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// 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 <cmath>
#include <type_traits>
#include "gtest/gtest.h"
#include "src/tint/resolver/resolver_test_helper.h"
#include "src/tint/sem/builtin_type.h"
#include "src/tint/sem/expression.h"
#include "src/tint/sem/index_accessor_expression.h"
#include "src/tint/sem/member_accessor_expression.h"
#include "src/tint/sem/test_helper.h"
#include "src/tint/utils/transform.h"
using namespace tint::number_suffixes; // NOLINT
namespace tint::resolver {
namespace {
template <typename T>
const auto kPi = T(UnwrapNumber<T>(3.14159265358979323846));
template <typename T>
const auto kPiOver2 = T(UnwrapNumber<T>(1.57079632679489661923));
template <typename T>
const auto kPiOver4 = T(UnwrapNumber<T>(0.785398163397448309616));
template <typename T>
const auto k3PiOver4 = T(UnwrapNumber<T>(2.356194490192344928846));
template <typename T>
constexpr auto Negate(const Number<T>& v) {
if constexpr (std::is_integral_v<T>) {
if constexpr (std::is_signed_v<T>) {
// For signed integrals, avoid C++ UB by not negating the smallest negative number. In
// WGSL, this operation is well defined to return the same value, see:
// https://gpuweb.github.io/gpuweb/wgsl/#arithmetic-expr.
if (v == std::numeric_limits<T>::min()) {
return v;
}
return -v;
} else {
// Allow negating unsigned values
using ST = std::make_signed_t<T>;
auto as_signed = Number<ST>{static_cast<ST>(v)};
return Number<T>{static_cast<T>(Negate(as_signed))};
}
} else {
// float case
return -v;
}
}
template <typename T>
auto Abs(const Number<T>& v) {
if constexpr (std::is_integral_v<T> && std::is_unsigned_v<T>) {
return v;
} else {
return Number<T>(std::abs(v));
}
}
// Concats any number of std::vectors
template <typename Vec, typename... Vecs>
[[nodiscard]] auto Concat(Vec&& v1, Vecs&&... vs) {
auto total_size = v1.size() + (vs.size() + ...);
v1.reserve(total_size);
(std::move(vs.begin(), vs.end(), std::back_inserter(v1)), ...);
return std::move(v1);
}
using ResolverConstEvalTest = ResolverTest;
////////////////////////////////////////////////////////////////////////////////////////////////////
// Construction
////////////////////////////////////////////////////////////////////////////////////////////////////
TEST_F(ResolverConstEvalTest, Scalar_i32) {
auto* expr = Expr(99_i);
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
ASSERT_NE(sem, nullptr);
EXPECT_TRUE(sem->Type()->Is<sem::I32>());
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_TRUE(sem->ConstantValue()->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->AllZero());
EXPECT_EQ(sem->ConstantValue()->As<AInt>(), 99);
}
TEST_F(ResolverConstEvalTest, Scalar_u32) {
auto* expr = Expr(99_u);
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
ASSERT_NE(sem, nullptr);
EXPECT_TRUE(sem->Type()->Is<sem::U32>());
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_TRUE(sem->ConstantValue()->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->AllZero());
EXPECT_EQ(sem->ConstantValue()->As<AInt>(), 99u);
}
TEST_F(ResolverConstEvalTest, Scalar_f32) {
auto* expr = Expr(9.9_f);
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
ASSERT_NE(sem, nullptr);
EXPECT_TRUE(sem->Type()->Is<sem::F32>());
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_TRUE(sem->ConstantValue()->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->AllZero());
EXPECT_EQ(sem->ConstantValue()->As<AFloat>().value, 9.9f);
}
TEST_F(ResolverConstEvalTest, Scalar_f16) {
Enable(ast::Extension::kF16);
auto* expr = Expr(9.9_h);
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
EXPECT_NE(sem, nullptr);
EXPECT_TRUE(sem->Type()->Is<sem::F16>());
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_TRUE(sem->ConstantValue()->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->AllZero());
// 9.9 is not exactly representable by f16, and should be quantized to 9.8984375
EXPECT_EQ(sem->ConstantValue()->As<AFloat>(), 9.8984375f);
}
TEST_F(ResolverConstEvalTest, Scalar_bool) {
auto* expr = Expr(true);
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
ASSERT_NE(sem, nullptr);
EXPECT_TRUE(sem->Type()->Is<sem::Bool>());
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_TRUE(sem->ConstantValue()->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->AllZero());
EXPECT_EQ(sem->ConstantValue()->As<bool>(), true);
}
TEST_F(ResolverConstEvalTest, Vec3_ZeroInit_i32) {
auto* expr = vec3<i32>();
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
ASSERT_NE(sem, nullptr);
auto* vec = sem->Type()->As<sem::Vector>();
ASSERT_NE(vec, nullptr);
EXPECT_TRUE(vec->type()->Is<sem::I32>());
EXPECT_EQ(vec->Width(), 3u);
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_TRUE(sem->ConstantValue()->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(0)->As<AInt>(), 0);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(1)->As<AInt>(), 0);
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(2)->As<AInt>(), 0);
}
TEST_F(ResolverConstEvalTest, Vec3_ZeroInit_u32) {
auto* expr = vec3<u32>();
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
ASSERT_NE(sem, nullptr);
auto* vec = sem->Type()->As<sem::Vector>();
ASSERT_NE(vec, nullptr);
EXPECT_TRUE(vec->type()->Is<sem::U32>());
EXPECT_EQ(vec->Width(), 3u);
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_TRUE(sem->ConstantValue()->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(0)->As<AInt>(), 0u);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(1)->As<AInt>(), 0u);
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(2)->As<AInt>(), 0u);
}
TEST_F(ResolverConstEvalTest, Vec3_ZeroInit_f32) {
auto* expr = vec3<f32>();
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
ASSERT_NE(sem, nullptr);
auto* vec = sem->Type()->As<sem::Vector>();
ASSERT_NE(vec, nullptr);
EXPECT_TRUE(vec->type()->Is<sem::F32>());
EXPECT_EQ(vec->Width(), 3u);
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_TRUE(sem->ConstantValue()->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(0)->As<AFloat>(), 0._a);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(1)->As<AFloat>(), 0._a);
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(2)->As<AFloat>(), 0._a);
}
TEST_F(ResolverConstEvalTest, Vec3_ZeroInit_f16) {
Enable(ast::Extension::kF16);
auto* expr = vec3<f16>();
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
EXPECT_NE(sem, nullptr);
auto* vec = sem->Type()->As<sem::Vector>();
ASSERT_NE(vec, nullptr);
EXPECT_TRUE(vec->type()->Is<sem::F16>());
EXPECT_EQ(vec->Width(), 3u);
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_TRUE(sem->ConstantValue()->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(0)->As<AFloat>(), 0._a);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(1)->As<AFloat>(), 0._a);
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(2)->As<AFloat>(), 0._a);
}
TEST_F(ResolverConstEvalTest, Vec3_ZeroInit_bool) {
auto* expr = vec3<bool>();
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
ASSERT_NE(sem, nullptr);
auto* vec = sem->Type()->As<sem::Vector>();
ASSERT_NE(vec, nullptr);
EXPECT_TRUE(vec->type()->Is<sem::Bool>());
EXPECT_EQ(vec->Width(), 3u);
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_TRUE(sem->ConstantValue()->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(0)->As<bool>(), false);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(1)->As<bool>(), false);
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(2)->As<bool>(), false);
}
TEST_F(ResolverConstEvalTest, Vec3_Splat_i32) {
auto* expr = vec3<i32>(99_i);
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
ASSERT_NE(sem, nullptr);
auto* vec = sem->Type()->As<sem::Vector>();
ASSERT_NE(vec, nullptr);
EXPECT_TRUE(vec->type()->Is<sem::I32>());
EXPECT_EQ(vec->Width(), 3u);
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_TRUE(sem->ConstantValue()->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(0)->As<AInt>(), 99);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(1)->As<AInt>(), 99);
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(2)->As<AInt>(), 99);
}
TEST_F(ResolverConstEvalTest, Vec3_Splat_u32) {
auto* expr = vec3<u32>(99_u);
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
ASSERT_NE(sem, nullptr);
auto* vec = sem->Type()->As<sem::Vector>();
ASSERT_NE(vec, nullptr);
EXPECT_TRUE(vec->type()->Is<sem::U32>());
EXPECT_EQ(vec->Width(), 3u);
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_TRUE(sem->ConstantValue()->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(0)->As<AInt>(), 99u);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(1)->As<AInt>(), 99u);
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(2)->As<AInt>(), 99u);
}
TEST_F(ResolverConstEvalTest, Vec3_Splat_f32) {
auto* expr = vec3<f32>(9.9_f);
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
ASSERT_NE(sem, nullptr);
auto* vec = sem->Type()->As<sem::Vector>();
ASSERT_NE(vec, nullptr);
EXPECT_TRUE(vec->type()->Is<sem::F32>());
EXPECT_EQ(vec->Width(), 3u);
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_TRUE(sem->ConstantValue()->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(0)->As<AFloat>(), 9.9f);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(1)->As<AFloat>(), 9.9f);
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(2)->As<AFloat>(), 9.9f);
}
TEST_F(ResolverConstEvalTest, Vec3_Splat_f16) {
Enable(ast::Extension::kF16);
auto* expr = vec3<f16>(9.9_h);
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
EXPECT_NE(sem, nullptr);
auto* vec = sem->Type()->As<sem::Vector>();
ASSERT_NE(vec, nullptr);
EXPECT_TRUE(vec->type()->Is<sem::F16>());
EXPECT_EQ(vec->Width(), 3u);
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_TRUE(sem->ConstantValue()->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->AllZero());
// 9.9 is not exactly representable by f16, and should be quantized to 9.8984375
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(0)->As<AFloat>(), 9.8984375f);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(1)->As<AFloat>(), 9.8984375f);
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(2)->As<AFloat>(), 9.8984375f);
}
TEST_F(ResolverConstEvalTest, Vec3_Splat_bool) {
auto* expr = vec3<bool>(true);
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
ASSERT_NE(sem, nullptr);
auto* vec = sem->Type()->As<sem::Vector>();
ASSERT_NE(vec, nullptr);
EXPECT_TRUE(vec->type()->Is<sem::Bool>());
EXPECT_EQ(vec->Width(), 3u);
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_TRUE(sem->ConstantValue()->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(0)->As<bool>(), true);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(1)->As<bool>(), true);
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(2)->As<bool>(), true);
}
TEST_F(ResolverConstEvalTest, Vec3_FullConstruct_i32) {
auto* expr = vec3<i32>(1_i, 2_i, 3_i);
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
ASSERT_NE(sem, nullptr);
auto* vec = sem->Type()->As<sem::Vector>();
ASSERT_NE(vec, nullptr);
EXPECT_TRUE(vec->type()->Is<sem::I32>());
EXPECT_EQ(vec->Width(), 3u);
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_FALSE(sem->ConstantValue()->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(0)->As<AInt>(), 1);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(1)->As<AInt>(), 2);
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(2)->As<AInt>(), 3);
}
TEST_F(ResolverConstEvalTest, Vec3_FullConstruct_u32) {
auto* expr = vec3<u32>(1_u, 2_u, 3_u);
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
ASSERT_NE(sem, nullptr);
auto* vec = sem->Type()->As<sem::Vector>();
ASSERT_NE(vec, nullptr);
EXPECT_TRUE(vec->type()->Is<sem::U32>());
EXPECT_EQ(vec->Width(), 3u);
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_FALSE(sem->ConstantValue()->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(0)->As<AInt>(), 1);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(1)->As<AInt>(), 2);
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(2)->As<AInt>(), 3);
}
TEST_F(ResolverConstEvalTest, Vec3_FullConstruct_f32) {
auto* expr = vec3<f32>(1_f, 2_f, 3_f);
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
ASSERT_NE(sem, nullptr);
auto* vec = sem->Type()->As<sem::Vector>();
ASSERT_NE(vec, nullptr);
EXPECT_TRUE(vec->type()->Is<sem::F32>());
EXPECT_EQ(vec->Width(), 3u);
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_FALSE(sem->ConstantValue()->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(0)->As<AFloat>(), 1.f);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(1)->As<AFloat>(), 2.f);
