Whitespace only in compiler/simplCore/CSE.lhs

1 files changed, 121 insertions, 130 deletions

diff --git a/compiler/simplCore/CSE.lhs b/compiler/simplCore/CSE.lhs
index 8bd15864c7..2f92708de2 100644
--- a/compiler/simplCore/CSE.lhs
+++ b/compiler/simplCore/CSE.lhs
@@ -4,16 +4,7 @@
 \section{Common subexpression}
 
 \begin{code}
-{-# OPTIONS -fno-warn-tabs #-}
--- The above warning supression flag is a temporary kludge.
--- While working on this module you are encouraged to remove it and
--- detab the module (please do the detabbing in a separate patch). See
---     http://hackage.haskell.org/trac/ghc/wiki/Commentary/CodingStyle#TabsvsSpaces
--- for details
-
-module CSE (
-	cseProgram
-    ) where
+module CSE (cseProgram) where
 
 #include "HsVersions.h"
 
@@ -26,8 +17,8 @@ module CSE (
 -- NB: when you remove this, also delete hashExpr from CoreUtils
 #ifdef OLD_CSENV_REP
 import CoreUtils        ( exprIsBig, hashExpr, eqExpr )
-import StaticFlags	( opt_PprStyle_Debug )
-import Util		( lengthExceeds )
+import StaticFlags      ( opt_PprStyle_Debug )
+import Util             ( lengthExceeds )
 import UniqFM
 import FastString
 #else
@@ -35,36 +26,36 @@ import TrieMap
 #endif
 
 import CoreSubst
-import Var		( Var )
-import Id		( Id, idType, idInlineActivation, zapIdOccInfo )
-import CoreUtils	( mkAltExpr
+import Var              ( Var )
+import Id               ( Id, idType, idInlineActivation, zapIdOccInfo )
+import CoreUtils        ( mkAltExpr
                         , exprIsTrivial)
-import Type		( tyConAppArgs )
+import Type             ( tyConAppArgs )
 import CoreSyn
 import Outputable
-import BasicTypes	( isAlwaysActive )
+import BasicTypes       ( isAlwaysActive )
 
 import Data.List
 \end{code}
 
 
-			Simple common sub-expression
-			~~~~~~~~~~~~~~~~~~~~~~~~~~~~
+                        Simple common sub-expression
+                        ~~~~~~~~~~~~~~~~~~~~~~~~~~~~
 When we see
-	x1 = C a b
-	x2 = C x1 b
+        x1 = C a b
+        x2 = C x1 b
 we build up a reverse mapping:   C a b  -> x1
-				 C x1 b -> x2
+                                 C x1 b -> x2
 and apply that to the rest of the program.
 
 When we then see
-	y1 = C a b
-	y2 = C y1 b
+        y1 = C a b
+        y2 = C y1 b
 we replace the C a b with x1.  But then we *dont* want to
 add   x1 -> y1  to the mapping.  Rather, we want the reverse, y1 -> x1
 so that a subsequent binding
-	y2 = C y1 b
-will get transformed to C x1 b, and then to x2.  
+        y2 = C y1 b
+will get transformed to C x1 b, and then to x2.
 
 So we carry an extra var->var substitution which we apply *before* looking up in the
 reverse mapping.
@@ -74,9 +65,9 @@ Note [Shadowing]
 ~~~~~~~~~~~~~~~~
 We have to be careful about shadowing.
 For example, consider
-	f = \x -> let y = x+x in
-	              h = \x -> x+x
-	          in ...
+        f = \x -> let y = x+x in
+                      h = \x -> x+x
+                  in ...
 
 Here we must *not* do CSE on the inner x+x!  The simplifier used to guarantee no
 shadowing, but it doesn't any more (it proved too hard), so we clone as we go.
@@ -86,9 +77,9 @@ Note [Case binders 1]
 ~~~~~~~~~~~~~~~~~~~~~~
 Consider
 
-	f = \x -> case x of wild { 
-			(a:as) -> case a of wild1 {
-				    (p,q) -> ...(wild1:as)...
+        f = \x -> case x of wild {
+                        (a:as) -> case a of wild1 {
+                                    (p,q) -> ...(wild1:as)...
 
