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// Copyright 2023 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"
#include "src/tint/constant/scalar.h"
using namespace tint::number_suffixes; // NOLINT
namespace tint::resolver {
namespace {
class ResolverConstEvalRuntimeSemanticsTest : public ResolverConstEvalTest {
protected:
/// Default constructor.
ResolverConstEvalRuntimeSemanticsTest()
: const_eval(ConstEval(*this, /* use_runtime_semantics */ true)) {}
/// The ConstEval object used during testing (has runtime semantics enabled).
ConstEval const_eval;
/// @returns the contents of the diagnostics list as a string
std::string error() {
diag::Formatter::Style style{};
style.print_newline_at_end = false;
diag::Formatter formatter{style};
return formatter.format(Diagnostics());
}
/// Helper to make a scalar constant::Value from a value.
template <typename T>
const constant::Value* Scalar(T value) {
if constexpr (IsAbstract<T>) {
if constexpr (IsFloatingPoint<T>) {
return create<constant::Scalar<AFloat>>(create<type::AbstractFloat>(), value);
} else if constexpr (IsIntegral<T>) {
return create<constant::Scalar<AInt>>(create<type::AbstractInt>(), value);
}
} else if constexpr (IsFloatingPoint<T>) {
return create<constant::Scalar<f32>>(create<type::F32>(), value);
} else if constexpr (IsSignedIntegral<T>) {
return create<constant::Scalar<i32>>(create<type::I32>(), value);
} else if constexpr (IsUnsignedIntegral<T>) {
return create<constant::Scalar<u32>>(create<type::U32>(), value);
}
}
};
TEST_F(ResolverConstEvalRuntimeSemanticsTest, Add_AInt_Overflow) {
auto* a = Scalar(AInt::Highest());
auto* b = Scalar(AInt(1));
auto result = const_eval.OpPlus(a->Type(), utils::Vector{a, b}, {});
ASSERT_TRUE(result);
EXPECT_EQ(result.Get()->ValueAs<AInt>(), 0);
EXPECT_EQ(error(),
R"(warning: '9223372036854775807 + 1' cannot be represented as 'abstract-int')");
}
TEST_F(ResolverConstEvalRuntimeSemanticsTest, Add_AFloat_Overflow) {
auto* a = Scalar(AFloat::Highest());
auto* b = Scalar(AFloat::Highest());
auto result = const_eval.OpPlus(a->Type(), utils::Vector{a, b}, {});
ASSERT_TRUE(result);
EXPECT_EQ(result.Get()->ValueAs<AFloat>(), 0.f);
EXPECT_EQ(
error(),
R"(warning: '1.7976931348623157081e+308 + 1.7976931348623157081e+308' cannot be represented as 'abstract-float')");
}
TEST_F(ResolverConstEvalRuntimeSemanticsTest, Add_F32_Overflow) {
auto* a = Scalar(f32::Highest());
auto* b = Scalar(f32::Highest());
auto result = const_eval.OpPlus(a->Type(), utils::Vector{a, b}, {});
ASSERT_TRUE(result);
EXPECT_EQ(result.Get()->ValueAs<f32>(), 0.f);
EXPECT_EQ(
error(),
R"(warning: '3.4028234663852885981e+38 + 3.4028234663852885981e+38' cannot be represented as 'f32')");
}
