path: root/kiki.hs

{-# LANGUAGE DoAndIfThenElse #-}
{-# LANGUAGE ViewPatterns  #-}
{-# LANGUAGE TupleSections #-}
{-# LANGUAGE OverloadedStrings #-}
{-# LANGUAGE RankNTypes #-}
{-# LANGUAGE FlexibleInstances #-}
{-# LANGUAGE DeriveDataTypeable #-}
{-# LANGUAGE CPP #-}
module Main where

import Debug.Trace
import GHC.Exts (Down(..))
import GHC.IO.Exception ( ioException, IOErrorType(..) )
import Data.IORef
import Data.Tuple
import Data.Binary
import Data.OpenPGP as OpenPGP
import qualified Data.ByteString.Lazy as L
import qualified Data.ByteString.Lazy.Char8 as Char8
import qualified Data.ByteString      as S
import qualified Data.ByteString.Char8 as S8
import Control.Monad
import qualified Text.Show.Pretty as PP
import Text.PrettyPrint as PP hiding ((<>))
import Data.List
import Data.OpenPGP.Util (verify,fingerprint,decryptSecretKey,pgpSign)
import Data.Ord
import Data.Maybe
import Data.Bits
import qualified Data.Text as T
import Data.Text.Encoding
import qualified Codec.Binary.Base32 as Base32
import qualified Codec.Binary.Base64 as Base64
import qualified Crypto.Hash.SHA1 as SHA1
import qualified Crypto.Hash.SHA256 as SHA256
import qualified Crypto.Hash.RIPEMD160 as RIPEMD160
import qualified Crypto.Types.PubKey.ECC as ECC
-- import qualified Crypto.Types.PubKey.ECDSA as ECDSA
-- import qualified Crypto.PubKey.ECC.ECDSA as ECDSA

import Data.Char (toLower)
import qualified Crypto.PubKey.RSA as RSA
-- import Crypto.Random (newGenIO,SystemRandom)
import Data.ASN1.Types
import Data.ASN1.Encoding
import Data.ASN1.BinaryEncoding
import Data.ASN1.BitArray
import qualified Data.Foldable as Foldable
import qualified Data.Sequence as Sequence
import Control.Applicative
import System.Environment
import System.Directory
import System.FilePath
import System.Exit
import System.Process
import System.Posix.IO (fdToHandle,fdRead)
import System.Posix.Files
import System.Posix.Signals
import System.Posix.Types (EpochTime)
import System.Process.Internals (runGenProcess_,defaultSignal)
import System.IO (hPutStrLn,stderr,withFile,IOMode(..))
import System.IO.Error
import ControlMaybe
import Data.Char
import Control.Arrow (first,second)
import Data.Traversable hiding (mapM,forM,sequence)
import qualified Data.Traversable as Traversable (mapM,forM,sequence)
import System.Console.CmdArgs
-- import System.Posix.Time
import Data.Time.Clock.POSIX
import Data.Monoid ((<>))
-- import Data.X509
import qualified Data.Map as Map
import DotLock
-- import Codec.Crypto.ECC.Base -- hecc package
import Text.Printf
import qualified CryptoCoins as CryptoCoins
import qualified Hosts
import Network.Socket -- (SockAddr)


-- instance Default S.ByteString where def = S.empty

-- DER-encoded elliptic curve ids
nistp256_id  = 0x2a8648ce3d030107
secp256k1_id = 0x2b8104000a

isCryptoCoinKey p =
    and [ isKey p
        , key_algorithm p == ECDSA
        , lookup 'c' (key p) == Just (MPI secp256k1_id)
        ]

getCryptoCoinTag p | isSignaturePacket p = do
    -- CryptoCoins.secret
    let sps = hashed_subpackets p ++ unhashed_subpackets p
    u <- listToMaybe $ mapMaybe usage sps
    CryptoCoins.lookupNetwork CryptoCoins.network_name u
getCryptoCoinTag _ = Nothing

warn str = hPutStrLn stderr str

unprefix c spec = if null (snd p) then swap p else (fst p, tail (snd p))
 where p = break (==c) spec


data RSAPublicKey = RSAKey MPI MPI deriving Show
data PKCS8_RSAPublicKey = RSAKey8 MPI MPI deriving Show

pkcs8 (RSAKey n e) = RSAKey8 n e

instance ASN1Object RSAPublicKey where
    -- PKCS #1 RSA Public Key
    toASN1 (RSAKey (MPI n) (MPI e))
                  = \xs -> Start Sequence
                         : IntVal n
                         : IntVal e
                         : End Sequence
                         : xs
    fromASN1 _ =
        Left "fromASN1: RSAPublicKey: unexpected format"

instance ASN1Object PKCS8_RSAPublicKey where

    -- PKCS #8 Public key data
    toASN1 (RSAKey8 (MPI n) (MPI e))
                  = \xs -> Start Sequence
                         : Start Sequence
                         : OID [1,2,840,113549,1,1,1]
                         : End Sequence
                         : BitString (toBitArray bs 0)
                         : End Sequence
                         : xs
        where
            pubkey = Start Sequence : IntVal n : IntVal e : End Sequence : []
            bs = encodeASN1' DER pubkey

    fromASN1 (Start Sequence:IntVal modulus:IntVal pubexp:End Sequence:xs) =
        Right (RSAKey8 (MPI modulus) (MPI pubexp) , xs)
    fromASN1 (Start Sequence:Start Sequence:OID [1,2,840,113549,1,1,1]:End Sequence:BitString b:End Sequence:xs) =
        case decodeASN1' DER bs of
            Right as -> fromASN1 as
            Left e -> Left ("fromASN1: RSAPublicKey: "++show e)
      where
        BitArray _ bs = b

    fromASN1 _ =
        Left "fromASN1: RSAPublicKey: unexpected format"

data RSAPrivateKey = RSAPrivateKey
    { rsaN :: MPI
    , rsaE :: MPI
    , rsaD :: MPI
    , rsaP :: MPI
    , rsaQ :: MPI
    , rsaDmodP1 :: MPI
    , rsaDmodQminus1 :: MPI
    , rsaCoefficient :: MPI
    }
 deriving Show

{-
RSAPrivateKey ::= SEQUENCE {
  version           Version,
  modulus           INTEGER,  -- n
  publicExponent    INTEGER,  -- e
  privateExponent   INTEGER,  -- d
  prime1            INTEGER,  -- p
  prime2            INTEGER,  -- q
  exponent1         INTEGER,  -- d mod (p1) -- ?? d mod (p-1)
  exponent2         INTEGER,  -- d mod (q-1)
  coefficient       INTEGER,  -- (inverse of q) mod p
  otherPrimeInfos   OtherPrimeInfos OPTIONAL
}
-}

instance ASN1Object RSAPrivateKey where
    toASN1 rsa@(RSAPrivateKey {})
        = \xs -> Start Sequence
               : IntVal 0
               : mpiVal rsaN
               : mpiVal rsaE
               : mpiVal rsaD
               : mpiVal rsaP
               : mpiVal rsaQ
               : mpiVal rsaDmodP1
               : mpiVal rsaDmodQminus1
               : mpiVal rsaCoefficient
               : End Sequence
               : xs
                  where mpiVal f = IntVal x where MPI x = f rsa

    fromASN1 ( Start Sequence
             : IntVal _ -- version
             : IntVal n
             : IntVal e
             : IntVal d
             : IntVal p
             : IntVal q
             : IntVal dmodp1
             : IntVal dmodqminus1
             : IntVal coefficient
             : ys) =
        Right ( privkey, tail $ dropWhile notend ys)
         where
            notend (End Sequence) = False
            notend _              = True
            privkey = RSAPrivateKey
                { rsaN = MPI n
                , rsaE = MPI e
                , rsaD = MPI d
                , rsaP = MPI p
                , rsaQ = MPI q
                , rsaDmodP1 = MPI dmodp1
                , rsaDmodQminus1 = MPI dmodqminus1
                , rsaCoefficient = MPI coefficient
                }
    fromASN1 _ =
        Left "fromASN1: RSAPrivateKey: unexpected format"

rsaKeyFromPacket :: Packet -> Maybe RSAPublicKey
rsaKeyFromPacket p@(PublicKeyPacket {}) = do
    n <- lookup 'n' $ key p
    e <- lookup 'e' $ key p
    return $ RSAKey n e
rsaKeyFromPacket p@(SecretKeyPacket {}) = do
    n <- lookup 'n' $ key p
    e <- lookup 'e' $ key p
    return $ RSAKey n e
rsaKeyFromPacket _ = Nothing

derRSA rsa = do
    k <- rsaKeyFromPacket rsa
    return $ encodeASN1 DER (toASN1 k [])

rsaPrivateKeyFromPacket :: Packet -> Maybe RSAPrivateKey
rsaPrivateKeyFromPacket pkt@(SecretKeyPacket {}) = do
    -- public fields...
    n <- lookup 'n' $ key pkt
    e <- lookup 'e' $ key pkt
    -- secret fields
    MPI d <- lookup 'd' $ key pkt
    MPI q <- lookup 'p' $ key pkt -- Note: p & q swapped
    MPI p <- lookup 'q' $ key pkt -- Note: p & q swapped

    -- Note: Here we fail if 'u' key is missing.
    -- Ideally, it would be better to compute (inverse q) mod p
    -- see Algebra.Structures.EuclideanDomain.extendedEuclidAlg
    --     (package constructive-algebra)
    coefficient <- lookup 'u' $ key pkt 

    let dmodp1 = MPI $ d `mod` (p - 1)
        dmodqminus1 = MPI $ d `mod` (q - 1)
    return $ RSAPrivateKey 
        { rsaN = n
        , rsaE = e
        , rsaD = MPI d
        , rsaP = MPI p
        , rsaQ = MPI q
        , rsaDmodP1 = dmodp1
        , rsaDmodQminus1 = dmodqminus1
        , rsaCoefficient = coefficient }
rsaPrivateKeyFromPacket _ = Nothing


getPackets :: IO [Packet]
getPackets = do
    input <- L.getContents
    case decodeOrFail input of
        Right (_,_,Message pkts) -> return pkts
        Left  (_,_,_)            -> return []


secretToPublic pkt@(SecretKeyPacket {}) =
    PublicKeyPacket { version = version pkt
                    , timestamp = timestamp pkt
                    , key_algorithm = key_algorithm pkt
                    -- , ecc_curve = ecc_curve pkt
                    , key = let seckey = key pkt
                                pubs = public_key_fields (key_algorithm pkt)
                            in filter (\(k,v) -> k `elem` pubs) seckey
                    , is_subkey = is_subkey pkt
                    , v3_days_of_validity = Nothing
                    }
secretToPublic pkt = pkt


extractPEM typ pem = dta
 where
    dta = case ys of
            _:dta_lines -> Char8.concat dta_lines
            []          -> ""
    xs = dropWhile (/="-----BEGIN " <> typ <> "-----") (Char8.lines pem)
    ys = takeWhile (/="-----END " <> typ <> "-----") xs

writePEM typ dta = pem
 where
    pem = unlines . concat $
            [ ["-----BEGIN " <> typ <> "-----"]
            , split64s dta
            , ["-----END " <> typ <> "-----"] ]
    split64s "" = []
    split64s dta = line : split64s rest where (line,rest) = splitAt 64 dta

    -- 64 byte lines

isKey (PublicKeyPacket {}) = True
isKey (SecretKeyPacket {}) = True
isKey _                    = False

isUserID (UserIDPacket {}) = True
isUserID _                 = False

isEmbeddedSignature (EmbeddedSignaturePacket {}) = True
isEmbeddedSignature _                            = False

isCertificationSig (CertificationSignature {}) = True
isCertificationSig _                           = True

isTrust (TrustPacket {}) = True
isTrust _                = False

issuer (IssuerPacket issuer) = Just issuer
issuer _                     = Nothing
backsig (EmbeddedSignaturePacket s) = Just s
backsig _                           = Nothing

isSubkeySignature (SubkeySignature {}) = True
isSubkeySignature _                    = False

isPublicMaster k@(PublicKeyPacket {}) = not $ is_subkey k
isPublicMaster _ = False

now = floor <$> Data.Time.Clock.POSIX.getPOSIXTime

usage (NotationDataPacket
        { human_readable = True
        , notation_name  = "usage@"
        , notation_value = u
        }) = Just u
usage _    = Nothing

verifyBindings keys nonkeys = (top ++ filter isSubkeySignature embedded,othersigs)
 where
    verified = do
        sig <- signatures (Message nonkeys)
        let v = verify (Message keys) sig
        guard (not . null $ signatures_over v)
        return v
    (top,othersigs) = partition isSubkeySignature verified
    embedded = do
        sub <- top
        let sigover = signatures_over sub
            unhashed = sigover >>= unhashed_subpackets
            subsigs = mapMaybe backsig unhashed
            -- This should consist only of 0x19 values
            -- subtypes = map signature_type subsigs
        -- trace ("subtypes = "++show subtypes) (return ())
        -- trace ("issuers: "++show (map signature_issuer subsigs)) (return ())
        sig <- signatures (Message ([topkey sub,subkey sub]++subsigs))
        let v = verify (Message [subkey sub]) sig
        guard (not . null $ signatures_over v)
        return v

grip k = drop 32 $ fingerprint k

smallpr k = drop 24 $ fingerprint k

-- matchpr computes the fingerprint of the given key truncated to
-- be the same lenght as the given fingerprint for comparison.
matchpr fp k = reverse $ zipWith const (reverse (fingerprint k)) fp


disjoint_fp ks = {- concatMap group2 $ -} transpose grouped
 where
    grouped    = groupBy samepr . sortBy (comparing smallpr) $ ks
    samepr a b = smallpr a == smallpr b

    {-
    -- useful for testing
    group2 :: [a] -> [[a]]
    group2 (x:y:ys) = [x,y]:group2 ys
    group2 [x]      = [[x]]
    group2 []       = []
    -}

verifyBindingsEx :: [Packet] -> ([SignatureOver], [SignatureOver]) -- ^ (binding signatures, other signatures)
verifyBindingsEx pkts = bicat . unzip $ do
        let (keys,_) = partition isKey pkts
        keys <- disjoint_fp keys
        return $ verifyBindings keys pkts
 where
    bicat (xs,ys) = (concat xs,concat ys)

getBindings ::
  [Packet]
  ->
    ( [([Packet],[SignatureOver])] -- ^ other signatures with key sets
                                   --   that were used for the verifications
    , [(Word8,
       (Packet, Packet), -- (topkey,subkey)
       [String],         -- usage flags
       [SignatureSubpacket], -- hashed data
       [Packet])] -- ^ binding signatures
    )
getBindings pkts = (sigs,bindings)
 where
    (sigs,concat->bindings) = unzip $ do
        let (keys,nonkeys) = partition isKey pkts
        keys <- disjoint_fp keys
        let (bs,sigs) = verifyBindings keys pkts
        return . ((keys,sigs),) $ do
            b <- bs -- trace ("sigs = "++show (map (map signature_issuer . signatures_over) sigs)) bs
            i <- map signature_issuer (signatures_over b)
            i <- maybeToList i
            who <- maybeToList $ find_key fingerprint (Message keys) i
            let (code,claimants) =
                    case () of
                        _ | who == topkey b -> (1,[])
                        _ | who == subkey b -> (2,[])
                        _                   -> (0,[who])
            let hashed = signatures_over b >>= hashed_subpackets
                kind = guard (code==1) >> hashed >>= maybeToList . usage
            return (code,(topkey b,subkey b), kind, hashed,claimants)

