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/* builtins.c - the GRUB builtin commands */
/*
* GRUB -- GRand Unified Bootloader
* Copyright (C) 1996 Erich Boleyn <erich@uruk.org>
* Copyright (C) 1999 Free Software Foundation, Inc.
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; either version 2 of the License, or
* (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
*/
#include <shared.h>
#include <filesys.h>
#ifndef GRUB_UTIL
# include "apic.h"
# include "smp-imps.h"
#endif
/* The type of kernel loaded. */
kernel_t kernel_type;
/* The boot device. */
static int bootdev;
/* True when the debug mode is turned on, and false when it is turned off. */
int debug = 0;
/* The default entry. */
int default_entry = 0;
/* The fallback entry. */
int fallback_entry = -1;
/* The address for Multiboot command-line buffer. */
static char *mb_cmdline;
/* The password. */
char *password;
/* Color settings. */
int normal_color;
int highlight_color;
/* The timeout. */
int grub_timeout = -1;
/* The BIOS drive map. */
static unsigned short bios_drive_map[DRIVE_MAP_SIZE + 1];
/* Initialize the data for builtins. */
void
init_builtins (void)
{
kernel_type = KERNEL_TYPE_NONE;
/* BSD and chainloading evil hacks! */
bootdev = set_bootdev (0);
mb_cmdline = (char *) MB_CMDLINE_BUF;
}
/* Initialize the data for the configuration file. */
void
init_config (void)
{
default_entry = 0;
normal_color = A_NORMAL;
highlight_color = A_REVERSE;
password = 0;
fallback_entry = -1;
grub_timeout = -1;
}
/* Print which sector is read when loading a file. */
static void
disk_read_print_func (int sector)
{
grub_printf ("[%d]", sector);
}
/* boot */
static int
boot_func (char *arg, int flags)
{
/* Clear the int15 handler if we can boot the kernel successfully.
This assumes that the boot code never fails only if KERNEL_TYPE is
not KERNEL_TYPE_NONE. Is this assumption is bad? */
if (kernel_type != KERNEL_TYPE_NONE)
unset_int15_handler ();
switch (kernel_type)
{
case KERNEL_TYPE_FREEBSD:
case KERNEL_TYPE_NETBSD:
/* *BSD */
bsd_boot (kernel_type, bootdev, (char *) mbi.cmdline);
break;
case KERNEL_TYPE_LINUX:
/* Linux */
linux_boot ();
break;
case KERNEL_TYPE_BIG_LINUX:
/* Big Linux */
big_linux_boot ();
break;
case KERNEL_TYPE_CHAINLOADER:
/* Chainloader */
/* Check if we should set the int13 handler. */
if (bios_drive_map[0] != 0)
{
int i;
/* Search for SAVED_DRIVE. */
for (i = 0; i < DRIVE_MAP_SIZE; i++)
{
if (! bios_drive_map[i])
break;
else if ((bios_drive_map[i] & 0xFF) == saved_drive)
{
/* Exchage SAVED_DRIVE with the mapped drive. */
saved_drive = (bios_drive_map[i] >> 8) & 0xFF;
break;
}
}
/* Set the handler. This is somewhat dangerous. */
set_int13_handler (bios_drive_map);
}
gateA20 (0);
boot_drive = saved_drive;
chain_stage1 (0, BOOTSEC_LOCATION, BOOTSEC_LOCATION - 16);
break;
case KERNEL_TYPE_MULTIBOOT:
/* Multiboot */
multi_boot ((int) entry_addr, (int) &mbi);
break;
default:
errnum = ERR_BOOT_COMMAND;
return 1;
}
return 0;
}
static struct builtin builtin_boot =
{
"boot",
boot_func,
BUILTIN_CMDLINE,
"boot",
"Boot the OS/chain-loader which has been loaded."
};
static int
cat_func (char *arg, int flags)
{
char c;
if (! grub_open (arg))
return 1;
while (grub_read (&c, 1))
grub_putchar (c);
grub_close ();
return 0;
}
static struct builtin builtin_cat =
{
"cat",
cat_func,
BUILTIN_CMDLINE,
"cat FILE",
"Print the contents of the file FILE."
};
/* chainloader */
static int
chainloader_func (char *arg, int flags)
{
if (! grub_open (arg))
{
kernel_type = KERNEL_TYPE_NONE;
return 1;
}
if (grub_read ((char *) BOOTSEC_LOCATION, SECTOR_SIZE) == SECTOR_SIZE
&& (*((unsigned short *) (BOOTSEC_LOCATION + BOOTSEC_SIG_OFFSET))
== BOOTSEC_SIGNATURE))
kernel_type = KERNEL_TYPE_CHAINLOADER;
else if (! errnum)
{
grub_close ();
errnum = ERR_EXEC_FORMAT;
kernel_type = KERNEL_TYPE_NONE;
return 1;
}
grub_close ();
return 0;
}
static struct builtin builtin_chainloader =
{
"chainloader",
chainloader_func,
BUILTIN_CMDLINE,
"chainloader FILE",
"Load the chain-loader FILE."
};
/* color */
/* Set new colors used for the menu interface. Support two methods to
specify a color name: a direct integer representation and a symbolic
color name. An example of the latter is "blink-light-gray/blue". */
static int
color_func (char *arg, int flags)
{
char *normal;
char *highlight;
int new_normal_color;
int new_highlight_color;
static char *color_list[16] =
{
"black",
"blue",
"green",
"cyan",
"red",
"magenta",
"brown",
"light-gray",
"dark-gray",
"light-blue",
"light-green",
"light-cyan",
"light-red",
"light-magenta",
"yellow",
"white"
};
/* Convert the color name STR into the magical number. */
static int color_number (char *str)
{
char *ptr;
int i;
int color = 0;
/* Find the separator. */
for (ptr = str; *ptr && *ptr != '/'; ptr++)
;
/* If not found, return -1. */
if (! *ptr)
return -1;
/* Terminate the string STR. */
*ptr++ = 0;
/* If STR contains the prefix "blink-", then set the `blink' bit
in COLOR. */
if (substring ("blink-", str) <= 0)
{
color = 0x80;
str += 6;
}
/* Search for the color name. */
for (i = 0; i < 16; i++)
if (grub_strcmp (color_list[i], str) == 0)
{
color |= i;
break;
}
if (i == 16)
return -1;
str = ptr;
nul_terminate (str);
/* Search for the color name. */
for (i = 0; i < 8; i++)
if (grub_strcmp (color_list[i], str) == 0)
{
color |= i << 4;
break;
}
if (i == 8)
return -1;
return color;
}
normal = arg;
highlight = skip_to (0, arg);
new_normal_color = color_number (normal);
if (new_normal_color < 0 && safe_parse_maxint (&normal, &new_normal_color))
return 1;
/* The second argument is optional, so set highlight_color
to inverted NORMAL_COLOR. */
if (! *highlight)
new_highlight_color = ((new_normal_color >> 4)
| ((new_normal_color & 0xf) << 4));
else
{
new_highlight_color = color_number (highlight);
if (new_highlight_color < 0
&& safe_parse_maxint (&highlight, &new_highlight_color))
return 1;
}
normal_color = new_normal_color;
highlight_color = new_highlight_color;
return 0;
}
static struct builtin builtin_color =
{
"color",
color_func,
BUILTIN_CMDLINE | BUILTIN_MENU,
"color NORMAL [HIGHLIGHT]",
"Change the menu colors. The color NORMAL is used for most"
" lines in the menu, and the color HIGHLIGHT is used to highlight the"
" line where the cursor points. If you omit HIGHLIGHT, then the"
" inverted color of NORMAL is used for the highlighted line."
" The format of a color is \"FG/BG\". FG and BG are symbolic color names."
" A symbolic color name must be one of these: black, blue, green,"
" cyan, red, magenta, brown, light-gray, dark-gray, light-blue,"
" light-green, light-cyan, light-red, light-magenta, yellow and white."
" But only the first eight names can be used for BG. You can prefix"
" \"blink-\" to FG if you want a blinking foreground color."
};
/* configfile */
static int
configfile_func (char *arg, int flags)
{
char *new_config = config_file;
/* Check if the file ARG is present. */
if (! grub_open (arg))
return 1;
grub_close ();
/* Copy ARG to CONFIG_FILE. */
while ((*new_config++ = *arg++) != 0)
;
#ifdef GRUB_UTIL
/* Force to load the configuration file. */
use_config_file = 1;
#endif
/* Restart cmain. */
cmain ();
/* Never reach here. */
return 0;
}
static struct builtin builtin_configfile =
{
"configfile",
configfile_func,
BUILTIN_CMDLINE,
"configfile FILE",
"Load FILE as the configuration file."