TEST_F(ResolverConstEvalRuntimeSemanticsTest, Sub_AInt_Overflow) {
auto* a = Scalar(AInt::Lowest());
auto* b = Scalar(AInt(1));
auto result = const_eval.OpMinus(a->Type(), utils::Vector{a, b}, {});
ASSERT_TRUE(result);
EXPECT_EQ(result.Get()->ValueAs<AInt>(), 0);
EXPECT_EQ(error(),
R"(warning: '-9223372036854775808 - 1' cannot be represented as 'abstract-int')");
}
TEST_F(ResolverConstEvalRuntimeSemanticsTest, Sub_AFloat_Overflow) {
auto* a = Scalar(AFloat::Lowest());
auto* b = Scalar(AFloat::Highest());
auto result = const_eval.OpMinus(a->Type(), utils::Vector{a, b}, {});
ASSERT_TRUE(result);
EXPECT_EQ(result.Get()->ValueAs<AFloat>(), 0.f);
EXPECT_EQ(
error(),
R"(warning: '-1.7976931348623157081e+308 - 1.7976931348623157081e+308' cannot be represented as 'abstract-float')");
}
TEST_F(ResolverConstEvalRuntimeSemanticsTest, Sub_F32_Overflow) {
auto* a = Scalar(f32::Lowest());
auto* b = Scalar(f32::Highest());
auto result = const_eval.OpMinus(a->Type(), utils::Vector{a, b}, {});
ASSERT_TRUE(result);
EXPECT_EQ(result.Get()->ValueAs<f32>(), 0.f);
EXPECT_EQ(
error(),
R"(warning: '-3.4028234663852885981e+38 - 3.4028234663852885981e+38' cannot be represented as 'f32')");
}
TEST_F(ResolverConstEvalRuntimeSemanticsTest, Mul_AInt_Overflow) {
auto* a = Scalar(AInt::Highest());
auto* b = Scalar(AInt(2));
auto result = const_eval.OpMultiply(a->Type(), utils::Vector{a, b}, {});
ASSERT_TRUE(result);
EXPECT_EQ(result.Get()->ValueAs<AInt>(), 0);
EXPECT_EQ(error(),
R"(warning: '9223372036854775807 * 2' cannot be represented as 'abstract-int')");
}
TEST_F(ResolverConstEvalRuntimeSemanticsTest, Mul_AFloat_Overflow) {
auto* a = Scalar(AFloat::Highest());
auto* b = Scalar(AFloat::Highest());
auto result = const_eval.OpMultiply(a->Type(), utils::Vector{a, b}, {});
ASSERT_TRUE(result);
EXPECT_EQ(result.Get()->ValueAs<AFloat>(), 0.f);
EXPECT_EQ(
error(),
R"(warning: '1.7976931348623157081e+308 * 1.7976931348623157081e+308' cannot be represented as 'abstract-float')");
}
TEST_F(ResolverConstEvalRuntimeSemanticsTest, Mul_F32_Overflow) {
auto* a = Scalar(f32::Highest());
auto* b = Scalar(f32::Highest());
auto result = const_eval.OpMultiply(a->Type(), utils::Vector{a, b}, {});
ASSERT_TRUE(result);
EXPECT_EQ(result.Get()->ValueAs<f32>(), 0.f);
EXPECT_EQ(
error(),
R"(warning: '3.4028234663852885981e+38 * 3.4028234663852885981e+38' cannot be represented as 'f32')");
}
TEST_F(ResolverConstEvalRuntimeSemanticsTest, Div_AInt_ZeroDenominator) {
auto* a = Scalar(AInt(42));
auto* b = Scalar(AInt(0));
auto result = const_eval.OpDivide(a->Type(), utils::Vector{a, b}, {});
ASSERT_TRUE(result);
EXPECT_EQ(result.Get()->ValueAs<AInt>(), 42);
EXPECT_EQ(error(), R"(warning: '42 / 0' cannot be represented as 'abstract-int')");
}
