path: root/runkernel.inc

;; $Id$
;; -----------------------------------------------------------------------
;;   
;;   Copyright 1994-2002 H. Peter Anvin - All Rights Reserved
;;
;;   This program is free software; you can redistribute it and/or modify
;;   it under the terms of the GNU General Public License as published by
;;   the Free Software Foundation, Inc., 53 Temple Place Ste 330,
;;   Bostom MA 02111-1307, USA; either version 2 of the License, or
;;   (at your option) any later version; incorporated herein by reference.
;;
;; -----------------------------------------------------------------------

;;
;; runkernel.inc
;; 
;; Common code for running a Linux kernel
;;

;
; Hook macros, that may or may not be defined
;
%ifndef HAVE_SPECIAL_APPEND
%macro SPECIAL_APPEND 0
%endmacro
%endif

%ifndef HAVE_UNLOAD_PREP
%macro UNLOAD_PREP 0
%endmacro
%endif

;
; A Linux kernel consists of three parts: boot sector, setup code, and
; kernel code.	The boot sector is never executed when using an external
; booting utility, but it contains some status bytes that are necessary.
;
; First check that our kernel is at least 1K and less than 8M (if it is
; more than 8M, we need to change the logic for loading it anyway...)
;
; We used to require the kernel to be 64K or larger, but it has gotten
; popular to use the Linux kernel format for other things, which may
; not be so large.
;
is_linux_kernel:
                cmp dx,80h			; 8 megs
		ja near kernel_corrupt
		and dx,dx
		jnz kernel_sane
		cmp ax,1024			; Bootsect + 1 setup sect
		jb near kernel_corrupt
kernel_sane:	push ax
		push dx
		push si
		mov si,loading_msg
                call cwritestr
;
; Now start transferring the kernel
;
		push word real_mode_seg
		pop es

		movzx eax,ax			; Fix this by using a 32-bit
		shl edx,16			; register for the kernel size
		or eax,edx
		mov [KernelSize],eax
		xor edx,edx
		div dword [ClustSize]		; # of clusters total
		; Round up...
		add edx,byte -1			; Sets CF if EDX >= 1
		adc eax,byte 0			; Add 1 to EAX if CF set
                mov [KernelClust],eax

;
; Now, if we transfer these straight, we'll hit 64K boundaries.	 Hence we
; have to see if we're loading more than 64K, and if so, load it step by
; step.
;

;
; Start by loading the bootsector/setup code, to see if we need to
; do something funky.  It should fit in the first 32K (loading 64K won't
; work since we might have funny stuff up near the end of memory).
; If we have larger than 32K clusters, yes, we're hosed.
;
		call abort_check		; Check for abort key
		mov ecx,[ClustPerMoby]
		shr ecx,1			; Half a moby
		cmp ecx,[KernelClust]
		jna .normalkernel
		mov ecx,[KernelClust]
.normalkernel:
		sub [KernelClust],ecx
		xor bx,bx
                pop si                          ; Cluster pointer on stack
		call getfssec
                cmp word [es:bs_bootsign],0AA55h
		jne near kernel_corrupt		; Boot sec signature missing
;
; Get the BIOS' idea of what the size of high memory is.
;
		push si				; Save our cluster pointer!
;
; First, try INT 15:E820 (get BIOS memory map)
;
get_e820:
		push es
		xor ebx,ebx			; Start with first record
		mov es,bx			; Need ES = DS = 0 for now
		jmp short .do_e820		; Skip "at end" check first time!
.int_loop:	and ebx,ebx			; If we're back at beginning...
		jz no_e820			; ... bail; nothing found
.do_e820:	mov eax,0000E820h
		mov edx,534D4150h		; "SMAP" backwards
		mov ecx,20
		mov di,E820Buf
		int 15h
		jc no_e820
		cmp eax,534D4150h
		jne no_e820
;
; Look for a memory block starting at <= 1 MB and continuing upward
;
		cmp dword [E820Buf+4], byte 0
		ja .int_loop			; Start >= 4 GB?
		mov edx, (1 << 20)
		sub edx, [E820Buf]
		jb .int_loop			; Start >= 1 MB?
		stc
		sbb eax,eax			; eax <- 0xFFFFFFFF
		cmp dword [E820Buf+12], byte 0
		ja .huge			; Size >= 4 GB
		mov eax, [E820Buf+8]
.huge:		sub eax, edx			; Adjust size to start at 1 MB
		jbe .int_loop			; Completely below 1 MB?

		; Now EAX contains the size of memory 1 MB...up
		cmp dword [E820Buf+16], byte 1
		jne near err_nohighmem		; High memory isn't usable memory!!!!

