/* * Copyright 1997-2008 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.Vector3d; /** * The IndexedLineStripArray object draws an array of vertices as a set of * connected line strips. An array of per-strip vertex counts specifies * where the separate strips appear in the vertex array. * For every strip in the set, each vertex, beginning with * the second vertex in the array, defines a line segment to be drawn * from the previous vertex to the current vertex. */ class IndexedLineStripArrayRetained extends IndexedGeometryStripArrayRetained { IndexedLineStripArrayRetained() { geoType = GEO_TYPE_INDEXED_LINE_STRIP_SET; } @Override boolean intersect(PickShape pickShape, PickInfo pickInfo, int flags, Point3d iPnt, GeometryRetained geom, int geomIndex) { Point3d pnts[] = new Point3d[2]; double sdist[] = new double[1]; double minDist = Double.MAX_VALUE; double x = 0, y = 0, z = 0; int scount, j, i = 0; int count = 0; int[] vtxIndexArr = new int[2]; pnts[0] = new Point3d(); pnts[1] = new Point3d(); switch (pickShape.getPickType()) { case PickShape.PICKRAY: PickRay pickRay= (PickRay) pickShape; while (i < stripIndexCounts.length) { vtxIndexArr[0] = indexCoord[count]; getVertexData(indexCoord[count++], pnts[0]); scount = stripIndexCounts[i++]; for (j=1; j < scount; j++) { vtxIndexArr[1] = indexCoord[count]; getVertexData(indexCoord[count++], pnts[1]); if (intersectLineAndRay(pnts[0], pnts[1], pickRay.origin, pickRay.direction, sdist, iPnt)) { if (flags == 0) { return true; } if (sdist[0] < minDist) { minDist = sdist[0]; x = iPnt.x; y = iPnt.y; z = iPnt.z; if((flags & PickInfo.CLOSEST_GEOM_INFO) != 0) { storeInterestData(pickInfo, flags, geom, geomIndex, vtxIndexArr, iPnt, sdist[0]); } } if((flags & PickInfo.ALL_GEOM_INFO) != 0) { storeInterestData(pickInfo, flags, geom, geomIndex, vtxIndexArr, iPnt, sdist[0]); } } pnts[0].set(pnts[1]); vtxIndexArr[0] = vtxIndexArr[1]; } } break; case PickShape.PICKSEGMENT: PickSegment pickSegment = (PickSegment) pickShape; Vector3d dir = new Vector3d(pickSegment.end.x - pickSegment.start.x, pickSegment.end.y - pickSegment.start.y, pickSegment.end.z - pickSegment.start.z); while (i < stripIndexCounts.length) { vtxIndexArr[0] = indexCoord[count]; getVertexData(indexCoord[count++], pnts[0]); scount = stripIndexCounts[i++]; for (j=1; j < scount; j++) { vtxIndexArr[1] = indexCoord[count]; getVertexData(indexCoord[count++], pnts[1]); if (intersectLineAndRay(pnts[0], pnts[1], pickSegment.start, dir, sdist, iPnt) && (sdist[0] <= 1.0)) { if (flags == 0) { return true; } if (sdist[0] < minDist) { minDist = sdist[0]; x = iPnt.x; y = iPnt.y; z = iPnt.z; if((flags & PickInfo.CLOSEST_GEOM_INFO) != 0) { storeInterestData(pickInfo, flags, geom, geomIndex, vtxIndexArr, iPnt, sdist[0]); } } if((flags & PickInfo.ALL_GEOM_INFO) != 0) { storeInterestData(pickInfo, flags, geom, geomIndex, vtxIndexArr, iPnt, sdist[0]); } } pnts[0].set(pnts[1]); vtxIndexArr[0] = vtxIndexArr[1]; } } break; case PickShape.PICKBOUNDINGBOX: BoundingBox bbox = (BoundingBox) ((PickBounds) pickShape).bounds; while (i < stripIndexCounts.length) { vtxIndexArr[0] = indexCoord[count]; getVertexData(indexCoord[count++], pnts[0]); scount = stripIndexCounts[i++]; for (j=1; j < scount; j++) { vtxIndexArr[1] = indexCoord[count]; getVertexData(indexCoord[count++], pnts[1]); if (intersectBoundingBox(pnts, bbox, sdist, iPnt)) { if (flags == 0) { return true; } if (sdist[0] < minDist) { minDist = sdist[0]; x = iPnt.x; y = iPnt.y; z = iPnt.z; if((flags & PickInfo.CLOSEST_GEOM_INFO) != 0) { storeInterestData(pickInfo, flags, geom, geomIndex, vtxIndexArr, iPnt, sdist[0]); } } if((flags & PickInfo.ALL_GEOM_INFO) != 0) { storeInterestData(pickInfo, flags, geom, geomIndex, vtxIndexArr, iPnt, sdist[0]); } } pnts[0].set(pnts[1]); vtxIndexArr[0] = vtxIndexArr[1]; } } break; case