{- (c) The University of Glasgow 2006 (c) The GRASP/AQUA Project, Glasgow University, 2000 -} {-# LANGUAGE CPP #-} -- | Functional dependencies -- -- It's better to read it as: "if we know these, then we're going to know these" module GHC.Tc.Instance.FunDeps ( FunDepEqn(..) , pprEquation , improveFromInstEnv , improveFromAnother , checkInstCoverage , checkFunDeps , pprFundeps ) where #include "HsVersions.h" import GHC.Prelude import GHC.Types.Name import GHC.Types.Var import GHC.Core.Class import GHC.Core.Predicate import GHC.Core.Type import GHC.Tc.Utils.TcType( transSuperClasses ) import GHC.Core.Coercion.Axiom( TypeEqn ) import GHC.Core.Unify import GHC.Core.InstEnv import GHC.Types.Var.Set import GHC.Types.Var.Env import GHC.Core.TyCo.FVs import GHC.Core.TyCo.Ppr( pprWithExplicitKindsWhen ) import GHC.Utils.FV import GHC.Utils.Outputable import GHC.Utils.Error( Validity(..), allValid ) import GHC.Types.SrcLoc import GHC.Utils.Misc import GHC.Data.Pair ( Pair(..) ) import Data.List ( nubBy ) import Data.Maybe import Data.Foldable ( fold ) {- ************************************************************************ * * \subsection{Generate equations from functional dependencies} * * ************************************************************************ Each functional dependency with one variable in the RHS is responsible for generating a single equality. For instance: class C a b | a -> b The constraints ([Wanted] C Int Bool) and [Wanted] C Int alpha will generate the following FunDepEqn FDEqn { fd_qtvs = [] , fd_eqs = [Pair Bool alpha] , fd_pred1 = C Int Bool , fd_pred2 = C Int alpha , fd_loc = ... } However notice that a functional dependency may have more than one variable in the RHS which will create more than one pair of types in fd_eqs. Example: class C a b c | a -> b c [Wanted] C Int alpha alpha [Wanted] C Int Bool beta Will generate: FDEqn { fd_qtvs = [] , fd_eqs = [Pair Bool alpha, Pair alpha beta] , fd_pred1 = C Int Bool , fd_pred2 = C Int alpha , fd_loc = ... } INVARIANT: Corresponding types aren't already equal That is, there exists at least one non-identity equality in FDEqs. Assume: class C a b c | a -> b c instance C Int x x And: [Wanted] C Int Bool alpha We will /match/ the LHS of fundep equations, producing a matching substitution and create equations for the RHS sides. In our last example we'd have generated: ({x}, [fd1,fd2]) where fd1 = FDEq 1 Bool x fd2 = FDEq 2 alpha x To ``execute'' the equation, make fresh type variable for each tyvar in the set, instantiate the two types with these fresh variables, and then unify or generate a new constraint. In the above example we would generate a new unification variable 'beta' for x and produce the following constraints: [Wanted] (Bool ~ beta) [Wanted] (alpha ~ beta) Notice the subtle difference between the above class declaration and: class C a b c | a -> b, a -> c where we would generate: ({x},[fd1]),({x},[fd2]) This means that the template variable would be instantiated to different unification variables when producing the FD constraints. Finally, the position parameters will help us rewrite the wanted constraint ``on the spot'' -} data FunDepEqn loc = FDEqn { fd_qtvs :: [TyVar] -- Instantiate these type and kind vars -- to fresh unification vars, -- Non-empty only for FunDepEqns arising from instance decls , fd_eqs :: [TypeEqn] -- Make these pairs of types equal , fd_pred1 :: PredType -- The FunDepEqn arose from , fd_pred2 :: PredType -- combining these two constraints , fd_loc :: loc } {- Given a bunch of predicates that must hold, such as C Int t1, C Int t2, C Bool t3, ?x::t4, ?x::t5 improve figures out what extra equations must hold. For example, if we have class C a