The @Inst@ type: dictionaries or method instances
\begin{code}
-{-# OPTIONS -w #-}
--- The above warning supression flag is a temporary kludge.
--- While working on this module you are encouraged to remove it and fix
--- any warnings in the module. See
--- http://hackage.haskell.org/trac/ghc/wiki/Commentary/CodingStyle#Warnings
--- for details
-
module Inst (
Inst,
newDictBndr, newDictBndrs, newDictBndrsO,
instCall, instStupidTheta,
- cloneDict,
- shortCutFracLit, shortCutIntLit, shortCutStringLit, newIPDict,
- newMethod, newMethodFromName, newMethodWithGivenTy,
+ cloneDict, mkOverLit,
+ newIPDict, newMethod, newMethodFromName, newMethodWithGivenTy,
tcInstClassOp,
tcSyntaxName, isHsVar,
eitherEqInst, mkEqInst, mkEqInsts, mkWantedEqInst,
finalizeEqInst, writeWantedCoercion,
eqInstType, updateEqInstCoercion,
- eqInstCoercion,
- eqInstLeftTy, eqInstRightTy
+ eqInstCoercion, eqInstTys
) where
#include "HsVersions.h"
import {-# SOURCE #-} TcExpr( tcPolyExpr )
-import {-# SOURCE #-} TcUnify( boxyUnify, unifyType )
+import {-# SOURCE #-} TcUnify( boxyUnify {- , unifyType -} )
-import FastString(FastString)
+import FastString
import HsSyn
import TcHsSyn
import TcRnMonad
import FunDeps
import TcMType
import TcType
+import DsUtils
import Type
import TypeRep
import Class
import Coercion
import HscTypes
import CoreFVs
-import DataCon
import Id
import Name
import NameSet
-import Literal
import Var ( Var, TyVar )
import qualified Var
import VarEnv
import VarSet
-import TysWiredIn
import PrelNames
import BasicTypes
import SrcLoc
import Bag
import Maybes
import Util
+import Unique
import Outputable
import Data.List
-import TypeRep
-import Class
+
+import Control.Monad
\end{code}
-- instType i@(EqInst {tci_co = co}) = eitherEqInst i TyVarTy id
instType (EqInst {tci_left = ty1, tci_right = ty2}) = mkPredTy (EqPred ty1 ty2)
+mkImplicTy :: [TyVar] -> [Inst] -> [Inst] -> Type
mkImplicTy tvs givens wanteds -- The type of an implication constraint
- = ASSERT( all isDict givens )
+ = ASSERT( all isAbstractableInst givens )
-- pprTrace "mkImplicTy" (ppr givens) $
-- See [Equational Constraints in Implication Constraints]
let dict_wanteds = filter (not . isEqInst) wanteds
in
mkForAllTys tvs $
mkPhiTy (map dictPred givens) $
- if isSingleton dict_wanteds then
- instType (head dict_wanteds)
- else
- mkTupleTy Boxed (length dict_wanteds) (map instType dict_wanteds)
+ mkBigCoreTupTy (map instType dict_wanteds)
+dictPred :: Inst -> TcPredType
dictPred (Dict {tci_pred = pred}) = pred
dictPred (EqInst {tci_left=ty1,tci_right=ty2}) = EqPred ty1 ty2
dictPred inst = pprPanic "dictPred" (ppr inst)
+getDictClassTys :: Inst -> (Class, [Type])
getDictClassTys (Dict {tci_pred = pred}) = getClassPredTys pred
getDictClassTys inst = pprPanic "getDictClassTys" (ppr inst)
-- Leaving these in is really important for the call to fdPredsOfInsts
-- in TcSimplify.inferLoop, because the result is fed to 'grow',
-- which is supposed to be conservative
