1 ; -*- fundamental -*- (asm-mode sucks) 2 ; **************************************************************************** 3 ; 4 ; pxelinux.asm 5 ; 6 ; A program to boot Linux kernels off a TFTP server using the Intel PXE 7 ; network booting API. It is based on the SYSLINUX boot loader for 8 ; MS-DOS floppies. 9 ; 10 ; Copyright 1994-2009 H. Peter Anvin - All Rights Reserved 11 ; Copyright 2009 Intel Corporation; author: H. Peter Anvin 12 ; 13 ; This program is free software; you can redistribute it and/or modify 14 ; it under the terms of the GNU General Public License as published by 15 ; the Free Software Foundation, Inc., 53 Temple Place Ste 330, 16 ; Boston MA 02111-1307, USA; either version 2 of the License, or 17 ; (at your option) any later version; incorporated herein by reference. 18 ; 19 ; **************************************************************************** 20 21 %define IS_PXELINUX 1 22 %include "head.inc" 1 <1> ; -*- fundamental -*- (asm-mode sucks) 2 <1> ; ----------------------------------------------------------------------- 3 <1> ; 4 <1> ; Copyright 2006-2008 H. Peter Anvin - All Rights Reserved 5 <1> ; 6 <1> ; This program is free software; you can redistribute it and/or modify 7 <1> ; it under the terms of the GNU General Public License as published by 8 <1> ; the Free Software Foundation, Inc., 53 Temple Place Ste 330, 9 <1> ; Boston MA 02111-1307, USA; either version 2 of the License, or 10 <1> ; (at your option) any later version; incorporated herein by reference. 11 <1> ; 12 <1> ; ----------------------------------------------------------------------- 13 <1> 14 <1> ; 15 <1> ; head.inc 16 <1> ; 17 <1> ; Common header includes 18 <1> ; 19 <1> 20 <1> %ifndef _HEAD_INC 21 <1> %define _HEAD_INC 22 <1> 23 <1> %if __NASM_MAJOR__ < 2 || (__NASM_MAJOR__ == 2 && __NASM_MINOR__ < 3) 24 <1> %error "NASM 2.03 or later required to compile correctly" 25 <1> %elif __NASM_VERSION_ID__ == 0x020b0600 26 <1> %fatal "NASM 2.11.06 is known to miscompile Syslinux" 27 <1> %endif 28 <1> 29 <1> %include "macros.inc" 1 <2> ;; ----------------------------------------------------------------------- 2 <2> ;; 3 <2> ;; Copyright 1994-2008 H. Peter Anvin - All Rights Reserved 4 <2> ;; Copyright 2009 Intel Corporation; author: H. Peter Anvin 5 <2> ;; 6 <2> ;; This program is free software; you can redistribute it and/or modify 7 <2> ;; it under the terms of the GNU General Public License as published by 8 <2> ;; the Free Software Foundation, Inc., 53 Temple Place Ste 330, 9 <2> ;; Boston MA 02111-1307, USA; either version 2 of the License, or 10 <2> ;; (at your option) any later version; incorporated herein by reference. 11 <2> ;; 12 <2> ;; ----------------------------------------------------------------------- 13 <2> 14 <2> ;; 15 <2> ;; macros.inc 16 <2> ;; 17 <2> ;; Convenient macros 18 <2> ;; 19 <2> 20 <2> %ifndef _MACROS_INC 21 <2> %define _MACROS_INC 22 <2> 23 <2> ; 24 <2> ; Identify the module we're compiling; the "correct" should be defined 25 <2> ; in the module itself to 1 26 <2> ; 27 <2> %ifdef IS_SYSLINUX 28 <2> %define MY_NAME 'SYSLINUX' 29 <2> %else 30 <2> %define IS_SYSLINUX 0 31 <2> %endif 32 <2> %ifdef IS_PXELINUX 33 <2> %define MY_NAME 'PXELINUX' 34 <2> %if IS_LPXELINUX > 0 35 <2> %define MY_TYPE 'lwIP' 36 <2> %else 37 <2> %define MY_TYPE 'PXE' 38 <2> %endif 39 <2> %else 40 <2> %define IS_PXELINUX 0 41 <2> %endif 42 <2> %ifdef IS_ISOLINUX 43 <2> %define MY_NAME 'ISOLINUX' 44 <2> %else 45 <2> %define IS_ISOLINUX 0 46 <2> %endif 47 <2> %ifdef IS_EXTLINUX 48 <2> %define MY_NAME 'EXTLINUX' 49 <2> %else 50 <2> %define IS_EXTLINUX 0 51 <2> %endif 52 <2> 53 <2> ; 54 <2> ; Macros similar to res[bwd], but which works in the code segment (after 55 <2> ; section .text16) or the data segment (section .data16) 56 <2> ; 57 <2> %macro zb 1.nolist 58 <2> times %1 db 0 59 <2> %endmacro 60 <2> 61 <2> %macro zw 1.nolist 62 <2> times %1 dw 0 63 <2> %endmacro 64 <2> 65 <2> %macro zd 1.nolist 66 <2> times %1 dd 0 67 <2> %endmacro 68 <2> 69 <2> ; 70 <2> ; Align with zero bytes in a progbits segment 71 <2> ; 72 <2> %macro alignz 1.nolist 73 <2> times (((%1) - (($-$$) % (%1))) % (%1)) db 0 74 <2> %endmacro 75 <2> 76 <2> ; 77 <2> ; Macro to emit an unsigned decimal number as a string 78 <2> ; 79 <2> %macro asciidec 1.nolist 80 <2> %ifndef DEPEND ; Not safe for "depend" 81 <2> %push asciidec 82 <2> %assign %$v %1 83 <2> %if %$v == 0 84 <2> db '0' 85 <2> %else 86 <2> %assign %$dcount 0 87 <2> %assign %$n %$v 88 <2> %assign %$d 1 89 <2> %rep 20 90 <2> %if %$n != 0 91 <2> %assign %$dcount %$dcount + 1 92 <2> %assign %$n %$n / 10 93 <2> %assign %$d %$d * 10 94 <2> %endif 95 <2> %endrep 96 <2> %rep %$dcount 97 <2> %assign %$d %$d / 10 98 <2> db ((%$v / %$d) % 10) + '0' 99 <2> %endrep 100 <2> %endif 101 <2> %pop 102 <2> %endif 103 <2> %endmacro 104 <2> 105 <2> ; 106 <2> ; Macros for network byte order of constants 107 <2> ; 108 <2> %define htons(x) ( ( ((x) & 0FFh) << 8 ) + ( ((x) & 0FF00h) >> 8 ) ) 109 <2> %define ntohs(x) htons(x) 110 <2> %define htonl(x) ( ( ((x) & 0FFh) << 24) + ( ((x) & 0FF00h) << 8 ) + ( ((x) & 0FF0000h) >> 8 ) + ( ((x) & 0FF000000h) >> 24) ) 111 <2> %define ntohl(x) htonl(x) 112 <2> 113 <2> ; 114 <2> ; ASCII 115 <2> ; 116 <2> CR equ 13 ; Carriage Return 117 <2> LF equ 10 ; Line Feed 118 <2> FF equ 12 ; Form Feed 119 <2> BS equ 8 ; Backspace 120 <2> 121 <2> %endif ; _MACROS_INC 30 <1> %include "config.inc" 1 <2> ;; ----------------------------------------------------------------------- 2 <2> ;; 3 <2> ;; Copyright 2002-2009 H. Peter Anvin - All Rights Reserved 4 <2> ;; Copyright 2009 Intel Corporation; author: H. Peter Anvin 5 <2> ;; 6 <2> ;; This program is free software; you can redistribute it and/or modify 7 <2> ;; it under the terms of the GNU General Public License as published by 8 <2> ;; the Free Software Foundation, Inc., 53 Temple Place Ste 330, 9 <2> ;; Boston MA 02111-1307, USA; either version 2 of the License, or 10 <2> ;; (at your option) any later version; incorporated herein by reference. 11 <2> ;; 12 <2> ;; ----------------------------------------------------------------------- 13 <2> 14 <2> ;; 15 <2> ;; config.inc 16 <2> ;; 17 <2> ;; Common configuration options. Some of these are imposed by the kernel. 18 <2> ;; 19 <2> 20 <2> %ifndef _CONFIG_INC 21 <2> %define _CONFIG_INC 22 <2> 23 <2> max_cmd_len equ 2047 ; Must be &3; 2047 is the kernel limit 24 <2> HIGHMEM_MAX equ 037FFFFFFh ; DEFAULT highest address for an initrd 25 <2> DEFAULT_BAUD equ 9600 ; Default baud rate for serial port 26 <2> BAUD_DIVISOR equ 115200 ; Serial port parameter 27 <2> MAX_FKEYS equ 12 ; Number of F-key help files 28 <2> 29 <2> ; 30 <2> ; log2(Max filename size Including final null) 31 <2> ; 32 <2> FILENAME_MAX_LG2 equ 8 33 <2> FILENAME_MAX equ (1 << FILENAME_MAX_LG2) ; Max mangled filename size 34 <2> 35 <2> ; 36 <2> ; Version number definitinons 37 <2> ; 38 <2> %include "../version.gen" 1 <3> %define VERSION 6.04 2 <3> %define VERSION_STR "6.04" 3 <3> %define VERSION_MAJOR 6 4 <3> %define VERSION_MINOR 4 5 <3> %define YEAR 2015 6 <3> %define YEAR_STR "2015" 39 <2> 40 <2> %endif ; _CONFIG_INC 31 <1> %include "layout.inc" 1 <2> ; ----------------------------------------------------------------------- 2 <2> ; 3 <2> ; Copyright 1994-2009 H. Peter Anvin - All Rights Reserved 4 <2> ; Copyright 2009-2010 Intel Corporation; author: H. Peter Anvin 5 <2> ; 6 <2> ; This program is free software; you can redistribute it and/or modify 7 <2> ; it under the terms of the GNU General Public License as published by 8 <2> ; the Free Software Foundation, Inc., 53 Temple Place Ste 330, 9 <2> ; Bostom MA 02111-1307, USA; either version 2 of the License, or 10 <2> ; (at your option) any later version; incorporated herein by reference. 11 <2> ; 12 <2> ; ----------------------------------------------------------------------- 13 <2> 14 <2> ; 15 <2> ; layout.inc 16 <2> ; 17 <2> ; Memory layout of segments 18 <2> ; 19 <2> 20 <2> ; Default to 16-bit code 21 <2> bits 16 22 <2> 23 <2> ; Memory below 0800h is reserved for the BIOS and the MBR. 24 <2> BSS_START equ 0800h 25 <2> 26 <2> ; Text starts at the load address of 07C00h. 27 <2> TEXT_START equ 7C00h 28 <2> 29 <2> ; 30 <2> ; 16-bit stack layout 31 <2> ; 32 <2> ; PXELINUX: There are apparently some AMI BIOSes in the field which 33 <2> ; put their BEV stack somewhere below 7C00h (and therefore don't 34 <2> ; handle localboot properly), so avoid that immediate memory region. 35 <2> ; The range that is known to be bad is approximately 75E8..7C00; the 36 <2> ; lower bound is tight. 37 <2> ; 38 <2> global STACK_LEN, STACK_TOP, STACK_BASE 39 <2> STACK_LEN equ 4096 40 <2> %if IS_PXELINUX 41 <2> STACK_TOP equ 7000h 42 <2> %else 43 <2> STACK_TOP equ 7c00h 44 <2> %endif 45 <2> STACK_BASE equ STACK_TOP - STACK_LEN 46 <2> 47 <2> ; The secondary BSS section, above the text; we really wish we could 48 <2> ; just make it follow .bcopy32 or hang off the end, 49 <2> ; but it doesn't seem to work that way. 50 <2> LATEBSS_START equ 0B800h 51 <2> 52 <2> ; 53 <2> ; 32-bit stack layout 54 <2> ; 55 <2> STACK32_LEN equ 64*1024 56 <2> 57 <2> section .stack nobits write align=4096 58 00000000 <2> resb STACK32_LEN 59 <2> 60 <2> ; 61 <2> ; The various sections and their relationship 62 <2> ; 63 <2> ; Use .earlybss for things that MUST be in low memory. 64 <2> section .earlybss nobits write 65 <2> section .config write progbits align=4 66 <2> section .replacestub exec write progbits align=16 67 <2> section .gentextnr exec write nobits align=16 68 <2> section .stack16 write nobits align=16 69 <2> 70 <2> ; Use .bss16 for things that doesn't have to be in low memory; 71 <2> ; .earlybss should be used for things that absolutely have 72 <2> ; to be below 0x7c00. 73 <2> section .bss16 write nobits align=16 74 <2> 75 <2> %if 0 ; IS_PXELINUX 76 <2> ; Warning here: RBFG build 22 randomly overwrites 77 <2> ; memory location [0x5680,0x576c), possibly more. It 78 <2> ; seems that it gets confused and screws up the 79 <2> ; pointer to its own internal packet buffer and starts 80 <2> ; writing a received ARP packet into low memory. 81 <2> section .rbfg write nobits 82 <2> RBFG_brainfuck: resb 2048 ; Bigger than an Ethernet packet... 83 <2> %endif 84 <2> 85 <2> section .init exec write progbits align=1 86 <2> section .text16 exec write progbits align=1 87 <2> section .textnr exec nowrite progbits align=1 88 <2> section .bcopyxx.text exec nowrite progbits align=16 89 <2> section .bcopyxx.data noexec write progbits align=16 90 <2> section .data16 noexec write progbits align=16 91 <2> 92 <2> section .adv write nobits align=512 93 <2> 94 <2> ; .uibss contains bss data which is guaranteed to be 95 <2> ; safe to clobber during the loading of the image. This 96 <2> ; is because while loading the primary image we will clobber 97 <2> ; the spillover from the last fractional sector load. 98 <2> section .uibss write nobits align=16 99 <2> 100 <2> section .savedata write nobits align=16 101 <2> 102 <2> ; Symbols from linker script 103 <2> %macro SECINFO 1 104 <2> extern __%1_start, __%1_end 105 <2> extern __%1_len, __%1_dwords 106 <2> %endmacro 107 <2> 108 <2> SECINFO bss16 108 <3> extern __%1_start, __%1_end 108 <3> extern __%1_len, __%1_dwords 109 <2> SECINFO uibss 109 <3> extern __%1_start, __%1_end 109 <3> extern __%1_len, __%1_dwords 110 <2> SECINFO config 110 <3> extern __%1_start, __%1_end 110 <3> extern __%1_len, __%1_dwords 111 <2> SECINFO replacestub 111 <3> extern __%1_start, __%1_end 111 <3> extern __%1_len, __%1_dwords 112 <2> SECINFO bcopyxx 112 <3> extern __%1_start, __%1_end 112 <3> extern __%1_len, __%1_dwords 113 <2> 114 <2> SECINFO pm_code 114 <3> extern __%1_start, __%1_end 114 <3> extern __%1_len, __%1_dwords 115 <2> SECINFO high_clear 115 <3> extern __%1_start, __%1_end 115 <3> extern __%1_len, __%1_dwords 116 <2> extern __pm_code_lma 117 <2> 118 <2> SECINFO bss 118 <3> extern __%1_start, __%1_end 118 <3> extern __%1_len, __%1_dwords 119 <2> 120 <2> extern free_high_memory 121 <2> 122 <2> global _start 123 <2> 124 <2> section .text16 125 <2> 126 <2> ; 127 <2> ; Segment assignments in the bottom 640K 128 <2> ; Keep the low-memory footprint as small as possible... overrun is a hard 129 <2> ; failure! 130 <2> ; 131 <2> 132 <2> serial_buf_size equ 4096 ; Should be a power of 2 133 <2> 134 <2> ; 135 <2> ; Transfer buffer segment: guaranteed to be aligned 64K, used for disk I/O 136 <2> ; One symbol for the segment number, one for the absolute address 137 <2> ; 138 <2> extern xfer_buf_seg 139 <2> section .xfer_buf write nobits align=65536 140 <2> global core_xfer_buf:data hidden 141 00000000 <2> core_xfer_buf resb 65536 142 <2> 143 <2> ; 144 <2> ; At the very end, the lowmem heap 145 <2> ; 146 <2> extern __lowmem_heap 147 <2> min_lowmem_heap equ 65536 148 <2> 149 <2> section .text16 32 <1> %include "pmcall.inc" 1 <2> ;; 2 <2> ;; pmcall.inc 3 <2> ;; 4 <2> ;; Macros for the stack frame set up by pm_call, assuming ebp is left 5 <2> ;; as the RM frame pointer. 6 <2> ;; 7 <2> 8 <2> %ifndef PMCALL_INC 9 <2> %define PMCALL_INC 10 <2> 11 <2> %define RM_GS word [ebp] 12 <2> %define RM_FS word [ebp+2] 13 <2> %define RM_ES word [ebp+4] 14 <2> %define RM_DS word [ebp+6] 15 <2> 16 <2> %define RM_EDI dword [ebp+8] 17 <2> %define RM_DI word [ebp+8] 18 <2> %define RM_HDI word [ebp+10] 19 <2> %define RM_DIL byte [ebp+8] 20 <2> %define RM_DIH byte [ebp+9] 21 <2> 22 <2> %define RM_ESI dword [ebp+12] 23 <2> %define RM_SI word [ebp+12] 24 <2> %define RM_HSI word [ebp+14] 25 <2> %define RM_SIL byte [ebp+12] 26 <2> %define RM_SIH byte [ebp+13] 27 <2> 28 <2> %define RM_EBP dword [ebp+16] 29 <2> %define RM_BP word [ebp+16] 30 <2> %define RM_HBP word [ebp+18] 31 <2> %define RM_BPL byte [ebp+16] 32 <2> %define RM_BPH byte [ebp+17] 33 <2> 34 <2> %define RM_EBX dword [ebp+24] 35 <2> %define RM_BX word [ebp+24] 36 <2> %define RM_HBX word [ebp+26] 37 <2> %define RM_BL byte [ebp+24] 38 <2> %define RM_BH byte [ebp+25] 39 <2> 40 <2> %define RM_EDX dword [ebp+28] 41 <2> %define RM_DX word [ebp+28] 42 <2> %define RM_HDX word [ebp+30] 43 <2> %define RM_DL byte [ebp+28] 44 <2> %define RM_DH byte [ebp+29] 45 <2> 46 <2> %define RM_ECX dword [ebp+32] 47 <2> %define RM_CX word [ebp+32] 48 <2> %define RM_HCX word [ebp+34] 49 <2> %define RM_CL byte [ebp+32] 50 <2> %define RM_CH byte [ebp+33] 51 <2> 52 <2> %define RM_EAX dword [ebp+36] 53 <2> %define RM_AX word [ebp+36] 54 <2> %define RM_HAX word [ebp+38] 55 <2> %define RM_AL byte [ebp+36] 56 <2> %define RM_AH byte [ebp+37] 57 <2> 58 <2> %define RM_EFLAGS dword [ebp+40] 59 <2> %define RM_FLAGS word [ebp+40] 60 <2> %define RM_HFLAGS word [ebp+42] 61 <2> %define RM_FLAGSL byte [ebp+40] 62 <2> %define RM_FLAGSH byte [ebp+41] 63 <2> 64 <2> ; Convenience macro to call a PM function 65 <2> %macro pm_call 1 66 <2> push dword %1 67 <2> call _pm_call 68 <2> %endmacro 69 <2> 70 <2> %endif ; PMCALL_INC 33 <1> %include "extern.inc" 1 <2> ; 2 <2> ; extern.inc 3 <2> ; 4 <2> ; Prototypes for external functions 5 <2> 6 <2> %ifndef EXTERN_INC 7 <2> %define EXTERN_INC 8 <2> 9 <2> ; rllpack.c 10 <2> extern rllpack, rllunpack 11 <2> 12 <2> ; hello.c 13 <2> extern hello 14 <2> 15 <2> ; elflink/load_env32.c 16 <2> extern load_env32, pm_env32_run 17 <2> 18 <2> extern mp1, mp2, mp3, mp4, mp5 19 <2> 20 <2> extern hexdump 21 <2> 22 <2> extern mem_init 23 <2> 24 <2> ; fs.c 25 <2> extern pm_fs_init 26 <2> extern SectorSize, SectorShift 27 <2> 28 <2> ; chdir.c 29 <2> extern pm_realpath 30 <2> 31 <2> ; readdir.c 32 <2> extern opendir, readdir, closedir 33 <2> 34 <2> ; idle.c 35 <2> extern __idle 36 <2> 37 <2> %ifdef DEBUG 38 <2> ; debug.c 39 <2> extern pm_debug_msg 40 <2> 41 <2> %macro dprint 1+ 42 <2> push ax 43 <2> call %%fwd 44 <2> db %1 45 <2> db 0 46 <2> %%fwd: pop ax 47 <2> pm_call pm_debug_msg 48 <2> pop ax 49 <2> %endmacro 50 <2> %else 51 <2> %macro dprint 1+ 52 <2> %endmacro 53 <2> %endif 54 <2> 55 <2> %if IS_PXELINUX 56 <2> ; pxe.c 57 <2> extern unload_pxe, reset_pxe 58 <2> %endif 59 <2> 60 <2> ; plaincon.c 61 <2> extern pm_writechr 62 <2> 63 <2> ; cleanup.c 64 <2> extern cleanup_hardware 65 <2> 66 <2> ; writestr.c 67 <2> extern pm_writestr, crlf 68 <2> 69 <2> ; writehex.c 70 <2> extern pm_writehex2, pm_writehex4, pm_writehex8 71 <2> 72 <2> ; graphics.c 73 <2> extern syslinux_force_text_mode, vgashowcursor, vgahidecursor, pm_using_vga 74 <2> 75 <2> ; conio.c 76 <2> extern pm_pollchar, pm_write_serial, pm_serialcfg 77 <2> 78 <2> ; font.c 79 <2> extern pm_getchar, pm_adjust_screen, pm_userfont 80 <2> 81 <2> %endif ; EXTERN_INC 34 <1> %include "kernel.inc" 1 <2> ;; ----------------------------------------------------------------------- 2 <2> ;; 3 <2> ;; Copyright 1994-2008 H. Peter Anvin - All Rights Reserved 4 <2> ;; 5 <2> ;; This program is free software; you can redistribute it and/or modify 6 <2> ;; it under the terms of the GNU General Public License as published by 7 <2> ;; the Free Software Foundation, Inc., 53 Temple Place Ste 330, 8 <2> ;; Boston MA 02111-1307, USA; either version 2 of the License, or 9 <2> ;; (at your option) any later version; incorporated herein by reference. 