14 = OpFMul %4 %13 %11
 OpStore %15 %14
 OpReturn
 OpFunctionEnd
 %19 = OpFunction %8 None %18
 %20 = OpLabel
 %22 = OpLoad %3 %1
 %23 = OpLoad %4 %5
 %21 = OpFunctionCall %8 %9 %22 %23
 OpReturn
 OpFunctionEnd
 )");

     Validate(b);
 }

 TEST_F(BuilderTest, EntryPoint_ReturnValue) {
     // @fragment
     // fn frag_main(@location(0) @interpolate(flat) loc_in : u32)
     //     -> @location(0) f32 {
     //   if (loc_in > 10) {
     //     return 0.5;
     //   }
     //   return 1.0;
     // }
     auto* loc_in = Param("loc_in", ty.u32(),
                          utils::Vector{
                              Location(0_a),
                              Flat(),
                          });
     auto* cond =
         create<ast::BinaryExpression>(ast::BinaryOp::kGreaterThan, Expr("loc_in"), Expr(10_u));
     Func("frag_main", utils::Vector{loc_in}, ty.f32(),
          utils::Vector{
              If(cond, Block(Return(0.5_f))),
              Return(1_f),
          },
          utils::Vector{
              Stage(ast::PipelineStage::kFragment),
          },
          utils::Vector{
              Location(0_a),
          });

     spirv::Builder& b = SanitizeAndBuild();

     ASSERT_TRUE(b.Build());

     // Test that the return value gets hoisted out to a global variable with the
     // Output address space, and the return statements are replaced with stores.
     EXPECT_EQ(DumpBuilder(b), R"(OpCapability Shader
 OpMemoryModel Logical GLSL450
 OpEntryPoint Fragment %21 "frag_main" %1 %4
 OpExecutionMode %21 OriginUpperLeft
 OpName %1 "loc_in_1"
 OpName %4 "value"
 OpName %9 "frag_main_inner"
 OpName %10 "loc_in"
 OpName %21 "frag_main"
 OpDecorate %1 Location 0
 OpDecorate %1 Flat
 OpDecorate %4 Location 0
 %3 = OpTypeInt 32 0
 %2 = OpTypePointer Input %3
 %1 = OpVariable %2 Input
 %6 = OpTypeFloat 32
 %5 = OpTypePointer Output %6
 %7 = OpConstantNull %6
 %4 = OpVariable %5 Output %7
 %8 = OpTypeFunction %6 %3
 %12 = OpConstant %3 10
 %14 = OpTypeBool
 %17 = OpConstant %6 0.5
 %18 = OpConstant %6 1
 %20 = OpTypeVoid
 %19 = OpTypeFunction %20
 %9 = OpFunction %6 None %8
 %10 = OpFunctionParameter %3
 %11 = OpLabel
 %13 = OpUGreaterThan %14 %10 %12
 OpSelectionMerge %15 None
 OpBranchConditional %13 %16 %15
 %16 = OpLabel
 OpReturnValue %17
 %15 = OpLabel
 OpReturnValue %18
 OpFunctionEnd
 %21 = OpFunction %20 None %19
 %22 = OpLabel
 %24 = OpLoad %3 %1
 %23 = OpFunctionCall %6 %9 %24
 OpStore %4 %23
 OpReturn
 OpFunctionEnd
 )");

     Validate(b);
 }

 TEST_F(BuilderTest, EntryPoint_SharedStruct) {
     // struct Interface {
     //   @location(1) value : f32;
     //   @builtin(position) pos : vec4<f32>;
     // };
     //
     // @vertex
     // fn vert_main() -> Interface {
     //   return Interface(42.0, vec4<f32>());
     // }
     //
     // @fragment
     // fn frag_main(inputs : Interface) -> @builtin(frag_depth) f32 {
     //   return inputs.value;
     // }

     auto* interface = Structure(
         "Interface",
         utils::Vector{
             Member("value", ty.f32(), utils::Vector{Location(1_u)}),
             Member("pos", ty.vec4<f32>(), utils::Vector{Builtin(ast::BuiltinValue::kPosition)}),
         });

     auto* vert_retval = Construct(ty.Of(interface), 42_f, Construct(ty.vec4<f32>()));
     Func("vert_main", utils::Empty, ty.Of(interface), utils::Vector{Return(vert_retval)},
          utils::Vector{
              Stage(ast::PipelineStage::kVertex),
          });

     auto* frag_inputs = Param("inputs", ty.Of(interface));
     Func("frag_main", utils::Vector{frag_inputs}, ty.f32(),
          utils::Vector{
              Return(MemberAccessor(Expr("inputs"), "value")),
          },
          utils::Vector{Stage(ast::PipelineStage::kFragment)},
          utils::Vector{
              Builtin(ast::BuiltinValue::kFragDepth),
          });

     spirv::Builder& b = SanitizeAndBuild();

