/** * Find a single-player spawnpoint. Kind of simplistic. * @return q2jgame.GameEntity, null if nothing available. */ public static GenericSpawnpoint getSpawnpointSingle() { String target = BaseQ2.getSpawnpoint(); if (target == null) { // look for an info_player_start spawnpoint that's not a target Vector list = Game.getLevelRegistryList(q2java.baseq2.spawn.info_player_start.REGISTRY_KEY); Enumeration enum = list.elements(); while (enum.hasMoreElements()) { GenericSpawnpoint sp = (GenericSpawnpoint) enum.nextElement(); if (sp.getTargetGroup() == null) return sp; } // all info_player_starts are targets, so settle for the first one (if available) if (list.size() > 0) return (GenericSpawnpoint) list.elementAt(0); } else
public CTFPlayer[] getPlayers() { CTFPlayer[] players = new CTFPlayer[ fPlayers.size() ]; fPlayers.copyInto( players ); return players; }
public int getNumPlayers() { return fPlayers.size(); }
/** * Select a random spawnpoint, but exclude the two points closest * to other players. * @return q2jgame.GameEntity */ public static GenericSpawnpoint getSpawnpointRandom() { GenericSpawnpoint spawnPoint = null; GenericSpawnpoint spot1 = null; GenericSpawnpoint spot2 = null; float range1 = Float.MAX_VALUE; float range2 = Float.MAX_VALUE; int count = 0; // find the two deathmatch spawnpoints that are closest to any players Vector list = Game.getLevelRegistryList(q2java.baseq2.spawn.info_player_deathmatch.REGISTRY_KEY); // if no deathmatch spawnpoint, try single-player ones if (list.size() < 1) list = Game.getLevelRegistryList(q2java.baseq2.spawn.info_player_start.REGISTRY_KEY); Enumeration enum = list.elements(); while (enum.hasMoreElements()) { count++; spawnPoint = (GenericSpawnpoint) enum.nextElement(); float range = MiscUtil.nearestPlayerDistance(spawnPoint); if (range < range1) { range1 = range; spot1 = spawnPoint; } else { if (range < range2) { range2 = range; spot2 = spawnPoint; } } } if (count == 0) return null; if (count <= 2) spot1 = spot2 = null; else count -= 2; int selection = (GameUtil.randomInt() & 0x0fff) % count; spawnPoint = null; enum = list.elements(); while (enum.hasMoreElements()) { spawnPoint = (GenericSpawnpoint) enum.nextElement(); // skip the undesirable spots if ((spawnPoint == spot1) || (spawnPoint == spot2)) continue; if ((selection--) == 0) break; } return spawnPoint; }
public boolean isCellWithinRegion(Point3f point, Cell cell, boolean completelyInside) { logger.logComment("Checking point: " + point + " in: " + toString()); float minXLoc, minYLoc, minZLoc; float maxXLoc, maxYLoc, maxZLoc; Segment firstSeg = cell.getFirstSomaSegment(); if (completelyInside) logger.logComment("Cell needs to be completely inside"); else logger.logComment( "Only cell centre (" + firstSeg.getStartPointPosition() + ") needs to be inside"); int factor = 0; if (completelyInside) factor = 1; minXLoc = parameterList[0].value + factor * firstSeg.getSection().getStartRadius(); minYLoc = parameterList[1].value + factor * firstSeg.getSection().getStartRadius(); minZLoc = parameterList[2].value + factor * firstSeg.getSection().getStartRadius(); maxXLoc = parameterList[0].value + parameterList[3].value - factor * firstSeg.getSection().getStartRadius(); maxYLoc = parameterList[1].value + parameterList[4].value - factor * firstSeg.getSection().getStartRadius(); maxZLoc = parameterList[2].value + parameterList[5].value - factor * firstSeg.getSection().getStartRadius(); Point3f actualStartOfSoma = new Point3f( point.x + firstSeg.getSection().getStartPointPositionX(), point.y + firstSeg.getSection().getStartPointPositionY(), point.z + firstSeg.getSection().getStartPointPositionZ()); logger.logComment( "actualStartOfSoma: " + actualStartOfSoma + ", radius: " + firstSeg.getSection().getStartRadius()); if (actualStartOfSoma.x < minXLoc || actualStartOfSoma.x > maxXLoc || actualStartOfSoma.y < minYLoc || actualStartOfSoma.y > maxYLoc || actualStartOfSoma.z < minZLoc || actualStartOfSoma.z > maxZLoc) return false; if (completelyInside) { Vector somaSegments = cell.getOnlySomaSegments(); for (int i = 0; i < somaSegments.size(); i++) { Segment nextSeg = (Segment) somaSegments.elementAt(i); Point3f actualEndPoint = new Point3f( point.x + nextSeg.getEndPointPositionX(), point.y + nextSeg.getEndPointPositionY(), point.z + nextSeg.getEndPointPositionZ()); logger.logComment("actualEndPoint: " + actualEndPoint + ", radius: " + nextSeg.getRadius()); if (actualEndPoint.x < parameterList[0].value + nextSeg.getRadius() || actualEndPoint.x > parameterList[0].value + parameterList[3].value - nextSeg.getRadius() || actualEndPoint.y < parameterList[1].value + nextSeg.getRadius() || actualEndPoint.y > parameterList[1].value + parameterList[4].value - nextSeg.getRadius() || actualEndPoint.z < parameterList[2].value + nextSeg.getRadius() || actualEndPoint.z > parameterList[2].value + parameterList[5].value - nextSeg.getRadius()) return false; } } return true; }
private void createSections() { float axonRadius = .5f; Point3f posnEndPoint = new Point3f(0, -15, 0); Segment rootAxon = addAxonalSegment(axonRadius, "root", posnEndPoint, somaSection, 1, "axonRootSec"); Vector<Segment> layer = new Vector<Segment>(); layer.add(addRelativeAxon(rootAxon, new Point3f(-30, -20, -30), axonRadius)); layer.add(addRelativeAxon(rootAxon, new Point3f(-30, -20, 30), axonRadius)); layer.add(addRelativeAxon(rootAxon, new Point3f(30, -20, 30), axonRadius)); layer.add(addRelativeAxon(rootAxon, new Point3f(30, -20, -30), axonRadius)); for (int i = 0; i < layer.size(); i++) { Segment axon = (Segment) layer.elementAt(i); Segment a1 = addRelativeAxon(axon, new Point3f(-6, -4, -6), axonRadius); Segment a2 = addRelativeAxon(axon, new Point3f(6, -4, -6), axonRadius); Segment a3 = addRelativeAxon(axon, new Point3f(-6, -4, 6), axonRadius); Segment a4 = addRelativeAxon(axon, new Point3f(6, -4, 6), axonRadius); a1.getSection().addToGroup(axonSynGroup); a2.getSection().addToGroup(axonSynGroup); a3.getSection().addToGroup(axonSynGroup); a4.getSection().addToGroup(axonSynGroup); } float dendriteDiam = 2; int numDendrites = 6; for (int i = 0; i < numDendrites; i++) { double theta = ((2 * Math.PI) / numDendrites) * i; float xFact = (float) Math.sin(theta); float zFact = (float) Math.cos(theta); posnEndPoint = new Point3f(60 * xFact, 60, 60 * zFact); Segment radialDend = addDendriticSegment( dendriteDiam, "radialDend_" + i, posnEndPoint, somaSection, 0, "radialDend_" + i + "_Sec", false); Point3f posnNew = new Point3f(30 * xFact, 40, 30 * zFact); Segment radialDend2 = addRelativeDendrite(radialDend, posnNew); radialDend2.getSection().addToGroup(dendSynGroup); Point3f posnNew2 = new Point3f(0, 30, 0); Segment radialDend3 = addRelativeDendrite(radialDend2, posnNew2); radialDend3.getSection().addToGroup(dendSynGroup); Point3f posnNew3 = new Point3f(-10 * xFact, 30, -10 * zFact); Segment radialDend4 = addRelativeDendrite(radialDend, posnNew3); radialDend4.getSection().addToGroup(dendSynGroup); Point3f posnNew4 = new Point3f(0, 25, 0); Segment radialDend5 = addRelativeDendrite(radialDend4, posnNew4); radialDend5.getSection().addToGroup(dendSynGroup); } }