{-# LANGUAGE BangPatterns #-} {-# LANGUAGE DeriveFunctor #-} {-# OPTIONS_GHC -Wno-incomplete-record-updates #-} module GHC.Tc.Solver.Rewrite( rewrite, rewriteArgsNom, rewriteType ) where import GHC.Prelude import GHC.Core.TyCo.Ppr ( pprTyVar ) import GHC.Tc.Types ( TcGblEnv(tcg_tc_plugin_rewriters), TcPluginRewriter, TcPluginRewriteResult(..), RewriteEnv(..), runTcPluginM ) import GHC.Tc.Types.Constraint import GHC.Core.Predicate import GHC.Tc.Utils.TcType import GHC.Core.Type import GHC.Tc.Types.Evidence import GHC.Core.TyCon import GHC.Core.TyCo.Rep -- performs delicate algorithm on types import GHC.Core.Coercion import GHC.Core.Reduction import GHC.Types.Unique.FM import GHC.Types.Var import GHC.Types.Var.Set import GHC.Types.Var.Env import GHC.Driver.Session import GHC.Utils.Outputable import GHC.Utils.Panic import GHC.Utils.Panic.Plain import GHC.Tc.Solver.Monad as TcS import GHC.Utils.Misc import GHC.Data.Maybe import GHC.Exts (oneShot) import Control.Monad import Control.Applicative (liftA3) import GHC.Builtin.Types.Prim (tYPETyCon) import Data.List ( find ) {- ************************************************************************ * * * RewriteEnv & RewriteM * The rewriting environment & monad * * ************************************************************************ -} -- | The 'RewriteM' monad is a wrapper around 'TcS' with a 'RewriteEnv' newtype RewriteM a = RewriteM { runRewriteM :: RewriteEnv -> TcS a } deriving (Functor) -- | Smart constructor for 'RewriteM', as describe in Note [The one-shot state -- monad trick] in "GHC.Utils.Monad". mkRewriteM :: (RewriteEnv -> TcS a) -> RewriteM a mkRewriteM f = RewriteM (oneShot f) {-# INLINE mkRewriteM #-} instance Monad RewriteM where m >>= k = mkRewriteM $ \env -> do { a <- runRewriteM m env ; runRewriteM (k a) env } instance Applicative RewriteM where pure x = mkRewriteM $ \_ -> pure x (<*>) = ap instance HasDynFlags RewriteM where getDynFlags = liftTcS getDynFlags liftTcS :: TcS a -> RewriteM a liftTcS thing_inside = mkRewriteM $ \_ -> thing_inside -- convenient wrapper when you have a CtEvidence describing -- the rewriting operation runRewriteCtEv :: CtEvidence -> RewriteM a -> TcS (a, RewriterSet) runRewriteCtEv ev = runRewrite (ctEvLoc ev) (ctEvFlavour ev) (ctEvEqRel ev) -- Run thing_inside (which does the rewriting) -- Also returns the set of Wanteds which rewrote a Wanted; -- See Note [Wanteds rewrite Wanteds] in GHC.Tc.Types.Constraint runRewrite :: CtLoc -> CtFlavour -> EqRel -> RewriteM a -> TcS (a, RewriterSet) runRewrite loc flav eq_rel thing_inside = do { rewriters_ref <- newTcRef emptyRewriterSet ; let fmode = RE { re_loc = loc , re_flavour = flav , re_eq_rel = eq_rel , re_rewriters = rewriters_ref } ; res <- runRewriteM thing_inside fmode ; rewriters <- readTcRef rewriters_ref ; return (res, rewriters) } traceRewriteM :: String -> SDoc -> RewriteM () traceRewriteM herald doc = liftTcS $ traceTcS herald doc {-# INLINE traceRewriteM #-} -- see Note [INLINE conditional tracing utilities] getRewriteEnv :: RewriteM RewriteEnv getRewriteEnv = mkRewriteM $ \env -> return env getRewriteEnvField :: (RewriteEnv -> a) -> RewriteM a getRewriteEnvField accessor = mkRewriteM $ \env -> return (accessor env) getEqRel :: RewriteM EqRel getEqRel = getRewriteEnvField re_eq_rel getRole :: RewriteM Role getRole = eqRelRole <$> getEqRel getFlavour :: RewriteM CtFlavour getFlavour = getRewriteEnvField re_flavour getFlavourRole :: RewriteM CtFlavourRole getFlavourRole = do { flavour <- getFlavour ; eq_rel <- getEqRel ; return (flavour, eq_rel) } getLoc :: RewriteM CtLoc getLoc = getRewriteEnvField re_loc checkStackDepth :: Type -> RewriteM () checkStackDepth ty = do { loc <- getLoc ; liftTcS $ checkReductionDepth loc ty } -- | Change the 'EqRel' in a 'RewriteM'. setEqRel :: EqRel -> RewriteM a -> RewriteM a setEqRel new_eq_rel thing_inside = mkRewriteM $ \env -> if new_eq_rel == re_eq_rel env then runRewriteM thing_inside env else runRewriteM thing_inside (env { re_eq_rel = new_eq_rel }) {-# INLINE setEqRel #-} bumpDepth :: RewriteM a -> RewriteM a bumpDepth (RewriteM thing_inside) = mkRewriteM $ \env -> do -- bumpDepth can be called a lot during rewriting so we force the -- new env to avoid accumulating thunks. { let !env' = env { re_loc = bumpCtLocDepth (re_loc env) } ; thing_inside env' } -- See Note [Wanteds rewrite Wanteds] in GHC.Tc.Types.Constraint -- Precondition: the CtEvidence is a CtWanted of an equality recordRewriter :: CtEvidence -> RewriteM () recordRewriter (CtWanted { ctev_dest = HoleDest hole }) = RewriteM $ \env -> updTcRef (re_rewriters env) (`addRewriterSet` hole) recordRewriter other = pprPanic "recordRewriter" (ppr other) {- Note [Rewriter EqRels] ~~~~~~~~~~~~~~~~~~~~~~~ When rewriting, we need to know which equality relation -- nominal or representation -- we should be respecting. The only difference is that we rewrite variables by representational equalities when re_eq_rel is ReprEq, and that we unwrap newtypes when rewriting w.r.t. representational equality. Note [Rewriter CtLoc] ~~~~~~~~~~~~~~~~~~~~~~ The rewriter does eager type-family reduction. Type families might loop, and we don't want GHC to do so. A natural solution is to have a bounded depth to these processes. A central difficulty is that such a solution isn't quite compositional. For example, say it takes F Int 10 steps to get to Bool. How many steps does it take to get from F Int -> F Int to Bool -> Bool? 10? 