All Downloads are FREE. Search and download functionalities are using the official Maven repository.

org.apache.commons.math3.geometry.spherical.twod.SphericalPolygonsSet Maven / Gradle / Ivy

Go to download

The Apache Commons Math project is a library of lightweight, self-contained mathematics and statistics components addressing the most common practical problems not immediately available in the Java programming language or commons-lang.

There is a newer version: 62
Show newest version
/*
 * Licensed to the Apache Software Foundation (ASF) under one or more
 * contributor license agreements.  See the NOTICE file distributed with
 * this work for additional information regarding copyright ownership.
 * The ASF licenses this file to You under the Apache License, Version 2.0
 * (the "License"); you may not use this file except in compliance with
 * the License.  You may obtain a copy of the License at
 *
 *      http://www.apache.org/licenses/LICENSE-2.0
 *
 * Unless required by applicable law or agreed to in writing, software
 * distributed under the License is distributed on an "AS IS" BASIS,
 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 * See the License for the specific language governing permissions and
 * limitations under the License.
 */
package org.apache.commons.math3.geometry.spherical.twod;

import java.util.ArrayList;
import java.util.Collection;
import java.util.Collections;
import java.util.Iterator;
import java.util.List;

import org.apache.commons.math3.exception.MathIllegalStateException;
import org.apache.commons.math3.geometry.enclosing.EnclosingBall;
import org.apache.commons.math3.geometry.enclosing.WelzlEncloser;
import org.apache.commons.math3.geometry.euclidean.threed.Euclidean3D;
import org.apache.commons.math3.geometry.euclidean.threed.Rotation;
import org.apache.commons.math3.geometry.euclidean.threed.RotationConvention;
import org.apache.commons.math3.geometry.euclidean.threed.SphereGenerator;
import org.apache.commons.math3.geometry.euclidean.threed.Vector3D;
import org.apache.commons.math3.geometry.partitioning.AbstractRegion;
import org.apache.commons.math3.geometry.partitioning.BSPTree;
import org.apache.commons.math3.geometry.partitioning.BoundaryProjection;
import org.apache.commons.math3.geometry.partitioning.RegionFactory;
import org.apache.commons.math3.geometry.partitioning.SubHyperplane;
import org.apache.commons.math3.geometry.spherical.oned.Sphere1D;
import org.apache.commons.math3.util.FastMath;
import org.apache.commons.math3.util.MathUtils;

/** This class represents a region on the 2-sphere: a set of spherical polygons.
 * @since 3.3
 */
public class SphericalPolygonsSet extends AbstractRegion {

    /** Boundary defined as an array of closed loops start vertices. */
    private List loops;

    /** Build a polygons set representing the whole real 2-sphere.
     * @param tolerance below which points are consider to be identical
     */
    public SphericalPolygonsSet(final double tolerance) {
        super(tolerance);
    }

    /** Build a polygons set representing a hemisphere.
     * @param pole pole of the hemisphere (the pole is in the inside half)
     * @param tolerance below which points are consider to be identical
     */
    public SphericalPolygonsSet(final Vector3D pole, final double tolerance) {
        super(new BSPTree(new Circle(pole, tolerance).wholeHyperplane(),
                                    new BSPTree(Boolean.FALSE),
                                    new BSPTree(Boolean.TRUE),
                                    null),
              tolerance);
    }

    /** Build a polygons set representing a regular polygon.
     * @param center center of the polygon (the center is in the inside half)
     * @param meridian point defining the reference meridian for first polygon vertex
     * @param outsideRadius distance of the vertices to the center
     * @param n number of sides of the polygon
     * @param tolerance below which points are consider to be identical
     */
    public SphericalPolygonsSet(final Vector3D center, final Vector3D meridian,
                                final double outsideRadius, final int n,
                                final double tolerance) {
        this(tolerance, createRegularPolygonVertices(center, meridian, outsideRadius, n));
    }

