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view src/mmu.h @ 280:21a5761e3e7a
mv_extraction_dg_compile_sources Context2Util
| author | anatofuz <anatofuz@cr.ie.u-ryukyu.ac.jp> |
|---|---|
| date | Tue, 28 Jan 2020 15:20:34 +0900 |
| parents | 83c23a36980d |
| children |
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// Definition for ARM MMU #ifndef MMU_INCLUDE #define MMU_INCLUDE // align_up/down: al must be of power of 2 #define align_up(sz, al) (((uint)(sz)+ (uint)(al)-1) & ~((uint)(al)-1)) #define align_dn(sz, al) ((uint)(sz) & ~((uint)(al)-1)) // // Since ARMv6, you may use two page tables, one for kernel pages (TTBR1), // and one for user pages (TTBR0). We use this architecture. Memory address // lower than UVIR_BITS^2 is translated by TTBR0, while higher memory is // translated by TTBR1. // Kernel pages are create statically during system initialization. It use // 1MB page mapping. User pages use 4K pages. // // access permission for page directory/page table entries. #define AP_NA 0x00 // no access #define AP_KO 0x01 // privilaged access, kernel: RW, user: no access #define AP_KUR 0x02 // no write access from user, read allowed #define AP_KU 0x03 // full access // domain definition for page table entries #define DM_NA 0x00 // any access causing a domain fault #define DM_CLIENT 0x01 // any access checked against TLB (page table) #define DM_RESRVED 0x02 // reserved #define DM_MANAGER 0x03 // no access check #define PE_CACHE (1 << 3)// cachable #define PE_BUF (1 << 2)// bufferable #define PE_TYPES 0x03 // mask for page type #define KPDE_TYPE 0x02 // use "section" type for kernel page directory #define UPDE_TYPE 0x01 // use "coarse page table" for user page directory #define PTE_TYPE 0x02 // executable user page(subpage disable) // 1st-level or large (1MB) page directory (always maps 1MB memory) #define PDE_SHIFT 20 // shift how many bits to get PDE index #define PDE_SZ (1 << PDE_SHIFT) #define PDE_MASK (PDE_SZ - 1) // offset for page directory entries #define PDE_IDX(v) ((uint)(v) >> PDE_SHIFT) // index for page table entry // 2nd-level page table #define PTE_SHIFT 12 // shift how many bits to get PTE index #define PTE_IDX(v) (((uint)(v) >> PTE_SHIFT) & (NUM_PTE - 1)) #define PTE_SZ (1 << PTE_SHIFT) #define PTE_ADDR(v) align_dn (v, PTE_SZ) #define PTE_AP(pte) (((pte) >> 4) & 0x03) // size of two-level page tables #define UADDR_BITS 28 // maximum user-application memory, 256MB #define UADDR_SZ (1 << UADDR_BITS) // maximum user address space size // must have NUM_UPDE == NUM_PTE #define NUM_UPDE (1 << (UADDR_BITS - PDE_SHIFT)) // # of PDE for user space #define NUM_PTE (1 << (PDE_SHIFT - PTE_SHIFT)) // how many PTE in a PT #define PT_SZ (NUM_PTE << 2) // user page table size (1K) #define PT_ADDR(v) align_dn(v, PT_SZ) // physical address of the PT #define PT_ORDER 10 #endif