Esempio n. 1
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  public void startDrag(Vector3f v3f) {
    dragPoint = new Vector2f();
    dragPoint.setX(v3f.getX());
    dragPoint.setY(v3f.getZ());

    dragPositions.clear();

    if (moveSmooth == false) {
      for (int i = 0; i < getSelectionCircles().size(); i++) {
        Vector2f v2f = new Vector2f();
        v2f.x = getSelectionCircles().get(i).getDoodad().getLocation().getX();
        v2f.y = getSelectionCircles().get(i).getDoodad().getLocation().getZ();

        dragPositions.add(v2f);
      }
    }

    for (int i = 0; i < getSelectionCircles().size(); i++) {
      Vector2f v2f = new Vector2f();
      v2f.x = getSelectionCircles().get(i).getDoodad().getLocation().getX();
      v2f.y = getSelectionCircles().get(i).getDoodad().getLocation().getZ();

      dragStartPositions.add(v2f);
    }
  }
Esempio n. 2
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  /**
   * Generate a collision shape for a prop.
   *
   * @param propType the type of the prop (not null)
   * @param relativeSize the prop's size relative to standard (&gt;0)
   * @param parts (not null)
   * @return a new instance
   */
  private CollisionShape createShape(String propType, float relativeSize, List<Spatial> parts) {
    assert propType != null;
    assert relativeSize > 0f : relativeSize;
    assert parts != null;
    assert !parts.isEmpty();

    if ("barrel".equals(propType)) {
      /*
       * Generate a cylindrical shape aligned with the Y-axis.
       */
      float halfHeight = 0.5f * relativeSize; // meters
      float radius = 0.472f * relativeSize; // meters
      Vector3f halfExtents = new Vector3f(radius, halfHeight, radius);
      float scaleFactor = scene.getScaleFactor();
      halfExtents.divideLocal(scaleFactor);
      CollisionShape shape = new CylinderCollisionShape(halfExtents, PhysicsSpace.AXIS_Y);
      return shape;
    }
    /*
     * Generate a compound shape composed of GImpact shapes,
     * one for each geometry.
     */
    CompoundCollisionShape shape = new CompoundCollisionShape();
    for (Spatial part : parts) {
      Geometry geometry = (Geometry) part;
      Mesh mesh = geometry.getMesh();
      CollisionShape partShape = new GImpactCollisionShape(mesh);
      Vector3f scale = part.getWorldScale();
      partShape.setScale(scale);
      shape.addChildShape(partShape, Vector3f.ZERO);
    }
    return shape;
  }
Esempio n. 3
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  public void onAnalog(String name, float value, float tpf) {
    if ((Boolean) player.getUserData("alive")) {
      if (name.equals("mousePick")) {
        // shoot Bullet
        if (System.currentTimeMillis() - bulletCooldown > 83f) {
          bulletCooldown = System.currentTimeMillis();

          Vector3f aim = getAimDirection();
          Vector3f offset = new Vector3f(aim.y / 3, -aim.x / 3, 0);

          //                    init bullet 1
          Spatial bullet = getSpatial("Bullet");
          Vector3f finalOffset = aim.add(offset).mult(30);
          Vector3f trans = player.getLocalTranslation().add(finalOffset);
          bullet.setLocalTranslation(trans);
          bullet.addControl(
              new BulletControl(
                  aim, settings.getWidth(), settings.getHeight(), particleManager, grid));
          bulletNode.attachChild(bullet);

          //                    init bullet 2
          Spatial bullet2 = getSpatial("Bullet");
          finalOffset = aim.add(offset.negate()).mult(30);
          trans = player.getLocalTranslation().add(finalOffset);
          bullet2.setLocalTranslation(trans);
          bullet2.addControl(
              new BulletControl(
                  aim, settings.getWidth(), settings.getHeight(), particleManager, grid));
          bulletNode.attachChild(bullet2);

          sound.shoot();
        }
      }
    }
  }
Esempio n. 4
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  /**
   * Returns true iff the node contains at least one intersection, after sampling at the MaxDepth
   * level.
   */
  public static boolean containsIntersection(
      OctreeNode octreeNode, int maxDepth, ArrayList<Primitive> primitives) {
    // First off, check if the node is null.
    if (octreeNode == null) {
      return false;
    }

    // Subdivide to the finest possible level.
    // The subdivision level equals 2^n, where n is max-current depth.
    int divisionLevel = 1 << (maxDepth - octreeNode.getDepth());