 Here, (wild1:as) is morally the same as (a:as) and hence equal to wild.
 But that's not quite obvious.  In general we want to keep it as (wild1:as),
@@ -101,44 +92,44 @@ to try to replaces uses of 'a' with uses of 'wild1'
 Note [Case binders 2]
 ~~~~~~~~~~~~~~~~~~~~~~
 Consider
-	case (h x) of y -> ...(h x)...
+        case (h x) of y -> ...(h x)...
 
 We'd like to replace (h x) in the alternative, by y.  But because of
 the preceding [Note: case binders 1], we only want to add the mapping
-	scrutinee -> case binder
+        scrutinee -> case binder
 to the reverse CSE mapping if the scrutinee is a non-trivial expression.
 (If the scrutinee is a simple variable we want to add the mapping
-	case binder -> scrutinee 
+        case binder -> scrutinee
 to the substitution
 
 Note [CSE for INLINE and NOINLINE]
 ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
 We are careful to do no CSE inside functions that the user has marked as
-INLINE or NOINLINE.  In terms of Core, that means 
+INLINE or NOINLINE.  In terms of Core, that means
 
-	a) we do not do CSE inside an InlineRule
+        a) we do not do CSE inside an InlineRule
 
-	b) we do not do CSE on the RHS of a binding b=e
-	   unless b's InlinePragma is AlwaysActive
+        b) we do not do CSE on the RHS of a binding b=e
+           unless b's InlinePragma is AlwaysActive
 
 Here's why (examples from Roman Leshchinskiy).  Consider
 
-	yes :: Int
-	{-# NOINLINE yes #-}
-	yes = undefined
+        yes :: Int
+        {-# NOINLINE yes #-}
+        yes = undefined
 
-	no :: Int
-	{-# NOINLINE no #-}
-	no = undefined
+        no :: Int
+        {-# NOINLINE no #-}
+        no = undefined
 
-	foo :: Int -> Int -> Int
-	{-# NOINLINE foo #-}
-	foo m n = n
+        foo :: Int -> Int -> Int
+        {-# NOINLINE foo #-}
+        foo m n = n
 
-	{-# RULES "foo/no" foo no = id #-}
+        {-# RULES "foo/no" foo no = id #-}
 
-	bar :: Int -> Int
-	bar = foo yes
+        bar :: Int -> Int
+        bar = foo yes
 
 We do not expect the rule to fire.  But if we do CSE, then we get
 yes=no, and the rule does fire.  Worse, whether we get yes=no or
@@ -147,26 +138,26 @@ no=yes depends on the order of the definitions.
 In general, CSE should probably never touch things with INLINE pragmas
 as this could lead to surprising results.  Consider
 
-	{-# INLINE foo #-}
-	foo = <rhs>
+        {-# INLINE foo #-}
+        foo = <rhs>
 
-	{-# NOINLINE bar #-}
-	bar = <rhs>	-- Same rhs as foo
+        {-# NOINLINE bar #-}
+        bar = <rhs>     -- Same rhs as foo
 
 If CSE produces
-	foo = bar
+        foo = bar
 then foo will never be inlined (when it should be); but if it produces
-	bar = foo
+        bar = foo
 bar will be inlined (when it should not be). Even if we remove INLINE foo,
 we'd still like foo to be inlined if rhs is small. This won't happen
 with foo = bar.
 
 Not CSE-ing inside INLINE also solves an annoying bug in CSE. Consider
 a worker/wrapper, in which the worker has turned into a single variable:
-	$wf = h
-	f = \x -> ...$wf...
+        $wf = h
+        f = \x -> ...$wf...
 Now CSE may transform to
-	f = \x -> ...h...
+        f = \x -> ...h...
 But the WorkerInfo for f still says $wf, which is now dead!  This won't
 happen now that we don't look inside INLINEs (which wrappers are).
 
@@ -178,9 +169,9 @@ Then we can CSE the inner (f x) to y.  In fact 'case' is like a strict
 let-binding, and we can use cseRhs for dealing with the scrutinee.
 
 %************************************************************************
-%*									*
+%*                                                                      *
 \section{Common subexpression}
-%*									*
+%*                                                                      *