     ASSERT_TRUE(b.Build()) << b.error();

     EXPECT_EQ(DumpBuilder(b), R"(OpCapability Shader
 OpMemoryModel Logical GLSL450
 OpEntryPoint Vertex %23 "vert_main" %1 %5 %9
 OpEntryPoint Fragment %34 "frag_main" %10 %12 %14
 OpExecutionMode %34 OriginUpperLeft
 OpExecutionMode %34 DepthReplacing
 OpName %1 "value_1"
 OpName %5 "pos_1"
 OpName %9 "vertex_point_size"
 OpName %10 "value_2"
 OpName %12 "pos_2"
 OpName %14 "value_3"
 OpName %16 "Interface"
 OpMemberName %16 0 "value"
 OpMemberName %16 1 "pos"
 OpName %17 "vert_main_inner"
 OpName %23 "vert_main"
 OpName %30 "frag_main_inner"
 OpName %31 "inputs"
 OpName %34 "frag_main"
 OpDecorate %1 Location 1
 OpDecorate %5 BuiltIn Position
 OpDecorate %9 BuiltIn PointSize
 OpDecorate %10 Location 1
 OpDecorate %12 BuiltIn FragCoord
 OpDecorate %14 BuiltIn FragDepth
 OpMemberDecorate %16 0 Offset 0
 OpMemberDecorate %16 1 Offset 16
 %3 = OpTypeFloat 32
 %2 = OpTypePointer Output %3
 %4 = OpConstantNull %3
 %1 = OpVariable %2 Output %4
 %7 = OpTypeVector %3 4
 %6 = OpTypePointer Output %7
 %8 = OpConstantNull %7
 %5 = OpVariable %6 Output %8
 %9 = OpVariable %2 Output %4
 %11 = OpTypePointer Input %3
 %10 = OpVariable %11 Input
 %13 = OpTypePointer Input %7
 %12 = OpVariable %13 Input
 %14 = OpVariable %2 Output %4
 %16 = OpTypeStruct %3 %7
 %15 = OpTypeFunction %16
 %19 = OpConstant %3 42
 %20 = OpConstantComposite %16 %19 %8
 %22 = OpTypeVoid
 %21 = OpTypeFunction %22
 %28 = OpConstant %3 1
 %29 = OpTypeFunction %3 %16
 %17 = OpFunction %16 None %15
 %18 = OpLabel
 OpReturnValue %20
 OpFunctionEnd
 %23 = OpFunction %22 None %21
 %24 = OpLabel
 %25 = OpFunctionCall %16 %17
 %26 = OpCompositeExtract %3 %25 0
 OpStore %1 %26
 %27 = OpCompositeExtract %7 %25 1
 OpStore %5 %27
 OpStore %9 %28
 OpReturn
 OpFunctionEnd
 %30 = OpFunction %3 None %29
 %31 = OpFunctionParameter %16
 %32 = OpLabel
 %33 = OpCompositeExtract %3 %31 0
 OpReturnValue %33
 OpFunctionEnd
 %34 = OpFunction %22 None %21
 %35 = OpLabel
 %37 = OpLoad %3 %10
 %38 = OpLoad %7 %12
 %39 = OpCompositeConstruct %16 %37 %38
 %36 = OpFunctionCall %3 %30 %39
 OpStore %14 %36
 OpReturn
 OpFunctionEnd
 )");

     Validate(b);
 }

 TEST_F(BuilderTest, SampleIndex_SampleRateShadingCapability) {
     Func("main",
          utils::Vector{Param("sample_index", ty.u32(),
                              utils::Vector{Builtin(ast::BuiltinValue::kSampleIndex)})},
          ty.void_(), utils::Empty,
          utils::Vector{
              Stage(ast::PipelineStage::kFragment),
          });

     spirv::Builder& b = SanitizeAndBuild();