10 <2> ;; 11 <2> ;; ----------------------------------------------------------------------- 12 <2> 13 <2> ;; 14 <2> ;; kernel.inc 15 <2> ;; 16 <2> ;; Header file for the kernel interface definitions 17 <2> ;; 18 <2> 19 <2> %ifndef _KERNEL_INC 20 <2> %define _KERNEL_INC 21 <2> 22 <2> ;; 23 <2> ;; Structure of the real_mode_seg 24 <2> ;; 25 <2> 26 <2> struc real_mode_seg_t 27 00000000 <2> resb 20h-($-$$) ; org 20h 28 00000020 <2> kern_cmd_magic resw 1 ; 0020 Magic # for command line 29 00000022 <2> kern_cmd_offset resw 1 ; 0022 Offset for kernel command line 30 00000024 <2> resb 497-($-$$) ; org 497d 31 000001F1 <2> bs_setupsecs resb 1 ; 01F1 Sectors for setup code (0 -> 4) 32 000001F2 <2> bs_rootflags resw 1 ; 01F2 Root readonly flag 33 000001F4 <2> bs_syssize resw 1 ; 01F4 34 000001F6 <2> bs_swapdev resw 1 ; 01F6 Swap device (obsolete) 35 000001F8 <2> bs_ramsize resw 1 ; 01F8 Ramdisk flags, formerly ramdisk size 36 000001FA <2> bs_vidmode resw 1 ; 01FA Video mode 37 000001FC <2> bs_rootdev resw 1 ; 01FC Root device 38 000001FE <2> bs_bootsign resw 1 ; 01FE Boot sector signature (0AA55h) 39 00000200 <2> su_jump resb 1 ; 0200 0EBh 40 00000201 <2> su_jump2 resb 1 ; 0201 Size of following header 41 00000202 <2> su_header resd 1 ; 0202 New setup code: header 42 00000206 <2> su_version resw 1 ; 0206 See linux/arch/i386/boot/setup.S 43 00000208 <2> su_switch resw 1 ; 0208 44 0000020A <2> su_setupseg resw 1 ; 020A 45 0000020C <2> su_startsys resw 1 ; 020C 46 0000020E <2> su_kver resw 1 ; 020E Kernel version pointer 47 00000210 <2> su_loader resb 1 ; 0210 Loader ID 48 00000211 <2> su_loadflags resb 1 ; 0211 Load high flag 49 00000212 <2> su_movesize resw 1 ; 0212 50 00000214 <2> su_code32start resd 1 ; 0214 Start of code loaded high 51 00000218 <2> su_ramdiskat resd 1 ; 0218 Start of initial ramdisk 52 0000021C <2> su_ramdisklen resd 1 ; 021C Length of initial ramdisk 53 00000220 <2> su_bsklugeoffs resw 1 ; 0220 54 00000222 <2> su_bsklugeseg resw 1 ; 0222 55 00000224 <2> su_heapend resw 1 ; 0224 56 00000226 <2> su_pad1 resw 1 ; 0226 57 00000228 <2> su_cmd_line_ptr resd 1 ; 0228 58 0000022C <2> su_ramdisk_max resd 1 ; 022C 59 00000230 <2> resb (0f800h-12)-($-$$) 60 <2> linux_stack equ $ ; F7F4 61 0000F7F4 <2> linux_fdctab resb 12 62 <2> cmd_line_here equ $ ; F800 Should be out of the way 63 <2> endstruc 64 <2> 65 <2> ; 66 <2> ; Old kernel command line signature 67 <2> ; 68 <2> CMD_MAGIC equ 0A33Fh ; Command line magic 69 <2> 70 <2> ; 71 <2> ; If we're loading the command line old-style, we need a smaller 72 <2> ; heap. 73 <2> ; 74 <2> old_cmd_line_here equ 9800h 75 <2> old_max_cmd_len equ 2047 76 <2> old_linux_fdctab equ old_cmd_line_here-12 77 <2> old_linux_stack equ old_linux_fdctab 78 <2> 79 <2> ; 80 <2> ; Magic number of su_header field 81 <2> ; 82 <2> HEADER_ID equ 'HdrS' ; HdrS (in littleendian hex) 83 <2> 84 <2> ; 85 <2> ; Flags for the su_loadflags field 86 <2> ; 87 <2> LOAD_HIGH equ 01h ; Large kernel, load high 88 <2> QUIET_FLAG equ 20h ; Quiet the kernel 89 <2> KEEP_SEGMENTS equ 40h ; Don't reload segments 90 <2> CAN_USE_HEAP equ 80h ; Boot loader reports heap size 91 <2> 92 <2> ; 93 <2> ; ID codes for various modules 94 <2> ; 95 <2> syslinux_id equ 031h ; 3 = SYSLINUX family; 1 = SYSLINUX 96 <2> pxelinux_id equ 032h ; 3 = SYSLINUX family; 2 = PXELINUX 97 <2> isolinux_id equ 033h ; 3 = SYSLINUX family; 3 = ISOLINUX 98 <2> extlinux_id equ 034h ; 3 = SYSLINUX family; 4 = EXTLINUX 99 <2> 100 <2> ; 101 <2> ; Types of vkernels 102 <2> ; 103 <2> VK_LOCALBOOT equ -1 ; localboot (no actual kernel loaded) 104 <2> VK_KERNEL equ 0 ; Choose by filename 105 <2> VK_LINUX equ 1 ; Linux kernel image 106 <2> VK_BOOT equ 2 ; Boot sector 107 <2> VK_BSS equ 3 ; BSS boot sector 108 <2> VK_PXE equ 4 ; PXE NBP 109 <2> VK_FDIMAGE equ 5 ; Floppy disk image 110 <2> VK_COMBOOT equ 6 ; COMBOOT image 111 <2> VK_COM32 equ 7 ; COM32 image 112 <2> VK_CONFIG equ 8 ; Configuration file 113 <2> VK_TYPES equ 9 ; Number of VK types 114 <2> 115 <2> %endif ; _KERNEL_INC 35 <1> %include "bios.inc" 1 <2> ;; ----------------------------------------------------------------------- 2 <2> ;; 3 <2> ;; Copyright 1994-2008 H. Peter Anvin - All Rights Reserved 4 <2> ;; 5 <2> ;; This program is free software; you can redistribute it and/or modify 6 <2> ;; it under the terms of the GNU General Public License as published by 7 <2> ;; the Free Software Foundation, Inc., 53 Temple Place Ste 330, 8 <2> ;; Boston MA 02111-1307, USA; either version 2 of the License, or 9 <2> ;; (at your option) any later version; incorporated herein by reference. 10 <2> ;; 11 <2> ;; ----------------------------------------------------------------------- 12 <2> 13 <2> ;; 14 <2> ;; bios.inc 15 <2> ;; 16 <2> ;; Header file for the BIOS data structures etc. 17 <2> ;; 18 <2> 19 <2> %ifndef _BIOS_INC 20 <2> %define _BIOS_INC 21 <2> 22 <2> ; Interrupt vectors 23 <2> absolute 4*1Ch 24 00000070 <2> BIOS_timer_hook resd 1 25 <2> 26 <2> absolute 4*1Eh 27 <2> fdctab equ $ 28 00000078 <2> fdctab1 resw 1 29 0000007A <2> fdctab2 resw 1 30 <2> 31 <2> absolute 0400h 32 00000400 <2> serial_base resw 4 ; Base addresses for 4 serial ports 33 <2> absolute 0413h 34 00000413 <2> BIOS_fbm resw 1 ; Free Base Memory (kilobytes) 35 <2> absolute 0462h 36 00000462 <2> BIOS_page resb 1 ; Current video page 37 <2> absolute 046Ch 38 0000046C <2> BIOS_timer resw 1 ; Timer ticks 39 <2> absolute 0472h 40 00000472 <2> BIOS_magic resw 1 ; BIOS reset magic 41 <2> absolute 0484h 42 00000484 <2> BIOS_vidrows resb 1 ; Number of screen rows 43 <2> 44 <2> %endif ; _BIOS_INC 36 <1> %include "tracers.inc" 1 <2> ;; ----------------------------------------------------------------------- 2 <2> ;; 3 <2> ;; Copyright 1994-2008 H. Peter Anvin - All Rights Reserved 4 <2> ;; 5 <2> ;; This program is free software; you can redistribute it and/or modify 6 <2> ;; it under the terms of the GNU General Public License as published by 7 <2> ;; the Free Software Foundation, Inc., 53 Temple Place Ste 330, 8 <2> ;; Boston MA 02111-1307, USA; either version 2 of the License, or 9 <2> ;; (at your option) any later version; incorporated herein by reference. 10 <2> ;; 11 <2> ;; ----------------------------------------------------------------------- 12 <2> 13 <2> ;; 14 <2> ;; tracers.inc 15 <2> ;; 16 <2> ;; Debugging tracers 17 <2> ;; 18 <2> 19 <2> %ifndef _TRACERS_INC 20 <2> %define _TRACERS_INC 21 <2> 22 <2> ; Note: The Makefile builds one version with DEBUG_MESSAGES automatically. 23 <2> ; %define DEBUG_TRACERS 1 ; Uncomment to get debugging tracers 24 <2> ; %define DEBUG_MESSAGES ; Uncomment to get debugging messages 25 <2> 26 <2> %ifdef DEBUG_TRACERS 27 <2> 28 <2> %macro TRACER 1 29 <2> call debug_tracer 30 <2> db %1 31 <2> %endmacro 32 <2> 33 <2> %else ; DEBUG_TRACERS 34 <2> 35 <2> %macro TRACER 1 36 <2> %endmacro 37 <2> 38 <2> %endif ; DEBUG_TRACERS 39 <2> 40 <2> %endif ; _TRACERS_INC 37 <1> %include "stack.inc" 1 <2> ; ----------------------------------------------------------------------- 2 <2> ; 3 <2> ; Copyright 2005-2008 H. Peter Anvin - All Rights Reserved 4 <2> ; Copyright 2009-2010 Intel Corporation; author: H. Peter Anvin 5 <2> ; 6 <2> ; This program is free software; you can redistribute it and/or modify 7 <2> ; it under the terms of the GNU General Public License as published by 8 <2> ; the Free Software Foundation, Inc., 53 Temple Place Ste 330, 9 <2> ; Boston MA 02111-1307, USA; either version 2 of the License, or 10 <2> ; (at your option) any later version; incorporated herein by reference. 11 <2> ; 12 <2> ; ----------------------------------------------------------------------- 13 <2> 14 <2> ; 15 <2> ; stack.inc 16 <2> ; 17 <2> ; How to reset the stack pointer 18 <2> ; 19 <2> 20 <2> %ifndef _STACK_INC 21 <2> %define _STACK_INC 22 <2> 23 <2> ; 24 <2> ; This macro resets the stack pointer (including SS), and sets 25 <2> ; DS == ES == 0, interrupts on, DF = 0. 26 <2> ; 27 <2> ; It takes a 16-bit register that can be safely clobbered as parameter. 28 <2> ; 29 <2> %macro RESET_STACK_AND_SEGS 1 30 <2> xor %1,%1 31 <2> mov ds,%1 32 <2> mov es,%1 33 <2> lss esp,[BaseStack] 34 <2> mov dword [PMESP],__stack_end ; Reset PM stack 35 <2> sti 36 <2> cld 37 <2> %endmacro 38 <2> 39 <2> section .data16 40 <2> alignz 4 41 <2> global BaseStack:data hidden 42 00000000 D46F0000 <2> BaseStack dd StackHome ; ESP of the "home" stack pointer 43 00000004 0000 <2> dw 0 ; SS of the "home" stack pointer 44 <2> 45 <2> section .text16 46 <2> 47 <2> %endif ; _STACK_INC 38 <1> %include "io.inc" 1 <2> ;; ----------------------------------------------------------------------- 2 <2> ;; 3 <2> ;; Copyright 1994-2009 H. Peter Anvin - All Rights Reserved 4 <2> ;; Copyright 2009 Intel Corporation; author: H. Peter Anvin 5 <2> ;; 6 <2> ;; This program is free software; you can redistribute it and/or modify 7 <2> ;; it under the terms of the GNU General Public License as published by 8 <2> ;; the Free Software Foundation, Inc., 53 Temple Place Ste 330, 9 <2> ;; Boston MA 02111-1307, USA; either version 2 of the License, or 10 <2> ;; (at your option) any later version; incorporated herein by reference. 11 <2> ;; 12 <2> ;; ----------------------------------------------------------------------- 13 <2> 14 <2> ;; 15 <2> ;; io.inc 16 <2> ;; 17 <2> ;; I/O related macros 18 <2> ;; 19 <2> 20 <2> %ifndef _IO_INC 21 <2> %define _IO_INC 22 <2> 23 <2> %define IO_DELAY_PORT 80h ; Invalid port (we hope!) 24 <2> 25 <2> %macro io_delay 0.nolist 26 <2> out IO_DELAY_PORT,al 27 <2> out IO_DELAY_PORT,al 28 <2> %endmacro 29 <2> 30 <2> %macro slow_out 2.nolist 31 <2> out %1,%2 32 <2> io_delay 33 <2> %endmacro 34 <2> 35 <2> %endif ; _IO_INC 39 <1> 40 <1> %endif ; _HEAD_INC 23 %include "pxe.inc" 1 <1> ;; ----------------------------------------------------------------------- 2 <1> ;; 3 <1> ;; Copyright 1999-2008 H. Peter Anvin - All Rights Reserved 4 <1> ;; 5 <1> ;; This program is free software; you can redistribute it and/or modify 6 <1> ;; it under the terms of the GNU General Public License as published by 7 <1> ;; the Free Software Foundation, Inc., 53 Temple Place Ste 330, 8 <1> ;; Boston MA 02111-1307, USA; either version 2 of the License, or 9 <1> ;; (at your option) any later version; incorporated herein by reference. 10 <1> ;; 11 <1> ;; ----------------------------------------------------------------------- 12 <1> 13 <1> ;; 14 <1> ;; pxe.inc 15 <1> ;; 16 <1> ;; PXE opcodes 17 <1> ;; 18 <1> 19 <1> %ifndef _PXE_INC 20 <1> %define _PXE_INC 1 21 <1> 22 <1> %define PXENV_TFTP_OPEN 0x0020 23 <1> %define PXENV_TFTP_CLOSE 0x0021 24 <1> %define PXENV_TFTP_READ 0x0022 25 <1> %define PXENV_TFTP_READ_FILE 0x0023 26 <1> %define PXENV_TFTP_READ_FILE_PMODE 0x0024 27 <1> %define PXENV_TFTP_GET_FSIZE 0x0025 28 <1> 29 <1> %define PXENV_UDP_OPEN 0x0030 30 <1> %define PXENV_UDP_CLOSE 0x0031 31 <1> %define PXENV_UDP_READ 0x0032 32 <1> %define PXENV_UDP_WRITE 0x0033 33 <1> 34 <1> %define PXENV_START_UNDI 0x0000 35 <1> %define PXENV_UNDI_STARTUP 0x0001 36 <1> %define PXENV_UNDI_CLEANUP 0x0002 37 <1> %define PXENV_UNDI_INITIALIZE 0x0003 38 <1> %define PXENV_UNDI_RESET_NIC 0x0004 39 <1> %define PXENV_UNDI_SHUTDOWN 0x0005 40 <1> %define PXENV_UNDI_OPEN 0x0006 41 <1> %define PXENV_UNDI_CLOSE 0x0007 42 <1> %define PXENV_UNDI_TRANSMIT 0x0008 43 <1> %define PXENV_UNDI_SET_MCAST_ADDR 0x0009 44 <1> %define PXENV_UNDI_SET_STATION_ADDR 0x000A 45 <1> %define PXENV_UNDI_SET_PACKET_FILTER 0x000B 46 <1> %define PXENV_UNDI_GET_INFORMATION 0x000C 47 <1> %define PXENV_UNDI_GET_STATISTICS 0x000D 48 <1> %define PXENV_UNDI_CLEAR_STATISTICS 0x000E 49 <1> %define PXENV_UNDI_INITIATE_DIAGS 0x000F 50 <1> %define PXENV_UNDI_FORCE_INTERRUPT 0x0010 51 <1> %define PXENV_UNDI_GET_MCAST_ADDR 0x0011 52 <1> %define PXENV_UNDI_GET_NIC_TYPE 0x0012 53 <1> %define PXENV_UNDI_GET_IFACE_INFO 0x0013 54 <1> %define PXENV_UNDI_ISR 0x0014 55 <1> %define PXENV_STOP_UNDI 0x0015 ; Overlap...? 56 <1> %define PXENV_UNDI_GET_STATE 0x0015 ; Overlap...? 57 <1> 58 <1> %define PXENV_UNLOAD_STACK 0x0070 59 <1> %define PXENV_GET_CACHED_INFO 0x0071 60 <1> %define PXENV_RESTART_DHCP 0x0072 61 <1> %define PXENV_RESTART_TFTP 0x0073 62 <1> %define PXENV_MODE_SWITCH 0x0074 63 <1> %define PXENV_START_BASE 0x0075 64 <1> %define PXENV_STOP_BASE 0x0076 65 <1> 66 <1> ; gPXE extensions... 