#include "HsVersions.h"
-import DynFlags ( DynFlags, DynFlag(..) )
-import Id ( Id, idName, idType, mkUserLocal,
- idInlinePragma, setInlinePragma )
+import Id ( Id, idName, idType, mkUserLocal, idCoreRules,
+ idInlineActivation, setInlineActivation, setIdUnfolding,
+ isLocalId, idArity, setIdArity )
import TcType ( Type, mkTyVarTy, tcSplitSigmaTy,
tyVarsOfTypes, tyVarsOfTheta, isClassPred,
tcCmpType, isUnLiftedType
)
import CoreSubst ( Subst, mkEmptySubst, extendTvSubstList, lookupIdSubst,
substBndr, substBndrs, substTy, substInScope,
- cloneIdBndr, cloneIdBndrs, cloneRecIdBndrs
+ cloneIdBndr, cloneIdBndrs, cloneRecIdBndrs,
+ extendIdSubst
)
+import CoreUnfold ( mkUnfolding )
+import SimplUtils ( interestingArg )
+import Var ( DictId )
import VarSet
import VarEnv
import CoreSyn
-import CoreUtils ( applyTypeToArgs, mkPiTypes )
+import Rules
+import CoreUtils ( exprIsTrivial, applyTypeToArgs, mkPiTypes )
import CoreFVs ( exprFreeVars, exprsFreeVars, idFreeVars )
-import CoreTidy ( tidyRules )
-import CoreLint ( showPass, endPass )
-import Rules ( addIdSpecialisations, mkLocalRule, lookupRule, emptyRuleBase, rulesOfBinds )
-import PprCore ( pprRules )
import UniqSupply ( UniqSupply,
UniqSM, initUs_,
MonadUnique(..)
import Name
import MkId ( voidArgId, realWorldPrimId )
import FiniteMap
-import Maybes ( catMaybes, maybeToBool )
-import ErrUtils ( dumpIfSet_dyn )
+import Maybes ( catMaybes, isJust )
import Bag
import Util
import Outputable
Still, this is no great hardship, because we intend to eliminate
overloading altogether anyway!
-
-
A note about non-tyvar dictionaries
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
Some Ids have types like
But it is simpler and more uniform to specialise wrt these dicts too;
and in future GHC is likely to support full fledged type signatures
like
- f ;: Eq [(a,b)] => ...
+ f :: Eq [(a,b)] => ...
%************************************************************************
%************************************************************************
\begin{code}
-specProgram :: DynFlags -> UniqSupply -> [CoreBind] -> IO [CoreBind]
-specProgram dflags us binds = do
-
- showPass dflags "Specialise"
-
- let binds' = initSM us (do (binds', uds') <- go binds
- return (dumpAllDictBinds uds' binds'))
-
- endPass dflags "Specialise" Opt_D_dump_spec binds'
-
- dumpIfSet_dyn dflags Opt_D_dump_rules "Top-level specialisations"
- (withPprStyle defaultUserStyle $
- pprRules (tidyRules emptyTidyEnv (rulesOfBinds binds')))
-
- return binds'
+specProgram :: UniqSupply -> [CoreBind] -> [CoreBind]
+specProgram us binds = initSM us (do (binds', uds') <- go binds
+ return (dumpAllDictBinds uds' binds'))
where
-- We need to start with a Subst that knows all the things
-- that are in scope, so that the substitution engine doesn't
specExpr :: Subst -> CoreExpr -> SpecM (CoreExpr, UsageDetails)
-- We carry a substitution down:
--- a) we must clone any binding that might flaot outwards,
+-- a) we must clone any binding that might float outwards,
-- to avoid name clashes
-- b) we carry a type substitution to use when analysing
-- the RHS of specialised bindings (no type-let!)
return (App fun' arg', uds_arg `plusUDs` uds_app)
go (Var f) args = case specVar subst f of
- Var f' -> return (Var f', mkCallUDs subst f' args)
+ Var f' -> return (Var f', mkCallUDs f' args)
e' -> return (e', emptyUDs) -- I don't expect this!
