Get things from one computer to another, safely.
This package provides a library and a command-line tool named
wormhole
, which makes it possible to get arbitrary-sized files and
directories (or short pieces of text) from one computer to another. The
two endpoints are identified by using identical “wormhole codes”: in
general, the sending machine generates and displays the code, which must
then be typed into the receiving machine.
The codes are short and human-pronounceable, using a phonetically-distinct wordlist. The receiving side offers tab-completion on the codewords, so usually only a few characters must be typed. Wormhole codes are single-use and do not need to be memorized.
As of now (2023) the magic-wormhole protocol has several client implementations; see the “Ecosystem” section.
Sender:
% wormhole send README.md Sending 7924 byte file named 'README.md' On the other computer, please run: wormhole receive Wormhole code is: 7-crossover-clockwork Sending (<-10.0.1.43:58988).. 100%|=========================| 7.92K/7.92K [00:00<00:00, 6.02MB/s] File sent.. waiting for confirmation Confirmation received. Transfer complete.
Receiver:
% wormhole receive Enter receive wormhole code: 7-crossover-clockwork Receiving file (7924 bytes) into: README.md ok? (y/n): y Receiving (->tcp:10.0.1.43:58986).. 100%|===========================| 7.92K/7.92K [00:00<00:00, 120KB/s] Received file written to README.md
The easiest way to install magic-wormhole is to use a packaged version from your operating system. If there is none, or you want to participate in development, you can install from source.
Install Homebrew, then run
brew install magic-wormhole
.
Magic-wormhole is available with apt
in Debian 9 “stretch”, Ubuntu
17.04 “zesty”, and later versions:
$ sudo apt install magic-wormhole
Note: magic-wormhole was removed from Fedora starting in Fedora 37. So this command will only work on Fedora 36 and earlier.
$ sudo dnf install magic-wormhole
$ sudo zypper install python-magic-wormhole
Many linux distributions (including Ubuntu) can install “Snap” packages. Magic-wormhole is available through a third-party package (published by the “snapcrafters” group):
$ sudo snap install wormhole
$ choco install magic-wormhole
The binaries for Windows are provided from this project: https://github.com/aquacash5/magic-wormhole-exe
Magic-wormhole is a Python package, and can be installed in the usual
ways. The basic idea is to do pip install magic-wormhole
, however to
avoid modifying the system’s python libraries, you probably want to put
it into a “user” environment (putting the wormhole
executable in
~/.local/bin/wormhole
) like this:
pip install --user magic-wormhole
or put it into a virtualenv, like this:
virtualenv venv source venv/bin/activate pip install magic-wormhole
You can then run venv/bin/wormhole
without first activating the
virtualenv, so e.g. you could make a symlink from ~/bin/wormhole
to
.../path/to/venv/bin/wormhole
, and then plain wormhole send
will
find it on your $PATH
.
You probably don’t want to use sudo
when you run pip
. This
tends to create
conflicts with
the system python libraries.
On OS X, you may need to pre-install pip
, and run
$ xcode-select --install
to get GCC, which is needed to compile the
libsodium
cryptography library during the installation process.
On Debian/Ubuntu systems, you may need to install some support libraries first:
$ sudo apt-get install python-pip build-essential python-dev libffi-dev libssl-dev
On Linux, if you get errors like
fatal error: sodium.h: No such file or directory
, either use
SODIUM_INSTALL=bundled pip install magic-wormhole
, or try installing
the libsodium-dev
/ libsodium-devel
package. These work around a
bug in pynacl which gets confused when the libsodium runtime is
installed (e.g. libsodium13
) but not the development package.
On Windows, python2 may work better than python3. On older systems,
$ pip install --upgrade pip
may be necessary to get a version that
can compile all the dependencies. Most of the dependencies are published
as binary wheels, but in case your system is unable to find these, it
will have to compile them, for which Microsoft Visual C++
9.0
may be required.
- Moving a file to a friend’s machine, when the humans can speak to each other (directly) but the computers cannot
- Delivering a properly-random password to a new user via the phone
- Supplying an SSH public key for future login use
Copying files onto a USB stick requires physical proximity, and is uncomfortable for transferring long-term secrets because flash memory is hard to erase. Copying files with ssh/scp is fine, but requires previous arrangements and an account on the target machine, and how do you bootstrap the account? Copying files through email first requires transcribing an email address in the opposite direction, and is even worse for secrets, because email is unencrypted. Copying files through encrypted email requires bootstrapping a GPG key as well as an email address. Copying files through Dropbox is not secure against the Dropbox server and results in a large URL that must be transcribed. Using a URL shortener adds an extra step, reveals the full URL to the shortening service, and leaves a short URL that can be guessed by outsiders.
Many common use cases start with a human-mediated communication channel, such as IRC, IM, email, a phone call, or a face-to-face conversation. Some of these are basically secret, or are “secret enough” to last until the code is delivered and used. If this does not feel strong enough, users can turn on additional verification that doesn’t depend upon the secrecy of the channel.
The notion of a “magic wormhole” comes from the image of two distant wizards speaking the same enchanted phrase at the same time, and causing a mystical connection to pop into existence between them. The wizards then throw books into the wormhole and they fall out the other side. Transferring files securely should be that easy.
