dejafu/Test/DejaFu/SCT.hs

{-# LANGUAGE Rank2Types #-}

-- | Systematic testing for concurrent computations.
module Test.DejaFu.SCT
 ( -- * Schedule Bounding
 -- | Schedule bounding is a means of cutting down the search space of
 -- schedules, by taking advantage of some intrinsic properties of
 -- schedules: such as the number of pre-emptions (pre-emption
 -- bounding), or the number of deviations from a deterministic
 -- scheduler (delay bounding); and then exploring all schedules
 -- within the bound.
   sctBounded
 , sctPreBound
 , sctDelayBound
 , sctBoundedIO
 , sctPreBoundIO
 , sctDelayBoundIO

 -- * Result Trees
 , SCTTree(..)
 , SCTTreeIO(..)
 , sequenceIOTree

 -- * Utilities
 , preEmpCount
 ) where

import Control.Applicative ((<$>), (<*>), pure)
import Control.DeepSeq (NFData(..), force)
import Data.Foldable (Foldable(foldMap))
import Data.Maybe (fromMaybe)
import Data.Traversable (Traversable(traverse), fmapDefault, foldMapDefault)
import Test.DejaFu.Deterministic
import Test.DejaFu.Deterministic.IO (ConcIO, runConcIO)

-- * Result trees

-- | Results are presented in a lazy tree, where each node contains a
-- trace and a result. The children of a node represent those
-- schedules obtainable from it on the next bounding level.
data SCTTree a = SCTTree (Either Failure a) Trace [SCTTree a]
  deriving (Eq, Show)

instance Functor SCTTree where
  fmap = fmapDefault

instance Foldable SCTTree where
  foldMap = foldMapDefault

instance Traversable SCTTree where
  traverse f (SCTTree (Left  x) t trees) = SCTTree (Left x) <$> pure t <*> traverse (traverse f) trees
  traverse f (SCTTree (Right x) t trees) = SCTTree . Right  <$> f x <*> pure t <*> traverse (traverse f) trees

instance NFData a => NFData (SCTTree a) where
  rnf (SCTTree a t trees) = rnf (a, t, trees)

-- | Results which need IO to compute. Laziness is preserved by
-- wrapping child nodes in an 'IO' list.
data SCTTreeIO a = SCTTreeIO (Either Failure a) Trace (IO [SCTTreeIO a])

instance Functor SCTTreeIO where
  fmap f (SCTTreeIO a t iotrees) = SCTTreeIO (fmap f a) t $ fmap (map $ fmap f) iotrees

-- | Perform all of the 'IO' in an 'SCTTreeIO' from left to right. As
-- '>>=' for IO is strict, this will evaluate the entire tree, which
-- may be a lot of work. To counter this, a depth limit can optionally
-- be provided, where children below level @0@ will not be present in
-- the output.
sequenceIOTree :: Maybe Int -> SCTTreeIO a -> IO (SCTTree a)
sequenceIOTree (Just n) (SCTTreeIO a t iotrees)
  | n <= 0 = return $ SCTTree a t []
  | otherwise = do
    trees <- iotrees
    SCTTree a t <$> mapM (sequenceIOTree . Just $ n-1) trees
sequenceIOTree Nothing (SCTTreeIO a t iotrees) = do
  trees <- iotrees
  SCTTree a t <$> mapM (sequenceIOTree Nothing) trees

-- * Pre-emption bounding

-- | An SCT runner using a pre-emption bounding scheduler.
sctPreBound :: (forall t. Conc t a) -> [SCTTree a]
sctPreBound = sctBounded pbSiblings (pbOffspring False)

-- | Variant of 'sctPreBound' for computations which do 'IO'.
sctPreBoundIO :: (forall t. ConcIO t a) -> IO [SCTTreeIO a]
sctPreBoundIO = sctBoundedIO pbSiblings (pbOffspring True)

