using System.Collections.Generic; using Unity.UIWidgets.foundation; using UnityEngine; namespace Unity.UIWidgets.uiOld{ class uiPathCache : PoolObject { float _distTol; float _tessTol; List _paths = new List(); List _points = new List(); float _scale; bool _fillConvex; //mesh cache uiMeshMesh _fillMesh; public uiMeshMesh fillMesh { get { return _fillMesh; } } uiMeshMesh _strokeMesh; public uiMeshMesh strokeMesh { get { return _strokeMesh; } } float _strokeWidth; StrokeCap _lineCap; StrokeJoin _lineJoin; float _miterLimit; float _fringe; uiPath.uiPathShapeHint _shapeHint; public static uiPathCache create(float scale, uiPath.uiPathShapeHint shapeHint) { uiPathCache newPathCache = ObjectPool.alloc(); newPathCache._distTol = 0.01f / scale; newPathCache._tessTol = 0.25f / scale; newPathCache._scale = scale; newPathCache._shapeHint = shapeHint; return newPathCache; } public bool canReuse(float scale) { if (_scale != scale) { return false; } return true; } public bool canSkipAAHairline { get { return _shapeHint == uiPath.uiPathShapeHint.Rect; } } public override void clear() { _paths.Clear(); _points.Clear(); ObjectPool.release(_fillMesh); _fillMesh = null; ObjectPool.release(_strokeMesh); _strokeMesh = null; _shapeHint = uiPath.uiPathShapeHint.Other; } public uiPathCache() { } public void addPath() { _paths.Add(uiPathPath.create( first: _points.Count, winding: uiPathWinding.counterClockwise )); } public void addPoint(float x, float y, uiPointFlags flags) { _addPoint(uiPathPoint.create(x: x, y: y, flags: flags)); } void _addPoint(uiPathPoint point) { if (_paths.Count == 0) { addPath(); addPoint(0, 0, uiPointFlags.corner); } var path = _paths[_paths.Count - 1]; if (path.count > 0) { var pt = _points[_points.Count - 1]; if (uiPathUtils.ptEquals(pt.x, pt.y, point.x, point.y, _distTol)) { pt.flags |= point.flags; _points[_points.Count - 1] = pt; return; } } _points.Add(point); path.count++; _paths[_paths.Count - 1] = path; } public void tessellateBezier( float x2, float y2, float x3, float y3, float x4, float y4, uiPointFlags flags) { float x1, y1; if (_points.Count == 0) { x1 = 0; y1 = 0; } else { var pt = _points[_points.Count - 1]; x1 = pt.x; y1 = pt.y; } if (x1 == x2 && x1 == x3 && x1 == x4 && y1 == y2 && y1 == y3 && y1 == y4) { return; } var points = uiTessellationGenerator.tessellateBezier(x1, y1, x2, y2, x3, y3, x4, y4, _tessTol); D.assert(points.Count > 0); for (int i = 0; i < points.Count; i++) { var point = points[i]; if (i == points.Count - 1) { _addPoint(uiPathPoint.create( x: point.x + x1, y: point.y + y1, flags: flags )); } else { _addPoint(uiPathPoint.create( x: point.x + x1, y: point.y + y1 )); } } } public void closePath() { if (_paths.Count == 0) { return; } var path = _paths[_paths.Count - 1]; path.closed = true; _paths[_paths.Count - 1] = path; } public void pathWinding(uiPathWinding winding) { if (_paths.Count == 0) { return; } var path = _paths[_paths.Count - 1]; path.winding = winding; _paths[_paths.Count - 1] = path; } public void normalize() { var points = _points; var paths = _paths; for (var j = 0; j < paths.Count; j++) { var path = paths[j]; if (path.count <= 1) { continue; } var ip0 = path.first + path.count - 1; var ip1 = path.first; var p0 = points[ip0]; var p1 = points[ip1]; if (uiPathUtils.ptEquals(p0.x, p0.y, p1.x, p1.y, _distTol)) { path.count--; path.closed = true; paths[j] = path; } if (path.count > 2) { if (path.winding == uiPathWinding.clockwise) { uiPathUtils.polyReverse(points, path.first, path.count); } } } } void _calculateJoins(float w, StrokeJoin lineJoin, float miterLimit) { float iw = w > 0.0f ? 