-- Returned data is simmilar to getBindings but the Word8 codes
-- are ORed together.
accBindings ::
  Bits t =>
  [(t, (Packet, Packet), [a], [a1], [a2])]
  -> [(t, (Packet, Packet), [a], [a1], [a2])]
accBindings bs = as
  where
    gs = groupBy samePair . sortBy (comparing bindingPair) $ bs
    as = map (foldl1 combine) gs
    bindingPair (_,p,_,_,_) = pub2 p
      where
        pub2 (a,b) = (pub a, pub b)
        pub a = fingerprint_material a
    samePair a b = bindingPair a == bindingPair b
    combine (ac,p,akind,ahashed,aclaimaints)
            (bc,_,bkind,bhashed,bclaimaints)
        = (ac .|. bc,p,akind++bkind,ahashed++bhashed,aclaimaints++bclaimaints)


data UserIDRecord = UserIDRecord {
    uid_full :: String,
    uid_realname :: T.Text,
    uid_user :: T.Text,
    uid_subdomain :: T.Text,
    uid_topdomain :: T.Text
}
 deriving Show

isBracket '<' = True
isBracket '>' = True
isBracket _   = False

parseUID str = UserIDRecord {
                    uid_full = str,
                    uid_realname = realname,
                    uid_user = user,
                    uid_subdomain = subdomain,
                    uid_topdomain = topdomain
                }
 where
    text = T.pack str
    (T.strip-> realname, T.dropAround isBracket-> email)
                              = T.break (=='<') text
    (user, T.drop 1-> hostname) = T.break (=='@') email
    ( T.reverse            -> topdomain,
      T.reverse . T.drop 1 -> subdomain)
                              = T.break (=='.') . T.reverse $ hostname


derToBase32 = map toLower . Base32.encode . S.unpack . SHA1.hashlazy

fpmatch grip key =
    (==) Nothing
         (fmap (backend (fingerprint key)) grip >>= guard . not)
 where
    backend xs ys = and $ zipWith (==) (reverse xs) (reverse ys)

listKeys pkts = listKeysFiltered [] pkts

ecc_curve k = printf "%x" num :: String
 where unmpi (MPI num) = num
       num =  maybe 0 unmpi $ lookup 'c' (key k)

listKeysFiltered grips pkts = do
    let (certs,bs) = getBindings pkts
        as = accBindings bs
        defaultkind (k:_) hs = k
        defaultkind []    hs = maybe "subkey"
                                     id
                                     ( listToMaybe
                                     . mapMaybe (fmap usageString . keyflags)
                                     $ hs)
        kinds = map (\(_,_,k,h,_)->defaultkind k h) as
        kindwidth = maximum $ map length kinds
        kindcol = min 20 kindwidth
        code (c,(m,s),_,_,_) = (fingerprint_material m,-c)
        ownerkey (_,(a,_),_,_,_) = a
        sameMaster (ownerkey->a) (ownerkey->b) = fingerprint_material a==fingerprint_material b
        matchgrip _ | null grips = True
        matchgrip ((code,(top,sub), kind, hashed,claimants):_) | any (flip fpmatch top . Just) grips = True
        matchgrip _ = False
        gs = filter matchgrip $ groupBy sameMaster (sortBy (comparing code) as)
        showsigs claimants = map (\k -> "      " ++ "^ signed: " ++ fingerprint k) claimants
    subs <- gs
    let (code,(top,sub), kind, hashed,claimants):_ = subs
        subkeys = do
            (code,(top,sub), kind, hashed,claimants) <- subs
            let ar = case code of
                        0 -> " ??? "
                        1 -> " --> "
                        2 -> " <-- "
                        3 -> " <-> "
                formkind = take kindcol $ defaultkind kind hashed ++ repeat ' '
                torhash = maybe "" id $ derToBase32 <$> derRSA sub
                (netid,kind') = maybe (0x0,"bitcoin")
                                      (\n->(CryptoCoins.publicByteFromName n,n))
                                      $ listToMaybe kind
            unlines $
                concat  [ " "
                        -- , grip top
                        , ar
                        , formkind
                        , " "
                        , fingerprint sub
                        -- , " " ++ torhash
                        -- , " " ++ (concatMap (printf "%02X") $ S.unpack (ecc_curve sub))
                        ] -- ++ ppShow hashed
                    : if isCryptoCoinKey sub
                        -- then ("      " ++ "B⃦ " ++ bitcoinAddress sub) : showsigs claimants
                        -- then ("      " ++ "BTC " ++ bitcoinAddress sub) : showsigs claimants
                        then ("      " ++ "¢ "++kind'++":" ++ bitcoinAddress netid sub) : showsigs claimants
                        else showsigs claimants
        torkeys = do
            (code,(top,sub), kind, hashed,claimants) <- subs
            guard ("tor" `elem` kind)
            guard (code .&. 0x2 /= 0)
            maybeToList $ derToBase32 <$> derRSA sub
        uid = {- maybe "" id . listToMaybe $ -} do
            (keys,sigs) <- certs
            sig <- sigs
            guard (isCertificationSig sig)
            guard (topkey sig == top)
            let issuers = do
                    sig_over <- signatures_over sig
                    i <- maybeToList $ signature_issuer sig_over
                    maybeToList $ find_key (matchpr i) (Message keys) (reverse (take 16 (reverse i)))
                (primary,secondary) = partition (==top) issuers

            -- trace ("PRIMARY: "++show (map fingerprint primary)) $ return ()
            -- trace ("SECONDARY: "++show (map fingerprint secondary)) $ return ()
            guard (not (null primary))

            let UserIDPacket uid = user_id sig
                parsed = parseUID uid
                ar = maybe " --> " (const " <-> ") $ do
                        guard (uid_topdomain parsed == "onion" )
                        guard ( uid_realname parsed `elem` ["","Anonymous"])
                        guard (     uid_user parsed == "root" )
                        let subdom0 = L.fromChunks [encodeUtf8 (uid_subdomain parsed)]
                            len = L.length subdom0
                            subdom = Char8.unpack subdom0
                            match = ( (==subdom) . take (fromIntegral len))
                        guard (len >= 16)
                        listToMaybe $ filter match torkeys
            unlines $ [ " " ++ ar ++ "@" ++ " " ++ uid_full parsed ]
                    ++ showsigs secondary
        (_,sigs) = unzip certs
    "master-key " ++ fingerprint top ++ "\n" ++ uid ++"  ...\n" ++ subkeys ++ "\n"


data PGPKeyFlags =
    Special
    | Vouch -- Signkey
    | Sign
    | VouchSign
    | Communication
    | VouchCommunication
    | SignCommunication
    | VouchSignCommunication
    | Storage
    | VouchStorage
    | SignStorage
    | VouchSignStorage
    | Encrypt
    | VouchEncrypt
    | SignEncrypt
    | VouchSignEncrypt
 deriving (Eq,Show,Read,Enum)

usageString flgs =
 case flgs of
    Special -> "special"
    Vouch -> "vouch" -- signkey
    Sign -> "sign"
    VouchSign -> "vouch-sign"
    Communication -> "communication"
    VouchCommunication -> "vouch-communication"
    SignCommunication -> "sign-communication"
    VouchSignCommunication -> "vouch-sign-communication"
    Storage -> "storage"
    VouchStorage -> "vouch-storage"
    SignStorage -> "sign-storage"
    VouchSignStorage -> "vouch-sign-storage"
    Encrypt -> "encrypt"
    VouchEncrypt -> "vouch-encrypt"
    SignEncrypt -> "sign-encrypt"
    VouchSignEncrypt -> "vouch-sign-encrypt"


keyflags flgs@(KeyFlagsPacket {}) =
    Just . toEnum $
        (   bit 0x1 certify_keys
        .|. bit 0x2 sign_data
        .|. bit 0x4 encrypt_communication
        .|. bit 0x8 encrypt_storage )     :: Maybe PGPKeyFlags
    -- other flags:
    --  split_key
    --  authentication (ssh-client)
    --  group_key
 where
    bit v f = if f flgs then v else 0
keyflags _ = Nothing


modifyUID (UserIDPacket str) = UserIDPacket str'
 where
    (fstname,rst) = break (==' ') str
    str' = mod fstname ++ rst
    mod "Bob" = "Bob Fucking"
    mod x     = x
modifyUID other              = other

todo = error "unimplemented"

-- TODO: switch to System.Environment.lookupEnv
--       when linking against newer base libraries.
lookupEnv var =
    handleIO_ (return Nothing) $ fmap Just (getEnv var)

unmaybe def = fmap (maybe def id)

expandPath path (c:cs) | c/='/'    = path ++ "/" ++ (c:cs)
                       | otherwise = c:cs
expandPath path []                 = []


-- type TimeStamp = Word32

slurpWIPKeys :: System.Posix.Types.EpochTime -> L.ByteString -> ( [(Word8,Packet)], [L.ByteString])
slurpWIPKeys stamp "" = ([],[])
slurpWIPKeys stamp cs =
    let (b58,xs) = Char8.span (\x -> elem x base58chars) cs
        mb        = decode_btc_key stamp (Char8.unpack b58)
    in if L.null b58 
        then let (ys,xs') = Char8.break (\x -> elem x base58chars) cs
                 (ks,js)  = slurpWIPKeys stamp xs'
             in (ks,ys:js) 
        else let (ks,js) = slurpWIPKeys stamp xs
             in maybe (ks,b58:js) (\(net,Message [k])->((net,k):ks,js)) mb

readPacketsFromWallet :: 
    Maybe Packet
    -> FilePath 
    -> IO [(Packet,Packet,(Packet,Map.Map FilePath Packet))]
readPacketsFromWallet wk fname = do
    timestamp <- handleIO_ (error $ fname++": modificaiton time?") $ 
                    modificationTime <$> getFileStatus fname
    input <- L.readFile fname
    let (ks,junk) = slurpWIPKeys timestamp input
    when (not (null ks)) $ do
        -- decrypt wk
        -- create sigs
        -- return key/sig pairs
        return ()
    return $ do
        wk <- maybeToList wk
        guard (not $ null ks)
        let prep (tagbyte,k) = (wk,k,(k,Map.singleton tag wk))
                                where tag = CryptoCoins.nameFromSecretByte tagbyte
        (wk,MarkerPacket,(MarkerPacket,Map.empty))
         :map prep ks

readPacketsFromFile :: FilePath -> IO Message
readPacketsFromFile fname = do
    -- warn $ fname ++ ": reading..."
    input <- L.readFile fname
    return $
      case decodeOrFail input of
        Right (_,_,msg ) -> msg
        Left  (_,_,_)    -> trace (fname++": read fail") $ Message []

lockFiles fs = do
    let dolock f = do
            lk <- dotlock_create f 0
            let fail = return Nothing
                dotake lk = do
                    e <- dotlock_take lk (-1)
                    if e==0 then return (Just lk)
                            else fail
            v <- maybe fail dotake lk
            return (v,f)
    ls <- mapM dolock fs
    let (lks, fails) = partition (isJust . fst) ls
    return (map (\(lk,f)->(fromJust lk,f)) lks, map snd fails)

unlockFiles lks = forM_ lks $ \(lk,f) -> do
    -- warn $ "unlocking "++show f
    dotlock_release lk

parseOptionFile fname = do
    xs <- fmap lines (readFile fname)
    let ys = filter notComment xs
        notComment ('#':_) = False
        notComment cs      = not (all isSpace cs)
    return ys

{-
options_from_file ::
        (forall a. [String] -> Term a -> IO (Either EvalExit a))
        -> Term b
        -> (String,String,Term (Maybe String))
        -> ([String],Term (Maybe String))
        -> IO [String]
options_from_file unwrapCmd term (homevar,appdir,home) (optfile_alts,options_file) = doit
 where
    homedir = envhomedir <$> home
    envhomedir opt = do
        gnupghome <- lookupEnv homevar >>=
                  \d -> return $ d >>= guard . (/="") >> d
        home <- flip fmap getHomeDirectory $
                  \d -> fmap (const d) $ guard (d/="")
        let homegnupg = (++('/':appdir)) <$> home
        let val = (opt `mplus` gnupghome `mplus` homegnupg)
        return $ val

    doit = do
        args <- getArgs
        {-
        let wants_help =
                not . null $ filter cryForHelp args
                        where cryForHelp "--help"    = True
                              cryForHelp "--version" = True
                              cryForHelp x =
                                and (zipWith (==) x "--help=")
        -}
        (o,h) <- do
            val <- unwrapCmd args (liftA2 (,) options_file homedir)
            case val of
                Left e -> return (Nothing,Nothing)
                Right (o,h)    -> (o,) <$> h
        ofile <- fmap listToMaybe . flip (maybe (return [])) h $ \h ->
                let optfiles = map (second ((h++"/")++))
                                   (maybe optfile_alts' (:[]) o')
                    optfile_alts' = zip (False:repeat True) optfile_alts
                    o' = fmap (False,) o
                in filterM (doesFileExist . snd) optfiles
        args <- flip (maybe $ return args) ofile $ \(forgive,fname) -> do
            let h' = fromJust h
            newargs <- (:) <$> pure ("homedir "++h') <*> parseOptionFile fname
            let toArgs = toHead ("--"++) . words
                toHead f (x:xs) = f x : xs
                toHead f []     = []
                voidTerm = fmap (const ())
                appendArgs as [] = return as
                appendArgs as (configline:cs) = do
                    let xs = toArgs configline
                    w <-unwrap (xs++as) (voidTerm term,defTI)
                    case w of
                        Left  _ -> appendArgs as cs
                        Right _ -> appendArgs (xs++as) cs
            -- TODO: check errors if forgive = False
            appendArgs args newargs
        return args

runWithOptionsFile :: (Term (IO b), TermInfo) -> IO b
runWithOptionsFile (term,ti) = do
    as <- options_from_file unwrapCmd
                            term
                            ("GNUPGHOME",".gnupg",opt_homedir)
                            (["keys.conf","gpg.conf-2","gpg.conf"]
                            ,opt_options)
    q <- eval as (term , ti)
    q
 where
    unwrapCmd args term = unwrap args (term,defTI)

runChoiceWithOptionsFile ::
  (Term (IO b), TermInfo) -> [(Term (IO b), TermInfo)] -> IO b
runChoiceWithOptionsFile (realterm,ti) choices = do
    as <- options_from_file unwrapCmd
                            realterm
                            ("GNUPGHOME",".gnupg",opt_homedir)
                            (["keys.conf","gpg.conf-2","gpg.conf"]
                            ,opt_options)
    -- putStrLn $ "as = " ++ show as
    q <- evalChoice as (realterm , ti) choices
    q
 where
    unwrapCmd args t =
        unwrapChoice args (realterm <:> t,ti) (map (neuter t) choices)
    neuter term (t,ti) = (t <:> term, ti)

data Command =
    List
    | Autosign
 deriving (Eq,Show,Read,Enum)

capitolizeFirstLetter (x:xs) = toUpper x : xs
capitolizeFirstLetter xs     = xs

instance ArgVal Command where
    converter =
      ( maybe (Left $ text "unknown command") Right
        . fmap fst . listToMaybe . reads
        . capitolizeFirstLetter . map toLower
      , text . map toLower . show
      )
class AutoMaybe a
instance AutoMaybe Command
instance (ArgVal a, AutoMaybe a) => ArgVal (Maybe a) where
    converter =
      ( toRight Just . fst converter
      , maybe (text "(unspecified)") id . fmap (snd converter)
      )

toRight f (Right x) = Right (f x)
toRight f (Left y)  = Left  y

cmd :: Term Command
cmd = required . pos 0 Nothing $ posInfo
  { posName = "command"
  , posDoc  = "What action to perform."
  }

a <:> b = flip const <$> a <*> b
infixr 2 <:>

selectAction cmd actions = actions !! fromEnum cmd

cmdInfo :: ArgVal cmd =>
    cmd -> String -> Term a -> (cmd, (Term a, TermInfo))
cmdInfo cmd doc action =
    ( cmd
    , ( action
      , defTI { termName = print cmd
              , termDoc  = doc } ) )
  where
    print = show . snd converter

cmdlist :: (Command, (Term (IO ()), TermInfo))
cmdlist = cmdInfo List "list key pairs for which secrets are known" $
    (>>= putStrLn . listKeys . unMessage) <$> secret_packets
 where unMessage (Message pkts) = pkts

cmdautosign = cmdInfo Autosign "auto-sign tor-style uids" $
    pure (putStrLn "autosign")


multiCommand ::
  TermInfo
  -> [(Command, (Term a, TermInfo))]
  -> ( (Term a, TermInfo)
     , [(Term a, TermInfo)] )
multiCommand ti choices =
    ( ( selectAction <$> cmd <*> sequenceA (map strip choices)
      , ti )
    , map snd choices )
 where
    selectAction cmd choices =
        fromJust $ lookup (cmd::Command) choices
    strip (cmd,(action,_)) = fmap (cmd,) action
-}


trimCR bs = fst $ S.spanEnd (\x -> x==10 || x==13) bs

guessKeyFormat 'P' "ssh-client" = "SSH"
guessKeyFormat 'S' "ssh-client" = "PEM"
guessKeyFormat 'S' "ssh-host"   = "PEM"
guessKeyFormat _   _            = "PEM" -- "PGP"

writeKeyToFile False "PEM" fname packet =
    case key_algorithm packet of
    RSA -> do
        flip (maybe (return ()))
             (rsaPrivateKeyFromPacket packet) -- RSAPrivateKey
            $ \rsa -> do
        let asn1 = toASN1 rsa []
            bs = encodeASN1 DER asn1
            dta = Base64.encode (L.unpack bs)
            output = writePEM "RSA PRIVATE KEY" dta
            stamp = toEnum . fromEnum $ timestamp packet
        createDirectoryIfMissing True (takeDirectory fname)
        handleIO_ (warn $ fname ++ ": write failure") $ do
            saved_mask <- setFileCreationMask 0o077
            writeFile fname output
            -- Note: The key's timestamp is included in it's fingerprint.
            --       Therefore, we should attempt to preserve it.
            setFileTimes fname stamp stamp
            setFileCreationMask saved_mask
            return ()
        warn $ fname ++ ": exported"
        return ()
    algo -> warn $ fname ++ ": unable to export "++show algo++" key "++fingerprint packet

readKeyFromFile False "PEM" fname = do
    -- warn $ fname ++ ": reading ..."
    -- Note: The key's timestamp is included in it's fingerprint.
    --       Therefore, we should attempt to preserve it.
    timestamp <- handleIO_ (error $ fname++": modificaiton time?") $ 
                    modificationTime <$> getFileStatus fname
    input <- L.readFile fname
    let dta = extractPEM "RSA PRIVATE KEY" input
    -- Char8.putStrLn $ "dta = " <> dta
    let rsa = do
           e <- decodeASN1 DER . L.pack <$> Base64.decode (Char8.unpack dta)
           asn1 <- either (const Nothing) Just e
           k <- either (const Nothing) (Just . fst) (fromASN1 asn1)
           let _ = k :: RSAPrivateKey
           return k
    -- putStrLn $ "rsa = "++ show rsa
    return . Message $ do
        rsa <- maybeToList rsa
        return $ SecretKeyPacket
            { version = 4
            , timestamp = toEnum (fromEnum timestamp)
            , key_algorithm = RSA
            , key = [ -- public fields...
                     ('n',rsaN rsa)
                    ,('e',rsaE rsa)
                    -- secret fields
                    ,('d',rsaD rsa)
                    ,('p',rsaQ rsa) -- Note: p & q swapped
                    ,('q',rsaP rsa) -- Note: p & q swapped
                    ,('u',rsaCoefficient rsa)
                    ]
            -- , ecc_curve = def
            , s2k_useage = 0
            , s2k = S2K 100 ""
            , symmetric_algorithm = Unencrypted
            , encrypted_data = ""
            , is_subkey = True
            }
readKeyFromFile is_public fmt filename = error ("unimplemented key type: "++fmt)

getPassphrase cmd =
         case passphrase_fd cmd of
                Just fd -> do pwh <- fdToHandle (toEnum fd)
                              fmap trimCR $ S.hGetContents pwh
                Nothing -> return ""


