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|
#!/usr/bin/perl
# isohybrid-acritox - written by Andreas Loibl <andreas@andreas-loibl.de>
#
# Post-process an ISO 9660 image generated with mkisofs/genisoimage and equipped with
# an embedded isohybrid-acritox space-file (default filename: /boot.isohybrid)
# to allow "multi-hybrid booting" as CD-ROM (EFI or El Torito) or as a hard-drive
# (e.g. a USB pendrive) on Intel-Macs (EFI) and PCs (EFI or MBR). By adding a fake
# ISO9660-structure of the original image as partition inside the image it is possible
# to repartition such a multi-hybrid-image even when it is currently being used live.
#
# This is accomplished by:
# * embedding a FAT-filesystem containing GRUB2EFI into the space-file
# * embedding a modified copy of the ISO9660-structure into the space-file
# * appending a HFS+-partiton containing GRUB2EFI at the end of the image
# * injecting an "Apple Partition Map" into the image referencing the HFS+-partition
# * adding a MBR partition table with two partitions:
# 1. EFI-FAT-partition representing the FAT-filesystem in the space-file
# 2. ISO-partition referencing the fake-ISO9660-header in the space-file,
# spanning until the end of the image
# name of the isohybrid-acritox space-file embedded in the ISO
# NOTE: it is important that this file is the first file on the ISO, so make sure
# you use the "-sort" option for mkisofs/genisofs and give it the highest weight
$space_filename="boot.isohybrid";
# EFI-FAT-image options
$fat_filename="efi-fat.img";
$fat_label="KANOTIX_EFI";
# EFI-HFS+-image options
$hfs_filename="efi-hfs.img";
$hfs_label="KANOTIX Mac";
$hfs_vollabel="http://kanotix.acritox.com/files/mac/label.vollabel";
$hfs_extras="http://kanotix.acritox.com/files/mac/imagewriter.tar.gz";
# Enable verbose debug ouput if $debug=1;
$debug=1;
# blocksize
$bs=0x0800; # 2048 bytes
# 512byte boot.img
$mbr='45520800eb5f90000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000000800100000000000000fffaeb07f6c2807502b280ea747c000031c08ed88ed0bc0020fba0647c3cff740288c252be807de81c01be057cf6c2807448b441bbaa55cd135a52723d81fb55aa753783e101743231c0894404408844ff894402c7041000668b1e5c7c66895c08668b1e607c66895c0cc744060070b442cd137205bb0070eb76b408cd13730df6c2800f84d800be8b7de98200660fb6c68864ff40668944040fb6d1c1e20288e888f4408944080fb6c2c0e80266890466a1607c6609c0754e66a15c7c6631d266f73488d131d266f774043b44087d37fec188c530c0c1e80208c188d05a88c6bb00708ec331dbb80102cd13721e8cc3601eb900018edb31f6bf00808ec6fcf3a51f61ff265a7cbe867deb03be957de83400be9a7de82e00cd18ebfe47525542200047656f6d0048617264204469736b005265616400204572726f720d0a00bb0100b40ecd10ac3c0075f4c3000000000000000000000000000024120f0900bebd7d31c0cd13468a0c80f900750fbeda7de8d2ffeb9c466c6f70707900bb0070b80102b500b600cd1372d7b601b54fe9fbfe000000000000000055aa';
# Apple Partition Map entries:
$pm1='504d000000000003000000010000000f4170706c650000000000000000000000000000000000000000000000000000004170706c655f706172746974696f6e5f6d617000000000000000000000000000000000000000000f00000003'; # Apple_partition_map
$pm2='504d00000000000300000400000005006469736b20696d616765000000000000000000000000000000000000000000004170706c655f4846530000000000000000000000000000000000000000000000000000000000040040000033'; # Apple_HFS
$pm3='504d00000000000300000001000004004b414e4f5449585f454649000000000000000000000000000000000000000000444f535f4641545f313200000000000000000000000000000000000000000000000000000000040040000033'; # DOS_FAT_12
# Pad the image to a fake cylinder boundary
$cylsize = 1024*1024; # 1MB
die "Usage: $0 <binary-hybrid.iso>\n" if $#ARGV != 0;
use integer;
