{- P2P protocol, IO implementation - - Copyright 2016 Joey Hess - - Licensed under the GNU GPL version 3 or higher. -} {-# LANGUAGE RankNTypes, FlexibleContexts, BangPatterns, CPP #-} module P2P.IO ( RunProto , RunEnv(..) , runNetProto , runNet ) where import P2P.Protocol import Utility.Process import Git import Git.Command import Utility.AuthToken import Utility.SafeCommand import Utility.SimpleProtocol import Utility.Exception import Control.Monad import Control.Monad.Free import Control.Monad.IO.Class import System.Exit (ExitCode(..)) import System.IO import Control.Concurrent import Control.Concurrent.Async import qualified Data.ByteString as B import qualified Data.ByteString.Lazy as L -- Type of interpreters of the Proto free monad. type RunProto m = forall a. (MonadIO m, MonadMask m) => Proto a -> m (Maybe a) data RunEnv = RunEnv { runRepo :: Repo , runCheckAuth :: (AuthToken -> Bool) , runIhdl :: Handle , runOhdl :: Handle } -- Purposefully incomplete interpreter of Proto. -- -- This only runs Net actions. No Local actions will be run -- (those need the Annex monad) -- if the interpreter reaches any, -- it returns Nothing. runNetProto :: RunEnv -> Proto a -> IO (Maybe a) runNetProto runenv = go where go :: RunProto IO go (Pure v) = pure (Just v) go (Free (Net n)) = runNet runenv go n go (Free (Local _)) = return Nothing -- Interpreter of the Net part of Proto. -- -- An interpreter of Proto has to be provided, to handle the rest of Proto -- actions. runNet :: (MonadIO m, MonadMask m) => RunEnv -> RunProto m -> NetF (Proto a) -> m (Maybe a) runNet runenv runner f = case f of SendMessage m next -> do v <- liftIO $ tryIO $ do hPutStrLn (runOhdl runenv) (unwords (formatMessage m)) hFlush (runOhdl runenv) case v of Left _e -> return Nothing Right () -> runner next ReceiveMessage next -> do v <- liftIO $ tryIO $ hGetLine (runIhdl runenv) case v of Left _e -> return Nothing Right l -> case parseMessage l of Just m -> runner (next m) Nothing -> runner $ do let e = ERROR $ "protocol parse error: " ++ show l net $ sendMessage e next e SendBytes len b next -> do v <- liftIO $ tryIO $ do ok <- sendExactly len b (runOhdl runenv) hFlush (runOhdl runenv) return ok case v of Right True -> runner next _ -> return Nothing ReceiveBytes (Len n) next -> do v <- liftIO $ tryIO $ L.hGet (runIhdl runenv) (fromIntegral n) case v of Left _e -> return Nothing Right b -> runner (next b) CheckAuthToken _u t next -> do let authed = runCheckAuth runenv t runner (next authed) Relay hin hout next -> do v <- liftIO $ runRelay runnerio hin hout case v of Nothing -> return Nothing Just exitcode -> runner (next exitcode) RelayService service next -> do v <- liftIO $ runRelayService runenv runnerio service case v of Nothing -> return Nothing Just () -> runner next where -- This is only used for running Net actions when relaying, -- so it's ok to use runNetProto, despite it not supporting -- all Proto actions. runnerio = runNetProto runenv -- Send exactly the specified number of bytes or returns False. -- -- The ByteString can be larger or smaller than the specified length. -- For example, it can be lazily streaming from a file that gets -- appended to, or truncated. -- -- Must avoid sending too many bytes as it would confuse the other end. -- This is easily dealt with by truncating it. -- -- If too few bytes are sent, the only option is to give up on this -- connection. False is returned to indicate this problem. -- -- We can't check the length of the whole lazy bytestring without buffering -- it in memory. Instead, process it one chunk at a time, and sum the length -- of the chunks. sendExactly :: Len -> L.ByteString -> Handle -> IO Bool sendExactly (Len l) lb h = go 0 $ L.toChunks $ L.take (fromIntegral l) lb where go n [] = return (toInteger n == l) go n (b:bs) = do B.hPut h b let !n' = n + B.length b go n' bs runRelay :: RunProto IO -> RelayHandle -> RelayHandle -> IO (Maybe ExitCode) runRelay runner (RelayHandle hout) (RelayHandle hin) = bracket setup cleanup go where setup = do v <- newEmptyMVar void $ async $ relayFeeder runner v void $ async $ relayReader v hout return v cleanup _ = do hClose hin hClose hout go v = relayHelper runner v hin runRelayService :: RunEnv -> RunProto IO -> Service -> IO (Maybe ()) runRelayService runenv runner service = bracket setup cleanup go where cmd = case service of UploadPack -> "upload-pack" ReceivePack -> "receive-pack" serviceproc = gitCreateProcess [ Param cmd , File (repoPath (runRepo runenv)) ] (runRepo runenv) setup = do (Just hin, Just hout, _, pid) <- createProcess serviceproc { std_out = CreatePipe , std_in = CreatePipe } v <- newEmptyMVar void $ async $ relayFeeder runner v void $ async $ relayReader v hout waiter <- async $ waitexit v pid return (v, waiter, hin, hout, pid) cleanup (_, waiter, hin, hout, pid) = do hClose hin hClose hout cancel waiter void $ waitForProcess pid go (v, _, hin, _, _) = do r <- relayHelper runner v hin case r of Nothing -> return Nothing Just exitcode -> runner $ net $ relayToPeer (RelayDone exitcode) waitexit v pid = putMVar v . RelayDone =<< waitForProcess pid -- Processes RelayData as it is put into the MVar. relayHelper :: RunProto IO -> MVar RelayData -> Handle -> IO (Maybe ExitCode) relayHelper runner v hin = loop where loop = do d <- takeMVar v case d of RelayFromPeer b -> do L.hPut hin b hFlush hin loop RelayToPeer b -> do r <- runner $ net $ relayToPeer (RelayToPeer b) case r of Nothing -> return Nothing Just () -> loop RelayDone exitcode -> do _ <- runner $ net $ relayToPeer (RelayDone exitcode) return (Just exitcode) -- Takes input from the peer, and puts it into the MVar for processing. -- Repeats until the peer tells it it's done or hangs up. relayFeeder :: RunProto IO -> MVar RelayData -> IO () relayFeeder runner v = loop where loop = do mrd <- runner $ net relayFromPeer case mrd of Nothing -> putMVar v (RelayDone (ExitFailure 1)) Just rd -> do putMVar v rd case rd of RelayDone _ -> return () _ -> loop -- Reads input from the Handle and puts it into the MVar for relaying to -- the peer. Continues until EOF on the Handle. relayReader :: MVar RelayData -> Handle -> IO () relayReader v hout = loop where loop = do bs <- getsome [] case bs of [] -> return () _ -> do putMVar v $ RelayToPeer (L.fromChunks bs) loop -- Waiit for the first available chunk. Then, without blocking, -- try to get more chunks, in case a stream of chunks is being -- written in close succession. -- -- On Windows, hGetNonBlocking is broken, so avoid using it there. getsome [] = do b <- B.hGetSome hout chunk if B.null b then return [] #ifndef mingw32_HOST_OS else getsome [b] #else else return [b] #endif getsome bs = do b <- B.hGetNonBlocking hout chunk if B.null b then return (reverse bs) else getsome (b:bs) chunk = 65536