hermit-0.3.2.0: src/HERMIT/Dictionary/Local/Case.hs
{-# LANGUAGE CPP, MultiWayIf, LambdaCase, ScopedTypeVariables, FlexibleContexts, TupleSections #-}
module HERMIT.Dictionary.Local.Case
( -- * Rewrites on Case Expressions
externals
, caseFloatAppR
, caseFloatArgR
, caseFloatCaseR
, caseFloatCastR
, caseFloatLetR
, caseFloatR
, caseFloatInR
, caseFloatInAppR
, caseFloatInArgsR
, caseReduceR
, caseReduceDataconR
, caseReduceLiteralR
, caseReduceIdR
, caseSplitR
, caseSplitInlineR
, caseInlineScrutineeR
, caseInlineAlternativeR
, caseMergeAltsR
, caseMergeAltsWithWildR
, caseElimR
, caseElimInlineScrutineeR
, caseElimMergeAltsR
, caseIntroSeqR
, caseElimSeqR
)
where
import Data.List
import Data.Monoid
import Control.Arrow
import Control.Applicative
import HERMIT.Core
import HERMIT.Context
import HERMIT.Monad
import HERMIT.Kure
import HERMIT.GHC
import HERMIT.External
import HERMIT.Utilities
import HERMIT.ParserCore
import HERMIT.Dictionary.Common
import HERMIT.Dictionary.Inline hiding (externals)
import HERMIT.Dictionary.AlphaConversion hiding (externals)
import HERMIT.Dictionary.Fold (foldVarR)
import HERMIT.Dictionary.Undefined (verifyStrictT)
import qualified Language.Haskell.TH as TH
-- NOTE: these are hard to test in small examples, as GHC does them for us, so use with caution
------------------------------------------------------------------------------
-- | Externals relating to Case expressions.
externals :: [External]
externals =
[ external "case-float-app" (promoteExprR caseFloatAppR :: RewriteH Core)
[ "(case ec of alt -> e) v ==> case ec of alt -> e v" ] .+ Commute .+ Shallow
, external "case-float-arg" ((\ f strict -> promoteExprR (caseFloatArg (Just (f, Just strict)))) :: CoreString -> RewriteH Core -> RewriteH Core)
[ "For a specific f, given a proof that f is strict, then"
, "f (case s of alt -> e) ==> case s of alt -> f e" ] .+ Commute .+ Shallow
, external "case-float-arg-unsafe" ((\ f -> promoteExprR (caseFloatArg (Just (f, Nothing)))) :: CoreString -> RewriteH Core)
[ "For a specific f,"
, "f (case s of alt -> e) ==> case s of alt -> f e" ] .+ Commute .+ Shallow .+ PreCondition
, external "case-float-arg-unsafe" (promoteExprR (caseFloatArg Nothing) :: RewriteH Core)
[ "f (case s of alt -> e) ==> case s of alt -> f e" ] .+ Commute .+ Shallow .+ PreCondition
, external "case-float-case" (promoteExprR caseFloatCaseR :: RewriteH Core)
[ "case (case ec of alt1 -> e1) of alta -> ea ==> case ec of alt1 -> case e1 of alta -> ea" ] .+ Commute .+ Eval
, external "case-float-cast" (promoteExprR caseFloatCastR :: RewriteH Core)
[ "cast (case s of p -> e) co ==> case s of p -> cast e co" ] .+ Shallow .+ Commute
, external "case-float-let" (promoteExprR caseFloatLetR :: RewriteH Core)
[ "let v = case ec of alt1 -> e1 in e ==> case ec of alt1 -> let v = e1 in e" ] .+ Commute .+ Shallow
, external "case-float" (promoteExprR caseFloatR :: RewriteH Core)
[ "case-float = case-float-app <+ case-float-case <+ case-float-let <+ case-float-cast" ] .+ Commute .+ Shallow
, external "case-float-in" (promoteExprR caseFloatInR :: RewriteH Core)
[ "Float in a Case whatever the context." ] .+ Commute .+ Shallow .+ PreCondition
, external "case-float-in-args" (promoteExprR caseFloatInArgsR :: RewriteH Core)
[ "Float in a Case whose alternatives are parallel applications of the same function." ] .+ Commute .+ Shallow .+ PreCondition
-- , external "case-float-in-app" (promoteExprR caseFloatInApp :: RewriteH Core)
-- [ "Float in a Case whose alternatives are applications of different functions with the same arguments." ] .+ Commute .+ Shallow .+ PreCondition
, external "case-reduce" (promoteExprR caseReduceR :: RewriteH Core)