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(2)->As<AFloat>(), 3.f);
}
TEST_F(ResolverConstEvalTest, Vec3_FullConstruct_f16) {
Enable(ast::Extension::kF16);
auto* expr = vec3<f16>(1_h, 2_h, 3_h);
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
EXPECT_NE(sem, nullptr);
auto* vec = sem->Type()->As<sem::Vector>();
ASSERT_NE(vec, nullptr);
EXPECT_TRUE(vec->type()->Is<sem::F16>());
EXPECT_EQ(vec->Width(), 3u);
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_FALSE(sem->ConstantValue()->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(0)->As<AFloat>(), 1.f);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(1)->As<AFloat>(), 2.f);
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(2)->As<AFloat>(), 3.f);
}
TEST_F(ResolverConstEvalTest, Vec3_FullConstruct_bool) {
auto* expr = vec3<bool>(true, false, true);
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
ASSERT_NE(sem, nullptr);
auto* vec = sem->Type()->As<sem::Vector>();
ASSERT_NE(vec, nullptr);
EXPECT_TRUE(vec->type()->Is<sem::Bool>());
EXPECT_EQ(vec->Width(), 3u);
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_FALSE(sem->ConstantValue()->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(0)->As<bool>(), true);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(1)->As<bool>(), false);
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(2)->As<bool>(), true);
}
TEST_F(ResolverConstEvalTest, Vec3_MixConstruct_i32) {
auto* expr = vec3<i32>(1_i, vec2<i32>(2_i, 3_i));
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
ASSERT_NE(sem, nullptr);
auto* vec = sem->Type()->As<sem::Vector>();
ASSERT_NE(vec, nullptr);
EXPECT_TRUE(vec->type()->Is<sem::I32>());
EXPECT_EQ(vec->Width(), 3u);
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_FALSE(sem->ConstantValue()->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(0)->As<AInt>(), 1);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(1)->As<AInt>(), 2);
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(2)->As<AInt>(), 3);
}
TEST_F(ResolverConstEvalTest, Vec3_MixConstruct_u32) {
auto* expr = vec3<u32>(vec2<u32>(1_u, 2_u), 3_u);
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
ASSERT_NE(sem, nullptr);
auto* vec = sem->Type()->As<sem::Vector>();
ASSERT_NE(vec, nullptr);
EXPECT_TRUE(vec->type()->Is<sem::U32>());
EXPECT_EQ(vec->Width(), 3u);
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_FALSE(sem->ConstantValue()->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(0)->As<AInt>(), 1);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(1)->As<AInt>(), 2);
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(2)->As<AInt>(), 3);
}
TEST_F(ResolverConstEvalTest, Vec3_MixConstruct_f32) {
auto* expr = vec3<f32>(1_f, vec2<f32>(2_f, 3_f));
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
ASSERT_NE(sem, nullptr);
auto* vec = sem->Type()->As<sem::Vector>();
ASSERT_NE(vec, nullptr);
EXPECT_TRUE(vec->type()->Is<sem::F32>());
EXPECT_EQ(vec->Width(), 3u);
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_FALSE(sem->ConstantValue()->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(0)->As<AFloat>(), 1.f);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(1)->As<AFloat>(), 2.f);
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(2)->As<AFloat>(), 3.f);
}
TEST_F(ResolverConstEvalTest, Vec3_MixConstruct_f32_all_10) {
auto* expr = vec3<f32>(10_f, vec2<f32>(10_f, 10_f));
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
EXPECT_NE(sem, nullptr);
auto* vec = sem->Type()->As<sem::Vector>();
ASSERT_NE(vec, nullptr);
EXPECT_TRUE(vec->type()->Is<sem::F32>());
EXPECT_EQ(vec->Width(), 3u);
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_TRUE(sem->ConstantValue()->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(0)->As<f32>(), 10_f);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(1)->As<f32>(), 10_f);
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(2)->As<f32>(), 10_f);
}
TEST_F(ResolverConstEvalTest, Vec3_MixConstruct_f32_all_positive_0) {
auto* expr = vec3<f32>(0_f, vec2<f32>(0_f, 0_f));
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
EXPECT_NE(sem, nullptr);
auto* vec = sem->Type()->As<sem::Vector>();
ASSERT_NE(vec, nullptr);
EXPECT_TRUE(vec->type()->Is<sem::F32>());
EXPECT_EQ(vec->Width(), 3u);
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_TRUE(sem->ConstantValue()->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(0)->As<f32>(), 0_f);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(1)->As<f32>(), 0_f);
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(2)->As<f32>(), 0_f);
}
TEST_F(ResolverConstEvalTest, Vec3_MixConstruct_f32_all_negative_0) {
auto* expr = vec3<f32>(vec2<f32>(-0_f, -0_f), -0_f);
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
EXPECT_NE(sem, nullptr);
auto* vec = sem->Type()->As<sem::Vector>();
ASSERT_NE(vec, nullptr);
EXPECT_TRUE(vec->type()->Is<sem::F32>());
EXPECT_EQ(vec->Width(), 3u);
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_TRUE(sem->ConstantValue()->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(0)->As<f32>(), -0_f);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(1)->As<f32>(), -0_f);
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(2)->As<f32>(), -0_f);
}
TEST_F(ResolverConstEvalTest, Vec3_MixConstruct_f32_mixed_sign_0) {
auto* expr = vec3<f32>(0_f, vec2<f32>(-0_f, 0_f));
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
EXPECT_NE(sem, nullptr);
auto* vec = sem->Type()->As<sem::Vector>();
ASSERT_NE(vec, nullptr);
EXPECT_TRUE(vec->type()->Is<sem::F32>());
EXPECT_EQ(vec->Width(), 3u);
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_FALSE(sem->ConstantValue()->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(0)->As<f32>(), 0_f);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(1)->As<f32>(), -0_f);
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(2)->As<f32>(), 0_f);
}
TEST_F(ResolverConstEvalTest, Vec3_MixConstruct_f16) {
Enable(ast::Extension::kF16);
auto* expr = vec3<f16>(1_h, vec2<f16>(2_h, 3_h));
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
EXPECT_NE(sem, nullptr);
auto* vec = sem->Type()->As<sem::Vector>();
ASSERT_NE(vec, nullptr);
EXPECT_TRUE(vec->type()->Is<sem::F16>());
EXPECT_EQ(vec->Width(), 3u);
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_FALSE(sem->ConstantValue()->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(0)->As<AFloat>(), 1.f);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(1)->As<AFloat>(), 2.f);
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(2)->As<AFloat>(), 3.f);
}
TEST_F(ResolverConstEvalTest, Vec3_MixConstruct_f16_all_10) {
Enable(ast::Extension::kF16);
auto* expr = vec3<f16>(10_h, vec2<f16>(10_h, 10_h));
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
EXPECT_NE(sem, nullptr);
auto* vec = sem->Type()->As<sem::Vector>();
ASSERT_NE(vec, nullptr);
EXPECT_TRUE(vec->type()->Is<sem::F16>());
EXPECT_EQ(vec->Width(), 3u);
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_TRUE(sem->ConstantValue()->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(0)->As<f16>(), 10_h);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(1)->As<f16>(), 10_h);
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(2)->As<f16>(), 10_h);
}
TEST_F(ResolverConstEvalTest, Vec3_MixConstruct_f16_all_positive_0) {
Enable(ast::Extension::kF16);
auto* expr = vec3<f16>(0_h, vec2<f16>(0_h, 0_h));
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
EXPECT_NE(sem, nullptr);
auto* vec = sem->Type()->As<sem::Vector>();
ASSERT_NE(vec, nullptr);
EXPECT_TRUE(vec->type()->Is<sem::F16>());
EXPECT_EQ(vec->Width(), 3u);
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_TRUE(sem->ConstantValue()->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(0)->As<f16>(), 0_h);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(1)->As<f16>(), 0_h);
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(2)->As<f16>(), 0_h);
}
TEST_F(ResolverConstEvalTest, Vec3_MixConstruct_f16_all_negative_0) {
Enable(ast::Extension::kF16);
auto* expr = vec3<f16>(vec2<f16>(-0_h, -0_h), -0_h);
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
EXPECT_NE(sem, nullptr);
auto* vec = sem->Type()->As<sem::Vector>();
ASSERT_NE(vec, nullptr);
EXPECT_TRUE(vec->type()->Is<sem::F16>());
EXPECT_EQ(vec->Width(), 3u);
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_TRUE(sem->ConstantValue()->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(0)->As<f16>(), -0_h);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(1)->As<f16>(), -0_h);
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(2)->As<f16>(), -0_h);
}
TEST_F(ResolverConstEvalTest, Vec3_MixConstruct_f16_mixed_sign_0) {
Enable(ast::Extension::kF16);
auto* expr = vec3<f16>(0_h, vec2<f16>(-0_h, 0_h));
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
EXPECT_NE(sem, nullptr);
auto* vec = sem->Type()->As<sem::Vector>();
ASSERT_NE(vec, nullptr);
EXPECT_TRUE(vec->type()->Is<sem::F16>());
EXPECT_EQ(vec->Width(), 3u);
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_FALSE(sem->ConstantValue()->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(0)->As<f16>(), 0_h);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(1)->As<f16>(), -0_h);
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(2)->As<f16>(), 0_h);
}
TEST_F(ResolverConstEvalTest, Vec3_MixConstruct_bool) {
auto* expr = vec3<bool>(vec2<bool>(true, false), true);
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
ASSERT_NE(sem, nullptr);
auto* vec = sem->Type()->As<sem::Vector>();
ASSERT_NE(vec, nullptr);
EXPECT_TRUE(vec->type()->Is<sem::Bool>());
EXPECT_EQ(vec->Width(), 3u);
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_FALSE(sem->ConstantValue()->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(0)->As<bool>(), true);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(1)->As<bool>(), false);
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(2)->As<bool>(), true);
}
TEST_F(ResolverConstEvalTest, Vec3_MixConstruct_all_true) {
auto* expr = vec3<bool>(true, vec2<bool>(true, true));
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
ASSERT_NE(sem, nullptr);
auto* vec = sem->Type()->As<sem::Vector>();
ASSERT_NE(vec, nullptr);
EXPECT_TRUE(vec->type()->Is<sem::Bool>());
EXPECT_EQ(vec->Width(), 3u);
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_TRUE(sem->ConstantValue()->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(0)->As<bool>(), true);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(1)->As<bool>(), true);
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(2)->As<bool>(), true);
}
TEST_F(ResolverConstEvalTest, Vec3_MixConstruct_all_false) {
auto* expr = vec3<bool>(false, vec2<bool>(false, false));
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
ASSERT_NE(sem, nullptr);
auto* vec = sem->Type()->As<sem::Vector>();
ASSERT_NE(vec, nullptr);
EXPECT_TRUE(vec->type()->Is<sem::Bool>());
EXPECT_EQ(vec->Width(), 3u);
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_TRUE(sem->ConstantValue()->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(0)->As<bool>(), false);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(1)->As<bool>(), false);
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(2)->As<bool>(), false);
}
TEST_F(ResolverConstEvalTest, Vec3_Convert_f32_to_i32) {
auto* expr = vec3<i32>(vec3<f32>(1.1_f, 2.2_f, 3.3_f));
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
ASSERT_NE(sem, nullptr);
auto* vec = sem->Type()->As<sem::Vector>();
ASSERT_NE(vec, nullptr);
EXPECT_TRUE(vec->type()->Is<sem::I32>());
EXPECT_EQ(vec->Width(), 3u);
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_FALSE(sem->ConstantValue()->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(0)->As<AInt>(), 1);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(1)->As<AInt>(), 2);
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(2)->As<AInt>(), 3);
}
TEST_F(ResolverConstEvalTest, Vec3_Convert_u32_to_f32) {
auto* expr = vec3<f32>(vec3<u32>(10_u, 20_u, 30_u));
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
ASSERT_NE(sem, nullptr);
auto* vec = sem->Type()->As<sem::Vector>();
ASSERT_NE(vec, nullptr);
EXPECT_TRUE(vec->type()->Is<sem::F32>());
EXPECT_EQ(vec->Width(), 3u);
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_FALSE(sem->ConstantValue()->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(0)->As<AFloat>(), 10.f);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(1)->As<AFloat>(), 20.f);
