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/*
* Copyright 1996-2008 Sun Microsystems, Inc. All Rights Reserved.
* DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
*
* This code is free software; you can redistribute it and/or modify it
* under the terms of the GNU General Public License version 2 only, as
* published by the Free Software Foundation. Sun designates this
* particular file as subject to the "Classpath" exception as provided
* by Sun in the LICENSE file that accompanied this code.
*
* This code 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 General Public License
* version 2 for more details (a copy is included in the LICENSE file that
* accompanied this code).
*
* You should have received a copy of the GNU General Public License version
* 2 along with this work; if not, write to the Free Software Foundation,
* Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
*
* Please contact Sun Microsystems, Inc., 4150 Network Circle, Santa Clara,
* CA 95054 USA or visit www.sun.com if you need additional information or
* have any questions.
*
*/
package javax.media.j3d;
import javax.vecmath.Point3d;
import javax.vecmath.Point4d;
import javax.vecmath.Vector3d;
import javax.vecmath.Vector4d;
/**
* This class defines an axis aligned bounding box which is used for
* bounding regions.
*
*/
public class BoundingBox extends Bounds {
/**
* The corner of the bounding box with the numerically smallest values.
*/
final Point3d lower;
/**
* The corner of the bounding box with the numerically largest values.
*/
final Point3d upper;
private static final double EPS = 1.0E-8;
/**
* Constructs and initializes a BoundingBox given min,max in x,y,z.
* @param lower the "small" corner
* @param upper the "large" corner
*/
public BoundingBox(Point3d lower, Point3d upper) {
boundId = BOUNDING_BOX;
this.lower = new Point3d(lower);
this.upper = new Point3d(upper);
updateBoundsStates();
}
/**
* Constructs and initializes a 2X bounding box about the origin. The lower
* corner is initialized to (-1.0d, -1.0d, -1.0d) and the upper corner is
* initialized to (1.0d, 1.0d, 1.0d).
*/
public BoundingBox() {
boundId = BOUNDING_BOX;
lower = new Point3d(-1.0d, -1.0d, -1.0d);
upper = new Point3d( 1.0d, 1.0d, 1.0d);
boundsIsEmpty = false;
boundsIsInfinite = false;
}
/**
* Constructs a BoundingBox from a bounding object.
* @param boundsObject a bounds object
*/
public BoundingBox(Bounds boundsObject) {
boundId = BOUNDING_BOX;
lower = new Point3d();
upper = new Point3d();
if (boundsObject == null || boundsObject.boundsIsEmpty) {
setEmptyBounds();
return;
}
if (boundsObject.boundsIsInfinite) {
setInfiniteBounds();
return;
}
if( boundsObject.boundId == BOUNDING_BOX){
BoundingBox box = (BoundingBox)boundsObject;
lower.set(box.lower);
upper.set(box.upper);
}
else if( boundsObject.boundId == BOUNDING_SPHERE ) {
BoundingSphere sphere = (BoundingSphere)boundsObject;
lower.set(sphere.center.x - sphere.radius,
sphere.center.y - sphere.radius,
sphere.center.z - sphere.radius);
upper.set(sphere.center.x + sphere.radius,
sphere.center.y + sphere.radius,
sphere.center.z + sphere.radius);
}
else if(boundsObject.boundId == BOUNDING_POLYTOPE) {
BoundingPolytope polytope = (BoundingPolytope)boundsObject;
if( polytope.nVerts < 1 ) { // handle degenerate case
lower.set(-1.0d, -1.0d, -1.0d);
upper.set( 1.0d, 1.0d, 1.0d);
} else {
lower.set(polytope.verts[0]);
upper.set(polytope.verts[0]);
for(int i=1;i upper.x )
upper.x = polytope.verts[i].x;
if( polytope.verts[i].y > upper.y )
upper.y = polytope.verts[i].y;
if( polytope.verts[i].z > upper.z )
upper.z = polytope.verts[i].z;
}
}
} else {
throw new IllegalArgumentException(J3dI18N.getString("BoundingBox0"));
}
updateBoundsStates();
}
/**
* Constructs a BoundingBox from an array of bounding objects.
* @param bounds an array of bounding objects
*/
public BoundingBox(Bounds[] bounds) {
boundId = BOUNDING_BOX;
upper = new Point3d();
lower = new Point3d();
if (bounds == null || bounds.length <= 0) {
setEmptyBounds();
return;
}
int i = 0;
// find first non empty bounds object
while ((i < bounds.length) && ((bounds[i] == null) || bounds[i].boundsIsEmpty)) {
i++;
}
if (i >= bounds.length) {
// all bounds objects were empty
setEmptyBounds();
return;
}
this.set(bounds[i++]);
if(boundsIsInfinite)
return;
for(;i box.lower.x) lower.x = box.lower.x;
if( lower.y > box.lower.y) lower.y = box.lower.y;
if( lower.z > box.lower.z) lower.z = box.lower.z;
if( upper.x < box.upper.x) upper.x = box.upper.x;
if( upper.y < box.upper.y) upper.y = box.upper.y;
if( upper.z < box.upper.z) upper.z = box.upper.z;
}
else if(bounds[i].boundId == BOUNDING_SPHERE) {
BoundingSphere sphere = (BoundingSphere)bounds[i];
if( lower.x > (sphere.center.x - sphere.radius))
lower.x = sphere.center.x - sphere.radius;
if( lower.y > (sphere.center.y - sphere.radius))
lower.y = sphere.center.y - sphere.radius;
if( lower.z > (sphere.center.z - sphere.radius))
lower.z = sphere.center.z - sphere.radius;
if( upper.x < (sphere.center.x + sphere.radius))
upper.x = sphere.center.x + sphere.radius;
if( upper.y < (sphere.center.y + sphere.radius))
upper.y = sphere.center.y + sphere.radius;
if( upper.z < (sphere.center.z + sphere.radius))
upper.z = sphere.center.z + sphere.radius;
}
else if(bounds[i].boundId == BOUNDING_POLYTOPE) {
BoundingPolytope polytope = (BoundingPolytope)bounds[i];
for(i=0;i upper.x )
upper.x = polytope.verts[i].x;
if( polytope.verts[i].y > upper.y )
upper.y = polytope.verts[i].y;
if( polytope.verts[i].z > upper.z )
upper.z = polytope.verts[i].z;
}
}
else {
throw new IllegalArgumentException(J3dI18N.getString("BoundingBox1"));
}
}
updateBoundsStates();
}
/**
* Gets the lower corner of this bounding box.
* @param p1 a Point to receive the lower corner of the bounding box
*/
public void getLower(Point3d p1) {
p1.set(lower);
}
/**
* Sets the lower corner of this bounding box.
* @param xmin minimum x value of bounding box
* @param ymin minimum y value of bounding box
* @param zmin minimum z value of bounding box
*/
public void setLower(double xmin, double ymin, double zmin) {
lower.set(xmin, ymin, zmin);
updateBoundsStates();
}
/**
* Sets the lower corner of this bounding box.