TEST_F(ResolverConstEvalRuntimeSemanticsTest, Div_I32_ZeroDenominator) {
auto* a = Scalar(i32(42));
auto* b = Scalar(i32(0));
auto result = const_eval.OpDivide(a->Type(), utils::Vector{a, b}, {});
ASSERT_TRUE(result);
EXPECT_EQ(result.Get()->ValueAs<i32>(), 42);
EXPECT_EQ(error(), R"(warning: '42 / 0' cannot be represented as 'i32')");
}
TEST_F(ResolverConstEvalRuntimeSemanticsTest, Div_U32_ZeroDenominator) {
auto* a = Scalar(u32(42));
auto* b = Scalar(u32(0));
auto result = const_eval.OpDivide(a->Type(), utils::Vector{a, b}, {});
ASSERT_TRUE(result);
EXPECT_EQ(result.Get()->ValueAs<u32>(), 42);
EXPECT_EQ(error(), R"(warning: '42 / 0' cannot be represented as 'u32')");
}
TEST_F(ResolverConstEvalRuntimeSemanticsTest, Div_AFloat_ZeroDenominator) {
auto* a = Scalar(AFloat(42));
auto* b = Scalar(AFloat(0));
auto result = const_eval.OpDivide(a->Type(), utils::Vector{a, b}, {});
ASSERT_TRUE(result);
EXPECT_EQ(result.Get()->ValueAs<AFloat>(), 42.f);
EXPECT_EQ(error(), R"(warning: '42 / 0' cannot be represented as 'abstract-float')");
}
TEST_F(ResolverConstEvalRuntimeSemanticsTest, Div_F32_ZeroDenominator) {
auto* a = Scalar(f32(42));
auto* b = Scalar(f32(0));
auto result = const_eval.OpDivide(a->Type(), utils::Vector{a, b}, {});
ASSERT_TRUE(result);
EXPECT_EQ(result.Get()->ValueAs<f32>(), 42.f);
EXPECT_EQ(error(), R"(warning: '42 / 0' cannot be represented as 'f32')");
}
TEST_F(ResolverConstEvalRuntimeSemanticsTest, Div_I32_MostNegativeByMinInt) {
auto* a = Scalar(i32::Lowest());
auto* b = Scalar(i32(-1));
auto result = const_eval.OpDivide(a->Type(), utils::Vector{a, b}, {});
ASSERT_TRUE(result);
EXPECT_EQ(result.Get()->ValueAs<i32>(), i32::Lowest());
EXPECT_EQ(error(), R"(warning: '-2147483648 / -1' cannot be represented as 'i32')");
}
TEST_F(ResolverConstEvalRuntimeSemanticsTest, Mod_AInt_ZeroDenominator) {
auto* a = Scalar(AInt(42));
auto* b = Scalar(AInt(0));
auto result = const_eval.OpModulo(a->Type(), utils::Vector{a, b}, {});
ASSERT_TRUE(result);
EXPECT_EQ(result.Get()->ValueAs<AInt>(), 42);
EXPECT_EQ(error(), R"(warning: '42 % 0' cannot be represented as 'abstract-int')");
}
TEST_F(ResolverConstEvalRuntimeSemanticsTest, Mod_I32_ZeroDenominator) {
auto* a = Scalar(i32(42));
auto* b = Scalar(i32(0));
auto result = const_eval.OpModulo(a->Type(), utils::Vector{a, b}, {});
ASSERT_TRUE(result);
EXPECT_EQ(result.Get()->ValueAs<i32>(), 42);
EXPECT_EQ(error(), R"(warning: '42 % 0' cannot be represented as 'i32')");
}
TEST_F(ResolverConstEvalRuntimeSemanticsTest, Mod_U32_ZeroDenominator) {
auto* a = Scalar(u32(42));
auto* b = Scalar(u32(0));
auto result = const_eval.OpModulo(a->Type(), utils::Vector{a, b}, {});
ASSERT_TRUE(result);
EXPECT_EQ(result.Get()->ValueAs<u32>(), 42);
EXPECT_EQ(error(), R"(warning: '42 % 0' cannot be represented as 'u32')");
