930 lines
36 KiB
ReStructuredText
930 lines
36 KiB
ReStructuredText
.. _pgpguide:
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===========================
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Kernel Maintainer PGP guide
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===========================
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:Author: Konstantin Ryabitsev <konstantin@linuxfoundation.org>
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This document is aimed at Linux kernel developers, and especially at
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subsystem maintainers. It contains a subset of information discussed in
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the more general "`Protecting Code Integrity`_" guide published by the
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Linux Foundation. Please read that document for more in-depth discussion
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on some of the topics mentioned in this guide.
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.. _`Protecting Code Integrity`: https://github.com/lfit/itpol/blob/master/protecting-code-integrity.md
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The role of PGP in Linux Kernel development
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===========================================
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PGP helps ensure the integrity of the code that is produced by the Linux
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kernel development community and, to a lesser degree, establish trusted
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communication channels between developers via PGP-signed email exchange.
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The Linux kernel source code is available in two main formats:
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- Distributed source repositories (git)
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- Periodic release snapshots (tarballs)
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Both git repositories and tarballs carry PGP signatures of the kernel
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developers who create official kernel releases. These signatures offer a
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cryptographic guarantee that downloadable versions made available via
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kernel.org or any other mirrors are identical to what these developers
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have on their workstations. To this end:
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- git repositories provide PGP signatures on all tags
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- tarballs provide detached PGP signatures with all downloads
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.. _devs_not_infra:
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Trusting the developers, not infrastructure
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-------------------------------------------
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Ever since the 2011 compromise of core kernel.org systems, the main
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operating principle of the Kernel Archives project has been to assume
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that any part of the infrastructure can be compromised at any time. For
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this reason, the administrators have taken deliberate steps to emphasize
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that trust must always be placed with developers and never with the code
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hosting infrastructure, regardless of how good the security practices
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for the latter may be.
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The above guiding principle is the reason why this guide is needed. We
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want to make sure that by placing trust into developers we do not simply
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shift the blame for potential future security incidents to someone else.
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The goal is to provide a set of guidelines developers can use to create
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a secure working environment and safeguard the PGP keys used to
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establish the integrity of the Linux kernel itself.
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.. _pgp_tools:
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PGP tools
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=========
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Use GnuPG v2
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------------
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Your distro should already have GnuPG installed by default, you just
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need to verify that you are using version 2.x and not the legacy 1.4
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release -- many distributions still package both, with the default
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``gpg`` command invoking GnuPG v.1. To check, run::
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$ gpg --version | head -n1
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If you see ``gpg (GnuPG) 1.4.x``, then you are using GnuPG v.1. Try the
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``gpg2`` command (if you don't have it, you may need to install the
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gnupg2 package)::
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$ gpg2 --version | head -n1
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If you see ``gpg (GnuPG) 2.x.x``, then you are good to go. This guide
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will assume you have the version 2.2 of GnuPG (or later). If you are
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using version 2.0 of GnuPG, then some of the commands in this guide will
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not work, and you should consider installing the latest 2.2 version of
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GnuPG. Versions of gnupg-2.1.11 and later should be compatible for the
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purposes of this guide as well.
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If you have both ``gpg`` and ``gpg2`` commands, you should make sure you
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are always using GnuPG v2, not the legacy version. You can enforce this
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by setting the appropriate alias::
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$ alias gpg=gpg2
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You can put that in your ``.bashrc`` to make sure it's always the case.
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Configure gpg-agent options
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~~~~~~~~~~~~~~~~~~~~~~~~~~~
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The GnuPG agent is a helper tool that will start automatically whenever
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you use the ``gpg`` command and run in the background with the purpose
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of caching the private key passphrase. There are two options you should
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know in order to tweak when the passphrase should be expired from cache:
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- ``default-cache-ttl`` (seconds): If you use the same key again before
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the time-to-live expires, the countdown will reset for another period.
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The default is 600 (10 minutes).
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- ``max-cache-ttl`` (seconds): Regardless of how recently you've used
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the key since initial passphrase entry, if the maximum time-to-live
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countdown expires, you'll have to enter the passphrase again. The
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default is 30 minutes.
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If you find either of these defaults too short (or too long), you can
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edit your ``~/.gnupg/gpg-agent.conf`` file to set your own values::
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# set to 30 minutes for regular ttl, and 2 hours for max ttl
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default-cache-ttl 1800
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max-cache-ttl 7200
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.. note::
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It is no longer necessary to start gpg-agent manually at the
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beginning of your shell session. You may want to check your rc files
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to remove anything you had in place for older versions of GnuPG, as
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it may not be doing the right thing any more.
