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[/] [zet86/] [trunk/] [soc/] [bios/] [rombios.c] - Rev 26
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// ROM BIOS compatability entry points: // =================================== // $e05b ; POST Entry Point // $e6f2 ; INT 19h Boot Load Service Entry Point // $f045 ; INT 10 Functions 0-Fh Entry Point // $f065 ; INT 10h Video Support Service Entry Point // $f0a4 ; MDA/CGA Video Parameter Table (INT 1Dh) // $fff0 ; Power-up Entry Point // $fff5 ; ASCII Date ROM was built - 8 characters in MM/DD/YY // $fffe ; System Model ID #include "rombios.h" /* model byte 0xFC = AT */ #define SYS_MODEL_ID 0xFC #ifndef BIOS_BUILD_DATE # define BIOS_BUILD_DATE "06/23/99" #endif // 1K of base memory used for Extended Bios Data Area (EBDA) // EBDA is used for PS/2 mouse support, and IDE BIOS, etc. #define EBDA_SEG 0x9FC0 #define EBDA_SIZE 1 // In KiB #define BASE_MEM_IN_K (640 - EBDA_SIZE) /* 256 bytes at 0x9ff00 -- 0x9ffff is used for the IPL boot table. */ #define IPL_SEG 0x9ff0 #define IPL_TABLE_OFFSET 0x0000 #define IPL_TABLE_ENTRIES 8 #define IPL_COUNT_OFFSET 0x0080 /* u16: number of valid table entries */ #define IPL_SEQUENCE_OFFSET 0x0082 /* u16: next boot device */ #define IPL_BOOTFIRST_OFFSET 0x0084 /* u16: user selected device */ #define IPL_SIZE 0xff #define IPL_TYPE_FLOPPY 0x01 #define IPL_TYPE_HARDDISK 0x02 #define IPL_TYPE_CDROM 0x03 #define IPL_TYPE_BEV 0x80 // This is for compiling with gcc2 and gcc3 #define ASM_START #asm #define ASM_END #endasm ASM_START .rom .org 0x0000 use16 8086 MACRO SET_INT_VECTOR mov ax, ?3 mov ?1*4, ax mov ax, ?2 mov ?1*4+2, ax MEND ASM_END typedef unsigned char Bit8u; typedef unsigned short Bit16u; typedef unsigned short bx_bool; typedef unsigned long Bit32u; void memsetb(seg,offset,value,count); void memcpyb(dseg,doffset,sseg,soffset,count); void memcpyd(dseg,doffset,sseg,soffset,count); // memset of count bytes void memsetb(seg,offset,value,count) Bit16u seg; Bit16u offset; Bit16u value; Bit16u count; { ASM_START push bp mov bp, sp push ax push cx push es push di mov cx, 10[bp] ; count test cx, cx je memsetb_end mov ax, 4[bp] ; segment mov es, ax mov ax, 6[bp] ; offset mov di, ax mov al, 8[bp] ; value cld rep stosb memsetb_end: pop di pop es pop cx pop ax pop bp ASM_END } // memcpy of count bytes void memcpyb(dseg,doffset,sseg,soffset,count) Bit16u dseg; Bit16u doffset; Bit16u sseg; Bit16u soffset; Bit16u count; { ASM_START push bp mov bp, sp push ax push cx push es push di push ds push si mov cx, 12[bp] ; count test cx, cx je memcpyb_end mov ax, 4[bp] ; dsegment mov es, ax mov ax, 6[bp] ; doffset mov di, ax mov ax, 8[bp] ; ssegment mov ds, ax mov ax, 10[bp] ; soffset mov si, ax cld rep movsb memcpyb_end: pop si pop ds pop di pop es pop cx pop ax pop bp ASM_END } // Bit32u (unsigned long) and long helper functions ASM_START idiv_u: xor dx,dx div bx ret ldivul: mov cx,[di] mov di,2[di] call ludivmod xchg ax,cx xchg bx,di ret .align 2 ldivmod: mov dx,di ; sign byte of b in dh mov dl,bh ; sign byte of a in dl test di,di jns set_asign