+%
+% (c) The University of Glasgow 2006
+%
+
\begin{code}
module Unify (
-- Matching of types:
-- the "tc" prefix indicates that matching always
-- respects newtypes (rather than looking through them)
- tcMatchTys, tcMatchTyX, ruleMatchTyX, tcMatchPreds, MatchEnv(..)
+ tcMatchTy, tcMatchTys, tcMatchTyX,
+ ruleMatchTyX, tcMatchPreds, MatchEnv(..),
+
+ dataConCannotMatch
) where
#include "HsVersions.h"
-import Var ( Var, TyVar, tyVarKind )
+import Var
import VarEnv
import VarSet
-import Type ( typeKind, tyVarsOfType, tyVarsOfTypes, tyVarsOfTheta,
- TvSubstEnv, emptyTvSubstEnv, TvSubst(..), tcEqTypeX,
- tcView, isSubKind, repSplitAppTy_maybe )
-import TypeRep ( Type(..), PredType(..) )
+import Type
+import TyCon
+import DataCon
+import TypeRep
import Outputable
+import Util
import Maybes
\end{code}
, me_env :: RnEnv2 -- Renaming envt for nested foralls
} -- In-scope set includes template tyvars
+tcMatchTy :: TyVarSet -- Template tyvars
+ -> Type -- Template
+ -> Type -- Target
+ -> Maybe TvSubst -- One-shot; in principle the template
+ -- variables could be free in the target
+
+tcMatchTy tmpls ty1 ty2
+ = case match menv emptyTvSubstEnv ty1 ty2 of
+ Just subst_env -> Just (TvSubst in_scope subst_env)
+ Nothing -> Nothing
+ where
+ menv = ME { me_tmpls = tmpls, me_env = mkRnEnv2 in_scope }
+ in_scope = mkInScopeSet (tmpls `unionVarSet` tyVarsOfType ty2)
+ -- We're assuming that all the interesting
+ -- tyvars in tys1 are in tmpls
+
tcMatchTys :: TyVarSet -- Template tyvars
- -> [Type] -- Template
- -> [Type] -- Target
- -> Maybe TvSubst -- One-shot; in principle the template
+ -> [Type] -- Template
+ -> [Type] -- Target
+ -> Maybe TvSubst -- One-shot; in principle the template
-- variables could be free in the target
tcMatchTys tmpls tys1 tys2
-- it respects NewTypes and PredType
match menv subst ty1 ty2 | Just ty1' <- tcView ty1 = match menv subst ty1' ty2
-match menv subst ty1 ty2 | Just ty2' <- tcView ty2 = match menv subst ty1 ty2'
+ | Just ty2' <- tcView ty2 = match menv subst ty1 ty2'
match menv subst (TyVarTy tv1) ty2
- | tv1 `elemVarSet` me_tmpls menv
+ | tv1' `elemVarSet` me_tmpls menv
= case lookupVarEnv subst tv1' of
- Nothing | any (inRnEnvR rn_env) (varSetElems (tyVarsOfType ty2))
- -> Nothing -- Occurs check
- | not (typeKind ty2 `isSubKind` tyVarKind tv1)
- -> Nothing -- Kind mis-match
- | otherwise
- -> Just (extendVarEnv subst tv1 ty2)
-
- Just ty1' | tcEqTypeX (nukeRnEnvL rn_env) ty1' ty2
+ Nothing -- No existing binding
+ | any (inRnEnvR rn_env) (varSetElems (tyVarsOfType ty2))
+ -> Nothing -- Occurs check
+ | not (typeKind ty2 `isSubKind` tyVarKind tv1)
+ -> Nothing -- Kind mis-match
+ | otherwise
+ -> Just (extendVarEnv subst tv1' ty2)
+
+ Just ty1' -- There is an existing binding; check whether ty2 matches it
+ | tcEqTypeX (nukeRnEnvL rn_env) ty1' ty2
-- ty1 has no locally-bound variables, hence nukeRnEnvL
-- Note tcEqType...we are doing source-type matching here
- -> Just subst
-
- other -> Nothing
+ -> Just subst
+ | otherwise -> Nothing -- ty2 doesn't match
+
| otherwise -- tv1 is not a template tyvar
= case ty2 of
; match menv subst' ty1b ty2b }
match menv subst (AppTy ty1a ty1b) ty2
| Just (ty2a, ty2b) <- repSplitAppTy_maybe ty2
+ -- 'repSplit' used because the tcView stuff is done above
= do { subst' <- match menv subst ty1a ty2a
; match menv subst' ty1b ty2b }
\end{code}
+%************************************************************************
+%* *
+ GADTs
+%* *
+%************************************************************************
+
+Note [Pruning dead case alternatives]
+~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
+Consider data T a where
+ T1 :: T Int
+ T2 :: T a
+
+ newtype X = MkX Int
+ newtype Y = MkY Char
+
+ type family F a
+ type instance F Bool = Int
+
+Now consider case x of { T1 -> e1; T2 -> e2 }
+
+The question before the house is this: if I know something about the type
+of x, can I prune away the T1 alternative?
