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dawn / tint / d2323c520c155e47d6e1103828483c8215114979 / . / src / tint / writer / spirv / builder_type_test.cc
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// 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 "src/tint/sem/depth_texture_type.h"
#include "src/tint/sem/multisampled_texture_type.h"
#include "src/tint/sem/sampled_texture_type.h"
#include "src/tint/writer/spirv/spv_dump.h"
#include "src/tint/writer/spirv/test_helper.h"
namespace tint::writer::spirv {
namespace {
using BuilderTest_Type = TestHelper;
TEST_F(BuilderTest_Type, GenerateRuntimeArray) {
auto* ary = ty.array(ty.i32());
auto* str = Structure("S", {Member("x", ary)});
Global("a", ty.Of(str), ast::StorageClass::kStorage, ast::Access::kRead,
ast::AttributeList{
create<ast::BindingAttribute>(0),
create<ast::GroupAttribute>(0),
});
spirv::Builder& b = Build();
auto id = b.GenerateTypeIfNeeded(program->TypeOf(ary));
ASSERT_FALSE(b.has_error()) << b.error();
EXPECT_EQ(1u, id);
EXPECT_EQ(DumpInstructions(b.types()), R"(%2 = OpTypeInt 32 1
%1 = OpTypeRuntimeArray %2
)");
}
TEST_F(BuilderTest_Type, ReturnsGeneratedRuntimeArray) {
auto* ary = ty.array(ty.i32());
auto* str = Structure("S", {Member("x", ary)});
Global("a", ty.Of(str), ast::StorageClass::kStorage, ast::Access::kRead,
ast::AttributeList{
create<ast::BindingAttribute>(0),
create<ast::GroupAttribute>(0),
});
spirv::Builder& b = Build();
EXPECT_EQ(b.GenerateTypeIfNeeded(program->TypeOf(ary)), 1u);
EXPECT_EQ(b.GenerateTypeIfNeeded(program->TypeOf(ary)), 1u);
ASSERT_FALSE(b.has_error()) << b.error();
EXPECT_EQ(DumpInstructions(b.types()), R"(%2 = OpTypeInt 32 1
%1 = OpTypeRuntimeArray %2
)");
}
TEST_F(BuilderTest_Type, GenerateArray) {
auto* ary = ty.array(ty.i32(), 4);
Global("a", ary, ast::StorageClass::kPrivate);
spirv::Builder& b = Build();
auto id = b.GenerateTypeIfNeeded(program->TypeOf(ary));
ASSERT_FALSE(b.has_error()) << b.error();
EXPECT_EQ(1u, id);
EXPECT_EQ(DumpInstructions(b.types()), R"(%2 = OpTypeInt 32 1
%3 = OpTypeInt 32 0
%4 = OpConstant %3 4
%1 = OpTypeArray %2 %4
)");
}
TEST_F(BuilderTest_Type, GenerateArray_WithStride) {
auto* ary = ty.array(ty.i32(), 4, 16u);
Global("a", ary, ast::StorageClass::kPrivate);
spirv::Builder& b = Build();
auto id = b.GenerateTypeIfNeeded(program->TypeOf(ary));
ASSERT_FALSE(b.has_error()) << b.error();
EXPECT_EQ(1u, id);
EXPECT_EQ(DumpInstructions(b.annots()), R"(OpDecorate %1 ArrayStride 16
)");
EXPECT_EQ(DumpInstructions(b.types()), R"(%2 = OpTypeInt 32 1
%3 = OpTypeInt 32 0
%4 = OpConstant %3 4
%1 = OpTypeArray %2 %4
)");
}
TEST_F(BuilderTest_Type, ReturnsGeneratedArray) {
auto* ary = ty.array(ty.i32(), 4);
Global("a", ary, ast::StorageClass::kPrivate);
spirv::Builder& b = Build();
EXPECT_EQ(b.GenerateTypeIfNeeded(program->TypeOf(ary)), 1u);
EXPECT_EQ(b.GenerateTypeIfNeeded(program->TypeOf(ary)), 1u);
ASSERT_FALSE(b.has_error()) << b.error();
EXPECT_EQ(DumpInstructions(b.types()), R"(%2 = OpTypeInt 32 1
%3 = OpTypeInt 32 0
%4 = OpConstant %3 4
%1 = OpTypeArray %2 %4
)");
}
TEST_F(BuilderTest_Type, GenerateBool) {
auto* bool_ = create<sem::Bool>();
spirv::Builder& b = Build();
auto id = b.GenerateTypeIfNeeded(bool_);
ASSERT_FALSE(b.has_error()) << b.error();
EXPECT_EQ(id, 1u);
ASSERT_EQ(b.types().size(), 1u);
EXPECT_EQ(DumpInstruction(b.types()[0]), R"(%1 = OpTypeBool
)");
}