b | a->b where ... then improve will return [(t1,t2), (t4,t5)] NOTA BENE: * improve does not iterate. It's possible that when we make t1=t2, for example, that will in turn trigger a new equation. This would happen if we also had C t1 t7, C t2 t8 If t1=t2, we also get t7=t8. improve does *not* do this extra step. It relies on the caller doing so. * The equations unify types that are not already equal. So there is no effect iff the result of improve is empty -} instFD :: FunDep TyVar -> [TyVar] -> [Type] -> FunDep Type -- (instFD fd tvs tys) returns fd instantiated with (tvs -> tys) instFD (ls,rs) tvs tys = (map lookup ls, map lookup rs) where env = zipVarEnv tvs tys lookup tv = lookupVarEnv_NF env tv zipAndComputeFDEqs :: (Type -> Type -> Bool) -- Discard this FDEq if true -> [Type] -> [Type] -> [TypeEqn] -- Create a list of (Type,Type) pairs from two lists of types, -- making sure that the types are not already equal zipAndComputeFDEqs discard (ty1:tys1) (ty2:tys2) | discard ty1 ty2 = zipAndComputeFDEqs discard tys1 tys2 | otherwise = Pair ty1 ty2 : zipAndComputeFDEqs discard tys1 tys2 zipAndComputeFDEqs _ _ _ = [] -- Improve a class constraint from another class constraint -- ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ improveFromAnother :: loc -> PredType -- Template item (usually given, or inert) -> PredType -- Workitem [that can be improved] -> [FunDepEqn loc] -- Post: FDEqs always oriented from the other to the workitem -- Equations have empty quantified variables improveFromAnother loc pred1 pred2 | Just (cls1, tys1) <- getClassPredTys_maybe pred1 , Just (cls2, tys2) <- getClassPredTys_maybe pred2 , cls1 == cls2 = [ FDEqn { fd_qtvs = [], fd_eqs = eqs, fd_pred1 = pred1, fd_pred2 = pred2, fd_loc = loc } | let (cls_tvs, cls_fds) = classTvsFds cls1 , fd <- cls_fds , let (ltys1, rs1) = instFD fd cls_tvs tys1 (ltys2, rs2) = instFD fd cls_tvs tys2 , eqTypes ltys1 ltys2 -- The LHSs match , let eqs = zipAndComputeFDEqs eqType rs1 rs2 , not (null eqs) ] improveFromAnother _ _ _ = [] -- Improve a class constraint from instance declarations -- ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ instance Outputable (FunDepEqn a) where ppr = pprEquation pprEquation :: FunDepEqn a -> SDoc pprEquation (FDEqn { fd_qtvs = qtvs, fd_eqs = pairs }) = vcat [text "forall" <+> braces (pprWithCommas ppr qtvs), nest 2 (vcat [ ppr t1 <+> text "~" <+> ppr t2 | Pair t1 t2 <- pairs])] improveFromInstEnv :: InstEnvs -> (PredType -> SrcSpan -> loc) -> PredType -> [FunDepEqn loc] -- Needs to be a FunDepEqn because -- of quantified variables -- Post: Equations oriented from the template (matching instance) to the workitem! improveFromInstEnv inst_env mk_loc pred | Just (cls, tys) <- ASSERT2( isClassPred pred, ppr pred ) getClassPredTys_maybe pred , let (cls_tvs, cls_fds) = classTvsFds cls instances = classInstances inst_env cls rough_tcs = roughMatchTcs tys = [ FDEqn { fd_qtvs = meta_tvs, fd_eqs = eqs , fd_pred1 = p_inst, fd_pred2 = pred , fd_loc = mk_loc p_inst (getSrcSpan (is_dfun ispec)) } | fd <- cls_fds -- Iterate through the fundeps first, -- because there often are none! , let trimmed_tcs = trimRoughMatchTcs cls_tvs fd rough_tcs -- Trim the rough_tcs based on the head of the fundep. -- Remember that instanceCantMatch treats both arguments -- symmetrically, so it's ok to trim the rough_tcs, -- rather than trimming each inst_tcs in turn , ispec <- instances , (meta_tvs, eqs) <- improveClsFD cls_tvs fd ispec tys trimmed_tcs -- NB: orientation , let p_inst = mkClassPred cls (is_tys ispec) ] improveFromInstEnv _ _ _ = [] improveClsFD :: [TyVar] -> FunDep TyVar -- One functional dependency from the class -> ClsInst -- An instance template -> [Type] -> [Maybe