+fdPredsOfInst :: Inst -> [TcPredType]
fdPredsOfInst (Dict {tci_pred = pred}) = [pred]
fdPredsOfInst (Method {tci_theta = theta}) = theta
fdPredsOfInst (ImplicInst {tci_given = gs,
fdPredsOfInsts :: [Inst] -> [PredType]
fdPredsOfInsts insts = concatMap fdPredsOfInst insts
+isInheritableInst :: Inst -> Bool
isInheritableInst (Dict {tci_pred = pred}) = isInheritablePred pred
isInheritableInst (Method {tci_theta = theta}) = all isInheritablePred theta
-isInheritableInst other = True
+isInheritableInst _ = True
---------------------------------
ipNamesOfInst (Dict {tci_pred = IParam n _}) = [ipNameName n]
ipNamesOfInst (Method {tci_theta = theta}) = [ipNameName n | IParam n _ <- theta]
-ipNamesOfInst other = []
+ipNamesOfInst _ = []
---------------------------------
tyVarsOfInst :: Inst -> TcTyVarSet
-- Remember the free tyvars of a coercion
tyVarsOfInst (EqInst {tci_left = ty1, tci_right = ty2}) = tyVarsOfType ty1 `unionVarSet` tyVarsOfType ty2
+tyVarsOfInsts :: [Inst] -> VarSet
tyVarsOfInsts insts = foldr (unionVarSet . tyVarsOfInst) emptyVarSet insts
+tyVarsOfLIE :: Bag Inst -> VarSet
tyVarsOfLIE lie = tyVarsOfInsts (lieToList lie)
isEqInst :: Inst -> Bool
isEqInst (EqInst {}) = True
-isEqInst other = False
+isEqInst _ = False
isDict :: Inst -> Bool
isDict (Dict {}) = True
-isDict other = False
+isDict _ = False
isClassDict :: Inst -> Bool
isClassDict (Dict {tci_pred = pred}) = isClassPred pred
-isClassDict other = False
+isClassDict _ = False
isTyVarDict :: Inst -> Bool
isTyVarDict (Dict {tci_pred = pred}) = isTyVarClassPred pred
-isTyVarDict other = False
+isTyVarDict _ = False
isIPDict :: Inst -> Bool
isIPDict (Dict {tci_pred = pred}) = isIPPred pred
-isIPDict other = False
+isIPDict _ = False
+isImplicInst :: Inst -> Bool
isImplicInst (ImplicInst {}) = True
-isImplicInst other = False
+isImplicInst _ = False
isMethod :: Inst -> Bool
isMethod (Method {}) = True
-isMethod other = False
+isMethod _ = False
isMethodFor :: TcIdSet -> Inst -> Bool
isMethodFor ids (Method {tci_oid = id}) = id `elemVarSet` ids
-isMethodFor ids inst = False
+isMethodFor _ _ = False
isMethodOrLit :: Inst -> Bool
isMethodOrLit (Method {}) = True
isMethodOrLit (LitInst {}) = True
-isMethodOrLit other = False
+isMethodOrLit _ = False
\end{code}
-- into the LIE, and returns a HsWrapper to enclose the call site.
-- This is the key place where equality predicates
-- are unleashed into the world
-instCallDicts loc [] = return idHsWrapper
+instCallDicts _ [] = return idHsWrapper
-- instCallDicts loc (EqPred ty1 ty2 : preds)
-- = do { unifyType ty1 ty2 -- For now, we insist that they unify right away
-------------
cloneDict :: Inst -> TcM Inst
-cloneDict dict@(Dict nm ty loc) = do { uniq <- newUnique
+cloneDict dict@(Dict nm _ _) = do { uniq <- newUnique
; return (dict {tci_name = setNameUnique nm uniq}) }
cloneDict eq@(EqInst {}) = return eq
cloneDict other = pprPanic "cloneDict" (ppr other)
-- scope, so we make up a new namea.
