{-# LANGUAGE CPP #-} {-# LANGUAGE ExplicitForAll #-} {-# LANGUAGE LambdaCase #-} {-# LANGUAGE OverloadedStrings #-} {-# LANGUAGE RecordWildCards #-} {-| Module : Data.Password.Argon2 Copyright : (c) Felix Paulusma, 2020 License : BSD-style (see LICENSE file) Maintainer : cdep.illabout@gmail.com Stability : experimental Portability : POSIX = Argon2 @Argon2@ is probably the newest password algorithm out there. Argon2 was selected as the winner of the Password Hashing Competition in July 2015. It has three variants, namely 'Argon2d', 'Argon2i' and 'Argon2id'. These protect against GPU cracking attacks, side-channel attacks, and both, respectively. All three modes allow specification by three parameters that control: * execution time * memory required * degree of parallelism == Other algorithms In comparison to other algorithms, Argon2 is the least "battle-tested", being the newest algorithm out there. It is, however, recommended over @'Data.Password.Scrypt.Scrypt'@ most of the time, and it also seems like it might become the go-to password algorithm if no vulnarabilities are discovered within the next couple of years. -} -- I think the portability is broadened to -- whatever, now that we use cryptonite... I think module Data.Password.Argon2 ( -- Algorithm Argon2 -- * Plain-text Password , Password , mkPassword -- * Hash Passwords (Argon2) , hashPassword , PasswordHash(..) -- * Verify Passwords (Argon2) , checkPassword , PasswordCheck(..) -- * Hashing Manually (Argon2) , hashPasswordWithParams , defaultParams , Argon2Params(..) , Argon2.Variant(..) , Argon2.Version(..) -- ** Hashing with salt (DISADVISED) -- -- | Hashing with a set 'Salt' is almost never what you want -- to do. Use 'hashPassword' or 'hashPasswordWithParams' to have -- automatic generation of randomized salts. , hashPasswordWithSalt , newSalt , Salt(..) -- * Unsafe debugging function to show a Password , unsafeShowPassword , -- * Setup for doctests. -- $setup ) where import Control.Monad (guard) import Control.Monad.IO.Class (MonadIO (liftIO)) import Crypto.Error (throwCryptoError) import Crypto.KDF.Argon2 as Argon2 (Options (..), Variant (..), Version (..), hash) import Data.ByteArray (Bytes, constEq, convert) import Data.ByteString as B (ByteString, length) import Data.ByteString.Base64 (encodeBase64) import Data.Maybe (fromMaybe) #if !MIN_VERSION_base(4,13,0) import Data.Semigroup ((<>)) #endif import Data.Text (Text) import qualified Data.Text as T (intercalate, split, splitAt, stripPrefix) import Data.Word (Word32) import Data.Password.Internal ( PasswordCheck (..), from64, readT, showT, toBytes, unsafePad64, unsafeRemovePad64, ) import Data.Password.Types ( Password, PasswordHash (..), Salt (..), mkPassword, unsafeShowPassword, ) import qualified Data.Password.Internal (newSalt) -- | Phantom type for __Argon2__ -- -- @since 2.0.0.0 data Argon2 -- $setup -- >>> :set -XFlexibleInstances -- >>> :set -XOverloadedStrings -- -- Import needed libraries. -- -- >>> import Data.Password.Types -- >>> import Data.ByteString (pack) -- >>> import Test.QuickCheck (Arbitrary(arbitrary), Blind(Blind), vector) -- >>> import Test.QuickCheck.Instances.Text () -- -- >>> instance Arbitrary (Salt a) where arbitrary = Salt . pack <$> vector 16 -- >>> instance Arbitrary Password where arbitrary = fmap mkPassword arbitrary -- >>> let testParams = defaultParams {argon2TimeCost = 1} -- >>> let salt = Salt "abcdefghijklmnop" -- -- >>> instance Arbitrary (PasswordHash Argon2) where arbitrary = hashPasswordWithSalt testParams <$> arbitrary <*> arbitrary -- | Hash the 'Password' using the 'Argon2' hash algorithm -- -- >>> hashPassword $ mkPassword "foobar" -- PasswordHash {unPasswordHash = "$argon2id$v=19$m=65536,t=2,p=1$...$..."