 %************************************************************************
 
 \begin{code}
@@ -190,12 +181,12 @@ cseProgram binds = cseBinds emptyCSEnv binds
 cseBinds :: CSEnv -> [CoreBind] -> [CoreBind]
 cseBinds _   []     = []
 cseBinds env (b:bs) = (b':bs')
-		    where
-		      (env1, b') = cseBind  env  b
-		      bs'        = cseBinds env1 bs
+                    where
+                      (env1, b') = cseBind  env  b
+                      bs'        = cseBinds env1 bs
 
 cseBind :: CSEnv -> CoreBind -> (CSEnv, CoreBind)
-cseBind env (NonRec b e) 
+cseBind env (NonRec b e)
   = (env2, NonRec b' e')
   where
     (env1, b') = addBinder env b
@@ -211,16 +202,16 @@ cseBind env (Rec pairs)
 cseRhs :: CSEnv -> (OutBndr, InExpr) -> (CSEnv, OutExpr)
 cseRhs env (id',rhs)
   = case lookupCSEnv env rhs' of
-	Just other_expr     -> (env, 			         other_expr)
-	Nothing             -> (addCSEnvItem env rhs' (Var id'), rhs')
+        Just other_expr     -> (env,                             other_expr)
+        Nothing             -> (addCSEnvItem env rhs' (Var id'), rhs')
   where
     rhs' | isAlwaysActive (idInlineActivation id') = cseExpr env rhs
-	 | otherwise			           = rhs
-		-- See Note [CSE for INLINE and NOINLINE]
+         | otherwise                               = rhs
+                -- See Note [CSE for INLINE and NOINLINE]
 
 tryForCSE :: CSEnv -> InExpr -> OutExpr
 tryForCSE env expr
-  | exprIsTrivial expr'                   = expr'	-- No point
+  | exprIsTrivial expr'                   = expr'       -- No point
   | Just smaller <- lookupCSEnv env expr' = smaller
   | otherwise                             = expr'
   where
@@ -230,24 +221,24 @@ cseExpr :: CSEnv -> InExpr -> OutExpr
 cseExpr env (Type t)               = Type (substTy (csEnvSubst env) t)
 cseExpr env (Coercion c)           = Coercion (substCo (csEnvSubst env) c)
 cseExpr _   (Lit lit)              = Lit lit
-cseExpr env (Var v)		   = lookupSubst env v
-cseExpr env (App f a)        	   = App (cseExpr env f) (tryForCSE env a)
+cseExpr env (Var v)                = lookupSubst env v
+cseExpr env (App f a)              = App (cseExpr env f) (tryForCSE env a)
 cseExpr env (Tick t e)             = Tick t (cseExpr env e)
 cseExpr env (Cast e co)            = Cast (cseExpr env e) (substCo (csEnvSubst env) co)
-cseExpr env (Lam b e)	     	   = let (env', b') = addBinder env b
-				     in Lam b' (cseExpr env' e)
-cseExpr env (Let bind e)    	   = let (env', bind') = cseBind env bind
-				     in Let bind' (cseExpr env' e)
+cseExpr env (Lam b e)              = let (env', b') = addBinder env b
+                                     in Lam b' (cseExpr env' e)
+cseExpr env (Let bind e)           = let (env', bind') = cseBind env bind
+                                     in Let bind' (cseExpr env' e)
 cseExpr env (Case scrut bndr ty alts) = Case scrut' bndr'' ty alts'
-				   where
-                                     alts' = cseAlts env2 scrut' bndr bndr'' alts
-				     (env1, bndr') = addBinder env bndr
-				     bndr'' = zapIdOccInfo bndr'
-					-- The swizzling from Note [Case binders 2] may
-					-- cause a dead case binder to be alive, so we
-					-- play safe here and bring them all to life
-                                     (env2, scrut') = cseRhs env1 (bndr'', scrut)
-                                        -- Note [CSE for case expressions]
+                          where
+                                alts' = cseAlts env2 scrut' bndr bndr'' alts
+                                (env1, bndr') = addBinder env bndr
+                                bndr'' = zapIdOccInfo bndr'
+                                -- The swizzling from Note [Case binders 2] may
+                                -- cause a dead case binder to be alive, so we
