FreeDOS/boot/boot.asm

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2012-10-15 02:08:06 +02:00
;
; File:
; boot.asm
; Description:
; DOS-C boot
;
; Copyright (c) 1997;
; Svante Frey
; All Rights Reserved
;
; This file is part of DOS-C.
;
; DOS-C 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; either version
; 2, or (at your option) any later version.
;
; DOS-C is distributed in the hope that it will be useful, but
; WITHOUT ANY WARRANTY; without even the implied warranty of
; MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See
; the GNU General Public License for more details.
;
; You should have received a copy of the GNU General Public
; License along with DOS-C; see the file COPYING. If not,
; write to the Free Software Foundation, 675 Mass Ave,
; Cambridge, MA 02139, USA.
;
;
; +--------+ 1FE0:7E00
; |BOOT SEC|
; |RELOCATE|
; |--------| 1FE0:7C00
; |LBA PKT |
; |--------| 1FE0:7BC0
; |--------| 1FE0:7BA0
; |BS STACK|
; |--------|
; |4KBRDBUF| used to avoid crossing 64KB DMA boundary
; |--------| 1FE0:63A0
; | |
; |--------| 1FE0:3000
; | CLUSTER|
; | LIST |
; |--------| 1FE0:2000
; | |
; |--------| 0000:7E00
; |BOOT SEC| overwritten by max 128k FAT buffer
; |ORIGIN | and later by max 134k loaded kernel
; |--------| 0000:7C00
; | |
; |--------|
; |KERNEL | also used as max 128k FAT buffer
; |LOADED | before kernel loading starts
; |--------| 0060:0000
; | |
; +--------+
;%define ISFAT12 1
;%define ISFAT16 1
segment .text
%define BASE 0x7c00
org BASE
Entry: jmp short real_start
nop
; bp is initialized to 7c00h
%define bsOemName bp+0x03 ; OEM label
%define bsBytesPerSec bp+0x0b ; bytes/sector
%define bsSecPerClust bp+0x0d ; sectors/allocation unit
%define bsResSectors bp+0x0e ; # reserved sectors
%define bsFATs bp+0x10 ; # of fats
%define bsRootDirEnts bp+0x11 ; # of root dir entries
%define bsSectors bp+0x13 ; # sectors total in image
%define bsMedia bp+0x15 ; media descrip: fd=2side9sec, etc...
%define sectPerFat bp+0x16 ; # sectors in a fat
%define sectPerTrack bp+0x18 ; # sectors/track
%define nHeads bp+0x1a ; # heads
%define nHidden bp+0x1c ; # hidden sectors
%define nSectorHuge bp+0x20 ; # sectors if > 65536
%define drive bp+0x24 ; drive number
%define extBoot bp+0x26 ; extended boot signature
%define volid bp+0x27
%define vollabel bp+0x2b
%define filesys bp+0x36
%define LOADSEG 0x0060
%define FATBUF 0x2000 ; offset of temporary buffer for FAT
; chain
; Some extra variables
;%define StoreSI bp+3h ;temp store
;-----------------------------------------------------------------------
times 0x3E-$+$$ db 0
; using bp-Entry+loadseg_xxx generates smaller code than using just
; loadseg_xxx, where bp is initialized to Entry, so bp-Entry equals 0
%define loadsegoff_60 bp-Entry+loadseg_off
%define loadseg_60 bp-Entry+loadseg_seg
%define LBA_PACKET bp-0x40
%define LBA_SIZE word [LBA_PACKET] ; size of packet, should be 10h
%define LBA_SECNUM word [LBA_PACKET+2] ; number of sectors to read
%define LBA_OFF LBA_PACKET+4 ; buffer to read/write to
%define LBA_SEG LBA_PACKET+6
%define LBA_SECTOR_0 word [LBA_PACKET+8 ] ; LBA starting sector #
%define LBA_SECTOR_16 word [LBA_PACKET+10]
%define LBA_SECTOR_32 word [LBA_PACKET+12]