    /** Build a polygons set from a BSP tree.
     * 

The leaf nodes of the BSP tree must have a * {@code Boolean} attribute representing the inside status of * the corresponding cell (true for inside cells, false for outside * cells). In order to avoid building too many small objects, it is * recommended to use the predefined constants * {@code Boolean.TRUE} and {@code Boolean.FALSE}

* @param tree inside/outside BSP tree representing the region * @param tolerance below which points are consider to be identical */ public SphericalPolygonsSet(final BSPTree tree, final double tolerance) { super(tree, tolerance); } /** Build a polygons set from a Boundary REPresentation (B-rep). *

The boundary is provided as a collection of {@link * SubHyperplane sub-hyperplanes}. Each sub-hyperplane has the * interior part of the region on its minus side and the exterior on * its plus side.

*

The boundary elements can be in any order, and can form * several non-connected sets (like for example polygons with holes * or a set of disjoint polygons considered as a whole). In * fact, the elements do not even need to be connected together * (their topological connections are not used here). However, if the * boundary does not really separate an inside open from an outside * open (open having here its topological meaning), then subsequent * calls to the {@link * org.apache.commons.math3.geometry.partitioning.Region#checkPoint(org.apache.commons.math3.geometry.Point) * checkPoint} method will not be meaningful anymore.

*

If the boundary is empty, the region will represent the whole * space.

* @param boundary collection of boundary elements, as a * collection of {@link SubHyperplane SubHyperplane} objects * @param tolerance below which points are consider to be identical */ public SphericalPolygonsSet(final Collection> boundary, final double tolerance) { super(boundary, tolerance); } /** Build a polygon from a simple list of vertices. *

The boundary is provided as a list of points considering to * represent the vertices of a simple loop. The interior part of the * region is on the left side of this path and the exterior is on its * right side.

*

This constructor does not handle polygons with a boundary * forming several disconnected paths (such as polygons with holes).

*

For cases where this simple constructor applies, it is expected to * be numerically more robust than the {@link #SphericalPolygonsSet(Collection, * double) general constructor} using {@link SubHyperplane subhyperplanes}.

*

If the list is empty, the region will represent the whole * space.

*

* Polygons with thin pikes or dents are inherently difficult to handle because * they involve circles with almost opposite directions at some vertices. Polygons * whose vertices come from some physical measurement with noise are also * difficult because an edge that should be straight may be broken in lots of * different pieces with almost equal directions. In both cases, computing the * circles intersections is not numerically robust due to the almost 0 or almost * π angle. Such cases need to carefully adjust the {@code hyperplaneThickness} * parameter. A too small value would often lead to completely wrong polygons * with large area wrongly identified as inside or outside. Large values are * often much safer. As a rule of thumb, a value slightly below the size of the * most accurate detail needed is a good value for the {@code hyperplaneThickness} * parameter. *

* @param hyperplaneThickness tolerance below which points are considered to * belong to the hyperplane (which is therefore more a slab) * @param vertices vertices of the simple loop boundary */ public SphericalPolygonsSet(final double hyperplaneThickness, final S2Point ... vertices) { super(verticesToTree(hyperplaneThickness, vertices), hyperplaneThickness); } /** Build the vertices representing a regular polygon. * @param center center of the polygon (the center is in the inside half) * @param meridian point defining the reference meridian for first polygon vertex * @param outsideRadius distance of the vertices to the center * @param n number of sides of the polygon * @return vertices array */ private static S2Point[] createRegularPolygonVertices(final Vector3D center, final Vector3D meridian, final double outsideRadius, final int n) { final S2Point[] array = new S2Point[n]; final Rotation r0 = new Rotation(Vector3D.crossProduct(center, meridian), outsideRadius, RotationConvention.VECTOR_OPERATOR); array[0] = new S2Point(r0.applyTo(center)); final Rotation r = new Rotation(center, MathUtils.TWO_PI / n, RotationConvention.VECTOR_OPERATOR); for (int i = 1; i < n; ++i) { array[i] = new S2Point(r.applyTo(array[i - 1].getVector())); } return array; } /** Build the BSP tree of a polygons set from a simple list of vertices. *

The boundary is provided as a list of points considering to * represent the vertices of a simple loop. The interior part of the * region is on the left side of this path and the exterior is on its * right side.

