blob: c9d9836851e05315691dda7080760eed30f6e06a [file] [log] [blame]
// 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 "src/tint/resolver/intrinsic_table.h"
#include <utility>
#include "gmock/gmock.h"
#include "src/tint/program_builder.h"
#include "src/tint/resolver/resolver_test_helper.h"
#include "src/tint/sem/atomic.h"
#include "src/tint/sem/depth_multisampled_texture.h"
#include "src/tint/sem/depth_texture.h"
#include "src/tint/sem/external_texture.h"
#include "src/tint/sem/multisampled_texture.h"
#include "src/tint/sem/reference.h"
#include "src/tint/sem/sampled_texture.h"
#include "src/tint/sem/storage_texture.h"
#include "src/tint/sem/test_helper.h"
#include "src/tint/sem/type_constructor.h"
#include "src/tint/sem/type_conversion.h"
namespace tint::resolver {
namespace {
using ::testing::HasSubstr;
using BuiltinType = sem::BuiltinType;
using Parameter = sem::Parameter;
using ParameterUsage = sem::ParameterUsage;
using AFloatV = builder::vec<3, AFloat>;
using AIntV = builder::vec<3, AInt>;
using f32V = builder::vec<3, f32>;
using i32V = builder::vec<3, i32>;
using u32V = builder::vec<3, u32>;
class IntrinsicTableTest : public testing::Test, public ProgramBuilder {
public:
std::unique_ptr<IntrinsicTable> table = IntrinsicTable::Create(*this);
};
TEST_F(IntrinsicTableTest, MatchF32) {
auto* f32 = create<sem::F32>();
auto result = table->Lookup(BuiltinType::kCos, {f32}, Source{});
ASSERT_NE(result.sem, nullptr) << Diagnostics().str();
ASSERT_EQ(Diagnostics().str(), "");
EXPECT_EQ(result.sem->Type(), BuiltinType::kCos);
EXPECT_EQ(result.sem->ReturnType(), f32);
ASSERT_EQ(result.sem->Parameters().size(), 1u);
EXPECT_EQ(result.sem->Parameters()[0]->Type(), f32);
}
TEST_F(IntrinsicTableTest, MismatchF32) {
auto* i32 = create<sem::I32>();
auto result = table->Lookup(BuiltinType::kCos, {i32}, Source{});
ASSERT_EQ(result.sem, nullptr);
ASSERT_THAT(Diagnostics().str(), HasSubstr("no matching call"));
}
TEST_F(IntrinsicTableTest, MatchU32) {
auto* f32 = create<sem::F32>();
auto* u32 = create<sem::U32>();
auto* vec2_f32 = create<sem::Vector>(f32, 2u);
auto result = table->Lookup(BuiltinType::kUnpack2x16float, {u32}, Source{});
ASSERT_NE(result.sem, nullptr) << Diagnostics().str();
ASSERT_EQ(Diagnostics().str(), "");
EXPECT_EQ(result.sem->Type(), BuiltinType::kUnpack2x16float);
EXPECT_EQ(result.sem->ReturnType(), vec2_f32);
ASSERT_EQ(result.sem->Parameters().size(), 1u);
EXPECT_EQ(result.sem->Parameters()[0]->Type(), u32);
}
TEST_F(IntrinsicTableTest, MismatchU32) {
auto* f32 = create<sem::F32>();
auto result = table->Lookup(BuiltinType::kUnpack2x16float, {f32}, Source{});
ASSERT_EQ(result.sem, nullptr);
ASSERT_THAT(Diagnostics().str(), HasSubstr("no matching call"));
}
TEST_F(IntrinsicTableTest, MatchI32) {
auto* f32 = create<sem::F32>();
auto* i32 = create<sem::I32>();
auto* vec4_f32 = create<sem::Vector>(f32, 4u);
auto* tex = create<sem::SampledTexture>(ast::TextureDimension::k1d, f32);
auto result = table->Lookup(BuiltinType::kTextureLoad, {tex, i32, i32}, Source{});
ASSERT_NE(result.sem, nullptr) << Diagnostics().str();
ASSERT_EQ(Diagnostics().str(), "");
EXPECT_EQ(result.sem->Type(), BuiltinType::kTextureLoad);
EXPECT_EQ(result.sem->ReturnType(), vec4_f32);
ASSERT_EQ(result.sem->Parameters().size(), 3u);
EXPECT_EQ(result.sem->Parameters()[0]->Type(), tex);
EXPECT_EQ(result.sem->Parameters()[0]->Usage(), ParameterUsage::kTexture);
EXPECT_EQ(result.sem->Parameters()[1]->Type(), i32);
EXPECT_EQ(result.sem->Parameters()[1]->Usage(), ParameterUsage::kCoords);
EXPECT_EQ(result.sem->Parameters()[2]->Type(), i32);
EXPECT_EQ(result.sem->Parameters()[2]->Usage(), ParameterUsage::kLevel);
}
TEST_F(IntrinsicTableTest, MismatchI32) {
auto* f32 = create<sem::F32>();
auto* tex = create<sem::SampledTexture>(ast::TextureDimension::k1d, f32);
auto result = table->Lookup(BuiltinType::kTextureLoad, {tex, f32}, Source{});
ASSERT_EQ(result.sem, nullptr);
ASSERT_THAT(Diagnostics().str(), HasSubstr("no matching call"));
}
TEST_F(IntrinsicTableTest, MatchIU32AsI32) {
auto* i32 = create<sem::I32>();
auto result = table->Lookup(BuiltinType::kCountOneBits, {i32}, Source{});
ASSERT_NE(result.sem, nullptr) << Diagnostics().str();
ASSERT_EQ(Diagnostics().str(), "");
EXPECT_EQ(result.sem->Type(), BuiltinType::kCountOneBits);
EXPECT_EQ(result.sem->ReturnType(), i32);
ASSERT_EQ(result.sem->Parameters().size(), 1u);
EXPECT_EQ(result.sem->Parameters()[0]->Type(), i32);
}
TEST_F(IntrinsicTableTest, MatchIU32AsU32) {
auto* u32 = create<sem::U32>();
auto result = table->Lookup(BuiltinType::kCountOneBits, {u32}, Source{});
ASSERT_NE(result.sem, nullptr) << Diagnostics().str();
ASSERT_EQ(Diagnostics().str(), "");
EXPECT_EQ(result.sem->Type(), BuiltinType::kCountOneBits);
EXPECT_EQ(result.sem->ReturnType(), u32);
ASSERT_EQ(result.sem->Parameters().size(), 1u);
EXPECT_EQ(result.sem->Parameters()[0]->Type(), u32);
}
TEST_F(IntrinsicTableTest, MismatchIU32) {
auto* f32 = create<sem::F32>();
auto result = table->Lookup(BuiltinType::kCountOneBits, {f32}, Source{});
ASSERT_EQ(result.sem, nullptr);
ASSERT_THAT(Diagnostics().str(), HasSubstr("no matching call"));
}
TEST_F(IntrinsicTableTest, MatchFIU32AsI32) {
auto* i32 = create<sem::I32>();
auto result = table->Lookup(BuiltinType::kClamp, {i32, i32, i32}, Source{});
ASSERT_NE(result.sem, nullptr) << Diagnostics().str();
ASSERT_EQ(Diagnostics().str(), "");
EXPECT_EQ(result.sem->Type(), BuiltinType::kClamp);
EXPECT_EQ(result.sem->ReturnType(), i32);
ASSERT_EQ(result.sem->Parameters().size(), 3u);
EXPECT_EQ(result.sem->Parameters()[0]->Type(), i32);
EXPECT_EQ(result.sem->Parameters()[1]->Type(), i32);
EXPECT_EQ(result.sem->Parameters()[2]->Type(), i32);
}
TEST_F(IntrinsicTableTest, MatchFIU32AsU32) {
auto* u32 = create<sem::U32>();
auto result = table->Lookup(BuiltinType::kClamp, {u32, u32, u32}, Source{});
ASSERT_NE(result.sem, nullptr) << Diagnostics().str();
ASSERT_EQ(Diagnostics().str(), "");
EXPECT_EQ(result.sem->Type(), BuiltinType::kClamp);
EXPECT_EQ(result.sem->ReturnType(), u32);
ASSERT_EQ(result.sem->Parameters().size(), 3u);
EXPECT_EQ(result.sem->Parameters()[0]->Type(), u32);
EXPECT_EQ(result.sem->Parameters()[1]->Type(), u32);
EXPECT_EQ(result.sem->Parameters()[2]->Type(), u32);
}
TEST_F(IntrinsicTableTest, MatchFIU32AsF32) {
auto* f32 = create<sem::F32>();
auto result = table->Lookup(BuiltinType::kClamp, {f32, f32, f32}, Source{});
ASSERT_NE(result.sem, nullptr) << Diagnostics().str();
ASSERT_EQ(Diagnostics().str(), "");
EXPECT_EQ(result.sem->Type(), BuiltinType::kClamp);
EXPECT_EQ(result.sem->ReturnType(), f32);