20? What about getting from Const Char (F Int) to Char? 11? 1? Hard to know and hard to track. So, we punt, essentially. We store a CtLoc in the RewriteEnv and just update the environment when recurring. In the TyConApp case, where there may be multiple type families to rewrite, we just copy the current CtLoc into each branch. If any branch hits the stack limit, then the whole thing fails. A consequence of this is that setting the stack limits appropriately will be essentially impossible. So, the official recommendation if a stack limit is hit is to disable the check entirely. Otherwise, there will be baffling, unpredictable errors. Note [Phantoms in the rewriter] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Suppose we have data Proxy p = Proxy and we're rewriting (Proxy ty) w.r.t. ReprEq. Then, we know that `ty` is really irrelevant -- it will be ignored when solving for representational equality later on. So, we omit rewriting `ty` entirely. This may violate the expectation of "xi"s for a bit, but the canonicaliser will soon throw out the phantoms when decomposing a TyConApp. (Or, the canonicaliser will emit an insoluble, in which case we get a better error message anyway.) -} {- ********************************************************************* * * * Externally callable rewriting functions * * * ************************************************************************ -} -- | See Note [Rewriting]. -- If (xi, co, rewriters) <- rewrite mode ev ty, then co :: xi ~r ty -- where r is the role in @ev@. -- rewriters is the set of coercion holes that have been used to rewrite -- See Note [Wanteds rewrite Wanteds] in GHC.Tc.Types.Constraint rewrite :: CtEvidence -> TcType -> TcS (Reduction, RewriterSet) rewrite ev ty = do { traceTcS "rewrite {" (ppr ty) ; result@(redn, _) <- runRewriteCtEv ev (rewrite_one ty) ; traceTcS "rewrite }" (ppr $ reductionReducedType redn) ; return result } -- See Note [Rewriting] rewriteArgsNom :: CtEvidence -> TyCon -> [TcType] -> TcS (Reductions, RewriterSet) -- Externally-callable, hence runRewrite -- Rewrite a vector of types all at once; in fact they are -- always the arguments of type family or class, so -- ctEvFlavour ev = Nominal -- and we want to rewrite all at nominal role -- The kind passed in is the kind of the type family or class, call it T -- The kind of T args must be constant (i.e. not depend on the args) -- -- Final return value returned which Wanteds rewrote another Wanted -- See Note [Wanteds rewrite Wanteds] in GHC.Tc.Types.Constraint rewriteArgsNom ev tc tys = do { traceTcS "rewrite_args {" (vcat (map ppr tys)) ; (ArgsReductions redns@(Reductions _ tys') kind_co, rewriters) <- runRewriteCtEv ev (rewrite_args_tc tc Nothing tys) ; massert (isReflMCo kind_co) ; traceTcS "rewrite }" (vcat (map ppr tys')) ; return (redns, rewriters) } -- | Rewrite a type w.r.t. nominal equality. This is useful to rewrite -- a type w.r.t. any givens. It does not do type-family reduction. This -- will never emit new constraints. Call this when the inert set contains -- only givens. rewriteType :: CtLoc -> TcType -> TcS TcType rewriteType loc ty = do { (redn, _) <- runRewrite loc Given NomEq $ rewrite_one ty -- use Given flavor so that it is rewritten -- only w.r.t. Givens, never Wanteds -- (Shouldn't matter, if only Givens are present -- anyway) ; return $ reductionReducedType redn } {- ********************************************************************* * * * The main rewriting functions * * ********************************************************************* -} {- Note [Rewriting] ~~~~~~~~~~~~~~~~~~~~ rewrite ty ==> Reduction co xi where xi has no reducible type functions has no skolems that are mapped in the inert set has no filled-in metavariables co :: ty ~ xi (coercions in reductions are always left-to-right) Key invariants: (F0) co :: zonk(ty') ~ xi where zonk(ty') ~ zonk(ty) (F1) tcTypeKind(xi) succeeds and returns a fully zonked kind (F2) tcTypeKind(xi) `eqType` zonk(tcTypeKind(ty)) Note that it is rewrite's job to try to reduce *every type function it sees*. Rewriting also: * zonks, removing any metavariables, and * applies the substitution embodied in the inert set Because