# Prerequisites for using `derivepassphrase vault` with an SSH key Using `derivepassphrase vault` with an SSH key requires: 1. [a running SSH agent](#ssh-agent), 2. [a Python installation that can talk to the SSH agent](#python-support), and 3. [a supported SSH key.](#ssh-key) ### A running SSH agent { #ssh-agent } SSH agents are usually packaged as part of SSH client distributions. `ssh-agent` from [OpenSSH][] and Pageant from [PuTTY][] are known to work. `gpg-agent` (v2) from [GnuPG][] is also known to work, but comes with caveats; see notes below. If in doubt, we recommend OpenSSH because it is the de-facto canonical SSH agent implementation. !!! note "Agent-specific features" * OpenSSH's `ssh-agent` supports limiting the time the agent holds the key in memory ("key lifetime"). We recommend its usage. * `ssh-agent` and GnuPG's `gpg-agent` support requiring confirmation upon each use for a specific key. We recommend its usage as well.
!!! note "Other agent-specific notes" === "GnuPG/`gpg-agent`" * `gpg-agent` v2.0 and later uses a *persistent* database of known keys, SSH or otherwise. "Adding" a key to the agent actually means *importing* it, and requires choosing an "import passphrase" to protect the key on disk, in the persistent database. `gpg-agent` will cache the import passphrase in memory, and if that cache entry expires, then the *import passphrase* must be provided to unlock the key. * The GnuPG distribution does not contain tools to generate native SSH keys or interactively add keys to a running `gpg-agent`, because its purpose is to expose keys in a different format (OpenPGP) to other (agent-compatible) SSH clients. A third-party tool (such as a full SSH client distribution) is necessary to load/import native SSH keys into `gpg-agent`. * As a design consequence of the persistent database, `gpg-agent` always lists all known SSH keys as available in the agent. It is impossible to remove an SSH key from `gpg-agent` using standard SSH agent operations. * `gpg-agent` does not advertise its communication socket by default, contrary to other SSH agents, so it must be manually advertised: ~~~~ console $ SSH_AUTH_SOCK="$(gpgconf --list-dirs agent-ssh-socket)" $ export SSH_AUTH_SOCK ~~~~
### A Python installation that can talk to the SSH agent { #python-support } !!! bug "Windows is currently *not* supported" → Further details: [Issue `the-13th-letter/derivepassphrase#13`: Support PuTTY/Pageant on Windows][ISSUE_WINDOWS_SUPPORT] The two major SSH agents on Windows (PuTTY/Pageant and OpenSSH) use Windows named pipes for communication, and Python on Windows does not inherently support named pipes. Since no comprehensive third-party Python modules to interface with named pipes appear to exist, teaching `derivepassphrase` to use Windows named pipes will require us developers to write a custom low-level C module specific to this application---an unrealistic task if we lack both technical know-how for the named pipe API as well as Windows hardware to test any potential implementation on. On non-Windows operating systems, the SSH agent is expected to advertise its communication socket via the `SSH_AUTH_SOCK` environment variable, which is common procedure. Therefore, [your Python installation must support UNIX domain sockets][socket.AF_UNIX]. ### A supported SSH key { #ssh-key } For an SSH key to be usable by `derivepassphrase`, the SSH agent must always generate the same signature for the same input, i.e. the signature must be deterministic for this key type. Commonly used SSH key types include [RSA][], [DSA][], [ECDSA][], [Ed25519][] and [Ed448][]. [RSA]: https://en.wikipedia.org/wiki/RSA_(cryptosystem) [DSA]: https://en.wikipedia.org/wiki/Digital_Signature_Algorithm [ECDSA]: https://en.wikipedia.org/wiki/Elliptic_Curve_Digital_Signature_Algorithm [Ed25519]: https://en.wikipedia.org/wiki/EdDSA#Ed25519 [Ed448]: https://en.wikipedia.org/wiki/EdDSA#Ed448 * RSA, Ed25519 and Ed448 signatures are deterministic by definition. Thus RSA, Ed25519 