[ "Case of Known Constructor"
, "case-reduce-datacon <+ case-reduce-literal" ] .+ Shallow .+ Eval
, external "case-reduce-datacon" (promoteExprR caseReduceDataconR :: RewriteH Core)
[ "Case of Known Constructor"
, "case C v1..vn of C w1..wn -> e ==> let { w1 = v1 ; .. ; wn = vn } in e" ] .+ Shallow .+ Eval
, external "case-reduce-literal" (promoteExprR caseReduceLiteralR :: RewriteH Core)
[ "Case of Known Constructor"
, "case L of L -> e ==> e" ] .+ Shallow .+ Eval
, external "case-reduce-id" (promoteExprR caseReduceIdR :: RewriteH Core)
[ "Inline the case scrutinee (if it is an identifier) and then case-reduce." ] .+ Shallow .+ Eval .+ Context
, external "case-split" (promoteExprR . caseSplitR :: TH.Name -> RewriteH Core)
[ "case-split 'x"
, "e ==> case x of C1 vs -> e; C2 vs -> e, where x is free in e" ] .+ Shallow
, external "case-split-inline" (caseSplitInlineR :: TH.Name -> RewriteH Core)
[ "Like case-split, but additionally inlines the matched constructor "
, "applications for all occurances of the named variable." ] .+ Deep
, external "case-intro-seq" (promoteExprR . caseIntroSeqR :: TH.Name -> RewriteH Core)
[ "Force evaluation of a variable by introducing a case."
, "case-seq 'v is is equivalent to adding @(seq v)@ in the source code." ] .+ Shallow .+ Introduce
, external "case-elim-seq" (promoteExprR caseElimSeqR :: RewriteH Core)
[ "Eliminate a case that corresponds to a pointless seq." ] .+ Deep .+ Eval
, external "case-inline-alternative" (promoteExprR caseInlineAlternativeR :: RewriteH Core)
[ "Inline the case wildcard binder as the case-alternative pattern everywhere in the case alternatives." ] .+ Deep
, external "case-inline-scrutinee" (promoteExprR caseInlineScrutineeR :: RewriteH Core)
[ "Inline the case wildcard binder as the case scrutinee everywhere in the case alternatives." ] .+ Deep
, external "case-merge-alts" (promoteExprR caseMergeAltsR :: RewriteH Core)
[ "Merge all case alternatives into a single default case."
, "The RHS of each alternative must be the same."
, "case s of {pat1 -> e ; pat2 -> e ; ... ; patn -> e} ==> case s of {_ -> e}" ]
, external "case-merge-alts-with-wild" (promoteExprR caseMergeAltsWithWildR :: RewriteH Core)
[ "A cleverer version of 'mergeCaseAlts' that first attempts to"
, "abstract out any occurrences of the alternative pattern using the wildcard binder." ] .+ Deep
, external "case-elim" (promoteExprR caseElimR :: RewriteH Core)
[ "case s of w; C vs -> e ==> e if w and vs are not free in e" ] .+ Shallow
, external "case-elim-inline-scrutinee" (promoteExprR caseElimInlineScrutineeR :: RewriteH Core)
[ "Eliminate a case, inlining any occurrences of the case binder as the scrutinee." ] .+ Deep
, external "case-elim-merge-alts" (promoteExprR caseElimMergeAltsR :: RewriteH Core)
[ "Eliminate a case, merging the case alternatives into a single default alternative",
"and inlining the case binder as the scrutinee (if possible)." ] .+ Deep
, external "case-fold-wild" (promoteExprR caseFoldWildR :: RewriteH Core)
[ "In the case alternatives, fold any occurrences of the case alt patterns to the wildcard binder." ]
]
------------------------------------------------------------------------------
-- | case s of w; C vs -> e ==> e if w and vs are not free in e
caseElimR :: Rewrite c HermitM CoreExpr
caseElimR = prefixFailMsg "Case elimination failed: " $
withPatFailMsg (wrongExprForm "Case s bnd ty alts") $
do Case _ bnd _ alts <- idR
case alts of
[(_, vs, e)] -> do let fvs = freeVarsExpr e
guardMsg (isEmptyVarSet $ intersectVarSet (mkVarSet (bnd:vs)) fvs) "wildcard or pattern binders free in RHS."
return e
_ -> fail "more than one case alternative."