ASSERT_EQ(result.sem->Parameters().size(), 3u);
EXPECT_EQ(result.sem->Parameters()[0]->Type(), f32);
EXPECT_EQ(result.sem->Parameters()[1]->Type(), f32);
EXPECT_EQ(result.sem->Parameters()[2]->Type(), f32);
}
TEST_F(IntrinsicTableTest, MismatchFIU32) {
auto* bool_ = create<sem::Bool>();
auto result = table->Lookup(BuiltinType::kClamp, {bool_, bool_, bool_}, Source{});
ASSERT_EQ(result.sem, nullptr);
ASSERT_THAT(Diagnostics().str(), HasSubstr("no matching call"));
}
TEST_F(IntrinsicTableTest, MatchBool) {
auto* f32 = create<sem::F32>();
auto* bool_ = create<sem::Bool>();
auto result = table->Lookup(BuiltinType::kSelect, {f32, f32, bool_}, Source{});
ASSERT_NE(result.sem, nullptr) << Diagnostics().str();
ASSERT_EQ(Diagnostics().str(), "");
EXPECT_EQ(result.sem->Type(), BuiltinType::kSelect);
EXPECT_EQ(result.sem->ReturnType(), f32);
ASSERT_EQ(result.sem->Parameters().size(), 3u);
EXPECT_EQ(result.sem->Parameters()[0]->Type(), f32);
EXPECT_EQ(result.sem->Parameters()[1]->Type(), f32);
EXPECT_EQ(result.sem->Parameters()[2]->Type(), bool_);
}
TEST_F(IntrinsicTableTest, MismatchBool) {
auto* f32 = create<sem::F32>();
auto result = table->Lookup(BuiltinType::kSelect, {f32, f32, f32}, Source{});
ASSERT_EQ(result.sem, nullptr);
ASSERT_THAT(Diagnostics().str(), HasSubstr("no matching call"));
}
TEST_F(IntrinsicTableTest, MatchPointer) {
auto* i32 = create<sem::I32>();
auto* atomicI32 = create<sem::Atomic>(i32);
auto* ptr =
create<sem::Pointer>(atomicI32, ast::StorageClass::kWorkgroup, ast::Access::kReadWrite);
auto result = table->Lookup(BuiltinType::kAtomicLoad, {ptr}, Source{});
ASSERT_NE(result.sem, nullptr) << Diagnostics().str();
ASSERT_EQ(Diagnostics().str(), "");
EXPECT_EQ(result.sem->Type(), BuiltinType::kAtomicLoad);
EXPECT_EQ(result.sem->ReturnType(), i32);
ASSERT_EQ(result.sem->Parameters().size(), 1u);
EXPECT_EQ(result.sem->Parameters()[0]->Type(), ptr);
}
TEST_F(IntrinsicTableTest, MismatchPointer) {
auto* i32 = create<sem::I32>();
auto* atomicI32 = create<sem::Atomic>(i32);
auto result = table->Lookup(BuiltinType::kAtomicLoad, {atomicI32}, Source{});
ASSERT_EQ(result.sem, nullptr);
ASSERT_THAT(Diagnostics().str(), HasSubstr("no matching call"));
}
TEST_F(IntrinsicTableTest, MatchArray) {
auto* arr = create<sem::Array>(create<sem::U32>(), 0u, 4u, 4u, 4u, 4u);
auto* arr_ptr = create<sem::Pointer>(arr, ast::StorageClass::kStorage, ast::Access::kReadWrite);
auto result = table->Lookup(BuiltinType::kArrayLength, {arr_ptr}, Source{});
ASSERT_NE(result.sem, nullptr) << Diagnostics().str();
ASSERT_EQ(Diagnostics().str(), "");
EXPECT_EQ(result.sem->Type(), BuiltinType::kArrayLength);
EXPECT_TRUE(result.sem->ReturnType()->Is<sem::U32>());
ASSERT_EQ(result.sem->Parameters().size(), 1u);
auto* param_type = result.sem->Parameters()[0]->Type();
ASSERT_TRUE(param_type->Is<sem::Pointer>());
EXPECT_TRUE(param_type->As<sem::Pointer>()->StoreType()->Is<sem::Array>());
}
TEST_F(IntrinsicTableTest, MismatchArray) {
auto* f32 = create<sem::F32>();
auto result = table->Lookup(BuiltinType::kArrayLength, {f32}, Source{});
ASSERT_EQ(result.sem, nullptr);
ASSERT_THAT(Diagnostics().str(), HasSubstr("no matching call"));
}
TEST_F(IntrinsicTableTest, MatchSampler) {
auto* f32 = create<sem::F32>();
auto* vec2_f32 = create<sem::Vector>(f32, 2u);
auto* vec4_f32 = create<sem::Vector>(f32, 4u);
auto* tex = create<sem::SampledTexture>(ast::TextureDimension::k2d, f32);
auto* sampler = create<sem::Sampler>(ast::SamplerKind::kSampler);
auto result = table->Lookup(BuiltinType::kTextureSample, {tex, sampler, vec2_f32}, Source{});
ASSERT_NE(result.sem, nullptr) << Diagnostics().str();
ASSERT_EQ(Diagnostics().str(), "");
EXPECT_EQ(result.sem->Type(), BuiltinType::kTextureSample);
EXPECT_EQ(result.sem->ReturnType(), vec4_f32);
ASSERT_EQ(result.sem->Parameters().size(), 3u);
EXPECT_EQ(result.sem->Parameters()[0]->Type(), tex);
EXPECT_EQ(result.sem->Parameters()[0]->Usage(), ParameterUsage::kTexture);
EXPECT_EQ(result.sem->Parameters()[1]->Type(), sampler);
EXPECT_EQ(result.sem->Parameters()[1]->Usage(), ParameterUsage::kSampler);
EXPECT_EQ(result.sem->Parameters()[2]->Type(), vec2_f32);
EXPECT_EQ(result.sem->Parameters()[2]->Usage(), ParameterUsage::kCoords);
}
TEST_F(IntrinsicTableTest, MismatchSampler) {
auto* f32 = create<sem::F32>();
auto* vec2_f32 = create<sem::Vector>(f32, 2u);
auto* tex = create<sem::SampledTexture>(ast::TextureDimension::k2d, f32);
auto result = table->Lookup(BuiltinType::kTextureSample, {tex, f32, vec2_f32}, Source{});
ASSERT_EQ(result.sem, nullptr);
ASSERT_THAT(Diagnostics().str(), HasSubstr("no matching call"));
}
TEST_F(IntrinsicTableTest, MatchSampledTexture) {
auto* i32 = create<sem::I32>();
auto* f32 = create<sem::F32>();
auto* vec2_i32 = create<sem::Vector>(i32, 2u);
auto* vec4_f32 = create<sem::Vector>(f32, 4u);
auto* tex = create<sem::SampledTexture>(ast::TextureDimension::k2d, f32);
auto result = table->Lookup(BuiltinType::kTextureLoad, {tex, vec2_i32, i32}, Source{});
ASSERT_NE(result.sem, nullptr) << Diagnostics().str();
ASSERT_EQ(Diagnostics().str(), "");
EXPECT_EQ(result.sem->Type(), BuiltinType::kTextureLoad);
EXPECT_EQ(result.sem->ReturnType(), vec4_f32);
ASSERT_EQ(result.sem->Parameters().size(), 3u);
EXPECT_EQ(result.sem->Parameters()[0]->Type(), tex);
EXPECT_EQ(result.sem->Parameters()[0]->Usage(), ParameterUsage::kTexture);
EXPECT_EQ(result.sem->Parameters()[1]->Type(), vec2_i32);
EXPECT_EQ(result.sem->Parameters()[1]->Usage(), ParameterUsage::kCoords);
EXPECT_EQ(result.sem->Parameters()[2]->Type(), i32);
EXPECT_EQ(result.sem->Parameters()[2]->Usage(), ParameterUsage::kLevel);
}
TEST_F(IntrinsicTableTest, MatchMultisampledTexture) {
auto* i32 = create<sem::I32>();
auto* f32 = create<sem::F32>();
auto* vec2_i32 = create<sem::Vector>(i32, 2u);
auto* vec4_f32 = create<sem::Vector>(f32, 4u);
auto* tex = create<sem::MultisampledTexture>(ast::TextureDimension::k2d, f32);
auto result = table->Lookup(BuiltinType::kTextureLoad, {tex, vec2_i32, i32}, Source{});
ASSERT_NE(result.sem, nullptr) << Diagnostics().str();
ASSERT_EQ(Diagnostics().str(), "");
EXPECT_EQ(result.sem->Type(), BuiltinType::kTextureLoad);
EXPECT_EQ(result.sem->ReturnType(), vec4_f32);
ASSERT_EQ(result.sem->Parameters().size(), 3u);
EXPECT_EQ(result.sem->Parameters()[0]->Type(), tex);
EXPECT_EQ(result.sem->Parameters()[0]->Usage(), ParameterUsage::kTexture);
EXPECT_EQ(result.sem->Parameters()[1]->Type(), vec2_i32);
EXPECT_EQ(result.sem->Parameters()[1]->Usage(), ParameterUsage::kCoords);
EXPECT_EQ(result.sem->Parameters()[2]->Type(), i32);
EXPECT_EQ(result.sem->Parameters()[2]->Usage(), ParameterUsage::kSampleIndex);
