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osu-lazer/osu.Game.Rulesets.Osu/Difficulty/Preprocessing/OsuDifficultyHitObject.cs

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// 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.Linq;
using osu.Game.Rulesets.Difficulty.Preprocessing;
using osu.Game.Rulesets.Objects;
using osu.Game.Rulesets.Osu.Objects;
using osuTK;
namespace osu.Game.Rulesets.Osu.Difficulty.Preprocessing
{
public class OsuDifficultyHitObject : DifficultyHitObject
{
private const int normalized_radius = 50; // Change radius to 50 to make 100 the diameter. Easier for mental maths.
private const int min_delta_time = 25;
protected new OsuHitObject BaseObject => (OsuHitObject)base.BaseObject;
/// <summary>
/// Normalized distance from the end position of the previous <see cref="OsuDifficultyHitObject"/> to the start position of this <see cref="OsuDifficultyHitObject"/>.
/// </summary>
public double JumpDistance { get; private set; }
/// <summary>
/// Minimum distance from the end position of the previous <see cref="OsuDifficultyHitObject"/> to the start position of this <see cref="OsuDifficultyHitObject"/>.
/// </summary>
public double MovementDistance { get; private set; }
/// <summary>
/// Normalized distance between the start and end position of the previous <see cref="OsuDifficultyHitObject"/>.
/// </summary>
public double TravelDistance { get; private set; }
/// <summary>
/// Angle the player has to take to hit this <see cref="OsuDifficultyHitObject"/>.
/// Calculated as the angle between the circles (current-2, current-1, current).
/// </summary>
public double? Angle { get; private set; }
/// <summary>
/// Milliseconds elapsed since the end time of the Previous <see cref="OsuDifficultyHitObject"/>, with a minimum of 25ms.
/// </summary>
public double MovementTime { get; private set; }
/// <summary>
/// Milliseconds elapsed since from the start time of the Previous <see cref="OsuDifficultyHitObject"/> to the end time of the same Previous <see cref="OsuDifficultyHitObject"/>, with a minimum of 25ms.
/// </summary>
public double TravelTime { get; private set; }
/// <summary>
/// Milliseconds elapsed since the start time of the previous <see cref="OsuDifficultyHitObject"/>, with a minimum of 25ms.
/// </summary>
public readonly double StrainTime;
private readonly OsuHitObject lastLastObject;
private readonly OsuHitObject lastObject;
public OsuDifficultyHitObject(HitObject hitObject, HitObject lastLastObject, HitObject lastObject, double clockRate)
: base(hitObject, lastObject, clockRate)
{
this.lastLastObject = (OsuHitObject)lastLastObject;
this.lastObject = (OsuHitObject)lastObject;
// Capped to 25ms to prevent difficulty calculation breaking from simulatenous objects.
StrainTime = Math.Max(DeltaTime, min_delta_time);
setDistances(clockRate);
}
private void setDistances(double clockRate)
{
// We don't need to calculate either angle or distance when one of the last->curr objects is a spinner
if (BaseObject is Spinner || lastObject is Spinner)
return;
// We will scale distances by this factor, so we can assume a uniform CircleSize among beatmaps.
float scalingFactor = normalized_radius / (float)BaseObject.Radius;
if (BaseObject.Radius < 30)
{
float smallCircleBonus = Math.Min(30 - (float)BaseObject.Radius, 5) / 50;
scalingFactor *= 1 + smallCircleBonus;
}
if (lastObject is Slider lastSlider)
{
computeSliderCursorPosition(lastSlider);
TravelDistance = 0;
TravelTime = Math.Max(lastSlider.LazyTravelTime / clockRate, min_delta_time);
MovementTime = Math.Max(StrainTime - lastSlider.LazyTravelTime / clockRate, min_delta_time);
MovementDistance = Vector2.Subtract(lastSlider.TailCircle.StackedPosition, BaseObject.StackedPosition).Length * scalingFactor;
int repeatCount = 0;
Vector2 currSliderPosition = ((OsuHitObject)lastSlider.NestedHitObjects[0]).StackedPosition;
for (int i = 1; i < lastSlider.NestedHitObjects.Count; i++)
{
Vector2 currSlider = Vector2.Subtract(((OsuHitObject)lastSlider.NestedHitObjects[i]).StackedPosition, currSliderPosition);
double currSliderLength = currSlider.Length * scalingFactor;
if ((OsuHitObject)lastSlider.NestedHitObjects[i] is SliderEndCircle && !((OsuHitObject)lastSlider.NestedHitObjects[i] is SliderRepeat))
{
Vector2 possSlider = Vector2.Subtract((Vector2)lastSlider.LazyEndPosition, currSliderPosition);
if (possSlider.Length < currSlider.Length)
currSlider = possSlider; // Take the least distance from slider end vs lazy end.
