#include <palacios/vmm_decoder.h>
#include <palacios/vmm_ctrl_regs.h>
+#include <palacios/vmm_hashtable.h>
+
#ifndef DEBUG_SHADOW_PAGING
#undef PrintDebug
#define PrintDebug(fmt, args...)
***/
+struct guest_table {
+ addr_t cr3;
+ struct list_head link;
+};
+
+
+struct backptr {
+ addr_t ptr;
+ struct list_head link;
+};
+
+
+struct shadow_page_data {
+ addr_t ptr;
+ addr_t guest_addr;
+
+ struct list_head backptrs;
+ struct list_head guest_tables;
+};
+
static int handle_shadow_pagefault_32pae(struct guest_info * info, addr_t fault_addr, pf_error_t error_code);
static int handle_shadow_pagefault_64(struct guest_info * info, addr_t fault_addr, pf_error_t error_code);
+
+static int cache_page_tables_32(struct guest_info * info, addr_t pde);
+static int cache_page_tables_64(struct guest_info * info, addr_t pde);
+
int v3_init_shadow_page_state(struct guest_info * info) {
struct shadow_page_state * state = &(info->shdw_pg_state);
-/*
- For now we'll do something a little more lightweight
-int cache_page_tables32(struct guest_info * info, addr_t pde) {
- struct shadow_page_state * state = &(info->shdw_pg_state);
- addr_t pde_host_addr;
- pde32_t * tmp_pde;
- struct hashtable * pte_cache = NULL;
- int i = 0;
-
-
- pte_cache = (struct hashtable *)find_cr3_in_cache(state->cr3_cache, pde);
- if (pte_cache != NULL) {
- PrintError("CR3 already present in cache\n");
- state->current_ptes = pte_cache;
- return 1;
- } else {
- PrintError("Creating new CR3 cache entry\n");
- pte_cache = create_hashtable(0, &pte_hash_fn, &pte_equals);
- state->current_ptes = pte_cache;
- add_cr3_to_cache(state->cr3_cache, pde, pte_cache);
- }
-
- if (guest_pa_to_host_va(info, pde, &pde_host_addr) == -1) {
- PrintError("Could not lookup host address of guest PDE\n");
- return -1;
- }
-
- tmp_pde = (pde32_t *)pde_host_addr;
-
- add_pte_map(pte_cache, pde, pde_host_addr);
-
-
- for (i = 0; i < MAX_PDE32_ENTRIES; i++) {
- if ((tmp_pde[i].present) && (tmp_pde[i].large_page == 0)) {
- addr_t pte_host_addr;
-
- if (guest_pa_to_host_va(info, (addr_t)(PDE32_T_ADDR(tmp_pde[i])), &pte_host_addr) == -1) {
- PrintError("Could not lookup host address of guest PDE\n");
- return -1;
- }
-
- add_pte_map(pte_cache, (addr_t)(PDE32_T_ADDR(tmp_pde[i])), pte_host_addr);
- }
- }
-
-
- return 0;
-}
-*/
-
int v3_cache_page_tables(struct guest_info * info, addr_t cr3) {
switch(v3_get_cpu_mode(info)) {
case PROTECTED:
- return v3_cache_page_tables32(info, CR3_TO_PDE32_PA(cr3));
+ return cache_page_tables_32(info, CR3_TO_PDE32_PA(cr3));
default:
return -1;
}
}
-int v3_cache_page_tables32(struct guest_info * info, addr_t pde) {
+static int cache_page_tables_32(struct guest_info * info, addr_t pde) {
struct shadow_page_state * state = &(info->shdw_pg_state);
addr_t pde_host_addr;
pde32_t * tmp_pde;
}
+static int cache_page_tables_64(struct guest_info * info, addr_t pde) {
+ return -1;
+}
+