}
TEST_F(IntrinsicTableTest, MatchDepthTexture) {
auto* f32 = create<sem::F32>();
auto* i32 = create<sem::I32>();
auto* vec2_i32 = create<sem::Vector>(i32, 2u);
auto* tex = create<sem::DepthTexture>(ast::TextureDimension::k2d);
auto result = table->Lookup(BuiltinType::kTextureLoad, {tex, vec2_i32, i32}, Source{});
ASSERT_NE(result.sem, nullptr) << Diagnostics().str();
ASSERT_EQ(Diagnostics().str(), "");
EXPECT_EQ(result.sem->Type(), BuiltinType::kTextureLoad);
EXPECT_EQ(result.sem->ReturnType(), f32);
ASSERT_EQ(result.sem->Parameters().size(), 3u);
EXPECT_EQ(result.sem->Parameters()[0]->Type(), tex);
EXPECT_EQ(result.sem->Parameters()[0]->Usage(), ParameterUsage::kTexture);
EXPECT_EQ(result.sem->Parameters()[1]->Type(), vec2_i32);
EXPECT_EQ(result.sem->Parameters()[1]->Usage(), ParameterUsage::kCoords);
EXPECT_EQ(result.sem->Parameters()[2]->Type(), i32);
EXPECT_EQ(result.sem->Parameters()[2]->Usage(), ParameterUsage::kLevel);
}
TEST_F(IntrinsicTableTest, MatchDepthMultisampledTexture) {
auto* f32 = create<sem::F32>();
auto* i32 = create<sem::I32>();
auto* vec2_i32 = create<sem::Vector>(i32, 2u);
auto* tex = create<sem::DepthMultisampledTexture>(ast::TextureDimension::k2d);
auto result = table->Lookup(BuiltinType::kTextureLoad, {tex, vec2_i32, i32}, Source{});
ASSERT_NE(result.sem, nullptr) << Diagnostics().str();
ASSERT_EQ(Diagnostics().str(), "");
EXPECT_EQ(result.sem->Type(), BuiltinType::kTextureLoad);
EXPECT_EQ(result.sem->ReturnType(), f32);
ASSERT_EQ(result.sem->Parameters().size(), 3u);
EXPECT_EQ(result.sem->Parameters()[0]->Type(), tex);
EXPECT_EQ(result.sem->Parameters()[0]->Usage(), ParameterUsage::kTexture);
EXPECT_EQ(result.sem->Parameters()[1]->Type(), vec2_i32);
EXPECT_EQ(result.sem->Parameters()[1]->Usage(), ParameterUsage::kCoords);
EXPECT_EQ(result.sem->Parameters()[2]->Type(), i32);
EXPECT_EQ(result.sem->Parameters()[2]->Usage(), ParameterUsage::kSampleIndex);
}
TEST_F(IntrinsicTableTest, MatchExternalTexture) {
auto* f32 = create<sem::F32>();
auto* i32 = create<sem::I32>();
auto* vec2_i32 = create<sem::Vector>(i32, 2u);
auto* vec4_f32 = create<sem::Vector>(f32, 4u);
auto* tex = create<sem::ExternalTexture>();
auto result = table->Lookup(BuiltinType::kTextureLoad, {tex, vec2_i32}, Source{});
ASSERT_NE(result.sem, nullptr) << Diagnostics().str();
ASSERT_EQ(Diagnostics().str(), "");
EXPECT_EQ(result.sem->Type(), BuiltinType::kTextureLoad);
EXPECT_EQ(result.sem->ReturnType(), vec4_f32);
ASSERT_EQ(result.sem->Parameters().size(), 2u);
EXPECT_EQ(result.sem->Parameters()[0]->Type(), tex);
EXPECT_EQ(result.sem->Parameters()[0]->Usage(), ParameterUsage::kTexture);
EXPECT_EQ(result.sem->Parameters()[1]->Type(), vec2_i32);
EXPECT_EQ(result.sem->Parameters()[1]->Usage(), ParameterUsage::kCoords);
}
TEST_F(IntrinsicTableTest, MatchWOStorageTexture) {
auto* f32 = create<sem::F32>();
auto* i32 = create<sem::I32>();
auto* vec2_i32 = create<sem::Vector>(i32, 2u);
auto* vec4_f32 = create<sem::Vector>(f32, 4u);
auto* subtype = sem::StorageTexture::SubtypeFor(ast::TexelFormat::kR32Float, Types());
auto* tex = create<sem::StorageTexture>(ast::TextureDimension::k2d, ast::TexelFormat::kR32Float,
ast::Access::kWrite, subtype);
auto result = table->Lookup(BuiltinType::kTextureStore, {tex, vec2_i32, vec4_f32}, Source{});
ASSERT_NE(result.sem, nullptr) << Diagnostics().str();
ASSERT_EQ(Diagnostics().str(), "");
EXPECT_EQ(result.sem->Type(), BuiltinType::kTextureStore);
EXPECT_TRUE(result.sem->ReturnType()->Is<sem::Void>());
ASSERT_EQ(result.sem->Parameters().size(), 3u);
EXPECT_EQ(result.sem->Parameters()[0]->Type(), tex);
EXPECT_EQ(result.sem->Parameters()[0]->Usage(), ParameterUsage::kTexture);
EXPECT_EQ(result.sem->Parameters()[1]->Type(), vec2_i32);
EXPECT_EQ(result.sem->Parameters()[1]->Usage(), ParameterUsage::kCoords);
EXPECT_EQ(result.sem->Parameters()[2]->Type(), vec4_f32);
EXPECT_EQ(result.sem->Parameters()[2]->Usage(), ParameterUsage::kValue);
}
TEST_F(IntrinsicTableTest, MismatchTexture) {
auto* f32 = create<sem::F32>();
auto* i32 = create<sem::I32>();
auto* vec2_i32 = create<sem::Vector>(i32, 2u);
auto result = table->Lookup(BuiltinType::kTextureLoad, {f32, vec2_i32}, Source{});
ASSERT_EQ(result.sem, nullptr);
ASSERT_THAT(Diagnostics().str(), HasSubstr("no matching call"));
}
TEST_F(IntrinsicTableTest, ImplicitLoadOnReference) {
auto* f32 = create<sem::F32>();
auto result = table->Lookup(
BuiltinType::kCos,
{create<sem::Reference>(f32, ast::StorageClass::kFunction, ast::Access::kReadWrite)},
Source{});
ASSERT_NE(result.sem, nullptr) << Diagnostics().str();
ASSERT_EQ(Diagnostics().str(), "");
EXPECT_EQ(result.sem->Type(), BuiltinType::kCos);
EXPECT_EQ(result.sem->ReturnType(), f32);
ASSERT_EQ(result.sem->Parameters().size(), 1u);
EXPECT_EQ(result.sem->Parameters()[0]->Type(), f32);
}
TEST_F(IntrinsicTableTest, MatchTemplateType) {
auto* f32 = create<sem::F32>();
auto result = table->Lookup(BuiltinType::kClamp, {f32, f32, f32}, Source{});
ASSERT_NE(result.sem, nullptr) << Diagnostics().str();
ASSERT_EQ(Diagnostics().str(), "");
EXPECT_EQ(result.sem->Type(), BuiltinType::kClamp);
EXPECT_EQ(result.sem->ReturnType(), f32);
EXPECT_EQ(result.sem->Parameters()[0]->Type(), f32);
EXPECT_EQ(result.sem->Parameters()[1]->Type(), f32);
EXPECT_EQ(result.sem->Parameters()[2]->Type(), f32);
}
TEST_F(IntrinsicTableTest, MismatchTemplateType) {
auto* f32 = create<sem::F32>();
auto* u32 = create<sem::U32>();
auto result = table->Lookup(BuiltinType::kClamp, {f32, u32, f32}, Source{});
ASSERT_EQ(result.sem, nullptr);
ASSERT_THAT(Diagnostics().str(), HasSubstr("no matching call"));
}
TEST_F(IntrinsicTableTest, MatchOpenSizeVector) {
auto* f32 = create<sem::F32>();
auto* vec2_f32 = create<sem::Vector>(f32, 2u);
auto result = table->Lookup(BuiltinType::kClamp, {vec2_f32, vec2_f32, vec2_f32}, Source{});
ASSERT_NE(result.sem, nullptr) << Diagnostics().str();
ASSERT_EQ(Diagnostics().str(), "");
EXPECT_EQ(result.sem->Type(), BuiltinType::kClamp);
EXPECT_EQ(result.sem->ReturnType(), vec2_f32);
ASSERT_EQ(result.sem->Parameters().size(), 3u);
EXPECT_EQ(result.sem->Parameters()[0]->Type(), vec2_f32);
EXPECT_EQ(result.sem->Parameters()[1]->Type(), vec2_f32);
EXPECT_EQ(result.sem->Parameters()[2]->Type(), vec2_f32);
}
TEST_F(IntrinsicTableTest, MismatchOpenSizeVector) {
auto* f32 = create<sem::F32>();
auto* u32 = create<sem::U32>();
auto* vec2_f32 = create<sem::Vector>(f32, 2u);
auto result = table->Lookup(BuiltinType::kClamp, {vec2_f32, u32, vec2_f32}, Source{});
ASSERT_EQ(result.sem, nullptr);
ASSERT_THAT(Diagnostics().str(), HasSubstr("no matching call"));