		; We're good!
		pop es
		jmp short got_highmem_add1mb	; Still need to add low 1 MB

;
; INT 15:E820 failed.  Try INT 15:E801.
;
no_e820:	pop es

		mov ax,0e801h			; Query high memory (semi-recent)
		int 15h
		jc no_e801
		cmp ax,3c00h
		ja no_e801			; > 3C00h something's wrong with this call
		jb e801_hole			; If memory hole we can only use low part

		mov ax,bx
		shl eax,16			; 64K chunks
		add eax,(16 << 20)		; Add first 16M
		jmp short got_highmem				

;
; INT 15:E801 failed.  Try INT 15:88.
;
no_e801:
		mov ah,88h			; Query high memory (oldest)
		int 15h
		cmp ax,14*1024			; Don't trust memory >15M
		jna e801_hole
		mov ax,14*1024
e801_hole:
		and eax,0ffffh
		shl eax,10			; Convert from kilobytes
got_highmem_add1mb:
		add eax,(1 << 20)		; First megabyte
got_highmem:
%if HIGHMEM_SLOP != 0
		sub eax,HIGHMEM_SLOP
%endif
		mov [HighMemSize],eax

;
; Construct the command line (append options have already been copied)
;
construct_cmdline:
		mov di,[CmdLinePtr]
                mov si,boot_image        	; BOOT_IMAGE=
                mov cx,boot_image_len
                rep movsb
                mov si,KernelCName       	; Unmangled kernel name
                mov cx,[KernelCNameLen]
                rep movsb
                mov al,' '                      ; Space
                stosb

		SPECIAL_APPEND			; Module-specific hook

                mov si,[CmdOptPtr]              ; Options from user input
		mov cx,(kern_cmd_len+3) >> 2
		rep movsd

;
; Scan through the command line for anything that looks like we might be
; interested in.  The original version of this code automatically assumed
; the first option was BOOT_IMAGE=, but that is no longer certain.
;
		mov si,cmd_line_here
                mov byte [initrd_flag],0
                push es				; Set DS <- real_mode_seg
                pop ds
get_next_opt:   lodsb
		and al,al
		jz near cmdline_end
		cmp al,' '
		jbe get_next_opt
		dec si
                mov eax,[si]
                cmp eax,'vga='
		je is_vga_cmd
                cmp eax,'mem='
		je is_mem_cmd
                push es                         ; Save ES -> real_mode_seg
                push cs
                pop es                          ; Set ES <- normal DS
                mov di,initrd_cmd
		mov cx,initrd_cmd_len
		repe cmpsb
                jne not_initrd
		mov di,InitRD
                push si                         ; mangle_dir mangles si
                call mangle_name                ; Mangle ramdisk name
                pop si
		cmp byte [es:InitRD],NULLFILE	; Null filename?
                seta byte [es:initrd_flag]	; Set flag if not
not_initrd:	pop es                          ; Restore ES -> real_mode_seg
skip_this_opt:  lodsb                           ; Load from command line
                cmp al,' '
                ja skip_this_opt
                dec si
                jmp short get_next_opt
is_vga_cmd:
                add si,byte 4
                mov eax,[si]
                mov bx,-1
                cmp eax, 'norm'                 ; vga=normal
                je vc0
                and eax,0ffffffh		; 3 bytes
                mov bx,-2
                cmp eax, 'ext'                  ; vga=ext
                je vc0
                mov bx,-3
                cmp eax, 'ask'                  ; vga=ask
                je vc0
                call parseint                   ; vga=<number>
		jc skip_this_opt		; Not an integer
vc0:		mov [bs_vidmode],bx		; Set video mode
		jmp short skip_this_opt
is_mem_cmd:
                add si,byte 4
                call parseint
		jc skip_this_opt		; Not an integer
%if HIGHMEM_SLOP != 0
		sub ebx,HIGHMEM_SLOP
%endif
		mov [cs:HighMemSize],ebx
		jmp short skip_this_opt
cmdline_end:
                push cs                         ; Restore standard DS
                pop ds
		sub si,cmd_line_here
		mov [CmdLineLen],si		; Length including final null
;
; Now check if we have a large kernel, which needs to be loaded high
;
		mov dword [RamdiskMax], HIGHMEM_MAX	; Default initrd limit
		cmp dword [es:su_header],HEADER_ID	; New setup code ID
		jne near old_kernel		; Old kernel, load low
		cmp word [es:su_version],0200h	; Setup code version 2.0
		jb near old_kernel		; Old kernel, load low
                cmp word [es:su_version],0201h	; Version 2.01+?
                jb new_kernel                   ; If 2.00, skip this step
                mov word [es:su_heapend],linux_stack	; Set up the heap
                or byte [es:su_loadflags],80h	; Let the kernel know we care
		cmp word [es:su_version],0203h	; Version 2.03+?
		jb new_kernel			; Not 2.03+
		mov eax,[es:su_ramdisk_max]
		mov [RamdiskMax],eax		; Set the ramdisk limit

