[ghc-hetmet.git] / ghc / compiler / simplCore / SimplUtils.lhs

%
% (c) The AQUA Project, Glasgow University, 1993-1998
%
\section[SimplUtils]{The simplifier utilities}

\begin{code}
module SimplUtils (
        simplBinder, simplBinders, simplRecBndrs, 
        simplLetBndr, simplLamBndrs, 
        newId, mkLam, prepareAlts, mkCase,

        -- The continuation type
        SimplCont(..), DupFlag(..), LetRhsFlag(..), 
        contIsDupable, contResultType,
        countValArgs, countArgs, pushContArgs,
        mkBoringStop, mkStop, contIsRhs, contIsRhsOrArg,
        getContArgs, interestingCallContext, interestingArg, isStrictType

    ) where

#include "HsVersions.h"

import CmdLineOpts      ( SimplifierSwitch(..),
                          opt_SimplDoLambdaEtaExpansion, opt_SimplDoEtaReduction,
                          opt_SimplCaseMerge, opt_UF_UpdateInPlace
                        )
import CoreSyn
import CoreUtils        ( cheapEqExpr, exprType, 
                          etaExpand, exprEtaExpandArity, bindNonRec, mkCoerce,
                          findDefault, exprOkForSpeculation, exprIsValue
                        )
import qualified Subst  ( simplBndrs, simplBndr, simplLetId, simplLamBndr )
import Id               ( Id, idType, idInfo, 
                          mkSysLocal, isDeadBinder, idNewDemandInfo,
                          idUnfolding, idNewStrictness
                        )
import NewDemand        ( isStrictDmd, isBotRes, splitStrictSig )
import SimplMonad
import Type             ( Type, seqType, splitRepFunTys, isStrictType,
                          splitTyConApp_maybe, tyConAppArgs, mkTyVarTys
                        )
import TcType           ( isDictTy )
import OccName          ( EncodedFS )
import TyCon            ( tyConDataCons_maybe, isAlgTyCon, isNewTyCon )
import DataCon          ( dataConRepArity, dataConSig, dataConArgTys )
import Var              ( mkSysTyVar, tyVarKind )
import Util             ( lengthExceeds, mapAccumL )
import Outputable
\end{code}


%************************************************************************
%*                                                                      *
\subsection{The continuation data type}
%*                                                                      *
%************************************************************************

\begin{code}
data SimplCont          -- Strict contexts
  = Stop     OutType            -- Type of the result
             LetRhsFlag
             Bool               -- True <=> This is the RHS of a thunk whose type suggests
                                --          that update-in-place would be possible
                                --          (This makes the inliner a little keener.)

  | CoerceIt OutType                    -- The To-type, simplified
             SimplCont

  | InlinePlease                        -- This continuation makes a function very
             SimplCont                  -- keen to inline itelf

  | ApplyTo  DupFlag 
             InExpr SimplEnv            -- The argument, as yet unsimplified, 
             SimplCont                  -- and its environment

  | Select   DupFlag 
             InId [InAlt] SimplEnv      -- The case binder, alts, and subst-env
             SimplCont

  | ArgOf    LetRhsFlag         -- An arbitrary strict context: the argument 
                                --      of a strict function, or a primitive-arg fn
                                --      or a PrimOp
                                -- No DupFlag because we never duplicate it
             OutType            -- arg_ty: type of the argument itself
             OutType            -- cont_ty: the type of the expression being sought by the context
                                --      f (error "foo") ==> coerce t (error "foo")
                                -- when f is strict
                                -- We need to know the type t, to which to coerce.

             (SimplEnv -> OutExpr -> SimplM FloatsWithExpr)     -- What to do with the result
                                -- The result expression in the OutExprStuff has type cont_ty

data LetRhsFlag = AnArg         -- It's just an argument not a let RHS
                | AnRhs         -- It's the RHS of a let (so please float lets out of big lambdas)

instance Outputable LetRhsFlag where
  ppr AnArg = ptext SLIT("arg")
  ppr AnRhs = ptext SLIT("rhs")

instance Outputable SimplCont where
  ppr (Stop _ is_rhs _)              = ptext SLIT("Stop") <> brackets (ppr is_rhs)
  ppr (ApplyTo dup arg se cont)      = (ptext SLIT("ApplyTo") <+> ppr dup <+> ppr arg) $$ ppr cont
  ppr (ArgOf _ _ _ _)                = ptext SLIT("ArgOf...")
  ppr (Select dup bndr alts se cont) = (ptext SLIT("Select") <+> ppr dup <+> ppr bndr) $$ 
                                       (nest 4 (ppr alts)) $$ ppr cont
  ppr (CoerceIt ty cont)             = (ptext SLIT("CoerceIt") <+> ppr ty) $$ ppr cont
  ppr (InlinePlease cont)            = ptext SLIT("InlinePlease") $$ ppr cont

data DupFlag = OkToDup | NoDup

instance Outputable DupFlag where
  ppr OkToDup = ptext SLIT("ok")
  ppr NoDup   = ptext SLIT("nodup")


-------------------
mkBoringStop :: OutType -> SimplCont
mkBoringStop ty = Stop ty AnArg (canUpdateInPlace ty)

mkStop :: OutType -> LetRhsFlag -> SimplCont
mkStop ty is_rhs = Stop ty is_rhs (canUpdateInPlace ty)

contIsRhs :: SimplCont -> Bool
contIsRhs (Stop _ AnRhs _)    = True
contIsRhs (ArgOf AnRhs _ _ _) = True
contIsRhs other               = False

contIsRhsOrArg (Stop _ _ _)    = True
contIsRhsOrArg (ArgOf _ _ _ _) = True
contIsRhsOrArg other           = False

-------------------
contIsDupable :: SimplCont -> Bool
contIsDupable (Stop _ _ _)               = True
contIsDupable (ApplyTo  OkToDup _ _ _)   = True
contIsDupable (Select   OkToDup _ _ _ _) = True
contIsDupable (CoerceIt _ cont)          = contIsDupable cont
contIsDupable (InlinePlease cont)        = contIsDupable cont
contIsDupable other                      = False

