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|
{-
(c) The University of Glasgow 2006
(c) The GRASP/AQUA Project, Glasgow University, 1992-1998
-}
{-# LANGUAGE CPP, MultiWayIf, TupleSections #-}
{-# LANGUAGE FlexibleContexts #-}
{-# OPTIONS_GHC -Wno-incomplete-uni-patterns #-}
{-# OPTIONS_GHC -Wno-incomplete-record-updates #-}
module GHC.Tc.Utils.Instantiate (
topSkolemise,
topInstantiate, instantiateSigma,
instCall, instDFunType, instStupidTheta, instTyVarsWith,
newWanted, newWanteds,
tcInstType, tcInstTypeBndrs,
tcInstSkolTyVars, tcInstSkolTyVarsX, tcInstSkolTyVarsAt,
tcSkolDFunType, tcSuperSkolTyVars, tcInstSuperSkolTyVarsX,
freshenTyVarBndrs, freshenCoVarBndrsX,
tcInstInvisibleTyBindersN, tcInstInvisibleTyBinders, tcInstInvisibleTyBinder,
newOverloadedLit, mkOverLit,
newClsInst,
tcGetInsts, tcGetInstEnvs, getOverlapFlag,
tcExtendLocalInstEnv,
instCallConstraints, newMethodFromName,
tcSyntaxName,
-- Simple functions over evidence variables
tyCoVarsOfWC,
tyCoVarsOfCt, tyCoVarsOfCts,
) where
#include "HsVersions.h"
import GHC.Prelude
import {-# SOURCE #-} GHC.Tc.Gen.Expr( tcCheckPolyExpr, tcSyntaxOp )
import {-# SOURCE #-} GHC.Tc.Utils.Unify( unifyType, unifyKind )
import GHC.Types.Basic ( IntegralLit(..), SourceText(..) )
import GHC.Hs
import GHC.Tc.Utils.Zonk
import GHC.Tc.Utils.Monad
import GHC.Tc.Types.Constraint
import GHC.Core.Predicate
import GHC.Tc.Types.Origin
import GHC.Tc.Utils.Env
import GHC.Tc.Types.Evidence
import GHC.Core.InstEnv
import GHC.Builtin.Types ( heqDataCon, eqDataCon, integerTyConName )
import GHC.Core ( isOrphan )
import GHC.Tc.Instance.FunDeps
import GHC.Tc.Utils.TcMType
import GHC.Core.Type
import GHC.Core.Multiplicity
import GHC.Core.TyCo.Rep
import GHC.Core.TyCo.Ppr ( debugPprType )
import GHC.Tc.Utils.TcType
import GHC.Driver.Types
import GHC.Core.Class( Class )
import GHC.Types.Id.Make( mkDictFunId )
import GHC.Core( Expr(..) ) -- For the Coercion constructor
import GHC.Types.Id
import GHC.Types.Name
import GHC.Types.Var
import GHC.Core.DataCon
import GHC.Types.Var.Env
import GHC.Types.Var.Set
import GHC.Builtin.Names
import GHC.Types.SrcLoc as SrcLoc
import GHC.Driver.Session
import GHC.Utils.Misc
import GHC.Utils.Panic
import GHC.Utils.Outputable
import GHC.Types.Basic ( TypeOrKind(..) )
import qualified GHC.LanguageExtensions as LangExt
import GHC.Unit.State
import Data.List ( sortBy, mapAccumL )
import Control.Monad( unless )
import Data.Function ( on )
{-
************************************************************************
* *
Creating and emittind constraints
* *
************************************************************************
-}
newMethodFromName
:: CtOrigin -- ^ why do we need this?
-> Name -- ^ name of the method
-> [TcRhoType] -- ^ types with which to instantiate the class
-> TcM (HsExpr GhcTc)
-- ^ Used when 'Name' is the wired-in name for a wired-in class method,
-- so the caller knows its type for sure, which should be of form
--
-- > forall a. C a => <blah>
--
-- 'newMethodFromName' is supposed to instantiate just the outer
-- type variable and constraint
newMethodFromName origin name ty_args
= do { id <- tcLookupId name
-- Use tcLookupId not tcLookupGlobalId; the method is almost
-- always a class op, but with -XRebindableSyntax GHC is
-- meant to find whatever thing is in scope, and that may
-- be an ordinary function.