rewriting zonks and the returned coercion ("co" above) is also zonked, it's possible that (co :: ty ~ xi) isn't quite true. So, instead, we can rely on this fact: (F0) co :: zonk(ty') ~ xi, where zonk(ty') ~ zonk(ty) Note that the right-hand type of co is *always* precisely xi. The left-hand type may or may not be ty, however: if ty has unzonked filled-in metavariables, then the left-hand type of co will be the zonk-equal to ty. It is for this reason that we occasionally have to explicitly zonk, when (co :: ty ~ xi) is important even before we zonk the whole program. For example, see the RTRNotFollowed case in rewriteTyVar. Why have these invariants on rewriting? Because we sometimes use tcTypeKind during canonicalisation, and we want this kind to be zonked (e.g., see GHC.Tc.Solver.Canonical.canEqCanLHS). Rewriting is always homogeneous. That is, the kind of the result of rewriting is always the same as the kind of the input, modulo zonking. More formally: (F2) zonk(tcTypeKind(ty)) `eqType` tcTypeKind(xi) This invariant means that the kind of a rewritten type might not itself be rewritten. Note that we prefer to leave type synonyms unexpanded when possible, so when the rewriter encounters one, it first asks whether its transitive expansion contains any type function applications or is forgetful -- that is, omits one or more type variables in its RHS. If so, it expands the synonym and proceeds; if not, it simply returns the unexpanded synonym. See also Note [Rewriting synonyms]. Where do we actually perform rewriting within a type? See Note [Rewritable] in GHC.Tc.Solver.InertSet. Note [rewrite_args performance] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ In programs with lots of type-level evaluation, rewrite_args becomes part of a tight loop. For example, see test perf/compiler/T9872a, which calls rewrite_args a whopping 7,106,808 times. It is thus important that rewrite_args be efficient. Performance testing showed that the current implementation is indeed efficient. It's critically important that zipWithAndUnzipM be specialized to TcS, and it's also quite helpful to actually `inline` it. On test T9872a, here are the allocation stats (Dec 16, 2014): * Unspecialized, uninlined: 8,472,613,440 bytes allocated in the heap * Specialized, uninlined: 6,639,253,488 bytes allocated in the heap * Specialized, inlined: 6,281,539,792 bytes allocated in the heap To improve performance even further, rewrite_args_nom is split off from rewrite_args, as nominal equality is the common case. This would be natural to write using mapAndUnzipM, but even inlined, that function is not as performant as a hand-written loop. * mapAndUnzipM, inlined: 7,463,047,432 bytes allocated in the heap * hand-written recursion: 5,848,602,848 bytes allocated in the heap If you make any change here, pay close attention to the T9872{a,b,c} tests and T5321Fun. If we need to make this yet more performant, a possible way forward is to duplicate the rewriter code for the nominal case, and make that case faster. This doesn't seem quite worth it, yet. Note [rewrite_exact_fam_app performance] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Once we've got a rewritten rhs, we extend the famapp-cache to record the result. Doing so can save lots of work when the same redex shows up more than once. Note that we record the link from the redex all the way to its *final* value, not just the single step reduction. If we can reduce the family application right away (the first call to try_to_reduce), we do *not* add to the cache. There are two possibilities here: 1) we just read the result from the cache, or 2) we used one type family instance. In either case, recording the result in the cache doesn't save much effort the next time around. And adding to the cache here is actually disastrous: it more than doubles the allocations for T9872a. So we skip adding to the cache here. -} {-# INLINE rewrite_args_tc #-} rewrite_args_tc :: TyCon -- T -> Maybe [Role] -- Nothing: ambient role is Nominal; all args are Nominal -- Otherwise: no assumptions; use roles provided -> [Type] -> RewriteM ArgsReductions -- See the commentary on rewrite_args rewrite_args_tc tc = rewrite_args all_bndrs any_named_bndrs inner_ki emptyVarSet -- NB: TyCon kinds are always closed where -- There are many bang patterns in here. It's been observed that they -- greatly improve performance of an optimized build. -- The T9872 test cases are good witnesses of this fact. (bndrs, named) = ty_con_binders_ty_binders' (tyConBinders tc) -- it's possible that the result kind has arrows (for, e.g., a type family) -- so we must split it (inner_bndrs, inner_ki, inner_named) = split_pi_tys' (tyConResKind tc) !all_bndrs = bndrs `chkAppend` inner_bndrs !any_named_bndrs = named || inner_named -- NB: Those bangs there drop allocations