% % (c) The University of Glasgow 2006 % (c) The GRASP/AQUA Project, Glasgow University, 1992-1998 % \section[TcType]{Types used in the typechecker} This module provides the Type interface for front-end parts of the compiler. These parts * treat "source types" as opaque: newtypes, and predicates are meaningful. * look through usage types The "tc" prefix is for "TypeChecker", because the type checker is the principal client. \begin{code}
{-# OPTIONS -fno-warn-tabs #-}
-- The above warning supression flag is a temporary kludge.
-- While working on this module you are encouraged to remove it and
-- detab the module (please do the detabbing in a separate patch). See
--     http://hackage.haskell.org/trac/ghc/wiki/Commentary/CodingStyle#TabsvsSpaces
-- for details

module TcType (
  --------------------------------
  -- Types 
  TcType, TcSigmaType, TcRhoType, TcTauType, TcPredType, TcThetaType, 
  TcTyVar, TcTyVarSet, TcKind, TcCoVar,

  -- Untouchables
  Untouchables(..), noUntouchables, pushUntouchables, isTouchable,

  --------------------------------
  -- MetaDetails
  UserTypeCtxt(..), pprUserTypeCtxt,
  TcTyVarDetails(..), pprTcTyVarDetails, vanillaSkolemTv, superSkolemTv,
  MetaDetails(Flexi, Indirect), MetaInfo(..), 
  isImmutableTyVar, isSkolemTyVar, isMetaTyVar,  isMetaTyVarTy, isTyVarTy,
  isSigTyVar, isOverlappableTyVar,  isTyConableTyVar, isFlatSkolTyVar,
  isAmbiguousTyVar, metaTvRef, metaTyVarInfo,
  isFlexi, isIndirect, isRuntimeUnkSkol,
  isTypeVar, isKindVar, 
  metaTyVarUntouchables, setMetaTyVarUntouchables, 
  isTouchableMetaTyVar, isFloatedTouchableMetaTyVar,

  --------------------------------
  -- Builders
  mkPhiTy, mkSigmaTy, mkTcEqPred,

  --------------------------------
  -- Splitters  
  -- These are important because they do not look through newtypes
  tcView,
  tcSplitForAllTys, tcSplitPhiTy, tcSplitPredFunTy_maybe,
  tcSplitFunTy_maybe, tcSplitFunTys, tcFunArgTy, tcFunResultTy, tcSplitFunTysN,
  tcSplitTyConApp, tcSplitTyConApp_maybe, tcTyConAppTyCon, tcTyConAppArgs,
  tcSplitAppTy_maybe, tcSplitAppTy, tcSplitAppTys, repSplitAppTy_maybe,
  tcInstHeadTyNotSynonym, tcInstHeadTyAppAllTyVars,
  tcGetTyVar_maybe, tcGetTyVar,
  tcSplitSigmaTy, tcDeepSplitSigmaTy_maybe,  

  ---------------------------------
  -- Predicates. 
  -- Again, newtypes are opaque
  eqType, eqTypes, eqPred, cmpType, cmpTypes, cmpPred, eqTypeX,
  pickyEqType, eqKind,
  isSigmaTy, isOverloadedTy,
  isDoubleTy, isFloatTy, isIntTy, isWordTy, isStringTy,
  isIntegerTy, isBoolTy, isUnitTy, isCharTy,
  isTauTy, isTauTyCon, tcIsTyVarTy, tcIsForAllTy, 
  isSynFamilyTyConApp,
  isPredTy, isTyVarClassPred,
  
  ---------------------------------
  -- Misc type manipulators
  deNoteType, occurCheckExpand, OccCheckResult(..),
  orphNamesOfType, orphNamesOfDFunHead, orphNamesOfCo,
  orphNamesOfTypes, orphNamesOfCoCon,
  getDFunTyKey,
  evVarPred_maybe, evVarPred,

  ---------------------------------
  -- Predicate types  
  mkMinimalBySCs, transSuperClasses, immSuperClasses,
  
  -- * Finding type instances
  tcTyFamInsts,

  -- * Finding "exact" (non-dead) type variables
  exactTyVarsOfType, exactTyVarsOfTypes,

  ---------------------------------
  -- Foreign import and export
  isFFIArgumentTy,     -- :: DynFlags -> Safety -> Type -> Bool
  isFFIImportResultTy, -- :: DynFlags -> Type -> Bool
  isFFIExportResultTy, -- :: Type -> Bool
  isFFIExternalTy,     -- :: Type -> Bool
  isFFIDynTy,          -- :: Type -> Type -> Bool
  isFFIPrimArgumentTy, -- :: DynFlags -> Type -> Bool
  isFFIPrimResultTy,   -- :: DynFlags -> Type -> Bool
  isFFILabelTy,        -- :: Type -> Bool
  isFFIDotnetTy,       -- :: DynFlags -> Type -> Bool
  isFFIDotnetObjTy,    -- :: Type -> Bool
  isFFITy,	       -- :: Type -> Bool
  isFunPtrTy,          -- :: Type -> Bool
  tcSplitIOType_maybe, -- :: Type -> Maybe Type  

  --------------------------------
  -- Rexported from Kind
  Kind, typeKind,
  unliftedTypeKind, liftedTypeKind,
  openTypeKind, constraintKind, mkArrowKind, mkArrowKinds, 
  isLiftedTypeKind, isUnliftedTypeKind, isSubOpenTypeKind, 
  tcIsSubKind, splitKindFunTys, defaultKind,

  --------------------------------
  -- Rexported from Type
  Type, PredType, ThetaType,
  mkForAllTy, mkForAllTys, 
  mkFunTy, mkFunTys, zipFunTys, 
  mkTyConApp, mkAppTy, mkAppTys, applyTy, applyTys,
  mkTyVarTy, mkTyVarTys, mkTyConTy,

  isClassPred, isEqPred, isIPPred,
  mkClassPred,
  isDictLikeTy,
  tcSplitDFunTy, tcSplitDFunHead, 
  mkEqPred, 

  -- Type substitutions
  TvSubst(..), 	-- Representation visible to a few friends
  TvSubstEnv, emptyTvSubst, 
  mkOpenTvSubst, zipOpenTvSubst, zipTopTvSubst, 
  mkTopTvSubst, notElemTvSubst, unionTvSubst,
  getTvSubstEnv, setTvSubstEnv, getTvInScope, extendTvInScope, 
  Type.lookupTyVar, Type.extendTvSubst, Type.substTyVarBndr,
  extendTvSubstList, isInScope, mkTvSubst, zipTyEnv,
  Type.substTy, substTys, substTyWith, substTheta, substTyVar, substTyVars, 

  isUnLiftedType,	-- Source types are always lifted
  isUnboxedTupleType,	-- Ditto
  isPrimitiveType, 

  tyVarsOfType, tyVarsOfTypes,
  tcTyVarsOfType, tcTyVarsOfTypes,

  pprKind, pprParendKind, pprSigmaType,
  pprType, pprParendType, pprTypeApp, pprTyThingCategory,
  pprTheta, pprThetaArrowTy, pprClassPred

  ) where

#include "HsVersions.h"

-- friends:
import Kind
import TypeRep
import Class
import Var
import ForeignCall
import VarSet
import Coercion
import Type
import TyCon
import CoAxiom

-- others:
import DynFlags
import Name -- hiding (varName)
            -- We use this to make dictionaries for type literals.
            -- Perhaps there's a better way to do this?
import NameSet
import VarEnv
import PrelNames
import TysWiredIn
import BasicTypes
import Util
import Maybes
import ListSetOps
import Outputable
import FastString

import Data.IORef
\end{code} %************************************************************************ %* * \subsection{Types} %* * %************************************************************************ The type checker divides the generic Type world into the following more structured beasts: sigma ::= forall tyvars. phi -- A sigma type is a qualified type -- -- Note that even if 'tyvars' is empty, theta -- may not be: e.g. (?x::Int) => Int -- Note that 'sigma' is in prenex form: -- all the foralls are at the front. -- A 'phi' type has no foralls to the right of -- an arrow phi :: theta => rho rho ::= sigma -> rho | tau -- A 'tau' type has no quantification anywhere -- Note that the args of a type constructor must be taus tau ::= tyvar | tycon tau_1 .. tau_n | tau_1 tau_2 | tau_1 -> tau_2 -- In all cases, a (saturated) type synonym application is legal, -- provided it expands to the required form. \begin{code}
type TcTyVar = TyVar  	-- Used only during type inference
type TcCoVar = CoVar  	-- Used only during type inference; mutable
type TcType = Type 	-- A TcType can have mutable type variables
	-- Invariant on ForAllTy in TcTypes:
	-- 	forall a. T
	-- a cannot occur inside a MutTyVar in T; that is,
	-- T is "flattened" before quantifying over a

