1
0
mirror of https://github.com/ppy/osu.git synced 2024-12-16 23:42:54 +08:00
osu-lazer/osu.Game.Rulesets.Catch.Tests/JuiceStreamPathTest.cs

289 lines
10 KiB
C#
Raw Normal View History

// Copyright (c) ppy Pty Ltd <contact@ppy.sh>. Licensed under the MIT Licence.
// See the LICENCE file in the repository root for full licence text.
using System;
using System.Collections.Generic;
using System.Linq;
using NUnit.Framework;
using osu.Framework.Utils;
using osu.Game.Rulesets.Catch.Objects;
using osu.Game.Rulesets.Objects;
using osu.Game.Rulesets.Objects.Types;
using osuTK;
namespace osu.Game.Rulesets.Catch.Tests
{
[TestFixture]
public class JuiceStreamPathTest
{
[TestCase(1e3, true, false)]
// When the coordinates are large, the slope invariant fails within the specified absolute allowance due to the floating-number precision.
[TestCase(1e9, false, false)]
// Using discrete values sometimes discover more edge cases.
[TestCase(10, true, true)]
public void TestRandomInsertSetPosition(double scale, bool checkSlope, bool integralValues)
{
var rng = new Random(1);
var path = new JuiceStreamPath();
for (int iteration = 0; iteration < 100000; iteration++)
{
if (rng.Next(10) == 0)
path.Clear();
int vertexCount = path.Vertices.Count;
switch (rng.Next(2))
{
case 0:
{
double distance = rng.NextDouble() * scale * 2 - scale;
if (integralValues)
distance = Math.Round(distance);
float oldX = path.PositionAtDistance(distance);
int index = path.InsertVertex(distance);
Assert.That(path.Vertices.Count, Is.EqualTo(vertexCount + 1));
Assert.That(path.Vertices[index].Distance, Is.EqualTo(distance));
Assert.That(path.Vertices[index].X, Is.EqualTo(oldX));
break;
}
case 1:
{
int index = rng.Next(path.Vertices.Count);
double distance = path.Vertices[index].Distance;
float newX = (float)(rng.NextDouble() * scale * 2 - scale);
if (integralValues)
newX = MathF.Round(newX);
path.SetVertexPosition(index, newX);
Assert.That(path.Vertices.Count, Is.EqualTo(vertexCount));
Assert.That(path.Vertices[index].Distance, Is.EqualTo(distance));
Assert.That(path.Vertices[index].X, Is.EqualTo(newX));
break;
}
}
assertInvariants(path.Vertices, checkSlope);
}
}
[Test]
public void TestRemoveVertices()
{
var path = new JuiceStreamPath();
path.Add(10, 5);
path.Add(20, -5);
int removeCount = path.RemoveVertices((v, i) => v.Distance == 10 && i == 1);
Assert.That(removeCount, Is.EqualTo(1));
Assert.That(path.Vertices, Is.EqualTo(new[]
{
new JuiceStreamPathVertex(0, 0),
new JuiceStreamPathVertex(20, -5)
}));
removeCount = path.RemoveVertices((_, i) => i == 0);
Assert.That(removeCount, Is.EqualTo(1));
Assert.That(path.Vertices, Is.EqualTo(new[]
{
new JuiceStreamPathVertex(20, -5)
}));
removeCount = path.RemoveVertices((_, i) => true);
Assert.That(removeCount, Is.EqualTo(1));
Assert.That(path.Vertices, Is.EqualTo(new[]
{
new JuiceStreamPathVertex()
}));
}
[Test]
public void TestResampleVertices()
{
var path = new JuiceStreamPath();
path.Add(-100, -10);
path.Add(100, 50);
path.ResampleVertices(new double[]
{
-50,
0,
70,
120
});
Assert.That(path.Vertices, Is.EqualTo(new[]
{
new JuiceStreamPathVertex(-100, -10),
new JuiceStreamPathVertex(-50, -5),
new JuiceStreamPathVertex(0, 0),
new JuiceStreamPathVertex(70, 35),
new JuiceStreamPathVertex(100, 50),
new JuiceStreamPathVertex(100, 50),
}));
path.Clear();
path.SetVertexPosition(0, 10);
path.ResampleVertices(Array.Empty<double>());
Assert.That(path.Vertices, Is.EqualTo(new[]
{
new JuiceStreamPathVertex(0, 10)
}));
}
[Test]
public void TestRandomConvertFromSliderPath()
{
var rng = new Random(1);
var path = new JuiceStreamPath();
var sliderPath = new SliderPath();
for (int iteration = 0; iteration < 10000; iteration++)
{
sliderPath.ControlPoints.Clear();
do
{
int start = sliderPath.ControlPoints.Count;
do
{