} hashPassword :: MonadIO m => Password -> m (PasswordHash Argon2) hashPassword = hashPasswordWithParams defaultParams -- | Parameters used in the 'Argon2' hashing algorithm. -- -- @since 2.0.0.0 data Argon2Params = Argon2Params { argon2Salt :: Word32, -- ^ Bytes to randomly generate as a unique salt, default is __16__ -- -- Limits are min: @8@, and max: @(2 ^ 32) - 1@ argon2Variant :: Argon2.Variant, -- ^ Which variant of Argon2 to use, default is __'Argon2id'__ argon2Version :: Argon2.Version, -- ^ Which version of Argon2 to use, default is __'Version13'__ argon2MemoryCost :: Word32, -- ^ Memory cost, given in /kibibytes/, default is __65536__ (i.e. 64MB) -- -- Limits are min: @8 * 'argon2Parallelism'@, and max is addressing -- space / 2, or @(2 ^ 32) - 1@, whichever is lower. argon2TimeCost :: Word32, -- ^ Amount of computation realized, default is __2__ -- -- Limits are min: @1@, and max: @(2 ^ 32) - 1@ argon2Parallelism :: Word32, -- ^ Parallelism factor, default is __1__ -- -- Limits are min: @1@, and max: @(2 ^ 24) - 1@ argon2OutputLength :: Word32 -- ^ Output key length in bytes, default is __32__ -- -- Limits are min: @4@, and max: @(2 ^ 32) - 1@ } deriving (Eq, Show) -- | Default parameters for the 'Argon2' algorithm. -- -- >>> defaultParams -- Argon2Params {argon2Salt = 16, argon2Variant = Argon2id, argon2Version = Version13, argon2MemoryCost = 65536, argon2TimeCost = 2, argon2Parallelism = 1, argon2OutputLength = 32} -- -- @since 2.0.0.0 defaultParams :: Argon2Params defaultParams = Argon2Params { argon2Salt = 16, argon2Variant = Argon2id, argon2Version = Version13, argon2MemoryCost = 2 ^ (16 :: Int), argon2TimeCost = 2, argon2Parallelism = 1, argon2OutputLength = 32 } -- | Hash a password with the given 'Argon2Params' and also with the given 'Salt' -- instead of a random generated salt using 'argon2Salt' from 'Argon2Params'. (cf. 'hashPasswordWithParams') -- Using 'hashPasswordWithSalt' is strongly __disadvised__ and 'hashPasswordWithParams' should be used instead. -- /Never use a static salt in production applications!/ -- -- __N.B.__: The salt HAS to be 8 bytes or more, or this function will throw an error! -- -- >>> let salt = Salt "abcdefghijklmnop" -- >>> hashPasswordWithSalt defaultParams salt (mkPassword "foobar") -- PasswordHash {unPasswordHash = "$argon2id$v=19$m=65536,t=2,p=1$YWJjZGVmZ2hpamtsbW5vcA$BztdyfEefG5V18ZNlztPrfZaU5duVFKZiI6dJeWht0o"} -- -- (Note that we use an explicit 'Salt' in the example above. This is so that the -- example is reproducible, but in general you should use 'hashPassword'. 'hashPassword' -- generates a new 'Salt' everytime it is called.) hashPasswordWithSalt :: Argon2Params -> Salt Argon2 -> Password -> PasswordHash Argon2 hashPasswordWithSalt params@Argon2Params{..} s@(Salt salt) pass = PasswordHash . mappend "$argon2" $ T.intercalate "$" [ variantToLetter argon2Variant , "v=" <> versionToNum argon2Version , parameters , encodeWithoutPadding salt , encodeWithoutPadding key ] where encodeWithoutPadding bs = unsafeRemovePad64 (B.length bs) $ encodeBase64 bs parameters = T.intercalate "," [ "m=" <> showT argon2MemoryCost , "t=" <> showT argon2TimeCost , "p=" <> showT argon2Parallelism ] key = hashPasswordWithSalt' params s pass -- | Only for internal use hashPasswordWithSalt' :: Argon2Params -> Salt Argon2 -> Password -> ByteString hashPasswordWithSalt' Argon2Params{..} (Salt salt) pass = convert (argon2Hash :: Bytes) where argon2Hash = throwCryptoError $ Argon2.hash options (toBytes $ unsafeShowPassword pass) (convert salt :: Bytes) $ fromIntegral argon2OutputLength options = Argon2.Options { iterations = argon2TimeCost, memory = argon2MemoryCost, parallelism = argon2Parallelism, variant = argon2Variant, version = argon2Version } -- | Hash a password using the 'Argon2' algorithm with the given 'Argon2Params'. -- -- __N.B.__: If you have any doubt in your knowledge of cryptography and/or the -- 'Argon2' algorithm, please just use 'hashPassword'. -- -- Advice to set the parameters: -- -- * Figure out how many threads you can use, choose "parallelism" accordingly. -- * Figure out how much memory you can use, choose "memory cost" accordingly. -- * Decide on the maximum time @x@ you can spend on it, choose the largest -- "time cost" such that it takes less than @x@ with your system and other -- parameter choices. -- -- @since 2.0.0.0 hashPasswordWithParams :: MonadIO m => Argon2Params -> Password -> m (PasswordHash Argon2) hashPasswordWithParams params pass = liftIO $ do salt <- Data.Password.Internal.newSalt . fromIntegral $ argon2Salt params return $ hashPasswordWithSalt params salt pass -- TODO: Parse different kinds of hashes, not only the ones from this library. -- e.g. hashes that miss the first $, or have 'argon2$' in front of the 'argon2id' part. -- | Check a 'Password' against a 'PasswordHash' 'Argon2'. -- -- Returns 'PasswordCheckSuccess' on success. -- -- >>> let pass = mkPassword "foobar" -- >>> passHash <- hashPassword pass -- >>> checkPassword pass passHash -- PasswordCheckSuccess -- -- Returns 'PasswordCheckFail' if an incorrect 'Password' or 'PasswordHash' 'Argon2' is used. -- -- >>> let badpass = mkPassword "incorrect-password" -- >>> checkPassword badpass passHash -- PasswordCheckFail -- -- This should always fail if an incorrect password is given. -- -- prop> \(Blind badpass) -> let correctPasswordHash = hashPasswordWithSalt testParams salt "foobar" in checkPassword badpass correctPasswordHash == PasswordCheckFail checkPassword :: Password -> PasswordHash Argon2 -> PasswordCheck checkPassword pass (PasswordHash passHash) = fromMaybe PasswordCheckFail $ do let paramList = T.split (== '$') passHash (argon2Params, salt, hashedKey) <- parseArgon2Params paramList let producedKey = hashPasswordWithSalt' argon2Params salt pass guard $ hashedKey `constEq` producedKey return PasswordCheckSuccess parseArgon2Params :: [Text] -> Maybe (Argon2Params, Salt Argon2, ByteString) -- vp - version or params -- ps - params or salt -- sh - salt or hash parseArgon2Params (_:variantT:vp:ps:sh:rest) = do variant <- parseVariant variantT case rest of -- If there is a 6th part, we'll assume the version is included [hashedKey64] -> do version <- parseVersion vp parseAll variant version ps sh hashedKey64 -- If there are only 5 parts, we'll assume the version is 'Version10' [] -> parseAll variant Version10 vp ps sh -- Any other amount of parts means the provided hash is malformed _ -> Nothing where parseVariant = splitMaybe "argon2" letterToVariant parseVersion = splitMaybe "v=" numToVersion -- If there are less than 5 parts, the hash is malformed parseArgon2Params _ = Nothing parseAll :: Argon2.Variant -> Argon2.Version -> Text -> Text -> Text -> Maybe (Argon2Params, Salt Argon2, ByteString) parseAll argon2Variant argon2Version parametersT salt64 hashedKey64 = do (argon2MemoryCost, argon2TimeCost, argon2Parallelism) <- parseParameters parametersT salt <- from64 $ unsafePad64 salt64 hashedKey <- from64 $ unsafePad64 hashedKey64 let argon2OutputLength = fromIntegral $ B.length hashedKey -- only here because of warnings argon2Salt = 16 -- only here because of warnings pure (Argon2Params{..}, Salt salt, hashedKey) where parseParameters paramsT = do let paramsL = T.split (== ',') paramsT guard $ Prelude.length paramsL == 3 go paramsL (Nothing, Nothing, Nothing) where go [] (Just m, Just t, Just p) = Just (m, t, p) go [] _ = Nothing go (x:xs) (m, t, p) = case T.splitAt 2 x of ("m=", i) -> go xs (readT i, t, p) ("t=", i) -> go xs (m, readT i, p) ("p=", i) -> go xs (m, t, readT i) _ -> Nothing -- | Strips the given 'match' if it matches and uses -- the function on the remainder of the given text. splitMaybe :: Text -> (Text -> Maybe a) -> Text -> Maybe a splitMaybe match f t = T.stripPrefix match t >>= f -- | Generate a random 16-byte @Argon2@ salt -- -- @since 2.0.0.0 newSalt :: MonadIO m => m (Salt Argon2) newSalt = Data.Password.Internal.newSalt 16 -- | Makes a letter out of the variant variantToLetter :: Argon2.Variant -> Text variantToLetter = \case Argon2i -> "i" Argon2d -> "d" Argon2id -> "id" -- | Parses the variant parameter in the encoded hash letterToVariant :: Text -> Maybe Argon2.Variant letterToVariant = \case "i" -> Just Argon2i "d" -> Just Argon2d "id" -> Just Argon2id _ -> Nothing -- | Parses the "v=" parameter in the encoded hash numToVersion :: Text -> Maybe Argon2.Version numToVersion "16" = Just Argon2.Version10 numToVersion "19" = Just Argon2.Version13 numToVersion _ = Nothing -- | Makes number for the "v=" parameter in the encoded hash versionToNum :: Argon2.Version -> Text versionToNum Version10 = "16" versionToNum Version13 = "19"