-- These types do not have boxy type variables in them
type TcPredType     = PredType
type TcThetaType    = ThetaType
type TcSigmaType    = TcType
type TcRhoType      = TcType
type TcTauType      = TcType
type TcKind         = Kind
type TcTyVarSet     = TyVarSet
\end{code} %************************************************************************ %* * \subsection{TyVarDetails} %* * %************************************************************************ TyVarDetails gives extra info about type variables, used during type checking. It's attached to mutable type variables only. It's knot-tied back to Var.lhs. There is no reason in principle why Var.lhs shouldn't actually have the definition, but it "belongs" here. Note [Signature skolems] ~~~~~~~~~~~~~~~~~~~~~~~~ Consider this x :: [a] y :: b (x,y,z) = ([y,z], z, head x) Here, x and y have type sigs, which go into the environment. We used to instantiate their types with skolem constants, and push those types into the RHS, so we'd typecheck the RHS with type ( [a*], b*, c ) where a*, b* are skolem constants, and c is an ordinary meta type varible. The trouble is that the occurrences of z in the RHS force a* and b* to be the *same*, so we can't make them into skolem constants that don't unify with each other. Alas. One solution would be insist that in the above defn the programmer uses the same type variable in both type signatures. But that takes explanation. The alternative (currently implemented) is to have a special kind of skolem constant, SigTv, which can unify with other SigTvs. These are *not* treated as rigid for the purposes of GADTs. And they are used *only* for pattern bindings and mutually recursive function bindings. See the function TcBinds.tcInstSig, and its use_skols parameter. \begin{code}
-- A TyVarDetails is inside a TyVar
data TcTyVarDetails
  = SkolemTv      -- A skolem
       Bool       -- True <=> this skolem type variable can be overlapped
                  --          when looking up instances
                  -- See Note [Binding when looking up instances] in InstEnv

  | RuntimeUnk    -- Stands for an as-yet-unknown type in the GHCi
                  -- interactive context

  | FlatSkol TcType
           -- The "skolem" obtained by flattening during
    	   -- constraint simplification
    
           -- In comments we will use the notation alpha[flat = ty]
           -- to represent a flattening skolem variable alpha
           -- identified with type ty.
          
  | MetaTv { mtv_info  :: MetaInfo
           , mtv_ref   :: IORef MetaDetails
           , mtv_untch :: Untouchables }  -- See Note [Untouchable type variables]

vanillaSkolemTv, superSkolemTv :: TcTyVarDetails
-- See Note [Binding when looking up instances] in InstEnv
vanillaSkolemTv = SkolemTv False  -- Might be instantiated
superSkolemTv   = SkolemTv True   -- Treat this as a completely distinct type

-----------------------------
data MetaDetails
  = Flexi  -- Flexi type variables unify to become Indirects  
  | Indirect TcType

instance Outputable MetaDetails where
  ppr Flexi         = ptext (sLit "Flexi")
  ppr (Indirect ty) = ptext (sLit "Indirect") <+> ppr ty

data MetaInfo
   = TauTv	   -- This MetaTv is an ordinary unification variable
     		   -- A TauTv is always filled in with a tau-type, which
		   -- never contains any ForAlls 

   | PolyTv        -- Like TauTv, but can unify with a sigma-type

   | SigTv 	   -- A variant of TauTv, except that it should not be
		   -- unified with a type, only with a type variable
		   -- SigTvs are only distinguished to improve error messages
		   --      see Note [Signature skolems]        
		   --      The MetaDetails, if filled in, will 
		   --      always be another SigTv or a SkolemTv

-------------------------------------
-- UserTypeCtxt describes the origin of the polymorphic type
-- in the places where we need to an expression has that type

data UserTypeCtxt
  = FunSigCtxt Name	-- Function type signature
			-- Also used for types in SPECIALISE pragmas
  | InfSigCtxt Name	-- Inferred type for function
  | ExprSigCtxt		-- Expression type signature
  | ConArgCtxt Name	-- Data constructor argument
  | TySynCtxt Name	-- RHS of a type synonym decl
  | LamPatSigCtxt		-- Type sig in lambda pattern
			-- 	f (x::t) = ...
  | BindPatSigCtxt	-- Type sig in pattern binding pattern
			--	(x::t, y) = e
  | RuleSigCtxt Name    -- LHS of a RULE forall
                        --    RULE "foo" forall (x :: a -> a). f (Just x) = ...
  | ResSigCtxt		-- Result type sig
			-- 	f x :: t = ....
  | ForSigCtxt Name	-- Foreign import or export signature
  | DefaultDeclCtxt	-- Types in a default declaration
  | InstDeclCtxt        -- An instance declaration
  | SpecInstCtxt	-- SPECIALISE instance pragma
  | ThBrackCtxt		-- Template Haskell type brackets [t| ... |]
  | GenSigCtxt          -- Higher-rank or impredicative situations
                        -- e.g. (f e) where f has a higher-rank type
                        -- We might want to elaborate this
  | GhciCtxt            -- GHCi command :kind <type>

  | ClassSCCtxt Name	-- Superclasses of a class
  | SigmaCtxt		-- Theta part of a normal for-all type
			--	f :: <S> => a -> a
  | DataTyCtxt Name	-- Theta part of a data decl
			--	data <S> => T a = MkT a
\end{code} -- Notes re TySynCtxt -- We allow type synonyms that aren't types; e.g. type List = [] -- -- If the RHS mentions tyvars that aren't in scope, we'll -- quantify over them: -- e.g. type T = a->a -- will become type T = forall a. a->a -- -- With gla-exts that's right, but for H98 we should complain. %************************************************************************ %* * Untoucable type variables %* * %************************************************************************ Note [Untouchable type variables] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ * Each unification variable (MetaTv) and each Implication has a level number (of type Untouchables) * INVARIANTS. In a tree of Implications, (ImplicInv) The level number of an Implication is STRICTLY GREATER THAN that of its parent (MetaTvInv) The level number of a unification variable is LESS THAN OR EQUAL TO that of its parent implication * A unification variable is *touchable* if its level number is EQUAL TO that of its immediate parent implication. Note [Skolem escape prevention] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ We only unify touchable unification variables. Because of (MetaTvInv), there can be no occurrences of he variable further out, so the unification can't cause the kolems to escape. Example: data T = forall a. MkT a (a->Int) f x (MkT v f) = length [v,x] We decide (x::alpha), and generate an implication like [1]forall a. (a ~ alpha[0]) But we must not unify alpha:=a, because the skolem would escape. For the cases where we DO want to unify, we rely on floating the equality. Example (with same T) g x (MkT v f) = x && True We decide (x::alpha), and generate an implication like [1]forall a. (Bool ~ alpha[0]) We do NOT unify directly, bur rather float out (if the constraint does not memtion 'a') to get (Bool ~ alpha[0]) /\ [1]forall a.() and NOW we can unify alpha. The same idea of only unifying touchables solves another problem. Suppose we had (F Int ~ uf[0]) /\ [1](forall a. C a => F Int ~ beta[1]) In this example, beta is touchable inside the implication. The first solveInteract step leaves 'uf' un-unified. Then we move inside the implication where a new constraint uf ~ beta emerges. If we (wrongly) spontaneously solved it to get uf := beta, the whole implication disappears but when we pop out again we are left with (F Int ~ uf) which will be unified by our final solveCTyFunEqs stage and uf will get unified *once more* to (F Int). \begin{code}
newtype Untouchables = Untouchables Int
  -- See Note [Untouchable type variables] for what this Int is

noUntouchables :: Untouchables
noUntouchables = Untouchables 0   -- 0 = outermost level

pushUntouchables :: Untouchables -> Untouchables 
pushUntouchables (Untouchables us) = Untouchables (us+1)

