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* DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
*
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* under the terms of the GNU General Public License version 2 only, as
* published by the Free Software Foundation. Sun designates this
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*
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* 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).
*
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* 2 along with this work; if not, write to the Free Software Foundation,
* Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
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package javax.media.j3d;
import java.util.Enumeration;
/**
* The Behavior leaf node provides a framework for adding user-defined
* actions into the scene graph. Behavior is an abstract class that
* defines two methods that must be overridden by a subclass: An
* initialization method, called once when the behavior
* becomes "live," and a processStimulus method called
* whenever appropriate by the Java 3D behavior scheduler. The
* Behavior node also contains an enable flag, a scheduling region,
* a scheduling interval, and a wakeup condition.
*
*
* The scheduling region defines a spatial volume that serves
* to enable the scheduling of Behavior nodes. A Behavior node is
* active (can receive stimuli) whenever an active ViewPlatform's
* activation volume intersects a Behavior object's scheduling
* region. Only active behaviors can receive stimuli.
*
*
* The scheduling interval defines a partial order of execution
* for behaviors that wake up in response to the same wakeup condition
* (that is, those behaviors that are processed at the same "time").
* Given a set of behaviors whose wakeup conditions are satisfied at
* the same time, the behavior scheduler will execute all behaviors in
* a lower scheduling interval before executing any behavior in a
* higher scheduling interval. Within a scheduling interval,
* behaviors can be executed in any order, or in parallel. Note that
* this partial ordering is only guaranteed for those behaviors that
* wake up at the same time in response to the same wakeup condition,
* for example, the set of behaviors that wake up every frame in
* response to a WakeupOnElapsedFrames(0) wakeup condition.
*
*
* The initialize method allows a Behavior object to
* initialize its internal state and specify its initial wakeup
* condition(s). Java 3D invokes a behavior's initialize code when the
* behavior's containing BranchGroup node is added to the virtual
* universe. Java 3D does not invoke the initialize method in a new
* thread. Thus, for Java 3D to regain control, the initialize method
* must not execute an infinite loop; it must return. Furthermore, a
* wakeup condition must be set or else the behavior's processStimulus
* method is never executed.
*
*
* The processStimulus method receives and processes a
* behavior's ongoing messages. The Java 3D behavior scheduler invokes
* a Behavior node's processStimulus method when an active ViewPlatform's
* activation volume intersects a Behavior object's scheduling region
* and all of that behavior's wakeup criteria are satisfied. The
* processStimulus method performs its computations and actions
* (possibly including the registration of state change information
* that could cause Java 3D to wake other Behavior objects),
* establishes its next wakeup condition, and finally exits.
* A typical behavior will modify one or more nodes or node components
* in the scene graph. These modifications can happen in parallel
* with rendering. In general, applications cannot count on behavior
* execution being synchronized with rendering. There are two
* exceptions to this general rule:
*
* - All modifications to scene graph objects (not including geometry
* by-reference or texture by-reference) made from the
*
processStimulus method of a single behavior instance
* are guaranteed to take effect in the same rendering frame.
* - All modifications to scene graph objects (not including geometry
* by-reference or texture by-reference) made from the
*
processStimulus methods of the set of behaviors that
* wake up in response to a WakeupOnElapsedFrames(0) wakeup condition
* are guaranteed to take effect in the same rendering frame.
*
*
* Note that modifications to geometry by-reference or texture
* by-reference are not guaranteed to show up in the same frame as
* other scene graph changes.
*
*
* Code Structure
*
* When the Java 3D behavior scheduler invokes a Behavior object's
* processStimulus method, that method may perform any computation it
* wishes. Usually, it will change its internal state and specify its
* new wakeup conditions. Most probably, it will manipulate scene
* graph elements. However, the behavior code can only change those
* aspects of a scene graph element permitted by the capabilities
* associated with that scene graph element. A scene graph's
* capabilities restrict behavioral manipulation to those
* manipulations explicitly allowed.
*
*
* The application must provide the Behavior object with references to
* those scene graph elements that the Behavior object will
* manipulate. The application provides those references as arguments
* to the behavior's constructor when it creates the Behavior
* object. Alternatively, the Behavior object itself can obtain access
* to the relevant scene graph elements either when Java 3D invokes
* its initialize method or each time Java 3D invokes its
* processStimulus method.