67 <1> %define PXENV_FILE_OPEN 0x00e0 68 <1> %define PXENV_FILE_CLOSE 0x00e1 69 <1> %define PXENV_FILE_SELECT 0x00e2 70 <1> %define PXENV_FILE_READ 0x00e3 71 <1> %define PXENV_GET_FILE_SIZE 0x00e4 72 <1> %define PXENV_FILE_EXEC 0x00e5 73 <1> %define PXENV_FILE_API_CHECK 0x00e6 74 <1> %define PXENV_FILE_EXIT_HOOK 0x00e7 75 <1> 76 <1> ; Exit codes 77 <1> %define PXENV_EXIT_SUCCESS 0x0000 78 <1> %define PXENV_EXIT_FAILURE 0x0001 79 <1> 80 <1> ; Status codes 81 <1> %define PXENV_STATUS_SUCCESS 0x00 82 <1> %define PXENV_STATUS_FAILURE 0x01 83 <1> %define PXENV_STATUS_BAD_FUNC 0x02 84 <1> %define PXENV_STATUS_UNSUPPORTED 0x03 85 <1> %define PXENV_STATUS_KEEP_UNDI 0x04 86 <1> %define PXENV_STATUS_KEEP_ALL 0x05 87 <1> %define PXENV_STATUS_OUT_OF_RESOURCES 0x06 88 <1> %define PXENV_STATUS_ARP_TIMEOUT 0x11 89 <1> %define PXENV_STATUS_UDP_CLOSED 0x18 90 <1> %define PXENV_STATUS_UDP_OPEN 0x19 91 <1> %define PXENV_STATUS_TFTP_CLOSED 0x1a 92 <1> %define PXENV_STATUS_TFTP_OPEN 0x1b 93 <1> %define PXENV_STATUS_MCOPY_PROBLEM 0x20 94 <1> %define PXENV_STATUS_BIS_INTEGRITY_FAILURE 0x21 95 <1> %define PXENV_STATUS_BIS_VALIDATE_FAILURE 0x22 96 <1> %define PXENV_STATUS_BIS_INIT_FAILURE 0x23 97 <1> %define PXENV_STATUS_BIS_SHUTDOWN_FAILURE 0x24 98 <1> %define PXENV_STATUS_BIS_GBOA_FAILURE 0x25 99 <1> %define PXENV_STATUS_BIS_FREE_FAILURE 0x26 100 <1> %define PXENV_STATUS_BIS_GSI_FAILURE 0x27 101 <1> %define PXENV_STATUS_BIS_BAD_CKSUM 0x28 102 <1> %define PXENV_STATUS_TFTP_CANNOT_ARP_ADDRESS 0x30 103 <1> %define PXENV_STATUS_TFTP_OPEN_TIMEOUT 0x32 104 <1> 105 <1> %define PXENV_STATUS_TFTP_UNKNOWN_OPCODE 0x33 106 <1> %define PXENV_STATUS_TFTP_READ_TIMEOUT 0x35 107 <1> %define PXENV_STATUS_TFTP_ERROR_OPCODE 0x36 108 <1> %define PXENV_STATUS_TFTP_CANNOT_OPEN_CONNECTION 0x38 109 <1> %define PXENV_STATUS_TFTP_CANNOT_READ_FROM_CONNECTION 0x39 110 <1> %define PXENV_STATUS_TFTP_TOO_MANY_PACKAGES 0x3a 111 <1> %define PXENV_STATUS_TFTP_FILE_NOT_FOUND 0x3b 112 <1> %define PXENV_STATUS_TFTP_ACCESS_VIOLATION 0x3c 113 <1> %define PXENV_STATUS_TFTP_NO_MCAST_ADDRESS 0x3d 114 <1> %define PXENV_STATUS_TFTP_NO_FILESIZE 0x3e 115 <1> %define PXENV_STATUS_TFTP_INVALID_PACKET_SIZE 0x3f 116 <1> %define PXENV_STATUS_DHCP_TIMEOUT 0x51 117 <1> %define PXENV_STATUS_DHCP_NO_IP_ADDRESS 0x52 118 <1> %define PXENV_STATUS_DHCP_NO_BOOTFILE_NAME 0x53 119 <1> %define PXENV_STATUS_DHCP_BAD_IP_ADDRESS 0x54 120 <1> %define PXENV_STATUS_UNDI_INVALID_FUNCTION 0x60 121 <1> %define PXENV_STATUS_UNDI_MEDIATEST_FAILED 0x61 122 <1> %define PXENV_STATUS_UNDI_CANNOT_INIT_NIC_FOR_MCAST 0x62 123 <1> %define PXENV_STATUS_UNDI_CANNOT_INITIALIZE_NIC 0x63 124 <1> %define PXENV_STATUS_UNDI_CANNOT_INITIALIZE_PHY 0x64 125 <1> %define PXENV_STATUS_UNDI_CANNOT_READ_CONFIG_DATA 0x65 126 <1> %define PXENV_STATUS_UNDI_CANNOT_READ_INIT_DATA 0x66 127 <1> %define PXENV_STATUS_UNDI_BAD_MAC_ADDRESS 0x67 128 <1> %define PXENV_STATUS_UNDI_BAD_EEPROM_CHECKSUM 0x68 129 <1> %define PXENV_STATUS_UNDI_ERROR_SETTING_ISR 0x69 130 <1> %define PXENV_STATUS_UNDI_INVALID_STATE 0x6a 131 <1> %define PXENV_STATUS_UNDI_TRANSMIT_ERROR 0x6b 132 <1> %define PXENV_STATUS_UNDI_INVALID_PARAMETER 0x6c 133 <1> %define PXENV_STATUS_BSTRAP_PROMPT_MENU 0x74 134 <1> %define PXENV_STATUS_BSTRAP_MCAST_ADDR 0x76 135 <1> %define PXENV_STATUS_BSTRAP_MISSING_LIST 0x77 136 <1> %define PXENV_STATUS_BSTRAP_NO_RESPONSE 0x78 137 <1> %define PXENV_STATUS_BSTRAP_FILE_TOO_BIG 0x79 138 <1> %define PXENV_STATUS_BINL_CANCELED_BY_KEYSTROKE 0xa0 139 <1> %define PXENV_STATUS_BINL_NO_PXE_SERVER 0xa1 140 <1> %define PXENV_STATUS_NOT_AVAILABLE_IN_PMODE 0xa2 141 <1> %define PXENV_STATUS_NOT_AVAILABLE_IN_RMODE 0xa3 142 <1> %define PXENV_STATUS_BUSD_DEVICE_NOT_SUPPORTED 0xb0 143 <1> %define PXENV_STATUS_LOADER_NO_FREE_BASE_MEMORY 0xc0 144 <1> %define PXENV_STATUS_LOADER_NO_BC_ROMID 0xc1 145 <1> %define PXENV_STATUS_LOADER_BAD_BC_ROMID 0xc2 146 <1> %define PXENV_STATUS_LOADER_BAD_BC_RUNTIME_IMAGE 0xc3 147 <1> %define PXENV_STATUS_LOADER_NO_UNDI_ROMID 0xc4 148 <1> %define PXENV_STATUS_LOADER_BAD_UNDI_ROMID 0xc5 149 <1> %define PXENV_STATUS_LOADER_BAD_UNDI_DRIVER_IMAGE 0xc6 150 <1> %define PXENV_STATUS_LOADER_NO_PXE_STRUCT 0xc8 151 <1> %define PXENV_STATUS_LOADER_NO_PXENV_STRUCT 0xc9 152 <1> %define PXENV_STATUS_LOADER_UNDI_START 0xca 153 <1> %define PXENV_STATUS_LOADER_BC_START 0xcb 154 <1> 155 <1> ; UNDI ISR codes 156 <1> %define PXENV_UNDI_ISR_IN_START 1 157 <1> %define PXENV_UNDI_ISR_IN_PROCESS 2 158 <1> %define PXENV_UNDI_ISR_IN_GET_NEXT 3 159 <1> 160 <1> %define PXENV_UNDI_ISR_OUT_OURS 0 161 <1> %define PXENV_UNDI_ISR_OUT_NOT_OURS 1 162 <1> 163 <1> %endif ; _PXE_INC 24 25 ; gPXE extensions support 26 %define GPXE 1 27 28 ; 29 ; Some semi-configurable constants... change on your own risk. 30 ; 31 my_id equ pxelinux_id 32 NULLFILE equ 0 ; Zero byte == null file name 33 NULLOFFSET equ 0 ; Position in which to look 34 REBOOT_TIME equ 5*60 ; If failure, time until full reset 35 %assign HIGHMEM_SLOP 128*1024 ; Avoid this much memory near the top 36 TFTP_BLOCKSIZE_LG2 equ 9 ; log2(bytes/block) 37 TFTP_BLOCKSIZE equ (1 << TFTP_BLOCKSIZE_LG2) 38 39 SECTOR_SHIFT equ TFTP_BLOCKSIZE_LG2 40 SECTOR_SIZE equ TFTP_BLOCKSIZE 41 42 ; --------------------------------------------------------------------------- 43 ; BEGIN CODE 44 ; --------------------------------------------------------------------------- 45 46 ; 47 ; Memory below this point is reserved for the BIOS and the MBR 48 ; 49 section .earlybss 50 global trackbuf 51 trackbufsize equ 8192 52 00000000 trackbuf resb trackbufsize ; Track buffer goes here 53 ; ends at 2800h 54 55 ; These fields save information from before the time 56 ; .bss is zeroed... must be in .earlybss 57 global InitStack 58 00002000 InitStack resd 1 59 60 section .bss16 61 alignb FILENAME_MAX 62 00000000 PXEStack resd 1 ; Saved stack during PXE call 63 64 alignb 4 65 global DHCPMagic, RebootTime, BIOSName 66 00000004 RebootTime resd 1 ; Reboot timeout, if set by option 67 00000008 LocalBootType resw 1 ; Local boot return code 68 0000000A DHCPMagic resb 1 ; PXELINUX magic flags 69 0000000B BIOSName resw 1 ; Dummy variable - always 0 70 71 section .text16 72 global StackBuf 73 StackBuf equ STACK_TOP-44 ; Base of stack if we use our own 74 StackHome equ StackBuf 75 76 ; PXE loads the whole file, but assume it can't be more 77 ; than (384-31)K in size. 78 MaxLMA equ 384*1024 79 80 ; 81 ; Primary entry point. 82 ; 83 bootsec equ $ 84 _start: 85 00000000 EA[2400]0000 jmp 0:_start1 ; Canonicalize the address and skip 86 ; the patch header 87 88 ; 89 ; Patch area for adding hardwired DHCP options 90 ; 91 00000005 90 align 4 92 93 00000008 ACC88329 hcdhcp_magic dd 0x2983c8ac ; Magic number 94 0000000C 1C000000 hcdhcp_len dd 7*4 ; Size of this structure 95 00000010 00000000 hcdhcp_flags dd 0 ; Reserved for the future 96 global bdhcp_len, adhcp_len 97 ; Parameters to be parsed before the ones from PXE 98 00000014 00000000 bdhcp_offset dd 0 ; Offset (entered by patcher) 99 00000018 00000000 bdhcp_len dd 0 ; Length (entered by patcher) 100 ; Parameters to be parsed *after* the ones from PXE 101 0000001C 00000000 adhcp_offset dd 0 ; Offset (entered by patcher) 102 00000020 00000000 adhcp_len dd 0 ; Length (entered by patcher) 103 104 _start1: 105 00000024 669C pushfd ; Paranoia... in case of return to PXE 106 00000026 6660 pushad ; ... save as much state as possible 107 00000028 1E push ds 108 00000029 06 push es 109 0000002A 0FA0 push fs 110 0000002C 0FA8 push gs 111 112 0000002E FC cld ; Copy upwards 113 0000002F 31C0 xor ax,ax 114 00000031 8ED8 mov ds,ax 115 00000033 8EC0 mov es,ax 116 117 %if 0 ; debugging code only... not intended for production use 118 ; Clobber the stack segment, to test for specific pathologies 119 mov di,STACK_BASE 120 mov cx,STACK_LEN >> 1 121 mov ax,0xf4f4 122 rep stosw 123 124 ; Clobber the tail of the 64K segment, too 125 extern __bss1_end 126 mov di,__bss1_end 127 sub cx,di ; CX = 0 previously 128 shr cx,1 129 rep stosw 130 %endif 131 132 ; That is all pushed onto the PXE stack. Save the pointer 133 ; to it and switch to an internal stack. 134 00000035 8926[0020] mov [InitStack],sp 135 00000039 8C16[0220] mov [InitStack+2],ss 136 137 0000003D 660FB226[0000] lss esp,[BaseStack] 138 00000043 FB sti ; Stack set up and ready 139 140 ; 141 ; Initialize screen (if we're using one) 142 ; 143 %include "init.inc" 1 <1> ; -*- fundamental -*- 2 <1> ; ----------------------------------------------------------------------- 3 <1> ; 4 <1> ; Copyright 2004-2008 H. Peter Anvin - All Rights Reserved 5 <1> ; Copyright 2009 Intel Corporation; author: H. Peter Anvin 6 <1> ; 7 <1> ; This program is free software; you can redistribute it and/or modify 8 <1> ; it under the terms of the GNU General Public License as published by 9 <1> ; the Free Software Foundation, Inc., 53 Temple Place Ste 330, 10 <1> ; Boston MA 02111-1307, USA; either version 2 of the License, or 11 <1> ; (at your option) any later version; incorporated herein by reference. 12 <1> ; 13 <1> ; ----------------------------------------------------------------------- 14 <1> 15 <1> ; 16 <1> ; init.inc 17 <1> ; 18 <1> ; Common initialization code (inline) 19 <1> ; 20 <1> 21 <1> section .text16 22 <1> common_init: 23 <1> ; Initialize PM invocation framework 24 00000044 E84C04 <1> call pm_init 25 <1> 26 <1> %if IS_PXELINUX 27 <1> ; Save derivative-specific data 28 <1> pm_call pm_save_data 28 00000047 6668[48000000] <2> push dword %1 28 0000004D E8C002 <2> call _pm_call 29 <1> %endif 30 <1> 31 <1> ; Decompress PM code to its target location 32 <1> pm_call pm_decompress 32 00000050 6668[00000000] <2> push dword %1 32 00000056 E8B702 <2> call _pm_call 33 00000059 663D[00000000] <1> cmp eax,__pm_code_len 34 0000005F 7573 <1> jne kaboom 35 <1> 36 <1> extern syslinux_register_bios, init 37 <1> 38 <1> pm_call syslinux_register_bios 38 00000061 6668[00000000] <2> push dword %1 38 00000067 E8A602 <2> call _pm_call 39 <1> pm_call init 39 0000006A 6668[00000000] <2> push dword %1 39 00000070 E89D02 <2> call _pm_call 40 <1> 41 <1> ; 42 <1> ; The code to decompress the PM code and initialize other segments. 43 <1> ; 44 <1> extern _lzo1x_decompress_asm_fast_safe 45 <1> 46 <1> section .textnr 47 <1> bits 32 48 <1> pm_decompress: 49 00000000 68[10000000] <1> push __pm_code_len + 16 ; Space for decompressed size 50 00000005 54 <1> push esp ; Pointer to previous word 51 00000006 68[00000000] <1> push __pm_code_start ; Target address 52 0000000B FF35[06000000] <1> push dword [lzo_data_size] ; Compressed size 53 00000011 68[00000000] <1> push dword __pm_code_lma 54 00000016 E8(00000000) <1> call _lzo1x_decompress_asm_fast_safe 55 0000001B 83C410 <1> add esp,16 56 0000001E 8F4524 <1> pop RM_EAX ; Decompressed size 57 <1> 58 <1> ; Zero bss sections (but not .earlybss, since it may 59 <1> ; contain already-live data.) 60 00000021 31C0 <1> xor eax,eax 61 00000023 BF[00000000] <1> mov edi,__bss_start 62 00000028 B9[00000000] <1> mov ecx,__bss_dwords 63 0000002D F3AB <1> rep stosd 64 0000002F BF[00000000] <1> mov edi,__bss16_start 65 00000034 B9[00000000] <1> mov ecx,__bss16_dwords 66 00000039 F3AB <1> rep stosd 67 0000003B BF[00000000] <1> mov edi,__high_clear_start ; .uibss, .lowmem 68 00000040 B9[00000000] <1> mov ecx,__high_clear_dwords 69 00000045 F3AB <1> rep stosd 70 <1> 71 00000047 C3 <1> ret 72 <1> 73 <1> section .data16 74 00000006 00000000 <1> lzo_data_size dd 0 ; filled in by compressor 75 <1> 76 <1> section .text16 77 <1> bits 16 144 145 ; 146 ; Tell the user we got this far 147 ; 148 00000073 BE[1E01] mov si,syslinux_banner 149 00000076 E8A901 call writestr_early 150 151 00000079 BE[9600] mov si,copyright_str 152 0000007C E8A301 call writestr_early 153 154 ; 155 ; do fs initialize 156 ; 157 0000007F 66B8[00000000] mov eax,ROOT_FS_OPS 158 00000085 6631ED xor ebp,ebp 159 pm_call pm_fs_init 159 00000088 6668[00000000] <1> push dword %1 159 0000008E E87F02 <1> call _pm_call 160 161 section .rodata 162 alignz 4 163 ROOT_FS_OPS: 164 extern pxe_fs_ops 165 00000000 [00000000] dd pxe_fs_ops 166 00000004 00000000 dd 0 167 168 169 section .text16 170 ; 171 ; Initialize the idle mechanism 172 ; 173 extern reset_idle 174 pm_call reset_idle 174 00000091 6668[00000000] <1> push dword %1 174 00000097 E87602 <1> call _pm_call 175 176 ; 177 ; Now we're all set to start with our *real* business. 178 ; 179 ; In previous versions I avoided using 32-bit registers because of a 180 ; rumour some BIOSes clobbered the upper half of 32-bit registers at 181 ; random. I figure, though, that if there are any of those still left 182 ; they probably won't be trying to install Linux on them... 183 ; 184 ; The code is still ripe with 16-bitisms, though. Not worth the hassle 185 ; to take'm out. In fact, we may want to put them back if we're going 186 ; to boot ELKS at some point. 187 ; 188 189 ; 190 ; Linux kernel loading code is common. However, we need to define 191 ; a couple of helper macros... 192 ; 193 194 ; Unload PXE stack 195 %define HAVE_UNLOAD_PREP 196 %macro UNLOAD_PREP 0 197 pm_call unload_pxe 198 %endmacro 199 200 ; 201 ; Jump to 32-bit ELF space 202 ; 203 pm_call load_env32 203 0000009A 6668[00000000] <1> push dword %1 203 000000A0 E86D02 <1> call _pm_call 204 000000A3 EB2F jmp kaboom ; load_env32() shouldn't return. If it does, then kaboom! 205 206 print_hello: 207 enter_command: 208 auto_boot: 209 pm_call hello 209 000000A5 6668[00000000] <1> push dword %1 209 000000AB E86202 <1> call _pm_call 210 211 ; 212 ; Save hardwired DHCP options. This is done before the C environment 213 ; is initialized, so it has to be done in assembly. 214 ; 215 %define MAX_DHCP_OPTS 4096 216 bits 32 217 218 section .savedata 219 global bdhcp_data, adhcp_data 220 00000000 bdhcp_data: resb MAX_DHCP_OPTS 221 00001000 adhcp_data: resb MAX_DHCP_OPTS 222 223 section .textnr 224 pm_save_data: 225 00000048 B800100000 mov eax,MAX_DHCP_OPTS 226 0000004D 0FB70D[18000000] movzx ecx,word [bdhcp_len] 227 00000054 39C1 cmp ecx,eax 228 00000056 7608 jna .oksize 229 00000058 89C1 mov ecx,eax 230 0000005A 66A3[18000000] mov [bdhcp_len],ax 231 .oksize: 232 00000060 8B35[14000000] mov esi,[bdhcp_offset] 233 00000066 81C6[00000000] add esi,_start 234 0000006C BF[00000000] mov edi,bdhcp_data 235 00000071 83C103 add ecx,3 236 00000074 C1E902 shr ecx,2 237 00000077 F3A5 rep movsd 238 239 adhcp_copy: 240 00000079 0FB70D[20000000] movzx ecx,word [adhcp_len] 241 00000080 39C1 cmp ecx,eax 242 00000082 7608 jna .oksize 243 00000084 89C1 mov ecx,eax 244 00000086 66A3[20000000] mov [adhcp_len],ax 245 .oksize: 246 0000008C 8B35[1C000000] mov esi,[adhcp_offset] 247 00000092 81C6[00000000] add esi,_start 248 00000098 BF[00100000] mov edi,adhcp_data 249 0000009D 83C103 add ecx,3 250 000000A0 C1E902 shr ecx,2 251 000000A3 F3A5 rep movsd 252 000000A5 C3 ret 253 254 bits 16 255 256 ; As core/ui.inc used to be included here in core/pxelinux.asm, and it's no 257 ; longer used, its global variables that were previously used by 258 ; core/pxelinux.asm are now declared here. 259 section .bss16 260 0000000D alignb 4 261 00000010 Kernel_EAX resd 1 262 00000014 Kernel_SI resw 1 263 264 section .bss16 265 00000016 alignb 4 266 00000018 ThisKbdTo resd 1 ; Temporary holder for KbdTimeout 267 0000001C ThisTotalTo resd 1 ; Temporary holder for TotalTimeout 268 00000020 KernelExtPtr resw 1 ; During search, final null pointer 269 00000022 FuncFlag resb 1 ; Escape sequences received from keyboard 270 00000023 KernelType resb 1 ; Kernel type, from vkernel, if known 271 global KernelName 272 00000024 KernelName resb FILENAME_MAX ; Mangled name for kernel 273 274 section .text16 275 ; 276 ; COM32 vestigial data structure 277 ; 278 %include "com32.inc" 1 <1> ;; ----------------------------------------------------------------------- 2 <1> ;; 3 <1> ;; Copyright 1994-2009 H. Peter Anvin - All Rights Reserved 4 <1> ;; Copyright 2009-2010 Intel Corporation; author: H. Peter Anvin 5 <1> ;; 6 <1> ;; This program is free software; you can redistribute it and/or modify 7 <1> ;; it under the terms of the GNU General Public License as published by 8 <1> ;; the Free Software Foundation, Inc., 53 Temple Place Ste 330, 9 <1> ;; Boston MA 02111-1307, USA; either version 2 of the License, or 10 <1> ;; (at your option) any later version; incorporated herein by reference. 11 <1> ;; 12 <1> ;; ----------------------------------------------------------------------- 13 <1> 14 <1> ;; 15 <1> ;; com32.inc 16 <1> ;; 17 <1> ;; Common code for running a COM32 image 18 <1> ;; 19 <1> 20 <1> extern pm_api_vector 21 <1> 22 <1> ; 23 <1> ; Load a COM32 image. A COM32 image is the 32-bit analogue to a DOS 24 <1> ; .com file. A COM32 image is loaded at address 0x101000, with %esp 25 <1> ; set to the high end of usable memory. 