*

This constructor does not handle polygons with a boundary * forming several disconnected paths (such as polygons with holes).

*

This constructor handles only polygons with edges strictly shorter * than \( \pi \). If longer edges are needed, they need to be broken up * in smaller sub-edges so this constraint holds.

*

For cases where this simple constructor applies, it is expected to * be numerically more robust than the {@link #PolygonsSet(Collection) general * constructor} using {@link SubHyperplane subhyperplanes}.

* @param hyperplaneThickness tolerance below which points are consider to * belong to the hyperplane (which is therefore more a slab) * @param vertices vertices of the simple loop boundary * @return the BSP tree of the input vertices */ private static BSPTree verticesToTree(final double hyperplaneThickness, final S2Point ... vertices) { final int n = vertices.length; if (n == 0) { // the tree represents the whole space return new BSPTree(Boolean.TRUE); } // build the vertices final Vertex[] vArray = new Vertex[n]; for (int i = 0; i < n; ++i) { vArray[i] = new Vertex(vertices[i]); } // build the edges List edges = new ArrayList(n); Vertex end = vArray[n - 1]; for (int i = 0; i < n; ++i) { // get the endpoints of the edge final Vertex start = end; end = vArray[i]; // get the circle supporting the edge, taking care not to recreate it // if it was already created earlier due to another edge being aligned // with the current one Circle circle = start.sharedCircleWith(end); if (circle == null) { circle = new Circle(start.getLocation(), end.getLocation(), hyperplaneThickness); } // create the edge and store it edges.add(new Edge(start, end, Vector3D.angle(start.getLocation().getVector(), end.getLocation().getVector()), circle)); // check if another vertex also happens to be on this circle for (final Vertex vertex : vArray) { if (vertex != start && vertex != end && FastMath.abs(circle.getOffset(vertex.getLocation())) <= hyperplaneThickness) { vertex.bindWith(circle); } } } // build the tree top-down final BSPTree tree = new BSPTree(); insertEdges(hyperplaneThickness, tree, edges); return tree; } /** Recursively build a tree by inserting cut sub-hyperplanes. * @param hyperplaneThickness tolerance below which points are considered to * belong to the hyperplane (which is therefore more a slab) * @param node current tree node (it is a leaf node at the beginning * of the call) * @param edges list of edges to insert in the cell defined by this node * (excluding edges not belonging to the cell defined by this node) */ private static void insertEdges(final double hyperplaneThickness, final BSPTree node, final List edges) { // find an edge with an hyperplane that can be inserted in the node int index = 0; Edge inserted = null; while (inserted == null && index < edges.size()) { inserted = edges.get(index++); if (!node.insertCut(inserted.getCircle())) { inserted = null; } } if (inserted == null) { // no suitable edge was found, the node remains a leaf node // we need to set its inside/outside boolean indicator final BSPTree parent = node.getParent(); if (parent == null || node == parent.getMinus()) { node.setAttribute(Boolean.TRUE); } else { node.setAttribute(Boolean.FALSE); } return; } // we have split the node by inserting an edge as a cut sub-hyperplane // distribute the remaining edges in the two sub-trees final List outsideList = new ArrayList(); final List insideList = new ArrayList(); for (final Edge edge : edges) { if (edge != inserted) { edge.split(inserted.getCircle(), outsideList, insideList); } } // recurse through lower levels if (!outsideList.isEmpty()) { insertEdges(hyperplaneThickness, node.getPlus(), outsideList); } else { node.getPlus().setAttribute(Boolean.FALSE); } if (!insideList.isEmpty()) { insertEdges(hyperplaneThickness, node.getMinus(), insideList); } else { node.getMinus().setAttribute(Boolean.TRUE); } } /** {@inheritDoc} */ @Override public SphericalPolygonsSet buildNew(final BSPTree tree) { return new SphericalPolygonsSet(tree, getTolerance()); } /** {@inheritDoc} * @exception MathIllegalStateException if the tolerance setting does not allow to build * a clean non-ambiguous boundary */ @Override protected void computeGeometricalProperties() throws MathIllegalStateException { final BSPTree tree = getTree(true); if (tree.getCut() == null) { // the instance has a single cell without any boundaries if (tree.getCut() == null && (Boolean) tree.getAttribute()) { // the instance covers the whole space setSize(4 * FastMath.PI); setBarycenter(new S2Point(0, 0)); } else { setSize(0); setBarycenter(S2Point.NaN); } } else { // the instance has a boundary final PropertiesComputer pc = new PropertiesComputer(getTolerance()); tree.visit(pc); setSize(pc.getArea()); setBarycenter(pc.getBarycenter()); } } /** Get the boundary loops of the polygon. *