%define LBA_SECTOR_48 word [LBA_PACKET+14]
%define READBUF 0x63A0 ; max 4KB buffer (min 2KB stack), == stacktop-0x1800
%define READADDR_OFF BP-0x60-0x1804 ; pointer within user buffer
%define READADDR_SEG BP-0x60-0x1802
%define PARAMS LBA_PACKET+0x10
;%define RootDirSecs PARAMS+0x0 ; # of sectors root dir uses
%define fat_start PARAMS+0x2 ; first FAT sector
%define root_dir_start PARAMS+0x6 ; first root directory sector
%define data_start PARAMS+0x0a ; first data sector
;-----------------------------------------------------------------------
; ENTRY
;-----------------------------------------------------------------------
real_start:
cli
cld
xor ax, ax
mov ds, ax
mov bp, BASE
; a reset should not be needed here
; int 0x13 ; reset drive
; int 0x12 ; get memory available in AX
; mov ax, 0x01e0
; mov cl, 6 ; move boot sector to higher memory
; shl ax, cl
; sub ax, 0x07e0
mov ax, 0x1FE0
mov es, ax
mov si, bp
mov di, bp
mov cx, 0x0100
rep movsw
jmp word 0x1FE0:cont
loadseg_off dw 0
loadseg_seg dw LOADSEG
cont:
mov ds, ax
mov ss, ax
lea sp, [bp-0x60]
sti
;
; Note: some BIOS implementations may not correctly pass drive number
; in DL, however we work around this in SYS.COM by NOP'ing out the use of DL
; (formerly we checked for [drive]==0xff; update sys.c if code moves)
;
mov [drive], dl ; rely on BIOS drive number in DL
mov LBA_SIZE, 10h
mov LBA_SECNUM,1 ; initialise LBA packet constants
mov word [LBA_SEG],ds
mov word [LBA_OFF],READBUF
; GETDRIVEPARMS: Calculate start of some disk areas.
;
mov si, word [nHidden]
mov di, word [nHidden+2]
add si, word [bsResSectors]
adc di, byte 0 ; DI:SI = first FAT sector
mov word [fat_start], si
mov word [fat_start+2], di
mov al, [bsFATs]
cbw
mul word [sectPerFat] ; DX:AX = total number of FAT sectors
add si, ax
adc di, dx ; DI:SI = first root directory sector
mov word [root_dir_start], si
mov word [root_dir_start+2], di
; Calculate how many sectors the root directory occupies.
mov bx, [bsBytesPerSec]
mov cl, 5 ; divide BX by 32
shr bx, cl ; BX = directory entries per sector
mov ax, [bsRootDirEnts]
xor dx, dx
div bx
; mov word [RootDirSecs], ax ; AX = sectors per root directory
push ax
add si, ax
adc di, byte 0 ; DI:SI = first data sector
mov [data_start], si
mov [data_start+2], di
; FINDFILE: Searches for the file in the root directory.
;
; Returns:
; AX = first cluster of file
; First, read the whole root directory
; into the temporary buffer.
mov ax, word [root_dir_start]
mov dx, word [root_dir_start+2]
pop di ; mov di, word [RootDirSecs]
les bx, [loadsegoff_60] ; es:bx = 60:0
call readDisk
les di, [loadsegoff_60] ; es:di = 60:0
; Search for KERNEL.SYS file name, and find start cluster.
next_entry: mov cx, 11
mov si, filename
push di
repe cmpsb
pop di
mov ax, [es:di+0x1A]; get cluster number from directory entry
je ffDone
add di, byte 0x20 ; go to next directory entry
cmp byte [es:di], 0 ; if the first byte of the name is 0,
jnz next_entry ; there is no more files in the directory
jc boot_error ; fail if not found
ffDone:
push ax ; store first cluster number
; GETFATCHAIN:
;
; Reads the FAT chain and stores it in a temporary buffer in the first
; 64 kb. The FAT chain is stored an array of 16-bit cluster numbers,
; ending with 0.