int v3_replace_shdw_page32(struct guest_info * info, addr_t location, pte32_t * new_page, pte32_t * old_page) {
pde32_t * shadow_pd = (pde32_t *)CR3_TO_PDE32_VA(info->ctrl_regs.cr3);
} else {
// currently unhandled
+ PrintError("Replacing large shadow pages not implemented\n");
return -1;
}
// We assume that shdw_pg_state.guest_cr3 is pointing to the page tables we want to activate
// We also assume that the CPU mode has not changed during this page table transition
static int activate_shadow_pt_32(struct guest_info * info) {
- struct cr3_32 * shadow_cr3 = (struct cr3_32 *)&(info->ctrl_regs.cr3);
- struct cr3_32 * guest_cr3 = (struct cr3_32 *)&(info->shdw_pg_state.guest_cr3);
- int cached = 0;
-
- // Check if shadow page tables are in the cache
- cached = v3_cache_page_tables32(info, CR3_TO_PDE32_PA(*(addr_t *)guest_cr3));
+ struct cr3_32 * shadow_cr3 = (struct cr3_32 *)&(info->ctrl_regs.cr3);
+ struct cr3_32 * guest_cr3 = (struct cr3_32 *)&(info->shdw_pg_state.guest_cr3);
+ int cached = 0;
+
+ // Check if shadow page tables are in the cache
+ cached = cache_page_tables_32(info, CR3_TO_PDE32_PA(*(addr_t *)guest_cr3));
+
+ if (cached == -1) {
+ PrintError("CR3 Cache failed\n");
+ return -1;
+ } else if (cached == 0) {
+ addr_t shadow_pt;
- if (cached == -1) {
- PrintError("CR3 Cache failed\n");
- return -1;
- } else if (cached == 0) {
- addr_t shadow_pt;
-
- PrintDebug("New CR3 is different - flushing shadow page table %p\n", shadow_cr3 );
- delete_page_tables_32(CR3_TO_PDE32_VA(*(uint_t*)shadow_cr3));
-
- shadow_pt = v3_create_new_shadow_pt();
-
- shadow_cr3->pdt_base_addr = (addr_t)V3_PAddr((void *)(addr_t)PAGE_BASE_ADDR(shadow_pt));
- PrintDebug( "Created new shadow page table %p\n", (void *)(addr_t)shadow_cr3->pdt_base_addr );
- } else {
- PrintDebug("Reusing cached shadow Page table\n");
- }
-
- shadow_cr3->pwt = guest_cr3->pwt;
- shadow_cr3->pcd = guest_cr3->pcd;
-
- return 0;
+ PrintDebug("New CR3 is different - flushing shadow page table %p\n", shadow_cr3 );
+ delete_page_tables_32(CR3_TO_PDE32_VA(*(uint_t*)shadow_cr3));
+
+ shadow_pt = v3_create_new_shadow_pt();
+
+ shadow_cr3->pdt_base_addr = (addr_t)V3_PAddr((void *)(addr_t)PAGE_BASE_ADDR(shadow_pt));
+ PrintDebug( "Created new shadow page table %p\n", (void *)(addr_t)shadow_cr3->pdt_base_addr );
+ } else {
+ PrintDebug("Reusing cached shadow Page table\n");
+ }
+
+ shadow_cr3->pwt = guest_cr3->pwt;
+ shadow_cr3->pcd = guest_cr3->pcd;
+
+ return 0;
}
static int activate_shadow_pt_32pae(struct guest_info * info) {
return -1;
}
+static int activate_shadow_pt_64_cb(page_type_t type, addr_t vaddr, addr_t page_ptr, addr_t page_pa, void * private_data) {
+ PrintDebug("CB: Page: %p->%p (host_ptr=%p), Type: %s\n", (void *)vaddr, (void *)page_pa, (void *)page_ptr, v3_page_type_to_str(type));
+ return 0;
+}
+
+
static int activate_shadow_pt_64(struct guest_info * info) {
- PrintError("Activating 64 bit page tables not implemented\n");
