* * Don't worry about it too much, though: you can provide * JavaBeans with as much customized information as you * want, or as little as you want, using the BeanInfo * interface (see BeanInfo for details).
* * Order of Operations
*
* When you call getBeanInfo(class c), the Introspector
* first searches for BeanInfo class to see if you
* provided any explicit information. It searches for a
* class named
*
* If it does not find a BeanInfo class, it acts as though
* it had found a BeanInfo class returning null from all
* methods (meaning it should discover everything through
* Introspection). If it does, then it takes the
* information it finds in the BeanInfo class to be
* canonical (that is, the information speaks for its
* class as well as all superclasses).
*
* When it has introspected the class, calls
* getBeanInfo(c.getSuperclass) and adds that information
* to the information it has, not adding to any information
* it already has that is canonical.
*
* Introspection Design Patterns
*
* When the Introspector goes in to read the class, it
* follows a well-defined order in order to not leave any
* methods unaccounted for. Its job is to step over all
* of the public methods in a class and determine whether
* they are part of a property, an event, or a method (in
* that order).
*
*
* Properties:
*
*
*
* If there is a pair of methods,
*
*
* If the addXXX() method throws
*
*
* Spec Note: the spec seems to say that
* the listener type's classname must be equal to the XXX
* part of addXXX() and removeXXX(), but that is not the
* case in Sun's implementation, so I am assuming it is
* not the case in general.
*
* Methods:
*
* Any public methods (including those which were used
* for Properties or Events) are used as Methods.
*
* @author John Keiser
* @since JDK1.1
* @see java.beans.BeanInfo
*/
public class Introspector {
public static final int USE_ALL_BEANINFO = 1;
public static final int IGNORE_IMMEDIATE_BEANINFO = 2;
public static final int IGNORE_ALL_BEANINFO = 3;
static String[] beanInfoSearchPath = {"gnu.java.beans.info"};
static Hashtable beanInfoCache = new Hashtable();
private Introspector() {}
/**
* Get the BeanInfo for class
*
*
* Events:public boolean isXXX()
* method, then XXX is a read-only boolean property.
* boolean getXXX() may be supplied in
* addition to this method, although isXXX() is the
* one that will be used in this case and getXXX()
* will be ignored. If there is a
* public void setXXX(boolean) method,
* it is part of this group and makes it a read-write
* property.public <type> getXXX(int)
* method, then XXX is a read-only indexed property of
* type <type>. If there is a
* public void setXXX(int,<type>)
* method, then it is a read-write indexed property of
* type <type>. There may also be a
* public <type>[] getXXX() and a
* public void setXXX(<type>)
* method as well.public void setXXX(int,<type>)
* method, then it is a write-only indexed property of
* type <type>. There may also be a
* public <type>[] getXXX() and a
* public void setXXX(<type>)
* method as well.public <type> getXXX() method,
* then XXX is a read-only property of type
* <type>. If there is a
* public void setXXX(<type>)
* method, then it will be used for the property and
* the property will be considered read-write.public void setXXX(<type>)
* method, then as long as XXX is not already used as
* the name of a property, XXX is assumed to be a
* write-only property of type <type>.PropertyVetoException, then the
* property in question is assumed to be constrained.
* No properties are ever assumed to be bound
* (Spec Note: this is not in the
* spec, it just makes sense). See PropertyDescriptor
* for a description of bound and constrained
* properties.public void addXXX(<type>) and
* public void removeXXX(<type>), where
* <type> is a descendant of
* java.util.EventListener, then the pair of
* methods imply that this Bean will fire events to
* listeners of type <type>.java.util.TooManyListenersException, then
* the event set is assumed to be unicast. See
* EventSetDescriptor for a discussion of unicast event
* sets.beanClass,
* first by looking for explicit information, next by
* using standard design patterns to determine
* information about the class.
*
* @param beanClass the class to get BeanInfo about.
* @return the BeanInfo object representing the class.
*/
public static BeanInfo getBeanInfo(Class beanClass)
throws IntrospectionException
{
BeanInfo cachedInfo;
synchronized(beanClass)
{
cachedInfo = (BeanInfo)beanInfoCache.get(beanClass);
if(cachedInfo != null)
{
return cachedInfo;
}
cachedInfo = getBeanInfo(beanClass,null);
beanInfoCache.put(beanClass,cachedInfo);
return cachedInfo;
}
}
/**
* Get the BeanInfo for class beanClass,
* first by looking for explicit information, next by
* using standard design patterns to determine
* information about the class. It crawls up the
* inheritance tree until it hits topClass.
*
* @param beanClass the Bean class.
* @param stopClass the class to stop at.
* @return the BeanInfo object representing the class.
*/
public static BeanInfo getBeanInfo(Class beanClass, Class stopClass)
throws IntrospectionException
{
ExplicitInfo explicit = new ExplicitInfo(beanClass,stopClass);
IntrospectionIncubator ii = new IntrospectionIncubator();
ii.setPropertyStopClass(explicit.propertyStopClass);
ii.setEventStopClass(explicit.eventStopClass);
ii.setMethodStopClass(explicit.methodStopClass);
ii.addMethods(beanClass.getMethods());
BeanInfoEmbryo currentInfo = ii.getBeanInfoEmbryo();
PropertyDescriptor[] p = explicit.explicitPropertyDescriptors;
if(p!=null)
{
for(int i=0;i