neg di neg cx sbb di,*0 set_asign: test bx,bx jns got_signs ; leave r = a positive neg bx neg ax sbb bx,*0 j got_signs .align 2 ludivmod: xor dx,dx ; both sign bytes 0 got_signs: push bp push si mov bp,sp push di ; remember b push cx b0 = -4 b16 = -2 test di,di jne divlarge test cx,cx je divzero cmp bx,cx jae divlarge ; would overflow xchg dx,bx ; a in dx:ax, signs in bx div cx xchg cx,ax ; q in di:cx, junk in ax xchg ax,bx ; signs in ax, junk in bx xchg ax,dx ; r in ax, signs back in dx mov bx,di ; r in bx:ax j zdivu1 divzero: ; return q = 0 and r = a test dl,dl jns return j negr ; a initially minus, restore it divlarge: push dx ; remember sign bytes mov si,di ; w in si:dx, initially b from di:cx mov dx,cx xor cx,cx ; q in di:cx, initially 0 mov di,cx ; r in bx:ax, initially a ; use di:cx rather than dx:cx in order ; to have dx free for a byte pair later cmp si,bx jb loop1 ja zdivu ; finished if b > r cmp dx,ax ja zdivu ; rotate w (= b) to greatest dyadic multiple of b <= r loop1: shl dx,*1 ; w = 2*w rcl si,*1 jc loop1_exit ; w was > r counting overflow (unsigned) cmp si,bx ; while w <= r (unsigned) jb loop1 ja loop1_exit cmp dx,ax jbe loop1 ; else exit with carry clear for rcr loop1_exit: rcr si,*1 rcr dx,*1 loop2: shl cx,*1 ; q = 2*q rcl di,*1 cmp si,bx ; if w <= r jb loop2_over ja loop2_test cmp dx,ax ja loop2_test loop2_over: add cx,*1 ; q++ adc di,*0 sub ax,dx ; r = r-w sbb bx,si loop2_test: shr si,*1 ; w = w/2 rcr dx,*1 cmp si,b16[bp] ; while w >= b ja loop2 jb zdivu cmp dx,b0[bp] jae loop2 zdivu: pop dx ; sign bytes zdivu1: test dh,dh js zbminus test dl,dl jns return ; else a initially minus, b plus mov dx,ax ; -a = b * q + r ==> a = b * (-q) + (-r) or dx,bx je negq ; use if r = 0 sub ax,b0[bp] ; use a = b * (-1 - q) + (b - r) sbb bx,b16[bp] not cx ; q = -1 - q (same as complement) not di negr: neg bx neg ax sbb bx,*0 return: mov sp,bp pop si pop bp ret .align 2 zbminus: test dl,dl ; (-a) = (-b) * q + r ==> a = b * q + (-r) js negr ; use if initial a was minus mov dx,ax ; a = (-b) * q + r ==> a = b * (-q) + r or dx,bx je negq ; use if r = 0 sub ax,b0[bp] ; use a = b * (-1 - q) + (b + r) ; (b is now -b) sbb bx,b16[bp] not cx not di mov sp,bp pop si pop bp ret .align 2 negq: neg di neg cx sbb di,*0 mov sp,bp pop si pop bp ret .align 2 ltstl: ltstul: test bx,bx je ltst_not_sure ret .align 2 ltst_not_sure: test ax,ax js ltst_fix_sign ret .align 2 ltst_fix_sign: inc bx ret .align 2 lmull: lmulul: mov cx,ax mul word ptr 2[di] xchg ax,bx mul word ptr [di] add bx,ax mov ax,ptr [di] mul cx add bx,dx ret .align 2 lsubl: lsubul: sub ax,[di] sbb bx,2[di] ret .align 2 laddl: laddul: add ax,[di] adc bx,2[di] ret .align 2 lorl: lorul: or ax,[di] or bx,2[di] ret .align 2 lsrul: mov cx,di jcxz lsru_exit cmp cx,*32 jae lsru_zero lsru_loop: shr bx,*1 rcr ax,*1 loop lsru_loop lsru_exit: ret .align 2 lsru_zero: xor ax,ax mov bx,ax ret .align 2 landl: landul: and ax,[di] and bx,2[di] ret .align 2 lcmpl: lcmpul: sub bx,2[di] je lcmp_not_sure ret .align 2 lcmp_not_sure: cmp ax,[di] jb lcmp_b_and_lt jge lcmp_exit inc bx lcmp_exit: ret .align 2 lcmp_b_and_lt: dec bx ret ASM_END typedef struct { Bit16u type; Bit16u flags; Bit32u vector; Bit32u description; Bit32u reserved; } ipl_entry_t; static Bit8u inb_cmos(); static Bit8u read_byte(); static Bit16u read_word(); static void write_byte(); static void write_word(); static void bios_printf(); static void int19_function(); static Bit16u get_CS(); static Bit16u get_SS(); static void print_bios_banner(); static void print_boot_device(); Bit8u inb_cmos(cmos_reg) Bit8u cmos_reg; { ASM_START push bp mov bp, sp mov al, 4[bp] ;; cmos_reg out 0x70, al in al, 0x71 pop bp ASM_END } Bit8u read_byte(seg, offset) Bit16u seg; Bit16u offset; { ASM_START push bp mov bp, sp push bx push ds mov ax, 4[bp] ; segment mov ds, ax mov bx, 6[bp] ; offset mov al, [bx] ;; al = return value (byte) pop ds pop bx pop bp ASM_END } Bit16u read_word(seg, offset) Bit16u seg; Bit16u offset; { ASM_START push bp mov bp, sp push bx push ds mov ax, 4[bp] ; segment mov ds, ax mov bx, 6[bp] ; offset mov ax, [bx] ;; ax = return value (word) pop ds pop bx pop bp ASM_END } void write_byte(seg, offset, data) Bit16u seg; Bit16u offset; Bit8u data; { ASM_START push bp mov bp, sp push ax push bx push ds mov ax, 4[bp] ; segment mov ds, ax mov bx, 6[bp] ; offset mov al, 8[bp] ; data byte mov [bx], al ; write data byte pop ds pop bx pop ax pop bp ASM_END } void write_word(seg, offset, data) Bit16u seg; Bit16u offset; Bit16u data; { ASM_START push bp mov bp, sp push ax push bx push ds mov ax, 4[bp] ; segment mov ds, ax mov bx, 6[bp] ; offset mov ax, 8[bp] ; data word mov [bx], ax ; write data word pop ds pop bx pop ax pop bp ASM_END } Bit16u get_CS() { ASM_START mov ax, cs ASM_END } Bit16u get_SS() { ASM_START mov ax, ss ASM_END } void wrch(c) Bit8u c; { ASM_START push bp mov bp, sp push bx mov ah, #0x0e mov al, 4[bp] xor bx,bx int #0x10 pop bx pop bp ASM_END } void send(action, c) Bit16u action; Bit8u c; { if (action & BIOS_PRINTF_SCREEN) { if (c == '\n') wrch('\r'); wrch(c); } } void put_int(action, val, width, neg) Bit16u action; short val, width; bx_bool neg; { short nval = val / 10; if (nval) put_int(action, nval, width - 1, neg); else { while (--width > 0) send(action, ' '); if (neg) send(action, '-'); } send(action, val - (nval * 10) + '0'); } void put_uint(action, val, width, neg) Bit16u action; unsigned short val; short width; bx_bool neg; { unsigned short nval = val / 10; if (nval) put_uint(action, nval, width - 1, neg); else { while (--width > 0) send(action, ' '); if (neg) send(action, '-'); } send(action, val - (nval * 10) + '0'); } void put_luint(action, val, width, neg) Bit16u action; unsigned long val; short width; bx_bool neg; { unsigned long nval = val / 10; if (nval) put_luint(action, nval, width - 1, neg); else { while (--width > 0) send(action, ' '); if (neg) send(action, '-'); } send(action, val - (nval * 10) + '0'); } void put_str(action, segment, offset) Bit16u action; Bit16u segment; Bit16u offset; { Bit8u c; while (c = read_byte(segment, offset)) { send(action, c); offset++; } } //-------------------------------------------------------------------------- // bios_printf() // A