#define HOMEOPTION (def &= explicit &= name "homedir" &= typDir )

data KeySpec =
      KeyGrip String
    | KeyTag Packet String
    | KeyUidMatch String
 deriving Show

is40digitHex xs = ys == xs && length ys==40
  where
    ys = filter ishex xs
    ishex c | '0' <= c && c <= '9' = True
            | 'A' <= c && c <= 'F' = True
            | 'a' <= c && c <= 'f' = True
    ishex c = False

scanPackets :: FilePath -> [Packet] -> [(Packet,Packet,(Packet,Map.Map FilePath Packet))]
scanPackets filename [] = []
scanPackets filename (p:ps) = scanl doit (doit (MarkerPacket,MarkerPacket,ret MarkerPacket) p) ps
 where
    ret p = (p,Map.empty)
    doit (top,sub,prev) p =
        case p of
            _ | isKey p && not (is_subkey p) -> (p,MarkerPacket,ret p)
            _ | isKey p && is_subkey p       -> (top,p,ret p)
            _ | isUserID p                   -> (top,p,ret p)
            _ | isTrust p                    -> (top,sub,updateTrust top sub prev p)
            _ | otherwise                    -> (top,sub,ret p)

    updateTrust top (PublicKeyPacket {}) (pre,t) p = (pre,Map.insert filename p t) -- public
    updateTrust (PublicKeyPacket {}) _   (pre,t) p = (pre,Map.insert filename p t) -- public
    updateTrust _                    _   (pre,t) p = (pre,Map.insert filename p t) -- secret


data OriginFlags = OriginFlags {
        originallyPublic :: Bool,
        originalNum :: Int
    }
    deriving Show
origin :: Packet -> Int -> OriginFlags
origin p n = OriginFlags ispub n
 where
    ispub = case p of
                    SecretKeyPacket {} -> False
                    _                  -> True

type OriginMap = Map.Map FilePath OriginFlags
data MappedPacket = MappedPacket
        { packet :: Packet
        , usage_tag :: Maybe String
        , locations :: OriginMap
        }

mappedPacket filename p = MappedPacket 
    { packet = p
    , usage_tag = Nothing
    , locations = Map.singleton filename (origin p (-1))
    }

type TrustMap = Map.Map FilePath Packet
type SigAndTrust = ( MappedPacket
                   , TrustMap     ) -- trust packets

type KeyKey = [Char8.ByteString]
data SubKey = SubKey MappedPacket [SigAndTrust]
data KeyData = KeyData MappedPacket    -- main key
                       [SigAndTrust]  -- sigs on main key
                       (Map.Map String ([SigAndTrust],OriginMap))  -- uids
                       (Map.Map KeyKey SubKey)    -- subkeys

type KeyDB = Map.Map KeyKey KeyData

torhash key = maybe "" id $ derToBase32 <$> derRSA key

keykey key =
    -- Note: The key's timestamp is included in it's fingerprint.
    --       Therefore, the same key with a different timestamp is
    --       considered distinct using this keykey implementation.
    fingerprint_material (key {timestamp=0}) -- TODO: smaller key?



uidkey (UserIDPacket str) = str

-- Compare master keys, LT is prefered for merging
keycomp (SecretKeyPacket {}) (PublicKeyPacket {}) = LT
keycomp (PublicKeyPacket {}) (SecretKeyPacket {}) = GT
keycomp a b | keykey a==keykey b = EQ
keycomp a b = error $ unlines ["Unable to merge keys:"
                              , fingerprint a
                              , PP.ppShow a
                              , fingerprint b
                              , PP.ppShow b
                              ]

-- Compare subkeys, LT is prefered for merging
subcomp (SecretKeyPacket {}) (PublicKeyPacket {}) = LT
subcomp (PublicKeyPacket {}) (SecretKeyPacket {}) = GT
subcomp a b | keykey a==keykey b = EQ
subcomp a b = error $ unlines ["Unable to merge subs:"
                              , fingerprint a
                              , PP.ppShow a
                              , fingerprint b
                              , PP.ppShow b
                              ]
subcomp_m a b = subcomp (packet a) (packet b)

merge :: KeyDB -> FilePath -> Message -> KeyDB
merge db filename (Message ps) = merge_ db filename qs
 where
    qs = scanPackets filename ps

merge_ :: KeyDB -> FilePath -> [(Packet,Packet,(Packet,Map.Map FilePath Packet))]
                -> KeyDB
merge_ db filename qs = foldl mergeit db (zip [0..] qs)
 where
    asMapped n p = let m = mappedPacket filename p
                   in m { locations = fmap (\x->x {originalNum=n}) (locations m) }
    asSigAndTrust n (p,tm) = (asMapped n p,tm)
    emptyUids = Map.empty
    -- mergeit db (_,_,TrustPacket {}) = db -- Filter TrustPackets
    mergeit :: KeyDB -> (Int,(Packet,Packet,(Packet,Map.Map FilePath Packet))) -> KeyDB
    mergeit db (n,(top,sub,ptt@(p,trustmap))) | isKey top = Map.alter update (keykey top) db
     where
        -- NOTE:
        --  if a keyring file has both a public key packet and a secret key packet
        --  for the same key, then only one of them will survive, which ever is 
        --  later in the file.
        -- 
        --  This is due to the use of statements like 
        --      (Map.insert filename (origin p n) (locations key))
        --
        update v | isKey p && not (is_subkey p)
          = case v of
             Nothing -> Just $ KeyData (asMapped n p) [] emptyUids Map.empty
             Just (KeyData key sigs uids subkeys) | keykey (packet key) == keykey p
                     -> Just $ KeyData ( (asMapped n (minimumBy keycomp [packet key,p]))
                                          { locations = Map.insert filename (origin p n) (locations key) } )
                                       sigs
                                       uids
                                       subkeys
             _       -> error . concat $ ["Unexpected master key merge error: "
                                         ,show (fingerprint top, fingerprint p)]
        update (Just (KeyData key sigs uids subkeys)) | isKey p && is_subkey p
          = Just $ KeyData key sigs uids (Map.alter (mergeSubkey n p) (keykey p) subkeys)
        update (Just (KeyData key sigs uids subkeys)) | isUserID p
          = Just $ KeyData key sigs (Map.alter (mergeUid n ptt) (uidkey p) uids)
                                    subkeys
        update (Just (KeyData key sigs uids subkeys))
          = case sub of
             MarkerPacket    -> Just $ KeyData key (mergeSig n ptt sigs) uids subkeys
             UserIDPacket {} -> Just $ KeyData key
                                               sigs
                                               (Map.alter (mergeUidSig n ptt) (uidkey sub) uids)
                                               subkeys
             _  | isKey sub  -> Just $ KeyData key
                                               sigs
                                               uids
                                               (Map.alter (mergeSubSig n ptt) (keykey sub) subkeys)
             _ -> error $ "Unexpected PGP packet 1: "++(words (show p) >>= take 1)
        update _ = error $ "Unexpected PGP packet 2: "++(words (show p) >>= take 1)

    mergeit _  (_,(_,_,p)) = error $ "Unexpected PGP packet 3: "++whatP p

    mergeSubkey :: Int -> Packet -> Maybe SubKey -> Maybe SubKey
    mergeSubkey n p Nothing                  = Just $ SubKey (asMapped n p) []
    mergeSubkey n p (Just (SubKey key sigs)) = Just $
        SubKey ((asMapped n (minimumBy subcomp [packet key,p]))
                 { locations = Map.insert filename (origin p n) (locations key) })
               sigs

    mergeUid :: Int ->(Packet,a) -> Maybe ([SigAndTrust],OriginMap) -> Maybe ([SigAndTrust],OriginMap)
    mergeUid n (UserIDPacket s,_) Nothing         = Just ([],Map.singleton filename (origin MarkerPacket n))
    mergeUid n (UserIDPacket s,_) (Just (sigs,m)) = Just (sigs, Map.insert filename (origin MarkerPacket n) m)
    mergeUid n p _ = error $ "Unable to merge into UID record: " ++whatP p

    whatP (a,_) = concat . take 1 . words . show $ a


    mergeSig :: Int -> (Packet,TrustMap) -> [SigAndTrust] -> [SigAndTrust]
    mergeSig n sig sigs =
      let (xs,ys) = break (isSameSig sig) sigs
      in if null ys
          then sigs++[first (asMapped n) sig]
          else let y:ys'=ys
               in xs ++ (mergeSameSig n sig y : ys')


    isSameSig (a,_) (MappedPacket {packet=b},_) | isSignaturePacket a && isSignaturePacket b =
        a { unhashed_subpackets=[] } == b { unhashed_subpackets = [] }
    isSameSig (a,_) (MappedPacket {packet=b},_) = a==b

    mergeSameSig :: Int -> (Packet,TrustMap) -> (MappedPacket,TrustMap) -> (MappedPacket, TrustMap)
    mergeSameSig n (a,ta) (m@(MappedPacket{packet=b,locations=locs}),tb) | isSignaturePacket a && isSignaturePacket b =
       ( m { packet = (b { unhashed_subpackets =
                            foldl mergeItem (unhashed_subpackets b) (unhashed_subpackets a) })
           , locations = Map.insert filename (origin a n) locs }
        , tb `Map.union` ta )

     where
        -- TODO: when merging items, we should delete invalidated origins
        -- from the orgin map.
        mergeItem ys x = if x `elem` ys then ys else ys++[x]

    mergeSameSig n a b = trace ("discarding dup "++show a) b

    mergeUidSig n sig (Just (sigs,m)) = Just (mergeSig n sig sigs, m)
    mergeUidSig n sig Nothing     = Just ([asSigAndTrust n sig],Map.empty)

    mergeSubSig n sig (Just (SubKey key sigs)) = Just $ SubKey key (mergeSig n sig sigs)
    mergeSubSig n sig Nothing = error $
        "Unable to merge subkey signature: "++(words (show sig) >>= take 1)

flattenKeys :: Bool -> KeyDB -> Message
flattenKeys isPublic db = Message $ concatMap (map packet . flattenTop "" isPublic . snd) (prefilter . Map.assocs $ db)
 where
    prefilter = if isPublic then id else filter isSecret
                 where
                  isSecret (_,(KeyData
                                  (MappedPacket { packet=(SecretKeyPacket {})})
                                  _
                                  _
                                  _)) = True
                  isSecret _          = False


concatSort fname getp f = concat . sortByHint fname getp . map f

flattenTop :: FilePath -> Bool -> KeyData -> [MappedPacket]
flattenTop fname ispub (KeyData key sigs uids subkeys) =
    unk ispub key : 
            ( flattenAllUids fname ispub uids
             ++ concatSort fname head (flattenSub fname ispub) (Map.elems subkeys))

flattenAllUids :: FilePath -> Bool -> Map.Map String ([SigAndTrust],OriginMap) -> [MappedPacket]
flattenAllUids fname ispub uids =
    concatSort fname head (flattenUid fname ispub) (Map.assocs uids)

flattenUid :: FilePath -> Bool -> (String,([SigAndTrust],OriginMap)) -> [MappedPacket]
flattenUid fname ispub (str,(sigs,om)) = 
    (mappedPacket "" $ UserIDPacket str) {locations=om} : concatSort fname head (unsig fname ispub) sigs

flattenSub :: FilePath -> Bool -> SubKey -> [MappedPacket]
flattenSub fname ispub (SubKey key sigs) = unk ispub key: concatSort fname head (unsig fname ispub) sigs

unk :: Bool -> MappedPacket -> MappedPacket
unk isPublic = if isPublic then toPacket secretToPublic else id
                where toPacket f mp@(MappedPacket {packet=p}) = mp {packet=(f p)}

unsig :: FilePath -> Bool -> SigAndTrust -> [MappedPacket]
unsig fname isPublic (sig,trustmap) = 
    [sig]++ map (asMapped (-1)) ( take 1 . Map.elems $ Map.filterWithKey f trustmap)
  where
    f n _ = n==fname -- && trace ("fname=n="++show n) True
    asMapped n p = let m = mappedPacket fname p
                   in m { locations = fmap (\x->x {originalNum=n}) (locations m) }

ifSecret (SecretKeyPacket {}) t f = t
ifSecret _                    t f = f

showPacket :: Packet -> String
showPacket p | isKey p   = (if is_subkey p 
                              then showPacket0 p
                              else ifSecret p "----Secret-----" "----Public-----")
                           ++ " "++show (key_algorithm p)++" "++fingerprint p
             | isUserID p = showPacket0 p ++ " " ++ show (uidkey p)
             | otherwise = showPacket0 p
showPacket0 p = concat . take 1 $ words (show p)

sortByHint fname f = sortBy (comparing gethint)
  where
    gethint = maybe defnum originalNum . Map.lookup fname . locations . f
    defnum = -1

keyPacket (KeyData k _ _ _) = k

writeOutKeyrings :: Map.Map FilePath DotLock -> KeyDB -> IO ()
writeOutKeyrings lkmap db = do
    let ks = Map.elems db
        fs = Map.keys (foldr unionfiles Map.empty ks)
                where unionfiles (KeyData p _ _ _) m =
                        Map.union m (locations p)
        fromfile f (KeyData p _ _ _) = Map.member f $ locations p
    let s = do
        f <- fs
        let x = do
                d@(KeyData p _ _ _) <- filter (fromfile f) (sortByHint f keyPacket ks)
                n <- maybeToList $ Map.lookup f (locations p)
                flattenTop f (originallyPublic n) d
            changes = filter isnew x
                where isnew p = isNothing (Map.lookup f $ locations p)
        {-
        trace (unlines $ ( (f ++ ":") : map (showPacket . packet) x) ++
                  ( "CHANGES: " : map (("  "++) . showPacket . packet) changes)) $ do
        -}
        return (f,(changes,x))
    towrites <- fmap catMaybes $ Control.Monad.forM s $ \(f,(changes,x)) -> do
        let noop    = return Nothing
            write f = return (Just f)
        case changes of
            [] -> noop -- warn (f ++": nothing to do.") >> noop
            cs -> case Map.lookup f lkmap of
                    Just lk -> do
                         forM_ cs $ \c -> warn $ f++": new "++showPacket (packet c)
                         write (f,lk,x)
                    Nothing -> do
                         forM_ cs $ \c -> warn $ f++": missing "++showPacket (packet c)
                         noop
    forM_ towrites $ \(f,lk,x) -> do
        let m = Message $ map packet x
        -- warn $ "writing "++f
        L.writeFile f (encode m)

cross_merge doDecrypt grip0 keyrings wallets f = do
        let relock = do
                (fsns,failed_locks) <- lockFiles keyrings
                (wsns,failed_wlocks) <- lockFiles wallets
                forM_ (failed_locks++failed_wlocks) $ \f -> warn $ "Failed to lock: " ++ f
                return (fsns,wsns,failed_locks,failed_wlocks)
            sec_n:_ = keyrings
        (fsns,wsns,failed_locks,failed_wlocks) <- relock
        -- let (lks,fs) = unzip fsns
        -- forM_ fs $ \f -> warn $ "locked: " ++ f
        let readp n = fmap (n,) (readPacketsFromFile n)
            readw wk n = fmap (n,) (readPacketsFromWallet wk n)
        let pass n (fsns,failed_locks) = do
                ms <- mapM readp (map snd fsns++failed_locks)
                let db0 = foldl' (uncurry . merge) Map.empty ms
                    fstkey = listToMaybe $ mapMaybe isSecringKey ms 
                              where isSecringKey (fn,Message ps)
                                        | fn==sec_n = listToMaybe ps
                                    isSecringKey _  = Nothing
                    grip = grip0 `mplus` (fingerprint <$> fstkey)
                    wk = listToMaybe $ do
                            fp <- maybeToList grip
                            elm <- Map.toList db0
                            guard $ matchSpec (KeyGrip fp) elm
                            let undata (KeyData p _ _ _) = packet p
                            return $ undata (snd elm)
                wms <- mapM (readw wk) (map snd wsns++failed_wlocks)
                let -- db1= foldl' (uncurry . merge_) db0 wms
                    ts = do
                        maybeToList wk
                        (fname,xs) <- wms
                        (_,sub,(_,m)) <- xs
                        (tag,top) <- Map.toList m
                        return (top,fname,sub,tag)