26 <1> ; 27 <1> ; A COM32 image should begin with the magic bytes: 28 <1> ; B8 FF 4C CD 21, which is "mov eax,0x21cd4cff" in 32-bit mode and 29 <1> ; "mov ax,0x4cff; int 0x21" in 16-bit mode. This will abort the 30 <1> ; program with an error if run in 16-bit mode. 31 <1> ; 32 <1> bits 16 33 <1> section .data16 34 <1> 35 <1> ; Ersatz com32 invocation structure, to make libcom32 36 <1> ; code run the same if linked to the core. This is in 37 <1> ; the .data16 segment so HighMemSize can live here. 38 <1> ; 39 <1> ; Danger, Will Robinson: it's not clear the use of 40 <1> ; core_xfer_buf is safe here. 41 <1> global __com32:data hidden 42 0000000A 00 <1> alignz 4 43 <1> __entry_esp: 44 0000000C 00000000 <1> dd 0 ; Dummy to avoid _exit issues 45 <1> __com32: 46 00000010 09000000 <1> dd 9 ; Argument count 47 00000014 00000000 <1> dd 0 ; No command line 48 00000018 [06000000] <1> dd core_intcall ; Intcall entry point 49 0000001C 00000000 <1> dd 0 ; Bounce buffer address 50 00000020 00000000 <1> dd 0 ; 64K bounce buffer 51 00000024 [00000000] <1> dd core_farcall ; Farcall entry point 52 00000028 [A6000000] <1> dd core_cfarcall ; Cfarcall entry point 53 0000002C 00000000 <1> HighMemSize dd 0 ; End of memory pointer (bytes) 54 00000030 00000000 <1> dd 0 ; No module name 55 00000034 [00000000] <1> dd pm_api_vector ; Protected mode functions 56 <1> 57 <1> section .uibss 58 00000000 <1> Com32Name resb FILENAME_MAX 59 <1> 60 <1> section .bss16 61 <1> %ifndef HAVE_CURRENTDIRNAME 62 <1> global CurrentDirName:data hidden 63 00000124 <1> CurrentDirName resb FILENAME_MAX 64 <1> %endif 65 <1> 66 <1> section .text16 279 280 section .text16 281 global local_boot16:function hidden 282 local_boot16: 283 000000AE A3[0800] mov [LocalBootType],ax 284 000000B1 0FB226[0020] lss sp,[InitStack] 285 000000B6 0FA9 pop gs 286 000000B8 0FA1 pop fs 287 000000BA 07 pop es 288 000000BB 1F pop ds 289 000000BC 6661 popad 290 000000BE 2EA1[0800] mov ax,[cs:LocalBootType] 291 000000C2 83F8FF cmp ax,-1 ; localboot -1 == INT 18h 292 000000C5 7403 je .int18 293 000000C7 669D popfd 294 000000C9 CB retf ; Return to PXE 295 .int18: 296 000000CA 669D popfd 297 000000CC CD18 int 18h 298 000000CE EAF0FF00F0 jmp 0F000h:0FFF0h 299 000000D3 F4 hlt 300 301 ; 302 ; kaboom: write a message and bail out. Wait for quite a while, 303 ; or a user keypress, then do a hard reboot. 304 ; 305 ; Note: use BIOS_timer here; we may not have jiffies set up. 306 ; 307 global kaboom 308 kaboom: 309 RESET_STACK_AND_SEGS AX 309 000000D4 31C0 <1> xor %1,%1 309 000000D6 8ED8 <1> mov ds,%1 309 000000D8 8EC0 <1> mov es,%1 309 000000DA 660FB226[0000] <1> lss esp,[BaseStack] 309 000000E0 66C706[4400]- <1> mov dword [PMESP],__stack_end 309 000000E5 [00000000] <1> 309 000000E9 FB <1> sti 309 000000EA FC <1> cld 310 000000EB BE[C500] .patch: mov si,bailmsg 311 000000EE E83101 call writestr_early ; Returns with AL = 0 312 000000F1 E83801 .drain: call pollchar 313 000000F4 7405 jz .drained 314 000000F6 E83D01 call getchar 315 000000F9 EBF6 jmp short .drain 316 .drained: 317 000000FB 668B3E[0400] mov edi,[RebootTime] 318 00000100 A0[0A00] mov al,[DHCPMagic] 319 00000103 2409 and al,09h ; Magic+Timeout 320 00000105 3C09 cmp al,09h 321 00000107 7406 je .time_set 322 00000109 66BF2C010000 mov edi,REBOOT_TIME 323 .time_set: 324 0000010F B91200 mov cx,18 325 00000112 51 .wait1: push cx 326 00000113 6689F9 mov ecx,edi 327 00000116 8B166C04 .wait2: mov dx,[BIOS_timer] 328 0000011A E80F01 .wait3: call pollchar 329 0000011D 7520 jnz .keypress 330 pm_call __idle 330 0000011F 6668[00000000] <1> push dword %1 330 00000125 E8E801 <1> call _pm_call 331 00000128 3B166C04 cmp dx,[BIOS_timer] 332 0000012C 74EC je .wait3 333 0000012E 67E2E5 loop .wait2,ecx 334 00000131 B02E mov al,'.' 335 pm_call pm_writechr 335 00000133 6668[00000000] <1> push dword %1 335 00000139 E8D401 <1> call _pm_call 336 0000013C 59 pop cx 337 0000013D E2D3 loop .wait1 338 .keypress: 339 pm_call crlf 339 0000013F 6668[00000000] <1> push dword %1 339 00000145 E8C801 <1> call _pm_call 340 00000148 C70672040000 mov word [BIOS_magic],0 ; Cold reboot 341 0000014E EAF0FF00F0 jmp 0F000h:0FFF0h ; Reset vector address 342 343 ; 344 ; pxenv 345 ; 346 ; This is the main PXENV+/!PXE entry point, using the PXENV+ 347 ; calling convention. This is a separate local routine so 348 ; we can hook special things from it if necessary. In particular, 349 ; some PXE stacks seem to not like being invoked from anything but 350 ; the initial stack, so humour it. 351 ; 352 ; While we're at it, save and restore all registers. 353 ; 354 global pxenv 355 pxenv: 356 00000153 669C pushfd 357 00000155 6660 pushad 358 359 ; We may be removing ourselves from memory 360 00000157 83FB73 cmp bx,PXENV_RESTART_TFTP 361 0000015A 7406 jz .disable_timer 362 0000015C 81FBE500 cmp bx,PXENV_FILE_EXEC 363 00000160 7503 jnz .store_stack 364 365 .disable_timer: 366 00000162 E84606 call bios_timer_cleanup 367 368 .store_stack: 369 00000165 9C pushf 370 00000166 FA cli 371 00000167 2EFF06[3800] inc word [cs:PXEStackLock] 372 0000016C 7512 jnz .skip1 373 0000016E 5D pop bp 374 0000016F 2E8926[0000] mov [cs:PXEStack],sp 375 00000174 2E8C16[0200] mov [cs:PXEStack+2],ss 376 00000179 2E0FB226[0020] lss sp,[cs:InitStack] 377 0000017F 55 push bp 378 .skip1: 379 00000180 9D popf 380 381 ; Pre-clear the Status field 382 00000181 268C0D mov word [es:di],cs 383 384 ; This works either for the PXENV+ or the !PXE calling 385 ; convention, as long as we ignore CF (which is redundant 386 ; with AX anyway.) 387 00000184 06 push es 388 00000185 57 push di 389 00000186 53 push bx 390 00000187 9A00000000 .jump: call 0:0 391 0000018C 83C406 add sp,6 392 0000018F 2EA3[2402] mov [cs:PXEStatus],ax 393 394 00000193 9C pushf 395 00000194 FA cli 396 00000195 2EFF0E[3800] dec word [cs:PXEStackLock] 397 0000019A 7908 jns .skip2 398 0000019C 5D pop bp 399 0000019D 2E0FB226[0000] lss sp,[cs:PXEStack] 400 000001A3 55 push bp 401 .skip2: 402 000001A4 9D popf 403 404 000001A5 89E5 mov bp,sp 405 000001A7 21C0 and ax,ax 406 000001A9 0F954620 setnz [bp+32] ; If AX != 0 set CF on return 407 408 ; This clobbers the AX return, but we already saved it into 409 ; the PXEStatus variable. 410 000001AD 6661 popad 411 412 ; If the call failed, it could return. 413 000001AF 83FB73 cmp bx,PXENV_RESTART_TFTP 414 000001B2 7406 jz .enable_timer 415 000001B4 81FBE500 cmp bx,PXENV_FILE_EXEC 416 000001B8 7503 jnz .pop_flags 417 418 .enable_timer: 419 000001BA E8DC05 call timer_init 420 421 .pop_flags: 422 000001BD 669D popfd ; Restore flags (incl. IF, DF) 423 000001BF C3 ret 424 425 ; Must be after function def due to NASM bug 426 global PXEEntry 427 PXEEntry equ pxenv.jump+1 428 429 ; 430 ; The PXEStackLock keeps us from switching stacks if we take an interrupt 431 ; (which ends up calling pxenv) while we are already on the PXE stack. 432 ; It will be -1 normally, 0 inside a PXE call, and a positive value 433 ; inside a *nested* PXE call. 434 ; 435 section .data16 436 alignb 2 437 00000038 FFFF PXEStackLock dw -1 438 439 section .bss16 440 alignb 2 441 00000224 PXEStatus resb 2 442 443 section .text16 444 ; 445 ; Invoke INT 1Ah on the PXE stack. This is used by the "Plan C" method 446 ; for finding the PXE entry point. 447 ; 448 global pxe_int1a 449 pxe_int1a: 450 000001C0 2E8926[0000] mov [cs:PXEStack],sp 451 000001C5 2E8C16[0200] mov [cs:PXEStack+2],ss 452 000001CA 2E0FB226[0020] lss sp,[cs:InitStack] 453 454 000001D0 CD1A int 1Ah ; May trash registers 455 456 000001D2 2E0FB226[0000] lss sp,[cs:PXEStack] 457 000001D8 C3 ret 458 459 ; 460 ; Special unload for gPXE: this switches the InitStack from 461 ; gPXE to the ROM PXE stack. 462 ; 463 %if GPXE 464 global gpxe_unload 465 gpxe_unload: 466 000001D9 BBE700 mov bx,PXENV_FILE_EXIT_HOOK 467 000001DC BF[3C00] mov di,pxe_file_exit_hook 468 000001DF E871FF call pxenv 469 000001E2 723D jc .plain 470 471 ; Now we actually need to exit back to gPXE, which will 472 ; give control back to us on the *new* "original stack"... 473 000001E4 669C pushfd 474 000001E6 1E push ds 475 000001E7 06 push es 476 000001E8 8926[0000] mov [PXEStack],sp 477 000001EC 8C16[0200] mov [PXEStack+2],ss 478 000001F0 0FB226[0020] lss sp,[InitStack] 479 000001F5 0FA9 pop gs 480 000001F7 0FA1 pop fs 481 000001F9 07 pop es 482 000001FA 1F pop ds 483 000001FB 6661 popad 484 000001FD 669D popfd 485 000001FF 31C0 xor ax,ax 486 00000201 CB retf 487 .resume: 488 00000202 FA cli 489 490 ; gPXE will have a stack frame looking much like our 491 ; InitStack, except it has a magic cookie at the top, 492 ; and the segment registers are in reverse order. 493 00000203 6658 pop eax 494 00000205 58 pop ax 495 00000206 5B pop bx 496 00000207 59 pop cx 497 00000208 5A pop dx 498 00000209 50 push ax 499 0000020A 53 push bx 500 0000020B 51 push cx 501 0000020C 52 push dx 502 0000020D 2E8926[0020] mov [cs:InitStack],sp 503 00000212 2E8C16[0220] mov [cs:InitStack+2],ss 504 00000217 2E0FB226[0000] lss sp,[cs:PXEStack] 505 0000021D 07 pop es 506 0000021E 1F pop ds 507 0000021F 669D popfd 508 509 .plain: 510 00000221 C3 ret 511 512 writestr_early: 513 pm_call pm_writestr 513 00000222 6668[00000000] <1> push dword %1 513 00000228 E8E500 <1> call _pm_call 514 0000022B C3 ret 515 516 pollchar: 517 pm_call pm_pollchar 517 0000022C 6668[00000000] <1> push dword %1 517 00000232 E8DB00 <1> call _pm_call 518 00000235 C3 ret 519 520 getchar: 521 pm_call pm_getchar 521 00000236 6668[00000000] <1> push dword %1 521 0000023C E8D100 <1> call _pm_call 522 0000023F C3 ret 523 524 section .data16 525 0000003A 00 alignz 4 526 pxe_file_exit_hook: 527 0000003C 0000 .status: dw 0 528 0000003E [0202] .offset: dw gpxe_unload.resume 529 00000040 0000 .seg: dw 0 530 %endif 531 532 section .text16 533 534 ; ----------------------------------------------------------------------------- 535 ; PXE modules 536 ; ----------------------------------------------------------------------------- 537 538 %if IS_LPXELINUX 539 %include "pxeisr.inc" 1 <1> ; 2 <1> ; Process a PXE interrupt 3 <1> ; 4 <1> section .text16 5 <1> 6 <1> PXEIRQ_MAX equ 100 ; Max spurious interrupts in a timer tick 7 <1> 8 <1> global pxe_isr 9 <1> pxe_isr: 10 00000240 FC <1> cld 11 00000241 60 <1> pusha 12 00000242 1E <1> push ds 13 00000243 06 <1> push es 14 00000244 0FA0 <1> push fs 15 00000246 0FA8 <1> push gs 16 <1> 17 00000248 31C0 <1> xor ax,ax 18 0000024A 8ED8 <1> mov ds,ax 19 0000024C 8EC0 <1> mov es,ax 20 <1> 21 0000024E BB1400 <1> mov bx,PXENV_UNDI_ISR 22 00000251 BF[2802] <1> mov di,pxenv_undi_isr_buf 23 <1> 24 00000254 B90800 <1> mov cx,pxenv_undi_isr_buf.size/2 25 00000257 57 <1> push di 26 00000258 F3AB <1> rep stosw 27 0000025A 5F <1> pop di 28 <1> 29 0000025B C606[2A02]01 <1> mov byte [pxenv_undi_isr_buf.funcflag],PXENV_UNDI_ISR_IN_START 30 <1> 31 00000260 E8F0FE <1> call pxenv 32 00000263 A1[8C00] <1> mov ax,[__jiffies] 33 00000266 722F <1> jc .notus 34 <1> 35 00000268 833E[2A02]00 <1> cmp word [pxenv_undi_isr_buf.funcflag],PXENV_UNDI_ISR_OUT_OURS 36 0000026D 7528 <1> jne .notus 37 <1> 38 <1> ; Its ours - set the flag for the return to PM. 39 <1> ; We need to EOI this ourselves, so that the 40 <1> ; leftover BC doesn't get control. 41 0000026F C606[4102]01 <1> mov byte [pxe_irq_pending],1 42 00000274 66FF06[3C02] <1> inc dword [pxe_irq_count] 43 <1> 44 00000279 803E[4002]08 <1> cmp byte [pxe_irq_vector], 8 45 0000027E B020 <1> mov al,0x20 ; Non-specific EOI 46 00000280 7202 <1> jb .pri_pic 47 <1> 48 00000282 E6A0 <1> out 0xA0, al ; Secondary PIC 49 <1> .pri_pic: 50 00000284 E620 <1> out 0x20,al ; Primary PIC 51 <1> 52 00000286 A3[3802] <1> mov [pxeirq_last],ax 53 00000289 C706[3A02]6400 <1> mov word [pxeirq_deadman],PXEIRQ_MAX 54 <1> 55 <1> .exit: 56 0000028F 0FA9 <1> pop gs 57 00000291 0FA1 <1> pop fs 58 00000293 07 <1> pop es 59 00000294 1F <1> pop ds 60 00000295 61 <1> popa 61 00000296 CF <1> iret 62 <1> 63 <1> .notus: 64 00000297 3B06[3802] <1> cmp ax,[pxeirq_last] 65 0000029B 7512 <1> jne .reset_timeout 66 0000029D FF0E[3A02] <1> dec word [pxeirq_deadman] 67 000002A1 7417 <1> jz .timeout 68 <1> 69 <1> .chain: 70 000002A3 0FA9 <1> pop gs 71 000002A5 0FA1 <1> pop fs 72 000002A7 07 <1> pop es 73 000002A8 1F <1> pop ds 74 000002A9 61 <1> popa 75 000002AA EA00000000 <1> jmp 0:0 76 <1> global pxe_irq_chain 77 <1> pxe_irq_chain equ $-4 78 <1> 79 <1> .reset_timeout: 80 000002AF A3[3802] <1> mov [pxeirq_last],ax 81 000002B2 C706[3A02]6400 <1> mov word [pxeirq_deadman],PXEIRQ_MAX 82 000002B8 EBE9 <1> jmp .chain 83 <1> 84 <1> ; Too many spurious interrupts, shut off the interrupts 85 <1> ; and go to polling mode 86 <1> .timeout: 87 000002BA A0[4002] <1> mov al,[pxe_irq_vector] 88 000002BD BA2100 <1> mov dx,21h 89 000002C0 0FB6C8 <1> movzx cx,al 90 000002C3 C1E104 <1> shl cx,7-3 91 000002C6 01CA <1> add dx,cx 92 000002C8 2407 <1> and al,7 93 000002CA 91 <1> xchg ax,cx 94 000002CB B501 <1> mov ch,1 95 000002CD D2E5 <1> shl ch,cl 96 000002CF EC <1> in al,dx 97 000002D0 08E8 <1> or al,ch 98 000002D2 EE <1> out dx,al 99 000002D3 800E[4202]01 <1> or byte [pxe_need_poll],1 100 000002D8 EBB5 <1> jmp .exit 101 <1> 102 <1> 103 <1> ; Emulate a PXE interrupt from the polling thread 104 <1> global pxe_poll 105 <1> pxe_poll: 106 000002DA 9C <1> pushf 107 000002DB FA <1> cli 108 000002DC FC <1> cld 109 000002DD 60 <1> pusha 110 000002DE 1E <1> push ds 111 000002DF 06 <1> push es 112 000002E0 0FA0 <1> push fs 113 000002E2 0FA8 <1> push gs 114 <1> 115 000002E4 BB1400 <1> mov bx,PXENV_UNDI_ISR 116 000002E7 BF[2802] <1> mov di,pxenv_undi_isr_buf 117 <1> 118 000002EA B90800 <1> mov cx,pxenv_undi_isr_buf.size/2 119 000002ED 57 <1> push di 120 000002EE F3AB <1> rep stosw 121 000002F0 5F <1> pop di 122 <1> 123 000002F1 C606[2A02]01 <1> mov byte [pxenv_undi_isr_buf.funcflag],PXENV_UNDI_ISR_IN_START 124 <1> 125 000002F6 E85AFE <1> call pxenv 126 000002F9 720C <1> jc .notus 127 <1> 128 000002FB 833E[2A02]00 <1> cmp word [pxenv_undi_isr_buf.funcflag],PXENV_UNDI_ISR_OUT_OURS 129 00000300 7505 <1> jne .notus 130 <1> 131 <1> ; Its ours - set the flag for the return to PM. 132 <1> ; We need to EOI this ourselves, so that the 133 <1> ; leftover BC doesn't get control. 134 00000302 C606[4102]01 <1> mov byte [pxe_irq_pending],1 135 <1> 136 <1> .notus: 137 00000307 0FA9 <1> pop gs 138 00000309 0FA1 <1> pop fs 139 0000030B 07 <1> pop es 140 0000030C 1F <1> pop ds 141 0000030D 61 <1> popa 142 0000030E 9D <1> popf 143 0000030F C3 <1> ret 144 <1> 145 <1> section .bss16 146 00000226 <1> alignb 4 147 <1> pxenv_undi_isr_buf: 148 00000228 <1> .status: resw 1 149 0000022A <1> .funcflag: resw 1 150 0000022C <1> .bufferlength: resw 1 151 0000022E <1> .framelen: resw 1 152 00000230 <1> .framehdrlen: resw 1 153 00000232 <1> .frame: resw 2 154 00000236 <1> .prottype: resb 1 155 00000237 <1> .pkttype: resb 1 156 <1> .size equ $-pxenv_undi_isr_buf 157 <1> 158 <1> alignb 4 159 00000238 <1> pxeirq_last resw 1 160 0000023A <1> pxeirq_deadman resw 1 161 <1> 162 <1> global pxe_irq_count 163 0000023C <1> pxe_irq_count resd 1 ; PXE IRQ counter 164 <1> global pxe_irq_vector 165 00000240 <1> pxe_irq_vector resb 1 ; PXE IRQ vector 166 <1> global pxe_irq_pending 167 00000241 <1> pxe_irq_pending resb 1 ; IRQ pending flag 168 <1> global pxe_need_poll 169 00000242 <1> pxe_need_poll resb 1 ; Bit 0 = need polling 170 <1> ; Bit 1 = polling active 171 <1> 172 <1> section .text16 540 %endif 541 542 ; ----------------------------------------------------------------------------- 543 ; Common modules 544 ; ----------------------------------------------------------------------------- 545 546 %include "common.inc" ; Universal modules 1 <1> ; 2 <1> ; Modules common to all derivatives. Do not include modules in this list 3 <1> ; which have special section requirements (i.e. need to be in .init for 4 <1> ; some derivatives.) 