go other _ = specExpr subst other
add (NonRec b r, b_fvs) (prs, fvs) = ((b,r) : prs, b_fvs `unionVarSet` fvs)
add (Rec b_prs, b_fvs) (prs, fvs) = (b_prs ++ prs, b_fvs `unionVarSet` fvs)
+---------------------------
specBindItself :: Subst -> CoreBind -> CallDetails -> SpecM (CoreBind, UsageDetails)
-- specBindItself deals with the RHS, specialising it according
-- to the calls found in the body (if any)
-specBindItself rhs_subst (NonRec bndr rhs) call_info = do
- ((bndr',rhs'), spec_defns, spec_uds) <- specDefn rhs_subst call_info (bndr,rhs)
- let
- new_bind | null spec_defns = NonRec bndr' rhs'
- | otherwise = Rec ((bndr',rhs'):spec_defns)
+specBindItself rhs_subst (NonRec fn rhs) call_info
+ = do { (rhs', rhs_uds) <- specExpr rhs_subst rhs -- Do RHS of original fn
+ ; (fn', spec_defns, spec_uds) <- specDefn rhs_subst call_info fn rhs
+ ; if null spec_defns then
+ return (NonRec fn rhs', rhs_uds)
+ else
+ return (Rec ((fn',rhs') : spec_defns), rhs_uds `plusUDs` spec_uds) }
-- bndr' mentions the spec_defns in its SpecEnv
-- Not sure why we couln't just put the spec_defns first
- return (new_bind, spec_uds)
-
-specBindItself rhs_subst (Rec pairs) call_info = do
- stuff <- mapM (specDefn rhs_subst call_info) pairs
- let
- (pairs', spec_defns_s, spec_uds_s) = unzip3 stuff
- spec_defns = concat spec_defns_s
- spec_uds = plusUDList spec_uds_s
- new_bind = Rec (spec_defns ++ pairs')
- return (new_bind, spec_uds)
-
-
-specDefn :: Subst -- Subst to use for RHS
+
+specBindItself rhs_subst (Rec pairs) call_info
+ -- Note [Specialising a recursive group]
+ = do { let (bndrs,rhss) = unzip pairs
+ ; (rhss', rhs_uds) <- mapAndCombineSM (specExpr rhs_subst) rhss
+ ; let all_calls = call_info `unionCalls` calls rhs_uds
+ ; (bndrs1, spec_defns1, spec_uds1) <- specDefns rhs_subst all_calls pairs
+
+ ; if null spec_defns1 then -- Common case: no specialisation
+ return (Rec (bndrs `zip` rhss'), rhs_uds)
+ else do -- Specialisation occurred; do it again
+ { (bndrs2, spec_defns2, spec_uds2) <-
+ -- pprTrace "specB" (ppr bndrs $$ ppr rhs_uds) $
+ specDefns rhs_subst (calls spec_uds1) (bndrs1 `zip` rhss)
+
+ ; let all_defns = spec_defns1 ++ spec_defns2 ++ zip bndrs2 rhss'
+
+ ; return (Rec all_defns, rhs_uds `plusUDs` spec_uds1 `plusUDs` spec_uds2) } }
+
+
+---------------------------
+specDefns :: Subst
+ -> CallDetails -- Info on how it is used in its scope
+ -> [(Id,CoreExpr)] -- The things being bound and their un-processed RHS
+ -> SpecM ([Id], -- Original Ids with RULES added
+ [(Id,CoreExpr)], -- Extra, specialised bindings
+ UsageDetails) -- Stuff to fling upwards from the specialised versions
+
+-- Specialise a list of bindings (the contents of a Rec), but flowing usages
+-- upwards binding by binding. Example: { f = ...g ...; g = ...f .... }
+-- Then if the input CallDetails has a specialised call for 'g', whose specialisation
+-- in turn generates a specialised call for 'f', we catch that in this one sweep.
+-- But not vice versa (it's a fixpoint problem).