in T9872{a,c,d} by 8%. {-# INLINE rewrite_args #-} rewrite_args :: [TyCoBinder] -> Bool -- Binders, and True iff any of them are -- named. -> Kind -> TcTyCoVarSet -- function kind; kind's free vars -> Maybe [Role] -> [Type] -- these are in 1-to-1 correspondence -- Nothing: use all Nominal -> RewriteM ArgsReductions -- This function returns ArgsReductions (Reductions cos xis) res_co -- coercions: co_i :: ty_i ~ xi_i, at roles given -- types: xi_i -- coercion: res_co :: tcTypeKind(fun tys) ~N tcTypeKind(fun xis) -- That is, the result coercion relates the kind of some function (whose kind is -- passed as the first parameter) instantiated at tys to the kind of that -- function instantiated at the xis. This is useful in keeping rewriting -- homogeneous. The list of roles must be at least as long as the list of -- types. rewrite_args orig_binders any_named_bndrs orig_inner_ki orig_fvs orig_m_roles orig_tys = case (orig_m_roles, any_named_bndrs) of (Nothing, False) -> rewrite_args_fast orig_tys _ -> rewrite_args_slow orig_binders orig_inner_ki orig_fvs orig_roles orig_tys where orig_roles = fromMaybe (repeat Nominal) orig_m_roles {-# INLINE rewrite_args_fast #-} -- | fast path rewrite_args, in which none of the binders are named and -- therefore we can avoid tracking a lifting context. rewrite_args_fast :: [Type] -> RewriteM ArgsReductions rewrite_args_fast orig_tys = fmap finish (iterate orig_tys) where iterate :: [Type] -> RewriteM Reductions iterate (ty : tys) = do Reduction co xi <- rewrite_one ty Reductions cos xis <- iterate tys pure $ Reductions (co : cos) (xi : xis) iterate [] = pure $ Reductions [] [] {-# INLINE finish #-} finish :: Reductions -> ArgsReductions finish redns = ArgsReductions redns MRefl {-# INLINE rewrite_args_slow #-} -- | Slow path, compared to rewrite_args_fast, because this one must track -- a lifting context. rewrite_args_slow :: [TyCoBinder] -> Kind -> TcTyCoVarSet -> [Role] -> [Type] -> RewriteM ArgsReductions rewrite_args_slow binders inner_ki fvs roles tys = do { rewritten_args <- zipWithM rw roles tys ; return (simplifyArgsWorker binders inner_ki fvs roles rewritten_args) } where {-# INLINE rw #-} rw :: Role -> Type -> RewriteM Reduction rw Nominal ty = setEqRel NomEq $ rewrite_one ty rw Representational ty = setEqRel ReprEq $ rewrite_one ty rw Phantom ty -- See Note [Phantoms in the rewriter] = do { ty <- liftTcS $ zonkTcType ty ; return $ mkReflRedn Phantom ty } ------------------ rewrite_one :: TcType -> RewriteM Reduction -- Rewrite a type to get rid of type function applications, returning -- the new type-function-free type, and a collection of new equality -- constraints. See Note [Rewriting] for more detail. -- -- Postcondition: -- the role on the result coercion matches the EqRel in the RewriteEnv rewrite_one ty | Just ty' <- rewriterView ty -- See Note [Rewriting synonyms] = rewrite_one ty' rewrite_one xi@(LitTy {}) = do { role <- getRole ; return $ mkReflRedn role xi } rewrite_one (TyVarTy tv) = rewriteTyVar tv rewrite_one (AppTy ty1 ty2) = rewrite_app_tys ty1 [ty2] rewrite_one (TyConApp tc tys) -- If it's a type family application, try to reduce it | isTypeFamilyTyCon tc = rewrite_fam_app tc tys -- For * a normal data type application -- * data family application -- we just recursively rewrite the arguments. | otherwise = rewrite_ty_con_app tc tys rewrite_one (FunTy { ft_af = vis, ft_mult = mult, ft_arg = ty1, ft_res = ty2 }) = do { arg_redn <- rewrite_one ty1 ; res_redn <- rewrite_one ty2 -- Important: look at the *reduced* type, so that any unzonked variables -- in kinds are gone and the getRuntimeRep succeeds. -- cf. Note [Decomposing FunTy] in GHC.Tc.Solver.Canonical. ; let arg_rep = getRuntimeRep (reductionReducedType arg_redn) res_rep = getRuntimeRep (reductionReducedType res_redn) ; (w_redn, arg_rep_redn, res_rep_redn) <- setEqRel NomEq $ liftA3 (,,) (rewrite_one mult) (rewrite_one arg_rep) (rewrite_one res_rep) ; role <- getRole ; let arg_rep_co = reductionCoercion arg_rep_redn -- :: arg_rep ~ arg_rep_xi arg_ki_co = mkTyConAppCo Nominal tYPETyCon [arg_rep_co] -- :: TYPE arg_rep ~ TYPE arg_rep_xi casted_arg_redn = mkCoherenceRightRedn role arg_redn arg_ki_co -- :: ty1 ~> arg_xi |> arg_ki_co res_rep_co = reductionCoercion res_rep_redn res_ki_co = mkTyConAppCo Nominal tYPETyCon [res_rep_co] casted_res_redn = mkCoherenceRightRedn role res_redn res_ki_co -- We must rewrite the representations, because that's what would -- be done if we used TyConApp instead of FunTy. These rewritten -- representations are seen only in casts of the arg and res, below. -- Forgetting this caused #19677. ; return $ mkFunRedn role vis w_redn casted_arg_redn casted_res_redn } rewrite_one ty@(ForAllTy {}) -- TODO (RAE): This is inadequate, as it doesn't rewrite the kind of -- the bound tyvar. Doing so will