isFloatedTouchable :: Untouchables -> Untouchables -> Bool
isFloatedTouchable (Untouchables ctxt_untch) (Untouchables tv_untch) 
  = ctxt_untch < tv_untch

isTouchable :: Untouchables -> Untouchables -> Bool
isTouchable (Untouchables ctxt_untch) (Untouchables tv_untch) 
  = ctxt_untch == tv_untch   -- NB: invariant ctxt_untch >= tv_untch
                             --     So <= would be equivalent

checkTouchableInvariant :: Untouchables -> Untouchables -> Bool
-- Checks (MetaTvInv) from Note [Untouchable type variables]
checkTouchableInvariant (Untouchables ctxt_untch) (Untouchables tv_untch) 
  = ctxt_untch >= tv_untch

instance Outputable Untouchables where
  ppr (Untouchables us) = ppr us
\end{code} %************************************************************************ %* * Pretty-printing %* * %************************************************************************ \begin{code}
pprTcTyVarDetails :: TcTyVarDetails -> SDoc
-- For debugging
pprTcTyVarDetails (SkolemTv True)  = ptext (sLit "ssk")
pprTcTyVarDetails (SkolemTv False) = ptext (sLit "sk")
pprTcTyVarDetails (RuntimeUnk {})  = ptext (sLit "rt")
pprTcTyVarDetails (FlatSkol {})    = ptext (sLit "fsk")
pprTcTyVarDetails (MetaTv { mtv_info = info, mtv_untch = untch })
  = pp_info <> brackets (ppr untch)
  where
    pp_info = case info of
                PolyTv -> ptext (sLit "poly")
                TauTv  -> ptext (sLit "tau")
                SigTv  -> ptext (sLit "sig")

pprUserTypeCtxt :: UserTypeCtxt -> SDoc
pprUserTypeCtxt (InfSigCtxt n)    = ptext (sLit "the inferred type for") <+> quotes (ppr n)
pprUserTypeCtxt (FunSigCtxt n)    = ptext (sLit "the type signature for") <+> quotes (ppr n)
pprUserTypeCtxt (RuleSigCtxt n)    = ptext (sLit "a RULE for") <+> quotes (ppr n)
pprUserTypeCtxt ExprSigCtxt       = ptext (sLit "an expression type signature")
pprUserTypeCtxt (ConArgCtxt c)    = ptext (sLit "the type of the constructor") <+> quotes (ppr c)
pprUserTypeCtxt (TySynCtxt c)     = ptext (sLit "the RHS of the type synonym") <+> quotes (ppr c)
pprUserTypeCtxt ThBrackCtxt       = ptext (sLit "a Template Haskell quotation [t|...|]")
pprUserTypeCtxt LamPatSigCtxt     = ptext (sLit "a pattern type signature")
pprUserTypeCtxt BindPatSigCtxt    = ptext (sLit "a pattern type signature")
pprUserTypeCtxt ResSigCtxt        = ptext (sLit "a result type signature")
pprUserTypeCtxt (ForSigCtxt n)    = ptext (sLit "the foreign declaration for") <+> quotes (ppr n)
pprUserTypeCtxt DefaultDeclCtxt   = ptext (sLit "a type in a `default' declaration")
pprUserTypeCtxt InstDeclCtxt      = ptext (sLit "an instance declaration")
pprUserTypeCtxt SpecInstCtxt      = ptext (sLit "a SPECIALISE instance pragma")
pprUserTypeCtxt GenSigCtxt        = ptext (sLit "a type expected by the context")
pprUserTypeCtxt GhciCtxt          = ptext (sLit "a type in a GHCi command")
pprUserTypeCtxt (ClassSCCtxt c)   = ptext (sLit "the super-classes of class") <+> quotes (ppr c)
pprUserTypeCtxt SigmaCtxt         = ptext (sLit "the context of a polymorphic type")
pprUserTypeCtxt (DataTyCtxt tc)   = ptext (sLit "the context of the data type declaration for") <+> quotes (ppr tc)
\end{code} %************************************************************************ %* * Finding type family instances %* * %************************************************************************ \begin{code}
-- | Finds outermost type-family applications occuring in a type,
-- after expanding synonyms.
tcTyFamInsts :: Type -> [(TyCon, [Type])]
tcTyFamInsts ty 
  | Just exp_ty <- tcView ty    = tcTyFamInsts exp_ty
tcTyFamInsts (TyVarTy _)        = []
tcTyFamInsts (TyConApp tc tys) 
  | isSynFamilyTyCon tc         = [(tc, tys)]
  | otherwise                   = concat (map tcTyFamInsts tys)
tcTyFamInsts (LitTy {})         = []
tcTyFamInsts (FunTy ty1 ty2)    = tcTyFamInsts ty1 ++ tcTyFamInsts ty2
tcTyFamInsts (AppTy ty1 ty2)    = tcTyFamInsts ty1 ++ tcTyFamInsts ty2
tcTyFamInsts (ForAllTy _ ty)    = tcTyFamInsts ty
\end{code} %************************************************************************ %* * The "exact" free variables of a type %* * %************************************************************************ Note [Silly type synonym] ~~~~~~~~~~~~~~~~~~~~~~~~~ Consider type T a = Int What are the free tyvars of (T x)? Empty, of course! Here's the example that Ralf Laemmel showed me: foo :: (forall a. C u a -> C u a) -> u mappend :: Monoid u => u -> u -> u bar :: Monoid u => u bar = foo (\t -> t `mappend` t) We have to generalise at the arg to f, and we don't want to capture the constraint (Monad (C u a)) because it appears to mention a. Pretty silly, but it was useful to him. exactTyVarsOfType is used by the type checker to figure out exactly which type variables are mentioned in a type. It's also used in the smart-app checking code --- see TcExpr.tcIdApp On the other hand, consider a *top-level* definition f = (\x -> x) :: T a -> T a If we don't abstract over 'a' it'll get fixed to GHC.Prim.Any, and then if we have an application like (f "x") we get a confusing error message involving Any. So the conclusion is this: when generalising - at top level use tyVarsOfType - in nested bindings use exactTyVarsOfType See Trac #1813 for example. \begin{code}
exactTyVarsOfType :: Type -> TyVarSet
-- Find the free type variables (of any kind)
-- but *expand* type synonyms.  See Note [Silly type synonym] above.
exactTyVarsOfType ty
  = go ty
  where
    go ty | Just ty' <- tcView ty = go ty'  -- This is the key line
    go (TyVarTy tv)         = unitVarSet tv
    go (TyConApp _ tys)     = exactTyVarsOfTypes tys
    go (LitTy {})           = emptyVarSet
    go (FunTy arg res)      = go arg `unionVarSet` go res
    go (AppTy fun arg)      = go fun `unionVarSet` go arg
    go (ForAllTy tyvar ty)  = delVarSet (go ty) tyvar

exactTyVarsOfTypes :: [Type] -> TyVarSet
exactTyVarsOfTypes tys = foldr (unionVarSet . exactTyVarsOfType) emptyVarSet tys
\end{code} %************************************************************************ %* * Predicates %* * %************************************************************************ \begin{code}
isTouchableMetaTyVar :: Untouchables -> TcTyVar -> Bool
isTouchableMetaTyVar ctxt_untch tv
  = ASSERT2( isTcTyVar tv, ppr tv )
    case tcTyVarDetails tv of 
      MetaTv { mtv_untch = tv_untch } 
        -> ASSERT2( checkTouchableInvariant ctxt_untch tv_untch, 
                    ppr tv $$ ppr tv_untch $$ ppr ctxt_untch )
           isTouchable ctxt_untch tv_untch
      _ -> False

isFloatedTouchableMetaTyVar :: Untouchables -> TcTyVar -> Bool
isFloatedTouchableMetaTyVar ctxt_untch tv
  = ASSERT2( isTcTyVar tv, ppr tv )
    case tcTyVarDetails tv of 
      MetaTv { mtv_untch = tv_untch } -> isFloatedTouchable ctxt_untch tv_untch
      _ -> False

isImmutableTyVar :: TyVar -> Bool
isImmutableTyVar tv
  | isTcTyVar tv = isSkolemTyVar tv
  | otherwise    = True

isTyConableTyVar, isSkolemTyVar, isOverlappableTyVar,
  isMetaTyVar, isAmbiguousTyVar, isFlatSkolTyVar :: TcTyVar -> Bool 

isTyConableTyVar tv	
	-- True of a meta-type variable that can be filled in 
	-- with a type constructor application; in particular,
	-- not a SigTv
  = ASSERT( isTcTyVar tv) 
    case tcTyVarDetails tv of
	MetaTv { mtv_info = SigTv } -> False
	_                           -> True
	
isFlatSkolTyVar tv
  = ASSERT2( isTcTyVar tv, ppr tv )
    case tcTyVarDetails tv of
        FlatSkol {} -> True
        _           -> False

isSkolemTyVar tv 
  = ASSERT2( isTcTyVar tv, ppr tv )
    case tcTyVarDetails tv of
        SkolemTv {}   -> True
        FlatSkol {}   -> True
        RuntimeUnk {} -> True
        MetaTv {}     -> False

isOverlappableTyVar tv
  = ASSERT( isTcTyVar tv )
    case tcTyVarDetails tv of
        SkolemTv overlappable -> overlappable
        _                     -> False

isMetaTyVar tv 
  = ASSERT2( isTcTyVar tv, ppr tv )
    case tcTyVarDetails tv of
	MetaTv {} -> True
	_         -> False

