/* * Copyright (c) 2009-2010 jMonkeyEngine * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions are * met: * * * Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * * * Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * * Neither the name of 'jMonkeyEngine' nor the names of its contributors * may be used to endorse or promote products derived from this software * without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED * TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR * PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR * CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, * EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, * PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR * PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF * LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING * NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS * SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ package com.jme3.bullet; import com.bulletphysics.BulletGlobals; import com.bulletphysics.ContactAddedCallback; import com.bulletphysics.ContactDestroyedCallback; import com.bulletphysics.ContactProcessedCallback; import com.bulletphysics.collision.broadphase.*; import com.bulletphysics.collision.dispatch.CollisionWorld.LocalConvexResult; import com.bulletphysics.collision.dispatch.CollisionWorld.LocalRayResult; import com.bulletphysics.collision.dispatch.*; import com.bulletphysics.collision.narrowphase.ManifoldPoint; import com.bulletphysics.collision.shapes.ConvexShape; import com.bulletphysics.dynamics.DiscreteDynamicsWorld; import com.bulletphysics.dynamics.DynamicsWorld; import com.bulletphysics.dynamics.InternalTickCallback; import com.bulletphysics.dynamics.RigidBody; import com.bulletphysics.dynamics.constraintsolver.ConstraintSolver; import com.bulletphysics.dynamics.constraintsolver.SequentialImpulseConstraintSolver; import com.bulletphysics.extras.gimpact.GImpactCollisionAlgorithm; import com.jme3.app.AppTask; import com.jme3.asset.AssetManager; import com.jme3.bullet.collision.*; import com.jme3.bullet.collision.shapes.CollisionShape; import com.jme3.bullet.control.PhysicsControl; import com.jme3.bullet.control.RigidBodyControl; import com.jme3.bullet.joints.PhysicsJoint; import com.jme3.bullet.objects.PhysicsCharacter; import com.jme3.bullet.objects.PhysicsGhostObject; import com.jme3.bullet.objects.PhysicsRigidBody; import com.jme3.bullet.objects.PhysicsVehicle; import com.jme3.bullet.util.Converter; import com.jme3.math.Transform; import com.jme3.math.Vector3f; import com.jme3.scene.Node; import com.jme3.scene.Spatial; import java.util.Iterator; import java.util.LinkedList; import java.util.List; import java.util.Map; import java.util.concurrent.Callable; import java.util.concurrent.ConcurrentHashMap; import java.util.concurrent.ConcurrentLinkedQueue; import java.util.concurrent.Future; import java.util.logging.Level; import java.util.logging.Logger; /** * <p>PhysicsSpace - The central jbullet-jme physics space</p> * @author normenhansen */ public class PhysicsSpace { public static final int AXIS_X = 0; public static final int AXIS_Y = 1; public static final int AXIS_Z = 2; private static ThreadLocal<ConcurrentLinkedQueue<AppTask<?>>> pQueueTL = new ThreadLocal<ConcurrentLinkedQueue<AppTask<?>>>() { @Override protected ConcurrentLinkedQueue<AppTask<?>> initialValue() { return new ConcurrentLinkedQueue<AppTask<?>>(); } }; private ConcurrentLinkedQueue<AppTask<?>> pQueue = new ConcurrentLinkedQueue<AppTask<?