2013-10-27 21:12:19 +00:00
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[[!toc]]
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2011-04-16 23:30:31 +00:00
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git-annex mostly does not use encryption. Anyone with access to a git
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repository can see all the filenames in it, its history, and can access
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any annexed file contents.
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Encryption is needed when using [[special_remotes]] like Amazon S3, where
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file content is sent to an untrusted party who does not have access to the
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git repository.
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2013-09-01 18:12:00 +00:00
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Such an encrypted remote uses strong ([[symmetric|design/encryption]] or
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asymmetric) encryption on the contents of files, as well as HMAC hashing
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of the filenames. The size of the encrypted files, and access patterns
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of the data, should be the only clues to what is stored in such a
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remote.
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2011-04-16 23:30:31 +00:00
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You should decide whether to use encryption with a special remote before
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any data is stored in it. So, `git annex initremote` requires you
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to specify "encryption=none" when first setting up a remote in order
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2013-09-05 00:11:25 +00:00
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to disable encryption. To use encryption, you run
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run `git-annex initremote` in one of these ways:
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2011-04-16 23:30:31 +00:00
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2013-09-05 00:11:25 +00:00
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* `git annex initremote newremote type=... encryption=hybrid keyid=KEYID ...`
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* `git annex initremote newremote type=... encryption=shared`
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* `git annex initremote newremote type=... encryption=pubkey keyid=KEYID ...`
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2011-04-16 23:30:31 +00:00
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2013-09-05 00:11:25 +00:00
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## hybrid encryption keys
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2013-03-29 16:06:02 +00:00
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2013-09-05 00:11:25 +00:00
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The [[hybrid_key_design|design/encryption]] allows additional
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encryption keys to be added on to a special remote later. Due to this
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2013-12-02 02:09:18 +00:00
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flexibility, it is the default and recommended encryption scheme.
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2013-09-05 00:11:25 +00:00
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git annex initremote newremote type=... [encryption=hybrid] keyid=KEYID ...
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Here the KEYID(s) are passed to `gpg` to find encryption keys.
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Typically, you will say "keyid=2512E3C7" to use a specific gpg key.
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Or, you might say "keyid=joey@kitenet.net" to search for matching keys.
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To add a new key and allow it to access all the content that is stored
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in the encrypted special remote, just run `git annex
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enableremote` specifying the new encryption key:
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2011-04-16 23:30:31 +00:00
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2013-08-28 02:24:14 +00:00
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git annex enableremote myremote keyid+=788A3F4C
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2011-04-16 23:30:31 +00:00
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2013-09-05 00:11:25 +00:00
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While a key can later be removed from the list, note that
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that will **not** necessarily prevent the owner of the key
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from accessing data on the remote (which is by design impossible to prevent,
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short of deleting the remote). In fact the only sound use of `keyid-=` is
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probably to replace a revoked key:
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git annex enableremote myremote keyid-=2512E3C7 keyid+=788A3F4C
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See also [[encryption_design|design/encryption]] for other security
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risks associated with encryption.
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2012-04-29 18:02:18 +00:00
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2013-09-05 00:11:25 +00:00
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## shared encryption key
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2012-04-29 18:02:18 +00:00
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Alternatively, you can configure git-annex to use a shared cipher to
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encrypt data stored in a remote. This shared cipher is stored,
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**unencrypted** in the git repository. So it's shared among every
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clone of the git repository.
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git annex initremote newremote type=... encryption=shared
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The advantage is you don't need to set up gpg keys. The disadvantage is
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that this is **insecure** unless you trust every clone of the git
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repository with access to the encrypted data stored in the special remote.
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## regular public key encryption
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This alternative simply encrypts the files in the special remotes to one or
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more public keys. It might be considered more secure due to its simplicity
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and since it's exactly the way everyone else uses gpg.
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git annex initremote newremote type=.... encryption=pubkey keyid=KEYID ...
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A disavantage is that is not easy to later add additional public keys
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to the special remote. While the `enableremote` parameters `keyid+=` and
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`keyid-=` can be used, they have **no effect** on files that are already
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present on the remote. Probably the only use for these parameters is
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to replace a revoked key:
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git annex enableremote myremote keyid-=2512E3C7 keyid+=788A3F4C
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But even in this case, since the files are not re-encrypted, the revoked
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key has to be kept around to be able to decrypt those files.
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(Of course, if the reason for revocation is
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2013-09-01 18:12:00 +00:00
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that the key has been compromised, it is **insecure** to leave files
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2013-09-05 00:11:25 +00:00
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encrypted using that old key, and the user should re-encrypt everything.)
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(Because filenames are MAC'ed, a cipher still needs to be
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generated (and encrypted to the given key IDs).)
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## MAC algorithm
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2013-09-05 00:11:25 +00:00
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The default MAC algorithm to be applied on the filenames is HMACSHA1. A
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stronger one, for instance HMACSHA512, one can be chosen upon creation
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of the special remote with the option `mac=HMACSHA512`. The available
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MAC algorithms are HMACSHA1, HMACSHA224, HMACSHA256, HMACSHA384, and
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HMACSHA512. Note that it is not possible to change algorithm for a
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non-empty remote.
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