5 <1> ; 6 <1> 7 <1> %include "pm.inc" ; Protected mode 1 <2> ;; ----------------------------------------------------------------------- 2 <2> ;; 3 <2> ;; Copyright 1994-2009 H. Peter Anvin - All Rights Reserved 4 <2> ;; Copyright 2009 Intel Corporation; author: H. Peter Anvin 5 <2> ;; 6 <2> ;; This program is free software; you can redistribute it and/or modify 7 <2> ;; it under the terms of the GNU General Public License as published by 8 <2> ;; the Free Software Foundation, Inc., 53 Temple Place Ste 330, 9 <2> ;; Boston MA 02111-1307, USA; either version 2 of the License, or 10 <2> ;; (at your option) any later version; incorporated herein by reference. 11 <2> ;; 12 <2> ;; ----------------------------------------------------------------------- 13 <2> 14 <2> ;; 15 <2> ;; pm.inc 16 <2> ;; 17 <2> ;; Functions to enter and exit 32-bit protected mode, handle interrupts 18 <2> ;; and cross-mode calls. 19 <2> ;; 20 <2> ;; PM refers to 32-bit flat protected mode; RM to 16-bit real mode. 21 <2> ;; 22 <2> 23 <2> bits 16 24 <2> section .text16 25 <2> ; 26 <2> ; _pm_call: call PM routine in low memory from RM 27 <2> ; 28 <2> ; on stack = PM routine to call (a 32-bit address) 29 <2> ; 30 <2> ; ECX, ESI, EDI passed to the called function; 31 <2> ; EAX = EBP in the called function points to the stack frame 32 <2> ; which includes all registers (which can be changed if desired.) 33 <2> ; 34 <2> ; All registers and the flags saved/restored 35 <2> ; 36 <2> ; This routine is invoked by the pm_call macro. 37 <2> ; 38 <2> _pm_call: 39 00000310 669C <2> pushfd 40 00000312 6660 <2> pushad 41 00000314 1E <2> push ds 42 00000315 06 <2> push es 43 00000316 0FA0 <2> push fs 44 00000318 0FA8 <2> push gs 45 0000031A 89E5 <2> mov bp,sp 46 0000031C 8CC8 <2> mov ax,cs 47 0000031E 66BB[A6000000] <2> mov ebx,.pm 48 00000324 8ED8 <2> mov ds,ax 49 00000326 EB0D <2> jmp enter_pm 50 <2> 51 <2> bits 32 52 <2> section .textnr 53 <2> .pm: 54 <2> ; EAX points to the top of the RM stack, which is EFLAGS 55 000000A6 F6452902 <2> test RM_FLAGSH,02h ; RM EFLAGS.IF 56 000000AA 7401 <2> jz .no_sti 57 000000AC FB <2> sti 58 <2> .no_sti: 59 000000AD FF552E <2> call [ebp+4*2+9*4+2] ; Entrypoint on RM stack 60 000000B0 66BB[2803] <2> mov bx,.rm 61 000000B4 EB20 <2> jmp enter_rm 62 <2> 63 <2> bits 16 64 <2> section .text16 65 <2> .rm: 66 00000328 0FA9 <2> pop gs 67 0000032A 0FA1 <2> pop fs 68 0000032C 07 <2> pop es 69 0000032D 1F <2> pop ds 70 0000032E 6661 <2> popad 71 00000330 669D <2> popfd 72 00000332 C20400 <2> ret 4 ; Drop entrypoint 73 <2> 74 <2> ; 75 <2> ; enter_pm: Go to PM with interrupt service configured 76 <2> ; EBX = PM entry point 77 <2> ; EAX = EBP = on exit, points to the RM stack as a 32-bit value 78 <2> ; ECX, EDX, ESI, EDI preserved across this routine 79 <2> ; 80 <2> ; Assumes CS == DS 81 <2> ; 82 <2> ; This routine doesn't enable interrupts, but the target routine 83 <2> ; can enable interrupts by executing STI. 84 <2> ; 85 <2> bits 16 86 <2> section .text16 87 <2> enter_pm: 88 00000335 FA <2> cli 89 00000336 6631C0 <2> xor eax,eax 90 00000339 8ED8 <2> mov ds,ax 91 0000033B 8CD0 <2> mov ax,ss 92 0000033D 8926[0828] <2> mov [RealModeSSSP],sp 93 00000341 A3[0A28] <2> mov [RealModeSSSP+2],ax 94 00000344 660FB7EC <2> movzx ebp,sp 95 00000348 66C1E004 <2> shl eax,4 96 0000034C 6601C5 <2> add ebp,eax ; EBP -> top of real-mode stack 97 0000034F FC <2> cld 98 00000350 E86400 <2> call enable_a20 99 <2> 100 <2> .a20ok: 101 00000353 C606[0D00]89 <2> mov byte [bcopy_gdt.TSS+5],89h ; Mark TSS unbusy 102 <2> 103 00000358 0F0116[0000] <2> lgdt [bcopy_gdt] ; We can use the same GDT just fine 104 0000035D 0F011E[4800] <2> lidt [PM_IDT_ptr] ; Set up the IDT 105 00000362 0F20C0 <2> mov eax,cr0 106 00000365 0C01 <2> or al,1 107 00000367 0F22C0 <2> mov cr0,eax ; Enter protected mode 108 0000036A EA[B600]2000 <2> jmp PM_CS32:.in_pm 109 <2> 110 <2> bits 32 111 <2> section .textnr 112 <2> .in_pm: 113 000000B6 31C0 <2> xor eax,eax ; Available for future use... 114 000000B8 8EE0 <2> mov fs,eax 115 000000BA 8EE8 <2> mov gs,eax 116 000000BC 0F00D0 <2> lldt ax 117 <2> 118 000000BF B028 <2> mov al,PM_DS32 ; Set up data segments 119 000000C1 8EC0 <2> mov es,eax 120 000000C3 8ED8 <2> mov ds,eax 121 000000C5 8ED0 <2> mov ss,eax 122 <2> 123 000000C7 B008 <2> mov al,PM_TSS ; Be nice to Intel's VT by 124 000000C9 0F00D8 <2> ltr ax ; giving it a valid TR 125 <2> 126 000000CC 8B25[44000000] <2> mov esp,[PMESP] ; Load protmode %esp 127 000000D2 89E8 <2> mov eax,ebp ; EAX -> top of real-mode stack 128 000000D4 FFE3 <2> jmp ebx ; Go to where we need to go 129 <2> 130 <2> ; 131 <2> ; enter_rm: Return to RM from PM 132 <2> ; 133 <2> ; BX = RM entry point (CS = 0) 134 <2> ; ECX, EDX, ESI, EDI preserved across this routine 135 <2> ; EAX clobbered 136 <2> ; EBP reserved 137 <2> ; 138 <2> ; This routine doesn't enable interrupts, but the target routine 139 <2> ; can enable interrupts by executing STI. 140 <2> ; 141 <2> bits 32 142 <2> section .textnr 143 <2> enter_rm: 144 000000D6 FA <2> cli 145 000000D7 FC <2> cld 146 000000D8 8925[44000000] <2> mov [PMESP],esp ; Save exit %esp 147 000000DE EA[6F030000]1000 <2> jmp PM_CS16:.in_pm16 ; Return to 16-bit mode first 148 <2> 149 <2> bits 16 150 <2> section .text16 151 <2> .in_pm16: 152 0000036F B81800 <2> mov ax,PM_DS16 ; Real-mode-like segment 153 00000372 8EC0 <2> mov es,ax 154 00000374 8ED8 <2> mov ds,ax 155 00000376 8ED0 <2> mov ss,ax 156 00000378 8EE0 <2> mov fs,ax 157 0000037A 8EE8 <2> mov gs,ax 158 <2> 159 0000037C 0F011E[3000] <2> lidt [RM_IDT_ptr] ; Real-mode IDT (rm needs no GDT) 160 00000381 31D2 <2> xor dx,dx 161 00000383 0F20C0 <2> mov eax,cr0 162 00000386 24FE <2> and al,~1 163 00000388 0F22C0 <2> mov cr0,eax 164 0000038B EA[9003]0000 <2> jmp 0:.in_rm 165 <2> 166 <2> .in_rm: ; Back in real mode 167 00000390 2E0FB226[0828] <2> lss sp,[cs:RealModeSSSP] ; Restore stack 168 00000396 660FB7E4 <2> movzx esp,sp ; Make sure the high bits are zero 169 0000039A 8EDA <2> mov ds,dx ; Set up sane segments 170 0000039C 8EC2 <2> mov es,dx 171 0000039E 8EE2 <2> mov fs,dx 172 000003A0 8EEA <2> mov gs,dx 173 000003A2 FFE3 <2> jmp bx ; Go to whereever we need to go... 174 <2> 175 <2> section .data16 176 00000042 00 <2> alignz 4 177 <2> 178 <2> extern __stack_end 179 00000044 [00000000] <2> PMESP dd __stack_end ; Protected-mode ESP 180 <2> 181 00000048 FF07 <2> PM_IDT_ptr: dw 8*256-1 ; Length 182 0000004A [08200000] <2> dd IDT ; Offset 183 <2> 184 <2> ; 185 <2> ; This is invoked on getting an interrupt in protected mode. At 186 <2> ; this point, we need to context-switch to real mode and invoke 187 <2> ; the interrupt routine. 188 <2> ; 189 <2> ; When this gets invoked, the registers are saved on the stack and 190 <2> ; AL contains the register number. 191 <2> ; 192 <2> bits 32 193 <2> section .textnr 194 <2> pm_irq: 195 000000E5 60 <2> pushad 196 000000E6 0FB6742420 <2> movzx esi,byte [esp+8*4] ; Interrupt number 197 000000EB FF05[50020000] <2> inc dword [CallbackCtr] 198 000000F1 BB[A4030000] <2> mov ebx,.rm 199 000000F6 EBDE <2> jmp enter_rm ; Go to real mode 200 <2> 201 <2> bits 16 202 <2> section .text16 203 <2> .rm: 204 000003A4 9C <2> pushf ; Flags on stack 205 000003A5 2E67FF1CB500000000 <2> call far [cs:esi*4] ; Call IVT entry 206 000003AE 66BB[F8000000] <2> mov ebx,.pm 207 000003B4 E97EFF <2> jmp enter_pm ; Go back to PM 208 <2> 209 <2> bits 32 210 <2> section .textnr 211 <2> .pm: 212 000000F8 FF0D[50020000] <2> dec dword [CallbackCtr] 213 000000FE 7506 <2> jnz .skip 214 00000100 FF15[50000000] <2> call [core_pm_hook] 215 <2> .skip: 216 00000106 61 <2> popad 217 00000107 83C404 <2> add esp,4 ; Drop interrupt number 218 0000010A CF <2> iretd 219 <2> 220 <2> ; 221 <2> ; Initially, the core_pm_hook does nothing; it is available for the 222 <2> ; threaded derivatives to run the scheduler, or examine the result from 223 <2> ; interrupt routines. 224 <2> ; 225 <2> global core_pm_null_hook 226 <2> core_pm_null_hook: 227 0000010B C3 <2> ret 228 <2> 229 <2> section .data16 230 0000004E 00 <2> alignz 4 231 <2> global core_pm_hook 232 00000050 [0B010000] <2> core_pm_hook: dd core_pm_null_hook 233 <2> 234 <2> bits 16 235 <2> section .text16 236 <2> ; 237 <2> ; Routines to enable and disable (yuck) A20. These routines are gathered 238 <2> ; from tips from a couple of sources, including the Linux kernel and 239 <2> ; http://www.x86.org/. The need for the delay to be as large as given here 240 <2> ; is indicated by Donnie Barnes of RedHat, the problematic system being an 241 <2> ; IBM ThinkPad 760EL. 242 <2> ; 243 <2> 244 <2> section .data16 245 <2> alignz 2 246 00000054 [C903] <2> A20Ptr dw a20_dunno 247 <2> 248 <2> section .bss16 249 00000243 <2> alignb 4 250 00000244 <2> A20Test resd 1 ; Counter for testing A20 status 251 00000248 <2> A20Tries resb 1 ; Times until giving up on A20 252 <2> 253 <2> section .text16 254 <2> enable_a20: 255 000003B7 6660 <2> pushad 256 000003B9 2EC606[4802]FF <2> mov byte [cs:A20Tries],255 ; Times to try to make this work 257 <2> 258 <2> try_enable_a20: 259 <2> 260 <2> ; 261 <2> ; First, see if we are on a system with no A20 gate, or the A20 gate 262 <2> ; is already enabled for us... 263 <2> ; 264 <2> a20_none: 265 000003BF E87C00 <2> call a20_test 266 000003C2 7577 <2> jnz a20_done 267 <2> ; Otherwise, see if we had something memorized... 268 000003C4 2EFF26[5400] <2> jmp word [cs:A20Ptr] 269 <2> 270 <2> ; 271 <2> ; Next, try the BIOS (INT 15h AX=2401h) 272 <2> ; 273 <2> a20_dunno: 274 <2> a20_bios: 275 000003C9 2EC706[5400][C903] <2> mov word [cs:A20Ptr], a20_bios 276 000003D0 B80124 <2> mov ax,2401h 277 000003D3 9C <2> pushf ; Some BIOSes muck with IF 278 000003D4 CD15 <2> int 15h 279 000003D6 9D <2> popf 280 <2> 281 000003D7 E86400 <2> call a20_test 282 000003DA 755F <2> jnz a20_done 283 <2> 284 <2> ; 285 <2> ; Enable the keyboard controller A20 gate 286 <2> ; 287 <2> a20_kbc: 288 000003DC B201 <2> mov dl, 1 ; Allow early exit 289 000003DE E88E00 <2> call empty_8042 290 000003E1 7558 <2> jnz a20_done ; A20 live, no need to use KBC 291 <2> 292 000003E3 2EC706[5400][DC03] <2> mov word [cs:A20Ptr], a20_kbc ; Starting KBC command sequence 293 <2> 294 000003EA B0D1 <2> mov al,0D1h ; Write output port 295 000003EC E664 <2> out 064h, al 296 000003EE E87C00 <2> call empty_8042_uncond 297 <2> 298 000003F1 B0DF <2> mov al,0DFh ; A20 on 299 000003F3 E660 <2> out 060h, al 300 000003F5 E87500 <2> call empty_8042_uncond 301 <2> 302 <2> ; Apparently the UHCI spec assumes that A20 toggle 303 <2> ; ends with a null command (assumed to be for sychronization?) 304 <2> ; Put it here to see if it helps anything... 305 000003F8 B0FF <2> mov al,0FFh ; Null command 306 000003FA E664 <2> out 064h, al 307 000003FC E86E00 <2> call empty_8042_uncond 308 <2> 309 <2> ; Verify that A20 actually is enabled. Do that by 310 <2> ; observing a word in low memory and the same word in 311 <2> ; the HMA until they are no longer coherent. Note that 312 <2> ; we don't do the same check in the disable case, because 313 <2> ; we don't want to *require* A20 masking (SYSLINUX should 314 <2> ; work fine without it, if the BIOS does.) 315 000003FF 51 <2> .kbc_wait: push cx 316 00000400 31C9 <2> xor cx,cx 317 <2> .kbc_wait_loop: 318 00000402 E83900 <2> call a20_test 319 00000405 7533 <2> jnz a20_done_pop 320 00000407 E2F9 <2> loop .kbc_wait_loop 321 <2> 322 00000409 59 <2> pop cx 323 <2> ; 324 <2> ; Running out of options here. Final attempt: enable the "fast A20 gate" 325 <2> ; 326 <2> a20_fast: 327 0000040A 2EC706[5400][0A04] <2> mov word [cs:A20Ptr], a20_fast 328 00000411 E492 <2> in al, 092h 329 00000413 0C02 <2> or al,02h 330 00000415 24FE <2> and al,~01h ; Don't accidentally reset the machine! 331 00000417 E692 <2> out 092h, al 332 <2> 333 00000419 51 <2> .fast_wait: push cx 334 0000041A 31C9 <2> xor cx,cx 335 <2> .fast_wait_loop: 336 0000041C E81F00 <2> call a20_test 337 0000041F 7519 <2> jnz a20_done_pop 338 00000421 E2F9 <2> loop .fast_wait_loop 339 <2> 340 00000423 59 <2> pop cx 341 <2> 342 <2> ; 343 <2> ; Oh bugger. A20 is not responding. Try frobbing it again; eventually give up 344 <2> ; and report failure to the user. 345 <2> ; 346 00000424 2EFE0E[4802] <2> dec byte [cs:A20Tries] 347 00000429 759E <2> jnz a20_dunno ; Did we get the wrong type? 348 <2> 349 0000042B BE[5600] <2> mov si, err_a20 350 <2> pm_call pm_writestr 350 0000042E 6668[00000000] <3> push dword %1 350 00000434 E8D9FE <3> call _pm_call 351 00000437 E99AFC <2> jmp kaboom 352 <2> 353 <2> section .data16 354 00000056 0D0A41323020676174- <2> err_a20 db CR, LF, 'A20 gate not responding!', CR, LF, 0 354 0000005F 65206E6F7420726573- <2> 354 00000068 706F6E64696E67210D- <2> 354 00000071 0A00 <2> 355 <2> section .text16 356 <2> 357 <2> ; 358 <2> ; A20 unmasked, proceed... 359 <2> ; 360 0000043A 59 <2> a20_done_pop: pop cx 361 0000043B 6661 <2> a20_done: popad 362 0000043D C3 <2> ret 363 <2> 364 <2> ; 365 <2> ; This routine tests if A20 is enabled (ZF = 0). This routine 366 <2> ; must not destroy any register contents. 367 <2> ; 368 <2> ; The no-write early out avoids the io_delay in the (presumably common) 369 <2> ; case of A20 already enabled (e.g. from a previous call.) 370 <2> ; 371 <2> a20_test: 372 0000043E 06 <2> push es 373 0000043F 51 <2> push cx 374 00000440 6650 <2> push eax 375 00000442 B9FFFF <2> mov cx,0FFFFh ; HMA = segment 0FFFFh 376 00000445 8EC1 <2> mov es,cx 377 00000447 2E66A1[4402] <2> mov eax,[cs:A20Test] 378 0000044C B92000 <2> mov cx,32 ; Loop count 379 0000044F EB0F <2> jmp .test ; First iteration = early out 380 00000451 660541EA0A43 <2> .wait: add eax,0x430aea41 ; A large prime number 381 00000457 2E66A3[4402] <2> mov [cs:A20Test],eax 382 0000045C E680E680 <2> io_delay ; Serialize, and fix delay 383 00000460 26663B06[5402] <2> .test: cmp eax,[es:A20Test+10h] 384 00000466 E1E9 <2> loopz .wait 385 00000468 6658 <2> .done: pop eax 386 0000046A 59 <2> pop cx 387 0000046B 07 <2> pop es 388 0000046C C3 <2> ret 389 <2> 390 <2> ; 391 <2> ; Routine to empty the 8042 KBC controller. If dl != 0 392 <2> ; then we will test A20 in the loop and exit if A20 is 393 <2> ; suddenly enabled. 394 <2> ; 395 <2> empty_8042_uncond: 396 0000046D 30D2 <2> xor dl,dl 397 <2> empty_8042: 398 0000046F E8CCFF <2> call a20_test 399 00000472 7404 <2> jz .a20_on 400 00000474 20D2 <2> and dl,dl 401 00000476 751A <2> jnz .done 402 00000478 E680E680 <2> .a20_on: io_delay 403 0000047C E464 <2> in al, 064h ; Status port 404 0000047E A801 <2> test al,1 405 00000480 7408 <2> jz .no_output 406 00000482 E680E680 <2> io_delay 407 00000486 E460 <2> in al, 060h ; Read input 408 00000488 EBE5 <2> jmp short empty_8042 409 <2> .no_output: 410 0000048A A802 <2> test al,2 411 0000048C 75E1 <2> jnz empty_8042 412 0000048E E680E680 <2> io_delay 413 00000492 C3 <2> .done: ret 414 <2> 415 <2> ; 416 <2> ; This initializes the protected-mode interrupt thunk set 417 <2> ; 418 <2> section .text16 419 <2> pm_init: 420 00000493 6631FF <2> xor edi,edi 421 00000496 BB[0820] <2> mov bx,IDT 422 00000499 BF[0000] <2> mov di,IRQStubs 423 <2> 424 0000049C 66B86A00EB7A <2> mov eax,7aeb006ah ; push byte .. jmp short .. 