-------------------
discardableCont :: SimplCont -> Bool
discardableCont (Stop _ _ _)        = False
discardableCont (CoerceIt _ cont)   = discardableCont cont
discardableCont (InlinePlease cont) = discardableCont cont
discardableCont other               = True

discardCont :: SimplCont        -- A continuation, expecting
            -> SimplCont        -- Replace the continuation with a suitable coerce
discardCont cont = case cont of
                     Stop to_ty is_rhs _ -> cont
                     other               -> CoerceIt to_ty (mkBoringStop to_ty)
                 where
                   to_ty = contResultType cont

-------------------
contResultType :: SimplCont -> OutType
contResultType (Stop to_ty _ _)      = to_ty
contResultType (ArgOf _ _ to_ty _)   = to_ty
contResultType (ApplyTo _ _ _ cont)  = contResultType cont
contResultType (CoerceIt _ cont)     = contResultType cont
contResultType (InlinePlease cont)   = contResultType cont
contResultType (Select _ _ _ _ cont) = contResultType cont

-------------------
countValArgs :: SimplCont -> Int
countValArgs (ApplyTo _ (Type ty) se cont) = countValArgs cont
countValArgs (ApplyTo _ val_arg   se cont) = 1 + countValArgs cont
countValArgs other                         = 0

countArgs :: SimplCont -> Int
countArgs (ApplyTo _ arg se cont) = 1 + countArgs cont
countArgs other                   = 0

-------------------
pushContArgs :: SimplEnv -> [OutArg] -> SimplCont -> SimplCont
-- Pushes args with the specified environment
pushContArgs env []           cont = cont
pushContArgs env (arg : args) cont = ApplyTo NoDup arg env (pushContArgs env args cont)
\end{code}


\begin{code}
getContArgs :: SwitchChecker
            -> OutId -> SimplCont 
            -> ([(InExpr, SimplEnv, Bool)],     -- Arguments; the Bool is true for strict args
                SimplCont,                      -- Remaining continuation
                Bool)                           -- Whether we came across an InlineCall
-- getContArgs id k = (args, k', inl)
--      args are the leading ApplyTo items in k
--      (i.e. outermost comes first)
--      augmented with demand info from the functionn
getContArgs chkr fun orig_cont
  = let
                -- Ignore strictness info if the no-case-of-case
                -- flag is on.  Strictness changes evaluation order
                -- and that can change full laziness
        stricts | switchIsOn chkr NoCaseOfCase = vanilla_stricts
                | otherwise                    = computed_stricts
    in
    go [] stricts False orig_cont
  where
    ----------------------------

        -- Type argument
    go acc ss inl (ApplyTo _ arg@(Type _) se cont)
        = go ((arg,se,False) : acc) ss inl cont
                -- NB: don't bother to instantiate the function type

        -- Value argument
    go acc (s:ss) inl (ApplyTo _ arg se cont)
        = go ((arg,se,s) : acc) ss inl cont

        -- An Inline continuation
    go acc ss inl (InlinePlease cont)
        = go acc ss True cont

        -- We're run out of arguments, or else we've run out of demands
        -- The latter only happens if the result is guaranteed bottom
        -- This is the case for
        --      * case (error "hello") of { ... }
        --      * (error "Hello") arg
        --      * f (error "Hello") where f is strict
        --      etc
    go acc ss inl cont 
        | null ss && discardableCont cont = (reverse acc, discardCont cont, inl)
        | otherwise                       = (reverse acc, cont,             inl)

    ----------------------------
    vanilla_stricts, computed_stricts :: [Bool]
    vanilla_stricts  = repeat False
    computed_stricts = zipWith (||) fun_stricts arg_stricts

    ----------------------------
    (val_arg_tys, _) = splitRepFunTys (idType fun)
    arg_stricts      = map isStrictType val_arg_tys ++ repeat False
        -- These argument types are used as a cheap and cheerful way to find
        -- unboxed arguments, which must be strict.  But it's an InType
        -- and so there might be a type variable where we expect a function
        -- type (the substitution hasn't happened yet).  And we don't bother
        -- doing the type applications for a polymorphic function.
        -- Hence the split*Rep*FunTys

    ----------------------------
        -- If fun_stricts is finite, it means the function returns bottom
        -- after that number of value args have been consumed
        -- Otherwise it's infinite, extended with False
    fun_stricts
      = case splitStrictSig (idNewStrictness fun) of
          (demands, result_info)
                | not (demands `lengthExceeds` countValArgs orig_cont)
                ->      -- Enough args, use the strictness given.
                        -- For bottoming functions we used to pretend that the arg
                        -- is lazy, so that we don't treat the arg as an
                        -- interesting context.  This avoids substituting
                        -- top-level bindings for (say) strings into 
                        -- calls to error.  But now we are more careful about
                        -- inlining lone variables, so its ok (see SimplUtils.analyseCont)
                   if isBotRes result_info then
                        map isStrictDmd demands         -- Finite => result is bottom
                   else
                        map isStrictDmd demands ++ vanilla_stricts

          other -> vanilla_stricts      -- Not enough args, or no strictness

-------------------
interestingArg :: OutExpr -> Bool
        -- An argument is interesting if it has *some* structure
        -- We are here trying to avoid unfolding a function that
        -- is applied only to variables that have no unfolding
        -- (i.e. they are probably lambda bound): f x y z
        -- There is little point in inlining f here.
interestingArg (Var v)           = hasSomeUnfolding (idUnfolding v)
                                        -- Was: isValueUnfolding (idUnfolding v')
                                        -- But that seems over-pessimistic
interestingArg (Type _)          = False
interestingArg (App fn (Type _)) = interestingArg fn
interestingArg (Note _ a)        = interestingArg a
interestingArg other             = True
        -- Consider     let x = 3 in f x
        -- The substitution will contain (x -> ContEx 3), and we want to
        -- to say that x is an interesting argument.
        -- But consider also (\x. f x y) y
        -- The substitution will contain (x -> ContEx y), and we want to say
        -- that x is not interesting (assuming y has no unfolding)
\end{code}

Comment about interestingCallContext
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
We want to avoid inlining an expression where there can't possibly be
any gain, such as in an argument position.  Hence, if the continuation
is interesting (eg. a case scrutinee, application etc.) then we
inline, otherwise we don't.  