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Set up a refresh cronjob
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~~~~~~~~~~~~~~~~~~~~~~~~
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You will need to regularly refresh your keyring in order to get the
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latest changes on other people's public keys, which is best done with a
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daily cronjob::
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@daily /usr/bin/gpg2 --refresh >/dev/null 2>&1
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Check the full path to your ``gpg`` or ``gpg2`` command and use the
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``gpg2`` command if regular ``gpg`` for you is the legacy GnuPG v.1.
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.. _master_key:
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Protect your master PGP key
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===========================
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This guide assumes that you already have a PGP key that you use for Linux
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kernel development purposes. If you do not yet have one, please see the
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"`Protecting Code Integrity`_" document mentioned earlier for guidance
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on how to create a new one.
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You should also make a new key if your current one is weaker than 2048 bits
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(RSA).
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Master key vs. Subkeys
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----------------------
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Subkeys are fully independent PGP keypairs that are tied to the "master"
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key using certifying key signatures (certificates). It is important to
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understand the following:
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1. There are no technical differences between the "master key" and "subkeys."
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2. At creation time, we assign functional limitations to each key by
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giving it specific capabilities.
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3. A PGP key can have 4 capabilities:
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- **[S]** key can be used for signing
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- **[E]** key can be used for encryption
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- **[A]** key can be used for authentication
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- **[C]** key can be used for certifying other keys
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4. A single key may have multiple capabilities.
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5. A subkey is fully independent from the master key. A message
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encrypted to a subkey cannot be decrypted with the master key. If you
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lose your private subkey, it cannot be recreated from the master key
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in any way.
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The key carrying the **[C]** (certify) capability is considered the
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"master" key because it is the only key that can be used to indicate
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relationship with other keys. Only the **[C]** key can be used to:
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- add or revoke other keys (subkeys) with S/E/A capabilities
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- add, change or revoke identities (uids) associated with the key
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- add or change the expiration date on itself or any subkey
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- sign other people's keys for web of trust purposes
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By default, GnuPG creates the following when generating new keys:
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- A master key carrying both Certify and Sign capabilities (**[SC]**)
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- A separate subkey with the Encryption capability (**[E]**)
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If you used the default parameters when generating your key, then that
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is what you will have. You can verify by running ``gpg --list-secret-keys``,
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for example::
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sec rsa2048 2018-01-23 [SC] [expires: 2020-01-23]
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000000000000000000000000AAAABBBBCCCCDDDD
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uid [ultimate] Alice Dev <adev@kernel.org>
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ssb rsa2048 2018-01-23 [E] [expires: 2020-01-23]
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Any key carrying the **[C]** capability is your master key, regardless
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of any other capabilities it may have assigned to it.
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The long line under the ``sec`` entry is your key fingerprint --
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whenever you see ``[fpr]`` in the examples below, that 40-character
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string is what it refers to.
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Ensure your passphrase is strong
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--------------------------------
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GnuPG uses passphrases to encrypt your private keys before storing them on
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disk. This way, even if your ``.gnupg`` directory is leaked or stolen in
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its entirety, the attackers cannot use your private keys without first
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obtaining the passphrase to decrypt them.
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It is absolutely essential that your private keys are protected by a
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strong passphrase. To set it or change it, use::
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$ gpg --change-passphrase [fpr]
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Create a separate Signing subkey
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--------------------------------
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Our goal is to protect your master key by moving it to offline media, so
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if you only have a combined **[SC]** key, then you should create a separate
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signing subkey::
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$ gpg --quick-add-key [fpr] ed25519 sign
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Remember to tell the keyservers about this change, so others can pull down
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your new subkey::
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$ gpg --send-key [fpr]
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.. note:: ECC support in GnuPG
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GnuPG 2.1 and later has full support for Elliptic Curve
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Cryptography, with ability to combine ECC subkeys with traditional
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RSA master keys. The main upside of ECC cryptography is that it is
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much faster computationally and creates much smaller signatures when
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compared byte for byte with 2048+ bit RSA keys. Unless you plan on
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using a smartcard device that does not support ECC operations, we
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recommend that you create an ECC signing subkey for your kernel
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work.
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If for some reason you prefer to stay with RSA subkeys, just replace
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"ed25519" with "rsa2048" in the above command.
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Back up your master key for disaster recovery
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---------------------------------------------
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The more signatures you have on your PGP key from other developers, the
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more reasons you have to create a backup version that lives on something
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other than digital media, for disaster recovery reasons.
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The best way to create a printable hardcopy of your private key is by
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using the ``paperkey`` software written for this very purpose. See ``man
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paperkey`` for more details on the output format and its benefits over
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other solutions. Paperkey should already be packaged for most
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distributions.
