Each stateful session bean is dedicated to one client for the life of the bean instance; it acts on behalf of that client as its agent. Stateful session beans are not swapped among EJB objects or kept in an instance pool like entity and stateless session bean instances. Once a stateful session bean is instantiated and assigned to an EJB object, it is dedicated to that EJB object for its entire life cycle.[31]
Stateful session beans maintain conversational state, which means that the instance variables of the bean class can maintain data specific to the client between method invocations. This makes it possible for methods to be interdependent, so that changes made to the bean’s state in one method call can affect the results of subsequent method invocations. Therefore, every method call from a client must be serviced by the same instance (at least conceptually), so the bean instance’s state can be predicted from one method invocation to the next. In contrast, stateless session beans don’t maintain client-specific data from one method call to the next, so any instance can be used to service any method call from any client.
Although stateful session beans maintain conversational state, they are not themselves persistent like entity beans. Entity beans represent data in the database; their persistence fields are written directly to the database. Stateful session beans can access the database but do not represent data in the database. In addition, stateful beans are not used concurrently like entity beans. If you have an entity EJB object that wraps an instance of the ship called Paradise, for example, all client requests for that ship will be coordinated through the same EJB object.[32] With stateful session beans, the EJB object is dedicated to one client—stateful session beans are not used concurrently.
Stateful session beans are often considered extensions of the client. This makes sense if you think of a client as being made up of operations and state. Each task may rely on some information gathered or changed by a previous operation. A GUI client is a perfect example: when you fill in the fields on a GUI client you are creating conversational state. Pressing a button executes an operation that might fill in more fields, based on the information you entered previously. The information in the fields is conversational state.
Stateful session beans allow you to encapsulate some of the business logic and conversational state of a client and move it to the server. Moving this logic to the server thins the client application and makes the system as a whole easier to manage. The stateful session bean acts as an agent for the client, managing processes or taskflow to accomplish a set of tasks; it manages the interactions of other beans in addition to direct data access over several operations to accomplish a complex set of tasks. By encapsulating and managing taskflow on behalf of the client, stateful beans present a simplified interface that hides the details of many interdependent operations on the database and other beans from the client.
The TravelAgent EJB will make use of the
Cabin, Cruise, Reservation, and Customer beans developed in Chapter 6 and Chapter 7. It
will coordinate the interaction of these entity beans to book a
passenger on a cruise. We’ll modify the Reservation
EJB that was used in Chapter 7 so that it can
be created with all its relationships identified right away. To do
so, we overload its ejbCreate( )
method:
public abstract class ReservationBean implements javax.ejb.EntityBean { public Integer ejbCreate(CustomerRemote customer, CruiseLocal cruise, CabinLocal cabin, double price, Date dateBooked) { setAmountPaid(price); setDate(dateBooked); return null; } public void ejbPostCreate(CustomerRemote customer, CruiseLocal cruise, CabinLocal cabin, double price, Date dateBooked) throws javax.ejb.CreateException { setCruise(cruise); // add Cabin to collection-based CMR field Set cabins = new HashSet( ); cabins.add(cabin); this.setCabins(cabins); try { Integer primKey = (Integer)customer.getPrimaryKey( ); javax.naming.Context jndiContext = new InitialContext( ); CustomerHomeLocal home = (CustomerHomeLocal) jndiContext.lookup("java:comp/env/ejb/CustomerHomeLocal"); CustomerLocal custL = home.findByPrimaryKey(primKey); // add Customer to collection-based CMR field Set customers = new HashSet( ); customers.add(custL); this.setCustomers(customers); } catch (RemoteException re) { throw new CreateException("Invalid Customer"); } catch (FinderException fe) { throw new CreateException("Invalid Customer"); } catch (NamingException ne) { throw new CreateException("Invalid Customer"); } }
Relationship fields use local EJB object references, so we must
convert the CustomerRemote
reference to a
CustomerLocal
reference in order to set the
Reservation EJB’s customer
relationship field. To do this, you can either use the JNDI ENC to
locate the local home interface and then execute the
findByPrimaryKey( )
method, or implement an
ejbSelect( )
method in the Reservation EJB to
locate the CustomerLocal
reference.
The TravelAgent EJB, which we have already seen, is a stateful session bean that encapsulates the process of making a reservation on a cruise. We will develop this bean further to demonstrate how stateful session beans can be used as taskflow objects. We won’t develop a local interface for the TravelAgent EJB, partly because it is designed to be used by remote clients (and therefore doesn’t require local component interfaces), and partly because the rules for developing local interfaces for stateful session beans are the same as those for stateless session and entity beans.