newIPDict :: InstOrigin -> IPName Name -> Type
-> TcM (IPName Id, Inst)
-newIPDict orig ip_name ty
- = getInstLoc orig `thenM` \ inst_loc ->
- newUnique `thenM` \ uniq ->
+newIPDict orig ip_name ty = do
+ inst_loc <- getInstLoc orig
+ uniq <- newUnique
let
pred = IParam ip_name ty
name = mkPredName uniq inst_loc pred
dict = Dict {tci_name = name, tci_pred = pred, tci_loc = inst_loc}
- in
- returnM (mapIPName (\n -> instToId dict) ip_name, dict)
+
+ return (mapIPName (\_ -> instToId dict) ip_name, dict)
\end{code}
\begin{code}
newMethodFromName :: InstOrigin -> BoxyRhoType -> Name -> TcM TcId
-newMethodFromName origin ty name
- = tcLookupId name `thenM` \ id ->
+newMethodFromName origin ty name = do
+ id <- tcLookupId name
-- Use tcLookupId not tcLookupGlobalId; the method is almost
- -- always a class op, but with -fno-implicit-prelude GHC is
+ -- always a class op, but with -XNoImplicitPrelude GHC is
-- meant to find whatever thing is in scope, and that may
-- be an ordinary function.
- getInstLoc origin `thenM` \ loc ->
- tcInstClassOp loc id [ty] `thenM` \ inst ->
- extendLIE inst `thenM_`
- returnM (instToId inst)
-
-newMethodWithGivenTy orig id tys
- = getInstLoc orig `thenM` \ loc ->
- newMethod loc id tys `thenM` \ inst ->
- extendLIE inst `thenM_`
- returnM (instToId inst)
+ loc <- getInstLoc origin
+ inst <- tcInstClassOp loc id [ty]
+ extendLIE inst
+ return (instToId inst)
+
+newMethodWithGivenTy :: InstOrigin -> Id -> [Type] -> TcRn TcId
+newMethodWithGivenTy orig id tys = do
+ loc <- getInstLoc orig
+ inst <- newMethod loc id tys
+ extendLIE inst
+ return (instToId inst)
--------------------------------------------
-- tcInstClassOp, and newMethod do *not* drop the
-- Hence the call to checkKind
-- A worry: is this needed anywhere else?
tcInstClassOp :: InstLoc -> Id -> [TcType] -> TcM Inst
-tcInstClassOp inst_loc sel_id tys
- = let
+tcInstClassOp inst_loc sel_id tys = do
+ let
(tyvars, _rho) = tcSplitForAllTys (idType sel_id)
- in
- zipWithM_ checkKind tyvars tys `thenM_`
+ zipWithM_ checkKind tyvars tys
newMethod inst_loc sel_id tys
checkKind :: TyVar -> TcType -> TcM ()
---------------------------
-newMethod inst_loc id tys
- = newUnique `thenM` \ new_uniq ->
+newMethod :: InstLoc -> Id -> [Type] -> TcRn Inst
+newMethod inst_loc id tys = do
+ new_uniq <- newUnique
let
(theta,tau) = tcSplitPhiTy (applyTys (idType id) tys)
meth_id = mkUserLocal (mkMethodOcc (getOccName id)) new_uniq tau loc
inst = Method {tci_id = meth_id, tci_oid = id, tci_tys = tys,
tci_theta = theta, tci_loc = inst_loc}
loc = instLocSpan inst_loc
- in
- returnM inst
+
+ return inst
\end{code}
\begin{code}
-shortCutIntLit :: Integer -> TcType -> Maybe (HsExpr TcId)
-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 ty))
- | otherwise = Nothing
-
-shortCutFracLit :: Rational -> TcType -> Maybe (HsExpr TcId)
-shortCutFracLit f ty