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(2)->As<AFloat>(), 30.f);
}
TEST_F(ResolverConstEvalTest, Vec3_Convert_f16_to_i32) {
Enable(ast::Extension::kF16);
auto* expr = vec3<i32>(vec3<f16>(1.1_h, 2.2_h, 3.3_h));
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
EXPECT_NE(sem, nullptr);
auto* vec = sem->Type()->As<sem::Vector>();
ASSERT_NE(vec, nullptr);
EXPECT_TRUE(vec->type()->Is<sem::I32>());
EXPECT_EQ(vec->Width(), 3u);
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_FALSE(sem->ConstantValue()->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(0)->As<AInt>(), 1_i);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(1)->As<AInt>(), 2_i);
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(2)->As<AInt>(), 3_i);
}
TEST_F(ResolverConstEvalTest, Vec3_Convert_u32_to_f16) {
Enable(ast::Extension::kF16);
auto* expr = vec3<f16>(vec3<u32>(10_u, 20_u, 30_u));
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
EXPECT_NE(sem, nullptr);
auto* vec = sem->Type()->As<sem::Vector>();
ASSERT_NE(vec, nullptr);
EXPECT_TRUE(vec->type()->Is<sem::F16>());
EXPECT_EQ(vec->Width(), 3u);
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_FALSE(sem->ConstantValue()->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(0)->As<AFloat>(), 10.f);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(1)->As<AFloat>(), 20.f);
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(2)->As<AFloat>(), 30.f);
}
TEST_F(ResolverConstEvalTest, Vec3_Convert_Large_f32_to_i32) {
auto* expr = vec3<i32>(vec3<f32>(1e10_f, -1e20_f, 1e30_f));
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
ASSERT_NE(sem, nullptr);
auto* vec = sem->Type()->As<sem::Vector>();
ASSERT_NE(vec, nullptr);
EXPECT_TRUE(vec->type()->Is<sem::I32>());
EXPECT_EQ(vec->Width(), 3u);
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_FALSE(sem->ConstantValue()->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(0)->As<AInt>(), i32::Highest());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(1)->As<AInt>(), i32::Lowest());
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(2)->As<AInt>(), i32::Highest());
}
TEST_F(ResolverConstEvalTest, Vec3_Convert_Large_f32_to_u32) {
auto* expr = vec3<u32>(vec3<f32>(1e10_f, -1e20_f, 1e30_f));
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
ASSERT_NE(sem, nullptr);
auto* vec = sem->Type()->As<sem::Vector>();
ASSERT_NE(vec, nullptr);
EXPECT_TRUE(vec->type()->Is<sem::U32>());
EXPECT_EQ(vec->Width(), 3u);
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_FALSE(sem->ConstantValue()->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(0)->As<AInt>(), u32::Highest());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(1)->As<AInt>(), u32::Lowest());
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(2)->As<AInt>(), u32::Highest());
}
TEST_F(ResolverConstEvalTest, Vec3_Convert_Large_f32_to_f16) {
Enable(ast::Extension::kF16);
auto* expr = vec3<f16>(vec3<f32>(1e10_f, -1e20_f, 1e30_f));
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
constexpr auto kInfinity = std::numeric_limits<double>::infinity();
auto* sem = Sem().Get(expr);
ASSERT_NE(sem, nullptr);
auto* vec = sem->Type()->As<sem::Vector>();
ASSERT_NE(vec, nullptr);
EXPECT_TRUE(vec->type()->Is<sem::F16>());
EXPECT_EQ(vec->Width(), 3u);
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_FALSE(sem->ConstantValue()->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(0)->As<AFloat>(), kInfinity);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(1)->As<AFloat>(), -kInfinity);
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(2)->As<AFloat>(), kInfinity);
}
TEST_F(ResolverConstEvalTest, Vec3_Convert_Small_f32_to_f16) {
Enable(ast::Extension::kF16);
auto* expr = vec3<f16>(vec3<f32>(1e-20_f, -2e-30_f, 3e-40_f));
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
ASSERT_NE(sem, nullptr);
auto* vec = sem->Type()->As<sem::Vector>();
ASSERT_NE(vec, nullptr);
EXPECT_TRUE(vec->type()->Is<sem::F16>());
EXPECT_EQ(vec->Width(), 3u);
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_FALSE(sem->ConstantValue()->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(0)->As<AFloat>(), 0.0);
EXPECT_FALSE(std::signbit(sem->ConstantValue()->Index(0)->As<AFloat>().value));
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(1)->As<AFloat>(), -0.0);
EXPECT_TRUE(std::signbit(sem->ConstantValue()->Index(1)->As<AFloat>().value));
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(2)->As<AFloat>(), 0.0);
EXPECT_FALSE(std::signbit(sem->ConstantValue()->Index(2)->As<AFloat>().value));
}
TEST_F(ResolverConstEvalTest, Mat2x3_ZeroInit_f32) {
auto* expr = mat2x3<f32>();
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
ASSERT_NE(sem, nullptr);
auto* mat = sem->Type()->As<sem::Matrix>();
ASSERT_NE(mat, nullptr);
EXPECT_TRUE(mat->type()->Is<sem::F32>());
EXPECT_EQ(mat->columns(), 2u);
EXPECT_EQ(mat->rows(), 3u);
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_TRUE(sem->ConstantValue()->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->Index(0)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->Index(0)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->Index(0)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(0)->Index(0)->As<f32>(), 0._f);
EXPECT_TRUE(sem->ConstantValue()->Index(0)->Index(1)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->Index(1)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->Index(1)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(0)->Index(1)->As<f32>(), 0._f);
EXPECT_TRUE(sem->ConstantValue()->Index(0)->Index(2)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->Index(2)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->Index(2)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(0)->Index(2)->As<f32>(), 0._f);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->Index(0)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->Index(0)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->Index(0)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(1)->Index(0)->As<f32>(), 0._f);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->Index(1)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->Index(1)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->Index(1)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(1)->Index(1)->As<f32>(), 0._f);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->Index(2)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->Index(2)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->Index(2)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(1)->Index(2)->As<f32>(), 0._f);
}
TEST_F(ResolverConstEvalTest, Mat2x3_ZeroInit_f16) {
Enable(ast::Extension::kF16);
auto* expr = mat2x3<f16>();
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
EXPECT_NE(sem, nullptr);
auto* mat = sem->Type()->As<sem::Matrix>();
ASSERT_NE(mat, nullptr);
EXPECT_TRUE(mat->type()->Is<sem::F16>());
EXPECT_EQ(mat->columns(), 2u);
EXPECT_EQ(mat->rows(), 3u);
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_TRUE(sem->ConstantValue()->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->Index(0)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->Index(0)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->Index(0)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(0)->Index(0)->As<f16>(), 0._h);
EXPECT_TRUE(sem->ConstantValue()->Index(0)->Index(1)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->Index(1)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->Index(1)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(0)->Index(1)->As<f16>(), 0._h);
EXPECT_TRUE(sem->ConstantValue()->Index(0)->Index(2)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->Index(2)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->Index(2)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(0)->Index(2)->As<f16>(), 0._h);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->Index(0)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->Index(0)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->Index(0)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(1)->Index(0)->As<f16>(), 0._h);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->Index(1)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->Index(1)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->Index(1)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(1)->Index(1)->As<f16>(), 0._h);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->Index(2)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->Index(2)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->Index(2)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(1)->Index(2)->As<f16>(), 0._h);
}
TEST_F(ResolverConstEvalTest, Mat3x2_Construct_Scalars_af) {
auto* expr = Construct(ty.mat(nullptr, 3, 2), 1.0_a, 2.0_a, 3.0_a, 4.0_a, 5.0_a, 6.0_a);
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
ASSERT_NE(sem, nullptr);
auto* mat = sem->Type()->As<sem::Matrix>();
ASSERT_NE(mat, nullptr);
EXPECT_TRUE(mat->type()->Is<sem::F32>());
EXPECT_EQ(mat->columns(), 3u);
EXPECT_EQ(mat->rows(), 2u);
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_FALSE(sem->ConstantValue()->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->Index(0)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->Index(0)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->Index(0)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(0)->Index(0)->As<AFloat>(), 1._a);
EXPECT_TRUE(sem->ConstantValue()->Index(0)->Index(1)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->Index(1)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->Index(1)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(0)->Index(1)->As<AFloat>(), 2._a);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->Index(0)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->Index(0)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->Index(0)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(1)->Index(0)->As<AFloat>(), 3._a);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->Index(1)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->Index(1)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->Index(1)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(1)->Index(1)->As<AFloat>(), 4._a);
EXPECT_TRUE(sem->ConstantValue()->Index(2)->Index(0)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->Index(0)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->Index(0)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(2)->Index(0)->As<AFloat>(), 5._a);
EXPECT_TRUE(sem->ConstantValue()->Index(2)->Index(1)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->Index(1)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->Index(1)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(2)->Index(1)->As<AFloat>(), 6._a);
}
TEST_F(ResolverConstEvalTest, Mat3x2_Construct_Columns_af) {
auto* expr = Construct(ty.mat(nullptr, 3, 2), //
vec(nullptr, 2u, 1.0_a, 2.0_a), //
vec(nullptr, 2u, 3.0_a, 4.0_a), //
vec(nullptr, 2u, 5.0_a, 6.0_a));
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
ASSERT_NE(sem, nullptr);
auto* mat = sem->Type()->As<sem::Matrix>();
ASSERT_NE(mat, nullptr);
EXPECT_TRUE(mat->type()->Is<sem::F32>());
EXPECT_EQ(mat->columns(), 3u);
EXPECT_EQ(mat->rows(), 2u);
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_FALSE(sem->ConstantValue()->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->Index(0)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->Index(0)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->Index(0)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(0)->Index(0)->As<AFloat>(), 1._a);
EXPECT_TRUE(sem->ConstantValue()->Index(0)->Index(1)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->Index(1)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->Index(1)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(0)->Index(1)->As<AFloat>(), 2._a);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->Index(0)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->Index(0)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->Index(0)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(1)->Index(0)->As<AFloat>(), 3._a);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->Index(1)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->Index(1)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->Index(1)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(1)->Index(1)->As<AFloat>(), 4._a);
