src/tint/lang/core/constant/eval_bitcast_test.cc - tint - Git at Google

 // Copyright 2022 The Dawn & Tint Authors
 //
 // Redistribution and use in source and binary forms, with or without
 // modification, are permitted provided that the following conditions are met:
 //
 // 1. Redistributions of source code must retain the above copyright notice, this
 //    list of conditions and the following disclaimer.
 //
 // 2. Redistributions in binary form must reproduce the above copyright notice,
 //    this list of conditions and the following disclaimer in the documentation
 //    and/or other materials provided with the distribution.
 //
 // 3. Neither the name of the copyright holder nor the names of its
 //    contributors may be used to endorse or promote products derived from
 //    this software without specific prior written permission.
 //
 // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
 // AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
 // IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
 // DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE
 // FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
 // DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR
 // SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER
 // CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,
 // OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
 // OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.

 #include "src/tint/lang/core/constant/eval_test.h"

 namespace tint::core::constant::test {
 namespace {

 using namespace tint::core::fluent_types;     // NOLINT
 using namespace tint::core::number_suffixes;  // NOLINT

 struct Case {
     Value input;
     struct Success {
         Value value;
     };
     struct Failure {
         builder::CreatePtrs create_ptrs;
     };
     tint::Result<Success, Failure> expected;
 };

 static std::ostream& operator<<(std::ostream& o, const Case& c) {
     o << "input: " << c.input;
     if (c.expected == Success) {
         o << ", expected: " << c.expected.Get().value;
     } else {
         o << ", expected failed bitcast to " << c.expected.Failure().create_ptrs;
     }
     return o;
 }

 template <typename TO, typename FROM>
 Case Success(FROM input, TO expected) {
     return Case{input, Case::Success{expected}};
 }

 template <typename TO, typename FROM>
 Case Failure(FROM input) {
     return Case{input, Case::Failure{builder::CreatePtrsFor<TO>()}};
 }

 using ConstEvalBitcastTest = ConstEvalTestWithParam<Case>;

 TEST_P(ConstEvalBitcastTest, Test) {
     const auto& input = GetParam().input;
     const auto& expected = GetParam().expected;

     // Get the target type CreatePtrs
     builder::CreatePtrs target_create_ptrs;
     if (expected == tint::Success) {
         target_create_ptrs = expected.Get().value.create_ptrs;
     } else {
         target_create_ptrs = expected.Failure().create_ptrs;
     }

     auto target_ty = target_create_ptrs.ast(*this);
     ASSERT_NE(target_ty, nullptr);
     auto* input_val = input.Expr(*this);
     const ast::Expression* expr = Bitcast(Source{{12, 34}}, target_ty, input_val);

     WrapInFunction(expr);

     auto* target_sem_ty = target_create_ptrs.sem(*this);

     if (expected == tint::Success) {
         EXPECT_TRUE(r()->Resolve()) << r()->error();

         auto* sem = Sem().GetVal(expr);
         ASSERT_NE(sem, nullptr);
         EXPECT_TYPE(sem->Type(), target_sem_ty);
         ASSERT_NE(sem->ConstantValue(), nullptr);
         EXPECT_TYPE(sem->ConstantValue()->Type(), target_sem_ty);

         auto expected_values = expected.Get().value.args;
         auto got_values = ScalarsFrom(sem->ConstantValue());
         EXPECT_EQ(expected_values, got_values);
     } else {
         ASSERT_FALSE(r()->Resolve());
         EXPECT_THAT(r()->error(), testing::StartsWith("12:34 error:"));
         EXPECT_THAT(r()->error(), testing::HasSubstr("cannot be represented as"));
     }
 }

 const u32 nan_as_u32 = tint::Bitcast<u32>(std::numeric_limits<float>::quiet_NaN());
 const i32 nan_as_i32 = tint::Bitcast<i32>(std::numeric_limits<float>::quiet_NaN());
 const u32 inf_as_u32 = tint::Bitcast<u32>(std::numeric_limits<float>::infinity());
 const i32 inf_as_i32 = tint::Bitcast<i32>(std::numeric_limits<float>::infinity());
 const u32 neg_inf_as_u32 = tint::Bitcast<u32>(-std::numeric_limits<float>::infinity());
 const i32 neg_inf_as_i32 = tint::Bitcast<i32>(-std::numeric_limits<float>::infinity());
 const AInt u32_highest_plus_one = AInt(AInt(u32::kHighestValue).value + 1);
 const AInt i32_lowest_minus_one = AInt(AInt(i32::kLowestValue).value - 1);

