module Test.Tasty.Ingredients.ConsoleReporter
( consoleTestReporter
, Quiet(..)
, HideSuccesses(..)
) where
import Prelude hiding (fail)
import Control.Monad.State hiding (fail)
import Control.Monad.Reader hiding (fail,reader)
import Control.Concurrent.STM
import Control.Exception
import Control.Applicative
import Test.Tasty.Core
import Test.Tasty.Run
import Test.Tasty.Ingredients
import Test.Tasty.Options
import Test.Tasty.Runners.Reducers
import Test.Tasty.Runners.Utils
import Text.Printf
import qualified Data.IntMap as IntMap
import Data.Char
import Data.Maybe
import Data.Monoid
import Data.Proxy
import Data.Tagged
import Data.Typeable
import Data.Foldable (foldMap)
import Options.Applicative
import System.IO
import System.Console.ANSI
data TestOutput
= PrintTest
(IO ())
(Result -> IO ())
| PrintHeading (IO ()) TestOutput
| Skip
| Seq TestOutput TestOutput
instance Monoid TestOutput where
mempty = Skip
mappend = Seq
type Level = Int
produceOutput :: (?colors :: Bool) => OptionSet -> TestTree -> TestOutput
produceOutput opts tree =
let
!alignment = computeAlignment opts tree
runSingleTest
:: (IsTest t, ?colors :: Bool)
=> OptionSet -> TestName -> t -> Ap (Reader Level) TestOutput
runSingleTest _opts name _test = Ap $ do
level <- ask
let
printTestName =
printf "%s%s: %s" (indent level) name
(replicate (alignment indentSize * level length name) ' ')
printTestResult result = do
rDesc <- formatMessage $ resultDescription result
let
printFn =
if resultSuccessful result
then ok
else fail
time = resultTime result
if resultSuccessful result
then printFn "OK"
else printFn "FAIL"
when (time >= 0.01) $
printFn (printf " (%.2fs)" time)
printFn "\n"
when (not $ null rDesc) $
(if resultSuccessful result then infoOk else infoFail) $
printf "%s%s\n" (indent $ level + 1) (formatDesc (level+1) rDesc)
return $ PrintTest printTestName printTestResult
runGroup :: TestName -> Ap (Reader Level) TestOutput -> Ap (Reader Level) TestOutput
runGroup name grp = Ap $ do
level <- ask
let
printHeading = printf "%s%s\n" (indent level) name
printBody = runReader (getApp grp) (level + 1)
return $ PrintHeading printHeading printBody
in
flip runReader 0 $ getApp $
foldTestTree
trivialFold
{ foldSingle = runSingleTest
, foldGroup = runGroup
}
opts tree
foldTestOutput
:: (?colors :: Bool, Monoid b)
=> (IO () -> IO Result -> (Result -> IO ()) -> b)
-> (IO () -> b -> b)
-> TestOutput -> StatusMap -> b
foldTestOutput foldTest foldHeading outputTree smap =
flip evalState 0 $ getApp $ go outputTree where
go (PrintTest printName printResult) = Ap $ do
ix <- get
put $! ix + 1
let
statusVar =
fromMaybe (error "internal error: index out of bounds") $
IntMap.lookup ix smap
readStatusVar = getResultFromTVar statusVar
return $ foldTest printName readStatusVar printResult
go (PrintHeading printName printBody) = Ap $
foldHeading printName <$> getApp (go printBody)
go (Seq a b) = mappend (go a) (go b)
go Skip = mempty
consoleOutput :: (?colors :: Bool) => TestOutput -> StatusMap -> IO ()
consoleOutput output smap =
getTraversal . fst $ foldTestOutput foldTest foldHeading output smap
where
foldTest printName getResult printResult =
( Traversal $ do
printName
r <- getResult
printResult r
, Any True)
foldHeading printHeading (printBody, Any nonempty) =
( Traversal $ do
when nonempty $ do printHeading; getTraversal printBody
, Any nonempty
)
consoleOutputHidingSuccesses :: (?colors :: Bool) => TestOutput -> StatusMap -> IO ()
consoleOutputHidingSuccesses output smap =
void . getApp $ foldTestOutput foldTest foldHeading output smap
where
foldTest printName getResult printResult =
Ap $ do
printName
r <- getResult
if resultSuccessful r
then do clearThisLine; return $ Any False
else do printResult r; return $ Any True
foldHeading printHeading printBody =
Ap $ do
printHeading
Any failed <- getApp printBody
unless failed clearAboveLine
return $ Any failed
clearAboveLine = do cursorUpLine 1; clearThisLine
clearThisLine = do clearLine; setCursorColumn 0
streamOutputHidingSuccesses :: (?colors :: Bool) => TestOutput -> StatusMap -> IO ()
streamOutputHidingSuccesses output smap =
void . flip evalStateT [] . getApp $
foldTestOutput foldTest foldHeading output smap
where
foldTest printName getResult printResult =
Ap $ do
r <- liftIO $ getResult
if resultSuccessful r
then return $ Any False
else do
stack <- get
put []
liftIO $ do
sequence_ $ reverse stack
printName
printResult r
return $ Any True
foldHeading printHeading printBody =
Ap $ do
modify (printHeading :)
Any failed <- getApp printBody
unless failed $
modify $ \stack ->
case stack of
_:rest -> rest
[] -> []
return $ Any failed
data Statistics = Statistics
{ statTotal :: !Int
, statFailures :: !Int
}
instance Monoid Statistics where
Statistics t1 f1 `mappend` Statistics t2 f2 = Statistics (t1 + t2) (f1 + f2)
mempty = Statistics 0 0
computeStatistics :: StatusMap -> IO Statistics