EXPECT_TRUE(sem->ConstantValue()->Index(2)->Index(0)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->Index(0)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->Index(0)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(2)->Index(0)->As<AFloat>(), 5._a);
EXPECT_TRUE(sem->ConstantValue()->Index(2)->Index(1)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->Index(1)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->Index(1)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(2)->Index(1)->As<AFloat>(), 6._a);
}
TEST_F(ResolverConstEvalTest, Array_i32_Zero) {
auto* expr = Construct(ty.array<i32, 4>());
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
ASSERT_NE(sem, nullptr);
auto* arr = sem->Type()->As<sem::Array>();
ASSERT_NE(arr, nullptr);
EXPECT_TRUE(arr->ElemType()->Is<sem::I32>());
EXPECT_EQ(arr->Count(), 4u);
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_TRUE(sem->ConstantValue()->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(0)->As<i32>(), 0_i);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(1)->As<i32>(), 0_i);
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(2)->As<i32>(), 0_i);
EXPECT_TRUE(sem->ConstantValue()->Index(3)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(3)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(3)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(3)->As<i32>(), 0_i);
}
TEST_F(ResolverConstEvalTest, Array_f32_Zero) {
auto* expr = Construct(ty.array<f32, 4>());
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
ASSERT_NE(sem, nullptr);
auto* arr = sem->Type()->As<sem::Array>();
ASSERT_NE(arr, nullptr);
EXPECT_TRUE(arr->ElemType()->Is<sem::F32>());
EXPECT_EQ(arr->Count(), 4u);
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_TRUE(sem->ConstantValue()->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(0)->As<f32>(), 0_f);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(1)->As<f32>(), 0_f);
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(2)->As<f32>(), 0_f);
EXPECT_TRUE(sem->ConstantValue()->Index(3)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(3)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(3)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(3)->As<f32>(), 0_f);
}
TEST_F(ResolverConstEvalTest, Array_vec3_f32_Zero) {
auto* expr = Construct(ty.array(ty.vec3<f32>(), 2_u));
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
ASSERT_NE(sem, nullptr);
auto* arr = sem->Type()->As<sem::Array>();
ASSERT_NE(arr, nullptr);
EXPECT_TRUE(arr->ElemType()->Is<sem::Vector>());
EXPECT_EQ(arr->Count(), 2u);
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_TRUE(sem->ConstantValue()->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->Index(0)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->Index(0)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->Index(0)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(0)->Index(0)->As<f32>(), 0_f);
EXPECT_TRUE(sem->ConstantValue()->Index(0)->Index(1)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->Index(1)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->Index(1)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(0)->Index(1)->As<f32>(), 0_f);
EXPECT_TRUE(sem->ConstantValue()->Index(0)->Index(2)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->Index(2)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->Index(2)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(0)->Index(2)->As<f32>(), 0_f);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->Index(0)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->Index(0)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->Index(0)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(1)->Index(0)->As<f32>(), 0_f);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->Index(1)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->Index(1)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->Index(1)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(1)->Index(1)->As<f32>(), 0_f);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->Index(2)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->Index(2)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->Index(2)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(1)->Index(2)->As<f32>(), 0_f);
}
TEST_F(ResolverConstEvalTest, Array_Struct_f32_Zero) {
Structure("S", utils::Vector{
Member("m1", ty.f32()),
Member("m2", ty.f32()),
});
auto* expr = Construct(ty.array(ty.type_name("S"), 2_u));
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
ASSERT_NE(sem, nullptr);
auto* arr = sem->Type()->As<sem::Array>();
ASSERT_NE(arr, nullptr);
EXPECT_TRUE(arr->ElemType()->Is<sem::Struct>());
EXPECT_EQ(arr->Count(), 2u);
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_TRUE(sem->ConstantValue()->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->Index(0)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->Index(0)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->Index(0)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(0)->Index(0)->As<f32>(), 0_f);
EXPECT_TRUE(sem->ConstantValue()->Index(0)->Index(1)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->Index(1)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->Index(1)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(0)->Index(1)->As<f32>(), 0_f);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->Index(0)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->Index(0)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->Index(0)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(1)->Index(0)->As<f32>(), 0_f);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->Index(1)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->Index(1)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->Index(1)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(1)->Index(1)->As<f32>(), 0_f);
}
TEST_F(ResolverConstEvalTest, Array_i32_Elements) {
auto* expr = Construct(ty.array<i32, 4>(), 10_i, 20_i, 30_i, 40_i);
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
ASSERT_NE(sem, nullptr);
auto* arr = sem->Type()->As<sem::Array>();
ASSERT_NE(arr, nullptr);
EXPECT_TRUE(arr->ElemType()->Is<sem::I32>());
EXPECT_EQ(arr->Count(), 4u);
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_FALSE(sem->ConstantValue()->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(0)->As<i32>(), 10_i);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(1)->As<i32>(), 20_i);
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(2)->As<i32>(), 30_i);
EXPECT_TRUE(sem->ConstantValue()->Index(3)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(3)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(3)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(3)->As<i32>(), 40_i);
}
TEST_F(ResolverConstEvalTest, Array_f32_Elements) {
auto* expr = Construct(ty.array<f32, 4>(), 10_f, 20_f, 30_f, 40_f);
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
ASSERT_NE(sem, nullptr);
auto* arr = sem->Type()->As<sem::Array>();
ASSERT_NE(arr, nullptr);
EXPECT_TRUE(arr->ElemType()->Is<sem::F32>());
EXPECT_EQ(arr->Count(), 4u);
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_FALSE(sem->ConstantValue()->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(0)->As<f32>(), 10_f);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(1)->As<f32>(), 20_f);
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(2)->As<f32>(), 30_f);
EXPECT_TRUE(sem->ConstantValue()->Index(3)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(3)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(3)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(3)->As<f32>(), 40_f);
}
TEST_F(ResolverConstEvalTest, Array_vec3_f32_Elements) {
auto* expr = Construct(ty.array(ty.vec3<f32>(), 2_u), //
vec3<f32>(1_f, 2_f, 3_f), vec3<f32>(4_f, 5_f, 6_f));
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
ASSERT_NE(sem, nullptr);
auto* arr = sem->Type()->As<sem::Array>();
ASSERT_NE(arr, nullptr);
EXPECT_TRUE(arr->ElemType()->Is<sem::Vector>());
EXPECT_EQ(arr->Count(), 2u);
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_FALSE(sem->ConstantValue()->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(0)->Index(0)->As<f32>(), 1_f);
EXPECT_EQ(sem->ConstantValue()->Index(0)->Index(1)->As<f32>(), 2_f);
EXPECT_EQ(sem->ConstantValue()->Index(0)->Index(2)->As<f32>(), 3_f);
EXPECT_EQ(sem->ConstantValue()->Index(1)->Index(0)->As<f32>(), 4_f);
EXPECT_EQ(sem->ConstantValue()->Index(1)->Index(1)->As<f32>(), 5_f);
EXPECT_EQ(sem->ConstantValue()->Index(1)->Index(2)->As<f32>(), 6_f);
}
TEST_F(ResolverConstEvalTest, Array_Struct_f32_Elements) {
Structure("S", utils::Vector{
Member("m1", ty.f32()),
Member("m2", ty.f32()),
});
auto* expr = Construct(ty.array(ty.type_name("S"), 2_u), //
Construct(ty.type_name("S"), 1_f, 2_f), //
Construct(ty.type_name("S"), 3_f, 4_f));
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
ASSERT_NE(sem, nullptr);
auto* arr = sem->Type()->As<sem::Array>();
ASSERT_NE(arr, nullptr);
EXPECT_TRUE(arr->ElemType()->Is<sem::Struct>());
EXPECT_EQ(arr->Count(), 2u);
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_FALSE(sem->ConstantValue()->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->Index(0)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->Index(0)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->Index(0)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(0)->Index(0)->As<f32>(), 1_f);
EXPECT_TRUE(sem->ConstantValue()->Index(0)->Index(1)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->Index(1)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->Index(1)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(0)->Index(1)->As<f32>(), 2_f);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->Index(0)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->Index(0)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->Index(0)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(1)->Index(0)->As<f32>(), 3_f);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->Index(1)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->Index(1)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->Index(1)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(1)->Index(1)->As<f32>(), 4_f);
}
TEST_F(ResolverConstEvalTest, Struct_I32s_ZeroInit) {
Structure(
"S", utils::Vector{Member("m1", ty.i32()), Member("m2", ty.i32()), Member("m3", ty.i32())});
auto* expr = Construct(ty.type_name("S"));
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
ASSERT_NE(sem, nullptr);
auto* str = sem->Type()->As<sem::Struct>();
ASSERT_NE(str, nullptr);
EXPECT_EQ(str->Members().size(), 3u);
ASSERT_NE(sem->ConstantValue(), nullptr);
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_TRUE(sem->ConstantValue()->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->Type()->Is<sem::I32>());
EXPECT_EQ(sem->ConstantValue()->Index(0)->As<i32>(), 0_i);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->Type()->Is<sem::I32>());
EXPECT_EQ(sem->ConstantValue()->Index(1)->As<i32>(), 0_i);
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(2)->Type()->Is<sem::I32>());
EXPECT_EQ(sem->ConstantValue()->Index(2)->As<i32>(), 0_i);
}
TEST_F(ResolverConstEvalTest, Struct_MixedScalars_ZeroInit) {
Enable(ast::Extension::kF16);
Structure("S", utils::Vector{
Member("m1", ty.i32()),
Member("m2", ty.u32()),
Member("m3", ty.f32()),
Member("m4", ty.f16()),
Member("m5", ty.bool_()),
});
auto* expr = Construct(ty.type_name("S"));
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
ASSERT_NE(sem, nullptr);
auto* str = sem->Type()->As<sem::Struct>();
ASSERT_NE(str, nullptr);
EXPECT_EQ(str->Members().size(), 5u);
ASSERT_NE(sem->ConstantValue(), nullptr);
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_FALSE(sem->ConstantValue()->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->Type()->Is<sem::I32>());
EXPECT_EQ(sem->ConstantValue()->Index(0)->As<i32>(), 0_i);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->Type()->Is<sem::U32>());
EXPECT_EQ(sem->ConstantValue()->Index(1)->As<u32>(), 0_u);
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(2)->Type()->Is<sem::F32>());
EXPECT_EQ(sem->ConstantValue()->Index(2)->As<f32>(), 0._f);