                -- sig' <- makeSig doDecrypt top fname subkey_p tag mbsig
                    importWalletKey db' (top,fname,sub,tag) = do
                        doImportG doDecrypt 
                                  db'
                                  (fmap keykey $ maybeToList wk)
                                  tag
                                  fname
                                  sub
                db <- foldM importWalletKey db0 ts
                let cs = do
                        wk <- maybeToList wk
                        let kk = keykey wk
                        KeyData top topsigs uids subs <- maybeToList $ Map.lookup kk db
                        (subkk,SubKey mp sigs) <- Map.toList subs
                        let sub = packet mp
                        guard $ isCryptoCoinKey sub
                        tag <- take 1 $ mapMaybe getCryptoCoinTag (map (packet . fst) sigs)
                        return (tag,mp)

                -- export wallet keys
                forM_ wsns $ \(_,n) -> do
                    let cs' = do
                        (nw,mp) <- cs
                        let fns = Map.keys (locations mp)
                        -- trace ("COIN KEY: "++show fns) $ return ()
                        guard . not $ Map.member n (locations mp)
                        let wip = walletImportFormat (CryptoCoins.private_byte_id nw) (packet mp)
                        return (CryptoCoins.network_name nw,wip)
                    handleIO_ (return ()) $ do
                    withFile n AppendMode $ \fh -> do
                    forM_ cs' $ \(net,wip) -> do
                        warn $ n++": new WalletKey "++net
                        hPutStrLn fh wip

                -- unlockFiles fsns ----------- Originally, I did this to enable altering the gpg keyrings
                ------------------------------- from external tools. 
                (db',_) <- f (sec_n,grip) db
                -- lk <- relock --------------- The design is not quite safe, so it is disabled for now.
                let lk = (fsns,failed_locks) -- 
                -------------------------------
                maybe (if n==0 then pass 1 lk else return (lk,db))
                      (return . (lk,))
                      db'
        ((fsns,failed_locks),db) <- pass 0 (fsns,failed_locks)
        let lkmap = Map.fromList $ map swap fsns
        writeOutKeyrings lkmap db
        unlockFiles fsns
        unlockFiles wsns
        return ()


data Arguments =
        Cross_Merge { homedir :: Maybe FilePath
                    , passphrase_fd :: Maybe Int
                    , files :: [FilePath]
                    }
  deriving (Show, Data, Typeable)

toLast f []  = []
toLast f [x] = [f x]
toLast f (x:xs) = x : toLast f xs

partitionStaticArguments specs args = psa args
 where
    smap = Map.fromList specs
    psa [] = ([],[])
    psa (a:as) = 
      case Map.lookup a smap of
        Nothing -> second (a:) $ psa as
        Just n  -> first ((a:take n as):) $ psa (drop n as)

show_wk secring_file grip db = do
    let sec_db = Map.filter gripmatch db
        gripmatch (KeyData p _ _ _) = 
            Map.member secring_file (locations p)
        Message sec = flattenKeys False sec_db
    putStrLn $ listKeysFiltered (maybeToList grip) sec

show_all db = do
    let Message packets = flattenKeys True db
    -- let ks = filter isKey packets
    -- forM_ ks (warn . showPacket)
    -- warn $ "BEGIN LIST "++show (length packets)++" packets."
    putStrLn $ listKeys packets
    -- warn $ "END   LIST "++show (length packets)++" packets."

show_pem keyspec wkgrip db = do
    let s = parseSpec wkgrip keyspec
    flip (maybe $ warn (keyspec ++ ": not found") >> return ())
         (selectPublicKey s db)
         $ \k -> do
    let rsa = pkcs8 . fromJust $ rsaKeyFromPacket k
        der = encodeASN1 DER (toASN1 rsa [])
        qq  = Base64.encode (L.unpack der)
    putStrLn $
        writePEM "PUBLIC KEY" qq -- ("TODO "++show keyspec)

show_key keyspec wkgrip db = do
    let s = parseSpec "" keyspec
    let ps = do 
            (_,k) <- filterMatches (fst s) (Map.toList db)
            mp <- flattenTop "" True k
            return $ packet mp
    -- putStrLn $ "show key " ++ show s
    putStrLn $ listKeys ps

show_wip keyspec wkgrip db = do
    let s = parseSpec wkgrip keyspec
    flip (maybe $ warn (keyspec ++ ": not found") >> return ())
         (selectSecretKey s db)
         $ \k -> do
    let nwb = maybe 0x80 CryptoCoins.secretByteFromName $ snd s
    putStrLn $ walletImportFormat nwb k

parseSpec :: String -> String -> (KeySpec,Maybe String)
parseSpec grip spec = (topspec,subspec)
 where
     (topspec0,subspec0) = unprefix '/' spec
     (toptyp,top) = unprefix ':' topspec0
     (subtyp,sub) = unprefix ':' subspec0
     topspec = case () of
                    _ | null top && or [ subtyp=="fp"
                                       , null subtyp && is40digitHex sub
                                       ]
                                 -> KeyGrip sub
                    _ | null top && null grip -> KeyUidMatch sub
                    _ | null top -> KeyGrip grip
                    _ | toptyp=="fp" || (null toptyp && is40digitHex top)
                                 -> {- trace "using top" $ -} KeyGrip top
                    _ | toptyp=="u" -> KeyUidMatch top
                    _ | otherwise -> KeyUidMatch top
     subspec = case subtyp of
                "t" -> Just sub
                "fp" | top=="" -> Nothing
                "" | top=="" && is40digitHex sub -> Nothing
                "" -> listToMaybe sub >> Just sub

splitAtMinBy comp xs = minimumBy comp' xxs
 where
    xxs = zip (inits xs) (tails xs)
    comp' (_,as) (_,bs) = compM (listToMaybe as) (listToMaybe bs)
    compM (Just a) (Just b) = comp a b
    compM Nothing  mb       = GT
    compM _        _        = LT


-- | systemEnv
-- This is like System.Process.system except that it lets you set
-- some environment variables.
systemEnv _    ""  = 
    ioException (ioeSetErrorString (mkIOError InvalidArgument "system" Nothing Nothing) "null command")
systemEnv vars cmd = do
    env0 <- getEnvironment
    let env1 = filter (isNothing . flip lookup vars . fst) env0
        env = vars ++ env1
    syncProcess "system" $ (shell cmd) {env=Just env}
 where
    -- This is a non-exported function from System.Process
    syncProcess fun c = do
      -- The POSIX version of system needs to do some manipulation of signal
      -- handlers.  Since we're going to be synchronously waiting for the child,
      -- we want to ignore ^C in the parent, but handle it the default way
      -- in the child (using SIG_DFL isn't really correct, it should be the
      -- original signal handler, but the GHC RTS will have already set up
      -- its own handler and we don't want to use that).
      old_int  <- installHandler sigINT  Ignore Nothing
      old_quit <- installHandler sigQUIT Ignore Nothing
      (_,_,_,p) <- runGenProcess_ fun c
            (Just defaultSignal) (Just defaultSignal)
      r <- waitForProcess p
      _ <- installHandler sigINT  old_int Nothing
      _ <- installHandler sigQUIT old_quit Nothing
      return r

doExport doDecrypt (db,use_db) (fname,subspec,ms,cmd) =
        case ms of
            [_]   -> export
            (_:_) -> ambiguous
            []    -> shcmd
 where
    ambiguous = error "Key specification is ambiguous."
    shcmd = do
        let noop warning = do
            warn warning
            return (db,use_db)
        if null cmd then noop (fname ++ ": missing.") else do
        let vars = [ ("file",fname)
                   , ("usage",maybe "" id subspec) ]
        e <- systemEnv vars cmd
        case e of
            ExitFailure num -> noop $ fname ++ ": failed external (code="++show num++")"
            ExitSuccess     -> do
                warn $ fname ++ ": generated"
                return (Nothing,use_db) -- need another pass
    export = do
        let [kk] = ms
            Just (KeyData key sigs uids subkeys) = Map.lookup kk use_db
            p = flip (maybe (Just $ packet key)) subspec $ \tag -> do
                  let subs = Map.elems subkeys
                      doSearch (SubKey sub_mp sigtrusts) =
                        let (_,v,_) = findTag tag
                                          (packet key)
                                          (packet sub_mp) 
                                          sigtrusts
                        in fmap fst v==Just True
                  case filter doSearch subs of
                    [SubKey mp _] -> Just $ packet mp
                    [] -> Nothing
                    _  -> ambiguous
        flip (maybe shcmd) p $ \p -> do
        pun <- doDecrypt p
        flip (maybe $ error "Bad passphrase?") pun $ \pun -> do
        writeKeyToFile False "PEM" fname pun
        return (db,use_db)

findTag tag wk subkey subsigs = (xs',minsig,ys')
         where
            vs = map (\sig ->
                          (sig, do
                                sig <- Just (packet . fst $ sig)
                                guard (isSignaturePacket sig)
                                guard $ flip isSuffixOf
                                             (fingerprint wk)
                                        . maybe "%bad%" id
                                        . signature_issuer
                                        $ sig
                                listToMaybe $
                                  map (signature_time . verify (Message [wk]))
                                      (signatures $ Message [wk,subkey,sig])))
                     subsigs
            (xs,ys) = splitAtMinBy (comparing (Down . snd)) vs
            xs' = map fst xs
            ys' = map fst $ if isNothing minsig then ys else drop 1 ys
            minsig = do
                (sig,ov) <- listToMaybe ys
                ov
                let hs = filter (\p->isNotation p && notation_name p=="usage@")
                                (hashed_subpackets . packet . fst $ sig)
                    ks = map notation_value hs
                    isNotation (NotationDataPacket {}) = True
                    isNotation _ = False
                return (tag `elem` ks, sig)

{-
applyCurve curve x = x*x*x + x*a + b where (a,b)=(geta curve,getb curve)

secp256k1_oid = [1,3,132,0,10]
secp256k1_curve = ECi l a b p r
 where
    -- y² = x³ + 7 (mod p)
    p = 0x0FFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFEFFFFFC2F 
    a = 0
    b = 7
    -- group order  (also order of base point G)
    r = n
    n = 0x0FFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFEBAAEDCE6AF48A03BBFD25E8CD0364141 
    -- cofactor
    h = 1 
    -- bit length
    l = 256

secp256k1_G = ECPa secp256k1_curve 
                0x79BE667EF9DCBBAC55A06295CE870B07029BFCDB2DCE28D959F2815B16F81798
                0x483ADA7726A3C4655DA4FBFC0E1108A8FD17B448A68554199C47D08FFB10D4B8 
    {-
    The base point G in compressed form is:

        G = 02 79BE667E F9DCBBAC 55A06295 CE870B07 029BFCDB 2DCE28D9 59F2815B 16F81798 

    and in uncompressed form is:

        G = 04 79BE667E F9DCBBAC 55A06295 CE870B07 029BFCDB 2DCE28D9 59F2815B 16F81798
               483ADA77 26A3C465 5DA4FBFC 0E1108A8 FD17B448 A6855419 9C47D08F FB10D4B8 
    -}
-}

base58chars = "123456789ABCDEFGHJKLMNPQRSTUVWXYZabcdefghijkmnopqrstuvwxyz"

base58digits :: [Char] -> Maybe [Int]
base58digits str = sequence mbs
 where
    mbs = map (flip elemIndex base58chars) str
    
-- 5HueCGU8rMjxEXxiPuD5BDku4MkFqeZyd4dZ1jvhTVqvbTLvyTJ
base58_decode :: [Char] -> Maybe (Word8,[Word8])
base58_decode str = do
    ds <- base58digits str
    let n = foldl' (\a b-> a*58 + b) 0 $ ( map fromIntegral ds :: [Integer] )
        rbytes = unfoldr getbyte n
        getbyte d = do
            guard (d/=0)
            let (q,b) = d `divMod` 256
            return (fromIntegral b,q)
    
    let (rcksum,rpayload) = splitAt 4 $ rbytes
        a_payload = reverse rpayload
        hash_result = S.take 4 . SHA256.hash . SHA256.hash . S.pack $ a_payload
        expected_hash = S.pack $ reverse rcksum
        (network_id,payload) = splitAt 1 a_payload
    
    network_id <- listToMaybe network_id
    guard (hash_result==expected_hash)
    return (network_id,payload)

walletImportFormat idbyte k = secret_base58_foo
 where
    isSecret (SecretKeyPacket {}) = True
    isSecret _                    = False
    secret_base58_foo = base58_encode seckey
    Just d = lookup 'd' (key k)
    (len16,bigendian) = S.splitAt 2 (S.concat $ L.toChunks $ encode d)
    seckey = S.cons idbyte bigendian


base58_encode :: S.ByteString -> String
base58_encode hash = replicate zcount '1' ++ map (base58chars !!) (reverse rdigits)
  where
    zcount = S.length . S.takeWhile (==0) $ hash
    cksum = S.take 4 . SHA256.hash . SHA256.hash $ hash
    n = foldl' (\a b->a*256+b) 0 . map asInteger $ concatMap S.unpack [hash, cksum]
    asInteger x = fromIntegral x :: Integer
    rdigits = unfoldr getdigit n
     where
        getdigit d = do
            guard (d/=0)
            let (q,b) = d `divMod` 58
            return (fromIntegral b,q)

cannonical_eckey x y = 0x4:pad32(numToBytes x) ++ pad32(numToBytes y) :: [Word8]
 where
  numToBytes n = reverse $ unfoldr getbyte n
    where
        getbyte d = do
            guard (d/=0)
            let (q,b) = d `divMod` 256
            return (fromIntegral b,q)
  pad32 xs = replicate zlen 0 ++ xs
    where
        zlen = 32 - length xs
    
oidToDER ns = S.pack $ b1 : concatMap encode ys
 where
    (xs,ys) = splitAt 2 ns
    b1 = fromIntegral $ foldl' (\a b->a*40+b) 0 xs
    encode x | x <= 127  = [fromIntegral x]
             | otherwise = (\(x:xs)-> reverse (x:map (0x80 .|.) xs)) 
                            (base128r x)
    base128r n = unfoldr getbyte n
     where
        getbyte d = do
            guard (d/=0)
            let (q,b) = d `divMod` 128
            return (fromIntegral b,q)

nistp256=[1,2,840,10045,3,1,7]
nistp256_der=[0x2A,0x86,0x48,0xCE,0x3D,0x03,0x01,0x07]
-- "\x2a\x86\x48\xce\x3d\x03\x01\x07"
{-     OID                  Curve description              Curve name
    ----------------------------------------------------------------   
    1.2.840.10045.3.1.7  NIST Curve P-256 [FIPS 186-2]  "NIST P-256"
    1.3.132.0.34         NIST Curve P-384 [FIPS 186-2]  "NIST P-384"  
    1.3.132.0.35         NIST Curve P-521 [FIPS 186-2]  "NIST P-521"  