Previously some_benefit used to return True only if the variable was
applied to some value arguments.  This didn't work:

        let x = _coerce_ (T Int) Int (I# 3) in
        case _coerce_ Int (T Int) x of
                I# y -> ....

we want to inline x, but can't see that it's a constructor in a case
scrutinee position, and some_benefit is False.

Another example:

dMonadST = _/\_ t -> :Monad (g1 _@_ t, g2 _@_ t, g3 _@_ t)

....  case dMonadST _@_ x0 of (a,b,c) -> ....

we'd really like to inline dMonadST here, but we *don't* want to
inline if the case expression is just

        case x of y { DEFAULT -> ... }

since we can just eliminate this case instead (x is in WHNF).  Similar
applies when x is bound to a lambda expression.  Hence
contIsInteresting looks for case expressions with just a single
default case.

\begin{code}
interestingCallContext :: Bool          -- False <=> no args at all
                       -> Bool          -- False <=> no value args
                       -> SimplCont -> Bool
        -- The "lone-variable" case is important.  I spent ages
        -- messing about with unsatisfactory varaints, but this is nice.
        -- The idea is that if a variable appear all alone
        --      as an arg of lazy fn, or rhs    Stop
        --      as scrutinee of a case          Select
        --      as arg of a strict fn           ArgOf
        -- then we should not inline it (unless there is some other reason,
        -- e.g. is is the sole occurrence).  We achieve this by making
        -- interestingCallContext return False for a lone variable.
        --
        -- Why?  At least in the case-scrutinee situation, turning
        --      let x = (a,b) in case x of y -> ...
        -- into
        --      let x = (a,b) in case (a,b) of y -> ...
        -- and thence to 
        --      let x = (a,b) in let y = (a,b) in ...
        -- is bad if the binding for x will remain.
        --
        -- Another example: I discovered that strings
        -- were getting inlined straight back into applications of 'error'
        -- because the latter is strict.
        --      s = "foo"
        --      f = \x -> ...(error s)...

        -- Fundamentally such contexts should not ecourage inlining because
        -- the context can ``see'' the unfolding of the variable (e.g. case or a RULE)
        -- so there's no gain.
        --
        -- However, even a type application or coercion isn't a lone variable.
        -- Consider
        --      case $fMonadST @ RealWorld of { :DMonad a b c -> c }
        -- We had better inline that sucker!  The case won't see through it.
        --
        -- For now, I'm treating treating a variable applied to types 
        -- in a *lazy* context "lone". The motivating example was
        --      f = /\a. \x. BIG
        --      g = /\a. \y.  h (f a)
        -- There's no advantage in inlining f here, and perhaps
        -- a significant disadvantage.  Hence some_val_args in the Stop case

interestingCallContext some_args some_val_args cont
  = interesting cont
  where
    interesting (InlinePlease _)       = True
    interesting (Select _ _ _ _ _)     = some_args
    interesting (ApplyTo _ _ _ _)      = True   -- Can happen if we have (coerce t (f x)) y
                                                -- Perhaps True is a bit over-keen, but I've
                                                -- seen (coerce f) x, where f has an INLINE prag,
                                                -- So we have to give some motivaiton for inlining it
    interesting (ArgOf _ _ _ _)          = some_val_args
    interesting (Stop ty _ upd_in_place) = some_val_args && upd_in_place
    interesting (CoerceIt _ cont)        = interesting cont
        -- If this call is the arg of a strict function, the context
        -- is a bit interesting.  If we inline here, we may get useful
        -- evaluation information to avoid repeated evals: e.g.
        --      x + (y * z)
        -- Here the contIsInteresting makes the '*' keener to inline,
        -- which in turn exposes a constructor which makes the '+' inline.
        -- Assuming that +,* aren't small enough to inline regardless.
        --
        -- It's also very important to inline in a strict context for things
        -- like
        --              foldr k z (f x)
        -- Here, the context of (f x) is strict, and if f's unfolding is
        -- a build it's *great* to inline it here.  So we must ensure that
        -- the context for (f x) is not totally uninteresting.


-------------------
canUpdateInPlace :: Type -> Bool
-- Consider   let x = <wurble> in ...
-- If <wurble> returns an explicit constructor, we might be able
-- to do update in place.  So we treat even a thunk RHS context
-- as interesting if update in place is possible.  We approximate
-- this by seeing if the type has a single constructor with a
-- small arity.  But arity zero isn't good -- we share the single copy
-- for that case, so no point in sharing.

canUpdateInPlace ty 
  | not opt_UF_UpdateInPlace = False
  | otherwise
  = case splitTyConApp_maybe ty of 
        Nothing         -> False 
        Just (tycon, _) -> case tyConDataCons_maybe tycon of
                                Just [dc]  -> arity == 1 || arity == 2
                                           where
                                              arity = dataConRepArity dc
                                other -> False
\end{code}



%************************************************************************
%*                                                                      *
\section{Dealing with a single binder}
%*                                                                      *
%************************************************************************

These functions are in the monad only so that they can be made strict via seq.