 INSTANTIATE_TEST_SUITE_P(
     Bitcast,
     ConstEvalBitcastTest,
     testing::ValuesIn({
         // Bitcast to same (concrete) type, no change
         Success(Val(0_u), Val(0_u)),                        //
         Success(Val(0_i), Val(0_i)),                        //
         Success(Val(0_f), Val(0_f)),                        //
         Success(Val(123_u), Val(123_u)),                    //
         Success(Val(123_i), Val(123_i)),                    //
         Success(Val(123.456_f), Val(123.456_f)),            //
         Success(Val(u32::Highest()), Val(u32::Highest())),  //
         Success(Val(u32::Lowest()), Val(u32::Lowest())),    //
         Success(Val(i32::Highest()), Val(i32::Highest())),  //
         Success(Val(i32::Lowest()), Val(i32::Lowest())),    //
         Success(Val(f32::Highest()), Val(f32::Highest())),  //
         Success(Val(f32::Lowest()), Val(f32::Lowest())),    //

         // Bitcast to different type
         Success(Val(0_u), Val(0_i)),               //
         Success(Val(0_u), Val(0_f)),               //
         Success(Val(0_i), Val(0_u)),               //
         Success(Val(0_i), Val(0_f)),               //
         Success(Val(0.0_f), Val(0_i)),             //
         Success(Val(0.0_f), Val(0_u)),             //
         Success(Val(1_u), Val(1_i)),               //
         Success(Val(1_u), Val(1.4013e-45_f)),      //
         Success(Val(1_i), Val(1_u)),               //
         Success(Val(1_i), Val(1.4013e-45_f)),      //
         Success(Val(1.0_f), Val(0x3F800000_u)),    //
         Success(Val(1.0_f), Val(0x3F800000_i)),    //
         Success(Val(123_u), Val(123_i)),           //
         Success(Val(123_u), Val(1.7236e-43_f)),    //
         Success(Val(123_i), Val(123_u)),           //
         Success(Val(123_i), Val(1.7236e-43_f)),    //
         Success(Val(123.0_f), Val(0x42F60000_u)),  //
         Success(Val(123.0_f), Val(0x42F60000_i)),  //

         // Abstracts
         Success(Val(0_a), Val(0_i)),                                                  //
         Success(Val(0_a), Val(0_f)),                                                  //
         Success(Val(0_a), Val(0_u)),                                                  //
         Success(Val(0_a), Val(0_f)),                                                  //
         Success(Val(0_a), Val(0_i)),                                                  //
         Success(Val(0_a), Val(0_u)),                                                  //
         Success(Val(1_a), Val(1_i)),                                                  //
         Success(Val(1_a), Val(1.4013e-45_f)),                                         //
         Success(Val(1_a), Val(1_u)),                                                  //
         Success(Val(1_a), Val(1.4013e-45_f)),                                         //
         Success(Val(1.0_a), Val(0x3F800000_u)),                                       //
         Success(Val(1.0_a), Val(0x3F800000_i)),                                       //
         Success(Val(123_a), Val(123_i)),                                              //
         Success(Val(123_a), Val(1.7236e-43_f)),                                       //
         Success(Val(123_a), Val(123_u)),                                              //
         Success(Val(123_a), Val(1.7236e-43_f)),                                       //
         Success(Val(123.0_a), Val(0x42F60000_u)),                                     //
         Success(Val(123.0_a), Val(0x42F60000_i)),                                     //
         Success(Val(AInt(u32::Highest())), Val(u32::Highest())),                      //
         Success(Val(AInt(u32::Lowest())), Val(u32::Lowest())),                        //
         Success(Val(AInt(i32::Highest())), Val(tint::Bitcast<u32>(i32::Highest()))),  //
         Success(Val(AInt(i32::Lowest())), Val(tint::Bitcast<u32>(i32::Lowest()))),    //
         Success(Val(AInt(i32::Highest())), Val(i32::Highest())),                      //
         Success(Val(AInt(i32::Lowest())), Val(i32::Lowest())),                        //

         // u32 <-> i32 sign bit
         Success(Val(0xFFFFFFFF_u), Val(-1_i)),           //
         Success(Val(-1_i), Val(0xFFFFFFFF_u)),           //
         Success(Val(0x80000000_u), Val(i32::Lowest())),  //
         Success(Val(i32::Lowest()), Val(0x80000000_u)),  //

