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I was reading about how OS works with interrupts to communicate with hardware, just wondering, if there is any other architecture other than Interrupt driven? In Robert Love's book for Linux kernel, he says that most of the architecture that Linux handles are Interrupt driven, so what are the other ones? Can some one give examples? Thanks.

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i suppose polling based architectures, ie we check external stimuli after we've finished some work on the last stimulus –  Luke McGregor Sep 29 '12 at 1:18
Polling, message passing are the only two that I can think of, and I'm not sure that message passing isn't a subset of interrupt-driving at some point. –  siride Sep 29 '12 at 1:20

4 Answers 4

up vote 3 down vote accepted

The short answer to your question is that there's only one other model and that's polling. In a polling model, the system repeatedly asks the hardware if anything has happened. The downside to this model is that the CPU is always busy asking and can only know about activity if it's asking for it. If it starts doing something else, it could miss an action (since it wasn't asking for activity at the time of the action).

The longer answer:

If you think about it, there can really only be two possible systems: polling (pull) and event-driven (push). In the former, you ask the hardware if anything's happened, and in the latter, the hardware tells you. Put another way: the agency in the former is with the CPU/OS, and in the latter, it's with the hardware. Since there are two parties, and each party can be doing one of two things, that means that we can only have two types of systems (push/interrupt and pull/polling), plus a hybrid (both interrupt-driven and polling based at different times or in different contexts).

One could imagine a variety of ways to implement any of the three systems, and one could count those as distinct models, even if, under the hood, they are really implementing one of the possible systems. I would imagine that's not really what you're looking for, though.

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spot on........ –  howtechstuffworks Sep 29 '12 at 1:38

At a low level, polling is the main alternative. However, architecturally, main approaches are monolithic, where interrupts directly drive the device drivers and micro-kernel, where the device drivers may be separate processes that get informed by the kernel when hardware events happen. Interrupts sill happen but they are managed by a very small kernel. I suspect this is the difference your quote is referring to. Polling is not very common any more. One of the best known micro kernel based OS is Minix because it is used for teaching.

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I'm guessing, its some hard real-time systems, where instead of using asynchronous interrupts, the system checks (polls) the state of I/O devices at well-defined times (could be periodic). If a device isn't ready or is in an unexpected state, the system reports a failure.

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wont that take performance or lag(if periodic) or both??? are they still in implementation? –  howtechstuffworks Sep 29 '12 at 1:24
@howtechstuffworks Depends on your target application sometimes polling can be much faster ie if you just want to synchronously process a queue (and thats all you want to do on your hardware) its way faster/simpler to poll than to get interrupted half way through processing with a new item –  Luke McGregor Sep 29 '12 at 1:26
@howtechstuffworks These systems are normally well designed to meet specific goals, not just be abstractly fast or have an arbitrarily small latency on average. They are still being made. –  Alexey Frunze Sep 29 '12 at 1:28
An example of polling that's usually okay is the spinlock, which is used in MP OSes when the code knows that the wait will be short and doesn't want to risk using a more expensive synchronization primitive. –  siride Sep 29 '12 at 1:28

I equate polling architecture to a deterministic process orientation, and interrupt driven to a random process orientation. Neither one is better on their own merits, and both are needed in general. It depends on the external tasks and interfaces. Often systems will have to permit the interaction of many processes and it is beneficial to plan the architecture to partition randomness in the context of processes than may meet requirements while experiencing random service constraints from those that must be serviced on a regular basis with no randomness. Poor design has certain timing constraint oriented services being violated randomly leaving no software level resolution to functional dilemmas. Random processes are modeled with additional complexity using discrete-event simulation modeling, while deterministic process orientation can be analyzed much more simply with continuous functions.

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