зеркало из https://github.com/mozilla/gecko-dev.git
416 строки
12 KiB
C++
416 строки
12 KiB
C++
/* -*- Mode: C++; tab-width: 2; indent-tabs-mode: nil; c-basic-offset: 2 -*-
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* This Source Code Form is subject to the terms of the Mozilla Public
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* License, v. 2.0. If a copy of the MPL was not distributed with this
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* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
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#ifndef MOZILLA_GFX_POLYGON_H
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#define MOZILLA_GFX_POLYGON_H
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#include "Matrix.h"
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#include "mozilla/Move.h"
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#include "nsTArray.h"
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#include "Point.h"
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#include "Triangle.h"
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#include <initializer_list>
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namespace mozilla {
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namespace gfx {
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/**
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* Calculates the w = 0 intersection point for the edge defined by
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* |aFirst| and |aSecond|.
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*/
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template<class Units>
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Point4DTyped<Units>
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CalculateEdgeIntersect(const Point4DTyped<Units>& aFirst,
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const Point4DTyped<Units>& aSecond)
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{
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static const float w = 0.00001f;
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const float t = (w - aFirst.w) / (aSecond.w - aFirst.w);
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return aFirst + (aSecond - aFirst) * t;
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}
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/**
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* Clips the polygon defined by |aPoints| so that there are no points with
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* w <= 0.
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*/
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template<class Units>
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nsTArray<Point4DTyped<Units>>
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ClipPointsAtInfinity(const nsTArray<Point4DTyped<Units>>& aPoints)
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{
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nsTArray<Point4DTyped<Units>> outPoints(aPoints.Length());
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const size_t pointCount = aPoints.Length();
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for (size_t i = 0; i < pointCount; ++i) {
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const Point4DTyped<Units>& first = aPoints[i];
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const Point4DTyped<Units>& second = aPoints[(i + 1) % pointCount];
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if (!first.w || !second.w) {
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// Skip edges at infinity.
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continue;
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}
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if (first.w > 0.0f) {
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outPoints.AppendElement(first);
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}
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if ((first.w <= 0.0f) ^ (second.w <= 0.0f)) {
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outPoints.AppendElement(CalculateEdgeIntersect(first, second));
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}
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}
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return outPoints;
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}
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/**
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* Calculates the distances between the points in |aPoints| and the plane
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* defined by |aPlaneNormal| and |aPlanePoint|.
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*/
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template<class Units>
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nsTArray<float>
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CalculatePointPlaneDistances(const nsTArray<Point4DTyped<Units>>& aPoints,
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const Point4DTyped<Units>& aPlaneNormal,
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const Point4DTyped<Units>& aPlanePoint,
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size_t& aPos, size_t& aNeg)
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{
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// Point classification might produce incorrect results due to numerical
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// inaccuracies. Using an epsilon value makes the splitting plane "thicker".
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const float epsilon = 0.05f;
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aPos = aNeg = 0;
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nsTArray<float> distances(aPoints.Length());
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for (const Point4DTyped<Units>& point : aPoints) {
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float dot = (point - aPlanePoint).DotProduct(aPlaneNormal);
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if (dot > epsilon) {
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aPos++;
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} else if (dot < -epsilon) {
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aNeg++;
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} else {
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// The point is within the thick plane.
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dot = 0.0f;
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}
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distances.AppendElement(dot);
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}
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return distances;
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}
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/**
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* Clips the polygon defined by |aPoints|. The clipping uses previously
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* calculated plane to point distances and the plane normal |aNormal|.
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* The result of clipping is stored in |aBackPoints| and |aFrontPoints|.
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*/
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template<class Units>
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void
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ClipPointsWithPlane(const nsTArray<Point4DTyped<Units>>& aPoints,
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const Point4DTyped<Units>& aNormal,
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const nsTArray<float>& aDots,
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nsTArray<Point4DTyped<Units>>& aBackPoints,
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nsTArray<Point4DTyped<Units>>& aFrontPoints)
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{
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static const auto Sign = [](const float& f) {
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if (f > 0.0f) return 1;
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if (f < 0.0f) return -1;
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return 0;
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};
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const size_t pointCount = aPoints.Length();
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for (size_t i = 0; i < pointCount; ++i) {
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size_t j = (i + 1) % pointCount;
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const Point4DTyped<Units>& a = aPoints[i];
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const Point4DTyped<Units>& b = aPoints[j];
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const float dotA = aDots[i];
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const float dotB = aDots[j];
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// The point is in front of or on the plane.
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if (dotA >= 0) {
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aFrontPoints.AppendElement(a);
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}
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// The point is behind or on the plane.
