aboutsummaryrefslogtreecommitdiff
path: root/Crypto.hs
blob: 01322c403cce450d201902cb264b0083d1d8fe4e (plain)
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
145
146
147
148
149
150
151
152
{- git-annex crypto
 -
 - Currently using gpg; could later be modified to support different
 - crypto backends if neccessary.
 -
 - Copyright 2011-2012 Joey Hess <joey@kitenet.net>
 -
 - Licensed under the GNU GPL version 3 or higher.
 -}

module Crypto (
	Cipher,
	KeyIds(..),
	StorableCipher(..),
	genEncryptedCipher,
	genSharedCipher,
	updateEncryptedCipher,
	describeCipher,
	decryptCipher,		
	encryptKey,
	withEncryptedHandle,
	withDecryptedHandle,
	withEncryptedContent,
	withDecryptedContent,

	prop_hmacWithCipher_sane
) where

import qualified Data.ByteString.Lazy as L
import Data.ByteString.Lazy.UTF8 (fromString)
import Data.Digest.Pure.SHA
import Control.Applicative

import Common.Annex
import qualified Utility.Gpg as Gpg
import Types.Key
import Types.Crypto

{- The first half of a Cipher is used for HMAC; the remainder
 - is used as the GPG symmetric encryption passphrase.
 -
 - HMAC SHA1 needs only 64 bytes. The remainder is for expansion,
 - perhaps to HMAC SHA512, which needs 128 bytes (ideally).
 -
 - 256 is enough for gpg's symetric cipher; unlike weaker public key
 - crypto, the key does not need to be too large.
 -}
cipherHalf :: Int
cipherHalf = 256

cipherSize :: Int
cipherSize = cipherHalf * 2

cipherPassphrase :: Cipher -> String
cipherPassphrase (Cipher c) = drop cipherHalf c

cipherHmac :: Cipher -> String
cipherHmac (Cipher c) = take cipherHalf c

{- Creates a new Cipher, encrypted to the specificed key id. -}
genEncryptedCipher :: String -> IO StorableCipher
genEncryptedCipher keyid = do
	ks <- Gpg.findPubKeys keyid
	random <- Gpg.genRandom cipherSize
	encryptCipher (Cipher random) ks

{- Creates a new, shared Cipher. -}
genSharedCipher :: IO StorableCipher
genSharedCipher = SharedCipher <$> Gpg.genRandom cipherSize

{- Updates an existing Cipher, re-encrypting it to add a keyid. -}
updateEncryptedCipher :: String -> StorableCipher -> IO StorableCipher
updateEncryptedCipher _ (SharedCipher _) = undefined
updateEncryptedCipher keyid encipher@(EncryptedCipher _ ks) = do
	ks' <- Gpg.findPubKeys keyid
	cipher <- decryptCipher encipher
	encryptCipher cipher (merge ks ks')
	where
		merge (KeyIds a) (KeyIds b) = KeyIds $ a ++ b

describeCipher :: StorableCipher -> String
describeCipher (SharedCipher _) = "shared cipher"
describeCipher (EncryptedCipher _ (KeyIds ks)) =
	"with gpg " ++ keys ks ++ " " ++ unwords ks
	where
		keys [_] = "key"
		keys _ = "keys"

{- Encrypts a Cipher to the specified KeyIds. -}
encryptCipher :: Cipher -> KeyIds -> IO StorableCipher
encryptCipher (Cipher c) (KeyIds ks) = do
	let ks' = nub $ sort ks -- gpg complains about duplicate recipient keyids
	encipher <- Gpg.pipeStrict (encrypt++recipients ks') c
	return $ EncryptedCipher encipher (KeyIds ks')
	where
		encrypt = [ Params "--encrypt" ]
		recipients l = force_recipients :
			concatMap (\k -> [Param "--recipient", Param k]) l
		-- Force gpg to only encrypt to the specified
		-- recipients, not configured defaults.
		force_recipients = Params "--no-encrypt-to --no-default-recipient"

{- Decrypting an EncryptedCipher is expensive; the Cipher should be cached. -}
decryptCipher :: StorableCipher -> IO Cipher
decryptCipher (SharedCipher t) = return $ Cipher t
decryptCipher (EncryptedCipher t _) = Cipher <$> Gpg.pipeStrict decrypt t
	where
		decrypt = [ Param "--decrypt" ]

{- Generates an encrypted form of a Key. The encryption does not need to be
 - reversable, nor does it need to be the same type of encryption used
 - on content. It does need to be repeatable. -}
encryptKey :: Cipher -> Key -> Key
encryptKey c k = Key
	{ keyName = hmacWithCipher c (show k)
	, keyBackendName = "GPGHMACSHA1"
	, keySize = Nothing -- size and mtime omitted
	, keyMtime = Nothing -- to avoid leaking data
	}

{- Runs an action, passing it a handle from which it can 
 - stream encrypted content. -}
withEncryptedHandle :: Cipher -> IO L.ByteString -> (Handle -> IO a) -> IO a
withEncryptedHandle = Gpg.passphraseHandle [Params "--symmetric --force-mdc"] . cipherPassphrase

{- Runs an action, passing it a handle from which it can
 - stream decrypted content. -}
withDecryptedHandle :: Cipher -> IO L.ByteString -> (Handle -> IO a) -> IO a
withDecryptedHandle = Gpg.passphraseHandle [Param "--decrypt"] . cipherPassphrase

{- Streams encrypted content to an action. -}
withEncryptedContent :: Cipher -> IO L.ByteString -> (L.ByteString -> IO a) -> IO a
withEncryptedContent = pass withEncryptedHandle

{- Streams decrypted content to an action. -}
withDecryptedContent :: Cipher -> IO L.ByteString -> (L.ByteString -> IO a) -> IO a
withDecryptedContent = pass withDecryptedHandle

pass :: (Cipher -> IO L.ByteString -> (Handle -> IO a) -> IO a) 
      -> Cipher -> IO L.ByteString -> (L.ByteString -> IO a) -> IO a
pass to n s a = to n s $ a <=< L.hGetContents

hmacWithCipher :: Cipher -> String -> String
hmacWithCipher c = hmacWithCipher' (cipherHmac c) 
hmacWithCipher' :: String -> String -> String
hmacWithCipher' c s = showDigest $ hmacSha1 (fromString c) (fromString s)

{- Ensure that hmacWithCipher' returns the same thing forevermore. -}
prop_hmacWithCipher_sane :: Bool
prop_hmacWithCipher_sane = known_good == hmacWithCipher' "foo" "bar"
	where
		known_good = "46b4ec586117154dacd49d664e5d63fdc88efb51"