compact variable argument printf function. // // Supports %[format_width][length]format // where format can be x,X,u,d,s,S,c // and the optional length modifier is l (ell) //-------------------------------------------------------------------------- void bios_printf(action, s) Bit16u action; Bit8u *s; { Bit8u c, format_char; bx_bool in_format; short i; Bit16u *arg_ptr; Bit16u arg_seg, arg, nibble, hibyte, shift_count, format_width, hexadd; arg_ptr = &s; arg_seg = get_SS(); in_format = 0; format_width = 0; if ((action & BIOS_PRINTF_DEBHALT) == BIOS_PRINTF_DEBHALT) bios_printf (BIOS_PRINTF_SCREEN, "FATAL: "); while (c = read_byte(get_CS(), s)) { if ( c == '%' ) { in_format = 1; format_width = 0; } else if (in_format) { if ( (c>='0') && (c<='9') ) { format_width = (format_width * 10) + (c - '0'); } else { arg_ptr++; // increment to next arg arg = read_word(arg_seg, arg_ptr); if (c == 'x' || c == 'X') { if (format_width == 0) format_width = 4; if (c == 'x') hexadd = 'a'; else hexadd = 'A'; for (i=format_width-1; i>=0; i--) { nibble = (arg >> (4 * i)) & 0x000f; send (action, (nibble<=9)? (nibble+'0') : (nibble-10+hexadd)); } } else if (c == 'u') { put_uint(action, arg, format_width, 0); } else if (c == 'l') { s++; c = read_byte(get_CS(), s); /* is it ld,lx,lu? */ arg_ptr++; /* increment to next arg */ hibyte = read_word(arg_seg, arg_ptr); if (c == 'd') { if (hibyte & 0x8000) put_luint(action, 0L-(((Bit32u) hibyte << 16) | arg), format_width-1, 1); else put_luint(action, ((Bit32u) hibyte << 16) | arg, format_width, 0); } else if (c == 'u') { put_luint(action, ((Bit32u) hibyte << 16) | arg, format_width, 0); } else if (c == 'x' || c == 'X') { if (format_width == 0) format_width = 8; if (c == 'x') hexadd = 'a'; else hexadd = 'A'; for (i=format_width-1; i>=0; i--) { nibble = ((((Bit32u) hibyte <<16) | arg) >> (4 * i)) & 0x000f; send (action, (nibble<=9)? (nibble+'0') : (nibble-10+hexadd)); } } } else if (c == 'd') { if (arg & 0x8000) put_int(action, -arg, format_width - 1, 1); else put_int(action, arg, format_width, 0); } else if (c == 's') { put_str(action, get_CS(), arg); } else if (c == 'S') { hibyte = arg; arg_ptr++; arg = read_word(arg_seg, arg_ptr); put_str(action, hibyte, arg); } else if (c == 'c') { send(action, arg); } else BX_PANIC("bios_printf: unknown format\n"); in_format = 0; } } else { send(action, c); } s ++; } if (action & BIOS_PRINTF_HALT) { // freeze in a busy loop. ASM_START cli halt2_loop: hlt jmp halt2_loop ASM_END } } static char bios_svn_version_string[] = "$Revision: 1.1 $ $Date: 2008-10-01 02:25:51 $"; //-------------------------------------------------------------------------- // print_bios_banner // displays a the bios version //-------------------------------------------------------------------------- void print_bios_banner() { printf("Zet BIOS - build: %s\n%s\n", BIOS_BUILD_DATE, bios_svn_version_string); } //-------------------------------------------------------------------------- // BIOS Boot Specification 1.0.1 compatibility // // Very basic support