1.0f / w : 0.0f; var points = _points; var paths = _paths; for (var i = 0; i < paths.Count; i++) { var path = paths[i]; if (path.count <= 1) { continue; } var ip0 = path.first + path.count - 1; var ip1 = path.first; for (var j = 0; j < path.count; j++) { var p0 = points[ip0]; var p1 = points[ip1]; p0.dx = p1.x - p0.x; p0.dy = p1.y - p0.y; p0.len = uiPathUtils.normalize(ref p0.dx, ref p0.dy); points[ip0] = p0; ip0 = ip1++; } ip0 = path.first + path.count - 1; ip1 = path.first; path.convex = true; for (var j = 0; j < path.count; j++) { var p0 = points[ip0]; var p1 = points[ip1]; float dlx0 = p0.dy; float dly0 = -p0.dx; float dlx1 = p1.dy; float dly1 = -p1.dx; // Calculate extrusions p1.dmx = (dlx0 + dlx1) * 0.5f; p1.dmy = (dly0 + dly1) * 0.5f; float dmr2 = p1.dmx * p1.dmx + p1.dmy * p1.dmy; if (dmr2 > 0.000001f) { float scale = 1.0f / dmr2; if (scale > 600.0f) { scale = 600.0f; } p1.dmx *= scale; p1.dmy *= scale; } // Clear flags, but keep the corner. p1.flags &= uiPointFlags.corner; // Keep track of left turns. float cross = p1.dx * p0.dy - p0.dx * p1.dy; if (cross > 0.0f) { p1.flags |= uiPointFlags.left; } else if (cross < 0.0f) { path.convex = false; } // Calculate if we should use bevel or miter for inner join. float limit = Mathf.Max(1.01f, Mathf.Min(p0.len, p1.len) * iw); if (dmr2 * limit * limit < 1.0f) { p1.flags |= uiPointFlags.innerBevel; } // Check to see if the corner needs to be beveled. if ((p1.flags & uiPointFlags.corner) != 0) { if (lineJoin == StrokeJoin.bevel || lineJoin == StrokeJoin.round || dmr2 * miterLimit * miterLimit < 1.0f) { p1.flags |= uiPointFlags.bevel; } } points[ip0] = p0; points[ip1] = p1; ip0 = ip1++; } paths[i] = path; } } uiVertexUV _expandStroke(float w, float fringe, StrokeCap lineCap, StrokeJoin lineJoin, float miterLimit) { float aa = fringe; float u0 = 0.0f, u1 = 1.0f; int ncap = 0; if (lineCap == StrokeCap.round || lineJoin == StrokeJoin.round) { ncap = uiPathUtils.curveDivs(w, Mathf.PI, _tessTol); } w += aa * 0.5f; if (aa == 0.0f) { u0 = 0.5f; u1 = 0.5f; } _calculateJoins(w, lineJoin, miterLimit); var points = _points; var paths = _paths; var cvertices = 0; for (var i = 0; i < paths.Count; i++) { var path = paths[i]; if (path.count <= 1) { continue; } cvertices += path.count * 2; cvertices += 8; } var _vertices = ObjectPool>.alloc(); _vertices.SetCapacity(cvertices); var _uv = ObjectPool>.alloc(); _uv.SetCapacity(cvertices); for (var i = 0; i < paths.Count; i++) { var path = paths[i]; if (path.count <= 1) { continue; } path.istroke = _vertices.Count; int s, e, ip0, ip1; if (path.closed) { ip0 = path.first + path.count - 1; ip1 = path.first; s = 0; e = path.count; } else { ip0 = path.first; ip1 = path.first + 1; s = 1; e = path.count - 1; } var p0 = points[ip0]; var p1 = points[ip1]; if (!path.closed) { if (lineCap == StrokeCap.butt) { _vertices.buttCapStart(_uv, p0, p0.dx, p0.dy, w, 0.0f, aa, u0, u1); } else if (lineCap == StrokeCap.square) { _vertices.buttCapStart(_uv, p0, p0.dx, p0.dy, w, w, aa, u0, u1); } else { // round _vertices.roundCapStart(_uv, p0, p0.dx, p0.dy, w, ncap, u0, u1); } } for (var j = s; j < e; j++) { p0 = points[ip0]; p1 = points[ip1]; if ((p1.flags & (uiPointFlags.bevel | uiPointFlags.innerBevel)) != 0) { if (lineJoin == StrokeJoin.round) { _vertices.roundJoin(_uv, p0, p1, w, w, ncap, u0, u1, aa); } else { _vertices.bevelJoin(_uv, p0, p1, w, w, u0, u1, aa); } } else { _vertices.Add(new Vector2(p1.x + p1.dmx * w, p1.y + p1.dmy * w)); _vertices.Add(new Vector2(p1.x - p1.dmx * w, p1.y - p1.dmy * w)); _uv.Add(new Vector2(u0, 1)); _uv.Add(new Vector2(u1, 1)); } ip0 = ip1++; } if (!path.closed) { p0 = points[ip0]; p1 = points[ip1]; if (lineCap == StrokeCap.butt) { _vertices.buttCapEnd(_uv, p1, p0.dx, p0.dy, w, 0.0f, aa, u0, u1); } else if (lineCap == StrokeCap.square) { _vertices.buttCapEnd(_uv, p1, p0.dx, p0.dy, w, w, aa, u0, u1); } else { // round _vertices.roundCapEnd(_uv, p1, p0.dx, p0.dy, w, ncap, u0, u1); } } else { _vertices.Add(_vertices[path.istroke]); _vertices.Add(_vertices[path.istroke + 1]); _uv.Add(new Vector2(u0, 1)); _uv.Add(new Vector2(u1, 1)); } path.nstroke = _vertices.Count - path.istroke; paths[i] = path; } D.assert(_uv.Count == _vertices.Count); return new uiVertexUV { strokeVertices = _vertices, strokeUV = _uv, }; } uiVertexUV _expandFill(float fringe) { float aa = canSkipAAHairline ? 0f : fringe; float woff = aa * 0.5f; var points = _points; var paths = _paths; _calculateJoins(fringe, StrokeJoin.miter, 4.0f); var cvertices = 0; for (var i = 0; i < paths.Count; i++) { var path = paths[i]; if (path.count <= 2) { continue; } cvertices += path.count; } _fillConvex = false; for (var i = 0; i < paths.Count; i++) { var path = paths[i]; if (path.count <= 2) { continue; } if (_fillConvex) { // if more than two paths, convex is false. _fillConvex = false; break; } if (!path.convex) { // if not convex, convex is false. break; } _fillConvex = true; } var _vertices = ObjectPool>.alloc(); _vertices.SetCapacity(cvertices); var _uv = ObjectPool>.alloc(); _uv.SetCapacity(cvertices); for (var i = 0; i < paths.Count; i++) { var path = paths[i]; if (path.count <= 2) { continue; } path.ifill = _vertices.Count; for (var j = 0; j < path.count; j++) { var p = points[path.first + j]; if (aa > 0.0f) { _vertices.Add(new Vector2(p.x + p.dmx * woff, p.y + p.dmy * woff)); } else { _vertices.Add(new Vector2(p.x, p.y)); } _uv.Add(new Vector2(0.5f, 1.0f)); } path.nfill = _vertices.Count - path.ifill; paths[i] = path; } uiList _strokeVertices = null; uiList _strokeUV = null; if (aa > 0.0f) { _strokeVertices = ObjectPool>.alloc(); _strokeUV = ObjectPool>.alloc(); cvertices = 0; for (var i = 0; i < paths.Count; i++) { var path = paths[i]; if (path.count <= 2) { continue; } cvertices += path.count * 2; } _strokeVertices.SetCapacity(cvertices); _strokeUV.SetCapacity(cvertices); float lw = _fillConvex ? woff : aa + woff; float rw = aa - woff; float lu = _fillConvex ? 0.5f : 0.0f; float ru = 1.0f; for (var i = 0; i < paths.Count; i++) { var path = paths[i]; if (path.count <= 2) { continue; } path.istroke = _strokeVertices.Count; for (var j = 0; j < path.count; j++) { var p = points[path.first + j]; _strokeVertices.Add(new Vector2(p.x + p.dmx * lw, p.y + p.dmy * lw)); _strokeUV.Add(new Vector2(lu, 1.0f)); _strokeVertices.Add(new Vector2(p.x - p.dmx * rw, p.y - p.dmy * rw)); _strokeUV.Add(new Vector2(ru, 1.0f)); } path.nstroke = _strokeVertices.Count - path.istroke; paths[i] = path; } } return new uiVertexUV { fillVertices = _vertices, fillUV = _uv, strokeVertices = _strokeVertices, strokeUV = _strokeUV, }; } public void computeStrokeMesh(float strokeWidth, float fringe, StrokeCap lineCap, StrokeJoin lineJoin, float miterLimit) { if (_strokeMesh != null && _fillMesh == null && // Ensure that