425 <2> 426 000004A2 B90800 <2> mov cx,8 ; 8 groups of 32 IRQs 427 <2> .gloop: 428 000004A5 51 <2> push cx 429 000004A6 B92000 <2> mov cx,32 ; 32 entries per group 430 <2> .eloop: 431 000004A9 893F <2> mov [bx],di ; IDT offset [15:0] 432 000004AB C747022000 <2> mov word [bx+2],PM_CS32 ; IDT segment 433 000004B0 66C74704008E0000 <2> mov dword [bx+4],08e00h ; IDT offset [31:16], 32-bit interrupt 434 <2> ; gate, CPL 0 (we don't have a TSS 435 <2> ; set up...) 436 000004B8 83C308 <2> add bx,8 437 <2> 438 000004BB 66AB <2> stosd 439 <2> ; Increment IRQ, decrement jmp short offset 440 000004BD 6605000100FC <2> add eax,(-4 << 24)+(1 << 8) 441 <2> 442 000004C3 E2E4 <2> loop .eloop 443 <2> 444 <2> ; At the end of each group, replace the EBxx with 445 <2> ; the final E9xxxxxxxx 446 000004C5 83C703 <2> add di,3 447 000004C8 C645FBE9 <2> mov byte [di-5],0E9h ; JMP NEAR 448 000004CC 66BA[E5000000] <2> mov edx,pm_irq 449 000004D2 6629FA <2> sub edx,edi 450 000004D5 668955FC <2> mov [di-4],edx 451 <2> 452 000004D9 660500000080 <2> add eax,(0x80 << 24) ; Proper offset for the next one 453 000004DF 59 <2> pop cx 454 000004E0 E2C3 <2> loop .gloop 455 <2> 456 000004E2 C3 <2> ret 457 <2> 458 <2> ; pm_init is called before bss clearing, so put these 459 <2> ; in .earlybss! 460 <2> section .earlybss 461 00002004 <2> alignb 8 462 00002008 <2> IDT: resq 256 463 <2> global RealModeSSSP 464 00002808 <2> RealModeSSSP resd 1 ; Real-mode SS:SP 465 <2> 466 <2> section .gentextnr ; Autogenerated 32-bit code 467 00000000 <2> IRQStubs: resb 4*256+3*8 468 <2> 469 <2> section .text16 470 <2> 471 <2> %include "callback.inc" ; Real-mode callbacks 1 <3> ;; ----------------------------------------------------------------------- 2 <3> ;; 3 <3> ;; Copyright 1994-2009 H. Peter Anvin - All Rights Reserved 4 <3> ;; Copyright 2009 Intel Corporation; author: H. Peter Anvin 5 <3> ;; 6 <3> ;; This program is free software; you can redistribute it and/or modify 7 <3> ;; it under the terms of the GNU General Public License as published by 8 <3> ;; the Free Software Foundation, Inc., 53 Temple Place Ste 330, 9 <3> ;; Boston MA 02111-1307, USA; either version 2 of the License, or 10 <3> ;; (at your option) any later version; incorporated herein by reference. 11 <3> ;; 12 <3> ;; ----------------------------------------------------------------------- 13 <3> 14 <3> ;; 15 <3> ;; callback.inc 16 <3> ;; 17 <3> ;; Callbacks from 32-bit mode to 16-bit mode 18 <3> ;; 19 <3> 20 <3> ; 21 <3> ; 16-bit intcall/farcall handling code 22 <3> ; 23 <3> 24 <3> ; 25 <3> ; 32-bit support code 26 <3> ; 27 <3> bits 32 28 <3> section .text 29 <3> 30 <3> ; 31 <3> ; Intcall/farcall invocation. We manifest a structure on the real-mode stack, 32 <3> ; containing the com32sys_t structure from as well as 33 <3> ; the following entries (from low to high address): 34 <3> ; - Target offset 35 <3> ; - Target segment 36 <3> ; - Return offset 37 <3> ; - Return segment (== real mode cs == 0) 38 <3> ; - Return flags 39 <3> ; 40 <3> global core_farcall:function hidden 41 <3> core_farcall: 42 00000000 8B442404 <3> mov eax,[esp+1*4] ; CS:IP 43 00000004 EB0C <3> jmp core_syscall 44 <3> 45 <3> global core_intcall:function hidden 46 <3> core_intcall: 47 00000006 0FB6442404 <3> movzx eax,byte [esp+1*4] ; INT number 48 0000000B 8B048500000000 <3> mov eax,[eax*4] ; Get CS:IP from low memory 49 <3> 50 <3> core_syscall: 51 00000012 9C <3> pushfd ; Save IF among other things... 52 00000013 FF05[50020000] <3> inc dword [CallbackCtr] 53 00000019 53 <3> push ebx 54 0000001A 55 <3> push ebp 55 0000001B 56 <3> push esi 56 0000001C 57 <3> push edi 57 0000001D FF35[4C020000] <3> push dword [CallbackSP] 58 <3> 59 00000023 FC <3> cld 60 <3> 61 00000024 670FB73E[0828] <3> movzx edi,word [word RealModeSSSP] 62 0000002A 670FB71E[0A28] <3> movzx ebx,word [word RealModeSSSP+2] 63 00000030 83EF36 <3> sub edi,54 ; Allocate 54 bytes 64 00000033 6667893E[0828] <3> mov [word RealModeSSSP],di 65 00000039 C1E304 <3> shl ebx,4 66 0000003C 01DF <3> add edi,ebx ; Create linear address 67 <3> 68 0000003E 8B742420 <3> mov esi,[esp+8*4] ; Source regs 69 00000042 31C9 <3> xor ecx,ecx 70 00000044 B10B <3> mov cl,11 ; 44 bytes to copy 71 00000046 F3A5 <3> rep movsd 72 <3> 73 <3> ; EAX is already set up to be CS:IP 74 00000048 AB <3> stosd ; Save in stack frame 75 00000049 B8[F6040000] <3> mov eax,.rm_return ; Return seg:offs 76 0000004E AB <3> stosd ; Save in stack frame 77 0000004F 8B47F4 <3> mov eax,[edi-12] ; Return flags 78 00000052 25D70E2000 <3> and eax,0x200ed7 ; Mask (potentially) unsafe flags 79 00000057 8947F4 <3> mov [edi-12],eax ; Primary flags entry 80 0000005A 66AB <3> stosw ; Return flags 81 <3> 82 0000005C 66BB[E304] <3> mov bx,.rm 83 00000060 E9(D6000000) <3> jmp enter_rm ; Go to real mode 84 <3> 85 <3> bits 16 86 <3> section .text16 87 <3> .rm: 88 000004E3 89E0 <3> mov ax,sp 89 000004E5 83C02C <3> add ax,9*4+4*2 90 000004E8 A3[4C02] <3> mov [CallbackSP],ax 91 000004EB 0FA9 <3> pop gs 92 000004ED 0FA1 <3> pop fs 93 000004EF 07 <3> pop es 94 000004F0 1F <3> pop ds 95 000004F1 6661 <3> popad 96 000004F3 669D <3> popfd 97 000004F5 CB <3> retf ; Invoke routine 98 <3> 99 <3> .rm_return: 100 <3> ; We clean up SP here because we don't know if the 101 <3> ; routine returned with RET, RETF or IRET 102 000004F6 2E8B26[4C02] <3> mov sp,[cs:CallbackSP] 103 000004FB 669C <3> pushfd 104 000004FD 6660 <3> pushad 105 000004FF 1E <3> push ds 106 00000500 06 <3> push es 107 00000501 0FA0 <3> push fs 108 00000503 0FA8 <3> push gs 109 00000505 66BB[65000000] <3> mov ebx,.pm_return 110 0000050B E927FE <3> jmp enter_pm 111 <3> 112 <3> ; On return, the 44-byte return structure is on the 113 <3> ; real-mode stack, plus the 10 additional bytes used 114 <3> ; by the target address (see above.) 115 <3> bits 32 116 <3> section .text 117 <3> .pm_return: 118 00000065 670FB736[0828] <3> movzx esi,word [word RealModeSSSP] 119 0000006B 670FB706[0A28] <3> movzx eax,word [word RealModeSSSP+2] 120 00000071 8B7C2424 <3> mov edi,[esp+9*4] ; Dest regs 121 00000075 C1E004 <3> shl eax,4 122 00000078 01C6 <3> add esi,eax ; Create linear address 123 0000007A 21FF <3> and edi,edi ; NULL pointer? 124 0000007C 7502 <3> jnz .do_copy 125 0000007E 89F7 <3> .no_copy: mov edi,esi ; Do a dummy copy-to-self 126 00000080 31C9 <3> .do_copy: xor ecx,ecx 127 00000082 B10B <3> mov cl,11 ; 44 bytes 128 00000084 F3A5 <3> rep movsd ; Copy register block 129 <3> 130 00000086 678306[0828]36 <3> add dword [word RealModeSSSP],54 131 <3> ; Remove from stack 132 <3> 133 0000008C 8F05[4C020000] <3> pop dword [CallbackSP] 134 00000092 FF0D[50020000] <3> dec dword [CallbackCtr] 135 00000098 7506 <3> jnz .skip 136 0000009A FF15[50000000] <3> call [core_pm_hook] 137 <3> .skip: 138 000000A0 5F <3> pop edi 139 000000A1 5E <3> pop esi 140 000000A2 5D <3> pop ebp 141 000000A3 5B <3> pop ebx 142 000000A4 9D <3> popfd 143 000000A5 C3 <3> ret ; Return to 32-bit program 144 <3> 145 <3> ; 146 <3> ; Cfarcall invocation. We copy the stack frame to the real-mode stack, 147 <3> ; followed by the return CS:IP and the CS:IP of the target function. 148 <3> ; The value of IF is copied from the calling routine. 149 <3> ; 150 <3> global core_cfarcall:function hidden 151 <3> core_cfarcall: 152 000000A6 9C <3> pushfd ; Save IF among other things... 153 000000A7 FF05[50020000] <3> inc dword [CallbackCtr] 154 000000AD 53 <3> push ebx 155 000000AE 55 <3> push ebp 156 000000AF 56 <3> push esi 157 000000B0 57 <3> push edi 158 000000B1 FF35[4C020000] <3> push dword [CallbackSP] 159 <3> 160 000000B7 FC <3> cld 161 000000B8 8B4C2424 <3> mov ecx,[esp+9*4] ; Size of stack frame 162 <3> 163 000000BC 670FB73E[0828] <3> movzx edi,word [word RealModeSSSP] 164 000000C2 670FB71E[0A28] <3> movzx ebx,word [word RealModeSSSP+2] 165 000000C8 6667893E[4C02] <3> mov [word CallbackSP],di 166 000000CE 29CF <3> sub edi,ecx ; Allocate space for stack frame 167 000000D0 83E7FC <3> and edi,~3 ; Round 168 000000D3 83EF0C <3> sub edi,4*3 ; Return pointer, return value, EFLAGS 169 000000D6 6667893E[0828] <3> mov [word RealModeSSSP],di 170 000000DC C1E304 <3> shl ebx,4 171 000000DF 01DF <3> add edi,ebx ; Create linear address 172 <3> 173 000000E1 8B442414 <3> mov eax,[esp+5*4] ; EFLAGS from entry 174 000000E5 2502020000 <3> and eax,0x202 ; IF only 175 000000EA AB <3> stosd 176 000000EB 8B44241C <3> mov eax,[esp+7*4] ; CS:IP 177 000000EF AB <3> stosd ; Save to stack frame 178 000000F0 B8[11050000] <3> mov eax,.rm_return ; Return seg:off 179 000000F5 AB <3> stosd 180 000000F6 8B742420 <3> mov esi,[esp+8*4] ; Stack frame 181 000000FA 89C8 <3> mov eax,ecx ; Copy the stack frame 182 000000FC C1E902 <3> shr ecx,2 183 000000FF F3A5 <3> rep movsd 184 00000101 89C1 <3> mov ecx,eax 185 00000103 83E103 <3> and ecx,3 186 00000106 F3A4 <3> rep movsb 187 <3> 188 00000108 66BB[0E05] <3> mov bx,.rm 189 0000010C E9(D6000000) <3> jmp enter_rm 190 <3> 191 <3> bits 16 192 <3> section .text16 193 <3> .rm: 194 0000050E 669D <3> popfd 195 00000510 CB <3> retf 196 <3> .rm_return: 197 00000511 2E8B26[4C02] <3> mov sp,[cs:CallbackSP] 198 00000516 6689C6 <3> mov esi,eax 199 00000519 66BB[11010000] <3> mov ebx,.pm_return 200 0000051F E913FE <3> jmp enter_pm 201 <3> 202 <3> bits 32 203 <3> section .text 204 <3> .pm_return: 205 00000111 89F0 <3> mov eax,esi 206 <3> ; EDX already set up to be the RM return value 207 00000113 8F05[4C020000] <3> pop dword [CallbackSP] 208 00000119 FF0D[50020000] <3> dec dword [CallbackCtr] 209 0000011F 7506 <3> jnz .skip 210 00000121 FF15[50000000] <3> call [core_pm_hook] 211 <3> .skip: 212 00000127 5B <3> pop ebx 213 00000128 5D <3> pop ebp 214 00000129 5E <3> pop esi 215 0000012A 5F <3> pop edi 216 0000012B 9D <3> popfd 217 0000012C C3 <3> ret 218 <3> 219 <3> section .bss16 220 00000249 <3> alignb 4 221 <3> global core_pm_hook 222 0000024C <3> CallbackSP resd 1 ; SP saved during callback 223 00000250 <3> CallbackCtr resd 1 224 <3> 225 <3> bits 16 226 <3> section .text16 8 <1> %include "bcopy32.inc" ; 32-bit bcopy 1 <2> ;; ----------------------------------------------------------------------- 2 <2> ;; 3 <2> ;; Copyright 1994-2009 H. Peter Anvin - All Rights Reserved 4 <2> ;; Copyright 2009 Intel Corporation; author: H. Peter Anvin 5 <2> ;; 6 <2> ;; This program is free software; you can redistribute it and/or modify 7 <2> ;; it under the terms of the GNU General Public License as published by 8 <2> ;; the Free Software Foundation, Inc., 53 Temple Place Ste 330, 9 <2> ;; Boston MA 02111-1307, USA; either version 2 of the License, or 10 <2> ;; (at your option) any later version; incorporated herein by reference. 11 <2> ;; 12 <2> ;; ----------------------------------------------------------------------- 13 <2> 14 <2> ;; 15 <2> ;; bcopy32.inc 16 <2> ;; 17 <2> ;; 32-bit bcopy routine for real mode 18 <2> ;; 19 <2> 20 <2> ; 21 <2> ; 32-bit bcopy routine for real mode 22 <2> ; 23 <2> ; We enter protected mode, set up a flat 32-bit environment, run rep movsd 24 <2> ; and then exit. IMPORTANT: This code assumes cs == 0. 25 <2> ; 26 <2> ; This code is probably excessively anal-retentive in its handling of 27 <2> ; segments, but this stuff is painful enough as it is without having to rely 28 <2> ; on everything happening "as it ought to." 29 <2> ; 30 <2> 31 <2> bits 16 32 <2> section .text16 33 <2> 34 <2> ; 35 <2> ; bcopy: 36 <2> ; 32-bit copy, overlap safe 37 <2> ; 38 <2> ; Inputs: 39 <2> ; ESI - source pointer (-1 means do bzero rather than bcopy) 40 <2> ; EDI - target pointer 41 <2> ; ECX - byte count 42 <2> ; 43 <2> ; Outputs: 44 <2> ; ESI - first byte after source (garbage if ESI == -1 on entry) 45 <2> ; EDI - first byte after target 46 <2> ; 47 00000522 67E30F <2> bcopy: jecxz .ret 48 <2> pm_call pm_bcopy 48 00000525 6668[00000000] <3> push dword %1 48 0000052B E8E2FD <3> call _pm_call 49 0000052E 6601CF <2> add edi,ecx 50 00000531 6601CE <2> add esi,ecx 51 00000534 C3 <2> .ret: ret 52 <2> 53 <2> ; 54 <2> ; shuffle_and_boot_raw: 55 <2> ; The new version of shuffle and boot. 56 <2> ; Inputs: 57 <2> ; ESI -> Pointer to list of (dst, src, len) pairs(*) 58 <2> ; EDI -> Pointer to safe area for list + shuffler 59 <2> ; (must not overlap this code nor the RM stack) 60 <2> ; ECX -> Byte count of list area (for initial copy) 61 <2> ; 62 <2> ; If src == -1: then the memory pointed to by (dst, len) is bzeroed; 63 <2> ; this is handled inside the bcopy routine. 64 <2> ; 65 <2> ; If len == 0: this marks the end of the list; dst indicates 66 <2> ; the entry point and src the mode (0 = pm, 1 = rm) 67 <2> ; 68 <2> ; (*) dst, src, and len are four bytes each 69 <2> ; 70 <2> shuffle_and_boot_raw: 71 00000535 BB[BA00] <2> mov bx,pm_shuffle 72 00000538 E9FAFD <2> jmp enter_pm 73 <2> 74 <2> ; 75 <2> ; The 32-bit copy and shuffle code is "special", so it is in its own file 76 <2> ; 77 <2> %include "bcopyxx.inc" 1 <3> ;; ----------------------------------------------------------------------- 2 <3> ;; 3 <3> ;; Copyright 1994-2009 H. Peter Anvin - All Rights Reserved 4 <3> ;; Copyright 2009-2010 Intel Corporation; author: H. Peter Anvin 5 <3> ;; 6 <3> ;; This program is free software; you can redistribute it and/or modify 7 <3> ;; it under the terms of the GNU General Public License as published by 8 <3> ;; the Free Software Foundation, Inc., 53 Temple Place Ste 330, 9 <3> ;; Boston MA 02111-1307, USA; either version 2 of the License, or 10 <3> ;; (at your option) any later version; incorporated herein by reference. 11 <3> ;; 12 <3> ;; ----------------------------------------------------------------------- 13 <3> 14 <3> ;; 15 <3> ;; bcopy32xx.inc 16 <3> ;; 17 <3> 18 <3> 19 <3> ; 20 <3> ; 32-bit bcopy routine 21 <3> ; 22 <3> ; This is the actual 32-bit portion of the bcopy and shuffle and boot 23 <3> ; routines. ALL THIS CODE NEEDS TO BE POSITION-INDEPENDENT, with the 24 <3> ; sole exception being the actual relocation code at the beginning of 25 <3> ; pm_shuffle_boot. 26 <3> ; 27 <3> ; It also really needs to live all in a single segment, for the 28 <3> ; address calculcations to actually work. 29 <3> ; 30 <3> 31 <3> bits 32 32 <3> section .bcopyxx.text 33 <3> align 16 34 <3> ; 35 <3> ; pm_bcopy: 36 <3> ; 37 <3> ; This is the protected-mode core of the "bcopy" routine. 38 <3> ; Try to do aligned transfers; if the src and dst are relatively 39 <3> ; misaligned, align the dst. 40 <3> ; 41 <3> ; ECX is guaranteed to not be zero on entry. 