// Copyright 2022 The Tint Authors. // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. #include "src/tint/resolver/const_eval_test.h" using namespace tint::number_suffixes; // NOLINT namespace tint::resolver { namespace { TEST_F(ResolverConstEvalTest, Vec3_Index) { auto* expr = IndexAccessor(vec3(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()); 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()->ValueAs(), 3_i); } TEST_F(ResolverConstEvalTest, Vec3_Index_OOB_High) { auto* expr = IndexAccessor(vec3(1_i, 2_i, 3_i), Expr(Source{{12, 34}}, 3_i)); WrapInFunction(expr); EXPECT_FALSE(r()->Resolve()) << r()->error(); EXPECT_EQ(r()->error(), "12:34 error: index 3 out of bounds [0..2]"); } TEST_F(ResolverConstEvalTest, Vec3_Index_OOB_Low) { auto* expr = IndexAccessor(vec3(1_i, 2_i, 3_i), Expr(Source{{12, 34}}, -3_i)); WrapInFunction(expr); EXPECT_FALSE(r()->Resolve()) << r()->error(); EXPECT_EQ(r()->error(), "12:34 error: index -3 out of bounds [0..2]"); } namespace Swizzle { struct Case { Value input; const char* swizzle; Value expected; }; static Case C(Value input, const char* swizzle, Value expected) { return Case{std::move(input), swizzle, std::move(expected)}; } static std::ostream& operator<<(std::ostream& o, const Case& c) { return o << "input: " << c.input << ", swizzle: " << c.swizzle << ", expected: " << c.expected; } using ResolverConstEvalSwizzleTest = ResolverTestWithParam; TEST_P(ResolverConstEvalSwizzleTest, Test) { Enable(builtin::Extension::kF16); auto& param = GetParam(); auto* expr = MemberAccessor(param.input.Expr(*this), param.swizzle); auto* a = Const("a", expr); WrapInFunction(a); EXPECT_TRUE(r()->Resolve()) << r()->error(); auto* sem = Sem().Get(expr); ASSERT_NE(sem, nullptr); EXPECT_TYPE(sem->ConstantValue()->Type(), sem->Type()); CheckConstant(sem->ConstantValue(), param.expected); } template std::vector SwizzleCases() { return { C(Vec(T(0), T(1), T(2)), "xyz", Vec(T(0), T(1), T(2))), C(Vec(T(0), T(1), T(2)), "xzy", Vec(T(0), T(2), T(1))), C(Vec(T(0), T(1), T(2)), "yxz", Vec(T(1), T(0), T(2))), C(Vec(T(0), T(1), T(2)), "yzx", Vec(T(1), T(2), T(0))), C(Vec(T(0), T(1), T(2)), "zxy", Vec(T(2), T(0), T(1))), C(Vec(T(0), T(1), T(2)), "zyx", Vec(T(2), T(1), T(0))), C(Vec(T(0), T(1), T(2)), "xy", Vec(T(0), T(1))), C(Vec(T(0), T(1), T(2)), "xz", Vec(T(0), T(2))), C(Vec(T(0), T(1), T(2)), "yx", Vec(T(1), T(0))), C(Vec(T(0), T(1), T(2)), "yz", Vec(T(1), T(2))), C(Vec(T(0), T(1), T(2)), "zx", Vec(T(2), T(0))), C(Vec(T(0), T(1), T(2)), "zy", Vec(T(2), T(1))), C(Vec(T(0), T(1), T(2)), "xxxx", Vec(T(0), T(0), T(0), T(0))), C(Vec(T(0), T(1), T(2)), "yyyy", Vec(T(1), T(1), T(1), T(1))), C(Vec(T(0), T(1), T(2)), "zzzz", Vec(T(2), T(2), T(2), T(2))), C(Vec(T(0), T(1), T(2)), "xxx", Vec(T(0), T(0), T(0))), C(Vec(T(0), T(1), T(2)), "yyy", Vec(T(1), T(1), T(1))), C(Vec(T(0), T(1), T(2)), "zzz", Vec(T(2), T(2), T(2))), C(Vec(T(0), T(1), T(2)), "xx", Vec(T(0), T(0))), C(Vec(T(0), T(1), T(2)), "yy", Vec(T(1), T(1))), C(Vec(T(0), T(1), T(2)), "zz", Vec(T(2), T(2))), C(Vec(T(0), T(1), T(2)), "x", Val(T(0))), C(Vec(T(0), T(1), T(2)), "y", Val(T(1))), C(Vec(T(0), T(1), T(2)), "z", Val(T(2))), }; } INSTANTIATE_TEST_SUITE_P(Swizzle, ResolverConstEvalSwizzleTest, testing::ValuesIn(Concat(SwizzleCases(), // SwizzleCases(), // SwizzleCases(), // SwizzleCases(), // SwizzleCases(), // SwizzleCases(), // SwizzleCases() // ))); } // namespace Swizzle TEST_F(ResolverConstEvalTest, Vec3_Swizzle_Scalar) { auto* expr = MemberAccessor(vec3(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()); 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()->ValueAs(), 2_i); } TEST_F(ResolverConstEvalTest, Vec3_Swizzle_Vector) { auto* expr = MemberAccessor(vec3(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(); 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)->ValueAs(), 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)->ValueAs(), 1._a); } TEST_F(ResolverConstEvalTest, Vec3_Swizzle_Chain) { auto* expr = // (1, 