Encrypted Root Filesystem HOWTO Christophe Devine Revision History Revision v1.3 2005-03-13 Revised by: cd Updated the packages version. Revision v1.2 2004-10-20 Revised by: cd Updated the packages version. Revision v1.1 2003-12-01 Revised by: cd Added support for GRUB. Revision v1.0 2003-09-24 Revised by: cd Initial release, reviewed by LDP. Revision v0.9 2003-09-11 Revised by: cd Updated and converted to DocBook XML. This document explains how to make your personal data secure by encrypting your Linux root filesystem using strong cryptography. This HOWTO is released under the GNU Free Documentation License Version 1.2. ----------------------------------------------------------------------------- Table of Contents 1. Preparing the system 1.1. Setting up the partition layout 1.2. Required packages 1.3. Installing Linux-2.4.29 1.4. Installing Linux-2.6.10 1.5. Installing util-linux-2.12p 2. Creating the encrypted root filesystem 3. Setting up the boot device 3.1. Creating the ramdisk 3.2. Booting from a CD-ROM 3.3. Booting from a HD partition 4. Final steps 5. About this HOWTO 1. Preparing the system 1.1. Setting up the partition layout Your hard disk (hda) should contain at least three partitions:   *  hda1: this small unencrypted partition will ask for a password in order to mount the encrypted root filesystem.   *  hda2: this partition will contain your encrypted root filesystem; make sure it is large enough.   *  hda3: this partition holds the current GNU/Linux system. At this point, both hda1 and hda2 are unused. hda3 is where your Linux distribution is currently installed; /usr and /boot must not be separated from this partition. Here's an example of what your partition layout might look like: # fdisk -l /dev/hda Disk /dev/hda: 255 heads, 63 sectors, 2432 cylinders Units = cylinders of 16065 * 512 bytes Device Boot Start End Blocks Id System /dev/hda1 1 1 8001 83 Linux /dev/hda2 2 263 2104515 83 Linux /dev/hda3 264 525 2104515 83 Linux /dev/hda4 526 2047 12225465 83 Linux ----------------------------------------------------------------------------- 1.2. Required packages If you use Debian, the following packages are mandatory: apt-get install gcc make libncurses5-dev patch bzip2 wget To make copy & paste easier, you should also install: apt-get install lynx gpm ----------------------------------------------------------------------------- 1.3. Installing Linux-2.4.29 There are two main projects which add loopback encryption support in the kernel: cryptoloop and loop-AES. This howto is based on loop-AES, since it features an extremely fast and highly optimized implementation of Rijndael in assembly language, and therefore provides maximum performance if you have an IA-32 (x86) CPU. Besides, there are some [http://groups.google.com/groups? selm=1emrG-1Ck-25%40gated-at.bofh.it] security concerns about cryptoloop. First of all, download and unpack the loop-AES package: cd /usr/src wget http://loop-aes.sourceforge.net/loop-AES/loop-AES-v3.0b.tar.bz2 tar -xvjf loop-AES-v3.0b.tar.bz2 Then you must download and patch the kernel source: wget http://ftp.kernel.org/pub/linux/kernel/v2.4/linux-2.4.29.tar.bz2 tar -xvjf linux-2.4.29.tar.bz2 cd linux-2.4.29 rm include/linux/loop.h drivers/block/loop.c patch -Np1 -i ../loop-AES-v3.0b/kernel-2.4.28.diff Setup the keyboard map: dumpkeys | loadkeys -m - > drivers/char/defkeymap.c Next, configure your kernel; make sure the following options are set: make menuconfig Block devices ---> <*> Loopback device support [*] AES encrypted loop device support (NEW) <*> RAM