In Chapter 4, we
developed an early version of the
TravelAgentRemote
interface that contained a
single business method, listCabins( )
. We are now
going to remove the listCabins( )
method and
redefine the TravelAgent EJB so that it behaves like a taskflow
object. Later in this chapter, we will add a modified listing method
for obtaining a more specific list of cabins for the user.
As a stateful session bean that models taskflow, the TravelAgent EJB
manages the interactions between several other beans while
maintaining conversational state. Here’s the
modified TravelAgentRemote
interface:
package com.titan.travelagent; import java.rmi.RemoteException; import javax.ejb.FinderException; import com.titan.processpayment.CreditCardDO; public interface TravelAgentRemote extends javax.ejb.EJBObject { public void setCruiseID(Integer cruise) throws RemoteException, FinderException; public void setCabinID(Integer cabin) throws RemoteException, FinderException; public TicketDO bookPassage(CreditCardDO card, double price) throws RemoteException,IncompleteConversationalState; }
The purpose of the TravelAgent EJB is to make cruise reservations. To
accomplish this task, the bean needs to know which cruise, cabin, and
customer make up the reservation. Therefore, the client using the
TravelAgent EJB needs to gather this kind of information before
making the booking. The TravelAgentRemote
interface provides methods for setting the IDs of the cruise and
cabin that the customer wants to book. We can assume that the cabin
ID comes from a list and that the cruise ID comes from some other
source. The customer is set in the create( )
method of the home interface—more about this later.
Once the customer, cruise, and cabin are chosen, the TravelAgent EJB
is ready to process the reservation. This operation is performed by
the bookPassage( )
method, which needs the
customer’s credit card information and the price of
the cruise. bookPassage( )
is responsible for
charging the customer’s account, reserving the
chosen cabin in the right ship on the right cruise, and generating a
ticket for the customer. How this is accomplished is not important to
us at this point; when we are developing the remote interface, we are
concerned only with the business definition of the bean. We will
discuss the implementation when we talk about the bean class.
Note that the bookPassage( )
method throws an
application-specific exception,
IncompleteConversationalState
. This exception is
used to communicate business problems encountered while booking a
customer on a cruise. The
IncompleteConversationalState
exception indicates
that the TravelAgent EJB did not have enough information to process
the booking. Here’s the
IncompleteConversationalState
class:
package com.titan.travelagent; public class IncompleteConversationalState extends java.lang.Exception { public IncompleteConversationalState( ){super( );} public IncompleteConversationalState(String msg){super(msg);} }
Like the
CreditCardDO
and CheckDO
classes used in the ProcessPayment EJB, the
TicketDO
class is defined as a pass-by-value
object. One could argue that a ticket should be an entity bean since
it is not dependent and may be accessed outside the context of the
TravelAgent EJB. However, determining how a business object is used
can also dictate whether it should be a bean or simply a class. The
TicketDO
object, for example, could be digitally
signed and emailed to the client as proof of purchase. This would not
be feasible if the TicketDO
object were an entity
bean, because enterprise beans are referenced only through their
component interfaces and are never passed by value.
The constructor for TicketDO uses the local interfaces of creating a
new TicketDO
object:
package com.titan.travelagent; import com.titan.cruise.CruiseLocal; import com.titan.cabin.CabinLocal; import com.titan.customer.CustomerRemote; public class TicketDO implements java.io.Serializable { public Integer customerID; public Integer cruiseID; public Integer cabinID; public double price; public String description; public TicketDO(CustomerRemote customer, CruiseLocal cruise, CabinLocal cabin, double price) throws javax.ejb.FinderException, RemoteException, javax.naming.NamingException { description = customer.getFirstName( )+ " " + customer.getLastName( ) + " has been booked for the " + cruise.getName( ) + " cruise on ship " + cruise.getShip( ).getName( ) + ". " + " Your accommodations include " + cabin.getName( ) + " a " + cabin.getBedCount( ) + " bed cabin on deck level " + cabin.getDeckLevel( ) + ". Total charge = " + price; customerID = (Integer)customer.getPrimaryKey( ); cruiseID = (Integer)cruise.getPrimaryKey( ); cabinID = (Integer)cabin.getPrimaryKey( ); this.price = price; } public String toString( ) { return description; } }
Starting with the
TravelAgentHomeRemote
interface we developed in
Chapter 4, we can modify the create( )
method to take a remote reference to the customer who is
making the reservation:
package com.titan.travelagent; import java.rmi.RemoteException; import javax.ejb.CreateException; import com.titan.customer.CustomerRemote; public interface TravelAgentHomeRemote extends javax.ejb.EJBHome { public TravelAgentRemote create(CustomerRemote cust) throws RemoteException, CreateException; }
The create( )
method in this home interface requires that a remote
reference to a Customer EJB be used to create the TravelAgent EJB.