and Ed448 keys are supported under any SSH agent that implements them. * DSA and ECDSA signatures require choosing a value specific to each signature (a "cryptographic nonce"), which must be unpredictable. Typical DSA/ECDSA implementations therefore generate a suitably large random number as the nonce. This makes signatures non-deterministic, and thus unsuitable for `derivepassphrase`. ??? info "Exception: PuTTY/Pageant and RFC 6979" [RFC 6979][] specifies a method to *calculate* the nonce from the DSA/ECDSA key and the message to be signed. DSA/ECDSA signatures from SSH agents implementing RFC 6979 are therefore deterministic, and thus *also* suitable for `derivepassphrase`. Pageant 0.81 implements RFC 6979. !!! warning "Warning: Pageant < 0.81" Pageant 0.80 and earlier uses a different, homegrown method to calculate the nonce deterministically. Those versions are *also* prinicipally suitable for use with `derivepassphrase`, but **they generate different signatures -- and different derived passphrases -- than Pageant 0.81 and later**. ??? info "What SSH key type do I have?" If, according to your SSH agent, your key's type… * …ends with `-cert-v01@openssh.com`, then, for the purposes of this list, ignore the `-cert-v01@openssh.com` suffix. * …is `dsa` or `ssh-dss`, or is `dsa` followed by a number, then your key type is **DSA**. * …is `rsa` or `ssh-rsa`, or is `rsa` followed by a number, then your key type is **RSA**. * …is `ecdsa` followed by a number, or is `ecdsa-sha2-nistp` followed by a number, then your key type is **ECDSA**. * …is `ssh-ed25519`, then your key type is **Ed25519**. * …is `ssh-ed448`, then your key type is **Ed448**. If you do not yet have a (supported) SSH key, we recommend Ed25519 for maximum speed and reasonable availability, otherwise RSA for maximum availability. We do not in general recommend Ed448 because it is not widely implemented. ??? example "Generating new SSH keys for `derivepassphrase`" === "OpenSSH" The resulting key will be stored in `~/.ssh/my-vault-ed25519-key`, using "vault key" as a comment. Replace `-t ed25519` with `-t rsa` if generating an RSA key, and adapt the filename accordingly. ~~~~ console $ ssh-keygen -t ed25519 -f ~/.ssh/my-vault-ed25519-key -C "vault key" Generating public/private ed25519 key pair. Enter passphrase for ".../.ssh/my-vault-ed25519-key" (empty for no passphrase): Enter same passphrase again: Your identification has been saved in .../.ssh/my-vault-ed25519-key Your public key has been saved in .../.ssh/my-vault-ed25519-key.pub The key fingerprint is: SHA256:BKD43lBB7qh4VvZxq6xSYDXUUbXF6snrRF7qUnOx1PA vault key The key's randomart image is: +--[ED25519 256]--+ | o=ooo..... | | . oo... oo | |. ..o. . .. + | | .o+ . . o E | | .+.+ . So.o.o | |.o =.. o +*oo | |o +.. . ..++ | | o. . ..o. | | ...o oo | +----[SHA256]-----+ ~~~~ (The key fingerprint and the randomart image will naturally differ, as they are key-specific.) === "PuTTY" The resulting key will be stored in `~/.ssh/my-vault-ed25519-key.ppk`, using "vault key" as a comment. Replace `-t ed25519` with `-t rsa` if generating an RSA key, and adapt the filename accordingly. ~~~~ console $ puttygen -t ed25519 -o ~/.ssh/my-vault-ed25519-key.ppk -C "vault key" Enter passphrase to save key: Re-enter passphrase to verify: ~~~~ === "GnuPG" Not supported natively. An alternative SSH client distribution such as OpenSSH or PuTTY is necessary Alternatively, GnuPG supports reusing keys in its native OpenPGP format for SSH as long as the underlying key type is compatible. --- !!! abstract "Further reading" → [How to set up `derivepassphrase vault` with an SSH key][HOWTO] [HOWTO]: ../how-tos/ssh-key.md [GnuPG]: https://gnupg.org/ [ISSUE_WINDOWS_SUPPORT]: https://github.com/the-13th-letter/derivepassphrase/issues/13 [OpenSSH]: https://www.openssh.com/ [PuTTY]: https://www.chiark.greenend.org.uk/~sgtatham/putty/ [PYTHON_AF_UNIX]: https://docs.python.org/3/library/socket.html#socket.AF_UNIX [RFC 6979]: https://www.rfc-editor.org/rfc/rfc6979