#region CPL License
/*
Nuclex Framework
Copyright (C) 2002-2017 Nuclex Development Labs
This library is free software; you can redistribute it and/or
modify it under the terms of the IBM Common Public License as
published by the IBM Corporation; either version 1.0 of the
License, or (at your option) any later version.
This library is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
IBM Common Public License for more details.
You should have received a copy of the IBM Common Public
License along with this library
*/
#endregion
#if UNITTEST
using System;
using System.Collections.Generic;
using NUnit.Framework;
namespace Nuclex.Support {
/// Unit Test for the FloatHelper class
[TestFixture]
internal class FloatHelperTest {
/// Tests the floating point value comparison helper
[Test]
public void UlpDistancesOnFloatsCompareAsEqual() {
Assert.IsTrue(
FloatHelper.AreAlmostEqual(0.00000001f, 0.0000000100000008f, 1),
"Minimal difference between very small floating point numbers is considered equal"
);
Assert.IsFalse(
FloatHelper.AreAlmostEqual(0.00000001f, 0.0000000100000017f, 1),
"Larger difference between very small floating point numbers is not considered equal"
);
Assert.IsTrue(
FloatHelper.AreAlmostEqual(1000000.00f, 1000000.06f, 1),
"Minimal difference between very large floating point numbers is considered equal"
);
Assert.IsFalse(
FloatHelper.AreAlmostEqual(1000000.00f, 1000000.13f, 1),
"Larger difference between very large floating point numbers is not considered equal"
);
}
/// Tests the double precision floating point value comparison helper
[Test]
public void UlpDistancesOnDoublesCompareAsEqual() {
Assert.IsTrue(
FloatHelper.AreAlmostEqual(0.00000001, 0.000000010000000000000002, 1),
"Minimal difference between very small double precision floating point " +
"numbers is considered equal"
);
Assert.IsFalse(
FloatHelper.AreAlmostEqual(0.00000001, 0.000000010000000000000004, 1),
"Larger difference between very small double precision floating point " +
"numbers is not considered equal"
);
Assert.IsTrue(
FloatHelper.AreAlmostEqual(1000000.00, 1000000.0000000001, 1),
"Minimal difference between very large double precision floating point " +
"numbers is considered equal"
);
Assert.IsFalse(
FloatHelper.AreAlmostEqual(1000000.00, 1000000.0000000002, 1),
"Larger difference between very large double precision floating point " +
"numbers is not considered equal"
);
}
/// Tests the integer reinterpretation functions
[Test]
public void IntegersCanBeReinterpretedAsFloats() {
Assert.AreEqual(
12345.0f,
FloatHelper.ReinterpretAsFloat(FloatHelper.ReinterpretAsInt(12345.0f)),
"Number hasn't changed after mirrored reinterpretation"
);
}
/// Tests the long reinterpretation functions
[Test]
public void LongsCanBeReinterpretedAsDoubles() {
Assert.AreEqual(
12345.67890,
FloatHelper.ReinterpretAsDouble(FloatHelper.ReinterpretAsLong(12345.67890)),
"Number hasn't changed after mirrored reinterpretation"
);
}
/// Tests the floating point reinterpretation functions
[Test]
public void FloatsCanBeReinterpretedAsIntegers() {
Assert.AreEqual(
12345,
FloatHelper.ReinterpretAsInt(FloatHelper.ReinterpretAsFloat(12345)),
"Number hasn't changed after mirrored reinterpretation"
);
}
///
/// Verifies that the IsZero() method can distinguish zero from very small values
///
[Test]
public void CanDetermineIfFloatIsZero() {
Assert.IsTrue(FloatHelper.IsZero(FloatHelper.PositiveZeroFloat));
Assert.IsTrue(FloatHelper.IsZero(FloatHelper.NegativeZeroFloat));
Assert.IsFalse(FloatHelper.IsZero(1.401298E-45f));
Assert.IsFalse(FloatHelper.IsZero(-1.401298E-45f));
}
///
/// Verifies that the IsZero() method can distinguish zero from very small values
///
[Test]
public void CanDetermineIfDoubleIsZero() {
Assert.IsTrue(FloatHelper.IsZero(FloatHelper.PositiveZeroDouble));
Assert.IsTrue(FloatHelper.IsZero(FloatHelper.NegativeZeroDouble));
Assert.IsFalse(FloatHelper.IsZero(4.94065645841247E-324));
Assert.IsFalse(FloatHelper.IsZero(-4.94065645841247E-324));
}
///
/// Tests the double prevision floating point reinterpretation functions
///
[Test]
