// Copyright (c) ppy Pty Ltd . Licensed under the MIT Licence. // See the LICENCE file in the repository root for full licence text. using System; using System.Diagnostics; using osu.Framework.Allocation; using osu.Framework.Extensions.Color4Extensions; using osu.Framework.Graphics; using osu.Framework.Graphics.Containers; using osu.Framework.Graphics.Shapes; using osuTK; using osuTK.Graphics; namespace osu.Game.Rulesets.Osu.Statistics { public class Heatmap : CompositeDrawable { ///

/// Full size of the heatmap. ///

private const float size = 130; ///

/// Size of the inner circle containing the "hit" points, relative to . /// All other points outside of the inner circle are "miss" points. ///

private const float inner_portion = 0.8f; private const float rotation = 45; private const float point_size = 4; private Container allPoints; public Heatmap() { Size = new Vector2(size); } [BackgroundDependencyLoader] private void load() { InternalChildren = new Drawable[] { new CircularContainer { Anchor = Anchor.Centre, Origin = Anchor.Centre, RelativeSizeAxes = Axes.Both, Size = new Vector2(inner_portion), Masking = true, BorderThickness = 2f, BorderColour = Color4.White, Child = new Box { RelativeSizeAxes = Axes.Both, Colour = Color4Extensions.FromHex("#202624") } }, new Container { RelativeSizeAxes = Axes.Both, Masking = true, Children = new Drawable[] { new Box { Anchor = Anchor.Centre, Origin = Anchor.Centre, RelativeSizeAxes = Axes.Y, Height = 2, // We're rotating along a diagonal - we don't really care how big this is. Width = 1f, Rotation = -rotation, Alpha = 0.3f, }, new Box { Anchor = Anchor.Centre, Origin = Anchor.Centre, RelativeSizeAxes = Axes.Y, Height = 2, // We're rotating along a diagonal - we don't really care how big this is. Width = 1f, Rotation = rotation }, new Box { Anchor = Anchor.TopRight, Origin = Anchor.TopRight, Width = 10, Height = 2f, }, new Box { Anchor = Anchor.TopRight, Origin = Anchor.TopRight, Y = -1, Width = 2f, Height = 10, } } }, allPoints = new Container { RelativeSizeAxes = Axes.Both } }; Vector2 centre = new Vector2(size / 2); int rows = (int)Math.Ceiling(size / point_size); int cols = (int)Math.Ceiling(size / point_size); for (int r = 0; r < rows; r++) { for (int c = 0; c < cols; c++) { Vector2 pos = new Vector2(c * point_size, r * point_size); HitPointType pointType = HitPointType.Hit; if (Vector2.Distance(pos, centre) > size * inner_portion / 2) pointType = HitPointType.Miss; allPoints.Add(new HitPoint(pos, pointType) { Size = new Vector2(point_size), Colour = pointType == HitPointType.Hit ? new Color4(102, 255, 204, 255) : new Color4(255, 102, 102, 255) }); } } } public void AddPoint(Vector2 start, Vector2 end, Vector2 hitPoint, float radius) { double angle1 = Math.Atan2(end.Y - hitPoint.Y, hitPoint.X - end.X); // Angle between the end point and the hit point. double angle2 = Math.Atan2(end.Y - start.Y, start.X - end.X); // Angle between the end point and the start point. double finalAngle = angle2 - angle1; // Angle between start, end, and hit points. float normalisedDistance = Vector2.Distance(hitPoint, end) / radius; // Find the most relevant hit point. double minDist = double.PositiveInfinity; HitPoint point = null; foreach (var p in allPoints) { Vector2 localCentre = new Vector2(size / 2); float localRadius = localCentre.X * inner_portion * normalisedDistance; double localAngle = finalAngle + 3 * Math.PI / 4; Vector2 localPoint = localCentre + localRadius * new Vector2((float)Math.Cos(localAngle), (float)Math.Sin(localAngle)); float dist = Vector2.Distance(p.DrawPosition + p.DrawSize / 2, localPoint); if (dist < minDist) { minDist = dist; point = p; } } Debug.Assert(point != null); point.Increment(); } private class HitPoint : Circle { private readonly HitPointType pointType; public HitPoint(Vector2 position, HitPointType pointType) { this.pointType = pointType; Position = position; Alpha = 0; } public void Increment() { if (Alpha < 1) Alpha += 0.1f; else if (pointType == HitPointType.Hit) Colour = ((Color4)Colour).Lighten(0.1f); } } private enum HitPointType { Hit, Miss } } }