Because there are no other create( )
methods, you
cannot create a TravelAgent EJB if you do not know who the customer
is. The Customer EJB reference provides the TravelAgent EJB with some
of the conversational state it will need to process the
bookPassage( )
method.
Before settling on definitions for your component interfaces, it is a good idea to figure out how clients will use the bean. Imagine that the TravelAgent EJB is used by a Java application with GUI fields. These fields capture the customer’s preference for the type of cruise and cabin. We start by examining the code used at the beginning of the reservation process:
Context jndiContext = getInitialContext( );
Object ref = jndiContext.lookup("CustomerHomeRemote");
CustomerHomeRemote customerHome =(CustomerHomeRemote)
PortableRemoteObject.narrow(ref, CustomerHomeRemote.class);
String ln = tfLastName.getText( );
String fn = tfFirstName.getText( );
String mn = tfMiddleName.getText( );
CustomerRemote customer = customerHome.create(nextID, ln, fn, mn);
ref = jndiContext.lookup("TravelAgentHomeRemote");
TravelAgentHomeRemote home = (TravelAgentHomeRemote)
PortableRemoteObject.narrow(ref, TravelAgentHomeRemote.class);
TravelAgentRemote agent = home.create(customer);
This code creates a new Customer EJB based on information the travel
agent gathered over the phone. The CustomerRemote
reference is then used to create a TravelAgent EJB. Next, we gather
the cruise and cabin choices from another part of the applet:
Integer cruise_id = new Integer(textField_cruiseNumber.getText( )); Integer cabin_id = new Integer( textField_cabinNumber.getText( )); agent.setCruiseID(cruise_id); agent.setCabinID(cabin_id);
The travel agent chooses the cruise and cabin the customer wishes to reserve. These IDs are set in the TravelAgent EJB, which maintains the conversational state for the whole process.
At the end of the process, the travel agent completes the reservation by processing the booking and generating a ticket. Because the TravelAgent EJB has maintained the conversational state, caching the customer, cabin, and cruise information, only the credit card and price are needed to complete the transaction:
String cardNumber = textField_cardNumber.getText( ); Date date = dateFormatter.parse(textField_cardExpiration.getText( )); String cardBrand = textField_cardBrand.getText( ); CreditCardDOcard
= new CreditCardDO(cardNumber,date,cardBrand); doubleprice
= double.valueOf(textField_cruisePrice.getText( )).doubleValue( ); TicketDO ticket = agent.bookPassage(card,price); PrintingService.print(ticket);
This summary of how the client will use the TravelAgent EJB confirms that our remote interface and home interface definitions are workable. We can now move ahead with development.
We can now implement all of the
behavior expressed in the new remote interface and home interface for
the TravelAgent EJB.[33] Here is a partial definition of the new
TravelAgentBean
class:
import com.titan.reservation.*; import java.sql.*; import javax.sql.DataSource; import java.util.Vector; import java.rmi.RemoteException; import javax.naming.NamingException; import javax.ejb.EJBException; import com.titan.processpayment.*; import com.titan.cruise.*; import com.titan.customer.*; import com.titan.cabin.*; public class TravelAgentBean implements javax.ejb.SessionBean { public CustomerRemote customer; public CruiseLocal cruise; public CabinLocal cabin; public javax.ejb.SessionContext ejbContext; public javax.naming.Context jndiContext; public void ejbCreate(CustomerRemote cust) { customer = cust; } public void setCabinID(Integer cabinID) throws javax.ejb.FinderException { try { CabinHomeLocal home = (CabinHomeLocal) jndiContext.lookup("java:comp/env/ejb/CabinHomeLocal"); cabin = home.findByPrimaryKey(cabinID); } catch(RemoteException re) { throw new EJBException(re); } } public void setCruiseID(Integer cruiseID) throws javax.ejb.FinderException { try { CruiseHomeLocal home = (CruiseHomeLocal) jndiContext.lookup("java:comp/env/ejb/CruiseHomeLocal"); cruise = home.findByPrimaryKey(cruiseID); } catch(RemoteException re) { throw new EJBException(re); } } public TicketDO bookPassage(CreditCardDO card, double price) throws IncompleteConversationalState { if (customer == null || cruise == null || cabin == null) { throw new IncompleteConversationalState( ); } try { ReservationHomeLocal resHome = (ReservationHomeLocal) jndiContext.lookup("java:comp/env/ejb/ReservationHomeLocal"); ReservationLocal reservation = resHome.create(customer, cruise, cabin, price, new Date( )); Object ref = jndiContext.lookup("java:comp/env/ejb/ ProcessPaymentHomeRemote"); ProcessPaymentHomeRemote ppHome = (ProcessPaymentHomeRemote) PortableRemoteObject.narrow (ref, ProcessPaymentHomeRemote.class); ProcessPaymentRemote process = ppHome.create( ); process.byCredit(customer, card, price); TicketDO ticket = new TicketDO(customer, cruise, cabin, price); return ticket; } catch(Exception e) { throw new EJBException(e); } } public void ejbRemove( ) {} public void ejbActivate( ) {} public void ejbPassivate( ) {} public void setSessionContext(javax.ejb.SessionContext cntx) { ejbContext = cntx; try { jndiContext = new javax.naming.InitialContext( ); } catch(NamingException ne) { throw new EJBException(ne); } } }
