๐พ Archived View for l-3.space โบ split-keys.gmi captured on 2023-09-08 at 16:02:18. Gemini links have been rewritten to link to archived content
โฌ ๏ธ Previous capture (2021-11-30)
-=-=-=-=-=-=-
Time-stamp: <2020-09-02 14h33 EDT>
This post is part of my Qubes OS content.
This post is about my implementation of data separation in Qubes. We'll see how i've chosen to keep SSH keys separate from the VMs which need them, and fuss about the problem of extending this to passwords.
Qubes allows for some fairly fine-grained control over which piece of software has access what data. In particular, the RPC functionality allows for inserting ``reasonably secure'' user approval in what might otherwise be un-audited data access.
Split-keys is the idea that the keys themselves (SSH, GPG, passwords, ...) should be contained in separate, isolated VM to the software that would otherwise directly access these data, while retaining an access path that requires user approval.
In particular, i'd like a system wherein:
So far i have only implemented SSH key handling, as this is my major use-case. GPG shouldn't be very different from this, but i have yet to look into the details of gpg-agent. Passwords are more problematic, and we'll think about these at the end.
The design of this system necessitates cooperating components across several VMs. These have been broken down by VM-type below.
These VMs will be configured to do most of the heavy lifting for this implementation. The software i have chosen to use is
Tomb is especially nice for our purposes because it has various hooks which we can leverage to auto-load keys and remove them from memory on unlocking and locking the vault, respectively. It also manages bind mounts for us, so we can set up reasonable defaults.
The scripts below function on the following layout of folders in a vault VM.
~ โโโ keys โ โโโ ssh โ โ โโโ appVM-1 โ โ โ โโโ <key 1> โ โ โ ยท โ โ โ ยท โ โ โ ยท โ ยท ยท โโโ <key N> โ ยท ยท โ ยท ยท โ โ โโโ appVM-K โ โ โโโ <key 1> โ โ ยท โ โ ยท โ โ ยท โ โ โโโ <key N> โ โ โ โโโ sockets โ โโโ ssh โ โโโ appVM-1 โ ยท โโโ auth_socket โ ยท โโโ pid โ ยท โ โโโ appVM-K โ โโโ auth_socket โ โโโ pid โโโ <vault name>.tomb โโโ <vault-name>.tomb.key
Everything under sockets is managed by the scripts, and a user only typically interacts with the keys directory by creating keys in sub-directories corresponding to the application VMs and services. When creating SSH keys it's important to give the keys reasonable comments so that the prompt displays something human readable.
Note that the scripts assume that all the keys are passwordless -- there's no reason i can see to set one -- and in fact we overwrite ssh-askpass. You have been warned!
The vault template contains most of the implementation, as there's very little that needs to be configured per vault VM instance.
To begin, lets set up the Qubes RPC handler for a service we'll call SshAgent.
/etc/qubes-rpc/qubes.SshAgent #!/bin/sh echo $QREXEC_REMOTE_DOMAIN > /tmp/qubes-ssh-agent-from if [ -z "$(pgrep socat)" ]; then ssh_socket_file="/home/user/sockets/ssh/$QREXEC_REMOTE_DOMAIN/auth_socket" if [ -f "$ssh_socket_file" ]; then auth_socket="$(cat $ssh_socket_file)" socat - UNIX-CONNECT:"$auth_socket" else return 1 fi else return 1 fi
The idea here is that SshAgent will connect an incoming request to the appropriate socket if there is no other transaction currently happening, and if there is potentially an agent designated to the application VM ($QREXEC_REMOTE_DOMAIN) to receive the request. The rest is book-keeping.
We're going to want to change ssh-askpass too, so that it includes the application VM that made the request.
/usr/bin/ssh-askpass #!/bin/sh from="$(cat /tmp/qubes-ssh-agent-from)" message="Request from: $from. $@" zenity --question --title "Request from $from." --text="$message"
Finally we have to manage ssh-agents. The basic idea is that ~/keys/ssh contains a directory named per allowed application VM, whose contents are all the SSH keys that that application VM has access to. See the above file-system diagram.