\begin{code}
simplBinders :: SimplEnv -> [InBinder] -> SimplM (SimplEnv, [OutBinder])
simplBinders env bndrs
  = let
        (subst', bndrs') = Subst.simplBndrs (getSubst env) bndrs
    in
    seqBndrs bndrs'     `seq`
    returnSmpl (setSubst env subst', bndrs')

simplBinder :: SimplEnv -> InBinder -> SimplM (SimplEnv, OutBinder)
simplBinder env bndr
  = let
        (subst', bndr') = Subst.simplBndr (getSubst env) bndr
    in
    seqBndr bndr'       `seq`
    returnSmpl (setSubst env subst', bndr')


simplLetBndr :: SimplEnv -> InBinder -> SimplM (SimplEnv, OutBinder)
simplLetBndr env id
  = let
        (subst', id') = Subst.simplLetId (getSubst env) id
    in
    seqBndr id'         `seq`
    returnSmpl (setSubst env subst', id')

simplLamBndrs, simplRecBndrs 
        :: SimplEnv -> [InBinder] -> SimplM (SimplEnv, [OutBinder])
simplRecBndrs = simplBndrs Subst.simplLetId
simplLamBndrs = simplBndrs Subst.simplLamBndr

simplBndrs simpl_bndr env bndrs
  = let
        (subst', bndrs') = mapAccumL simpl_bndr (getSubst env) bndrs
    in
    seqBndrs bndrs'     `seq`
    returnSmpl (setSubst env subst', bndrs')

seqBndrs [] = ()
seqBndrs (b:bs) = seqBndr b `seq` seqBndrs bs

seqBndr b | isTyVar b = b `seq` ()
          | otherwise = seqType (idType b)      `seq`
                        idInfo b                `seq`
                        ()
\end{code}


\begin{code}
newId :: EncodedFS -> Type -> SimplM Id
newId fs ty = getUniqueSmpl     `thenSmpl` \ uniq ->
              returnSmpl (mkSysLocal fs uniq ty)
\end{code}


%************************************************************************
%*                                                                      *
\subsection{Rebuilding a lambda}
%*                                                                      *
%************************************************************************

\begin{code}
mkLam :: SimplEnv -> [OutBinder] -> OutExpr -> SimplCont -> SimplM FloatsWithExpr
\end{code}

Try three things
        a) eta reduction, if that gives a trivial expression
        b) eta expansion [only if there are some value lambdas]
        c) floating lets out through big lambdas 
                [only if all tyvar lambdas, and only if this lambda
                 is the RHS of a let]

\begin{code}
mkLam env bndrs body cont
 | opt_SimplDoEtaReduction,
   Just etad_lam <- tryEtaReduce bndrs body
 = tick (EtaReduction (head bndrs))     `thenSmpl_`
   returnSmpl (emptyFloats env, etad_lam)

 | opt_SimplDoLambdaEtaExpansion,
   any isRuntimeVar bndrs
 = tryEtaExpansion body         `thenSmpl` \ body' ->
   returnSmpl (emptyFloats env, mkLams bndrs body')

{-      Sept 01: I'm experimenting with getting the
        full laziness pass to float out past big lambdsa
 | all isTyVar bndrs,   -- Only for big lambdas
   contIsRhs cont       -- Only try the rhs type-lambda floating
                        -- if this is indeed a right-hand side; otherwise
                        -- we end up floating the thing out, only for float-in
                        -- to float it right back in again!
 = tryRhsTyLam env bndrs body           `thenSmpl` \ (floats, body') ->
   returnSmpl (floats, mkLams bndrs body')
-}

 | otherwise 
 = returnSmpl (emptyFloats env, mkLams bndrs body)
\end{code}


%************************************************************************
%*                                                                      *
\subsection{Eta expansion and reduction}
%*                                                                      *
%************************************************************************

We try for eta reduction here, but *only* if we get all the 
way to an exprIsTrivial expression.    
We don't want to remove extra lambdas unless we are going 
to avoid allocating this thing altogether

\begin{code}
tryEtaReduce :: [OutBinder] -> OutExpr -> Maybe OutExpr
tryEtaReduce bndrs body 
        -- We don't use CoreUtils.etaReduce, because we can be more
        -- efficient here:
        --  (a) we already have the binders
        --  (b) we can do the triviality test before computing the free vars
        --      [in fact I take the simple path and look for just a variable]
  = go (reverse bndrs) body
  where
    go (b : bs) (App fun arg) | ok_arg b arg = go bs fun        -- Loop round
    go []       (Var fun)     | ok_fun fun   = Just (Var fun)   -- Success!
    go _        _                            = Nothing          -- Failure!

    ok_fun fun = not (fun `elem` bndrs) && 
                 (isEvaldUnfolding (idUnfolding fun) || all ok_lam bndrs)
    ok_lam v = isTyVar v || isDictTy (idType v)
        -- The isEvaldUnfolding is because eta reduction is not 
        -- valid in general:  \x. bot  /=  bot
        -- So we need to be sure that the "fun" is a value.
        --
        -- However, we always want to reduce (/\a -> f a) to f
        -- This came up in a RULE: foldr (build (/\a -> g a))
        --      did not match      foldr (build (/\b -> ...something complex...))
        -- The type checker can insert these eta-expanded versions,
        -- with both type and dictionary lambdas; hence the slightly 
        -- ad-hoc isDictTy

    ok_arg b arg = varToCoreExpr b `cheapEqExpr` arg
\end{code}


        Try eta expansion for RHSs

We go for:
   f = \x1..xn -> N  ==>   f = \x1..xn y1..ym -> N y1..ym
                                 (n >= 0)

where (in both cases) 

        * The xi can include type variables

        * The yi are all value variables

        * N is a NORMAL FORM (i.e. no redexes anywhere)
          wanting a suitable number of extra args.