; let ty = piResultTys (idType id) ty_args
(theta, _caller_knows_this) = tcSplitPhiTy ty
; wrap <- ASSERT( not (isForAllTy ty) && isSingleton theta )
instCall origin ty_args theta
; return (mkHsWrap wrap (HsVar noExtField (noLoc id))) }
{-
************************************************************************
* *
Instantiation and skolemisation
* *
************************************************************************
Note [Skolemisation]
~~~~~~~~~~~~~~~~~~~~
topSkolemise decomposes and skolemises a type, returning a type
with no top level foralls or (=>)
Examples:
topSkolemise (forall a. Ord a => a -> a)
= ( wp, [a], [d:Ord a], a->a )
where wp = /\a. \(d:Ord a). <hole> a d
topSkolemise (forall a. Ord a => forall b. Eq b => a->b->b)
= ( wp, [a,b], [d1:Ord a,d2:Eq b], a->b->b )
where wp = /\a.\(d1:Ord a)./\b.\(d2:Ord b). <hole> a d1 b d2
This second example is the reason for the recursive 'go'
function in topSkolemise: we must remove successive layers
of foralls and (=>).
In general,
if topSkolemise ty = (wrap, tvs, evs, rho)
and e :: rho
then wrap e :: ty
and 'wrap' binds {tvs, evs}
-}
topSkolemise :: TcSigmaType
-> TcM ( HsWrapper
, [(Name,TyVar)] -- All skolemised variables
, [EvVar] -- All "given"s
, TcRhoType )
-- See Note [Skolemisation]
topSkolemise ty
= go init_subst idHsWrapper [] [] ty
where
init_subst = mkEmptyTCvSubst (mkInScopeSet (tyCoVarsOfType ty))
-- Why recursive? See Note [Skolemisation]
go subst wrap tv_prs ev_vars ty
| (tvs, theta, inner_ty) <- tcSplitSigmaTy ty
, not (null tvs && null theta)
= do { (subst', tvs1) <- tcInstSkolTyVarsX subst tvs
; ev_vars1 <- newEvVars (substTheta subst' theta)
; go subst'
(wrap <.> mkWpTyLams tvs1 <.> mkWpLams ev_vars1)
(tv_prs ++ (map tyVarName tvs `zip` tvs1))
(ev_vars ++ ev_vars1)
inner_ty }
| otherwise
= return (wrap, tv_prs, ev_vars, substTy subst ty)
-- substTy is a quick no-op on an empty substitution
-- | Instantiate all outer type variables
-- and any context. Never looks through arrows.
topInstantiate :: CtOrigin -> TcSigmaType -> TcM (HsWrapper, TcRhoType)
-- if topInstantiate ty = (wrap, rho)
-- and e :: ty
-- then wrap e :: rho (that is, wrap :: ty "->" rho)
-- NB: always returns a rho-type, with no top-level forall or (=>)
topInstantiate orig ty
| (tvs, theta, body) <- tcSplitSigmaTy ty
, not (null tvs && null theta)
= do { (_, wrap1, body1) <- instantiateSigma orig tvs theta body
-- Loop, to account for types like
-- forall a. Num a => forall b. Ord b => ...
; (wrap2, rho) <- topInstantiate orig body1
; return (wrap2 <.> wrap1, rho) }
| otherwise = return (idHsWrapper, ty)
instantiateSigma :: CtOrigin -> [TyVar] -> TcThetaType -> TcSigmaType
-> TcM ([TcTyVar], HsWrapper, TcSigmaType)
-- (instantiate orig tvs theta ty)
-- instantiates the the type variables tvs, emits the (instantiated)
-- constraints theta, and returns the (instantiated) type ty
instantiateSigma orig tvs theta body_ty
= do { (subst, inst_tvs) <- mapAccumLM newMetaTyVarX empty_subst tvs
; let inst_theta = substTheta subst theta
inst_body = substTy subst body_ty
inst_tv_tys = mkTyVarTys inst_tvs
; wrap <- instCall orig inst_tv_tys inst_theta
; traceTc "Instantiating"
(vcat [ text "origin" <+> pprCtOrigin orig
, text "tvs" <+> ppr tvs
, text "theta" <+> ppr theta
, text "type" <+> debugPprType body_ty
, text "with" <+> vcat (map debugPprType inst_tv_tys)
, text "theta:" <+> ppr inst_theta ])
; return (inst_tvs, wrap, inst_body) }
where
free_tvs = tyCoVarsOfType body_ty `unionVarSet` tyCoVarsOfTypes theta
in_scope = mkInScopeSet (free_tvs `delVarSetList` tvs)
empty_subst = mkEmptyTCvSubst in_scope
instTyVarsWith :: CtOrigin -> [TyVar] -> [TcType] -> TcM TCvSubst
-- Use this when you want to instantiate (forall a b c. ty) with
-- types [ta, tb, tc], but when the kinds of 'a' and 'ta' might
-- not yet match (perhaps because there are unsolved constraints; #14154)
-- If they don't match, emit a kind-equality to promise that they will
-- eventually do so, and thus make a kind-homongeneous substitution.
instTyVarsWith orig tvs tys
= go emptyTCvSubst tvs tys
where
go subst [] []
= return subst
go subst (tv:tvs) (ty:tys)
| tv_kind `tcEqType` ty_kind
= go (extendTvSubstAndInScope subst tv ty) tvs tys
| otherwise
= do { co <- emitWantedEq orig KindLevel Nominal ty_kind tv_kind
; go (extendTvSubstAndInScope subst tv (ty `mkCastTy` co)) tvs tys }
where
tv_kind = substTy subst (tyVarKind tv)
ty_kind = tcTypeKind ty
go _ _ _ = pprPanic "instTysWith" (ppr tvs $$ ppr tys)
{-
************************************************************************
* *
Instantiating a call
* *
************************************************************************
Note [Handling boxed equality]
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
The solver deals entirely in terms of unboxed (primitive) equality.