}
TEST_F(IntrinsicTableTest, MatchOpenSizeMatrix) {
auto* f32 = create<sem::F32>();
auto* vec3_f32 = create<sem::Vector>(f32, 3u);
auto* mat3_f32 = create<sem::Matrix>(vec3_f32, 3u);
auto result = table->Lookup(BuiltinType::kDeterminant, {mat3_f32}, Source{});
ASSERT_NE(result.sem, nullptr) << Diagnostics().str();
ASSERT_EQ(Diagnostics().str(), "");
EXPECT_EQ(result.sem->Type(), BuiltinType::kDeterminant);
EXPECT_EQ(result.sem->ReturnType(), f32);
ASSERT_EQ(result.sem->Parameters().size(), 1u);
EXPECT_EQ(result.sem->Parameters()[0]->Type(), mat3_f32);
}
TEST_F(IntrinsicTableTest, MismatchOpenSizeMatrix) {
auto* f32 = create<sem::F32>();
auto* vec2_f32 = create<sem::Vector>(f32, 2u);
auto* mat3x2_f32 = create<sem::Matrix>(vec2_f32, 3u);
auto result = table->Lookup(BuiltinType::kDeterminant, {mat3x2_f32}, Source{});
ASSERT_EQ(result.sem, nullptr);
ASSERT_THAT(Diagnostics().str(), HasSubstr("no matching call"));
}
TEST_F(IntrinsicTableTest, OverloadOrderByNumberOfParameters) {
// None of the arguments match, so expect the overloads with 2 parameters to
// come first
auto* bool_ = create<sem::Bool>();
table->Lookup(BuiltinType::kTextureDimensions, {bool_, bool_}, Source{});
ASSERT_EQ(Diagnostics().str(),
R"(error: no matching call to textureDimensions(bool, bool)
27 candidate functions:
textureDimensions(texture: texture_1d<T>, level: i32) -> i32 where: T is f32, i32 or u32
textureDimensions(texture: texture_2d<T>, level: i32) -> vec2<i32> where: T is f32, i32 or u32
textureDimensions(texture: texture_2d_array<T>, level: i32) -> vec2<i32> where: T is f32, i32 or u32
textureDimensions(texture: texture_3d<T>, level: i32) -> vec3<i32> where: T is f32, i32 or u32
textureDimensions(texture: texture_cube<T>, level: i32) -> vec2<i32> where: T is f32, i32 or u32
textureDimensions(texture: texture_cube_array<T>, level: i32) -> vec2<i32> where: T is f32, i32 or u32
textureDimensions(texture: texture_depth_2d, level: i32) -> vec2<i32>
textureDimensions(texture: texture_depth_2d_array, level: i32) -> vec2<i32>
textureDimensions(texture: texture_depth_cube, level: i32) -> vec2<i32>
textureDimensions(texture: texture_depth_cube_array, level: i32) -> vec2<i32>
textureDimensions(texture: texture_1d<T>) -> i32 where: T is f32, i32 or u32
textureDimensions(texture: texture_2d<T>) -> vec2<i32> where: T is f32, i32 or u32
textureDimensions(texture: texture_2d_array<T>) -> vec2<i32> where: T is f32, i32 or u32
textureDimensions(texture: texture_3d<T>) -> vec3<i32> where: T is f32, i32 or u32
textureDimensions(texture: texture_cube<T>) -> vec2<i32> where: T is f32, i32 or u32
textureDimensions(texture: texture_cube_array<T>) -> vec2<i32> where: T is f32, i32 or u32
textureDimensions(texture: texture_multisampled_2d<T>) -> vec2<i32> where: T is f32, i32 or u32
textureDimensions(texture: texture_depth_2d) -> vec2<i32>
textureDimensions(texture: texture_depth_2d_array) -> vec2<i32>
textureDimensions(texture: texture_depth_cube) -> vec2<i32>
textureDimensions(texture: texture_depth_cube_array) -> vec2<i32>
textureDimensions(texture: texture_depth_multisampled_2d) -> vec2<i32>
textureDimensions(texture: texture_storage_1d<F, A>) -> i32 where: A is write
textureDimensions(texture: texture_storage_2d<F, A>) -> vec2<i32> where: A is write
textureDimensions(texture: texture_storage_2d_array<F, A>) -> vec2<i32> where: A is write
textureDimensions(texture: texture_storage_3d<F, A>) -> vec3<i32> where: A is write
textureDimensions(texture: texture_external) -> vec2<i32>
)");
}
TEST_F(IntrinsicTableTest, OverloadOrderByMatchingParameter) {
auto* tex = create<sem::DepthTexture>(ast::TextureDimension::k2d);
auto* bool_ = create<sem::Bool>();
table->Lookup(BuiltinType::kTextureDimensions, {tex, bool_}, Source{});
ASSERT_EQ(Diagnostics().str(),
R"(error: no matching call to textureDimensions(texture_depth_2d, bool)
27 candidate functions:
textureDimensions(texture: texture_depth_2d, level: i32) -> vec2<i32>
textureDimensions(texture: texture_depth_2d) -> vec2<i32>
textureDimensions(texture: texture_1d<T>, level: i32) -> i32 where: T is f32, i32 or u32
textureDimensions(texture: texture_2d<T>, level: i32) -> vec2<i32> where: T is f32, i32 or u32
textureDimensions(texture: texture_2d_array<T>, level: i32) -> vec2<i32> where: T is f32, i32 or u32
textureDimensions(texture: texture_3d<T>, level: i32) -> vec3<i32> where: T is f32, i32 or u32
textureDimensions(texture: texture_cube<T>, level: i32) -> vec2<i32> where: T is f32, i32 or u32
textureDimensions(texture: texture_cube_array<T>, level: i32) -> vec2<i32> where: T is f32, i32 or u32
textureDimensions(texture: texture_depth_2d_array, level: i32) -> vec2<i32>
textureDimensions(texture: texture_depth_cube, level: i32) -> vec2<i32>
textureDimensions(texture: texture_depth_cube_array, level: i32) -> vec2<i32>
textureDimensions(texture: texture_1d<T>) -> i32 where: T is f32, i32 or u32
textureDimensions(texture: texture_2d<T>) -> vec2<i32> where: T is f32, i32 or u32
textureDimensions(texture: texture_2d_array<T>) -> vec2<i32> where: T is f32, i32 or u32
textureDimensions(texture: texture_3d<T>) -> vec3<i32> where: T is f32, i32 or u32
textureDimensions(texture: texture_cube<T>) -> vec2<i32> where: T is f32, i32 or u32
textureDimensions(texture: texture_cube_array<T>) -> vec2<i32> where: T is f32, i32 or u32
textureDimensions(texture: texture_multisampled_2d<T>) -> vec2<i32> where: T is f32, i32 or u32
textureDimensions(texture: texture_depth_2d_array) -> vec2<i32>
textureDimensions(texture: texture_depth_cube) -> vec2<i32>
textureDimensions(texture: texture_depth_cube_array) -> vec2<i32>
textureDimensions(texture: texture_depth_multisampled_2d) -> vec2<i32>
textureDimensions(texture: texture_storage_1d<F, A>) -> i32 where: A is write
textureDimensions(texture: texture_storage_2d<F, A>) -> vec2<i32> where: A is write
textureDimensions(texture: texture_storage_2d_array<F, A>) -> vec2<i32> where: A is write
textureDimensions(texture: texture_storage_3d<F, A>) -> vec3<i32> where: A is write
textureDimensions(texture: texture_external) -> vec2<i32>
)");
}
TEST_F(IntrinsicTableTest, SameOverloadReturnsSameBuiltinPointer) {
auto* f32 = create<sem::F32>();
auto* vec2_f32 = create<sem::Vector>(create<sem::F32>(), 2u);
auto* bool_ = create<sem::Bool>();
auto a = table->Lookup(BuiltinType::kSelect, {f32, f32, bool_}, Source{});
ASSERT_NE(a.sem, nullptr) << Diagnostics().str();
auto b = table->Lookup(BuiltinType::kSelect, {f32, f32, bool_}, Source{});
ASSERT_NE(b.sem, nullptr) << Diagnostics().str();
ASSERT_EQ(Diagnostics().str(), "");