;
; We definitely have a new-style kernel.  Let the kernel know who we are,
; and that we are clueful
;
new_kernel:
		mov byte [es:su_loader],my_id	; Show some ID
		movzx ax,byte [es:bs_setupsecs]	; Variable # of setup sectors
		mov [SetupSecs],ax
;
; About to load the kernel.  This is a modern kernel, so use the boot flags
; we were provided.
;
                mov al,[es:su_loadflags]
		mov [LoadFlags],al
;
; Load the kernel.  We always load it at 100000h even if we're supposed to
; load it "low"; for a "low" load we copy it down to low memory right before
; jumping to it.
;
read_kernel:
                mov si,KernelCName		; Print kernel name part of
                call cwritestr                  ; "Loading" message
                mov si,dotdot_msg		; Print dots
                call cwritestr

                mov eax,[HighMemSize]
		sub eax,100000h			; Load address
		cmp eax,[KernelSize]
		jb near no_high_mem		; Not enough high memory
;
; Move the stuff beyond the setup code to high memory at 100000h
;
		movzx esi,word [SetupSecs]	; Setup sectors
		inc si				; plus 1 boot sector
                shl si,9			; Convert to bytes
                mov ecx,8000h			; 32K
		sub ecx,esi			; Number of bytes to copy
		push ecx
		add esi,(real_mode_seg << 4)	; Pointer to source
                mov edi,100000h                 ; Copy to address 100000h

                call bcopy			; Transfer to high memory

		; On exit EDI -> where to load the rest

                mov si,dot_msg			; Progress report
                call cwritestr
                call abort_check

		pop ecx				; Number of bytes in the initial portion
		pop si				; Restore file handle/cluster pointer
		mov eax,[KernelSize]
		sub eax,ecx			; Amount of kernel left over
		jbe high_load_done		; Zero left (tiny kernel)

		call load_high			; Copy the file

high_load_done:
                mov ax,real_mode_seg		; Set to real mode seg
                mov es,ax

                mov si,dot_msg
                call cwritestr

;
; Now see if we have an initial RAMdisk; if so, do requisite computation
; We know we have a new kernel; the old_kernel code already will have objected
; if we tried to load initrd using an old kernel
;
load_initrd:
                test byte [initrd_flag],1
                jz near nk_noinitrd
                push es                         ; ES->real_mode_seg
                push ds
                pop es                          ; We need ES==DS
                mov si,InitRD
                mov di,InitRDCName
                call unmangle_name              ; Create human-readable name
                sub di,InitRDCName
                mov [InitRDCNameLen],di
                mov di,InitRD
                call searchdir                  ; Look for it in directory
                pop es
		jz initrd_notthere
		mov [es:su_ramdisklen1],ax	; Ram disk length
		mov [es:su_ramdisklen2],dx
		mov edx,[HighMemSize]		; End of memory
		dec edx
		mov eax,[RamdiskMax]		; Highest address allowed by kernel
		cmp edx,eax
		jna memsize_ok
		mov edx,eax			; Adjust to fit inside limit
memsize_ok:
		inc edx
                xor dx,dx			; Round down to 64K boundary
		sub edx,[es:su_ramdisklen]	; Subtract size of ramdisk
                xor dx,dx			; Round down to 64K boundary
                mov [es:su_ramdiskat],edx	; Load address
		call loadinitrd			; Load initial ramdisk
		jmp short initrd_end

initrd_notthere:
                mov si,err_noinitrd
                call cwritestr
                mov si,InitRDCName
                call cwritestr
                mov si,crlf_msg
                jmp abort_load

no_high_mem:    mov si,err_nohighmem		; Error routine
                jmp abort_load

initrd_end:
nk_noinitrd:
;
; Abandon hope, ye that enter here!  We do no longer permit aborts.
;
                call abort_check        	; Last chance!!

		mov si,ready_msg
		call cwritestr

		call vgaclearmode		; We can't trust ourselves after this

		UNLOAD_PREP			; Module-specific hook

;
; Now, if we were supposed to load "low", copy the kernel down to 10000h
; and the real mode stuff to 90000h.  We assume that all bzImage kernels are
; capable of starting their setup from a different address.
;
		mov ax,real_mode_seg
		mov fs,ax