+ // struct cr3_64 * shadow_cr3 = (struct cr3_64 *)&(info->ctrl_regs.cr3);
+ struct cr3_64 * guest_cr3 = (struct cr3_64 *)&(info->shdw_pg_state.guest_cr3);
+ int cached = 0;
+
+ v3_walk_guest_pt_64(info, info->shdw_pg_state.guest_cr3, activate_shadow_pt_64_cb, NULL);
+
+
+
return -1;
+
+
+ // Check if shadow page tables are in the cache
+ cached = cache_page_tables_64(info, CR3_TO_PDE32_PA(*(addr_t *)guest_cr3));
+ /*
+ if (cached == -1) {
+ PrintError("CR3 Cache failed\n");
+ return -1;
+ } else if (cached == 0) {
+ addr_t shadow_pt;
+
+ PrintDebug("New CR3 is different - flushing shadow page table %p\n", shadow_cr3 );
+ delete_page_tables_32(CR3_TO_PDE32_VA(*(uint_t*)shadow_cr3));
+
+ shadow_pt = v3_create_new_shadow_pt();
+
+ shadow_cr3->pml4t_base_addr = (addr_t)V3_PAddr((void *)(addr_t)PAGE_BASE_ADDR(shadow_pt));
+ PrintDebug( "Created new shadow page table %p\n", (void *)(addr_t)shadow_cr3->pml4t_base_addr );
+ } else {
+ PrintDebug("Reusing cached shadow Page table\n");
+ }
+
+ shadow_cr3->pwt = guest_cr3->pwt;
+ shadow_cr3->pcd = guest_cr3->pcd;
+
+ return 0;
+ */
}
// If paging is not turned on we need to handle the special cases
#ifdef DEBUG_SHADOW_PAGING
- PrintPageTree(info->cpu_mode, fault_addr, info->ctrl_regs.cr3);
+ PrintHostPageTree(info->cpu_mode, fault_addr, info->ctrl_regs.cr3);
+ PrintGuestPageTree(info, fault_addr, info->shdw_pg_state.guest_cr3);
#endif
return handle_special_page_fault(info, fault_addr, fault_addr, error_code);
*/
static int handle_shadow_pagefault_64(struct guest_info * info, addr_t fault_addr, pf_error_t error_code) {
+ pt_access_status_t guest_access;
+ pt_access_status_t shadow_access;
+ int ret;
+ PrintDebug("64 bit shadow page fault\n");
+
+ ret = v3_check_guest_pt_32(info, info->shdw_pg_state.guest_cr3, fault_addr, error_code, &guest_access);
+
+ PrintDebug("Guest Access Check: %d (access=%d)\n", ret, guest_access);
+
+ ret = v3_check_host_pt_32(info->ctrl_regs.cr3, fault_addr, error_code, &shadow_access);
+
+ PrintDebug("Shadow Access Check: %d (access=%d)\n", ret, shadow_access);
+
+
PrintError("64 bit shadow paging not implemented\n");
return -1;
}
PrintDebug("Manual Says to inject page fault into guest\n");
#ifdef DEBUG_SHADOW_PAGING
PrintDebug("Guest PDE: (access=%d)\n\t", guest_pde_access);
- PrintPDE32(fault_addr, guest_pde);
+ PrintPTEntry(PAGE_PD32, fault_addr, guest_pde);
PrintDebug("Shadow PDE: (access=%d)\n\t", shadow_pde_access);
- PrintPDE32(fault_addr, shadow_pde);
+ PrintPTEntry(PAGE_PD32, fault_addr, shadow_pde);
#endif
return 0;
{
pt_access_status_t shadow_pte_access = v3_can_access_pte32(shadow_pt, fault_addr, error_code);
pte32_t * shadow_pte = (pte32_t *)&(shadow_pt[PTE32_INDEX(fault_addr)]);
-
+ addr_t guest_fault_pa = BASE_TO_PAGE_ADDR_4MB(large_guest_pde->page_base_addr) + PAGE_OFFSET_4MB(fault_addr);
+
if (shadow_pte_access == PT_ACCESS_OK) {
// Inconsistent state...