require carrying around a substitution -- and the usual substTyVarBndr-like silliness. Argh. -- We allow for-alls when, but only when, no type function -- applications inside the forall involve the bound type variables. = do { let (bndrs, rho) = tcSplitForAllTyVarBinders ty ; redn <- rewrite_one rho ; return $ mkHomoForAllRedn bndrs redn } rewrite_one (CastTy ty g) = do { redn <- rewrite_one ty ; g' <- rewrite_co g ; role <- getRole ; return $ mkCastRedn1 role ty g' redn } -- This calls castCoercionKind1. -- It makes a /big/ difference to call castCoercionKind1 not -- the more general castCoercionKind2. -- See Note [castCoercionKind1] in GHC.Core.Coercion rewrite_one (CoercionTy co) = do { co' <- rewrite_co co ; role <- getRole ; return $ mkReflCoRedn role co' } -- | "Rewrite" a coercion. Really, just zonk it so we can uphold -- (F1) of Note [Rewriting] rewrite_co :: Coercion -> RewriteM Coercion rewrite_co co = liftTcS $ zonkCo co -- | Rewrite a reduction, composing the resulting coercions. rewrite_reduction :: Reduction -> RewriteM Reduction rewrite_reduction (Reduction co xi) = do { redn <- bumpDepth $ rewrite_one xi ; return $ co `mkTransRedn` redn } -- rewrite (nested) AppTys rewrite_app_tys :: Type -> [Type] -> RewriteM Reduction -- commoning up nested applications allows us to look up the function's kind -- only once. Without commoning up like this, we would spend a quadratic amount -- of time looking up functions' types rewrite_app_tys (AppTy ty1 ty2) tys = rewrite_app_tys ty1 (ty2:tys) rewrite_app_tys fun_ty arg_tys = do { redn <- rewrite_one fun_ty ; rewrite_app_ty_args redn arg_tys } -- Given a rewritten function (with the coercion produced by rewriting) and -- a bunch of unrewritten arguments, rewrite the arguments and apply. -- The coercion argument's role matches the role stored in the RewriteM monad. -- -- The bang patterns used here were observed to improve performance. If you -- wish to remove them, be sure to check for regressions in allocations. rewrite_app_ty_args :: Reduction -> [Type] -> RewriteM Reduction rewrite_app_ty_args redn [] -- this will be a common case when called from rewrite_fam_app, so shortcut = return redn rewrite_app_ty_args fun_redn@(Reduction fun_co fun_xi) arg_tys = do { het_redn <- case tcSplitTyConApp_maybe fun_xi of Just (tc, xis) -> do { let tc_roles = tyConRolesRepresentational tc arg_roles = dropList xis tc_roles ; ArgsReductions (Reductions arg_cos arg_xis) kind_co <- rewrite_vector (tcTypeKind fun_xi) arg_roles arg_tys -- We start with a reduction of the form -- fun_co :: ty ~ T xi_1 ... xi_n -- and further arguments a_1, ..., a_m. -- We rewrite these arguments, and obtain coercions: -- arg_co_i :: a_i ~ zeta_i -- Now, we need to apply fun_co to the arg_cos. The problem is -- that using mkAppCo is wrong because that function expects -- its second coercion to be Nominal, and the arg_cos might -- not be. The solution is to use transitivity: -- fun_co ... ;; T .. arg_co_1 ... arg_co_m ; eq_rel <- getEqRel ; let app_xi = mkTyConApp tc (xis ++ arg_xis) app_co = case eq_rel of NomEq -> mkAppCos fun_co arg_cos ReprEq -> mkAppCos fun_co (map mkNomReflCo arg_tys) `mkTcTransCo` mkTcTyConAppCo Representational tc (zipWith mkReflCo tc_roles xis ++ arg_cos) ; return $ mkHetReduction (mkReduction app_co app_xi ) kind_co } Nothing -> do { ArgsReductions redns kind_co <- rewrite_vector (tcTypeKind fun_xi) (repeat Nominal) arg_tys ; return $ mkHetReduction (mkAppRedns fun_redn redns) kind_co } ; role <- getRole ; return (homogeniseHetRedn role het_redn) } rewrite_ty_con_app :: TyCon -> [TcType] -> RewriteM Reduction rewrite_ty_con_app tc tys = do { role <- getRole ; let m_roles | Nominal <- role = Nothing | otherwise = Just $ tyConRolesX role tc ; ArgsReductions redns kind_co <- rewrite_args_tc tc m_roles tys ; let tyconapp_redn = mkHetReduction (mkTyConAppRedn role tc redns) kind_co ; return $ homogeniseHetRedn role tyconapp_redn } -- Rewrite a vector (list of arguments). rewrite_vector :: Kind -- of the function being applied to these arguments -> [Role] -- If we're rewriting w.r.t. ReprEq, what roles do the -- args have? -> [Type] -- the args to rewrite -> RewriteM ArgsReductions rewrite_vector ki roles tys = do { eq_rel <- getEqRel ; let mb_roles = case eq_rel of { NomEq -> Nothing; ReprEq -> Just roles } ; rewrite_args bndrs any_named_bndrs inner_ki fvs mb_roles tys } where (bndrs, inner_ki, any_named_bndrs) = split_pi_tys' ki fvs = tyCoVarsOfType ki {-# INLINE rewrite_vector #-} {- Note [Rewriting synonyms] ~~~~~~~~~~~~~~~~~~~~~~~~~~ Not expanding synonyms aggressively improves error messages, and keeps types smaller. But we need to take care. Suppose type Syn a = Int type instance F Bool = Syn (F Bool) [G] F Bool ~ Syn (F Bool) If we don't expand the synonym, we'll get a spurious occurs-check