- | isFloatTy ty
- = Just (mk_lit floatDataCon (HsFloatPrim f))
- | isDoubleTy ty
- = Just (mk_lit doubleDataCon (HsDoublePrim f))
- | otherwise = Nothing
- where
- mk_lit con lit = HsApp (nlHsVar (dataConWrapId con)) (nlHsLit lit)
-
-shortCutStringLit :: FastString -> TcType -> Maybe (HsExpr TcId)
-shortCutStringLit s ty
- | isStringTy ty -- Short cut for String
- = Just (HsLit (HsString s))
- | otherwise = Nothing
-
-mkIntegerLit :: Integer -> TcM (LHsExpr TcId)
-mkIntegerLit i
- = tcMetaTy integerTyConName `thenM` \ integer_ty ->
- getSrcSpanM `thenM` \ span ->
- returnM (L span $ HsLit (HsInteger i integer_ty))
-
-mkRatLit :: Rational -> TcM (LHsExpr TcId)
-mkRatLit r
- = tcMetaTy rationalTyConName `thenM` \ rat_ty ->
- getSrcSpanM `thenM` \ span ->
- returnM (L span $ HsLit (HsRat r rat_ty))
-
-mkStrLit :: FastString -> TcM (LHsExpr TcId)
-mkStrLit s
- = --tcMetaTy stringTyConName `thenM` \ string_ty ->
- getSrcSpanM `thenM` \ span ->
- returnM (L span $ HsLit (HsString s))
+mkOverLit :: OverLitVal -> TcM HsLit
+mkOverLit (HsIntegral i)
+ = do { integer_ty <- tcMetaTy integerTyConName
+ ; return (HsInteger i integer_ty) }
+
+mkOverLit (HsFractional r)
+ = do { rat_ty <- tcMetaTy rationalTyConName
+ ; return (HsRat r rat_ty) }
+
+mkOverLit (HsIsString s) = return (HsString s)
isHsVar :: HsExpr Name -> Name -> Bool
-isHsVar (HsVar f) g = f==g
-isHsVar other g = False
+isHsVar (HsVar f) g = f == g
+isHsVar _ _ = False
\end{code}
\begin{code}
zonkInst :: Inst -> TcM Inst
-zonkInst dict@(Dict { tci_pred = pred})
- = zonkTcPredType pred `thenM` \ new_pred ->
- returnM (dict {tci_pred = new_pred})
+zonkInst dict@(Dict { tci_pred = pred}) = do
+ new_pred <- zonkTcPredType pred
+ return (dict {tci_pred = new_pred})
-zonkInst meth@(Method {tci_oid = id, tci_tys = tys, tci_theta = theta})
- = zonkId id `thenM` \ new_id ->
+zonkInst meth@(Method {tci_oid = id, tci_tys = tys, tci_theta = theta}) = do
+ new_id <- zonkId 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 `thenM` \ new_tys ->
- zonkTcThetaType theta `thenM` \ new_theta ->
- returnM (meth { tci_oid = new_id, tci_tys = new_tys, tci_theta = new_theta })
+ new_tys <- zonkTcTypes tys
+ new_theta <- zonkTcThetaType theta
+ return (meth { tci_oid = new_id, tci_tys = new_tys, tci_theta = new_theta })
-- No need to zonk the tci_id
-zonkInst lit@(LitInst {tci_ty = ty})
- = zonkTcType ty `thenM` \ new_ty ->
- returnM (lit {tci_ty = new_ty})
+zonkInst lit@(LitInst {tci_ty = ty}) = do
+ new_ty <- zonkTcType ty
+ return (lit {tci_ty = new_ty})
zonkInst implic@(ImplicInst {})
= ASSERT( all isImmutableTyVar (tci_tyvars implic) )
zonkInst eqinst@(EqInst {tci_left = ty1, tci_right = ty2})
= do { co' <- eitherEqInst eqinst
- (\covar -> return (mkWantedCo covar))
- (\co -> zonkTcType co >>= \coercion -> return (mkGivenCo coercion))
+ (\covar -> return (mkWantedCo covar))