auto c = table->Lookup(BuiltinType::kSelect, {vec2_f32, vec2_f32, bool_}, Source{});
ASSERT_NE(c.sem, nullptr) << Diagnostics().str();
ASSERT_EQ(Diagnostics().str(), "");
EXPECT_EQ(a.sem, b.sem);
EXPECT_NE(a.sem, c.sem);
EXPECT_NE(b.sem, c.sem);
}
TEST_F(IntrinsicTableTest, MatchUnaryOp) {
auto* i32 = create<sem::I32>();
auto* vec3_i32 = create<sem::Vector>(i32, 3u);
auto result = table->Lookup(ast::UnaryOp::kNegation, vec3_i32, Source{{12, 34}});
EXPECT_EQ(result.result, vec3_i32);
EXPECT_EQ(result.result, vec3_i32);
EXPECT_EQ(Diagnostics().str(), "");
}
TEST_F(IntrinsicTableTest, MismatchUnaryOp) {
auto* bool_ = create<sem::Bool>();
auto result = table->Lookup(ast::UnaryOp::kNegation, bool_, Source{{12, 34}});
ASSERT_EQ(result.result, nullptr);
EXPECT_EQ(Diagnostics().str(), R"(12:34 error: no matching overload for operator - (bool)
2 candidate operators:
operator - (T) -> T where: T is f32 or i32
operator - (vecN<T>) -> vecN<T> where: T is f32 or i32
)");
}
TEST_F(IntrinsicTableTest, MatchBinaryOp) {
auto* i32 = create<sem::I32>();
auto* vec3_i32 = create<sem::Vector>(i32, 3u);
auto result = table->Lookup(ast::BinaryOp::kMultiply, i32, vec3_i32, Source{{12, 34}},
/* is_compound */ false);
EXPECT_EQ(result.result, vec3_i32);
EXPECT_EQ(result.lhs, i32);
EXPECT_EQ(result.rhs, vec3_i32);
EXPECT_EQ(Diagnostics().str(), "");
}
TEST_F(IntrinsicTableTest, MismatchBinaryOp) {
auto* f32 = create<sem::F32>();
auto* bool_ = create<sem::Bool>();
auto result = table->Lookup(ast::BinaryOp::kMultiply, f32, bool_, Source{{12, 34}},
/* is_compound */ false);
ASSERT_EQ(result.result, nullptr);
EXPECT_EQ(Diagnostics().str(), R"(12:34 error: no matching overload for operator * (f32, bool)
9 candidate operators:
operator * (T, T) -> T where: T is f32, i32 or u32
operator * (vecN<T>, T) -> vecN<T> where: T is f32, i32 or u32
operator * (T, vecN<T>) -> vecN<T> where: T is f32, i32 or u32
operator * (f32, matNxM<f32>) -> matNxM<f32>
operator * (vecN<T>, vecN<T>) -> vecN<T> where: T is f32, i32 or u32
operator * (matNxM<f32>, f32) -> matNxM<f32>
operator * (matCxR<f32>, vecC<f32>) -> vecR<f32>
operator * (vecR<f32>, matCxR<f32>) -> vecC<f32>
operator * (matKxR<f32>, matCxK<f32>) -> matCxR<f32>
)");
}
TEST_F(IntrinsicTableTest, MatchCompoundOp) {
auto* i32 = create<sem::I32>();
auto* vec3_i32 = create<sem::Vector>(i32, 3u);
auto result = table->Lookup(ast::BinaryOp::kMultiply, i32, vec3_i32, Source{{12, 34}},
/* is_compound */ true);
EXPECT_EQ(result.result, vec3_i32);
EXPECT_EQ(result.lhs, i32);
EXPECT_EQ(result.rhs, vec3_i32);
EXPECT_EQ(Diagnostics().str(), "");
}
TEST_F(IntrinsicTableTest, MismatchCompoundOp) {
auto* f32 = create<sem::F32>();
auto* bool_ = create<sem::Bool>();
auto result = table->Lookup(ast::BinaryOp::kMultiply, f32, bool_, Source{{12, 34}},
/* is_compound */ true);
ASSERT_EQ(result.result, nullptr);
EXPECT_EQ(Diagnostics().str(), R"(12:34 error: no matching overload for operator *= (f32, bool)
9 candidate operators:
operator *= (T, T) -> T where: T is f32, i32 or u32
operator *= (vecN<T>, T) -> vecN<T> where: T is f32, i32 or u32
operator *= (T, vecN<T>) -> vecN<T> where: T is f32, i32 or u32
operator *= (f32, matNxM<f32>) -> matNxM<f32>
operator *= (vecN<T>, vecN<T>) -> vecN<T> where: T is f32, i32 or u32
operator *= (matNxM<f32>, f32) -> matNxM<f32>
operator *= (matCxR<f32>, vecC<f32>) -> vecR<f32>
operator *= (vecR<f32>, matCxR<f32>) -> vecC<f32>
operator *= (matKxR<f32>, matCxK<f32>) -> matCxR<f32>
)");
}
TEST_F(IntrinsicTableTest, MatchTypeConstructorImplicit) {
auto* i32 = create<sem::I32>();
auto* vec3_i32 = create<sem::Vector>(i32, 3u);
auto result =
table->Lookup(CtorConvIntrinsic::kVec3, nullptr, {i32, i32, i32}, Source{{12, 34}});
ASSERT_NE(result.target, nullptr);
EXPECT_EQ(result.target->ReturnType(), vec3_i32);
EXPECT_TRUE(result.target->Is<sem::TypeConstructor>());
ASSERT_EQ(result.target->Parameters().size(), 3u);
EXPECT_EQ(result.target->Parameters()[0]->Type(), i32);
EXPECT_EQ(result.target->Parameters()[1]->Type(), i32);
EXPECT_EQ(result.target->Parameters()[2]->Type(), i32);
EXPECT_NE(result.const_eval_fn, nullptr);
}
TEST_F(IntrinsicTableTest, MatchTypeConstructorExplicit) {
auto* i32 = create<sem::I32>();
auto* vec3_i32 = create<sem::Vector>(i32, 3u);
auto result = table->Lookup(CtorConvIntrinsic::kVec3, i32, {i32, i32, i32}, Source{{12, 34}});
ASSERT_NE(result.target, nullptr);
EXPECT_EQ(result.target->ReturnType(), vec3_i32);
EXPECT_TRUE(result.target->Is<sem::TypeConstructor>());
ASSERT_EQ(result.target->Parameters().size(), 3u);
EXPECT_EQ(result.target->Parameters()[0]->Type(), i32);
EXPECT_EQ(result.target->Parameters()[1]->Type(), i32);
EXPECT_EQ(result.target->Parameters()[2]->Type(), i32);
EXPECT_NE(result.const_eval_fn, nullptr);
}
TEST_F(IntrinsicTableTest, MismatchTypeConstructorImplicit) {
auto* i32 = create<sem::I32>();
auto* f32 = create<sem::F32>();
auto result =
table->Lookup(CtorConvIntrinsic::kVec3, nullptr, {i32, f32, i32}, Source{{12, 34}});
ASSERT_EQ(result.target, nullptr);
EXPECT_EQ(Diagnostics().str(), R"(12:34 error: no matching constructor for vec3(i32, f32, i32)
6 candidate constructors:
vec3(x: T, y: T, z: T) -> vec3<T> where: T is abstract-int, abstract-float, f32, f16, i32, u32 or bool
vec3(xy: vec2<T>, z: T) -> vec3<T> where: T is abstract-int, abstract-float, f32, f16, i32, u32 or bool
vec3(x: T, yz: vec2<T>) -> vec3<T> where: T is abstract-int, abstract-float, f32, f16, i32, u32 or bool
vec3(T) -> vec3<T> where: T is abstract-int, abstract-float, f32, f16, i32, u32 or bool
vec3(vec3<T>) -> vec3<T> where: T is f32, f16, i32, u32 or bool
vec3() -> vec3<T> where: T is f32, f16, i32, u32 or bool
5 candidate conversions:
vec3(vec3<U>) -> vec3<f32> where: T is f32, U is i32, f16, u32 or bool
vec3(vec3<U>) -> vec3<f16> where: T is f16, U is f32, i32, u32 or bool
vec3(vec3<U>) -> vec3<i32> where: T is i32, U is f32, f16, u32 or bool
vec3(vec3<U>) -> vec3<u32> where: T is u32, U is f32, f16, i32 or bool
vec3(vec3<U>) -> vec3<bool> where: T is bool, U is f32, f16, i32 or u32
)");
}
TEST_F(IntrinsicTableTest, MismatchTypeConstructorExplicit) {
auto* i32 = create<sem::I32>();
auto* f32 = create<sem::F32>();
auto result = table->Lookup(CtorConvIntrinsic::kVec3, i32, {i32, f32, i32}, Source{{12, 34}});
ASSERT_EQ(result.target, nullptr);
EXPECT_EQ(Diagnostics().str(),
R"(12:34 error: no matching constructor for vec3<i32>(i32, f32, i32)
6 candidate constructors:
vec3(x: T, y: T, z: T) -> vec3<T> where: T is abstract-int, abstract-float, f32, f16, i32, u32 or bool
vec3(x: T, yz: vec2<T>) -> vec3<T> where: T is abstract-int, abstract-float, f32, f16, i32, u32 or bool