-- | Return all modifications to this schedule which do not introduce
-- extra pre-emptions.
pbSiblings :: Trace -> [[Decision]]
pbSiblings = siblings . map (\(d,a,_) -> (d,map fst a)) where
  siblings ((Start    i, alts):ds) = [[a] | a@(Start    _) <- alts] ++ [Start    i : o | o <- siblings ds, not $ null o]
  siblings ((SwitchTo i, alts):ds) = [[a] | a@(SwitchTo _) <- alts] ++ [SwitchTo i : o | o <- siblings ds, not $ null o]
  siblings ((d, _):ds) = [d : o | o <- siblings ds, not $ null o]
  siblings [] = []

-- | Return all modifications to this schedule which do introduce an
-- extra pre-emption. Only introduce pre-emptions around CVar actions
-- and lifts.
pbOffspring :: Bool -> Trace -> [[Decision]]
pbOffspring lifts ((Continue, alts, ta):ds)
  | interesting lifts ta = [[n] | (n@(SwitchTo _), _) <- alts] ++ [Continue : n | n <- pbOffspring lifts ds, not $ null n]
  | otherwise = [Continue : n | n <- pbOffspring lifts ds, not $ null n]

pbOffspring lifts ((d, _, _):ds) = [d : n | n <- pbOffspring lifts ds, not $ null n]
pbOffspring _ [] = []

-- | Check the pre-emption count of some scheduling decisions.
preEmpCount :: [Decision] -> Int
preEmpCount (SwitchTo _:ss) = 1 + preEmpCount ss
preEmpCount (_:ss) = preEmpCount ss
preEmpCount [] = 0

-- * Delay bounding

-- | An SCT runner using a delay-bounding scheduler.
sctDelayBound :: (forall t. Conc t a) -> [SCTTree a]
sctDelayBound = sctBounded (const []) (dbOffspring False)

-- | Variant of 'sctDelayBound' for computations which do 'IO'.
sctDelayBoundIO :: (forall t. ConcIO t a) -> IO [SCTTreeIO a]
sctDelayBoundIO = sctBoundedIO (const []) (dbOffspring True)

-- | Return all modifications to the schedule which introduce an extra
-- delay. Only introduce delays around CVar actions and lifts.
dbOffspring :: Bool -> Trace -> [[Decision]]
dbOffspring lifts ((d, alts, ta):ds)
  | interesting lifts ta = [[fst n] | n <- alts] ++ [d : n | n <- dbOffspring lifts ds, not $ null n]
  | otherwise = [d : n | n <- dbOffspring lifts ds, not $ null n]

dbOffspring _ [] = []

-- * SCT runners

-- | SCT via schedule bounding. Results are proeduced as a lazy
-- forest, where each level represents one bounding level.
--
-- Schedules are generated by running the computation with a
-- deterministic scheduler with some initial list of decisions, after
-- which non-pre-emptive decisions are made. The generated suffix is
-- then used to generate \"siblings\" (schedule fragments which, when
-- appended to the prefix, form the prefix of a new schedule which
-- does not increase the bound), and \"offspring\" (like siblings, but
-- the bound has been increased by one). It is important that siblings
-- and offspring are unique, and that the same
-- prefix+sibling/offspring cannot arise from two distinct traces, as
-- otherwise the runner may loop.
--
-- For example, the siblings in the pre-emption bounding runner are
-- those schedule fragments which, when appended to the prefix, form
-- the prefix of a new schedule which does not introduce any new
-- pre-emptions; and the offspring do introduce one new pre-emption.
sctBounded :: (Trace -> [[Decision]])
           -- ^ Sibling generation function.
           -> (Trace -> [[Decision]])
           -- ^ Child generation function.
           -> (forall t. Conc t a) -> [SCTTree a]
sctBounded siblings offspring c = go [] where
  go ds = case res of
    Left  f -> SCTTree (Left  f) trace [] : concatMap go sibs
    Right a -> SCTTree (Right a) trace (concatMap go offs) : concatMap go sibs

    where
      (res, _, trace) = runConc prefixSched ds c

      (pref, suff) = let (p, s) = splitAt (length ds) trace in (map (\(a,_,_) -> a) p, s)

      sibs = [ pref ++ y | y <- siblings  suff]
      offs = [ pref ++ y | y <- offspring suff]

