\begin{code}
module Inst (
- LIE, emptyLIE, unitLIE, plusLIE, consLIE, zonkLIE,
+ LIE, emptyLIE, unitLIE, plusLIE, consLIE,
plusLIEs, mkLIE, isEmptyLIE, lieToList, listToLIE,
+ showLIE,
Inst,
- pprInst, pprInsts, pprInstsInFull, tidyInsts,
+ pprInst, pprInsts, pprInstsInFull, tidyInsts, tidyMoreInsts,
- newDictsFromOld, newDicts,
- newMethod, newMethodWithGivenTy, newOverloadedLit,
- newIPDict, tcInstId,
+ newDictsFromOld, newDicts, cloneDict,
+ newMethod, newMethodFromName, newMethodWithGivenTy,
+ newMethodWith, newMethodAtLoc,
+ newOverloadedLit, newIPDict,
+ tcInstCall, tcInstDataCon, tcSyntaxName,
- tyVarsOfInst, tyVarsOfInsts, tyVarsOfLIE, instLoc, getDictClassTys,
- getIPs,
- predsOfInsts, predsOfInst,
+ tyVarsOfInst, tyVarsOfInsts, tyVarsOfLIE,
+ ipNamesOfInst, ipNamesOfInsts, fdPredsOfInst, fdPredsOfInsts,
+ instLoc, getDictClassTys, dictPred,
lookupInst, lookupSimpleInst, LookupInstResult(..),
- isDict, isClassDict, isMethod, instMentionsIPs,
+ isDict, isClassDict, isMethod,
+ isLinearInst, linearInstType, isIPDict, isInheritableInst,
isTyVarDict, isStdClassTyVarDict, isMethodFor,
instBindingRequired, instCanBeGeneralised,
zonkInst, zonkInsts,
- instToId,
+ instToId, instName,
InstOrigin(..), InstLoc, pprInstLoc
) where
#include "HsVersions.h"
-import CmdLineOpts ( opt_NoMethodSharing )
+import {-# SOURCE #-} TcExpr( tcExpr )
+
import HsSyn ( HsLit(..), HsOverLit(..), HsExpr(..) )
-import TcHsSyn ( TcExpr, TcId,
+import TcHsSyn ( TcExpr, TcId, TcIdSet, TypecheckedHsExpr,
mkHsTyApp, mkHsDictApp, mkHsConApp, zonkId
)
-import TcMonad
-import TcEnv ( TcIdSet, tcGetInstEnv, tcLookupSyntaxId )
+import TcRnMonad
+import TcEnv ( tcGetInstEnv, tcLookupId, tcLookupTyCon )
import InstEnv ( InstLookupResult(..), lookupInstEnv )
-import TcType ( TcThetaType,
- TcType, TcTauType, TcTyVarSet,
- zonkTcType, zonkTcTypes, zonkTcPredType,
- zonkTcThetaType, tcInstTyVar, tcInstType
+import TcMType ( zonkTcType, zonkTcTypes, zonkTcPredType, zapToType,
+ zonkTcThetaType, tcInstTyVar, tcInstType, tcInstTyVars
)
-import CoreFVs ( idFreeTyVars )
-import Class ( Class )
-import Id ( Id, idType, mkUserLocal, mkSysLocal, mkLocalId )
-import PrelInfo ( isStandardClass, isCcallishClass, isNoDictClass )
-import Name ( mkMethodOcc, getOccName )
-import NameSet ( NameSet )
-import PprType ( pprPred )
-import Type ( Type, PredType(..), ThetaType,
- isTyVarTy, mkPredTy, mkTyVarTy, mkTyVarTys,
- splitForAllTys, splitSigmaTy, funArgTy,
- splitMethodTy, splitRhoTy,
+import TcType ( Type, TcType, TcThetaType, TcTyVarSet,
+ SourceType(..), PredType, ThetaType, TyVarDetails(VanillaTv),
+ tcSplitForAllTys, tcSplitForAllTys, mkTyConApp,
+ tcSplitMethodTy, tcSplitPhiTy, mkGenTyConApp,
+ isIntTy,isFloatTy, isIntegerTy, isDoubleTy,
+ tcIsTyVarTy, mkPredTy, mkTyVarTy, mkTyVarTys,
tyVarsOfType, tyVarsOfTypes, tyVarsOfPred, tidyPred,
- predMentionsIPs, isClassPred, isTyVarClassPred,
+ isClassPred, isTyVarClassPred, isLinearPred, predHasFDs,
getClassPredTys, getClassPredTys_maybe, mkPredName,
- tidyType, tidyTypes, tidyFreeTyVars
+ isInheritablePred, isIPPred,
+ tidyType, tidyTypes, tidyFreeTyVars, tcSplitSigmaTy
)
+import CoreFVs ( idFreeTyVars )
+import Class ( Class )
+import DataCon ( DataCon,dataConSig )
+import Id ( Id, idName, idType, mkUserLocal, mkSysLocal, mkLocalId, setIdUnique )
+import PrelInfo ( isStandardClass, isCcallishClass, isNoDictClass )
+import Name ( Name, mkMethodOcc, getOccName )
+import PprType ( pprPred, pprParendType )
import Subst ( emptyInScopeSet, mkSubst,
- substTy, substTheta, mkTyVarSubst, mkTopTyVarSubst
+ substTy, substTyWith, substTheta, mkTyVarSubst, mkTopTyVarSubst
)
import Literal ( inIntRange )
-import VarEnv ( TidyEnv, lookupSubstEnv, SubstResult(..) )
+import Var ( TyVar )
+import VarEnv ( TidyEnv, emptyTidyEnv, lookupSubstEnv, SubstResult(..) )
import VarSet ( elemVarSet, emptyVarSet, unionVarSet )
-import TysWiredIn ( isIntTy,
- floatDataCon, isFloatTy,
- doubleDataCon, isDoubleTy,
- isIntegerTy
- )
-import PrelNames( fromIntegerName, fromRationalName )
-import Util ( thenCmp, zipWithEqual )
-import Bag
+import TysWiredIn ( floatDataCon, doubleDataCon )
+import PrelNames( fromIntegerName, fromRationalName, rationalTyConName )
+import Util ( equalLength )
+import BasicTypes( IPName(..), mapIPName, ipNameName )
+import UniqSupply( uniqsFromSupply )
import Outputable
\end{code}
-%************************************************************************
-%* *