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Run the following command to create a hardcopy backup of your private
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key::
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$ gpg --export-secret-key [fpr] | paperkey -o /tmp/key-backup.txt
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Print out that file (or pipe the output straight to lpr), then take a
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pen and write your passphrase on the margin of the paper. **This is
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strongly recommended** because the key printout is still encrypted with
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that passphrase, and if you ever change it you will not remember what it
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used to be when you had created the backup -- *guaranteed*.
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Put the resulting printout and the hand-written passphrase into an envelope
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and store in a secure and well-protected place, preferably away from your
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home, such as your bank vault.
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.. note::
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Your printer is probably no longer a simple dumb device connected to
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your parallel port, but since the output is still encrypted with
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your passphrase, printing out even to "cloud-integrated" modern
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printers should remain a relatively safe operation. One option is to
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change the passphrase on your master key immediately after you are
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done with paperkey.
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Back up your whole GnuPG directory
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----------------------------------
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.. warning::
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**!!!Do not skip this step!!!**
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It is important to have a readily available backup of your PGP keys
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should you need to recover them. This is different from the
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disaster-level preparedness we did with ``paperkey``. You will also rely
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on these external copies whenever you need to use your Certify key --
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such as when making changes to your own key or signing other people's
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keys after conferences and summits.
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Start by getting a small USB "thumb" drive (preferably two!) that you
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will use for backup purposes. You will need to encrypt them using LUKS
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-- refer to your distro's documentation on how to accomplish this.
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For the encryption passphrase, you can use the same one as on your
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master key.
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Once the encryption process is over, re-insert the USB drive and make
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sure it gets properly mounted. Copy your entire ``.gnupg`` directory
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over to the encrypted storage::
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$ cp -a ~/.gnupg /media/disk/foo/gnupg-backup
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You should now test to make sure everything still works::
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$ gpg --homedir=/media/disk/foo/gnupg-backup --list-key [fpr]
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If you don't get any errors, then you should be good to go. Unmount the
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USB drive, distinctly label it so you don't blow it away next time you
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need to use a random USB drive, and put in a safe place -- but not too
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far away, because you'll need to use it every now and again for things
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like editing identities, adding or revoking subkeys, or signing other
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people's keys.
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Remove the master key from your homedir
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----------------------------------------
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The files in our home directory are not as well protected as we like to
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think. They can be leaked or stolen via many different means:
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- by accident when making quick homedir copies to set up a new workstation
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- by systems administrator negligence or malice
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- via poorly secured backups
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- via malware in desktop apps (browsers, pdf viewers, etc)
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- via coercion when crossing international borders
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Protecting your key with a good passphrase greatly helps reduce the risk
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of any of the above, but passphrases can be discovered via keyloggers,
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shoulder-surfing, or any number of other means. For this reason, the
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recommended setup is to remove your master key from your home directory
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and store it on offline storage.
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.. warning::
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Please see the previous section and make sure you have backed up
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your GnuPG directory in its entirety. What we are about to do will
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render your key useless if you do not have a usable backup!
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First, identify the keygrip of your master key::
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$ gpg --with-keygrip --list-key [fpr]
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The output will be something like this::
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pub rsa2048 2018-01-24 [SC] [expires: 2020-01-24]
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000000000000000000000000AAAABBBBCCCCDDDD
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Keygrip = 1111000000000000000000000000000000000000
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uid [ultimate] Alice Dev <adev@kernel.org>
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sub rsa2048 2018-01-24 [E] [expires: 2020-01-24]
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Keygrip = 2222000000000000000000000000000000000000
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sub ed25519 2018-01-24 [S]
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Keygrip = 3333000000000000000000000000000000000000
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Find the keygrip entry that is beneath the ``pub`` line (right under the
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master key fingerprint). This will correspond directly to a file in your
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``~/.gnupg`` directory::
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$ cd ~/.gnupg/private-keys-v1.d
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$ ls
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1111000000000000000000000000000000000000.key
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2222000000000000000000000000000000000000.key
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3333000000000000000000000000000000000000.key
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All you have to do is simply remove the .key file that corresponds to
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the master keygrip::
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$ cd ~/.gnupg/private-keys-v1.d
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$ rm 1111000000000000000000000000000000000000.key
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Now, if you issue the ``--list-secret-keys`` command, it will show that
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the master key is missing (the ``#`` indicates it is not available)::
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$ gpg --list-secret-keys
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sec# rsa2048 2018-01-24 [SC] [expires: 2020-01-24]
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000000000000000000000000AAAABBBBCCCCDDDD
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uid [ultimate] Alice Dev <adev@kernel.org>
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ssb rsa2048 2018-01-24 [E] [expires: 2020-01-24]
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ssb ed25519 2018-01-24 [S]
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You should also remove any ``secring.gpg`` files in the ``~/.gnupg``
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directory, which are left over from earlier versions of GnuPG.
