2 * This file is part of the Palacios Virtual Machine Monitor developed
3 * by the V3VEE Project with funding from the United States National
4 * Science Foundation and the Department of Energy.
6 * The V3VEE Project is a joint project between Northwestern University
7 * and the University of New Mexico. You can find out more at
10 * Copyright (c) 2008, Jack Lange <jarusl@cs.northwestern.edu>
11 * Copyright (c) 2008, The V3VEE Project <http://www.v3vee.org>
12 * All rights reserved.
14 * Author: Jack Lange <jarusl@cs.northwestern.edu>
16 * This is free software. You are permitted to use,
17 * redistribute, and modify it as specified in the file "V3VEE_LICENSE".
21 #ifndef __VMM_PAGING_H__
22 #define __VMM_PAGING_H__
27 #include <palacios/vmm_types.h>
28 #include <palacios/vmm_util.h>
33 In the following, when we say "page table", we mean the whole 2 or 4 layer
34 page table (PDEs, PTEs), etc.
37 guest-visible paging state
38 This is the state that the guest thinks the machine is using
40 - guest physical memory
41 The physical memory addresses the guest is allowed to use
42 (see shadow page maps, below)
44 (we care about when the current one changes)
45 - guest paging registers (these are never written to hardware)
51 This the state that the machine will actually use when the guest
52 is running. It consists of:
53 - current shadow page table
54 This is the page table actually useed when the guest is running.
55 It is changed/regenerated when the guest page table changes
56 It mostly reflects the guest page table, except that it restricts
57 physical addresses to those the VMM allocates to the guest.
59 This is a mapping from guest physical memory addresses to
60 the current location of the guest physical memory content.
61 It maps from regions of physical memory addresses to regions
62 located in physical memory or elsewhere.
63 (8192,16384) -> MEM(8912,...)
64 (0,8191) -> DISK(65536,..)
65 - guest paging registers (these are written to guest state)
70 This is the state we expect to be operative when the VMM is running.
71 Typically, this is set up by the host os into which we have embedded
72 the VMM, but we include the description here for clarity.
74 This is the page table we use when we are executing in
75 the VMM (or the host os)
81 The reason why the shadow paging state and the host paging state are
82 distinct is to permit the guest to use any virtual address it wants,
83 irrespective of the addresses the VMM or the host os use. These guest
84 virtual addresses are reflected in the shadow paging state. When we
85 exit from the guest, we switch to the host paging state so that any
86 virtual addresses that overlap between the guest and VMM/host now map
87 to the physical addresses epxected by the VMM/host. On AMD SVM, this
88 switch is done by the hardware. On Intel VT, the switch is done
89 by the hardware as well, but we are responsible for manually updating
90 the host state in the vmcs before entering the guest.
96 #define MAX_PDE32_ENTRIES 1024
97 #define MAX_PTE32_ENTRIES 1024
99 #define MAX_PDPE32PAE_ENTRIES 4
100 #define MAX_PDE32PAE_ENTRIES 512
101 #define MAX_PTE32PAE_ENTRIES 512