-- | Variant of 'sctBounded' for computations which do 'IO'.
sctBoundedIO :: (Trace -> [[Decision]])
             -> (Trace -> [[Decision]])
             -> (forall t. ConcIO t a) -> IO [SCTTreeIO a]
sctBoundedIO siblings offspring c = go [] where
  go ds = do
    (res, _, trace) <- runConcIO prefixSched ds c

    let (pref, suff) = let (p, s) = splitAt (length ds + 1) trace in (map (\(a,_,_) -> a) p, s)

    let sibs = [ pref ++ y | y <- siblings  suff]
    let offs = [ pref ++ y | y <- offspring suff]

    sibs' <- concat <$> mapM go sibs

    return $ case res of
      Left  f -> SCTTreeIO (Left f)  trace (return []) : sibs'
      Right a -> SCTTreeIO (Right a) trace (concat <$> mapM go offs) : sibs'

-- * Prefix scheduler

-- | Scheduler which uses a list of scheduling decisions to drive the
-- initial decisions.
prefixSched :: Scheduler [Decision]
prefixSched = force $ \s prior threads@(next:|_) -> case s of
  -- If we have a decision queued, make it.
  (Start t:ds)    -> (t, ds)
  (Continue:ds)   -> (fromMaybe 0 prior, ds)
  (SwitchTo t:ds) -> (t, ds)

  -- Otherwise just use a non-pre-emptive scheduler.
  [] -> case prior of
    Just prior' | prior' `elem` toList threads -> (prior', [])
    _ -> (next, [])

-- * Utils

-- | Check if a 'ThreadAction' might be an interesting candidate for
-- pre-empting or delaying.
interesting :: Bool -> ThreadAction -> Bool
interesting _ (Put _ _)       = True
interesting _ (TryPut _ _ _)  = True
interesting _ (Take _ _)      = True
interesting _ (TryTake _ _ _) = True
interesting _ (BlockedPut _)  = True
interesting _ (Read _)        = True
interesting _ (BlockedRead _) = True
interesting _ (BlockedTake _) = True
interesting _ (ReadRef _)     = True
interesting _ (ModRef _)      = True
interesting _ (STM _)         = True
interesting _ BlockedSTM      = True
interesting _ (ThrowTo _)     = True
interesting _ (SetMasking _ _) = True
interesting _ (ResetMasking _ _ ) = True
interesting l Lift = l
interesting _ _ = False
Use schedule bounding as the primary SCT approach. This allows results to be naturally reported as lazy trees, rather than as lists representing a tree traversal. This in turn means that the actual bound can be moved outwards to the testing code, and not used at all in the runner. Trees let us do nice things with shrinking and short-circuiting, if we make the (fairly reasonable) assumption that the children of a buggy result will exhibit the same bug. Storing results as trees does complicate the predicate helper functions somewhat, but I think the clarity gained in the actual SCT code is well worth it. 2015-06-19 18:50:51 +03:00			`{-# LANGUAGE Rank2Types #-}`