+                                -- play safe here and bring them all to life
+                                (env2, scrut') = cseRhs env1 (bndr'', scrut)
+                                -- Note [CSE for case expressions]
 
 cseAlts :: CSEnv -> OutExpr -> InBndr -> InBndr -> [InAlt] -> [OutAlt]
 
@@ -255,47 +246,47 @@ cseAlts env scrut' bndr bndr' alts
   = map cse_alt alts
   where
     (con_target, alt_env)
-	= case scrut' of
-	    Var v' -> (v',     extendCSSubst env bndr v')	-- See Note [Case binders 1]
-								-- map: bndr -> v'
+        = case scrut' of
+            Var v' -> (v',     extendCSSubst env bndr v')       -- See Note [Case binders 1]
+                                                                -- map: bndr -> v'
 
-	    _      ->  (bndr', extendCSEnv env scrut' (Var  bndr')) -- See Note [Case binders 2]
-								    -- map: scrut' -> bndr'
+            _      ->  (bndr', extendCSEnv env scrut' (Var  bndr')) -- See Note [Case binders 2]
+                                                                    -- map: scrut' -> bndr'
 
     arg_tys = tyConAppArgs (idType bndr)
 
     cse_alt (DataAlt con, args, rhs)
-	| not (null args)
-		-- Don't try CSE if there are no args; it just increases the number
-		-- of live vars.  E.g.
-		--	case x of { True -> ....True.... }
-		-- Don't replace True by x!  
-		-- Hence the 'null args', which also deal with literals and DEFAULT
-	= (DataAlt con, args', tryForCSE new_env rhs)
-	where
-	  (env', args') = addBinders alt_env args
-	  new_env       = extendCSEnv env' (mkAltExpr (DataAlt con) args' arg_tys)
-					   (Var con_target)
+        | not (null args)
+                -- Don't try CSE if there are no args; it just increases the number
+                -- of live vars.  E.g.
+                --      case x of { True -> ....True.... }
+                -- Don't replace True by x!
+                -- Hence the 'null args', which also deal with literals and DEFAULT
+        = (DataAlt con, args', tryForCSE new_env rhs)
+        where
+          (env', args') = addBinders alt_env args
+          new_env       = extendCSEnv env' (mkAltExpr (DataAlt con) args' arg_tys)
+                                           (Var con_target)
 
     cse_alt (con, args, rhs)
-	= (con, args', tryForCSE env' rhs)
-	where
-	  (env', args') = addBinders alt_env args
+        = (con, args', tryForCSE env' rhs)
+        where
+          (env', args') = addBinders alt_env args
 \end{code}
 
 
 %************************************************************************
-%*									*
+%*                                                                      *
 \section{The CSE envt}
-%*									*
+%*                                                                      *
 %************************************************************************
 
 \begin{code}
-type InExpr  = CoreExpr		-- Pre-cloning
+type InExpr  = CoreExpr         -- Pre-cloning
 type InBndr  = CoreBndr
 type InAlt   = CoreAlt
 
-type OutExpr  = CoreExpr	-- Post-cloning
+type OutExpr  = CoreExpr        -- Post-cloning
 type OutBndr  = CoreBndr
 type OutAlt   = CoreAlt
 
@@ -304,10 +295,10 @@ type OutAlt   = CoreAlt
 data CSEnv  = CS { cs_map    :: CSEMap
                  , cs_subst  :: Subst }
 
-type CSEMap = UniqFM [(OutExpr, OutExpr)]	-- This is the reverse mapping
-	-- It maps the hash-code of an expression e to list of (e,e') pairs
-	-- This means that it's good to replace e by e'
-	-- INVARIANT: The expr in the range has already been CSE'd
+type CSEMap = UniqFM [(OutExpr, OutExpr)]       -- This is the reverse mapping
+        -- It maps the hash-code of an expression e to list of (e,e') pairs
+        -- This means that it's good to replace e by e'