TEST_F(BuilderTest_Type, ReturnsGeneratedBool) {
auto* bool_ = create<sem::Bool>();
auto* i32 = create<sem::I32>();
spirv::Builder& b = Build();
EXPECT_EQ(b.GenerateTypeIfNeeded(bool_), 1u);
ASSERT_FALSE(b.has_error()) << b.error();
EXPECT_EQ(b.GenerateTypeIfNeeded(i32), 2u);
ASSERT_FALSE(b.has_error()) << b.error();
EXPECT_EQ(b.GenerateTypeIfNeeded(bool_), 1u);
ASSERT_FALSE(b.has_error()) << b.error();
}
TEST_F(BuilderTest_Type, GenerateF32) {
auto* f32 = create<sem::F32>();
spirv::Builder& b = Build();
auto id = b.GenerateTypeIfNeeded(f32);
ASSERT_FALSE(b.has_error()) << b.error();
EXPECT_EQ(id, 1u);
ASSERT_EQ(b.types().size(), 1u);
EXPECT_EQ(DumpInstruction(b.types()[0]), R"(%1 = OpTypeFloat 32
)");
}
TEST_F(BuilderTest_Type, ReturnsGeneratedF32) {
auto* f32 = create<sem::F32>();
auto* i32 = create<sem::I32>();
spirv::Builder& b = Build();
EXPECT_EQ(b.GenerateTypeIfNeeded(f32), 1u);
ASSERT_FALSE(b.has_error()) << b.error();
EXPECT_EQ(b.GenerateTypeIfNeeded(i32), 2u);
ASSERT_FALSE(b.has_error()) << b.error();
EXPECT_EQ(b.GenerateTypeIfNeeded(f32), 1u);
ASSERT_FALSE(b.has_error()) << b.error();
}
TEST_F(BuilderTest_Type, GenerateI32) {
auto* i32 = create<sem::I32>();
spirv::Builder& b = Build();
auto id = b.GenerateTypeIfNeeded(i32);
ASSERT_FALSE(b.has_error()) << b.error();
EXPECT_EQ(id, 1u);
ASSERT_EQ(b.types().size(), 1u);
EXPECT_EQ(DumpInstruction(b.types()[0]), R"(%1 = OpTypeInt 32 1
)");
}
TEST_F(BuilderTest_Type, ReturnsGeneratedI32) {
auto* f32 = create<sem::F32>();
auto* i32 = create<sem::I32>();
spirv::Builder& b = Build();
EXPECT_EQ(b.GenerateTypeIfNeeded(i32), 1u);
ASSERT_FALSE(b.has_error()) << b.error();
EXPECT_EQ(b.GenerateTypeIfNeeded(f32), 2u);
ASSERT_FALSE(b.has_error()) << b.error();
EXPECT_EQ(b.GenerateTypeIfNeeded(i32), 1u);
ASSERT_FALSE(b.has_error()) << b.error();
}
TEST_F(BuilderTest_Type, GenerateMatrix) {
auto* f32 = create<sem::F32>();
auto* vec3 = create<sem::Vector>(f32, 3u);
auto* mat2x3 = create<sem::Matrix>(vec3, 2u);
spirv::Builder& b = Build();
auto id = b.GenerateTypeIfNeeded(mat2x3);
ASSERT_FALSE(b.has_error()) << b.error();
EXPECT_EQ(id, 1u);
EXPECT_EQ(b.types().size(), 3u);
EXPECT_EQ(DumpInstructions(b.types()), R"(%3 = OpTypeFloat 32
%2 = OpTypeVector %3 3
%1 = OpTypeMatrix %2 2
)");
}
TEST_F(BuilderTest_Type, ReturnsGeneratedMatrix) {
auto* i32 = create<sem::I32>();
auto* col = create<sem::Vector>(i32, 4u);
auto* mat = create<sem::Matrix>(col, 3u);
spirv::Builder& b = Build();
EXPECT_EQ(b.GenerateTypeIfNeeded(mat), 1u);
ASSERT_FALSE(b.has_error()) << b.error();
EXPECT_EQ(b.GenerateTypeIfNeeded(i32), 3u);
ASSERT_FALSE(b.has_error()) << b.error();
EXPECT_EQ(b.GenerateTypeIfNeeded(mat), 1u);
ASSERT_FALSE(b.has_error()) << b.error();
}
TEST_F(BuilderTest_Type, GeneratePtr) {
auto* i32 = create<sem::I32>();
auto* ptr = create<sem::Pointer>(i32, ast::StorageClass::kOutput,
ast::Access::kReadWrite);
spirv::Builder& b = Build();
auto id = b.GenerateTypeIfNeeded(ptr);
ASSERT_FALSE(b.has_error()) << b.error();
EXPECT_EQ(1u, id);
EXPECT_EQ(DumpInstructions(b.types()), R"(%2 = OpTypeInt 32 1
%1 = OpTypePointer Output %2
)");
}
TEST_F(BuilderTest_Type, ReturnsGeneratedPtr) {
auto* i32 = create<sem::I32>();
auto* ptr = create<sem::Pointer>(i32, ast::StorageClass::kOutput,
ast::Access::kReadWrite);
spirv::Builder& b = Build();
EXPECT_EQ(b.GenerateTypeIfNeeded(ptr), 1u);