* @param p1 a Point defining the new lower corner of the bounding box
*/
public void setLower(Point3d p1) {
lower.set(p1);
updateBoundsStates();
}
/**
* Gets the upper corner of this bounding box.
* @param p1 a Point to receive the upper corner of the bounding box
*/
public void getUpper(Point3d p1) {
p1.set(upper);
}
/**
* Sets the upper corner of this bounding box.
* @param xmax max x value of bounding box
* @param ymax max y value of bounding box
* @param zmax max z value of bounding box
*/
public void setUpper(double xmax, double ymax, double zmax) {
upper.set(xmax, ymax, zmax);
updateBoundsStates();
}
/**
* Sets the upper corner of this bounding box.
* @param p1 a Point defining the new upper corner of the bounding box
*/
public void setUpper(Point3d p1) {
upper.set(p1);
updateBoundsStates();
}
/**
* Sets the the value of this BoundingBox
* @param boundsObject another bounds object
*/
@Override
public void set(Bounds boundsObject) {
int i;
if (boundsObject == null || boundsObject.boundsIsEmpty) {
setEmptyBounds();
return;
}
if (boundsObject.boundsIsInfinite) {
setInfiniteBounds();
return;
}
if( boundsObject.boundId == BOUNDING_BOX){
BoundingBox box = (BoundingBox)boundsObject;
lower.x = box.lower.x;
lower.y = box.lower.y;
lower.z = box.lower.z;
upper.x = box.upper.x;
upper.y = box.upper.y;
upper.z = box.upper.z;
} else if( boundsObject.boundId == BOUNDING_SPHERE ) {
BoundingSphere sphere = (BoundingSphere)boundsObject;
lower.x = sphere.center.x - sphere.radius;
lower.y = sphere.center.y - sphere.radius;
lower.z = sphere.center.z - sphere.radius;
upper.x = sphere.center.x + sphere.radius;
upper.y = sphere.center.y + sphere.radius;
upper.z = sphere.center.z + sphere.radius;
} else if(boundsObject.boundId == BOUNDING_POLYTOPE) {
BoundingPolytope polytope = (BoundingPolytope)boundsObject;
lower.x = upper.x = polytope.verts[0].x;
lower.y = upper.y = polytope.verts[0].y;
lower.z = upper.z = polytope.verts[0].z;
for(i=1;i upper.x ) upper.x = polytope.verts[i].x;
if( polytope.verts[i].y > upper.y ) upper.y = polytope.verts[i].y;
if( polytope.verts[i].z > upper.z ) upper.z = polytope.verts[i].z;
}
} else {
throw new IllegalArgumentException(J3dI18N.getString("BoundingBox0"));
}
updateBoundsStates();
}
/**
* Creates a copy of this bounding box.
* @return a new bounding box
*/
@Override
public Object clone() {
return new BoundingBox(this.lower, this.upper);
}
/**
* Indicates whether the specified bounds object is
* equal to this BoundingBox object. They are equal if the
* specified bounds object is an instance of
* BoundingBox and all of the data
* members of bounds are equal to the corresponding
* data members in this BoundingBox.
* @param bounds the object with which the comparison is made.
* @return true if this BoundingBox is equal to bounds;
* otherwise false
*
* @since Java 3D 1.2
*/
@Override
public boolean equals(Object bounds) {
try {
BoundingBox box = (BoundingBox)bounds;
return (lower.equals(box.lower) &&
upper.equals(box.upper));
}
catch (NullPointerException e) {
return false;
}
catch (ClassCastException e) {
return false;
}
}
/**
* Returns a hash code value for this BoundingBox object
* based on the data values in this object. Two different
* BoundingBox objects with identical data values (i.e.,
* BoundingBox.equals returns true) will return the same hash
* code value. Two BoundingBox objects with different data
* members may return the same hash code value, although this is
* not likely.
* @return a hash code value for this BoundingBox object.
*
* @since Java 3D 1.2
*/
@Override
public int hashCode() {
long bits = 1L;
bits = J3dHash.mixDoubleBits(bits, lower.x);
bits = J3dHash.mixDoubleBits(bits, lower.y);
bits = J3dHash.mixDoubleBits(bits, lower.z);
bits = J3dHash.mixDoubleBits(bits, upper.x);
bits = J3dHash.mixDoubleBits(bits, upper.y);
bits = J3dHash.mixDoubleBits(bits, upper.z);
return J3dHash.finish(bits);
}
/**
* Combines this bounding box with a bounding object so that the
* resulting bounding box encloses the original bounding box and the
* specified bounds object.
* @param boundsObject another bounds object
*/
@Override
public void combine(Bounds boundsObject) {
if((boundsObject == null) || (boundsObject.boundsIsEmpty)
|| (boundsIsInfinite))
return;
if((boundsIsEmpty) || (boundsObject.boundsIsInfinite)) {
this.set(boundsObject);
return;
}
if( boundsObject.boundId == BOUNDING_BOX){
BoundingBox box = (BoundingBox)boundsObject;
if( lower.x > box.lower.x) lower.x = box.lower.x;
if( lower.y > box.lower.y) lower.y = box.lower.y;
if( lower.z > box.lower.z) lower.z = box.lower.z;
if( upper.x < box.upper.x) upper.x = box.upper.x;
if( upper.y < box.upper.y) upper.y = box.upper.y;
if( upper.z < box.upper.z) upper.z = box.upper.z;
}
else if( boundsObject.boundId == BOUNDING_SPHERE ) {
BoundingSphere sphere = (BoundingSphere)boundsObject;
if( lower.x > (sphere.center.x - sphere.radius))
lower.x = sphere.center.x - sphere.radius;
if( lower.y > (sphere.center.y - sphere.radius))
lower.y = sphere.center.y - sphere.radius;
if( lower.z > (sphere.center.z - sphere.radius))
lower.z = sphere.center.z - sphere.radius;
if( upper.x < (sphere.center.x + sphere.radius))
upper.x = sphere.center.x + sphere.radius;
if( upper.y < (sphere.center.y + sphere.radius))
upper.y = sphere.center.y + sphere.radius;
if( upper.z < (sphere.center.z + sphere.radius))
upper.z = sphere.center.z + sphere.radius;
}
else if(boundsObject.boundId == BOUNDING_POLYTOPE) {
BoundingPolytope polytope = (BoundingPolytope)boundsObject;
int i;
for(i=1;i upper.x ) upper.x = polytope.verts[i].x;
if( polytope.verts[i].y > upper.y ) upper.y = polytope.verts[i].y;
if( polytope.verts[i].z > upper.z ) upper.z = polytope.verts[i].z;
}
} else {
throw new IllegalArgumentException(J3dI18N.getString("BoundingBox3"));
}
updateBoundsStates();
}
/**
* Combines this bounding box with an array of bounding objects
* so that the resulting bounding box encloses the original bounding
* box and the array of bounding objects.
