Why do many people say I/O completion port is fast and nice model?
What is the I/O completion port's advantages and disadvantages?

I want to know some points which make faster IOCP than other model.

If you can explain it comparing other models(select, epoll, traditional multi thread/process), it would be better.


I/O completion ports are awesome. There's no better word to describe them. If anything in Windows was done right, it's completion ports.

You can create some number of threads (does not really matter how many) and make them all block on one completion port until an event (either one you post manually, or an event from a timer or asynchronous I/O, or whatever) arrives. Then the completion port will wake one thread to handle the event, up to the limit that you specified. If you didn't specify anything, it will assume "up to number of CPU cores", which is really nice.

If there are already more threads active than the maximum limit, it will wait until one of them is done and then hand the event to the thread as soon as it goes to wait state. Also, it will always wake threads in a LIFO order, so chances are that caches are still warm.

In other words, completion ports are a no-fuss "poll for events" as well as "fill CPU as much as you can" solution.

You can throw file reads and writes at a completion port, sockets, or anything else that's waitable. And, you can post your own events if you want. Each custom event has at least one integer and one pointer worth of data (if you use the default structure), but you are not really limited to that as the system will happily accept any other structure too.

Also, completion ports are fast, really really fast. Once upon a time, I needed to notify one thread from another. As it happened, that thread already had a completion port for file I/O, but it didn't pump messages. So, I wondered if I should just bite the bullet and use the completion port for simplicity, even though posting a thread message would obviously be much more efficient. I was undecided, so I benchmarked. Surprise, it turned out completion ports were about 3 times faster. So... faster and more flexible, the decision was not hard.

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    I/O wait in general is done extremely well in Windows, whether it's IOCP, overlapped with events, overlapped with completion routines, or waiting for all of the above simultaneously with a semaphore, completion of a child process, and UI messages. – Ben Voigt Mar 12 '11 at 18:48
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    One nice thing to know is that even with ReadFile/WriteFile you can extend the OVERLAPPED structure arbitrarily. Just embed it in a bigger struct and use CONTAINING_RECORD to retrieve your extra data. – Paolo Bonzini Sep 25 '12 at 13:17
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    "... until an event (either one you post manually, or an event from a timer or asynchronous I/O, or whatever) arrives." Are you sure you can poll a timer with IOCP? The answer to stackoverflow.com/questions/3239080 says otherwise. – Joey Adams Oct 25 '12 at 4:10
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    @Joey Adams: I was going to say "of course" and link to a working example that you can try for yourself, but embarrassingly enough that working example doesn't work. Which is twice embarrassing for me, because it means not only that the above statement about timers is wrong, but also I have to explain to my boss that I built shit into a software that shipped 6 months ago and didn't notice, and none in QA noticed either (this was to guarantee a deadline in case no events come in otherwise, it must have worked accidentially during QA because always enough other events were available). – Damon Oct 26 '12 at 9:27
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    @Damon: Thanks for the followups. Another option would be to pass a timeout to GetQueuedCompletionStatus. If your app needs to time things out in multiple places, you could use a priority queue to track expirations, and have a worker thread call GetQueuedCompletionStatus over and over with the most recent time. Wake the worker thread using PostQueuedCompletionStatus. – Joey Adams Nov 2 '12 at 1:27

by using IOCP, we can overcome the "one-thread-per-client" problem. It is commonly known that the performance decreases heavily if the software does not run on a true multiprocessor machine. Threads are system resources that are neither unlimited nor cheap.

IOCP provides a way to have a few (I/O worker) threads handle multiple clients' input/output "fairly". The threads are suspended, and don't use the CPU cycles until there is something to do.

Also you can read some information in this nice book http://www.amazon.com/Windows-System-Programming-Johnson-Hart/dp/0321256190

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    OVERLAPPED I/O overcomes "one-thread-per-client" very well thank you. What IOCP brings to the table is (as you have correctly mentioned) sharing the load between multiple threads. For most applications using OVERLAPPED I/O from a single thread is simpler and more efficient. Only high volume application servers should consider IOCP. – Ben Voigt Mar 12 '11 at 15:10
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    @Ben: To be honest, I find that IOCP programming leads to a more understandable programming style than you get using overlapped I/O. This is especially true if you've got multiple operations going on simultaneously (like you would when copying a file). – ReinstateMonica Larry Osterman Mar 12 '11 at 16:50
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    @Larry: I don't know how you handle overlapped I/O, but I use MsgWaitForMultipleObjectsEx and completion routines. Same state-machine programming style as IOCP and no need for thread synchronization. – Ben Voigt Mar 12 '11 at 18:27
  • @Ben Voigt +1 Fully agree with you it need only for high volume application servers – Sanja Melnichuk Mar 12 '11 at 18:40

I/O completion ports are provided by the O/S as an asynchronous I/O operation, which means that it occurs in the background (usually in hardware). The system does not waste any resources (e.g. threads) waiting for the I/O to complete. When the I/O is complete, the hardware sends an interrupt to the O/S, which then wakes up the relevant process/thread to handle the result. WRONG: IOCP does NOT require hardware support (see comments below)

Typically a single thread can wait on a large number of I/O completions while taking up very little resources when the I/O has not returned.

Other async models that are not based on I/O completion ports usually employ a thread pool and have threads wait for I/O to complete, thereby using more system resources.

The flip side is that I/O completion ports usually require hardware support, and so they are not generally applicable to all async scenarios.

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    What hardware support? I don't think IOCP mechanism is releated with hardware. – Benjamin Mar 12 '11 at 14:33
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    Async I/O does not use a thread pool, ever. Some widely-used frameworks have put a thread pool wrapper around synchronous I/O calls, but that isn't async I/O. – Ben Voigt Mar 12 '11 at 15:07
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    IOCP does not require hardware support. – Ana Betts Mar 13 '11 at 8:29
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    The phrasing here was bad, but the objections are similarly misleading. The point here is that hardware can perform operations (e.g. posting network buffers, etc) without the involvement of a userland thread. The program's thread need only wake after the hardware signals that an event of interest has occurred. – EricLaw Aug 21 '13 at 21:54
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    @0xC0000022L: If by "provided since Vista" you mean "still available since Vista" (but introduced long before). But no, it's not limited to the OS thread pool. Any thread pool that ends threads based on demand will break in-flight I/O. – Ben Voigt Oct 25 '18 at 15:15

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