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I was just reading up on how linux works in my OS-book when I came across this..

[...] the kernel is created as a single, monolitic binary. The main reason is to improve performance. Because all kernel code and data structures are kept in a single address space, no context switches are necessary when a process calls an operating-system function or when a hardware interrup is delivered.

That sounded quite amazing to me, surely it must store the process's context before running off into kernel mode to handle an interrupt.. But ok, I'll buy it for now. A few pages on, while describing a process's scheduling context, it said:

Both system calls and interrups that occur while the process is executing will use this stack.

"this stack" being the place where the kernel stores the process's registers and such.

Isn't this a direct contradiction to the first quote? Am I missinterpreting it somehow?

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up vote 2 down vote accepted

I think the first quote is referring to the differences between a monolithic kernel and a microkernel.

Linux being monolithic, all its kernel components (device drivers, scheduler, VM manager) run at ring 0. Therefore, no context switch is necessary when performing system calls and handling interrupts.

Contrast microkernels, where components like device drivers and IPC providers run in user space, outside of ring 0. Therefore, this architecture requires additional context switches when performing system calls (because the performing module might reside in user space) and handling interrupts (to relay the interrupts to the device drivers).

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Thank you. It's been a long time since I studied this, but I was under the impression that hardware interrupts actually interrupts the execution and jumps immediately to the handling procedure rather than polling for interrupts later on. I figured that if the process was executing in kernel mode it would still need to store its context before that jump, but perhaps that was my mistake? I suppose now that would be no different from any other method call if the called method handles the used registers correctly.. did I get it right? – user1130005 Jan 16 '12 at 10:57
My understanding is that process is running in user mode, and there's indeed a context switch to kernel mode before the interrupt is handled. However, handling the interrupt does not require an additional context switch in monolithic kernels, but does in microkernels (since device drivers reside in user space). – Frédéric Hamidi Jan 16 '12 at 11:07

"Context switch" could mean one of a couple of things, both relevant: (1) switching from user to kernel mode to process the system call, or an involuntary switch to kernel mode to process an interrupt against the interrupt stack, or (2) switching to run another user process in user space, with a jump to kernel space in between the two.

Any movement from user space to kernel space implies saving enough user-space to return to it reliably. If the kernel-space code decides that - while you're no longer running the user-code for that process - it's time to let another user-process run, it gets in.

So at the least, you're talking 2-3 stacks or places to store a "context": hardware-interrupts need a kernel-level stack to say what to return to; user method/subroutine calls use a standard stack for getting that done. Etc.

The original Unix kernels - and the model isn't that different now for this part - ran the system calls like a short-order cook processing breakfast orders: move this over on the stove to make room for the order of bacon that just arrived, start the bacon, go back to the first order. All in kernel switching context. Was not a huge monitoring application, which probably drove the IBM and DEC software folks mad.

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