* @param bounds an array of bounds objects
*/
@Override
public void combine(Bounds[] bounds) {
int i=0;
if( (bounds == null) || (bounds.length <= 0)
|| (boundsIsInfinite))
return;
// find first non empty bounds object
while( (i= bounds.length)
return; // no non empty bounds so do not modify current bounds
if(boundsIsEmpty)
this.set(bounds[i++]);
if(boundsIsInfinite)
return;
for(;i box.lower.x) lower.x = box.lower.x;
if( lower.y > box.lower.y) lower.y = box.lower.y;
if( lower.z > box.lower.z) lower.z = box.lower.z;
if( upper.x < box.upper.x) upper.x = box.upper.x;
if( upper.y < box.upper.y) upper.y = box.upper.y;
if( upper.z < box.upper.z) upper.z = box.upper.z;
}
else if( bounds[i].boundId == BOUNDING_SPHERE ) {
BoundingSphere sphere = (BoundingSphere)bounds[i];
if( lower.x > (sphere.center.x - sphere.radius))
lower.x = sphere.center.x - sphere.radius;
if( lower.y > (sphere.center.y - sphere.radius))
lower.y = sphere.center.y - sphere.radius;
if( lower.z > (sphere.center.z - sphere.radius))
lower.z = sphere.center.z - sphere.radius;
if( upper.x < (sphere.center.x + sphere.radius))
upper.x = sphere.center.x + sphere.radius;
if( upper.y < (sphere.center.y + sphere.radius))
upper.y = sphere.center.y + sphere.radius;
if( upper.z < (sphere.center.z + sphere.radius))
upper.z = sphere.center.z + sphere.radius;
}
else if(bounds[i].boundId == BOUNDING_POLYTOPE) {
BoundingPolytope polytope = (BoundingPolytope)bounds[i];
for(i=1;i upper.x ) upper.x = polytope.verts[i].x;
if( polytope.verts[i].y > upper.y ) upper.y = polytope.verts[i].y;
if( polytope.verts[i].z > upper.z ) upper.z = polytope.verts[i].z;
}
} else {
throw new IllegalArgumentException(J3dI18N.getString("BoundingBox4"));
}
}
updateBoundsStates();
}
/**
* Combines this bounding box with a point so that the resulting
* bounding box encloses the original bounding box and the point.
* @param point a 3d point in space
*/
@Override
public void combine(Point3d point) {
if( boundsIsInfinite) {
return;
}
if( boundsIsEmpty) {
upper.x = lower.x = point.x;
upper.y = lower.y = point.y;
upper.z = lower.z = point.z;
} else {
if( point.x > upper.x) upper.x = point.x;
if( point.y > upper.y) upper.y = point.y;
if( point.z > upper.z) upper.z = point.z;
if( point.x < lower.x) lower.x = point.x;
if( point.y < lower.y) lower.y = point.y;
if( point.z < lower.z) lower.z = point.z;
}
updateBoundsStates();
}
/**
* Combines this bounding box with an array of points so that the
* resulting bounding box encloses the original bounding box and the
* array of points.
* @param points an array of 3d points in space
*/
@Override
public void combine(Point3d[] points) {
int i;
if( boundsIsInfinite) {
return;
}
if( boundsIsEmpty) {
this.setUpper(points[0]);
this.setLower(points[0]);
}
for(i=0;i upper.x) upper.x = points[i].x;
if( points[i].y > upper.y) upper.y = points[i].y;
if( points[i].z > upper.z) upper.z = points[i].z;
if( points[i].x < lower.x) lower.x = points[i].x;
if( points[i].y < lower.y) lower.y = points[i].y;
if( points[i].z < lower.z) lower.z = points[i].z;
}
updateBoundsStates();
}
/**
* Modifies the bounding box so that it bounds the volume
* generated by transforming the given bounding object.
* @param boundsObject the bounding object to be transformed
* @param matrix a transformation matrix
*/
@Override
public void transform( Bounds boundsObject, Transform3D matrix) {
if (boundsObject == null || boundsObject.boundsIsEmpty) {
setEmptyBounds();
return;
}
if (boundsObject.boundsIsInfinite) {
setInfiniteBounds();
return;
}
if(boundsObject.boundId == BOUNDING_BOX){
this.set(boundsObject);
this.transform(matrix);
}
else if(boundsObject.boundId == BOUNDING_SPHERE) {
BoundingSphere tmpSphere = new BoundingSphere(boundsObject);
tmpSphere.transform(matrix);
this.set(tmpSphere);
}
else if(boundsObject.boundId == BOUNDING_POLYTOPE) {
BoundingPolytope tmpPolytope = new BoundingPolytope(boundsObject);
tmpPolytope.transform(matrix);
this.set(tmpPolytope);
}
else {
throw new IllegalArgumentException(J3dI18N.getString("BoundingBox5"));
}
}
/**
* Transforms this bounding box by the given matrix.
* @param matrix a transformation matrix
*/
@Override
public void transform(Transform3D matrix) {
if (boundsIsInfinite)
return;
Point3d tmpP3d = new Point3d();
double ux, uy, uz, lx, ly, lz;
ux = upper.x; uy = upper.y; uz = upper.z;
lx = lower.x; ly = lower.y; lz = lower.z;
tmpP3d.set(ux, uy, uz);
matrix.transform( tmpP3d );
upper.x = tmpP3d.x;
upper.y = tmpP3d.y;
upper.z = tmpP3d.z;
lower.x = tmpP3d.x;
lower.y = tmpP3d.y;
lower.z = tmpP3d.z;
tmpP3d.set(lx, uy, uz);
matrix.transform( tmpP3d );
if ( tmpP3d.x > upper.x ) upper.x = tmpP3d.x;
if ( tmpP3d.y > upper.y ) upper.y = tmpP3d.y;
if ( tmpP3d.z > upper.z ) upper.z = tmpP3d.z;
if ( tmpP3d.x < lower.x ) lower.x = tmpP3d.x;
if ( tmpP3d.y < lower.y ) lower.y = tmpP3d.y;
if ( tmpP3d.z < lower.z ) lower.z = tmpP3d.z;
tmpP3d.set(lx, ly, uz);
matrix.transform( tmpP3d );
if ( tmpP3d.x > upper.x ) upper.x = tmpP3d.x;
if ( tmpP3d.y > upper.y ) upper.y = tmpP3d.y;
if ( tmpP3d.z > upper.z ) upper.z = tmpP3d.z;
if ( tmpP3d.x < lower.x ) lower.x = tmpP3d.x;
if ( tmpP3d.y < lower.y ) lower.y = tmpP3d.y;
if ( tmpP3d.z < lower.z ) lower.z = tmpP3d.z;
tmpP3d.set(ux, ly, uz);
matrix.transform( tmpP3d );
if ( tmpP3d.x > upper.x ) upper.x = tmpP3d.x;
if ( tmpP3d.y > upper.y ) upper.y = tmpP3d.y;
if ( tmpP3d.z > upper.z ) upper.z = tmpP3d.z;
if ( tmpP3d.x < lower.x ) lower.x = tmpP3d.x;
if ( tmpP3d.y < lower.y ) lower.y = tmpP3d.y;
if ( tmpP3d.z < lower.z ) lower.z = tmpP3d.z;
