10213903403
/
os_kernel_lab


								#ifndef __KERN_MM_PMM_H__

								#define __KERN_MM_PMM_H__


								#include <defs.h>

								#include <mmu.h>

								#include <memlayout.h>

								#include <atomic.h>

								#include <assert.h>


								// pmm_manager is a physical memory management class. A special pmm manager - XXX_pmm_manager

								// only needs to implement the methods in pmm_manager class, then XXX_pmm_manager can be used

								// by ucore to manage the total physical memory space.

								struct pmm_manager {

								    const char *name;                                 // XXX_pmm_manager's name

								    void (*init)(void);                               // initialize internal description&management data structure

								                                                      // (free block list, number of free block) of XXX_pmm_manager

								    void (*init_memmap)(struct Page *base, size_t n); // setup description&management data structcure according to

								                                                      // the initial free physical memory space

								    struct Page *(*alloc_pages)(size_t n);            // allocate >=n pages, depend on the allocation algorithm

								    void (*free_pages)(struct Page *base, size_t n);  // free >=n pages with "base" addr of Page descriptor structures(memlayout.h)

								    size_t (*nr_free_pages)(void);                    // return the number of free pages

								    void (*check)(void);                              // check the correctness of XXX_pmm_manager

								};


								extern const struct pmm_manager *pmm_manager;

								extern pde_t *boot_pgdir;

								extern uintptr_t boot_cr3;


								void pmm_init(void);


								struct Page *alloc_pages(size_t n);

								void free_pages(struct Page *base, size_t n);

								size_t nr_free_pages(void);


								#define alloc_page() alloc_pages(1)

								#define free_page(page) free_pages(page, 1)


								pte_t *get_pte(pde_t *pgdir, uintptr_t la, bool create);

								struct Page *get_page(pde_t *pgdir, uintptr_t la, pte_t **ptep_store);

								void page_remove(pde_t *pgdir, uintptr_t la);

								int page_insert(pde_t *pgdir, struct Page *page, uintptr_t la, uint32_t perm);


								void load_esp0(uintptr_t esp0);

								void tlb_invalidate(pde_t *pgdir, uintptr_t la);

								struct Page *pgdir_alloc_page(pde_t *pgdir, uintptr_t la, uint32_t perm);


								void print_pgdir(void);


								/* *

								 * PADDR - takes a kernel virtual address (an address that points above KERNBASE),

								 * where the machine's maximum 256MB of physical memory is mapped and returns the

								 * corresponding physical address.  It panics if you pass it a non-kernel virtual address.

								 * */

								#define PADDR(kva) ({                                                   \

								            uintptr_t __m_kva = (uintptr_t)(kva);                       \

								            if (__m_kva < KERNBASE) {                                   \

								                panic("PADDR called with invalid kva %08lx", __m_kva);  \

								            }                                                           \

								            __m_kva - KERNBASE;                                         \

								        })


								/* *

								 * KADDR - takes a physical address and returns the corresponding kernel virtual

								 * address. It panics if you pass an invalid physical address.

								 * */

								#define KADDR(pa) ({                                                    \

								            uintptr_t __m_pa = (pa);                                    \

								            size_t __m_ppn = PPN(__m_pa);                               \

								            if (__m_ppn >= npage) {                                     \

								                panic("KADDR called with invalid pa %08lx", __m_pa);    \

								            }                                                           \

								            (void *) (__m_pa + KERNBASE);                               \

								        })


								extern struct Page *pages;

								extern size_t npage;


								static inline ppn_t

								page2ppn(struct Page *page) {

								    return page - pages;

								}


								static inline uintptr_t

								page2pa(struct Page *page) {

								    return page2ppn(page) << PGSHIFT;

								}


								static inline struct Page *

								pa2page(uintptr_t pa) {

								    if (PPN(pa) >= npage) {

								        panic("pa2page called with invalid pa");

								    }

								    return &pages[PPN(pa)];

								}


								static inline void *

								page2kva(struct Page *page) {

								    return KADDR(page2pa(page));

								}


								static inline struct Page *

								kva2page(void *kva) {

								    return pa2page(PADDR(kva));

								}


								static inline struct Page *

								pte2page(pte_t pte) {

								    if (!(pte & PTE_P)) {

								        panic("pte2page called with invalid pte");

								    }

								    return pa2page(PTE_ADDR(pte));

								}


								static inline struct Page *

								pde2page(pde_t pde) {

								    return pa2page(PDE_ADDR(pde));

								}


								static inline int

								page_ref(struct Page *page) {

								    return page->ref;

								}


								static inline void

								set_page_ref(struct Page *page, int val) {

								    page->ref = val;

								}


								static inline int

								page_ref_inc(struct Page *page) {

								    page->ref += 1;

								    return page->ref;

								}


								static inline int

								page_ref_dec(struct Page *page) {

								    page->ref -= 1;

								    return page->ref;

								}


								extern char bootstack[], bootstacktop[];


								extern void * kmalloc(size_t n);

								extern void kfree(void *ptr, size_t n);

								#endif /* !__KERN_MM_PMM_H__ */