EXPECT_EQ(b.GenerateTypeIfNeeded(ptr), 1u);
}
TEST_F(BuilderTest_Type, GenerateStruct) {
auto* s = Structure("my_struct", {Member("a", ty.f32())});
spirv::Builder& b = Build();
auto id = b.GenerateTypeIfNeeded(program->TypeOf(s));
ASSERT_FALSE(b.has_error()) << b.error();
EXPECT_EQ(id, 1u);
EXPECT_EQ(DumpInstructions(b.types()), R"(%2 = OpTypeFloat 32
%1 = OpTypeStruct %2
)");
EXPECT_EQ(DumpInstructions(b.debug()), R"(OpName %1 "my_struct"
OpMemberName %1 0 "a"
)");
}
TEST_F(BuilderTest_Type, GenerateStruct_DecoratedMembers) {
auto* s = Structure("S", {
Member("a", ty.f32()),
Member("b", ty.f32(), {MemberAlign(8)}),
});
spirv::Builder& b = Build();
auto id = b.GenerateTypeIfNeeded(program->TypeOf(s));
ASSERT_FALSE(b.has_error()) << b.error();
EXPECT_EQ(id, 1u);
EXPECT_EQ(DumpInstructions(b.types()), R"(%2 = OpTypeFloat 32
%1 = OpTypeStruct %2 %2
)");
EXPECT_EQ(DumpInstructions(b.debug()), R"(OpName %1 "S"
OpMemberName %1 0 "a"
OpMemberName %1 1 "b"
)");
EXPECT_EQ(DumpInstructions(b.annots()), R"(OpMemberDecorate %1 0 Offset 0
OpMemberDecorate %1 1 Offset 8
)");
}
TEST_F(BuilderTest_Type, GenerateStruct_NonLayout_Matrix) {
auto* s = Structure("S", {
Member("a", ty.mat2x2<f32>()),
Member("b", ty.mat2x3<f32>()),
Member("c", ty.mat4x4<f32>()),
});
spirv::Builder& b = Build();
auto id = b.GenerateTypeIfNeeded(program->TypeOf(s));
ASSERT_FALSE(b.has_error()) << b.error();
EXPECT_EQ(id, 1u);
EXPECT_EQ(DumpInstructions(b.types()), R"(%4 = OpTypeFloat 32
%3 = OpTypeVector %4 2
%2 = OpTypeMatrix %3 2
%6 = OpTypeVector %4 3
%5 = OpTypeMatrix %6 2
%8 = OpTypeVector %4 4
%7 = OpTypeMatrix %8 4
%1 = OpTypeStruct %2 %5 %7
)");
EXPECT_EQ(DumpInstructions(b.debug()), R"(OpName %1 "S"
OpMemberName %1 0 "a"
OpMemberName %1 1 "b"
OpMemberName %1 2 "c"
)");
EXPECT_EQ(DumpInstructions(b.annots()), R"(OpMemberDecorate %1 0 Offset 0
OpMemberDecorate %1 0 ColMajor
OpMemberDecorate %1 0 MatrixStride 8
OpMemberDecorate %1 1 Offset 16
OpMemberDecorate %1 1 ColMajor
OpMemberDecorate %1 1 MatrixStride 16
OpMemberDecorate %1 2 Offset 48
OpMemberDecorate %1 2 ColMajor
OpMemberDecorate %1 2 MatrixStride 16
)");
}
TEST_F(BuilderTest_Type, GenerateStruct_DecoratedMembers_LayoutMatrix) {
// We have to infer layout for matrix when it also has an offset.
auto* s = Structure("S", {
Member("a", ty.mat2x2<f32>()),
Member("b", ty.mat2x3<f32>()),
Member("c", ty.mat4x4<f32>()),
});
spirv::Builder& b = Build();
auto id = b.GenerateTypeIfNeeded(program->TypeOf(s));
ASSERT_FALSE(b.has_error()) << b.error();
EXPECT_EQ(id, 1u);
EXPECT_EQ(DumpInstructions(b.types()), R"(%4 = OpTypeFloat 32
%3 = OpTypeVector %4 2
%2 = OpTypeMatrix %3 2
%6 = OpTypeVector %4 3
%5 = OpTypeMatrix %6 2
%8 = OpTypeVector %4 4
%7 = OpTypeMatrix %8 4
%1 = OpTypeStruct %2 %5 %7
)");
EXPECT_EQ(DumpInstructions(b.debug()), R"(OpName %1 "S"
OpMemberName %1 0 "a"
OpMemberName %1 1 "b"
OpMemberName %1 2 "c"
)");
EXPECT_EQ(DumpInstructions(b.annots()), R"(OpMemberDecorate %1 0 Offset 0
OpMemberDecorate %1 0 ColMajor
OpMemberDecorate %1 0 MatrixStride 8
OpMemberDecorate %1 1 Offset 16
OpMemberDecorate %1 1 ColMajor
OpMemberDecorate %1 1 MatrixStride 16
OpMemberDecorate %1 2 Offset 48
OpMemberDecorate %1 2 ColMajor
OpMemberDecorate %1 2 MatrixStride 16
)");
}
TEST_F(BuilderTest_Type, GenerateStruct_DecoratedMembers_LayoutArraysOfMatrix) {
// We have to infer layout for matrix when it also has an offset.