+
+specDefns _subst _call_info []
+ = return ([], [], emptyUDs)
+specDefns subst call_info ((bndr,rhs):pairs)
+ = do { (bndrs', spec_defns, spec_uds) <- specDefns subst call_info pairs
+ ; let all_calls = call_info `unionCalls` calls spec_uds
+ ; (bndr', spec_defns1, spec_uds1) <- specDefn subst all_calls bndr rhs
+ ; return (bndr' : bndrs',
+ spec_defns1 ++ spec_defns,
+ spec_uds1 `plusUDs` spec_uds) }
+
+---------------------------
+specDefn :: Subst
-> CallDetails -- Info on how it is used in its scope
- -> (Id, CoreExpr) -- The thing being bound and its un-processed RHS
- -> SpecM ((Id, CoreExpr), -- The thing and its processed RHS
- -- the Id may now have specialisations attached
+ -> Id -> CoreExpr -- The thing being bound and its un-processed RHS
+ -> SpecM (Id, -- Original Id with added RULES
[(Id,CoreExpr)], -- Extra, specialised bindings
- UsageDetails -- Stuff to fling upwards from the RHS and its
- ) -- specialised versions
+ UsageDetails) -- Stuff to fling upwards from the specialised versions
-specDefn subst calls (fn, rhs)
+specDefn subst calls fn rhs
-- The first case is the interesting one
| rhs_tyvars `lengthIs` n_tyvars -- Rhs of fn's defn has right number of big lambdas
&& rhs_ids `lengthAtLeast` n_dicts -- and enough dict args
-- && not (certainlyWillInline (idUnfolding fn)) -- And it's not small
-- See Note [Inline specialisation] for why we do not
--- switch off specialisation for inline functions = do
- = do
- -- Specialise the body of the function
- (rhs', rhs_uds) <- specExpr subst rhs
-
- -- Make a specialised version for each call in calls_for_me
- stuff <- mapM spec_call calls_for_me
- let
- (spec_defns, spec_uds, spec_rules) = unzip3 stuff
-
- fn' = addIdSpecialisations fn spec_rules
+-- switch off specialisation for inline functions
- return ((fn',rhs'),
- spec_defns,
- rhs_uds `plusUDs` plusUDList spec_uds)
+ = do { -- Make a specialised version for each call in calls_for_me
+ stuff <- mapM spec_call calls_for_me
+ ; let (spec_defns, spec_uds, spec_rules) = unzip3 (catMaybes stuff)
+ fn' = addIdSpecialisations fn spec_rules
+ ; return (fn', spec_defns, plusUDList spec_uds) }
| otherwise -- No calls or RHS doesn't fit our preconceptions
= WARN( notNull calls_for_me, ptext (sLit "Missed specialisation opportunity for") <+> ppr fn )
-- Note [Specialisation shape]
- (do { (rhs', rhs_uds) <- specExpr subst rhs
- ; return ((fn, rhs'), [], rhs_uds) })
+ return (fn, [], emptyUDs)
where
fn_type = idType fn
+ fn_arity = idArity fn
(tyvars, theta, _) = tcSplitSigmaTy fn_type
n_tyvars = length tyvars
n_dicts = length theta
- inline_prag = idInlinePragma fn
+ inline_act = idInlineActivation fn
-- It's important that we "see past" any INLINE pragma
-- else we'll fail to specialise an INLINE thing
(inline_rhs, rhs_inside) = dropInline rhs
(rhs_tyvars, rhs_ids, rhs_body) = collectTyAndValBinders rhs_inside
- rhs_dicts = take n_dicts rhs_ids
- body = mkLams (drop n_dicts rhs_ids) rhs_body
+ rhs_dict_ids = take n_dicts rhs_ids
+ body = mkLams (drop n_dicts rhs_ids) rhs_body
-- Glue back on the non-dict lambdas
calls_for_me = case lookupFM calls fn of
Nothing -> []
Just cs -> fmToList cs
+ already_covered :: [CoreExpr] -> Bool
+ already_covered args -- Note [Specialisations already covered]
+ = isJust (lookupRule (const True) (substInScope subst)
+ fn args (idCoreRules fn))
+
+ mk_ty_args :: [Maybe Type] -> [CoreExpr]
+ mk_ty_args call_ts = zipWithEqual "spec_call" mk_ty_arg rhs_tyvars call_ts