// Guest Re-Entry will flush tables and everything should now workd
if (shadow_pte_access == PT_ACCESS_NOT_PRESENT) {
// Get the guest physical address of the fault
- addr_t guest_fault_pa = BASE_TO_PAGE_ADDR_4MB(large_guest_pde->page_base_addr) + PAGE_OFFSET_4MB(fault_addr);
- host_region_type_t host_page_type = get_shadow_addr_type(info, guest_fault_pa);
+ shdw_region_type_t host_page_type = get_shadow_addr_type(info, guest_fault_pa);
- if (host_page_type == HOST_REGION_INVALID) {
+ if (host_page_type == SHDW_REGION_INVALID) {
// Inject a machine check in the guest
PrintDebug("Invalid Guest Address in page table (0x%p)\n", (void *)guest_fault_pa);
v3_raise_exception(info, MC_EXCEPTION);
return 0;
}
- if (host_page_type == HOST_REGION_PHYSICAL_MEMORY) {
+ if ((host_page_type == SHDW_REGION_ALLOCATED) ||
+ (host_page_type == SHDW_REGION_WRITE_HOOK)) {
struct shadow_page_state * state = &(info->shdw_pg_state);
addr_t shadow_pa = get_shadow_addr(info, guest_fault_pa);
PrintDebug("Marking page as Guest Page Table (large page)\n");
shadow_pte->vmm_info = PT32_GUEST_PT;
shadow_pte->writable = 0;
+ } else if (host_page_type == SHDW_REGION_WRITE_HOOK) {
+ shadow_pte->writable = 0;
} else {
shadow_pte->writable = 1;
}
-
//set according to VMM policy
shadow_pte->write_through = 0;
shadow_pte->cache_disable = 0;
} else {
// Handle hooked pages as well as other special pages
- if (handle_special_page_fault(info, fault_addr, guest_fault_pa, error_code) == -1) {
+ // if (handle_special_page_fault(info, fault_addr, guest_fault_pa, error_code) == -1) {
+ struct shadow_region * reg = v3_get_shadow_region(info, guest_fault_pa);
+
+ if (v3_handle_mem_full_hook(info, fault_addr, guest_fault_pa, reg, error_code) == -1) {
PrintError("Special Page Fault handler returned error for address: %p\n", (void *)fault_addr);
return -1;
}
}
- } else if ((shadow_pte_access == PT_ACCESS_WRITE_ERROR) &&
- (shadow_pte->vmm_info == PT32_GUEST_PT)) {
+ } else if (shadow_pte_access == PT_ACCESS_WRITE_ERROR) {
+ shdw_region_type_t host_page_type = get_shadow_addr_type(info, guest_fault_pa);
+
+ if (host_page_type == SHDW_REGION_WRITE_HOOK) {
+ struct shadow_region * reg = v3_get_shadow_region(info, guest_fault_pa);
- struct shadow_page_state * state = &(info->shdw_pg_state);
- PrintDebug("Write operation on Guest PAge Table Page (large page)\n");
- state->cached_cr3 = 0;
- shadow_pte->writable = 1;
+ if (v3_handle_mem_wr_hook(info, fault_addr, guest_fault_pa, reg, error_code) == -1) {
+ PrintError("Special Page Fault handler returned error for address: %p\n", (void *)fault_addr);
+ return -1;
+ }
+ } else if (shadow_pte->vmm_info == PT32_GUEST_PT) {
+ struct shadow_page_state * state = &(info->shdw_pg_state);
+ PrintDebug("Write operation on Guest PAge Table Page (large page)\n");
+ state->cached_cr3 = 0;
+ shadow_pte->writable = 1;
+ }
} else {
PrintError("Error in large page fault handler...\n");
pt_access_status_t shadow_pte_access;
pte32_t * guest_pte = (pte32_t *)&(guest_pt[PTE32_INDEX(fault_addr)]);;
pte32_t * shadow_pte = (pte32_t *)&(shadow_pt[PTE32_INDEX(fault_addr)]);
+ addr_t guest_pa = BASE_TO_PAGE_ADDR((addr_t)(guest_pte->page_base_addr)) + PAGE_OFFSET(fault_addr);
// Check the guest page permissions
#ifdef DEBUG_SHADOW_PAGING
PrintDebug("Guest PTE: (access=%d)\n\t", guest_pte_access);
- PrintPTE32(fault_addr, guest_pte);
+ PrintPTEntry(PAGE_PT32, fault_addr, guest_pte);
PrintDebug("Shadow PTE: (access=%d)\n\t", shadow_pte_access);
- PrintPTE32(fault_addr, shadow_pte);
+ PrintPTEntry(PAGE_PT32, fault_addr, shadow_pte);
#endif
/* Was the page fault caused by the Guest's page tables? */
if (shadow_pte_access == PT_ACCESS_NOT_PRESENT) {
- addr_t guest_pa = BASE_TO_PAGE_ADDR((addr_t)(guest_pte->page_base_addr)) + PAGE_OFFSET(fault_addr);
// Page Table Entry Not Present
PrintDebug("guest_pa =%p\n", (void *)guest_pa);
- host_region_type_t host_page_type = get_shadow_addr_type(info, guest_pa);
+ shdw_region_type_t host_page_type = get_shadow_addr_type(info, guest_pa);
- if (host_page_type == HOST_REGION_INVALID) {
+ if (host_page_type == SHDW_REGION_INVALID) {
// Inject a machine check in the guest
PrintDebug("Invalid Guest Address in page table (0x%p)\n", (void *)guest_pa);
v3_raise_exception(info, MC_EXCEPTION);
// else...