     ASSERT_TRUE(b.Build()) << b.error();

     // Make sure we generate the SampleRateShading capability.
     EXPECT_EQ(DumpInstructions(b.capabilities()),
               R"(OpCapability Shader
 OpCapability SampleRateShading
 )");
     EXPECT_EQ(DumpInstructions(b.annots()), R"(OpDecorate %1 BuiltIn SampleId
 OpDecorate %1 Flat
 )");
 }

 }  // namespace
 }  // namespace tint::writer::spirv
	// Copyright 2021 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 <memory>

	#include "gtest/gtest.h"
	#include "src/tint/ast/address_space.h"
	#include "src/tint/ast/builtin_attribute.h"
	#include "src/tint/ast/builtin_value.h"
	#include "src/tint/ast/location_attribute.h"
	#include "src/tint/ast/return_statement.h"
	#include "src/tint/ast/stage_attribute.h"
	#include "src/tint/ast/variable.h"
	#include "src/tint/program.h"
	#include "src/tint/sem/f32.h"
	#include "src/tint/sem/vector.h"
	#include "src/tint/writer/spirv/builder.h"
	#include "src/tint/writer/spirv/spv_dump.h"
	#include "src/tint/writer/spirv/test_helper.h"

	using namespace tint::number_suffixes; // NOLINT

	namespace tint::writer::spirv {
	namespace {

	using BuilderTest = TestHelper;

	TEST_F(BuilderTest, EntryPoint_Parameters) {
	// @fragment
	// fn frag_main(@builtin(position) coord : vec4<f32>,
	// @location(1) loc1 : f32) {
	// var col : f32 = (coord.x * loc1);
	// }
	auto* coord = Param("coord", ty.vec4<f32>(),
	utils::Vector{
	Builtin(ast::BuiltinValue::kPosition),
	});
	auto* loc1 = Param("loc1", ty.f32(),
	utils::Vector{
	Location(1_u),
	});
	auto* mul = Mul(Expr(MemberAccessor("coord", "x")), Expr("loc1"));
	auto* col = Var("col", ty.f32(), mul);
	Func("frag_main", utils::Vector{coord, loc1}, ty.void_(), utils::Vector{WrapInStatement(col)},
	utils::Vector{
	Stage(ast::PipelineStage::kFragment),
	});

	spirv::Builder& b = SanitizeAndBuild();

	ASSERT_TRUE(b.Build());

	// Test that "coord" and "loc1" get hoisted out to global variables with the
	// Input address space, retaining their decorations.
	EXPECT_EQ(DumpBuilder(b), R"(OpCapability Shader
	OpMemoryModel Logical GLSL450
	OpEntryPoint Fragment %19 "frag_main" %1 %5
	OpExecutionMode %19 OriginUpperLeft
	OpName %1 "coord_1"
	OpName %5 "loc1_1"
	OpName %9 "frag_main_inner"
	OpName %10 "coord"
	OpName %11 "loc1"
	OpName %15 "col"
	OpName %19 "frag_main"
	OpDecorate %1 BuiltIn FragCoord
	OpDecorate %5 Location 1
	%4 = OpTypeFloat 32
	%3 = OpTypeVector %4 4
	%2 = OpTypePointer Input %3
	%1 = OpVariable %2 Input
	%6 = OpTypePointer Input %4
	%5 = OpVariable %6 Input
	%8 = OpTypeVoid
	%7 = OpTypeFunction %8 %3 %4
	%16 = OpTypePointer Function %4
	%17 = OpConstantNull %4
	%18 = OpTypeFunction %8
	%9 = OpFunction %8 None %7
	%10 = OpFunctionParameter %3
	%11 = OpFunctionParameter %4
	%12 = OpLabel
	%15 = OpVariable %16 Function %17
	%13 = OpCompositeExtract %4 %10 0
	%14 = OpFMul %4 %13 %11
	OpStore %15 %14
	OpReturn
	OpFunctionEnd
	%19 = OpFunction %8 None %18
	%20 = OpLabel
	%22 = OpLoad %3 %1
	%23 = OpLoad %4 %5
	%21 = OpFunctionCall %8 %9 %22 %23
	OpReturn
	OpFunctionEnd
	)");