>>(); private static ThreadLocal<PhysicsSpace> physicsSpaceTL = new ThreadLocal<PhysicsSpace>(); private DiscreteDynamicsWorld dynamicsWorld = null; private BroadphaseInterface broadphase; private BroadphaseType broadphaseType = BroadphaseType.DBVT; private CollisionDispatcher dispatcher; private ConstraintSolver solver; private DefaultCollisionConfiguration collisionConfiguration; // private Map<GhostObject, PhysicsGhostObject> physicsGhostNodes = new ConcurrentHashMap<GhostObject, PhysicsGhostObject>(); private Map<RigidBody, PhysicsRigidBody> physicsNodes = new ConcurrentHashMap<RigidBody, PhysicsRigidBody>(); private List<PhysicsJoint> physicsJoints = new LinkedList<PhysicsJoint>(); private List<PhysicsCollisionListener> collisionListeners = new LinkedList<PhysicsCollisionListener>(); private List<PhysicsCollisionEvent> collisionEvents = new LinkedList<PhysicsCollisionEvent>(); private Map<Integer, PhysicsCollisionGroupListener> collisionGroupListeners = new ConcurrentHashMap<Integer, PhysicsCollisionGroupListener>(); private ConcurrentLinkedQueue<PhysicsTickListener> tickListeners = new ConcurrentLinkedQueue<PhysicsTickListener>(); private PhysicsCollisionEventFactory eventFactory = new PhysicsCollisionEventFactory(); private Vector3f worldMin = new Vector3f(-10000f, -10000f, -10000f); private Vector3f worldMax = new Vector3f(10000f, 10000f, 10000f); private float accuracy = 1f / 60f; private int maxSubSteps = 4; private javax.vecmath.Vector3f rayVec1 = new javax.vecmath.Vector3f(); private javax.vecmath.Vector3f rayVec2 = new javax.vecmath.Vector3f(); private com.bulletphysics.linearmath.Transform sweepTrans1 = new com.bulletphysics.linearmath.Transform(new javax.vecmath.Matrix3f()); private com.bulletphysics.linearmath.Transform sweepTrans2 = new com.bulletphysics.linearmath.Transform(new javax.vecmath.Matrix3f()); private AssetManager debugManager; /** * Get the current PhysicsSpace <b>running on this thread</b><br/> * For parallel physics, this can also be called from the OpenGL thread to receive the PhysicsSpace * @return the PhysicsSpace running on this thread */ public static PhysicsSpace getPhysicsSpace() { return physicsSpaceTL.get(); } /** * Used internally * @param space */ public static void setLocalThreadPhysicsSpace(PhysicsSpace space) { physicsSpaceTL.set(space); } public PhysicsSpace() { this(new Vector3f(-10000f, -10000f, -10000f), new Vector3f(10000f, 10000f, 10000f), BroadphaseType.DBVT); } public PhysicsSpace(BroadphaseType broadphaseType) { this(new Vector3f(-10000f, -10000f, -10000f), new Vector3f(10000f, 10000f, 10000f), broadphaseType); } public PhysicsSpace(Vector3f worldMin, Vector3f worldMax) { this(worldMin, worldMax, BroadphaseType.AXIS_SWEEP_3); } public PhysicsSpace(Vector3f worldMin, Vector3f worldMax, BroadphaseType broadphaseType) { this.worldMin.set(worldMin); this.worldMax.set(worldMax); this.broadphaseType = broadphaseType; create(); } /** * Has to be called from the (designated) physics thread */ public void create() { pQueueTL.set(pQueue); collisionConfiguration = new DefaultCollisionConfiguration(); dispatcher = new CollisionDispatcher(collisionConfiguration); switch (broadphaseType) { case SIMPLE: broadphase = new SimpleBroadphase(); break; case AXIS_SWEEP_3: broadphase = new AxisSweep3(Converter.convert(worldMin), Converter.convert(worldMax)); break; case AXIS_SWEEP_3_32: broadphase = new AxisSweep3_32(Converter.convert(worldMin), Converter.convert(worldMax)); break; case DBVT: broadphase = new DbvtBroadphase(); break; } solver = new SequentialImpulseConstraintSolver(); dynamicsWorld = new DiscreteDynamicsWorld(dispatcher, broadphase, solver, collisionConfiguration); dynamicsWorld.setGravity(new javax.vecmath.Vector3f(0, -9.81f, 0)); broadphase.getOverlappingPairCache().setInternalGhostPairCallback(new GhostPairCallback()); GImpactCollisionAlgorithm.registerAlgorithm(dispatcher); physicsSpaceTL.set(this); //register filter callback for tick / collision setTickCallback(); setContactCallbacks(); //register filter callback for collision groups setOverlapFilterCallback(); } private void setOverlapFilterCallback() { OverlapFilterCallback callback = new OverlapFilterCallback() { public boolean needBroadphaseCollision(BroadphaseProxy bp, BroadphaseProxy bp1) { boolean collides = (bp.collisionFilterGroup & bp1.collisionFilterMask) != 0; if (collides) { collides = (bp1.collisionFilterGroup & bp.collisionFilterMask) != 0; } if (collides) { assert (bp.clientObject instanceof com.bulletphysics.collision.dispatch.CollisionObject && bp.clientObject instanceof com.bulletphysics.collision.dispatch.CollisionObject); com.bulletphysics.collision.dispatch.CollisionObject colOb = (com.bulletphysics.collision.dispatch.CollisionObject) bp.clientObject; com.bulletphysics.collision.dispatch.CollisionObject colOb1 = (com.bulletphysics.collision.dispatch.CollisionObject) bp1.clientObject; assert (colOb.getUserPointer() != null && colOb1.getUserPointer() != null); PhysicsCollisionObject collisionObject = (PhysicsCollisionObject) colOb.getUserPointer(); PhysicsCollisionObject collisionObject1 = (PhysicsCollisionObject) colOb1.getUserPointer(); if ((collisionObject.getCollideWithGroups() & collisionObject1.getCollisionGroup()) > 0 || (collisionObject1.getCollideWithGroups() & collisionObject.getCollisionGroup()) > 0) { PhysicsCollisionGroupListener listener = collisionGroupListeners.get(collisionObject.getCollisionGroup()); PhysicsCollisionGroupListener listener1 = collisionGroupListeners.get(collisionObject1.getCollisionGroup()); if (listener != null) { return listener.collide(collisionObject, collisionObject1); } else if (listener1 != null) { return listener1.collide(collisionObject, collisionObject1); } return true; } else { return false; } } return collides; } }; dynamicsWorld.getPairCache().setOverlapFilterCallback(callback); } private void setTickCallback() { final PhysicsSpace space = this; InternalTickCallback callback2 = new InternalTickCallback() { @Override public void internalTick(DynamicsWorld dw, float f) { //execute task list AppTask task = pQueue.poll(); task = pQueue.poll(); while (task != null) { while (task.isCancelled()) { task = pQueue.poll(); } try { task.invoke(); } catch (Exception ex) { Logger.getLogger(PhysicsSpace.class.getName()).log(Level.SEVERE, null, ex); } task = pQueue.poll(); } for (Iterator<PhysicsTickListener> it = tickListeners.iterator(); it.hasNext();) { PhysicsTickListener physicsTickCallback = it.next(); physicsTickCallback.prePhysicsTick(space, f); } } }; dynamicsWorld.setPreTickCallback(callback2); InternalTickCallback callback = new InternalTickCallback() { @Override public void internalTick(DynamicsWorld dw, float f) { for (Iterator<PhysicsTickListener> it = tickListeners.iterator(); it.hasNext();) { PhysicsTickListener physicsTickCallback = it.next(); physicsTickCallback.physicsTick(space, f); } } }; dynamicsWorld.setInternalTickCallback(callback, this); } private void setContactCallbacks() { BulletGlobals.setContactAddedCallback(new ContactAddedCallback() { public boolean contactAdded(ManifoldPoint cp, com.bulletphysics.collision.dispatch.CollisionObject colObj0, int partId0, int index0, com.bulletphysics.collision.dispatch.CollisionObject colObj1, int partId1, int index1) { System.out.println("contact added"); return true; } }); BulletGlobals.setContactProcessedCallback(new ContactProcessedCallback() { public boolean contactProcessed(ManifoldPoint cp, Object body0, Object body1) { if (body0 instanceof CollisionObject && body1 instanceof CollisionObject) { PhysicsCollisionObject node = null, node1 = null; CollisionObject rBody0 = (CollisionObject) body0; CollisionObject rBody1 = (CollisionObject) body1; node = (PhysicsCollisionObject) rBody0.getUserPointer(); node1 = (PhysicsCollisionObject) rBody1.getUserPointer(); collisionEvents.add(eventFactory.getEvent(PhysicsCollisionEvent.TYPE_PROCESSED, node, node1, cp)); } return true; } }); BulletGlobals.setContactDestroyedCallback(new ContactDestroyedCallback() { public boolean contactDestroyed(Object userPersistentData) { System.out.println("contact destroyed"); return true; } }); } /** * updates the physics space * @param time the current time value */ public void update(float time) { update(time, maxSubSteps); } /** * updates the physics space, uses maxSteps<br> * @param time the current time value * @param maxSteps */ public void update(float time, int maxSteps) { if (getDynamicsWorld() == null) { return; } //step simulation dynamicsWorld.stepSimulation(time, maxSteps, accuracy); } public void distributeEvents() { //add collision callbacks synchronized (collisionEvents) { for (Iterator<PhysicsCollisionEvent> it = collisionEvents.iterator(); it.hasNext();) { PhysicsCollisionEvent physicsCollisionEvent = it.next(); for (PhysicsCollisionListener listener : collisionListeners) { listener.collision(physicsCollisionEvent); } //recycle