sub max ($$) { $_[$_[0] < $_[1]] }
sub min ($$) { $_[$_[0] > $_[1]] }
($file) = @ARGV;
open(FIMG, "+< $file\0") or die "$0: cannot open $file: $!\n";
binmode FIMG;
# Check if image has already been "patched" (i.e. it has the APM signature from $block0)
seek(FIMG, 0, SEEK_SET) or die "$0: $file: $!\n";
read(FIMG, $test, 2) == 2 or die "$0: $file: read error\n";
die "$file seems to have an APM signature already...\n" if($test eq 'ER');
# Check if image is already a isohybrid-bg2 image (i.e. it has GRUB in its MBR)
seek(FIMG, 0x180, SEEK_SET) or die "$0: $file: $!\n";
read(FIMG, $test, 4) == 4 or die "$0: $file: read error\n";
die "$file seems to have GRUB in its MBR already...\n" if($test eq 'GRUB');
die "$0: /usr/bin/isoinfo missing!\n" unless (-e '/usr/bin/isoinfo');
# Get the position of the space-file
$csf_pos_blk = int(`/usr/bin/isoinfo -R -s -l -i "$file" | awk '/$space_filename/{print \$10}'`);
if (!$csf_pos_blk) {
die "$0: cannot determine position of space-file: $space_filename\n";
}
$csf_pos_lba = $csf_pos_blk*4;
$csf_pos = $csf_pos_lba*512;
# Get the size of the space-file
$csf_size_blk = int(`/usr/bin/isoinfo -R -s -l -i "$file" | awk '/$space_filename/{print \$5}'`);
if (!$csf_size_blk) {
die "$0: cannot determine size of space-file: $space_filename\n";
}
$csf_size_lba = $csf_size_blk*4;
$csf_size = $csf_size_lba*512;
# Get the total size of the image
(@imgstat = stat(FIMG)) or die "$0: $file: $!\n";
$imgsize = $imgstat[7];
if (!$imgsize) {
die "$0: $file: cannot determine length of file\n";
}
print "imgsize: $imgsize\n" if($debug);
# Fixed position of FAT partition at LBA 2048
# TODO: add check if LBA 2048 is actually inside the space-file
$fat_pos_lba = 2048;
$fat_pos = $fat_pos_lba*512;
$fat_pos_blk = $fat_pos_lba/4;
# Set the maximum size of the FAT partiton
$fat_maxsize_blk = $csf_size_blk - $fat_pos_blk;
$fat_maxsize_blk -= $fat_maxsize_blk % 16;
# Generate the FAT partition
print <<`SHELL`;
if [ ! -x /usr/bin/mmd ]; then
echo "Error: mtools are needed! Run: apt-get install mtools" >&2
exit 1
fi
rm -f "$fat_filename"
# Stuff boot*.efi into a FAT filesystem
# mkfs.msdos has blocksize 1024 => multiply with 2
mkfs.msdos -n "$fat_label" -C "$fat_filename" \$(($fat_maxsize_blk*2)) >&2
mmd -i "$fat_filename" ::efi
mmd -i "$fat_filename" ::efi/boot
for file in binary/efi/boot/boot*.efi
do
mcopy -i "$fat_filename" \$file "::efi/boot/\$(basename "\$file")"
done
# hide the FAT-EFI-partition from the Mac Bootloader by f***ing up the "EFI" directory entry
mattrib -i "$fat_filename" +h ::efi
sed -i -e '0,/EFI /s/EFI /efi /' "$fat_filename"
exit 0
SHELL
die "$0: EFI-FAT-image creation failed" if (${^CHILD_ERROR_NATIVE});
open(FFAT, "< $fat_filename\0") or die "$0: cannot open $fat_filename: $!\n";
binmode FFAT;
# Get the total size of the FAT partiton
(@fat_stat = stat(FFAT)) or die "$0: $fat_filename: $!\n";
$fat_size = $fat_stat[7];
$fat_size_lba = $fat_size/512;
$fat_size_blk = $fat_size_lba/4;
if (!$fat_size) {
die "$0: $fat_filename: cannot determine length of file\n";
}
print "fat_pos: $fat_pos fat_size: $fat_size\n" if($debug);
# Write FAT partition to image
seek(FFAT, 0, SEEK_SET) or die "$0: $fat_filename: $!\n";
read FFAT, $partition, $fat_size;
seek(FIMG, $fat_pos, SEEK_SET) or die "$0: $file: $!\n";
print FIMG $partition;
close(FFAT);
# Generate the HFS partition
$inode = int(<<`SHELL`);
img="$hfs_filename"
label="$hfs_label"
vollabel="$hfs_vollabel"
extras="$hfs_extras"
workdir=
cleanup () {
[ "\$workdir" ] || exit
umount "\$workdir" 2>/dev/null | :
rm -rf "\$workdir"
}
trap cleanup EXIT HUP INT QUIT TERM
workdir="\$(mktemp -d efi-image.XXXXXX)"