};
/* debug */
static int
debug_func (char *arg, int flags)
{
if (debug)
{
debug = 0;
grub_printf (" Debug mode is turned off\n");
}
else
{
debug = 1;
grub_printf (" Debug mode is turned on\n");
}
return 0;
}
static struct builtin builtin_debug =
{
"debug",
debug_func,
BUILTIN_CMDLINE,
"debug",
"Turn on/off the debug mode."
};
/* default */
static int
default_func (char *arg, int flags)
{
if (! safe_parse_maxint (&arg, &default_entry))
return 1;
return 0;
}
static struct builtin builtin_default =
{
"default",
default_func,
BUILTIN_MENU,
#if 0
"default NUM",
"Set the default entry to entry number NUM (if not specified, it is"
" 0, the first entry)."
#endif
};
/* device */
static int
device_func (char *arg, int flags)
{
#ifdef GRUB_UTIL
char *drive = arg;
char *device;
/* Get the drive number from DRIVE. */
if (! set_device (drive))
return 1;
/* Get the device argument. */
device = skip_to (0, drive);
/* Terminate DEVICE. */
nul_terminate (device);
if (! *device || ! check_device (device))
{
errnum = ERR_FILE_NOT_FOUND;
return 1;
}
assign_device_name (current_drive, device);
return 0;
#else /* ! GRUB_UTIL */
/* In Stage 2, this command cannot be used. */
errnum = ERR_UNRECOGNIZED;
return 1;
#endif /* GRUB_UTIL */
}
static struct builtin builtin_device =
{
"device",
device_func,
BUILTIN_MENU | BUILTIN_CMDLINE,
"device DRIVE DEVICE",
"Specify DEVICE as the actual drive for a BIOS drive DRIVE. This command"
" can be used only in the grub shell."
};
/* displaymem */
static int
displaymem_func (char *arg, int flags)
{
if (get_eisamemsize () != -1)
grub_printf (" EISA Memory BIOS Interface is present\n");
if (get_mmap_entry ((void *) SCRATCHADDR, 0) != 0
|| *((int *) SCRATCHADDR) != 0)
grub_printf (" Address Map BIOS Interface is present\n");
grub_printf (" Lower memory: %uK, "
"Upper memory (to first chipset hole): %uK\n",
mbi.mem_lower, mbi.mem_upper);
if (mbi.flags & MB_INFO_MEM_MAP)
{
struct AddrRangeDesc *map = (struct AddrRangeDesc *) mbi.mmap_addr;
int end_addr = mbi.mmap_addr + mbi.mmap_length;
grub_printf (" [Address Range Descriptor entries "
"immediately follow (values are 64-bit)]\n");
while (end_addr > (int) map)
{
char *str;
if (map->Type == MB_ARD_MEMORY)
str = "Usable RAM";
else
str = "Reserved";
grub_printf (" %s: Base Address: 0x%x X 4GB + 0x%x,\n"
" Length: %u X 4GB + %u bytes\n",
str, map->BaseAddrHigh, map->BaseAddrLow,
map->LengthHigh, map->LengthLow);
map = ((struct AddrRangeDesc *) (((int) map) + 4 + map->size));
}
}
return 0;
}
static struct builtin builtin_displaymem =
{
"displaymem",
displaymem_func,
BUILTIN_CMDLINE,
"displaymem",
"Display what GRUB thinks the system address space map of the"
" machine is, including all regions of physical RAM installed."
};
/* embed */
/* Embed a Stage 1.5 in the first cylinder after MBR or in the
bootloader block in a FFS. */
static int
embed_func (char *arg, int flags)
{
char *stage1_5;
char *device;
char *stage1_5_buffer = (char *) RAW_ADDR (0x100000);
int len, size;
int sector;
int i;
stage1_5 = arg;
device = skip_to (0, stage1_5);
/* Open a Stage 1.5. */
if (! grub_open (stage1_5))
return 1;
/* Read the whole of the Stage 1.5. */
len = grub_read (stage1_5_buffer, -1);
grub_close ();
if (errnum)
return 1;
size = (len + SECTOR_SIZE - 1) / SECTOR_SIZE;
/* Get the device where the Stage 1.5 will be embedded. */
set_device (device);
if (errnum)
return 1;
if (current_partition == 0xFFFFFF)
{
/* Embed it after the MBR. */
char mbr[SECTOR_SIZE];
/* No floppy has MBR. */
if (! (current_drive & 0x80))
{
errnum = ERR_DEV_VALUES;
return 1;
}
/* Read the MBR of CURRENT_DRIVE. */
if (! rawread (current_drive, PC_MBR_SECTOR, 0, SECTOR_SIZE, mbr))
return 1;
/* Sanity check. */
if (! PC_MBR_CHECK_SIG (mbr))
{
errnum = ERR_BAD_PART_TABLE;
return 1;
}
/* Check if the disk can store the Stage 1.5. */
if (PC_SLICE_START (mbr, 0) - 1 < size)
{
errnum = ERR_DEV_VALUES;
return 1;
}
sector = 1;
}
else
{
/* Embed it in the bootloader block in the FFS. */
/* Open the partition. */
if (! open_partition ())
return 1;
/* Check if the current slice is a BSD slice. */
if (grub_strcmp (fsys_table[fsys_type].name, "ffs") != 0)
{
errnum = ERR_DEV_VALUES;
return 1;
}
/* Sanity check. */
if (size > 14)
{
errnum = ERR_BAD_VERSION;
return 1;
}
/* XXX: I don't know this is really correct. Someone who is
familiar with BSD should check for this. */
sector = part_start + 1;
#if 1
/* FIXME: Disable the embedding in FFS until someone checks if
the code above is correct. */
errnum = ERR_DEV_VALUES;
return 1;
#endif
}
/* Clear the cache. */
buf_track = -1;
/* Now perform the embedding. */
for (i = 0; i < size; i++)
{
grub_memmove ((char *) SCRATCHADDR, stage1_5_buffer + i * SECTOR_SIZE,
SECTOR_SIZE);
if (biosdisk (BIOSDISK_WRITE, current_drive, &buf_geom,
sector + i, 1, SCRATCHSEG))
{
errnum = ERR_WRITE;
return 1;
}
}
grub_printf (" %d sectors are embedded.\n", size);
return 0;
}
static struct builtin builtin_embed =
{
"embed",
embed_func,
BUILTIN_CMDLINE,
"embed STAGE1_5 DEVICE",
"Embed the Stage 1.5 STAGE1_5 in the sectors after MBR if DEVICE"
" is a drive, or in the \"bootloader\" area if DEVICE is a FFS partition."
" Print the number of sectors which STAGE1_5 occupies if successful."
};
/* fallback */
static int
fallback_func (char *arg, int flags)
{
if (! safe_parse_maxint (&arg, &fallback_entry))
return 1;
return 0;
}
static struct builtin builtin_fallback =
{
"fallback",
fallback_func,
BUILTIN_MENU,
#if 0
"fallback NUM",
"Go into unattended boot mode: if the default boot entry has any"
" errors, instead of waiting for the user to do anything, it"
" immediately starts over using the NUM entry (same numbering as the"
" `default' command). This obviously won't help if the machine"
" was rebooted by a kernel that GRUB loaded."
#endif
};
/* find */
/* Search for the filename ARG in all of partitions. */
static int
find_func (char *arg, int flags)
{
char *filename = arg;
unsigned long drive;
unsigned long tmp_drive = saved_drive;
unsigned long tmp_partition = saved_partition;
/* Floppies. */
for (drive = 0; drive < 8; drive++)
{
errnum = ERR_NONE;
current_drive = drive;
current_partition = 0xFFFFFF;
if (! open_device ())
continue;
saved_drive = current_drive;
saved_partition = current_partition;
if (grub_open (filename))
{
grub_close ();
grub_printf (" (fd%d)\n", drive);
}
}
/* Hard disks. */
for (drive = 0x80; drive < 0x88; drive++)
{
unsigned long slice;
current_drive = drive;
/* FIXME: is what maximum number right? */
for (slice = 0; slice < 12; slice++)
{
errnum = ERR_NONE;
current_partition = (slice << 16) | 0xFFFF;
if (! open_device () && IS_PC_SLICE_TYPE_BSD (current_slice))
{
unsigned long part;
for (part = 0; part < 8; part++)
{
errnum = ERR_NONE;
current_partition = (slice << 16) | (part << 8) | 0xFF;
if (! open_device ())
continue;
saved_drive = current_drive;
saved_partition = current_partition;
if (grub_open (filename))
{
grub_close ();
grub_printf (" (hd%d,%d,%c)",
drive - 0x80, slice, part + 'a');
}
}
}
else
{
errnum = ERR_NONE;
saved_drive = current_drive;
saved_partition = current_partition;
if (grub_open (filename))
{
grub_close ();
grub_printf (" (hd%d,%d)", drive - 0x80, slice);
}
}
}
}
errnum = ERR_NONE;
saved_drive = tmp_drive;
saved_partition = tmp_partition;
return 0;
}
static struct builtin builtin_find =
{
"find",
find_func,
BUILTIN_CMDLINE,
"find FILENAME",
"Search for the filename FILENAME in all of partitions and print the list of"
" the devices which contain the file."