+ where
+ mk_ty_arg rhs_tyvar Nothing = Type (mkTyVarTy rhs_tyvar)
+ mk_ty_arg _ (Just ty) = Type ty
+
----------------------------------------------------------
-- Specialise to one particular call pattern
- spec_call :: (CallKey, ([DictExpr], VarSet)) -- Call instance
- -> SpecM ((Id,CoreExpr), -- Specialised definition
- UsageDetails, -- Usage details from specialised body
- CoreRule) -- Info for the Id's SpecEnv
+ spec_call :: (CallKey, ([DictExpr], VarSet)) -- Call instance
+ -> SpecM (Maybe ((Id,CoreExpr), -- Specialised definition
+ UsageDetails, -- Usage details from specialised body
+ CoreRule)) -- Info for the Id's SpecEnv
spec_call (CallKey call_ts, (call_ds, _))
- = ASSERT( call_ts `lengthIs` n_tyvars && call_ds `lengthIs` n_dicts ) do
- -- Calls are only recorded for properly-saturated applications
+ = ASSERT( call_ts `lengthIs` n_tyvars && call_ds `lengthIs` n_dicts )
- -- Suppose f's defn is f = /\ a b c d -> \ d1 d2 -> rhs
- -- Supppose the call is for f [Just t1, Nothing, Just t3, Nothing] [dx1, dx2]
+ -- Suppose f's defn is f = /\ a b c -> \ d1 d2 -> rhs
+ -- Supppose the call is for f [Just t1, Nothing, Just t3] [dx1, dx2]
-- Construct the new binding
- -- f1 = SUBST[a->t1,c->t3, d1->d1', d2->d2'] (/\ b d -> rhs)
+ -- f1 = SUBST[a->t1,c->t3, d1->d1', d2->d2'] (/\ b -> rhs)
-- PLUS the usage-details
-- { d1' = dx1; d2' = dx2 }
- -- where d1', d2' are cloned versions of d1,d2, with the type substitution applied.
+ -- where d1', d2' are cloned versions of d1,d2, with the type substitution
+ -- applied. These auxiliary bindings just avoid duplication of dx1, dx2
--
-- Note that the substitution is applied to the whole thing.
-- This is convenient, but just slightly fragile. Notably:
- -- * There had better be no name clashes in a/b/c/d
- --
- let
- -- poly_tyvars = [b,d] in the example above
+ -- * There had better be no name clashes in a/b/c
+ do { let
+ -- poly_tyvars = [b] in the example above
-- spec_tyvars = [a,c]
- -- ty_args = [t1,b,t3,d]
- poly_tyvars = [tv | (tv, Nothing) <- rhs_tyvars `zip` call_ts]
- spec_tyvars = [tv | (tv, Just _) <- rhs_tyvars `zip` call_ts]
- ty_args = zipWithEqual "spec_call" mk_ty_arg rhs_tyvars call_ts
- where
- mk_ty_arg rhs_tyvar Nothing = Type (mkTyVarTy rhs_tyvar)
- mk_ty_arg _ (Just ty) = Type ty
- rhs_subst = extendTvSubstList subst (spec_tyvars `zip` [ty | Just ty <- call_ts])
-
- (rhs_subst', rhs_dicts') <- cloneBinders rhs_subst rhs_dicts
- let
- inst_args = ty_args ++ map Var rhs_dicts'
-
- -- Figure out the type of the specialised function
- body_ty = applyTypeToArgs rhs fn_type inst_args
- (lam_args, app_args) -- Add a dummy argument if body_ty is unlifted
- | isUnLiftedType body_ty -- C.f. WwLib.mkWorkerArgs
- = (poly_tyvars ++ [voidArgId], poly_tyvars ++ [realWorldPrimId])
- | otherwise = (poly_tyvars, poly_tyvars)
- spec_id_ty = mkPiTypes lam_args body_ty
-
- spec_f <- newIdSM fn spec_id_ty
- (spec_rhs, rhs_uds) <- specExpr rhs_subst' (mkLams lam_args body)
- let
+ -- ty_args = [t1,b,t3]
+ poly_tyvars = [tv | (tv, Nothing) <- rhs_tyvars `zip` call_ts]
+ spec_tv_binds = [(tv,ty) | (tv, Just ty) <- rhs_tyvars `zip` call_ts]
+ spec_ty_args = map snd spec_tv_binds
+ ty_args = mk_ty_args call_ts
+ rhs_subst = extendTvSubstList subst spec_tv_binds
+
+ ; (rhs_subst1, inst_dict_ids) <- cloneDictBndrs rhs_subst rhs_dict_ids
+ -- Clone rhs_dicts, including instantiating their types
+
+ ; let (rhs_subst2, dx_binds) = bindAuxiliaryDicts rhs_subst1 $