+ (\co -> liftM mkGivenCo $ zonkTcType co)
; ty1' <- zonkTcType ty1
; ty2' <- zonkTcType ty2
- ; return (eqinst {tci_co = co',tci_left=ty1',tci_right=ty2})
+ ; return (eqinst {tci_co = co', tci_left= ty1', tci_right = ty2' })
}
-zonkInsts insts = mappM zonkInst insts
+zonkInsts :: [Inst] -> TcRn [Inst]
+zonkInsts insts = mapM zonkInst insts
\end{code}
pprInst, pprInstInFull :: Inst -> SDoc
-- Debugging: print the evidence :: type
-pprInst i@(EqInst {tci_left = ty1, tci_right = ty2, tci_co = co})
+pprInst i@(EqInst {tci_left = ty1, tci_right = ty2})
= eitherEqInst i
(\covar -> text "Wanted" <+> ppr (TyVarTy covar) <+> dcolon <+> ppr (EqPred ty1 ty2))
(\co -> text "Given" <+> ppr co <+> dcolon <+> ppr (EqPred ty1 ty2))
-pprInst inst = ppr (instName inst) <+> dcolon
- <+> (braces (ppr (instType inst)) $$
- ifPprDebug implic_stuff)
+pprInst inst = ppr name <> braces (pprUnique (getUnique name)) <+> dcolon
+ <+> braces (ppr (instType inst) <> implicWantedEqs)
where
- implic_stuff | isImplicInst inst = ppr (tci_reft inst)
- | otherwise = empty
+ name = instName inst
+ implicWantedEqs
+ | isImplicInst inst = text " &" <+>
+ ppr (filter isEqInst (tci_wanted inst))
+ | otherwise = empty
pprInstInFull inst@(EqInst {}) = pprInst inst
pprInstInFull inst = sep [quotes (pprInst inst), nest 2 (pprInstArising inst)]
; return overlap_flag }
+traceDFuns :: [Instance] -> TcRn ()
traceDFuns ispecs
= traceTc (hang (text "Adding instances:") 2 (vcat (map pp ispecs)))
where
pp ispec = ppr (instanceDFunId ispec) <+> colon <+> ppr ispec
-- Print the dfun name itself too
+funDepErr :: Instance -> [Instance] -> TcRn ()
funDepErr ispec ispecs
= addDictLoc ispec $
- addErr (hang (ptext SLIT("Functional dependencies conflict between instance declarations:"))
+ addErr (hang (ptext (sLit "Functional dependencies conflict between instance declarations:"))
2 (pprInstances (ispec:ispecs)))
+dupInstErr :: Instance -> Instance -> TcRn ()
dupInstErr ispec dup_ispec
= addDictLoc ispec $
- addErr (hang (ptext SLIT("Duplicate instance declarations:"))
+ addErr (hang (ptext (sLit "Duplicate instance declarations:"))
2 (pprInstances [ispec, dup_ispec]))
+addDictLoc :: Instance -> TcRn a -> TcRn a
addDictLoc ispec thing_inside
= setSrcSpan (mkSrcSpan loc loc) thing_inside
where
-- [Same shortcut as in newOverloadedLit, but we
-- may have done some unification by now]
-lookupSimpleInst (LitInst {tci_lit = HsIntegral i from_integer_name, tci_ty = ty, tci_loc = loc})
- | Just expr <- shortCutIntLit i ty
- = returnM (GenInst [] (noLoc expr))
- | otherwise
- = ASSERT( from_integer_name `isHsVar` fromIntegerName ) -- A LitInst invariant
- tcLookupId fromIntegerName `thenM` \ from_integer ->
- tcInstClassOp loc from_integer [ty] `thenM` \ method_inst ->
- mkIntegerLit i `thenM` \ integer_lit ->
- returnM (GenInst [method_inst]