There should never be a boxed Wanted equality. Ever. But, what if
we are calling `foo :: forall a. (F a ~ Bool) => ...`? That equality
is boxed, so naive treatment here would emit a boxed Wanted equality.
So we simply check for this case and make the right boxing of evidence.
-}
----------------
instCall :: CtOrigin -> [TcType] -> TcThetaType -> TcM HsWrapper
-- Instantiate the constraints of a call
-- (instCall o tys theta)
-- (a) Makes fresh dictionaries as necessary for the constraints (theta)
-- (b) Throws these dictionaries into the LIE
-- (c) Returns an HsWrapper ([.] tys dicts)
instCall orig tys theta
= do { dict_app <- instCallConstraints orig theta
; return (dict_app <.> mkWpTyApps tys) }
----------------
instCallConstraints :: CtOrigin -> TcThetaType -> TcM HsWrapper
-- Instantiates the TcTheta, puts all constraints thereby generated
-- into the LIE, and returns a HsWrapper to enclose the call site.
instCallConstraints orig preds
| null preds
= return idHsWrapper
| otherwise
= do { evs <- mapM go preds
; traceTc "instCallConstraints" (ppr evs)
; return (mkWpEvApps evs) }
where
go :: TcPredType -> TcM EvTerm
go pred
| Just (Nominal, ty1, ty2) <- getEqPredTys_maybe pred -- Try short-cut #1
= do { co <- unifyType Nothing ty1 ty2
; return (evCoercion co) }
-- Try short-cut #2
| Just (tc, args@[_, _, ty1, ty2]) <- splitTyConApp_maybe pred
, tc `hasKey` heqTyConKey
= do { co <- unifyType Nothing ty1 ty2
; return (evDFunApp (dataConWrapId heqDataCon) args [Coercion co]) }
| otherwise
= emitWanted orig pred
instDFunType :: DFunId -> [DFunInstType]
-> TcM ( [TcType] -- instantiated argument types
, TcThetaType ) -- instantiated constraint
-- See Note [DFunInstType: instantiating types] in GHC.Core.InstEnv
instDFunType dfun_id dfun_inst_tys
= do { (subst, inst_tys) <- go empty_subst dfun_tvs dfun_inst_tys
; return (inst_tys, substTheta subst dfun_theta) }
where
dfun_ty = idType dfun_id
(dfun_tvs, dfun_theta, _) = tcSplitSigmaTy dfun_ty
empty_subst = mkEmptyTCvSubst (mkInScopeSet (tyCoVarsOfType dfun_ty))
-- With quantified constraints, the
-- type of a dfun may not be closed
go :: TCvSubst -> [TyVar] -> [DFunInstType] -> TcM (TCvSubst, [TcType])
go subst [] [] = return (subst, [])
go subst (tv:tvs) (Just ty : mb_tys)
= do { (subst', tys) <- go (extendTvSubstAndInScope subst tv ty)
tvs
mb_tys
; return (subst', ty : tys) }
go subst (tv:tvs) (Nothing : mb_tys)
= do { (subst', tv') <- newMetaTyVarX subst tv
; (subst'', tys) <- go subst' tvs mb_tys
; return (subst'', mkTyVarTy tv' : tys) }
go _ _ _ = pprPanic "instDFunTypes" (ppr dfun_id $$ ppr dfun_inst_tys)
----------------
instStupidTheta :: CtOrigin -> TcThetaType -> TcM ()
-- Similar to instCall, but only emit the constraints in the LIE
-- Used exclusively for the 'stupid theta' of a data constructor
instStupidTheta orig theta
= do { _co <- instCallConstraints orig theta -- Discard the coercion
; return () }
{- *********************************************************************
* *
Instantiating Kinds
* *
********************************************************************* -}
-- | Given ty::forall k1 k2. k, instantiate all the invisible forall-binders
-- returning ty @kk1 @kk2 :: k[kk1/k1, kk2/k1]
tcInstInvisibleTyBinders :: TcType -> TcKind -> TcM (TcType, TcKind)
tcInstInvisibleTyBinders ty kind
= do { (extra_args, kind') <- tcInstInvisibleTyBindersN n_invis kind
; return (mkAppTys ty extra_args, kind') }
where
n_invis = invisibleTyBndrCount kind
tcInstInvisibleTyBindersN :: Int -> TcKind -> TcM ([TcType], TcKind)
tcInstInvisibleTyBindersN 0 kind
= return ([], kind)
tcInstInvisibleTyBindersN n ty
= go n empty_subst ty
where
empty_subst = mkEmptyTCvSubst (mkInScopeSet (tyCoVarsOfType ty))
go n subst kind
| n > 0
, Just (bndr, body) <- tcSplitPiTy_maybe kind
, isInvisibleBinder bndr
= do { (subst', arg) <- tcInstInvisibleTyBinder subst bndr
; (args, inner_ty) <- go (n-1) subst' body
; return (arg:args, inner_ty) }
| otherwise
= return ([], substTy subst kind)
-- | Used only in *types*
tcInstInvisibleTyBinder :: TCvSubst -> TyBinder -> TcM (TCvSubst, TcType)
tcInstInvisibleTyBinder subst (Named (Bndr tv _))
= do { (subst', tv') <- newMetaTyVarX subst tv
; return (subst', mkTyVarTy tv') }
tcInstInvisibleTyBinder subst (Anon af ty)
| Just (mk, k1, k2) <- get_eq_tys_maybe (substTy subst (scaledThing ty))
-- Equality is the *only* constraint currently handled in types.