+        -- INVARIANT: The expr in the range has already been CSE'd
 
 emptyCSEnv :: CSEnv
 emptyCSEnv = CS { cs_map = emptyUFM, cs_subst = emptySubst }
@@ -315,24 +306,24 @@ emptyCSEnv = CS { cs_map = emptyUFM, cs_subst = emptySubst }
 lookupCSEnv :: CSEnv -> OutExpr -> Maybe OutExpr
 lookupCSEnv (CS { cs_map = oldmap, cs_subst = sub}) expr
   = case lookupUFM oldmap (hashExpr expr) of
-             	Nothing -> Nothing
-         	Just pairs -> lookup_list pairs
+                Nothing -> Nothing
+                Just pairs -> lookup_list pairs
   where
     in_scope = substInScope sub
 
   -- In this lookup we use full expression equality
   -- Reason: when expressions differ we generally find out quickly
   --         but I found that cheapEqExpr was saying (\x.x) /= (\y.y),
-  -- 	     and this kind of thing happened in real programs
+  --         and this kind of thing happened in real programs
     lookup_list :: [(OutExpr,OutExpr)] -> Maybe OutExpr
-    lookup_list ((e,e'):es) 
+    lookup_list ((e,e'):es)
       | eqExpr in_scope e expr = Just e'
-      | otherwise	                 = lookup_list es
+      | otherwise                        = lookup_list es
     lookup_list []                       = Nothing
 
 addCSEnvItem :: CSEnv -> OutExpr -> OutExpr -> CSEnv
 addCSEnvItem env expr expr' | exprIsBig expr = env
-			    | otherwise      = extendCSEnv env expr expr'
+                            | otherwise      = extendCSEnv env expr expr'
    -- We don't try to CSE big expressions, because they are expensive to compare
    -- (and are unlikely to be the same anyway)
 
@@ -341,13 +332,13 @@ extendCSEnv cse@(CS { cs_map = oldmap }) expr expr'
   = cse { cs_map = addToUFM_C combine oldmap hash [(expr, expr')] }
   where
     hash = hashExpr expr
-    combine old new 
-	= WARN( result `lengthExceeds` 4, short_msg $$ nest 2 long_msg ) result
-	where
-	  result = new ++ old
-	  short_msg = ptext (sLit "extendCSEnv: long list, length") <+> int (length result)
-	  long_msg | opt_PprStyle_Debug = (text "hash code" <+> text (show hash)) $$ ppr result 
-		   | otherwise	        = empty
+    combine old new
+        = WARN( result `lengthExceeds` 4, short_msg $$ nest 2 long_msg ) result
+        where
+          result = new ++ old
+          short_msg = ptext (sLit "extendCSEnv: long list, length") <+> int (length result)
+          long_msg | opt_PprStyle_Debug = (text "hash code" <+> text (show hash)) $$ ppr result
+                   | otherwise          = empty
 
 #else
 ------------ NEW ----------------
@@ -359,7 +350,7 @@ emptyCSEnv :: CSEnv
 emptyCSEnv = CS { cs_map = emptyCoreMap, cs_subst = emptySubst }
 
 lookupCSEnv :: CSEnv -> OutExpr -> Maybe OutExpr
-lookupCSEnv (CS { cs_map = csmap }) expr 
+lookupCSEnv (CS { cs_map = csmap }) expr
   = case lookupCoreMap csmap expr of
       Just (_,e) -> Just e
       Nothing    -> Nothing
@@ -387,17 +378,17 @@ extendCSSubst :: CSEnv -> Id  -> Id -> CSEnv
 extendCSSubst cse x y = cse { cs_subst = extendIdSubst (cs_subst cse) x (Var y) }
 
 addBinder :: CSEnv -> Var -> (CSEnv, Var)
-addBinder cse v = (cse { cs_subst = sub' }, v') 
+addBinder cse v = (cse { cs_subst = sub' }, v')
                 where
                   (sub', v') = substBndr (cs_subst cse) v
 
 addBinders :: CSEnv -> [Var] -> (CSEnv, [Var])
-addBinders cse vs = (cse { cs_subst = sub' }, vs') 
+addBinders cse vs = (cse { cs_subst = sub' }, vs')
                 where
                   (sub', vs') = substBndrs (cs_subst cse) vs
 
 addRecBinders :: CSEnv -> [Id] -> (CSEnv, [Id])
-addRecBinders cse vs = (cse { cs_subst = sub' }, vs') 
+addRecBinders cse vs = (cse { cs_subst = sub' }, vs')
                 where
                   (sub', vs') = substRecBndrs (cs_subst cse) vs
 \end{code}