- (mkHsApp (L (instLocSpan loc)
- (HsVar (instToId method_inst))) integer_lit))
-
-lookupSimpleInst (LitInst {tci_lit = HsFractional f from_rat_name, tci_ty = ty, tci_loc = loc})
- | Just expr <- shortCutFracLit f ty
- = returnM (GenInst [] (noLoc expr))
+lookupSimpleInst (LitInst { tci_lit = lit@OverLit { ol_val = lit_val
+ , ol_rebindable = rebindable }
+ , tci_ty = ty, tci_loc = iloc})
+ | debugIsOn && rebindable = panic "lookupSimpleInst" -- A LitInst invariant
+ | Just witness <- shortCutLit lit_val ty
+ = do { let lit' = lit { ol_witness = witness, ol_type = ty }
+ ; return (GenInst [] (L loc (HsOverLit lit'))) }
| otherwise
- = ASSERT( from_rat_name `isHsVar` fromRationalName ) -- A LitInst invariant
- tcLookupId fromRationalName `thenM` \ from_rational ->
- tcInstClassOp loc from_rational [ty] `thenM` \ method_inst ->
- mkRatLit f `thenM` \ rat_lit ->
- returnM (GenInst [method_inst] (mkHsApp (L (instLocSpan loc)
- (HsVar (instToId method_inst))) rat_lit))
-
-lookupSimpleInst (LitInst {tci_lit = HsIsString s from_string_name, tci_ty = ty, tci_loc = loc})
- | Just expr <- shortCutStringLit s ty
- = returnM (GenInst [] (noLoc expr))
- | otherwise
- = ASSERT( from_string_name `isHsVar` fromStringName ) -- A LitInst invariant
- tcLookupId fromStringName `thenM` \ from_string ->
- tcInstClassOp loc from_string [ty] `thenM` \ method_inst ->
- mkStrLit s `thenM` \ string_lit ->
- returnM (GenInst [method_inst]
- (mkHsApp (L (instLocSpan loc)
- (HsVar (instToId method_inst))) string_lit))
+ = do { hs_lit <- mkOverLit lit_val
+ ; from_thing <- tcLookupId (hsOverLitName lit_val)
+ -- Not rebindable, so hsOverLitName is the right thing
+ ; method_inst <- tcInstClassOp iloc from_thing [ty]
+ ; let witness = HsApp (L loc (HsVar (instToId method_inst)))
+ (L loc (HsLit hs_lit))
+ lit' = lit { ol_witness = witness, ol_type = ty }
+ ; return (GenInst [method_inst] (L loc (HsOverLit lit'))) }
+ where
+ loc = instLocSpan iloc
--------------------- Dictionaries ------------------------
lookupSimpleInst (Dict {tci_pred = pred, tci_loc = loc})
Just (dfun_id, mb_inst_tys) -> do
{ use_stage <- getStage
- ; checkWellStaged (ptext SLIT("instance for") <+> quotes (ppr pred))
+ ; checkWellStaged (ptext (sLit "instance for") <+> quotes (ppr pred))
(topIdLvl dfun_id) use_stage
-- It's possible that not all the tyvars are in
; let inst_tv (Left tv) = do { tv' <- tcInstTyVar tv; return (mkTyVarTy tv') }
inst_tv (Right ty) = return ty
- ; tys <- mappM inst_tv mb_inst_tys
+ ; tys <- mapM inst_tv mb_inst_tys
; let
(theta, _) = tcSplitPhiTy (applyTys (idType dfun_id) tys)
src_loc = instLocSpan loc
dfun = HsVar dfun_id
; if null theta then
- returnM (GenInst [] (L src_loc $ HsWrap (mkWpTyApps tys) dfun))
+ return (GenInst [] (L src_loc $ HsWrap (mkWpTyApps tys) dfun))
else do
{ (dict_app, dicts) <- getLIE $ instCallDicts loc theta -- !!!