-- See Note [Constraints in kinds] in GHC.Core.TyCo.Rep
= ASSERT( af == InvisArg )
do { co <- unifyKind Nothing k1 k2
; arg' <- mk co
; return (subst, arg') }
| otherwise -- This should never happen
-- See GHC.Core.TyCo.Rep Note [Constraints in kinds]
= pprPanic "tcInvisibleTyBinder" (ppr ty)
-------------------------------
get_eq_tys_maybe :: Type
-> Maybe ( Coercion -> TcM Type
-- given a coercion proving t1 ~# t2, produce the
-- right instantiation for the TyBinder at hand
, Type -- t1
, Type -- t2
)
-- See Note [Constraints in kinds] in GHC.Core.TyCo.Rep
get_eq_tys_maybe ty
-- Lifted heterogeneous equality (~~)
| Just (tc, [_, _, k1, k2]) <- splitTyConApp_maybe ty
, tc `hasKey` heqTyConKey
= Just (\co -> mkHEqBoxTy co k1 k2, k1, k2)
-- Lifted homogeneous equality (~)
| Just (tc, [_, k1, k2]) <- splitTyConApp_maybe ty
, tc `hasKey` eqTyConKey
= Just (\co -> mkEqBoxTy co k1 k2, k1, k2)
| otherwise
= Nothing
-- | This takes @a ~# b@ and returns @a ~~ b@.
mkHEqBoxTy :: TcCoercion -> Type -> Type -> TcM Type
-- monadic just for convenience with mkEqBoxTy
mkHEqBoxTy co ty1 ty2
= return $
mkTyConApp (promoteDataCon heqDataCon) [k1, k2, ty1, ty2, mkCoercionTy co]
where k1 = tcTypeKind ty1
k2 = tcTypeKind ty2
-- | This takes @a ~# b@ and returns @a ~ b@.
mkEqBoxTy :: TcCoercion -> Type -> Type -> TcM Type
mkEqBoxTy co ty1 ty2
= return $
mkTyConApp (promoteDataCon eqDataCon) [k, ty1, ty2, mkCoercionTy co]
where k = tcTypeKind ty1
{- *********************************************************************
* *
SkolemTvs (immutable)
* *
********************************************************************* -}
tcInstType :: ([TyVar] -> TcM (TCvSubst, [TcTyVar]))
-- ^ How to instantiate the type variables
-> Id -- ^ Type to instantiate
-> TcM ([(Name, TcTyVar)], TcThetaType, TcType) -- ^ Result
-- (type vars, preds (incl equalities), rho)
tcInstType inst_tyvars id
| null tyvars -- There may be overloading despite no type variables;
-- (?x :: Int) => Int -> Int
= return ([], theta, tau)
| otherwise
= do { (subst, tyvars') <- inst_tyvars tyvars
; let tv_prs = map tyVarName tyvars `zip` tyvars'
subst' = extendTCvInScopeSet subst (tyCoVarsOfType rho)
; return (tv_prs, substTheta subst' theta, substTy subst' tau) }
where
(tyvars, rho) = tcSplitForAllTys (idType id)
(theta, tau) = tcSplitPhiTy rho
tcInstTypeBndrs :: Id -> TcM ([(Name, InvisTVBinder)], TcThetaType, TcType)
-- (type vars, preds (incl equalities), rho)
-- Instantiate the binders of a type signature with TyVarTvs
tcInstTypeBndrs id
| null tyvars -- There may be overloading despite no type variables;
-- (?x :: Int) => Int -> Int
= return ([], theta, tau)
| otherwise
= do { (subst, tyvars') <- mapAccumLM inst_invis_bndr emptyTCvSubst tyvars
; let tv_prs = map (tyVarName . binderVar) tyvars `zip` tyvars'
subst' = extendTCvInScopeSet subst (tyCoVarsOfType rho)
; return (tv_prs, substTheta subst' theta, substTy subst' tau) }
where
(tyvars, rho) = splitForAllTysInvis (idType id)
(theta, tau) = tcSplitPhiTy rho
inst_invis_bndr :: TCvSubst -> InvisTVBinder
-> TcM (TCvSubst, InvisTVBinder)
inst_invis_bndr subst (Bndr tv spec)
= do { (subst', tv') <- newMetaTyVarTyVarX subst tv
; return (subst', Bndr tv' spec) }
tcSkolDFunType :: DFunId -> TcM ([TcTyVar], TcThetaType, TcType)
-- Instantiate a type signature with skolem constants.