103 #define MAX_PML4E64_ENTRIES 512
104 #define MAX_PDPE64_ENTRIES 512
105 #define MAX_PDE64_ENTRIES 512
106 #define MAX_PTE64_ENTRIES 512
109 typedef enum {PAGE_4KB, PAGE_2MB, PAGE_4MB, PAGE_1GB,
111 PAGE_PT32, PAGE_PD32,
112 PAGE_PDP32PAE, PAGE_PD32PAE, PAGE_PT32PAE,
113 PAGE_PML464, PAGE_PDP64, PAGE_PD64, PAGE_PT64} page_type_t;
116 /* Converts an address into a page table index */
117 #define PDE32_INDEX(x) ((((uint_t)x) >> 22) & 0x3ff)
118 #define PTE32_INDEX(x) ((((uint_t)x) >> 12) & 0x3ff)
121 #define PDPE32PAE_INDEX(x) ((((uint_t)x) >> 30) & 0x3)
122 #define PDE32PAE_INDEX(x) ((((uint_t)x) >> 21) & 0x1ff)
123 #define PTE32PAE_INDEX(x) ((((uint_t)x) >> 12) & 0x1ff)
125 #define PML4E64_INDEX(x) ((((ullong_t)x) >> 39) & 0x1ff)
126 #define PDPE64_INDEX(x) ((((ullong_t)x) >> 30) & 0x1ff)
127 #define PDE64_INDEX(x) ((((ullong_t)x) >> 21) & 0x1ff)
128 #define PTE64_INDEX(x) ((((ullong_t)x) >> 12) & 0x1ff)
131 /* Gets the base address needed for a Page Table entry */
133 #define PAGE_BASE_ADDR(x) ((x) >> 12)
134 #define PAGE_BASE_ADDR_4KB(x) ((x) >> 12)
135 #define PAGE_BASE_ADDR_2MB(x) ((x) >> 21)
136 #define PAGE_BASE_ADDR_4MB(x) ((x) >> 22)
137 #define PAGE_BASE_ADDR_1GB(x) ((x) >> 30)
139 #define BASE_TO_PAGE_ADDR(x) (((addr_t)x) << 12)
140 #define BASE_TO_PAGE_ADDR_4KB(x) (((addr_t)x) << 12)
141 #define BASE_TO_PAGE_ADDR_2MB(x) (((addr_t)x) << 21)
142 #define BASE_TO_PAGE_ADDR_4MB(x) (((addr_t)x) << 22)
143 #define BASE_TO_PAGE_ADDR_1GB(x) (((addr_t)x) << 30)
147 #define PAGE_OFFSET(x) ((x) & 0xfff)
148 #define PAGE_OFFSET_4KB(x) ((x) & 0xfff)
149 #define PAGE_OFFSET_2MB(x) ((x) & 0x1fffff)
150 #define PAGE_OFFSET_4MB(x) ((x) & 0x3fffff)
151 #define PAGE_OFFSET_1GB(x) ((x) & 0x3fffffff)
153 #define PAGE_POWER 12
154 #define PAGE_POWER_4KB 12
155 #define PAGE_POWER_2MB 21
156 #define PAGE_POWER_4MB 22
157 #define PAGE_POWER_1GB 30
159 // We shift instead of mask because we don't know the address size
160 #define PAGE_ADDR(x) (((x) >> PAGE_POWER) << PAGE_POWER)
161 #define PAGE_ADDR_4KB(x) (((x) >> PAGE_POWER_4KB) << PAGE_POWER_4KB)
162 #define PAGE_ADDR_2MB(x) (((x) >> PAGE_POWER_2MB) << PAGE_POWER_2MB)
163 #define PAGE_ADDR_4MB(x) (((x) >> PAGE_POWER_4MB) << PAGE_POWER_4MB)
164 #define PAGE_ADDR_1GB(x) (((x) >> PAGE_POWER_1GB) << PAGE_POWER_1GB)
166 #define PAGE_SIZE 4096
167 #define PAGE_SIZE_4KB 4096
168 #define PAGE_SIZE_2MB (4096 * 512)
169 #define PAGE_SIZE_4MB (4096 * 1024)
170 #define PAGE_SIZE_1GB 0x40000000
178 #define CR3_TO_PDE32_PA(cr3) ((addr_t)(((uint_t)cr3) & 0xfffff000))
179 #define CR3_TO_PDPE32PAE_PA(cr3) ((addr_t)(((uint_t)cr3) & 0xffffffe0))
180 #define CR3_TO_PML4E64_PA(cr3) ((addr_t)(((ullong_t)cr3) & 0x000ffffffffff000LL))
182 #define CR3_TO_PDE32_VA(cr3) ((pde32_t *)V3_VAddr((void *)(addr_t)(((uint_t)cr3) & 0xfffff000)))
183 #define CR3_TO_PDPE32PAE_VA(cr3) ((pdpe32pae_t *)V3_VAddr((void *)(addr_t)(((uint_t)cr3) & 0xffffffe0)))
184 #define CR3_TO_PML4E64_VA(cr3) ((pml4e64_t *)V3_VAddr((void *)(addr_t)(((ullong_t)cr3) & 0x000ffffffffff000LL)))
191 /* Page Table Flag Values */
192 #define PT32_HOOK 0x1
193 #define PT32_GUEST_PT 0x2
197 /* We'll use the general form for now....