;
; The file must fit in conventional memory, so it can't be larger than
; 640 kb. The sector size must be at least 512 bytes, so the FAT chain
; can't be larger than 2.5 KB (655360 / 512 * 2 = 2560).
;
; Call with: AX = first cluster in chain
les bx, [loadsegoff_60] ; es:bx=60:0
mov di, [sectPerFat]
mov ax, word [fat_start]
mov dx, word [fat_start+2]
call readDisk
pop ax ; restore first cluster number
; Set ES:DI to the temporary storage for the FAT chain.
push ds
pop es
mov ds, [loadseg_60]
mov di, FATBUF
next_clust: stosw ; store cluster number
mov si, ax ; SI = cluster number
%ifdef ISFAT12
; This is a FAT-12 disk.
fat_12: add si, si ; multiply cluster number by 3...
add si, ax
shr si, 1 ; ...and divide by 2
lodsw
; If the cluster number was even, the cluster value is now in
; bits 0-11 of AX. If the cluster number was odd, the cluster
; value is in bits 4-15, and must be shifted right 4 bits. If
; the number was odd, CF was set in the last shift instruction.
jnc fat_even
mov cl, 4
shr ax, cl
fat_even: and ah, 0x0f ; mask off the highest 4 bits
cmp ax, 0x0ff8 ; check for EOF
jb next_clust ; continue if not EOF
%endif
%ifdef ISFAT16
; This is a FAT-16 disk. The maximal size of a 16-bit FAT
; is 128 kb, so it may not fit within a single 64 kb segment.
fat_16: mov dx, [loadseg_60]
add si, si ; multiply cluster number by two
jnc first_half ; if overflow...
add dh, 0x10 ; ...add 64 kb to segment value
first_half: mov ds, dx ; DS:SI = pointer to next cluster
lodsw ; AX = next cluster
cmp ax, 0xfff8 ; >= FFF8 = 16-bit EOF
jb next_clust ; continue if not EOF
%endif
finished: ; Mark end of FAT chain with 0, so we have a single
; EOF marker for both FAT-12 and FAT-16 systems.
xor ax, ax
stosw
push cs
pop ds
; loadFile: Loads the file into memory, one cluster at a time.
les bx, [loadsegoff_60] ; set ES:BX to load address 60:0
mov si, FATBUF ; set DS:SI to the FAT chain
cluster_next: lodsw ; AX = next cluster to read
or ax, ax ; EOF?
jne load_next ; no, continue
mov bl,dl ; drive (left from readDisk)
jmp far [loadsegoff_60] ; yes, pass control to kernel
load_next: dec ax ; cluster numbers start with 2
dec ax
mov di, word [bsSecPerClust]
and di, 0xff ; DI = sectors per cluster
mul di
add ax, [data_start]
adc dx, [data_start+2] ; DX:AX = first sector to read
call readDisk
jmp short cluster_next
; shows text after the call to this function.
show.do_show:
mov ah, 0Eh ; show character
int 10h ; via "TTY" mode
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show: pop si
lodsb ; get character
push si ; stack up potential return address
cmp al, 0 ; end of string?
jne .do_show ; until done
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ret
boot_error: call show
; db "Error! Hit a key to reboot.",0
db "Error!",0
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xor ah,ah
int 0x13 ; reset floppy
int 0x16 ; wait for a key
int 0x19 ; reboot the machine
; readDisk: Reads a number of sectors into memory.