This is a lot of code to
digest, so we will approach it in small pieces. First,
let’s examine the
ejbCreate( )
method:
public class TravelAgentBean implements javax.ejb.SessionBean { public CustomerRemote customer; ... public javax.ejb.SessionContext ejbContext; public javax.naming.Context jndiContext; public void ejbCreate(CustomerRemote cust) { customer = cust; }
When the bean is created, the remote reference to the Customer EJB is
passed to the bean instance and maintained in the
customer
field. The customer
field is part of the bean’s conversational state. We
could have obtained the customer’s identity as an
integer ID and constructed the remote reference to the Customer EJB
in the ejbCreate( )
method. However, we passed the
reference directly to demonstrate that remote references to beans can
be passed from a client application to a bean. They can also be
returned from the bean to the client and passed between beans on the
same EJB server or between EJB servers.
References to the SessionContext
and JNDI context
are held in fields called ejbContext
and
jndiContext
. The
“ejb” and
“jndi” prefixes help to avoid
confusion between the different content types.
When a bean is passivated, the JNDI ENC must be maintained as part of
the bean’s conversational state. This means that the
JNDI context should not be transient
. Once a field
is set to reference the JNDI ENC, the reference remains valid for the
life of the bean. In the TravelAgentBean
, we set
the jndiContext
field when the
SessionContext
is set, at the beginning of the
bean’s life cycle:
public void setSessionContext(javax.ejb.SessionContext cntx) { ejbContext = cntx; try { jndiContext = new InitialContext( ); } catch(NamingException ne) { throw new EJBException(ne); } }
The EJB container makes special accommodations for references to the
SessionContext
, the JNDI ENC, references to other
beans (remote and home interface types), and the JTA
UserTransaction
type (discussed in Chapter 15). The container must maintain any instance
fields that reference objects of these types as part of the
conversational state, even if they are not serializable. All other
fields must be serializable or null
when the bean
is passivated.
The TravelAgent EJB has methods for setting the desired cruise and
cabin. These methods take Integer
IDs as arguments
and retrieve references to the appropriate Cruise or Cabin EJB from
the appropriate home interface. These references are also part of the
TravelAgent EJB’s conversational state.
Here’s how setCabinID( )
and
getCabinID( )
are defined:
public void setCabinID(Integer cabinID) throws javax.ejb.FinderException { try { CabinHomeLocal home = (CabinHomeLocal) jndiContext.lookup("java:comp/env/ejb/CabinHomeLocal"); cabin = home.findByPrimaryKey(cabinID); } catch(RemoteException re) { throw new EJBException(re); } } public void setCruiseID(Integer cruiseID) throws javax.ejb.FinderException { try { CruiseHomeLocal home = (CruiseHomeLocal) jndiContext.lookup("java:comp/env/ejb/CruiseHomeLocal"); cruise = home.findByPrimaryKey(cruiseID); } catch(RemoteException re) { throw new EJBException(re); } }
It may seem strange that we set these values using
Integer
IDs, but we keep them in the
conversational state as entity bean references. Using
Integer
IDs is simpler for the client, which does
not work with their entity bean references. In the client code, we
get the cabin and cruise IDs from text fields. Why make the client
obtain a bean reference to the Cruise and Cabin EJBs when an ID is
simpler? In addition, using the IDs is cheaper (i.e., requires less
network traffic) than passing a remote reference. We need the EJB
object references to these bean types in the bookPassage( )
method, so we use their IDs to obtain actual entity bean
references. We could have waited until the bookPassage( )
method was invoked before reconstructing the remote
references, but this strategy keeps the bookPassage( )
method simple.