42 <3> ; 43 <3> ; Clobbers ESI, EDI, ECX. 44 <3> ; 45 <3> 46 <3> pm_bcopy: 47 00000000 53 <3> push ebx 48 00000001 52 <3> push edx 49 00000002 50 <3> push eax 50 <3> 51 00000003 83FEFF <3> cmp esi,-1 52 00000006 747E <3> je .bzero 53 <3> 54 00000008 39FE <3> cmp esi,edi ; If source < destination, we might 55 0000000A 722E <3> jb .reverse ; have to copy backwards 56 <3> 57 <3> .forward: 58 <3> ; Initial alignment 59 0000000C 89FA <3> mov edx,edi 60 0000000E D1EA <3> shr edx,1 61 00000010 7302 <3> jnc .faa1 62 00000012 A4 <3> movsb 63 00000013 49 <3> dec ecx 64 <3> .faa1: 65 00000014 88C8 <3> mov al,cl 66 00000016 83F902 <3> cmp ecx,2 67 00000019 7216 <3> jb .f_tiny 68 <3> 69 0000001B D1EA <3> shr edx,1 70 0000001D 7305 <3> jnc .faa2 71 0000001F 66A5 <3> movsw 72 00000021 83E902 <3> sub ecx,2 73 <3> .faa2: 74 <3> 75 <3> ; Bulk transfer 76 00000024 88C8 <3> mov al,cl ; Save low bits 77 00000026 C1E902 <3> shr ecx,2 ; Convert to dwords 78 00000029 F3A5 <3> rep movsd ; Do our business 79 <3> ; At this point ecx == 0 80 <3> 81 0000002B A802 <3> test al,2 82 0000002D 7402 <3> jz .fab2 83 0000002F 66A5 <3> movsw 84 <3> .fab2: 85 <3> .f_tiny: 86 00000031 A801 <3> test al,1 87 00000033 7401 <3> jz .fab1 88 00000035 A4 <3> movsb 89 <3> .fab1: 90 <3> .done: 91 00000036 58 <3> pop eax 92 00000037 5A <3> pop edx 93 00000038 5B <3> pop ebx 94 00000039 C3 <3> ret 95 <3> 96 <3> .reverse: 97 0000003A 8D440EFF <3> lea eax,[esi+ecx-1] ; Point to final byte 98 0000003E 39C7 <3> cmp edi,eax 99 00000040 77CA <3> ja .forward ; No overlap, do forward copy 100 <3> 101 00000042 FD <3> std ; Reverse copy 102 00000043 8D7C0FFF <3> lea edi,[edi+ecx-1] 103 00000047 89C6 <3> mov esi,eax 104 <3> 105 <3> ; Initial alignment 106 00000049 89FA <3> mov edx,edi 107 0000004B D1EA <3> shr edx,1 108 0000004D 7202 <3> jc .raa1 109 0000004F A4 <3> movsb 110 00000050 49 <3> dec ecx 111 <3> .raa1: 112 <3> 113 00000051 4E <3> dec esi 114 00000052 4F <3> dec edi 115 00000053 88C8 <3> mov al,cl 116 00000055 83F902 <3> cmp ecx,2 117 00000058 7222 <3> jb .r_tiny 118 0000005A D1EA <3> shr edx,1 119 0000005C 7205 <3> jc .raa2 120 0000005E 66A5 <3> movsw 121 00000060 83E902 <3> sub ecx,2 122 <3> .raa2: 123 <3> 124 <3> ; Bulk copy 125 00000063 83EE02 <3> sub esi,2 126 00000066 83EF02 <3> sub edi,2 127 00000069 88C8 <3> mov al,cl ; Save low bits 128 0000006B C1E902 <3> shr ecx,2 129 0000006E F3A5 <3> rep movsd 130 <3> 131 <3> ; Final alignment 132 <3> .r_final: 133 00000070 83C602 <3> add esi,2 134 00000073 83C702 <3> add edi,2 135 00000076 A802 <3> test al,2 136 00000078 7402 <3> jz .rab2 137 0000007A 66A5 <3> movsw 138 <3> .rab2: 139 <3> .r_tiny: 140 0000007C 46 <3> inc esi 141 0000007D 47 <3> inc edi 142 0000007E A801 <3> test al,1 143 00000080 7401 <3> jz .rab1 144 00000082 A4 <3> movsb 145 <3> .rab1: 146 00000083 FC <3> cld 147 00000084 EBB0 <3> jmp short .done 148 <3> 149 <3> .bzero: 150 00000086 31C0 <3> xor eax,eax 151 <3> 152 <3> ; Initial alignment 153 00000088 89FA <3> mov edx,edi 154 0000008A D1EA <3> shr edx,1 155 0000008C 7302 <3> jnc .zaa1 156 0000008E AA <3> stosb 157 0000008F 49 <3> dec ecx 158 <3> .zaa1: 159 <3> 160 00000090 88CB <3> mov bl,cl 161 00000092 83F902 <3> cmp ecx,2 162 00000095 7217 <3> jb .z_tiny 163 00000097 D1EA <3> shr edx,1 164 00000099 7305 <3> jnc .zaa2 165 0000009B 66AB <3> stosw 166 0000009D 83E902 <3> sub ecx,2 167 <3> .zaa2: 168 <3> 169 <3> ; Bulk 170 000000A0 88CB <3> mov bl,cl ; Save low bits 171 000000A2 C1E902 <3> shr ecx,2 172 000000A5 F3AB <3> rep stosd 173 <3> 174 000000A7 F6C302 <3> test bl,2 175 000000AA 7402 <3> jz .zab2 176 000000AC 66AB <3> stosw 177 <3> .zab2: 178 <3> .z_tiny: 179 000000AE F6C301 <3> test bl,1 180 000000B1 7401 <3> jz .zab1 181 000000B3 AA <3> stosb 182 <3> .zab1: 183 000000B4 EB80 <3> jmp short .done 184 <3> 185 <3> ; 186 <3> ; shuffle_and_boot: 187 <3> ; 188 <3> ; This routine is used to shuffle memory around, followed by 189 <3> ; invoking an entry point somewhere in low memory. This routine 190 <3> ; can clobber any memory outside the bcopy special area. 191 <3> ; 192 <3> ; IMPORTANT: This routine does not set up any registers. 193 <3> ; It is the responsibility of the caller to generate an appropriate entry 194 <3> ; stub; *especially* when going to real mode. 195 <3> ; 196 <3> ; Inputs: 197 <3> ; ESI -> Pointer to list of (dst, src, len) pairs(*) 198 <3> ; EDI -> Pointer to safe area for list + shuffler 199 <3> ; (must not overlap this code nor the RM stack) 200 <3> ; ECX -> Byte count of list area (for initial copy) 201 <3> ; 202 <3> ; If src == -1: then the memory pointed to by (dst, len) is bzeroed; 203 <3> ; this is handled inside the bcopy routine. 204 <3> ; 205 <3> ; If len == 0: this marks the end of the list; dst indicates 206 <3> ; the entry point and src the mode (0 = pm, 1 = rm) 207 <3> ; 208 <3> ; (*) dst, src, and len are four bytes each 209 <3> ; 210 <3> ; do_raw_shuffle_and_boot is the same entry point, but with a C ABI: 211 <3> ; do_raw_shuffle_and_boot(safearea, descriptors, bytecount) 212 <3> ; 213 <3> global do_raw_shuffle_and_boot 214 <3> do_raw_shuffle_and_boot: 215 000000B6 89C7 <3> mov edi,eax 216 000000B8 89D6 <3> mov esi,edx 217 <3> 218 <3> pm_shuffle: 219 000000BA FA <3> cli ; End interrupt service (for good) 220 000000BB 89FB <3> mov ebx,edi ; EBX <- descriptor list 221 000000BD 8D540F0F <3> lea edx,[edi+ecx+15] ; EDX <- where to relocate our code to 222 000000C1 83E2F0 <3> and edx,~15 ; Align 16 to benefit the GDT 223 000000C4 E837FFFFFF <3> call pm_bcopy 224 000000C9 BE[00000000] <3> mov esi,__bcopyxx_start ; Absolute source address 225 000000CE 89D7 <3> mov edi,edx ; Absolute target address 226 000000D0 29F2 <3> sub edx,esi ; EDX <- address delta 227 000000D2 B9[00000000] <3> mov ecx,__bcopyxx_dwords 228 000000D7 8D82[E1000000] <3> lea eax,[edx+.safe] ; Resume point 229 <3> ; Relocate this code 230 000000DD F3A5 <3> rep movsd 231 000000DF FFE0 <3> jmp eax ; Jump to safe location 232 <3> .safe: 233 <3> ; Give ourselves a safe stack 234 000000E1 8DA2[80000000] <3> lea esp,[edx+bcopyxx_stack+__bcopyxx_end] 235 000000E7 81C2[00000000] <3> add edx,bcopy_gdt ; EDX <- new GDT 236 000000ED 895202 <3> mov [edx+2],edx ; GDT self-pointer 237 000000F0 0F0112 <3> lgdt [edx] ; Switch to local GDT 238 <3> 239 <3> ; Now for the actual shuffling... 240 <3> .loop: 241 000000F3 8B3B <3> mov edi,[ebx] 242 000000F5 8B7304 <3> mov esi,[ebx+4] 243 000000F8 8B4B08 <3> mov ecx,[ebx+8] 244 000000FB 83C30C <3> add ebx,12 245 000000FE E307 <3> jecxz .done 246 00000100 E8FBFEFFFF <3> call pm_bcopy 247 00000105 EBEC <3> jmp .loop 248 <3> .done: 249 00000107 0F015A30 <3> lidt [edx+RM_IDT_ptr-bcopy_gdt] ; RM-like IDT 250 0000010B 51 <3> push ecx ; == 0, for cleaning the flags register 251 0000010C 21F6 <3> and esi,esi 252 0000010E 7403 <3> jz pm_shuffle_16 253 00000110 9D <3> popfd ; Clean the flags 254 00000111 FFE7 <3> jmp edi ; Protected mode entry 255 <3> 256 <3> ; We have a 16-bit entry point, so we need to return 257 <3> ; to 16-bit mode. Note: EDX already points to the GDT. 258 <3> pm_shuffle_16: 259 00000113 89F8 <3> mov eax,edi 260 00000115 66894212 <3> mov [edx+PM_CS16+2],ax 261 00000119 6689421A <3> mov [edx+PM_DS16+2],ax 262 0000011D C1E810 <3> shr eax,16 263 00000120 884214 <3> mov [edx+PM_CS16+4],al 264 00000123 886217 <3> mov [edx+PM_CS16+7],ah 265 00000126 88421C <3> mov [edx+PM_DS16+4],al 266 00000129 88621F <3> mov [edx+PM_DS16+7],ah 267 0000012C 0F20C0 <3> mov eax,cr0 268 0000012F 24FE <3> and al,~1 269 00000131 9D <3> popfd ; Clean the flags 270 <3> ; No flag-changing instructions below... 271 00000132 66BA1800 <3> mov dx,PM_DS16 272 00000136 8EDA <3> mov ds,edx 273 00000138 8EC2 <3> mov es,edx 274 0000013A 8EE2 <3> mov fs,edx 275 0000013C 8EEA <3> mov gs,edx 276 0000013E 8ED2 <3> mov ss,edx 277 00000140 EA000000001000 <3> jmp PM_CS16:0 278 <3> 279 <3> section .bcopyxx.data 280 <3> 281 <3> alignz 16 282 <3> ; GDT descriptor entry 283 <3> %macro desc 1 284 <3> bcopy_gdt.%1: 285 <3> PM_%1 equ bcopy_gdt.%1-bcopy_gdt 286 <3> %endmacro 287 <3> 288 <3> bcopy_gdt: 289 00000000 2F00 <3> dw bcopy_gdt_size-1 ; Null descriptor - contains GDT 290 00000002 [00000000] <3> dd bcopy_gdt ; pointer for LGDT instruction 291 00000006 0000 <3> dw 0 292 <3> 293 <3> ; TSS segment to keep Intel VT happy. Intel VT is 294 <3> ; unhappy about anything that doesn't smell like a 295 <3> ; full-blown 32-bit OS. 296 <3> desc TSS 296 <4> bcopy_gdt.%1: 296 <4> PM_%1 equ bcopy_gdt.%1-bcopy_gdt 297 00000008 67008005 <3> dw 104-1, DummyTSS ; 08h 32-bit task state segment 298 0000000C 00890000 <3> dd 00008900h ; present, dpl 0, 104 bytes @DummyTSS 299 <3> 300 <3> desc CS16 300 <4> bcopy_gdt.%1: 300 <4> PM_%1 equ bcopy_gdt.%1-bcopy_gdt 301 00000010 FFFF0000 <3> dd 0000ffffh ; 10h Code segment, use16, readable, 302 00000014 009B0000 <3> dd 00009b00h ; present, dpl 0, cover 64K 303 <3> desc DS16 303 <4> bcopy_gdt.%1: 303 <4> PM_%1 equ bcopy_gdt.%1-bcopy_gdt 304 00000018 FFFF0000 <3> dd 0000ffffh ; 18h Data segment, use16, read/write, 305 0000001C 00930000 <3> dd 00009300h ; present, dpl 0, cover 64K 306 <3> desc CS32 306 <4> bcopy_gdt.%1: 306 <4> PM_%1 equ bcopy_gdt.%1-bcopy_gdt 307 00000020 FFFF0000 <3> dd 0000ffffh ; 20h Code segment, use32, readable, 308 00000024 009BCF00 <3> dd 00cf9b00h ; present, dpl 0, cover all 4G 309 <3> desc DS32 309 <4> bcopy_gdt.%1: 309 <4> PM_%1 equ bcopy_gdt.%1-bcopy_gdt 310 00000028 FFFF0000 <3> dd 0000ffffh ; 28h Data segment, use32, read/write, 311 0000002C 0093CF00 <3> dd 00cf9300h ; present, dpl 0, cover all 4G 312 <3> 313 <3> bcopy_gdt_size: equ $-bcopy_gdt 314 <3> ; 315 <3> ; Space for a dummy task state segment. It should never be actually 316 <3> ; accessed, but just in case it is, point to a chunk of memory that 317 <3> ; has a chance to not be used for anything real... 318 <3> ; 319 <3> DummyTSS equ 0x580 320 <3> 321 <3> align 4 322 00000030 FFFF <3> RM_IDT_ptr: dw 0FFFFh ; Length (nonsense, but matches CPU) 323 00000032 00000000 <3> dd 0 ; Offset 324 <3> 325 <3> bcopyxx_stack equ 128 ; We want this much stack 326 <3> 327 <3> section .rodata 328 <3> global __syslinux_shuffler_size 329 <3> extern __bcopyxx_len 330 <3> align 4 331 <3> __syslinux_shuffler_size: 332 00000008 [00000000] <3> dd __bcopyxx_len 333 <3> 334 <3> bits 16 335 <3> section .text16 9 <1> %include "strcpy.inc" ; strcpy() 1 <2> ; 2 <2> ; strcpy: Copy DS:SI -> ES:DI up to and including a null byte; 3 <2> ; on exit SI and DI point to the byte *after* the null byte 4 <2> ; 5 <2> section .text16 6 <2> 7 0000053B 50 <2> strcpy: push ax 8 0000053C AC <2> .loop: lodsb 9 0000053D AA <2> stosb 10 0000053E 20C0 <2> and al,al 11 00000540 75FA <2> jnz .loop 12 00000542 58 <2> pop ax 13 00000543 C3 <2> ret 10 <1> %include "adv.inc" ; Auxiliary Data Vector 1 <2> ;; ----------------------------------------------------------------------- 2 <2> ;; 3 <2> ;; Copyright 2007-2008 H. Peter Anvin - All Rights Reserved 4 <2> ;; 5 <2> ;; This program is free software; you can redistribute it and/or modify 6 <2> ;; it under the terms of the GNU General Public License as published by 7 <2> ;; the Free Software Foundation, Inc., 51 Franklin St, Fifth Floor, 8 <2> ;; Boston MA 02110-1301, USA; either version 2 of the License, or 9 <2> ;; (at your option) any later version; incorporated herein by reference. 10 <2> ;; 11 <2> ;; ----------------------------------------------------------------------- 12 <2> 13 <2> ;; 14 <2> ;; adv.inc 15 <2> ;; 16 <2> ;; The auxiliary data vector and its routines 17 <2> ;; 18 <2> ;; The auxiliary data vector is a 512-byte aligned block that on the 19 <2> ;; disk-based derivatives can be part of the syslinux file itself. It 20 <2> ;; exists in two copies; when written, both copies are written (with a 21 <2> ;; sync in between, if from the operating system.) The first two 22 <2> ;; dwords are magic number and inverse checksum, then follows the data 23 <2> ;; area as a tagged array similar to BOOTP/DHCP, finally a tail 24 <2> ;; signature. 25 <2> ;; 26 <2> ;; Note that unlike BOOTP/DHCP, zero terminates the chain, and FF 27 <2> ;; has no special meaning. 28 <2> ;; 29 <2> 30 <2> ;; 31 <2> ;; List of ADV tags... 32 <2> ;; 33 <2> ADV_BOOTONCE equ 1 34 <2> 35 <2> ;; 36 <2> ;; Other ADV data... 37 <2> ;; 38 <2> ADV_MAGIC1 equ 0x5a2d2fa5 ; Head signature 39 <2> ADV_MAGIC2 equ 0xa3041767 ; Total checksum 40 <2> ADV_MAGIC3 equ 0xdd28bf64 ; Tail signature 41 <2> 42 <2> ADV_LEN equ 500 ; Data bytes 43 <2> 44 <2> adv_retries equ 6 ; Disk retries 45 <2> 46 <2> section .data 47 <2> global __syslinux_adv_ptr, __syslinux_adv_size 48 <2> __syslinux_adv_ptr: 49 00000000 [08000000] <2> dd adv0.data 50 <2> __syslinux_adv_size: 51 00000004 F4010000 <2> dd ADV_LEN 52 <2> 53 <2> section .adv 54 <2> ; Introduce the ADVs to valid but blank 55 <2> adv0: 56 00000000 <2> .head resd 1 57 00000004 <2> .csum resd 1 58 00000008 <2> .data resb ADV_LEN 59 000001FC <2> .tail resd 1 60 <2> .end equ $ 61 <2> adv1: 62 00000200 <2> .head resd 1 63 00000204 <2> .csum resd 1 64 00000208 <2> .data resb ADV_LEN 65 000003FC <2> .tail resd 1 66 <2> .end equ $ 67 <2> section .text16 68 <2> 69 <2> ; 70 <2> ; This is called after config file parsing, so we know 71 <2> ; the intended location of the ADV 72 <2> ; 73 <2> global adv_init 74 <2> adv_init: 75 00000544 803E[8800]FF <2> cmp byte [ADVDrive],-1 76 00000549 0F855901 <2> jne adv_read 77 <2> 78 <2> %if IS_SYSLINUX || IS_EXTLINUX 79 <2> cmp word [ADVSectors],2 ; Not present? 80 <2> jb adv_verify 81 <2> 82 <2> mov eax,[Hidden] 83 <2> mov edx,[Hidden+4] 84 <2> add [ADVSec0],eax 85 <2> adc [ADVSec0+4],edx 86 <2> add [ADVSec1],eax 87 <2> adc [ADVSec1+4],edx 88 <2> mov al,[DriveNumber] 89 <2> mov [ADVDrive],al 90 <2> jmp adv_read 91 <2> %endif 92 <2> 93 <2> ; 94 <2> ; Initialize the ADV data structure in memory 95 <2> ; 96 <2> adv_verify: 97 0000054D 803E[8800]FF <2> cmp byte [ADVDrive],-1 ; No ADV configured, still? 98 00000552 7410 <2> je .reset ; Then unconditionally reset 99 <2> 100 00000554 BE[0000] <2> mov si,adv0 101 00000557 E83900 <2> call .check_adv 102 0000055A 742C <2> jz .ok ; Primary ADV okay 103 0000055C BE[0002] <2> mov si,adv1 104 0000055F E83100 <2> call .check_adv 105 00000562 7425 <2> jz .adv1ok 106 <2> 107 <2> ; Neither ADV is usable; initialize to blank 108 <2> .reset: 109 00000564 BF[0000] <2> mov di,adv0 110 00000567 66B8A52F2D5A <2> mov eax,ADV_MAGIC1 111 0000056D 66AB <2> stosd 112 0000056F 66B8671704A3 <2> mov eax,ADV_MAGIC2 113 00000575 66AB <2> stosd 114 00000577 6631C0 <2> xor eax,eax 115 0000057A B97D00 <2> mov cx,ADV_LEN/4 116 0000057D F366AB <2> rep stosd 117 00000580 66B864BF28DD <2> mov eax,ADV_MAGIC3 118 00000586 66AB <2> stosd 119 <2> 120 <2> .ok: 121 00000588 C3 <2> ret 122 <2> 123 <2> ; The primary ADV is bad, but the backup is OK 124 <2> .adv1ok: 125 00000589 BF[0000] <2> mov di,adv0 126 0000058C B98000 <2> mov cx,512/4 127 0000058F F366A5 <2> rep movsd 128 00000592 C3 <2> ret 129 <2> 130 <2> 131 <2> ; SI points to the putative ADV; unchanged by routine 132 <2> ; ZF=1 on return if good 133 <2> .check_adv: 134 00000593 56 <2> push si 135 00000594 66AD <2> lodsd 136 00000596 663DA52F2D5A <2> cmp eax,ADV_MAGIC1 137 0000059C 751E <2> jne .done ; ZF=0, i.e. bad 138 0000059E 6631D2 <2> xor edx,edx 139 000005A1 B97E00 <2> mov cx,ADV_LEN/4+1 ; Remaining dwords 140 <2> .csum: 141 000005A4 66AD <2> lodsd 142 000005A6 6601C2 <2> add edx,eax 143 000005A9 E2F9 <2> loop .csum 144 000005AB 6681FA671704A3 <2> cmp edx,ADV_MAGIC2 145 000005B2 7508 <2> jne .done 146 000005B4 66AD <2> lodsd 147 000005B6 663D64BF28DD <2> cmp eax,ADV_MAGIC3 148 <2> .done: 149 000005BC 5E <2> pop si 150 000005BD C3 <2> ret 151 <2> 152 <2> ; 153 <2> ; adv_get: find an ADV string if present 154 <2> ; 155 <2> ; Input: DL = ADV ID 156 <2> ; Output: CX = byte count (zero on not found) 157 <2> ; SI = pointer to data 158 <2> ; DL = unchanged 159 <2> ; 160 <2> ; Assumes CS == DS. 161 <2> ; 162 <2> 163 <2> adv_get: 164 000005BE 50 <2> push ax 165 000005BF BE[0800] <2> mov si,adv0.data 166 000005C2 31C0 <2> xor ax,ax ; Keep AH=0 at all times 167 <2> .loop: 168 000005C4 AC <2> lodsb ; Read ID 169 000005C5 38D0 <2> cmp al,dl 170 000005C7 740F <2> je .found 171 000005C9 20C0 <2> and al,al 172 000005CB 7415 <2> jz .end 173 000005CD AC <2> lodsb ; Read length 174 000005CE 01C6 <2> add si,ax 175 000005D0 81FE[FC01] <2> cmp si,adv0.tail 176 000005D4 72EE <2> jb .loop 177 000005D6 EB0A <2> jmp .end 178 <2> 179 <2> .found: 180 000005D8 AC <2> lodsb 181 000005D9 89C1 <2> mov cx,ax 182 000005DB 01F0 <2> add ax,si ; Make sure it fits 183 000005DD 3D[FC01] <2> cmp ax,adv0.tail 184 000005E0 7602 <2> jbe .ok 185 <2> .end: 186 000005E2 31C9 <2> xor cx,cx 187 <2> .ok: 188 000005E4 58 <2> pop ax 189 000005E5 C3 <2> ret 190 <2> 191 <2> ; 192 <2> ; adv_set: insert a string into the ADV in memory 193 <2> ; 194 <2> ; Input: DL = ADV ID 195 <2> ; FS:BX = input buffer 196 <2> ; CX = byte count (max = 255!) 