Our split-ssh-add script below will scan this structure, and spawn a separate ssh-agent per directory. It will also organise the socket and PID information of these agents in ~/sockets/ssh so that it can later reconnect to them to add more keys, clear keys, or otherwise interact with the SshAgent RPC above.
Note that we have used the `-c' flag so that ssh-agent will confirm each use of a key, by calling our ssh-askpass script above.
/usr/bin/split-ssh-add #!/bin/sh key="$2" dom="$1" start_agent() { echo "Starting agent for "$dom"...\n" eval `ssh-agent -s` dir="/home/user/sockets/ssh/$dom/" mkdir "$dir" echo $SSH_AGENT_PID > "$dir/pid" echo $SSH_AUTH_SOCK > "$dir/auth_socket" } # Ensure that we have an agent for this domain if [ -f "/home/user/sockets/ssh/$dom/pid" -a -f "/home/user/sockets/ssh/$dom/auth_socket" ]; then pid="$(cat /home/user/sockets/ssh/$dom/pid)" socket="$(cat /home/user/sockets/ssh/$dom/auth_socket)" if [ -d "/proc/$pid" ]; then echo "Connecting to running agent...\n" export SSH_AGENT_PID="$pid" export SSH_AUTH_SOCK="$socket" else echo Cleaning up dead agent... rm -rf "/home/user/sockets/ssh/$dom" start_agent fi; else start_agent fi if [ -f "/home/user/keys/ssh/$dom/$key" ]; then ssh-add -c "/home/user/keys/ssh/$dom/$key" echo "\nCurrent keyring:" ssh-add -l else echo Cannot find "$key" for domain "$dom" in ~/keys/ssh/. return 1 fi;
We also want to be able to clear the keys that a particular agent has.
/usr/bin/split-ssh-clear #!/bin/sh for dir in /home/user/sockets/ssh/*; do if [ -d "$dir" ]; then echo "Processing $(basename $dir)" if [ -f "$dir/pid" ]; then pid="$(cat $dir/pid)" if [ -f "$dir/auth_socket" ]; then socket="$(cat $dir/auth_socket)" if [ -d "/proc/$pid" ]; then echo "Connecting to running agent and clearing..." export SSH_AGENT_PID="$pid" export SSH_AUTH_SOCK="$socket" ssh-add -D else rm -rf "$dir" echo "Cleaned up dead agent" fi; else echo "Can't find socket for agent, attempting to kill... " kill -9 $pid [ "$?" = "0" ] && echo "Agent killed!" || echo "Agent was not running!" rm -rf "$dir" echo "Cleaned up" fi fi; echo fi; done
That is about all we can configure globally, the rest of the configuration happens per vault VM instance. For each such instance we're going to set up a Tomb ``crypt'' to handle the encrypted storage of our keys. I have employed the naming scheme vault-<description> for my vault VMs, but you're free to choose your own.
Tomb is a handy piece of software for managing encrypted volumes. We're going to make use of its bind-mount system and exec-hooks to automatically link directories in ~/ to their encrypted counterparts, and to load all keys on unlock.
Follow the on-line (or man page) documentation to set up a small-ish crypt -- 128mb is plenty for our purposes. Be sure to use the --kdf flag for a more secure password derivation scheme (you'll also want a reasonable value of iteration time, i aimed for 3 seconds). The scripts below assume that the tomb file will be called $VMNAME.tomb, that the tomb key file will be called $VMNAME.tomb.key, and that both of these reside in $HOME.
Then, ensure that the directories
exist in the vault VM. With that achieved, ``open the tomb'' and write the following `exec-hooks' file in the mounted tomb.
