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I'm learning reactive programming techniques, with async I/O etc, and I just can't find decent authoritative comparative data about the benefits of not switching threads.

Apparently switching threads is "expensive" compared to computations. But what scale are we talking on?

The essential question is "How many processor cycles/instructions does it take to switch a java thread?" (I'm expecting a range)

Is it affected by OS? I presume it's affected by number of threads, which is why async IO is so much better than blocking - the more threads, the further away the context has to be stored (presumably even out of the cache into main memory).

I've seen Approximate timings for various operations which although it's (way) out of date, is probably still useful for relating processor cycles (network would likely take more "instructions", SSD disk probably less).

I understand that reactive applications enable web apps to go from 1000's to 10,000's requests per second (per server), but that's hard to tell too - comments welcome

NOTE - I know this is a bit of a vague, useless, fluffy question at the moment because I have little idea on the inputs that would affect the speed of a context switch. Perhaps statistical answers would help - as an example I'd guess >=60% of threads would take between 100-10000 processor cycles to switch.

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y not make a measurement yourself, and share it with us? it will be useful! – Rugal Jan 9 '14 at 6:14
Because benchmarking is fraught with difficulties. Even though I know that if I don't use Google caliper I'm going to mess it up completely, I would think thread switching is very hard to specify. I'm looking for typical values of applications (primarly web I guess) which is not easy to set up. To benchmark usefully, I would need to know the dimensions that affect performance, and I can only guess at # of local references, # of registers, cache size, thread count, locks, shared variables etc. – Stephen Jan 9 '14 at 6:22

1 Answer 1

Rugal has a point. In modern architectures theoretical turn-around times are usually far off from actual measurements because the hardware, as well as the software have become so much more complex. It also inherently depends on your application. Many web-applications for example are I/O-bound where the context switch time matters a lot less.

Also note that context switching (what you refer to as thread switching) is an OS thing and not a Java thing. There is no guarantee as to how "heavy" a context switch in your OS is. It used to take tens if not hundreds of thousands of CPU cycles to do a kernel-level switch, but there are also user-level switches, as well as experimental systems, where even kernel-level switches can take only a few hundred cycles.

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That's a good start! I'm specifically using "java thread" for it's terminology since that's the platform I'm on. I understand it's (historically) faster than process switching, but does it completely equate to a context switch? It seems to me that your second paragraph says that "java thread context switch" is indeed a good restriction instead of "general context switch" – Stephen Jan 9 '14 at 6:35
@Stephen Java simply offers a high level API to the low-level system threads. If you look at JVM source code, you will most probably find that the Thread class simply calls the underlying sys calls. That is pthreads on *nix and its corresponding counter part on Windows. – Domi Jan 9 '14 at 6:45
Ah yes - that's terminology I recognize (from years back ;)) – Stephen Jan 9 '14 at 6:57

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