public void DoublesCanBeReinterpretedAsLongs() {
Assert.AreEqual(
1234567890,
FloatHelper.ReinterpretAsLong(FloatHelper.ReinterpretAsDouble(1234567890)),
"Number hasn't changed after mirrored reinterpretation"
);
}
///
/// Verifies that two denormalized floats can be compared in ulps
///
[Test]
public void DenormalizedFloatsCanBeCompared() {
float zero = 0.0f;
float zeroPlusOneUlp = FloatHelper.ReinterpretAsFloat(
FloatHelper.ReinterpretAsInt(zero) + 1
);
float zeroMinusOneUlp = -zeroPlusOneUlp;
// Across zero
Assert.IsFalse(FloatHelper.AreAlmostEqual(zeroMinusOneUlp, zeroPlusOneUlp, 1));
Assert.IsTrue(FloatHelper.AreAlmostEqual(zeroPlusOneUlp, zeroMinusOneUlp, 2));
// Against zero
Assert.IsFalse(FloatHelper.AreAlmostEqual(zero, zeroPlusOneUlp, 0));
Assert.IsTrue(FloatHelper.AreAlmostEqual(zero, zeroPlusOneUlp, 1));
Assert.IsFalse(FloatHelper.AreAlmostEqual(zero, zeroMinusOneUlp, 0));
Assert.IsTrue(FloatHelper.AreAlmostEqual(zero, zeroMinusOneUlp, 1));
}
///
/// Verifies that the negative floating point zero is within one ulp of the positive
/// floating point zero and vice versa
///
[Test]
public void NegativeZeroFloatEqualsPositiveZero() {
Assert.IsTrue(
FloatHelper.AreAlmostEqual(
FloatHelper.NegativeZeroFloat, FloatHelper.PositiveZeroFloat, 0
)
);
Assert.IsTrue(
FloatHelper.AreAlmostEqual(
FloatHelper.PositiveZeroFloat, FloatHelper.NegativeZeroFloat, 0
)
);
}
/// Verifies that floats can be compared across the zero boundary
[Test]
public void FloatsCanBeComparedAcrossZeroInUlps() {
float tenUlps = float.Epsilon * 10.0f;
Assert.IsTrue(FloatHelper.AreAlmostEqual(-tenUlps, tenUlps, 20));
Assert.IsTrue(FloatHelper.AreAlmostEqual(tenUlps, -tenUlps, 20));
Assert.IsFalse(FloatHelper.AreAlmostEqual(-tenUlps, tenUlps, 19));
Assert.IsTrue(FloatHelper.AreAlmostEqual(-tenUlps, 0, 10));
Assert.IsTrue(FloatHelper.AreAlmostEqual(0, -tenUlps, 10));
Assert.IsFalse(FloatHelper.AreAlmostEqual(-tenUlps, 0, 9));
Assert.IsTrue(FloatHelper.AreAlmostEqual(0, tenUlps, 10));
Assert.IsTrue(FloatHelper.AreAlmostEqual(tenUlps, 0, 10));
Assert.IsFalse(FloatHelper.AreAlmostEqual(0, tenUlps, 9));
}
///
/// Verifies that two denormalized doubles can be compared in ulps
///
[Test]
public void DenormalizedDoublesCanBeCompared() {
double zero = 0.0;
double zeroPlusOneUlp = FloatHelper.ReinterpretAsDouble(
FloatHelper.ReinterpretAsLong(zero) + 1
);
double zeroMinusOneUlp = -zeroPlusOneUlp;
// Across zero
Assert.IsFalse(FloatHelper.AreAlmostEqual(zeroMinusOneUlp, zeroPlusOneUlp, 1));
Assert.IsTrue(FloatHelper.AreAlmostEqual(zeroPlusOneUlp, zeroMinusOneUlp, 2));
// Against zero
Assert.IsFalse(FloatHelper.AreAlmostEqual(zero, zeroPlusOneUlp, 0));
Assert.IsTrue(FloatHelper.AreAlmostEqual(zero, zeroPlusOneUlp, 1));
Assert.IsFalse(FloatHelper.AreAlmostEqual(zero, zeroMinusOneUlp, 0));
Assert.IsTrue(FloatHelper.AreAlmostEqual(zero, zeroMinusOneUlp, 1));
}
///
/// Verifies that the negative double precision floating point zero is within one ulp
/// of the positive double precision floating point zero and vice versa
///
[Test]
public void NegativeZeroDoubleEqualsPositiveZero() {
Assert.IsTrue(
FloatHelper.AreAlmostEqual(
FloatHelper.NegativeZeroDouble, FloatHelper.NegativeZeroDouble, 0
)
);
Assert.IsTrue(
FloatHelper.AreAlmostEqual(
FloatHelper.NegativeZeroDouble, FloatHelper.NegativeZeroDouble, 0
)
);
}
/// Verifies that doubles can be compared across the zero boundary
[Test]
public void DoublesCanBeComparedAcrossZeroInUlps() {
double tenUlps = double.Epsilon * 10.0;
Assert.IsTrue(FloatHelper.AreAlmostEqual(-tenUlps, tenUlps, 20));
Assert.IsTrue(FloatHelper.AreAlmostEqual(tenUlps, -tenUlps, 20));
Assert.IsFalse(FloatHelper.AreAlmostEqual(-tenUlps, tenUlps, 19));
Assert.IsTrue(FloatHelper.AreAlmostEqual(-tenUlps, 0, 10));
Assert.IsTrue(FloatHelper.AreAlmostEqual(0, -tenUlps, 10));
Assert.IsFalse(FloatHelper.AreAlmostEqual(-tenUlps, 0, 9));
Assert.IsTrue(FloatHelper.AreAlmostEqual(0, tenUlps, 10));
Assert.IsTrue(FloatHelper.AreAlmostEqual(tenUlps, 0, 10));
Assert.IsFalse(FloatHelper.AreAlmostEqual(0, tenUlps, 9));
}
}
} // namespace Nuclex.Support
#endif // UNITTEST