failure. This is normally what occCheckExpand takes care of, but the LHS is a type family application, and occCheckExpand (already complex enough as it is) does not know how to expand to avoid a type family application. In addition, expanding the forgetful synonym like this will generally yield a *smaller* type. To wit, if we spot S ( ... F tys ... ), where S is forgetful, we don't want to bother doing hard work simplifying (F tys). We thus expand forgetful synonyms, but not others. isForgetfulSynTyCon returns True more often than it needs to, so we err on the side of more expansion. We also, of course, must expand type synonyms that mention type families, so those families can get reduced. ************************************************************************ * * Rewriting a type-family application * * ************************************************************************ Note [How to normalise a family application] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ Given an exactly saturated family application, how should we normalise it? This Note spells out the algorithm and its reasoning. First, we attempt to directly rewrite the type family application, without simplifying any of the arguments first, in an attempt to avoid doing unnecessary work. STEP 1a. Call the rewriting plugins. If any plugin rewrites the type family application, jump to FINISH. STEP 1b. Try the famapp-cache. If we get a cache hit, jump to FINISH. STEP 1c. Try top-level instances. Remember: we haven't simplified the arguments yet. Example: type instance F (Maybe a) = Int target: F (Maybe (G Bool)) Instead of first trying to simplify (G Bool), we use the instance first. This avoids the work of simplifying G Bool. If an instance is found, jump to FINISH. STEP 2: At this point we rewrite all arguments. This might expose more information, which might allow plugins to make progress, or allow us to pick up a top-level instance. STEP 3. Try the inerts. Note that we try the inerts *after* rewriting the arguments, because the inerts will have rewritten LHSs. If an inert is found, jump to FINISH. Next, we try STEP 1 again, as we might be able to make further progress after having rewritten the arguments: STEP 4a. Query the rewriting plugins again. If any plugin supplies a rewriting, jump to FINISH. STEP 4b. Try the famapp-cache again. If we get a cache hit, jump to FINISH. STEP 4c. Try top-level instances again. If an instance is found, jump to FINISH. STEP 5: GIVEUP. No progress to be made. Return what we have. (Do not FINISH.) FINISH 1. We've made a reduction, but the new type may still have more work to do. So rewrite the new type. FINISH 2. Add the result to the famapp-cache, connecting the type we started with to the one we ended with. Because STEP 1{a,b,c} and STEP 4{a,b,c} happen the same way, they are abstracted into try_to_reduce. FINISH is naturally implemented in `finish`. But, Note [rewrite_exact_fam_app performance] tells us that we should not add to the famapp-cache after STEP 1. So `finish` is inlined in that case, and only FINISH 1 is performed. -} rewrite_fam_app :: TyCon -> [TcType] -> RewriteM Reduction -- rewrite_fam_app can be over-saturated -- rewrite_exact_fam_app lifts out the application to top level -- Postcondition: Coercion :: Xi ~ F tys rewrite_fam_app tc tys -- Can be over-saturated = assertPpr (tys `lengthAtLeast` tyConArity tc) (ppr tc $$ ppr (tyConArity tc) $$ ppr tys) $ -- Type functions are saturated -- The type function might be *over* saturated -- in which case the remaining arguments should -- be dealt with by AppTys do { let (tys1, tys_rest) = splitAt (tyConArity tc) tys ; redn <- rewrite_exact_fam_app tc tys1 ; rewrite_app_ty_args redn tys_rest } -- the [TcType] exactly saturate the TyCon -- See Note [How to normalise a family application] rewrite_exact_fam_app :: TyCon -> [TcType] -> RewriteM Reduction rewrite_exact_fam_app tc tys = do { checkStackDepth (mkTyConApp tc tys) -- Query the typechecking plugins for all their rewriting functions -- which apply to a type family application headed by the TyCon 'tc'. ; tc_rewriters <- getTcPluginRewritersForTyCon tc -- STEP 1. Try to reduce without reducing arguments first. ; result1 <- try_to_reduce tc tys tc_rewriters ; case result1 of -- Don't use the cache; -- See Note [rewrite_exact_fam_app performance] { Just redn -> finish False redn ; Nothing -> -- That didn't work. So reduce the arguments, in STEP 2. do { eq_rel <- getEqRel -- checking eq_rel == NomEq saves ~0.5% in T9872a ; ArgsReductions (Reductions cos xis) kind_co <- if eq_rel == NomEq then rewrite_args_tc tc Nothing tys else setEqRel NomEq $ rewrite_args_tc tc Nothing tys -- If we manage to rewrite the type family application after -- rewriting the arguments, we will need to compose these -- reductions. -- -- We