-- isAmbiguousTyVar is used only when reporting type errors
-- It picks out variables that are unbound, namely meta
-- type variables and the RuntimUnk variables created by
-- RtClosureInspect.zonkRTTIType.  These are "ambiguous" in
-- the sense that they stand for an as-yet-unknown type
isAmbiguousTyVar tv 
  = ASSERT2( isTcTyVar tv, ppr tv )
    case tcTyVarDetails tv of
	MetaTv {}     -> True
	RuntimeUnk {} -> True
	_             -> False

isMetaTyVarTy :: TcType -> Bool
isMetaTyVarTy (TyVarTy tv) = isMetaTyVar tv
isMetaTyVarTy _            = False

metaTyVarInfo :: TcTyVar -> MetaInfo
metaTyVarInfo tv
  = ASSERT( isTcTyVar tv )
    case tcTyVarDetails tv of
      MetaTv { mtv_info = info } -> info
      _ -> pprPanic "metaTyVarInfo" (ppr tv)

metaTyVarUntouchables :: TcTyVar -> Untouchables
metaTyVarUntouchables tv
  = ASSERT( isTcTyVar tv )
    case tcTyVarDetails tv of
      MetaTv { mtv_untch = untch } -> untch
      _ -> pprPanic "metaTyVarUntouchables" (ppr tv)

setMetaTyVarUntouchables :: TcTyVar -> Untouchables -> TcTyVar
setMetaTyVarUntouchables tv untch
  = ASSERT( isTcTyVar tv )
    case tcTyVarDetails tv of
      details@(MetaTv {}) -> setTcTyVarDetails tv (details { mtv_untch = untch })
      _ -> pprPanic "metaTyVarUntouchables" (ppr tv)

isSigTyVar :: Var -> Bool
isSigTyVar tv 
  = ASSERT( isTcTyVar tv )
    case tcTyVarDetails tv of
	MetaTv { mtv_info = SigTv } -> True
	_                           -> False

metaTvRef :: TyVar -> IORef MetaDetails
metaTvRef tv 
  = ASSERT2( isTcTyVar tv, ppr tv )
    case tcTyVarDetails tv of
	MetaTv { mtv_ref = ref } -> ref
	_ -> pprPanic "metaTvRef" (ppr tv)

isFlexi, isIndirect :: MetaDetails -> Bool
isFlexi Flexi = True
isFlexi _     = False

isIndirect (Indirect _) = True
isIndirect _            = False

isRuntimeUnkSkol :: TyVar -> Bool
-- Called only in TcErrors; see Note [Runtime skolems] there
isRuntimeUnkSkol x
  | isTcTyVar x, RuntimeUnk <- tcTyVarDetails x = True
  | otherwise                                   = False
\end{code} %************************************************************************ %* * \subsection{Tau, sigma and rho} %* * %************************************************************************ \begin{code}
mkSigmaTy :: [TyVar] -> [PredType] -> Type -> Type
mkSigmaTy tyvars theta tau = mkForAllTys tyvars (mkPhiTy theta tau)

mkPhiTy :: [PredType] -> Type -> Type
mkPhiTy theta ty = foldr mkFunTy ty theta

mkTcEqPred :: TcType -> TcType -> Type
-- During type checking we build equalities between 
-- type variables with OpenKind or ArgKind.  Ultimately
-- they will all settle, but we want the equality predicate
-- itself to have kind '*'.  I think.
--
-- But for now we call mkTyConApp, not mkEqPred, because the invariants
-- of the latter might not be satisfied during type checking.
-- Notably when we form an equalty   (a : OpenKind) ~ (Int : *)
--
-- But this is horribly delicate: what about type variables
-- that turn out to be bound to Int#?
mkTcEqPred ty1 ty2
  = mkTyConApp eqTyCon [k, ty1, ty2]
  where
    k = defaultKind (typeKind ty1)
\end{code} @isTauTy@ tests for nested for-alls. It should not be called on a boxy type. \begin{code}
isTauTy :: Type -> Bool
isTauTy ty | Just ty' <- tcView ty = isTauTy ty'
isTauTy (TyVarTy _)	  = True
isTauTy (LitTy {})        = True
isTauTy (TyConApp tc tys) = all isTauTy tys && isTauTyCon tc
isTauTy (AppTy a b)	  = isTauTy a && isTauTy b
isTauTy (FunTy a b)	  = isTauTy a && isTauTy b
isTauTy (ForAllTy {})     = False

isTauTyCon :: TyCon -> Bool
-- Returns False for type synonyms whose expansion is a polytype
isTauTyCon tc 
  | Just (_, rhs) <- synTyConDefn_maybe tc = isTauTy rhs
  | otherwise                              = True

---------------
getDFunTyKey :: Type -> OccName -- Get some string from a type, to be used to
				-- construct a dictionary function name
getDFunTyKey ty | Just ty' <- tcView ty = getDFunTyKey ty'
getDFunTyKey (TyVarTy tv)    = getOccName tv
getDFunTyKey (TyConApp tc _) = getOccName tc
getDFunTyKey (LitTy x)       = getDFunTyLitKey x
getDFunTyKey (AppTy fun _)   = getDFunTyKey fun
getDFunTyKey (FunTy _ _)     = getOccName funTyCon
getDFunTyKey (ForAllTy _ t)  = getDFunTyKey t

getDFunTyLitKey :: TyLit -> OccName
getDFunTyLitKey (NumTyLit n) = mkOccName Name.varName (show n)
getDFunTyLitKey (StrTyLit n) = mkOccName Name.varName (show n)  -- hm
\end{code} %************************************************************************ %* * \subsection{Expanding and splitting} %* * %************************************************************************ These tcSplit functions are like their non-Tc analogues, but *) they do not look through newtypes However, they are non-monadic and do not follow through mutable type variables. It's up to you to make sure this doesn't matter. \begin{code}
tcSplitForAllTys :: Type -> ([TyVar], Type)
tcSplitForAllTys ty = split ty ty []
   where
     split orig_ty ty tvs | Just ty' <- tcView ty = split orig_ty ty' tvs
     split _ (ForAllTy tv ty) tvs = split ty ty (tv:tvs)
     split orig_ty _          tvs = (reverse tvs, orig_ty)

tcIsForAllTy :: Type -> Bool
tcIsForAllTy ty | Just ty' <- tcView ty = tcIsForAllTy ty'
tcIsForAllTy (ForAllTy {}) = True
tcIsForAllTy _             = False

tcSplitPredFunTy_maybe :: Type -> Maybe (PredType, Type)
-- Split off the first predicate argument from a type
tcSplitPredFunTy_maybe ty 
  | Just ty' <- tcView ty = tcSplitPredFunTy_maybe ty'
tcSplitPredFunTy_maybe (FunTy arg res)
  | isPredTy arg = Just (arg, res)
tcSplitPredFunTy_maybe _
  = Nothing

tcSplitPhiTy :: Type -> (ThetaType, Type)
tcSplitPhiTy ty
  = split ty []
  where
    split ty ts 
      = case tcSplitPredFunTy_maybe ty of
	  Just (pred, ty) -> split ty (pred:ts)
	  Nothing         -> (reverse ts, ty)

tcSplitSigmaTy :: Type -> ([TyVar], ThetaType, Type)
tcSplitSigmaTy ty = case tcSplitForAllTys ty of
			(tvs, rho) -> case tcSplitPhiTy rho of
					(theta, tau) -> (tvs, theta, tau)