We may have to sandwich some coerces between the lambdas
to make the types work.   exprEtaExpandArity looks through coerces
when computing arity; and etaExpand adds the coerces as necessary when
actually computing the expansion.

\begin{code}
tryEtaExpansion :: OutExpr -> SimplM OutExpr
-- There is at least one runtime binder in the binders
tryEtaExpansion body
  = getUniquesSmpl                      `thenSmpl` \ us ->
    returnSmpl (etaExpand fun_arity us body (exprType body))
  where
    fun_arity = exprEtaExpandArity body
\end{code}


%************************************************************************
%*                                                                      *
\subsection{Floating lets out of big lambdas}
%*                                                                      *
%************************************************************************

tryRhsTyLam tries this transformation, when the big lambda appears as
the RHS of a let(rec) binding:

        /\abc -> let(rec) x = e in b
   ==>
        let(rec) x' = /\abc -> let x = x' a b c in e
        in 
        /\abc -> let x = x' a b c in b

This is good because it can turn things like:

        let f = /\a -> letrec g = ... g ... in g
into
        letrec g' = /\a -> ... g' a ...
        in
        let f = /\ a -> g' a

which is better.  In effect, it means that big lambdas don't impede
let-floating.

This optimisation is CRUCIAL in eliminating the junk introduced by
desugaring mutually recursive definitions.  Don't eliminate it lightly!

So far as the implementation is concerned:

        Invariant: go F e = /\tvs -> F e
        
        Equalities:
                go F (Let x=e in b)
                = Let x' = /\tvs -> F e 
                  in 
                  go G b
                where
                    G = F . Let x = x' tvs
        
                go F (Letrec xi=ei in b)
                = Letrec {xi' = /\tvs -> G ei} 
                  in
                  go G b
                where
                  G = F . Let {xi = xi' tvs}

[May 1999]  If we do this transformation *regardless* then we can
end up with some pretty silly stuff.  For example, 

        let 
            st = /\ s -> let { x1=r1 ; x2=r2 } in ...
        in ..
becomes
        let y1 = /\s -> r1
            y2 = /\s -> r2
            st = /\s -> ...[y1 s/x1, y2 s/x2]
        in ..

Unless the "..." is a WHNF there is really no point in doing this.
Indeed it can make things worse.  Suppose x1 is used strictly,
and is of the form

        x1* = case f y of { (a,b) -> e }

If we abstract this wrt the tyvar we then can't do the case inline
as we would normally do.


\begin{code}
{-      Trying to do this in full laziness

tryRhsTyLam :: SimplEnv -> [OutTyVar] -> OutExpr -> SimplM FloatsWithExpr
-- Call ensures that all the binders are type variables

tryRhsTyLam env tyvars body             -- Only does something if there's a let
  |  not (all isTyVar tyvars)
  || not (worth_it body)                -- inside a type lambda, 
  = returnSmpl (emptyFloats env, body)  -- and a WHNF inside that

  | otherwise
  = go env (\x -> x) body

  where
    worth_it e@(Let _ _) = whnf_in_middle e
    worth_it e           = False

    whnf_in_middle (Let (NonRec x rhs) e) | isUnLiftedType (idType x) = False
    whnf_in_middle (Let _ e) = whnf_in_middle e
    whnf_in_middle e         = exprIsCheap e

    main_tyvar_set = mkVarSet tyvars

    go env fn (Let bind@(NonRec var rhs) body)
      | exprIsTrivial rhs
      = go env (fn . Let bind) body

    go env fn (Let (NonRec var rhs) body)
      = mk_poly tyvars_here var                                                 `thenSmpl` \ (var', rhs') ->
        addAuxiliaryBind env (NonRec var' (mkLams tyvars_here (fn rhs)))        $ \ env -> 
        go env (fn . Let (mk_silly_bind var rhs')) body

      where

        tyvars_here = varSetElems (main_tyvar_set `intersectVarSet` exprSomeFreeVars isTyVar rhs)
                -- Abstract only over the type variables free in the rhs
                -- wrt which the new binding is abstracted.  But the naive
                -- approach of abstract wrt the tyvars free in the Id's type
                -- fails. Consider:
                --      /\ a b -> let t :: (a,b) = (e1, e2)
                --                    x :: a     = fst t
                --                in ...
                -- Here, b isn't free in x's type, but we must nevertheless
                -- abstract wrt b as well, because t's type mentions b.
                -- Since t is floated too, we'd end up with the bogus:
                --      poly_t = /\ a b -> (e1, e2)
                --      poly_x = /\ a   -> fst (poly_t a *b*)
                -- So for now we adopt the even more naive approach of
                -- abstracting wrt *all* the tyvars.  We'll see if that
                -- gives rise to problems.   SLPJ June 98

    go env fn (Let (Rec prs) body)
       = mapAndUnzipSmpl (mk_poly tyvars_here) vars     `thenSmpl` \ (vars', rhss') ->
         let
            gn body = fn (foldr Let body (zipWith mk_silly_bind vars rhss'))
            pairs   = vars' `zip` [mkLams tyvars_here (gn rhs) | rhs <- rhss]
         in
         addAuxiliaryBind env (Rec pairs)               $ \ env ->
         go env gn body 
       where
         (vars,rhss) = unzip prs
         tyvars_here = varSetElems (main_tyvar_set `intersectVarSet` exprsSomeFreeVars isTyVar (map snd prs))
                -- See notes with tyvars_here above

    go env fn body = returnSmpl (emptyFloats env, fn body)

    mk_poly tyvars_here var
      = getUniqueSmpl           `thenSmpl` \ uniq ->
        let
            poly_name = setNameUnique (idName var) uniq         -- Keep same name
            poly_ty   = mkForAllTys tyvars_here (idType var)    -- But new type of course
            poly_id   = mkLocalId poly_name poly_ty 

