Does anyone have any real world experience with Hazelcast distributed data grid and execution product? How has it worked for you? It has an astonishingly simple API and functionality that seems almost to good to be true for such a simple to use tool. I have done some very simple apps and it seems to work as advertised so far. So here I am looking for the real world 'reality check'. Thank you.
closed as primarily opinion-based by Mark, Filburt, jontro, BlackHatSamurai, Strelok Aug 24 '17 at 23:41
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We've been using it in production since version 1.8+, using mainly the distributed locking feature. It works great, we've found a couple of workarounds/bugs, but those were fixed relatively fast.
With 1.8M locks per day we found no problems so far.
I recommend start using version 18.104.22.168.
There are still some issues still with its development,
Generally, you can choose to either let it use its own multicast algorithm or specify your own ip's. We've tried it in a LAN environment and it works pretty well. Performance wise it's not bad but the monitoring tool didn't work very well as it failed to update most of the time. If you can live with the current issues then by all mean go for it. I would use it with caution but it's a great working tool IMHO.
Update: We've been using Hazelcast for a few months now and it's working very well. The settings are relatively easy to set up and with the new updates, are comprehensive enough to customize even small things like the number of threads allowed in read/write operations.
We are using Hazelcast (22.214.171.124 now) in production integrated with a complicated transactional service. It was added to alleviate immediate database throughput issues. We have discovered that we frequently have to stop it bringing down all transaction services for at least an hour. We are running clients in superclient mode because it is the only option that even remotely meets our performance requirements (about 4 times faster than native clients.) Unfortunately stopping a superclient node causes split brain issues and causes the grid to lose records, forcing a complete shutdown of services. We have been trying to make this product work for us for almost a full year now, and even paid to have 2 hazelcast reps flown in to help. They were unable to produce a solution, but were able to let us know that we were probably doing it wrong. In their opinion it should work better but it was pretty much a wasted trip.
At this point we are on the hook for over 6 figures per year in licensing fees and we are currently using about 5 times the resources to keep the grid alive and meet our performance needs than we would be using with a clustered and optimized database stack. This was absolutely the wrong decision for us.
This product is killing us off. Use with caution, sparingly, and only for simple services.
If my own company and projects count as real world, here's my experience. I wanted to get as close to eliminating external (disk) storage in favor of limitless and persistent "RAM". For starters that eliminates CRUD plumbing which sometimes makes up to 90% of the so-called "middle tier". There are other benefits. Since RAM is your "database" you don't need any complex caches or HTTP session replication (which in turn eliminates ugly sticky session technique).
I believe RAM is the future and Hazelcast has everything to be an in-memory database: queries, transactions, etc. So I wrote a mini-framework abstracting it: to load data from the persistent storage (I can plugin anything that can store BLOBs - the fastest turned out to be MySQL). It is too long to explain why I didn't like Hazelcast's built-in persistence support. It's rather generic and rudimentary. They should remove it. It is not rocket science to implement your own distributed and optimized write-behind and write-through. Took me a week.
Everything was fine until I started performance-testing. Queries are slow - after all of the optimizations I did: indexes, Portable serialization, explicit comparators, etc. A simple "greater than" query on an indexed field takes 30 seconds on the set of 60K of 1K records (map entries). I believe Hazelcast team did everything they could. As much as I hate to say it, Java collections are still slow compared to super-optimized C++ code normal databases use. There are some open-source Java projects that address that. However at this time query persistence is unacceptable. It should be instant on a single local instance. It is an in-memory technology after all.
I switched to Mongo for the database, however left Hazelcast for shared runtime data - namely sessions. Once they improve query performance I'll switch back.
We use Hazelcast in our e-commerce application to make sure that our inventory is consistent.
We use extensive use of distributed locking to make sure SKU Items of inventory are modified in atomic way because there are hundred of nodes in our web application cluster that operates concurrently on these items.
Also, we use distributed map for caching purpose which are shared across all the nodes. Since scaling node in Hazelcast is so simple and it utilises all its CPU core, it gives added advantage over redis or any other caching framework.
We are using Hazelcast from last 3 years in our e-commerce application to make sure availability (supply & demand) is consistent, atomic, available & scalable. We are using IMap (distributed map) to cache the data and Entry Processor for read & write operations to do fast in-memory operations on IMap without you having to worry about locks.