Name] -- Arguments of this (C tys) predicate -> [([TyCoVar], [TypeEqn])] -- Empty or singleton improveClsFD clas_tvs fd (ClsInst { is_tvs = qtvs, is_tys = tys_inst, is_tcs = rough_tcs_inst }) tys_actual rough_tcs_actual -- Compare instance {a,b} C sx sp sy sq -- with wanted [W] C tx tp ty tq -- for fundep (x,y -> p,q) from class (C x p y q) -- If (sx,sy) unifies with (tx,ty), take the subst S -- 'qtvs' are the quantified type variables, the ones which can be instantiated -- to make the types match. For example, given -- class C a b | a->b where ... -- instance C (Maybe x) (Tree x) where .. -- -- and a wanted constraint of form (C (Maybe t1) t2), -- then we will call checkClsFD with -- -- is_qtvs = {x}, is_tys = [Maybe x, Tree x] -- tys_actual = [Maybe t1, t2] -- -- We can instantiate x to t1, and then we want to force -- (Tree x) [t1/x] ~ t2 | instanceCantMatch rough_tcs_inst rough_tcs_actual = [] -- Filter out ones that can't possibly match, | otherwise = ASSERT2( equalLength tys_inst tys_actual && equalLength tys_inst clas_tvs , ppr tys_inst <+> ppr tys_actual ) case tcMatchTyKis ltys1 ltys2 of Nothing -> [] Just subst | isJust (tcMatchTyKisX subst rtys1 rtys2) -- Don't include any equations that already hold. -- Reason: then we know if any actual improvement has happened, -- in which case we need to iterate the solver -- In making this check we must taking account of the fact that any -- qtvs that aren't already instantiated can be instantiated to anything -- at all -- NB: We can't do this 'is-useful-equation' check element-wise -- because of: -- class C a b c | a -> b c -- instance C Int x x -- [Wanted] C Int alpha Int -- We would get that x -> alpha (isJust) and x -> Int (isJust) -- so we would produce no FDs, which is clearly wrong. -> [] | null fdeqs -> [] | otherwise -> -- pprTrace "iproveClsFD" (vcat -- [ text "is_tvs =" <+> ppr qtvs -- , text "tys_inst =" <+> ppr tys_inst -- , text "tys_actual =" <+> ppr tys_actual -- , text "ltys1 =" <+> ppr ltys1 -- , text "ltys2 =" <+> ppr ltys2 -- , text "subst =" <+> ppr subst ]) $ [(meta_tvs, fdeqs)] -- We could avoid this substTy stuff by producing the eqn -- (qtvs, ls1++rs1, ls2++rs2) -- which will re-do the ls1/ls2 unification when the equation is -- executed. What we're doing instead is recording the partial -- work of the ls1/ls2 unification leaving a smaller unification problem where rtys1' = map (substTyUnchecked subst) rtys1 fdeqs = zipAndComputeFDEqs (\_ _ -> False) rtys1' rtys2 -- Don't discard anything! -- We could discard equal types but it's an overkill to call -- eqType again, since we know for sure that /at least one/ -- equation in there is useful) meta_tvs = [ setVarType tv (substTyUnchecked subst (varType tv)) | tv <- qtvs, tv `notElemTCvSubst` subst ] -- meta_tvs are the quantified type variables -- that have not been substituted out -- -- Eg. class C a b | a -> b -- instance C Int [y] -- Given constraint C Int z -- we generate the equation -- ({y}, [y], z) -- -- But note (a) we get them from the dfun_id, so they are *in order* -- because the kind variables may be mentioned in the -- type variables' kinds -- (b) we must apply 'subst' to the kinds, in case we have -- matched out a kind variable, but not a type variable -- whose kind mentions that kind variable! -- #6015, #6068 where (ltys1, rtys1) = instFD fd clas_tvs tys_inst (ltys2, rtys2) = instFD fd clas_tvs tys_actual {- %************************************************************************ %* * The Coverage condition for instance declarations * * ************************************************************************ Note [Coverage condition] ~~~~~~~~~~~~~~~~~~~~~~~~~ Example class C a b | a -> b instance theta => C t1 t2 For the coverage condition, we check (normal) fv(t2) `subset` fv(t1) (liberal) fv(t2) `subset` oclose(fv(t1), theta) The liberal version ensures the self-consistency of the instance, but it does not guarantee termination. Example: class Mul a b c | a b -> c where (.