;
; Call with: DX:AX = 32-bit DOS sector number
; DI = number of sectors to read
; ES:BX = destination buffer
;
; Returns: CF set on error
; ES:BX points one byte after the last byte read.
readDisk: push si
mov LBA_SECTOR_0,ax
mov LBA_SECTOR_16,dx
mov word [READADDR_SEG], es
mov word [READADDR_OFF], bx
call show
db ".",0
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read_next:
;******************** LBA_READ *******************************
; check for LBA support
mov ah,041h ;
mov bx,055aah ;
mov dl, [drive]
; NOTE: sys must be updated if location changes!!!
test dl,dl ; don't use LBA addressing on A:
jz read_normal_BIOS ; might be a (buggy)
; CDROM-BOOT floppy emulation
int 0x13
jc read_normal_BIOS
shr cx,1 ; CX must have 1 bit set
sbb bx,0aa55h - 1 ; tests for carry (from shr) too!
jne read_normal_BIOS
; OK, drive seems to support LBA addressing
lea si,[LBA_PACKET]
; setup LBA disk block
mov LBA_SECTOR_32,bx ; bx is 0 if extended 13h mode supported
mov LBA_SECTOR_48,bx
mov ah,042h
jmp short do_int13_read
read_normal_BIOS:
;******************** END OF LBA_READ ************************
mov cx,LBA_SECTOR_0
mov dx,LBA_SECTOR_16
;
; translate sector number to BIOS parameters
;
;
; abs = sector offset in track
; + head * sectPerTrack offset in cylinder
; + track * sectPerTrack * nHeads offset in platter
;
mov al, [sectPerTrack]
mul byte [nHeads]
xchg ax, cx
; cx = nHeads * sectPerTrack <= 255*63
; dx:ax = abs
div cx
; ax = track, dx = sector + head * sectPertrack
xchg ax, dx
; dx = track, ax = sector + head * sectPertrack
div byte [sectPerTrack]
; dx = track, al = head, ah = sector
mov cx, dx
; cx = track, al = head, ah = sector
; the following manipulations are necessary in order to
; properly place parameters into registers.
; ch = cylinder number low 8 bits
; cl = 7-6: cylinder high two bits
; 5-0: sector
mov dh, al ; save head into dh for bios
xchg ch, cl ; set cyl no low 8 bits
ror cl, 1 ; move track high bits into
ror cl, 1 ; bits 7-6 (assumes top = 0)
or cl, ah ; merge sector into cylinder
inc cx ; make sector 1-based (1-63)
les bx,[LBA_OFF]
mov ax, 0x0201
do_int13_read:
mov dl, [drive]
int 0x13
jc boot_error ; exit on error
mov ax, word [bsBytesPerSec]
push di
mov si,READBUF ; copy read in sector data to
les di,[READADDR_OFF] ; user provided buffer
mov cx, ax
; shr cx, 1 ; convert bytes to word count
; rep movsw
rep movsb
pop di
; div byte[LBA_PACKET] ; luckily 16 !!
mov cl, 4
shr ax, cl ; adjust segment pointer by increasing
add word [READADDR_SEG], ax ; by paragraphs read in (per sector)
add LBA_SECTOR_0, byte 1
adc LBA_SECTOR_16, byte 0 ; DX:AX = next sector to read
dec di ; if there is anything left to read,
jnz read_next ; continue
les bx, [READADDR_OFF]
; clear carry: unnecessary since adc clears it
pop si
ret
times 0x01f1-$+$$ db 0
filename db "KERNEL SYS",0,0
sign dw 0xAA55
%ifdef DBGPRNNUM
; DEBUG print hex digit routines
PrintLowNibble: ; Prints low nibble of AL, AX is destroyed
and AL, 0Fh ; ignore upper nibble
cmp AL, 09h ; if greater than 9, then don't base on '0', base on 'A'
jbe .printme
add AL, 7 ; convert to character A-F
.printme:
add AL, '0' ; convert to character 0-9
mov AH,0x0E ; show character
int 0x10 ; via "TTY" mode
retn
PrintAL: ; Prints AL, AX is preserved
push AX ; store value so we can process a nibble at a time
shr AL, 4 ; move upper nibble into lower nibble
call PrintLowNibble
pop AX ; restore for other nibble
push AX ; but save so we can restore original AX
call PrintLowNibble
pop AX ; restore for other nibble
retn
PrintNumber: ; Prints (in Hex) value in AX, AX is preserved
xchg AH, AL ; high byte 1st
call PrintAL
xchg AH, AL ; now low byte
call PrintAL
retn
%endif