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If you don't have the "private-keys-v1.d" directory
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~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
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If you do not have a ``~/.gnupg/private-keys-v1.d`` directory, then your
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secret keys are still stored in the legacy ``secring.gpg`` file used by
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GnuPG v1. Making any changes to your key, such as changing the
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passphrase or adding a subkey, should automatically convert the old
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``secring.gpg`` format to use ``private-keys-v1.d`` instead.
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Once you get that done, make sure to delete the obsolete ``secring.gpg``
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file, which still contains your private keys.
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.. _smartcards:
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Move the subkeys to a dedicated crypto device
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=============================================
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Even though the master key is now safe from being leaked or stolen, the
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subkeys are still in your home directory. Anyone who manages to get
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their hands on those will be able to decrypt your communication or fake
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your signatures (if they know the passphrase). Furthermore, each time a
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GnuPG operation is performed, the keys are loaded into system memory and
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can be stolen from there by sufficiently advanced malware (think
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Meltdown and Spectre).
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The best way to completely protect your keys is to move them to a
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specialized hardware device that is capable of smartcard operations.
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The benefits of smartcards
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--------------------------
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A smartcard contains a cryptographic chip that is capable of storing
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private keys and performing crypto operations directly on the card
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itself. Because the key contents never leave the smartcard, the
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operating system of the computer into which you plug in the hardware
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device is not able to retrieve the private keys themselves. This is very
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different from the encrypted USB storage device we used earlier for
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backup purposes -- while that USB device is plugged in and mounted, the
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operating system is able to access the private key contents.
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Using external encrypted USB media is not a substitute to having a
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smartcard-capable device.
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Available smartcard devices
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---------------------------
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Unless all your laptops and workstations have smartcard readers, the
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easiest is to get a specialized USB device that implements smartcard
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functionality. There are several options available:
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- `Nitrokey Start`_: Open hardware and Free Software, based on FSI
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Japan's `Gnuk`_. Offers support for ECC keys, but fewest security
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features (such as resistance to tampering or some side-channel
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attacks).
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- `Nitrokey Pro`_: Similar to the Nitrokey Start, but more
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tamper-resistant and offers more security features, but no ECC
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support.
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- `Yubikey 4`_: proprietary hardware and software, but cheaper than
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Nitrokey Pro and comes available in the USB-C form that is more useful
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with newer laptops. Offers additional security features such as FIDO
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U2F, but no ECC.
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`LWN has a good review`_ of some of the above models, as well as several
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others. If you want to use ECC keys, your best bet among commercially
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available devices is the Nitrokey Start.
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.. _`Nitrokey Start`: https://shop.nitrokey.com/shop/product/nitrokey-start-6
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.. _`Nitrokey Pro`: https://shop.nitrokey.com/shop/product/nitrokey-pro-3
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.. _`Yubikey 4`: https://www.yubico.com/product/yubikey-4-series/
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.. _Gnuk: http://www.fsij.org/doc-gnuk/
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.. _`LWN has a good review`: https://lwn.net/Articles/736231/
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Configure your smartcard device
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-------------------------------
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Your smartcard device should Just Work (TM) the moment you plug it into
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any modern Linux workstation. You can verify it by running::
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$ gpg --card-status
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If you see full smartcard details, then you are good to go.
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Unfortunately, troubleshooting all possible reasons why things may not
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be working for you is way beyond the scope of this guide. If you are
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having trouble getting the card to work with GnuPG, please seek help via
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usual support channels.
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To configure your smartcard, you will need to use the GnuPG menu system, as
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there are no convenient command-line switches::
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$ gpg --card-edit
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[...omitted...]
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gpg/card> admin
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Admin commands are allowed
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gpg/card> passwd
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You should set the user PIN (1), Admin PIN (3), and the Reset Code (4).
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Please make sure to record and store these in a safe place -- especially
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the Admin PIN and the Reset Code (which allows you to completely wipe
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the smartcard). You so rarely need to use the Admin PIN, that you will
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inevitably forget what it is if you do not record it.