}
TEST_F(ResolverConstEvalRuntimeSemanticsTest, Mod_AFloat_ZeroDenominator) {
auto* a = Scalar(AFloat(42));
auto* b = Scalar(AFloat(0));
auto result = const_eval.OpModulo(a->Type(), utils::Vector{a, b}, {});
ASSERT_TRUE(result);
EXPECT_EQ(result.Get()->ValueAs<AFloat>(), 42.f);
EXPECT_EQ(error(), R"(warning: '42 % 0' cannot be represented as 'abstract-float')");
}
TEST_F(ResolverConstEvalRuntimeSemanticsTest, Mod_F32_ZeroDenominator) {
auto* a = Scalar(f32(42));
auto* b = Scalar(f32(0));
auto result = const_eval.OpModulo(a->Type(), utils::Vector{a, b}, {});
ASSERT_TRUE(result);
EXPECT_EQ(result.Get()->ValueAs<f32>(), 42.f);
EXPECT_EQ(error(), R"(warning: '42 % 0' cannot be represented as 'f32')");
}
TEST_F(ResolverConstEvalRuntimeSemanticsTest, Mod_I32_MostNegativeByMinInt) {
auto* a = Scalar(i32::Lowest());
auto* b = Scalar(i32(-1));
auto result = const_eval.OpModulo(a->Type(), utils::Vector{a, b}, {});
ASSERT_TRUE(result);
EXPECT_EQ(result.Get()->ValueAs<i32>(), i32::Lowest());
EXPECT_EQ(error(), R"(warning: '-2147483648 % -1' cannot be represented as 'i32')");
}
TEST_F(ResolverConstEvalRuntimeSemanticsTest, ShiftLeft_AInt_SignChange) {
auto* a = Scalar(AInt(0x0FFFFFFFFFFFFFFFll));
auto* b = Scalar(u32(9));
auto result = const_eval.OpShiftLeft(a->Type(), utils::Vector{a, b}, {});
ASSERT_TRUE(result);
EXPECT_EQ(result.Get()->ValueAs<AInt>(), static_cast<AInt>(0x0FFFFFFFFFFFFFFFull << 9));
EXPECT_EQ(error(), R"(warning: shift left operation results in sign change)");
}
TEST_F(ResolverConstEvalRuntimeSemanticsTest, ShiftLeft_I32_SignChange) {
auto* a = Scalar(i32(0x0FFFFFFF));
auto* b = Scalar(u32(9));
auto result = const_eval.OpShiftLeft(a->Type(), utils::Vector{a, b}, {});
ASSERT_TRUE(result);
EXPECT_EQ(result.Get()->ValueAs<i32>(), static_cast<i32>(0x0FFFFFFFu << 9));
EXPECT_EQ(error(), R"(warning: shift left operation results in sign change)");
}
TEST_F(ResolverConstEvalRuntimeSemanticsTest, ShiftLeft_I32_MoreThanBitWidth) {
auto* a = Scalar(i32(0x1));
auto* b = Scalar(u32(33));
auto result = const_eval.OpShiftLeft(a->Type(), utils::Vector{a, b}, {});
ASSERT_TRUE(result);
EXPECT_EQ(result.Get()->ValueAs<i32>(), 2);
EXPECT_EQ(
error(),
R"(warning: shift left value must be less than the bit width of the lhs, which is 32)");
}
TEST_F(ResolverConstEvalRuntimeSemanticsTest, ShiftLeft_U32_MoreThanBitWidth) {
auto* a = Scalar(u32(0x1));
auto* b = Scalar(u32(33));
auto result = const_eval.OpShiftLeft(a->Type(), utils::Vector{a, b}, {});
ASSERT_TRUE(result);
EXPECT_EQ(result.Get()->ValueAs<u32>(), 2);
EXPECT_EQ(
error(),
R"(warning: shift left value must be less than the bit width of the lhs, which is 32)");
}
TEST_F(ResolverConstEvalRuntimeSemanticsTest, ShiftRight_I32_MoreThanBitWidth) {