EXPECT_TRUE(sem->ConstantValue()->Index(3)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(3)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(3)->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(3)->Type()->Is<sem::F16>());
EXPECT_EQ(sem->ConstantValue()->Index(3)->As<f16>(), 0._h);
EXPECT_TRUE(sem->ConstantValue()->Index(4)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(4)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(4)->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(4)->Type()->Is<sem::Bool>());
EXPECT_EQ(sem->ConstantValue()->Index(4)->As<bool>(), false);
}
TEST_F(ResolverConstEvalTest, Struct_VectorF32s_ZeroInit) {
Structure("S", utils::Vector{
Member("m1", ty.vec3<f32>()),
Member("m2", ty.vec3<f32>()),
Member("m3", ty.vec3<f32>()),
});
auto* expr = Construct(ty.type_name("S"));
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
ASSERT_NE(sem, nullptr);
auto* str = sem->Type()->As<sem::Struct>();
ASSERT_NE(str, nullptr);
EXPECT_EQ(str->Members().size(), 3u);
ASSERT_NE(sem->ConstantValue(), nullptr);
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_TRUE(sem->ConstantValue()->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->Type()->Is<sem::Vector>());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->Type()->As<sem::Vector>()->type()->Is<sem::F32>());
EXPECT_EQ(sem->ConstantValue()->Index(0)->Index(0)->As<f32>(), 0._f);
EXPECT_EQ(sem->ConstantValue()->Index(0)->Index(1)->As<f32>(), 0._f);
EXPECT_EQ(sem->ConstantValue()->Index(0)->Index(2)->As<f32>(), 0._f);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->Type()->Is<sem::Vector>());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->Type()->As<sem::Vector>()->type()->Is<sem::F32>());
EXPECT_EQ(sem->ConstantValue()->Index(1)->Index(0)->As<f32>(), 0._f);
EXPECT_EQ(sem->ConstantValue()->Index(1)->Index(1)->As<f32>(), 0._f);
EXPECT_EQ(sem->ConstantValue()->Index(1)->Index(2)->As<f32>(), 0._f);
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(2)->Type()->Is<sem::Vector>());
EXPECT_TRUE(sem->ConstantValue()->Index(2)->Type()->As<sem::Vector>()->type()->Is<sem::F32>());
EXPECT_EQ(sem->ConstantValue()->Index(2)->Index(0)->As<f32>(), 0._f);
EXPECT_EQ(sem->ConstantValue()->Index(2)->Index(1)->As<f32>(), 0._f);
EXPECT_EQ(sem->ConstantValue()->Index(2)->Index(2)->As<f32>(), 0._f);
}
TEST_F(ResolverConstEvalTest, Struct_MixedVectors_ZeroInit) {
Enable(ast::Extension::kF16);
Structure("S", utils::Vector{
Member("m1", ty.vec2<i32>()),
Member("m2", ty.vec3<u32>()),
Member("m3", ty.vec4<f32>()),
Member("m4", ty.vec3<f16>()),
Member("m5", ty.vec2<bool>()),
});
auto* expr = Construct(ty.type_name("S"));
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
ASSERT_NE(sem, nullptr);
auto* str = sem->Type()->As<sem::Struct>();
ASSERT_NE(str, nullptr);
EXPECT_EQ(str->Members().size(), 5u);
ASSERT_NE(sem->ConstantValue(), nullptr);
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_FALSE(sem->ConstantValue()->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->Type()->Is<sem::Vector>());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->Type()->As<sem::Vector>()->type()->Is<sem::I32>());
EXPECT_EQ(sem->ConstantValue()->Index(0)->Index(0)->As<i32>(), 0_i);
EXPECT_EQ(sem->ConstantValue()->Index(0)->Index(1)->As<i32>(), 0_i);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->Type()->Is<sem::Vector>());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->Type()->As<sem::Vector>()->type()->Is<sem::U32>());
EXPECT_EQ(sem->ConstantValue()->Index(1)->Index(0)->As<u32>(), 0_u);
EXPECT_EQ(sem->ConstantValue()->Index(1)->Index(1)->As<u32>(), 0_u);
EXPECT_EQ(sem->ConstantValue()->Index(1)->Index(2)->As<u32>(), 0_u);
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(2)->Type()->Is<sem::Vector>());
EXPECT_TRUE(sem->ConstantValue()->Index(2)->Type()->As<sem::Vector>()->type()->Is<sem::F32>());
EXPECT_EQ(sem->ConstantValue()->Index(2)->Index(0)->As<f32>(), 0._f);
EXPECT_EQ(sem->ConstantValue()->Index(2)->Index(1)->As<f32>(), 0._f);
EXPECT_EQ(sem->ConstantValue()->Index(2)->Index(2)->As<f32>(), 0._f);
EXPECT_EQ(sem->ConstantValue()->Index(2)->Index(3)->As<f32>(), 0._f);
EXPECT_TRUE(sem->ConstantValue()->Index(3)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(3)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(3)->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(3)->Type()->Is<sem::Vector>());
EXPECT_TRUE(sem->ConstantValue()->Index(3)->Type()->As<sem::Vector>()->type()->Is<sem::F16>());
EXPECT_EQ(sem->ConstantValue()->Index(3)->Index(0)->As<f16>(), 0._h);
EXPECT_EQ(sem->ConstantValue()->Index(3)->Index(1)->As<f16>(), 0._h);
EXPECT_EQ(sem->ConstantValue()->Index(3)->Index(2)->As<f16>(), 0._h);
EXPECT_TRUE(sem->ConstantValue()->Index(4)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(4)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(4)->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(4)->Type()->Is<sem::Vector>());
EXPECT_TRUE(sem->ConstantValue()->Index(4)->Type()->As<sem::Vector>()->type()->Is<sem::Bool>());
EXPECT_EQ(sem->ConstantValue()->Index(4)->Index(0)->As<bool>(), false);
EXPECT_EQ(sem->ConstantValue()->Index(4)->Index(1)->As<bool>(), false);
}
TEST_F(ResolverConstEvalTest, Struct_Struct_ZeroInit) {
Structure("Inner", utils::Vector{
Member("m1", ty.i32()),
Member("m2", ty.u32()),
Member("m3", ty.f32()),
});
Structure("Outer", utils::Vector{
Member("m1", ty.type_name("Inner")),
Member("m2", ty.type_name("Inner")),
});
auto* expr = Construct(ty.type_name("Outer"));
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
ASSERT_NE(sem, nullptr);
auto* str = sem->Type()->As<sem::Struct>();
ASSERT_NE(str, nullptr);
EXPECT_EQ(str->Members().size(), 2u);
ASSERT_NE(sem->ConstantValue(), nullptr);
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_TRUE(sem->ConstantValue()->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->AllZero());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->Type()->Is<sem::Struct>());
EXPECT_EQ(sem->ConstantValue()->Index(0)->Index(0)->As<i32>(), 0_i);
EXPECT_EQ(sem->ConstantValue()->Index(0)->Index(1)->As<u32>(), 0_u);
EXPECT_EQ(sem->ConstantValue()->Index(0)->Index(2)->As<f32>(), 0_f);
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->Type()->Is<sem::Struct>());
EXPECT_EQ(sem->ConstantValue()->Index(1)->Index(0)->As<i32>(), 0_i);
EXPECT_EQ(sem->ConstantValue()->Index(1)->Index(1)->As<u32>(), 0_u);
EXPECT_EQ(sem->ConstantValue()->Index(1)->Index(2)->As<f32>(), 0_f);
}
TEST_F(ResolverConstEvalTest, Struct_MixedScalars_Construct) {
Enable(ast::Extension::kF16);
Structure("S", utils::Vector{
Member("m1", ty.i32()),
Member("m2", ty.u32()),
Member("m3", ty.f32()),
Member("m4", ty.f16()),
Member("m5", ty.bool_()),
});
auto* expr = Construct(ty.type_name("S"), 1_i, 2_u, 3_f, 4_h, false);
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
ASSERT_NE(sem, nullptr);
auto* str = sem->Type()->As<sem::Struct>();
ASSERT_NE(str, nullptr);
EXPECT_EQ(str->Members().size(), 5u);
ASSERT_NE(sem->ConstantValue(), nullptr);
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_FALSE(sem->ConstantValue()->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->Type()->Is<sem::I32>());
EXPECT_EQ(sem->ConstantValue()->Index(0)->As<i32>(), 1_i);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->Type()->Is<sem::U32>());
EXPECT_EQ(sem->ConstantValue()->Index(1)->As<u32>(), 2_u);
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(2)->Type()->Is<sem::F32>());
EXPECT_EQ(sem->ConstantValue()->Index(2)->As<f32>(), 3._f);
EXPECT_TRUE(sem->ConstantValue()->Index(3)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(3)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(3)->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(3)->Type()->Is<sem::F16>());
EXPECT_EQ(sem->ConstantValue()->Index(3)->As<f16>(), 4._h);
EXPECT_TRUE(sem->ConstantValue()->Index(4)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(4)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(4)->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(4)->Type()->Is<sem::Bool>());
EXPECT_EQ(sem->ConstantValue()->Index(4)->As<bool>(), false);
}
TEST_F(ResolverConstEvalTest, Struct_MixedVectors_Construct) {
Enable(ast::Extension::kF16);
Structure("S", utils::Vector{
Member("m1", ty.vec2<i32>()),
Member("m2", ty.vec3<u32>()),
Member("m3", ty.vec4<f32>()),
Member("m4", ty.vec3<f16>()),
Member("m5", ty.vec2<bool>()),
});
auto* expr = Construct(ty.type_name("S"), vec2<i32>(1_i), vec3<u32>(2_u), vec4<f32>(3_f),
vec3<f16>(4_h), vec2<bool>(false));
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
ASSERT_NE(sem, nullptr);
auto* str = sem->Type()->As<sem::Struct>();
ASSERT_NE(str, nullptr);
EXPECT_EQ(str->Members().size(), 5u);
ASSERT_NE(sem->ConstantValue(), nullptr);
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_FALSE(sem->ConstantValue()->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->Type()->Is<sem::Vector>());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->Type()->As<sem::Vector>()->type()->Is<sem::I32>());
EXPECT_EQ(sem->ConstantValue()->Index(0)->Index(0)->As<i32>(), 1_i);
EXPECT_EQ(sem->ConstantValue()->Index(0)->Index(1)->As<i32>(), 1_i);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->Type()->Is<sem::Vector>());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->Type()->As<sem::Vector>()->type()->Is<sem::U32>());
EXPECT_EQ(sem->ConstantValue()->Index(1)->Index(0)->As<u32>(), 2_u);
EXPECT_EQ(sem->ConstantValue()->Index(1)->Index(1)->As<u32>(), 2_u);
EXPECT_EQ(sem->ConstantValue()->Index(1)->Index(2)->As<u32>(), 2_u);
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(2)->Type()->Is<sem::Vector>());
EXPECT_TRUE(sem->ConstantValue()->Index(2)->Type()->As<sem::Vector>()->type()->Is<sem::F32>());
EXPECT_EQ(sem->ConstantValue()->Index(2)->Index(0)->As<f32>(), 3._f);
EXPECT_EQ(sem->ConstantValue()->Index(2)->Index(1)->As<f32>(), 3._f);
EXPECT_EQ(sem->ConstantValue()->Index(2)->Index(2)->As<f32>(), 3._f);
EXPECT_EQ(sem->ConstantValue()->Index(2)->Index(3)->As<f32>(), 3._f);
EXPECT_TRUE(sem->ConstantValue()->Index(3)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(3)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(3)->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(3)->Type()->Is<sem::Vector>());
EXPECT_TRUE(sem->ConstantValue()->Index(3)->Type()->As<sem::Vector>()->type()->Is<sem::F16>());
EXPECT_EQ(sem->ConstantValue()->Index(3)->Index(0)->As<f16>(), 4._h);
EXPECT_EQ(sem->ConstantValue()->Index(3)->Index(1)->As<f16>(), 4._h);
EXPECT_EQ(sem->ConstantValue()->Index(3)->Index(2)->As<f16>(), 4._h);
EXPECT_TRUE(sem->ConstantValue()->Index(4)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(4)->AnyZero());
EXPECT_TRUE(sem->ConstantValue()->Index(4)->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(4)->Type()->Is<sem::Vector>());
EXPECT_TRUE(sem->ConstantValue()->Index(4)->Type()->As<sem::Vector>()->type()->Is<sem::Bool>());
EXPECT_EQ(sem->ConstantValue()->Index(4)->Index(0)->As<bool>(), false);
EXPECT_EQ(sem->ConstantValue()->Index(4)->Index(1)->As<bool>(), false);
}
TEST_F(ResolverConstEvalTest, Struct_Struct_Construct) {
Structure("Inner", utils::Vector{
Member("m1", ty.i32()),
Member("m2", ty.u32()),
Member("m3", ty.f32()),
});
Structure("Outer", utils::Vector{
Member("m1", ty.type_name("Inner")),
Member("m2", ty.type_name("Inner")),
});
auto* expr = Construct(ty.type_name("Outer"), //
Construct(ty.type_name("Inner"), 1_i, 2_u, 3_f),
Construct(ty.type_name("Inner"), 4_i, 0_u, 6_f));
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
ASSERT_NE(sem, nullptr);
auto* str = sem->Type()->As<sem::Struct>();
ASSERT_NE(str, nullptr);
EXPECT_EQ(str->Members().size(), 2u);
ASSERT_NE(sem->ConstantValue(), nullptr);
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_FALSE(sem->ConstantValue()->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->AllZero());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->Type()->Is<sem::Struct>());
EXPECT_EQ(sem->ConstantValue()->Index(0)->Index(0)->As<i32>(), 1_i);
EXPECT_EQ(sem->ConstantValue()->Index(0)->Index(1)->As<u32>(), 2_u);
EXPECT_EQ(sem->ConstantValue()->Index(0)->Index(2)->As<f32>(), 3_f);
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AllEqual());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->Type()->Is<sem::Struct>());
EXPECT_EQ(sem->ConstantValue()->Index(1)->Index(0)->As<i32>(), 4_i);
EXPECT_EQ(sem->ConstantValue()->Index(1)->Index(1)->As<u32>(), 0_u);
EXPECT_EQ(sem->ConstantValue()->Index(1)->Index(2)->As<f32>(), 6_f);