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|
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Getting back to the main card menu, you can also set other values (such
|
|
as name, sex, login data, etc), but it's not necessary and will
|
|
additionally leak information about your smartcard should you lose it.
|
|
|
|
.. note::
|
|
|
|
Despite having the name "PIN", neither the user PIN nor the admin
|
|
PIN on the card need to be numbers.
|
|
|
|
Move the subkeys to your smartcard
|
|
----------------------------------
|
|
|
|
Exit the card menu (using "q") and save all changes. Next, let's move
|
|
your subkeys onto the smartcard. You will need both your PGP key
|
|
passphrase and the admin PIN of the card for most operations::
|
|
|
|
$ gpg --edit-key [fpr]
|
|
|
|
Secret subkeys are available.
|
|
|
|
pub rsa2048/AAAABBBBCCCCDDDD
|
|
created: 2018-01-23 expires: 2020-01-23 usage: SC
|
|
trust: ultimate validity: ultimate
|
|
ssb rsa2048/1111222233334444
|
|
created: 2018-01-23 expires: never usage: E
|
|
ssb ed25519/5555666677778888
|
|
created: 2017-12-07 expires: never usage: S
|
|
[ultimate] (1). Alice Dev <adev@kernel.org>
|
|
|
|
gpg>
|
|
|
|
Using ``--edit-key`` puts us into the menu mode again, and you will
|
|
notice that the key listing is a little different. From here on, all
|
|
commands are done from inside this menu mode, as indicated by ``gpg>``.
|
|
|
|
First, let's select the key we'll be putting onto the card -- you do
|
|
this by typing ``key 1`` (it's the first one in the listing, the **[E]**
|
|
subkey)::
|
|
|
|
gpg> key 1
|
|
|
|
In the output, you should now see ``ssb*`` on the **[E]** key. The ``*``
|
|
indicates which key is currently "selected." It works as a *toggle*,
|
|
meaning that if you type ``key 1`` again, the ``*`` will disappear and
|
|
the key will not be selected any more.
|
|
|
|
Now, let's move that key onto the smartcard::
|
|
|
|
gpg> keytocard
|
|
Please select where to store the key:
|
|
(2) Encryption key
|
|
Your selection? 2
|
|
|
|
Since it's our **[E]** key, it makes sense to put it into the Encryption
|
|
slot. When you submit your selection, you will be prompted first for
|
|
your PGP key passphrase, and then for the admin PIN. If the command
|
|
returns without an error, your key has been moved.
|
|
|
|
**Important**: Now type ``key 1`` again to unselect the first key, and
|
|
``key 2`` to select the **[S]** key::
|
|
|
|
gpg> key 1
|
|
gpg> key 2
|
|
gpg> keytocard
|
|
Please select where to store the key:
|
|
(1) Signature key
|
|
(3) Authentication key
|
|
Your selection? 1
|
|
|
|
You can use the **[S]** key both for Signature and Authentication, but
|
|
we want to make sure it's in the Signature slot, so choose (1). Once
|
|
again, if your command returns without an error, then the operation was
|
|
successful::
|
|
|
|
gpg> q
|
|
Save changes? (y/N) y
|
|
|
|
Saving the changes will delete the keys you moved to the card from your
|
|
home directory (but it's okay, because we have them in our backups
|
|
should we need to do this again for a replacement smartcard).
|
|
|
|
Verifying that the keys were moved
|
|
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
|
|
|
|
If you perform ``--list-secret-keys`` now, you will see a subtle
|
|
difference in the output::
|
|
|
|
$ gpg --list-secret-keys
|
|
sec# rsa2048 2018-01-24 [SC] [expires: 2020-01-24]
|
|
000000000000000000000000AAAABBBBCCCCDDDD
|
|
uid [ultimate] Alice Dev <adev@kernel.org>
|
|
ssb> rsa2048 2018-01-24 [E] [expires: 2020-01-24]
|
|
ssb> ed25519 2018-01-24 [S]
|
|
|
|
The ``>`` in the ``ssb>`` output indicates that the subkey is only
|
|
available on the smartcard. If you go back into your secret keys
|
|
directory and look at the contents there, you will notice that the
|
|
``.key`` files there have been replaced with stubs::
|
|
|
|
$ cd ~/.gnupg/private-keys-v1.d
|
|
$ strings *.key | grep 'private-key'
|
|
|
|
The output should contain ``shadowed-private-key`` to indicate that
|
|
these files are only stubs and the actual content is on the smartcard.
|
|
|
|
Verifying that the smartcard is functioning
|
|
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
|
|
|
|
To verify that the smartcard is working as intended, you can create a
|
|
signature::
|
|
|
|
$ echo "Hello world" | gpg --clearsign > /tmp/test.asc
|
|
$ gpg --verify /tmp/test.asc
|
|
|
|
This should ask for your smartcard PIN on your first command, and then
|
|
show "Good signature" after you run ``gpg --verify``.
|
|
|
|
Congratulations, you have successfully made it extremely difficult to
|
|
steal your digital developer identity!
|
|
|
|
Other common GnuPG operations
|
|
-----------------------------
|
|
|
|
Here is a quick reference for some common operations you'll need to do
|
|
with your PGP key.