events eventFactory.recycle(physicsCollisionEvent); it.remove(); } } } public static <V> Future<V> enqueueOnThisThread(Callable<V> callable) { AppTask<V> task = new AppTask<V>(callable); System.out.println("created apptask"); pQueueTL.get().add(task); return task; } /** * calls the callable on the next physics tick (ensuring e.g. force applying) * @param <V> * @param callable * @return */ public <V> Future<V> enqueue(Callable<V> callable) { AppTask<V> task = new AppTask<V>(callable); pQueue.add(task); return task; } /** * adds an object to the physics space * @param obj the PhysicsControl or Spatial with PhysicsControl to add */ public void add(Object obj) { if (obj instanceof PhysicsControl) { ((PhysicsControl) obj).setPhysicsSpace(this); } else if (obj instanceof Spatial) { Spatial node = (Spatial) obj; PhysicsControl control = node.getControl(PhysicsControl.class); control.setPhysicsSpace(this); } else if (obj instanceof PhysicsCollisionObject) { addCollisionObject((PhysicsCollisionObject) obj); } else if (obj instanceof PhysicsJoint) { addJoint((PhysicsJoint) obj); } else { throw (new UnsupportedOperationException("Cannot add this kind of object to the physics space.")); } } public void addCollisionObject(PhysicsCollisionObject obj) { if (obj instanceof PhysicsGhostObject) { addGhostObject((PhysicsGhostObject) obj); } else if (obj instanceof PhysicsRigidBody) { addRigidBody((PhysicsRigidBody) obj); } else if (obj instanceof PhysicsVehicle) { addRigidBody((PhysicsVehicle) obj); } else if (obj instanceof PhysicsCharacter) { addCharacter((PhysicsCharacter) obj); } } /** * removes an object from the physics space * @param obj the PhysicsControl or Spatial with PhysicsControl to remove */ public void remove(Object obj) { if (obj instanceof PhysicsControl) { ((PhysicsControl) obj).setPhysicsSpace(null); } else if (obj instanceof Spatial) { Spatial node = (Spatial) obj; PhysicsControl control = node.getControl(PhysicsControl.class); control.setPhysicsSpace(null); } else if (obj instanceof PhysicsCollisionObject) { removeCollisionObject((PhysicsCollisionObject) obj); } else if (obj instanceof PhysicsJoint) { removeJoint((PhysicsJoint) obj); } else { throw (new UnsupportedOperationException("Cannot remove this kind of object from the physics space.")); } } public void removeCollisionObject(PhysicsCollisionObject obj) { if (obj instanceof PhysicsGhostObject) { removeGhostObject((PhysicsGhostObject) obj); } else if (obj instanceof PhysicsRigidBody) { removeRigidBody((PhysicsRigidBody) obj); } else if (obj instanceof PhysicsCharacter) { removeCharacter((PhysicsCharacter) obj); } } /** * adds all physics controls and joints in the given spatial node to the physics space * (e.g. after loading from disk) - recursive if node * @param spatial the rootnode containing the physics objects */ public void addAll(Spatial spatial) { if (spatial.getControl(RigidBodyControl.class) != null) { RigidBodyControl physicsNode = spatial.getControl(RigidBodyControl.class); if (!physicsNodes.containsValue(physicsNode)) { physicsNode.setPhysicsSpace(this); } //add joints List<PhysicsJoint> joints = physicsNode.getJoints(); for (Iterator<PhysicsJoint> it1 = joints.iterator(); it1.hasNext();) { PhysicsJoint physicsJoint = it1.next(); //add connected physicsnodes if they are not already added if (!physicsNodes.containsValue(physicsJoint.getBodyA())) { if (physicsJoint.getBodyA() instanceof PhysicsControl) { add(physicsJoint.getBodyA()); } else { addRigidBody(physicsJoint.getBodyA()); } } if (!physicsNodes.containsValue(physicsJoint.getBodyB())) { if (physicsJoint.getBodyA() instanceof PhysicsControl) { add(physicsJoint.getBodyB()); } else { addRigidBody(physicsJoint.getBodyB()); } } if (!physicsJoints.contains(physicsJoint)) { addJoint(physicsJoint); } } } else if (spatial.getControl(PhysicsControl.class) != null) { spatial.getControl(PhysicsControl.class).setPhysicsSpace(this); } //recursion if (spatial instanceof Node) { List<Spatial> children = ((Node) spatial).getChildren(); for (Iterator<Spatial> it = children.iterator(); it.hasNext();) { Spatial spat = it.next(); addAll(spat); } } } /** * Removes