    Vector3f startPoint = octreeNode.getMinBound();
    Vector3f offset = octreeNode.getMaxBound().subtract(startPoint).divideLocal(divisionLevel);
    boolean sign = getValueAt(startPoint, primitives) > 0;
    Vector3f currentPoint = new Vector3f();
    for (int i = 0; i < divisionLevel + 1; i++) {
      for (int j = 0; j < divisionLevel + 1; j++) {
        for (int k = 0; k < divisionLevel + 1; k++) {
          currentPoint.x = startPoint.x + i * offset.x;
          currentPoint.y = startPoint.y + j * offset.y;
          currentPoint.z = startPoint.z + k * offset.z;

          if (getValueAt(currentPoint, primitives) > 0 != sign) {
            return true;
          }
        }
      }
    }

    return false;
  }
Esempio n. 5
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  /**
   * <code>rotateUpTo</code> is a utility function that alters the local rotation to point the Y
   * axis in the direction given by newUp.
   *
   * @param newUp the up vector to use - assumed to be a unit vector.
   */
  public void rotateUpTo(Vector3f newUp) {
    TempVars vars = TempVars.get();

    Vector3f compVecA = vars.vect1;
    Quaternion q = vars.quat1;

    // First figure out the current up vector.
    Vector3f upY = compVecA.set(Vector3f.UNIT_Y);
    Quaternion rot = localTransform.getRotation();
    rot.multLocal(upY);

    // get angle between vectors
    float angle = upY.angleBetween(newUp);

    // figure out rotation axis by taking cross product
    Vector3f rotAxis = upY.crossLocal(newUp).normalizeLocal();

    // Build a rotation quat and apply current local rotation.
    q.fromAngleNormalAxis(angle, rotAxis);
    q.mult(rot, rot);

    vars.release();

    setTransformRefresh();
  }
  public double flt(Vector3f point, Vector3f A, Vector3f B) {
    Vector3f vec_b = B;
    Vector3f vec_a = A.subtract(vec_b);
    double L = vec_a.length();

    return L * f1(point, A, B) - ft(point, A, B);
  }
Esempio n. 7
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  @Override
  public void update(float tpf) {

    entities.applyChanges();
    for (Entity e : entities) {
      // if the entity is off one side or the
      // other then teleport it
      Position pos = e.get(Position.class);
      Vector3f loc = pos.getLocation();

      boolean changed = false;
      if (loc.x < min.x) {
        loc.x += max.x - min.x;
        changed = true;
      } else if (loc.x > max.x) {
        loc.x -= max.x - min.x;
        changed = true;
      }

      if (loc.y < min.y) {
        loc.y += max.y - min.y;
        changed = true;
      } else if (loc.y > max.y) {
        loc.y -= max.y - min.y;
        changed = true;
      }

      if (changed) {
        e.set(new Position(loc, pos.getFacing()));
      }
    }
  }
Esempio n. 8
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 /**
  * Create a prop, add it to the scene with its base at the insertion point, and pick it. Assumes
  * that the application is in world-building mode.
  *
  * @param propType which kind of prop to add (not null)
  * @param relativeSize the prop's size relative to standard (&gt;0)
  */
 private void addAsPick(String propType, float relativeSize) {
   assert propType != null;
   assert relativeSize > 0f : relativeSize;
   /*
    * Create the prop.
    */
   Node node = create(propType, relativeSize);
   /*
    * The new prop is to be the ONLY picked spatial, so unpick the rest.
    */
   PickablesNode pickables = scene.getWorld().getPickables();
   pickables.clearPick();
   /*
    * Add and pick the prop.
    */
   pickables.add(node);
   SpatialProperties.setPicked(node, true);
   /*
    * Initialize the prop's position.
    */
   Cursor3DIndicator cursor3D = scene.getIndicators().getCursor3D();
   Vector3f baseLocation = cursor3D.getWorldLocation();
   float baseY = MySpatial.getMinY(node);
   Vector3f centerLocation = baseLocation.add(0f, -baseY, 0f);
   MySpatial.setWorldLocation(node, centerLocation);
 }
 @Override
 protected void serialize(int i, Vector3f store) {
   int j = i * getTupleSize();
   array[j] = store.getX();
   array[j + 1] = store.getY();
   array[j + 2] = store.getZ();
 }
  @Override
  public void simpleUpdate(float tpf) {
    Vector3f intersection = getWorldIntersection();
    updateHintText(intersection);

    if (raiseTerrain) {

      if (intersection != null) {
        adjustHeight(intersection, 64, tpf * 60);
      }
    } else if (lowerTerrain) {
      if (intersection != null) {
        adjustHeight(intersection, 64, -tpf * 60);
      }
    }

    if (terrain != null && intersection != null) {
      float h = terrain.getHeight(new Vector2f(intersection.x, intersection.z));
      Vector3f tl = terrain.getWorldTranslation();
      marker.setLocalTranslation(tl.add(new Vector3f(intersection.x, h, intersection.z)));
      markerNormal.setLocalTranslation(tl.add(new Vector3f(intersection.x, h, intersection.z)));