vec3(T) -> vec3<T> where: T is abstract-int, abstract-float, f32, f16, i32, u32 or bool
vec3(xy: vec2<T>, z: T) -> vec3<T> where: T is abstract-int, abstract-float, f32, f16, i32, u32 or bool
vec3(vec3<T>) -> vec3<T> where: T is f32, f16, i32, u32 or bool
vec3() -> vec3<T> where: T is f32, f16, i32, u32 or bool
5 candidate conversions:
vec3(vec3<U>) -> vec3<f32> where: T is f32, U is i32, f16, u32 or bool
vec3(vec3<U>) -> vec3<f16> where: T is f16, U is f32, i32, u32 or bool
vec3(vec3<U>) -> vec3<i32> where: T is i32, U is f32, f16, u32 or bool
vec3(vec3<U>) -> vec3<u32> where: T is u32, U is f32, f16, i32 or bool
vec3(vec3<U>) -> vec3<bool> where: T is bool, U is f32, f16, i32 or u32
)");
}
TEST_F(IntrinsicTableTest, MatchTypeConversion) {
auto* i32 = create<sem::I32>();
auto* vec3_i32 = create<sem::Vector>(i32, 3u);
auto* f32 = create<sem::F32>();
auto* vec3_f32 = create<sem::Vector>(f32, 3u);
auto result = table->Lookup(CtorConvIntrinsic::kVec3, i32, {vec3_f32}, Source{{12, 34}});
ASSERT_NE(result.target, nullptr);
EXPECT_EQ(result.target->ReturnType(), vec3_i32);
EXPECT_TRUE(result.target->Is<sem::TypeConversion>());
ASSERT_EQ(result.target->Parameters().size(), 1u);
EXPECT_EQ(result.target->Parameters()[0]->Type(), vec3_f32);
}
TEST_F(IntrinsicTableTest, MismatchTypeConversion) {
auto* arr = create<sem::Array>(create<sem::U32>(), 0u, 4u, 4u, 4u, 4u);
auto* f32 = create<sem::F32>();
auto result = table->Lookup(CtorConvIntrinsic::kVec3, f32, {arr}, Source{{12, 34}});
ASSERT_EQ(result.target, nullptr);
EXPECT_EQ(Diagnostics().str(),
R"(12:34 error: no matching constructor for vec3<f32>(array<u32>)
6 candidate constructors:
vec3(vec3<T>) -> vec3<T> where: T is f32, f16, i32, u32 or bool
vec3(T) -> vec3<T> where: T is abstract-int, abstract-float, f32, f16, i32, u32 or bool
vec3() -> vec3<T> where: T is f32, f16, i32, u32 or bool
vec3(xy: vec2<T>, z: T) -> vec3<T> where: T is abstract-int, abstract-float, f32, f16, i32, u32 or bool
vec3(x: T, yz: vec2<T>) -> vec3<T> where: T is abstract-int, abstract-float, f32, f16, i32, u32 or bool
vec3(x: T, y: T, z: T) -> vec3<T> where: T is abstract-int, abstract-float, f32, f16, i32, u32 or bool
5 candidate conversions:
vec3(vec3<U>) -> vec3<f32> where: T is f32, U is i32, f16, u32 or bool
vec3(vec3<U>) -> vec3<f16> where: T is f16, U is f32, i32, u32 or bool
vec3(vec3<U>) -> vec3<i32> where: T is i32, U is f32, f16, u32 or bool
vec3(vec3<U>) -> vec3<u32> where: T is u32, U is f32, f16, i32 or bool
vec3(vec3<U>) -> vec3<bool> where: T is bool, U is f32, f16, i32 or u32
)");
}
TEST_F(IntrinsicTableTest, Err257Arguments) { // crbug.com/1323605
auto* f32 = create<sem::F32>();
std::vector<const sem::Type*> arg_tys(257, f32);
auto result = table->Lookup(BuiltinType::kAbs, std::move(arg_tys), Source{});
ASSERT_EQ(result.sem, nullptr);
ASSERT_THAT(Diagnostics().str(), HasSubstr("no matching call"));
}
TEST_F(IntrinsicTableTest, OverloadResolution) {
// i32(abstract-int) produces candidates for both:
// ctor i32(i32) -> i32
// conv i32<T: scalar_no_i32>(T) -> i32
// The first should win overload resolution.
auto* ai = create<sem::AbstractInt>();
auto* i32 = create<sem::I32>();
auto result = table->Lookup(CtorConvIntrinsic::kI32, nullptr, {ai}, Source{});
ASSERT_NE(result.target, nullptr);
EXPECT_EQ(result.target->ReturnType(), i32);
EXPECT_EQ(result.target->Parameters().size(), 1u);
EXPECT_EQ(result.target->Parameters()[0]->Type(), i32);
}
////////////////////////////////////////////////////////////////////////////////
// AbstractBinaryTests
////////////////////////////////////////////////////////////////////////////////
namespace AbstractBinaryTests {
struct Case {
template <typename RESULT,
typename PARAM_LHS,
typename PARAM_RHS,
typename ARG_LHS,
typename ARG_RHS>
static Case Create(bool match = true) {
return {
match, //
builder::DataType<RESULT>::Sem, //
builder::DataType<PARAM_LHS>::Sem, //
builder::DataType<PARAM_RHS>::Sem, //
builder::DataType<ARG_LHS>::Sem, //
builder::DataType<ARG_RHS>::Sem, //
};
}
bool expected_match;
builder::sem_type_func_ptr expected_result;
builder::sem_type_func_ptr expected_param_lhs;
builder::sem_type_func_ptr expected_param_rhs;
builder::sem_type_func_ptr arg_lhs;
builder::sem_type_func_ptr arg_rhs;
};
struct IntrinsicTableAbstractBinaryTest : public ResolverTestWithParam<Case> {
std::unique_ptr<IntrinsicTable> table = IntrinsicTable::Create(*this);
};
TEST_P(IntrinsicTableAbstractBinaryTest, MatchAdd) {
auto* arg_lhs = GetParam().arg_lhs(*this);
auto* arg_rhs = GetParam().arg_rhs(*this);
auto result = table->Lookup(ast::BinaryOp::kAdd, arg_lhs, arg_rhs, Source{{12, 34}},
/* is_compound */ false);
bool matched = result.result != nullptr;
bool expected_match = GetParam().expected_match;
EXPECT_EQ(matched, expected_match) << Diagnostics().str();
auto* expected_result = GetParam().expected_result(*this);
EXPECT_TYPE(result.result, expected_result);
auto* expected_param_lhs = GetParam().expected_param_lhs(*this);
EXPECT_TYPE(result.lhs, expected_param_lhs);
auto* expected_param_rhs = GetParam().expected_param_rhs(*this);
EXPECT_TYPE(result.rhs, expected_param_rhs);
}
INSTANTIATE_TEST_SUITE_P(AFloat_AInt,
IntrinsicTableAbstractBinaryTest,
testing::Values( // clang-format off
// result | param lhs | param rhs | arg lhs | arg rhs
Case::Create<f32, f32, f32, AFloat, AFloat>(),
Case::Create<f32, f32, f32, AFloat, AInt>(),
Case::Create<f32, f32, f32, AInt, AFloat>(),
Case::Create<i32, i32, i32, AInt, AInt>()
)); // clang-format on
INSTANTIATE_TEST_SUITE_P(VecAFloat_VecAInt,
IntrinsicTableAbstractBinaryTest,
testing::Values( // clang-format off
// result | param lhs | param rhs | arg lhs | arg rhs
Case::Create<f32V, f32V, f32V, AFloatV, AFloatV>(),
Case::Create<f32V, f32V, f32V, AFloatV, AIntV>(),
Case::Create<f32V, f32V, f32V, AIntV, AFloatV>(),
Case::Create<i32V, i32V, i32V, AIntV, AIntV>()
)); // clang-format on
INSTANTIATE_TEST_SUITE_P(AFloat_f32,
IntrinsicTableAbstractBinaryTest,
testing::Values( // clang-format off
// result | param lhs | param rhs | arg lhs | arg rhs
Case::Create<f32, f32, f32, AFloat, f32>(),
Case::Create<f32, f32, f32, f32, AFloat>()
)); // clang-format on
INSTANTIATE_TEST_SUITE_P(VecAFloat_Vecf32,
IntrinsicTableAbstractBinaryTest,
testing::Values( // clang-format off
// result | param lhs | param rhs | arg lhs | arg rhs
Case::Create<f32V, f32V, f32V, AFloatV, f32V>(),
Case::Create<f32V, f32V, f32V, f32V, AFloatV>()
)); // clang-format on
INSTANTIATE_TEST_SUITE_P(
AFloat_i32,
IntrinsicTableAbstractBinaryTest,
testing::Values( // clang-format off