}
TEST_F(ResolverConstEvalTest, Struct_Array_Construct) {
Structure("S", utils::Vector{
Member("m1", ty.array<i32, 2>()),
Member("m2", ty.array<f32, 3>()),
});
auto* expr = Construct(ty.type_name("S"), //
Construct(ty.array<i32, 2>(), 1_i, 2_i),
Construct(ty.array<f32, 3>(), 1_f, 2_f, 3_f));
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
ASSERT_NE(sem, nullptr);
auto* str = sem->Type()->As<sem::Struct>();
ASSERT_NE(str, nullptr);
EXPECT_EQ(str->Members().size(), 2u);
ASSERT_NE(sem->ConstantValue(), nullptr);
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_FALSE(sem->ConstantValue()->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->AllZero());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->Type()->Is<sem::Array>());
EXPECT_EQ(sem->ConstantValue()->Index(0)->Index(0)->As<i32>(), 1_i);
EXPECT_EQ(sem->ConstantValue()->Index(0)->Index(1)->As<u32>(), 2_i);
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(1)->Type()->Is<sem::Array>());
EXPECT_EQ(sem->ConstantValue()->Index(1)->Index(0)->As<i32>(), 1_f);
EXPECT_EQ(sem->ConstantValue()->Index(1)->Index(1)->As<u32>(), 2_f);
EXPECT_EQ(sem->ConstantValue()->Index(1)->Index(2)->As<f32>(), 3_f);
}
////////////////////////////////////////////////////////////////////////////////////////////////////
// Indexing
////////////////////////////////////////////////////////////////////////////////////////////////////
TEST_F(ResolverConstEvalTest, Vec3_Index) {
auto* expr = IndexAccessor(vec3<i32>(1_i, 2_i, 3_i), 2_i);
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
ASSERT_NE(sem, nullptr);
ASSERT_TRUE(sem->Type()->Is<sem::I32>());
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_TRUE(sem->ConstantValue()->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->AllZero());
EXPECT_EQ(sem->ConstantValue()->As<i32>(), 3_i);
}
TEST_F(ResolverConstEvalTest, Vec3_Index_OOB_High) {
auto* expr = IndexAccessor(vec3<i32>(1_i, 2_i, 3_i), Expr(Source{{12, 34}}, 3_i));
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
EXPECT_EQ(r()->error(), "12:34 warning: index 3 out of bounds [0..2]. Clamping index to 2");
auto* sem = Sem().Get(expr);
ASSERT_NE(sem, nullptr);
ASSERT_TRUE(sem->Type()->Is<sem::I32>());
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_TRUE(sem->ConstantValue()->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->AllZero());
EXPECT_EQ(sem->ConstantValue()->As<i32>(), 3_i);
}
TEST_F(ResolverConstEvalTest, Vec3_Index_OOB_Low) {
auto* expr = IndexAccessor(vec3<i32>(1_i, 2_i, 3_i), Expr(Source{{12, 34}}, -3_i));
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
EXPECT_EQ(r()->error(), "12:34 warning: index -3 out of bounds [0..2]. Clamping index to 0");
auto* sem = Sem().Get(expr);
ASSERT_NE(sem, nullptr);
ASSERT_TRUE(sem->Type()->Is<sem::I32>());
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_TRUE(sem->ConstantValue()->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->AllZero());
EXPECT_EQ(sem->ConstantValue()->As<i32>(), 1_i);
}
TEST_F(ResolverConstEvalTest, Vec3_Swizzle_Scalar) {
auto* expr = MemberAccessor(vec3<i32>(1_i, 2_i, 3_i), "y");
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
ASSERT_NE(sem, nullptr);
ASSERT_TRUE(sem->Type()->Is<sem::I32>());
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_TRUE(sem->ConstantValue()->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->AllZero());
EXPECT_EQ(sem->ConstantValue()->As<i32>(), 2_i);
}
TEST_F(ResolverConstEvalTest, Vec3_Swizzle_Vector) {
auto* expr = MemberAccessor(vec3<i32>(1_i, 2_i, 3_i), "zx");
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
ASSERT_NE(sem, nullptr);
auto* vec = sem->Type()->As<sem::Vector>();
ASSERT_NE(vec, nullptr);
EXPECT_EQ(vec->Width(), 2u);
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(0)->As<f32>(), 3._a);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(1)->As<f32>(), 1._a);
}
TEST_F(ResolverConstEvalTest, Vec3_Swizzle_Chain) {
auto* expr = // (1, 2, 3) -> (2, 3, 1) -> (3, 2) -> 2
MemberAccessor(MemberAccessor(MemberAccessor(vec3<i32>(1_i, 2_i, 3_i), "gbr"), "yx"), "y");
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
ASSERT_NE(sem, nullptr);
ASSERT_TRUE(sem->Type()->Is<sem::I32>());
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_TRUE(sem->ConstantValue()->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->AllZero());
EXPECT_EQ(sem->ConstantValue()->As<i32>(), 2_i);
}
TEST_F(ResolverConstEvalTest, Mat3x2_Index) {
auto* expr = IndexAccessor(
mat3x2<f32>(vec2<f32>(1._a, 2._a), vec2<f32>(3._a, 4._a), vec2<f32>(5._a, 6._a)), 2_i);
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
ASSERT_NE(sem, nullptr);
auto* vec = sem->Type()->As<sem::Vector>();
ASSERT_NE(vec, nullptr);
EXPECT_EQ(vec->Width(), 2u);
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(0)->As<f32>(), 5._a);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(1)->As<f32>(), 6._a);
}
TEST_F(ResolverConstEvalTest, Mat3x2_Index_OOB_High) {
auto* expr = IndexAccessor(
mat3x2<f32>(vec2<f32>(1._a, 2._a), vec2<f32>(3._a, 4._a), vec2<f32>(5._a, 6._a)),
Expr(Source{{12, 34}}, 3_i));
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
EXPECT_EQ(r()->error(), "12:34 warning: index 3 out of bounds [0..2]. Clamping index to 2");
auto* sem = Sem().Get(expr);
ASSERT_NE(sem, nullptr);
auto* vec = sem->Type()->As<sem::Vector>();
ASSERT_NE(vec, nullptr);
EXPECT_EQ(vec->Width(), 2u);
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(0)->As<f32>(), 5._a);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(1)->As<f32>(), 6._a);
}
TEST_F(ResolverConstEvalTest, Mat3x2_Index_OOB_Low) {
auto* expr = IndexAccessor(
mat3x2<f32>(vec2<f32>(1._a, 2._a), vec2<f32>(3._a, 4._a), vec2<f32>(5._a, 6._a)),
Expr(Source{{12, 34}}, -3_i));
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
EXPECT_EQ(r()->error(), "12:34 warning: index -3 out of bounds [0..2]. Clamping index to 0");
auto* sem = Sem().Get(expr);
ASSERT_NE(sem, nullptr);
auto* vec = sem->Type()->As<sem::Vector>();
ASSERT_NE(vec, nullptr);
EXPECT_EQ(vec->Width(), 2u);
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(0)->As<f32>(), 1._a);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(1)->As<f32>(), 2._a);
}
TEST_F(ResolverConstEvalTest, Array_vec3_f32_Index) {
auto* expr = IndexAccessor(Construct(ty.array(ty.vec3<f32>(), 2_u), //
vec3<f32>(1_f, 2_f, 3_f), vec3<f32>(4_f, 5_f, 6_f)),
1_i);
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
ASSERT_NE(sem, nullptr);
auto* vec = sem->Type()->As<sem::Vector>();
ASSERT_NE(vec, nullptr);
EXPECT_TRUE(vec->type()->Is<sem::F32>());
EXPECT_EQ(vec->Width(), 3u);
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(0)->As<f32>(), 4_f);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(1)->As<f32>(), 5_f);
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(2)->As<f32>(), 6_f);
}
TEST_F(ResolverConstEvalTest, Array_vec3_f32_Index_OOB_High) {
auto* expr = IndexAccessor(Construct(ty.array(ty.vec3<f32>(), 2_u), //
vec3<f32>(1_f, 2_f, 3_f), vec3<f32>(4_f, 5_f, 6_f)),
Expr(Source{{12, 34}}, 2_i));
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
EXPECT_EQ(r()->error(), "12:34 warning: index 2 out of bounds [0..1]. Clamping index to 1");
auto* sem = Sem().Get(expr);
ASSERT_NE(sem, nullptr);
auto* vec = sem->Type()->As<sem::Vector>();
ASSERT_NE(vec, nullptr);
EXPECT_TRUE(vec->type()->Is<sem::F32>());
EXPECT_EQ(vec->Width(), 3u);
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(0)->As<f32>(), 4_f);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(1)->As<f32>(), 5_f);
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(2)->As<f32>(), 6_f);
}
TEST_F(ResolverConstEvalTest, Array_vec3_f32_Index_OOB_Low) {
auto* expr = IndexAccessor(Construct(ty.array(ty.vec3<f32>(), 2_u), //
vec3<f32>(1_f, 2_f, 3_f), vec3<f32>(4_f, 5_f, 6_f)),
Expr(Source{{12, 34}}, -2_i));
WrapInFunction(expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
EXPECT_EQ(r()->error(), "12:34 warning: index -2 out of bounds [0..1]. Clamping index to 0");
auto* sem = Sem().Get(expr);
ASSERT_NE(sem, nullptr);
auto* vec = sem->Type()->As<sem::Vector>();
ASSERT_NE(vec, nullptr);
EXPECT_TRUE(vec->type()->Is<sem::F32>());
EXPECT_EQ(vec->Width(), 3u);
EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type());
EXPECT_FALSE(sem->ConstantValue()->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->AllZero());
EXPECT_TRUE(sem->ConstantValue()->Index(0)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(0)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(0)->As<f32>(), 1_f);
EXPECT_TRUE(sem->ConstantValue()->Index(1)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(1)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(1)->As<f32>(), 2_f);
EXPECT_TRUE(sem->ConstantValue()->Index(2)->AllEqual());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->AnyZero());
EXPECT_FALSE(sem->ConstantValue()->Index(2)->AllZero());
EXPECT_EQ(sem->ConstantValue()->Index(2)->As<f32>(), 3_f);
}
TEST_F(ResolverConstEvalTest, ChainedIndex) {
auto* arr_expr = Construct(ty.array(ty.mat2x3<f32>(), 2_u), // array<mat2x3<f32>, 2u>
mat2x3<f32>(vec3<f32>(1_f, 2_f, 3_f), //
vec3<f32>(4_f, 5_f, 6_f)), //
mat2x3<f32>(vec3<f32>(7_f, 0_f, 9_f), //
vec3<f32>(10_f, 11_f, 12_f)));
auto* mat_expr = IndexAccessor(arr_expr, 1_i); // arr[1]
auto* vec_expr = IndexAccessor(mat_expr, 0_i); // arr[1][0]
auto* f32_expr = IndexAccessor(vec_expr, 2_i); // arr[1][0][2]
WrapInFunction(f32_expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
{
auto* mat = Sem().Get(mat_expr);
EXPECT_NE(mat, nullptr);
auto* ty = mat->Type()->As<sem::Matrix>();
ASSERT_NE(mat->Type(), nullptr);
EXPECT_TRUE(ty->ColumnType()->Is<sem::Vector>());
EXPECT_EQ(ty->columns(), 2u);
EXPECT_EQ(ty->rows(), 3u);
EXPECT_EQ(mat->ConstantValue()->Type(), mat->Type());
EXPECT_FALSE(mat->ConstantValue()->AllEqual());
EXPECT_TRUE(mat->ConstantValue()->AnyZero());
EXPECT_FALSE(mat->ConstantValue()->AllZero());
EXPECT_TRUE(mat->ConstantValue()->Index(0)->Index(0)->AllEqual());
EXPECT_FALSE(mat->ConstantValue()->Index(0)->Index(0)->AnyZero());
EXPECT_FALSE(mat->ConstantValue()->Index(0)->Index(0)->AllZero());
EXPECT_EQ(mat->ConstantValue()->Index(0)->Index(0)->As<f32>(), 7_f);
EXPECT_TRUE(mat->ConstantValue()->Index(0)->Index(1)->AllEqual());
EXPECT_TRUE(mat->ConstantValue()->Index(0)->Index(1)->AnyZero());
EXPECT_TRUE(mat->ConstantValue()->Index(0)->Index(1)->AllZero());
EXPECT_EQ(mat->ConstantValue()->Index(0)->Index(1)->As<f32>(), 0_f);
EXPECT_TRUE(mat->ConstantValue()->Index(0)->Index(2)->AllEqual());
EXPECT_FALSE(mat->ConstantValue()->Index(0)->Index(2)->AnyZero());
EXPECT_FALSE(mat->ConstantValue()->Index(0)->Index(2)->AllZero());
EXPECT_EQ(mat->ConstantValue()->Index(0)->Index(2)->As<f32>(), 9_f);
EXPECT_TRUE(mat->ConstantValue()->Index(1)->Index(0)->AllEqual());
EXPECT_FALSE(mat->ConstantValue()->Index(1)->Index(0)->AnyZero());
EXPECT_FALSE(mat->ConstantValue()->Index(1)->Index(0)->AllZero());
EXPECT_EQ(mat->ConstantValue()->Index(1)->Index(0)->As<f32>(), 10_f);
EXPECT_TRUE(mat->ConstantValue()->Index(1)->Index(1)->AllEqual());
EXPECT_FALSE(mat->ConstantValue()->Index(1)->Index(1)->AnyZero());
EXPECT_FALSE(mat->ConstantValue()->Index(1)->Index(1)->AllZero());
EXPECT_EQ(mat->ConstantValue()->Index(1)->Index(1)->As<f32>(), 11_f);
EXPECT_TRUE(mat->ConstantValue()->Index(1)->Index(2)->AllEqual());
EXPECT_FALSE(mat->ConstantValue()->Index(1)->Index(2)->AnyZero());
EXPECT_FALSE(mat->ConstantValue()->Index(1)->Index(2)->AllZero());
EXPECT_EQ(mat->ConstantValue()->Index(1)->Index(2)->As<f32>(), 12_f);
}
{
auto* vec = Sem().Get(vec_expr);
EXPECT_NE(vec, nullptr);
auto* ty = vec->Type()->As<sem::Vector>();
ASSERT_NE(vec->Type(), nullptr);
EXPECT_TRUE(ty->type()->Is<sem::F32>());
EXPECT_EQ(ty->Width(), 3u);
EXPECT_EQ(vec->ConstantValue()->Type(), vec->Type());
EXPECT_FALSE(vec->ConstantValue()->AllEqual());
EXPECT_TRUE(vec->ConstantValue()->AnyZero());
EXPECT_FALSE(vec->ConstantValue()->AllZero());
EXPECT_TRUE(vec->ConstantValue()->Index(0)->AllEqual());
EXPECT_FALSE(vec->ConstantValue()->Index(0)->AnyZero());
EXPECT_FALSE(vec->ConstantValue()->Index(0)->AllZero());
EXPECT_EQ(vec->ConstantValue()->Index(0)->As<f32>(), 7_f);
EXPECT_TRUE(vec->ConstantValue()->Index(1)->AllEqual());
EXPECT_TRUE(vec->ConstantValue()->Index(1)->AnyZero());
EXPECT_TRUE(vec->ConstantValue()->Index(1)->AllZero());
EXPECT_EQ(vec->ConstantValue()->Index(1)->As<f32>(), 0_f);
