Can anyone explain in simple words what First and Second Level caching in Hibernate/NHibernate are?
1.1) First-level cache
First-level cache always Associates with the Session object. Hibernate uses this cache by default. Here, it processes one transaction after another one, means wont process one transaction many times. Mainly it reduces the number of SQL queries it needs to generate within a given transaction. That is instead of updating after every modification done in the transaction, it updates the transaction only at the end of the transaction.
1.2) Second-level cache
Second-level cache always associates with the Session Factory object. While running the transactions, in between it loads the objects at the Session Factory level, so that those objects will be available to the entire application, not bound to single user. Since the objects are already loaded in the cache, whenever an object is returned by the query, at that time no need to go for a database transaction. In this way the second level cache works. Here we can use query level cache also.
There's a pretty good explanation of first level caching on the Streamline Logic blog.
Basically, first level caching happens on a per session basis where as second level caching can be shared across multiple sessions.
Here some basic explanation of hibernate cache...
First level cache is associated with “session” object.
The scope of cache objects is of session. Once session is closed, cached objects are gone forever.
First level cache is enabled by default and you can not disable it.
When we query an entity first time, it is retrieved from database and stored in first level cache associated with hibernate session.
If we query same object again with same session object, it will be loaded from cache and no sql query will be executed.
The loaded entity can be removed from session using
evict() method. The next loading of this entity will again make a database call if it has been removed using
The whole session cache can be removed using
clear() method. It will remove all the entities stored in cache.
Second level cache is apart from first level cache which is available to be used globally in session factory scope.
second level cache is created in session factory scope and is available to be used in all sessions which are created using that particular session factory.
It also means that once session factory is closed, all cache associated with it die and cache manager also closed down.
Whenever hibernate session try to load an entity, the very first place it look for cached copy of entity in first level cache (associated with particular hibernate session).
If cached copy of entity is present in first level cache, it is returned as result of load method.
If there is no cached entity in first level cache, then second level cache is looked up for cached entity.
If second level cache has cached entity, it is returned as result of load method. But, before returning the entity, it is stored in first level cache also so that next invocation to load method for entity will return the entity from first level cache itself, and there will not be need to go to second level cache again.
If entity is not found in first level cache and second level cache also, then database query is executed and entity is stored in both cache levels, before returning as response of
Hibernate tries to defer the Persistence Context flushing up until the last possible moment. This strategy has been traditionally known as transactional write-behind.
The write-behind is more related to Hibernate flushing rather than any logical or physical transaction. During a transaction, the flush may occur multiple times.
The flushed changes are visible only for the current database transaction. Until the current transaction is committed, no change is visible by other concurrent transactions.
Due to the first-level cache, Hibernate can do several optimizations:
- JDBC statement batching
- prevent lost update anomalies
A proper caching solution would have to span across multiple Hibernate Sessions and that’s the reason Hibernate supports an additional second-level cache as well.
The second-level cache is bound to the SessionFactory life-cycle, so it’s destroyed only when the
SessionFactory is closed (typically when the application is shutting down). The second-level cache is primarily entity-based oriented, although it supports an optional query-caching solution as well.
When loading an entity, Hibernate will execute the following actions:
- If the entity is stored in the first-level cache, then the cached object reference is returned. This ensures application-level repeatable reads.
- If the entity is not stored in the first-level cache and the second-level cache is activated, then Hibernate checks if the entity has been cached in the second-level cache, and if it were, it returns it to the caller.
- Otherwise, if the entity is not stored in the first or second-level cache, it will be loaded from the DB.
by default, NHibernate uses first level caching which is Session Object based. but if you are running in a multi-server environment, then the first level cache may not very scalable along with some performance issues. it is happens because of the fact that it has to make very frequent trips to the database as the data is distributed over multiple servers. in other words NHibernate provides a basic, not-so-sophisticated in-process L1 cache out of box. However, it doesn’t provide features that a caching solution must have to have a notable impact on the application performance.
so the questions of all these problem is the use of a L2 cache which is associated with the session factory objects. it reduces the time consuming trips to the database so ultimately increases the app response time.
First Level Cache
Session object holds the first level cache data. It is enabled by default. The first level cache data will not be available to entire application. An application can use many session object.
Second Level Cache
SessionFactory object holds the second level cache data. The data stored in the second level cache will be available to entire application. But we need to enable it explicitly.