auto* a = Scalar(i32(0x2));
auto* b = Scalar(u32(33));
auto result = const_eval.OpShiftRight(a->Type(), utils::Vector{a, b}, {});
ASSERT_TRUE(result);
EXPECT_EQ(result.Get()->ValueAs<i32>(), 1);
EXPECT_EQ(
error(),
R"(warning: shift right value must be less than the bit width of the lhs, which is 32)");
}
TEST_F(ResolverConstEvalRuntimeSemanticsTest, ShiftRight_U32_MoreThanBitWidth) {
auto* a = Scalar(u32(0x2));
auto* b = Scalar(u32(33));
auto result = const_eval.OpShiftRight(a->Type(), utils::Vector{a, b}, {});
ASSERT_TRUE(result);
EXPECT_EQ(result.Get()->ValueAs<u32>(), 1);
EXPECT_EQ(
error(),
R"(warning: shift right value must be less than the bit width of the lhs, which is 32)");
}
TEST_F(ResolverConstEvalRuntimeSemanticsTest, Acos_F32_OutOfRange) {
auto* a = Scalar(f32(2));
auto result = const_eval.acos(a->Type(), utils::Vector{a}, {});
ASSERT_TRUE(result);
EXPECT_EQ(result.Get()->ValueAs<f32>(), 0.f);
EXPECT_EQ(error(),
R"(warning: acos must be called with a value in the range [-1 .. 1] (inclusive))");
}
TEST_F(ResolverConstEvalRuntimeSemanticsTest, Acosh_F32_OutOfRange) {
auto* a = Scalar(f32(-1));
auto result = const_eval.acosh(a->Type(), utils::Vector{a}, {});
ASSERT_TRUE(result);
EXPECT_EQ(result.Get()->ValueAs<f32>(), 0.f);
EXPECT_EQ(error(), R"(warning: acosh must be called with a value >= 1.0)");
}
TEST_F(ResolverConstEvalRuntimeSemanticsTest, Asin_F32_OutOfRange) {
auto* a = Scalar(f32(2));
auto result = const_eval.asin(a->Type(), utils::Vector{a}, {});
ASSERT_TRUE(result);
EXPECT_EQ(result.Get()->ValueAs<f32>(), 0.f);
EXPECT_EQ(error(),
R"(warning: asin must be called with a value in the range [-1 .. 1] (inclusive))");
}
TEST_F(ResolverConstEvalRuntimeSemanticsTest, Atanh_F32_OutOfRange) {
auto* a = Scalar(f32(2));
auto result = const_eval.atanh(a->Type(), utils::Vector{a}, {});
ASSERT_TRUE(result);
EXPECT_EQ(result.Get()->ValueAs<f32>(), 0.f);
EXPECT_EQ(error(),
R"(warning: atanh must be called with a value in the range (-1 .. 1) (exclusive))");
}
TEST_F(ResolverConstEvalRuntimeSemanticsTest, Exp_F32_Overflow) {
auto* a = Scalar(f32(1000));
auto result = const_eval.exp(a->Type(), utils::Vector{a}, {});
ASSERT_TRUE(result);
EXPECT_EQ(result.Get()->ValueAs<f32>(), 0.f);
EXPECT_EQ(error(), R"(warning: e^1000 cannot be represented as 'f32')");
}
TEST_F(ResolverConstEvalRuntimeSemanticsTest, Exp2_F32_Overflow) {
auto* a = Scalar(f32(1000));
auto result = const_eval.exp2(a->Type(), utils::Vector{a}, {});
ASSERT_TRUE(result);
EXPECT_EQ(result.Get()->ValueAs<f32>(), 0.f);
EXPECT_EQ(error(), R"(warning: 2^1000 cannot be represented as 'f32')");
}
TEST_F(ResolverConstEvalRuntimeSemanticsTest, ExtractBits_I32_TooManyBits) {
auto* a = Scalar(i32(0x12345678));