};
/* fstest */
static int
fstest_func (char *arg, int flags)
{
if (disk_read_hook)
{
disk_read_hook = NULL;
printf (" Filesystem tracing is now off\n");
}
else
{
disk_read_hook = disk_read_print_func;
printf (" Filesystem tracing is now on\n");
}
return 0;
}
static struct builtin builtin_fstest =
{
"fstest",
fstest_func,
BUILTIN_CMDLINE,
"fstest",
"Toggle filesystem test mode."
};
/* geometry */
static int
geometry_func (char *arg, int flags)
{
struct geometry geom;
char *msg;
char *device = arg;
#ifdef GRUB_UTIL
char *ptr;
#endif
set_device (device);
if (errnum)
return 1;
if (get_diskinfo (current_drive, &geom))
{
errnum = ERR_NO_DISK;
return 1;
}
#ifdef GRUB_UTIL
ptr = skip_to (0, device);
if (*ptr)
{
char *cylinder, *head, *sector, *total_sector;
int num_cylinder, num_head, num_sector, num_total_sector;
cylinder = ptr;
head = skip_to (0, cylinder);
sector = skip_to (0, head);
total_sector = skip_to (0, sector);
if (! safe_parse_maxint (&cylinder, &num_cylinder)
|| ! safe_parse_maxint (&head, &num_head)
|| ! safe_parse_maxint (&sector, &num_sector))
return 1;
disks[current_drive].cylinders = num_cylinder;
disks[current_drive].heads = num_head;
disks[current_drive].sectors = num_sector;
if (safe_parse_maxint (&total_sector, &num_total_sector))
disks[current_drive].total_sectors = num_total_sector;
else
disks[current_drive].total_sectors
= num_cylinder * num_head * num_sector;
errnum = 0;
geom = disks[current_drive];
buf_drive = -1;
}
#endif /* GRUB_UTIL */
#ifdef GRUB_UTIL
msg = device_map[current_drive];
#else
if (geom.flags & BIOSDISK_FLAG_LBA_EXTENSION)
msg = "LBA";
else
msg = "CHS";
#endif
grub_printf ("drive 0x%x: C/H/S = %d/%d/%d, "
"The number of sectors = %d, %s\n",
current_drive,
geom.cylinders, geom.heads, geom.sectors,
geom.total_sectors, msg);
real_open_partition (1);
return 0;
}
static struct builtin builtin_geometry =
{
"geometry",
geometry_func,
BUILTIN_CMDLINE,
"geometry DRIVE [CYLINDER HEAD SECTOR [TOTAL_SECTOR]]",
"Print the information for a drive DRIVE. In the grub shell, you can"
"set the geometry of the drive arbitrarily. The number of the cylinders,"
" the one of the heads, the one of the sectors and the one of the total"
" sectors are set to CYLINDER, HEAD, SECTOR and TOTAL_SECTOR,"
"respectively. If you omit TOTAL_SECTOR, then it will be calculated based"
" on the C/H/S values automatically."
};
/* help */
#define MAX_SHORT_DOC_LEN 39
#define MAX_LONG_DOC_LEN 66
static int
help_func (char *arg, int flags)
{
if (! *arg)
{
/* Invoked with no argument. Print the list of the short docs. */
struct builtin **builtin;
int left = 1;
for (builtin = builtin_table; *builtin != 0; builtin++)
{
int len;
int i;
/* If this cannot be run in the command-line interface,
skip this. */
if (! ((*builtin)->flags & BUILTIN_CMDLINE))
continue;
len = grub_strlen ((*builtin)->short_doc);
/* If the length of SHORT_DOC is too long, truncate it. */
if (len > MAX_SHORT_DOC_LEN - 1)
len = MAX_SHORT_DOC_LEN - 1;
for (i = 0; i < len; i++)
grub_putchar ((*builtin)->short_doc[i]);
for (; i < MAX_SHORT_DOC_LEN; i++)
grub_putchar (' ');
if (! left)
grub_putchar ('\n');
left = ! left;
}
}
else
{
/* Invoked with one or more patterns. */
do
{
struct builtin **builtin;
char *next_arg;
/* Get the next argument. */
next_arg = skip_to (0, arg);
/* Terminate ARG. */
nul_terminate (arg);
for (builtin = builtin_table; *builtin; builtin++)
{
/* Skip this if this is only for the configuration file. */
if (! ((*builtin)->flags & BUILTIN_CMDLINE))
continue;
if (substring (arg, (*builtin)->name) < 1)
{
char *doc = (*builtin)->long_doc;
/* At first, print the name and the short doc. */
grub_printf ("%s: %s\n",
(*builtin)->name, (*builtin)->short_doc);
/* Print the long doc. */
while (*doc)
{
int len = grub_strlen (doc);
int i;
/* If LEN is too long, fold DOC. */
if (len > MAX_LONG_DOC_LEN)
{
/* Fold this line at the position of a space. */
for (len = MAX_LONG_DOC_LEN; len > 0; len--)
if (doc[len - 1] == ' ')
break;
}
grub_printf (" ");
for (i = 0; i < len; i++)
grub_putchar (*doc++);
grub_putchar ('\n');
}
}
}
arg = next_arg;
}
while (*arg);
}
return 0;
}
static struct builtin builtin_help =
{
"help",
help_func,
BUILTIN_CMDLINE,
"help [PATTERN ...]",
"Display helpful information about builtin commands."
};
/* hide */
static int
hide_func (char *arg, int flags)
{
unsigned long tmp_drive = saved_drive;
unsigned long tmp_partition = saved_partition;
if (! set_device (arg))
return 1;
saved_partition = current_partition;
saved_drive = current_drive;
if (! set_partition_hidden_flag (1))
{
saved_drive = tmp_drive;
saved_partition = tmp_partition;
return 1;
}
saved_drive = tmp_drive;
saved_partition = tmp_partition;
return 0;
}
static struct builtin builtin_hide =
{
"hide",
hide_func,
BUILTIN_CMDLINE | BUILTIN_MENU,
"hide PARTITION",
"Hide PARTITION by setting the \"hidden\" bit in"
" its partition type code."
};
/* impsprobe */
static int
impsprobe_func (char *arg, int flags)
{
#ifdef GRUB_UTIL
/* In the grub shell, we cannot probe IMPS. */
errnum = ERR_UNRECOGNIZED;
return 1;
#else /* ! GRUB_UTIL */
if (!imps_probe ())
printf (" No MPS information found or probe failed\n");
return 0;
#endif /* ! GRUB_UTIL */
}
static struct builtin builtin_impsprobe =
{
"impsprobe",
impsprobe_func,
BUILTIN_CMDLINE,
"impsprobe",
"Probe the Intel Multiprocessor Specification 1.1 or 1.4"
" configuration table and boot the various CPUs which are found into"
" a tight loop."
};
/* initrd */
static int
initrd_func (char *arg, int flags)
{
switch (kernel_type)
{
case KERNEL_TYPE_LINUX:
case KERNEL_TYPE_BIG_LINUX:
if (! load_initrd (arg))
return 1;
break;
default:
errnum = ERR_NEED_LX_KERNEL;
return 1;
}
return 0;
}
static struct builtin builtin_initrd =
{
"initrd",
initrd_func,
BUILTIN_CMDLINE,
"initrd FILE [ARG ...]",
"Load an initial ramdisk FILE for a Linux format boot image and set the"
" appropriate parameters in the Linux setup area in memory."
