I developed a server for a custom protocol based on tcp/ip-stack with Netty. Writing this was a pleasure.
Right now I am testing performance. I wrote a test-application on netty that simply connects lots (20.000+) of "clients" to the server (for-loop with Thread.wait(1) after each bootstrap-connect). As soon as a client-channel is connected it sends a login-request to the server, that checks the account and sends a login-response.
The overall performance seems to be quite OK. All clients are logged in below 60s. But what's not so good is the spread waiting time per connections. I have extremely fast logins and extremely slow logins. Variing from 9ms to 40.000ms spread over the whole test-time. Is it somehow possible to share waiting time among the requesting channels (Fifo)?
I measured a lot of significant timestamps and found a strange phenomenon. I have a lot of connections where the server's timestamp of "channel-connected" is way after the client's timestamp (up to 19 seconds). I also do have the "normal" case, where they match and just the time between client-sending and server-reception is several seconds. And there are cases of everything in between those two cases. How can it be, that client and server "channel-connected" are so much time away from each other?
What is for sure is, that the client immediatly receives the server's login-response after it has been send.
Tuning: I think I read most of the performance-articles around here. I am using the OrderMemoryAwareThreadPool with 200 Threads on a 4CPU-Hyper-Threading-i7 for the incoming connections and also do start the server-application with the known aggressive-options. I also completely tweaked my Win7-TCP-Stack. The server runs very smooth on my machine. CPU-usage and memory consumption is ca. at 50% from what could be used.
Too much information: I also started 2 of my test-apps from 2 seperate machines "attacking" the server in parallel with 15.000 connections each. There I had about 800 connections that got a timeout from the server. Any comments here?
Best regards and cheers to Netty, Martin