auto* offset = Scalar(u32(24));
auto* count = Scalar(u32(16));
auto result = const_eval.extractBits(a->Type(), utils::Vector{a, offset, count}, {});
ASSERT_TRUE(result);
EXPECT_EQ(result.Get()->ValueAs<i32>(), 0x12);
EXPECT_EQ(error(),
R"(warning: 'offset + 'count' must be less than or equal to the bit width of 'e')");
}
TEST_F(ResolverConstEvalRuntimeSemanticsTest, ExtractBits_U32_TooManyBits) {
auto* a = Scalar(u32(0x12345678));
auto* offset = Scalar(u32(24));
auto* count = Scalar(u32(16));
auto result = const_eval.extractBits(a->Type(), utils::Vector{a, offset, count}, {});
ASSERT_TRUE(result);
EXPECT_EQ(result.Get()->ValueAs<u32>(), 0x12);
EXPECT_EQ(error(),
R"(warning: 'offset + 'count' must be less than or equal to the bit width of 'e')");
}
TEST_F(ResolverConstEvalRuntimeSemanticsTest, InsertBits_I32_TooManyBits) {
auto* a = Scalar(i32(0x99345678));
auto* b = Scalar(i32(0x12));
auto* offset = Scalar(u32(24));
auto* count = Scalar(u32(16));
auto result = const_eval.insertBits(a->Type(), utils::Vector{a, b, offset, count}, {});
ASSERT_TRUE(result);
EXPECT_EQ(result.Get()->ValueAs<i32>(), 0x12345678);
EXPECT_EQ(error(),
R"(warning: 'offset + 'count' must be less than or equal to the bit width of 'e')");
}
TEST_F(ResolverConstEvalRuntimeSemanticsTest, InsertBits_U32_TooManyBits) {
auto* a = Scalar(u32(0x99345678));
auto* b = Scalar(u32(0x12));
auto* offset = Scalar(u32(24));
auto* count = Scalar(u32(16));
auto result = const_eval.insertBits(a->Type(), utils::Vector{a, b, offset, count}, {});
ASSERT_TRUE(result);
EXPECT_EQ(result.Get()->ValueAs<u32>(), 0x12345678);
EXPECT_EQ(error(),
R"(warning: 'offset + 'count' must be less than or equal to the bit width of 'e')");
}
TEST_F(ResolverConstEvalRuntimeSemanticsTest, InverseSqrt_F32_OutOfRange) {
auto* a = Scalar(f32(-1));
auto result = const_eval.inverseSqrt(a->Type(), utils::Vector{a}, {});
ASSERT_TRUE(result);
EXPECT_EQ(result.Get()->ValueAs<f32>(), 0.f);
EXPECT_EQ(error(), R"(warning: inverseSqrt must be called with a value > 0)");
}
TEST_F(ResolverConstEvalRuntimeSemanticsTest, LDExpr_F32_OutOfRange) {
auto* a = Scalar(f32(42.f));
auto* b = Scalar(f32(200));
auto result = const_eval.ldexp(a->Type(), utils::Vector{a, b}, {});
ASSERT_TRUE(result);
EXPECT_EQ(result.Get()->ValueAs<f32>(), 0.f);
EXPECT_EQ(error(), R"(warning: e2 must be less than or equal to 128)");
}
TEST_F(ResolverConstEvalRuntimeSemanticsTest, Log_F32_OutOfRange) {
auto* a = Scalar(f32(-1));
auto result = const_eval.log(a->Type(), utils::Vector{a}, {});
ASSERT_TRUE(result);
EXPECT_EQ(result.Get()->ValueAs<f32>(), 0.f);
EXPECT_EQ(error(), R"(warning: log must be called with a value > 0)");
}
TEST_F(ResolverConstEvalRuntimeSemanticsTest, Log2_F32_OutOfRange) {
