mirror of
https://github.com/ppy/osu
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451 lines
20 KiB
C#
451 lines
20 KiB
C#
// Copyright (c) ppy Pty Ltd <contact@ppy.sh>. Licensed under the MIT Licence.
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// See the LICENCE file in the repository root for full licence text.
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using System;
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using System.Collections.Generic;
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using System.Linq;
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using osu.Framework.Graphics.Primitives;
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using osu.Framework.Utils;
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using osu.Game.Rulesets.Osu.Objects;
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using osu.Game.Rulesets.Osu.UI;
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using osuTK;
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namespace osu.Game.Rulesets.Osu.Utils
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{
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public static partial class OsuHitObjectGenerationUtils
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{
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/// <summary>
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/// Number of previous hitobjects to be shifted together when an object is being moved.
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/// </summary>
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private const int preceding_hitobjects_to_shift = 10;
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private static readonly Vector2 playfield_centre = OsuPlayfield.BASE_SIZE / 2;
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/// <summary>
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/// Generate a list of <see cref="ObjectPositionInfo"/>s containing information for how the given list of
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/// <see cref="OsuHitObject"/>s are positioned.
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/// </summary>
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/// <param name="hitObjects">A list of <see cref="OsuHitObject"/>s to process.</param>
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/// <returns>A list of <see cref="ObjectPositionInfo"/>s describing how each hit object is positioned relative to the previous one.</returns>
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public static List<ObjectPositionInfo> GeneratePositionInfos(IEnumerable<OsuHitObject> hitObjects)
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{
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var positionInfos = new List<ObjectPositionInfo>();
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Vector2 previousPosition = playfield_centre;
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float previousAngle = 0;
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foreach (OsuHitObject hitObject in hitObjects)
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{
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Vector2 relativePosition = hitObject.Position - previousPosition;
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float absoluteAngle = MathF.Atan2(relativePosition.Y, relativePosition.X);
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float relativeAngle = absoluteAngle - previousAngle;
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ObjectPositionInfo positionInfo;
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positionInfos.Add(positionInfo = new ObjectPositionInfo(hitObject)
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{
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RelativeAngle = relativeAngle,
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DistanceFromPrevious = relativePosition.Length
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});
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if (hitObject is Slider slider)
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{
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float absoluteRotation = getSliderRotation(slider);
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positionInfo.Rotation = absoluteRotation - absoluteAngle;
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absoluteAngle = absoluteRotation;
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}
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previousPosition = hitObject.EndPosition;
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previousAngle = absoluteAngle;
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}
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return positionInfos;
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}
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/// <summary>
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/// Reposition the hit objects according to the information in <paramref name="objectPositionInfos"/>.
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/// </summary>
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/// <param name="objectPositionInfos">Position information for each hit object.</param>
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/// <returns>The repositioned hit objects.</returns>
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public static List<OsuHitObject> RepositionHitObjects(IEnumerable<ObjectPositionInfo> objectPositionInfos)
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{
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List<WorkingObject> workingObjects = objectPositionInfos.Select(o => new WorkingObject(o)).ToList();
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WorkingObject? previous = null;
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for (int i = 0; i < workingObjects.Count; i++)
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{
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var current = workingObjects[i];
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var hitObject = current.HitObject;
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if (hitObject is Spinner)
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{
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previous = current;
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continue;
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}
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computeModifiedPosition(current, previous, i > 1 ? workingObjects[i - 2] : null);
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// Move hit objects back into the playfield if they are outside of it
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Vector2 shift = Vector2.Zero;
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switch (hitObject)
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{
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case HitCircle:
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shift = clampHitCircleToPlayfield(current);
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break;
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case Slider:
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shift = clampSliderToPlayfield(current);
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break;
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}
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if (shift != Vector2.Zero)
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{
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var toBeShifted = new List<OsuHitObject>();
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for (int j = i - 1; j >= i - preceding_hitobjects_to_shift && j >= 0; j--)
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{
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// only shift hit circles
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if (!(workingObjects[j].HitObject is HitCircle)) break;
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toBeShifted.Add(workingObjects[j].HitObject);
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}
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if (toBeShifted.Count > 0)
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applyDecreasingShift(toBeShifted, shift);
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}
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previous = current;
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}
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return workingObjects.Select(p => p.HitObject).ToList();
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}
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/// <summary>
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/// Compute the modified position of a hit object while attempting to keep it inside the playfield.