+ (my_zipEqual rhs_dict_ids inst_dict_ids call_ds)
+ inst_args = ty_args ++ map Var inst_dict_ids
+
+ ; if already_covered inst_args then
+ return Nothing
+ else do
+ { -- Figure out the type of the specialised function
+ let body_ty = applyTypeToArgs rhs fn_type inst_args
+ (lam_args, app_args) -- Add a dummy argument if body_ty is unlifted
+ | isUnLiftedType body_ty -- C.f. WwLib.mkWorkerArgs
+ = (poly_tyvars ++ [voidArgId], poly_tyvars ++ [realWorldPrimId])
+ | otherwise = (poly_tyvars, poly_tyvars)
+ spec_id_ty = mkPiTypes lam_args body_ty
+
+ ; spec_f <- newSpecIdSM fn spec_id_ty
+ ; let spec_f_w_arity = setIdArity spec_f (max 0 (fn_arity - n_dicts))
+ -- Adding arity information just propagates it a bit faster
+ -- See Note [Arity decrease] in Simplify
+
+ ; (spec_rhs, rhs_uds) <- specExpr rhs_subst2 (mkLams lam_args body)
+ ; let
-- The rule to put in the function's specialisation is:
- -- forall b,d, d1',d2'. f t1 b t3 d d1' d2' = f1 b d
- spec_env_rule = mkLocalRule (mkFastString ("SPEC " ++ showSDoc (ppr fn)))
- inline_prag -- Note [Auto-specialisation and RULES]
- (idName fn)
- (poly_tyvars ++ rhs_dicts')
- inst_args
- (mkVarApps (Var spec_f) app_args)
+ -- forall b, d1',d2'. f t1 b t3 d1' d2' = f1 b
+ rule_name = mkFastString ("SPEC " ++ showSDoc (ppr fn <+> ppr spec_ty_args))
+ spec_env_rule = mkLocalRule
+ rule_name
+ inline_act -- Note [Auto-specialisation and RULES]
+ (idName fn)
+ (poly_tyvars ++ inst_dict_ids)
+ inst_args
+ (mkVarApps (Var spec_f_w_arity) app_args)
-- Add the { d1' = dx1; d2' = dx2 } usage stuff
- final_uds = foldr addDictBind rhs_uds (my_zipEqual "spec_call" rhs_dicts' call_ds)
-
- spec_pr | inline_rhs = (spec_f `setInlinePragma` inline_prag, Note InlineMe spec_rhs)
- | otherwise = (spec_f, spec_rhs)
+ final_uds = foldr addDictBind rhs_uds dx_binds
- return (spec_pr, final_uds, spec_env_rule)
+ spec_pr | inline_rhs = (spec_f_w_arity `setInlineActivation` inline_act, Note InlineMe spec_rhs)
+ | otherwise = (spec_f_w_arity, spec_rhs)
+ ; return (Just (spec_pr, final_uds, spec_env_rule)) } }
+ where
+ my_zipEqual xs ys zs
+ | debugIsOn && not (equalLength xs ys && equalLength ys zs)
+ = pprPanic "my_zipEqual" (vcat [ ppr xs, ppr ys
+ , ppr fn <+> ppr call_ts
+ , ppr (idType fn), ppr theta
+ , ppr n_dicts, ppr rhs_dict_ids
+ , ppr rhs])
+ | otherwise = zip3 xs ys zs
+
+bindAuxiliaryDicts
+ :: Subst
+ -> [(DictId,DictId,CoreExpr)] -- (orig_dict, inst_dict, dx)
+ -> (Subst, -- Substitute for all orig_dicts
+ [(DictId, CoreExpr)]) -- Auxiliary bindings
+-- Bind any dictionary arguments to fresh names, to preserve sharing
+-- Substitution already substitutes orig_dict -> inst_dict
+bindAuxiliaryDicts subst triples = go subst [] triples
+ where
+ go subst binds [] = (subst, binds)
+ go subst binds ((d, dx_id, dx) : pairs)
+ | exprIsTrivial dx = go (extendIdSubst subst d dx) binds pairs
+ -- No auxiliary binding necessary
+ | otherwise = go subst_w_unf ((dx_id,dx) : binds) pairs
where
- my_zipEqual doc xs ys
- | debugIsOn && not (equalLength xs ys)
- = pprPanic "my_zipEqual" (vcat
- [ ppr xs, ppr ys
- , ppr fn <+> ppr call_ts
- , ppr (idType fn), ppr theta
- , ppr n_dicts, ppr rhs_dicts
- , ppr rhs])
- | otherwise = zipEqual doc xs ys
+ dx_id1 = dx_id `setIdUnfolding` mkUnfolding False dx
+ subst_w_unf = extendIdSubst subst d (Var dx_id1)
+ -- Important! We're going to substitute dx_id1 for d
+ -- and we want it to look "interesting", else we won't gather *any*
+ -- consequential calls. E.g.
