Can someone explain what isolation & propagation parameters are for in the
@Transactional annotation via real world example. Basically when and why I should choose to change their default values.
Good question, although not a trivial one to answer.
Defines how transactions relate to each other. Common options
Defines the data contract between transactions.
The different levels have different performance characteristics in a multi threaded application. I think if you understand the
Example when a dirty read can occur
So a sane default (if such can be claimed) could be
A practical example where a new transaction will always be created when entering the
Had we used
We can easily verify the behaviour with a test and see how results differ with propagation levels
With a propagation level of
PROPAGATION_REQUIRED = 0; If DataSourceTransactionObject T1 is already started for Method M1.If for another Method M2 Transaction object is required ,no new Transaction object is created .Same object T1 is used for M2
PROPAGATION_MANDATORY = 2; method must run within a transaction. If no existing transaction is in progress, an exception will be thrown
PROPAGATION_REQUIRES_NEW = 3; If DataSourceTransactionObject T1 is already started for Method M1 and it is in progress(executing method M1) .If another method M2 start executing then T1 is suspended for the duration of method M2 with new DataSourceTransactionObject T2 for M2.M2 run within its own transaction context
PROPAGATION_NOT_SUPPORTED = 4; If DataSourceTransactionObject T1 is already started for Method M1.If another method M2 is run concurrently .Then M2 should not run within transaction context. T1 is suspended till M2 is finished.
PROPAGATION_NEVER = 5; None of the methods run in transaction context.
An isolation level: It is about how much a transaction may be impacted by the activities of other concurrent transactions.It a supports consistency leaving the data across many tables in a consistent state. It involves locking rows and/or tables in a database.
The problem with multiple transaction
Scenario 1.If T1 transaction reads data from table A1 that was written by another concurrent transaction T2.If on the way T2 is rollback,the data obtained by T1 is invalid one.E.g a=2 is original data .If T1 read a=1 that was written by T2.If T2 rollback then a=1 will be rollback to a=2 in DB.But,Now ,T1 has a=1 but in DB table it is changed to a=2.
Scenario2.If T1 transaction reads data from table A1.If another concurrent transaction(T2) update data on table A1.Then the data that T1 has read is different from table A1.Because T2 has updated the data on table A1.E.g if T1 read a=1 and T2 updated a=2.Then a!=b.
Scenario 3.If T1 transaction reads data from table A1 with certain number of rows. If another concurrent transaction(T2) inserts more rows on table A1.The number of rows read by T1 is different from rows on table A1
Scenario 1 is called Dirty reads
Scenario 2 is called Nonrepeatable reads
Scenario 3 is called Phantom reads .
So,isolation level is the extend to which Scenario 1 ,Scenario 2 ,Scenario 3 can be prevented. You can obtained complete isolation level by implementing locking.That is preventing concurrent reads and writes to the same data from occurring.But it affects performance .The level of isolation depends upon application to application how much isolation is required.
ISOLATION_READ_UNCOMMITTED :Allows to read changes that haven’t yet been committed.It suffer from Scenario 1 ,Scenario 2 ,Scenario 3
ISOLATION_READ_COMMITTED:Allows reads from concurrent transactions that have been com- mitted.It may suffer from Scenario 2 ,Scenario 3 . Because other transactions may be updating the data.
ISOLATION_REPEATABLE_READ:Multiple reads of the same field will yield the same results untill it is changed by itself.It may suffer from Scenario 3.Because other transactions may be inserting the data
ISOLATION_SERIALIZABLE: Scenario 1,Scenario 2,Scenario 3 never happens.It is complete isolation.It involves full locking.It affets performace because of locking.
You can test using
You can debug and see the result with different values for isolation and propagation.
Enough explanation about each parameter is given by other answers; However you asked for a real world example,here is the one that clarifies the purpose of different propagation options:Supppose you're in charge of implementing a signup service in which a confirmation e-mail is sent to the user.You come up with two service objects, one for enrolling the user and one for sending e-mails, which the latter is called inside the first one.For example something like this:
You may have noticed that the second service is of propagation type REQUIRES_NEW and moreover chances are it throws an exceptin (SMTP server down ,invalid e-mail or other reasons).You probably don't want the whole process to roll-back, like removing the user information from database or other things; therefor you call the second service in a separate transaction.Back to our example, this time you are concerned about the database security, so you define your DAO classes this way:
Meaning that whenever a DAO object, and hence a potential access to db, is created, we need to reassure that the call was made from inside one of our services, implying that a live transaction should exist; otherwise an exception occurs.Therefor the propagation is of type MANDATORY.
You almost never want to use
Transaction Isolation and Transaction Propagation although related but are clearly two very different concepts. In both cases defaults are customized at client boundary component either by using Declarative transaction management or Programmatic transaction management. Details of each isolation levels and propagation attributes can be found in reference links below.
For given two or more running transactions/connections to a database, how and when are changes made by queries in one transaction impact/visible to the queries in a different transaction. It also related to what kind of database record locking will be used to isolate changes in this transaction from other transactions and vice versa. This is typically implemented by database/resource that is participating in transaction.
In an enterprise application for any given request/processing there are many components that are involved to get the job done. Some of this components mark the boundaries (start/end) of a transaction that will be used in respective component and it's sub components. For this transactional boundary of components, Transaction Propogation specifies if respective component will or will not participate in transaction and what happens if calling component already has or does not have a transaction already created/started. This is same as Java EE Transaction Attributes. This is typically implemented by the client transaction/connection manager.