Java程序  |  275行  |  8.5 KB

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package com.jme3.bullet;

import com.jme3.app.Application;
import com.jme3.app.state.AppState;
import com.jme3.app.state.AppStateManager;
import com.jme3.bullet.PhysicsSpace.BroadphaseType;
import com.jme3.math.Vector3f;
import com.jme3.renderer.RenderManager;
import java.util.concurrent.*;
import java.util.logging.Level;
import java.util.logging.Logger;

/**
 * <code>BulletAppState</code> allows using bullet physics in an Application.
 * @author normenhansen
 */
public class BulletAppState implements AppState, PhysicsTickListener {

    protected boolean initialized = false;
    protected Application app;
    protected AppStateManager stateManager;
    protected ScheduledThreadPoolExecutor executor;
    protected PhysicsSpace pSpace;
    protected ThreadingType threadingType = ThreadingType.SEQUENTIAL;
    protected BroadphaseType broadphaseType = BroadphaseType.DBVT;
    protected Vector3f worldMin = new Vector3f(-10000f, -10000f, -10000f);
    protected Vector3f worldMax = new Vector3f(10000f, 10000f, 10000f);
    private float speed = 1;
    protected boolean active = true;
    protected float tpf;
    protected Future physicsFuture;

    /**
     * Creates a new BulletAppState running a PhysicsSpace for physics simulation,
     * use getStateManager().addState(bulletAppState) to enable physics for an Application.
     */
    public BulletAppState() {
    }

    /**
     * Creates a new BulletAppState running a PhysicsSpace for physics simulation,
     * use getStateManager().addState(bulletAppState) to enable physics for an Application.
     * @param broadphaseType The type of broadphase collision detection, BroadphaseType.DVBT is the default
     */
    public BulletAppState(BroadphaseType broadphaseType) {
        this(new Vector3f(-10000f, -10000f, -10000f), new Vector3f(10000f, 10000f, 10000f), broadphaseType);
    }

    /**
     * Creates a new BulletAppState running a PhysicsSpace for physics simulation,
     * use getStateManager().addState(bulletAppState) to enable physics for an Application.
     * An AxisSweep broadphase is used.
     * @param worldMin The minimum world extent
     * @param worldMax The maximum world extent
     */
    public BulletAppState(Vector3f worldMin, Vector3f worldMax) {
        this(worldMin, worldMax, BroadphaseType.AXIS_SWEEP_3);
    }

    public BulletAppState(Vector3f worldMin, Vector3f worldMax, BroadphaseType broadphaseType) {
        this.worldMin.set(worldMin);
        this.worldMax.set(worldMax);
        this.broadphaseType = broadphaseType;
    }

    private boolean startPhysicsOnExecutor() {
        if (executor != null) {
            executor.shutdown();
        }
        executor = new ScheduledThreadPoolExecutor(1);
        final BulletAppState app = this;
        Callable<Boolean> call = new Callable<Boolean>() {

            public Boolean call() throws Exception {
                detachedPhysicsLastUpdate = System.currentTimeMillis();
                pSpace = new PhysicsSpace(worldMin, worldMax, broadphaseType);
                pSpace.addTickListener(app);
                return true;
            }
        };
        try {
            return executor.submit(call).get();
        } catch (InterruptedException ex) {
            Logger.getLogger(BulletAppState.class.getName()).log(Level.SEVERE, null, ex);
            return false;
        } catch (ExecutionException ex) {
            Logger.getLogger(BulletAppState.class.getName()).log(Level.SEVERE, null, ex);
            return false;
        }
    }
    private Callable<Boolean> parallelPhysicsUpdate = new Callable<Boolean>() {

        public Boolean call() throws Exception {
            pSpace.update(tpf * getSpeed());
            return true;
        }
    };
    long detachedPhysicsLastUpdate = 0;
    private Callable<Boolean> detachedPhysicsUpdate = new Callable<Boolean>() {

        public Boolean call() throws Exception {
            pSpace.update(getPhysicsSpace().getAccuracy() * getSpeed());
            pSpace.distributeEvents();
            long update = System.currentTimeMillis() - detachedPhysicsLastUpdate;
            detachedPhysicsLastUpdate = System.currentTimeMillis();
            executor.schedule(detachedPhysicsUpdate, Math.round(getPhysicsSpace().getAccuracy() * 1000000.0f) - (update * 1000), TimeUnit.MICROSECONDS);
            return true;
        }
    };