      Vector3f normal = terrain.getNormal(new Vector2f(intersection.x, intersection.z));
      ((Arrow) markerNormal.getMesh()).setArrowExtent(normal);
    }
  }
  @SuppressWarnings("unused")
  private double cauchy(Vector3f point, Vector3f center) {
    Vector3f vec_r = point.subtract(center);
    double s = 0.85; // 0.85 - example on thesis; //kernel width

    double r_2 = vec_r.lengthSquared();
    return 1.0 / ((1 + s * s * r_2) * (1 + s * s * r_2));
  }
 @Override
 public void getRandomPoint(Vector3f store) {
   do {
     store.x = (FastMath.nextRandomFloat() * 2f - 1f) * radius;
     store.y = (FastMath.nextRandomFloat() * 2f - 1f) * radius;
     store.z = (FastMath.nextRandomFloat() * 2f - 1f) * radius;
   } while (store.distance(center) > radius);
 }
 /**
  * Warp into the scene on the nav mesh, finding the nearest cell. The currentCell and position3d
  * are updated and this new position is returned. This updates the state of the path finder!
  *
  * @return the new position in the nearest cell
  */
 public Vector3f warp(Vector3f newPos) {
   Vector3f newPos2d = new Vector3f(newPos.x, 0, newPos.z);
   currentCell = navMesh.findClosestCell(newPos2d);
   currentPos3d.set(navMesh.snapPointToCell(currentCell, newPos2d));
   currentPos3d.setY(newPos.getY());
   currentPos.set(currentPos3d.getX(), currentPos3d.getZ());
   return currentPos3d;
 }
Esempio n. 14
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 /**
  * A variation of Hermite where a velocity is given only for the first point. It interpolates P0
  * at t=0 and P1 at t=1. P(t) = (t^2 - 2*t + 1) * P0 + (-t^2 + 2*t) * P1 + (t^2 - t) * T0
  *
  * @param P0
  * @param T0
  * @param P1
  * @param t
  * @return
  */
 private static Vector3f quadraticHermite(Vector3f P0, Vector3f T0, Vector3f P1, float t) {
   float t2 = t * t;
   Vector3f P = new Vector3f();
   P.scaleAdd(t2 - 2 * t + 1, P0, P);
   P.scaleAdd(-t2 + 2 * t, P1, P);
   P.scaleAdd(t2 - t, T0, P);
   return P;
 }
 /**
  * This method applies the variation to the particle with already set velocity.
  *
  * @param particle the particle to be affected
  */
 protected void applyVelocityVariation(Particle particle) {
   particle.velocity.set(initialVelocity);
   temp.set(FastMath.nextRandomFloat(), FastMath.nextRandomFloat(), FastMath.nextRandomFloat());
   temp.multLocal(2f);
   temp.subtractLocal(1f, 1f, 1f);
   temp.multLocal(initialVelocity.length());
   particle.velocity.interpolate(temp, velocityVariation);
 }
Esempio n. 16
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  /**
   * Centers the spatial in the origin of the world bound.
   *
   * @return The spatial on which this method is called, e.g <code>this</code>.
   */
  public Spatial center() {
    Vector3f worldTrans = getWorldTranslation();
    Vector3f worldCenter = getWorldBound().getCenter();

    Vector3f absTrans = worldTrans.subtract(worldCenter);
    setLocalTranslation(absTrans);

    return this;
  }
Esempio n. 17
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 protected void computeRandomSpawnPoint(Flight flight) {
   Vector3f position =
       new Vector3f(
           randomSpawnGenerator.nextInt(7000) - 3500,
           randomSpawnGenerator.nextInt(7000) - 3500,
           randomSpawnGenerator.nextInt(7000) - 3500);
   Quaternion rotation = new Quaternion();
   rotation.lookAt(position.negate(), Vector3f.UNIT_Z);
   flight.setSpawn(new Spawn(position, rotation));
 }
Esempio n. 18
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  @Override
  public void onPreUpdate(float tpf) {
    Vector3f delta = velocity.mult(tpf);
    Vector3f pos = movedNode.getLocalTranslation().clone();
    smal.checkMotionAllowed(pos, delta, normal);
    movedNode.setLocalTranslation(pos.add(delta));
    velocity.set(0, 0, 0);