// The decoration goes on the struct member, even if the matrix is buried
// in levels of arrays.
auto* arr_mat2x2 = ty.array(ty.mat2x2<f32>(), 1); // Singly nested array
auto* arr_arr_mat2x3 = ty.array(ty.mat2x3<f32>(), 1); // Doubly nested array
auto* rtarr_mat4x4 = ty.array(ty.mat4x4<f32>()); // Runtime array
auto* s = Structure("S", {
Member("a", arr_mat2x2),
Member("b", arr_arr_mat2x3),
Member("c", rtarr_mat4x4),
});
spirv::Builder& b = Build();
auto id = b.GenerateTypeIfNeeded(program->TypeOf(s));
ASSERT_FALSE(b.has_error()) << b.error();
EXPECT_EQ(id, 1u);
EXPECT_EQ(DumpInstructions(b.types()), R"(%5 = OpTypeFloat 32
%4 = OpTypeVector %5 2
%3 = OpTypeMatrix %4 2
%6 = OpTypeInt 32 0
%7 = OpConstant %6 1
%2 = OpTypeArray %3 %7
%10 = OpTypeVector %5 3
%9 = OpTypeMatrix %10 2
%8 = OpTypeArray %9 %7
%13 = OpTypeVector %5 4
%12 = OpTypeMatrix %13 4
%11 = OpTypeRuntimeArray %12
%1 = OpTypeStruct %2 %8 %11
)");
EXPECT_EQ(DumpInstructions(b.debug()), R"(OpName %1 "S"
OpMemberName %1 0 "a"
OpMemberName %1 1 "b"
OpMemberName %1 2 "c"
)");
EXPECT_EQ(DumpInstructions(b.annots()), R"(OpMemberDecorate %1 0 Offset 0
OpMemberDecorate %1 0 ColMajor
OpMemberDecorate %1 0 MatrixStride 8
OpDecorate %2 ArrayStride 16
OpMemberDecorate %1 1 Offset 16
OpMemberDecorate %1 1 ColMajor
OpMemberDecorate %1 1 MatrixStride 16
OpDecorate %8 ArrayStride 32
OpMemberDecorate %1 2 Offset 48
OpMemberDecorate %1 2 ColMajor
OpMemberDecorate %1 2 MatrixStride 16
OpDecorate %11 ArrayStride 64
)");
}
TEST_F(BuilderTest_Type, GenerateU32) {
auto* u32 = create<sem::U32>();
spirv::Builder& b = Build();
auto id = b.GenerateTypeIfNeeded(u32);
ASSERT_FALSE(b.has_error()) << b.error();
EXPECT_EQ(id, 1u);
ASSERT_EQ(b.types().size(), 1u);
EXPECT_EQ(DumpInstruction(b.types()[0]), R"(%1 = OpTypeInt 32 0
)");
}
TEST_F(BuilderTest_Type, ReturnsGeneratedU32) {
auto* u32 = create<sem::U32>();
auto* f32 = create<sem::F32>();
spirv::Builder& b = Build();
EXPECT_EQ(b.GenerateTypeIfNeeded(u32), 1u);
ASSERT_FALSE(b.has_error()) << b.error();
EXPECT_EQ(b.GenerateTypeIfNeeded(f32), 2u);
ASSERT_FALSE(b.has_error()) << b.error();
EXPECT_EQ(b.GenerateTypeIfNeeded(u32), 1u);
ASSERT_FALSE(b.has_error()) << b.error();
}
TEST_F(BuilderTest_Type, GenerateVector) {
auto* vec = create<sem::Vector>(create<sem::F32>(), 3u);
spirv::Builder& b = Build();
auto id = b.GenerateTypeIfNeeded(vec);
ASSERT_FALSE(b.has_error()) << b.error();
EXPECT_EQ(id, 1u);
EXPECT_EQ(b.types().size(), 2u);
EXPECT_EQ(DumpInstructions(b.types()), R"(%2 = OpTypeFloat 32
%1 = OpTypeVector %2 3
)");
}
TEST_F(BuilderTest_Type, ReturnsGeneratedVector) {
auto* i32 = create<sem::I32>();
auto* vec = create<sem::Vector>(i32, 3u);
spirv::Builder& b = Build();
EXPECT_EQ(b.GenerateTypeIfNeeded(vec), 1u);
ASSERT_FALSE(b.has_error()) << b.error();
EXPECT_EQ(b.GenerateTypeIfNeeded(i32), 2u);
ASSERT_FALSE(b.has_error()) << b.error();
EXPECT_EQ(b.GenerateTypeIfNeeded(vec), 1u);
ASSERT_FALSE(b.has_error()) << b.error();
}
TEST_F(BuilderTest_Type, GenerateVoid) {
auto* void_ = create<sem::Void>();
spirv::Builder& b = Build();
auto id = b.GenerateTypeIfNeeded(void_);
ASSERT_FALSE(b.has_error()) << b.error();