computeStatistics = getApp . foldMap (\var -> Ap $
(\r -> Statistics 1 (if resultSuccessful r then 0 else 1))
<$> getResultFromTVar var)
printStatistics :: (?colors :: Bool) => Statistics -> Time -> IO ()
printStatistics st time = do
printf "\n"
case statFailures st of
0 -> do
ok $ printf "All %d tests passed (%.2fs)\n" (statTotal st) time
fs -> do
fail $ printf "%d out of %d tests failed (%.2fs)\n" fs (statTotal st) time
data FailureStatus
= Unknown
| Failed
| OK
instance Monoid FailureStatus where
mappend Failed _ = Failed
mappend _ Failed = Failed
mappend OK OK = OK
mappend _ _ = Unknown
mempty = OK
failureStatus :: StatusMap -> IO FailureStatus
failureStatus smap = atomically $ do
fst <- getApp $ flip foldMap smap $ \svar -> Ap $ do
status <- readTVar svar
return $ case status of
Done r ->
if resultSuccessful r then OK else Failed
_ -> Unknown
case fst of
Unknown -> retry
_ -> return fst
consoleTestReporter :: Ingredient
consoleTestReporter =
TestReporter
[ Option (Proxy :: Proxy Quiet)
, Option (Proxy :: Proxy HideSuccesses)
, Option (Proxy :: Proxy UseColor)
] $
\opts tree -> Just $ \smap ->
do
isTerm <- hSupportsANSI stdout
(\k -> if isTerm
then (do hideCursor; k) `finally` showCursor
else k) $ do
hSetBuffering stdout NoBuffering
let
whenColor = lookupOption opts
Quiet quiet = lookupOption opts
HideSuccesses hideSuccesses = lookupOption opts
let
?colors = useColor whenColor isTerm
let
output = produceOutput opts tree
case () of { _
| quiet -> return ()
| hideSuccesses && isTerm ->
consoleOutputHidingSuccesses output smap
| hideSuccesses && not isTerm ->
streamOutputHidingSuccesses output smap
| otherwise -> consoleOutput output smap
}
return $ \time ->
if quiet
then do
fst <- failureStatus smap
return $ case fst of
OK -> True
_ -> False
else do
stats <- computeStatistics smap
printStatistics stats time
return $ statFailures stats == 0
newtype Quiet = Quiet Bool
deriving (Eq, Ord, Typeable)
instance IsOption Quiet where
defaultValue = Quiet False
parseValue = fmap Quiet . safeRead
optionName = return "quiet"
optionHelp = return "Do not produce any output; indicate success only by the exit code"
optionCLParser = flagCLParser (Just 'q') (Quiet True)
newtype HideSuccesses = HideSuccesses Bool
deriving (Eq, Ord, Typeable)
instance IsOption HideSuccesses where
defaultValue = HideSuccesses False
parseValue = fmap HideSuccesses . safeRead
optionName = return "hide-successes"
optionHelp = return "Do not print tests that passed successfully"
optionCLParser = flagCLParser Nothing (HideSuccesses True)
data UseColor
= Never | Always | Auto
deriving (Eq, Ord, Typeable)
instance IsOption UseColor where
defaultValue = Auto
parseValue = parseUseColor
optionName = return "color"
optionHelp = return "When to use colored output. Options are 'never', 'always' and 'auto' (default: 'auto')"
optionCLParser =
option parse
( long name
<> help (untag (optionHelp :: Tagged UseColor String))
)
where
name = untag (optionName :: Tagged UseColor String)
parse = str >>=
maybe (readerError $ "Could not parse " ++ name) pure <$> parseValue
useColor :: UseColor -> Bool -> Bool
useColor when isTerm =
case when of
Never -> False
Always -> True
Auto -> isTerm
parseUseColor :: String -> Maybe UseColor
parseUseColor s =
case map toLower s of
"never" -> return Never
"always" -> return Always
"auto" -> return Auto
_ -> Nothing
getResultFromTVar :: TVar Status -> IO Result
getResultFromTVar var =
atomically $ do
status <- readTVar var
case status of
Done r -> return r
_ -> retry
indentSize :: Int
indentSize = 2
indent :: Int -> String
indent n = replicate (indentSize * n) ' '
formatDesc
:: Int
-> String
-> String
formatDesc n desc =
let
chomped = reverse . dropWhile (== '\n') . reverse $ desc
multiline = '\n' `elem` chomped
paddedDesc = flip concatMap chomped $ \c ->
if c == '\n'
then c : indent n
else [c]
in
if multiline
then paddedDesc
else chomped
data Maximum a
= Maximum a
| MinusInfinity
instance Ord a => Monoid (Maximum a) where
mempty = MinusInfinity
Maximum a `mappend` Maximum b = Maximum (a `max` b)
MinusInfinity `mappend` a = a
a `mappend` MinusInfinity = a
computeAlignment :: OptionSet -> TestTree -> Int
computeAlignment opts =
fromMonoid .
foldTestTree
trivialFold
{ foldSingle = \_ name _ level -> Maximum (length name + level)
, foldGroup = \_ m -> m . (+ indentSize)
}
opts
where
fromMonoid m =
case m 0 of
MinusInfinity -> 0
Maximum x -> x
ok, fail, infoOk, infoFail :: (?colors :: Bool) => String -> IO ()
fail = output BoldIntensity Vivid Red
ok = output NormalIntensity Dull Green
infoOk = output NormalIntensity Dull White
infoFail = output NormalIntensity Dull Red
output
:: (?colors :: Bool)
=> ConsoleIntensity
-> ColorIntensity
-> Color
-> String
-> IO ()
output bold intensity color str
| ?colors =
(do
setSGR
[ SetColor Foreground intensity color
, SetConsoleIntensity bold
]
putStr str
) `finally` setSGR []
| otherwise = putStr str