# Stuff boot*.efi into a HFS+ filesystem, making it as small as possible (in MB steps).
# (x+1023)/1024*1024 rounds up to multiple of 1024.
dd if=/dev/zero of="\$img" bs=1k count=\$(( (\$(stat -c %s binary/efi/boot/boot*.efi | awk '{s+=\$1} END {print s}') / 1024 + 1023) / 1024 * 1024 )) 2>/dev/null
mkfs.hfsplus -v "\$label" "\$img" >&2
mount -o loop,creator=prhc,type=jxbt,uid=99,gid=99 "\$img" "\$workdir"
case "\$vollabel" in
http*|ftp*)
wget -qO"\$workdir"/.disk_label "\$vollabel"
;;
*)
[ -e "\$vollabel" ] && cp "\$vollabel" "\$workdir"/.disk_label
;;
esac
mkdir -p "\$workdir"/efi/boot
for file in binary/efi/boot/boot*.efi
do
cp "\$file" "\$workdir/efi/boot/\$(basename "\$file")"
done
for extra in \$extras
do
extrabase="\$(basename "\$extra")"
case "\$extra" in
http*|ftp*)
wget -qO"\$workdir/\$extrabase" "\$extra"
;;
*)
[ -e "\$extra" ] && cp "\$extra" "\$workdir/\$extrabase"
;;
esac
case "\$extrabase" in
*.tar.gz)
if [ -e "\$workdir/\$extrabase" ]; then
tar xzf "\$workdir/\$extrabase" -C "\$workdir"
rm "\$workdir/\$extrabase"
fi
;;
esac
done
set -- \$(ls -i \$workdir/efi/boot/boot*.efi)
inode=\$1
umount "\$workdir"
# return the inode that needs to be blessed
echo "\$inode"
exit 0
SHELL
die "$0: EFI-HFS-image creation failed" if (${^CHILD_ERROR_NATIVE} || $inode < 1);
open(FHFS, "+< $hfs_filename\0") or die "$0: cannot open $hfs_filename: $!\n";
binmode FHFS;
# Check if partition contains a HFS+ filesystem
seek(FHFS, 0x400, SEEK_SET) or die "$0: $file: $!\n";
read(FHFS, $test, 2) == 2 or die "$0: $file: read error\n";
die "$hfs_filename doesn't seem to contain a HFS+ filesystem\n" if($test ne 'H+');
# Bless the HFS image
print "HFS: blessing file with inode $inode\n" if($debug);
seek(FHFS, 0x450, SEEK_SET) or die "$!\n";
print FHFS pack('NN', 2, $inode);
seek(FHFS, 0x464, SEEK_SET) or die "$!\n";
print FHFS pack('N', 2, $inode);
# Get the total size of the HFS partiton
(@hfs_stat = stat(FHFS)) or die "$0: $hfs_filename: $!\n";
$hfs_size = $hfs_stat[7];
$hfs_size_lba = $hfs_size/512;
$hfs_size_blk = $hfs_size_lba/4;
if (!$hfs_size) {
die "$0: $hfs_filename: cannot determine length of file\n";
}
# Write MBR
seek(FIMG, 0, SEEK_SET) or die "$0: $file: $!\n";
print FIMG pack('H*',$mbr);
# Update GRUB2 locations
seek(FIMG, 0x5c, SEEK_SET) or die "$0: $file: $!\n";
print FIMG pack("V", $csf_pos_lba);
seek(FIMG, $csf_pos + 0x1f4, SEEK_SET) or die "$0: $file: $!\n";
print FIMG pack("V", $csf_pos_lba+1);
# Write ApplePartitionMap entries
seek(FIMG, $bs*1, SEEK_SET) or die "$0: $file: $!\n";
print FIMG pack('H*',$pm1);
seek(FIMG, $bs*2, SEEK_SET) or die "$0: $file: $!\n";
print FIMG pack('H*',$pm2);
seek(FIMG, $bs*3, SEEK_SET) or die "$0: $file: $!\n";
print FIMG pack('H*',$pm3);
# Pad the image to a fake cylinder boundary
$frac = $imgsize % $cylsize;
$padding = ($frac > 0) ? $cylsize - $frac : 0;
if ($padding) {
seek(FIMG, $imgsize, SEEK_SET) or die "$0: $file: $!\n";
print FIMG "\0" x $padding;
$imgsize += $padding;
}
# Position of the HFS partition
$hfs_pos = $imgsize;
$hfs_pos_lba = $hfs_pos/512;