    Implementations MUST implement "NIST P-256", "NIST P-384" and "NIST
    P-521".  The hexadecimal representation used in the public and
    private key encodings are:

    Curve Name   Len  Hexadecimal representation of the OID
    ----------------------------------------------------------------   
    "NIST P-256"  8   0x2A, 0x86, 0x48, 0xCE, 0x3D, 0x03, 0x01, 0x07 
    "NIST P-384"  6   0x05, 0x2B, 0x81, 0x04, 0x00, 0x22            
    "NIST P-521"  6   0x05, 0x2B, 0x81, 0x04, 0x00, 0x23          
-}

bitcoinAddress network_id k = address
    where
            Just (MPI x) = lookup 'x' (key k)
            Just (MPI y) = lookup 'y' (key k)
            pub = cannonical_eckey x y
            hash = S.cons network_id . RIPEMD160.hash . SHA256.hash . S.pack $  pub
            address = base58_encode hash

-- gpg supported ECDSA curve: 2A8648CE3D030107
-- 2A 86 48 CE 3D 03 01 07 
-- 1,2,134,72,206,61,3,1,7
--  6*128+0x48 840
--  0x4e*128+0x3d 10045
-- 1.2.840.10045.3.1.7  --> NIST P-256
--
decode_btc_key timestamp str = do
    (network_id,us) <- base58_decode str
    return . (network_id,) $ Message $ do
        let d = foldl' (\a b->a*256+b) 0 (map fromIntegral us :: [Integer])
            {-
            xy = secp256k1_G `pmul` d
            x = getx xy
            y = gety xy
            -- y² = x³ + 7 (mod p)
            y' = sqrtModP' (applyCurve secp256k1_curve x) (getp secp256k1_curve)
            y'' = sqrtModPList (applyCurve secp256k1_curve x) (getp secp256k1_curve)
            -}
            secp256k1 = ECC.getCurveByName ECC.SEC_p256k1
            ECC.Point x y = ECC.ecc_g $ ECC.common_curve secp256k1
            pub = cannonical_eckey x y
            hash = S.cons network_id . RIPEMD160.hash . SHA256.hash . S.pack $  pub
            address = base58_encode hash
            pubstr = concatMap (printf "%02x") $ pub
            _ = pubstr :: String
        return $ {- trace (unlines ["pub="++show pubstr
                                ,"add="++show address
                                ,"y  ="++show y
                                ,"y' ="++show y'
                                ,"y''="++show y'']) -}
            SecretKeyPacket 
            { version = 4
            , timestamp = toEnum (fromEnum timestamp)
            , key_algorithm = ECDSA
            , key = [ -- public fields...
                     ('c',MPI secp256k1_id) -- secp256k1 (bitcoin curve)
                    ,('l',MPI 256)
                    ,('x',MPI x)
                    ,('y',MPI y)
                    -- secret fields
                    ,('d',MPI d)
                    ]
            , s2k_useage = 0
            , s2k = S2K 100 ""
            , symmetric_algorithm = Unencrypted
            , encrypted_data = ""
            , is_subkey = True
            }

doBTCImport doDecrypt db (ms,subspec,content) = do
    let fetchkey = do
            timestamp <- now
            let mbk = fmap discardNetworkID $ decode_btc_key timestamp content
                discardNetworkID = snd
            return $ maybe (Message []) id mbk
    let error s = do
                        warn s
                        exitFailure
    flip (maybe $ error "Cannot import master key.")
         subspec $ \tag -> do
    Message parsedkey <- fetchkey
    flip (maybe $ return db)
         (listToMaybe parsedkey) $ \key -> do
    let (m0,tailms) = splitAt 1 ms
    when (not (null tailms) || null m0)
        $ error "Key specification is ambiguous."
    doImportG doDecrypt db m0 tag "" key

doImport doDecrypt db (fname,subspec,ms,_) = do
    let fetchkey = readKeyFromFile False "PEM" fname
    let error s = do
                        warn s
                        exitFailure
    flip (maybe $ error "Cannot import master key.")
         subspec $ \tag -> do
    Message parsedkey <- fetchkey
    flip (maybe $ return db)
         (listToMaybe parsedkey) $ \key -> do
    let (m0,tailms) = splitAt 1 ms
    when (not (null tailms) || null m0)
        $ error "Key specification is ambiguous."
    doImportG doDecrypt db m0 tag fname key

doImportG doDecrypt db m0 tag fname key = do
    let error s = do
                        warn s
                        exitFailure
    let kk = head m0
        Just (KeyData top topsigs uids subs) = Map.lookup kk db
        subkk = keykey key
        (is_new, subkey) = maybe (True, SubKey (mappedPacket fname key)
                                               [])
                                 ( (False,) . addOrigin )
                                 (Map.lookup subkk subs)
                             where
                                addOrigin (SubKey mp sigs) = 
                                    let mp' = mp
                                          { locations = Map.insert fname
                                                             (origin (packet mp) (-1))
                                                             (locations mp) }
                                    in SubKey mp' sigs
        subs' = Map.insert subkk subkey subs

        istor = do
            guard (tag == "tor")
            return $ "Anonymous <root@" ++ take 16 (torhash key) ++ ".onion>"

    uids' <- flip (maybe $ return uids) istor $ \idstr -> do
                let has_torid = do
                     -- TODO: check for omitted real name field
                     (sigtrusts,om) <- Map.lookup idstr uids
                     listToMaybe $ do
                         s <- (signatures $ Message (packet top:UserIDPacket idstr:map (packet . fst) sigtrusts))
                         signatures_over $ verify (Message [packet top]) s
                flip (flip maybe $ const $ return uids) has_torid $ do
                wkun <- doDecrypt (packet top)
                flip (maybe $ error "Bad passphrase?") wkun $ \wkun -> do
                let keyflags = keyFlags wkun (map packet $ flattenAllUids fname True uids)
                    uid = UserIDPacket idstr
                    -- sig_ov = fst $ torsig g (packet top) wkun uid timestamp keyflags
                    tor_ov = torSigOver (packet top) wkun uid keyflags
                sig_ov <- pgpSign (Message [wkun])
                                  tor_ov
                                  SHA1
                                  (fingerprint wkun)
                flip (maybe $ warn "Failed to make signature" >> return uids)
                     (sig_ov >>= listToMaybe . signatures_over)
                     $ \sig -> do
                let om = Map.singleton fname (origin sig (-1))
                    trust = Map.empty
                return $ Map.insert idstr ([( (mappedPacket fname sig) {locations=om}
                                            ,trust)],om) uids

    let SubKey subkey_p subsigs = subkey
        wk = packet top
        (xs',minsig,ys') = findTag tag wk key subsigs
        doInsert mbsig db = do
            sig' <- makeSig doDecrypt top fname subkey_p tag mbsig
            warn $ fname ++ ": yield SignaturePacket"
            let subs' = Map.insert subkk
                                   (SubKey subkey_p $ xs'++[sig']++ys')
                                   subs
            return $ Map.insert kk (KeyData top topsigs uids' subs') db
    when is_new (warn $ fname ++ ": yield SecretKeyPacket "++show (fmap fst minsig,fingerprint key))
    case minsig of
        Nothing          -> doInsert Nothing db    -- we need to create a new sig
        Just (True,sig)  -> -- we can deduce is_new == False
                            -- we may need to add a tor id
                            return $ Map.insert kk (KeyData top topsigs uids' subs') db
        Just (False,sig) -> doInsert (Just sig) db -- We have a sig, but is missing usage@ tag


makeSig doDecrypt top fname subkey_p tag mbsig = do
    let wk = packet top
    wkun <- doDecrypt wk
    flip (maybe $ error "Bad passphrase?") wkun $ \wkun -> do
    let grip = fingerprint wk
        addOrigin new_sig = do
            flip (maybe $ error "Failed to make signature.") 
                 (new_sig >>= listToMaybe . signatures_over) 
                 $ \new_sig -> do
            let mp' = mappedPacket fname new_sig
            return (mp', Map.empty)
        parsedkey = [packet $ subkey_p]
        hashed0 =
                    [ KeyFlagsPacket
                        { certify_keys = False
                        , sign_data = False
                        , encrypt_communication = False
                        , encrypt_storage = False
                        , split_key = False
                        , authentication = True
                        , group_key = False }
                    , NotationDataPacket
                        { human_readable = True
                        , notation_name = "usage@"
                        , notation_value = tag
                        }
                    -- implicitly added:
                    -- , SignatureCreationTimePacket (fromIntegral timestamp)
                    ]
        subgrip = fingerprint (head parsedkey)

    back_sig <- pgpSign (Message parsedkey)
                        (SubkeySignature wk
                                         (head parsedkey)
                                         (sigpackets 0x19
                                                     hashed0
                                                     [IssuerPacket subgrip]))
                        (if key_algorithm (head parsedkey)==ECDSA
                            then SHA256
                            else SHA1)
                        subgrip
    let iss = IssuerPacket (fingerprint wk)
        cons_iss back_sig = iss : map EmbeddedSignaturePacket (signatures_over back_sig)
        unhashed0 = maybe [iss] cons_iss back_sig

    new_sig <- pgpSign (Message [wkun])
                       (SubkeySignature wk
                                        (head parsedkey)
                                        (sigpackets 0x18
                                                   hashed0
                                                   unhashed0))
                      SHA1
                      grip
    let newSig = addOrigin new_sig
    flip (maybe newSig) mbsig $ \(mp,trustmap) -> do
    let sig = packet mp
        isCreation (SignatureCreationTimePacket {}) = True
        isCreation _ = False
        isExpiration (SignatureExpirationTimePacket {}) = True
        isExpiration _ = False
        (cs,ps) = partition isCreation (hashed_subpackets sig)
        (es,qs) = partition isExpiration ps
        stamp = listToMaybe . sortBy (comparing Down) $
                 map unwrap cs where unwrap (SignatureCreationTimePacket x) = x
        exp = listToMaybe $ sort $
                 map unwrap es where unwrap (SignatureExpirationTimePacket x) = x
        expires = liftA2 (+) stamp exp
    timestamp <- now
    if fmap ( (< timestamp) . fromIntegral) expires == Just True then do
        warn $ "Unable to update expired signature"
        return (mp,trustmap)
    else do
        let times = (:) (SignatureExpirationTimePacket (fromIntegral timestamp))
                        $ maybeToList $ do
                            e <- expires
                            return $ SignatureExpirationTimePacket (e - fromIntegral timestamp)
            notation = NotationDataPacket
                        { notation_name = "usage@"
                        , notation_value = tag
                        , human_readable = True }
            sig' = sig { hashed_subpackets = times ++ [notation] ++ qs }
        new_sig <- pgpSign (Message [wkun])
                           (SubkeySignature wk
                                            (packet subkey_p)
                                            [sig'] )
                           SHA1
                           (fingerprint wk)
        addOrigin new_sig

signature_time ov = case if null cs then ds else cs of
                                [] -> minBound
                                xs -> last (sort xs)
          where
            ps = signatures_over ov
            ss = filter isSignaturePacket ps
            cs = concatMap (concatMap creationTime . hashed_subpackets) ss
            ds = concatMap (concatMap creationTime . unhashed_subpackets) ss
            creationTime (SignatureCreationTimePacket t) = [t]
            creationTime _                               = []

-- We return into IO in case we want to make a signature here.
setHostnames :: (SockAddr -> Bool) -> Hosts.Hosts -> KeyData -> IO KeyData
setHostnames pred hosts kd@(KeyData topmp topsigs uids subs) =
    -- TODO: we are removing the origin from the UID OriginMap,
    --       when we should be removing origins from the locations
    --       field of the sig's MappedPacket records.
    -- Call getHostnames and compare to see if no-op.
    if not (pred addr) || names0 == names \\ onions 
        then {- trace (unlines [ "setHostnames NO-OP: gpg: "++show (map Char8.unpack onions, map Char8.unpack names0)
                             , "                   file: "++show (map Char8.unpack names)
                             , "                   pred: "++show (pred addr)]) -}
                    (return kd)
        else do
    -- We should be sure to remove origins so that the data is written
    --   (but only if something changed).
    -- Filter all hostnames present in uids
    -- Write notations into first uid
    {-
    trace (unlines [ "setHostnames ACTION: gpg: "++show (map Char8.unpack onions, map Char8.unpack names0)
                   , "                    file: "++show (map Char8.unpack names) ]) $ do
    -}
    return $ KeyData topmp topsigs uids1 subs
 where
    topk = packet topmp
    addr = fingerdress topk
    names :: [Char8.ByteString]
    names = Hosts.namesForAddress addr hosts
    (_,(onions,names0)) = getHostnames kd
    notations = map (NotationDataPacket True "hostname@" . Char8.unpack) (names \\ onions)
    isName (NotationDataPacket True "hostname@" _) = True
    isName _ = False
    uids0 = fmap zapIfHasName uids
    fstuid = head $ do
        p <- map packet $ flattenAllUids "" True uids
        guard $ isUserID p
        return $ uidkey p
    uids1 = Map.adjust addnames fstuid uids0
    addnames (sigs,om) = (fmap f ss ++ ts, om ) -- XXX: removed om=Map.empty, preserve UserId origin
     where
        (ss,ts) = splitAt 1 sigs
        f (sig,tm) = if isSignaturePacket (packet sig) then (sig { packet = p', locations=Map.empty }, tm)
                                                       else (sig, tm)
         where p' = (packet sig) { unhashed_subpackets=uh }
               uh = unhashed_subpackets (packet sig) ++ notations
    zapIfHasName (sigs,om) = if or bs then (sigs',om)  -- XXX: removed om=Map.empty to preserve UserID origin
                                      else (sigs,om)
     where
        (bs, sigs') = unzip $ map unhash sigs

        unhash (sig,tm) = ( not (null ns)
                          , ( sig { packet = p', locations = Map.empty }
                            , tm ) )
         where
            psig = packet sig
            p' = if isSignaturePacket psig then psig { unhashed_subpackets = ps }
                                           else psig
            uh = unhashed_subpackets $ psig
            (ns,ps) = partition isName uh

socketFamily (SockAddrInet _ _)      = AF_INET
socketFamily (SockAddrInet6 _ _ _ _) = AF_INET6
socketFamily (SockAddrUnix _)        = AF_UNIX


hasFingerDress :: KeyDB -> SockAddr -> Bool
hasFingerDress db addr | socketFamily addr/=AF_INET6 = False
hasFingerDress db addr = pre=="fd" && isJust (selectPublicKey (KeyGrip g',Nothing) db)
 where
    (pre,g) = splitAt 2 $ filter (/=':') $ Hosts.inet_ntop addr
    g' = map toUpper g

fingerdress :: Packet -> SockAddr
fingerdress topk = maybe zero id $ Hosts.inet_pton addr_str
 where
    zero = SockAddrInet 0 0
    addr_str = colons $  "fd" ++ (drop 10 $ map toLower $ fingerprint topk)
    colons (a:b:c:d:xs@(_:_)) = [a,b,c,d,':'] ++ colons xs
    colons xs                 = xs