for the BIOS Boot Specification, which allows expansion // ROMs to register themselves as boot devices, instead of just stealing the // INT 19h boot vector. // // This is a hack: to do it properly requires a proper PnP BIOS and we aren't // one; we just lie to the option ROMs to make them behave correctly. // We also don't support letting option ROMs register as bootable disk // drives (BCVs), only as bootable devices (BEVs). // // http://www.phoenix.com/en/Customer+Services/White+Papers-Specs/pc+industry+specifications.htm //-------------------------------------------------------------------------- static char drivetypes[][10]={"", "Floppy","Hard Disk","CD-Rom", "Network"}; static void init_boot_vectors() { ipl_entry_t e; Bit16u count = 0; Bit16u ss = get_SS(); /* Clear out the IPL table. */ memsetb(IPL_SEG, IPL_TABLE_OFFSET, 0, IPL_SIZE); /* User selected device not set */ write_word(IPL_SEG, IPL_BOOTFIRST_OFFSET, 0xFFFF); /* * Zet: We don't have support for floppy, hdd or cdrom */ /* Remember how many devices we have */ write_word(IPL_SEG, IPL_COUNT_OFFSET, count); /* Not tried booting anything yet */ write_word(IPL_SEG, IPL_SEQUENCE_OFFSET, 0xffff); } static Bit8u get_boot_vector(i, e) Bit16u i; ipl_entry_t *e; { Bit16u count; Bit16u ss = get_SS(); /* Get the count of boot devices, and refuse to overrun the array */ count = read_word(IPL_SEG, IPL_COUNT_OFFSET); if (i >= count) return 0; /* OK to read this device */ memcpyb(ss, e, IPL_SEG, IPL_TABLE_OFFSET + i * sizeof (*e), sizeof (*e)); return 1; } //-------------------------------------------------------------------------- // print_boot_device // displays the boot device //-------------------------------------------------------------------------- void print_boot_device(e) ipl_entry_t *e; { Bit16u type; char description[33]; Bit16u ss = get_SS(); type = e->type; /* NIC appears as type 0x80 */ if (type == IPL_TYPE_BEV) type = 0x4; if (type == 0 || type > 0x4) BX_PANIC("Bad drive type\n"); printf("Booting from %s", drivetypes[type]); /* print product string if BEV */ if (type == 4 && e->description != 0) { /* first 32 bytes are significant */ memcpyb(ss, &description, (Bit16u)(e->description >> 16), (Bit16u)(e->description & 0xffff), 32); /* terminate string */ description[32] = 0; printf(" [%S]", ss, description); } printf("...\n"); } void int19_function(seq_nr) Bit16u seq_nr; { Bit16u ebda_seg=read_word(0x0040,0x000E); Bit16u bootdev; Bit8u bootdrv; Bit8u bootchk; Bit16u bootseg; Bit16u bootip; Bit16u status; Bit16u bootfirst; ipl_entry_t e; // Here we assume that BX_ELTORITO_BOOT is defined, so // CMOS regs 0x3D and 0x38 contain the boot sequence: // CMOS reg 0x3D & 0x0f : 1st boot device // CMOS reg 0x3D & 0xf0 : 2nd boot device // CMOS reg 0x38 & 0xf0 : 3rd boot device // boot device codes: // 0x00 : not defined // 0x01 : first floppy // 0x02 : first harddrive // 0x03 : first cdrom // 0x04 - 0x0f : PnP expansion ROMs (e.g. Etherboot) // else : boot failure // Get the boot sequence bootdev = inb_cmos(0x3d); bootdev |= ((inb_cmos(0x38) & 0xf0) << 4); bootdev >>= 4 * seq_nr; bootdev &= 0xf; /* Read user selected device */ bootfirst = read_word(IPL_SEG, IPL_BOOTFIRST_OFFSET); if (bootfirst != 0xFFFF) { bootdev = bootfirst; /* User selected device not set */ write_word(IPL_SEG, IPL_BOOTFIRST_OFFSET, 0xFFFF); /* Reset boot sequence */ write_word(IPL_SEG, IPL_SEQUENCE_OFFSET, 0xFFFF); } else if (bootdev == 0) BX_PANIC("No bootable device.