-\subsection[Inst-collections]{LIE: a collection of Insts}
-%* *
-%************************************************************************
-
-\begin{code}
-type LIE = Bag Inst
-
-isEmptyLIE = isEmptyBag
-emptyLIE = emptyBag
-unitLIE inst = unitBag inst
-mkLIE insts = listToBag insts
-plusLIE lie1 lie2 = lie1 `unionBags` lie2
-consLIE inst lie = inst `consBag` lie
-plusLIEs lies = unionManyBags lies
-lieToList = bagToList
-listToLIE = listToBag
-
-zonkLIE :: LIE -> NF_TcM LIE
-zonkLIE lie = mapBagNF_Tc zonkInst lie
-
-pprInsts :: [Inst] -> SDoc
-pprInsts insts = parens (sep (punctuate comma (map pprInst insts)))
-
-
-pprInstsInFull insts
- = vcat (map go insts)
- where
- go inst = quotes (ppr inst) <+> pprInstLoc (instLoc inst)
-\end{code}
-
-%************************************************************************
-%* *
-\subsection[Inst-types]{@Inst@ types}
-%* *
-%************************************************************************
-
-An @Inst@ is either a dictionary, an instance of an overloaded
-literal, or an instance of an overloaded value. We call the latter a
-``method'' even though it may not correspond to a class operation.
-For example, we might have an instance of the @double@ function at
-type Int, represented by
-
- Method 34 doubleId [Int] origin
-
-\begin{code}
-data Inst
- = Dict
- Id
- TcPredType
- InstLoc
-
- | Method
- Id
-
- TcId -- The overloaded function
- -- This function will be a global, local, or ClassOpId;
- -- inside instance decls (only) it can also be an InstId!
- -- The id needn't be completely polymorphic.
- -- You'll probably find its name (for documentation purposes)
- -- inside the InstOrigin
-
- [TcType] -- The types to which its polymorphic tyvars
- -- should be instantiated.
- -- These types must saturate the Id's foralls.
-
- TcThetaType -- The (types of the) dictionaries to which the function
- -- must be applied to get the method
-
- TcTauType -- The type of the method
-
- InstLoc
-
- -- INVARIANT: in (Method u f tys theta tau loc)
- -- type of (f tys dicts(from theta)) = tau
-
- | LitInst
- Id
- HsOverLit -- The literal from the occurrence site
- TcType -- The type at which the literal is used
- InstLoc
-\end{code}
-
-Ordering
-~~~~~~~~
-@Insts@ are ordered by their class/type info, rather than by their
-unique. This allows the context-reduction mechanism to use standard finite
-maps to do their stuff.
-
-\begin{code}
-instance Ord Inst where
- compare = cmpInst
-
-instance Eq Inst where
- (==) i1 i2 = case i1 `cmpInst` i2 of
- EQ -> True
- other -> False
-
-cmpInst (Dict _ pred1 _) (Dict _ pred2 _) = (pred1 `compare` pred2)
-cmpInst (Dict _ _ _) other = LT
-
-cmpInst (Method _ _ _ _ _ _) (Dict _ _ _) = GT
-cmpInst (Method _ id1 tys1 _ _ _) (Method _ id2 tys2 _ _ _) = (id1 `compare` id2) `thenCmp` (tys1 `compare` tys2)
-cmpInst (Method _ _ _ _ _ _) other = LT
-
-cmpInst (LitInst _ lit1 ty1 _) (LitInst _ lit2 ty2 _) = (lit1 `compare` lit2) `thenCmp` (ty1 `compare` ty2)
-cmpInst (LitInst _ _ _ _) other = GT
-
--- and they can only have HsInt or HsFracs in them.
-\end{code}
-
Selection
~~~~~~~~~
\begin{code}
+instName :: Inst -> Name
+instName inst = idName (instToId inst)
+
instToId :: Inst -> TcId
instToId (Dict id _ _) = id
instToId (Method id _ _ _ _ _) = id
instLoc (Method _ _ _ _ _ loc) = loc
instLoc (LitInst _ _ _ loc) = loc
+dictPred (Dict _ pred _ ) = pred
+dictPred inst = pprPanic "dictPred" (ppr inst)
+
getDictClassTys (Dict _ pred _) = getClassPredTys pred
-predsOfInsts :: [Inst] -> [PredType]
-predsOfInsts insts = concatMap predsOfInst insts
+-- fdPredsOfInst is used to get predicates that contain functional
+-- dependencies; i.e. should participate in improvement
+fdPredsOfInst (Dict _ pred _) | predHasFDs pred = [pred]
+ | otherwise = []
+fdPredsOfInst (Method _ _ _ theta _ _) = filter predHasFDs theta
+fdPredsOfInst other = []
+
+fdPredsOfInsts :: [Inst] -> [PredType]
+fdPredsOfInsts insts = concatMap fdPredsOfInst insts
+
+isInheritableInst (Dict _ pred _) = isInheritablePred pred
+isInheritableInst (Method _ _ _ theta _ _) = all isInheritablePred theta
+isInheritableInst other = True
-predsOfInst (Dict _ pred _) = [pred]
-predsOfInst (Method _ _ _ theta _ _) = theta
-predsOfInst (LitInst _ _ _ _) = []
- -- The last case is is really a big cheat
- -- LitInsts to give rise to a (Num a) or (Fractional a) predicate
- -- But Num and Fractional have only one parameter and no functional
- -- dependencies, so I think no caller of predsOfInst will care.
