墙外通道:http://thinkiii.blogspot.com/2014/02/arm64-linux-kernel-virtual-address-space.html
Now let's talk about the Linux kernel virtual address space on 64-bit ARM CPU. You can find information about ARMv8 in ARM official website. http://www.arm.com/products/processors/armv8-architecture.php
Actually 2^64 is too large, so in the Linux kernel implementation, only part of 64 bits are used (42 bits for CONFIG_ARM64_64K_PAGES, 39 bit for 4K page). This article is assuming 4K page is used (VA_BITS = 39 case)
#ifdef CONFIG_ARM64_64K_PAGES #define VA_BITS (42) #else #define VA_BITS (39) #endif
All user virtual addresses have 25 leading zeros and kernel addresses have 25 leading ones. Address between user space and kernel space are not used and they are used to trap illegal accesses.
ARM64 Linux virtual address space layout
kernel:
Although we have no ARM64 environment now, we can analysis the kernel virtual address space by reading the source code and observing a running AMD64 Linux box.
In arch/arm64/include/asm/memory.h, we can see the some differences: we have no lowmem zone, since the virtual address is so big that we can treat all memory of lowmem and do not have to worry about virtual address. (Yes, there is still a limit of kernel virtual address). Second, the order of different kernel virtual address changes:
#ifdef CONFIG_ARM64_64K_PAGES #define VA_BITS (42) #else #define VA_BITS (39) #endif #define PAGE_OFFSET (UL(0xffffffffffffffff) << (VA_BITS - 1)) #define MODULES_END (PAGE_OFFSET) #define MODULES_VADDR (MODULES_END - SZ_64M) #define EARLYCON_IOBASE (MODULES_VADDR - SZ_4M)
pr_notice("Virtual kernel memory layout:\n" " vmalloc : 0x%16lx - 0x%16lx (%6ld MB)\n" #ifdef CONFIG_SPARSEMEM_VMEMMAP " vmemmap : 0x%16lx - 0x%16lx (%6ld MB)\n" #endif " modules : 0x%16lx - 0x%16lx (%6ld MB)\n" " memory : 0x%16lx - 0x%16lx (%6ld MB)\n" " .init : 0x%p" " - 0x%p" " (%6ld kB)\n" " .text : 0x%p" " - 0x%p" " (%6ld kB)\n" " .data : 0x%p" " - 0x%p" " (%6ld kB)\n", MLM(VMALLOC_START, VMALLOC_END), #ifdef CONFIG_SPARSEMEM_VMEMMAP MLM((unsigned long)virt_to_page(PAGE_OFFSET), (unsigned long)virt_to_page(high_memory)), #endif MLM(MODULES_VADDR, MODULES_END), MLM(PAGE_OFFSET, (unsigned long)high_memory), MLK_ROUNDUP(__init_begin, __init_end), MLK_ROUNDUP(_text, _etext), MLK_ROUNDUP(_sdata, _edata));
see also:
arch/arm64/mm/init.c
arch/arm64/include/asm/pgtable.h
You can see that there is no pkmap or fixmap, it's because the kernel is assuming every memory has a valid kernel virtual address and there's no need to create pkmap/fixmap.
ARM64 kernel virtual address space layout
One interesting topic is that ARM claims the ARMv8 is compatible with ARM 32-bit applications, all 32-bit applications can run on ARMv8 without modification.How does the 32-bit application virtual memory layout look like on a 64-bit kernel?
Actually, all process on 64-bit kernel is a 64-bit process. To run ARM 32-bit applications, Linux kernel still create a process from a 64-bit init process, but limit the user address space to 4GB. In this way, we can have both 32-bit and 64-bit application on a 64-bit Linux kernel.
#ifdef CONFIG_COMPAT #define TASK_SIZE_32 UL(0x100000000) #define TASK_SIZE (test_thread_flag(TIF_32BIT) ? \ TASK_SIZE_32 : TASK_SIZE_64) #else #define TASK_SIZE TASK_SIZE_64 #endif /* CONFIG_COMPAT */
64-bit ARM applications on 64-bit Linux kernel
ARM64 64-bit user space program virtual address space layout
32-bit ARM applications on 64-bit Linux kernel
ARM64 32-bit user space program virtual address space layout
Note that the 32-bit application still have a 512GB kernel virtual address space and do not share it's own 4GB of virtual address space with kernel, the user applications have a complete 4GB of virtual address. On the other hand, 32-bit applications on 32-bit kernel have only 3GB of virtual address space.