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module Main(main) where
import Test.HUnit
import Test.HUnit.Base
import Data.Word (Word8)
import Data.Bits (xor)
import Network.EBus.Layer2 as L2
import Test.Layer2 as Test.Layer2
-- main = do
-- -- * Select binary mode (True) or text mode (False) on a open handle. (See also openBinaryFile.)
-- hSetBinaryMode stdin True
-- -- * run
-- -- Run an iteratee until it finishes, and return either the final value (if it succeeded) or the error (if it failed).
-- -- * run_
-- -- Like run, except errors are converted to exceptions and thrown. Primarily useful for small scripts or other simple cases.
-- maybePacket <- run( enumSource $$ runParser )
-- case maybePacket of
-- Right result -> print result
-- Left error -> print error
-- maybePacket <- run( enumSource $$ runParser )
-- case maybePacket of
-- Right result -> print result
-- Left error -> print error
-- enumSource :: Enumerator ByteString IO a
-- enumSource = enumHandle 1 stdin
-- runParser :: Iteratee ByteString IO EbusPacket
-- runParser = do
-- p <- iterParser parser
-- return p
main = runTestTT $ TestList Test.Layer2.tests
-- defaultMain [
-- testGroup "SomeModule" [ testCase "foo" foooo]
-- ]
--tests = TestList [TestLabel "bla" foooo]
tests = TestList [ ]
--"Test:" ~: L2.ebusCrc [1 .. 7] ~=? 96
-- , "Test:" ~: L2.ebusCrc [8,1,1,16,255,88,255,60,9] ~=? 247]
-- listEnumerator :: Enumerator ByteString IO a
-- listEnumerator = enumLists l
-- where l::[[ByteString]]
-- l = [[pack [1,2,3]]]
--foooo = -- TestList(
-- ~: ~=? "asd" 2 2
-- assertBool "foo" True
-- print $ ebusCrc [1,2,3]
-- quickCheck (\s(\s -> length (take5 s) == 5)
-- if ebusCrc [1,2,3,4,5,6,7] == 96
-- then IO ()
-- else assertFailure "Failed"
-- print "\nOK"
-- )
-- import Control.Concurrent (forkOS)
-- import Control.Concurrent.MVar (MVar, newEmptyMVar, readMVar, putMVar)
-- import Control.Exception (finally)
-- import Control.Monad.Trans (liftIO)
-- import qualified Data.Binary as B
-- import qualified System.ZMQ as ZMQ
-- import Control.Monad.BinaryProtocol.ZMQ
-- (BinaryProtocol, runProtocol, send, receive, flush)
-- main :: IO ()
-- main = defaultMain tests
-- tests :: [TF.Test]
-- tests =
-- [ testGroup "unidirectional communications"
-- [ testCase "send unit" testSendUnit
-- , testCase "send number" testSendNumber
-- , testCase "send list of numbers" testSendListOfNumbers
-- ]
-- , testGroup "bidirectional communications"
-- [ testCase "addition" testAddition
-- ]
-- ]
-- makeChannels :: ZMQ.Context -> String -> IO (ZMQ.Socket ZMQ.Up,
-- ZMQ.Socket ZMQ.Down)
-- makeChannels ctx address = do
-- chan1 <- ZMQ.socket ctx ZMQ.Up
-- chan2 <- ZMQ.socket ctx ZMQ.Down
-- ZMQ.bind chan1 address
-- ZMQ.connect chan2 address
-- return (chan1, chan2)
-- makeSendTest :: (B.Binary a, Eq a, Show a) => a -> IO ()
-- makeSendTest value = do
-- ctx <- ZMQ.init 1
-- (chan_in, chan_out) <- makeChannels ctx "inproc://pipe"
-- result <- runProtocol actions chan_in chan_out `finally` do
-- ZMQ.close chan_out
-- ZMQ.close chan_in
-- ZMQ.term ctx
-- assertEqual "Was the correct value received?" value result
-- where actions = do
-- send value
-- flush
-- receive
-- testSendUnit :: IO ()
-- testSendUnit = makeSendTest ()
-- testSendNumber :: IO ()
-- testSendNumber = makeSendTest (3 :: Int)
-- testSendListOfNumbers :: IO ()
-- testSendListOfNumbers = makeSendTest [3 :: Int, 4, 5, 6]
-- makeExchangeTest :: (B.Binary a, Show a, Eq a) =>
-- a ->
-- (MVar a -> BinaryProtocol ZMQ.Up ZMQ.Down ()) ->
-- (MVar a -> BinaryProtocol ZMQ.Up ZMQ.Down ()) ->
-- IO ()
-- makeExchangeTest correct_result protocol1 protocol2 = do
-- resultMVar <- newEmptyMVar
-- ctx <- ZMQ.init 1
-- lock1 <- newEmptyMVar
-- lock2 <- newEmptyMVar
-- -- ZeroMQ sockets can only be used in the thread which created them.
-- -- We need some magic to get this right.
-- f $ forkOS $ runProtocol' address1 address2 ctx lock1 lock2
-- (protocol1 resultMVar)
-- f $ forkOS $ runProtocol' address2 address1 ctx lock2 lock1
-- (protocol2 resultMVar)
-- result <- readMVar resultMVar `finally` ZMQ.term ctx
-- assertEqual "Was the correct result computed?" correct_result result
-- where address1 = "inproc://pipe1"
-- address2 = "inproc://pipe2"
-- f :: IO a -> IO ()
-- f a = a >> return ()
-- runProtocol' :: String -> String -> ZMQ.Context ->
-- MVar () -> MVar () ->
-- BinaryProtocol ZMQ.Up ZMQ.Down () -> IO ()
-- runProtocol' a1 a2 ctx l1 l2 p = do
-- chan_in <- ZMQ.socket ctx ZMQ.Up
-- chan_out <- ZMQ.socket ctx ZMQ.Down
-- ZMQ.bind chan_in a1
-- putMVar l1 ()
-- f $ readMVar l2
-- ZMQ.connect chan_out a2
-- runProtocol p chan_in chan_out `finally` do
-- ZMQ.close chan_in
-- ZMQ.close chan_out
-- testAddition :: IO ()
-- testAddition =
-- makeExchangeTest (3 :: Int)
-- (\resultMVar -> do
-- send (1 :: Int)
-- flush
-- receive >>= liftIO . putMVar resultMVar
-- )
-- (\_ -> do
-- a <- receive
-- send (a + (2 :: Int))
-- flush
-- )
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