};
/* install */
static int
install_func (char *arg, int flags)
{
char *stage1_file, *dest_dev, *file, *addr;
char *stage1_buffer = (char *) RAW_ADDR (0x100000);
char *old_sect = stage1_buffer + SECTOR_SIZE;
char *stage2_first_buffer = old_sect + SECTOR_SIZE;
char *stage2_second_buffer = stage2_first_buffer + SECTOR_SIZE;
/* XXX: Probably SECTOR_SIZE is reasonable. */
char *config_filename = stage2_second_buffer + SECTOR_SIZE;
char *dummy = config_filename + SECTOR_SIZE;
int new_drive = 0xFF;
int dest_drive, dest_sector;
int src_drive, src_partition;
int i;
struct geometry dest_geom, src_geom;
int saved_sector;
int stage2_first_sector, stage2_second_sector;
char *ptr;
int installaddr, installlist;
/* Point to the location of the name of a configuration file in Stage 2. */
char *config_file_location;
/* If FILE is a Stage 1.5? */
int is_stage1_5 = 0;
/* Must call grub_close? */
int is_open = 0;
/* Save the first sector of Stage2 in STAGE2_SECT. */
static void disk_read_savesect_func (int sector)
{
if (debug)
printf ("[%d]", sector);
saved_sector = sector;
}
/* Write SECTOR to INSTALLLIST, and update INSTALLADDR and
INSTALLSECT. */
static void disk_read_blocklist_func (int sector)
{
if (debug)
printf("[%d]", sector);
if (*((unsigned long *) (installlist - 4))
+ *((unsigned short *) installlist) != sector
|| installlist == (int) stage2_first_buffer + SECTOR_SIZE + 4)
{
installlist -= 8;
if (*((unsigned long *) (installlist - 8)))
errnum = ERR_WONT_FIT;
else
{
*((unsigned short *) (installlist + 2)) = (installaddr >> 4);
*((unsigned long *) (installlist - 4)) = sector;
}
}
*((unsigned short *) installlist) += 1;
installaddr += 512;
}
stage1_file = arg;
dest_dev = skip_to (0, stage1_file);
if (*dest_dev == 'd')
{
new_drive = 0;
dest_dev = skip_to (0, dest_dev);
}
file = skip_to (0, dest_dev);
addr = skip_to (0, file);
/* Get the installation address. */
if (! safe_parse_maxint (&addr, &installaddr))
{
/* ADDR is not specified. */
installaddr = 0;
ptr = addr;
errnum = 0;
}
else
ptr = skip_to (0, addr);
#ifndef NO_DECOMPRESSION
/* Do not decompress Stage 1 or Stage 2. */
no_decompression = 1;
#endif
/* Read Stage 1. */
is_open = grub_open (stage1_file);
if (! is_open
|| ! grub_read (stage1_buffer, SECTOR_SIZE) == SECTOR_SIZE)
goto fail;
/* Read the old sector from DEST_DEV. */
if (! set_device (dest_dev)
|| ! open_partition ()
|| ! devread (0, 0, SECTOR_SIZE, old_sect))
goto fail;
/* Store the information for the destination device. */
dest_drive = current_drive;
dest_geom = buf_geom;
dest_sector = part_start;
/* Copy the possible DOS BPB, 59 bytes at byte offset 3. */
grub_memmove (stage1_buffer + BOOTSEC_BPB_OFFSET,
old_sect + BOOTSEC_BPB_OFFSET,
BOOTSEC_BPB_LENGTH);
/* If for a hard disk, copy the possible MBR/extended part table. */
if ((dest_drive & 0x80) && current_partition == 0xFFFFFF)
grub_memmove (stage1_buffer + BOOTSEC_PART_OFFSET,
old_sect + BOOTSEC_PART_OFFSET,
BOOTSEC_PART_LENGTH);
/* Check for the version and the signature of Stage 1. */
if (*((short *)(stage1_buffer + STAGE1_VER_MAJ_OFFS)) != COMPAT_VERSION
|| (*((unsigned short *) (stage1_buffer + BOOTSEC_SIG_OFFSET))
!= BOOTSEC_SIGNATURE))
{
errnum = ERR_BAD_VERSION;
goto fail;
}
/* If DEST_DRIVE is a floppy, Stage 2 must have the iteration probe
routine. */
if (! (dest_drive & 0x80)
&& (*((unsigned char *) (stage1_buffer + BOOTSEC_PART_OFFSET)) == 0x80
|| stage1_buffer[BOOTSEC_PART_OFFSET] == 0))
{
errnum = ERR_BAD_VERSION;
goto fail;
}
grub_close ();
/* Open Stage 2. */
is_open = grub_open (file);
if (! is_open)
goto fail;
src_drive = current_drive;
src_partition = current_partition;
src_geom = buf_geom;
if (! new_drive)
new_drive = src_drive;
else if (src_drive != dest_drive)
grub_printf ("Warning: the option `d' was not used, but the Stage 1 will"
" be installed on a\ndifferent drive than the drive where"
" the Stage 2 resides.\n");
*((unsigned char *) (stage1_buffer + STAGE1_BOOT_DRIVE)) = new_drive;
/* Read the first sector of Stage 2. */
disk_read_hook = disk_read_savesect_func;
if (grub_read (stage2_first_buffer, SECTOR_SIZE) != SECTOR_SIZE)
goto fail;
stage2_first_sector = saved_sector;
/* Read the second sector of Stage 2. */
if (grub_read (stage2_second_buffer, SECTOR_SIZE) != SECTOR_SIZE)
goto fail;
stage2_second_sector = saved_sector;
/* Check for the version of Stage 2. */
if (*((short *) (stage2_second_buffer + STAGE2_VER_MAJ_OFFS))
!= COMPAT_VERSION)
{
errnum = ERR_BAD_VERSION;
goto fail;
}
/* Check for the Stage 2 id. */
if (stage2_second_buffer[STAGE2_STAGE2_ID] != STAGE2_ID_STAGE2)
is_stage1_5 = 1;
/* If INSTALLADDR is not specified explicitly in the command-line,
determine it by the Stage 2 id. */
if (! installaddr)
{
if (! is_stage1_5)
/* Stage 2. */
installaddr = 0x8000;
else
/* Stage 1.5. */
installaddr = 0x2000;
}
*((unsigned long *) (stage1_buffer + STAGE1_STAGE2_SECTOR))
= stage2_first_sector;
*((unsigned short *) (stage1_buffer + STAGE1_STAGE2_ADDRESS))
= installaddr;
*((unsigned short *) (stage1_buffer + STAGE1_STAGE2_SEGMENT))
= installaddr >> 4;
i = (int) stage2_first_buffer + SECTOR_SIZE - 4;
while (*((unsigned long *) i))
{
if (i < (int) stage2_first_buffer
|| (*((int *) (i - 4)) & 0x80000000)
|| *((unsigned short *) i) >= 0xA00
|| *((short *) (i + 2)) == 0)
{
errnum = ERR_BAD_VERSION;
goto fail;
}
*((int *) i) = 0;
*((int *) (i - 4)) = 0;
i -= 8;
}
installlist = (int) stage2_first_buffer + SECTOR_SIZE + 4;
installaddr += SECTOR_SIZE;
/* Read the whole of Stage2 except for the first sector. */
grub_seek (SECTOR_SIZE);
disk_read_hook = disk_read_blocklist_func;
if (! grub_read (dummy, -1))
goto fail;
disk_read_hook = 0;
/* Find a string for the configuration filename. */
config_file_location = stage2_second_buffer + STAGE2_VER_STR_OFFS;
while (*(config_file_location++))
;
if (*ptr == 'p')
{
*((long *) (stage2_second_buffer + STAGE2_INSTALLPART))
= src_partition;
if (is_stage1_5)
{
/* Reset the device information in FILE if it is a Stage 1.5. */
unsigned long device = 0xFFFFFFFF;
grub_memmove (config_file_location, (char *) &device,
sizeof (device));
}
ptr = skip_to (0, ptr);
}
if (*ptr)
{
grub_strcpy (config_filename, ptr);
nul_terminate (config_filename);
if (! is_stage1_5)
/* If it is a Stage 2, just copy PTR to CONFIG_FILE_LOCATION. */
grub_strcpy (config_file_location, ptr);
else
{
char *config_file;
unsigned long device;
/* Translate the external device syntax to the internal device
syntax. */
if (! (config_file = set_device (ptr)))
{
/* The Stage 2 PTR does not contain the device name, so
use the root device instead. */
errnum = ERR_NONE;
current_drive = saved_drive;
current_partition = saved_partition;
config_file = ptr;
}
if (current_drive == src_drive)
{
/* If the drive where the Stage 2 resides is the same as
the one where the Stage 1.5 resides, do not embed the
drive number. */
current_drive = 0xFF;
}
device = (current_drive << 24) | current_partition;
