I came up with this question because I don't understand how address translation is carried out in kernel area.
From what I understand, to translate any address above
0xC0000000, we just need to minus this address with
PAGE_OFFSET (except the kernel initializing process, where we need a page table for 8MB range). But this does not make sense where CPU executes an instruction that requires address at, say
0xF0000020, while the system only have a 256MB RAM.
For the above reason, I think the kernel indeed has a page table which allows the MMU to translate virtual address above
0xC0000000 to physical. Thus, in what situation we can directly minus the
PAGE_OFFSET and in what situation we need the kernel page table?
I may get wrong at the beginning, so please correct.
From << Understanding the Linux Virtual Memory Manager >>, where it says kernel page table exists. Now, more confused...
3.6 Kernel Page Tables
When the system first starts, paging is not enabled because page tables do not magically initialize themselves. Each architecture implements this differently so only the x86 case will be discussed. The page table initialization is divided into two phases. The bootstrap phase sets up page tables for just 8MiB so that the paging unit can be enabled. The second phase initializes the rest of the page tables. We discuss both of these phases in the following sections.
The function responsible for finalizing the page tables is called paging_init(). The call graph for this function on the x86 can be seen on Figure 3.4.
The function first calls pagetable_init() to initialize the page tables necessary to reference all physical memory in ZONE_DMA and ZONE_NORMAL. Remember that high memory in ZONE_HIGHMEM cannot be directly referenced and that mappings are set up for it temporarily. For each pgd t used by the kernel, the boot memory allocator (see Chapter 5) is called to allocate a page for the PGD, and the PSE bit will be set if available to use 4MiB TLB entries instead of 4KiB. If the PSE bit is not supported, a page for PTEs will be allocated for each pmd t. If the CPU supports the PGE flag, it also will be set so that the page table entry will be global and visible to all processes.
Next, pagetable_init() calls fixrange_init() to set up the fixed address space mappings at the end of the virtual address space starting at FIXADDR_START. These mappings are used for purposes such as the local Advanced Programmable Interrupt Controller (APIC) and the atomic kmappings between FIX_KMAP_BEGIN and FIX_KMAP_END required by kmap_atomic(). Finally, the function calls fixrang_init() to initialize the page table entries required for normal high memory mappings with kmap().
After pagetable_init() returns, the page tables for kernel space are now fully initialized, so the static PGD (swapper_pg_dir) is loaded into the CR3 register so that the static table is now being used by the paging unit.
The next task of the paging_init() is responsible for calling kmap_init() to initialize each of the PTEs with the PAGE_KERNEL protection flags. The final task is to call zone_sizes_init(), which initializes all the zone structures used.