I'm working on modifying a routine that switches to and from realmode to perform a BIOS interrupt, but running into issues with paging. I had it working prior with no paging, but now that my OS uses paging, I need to disable it before entering realmode (and enable it after).
My issue is that when performing the far jump to cause the page disabling to take effect, something goes terribly wrong and I get a reboot.
The code shown below works by creating an identity mapping first using the page table
boot_page_table1 which is simply a page table that identity maps the first 4 MiB. This has to be done since im curently using paging to run my kernel code from higher memory and all kernel code is addressed starting at
0xC0100000 while being loaded starting at
0x00100000. I then flush the TLB and jump to a nearby label, but this time using an address in lower memory. My instruction pointer should now be pointing to identity mapped code and it should be safe to disable paging. The paging bit is then disabled in
cr3, the TLB is flushed again because I'm paranoid, and the code to switch modes continues.
The code works by coping itself into 16-bit memory at 0x7c00 and then jumping to that so it can work in 16-bit realmode.
If I do NOT disable the paging bit and leave everything else the same, the
jmpw CODE16:REBASE(p_mode16) works and the infinite loop after the jump is entered leaving me to think that this problem occurs due to how I disabled paging. Am I missing something when disabling paging? I saw on other posts that "because what you're doing is very unusual you may run into bugs and compatibility problems with your emulator", but I'm not yet sure if its just my code thats wrong.
The code is written using intel syntax with the GAS assembler.
.intel_syntax noprefix .code32 .global int32, _int32 #define regs16_t_size 13*2 #define INT32_BASE 0x00007C00 #define REBASE(x) (((x) - reloc) + INT32_BASE) #define GDTENTRY(x) ((x) << 3) #define CODE32 0x08 #define DATA32 0x10 #define CODE16 0x18 #define DATA16 0x20 #define STACK16 (INT32_BASE - regs16_t_size) .global reloc .global int32_end .section .text int32: .code32 # by Napalm _int32: cli # disable interrupts pusha # save register state to 32bit stack # Enable identity mapping the first MiB, jump, then disable paging push [boot_page_directory] # Push first page directory entry to restore it after mov eax, (offset boot_page_table1) - 0xC0000000 + 0x003 mov [boot_page_directory], eax mov ecx, cr3 # Reload crc3 to force a TLB flush so the changes to take effect. mov cr3, ecx mov eax, (offset napalm_switch_disable_paging) - 0xC0000000 jmp eax napalm_switch_disable_paging: # Code is now running with the instruction pointer in lower memory, # but the code is still assembled as though its in higher memory. Because # of this, something like jmp INT32_BASE would fail since it would # assemble as a relative jump from an address around 0xC0100000 to 0x7C00 # but will be running at an address around 0x00100000 causing it to jump to # 0x40007C00. # Disable paging bit mov eax, cr0 and eax, ~0x80000000 mov cr0, eax mov ecx, cr3 # Reload crc3 to force a TLB flush so the changes to take effect. mov cr3, ecx mov esi, (offset reloc) - 0xC0000000 # set source to code below mov edi, INT32_BASE # set destination to new base address mov ecx, int32_end - reloc # set copy size to our codes size cld # clear direction flag (so we copy forward) rep movsb # do the actual copy (relocate code to low 16bit space) mov eax, INT32_BASE jmp eax # jump to new code location reloc: .code32 # by Napalm mov [REBASE(stack32_ptr)], esp # save 32bit stack pointer sidt [idt_ptr] # save 32bit idt pointer sgdt [gdt_ptr] # save 32bit gdt pointer lgdt [REBASE(gdt16_ptr)] # load 16bit gdt pointer lea esi, [esp+0x24] # set position of intnum on 32bit stack lodsd # read intnum into eax mov [REBASE(ib)], al # set intrrupt immediate byte from our arguments mov esi, [esi] # read regs pointer in esi as source mov edi, STACK16 # set destination to 16bit stack mov ecx, regs16_t_size # set copy size to our struct size mov esp, edi # save destination to as 16bit stack offset rep movsb # do the actual copy (32bit stack to 16bit stack) jmpw CODE16:REBASE(p_mode16) # switch to 16bit selector (16bit protected mode) p_mode16: .code16 jmp .-2 ... more of the routine thats not run due to the bug ... stack32_ptr: # address in 32bit stack after we .4byte 0x00000000 # save all general purpose registers idt16_ptr: # IDT table pointer for 16bit access .2byte 0x03FF # table limit (size) .4byte 0x00000000 # table base address gdt16_base: # GDT descriptor table .null: # 0x00 - null segment descriptor .4byte 0x00000000 # must be left zero'd .4byte 0x00000000 # must be left zero'd .code32: # 0x01 - 32bit code segment descriptor 0xFFFFFFFF .2byte 0xFFFF # limit 0:15 .2byte 0x0000 # base 0:15 .byte 0x00 # base 16:23 .byte 0x9A # present, iopl/0, code, execute/read .byte 0xCF # 4Kbyte granularity, 32bit selector; limit 16:19 .byte 0x00 # base 24:31 .data32: # 0x02 - 32bit data segment descriptor 0xFFFFFFFF .2byte 0xFFFF # limit 0:15 .2byte 0x0000 # base 0:15 .byte 0x00 # base 16:23 .byte 0x92 # present, iopl/0, data, read/write .byte 0xCF # 4Kbyte granularity, 32bit selector; limit 16:19 .byte 0x00 # base 24:31 .code16: # 0x03 - 16bit code segment descriptor 0x000FFFFF .2byte 0xFFFF # limit 0:15 .2byte 0x0000 # base 0:15 .byte 0x00 # base 16:23 .byte 0x9A # present, iopl/0, code, execute/read .byte 0x0F # 1Byte granularity, 16bit selector; limit 16:19 .byte 0x00 # base 24:31 .data16: # 0x04 - 16bit data segment descriptor 0x000FFFFF .2byte 0xFFFF # limit 0:15 .2byte 0x0000 # base 0:15 .byte 0x00 # base 16:23 .byte 0x92 # present, iopl/0, data, read/write .byte 0x0F # 1Byte granularity, 16bit selector; limit 16:19 .byte 0x00 # base 24:31 gdt16_ptr: # GDT table pointer for 16bit access .2byte gdt16_ptr - gdt16_base - 1 # table limit (size) .4byte gdt16_base # table base address int32_end: # end marker (so we can copy the code) .byte 0x00
The line with
jmp .-2 at the
p_mode16 label is never reached and a reboot happens instead. If the
jmp .-2 is put right before the
jmpw then the OS enters an infinite loop as expected. Im running this on QEMU version 2.11.1 with