// Copyright (c) 2007-2018 ppy Pty Ltd . // Licensed under the MIT Licence - https://raw.githubusercontent.com/ppy/osu/master/LICENCE using System; using System.Linq; using osu.Game.Rulesets.Osu.Objects; using OpenTK; namespace osu.Game.Rulesets.Osu.Difficulty.Preprocessing { ///

/// A wrapper around extending it with additional data required for difficulty calculation. ///

public class OsuDifficultyHitObject { private const int normalized_radius = 52; ///

/// The this refers to. ///

public OsuHitObject BaseObject { get; } ///

/// Normalized distance from the end position of the previous to the start position of this . ///

public double JumpDistance { get; private set; } ///

/// Normalized distance between the start and end position of the previous . ///

public double TravelDistance { get; private set; } ///

/// Milliseconds elapsed since the StartTime of the previous . ///

public double DeltaTime { get; private set; } ///

/// Milliseconds elapsed since the start time of the previous , with a minimum of 50ms. ///

public double StrainTime { get; private set; } private readonly OsuHitObject lastObject; private readonly double timeRate; ///

/// Initializes the object calculating extra data required for difficulty calculation. ///

public OsuDifficultyHitObject(OsuHitObject currentObject, OsuHitObject lastObject, double timeRate) { this.lastObject = lastObject; this.timeRate = timeRate; BaseObject = currentObject; setDistances(); setTimingValues(); // Calculate angle here } private void setDistances() { // 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; } Vector2 lastCursorPosition = lastObject.StackedPosition; var lastSlider = lastObject as Slider; if (lastSlider != null) { computeSliderCursorPosition(lastSlider); lastCursorPosition = lastSlider.LazyEndPosition ?? lastCursorPosition; TravelDistance = lastSlider.LazyTravelDistance * scalingFactor; } // Don't need to jump to reach spinners if (!(BaseObject is Spinner)) JumpDistance = (BaseObject.StackedPosition * scalingFactor - lastCursorPosition * scalingFactor).Length; } private void setTimingValues() { DeltaTime = (BaseObject.StartTime - lastObject.StartTime) / timeRate; // Every strain interval is hard capped at the equivalent of 375 BPM streaming speed as a safety measure StrainTime = Math.Max(50, DeltaTime); } private void computeSliderCursorPosition(Slider slider) { if (slider.LazyEndPosition != null) return; slider.LazyEndPosition = slider.StackedPosition; float approxFollowCircleRadius = (float)(slider.Radius * 3); var computeVertex = new Action(t => { double progress = ((int)t - (int)slider.StartTime) / (float)(int)slider.SpanDuration; if (progress % 2 > 1) progress = 1 - progress % 1; else progress = progress % 1; // ReSharper disable once PossibleInvalidOperationException (bugged in current r# version) var diff = slider.StackedPosition + slider.Curve.PositionAt(progress) - slider.LazyEndPosition.Value; float dist = diff.Length; 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); computeVertex(slider.EndTime); } } }