grub_memmove (config_file_location, (char *) &device,
sizeof (device));
grub_strcpy (config_file_location + sizeof (device), config_file);
}
/* Check if the configuration filename is specified, if a Stage 1.5
is used. */
if (is_stage1_5)
{
char *real_config_filename = skip_to (0, ptr);
if (*real_config_filename)
{
/* Specified */
char *location;
is_open = grub_open (config_filename);
if (! is_open)
goto fail;
/* Skip the first sector. */
grub_seek (SECTOR_SIZE);
disk_read_hook = disk_read_savesect_func;
if (grub_read ((char *) SCRATCHADDR, SECTOR_SIZE) != SECTOR_SIZE)
goto fail;
disk_read_hook = 0;
grub_close ();
is_open = 0;
/* Sanity check. */
if (*((unsigned char *) SCRATCHADDR + STAGE2_STAGE2_ID)
!= STAGE2_ID_STAGE2)
{
errnum = ERR_BAD_VERSION;
goto fail;
}
/* Find a string for the configuration filename. */
location = (char *) SCRATCHADDR + STAGE2_VER_STR_OFFS;
while (*(location++))
;
/* Copy the name. */
grub_strcpy (location, real_config_filename);
/* Write it to the disk. */
buf_track = -1;
if (biosdisk (BIOSDISK_WRITE, current_drive, &buf_geom,
saved_sector, 1, SCRATCHSEG))
{
errnum = ERR_WRITE;
goto fail;
}
}
}
}
/* Clear the cache. */
buf_track = -1;
/* Write the modified first sector of Stage2 to the disk. */
grub_memmove ((char *) SCRATCHADDR, stage2_first_buffer, SECTOR_SIZE);
if (biosdisk (BIOSDISK_WRITE, src_drive, &src_geom,
stage2_first_sector, 1, SCRATCHSEG))
{
errnum = ERR_WRITE;
goto fail;
}
/* Write the modified second sector of Stage2 to the disk. */
grub_memmove ((char *) SCRATCHADDR, stage2_second_buffer, SECTOR_SIZE);
if (biosdisk (BIOSDISK_WRITE, src_drive, &src_geom,
stage2_second_sector, 1, SCRATCHSEG))
{
errnum = ERR_WRITE;
goto fail;
}
/* Write the modified sector of Stage 1 to the disk. */
grub_memmove ((char *) SCRATCHADDR, stage1_buffer, SECTOR_SIZE);
if (biosdisk (BIOSDISK_WRITE, dest_drive, &dest_geom,
dest_sector, 1, SCRATCHSEG))
{
errnum = ERR_WRITE;
goto fail;
}
fail:
if (is_open)
grub_close ();
disk_read_hook = 0;
#ifndef NO_DECOMPRESSION
no_decompression = 0;
#endif
return errnum;
}
static struct builtin builtin_install =
{
"install",
install_func,
BUILTIN_CMDLINE,
"install STAGE1 [d] DEVICE STAGE2 [ADDR] [p] [CONFIG_FILE] [REAL_CONFIG_FILE]",
"Install STAGE1 on DEVICE, and install a blocklist for loading STAGE2"
" as a Stage 2. If the option `d' is present, the Stage 1 will always"
" look for the disk where STAGE2 was installed, rather than using"
" the booting drive. The Stage 2 will be loaded at address ADDR, which"
" will be determined automatically if you don't specify it. If"
" the option `p' or CONFIG_FILE is present, then the first block"
" of Stage 2 is patched with new values of the partition and name"
" of the configuration file used by the true Stage 2 (for a Stage 1.5,"
" this is the name of the true Stage 2) at boot time. If STAGE2 is a Stage"
" 1.5 and REAL_CONFIG_FILE is present, then the Stage 2 CONFIG_FILE is"
" patched with the configuration filename REAL_CONFIG_FILE."
};
/* ioprobe */
static int
ioprobe_func (char *arg, int flags)
{
#ifdef GRUB_UTIL
errnum = ERR_UNRECOGNIZED;
return 1;
#else /* ! GRUB_UTIL */
unsigned short *port;
/* Get the drive number. */
set_device (arg);
if (errnum)
return 1;
/* Clean out IO_MAP. */
grub_memset ((char *) io_map, 0, IO_MAP_SIZE * sizeof (unsigned short));
/* Track the int13 handler. */
track_int13 (current_drive);
/* Print out the result. */
for (port = io_map; *port != 0; port++)
grub_printf (" 0x%x", (unsigned int) *port);
return 0;
#endif /* ! GRUB_UTIL */
}
static struct builtin builtin_ioprobe =
{
"ioprobe",
ioprobe_func,
BUILTIN_CMDLINE,
"ioprobe DRIVE",
"Probe I/O ports used for the drive DRIVE."
};
/* kernel */
static int
kernel_func (char *arg, int flags)
{
int len = grub_strlen (arg);
/* Reset MB_CMDLINE. */
mb_cmdline = (char *) MB_CMDLINE_BUF;
if (len + 1 > MB_CMDLINE_BUFLEN)
{
errnum = ERR_WONT_FIT;
return 1;
}
/* Copy the command-line to MB_CMDLINE. */
grub_memmove (mb_cmdline, arg, len + 1);
kernel_type = load_image (arg, mb_cmdline);
if (kernel_type == KERNEL_TYPE_NONE)
return 1;
mb_cmdline += len + 1;
return 0;
}
static struct builtin builtin_kernel =
{
"kernel",
kernel_func,
BUILTIN_CMDLINE,
"kernel FILE [ARG ...]",
"Attempt to load the primary boot image from"
" FILE. The rest of the line is passed verbatim as the"
" \"kernel command line\". Any modules must be reloaded after"
" using this command."
};
/* makeactive */
static int
makeactive_func (char *arg, int flags)
{
if (! make_saved_active ())
return 1;
return 0;
}
static struct builtin builtin_makeactive =
{
"makeactive",
makeactive_func,
BUILTIN_CMDLINE,
"makeactive",
"Set the active partition on the root disk to GRUB's root device."
" This command is limited to _primary_ PC partitions on a hard disk."
};
/* map */
/* Map FROM_DRIVE to TO_DRIVE. */
static int
map_func (char *arg, int flags)
{
char *to_drive;
char *from_drive;
unsigned long to, from;
int i;
to_drive = arg;
from_drive = skip_to (0, arg);
/* Get the drive number for TO_DRIVE. */
set_device (to_drive);
if (errnum)
return 1;
to = current_drive;
/* Get the drive number for FROM_DRIVE. */
set_device (from_drive);
if (errnum)
return 1;
from = current_drive;
/* Search for an empty slot in BIOS_DRIVE_MAP. */
for (i = 0; i < DRIVE_MAP_SIZE; i++)
{
/* Perhaps the user wants to override the map. */
if ((bios_drive_map[i] & 0xff) == from)
break;
if (! bios_drive_map[i])
break;
}
if (i == DRIVE_MAP_SIZE)
{
errnum = ERR_WONT_FIT;
return 1;
}
if (to == from)
/* If TO is equal to FROM, delete the entry. */
grub_memmove ((char *) &bios_drive_map[i], (char *) &bios_drive_map[i + 1],
sizeof (unsigned short) * (DRIVE_MAP_SIZE - i));
else
bios_drive_map[i] = from | (to << 8);
return 0;
}
static struct builtin builtin_map =
{
"map",
map_func,
BUILTIN_CMDLINE,
"map TO_DRIVE FROM_DRIVE",
"Map the drive FROM_DRIVE to the drive TO_DRIVE. This is necessary"
" when you chain-load some operating systems, such as DOS, if such an"
" OS resides at a non-first drive."
};
/* module */
static int
module_func (char *arg, int flags)
{
int len = grub_strlen (arg);
switch (kernel_type)
{
case KERNEL_TYPE_MULTIBOOT:
if (mb_cmdline + len + 1 > (char *) MB_CMDLINE_BUF + MB_CMDLINE_BUFLEN)
{
errnum = ERR_WONT_FIT;
return 1;
}
grub_memmove (mb_cmdline, arg, len + 1);
if (! load_module (arg, mb_cmdline))
return 1;
mb_cmdline += len + 1;
break;
case KERNEL_TYPE_LINUX:
case KERNEL_TYPE_BIG_LINUX:
if (! load_initrd (arg))
return 1;
break;
default:
errnum = ERR_NEED_MB_KERNEL;
return 1;
}
return 0;
}
static struct builtin builtin_module =
{
"module",
module_func,
BUILTIN_CMDLINE,
"module FILE [ARG ...]",
"Load a boot module FILE for a Multiboot format boot image (no"
" interpretation of the file contents is made, so users of this"
" command must know what the kernel in question expects). The"
" rest of the line is passed as the \"module command line\", like"
" the `kernel' command."