	Validate(b);
	}

	TEST_F(BuilderTest, EntryPoint_ReturnValue) {
	// @fragment
	// fn frag_main(@location(0) @interpolate(flat) loc_in : u32)
	// -> @location(0) f32 {
	// if (loc_in > 10) {
	// return 0.5;
	// }
	// return 1.0;
	// }
	auto* loc_in = Param("loc_in", ty.u32(),
	utils::Vector{
	Location(0_a),
	Flat(),
	});
	auto* cond =
	create<ast::BinaryExpression>(ast::BinaryOp::kGreaterThan, Expr("loc_in"), Expr(10_u));
	Func("frag_main", utils::Vector{loc_in}, ty.f32(),
	utils::Vector{
	If(cond, Block(Return(0.5_f))),
	Return(1_f),
	},
	utils::Vector{
	Stage(ast::PipelineStage::kFragment),
	},
	utils::Vector{
	Location(0_a),
	});

	spirv::Builder& b = SanitizeAndBuild();

	ASSERT_TRUE(b.Build());

	// Test that the return value gets hoisted out to a global variable with the
	// Output address space, and the return statements are replaced with stores.
	EXPECT_EQ(DumpBuilder(b), R"(OpCapability Shader
	OpMemoryModel Logical GLSL450
	OpEntryPoint Fragment %21 "frag_main" %1 %4
	OpExecutionMode %21 OriginUpperLeft
	OpName %1 "loc_in_1"
	OpName %4 "value"
	OpName %9 "frag_main_inner"
	OpName %10 "loc_in"
	OpName %21 "frag_main"
	OpDecorate %1 Location 0
	OpDecorate %1 Flat
	OpDecorate %4 Location 0
	%3 = OpTypeInt 32 0
	%2 = OpTypePointer Input %3
	%1 = OpVariable %2 Input
	%6 = OpTypeFloat 32
	%5 = OpTypePointer Output %6
	%7 = OpConstantNull %6
	%4 = OpVariable %5 Output %7
	%8 = OpTypeFunction %6 %3
	%12 = OpConstant %3 10
	%14 = OpTypeBool
	%17 = OpConstant %6 0.5
	%18 = OpConstant %6 1
	%20 = OpTypeVoid
	%19 = OpTypeFunction %20
	%9 = OpFunction %6 None %8
	%10 = OpFunctionParameter %3
	%11 = OpLabel
	%13 = OpUGreaterThan %14 %10 %12
	OpSelectionMerge %15 None
	OpBranchConditional %13 %16 %15
	%16 = OpLabel
	OpReturnValue %17
	%15 = OpLabel
	OpReturnValue %18
	OpFunctionEnd
	%21 = OpFunction %20 None %19
	%22 = OpLabel
	%24 = OpLoad %3 %1
	%23 = OpFunctionCall %6 %9 %24
	OpStore %4 %23
	OpReturn
	OpFunctionEnd
	)");

	Validate(b);
	}

	TEST_F(BuilderTest, EntryPoint_SharedStruct) {
	// struct Interface {
	// @location(1) value : f32;
	// @builtin(position) pos : vec4<f32>;
	// };
	//
	// @vertex
	// fn vert_main() -> Interface {
	// return Interface(42.0, vec4<f32>());
	// }
	//
	// @fragment
	// fn frag_main(inputs : Interface) -> @builtin(frag_depth) f32 {
	// return inputs.value;
	// }

	auto* interface = Structure(
	"Interface",
	utils::Vector{
	Member("value", ty.f32(), utils::Vector{Location(1_u)}),
	Member("pos", ty.vec4<f32>(), utils::Vector{Builtin(ast::BuiltinValue::kPosition)}),
	});

	auto* vert_retval = Construct(ty.Of(interface), 42_f, Construct(ty.vec4<f32>()));
	Func("vert_main", utils::Empty, ty.Of(interface), utils::Vector{Return(vert_retval)},
	utils::Vector{
	Stage(ast::PipelineStage::kVertex),
	});

	auto* frag_inputs = Param("inputs", ty.Of(interface));
	Func("frag_main", utils::Vector{frag_inputs}, ty.f32(),
	utils::Vector{
	Return(MemberAccessor(Expr("inputs"), "value")),
	},
	utils::Vector{Stage(ast::PipelineStage::kFragment)},
	utils::Vector{
	Builtin(ast::BuiltinValue::kFragDepth),
	});

	spirv::Builder& b = SanitizeAndBuild();