tmpP3d.set(lx, uy, lz);
matrix.transform( tmpP3d );
if ( tmpP3d.x > upper.x ) upper.x = tmpP3d.x;
if ( tmpP3d.y > upper.y ) upper.y = tmpP3d.y;
if ( tmpP3d.z > upper.z ) upper.z = tmpP3d.z;
if ( tmpP3d.x < lower.x ) lower.x = tmpP3d.x;
if ( tmpP3d.y < lower.y ) lower.y = tmpP3d.y;
if ( tmpP3d.z < lower.z ) lower.z = tmpP3d.z;
tmpP3d.set(ux, uy, lz);
matrix.transform( tmpP3d );
if ( tmpP3d.x > upper.x ) upper.x = tmpP3d.x;
if ( tmpP3d.y > upper.y ) upper.y = tmpP3d.y;
if ( tmpP3d.z > upper.z ) upper.z = tmpP3d.z;
if ( tmpP3d.x < lower.x ) lower.x = tmpP3d.x;
if ( tmpP3d.y < lower.y ) lower.y = tmpP3d.y;
if ( tmpP3d.z < lower.z ) lower.z = tmpP3d.z;
tmpP3d.set(lx, ly, lz);
matrix.transform( tmpP3d );
if ( tmpP3d.x > upper.x ) upper.x = tmpP3d.x;
if ( tmpP3d.y > upper.y ) upper.y = tmpP3d.y;
if ( tmpP3d.z > upper.z ) upper.z = tmpP3d.z;
if ( tmpP3d.x < lower.x ) lower.x = tmpP3d.x;
if ( tmpP3d.y < lower.y ) lower.y = tmpP3d.y;
if ( tmpP3d.z < lower.z ) lower.z = tmpP3d.z;
tmpP3d.set(ux, ly, lz);
matrix.transform( tmpP3d );
if ( tmpP3d.x > upper.x ) upper.x = tmpP3d.x;
if ( tmpP3d.y > upper.y ) upper.y = tmpP3d.y;
if ( tmpP3d.z > upper.z ) upper.z = tmpP3d.z;
if ( tmpP3d.x < lower.x ) lower.x = tmpP3d.x;
if ( tmpP3d.y < lower.y ) lower.y = tmpP3d.y;
if ( tmpP3d.z < lower.z ) lower.z = tmpP3d.z;
}
/**
* Test for intersection with a ray.
* @param origin the starting point of the ray
* @param direction the direction of the ray
* @param position3 a point defining the location of the pick w= distance to pick
* @return true or false indicating if an intersection occured
*/
@Override
boolean intersect(Point3d origin, Vector3d direction, Point4d position ) {
double t1,t2,tmp,tnear,tfar,invDir,invMag;
double dirx, diry, dirz;
/*
System.err.println("BoundingBox.intersect(p,d,p) called\n");
System.err.println("bounds = " + lower + " -> " + upper);
*/
if( boundsIsEmpty ) {
return false;
}
if( boundsIsInfinite ) {
position.x = origin.x;
position.y = origin.y;
position.z = origin.z;
position.w = 0.0;
return true;
}
double dirLen = direction.x*direction.x + direction.y*direction.y +
direction.z*direction.z;
// Handle zero length direction vector.
if(dirLen == 0.0)
return intersect(origin, position);
invMag = 1.0/Math.sqrt(dirLen);
dirx = direction.x*invMag;
diry = direction.y*invMag;
dirz = direction.z*invMag;
/*
System.err.println("dir = " + dirx + ", " + diry + ", " + dirz);
System.err.println("origin = " + origin);
*/
// initialize tnear and tfar to handle dir.? == 0 cases
tnear = -Double.MAX_VALUE;
tfar = Double.MAX_VALUE;
if(dirx == 0.0) {
//System.err.println("dirx == 0.0");
if (origin.x < lower.x || origin.x > upper.x ) {
//System.err.println( "parallel to x plane and outside");
return false;
}
} else {
invDir = 1.0/dirx;
t1 = (lower.x-origin.x)*invDir;
t2 = (upper.x-origin.x)*invDir;
//System.err.println("x t1 = " + t1 + " t2 = " + t2);
if( t1 > t2) {
tnear = t2;
tfar = t1;
}else {
tnear = t1;
tfar = t2;
}
if( tfar < 0.0 ) {
//System.err.println( "x failed: tnear="+tnear+" tfar="+tfar);
return false;
}
//System.err.println("x tnear = " + tnear + " tfar = " + tfar);
}
// y
if (diry == 0.0) {
//System.err.println("diry == 0.0");
if( origin.y < lower.y || origin.y > upper.y ){
//System.err.println( "parallel to y plane and outside");
return false;
}
} else {
invDir = 1.0/diry;
//System.err.println("invDir = " + invDir);
t1 = (lower.y-origin.y)*invDir;
t2 = (upper.y-origin.y)*invDir;
if( t1 > t2) {
tmp = t1;
t1 = t2;
t2 = tmp;
}
//System.err.println("y t1 = " + t1 + " t2 = " + t2);
if( t1 > tnear) tnear = t1;
if( t2 < tfar ) tfar = t2;
if( (tfar < 0.0) || (tnear > tfar)){
//System.err.println( "y failed: tnear="+tnear+" tfar="+tfar);
return false;
}
//System.err.println("y tnear = " + tnear + " tfar = " + tfar);
}
// z
if (dirz == 0.0) {
//System.err.println("dirz == 0.0");
if( origin.z < lower.z || origin.z > upper.z ) {
//System.err.println( "parallel to z plane and outside");
return false;
}
} else {
invDir = 1.0/dirz;
t1 = (lower.z-origin.z)*invDir;
t2 = (upper.z-origin.z)*invDir;
if( t1 > t2) {
tmp = t1;
t1 = t2;
t2 = tmp;
}
//System.err.println("z t1 = " + t1 + " t2 = " + t2);
if( t1 > tnear) tnear = t1;
if( t2 < tfar ) tfar = t2;
if( (tfar < 0.0) || (tnear > tfar)){
//System.err.println( "z failed: tnear="+tnear+" tfar="+tfar);
return false;
}
//System.err.println("z tnear = " + tnear + " tfar = " + tfar);
}
if((tnear < 0.0) && (tfar >= 0.0)) {
// origin is inside the BBox.
position.x = origin.x + dirx*tfar;
position.y = origin.y + diry*tfar;
position.z = origin.z + dirz*tfar;
position.w = tfar;
}
else {
position.x = origin.x + dirx*tnear;
position.y = origin.y + diry*tnear;
position.z = origin.z + dirz*tnear;
position.w = tnear;
}
return true;
}
/**
* Test for intersection with a point.
* @param point the pick point
* @param position a point defining the location of the pick w= distance to pick
* @return true or false indicating if an intersection occured
*/
@Override
boolean intersect(Point3d point, Point4d position ) {
if( boundsIsEmpty ) {
return false;
}
if( boundsIsInfinite ) {
position.x = point.x;
position.y = point.y;
position.z = point.z;
position.w = 0.0;
return true;
}
if( point.x <= upper.x && point.x >= lower.x &&
point.y <= upper.y && point.y >= lower.y &&
point.z <= upper.z && point.z >= lower.z) {
position.x = point.x;
position.y = point.y;
position.z = point.z;
position.w = 0.0;
return true;
} else
return false;
}
/**
* Test for intersection with a segment.