-----------------------
tcDeepSplitSigmaTy_maybe
  :: TcSigmaType -> Maybe ([TcType], [TyVar], ThetaType, TcSigmaType)
-- Looks for a *non-trivial* quantified type, under zero or more function arrows
-- By "non-trivial" we mean either tyvars or constraints are non-empty

tcDeepSplitSigmaTy_maybe ty
  | Just (arg_ty, res_ty)           <- tcSplitFunTy_maybe ty
  , Just (arg_tys, tvs, theta, rho) <- tcDeepSplitSigmaTy_maybe res_ty
  = Just (arg_ty:arg_tys, tvs, theta, rho)

  | (tvs, theta, rho) <- tcSplitSigmaTy ty
  , not (null tvs && null theta)
  = Just ([], tvs, theta, rho)

  | otherwise = Nothing

-----------------------
tcTyConAppTyCon :: Type -> TyCon
tcTyConAppTyCon ty = case tcSplitTyConApp_maybe ty of
			Just (tc, _) -> tc
			Nothing	     -> pprPanic "tcTyConAppTyCon" (pprType ty)

tcTyConAppArgs :: Type -> [Type]
tcTyConAppArgs ty = case tcSplitTyConApp_maybe ty of
			Just (_, args) -> args
			Nothing	       -> pprPanic "tcTyConAppArgs" (pprType ty)

tcSplitTyConApp :: Type -> (TyCon, [Type])
tcSplitTyConApp ty = case tcSplitTyConApp_maybe ty of
			Just stuff -> stuff
			Nothing	   -> pprPanic "tcSplitTyConApp" (pprType ty)

tcSplitTyConApp_maybe :: Type -> Maybe (TyCon, [Type])
tcSplitTyConApp_maybe ty | Just ty' <- tcView ty = tcSplitTyConApp_maybe ty'
tcSplitTyConApp_maybe (TyConApp tc tys) = Just (tc, tys)
tcSplitTyConApp_maybe (FunTy arg res)   = Just (funTyCon, [arg,res])
	-- Newtypes are opaque, so they may be split
	-- However, predicates are not treated
	-- as tycon applications by the type checker
tcSplitTyConApp_maybe _                 = Nothing

-----------------------
tcSplitFunTys :: Type -> ([Type], Type)
tcSplitFunTys ty = case tcSplitFunTy_maybe ty of
			Nothing	       -> ([], ty)
			Just (arg,res) -> (arg:args, res')
				       where
					  (args,res') = tcSplitFunTys res

tcSplitFunTy_maybe :: Type -> Maybe (Type, Type)
tcSplitFunTy_maybe ty | Just ty' <- tcView ty           = tcSplitFunTy_maybe ty'
tcSplitFunTy_maybe (FunTy arg res) | not (isPredTy arg) = Just (arg, res)
tcSplitFunTy_maybe _                                    = Nothing
	-- Note the typeKind guard
	-- Consider	(?x::Int) => Bool
	-- We don't want to treat this as a function type!
	-- A concrete example is test tc230:
	--	f :: () -> (?p :: ()) => () -> ()
	--
	--	g = f () ()

tcSplitFunTysN
	:: TcRhoType 
	-> Arity		-- N: Number of desired args
	-> ([TcSigmaType], 	-- Arg types (N or fewer)
	    TcSigmaType)	-- The rest of the type

tcSplitFunTysN ty n_args
  | n_args == 0
  = ([], ty)
  | Just (arg,res) <- tcSplitFunTy_maybe ty
  = case tcSplitFunTysN res (n_args - 1) of
	(args, res) -> (arg:args, res)
  | otherwise
  = ([], ty)

tcSplitFunTy :: Type -> (Type, Type)
tcSplitFunTy  ty = expectJust "tcSplitFunTy" (tcSplitFunTy_maybe ty)

tcFunArgTy :: Type -> Type
tcFunArgTy    ty = fst (tcSplitFunTy ty)

tcFunResultTy :: Type -> Type
tcFunResultTy ty = snd (tcSplitFunTy ty)

-----------------------
tcSplitAppTy_maybe :: Type -> Maybe (Type, Type)
tcSplitAppTy_maybe ty | Just ty' <- tcView ty = tcSplitAppTy_maybe ty'
tcSplitAppTy_maybe ty = repSplitAppTy_maybe ty

tcSplitAppTy :: Type -> (Type, Type)
tcSplitAppTy ty = case tcSplitAppTy_maybe ty of
		    Just stuff -> stuff
		    Nothing    -> pprPanic "tcSplitAppTy" (pprType ty)

tcSplitAppTys :: Type -> (Type, [Type])
tcSplitAppTys ty
  = go ty []
  where
    go ty args = case tcSplitAppTy_maybe ty of
		   Just (ty', arg) -> go ty' (arg:args)
		   Nothing	   -> (ty,args)

-----------------------
tcGetTyVar_maybe :: Type -> Maybe TyVar
tcGetTyVar_maybe ty | Just ty' <- tcView ty = tcGetTyVar_maybe ty'
tcGetTyVar_maybe (TyVarTy tv)   = Just tv
tcGetTyVar_maybe _              = Nothing

tcGetTyVar :: String -> Type -> TyVar
tcGetTyVar msg ty = expectJust msg (tcGetTyVar_maybe ty)

tcIsTyVarTy :: Type -> Bool
tcIsTyVarTy ty = maybeToBool (tcGetTyVar_maybe ty)

-----------------------
tcSplitDFunTy :: Type -> ([TyVar], [Type], Class, [Type])
-- Split the type of a dictionary function
-- We don't use tcSplitSigmaTy,  because a DFun may (with NDP)
-- have non-Pred arguments, such as
--     df :: forall m. (forall b. Eq b => Eq (m b)) -> C m
-- 
-- Also NB splitFunTys, not tcSplitFunTys; 
-- the latter  specifically stops at PredTy arguments, 
-- and we don't want to do that here
tcSplitDFunTy ty 
  = case tcSplitForAllTys ty   of { (tvs, rho)   ->
    case splitFunTys rho       of { (theta, tau) ->  
    case tcSplitDFunHead tau   of { (clas, tys)  ->
    (tvs, theta, clas, tys) }}}

tcSplitDFunHead :: Type -> (Class, [Type])
tcSplitDFunHead = getClassPredTys

tcInstHeadTyNotSynonym :: Type -> Bool
-- Used in Haskell-98 mode, for the argument types of an instance head
-- These must not be type synonyms, but everywhere else type synonyms
-- are transparent, so we need a special function here
tcInstHeadTyNotSynonym ty
  = case ty of
        TyConApp tc _ -> not (isSynTyCon tc)
        _ -> True

tcInstHeadTyAppAllTyVars :: Type -> Bool
-- Used in Haskell-98 mode, for the argument types of an instance head
-- These must be a constructor applied to type variable arguments.
-- But we allow kind instantiations.
tcInstHeadTyAppAllTyVars ty
  | Just ty' <- tcView ty       -- Look through synonyms
  = tcInstHeadTyAppAllTyVars ty'
  | otherwise
  = case ty of
	TyConApp _ tys  -> ok (filter (not . isKind) tys)  -- avoid kinds
	FunTy arg res   -> ok [arg, res]
	_               -> False
  where
	-- Check that all the types are type variables,
	-- and that each is distinct
    ok tys = equalLength tvs tys && hasNoDups tvs
	   where
	     tvs = mapCatMaybes get_tv tys