-ipsOfPreds theta = [(n,ty) | IParam n ty <- theta]
+ipNamesOfInsts :: [Inst] -> [Name]
+ipNamesOfInst :: Inst -> [Name]
+-- Get the implicit parameters mentioned by these Insts
+-- NB: ?x and %x get different Names
+ipNamesOfInsts insts = [n | inst <- insts, n <- ipNamesOfInst inst]
-getIPs inst = ipsOfPreds (predsOfInst inst)
+ipNamesOfInst (Dict _ (IParam n _) _) = [ipNameName n]
+ipNamesOfInst (Method _ _ _ theta _ _) = [ipNameName n | IParam n _ <- theta]
+ipNamesOfInst other = []
tyVarsOfInst :: Inst -> TcTyVarSet
tyVarsOfInst (LitInst _ _ ty _) = tyVarsOfType ty
-- The id might have free type variables; in the case of
-- locally-overloaded class methods, for example
+
tyVarsOfInsts insts = foldr (unionVarSet . tyVarsOfInst) emptyVarSet insts
tyVarsOfLIE lie = tyVarsOfInsts (lieToList lie)
\end{code}
isTyVarDict (Dict _ pred _) = isTyVarClassPred pred
isTyVarDict other = False
+isIPDict :: Inst -> Bool
+isIPDict (Dict _ pred _) = isIPPred pred
+isIPDict other = False
+
isMethod :: Inst -> Bool
isMethod (Method _ _ _ _ _ _) = True
isMethod other = False
isMethodFor ids (Method uniq id tys _ _ loc) = id `elemVarSet` ids
isMethodFor ids inst = False
-instMentionsIPs :: Inst -> NameSet -> Bool
- -- True if the Inst mentions any of the implicit
- -- parameters in the supplied set of names
-instMentionsIPs (Dict _ pred _) ip_names = pred `predMentionsIPs` ip_names
-instMentionsIPs (Method _ _ _ theta _ _) ip_names = any (`predMentionsIPs` ip_names) theta
-instMentionsIPs other ip_names = False
+isLinearInst :: Inst -> Bool
+isLinearInst (Dict _ pred _) = isLinearPred pred
+isLinearInst other = False
+ -- We never build Method Insts that have
+ -- linear implicit paramters in them.
+ -- Hence no need to look for Methods
+ -- See TcExpr.tcId
+
+linearInstType :: Inst -> TcType -- %x::t --> t
+linearInstType (Dict _ (IParam _ ty) _) = ty
+
isStdClassTyVarDict (Dict _ pred _) = case getClassPredTys_maybe pred of
- Just (clas, [ty]) -> isStandardClass clas && isTyVarTy ty
+ Just (clas, [ty]) -> isStandardClass clas && tcIsTyVarTy ty
other -> False
\end{code}
\begin{code}
instBindingRequired :: Inst -> Bool
instBindingRequired (Dict _ (ClassP clas _) _) = not (isNoDictClass clas)
-instBindingRequired (Dict _ (IParam _ _) _) = False
instBindingRequired other = True
instCanBeGeneralised :: Inst -> Bool
\begin{code}
newDicts :: InstOrigin
-> TcThetaType
- -> NF_TcM [Inst]
+ -> TcM [Inst]
newDicts orig theta
- = tcGetInstLoc orig `thenNF_Tc` \ loc ->
+ = getInstLoc orig `thenM` \ loc ->
newDictsAtLoc loc theta
-newDictsFromOld :: Inst -> TcThetaType -> NF_TcM [Inst]
+cloneDict :: Inst -> TcM Inst
+cloneDict (Dict id ty loc) = newUnique `thenM` \ uniq ->
+ returnM (Dict (setIdUnique id uniq) ty loc)
+
+newDictsFromOld :: Inst -> TcThetaType -> TcM [Inst]
newDictsFromOld (Dict _ _ loc) theta = newDictsAtLoc loc theta
-- Local function, similar to newDicts,
-- but with slightly different interface
newDictsAtLoc :: InstLoc
-> TcThetaType
- -> NF_TcM [Inst]
+ -> TcM [Inst]
newDictsAtLoc inst_loc@(_,loc,_) theta
- = tcGetUniques (length theta) `thenNF_Tc` \ new_uniqs ->
- returnNF_Tc (zipWithEqual "newDictsAtLoc" mk_dict new_uniqs theta)
+ = newUniqueSupply `thenM` \ us ->
+ returnM (zipWith mk_dict (uniqsFromSupply us) theta)
where
mk_dict uniq pred = Dict (mkLocalId (mkPredName uniq loc pred) (mkPredTy pred)) pred inst_loc
-newIPDict orig name ty
- = tcGetInstLoc orig `thenNF_Tc` \ inst_loc ->
- returnNF_Tc (Dict (mkLocalId name (mkPredTy pred)) pred inst_loc)
- where pred = IParam name ty
+-- For vanilla implicit parameters, there is only one in scope
+-- at any time, so we used to use the name of the implicit parameter itself
+-- But with splittable implicit parameters there may be many in
+-- scope, so we make up a new name.