the cached stroke mesh was not calculated in computeFillMesh _strokeWidth == strokeWidth && _fringe == fringe && _lineCap == lineCap && _lineJoin == lineJoin && _miterLimit == miterLimit) { return; } var verticesUV = _expandStroke(strokeWidth, fringe, lineCap, lineJoin, miterLimit); var paths = _paths; var cindices = 0; for (var i = 0; i < paths.Count; i++) { var path = paths[i]; if (path.count <= 1) { continue; } if (path.nstroke > 0) { D.assert(path.nstroke >= 2); cindices += (path.nstroke - 2) * 3; } } var indices = ObjectPool>.alloc(); indices.SetCapacity(cindices); for (var i = 0; i < paths.Count; i++) { var path = paths[i]; if (path.count <= 1) { continue; } if (path.nstroke > 0) { for (var j = 2; j < path.nstroke; j++) { if ((j & 1) == 0) { indices.Add(path.istroke + j - 1); indices.Add(path.istroke + j - 2); indices.Add(path.istroke + j); } else { indices.Add(path.istroke + j - 2); indices.Add(path.istroke + j - 1); indices.Add(path.istroke + j); } } } } D.assert(indices.Count == cindices); ObjectPool.release(_strokeMesh); _strokeMesh = uiMeshMesh.create(null, verticesUV.strokeVertices, indices, verticesUV.strokeUV); ObjectPool.release(_fillMesh); _fillMesh = null; _strokeWidth = strokeWidth; _fringe = fringe; _lineCap = lineCap; _lineJoin = lineJoin; _miterLimit = miterLimit; return; } public void computeFillMesh(float fringe, out bool convex) { if (_fillMesh != null && (fringe != 0.0f || _strokeMesh != null) && _fringe == fringe) { convex = _fillConvex; return; } var verticesUV = _expandFill(fringe); convex = _fillConvex; var paths = _paths; var cindices = 0; for (var i = 0; i < paths.Count; i++) { var path = paths[i]; if (path.count <= 2) { continue; } if (path.nfill > 0) { D.assert(path.nfill >= 2); cindices += (path.nfill - 2) * 3; } } var indices = ObjectPool>.alloc(); indices.SetCapacity(cindices); for (var i = 0; i < paths.Count; i++) { var path = paths[i]; if (path.count <= 2) { continue; } if (path.nfill > 0) { for (var j = 2; j < path.nfill; j++) { indices.Add(path.ifill); indices.Add(path.ifill + j); indices.Add(path.ifill + j - 1); } } } D.assert(indices.Count == cindices); if (verticesUV.strokeVertices != null) { cindices = 0; for (var i = 0; i < paths.Count; i++) { var path = paths[i]; if (path.count <= 2) { continue; } if (path.nstroke > 0) { D.assert(path.nstroke >= 6); cindices += path.nstroke * 3; } } var strokeIndices = ObjectPool>.alloc(); strokeIndices.SetCapacity(cindices); for (var i = 0; i < paths.Count; i++) { var path = paths[i]; if (path.count <= 2) { continue; } if (path.nstroke > 0) { strokeIndices.Add(path.istroke + path.nstroke - 1); strokeIndices.Add(path.istroke + path.nstroke - 2); strokeIndices.Add(path.istroke); strokeIndices.Add(path.istroke + path.nstroke - 1); strokeIndices.Add(path.istroke); strokeIndices.Add(path.istroke + 1); for (var j = 2; j < path.nstroke; j++) { if ((j & 1) == 0) { strokeIndices.Add(path.istroke + j - 1); strokeIndices.Add(path.istroke + j - 2); strokeIndices.Add(path.istroke + j); } else { strokeIndices.Add(path.istroke + j - 2); strokeIndices.Add(path.istroke + j - 1); strokeIndices.Add(path.istroke + j); } } } } D.assert(strokeIndices.Count == cindices); ObjectPool.release(_strokeMesh); _strokeMesh = uiMeshMesh.create(null, verticesUV.strokeVertices, strokeIndices, verticesUV.strokeUV); } var mesh = uiMeshMesh.create(null, verticesUV.fillVertices, indices, verticesUV.fillUV); _fillMesh = mesh; _fringe = fringe; } } }