You can use the JNDI ENC to obtain a reference to the home interfaces of other beans. Using the ENC lets you avoid hardcoding vendor-specific JNDI properties into the bean. In other words, the JNDI ENC allows EJB references to be network and vendor independent.
In the TravelAgentBean
, we used the JNDI ENC to
acquire both the remote home interface of the ProcessPayment EJB and
the local home interfaces of the Cruise and Cabin EJBs. The EJB
specification recommends that all EJB references be bound to the
"java:comp/env/ejb
" context, which is the
convention followed here. In the TravelAgent EJB, we append the name
of the home object to "java:comp/env/ejb
“, giving
a result like "java:comp/env/ejb/CruiseHomeLocal
“.
The deployment descriptor provides a special set of tags for
declaring remote EJB references. Here’s how the
<ejb-ref>
tag and its subelements are used:
<ejb-ref> <ejb-ref-name>ejb/ProcessPaymentHomeRemote</ejb-ref-name> <ejb-ref-type>Session</ejb-ref-type> <home> com.titan.processpayment.ProcessPaymentHomeRemote </home> <remote> com.titan.processpayment.ProcessPaymentRemote </remote> </ejb-ref>
These elements define a name for the bean within the ENC, declare the
bean’s type, and give the names of its remote and
home interfaces. When a bean is deployed, the deployer maps the
<ejb-ref>
elements to actual beans in a way
specific to the vendor. The <ejb-ref>
elements can also be linked by the application assembler to beans in
the same deployment (a subject covered in detail in Chapter 17). However, you should try to use local
component interfaces for beans located in the same deployment and
container.
The deployment descriptor also provides a special set of tags, the
<ejb-local-ref>
elements, to declare local
EJB references: enterprise beans that are co-located in the same
container and deployed in the same EJB JAR file. The
<ejb-local-ref>
elements are declared
immediately after the <ejb-ref>
elements:
<ejb-local-ref> <ejb-ref-name>ejb/CruiseHomeLocal</ejb-ref-name> <ejb-ref-type>Entity</ejb-ref-type> <local-home> com.titan.cruise.CruiseHomeLocal </local-home> <local> com.titan.cruise.CruiseLocal </local> <ejb-link>CruiseEJB</ejb-link> </ejb-local-ref> <ejb-local-ref> <ejb-ref-name>ejb/CabinHomeLocal</ejb-ref-name> <ejb-ref-type>Entity</ejb-ref-type> <local-home> com.titan.cabin.CabinHomeLocal </local-home> <local> com.titan.cabin.CabinLocal </local> <ejb-link>CabinEJB</ejb-link> </ejb-local-ref>
The <ejb-local-ref>
element defines a name
for the bean within the ENC, declares the bean’s
type, and gives the names of its local component interfaces. These
elements should be linked explicitly to other co-located beans using
the <ejb-link>
element, although linking
them is not strictly required at this stage—the application
assembler or deployer can do it later. The value of the
<ejb-link>
element within the
<ejb-local-ref>
must be the same as the
<ejb-name>
of the appropriate bean in the
same JAR file.
At deployment time the EJB container’s tools map the
local references declared in the
<ejb-local-ref>
elements to entity beans
that are co-located in the same container system.
The
last point of interest in our bean definition is the
bookPassage( )
method. This method makes use of
the conversational state accumulated by the ejbCreate( )
, setCabinID( )
, and
setCruiseID( )
methods to process a reservation
for a customer. Here’s how the bookPassage( )
method is defined:
public TicketDO bookPassage(CreditCardDO card, double price) throws IncompleteConversationalState { if (customer == null || cruise == null || cabin == null) { throw new IncompleteConversationalState( ); } try { ReservationHomeLocal resHome = (ReservationHomeLocal) jndiContext.lookup("java:comp/env/ejb/ReservationHomeLocal"); ReservationLocal reservation = resHome.create(customer, cruise, cabin, price, new Date( )); Object ref = jndiContext.lookup("java:comp/env/ejb/ ProcessPaymentHomeRemote"); ProcessPaymentHomeRemote ppHome = (ProcessPaymentHomeRemote) PortableRemoteObject.narrow(ref, ProcessPaymentHomeRemote.class); ProcessPaymentRemote process = ppHome.create( ); process.byCredit(customer, card, price); TicketDO ticket = new TicketDO(customer,cruise,cabin,price); return ticket; } catch(Exception e) { throw new EJBException(e); } }
This method deomonstrates the concept of
taskflow. It uses several beans, including
the Reservation, ProcessPayment, Customer, Cabin, and Cruise EJBs, to
accomplish one task: booking a customer on a cruise. Deceptively
simple, this method encapsulates several interactions that ordinarily
might have been performed on the client. For the price of one
bookPassage( )
call from the client, the
TravelAgent EJB performs many operations:
Looks up and obtains a reference to the Reservation EJB’s home.