currSliderLength = currSlider.Length * scalingFactor;
}
if ((OsuHitObject)lastSlider.NestedHitObjects[i] is SliderTick)
{
if (currSliderLength > 120)
{
currSliderPosition = Vector2.Add(currSliderPosition, Vector2.Multiply(currSlider, (float)((currSliderLength - 120) / currSliderLength)));
currSliderLength *= (currSliderLength - 120) / currSliderLength;
}
else
currSliderLength = 0;
}
else if ((OsuHitObject)lastSlider.NestedHitObjects[i] is SliderRepeat)
{
if (currSliderLength > 50)
{
currSliderPosition = Vector2.Add(currSliderPosition, Vector2.Multiply(currSlider, (float)((currSliderLength - 50) / currSliderLength)));
currSliderLength *= (currSliderLength - 50) / currSliderLength;
}
else
currSliderLength = 0;
}
else
{
if (currSliderLength > 0)
{
currSliderPosition = Vector2.Add(currSliderPosition, Vector2.Multiply(currSlider, (float)((currSliderLength - 0) / currSliderLength)));
currSliderLength *= (currSliderLength - 0) / currSliderLength;
}
else
currSliderLength = 0;
}
if ((OsuHitObject)lastSlider.NestedHitObjects[i] is SliderRepeat)
repeatCount++;
TravelDistance += currSliderLength;
}
TravelDistance *= Math.Pow(1 + repeatCount / 2.5, 1.0 / 2.5); // Bonus for repeat sliders until a better per nested object strain system can be achieved.
}
Vector2 lastCursorPosition = getEndCursorPosition(lastObject);
JumpDistance = (BaseObject.StackedPosition * scalingFactor - lastCursorPosition * scalingFactor).Length;
MovementDistance = Math.Max(0, Math.Min(JumpDistance - 50, MovementDistance - 120)); // radius for jumpdistance is within 50 of maximum possible sliderLeniency, 120 for movement distance.
if (lastLastObject != null && !(lastLastObject is Spinner))
{
Vector2 lastLastCursorPosition = getEndCursorPosition(lastLastObject);
Vector2 v1 = lastLastCursorPosition - lastObject.StackedPosition;
Vector2 v2 = BaseObject.StackedPosition - lastCursorPosition;
float dot = Vector2.Dot(v1, v2);
float det = v1.X * v2.Y - v1.Y * v2.X;
Angle = Math.Abs(Math.Atan2(det, dot));
}
}
private void computeSliderCursorPosition(Slider slider)
{
if (slider.LazyEndPosition != null)
return;
slider.LazyEndPosition = slider.StackedPosition;
float approxFollowCircleRadius = (float)(slider.Radius * 1.4); // using 1.4 to better follow the real movement of a cursor.
var computeVertex = new Action<double>(t =>
{
double progress = (t - slider.StartTime) / slider.SpanDuration;
if (progress % 2 >= 1)
progress = 1 - progress % 1;
else
progress %= 1;
// ReSharper disable once PossibleInvalidOperationException (bugged in current r# version)
var diff = slider.StackedPosition + slider.Path.PositionAt(progress) - slider.LazyEndPosition.Value;
float dist = diff.Length;
slider.LazyTravelTime = t - slider.StartTime;
if (dist > approxFollowCircleRadius)
{
// The cursor would be outside the follow circle, we need to move it
diff.Normalize(); // Obtain direction of diff
dist -= approxFollowCircleRadius;
slider.LazyEndPosition += diff * dist;
slider.LazyTravelDistance += dist;
}
});
// Skip the head circle
var scoringTimes = slider.NestedHitObjects.Skip(1).Select(t => t.StartTime);
foreach (var time in scoringTimes)
computeVertex(time);
}
private Vector2 getEndCursorPosition(OsuHitObject hitObject)
{
Vector2 pos = hitObject.StackedPosition;
if (hitObject is Slider slider)
{
computeSliderCursorPosition(slider);
pos = slider.LazyEndPosition ?? pos;
}
return pos;
}
}
}
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