	ASSERT_TRUE(b.Build()) << b.error();

	EXPECT_EQ(DumpBuilder(b), R"(OpCapability Shader
	OpMemoryModel Logical GLSL450
	OpEntryPoint Vertex %23 "vert_main" %1 %5 %9
	OpEntryPoint Fragment %34 "frag_main" %10 %12 %14
	OpExecutionMode %34 OriginUpperLeft
	OpExecutionMode %34 DepthReplacing
	OpName %1 "value_1"
	OpName %5 "pos_1"
	OpName %9 "vertex_point_size"
	OpName %10 "value_2"
	OpName %12 "pos_2"
	OpName %14 "value_3"
	OpName %16 "Interface"
	OpMemberName %16 0 "value"
	OpMemberName %16 1 "pos"
	OpName %17 "vert_main_inner"
	OpName %23 "vert_main"
	OpName %30 "frag_main_inner"
	OpName %31 "inputs"
	OpName %34 "frag_main"
	OpDecorate %1 Location 1
	OpDecorate %5 BuiltIn Position
	OpDecorate %9 BuiltIn PointSize
	OpDecorate %10 Location 1
	OpDecorate %12 BuiltIn FragCoord
	OpDecorate %14 BuiltIn FragDepth
	OpMemberDecorate %16 0 Offset 0
	OpMemberDecorate %16 1 Offset 16
	%3 = OpTypeFloat 32
	%2 = OpTypePointer Output %3
	%4 = OpConstantNull %3
	%1 = OpVariable %2 Output %4
	%7 = OpTypeVector %3 4
	%6 = OpTypePointer Output %7
	%8 = OpConstantNull %7
	%5 = OpVariable %6 Output %8
	%9 = OpVariable %2 Output %4
	%11 = OpTypePointer Input %3
	%10 = OpVariable %11 Input
	%13 = OpTypePointer Input %7
	%12 = OpVariable %13 Input
	%14 = OpVariable %2 Output %4
	%16 = OpTypeStruct %3 %7
	%15 = OpTypeFunction %16
	%19 = OpConstant %3 42
	%20 = OpConstantComposite %16 %19 %8
	%22 = OpTypeVoid
	%21 = OpTypeFunction %22
	%28 = OpConstant %3 1
	%29 = OpTypeFunction %3 %16
	%17 = OpFunction %16 None %15
	%18 = OpLabel
	OpReturnValue %20
	OpFunctionEnd
	%23 = OpFunction %22 None %21
	%24 = OpLabel
	%25 = OpFunctionCall %16 %17
	%26 = OpCompositeExtract %3 %25 0
	OpStore %1 %26
	%27 = OpCompositeExtract %7 %25 1
	OpStore %5 %27
	OpStore %9 %28
	OpReturn
	OpFunctionEnd
	%30 = OpFunction %3 None %29
	%31 = OpFunctionParameter %16
	%32 = OpLabel
	%33 = OpCompositeExtract %3 %31 0
	OpReturnValue %33
	OpFunctionEnd
	%34 = OpFunction %22 None %21
	%35 = OpLabel
	%37 = OpLoad %3 %10
	%38 = OpLoad %7 %12
	%39 = OpCompositeConstruct %16 %37 %38
	%36 = OpFunctionCall %3 %30 %39
	OpStore %14 %36
	OpReturn
	OpFunctionEnd
	)");

	Validate(b);
	}

	TEST_F(BuilderTest, SampleIndex_SampleRateShadingCapability) {
	Func("main",
	utils::Vector{Param("sample_index", ty.u32(),
	utils::Vector{Builtin(ast::BuiltinValue::kSampleIndex)})},
	ty.void_(), utils::Empty,
	utils::Vector{
	Stage(ast::PipelineStage::kFragment),
	});

	spirv::Builder& b = SanitizeAndBuild();

	ASSERT_TRUE(b.Build()) << b.error();

	// Make sure we generate the SampleRateShading capability.
	EXPECT_EQ(DumpInstructions(b.capabilities()),
	R"(OpCapability Shader
	OpCapability SampleRateShading
	)");
	EXPECT_EQ(DumpInstructions(b.annots()), R"(OpDecorate %1 BuiltIn SampleId
	OpDecorate %1 Flat
	)");
	}

	} // namespace
	} // namespace tint::writer::spirv