disk support (4096) Default RAM disk size (NEW) [*] Initial RAM disk (initrd) support File systems ---> <*> Ext3 journalling file system support <*> Second extended fs support (important note: do not enable /dev file system support) Compile the kernel and install it: make dep bzImage make modules modules_install cp arch/i386/boot/bzImage /boot/vmlinuz If grub is your bootloader, update /boot/grub/menu.lst or /boot/grub/ grub.conf: cat > /boot/grub/menu.lst << EOF default 0 timeout 10 color green/black light-green/black title Linux root (hd0,2) kernel /boot/vmlinuz ro root=/dev/hda3 EOF Otherwise, update /etc/lilo.conf and run lilo: cat > /etc/lilo.conf << EOF lba32 boot=/dev/hda prompt timeout=60 image=/boot/vmlinuz label=Linux read-only root=/dev/hda3 EOF lilo You may now restart the system. ----------------------------------------------------------------------------- 1.4. Installing Linux-2.6.10 Proceed as described in the previous section, using loop-aes' kernel-2.6.10.diff patch instead, and make sure cryptoloop support is not activated. Note that modules support require that you have the module-init-tools package installed. ----------------------------------------------------------------------------- 1.5. Installing util-linux-2.12p The losetup program, which is part of the util-linux package, must be patched and recompiled in order to add strong cryptography support. Download, unpack and patch util-linux: cd /usr/src wget http://ftp.kernel.org/pub/linux/utils/util-linux/util-linux-2.12p.tar.bz2 tar -xvjf util-linux-2.12p.tar.bz2 cd util-linux-2.12p patch -Np1 -i ../loop-AES-v3.0b/util-linux-2.12p.diff To use passwords that are less than 20 characters, enter: CFLAGS="-O2 -DLOOP_PASSWORD_MIN_LENGTH=8"; export CFLAGS Security is certainly your major concern. For this reason, please do not enable passwords shorter than 20 characters. Data privacy is not free, one has to 'pay' in form of long passwords. Compile losetup and install it as root: ./configure && make lib mount mv -f /sbin/losetup /sbin/losetup~ rm -f /usr/share/man/man8/losetup.8* cd mount gzip losetup.8 cp losetup /sbin cp losetup.8.gz /usr/share/man/man8/ chattr +i /sbin/losetup ----------------------------------------------------------------------------- 2. Creating the encrypted root filesystem Fill the target partition with random data: shred -n 1 -v /dev/hda2 Setup the encrypted loopback device: losetup -e aes256 -S xxxxxx /dev/loop0 /dev/hda2 To prevent optimized dictionary attacks, it is recommended to add the -S xxxxxx option, where "xxxxxx" is your randomly chosen seed (for example, you might choose "gPk4lA"). Write down your seed on a piece of paper so that you don't loose it afterwards. Also, in order to avoid boot-time problems with the keyboard map, do not use non-ASCII characters (accents, etc.) in your password. The [http://www.diceware.com/] Diceware site offers a simple way to create strong, yet easy to remember, passphrases. Now create the ext3 filesystem: mke2fs -j /dev/loop0 Check that the password you entered is correct: losetup -d /dev/loop0 losetup -e aes256 -S xxxxxx /dev/loop0 /dev/hda2 mkdir /mnt/efs mount /dev/loop0 /mnt/efs You can compare the encrypted and unencrypted data: xxd /dev/hda2 | less xxd /dev/loop0 | less It's time to install your encrypted Linux system. If you use a GNU/Linux distribution (such as Debian, Slackware, Gentoo, Mandrake, RedHat/Fedora, SuSE, etc.), run the following command: cp -avx / /mnt/efs If you use the Linux From Scratch book, proceed as described in the manual, with the modifications below:   * Chapter 6 - Installing util-linux: Apply the loop-AES patch after unpacking the sources.   * Chapter 8 - Making the LFS system bootable: Refer to the next section (Setting up the boot device). ----------------------------------------------------------------------------- 3. Setting up the boot device 3.1. Creating the ramdisk To begin with, chroot inside the encrypted partition and create the boot device mount point: chroot /mnt/efs mkdir /loader Then, create the initial ramdisk (initrd), which will be needed afterwards: cd dd if=/dev/zero of=initrd bs=1k count=4096 mke2fs -F initrd mkdir ramdisk mount -o loop initrd ramdisk If you're using grsecurity, you may get a "Permission denied" error message; in this case you'll have to run the mount command outside chroot. Create the filesystem hierarchy and copy the required files in it: mkdir ramdisk/{bin,dev,lib,mnt,sbin} cp /bin/{bash,mount} ramdisk/bin/ ln -s bash ramdisk/bin/sh mknod -m 600 ramdisk/dev/console c 5 1 mknod -m 600 ramdisk/dev/hda2 b 3 2 mknod -m 600 ramdisk/dev/loop0 b 7 0 cp /lib/{ld-linux.so.2,libc.so.6,libdl.so.2} ramdisk/lib/ cp /lib/{libncurses.so.5,libtermcap.so.2} ramdisk/lib/ cp /sbin/{losetup,pivot_root} ramdisk/sbin/ It's ok if you see a message like "/lib/libncurses.so.5: No such file or directory", or "/lib/libtermcap.so.2: No such file or directory"; bash only requires one of these two libraries. You can check which one is actually required with: ldd /bin/bash Compile the sleep program, which will prevent the password prompt being flooded by kernel messages (such as usb devices being registered). cat > sleep.c << "EOF" #include #include int main( int argc, char *argv[] ) { if( argc == 2 ) sleep( atoi( argv[1] ) ); return( 0 ); } EOF gcc -s sleep.c -o ramdisk/bin/sleep rm sleep.c Create the init script: cat > ramdisk/sbin/init << "EOF" #!/bin/sh /bin/sleep 3 echo -n "Enter seed value: " read SEED /sbin/losetup -e aes256 -S $SEED /dev/loop0 /dev/hda2 /bin/mount -r -n -t ext3 /dev/loop0 /mnt while [ $? -ne 0 ] do /sbin/losetup -d /dev/loop0 /sbin/losetup -e aes256 -S $SEED /dev/loop0 /dev/hda2 /bin/mount -r -n -t ext3 /dev/loop0 /mnt done cd /mnt /sbin/pivot_root . loader exec /usr/sbin/chroot . /sbin/init EOF chmod 755 ramdisk/sbin/init Umount the loopback device and compress the initrd: umount -d ramdisk rmdir ramdisk gzip initrd mv initrd.gz /boot/ ----------------------------------------------------------------------------- 3.2. Booting from a CD-ROM I strongly advise you to start your system with a read-only media, such as a bootable CD-ROM. Download and unpack syslinux: wget http://ftp.kernel.org/pub/linux/utils/boot/syslinux/syslinux-3.07.tar.bz2 tar -xvjf syslinux-3.07.tar.bz2 Configure isolinux: mkdir bootcd cp /boot/{vmlinuz,initrd.gz} syslinux-3.07/isolinux.bin bootcd echo "DEFAULT /vmlinuz initrd=initrd.gz ro root=/dev/ram0" \ > bootcd/isolinux.cfg Create and burn the bootable cd-rom iso image: mkisofs -o bootcd.iso -b isolinux.bin -c boot.cat \ -no-emul-boot -boot-load-size 4 -boot-info-table \ -J -hide-rr-moved -R bootcd/ cdrecord -dev 0,0,0 -speed 4 -v bootcd.iso rm -rf bootcd{,.iso} ----------------------------------------------------------------------------- 3.3. Booting from a HD partition The boot partition can come in handy if you happen to lose your bootable CD. Remember that hda1 is a writable media and is thus insecure; use it only in case of emergency! Create and mount the ext2 filesystem: dd if=/dev/zero of=/dev/hda1 bs=8192 mke2fs /dev/hda1 mount /dev/hda1 /loader Copy