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if (dotA <= 0) {
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aBackPoints.AppendElement(a);
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}
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// If the sign of the dot products changes between two consecutive
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// vertices, then the plane intersects with the polygon edge.
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// The case where the polygon edge is within the plane is handled above.
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if (Sign(dotA) && Sign(dotB) && Sign(dotA) != Sign(dotB)) {
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// Calculate the line segment and plane intersection point.
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const Point4DTyped<Units> ab = b - a;
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const float dotAB = ab.DotProduct(aNormal);
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const float t = -dotA / dotAB;
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const Point4DTyped<Units> p = a + (ab * t);
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// Add the intersection point to both polygons.
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aBackPoints.AppendElement(p);
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aFrontPoints.AppendElement(p);
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}
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}
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}
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/**
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* PolygonTyped stores the points of a convex planar polygon.
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*/
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template<class Units>
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class PolygonTyped {
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typedef Point3DTyped<Units> Point3DType;
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typedef Point4DTyped<Units> Point4DType;
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public:
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PolygonTyped() {}
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explicit PolygonTyped(const nsTArray<Point4DType>& aPoints,
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const Point4DType& aNormal = DefaultNormal())
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: mNormal(aNormal), mPoints(aPoints) {}
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explicit PolygonTyped(nsTArray<Point4DType>&& aPoints,
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const Point4DType& aNormal = DefaultNormal())
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: mNormal(aNormal), mPoints(Move(aPoints)) {}
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explicit PolygonTyped(const std::initializer_list<Point4DType>& aPoints,
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const Point4DType& aNormal = DefaultNormal())
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: mNormal(aNormal), mPoints(aPoints)
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{
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#ifdef DEBUG
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EnsurePlanarPolygon();
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#endif
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}
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/**
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* Returns the smallest 2D rectangle that can fully cover the polygon.
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*/
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RectTyped<Units> BoundingBox() const
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{
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if (mPoints.IsEmpty()) {
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return RectTyped<Units>();
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}
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float minX, maxX, minY, maxY;
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minX = maxX = mPoints[0].x;
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minY = maxY = mPoints[0].y;
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for (const Point4DType& point : mPoints) {
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minX = std::min(point.x, minX);
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maxX = std::max(point.x, maxX);
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minY = std::min(point.y, minY);
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maxY = std::max(point.y, maxY);
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}
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return RectTyped<Units>(minX, minY, maxX - minX, maxY - minY);
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}
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/**
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* Clips the polygon against the given 2D rectangle.
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*/
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PolygonTyped<Units> ClipPolygon(const RectTyped<Units>& aRect) const
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{
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if (aRect.IsEmpty()) {
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return PolygonTyped<Units>();
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}
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return ClipPolygon(FromRect(aRect));
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}
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/**
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* Clips this polygon against |aPolygon| in 2D and returns a new polygon.
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*/
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PolygonTyped<Units> ClipPolygon(const PolygonTyped<Units>& aPolygon) const
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{
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const nsTArray<Point4DType>& points = aPolygon.GetPoints();
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if (mPoints.IsEmpty() || points.IsEmpty()) {
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return PolygonTyped<Units>();
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}
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nsTArray<Point4DType> clippedPoints(mPoints);
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size_t pos, neg;
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nsTArray<Point4DType> backPoints(4), frontPoints(4);
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// Iterate over all the edges of the clipping polygon |aPolygon| and clip
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// this polygon against the edges.
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const size_t pointCount = points.Length();
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for (size_t i = 0; i < pointCount; ++i) {
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const Point4DType p1 = points[(i + 1) % pointCount];
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const Point4DType p2 = points[i];
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// Calculate the normal for the edge defined by |p1| and |p2|.
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const Point4DType normal(p2.y - p1.y, p1.x - p2.x, 0.0f, 0.0f);
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// Calculate the distances between the points of the polygon and the
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// plane defined by |aPolygon|.
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const nsTArray<float> distances =
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CalculatePointPlaneDistances(clippedPoints, normal, p1, pos, neg);
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backPoints.ClearAndRetainStorage();
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frontPoints.ClearAndRetainStorage();
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// Clip the polygon points using the previously calculated distances.
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ClipPointsWithPlane(clippedPoints, normal, distances,
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backPoints, frontPoints);
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// Only use the points behind the clipping plane.
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clippedPoints = Move(backPoints);
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if (clippedPoints.Length() < 3) {
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// The clipping created a polygon with no area.
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return PolygonTyped<Units>();
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}
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}
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return PolygonTyped<Units>(Move(clippedPoints), mNormal);
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}
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/**
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* Returns a new polygon containing the bounds of the given 2D rectangle.