all physics controls and joints in the given spatial from the physics space * (e.g. before saving to disk) - recursive if node * @param spatial the rootnode containing the physics objects */ public void removeAll(Spatial spatial) { if (spatial.getControl(RigidBodyControl.class) != null) { RigidBodyControl physicsNode = spatial.getControl(RigidBodyControl.class); if (physicsNodes.containsValue(physicsNode)) { physicsNode.setPhysicsSpace(null); } //remove joints List<PhysicsJoint> joints = physicsNode.getJoints(); for (Iterator<PhysicsJoint> it1 = joints.iterator(); it1.hasNext();) { PhysicsJoint physicsJoint = it1.next(); //add connected physicsnodes if they are not already added if (physicsNodes.containsValue(physicsJoint.getBodyA())) { if (physicsJoint.getBodyA() instanceof PhysicsControl) { remove(physicsJoint.getBodyA()); } else { removeRigidBody(physicsJoint.getBodyA()); } } if (physicsNodes.containsValue(physicsJoint.getBodyB())) { if (physicsJoint.getBodyA() instanceof PhysicsControl) { remove(physicsJoint.getBodyB()); } else { removeRigidBody(physicsJoint.getBodyB()); } } if (physicsJoints.contains(physicsJoint)) { removeJoint(physicsJoint); } } } else if (spatial.getControl(PhysicsControl.class) != null) { spatial.getControl(PhysicsControl.class).setPhysicsSpace(null); } //recursion if (spatial instanceof Node) { List<Spatial> children = ((Node) spatial).getChildren(); for (Iterator<Spatial> it = children.iterator(); it.hasNext();) { Spatial spat = it.next(); removeAll(spat); } } } private void addGhostObject(PhysicsGhostObject node) { Logger.getLogger(PhysicsSpace.class.getName()).log(Level.INFO, "Adding ghost object {0} to physics space.", node.getObjectId()); dynamicsWorld.addCollisionObject(node.getObjectId()); } private void removeGhostObject(PhysicsGhostObject node) { Logger.getLogger(PhysicsSpace.class.getName()).log(Level.INFO, "Removing ghost object {0} from physics space.", node.getObjectId()); dynamicsWorld.removeCollisionObject(node.getObjectId()); } private void addCharacter(PhysicsCharacter node) { Logger.getLogger(PhysicsSpace.class.getName()).log(Level.INFO, "Adding character {0} to physics space.", node.getObjectId()); // dynamicsWorld.addCollisionObject(node.getObjectId()); dynamicsWorld.addCollisionObject(node.getObjectId(), CollisionFilterGroups.CHARACTER_FILTER, (short) (CollisionFilterGroups.STATIC_FILTER | CollisionFilterGroups.DEFAULT_FILTER)); dynamicsWorld.addAction(node.getControllerId()); } private void removeCharacter(PhysicsCharacter node) { Logger.getLogger(PhysicsSpace.class.getName()).log(Level.INFO, "Removing character {0} from physics space.", node.getObjectId()); dynamicsWorld.removeAction(node.getControllerId()); dynamicsWorld.removeCollisionObject(node.getObjectId()); } private void addRigidBody(PhysicsRigidBody node) { physicsNodes.put(node.getObjectId(), node); //Workaround //It seems that adding a Kinematic RigidBody to the dynamicWorld prevent it from being non kinematic again afterward. //so we add it non kinematic, then set it kinematic again. boolean kinematic = false; if (node.isKinematic()) { kinematic = true; node.setKinematic(false); } dynamicsWorld.addRigidBody(node.getObjectId()); if (kinematic) { node.setKinematic(true); } Logger.getLogger(PhysicsSpace.class.getName()).log(Level.INFO, "Adding RigidBody {0} to physics space.", node.getObjectId()); if (node instanceof PhysicsVehicle) { Logger.getLogger(PhysicsSpace.class.getName()).log(Level.INFO, "Adding vehicle constraint {0} to physics space.", ((PhysicsVehicle) node).getVehicleId()); ((PhysicsVehicle) node).createVehicle(this); dynamicsWorld.addVehicle(((PhysicsVehicle) node).getVehicleId()); } } private void removeRigidBody(PhysicsRigidBody node) { if (node instanceof PhysicsVehicle) { Logger.getLogger(PhysicsSpace.class.getName()).log(Level.INFO, "Removing vehicle constraint {0} from physics space.", ((PhysicsVehicle) node).getVehicleId()); dynamicsWorld.removeVehicle(((PhysicsVehicle) node).getVehicleId()); } Logger.getLogger(PhysicsSpace.class.getName()).log(Level.INFO, "Removing RigidBody {0} from physics