|
|
|
|
Mounting your master key offline storage
|
|
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
|
|
|
|
You will need your master key for any of the operations below, so you
|
|
will first need to mount your backup offline storage and tell GnuPG to
|
|
use it::
|
|
|
|
$ export GNUPGHOME=/media/disk/foo/gnupg-backup
|
|
$ gpg --list-secret-keys
|
|
|
|
You want to make sure that you see ``sec`` and not ``sec#`` in the
|
|
output (the ``#`` means the key is not available and you're still using
|
|
your regular home directory location).
|
|
|
|
Extending key expiration date
|
|
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
|
|
|
|
The master key has the default expiration date of 2 years from the date
|
|
of creation. This is done both for security reasons and to make obsolete
|
|
keys eventually disappear from keyservers.
|
|
|
|
To extend the expiration on your key by a year from current date, just
|
|
run::
|
|
|
|
$ gpg --quick-set-expire [fpr] 1y
|
|
|
|
You can also use a specific date if that is easier to remember (e.g.
|
|
your birthday, January 1st, or Canada Day)::
|
|
|
|
$ gpg --quick-set-expire [fpr] 2020-07-01
|
|
|
|
Remember to send the updated key back to keyservers::
|
|
|
|
$ gpg --send-key [fpr]
|
|
|
|
Updating your work directory after any changes
|
|
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
|
|
|
|
After you make any changes to your key using the offline storage, you will
|
|
want to import these changes back into your regular working directory::
|
|
|
|
$ gpg --export | gpg --homedir ~/.gnupg --import
|
|
$ unset GNUPGHOME
|
|
|
|
|
|
Using PGP with Git
|
|
==================
|
|
|
|
One of the core features of Git is its decentralized nature -- once a
|
|
repository is cloned to your system, you have full history of the
|
|
project, including all of its tags, commits and branches. However, with
|
|
hundreds of cloned repositories floating around, how does anyone verify
|
|
that their copy of linux.git has not been tampered with by a malicious
|
|
third party?
|
|
|
|
Or what happens if a backdoor is discovered in the code and the "Author"
|
|
line in the commit says it was done by you, while you're pretty sure you
|
|
had `nothing to do with it`_?
|
|
|
|
To address both of these issues, Git introduced PGP integration. Signed
|
|
tags prove the repository integrity by assuring that its contents are
|
|
exactly the same as on the workstation of the developer who created the
|
|
tag, while signed commits make it nearly impossible for someone to
|
|
impersonate you without having access to your PGP keys.
|
|
|
|
.. _`nothing to do with it`: https://github.com/jayphelps/git-blame-someone-else
|
|
|
|
Configure git to use your PGP key
|
|
---------------------------------
|
|
|
|
If you only have one secret key in your keyring, then you don't really
|
|
need to do anything extra, as it becomes your default key. However, if
|
|
you happen to have multiple secret keys, you can tell git which key
|
|
should be used (``[fpr]`` is the fingerprint of your key)::
|
|
|
|
$ git config --global user.signingKey [fpr]
|
|
|
|
**IMPORTANT**: If you have a distinct ``gpg2`` command, then you should
|
|
tell git to always use it instead of the legacy ``gpg`` from version 1::
|
|
|
|
$ git config --global gpg.program gpg2
|
|
|
|
How to work with signed tags
|
|
----------------------------
|
|
|
|
To create a signed tag, simply pass the ``-s`` switch to the tag
|
|
command::
|
|
|
|
$ git tag -s [tagname]
|
|
|
|
Our recommendation is to always sign git tags, as this allows other
|
|
developers to ensure that the git repository they are pulling from has
|
|
not been maliciously altered.
|
|
|
|
How to verify signed tags
|
|
~~~~~~~~~~~~~~~~~~~~~~~~~
|
|
|
|
To verify a signed tag, simply use the ``verify-tag`` command::
|
|
|
|
$ git verify-tag [tagname]
|
|
|
|
If you are pulling a tag from another fork of the project repository,
|
|
git should automatically verify the signature at the tip you're pulling
|
|
and show you the results during the merge operation::
|
|
|
|
$ git pull [url] tags/sometag
|
|
|
|
The merge message will contain something like this::
|
|
|
|
Merge tag 'sometag' of [url]
|
|
|
|
[Tag message]
|
|
|
|
# gpg: Signature made [...]
|
|
# gpg: Good signature from [...]
|
|
|
|
If you are verifying someone else's git tag, then you will need to
|
|
import their PGP key. Please refer to the
|
|
":ref:`verify_identities`" section below.