198 typedef enum {PDE32_ENTRY_NOT_PRESENT, PDE32_ENTRY_PTE32, PDE32_ENTRY_LARGE_PAGE} pde32_entry_type_t;
199 typedef enum {PTE32_ENTRY_NOT_PRESENT, PTE32_ENTRY_PAGE} pte32_entry_type_t;
201 typedef enum {PDPE32PAE_ENTRY_NOT_PRESENT, PDPE32PAE_ENTRY_PAGE} pdpe32pae_entry_type_t;
202 typedef enum {PDE32PAE_ENTRY_NOT_PRESENT, PDE32PAE_ENTRY_PTE32, PDE32PAE_ENTRY_LARGE_PAGE} pde32pae_entry_type_t;
203 typedef enum {PTE32PAE_ENTRY_NOT_PRESENT, PTE32PAE_ENTRY_PAGE} pte32pae_entry_type_t;
205 typedef enum {PML4E64_ENTRY_NOT_PRESENT, PML4E64_ENTRY_PAGE} pml4e64_entry_type_t;
206 typedef enum {PDPE64_ENTRY_NOT_PRESENT, PDPE64_ENTRY_PTE32, PDPE64_ENTRY_LARGE_PAGE} pdpe64_entry_type_t;
207 typedef enum {PDE64_ENTRY_NOT_PRESENT, PDE64_ENTRY_PTE32, PDE64_ENTRY_LARGE_PAGE} pde64_entry_type_t;
208 typedef enum {PTE64_ENTRY_NOT_PRESENT, PTE64_ENTRY_PAGE} pte64_entry_type_t;
212 typedef enum {PT_ENTRY_NOT_PRESENT, PT_ENTRY_LARGE_PAGE, PT_ENTRY_PAGE} pt_entry_type_t;
213 typedef enum {PT_ACCESS_OK, PT_ACCESS_NOT_PRESENT, PT_ACCESS_WRITE_ERROR, PT_ACCESS_USER_ERROR} pt_access_status_t;
216 typedef struct gen_pt {
219 uint_t user_page : 1;
220 } __attribute__((packed)) gen_pt_t;
222 typedef struct pde32 {
225 uint_t user_page : 1;
226 uint_t write_through : 1;
227 uint_t cache_disable : 1;
230 uint_t large_page : 1;
231 uint_t global_page : 1;
233 uint_t pt_base_addr : 20;
234 } __attribute__((packed)) pde32_t;
236 typedef struct pde32_4MB {
239 uint_t user_page : 1;
240 uint_t write_through : 1;
241 uint_t cache_disable : 1;
244 uint_t large_page : 1;
245 uint_t global_page : 1;
249 uint_t page_base_addr : 10;
251 } __attribute__((packed)) pde32_4MB_t;
253 typedef struct pte32 {
256 uint_t user_page : 1;
257 uint_t write_through : 1;
258 uint_t cache_disable : 1;
262 uint_t global_page : 1;
264 uint_t page_base_addr : 20;
265 } __attribute__((packed)) pte32_t;
268 /* 32 bit PAE PAGE STRUCTURES */
269 typedef struct pdpe32pae {
271 uint_t rsvd : 2; // MBZ
272 uint_t write_through : 1;
273 uint_t cache_disable : 1;
276 uint_t rsvd2 : 2; // MBZ
278 uint_t pd_base_addr : 24;
279 uint_t rsvd3 : 28; // MBZ
280 } __attribute__((packed)) pdpe32pae_t;
284 typedef struct pde32pae {
287 uint_t user_page : 1;
288 uint_t write_through : 1;
289 uint_t cache_disable : 1;
292 uint_t large_page : 1;
293 uint_t global_page : 1;
295 uint_t pt_base_addr : 24;
297 } __attribute__((packed)) pde32pae_t;
299 typedef struct pde32pae_2MB {
302 uint_t user_page : 1;