* @param start a point defining the start of the line segment
* @param end a point defining the end of the line segment
* @param position a point defining the location of the pick w= distance to pick
* @return true or false indicating if an intersection occured
*/
@Override
boolean intersect( Point3d start, Point3d end, Point4d position ) {
double t1,t2,tmp,tnear,tfar,invDir,invMag;
double dirx, diry, dirz;
if( boundsIsEmpty ) {
return false;
}
if( boundsIsInfinite ) {
position.x = start.x;
position.y = start.y;
position.z = start.z;
position.w = 0.0;
return true;
}
dirx = end.x - start.x;
diry = end.y - start.y;
dirz = end.z - start.z;
double dirLen = dirx*dirx + diry*diry + dirz*dirz;
// Optimization : Handle zero length direction vector.
if(dirLen == 0.0)
return intersect(start, position);
dirLen = Math.sqrt(dirLen);
// System.err.println("dirLen is " + dirLen);
invMag = 1.0/dirLen;
dirx = dirx*invMag;
diry = diry*invMag;
dirz = dirz*invMag;
/*
System.err.println("dir = " + dir);
System.err.println("start = " + start);
System.err.println("lower = " + lower);
System.err.println("upper = " + upper);
*/
// initialize tnear and tfar to handle dir.? == 0 cases
tnear = -Double.MAX_VALUE;
tfar = Double.MAX_VALUE;
if(dirx == 0.0) {
//System.err.println("dirx == 0.0");
if (start.x < lower.x || start.x > upper.x ) {
//System.err.println( "parallel to x plane and outside");
return false;
}
} else {
invDir = 1.0/dirx;
t1 = (lower.x-start.x)*invDir;
t2 = (upper.x-start.x)*invDir;
//System.err.println("x t1 = " + t1 + " t2 = " + t2);
if( t1 > t2) {
tnear = t2;
tfar = t1;
}else {
tnear = t1;
tfar = t2;
}
if( tfar < 0.0 ) {
//System.err.println( "x failed: tnear="+tnear+" tfar="+tfar);
return false;
}
//System.err.println("x tnear = " + tnear + " tfar = " + tfar);
}
// y
if (diry == 0.0) {
//System.err.println("diry == 0.0");
if( start.y < lower.y || start.y > upper.y ){
//System.err.println( "parallel to y plane and outside");
return false;
}
} else {
invDir = 1.0/diry;
//System.err.println("invDir = " + invDir);
t1 = (lower.y-start.y)*invDir;
t2 = (upper.y-start.y)*invDir;
if( t1 > t2) {
tmp = t1;
t1 = t2;
t2 = tmp;
}
//System.err.println("y t1 = " + t1 + " t2 = " + t2);
if( t1 > tnear) tnear = t1;
if( t2 < tfar ) tfar = t2;
if( (tfar < 0.0) || (tnear > tfar)){
//System.err.println( "y failed: tnear="+tnear+" tfar="+tfar);
return false;
}
//System.err.println("y tnear = " + tnear + " tfar = " + tfar);
}
// z
if (dirz == 0.0) {
//System.err.println("dirz == 0.0");
if( start.z < lower.z || start.z > upper.z ) {
//System.err.println( "parallel to z plane and outside");
return false;
}
} else {
invDir = 1.0/dirz;
t1 = (lower.z-start.z)*invDir;
t2 = (upper.z-start.z)*invDir;
if( t1 > t2) {
tmp = t1;
t1 = t2;
t2 = tmp;
}
//System.err.println("z t1 = " + t1 + " t2 = " + t2);
if( t1 > tnear) tnear = t1;
if( t2 < tfar ) tfar = t2;
if( (tfar < 0.0) || (tnear > tfar)){
//System.err.println( "z failed: tnear="+tnear+" tfar="+tfar);
return false;
}
//System.err.println("z tnear = " + tnear + " tfar = " + tfar);
}
if((tnear < 0.0) && (tfar >= 0.0)) {
// origin is inside the BBox.
position.x = start.x + dirx*tfar;
position.y = start.y + diry*tfar;
position.z = start.z + dirz*tfar;
position.w = tfar;
}
else {
if(tnear>dirLen) {
// Segment is behind BBox.
/*
System.err.println("PickSegment : intersected postion : " + position
+ " tnear " + tnear + " tfar " + tfar );
*/
return false;
}
position.x = start.x + dirx*tnear;
position.y = start.y + diry*tnear;
position.z = start.z + dirz*tnear;
position.w = tnear;
}
/*
System.err.println("tnear = " + tnear + " tfar = " + tfar + " w " +
position.w);
System.err.println("lower = " + lower);
System.err.println("upper = " + upper + "\n");
*/
return true;
}
/**
* Test for intersection with a ray.
* @param origin the starting point of the ray
* @param direction the direction of the ray
* @return true or false indicating if an intersection occured
*/
@Override
public boolean intersect(Point3d origin, Vector3d direction ) {
if( boundsIsEmpty ) {
return false;
}
if( boundsIsInfinite ) {
return true;
}
Point3d p=new Point3d();
return intersect( origin, direction, p );
}
/**
* A protected intersect method that returns the point of intersection.
* Used by Picking methods to sort or return closest picked item.
*/
boolean intersect(Point3d origin, Vector3d direction, Point3d intersect ) {
double theta=0.0;
if( boundsIsEmpty ) {
return false;
}
if( boundsIsInfinite ) {
intersect.x = origin.x;
intersect.y = origin.y;
intersect.z = origin.z;
return true;
}
if (direction.x > 0.0 )
theta = Math.max( theta, (lower.x - origin.x)/direction.x );
if (direction.x < 0.0 )
theta = Math.max( theta, (upper.x - origin.x)/direction.x );
if (direction.y > 0.0 )
theta = Math.max( theta, (lower.y - origin.y)/direction.y );
if (direction.y < 0.0 )
theta = Math.max( theta, (upper.y - origin.y)/direction.y );
if (direction.z > 0.0 )
theta = Math.max( theta, (lower.z - origin.z)/direction.z );
if (direction.z < 0.0 )
theta = Math.max( theta, (upper.z - origin.z)/direction.z );
intersect.x = origin.x + theta*direction.x;
intersect.y = origin.y + theta*direction.y;
intersect.z = origin.z + theta*direction.z;
if (intersect.x < (lower.x-EPS)) return false;
if (intersect.x > (upper.x+EPS)) return false;
if (intersect.y < (lower.y-EPS)) return false;
if (intersect.y > (upper.y+EPS)) return false;
if (intersect.z < (lower.z-EPS)) return false;
if (intersect.z > (upper.z+EPS)) return false;
return true;
}
/**
* Test for intersection with a point.