-- We could give them fresh names, but no need to do so
tcSkolDFunType dfun
= do { (tv_prs, theta, tau) <- tcInstType tcInstSuperSkolTyVars dfun
; return (map snd tv_prs, theta, tau) }
tcSuperSkolTyVars :: [TyVar] -> (TCvSubst, [TcTyVar])
-- Make skolem constants, but do *not* give them new names, as above
-- Moreover, make them "super skolems"; see comments with superSkolemTv
-- see Note [Kind substitution when instantiating]
-- Precondition: tyvars should be ordered by scoping
tcSuperSkolTyVars = mapAccumL tcSuperSkolTyVar emptyTCvSubst
tcSuperSkolTyVar :: TCvSubst -> TyVar -> (TCvSubst, TcTyVar)
tcSuperSkolTyVar subst tv
= (extendTvSubstWithClone subst tv new_tv, new_tv)
where
kind = substTyUnchecked subst (tyVarKind tv)
new_tv = mkTcTyVar (tyVarName tv) kind superSkolemTv
-- | Given a list of @['TyVar']@, skolemize the type variables,
-- returning a substitution mapping the original tyvars to the
-- skolems, and the list of newly bound skolems.
tcInstSkolTyVars :: [TyVar] -> TcM (TCvSubst, [TcTyVar])
-- See Note [Skolemising type variables]
tcInstSkolTyVars = tcInstSkolTyVarsX emptyTCvSubst
tcInstSkolTyVarsX :: TCvSubst -> [TyVar] -> TcM (TCvSubst, [TcTyVar])
-- See Note [Skolemising type variables]
tcInstSkolTyVarsX = tcInstSkolTyVarsPushLevel False
tcInstSuperSkolTyVars :: [TyVar] -> TcM (TCvSubst, [TcTyVar])
-- See Note [Skolemising type variables]
tcInstSuperSkolTyVars = tcInstSuperSkolTyVarsX emptyTCvSubst
tcInstSuperSkolTyVarsX :: TCvSubst -> [TyVar] -> TcM (TCvSubst, [TcTyVar])
-- See Note [Skolemising type variables]
tcInstSuperSkolTyVarsX subst = tcInstSkolTyVarsPushLevel True subst
tcInstSkolTyVarsPushLevel :: Bool -> TCvSubst -> [TyVar]
-> TcM (TCvSubst, [TcTyVar])
-- Skolemise one level deeper, hence pushTcLevel
-- See Note [Skolemising type variables]
tcInstSkolTyVarsPushLevel overlappable subst tvs
= do { tc_lvl <- getTcLevel
; let pushed_lvl = pushTcLevel tc_lvl
; tcInstSkolTyVarsAt pushed_lvl overlappable subst tvs }
tcInstSkolTyVarsAt :: TcLevel -> Bool
-> TCvSubst -> [TyVar]
-> TcM (TCvSubst, [TcTyVar])
tcInstSkolTyVarsAt lvl overlappable subst tvs
= freshenTyCoVarsX new_skol_tv subst tvs
where
details = SkolemTv lvl overlappable
new_skol_tv name kind = mkTcTyVar name kind details
------------------
freshenTyVarBndrs :: [TyVar] -> TcM (TCvSubst, [TyVar])
-- ^ Give fresh uniques to a bunch of TyVars, but they stay
-- as TyVars, rather than becoming TcTyVars
-- Used in 'GHC.Tc.Instance.Family.newFamInst', and 'GHC.Tc.Utils.Instantiate.newClsInst'
freshenTyVarBndrs = freshenTyCoVars mkTyVar
freshenCoVarBndrsX :: TCvSubst -> [CoVar] -> TcM (TCvSubst, [CoVar])
-- ^ Give fresh uniques to a bunch of CoVars
-- Used in "GHC.Tc.Instance.Family.newFamInst"
freshenCoVarBndrsX subst = freshenTyCoVarsX mkCoVar subst
------------------
freshenTyCoVars :: (Name -> Kind -> TyCoVar)
-> [TyVar] -> TcM (TCvSubst, [TyCoVar])
freshenTyCoVars mk_tcv = freshenTyCoVarsX mk_tcv emptyTCvSubst
freshenTyCoVarsX :: (Name -> Kind -> TyCoVar)
-> TCvSubst -> [TyCoVar]
-> TcM (TCvSubst, [TyCoVar])
freshenTyCoVarsX mk_tcv = mapAccumLM (freshenTyCoVarX mk_tcv)
freshenTyCoVarX :: (Name -> Kind -> TyCoVar)
-> TCvSubst -> TyCoVar -> TcM (TCvSubst, TyCoVar)
-- This a complete freshening operation:
-- the skolems have a fresh unique, and a location from the monad
-- See Note [Skolemising type variables]
freshenTyCoVarX mk_tcv subst tycovar
= do { loc <- getSrcSpanM
; uniq <- newUnique
; let old_name = tyVarName tycovar
new_name = mkInternalName uniq (getOccName old_name) loc
new_kind = substTyUnchecked subst (tyVarKind tycovar)
new_tcv = mk_tcv new_name new_kind
subst1 = extendTCvSubstWithClone subst tycovar new_tcv
; return (subst1, new_tcv) }
{- Note [Skolemising type variables]
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
The tcInstSkolTyVars family of functions instantiate a list of TyVars
to fresh skolem TcTyVars. Important notes:
a) Level allocation. We generally skolemise /before/ calling
pushLevelAndCaptureConstraints. So we want their level to the level
of the soon-to-be-created implication, which has a level ONE HIGHER
than the current level. Hence the pushTcLevel. It feels like a
slight hack.
b) The [TyVar] should be ordered (kind vars first)
See Note [Kind substitution when instantiating]
c) It's a complete freshening operation: the skolems have a fresh
unique, and a location from the monad
d) The resulting skolems are
non-overlappable for tcInstSkolTyVars,
but overlappable for tcInstSuperSkolTyVars
See GHC.Tc.Deriv.Infer Note [Overlap and deriving] for an example
of where this matters.
Note [Kind substitution when instantiating]
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
When we instantiate a bunch of kind and type variables, first we
expect them to be topologically sorted.
Then we have to instantiate the kind variables, build a substitution
from old variables to the new variables, then instantiate the type
variables substituting the original kind.
Exemple: If we want to instantiate
[(k1 :: *), (k2 :: *), (a :: k1 -> k2), (b :: k1)]
we want
[(?k1 :: *), (?k2 :: *), (?a :: ?k1 -> ?k2), (?b :: ?k1)]
instead of the bogus
[(?k1 :: *), (?k2 :: *), (?a :: k1 -> k2), (?b :: k1)]
-}
{- *********************************************************************
* *
Literals
* *
********************************************************************* -}
{-
In newOverloadedLit we convert directly to an Int or Integer if we
know that's what we want. This may save some time, by not
temporarily generating overloaded literals, but it won't catch all
cases (the rest are caught in lookupInst).
-}
newOverloadedLit :: HsOverLit GhcRn
-> ExpRhoType
-> TcM (HsOverLit GhcTc)
newOverloadedLit
lit@(OverLit { ol_val = val, ol_ext = rebindable }) res_ty
| not rebindable
= do { res_ty <- expTypeToType res_ty
; dflags <- getDynFlags
; let platform = targetPlatform dflags
; case shortCutLit platform val res_ty of
-- Do not generate a LitInst for rebindable syntax.
-- Reason: If we do, tcSimplify will call lookupInst, which
-- will call tcSyntaxName, which does unification,
-- which tcSimplify doesn't like
Just expr -> return (lit { ol_witness = expr
, ol_ext = OverLitTc False res_ty })
Nothing -> newNonTrivialOverloadedLit orig lit
(mkCheckExpType res_ty) }
| otherwise
= newNonTrivialOverloadedLit orig lit res_ty
where
orig = LiteralOrigin lit
-- Does not handle things that 'shortCutLit' can handle. See also
-- newOverloadedLit in GHC.Tc.Utils.Unify
newNonTrivialOverloadedLit :: CtOrigin
-> HsOverLit GhcRn
-> ExpRhoType
-> TcM (HsOverLit GhcTc)
newNonTrivialOverloadedLit orig
lit@(OverLit { ol_val = val, ol_witness = HsVar _ (L _ meth_name)
, ol_ext = rebindable }) res_ty
= do { hs_lit <- mkOverLit val
; let lit_ty = hsLitType hs_lit
; (_, fi') <- tcSyntaxOp orig (mkRnSyntaxExpr meth_name)
[synKnownType lit_ty] res_ty $
\_ _ -> return ()
; let L _ witness = nlHsSyntaxApps fi' [nlHsLit hs_lit]
; res_ty <- readExpType res_ty
; return (lit { ol_witness = witness
, ol_ext = OverLitTc rebindable res_ty }) }
newNonTrivialOverloadedLit _ lit _
= pprPanic "newNonTrivialOverloadedLit" (ppr lit)
------------
mkOverLit ::OverLitVal -> TcM (HsLit GhcTc)
mkOverLit (HsIntegral i)
= do { integer_ty <- tcMetaTy integerTyConName
; return (HsInteger (il_text i)
(il_value i) integer_ty) }
mkOverLit (HsFractional r)
= do { rat_ty <- tcMetaTy rationalTyConName
; return (HsRat noExtField r rat_ty) }
mkOverLit (HsIsString src s) = return (HsString src s)
{-
************************************************************************
* *
Re-mappable syntax
Used only for arrow syntax -- find a way to nuke this
* *
************************************************************************
Suppose we are doing the -XRebindableSyntax 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.
