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module Analysis.Termination
( terminationAnalysis, showTermination
, productivityAnalysis, showProductivity, Productivity(..)
) where
import Analysis.Types
import Analysis.ProgInfo
import Analysis.RootReplaced (rootCyclicAnalysis)
import Char(isDigit)
import FlatCurry.Types
import FlatCurry.Goodies
import List
import SCC(scc)
import Sort(sort)
terminationAnalysis :: Analysis Bool
terminationAnalysis = dependencyFuncAnalysis "Terminating" False isTerminating
showTermination :: AOutFormat -> Bool -> String
showTermination AText True = "terminating"
showTermination ANote True = ""
showTermination AText False = "possibly non-terminating"
showTermination ANote False = "maybe not term."
isTerminating :: FuncDecl -> [(QName,Bool)] -> Bool
isTerminating (Func qfunc _ _ _ rule) calledFuncs = hasTermRule rule
where
hasTermRule (Rule args e) = hasTermExp (map (\a -> (a,[])) args) e
hasTermRule (External _) = True
hasTermExp _ (Var _) = True
hasTermExp _ (Lit _) = True
hasTermExp _ (Free _ _) = False
hasTermExp args (Let bs e) =
let sccs = scc ((:[]) . fst) (allVars . snd) bs
in if any (\scc -> any (`elem` concatMap allVars (map snd scc))
(map fst scc))
sccs
then False
else all (hasTermExp args) (e : map snd bs)
hasTermExp args (Or e1 e2) =
hasTermExp args e1 && hasTermExp args e2
hasTermExp args (Case _ e bs) =
hasTermExp args e &&
all (\ (Branch pt be) -> hasTermExp (addSmallerArgs args e pt) be) bs
hasTermExp args (Typed e _) = hasTermExp args e
hasTermExp args (Comb ct qf es) =
case ct of
ConsCall -> all (hasTermExp args) es
ConsPartCall _ -> all (hasTermExp args) es
_ -> (if qf == qfunc
then any isSmallerArg (zip args es)
else maybe False id (lookup qf calledFuncs)) &&
all (hasTermExp args) es
isSmallerArg ((_,sargs),exp) = case exp of
Var v -> v `elem` sargs
_ -> False
addSmallerArgs :: [(Int, [Int])] -> Expr -> Pattern -> [(Int, [Int])]
addSmallerArgs args de pat =
case de of
Var v -> maybe args
(\argpos -> let (av,vs) = args!!argpos
in replace (av, varsOf pat ++ vs) argpos args)
(findIndex (isInArg v) args)
_ -> args
where
varsOf (LPattern _) = []
varsOf (Pattern _ pargs) = pargs
isInArg v (argv,svs) = v==argv || v `elem` svs
data Productivity =
NoInfo
| Terminating
| DCalls [QName]
| Looping
productivityAnalysis :: Analysis Productivity
productivityAnalysis =
combinedDependencyFuncAnalysis "Productive"
terminationAnalysis
NoInfo
isProductive
showProductivity :: AOutFormat -> Productivity -> String
showProductivity _ NoInfo = "no info"
showProductivity _ Terminating = "terminating"
showProductivity _ (DCalls qfs) =
"productive / calls: " ++ "[" ++ intercalate ", " (map snd qfs) ++ "]"
showProductivity _ Looping = "possibly looping"
lubProd :: Productivity -> Productivity -> Productivity
lubProd Looping _ = Looping
lubProd (DCalls _ ) Looping = Looping
lubProd (DCalls xs) (DCalls ys) = DCalls (sort (union xs ys))
lubProd (DCalls xs) Terminating = DCalls xs
lubProd (DCalls xs) NoInfo = DCalls xs
lubProd Terminating p = if p==NoInfo then Terminating else p
lubProd NoInfo p = p
isProductive :: ProgInfo Bool -> FuncDecl -> [(QName,Productivity)]
-> Productivity
isProductive terminfo (Func qf _ _ _ rule) calledFuncs = hasProdRule rule
where
hasProdRule (External _) = Terminating
hasProdRule (Rule _ e) =
case hasProdExp False e of
DCalls fs -> if qf `elem` fs then Looping else DCalls fs
prodinfo -> prodinfo
hasProdExp _ (Var _) = Terminating
hasProdExp _ (Lit _) = Terminating
hasProdExp bc (Free _ e) =
lubProd (DCalls []) (hasProdExp bc e)
hasProdExp bc (Let bs e) =
let sccs = scc ((:[]) . fst) (allVars . snd) bs
in if any (\scc -> any (`elem` concatMap allVars (map snd scc))
(map fst scc))
sccs
then Looping
else foldr lubProd (hasProdExp bc e)
(map (\ (_,be) -> hasProdExp bc be) bs)
hasProdExp bc (Or e1 e2) = lubProd (hasProdExp bc e1) (hasProdExp bc e2)
hasProdExp bc (Case _ e bs) =
foldr lubProd (hasProdExp bc e)
(map (\ (Branch _ be) -> hasProdExp bc be) bs)
hasProdExp bc (Typed e _) = hasProdExp bc e
hasProdExp bc (Comb ct qg es) = case ct of
ConsCall -> cprodargs
ConsPartCall _ -> cprodargs
FuncCall -> if qg == ("Prelude","?")
then fprodargs
else funCallInfo
FuncPartCall _ -> funCallInfo
where
cprodargs = foldr lubProd NoInfo (map (hasProdExp True) es)
fprodargs = foldr lubProd NoInfo (map (hasProdExp bc ) es)
funCallInfo =
let prodinfo = if fprodargs <= Terminating
then if maybe False id (lookupProgInfo qg terminfo)
then Terminating
else lubProd (DCalls [qg])
(maybe Looping id (lookup qg calledFuncs))
else Looping
in if not bc then prodinfo
else case prodinfo of
DCalls _ -> DCalls []
_ -> prodinfo
|