         // Vector tests
         Success(Vec(0_u, 1_u, 123_u), Vec(0_i, 1_i, 123_i)),
         Success(Vec(0.0_f, 1.0_f, 123.0_f), Vec(0_i, 0x3F800000_i, 0x42F60000_i)),
         Success(Vec(0xffffffff_a, -1_a), Vec(0xffffffff_u, 0xffffffff_u)),

         // Unrepresentable
         Failure<f32>(Val(nan_as_u32)),                 //
         Failure<f32>(Val(nan_as_i32)),                 //
         Failure<f32>(Val(inf_as_u32)),                 //
         Failure<f32>(Val(inf_as_i32)),                 //
         Failure<f32>(Val(neg_inf_as_u32)),             //
         Failure<f32>(Val(neg_inf_as_i32)),             //
         Failure<vec2<f32>>(Vec(nan_as_u32, 0_u)),      //
         Failure<vec2<f32>>(Vec(nan_as_i32, 0_i)),      //
         Failure<vec2<f32>>(Vec(inf_as_u32, 0_u)),      //
         Failure<vec2<f32>>(Vec(inf_as_i32, 0_i)),      //
         Failure<vec2<f32>>(Vec(neg_inf_as_u32, 0_u)),  //
         Failure<vec2<f32>>(Vec(neg_inf_as_i32, 0_i)),  //
         Failure<vec2<f32>>(Vec(0_u, nan_as_u32)),      //
         Failure<vec2<f32>>(Vec(0_i, nan_as_i32)),      //
         Failure<vec2<f32>>(Vec(0_u, inf_as_u32)),      //
         Failure<vec2<f32>>(Vec(0_i, inf_as_i32)),      //
         Failure<vec2<f32>>(Vec(0_u, neg_inf_as_u32)),  //
         Failure<vec2<f32>>(Vec(0_i, neg_inf_as_i32)),  //

         // Abstract too large
         Failure<u32>(Val(u32_highest_plus_one)),             //
         Failure<u32>(Val(i32_lowest_minus_one)),             //
         Failure<vec2<u32>>(Vec(0_a, u32_highest_plus_one)),  //
         Failure<vec2<u32>>(Vec(i32_lowest_minus_one, 0_a)),  //
     }));

 }  // namespace
 }  // namespace tint::core::constant::test
	// Copyright 2022 The Dawn & Tint Authors
	//
	// Redistribution and use in source and binary forms, with or without
	// modification, are permitted provided that the following conditions are met:
	//
	// 1. Redistributions of source code must retain the above copyright notice, this
	// list of conditions and the following disclaimer.
	//
	// 2. Redistributions in binary form must reproduce the above copyright notice,
	// this list of conditions and the following disclaimer in the documentation
	// and/or other materials provided with the distribution.
	//
	// 3. Neither the name of the copyright holder nor the names of its
	// contributors may be used to endorse or promote products derived from
	// this software without specific prior written permission.
	//
	// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
	// AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
	// IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
	// DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE
	// FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
	// DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR
	// SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER
	// CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,
	// OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
	// OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.

	#include "src/tint/lang/core/constant/eval_test.h"

	namespace tint::core::constant::test {
	namespace {

	using namespace tint::core::fluent_types; // NOLINT
	using namespace tint::core::number_suffixes; // NOLINT

	struct Case {
	Value input;
	struct Success {
	Value value;
	};
	struct Failure {
	builder::CreatePtrs create_ptrs;
	};
	tint::Result<Success, Failure> expected;
	};

	static std::ostream& operator<<(std::ostream& o, const Case& c) {
	o << "input: " << c.input;
	if (c.expected == Success) {
	o << ", expected: " << c.expected.Get().value;
	} else {
	o << ", expected failed bitcast to " << c.expected.Failure().create_ptrs;
	}
	return o;
	}

	template <typename TO, typename FROM>
	Case Success(FROM input, TO expected) {
	return Case{input, Case::Success{expected}};
	}

	template <typename TO, typename FROM>
	Case Failure(FROM input) {
	return Case{input, Case::Failure{builder::CreatePtrsFor<TO>()}};
	}

	using ConstEvalBitcastTest = ConstEvalTestWithParam<Case>;

	TEST_P(ConstEvalBitcastTest, Test) {
	const auto& input = GetParam().input;
	const auto& expected = GetParam().expected;