Creates a new Reservation EJB.
Looks up and obtains a remote reference to the ProcessPayment EJB’s home.
Creates a new ProcessPayment EJB.
Charges the customer’s credit card using the ProcessPayment EJB.
Generates a new TicketDO
with all the pertinent
information describing the customer’s purchase.
From a design standpoint, encapsulating the taskflow in a stateful
session bean means a less complex interface for the client and more
flexibility for implementing changes. We could easily change
bookPassage( )
to check for overlapped booking
(when a customer books passage on two cruises with overlapping
dates). This type of enhancement does not change the remote
interface, so the client application does not need modification.
Encapsulating taskflow in stateful session beans allows the system to
evolve without impacting clients.
In addition, the type of clients used can change. One of the biggest problems with two-tier architectures—besides scalability and transactional control—is that the business logic is intertwined with the client logic. As a result, it is difficult to reuse the business logic in a different kind of client. With stateful session beans this is not a problem, because stateful session beans are an extension of the client but are not bound to the client’s presentation. Let’s say that our first implementation of the reservation system used a Java applet with GUI widgets. The TravelAgent EJB would manage conversational state and perform all the business logic while the applet focused on the GUI presentation. If, at a later date, we decide to go to a thin client (HTML generated by a Java servlet, for example), we would simply reuse the TravelAgent EJB in the servlet. Because all the business logic is in the stateful session bean, the presentation (Java applet or servlet or something else) can change easily.
The TravelAgent EJB also provides transactional integrity for
processing the customer’s reservation. If any of the
operations within the body of the bookPassage( )
method fails, all the operations are rolled back so that none of the
changes are accepted. If the credit card cannot be charged by the
ProcessPayment EJB, the newly created Reservation EJB and its
associated record are not created. The transactional aspects of the
TravelAgent EJB are explained in detail in Chapter 15.
The remote and local EJB references can be used within the same
taskflow. For example, the bookPassage( )
method
uses local references when accessing the Cruise and Cabin beans, but
remote references when accessing the ProcessPayment and Customer
EJBs. This usage is totally appropriate. The EJB container ensures
that the transaction is atomic, i.e., that failures in either the
remote or local EJB reference will affect the entire transaction.
If we have a Reservation EJB, why do we need a TravelAgent EJB? The TravelAgent EJB uses the Reservation EJB to create a reservation, but it also has to charge the customer and generate a ticket. These activities are not specific to the Reservation EJB, so they need to be captured in a stateful session bean that can manage taskflow and transactional scope. In addition, the TravelAgent EJB provides listing behavior, which spans concepts in Titan’s system. It would have been inappropriate to include any of these other behaviors in the Reservation entity bean.
As promised, we are going to bring back the cabin-listing behavior we played around with in Chapter 4. This time we are not going to use the Cabin EJB to get the list; instead, we will access the database directly. Accessing the database directly is a double-edged sword. On one hand, we don’t want to access the database directly if entity beans exist that can access the same information. Entity beans provide a safe and consistent interface for a particular set of data. Once an entity bean has been tested and proven, it can be reused throughout the system, substantially reducing data-integrity problems. The Reservation EJB is an example of that kind of usage. Entity beans can also pull together disjointed data and apply additional business logic such as validation, limits, and security to ensure that data access follows the business rules.
But entity beans cannot define every possible data access needed, and they shouldn’t. One of the biggest problems with entity beans is that they tend to become bloated over time. Huge entity beans containing dozens of methods are a sure sign of poor design. Entity beans should be focused on providing data access to a very limited, but conceptually bound, set of data. You should be able to update, read, and insert records or data. Data access that spans concepts, like listing behavior, should not be encapsulated in an entity bean.
Systems always need listing behavior to present clients with choices. In the reservation system, for example, customers need to choose a cabin from a list of available cabins. The word available is key to the definition of this behavior. The Cabin EJB can provide us with a list of cabins, but it does not know whether any given cabin is available. As you may recall, the Cabin-Reservation relationship we defined in Chapter 7 was unidirectional: the Reservation was aware of its Cabin relationships, but the reverse was not true. The question of whether a cabin is available is relevant to the process using it—in this case, the TravelAgent EJB—but may not be relevant to the cabin itself. As an analogy, an automobile entity would not care what road it is on; it is concerned only with characteristics that describe its state and behavior. An automobile-tracking system, on the other hand, would be concerned with the locations of individual automobiles.