{-
onionName :: KeyData -> (SockAddr,L.ByteString)
onionName kd = (addr,name)
 where
    (addr,(name:_,_)) = getHostnames kd
-}

getHostnames :: KeyData -> (SockAddr, ([L.ByteString],[L.ByteString]))
getHostnames (KeyData topmp _ uids subs) = (addr,(onames,othernames))
 where
    othernames = do
        mp <- flattenAllUids "" True uids
        let p = packet mp
        guard $ isSignaturePacket p
        uh <- unhashed_subpackets p
        case uh of
            NotationDataPacket True "hostname@" v
              -> return $ Char8.pack v
            _ -> mzero

    addr = fingerdress topk
    name = maybe "" id $ listToMaybe onames -- TODO: more than one tor key?
    topk = packet topmp
    torkeys = do
        SubKey k sigs <- Map.elems subs
        let subk = packet k
        let sigs' = do
                torsig <- filter (has_tag "tor") $ map (packet . fst) sigs
                sig <- (signatures $ Message [topk,subk,torsig])
                let v = verify (Message [topk]) sig
                -- Require parent's signature
                guard (not . null $ signatures_over v)
                let unhashed = unhashed_subpackets torsig
                    subsigs = mapMaybe backsig unhashed
                    -- This should consist only of 0x19 values
                    -- subtypes = map signature_type subsigs
                sig' <- signatures . Message $ [topk,subk]++subsigs
                let v' = verify (Message [subk]) sig'
                -- Require subkey's signature
                guard . not . null $ signatures_over v'
                return torsig
        guard (not $ null sigs')
        return $ subk
    has_tag tag p = isSignaturePacket p
                    && or [ tag `elem` mapMaybe usage (hashed_subpackets p)
                          , tag `elem` map usageString (mapMaybe keyflags (hashed_subpackets p)) ]
    subkeyPacket (SubKey k _ ) = k
    onames :: [L.ByteString]
    onames = map ( (<> ".onion")
                 . Char8.pack
                 . take 16
                 . torhash )
                 torkeys

kiki_usage = do
    putStr . unlines $
        ["kiki - a pgp key editing utility"
        ,""
        ,"kiki [OPTIONS]"
        ,""
        ,"     kiki merges a set of keyring files into a combined database and then"
        ,"     uses the database to update the files so that they have the most complete"
        ,"     information."
        ,""
        ,"     The files pubring.gpg and subring.gpg in the directory specified by the "
        ,"     --homedir option are implicitly included in the keyring set."
        ,""
        ,"     kiki can also import or export secret subkeys by using the --keypairs option."
        ,""
        ,"     Subkeys that are imported with kiki are given an annotation \"usage@\" which"
        ,"     indicates what the key is for.  This tag can be used as a SPEC to select a"
        ,"     particular key.  Master keys may be specified by using fingerprints or by"
        ,"     specifying a substring of an associated UID."
        ,""
        ,"Flags:"
        ,"     --homedir DIR"
        ,"                Where to find the the files secring.gpg and pubring.gpg. The "
        ,"                default location is taken from the environment variable "
        ,"                GNUPGHOME."
        ,""
        ,"     --passphrase-fd N"
        ,"                Read passphrase from the given file descriptor."
        ,""
        ,"     --import   Add master keys to pubring.gpg.  Without this option, only UID"
        ,"                and subkey data is updated. "
        ,""
        ,"     --autosign Sign all cross-certified tor-style UIDs."
        ,"                A tor-style UID is of the form:"
        ,"                        Anonymous <root@HOSTNAME.onion>"
        ,"                It is considered cross certified if there exists a cross-certified"
        ,"                'tor' subkey corresponding to the address HOSTNAME.onion."
        ,""
        ,"Merging:"
        ,"     --keyrings FILE FILE..."
        ,"                Provide keyring files other than the implicit secring.gpg and"
        ,"                pubring.gpg in the --homedir.  This option is implicit unless"
        ,"                --keypairs or --wallets is used."
        ,""
        ,"     --wallets  FILE FILE..."
        ,"                Provide wallet files with secret crypto-coin keys in Wallet"
        ,"                Import Format.  The keys will be treated as subkeys of your"
        ,"                current working key (the one shown by --show-wk)."
        ,""
        ,"     --keypairs KEYSPEC KEYSPEC..."
        ,"                Each KEYSPEC specifies that a key should match the content and"
        ,"                timestamp of an external PKCS #1 private RSA key file."
        ,"                "
        ,"                KEYSPEC ::= SPEC=FILE{CMD} "
        ,""
        ,"                If neither SPEC or FILE match any keys, then the CMD will be "
        ,"                executed in order to create the FILE."
        ,""
        ,"Output:"
        ,"     --show-wk  Show fingerprints for the working key (which will be used to"
        ,"                make signatures) and all its subkeys and UID."
        ,""
        ,"     --show-key Show fingerprints for the specified key and all its subkeys"
        ,"                and UID."
        ,""
        ,"     --show-all Show fingerprints and UIDs and usage tags for all known keys."
        ,""
        ,"     --show-pem SPEC"
        ,"                Outputs the PKCS #8 public key corresponding to SPEC."
        ,""
        ,"     --show-wip SPEC"
        ,"                Outputs the secret crypto-coin key in Wallet Input Format."
        ,""
        ,"     --help     Shows this help screen."
        ]

main = do
    dotlock_init
    {-
    args <- cmdArgs $ modes
        [ Cross_Merge HOMEOPTION
              (def &= opt ("passphrase"::String)
                &= typ "FD"
                &= (help . concat)  ["file descriptor from "
                                    ,"which to read passphrase"])
              (def &= args &= typFile)
            &= help "Merge multiple secret keyrings to stdout."
        ]
        &= program "kiki"
        &= summary "kiki - a pgp key editing utility"
    doCmd args
    -}
    args_raw <- getArgs
    let (args,trail1) = break (=="--") args_raw
        trail = drop 1 trail1
        (sargs,margs) = 
                (sargs, foldl' (\m (k:xs)->Map.alter (appendArgs k xs) k m)
                               Map.empty
                               gargs)
                    where (sargs,vargs) = partitionStaticArguments sargspec args
                          sargspec = [ ("--homedir",1)
                                     , ("--passphrase-fd",1)
                                     , ("--import",0)
                                     , ("--autosign",0)
                                     , ("--show-wk",0)
                                     , ("--show-all",0)
                                     , ("--show-key",1)
                                     , ("--show-pem",1)
                                     , ("--show-wip",1)
                                     , ("--help",0)
                                     ]
                          argspec = map fst sargspec ++ ["--keyrings"
                                                        ,"--keypairs"
                                                        ,"--wallets"
                                                        ,"--hosts"] 
                                        -- "--bitcoin-keypairs"
                                        -- Disabled.  We shouldn't accept private key
                                        -- data on the command line.
                          args' = if map (take 1) (take 1 vargs) == ["-"]
                                    then vargs
                                    else "--keyrings":vargs
                          gargs = (sargs ++)
                                  . toLast (++trail) 
                                  . groupBy (\_ s-> take 1 s /= "-")
                                  $ args'
                          appendArgs k xs opt = 
                            if k `elem` argspec
                              then Just . maybe xs (++xs) $ opt
                              else error . unlines $ [ "unrecognized option "++k
                                                     , "Use --help for usage." ]
    -- putStrLn $ "margs = " ++ show (Map.assocs margs)
    unkeysRef <- newIORef Map.empty
    pwRef <- newIORef Nothing
    let keypairs0 =
            flip map (maybe [] id $ Map.lookup "--keypairs" margs) $ \specfile -> do
                let (spec,efilecmd) = break (=='=') specfile
                guard $ take 1 efilecmd=="="
                let filecmd = drop 1 efilecmd
                let (file,bcmdb0) = break (=='{') filecmd
                    bcmdb = if null bcmdb0 then "{}" else bcmdb0
                guard $ take 1 bcmdb=="{"
                let bdmcb = (dropWhile isSpace . reverse) bcmdb
                guard $ take 1 bdmcb == "}"
                let cmd = (drop 1 . reverse . drop 1) bdmcb
                Just (spec,file,cmd)
        btcpairs0 =
            flip map (maybe [] id $ Map.lookup "--bitcoin-keypairs" margs) $ \specfile -> do
                let (spec,efilecmd) = break (=='=') specfile
                (spec,protocnt) <- do
                    return $ if take 1 efilecmd=="=" then (spec,drop 1 efilecmd)
                                                     else ("",spec)
                let (proto,content) = break (==':') protocnt
                spec <- return $ if null spec then "bitcoin" else spec
                return $ 
                    if take 1 content =="=" then (spec,proto,drop 1 content)
                                            else (spec,"base58",proto)
        publics =
            flip map (maybe [] id $ Map.lookup "--public" margs) $ \specfile -> do
                let (spec,efile) = break (=='=') specfile
                guard $ take 1 efile=="="
                let file= drop 1 efile
                Just (spec,file)
        keyrings_ = maybe [] id $ Map.lookup "--keyrings" margs
        wallets   = maybe [] id $ Map.lookup "--wallets" margs
        passphrase_fd = concat <$> Map.lookup "--passphrase-fd" margs
        decrypt wk = do
            -- warn $ "decryptKey "++fingerprint wk
            unkeys <- readIORef unkeysRef
            let kk = keykey wk
            flip (flip maybe $ return . Just) (Map.lookup kk unkeys) $ do
            let ret wkun = do writeIORef unkeysRef (Map.insert kk wkun unkeys)
                              return (Just wkun)
            if symmetric_algorithm wk == Unencrypted then ret wk else do
            pw <- do
                pw <- readIORef pwRef
                flip (flip maybe return) pw $ do
                case passphrase_fd of
                    Just fd -> do pwh <- fdToHandle (read fd)
                                  pw <- fmap trimCR $ S.hGetContents pwh
                                  writeIORef pwRef (Just pw)
                                  return pw
                    Nothing -> return ""
            let wkun = do
                k <- decryptSecretKey pw wk
                guard (symmetric_algorithm k == Unencrypted)
                return k
            maybe (return Nothing) ret wkun

    when (not . null $ filter isNothing keypairs0) $ do
        warn "syntax error"
        exitFailure

    let keypairs = catMaybes keypairs0
        btcpairs = catMaybes btcpairs0

    (homedir,secring,pubring,grip0) <- getHomeDir ( concat <$> Map.lookup "--homedir" margs)

    let keyrings = secring:pubring:keyrings_

    {-
    putStrLn $ "keypairs = "++show keypairs
    putStrLn $ "publics  = "++show publics
    putStrLn $ "keyrings = "++show keyrings
    -}

    cross_merge decrypt grip0 keyrings wallets $ \(secfile,grip) db -> do
        let get_use_db = maybe (return db) import_db 
                            $ Map.lookup "--import" margs
            import_db _ = do
                  forM_ to_alters $ \(_,KeyData c _ _ _) ->
                    warn $ pubring ++ ": new "++showPacket (packet c)
                  let db' = Map.union (Map.fromList altered)
                                      db
                  return db'
              where
                to_alters = filter (dont_have . snd) $ Map.toList db
                altered = map (second append_loc) to_alters
                append_loc (KeyData p a b c) = KeyData p' a b c
                 where p' = p { locations = Map.insert pubring
                                                       (origin (secretToPublic (packet p)) (-1))
                                                       (locations p) 
                              }
                dont_have (KeyData p _ _ _) = not . Map.member pubring
                                                   $ locations p
        use_db0 <- get_use_db

        let pkeypairs = maybe [] id $ do
                            keygrip <- grip
                            return $ map (\(spec,f,cmd)-> (parseSpec keygrip spec,f,cmd)) keypairs
        fs <- forM pkeypairs $ \((topspec,subspec),f,cmd) -> do
            -- Note that it's important to discard the KeyData objects
            -- returned by filterMatches and retain only the keys.
            -- Otherwise, the iterations within the foldM would not be
            -- able to alter them by returning a modified KeyDB.
            let ms = map fst $ filterMatches topspec (Map.toList db)
            f_found <- doesFileExist f
            return (f_found,(f,subspec,ms,cmd))


        let (imports,exports) = partition fst fs
        use_db <- foldM (doImport decrypt) use_db0 (map snd imports)

        let (btcs,bad_btcs) = partition isSupportedBTC btcpairs
            isSupportedBTC (spec,"base58",cnt) = True
            isSupportedBTC _                   = False
            dblist = Map.toList use_db
            pbtcs = maybe [] id $ do
                        keygrip <- grip
                        let conv (spec,proto,cnt) = 
                                    let (topspec,subspec) = parseSpec keygrip spec
                                        ms = map fst $ filterMatches topspec dblist
                                    in (ms,subspec,cnt)
                        return $ map conv btcs

        use_db <- foldM (doBTCImport decrypt) use_db pbtcs

        (ret_db,_) <- foldM (doExport decrypt) (Just use_db,use_db) (map snd exports)

        use_db <-
            flip (maybe $ return use_db) 
                 (lookup "--autosign" $ map (\(x:xs)->(x,xs)) sargs)
                 $ \_ -> do
                let keys = map undata $ Map.elems use_db
                    wk = listToMaybe $ do
                            fp <- maybeToList grip
                            elm <- Map.toList use_db
                            guard $ matchSpec (KeyGrip fp) elm
                            return $ undata (snd elm)
                            
                    undata (KeyData p _ _ _) = packet p
                -- g <- newGenIO
                -- stamp <- now
                wkun <- flip (maybe $ return Nothing) wk $ \wk -> do
                            wkun <- decrypt wk
                            maybe (error $ "Bad passphrase?") (return . Just) wkun
                -- return . snd $ Map.mapAccum (signTorIds stamp wkun keys) g use_db
                Traversable.mapM (signTorIds wkun keys) use_db
        ret_db <- return $ fmap (const use_db) ret_db
            
        ret_db <- flip (maybe $ return ret_db) ret_db $ \db -> do
            let hns = maybe [] id $ Map.lookup "--hosts" margs
            hostdbs0 <- mapM (fmap Hosts.decode . L.readFile) hns

            let gpgnames = map getHostnames $ Map.elems db
                os = do
                    (addr,(ns,_)) <- gpgnames
                    n <- ns
                    return (addr,n)
                setOnions hosts = foldl' (flip $ uncurry Hosts.assignName) hosts os
                -- we ensure .onion names are set properly
                hostdbs = map setOnions hostdbs0
                outgoing_names = do
                    (addr,(_,gns)) <- gpgnames
                    guard . not $ null gns
                    guard $ all (null . Hosts.namesForAddress addr) hostdbs0
                    return addr
            -- putStrLn $ "hostdbs = " ++ show hostdbs

            -- 1. let U = union all the host dbs 
            --     preserving whitespace and comments of the first
            let u0 = foldl' Hosts.plus Hosts.empty hostdbs
                -- we filter U to be only finger-dresses
                u1 = Hosts.filterAddrs (hasFingerDress db) u0

            let nf h = map Char8.unpack $ Hosts.namesForAddress (fromJust $ Hosts.inet_pton "fdf4:ed98:29c7:6226:9bde:a5b4:d564:3321") h
            {-
            putStrLn $ "_  = {\n" ++ show (head hostdbs) ++ "}"
            putStrLn $ "--> " ++ show (nf (head hostdbs))
            putStrLn $ "u0 = {\n" ++ show u0 ++ "}"
            putStrLn $ "--> " ++ show (nf u0)
            putStrLn $ "u1 = {\n" ++ show u1 ++ "}"
            putStrLn $ "--> " ++ show (nf u1)
            -}
            
            -- 2. replace gpg annotations with those in U
            -- forM use_db
            db' <- Traversable.mapM (setHostnames (\a -> not $ elem a outgoing_names) u1) db

            -- 3. add hostnames from gpg for addresses not in U
            let u = foldl' f u1 ans
                ans = reverse $ do
                    (addr,(_,ns)) <- gpgnames
                    guard $ addr `elem` outgoing_names -- . null $ Hosts.namesForAddress addr u0
                    n <- ns
                    return (addr,n)
                f h (addr,n) = Hosts.assignNewName addr n h

            {-
            putStrLn $ "u = {\n" ++ show u ++ "}"
            putStrLn $ "--> " ++ show (nf u)
            -}

            -- 4. for each host db H, union H with U and write it out as H'
            --     only if there is a non-empty diff
            forM_ (zip hns $ zip hostdbs0 hostdbs) $ \(fname,(h0,h1)) -> do 
                let h = h1 `Hosts.plus` u
                    d = Hosts.diff h0 h
                    fnamecolon = Char8.pack fname <> ": "
                {-
                putStrLn $ "h = {\n" ++ show h ++ "}"
                putStrLn $ "--> " ++ show (nf h)
                -}
                Char8.hPutStrLn stderr $ Char8.unlines (map (fnamecolon <>) d)
                when (not $ null d) $ L.writeFile fname $ Hosts.encode h
                return ()

            return (Just db')

        flip (maybe $ return ()) ret_db . const $ do

            
            -- On last pass, interpret --show-* commands.
            let shspec = Map.fromList [("--show-wk", const $ show_wk secfile grip)
                                      ,("--show-all",const $ show_all)
                                      ,("--show-key",\[x] -> show_key x $ maybe "" id grip)
                                      ,("--show-pem",\[x] -> show_pem x $ maybe "" id grip)
                                      ,("--show-wip",\[x] -> show_wip x $ maybe "" id grip)
                                      ,("--help", \_ _ ->kiki_usage)]
                shargs = mapMaybe (\(x:xs) -> (,xs) <$> Map.lookup x shspec) sargs

            forM_ shargs $ \(cmd,args) -> cmd args use_db
        return $ (ret_db,use_db)

    return()
 where
    envhomedir opt = do
        gnupghome <- lookupEnv homevar >>=
                  \d -> return $ d >>= guard . (/="") >> d
        home <- flip fmap getHomeDirectory $
                  \d -> fmap (const d) $ guard (d/="")
        let homegnupg = (++('/':appdir)) <$> home
        let val = (opt `mplus` gnupghome `mplus` homegnupg)
        return $ val

    homevar = "GNUPGHOME"
    appdir  = ".gnupg"
    optfile_alts = ["keys.conf","gpg.conf-2","gpg.conf"]

    getHomeDir protohome = do
        homedir <- envhomedir protohome
        flip (maybe (error "Could not determine home directory."))
             homedir $ \homedir -> do
        -- putStrLn $ "homedir = " ++show homedir
        let secring = homedir ++ "/" ++ "secring.gpg"
            pubring = homedir ++ "/" ++ "pubring.gpg"
        -- putStrLn $ "secring = " ++ show secring
        workingkey <- getWorkingKey homedir
        return (homedir,secring,pubring,workingkey)

