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{-|
Module : VeriFuzz.Fuzz
Description : Environment to run the simulator and synthesisers in a matrix.
Copyright : (c) 2019, Yann Herklotz
License : GPL-3
Maintainer : ymherklotz [at] gmail [dot] com
Stability : experimental
Portability : POSIX
Environment to run the simulator and synthesisers in a matrix.
-}
{-# LANGUAGE ConstraintKinds #-}
{-# LANGUAGE FlexibleContexts #-}
{-# LANGUAGE TemplateHaskell #-}
module VeriFuzz.Fuzz
( Fuzz
, fuzz
, fuzzInDir
, fuzzMultiple
, runFuzz
, sampleSeed
)
where
import Control.DeepSeq (force)
import Control.Exception.Lifted (finally)
import Control.Lens hiding ((<.>))
import Control.Monad (forM, void)
import Control.Monad.IO.Class
import Control.Monad.Trans.Class (lift)
import Control.Monad.Trans.Control (MonadBaseControl)
import Control.Monad.Trans.Maybe (runMaybeT)
import Control.Monad.Trans.Reader hiding (local)
import Control.Monad.Trans.State.Strict
import Data.List (nubBy)
import Data.Maybe (isNothing)
import Data.Text (Text)
import qualified Data.Text as T
import Data.Time
import Hedgehog (Gen)
import qualified Hedgehog.Internal.Gen as Hog
import Hedgehog.Internal.Seed (Seed)
import qualified Hedgehog.Internal.Seed as Hog
import qualified Hedgehog.Internal.Tree as Hog
import Prelude hiding (FilePath)
import Shelly hiding (get)
import Shelly.Lifted (MonadSh, liftSh)
import System.FilePath.Posix (takeBaseName)
import VeriFuzz.Config
import VeriFuzz.Internal
import VeriFuzz.Reduce
import VeriFuzz.Report
import VeriFuzz.Result
import VeriFuzz.Sim.Internal
import VeriFuzz.Sim.Yosys
import VeriFuzz.Verilog.AST
import VeriFuzz.Verilog.CodeGen
data FuzzEnv = FuzzEnv { getSynthesisers :: ![SynthTool]
, getSimulators :: ![SimTool]
, yosysInstance :: {-# UNPACK #-} !Yosys
}
deriving (Eq, Show)
-- | The main type for the fuzzing, which contains an environment that can be
-- read from and the current state of all the results.
type Fuzz m = StateT FuzzReport (ReaderT FuzzEnv m)
type MonadFuzz m = (MonadBaseControl IO m, MonadIO m, MonadSh m)
runFuzz :: MonadIO m => Config -> Yosys -> (Config -> Fuzz Sh a) -> m a
runFuzz conf yos m = shelly $ runFuzz' conf yos m
runFuzz' :: Monad m => Config -> Yosys -> (Config -> Fuzz m b) -> m b
runFuzz' conf yos m = runReaderT
(evalStateT (m conf) (FuzzReport [] [] []))
(FuzzEnv
( force
$ defaultIdentitySynth
: (descriptionToSynth <$> conf ^. configSynthesisers)
)
(force $ descriptionToSim <$> conf ^. configSimulators)
yos
)
synthesisers :: Monad m => Fuzz m [SynthTool]
synthesisers = lift $ asks getSynthesisers
--simulators :: (Monad m) => Fuzz () m [SimTool]
--simulators = lift $ asks getSimulators
combinations :: [a] -> [b] -> [(a, b)]
combinations l1 l2 = [ (x, y) | x <- l1, y <- l2 ]
logT :: MonadSh m => Text -> m ()
logT = liftSh . logger
timeit :: (MonadIO m, MonadSh m) => m a -> m (NominalDiffTime, a)
timeit a = do
start <- liftIO getCurrentTime
result <- a
end <- liftIO getCurrentTime
return (diffUTCTime end start, result)
synthesis :: (MonadBaseControl IO m, MonadSh m) => SourceInfo -> Fuzz m ()
synthesis src = do
synth <- synthesisers
results <- liftSh $ mapM exec synth
synthStatus .= zipWith SynthStatus synth results
liftSh $ inspect results
where
exec a = runResultT $ do
liftSh . mkdir_p . fromText $ toText a
pop (fromText $ toText a) $ runSynth a src
generateSample
:: (MonadIO m, MonadSh m)
=> Maybe Seed
-> Gen SourceInfo
-> Fuzz m (Seed, SourceInfo)
generateSample seed gen = do
logT "Sampling Verilog from generator"
(t, v) <- timeit $ sampleSeed seed gen
logT $ "Generated Verilog (" <> showT t <> ")"
return v
passedSynthesis :: MonadSh m => Fuzz m [SynthTool]
passedSynthesis = fmap toSynth . filter passed . _synthStatus <$> get
where