auto* a = Scalar(f32(-1));
auto result = const_eval.log2(a->Type(), utils::Vector{a}, {});
ASSERT_TRUE(result);
EXPECT_EQ(result.Get()->ValueAs<f32>(), 0.f);
EXPECT_EQ(error(), R"(warning: log2 must be called with a value > 0)");
}
TEST_F(ResolverConstEvalRuntimeSemanticsTest, Normalize_ZeroLength) {
auto* zero = Scalar(f32(0));
auto* vec =
const_eval.VecSplat(create<type::Vector>(create<type::F32>(), 4u), utils::Vector{zero}, {})
.Get();
auto result = const_eval.normalize(vec->Type(), utils::Vector{vec}, {});
ASSERT_TRUE(result);
EXPECT_EQ(result.Get()->Index(0)->ValueAs<f32>(), 0.f);
EXPECT_EQ(result.Get()->Index(1)->ValueAs<f32>(), 0.f);
EXPECT_EQ(result.Get()->Index(2)->ValueAs<f32>(), 0.f);
EXPECT_EQ(result.Get()->Index(3)->ValueAs<f32>(), 0.f);
EXPECT_EQ(error(), R"(warning: zero length vector can not be normalized)");
}
TEST_F(ResolverConstEvalRuntimeSemanticsTest, Pack2x16Float_OutOfRange) {
auto* a = Scalar(f32(75250.f));
auto* b = Scalar(f32(42.1f));
auto* vec =
const_eval.VecInitS(create<type::Vector>(create<type::F32>(), 2u), utils::Vector{a, b}, {})
.Get();
auto result = const_eval.pack2x16float(create<type::U32>(), utils::Vector{vec}, {});
ASSERT_TRUE(result);
EXPECT_EQ(result.Get()->ValueAs<u32>(), 0x51430000);
EXPECT_EQ(error(), R"(warning: value 75250 cannot be represented as 'f16')");
}
TEST_F(ResolverConstEvalRuntimeSemanticsTest, Pow_F32_Overflow) {
auto* a = Scalar(f32(2));
auto* b = Scalar(f32(1000));
auto result = const_eval.pow(a->Type(), utils::Vector{a, b}, {});
ASSERT_TRUE(result);
EXPECT_EQ(result.Get()->ValueAs<f32>(), 0.f);
EXPECT_EQ(error(), R"(warning: '2 ^ 1000' cannot be represented as 'f32')");
}
TEST_F(ResolverConstEvalRuntimeSemanticsTest, Unpack2x16Float_OutOfRange) {
auto* a = Scalar(u32(0x51437C00));
auto result = const_eval.unpack2x16float(create<type::U32>(), utils::Vector{a}, {});
ASSERT_TRUE(result);
EXPECT_FLOAT_EQ(result.Get()->Index(0)->ValueAs<f32>(), 0.f);
EXPECT_FLOAT_EQ(result.Get()->Index(1)->ValueAs<f32>(), 42.09375f);
EXPECT_EQ(error(), R"(warning: value inf cannot be represented as 'f32')");
}
TEST_F(ResolverConstEvalRuntimeSemanticsTest, QuantizeToF16_OutOfRange) {
auto* a = Scalar(f32(75250.f));
auto result = const_eval.quantizeToF16(create<type::U32>(), utils::Vector{a}, {});
ASSERT_TRUE(result);
EXPECT_EQ(result.Get()->ValueAs<u32>(), 0);
EXPECT_EQ(error(), R"(warning: value 75250 cannot be represented as 'f16')");
}
TEST_F(ResolverConstEvalRuntimeSemanticsTest, Sqrt_F32_OutOfRange) {
auto* a = Scalar(f32(-1));
auto result = const_eval.sqrt(a->Type(), utils::Vector{a}, {});
ASSERT_TRUE(result);
EXPECT_EQ(result.Get()->ValueAs<f32>(), 0.f);
EXPECT_EQ(error(), R"(warning: sqrt must be called with a value >= 0)");
}