EXPECT_TRUE(vec->ConstantValue()->Index(2)->AllEqual());
EXPECT_FALSE(vec->ConstantValue()->Index(2)->AnyZero());
EXPECT_FALSE(vec->ConstantValue()->Index(2)->AllZero());
EXPECT_EQ(vec->ConstantValue()->Index(2)->As<f32>(), 9_f);
}
{
auto* f = Sem().Get(f32_expr);
EXPECT_NE(f, nullptr);
EXPECT_TRUE(f->Type()->Is<sem::F32>());
EXPECT_EQ(f->ConstantValue()->Type(), f->Type());
EXPECT_TRUE(f->ConstantValue()->AllEqual());
EXPECT_FALSE(f->ConstantValue()->AnyZero());
EXPECT_FALSE(f->ConstantValue()->AllZero());
EXPECT_EQ(f->ConstantValue()->As<f32>(), 9_f);
}
}
TEST_F(ResolverConstEvalTest, ChainedIndex_OOB) {
auto* arr_expr = Construct(ty.array(ty.mat2x3<f32>(), 2_u), // array<mat2x3<f32>, 2u>
mat2x3<f32>(vec3<f32>(1_f, 2_f, 3_f), //
vec3<f32>(4_f, 5_f, 6_f)), //
mat2x3<f32>(vec3<f32>(7_f, 8_f, 9_f), //
vec3<f32>(10_f, 11_f, 12_f)));
auto* mat_expr = IndexAccessor(arr_expr, Expr(Source{{1, 2}}, -3_i)); // arr[3]
auto* vec_expr = IndexAccessor(mat_expr, Expr(Source{{3, 4}}, -2_i)); // arr[3][-2]
auto* f32_expr = IndexAccessor(vec_expr, Expr(Source{{5, 6}}, 4_i)); // arr[3][-2][4]
WrapInFunction(f32_expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
EXPECT_EQ(r()->error(), R"(1:2 warning: index -3 out of bounds [0..1]. Clamping index to 0
3:4 warning: index -2 out of bounds [0..1]. Clamping index to 0
5:6 warning: index 4 out of bounds [0..2]. Clamping index to 2)");
{
auto* mat = Sem().Get(mat_expr);
EXPECT_NE(mat, nullptr);
auto* ty = mat->Type()->As<sem::Matrix>();
ASSERT_NE(mat->Type(), nullptr);
EXPECT_TRUE(ty->ColumnType()->Is<sem::Vector>());
EXPECT_EQ(ty->columns(), 2u);
EXPECT_EQ(ty->rows(), 3u);
EXPECT_EQ(mat->ConstantValue()->Type(), mat->Type());
EXPECT_FALSE(mat->ConstantValue()->AllEqual());
EXPECT_FALSE(mat->ConstantValue()->AnyZero());
EXPECT_FALSE(mat->ConstantValue()->AllZero());
EXPECT_TRUE(mat->ConstantValue()->Index(0)->Index(0)->AllEqual());
EXPECT_FALSE(mat->ConstantValue()->Index(0)->Index(0)->AnyZero());
EXPECT_FALSE(mat->ConstantValue()->Index(0)->Index(0)->AllZero());
EXPECT_EQ(mat->ConstantValue()->Index(0)->Index(0)->As<f32>(), 1_f);
EXPECT_TRUE(mat->ConstantValue()->Index(0)->Index(1)->AllEqual());
EXPECT_FALSE(mat->ConstantValue()->Index(0)->Index(1)->AnyZero());
EXPECT_FALSE(mat->ConstantValue()->Index(0)->Index(1)->AllZero());
EXPECT_EQ(mat->ConstantValue()->Index(0)->Index(1)->As<f32>(), 2_f);
EXPECT_TRUE(mat->ConstantValue()->Index(0)->Index(2)->AllEqual());
EXPECT_FALSE(mat->ConstantValue()->Index(0)->Index(2)->AnyZero());
EXPECT_FALSE(mat->ConstantValue()->Index(0)->Index(2)->AllZero());
EXPECT_EQ(mat->ConstantValue()->Index(0)->Index(2)->As<f32>(), 3_f);
EXPECT_TRUE(mat->ConstantValue()->Index(1)->Index(0)->AllEqual());
EXPECT_FALSE(mat->ConstantValue()->Index(1)->Index(0)->AnyZero());
EXPECT_FALSE(mat->ConstantValue()->Index(1)->Index(0)->AllZero());
EXPECT_EQ(mat->ConstantValue()->Index(1)->Index(0)->As<f32>(), 4_f);
EXPECT_TRUE(mat->ConstantValue()->Index(1)->Index(1)->AllEqual());
EXPECT_FALSE(mat->ConstantValue()->Index(1)->Index(1)->AnyZero());
EXPECT_FALSE(mat->ConstantValue()->Index(1)->Index(1)->AllZero());
EXPECT_EQ(mat->ConstantValue()->Index(1)->Index(1)->As<f32>(), 5_f);
EXPECT_TRUE(mat->ConstantValue()->Index(1)->Index(2)->AllEqual());
EXPECT_FALSE(mat->ConstantValue()->Index(1)->Index(2)->AnyZero());
EXPECT_FALSE(mat->ConstantValue()->Index(1)->Index(2)->AllZero());
EXPECT_EQ(mat->ConstantValue()->Index(1)->Index(2)->As<f32>(), 6_f);
}
{
auto* vec = Sem().Get(vec_expr);
EXPECT_NE(vec, nullptr);
auto* ty = vec->Type()->As<sem::Vector>();
ASSERT_NE(vec->Type(), nullptr);
EXPECT_TRUE(ty->type()->Is<sem::F32>());
EXPECT_EQ(ty->Width(), 3u);
EXPECT_EQ(vec->ConstantValue()->Type(), vec->Type());
EXPECT_FALSE(vec->ConstantValue()->AllEqual());
EXPECT_FALSE(vec->ConstantValue()->AnyZero());
EXPECT_FALSE(vec->ConstantValue()->AllZero());
EXPECT_TRUE(vec->ConstantValue()->Index(0)->AllEqual());
EXPECT_FALSE(vec->ConstantValue()->Index(0)->AnyZero());
EXPECT_FALSE(vec->ConstantValue()->Index(0)->AllZero());
EXPECT_EQ(vec->ConstantValue()->Index(0)->As<f32>(), 1_f);
EXPECT_TRUE(vec->ConstantValue()->Index(1)->AllEqual());
EXPECT_FALSE(vec->ConstantValue()->Index(1)->AnyZero());
EXPECT_FALSE(vec->ConstantValue()->Index(1)->AllZero());
EXPECT_EQ(vec->ConstantValue()->Index(1)->As<f32>(), 2_f);
EXPECT_TRUE(vec->ConstantValue()->Index(2)->AllEqual());
EXPECT_FALSE(vec->ConstantValue()->Index(2)->AnyZero());
EXPECT_FALSE(vec->ConstantValue()->Index(2)->AllZero());
EXPECT_EQ(vec->ConstantValue()->Index(2)->As<f32>(), 3_f);
}
{
auto* f = Sem().Get(f32_expr);
EXPECT_NE(f, nullptr);
EXPECT_TRUE(f->Type()->Is<sem::F32>());
EXPECT_EQ(f->ConstantValue()->Type(), f->Type());
EXPECT_TRUE(f->ConstantValue()->AllEqual());
EXPECT_FALSE(f->ConstantValue()->AnyZero());
EXPECT_FALSE(f->ConstantValue()->AllZero());
EXPECT_EQ(f->ConstantValue()->As<f32>(), 3_f);
}
}
////////////////////////////////////////////////////////////////////////////////////////////////////
// Member accessing
////////////////////////////////////////////////////////////////////////////////////////////////////
TEST_F(ResolverConstEvalTest, MemberAccess) {
Structure("Inner", utils::Vector{
Member("i1", ty.i32()),
Member("i2", ty.u32()),
Member("i3", ty.f32()),
});
Structure("Outer", utils::Vector{
Member("o1", ty.type_name("Inner")),
Member("o2", ty.type_name("Inner")),
});
auto* outer_expr = Construct(ty.type_name("Outer"), //
Construct(ty.type_name("Inner"), 1_i, 2_u, 3_f),
Construct(ty.type_name("Inner")));
auto* o1_expr = MemberAccessor(outer_expr, "o1");
auto* i2_expr = MemberAccessor(o1_expr, "i2");
WrapInFunction(i2_expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* outer = Sem().Get(outer_expr);
ASSERT_NE(outer, nullptr);
auto* str = outer->Type()->As<sem::Struct>();
ASSERT_NE(str, nullptr);
EXPECT_EQ(str->Members().size(), 2u);
ASSERT_NE(outer->ConstantValue(), nullptr);
EXPECT_TYPE(outer->ConstantValue()->Type(), outer->Type());
EXPECT_FALSE(outer->ConstantValue()->AllEqual());
EXPECT_TRUE(outer->ConstantValue()->AnyZero());
EXPECT_FALSE(outer->ConstantValue()->AllZero());
auto* o1 = Sem().Get(o1_expr);
ASSERT_NE(o1->ConstantValue(), nullptr);
EXPECT_FALSE(o1->ConstantValue()->AllEqual());
EXPECT_FALSE(o1->ConstantValue()->AnyZero());
EXPECT_FALSE(o1->ConstantValue()->AllZero());
EXPECT_TRUE(o1->ConstantValue()->Type()->Is<sem::Struct>());
EXPECT_EQ(o1->ConstantValue()->Index(0)->As<i32>(), 1_i);
EXPECT_EQ(o1->ConstantValue()->Index(1)->As<u32>(), 2_u);
EXPECT_EQ(o1->ConstantValue()->Index(2)->As<f32>(), 3_f);
auto* i2 = Sem().Get(i2_expr);
ASSERT_NE(i2->ConstantValue(), nullptr);
EXPECT_TRUE(i2->ConstantValue()->AllEqual());
EXPECT_FALSE(i2->ConstantValue()->AnyZero());
EXPECT_FALSE(i2->ConstantValue()->AllZero());
EXPECT_TRUE(i2->ConstantValue()->Type()->Is<sem::U32>());
EXPECT_EQ(i2->ConstantValue()->As<u32>(), 2_u);
}
////////////////////////////////////////////////////////////////////////////////////////////////////
// Unary op
////////////////////////////////////////////////////////////////////////////////////////////////////
namespace unary_op {
template <typename T>
struct Values {
T input;
T expect;
};
struct Case {
std::variant<Values<AInt>, Values<AFloat>, Values<u32>, Values<i32>, Values<f32>, Values<f16>>
values;
};
static std::ostream& operator<<(std::ostream& o, const Case& c) {
std::visit([&](auto&& v) { o << v.input; }, c.values);
return o;
}
template <typename T>
Case C(T input, T expect) {
return Case{Values<T>{input, expect}};
}
using ResolverConstEvalUnaryOpTest = ResolverTestWithParam<std::tuple<ast::UnaryOp, Case>>;
TEST_P(ResolverConstEvalUnaryOpTest, Test) {
Enable(ast::Extension::kF16);
auto op = std::get<0>(GetParam());
auto c = std::get<1>(GetParam());
std::visit(
[&](auto&& values) {
using T = decltype(values.expect);
auto* expr = create<ast::UnaryOpExpression>(op, Expr(values.input));
GlobalConst("C", expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
const sem::Constant* value = sem->ConstantValue();
ASSERT_NE(value, nullptr);
EXPECT_TYPE(value->Type(), sem->Type());
EXPECT_EQ(value->As<T>(), values.expect);
if constexpr (IsInteger<UnwrapNumber<T>>) {
// Check that the constant's integer doesn't contain unexpected data in the MSBs
// that are outside of the bit-width of T.
EXPECT_EQ(value->As<AInt>(), AInt(values.expect));
}
},
c.values);
}
INSTANTIATE_TEST_SUITE_P(Complement,
ResolverConstEvalUnaryOpTest,
testing::Combine(testing::Values(ast::UnaryOp::kComplement),
testing::ValuesIn({
// AInt
C(0_a, 0xffffffffffffffff_a),
C(0xffffffffffffffff_a, 0_a),
C(0xf0f0f0f0f0f0f0f0_a, 0x0f0f0f0f0f0f0f0f_a),
C(0xaaaaaaaaaaaaaaaa_a, 0x5555555555555555_a),
C(0x5555555555555555_a, 0xaaaaaaaaaaaaaaaa_a),
// u32
C(0_u, 0xffffffff_u),
C(0xffffffff_u, 0_u),
C(0xf0f0f0f0_u, 0x0f0f0f0f_u),
C(0xaaaaaaaa_u, 0x55555555_u),
C(0x55555555_u, 0xaaaaaaaa_u),
// i32
C(0_i, -1_i),
C(-1_i, 0_i),
C(1_i, -2_i),
C(-2_i, 1_i),
C(2_i, -3_i),
C(-3_i, 2_i),
})));
INSTANTIATE_TEST_SUITE_P(Negation,
ResolverConstEvalUnaryOpTest,
testing::Combine(testing::Values(ast::UnaryOp::kNegation),
testing::ValuesIn({
// AInt
C(0_a, -0_a),
C(-0_a, 0_a),
C(1_a, -1_a),
C(-1_a, 1_a),
C(AInt::Highest(), -AInt::Highest()),
C(-AInt::Highest(), AInt::Highest()),
C(AInt::Lowest(), Negate(AInt::Lowest())),
C(Negate(AInt::Lowest()), AInt::Lowest()),
// i32
C(0_i, -0_i),
C(-0_i, 0_i),
C(1_i, -1_i),
C(-1_i, 1_i),
C(i32::Highest(), -i32::Highest()),
C(-i32::Highest(), i32::Highest()),
C(i32::Lowest(), Negate(i32::Lowest())),
C(Negate(i32::Lowest()), i32::Lowest()),
// AFloat
C(0.0_a, -0.0_a),
C(-0.0_a, 0.0_a),
C(1.0_a, -1.0_a),
C(-1.0_a, 1.0_a),
C(AFloat::Highest(), -AFloat::Highest()),
C(-AFloat::Highest(), AFloat::Highest()),
C(AFloat::Lowest(), Negate(AFloat::Lowest())),
C(Negate(AFloat::Lowest()), AFloat::Lowest()),
// f32
C(0.0_f, -0.0_f),
C(-0.0_f, 0.0_f),
C(1.0_f, -1.0_f),
C(-1.0_f, 1.0_f),
C(f32::Highest(), -f32::Highest()),
C(-f32::Highest(), f32::Highest()),
C(f32::Lowest(), Negate(f32::Lowest())),
C(Negate(f32::Lowest()), f32::Lowest()),
// f16
C(0.0_h, -0.0_h),
C(-0.0_h, 0.0_h),
C(1.0_h, -1.0_h),
C(-1.0_h, 1.0_h),
C(f16::Highest(), -f16::Highest()),
C(-f16::Highest(), f16::Highest()),
C(f16::Lowest(), Negate(f16::Lowest())),
C(Negate(f16::Lowest()), f16::Lowest()),
})));
// Make sure UBSan doesn't trip on C++'s undefined behaviour of negating the smallest negative
// number.
TEST_F(ResolverConstEvalTest, UnaryNegateLowestAbstract) {
// const break_me = -(-9223372036854775808);
auto* c = GlobalConst("break_me", Negation(Negation(Expr(9223372036854775808_a))));
(void)c;
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(c);
EXPECT_EQ(sem->ConstantValue()->As<AInt>(), 9223372036854775808_a);
}
} // namespace unary_op
////////////////////////////////////////////////////////////////////////////////////////////////////
// Binary op
////////////////////////////////////////////////////////////////////////////////////////////////////
namespace binary_op {
using Types = std::variant<AInt, AFloat, u32, i32, f32, f16>;
struct Case {
Types lhs;
Types rhs;
Types expected;
bool is_overflow;
};
static std::ostream& operator<<(std::ostream& o, const Case& c) {
std::visit(
[&](auto&& lhs, auto&& rhs, auto&& expected) {
o << "lhs: " << lhs << ", rhs: " << rhs << ", expected: " << expected;
},
c.lhs, c.rhs, c.expected);
return o;
}
template <typename T, typename U, typename V>
Case C(T lhs, U rhs, V expected, bool is_overflow = false) {
return Case{lhs, rhs, expected, is_overflow};
}
using ResolverConstEvalBinaryOpTest = ResolverTestWithParam<std::tuple<ast::BinaryOp, Case>>;
TEST_P(ResolverConstEvalBinaryOpTest, Test) {
Enable(ast::Extension::kF16);
auto op = std::get<0>(GetParam());
auto c = std::get<1>(GetParam());
std::visit(
[&](auto&& lhs, auto&& rhs, auto&& expected) {
using T = std::decay_t<decltype(expected)>;
if constexpr (std::is_same_v<T, AInt> || std::is_same_v<T, AFloat>) {
if (c.is_overflow) {
return;
}
}
auto* expr = create<ast::BinaryExpression>(op, Expr(lhs), Expr(rhs));
GlobalConst("C", expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
const sem::Constant* value = sem->ConstantValue();
ASSERT_NE(value, nullptr);
EXPECT_TYPE(value->Type(), sem->Type());
EXPECT_EQ(value->As<T>(), expected);
if constexpr (IsInteger<UnwrapNumber<T>>) {
// Check that the constant's integer doesn't contain unexpected data in the MSBs
// that are outside of the bit-width of T.