+
+Suppose x::T Char. It's impossible to construct a (T Char) using T1,
+ Answer = YES (clearly)
+
+Suppose x::T (F a), where 'a' is in scope. Then 'a' might be instantiated
+to 'Bool', in which case x::T Int, so
+ ANSWER = NO (clearly)
+
+Suppose x::T X. Then *in Haskell* it's impossible to construct a (non-bottom)
+value of type (T X) using T1. But *in FC* it's quite possible. The newtype
+gives a coercion
+ CoX :: X ~ Int
+So (T CoX) :: T X ~ T Int; hence (T1 `cast` sym (T CoX)) is a non-bottom value
+of type (T X) constructed with T1. Hence
+ ANSWER = NO (surprisingly)
+
+Furthermore, this can even happen; see Trac #1251. GHC's newtype-deriving
+mechanism uses a cast, just as above, to move from one dictionary to another,
+in effect giving the programmer access to CoX.
+
+Finally, suppose x::T Y. Then *even in FC* we can't construct a
+non-bottom value of type (T Y) using T1. That's because we can get
+from Y to Char, but not to Int.
+
+
+Here's a related question. data Eq a b where EQ :: Eq a a
+Consider
+ case x of { EQ -> ... }
+
+Suppose x::Eq Int Char. Is the alternative dead? Clearly yes.
+
+What about x::Eq Int a, in a context where we have evidence that a~Char.
+Then again the alternative is dead.
+
+
+ Summary
+
+We are really doing a test for unsatisfiability of the type
+constraints implied by the match. And that is clearly, in general, a
+hard thing to do.
+
+However, since we are simply dropping dead code, a conservative test
+suffices. There is a continuum of tests, ranging from easy to hard, that
+drop more and more dead code.
+
+For now we implement a very simple test: type variables match
+anything, type functions (incl newtypes) match anything, and only
+distinct data types fail to match. We can elaborate later.
+
+\begin{code}
+dataConCannotMatch :: [Type] -> DataCon -> Bool
+-- Returns True iff the data con *definitely cannot* match a
+-- scrutinee of type (T tys)
+-- where T is the type constructor for the data con
+--
+dataConCannotMatch tys con
+ | null eq_spec = False -- Common
+ | all isTyVarTy tys = False -- Also common
+ | otherwise
+ = cant_match_s (map (substTyVar subst . fst) eq_spec)
+ (map snd eq_spec)
+ where
+ dc_tvs = dataConUnivTyVars con
+ eq_spec = dataConEqSpec con
+ subst = zipTopTvSubst dc_tvs tys
+
+ cant_match_s :: [Type] -> [Type] -> Bool
+ cant_match_s tys1 tys2 = ASSERT( equalLength tys1 tys2 )
+ or (zipWith cant_match tys1 tys2)
+
+ cant_match :: Type -> Type -> Bool
+ cant_match t1 t2
+ | Just t1' <- coreView t1 = cant_match t1' t2
+ | Just t2' <- coreView t2 = cant_match t1 t2'
+
+ cant_match (FunTy a1 r1) (FunTy a2 r2)
+ = cant_match a1 a2 || cant_match r1 r2
+
+ cant_match (TyConApp tc1 tys1) (TyConApp tc2 tys2)
+ | isDataTyCon tc1 && isDataTyCon tc2
+ = tc1 /= tc2 || cant_match_s tys1 tys2
+
+ cant_match (FunTy {}) (TyConApp tc _) = isDataTyCon tc
+ cant_match (TyConApp tc _) (FunTy {}) = isDataTyCon tc
+ -- tc can't be FunTyCon by invariant
+
+ cant_match (AppTy f1 a1) ty2
+ | Just (f2, a2) <- repSplitAppTy_maybe ty2
+ = cant_match f1 f2 || cant_match a1 a2
+ cant_match ty1 (AppTy f2 a2)
+ | Just (f1, a1) <- repSplitAppTy_maybe ty1
+ = cant_match f1 f2 || cant_match a1 a2
+
+ cant_match ty1 ty2 = False -- Safe!
+
+-- Things we could add;
+-- foralls
+-- look through newtypes
+-- take account of tyvar bindings (EQ example above)
+\end{code}
\ No newline at end of file