EXPECT_EQ(id, 1u);
ASSERT_EQ(b.types().size(), 1u);
EXPECT_EQ(DumpInstruction(b.types()[0]), R"(%1 = OpTypeVoid
)");
}
TEST_F(BuilderTest_Type, ReturnsGeneratedVoid) {
auto* void_ = create<sem::Void>();
auto* i32 = create<sem::I32>();
spirv::Builder& b = Build();
EXPECT_EQ(b.GenerateTypeIfNeeded(void_), 1u);
ASSERT_FALSE(b.has_error()) << b.error();
EXPECT_EQ(b.GenerateTypeIfNeeded(i32), 2u);
ASSERT_FALSE(b.has_error()) << b.error();
EXPECT_EQ(b.GenerateTypeIfNeeded(void_), 1u);
ASSERT_FALSE(b.has_error()) << b.error();
}
struct PtrData {
ast::StorageClass ast_class;
SpvStorageClass result;
};
inline std::ostream& operator<<(std::ostream& out, PtrData data) {
out << data.ast_class;
return out;
}
using PtrDataTest = TestParamHelper<PtrData>;
TEST_P(PtrDataTest, ConvertStorageClass) {
auto params = GetParam();
spirv::Builder& b = Build();
EXPECT_EQ(b.ConvertStorageClass(params.ast_class), params.result);
}
INSTANTIATE_TEST_SUITE_P(
BuilderTest_Type,
PtrDataTest,
testing::Values(
PtrData{ast::StorageClass::kNone, SpvStorageClassMax},
PtrData{ast::StorageClass::kInput, SpvStorageClassInput},
PtrData{ast::StorageClass::kOutput, SpvStorageClassOutput},
PtrData{ast::StorageClass::kUniform, SpvStorageClassUniform},
PtrData{ast::StorageClass::kWorkgroup, SpvStorageClassWorkgroup},
PtrData{ast::StorageClass::kUniformConstant,
SpvStorageClassUniformConstant},
PtrData{ast::StorageClass::kStorage, SpvStorageClassStorageBuffer},
PtrData{ast::StorageClass::kPrivate, SpvStorageClassPrivate},
PtrData{ast::StorageClass::kFunction, SpvStorageClassFunction}));
TEST_F(BuilderTest_Type, DepthTexture_Generate_2d) {
auto* two_d = create<sem::DepthTexture>(ast::TextureDimension::k2d);
spirv::Builder& b = Build();
auto id_two_d = b.GenerateTypeIfNeeded(two_d);
ASSERT_FALSE(b.has_error()) << b.error();
EXPECT_EQ(1u, id_two_d);
EXPECT_EQ(DumpInstructions(b.types()), R"(%2 = OpTypeFloat 32
%1 = OpTypeImage %2 2D 0 0 0 1 Unknown
)");
}
TEST_F(BuilderTest_Type, DepthTexture_Generate_2dArray) {
auto* two_d_array =
create<sem::DepthTexture>(ast::TextureDimension::k2dArray);
spirv::Builder& b = Build();
auto id_two_d_array = b.GenerateTypeIfNeeded(two_d_array);
ASSERT_FALSE(b.has_error()) << b.error();
EXPECT_EQ(1u, id_two_d_array);
EXPECT_EQ(DumpInstructions(b.types()), R"(%2 = OpTypeFloat 32
%1 = OpTypeImage %2 2D 0 1 0 1 Unknown
)");
}
TEST_F(BuilderTest_Type, DepthTexture_Generate_Cube) {
auto* cube = create<sem::DepthTexture>(ast::TextureDimension::kCube);
spirv::Builder& b = Build();
auto id_cube = b.GenerateTypeIfNeeded(cube);
ASSERT_FALSE(b.has_error()) << b.error();
EXPECT_EQ(1u, id_cube);
EXPECT_EQ(DumpInstructions(b.types()), R"(%2 = OpTypeFloat 32
%1 = OpTypeImage %2 Cube 0 0 0 1 Unknown
)");
EXPECT_EQ(DumpInstructions(b.capabilities()), "");
}
TEST_F(BuilderTest_Type, DepthTexture_Generate_CubeArray) {
auto* cube_array =
create<sem::DepthTexture>(ast::TextureDimension::kCubeArray);
spirv::Builder& b = Build();
auto id_cube_array = b.GenerateTypeIfNeeded(cube_array);
ASSERT_FALSE(b.has_error()) << b.error();
EXPECT_EQ(1u, id_cube_array);
EXPECT_EQ(DumpInstructions(b.types()), R"(%2 = OpTypeFloat 32
%1 = OpTypeImage %2 Cube 0 1 0 1 Unknown
