In practice, many operating systems are designed to have one kernel stack for each thread, or at least one for each CPU. But for an operating system that the kernel is locked every time a process traps, it seems unnecessary to have separated kernel stacks for each CPU. Since the kernel (with its own stack) only allows single CPU access, the CPUs should never be in kernel mode simultaneously. A CPU is always blocked until the previous CPU leaves and cleans up the kernel stack, even in the nested trap case. So in which case will multiple kernel stack be necessary in such an OS? Thanks.
closed as off topic by Krister Andersson, Linger, kazanaki, EdChum, RaYell Dec 21 '12 at 10:50
Questions on Stack Overflow are expected to relate to programming within the scope defined by the community. Consider editing the question or leaving comments for improvement if you believe the question can be reworded to fit within the scope. Read more about reopening questions here.If this question can be reworded to fit the rules in the help center, please edit the question.
You're right; in such a case multiple kernel stacks wouldn't be useful as long as you have a solid multi-core locking feature.
We usually have multiple kernel stacks (i.e. at least one kernel stack for each thread) for the following purposes:
In practice, many operating systems do not restrict the number of threads running kernel-level code. In fact, placing this restriction would seriously limit the scalability of the kernel. Without this restriction, multiple kernel stacks are required.
Furthermore, in practice, operating systems may permit the preemption and migration of threads that are currently executing in kernel-mode, which again ties the kernel stack to the thread and not the processor.
If you are designing an operating system that does not have these features, and instead restricts kernel-level execution to a single thread, then a single stack would be all that is required.