com.vividsolutions.jts.triangulate.quadedge.Vertex Maven / Gradle / Ivy
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/*
* The JTS Topology Suite is a collection of Java classes that
* implement the fundamental operations required to validate a given
* geo-spatial data set to a known topological specification.
*
* Copyright (C) 2001 Vivid Solutions
*
* This library is free software; you can redistribute it and/or
* modify it under the terms of the GNU Lesser General Public
* License as published by the Free Software Foundation; either
* version 2.1 of the License, or (at your option) any later version.
*
* This library is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
* Lesser General Public License for more details.
*
* You should have received a copy of the GNU Lesser General Public
* License along with this library; if not, write to the Free Software
* Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
*
* For more information, contact:
*
* Vivid Solutions
* Suite #1A
* 2328 Government Street
* Victoria BC V8T 5G5
* Canada
*
* (250)385-6040
* www.vividsolutions.com
*/
package com.vividsolutions.jts.triangulate.quadedge;
import com.vividsolutions.jts.geom.Coordinate;
import com.vividsolutions.jts.geom.Triangle;
import com.vividsolutions.jts.geom.impl.CoordinateArraySequence;
import com.vividsolutions.jts.io.WKTWriter;
import com.vividsolutions.jts.algorithm.*;
/**
* Models a site (node) in a {@link QuadEdgeSubdivision}.
* The sites can be points on a line string representing a
* linear site.
*
* The vertex can be considered as a vector with a norm, length, inner product, cross
* product, etc. Additionally, point relations (e.g., is a point to the left of a line, the circle
* defined by this point and two others, etc.) are also defined in this class.
*
* It is common to want to attach user-defined data to
* the vertices of a subdivision.
* One way to do this is to subclass Vertex
* to carry any desired information.
*
* @author David Skea
* @author Martin Davis
*/
public class Vertex
{
public static final int LEFT = 0;
public static final int RIGHT = 1;
public static final int BEYOND = 2;
public static final int BEHIND = 3;
public static final int BETWEEN = 4;
public static final int ORIGIN = 5;
public static final int DESTINATION = 6;
private Coordinate p;
// private int edgeNumber = -1;
public Vertex(double _x, double _y) {
p = new Coordinate(_x, _y);
}
public Vertex(double _x, double _y, double _z) {
p = new Coordinate(_x, _y, _z);
}
public Vertex(Coordinate _p) {
p = new Coordinate(_p);
}
public double getX() {
return p.x;
}
public double getY() {
return p.y;
}
public double getZ() {
return p.z;
}
public void setZ(double _z) {
p.z = _z;
}
public Coordinate getCoordinate() {
return p;
}
public String toString() {
return "POINT (" + p.x + " " + p.y + ")";
}
public boolean equals(Vertex _x) {
if (p.x == _x.getX() && p.y == _x.getY()) {
return true;
} else {
return false;
}
}
public boolean equals(Vertex _x, double tolerance) {
if (p.distance(_x.getCoordinate()) < tolerance) {
return true;
} else {
return false;
}
}
public int classify(Vertex p0, Vertex p1) {
Vertex p2 = this;
Vertex a = p1.sub(p0);
Vertex b = p2.sub(p0);
double sa = a.crossProduct(b);
if (sa > 0.0)
return LEFT;
if (sa < 0.0)
return RIGHT;
if ((a.getX() * b.getX() < 0.0) || (a.getY() * b.getY() < 0.0))
return BEHIND;
if (a.magn() < b.magn())
return BEYOND;
if (p0.equals(p2))
return ORIGIN;
if (p1.equals(p2))
return DESTINATION;
return BETWEEN;
}
/**
* Computes the cross product k = u X v.