// result | param lhs | param rhs | arg lhs | arg rhs
Case::Create<void, void, void, AFloat, i32>(false),
Case::Create<void, void, void, i32, AFloat>(false)
)); // clang-format on
INSTANTIATE_TEST_SUITE_P(
VecAFloat_Veci32,
IntrinsicTableAbstractBinaryTest,
testing::Values( // clang-format off
// result | param lhs | param rhs | arg lhs | arg rhs
Case::Create<void, void, void, AFloatV, i32V>(false),
Case::Create<void, void, void, i32V, AFloatV>(false)
)); // clang-format on
INSTANTIATE_TEST_SUITE_P(
AFloat_u32,
IntrinsicTableAbstractBinaryTest,
testing::Values( // clang-format off
// result | param lhs | param rhs | arg lhs | arg rhs
Case::Create<void, void, void, AFloat, u32>(false),
Case::Create<void, void, void, u32, AFloat>(false)
)); // clang-format on
INSTANTIATE_TEST_SUITE_P(
VecAFloat_Vecu32,
IntrinsicTableAbstractBinaryTest,
testing::Values( // clang-format off
// result | param lhs | param rhs | arg lhs | arg rhs
Case::Create<void, void, void, AFloatV, u32V>(false),
Case::Create<void, void, void, u32V, AFloatV>(false)
)); // clang-format on
INSTANTIATE_TEST_SUITE_P(AInt_f32,
IntrinsicTableAbstractBinaryTest,
testing::Values( // clang-format off
// result | param lhs | param rhs | arg lhs | arg rhs
Case::Create<f32, f32, f32, AInt, f32>(),
Case::Create<f32, f32, f32, f32, AInt>()
)); // clang-format on
INSTANTIATE_TEST_SUITE_P(VecAInt_Vecf32,
IntrinsicTableAbstractBinaryTest,
testing::Values( // clang-format off
// result | param lhs | param rhs | arg lhs | arg rhs
Case::Create<f32V, f32V, f32V, AIntV, f32V>(),
Case::Create<f32V, f32V, f32V, f32V, AIntV>()
)); // clang-format on
INSTANTIATE_TEST_SUITE_P(AInt_i32,
IntrinsicTableAbstractBinaryTest,
testing::Values( // clang-format off
// result | param lhs | param rhs | arg lhs | arg rhs
Case::Create<i32, i32, i32, AInt, i32>(),
Case::Create<i32, i32, i32, i32, AInt>()
)); // clang-format on
INSTANTIATE_TEST_SUITE_P(VecAInt_Veci32,
IntrinsicTableAbstractBinaryTest,
testing::Values( // clang-format off
// result | param lhs | param rhs | arg lhs | arg rhs
Case::Create<i32V, i32V, i32V, AIntV, i32V>(),
Case::Create<i32V, i32V, i32V, i32V, AIntV>()
)); // clang-format on
INSTANTIATE_TEST_SUITE_P(AInt_u32,
IntrinsicTableAbstractBinaryTest,
testing::Values( // clang-format off
// result | param lhs | param rhs | arg lhs | arg rhs
Case::Create<u32, u32, u32, AInt, u32>(),
Case::Create<u32, u32, u32, u32, AInt>()
)); // clang-format on
INSTANTIATE_TEST_SUITE_P(VecAInt_Vecu32,
IntrinsicTableAbstractBinaryTest,
testing::Values( // clang-format off
// result | param lhs | param rhs | arg lhs | arg rhs
Case::Create<u32V, u32V, u32V, AIntV, u32V>(),
Case::Create<u32V, u32V, u32V, u32V, AIntV>()
)); // clang-format on
} // namespace AbstractBinaryTests
////////////////////////////////////////////////////////////////////////////////
// AbstractTernaryTests
////////////////////////////////////////////////////////////////////////////////
namespace AbstractTernaryTests {
struct Case {
template <typename RESULT,
typename PARAM_A,
typename PARAM_B,
typename PARAM_C,
typename ARG_A,
typename ARG_B,
typename ARG_C>
static Case Create(bool match = true) {
return {
match,
builder::DataType<RESULT>::Sem, //
builder::DataType<PARAM_A>::Sem, //
builder::DataType<PARAM_B>::Sem, //
builder::DataType<PARAM_C>::Sem, //
builder::DataType<ARG_A>::Sem, //
builder::DataType<ARG_B>::Sem, //
builder::DataType<ARG_C>::Sem, //
};
}
bool expected_match;
builder::sem_type_func_ptr expected_result;
builder::sem_type_func_ptr expected_param_a;
builder::sem_type_func_ptr expected_param_b;
builder::sem_type_func_ptr expected_param_c;
builder::sem_type_func_ptr arg_a;
builder::sem_type_func_ptr arg_b;
builder::sem_type_func_ptr arg_c;
};
struct IntrinsicTableAbstractTernaryTest : public ResolverTestWithParam<Case> {
std::unique_ptr<IntrinsicTable> table = IntrinsicTable::Create(*this);
};
TEST_P(IntrinsicTableAbstractTernaryTest, MatchClamp) {
auto* arg_a = GetParam().arg_a(*this);
auto* arg_b = GetParam().arg_b(*this);
auto* arg_c = GetParam().arg_c(*this);
auto builtin = table->Lookup(sem::BuiltinType::kClamp, {arg_a, arg_b, arg_c}, Source{{12, 34}});
bool matched = builtin.sem != nullptr;
bool expected_match = GetParam().expected_match;
EXPECT_EQ(matched, expected_match) << Diagnostics().str();
auto* result = builtin.sem ? builtin.sem->ReturnType() : nullptr;
auto* expected_result = GetParam().expected_result(*this);
EXPECT_TYPE(result, expected_result);
auto* param_a = builtin.sem ? builtin.sem->Parameters()[0]->Type() : nullptr;
auto* expected_param_a = GetParam().expected_param_a(*this);
EXPECT_TYPE(param_a, expected_param_a);
auto* param_b = builtin.sem ? builtin.sem->Parameters()[1]->Type() : nullptr;
auto* expected_param_b = GetParam().expected_param_b(*this);
EXPECT_TYPE(param_b, expected_param_b);
auto* param_c = builtin.sem ? builtin.sem->Parameters()[2]->Type() : nullptr;
auto* expected_param_c = GetParam().expected_param_c(*this);
EXPECT_TYPE(param_c, expected_param_c);
}
INSTANTIATE_TEST_SUITE_P(
AFloat_AInt,
IntrinsicTableAbstractTernaryTest,
testing::Values( // clang-format off
// result | param a | param b | param c | arg a | arg b | arg c
Case::Create<f32, f32, f32, f32, AFloat, AFloat, AFloat>(),
Case::Create<f32, f32, f32, f32, AFloat, AFloat, AInt>(),
Case::Create<f32, f32, f32, f32, AFloat, AInt, AFloat>(),
Case::Create<f32, f32, f32, f32, AFloat, AInt, AInt>(),
Case::Create<f32, f32, f32, f32, AInt, AFloat, AFloat>(),
Case::Create<f32, f32, f32, f32, AInt, AFloat, AInt>(),
Case::Create<f32, f32, f32, f32, AInt, AInt, AFloat>(),
Case::Create<i32, i32, i32, i32, AInt, AInt, AInt>()
// clang-format on
));
INSTANTIATE_TEST_SUITE_P(
VecAFloat_VecAInt,
IntrinsicTableAbstractTernaryTest,
testing::Values( // clang-format off
// result | param a | param b | param c | arg a | arg b | arg c
Case::Create<f32V, f32V, f32V, f32V, AFloatV, AFloatV, AFloatV>(),
Case::Create<f32V, f32V, f32V, f32V, AFloatV, AFloatV, AIntV>(),
Case::Create<f32V, f32V, f32V, f32V, AFloatV, AIntV, AFloatV>(),
Case::Create<f32V, f32V, f32V, f32V, AFloatV, AIntV, AIntV>(),
Case::Create<f32V, f32V, f32V, f32V, AIntV, AFloatV, AFloatV>(),
Case::Create<f32V, f32V, f32V, f32V, AIntV, AFloatV, AIntV>(),
Case::Create<f32V, f32V, f32V, f32V, AIntV, AIntV, AFloatV>(),
Case::Create<i32V, i32V, i32V, i32V, AIntV, AIntV, AIntV>()
// clang-format on
));
INSTANTIATE_TEST_SUITE_P(
AFloat_f32,
IntrinsicTableAbstractTernaryTest,
testing::Values( // clang-format off
// result | param a | param b | param c | arg a | arg b | arg c