space.", node.getObjectId()); physicsNodes.remove(node.getObjectId()); dynamicsWorld.removeRigidBody(node.getObjectId()); } private void addJoint(PhysicsJoint joint) { Logger.getLogger(PhysicsSpace.class.getName()).log(Level.INFO, "Adding Joint {0} to physics space.", joint.getObjectId()); physicsJoints.add(joint); dynamicsWorld.addConstraint(joint.getObjectId(), !joint.isCollisionBetweenLinkedBodys()); } private void removeJoint(PhysicsJoint joint) { Logger.getLogger(PhysicsSpace.class.getName()).log(Level.INFO, "Removing Joint {0} from physics space.", joint.getObjectId()); physicsJoints.remove(joint); dynamicsWorld.removeConstraint(joint.getObjectId()); } /** * Sets the gravity of the PhysicsSpace, set before adding physics objects! * @param gravity */ public void setGravity(Vector3f gravity) { dynamicsWorld.setGravity(Converter.convert(gravity)); } /** * applies gravity value to all objects */ public void applyGravity() { dynamicsWorld.applyGravity(); } /** * clears forces of all objects */ public void clearForces() { dynamicsWorld.clearForces(); } /** * Adds the specified listener to the physics tick listeners. * The listeners are called on each physics step, which is not necessarily * each frame but is determined by the accuracy of the physics space. * @param listener */ public void addTickListener(PhysicsTickListener listener) { tickListeners.add(listener); } public void removeTickListener(PhysicsTickListener listener) { tickListeners.remove(listener); } /** * Adds a CollisionListener that will be informed about collision events * @param listener the CollisionListener to add */ public void addCollisionListener(PhysicsCollisionListener listener) { collisionListeners.add(listener); } /** * Removes a CollisionListener from the list * @param listener the CollisionListener to remove */ public void removeCollisionListener(PhysicsCollisionListener listener) { collisionListeners.remove(listener); } /** * Adds a listener for a specific collision group, such a listener can disable collisions when they happen.<br> * There can be only one listener per collision group. * @param listener * @param collisionGroup */ public void addCollisionGroupListener(PhysicsCollisionGroupListener listener, int collisionGroup) { collisionGroupListeners.put(collisionGroup, listener); } public void removeCollisionGroupListener(int collisionGroup) { collisionGroupListeners.remove(collisionGroup); } /** * Performs a ray collision test and returns the results as a list of PhysicsRayTestResults */ public List<PhysicsRayTestResult> rayTest(Vector3f from, Vector3f to) { List<PhysicsRayTestResult> results = new LinkedList<PhysicsRayTestResult>(); dynamicsWorld.rayTest(Converter.convert(from, rayVec1), Converter.convert(to, rayVec2), new InternalRayListener(results)); return results; } /** * Performs a ray collision test and returns the results as a list of PhysicsRayTestResults */ public List<PhysicsRayTestResult> rayTest(Vector3f from, Vector3f to, List<PhysicsRayTestResult> results) { results.clear(); dynamicsWorld.rayTest(Converter.convert(from, rayVec1), Converter.convert(to, rayVec2), new InternalRayListener(results)); return results; } private class InternalRayListener extends CollisionWorld.RayResultCallback { private List<PhysicsRayTestResult> results; public InternalRayListener(List<PhysicsRayTestResult> results) { this.results = results; } @Override public float addSingleResult(LocalRayResult lrr, boolean bln) { PhysicsCollisionObject obj = (PhysicsCollisionObject) lrr.collisionObject.getUserPointer(); results.add(new PhysicsRayTestResult(obj, Converter.convert(lrr.hitNormalLocal), lrr.hitFraction, bln)); return lrr.hitFraction; } } /** * Performs a sweep collision test and returns the results as a list of PhysicsSweepTestResults<br/> * You have to use different Transforms for start and end (at least distance > 0.4f). * SweepTest will not see a collision if it starts INSIDE an object and is moving AWAY from its center. */ public List<PhysicsSweepTestResult> sweepTest(CollisionShape shape, Transform start, Transform end) { List<PhysicsSweepTestResult> results = new LinkedList<PhysicsSweepTestResult>(); if (!