2019-04-03 15:14:27 +02:00
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---
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title: Advanced setup
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2022-06-20 10:16:21 +02:00
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sort_key: D
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2019-04-03 15:14:27 +02:00
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---
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2019-04-03 14:04:56 +02:00
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This document describes how Clef can be used in a more secure manner than executing it from your everyday laptop,
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in order to ensure that the keys remain safe in the event that your computer should get compromised.
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## Qubes OS
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### Background
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The Qubes operating system is based around virtual machines (qubes), where a set of virtual machines are configured, typically for
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different purposes such as:
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- personal
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- Your personal email, browsing etc
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- work
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- Work email etc
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- vault
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- a VM without network access, where gpg-keys and/or keepass credentials are stored.
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A couple of dedicated virtual machines handle externalities:
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- sys-net provides networking to all other (network-enabled) machines
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- sys-firewall handles firewall rules
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- sys-usb handles USB devices, and can map usb-devices to certain qubes.
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The goal of this document is to describe how we can set up clef to provide secure transaction
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signing from a `vault` vm, to another networked qube which runs Dapps.
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### Setup
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There are two ways that this can be achieved: integrated via Qubes or integrated via networking.
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#### 1. Qubes Integrated
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2020-07-08 10:53:14 +01:00
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Qubes provides a facility for inter-qubes communication via `qrexec`. A qube can request to make a cross-qube RPC request
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to another qube. The OS then asks the user if the call is permitted.
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2019-10-01 10:40:09 +02:00
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![Example](qrexec-example.png)
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A policy-file can be created to allow such interaction. On the `target` domain, a service is invoked which can read the
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`stdin` from the `client` qube.
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This is how [Split GPG](https://www.qubes-os.org/doc/split-gpg/) is implemented. We can set up Clef the same way:
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##### Server
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2019-10-01 10:40:09 +02:00
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![Clef via qrexec](clef_qubes_qrexec.png)
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2019-04-03 14:04:56 +02:00
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2020-07-08 10:53:14 +01:00
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On the `target` qubes, we need to define the RPC service.
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2019-10-01 10:40:09 +02:00
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[qubes.Clefsign](qubes.Clefsign):
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```bash
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#!/bin/bash
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SIGNER_BIN="/home/user/tools/clef/clef"
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SIGNER_CMD="/home/user/tools/gtksigner/gtkui.py -s $SIGNER_BIN"
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# Start clef if not already started
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if [ ! -S /home/user/.clef/clef.ipc ]; then
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$SIGNER_CMD &
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sleep 1
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fi
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# Should be started by now
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if [ -S /home/user/.clef/clef.ipc ]; then
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# Post incoming request to HTTP channel
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curl -H "Content-Type: application/json" -X POST -d @- http://localhost:8550 2>/dev/null
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fi
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```
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This RPC service is not complete (see notes about HTTP headers below), but works as a proof-of-concept.
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It will forward the data received on `stdin` (forwarded by the OS) to Clef's HTTP channel.
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It would have been possible to send data directly to the `/home/user/.clef/.clef.ipc`
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socket via e.g `nc -U /home/user/.clef/clef.ipc`, but the reason for sending the request
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data over `HTTP` instead of `IPC` is that we want the ability to forward `HTTP` headers.
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To enable the service:
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``` bash
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sudo cp qubes.Clefsign /etc/qubes-rpc/
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sudo chmod +x /etc/qubes-rpc/ qubes.Clefsign
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```
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This setup uses [gtksigner](https://github.com/holiman/gtksigner), which is a very minimal GTK-based UI that works well
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with minimal requirements.
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##### Client
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On the `client` qube, we need to create a listener which will receive the request from the Dapp, and proxy it.
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2019-10-01 10:40:09 +02:00
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[qubes-client.py](qubes-client.py):
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```python
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"""
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This implements a dispatcher which listens to localhost:8550, and proxies
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requests via qrexec to the service qubes.EthSign on a target domain
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"""
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import http.server
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import socketserver,subprocess
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PORT=8550
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TARGET_DOMAIN= 'debian-work'
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class Dispatcher(http.server.BaseHTTPRequestHandler):
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def do_POST(self):
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post_data = self.rfile.read(int(self.headers['Content-Length']))
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p = subprocess.Popen(['/usr/bin/qrexec-client-vm',TARGET_DOMAIN,'qubes.Clefsign'],stdin=subprocess.PIPE, stdout=subprocess.PIPE)
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output = p.communicate(post_data)[0]
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self.wfile.write(output)
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with socketserver.TCPServer(("",PORT), Dispatcher) as httpd:
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print("Serving at port", PORT)
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httpd.serve_forever()
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```
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#### Testing
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To test the flow, if we have set up `debian-work` as the `target`, we can do
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```bash
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$ cat newaccnt.json
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{ "id": 0, "jsonrpc": "2.0","method": "account_new","params": []}
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$ cat newaccnt.json| qrexec-client-vm debian-work qubes.Clefsign
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```
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2020-07-08 10:53:14 +01:00
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A dialog should pop up first to allow the IPC call:
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2019-10-01 10:40:09 +02:00
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![one](qubes_newaccount-1.png)
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2020-07-08 10:53:14 +01:00
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Followed by a GTK-dialog to approve the operation:
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2019-10-01 10:40:09 +02:00
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![two](qubes_newaccount-2.png)
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To test the full flow, we use the client wrapper. Start it on the `client` qube:
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```
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[user@work qubes]$ python3 qubes-client.py
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```
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Make the request over http (`client` qube):
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```
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[user@work clef]$ cat newaccnt.json | curl -X POST -d @- http://localhost:8550
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```
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And it should show the same popups again.
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##### Pros and cons
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The benefits of this setup are:
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- This is the qubes-os intended model for inter-qube communication,
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- and thus benefits from qubes-os dialogs and policies for user approval
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However, it comes with a couple of drawbacks:
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- The `qubes-gpg-client` must forward the http request via RPC to the `target` qube. When doing so, the proxy
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will either drop important headers, or replace them.
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- The `Host` header is most likely `localhost`
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- The `Origin` header must be forwarded
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- Information about the remote ip must be added as a `X-Forwarded-For`. However, Clef cannot always trust an `XFF` header,
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since malicious clients may lie about `XFF` in order to fool the http server into believing it comes from another address.
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- Even with a policy in place to allow RPC calls between `caller` and `target`, there will be several popups:
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- One qubes-specific where the user specifies the `target` vm
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- One clef-specific to approve the transaction
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#### 2. Network integrated
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The second way to set up Clef on a qubes system is to allow networking, and have Clef listen to a port which is accessible
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2020-07-08 10:53:14 +01:00
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from other qubes.
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2019-04-03 14:04:56 +02:00
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2019-10-01 10:40:09 +02:00
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![Clef via http](clef_qubes_http.png)
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2019-04-03 14:04:56 +02:00
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## USBArmory
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2020-07-08 10:53:14 +01:00
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The [USB armory](https://inversepath.com/usbarmory) is an open source hardware design with an 800 MHz ARM processor. It is a pocket-size
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computer. When inserted into a laptop, it identifies itself as a USB network interface, basically adding another network
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to your computer. Over this new network interface, you can SSH into the device.
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Running Clef off a USB armory means that you can use the armory as a very versatile offline computer, which only
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ever connects to a local network between your computer and the device itself.
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2020-07-08 10:53:14 +01:00
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Needless to say, while this model should be fairly secure against remote attacks, an attacker with physical access
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to the USB Armory would trivially be able to extract the contents of the device filesystem.
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