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/// </summary>
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/// <param name="current">The <see cref="WorkingObject"/> representing the hit object to have the modified position computed for.</param>
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/// <param name="previous">The <see cref="WorkingObject"/> representing the hit object immediately preceding the current one.</param>
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/// <param name="beforePrevious">The <see cref="WorkingObject"/> representing the hit object immediately preceding the <paramref name="previous"/> one.</param>
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private static void computeModifiedPosition(WorkingObject current, WorkingObject? previous, WorkingObject? beforePrevious)
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{
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float previousAbsoluteAngle = 0f;
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if (previous != null)
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{
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if (previous.HitObject is Slider s)
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{
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previousAbsoluteAngle = getSliderRotation(s);
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}
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else
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{
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Vector2 earliestPosition = beforePrevious?.HitObject.EndPosition ?? playfield_centre;
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Vector2 relativePosition = previous.HitObject.Position - earliestPosition;
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previousAbsoluteAngle = MathF.Atan2(relativePosition.Y, relativePosition.X);
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}
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}
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float absoluteAngle = previousAbsoluteAngle + current.PositionInfo.RelativeAngle;
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var posRelativeToPrev = new Vector2(
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current.PositionInfo.DistanceFromPrevious * MathF.Cos(absoluteAngle),
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current.PositionInfo.DistanceFromPrevious * MathF.Sin(absoluteAngle)
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);
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Vector2 lastEndPosition = previous?.EndPositionModified ?? playfield_centre;
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posRelativeToPrev = RotateAwayFromEdge(lastEndPosition, posRelativeToPrev);
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current.PositionModified = lastEndPosition + posRelativeToPrev;
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if (!(current.HitObject is Slider slider))
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return;
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absoluteAngle = MathF.Atan2(posRelativeToPrev.Y, posRelativeToPrev.X);
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Vector2 centreOfMassOriginal = calculateCentreOfMass(slider);
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Vector2 centreOfMassModified = rotateVector(centreOfMassOriginal, current.PositionInfo.Rotation + absoluteAngle - getSliderRotation(slider));
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centreOfMassModified = RotateAwayFromEdge(current.PositionModified, centreOfMassModified);
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float relativeRotation = MathF.Atan2(centreOfMassModified.Y, centreOfMassModified.X) - MathF.Atan2(centreOfMassOriginal.Y, centreOfMassOriginal.X);
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if (!Precision.AlmostEquals(relativeRotation, 0))
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RotateSlider(slider, relativeRotation);
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}
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/// <summary>
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/// Move the modified position of a <see cref="HitCircle"/> so that it fits inside the playfield.
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/// </summary>
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/// <returns>The deviation from the original modified position in order to fit within the playfield.</returns>
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private static Vector2 clampHitCircleToPlayfield(WorkingObject workingObject)
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{
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var previousPosition = workingObject.PositionModified;
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workingObject.EndPositionModified = workingObject.PositionModified = clampToPlayfieldWithPadding(
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workingObject.PositionModified,
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(float)workingObject.HitObject.Radius
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);
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workingObject.HitObject.Position = workingObject.PositionModified;
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return workingObject.PositionModified - previousPosition;
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}
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/// <summary>
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/// Moves the <see cref="Slider"/> and all necessary nested <see cref="OsuHitObject"/>s into the <see cref="OsuPlayfield"/> if they aren't already.
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/// </summary>
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/// <returns>The deviation from the original modified position in order to fit within the playfield.</returns>
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private static Vector2 clampSliderToPlayfield(WorkingObject workingObject)
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{
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var slider = (Slider)workingObject.HitObject;
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var possibleMovementBounds = CalculatePossibleMovementBounds(slider);
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// The slider rotation applied in computeModifiedPosition might make it impossible to fit the slider into the playfield
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// For example, a long horizontal slider will be off-screen when rotated by 90 degrees
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// In this case, limit the rotation to either 0 or 180 degrees
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if (possibleMovementBounds.Width < 0 || possibleMovementBounds.Height < 0)
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{
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float currentRotation = getSliderRotation(slider);
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float diff1 = getAngleDifference(workingObject.RotationOriginal, currentRotation);
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float diff2 = getAngleDifference(workingObject.RotationOriginal + MathF.PI, currentRotation);
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if (diff1 < diff2)
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{
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RotateSlider(slider, workingObject.RotationOriginal - getSliderRotation(slider));
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}
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else
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{
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RotateSlider(slider, workingObject.RotationOriginal + MathF.PI - getSliderRotation(slider));
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}
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possibleMovementBounds = CalculatePossibleMovementBounds(slider);
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}
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var previousPosition = workingObject.PositionModified;
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// Clamp slider position to the placement area
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// If the slider is larger than the playfield, at least make sure that the head circle is inside the playfield
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float newX = possibleMovementBounds.Width < 0
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? Math.Clamp(possibleMovementBounds.Left, 0, OsuPlayfield.BASE_SIZE.X)
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: Math.Clamp(previousPosition.X, possibleMovementBounds.Left, possibleMovementBounds.Right);
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float newY = possibleMovementBounds.Height < 0
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? Math.Clamp(possibleMovementBounds.Top, 0, OsuPlayfield.BASE_SIZE.Y)
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: Math.Clamp(previousPosition.Y, possibleMovementBounds.Top, possibleMovementBounds.Bottom);
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slider.Position = workingObject.PositionModified = new Vector2(newX, newY);
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workingObject.EndPositionModified = slider.EndPosition;
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shiftNestedObjects(slider, workingObject.PositionModified - workingObject.PositionOriginal);
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return workingObject.PositionModified - previousPosition;
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}
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/// <summary>
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/// Decreasingly shift a list of <see cref="OsuHitObject"/>s by a specified amount.