The polygon boundary can be represented as a list of closed loops, * each loop being given by exactly one of its vertices. From each loop * start vertex, one can follow the loop by finding the outgoing edge, * then the end vertex, then the next outgoing edge ... until the start * vertex of the loop (exactly the same instance) is found again once * the full loop has been visited.

*

If the polygon has no boundary at all, a zero length loop * array will be returned.

*

If the polygon is a simple one-piece polygon, then the returned * array will contain a single vertex. *

*

All edges in the various loops have the inside of the region on * their left side (i.e. toward their pole) and the outside on their * right side (i.e. away from their pole) when moving in the underlying * circle direction. This means that the closed loops obey the direct * trigonometric orientation.

* @return boundary of the polygon, organized as an unmodifiable list of loops start vertices. * @exception MathIllegalStateException if the tolerance setting does not allow to build * a clean non-ambiguous boundary * @see Vertex * @see Edge */ public List getBoundaryLoops() throws MathIllegalStateException { if (loops == null) { if (getTree(false).getCut() == null) { loops = Collections.emptyList(); } else { // sort the arcs according to their start point final BSPTree root = getTree(true); final EdgesBuilder visitor = new EdgesBuilder(root, getTolerance()); root.visit(visitor); final List edges = visitor.getEdges(); // convert the list of all edges into a list of start vertices loops = new ArrayList(); while (!edges.isEmpty()) { // this is an edge belonging to a new loop, store it Edge edge = edges.get(0); final Vertex startVertex = edge.getStart(); loops.add(startVertex); // remove all remaining edges in the same loop do { // remove one edge for (final Iterator iterator = edges.iterator(); iterator.hasNext();) { if (iterator.next() == edge) { iterator.remove(); break; } } // go to next edge following the boundary loop edge = edge.getEnd().getOutgoing(); } while (edge.getStart() != startVertex); } } } return Collections.unmodifiableList(loops); } /** Get a spherical cap enclosing the polygon. *

* This method is intended as a first test to quickly identify points * that are guaranteed to be outside of the region, hence performing a full * {@link #checkPoint(org.apache.commons.math3.geometry.Vector) checkPoint} * only if the point status remains undecided after the quick check. It is * is therefore mostly useful to speed up computation for small polygons with * complex shapes (say a country boundary on Earth), as the spherical cap will * be small and hence will reliably identify a large part of the sphere as outside, * whereas the full check can be more computing intensive. A typical use case is * therefore: *

*
     *   // compute region, plus an enclosing spherical cap
     *   SphericalPolygonsSet complexShape = ...;
     *   EnclosingBall cap = complexShape.getEnclosingCap();
     *
     *   // check lots of points
     *   for (Vector3D p : points) {
     *
     *     final Location l;
     *     if (cap.contains(p)) {
     *       // we cannot be sure where the point is
     *       // we need to perform the full computation
     *       l = complexShape.checkPoint(v);
     *     } else {
     *       // no need to do further computation,
     *       // we already know the point is outside
     *       l = Location.OUTSIDE;
     *     }
     *
     *     // use l ...
     *
     *   }
     * 
*