+newIPDict :: InstOrigin -> IPName Name -> Type
+ -> TcM (IPName Id, Inst)
+newIPDict orig ip_name ty
+ = getInstLoc orig `thenM` \ inst_loc@(_,loc,_) ->
+ newUnique `thenM` \ uniq ->
+ let
+ pred = IParam ip_name ty
+ id = mkLocalId (mkPredName uniq loc pred) (mkPredTy pred)
+ in
+ returnM (mapIPName (\n -> id) ip_name, Dict id pred inst_loc)
\end{code}
+
%************************************************************************
%* *
\subsection{Building methods (calls of overloaded functions)}
%* *
%************************************************************************
-tcInstId instantiates an occurrence of an Id.
-The instantiate_it loop runs round instantiating the Id.
-It has to be a loop because we are now prepared to entertain
-types like
- f:: forall a. Eq a => forall b. Baz b => tau
-We want to instantiate this to
- f2::tau {f2 = f1 b (Baz b), f1 = f a (Eq a)}
-
-The -fno-method-sharing flag controls what happens so far as the LIE
-is concerned. The default case is that for an overloaded function we
-generate a "method" Id, and add the Method Inst to the LIE. So you get
-something like
- f :: Num a => a -> a
- f = /\a (d:Num a) -> let m = (+) a d in \ (x:a) -> m x x
-If you specify -fno-method-sharing, the dictionary application
-isn't shared, so we get
- f :: Num a => a -> a
- f = /\a (d:Num a) (x:a) -> (+) a d x x
-This gets a bit less sharing, but
- a) it's better for RULEs involving overloaded functions
- b) perhaps fewer separated lambdas
-
\begin{code}
-tcInstId :: Id -> NF_TcM (TcExpr, LIE, TcType)
-tcInstId fun
- | opt_NoMethodSharing = loop_noshare (HsVar fun) (idType fun)
- | otherwise = loop_share fun
- where
- orig = OccurrenceOf fun
- loop_noshare fun fun_ty
- = tcInstType fun_ty `thenNF_Tc` \ (tyvars, theta, tau) ->
- let
- ty_app = mkHsTyApp fun (mkTyVarTys tyvars)
- in
- if null theta then -- Is it overloaded?
- returnNF_Tc (ty_app, emptyLIE, tau)
- else
- newDicts orig theta `thenNF_Tc` \ dicts ->
- loop_noshare (mkHsDictApp ty_app (map instToId dicts)) tau `thenNF_Tc` \ (expr, lie, final_tau) ->
- returnNF_Tc (expr, mkLIE dicts `plusLIE` lie, final_tau)
-
- loop_share fun
- = tcInstType (idType fun) `thenNF_Tc` \ (tyvars, theta, tau) ->
- let
- arg_tys = mkTyVarTys tyvars
- in
- if null theta then -- Is it overloaded?
- returnNF_Tc (mkHsTyApp (HsVar fun) arg_tys, emptyLIE, tau)
- else
- -- Yes, it's overloaded
- newMethodWithGivenTy orig fun arg_tys theta tau `thenNF_Tc` \ meth ->
- loop_share (instToId meth) `thenNF_Tc` \ (expr, lie, final_tau) ->
- returnNF_Tc (expr, unitLIE meth `plusLIE` lie, final_tau)
+tcInstCall :: InstOrigin -> TcType -> TcM (TypecheckedHsExpr -> TypecheckedHsExpr, TcType)
+tcInstCall orig fun_ty -- fun_ty is usually a sigma-type
+ = tcInstType VanillaTv fun_ty `thenM` \ (tyvars, theta, tau) ->
+ newDicts orig theta `thenM` \ dicts ->
+ extendLIEs dicts `thenM_`
+ let
+ inst_fn e = mkHsDictApp (mkHsTyApp e (mkTyVarTys tyvars)) (map instToId dicts)
+ in
+ returnM (inst_fn, tau)
+
+tcInstDataCon :: InstOrigin -> DataCon
+ -> TcM ([TcType], -- Types to instantiate at
+ [Inst], -- Existential dictionaries to apply to
+ [TcType], -- Argument types of constructor
+ TcType, -- Result type
+ [TyVar]) -- Existential tyvars
+tcInstDataCon orig data_con
+ = let
+ (tvs, stupid_theta, ex_tvs, ex_theta, arg_tys, tycon) = dataConSig data_con
+ -- We generate constraints for the stupid theta even when
+ -- pattern matching (as the Report requires)
+ in
+ tcInstTyVars VanillaTv (tvs ++ ex_tvs) `thenM` \ (all_tvs', ty_args', tenv) ->
+ let
+ stupid_theta' = substTheta tenv stupid_theta
+ ex_theta' = substTheta tenv ex_theta
+ arg_tys' = map (substTy tenv) arg_tys
+
+ n_normal_tvs = length tvs
+ ex_tvs' = drop n_normal_tvs all_tvs'
+ result_ty = mkTyConApp tycon (take n_normal_tvs ty_args')
+ in
+ newDicts orig stupid_theta' `thenM` \ stupid_dicts ->
+ newDicts orig ex_theta' `thenM` \ ex_dicts ->
+
+ -- Note that we return the stupid theta *only* in the LIE;
+ -- we don't otherwise use it at all
+ extendLIEs stupid_dicts `thenM_`
+
+ returnM (ty_args', ex_dicts, arg_tys', result_ty, ex_tvs')
+newMethodFromName :: InstOrigin -> TcType -> Name -> TcM TcId
+newMethodFromName origin ty name
+ = tcLookupId name `thenM` \ id ->
+ -- Use tcLookupId not tcLookupGlobalId; the method is almost
+ -- always a class op, but with -fno-implicit-prelude GHC is
+ -- meant to find whatever thing is in scope, and that may
+ -- be an ordinary function.