|
|
|
|
Configure git to always sign annotated tags
|
|
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
|
|
|
|
Chances are, if you're creating an annotated tag, you'll want to sign
|
|
it. To force git to always sign annotated tags, you can set a global
|
|
configuration option::
|
|
|
|
$ git config --global tag.forceSignAnnotated true
|
|
|
|
How to work with signed commits
|
|
-------------------------------
|
|
|
|
It is easy to create signed commits, but it is much more difficult to
|
|
use them in Linux kernel development, since it relies on patches sent to
|
|
the mailing list, and this workflow does not preserve PGP commit
|
|
signatures. Furthermore, when rebasing your repository to match
|
|
upstream, even your own PGP commit signatures will end up discarded. For
|
|
this reason, most kernel developers don't bother signing their commits
|
|
and will ignore signed commits in any external repositories that they
|
|
rely upon in their work.
|
|
|
|
However, if you have your working git tree publicly available at some
|
|
git hosting service (kernel.org, infradead.org, ozlabs.org, or others),
|
|
then the recommendation is that you sign all your git commits even if
|
|
upstream developers do not directly benefit from this practice.
|
|
|
|
We recommend this for the following reasons:
|
|
|
|
1. Should there ever be a need to perform code forensics or track code
|
|
provenance, even externally maintained trees carrying PGP commit
|
|
signatures will be valuable for such purposes.
|
|
2. If you ever need to re-clone your local repository (for example,
|
|
after a disk failure), this lets you easily verify the repository
|
|
integrity before resuming your work.
|
|
3. If someone needs to cherry-pick your commits, this allows them to
|
|
quickly verify their integrity before applying them.
|
|
|
|
Creating signed commits
|
|
~~~~~~~~~~~~~~~~~~~~~~~
|
|
|
|
To create a signed commit, you just need to pass the ``-S`` flag to the
|
|
``git commit`` command (it's capital ``-S`` due to collision with
|
|
another flag)::
|
|
|
|
$ git commit -S
|
|
|
|
Configure git to always sign commits
|
|
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
|
|
|
|
You can tell git to always sign commits::
|
|
|
|
git config --global commit.gpgSign true
|
|
|
|
.. note::
|
|
|
|
Make sure you configure ``gpg-agent`` before you turn this on.
|
|
|
|
.. _verify_identities:
|
|
|
|
How to verify kernel developer identities
|
|
=========================================
|
|
|
|
Signing tags and commits is easy, but how does one go about verifying
|
|
that the key used to sign something belongs to the actual kernel
|
|
developer and not to a malicious imposter?
|
|
|
|
Configure auto-key-retrieval using WKD and DANE
|
|
-----------------------------------------------
|
|
|
|
If you are not already someone with an extensive collection of other
|
|
developers' public keys, then you can jumpstart your keyring by relying
|
|
on key auto-discovery and auto-retrieval. GnuPG can piggyback on other
|
|
delegated trust technologies, namely DNSSEC and TLS, to get you going if
|
|
the prospect of starting your own Web of Trust from scratch is too
|
|
daunting.
|
|
|
|
Add the following to your ``~/.gnupg/gpg.conf``::
|
|
|
|
auto-key-locate wkd,dane,local
|
|
auto-key-retrieve
|
|
|
|
DNS-Based Authentication of Named Entities ("DANE") is a method for
|
|
publishing public keys in DNS and securing them using DNSSEC signed
|
|
zones. Web Key Directory ("WKD") is the alternative method that uses
|
|
https lookups for the same purpose. When using either DANE or WKD for
|
|
looking up public keys, GnuPG will validate DNSSEC or TLS certificates,
|
|
respectively, before adding auto-retrieved public keys to your local
|
|
keyring.
|
|
|
|
Kernel.org publishes the WKD for all developers who have kernel.org
|
|
accounts. Once you have the above changes in your ``gpg.conf``, you can
|
|
auto-retrieve the keys for Linus Torvalds and Greg Kroah-Hartman (if you
|
|
don't already have them)::
|
|
|
|
$ gpg --locate-keys torvalds@kernel.org gregkh@kernel.org
|
|
|
|
If you have a kernel.org account, then you should `add the kernel.org
|
|
UID to your key`_ to make WKD more useful to other kernel developers.
|
|
|
|
.. _`add the kernel.org UID to your key`: https://korg.wiki.kernel.org/userdoc/mail#adding_a_kernelorg_uid_to_your_pgp_key
|
|
|
|
Web of Trust (WOT) vs. Trust on First Use (TOFU)
|
|
------------------------------------------------
|
|
|
|
PGP incorporates a trust delegation mechanism known as the "Web of
|
|
Trust." At its core, this is an attempt to replace the need for
|
|
centralized Certification Authorities of the HTTPS/TLS world. Instead of
|
|
various software makers dictating who should be your trusted certifying
|
|
entity, PGP leaves this responsibility to each user.
|
|
|
|
Unfortunately, very few people understand how the Web of Trust works.
