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We have been working very hard to try come up with solutions for a "High Performance" application. The application is basically a high throughput in-memory manager, with a sync back to disk. The "reads" and "writes" are tremendously high, around 3000 transactions a second. We try and do as much as possible in memory, but eventually the data gets stale and needs to be flushed to disk, and this is where a huge "bottleneck" ensues. The app is multi-threaded, with about 50 threads. There is no IPC (inter-process comms)


We initially wrote this in Java, and it worked quite well, up until a certain load, the bottleneck was hit and it just couldn't keep up. Then we tried it in C#, and the same bottle-neck was reached. We tried this with unmanaged code (C#), and though on initial tests was blindingly fast using MMF (Memory-map files), in production, reading was slow (are using Views). We did try CouchBase, but we stumbled into problems surround high network utilization. This might be poor configuration on our part!

Extra Info: In our Java attempt (non-MMF), our thread with the Queue of information that needs to get flushed to disk builds to the extent of being unable to keep up "writing" to disk. In our C# Memory-Map File Approach, the problems is that READS are very slow, and the WRITES working perfectly. For some reason, the Views are slow!


So the question is, situations where you intend of transferring massive amounts of data; can someone please assist with a possible approach or architectural design that might be able to assist? I know this seems a bit broad, but I think the specific nature of high performance, high throughput should narrow down the answers.

Can anyone vouch for using Couchbase, MongoDB or Cassandra at such a level? Other ideas or solutions would be appreciated.

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I am not sure, but I think writing data in other thread to disk when when certain limit reached (but not huge number, for example a quarter of what you are using now) while keep reading data can help. Then you can free this memory and begin writing others. I don't really know the answer I just think that it can help –  Adil Mammadov Aug 17 '12 at 6:58
Not sure if it fits to your data transferring issue but there was a software design shown in a paper of the University of California. "SEDA: An Architecture for Well-Conditioned, Scalable Internet Services". ACM ISBN 1-58113-389-8-1/01/10. It talks about how to obtain high throughput in a multithreaded/-staged system. –  coding.mof Aug 17 '12 at 6:58
Adil, thanks we are doing that. Coding.mof will check out the paper, much appreciated. –  Dane Balia Aug 17 '12 at 7:02
How are you sharding the data among disks? Also, I can't personally vouch for how Mongo performs under such high loads, but they seem to place a lot of emphasis on speed and provide a lot of facilities for trying to distribute read/write load among several servers/disks. –  Keith Ripley Aug 17 '12 at 7:06
You say you've tried Java/C#/Unmanaged C# and everything was slow. Sounds like the architecture and dev environment are not the issue here, rather you are simply trying to just do too much on your current hardware. You need some serious power here, and I would advise spending some money on some serious hardware. –  Simon Aug 17 '12 at 7:13

3 Answers 3

up vote 2 down vote accepted

Massive amounts of data and disk access. What kind of disk are we talking about? HDDs tend to spend a lot of time moving the head around if you work with more than one file. (That shouldn't be a problem if you use SSDs, though.) Also, you should take advantage of the fact that memory-mapped files are managed in page-sized chunks. Data structures should be aligned to page boundaries, if possible.

But in any case, you must make sure you know what the bottleneck is. Optimizing data structures wouldn't help much if you actually lose the time due to thread synchronization, for example. And if you're using a HDD, page alignment might not help as much as stuffing everything into a single file somehow. So use appropriate tools to figure out which brakes are still holding you back.

Using a general-purpose database implementation might not help you as much as you hope. They are, after all, general-purpose. If performance really is that much of an issue, a special implementation with your requirements in mind might outperform these more general implementations.

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Such a profiling tool e.g. for Java is JProfiler –  coding.mof Aug 17 '12 at 7:03
Hi Wormbo, thanks. Good tips; I researched the SSD route previously, but unfortunately because of the "cell" problems of limit reads and writes despite updated algorithms to prevent this by hardware manufacturers; our processing rate will kill the disk in a short period. Can you elaborate on "Data structure aligning to page boundaries"? why is that beneficial? –  Dane Balia Aug 17 '12 at 7:08
coding.mof, yip done the profiling thing, using IBM products as well as Microsofts. Thanks –  Dane Balia Aug 17 '12 at 7:09
@DaneBalia: You might like to share what you discovered with your profiling. –  jgauffin Aug 17 '12 at 7:35
Wormbo hit the nail on the head when he said "make sure you know what the bottleneck is". The bottleneck according to our profiling revealed problems first with "jvm not releasing memory". Upon further expectation we noticed it was Queues not releasing objects, which points straight back at the disk being unable to keep up (I/O). –  Dane Balia Aug 17 '12 at 7:49

First off, I would like to make clear that I have little (if any) experience building high-performance, scalable applications..

Martin Fowler has a description of the LMAX architecture that allowed an application to process about 6 million orders per second on a single thread. I'm not sure it can help you (as you seemingly need to move alot of data), but maybe you can get some ideas from it: http://martinfowler.com/articles/lmax.html

The architecture is based on Event Sourcing which is often used to provide (relatively) easy scalability.

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Tx, will check out –  Dane Balia Aug 17 '12 at 8:48
That looks promising, takes a bit of time to kind of get the "concept". But will see if we can get something out from the Disruptor pattern. –  Dane Balia Aug 17 '12 at 9:24
Yeah this doesn't really solve our problem. Disruptor pattern focuses more on when there is alot of work (steps of work) to be done, and that contention between work (for example, that found in Queue). Our problem is in a Queue that is stand-alone and unable to write efficiently to disk, without the Queue reaching an unmanageable size. –  Dane Balia Aug 17 '12 at 10:23

If you want fast avoid persistence and queues as much as possible for writes and use memory sores/ caching on reads.

Language has little to do with it.\

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Not sure on the down vote .. languages generally vary by about 10-30% ( some by 50% ). But IO to disk is like 10K slower than memory.. Look at Lmax minimize IO and do 6M transactions / second on a single machine . Same goes for common usage use a persistent queue and i guarantee your throughput will reduce by at least a factor of 10. And you have the horrible manual maintenance of dead letter queues. Now look at the language figures compared to persistent costs.. That does not mean you dont have persistent but minimizing it helps.. –  user1496062 Nov 3 '12 at 5:03

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