To get availability information, we need to compare the list of
cabins on our ship to the list of cabins that have already been
reserved. The listAvailableCabins( )
method does
exactly that. It uses an SQL query to produce a list of cabins that
have not yet been reserved for the cruise chosen by the client:
public String [] listAvailableCabins(int bedCount) throws IncompleteConversationalState { if (cruise == null) throw new IncompleteConversationalState( ); Connection con = null; PreparedStatement ps = null;; ResultSet result = null; try { Integer cruiseID = (Integer)cruise.getPrimaryKey( ); Integer shipID = (Integer)cruise.getShip( ).getPrimaryKey( ); con = getConnection( ); ps = con.prepareStatement( "select ID, NAME, DECK_LEVEL from CABIN "+ "where SHIP_ID = ? and BED_COUNT = ? and ID NOT IN "+ "(SELECT CABIN_ID FROM RESERVATION "+" WHERE CRUISE_ID = ?)"); ps.setInt(1,shipID.intValue( )); ps.setInt(2, bedCount); ps.setInt(3,cruiseID.intValue( )); result = ps.executeQuery( ); Vector vect = new Vector( ); while(result.next( )) { StringBuffer buf = new StringBuffer( ); buf.append(result.getString(1)); buf.append(','), buf.append(result.getString(2)); buf.append(','), buf.append(result.getString(3)); vect.addElement(buf.toString( )); } String [] returnArray = new String[vect.size( )]; vect.copyInto(returnArray); return returnArray; } catch (Exception e) { throw new EJBException(e); } finally { try { if (result != null) result.close( ); if (ps != null) ps.close( ); if (con!= null) con.close( ); } catch(SQLException se){se.printStackTrace( );} } }
As you can see, the SQL query is complex. It could have been defined
using a method like
Cabin.findAvailableCabins(Cruise
cruise)
in the Cabin EJB. However, this method
would be difficult to implement because the Cabin EJB would need to
access the Reservation EJB’s data.
It’s also easy to imagine cluttering an entity bean
with lots of fairly specific find methods that are tied to particular
situations. Such clutter isn’t necessary or
desirable. To avoid adding find methods for every possible query, you
can instead use direct database access as shown in the
listAvailableCabins( )
method. Direct database
access generally has less impact on performance because the container
does not have to manifest EJB object references, but it is also less
reusable. When you are deciding whether to add a find method to an
entity bean or to make a direct query in a session bean, keep in mind
the tradeoff between reusability, performance, and clarity.
The listAvailableCabins( )
method returns an array
of String
objects. We could have opted to return a
collection of remote Cabin references, but we didn’t
because we want to keep the client application as lightweight as
possible. A list of String
objects is much more
lightweight than a collection of remote references; this way, the
client doesn’t have to work with a group of stubs,
each with its own connection to EJB objects on the server. By
returning a lightweight String
array, we reduce
the number of stubs on the client, which keeps the client simple and
conserves resources on the server.
To make this method work, you need to create a private
getConnection( )
method for obtaining a database
connection. This method becomes part of the
TravelAgentBean
:
private Connection getConnection( ) throws SQLException { try { DataSource ds = (DataSource)jndiContext.lookup( "java:comp/env/jdbc/titanDB"); return ds.getConnection( ); } catch(NamingException ne) { throw new EJBException(ne); } }
Change the remote interface for TravelAgent EJB to include the
listAvailableCabins( )
method:
package com.titan.travelagent; import java.rmi.RemoteException; import javax.ejb.FinderException; import com.titan.processpayment.CreditCard; public interface TravelAgentRemote extends javax.ejb.EJBObject { public void setCruiseID(Integer cruise) throws RemoteException, FinderException; public void setCabinID(Integer cabin) throws RemoteException, FinderException; public TicketDO bookPassage(CreditCardDO card, double price) throws RemoteException,IncompleteConversationalState;public String [] listAvailableCabins(int bedCount)
throws RemoteException, IncompleteConversationalState;
}