(shape.getCShape() instanceof ConvexShape)) { Logger.getLogger(PhysicsSpace.class.getName()).log(Level.WARNING, "Trying to sweep test with incompatible mesh shape!"); return results; } dynamicsWorld.convexSweepTest((ConvexShape) shape.getCShape(), Converter.convert(start, sweepTrans1), Converter.convert(end, sweepTrans2), new InternalSweepListener(results)); return results; } /** * Performs a sweep collision test and returns the results as a list of PhysicsSweepTestResults<br/> * You have to use different Transforms for start and end (at least distance > 0.4f). * SweepTest will not see a collision if it starts INSIDE an object and is moving AWAY from its center. */ public List<PhysicsSweepTestResult> sweepTest(CollisionShape shape, Transform start, Transform end, List<PhysicsSweepTestResult> results) { results.clear(); if (!(shape.getCShape() instanceof ConvexShape)) { Logger.getLogger(PhysicsSpace.class.getName()).log(Level.WARNING, "Trying to sweep test with incompatible mesh shape!"); return results; } dynamicsWorld.convexSweepTest((ConvexShape) shape.getCShape(), Converter.convert(start, sweepTrans1), Converter.convert(end, sweepTrans2), new InternalSweepListener(results)); return results; } private class InternalSweepListener extends CollisionWorld.ConvexResultCallback { private List<PhysicsSweepTestResult> results; public InternalSweepListener(List<PhysicsSweepTestResult> results) { this.results = results; } @Override public float addSingleResult(LocalConvexResult lcr, boolean bln) { PhysicsCollisionObject obj = (PhysicsCollisionObject) lcr.hitCollisionObject.getUserPointer(); results.add(new PhysicsSweepTestResult(obj, Converter.convert(lcr.hitNormalLocal), lcr.hitFraction, bln)); return lcr.hitFraction; } } /** * destroys the current PhysicsSpace so that a new one can be created */ public void destroy() { physicsNodes.clear(); physicsJoints.clear(); dynamicsWorld.destroy(); dynamicsWorld = null; } /** * used internally * @return the dynamicsWorld */ public DynamicsWorld getDynamicsWorld() { return dynamicsWorld; } public BroadphaseType getBroadphaseType() { return broadphaseType; } public void setBroadphaseType(BroadphaseType broadphaseType) { this.broadphaseType = broadphaseType; } /** * Sets the maximum amount of extra steps that will be used to step the physics * when the fps is below the physics fps. Doing this maintains determinism in physics. * For example a maximum number of 2 can compensate for framerates as low as 30fps * when the physics has the default accuracy of 60 fps. Note that setting this * value too high can make the physics drive down its own fps in case its overloaded. * @param steps The maximum number of extra steps, default is 4. */ public void setMaxSubSteps(int steps) { maxSubSteps = steps; } /** * get the current accuracy of the physics computation * @return the current accuracy */ public float getAccuracy() { return accuracy; } /** * sets the accuracy of the physics computation, default=1/60s<br> * @param accuracy */ public void setAccuracy(float accuracy) { this.accuracy = accuracy; } public Vector3f getWorldMin() { return worldMin; } /** * only applies for AXIS_SWEEP broadphase * @param worldMin */ public void setWorldMin(Vector3f worldMin) { this.worldMin.set(worldMin); } public Vector3f getWorldMax() { return worldMax; } /** * only applies for AXIS_SWEEP broadphase * @param worldMax */ public void setWorldMax(Vector3f worldMax) { this.worldMax.set(worldMax); } /** * Enable debug display for physics * @param manager AssetManager to use to create debug materials */ public void enableDebug(AssetManager manager) { debugManager = manager; } /** * Disable debug display */ public void disableDebug() { debugManager = null; } public AssetManager getDebugManager() { return debugManager; } /** * interface with Broadphase types */ public enum BroadphaseType { /** * basic Broadphase */ SIMPLE, /** * better Broadphase, needs worldBounds , max Object number = 16384 */ AXIS_SWEEP_3, /** * better Broadphase, needs worldBounds , max Object number = 65536 */ AXIS_SWEEP_3_32, /** * Broadphase allowing quicker adding/removing of physics objects */ DBVT; } }