*
* @param v a vertex
* @return returns the magnitude of u X v
*/
double crossProduct(Vertex v) {
return (p.x * v.getY() - p.y * v.getX());
}
/**
* Computes the inner or dot product
*
* @param v a vertex
* @return returns the dot product u.v
*/
double dot(Vertex v) {
return (p.x * v.getX() + p.y * v.getY());
}
/**
* Computes the scalar product c(v)
*
* @param v a vertex
* @return returns the scaled vector
*/
Vertex times(double c) {
return (new Vertex(c * p.x, c * p.y));
}
/* Vector addition */
Vertex sum(Vertex v) {
return (new Vertex(p.x + v.getX(), p.y + v.getY()));
}
/* and subtraction */
Vertex sub(Vertex v) {
return (new Vertex(p.x - v.getX(), p.y - v.getY()));
}
/* magnitude of vector */
double magn() {
return (Math.sqrt(p.x * p.x + p.y * p.y));
}
/* returns k X v (cross product). this is a vector perpendicular to v */
Vertex cross() {
return (new Vertex(p.y, -p.x));
}
/** ************************************************************* */
/***********************************************************************************************
* Geometric primitives /
**********************************************************************************************/
/**
* Tests if the vertex is inside the circle defined by
* the triangle with vertices a, b, c (oriented counter-clockwise).
*
* @param a a vertex of the triangle
* @param b a vertex of the triangle
* @param c a vertex of the triangle
* @return true if this vertex is in the circumcircle of (a,b,c)
*/
public boolean isInCircle(Vertex a, Vertex b, Vertex c)
{
return TrianglePredicate.isInCircleRobust(a.p, b.p, c.p, this.p);
// non-robust - best to not use
//return TrianglePredicate.isInCircle(a.p, b.p, c.p, this.p);
}
/**
* Tests whether the triangle formed by this vertex and two
* other vertices is in CCW orientation.
*
* @param b a vertex
* @param c a vertex
* @returns true if the triangle is oriented CCW
*/
public final boolean isCCW(Vertex b, Vertex c)
{
/*
// test code used to check for robustness of triArea
boolean isCCW = (b.p.x - p.x) * (c.p.y - p.y)
- (b.p.y - p.y) * (c.p.x - p.x) > 0;
//boolean isCCW = triArea(this, b, c) > 0;
boolean isCCWRobust = CGAlgorithms.orientationIndex(p, b.p, c.p) == CGAlgorithms.COUNTERCLOCKWISE;
if (isCCWRobust != isCCW)
System.out.println("CCW failure");
//*/
// is equal to the signed area of the triangle
return (b.p.x - p.x) * (c.p.y - p.y)
- (b.p.y - p.y) * (c.p.x - p.x) > 0;
// original rolled code
//boolean isCCW = triArea(this, b, c) > 0;
//return isCCW;
}
public final boolean rightOf(QuadEdge e) {
return isCCW(e.dest(), e.orig());
}
public final boolean leftOf(QuadEdge e) {
return isCCW(e.orig(), e.dest());
}
private HCoordinate bisector(Vertex a, Vertex b) {
// returns the perpendicular bisector of the line segment ab
double dx = b.getX() - a.getX();
double dy = b.getY() - a.getY();
HCoordinate l1 = new HCoordinate(a.getX() + dx / 2.0, a.getY() + dy / 2.0, 1.0);
HCoordinate l2 = new HCoordinate(a.getX() - dy + dx / 2.0, a.getY() + dx + dy / 2.0, 1.0);
return new HCoordinate(l1, l2);
}
private double distance(Vertex v1, Vertex v2) {
return Math.sqrt(Math.pow(v2.getX() - v1.getX(), 2.0)
+ Math.pow(v2.getY() - v1.getY(), 2.0));
}
/**
* Computes the value of the ratio of the circumradius to shortest edge. If smaller than some
* given tolerance B, the associated triangle is considered skinny. For an equal lateral
* triangle this value is 0.57735. The ratio is related to the minimum triangle angle theta by:
* circumRadius/shortestEdge = 1/(2sin(theta)).
*
* @param b second vertex of the triangle
* @param c third vertex of the triangle
* @return ratio of circumradius to shortest edge.