\n"); /* Translate from CMOS runes to an IPL table offset by subtracting 1 */ bootdev -= 1; /* Read the boot device from the IPL table */ if (get_boot_vector(bootdev, &e) == 0) { BX_INFO("Invalid boot device (0x%x)\n", bootdev); return; } /* Do the loading, and set up vector as a far pointer to the boot * address, and bootdrv as the boot drive */ print_boot_device(&e); switch(e.type) { case IPL_TYPE_BEV: /* Expansion ROM with a Bootstrap Entry Vector (a far pointer) */ bootseg = e.vector >> 16; bootip = e.vector & 0xffff; break; default: return; } /* Debugging info */ BX_INFO("Booting from %x:%x\n", bootseg, bootip); /* Jump to the boot vector */ ASM_START mov bp, sp ;; Build an iret stack frame that will take us to the boot vector. ;; iret pops ip, then cs, then flags, so push them in the opposite order. pushf mov ax, _int19_function.bootseg + 0[bp] push ax mov ax, _int19_function.bootip + 0[bp] push ax ;; Set the magic number in ax and the boot drive in dl. mov ax, #0xaa55 mov dl, _int19_function.bootdrv + 0[bp] ;; Zero some of the other registers. xor bx, bx mov ds, bx mov es, bx mov bp, bx ;; Go! iret ASM_END } ASM_START ;---------- ;- INT18h - ;---------- int18_handler: ;; Boot Failure recovery: try the next device. ;; Reset SP and SS mov ax, #0xfffe mov sp, ax xor ax, ax mov ss, ax ;; Get the boot sequence number out of the IPL memory mov bx, #IPL_SEG mov ds, bx ;; Set segment mov bx, IPL_SEQUENCE_OFFSET ;; BX is now the sequence number inc bx ;; ++ mov IPL_SEQUENCE_OFFSET, bx ;; Write it back mov ds, ax ;; and reset the segment to zero. ;; Carry on in the INT 19h handler, using the new sequence number push bx jmp int19_next_boot ;---------- ;- INT19h - ;---------- int19_relocated: ;; Boot function, relocated ;; int19 was beginning to be really complex, so now it ;; just calls a C function that does the work push bp mov bp, sp ;; Reset SS and SP mov ax, #0xfffe mov sp, ax xor ax, ax mov ss, ax ;; Start from the first boot device (0, in AX) mov bx, #IPL_SEG mov ds, bx ;; Set segment to write to the IPL memory mov IPL_SEQUENCE_OFFSET, ax ;; Save the sequence number mov ds, ax ;; and reset the segment. push ax int19_next_boot: ;; Call the C code for the next boot device call _int19_function ;; Boot failed: invoke the boot recovery function int #0x18 ;-------------------- ;- POST: EBDA segment ;-------------------- ; relocated here because the primary POST area isnt big enough. ebda_post: #if BX_USE_EBDA mov ax, #EBDA_SEG mov ds, ax mov byte ptr [0x0], #EBDA_SIZE #endif xor ax, ax ; mov EBDA seg into 40E mov ds, ax mov word ptr [0x40E], #EBDA_SEG ret;; rom_checksum: push ax push bx push cx xor ax, ax xor bx, bx xor cx, cx mov ch, [2] shl cx, #1 