    normalAligned.rotateUpTo(normal);
  }
  /**
   * Method for calculating new velocity of agent based on steering vector.
   *
   * @see AbstractSteeringBehavior#calculateSteering()
   * @return The new velocity for this agent based on steering vector
   */
  protected Vector3f calculateNewVelocity() {
    agent.setAcceleration(calculateSteering().mult(1 / agentTotalMass()));
    velocity = velocity.add(agent.getAcceleration());
    agent.setVelocity(velocity);

    if (velocity.length() > agent.getMaxMoveSpeed()) {
      velocity = velocity.normalize().mult(agent.getMaxMoveSpeed());
    }
    return velocity;
  }
  public double f1(Vector3f point, Vector3f A, Vector3f B) {
    // ****** basic parameters ******
    Vector3f vec_b = B;
    Vector3f vec_a = A.subtract(vec_b);
    Vector3f vec_r = point;
    double L = vec_a.length();
    Vector3f vec_d = vec_r.subtract(vec_b);
    double d = vec_d.length();
    double h = vec_d.dot(vec_a.normalize());

    // terms
    double s2 = s * s;
    double h2 = h * h;
    double lmh = L - h;
    double d2 = d * d;
    double p2 = 1 + s2 * (d2 - h2);
    double p = Math.sqrt(p2);
    double ww = p2 + s2 * h2;
    double qq = p2 + s2 * lmh * lmh;
    double sdp = s / p;
    double tpp = 2.0 * p2;
    double sp = s * p;
    double term = Math.atan(sdp * h) + Math.atan(sdp * lmh);

    return (h / ww + lmh / qq) / tpp + term / (tpp * sp);
  }
Esempio n. 21
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  /**
   * Using this slot's camera, construct a pick ray for the specified screen coordinates.
   *
   * @param screenLocation screen coordinates (in pixels, measured from the lower left, not null,
   *     unaffected)
   * @return new instance
   */
  @Override
  public Ray pickRay(Vector2f screenLocation) {
    Validate.nonNull(screenLocation, "screen location");

    Vector3f startLocation = cam.getWorldCoordinates(screenLocation, 0f);
    Vector3f farPoint = cam.getWorldCoordinates(screenLocation, 1f);
    Vector3f direction = farPoint.subtract(startLocation).normalizeLocal();
    Ray result = new Ray(startLocation, direction);

    return result;
  }
Esempio n. 22
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 private Vector3f getSpawnPosition() {
   Vector3f pos;
   do {
     pos =
         new Vector3f(
             new Random().nextInt(settings.getWidth()),
             new Random().nextInt(settings.getHeight()),
             0);
   } while (pos.distanceSquared(player.getLocalTranslation()) < 8000);
   return pos;
 }
Esempio n. 23
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 /**
  * Hermite interpolation of the points P0 to P1 at time t=0 to t=1 with the specified velocities
  * T0 and T1.
  *
  * @param P0
  * @param T0
  * @param P1
  * @param T1
  * @param t
  * @return
  */
 private static Vector3f cubicHermite(
     Vector3f P0, Vector3f T0, Vector3f P1, Vector3f T1, float t) {
   float t2 = t * t;
   float t3 = t2 * t;
   Vector3f P = new Vector3f();
   P.scaleAdd(2 * t3 - 3 * t2 + 1, P0, P);
   P.scaleAdd(t3 - 2 * t2 + t, T0, P);
   P.scaleAdd(-2 * t3 + 3 * t2, P1, P);
   P.scaleAdd(t3 - t2, T1, P);
   return P;
 }
 private boolean lastCameraLocationsTheSame(List<Vector3f> locations) {
   boolean theSame = true;
   for (Vector3f l : locations) {
     for (Vector3f v : lastCameraLocations) {
       if (!v.equals(l)) {
         theSame = false;
         return false;
       }
     }
   }
   return theSame;
 }
Esempio n. 25
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  public void rotateToPoint(Vector3f v3f) {
    for (int i = 0; i < getSelectionCircles().size(); i++) {
      Doodad d = getSelectionCircles().get(i).getDoodad();

