import TcType
import TcRnMonad
import TyCon
-import Type
import Name
import Module
import SrcLoc
-- (since we do unification).
-- We use tcInstSkolType because we don't want to allocate
-- fresh *meta* type variables.
- ; let { tycon = famInstTyCon famInst
- ; ty = case tyConFamInst_maybe tycon of
- Nothing -> panic "FamInst.checkForConflicts"
- Just (tc, tys) -> tc `mkTyConApp` tys
- }
- ; (_, _, tau') <- tcInstSkolType FamInstSkol ty
-
- ; let (fam, tys') = tcSplitTyConApp tau'
-
- ; let { matches = lookupFamInstEnvUnify inst_envs fam tys'
- ; conflicts = [ conflictingFamInst
- | match@((conflictingFamInst, _), _) <- matches
- , conflicting tycon match
- ]
- }
+
+ ; skol_tvs <- tcInstSkolTyVars FamInstSkol (tyConTyVars (famInstTyCon famInst))
+ ; let conflicts = lookupFamInstEnvConflicts inst_envs famInst skol_tvs
; unless (null conflicts) $
- conflictInstErr famInst (head conflicts)
+ conflictInstErr famInst (fst (head conflicts))
}
where
- -- - In the case of data family instances, any overlap is fundamentally a
- -- conflict (as these instances imply injective type mappings).
- -- - In the case of type family instances, overlap is admitted as long as
- -- the right-hand sides of the overlapping rules coincide under the
- -- overlap substitution. We require that they are syntactically equal;
- -- anything else would be difficult to test for at this stage.
- conflicting tycon1 ((famInst2, _), subst)
- | isAlgTyCon tycon1 = True
- | otherwise = not (rhs1 `tcEqType` rhs2)
- where
- tycon2 = famInstTyCon famInst2
- rhs1 = substTy subst $ synTyConType tycon1
- rhs2 = substTy subst $ synTyConType tycon2
conflictInstErr :: FamInst -> FamInst -> TcRn ()
conflictInstErr famInst conflictingFamInst