- if (host_page_type == HOST_REGION_PHYSICAL_MEMORY) {
+ if ((host_page_type == SHDW_REGION_ALLOCATED) ||
+ (host_page_type == SHDW_REGION_WRITE_HOOK)) {
struct shadow_page_state * state = &(info->shdw_pg_state);
addr_t shadow_pa = get_shadow_addr(info, guest_pa);
shadow_pte->vmm_info = PT32_GUEST_PT;
}
- if (guest_pte->dirty == 1) {
+ if (host_page_type == SHDW_REGION_WRITE_HOOK) {
+ shadow_pte->writable = 0;
+ } else if (guest_pte->dirty == 1) {
shadow_pte->writable = guest_pte->writable;
} else if ((guest_pte->dirty == 0) && (error_code.write == 1)) {
shadow_pte->writable = guest_pte->writable;
shadow_pte->writable = 0;
}
-
-
} else {
// Page fault handled by hook functions
- if (handle_special_page_fault(info, fault_addr, guest_pa, error_code) == -1) {
+ struct shadow_region * reg = v3_get_shadow_region(info, guest_pa);
+
+ if (v3_handle_mem_full_hook(info, fault_addr, guest_pa, reg, error_code) == -1) {
PrintError("Special Page fault handler returned error for address: %p\n", (void *)fault_addr);
return -1;
}
}
-
+ /*
} else if ((shadow_pte_access == PT_ACCESS_WRITE_ERROR) &&
(guest_pte->dirty == 0)) {
-
- PrintDebug("Shadow PTE Write Error\n");
+ */
+ } else if (shadow_pte_access == PT_ACCESS_WRITE_ERROR) {
guest_pte->dirty = 1;
- shadow_pte->writable = guest_pte->writable;
+
+ shdw_region_type_t host_page_type = get_shadow_addr_type(info, guest_pa);
+
+ if (host_page_type == SHDW_REGION_WRITE_HOOK) {
+ struct shadow_region * reg = v3_get_shadow_region(info, guest_pa);
+
+ if (v3_handle_mem_wr_hook(info, fault_addr, guest_pa, reg, error_code) == -1) {
+ PrintError("Special Page fault handler returned error for address: %p\n", (void *)fault_addr);
+ return -1;
+ }
+ } else {
+ PrintDebug("Shadow PTE Write Error\n");
+ shadow_pte->writable = guest_pte->writable;
+ }
if (shadow_pte->vmm_info == PT32_GUEST_PT) {
struct shadow_page_state * state = &(info->shdw_pg_state);
PrintDebug("Write operation on Guest PAge Table Page\n");
state->cached_cr3 = 0;
}
-
+
return 0;
} else {
if (info->cpu_mode != PROTECTED) {
- return 0;
+ PrintError("Unsupported CPU mode (mode=%s)\n", v3_cpu_mode_to_str(info->cpu_mode));
+ return -1;
}
uchar_t instr[15];
#ifdef DEBUG_SHADOW_PAGING
PrintDebug("Setting not present\n");
- PrintPTE32(first_operand, shadow_pte );
+ PrintPTEntry(PAGE_PT32, first_operand, shadow_pte);
#endif
shadow_pte->present = 0;
}
-/*
-
-
-static int create_pd32_nonaligned_4MB_page(struct guest_info * info, pte32_t * pt, addr_t guest_addr, pde32_4MB_t * large_shadow_pde) {
- uint_t i = 0;
- pte32_t * pte_cursor;
- addr_t guest_pa = 0;
-
- for (i = 0; i < 1024; i++) {
- guest_pa = guest_addr + (PAGE_SIZE * i);
- host_region_type_t host_page_type = get_shadow_addr_type(info, guest_pa);
-
- pte_cursor = &(pt[i]);
-
- if (host_page_type == HOST_REGION_INVALID) {
- // Currently we don't support this, but in theory we could
- PrintError("Invalid Host Memory Type\n");
- return -1;
- } else if (host_page_type == HOST_REGION_PHYSICAL_MEMORY) {
- addr_t shadow_pa = get_shadow_addr(info, guest_pa);
-
-
- pte_cursor->page_base_addr = PT32_BASE_ADDR(shadow_pa);
- pte_cursor->present = 1;
- pte_cursor->writable = large_shadow_pde->writable;
- pte_cursor->user_page = large_shadow_pde->user_page;