      Vector3f location = d.getLocation();
      float rotation =
          (float)
              Math.atan2(
                  (float) (v3f.getX() - location.getX()), (float) (v3f.getZ() - location.getZ()));
      d.setRotation(rotation);
      d.updateRotation();
    }
  }
Esempio n. 26
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 private void computeLength() {
   int M = 16;
   Vector3f old = null;
   float length = 0;
   for (int i = 0; i <= M; ++i) {
     Vector3f v = interpolate(i / (float) M).position;
     if (old != null) {
       length += old.distance(v);
     }
     old = v;
   }
   stepLength = length;
 }
  public boolean calculateLod(
      TerrainPatch patch, List<Vector3f> locations, HashMap<String, UpdatedTerrainPatch> updates) {
    if (turnOffLod) {
      // set to full detail
      int prevLOD = patch.getLod();
      UpdatedTerrainPatch utp = updates.get(patch.getName());
      if (utp == null) {
        utp = new UpdatedTerrainPatch(patch);
        updates.put(utp.getName(), utp);
      }
      utp.setNewLod(0);
      utp.setPreviousLod(prevLOD);
      // utp.setReIndexNeeded(true);
      return true;
    }

    float[] lodEntropies = patch.getLodEntropies();
    float cameraConstant = getCameraConstant(cam, pixelError);

    Vector3f patchPos = getCenterLocation(patch);

    // vector from camera to patch
    // Vector3f toPatchDir = locations.get(0).subtract(patchPos).normalizeLocal();
    // float facing = cam.getDirection().dot(toPatchDir);
    float distance = patchPos.distance(locations.get(0));

    // go through each lod level to find the one we are in
    for (int i = 0; i <= patch.getMaxLod(); i++) {
      if (distance < lodEntropies[i] * cameraConstant || i == patch.getMaxLod()) {
        boolean reIndexNeeded = false;
        if (i != patch.getLod()) {
          reIndexNeeded = true;
          //                    System.out.println("lod change: "+lod+" > "+i+"    dist:
          // "+distance);
        }
        int prevLOD = patch.getLod();

        UpdatedTerrainPatch utp = updates.get(patch.getName());
        if (utp == null) {
          utp = new UpdatedTerrainPatch(patch); // save in here, do not update actual variables
          updates.put(utp.getName(), utp);
        }
        utp.setNewLod(i);
        utp.setPreviousLod(prevLOD);
        // utp.setReIndexNeeded(reIndexNeeded);
        return reIndexNeeded;
      }
    }

    return false;
  }
  /**
   * Interpolates unspecified translation values for objectIndex from start to end.
   *
   * @param objectIndex Index to interpolate.
   * @param startPosIndex Starting translation index.
   * @param endPosIndex Ending translation index.
   */
  private void fillVecs(int objectIndex, int startPosIndex, int endPosIndex) {
    keyframes.get(startPosIndex).look[objectIndex].getTranslation(unSyncbeginPos);
    keyframes.get(endPosIndex).look[objectIndex].getTranslation(unSyncendPos);
    float startTime = keyframes.get(startPosIndex).time;
    float endTime = keyframes.get(endPosIndex).time;
    float delta = endTime - startTime;
    Vector3f tempVec = new Vector3f();

    for (int i = startPosIndex + 1; i < endPosIndex; i++) {
      float thisTime = keyframes.get(i).time;
      tempVec.interpolate(unSyncbeginPos, unSyncendPos, (thisTime - startTime) / delta);
      keyframes.get(i).look[objectIndex].setTranslation(tempVec);
    }
  }
Esempio n. 29
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  private boolean maxDistanceExceeded(Vector3f vehiclePos) {
    // get box's position on xz-plane (ignore y component)
    Vector3f followBoxPosition = getPosition();
    followBoxPosition.setY(0);

    // get vehicle's position on xz-plane (ignore y component)
    Vector3f vehiclePosition = vehiclePos;
    vehiclePosition.setY(0);

    // distance between box and vehicle
    float currentDistance = followBoxPosition.distance(vehiclePosition);

    // report whether maximum distance is exceeded
    return currentDistance > maxDistance;
  }
Esempio n. 30
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  @Override
  protected void initialize(Application app) {

    ed = getState(EntityDataState.class).getEntityData();
    entities = ed.getEntities(Position.class, ModelType.class);

    // Calculate how big min/max needs to be to incorporate
    // the full view + margin at z = 0
    Camera cam = app.getCamera();
    float z = cam.getViewToProjectionZ(cam.getLocation().z);
    Vector3f worldMin = cam.getWorldCoordinates(new Vector2f(0, 0), z);
    Vector3f worldMax = cam.getWorldCoordinates(new Vector2f(cam.getWidth(), cam.getHeight()), z);
    min = worldMin.addLocal(-margin, -margin, 0);
    max = worldMax.addLocal(margin, margin, 0);
  }