checksum_loop: add al, [bx] inc bx loop checksum_loop and al, #0xff pop cx pop bx pop ax ret ;; We need a copy of this string, but we are not actually a PnP BIOS, ;; so make sure it is *not* aligned, so OSes will not see it if they scan. .align 16 db 0 pnp_string: .ascii "$PnP" rom_scan: ;; Scan for existence of valid expansion ROMS. ;; Video ROM: from 0xC0000..0xC7FFF in 2k increments ;; General ROM: from 0xC8000..0xDFFFF in 2k increments ;; System ROM: only 0xE0000 ;; ;; Header: ;; Offset Value ;; 0 0x55 ;; 1 0xAA ;; 2 ROM length in 512-byte blocks ;; 3 ROM initialization entry point (FAR CALL) rom_scan_loop: push ax ;; Save AX mov ds, cx mov ax, #0x0004 ;; start with increment of 4 (512-byte) blocks = 2k cmp [0], #0xAA55 ;; look for signature jne rom_scan_increment call rom_checksum jnz rom_scan_increment mov al, [2] ;; change increment to ROM length in 512-byte blocks ;; We want our increment in 512-byte quantities, rounded to ;; the nearest 2k quantity, since we only scan at 2k intervals. test al, #0x03 jz block_count_rounded and al, #0xfc ;; needs rounding up add al, #0x04 block_count_rounded: xor bx, bx ;; Restore DS back to 0000: mov ds, bx push ax ;; Save AX push di ;; Save DI ;; Push addr of ROM entry point push cx ;; Push seg push #0x0003 ;; Push offset ;; Point ES:DI at "$PnP", which tells the ROM that we are a PnP BIOS. ;; That should stop it grabbing INT 19h; we will use its BEV instead. mov ax, #0xf000 mov es, ax lea di, pnp_string mov bp, sp ;; Call ROM init routine using seg:off on stack db 0xff ;; call_far ss:[bp+0] db 0x5e db 0 cli ;; In case expansion ROM BIOS turns IF on add sp, #2 ;; Pop offset value pop cx ;; Pop seg value (restore CX) ;; Look at the ROM's PnP Expansion header. Properly, we're supposed ;; to init all the ROMs and then go back and build an IPL table of ;; all the bootable devices, but we can get away with one pass. mov ds, cx ;; ROM base mov bx, 0x001a ;; 0x1A is the offset into ROM header that contains... mov ax, [bx] ;; the offset of PnP expansion header, where... cmp ax, #0x5024 ;; we look for signature "$PnP" jne no_bev mov ax, 2[bx] cmp ax, #0x506e jne no_bev mov ax, 0x1a[bx] ;; 0x1A is also the offset into the expansion header of... cmp ax, #0x0000 ;; the Bootstrap Entry Vector, or zero if there is none. je no_bev ;; Found a device that thinks it can boot the system. Record its BEV and product name string. mov di, 0x10[bx] ;; Pointer to the product name string or zero if none mov bx, #IPL_SEG ;; Go to the segment where the IPL table lives mov ds, bx mov bx, IPL_COUNT_OFFSET ;; Read the number of entries so far cmp bx, #IPL_TABLE_ENTRIES je no_bev ;; Get out if the table is full push cx mov cx, #0x4 ;; Zet: Needed to be compatible with 8086 shl bx, cl ;; Turn count into offset (entries are 16 bytes) pop cx mov 0[bx], #IPL_TYPE_BEV ;; This entry is a BEV device mov 6[bx], cx ;; Build a far pointer from the segment... mov 4[bx], ax ;; and the offset cmp di, #0x0000 je no_prod_str mov 0xA[bx], cx ;; Build a far pointer from the segment... mov 8[bx], di ;; and the offset no_prod_str: push cx mov cx, #0x4 shr bx, cl ;; Turn the offset back into a count pop cx inc bx ;; We have one more entry now mov IPL_COUNT_OFFSET, bx ;; Remember that. no_bev: pop di ;; Restore DI pop ax ;; Restore AX rom_scan_increment: push cx mov cx, #5 shl ax, cl ;; convert 512-bytes blocks to 16-byte increments ;; because the segment selector is shifted left 4 bits. pop cx add cx, ax pop ax ;; Restore AX cmp cx, ax jbe rom_scan_loop xor ax, ax ;; Restore DS back to 0000: mov ds, ax ret ;; for 'C' strings and other data, insert them here with ;; a the following hack: ;; DATA_SEG_DEFS_HERE ;; the following area can be used to write dynamically generated tables .align 16 bios_table_area_start: dd 0xaafb4442 dd bios_table_area_end - bios_table_area_start - 8; ;-------- ;- POST - ;-------- .org 0xe05b ; POST Entry Point post: xor ax, ax normal_post: ; case 0: normal startup cli mov ax, #0xfffe mov sp, ax xor ax, ax mov ds, ax mov ss, ax ;; zero out BIOS data area (40:00..40:ff) mov es, ax mov cx, #0x0080 ;; 128 words mov di, #0x0400 cld rep stosw ;; set all interrupts to default handler xor bx, bx ;; offset index mov cx, #0x0100 ;; counter (256 interrupts) mov ax, #dummy_iret_handler mov dx, #0xF000 post_default_ints: mov [bx], ax add bx, #2 mov [bx], dx add bx, #2 loop post_default_ints ;; set vector 0x79 to zero ;; this is used by 'gardian angel' protection system SET_INT_VECTOR(0x79, #0, #0) ;; base memory in K 40:13 (word) mov ax, #BASE_MEM_IN_K mov 0x0413, ax ;; Manufacturing Test 40:12 ;; zerod out above ;; Warm Boot Flag 0040:0072 ;; value of 1234h = skip memory checks ;; zerod out above ;; Bootstrap failure vector SET_INT_VECTOR(0x18, #0xF000, #int18_handler) ;; Bootstrap Loader vector SET_INT_VECTOR(0x19, #0xF000, #int19_handler) ;; EBDA setup call ebda_post ;; Video setup SET_INT_VECTOR(0x10, #0xF000, #int10_handler) mov cx, #0xc000 ;; init vga bios mov ax, #0xc780 call rom_scan call _print_bios_banner call _init_boot_vectors mov cx, #0xc800 ;; init option roms mov ax, #0xe000 call rom_scan sti ;; enable interrupts int #0x19 ;---------- ;- INT19h - ;---------- .org 0xe6f2 ; INT 19h Boot Load Service Entry Point int19_handler: jmp int19_relocated .org 0xf045 ; INT 10 Functions 0-Fh Entry Point ;; HALT(__LINE__) iret ;---------- ;- INT10h - ;---------- .org 0xf065 ; INT 10h Video Support Service Entry Point int10_handler: ;; dont do anything, since the VGA BIOS handles int10h requests iret .org 0xf0a4 ; MDA/CGA Video Parameter Table (INT 1Dh) ;------------------------------------------------ ;- IRET Instruction for Dummy Interrupt Handler - ;------------------------------------------------ .org 0xff53 ; IRET Instruction for Dummy Interrupt Handler dummy_iret_handler: iret .org 0xfff0 ; Power-up Entry Point jmp 0xf000:post .org 0xfff5 ; ASCII Date ROM was built - 8 characters in MM/DD/YY .ascii BIOS_BUILD_DATE .org 0xfffe ; System Model ID db SYS_MODEL_ID db 0x00 ; filler ASM_END ASM_START .org 0xcc00 bios_table_area_end: // bcc-generated data will be placed here ASM_END
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