Refactor code and update docs to make more not-me friendly 2015-02-01 04:21:42 +03:00			`-- \| Systematic testing for concurrent computations.`
Rename and remodularise 2015-01-31 18:50:54 +03:00			`module Test.DejaFu.SCT`
Use schedule bounding as the primary SCT approach. This allows results to be naturally reported as lazy trees, rather than as lists representing a tree traversal. This in turn means that the actual bound can be moved outwards to the testing code, and not used at all in the runner. Trees let us do nice things with shrinking and short-circuiting, if we make the (fairly reasonable) assumption that the children of a buggy result will exhibit the same bug. Storing results as trees does complicate the predicate helper functions somewhat, but I think the clarity gained in the actual SCT code is well worth it. 2015-06-19 18:50:51 +03:00			`( -- * Schedule Bounding`
Implement delay bounding 2015-01-26 18:34:40 +03:00			`-- \| Schedule bounding is a means of cutting down the search space of`
			`-- schedules, by taking advantage of some intrinsic properties of`
			`-- schedules: such as the number of pre-emptions (pre-emption`
			`-- bounding), or the number of deviations from a deterministic`
			`-- scheduler (delay bounding); and then exploring all schedules`
			`-- within the bound.`
Use schedule bounding as the primary SCT approach. This allows results to be naturally reported as lazy trees, rather than as lists representing a tree traversal. This in turn means that the actual bound can be moved outwards to the testing code, and not used at all in the runner. Trees let us do nice things with shrinking and short-circuiting, if we make the (fairly reasonable) assumption that the children of a buggy result will exhibit the same bug. Storing results as trees does complicate the predicate helper functions somewhat, but I think the clarity gained in the actual SCT code is well worth it. 2015-06-19 18:50:51 +03:00			`sctBounded`
Add a pre-emption bounding runner, and use it for tests 2015-01-05 00:48:00 +03:00			`, sctPreBound`
Implement delay bounding 2015-01-26 18:34:40 +03:00			`, sctDelayBound`
Refactor code and update docs to make more not-me friendly 2015-02-01 04:21:42 +03:00			`, sctBoundedIO`
			`, sctPreBoundIO`
Implement delay bounding 2015-01-26 18:34:40 +03:00			`, sctDelayBoundIO`
Add a pre-emption bounding runner, and use it for tests 2015-01-05 00:48:00 +03:00
Use schedule bounding as the primary SCT approach. This allows results to be naturally reported as lazy trees, rather than as lists representing a tree traversal. This in turn means that the actual bound can be moved outwards to the testing code, and not used at all in the runner. Trees let us do nice things with shrinking and short-circuiting, if we make the (fairly reasonable) assumption that the children of a buggy result will exhibit the same bug. Storing results as trees does complicate the predicate helper functions somewhat, but I think the clarity gained in the actual SCT code is well worth it. 2015-06-19 18:50:51 +03:00			`-- * Result Trees`
			`, SCTTree(..)`
			`, SCTTreeIO(..)`
			`, sequenceIOTree`

Provide a helper function to turn Schedulers into SCTSchedulers 2014-12-21 16:50:52 +03:00			`-- * Utilities`
Implement delay bounding 2015-01-26 18:34:40 +03:00			`, preEmpCount`
Add a simple runner which gathers results and schedulings from multiple runs 2014-12-20 14:01:51 +03:00			`) where`

Use schedule bounding as the primary SCT approach. This allows results to be naturally reported as lazy trees, rather than as lists representing a tree traversal. This in turn means that the actual bound can be moved outwards to the testing code, and not used at all in the runner. Trees let us do nice things with shrinking and short-circuiting, if we make the (fairly reasonable) assumption that the children of a buggy result will exhibit the same bug. Storing results as trees does complicate the predicate helper functions somewhat, but I think the clarity gained in the actual SCT code is well worth it. 2015-06-19 18:50:51 +03:00			`import Control.Applicative ((<$>), (<*>), pure)`
			`import Control.DeepSeq (NFData(..), force)`
			`import Data.Foldable (Foldable(foldMap))`
			`import Data.Maybe (fromMaybe)`
			`import Data.Traversable (Traversable(traverse), fmapDefault, foldMapDefault)`
			`import Test.DejaFu.Deterministic`
			`import Test.DejaFu.Deterministic.IO (ConcIO, runConcIO)`

			`-- * Result trees`

			`-- \| Results are presented in a lazy tree, where each node contains a`
			`-- trace and a result. The children of a node represent those`
			`-- schedules obtainable from it on the next bounding level.`
			`data SCTTree a = SCTTree (Either Failure a) Trace [SCTTree a]`
Add a Show instance for SCTTrees 2015-07-08 20:17:48 +03:00			`deriving (Eq, Show)`
Use schedule bounding as the primary SCT approach. This allows results to be naturally reported as lazy trees, rather than as lists representing a tree traversal. This in turn means that the actual bound can be moved outwards to the testing code, and not used at all in the runner. Trees let us do nice things with shrinking and short-circuiting, if we make the (fairly reasonable) assumption that the children of a buggy result will exhibit the same bug. Storing results as trees does complicate the predicate helper functions somewhat, but I think the clarity gained in the actual SCT code is well worth it. 2015-06-19 18:50:51 +03:00
			`instance Functor SCTTree where`
			`fmap = fmapDefault`