------------------------------------------------------------------------------
-- | (case s of alt1 -> e1; alt2 -> e2) v ==> case s of alt1 -> e1 v; alt2 -> e2 v
caseFloatAppR :: (ExtendPath c Crumb, ReadPath c Crumb, AddBindings c, ReadBindings c) => Rewrite c HermitM CoreExpr
caseFloatAppR = prefixFailMsg "Case floating from App function failed: " $
do
captures <- appT (map mkVarSet <$> caseAltVarsT) (arr freeVarsExpr) (flip (map . intersectVarSet))
wildCapture <- appT caseWildIdT (arr freeVarsExpr) elemVarSet
appT ((if not wildCapture then idR else alphaCaseBinderR Nothing)
>>> caseAllR idR idR idR (\i -> if isEmptyVarSet (captures !! i) then idR else alphaAltR)
)
idR
(\(Case s b _ alts) v -> let newAlts = mapAlts (`App` v) alts
in Case s b (coreAltsType newAlts) newAlts)
caseFloatArg :: Maybe (CoreString, Maybe (RewriteH Core)) -> RewriteH CoreExpr
caseFloatArg Nothing = caseFloatArgR Nothing
caseFloatArg (Just (f_str, mstrict)) =
do f <- parseCoreExprT f_str
caseFloatArgR (Just (f, extractR <$> mstrict))
-- | @f (case s of alt1 -> e1; alt2 -> e2)@ ==> @case s of alt1 -> f e1; alt2 -> f e2@
-- Only safe if @f@ is strict.
caseFloatArgR :: (ExtendPath c Crumb, ReadPath c Crumb, AddBindings c, BoundVars c, HasGlobalRdrEnv c)
=> Maybe (CoreExpr, Maybe (Rewrite c HermitM CoreExpr)) -- ^ Maybe the function to float past, and maybe a proof of its strictness.
-> Rewrite c HermitM CoreExpr
caseFloatArgR mfstrict = prefixFailMsg "Case floating from App argument failed: " $
withPatFailMsg "App f (Case s w ty alts)" $
do App f (Case s w _ alts) <- idR
whenJust (\ (f', mstrict) ->
do guardMsg (exprAlphaEq f f') "given function does not match current application."
whenJust (verifyStrictT f) mstrict
)
mfstrict
let fvs = freeVarsExpr f
altCaptures = map (intersectVarSet fvs . mkVarSet . altVars) alts
wildCapture = elemVarSet w fvs
if | wildCapture -> appAllR idR (alphaCaseBinderR Nothing) >>> caseFloatArgR Nothing
| all isEmptyVarSet altCaptures -> let new_alts = mapAlts (App f) alts
in return $ Case s w (coreAltsType new_alts) new_alts
| otherwise -> appAllR idR (caseAllR idR idR idR (\ n -> let vs = varSetElems (altCaptures !! n)
in if null vs then idR else alphaAltVarsR vs
)
) >>> caseFloatArgR Nothing
-- | case (case s1 of alt11 -> e11; alt12 -> e12) of alt21 -> e21; alt22 -> e22
-- ==>
-- case s1 of
-- alt11 -> case e11 of alt21 -> e21; alt22 -> e22
-- alt12 -> case e12 of alt21 -> e21; alt22 -> e22
caseFloatCaseR :: (ExtendPath c Crumb, ReadPath c Crumb, AddBindings c, ReadBindings c) => Rewrite c HermitM CoreExpr
caseFloatCaseR = prefixFailMsg "Case floating from Case failed: " $
do
captures <- caseT (map mkVarSet <$> caseAltVarsT) idR mempty (const $ arr freeVarsAlt) (\ vss w () fvs -> map (intersectVarSet (delVarSet (unionVarSets fvs) w)) vss)
-- does the binder of the inner case, shadow a free variable in any of the outer case alts?