* @param point a point defining a position in 3-space
* @return true or false indicating if an intersection occured
*/
@Override
public boolean intersect(Point3d point ) {
if( boundsIsEmpty ) {
return false;
}
if( boundsIsInfinite ) {
return true;
}
if( point.x <= upper.x && point.x >= lower.x &&
point.y <= upper.y && point.y >= lower.y &&
point.z <= upper.z && point.z >= lower.z)
return true;
else
return false;
}
/**
* Tests whether the bounding box is empty. A bounding box is
* empty if it is null (either by construction or as the result of
* a null intersection) or if its volume is negative. A bounding box
* with a volume of zero is not empty.
* @return true if the bounding box is empty; otherwise, it returns false
*/
@Override
public boolean isEmpty() {
return boundsIsEmpty;
}
/**
* Test for intersection with another bounds object.
* @param boundsObject another bounds object
* @return true or false indicating if an intersection occured
*/
@Override
boolean intersect(Bounds boundsObject, Point4d position) {
return intersect(boundsObject);
}
/**
* Test for intersection with another bounds object.
* @param boundsObject another bounds object
* @return true or false indicating if an intersection occured
*/
@Override
public boolean intersect(Bounds boundsObject) {
if( boundsObject == null ) {
return false;
}
if( boundsIsEmpty || boundsObject.boundsIsEmpty ) {
return false;
}
if( boundsIsInfinite || boundsObject.boundsIsInfinite ) {
return true;
}
if( boundsObject.boundId == BOUNDING_BOX){
BoundingBox box = (BoundingBox)boundsObject;
// both boxes are axis aligned
if( upper.x > box.lower.x && box.upper.x > lower.x &&
upper.y > box.lower.y && box.upper.y > lower.y &&
upper.z > box.lower.z && box.upper.z > lower.z )
return true;
else
return false;
} else if( boundsObject.boundId == BOUNDING_SPHERE) {
BoundingSphere sphere = (BoundingSphere)boundsObject;
double rad_sq = sphere.radius*sphere.radius;
double dis = 0.0;
if( sphere.center.x < lower.x )
dis = (sphere.center.x-lower.x)*(sphere.center.x-lower.x);
else
if( sphere.center.x > upper.x )
dis = (sphere.center.x-upper.x)*(sphere.center.x-upper.x);
if( sphere.center.y < lower.y )
dis += (sphere.center.y-lower.y)*(sphere.center.y-lower.y);
else
if( sphere.center.y > upper.y )
dis += (sphere.center.y-upper.y)*(sphere.center.y-upper.y);
if( sphere.center.z < lower.z )
dis += (sphere.center.z-lower.z)*(sphere.center.z-lower.z);
else
if( sphere.center.z > upper.z )
dis += (sphere.center.z-upper.z)*(sphere.center.z-upper.z);
if( dis <= rad_sq )
return true;
else
return false;
} else if(boundsObject.boundId == BOUNDING_POLYTOPE) {
// intersect an axis aligned box with a polytope
return intersect_ptope_abox ( (BoundingPolytope)boundsObject, this );
} else {
throw new IllegalArgumentException(J3dI18N.getString("BoundingBox6"));
}
}
/**
* Test for intersection with an array of bounds objects.
* @param boundsObjects an array of bounding objects
* @return true or false indicating if an intersection occured
*/
@Override
public boolean intersect(Bounds[] boundsObjects) {
int i;
if( boundsObjects == null || boundsObjects.length <= 0 ) {
return false;
}
if( boundsIsEmpty ) {
return false;
}
for(i = 0; i < boundsObjects.length; i++){
if( boundsObjects[i] == null || boundsObjects[i].boundsIsEmpty) ;
else if( boundsIsInfinite || boundsObjects[i].boundsIsInfinite ) {
return true; // We're done here.
}
else if( boundsObjects[i].boundId == BOUNDING_BOX){
BoundingBox box = (BoundingBox)boundsObjects[i];
// both boxes are axis aligned
if( upper.x > box.lower.x && box.upper.x > lower.x &&
upper.y > box.lower.y && box.upper.y > lower.y &&
upper.z > box.lower.z && box.upper.z > lower.z )
return true;
}
else if( boundsObjects[i].boundId == BOUNDING_SPHERE ) {
BoundingSphere sphere = (BoundingSphere)boundsObjects[i];
double rad_sq = sphere.radius*sphere.radius;
double dis = 0.0;
if( sphere.center.x < lower.x )
dis = (sphere.center.x-lower.x)*(sphere.center.x-lower.x);
else
if( sphere.center.x > upper.x )
dis = (sphere.center.x-upper.x)*(sphere.center.x-upper.x);
if( sphere.center.y < lower.y )
dis += (sphere.center.y-lower.y)*(sphere.center.y-lower.y);
else
if( sphere.center.y > upper.y )
dis += (sphere.center.y-upper.y)*(sphere.center.y-upper.y);
if( sphere.center.z < lower.z )
dis += (sphere.center.z-lower.z)*(sphere.center.z-lower.z);
else
if( sphere.center.z > upper.z )
dis += (sphere.center.z-upper.z)*(sphere.center.z-upper.z);
if( dis <= rad_sq )
return true;
}
else if(boundsObjects[i].boundId == BOUNDING_POLYTOPE) {
if( intersect_ptope_abox ( (BoundingPolytope)boundsObjects[i], this ))
return true;
}
else {
// System.err.println("intersect ?? ");
}
}
return false;
}
/**
* Test for intersection with another bounding box.
* @param boundsObject another bounding object
* @param newBoundBox the new bounding box which is the intersection of
* the boundsObject and this BoundingBox
* @return true or false indicating if an intersection occured
*/
public boolean intersect(Bounds boundsObject, BoundingBox newBoundBox) {
if((boundsObject == null) || boundsIsEmpty || boundsObject.boundsIsEmpty ) {
newBoundBox.set((Bounds)null);
return false;
}
if(boundsIsInfinite && (!boundsObject.boundsIsInfinite)) {
newBoundBox.set(boundsObject);
return true;
}
else if((!boundsIsInfinite) && boundsObject.boundsIsInfinite) {
newBoundBox.set(this);
return true;
}
else if(boundsIsInfinite && boundsObject.boundsIsInfinite) {
newBoundBox.set(this);
return true;
}
else if( boundsObject.boundId == BOUNDING_BOX){
BoundingBox box = (BoundingBox)boundsObject;
// both boxes are axis aligned
if( upper.x > box.lower.x && box.upper.x > lower.x &&
upper.y > box.lower.y && box.upper.y > lower.y &&
upper.z > box.lower.z && box.upper.z > lower.z ){
if(upper.x > box.upper.x)
newBoundBox.upper.x = box.upper.x;
else
newBoundBox.upper.x = upper.x;
if(upper.y > box.upper.y)
newBoundBox.upper.y = box.upper.y;
else
newBoundBox.upper.y = upper.y;
if(upper.z > box.upper.z)
newBoundBox.upper.z = box.upper.z;
else
newBoundBox.upper.z = upper.z;
if(lower.x < box.lower.x)
newBoundBox.lower.x = box.lower.x;
else
newBoundBox.lower.x = lower.x;
if(lower.y < box.lower.y)
newBoundBox.lower.y = box.lower.y;
else
newBoundBox.lower.y = lower.y;
if(lower.z < box.lower.z)
newBoundBox.lower.z = box.lower.z;
else
newBoundBox.lower.z = lower.z;
newBoundBox.updateBoundsStates();
return true;
} else {
// Negative volume.