+ newMethod origin id [ty]
+
newMethod :: InstOrigin
-> TcId
-> [TcType]
- -> NF_TcM Inst
+ -> TcM Id
newMethod orig id tys
= -- Get the Id type and instantiate it at the specified types
let
- (tyvars, rho) = splitForAllTys (idType id)
- rho_ty = substTy (mkTyVarSubst tyvars tys) rho
- (pred, tau) = splitMethodTy rho_ty
+ (tyvars, rho) = tcSplitForAllTys (idType id)
+ rho_ty = substTyWith tyvars tys rho
+ (pred, tau) = tcSplitMethodTy rho_ty
in
newMethodWithGivenTy orig id tys [pred] tau
newMethodWithGivenTy orig id tys theta tau
- = tcGetInstLoc orig `thenNF_Tc` \ loc ->
- newMethodWith loc id tys theta tau
+ = getInstLoc orig `thenM` \ loc ->
+ newMethodWith loc id tys theta tau `thenM` \ inst ->
+ extendLIE inst `thenM_`
+ returnM (instToId inst)
+
+--------------------------------------------
+-- newMethodWith and newMethodAtLoc do *not* drop the
+-- Inst into the LIE; they just returns the Inst
+-- This is important because they are used by TcSimplify
+-- to simplify Insts
newMethodWith inst_loc@(_,loc,_) id tys theta tau
- = tcGetUnique `thenNF_Tc` \ new_uniq ->
+ = newUnique `thenM` \ new_uniq ->
let
meth_id = mkUserLocal (mkMethodOcc (getOccName id)) new_uniq tau loc
+ inst = Method meth_id id tys theta tau inst_loc
in
- returnNF_Tc (Method meth_id id tys theta tau inst_loc)
+ returnM inst
newMethodAtLoc :: InstLoc
-> Id -> [TcType]
- -> NF_TcM (Inst, TcId)
+ -> TcM Inst
newMethodAtLoc inst_loc real_id tys
-- This actually builds the Inst
= -- Get the Id type and instantiate it at the specified types
let
- (tyvars,rho) = splitForAllTys (idType real_id)
- rho_ty = ASSERT( length tyvars == length tys )
+ (tyvars,rho) = tcSplitForAllTys (idType real_id)
+ rho_ty = ASSERT( equalLength tyvars tys )
substTy (mkTopTyVarSubst tyvars tys) rho
- (theta, tau) = splitRhoTy rho_ty
+ (theta, tau) = tcSplitPhiTy rho_ty
in
- newMethodWith inst_loc real_id tys theta tau `thenNF_Tc` \ meth_inst ->
- returnNF_Tc (meth_inst, instToId meth_inst)
+ newMethodWith inst_loc real_id tys theta tau
\end{code}
In newOverloadedLit we convert directly to an Int or Integer if we
newOverloadedLit :: InstOrigin
-> HsOverLit
-> TcType
- -> NF_TcM (TcExpr, LIE)
-newOverloadedLit orig (HsIntegral i) ty
- | isIntTy ty && inIntRange i -- Short cut for Int
- = returnNF_Tc (int_lit, emptyLIE)
-
- | isIntegerTy ty -- Short cut for Integer
- = returnNF_Tc (integer_lit, emptyLIE)
-
- where
- int_lit = HsLit (HsInt i)
- integer_lit = HsLit (HsInteger i)
-
-newOverloadedLit orig lit ty -- The general case
- = tcGetInstLoc orig `thenNF_Tc` \ loc ->
- tcGetUnique `thenNF_Tc` \ new_uniq ->
+ -> TcM TcExpr
+newOverloadedLit orig lit@(HsIntegral i fi) expected_ty
+ | fi /= fromIntegerName -- Do not generate a LitInst for rebindable
+ -- syntax. Reason: tcSyntaxName does unification
+ -- which is very inconvenient in tcSimplify
+ = tcSyntaxName orig expected_ty fromIntegerName fi `thenM` \ (expr, _) ->
+ returnM (HsApp expr (HsLit (HsInteger i)))
+
+ | Just expr <- shortCutIntLit i expected_ty
+ = returnM expr
+
+ | otherwise
+ = newLitInst orig lit expected_ty
+
+newOverloadedLit orig lit@(HsFractional r fr) expected_ty
+ | fr /= fromRationalName -- c.f. HsIntegral case
+ = tcSyntaxName orig expected_ty fromRationalName fr `thenM` \ (expr, _) ->
+ mkRatLit r `thenM` \ rat_lit ->
+ returnM (HsApp expr rat_lit)
+
+ | Just expr <- shortCutFracLit r expected_ty
+ = returnM expr
+
+ | otherwise
+ = newLitInst orig lit expected_ty
+
+newLitInst orig lit expected_ty
+ = getInstLoc orig `thenM` \ loc ->
+ newUnique `thenM` \ new_uniq ->
+ zapToType expected_ty `thenM_`
+ -- The expected type might be a 'hole' type variable,
+ -- in which case we must zap it to an ordinary type variable
+ let
+ lit_inst = LitInst lit_id lit expected_ty loc
+ lit_id = mkSysLocal FSLIT("lit") new_uniq expected_ty
+ in
+ extendLIE lit_inst `thenM_`
+ returnM (HsVar (instToId lit_inst))
+
+shortCutIntLit :: Integer -> TcType -> Maybe TcExpr
+shortCutIntLit i ty
+ | isIntTy ty && inIntRange i -- Short cut for Int
+ = Just (HsLit (HsInt i))
+ | isIntegerTy ty -- Short cut for Integer
+ = Just (HsLit (HsInteger i))
+ | otherwise = Nothing
+
+shortCutFracLit :: Rational -> TcType -> Maybe TcExpr