303 uint_t write_through : 1;
304 uint_t cache_disable : 1;
308 uint_t global_page : 1;
312 uint_t page_base_addr : 15;
315 } __attribute__((packed)) pde32pae_2MB_t;
317 typedef struct pte32pae {
320 uint_t user_page : 1;
321 uint_t write_through : 1;
322 uint_t cache_disable : 1;
326 uint_t global_page : 1;
328 uint_t page_base_addr : 24;
330 } __attribute__((packed)) pte32pae_t;
339 /* LONG MODE 64 bit PAGE STRUCTURES */
340 typedef struct pml4e64 {
343 uint_t user_page : 1;
344 uint_t write_through : 1;
345 uint_t cache_disable : 1;
350 ullong_t pdp_base_addr : 40;
351 uint_t available : 11;
352 uint_t no_execute : 1;
353 } __attribute__((packed)) pml4e64_t;
356 typedef struct pdpe64 {
359 uint_t user_page : 1;
360 uint_t write_through : 1;
361 uint_t cache_disable : 1;
364 uint_t large_page : 1;
367 ullong_t pd_base_addr : 40;
368 uint_t available : 11;
369 uint_t no_execute : 1;
370 } __attribute__((packed)) pdpe64_t;
373 // We Don't support this
374 typedef struct pdpe64_1GB {
377 uint_t user_page : 1;
378 uint_t write_through : 1;
379 uint_t cache_disable : 1;
382 uint_t large_page : 1;
383 uint_t global_page : 1;
387 ullong_t page_base_addr : 22;
388 uint_t available : 11;
389 uint_t no_execute : 1;
390 } __attribute__((packed)) pdpe64_1GB_t;
394 typedef struct pde64 {
397 uint_t user_page : 1;
398 uint_t write_through : 1;
399 uint_t cache_disable : 1;
402 uint_t large_page : 1;
403 uint_t global_page : 1;
405 ullong_t pt_base_addr : 40;
406 uint_t available : 11;
407 uint_t no_execute : 1;
408 } __attribute__((packed)) pde64_t;
410 typedef struct pde64_2MB {
413 uint_t user_page : 1;
414 uint_t write_through : 1;
415 uint_t cache_disable : 1;
418 uint_t large_page : 1;
419 uint_t global_page : 1;
423 ullong_t page_base_addr : 31;
424 uint_t available : 11;
425 uint_t no_execute : 1;
426 } __attribute__((packed)) pde64_2MB_t;
429 typedef struct pte64 {
432 uint_t user_page : 1;
433 uint_t write_through : 1;
434 uint_t cache_disable : 1;
438 uint_t global_page : 1;
440 ullong_t page_base_addr : 40;
441 uint_t available : 11;
442 uint_t no_execute : 1;
443 } __attribute__((packed)) pte64_t;
445 /* *************** */
447 typedef struct pf_error_code {
448 uint_t present : 1; // if 0, fault due to page not present
449 uint_t write : 1; // if 1, faulting access was a write
450 uint_t user : 1; // if 1, faulting access was in user mode
451 uint_t rsvd_access : 1; // if 1, fault from reading a 1 from a reserved field (?)