the kernel and the initial ramdisk: cp /boot/{vmlinuz,initrd.gz} /loader If you use grub: mkdir /loader/boot cp -av /boot/grub /loader/boot/ cat > /loader/boot/grub/menu.lst << EOF default 0 timeout 10 color green/black light-green/black title Linux root (hd0,0) kernel /vmlinuz ro root=/dev/ram0 initrd /initrd.gz EOF grub-install --root-directory=/loader /dev/hda umount /loader If you use lilo: mkdir /loader/{boot,dev,etc} cp /boot/boot.b /loader/boot/ mknod -m 600 /loader/dev/hda b 3 0 mknod -m 600 /loader/dev/hda1 b 3 1 mknod -m 600 /loader/dev/hda2 b 3 2 mknod -m 600 /loader/dev/hda3 b 3 3 mknod -m 600 /loader/dev/hda4 b 3 4 mknod -m 600 /loader/dev/ram0 b 1 0 cat > /loader/etc/lilo.conf << EOF lba32 boot=/dev/hda prompt timeout=60 image=/vmlinuz label=Linux initrd=/initrd.gz read-only root=/dev/ram0 EOF lilo -r /loader umount /loader ----------------------------------------------------------------------------- 4. Final steps Still inside chroot, modify /etc/fstab so that it contains: /dev/loop0 / ext3 defaults 0 1 Delete /etc/mtab and exit from chroot. Finally, run "umount -d /mnt/efs" and reboot. If something goes wrong, you can still boot your unencrypted partition by entering "Linux root=/dev/hda3" at the LILO: prompt. If everything went well, you can now re-partition your disk and encrypt hda3 as well as hda4. In the following scripts, we assume that hda3 will hold the swap device and hda4 will contain /home; you should initialize both partitions first: shred -n 1 -v /dev/hda3 shred -n 1 -v /dev/hda4 losetup -e aes256 -S xxxxxx /dev/loop1 /dev/hda3 losetup -e aes256 -S xxxxxx /dev/loop2 /dev/hda4 mkswap /dev/loop1 mke2fs -j /dev/loop2 Then create a script in the system startup directory and update fstab: cat > /etc/init.d/loop << "EOF" #!/bin/sh if [ "`/usr/bin/md5sum /dev/hda1`" != \ "5671cebdb3bed87c3b3c345f0101d016 /dev/hda1" ] then echo -n "WARNING! hda1 integrity verification FAILED - press enter." read fi echo "1st password chosen above" | \ /sbin/losetup -p 0 -e aes256 -S xxxxxx /dev/loop1 /dev/hda3 echo "2nd password chosen above" | \ /sbin/losetup -p 0 -e aes256 -S xxxxxx /dev/loop2 /dev/hda4 /sbin/swapon /dev/loop1 for i in `seq 0 63` do echo -n -e "\33[10;10]\33[11;10]" > /dev/tty$i done EOF chmod 700 /etc/init.d/loop ln -s ../init.d/loop /etc/rcS.d/S00loop vi /etc/fstab ... /dev/loop2 /home ext3 defaults 0 2 ----------------------------------------------------------------------------- 5. About this HOWTO The Encrypted Root Filesystem HOWTO was first written in november 2002 for the [http://www.linuxfromscratch.org/lfs/news.html] Linux From Scratch project. I'd like to thank the many people who have since contributed to this document (in reverse chronological order): Micha Borrmann, Dennis Lemckert, Oleg Vyushin, Ellen Bokhorst, Daczi László, Gaetano Zappulla, Guillaume Lehmann, Claude Thomassin, Jean-Philippe Guérard, Luc Vo Van, Jacobus Brink, Ernesto Pérez Estévez, Matthew Ploessel, Mike Lorek, Lars Bungum, Michael Shields, Julien Perrot, Grant Stephenson, Cary W. Gilmer, James Howells, Pedro Baez, Josh Purinton, Jari Ruusu and Zibeli Aton. This HOWTO has been translated in various languages:   * [http://www.traduc.org/docs/HOWTO/lecture/ Encrypted-Root-Filesystem-HOWTO.html] French   * [http://www.linux.it/~gaetano/erfs/] Italian   * [http://tldp.fsf.hu/HOWTO/Encrypted-Root-Filesystem-HOWTO-hu/] Hungarian   * [http://doc.nl.linux.org/HOWTO/Encrypted-Root-Filesystem-HOWTO-NL/ article.html] Dutch Please send any comment to [http://www.cr0.net:8040/about/] Christophe Devine.