			`instance Foldable SCTTree where`
			`foldMap = foldMapDefault`

			`instance Traversable SCTTree where`
			`traverse f (SCTTree (Left x) t trees) = SCTTree (Left x) <$> pure t <*> traverse (traverse f) trees`
			`traverse f (SCTTree (Right x) t trees) = SCTTree . Right <$> f x <> pure t <> traverse (traverse f) trees`

			`instance NFData a => NFData (SCTTree a) where`
			`rnf (SCTTree a t trees) = rnf (a, t, trees)`

			`-- \| Results which need IO to compute. Laziness is preserved by`
			`-- wrapping child nodes in an 'IO' list.`
			`data SCTTreeIO a = SCTTreeIO (Either Failure a) Trace (IO [SCTTreeIO a])`

			`instance Functor SCTTreeIO where`
			`fmap f (SCTTreeIO a t iotrees) = SCTTreeIO (fmap f a) t $ fmap (map $ fmap f) iotrees`

			`-- \| Perform all of the 'IO' in an 'SCTTreeIO' from left to right. As`
			`-- '>>=' for IO is strict, this will evaluate the entire tree, which`
			`-- may be a lot of work. To counter this, a depth limit can optionally`
			`-- be provided, where children below level @0@ will not be present in`
			`-- the output.`
			`sequenceIOTree :: Maybe Int -> SCTTreeIO a -> IO (SCTTree a)`
			`sequenceIOTree (Just n) (SCTTreeIO a t iotrees)`
			`\| n <= 0 = return $ SCTTree a t []`
			`\| otherwise = do`
			`trees <- iotrees`
			`SCTTree a t <$> mapM (sequenceIOTree . Just $ n-1) trees`
			`sequenceIOTree Nothing (SCTTreeIO a t iotrees) = do`
			`trees <- iotrees`
			`SCTTree a t <$> mapM (sequenceIOTree Nothing) trees`

			`-- * Pre-emption bounding`

			`-- \| An SCT runner using a pre-emption bounding scheduler.`
			`sctPreBound :: (forall t. Conc t a) -> [SCTTree a]`
			`sctPreBound = sctBounded pbSiblings (pbOffspring False)`

			`-- \| Variant of 'sctPreBound' for computations which do 'IO'.`
			`sctPreBoundIO :: (forall t. ConcIO t a) -> IO [SCTTreeIO a]`
			`sctPreBoundIO = sctBoundedIO pbSiblings (pbOffspring True)`

			`-- \| Return all modifications to this schedule which do not introduce`
			`-- extra pre-emptions.`
			`pbSiblings :: Trace -> [[Decision]]`
Include one-step lookahead in traces 2015-07-08 20:55:30 +03:00			`pbSiblings = siblings . map (\(d,a,_) -> (d,map fst a)) where`
Use schedule bounding as the primary SCT approach. This allows results to be naturally reported as lazy trees, rather than as lists representing a tree traversal. This in turn means that the actual bound can be moved outwards to the testing code, and not used at all in the runner. Trees let us do nice things with shrinking and short-circuiting, if we make the (fairly reasonable) assumption that the children of a buggy result will exhibit the same bug. Storing results as trees does complicate the predicate helper functions somewhat, but I think the clarity gained in the actual SCT code is well worth it. 2015-06-19 18:50:51 +03:00			`siblings ((Start i, alts):ds) = [[a] \| a@(Start _) <- alts] ++ [Start i : o \| o <- siblings ds, not $ null o]`
			`siblings ((SwitchTo i, alts):ds) = [[a] \| a@(SwitchTo _) <- alts] ++ [SwitchTo i : o \| o <- siblings ds, not $ null o]`
			`siblings ((d, _):ds) = [d : o \| o <- siblings ds, not $ null o]`
			`siblings [] = []`