};
/* modulenounzip */
static int
modulenounzip_func (char *arg, int flags)
{
int ret;
#ifndef NO_DECOMPRESSION
no_decompression = 1;
#endif
ret = module_func (arg, flags);
#ifndef NO_DECOMPRESSION
no_decompression = 0;
#endif
return ret;
}
static struct builtin builtin_modulenounzip =
{
"modulenounzip",
modulenounzip_func,
BUILTIN_CMDLINE,
"modulenounzip FILE [ARG ...]",
"The same as `module', except that automatic decompression is"
" disabled."
};
/* password */
static int
password_func (char *arg, int flags)
{
int len = grub_strlen (arg);
if (len > PASSWORD_BUFLEN)
{
errnum = ERR_WONT_FIT;
return 1;
}
password = (char *) PASSWORD_BUF;
grub_memmove (password, arg, len + 1);
return 0;
}
static struct builtin builtin_password =
{
"password",
password_func,
BUILTIN_MENU,
#if 0
"password PASSWD FILE",
"Disable all interactive editing control (menu entry editor and"
" command line). If the password PASSWD is entered, it loads the"
" FILE as a new config file and restarts the GRUB Stage 2."
#endif
};
/* pause */
static int
pause_func (char *arg, int flags)
{
/* If ESC is returned, then abort this entry. */
if (ASCII_CHAR (getkey ()) == 27)
return 1;
return 0;
}
static struct builtin builtin_pause =
{
"pause",
pause_func,
BUILTIN_CMDLINE,
"pause [MESSAGE ...]",
"Print MESSAGE, then wait until a key is pressed."
};
/* quit */
static int
quit_func (char *arg, int flags)
{
#ifdef GRUB_UTIL
stop ();
/* Never reach here. */
return 0;
#else /* ! GRUB_UTIL */
errnum = ERR_UNRECOGNIZED;
return 1;
#endif /* ! GRUB_UTIL */
}
static struct builtin builtin_quit =
{
"quit",
quit_func,
BUILTIN_CMDLINE,
"quit",
"Exit from the GRUB shell."
};
static int
read_func (char *arg, int flags)
{
int addr;
if (! safe_parse_maxint (&arg, &addr))
return 1;
grub_printf ("Address 0x%x: Value 0x%x\n",
addr, *((unsigned *) RAW_ADDR (addr)));
return 0;
}
static struct builtin builtin_read =
{
"read",
read_func,
BUILTIN_CMDLINE,
"read ADDR",
"Read a 32-bit value from memory at address ADDR and"
" display it in hex format."
};
/* Print the root device information. */
static void
print_root_device (void)
{
if (saved_drive == 0x20)
{
/* Network drive. */
grub_printf (" (nd):");
}
else if (saved_drive & 0x80)
{
/* Hard disk drive. */
grub_printf (" (hd%d", saved_drive - 0x80);
if ((saved_partition & 0xFF0000) != 0xFF0000)
grub_printf (",%d", saved_partition >> 16);
if ((saved_partition & 0x00FF00) != 0x00FF00)
grub_printf (",%c", ((saved_partition >> 8) & 0xFF) + 'a');
grub_printf ("):");
}
else
{
/* Floppy disk drive. */
grub_printf (" (fd%d):", saved_drive);
}
/* Print the filesystem information. */
current_partition = saved_partition;
current_drive = saved_drive;
print_fsys_type ();
}
static int
root_func (char *arg, int flags)
{
int hdbias = 0;
char *biasptr;
char *next;
/* If ARG is empty, just print the current root device. */
if (! *arg)
{
print_root_device ();
return 0;
}
/* Call set_device to get the drive and the partition in ARG. */
next = set_device (arg);
if (! next)
return 1;
/* Ignore ERR_FSYS_MOUNT. */
if (! open_device () && errnum != ERR_FSYS_MOUNT)
return 1;
/* Clear ERRNUM. */
errnum = 0;
saved_partition = current_partition;
saved_drive = current_drive;
/* BSD and chainloading evil hacks !! */
biasptr = skip_to (0, next);
safe_parse_maxint (&biasptr, &hdbias);
errnum = 0;
bootdev = set_bootdev (hdbias);
/* Print the type of the filesystem. */
print_fsys_type ();
return 0;
}
static struct builtin builtin_root =
{
"root",
root_func,
BUILTIN_CMDLINE,
"root [DEVICE [HDBIAS]]",
"Set the current \"root device\" to the device DEVICE, then"
" attempt to mount it to get the partition size (for passing the"
" partition descriptor in `ES:ESI', used by some chain-loaded"
" bootloaders), the BSD drive-type (for booting BSD kernels using"
" their native boot format), and correctly determine "
" the PC partition where a BSD sub-partition is located. The"
" optional HDBIAS parameter is a number to tell a BSD kernel"
" how many BIOS drive numbers are on controllers before the current"
" one. For example, if there is an IDE disk and a SCSI disk, and your"
" FreeBSD root partition is on the SCSI disk, then use a `1' for HDBIAS."
};
/* rootnoverify */
static int
rootnoverify_func (char *arg, int flags)
{
/* If ARG is empty, just print the current root device. */
if (! *arg)
{
print_root_device ();
return 0;
}
if (! set_device (arg))
return 1;
saved_partition = current_partition;
saved_drive = current_drive;
current_drive = -1;
return 0;
}
static struct builtin builtin_rootnoverify =
{
"rootnoverify",
rootnoverify_func,
BUILTIN_CMDLINE,
"rootnoverify [DEVICE [HDBIAS]]",
"Similar to `root', but don't attempt to mount the partition. This"
" is useful for when an OS is outside of the area of the disk that"
" GRUB can read, but setting the correct root device is still"
" desired. Note that the items mentioned in `root' which"
" derived from attempting the mount will NOT work correctly."
};
/* setkey */
struct keysym
{
char *unshifted_name; /* the name in unshifted state */
char *shifted_name; /* the name in shifted state */
unsigned char unshifted_ascii; /* the ascii code in unshifted state */
unsigned char shifted_ascii; /* the ascii code in shifted state */
unsigned char keycode; /* keyboard scancode */
};
/* The table for key symbols. If the "shifted" member of an entry is
NULL, the entry does not have shifted state. */
static struct keysym keysym_table[] =
{
{"escape", 0, 0x1b, 0, 0x01},
{"1", "exclam", '1', '!', 0x02},
{"2", "at", '2', '@', 0x03},
{"3", "numbersign", '3', '#', 0x04},
{"4", "dollar", '4', '$', 0x05},
{"5", "percent", '5', '%', 0x06},
{"6", "caret", '6', '^', 0x07},
{"7", "ampersand", '7', '&', 0x08},
{"8", "asterisk", '8', '*', 0x09},
{"9", "parenleft", '9', '(', 0x0a},
{"0", "parenright", '0', ')', 0x0b},
{"minus", "underscore", '-', '_', 0x0c},
{"equal", "plus", '=', '+', 0x0d},
{"backspace", 0, '\b', 0, 0x0e},
{"tab", 0, '\t', 0, 0x0f},
{"q", "Q", 'q', 'Q', 0x10},
{"w", "W", 'w', 'W', 0x11},
{"e", "E", 'e', 'E', 0x12},
{"r", "R", 'r', 'R', 0x13},
{"t", "T", 't', 'T', 0x14},
{"y", "Y", 'y', 'Y', 0x15},
{"u", "U", 'u', 'U', 0x16},
{"i", "I", 'i', 'I', 0x17},
{"o", "O", 'o', 'O', 0x18},
{"p", "P", 'p', 'P', 0x19},
{"bracketleft", "braceleft", '[', '{', 0x1a},
{"bracketright", "braceright", ']', '}', 0x1b},
{"enter", 0, '\n', 0, 0x1c},
{"control", 0, 0, 0, 0x1d},
{"a", "A", 'a', 'A', 0x1e},
{"s", "S", 's', 'S', 0x1f},
{"d", "D", 'd', 'D', 0x20},
{"f", "F", 'f', 'F', 0x21},
{"g", "G", 'g', 'G', 0x22},
{"h", "H", 'h', 'H', 0x23},
{"j", "J", 'j', 'J', 0x24},
{"k", "K", 'k', 'K', 0x25},
{"l", "L", 'l', 'L', 0x26},
{"semicolon", "colon", ';', ':', 0x27},
{"quote", "doublequote", '\'', '"', 0x28},
{"backquote", "tilde", '`', '~', 0x29},
{"shift", 0, 0, 0, 0x2a},
{"backslash", "bar", '\\', '|', 0x2b},
{"z", "Z", 'z', 'Z', 0x2c},
{"x", "X", 'x', 'X', 0x2d},
{"c", "C", 'c', 'C', 0x2e},
{"v", "V", 'v', 'V', 0x2f},
{"b", "B", 'b', 'B', 0x30},
{"n", "N", 'n', 'N', 0x31},
{"m", "M", 'm', 'M', 0x32},
{"comma", "less", ',', '<', 0x33},
{"period", "greater", '.', '>', 0x34},
{"slash", "question", '/', '?', 0x35},
{"alt", 0, 0, 0, 0x38},
{"space", 0, ' ', 0, 0x39},
{"capslock", 0, 0, 0, 0x3a},
{"F1", 0, 0, 0, 0x3b},
{"F2", 0, 0, 0, 0x3c},
{"F3", 0, 0, 0, 0x3d},
{"F4", 0, 0, 0, 0x3e},
{"F5", 0, 0, 0, 0x3f},
{"F6", 0, 0, 0, 0x40},
{"F7", 0, 0, 0, 0x41},
{"F8", 0, 0, 0, 0x42},
{"F9", 0, 0, 0, 0x43},
{"F10", 0, 0, 0, 0x44},
/* Caution: do not add NumLock here! we cannot deal with it properly. */
{"delete", 0, 0x7f, 0, 0x53}
};
static int
setkey_func (char *arg, int flags)
{
char *to_key, *from_key;
int to_code, from_code;
int map_in_interrupt = 0;
static int find_key_code (char *key)
{
int i;
for (i = 0; i < sizeof (keysym_table) / sizeof (keysym_table[0]); i++)