wildCapture <- caseT caseWildIdT idR mempty (const $ arr freeVarsAlt) (\ innerBndr w () fvs -> innerBndr `elemVarSet` (delVarSet (unionVarSets fvs) w))
caseT ((if not wildCapture then idR else alphaCaseBinderR Nothing)
>>> caseAllR idR idR idR (\i -> if isEmptyVarSet (captures !! i) then idR else alphaAltR)
)
idR
idR
(const idR)
(\ (Case s1 b1 _ alts1) b2 ty alts2 -> Case s1 b1 ty $ mapAlts (\s -> Case s b2 ty alts2) alts1)
-- | let v = case s of alt1 -> e1 in e ==> case s of alt1 -> let v = e1 in e
caseFloatLetR :: (ExtendPath c Crumb, ReadPath c Crumb, AddBindings c, ReadBindings c) => Rewrite c HermitM CoreExpr
caseFloatLetR = prefixFailMsg "Case floating from Let failed: " $
do vs <- letNonRecT idR caseAltVarsT mempty (\ letVar caseVars () -> letVar `elem` concat caseVars)
let bdsAction = if not vs then idR else nonRecAllR idR alphaCaseR
letT bdsAction idR $ \ (NonRec v (Case s b _ alts)) e -> let newAlts = mapAlts (\ rhs -> Let (NonRec v rhs) e) alts
in Case s b (coreAltsType newAlts) newAlts
-- | cast (case s of p -> e) co ==> case s of p -> cast e co
caseFloatCastR :: MonadCatch m => Rewrite c m CoreExpr
caseFloatCastR = prefixFailMsg "Case float from cast failed: " $
withPatFailMsg (wrongExprForm "Cast (Case s bnd ty alts) co") $
do Cast (Case s bnd _ alts) co <- idR
let alts' = mapAlts (flip Cast co) alts
return $ Case s bnd (coreAltsType alts') alts'
-- | caseFloatR = caseFloatAppR <+ caseFloatCaseR <+ caseFloatLetR <+ caseFloatCastR
-- Note: does NOT include caseFloatArg
caseFloatR :: (ExtendPath c Crumb, ReadPath c Crumb, AddBindings c, ReadBindings c) => Rewrite c HermitM CoreExpr
caseFloatR = setFailMsg "Unsuitable expression for Case floating." $
caseFloatAppR <+ caseFloatCaseR <+ caseFloatLetR <+ caseFloatCastR
------------------------------------------------------------------------------
-- | Float in a Case whatever the context.
caseFloatInR :: (ExtendPath c Crumb, ReadPath c Crumb, AddBindings c, MonadCatch m) => Rewrite c m CoreExpr
caseFloatInR = setFailMsg "Case floating in failed." $
caseFloatInAppR <+ caseFloatInArgsR
-- | Unimplemented!
caseFloatInAppR :: Monad m => Rewrite c m CoreExpr
caseFloatInAppR = fail "caseFloatInApp: TODO"
caseFloatInArgsR :: (ExtendPath c Crumb, ReadPath c Crumb, AddBindings c, MonadCatch m) => Rewrite c m CoreExpr
caseFloatInArgsR = prefixFailMsg "Case floating into arguments failed: " $
withPatFailMsg (wrongExprForm "Case s v t alts") $
do Case s wild _ty alts <- idR
(vss, fs, argss) <- caseT mempty mempty mempty (\ _ -> altT mempty (\ _ -> idR) callT $ \ () vs (fn, args) -> (vs, fn, args))
(\ () () () alts' -> unzip3 [ (wild:vs, fn, args) | (vs,fn,args) <- alts' ])
guardMsg (equivalentBy exprAlphaEq fs) "alternatives are not parallel in function call."
let fvs = [ varSetElems $ unionVarSets $ map freeVarsExpr $ f:tyArgs
| (f,args) <- zip fs argss
, let tyArgs = takeWhile isTyCoArg args ] -- pattern binders can be existential types
guardMsg (all null $ zipWith intersect fvs vss) "function bound by case binders."