- pte_cursor->write_through = 0;
- pte_cursor->cache_disable = 0;
- pte_cursor->global_page = 0;
-
- } else {
- PrintError("Unsupported Host Memory Type\n");
- return -1;
- }
- }
- return 0;
-}
-
-
-static int handle_large_pagefault32(struct guest_info * info,
- pde32_t * guest_pde, pde32_t * shadow_pde,
- addr_t fault_addr, pf_error_t error_code ) {
- struct shadow_region * mem_reg;
- pde32_4MB_t * large_guest_pde = (pde32_4MB_t *)guest_pde;
- pde32_4MB_t * large_shadow_pde = (pde32_4MB_t *)shadow_pde;
- host_region_type_t host_page_type;
- addr_t guest_start_addr = PDE32_4MB_T_ADDR(*large_guest_pde);
- // addr_t guest_end_addr = guest_start_addr + PAGE_SIZE_4MB; // start address + 4MB
-
-
- // Check that the Guest PDE entry points to valid memory
- // else Machine Check the guest
- PrintDebug("Large Page: Page Base Addr=%x\n", guest_start_addr);
-
- host_page_type = get_shadow_addr_type(info, guest_start_addr);
-
- if (host_page_type == HOST_REGION_INVALID) {
- PrintError("Invalid guest address in large page (0x%x)\n", guest_start_addr);
- v3_raise_exception(info, MC_EXCEPTION);
- return -1;
- }
-
- // else...
-
- if (host_page_type == HOST_REGION_PHYSICAL_MEMORY) {
-
- addr_t host_start_addr = 0;
- addr_t region_end_addr = 0;
-
- // Check for a large enough region in host memory
- mem_reg = get_shadow_region_by_addr(&(info->mem_map), guest_start_addr);
- PrintDebug("Host region: host_addr=%x (guest_start=%x, end=%x)\n",
- mem_reg->host_addr, mem_reg->guest_start, mem_reg->guest_end);
- host_start_addr = mem_reg->host_addr + (guest_start_addr - mem_reg->guest_start);
- region_end_addr = mem_reg->host_addr + (mem_reg->guest_end - mem_reg->guest_start);
-
- PrintDebug("Host Start Addr=%x; Region End Addr=%x\n", host_start_addr, region_end_addr);
-
-
- //4f
- if (large_guest_pde->dirty == 1) { // dirty
- large_shadow_pde->writable = guest_pde->writable;
- } else if (error_code.write == 1) { // not dirty, access is write
- large_shadow_pde->writable = guest_pde->writable;
- large_guest_pde->dirty = 1;
- } else { // not dirty, access is read
- large_shadow_pde->writable = 0;
- }
-
-
- // Check if the region is at least an additional 4MB
-
-
- //4b.
- if ((PD32_4MB_PAGE_OFFSET(host_start_addr) == 0) &&
- (region_end_addr >= host_start_addr + PAGE_SIZE_4MB)) { // if 4MB boundary
- large_shadow_pde->page_base_addr = PD32_4MB_BASE_ADDR(host_start_addr);
- } else { // else generate 4k pages
- pte32_t * shadow_pt = NULL;
- PrintDebug("Handling non aligned large page\n");
-
- shadow_pde->large_page = 0;
-
- shadow_pt = create_new_shadow_pt32();
-
- if (create_pd32_nonaligned_4MB_page(info, shadow_pt, guest_start_addr, large_shadow_pde) == -1) {
- PrintError("Non Aligned Large Page Error\n");
- V3_Free(shadow_pt);
- return -1;
- }
-
-
-#ifdef DEBUG_SHADOW_PAGING
- PrintDebug("non-aligned Shadow PT\n");
- PrintPT32(PT32_PAGE_ADDR(fault_addr), shadow_pt);
-#endif
- shadow_pde->pt_base_addr = PD32_BASE_ADDR(shadow_pt);
- }
-
- } else {
- // Handle hooked pages as well as other special pages
- if (handle_special_page_fault(info, fault_addr, guest_start_addr, error_code) == -1) {
- PrintError("Special Page Fault handler returned error for address: %x\n", fault_addr);
- return -1;
- }
- }
-
- return 0;
-}
-*/