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*/
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static PolygonTyped<Units> FromRect(const RectTyped<Units>& aRect)
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{
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nsTArray<Point4DType> points {
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Point4DType(aRect.x, aRect.y, 0.0f, 1.0f),
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Point4DType(aRect.x, aRect.YMost(), 0.0f, 1.0f),
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Point4DType(aRect.XMost(), aRect.YMost(), 0.0f, 1.0f),
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Point4DType(aRect.XMost(), aRect.y, 0.0f, 1.0f)
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};
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return PolygonTyped<Units>(Move(points));
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}
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const Point4DType& GetNormal() const
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{
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return mNormal;
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}
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const nsTArray<Point4DType>& GetPoints() const
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{
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return mPoints;
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}
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bool IsEmpty() const
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{
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// If the polygon has less than three points, it has no visible area.
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return mPoints.Length() < 3;
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}
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/**
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* Returns a list of triangles covering the polygon.
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*/
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nsTArray<TriangleTyped<Units>> ToTriangles() const
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{
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nsTArray<TriangleTyped<Units>> triangles;
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if (IsEmpty()) {
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return triangles;
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}
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// This fan triangulation method only works for convex polygons.
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for (size_t i = 1; i < mPoints.Length() - 1; ++i) {
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TriangleTyped<Units> triangle(Point(mPoints[0].x, mPoints[0].y),
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Point(mPoints[i].x, mPoints[i].y),
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Point(mPoints[i + 1].x, mPoints[i + 1].y));
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triangles.AppendElement(Move(triangle));
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}
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return triangles;
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}
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void TransformToLayerSpace(const Matrix4x4Typed<Units, Units>& aTransform)
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{
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TransformPoints(aTransform, true);
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mNormal = DefaultNormal();
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}
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void TransformToScreenSpace(const Matrix4x4Typed<Units, Units>& aTransform)
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{
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MOZ_ASSERT(!aTransform.IsSingular());
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TransformPoints(aTransform, false);
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// Perspective projection transformation might produce points with w <= 0,
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// so we need to clip these points.
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mPoints = ClipPointsAtInfinity(mPoints);
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// Normal vectors should be transformed using inverse transpose.
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mNormal = aTransform.Inverse().Transpose().TransformPoint(mNormal);
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}
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private:
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static Point4DType DefaultNormal()
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{
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return Point4DType(0.0f, 0.0f, 1.0f, 0.0f);
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}
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#ifdef DEBUG
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void EnsurePlanarPolygon() const
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{
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if (mPoints.Length() <= 3) {
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// Polygons with three or less points are guaranteed to be planar.
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return;
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}
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// This normal calculation method works only for planar polygons.
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// The resulting normal vector will point towards the viewer when the
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// polygon has a counter-clockwise winding order from the perspective
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// of the viewer.
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Point3DType normal;
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const Point3DType p0 = mPoints[0].As3DPoint();
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for (size_t i = 1; i < mPoints.Length() - 1; ++i) {
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const Point3DType p1 = mPoints[i].As3DPoint();
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const Point3DType p2 = mPoints[i + 1].As3DPoint();
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normal += (p1 - p0).CrossProduct(p2 - p0);
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}
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// Ensure that at least one component is greater than zero.
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// This avoids division by zero when normalizing the vector.
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bool hasNonZeroComponent = std::abs(normal.x) > 0.0f ||
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std::abs(normal.y) > 0.0f ||
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std::abs(normal.z) > 0.0f;
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MOZ_ASSERT(hasNonZeroComponent);
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normal.Normalize();
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// Ensure that the polygon is planar.
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// http://mathworld.wolfram.com/Point-PlaneDistance.html
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const float epsilon = 0.01f;
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for (const Point4DType& point : mPoints) {
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const Point3DType p1 = point.As3DPoint();
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const float d = normal.DotProduct(p1 - p0);
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MOZ_ASSERT(std::abs(d) < epsilon);
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}
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}
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#endif
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void TransformPoints(const Matrix4x4Typed<Units, Units>& aTransform,
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const bool aDivideByW)
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{
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for (Point4DType& point : mPoints) {
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point = aTransform.TransformPoint(point);
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if (aDivideByW && point.w > 0.0f) {
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point = point / point.w;
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}
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}
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}
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Point4DType mNormal;
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nsTArray<Point4DType> mPoints;
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};
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typedef PolygonTyped<UnknownUnits> Polygon;
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} // namespace gfx
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} // namespace mozilla
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#endif /* MOZILLA_GFX_POLYGON_H */
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