I have a quite heavy java webapp that serves thousands of requests/sec and it uses a master Postgresql db which replicates itself to one secondary (read-only) database using streaming (asynchronous) replication.

So, I separate the request from primary to secondary(read-only) using URLs to avoid read-only calls to bug primary database considering replication time is minimal.

NOTE: I use one sessionFactory with a RoutingDataSource provided by spring that looks up db to use based on a key. I am interested in multitenancy as I am using hibernate 4.3.4 that supports it.

I have two questions:

  1. I dont think splitting on the basis of URLs is efficient as I can only move 10% of traffic around means there are not many read-only URLs. What approach should I consider?
  2. May be,somehow, on the basis of URLs I achieve some level of distribution among both nodes but what would I do with my quartz jobs(that even have separate JVM)? What pragmatic approach should I take?

I know I might not get a perfect answer here as this really is broad but I just want your opinion for the context.

Dudes I have in my team:

  • Spring4
  • Hibernate4
  • Quartz2.2
  • Java7 / Tomcat7

Please take interest. Thanks in advance.

  • I'd have two persistence units - one for read-only, and one for read-write, work. The read-only one might point to a PgBouncer that backs on to multiple PostgreSQL replicas. Then I'd pick which to use based on the particular method invoked on my data access abstraction objects and other relevant context. You have to think very carefully about logical consistency if you do this though, and avoid read/modify/write cycles. – Craig Ringer Sep 18 '14 at 14:06
  • User tracking is an area that can be optimized, if not already done: separation into R/O + R+W tables, session held cache, written out. Archiving tables that only receive new records, but the records being immutable, can be split too in R/O and R+W, possibly with DB triggers. – Joop Eggen Sep 22 '14 at 11:30

You should have:

  1. a DataSource configured to connect to the master node
  2. a DataSource configured to connect to the slave node
  3. the routing DataSource stands in front of these two, being the one your SessionFactory uses.
  4. you can use the @Transactional(readOnly=true) flag to make sure you route read-only transactions to the slave DataSource.
  5. Both the master and the slave DataSource require a connection pooling mechanism, and the fastest one is definitely HikariCP. HikariCP is so fast, that on one test of mine I got a 100us average connection acquire time.
  6. You need to make sure you set the right size for you connection pools, because that can make a huge difference. For this I recommend using flexy-pool. You can find more about it here and here.
  7. You need to be very diligent and make sure you mark all read-only transactions accordingly. It's unusual that only 10% of your transactions are read-only. Could it be that you have such a write-most application or you are using write transactions where you only issue query statements?
  8. Monitor all queries executions using an SQL logging framework. The shorter the query execution the shorter the lock acquisition times the more transactions per seconds will your system accommodate.
  9. For batch processing you definitely need write-most transactions, but OLTP in general and Hibernate in particular are not the best fit for OLAP. If you still decide to use Hibernate for your quartz jobs make sure you enable JDBC batching and you should have these Hibernate properties set:

    <property name="hibernate.order_updates" value="true"/>
    <property name="hibernate.order_inserts" value="true"/>
    <property name="hibernate.jdbc.batch_versioned_data" value="true"/>
    <property name="hibernate.jdbc.fetch_size" value="25"/>
    <property name="hibernate.jdbc.batch_size" value="25"/>
    

For batching you can use a separate data source that using a different connection pool (and because you already said you have a different JVM then that's what you already have). Just make sure your total connection size of all connection pools is less than the number of connections PostgreSQL has been configured with.

So the batch processor uses a separate HikariCPDataSource that connects to master. Each batch job must use a dedicated transaction, so make sure you use a reasonable batch size. You want to hold locks and to finish transactions as fast as possible. If the batch processor is using concurrent processing workers, make sure the associated connection pool size is equal to the number of workers, so they don't wait for others to release connections.

You are saying that your application URL's are only 10% read only so the other 90% have at least some form of database writing.

10% READ

You can think about using a CQRS design that may improve your database read performance. It can certainly read from the secondary database, and possibly be made more efficient by designing the queries and domain models specifically for the read/view layer.

You haven't said whether the 10% requests are expensive or not (e.g. running reports)

I would prefer to use a separate sessionFactory if you were to follow the CQRS design as the objects being loaded/cached will most likely be different to those being written.

90% WRITE

As far as the other 90% go, you wouldn't want to read from the secondary database (while writing to the primary) during some write logic as you will not want potentially stale data involved.

Some of these reads are likely to be looking up "static" data. If Hibernate's caching is not reducing database hits for reads, I would consider an in memory cache like Memcached or Redis for this type of data. This same cache could be used by both 10%-Read and 90%-write processes.

For reads that are not static (i.e. reading data you have recently written) Hibernate should hold data in its object cache if its' sized appropriately. Can you determine your cache hit/miss performance?

QUARTZ

If you know for sure that a scheduled job won't impact the same set of data as another job, you could run them against different databases, however if in doubt always perform batch updates to one (primary) server and replicate changes out. It is better to be logically correct, than to introduce replication issues.

DB PARTITIONING

If your 1,000 requests per second are writing a lot of data, look at partitioning your database. You may find you have ever growing tables. Partitioning is one way to address this without archiving data.

Sometimes you need little or no change to your application code.

Archiving is obviously another option

Disclaimer: Any question like this is always going to be application specific. Always try to keep your architecture as simple as possible.

If I correctly understand, 90% of the HTTP requests to your webapp involve at least one write and have to operate on master database. You can direct read only transactions to the copy database, but the improvement will only affect 10% of global databases operation and even those read only operations will hit a database.

The common architecture here is to use a good database cache (Infinispan or Ehcache). If you can offer a big enough cache, you can hope the a good part of the database reads only hit the cache and become memory only operations, either being part of a read only transaction or not. Cache tuning is a delicate operation, but IMHO is necessary to achieve high performance gain. Those cache even allow for distributed front ends even if the configuration is a bit harder in that case (you might have to look for Terracotta clusters if you want to use Ehcache).

Currently, database replication is mainly used to secure the data, and is used as an concurrency improvement mechanizme only if you have high parts of the Information Systems that only read data - and it is not what you are describing.

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