$hfs_pos_blk = $hfs_pos_lba/4;
# Append HFS partition to image
seek(FHFS, 0, SEEK_SET) or die "$0: $file: $!\n";
read FHFS, $partition, $hfs_size;
seek(FIMG, $imgsize, SEEK_SET) or die "$0: $file: $!\n";
print FIMG $partition;
close(FHFS);
# Pad the HFS partition to a fake cylinder boundary
$frac = $hfs_size % $cylsize;
$padding = ($frac > 0) ? $cylsize - $frac : 0;
if ($padding) {
print FIMG "\0" x $padding;
}
$hfs_size += $padding;
$hfs_size_lba = $hfs_size/512;
$hfs_size_blk = $hfs_size_lba/4;
print "hfs_pos: $hfs_pos hfs_size: $hfs_size\n" if($debug);
# Adjust $pm2 (Apple_HFS)
# "physical block start" and "physical block count" of partition:
seek(FIMG, $bs*2+8, SEEK_SET) or die "$0: $file: $!\n";
print FIMG pack('NN', $hfs_pos_blk, $hfs_size_blk);
# "logical block start" and "logical block count" of partition:
seek(FIMG, $bs*2+80, SEEK_SET) or die "$0: $file: $!\n";
print FIMG pack('NN', 0, $hfs_size_blk);
# Adjust $pm3 (DOS_FAT_12)
# "physical block start" and "physical block count" of partition:
seek(FIMG, $bs*3+8, SEEK_SET) or die "$0: $file: $!\n";
print FIMG pack('NN', $fat_pos_blk, $fat_size_blk);
# "logical block start" and "logical block count" of partition:
seek(FIMG, $bs*3+80, SEEK_SET) or die "$0: $file: $!\n";
print FIMG pack('NN', 0, $fat_size_blk);
$imgsize += $hfs_size;
seek(FIMG, $imgsize, SEEK_SET) or die "$0: $file: $!\n";
# Pad the image to a fake cylinder boundary
$frac = $imgsize % $cylsize;
$padding = ($frac > 0) ? $cylsize - $frac : 0;
$imgsize += $padding;
if ($padding) {
print FIMG "\0" x $padding;
}
# Position of the ISO partition: one block after the FAT partition
$iso_pos_blk = $fat_pos_blk + $fat_size_blk;
$iso_pos_lba = $iso_pos_blk*4;
$iso_pos = $iso_pos_lba*512;
# Size of the ISO partition: spanning until the end of the image (including HFS partition)
$iso_size = $imgsize - $iso_pos;
$iso_size_lba = $iso_size/512;
$iso_size_blk = $iso_size_lba/4;
print "iso_pos: $iso_pos iso_size: $iso_size\n" if($debug);
print "final imgsize: $imgsize\n" if($debug);
# Calculate and write partiton table (MBR)
$h = 64; $s = 32;
$hpc = 32; $spt = 63;
$cc = min(1024, $imgsize/$cylsize);
$pentry = 1;
$fstype = 0xEF;
$bcyl = $fat_pos_lba / ($spt * $hpc);
$bhead = ($fat_pos_lba / $spt) % $hpc;
$bsect = ($fat_pos_lba % $spt) + 1;
$ehead = $h-1;
$esect = $s + ((($cc-1) & 0x300) >> 2);
$ecyl = ($cc-1) & 0xff;
seek(FIMG, 430+16*$pentry, SEEK_SET) or die "$0: $file: $!\n";
print FIMG pack("CCCCCCCCVV", 0x80, $bhead, $bsect, $bcyl, $fstype, $ehead, $esect, $ecyl, $fat_pos_lba, $fat_size_lba);
$pentry = 2;
$fstype = 0x83;
$bcyl = $iso_pos_lba / ($spt * $hpc);
$bhead = ($iso_pos_lba / $spt) % $hpc;
$bsect = ($iso_pos_lba % $spt) + 1;
$ehead = $h-1;
$esect = $s + ((($cc-1) & 0x300) >> 2);
$ecyl = ($cc-1) & 0xff;
seek(FIMG, 430+16*$pentry, SEEK_SET) or die "$0: $file: $!\n";
print FIMG pack("CCCCCCCCVV", 0x00, $bhead, $bsect, $bcyl, $fstype, $ehead, $esect, $ecyl, $iso_pos_lba, $iso_size_lba);
# Delete partition entries 3 and 4
print FIMG "\0" x 32;