452 uint_t ifetch : 1; // if 1, faulting access was an instr fetch (only with NX)
454 } __attribute__((packed)) pf_error_t;
462 int v3_translate_guest_pt_32(struct guest_info * info, v3_reg_t guest_cr3, addr_t vaddr, addr_t * paddr);
463 int v3_translate_guest_pt_32pae(struct guest_info * info, v3_reg_t guest_cr3, addr_t vaddr, addr_t * paddr);
464 int v3_translate_guest_pt_64(struct guest_info * info, v3_reg_t guest_cr3, addr_t vaddr, addr_t * paddr);
466 int v3_translate_host_pt_32(v3_reg_t host_cr3, addr_t vaddr, addr_t * paddr);
467 int v3_translate_host_pt_32pae(v3_reg_t host_cr3, addr_t vaddr, addr_t * paddr);
468 int v3_translate_host_pt_64(v3_reg_t host_cr3, addr_t vaddr, addr_t * paddr);
471 int v3_find_host_pt_32_page(v3_reg_t host_cr3, page_type_t type, addr_t vaddr, addr_t * page_addr);
472 int v3_find_host_pt_32pae_page(v3_reg_t host_cr3, page_type_t type, addr_t vaddr, addr_t * page_addr);
473 int v3_find_host_pt_64_page(v3_reg_t host_cr3, page_type_t type, addr_t vaddr, addr_t * page_addr);
474 int v3_find_guest_pt_32_page(struct guest_info * info, v3_reg_t guest_cr3,
475 page_type_t type, addr_t vaddr,
477 int v3_find_guest_pt_32pae_page(struct guest_info * info, v3_reg_t guest_cr3,
478 page_type_t type, addr_t vaddr,
480 int v3_find_guest_pt_64_page(struct guest_info * info, v3_reg_t guest_cr3,
481 page_type_t type, addr_t vaddr,
484 pt_access_status_t inline v3_can_access_pde32(pde32_t * pde, addr_t addr, pf_error_t access_type);
485 pt_access_status_t inline v3_can_access_pte32(pte32_t * pte, addr_t addr, pf_error_t access_type);
487 pt_access_status_t inline v3_can_access_pdpe32pae(pdpe32pae_t * pdpe, addr_t addr, pf_error_t access_type);
488 pt_access_status_t inline v3_can_access_pde32pae(pde32pae_t * pde, addr_t addr, pf_error_t access_type);
489 pt_access_status_t inline v3_can_access_pte32pae(pte32pae_t * pte, addr_t addr, pf_error_t access_type);
491 pt_access_status_t inline v3_can_access_pml4e64(pml4e64_t * pmle, addr_t addr, pf_error_t access_type);
492 pt_access_status_t inline v3_can_access_pdpe64(pdpe64_t * pdpe, addr_t addr, pf_error_t access_type);
493 pt_access_status_t inline v3_can_access_pde64(pde64_t * pde, addr_t addr, pf_error_t access_type);
494 pt_access_status_t inline v3_can_access_pte64(pte64_t * pte, addr_t addr, pf_error_t access_type);
497 int v3_check_host_pt_32(v3_reg_t host_cr3, addr_t vaddr,
498 pf_error_t access_type, pt_access_status_t * access_status);
499 int v3_check_host_pt_32pae(v3_reg_t host_cr3, addr_t vaddr,
500 pf_error_t access_type, pt_access_status_t * access_status);
501 int v3_check_host_pt_64(v3_reg_t host_cr3, addr_t vaddr,
502 pf_error_t access_type, pt_access_status_t * access_status);
503 int v3_check_guest_pt_32(struct guest_info * info, v3_reg_t guest_cr3, addr_t vaddr,
504 pf_error_t access_type, pt_access_status_t * access_status);
505 int v3_check_guest_pt_32pae(struct guest_info * info, v3_reg_t guest_cr3, addr_t vaddr,
506 pf_error_t access_type, pt_access_status_t * access_status);
507 int v3_check_guest_pt_64(struct guest_info * info, v3_reg_t guest_cr3, addr_t vaddr,
508 pf_error_t access_type, pt_access_status_t * access_status);