passed (SynthStatus _ (Pass _)) = True
passed _ = False
toSynth (SynthStatus s _) = s
make :: MonadSh m => FilePath -> m ()
make f = liftSh $ do
mkdir_p f
cp_r "data" $ f </> fromText "data"
pop :: (MonadBaseControl IO m, MonadSh m) => FilePath -> m a -> m a
pop f a = do
dir <- liftSh pwd
finally (liftSh (cd f) >> a) . liftSh $ cd dir
applyList :: [a -> b] -> [a] -> [b]
applyList a b = apply' <$> zip a b where apply' (a', b') = a' b'
toSynthResult :: [(SynthTool, SynthTool)] -> [Result Failed ()] -> [SynthResult]
toSynthResult a b = flip applyList b $ uncurry SynthResult <$> a
equivalence :: (MonadBaseControl IO m, MonadSh m) => SourceInfo -> Fuzz m ()
equivalence src = do
synth <- passedSynthesis
-- let synthComb =
-- nubBy tupEq . filter (uncurry (/=)) $ combinations synth synth
let synthComb = nubBy tupEq . filter (uncurry (/=)) $ (,) defaultIdentitySynth <$> synth
results <- liftSh $ mapM (uncurry equiv) synthComb
synthResults .= toSynthResult synthComb results
liftSh $ inspect results
where
tupEq (a, b) (a', b') = (a == a' && b == b') || (a == b' && b == a')
equiv a b = runResultT $ do
make dir
pop dir $ do
liftSh $ do
cp (fromText ".." </> fromText (toText a) </> synthOutput a)
$ synthOutput a
cp (fromText ".." </> fromText (toText b) </> synthOutput b)
$ synthOutput b
writefile "rtl.v" $ genSource src
runEquiv a b src
where dir = fromText $ "equiv_" <> toText a <> "_" <> toText b
failEquivWithIdentity :: (MonadSh m) => Fuzz m [SynthResult]
failEquivWithIdentity = filter withIdentity . _synthResults <$> get
where
withIdentity (SynthResult (IdentitySynth _) _ (Fail EquivFail)) = True
withIdentity (SynthResult _ (IdentitySynth _) (Fail EquivFail)) = True
withIdentity _ = False
-- | Always reduces with respect to 'Identity'.
reduction :: (MonadSh m) => SourceInfo -> Fuzz m ()
reduction src = do
fails <- failEquivWithIdentity
_ <- liftSh $ mapM red fails
return ()
where
red (SynthResult a b _) = do
make dir
pop dir $ do
s <- reduceSynth a b src
writefile (fromText ".." </> dir <.> "v") $ genSource s
return s
where dir = fromText $ "reduce_" <> toText a <> "_" <> toText b
fuzz :: MonadFuzz m => Gen SourceInfo -> Config -> Fuzz m FuzzReport
fuzz gen conf = do
(seed', src) <- generateSample seed gen
liftSh
. writefile "config.toml"
. encodeConfig
$ conf
& configProperty
. propSeed
.~ Just seed'
synthesis src
equivalence src
reduction src
report <- get
currdir <- liftSh pwd
liftSh . writefile "index.html" $ printResultReport (bname currdir) report
return report
where
seed = conf ^. configProperty . propSeed
bname = T.pack . takeBaseName . T.unpack . toTextIgnore
fuzzInDir
:: MonadFuzz m => FilePath -> Gen SourceInfo -> Config -> Fuzz m FuzzReport
fuzzInDir fp src conf = do
make fp
pop fp $ fuzz src conf
fuzzMultiple
:: MonadFuzz m
=> Int
-> Maybe FilePath
-> Gen SourceInfo
-> Config
-> Fuzz m FuzzReport
fuzzMultiple n fp src conf = do
x <- case fp of
Nothing -> do
ct <- liftIO getZonedTime
return
. fromText
. T.pack
$ "output_"
<> formatTime defaultTimeLocale "%Y-%m-%d_%H-%M-%S" ct
Just f -> return f
make x
when (isNothing seed) . void . pop x . forM [1 .. n] $ fuzzDir
unless (isNothing seed) . void . pop x $ fuzzDir (1 :: Int)
return mempty
where
fuzzDir n' = fuzzInDir (fromText $ "fuzz_" <> showT n') src conf
seed = conf ^. configProperty . propSeed
sampleSeed :: MonadSh m => Maybe Seed -> Gen a -> m (Seed, a)
sampleSeed s gen =
liftSh
$ let
loop n = if n <= 0
then
error
"Hedgehog.Gen.sample: too many discards, could not generate a sample"
else do
seed <- maybe Hog.random return s
case
runIdentity
. runMaybeT
. Hog.runTree
$ Hog.runGenT 30 seed gen
of
Nothing -> loop (n - 1)
Just x -> do
liftSh . logT $ showT seed
return (seed, Hog.nodeValue x)
in loop (100 :: Int)
|