)");
EXPECT_EQ(DumpInstructions(b.capabilities()),
R"(OpCapability SampledCubeArray
)");
}
TEST_F(BuilderTest_Type, MultisampledTexture_Generate_2d_i32) {
auto* i32 = create<sem::I32>();
auto* ms = create<sem::MultisampledTexture>(ast::TextureDimension::k2d, i32);
spirv::Builder& b = Build();
EXPECT_EQ(1u, b.GenerateTypeIfNeeded(ms));
ASSERT_FALSE(b.has_error()) << b.error();
EXPECT_EQ(DumpInstructions(b.types()), R"(%2 = OpTypeInt 32 1
%1 = OpTypeImage %2 2D 0 0 1 1 Unknown
)");
}
TEST_F(BuilderTest_Type, MultisampledTexture_Generate_2d_u32) {
auto* u32 = create<sem::U32>();
auto* ms = create<sem::MultisampledTexture>(ast::TextureDimension::k2d, u32);
spirv::Builder& b = Build();
EXPECT_EQ(b.GenerateTypeIfNeeded(ms), 1u);
ASSERT_FALSE(b.has_error()) << b.error();
EXPECT_EQ(DumpInstructions(b.types()),
R"(%2 = OpTypeInt 32 0
%1 = OpTypeImage %2 2D 0 0 1 1 Unknown
)");
}
TEST_F(BuilderTest_Type, MultisampledTexture_Generate_2d_f32) {
auto* f32 = create<sem::F32>();
auto* ms = create<sem::MultisampledTexture>(ast::TextureDimension::k2d, f32);
spirv::Builder& b = Build();
EXPECT_EQ(b.GenerateTypeIfNeeded(ms), 1u);
ASSERT_FALSE(b.has_error()) << b.error();
EXPECT_EQ(DumpInstructions(b.types()),
R"(%2 = OpTypeFloat 32
%1 = OpTypeImage %2 2D 0 0 1 1 Unknown
)");
}
TEST_F(BuilderTest_Type, SampledTexture_Generate_1d_i32) {
auto* s = create<sem::SampledTexture>(ast::TextureDimension::k1d,
create<sem::I32>());
spirv::Builder& b = Build();
EXPECT_EQ(b.GenerateTypeIfNeeded(s), 1u);
ASSERT_FALSE(b.has_error()) << b.error();
EXPECT_EQ(DumpInstructions(b.types()),
R"(%2 = OpTypeInt 32 1
%1 = OpTypeImage %2 1D 0 0 0 1 Unknown
)");
EXPECT_EQ(DumpInstructions(b.capabilities()),
R"(OpCapability Sampled1D
)");
}
TEST_F(BuilderTest_Type, SampledTexture_Generate_1d_u32) {
auto* u32 = create<sem::U32>();
auto* s = create<sem::SampledTexture>(ast::TextureDimension::k1d, u32);
spirv::Builder& b = Build();
EXPECT_EQ(b.GenerateTypeIfNeeded(s), 1u);
ASSERT_FALSE(b.has_error()) << b.error();
EXPECT_EQ(DumpInstructions(b.types()),
R"(%2 = OpTypeInt 32 0
%1 = OpTypeImage %2 1D 0 0 0 1 Unknown
)");
EXPECT_EQ(DumpInstructions(b.capabilities()),
R"(OpCapability Sampled1D
)");
}
TEST_F(BuilderTest_Type, SampledTexture_Generate_1d_f32) {
auto* f32 = create<sem::F32>();
auto* s = create<sem::SampledTexture>(ast::TextureDimension::k1d, f32);
spirv::Builder& b = Build();
EXPECT_EQ(b.GenerateTypeIfNeeded(s), 1u);
ASSERT_FALSE(b.has_error()) << b.error();
EXPECT_EQ(DumpInstructions(b.types()),
R"(%2 = OpTypeFloat 32
%1 = OpTypeImage %2 1D 0 0 0 1 Unknown
)");
EXPECT_EQ(DumpInstructions(b.capabilities()),
R"(OpCapability Sampled1D
)");
}
TEST_F(BuilderTest_Type, SampledTexture_Generate_2d) {
auto* f32 = create<sem::F32>();
auto* s = create<sem::SampledTexture>(ast::TextureDimension::k2d, f32);
spirv::Builder& b = Build();
EXPECT_EQ(b.GenerateTypeIfNeeded(s), 1u);
ASSERT_FALSE(b.has_error()) << b.error();
EXPECT_EQ(DumpInstructions(b.types()),
R"(%2 = OpTypeFloat 32
%1 = OpTypeImage %2 2D 0 0 0 1 Unknown
)");
}
TEST_F(BuilderTest_Type, SampledTexture_Generate_2d_array) {
auto* f32 = create<sem::F32>();