+shortCutFracLit f ty
+ | isFloatTy ty
+ = Just (mkHsConApp floatDataCon [] [HsLit (HsFloatPrim f)])
+ | isDoubleTy ty
+ = Just (mkHsConApp doubleDataCon [] [HsLit (HsDoublePrim f)])
+ | otherwise = Nothing
+
+mkRatLit :: Rational -> TcM TcExpr
+mkRatLit r
+ = tcLookupTyCon rationalTyConName `thenM` \ rat_tc ->
let
- lit_inst = LitInst lit_id lit ty loc
- lit_id = mkSysLocal SLIT("lit") new_uniq ty
+ rational_ty = mkGenTyConApp rat_tc []
in
- returnNF_Tc (HsVar (instToId lit_inst), unitLIE lit_inst)
+ returnM (HsLit (HsRat r rational_ty))
\end{code}
need, and it's a lot of extra work.
\begin{code}
-zonkInst :: Inst -> NF_TcM Inst
+zonkInst :: Inst -> TcM Inst
zonkInst (Dict id pred loc)
- = zonkTcPredType pred `thenNF_Tc` \ new_pred ->
- returnNF_Tc (Dict id new_pred loc)
+ = zonkTcPredType pred `thenM` \ new_pred ->
+ returnM (Dict id new_pred loc)
zonkInst (Method m id tys theta tau loc)
- = zonkId id `thenNF_Tc` \ new_id ->
+ = zonkId id `thenM` \ new_id ->
-- Essential to zonk the id in case it's a local variable
-- Can't use zonkIdOcc because the id might itself be
-- an InstId, in which case it won't be in scope
- zonkTcTypes tys `thenNF_Tc` \ new_tys ->
- zonkTcThetaType theta `thenNF_Tc` \ new_theta ->
- zonkTcType tau `thenNF_Tc` \ new_tau ->
- returnNF_Tc (Method m new_id new_tys new_theta new_tau loc)
+ zonkTcTypes tys `thenM` \ new_tys ->
+ zonkTcThetaType theta `thenM` \ new_theta ->
+ zonkTcType tau `thenM` \ new_tau ->
+ returnM (Method m new_id new_tys new_theta new_tau loc)
zonkInst (LitInst id lit ty loc)
- = zonkTcType ty `thenNF_Tc` \ new_ty ->
- returnNF_Tc (LitInst id lit new_ty loc)
+ = zonkTcType ty `thenM` \ new_ty ->
+ returnM (LitInst id lit new_ty loc)
-zonkInsts insts = mapNF_Tc zonkInst insts
+zonkInsts insts = mappM zonkInst insts
\end{code}
instance Outputable Inst where
ppr inst = pprInst inst
+pprInsts :: [Inst] -> SDoc
+pprInsts insts = parens (sep (punctuate comma (map pprInst insts)))
+
+pprInstsInFull insts
+ = vcat (map go insts)
+ where
+ go inst = quotes (ppr inst) <+> pprInstLoc (instLoc inst)
+
pprInst (LitInst u lit ty loc)
= hsep [ppr lit, ptext SLIT("at"), ppr ty, show_uniq u]
pprInst m@(Method u id tys theta tau loc)
= hsep [ppr id, ptext SLIT("at"),
- brackets (interppSP tys) {- ,
+ brackets (sep (map pprParendType tys)) {- ,
ptext SLIT("theta"), ppr theta,
ptext SLIT("tau"), ppr tau
show_uniq u,
tidyInst env (Dict u pred loc) = Dict u (tidyPred env pred) loc
tidyInst env (Method u id tys theta tau loc) = Method u id (tidyTypes env tys) theta tau loc
-tidyInsts :: [Inst] -> (TidyEnv, [Inst])
+tidyMoreInsts :: TidyEnv -> [Inst] -> (TidyEnv, [Inst])
-- This function doesn't assume that the tyvars are in scope
-- so it works like tidyOpenType, returning a TidyEnv
-tidyInsts insts
- = (env, map (tidyInst env) insts)
+tidyMoreInsts env insts
+ = (env', map (tidyInst env') insts)
where
- env = tidyFreeTyVars emptyTidyEnv (tyVarsOfInsts insts)
+ env' = tidyFreeTyVars env (tyVarsOfInsts insts)
+
+tidyInsts :: [Inst] -> (TidyEnv, [Inst])
+tidyInsts insts = tidyMoreInsts emptyTidyEnv insts
+
+showLIE :: String -> TcM () -- Debugging
+showLIE str
+ = do { lie_var <- getLIEVar ;
+ lie <- readMutVar lie_var ;
+ traceTc (text str <+> pprInstsInFull (lieToList lie)) }
\end{code}
| SimpleInst TcExpr -- Just a variable, type application, or literal
| GenInst [Inst] TcExpr -- The expression and its needed insts
-lookupInst :: Inst
- -> NF_TcM (LookupInstResult s)
+lookupInst :: Inst -> TcM (LookupInstResult s)
+-- It's important that lookupInst does not put any new stuff into
+-- the LIE. Instead, any Insts needed by the lookup are returned in
+-- the LookupInstResult, where they can be further processed by tcSimplify
--- Dictionaries
+-- Dictionaries
lookupInst dict@(Dict _ (ClassP clas tys) loc)
- = tcGetInstEnv `thenNF_Tc` \ inst_env ->
- case lookupInstEnv inst_env clas tys of
+ = getDOpts `thenM` \ dflags ->
+ tcGetInstEnv `thenM` \ inst_env ->
+ case lookupInstEnv dflags inst_env clas tys of
FoundInst tenv dfun_id
- -> let
- (tyvars, rho) = splitForAllTys (idType dfun_id)
+ -> -- It's possible that not all the tyvars are in
+ -- the substitution, tenv. For example:
+ -- instance C X a => D X where ...