|
|
While it remains an important aspect of the OpenPGP specification,
|
|
recent versions of GnuPG (2.2 and above) have implemented an alternative
|
|
mechanism called "Trust on First Use" (TOFU). You can think of TOFU as
|
|
"the SSH-like approach to trust." With SSH, the first time you connect
|
|
to a remote system, its key fingerprint is recorded and remembered. If
|
|
the key changes in the future, the SSH client will alert you and refuse
|
|
to connect, forcing you to make a decision on whether you choose to
|
|
trust the changed key or not. Similarly, the first time you import
|
|
someone's PGP key, it is assumed to be valid. If at any point in the
|
|
future GnuPG comes across another key with the same identity, both the
|
|
previously imported key and the new key will be marked as invalid and
|
|
you will need to manually figure out which one to keep.
|
|
|
|
We recommend that you use the combined TOFU+PGP trust model (which is
|
|
the new default in GnuPG v2). To set it, add (or modify) the
|
|
``trust-model`` setting in ``~/.gnupg/gpg.conf``::
|
|
|
|
trust-model tofu+pgp
|
|
|
|
How to use keyservers (more) safely
|
|
-----------------------------------
|
|
|
|
If you get a "No public key" error when trying to validate someone's
|
|
tag, then you should attempt to lookup that key using a keyserver. It is
|
|
important to keep in mind that there is absolutely no guarantee that the
|
|
key you retrieve from PGP keyservers belongs to the actual person --
|
|
that much is by design. You are supposed to use the Web of Trust to
|
|
establish key validity.
|
|
|
|
How to properly maintain the Web of Trust is beyond the scope of this
|
|
document, simply because doing it properly requires both effort and
|
|
dedication that tends to be beyond the caring threshold of most human
|
|
beings. Here are some shortcuts that will help you reduce the risk of
|
|
importing a malicious key.
|
|
|
|
First, let's say you've tried to run ``git verify-tag`` but it returned
|
|
an error saying the key is not found::
|
|
|
|
$ git verify-tag sunxi-fixes-for-4.15-2
|
|
gpg: Signature made Sun 07 Jan 2018 10:51:55 PM EST
|
|
gpg: using RSA key DA73759BF8619E484E5A3B47389A54219C0F2430
|
|
gpg: issuer "wens@...org"
|
|
gpg: Can't check signature: No public key
|
|
|
|
Let's query the keyserver for more info about that key fingerprint (the
|
|
fingerprint probably belongs to a subkey, so we can't use it directly
|
|
without finding out the ID of the master key it is associated with)::
|
|
|
|
$ gpg --search DA73759BF8619E484E5A3B47389A54219C0F2430
|
|
gpg: data source: hkp://keys.gnupg.net
|
|
(1) Chen-Yu Tsai <wens@...org>
|
|
4096 bit RSA key C94035C21B4F2AEB, created: 2017-03-14, expires: 2019-03-15
|
|
Keys 1-1 of 1 for "DA73759BF8619E484E5A3B47389A54219C0F2430". Enter number(s), N)ext, or Q)uit > q
|
|
|
|
Locate the ID of the master key in the output, in our example
|
|
``C94035C21B4F2AEB``. Now display the key of Linus Torvalds that you
|
|
have on your keyring::
|
|
|
|
$ gpg --list-key torvalds@kernel.org
|
|
pub rsa2048 2011-09-20 [SC]
|
|
ABAF11C65A2970B130ABE3C479BE3E4300411886
|
|
uid [ unknown] Linus Torvalds <torvalds@kernel.org>
|
|
sub rsa2048 2011-09-20 [E]
|
|
|
|
Next, open the `PGP pathfinder`_. In the "From" field, paste the key
|
|
fingerprint of Linus Torvalds from the output above. In the "To" field,
|
|
paste they key-id you found via ``gpg --search`` of the unknown key, and
|
|
check the results:
|
|
|
|
- `Finding paths to Linus`_
|
|
|
|
If you get a few decent trust paths, then it's a pretty good indication
|
|
that it is a valid key. You can add it to your keyring from the
|
|
keyserver now::
|
|
|
|
$ gpg --recv-key C94035C21B4F2AEB
|
|
|
|
This process is not perfect, and you are obviously trusting the
|
|
administrators of the PGP Pathfinder service to not be malicious (in
|
|
fact, this goes against :ref:`devs_not_infra`). However, if you
|
|
do not carefully maintain your own web of trust, then it is a marked
|
|
improvement over blindly trusting keyservers.
|
|
|
|
.. _`PGP pathfinder`: https://pgp.cs.uu.nl/
|
|
.. _`Finding paths to Linus`: https://pgp.cs.uu.nl/paths/79BE3E4300411886/to/C94035C21B4F2AEB.html
|