513 int v3_drill_host_pt_32(v3_reg_t host_cr3, addr_t vaddr,
514 int (*callback)(page_type_t type, addr_t vaddr, addr_t page_ptr, addr_t page_pa, void * private_data),
515 void * private_data);
516 int v3_drill_host_pt_32pae(v3_reg_t host_cr3, addr_t vaddr,
517 int (*callback)(page_type_t type, addr_t vaddr, addr_t page_ptr, addr_t page_pa, void * private_data),
518 void * private_data);
519 int v3_drill_host_pt_64(v3_reg_t host_cr3, addr_t vaddr,
520 int (*callback)(page_type_t type, addr_t vaddr, addr_t page_ptr, addr_t page_pa, void * private_data),
521 void * private_data);
523 int v3_drill_guest_pt_32(struct guest_info * info, v3_reg_t guest_cr3, addr_t vaddr,
524 int (*callback)(page_type_t type, addr_t vaddr, addr_t page_ptr, addr_t page_pa, void * private_data),
525 void * private_data);
526 int v3_drill_guest_pt_32pae(struct guest_info * info, v3_reg_t guest_cr3, addr_t vaddr,
527 int (*callback)(page_type_t type, addr_t vaddr, addr_t page_ptr, addr_t page_pa, void * private_data),
528 void * private_data);
529 int v3_drill_guest_pt_64(struct guest_info * info, v3_reg_t guest_cr3, addr_t vaddr,
530 int (*callback)(page_type_t type, addr_t vaddr, addr_t page_ptr, addr_t page_pa, void * private_data),
531 void * private_data);
535 int v3_walk_host_pt_32(v3_reg_t host_cr3,
536 int (*callback)(page_type_t type, addr_t vaddr, addr_t page_va, addr_t page_pa, void * private_data),
537 void * private_data);
539 int v3_walk_host_pt_32pae(v3_reg_t host_cr3,
540 int (*callback)(page_type_t type, addr_t vaddr, addr_t page_va, addr_t page_pa, void * private_data),
541 void * private_data);
543 int v3_walk_host_pt_64(v3_reg_t host_cr3,
544 int (*callback)(page_type_t type, addr_t vaddr, addr_t page_va, addr_t page_pa, void * private_data),
545 void * private_data);
547 int v3_walk_guest_pt_32(struct guest_info * info, v3_reg_t guest_cr3,
548 int (*callback)(page_type_t type, addr_t vaddr, addr_t page_va, addr_t page_pa, void * private_data),
549 void * private_data);
551 int v3_walk_guest_pt_32pae(struct guest_info * info, v3_reg_t guest_cr3,
552 int (*callback)(page_type_t type, addr_t vaddr, addr_t page_va, addr_t page_pa, void * private_data),
553 void * private_data);
555 int v3_walk_guest_pt_64(struct guest_info * info, v3_reg_t guest_cr3,
556 int (*callback)(page_type_t type, addr_t vaddr, addr_t page_va, addr_t page_pa, void * private_data),
557 void * private_data);
560 pde32_t * create_passthrough_pts_32(struct guest_info * guest_info);
561 pdpe32pae_t * create_passthrough_pts_32PAE(struct guest_info * guest_info);
562 pml4e64_t * create_passthrough_pts_64(struct guest_info * info);
565 void delete_page_tables_32(pde32_t * pde);
566 void delete_page_tables_32PAE(pdpe32pae_t * pdpe);
567 void delete_page_tables_64(pml4e64_t * pml4);
571 const uchar_t * v3_page_type_to_str(page_type_t type);
575 void PrintPTEntry(page_type_t type, addr_t vaddr, void * entry);
576 void PrintHostPageTables(v3_vm_cpu_mode_t cpu_mode, addr_t cr3);
577 void PrintGuestPageTables(struct guest_info * info, addr_t cr3);
578 void PrintHostPageTree(v3_vm_cpu_mode_t cpu_mode, addr_t virtual_addr, addr_t cr3);
579 void PrintGuestPageTree(struct guest_info * info, addr_t virtual_addr, addr_t cr3);