let argss' = transpose argss
guardMsg (all (equivalentBy exprAlphaEq) $ filter (isTyCoArg . head) argss') "function applied at different types."
return $ mkCoreApps (head fs) [ if isTyCoArg (head args)
then head args
else let alts' = [ (ac, vs, arg) | ((ac,vs,_),arg) <- zip alts args ]
in Case s wild (coreAltsType alts') alts'
| args <- argss' ]
------------------------------------------------------------------------------
-- | Inline the case scrutinee (if it is an identifier), and then perform case reduction.
caseReduceIdR :: (ExtendPath c Crumb, ReadPath c Crumb, AddBindings c, ReadBindings c) => Rewrite c HermitM CoreExpr
caseReduceIdR = caseAllR inlineR idR idR (const idR) >>> caseReduceR
-- | Case of Known Constructor.
-- Eliminate a case if the scrutinee is a data constructor or a literal.
caseReduceR :: (ExtendPath c Crumb, ReadPath c Crumb, AddBindings c, ReadBindings c) => Rewrite c HermitM CoreExpr
caseReduceR = setFailMsg "Unsuitable expression for Case reduction." $
caseReduceDataconR <+ caseReduceLiteralR
-- | Case of Known Constructor.
-- Eliminate a case if the scrutinee is a literal.
-- NB: LitAlt cases don't do evaluation
caseReduceLiteralR :: MonadCatch m => Rewrite c m CoreExpr
caseReduceLiteralR = prefixFailMsg "Case reduction failed: " $
withPatFailMsg (wrongExprForm "Case (Lit l) v t alts") $
do Case s wild _ alts <- idR
#if __GLASGOW_HASKELL__ > 706
let in_scope = mkInScopeSet (mkVarEnv [ (v,v) | v <- varSetElems (localFreeVarsExpr s) ])
case exprIsLiteral_maybe (in_scope, idUnfolding) s of
#else
case exprIsLiteral_maybe idUnfolding s of
#endif
Nothing -> fail "scrutinee is not a literal."
Just l -> do guardMsg (not (litIsLifted l)) "cannot case-reduce lifted literals" -- see Trac #5603
case findAlt (LitAlt l) alts of
Nothing -> fail "no matching alternative."
Just (_, _, rhs) -> return $ mkCoreLet (NonRec wild (Lit l)) rhs
-- | Case of Known Constructor.
-- Eliminate a case if the scrutinee is a data constructor.
caseReduceDataconR :: forall c. (ExtendPath c Crumb, ReadPath c Crumb, AddBindings c, ReadBindings c) => Rewrite c HermitM CoreExpr
caseReduceDataconR = prefixFailMsg "Case reduction failed: " $
withPatFailMsg (wrongExprForm "Case e v t alts")
go
where
go :: Rewrite c HermitM CoreExpr
go = do Case e wild _ alts <- idR
#if __GLASGOW_HASKELL__ > 706
let in_scope = mkInScopeSet (mkVarEnv [ (v,v) | v <- varSetElems (localFreeVarsExpr e) ])
case exprIsConApp_maybe (in_scope, idUnfolding) e of
#else
case exprIsConApp_maybe idUnfolding e of
#endif
Nothing -> fail "head of scrutinee is not a data constructor."
Just (dc, univTys, es) -> case findAlt (DataAlt dc) alts of
Nothing -> fail "no matching alternative."
Just (dc', vs, rhs) -> -- dc' is either DEFAULT or dc
-- NB: It is possible that es contains one or more existentially quantified types.
let fvss = map freeVarsExpr $ map Type univTys ++ es
shadows = [ v | (v,n) <- zip vs [1..], any (elemVarSet v) (drop n fvss) ]
in if | any (elemVarSet wild) fvss -> alphaCaseBinderR Nothing >>> go
| null shadows -> return $ flip mkCoreLets rhs $ zipWith NonRec (wild : vs) (e : es)
| otherwise -> caseOneR (fail "scrutinee") (fail "binder") (fail "type") (\ _ -> acceptR (\ (dc'',_,_) -> dc'' == dc') >>> alphaAltVarsR shadows) >>> go
-- WARNING: The alpha-renaming to avoid variable capture has not been tested. We need testing infrastructure!