    get_tv (TyVarTy tv)  = Just tv	-- through synonyms
    get_tv _             = Nothing
\end{code} \begin{code}
pickyEqType :: TcType -> TcType -> Bool
-- Check when two types _look_ the same, _including_ synonyms.  
-- So (pickyEqType String [Char]) returns False
pickyEqType ty1 ty2
  = go init_env ty1 ty2
  where
    init_env = mkRnEnv2 (mkInScopeSet (tyVarsOfType ty1 `unionVarSet` tyVarsOfType ty2))
    go env (TyVarTy tv1)       (TyVarTy tv2)     = rnOccL env tv1 == rnOccR env tv2
    go env (ForAllTy tv1 t1)   (ForAllTy tv2 t2) = go (rnBndr2 env tv1 tv2) t1 t2
    go env (AppTy s1 t1)       (AppTy s2 t2)     = go env s1 s2 && go env t1 t2
    go env (FunTy s1 t1)       (FunTy s2 t2)     = go env s1 s2 && go env t1 t2
    go env (TyConApp tc1 ts1) (TyConApp tc2 ts2) = (tc1 == tc2) && gos env ts1 ts2
    go _ _ _ = False

    gos _   []       []       = True
    gos env (t1:ts1) (t2:ts2) = go env t1 t2 && gos env ts1 ts2
    gos _ _ _ = False
\end{code} Note [Occurs check expansion] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ @occurCheckExpand tv xi@ expands synonyms in xi just enough to get rid of occurrences of tv outside type function arguments, if that is possible; otherwise, it returns Nothing. For example, suppose we have type F a b = [a] Then occurCheckExpand b (F Int b) = Just [Int] but occurCheckExpand a (F a Int) = Nothing We don't promise to do the absolute minimum amount of expanding necessary, but we try not to do expansions we don't need to. We prefer doing inner expansions first. For example, type F a b = (a, Int, a, [a]) type G b = Char We have occurCheckExpand b (F (G b)) = F Char even though we could also expand F to get rid of b. See also Note [Type synonyms and canonicalization] in TcCanonical \begin{code}
data OccCheckResult a
  = OC_OK a
  | OC_Forall 
  | OC_NonTyVar
  | OC_Occurs

instance Monad OccCheckResult where
  return x = OC_OK x
  OC_OK x     >>= k = k x
  OC_Forall   >>= _ = OC_Forall
  OC_NonTyVar >>= _ = OC_NonTyVar
  OC_Occurs   >>= _ = OC_Occurs
  
occurCheckExpand :: DynFlags -> TcTyVar -> Type -> OccCheckResult Type
-- See Note [Occurs check expansion]
-- Check whether 
--   a) the given variable occurs in the given type.  
--   b) there is a forall in the type (unless we have -XImpredicativeTypes
--                                     or it's a PolyTv
--   c) if it's a SigTv, ty should be a tyvar
--
-- We may have needed to do some type synonym unfolding in order to
-- get rid of the variable (or forall), so we also return the unfolded
-- version of the type, which is guaranteed to be syntactically free 
-- of the given type variable.  If the type is already syntactically 
-- free of the variable, then the same type is returned.

occurCheckExpand dflags tv ty
  | MetaTv { mtv_info = SigTv } <- details
                  = go_sig_tv ty
  | fast_check ty = return ty
  | otherwise     = go ty
  where
    details = ASSERT2( isTcTyVar tv, ppr tv ) tcTyVarDetails tv

    impredicative 
      = case details of
          MetaTv { mtv_info = PolyTv } -> True
          MetaTv { mtv_info = SigTv }  -> False
          MetaTv { mtv_info = TauTv }  -> xopt Opt_ImpredicativeTypes dflags
                                       || isOpenTypeKind (tyVarKind tv)
                                          -- Note [OpenTypeKind accepts foralls]
                                          -- in TcUnify
          _other                       -> True
          -- We can have non-meta tyvars in given constraints

    -- Check 'ty' is a tyvar, or can be expanded into one
    go_sig_tv ty@(TyVarTy {})            = OC_OK ty
    go_sig_tv ty | Just ty' <- tcView ty = go_sig_tv ty'
    go_sig_tv _                          = OC_NonTyVar

    -- True => fine
    fast_check (LitTy {})        = True
    fast_check (TyVarTy tv')     = tv /= tv'
    fast_check (TyConApp _ tys)  = all fast_check tys
    fast_check (FunTy arg res)   = fast_check arg && fast_check res
    fast_check (AppTy fun arg)   = fast_check fun && fast_check arg
    fast_check (ForAllTy tv' ty) = impredicative 
                                && fast_check (tyVarKind tv')
                                && (tv == tv' || fast_check ty)

    go t@(TyVarTy tv') | tv == tv' = OC_Occurs
                       | otherwise = return t
    go ty@(LitTy {}) = return ty
    go (AppTy ty1 ty2) = do { ty1' <- go ty1
           		    ; ty2' <- go ty2  
           		    ; return (mkAppTy ty1' ty2') }
    go (FunTy ty1 ty2) = do { ty1' <- go ty1 
           		    ; ty2' <- go ty2 
           		    ; return (mkFunTy ty1' ty2') } 
    go ty@(ForAllTy tv' body_ty)
       | not impredicative                = OC_Forall
       | not (fast_check (tyVarKind tv')) = OC_Occurs
           -- Can't expand away the kinds unless we create 
           -- fresh variables which we don't want to do at this point.
           -- In principle fast_check might fail because of a for-all
           -- but we don't yet have poly-kinded tyvars so I'm not
           -- going to worry about that now
       | tv == tv' = return ty
       | otherwise = do { body' <- go body_ty
                        ; return (ForAllTy tv' body') }

    -- For a type constructor application, first try expanding away the
    -- offending variable from the arguments.  If that doesn't work, next
    -- see if the type constructor is a type synonym, and if so, expand
    -- it and try again.
    go ty@(TyConApp tc tys)
      = case do { tys <- mapM go tys; return (mkTyConApp tc tys) } of
          OC_OK ty -> return ty  -- First try to eliminate the tyvar from the args
          bad | Just ty' <- tcView ty -> go ty'
              | otherwise             -> bad
                      -- Failing that, try to expand a synonym
\end{code} %************************************************************************ %* * \subsection{Predicate types} %* * %************************************************************************ Deconstructors and tests on predicate types \begin{code}
isTyVarClassPred :: PredType -> Bool
isTyVarClassPred ty = case getClassPredTys_maybe ty of
    Just (_, tys) -> all isTyVarTy tys
    _             -> False

evVarPred_maybe :: EvVar -> Maybe PredType
evVarPred_maybe v = if isPredTy ty then Just ty else Nothing
  where ty = varType v

evVarPred :: EvVar -> PredType
evVarPred var
 | debugIsOn
  = case evVarPred_maybe var of
      Just pred -> pred
      Nothing   -> pprPanic "tcEvVarPred" (ppr var <+> ppr (varType var))
 | otherwise
  = varType var
\end{code} Superclasses \begin{code}
mkMinimalBySCs :: [PredType] -> [PredType]
-- Remove predicates that can be deduced from others by superclasses
mkMinimalBySCs ptys = [ ploc |  ploc <- ptys
                             ,  ploc `not_in_preds` rec_scs ]
 where
   rec_scs = concatMap trans_super_classes ptys
   not_in_preds p ps = not (any (eqPred p) ps)

   trans_super_classes pred   -- Superclasses of pred, excluding pred itself
     = case classifyPredType pred of
         ClassPred cls tys -> transSuperClasses cls tys
         TuplePred ts      -> concatMap trans_super_classes ts
         _                 -> []

transSuperClasses :: Class -> [Type] -> [PredType]
transSuperClasses cls tys    -- Superclasses of (cls tys),
                             -- excluding (cls tys) itself
  = concatMap trans_sc (immSuperClasses cls tys)
  where 
    trans_sc :: PredType -> [PredType]
    -- (trans_sc p) returns (p : p's superclasses)
    trans_sc p = case classifyPredType p of
                   ClassPred cls tys -> p : transSuperClasses cls tys
                   TuplePred ps      -> concatMap trans_sc ps
                   _                 -> [p]

immSuperClasses :: Class -> [Type] -> [PredType]
immSuperClasses cls tys
  = substTheta (zipTopTvSubst tyvars tys) sc_theta
  where 
    (tyvars,sc_theta,_,_) = classBigSig cls
\end{code} %************************************************************************ %* * \subsection{Predicates} %* * %************************************************************************ isSigmaTy returns true of any qualified type. It doesn't *necessarily* have any foralls. E.g. f :: (?x::Int) => Int -> Int \begin{code}
isSigmaTy :: Type -> Bool
isSigmaTy ty | Just ty' <- tcView ty = isSigmaTy ty'
isSigmaTy (ForAllTy _ _) = True
isSigmaTy (FunTy a _)    = isPredTy a
isSigmaTy _              = False