* In the special cases of empty or whole sphere polygons, special * spherical caps are returned, with angular radius set to negative * or positive infinity so the {@link * EnclosingBall#contains(org.apache.commons.math3.geometry.Point) ball.contains(point)} * method return always false or true. *

*

* This method is not guaranteed to return the smallest enclosing cap. *

* @return a spherical cap enclosing the polygon */ public EnclosingBall getEnclosingCap() { // handle special cases first if (isEmpty()) { return new EnclosingBall(S2Point.PLUS_K, Double.NEGATIVE_INFINITY); } if (isFull()) { return new EnclosingBall(S2Point.PLUS_K, Double.POSITIVE_INFINITY); } // as the polygons is neither empty nor full, it has some boundaries and cut hyperplanes final BSPTree root = getTree(false); if (isEmpty(root.getMinus()) && isFull(root.getPlus())) { // the polygon covers an hemisphere, and its boundary is one 2π long edge final Circle circle = (Circle) root.getCut().getHyperplane(); return new EnclosingBall(new S2Point(circle.getPole()).negate(), 0.5 * FastMath.PI); } if (isFull(root.getMinus()) && isEmpty(root.getPlus())) { // the polygon covers an hemisphere, and its boundary is one 2π long edge final Circle circle = (Circle) root.getCut().getHyperplane(); return new EnclosingBall(new S2Point(circle.getPole()), 0.5 * FastMath.PI); } // gather some inside points, to be used by the encloser final List points = getInsidePoints(); // extract points from the boundary loops, to be used by the encloser as well final List boundary = getBoundaryLoops(); for (final Vertex loopStart : boundary) { int count = 0; for (Vertex v = loopStart; count == 0 || v != loopStart; v = v.getOutgoing().getEnd()) { ++count; points.add(v.getLocation().getVector()); } } // find the smallest enclosing 3D sphere final SphereGenerator generator = new SphereGenerator(); final WelzlEncloser encloser = new WelzlEncloser(getTolerance(), generator); EnclosingBall enclosing3D = encloser.enclose(points); final Vector3D[] support3D = enclosing3D.getSupport(); // convert to 3D sphere to spherical cap final double r = enclosing3D.getRadius(); final double h = enclosing3D.getCenter().getNorm(); if (h < getTolerance()) { // the 3D sphere is centered on the unit sphere and covers it // fall back to a crude approximation, based only on outside convex cells EnclosingBall enclosingS2 = new EnclosingBall(S2Point.PLUS_K, Double.POSITIVE_INFINITY); for (Vector3D outsidePoint : getOutsidePoints()) { final S2Point outsideS2 = new S2Point(outsidePoint); final BoundaryProjection projection = projectToBoundary(outsideS2); if (FastMath.PI - projection.getOffset() < enclosingS2.getRadius()) { enclosingS2 = new EnclosingBall(outsideS2.negate(), FastMath.PI - projection.getOffset(), (S2Point) projection.getProjected()); } } return enclosingS2; } final S2Point[] support = new S2Point[support3D.length]; for (int i = 0; i < support3D.length; ++i) { support[i] = new S2Point(support3D[i]); } final EnclosingBall enclosingS2 = new EnclosingBall(new S2Point(enclosing3D.getCenter()), FastMath.acos((1 + h * h - r * r) / (2 * h)), support); return enclosingS2; } /** Gather some inside points. * @return list of points known to be strictly in all inside convex cells */ private List getInsidePoints() { final PropertiesComputer pc = new PropertiesComputer(getTolerance()); getTree(true).visit(pc); return pc.getConvexCellsInsidePoints(); } /** Gather some outside points. * @return list of points known to be strictly in all outside convex cells */ private List getOutsidePoints() { final SphericalPolygonsSet complement = (SphericalPolygonsSet) new RegionFactory().getComplement(this); final PropertiesComputer pc = new PropertiesComputer(getTolerance()); complement.getTree(true).visit(pc); return pc.getConvexCellsInsidePoints(); } }




© 2015 - 2024 Weber Informatics LLC | Privacy Policy