newBoundBox.set((Bounds)null);
return false;
}
}
else if( boundsObject.boundId == BOUNDING_SPHERE) {
BoundingSphere sphere = (BoundingSphere)boundsObject;
if( this.intersect( sphere) ) {
BoundingBox sbox = new BoundingBox( sphere );
this.intersect( sbox, newBoundBox );
return true;
} else {
// Negative volume.
newBoundBox.set((Bounds)null);
return false;
}
// System.err.println("intersect Sphere ");
}
else if(boundsObject.boundId == BOUNDING_POLYTOPE) {
BoundingPolytope polytope = (BoundingPolytope)boundsObject;
if( this.intersect( polytope)) {
BoundingBox pbox = new BoundingBox( polytope); // convert polytope to box
this.intersect( pbox, newBoundBox );
return true;
} else {
// Negative volume.
newBoundBox.set((Bounds)null);
return false;
}
} else {
throw new IllegalArgumentException(J3dI18N.getString("BoundingBox7"));
}
}
/**
* Test for intersection with an array of bounds objects.
* @param boundsObjects an array of bounds objects
* @param newBoundBox the new bounding box which is the intersection of
* the boundsObject and this BoundingBox
* @return true or false indicating if an intersection occured
*/
public boolean intersect(Bounds[] boundsObjects, BoundingBox newBoundBox) {
if( boundsObjects == null || boundsObjects.length <= 0 || boundsIsEmpty ) {
// Negative volume.
newBoundBox.set((Bounds)null);
return false;
}
int i=0;
// find first non null bounds object
while( boundsObjects[i] == null && i < boundsObjects.length) {
i++;
}
if( i >= boundsObjects.length ) { // all bounds objects were empty
// Negative volume.
newBoundBox.set((Bounds)null);
return false;
}
boolean status = false;
BoundingBox tbox = new BoundingBox();
for(;i box.lower.x && box.upper.x > lower.x &&
upper.y > box.lower.y && box.upper.y > lower.y &&
upper.z > box.lower.z && box.upper.z > lower.z ){
if(upper.x > box.upper.x)
newBoundBox.upper.x = box.upper.x;
else
newBoundBox.upper.x = upper.x;
if(upper.y > box.upper.y)
newBoundBox.upper.y = box.upper.y;
else
newBoundBox.upper.y = upper.y;
if(upper.z > box.upper.z)
newBoundBox.upper.z = box.upper.z;
else
newBoundBox.upper.z = upper.z;
if(lower.x < box.lower.x)
newBoundBox.lower.x = box.lower.x;
else
newBoundBox.lower.x = lower.x;
if(lower.y < box.lower.y)
newBoundBox.lower.y = box.lower.y;
else
newBoundBox.lower.y = lower.y;
if(lower.z < box.lower.z)
newBoundBox.lower.z = box.lower.z;
else
newBoundBox.lower.z = lower.z;
status = true;
newBoundBox.updateBoundsStates();
}
}
else if( boundsObjects[i].boundId == BOUNDING_SPHERE) {
BoundingSphere sphere = (BoundingSphere)boundsObjects[i];
if( this.intersect(sphere)) {
BoundingBox sbox = new BoundingBox( sphere ); // convert sphere to box
this.intersect(sbox,tbox); // insersect two boxes
if( status ) {
newBoundBox.combine( tbox );
} else {
newBoundBox.set( tbox );
status = true;
}
}
}
else if(boundsObjects[i].boundId == BOUNDING_POLYTOPE) {
BoundingPolytope polytope = (BoundingPolytope)boundsObjects[i];
if( this.intersect( polytope)) {
BoundingBox pbox = new BoundingBox( polytope ); // convert polytope to box
this.intersect(pbox,tbox); // insersect two boxes
if ( status ) {
newBoundBox.combine( tbox );
} else {
newBoundBox.set( tbox );
status = true;
}
}
} else {
throw new IllegalArgumentException(J3dI18N.getString("BoundingBox6"));
}
if(newBoundBox.boundsIsInfinite)
break; // We're done.
}
if( status == false ) {
// Negative volume.
newBoundBox.set((Bounds)null);
}
return status;
}
/**
* Finds closest bounding object that intersects this bounding box.
* @param boundsObjects an array of bounds objects
* @return closest bounding object
*/
@Override
public Bounds closestIntersection( Bounds[] boundsObjects) {
if( boundsObjects == null || boundsObjects.length <= 0 ) {
return null;
}
if( boundsIsEmpty ) {
return null;
}
Point3d centroid = getCenter();
double dis;
double cenX = 0.0, cenY = 0.0, cenZ = 0.0;
boolean contains = false;
boolean inside;
boolean intersect = false;
double smallest_distance = Double.MAX_VALUE;
int i,j,index=0;
for(i = 0; i < boundsObjects.length; i++){
if( boundsObjects[i] == null ) ;
else if( this.intersect( boundsObjects[i])) {
intersect = true;
if( boundsObjects[i].boundId == BOUNDING_BOX){
BoundingBox box = (BoundingBox)boundsObjects[i];
cenX = (box.upper.x+box.lower.x)/2.0;
cenY = (box.upper.y+box.lower.y)/2.0;
cenZ = (box.upper.z+box.lower.z)/2.0;
dis = Math.sqrt( (centroid.x-cenX)*(centroid.x-cenX) +
(centroid.y-cenY)*(centroid.y-cenY) +
(centroid.z-cenZ)*(centroid.z-cenZ) );
inside = false;
if( lower.x <= box.lower.x &&
lower.y <= box.lower.y &&
lower.z <= box.lower.z &&
upper.x >= box.upper.x &&
upper.y >= box.upper.y &&
upper.z >= box.upper.z ) { // box is contained
inside = true;
}
if( inside ) {
if( !contains ){ // initialize smallest_distance for the first containment
index = i;
smallest_distance = dis;
contains = true;
} else{
if( dis < smallest_distance){
index = i;
smallest_distance = dis;
}
}
} else if (!contains) {
if( dis < smallest_distance){
index = i;
smallest_distance = dis;
}
}
}
else if( boundsObjects[i].boundId == BOUNDING_SPHERE ) {
BoundingSphere sphere = (BoundingSphere)boundsObjects[i];
dis = Math.sqrt( (centroid.x-sphere.center.x)*
(centroid.x-sphere.center.x) +
(centroid.y-sphere.center.y)*
(centroid.y-sphere.center.y) +
(centroid.z-sphere.center.z)*
(centroid.z-sphere.center.z) );
inside = false;
// sphere sphere.center is inside box
if(sphere.center.x <= upper.x && sphere.center.x >= lower.x &&
sphere.center.y <= upper.y && sphere.center.y >= lower.y &&
sphere.center.z <= upper.z && sphere.center.z >= lower.z ) {
// check if sphere intersects any side
if (sphere.center.x - lower.x >= sphere.radius &&
upper.x - sphere.center.x >= sphere.radius &&
sphere.center.y - lower.y >= sphere.radius &&
upper.y - sphere.center.y >= sphere.radius &&
sphere.center.z - lower.z >= sphere.radius &&
upper.z - sphere.center.z >= sphere.radius ) {
// contains the sphere
inside = true;
}
}
if (inside ) {
// initialize smallest_distance for the first containment
if( !contains ){
index = i;
smallest_distance = dis;
contains = true;
} else{
if( dis < smallest_distance){
index = i;
smallest_distance = dis;
}
}
} else if (!contains) {
if( dis < smallest_distance){
index = i;
smallest_distance = dis;
}
}
}
else if(boundsObjects[i].boundId == BOUNDING_POLYTOPE) {
BoundingPolytope polytope =
(BoundingPolytope)boundsObjects[i];
dis = Math.sqrt( (centroid.x-polytope.centroid.x)*
(centroid.x-polytope.centroid.x) +
(centroid.y-polytope.centroid.y)*
(centroid.y-polytope.centroid.y) +
(centroid.z-polytope.centroid.z)*
(centroid.z-polytope.centroid.z) );
inside = true;
for(j=0;j upper.x ||
polytope.verts[j].y > upper.y ||
polytope.verts[j].z > upper.z ) { // box contains polytope
inside = false;
}
}
if( inside ) {
if( !contains ){ // initialize smallest_distance for the first containment
index = i;
smallest_distance = dis;
contains = true;
} else{
if( dis < smallest_distance){
index = i;
smallest_distance = dis;
}
}
} else if (!contains) {
if( dis < smallest_distance){
index = i;
smallest_distance = dis;
}
}
} else {
throw new IllegalArgumentException(J3dI18N.getString("BoundingBox9"));
}
}
}
if ( intersect )
return boundsObjects[index];
else
return null;
}
/**
* Tests for intersection of box and frustum.