2, 3) -> (2, 3, 1) -> (3, 2) -> 2 MemberAccessor(MemberAccessor(MemberAccessor(vec3(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()); 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()->ValueAs(), 2_i); } TEST_F(ResolverConstEvalTest, Mat3x2_Index) { auto* expr = IndexAccessor( mat3x2(vec2(1._a, 2._a), vec2(3._a, 4._a), vec2(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(); 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)->ValueAs(), 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)->ValueAs(), 6._a); } TEST_F(ResolverConstEvalTest, Mat3x2_Index_OOB_High) { auto* expr = IndexAccessor( mat3x2(vec2(1._a, 2._a), vec2(3._a, 4._a), vec2(5._a, 6._a)), Expr(Source{{12, 34}}, 3_i)); WrapInFunction(expr); EXPECT_FALSE(r()->Resolve()) << r()->error(); EXPECT_EQ(r()->error(), "12:34 error: index 3 out of bounds [0..2]"); } TEST_F(ResolverConstEvalTest, Mat3x2_Index_OOB_Low) { auto* expr = IndexAccessor( mat3x2(vec2(1._a, 2._a), vec2(3._a, 4._a), vec2(5._a, 6._a)), Expr(Source{{12, 34}}, -3_i)); WrapInFunction(expr); EXPECT_FALSE(r()->Resolve()) << r()->error(); EXPECT_EQ(r()->error(), "12:34 error: index -3 out of bounds [0..2]"); } TEST_F(ResolverConstEvalTest, Array_vec3_f32_Index) { auto* expr = IndexAccessor(Call(ty.array(ty.vec3(), 2_u), // vec3(1_f, 2_f, 3_f), vec3(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(); ASSERT_NE(vec, nullptr); EXPECT_TRUE(vec->type()->Is()); 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)->ValueAs(), 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)->ValueAs(), 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)->ValueAs(), 6_f); } TEST_F(ResolverConstEvalTest, Array_vec3_f32_Index_OOB_High) { auto* expr = IndexAccessor(Call(ty.array(ty.vec3(), 2_u), // vec3(1_f, 2_f, 3_f), vec3(4_f, 5_f, 6_f)), Expr(Source{{12, 34}}, 2_i)); WrapInFunction(expr); EXPECT_FALSE(r()->Resolve()) << r()->error(); EXPECT_EQ(r()->error(), "12:34 error: index 2 out of bounds [0..1]"); } TEST_F(ResolverConstEvalTest, Array_vec3_f32_Index_OOB_Low) { auto* expr = IndexAccessor(Call(ty.array(ty.vec3(), 2_u), // vec3(1_f, 2_f, 3_f), vec3(4_f, 5_f, 6_f)), Expr(Source{{12, 34}}, -2_i)); WrapInFunction(expr); EXPECT_FALSE(r()->Resolve()) << r()->error(); EXPECT_EQ(r()->error(), "12:34 error: index -2 out of bounds [0..1]"); } TEST_F(ResolverConstEvalTest, RuntimeArray_vec3_f32_Index_OOB_Low) { auto* sb = GlobalVar("sb", ty.array(ty.vec3()), Group(0_a), Binding(0_a), builtin::AddressSpace::kStorage); auto* expr = IndexAccessor(sb, Expr(Source{{12, 34}}, -2_i)); WrapInFunction(expr); EXPECT_FALSE(r()->Resolve()) << r()->error(); EXPECT_EQ(r()->error(), "12:34 error: index -2 out of bounds"); } TEST_F(ResolverConstEvalTest, ChainedIndex) { auto* arr_expr = Call(ty.array(ty.mat2x3(), 2_u), // array, 2u> mat2x3(vec3(1_f, 2_f, 3_f), // vec3(4_f, 5_f, 6_f)), // mat2x3(vec3(7_f, 0_f, 9_f), // vec3(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(); ASSERT_NE(mat->Type(), nullptr); EXPECT_TRUE(ty->ColumnType()->Is()); 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)->ValueAs(), 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)->ValueAs(), 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)->ValueAs(), 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)->ValueAs(), 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)->ValueAs(), 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)->ValueAs(), 12_f); } { auto* vec = Sem().Get(vec_expr); EXPECT_NE(vec, nullptr); auto* ty = vec->Type()->As(); ASSERT_NE(vec->Type(), nullptr); EXPECT_TRUE(ty->type()->Is()); 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)->ValueAs(), 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)->ValueAs(), 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)->ValueAs(), 9_f); } { auto* f = Sem().Get(f32_expr); EXPECT_NE(f, nullptr); EXPECT_TRUE(f->Type()->Is()); 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()->ValueAs(), 9_f); } } } // namespace } // namespace tint::resolver