# Embed a copy of the ISO filesystem into the ISO at the second partition
seek(FIMG, 0, SEEK_SET) or die "$0: $file: $!\n";
read FIMG, $iso_copy, $csf_pos;
seek(FIMG, $iso_pos, SEEK_SET) or die "$0: $file: $!\n";
print FIMG $iso_copy;
sub write_val
{
my($offset, $value) = @_;
$cur = tell(FIMG);
$offset += $cur if $offset < 0;
printf("byte-offset: 0x%X -> 0x%X\n", $offset, $offset-$iso_pos) if($debug);
seek(FIMG, $offset, SEEK_SET);
print FIMG $value;
seek(FIMG, $cur, SEEK_SET);
}
# ISO9660 Primary Volume Descriptor
$off_pvd = $iso_pos+0x8000;
do
{
seek(FIMG, $off_pvd, SEEK_SET) or die "$0: $file: $!\n";
read(FIMG, $voldesc_head, 7) > 0 or die "$0: $file: read error\n";
($type, $magic, $version) = unpack("Ca[5]C", $voldesc_head);
if($type == 1)
{
seek(FIMG, 0x97, 1);
read(FIMG, $voldesc, 8) > 0 or die "$0: $file: read error\n";
($first_sector_blk, $first_sector_blk_be) = unpack("VN", $voldesc);
seek(FIMG, $iso_pos+$first_sector_blk*$bs, SEEK_SET) or die "$0: $file: $!\n";
printf("root-directory entry at 0x%X:\n", tell(FIMG)) if($debug);
read(FIMG, $bytes, 1) > 0 or die "$0: $file: read error\n";
$bytes = unpack("C", $bytes) - 1; $sector_blk = 0;
do {
printf("SUSP entry - %u bytes (0x%X)\n", $bytes+1, $bytes+1) if($debug);
do {
$wp = tell(FIMG);
$bytes -= read(FIMG, $voldesc, 32);
($ext_sectors, $susp_pos_blk, $susp_pos_blk_be, $size, $size_be, $uu, $namelen)
= unpack("CVNVNa[14]C", $voldesc);
if($susp_pos_blk > $iso_pos_blk)
{
printf("LBA 0x%x -> LBA 0x%x\n", $susp_pos_blk, $susp_pos_blk - $iso_pos_blk) if($debug);
write_val($wp+1, pack("VN", $susp_pos_blk - $iso_pos_blk, $susp_pos_blk - $iso_pos_blk));
}
$namelen++ if $namelen % 2 == 0;
$bytes -= read(FIMG, $name, $namelen);
$filename = unpack("Z*", $name);
print("file: $filename\n") if($debug);
# hide the second ISOFS-EFI-partition from the Mac Bootloader by f***ing up the "EFI" directory entry
write_val(-$namelen, pack("Z*", ".PC")) if($filename eq "EFI");
$bytes -= read(FIMG, $sua_head, 4);
($sig, $len, $version) = unpack("a[2]CC", $sua_head);
$len -= 4;
$bytes -= read(FIMG, $data, $len);
do {
$bytes -= read(FIMG, $sua_head, 4);
($sig, $len, $version) = unpack("a[2]CCa", $sua_head);
$len -= 4;
$bytes -= read(FIMG, $data, $len);
if($sig eq "CE")
{
($sua_block, $uu1, $sua_pos, $uu2, $sua_size, $uu3) = unpack("VNVNVN", $data);
printf("CE is at LBA 0x%X -> 0x%x\n", $sua_block) if($debug);
}
} while($bytes > 4);
$bytes -= read(FIMG, $uu, $bytes) if $bytes > 0; # skip bytes (if unaligned)
read(FIMG, $bytes, 1) > 0 or die "$0: $file: read error\n";
$bytes = unpack("C", $bytes) - 1;
printf("SUSP Entry - %u bytes (0x%X)\n", $bytes+1, $bytes+1) if($debug);
} while $bytes > 0;
$sector_blk++;
seek(FIMG, $iso_pos+$first_sector_blk*$bs+$sector_blk*$bs, SEEK_SET) or die "$0: $file: $!\n";
printf("\ndirectory entry at 0x%X:\n", tell(FIMG)) if($debug);
read(FIMG, $bytes, 1) > 0 or break;
$bytes = unpack("C", $bytes) - 1;
} while $bytes != 0x21 && $bytes != 0;
}
$off_pvd+=$bs;
} while $type != 255;
# Done...
close(FIMG);
exit 0;
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