+ -- (presumably there's a functional dependency in class C)
+ -- Hence the mk_ty_arg to instantiate any un-substituted tyvars.
+ let
+ (tyvars, rho) = tcSplitForAllTys (idType dfun_id)
mk_ty_arg tv = case lookupSubstEnv tenv tv of
- Just (DoneTy ty) -> returnNF_Tc ty
- Nothing -> tcInstTyVar tv `thenNF_Tc` \ tc_tv ->
- returnTc (mkTyVarTy tc_tv)
+ Just (DoneTy ty) -> returnM ty
+ Nothing -> tcInstTyVar VanillaTv tv `thenM` \ tc_tv ->
+ returnM (mkTyVarTy tc_tv)
in
- mapNF_Tc mk_ty_arg tyvars `thenNF_Tc` \ ty_args ->
+ mappM mk_ty_arg tyvars `thenM` \ ty_args ->
let
- subst = mkTyVarSubst tyvars ty_args
- dfun_rho = substTy subst rho
- (theta, _) = splitRhoTy dfun_rho
- ty_app = mkHsTyApp (HsVar dfun_id) ty_args
+ dfun_rho = substTy (mkTyVarSubst tyvars ty_args) rho
+ (theta, _) = tcSplitPhiTy dfun_rho
+ ty_app = mkHsTyApp (HsVar dfun_id) ty_args
in
if null theta then
- returnNF_Tc (SimpleInst ty_app)
+ returnM (SimpleInst ty_app)
else
- newDictsAtLoc loc theta `thenNF_Tc` \ dicts ->
+ newDictsAtLoc loc theta `thenM` \ dicts ->
let
rhs = mkHsDictApp ty_app (map instToId dicts)
in
- returnNF_Tc (GenInst dicts rhs)
+ returnM (GenInst dicts rhs)
- other -> returnNF_Tc NoInstance
+ other -> returnM NoInstance
-lookupInst dict@(Dict _ _ loc) = returnNF_Tc NoInstance
+lookupInst (Dict _ _ _) = returnM NoInstance
-- Methods
lookupInst inst@(Method _ id tys theta _ loc)
- = newDictsAtLoc loc theta `thenNF_Tc` \ dicts ->
- returnNF_Tc (GenInst dicts (mkHsDictApp (mkHsTyApp (HsVar id) tys) (map instToId dicts)))
+ = newDictsAtLoc loc theta `thenM` \ dicts ->
+ returnM (GenInst dicts (mkHsDictApp (mkHsTyApp (HsVar id) tys) (map instToId dicts)))
-- Literals
-lookupInst inst@(LitInst u (HsIntegral i) ty loc)
- | isIntTy ty && in_int_range -- Short cut for Int
- = returnNF_Tc (GenInst [] int_lit)
- -- GenInst, not SimpleInst, because int_lit is actually a constructor application
-
- | isIntegerTy ty -- Short cut for Integer
- = returnNF_Tc (GenInst [] integer_lit)
-
- | otherwise -- Alas, it is overloaded and a big literal!
- = tcLookupSyntaxId fromIntegerName `thenNF_Tc` \ from_integer ->
- newMethodAtLoc loc from_integer [ty] `thenNF_Tc` \ (method_inst, method_id) ->
- returnNF_Tc (GenInst [method_inst] (HsApp (HsVar method_id) integer_lit))
- where
- in_int_range = inIntRange i
- integer_lit = HsLit (HsInteger i)
- int_lit = HsLit (HsInt i)
-
--- similar idea for overloaded floating point literals: if the literal is
--- *definitely* a float or a double, generate the real thing here.
+-- Look for short cuts first: if the literal is *definitely* a
+-- int, integer, float or a double, generate the real thing here.
-- This is essential (see nofib/spectral/nucleic).