{
if (grub_strcmp (key, keysym_table[i].unshifted_name) == 0)
return keysym_table[i].keycode;
else if (grub_strcmp (key, keysym_table[i].shifted_name) == 0)
return keysym_table[i].keycode;
}
return 0;
}
static int find_ascii_code (char *key)
{
int i;
for (i = 0; i < sizeof (keysym_table) / sizeof (keysym_table[0]); i++)
{
if (grub_strcmp (key, keysym_table[i].unshifted_name) == 0)
return keysym_table[i].unshifted_ascii;
else if (grub_strcmp (key, keysym_table[i].shifted_name) == 0)
return keysym_table[i].shifted_ascii;
}
return 0;
}
to_key = arg;
from_key = skip_to (0, to_key);
nul_terminate (to_key);
nul_terminate (from_key);
to_code = find_ascii_code (to_key);
from_code = find_ascii_code (from_key);
if (! to_code || ! from_code)
{
map_in_interrupt = 1;
to_code = find_key_code (to_key);
from_code = find_key_code (from_key);
if (! to_code || ! from_code)
{
errnum = ERR_BAD_ARGUMENT;
return 1;
}
}
if (map_in_interrupt)
{
int i;
/* Find an empty slot. */
for (i = 0; i < KEY_MAP_SIZE; i++)
{
if ((bios_key_map[i] & 0xff) == from_code)
/* Perhaps the user wants to overwrite the map. */
break;
if (! bios_key_map[i])
break;
}
if (i == KEY_MAP_SIZE)
{
errnum = ERR_WONT_FIT;
return 1;
}
if (to_code == from_code)
/* If TO is equal to FROM, delete the entry. */
grub_memmove ((char *) &bios_key_map[i], (char *) &bios_key_map[i + 1],
sizeof (unsigned short) * (KEY_MAP_SIZE - i));
else
bios_key_map[i] = (to_code << 8) | from_code;
/* Ugly but should work. */
unset_int15_handler ();
set_int15_handler ();
}
else
{
int i;
/* Find an empty slot. */
for (i = 0; i < KEY_MAP_SIZE; i++)
{
if ((ascii_key_map[i] & 0xff) == from_code)
/* Perhaps the user wants to overwrite the map. */
break;
if (! ascii_key_map[i])
break;
}
if (i == KEY_MAP_SIZE)
{
errnum = ERR_WONT_FIT;
return 1;
}
if (to_code == from_code)
/* If TO is equal to FROM, delete the entry. */
grub_memmove ((char *) &ascii_key_map[i],
(char *) &ascii_key_map[i + 1],
sizeof (unsigned short) * (KEY_MAP_SIZE - i));
else
ascii_key_map[i] = (to_code << 8) | from_code;
}
return 0;
}
static struct builtin builtin_setkey =
{
"setkey",
setkey_func,
BUILTIN_CMDLINE | BUILTIN_MENU,
"setkey TO_KEY FROM_KEY",
"Change the keyboard map. The key FROM_KEY is mapped to the key TO_KEY."
" A key must be an alphabet, a digit, or one of these: escape, exclam,"
" at, numbersign, dollar, percent, caret, ampersand, asterisk, parenleft,"
" parenright, minus, underscore, equal, plus, backspace, tab, bracketleft,"
" braceleft, bracketright, braceright, enter, control, semicolon, colon,"
" quote, doublequote, backquote, tilde, shift, backslash, bar, comma,"
" less, period, greater, slash, question, alt, space, capslock, FX (X"
" is a digit), and delete."
};
/* setup */
static int
setup_func (char *arg, int flags)
{
/* Point to the string of the installed drive/partition. */
char *install_ptr;
/* Point to the string of the drive/parition where the GRUB images
reside. */
char *image_ptr;
unsigned long install_drive, install_partition;
unsigned long image_drive, image_partition;
unsigned long tmp_drive, tmp_partition;
char stage1[64];
char stage2[64];
char config_file[64];
char cmd_arg[256];
char device[16];
char *buffer = (char *) RAW_ADDR (0x100000);
static void sprint_device (int drive, int partition)
{
grub_sprintf (device, "(%cd%d",
(drive & 0x80) ? 'h' : 'f',
drive & ~0x80);
if ((partition & 0xFF0000) != 0xFF0000)
{
char tmp[16];
grub_sprintf (tmp, ",%d", (partition >> 16) & 0xFF);
grub_strncat (device, tmp, 256);
}
if ((partition & 0x00FF00) != 0x00FF00)
{
char tmp[16];
grub_sprintf (tmp, ",%c", 'a' + ((partition >> 8) & 0xFF));
grub_strncat (device, tmp, 256);
}
grub_strncat (device, ")", 256);
}
struct stage1_5_map {
char *fsys;
char *name;
};
struct stage1_5_map stage1_5_map[] =
{
{"ext2fs", "/boot/grub/e2fs_stage1_5"},
{"ffs", "/boot/grub/ffs_stage1_5"},
{"fat", "/boot/grub/fat_stage1_5"},
{"minix", "/boot/grub/minix_stage1_5"}
};
/* Initialize some strings. */
grub_strcpy (stage1, "/boot/grub/stage1");
grub_strcpy (stage2, "/boot/grub/stage2");
grub_strcpy (config_file, "/boot/grub/menu.lst");
tmp_drive = saved_drive;
tmp_partition = saved_partition;
install_ptr = arg;
image_ptr = skip_to (0, install_ptr);
/* Make sure that INSTALL_PTR is valid. */
set_device (install_ptr);
if (errnum)
return 1;
install_drive = current_drive;
install_partition = current_partition;
/* Mount the drive pointed by IMAGE_PTR. */
if (*image_ptr)
{
/* If the drive/partition where the images reside is specified,
get the drive and the partition. */
set_device (image_ptr);
if (errnum)
return 1;
}
else
{
/* If omitted, use SAVED_PARTITION and SAVED_DRIVE. */
current_drive = saved_drive;
current_partition = saved_partition;
}
image_drive = saved_drive = current_drive;
image_partition = saved_partition = current_partition;
/* Open it. */
if (! open_device ())
goto fail;
/* Check for stage1 and stage2. We hardcode the filenames, so
if the user installed GRUB in a uncommon directory, this never
succeed. */
if (! grub_open (stage1))
goto fail;
grub_close ();
if (! grub_open (stage2))
goto fail;
grub_close ();
/* If the drive where stage2 resides is a hard disk, try to use a
Stage 1.5. */
if (image_drive & 0x80)
{
char *fsys = fsys_table[fsys_type].name;
int i;
int size = sizeof (stage1_5_map) / sizeof (stage1_5_map[0]);
/* Iterate finding the same filesystem name as FSYS. */
for (i = 0; i < size; i++)
if (grub_strcmp (fsys, stage1_5_map[i].fsys) == 0)
{
/* OK, check if the Stage 1.5 exists. */
if (grub_open (stage1_5_map[i].name))
{
grub_close ();
grub_strcpy (config_file, stage2);
grub_strcpy (stage2, stage1_5_map[i].name);
if (install_partition == 0xFFFFFF)
{
/* We install GRUB into the MBR, so try to embed the
Stage 1.5 in the sectors right after the MBR. */
sprint_device (install_drive, install_partition);
grub_sprintf (cmd_arg, "%s %s", stage2, device);
/* Notify what will be run. */
grub_printf (" Run \"embed %s\"\n", cmd_arg);
embed_func (cmd_arg, flags);
if (! errnum)
{
int len;
/* Need to know the size of the Stage 1.5. */
grub_seek (0);
len = grub_read (buffer, -1);
/* Construct the blocklist representation. */
grub_sprintf (stage2, "%s1+%d",
device,
(len + SECTOR_SIZE - 1) / SECTOR_SIZE);
/* Need to prepend the device name to the
configuration filename. */
sprint_device (image_drive, image_partition);
grub_sprintf (buffer, "%s%s", device, config_file);
grub_strcpy (config_file, buffer);
}
}
else if (grub_strcmp (fsys, "ffs") == 0)
{
/* We can embed the Stage 1.5 into the "bootloader"
area in the FFS partition. */
/* FIXME */
}
}
errnum = 0;
break;
}
}
/* Construct a string that is used by the command "install" as its
arguments. */
sprint_device (install_drive, install_partition);
grub_sprintf (cmd_arg, "%s %s%s %s p %s",
stage1,
(install_drive != image_drive) ? "d " : "",
device,
stage2,
config_file);
/* Notify what will be run. */
grub_printf (" Run \"install %s\"\n", cmd_arg);
/* Make sure that SAVED_DRIVE and SAVED_PARTITION are identical
with IMAGE_DRIVE and IMAGE_PARTITION, respectively. */
saved_drive = image_drive;
saved_partition = image_partition;
/* Run the command. */
install_func (cmd_arg, flags);
fail:
saved_drive = tmp_drive;
saved_partition = tmp_partition;
return errnum;
}
static struct builtin builtin_setup =
{
"setup",
setup_func,
BUILTIN_CMDLINE,
"setup INSTALL_DEVICE [IMAGE_DEVICE]",
"Set up the installation of GRUB automatically. This command uses"
" the more flexible command \"install\" in the backend and installs"
" GRUB into the device INSTALL_DEVICE. If IMAGE_DEVICE is specified,"
" then find the GRUB images in the device IMAGE_DEVICE, otherwise"
" use the current \"root device\", which can be set by the command"
" \"root\"."