* @param frustum
* @return true if they intersect
*/
boolean intersect(CachedFrustum frustum ) {
if (boundsIsEmpty)
return false;
if(boundsIsInfinite)
return true;
// System.err.println("intersect frustum with box="+this.toString());
// System.err.println("frustum "+frustum.toString());
// check if box and bounding box of frustum intersect
if ((upper.x < frustum.lower.x) ||
(lower.x > frustum.upper.x) ||
(upper.y < frustum.lower.y) ||
(lower.y > frustum.upper.y) ||
(upper.z < frustum.lower.z) ||
(lower.z > frustum.upper.z) ) {
// System.err.println("*** box and bounding box of frustum do not intersect");
return false;
}
// check if all box points out any frustum plane
int i = 5;
while (i>=0){
Vector4d vc = frustum.clipPlanes[i--];
if ((( upper.x*vc.x + upper.y*vc.y +
upper.z*vc.z + vc.w ) < 0.0 ) &&
(( upper.x*vc.x + lower.y*vc.y +
upper.z*vc.z + vc.w ) < 0.0 ) &&
(( upper.x*vc.x + lower.y*vc.y +
lower.z*vc.z + vc.w ) < 0.0 ) &&
(( upper.x*vc.x + upper.y*vc.y +
lower.z*vc.z + vc.w ) < 0.0 ) &&
(( lower.x*vc.x + upper.y*vc.y +
upper.z*vc.z + vc.w ) < 0.0 ) &&
(( lower.x*vc.x + lower.y*vc.y +
upper.z*vc.z + vc.w ) < 0.0 ) &&
(( lower.x*vc.x + lower.y*vc.y +
lower.z*vc.z + vc.w ) < 0.0 ) &&
(( lower.x*vc.x + upper.y*vc.y +
lower.z*vc.z + vc.w ) < 0.0 )) {
// all corners outside this frustum plane
// System.err.println("*** all corners outside this frustum plane");
return false;
}
}
return true;
}
/**
* Returns a string representation of this class.
*/
@Override
public String toString() {
return new String( "Bounding box: Lower="+lower.x+" "+
lower.y+" "+lower.z+" Upper="+upper.x+" "+
upper.y+" "+upper.z );
}
private void setEmptyBounds() {
lower.set( 1.0d, 1.0d, 1.0d);
upper.set(-1.0d, -1.0d, -1.0d);
boundsIsInfinite = false;
boundsIsEmpty = true;
}
private void setInfiniteBounds() {
lower.set(Double.NEGATIVE_INFINITY,
Double.NEGATIVE_INFINITY,
Double.NEGATIVE_INFINITY);
upper.set(Double.POSITIVE_INFINITY,
Double.POSITIVE_INFINITY,
Double.POSITIVE_INFINITY);
boundsIsInfinite = true;
boundsIsEmpty = false;
}
private void updateBoundsStates() {
if((lower.x == Double.NEGATIVE_INFINITY) &&
(lower.y == Double.NEGATIVE_INFINITY) &&
(lower.z == Double.NEGATIVE_INFINITY) &&
(upper.x == Double.POSITIVE_INFINITY) &&
(upper.y == Double.POSITIVE_INFINITY) &&
(upper.z == Double.POSITIVE_INFINITY)) {
boundsIsEmpty = false;
boundsIsInfinite = true;
return;
}
if (Double.isNaN(lower.x + lower.y + lower.z + upper.x + upper.y + upper.z)) {
boundsIsEmpty = true;
boundsIsInfinite = false;
return;
}
else {
boundsIsInfinite = false;
if( lower.x > upper.x ||
lower.y > upper.y ||
lower.z > upper.z ) {
boundsIsEmpty = true;
} else {
boundsIsEmpty = false;
}
}
}
// For a infinite bounds. What is the centroid ?
@Override
Point3d getCenter() {
Point3d cent = new Point3d();
cent.add(upper, lower);
cent.scale(0.5d);
return cent;
}
@Override
public void getCenter(Point3d center) {
center.add(lower, upper);
center.scale(0.5d);
}
void translate(BoundingBox bbox, Vector3d value) {
if (bbox == null || bbox.boundsIsEmpty) {
setEmptyBounds();
return;
}
if (bbox.boundsIsInfinite) {
setInfiniteBounds();
return;
}
lower.x = bbox.lower.x + value.x;
lower.y = bbox.lower.y + value.y;
lower.z = bbox.lower.z + value.z;
upper.x = bbox.upper.x + value.x;
upper.y = bbox.upper.y + value.y;
upper.z = bbox.upper.z + value.z;
}
/**
* if the passed the "region" is same type as this object
* then do a copy, otherwise clone the Bounds and
* return
*/
@Override
Bounds copy(Bounds r) {
if (r != null && this.boundId == r.boundId) {
BoundingBox region = (BoundingBox) r;
region.lower.x = lower.x;
region.lower.y = lower.y;
region.lower.z = lower.z;
region.upper.x = upper.x;
region.upper.y = upper.y;
region.upper.z = upper.z;
region.boundsIsEmpty = boundsIsEmpty;
region.boundsIsInfinite = boundsIsInfinite;
return region;
}
else {
return (Bounds) this.clone();
}
}
@Override
int getPickType() {
return PickShape.PICKBOUNDINGBOX;
}
}