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/// The first item in the list is shifted by the largest amount, while the last item is shifted by the smallest amount.
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/// </summary>
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/// <param name="hitObjects">The list of hit objects to be shifted.</param>
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/// <param name="shift">The amount to be shifted.</param>
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private static void applyDecreasingShift(IList<OsuHitObject> hitObjects, Vector2 shift)
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{
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for (int i = 0; i < hitObjects.Count; i++)
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{
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var hitObject = hitObjects[i];
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// The first object is shifted by a vector slightly smaller than shift
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// The last object is shifted by a vector slightly larger than zero
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Vector2 position = hitObject.Position + shift * ((hitObjects.Count - i) / (float)(hitObjects.Count + 1));
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hitObject.Position = clampToPlayfieldWithPadding(position, (float)hitObject.Radius);
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}
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}
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/// <summary>
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/// Calculates a <see cref="RectangleF"/> which contains all of the possible movements of the slider (in relative X/Y coordinates)
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/// such that the entire slider is inside the playfield.
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/// </summary>
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/// <param name="slider">The <see cref="Slider"/> for which to calculate a movement bounding box.</param>
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/// <returns>A <see cref="RectangleF"/> which contains all of the possible movements of the slider such that the entire slider is inside the playfield.</returns>
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/// <remarks>
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/// If the slider is larger than the playfield, the returned <see cref="RectangleF"/> may have negative width/height.
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/// </remarks>
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public static RectangleF CalculatePossibleMovementBounds(Slider slider)
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{
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var pathPositions = new List<Vector2>();
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slider.Path.GetPathToProgress(pathPositions, 0, 1);
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float minX = float.PositiveInfinity;
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float maxX = float.NegativeInfinity;
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float minY = float.PositiveInfinity;
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float maxY = float.NegativeInfinity;
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// Compute the bounding box of the slider.
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foreach (var pos in pathPositions)
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{
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minX = MathF.Min(minX, pos.X);
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maxX = MathF.Max(maxX, pos.X);
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minY = MathF.Min(minY, pos.Y);
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maxY = MathF.Max(maxY, pos.Y);
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}
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// Take the circle radius into account.
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float radius = (float)slider.Radius;
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minX -= radius;
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minY -= radius;
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maxX += radius;
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maxY += radius;
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// Given the bounding box of the slider (via min/max X/Y),
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// the amount that the slider can move to the left is minX (with the sign flipped, since positive X is to the right),
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// and the amount that it can move to the right is WIDTH - maxX.
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// Same calculation applies for the Y axis.
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float left = -minX;
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float right = OsuPlayfield.BASE_SIZE.X - maxX;
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float top = -minY;
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float bottom = OsuPlayfield.BASE_SIZE.Y - maxY;
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return new RectangleF(left, top, right - left, bottom - top);
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}
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/// <summary>
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/// Shifts all nested <see cref="SliderTick"/>s and <see cref="SliderRepeat"/>s by the specified shift.
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/// </summary>
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/// <param name="slider"><see cref="Slider"/> whose nested <see cref="SliderTick"/>s and <see cref="SliderRepeat"/>s should be shifted</param>
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/// <param name="shift">The <see cref="Vector2"/> the <see cref="Slider"/>'s nested <see cref="SliderTick"/>s and <see cref="SliderRepeat"/>s should be shifted by</param>
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private static void shiftNestedObjects(Slider slider, Vector2 shift)
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{
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foreach (var hitObject in slider.NestedHitObjects.Where(o => o is SliderTick || o is SliderRepeat))
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{
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if (!(hitObject is OsuHitObject osuHitObject))
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continue;
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osuHitObject.Position += shift;
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}
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}
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/// <summary>
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/// Clamp a position to playfield, keeping a specified distance from the edges.