-- | Case split a free identifier in an expression:
--
-- E.g. Assume expression e which mentions i :: [a]
--
-- e ==> case i of i
-- [] -> e
-- (a:as) -> e
caseSplitR :: TH.Name -> Rewrite c HermitM CoreExpr
caseSplitR nm = prefixFailMsg "caseSplit failed: " $
do i <- matchingFreeIdT nm
let (tycon, tys) = splitTyConApp (idType i)
aNms = map (:[]) $ cycle ['a'..'z']
contextfreeT $ \ e -> do dcsAndVars <- mapM (\ dc -> (dc,) <$> sequence [ newIdH a ty | (a,ty) <- zip aNms $ dataConInstArgTys dc tys ])
(tyConDataCons tycon)
let alts = [ (DataAlt dc, as, e) | (dc,as) <- dcsAndVars ]
return $ Case (Var i) i (coreAltsType alts) alts
-- | Force evaluation of an identifier by introducing a case.
-- This is equivalent to adding @(seq v)@ in the source code.
--
-- e -> case v of v
-- _ -> e
caseIntroSeqR :: TH.Name -> Rewrite c HermitM CoreExpr
caseIntroSeqR nm = prefixFailMsg "case-intro-seq failed: " $
do i <- matchingFreeIdT nm
e <- idR
guardMsg (not $ isTyCoArg e) "cannot case on a type or coercion."
let alts = [(DEFAULT, [], e)]
return $ Case (Var i) i (coreAltsType alts) alts
-- auxillary function for use by caseSplit and caseSeq
matchingFreeIdT :: Monad m => TH.Name -> Translate c m CoreExpr Id
matchingFreeIdT nm = do
fvs <- arr freeVarsExpr
case varSetElems (filterVarSet (\ v -> cmpTHName2Var nm v && isId v) fvs) of
[] -> fail "provided name is not a free identifier."
[i] -> return i
is -> fail ("provided name matches " ++ show (length is) ++ " free identifiers.")
-- | Like caseSplit, but additionally inlines the constructor applications
-- for each occurance of the named variable.
--
-- > caseSplitInline nm = caseSplit nm >>> anybuR (inlineName nm)
caseSplitInlineR :: (ExtendPath c Crumb, ReadPath c Crumb, AddBindings c, ReadBindings c) => TH.Name -> Rewrite c HermitM Core
caseSplitInlineR nm = promoteR (caseSplitR nm) >>> anybuR (promoteExprR $ inlineNameR nm)
------------------------------------------------------------------------------
caseInlineBinderR :: forall c. (ExtendPath c Crumb, ReadPath c Crumb, AddBindings c, ReadBindings c) => CaseBinderInlineOption -> Rewrite c HermitM CoreExpr
caseInlineBinderR opt =
do w <- caseWildIdT
caseAllR idR idR idR $ \ _ -> setFailMsg "no inlinable occurrences." $
do depth <- varBindingDepthT w
extractR $ anybuR (promoteExprR (configurableInlineR (CaseBinderOnly opt) (varIsOccurrenceOfT w depth)) :: Rewrite c HermitM Core)
-- | Inline the case wildcard binder as the case scrutinee everywhere in the case alternatives.
caseInlineScrutineeR :: (ExtendPath c Crumb, ReadPath c Crumb, AddBindings c, ReadBindings c) => Rewrite c HermitM CoreExpr
caseInlineScrutineeR = prefixFailMsg "case-inline-scrutinee failed: " $
caseInlineBinderR Scrutinee
-- | Inline the case wildcard binder as the case-alternative pattern everywhere in the case alternatives.
caseInlineAlternativeR :: (ExtendPath c Crumb, ReadPath c Crumb, AddBindings c, ReadBindings c) => Rewrite c HermitM CoreExpr
caseInlineAlternativeR = prefixFailMsg "case-inline-alternative failed: " $
caseInlineBinderR Alternative
------------------------------------------------------------------------------
-- | Merge all case alternatives into a single default case.
-- The RHS of each alternative must be the same.