*.) :: a -> b -> c instance Mul Int Int Int where (.*.) = (*) instance Mul Int Float Float where x .*. y = fromIntegral x * y instance Mul a b c => Mul a [b] [c] where x .*. v = map (x.*.) v In the third instance, it's not the case that fv([c]) `subset` fv(a,[b]). But it is the case that fv([c]) `subset` oclose( theta, fv(a,[b]) ) But it is a mistake to accept the instance because then this defn: f = \ b x y -> if b then x .*. [y] else y makes instance inference go into a loop, because it requires the constraint Mul a [b] b -} checkInstCoverage :: Bool -- Be liberal -> Class -> [PredType] -> [Type] -> Validity -- "be_liberal" flag says whether to use "liberal" coverage of -- See Note [Coverage Condition] below -- -- Return values -- Nothing => no problems -- Just msg => coverage problem described by msg checkInstCoverage be_liberal clas theta inst_taus = allValid (map fundep_ok fds) where (tyvars, fds) = classTvsFds clas fundep_ok fd | and (isEmptyVarSet <$> undetermined_tvs) = IsValid | otherwise = NotValid msg where (ls,rs) = instFD fd tyvars inst_taus ls_tvs = tyCoVarsOfTypes ls rs_tvs = splitVisVarsOfTypes rs undetermined_tvs | be_liberal = liberal_undet_tvs | otherwise = conserv_undet_tvs closed_ls_tvs = oclose theta ls_tvs liberal_undet_tvs = (`minusVarSet` closed_ls_tvs) <$> rs_tvs conserv_undet_tvs = (`minusVarSet` ls_tvs) <$> rs_tvs undet_set = fold undetermined_tvs msg = pprWithExplicitKindsWhen (isEmptyVarSet $ pSnd undetermined_tvs) $ vcat [ -- text "ls_tvs" <+> ppr ls_tvs -- , text "closed ls_tvs" <+> ppr (closeOverKinds ls_tvs) -- , text "theta" <+> ppr theta -- , text "oclose" <+> ppr (oclose theta (closeOverKinds ls_tvs)) -- , text "rs_tvs" <+> ppr rs_tvs sep [ text "The" <+> ppWhen be_liberal (text "liberal") <+> text "coverage condition fails in class" <+> quotes (ppr clas) , nest 2 $ text "for functional dependency:" <+> quotes (pprFunDep fd) ] , sep [ text "Reason: lhs type"<>plural ls <+> pprQuotedList ls , nest 2 $ (if isSingleton ls then text "does not" else text "do not jointly") <+> text "determine rhs type"<>plural rs <+> pprQuotedList rs ] , text "Un-determined variable" <> pluralVarSet undet_set <> colon <+> pprVarSet undet_set (pprWithCommas ppr) , ppWhen (not be_liberal && and (isEmptyVarSet <$> liberal_undet_tvs)) $ text "Using UndecidableInstances might help" ] {- Note [Closing over kinds in coverage] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Suppose we have a fundep (a::k) -> b Then if 'a' is instantiated to (x y), where x:k2->*, y:k2, then fixing x really fixes k2 as well, and so k2 should be added to the lhs tyvars in the fundep check. Example (#8391), using liberal coverage data Foo a = ... -- Foo :: forall k. k -> * class Bar a b | a -> b instance Bar a (Foo a) In the instance decl, (a:k) does fix (Foo k a), but only if we notice that (a:k) fixes k. #10109 is another example. Here is a more subtle example, from HList-0.4.0.0 (#10564) class HasFieldM (l :: k) r (v :: Maybe *) | l r -> v where ... class HasFieldM1 (b :: Maybe [*]) (l :: k) r v | b l r -> v where ... class HMemberM (e1 :: k) (l :: [k]) (r :: Maybe [k]) | e1 l -> r data Label :: k -> * type family LabelsOf (a :: [*]) :: * instance (HMemberM (Label {k} (l::k)) (LabelsOf xs) b, HasFieldM1 b l (r xs) v) => HasFieldM l (r xs) v where Is the instance OK? Does {l,r,xs} determine v? Well: * From the instance constraint HMemberM (Label k l) (LabelsOf xs) b, plus