have: -- -- arg_co_i :: ty_i ~ xi_i -- fam_co :: F xi_1 ... xi_n ~ zeta -- -- The full reduction is obtained as a composite: -- -- full_co :: F ty_1 ... ty_n ~ zeta -- full_co = F co_1 ... co_n ;; fam_co ; let role = eqRelRole eq_rel args_co = mkTyConAppCo role tc cos ; let homogenise :: Reduction -> Reduction homogenise redn = homogeniseHetRedn role $ mkHetReduction (args_co `mkTransRedn` redn) kind_co give_up :: Reduction give_up = homogenise $ mkReflRedn role reduced where reduced = mkTyConApp tc xis -- STEP 3: try the inerts ; flavour <- getFlavour ; result2 <- liftTcS $ lookupFamAppInert (`eqCanRewriteFR` (flavour, eq_rel)) tc xis ; case result2 of { Just (redn, (inert_flavour, inert_eq_rel)) -> do { traceRewriteM "rewrite family application with inert" (ppr tc <+> ppr xis $$ ppr redn) ; finish (inert_flavour == Given) (homogenise downgraded_redn) } -- this will sometimes duplicate an inert in the cache, -- but avoiding doing so had no impact on performance, and -- it seems easier not to weed out that special case where inert_role = eqRelRole inert_eq_rel role = eqRelRole eq_rel downgraded_redn = downgradeRedn role inert_role redn ; _ -> -- inerts didn't work. Try to reduce again, in STEP 4. do { result3 <- try_to_reduce tc xis tc_rewriters ; case result3 of Just redn -> finish True (homogenise redn) -- we have made no progress at all: STEP 5 (GIVEUP). _ -> return give_up }}}}} where -- call this if the above attempts made progress. -- This recursively rewrites the result and then adds to the cache finish :: Bool -- add to the cache? -- Precondition: True ==> input coercion has -- no coercion holes -> Reduction -> RewriteM Reduction finish use_cache redn = do { -- rewrite the result: FINISH 1 final_redn <- rewrite_reduction redn ; eq_rel <- getEqRel -- extend the cache: FINISH 2 ; when (use_cache && eq_rel == NomEq) $ -- the cache only wants Nominal eqs liftTcS $ extendFamAppCache tc tys final_redn ; return final_redn } {-# INLINE finish #-} -- Returned coercion is input ~r output, where r is the role in the RewriteM monad -- See Note [How to normalise a family application] try_to_reduce :: TyCon -> [TcType] -> [TcPluginRewriter] -> RewriteM (Maybe Reduction) try_to_reduce tc tys tc_rewriters = do { rewrite_env <- getRewriteEnv ; result <- liftTcS $ firstJustsM [ runTcPluginRewriters rewrite_env tc_rewriters tys -- STEP 1a & STEP 4a , lookupFamAppCache tc tys -- STEP 1b & STEP 4b , matchFam tc tys ] -- STEP 1c & STEP 4c ; traverse downgrade result } where -- The result above is always Nominal. We might want a Representational -- coercion; this downgrades (and prints, out of convenience). downgrade :: Reduction -> RewriteM Reduction downgrade redn = do { traceRewriteM "Eager T.F. reduction success" $ vcat [ ppr tc , ppr tys , ppr redn ] ; eq_rel <- getEqRel -- manually doing it this way avoids allocation in the vastly -- common NomEq case ; case eq_rel of NomEq -> return redn ReprEq -> return $ mkSubRedn redn } -- Retrieve all type-checking plugins that can rewrite a (saturated) type-family application -- headed by the given 'TyCon`. getTcPluginRewritersForTyCon :: TyCon -> RewriteM [TcPluginRewriter] getTcPluginRewritersForTyCon tc = liftTcS $ do { rewriters <- tcg_tc_plugin_rewriters <$> getGblEnv ; return (lookupWithDefaultUFM rewriters [] tc) } -- Run a collection of rewriting functions obtained from type-checking plugins, -- querying in sequence if any plugin wants to rewrite the type family -- applied to the given arguments. -- -- Note that the 'TcPluginRewriter's provided all pertain to the same type family -- (the 'TyCon' of which has been obtained ahead of calling this function). runTcPluginRewriters :: RewriteEnv -> [TcPluginRewriter] -> [TcType] -> TcS (Maybe Reduction) runTcPluginRewriters rewriteEnv rewriterFunctions tys | null rewriterFunctions = return Nothing -- short-circuit for common case | otherwise = do { givens <- getInertGivens ; runRewriters givens rewriterFunctions } where runRewriters :: [Ct] -> [TcPluginRewriter] -> TcS (Maybe Reduction) runRewriters _ [] = return Nothing runRewriters givens (rewriter:rewriters) = do rewriteResult <- wrapTcS . runTcPluginM $ rewriter rewriteEnv givens tys case rewriteResult of TcPluginRewriteTo { tcPluginReduction = redn , tcRewriterNewWanteds = wanteds } -> do { emitWork wanteds; return $ Just redn } TcPluginNoRewrite {} -> runRewriters givens rewriters {- ************************************************************************ * * Rewriting a type variable * * ********************************************************************* -} -- | The result of rewriting a tyvar "one step". data RewriteTvResult = RTRNotFollowed -- ^ The inert set doesn't make the tyvar equal to anything else | RTRFollowed !Reduction -- ^ The tyvar rewrites to a not-necessarily rewritten