float x = (float)(rng.NextDouble() * 1e3);
float y = (float)(rng.NextDouble() * 1e3);
sliderPath.ControlPoints.Add(new PathControlPoint(new Vector2(x, y)));
} while (rng.Next(2) != 0);
int length = sliderPath.ControlPoints.Count - start + 1;
sliderPath.ControlPoints[start].Type = length <= 2 ? PathType.Linear : length == 3 ? PathType.PerfectCurve : PathType.Bezier;
} while (rng.Next(3) != 0);
if (rng.Next(5) == 0)
sliderPath.ExpectedDistance.Value = rng.NextDouble() * 3e3;
else
sliderPath.ExpectedDistance.Value = null;
path.ConvertFromSliderPath(sliderPath);
Assert.That(path.Vertices[0].Distance, Is.EqualTo(0));
Assert.That(path.Distance, Is.EqualTo(sliderPath.Distance).Within(1e-3));
assertInvariants(path.Vertices, true);
double[] sampleDistances = Enumerable.Range(0, 10)
.Select(_ => rng.NextDouble() * sliderPath.Distance)
.ToArray();
foreach (double distance in sampleDistances)
{
float expected = sliderPath.PositionAt(distance / sliderPath.Distance).X;
Assert.That(path.PositionAtDistance(distance), Is.EqualTo(expected).Within(1e-3));
}
path.ResampleVertices(sampleDistances);
assertInvariants(path.Vertices, true);
foreach (double distance in sampleDistances)
{
float expected = sliderPath.PositionAt(distance / sliderPath.Distance).X;
Assert.That(path.PositionAtDistance(distance), Is.EqualTo(expected).Within(1e-3));
}
}
}
[Test]
public void TestRandomConvertToSliderPath()
{
var rng = new Random(1);
var path = new JuiceStreamPath();
var sliderPath = new SliderPath();
for (int iteration = 0; iteration < 10000; iteration++)
{
path.Clear();
do
{
double distance = rng.NextDouble() * 1e3;
float x = (float)(rng.NextDouble() * 1e3);
path.Add(distance, x);
} while (rng.Next(5) != 0);
float sliderStartY = (float)(rng.NextDouble() * JuiceStreamPath.OSU_PLAYFIELD_HEIGHT);
path.ConvertToSliderPath(sliderPath, sliderStartY);
Assert.That(sliderPath.Distance, Is.EqualTo(path.Distance).Within(1e-3));
Assert.That(sliderPath.ControlPoints[0].Position.X, Is.EqualTo(path.Vertices[0].X));
assertInvariants(path.Vertices, true);
foreach (var point in sliderPath.ControlPoints)
{
Assert.That(point.Type, Is.EqualTo(PathType.Linear).Or.Null);
Assert.That(sliderStartY + point.Position.Y, Is.InRange(0, JuiceStreamPath.OSU_PLAYFIELD_HEIGHT));
}
for (int i = 0; i < 10; i++)
{
double distance = rng.NextDouble() * path.Distance;
float expected = path.PositionAtDistance(distance);
Assert.That(sliderPath.PositionAt(distance / sliderPath.Distance).X, Is.EqualTo(expected).Within(1e-3));
}
}
}
[Test]
public void TestInvalidation()
{
var path = new JuiceStreamPath();
Assert.That(path.InvalidationID, Is.EqualTo(1));
int previousId = path.InvalidationID;
path.InsertVertex(10);
checkNewId();
path.SetVertexPosition(1, 5);
checkNewId();
path.Add(20, 0);
checkNewId();
path.RemoveVertices((v, _) => v.Distance == 20);
checkNewId();
path.ResampleVertices(new double[] { 5, 10, 15 });
checkNewId();
path.Clear();
checkNewId();
path.ConvertFromSliderPath(new SliderPath());
checkNewId();
void checkNewId()
{
Assert.That(path.InvalidationID, Is.Not.EqualTo(previousId));
previousId = path.InvalidationID;
}
}
private void assertInvariants(IReadOnlyList<JuiceStreamPathVertex> vertices, bool checkSlope)
{
Assert.That(vertices, Is.Not.Empty);
for (int i = 0; i < vertices.Count; i++)
{
Assert.That(double.IsFinite(vertices[i].Distance));
Assert.That(float.IsFinite(vertices[i].X));
}
for (int i = 1; i < vertices.Count; i++)
{
Assert.That(vertices[i].Distance, Is.GreaterThanOrEqualTo(vertices[i - 1].Distance));
if (!checkSlope) continue;
float xDiff = Math.Abs(vertices[i].X - vertices[i - 1].X);
double distanceDiff = vertices[i].Distance - vertices[i - 1].Distance;
Assert.That(xDiff, Is.LessThanOrEqualTo(distanceDiff).Within(Precision.FLOAT_EPSILON));
}
}
}
}