/* $OpenBSD: biosboot.S,v 1.41 2011/07/05 17:38:54 krw Exp $ */ /* * Copyright (c) 2003 Tobias Weingartner * Copyright (c) 2003 Tom Cosgrove * Copyright (c) 1997 Michael Shalayeff, Tobias Weingartner * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED * WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. * */ .file "biosboot.S" #include #include /* Error indicators */ #define PBR_READ_ERROR 'R' #define PBR_CANT_BOOT 'X' #define PBR_BAD_MAGIC 'M' #define PBR_TOO_MANY_INDIRECTS 'I' #define CHAR_BLOCK_READ '.' #define CHAR_CHS_READ ';' /* * Memory layout: * * 0x00000 -> 0x07BFF our stack (to 31k) * 0x07A00 -> 0x07BFF typical MBR loc (at 30k5) * 0x07C00 -> 0x07DFF our code (at 31k) * 0x07E00 -> ... /boot inode block (at 31k5) * 0x07E00 -> ... (indirect block if nec) * 0x40000 -> ... /boot (at 256k) * * The BIOS loads the MBR at physical address 0x07C00. It then relocates * itself to (typically) 0x07A00. * * The MBR then loads us at physical address 0x07C00. * * We use a long jmp to normalise our address to seg:offset 07C0:0000. * (In real mode on x86, segment registers contain a base address in * paragraphs (16 bytes). 0000:00010 is the same as 0001:0000.) * * We set the stack to start at 0000:7BFC (grows down on i386) * * We then read the inode for /boot into memory just above us at * 07E0:0000, and run through the direct block table (and the first * indirect block table, if necessary). * * We load /boot at seg:offset 4000:0000. * * Previous versions limited the size of /boot to 64k (loaded in a single * segment). This version does not have this limitation. */ #define INODESEG 0x07e0 /* where we put /boot's inode's block */ #define INDIRECTSEG 0x07e0 /* where we put indirect table, if nec */ #define BOOTSEG 0x07c0 /* biosboot loaded here */ #define BOOTSTACKOFF ((BOOTSEG << 4) - 4) /* stack starts here, grows down */ #define LFMAGIC 0x464c /* LFMAGIC (last two bytes of \7fELF) */ #define ELFMAGIC 0x464c457f /* ELFMAGIC ("\7fELF") */ #define INODEOFF ((INODESEG-BOOTSEG) << 4) /* * The data passed by installboot is: * * inodeblk uint32 the filesystem block that holds /boot's inode * inodedbl uint32 the memory offset to the beginning of the * direct block list (di_db[]). (This is the * offset within the block + $INODEOFF, which is * where we load the block to.) * fs_bsize_p uint16 the filesystem block size _in paragraphs_ * (i.e. fs_bsize / 16) * fs_bsize_s uint16 the number of disk sectors in a filesystem * block (i.e. fs_bsize / d_secsize). Directly written * into the LBA command block, at lba_count. * XXX LIMITED TO 127 BY PHOENIX EDD SPEC. * fsbtodb uint8 shift count to convert filesystem blocks to * disk blocks (sectors). Note that this is NOT * log2 fs_bsize, since fragmentation allows * the trailing part of a file to use part of a * filesystem block. In other words, filesystem * block numbers can point into the middle of * filesystem blocks. * p_offset uint32 the starting disk block (sector) of the * filesystem * nblocks uint16 the number of filesystem blocks to read. * While this can be calculated as * howmany(di_size, fs_bsize) it takes us too * many code bytes to do it. * * All of these are patched directly into the code where they are used * (once only, each), to save space. * * One more symbol is exported, in anticipation of a "-c" flag in * installboot to force CHS reads: * * force_chs uint8 set to the value 1 to force biosboot to use CHS * reads (this will of course cause the boot sequence * to fail if /boot is above 8 GB). */ .globl inodeblk, inodedbl, fs_bsize_p, fsbtodb, p_offset, nblocks .globl fs_bsize_s, force_chs .type inodeblk, @function .type inodedbl, @function .type fs_bsize_p, @function .type fs_bsize_s, @function .type fsbtodb, @function .type p_offset, @function .type nblocks, @function .type force_chs, @function /* Clobbers %ax, maybe more */ #define putc(c) movb $c, %al; call Lchr /* Clobbers %ax, %si, maybe more */ #define puts(s) movw $s, %si; call Lmessage .text .code16 .globl _start _start: jmp begin nop /* * BIOS Parameter Block. Read by many disk utilities. * * We would have liked biosboot to go from the superblock to * the root directory to the inode for /boot, thence to read * its blocks into memory. * * As code and data space is quite tight in the 512-byte * partition boot sector, we instead get installboot to pass * us some pre-processed fields. * * We would have liked to put these in the BIOS parameter block, * as that seems to be the right place to put them (it's really * the equivalent of the superblock for FAT filesystems), but * caution prevents us. * * For now, these fields are either directly in the code (when they * are used once only) or at the end of this sector. */ . = _start + 3 .asciz "OpenBSD" /* BPB */ . = _start + 0x0b bpb: .word DEV_BSIZE /* sector size */ .byte 2 /* sectors/cluster */ .word 0 /* reserved sectors */ .byte 0 /* # of FAT */ .word 0 /* root entries */ .word 0 /* small sectors */ .byte 0xf8 /* media type (hd) */ .word 0 /* sectors/fat */ .word 0 /* sectors per track */ .word 0 /* # of heads */ /* EBPB */ . = _start + 0x1c ebpb: .long 16 /* hidden sectors */ .long 0 /* large sectors */ .word 0 /* physical disk */ .byte 0x29 /* signature, needed by NT */ .space 4, 0 /* volume serial number */ .asciz "UNIX LABEL" .asciz "UFS 4.4" /* boot code */ . = _start + 0x3e begin: /* Fix up %cs just in case */ ljmp $BOOTSEG, $main /* * Come here if we have to do a CHS boot, but we get an error from * BIOS get drive parameters, or it returns nsectors == 0 (in which * case we can't do the division we need to convert LBA sector * number to CHS). */ cant_boot: movb $PBR_CANT_BOOT, %al jmp err_print_crlf main: /* Set up stack */ xorw %ax, %ax movw %ax, %ss movw $BOOTSTACKOFF, %sp /* Set up needed data segment reg */ pushw %cs popw %ds /* Now %cs == %ds, != %ss (%ss == 0) */ #ifdef SERIAL /* Initialize the serial port to 9600 baud, 8N1 */ push %dx movw $0x00e3, %ax movw SERIAL, %dx int $0x14 pop %dx #endif #ifdef BDEBUG putc('R') #endif /* * We're going to print our sign-on message. * * We're now LBA-aware, and will use LBA to load /boot if the * BIOS says it's available. However, we have seen machines * where CHS is required even when LBA is available. Therefore * we provide a way to force CHS use: * * If the SHIFT key is held down on entry, force CHS reads. */ movw $load_msg+1, %si /* "Loading" */ movb %dl, %dh /* * BIOS call "INT 0x16 Get Keyboard Shift Flags * Call with %ah = 0x02 * Return: * %al = shift flags * %ah - undefined by many BIOSes */ movb $0x02, %ah int $0x16 /* * We provide the ability to force CHS use without having to hold * down the SHIFT key each boot. Just set the byte at force_chs * to 1 (more accurately any value with either of the bottom two * bits set, but the use of 1 is recommended). */ force_chs = .+1 orb $0, %al testb $0x3, %al /* Either shift key down? */ jz no_force_chs decw %si /* "!Loading" indicates forced CHS */ xorb %dh, %dh /* Pretend a floppy, so no LBA use */ no_force_chs: /* Print pretty message */ call Lmessage /* * We will use LBA reads if we have LBA support, so find out. */ /* * But don't even try on floppies, OR if forcing to CHS. * * (We're really testing %dl, but use %dh so we can force the * top bit to zero to force CHS boot.) */ testb $0x80, %dh jz no_lba /* * BIOS call "INT 0x13 Extensions Installation Check" * Call with %ah = 0x41 * %bx = 0x55AA * %dl = drive (0x80 for 1st hd, 0x81 for 2nd, etc) * Return: * carry set: failure * %ah = error code (0x01, invalid func) * carry clear: success * %bx = 0xAA55 (must verify) * %ah = major version of extensions * %al (internal use) * %cx = capabilities bitmap * 0x0001 - extnd disk access funcs * 0x0002 - rem. drive ctrl funcs * 0x0004 - EDD functions with EBP * %dx (extension version?) */ pushw %dx /* Save the drive number (%dl) */ movw $0x55AA, %bx movb $0x41, %ah int $0x13 popw %dx /* Retrieve drive number */ jc no_lba /* Did the command work? Jump if not */ cmpw $0xAA55, %bx /* Check that bl, bh exchanged */ jne no_lba /* If not, don't have EDD extensions */ testb $0x01, %cl /* And do we have "read" available? */ jz no_lba /* Again, use CHS if not */ /* We have LBA support, so that's the vector to use */ movw $load_lba, load_fsblock jmp get_going no_lba: pushw %dx /* * BIOS call "INT 0x13 Function 0x08" to get drive parameters * Call with %ah = 0x08 * %dl = drive (0x80 for 1st hd, 0x81 for 2nd...) * Return: * carry set: failure * %ah = err code * carry clear: success * %ah = 0x00 * %al = 0x00 (some BIOSes) * %ch = 0x00 (some BIOSes) * %ch = max-cylinder & 0xFF * %cl = max sector | rest of max-cyl bits * %dh = max head number * %dl = number of drives * (according to Ralph Brown Int List) */ movb $0x08, %ah int $0x13 /* We need to know heads & sectors */ jc cant_boot /* If error, can't boot */ movb %dh, maxheads /* Remember this */ andb $0x3F, %cl jz cant_boot movb %cl, nsectors putc(CHAR_CHS_READ) /* Indicate (subtly) CHS reads */ popw %dx /* Retrieve the drive number */ get_going: /* * Older versions of biosboot used to set up the destination * segment, and increase the target offset every time a number * of blocks was read. That limits /boot to 64k. * * In order to support /boots > 64k, we always read to offset * 0000 in the target segment, and just increase the target segment * each time. */ /* * We would do movl inodeblk, %eax here, but that instruction * is 4 bytes long; add 4 bytes for data takes 8 bytes. Using * a load immediate takes 6 bytes, and we just get installboot * to patch here, rather than data anywhere else. */ inodeblk = .+2 movl $0x90909090, %eax /* mov $inodeblk, %eax */ movw $INODESEG, %bx /* Where to put /boot's inode */ /* * %eax - filesystem block to read * %bx - target segment (target offset is 0000) * %dl - BIOS drive number */ call *load_fsblock /* This will crash'n'burn on errs */ /* * We now have /boot's inode in memory. * * /usr/include/ufs/ufs/dinode.h for the details: * * Offset 8 (decimal): 64-bit file size (only use low 32 bits) * Offset 40 (decimal): list of NDADDR (12) direct disk blocks * Offset 88 (decimal): list of NIADDR (3) indirect disk blocks * * NOTE: list of indirect blocks immediately follows list of * direct blocks. We use this fact in the code. * * We only support loading from direct blocks plus the first * indirect block. This is the same as the previous biosboot/ * installboot limit. Note that, with default 16,384-bytes * filesystem blocks, the direct block list supports files up * to 192 KB. /boot is currently around 60 KB. * * The on-disk format can't change (filesystems with this format * already exist) so okay to hardcode offsets here. * * The nice thing about doing things with filesystem blocks * rather than sectors is that filesystem blocks numbers have * 32 bits, so fit into a single register (even if "e"d). * * Note that this code does need updating if booting from a new * filesystem is required. */ #define NDADDR 12 #define di_db 40 /* Not used; addr put in by instboot */ #define di_ib 88 /* Not used; run on from direct blks */ /* * Register usage: * * %eax - block number for load_fsblock * %bx - target segment (target offset is 0000) for load_fsblock * %dl - BIOS drive number for load_fsblock * %esi - points to block table in inode/indirect block * %cx - number of blocks to load within loop (i.e. from current * block list, which is either the direct block list di_db[] * or the indirect block list) * %di - total number of blocks to load */ /* * We would do movl inodedbl, %esi here, but that instruction * is 4 bytes long; add 4 bytes for data takes 8 bytes. Using * a load immediate takes 6 bytes, and we just get installboot * to patch here, rather than in data anywhere else. */ inodedbl = .+2 movl $0x90909090, %esi /* mov $inodedbl, %esi */ /* Now esi -> di_db[] */ nblocks = .+1 movw $0x9090, %di /* mov nblocks, %di */ movw %di, %cx cmpw $NDADDR, %cx jc 1f movw $NDADDR, %cx 1: /* %cx = min(nblocks, $NADDR) */ movw $(LOADADDR >> 4), %bx /* Target segment for /boot */ load_blocks: putc(CHAR_BLOCK_READ) /* Show progress indicator */ cld /* Get the next filesystem block number into %eax */ lodsl /* %eax = *(%si++), make sure 0x66 0xad */ pushal /* Save all 32-bit registers */ /* * Read a single filesystem block (will almost certainly be multiple * disk sectors) * * %eax - filesystem block to read * %bx - target segment (target offset is 0000) * %dl - BIOS drive number */ call *load_fsblock /* This will crash'n'burn on errs */ popal /* Restore 32-bit registers */ /* * We want to put addw fs_bsize_p, %bx, which takes 4 bytes * of code and two bytes of data. * * Instead, use an immediate load, and have installboot patch * here directly. */ /* Move on one filesystem block */ fs_bsize_p = .+2 addw $0x9090, %bx /* addw $fs_bsize_p, %bx */ decw %di loop load_blocks /* %cx == 0 ... important it stays this way (used later) */ /* * Finished reading a set of blocks. * * This was either the direct blocks, and there may or may not * be indirect blocks to read, or it was the indirect blocks, * and we may or may not have read in all of /boot. (Ideally * will have read in all of /boot.) */ orw %di, %di jz done_load /* No more sectors to read */ /* We have more blocks to load */ /* We only support a single indirect block (the same as previous * versions of installboot. This is required for the boot floppies. * * We use a bit of the code to store a flag that indicates * whether we have read the first indirect block or not. * * If we've already read the indirect list, we can't load this /boot. * * indirect uint8 0 => running through load_blocks loop reading * direct blocks. If != 0, we're reading the * indirect blocks. Must use a field that is * initialised to 0. */ indirect = .+2 movw $PBR_TOO_MANY_INDIRECTS, %ax /* movb $PRB_TOO..., %al */ /* movb indirect, %ah */ orb %ah, %ah jnz err_print_crlf incb indirect /* No need to worry about wrap */ /* around, as this will only be done */ /* once before we fail */ /* Okay, let's read in the indirect block */ lodsl /* Get blk num of 1st indirect blk */ pushw %bx /* Remember where we got to */ movw $INODESEG, %bx call *load_fsblock /* This will crash'n'burn on errs */ popw %bx /* Indirect blocks get added on to */ /* just after where we got to */ movl $INODEOFF, %esi movw %di, %cx /* How many blocks left to read */ jmp load_blocks done_load: puts(crlf) /* %cx == 0 from loop above... keep it that way */ /* * Check the magic signature at the beginning of /boot. * Since /boot is now ELF, this should be 0x7F E L F. */ movw $(LOADADDR >> 4), %ax /* Target segment */ movw %ax, %es /* * We cheat a little here, and only check the L and F. * * (Saves 3 bytes of code... the two signature bytes we * don't check, and the operand size