    -- TODO: rename this to getGrip
    getWorkingKey homedir = do
        let o = Nothing
            h = Just homedir
            args = ["hi"]
        ofile <- fmap listToMaybe . flip (maybe (return [])) h $ \h ->
                let optfiles = map (second ((h++"/")++))
                                   (maybe optfile_alts' (:[]) o')
                    optfile_alts' = zip (False:repeat True) optfile_alts
                    o' = fmap (False,) o
                in filterM (doesFileExist . snd) optfiles
        args <- flip (maybe $ return []) ofile $
            \(forgive,fname) -> parseOptionFile fname
        let config = map (topair . words) args
                        where topair (x:xs) = (x,xs)
        return $ lookup "default-key" config >>= listToMaybe

    getPGPEnviron cmd = do
        (homedir,secring,pubring,grip) <- getHomeDir (homedir cmd)
        (Message sec) <- readPacketsFromFile secring
        let (keys,_) = partition (\k -> case k of
                                   { SecretKeyPacket {} -> True
                                   ; _                  -> False })
                                 sec
        return (homedir,sec, grip `mplus` fmap fingerprint (listToMaybe keys))

    getTorKeys pub = do
        xs <- groupBindings pub
        (_,(top,sub),us,_,_) <- xs
        guard ("tor" `elem` us)
        let torhash = maybe "" id $ derToBase32 <$> derRSA sub
        return (top,(torhash,sub))

    uidScan pub = scanl (\(mkey,u) w ->
                             case () of
                              _ | isPublicMaster w -> (w,u)
                              _ | isUserID w -> (mkey,w)
                              _ | otherwise  -> (mkey,u)
                            )
                          (w0,w0)
                          ws
                        where
                            w0:ws = pub

    signTorIds selfkey keys kd@(KeyData k ksigs umap submap) = do
        umap' <- Traversable.mapM signIfTor (Map.mapWithKey (,) umap)
        return (KeyData k ksigs umap' submap) :: IO KeyData
     where
        mkey = packet k
        signIfTor (str,ps) =
            if isTorID str 
                then do
                    let uidxs0 = map packet $ flattenUid "" True (str,ps)
                    -- addition<- signSelfAuthTorKeys' selfkey g keys grip timestamp mkey uidxs0
                    additional <- signSelfAuthTorKeys' selfkey   keys grip           mkey uidxs0
                    let ps' = ( map ( (,tmap) . toMappedPacket om) additional 
                                 ++ fst ps
                              , Map.union om (snd ps) )
                        toMappedPacket om p = (mappedPacket "" p) {locations=om}
                        om = Map.singleton "--autosign" (origin p (-1)) where p = UserIDPacket str
                        tmap = Map.empty
                    return ps'
                else return ps

        torbindings = getTorKeys (map packet $ flattenTop "" True kd)
        isTorID str = and [ uid_topdomain parsed == "onion"
                            , uid_realname parsed `elem` ["","Anonymous"]
                            , uid_user parsed == "root"
                            , fmap (match . fst) (lookup mkey torbindings)
                                == Just True ]
                      where parsed = parseUID str
                            match = ( (==subdom) . take (fromIntegral len))
                            subdom0 = L.fromChunks [encodeUtf8 (uid_subdomain parsed)]
                            subdom = Char8.unpack subdom0
                            len = T.length (uid_subdomain parsed)

    {-
    signSelfAuthTorKeys selfkey g sec grip timestamp xs = ys
     where
        keys = filter isKey sec
        mainpubkey = fst (head xs)
        uidxs0 = map snd xs
        (uidxs, additional, xs'',g') = signSelfAuthTorKeys' selfkey g keys grip timestamp mainpubkey uidxs0
        ys = uidxs++ additional++xs''
    -}

    signSelfAuthTorKeys' selfkey keys grip mainpubkey (uid:xs') = do
        new_sig <- let wkun = fromJust selfkey
                       tor_ov = torSigOver mainpubkey wkun uid flgs
                   in pgpSign (Message [wkun])
                              tor_ov
                              SHA1
                              (fingerprint wkun)
        return (additional new_sig) -- (uid:sigs,additional,xs'',g')
     where
        (sigs, xs'') = span isSignaturePacket xs'
        overs sig = signatures $ Message (keys++[mainpubkey,uid,sig])
        vs :: [ ( Packet -- signature
                , Maybe SignatureOver -- Nothing means non-verified
                , Packet ) -- key who signed
              ]
        vs = do
            sig <- sigs
            o <- overs sig 
            k <- keys
            let ov = verify (Message [k]) $ o
            signatures_over ov
            return (sig,Just ov,k)
        {-
        mainsigs = filter (\(sig,v,whosign) -> isJust (v >> Just mainpubkey >>= guard 
                                                                   . (== keykey whosign) 
                                                                   . keykey))
                          vs
        -}
        selfsigs = filter (\(sig,v,whosign) -> isJust (v >> selfkey >>= guard 
                                                                   . (== keykey whosign) 
                                                                   . keykey))
                          vs
        additional new_sig = do
            new_sig <- maybeToList new_sig
            guard $ {- trace (unlines $ [ "selfsigs = "++show (map ((\(_,_,k)->fingerprint k)) selfsigs)
                                     , " for mainkey = "++fingerprint mainpubkey] )
                        -}
                          (null $ selfsigs)
            signatures_over new_sig
        modsig sig = sig { signature = map id (signature sig) }
            where plus1 (MPI x) = MPI (x+1)
        params newtop = public ++ map fst (key newtop) ++ "}"
                where
                    public = case newtop of
                                PublicKeyPacket {} -> "public{"
                                SecretKeyPacket {} -> if L.null (encrypted_data newtop )
                                                            then "secret{"
                                                            else "encrypted{"
                                _                  -> "??????{"
        traceSig newtop newuid new_sig = (unlines ["mainpubkey:"++ show (fingerprint mainpubkey)
                                        ,"new_sig topkey:"++ (show . fingerprint $ newtop)
                                        ,"new_sig topkey params: "++ params newtop
                                        ,"new_sig user_id:"++ (show newuid)
                                        ,"new_sig |over| = " ++ (show . length $ new_sig)
                                        ,"new_sig hashed = " ++ (PP.ppShow . concatMap hashed_subpackets $ new_sig)
                                        ,"new_sig unhashed = " ++ (show . concatMap unhashed_subpackets $ new_sig)
                                        ,"new_sig type: " ++ (show . map signature_type $ new_sig)
                                        ,"new_sig signature:" ++ (show . concatMap signature $ new_sig)
                                        ,"new_sig isSignaturePacket(over) = " ++ (show . map isSignaturePacket $ new_sig)
                                        ,"issuer = " ++ show (map signature_issuer new_sig)
                                        ])
        flgs = if keykey mainpubkey == keykey (fromJust selfkey)
                then keyFlags0 mainpubkey (map (\(x,_,_)->x) selfsigs)
                else []
        -- (new_sig,g') = todo g mainpubkey (fromJust selfkey) uid timestamp flgs
        {-
        new_sig <- let wkun = fromJust selfkey
                   in pgpSign (Message [wkun])
                              tor_ov
                              SHA1
                              (fingerprint wkun)
        -}

        -- ys = uid:sigs++ additional++xs''

    {-
    doCmd cmd@(List {}) = do
        (homedir,secring,grip) <- getHomeDir cmd
        (Message sec) <- readPacketsFromFile secring
        putStrLn $ listKeys sec

    doCmd cmd@(WorkingKey {}) = do
        (homedir,secring,grip) <- getHomeDir cmd
        (Message sec) <- readPacketsFromFile secring
        -- let s2k' = map s2k (filter isKey sec)
        -- putStrLn $ "s2k = " ++ show s2k'
        putStrLn $ listKeysFiltered (maybeToList grip) sec
        return ()

    doCmd cmd@(AutoSign {}) = do
        ( homedir -- e3ozbhvej4jvlu43.onion/gpg/gnupghome
          , sec   -- e3ozbhvej4jvlu43.onion/gpg/gnupghome/secring.gpg
          , grip  -- Just "AD1CA892FCF4ED9829C762269BDEA5B4D5643321"
          ) <- getPGPEnviron cmd
        flip (maybe (error "No working key?")) grip $ \grip -> do
        pw <- getPassphrase cmd
        let (pre, wk:subs) = seek_key (KeyGrip grip) sec
            wkun = if symmetric_algorithm wk == Unencrypted
                    then Just wk
                    else do
                        k <- decryptSecretKey pw wk
                        guard (symmetric_algorithm k == Unencrypted)
                        return k
        flip (maybe (error "Bad passphrase?")) wkun$ \wkun -> do
        -- putStrLn $ "getPGPEnviron -> " ++ show (homedir,length sec,grip)
        (Message pub) <- readPacketsFromFile (input cmd)
        putStrLn $ listKeys pub
        -- forM_ (zip [1..] pub) $ \(i,k) -> do
        --     putStrLn $ show i ++ ": " ++ show k
        let torbindings = getTorKeys pub
            keyed = uidScan pub
            marked = zipWith doit keyed pub
            doit (mkey,u) packet = (isTorID packet, (mkey,u,packet))
                where
                    isTorID (UserIDPacket str) =
                        and [ uid_topdomain parsed == "onion"
                            , uid_realname parsed `elem` ["","Anonymous"]
                            , uid_user parsed == "root"
                            , fmap (match . fst) (lookup mkey torbindings)
                                == Just True ]
                      where parsed = parseUID str
                            match = ( (==subdom) . take (fromIntegral len))
                            subdom0 = L.fromChunks [encodeUtf8 (uid_subdomain parsed)]
                            subdom = Char8.unpack subdom0
                            len = T.length (uid_subdomain parsed)

                    isTorID _                  = False

        g <- newGenIO
        timestamp <- now
        -- timestamp <- epochTime
        let xs:xss = groupBy (\_ (b,_)->not b) marked
            pub' = map (snd . cleanup) xs
                    ++ concatMap (signSelfAuthTorKeys (Just wkun) (g::SystemRandom) sec grip timestamp)
                                 (map (map cleanup) xss)
            cleanup (_,(topkey,_,pkt)) = (topkey,pkt)
        putStrLn $ "-------- signed ------> " -- ++ show (length pub, length pub')
        putStrLn ""
        putStrLn $ listKeysFiltered (map fingerprint (filter isPublicMaster pub'))  (sec++pub')

        let signed_bs = encode (Message pub')
        L.writeFile (output cmd) signed_bs

    doCmd cmd@(Public {}) = do
        ( homedir -- e3ozbhvej4jvlu43.onion/gpg/gnupghome
          , sec   -- e3ozbhvej4jvlu43.onion/gpg/gnupghome/secring.gpg
          , grip  -- Just "AD1CA892FCF4ED9829C762269BDEA5B4D5643321"
          ) <- getPGPEnviron cmd
        let pub = map secretToPublic sec
            bs = encode (Message pub)
        L.writeFile (output cmd) bs

    doCmd cmd@(DumpPackets {}) = do
        ( homedir -- e3ozbhvej4jvlu43.onion/gpg/gnupghome
          , sec   -- e3ozbhvej4jvlu43.onion/gpg/gnupghome/secring.gpg
          , grip  -- Just "AD1CA892FCF4ED9829C762269BDEA5B4D5643321"
          ) <- getPGPEnviron cmd
        p <- case files cmd of
                    [] -> return sec
                    fs -> do
                            ms <- mapM readPacketsFromFile fs
                            let unwrap (Message ps) = ps
                            return (concatMap unwrap ms)
        if map toLower (marshal_test cmd) `elem` ["y","yes"]
            then L.putStr $ encode (Message p)
            else putStrLn $ PP.ppShow p

    doCmd cmd@(MergeSecrets {}) = do
        ( homedir -- e3ozbhvej4jvlu43.onion/gpg/gnupghome
          , sec   -- e3ozbhvej4jvlu43.onion/gpg/gnupghome/secring.gpg
          , grip  -- Just "AD1CA892FCF4ED9829C762269BDEA5B4D5643321"
          ) <- getPGPEnviron cmd
        let db = merge Map.empty "%secring" (Message sec)
        ms <- mapM readPacketsFromFile' (files cmd)
        let db' = foldl' (uncurry . merge) db ms
            m = flattenKeys False db'
        L.putStr (encode m)
        return ()

    -}

    {-
    doCmd cmd@(Cross_Merge {}) = do
        (homedir,secring,pubring,grip0) <- getHomeDir (homedir cmd)
        -- grip0 may be empty, in which case we should use the first key
        cross_merge (secring:pubring:files cmd) $ \_ db -> return $ (Just db,db)

    doCmd cmd@(CatPub {}) = do
        let spec:files = catpub_args cmd
        let (topspec,subspec) = unprefix '/' spec
            (toptyp,top) = unprefix ':' topspec
            (subtyp,sub) = unprefix ':' subspec

        {-
        putStrLn $ "files = " ++ show files
        putStrLn $ "topspec = " ++show (toptyp,top)
        putStrLn $ "subspec = " ++show (subtyp,sub)
        -}
        ( homedir -- e3ozbhvej4jvlu43.onion/gpg/gnupghome
          , sec   -- e3ozbhvej4jvlu43.onion/gpg/gnupghome/secring.gpg
          , grip  -- Just "AD1CA892FCF4ED9829C762269BDEA5B4D5643321"
          ) <- getPGPEnviron cmd

        flip (maybe (error "No working key?")) grip $ \grip -> do

        ms <- mapM readPacketsFromFile' files
        let db = merge Map.empty "%secring" (Message sec)
            db' = foldl' (uncurry . merge) db ms
            m = flattenKeys True db'
            Message allpkts = m

        let topspec = case () of
                        _ | null top && (subtyp=="fp" || (null subtyp && is40digitHex sub))
                                     -> KeyGrip sub
                        _ | null top -> KeyGrip grip
                        _ | toptyp=="fp" || (null toptyp && is40digitHex top)
                                     -> {- trace "using top" $ -} KeyGrip top
                        _ | toptyp=="u" -> KeyUidMatch top
                        _ | otherwise -> KeyUidMatch top
            (pre, wksubs) = seek_key topspec allpkts
        if null wksubs then error ("No match for "++spec) else do
        let wk:subs = wksubs
            (_,wksubs') = seek_key topspec subs -- ambiguity check
            (_,ys) = case subtyp of
                        "t" -> seek_key (KeyTag wk sub) subs
                        "fp" | top=="" -> ([],wk:subs)
                        "" | top=="" && is40digitHex sub -> ([],wk:subs)
                        "" -> seek_key (KeyTag wk sub) subs
        when (not (null ys)) $ do
        let (_,ys') = seek_key (KeyTag wk sub) (tail ys) -- ambiguity check
            k = head ys
            rsa = pkcs8 . fromJust $ rsaKeyFromPacket k
            der = encodeASN1 DER (toASN1 rsa [])
            qq  = Base64.encode (L.unpack der)
            split64 [] = []
            split64 qq = as : split64 bs where (as,bs) = splitAt 64 qq
        -- putStrLn $ "top = " ++ show top
        -- putStrLn $ "wk = " ++ fingerprint wk
        -- putStrLn $ fingerprint k
        {-
        putStrLn $ show rsa
        putStrLn $ show der
        -}
        if null ys' && null wksubs'
         then
            putStr $ unlines (["-----BEGIN PUBLIC KEY-----"]
                              ++split64 qq
                              ++["-----END PUBLIC KEY-----"])
         else
            error "Key specification is ambiguous."

    doCmd cmd@(Add {}) = do
        ( homedir -- e3ozbhvej4jvlu43.onion/gpg/gnupghome
          , sec   -- e3ozbhvej4jvlu43.onion/gpg/gnupghome/secring.gpg
          , grip  -- Just "AD1CA892FCF4ED9829C762269BDEA5B4D5643321"
          ) <- getPGPEnviron cmd
        pw <- getPassphrase cmd

        flip (maybe (error "No working key?")) grip $ \grip -> do

        let (pre, wk:subs) = seek_key (KeyGrip grip) sec
            wkun = if symmetric_algorithm wk == Unencrypted
                    then Just wk
                    else do
                        k <- decryptSecretKey pw wk
                        guard (symmetric_algorithm k == Unencrypted)
                        return k

        flip (maybe (error "Bad passphrase?")) wkun$ \wkun -> do

        let (uids,subkeys) = break isSubkey subs
            isSubkey p = isKey p && is_subkey p