-}
tcSyntaxName :: CtOrigin
-> TcType -- ^ Type to instantiate it at
-> (Name, HsExpr GhcRn) -- ^ (Standard name, user name)
-> TcM (Name, HsExpr GhcTc)
-- ^ (Standard name, suitable expression)
-- USED ONLY FOR CmdTop (sigh) ***
-- See Note [CmdSyntaxTable] in "GHC.Hs.Expr"
tcSyntaxName orig ty (std_nm, HsVar _ (L _ user_nm))
| std_nm == user_nm
= do rhs <- newMethodFromName orig std_nm [ty]
return (std_nm, rhs)
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.
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
span <- getSrcSpanM
expr <- tcCheckPolyExpr (L span user_nm_expr) sigma1
return (std_nm, unLoc expr)
syntaxNameCtxt :: HsExpr GhcRn -> CtOrigin -> Type -> TidyEnv
-> TcRn (TidyEnv, SDoc)
syntaxNameCtxt name orig ty tidy_env
= do { inst_loc <- getCtLocM orig (Just TypeLevel)
; let msg = vcat [ text "When checking that" <+> quotes (ppr name)
<+> text "(needed by a syntactic construct)"
, nest 2 (text "has the required type:"
<+> ppr (tidyType tidy_env ty))
, nest 2 (pprCtLoc inst_loc) ]
; return (tidy_env, msg) }
{-
************************************************************************
* *
Instances
* *
************************************************************************
-}
getOverlapFlag :: Maybe OverlapMode -> TcM OverlapFlag
-- Construct the OverlapFlag from the global module flags,
-- but if the overlap_mode argument is (Just m),
-- set the OverlapMode to 'm'
getOverlapFlag overlap_mode
= do { dflags <- getDynFlags
; let overlap_ok = xopt LangExt.OverlappingInstances dflags
incoherent_ok = xopt LangExt.IncoherentInstances dflags
use x = OverlapFlag { isSafeOverlap = safeLanguageOn dflags
, overlapMode = x }
default_oflag | incoherent_ok = use (Incoherent NoSourceText)
| overlap_ok = use (Overlaps NoSourceText)
| otherwise = use (NoOverlap NoSourceText)
final_oflag = setOverlapModeMaybe default_oflag overlap_mode
; return final_oflag }
tcGetInsts :: TcM [ClsInst]
-- Gets the local class instances.