+ -- f d = ...g d....
+ -- If we specialise f for a call (f (dfun dNumInt)), we'll get
+ -- a consequent call (g d') with an auxiliary definition
+ -- d' = df dNumInt
+ -- We want that consequent call to look interesting
\end{code}
+Note [Specialising a recursive group]
+~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
+Consider
+ let rec { f x = ...g x'...
+ ; g y = ...f y'.... }
+ in f 'a'
+Here we specialise 'f' at Char; but that is very likely to lead to
+a specialisation of 'g' at Char. We must do the latter, else the
+whole point of specialisation is lost.
+
+But we do not want to keep iterating to a fixpoint, because in the
+presence of polymorphic recursion we might generate an infinite number
+of specialisations.
+
+So we use the following heuristic:
+ * Arrange the rec block in dependency order, so far as possible
+ (the occurrence analyser already does this)
+
+ * Specialise it much like a sequence of lets
+
+ * Then go through the block a second time, feeding call-info from
+ the RHSs back in the bottom, as it were
+
+In effect, the ordering maxmimises the effectiveness of each sweep,
+and we do just two sweeps. This should catch almost every case of
+monomorphic recursion -- the exception could be a very knotted-up
+recursion with multiple cycles tied up together.
+
+This plan is implemented in the Rec case of specBindItself.
+
+Note [Specialisations already covered]
+~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
+We obviously don't want to generate two specialisations for the same
+argument pattern. There are two wrinkles
+
+1. We do the already-covered test in specDefn, not when we generate
+the CallInfo in mkCallUDs. We used to test in the latter place, but
+we now iterate the specialiser somewhat, and the Id at the call site
+might therefore not have all the RULES that we can see in specDefn
+
+2. What about two specialisations where the second is an *instance*
+of the first? If the more specific one shows up first, we'll generate
+specialisations for both. If the *less* specific one shows up first,
+we *don't* currently generate a specialisation for the more specific
+one. (See the call to lookupRule in already_covered.) Reasons:
+ (a) lookupRule doesn't say which matches are exact (bad reason)
+ (b) if the earlier specialisation is user-provided, it's
+ far from clear that we should auto-specialise further
+
Note [Auto-specialisation and RULES]
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
Consider:
Reason: when specialising the body for a call (f ty dexp), we want to
substitute dexp for d, and pick up specialised calls in the body of f.
-This doesn't always work. One example I came across was htis:
+This doesn't always work. One example I came across was this:
newtype Gen a = MkGen{ unGen :: Int -> a }
choose :: Eq a => a -> Gen a
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
We transfer to the specialised function any INLINE stuff from the
original. This means (a) the Activation in the IdInfo, and (b) any
-InlineMe on the RHS.
+InlineMe on the RHS. We do not, however, transfer the RuleMatchInfo
+since we do not expect the specialisation to occur in rewrite rules.
This is a change (Jun06). Previously the idea is that the point of
inlining was precisely to specialise the function at its call site,
------------------------------------------------------------
type CallDetails = FiniteMap Id CallInfo
newtype CallKey = CallKey [Maybe Type] -- Nothing => unconstrained type argument
-type CallInfo = FiniteMap CallKey
- ([DictExpr], VarSet) -- Dict args and the vars of the whole
- -- call (including tyvars)
- -- [*not* include the main id itself, of course]
- -- The finite maps eliminate duplicates
- -- The list of types and dictionaries is guaranteed to
- -- match the type of f
+
+-- CallInfo uses a FiniteMap, thereby ensuring that
+-- we record only one call instance for any key
+--
+-- The list of types and dictionaries is guaranteed to
+-- match the type of f
+type CallInfo = FiniteMap CallKey ([DictExpr], VarSet)
+ -- Range is dict args and the vars of the whole
+ -- call (including tyvars)
+ -- [*not* include the main id itself, of course]
instance Outputable CallKey where
ppr (CallKey ts) = ppr ts
--
-- We don't include the 'id' itself.
