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my understanding is that user task can access both 3G of user space and 1G of kernel space. But kernel task can only access its only 1G kernel space. But in task_struct, it links to vm_area_struct which points to user space, am I right? If right, then this means kernel task can also access user space directly?

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2 Answers 2

User task can access the only low 3G of user space(the areas which is mapped), The kernel can access all 3G+1G space. The kernel don't directly access to the user space address, it uses copy_from(to)_user() APIs.

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It should be noted that those limits only apply to 32-bit applications... –  thkala Jul 27 '12 at 9:09
@thkala you are right, thanks. –  Lai Jiangshan Jul 27 '12 at 9:22
But the kernel struct does not access the user space directly. So my question is how it handles its vm_area_struct which should links to user space? –  Tom Xue Jul 27 '12 at 11:21
up vote 0 down vote accepted

Below is from Robert Love's LKD3: The mm_struct and Kernel Threads (P309)

Kernel threads do not have a process address space and therefore do not have an associ- ated memory descriptor.Thus, the mm field of a kernel thread’s process descriptor is NULL . This is the definition of a kernel thread—processes that have no user context.

This lack of an address space is fine because kernel threads do not ever access any user- space memory. (Whose would they access?) Because kernel threads do not have any pages in user-space, they do not deserve their own memory descriptor and page tables. (Page tables are discussed later in the chapter.) Despite this, kernel threads need some of the data, such as the page tables, even to access kernel memory.To provide kernel threads the needed data, without wasting memory on a memory descriptor and page tables, or wast- ing processor cycles to switch to a new address space whenever a kernel thread begins running, kernel threads use the memory descriptor of whatever task ran previously.

Whenever a process is scheduled, the process address space referenced by the process’s mm field is loaded.The active_mm field in the process descriptor is then updated to refer to the new address space. Kernel threads do not have an address space and mm is NULL . Therefore, when a kernel thread is scheduled, the kernel notices that mm is NULL and keeps the previous process’s address space loaded.The kernel then updates the active_mm field of the kernel thread’s process descriptor to refer to the previous process’s memory descriptor.The kernel thread can then use the previous process’s page tables as needed. Because kernel threads do not access user-space memory, they make use of only the information in the address space pertaining to kernel memory, which is the same for all processes.

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