};
/* testload */
static int
testload_func (char *arg, int flags)
{
int i;
kernel_type = KERNEL_TYPE_NONE;
if (! grub_open (arg))
return 1;
disk_read_hook = disk_read_print_func;
/* Perform filesystem test on the specified file. */
/* Read whole file first. */
grub_printf ("Whole file: ");
grub_read ((char *) RAW_ADDR (0x100000), -1);
/* Now compare two sections of the file read differently. */
for (i = 0; i < 0x10ac0; i++)
{
*((unsigned char *) RAW_ADDR (0x200000 + i)) = 0;
*((unsigned char *) RAW_ADDR (0x300000 + i)) = 1;
}
/* First partial read. */
grub_printf ("\nPartial read 1: ");
grub_seek (0);
grub_read ((char *) RAW_ADDR (0x200000), 0x7);
grub_read ((char *) RAW_ADDR (0x200007), 0x100);
grub_read ((char *) RAW_ADDR (0x200107), 0x10);
grub_read ((char *) RAW_ADDR (0x200117), 0x999);
grub_read ((char *) RAW_ADDR (0x200ab0), 0x10);
grub_read ((char *) RAW_ADDR (0x200ac0), 0x10000);
/* Second partial read. */
grub_printf ("\nPartial read 2: ");
grub_seek (0);
grub_read ((char *) RAW_ADDR (0x300000), 0x10000);
grub_read ((char *) RAW_ADDR (0x310000), 0x10);
grub_read ((char *) RAW_ADDR (0x310010), 0x7);
grub_read ((char *) RAW_ADDR (0x310017), 0x10);
grub_read ((char *) RAW_ADDR (0x310027), 0x999);
grub_read ((char *) RAW_ADDR (0x3109c0), 0x100);
grub_printf ("\nHeader1 = 0x%x, next = 0x%x, next = 0x%x, next = 0x%x\n",
*((int *) RAW_ADDR (0x200000)),
*((int *) RAW_ADDR (0x200004)),
*((int *) RAW_ADDR (0x200008)),
*((int *) RAW_ADDR (0x20000c)));
grub_printf ("Header2 = 0x%x, next = 0x%x, next = 0x%x, next = 0x%x\n",
*((int *) RAW_ADDR (0x300000)),
*((int *) RAW_ADDR (0x300004)),
*((int *) RAW_ADDR (0x300008)),
*((int *) RAW_ADDR (0x30000c)));
for (i = 0; i < 0x10ac0; i++)
if (*((unsigned char *) RAW_ADDR (0x200000 + i))
!= *((unsigned char *) RAW_ADDR (0x300000 + i)))
break;
grub_printf ("Max is 0x10ac0: i=0x%x, filepos=0x%x\n", i, filepos);
disk_read_hook = 0;
grub_close ();
return 0;
}
static struct builtin builtin_testload =
{
"testload",
testload_func,
BUILTIN_CMDLINE,
"testload FILE",
"Read the entire contents of FILE in several different ways and"
" compares them, to test the filesystem code. The output is somewhat"
" cryptic, but if no errors are reported and the final `i=X,"
" filepos=Y' reading has X and Y equal, then it is definitely"
" consistent, and very likely works correctly subject to a"
" consistent offset error. If this test succeeds, then a good next"
" step is to try loading a kernel."
};
/* timeout */
static int
timeout_func (char *arg, int flags)
{
if (! safe_parse_maxint (&arg, &grub_timeout))
return 1;
return 0;
}
static struct builtin builtin_timeout =
{
"timeout",
timeout_func,
BUILTIN_MENU,
#if 0
"timeout SEC",
"Set a timeout, in SEC seconds, before automatically booting the"
" default entry (normally the first entry defined)."
#endif
};
/* title */
static int
title_func (char *arg, int flags)
{
/* This function is not actually used at least currently. */
return 0;
}
static struct builtin builtin_title =
{
"title",
title_func,
BUILTIN_TITLE,
#if 0
"title [NAME ...]",
"Start a new boot entry, and set its name to the contents of the"
" rest of the line, starting with the first non-space character."
#endif
};
/* unhide */
static int
unhide_func (char *arg, int flags)
{
unsigned long tmp_drive = saved_drive;
unsigned long tmp_partition = saved_partition;
if (! set_device (arg))
return 1;
saved_partition = current_partition;
saved_drive = current_drive;
if (! set_partition_hidden_flag (0))
{
saved_drive = tmp_drive;
saved_partition = tmp_partition;
return 1;
}
saved_drive = tmp_drive;
saved_partition = tmp_partition;
return 0;
}
static struct builtin builtin_unhide =
{
"unhide",
unhide_func,
BUILTIN_CMDLINE | BUILTIN_MENU,
"unhide PARTITION",
"Unhide PARTITION by clearing the \"hidden\" bit in its"
" partition type code."
};
/* uppermem */
static int
uppermem_func (char *arg, int flags)
{
if (! safe_parse_maxint (&arg, (int *) &mbi.mem_upper))
return 1;
mbi.flags &= ~MB_INFO_MEM_MAP;
return 0;
}
static struct builtin builtin_uppermem =
{
"uppermem",
uppermem_func,
BUILTIN_CMDLINE,
"uppermem KBYTES",
"Force GRUB to assume that only KBYTES kilobytes of upper memory are"
" installed. Any system address range maps are discarded."
};
/* The table of builtin commands. Sorted in dictionary order. */
struct builtin *builtin_table[] =
{
&builtin_boot,
&builtin_cat,
&builtin_chainloader,
&builtin_color,
&builtin_configfile,
&builtin_debug,
&builtin_default,
&builtin_device,
&builtin_displaymem,
&builtin_embed,
&builtin_fallback,
&builtin_find,
&builtin_fstest,
&builtin_geometry,
&builtin_help,
&builtin_hide,
&builtin_impsprobe,
&builtin_initrd,
&builtin_install,
&builtin_ioprobe,
&builtin_kernel,
&builtin_makeactive,
&builtin_map,
&builtin_module,
&builtin_modulenounzip,
&builtin_password,
&builtin_pause,
&builtin_quit,
&builtin_read,
&builtin_root,
&builtin_rootnoverify,
&builtin_setkey,
&builtin_setup,
&builtin_testload,
&builtin_timeout,
&builtin_title,
&builtin_unhide,
&builtin_uppermem,
0
};