	// Get the target type CreatePtrs
	builder::CreatePtrs target_create_ptrs;
	if (expected == tint::Success) {
	target_create_ptrs = expected.Get().value.create_ptrs;
	} else {
	target_create_ptrs = expected.Failure().create_ptrs;
	}

	auto target_ty = target_create_ptrs.ast(*this);
	ASSERT_NE(target_ty, nullptr);
	auto* input_val = input.Expr(*this);
	const ast::Expression* expr = Bitcast(Source{{12, 34}}, target_ty, input_val);

	WrapInFunction(expr);

	auto* target_sem_ty = target_create_ptrs.sem(*this);

	if (expected == tint::Success) {
	EXPECT_TRUE(r()->Resolve()) << r()->error();

	auto* sem = Sem().GetVal(expr);
	ASSERT_NE(sem, nullptr);
	EXPECT_TYPE(sem->Type(), target_sem_ty);
	ASSERT_NE(sem->ConstantValue(), nullptr);
	EXPECT_TYPE(sem->ConstantValue()->Type(), target_sem_ty);

	auto expected_values = expected.Get().value.args;
	auto got_values = ScalarsFrom(sem->ConstantValue());
	EXPECT_EQ(expected_values, got_values);
	} else {
	ASSERT_FALSE(r()->Resolve());
	EXPECT_THAT(r()->error(), testing::StartsWith("12:34 error:"));
	EXPECT_THAT(r()->error(), testing::HasSubstr("cannot be represented as"));
	}
	}

	const u32 nan_as_u32 = tint::Bitcast<u32>(std::numeric_limits<float>::quiet_NaN());
	const i32 nan_as_i32 = tint::Bitcast<i32>(std::numeric_limits<float>::quiet_NaN());
	const u32 inf_as_u32 = tint::Bitcast<u32>(std::numeric_limits<float>::infinity());
	const i32 inf_as_i32 = tint::Bitcast<i32>(std::numeric_limits<float>::infinity());
	const u32 neg_inf_as_u32 = tint::Bitcast<u32>(-std::numeric_limits<float>::infinity());
	const i32 neg_inf_as_i32 = tint::Bitcast<i32>(-std::numeric_limits<float>::infinity());
	const AInt u32_highest_plus_one = AInt(AInt(u32::kHighestValue).value + 1);
	const AInt i32_lowest_minus_one = AInt(AInt(i32::kLowestValue).value - 1);

	INSTANTIATE_TEST_SUITE_P(
	Bitcast,
	ConstEvalBitcastTest,
	testing::ValuesIn({
	// Bitcast to same (concrete) type, no change
	Success(Val(0_u), Val(0_u)), //
	Success(Val(0_i), Val(0_i)), //
	Success(Val(0_f), Val(0_f)), //
	Success(Val(123_u), Val(123_u)), //
	Success(Val(123_i), Val(123_i)), //
	Success(Val(123.456_f), Val(123.456_f)), //
	Success(Val(u32::Highest()), Val(u32::Highest())), //
	Success(Val(u32::Lowest()), Val(u32::Lowest())), //
	Success(Val(i32::Highest()), Val(i32::Highest())), //
	Success(Val(i32::Lowest()), Val(i32::Lowest())), //
	Success(Val(f32::Highest()), Val(f32::Highest())), //
	Success(Val(f32::Lowest()), Val(f32::Lowest())), //

	// Bitcast to different type
	Success(Val(0_u), Val(0_i)), //
	Success(Val(0_u), Val(0_f)), //
	Success(Val(0_i), Val(0_u)), //
	Success(Val(0_i), Val(0_f)), //
	Success(Val(0.0_f), Val(0_i)), //
	Success(Val(0.0_f), Val(0_u)), //
	Success(Val(1_u), Val(1_i)), //
	Success(Val(1_u), Val(1.4013e-45_f)), //
	Success(Val(1_i), Val(1_u)), //
	Success(Val(1_i), Val(1.4013e-45_f)), //
	Success(Val(1.0_f), Val(0x3F800000_u)), //
	Success(Val(1.0_f), Val(0x3F800000_i)), //
	Success(Val(123_u), Val(123_i)), //
	Success(Val(123_u), Val(1.7236e-43_f)), //
	Success(Val(123_i), Val(123_u)), //
	Success(Val(123_i), Val(1.7236e-43_f)), //
	Success(Val(123.0_f), Val(0x42F60000_u)), //
	Success(Val(123.0_f), Val(0x42F60000_i)), //