TEST_F(ResolverConstEvalRuntimeSemanticsTest, Bitcast_Infinity) {
auto* a = Scalar(u32(0x7F800000));
auto result = const_eval.Bitcast(create<type::F32>(), a, {});
ASSERT_TRUE(result);
EXPECT_EQ(result.Get()->ValueAs<f32>(), 0.f);
EXPECT_EQ(error(), R"(warning: value inf cannot be represented as 'f32')");
}
TEST_F(ResolverConstEvalRuntimeSemanticsTest, Bitcast_NaN) {
auto* a = Scalar(u32(0x7FC00000));
auto result = const_eval.Bitcast(create<type::F32>(), a, {});
ASSERT_TRUE(result);
EXPECT_EQ(result.Get()->ValueAs<f32>(), 0.f);
EXPECT_EQ(error(), R"(warning: value nan cannot be represented as 'f32')");
}
TEST_F(ResolverConstEvalRuntimeSemanticsTest, Convert_F32_TooHigh) {
auto* a = Scalar(AFloat::Highest());
auto result = const_eval.Convert(create<type::F32>(), a, {});
ASSERT_TRUE(result);
EXPECT_EQ(result.Get()->ValueAs<f32>(), f32::kHighestValue);
EXPECT_EQ(error(),
R"(warning: value 1.7976931348623157081e+308 cannot be represented as 'f32')");
}
TEST_F(ResolverConstEvalRuntimeSemanticsTest, Convert_F32_TooLow) {
auto* a = Scalar(AFloat::Lowest());
auto result = const_eval.Convert(create<type::F32>(), a, {});
ASSERT_TRUE(result);
EXPECT_EQ(result.Get()->ValueAs<f32>(), f32::kLowestValue);
EXPECT_EQ(error(),
R"(warning: value -1.7976931348623157081e+308 cannot be represented as 'f32')");
}
TEST_F(ResolverConstEvalRuntimeSemanticsTest, Convert_F16_TooHigh) {
auto* a = Scalar(f32(1000000.0));
auto result = const_eval.Convert(create<type::F16>(), a, {});
ASSERT_TRUE(result);
EXPECT_EQ(result.Get()->ValueAs<f32>(), f16::kHighestValue);
EXPECT_EQ(error(), R"(warning: value 1000000 cannot be represented as 'f16')");
}
TEST_F(ResolverConstEvalRuntimeSemanticsTest, Convert_F16_TooLow) {
auto* a = Scalar(f32(-1000000.0));
auto result = const_eval.Convert(create<type::F16>(), a, {});
ASSERT_TRUE(result);
EXPECT_EQ(result.Get()->ValueAs<f32>(), f16::kLowestValue);
EXPECT_EQ(error(), R"(warning: value -1000000 cannot be represented as 'f16')");
}
TEST_F(ResolverConstEvalRuntimeSemanticsTest, Vec_Overflow_SingleComponent) {
// Test that overflow for an element-wise vector operation only affects a single component.
auto* vec4f = create<type::Vector>(create<type::F32>(), 4u);
auto* a = const_eval
.VecInitS(vec4f,
utils::Vector{
Scalar(f32(1)),
Scalar(f32(4)),
Scalar(f32(-1)),
Scalar(f32(65536)),
},
{})
.Get();
auto result = const_eval.sqrt(a->Type(), utils::Vector{a}, {});
ASSERT_TRUE(result);
EXPECT_EQ(result.Get()->Index(0)->ValueAs<f32>(), 1);
EXPECT_EQ(result.Get()->Index(1)->ValueAs<f32>(), 2);
EXPECT_EQ(result.Get()->Index(2)->ValueAs<f32>(), 0);
EXPECT_EQ(result.Get()->Index(3)->ValueAs<f32>(), 256);
EXPECT_EQ(error(), R"(warning: sqrt must be called with a value >= 0)");
}
} // namespace
} // namespace tint::resolver