*
*
* Behavior methods have a very rigid structure. Java 3D assumes that
* they always run to completion (if needed, they can spawn
* threads). Each method's basic structure consists of the following:
*
*
*
* - Code to decode and extract references from the WakeupCondition
* enumeration that caused the object's awakening.
* - Code to perform the manipulations associated with the
* WakeupCondition
* - Code to establish this behavior's new WakeupCondition
* - A path to Exit (so that execution returns to the Java 3D
* behavior scheduler)
*
*
*
* WakeupCondition Object
*
* A WakeupCondition object is an abstract class specialized to
* fourteen different WakeupCriterion objects and to four combining
* objects containing multiple WakeupCriterion objects. A Behavior
* node provides the Java 3D behavior scheduler with a WakeupCondition
* object. When that object's WakeupCondition has been satisfied, the
* behavior scheduler hands that same WakeupCondition back to the
* Behavior via an enumeration.
*
*
* WakeupCriterion Object
*
* Java 3D provides a rich set of wakeup criteria that Behavior
* objects can use in specifying a complex WakeupCondition. These
* wakeup criteria can cause Java 3D's behavior scheduler to invoke a
* behavior's processStimulus method whenever
*
*
* - The center of a ViewPlatform enters a specified region
* - The center of a ViewPlatform exits a specified region
* - A behavior is activated
* - A behavior is deactivated
* - A specified TransformGroup node's transform changes
* - Collision is detected between a specified Shape3D node's
* Geometry object and any other object
* - Movement occurs between a specified Shape3D node's Geometry
* object and any other object with which it collides
* - A specified Shape3D node's Geometry object no longer collides
* with any other object
* - A specified Behavior object posts a specific event
* - A specified AWT event occurs
* - A specified time interval elapses
* - A specified number of frames have been drawn
* - The center of a specified Sensor enters a specified region
* - The center of a specified Sensor exits a specified region
*
*
*
* A Behavior object constructs a WakeupCriterion by constructing the
* appropriate criterion object. The Behavior object must provide the
* appropriate arguments (usually a reference to some scene graph
* object and possibly a region of interest). Thus, to specify a
* WakeupOnViewPlatformEntry, a behavior would specify the region that
* will cause the behavior to execute if an active ViewPlatform enters it.
*
*
* Note that a unique WakeupCriterion object must be used with each
* instance of a Behavior. Sharing wakeup criteria among different
* instances of a Behavior is illegal.
*
*
* Additional Information
*
* For more information, see the
* Introduction to the Java 3D API and
* Behaviors and Interpolators
* documents.
*
* @see WakeupCondition
*/
public abstract class Behavior extends Leaf {
/**
* Constructs a Behavior node with default parameters. The default
* values are as follows:
*
* enable flag : true
* scheduling bounds : null
* scheduling bounding leaf : null
* scheduling interval : numSchedulingIntervals / 2
*
*/
public Behavior() {
}
/**
* Initialize this behavior. Classes that extend Behavior must
* provide their own initialize method.
*
* NOTE: Applications should not call this method. It is called
* by the Java 3D behavior scheduler.
*/
public abstract void initialize();
/**
* Process a stimulus meant for this behavior. This method is invoked
* if the Behavior's wakeup criteria are satisfied and an active
* ViewPlatform's
* activation volume intersects with the Behavior's scheduling region.
* Classes that extend Behavior must provide their own processStimulus
* method.
*
* NOTE: Applications should not call this method. It is called
* by the Java 3D behavior scheduler.
* @param criteria an enumeration of triggered wakeup criteria for this
* behavior
*/
public abstract void processStimulus(Enumeration criteria);
/**
* Set the Behavior's scheduling region to the specified bounds.
* This is used when the scheduling bounding leaf is set to null.
* @param region the bounds that contains the Behavior's new scheduling
* region
*/
public void setSchedulingBounds(Bounds region) {
((BehaviorRetained)this.retained).setSchedulingBounds(region);
}
/**
* Retrieves the Behavior node's scheduling bounds.