PickShape.PICKBOUNDINGSPHERE: BoundingSphere bsphere = (BoundingSphere) ((PickBounds) pickShape).bounds; while (i < stripIndexCounts.length) { vtxIndexArr[0] = indexCoord[count]; getVertexData(indexCoord[count++], pnts[0]); scount = stripIndexCounts[i++]; for (j=1; j < scount; j++) { vtxIndexArr[1] = indexCoord[count]; getVertexData(indexCoord[count++], pnts[1]); if (intersectBoundingSphere(pnts, bsphere, sdist, iPnt)) { if (flags == 0) { return true; } if (sdist[0] < minDist) { minDist = sdist[0]; x = iPnt.x; y = iPnt.y; z = iPnt.z; if((flags & PickInfo.CLOSEST_GEOM_INFO) != 0) { storeInterestData(pickInfo, flags, geom, geomIndex, vtxIndexArr, iPnt, sdist[0]); } } if((flags & PickInfo.ALL_GEOM_INFO) != 0) { storeInterestData(pickInfo, flags, geom, geomIndex, vtxIndexArr, iPnt, sdist[0]); } } pnts[0].set(pnts[1]); vtxIndexArr[0] = vtxIndexArr[1]; } } break; case PickShape.PICKBOUNDINGPOLYTOPE: BoundingPolytope bpolytope = (BoundingPolytope) ((PickBounds) pickShape).bounds; while (i < stripIndexCounts.length) { vtxIndexArr[0] = indexCoord[count]; getVertexData(indexCoord[count++], pnts[0]); scount = stripIndexCounts[i++]; for (j=1; j < scount; j++) { vtxIndexArr[1] = indexCoord[count]; getVertexData(indexCoord[count++], pnts[1]); if (intersectBoundingPolytope(pnts, bpolytope, sdist, iPnt)) { if (flags == 0) { return true; } if (sdist[0] < minDist) { minDist = sdist[0]; x = iPnt.x; y = iPnt.y; z = iPnt.z; if((flags & PickInfo.CLOSEST_GEOM_INFO) != 0) { storeInterestData(pickInfo, flags, geom, geomIndex, vtxIndexArr, iPnt, sdist[0]); } } if((flags & PickInfo.ALL_GEOM_INFO) != 0) { storeInterestData(pickInfo, flags, geom, geomIndex, vtxIndexArr, iPnt, sdist[0]); } } pnts[0].set(pnts[1]); vtxIndexArr[0] = vtxIndexArr[1]; } } break; case PickShape.PICKCYLINDER: PickCylinder pickCylinder= (PickCylinder) pickShape; while (i < stripIndexCounts.length) { vtxIndexArr[0] = indexCoord[count]; getVertexData(indexCoord[count++], pnts[0]); scount = stripIndexCounts[i++]; for (j=1; j < scount; j++) { vtxIndexArr[1] = indexCoord[count]; getVertexData(indexCoord[count++], pnts[1]); if (intersectCylinder(pnts, pickCylinder, sdist, iPnt)) { if (flags == 0) { return true; } if (sdist[0] < minDist) { minDist = sdist[0]; x = iPnt.x; y = iPnt.y; z = iPnt.z; if((flags & PickInfo.CLOSEST_GEOM_INFO) != 0) { storeInterestData(pickInfo, flags, geom, geomIndex, vtxIndexArr, iPnt, sdist[0]); } } if((flags & PickInfo.ALL_GEOM_INFO) != 0) { storeInterestData(pickInfo, flags, geom, geomIndex, vtxIndexArr, iPnt, sdist[0]); } } pnts[0].set(pnts[1]); vtxIndexArr[0] = vtxIndexArr[1]; } } break; case PickShape.PICKCONE: PickCone pickCone= (PickCone) pickShape; while (i < stripIndexCounts.length) { vtxIndexArr[0] = indexCoord[count]; getVertexData(indexCoord[count++], pnts[0]); scount = stripIndexCounts[i++]; for (j=1; j < scount; j++) { vtxIndexArr[1] = indexCoord[count]; getVertexData(indexCoord[count++], pnts[1]); if (intersectCone(pnts, pickCone, sdist, iPnt)) { if (flags == 0) { return true; } if (sdist[0] < minDist) { minDist = sdist[0]; x = iPnt.x; y = iPnt.y; z = iPnt.z; if((flags & PickInfo.CLOSEST_GEOM_INFO) != 0) { storeInterestData(pickInfo, flags, geom, geomIndex, vtxIndexArr, iPnt, sdist[0]); } } if((flags & PickInfo.ALL_GEOM_INFO) != 0) { storeInterestData(pickInfo, flags, geom, geomIndex, vtxIndexArr, iPnt, sdist[0]); } } pnts[0].set(pnts[1]); vtxIndexArr[0] = vtxIndexArr[1]; } } break; case PickShape.PICKPOINT: // Should not happen since API already check for this throw new IllegalArgumentException(J3dI18N.getString("IndexedLineStripArrayRetained0")); default: throw new RuntimeException ("PickShape not supported for intersection"); } if (minDist < Double.MAX_VALUE) { iPnt.x = x; iPnt.y = y; iPnt.z = z; return true; } return false; } // intersect pnts[] with every triangle in this object @Override boolean intersect(Point3d[] pnts) { int i = 0; int j, count=0; int scount; Point3d[] points = new Point3d[2]; double dist[] = new double[1]; Vector3d dir; points[0] = new Point3d(); points[1] = new Point3d(); switch (pnts.length) { case 3: case 4: // Triangle, Quad while (i < stripIndexCounts.length) { getVertexData(indexCoord[count++], points[0]); scount = stripIndexCounts[i++]; for (j=1; j < scount; j++) { getVertexData(indexCoord[count++], points[1]); if (intersectSegment(pnts, points[0], points[1], dist, null)) { return true; } points[0].set(points[1]); } } break; case 2: // line dir = new Vector3d(); while (i < stripIndexCounts.length) { getVertexData(indexCoord[count++], points[0]); scount = stripIndexCounts[i++]; for (j=1; j < scount; j++) { getVertexData(indexCoord[count++], points[1]); dir.x = points[1].x - points[0].x; dir.y = points[1].y - points[0].y; dir.z = points[1].z - points[0].z; if (intersectLineAndRay(pnts[0], pnts[1], points[0], dir, dist, null) && (dist[0] <= 1.0)) { return true; } points[0].set(points[1]); } } break; case 1: // point dir = new Vector3d(); while (i < stripIndexCounts.length) { getVertexData(indexCoord[count++], points[0]); scount = stripIndexCounts[i++]; for (j=1; j < scount; j++) { getVertexData(indexCoord[count++], points[1]); dir.x = points[1].x - points[0].x; dir.y = points[1].y - points[0].y; dir.z = points[1].z - points[0].z; if (intersectPntAndRay(pnts[0], points[0], dir, dist) && (dist[0] <= 1.0)) { return true; } points[0].set(points[1]); } } break; } return false; } @Override boolean intersect(Transform3D thisToOtherVworld, GeometryRetained geom) { int i = 0; int j, count=0; Point3d[] pnts = new Point3d[2]; int scount; pnts[0] = new Point3d(); pnts[1] = new Point3d(); while (i < stripIndexCounts.length) { getVertexData(indexCoord[count++], pnts[0]); thisToOtherVworld.transform(pnts[0]); scount = stripIndexCounts[i++]; for (j = 1; j < scount; j++) { getVertexData(indexCoord[count++], pnts[1]); thisToOtherVworld.transform(pnts[1]); if (geom.intersect( pnts)) { return true; } pnts[0].set(pnts[1]); } } return false; } // the bounds argument is already transformed @Override boolean intersect(Bounds targetBound) { int i = 0; int j, count=0; Point3d[] pnts = new Point3d[2]; int scount; pnts[0] = new Point3d(); pnts[1] = new Point3d(); switch(targetBound.getPickType()) { case PickShape.PICKBOUNDINGBOX: BoundingBox box = (BoundingBox) targetBound; while (i < stripIndexCounts.length) { getVertexData(indexCoord[count++], pnts[0]); scount = stripIndexCounts[i++]; for (j=1; j < scount; j++) { getVertexData(indexCoord[count++], pnts[1]); if (intersectBoundingBox(pnts, box, null, null)) { return true; } pnts[0].set(pnts[1]); } } break; case PickShape.PICKBOUNDINGSPHERE: BoundingSphere bsphere = (BoundingSphere) targetBound; while (i < stripIndexCounts.length) { getVertexData(indexCoord[count++], pnts[0]); scount = stripIndexCounts[i++]; for (j=1; j < scount; j++) { getVertexData(indexCoord[count++], pnts[1]); if (intersectBoundingSphere(pnts, bsphere, null, null)) { return true; } pnts[0].set(pnts[1]); } } break; case PickShape.PICKBOUNDINGPOLYTOPE: BoundingPolytope bpolytope = (BoundingPolytope) targetBound; while (i < stripIndexCounts.length) { getVertexData(indexCoord[count++], pnts[0]); scount = stripIndexCounts[i++]; for (j=1; j < scount; j++) { getVertexData(indexCoord[count++], pnts[1]); if (intersectBoundingPolytope(pnts, bpolytope, null, null)) { return true; } pnts[0].set(pnts[1]); } } break; default: throw new RuntimeException("Bounds not supported for intersection " + targetBound); } return false; } @Override int getClassType() { return LINE_TYPE; } }