-- @case s of {pat1 -> e ; pat2 -> e ; ... ; patn -> e}@ ==> @case s of {_ -> e}@
caseMergeAltsR :: MonadCatch m => Rewrite c m CoreExpr
caseMergeAltsR = prefixFailMsg "merge-case-alts failed: " $
withPatFailMsg (wrongExprForm "Case e w ty alts") $
do Case e w ty alts <- idR
guardMsg (notNull alts) "zero alternatives cannot be merged."
let rhss = [ rhs | (_,_,rhs) <- alts ]
guardMsg (equivalentBy exprAlphaEq rhss) "right-hand sides are not all equal."
guardMsg (all altVarsUnused alts) "variables bound in case alt pattern appear free in alt right-hand side."
return $ Case e w ty [(DEFAULT,[],head rhss)]
-- | In the case alternatives, fold any occurrences of the case alt patterns to the wildcard binder.
caseFoldWildR :: forall c. (ExtendPath c Crumb, ReadPath c Crumb, AddBindings c, ReadBindings c) => Rewrite c HermitM CoreExpr
caseFoldWildR = prefixFailMsg "case-fold-wild failed: " $
do w <- caseWildIdT
caseAllR idR idR idR $ \ _ -> do depth <- varBindingDepthT w
extractR $ anybuR (promoteExprR (foldVarR w (Just depth)) :: Rewrite c HermitM Core)
-- | A cleverer version of 'mergeCaseAlts' that first attempts to abstract out any occurrences of the alternative pattern using the wildcard binder.
caseMergeAltsWithWildR :: (ExtendPath c Crumb, ReadPath c Crumb, AddBindings c, ReadBindings c) => Rewrite c HermitM CoreExpr
caseMergeAltsWithWildR = prefixFailMsg "merge-case-alts-with-wild failed: " $
withPatFailMsg (wrongExprForm "Case e w ty alts") $
tryR caseFoldWildR >>> caseMergeAltsR
-- | Eliminate a case, inlining any occurrences of the case binder as the scrutinee.
caseElimInlineScrutineeR :: (ExtendPath c Crumb, ReadPath c Crumb, AddBindings c, ReadBindings c) => Rewrite c HermitM CoreExpr
caseElimInlineScrutineeR = alphaCaseBinderR Nothing >>> tryR caseInlineScrutineeR >>> caseElimR
-- | Eliminate a case, merging the case alternatives into a single default alternative and inlining the case binder as the scrutinee (if possible).
caseElimMergeAltsR :: (ExtendPath c Crumb, ReadPath c Crumb, AddBindings c, ReadBindings c) => Rewrite c HermitM CoreExpr
caseElimMergeAltsR = tryR caseFoldWildR >>> tryR caseMergeAltsR >>> caseElimInlineScrutineeR
------------------------------------------------------------------------------
-- | Eliminate a case that corresponds to a pointless 'seq'.
caseElimSeqR :: (ExtendPath c Crumb, ReadPath c Crumb, AddBindings c, ReadBindings c) => Rewrite c HermitM CoreExpr
caseElimSeqR = prefixFailMsg "case-elim-seq failed: " $
withPatFailMsg "not a seq case." $
do Case s w _ [(DEFAULT,[],rhs)] <- idR
let is = case s of
Var i -> [i,w]
_ -> [w]
if is `isForcedIn` rhs
then caseElimInlineScrutineeR
else fail "cannot be sure that this seq case is pointless. Use case-elim-inline-scrutinee if you want to proceed anyway."
-- | Will forcing the expression to WHNF always force one of the given identifiers?
isForcedIn :: [Id] -> CoreExpr -> Bool
isForcedIn is = \case
Var i -> i `elem` is
App f _ -> is `isForcedIn` f
Let _ body -> is `isForcedIn` body
Case s _ _ _ -> is `isForcedIn` s
Cast e _ -> is `isForcedIn` e
Tick _ e -> is `isForcedIn` e
_ -> False
------------------------------------------------------------------------------
altVarsUnused :: CoreAlt -> Bool
altVarsUnused (_,vs,rhs) = all (`notElemVarSet` freeVarsExpr rhs) vs
------------------------------------------------------------------------------