prefix that's not * needed.) */ cmpw $LFMAGIC, %es:2(,1) je exec_boot movb $PBR_BAD_MAGIC, %al err_print: movw $err_txt, %si err_print2: movb %al, err_id err_stop: call Lmessage stay_stopped: sti /* Ensure Ctl-Alt-Del will work */ hlt /* (don't require power cycle) */ jmp stay_stopped /* Just to make sure :-) */ exec_boot: /* At this point we could try to use the entry point in * the image we just loaded. But if we do that, we also * have to potentially support loading that image where it * is supposed to go. Screw it, just assume that the image * is sane. */ #ifdef BDEBUG putc('P') #endif /* %cx == 0 from loop above... keep it that way */ /* * We want to do movzbl %dl, %eax ; pushl %eax to zero-extend the * drive number to 32 bits and pass it to /boot. However, this * takes 6 bytes. * * Doing it this way saves 2 bytes. */ pushw %cx movb %dl, %cl pushw %cx pushl $BOOTMAGIC /* use some magic */ /* jmp /boot */ ljmp $(LINKADDR >> 4), $0 /* not reached */ /* * Load a single filesystem block into memory using CHS calls. * * Input: %eax - 32-bit filesystem block number * %bx - target segment (target offset is 0000) * %dl - BIOS drive number * * Output: block successfully read in (panics if not) * all general purpose registers may have been trashed */ load_chs: /* * BIOS call "INT 0x13 Function 0x2" to read sectors from disk into * memory. * Call with %ah = 0x42 * %ah = 0x2 * %al = number of sectors * %ch = cylinder & 0xFF * %cl = sector (0-63) | rest of cylinder bits * %dh = head * %dl = drive (0x80 for 1st hd, 0x81 for 2nd...) * %es:%bx = segment:offset of buffer * Return: * carry set: failure * %ah = err code * %al = number of sectors transferred * carry clear: success * %al = 0x0 OR number of sectors transferred * (depends on BIOS!) * (according to Ralph Brown Int List) */ /* Convert the filesystem block into a sector value */ call fsbtosector movl lba_sector, %eax /* we can only use 24 bits, really */ movw fs_bsize_s, %cx /* sectors per filesystem block */ /* * Some BIOSes require that reads don't cross track boundaries. * Therefore we do all CHS reads single-sector. */ calc_chs: pushal movw %bx, %es /* Set up target segment */ pushw %dx /* Save drive number (in %dl) */ xorl %edx, %edx movl %edx, %ecx nsectors = .+1 movb $0x90, %cl /* movb $nsectors, %cl */ /* Doing it this way saves 4-2 = 2 bytes code */ /* bytes (no data, since we would overload) */ divl %ecx, %eax /* Now have sector number in %dl */ pushw %dx /* Remember for later */ xorl %edx, %edx maxheads = .+1 movb $0x90, %cl /* movb $maxheads, %cl; 0 <= maxheads <= 255 */ /* Doing it this way saves 4-2 = 2 code */ /* bytes (no data, since we would overload */ incw %cx /* Number of heads is 1..256, no "/0" worries */ divl %ecx, %eax /* Have head number in %dl */ /* Cylinder number in %ax */ movb %al, %ch /* Bottom 8 bits of cyl number */ shlb $6, %ah /* Move up top 2 bits of cyl number */ movb %ah, %cl /* Top 2 bits of cyl number in here */ popw %bx /* (pushed %dx, but need %dl for now */ incb %bl /* Sector numbers run from 1, not 0 */ orb %bl, %cl /* Or the sector number into top bits cyl */ /* Remember, %dl has head number */ popw %ax /* %al has BIOS drive number -> %dl */ movb %dl, %dh /* Now %dh has head number (from 0) */ movb %al, %dl /* Now %dl has BIOS drive number */ xorw %bx, %bx /* Set up target offset */ movw $0x0201, %ax /* %al = 1 - read one sector at a time */ /* %ah = 2 - int 0x13 function for CHS read */ call do_int_13 /* saves us 1 byte :-) */ /* Get the next sector */ popal incl %eax addw $32, %bx /* Number of segments/paras in a sector */ loop calc_chs ret /* read error */ read_error: movb $PBR_READ_ERROR, %al err_print_crlf: movw $err_txt_crlf, %si jmp err_print2 /* * Load a single filesystem block into memory using LBA calls. * * Input: %eax - 32-bit filesystem block number * %bx - target segment (target offset is 0000) * %dl - BIOS drive number * * Output: block successfully read in (panics if not) * all general purpose registers may have been trashed */ load_lba: /* * BIOS call "INT 0x13 Extensions Extended Read" * Call with %ah = 0x42 * %dl = drive (0x80 for 1st hd, 0x81 for 2nd, etc) * %ds:%si = segment:offset of command packet * Return: * carry set: failure * %ah = error code (0x01, invalid func) * command packet's sector count field set * to the number of sectors successfully * transferred * carry clear: success * %ah = 0 (success) * Command Packet: * 0x0000 BYTE packet size (0x10 or 0x18) * 0x0001 BYTE reserved (should be 0) * 0x0002 WORD sectors to transfer (max 127) * 0x0004 DWORD seg:offset of transfer buffer * 0x0008 QWORD starting sector number */ call fsbtosector /* Set up lba_sector & lba_sector+4 */ /* movb %dh, lba_count <- XXX done by installboot */ movw %bx, lba_seg movw $lba_command, %si movb $0x42, %ah do_int_13: int $0x13 jc read_error ret /* * Converts a given filesystem block number into a disk sector * at lba_sector and lba_sector+4. * * Input: %eax - 32-bit filesystem block number * * Output: lba_sector and lba_sector+4 set up * XXX */ fsbtosector: /* * We want to do * * movb fsbtodb, %ch /# Shift counts we'll need #/ * movb $32, %cl * * which is 6 bytes of code + 1 byte of data. * * We'll actually code it with an immediate 16-bit load into %cx, * which is just 3 bytes of data (saves 4 bytes). */ fsbtodb = .+2 movw $0x9020, %cx /* %ch = fsbtodb, %cl = 0x20 */ pushl %eax subb %ch, %cl shrl %cl, %eax movl %eax, lba_sector+4 popl %eax movb %ch, %cl shll %cl, %eax /* * And add p_offset, which is the block offset to the start * of the filesystem. * * We would do addl p_offset, %eax, which is 5 bytes of code * and 4 bytes of data, but it's more efficient to have * installboot patch directly in the code (this variable is * only used here) for 6 bytes of code (but no data). */ p_offset = .+2 addl $0x90909090, %eax /* addl $p_offset, %eax */ movl %eax, lba_sector jnc 1f incl lba_sector+4 1: ret /* * Display string */ Lmessage: cld 1: lodsb /* load a byte into %al */ orb %al, %al jz 1f call Lchr jmp 1b /* * Lchr: write the character in %al to console */ Lchr: #ifdef SERIAL pushw %dx movb $0x01, %ah xorw %dx, %dx movb SERIAL, %dl int $0x14 popw %dx #else pushw %bx movb $0x0e, %ah xorw %bx, %bx incw %bx /* movw $0x01, %bx */ int $0x10 popw %bx #endif 1: ret /* .data */ /* vector to the routine to read a particular filesystem block for us */ load_fsblock: .word load_chs /* This next block is used for the EDD command packet used to read /boot * sectors. * * lba_count is set up for us by installboot. It is the number of sectors * in a filesystem block. (Max value 127.) * * XXX The EDD limit of 127 sectors in one read means that we currently * restrict filesystem blocks to 127 sectors, or < 64 KB. That is * effectively a 32 KB block limit, as filesystem block sizes are * powers of two. The default filesystem block size is 16 KB. * * I say we run with this limitation and see where it bites us... */ lba_command: .byte 0x10 /* size of command packet */ .byte 0x00 /* reserved */ fs_bsize_s: lba_count: .word 0 /* sectors to transfer, max 127 */ .word 0 /* target buffer, offset */ lba_seg: .word 0 /* target buffer, segment */ lba_sector: .long 0, 0 /* sector number */ load_msg: .asciz "!Loading" err_txt_crlf: .ascii "\r\n" err_txt: .ascii "ERR " err_id: .ascii "?" crlf: .asciz "\r\n" . = 0x200 - 2 /* a little signature */ .word DOSMBR_SIGNATURE