auto* s = create<sem::SampledTexture>(ast::TextureDimension::k2dArray, f32);
spirv::Builder& b = Build();
EXPECT_EQ(b.GenerateTypeIfNeeded(s), 1u);
ASSERT_FALSE(b.has_error()) << b.error();
EXPECT_EQ(DumpInstructions(b.types()),
R"(%2 = OpTypeFloat 32
%1 = OpTypeImage %2 2D 0 1 0 1 Unknown
)");
}
TEST_F(BuilderTest_Type, SampledTexture_Generate_3d) {
auto* f32 = create<sem::F32>();
auto* s = create<sem::SampledTexture>(ast::TextureDimension::k3d, f32);
spirv::Builder& b = Build();
EXPECT_EQ(b.GenerateTypeIfNeeded(s), 1u);
ASSERT_FALSE(b.has_error()) << b.error();
EXPECT_EQ(DumpInstructions(b.types()),
R"(%2 = OpTypeFloat 32
%1 = OpTypeImage %2 3D 0 0 0 1 Unknown
)");
}
TEST_F(BuilderTest_Type, SampledTexture_Generate_Cube) {
auto* f32 = create<sem::F32>();
auto* s = create<sem::SampledTexture>(ast::TextureDimension::kCube, f32);
spirv::Builder& b = Build();
EXPECT_EQ(b.GenerateTypeIfNeeded(s), 1u);
ASSERT_FALSE(b.has_error()) << b.error();
EXPECT_EQ(DumpInstructions(b.types()),
R"(%2 = OpTypeFloat 32
%1 = OpTypeImage %2 Cube 0 0 0 1 Unknown
)");
EXPECT_EQ(DumpInstructions(b.capabilities()), "");
}
TEST_F(BuilderTest_Type, SampledTexture_Generate_CubeArray) {
auto* f32 = create<sem::F32>();
auto* s = create<sem::SampledTexture>(ast::TextureDimension::kCubeArray, f32);
spirv::Builder& b = Build();
EXPECT_EQ(b.GenerateTypeIfNeeded(s), 1u);
ASSERT_FALSE(b.has_error()) << b.error();
EXPECT_EQ(DumpInstructions(b.types()),
R"(%2 = OpTypeFloat 32
%1 = OpTypeImage %2 Cube 0 1 0 1 Unknown
)");
EXPECT_EQ(DumpInstructions(b.capabilities()),
R"(OpCapability SampledCubeArray
)");
}
TEST_F(BuilderTest_Type, StorageTexture_Generate_1d) {
auto* s =
ty.storage_texture(ast::TextureDimension::k1d,
ast::TexelFormat::kR32Float, ast::Access::kWrite);
Global("test_var", s,
ast::AttributeList{
create<ast::BindingAttribute>(0),
create<ast::GroupAttribute>(0),
});
spirv::Builder& b = Build();
EXPECT_EQ(b.GenerateTypeIfNeeded(program->TypeOf(s)), 1u);
ASSERT_FALSE(b.has_error()) << b.error();
EXPECT_EQ(DumpInstructions(b.types()), R"(%2 = OpTypeFloat 32
%1 = OpTypeImage %2 1D 0 0 0 2 R32f
)");
}
TEST_F(BuilderTest_Type, StorageTexture_Generate_2d) {
auto* s =
ty.storage_texture(ast::TextureDimension::k2d,
ast::TexelFormat::kR32Float, ast::Access::kWrite);
Global("test_var", s,
ast::AttributeList{
create<ast::BindingAttribute>(0),
create<ast::GroupAttribute>(0),
});
spirv::Builder& b = Build();
EXPECT_EQ(b.GenerateTypeIfNeeded(program->TypeOf(s)), 1u);
ASSERT_FALSE(b.has_error()) << b.error();
EXPECT_EQ(DumpInstructions(b.types()), R"(%2 = OpTypeFloat 32
%1 = OpTypeImage %2 2D 0 0 0 2 R32f
)");
}
TEST_F(BuilderTest_Type, StorageTexture_Generate_2dArray) {
auto* s =
ty.storage_texture(ast::TextureDimension::k2dArray,
ast::TexelFormat::kR32Float, ast::Access::kWrite);
Global("test_var", s,
ast::AttributeList{
create<ast::BindingAttribute>(0),
create<ast::GroupAttribute>(0),
});
spirv::Builder& b = Build();
EXPECT_EQ(b.GenerateTypeIfNeeded(program->TypeOf(s)), 1u);
ASSERT_FALSE(b.has_error()) << b.error();
EXPECT_EQ(DumpInstructions(b.types()), R"(%2 = OpTypeFloat 32
%1 = OpTypeImage %2 2D 0 1 0 2 R32f
)");
}
TEST_F(BuilderTest_Type, StorageTexture_Generate_3d) {