	// Abstracts
	Success(Val(0_a), Val(0_i)), //
	Success(Val(0_a), Val(0_f)), //
	Success(Val(0_a), Val(0_u)), //
	Success(Val(0_a), Val(0_f)), //
	Success(Val(0_a), Val(0_i)), //
	Success(Val(0_a), Val(0_u)), //
	Success(Val(1_a), Val(1_i)), //
	Success(Val(1_a), Val(1.4013e-45_f)), //
	Success(Val(1_a), Val(1_u)), //
	Success(Val(1_a), Val(1.4013e-45_f)), //
	Success(Val(1.0_a), Val(0x3F800000_u)), //
	Success(Val(1.0_a), Val(0x3F800000_i)), //
	Success(Val(123_a), Val(123_i)), //
	Success(Val(123_a), Val(1.7236e-43_f)), //
	Success(Val(123_a), Val(123_u)), //
	Success(Val(123_a), Val(1.7236e-43_f)), //
	Success(Val(123.0_a), Val(0x42F60000_u)), //
	Success(Val(123.0_a), Val(0x42F60000_i)), //
	Success(Val(AInt(u32::Highest())), Val(u32::Highest())), //
	Success(Val(AInt(u32::Lowest())), Val(u32::Lowest())), //
	Success(Val(AInt(i32::Highest())), Val(tint::Bitcast<u32>(i32::Highest()))), //
	Success(Val(AInt(i32::Lowest())), Val(tint::Bitcast<u32>(i32::Lowest()))), //
	Success(Val(AInt(i32::Highest())), Val(i32::Highest())), //
	Success(Val(AInt(i32::Lowest())), Val(i32::Lowest())), //

	// u32 <-> i32 sign bit
	Success(Val(0xFFFFFFFF_u), Val(-1_i)), //
	Success(Val(-1_i), Val(0xFFFFFFFF_u)), //
	Success(Val(0x80000000_u), Val(i32::Lowest())), //
	Success(Val(i32::Lowest()), Val(0x80000000_u)), //

	// Vector tests
	Success(Vec(0_u, 1_u, 123_u), Vec(0_i, 1_i, 123_i)),
	Success(Vec(0.0_f, 1.0_f, 123.0_f), Vec(0_i, 0x3F800000_i, 0x42F60000_i)),
	Success(Vec(0xffffffff_a, -1_a), Vec(0xffffffff_u, 0xffffffff_u)),

	// Unrepresentable
	Failure<f32>(Val(nan_as_u32)), //
	Failure<f32>(Val(nan_as_i32)), //
	Failure<f32>(Val(inf_as_u32)), //
	Failure<f32>(Val(inf_as_i32)), //
	Failure<f32>(Val(neg_inf_as_u32)), //
	Failure<f32>(Val(neg_inf_as_i32)), //
	Failure<vec2<f32>>(Vec(nan_as_u32, 0_u)), //
	Failure<vec2<f32>>(Vec(nan_as_i32, 0_i)), //
	Failure<vec2<f32>>(Vec(inf_as_u32, 0_u)), //
	Failure<vec2<f32>>(Vec(inf_as_i32, 0_i)), //
	Failure<vec2<f32>>(Vec(neg_inf_as_u32, 0_u)), //
	Failure<vec2<f32>>(Vec(neg_inf_as_i32, 0_i)), //
	Failure<vec2<f32>>(Vec(0_u, nan_as_u32)), //
	Failure<vec2<f32>>(Vec(0_i, nan_as_i32)), //
	Failure<vec2<f32>>(Vec(0_u, inf_as_u32)), //
	Failure<vec2<f32>>(Vec(0_i, inf_as_i32)), //
	Failure<vec2<f32>>(Vec(0_u, neg_inf_as_u32)), //
	Failure<vec2<f32>>(Vec(0_i, neg_inf_as_i32)), //

	// Abstract too large
	Failure<u32>(Val(u32_highest_plus_one)), //
	Failure<u32>(Val(i32_lowest_minus_one)), //
	Failure<vec2<u32>>(Vec(0_a, u32_highest_plus_one)), //
	Failure<vec2<u32>>(Vec(i32_lowest_minus_one, 0_a)), //
	}));

	} // namespace
	} // namespace tint::core::constant::test