- Jpa Tools Generate Composite Key Tables For Kids
- Sql Composite Key Example
- Jpa Tools Generate Composite Key Tables For Beginners
- Jpa Tools Generate Composite Key Tables 2016
The issue of the legacy database schema
How to generate entities from tables with Eclipse JPA Tools. Creating JPA project and generating entities. Configuring persistence properties and JPA project. Testing the JPA project. Update database when entity changed.
The problem definition
This tip starts with a simple description of the problem: defining a composite database key. This is a key that combines a number of columns to uniquely define the rows of a database table. Sometimes, composite keys are called natural keys or business keys. Composite keys are sometimes used because the choice of key relates in some way to the end-user business domain. To define a composite key, you simply take some attributes from the domain and combine them to provide the required degree of row uniqueness. The downside to composite keys is that they are a little difficult to design and code. Also, they tend to tie your database and ORM design to the original domain. The latter may or may not be a big issue.
Entity code
Listing 1 illustrates a Java class called
BillingAddress
. This class models the billing address for a person or an organization. The billing itself relates to another Java class called PurchaseOrder
. There's nothing too amazing here — a purchase order is placed and a billing process ensues.Listing 1. The BillingAddress
class
An important point to note is that the class implements the Java
Serializable
interface. Notice also the line with the annotation @Embeddable
. This annotation is the first piece of the composite key jigsaw puzzle. A Java class with the @Embeddable
annotation can itself become a subcomponent of another class. That sounds a lot more complicated than it is. To illustrate, Listing 2 shows the PurchaseOrder
class, which uses the BillingAddress
class from Listing 1.Listing 2. The PurchaseOrder
class
I always find annotations a bit hard to follow, and Listing 2 is no exception, so I'll break it down into manageable chunks. The first annotation is
@Entity
, which indicates that the class is a database entity (that is, it will form part of the ORM solution). Typically, when you see the @Entity
annotation, you can expect to see a corresponding database table. The latter is indicated by the next annotation — namely, @Table
. I find when you break down the process in this way, it becomes easier to understand.Next up in Listing 2 is the
@IdClass
annotation, which defines the composite key class reference. You may have noted that this annotation refers to the BillingAddress
class from Listing 1. Skipping past the constructors in Listing 2, notice the @Id
annotation. This is where the composite key is defined with nested @AttributeOverrides
annotations. These annotations are used to define the composite key columns: 'STREET' and 'CITY' respectively.Just after the annotations in Listing 2, can you spot two lines of duplicate code from Listing 1? The duplicate code is, of course, the two private data members for street and city. This duplication is required to create the composite key.
The database schema
So far, it's all been fairly technical. Now see this expressed in a more concrete fashion by generating a database schema. Listing 3 illustrates the schema from this ultra-simple ORM database design.
Jpa Tools Generate Composite Key Tables For Kids
Listing 3. The database schema
You can see that the primary key is indeed a composite made up of the street and city fields. What does this look like in a real database — for example, one with a graphical user interface (GUI) tool? Before answering that, I write some simple client code to persist one or two entities to a database.
Listing 4 illustrates an excerpt of some code to instantiate objects of the classes defined earlier.
Listing 4. Some ORM client code
The code in Listing 4 illustrates the journey from
PurchaseOrder
object instantiation and setup all the way through to persistence of this object in the database. This really illustrates the magic that is ORM. Have a look at what happens.To begin with, an instance of
EntityManagerFactory
is created, and this is, in turn, used to create an instance of EntityManager
called em
. The latter is then used to write the PurchaseOrder
object instance to the database. The actual persistence into the database occurs as part of a transaction.A transaction is a set of atomic actions that either all occur successfully or are rolled back in the case of error. As you can see from Listing 4, the
EntityManager
object is used to create an instance of EntityTransaction
called tx
. It is the latter object that wraps the unit of work in a transaction.Notice the calls to
persist()
and commit()
. It's important to remember that no changes to the database occur unless both of these invocations occur. This is the simple pattern of the Java Persistence API (JPA).To complete the ORM tour, Figure 1 shows what the database looks like after running the code in Listing 4. The code was tested using an in-memory database called HSQLDB, and this product includes a simple GUI tool. The state of the HSQLDB database is shown in Figure 1. You can see that I ran an SQL query on the PURCHASE_ORDERS table. This table was created from the schema, which itself was created from the Java code in the earlier listings.
Figure 1. The populated database
In Figure 1, you can see the effect that this line of code from Listing 4 had:
purchaseOrder.setItemName('My new computer')
. The invocation of the setter code populated the associated column in the database row with the String data: 'My new computer.' In terms of workflow, you can think of the overall program run as the creation of a purchase order for a new computer followed by a billing process. All the steps in the workflow are implicitly stored in the database.Concluding comments about composite keys
![Jpa tools generate composite key tables for sale Jpa tools generate composite key tables for sale](/uploads/1/2/6/6/126623391/278694033.jpg)
The composite key defined in listings 1 and 2 allows you to bundle a number of columns together. The combination of columns then provides the required uniqueness so you can have an arbitrary number of rows in the database table. You've seen how it's done. Now, you need to briefly understand why one might take this quirky approach to database design.
Sql Composite Key Example
Probably the most common reason for using composite keys is for backwards-compatibility. In other words, it occurs in those cases where you need to integrate new database code into a legacy environment. I think it's quite unusual to intentionally design a database this way nowadays, so it's likely you'll only need to create composite keys where it is a long-established practice.
In such cases, my experience is that it's pointless arguing against this approach. If composite keys are the standard, then that's not likely to change any time soon. In many cases, there may be masses of existing data already structured in this way. So, if a change is made from composite keys to numerical keys, then the legacy data has to be migrated. Also, there may be business processes that map onto the composite key data. The combination of all these factors may make composite key design a necessity.
Downloadable resources
Related topics
Jpa Tools Generate Composite Key Tables For Beginners
![Jpa Tools Generate Composite Key Tables Jpa Tools Generate Composite Key Tables](/uploads/1/2/6/6/126623391/175924936.png)
Jpa Tools Generate Composite Key Tables 2016
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