tcGetInsts = fmap tcg_insts getGblEnv
newClsInst :: Maybe OverlapMode -> Name -> [TyVar] -> ThetaType
-> Class -> [Type] -> TcM ClsInst
newClsInst overlap_mode dfun_name tvs theta clas tys
= do { (subst, tvs') <- freshenTyVarBndrs tvs
-- Be sure to freshen those type variables,
-- so they are sure not to appear in any lookup
; let tys' = substTys subst tys
dfun = mkDictFunId dfun_name tvs theta clas tys
-- The dfun uses the original 'tvs' because
-- (a) they don't need to be fresh
-- (b) they may be mentioned in the ib_binds field of
-- an InstInfo, and in GHC.Tc.Utils.Env.pprInstInfoDetails it's
-- helpful to use the same names
; oflag <- getOverlapFlag overlap_mode
; let inst = mkLocalInstance dfun oflag tvs' clas tys'
; warnIfFlag Opt_WarnOrphans
(isOrphan (is_orphan inst))
(instOrphWarn inst)
; return inst }
instOrphWarn :: ClsInst -> SDoc
instOrphWarn inst
= hang (text "Orphan instance:") 2 (pprInstanceHdr inst)
$$ text "To avoid this"
$$ nest 4 (vcat possibilities)
where
possibilities =
text "move the instance declaration to the module of the class or of the type, or" :
text "wrap the type with a newtype and declare the instance on the new type." :
[]
tcExtendLocalInstEnv :: [ClsInst] -> TcM a -> TcM a
-- Add new locally-defined instances
tcExtendLocalInstEnv dfuns thing_inside
= do { traceDFuns dfuns
; env <- getGblEnv
; (inst_env', cls_insts') <- foldlM addLocalInst
(tcg_inst_env env, tcg_insts env)
dfuns
; let env' = env { tcg_insts = cls_insts'
, tcg_inst_env = inst_env' }
; setGblEnv env' thing_inside }
addLocalInst :: (InstEnv, [ClsInst]) -> ClsInst -> TcM (InstEnv, [ClsInst])
-- Check that the proposed new instance is OK,
-- and then add it to the home inst env
-- If overwrite_inst, then we can overwrite a direct match
addLocalInst (home_ie, my_insts) ispec
= do {
-- Load imported instances, so that we report
-- duplicates correctly
-- 'matches' are existing instance declarations that are less
-- specific than the new one
-- 'dups' are those 'matches' that are equal to the new one
; isGHCi <- getIsGHCi
; eps <- getEps
; tcg_env <- getGblEnv
-- In GHCi, we *override* any identical instances
-- that are also defined in the interactive context
-- See Note [Override identical instances in GHCi]
; let home_ie'
| isGHCi = deleteFromInstEnv home_ie ispec
| otherwise = home_ie
global_ie = eps_inst_env eps
inst_envs = InstEnvs { ie_global = global_ie
, ie_local = home_ie'
, ie_visible = tcVisibleOrphanMods tcg_env }
-- Check for inconsistent functional dependencies
; let inconsistent_ispecs = checkFunDeps inst_envs ispec
; unless (null inconsistent_ispecs) $
funDepErr ispec inconsistent_ispecs
-- Check for duplicate instance decls.
; let (_tvs, cls, tys) = instanceHead ispec
(matches, _, _) = lookupInstEnv False inst_envs cls tys
dups = filter (identicalClsInstHead ispec) (map fst matches)
; unless (null dups) $
dupInstErr ispec (head dups)
; return (extendInstEnv home_ie' ispec, ispec : my_insts) }
{-
Note [Signature files and type class instances]
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
Instances in signature files do not have an effect when compiling:
when you compile a signature against an implementation, you will
see the instances WHETHER OR NOT the instance is declared in
the file (this is because the signatures go in the EPS and we
can't filter them out easily.) This is also why we cannot
place the instance in the hi file: it would show up as a duplicate,
and we don't have instance reexports anyway.
However, you might find them useful when typechecking against
a signature: the instance is a way of indicating to GHC that
some instance exists, in case downstream code uses it.
Implementing this is a little tricky. Consider the following
situation (sigof03):
module A where
instance C T where ...
module ASig where
instance C T
When compiling ASig, A.hi is loaded, which brings its instances
into the EPS. When we process the instance declaration in ASig,
we should ignore it for the purpose of doing a duplicate check,
since it's not actually a duplicate. But don't skip the check
entirely, we still want this to fail (tcfail221):
module ASig where
instance C T
instance C T
Note that in some situations, the interface containing the type
class instances may not have been loaded yet at all. The usual
situation when A imports another module which provides the
instances (sigof02m):
module A(module B) where
import B
See also Note [Signature lazy interface loading]. We can't
rely on this, however, since sometimes we'll have spurious
type class instances in the EPS, see #9422 (sigof02dm)
************************************************************************
* *
Errors and tracing
* *
************************************************************************
-}
traceDFuns :: [ClsInst] -> TcRn ()
traceDFuns ispecs
= traceTc "Adding instances:" (vcat (map pp ispecs))
where
pp ispec = hang (ppr (instanceDFunId ispec) <+> colon)
2 (ppr ispec)
-- Print the dfun name itself too
funDepErr :: ClsInst -> [ClsInst] -> TcRn ()
funDepErr ispec ispecs
= addClsInstsErr (text "Functional dependencies conflict between instance declarations:")
(ispec : ispecs)
dupInstErr :: ClsInst -> ClsInst -> TcRn ()
dupInstErr ispec dup_ispec
= addClsInstsErr (text "Duplicate instance declarations:")
[ispec, dup_ispec]
addClsInstsErr :: SDoc -> [ClsInst] -> TcRn ()
addClsInstsErr herald ispecs = do
unit_state <- unitState <$> getDynFlags
setSrcSpan (getSrcSpan (head sorted)) $
addErr $ pprWithUnitState unit_state $ (hang herald 2 (pprInstances sorted))
where
sorted = sortBy (SrcLoc.leftmost_smallest `on` getSrcSpan) ispecs
-- The sortBy just arranges that instances are displayed in order
-- of source location, which reduced wobbling in error messages,
-- and is better for users
|