* @return this Behavior's scheduling bounds information
*/
public Bounds getSchedulingBounds() {
return ((BehaviorRetained)this.retained).getSchedulingBounds();
}
/**
* Set the Behavior's scheduling region to the specified bounding leaf.
* When set to a value other than null, this overrides the scheduling
* bounds object.
* @param region the bounding leaf node used to specify the Behavior
* node's new scheduling region
*/
public void setSchedulingBoundingLeaf(BoundingLeaf region) {
((BehaviorRetained)this.retained).setSchedulingBoundingLeaf(region);
}
/**
* Retrieves the Behavior node's scheduling bounding leaf.
* @return this Behavior's scheduling bounding leaf information
*/
public BoundingLeaf getSchedulingBoundingLeaf() {
return ((BehaviorRetained)this.retained).getSchedulingBoundingLeaf();
}
/**
* Creates the retained mode BehaviorRetained object that this
* Behavior object will point to.
*/
@Override
void createRetained() {
this.retained = new BehaviorRetained();
this.retained.setSource(this);
}
/**
* Defines this behavior's wakeup criteria. This method
* may only be called from a Behavior object's initialize
* or processStimulus methods to (re)arm the next wakeup.
* It should be the last thing done by those methods.
* @param criteria the wakeup criteria for this behavior
* @exception IllegalStateException if this method is called by
* a method other than initialize or processStimulus
*/
protected void wakeupOn(WakeupCondition criteria) {
BehaviorRetained behavret = (BehaviorRetained) this.retained;
synchronized (behavret) {
if (!behavret.inCallback) {
throw new IllegalStateException(J3dI18N.getString("Behavior0"));
}
}
behavret.wakeupOn(criteria);
}
/**
* Retrieves this behavior's current wakeup condition as set by
* the wakeupOn method. If no wakeup condition is currently
* active, null will be returned. In particular, this means that
* null will be returned if Java 3D is executing this behavior's
* processStimulus routine and wakeupOn has not yet been called to
* re-arm the wakeup condition for next time.
*
* @return the current wakeup condition for this behavior
*
* @since Java 3D 1.3
*/
protected WakeupCondition getWakeupCondition() {
return ((BehaviorRetained)this.retained).getWakeupCondition();
}
/**
* Posts the specified postId to the Behavior Scheduler. All behaviors
* that have registered WakeupOnBehaviorPost with this postId, or a postId
* of 0, and with this behavior, or a null behavior, will have that wakeup
* condition met.
*
* This feature allows applications to send arbitrary events into the
* behavior scheduler stream. It can be used as a notification scheme
* for communicating events to behaviors in the system.
*
* @param postId the Id being posted
*
* @see WakeupOnBehaviorPost
*/
public void postId(int postId){
((BehaviorRetained)this.retained).postId(postId);
}
/**
* Enables or disables this Behavior. The default state is enabled.
* @param state true or false to enable or disable this Behavior
*/
public void setEnable(boolean state) {
((BehaviorRetained)this.retained).setEnable(state);
}
/**
* Retrieves the state of the Behavior enable flag.
* @return the Behavior enable state
*/
public boolean getEnable() {
return ((BehaviorRetained)this.retained).getEnable();
}
/**
* Returns the number of scheduling intervals supported by this
* implementation of Java 3D. The minimum number of supported
* intervals must be at least 10. The default scheduling interval
* for each behavior instance is set to
* numSchedulingIntervals / 2.
*
* @return the number of supported scheduling intervals
*
* @since Java 3D 1.3
*/
public static int getNumSchedulingIntervals() {
return BehaviorRetained.NUM_SCHEDULING_INTERVALS;
}
/**
* Sets the scheduling interval of this Behavior node to the
* specified value.
*
* The scheduling interval defines a partial order of execution
* for behaviors that wake up in response to the same wakeup
* condition (that is, those behaviors that are processed at the
* same "time"). Given a set of behaviors whose wakeup conditions
* are satisfied at the same time, the behavior scheduler will
* execute all behaviors in a lower scheduling interval before
* executing any behavior in a higher scheduling interval. Within
* a scheduling interval, behaviors can be executed in any order,
* or in parallel. Note that this partial ordering is only
* guaranteed for those behaviors that wake up at the same time in
* response to the same wakeup condition, for example, the set of
* behaviors that wake up every frame in response to a
* WakeupOnElapsedFrames(0) wakeup condition.