;
; Copy command line.  Unfortunately, the kernel boot protocol requires
; the command line to exist in the 9xxxxh range even if the rest of the
; setup doesn't.
;
		cli				; In case of hooked interrupts
		test byte [LoadFlags],LOAD_HIGH
		jz need_high_cmdline
		cmp word [fs:su_version],0202h	; Support new cmdline protocol?
		jb need_high_cmdline
		; New cmdline protocol
		; Store 32-bit (flat) pointer to command line
		mov dword [fs:su_cmd_line_ptr],(real_mode_seg << 4) + cmd_line_here
		jmp short in_proper_place

need_high_cmdline:
;
; Copy command line up to 90000h
;
		mov ax,9000h
		mov es,ax
		mov si,cmd_line_here
		mov di,si
		mov [fs:kern_cmd_magic],word CMD_MAGIC ; Store magic
		mov [fs:kern_cmd_offset],di	; Store pointer

		mov cx,[CmdLineLen]
		add cx,byte 3
		shr cx,2			; Convert to dwords
		fs rep movsd

		push fs
		pop es

		test byte [LoadFlags],LOAD_HIGH
		jnz in_proper_place		; If high load, we're done

;
; Loading low; we can't assume it's safe to run in place.
;
; Copy real_mode stuff up to 90000h
;
		mov ax,9000h
		mov es,ax
		mov cx,[SetupSecs]
		inc cx				; Setup + boot sector
		shl cx,7			; Sectors -> dwords
		xor si,si
		xor di,di
		fs rep movsd			; Copy setup + boot sector
;
; Some kernels in the 1.2 ballpark but pre-bzImage have more than 4
; setup sectors, but the boot protocol had not yet been defined.  They
; rely on a signature to figure out if they need to copy stuff from
; the "protected mode" kernel area.  Unfortunately, we used that area
; as a transfer buffer, so it's going to find the signature there.
; Hence, zero the low 32K beyond the setup area.
;
		mov di,[SetupSecs]
		inc di				; Setup + boot sector
		mov cx,32768/512		; Sectors/32K
		sub cx,di			; Remaining sectors
		shl di,9			; Sectors -> bytes
		shl cx,7			; Sectors -> dwords
		xor eax,eax
		rep stosd			; Clear region
;
; Copy the kernel down to the "low" location
;
		mov ecx,[KernelSize]
		mov esi,100000h
		mov edi,10000h
		call bcopy

;
; Now everything is where it needs to be...
;
; When we get here, es points to the final segment, either
; 9000h or real_mode_seg
;
in_proper_place:

;
; If the default root device is set to FLOPPY (0000h), change to
; /dev/fd0 (0200h)
;
		cmp word [es:bs_rootdev],byte 0
		jne root_not_floppy
		mov word [es:bs_rootdev],0200h
root_not_floppy:
;
; Copy the disk table to high memory, then re-initialize the floppy
; controller
;
; This needs to be moved before the copy
;
%if 0
		push ds
		push bx
		lds si,[fdctab]
		mov di,linux_fdctab
		mov cx,3			; 12 bytes
		push di
		rep movsd
		pop di
		mov [fdctab1],di		; Save new floppy tab pos
		mov [fdctab2],es
		xor ax,ax
		xor dx,dx
		int 13h
		pop bx
		pop ds
%endif
;
; Linux wants the floppy motor shut off before starting the kernel,
; at least bootsect.S seems to imply so
;
kill_motor:
		mov dx,03F2h
		xor al,al
		call slow_out
;
; If we're debugging, wait for a keypress so we can read any debug messages
;
%ifdef debug
                xor ax,ax
                int 16h
%endif
;
; Set up segment registers and the Linux real-mode stack
; Note: es == the real mode segment
;
		cli
		mov bx,es
		mov ds,bx
		mov fs,bx
		mov gs,bx
		mov ss,bx
		mov sp,linux_stack
;
; We're done... now RUN THAT KERNEL!!!!
; Setup segment == real mode segment + 020h; we need to jump to offset
; zero in the real mode segment.
;
		add bx,020h
		push bx
		push word 0h
		retf

;
; Load an older kernel.  Older kernels always have 4 setup sectors, can't have
; initrd, and are always loaded low.
;
old_kernel:
                test byte [initrd_flag],1	; Old kernel can't have initrd
                jz load_old_kernel
                mov si,err_oldkernel
                jmp abort_load
load_old_kernel:
		mov word [SetupSecs],4		; Always 4 setup sectors
		mov byte [LoadFlags],0		; Always low
		jmp read_kernel

;
; Load RAM disk into high memory
;
; Need to be set:
;	su_ramdiskat	- Where in memory to load
;	su_ramdisklen	- Size of file
;	SI		- initrd filehandle/cluster pointer
;
loadinitrd:
                push es                         ; Save ES on entry
		mov ax,real_mode_seg
                mov es,ax
                mov edi,[es:su_ramdiskat]	; initrd load address
		push si
		mov si,crlfloading_msg		; Write "Loading "
		call cwritestr
                mov si,InitRDCName		; Write ramdisk name
                call cwritestr
                mov si,dotdot_msg		; Write dots
                call cwritestr
		pop si

		mov eax,[es:su_ramdisklen]
		call load_high			; Load the file

		call crlf
                pop es                          ; Restore original ES
                ret