other type. -- The role is determined by the RewriteEnv. -- -- With Quick Look, the returned TcType can be a polytype; -- that is, in the constraint solver, a unification variable -- can contain a polytype. See GHC.Tc.Gen.App -- Note [Instantiation variables are short lived] rewriteTyVar :: TyVar -> RewriteM Reduction rewriteTyVar tv = do { mb_yes <- rewrite_tyvar1 tv ; case mb_yes of RTRFollowed redn -> rewrite_reduction redn RTRNotFollowed -- Done, but make sure the kind is zonked -- Note [Rewriting] invariant (F0) and (F1) -> do { tv' <- liftTcS $ updateTyVarKindM zonkTcType tv ; role <- getRole ; let ty' = mkTyVarTy tv' ; return $ mkReflRedn role ty' } } rewrite_tyvar1 :: TcTyVar -> RewriteM RewriteTvResult -- "Rewriting" a type variable means to apply the substitution to it -- Specifically, look up the tyvar in -- * the internal MetaTyVar box -- * the inerts -- See also the documentation for RewriteTvResult rewrite_tyvar1 tv = do { mb_ty <- liftTcS $ isFilledMetaTyVar_maybe tv ; case mb_ty of Just ty -> do { traceRewriteM "Following filled tyvar" (ppr tv <+> equals <+> ppr ty) ; role <- getRole ; return $ RTRFollowed $ mkReflRedn role ty } Nothing -> do { traceRewriteM "Unfilled tyvar" (pprTyVar tv) ; fr <- getFlavourRole ; rewrite_tyvar2 tv fr } } rewrite_tyvar2 :: TcTyVar -> CtFlavourRole -> RewriteM RewriteTvResult -- The tyvar is not a filled-in meta-tyvar -- Try in the inert equalities -- See Definition [Applying a generalised substitution] in GHC.Tc.Solver.Monad -- See Note [Stability of rewriting] in GHC.Tc.Solver.Monad rewrite_tyvar2 tv fr@(_, eq_rel) = do { ieqs <- liftTcS $ getInertEqs ; case lookupDVarEnv ieqs tv of Just equal_ct_list | Just ct <- find can_rewrite equal_ct_list , CEqCan { cc_ev = ctev, cc_lhs = TyVarLHS tv , cc_rhs = rhs_ty, cc_eq_rel = ct_eq_rel } <- ct -> do { let wrw = isWantedCt ct ; traceRewriteM "Following inert tyvar" $ vcat [ ppr tv <+> equals <+> ppr rhs_ty , ppr ctev , text "wanted_rewrite_wanted:" <+> ppr wrw ] ; when wrw $ recordRewriter ctev ; let rewriting_co1 = ctEvCoercion ctev rewriting_co = case (ct_eq_rel, eq_rel) of (ReprEq, _rel) -> assert (_rel == ReprEq) -- if this assert fails, then -- eqCanRewriteFR answered incorrectly rewriting_co1 (NomEq, NomEq) -> rewriting_co1 (NomEq, ReprEq) -> mkSubCo rewriting_co1 ; return $ RTRFollowed $ mkReduction rewriting_co rhs_ty } _other -> return RTRNotFollowed } where can_rewrite :: Ct -> Bool can_rewrite ct = ctFlavourRole ct `eqCanRewriteFR` fr -- This is THE key call of eqCanRewriteFR {- Note [An alternative story for the inert substitution] ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ (This entire note is just background, left here in case we ever want to return the previous state of affairs) We used (GHC 7.8) to have this story for the inert substitution inert_eqs * 'a' is not in fvs(ty) * They are *inert* in the weaker sense that there is no infinite chain of (i1 `eqCanRewrite` i2), (i2 `eqCanRewrite` i3), etc This means that rewriting must be recursive, but it does allow [G] a ~ [b] [G] b ~ Maybe c This avoids "saturating" the Givens, which can save a modest amount of work. It is easy to implement, in GHC.Tc.Solver.Interact.kick_out, by only kicking out an inert only if (a) the work item can rewrite the inert AND (b) the inert cannot rewrite the work item This is significantly harder to think about. It can save a LOT of work in occurs-check cases, but we don't care about them much. #5837 is an example, but it causes trouble only with the old (pre-Fall 2020) rewriting story. It is unclear if there is any gain w.r.t. to the new story. -} -------------------------------------- -- Utilities -- | Like 'splitPiTys'' but comes with a 'Bool' which is 'True' iff there is at -- least one named binder. split_pi_tys' :: Type -> ([TyCoBinder], Type, Bool) split_pi_tys' ty = split ty ty where -- put common cases first split _ (ForAllTy b res) = let -- This bang is necessary lest we see rather -- terrible reboxing, as noted in #19102. !(bs, ty, _) = split res res in (Named b : bs, ty, True) split _ (FunTy { ft_af = af, ft_mult = w, ft_arg = arg, ft_res = res }) = let -- See #19102 !(bs, ty, named) = split res res in (Anon af (mkScaled w arg) : bs, ty, named) split orig_ty ty | Just ty' <- coreView ty = split orig_ty ty' split orig_ty _ = ([], orig_ty, False) {-# INLINE split_pi_tys' #-} -- | Like 'tyConBindersTyCoBinders' but you also get a 'Bool' which is true iff -- there is at least one named binder. ty_con_binders_ty_binders' :: [TyConBinder] -> ([TyCoBinder], Bool) ty_con_binders_ty_binders' = foldr go ([], False) where go (Bndr tv (NamedTCB vis)) (bndrs, _) = (Named (Bndr tv vis) : bndrs, True) go (Bndr tv (AnonTCB af)) (bndrs, n) = (Anon af (tymult (tyVarKind tv)) : bndrs, n) {-# INLINE go #-} {-# INLINE ty_con_binders_ty_binders' #-}