-
-lookupInst inst@(LitInst u (HsFractional f) ty loc)
- | isFloatTy ty = returnNF_Tc (GenInst [] float_lit)
- | isDoubleTy ty = returnNF_Tc (GenInst [] double_lit)
-
- | otherwise
- = tcLookupSyntaxId fromRationalName `thenNF_Tc` \ from_rational ->
- newMethodAtLoc loc from_rational [ty] `thenNF_Tc` \ (method_inst, method_id) ->
- let
- rational_ty = funArgTy (idType method_id)
- rational_lit = HsLit (HsRat f rational_ty)
- in
- returnNF_Tc (GenInst [method_inst] (HsApp (HsVar method_id) rational_lit))
-
- where
- floatprim_lit = HsLit (HsFloatPrim f)
- float_lit = mkHsConApp floatDataCon [] [floatprim_lit]
- doubleprim_lit = HsLit (HsDoublePrim f)
- double_lit = mkHsConApp doubleDataCon [] [doubleprim_lit]
+-- [Same shortcut as in newOverloadedLit, but we
+-- may have done some unification by now]
+
+
+lookupInst inst@(LitInst u (HsIntegral i from_integer_name) ty loc)
+ | Just expr <- shortCutIntLit i ty
+ = returnM (GenInst [] expr) -- GenInst, not SimpleInst, because
+ -- expr may be a constructor application
+ | otherwise
+ = ASSERT( from_integer_name == fromIntegerName ) -- A LitInst invariant
+ tcLookupId fromIntegerName `thenM` \ from_integer ->
+ newMethodAtLoc loc from_integer [ty] `thenM` \ method_inst ->
+ returnM (GenInst [method_inst]
+ (HsApp (HsVar (instToId method_inst)) (HsLit (HsInteger i))))
+
+
+lookupInst inst@(LitInst u (HsFractional f from_rat_name) ty loc)
+ | Just expr <- shortCutFracLit f ty
+ = returnM (GenInst [] expr)
+
+ | otherwise
+ = ASSERT( from_rat_name == fromRationalName ) -- A LitInst invariant
+ tcLookupId fromRationalName `thenM` \ from_rational ->
+ newMethodAtLoc loc from_rational [ty] `thenM` \ method_inst ->
+ mkRatLit f `thenM` \ rat_lit ->
+ returnM (GenInst [method_inst] (HsApp (HsVar (instToId method_inst)) rat_lit))
\end{code}
There is a second, simpler interface, when you want an instance of a
\begin{code}
lookupSimpleInst :: Class
- -> [Type] -- Look up (c,t)
- -> NF_TcM (Maybe ThetaType) -- Here are the needed (c,t)s
+ -> [Type] -- Look up (c,t)
+ -> TcM (Maybe ThetaType) -- Here are the needed (c,t)s
lookupSimpleInst clas tys
- = tcGetInstEnv `thenNF_Tc` \ inst_env ->
- case lookupInstEnv inst_env clas tys of
+ = getDOpts `thenM` \ dflags ->
+ tcGetInstEnv `thenM` \ inst_env ->
+ case lookupInstEnv dflags inst_env clas tys of
FoundInst tenv dfun
- -> returnNF_Tc (Just (substTheta (mkSubst emptyInScopeSet tenv) theta))
+ -> returnM (Just (substTheta (mkSubst emptyInScopeSet tenv) theta))
where
- (_, theta, _) = splitSigmaTy (idType dfun)
+ (_, rho) = tcSplitForAllTys (idType dfun)
+ (theta,_) = tcSplitPhiTy rho
- other -> returnNF_Tc Nothing
+ other -> returnM Nothing
\end{code}
+%************************************************************************
+%* *
+ Re-mappable syntax
+%* *
+%************************************************************************
+
+
+Suppose we are doing the -fno-implicit-prelude thing, and we encounter
+a do-expression. We have to find (>>) in the current environment, which is
+done by the rename. Then we have to check that it has the same type as
+Control.Monad.(>>). Or, more precisely, a compatible type. One 'customer' had
+this:
+
+ (>>) :: HB m n mn => m a -> n b -> mn b
+
+So the idea is to generate a local binding for (>>), thus:
+
+ let then72 :: forall a b. m a -> m b -> m b
+ then72 = ...something involving the user's (>>)...
+ in
+ ...the do-expression...
+
+Now the do-expression can proceed using then72, which has exactly
+the expected type.
+
+In fact tcSyntaxName just generates the RHS for then72, because we only
+want an actual binding in the do-expression case. For literals, we can
+just use the expression inline.
+
+\begin{code}
+tcSyntaxName :: InstOrigin
+ -> TcType -- Type to instantiate it at
+ -> Name -> Name -- (Standard name, user name)
+ -> TcM (TcExpr, TcType) -- Suitable expression with its type
+
+-- NB: tcSyntaxName calls tcExpr, and hence can do unification.
+-- So we do not call it from lookupInst, which is called from tcSimplify
+
+tcSyntaxName orig ty std_nm user_nm
+ | std_nm == user_nm
+ = newMethodFromName orig ty std_nm `thenM` \ id ->
+ returnM (HsVar id, idType id)
+
+ | otherwise
+ = tcLookupId std_nm `thenM` \ std_id ->
+ let
+ -- C.f. newMethodAtLoc
+ ([tv], _, tau) = tcSplitSigmaTy (idType std_id)
+ tau1 = substTy (mkTopTyVarSubst [tv] [ty]) tau
+ in
+ addErrCtxtM (syntaxNameCtxt user_nm orig tau1) $
+ tcExpr (HsVar user_nm) tau1 `thenM` \ user_fn ->
+ returnM (user_fn, tau1)
+
+syntaxNameCtxt name orig ty tidy_env
+ = getInstLoc orig `thenM` \ inst_loc ->
+ let
+ msg = vcat [ptext SLIT("When checking that") <+> quotes (ppr name) <+>
+ ptext SLIT("(needed by a syntactic construct)"),
+ nest 2 (ptext SLIT("has the required type:") <+> ppr (tidyType tidy_env ty)),
+ nest 2 (pprInstLoc inst_loc)]
+ in
+ returnM (tidy_env, msg)
+\end{code}