*/
public double circumRadiusRatio(Vertex b, Vertex c) {
Vertex x = this.circleCenter(b, c);
double radius = distance(x, b);
double edgeLength = distance(this, b);
double el = distance(b, c);
if (el < edgeLength) {
edgeLength = el;
}
el = distance(c, this);
if (el < edgeLength) {
edgeLength = el;
}
return radius / edgeLength;
}
/**
* returns a new vertex that is mid-way between this vertex and another end point.
*
* @param a the other end point.
* @return the point mid-way between this and that.
*/
public Vertex midPoint(Vertex a) {
double xm = (p.x + a.getX()) / 2.0;
double ym = (p.y + a.getY()) / 2.0;
double zm = (p.z + a.getZ()) / 2.0;
return new Vertex(xm, ym, zm);
}
/**
* Computes the centre of the circumcircle of this vertex and two others.
*
* @param b
* @param c
* @return the Coordinate which is the circumcircle of the 3 points.
*/
public Vertex circleCenter(Vertex b, Vertex c) {
Vertex a = new Vertex(this.getX(), this.getY());
// compute the perpendicular bisector of cord ab
HCoordinate cab = bisector(a, b);
// compute the perpendicular bisector of cord bc
HCoordinate cbc = bisector(b, c);
// compute the intersection of the bisectors (circle radii)
HCoordinate hcc = new HCoordinate(cab, cbc);
Vertex cc = null;
try {
cc = new Vertex(hcc.getX(), hcc.getY());
} catch (NotRepresentableException nre) {
System.err.println("a: " + a + " b: " + b + " c: " + c);
System.err.println(nre);
}
return cc;
}
/**
* For this vertex enclosed in a triangle defined by three vertices v0, v1 and v2, interpolate
* a z value from the surrounding vertices.
*/
public double interpolateZValue(Vertex v0, Vertex v1, Vertex v2) {
double x0 = v0.getX();
double y0 = v0.getY();
double a = v1.getX() - x0;
double b = v2.getX() - x0;
double c = v1.getY() - y0;
double d = v2.getY() - y0;
double det = a * d - b * c;
double dx = this.getX() - x0;
double dy = this.getY() - y0;
double t = (d * dx - b * dy) / det;
double u = (-c * dx + a * dy) / det;
double z = v0.getZ() + t * (v1.getZ() - v0.getZ()) + u * (v2.getZ() - v0.getZ());
return z;
}
/**
* Interpolates the Z-value (height) of a point enclosed in a triangle
* whose vertices all have Z values.
* The containing triangle must not be degenerate
* (in other words, the three vertices must enclose a
* non-zero area).
*
* @param p the point to interpolate the Z value of
* @param v0 a vertex of a triangle containing the p
* @param v1 a vertex of a triangle containing the p
* @param v2 a vertex of a triangle containing the p
* @return the interpolated Z-value (height) of the point
*/
public static double interpolateZ(Coordinate p, Coordinate v0, Coordinate v1, Coordinate v2) {
double x0 = v0.x;
double y0 = v0.y;
double a = v1.x - x0;
double b = v2.x - x0;
double c = v1.y - y0;
double d = v2.y - y0;
double det = a * d - b * c;
double dx = p.x - x0;
double dy = p.y - y0;
double t = (d * dx - b * dy) / det;
double u = (-c * dx + a * dy) / det;
double z = v0.z + t * (v1.z - v0.z) + u * (v2.z - v0.z);
return z;
}
/**
* Computes the interpolated Z-value for a point p lying on the segment p0-p1
*
* @param p
* @param p0
* @param p1
* @return the interpolated Z value
*/
public static double interpolateZ(Coordinate p, Coordinate p0, Coordinate p1) {
double segLen = p0.distance(p1);
double ptLen = p.distance(p0);
double dz = p1.z - p0.z;
double pz = p0.z + dz * (ptLen / segLen);
return pz;
}
}