*
* The default value is numSchedulingIntervals / 2.
*
* @param schedulingInterval the new scheduling interval
*
* @exception IllegalArgumentException if
* schedulingInterval < 0 or
* schedulingInterval >=
* numSchedulingIntervals
*
* @since Java 3D 1.3
*/
public void setSchedulingInterval(int schedulingInterval) {
if (schedulingInterval < 0 ||
schedulingInterval >= getNumSchedulingIntervals()) {
throw new IllegalStateException(J3dI18N.getString("Behavior1"));
}
((BehaviorRetained)this.retained).
setSchedulingInterval(schedulingInterval);
}
/**
* Retrieves the current scheduling interval of this Behavior
* node.
*
* @return the current scheduling interval
*
* @since Java 3D 1.3
*/
public int getSchedulingInterval() {
return ((BehaviorRetained)this.retained).getSchedulingInterval();
}
/**
* Returns the primary view associated with this behavior. This method
* is useful with certain types of behaviors (e.g., Billboard, LOD) that
* rely on per-View information and with behaviors in general in regards
* to scheduling (the distance from the view platform determines the
* active behaviors). The "primary" view is defined to be the first
* View attached to a live ViewPlatform, if there is more than one active
* View. So, for instance, Billboard behaviors would be oriented toward
* this primary view, in the case of multiple active views into the same
* scene graph.
*/
protected View getView() {
return ((BehaviorRetained)this.retained).getView();
}
/**
* Copies all Behavior information from
* originalNode into
* the current node. This method is called from the
* cloneNode method which is, in turn, called by the
* cloneTree method.
*
* @param originalNode the original node to duplicate
* @param forceDuplicate when set to true, causes the
* duplicateOnCloneTree flag to be ignored. When
* false, the value of each node's
* duplicateOnCloneTree variable determines whether
* NodeComponent data is duplicated or copied.
*
* @exception RestrictedAccessException if this object is part of a live
* or compiled scenegraph.
*
* @see Node#duplicateNode
* @see Node#cloneTree
* @see NodeComponent#setDuplicateOnCloneTree
*/
@Override
void duplicateAttributes(Node originalNode, boolean forceDuplicate) {
super.duplicateAttributes(originalNode, forceDuplicate);
BehaviorRetained attr = (BehaviorRetained) originalNode.retained;
BehaviorRetained rt = (BehaviorRetained) retained;
rt.setEnable(attr.getEnable());
rt.setSchedulingBounds(attr.getSchedulingBounds());
rt.setSchedulingInterval(attr.getSchedulingInterval());
// will set to the correct one in updateNodeReferences
rt.setSchedulingBoundingLeaf(attr.getSchedulingBoundingLeaf());
}
/**
* Callback used to allow a node to check if any scene graph objects
* referenced
* by that node have been duplicated via a call to cloneTree.
* This method is called by cloneTree after all nodes in
* the sub-graph have been duplicated. The cloned Leaf node's method
* will be called and the Leaf node can then look up any object references
* by using the getNewObjectReference method found in the
* NodeReferenceTable object. If a match is found, a
* reference to the corresponding object in the newly cloned sub-graph
* is returned. If no corresponding reference is found, either a
* DanglingReferenceException is thrown or a reference to the original
* object is returned depending on the value of the
* allowDanglingReferences parameter passed in the
* cloneTree call.
*
* NOTE: Applications should not call this method directly.
* It should only be called by the cloneTree method.
*
* @param referenceTable a NodeReferenceTableObject that contains the
* getNewObjectReference method needed to search for
* new object instances.
*
* @see NodeReferenceTable
* @see Node#cloneTree
* @see DanglingReferenceException
*/
@Override
public void updateNodeReferences(NodeReferenceTable referenceTable) {
super.updateNodeReferences(referenceTable);
BehaviorRetained rt = (BehaviorRetained) retained;
BoundingLeaf bl= rt.getSchedulingBoundingLeaf();
// check for schedulingBoundingLeaf
if (bl != null) {
Object o = referenceTable.getNewObjectReference(bl);
rt.setSchedulingBoundingLeaf((BoundingLeaf) o);
}
}
}