197 <2> ; Output: CF=1 on error 198 <2> ; CX clobbered 199 <2> ; 200 <2> ; Assumes CS == DS == ES. 201 <2> ; 202 <2> adv_set: 203 000005E6 50 <2> push ax 204 000005E7 56 <2> push si 205 000005E8 57 <2> push di 206 000005E9 20ED <2> and ch,ch 207 000005EB 7559 <2> jnz .overflow 208 <2> 209 000005ED 51 <2> push cx 210 000005EE BE[0800] <2> mov si,adv0.data 211 000005F1 31C0 <2> xor ax,ax 212 <2> .loop: 213 000005F3 AC <2> lodsb 214 000005F4 38D0 <2> cmp al,dl 215 000005F6 740F <2> je .found 216 000005F8 20C0 <2> and al,al 217 000005FA 7423 <2> jz .endz 218 000005FC AC <2> lodsb 219 000005FD 01C6 <2> add si,ax 220 000005FF 81FE[FC01] <2> cmp si,adv0.tail 221 00000603 72EE <2> jb .loop 222 00000605 EB19 <2> jmp .end 223 <2> 224 <2> .found: ; Found, need to delete old copy 225 00000607 AC <2> lodsb 226 00000608 8D7CFE <2> lea di,[si-2] 227 0000060B 57 <2> push di 228 0000060C 01C6 <2> add si,ax 229 0000060E B9[FC01] <2> mov cx,adv0.tail 230 00000611 29F1 <2> sub cx,si 231 00000613 7207 <2> jb .nukeit 232 00000615 F3A4 <2> rep movsb ; Remove the old one 233 00000617 8825 <2> mov [di],ah ; Termination zero 234 00000619 5E <2> pop si 235 0000061A EBD7 <2> jmp .loop 236 <2> .nukeit: 237 0000061C 5E <2> pop si 238 0000061D EB01 <2> jmp .end 239 <2> .endz: 240 0000061F 4E <2> dec si 241 <2> .end: 242 <2> ; Now SI points to where we want to put our data 243 00000620 59 <2> pop cx 244 00000621 89F7 <2> mov di,si 245 00000623 E313 <2> jcxz .empty 246 00000625 01CE <2> add si,cx 247 00000627 81FE[FA01] <2> cmp si,adv0.tail-2 248 0000062B 7319 <2> jae .overflow ; CF=0 249 <2> 250 0000062D 89DE <2> mov si,bx 251 0000062F 88D0 <2> mov al,dl 252 00000631 AA <2> stosb 253 00000632 88C8 <2> mov al,cl 254 00000634 AA <2> stosb 255 00000635 F364A4 <2> fs rep movsb 256 <2> 257 <2> .empty: 258 00000638 B9[FC01] <2> mov cx,adv0.tail 259 0000063B 29F9 <2> sub cx,di 260 0000063D 31C0 <2> xor ax,ax 261 0000063F F3AA <2> rep stosb ; Zero-fill remainder 262 <2> 263 00000641 F8 <2> clc 264 <2> .done: 265 00000642 5F <2> pop di 266 00000643 5E <2> pop si 267 00000644 58 <2> pop ax 268 00000645 C3 <2> ret 269 <2> .overflow: 270 00000646 F9 <2> stc 271 00000647 EBF9 <2> jmp .done 272 <2> 273 <2> ; 274 <2> ; adv_cleanup: checksum adv0 and copy to adv1 275 <2> ; Assumes CS == DS == ES. 276 <2> ; 277 <2> adv_cleanup: 278 00000649 6660 <2> pushad 279 0000064B BE[0800] <2> mov si,adv0.data 280 0000064E B97D00 <2> mov cx,ADV_LEN/4 281 00000651 6631D2 <2> xor edx,edx 282 <2> .loop: 283 00000654 66AD <2> lodsd 284 00000656 6601C2 <2> add edx,eax 285 00000659 E2F9 <2> loop .loop 286 0000065B 66B8671704A3 <2> mov eax,ADV_MAGIC2 287 00000661 6629D0 <2> sub eax,edx 288 00000664 8D7C04 <2> lea di,[si+4] ; adv1 289 00000667 BE[0000] <2> mov si,adv0 290 0000066A 66894404 <2> mov [si+4],eax ; Store checksum 291 0000066E B98000 <2> mov cx,(ADV_LEN+12)/4 292 00000671 F366A5 <2> rep movsd 293 00000674 6661 <2> popad 294 00000676 C3 <2> ret 295 <2> 296 <2> ; 297 <2> ; adv_write: write the ADV to disk. 298 <2> ; 299 <2> ; Location is in memory variables. 300 <2> ; Assumes CS == DS == ES. 301 <2> ; 302 <2> ; Returns CF=1 if the ADV cannot be written. 303 <2> ; 304 <2> global adv_write 305 <2> adv_write: 306 00000677 6650 <2> push eax 307 00000679 66A1[7800] <2> mov eax,[ADVSec0] 308 0000067D 660B06[7C00] <2> or eax,[ADVSec0+4] 309 00000682 741E <2> je .bad 310 00000684 66A1[8000] <2> mov eax,[ADVSec1] 311 00000688 660B06[8400] <2> or eax,[ADVSec1+4] 312 0000068D 7413 <2> je .bad 313 0000068F 803E[8800]FF <2> cmp byte [ADVDrive],-1 314 00000694 740C <2> je .bad 315 <2> 316 00000696 E8B0FF <2> call adv_cleanup 317 00000699 B403 <2> mov ah,3 ; Write 318 0000069B E81300 <2> call adv_read_write 319 <2> 320 0000069E F8 <2> clc 321 0000069F 6658 <2> pop eax 322 000006A1 C3 <2> ret 323 <2> .bad: ; No location for ADV set 324 000006A2 F9 <2> stc 325 000006A3 6658 <2> pop eax 326 000006A5 C3 <2> ret 327 <2> 328 <2> ; 329 <2> ; adv_read: read the ADV from disk 330 <2> ; 331 <2> ; Location is in memory variables. 332 <2> ; Assumes CS == DS == ES. 333 <2> ; 334 <2> adv_read: 335 000006A6 50 <2> push ax 336 000006A7 B402 <2> mov ah,2 ; Read 337 000006A9 E80500 <2> call adv_read_write 338 000006AC E89EFE <2> call adv_verify 339 000006AF 58 <2> pop ax 340 000006B0 C3 <2> ret 341 <2> 342 <2> ; 343 <2> ; adv_read_write: disk I/O for the ADV 344 <2> ; 345 <2> ; On input, AH=2 for read, AH=3 for write. 346 <2> ; Assumes CS == DS == ES. 347 <2> ; 348 <2> adv_read_write: 349 000006B1 8826[5402] <2> mov [ADVOp],ah 350 000006B5 6660 <2> pushad 351 <2> 352 <2> ; Check for EDD 353 000006B7 BBAA55 <2> mov bx,55AAh 354 000006BA B441 <2> mov ah,41h ; EDD existence query 355 000006BC 8A16[8800] <2> mov dl,[ADVDrive] 356 000006C0 CD13 <2> int 13h 357 000006C2 BE[2907] <2> mov si,.cbios 358 000006C5 720E <2> jc .noedd 359 000006C7 81FB55AA <2> cmp bx,0AA55h 360 000006CB 7508 <2> jne .noedd 361 000006CD F6C101 <2> test cl,1 362 000006D0 7403 <2> jz .noedd 363 000006D2 BE[F906] <2> mov si,.ebios 364 <2> .noedd: 365 <2> 366 000006D5 66A1[7800] <2> mov eax,[ADVSec0] 367 000006D9 668B16[7C00] <2> mov edx,[ADVSec0+4] 368 000006DE BB[0000] <2> mov bx,adv0 369 000006E1 E81200 <2> call .doone 370 <2> 371 000006E4 66A1[8000] <2> mov eax,[ADVSec1] 372 000006E8 668B16[8400] <2> mov edx,[ADVSec1+4] 373 000006ED BB[0002] <2> mov bx,adv1 374 000006F0 E80300 <2> call .doone 375 <2> 376 000006F3 6661 <2> popad 377 000006F5 C3 <2> ret 378 <2> 379 <2> .doone: 380 000006F6 56 <2> push si 381 000006F7 FFE6 <2> jmp si 382 <2> 383 <2> .ebios: 384 000006F9 B90600 <2> mov cx,adv_retries 385 <2> .eb_retry: 386 <2> ; Form DAPA on stack 387 000006FC 6652 <2> push edx 388 000006FE 6650 <2> push eax 389 00000700 06 <2> push es 390 00000701 53 <2> push bx 391 00000702 6A01 <2> push word 1 ; Sector count 392 00000704 6A10 <2> push word 16 ; DAPA size 393 00000706 89E6 <2> mov si,sp 394 00000708 6660 <2> pushad 395 0000070A 8A16[8800] <2> mov dl,[ADVDrive] 396 0000070E B80040 <2> mov ax,4000h 397 00000711 0A26[5402] <2> or ah,[ADVOp] 398 00000715 1E <2> push ds 399 00000716 16 <2> push ss 400 00000717 1F <2> pop ds 401 00000718 CD13 <2> int 13h 402 0000071A 1F <2> pop ds 403 0000071B 6661 <2> popad 404 0000071D 8D6410 <2> lea sp,[si+16] ; Remove DAPA 405 00000720 7202 <2> jc .eb_error 406 00000722 5E <2> pop si 407 00000723 C3 <2> ret 408 <2> .eb_error: 409 00000724 E2D6 <2> loop .eb_retry 410 00000726 F9 <2> stc 411 00000727 5E <2> pop si 412 00000728 C3 <2> ret 413 <2> 414 <2> .cbios: 415 00000729 6652 <2> push edx 416 0000072B 6650 <2> push eax 417 0000072D 55 <2> push bp 418 <2> 419 0000072E 6621D2 <2> and edx,edx ; > 2 TiB not possible 420 00000731 7563 <2> jnz .cb_overflow 421 <2> 422 00000733 8A16[8800] <2> mov dl,[ADVDrive] 423 00000737 20D2 <2> and dl,dl 424 <2> ; Floppies: can't trust INT 13h 08h, we better know 425 <2> ; the geometry a priori, which means it better be our 426 <2> ; boot device... 427 00000739 791B <2> jns .noparm ; Floppy drive... urk 428 <2> 429 0000073B B408 <2> mov ah,08h ; Get disk parameters 430 0000073D CD13 <2> int 13h 431 0000073F 7215 <2> jc .noparm 432 00000741 20E4 <2> and ah,ah 433 00000743 7511 <2> jnz .noparm 434 00000745 C1EA08 <2> shr dx,8 435 00000748 42 <2> inc dx 436 00000749 660FB7FA <2> movzx edi,dx ; EDI = heads 437 0000074D 83E13F <2> and cx,3fh 438 00000750 660FB7F1 <2> movzx esi,cx ; ESI = sectors/track 439 00000754 EB02 <2> jmp .parmok 440 <2> 441 <2> .noparm: 442 <2> ; No CHS info... this better be our boot drive, then 443 <2> %if IS_SYSLINUX || IS_EXTLINUX 444 <2> cmp dl,[DriveNumber] 445 <2> jne .cb_overflow ; Fatal error! 446 <2> movzx esi,word [bsSecPerTrack] 447 <2> movzx edi,word [bsHeads] 448 <2> %else 449 <2> ; Not a disk-based derivative... there is no hope 450 00000756 EB3E <2> jmp .cb_overflow 451 <2> %endif 452 <2> 453 <2> .parmok: 454 <2> ; 455 <2> ; Dividing by sectors to get (track,sector): we may have 456 <2> ; up to 2^18 tracks, so we need to use 32-bit arithmetric. 457 <2> ; 458 00000758 6631D2 <2> xor edx,edx 459 0000075B 66F7F6 <2> div esi 460 0000075E 31C9 <2> xor cx,cx 461 00000760 87CA <2> xchg cx,dx ; CX <- sector index (0-based) 462 <2> ; EDX <- 0 463 <2> ; eax = track # 464 00000762 66F7F7 <2> div edi ; Convert track to head/cyl 465 <2> 466 <2> ; Watch out for overflow, we might be writing! 467 00000765 663DFF030000 <2> cmp eax,1023 468 0000076B 7729 <2> ja .cb_overflow 469 <2> 470 <2> ; 471 <2> ; Now we have AX = cyl, DX = head, CX = sector (0-based), 472 <2> ; BP = sectors to transfer, SI = bsSecPerTrack, 473 <2> ; ES:BX = data target 474 <2> ; 475 <2> 476 0000076D C0E406 <2> shl ah,6 ; Because IBM was STOOPID 477 <2> ; and thought 8 bits were enough 478 <2> ; then thought 10 bits were enough... 479 00000770 41 <2> inc cx ; Sector numbers are 1-based, sigh 480 00000771 08E1 <2> or cl,ah 481 00000773 88C5 <2> mov ch,al 482 00000775 88D6 <2> mov dh,dl 483 00000777 8A16[8800] <2> mov dl,[ADVDrive] 484 0000077B B001 <2> mov al,01h ; Transfer one sector 485 0000077D 8A26[5402] <2> mov ah,[ADVOp] ; Operation 486 <2> 487 00000781 BD0600 <2> mov bp,adv_retries 488 <2> .cb_retry: 489 00000784 6660 <2> pushad 490 00000786 CD13 <2> int 13h 491 00000788 6661 <2> popad 492 0000078A 7207 <2> jc .cb_error 493 <2> 494 <2> .cb_done: 495 0000078C 5D <2> pop bp 496 0000078D 6658 <2> pop eax 497 0000078F 665A <2> pop edx 498 00000791 5E <2> pop si 499 00000792 C3 <2> ret 500 <2> 501 <2> .cb_error: 502 00000793 4D <2> dec bp 503 00000794 75EE <2> jnz .cb_retry 504 <2> .cb_overflow: 505 00000796 F9 <2> stc 506 00000797 EBF3 <2> jmp .cb_done 507 <2> 508 <2> section .data16 509 00000073 00 <2> alignz 8 510 00000078 0000000000000000 <2> ADVSec0 dq 0 ; Not specified 511 00000080 0000000000000000 <2> ADVSec1 dq 0 ; Not specified 512 00000088 FF <2> ADVDrive db -1 ; No ADV defined 513 00000089 FF <2> ADVCHSInfo db -1 ; We have CHS info for this drive 514 <2> 515 <2> section .bss16 516 00000254 <2> ADVOp resb 1 517 <2> 518 <2> section .text16 11 <1> %include "timer.inc" ; Timer handling 1 <2> ;; ----------------------------------------------------------------------- 2 <2> ;; 3 <2> ;; Copyright 2009 Intel Corporation; author: H. Peter Anvin 4 <2> ;; 5 <2> ;; This program is free software; you can redistribute it and/or modify 6 <2> ;; it under the terms of the GNU General Public License as published by 7 <2> ;; the Free Software Foundation, Inc., 51 Franklin St, Fifth Floor, 8 <2> ;; Boston MA 02110-1301, USA; either version 2 of the License, or 9 <2> ;; (at your option) any later version; incorporated herein by reference. 10 <2> ;; 11 <2> ;; ----------------------------------------------------------------------- 12 <2> 13 <2> ;; 14 <2> ;; timer.inc 15 <2> ;; 16 <2> ;; Very simple counting timer 17 <2> ;; 18 <2> ;; This lets us have a simple incrementing variable without worrying 19 <2> ;; about the BIOS_timer variable wrapping around at "midnight" and other 20 <2> ;; weird things. 21 <2> ;; 22 <2> ;; This also maintains a timer variable calibrated in milliseconds 23 <2> ;; (wraparound time = 49.7 days!) 24 <2> ;; 25 <2> 26 <2> section .text16 27 <2> 28 <2> timer_init: 29 <2> ; Hook INT 1Ch 30 00000799 66A17000 <2> mov eax,[BIOS_timer_hook] 31 0000079D 66A3[C907] <2> mov [BIOS_timer_next],eax 32 000007A1 66C7067000- <2> mov dword [BIOS_timer_hook],timer_irq 32 000007A6 [B4070000] <2> 33 000007AA C3 <2> ret 34 <2> 35 <2> global bios_timer_cleanup:function hidden 36 <2> bios_timer_cleanup: 37 <2> ; Unhook INT 1Ch 38 000007AB 66A1[C907] <2> mov eax,[BIOS_timer_next] 39 000007AF 66A37000 <2> mov [BIOS_timer_hook],eax 40 000007B3 C3 <2> ret 41 <2> 42 <2> ; 43 <2> ; The specified frequency is 14.31818 MHz/12/65536; this turns out 44 <2> ; to be a period of 54.92542 ms, or 0x36.ece8(187c) hexadecimal. 45 <2> ; 46 <2> global timer_irq:function hidden 47 <2> timer_irq: 48 000007B4 2E66FF06[8C00] <2> inc dword [cs:__jiffies] 49 000007BA 2E8106[9400]E8EC <2> add word [cs:__ms_timer_adj],0xece8 50 000007C1 2E668316[9000]36 <2> adc dword [cs:__ms_timer],0x36 51 000007C8 EA00000000 <2> jmp 0:0 52 <2> global BIOS_timer_next:data hidden 53 <2> BIOS_timer_next equ $-4 54 <2> 55 <2> section .data16 56 0000008A 00 <2> alignz 4 57 <2> global __jiffies:data hidden, __ms_timer 58 0000008C 00000000 <2> __jiffies dd 0 ; Clock tick timer 59 00000090 00000000 <2> __ms_timer dd 0 ; Millisecond timer 60 00000094 0000 <2> __ms_timer_adj dw 0 ; Millisecond timer correction factor 12 <1> 13 <1> ; Note: the prefix section is included late, to avoid problems with some 14 <1> ; versions of NASM that had issues with forward references to EQU symbols. 15 <1> %include "prefix.inc" ; Prefix section for prepcore 1 <2> ; 2 <2> ; The prefix is a small structure that prefaces the actual code; 3 <2> ; it gives the compression program necessary information. 4 <2> ; 5 <2> 6 <2> section .prefix nowrite progbits align=16 7 00000000 [00000000] <2> pfx_start dd _start ; Start of raw chunk 8 00000004 [00000000] <2> pfx_compressed dd __pm_code_lma ; Start of compressed chunk 9 00000008 [06000000] <2> pfx_cdatalen dd lzo_data_size ; Pointer to compressed size field 10 <2> %if IS_ISOLINUX 11 <2> pfx_checksum dd bi_length ; File length and checksum fields 12 <2> %else 13 0000000C 00000000 <2> pfx_checksum dd 0 ; No checksum 14 <2> %endif 15 00000010 00000600 <2> pfx_maxlma dd MaxLMA ; Maximum size 16 <2> 17 <2> section .text16 547 548 ; ----------------------------------------------------------------------------- 549 ; Begin data section 550 ; ----------------------------------------------------------------------------- 551 552 section .data16 553 554 global copyright_str, syslinux_banner 555 00000096 436F70797269676874- copyright_str db 'Copyright (C) 1994-' 555 0000009F 202843292031393934- 555 000000A8 2D 556 000000A9 32303135 asciidec YEAR 557 000000AD 20482E205065746572- db ' H. Peter Anvin et al', CR, LF, 0 557 000000B6 20416E76696E206574- 557 000000BF 20616C0D0A00 558 000000C5 0D0A426F6F74206661- err_bootfailed db CR, LF, 'Boot failed: press a key to retry, or wait for reset...', CR, LF, 0 558 000000CE 696C65643A20707265- 558 000000D7 73732061206B657920- 558 000000E0 746F2072657472792C- 558 000000E9 206F72207761697420- 558 000000F2 666F72207265736574- 558 000000FB 2E2E2E0D0A00 559 bailmsg equ err_bootfailed 560 00000101 426F6F74696E672066- localboot_msg db 'Booting from local disk...', CR, LF, 0 560 0000010A 726F6D206C6F63616C- 560 00000113 206469736B2E2E2E0D- 560 0000011C 0A00 561 0000011E 0D0A5058454C494E55- syslinux_banner db CR, LF, MY_NAME, ' ', VERSION_STR, ' ', MY_TYPE, ' ' 561 00000127 5820362E3034206C77- 561 00000130 495020 562 00000133 362E30342D70726532- db DATE_STR, ' ', 0 562 0000013C 2A2000 563 564 ; 565 ; Misc initialized (data) variables 566 ; 567 section .data16 568 global KeepPXE 569 0000013F 00 KeepPXE db 0 ; Should PXE be kept around? 570 571 section .bss16 572 global OrigFDCTabPtr 573 00000255 OrigFDCTabPtr resd 1 ; Keep bios_cleanup_hardware() honest