; let co_fn = dict_app <.> mkWpTyApps tys
- ; returnM (GenInst dicts (L src_loc $ HsWrap co_fn dfun))
+ ; return (GenInst dicts (L src_loc $ HsWrap co_fn dfun))
}}}}
---------------
; return Nothing }
}}
-lookupPred ip_pred = return Nothing -- Implicit parameters
+lookupPred (IParam {}) = return Nothing -- Implicit parameters
+lookupPred (EqPred {}) = panic "lookupPred EqPred"
+record_dfun_usage :: Id -> TcRn ()
record_dfun_usage dfun_id
= do { hsc_env <- getTopEnv
; let dfun_name = idName dfun_id
%* *
%************************************************************************
-Suppose we are doing the -fno-implicit-prelude thing, and we encounter
+Suppose we are doing the -XNoImplicitPrelude 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
tcSyntaxName orig ty (std_nm, HsVar user_nm)
| std_nm == user_nm
- = newMethodFromName orig ty std_nm `thenM` \ id ->
- returnM (std_nm, HsVar id)
+ = do id <- newMethodFromName orig ty std_nm
+ return (std_nm, HsVar id)
-tcSyntaxName orig ty (std_nm, user_nm_expr)
- = tcLookupId std_nm `thenM` \ std_id ->
+tcSyntaxName orig ty (std_nm, user_nm_expr) = do
+ std_id <- tcLookupId std_nm
let
-- C.f. newMethodAtLoc
([tv], _, tau) = tcSplitSigmaTy (idType std_id)
sigma1 = substTyWith [tv] [ty] tau
-- Actually, the "tau-type" might be a sigma-type in the
-- case of locally-polymorphic methods.
- in
- addErrCtxtM (syntaxNameCtxt user_nm_expr orig sigma1) $
+
+ addErrCtxtM (syntaxNameCtxt user_nm_expr orig sigma1) $ do
-- Check that the user-supplied thing has the
-- same type as the standard one.
-- Tiresome jiggling because tcCheckSigma takes a located expression
- getSrcSpanM `thenM` \ span ->
- tcPolyExpr (L span user_nm_expr) sigma1 `thenM` \ expr ->
- returnM (std_nm, unLoc expr)
-
-syntaxNameCtxt name orig ty tidy_env
- = getInstLoc orig `thenM` \ inst_loc ->
+ span <- getSrcSpanM
+ expr <- tcPolyExpr (L span user_nm_expr) sigma1
+ return (std_nm, unLoc expr)
+
+syntaxNameCtxt :: HsExpr Name -> InstOrigin -> Type -> TidyEnv
+ -> TcRn (TidyEnv, SDoc)
+syntaxNameCtxt name orig ty tidy_env = do
+ inst_loc <- getInstLoc orig
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 (ptext SLIT("arising from") <+> pprInstLoc inst_loc)]
- in
- returnM (tidy_env, msg)
+ 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 (ptext (sLit "arising from") <+> pprInstLoc inst_loc)]
+
+ return (tidy_env, msg)
\end{code}
%************************************************************************
= case either_co of
Left covar -> withWanted covar
Right co -> withGiven co
+eitherEqInst i _ _ = pprPanic "eitherEqInst" (ppr i)
mkEqInsts :: [PredType] -> [Either TcTyVar Coercion] -> TcM [Inst]
mkEqInsts preds cos = zipWithM mkEqInst preds cos
; return inst
}
where mkName uniq src_span = mkInternalName uniq (mkVarOcc "co") src_span
+mkEqInst pred _ = pprPanic "mkEqInst" (ppr pred)
mkWantedEqInst :: PredType -> TcM Inst
mkWantedEqInst pred@(EqPred ty1 ty2)
= do { cotv <- newMetaCoVar ty1 ty2
; mkEqInst pred (Left cotv)
}
+mkWantedEqInst pred = pprPanic "mkWantedEqInst" (ppr pred)
-- type inference:
-- We want to promote the wanted EqInst to a given EqInst
; let given = wanted { tci_co = mkGivenCo $ TyVarTy var }
; return given
}
+finalizeEqInst i = pprPanic "finalizeEqInst" (ppr i)
writeWantedCoercion
:: Inst -- wanted EqInst
eqInstCoercion :: Inst -> Either TcTyVar Coercion
eqInstCoercion = tci_co
-eqInstLeftTy, eqInstRightTy :: Inst -> TcType
-eqInstLeftTy = tci_left
-eqInstRightTy = tci_right
+eqInstTys :: Inst -> (TcType, TcType)
+eqInstTys inst = (tci_left inst, tci_right inst)
updateEqInstCoercion :: (Either TcTyVar Coercion -> Either TcTyVar Coercion) -> Inst -> Inst
updateEqInstCoercion f inst = inst {tci_co = f $ tci_co inst}