the fundep "| el l -> r" in class HMameberM, we get {l,k,xs} -> b * Note the 'k'!! We must call closeOverKinds on the seed set ls_tvs = {l,r,xs}, BEFORE doing oclose, else the {l,k,xs}->b fundep won't fire. This was the reason for #10564. * So starting from seeds {l,r,xs,k} we do oclose to get first {l,r,xs,k,b}, via the HMemberM constraint, and then {l,r,xs,k,b,v}, via the HasFieldM1 constraint. * And that fixes v. However, we must closeOverKinds whenever augmenting the seed set in oclose! Consider #10109: data Succ a -- Succ :: forall k. k -> * class Add (a :: k1) (b :: k2) (ab :: k3) | a b -> ab instance (Add a b ab) => Add (Succ {k1} (a :: k1)) b (Succ {k3} (ab :: k3}) We start with seed set {a:k1,b:k2} and closeOverKinds to {a,k1,b,k2}. Now use the fundep to extend to {a,k1,b,k2,ab}. But we need to closeOverKinds *again* now to {a,k1,b,k2,ab,k3}, so that we fix all the variables free in (Succ {k3} ab). Bottom line: * closeOverKinds on initial seeds (done automatically by tyCoVarsOfTypes in checkInstCoverage) * and closeOverKinds whenever extending those seeds (in oclose) Note [The liberal coverage condition] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ (oclose preds tvs) closes the set of type variables tvs, wrt functional dependencies in preds. The result is a superset of the argument set. For example, if we have class C a b | a->b where ... then oclose [C (x,y) z, C (x,p) q] {x,y} = {x,y,z} because if we know x and y then that fixes z. We also use equality predicates in the predicates; if we have an assumption `t1 ~ t2`, then we use the fact that if we know `t1` we also know `t2` and the other way. eg oclose [C (x,y) z, a ~ x] {a,y} = {a,y,z,x} oclose is used (only) when checking the coverage condition for an instance declaration Note [Equality superclasses] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Suppose we have class (a ~ [b]) => C a b Remember from Note [The equality types story] in GHC.Builtin.Types.Prim, that * (a ~~ b) is a superclass of (a ~ b) * (a ~# b) is a superclass of (a ~~ b) So when oclose expands superclasses we'll get a (a ~# [b]) superclass. But that's an EqPred not a ClassPred, and we jolly well do want to account for the mutual functional dependencies implied by (t1 ~# t2). Hence the EqPred handling in oclose. See #10778. Note [Care with type functions] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Consider (#12803) class C x y | x -> y type family F a b type family G c d = r | r -> d Now consider oclose (C (F a b) (G c d)) {a,b} Knowing {a,b} fixes (F a b) regardless of the injectivity of F. But knowing (G c d) fixes only {d}, because G is only injective in its second parameter. Hence the tyCoVarsOfTypes/injTyVarsOfTypes dance in tv_fds. -} oclose :: [PredType] -> TyCoVarSet -> TyCoVarSet -- See Note [The liberal coverage condition] oclose preds fixed_tvs | null tv_fds = fixed_tvs -- Fast escape hatch for common case. | otherwise = fixVarSet extend fixed_tvs where extend fixed_tvs = foldl' add fixed_tvs tv_fds where add fixed_tvs (ls,rs) | ls `subVarSet` fixed_tvs = fixed_tvs `unionVarSet` closeOverKinds rs | otherwise = fixed_tvs -- closeOverKinds: see Note [Closing over kinds in coverage] tv_fds :: [(TyCoVarSet,TyCoVarSet)] tv_fds = [ (tyCoVarsOfTypes ls, fvVarSet $ injectiveVarsOfTypes True rs) -- See Note [Care with type functions] | pred <- preds , pred' <- pred : transSuperClasses pred -- Look for fundeps in superclasses too , (ls, rs) <- determined pred' ] determined :: PredType -> [([Type],[Type])] determined pred = case classifyPredType pred of EqPred NomEq t1 t2 -> [([t1],[t2]), ([t2],[t1])] -- See Note [Equality superclasses] ClassPred cls tys -> [ instFD fd cls_tvs tys | let (cls_tvs, cls_fds) = classTvsFds cls , fd <- cls_fds ] _ -> [] {- ********************************************************************* * * Check that a new instance decl is OK wrt fundeps * * ************************************************************************ Here is the bad case: class C a b | a->b where ... instance C Int Bool where ... instance C Int Char where ... The point is that a->b, so Int in the first parameter must uniquely determine the second. In general, given the same class decl, and given instance C s1 s2 where ... instance C t1 t2 where ... Then the criterion is: if U=unify(s1,t1) then U(s2) = U(t2). Matters are a little more complicated if there are free variables in the s2/t2. class D a b c | a -> b instance D a b => D [(a,a)] [b] Int instance D a b => D [a] [b] Bool The instance decls don't overlap, because the third parameter keeps them separate. But we want to make sure that given any constraint D s1 s2 s3 if s1 matches Note [Bogus consistency check] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ In checkFunDeps we check that a new ClsInst is consistent with all the ClsInsts in the environment. The bogus aspect is discussed in #10675. Currently it if the two types are *contradicatory*, using (isNothing . tcUnifyTys). But all the papers say we should check if the two types are *equal* thus not (substTys subst rtys1 `eqTypes` substTys subst rtys2) For now I'm leaving the bogus form because that's the way it has been for years. -} checkFunDeps :: InstEnvs -> ClsInst -> [ClsInst] -- The Consistency Check. -- Check whether adding DFunId would break functional-dependency constraints -- Used only for instance decls defined in the module being compiled -- Returns a list of the ClsInst in InstEnvs that are inconsistent -- with the proposed new ClsInst checkFunDeps inst_envs (ClsInst { is_tvs = qtvs1, is_cls = cls , is_tys = tys1, is_tcs = rough_tcs1 }) | null fds = [] | otherwise = nubBy eq_inst $ [ ispec | ispec <- cls_insts , fd <- fds , is_inconsistent fd ispec ] where cls_insts = classInstances inst_envs cls (cls_tvs, fds) = classTvsFds cls qtv_set1 = mkVarSet qtvs1 is_inconsistent fd (ClsInst { is_tvs = qtvs2, is_tys = tys2, is_tcs = rough_tcs2 }) | instanceCantMatch trimmed_tcs rough_tcs2 = False | otherwise = case tcUnifyTyKis bind_fn ltys1 ltys2 of Nothing -> False Just subst -> isNothing $ -- Bogus legacy test (#10675) -- See Note [Bogus consistency check] tcUnifyTyKis bind_fn (substTysUnchecked subst rtys1) (substTysUnchecked subst rtys2) where trimmed_tcs = trimRoughMatchTcs cls_tvs fd rough_tcs1 (ltys1, rtys1) = instFD fd cls_tvs tys1 (ltys2, rtys2) = instFD fd cls_tvs tys2 qtv_set2 = mkVarSet qtvs2 bind_fn tv | tv `elemVarSet` qtv_set1 = BindMe | tv `elemVarSet` qtv_set2 = BindMe | otherwise = Skolem eq_inst i1 i2 = instanceDFunId i1 == instanceDFunId i2 -- A single instance may appear twice in the un-nubbed conflict list -- because it may conflict with more than one fundep. E.g. -- class C a b c | a -> b, a -> c -- instance C Int Bool Bool -- instance C Int Char Char -- The second instance conflicts with the first by *both* fundeps trimRoughMatchTcs :: [TyVar] -> FunDep TyVar -> [Maybe Name] -> [Maybe Name] -- Computing rough_tcs for a particular fundep -- class C a b c | a -> b where ... -- For each instance .... => C ta tb tc -- we want to match only on the type ta; so our -- rough-match thing must similarly be filtered. -- Hence, we Nothing-ise the tb and tc types right here -- -- Result list is same length as input list, just with more Nothings trimRoughMatchTcs clas_tvs (ltvs, _) mb_tcs = zipWith select clas_tvs mb_tcs where select clas_tv mb_tc | clas_tv `elem` ltvs = mb_tc | otherwise = Nothing