EXPECT_EQ(value->As<AInt>(), AInt(expected));
}
},
c.lhs, c.rhs, c.expected);
}
INSTANTIATE_TEST_SUITE_P(MixedAbstractArgs,
ResolverConstEvalBinaryOpTest,
testing::Combine(testing::Values(ast::BinaryOp::kAdd),
testing::ValuesIn(std::vector{
// Mixed abstract type args
C(1_a, 2.3_a, 3.3_a),
C(2.3_a, 1_a, 3.3_a),
})));
template <typename T>
std::vector<Case> OpAddIntCases() {
static_assert(IsInteger<UnwrapNumber<T>>);
return {
C(T{0}, T{0}, T{0}),
C(T{1}, T{2}, T{3}),
C(T::Lowest(), T{1}, T{T::Lowest() + 1}),
C(T::Highest(), Negate(T{1}), T{T::Highest() - 1}),
C(T::Lowest(), T::Highest(), Negate(T{1})),
C(T::Highest(), T{1}, T::Lowest(), true),
C(T::Lowest(), Negate(T{1}), T::Highest(), true),
};
}
template <typename T>
std::vector<Case> OpAddFloatCases() {
static_assert(IsFloatingPoint<UnwrapNumber<T>>);
return {
C(T{0}, T{0}, T{0}),
C(T{1}, T{2}, T{3}),
C(T::Lowest(), T{1}, T{T::Lowest() + 1}),
C(T::Highest(), Negate(T{1}), T{T::Highest() - 1}),
C(T::Lowest(), T::Highest(), T{0}),
C(T::Highest(), T::Highest(), T::Inf(), true),
C(T::Lowest(), Negate(T::Highest()), -T::Inf(), true),
};
}
INSTANTIATE_TEST_SUITE_P(Add,
ResolverConstEvalBinaryOpTest,
testing::Combine(testing::Values(ast::BinaryOp::kAdd),
testing::ValuesIn(Concat( //
OpAddIntCases<AInt>(),
OpAddIntCases<i32>(),
OpAddIntCases<u32>(),
OpAddFloatCases<AFloat>(),
OpAddFloatCases<f32>(),
OpAddFloatCases<f16>()))));
template <typename T>
std::vector<Case> OpSubIntCases() {
static_assert(IsInteger<UnwrapNumber<T>>);
return {
C(T{0}, T{0}, T{0}),
C(T{3}, T{2}, T{1}),
C(T{T::Lowest() + 1}, T{1}, T::Lowest()),
C(T{T::Highest() - 1}, Negate(T{1}), T::Highest()),
C(Negate(T{1}), T::Highest(), T::Lowest()),
C(T::Lowest(), T{1}, T::Highest(), true),
C(T::Highest(), Negate(T{1}), T::Lowest(), true),
};
}
template <typename T>
std::vector<Case> OpSubFloatCases() {
static_assert(IsFloatingPoint<UnwrapNumber<T>>);
return {
C(T{0}, T{0}, T{0}),
C(T{3}, T{2}, T{1}),
C(T::Highest(), T{1}, T{T::Highest() - 1}),
C(T::Lowest(), Negate(T{1}), T{T::Lowest() + 1}),
C(T{0}, T::Highest(), T::Lowest()),
C(T::Highest(), Negate(T::Highest()), T::Inf(), true),
C(T::Lowest(), T::Highest(), -T::Inf(), true),
};
}
INSTANTIATE_TEST_SUITE_P(Sub,
ResolverConstEvalBinaryOpTest,
testing::Combine(testing::Values(ast::BinaryOp::kSubtract),
testing::ValuesIn(Concat( //
OpSubIntCases<AInt>(),
OpSubIntCases<i32>(),
OpSubIntCases<u32>(),
OpSubFloatCases<AFloat>(),
OpSubFloatCases<f32>(),
OpSubFloatCases<f16>()))));
TEST_F(ResolverConstEvalTest, BinaryAbstractAddOverflow_AInt) {
GlobalConst("c", Add(Source{{1, 1}}, Expr(AInt::Highest()), 1_a));
EXPECT_FALSE(r()->Resolve());
EXPECT_EQ(r()->error(),
"1:1 error: '-9223372036854775808' cannot be represented as 'abstract-int'");
}
TEST_F(ResolverConstEvalTest, BinaryAbstractAddUnderflow_AInt) {
GlobalConst("c", Add(Source{{1, 1}}, Expr(AInt::Lowest()), -1_a));
EXPECT_FALSE(r()->Resolve());
EXPECT_EQ(r()->error(),
"1:1 error: '9223372036854775807' cannot be represented as 'abstract-int'");
}
TEST_F(ResolverConstEvalTest, BinaryAbstractAddOverflow_AFloat) {
GlobalConst("c", Add(Source{{1, 1}}, Expr(AFloat::Highest()), AFloat::Highest()));
EXPECT_FALSE(r()->Resolve());
EXPECT_EQ(r()->error(), "1:1 error: 'inf' cannot be represented as 'abstract-float'");
}
TEST_F(ResolverConstEvalTest, BinaryAbstractAddUnderflow_AFloat) {
GlobalConst("c", Add(Source{{1, 1}}, Expr(AFloat::Lowest()), AFloat::Lowest()));
EXPECT_FALSE(r()->Resolve());
EXPECT_EQ(r()->error(), "1:1 error: '-inf' cannot be represented as 'abstract-float'");
}
TEST_F(ResolverConstEvalTest, BinaryAbstractMixed_ScalarScalar) {
auto* a = Const("a", Expr(1_a)); // AInt
auto* b = Const("b", Expr(2.3_a)); // AFloat
auto* c = Add(Expr("a"), Expr("b"));
WrapInFunction(a, b, c);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(c);
ASSERT_TRUE(sem);
ASSERT_TRUE(sem->ConstantValue());
auto result = sem->ConstantValue()->As<AFloat>();
EXPECT_EQ(result, 3.3f);
}
TEST_F(ResolverConstEvalTest, BinaryAbstractMixed_ScalarVector) {
auto* a = Const("a", Expr(1_a)); // AInt
auto* b = Const("b", Construct(ty.vec(nullptr, 3), Expr(2.3_a))); // AFloat
auto* c = Add(Expr("a"), Expr("b"));
WrapInFunction(a, b, c);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(c);
ASSERT_TRUE(sem);
ASSERT_TRUE(sem->ConstantValue());
EXPECT_EQ(sem->ConstantValue()->Index(0)->As<AFloat>(), 3.3f);
EXPECT_EQ(sem->ConstantValue()->Index(1)->As<AFloat>(), 3.3f);
EXPECT_EQ(sem->ConstantValue()->Index(2)->As<AFloat>(), 3.3f);
}
} // namespace binary_op
////////////////////////////////////////////////////////////////////////////////////////////////////
// Builtin
////////////////////////////////////////////////////////////////////////////////////////////////////
namespace builtin {
using Types = std::variant<AInt, AFloat, u32, i32, f32, f16>;
struct Case {
utils::Vector<Types, 8> args;
Types result;
bool result_pos_or_neg;
};
static std::ostream& operator<<(std::ostream& o, const Case& c) {
for (auto& a : c.args) {
std::visit([&](auto&& v) { o << v << ((&a != &c.args.Back()) ? " " : ""); }, a);
}
return o;
}
template <typename T>
Case C(std::initializer_list<Types> args, T result, bool result_pos_or_neg = false) {
return Case{std::move(args), std::move(result), result_pos_or_neg};
}
using ResolverConstEvalBuiltinTest = ResolverTestWithParam<std::tuple<sem::BuiltinType, Case>>;
TEST_P(ResolverConstEvalBuiltinTest, Test) {
Enable(ast::Extension::kF16);
auto builtin = std::get<0>(GetParam());
auto c = std::get<1>(GetParam());
utils::Vector<const ast::Expression*, 8> args;
for (auto& a : c.args) {
std::visit([&](auto&& v) { args.Push(Expr(v)); }, a);
}
std::visit(
[&](auto&& result) {
using T = std::decay_t<decltype(result)>;
auto* expr = Call(sem::str(builtin), std::move(args));
GlobalConst("C", expr);
EXPECT_TRUE(r()->Resolve()) << r()->error();
auto* sem = Sem().Get(expr);
const sem::Constant* value = sem->ConstantValue();
ASSERT_NE(value, nullptr);
EXPECT_TYPE(value->Type(), sem->Type());
auto actual = value->As<T>();
if constexpr (IsFloatingPoint<UnwrapNumber<T>>) {
if (std::isnan(result)) {
EXPECT_TRUE(std::isnan(actual));
} else {
EXPECT_FLOAT_EQ(c.result_pos_or_neg ? Abs(actual) : actual, result);
}
} else {
EXPECT_EQ(c.result_pos_or_neg ? Abs(actual) : actual, result);
}
if constexpr (IsInteger<UnwrapNumber<T>>) {
// Check that the constant's integer doesn't contain unexpected data in the MSBs
// that are outside of the bit-width of T.
EXPECT_EQ(value->As<AInt>(), AInt(result));
}
},
c.result);
}
template <typename T, bool finite_only>
std::vector<Case> Atan2Cases() {
std::vector<Case> cases = {
// If y is +/-0 and x is negative or -0, +/-PI is returned
C({T(0.0), -T(0.0)}, kPi<T>, true),
// If y is +/-0 and x is positive or +0, +/-0 is returned
C({T(0.0), T(0.0)}, T(0.0), true),
// If x is +/-0 and y is negative, -PI/2 is returned
C({-T(1.0), T(0.0)}, -kPiOver2<T>),
C({-T(1.0), -T(0.0)}, -kPiOver2<T>),
// If x is +/-0 and y is positive, +PI/2 is returned
C({T(1.0), T(0.0)}, kPiOver2<T>),
C({T(1.0), -T(0.0)}, kPiOver2<T>),
};
if constexpr (!finite_only) {
std::vector<Case> non_finite_cases = {
// If y is +/-INF and x is finite, +/-PI/2 is returned
C({T::Inf(), T(0.0)}, kPiOver2<T>, true),
C({-T::Inf(), T(0.0)}, kPiOver2<T>, true),
// If y is +/-INF and x is -INF, +/-3PI/4 is returned
C({T::Inf(), -T::Inf()}, k3PiOver4<T>, true),
C({-T::Inf(), -T::Inf()}, k3PiOver4<T>, true),
// If y is +/-INF and x is +INF, +/-PI/4 is returned
C({T::Inf(), T::Inf()}, kPiOver4<T>, true),
C({-T::Inf(), T::Inf()}, kPiOver4<T>, true),
// If x is -INF and y is finite and positive, +PI is returned
C({T(0.0), -T::Inf()}, kPi<T>),
// If x is -INF and y is finite and negative, -PI is returned
C({-T(0.0), -T::Inf()}, -kPi<T>),
// If x is +INF and y is finite and positive, +0 is returned
C({T(0.0), T::Inf()}, T(0.0)),
// If x is +INF and y is finite and negative, -0 is returned
C({-T(0.0), T::Inf()}, -T(0.0)),
// If either x is NaN or y is NaN, NaN is returned
C({T::NaN(), T(0.0)}, T::NaN()),
C({T(0.0), T::NaN()}, T::NaN()),
C({T::NaN(), T::NaN()}, T::NaN()),
};
cases = Concat(cases, non_finite_cases);
}
return cases;
}
INSTANTIATE_TEST_SUITE_P( //
MixedAbstractArgs,
ResolverConstEvalBuiltinTest,
testing::Combine(testing::Values(sem::BuiltinType::kAtan2),
testing::ValuesIn(std::vector{
C({1_a, 1.0_a}, 0.78539819_a),
C({1.0_a, 1_a}, 0.78539819_a),
})));
INSTANTIATE_TEST_SUITE_P( //
Atan2,
ResolverConstEvalBuiltinTest,
testing::Combine(testing::Values(sem::BuiltinType::kAtan2),
testing::ValuesIn(Concat(Atan2Cases<AFloat, true>(), //
Atan2Cases<f32, false>(),
Atan2Cases<f16, false>()))));
template <typename T>
std::vector<Case> ClampCases() {
return {
C({T(0), T(0), T(0)}, T(0)),
C({T(0), T(42), T::Highest()}, T(42)),
C({T::Lowest(), T(0), T(42)}, T(0)),
C({T(0), T::Lowest(), T::Highest()}, T(0)),
C({T(0), T::Highest(), T::Lowest()}, T::Lowest()),
C({T::Highest(), T::Highest(), T::Highest()}, T::Highest()),
C({T::Lowest(), T::Lowest(), T::Lowest()}, T::Lowest()),
C({T::Highest(), T::Lowest(), T::Highest()}, T::Highest()),
C({T::Lowest(), T::Lowest(), T::Highest()}, T::Lowest()),
};
}
INSTANTIATE_TEST_SUITE_P( //
Clamp,
ResolverConstEvalBuiltinTest,
testing::Combine(testing::Values(sem::BuiltinType::kClamp),
testing::ValuesIn(Concat(ClampCases<AInt>(), //
ClampCases<i32>(),
ClampCases<u32>(),
ClampCases<AFloat>(),
ClampCases<f32>(),
ClampCases<f16>()))));
} // namespace builtin
} // namespace
} // namespace tint::resolver