    public PhysicsSpace getPhysicsSpace() {
        return pSpace;
    }

    /**
     * The physics system is started automatically on attaching, if you want to start it
     * before for some reason, you can use this method.
     */
    public void startPhysics() {
        //start physics thread(pool)
        if (threadingType == ThreadingType.PARALLEL) {
            startPhysicsOnExecutor();
//        } else if (threadingType == ThreadingType.DETACHED) {
//            startPhysicsOnExecutor();
//            executor.submit(detachedPhysicsUpdate);
        } else {
            pSpace = new PhysicsSpace(worldMin, worldMax, broadphaseType);
        }
        pSpace.addTickListener(this);
        initialized = true;
    }

    public void initialize(AppStateManager stateManager, Application app) {
        if (!initialized) {
            startPhysics();
        }
        initialized = true;
    }

    public boolean isInitialized() {
        return initialized;
    }
    
    public void setEnabled(boolean enabled) {
        this.active = enabled;
    }
    
    public boolean isEnabled() {
        return active;
    }

    public void stateAttached(AppStateManager stateManager) {
        if (!initialized) {
            startPhysics();
        }
        if (threadingType == ThreadingType.PARALLEL) {
            PhysicsSpace.setLocalThreadPhysicsSpace(pSpace);
        }
    }

    public void stateDetached(AppStateManager stateManager) {
    }

    public void update(float tpf) {
        if (!active) {
            return;
        }
//        if (threadingType != ThreadingType.DETACHED) {
            pSpace.distributeEvents();
//        }
        this.tpf = tpf;
    }

    public void render(RenderManager rm) {
        if (!active) {
            return;
        }
        if (threadingType == ThreadingType.PARALLEL) {
            physicsFuture = executor.submit(parallelPhysicsUpdate);
        } else if (threadingType == ThreadingType.SEQUENTIAL) {
            pSpace.update(active ? tpf * speed : 0);
        } else {
        }
    }

    public void postRender() {
        if (physicsFuture != null) {
            try {
                physicsFuture.get();
                physicsFuture = null;
            } catch (InterruptedException ex) {
                Logger.getLogger(BulletAppState.class.getName()).log(Level.SEVERE, null, ex);
            } catch (ExecutionException ex) {
                Logger.getLogger(BulletAppState.class.getName()).log(Level.SEVERE, null, ex);
            }
        }
    }

    public void cleanup() {
        if (executor != null) {
            executor.shutdown();
            executor = null;
        }
        pSpace.removeTickListener(this);
        pSpace.destroy();
    }

    /**
     * @return the threadingType
     */
    public ThreadingType getThreadingType() {
        return threadingType;
    }

    /**
     * Use before attaching state
     * @param threadingType the threadingType to set
     */
    public void setThreadingType(ThreadingType threadingType) {
        this.threadingType = threadingType;
    }

    /**
     * Use before attaching state
     */
    public void setBroadphaseType(BroadphaseType broadphaseType) {
        this.broadphaseType = broadphaseType;
    }

    /**
     * Use before attaching state
     */
    public void setWorldMin(Vector3f worldMin) {
        this.worldMin = worldMin;
    }

    /**
     * Use before attaching state
     */
    public void setWorldMax(Vector3f worldMax) {
        this.worldMax = worldMax;
    }

    public float getSpeed() {
        return speed;
    }

    public void setSpeed(float speed) {
        this.speed = speed;
    }

    public void prePhysicsTick(PhysicsSpace space, float f) {
    }

    public void physicsTick(PhysicsSpace space, float f) {
    }

    public enum ThreadingType {

        /**
         * Default mode; user update, physics update and rendering happen sequentially (single threaded)
         */
        SEQUENTIAL,
        /**
         * Parallel threaded mode; physics update and rendering are executed in parallel, update order is kept.<br/>
         * Multiple BulletAppStates will execute in parallel in this mode.
         */
        PARALLEL,
    }
}