            (subkeys',remainder) = break isTopKey subkeys
            isTopKey p@(SecretKeyPacket {}) | not (is_subkey p) = True
            isTopKey _ = False

        let parseKeySpec hint spec = case break (==':') spec of
                                    (fmt,_:file) -> (fmt,file)
                                    (file,"") -> (guessKeyFormat hint (key_usage cmd), file)
            (secfmt,secfile) = parseKeySpec 'S' $ seckey cmd
            -- (pubfmt,pubfile) = parseKeySpec 'P' $ pubkey cmd
        Message parsedkey <- readKeyFromFile False secfmt secfile

        let pkf = fingerprint (head parsedkey)
            (prepk,pks) = seek_key (KeyGrip pkf) subkeys'

        g <- newGenIO
        timestamp <- now
        let uids' = do
                        torkey <- parsedkey
                        if key_usage cmd /= "tor"
                         then uids
                         else let ps = makeTorUID (g::SystemRandom)
                                                  timestamp
                                                  wkun
                                                  (keyFlags wkun uids)
                                                  wk
                                                  torkey
                                  toruid = head ps
                              in if toruid `elem` uids then uids else uids ++ ps
        if not (null pks)
            then existingKey (prepk,pks) remainder  wkun wk parsedkey (key_usage cmd) pre uids' subkeys (output cmd) grip
            else newKey                             wkun wk parsedkey (key_usage cmd) pre uids' subkeys (output cmd) grip

    doCmd cmd@(PemFP {}) = do
        let parseKeySpec hint spec = case break (==':') spec of
                                        (fmt,_:file) -> (fmt,file)
                                        (file,"") -> (guessKeyFormat hint ("ssh-host"), file)
            (secfmt,secfile) = parseKeySpec 'S' $ seckey cmd
        Message seckey <- readKeyFromFile False secfmt secfile
        -- Message pubkey <- readKeyFromFile True  pubfmt pubfile
        -- Tor requires public key file... TODO
        -- let torhash sub = maybe "" id $ derToBase32 <$> derRSA sub
        putStrLn $ fingerprint (head seckey) -- ++ " " ++ torhash (head seckey)

    -}

isSameKey a b = sort (key apub) == sort (key bpub)
 where
    apub = secretToPublic a
    bpub = secretToPublic b

{-
existingKey (prepk,pks) remainder wkun wk parsedkey tag pre uids subkeys output_file grip = do
        -- putStrLn "Key already present."
        let pk:trail = pks
            (trailsigs,trail') = span isSignaturePacket trail
            (mysigs,notmines) = partition (endsWith grip . maybe "%bad%" id . signature_issuer)
                                          trailsigs
            endsWith big small = drop (length big - length small) big == small
            vs = map (\sig ->
                      (sig, map (verify (Message [wk]))
                               (signatures $ Message [wk,pk,sig])))
                     mysigs
            (verified,unverified) = partition (not . null . snd) vs
            sorted = sortBy (comparing (Down . signature_time . head . snd)) verified
        -- Note: format allows for signatures of type 0x28 Subkey revocation signature.
        case sorted of
            [] -> do
                    putStrLn "Adding valid signature to existing key..."
                    newKey wkun wk [pk] tag pre uids (trail++prepk++remainder) output_file grip
            (sig,ov):vs -> do
                -- sig exists.
                -- update sig to contain usage@ = tag
                let hs = filter (\p->isNotation p && notation_name p=="usage@") (hashed_subpackets sig)
                    ks = map notation_value hs
                    isNotation (NotationDataPacket {}) = True
                    isNotation _ = False
                    noop = do
                        -- Nothing to do
                        let sec' = pre ++ [wk] ++ uids ++ subkeys
                        putStrLn $ tag ++ " key already present."
                        L.writeFile output_file (encode (Message sec'))
                if tag `elem` ks
                    then noop
                    else do
                        g <- newGenIO
                        timestamp <- now
                        let isCreation (SignatureCreationTimePacket {}) = True
                            isCreation _ = False
                            isExpiration (SignatureExpirationTimePacket {}) = True
                            isExpiration _ = False
                            (cs,ps) = partition isCreation (hashed_subpackets sig)
                            (es,qs) = partition isExpiration ps
                            stamp = listToMaybe . sortBy (comparing Down) $
                                     map unwrap cs where unwrap (SignatureCreationTimePacket x) = x
                            exp = listToMaybe $ sort $
                                     map unwrap es where unwrap (SignatureExpirationTimePacket x) = x
                            expires = liftA2 (+) stamp exp
                        if fmap ( (< timestamp) . fromIntegral) expires == Just True then do
                            putStrLn $ "Unable to update expired signature"
                            noop
                        else do
                            let new_sig = fst $ sign (Message [wkun])
                                                     (SubkeySignature wk
                                                        (head parsedkey)
                                                         [sig'] )
                                                 SHA1
                                                 grip
                                                 timestamp
                                                 (g::SystemRandom)
                                times = (:) (SignatureExpirationTimePacket (fromIntegral timestamp))
                                            $ maybeToList $ do
                                                e <- expires
                                                return $ SignatureExpirationTimePacket (e - fromIntegral timestamp)
                                notation = NotationDataPacket
                                            { notation_name = "usage@"
                                            , notation_value = tag
                                            , human_readable = True }
                                sig' = sig { hashed_subpackets = times ++ [notation] ++ qs }

                        -- noop let sec' = pre ++ [wk] ++ uids ++ subkeys
                                sec' = pre
                                        ++ [wk]
                                        ++ uids
                                        ++ prepk
                                        ++ [pk]
                                        ++ signatures_over new_sig
                                        ++ map fst vs
                                        ++ map fst unverified
                                        ++ notmines
                                        ++ trail'
                                        ++ remainder
                            putStrLn $ "Adding usage@="++tag
                            L.writeFile output_file (encode (Message sec'))

newKey wkun wk parsedkey tag pre uids subkeys output_file grip = do
        g <- newGenIO
        timestamp <- now

        let
                new_sig = fst $ sign (Message [wkun])
                             (SubkeySignature wk
                                              (head parsedkey)
                                              (sigpackets 0x18
                                                          hashed0
                                                          ( IssuerPacket (fingerprint wk)
                                                            : map EmbeddedSignaturePacket (signatures_over back_sig))))
                             SHA1
                             grip
                             timestamp
                             (g::SystemRandom)

                hashed0 =
                    [ KeyFlagsPacket
                        { certify_keys = False
                        , sign_data = False
                        , encrypt_communication = False
                        , encrypt_storage = False
                        , split_key = False
                        , authentication = True
                        , group_key = False }
                    , NotationDataPacket
                        { human_readable = True
                        , notation_name = "usage@"
                        , notation_value = tag
                        }
                    , SignatureCreationTimePacket (fromIntegral timestamp)
                    ]

                subgrip = fingerprint (head parsedkey)

                back_sig = fst $ sign (Message parsedkey)
                             (SubkeySignature wk
                                              (head parsedkey)
                                              (sigpackets 0x19
                                                          hashed0
                                                          [IssuerPacket subgrip]))
                             SHA1
                             subgrip
                             timestamp
                             (g::SystemRandom)

        let sec' = pre ++ [wk] ++ uids ++ parsedkey ++ signatures_over new_sig ++ subkeys
        putStrLn $ listKeys sec'

        L.writeFile output_file (encode (Message sec'))

        {-
        let backsigs = do
                sig <- signatures (Message sec')
                sigover <- signatures_over sig
                subp <- unhashed_subpackets sigover
                -- guard (isEmbeddedSignature subp)
                subp <- maybeToList (backsig subp)
                over <- signatures (Message (filter isKey sec ++ [subp]))
                return over

        -- putStrLn $ PP.ppShow backsigs
        -}

        return ()
-}



groupBindings pub =
        let (sigs,bindings) = getBindings pub
            bindings' = accBindings bindings
            code (c,(m,s),_,_,_) = (fingerprint_material m,-c)
            ownerkey (_,(a,_),_,_,_) = a
            sameMaster (ownerkey->a) (ownerkey->b) = fingerprint_material a==fingerprint_material b
            -- matchgrip ((code,(top,sub), kind, hashed,claimants):_) | fpmatch grip top = True
            -- matchgrip _ = False
            gs = {- filter matchgrip $ -} groupBy sameMaster (sortBy (comparing code) bindings')
        in gs

isTopKey p@(SecretKeyPacket {}) | not (is_subkey p) = True
isTopKey p@(PublicKeyPacket {}) | not (is_subkey p) = True
isTopKey _ = False

filterMatches :: KeySpec -> [(KeyKey,KeyData)] -> [(KeyKey,KeyData)]
filterMatches spec ks = filter (matchSpec spec) ks

selectSecretKey :: (KeySpec,Maybe String) -> KeyDB -> Maybe Packet
selectSecretKey (spec,mtag) db = selectKey0 False (spec,mtag) db

selectPublicKey :: (KeySpec,Maybe String) -> KeyDB -> Maybe Packet
selectPublicKey (spec,mtag) db = selectKey0 True (spec,mtag) db

selectKey0 :: Bool -> (KeySpec,Maybe String) -> KeyDB -> Maybe Packet
selectKey0 wantPublic (spec,mtag) db = do
    let Message ps = flattenKeys wantPublic db
        ys = snd $ seek_key spec ps
    flip (maybe (listToMaybe ys)) mtag $ \tag -> do
    let (subspec,ys1) = (KeyTag y tag,ys1) where y:ys1 = ys
        zs = snd $ seek_key subspec ys1
    listToMaybe zs

matchSpec (KeyGrip grip) (_,KeyData p _ _ _) 
    | matchpr grip (packet p)==grip = True
    | otherwise                     = False

matchSpec (KeyTag key tag) (_,KeyData _ sigs _ _) = not . null $ filter match ps
 where
    ps = map (packet .fst) sigs
    match p = isSignaturePacket p
                && has_tag tag p
                && has_issuer key p
    has_issuer key p = isJust $ do
        issuer <- signature_issuer p
        guard $ matchpr issuer key == issuer
    has_tag tag p = tag `elem` mapMaybe usage (hashed_subpackets p)
                    || tag `elem` map usageString (mapMaybe keyflags (hashed_subpackets p))

matchSpec (KeyUidMatch pat) (_,KeyData _ _ uids _) = not $ null us
  where
    us = filter (isInfixOf pat) $ Map.keys uids

seek_key :: KeySpec -> [Packet] -> ([Packet],[Packet])
seek_key (KeyGrip grip) sec = (pre, subs)
  where
    (pre,subs) = break pred sec
    pred p@(SecretKeyPacket {}) = matchpr grip p == grip
    pred p@(PublicKeyPacket {}) = matchpr grip p == grip
    pred _                      = False

seek_key (KeyTag key tag) ps = if null bs
                                then (ps,[])
                                else if null qs
                                 then let (as',bs') = seek_key (KeyTag key tag) (tail bs)
                                      in (as ++ (head bs:as'), bs')
                                 else (reverse (tail qs), head qs : reverse rs ++ bs)
  where
    (as,bs) = break (\p -> isSignaturePacket p
                        && has_tag tag p
                        && isJust (signature_issuer p)
                        && matchpr (fromJust $ signature_issuer p) key == fromJust (signature_issuer p) )
                    ps
    (rs,qs) = break isKey (reverse as)

    has_tag tag p = tag `elem` mapMaybe usage (hashed_subpackets p)
                    || tag `elem` map usageString (mapMaybe keyflags (hashed_subpackets p))

seek_key (KeyUidMatch pat) ps = if null bs
                                then (ps,[])
                                else if null qs
                                 then let (as',bs') = seek_key (KeyUidMatch pat) (tail bs)
                                      in (as ++ (head bs:as'), bs')
                                 else (reverse (tail qs), head qs : reverse rs ++ bs)
  where
    (as,bs) = break (isInfixOf pat . uidStr)
                    ps
    (rs,qs) = break isKey (reverse as)

    uidStr (UserIDPacket s) = s
    uidStr _                = ""

groupTops ps = groupBy (\_ b -> not (isTopKey b)) ps


{-
makeTorUID g timestamp wkun keyflags topkey torkey = uid:signatures_over sig
 where
    torhash sub = maybe "" id $ derToBase32 <$> derRSA sub
    s = "Anonymous <root@" ++ take 16 (torhash torkey) ++ ".onion>"
    uid = UserIDPacket s
    sig = fst $ torsig g topkey wkun uid timestamp keyflags
-}

-- torsig g topk wkun uid timestamp extras = todo
torSigOver topk wkun uid extras
    = CertificationSignature (secretToPublic topk)
                             uid
                             (sigpackets 0x13
                                         subpackets
                                         subpackets_unh)
   where
    subpackets = -- implicit: [ SignatureCreationTimePacket (fromIntegral timestamp) ]
                 tsign
                 ++ extras
    subpackets_unh = [IssuerPacket (fingerprint wkun)]
    tsign = if keykey wkun == keykey topk
             then [] -- tsign doesnt make sense for self-signatures
             else [ TrustSignaturePacket 1 120
                  , RegularExpressionPacket regex]
    -- <[^>]+[@.]asdf\.nowhere>$
    regex = "<[^>]+[@.]"++hostname++">$"
    -- regex = username ++ "@" ++ hostname
    -- username = "[a-zA-Z0-9.][-a-zA-Z0-9.]*\\$?" :: String
    hostname = subdomain' pu ++ "\\." ++ topdomain' pu
    pu = parseUID uidstr where UserIDPacket uidstr = uid
    subdomain' = escape . T.unpack . uid_subdomain
    topdomain' = escape . T.unpack . uid_topdomain
    escape s = concatMap echar s
      where
        echar '|' = "\\|"
        echar '*' = "\\*"
        echar '+' = "\\+"
        echar '?' = "\\?"
        echar '.' = "\\."
        echar '^' = "\\^"
        echar '$' = "\\$"
        echar '\\' = "\\\\"
        echar '[' = "\\["
        echar ']' = "\\]"
        echar c = [c]

sigpackets typ hashed unhashed = return $
    signaturePacket
        4 -- version
        typ -- 0x18 subkey binding sig, or 0x19 back-signature
        RSA
        SHA1
        hashed
        unhashed
        0 -- Word16 -- Left 16 bits of the signed hash value
        [] -- [MPI]

keyFlags  wkun uids = keyFlags0 wkun (filter isSignaturePacket uids)
 {-
 where
    vs = map (verify (Message [wkun])) (signatures (Message (wkun:uids)))
    ws = map signatures_over vs
    xs = filter null ws
    -}

keyFlags0 wkun uidsigs = concat
                      [ keyflags
                      , preferredsym
                      , preferredhash
                      , preferredcomp
                      , features ]

 where
    subs = concatMap hashed_subpackets uidsigs
    keyflags = filterOr isflags subs $
               KeyFlagsPacket { certify_keys = True
                              , sign_data = True
                              , encrypt_communication = False
                              , encrypt_storage = False
                              , split_key = False
                              , authentication = False
                              , group_key = False
                              }
    preferredsym = filterOr ispreferedsym subs $
               PreferredSymmetricAlgorithmsPacket
                              [ AES256
                              , AES192
                              , AES128
                              , CAST5
                              , TripleDES
                              ]
    preferredhash = filterOr ispreferedhash subs $
               PreferredHashAlgorithmsPacket
                              [ SHA256
                              , SHA1
                              , SHA384
                              , SHA512
                              , SHA224
                              ]
    preferredcomp = filterOr ispreferedcomp subs $
               PreferredCompressionAlgorithmsPacket
                              [ ZLIB
                              , BZip2
                              , ZIP
                              ]
    features = filterOr isfeatures subs $
               FeaturesPacket { supports_mdc = True
                              }

    filterOr pred xs def = if null rs then [def] else rs where rs=filter pred xs

    isflags (KeyFlagsPacket {}) = True
    isflags _ = False
    ispreferedsym (PreferredSymmetricAlgorithmsPacket {}) = True
    ispreferedsym _ = False
    ispreferedhash (PreferredHashAlgorithmsPacket {}) = True
    ispreferedhash _ = False
    ispreferedcomp (PreferredCompressionAlgorithmsPacket {}) = True
    ispreferedcomp _ = False
    isfeatures (FeaturesPacket {}) = True
    isfeatures _ = False