Case::Create<f32, f32, f32, f32, AFloat, AFloat, f32>(),
Case::Create<f32, f32, f32, f32, AFloat, f32, AFloat>(),
Case::Create<f32, f32, f32, f32, AFloat, f32, f32>(),
Case::Create<f32, f32, f32, f32, f32, AFloat, AFloat>(),
Case::Create<f32, f32, f32, f32, f32, AFloat, f32>(),
Case::Create<f32, f32, f32, f32, f32, f32, AFloat>()
// clang-format on
));
INSTANTIATE_TEST_SUITE_P(
VecAFloat_Vecf32,
IntrinsicTableAbstractTernaryTest,
testing::Values( // clang-format off
// result | param a | param b | param c | arg a | arg b | arg c
Case::Create<f32V, f32V, f32V, f32V, AFloatV, AFloatV, f32V>(),
Case::Create<f32V, f32V, f32V, f32V, AFloatV, f32V, AFloatV>(),
Case::Create<f32V, f32V, f32V, f32V, AFloatV, f32V, f32V>(),
Case::Create<f32V, f32V, f32V, f32V, f32V, AFloatV, AFloatV>(),
Case::Create<f32V, f32V, f32V, f32V, f32V, AFloatV, f32V>(),
Case::Create<f32V, f32V, f32V, f32V, f32V, f32V, AFloatV> ()
// clang-format on
));
INSTANTIATE_TEST_SUITE_P(
AFloat_i32,
IntrinsicTableAbstractTernaryTest,
testing::Values( // clang-format off
// result | param a | param b | param c | arg a | arg b | arg c
Case::Create<void, void, void, void, AFloat, AFloat, i32>(false),
Case::Create<void, void, void, void, AFloat, i32, AFloat>(false),
Case::Create<void, void, void, void, AFloat, i32, i32>(false),
Case::Create<void, void, void, void, i32, AFloat, AFloat>(false),
Case::Create<void, void, void, void, i32, AFloat, i32>(false),
Case::Create<void, void, void, void, i32, i32, AFloat>(false)
// clang-format on
));
INSTANTIATE_TEST_SUITE_P(
VecAFloat_Veci32,
IntrinsicTableAbstractTernaryTest,
testing::Values( // clang-format off
// result | param a | param b | param c | arg a | arg b | arg c
Case::Create<void, void, void, void, AFloatV, AFloatV, i32V>(false),
Case::Create<void, void, void, void, AFloatV, i32V, AFloatV>(false),
Case::Create<void, void, void, void, AFloatV, i32V, i32V>(false),
Case::Create<void, void, void, void, i32V, AFloatV, AFloatV>(false),
Case::Create<void, void, void, void, i32V, AFloatV, i32V>(false),
Case::Create<void, void, void, void, i32V, i32V, AFloatV>(false)
// clang-format on
));
INSTANTIATE_TEST_SUITE_P(
AFloat_u32,
IntrinsicTableAbstractTernaryTest,
testing::Values( // clang-format off
// result | param a | param b | param c | arg a | arg b | arg c
Case::Create<void, void, void, void, AFloat, AFloat, u32>(false),
Case::Create<void, void, void, void, AFloat, u32, AFloat>(false),
Case::Create<void, void, void, void, AFloat, u32, u32>(false),
Case::Create<void, void, void, void, u32, AFloat, AFloat>(false),
Case::Create<void, void, void, void, u32, AFloat, u32>(false),
Case::Create<void, void, void, void, u32, u32, AFloat>(false)
// clang-format on
));
INSTANTIATE_TEST_SUITE_P(
VecAFloat_Vecu32,
IntrinsicTableAbstractTernaryTest,
testing::Values( // clang-format off
// result | param a | param b | param c | arg a | arg b | arg c
Case::Create<void, void, void, void, AFloatV, AFloatV, u32V>(false),
Case::Create<void, void, void, void, AFloatV, u32V, AFloatV>(false),
Case::Create<void, void, void, void, AFloatV, u32V, u32V>(false),
Case::Create<void, void, void, void, u32V, AFloatV, AFloatV>(false),
Case::Create<void, void, void, void, u32V, AFloatV, u32V>(false),
Case::Create<void, void, void, void, u32V, u32V, AFloatV>(false)
// clang-format on
));
INSTANTIATE_TEST_SUITE_P(
AInt_f32,
IntrinsicTableAbstractTernaryTest,
testing::Values( // clang-format off
// result | param a | param b | param c | arg a | arg b | arg c
Case::Create<f32, f32, f32, f32, AInt, AInt, f32>(),
Case::Create<f32, f32, f32, f32, AInt, f32, AInt>(),
Case::Create<f32, f32, f32, f32, AInt, f32, f32>(),
Case::Create<f32, f32, f32, f32, f32, AInt, AInt>(),
Case::Create<f32, f32, f32, f32, f32, AInt, f32>(),
Case::Create<f32, f32, f32, f32, f32, f32, AInt>()
// clang-format on
));
INSTANTIATE_TEST_SUITE_P(
VecAInt_Vecf32,
IntrinsicTableAbstractTernaryTest,
testing::Values( // clang-format off
// result | param a | param b | param c | arg a | arg b | arg c
Case::Create<f32V, f32V, f32V, f32V, AIntV, AIntV, f32V>(),
Case::Create<f32V, f32V, f32V, f32V, AIntV, f32V, AIntV>(),
Case::Create<f32V, f32V, f32V, f32V, AIntV, f32V, f32V>(),
Case::Create<f32V, f32V, f32V, f32V, f32V, AIntV, AIntV>(),
Case::Create<f32V, f32V, f32V, f32V, f32V, AIntV, f32V>(),
Case::Create<f32V, f32V, f32V, f32V, f32V, f32V, AIntV>()
// clang-format on
));
INSTANTIATE_TEST_SUITE_P(
AInt_i32,
IntrinsicTableAbstractTernaryTest,
testing::Values( // clang-format off
// result | param a | param b | param c | arg a | arg b | arg c
Case::Create<i32, i32, i32, i32, AInt, AInt, i32>(),
Case::Create<i32, i32, i32, i32, AInt, i32, AInt>(),
Case::Create<i32, i32, i32, i32, AInt, i32, i32>(),
Case::Create<i32, i32, i32, i32, i32, AInt, AInt>(),
Case::Create<i32, i32, i32, i32, i32, AInt, i32>(),
Case::Create<i32, i32, i32, i32, i32, i32, AInt>()
// clang-format on
));
INSTANTIATE_TEST_SUITE_P(
VecAInt_Veci32,
IntrinsicTableAbstractTernaryTest,
testing::Values( // clang-format off
// result | param a | param b | param c | arg a | arg b | arg c
Case::Create<i32V, i32V, i32V, i32V, AIntV, AIntV, i32V>(),
Case::Create<i32V, i32V, i32V, i32V, AIntV, i32V, AIntV>(),
Case::Create<i32V, i32V, i32V, i32V, AIntV, i32V, i32V>(),
Case::Create<i32V, i32V, i32V, i32V, i32V, AIntV, AIntV>(),
Case::Create<i32V, i32V, i32V, i32V, i32V, AIntV, i32V>(),
Case::Create<i32V, i32V, i32V, i32V, i32V, i32V, AIntV>()
// clang-format on
));
INSTANTIATE_TEST_SUITE_P(
AInt_u32,
IntrinsicTableAbstractTernaryTest,
testing::Values( // clang-format off
// result | param a | param b | param c | arg a | arg b | arg c
Case::Create<u32, u32, u32, u32, AInt, AInt, u32>(),
Case::Create<u32, u32, u32, u32, AInt, u32, AInt>(),
Case::Create<u32, u32, u32, u32, AInt, u32, u32>(),
Case::Create<u32, u32, u32, u32, u32, AInt, AInt>(),
Case::Create<u32, u32, u32, u32, u32, AInt, u32>(),
Case::Create<u32, u32, u32, u32, u32, u32, AInt>()
// clang-format on
));
INSTANTIATE_TEST_SUITE_P(
VecAInt_Vecu32,
IntrinsicTableAbstractTernaryTest,
testing::Values( // clang-format off
// result | param a | param b | param c | arg a | arg b | arg c
Case::Create<u32V, u32V, u32V, u32V, AIntV, AIntV, u32V>(),
Case::Create<u32V, u32V, u32V, u32V, AIntV, u32V, AIntV>(),
Case::Create<u32V, u32V, u32V, u32V, AIntV, u32V, u32V>(),
Case::Create<u32V, u32V, u32V, u32V, u32V, AIntV, AIntV>(),
Case::Create<u32V, u32V, u32V, u32V, u32V, AIntV, u32V>(),
Case::Create<u32V, u32V, u32V, u32V, u32V, u32V, AIntV>()
// clang-format on
));
} // namespace AbstractTernaryTests
} // namespace
} // namespace tint::resolver