The wormhole
tool uses PAKE “Password-Authenticated Key Exchange”, a
family of cryptographic algorithms that uses a short low-entropy
password to establish a strong high-entropy shared key. This key can
then be used to encrypt data. wormhole
uses the SPAKE2 algorithm,
due to Abdalla and
Pointcheval1.
PAKE effectively trades off interaction against offline attacks. The only way for a network attacker to learn the shared key is to perform a man-in-the-middle attack during the initial connection attempt, and to correctly guess the code being used by both sides. Their chance of doing this is inversely proportional to the entropy of the wormhole code. The default is to use a 16-bit code (use –code-length= to change this), so for each use of the tool, an attacker gets a 1-in-65536 chance of success. As such, users can expect to see many error messages before the attacker has a reasonable chance of success.
The program does not have any built-in timeouts, however it is expected that both clients will be run within an hour or so of each other. This makes the tool most useful for people who are having a real-time conversation already, and want to graduate to a secure connection. Both clients must be left running until the transfer has finished.
The wormhole library requires a “Mailbox Server” (also known as the
“Rendezvous Server”): a simple WebSocket-based relay that delivers
messages from one client to another. This allows the wormhole codes to
omit IP addresses and port numbers. The URL of a public server is baked
into the library for use as a default, and will be freely available
until volume or abuse makes it infeasible to support. Applications which
desire more reliability can easily run their own relay and configure
their clients to use it instead. Code for the Mailbox Server is in a
separate package named magic-wormhole-mailbox-server
and has
documentation
here.
Both clients must use the same mailbox server. The default can be
overridden with the --relay-url
option.
The file-transfer commands also use a “Transit Relay”, which is another
simple server that glues together two inbound TCP connections and
transfers data on each to the other (the moral equivalent of a TURN
server). The wormhole send
file mode shares the IP addresses of each
client with the other (inside the encrypted message), and both clients
first attempt to connect directly. If this fails, they fall back to
using the transit relay. As before, the host/port of a public server is
baked into the library, and should be sufficient to handle moderate
traffic. Code for the Transit Relay is provided a separate package named
magic-wormhole-transit-relay
with instructions
here.
The clients exchange transit relay information during connection
negotiation, so they can be configured to use different ones without
problems. Use the --transit-helper
option to override the default.
The protocol includes provisions to deliver notices and error messages to clients: if either relay must be shut down, these channels will be used to provide information about alternatives.
wormhole send [args] --text TEXT
wormhole send [args] FILENAME
wormhole send [args] DIRNAME
wormhole receive [args]
Both commands accept additional arguments to influence their behavior:
--code-length WORDS
: use more or fewer than 2 words for the code--verify
: print (and ask user to compare) extra verification string
Wormhole codes will tab-complete for receivers out-of-the-box.
If you desire shell tab-completion on sub-commands, we include generated
files from
Click
for Bash, Zsh and Fish shells in
wormhole_completion.bash
(or .zsh
, .fish
). Put this file in your favourite location and
add a line like source ~/wormhole_completion.bash
to ~/.bashrc
(or similar for zsh
and fish
shells).
The wormhole
module makes it possible for other applications to use
these code-protected channels. This includes Twisted support, and (in
the future) will include blocking/synchronous support too. See
docs/api.md for details.
The file-transfer tools use a second module named wormhole.transit
,
which provides an encrypted record-pipe. It knows how to use the Transit
Relay as well as direct connections, and attempts them all in parallel.
TransitSender
and TransitReceiver
are distinct, although once
the connection is established, data can flow in either direction. All
data is encrypted (using nacl/libsodium “secretbox”) using a key derived
from the PAKE phase. See src/wormhole/cli/cmd_send.py
for examples.
- Bugs and patches at the GitHub project page.
- Chat via IRC: #magic-wormhole on irc.libera.chat
- Chat via Matrix: #magic-wormhole on matrix.org
To set up Magic Wormhole for development, you will first need to install virtualenv.
Once you’ve done that, git clone
the repo, cd
into the root of
the repository, and run:
virtualenv venv source venv/bin/activate pip install --upgrade pip setuptools
Now your virtualenv has been activated. You’ll want to re-run
source venv/bin/activate
for every new terminal session you open.
To install Magic Wormhole and its development dependencies into your virtualenv, run:
pip install -e .[dev]
If you are using zsh, such as on macOS Catalina or later, you will have
to run pip install -e .'[dev]'
instead.
While the virtualenv is active, running wormhole
will get you the
development version.
Within your virtualenv, the command-line program trial
will run the
test suite:
trial wormhole
This tests the entire wormhole
package. If you want to run only the
tests for a specific module, or even just a specific test, you can
specify it instead via Python’s standard dotted import notation, e.g.:
trial wormhole.test.test_cli.PregeneratedCode.test_file_tor
Developers can also just clone the source tree and run tox
to run
the unit tests on all supported (and installed) versions of python: 2.7,
3.7 and 3.8.
Every so often, you might get a traceback with the following kind of error:
pkg_resources.DistributionNotFound: The 'magic-wormhole==0.9.1-268.g66e0d86.dirty' distribution was not found and is required by the application
If this happens, run pip install -e .[dev]
again.
Relevant xkcd :-)
This library is released under the MIT license, see LICENSE for details.
This library is compatible with python2.7, 3.7 and 3.8 .