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/// </summary>
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/// <param name="position">The position to be clamped.</param>
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/// <param name="padding">The minimum distance allowed from playfield edges.</param>
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/// <returns>The clamped position.</returns>
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private static Vector2 clampToPlayfieldWithPadding(Vector2 position, float padding)
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{
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return new Vector2(
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Math.Clamp(position.X, padding, OsuPlayfield.BASE_SIZE.X - padding),
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Math.Clamp(position.Y, padding, OsuPlayfield.BASE_SIZE.Y - padding)
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);
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}
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/// <summary>
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/// Estimate the centre of mass of a slider relative to its start position.
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/// </summary>
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/// <param name="slider">The slider to process.</param>
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/// <returns>The centre of mass of the slider.</returns>
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private static Vector2 calculateCentreOfMass(Slider slider)
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{
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const double sample_step = 50;
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// just sample the start and end positions if the slider is too short
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if (slider.Distance <= sample_step)
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{
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return Vector2.Divide(slider.Path.PositionAt(1), 2);
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}
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int count = 0;
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Vector2 sum = Vector2.Zero;
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double pathDistance = slider.Distance;
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for (double i = 0; i < pathDistance; i += sample_step)
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{
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sum += slider.Path.PositionAt(i / pathDistance);
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count++;
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}
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return sum / count;
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}
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/// <summary>
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/// Get the absolute rotation of a slider, defined as the angle from its start position to the end of its path.
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/// </summary>
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/// <param name="slider">The slider to process.</param>
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/// <returns>The angle in radians.</returns>
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private static float getSliderRotation(Slider slider)
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{
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var endPositionVector = slider.Path.PositionAt(1);
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return MathF.Atan2(endPositionVector.Y, endPositionVector.X);
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}
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/// <summary>
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/// Get the absolute difference between 2 angles measured in Radians.
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/// </summary>
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/// <param name="angle1">The first angle</param>
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/// <param name="angle2">The second angle</param>
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/// <returns>The absolute difference with interval <c>[0, MathF.PI)</c></returns>
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private static float getAngleDifference(float angle1, float angle2)
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{
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float diff = MathF.Abs(angle1 - angle2) % (MathF.PI * 2);
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return MathF.Min(diff, MathF.PI * 2 - diff);
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}
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public class ObjectPositionInfo
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{
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/// <summary>
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/// The jump angle from the previous hit object to this one, relative to the previous hit object's jump angle.
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/// </summary>
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/// <remarks>
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/// <see cref="RelativeAngle"/> of the first hit object in a beatmap represents the absolute angle from playfield center to the object.
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/// </remarks>
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/// <example>
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/// If <see cref="RelativeAngle"/> is 0, the player's cursor doesn't need to change its direction of movement when passing
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/// the previous object to reach this one.
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/// </example>
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public float RelativeAngle { get; set; }
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/// <summary>
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/// The jump distance from the previous hit object to this one.
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/// </summary>
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/// <remarks>
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/// <see cref="DistanceFromPrevious"/> of the first hit object in a beatmap is relative to the playfield center.
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/// </remarks>
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public float DistanceFromPrevious { get; set; }
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/// <summary>
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/// The rotation of the hit object, relative to its jump angle.
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/// For sliders, this is defined as the angle from the slider's start position to the end of its path, relative to its jump angle.
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/// For hit circles and spinners, this property is ignored.
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/// </summary>
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public float Rotation { get; set; }
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/// <summary>
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/// The hit object associated with this <see cref="ObjectPositionInfo"/>.
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/// </summary>
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public OsuHitObject HitObject { get; }
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public ObjectPositionInfo(OsuHitObject hitObject)
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{
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HitObject = hitObject;
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}
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}
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private class WorkingObject
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{
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public float RotationOriginal { get; }
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public Vector2 PositionOriginal { get; }
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public Vector2 PositionModified { get; set; }
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public Vector2 EndPositionModified { get; set; }
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public ObjectPositionInfo PositionInfo { get; }
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public OsuHitObject HitObject => PositionInfo.HitObject;
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public WorkingObject(ObjectPositionInfo positionInfo)
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{
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PositionInfo = positionInfo;
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RotationOriginal = HitObject is Slider slider ? getSliderRotation(slider) : 0;
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PositionModified = PositionOriginal = HitObject.Position;
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EndPositionModified = HitObject.EndPosition;
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}
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}
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}
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}
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