			`-- \| Return all modifications to this schedule which do introduce an`
			`-- extra pre-emption. Only introduce pre-emptions around CVar actions`
			`-- and lifts.`
			`pbOffspring :: Bool -> Trace -> [[Decision]]`
			`pbOffspring lifts ((Continue, alts, ta):ds)`
Include one-step lookahead in traces 2015-07-08 20:55:30 +03:00			`\| interesting lifts ta = [[n] \| (n@(SwitchTo _), _) <- alts] ++ [Continue : n \| n <- pbOffspring lifts ds, not $ null n]`
Use schedule bounding as the primary SCT approach. This allows results to be naturally reported as lazy trees, rather than as lists representing a tree traversal. This in turn means that the actual bound can be moved outwards to the testing code, and not used at all in the runner. Trees let us do nice things with shrinking and short-circuiting, if we make the (fairly reasonable) assumption that the children of a buggy result will exhibit the same bug. Storing results as trees does complicate the predicate helper functions somewhat, but I think the clarity gained in the actual SCT code is well worth it. 2015-06-19 18:50:51 +03:00			`\| otherwise = [Continue : n \| n <- pbOffspring lifts ds, not $ null n]`

			`pbOffspring lifts ((d, _, _):ds) = [d : n \| n <- pbOffspring lifts ds, not $ null n]`
			`pbOffspring _ [] = []`

			`-- \| Check the pre-emption count of some scheduling decisions.`
			`preEmpCount :: [Decision] -> Int`
			`preEmpCount (SwitchTo _:ss) = 1 + preEmpCount ss`
			`preEmpCount (_:ss) = preEmpCount ss`
			`preEmpCount [] = 0`

			`-- * Delay bounding`

			`-- \| An SCT runner using a delay-bounding scheduler.`
			`sctDelayBound :: (forall t. Conc t a) -> [SCTTree a]`
			`sctDelayBound = sctBounded (const []) (dbOffspring False)`

			`-- \| Variant of 'sctDelayBound' for computations which do 'IO'.`
			`sctDelayBoundIO :: (forall t. ConcIO t a) -> IO [SCTTreeIO a]`
			`sctDelayBoundIO = sctBoundedIO (const []) (dbOffspring True)`

			`-- \| Return all modifications to the schedule which introduce an extra`
			`-- delay. Only introduce delays around CVar actions and lifts.`
			`dbOffspring :: Bool -> Trace -> [[Decision]]`
			`dbOffspring lifts ((d, alts, ta):ds)`
Include one-step lookahead in traces 2015-07-08 20:55:30 +03:00			`\| interesting lifts ta = [[fst n] \| n <- alts] ++ [d : n \| n <- dbOffspring lifts ds, not $ null n]`
Use schedule bounding as the primary SCT approach. This allows results to be naturally reported as lazy trees, rather than as lists representing a tree traversal. This in turn means that the actual bound can be moved outwards to the testing code, and not used at all in the runner. Trees let us do nice things with shrinking and short-circuiting, if we make the (fairly reasonable) assumption that the children of a buggy result will exhibit the same bug. Storing results as trees does complicate the predicate helper functions somewhat, but I think the clarity gained in the actual SCT code is well worth it. 2015-06-19 18:50:51 +03:00			`\| otherwise = [d : n \| n <- dbOffspring lifts ds, not $ null n]`