/media/$(hostname)/exec-hooks #!/bin/sh vault_name="$(hostname)" if [ "$1" = "open" ]; then # Start tray icon if [ -z "$(pidof tomb-gtk-tray)" ]; then nohup tomb-gtk-tray "$vault_name" >/dev/null 2>&1 & fi # Bind directories to /rw/home/user for dir in $(cat "/media/$vault_name/bind"); do if [ -d "/rw/home/user/$dir" -a -d "/media/$vault_name/$dir" ]; then sudo mount -o bind "/media/$vault_name/$dir" "/rw/home/user/$dir" fi done; # Unlock keys if [ -d "$HOME/keys/" ]; then cd "$HOME/keys/" for dir in ssh/*; do if [ -d "$dir" ]; then dom="$(echo $dir | cut -d \/ -f 2-)" for key in $dir/*; do if [ -n "$(file $key | grep 'OpenSSH private key')" ]; then split-ssh-add "$dom" "$(basename $key)" fi done fi done fi else # Dismiss tray icon killall tomb-gtk-tray || true # Unload keys split-ssh-clear # Unmount binds for dir in $(cat "/media/$vault_name/bind"); do if [ -d "/rw/home/user/$dir" -a -d "/media/$vault_name/$dir" ]; then sudo umount "/rw/home/user/$dir" || true fi done fi
Qubes seems to be a little fussy with the way that bind-mounts are handled, and vanilla tomb was not successfully closing the file. To remedy this i added some code on-close code to manually unmount the necessary things.
Set the `binds' file of the tomb to the below.
/media/$(hostname)/exec-hooks sockets sockets keys keys QubesIncoming QubesIncoming
Finally ensure that the directories
all exist (note the difference to the above list!).
The last bit of back-end we need to set up is in dom0. Here we will enable the RPC we've created above, and in so doing choose a whitelist of application VMs and their corresponding vault VMs.
/etc/qubes-rpc/policy/qubes.SshAgent <app-vm> <vault-vm> allow
The final piece of the puzzle is having OpenSSH conduct its business over the Qubes RPC instead of locally. But the way we have things so far this isn't so difficult.
/rw/config/rc.local SSH_VAULT_VM="<vault name here>" if [ "$SSH_VAULT_VM" != "" ]; then export SSH_AUTH_SOCK=/home/user/.SSH_AGENT_$SSH_VAULT_VM rm -f "$SSH_AUTH_SOCK" killall socat sudo -u user /bin/sh -c "umask 177 && exec socat 'UNIX-LISTEN:$SSH_AUTH_SOCK,fork' 'EXEC:qrexec-client-vm $SSH_VAULT_VM qubes.SshAgent'" & fi
~/.bash_profile (or similar) SSH_VAULT_VM="<vault name here>" if [ "$SSH_VAULT_VM" != "" ]; then export SSH_AUTH_SOCK=/home/user/.SSH_AGENT_$SSH_VAULT_VM fi
... and that's it. Everything should Just Work (TM) from this point.
Both of these are solvable by manually recreating the socket on the application VM, however. If anyone works out what's going in, i'd love to hear about it.
Qubes already has an implementation of split-gpg
https://www.qubes-os.org/doc/split-gpg/
I haven't yet looked into this, but hopefully it will prove straightforward to combine this with the tomb setup above and have a uniform interface for vaults.
Passwords, on the other hand, are far more tricky. I can see no easy way to enforce ``access for a single operation'' and so having an RPC to request passwords over clear text is unsatisfactory (something like split-pass). This wouldn't be a bad compromise, but it seems that the better thing to do would involve (potentially hardware) U2F or some such. Despite its name, however, this isn't quite so universally supported. I'd certainly be open to suggestions!
Finally, there's the case of emails. Ideally the email client would run on an application VM, and request all email operations (list, fetch, store, send, ...) through an RPC channel with user approval. That is, i'd love to have my emails, passwords, and everything else live in a vault, but access these through an interface on another VM so that the vault is not internet connected.
I have no real idea how to do this, and it seems incredibly mail back-end sensitive. Perhaps an mbox file somehow accessed over RPC?
As a compromise i wouldn't mind storing my emails on an application VM, but the account information should definitely be in a vault. I believe offlineimap allows embedding arbitrary scripts in its authentication procedure, so something like this should be possible with split-pass (or a bespoke solution).