isOverloadedTy :: Type -> Bool
-- Yes for a type of a function that might require evidence-passing
-- Used only by bindLocalMethods
isOverloadedTy ty | Just ty' <- tcView ty = isOverloadedTy ty'
isOverloadedTy (ForAllTy _ ty) = isOverloadedTy ty
isOverloadedTy (FunTy a _)     = isPredTy a
isOverloadedTy _               = False
\end{code} \begin{code}
isFloatTy, isDoubleTy, isIntegerTy, isIntTy, isWordTy, isBoolTy,
    isUnitTy, isCharTy, isAnyTy :: Type -> Bool
isFloatTy      = is_tc floatTyConKey
isDoubleTy     = is_tc doubleTyConKey
isIntegerTy    = is_tc integerTyConKey
isIntTy        = is_tc intTyConKey
isWordTy       = is_tc wordTyConKey
isBoolTy       = is_tc boolTyConKey
isUnitTy       = is_tc unitTyConKey
isCharTy       = is_tc charTyConKey
isAnyTy        = is_tc anyTyConKey

isStringTy :: Type -> Bool
isStringTy ty
  = case tcSplitTyConApp_maybe ty of
      Just (tc, [arg_ty]) -> tc == listTyCon && isCharTy arg_ty
      _                   -> False

is_tc :: Unique -> Type -> Bool
-- Newtypes are opaque to this
is_tc uniq ty = case tcSplitTyConApp_maybe ty of
			Just (tc, _) -> uniq == getUnique tc
			Nothing	     -> False
\end{code} \begin{code}
-- NB: Currently used in places where we have already expanded type synonyms;
--     hence no 'coreView'.  This could, however, be changed without breaking
--     any code.
isSynFamilyTyConApp :: TcTauType -> Bool
isSynFamilyTyConApp (TyConApp tc tys) = isSynFamilyTyCon tc && 
                                      length tys == tyConArity tc 
isSynFamilyTyConApp _other            = False
\end{code} %************************************************************************ %* * \subsection{Misc} %* * %************************************************************************ \begin{code}
deNoteType :: Type -> Type
-- Remove all *outermost* type synonyms and other notes
deNoteType ty | Just ty' <- tcView ty = deNoteType ty'
deNoteType ty = ty

tcTyVarsOfType :: Type -> TcTyVarSet
-- Just the *TcTyVars* free in the type
-- (Types.tyVarsOfTypes finds all free TyVars)
tcTyVarsOfType (TyVarTy tv)	    = if isTcTyVar tv then unitVarSet tv
						      else emptyVarSet
tcTyVarsOfType (TyConApp _ tys)     = tcTyVarsOfTypes tys
tcTyVarsOfType (LitTy {})           = emptyVarSet
tcTyVarsOfType (FunTy arg res)	    = tcTyVarsOfType arg `unionVarSet` tcTyVarsOfType res
tcTyVarsOfType (AppTy fun arg)	    = tcTyVarsOfType fun `unionVarSet` tcTyVarsOfType arg
tcTyVarsOfType (ForAllTy tyvar ty)  = tcTyVarsOfType ty `delVarSet` tyvar
	-- We do sometimes quantify over skolem TcTyVars

tcTyVarsOfTypes :: [Type] -> TyVarSet
tcTyVarsOfTypes tys = foldr (unionVarSet.tcTyVarsOfType) emptyVarSet tys
\end{code} Find the free tycons and classes of a type. This is used in the front end of the compiler. \begin{code}
orphNamesOfTyCon :: TyCon -> NameSet
orphNamesOfTyCon tycon = unitNameSet (getName tycon) `unionNameSets` case tyConClass_maybe tycon of
    Nothing  -> emptyNameSet
    Just cls -> unitNameSet (getName cls)

orphNamesOfType :: Type -> NameSet
orphNamesOfType ty | Just ty' <- tcView ty = orphNamesOfType ty'
		-- Look through type synonyms (Trac #4912)
orphNamesOfType (TyVarTy _)		   = emptyNameSet
orphNamesOfType (TyConApp tycon tys)       = orphNamesOfTyCon tycon
                                             `unionNameSets` orphNamesOfTypes tys
orphNamesOfType (LitTy {})          = emptyNameSet
orphNamesOfType (FunTy arg res)	    = orphNamesOfType arg `unionNameSets` orphNamesOfType res
orphNamesOfType (AppTy fun arg)	    = orphNamesOfType fun `unionNameSets` orphNamesOfType arg
orphNamesOfType (ForAllTy _ ty)	    = orphNamesOfType ty

orphNamesOfThings :: (a -> NameSet) -> [a] -> NameSet
orphNamesOfThings f = foldr (unionNameSets . f) emptyNameSet

orphNamesOfTypes :: [Type] -> NameSet
orphNamesOfTypes = orphNamesOfThings orphNamesOfType

orphNamesOfDFunHead :: Type -> NameSet
-- Find the free type constructors and classes 
-- of the head of the dfun instance type
-- The 'dfun_head_type' is because of
--	instance Foo a => Baz T where ...
-- The decl is an orphan if Baz and T are both not locally defined,
--	even if Foo *is* locally defined
orphNamesOfDFunHead dfun_ty 
  = case tcSplitSigmaTy dfun_ty of
	(_, _, head_ty) -> orphNamesOfType head_ty
        
orphNamesOfCo :: Coercion -> NameSet
orphNamesOfCo (Refl _ ty)           = orphNamesOfType ty
orphNamesOfCo (TyConAppCo _ tc cos) = unitNameSet (getName tc) `unionNameSets` orphNamesOfCos cos
orphNamesOfCo (AppCo co1 co2)       = orphNamesOfCo co1 `unionNameSets` orphNamesOfCo co2
orphNamesOfCo (ForAllCo _ co)       = orphNamesOfCo co
orphNamesOfCo (CoVarCo _)           = emptyNameSet
orphNamesOfCo (AxiomInstCo con _ cos) = orphNamesOfCoCon con `unionNameSets` orphNamesOfCos cos
orphNamesOfCo (UnivCo _ ty1 ty2)    = orphNamesOfType ty1 `unionNameSets` orphNamesOfType ty2
orphNamesOfCo (SymCo co)            = orphNamesOfCo co
orphNamesOfCo (TransCo co1 co2)     = orphNamesOfCo co1 `unionNameSets` orphNamesOfCo co2
orphNamesOfCo (NthCo _ co)          = orphNamesOfCo co
orphNamesOfCo (LRCo  _ co)          = orphNamesOfCo co
orphNamesOfCo (InstCo co ty)        = orphNamesOfCo co `unionNameSets` orphNamesOfType ty
orphNamesOfCo (SubCo co)            = orphNamesOfCo co

orphNamesOfCos :: [Coercion] -> NameSet
orphNamesOfCos = orphNamesOfThings orphNamesOfCo

orphNamesOfCoCon :: CoAxiom br -> NameSet
orphNamesOfCoCon (CoAxiom { co_ax_tc = tc, co_ax_branches = branches })
  = orphNamesOfTyCon tc `unionNameSets` orphNamesOfCoAxBranches branches

orphNamesOfCoAxBranches :: BranchList CoAxBranch br -> NameSet
orphNamesOfCoAxBranches = brListFoldr (unionNameSets . orphNamesOfCoAxBranch) emptyNameSet

orphNamesOfCoAxBranch :: CoAxBranch -> NameSet
orphNamesOfCoAxBranch (CoAxBranch { cab_lhs = lhs, cab_rhs = rhs })
  = orphNamesOfTypes lhs `unionNameSets` orphNamesOfType rhs
\end{code} %************************************************************************ %* * \subsection[TysWiredIn-ext-type]{External types} %* * %************************************************************************ The compiler's foreign function interface supports the passing of a restricted set of types as arguments and results (the restricting factor being the ) \begin{code}
tcSplitIOType_maybe :: Type -> Maybe (TyCon, Type)
-- (tcSplitIOType_maybe t) returns Just (IO,t',co)
--              if co : t ~ IO t'
--              returns Nothing otherwise
tcSplitIOType_maybe ty
  = case tcSplitTyConApp_maybe ty of
        Just (io_tycon, [io_res_ty])
         | io_tycon `hasKey` ioTyConKey ->
            Just (io_tycon, io_res_ty)
        _ ->
            Nothing