                -- In the olden days, it was crucial to copy the occInfo of the original var, 
                -- because we were looking at occurrence-analysed but as yet unsimplified code!
                -- In particular, we mustn't lose the loop breakers.  BUT NOW we are looking
                -- at already simplified code, so it doesn't matter
                -- 
                -- It's even right to retain single-occurrence or dead-var info:
                -- Suppose we started with  /\a -> let x = E in B
                -- where x occurs once in B. Then we transform to:
                --      let x' = /\a -> E in /\a -> let x* = x' a in B
                -- where x* has an INLINE prag on it.  Now, once x* is inlined,
                -- the occurrences of x' will be just the occurrences originally
                -- pinned on x.
        in
        returnSmpl (poly_id, mkTyApps (Var poly_id) (mkTyVarTys tyvars_here))

    mk_silly_bind var rhs = NonRec var (Note InlineMe rhs)
                -- Suppose we start with:
                --
                --      x = /\ a -> let g = G in E
                --
                -- Then we'll float to get
                --
                --      x = let poly_g = /\ a -> G
                --          in /\ a -> let g = poly_g a in E
                --
                -- But now the occurrence analyser will see just one occurrence
                -- of poly_g, not inside a lambda, so the simplifier will
                -- PreInlineUnconditionally poly_g back into g!  Badk to square 1!
                -- (I used to think that the "don't inline lone occurrences" stuff
                --  would stop this happening, but since it's the *only* occurrence,
                --  PreInlineUnconditionally kicks in first!)
                --
                -- Solution: put an INLINE note on g's RHS, so that poly_g seems
                --           to appear many times.  (NB: mkInlineMe eliminates
                --           such notes on trivial RHSs, so do it manually.)
-}
\end{code}

%************************************************************************
%*                                                                      *
\subsection{Case alternative filtering
%*                                                                      *
%************************************************************************

prepareAlts does two things:

1.  Eliminate alternatives that cannot match, including the
    DEFAULT alternative.

2.  If the DEFAULT alternative can match only one possible constructor,
    then make that constructor explicit.
    e.g.
        case e of x { DEFAULT -> rhs }
     ===>
        case e of x { (a,b) -> rhs }
    where the type is a single constructor type.  This gives better code
    when rhs also scrutinises x or e.

It's a good idea do do this stuff before simplifying the alternatives, to
avoid simplifying alternatives we know can't happen, and to come up with
the list of constructors that are handled, to put into the IdInfo of the
case binder, for use when simplifying the alternatives.

Eliminating the default alternative in (1) isn't so obvious, but it can
happen:

data Colour = Red | Green | Blue

f x = case x of
        Red -> ..
        Green -> ..
        DEFAULT -> h x

h y = case y of
        Blue -> ..
        DEFAULT -> [ case y of ... ]

If we inline h into f, the default case of the inlined h can't happen.
If we don't notice this, we may end up filtering out *all* the cases
of the inner case y, which give us nowhere to go!


\begin{code}
prepareAlts :: OutExpr          -- Scrutinee
            -> InId             -- Case binder
            -> [InAlt]
            -> SimplM ([InAlt],         -- Better alternatives
                        [AltCon])       -- These cases are handled

prepareAlts scrut case_bndr alts
  = let
        (alts_wo_default, maybe_deflt) = findDefault alts

        impossible_cons = case scrut of
                            Var v -> otherCons (idUnfolding v)
                            other -> []

        -- Filter out alternatives that can't possibly match
        better_alts | null impossible_cons = alts_wo_default
                    | otherwise            = [alt | alt@(con,_,_) <- alts_wo_default, 
                                                    not (con `elem` impossible_cons)]

        -- "handled_cons" are handled either by the context, 
        -- or by a branch in this case expression
        -- (Don't add DEFAULT to the handled_cons!!)
        handled_cons = impossible_cons ++ [con | (con,_,_) <- better_alts]
    in
        -- Filter out the default, if it can't happen,
        -- or replace it with "proper" alternative if there
        -- is only one constructor left
    prepareDefault case_bndr handled_cons maybe_deflt   `thenSmpl` \ deflt_alt ->

    returnSmpl (deflt_alt ++ better_alts, handled_cons)

prepareDefault case_bndr handled_cons (Just rhs)
  | Just (tycon, inst_tys) <- splitTyConApp_maybe (idType case_bndr),
    isAlgTyCon tycon,           -- It's a data type, tuple, or unboxed tuples.  
    not (isNewTyCon tycon),     -- We can have a newtype, if we are just doing an eval:
                                --      case x of { DEFAULT -> e }
                                -- and we don't want to fill in a default for them!
    Just all_cons <- tyConDataCons_maybe tycon,
    let handled_data_cons = [data_con | DataAlt data_con <- handled_cons],
    let missing_cons      = [con | con <- all_cons, 
                                   not (con `elem` handled_data_cons)]
  = case missing_cons of
        []          -> returnSmpl []    -- Eliminate the default alternative
                                        -- if it can't match

        [con]       ->  -- It matches exactly one constructor, so fill it in
                       tick (FillInCaseDefault case_bndr)       `thenSmpl_`
                       mk_args con inst_tys                     `thenSmpl` \ args ->
                       returnSmpl [(DataAlt con, args, rhs)]

        two_or_more -> returnSmpl [(DEFAULT, [], rhs)]

  | otherwise
  = returnSmpl [(DEFAULT, [], rhs)]

prepareDefault case_bndr handled_cons Nothing
  = returnSmpl []

mk_args missing_con inst_tys
  = getUniquesSmpl              `thenSmpl` \ tv_uniqs ->
    getUniquesSmpl              `thenSmpl` \ id_uniqs ->
    let
        (_,_,ex_tyvars,_,_,_) = dataConSig missing_con
        ex_tyvars'  = zipWith mk tv_uniqs ex_tyvars
        mk uniq tv  = mkSysTyVar uniq (tyVarKind tv)
        arg_tys     = dataConArgTys missing_con (inst_tys ++ mkTyVarTys ex_tyvars')
        arg_ids     = zipWith (mkSysLocal FSLIT("a")) id_uniqs arg_tys
    in 
    returnSmpl (ex_tyvars' ++ arg_ids)
\end{code}


%************************************************************************
%*                                                                      *
\subsection{Case absorption and identity-case elimination}
%*                                                                      *
%************************************************************************

mkCase puts a case expression back together, trying various transformations first.

\begin{code}
mkCase :: OutExpr -> OutId -> [OutAlt] -> SimplM OutExpr

mkCase scrut case_bndr alts
  = mkAlts scrut case_bndr alts `thenSmpl` \ better_alts ->
    mkCase1 scrut case_bndr better_alts
\end{code}


mkAlts tries these things:

1.  If several alternatives are identical, merge them into
    a single DEFAULT alternative.  I've occasionally seen this 
    making a big difference:

        case e of               =====>     case e of
          C _ -> f x                         D v -> ....v....
          D v -> ....v....                   DEFAULT -> f x
          DEFAULT -> f x

   The point is that we merge common RHSs, at least for the DEFAULT case.
   [One could do something more elaborate but I've never seen it needed.]
   To avoid an expensive test, we just merge branches equal to the *first*
   alternative; this picks up the common cases
        a) all branches equal
        b) some branches equal to the DEFAULT (which occurs first)

2.  Case merging:
       case e of b {             ==>   case e of b {
         p1 -> rhs1                      p1 -> rhs1
         ...                             ...
         pm -> rhsm                      pm -> rhsm
         _  -> case b of b' {            pn -> let b'=b in rhsn
                     pn -> rhsn          ...
                     ...                 po -> let b'=b in rhso
                     po -> rhso          _  -> let b'=b in rhsd
                     _  -> rhsd
       }  
    
    which merges two cases in one case when -- the default alternative of
    the outer case scrutises the same variable as the outer case This
    transformation is called Case Merging.  It avoids that the same
    variable is scrutinised multiple times.


The case where transformation (1) showed up was like this (lib/std/PrelCError.lhs):

        x | p `is` 1 -> e1
          | p `is` 2 -> e2
        ...etc...

where @is@ was something like
        
        p `is` n = p /= (-1) && p == n

This gave rise to a horrible sequence of cases

        case p of
          (-1) -> $j p
          1    -> e1
          DEFAULT -> $j p

and similarly in cascade for all the join points!



\begin{code}
--------------------------------------------------
--      1. Merge identical branches
--------------------------------------------------
mkAlts scrut case_bndr alts@((con1,bndrs1,rhs1) : con_alts)
  | all isDeadBinder bndrs1,                    -- Remember the default 
    length filtered_alts < length con_alts      -- alternative comes first
  = tick (AltMerge case_bndr)                   `thenSmpl_`
    returnSmpl better_alts
  where
    filtered_alts        = filter keep con_alts
    keep (con,bndrs,rhs) = not (all isDeadBinder bndrs && rhs `cheapEqExpr` rhs1)
    better_alts          = (DEFAULT, [], rhs1) : filtered_alts


--------------------------------------------------
--      2.  Merge nested cases
--------------------------------------------------

mkAlts scrut outer_bndr outer_alts
  | opt_SimplCaseMerge,
    (outer_alts_without_deflt, maybe_outer_deflt)   <- findDefault outer_alts,
    Just (Case (Var scrut_var) inner_bndr inner_alts) <- maybe_outer_deflt,
    scruting_same_var scrut_var

  = let     --  Eliminate any inner alts which are shadowed by the outer ones
        outer_cons = [con | (con,_,_) <- outer_alts_without_deflt]
    
        munged_inner_alts = [ (con, args, munge_rhs rhs) 
                            | (con, args, rhs) <- inner_alts, 
                               not (con `elem` outer_cons)      -- Eliminate shadowed inner alts
                            ]
        munge_rhs rhs = bindCaseBndr inner_bndr (Var outer_bndr) rhs
    
        (inner_con_alts, maybe_inner_default) = findDefault munged_inner_alts

        new_alts = add_default maybe_inner_default
                               (outer_alts_without_deflt ++ inner_con_alts)
    in
    tick (CaseMerge outer_bndr)                         `thenSmpl_`
    returnSmpl new_alts
        -- Warning: don't call mkAlts recursively!
        -- Firstly, there's no point, because inner alts have already had
        -- mkCase applied to them, so they won't have a case in their default
        -- Secondly, if you do, you get an infinite loop, because the bindCaseBndr
        -- in munge_rhs may put a case into the DEFAULT branch!
  where
        -- We are scrutinising the same variable if it's
        -- the outer case-binder, or if the outer case scrutinises a variable
        -- (and it's the same).  Testing both allows us not to replace the
        -- outer scrut-var with the outer case-binder (Simplify.simplCaseBinder).
    scruting_same_var = case scrut of
                          Var outer_scrut -> \ v -> v == outer_bndr || v == outer_scrut
                          other           -> \ v -> v == outer_bndr

    add_default (Just rhs) alts = (DEFAULT,[],rhs) : alts
    add_default Nothing    alts = alts


--------------------------------------------------
--      Catch-all
--------------------------------------------------

mkAlts scrut case_bndr other_alts = returnSmpl other_alts
\end{code}



=================================================================================

mkCase1 tries these things

1.  Eliminate the case altogether if possible

2.  Case-identity:

        case e of               ===> e
                True  -> True;
                False -> False

    and similar friends.


Start with a simple situation:

        case x# of      ===>   e[x#/y#]
          y# -> e

(when x#, y# are of primitive type, of course).  We can't (in general)
do this for algebraic cases, because we might turn bottom into
non-bottom!

Actually, we generalise this idea to look for a case where we're
scrutinising a variable, and we know that only the default case can
match.  For example:
\begin{verbatim}
        case x of
          0#    -> ...
          other -> ...(case x of
                         0#    -> ...
                         other -> ...) ...
\end{code}
Here the inner case can be eliminated.  This really only shows up in
eliminating error-checking code.

We also make sure that we deal with this very common case:

        case e of 
          x -> ...x...

Here we are using the case as a strict let; if x is used only once
then we want to inline it.  We have to be careful that this doesn't 
make the program terminate when it would have diverged before, so we
check that 
        - x is used strictly, or
        - e is already evaluated (it may so if e is a variable)

Lastly, we generalise the transformation to handle this:

        case e of       ===> r
           True  -> r
           False -> r

We only do this for very cheaply compared r's (constructors, literals
and variables).  If pedantic bottoms is on, we only do it when the
scrutinee is a PrimOp which can't fail.