			`dbOffspring _ [] = []`

			`-- * SCT runners`

			`-- \| SCT via schedule bounding. Results are proeduced as a lazy`
			`-- forest, where each level represents one bounding level.`
			`--`
			`-- Schedules are generated by running the computation with a`
			`-- deterministic scheduler with some initial list of decisions, after`
			`-- which non-pre-emptive decisions are made. The generated suffix is`
			`-- then used to generate \"siblings\" (schedule fragments which, when`
			`-- appended to the prefix, form the prefix of a new schedule which`
			`-- does not increase the bound), and \"offspring\" (like siblings, but`
			`-- the bound has been increased by one). It is important that siblings`
			`-- and offspring are unique, and that the same`
			`-- prefix+sibling/offspring cannot arise from two distinct traces, as`
			`-- otherwise the runner may loop.`
			`--`
			`-- For example, the siblings in the pre-emption bounding runner are`
			`-- those schedule fragments which, when appended to the prefix, form`
			`-- the prefix of a new schedule which does not introduce any new`
			`-- pre-emptions; and the offspring do introduce one new pre-emption.`
			`sctBounded :: (Trace -> [[Decision]])`
			`-- ^ Sibling generation function.`
			`-> (Trace -> [[Decision]])`
			`-- ^ Child generation function.`
			`-> (forall t. Conc t a) -> [SCTTree a]`
			`sctBounded siblings offspring c = go [] where`
			`go ds = case res of`
			`Left f -> SCTTree (Left f) trace [] : concatMap go sibs`
			`Right a -> SCTTree (Right a) trace (concatMap go offs) : concatMap go sibs`

			`where`
			`(res, _, trace) = runConc prefixSched ds c`

			`(pref, suff) = let (p, s) = splitAt (length ds) trace in (map (\(a,_,_) -> a) p, s)`

			`sibs = [ pref ++ y \| y <- siblings suff]`
			`offs = [ pref ++ y \| y <- offspring suff]`

			`-- \| Variant of 'sctBounded' for computations which do 'IO'.`
			`sctBoundedIO :: (Trace -> [[Decision]])`
			`-> (Trace -> [[Decision]])`
			`-> (forall t. ConcIO t a) -> IO [SCTTreeIO a]`
			`sctBoundedIO siblings offspring c = go [] where`
			`go ds = do`
			`(res, _, trace) <- runConcIO prefixSched ds c`

			`let (pref, suff) = let (p, s) = splitAt (length ds + 1) trace in (map (\(a,_,_) -> a) p, s)`

			`let sibs = [ pref ++ y \| y <- siblings suff]`
			`let offs = [ pref ++ y \| y <- offspring suff]`

			`sibs' <- concat <$> mapM go sibs`

			`return $ case res of`
			`Left f -> SCTTreeIO (Left f) trace (return []) : sibs'`
			`Right a -> SCTTreeIO (Right a) trace (concat <$> mapM go offs) : sibs'`

			`-- * Prefix scheduler`

			`-- \| Scheduler which uses a list of scheduling decisions to drive the`
			`-- initial decisions.`
			`prefixSched :: Scheduler [Decision]`
			`prefixSched = force $ \s prior threads@(next:\|_) -> case s of`
			`-- If we have a decision queued, make it.`
			`(Start t:ds) -> (t, ds)`
			`(Continue:ds) -> (fromMaybe 0 prior, ds)`
			`(SwitchTo t:ds) -> (t, ds)`

			`-- Otherwise just use a non-pre-emptive scheduler.`
			`[] -> case prior of`
			Just prior' \| prior' `elem` toList threads -> (prior', [])
			`_ -> (next, [])`

			`-- * Utils`

			`-- \| Check if a 'ThreadAction' might be an interesting candidate for`
			`-- pre-empting or delaying.`
			`interesting :: Bool -> ThreadAction -> Bool`
			`interesting _ (Put _ _) = True`
			`interesting _ (TryPut _ _ _) = True`
			`interesting _ (Take _ _) = True`
			`interesting _ (TryTake _ _ _) = True`
			`interesting _ (BlockedPut _) = True`
			`interesting _ (Read _) = True`
			`interesting _ (BlockedRead _) = True`
			`interesting _ (BlockedTake _) = True`
			`interesting _ (ReadRef _) = True`
			`interesting _ (ModRef _) = True`
			`interesting _ (STM _) = True`
			`interesting _ BlockedSTM = True`
			`interesting _ (ThrowTo _) = True`
			`interesting _ (SetMasking _ _) = True`
			`interesting _ (ResetMasking _ _ ) = True`
			`interesting l Lift = l`
			`interesting _ _ = False`