isFFITy :: Type -> Bool
-- True for any TyCon that can possibly be an arg or result of an FFI call
isFFITy ty = checkRepTyCon legalFFITyCon ty

isFFIArgumentTy :: DynFlags -> Safety -> Type -> Bool
-- Checks for valid argument type for a 'foreign import'
isFFIArgumentTy dflags safety ty 
   = checkRepTyCon (legalOutgoingTyCon dflags safety) ty

isFFIExternalTy :: Type -> Bool
-- Types that are allowed as arguments of a 'foreign export'
isFFIExternalTy ty = checkRepTyCon legalFEArgTyCon ty

isFFIImportResultTy :: DynFlags -> Type -> Bool
isFFIImportResultTy dflags ty 
  = checkRepTyCon (legalFIResultTyCon dflags) ty

isFFIExportResultTy :: Type -> Bool
isFFIExportResultTy ty = checkRepTyCon legalFEResultTyCon ty

isFFIDynTy :: Type -> Type -> Bool
-- The type in a foreign import dynamic must be Ptr, FunPtr, or a newtype of
-- either, and the wrapped function type must be equal to the given type.
-- We assume that all types have been run through normalizeFfiType, so we don't
-- need to worry about expanding newtypes here.
isFFIDynTy expected ty
    -- Note [Foreign import dynamic]
    -- In the example below, expected would be 'CInt -> IO ()', while ty would
    -- be 'FunPtr (CDouble -> IO ())'.
    | Just (tc, [ty']) <- splitTyConApp_maybe ty
    , tyConUnique tc `elem` [ptrTyConKey, funPtrTyConKey]
    , eqType ty' expected
    = True
    | otherwise
    = False

isFFILabelTy :: Type -> Bool
-- The type of a foreign label must be Ptr, FunPtr, or a newtype of either.
isFFILabelTy = checkRepTyConKey [ptrTyConKey, funPtrTyConKey]

isFFIPrimArgumentTy :: DynFlags -> Type -> Bool
-- Checks for valid argument type for a 'foreign import prim'
-- Currently they must all be simple unlifted types, or the well-known type
-- Any, which can be used to pass the address to a Haskell object on the heap to
-- the foreign function.
isFFIPrimArgumentTy dflags ty
   = isAnyTy ty || checkRepTyCon (legalFIPrimArgTyCon dflags) ty

isFFIPrimResultTy :: DynFlags -> Type -> Bool
-- Checks for valid result type for a 'foreign import prim'
-- Currently it must be an unlifted type, including unboxed tuples.
isFFIPrimResultTy dflags ty
   = checkRepTyCon (legalFIPrimResultTyCon dflags) ty

isFFIDotnetTy :: DynFlags -> Type -> Bool
isFFIDotnetTy dflags ty
  = checkRepTyCon (\ tc -> (legalFIResultTyCon dflags tc || 
			   isFFIDotnetObjTy ty || isStringTy ty)) ty
	-- NB: isStringTy used to look through newtypes, but
	--     it no longer does so.  May need to adjust isFFIDotNetTy
	--     if we do want to look through newtypes.

isFFIDotnetObjTy :: Type -> Bool
isFFIDotnetObjTy ty
  = checkRepTyCon check_tc t_ty
  where
   (_, t_ty) = tcSplitForAllTys ty
   check_tc tc = getName tc == objectTyConName

isFunPtrTy :: Type -> Bool
isFunPtrTy = checkRepTyConKey [funPtrTyConKey]

-- normaliseFfiType gets run before checkRepTyCon, so we don't
-- need to worry about looking through newtypes or type functions
-- here; that's already been taken care of.
checkRepTyCon :: (TyCon -> Bool) -> Type -> Bool
checkRepTyCon check_tc ty
    | Just (tc, _) <- splitTyConApp_maybe ty
    = check_tc tc
    | otherwise
    = False

checkRepTyConKey :: [Unique] -> Type -> Bool
-- Like checkRepTyCon, but just looks at the TyCon key
checkRepTyConKey keys
  = checkRepTyCon (\tc -> tyConUnique tc `elem` keys)
\end{code} Note [Foreign import dynamic] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ A dynamic stub must be of the form 'FunPtr ft -> ft' where ft is any foreign type. Similarly, a wrapper stub must be of the form 'ft -> IO (FunPtr ft)'. We use isFFIDynTy to check whether a signature is well-formed. For example, given a (illegal) declaration like: foreign import ccall "dynamic" foo :: FunPtr (CDouble -> IO ()) -> CInt -> IO () isFFIDynTy will compare the 'FunPtr' type 'CDouble -> IO ()' with the curried result type 'CInt -> IO ()', and return False, as they are not equal. ---------------------------------------------- These chaps do the work; they are not exported ---------------------------------------------- \begin{code}
legalFEArgTyCon :: TyCon -> Bool
legalFEArgTyCon tc
  -- It's illegal to make foreign exports that take unboxed
  -- arguments.  The RTS API currently can't invoke such things.  --SDM 7/2000
  = boxedMarshalableTyCon tc

legalFIResultTyCon :: DynFlags -> TyCon -> Bool
legalFIResultTyCon dflags tc
  | tc == unitTyCon         = True
  | otherwise	            = marshalableTyCon dflags tc

legalFEResultTyCon :: TyCon -> Bool
legalFEResultTyCon tc
  | tc == unitTyCon         = True
  | otherwise               = boxedMarshalableTyCon tc

legalOutgoingTyCon :: DynFlags -> Safety -> TyCon -> Bool
-- Checks validity of types going from Haskell -> external world
legalOutgoingTyCon dflags _ tc
  = marshalableTyCon dflags tc

legalFFITyCon :: TyCon -> Bool
-- True for any TyCon that can possibly be an arg or result of an FFI call
legalFFITyCon tc
  = isUnLiftedTyCon tc || boxedMarshalableTyCon tc || tc == unitTyCon

marshalableTyCon :: DynFlags -> TyCon -> Bool
marshalableTyCon dflags tc
  =  (xopt Opt_UnliftedFFITypes dflags 
      && isUnLiftedTyCon tc
      && not (isUnboxedTupleTyCon tc)
      && case tyConPrimRep tc of	-- Note [Marshalling VoidRep]
	   VoidRep -> False
	   _       -> True)
  || boxedMarshalableTyCon tc

boxedMarshalableTyCon :: TyCon -> Bool
boxedMarshalableTyCon tc
   = getUnique tc `elem` [ intTyConKey, int8TyConKey, int16TyConKey
			 , int32TyConKey, int64TyConKey
			 , wordTyConKey, word8TyConKey, word16TyConKey
			 , word32TyConKey, word64TyConKey
			 , floatTyConKey, doubleTyConKey
			 , ptrTyConKey, funPtrTyConKey
			 , charTyConKey
			 , stablePtrTyConKey
			 , boolTyConKey
			 ]

legalFIPrimArgTyCon :: DynFlags -> TyCon -> Bool
-- Check args of 'foreign import prim', only allow simple unlifted types.
-- Strictly speaking it is unnecessary to ban unboxed tuples here since
-- currently they're of the wrong kind to use in function args anyway.
legalFIPrimArgTyCon dflags tc
  = xopt Opt_UnliftedFFITypes dflags
    && isUnLiftedTyCon tc
    && not (isUnboxedTupleTyCon tc)

legalFIPrimResultTyCon :: DynFlags -> TyCon -> Bool
-- Check result type of 'foreign import prim'. Allow simple unlifted
-- types and also unboxed tuple result types '... -> (# , , #)'
legalFIPrimResultTyCon dflags tc
  = xopt Opt_UnliftedFFITypes dflags
    && isUnLiftedTyCon tc
    && (isUnboxedTupleTyCon tc
        || case tyConPrimRep tc of	-- Note [Marshalling VoidRep]
	   VoidRep -> False
	   _       -> True)
\end{code} Note [Marshalling VoidRep] ~~~~~~~~~~~~~~~~~~~~~~~~~~ We don't treat State# (whose PrimRep is VoidRep) as marshalable. In turn that means you can't write foreign import foo :: Int -> State# RealWorld Reason: the back end falls over with panic "primRepHint:VoidRep"; and there is no compelling reason to permit it