We do it *here*, looking at un-simplified alternatives, because we
have to check that r doesn't mention the variables bound by the
pattern in each alternative, so the binder-info is rather useful.

So the case-elimination algorithm is:

        1. Eliminate alternatives which can't match

        2. Check whether all the remaining alternatives
                (a) do not mention in their rhs any of the variables bound in their pattern
           and  (b) have equal rhss

        3. Check we can safely ditch the case:
                   * PedanticBottoms is off,
                or * the scrutinee is an already-evaluated variable
                or * the scrutinee is a primop which is ok for speculation
                        -- ie we want to preserve divide-by-zero errors, and
                        -- calls to error itself!

                or * [Prim cases] the scrutinee is a primitive variable

                or * [Alg cases] the scrutinee is a variable and
                     either * the rhs is the same variable
                        (eg case x of C a b -> x  ===>   x)
                     or     * there is only one alternative, the default alternative,
                                and the binder is used strictly in its scope.
                                [NB this is helped by the "use default binder where
                                 possible" transformation; see below.]


If so, then we can replace the case with one of the rhss.

Further notes about case elimination
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
Consider:       test :: Integer -> IO ()
                test = print

Turns out that this compiles to:
    Print.test
      = \ eta :: Integer
          eta1 :: State# RealWorld ->
          case PrelNum.< eta PrelNum.zeroInteger of wild { __DEFAULT ->
          case hPutStr stdout
                 (PrelNum.jtos eta ($w[] @ Char))
                 eta1
          of wild1 { (# new_s, a4 #) -> PrelIO.lvl23 new_s  }}

Notice the strange '<' which has no effect at all. This is a funny one.  
It started like this:

f x y = if x < 0 then jtos x
          else if y==0 then "" else jtos x

At a particular call site we have (f v 1).  So we inline to get

        if v < 0 then jtos x 
        else if 1==0 then "" else jtos x

Now simplify the 1==0 conditional:

        if v<0 then jtos v else jtos v

Now common-up the two branches of the case:

        case (v<0) of DEFAULT -> jtos v

Why don't we drop the case?  Because it's strict in v.  It's technically
wrong to drop even unnecessary evaluations, and in practice they
may be a result of 'seq' so we *definitely* don't want to drop those.
I don't really know how to improve this situation.


\begin{code}
--------------------------------------------------
--      1. Eliminate the case altogether if poss
--------------------------------------------------

mkCase1 scrut case_bndr [(con,bndrs,rhs)]
  -- See if we can get rid of the case altogether
  -- See the extensive notes on case-elimination above
  -- mkCase made sure that if all the alternatives are equal, 
  -- then there is now only one (DEFAULT) rhs
 |  all isDeadBinder bndrs,

        -- Check that the scrutinee can be let-bound instead of case-bound
    exprOkForSpeculation scrut
                -- OK not to evaluate it
                -- This includes things like (==# a# b#)::Bool
                -- so that we simplify 
                --      case ==# a# b# of { True -> x; False -> x }
                -- to just
                --      x
                -- This particular example shows up in default methods for
                -- comparision operations (e.g. in (>=) for Int.Int32)
        || exprIsValue scrut                    -- It's already evaluated
        || var_demanded_later scrut             -- It'll be demanded later

--      || not opt_SimplPedanticBottoms)        -- Or we don't care!
--      We used to allow improving termination by discarding cases, unless -fpedantic-bottoms was on,
--      but that breaks badly for the dataToTag# primop, which relies on a case to evaluate
--      its argument:  case x of { y -> dataToTag# y }
--      Here we must *not* discard the case, because dataToTag# just fetches the tag from
--      the info pointer.  So we'll be pedantic all the time, and see if that gives any
--      other problems
--      Also we don't want to discard 'seq's
  = tick (CaseElim case_bndr)                   `thenSmpl_` 
    returnSmpl (bindCaseBndr case_bndr scrut rhs)

  where
        -- The case binder is going to be evaluated later, 
        -- and the scrutinee is a simple variable
    var_demanded_later (Var v) = isStrictDmd (idNewDemandInfo case_bndr)
    var_demanded_later other   = False


--------------------------------------------------
--      2. Identity case
--------------------------------------------------

#ifdef DEBUG
mkCase1 scrut case_bndr []
  = pprTrace "mkCase1: null alts" (ppr case_bndr <+> ppr scrut) $
    returnSmpl scrut
#endif

mkCase1 scrut case_bndr alts    -- Identity case
  | all identity_alt alts
  = tick (CaseIdentity case_bndr)               `thenSmpl_`
    returnSmpl (re_note scrut)
  where
    identity_alt (con, args, rhs) = de_note rhs `cheapEqExpr` identity_rhs con args

    identity_rhs (DataAlt con) args = mkConApp con (arg_tys ++ map varToCoreExpr args)
    identity_rhs (LitAlt lit)  _    = Lit lit
    identity_rhs DEFAULT       _    = Var case_bndr

    arg_tys = map Type (tyConAppArgs (idType case_bndr))

        -- We've seen this:
        --      case coerce T e of x { _ -> coerce T' x }
        -- And we definitely want to eliminate this case!
        -- So we throw away notes from the RHS, and reconstruct
        -- (at least an approximation) at the other end
    de_note (Note _ e) = de_note e
    de_note e          = e

        -- re_note wraps a coerce if it might be necessary
    re_note scrut = case head alts of
                        (_,_,rhs1@(Note _ _)) -> mkCoerce (exprType rhs1) (idType case_bndr) scrut
                        other                 -> scrut


--------------------------------------------------
--      Catch-all
--------------------------------------------------
mkCase1 scrut bndr alts = returnSmpl (Case scrut bndr alts)
\end{code}


When adding auxiliary bindings for the case binder, it's worth checking if
its dead, because it often is, and occasionally these mkCase transformations
cascade rather nicely.

\begin{code}
bindCaseBndr bndr rhs body
  | isDeadBinder bndr = body
  | otherwise         = bindNonRec bndr rhs body
\end{code}