Here’s an abbreviated version of the XML deployment descriptor used for the TravelAgent EJB. It defines not only the TravelAgent EJB, but also the Customer, Cruise, Cabin, and Reservation EJBs. The ProcessPayment EJB is not defined in this deployment descriptor because it is assumed to be deployed in a separate JAR file, or possibly even a separate EJB server on a different network node:
<?xml version="1.0" encoding="UTF-8" ?> <ejb-jar xmlns="http://java.sun.com/xml/ns/j2ee" xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance" xsi:schemaLocation="http://java.sun.com/xml/ns/j2ee http://java.sun.com/xml/ns/j2ee/ejb-jar_2_1.xsd" version="2.1"> <enterprise-beans> <session> <ejb-name>TravelAgentEJB</ejb-name> <home>com.titan.travelagent.TravelAgentHomeRemote</home> <remote>com.titan.travelagent.TravelAgentRemote</remote> <ejb-class>com.titan.travelagent.TravelAgentBean</ejb-class> <session-type>Stateful</session-type> <transaction-type>Container</transaction-type> <ejb-ref> <ejb-ref-name>ejb/ProcessPaymentHomeRemote</ejb-ref-name> <ejb-ref-type>Session</ejb-ref-type> <home>com.titan.processpayment.ProcessPaymentHomeRemote</home> <remote>com.titan.processpayment.ProcessPaymentRemote</remote> </ejb-ref> <ejb-local-ref> <ejb-ref-name>ejb/CabinHomeLocal</ejb-ref-name> <ejb-ref-type>Entity</ejb-ref-type> <local-home>com.titan.cabin.CabinHomeLocal</local-home> <local>com.titan.cabin.CabinLocal</local> </ejb-local-ref> <ejb-local-ref> <ejb-ref-name>ejb/CruiseHomeLocal</ejb-ref-name> <ejb-ref-type>Entity</ejb-ref-type> <local-home>com.titan.cruise.CruiseHomeLocal</local-home> <local>com.titan.cruise.CruiseLocal</local> </ejb-local-ref> <ejb-local-ref> <ejb-ref-name>ejb/ReservationHomeLocal</ejb-ref-name> <ejb-ref-type>Entity</ejb-ref-type> <local-home>com.titan.reservation.ReservationHomeLocal</local-home> <local>com.titan.reservation.ReservationLocal</local> </ejb-local-ref> <resource-ref> <description>DataSource for the Titan database</description> <res-ref-name>jdbc/titanDB</res-ref-name> <res-type>javax.sql.DataSource</res-type> <res-auth>Container</res-auth> </resource-ref> </session> <entity> <ejb-name>CabinEJB</ejb-name> <local-home>com.titan.cabin.CabinHomeLocal</local-home> <local>com.titan.cabin.CabinLocal</local> ... </entity> <entity> <ejb-name>CruiseEJB</ejb-name> <local-home>com.titan.cruise.CruiseHomeLocal</local-home> <local>com.titan.cruise.CruiseLocal</local> ... </entity> <entity> <ejb-name>ReservationEJB</ejb-name> <local-home>com.titan.reservation.ReservationHomeLocal</local-home> <local>com.titan.reservation.ReservationLocal</local> ... </entity> </enterprise-beans> <assembly-descriptor> <security-role> <description>This role represents everyone</description> <role-name>everyone</role-name> </security-role> <method-permission> <role-name>everyone</role-name> <method> <ejb-name>TravelAgentEJB</ejb-name> <method-name>*</method-name> </method> </method-permission> <container-transaction> <method> <ejb-name>TravelAgentEJB</ejb-name> <method-name>*</method-name> </method> <trans-attribute>Required</trans-attribute> </container-transaction> </assembly-descriptor> </ejb-jar>
The deployment descriptor for EJB 2.0 is exactly the same, except
it’s based on a DTD instead of an XML Schema, so it
uses a document declaration and has a simpler
<ejb-jar>
element.
<?xml version="1.0" encoding="UTF-8" ?> <!DOCTYPE ejb-jar PUBLIC "-//Sun Microsystems, Inc.//DTD Enterprise JavaBeans 2.0//EN" "http://java.sun.com/dtd/ejb-jar_2_0.dtd"> <ejb-jar> <enterprise-beans> ...
Once you have generated the deployment descriptor, jar the TravelAgent EJB and deploy it in your EJB server. You will also need to deploy the Reservation, Cruise, and Customer EJBs you downloaded earlier. Based on the business methods in the remote interface of the TravelAgent EJB and your past experiences with the Cabin, Ship, and ProcessPayment EJBs, you should be able to create your own client application to test this code.
Exercise 11.2 in the Workbook shows how to deploy the examples in this section.
[31] This is a conceptual model. Some EJB containers may actually use instance swapping with stateful session beans but make it appear as if the same instance is servicing all requests. Conceptually, however, the same stateful session bean instance services all requests.
[32] This is also a conceptual model. Some EJB containers may use separate EJB objects for concurrent access to the same entity, relying on the database to control concurrency. Conceptually, however, the end result is the same.