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I have been reading up on the threaded model of programming versus the asynchronous model from this really good article. http://krondo.com/blog/?p=1209

However, the article mentions the following points.

  1. An async program will simply outperform a sync program by switching between tasks whenever there is a I/O.
  2. Threads are managed by the operating system.

I remember reading that threads are managed by the operating system by moving around TCBs between the Ready-Queue and the Waiting-Queue(amongst other queues). In this case, threads don't waste time on waiting either do they?

In light of the above mentioned, what are the advantages of async programs over threaded programs?

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I think you mean synchronous vs asynchronous. – someguy Oct 26 '10 at 13:26
No, I meant Threaded vs. Async. I mentioned point one only because it was something I understood from the article. – uki Oct 26 '10 at 13:41
up vote 36 down vote accepted
  1. It is very difficult to write code that is thread safe. With asyncronous code you know exactly where the code will shift from one task to the next and race conditions are much therefore much harder to come by.
  2. Threads consume a fair amount of data since each thread needs to have its own stack; with async code all the code shares the same stack and the stack is kept small due to continuously unwinding the stack between tasks.
  3. Threads are OS structures and are therefore more memory for the platform to support. There is no such problem with asynchronous tasks.
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To elaborate a bit: 1. The I/O part of threaded code is relatively easy but managing the shared state between threads (using locks/queues/etc) without race conditions is what makes it tricky. Using an async model means you have less going on at the same time so races are easily avoided. 2/3. each thread will consume at least one memory page of stack (4KB or 8KB typically), plus some unknown amount of memory for other data structures related to that thread's state. – Dobes Vandermeer Jul 29 '13 at 16:47

First of all, note that a lot of the detail of how threads are implemented and scheduled are very OS-specific. In general, you shouldn't need to worry about threads waiting on each other, since the OS and the hardware will attempt to arrange for them to run efficiently, whether asynchronously on a single-processor system or in parallel on multi-processors.

Once a thread has finished waiting for something, say I/O, it can be thought of as runnable. Threads that are runnable will be scheduled for execution at some point soon. Whether this is implemented as a simple queue or something more sophisticated is, again, OS- and hardware-specific. You can think of the set of blocked threads as a set rather than as a strictly ordered queue.

Note that on a single-processor system, asynchronous programs as defined here are equivalent to threaded programs.

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see http://en.wikipedia.org/wiki/Thread_(computing)#I.2FO_and_scheduling

However, the use of blocking system calls in user threads (as opposed to kernel threads) or fibers can be problematic. If a user thread or a fiber performs a system call that blocks, the other user threads and fibers in the process are unable to run until the system call returns. A typical example of this problem is when performing I/O: most programs are written to perform I/O synchronously. When an I/O operation is initiated, a system call is made, and does not return until the I/O operation has been completed. In the intervening period, the entire process is "blocked" by the kernel and cannot run, which starves other user threads and fibers in the same process from executing.

According to this, your whole process might be blocked, and no thread will be scheduled when one thread is blocked in IO. I think this is os-specific, and will not always be hold.

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There are two ways to create threads:

synchronous threading - the parent creates one (or more) child threads and then must wait for each child to terminate. Synchronous threading is often referred to as the fork-join model.

asynchronous threading - the parent and child run concurrently/independently of one another. Multithreaded servers typically follow this model.

resource - http://www.amazon.com/Operating-System-Concepts-Abraham-Silberschatz/dp/0470128720

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Async I/O means there is already a thread in the driver that does the job, so you are duplicating functionality and incurring some overhead. On the other hand, often it is not documented how exactly the driver thread behaves, and in complex scenarios, when you want to control timeout/cancellation/start/stop behaviour, synchronization with other threads, it makes sense to implement your own thread. It is also sometimes easier to reason in sync terms.

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That's not how async I/O works at all. Fundamentally, I/O is event-driven (you initiate an I/O to a device, later, the device completes it and hopefully tells you so with an interrupt). There are some kinds of I/O (like disk I/O) where the driver uses a kernel thread for somewhat obscure reason; but for networks, it's async operations all the way down. – Glyph Apr 16 '13 at 20:46

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