-mkCallUDs :: Subst -> Id -> [CoreExpr] -> UsageDetails
-mkCallUDs subst f args
- | null theta
+mkCallUDs :: Id -> [CoreExpr] -> UsageDetails
+mkCallUDs f args
+ | not (isLocalId f) -- Imported from elsewhere
+ || null theta -- Not overloaded
|| not (all isClassPred theta)
-- Only specialise if all overloading is on class params.
-- In ptic, with implicit params, the type args
-- *don't* say what the value of the implicit param is!
|| not (spec_tys `lengthIs` n_tyvars)
|| not ( dicts `lengthIs` n_dicts)
- || maybeToBool (lookupRule (\_act -> True) (substInScope subst) emptyRuleBase f args)
- -- There's already a rule covering this call. A typical case
- -- is where there's an explicit user-provided rule. Then
- -- we don't want to create a specialised version
- -- of the function that overlaps.
- = emptyUDs -- Not overloaded, or no specialisation wanted
+ || not (any interestingArg dicts) -- Note [Interesting dictionary arguments]
+ -- See also Note [Specialisations already covered]
+ = -- pprTrace "mkCallUDs: discarding" (vcat [ppr f, ppr args, ppr n_tyvars, ppr n_dicts, ppr (map interestingArg dicts)])
+ emptyUDs -- Not overloaded, or no specialisation wanted
| otherwise
- = singleCall f spec_tys dicts
+ = -- pprTrace "mkCallUDs: keeping" (vcat [ppr f, ppr args, ppr n_tyvars, ppr n_dicts, ppr (map interestingArg dicts)])
+ singleCall f spec_tys dicts
where
(tyvars, theta, _) = tcSplitSigmaTy (idType f)
constrained_tyvars = tyVarsOfTheta theta
mk_spec_ty tyvar ty
| tyvar `elemVarSet` constrained_tyvars = Just ty
| otherwise = Nothing
+\end{code}
-------------------------------------------------------------
+Note [Interesting dictionary arguments]
+~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
+Consider this
+ \a.\d:Eq a. let f = ... in ...(f d)...
+There really is not much point in specialising f wrt the dictionary d,
+because the code for the specialised f is not improved at all, because
+d is lambda-bound. We simply get junk specialisations.
+
+We re-use the function SimplUtils.interestingArg function to determine
+what sort of dictionary arguments have *some* information in them.
+
+
+\begin{code}
plusUDs :: UsageDetails -> UsageDetails -> UsageDetails
plusUDs (MkUD {dict_binds = db1, calls = calls1, ud_fvs = fvs1})
(MkUD {dict_binds = db2, calls = calls2, ud_fvs = fvs2})
let (subst', bndrs') = cloneRecIdBndrs subst us (map fst pairs)
return (subst', subst', Rec (bndrs' `zip` map snd pairs))
-cloneBinders :: Subst -> [CoreBndr] -> SpecM (Subst, [CoreBndr])
-cloneBinders subst bndrs = do
- us <- getUniqueSupplyM
- return (cloneIdBndrs subst us bndrs)
-
-newIdSM :: Id -> Type -> SpecM Id
-newIdSM old_id new_ty = do
- uniq <- getUniqueM
- let
- -- Give the new Id a similar occurrence name to the old one
- name = idName old_id
- new_id = mkUserLocal (mkSpecOcc (nameOccName name)) uniq new_ty (getSrcSpan name)
- return new_id
+cloneDictBndrs :: Subst -> [CoreBndr] -> SpecM (Subst, [CoreBndr])
+cloneDictBndrs subst bndrs
+ = do { us <- getUniqueSupplyM
+ ; return (cloneIdBndrs subst us bndrs) }
+
+newSpecIdSM :: Id -> Type -> SpecM Id
+ -- Give the new Id a similar occurrence name to the old one
+newSpecIdSM old_id new_ty
+ = do { uniq <- getUniqueM
+ ; let
+ name = idName old_id
+ new_occ = mkSpecOcc (nameOccName name)
+ new_id = mkUserLocal new_occ uniq new_ty (getSrcSpan name)
+ ; return new_id }
\end{code}