auto* s =
ty.storage_texture(ast::TextureDimension::k3d,
ast::TexelFormat::kR32Float, ast::Access::kWrite);
Global("test_var", s,
ast::AttributeList{
create<ast::BindingAttribute>(0),
create<ast::GroupAttribute>(0),
});
spirv::Builder& b = Build();
EXPECT_EQ(b.GenerateTypeIfNeeded(program->TypeOf(s)), 1u);
ASSERT_FALSE(b.has_error()) << b.error();
EXPECT_EQ(DumpInstructions(b.types()), R"(%2 = OpTypeFloat 32
%1 = OpTypeImage %2 3D 0 0 0 2 R32f
)");
}
TEST_F(BuilderTest_Type,
StorageTexture_Generate_SampledTypeFloat_Format_r32float) {
auto* s =
ty.storage_texture(ast::TextureDimension::k2d,
ast::TexelFormat::kR32Float, ast::Access::kWrite);
Global("test_var", s,
ast::AttributeList{
create<ast::BindingAttribute>(0),
create<ast::GroupAttribute>(0),
});
spirv::Builder& b = Build();
EXPECT_EQ(b.GenerateTypeIfNeeded(program->TypeOf(s)), 1u);
ASSERT_FALSE(b.has_error()) << b.error();
EXPECT_EQ(DumpInstructions(b.types()), R"(%2 = OpTypeFloat 32
%1 = OpTypeImage %2 2D 0 0 0 2 R32f
)");
}
TEST_F(BuilderTest_Type,
StorageTexture_Generate_SampledTypeSint_Format_r32sint) {
auto* s = ty.storage_texture(ast::TextureDimension::k2d,
ast::TexelFormat::kR32Sint, ast::Access::kWrite);
Global("test_var", s,
ast::AttributeList{
create<ast::BindingAttribute>(0),
create<ast::GroupAttribute>(0),
});
spirv::Builder& b = Build();
EXPECT_EQ(b.GenerateTypeIfNeeded(program->TypeOf(s)), 1u);
ASSERT_FALSE(b.has_error()) << b.error();
EXPECT_EQ(DumpInstructions(b.types()), R"(%2 = OpTypeInt 32 1
%1 = OpTypeImage %2 2D 0 0 0 2 R32i
)");
}
TEST_F(BuilderTest_Type,
StorageTexture_Generate_SampledTypeUint_Format_r32uint) {
auto* s = ty.storage_texture(ast::TextureDimension::k2d,
ast::TexelFormat::kR32Uint, ast::Access::kWrite);
Global("test_var", s,
ast::AttributeList{
create<ast::BindingAttribute>(0),
create<ast::GroupAttribute>(0),
});
spirv::Builder& b = Build();
EXPECT_EQ(b.GenerateTypeIfNeeded(program->TypeOf(s)), 1u);
ASSERT_FALSE(b.has_error()) << b.error();
EXPECT_EQ(DumpInstructions(b.types()), R"(%2 = OpTypeInt 32 0
%1 = OpTypeImage %2 2D 0 0 0 2 R32ui
)");
}
TEST_F(BuilderTest_Type, Sampler) {
auto* sampler = create<sem::Sampler>(ast::SamplerKind::kSampler);
spirv::Builder& b = Build();
EXPECT_EQ(b.GenerateTypeIfNeeded(sampler), 1u);
ASSERT_FALSE(b.has_error()) << b.error();
EXPECT_EQ(DumpInstructions(b.types()), "%1 = OpTypeSampler\n");
}
TEST_F(BuilderTest_Type, ComparisonSampler) {
auto* sampler = create<sem::Sampler>(ast::SamplerKind::kComparisonSampler);
spirv::Builder& b = Build();
EXPECT_EQ(b.GenerateTypeIfNeeded(sampler), 1u);
ASSERT_FALSE(b.has_error()) << b.error();
EXPECT_EQ(DumpInstructions(b.types()), "%1 = OpTypeSampler\n");
}
TEST_F(BuilderTest_Type, Dedup_Sampler_And_ComparisonSampler) {
auto* comp_sampler =
create<sem::Sampler>(ast::SamplerKind::kComparisonSampler);
auto* sampler = create<sem::Sampler>(ast::SamplerKind::kSampler);
spirv::Builder& b = Build();
EXPECT_EQ(b.GenerateTypeIfNeeded(comp_sampler), 1u);
EXPECT_EQ(b.GenerateTypeIfNeeded(sampler), 1u);
ASSERT_FALSE(b.has_error()) << b.error();
EXPECT_EQ(DumpInstructions(b.types()), "%1 = OpTypeSampler\n");
}
} // namespace
} // namespace tint::writer::spirv