{-# LANGUAGE GeneralizedNewtypeDeriving #-} {-# LANGUAGE ViewPatterns #-} ------------------------------------------------------------------------------ -- The MIT License (MIT) -- -- Copyright (c) 2017 Luka Horvat -- -- Permission is hereby granted, free of charge, to any person obtaining a copy -- of this software and associated documentation files (the "Software"), to -- deal in the Software without restriction, including without limitation the -- rights to use, copy, modify, merge, publish, distribute, sublicense, and/or -- sell copies of the Software, and to permit persons to whom the Software is -- furnished to do so, subject to the following conditions: -- -- The above copyright notice and this permission notice shall be included in -- all copies or substantial portions of the Software. -- -- THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR -- IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, -- FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE -- AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER -- LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING -- FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS -- IN THE SOFTWARE. -- ------------------------------------------------------------------------------ -- -- This module is heavily based on 'Control.Effects.Plugin' from the -- 'simple-effects' package, originally by Luka Horvat. -- -- https://gitlab.com/LukaHorvat/simple-effects/commit/966ce80b8b5777a4bd8f87ffd443f5fa80cc8845#f51c1641c95dfaa4827f641013f8017e8cd02aab module Polysemy.Plugin.Fundep (fundepPlugin) where import Class import CoAxiom import Control.Applicative import Control.Monad import Data.Bifunctor import Data.Bool import Data.Coerce import Data.Function (on) import Data.IORef import qualified Data.Kind as K import Data.List import Data.Maybe import qualified Data.Set as S import FastString (fsLit) import GHC (TyCon, Name) import GHC.TcPluginM.Extra (lookupModule, lookupName) import Module (mkModuleName) import OccName (mkTcOcc) import TcEvidence import TcPluginM (TcPluginM, tcLookupClass, tcLookupTyCon, tcPluginIO) import TcRnTypes import TcSMonad hiding (tcLookupClass) import TyCoRep (Type (..)) import Type data LookupState = Locations | Things type family ThingOf (l :: LookupState) (a :: K.Type) :: K.Type where ThingOf 'Locations _ = (String, String) ThingOf 'Things a = a data PolysemyStuff (l :: LookupState) = PolysemyStuff { findClass :: ThingOf l Class , semTyCon :: ThingOf l TyCon , ifStuckTyCon :: ThingOf l TyCon , indexOfTyCon :: ThingOf l TyCon } class CanLookup a where lookupStrategy :: Name -> TcPluginM a instance CanLookup Class where lookupStrategy = tcLookupClass instance CanLookup TyCon where lookupStrategy = tcLookupTyCon doLookup :: CanLookup a => ThingOf 'Locations a -> TcPluginM (ThingOf 'Things a) doLookup (mdname, name) = do md <- lookupModule (mkModuleName mdname) $ fsLit "polysemy" nm <- lookupName md $ mkTcOcc name lookupStrategy nm lookupEverything :: PolysemyStuff 'Locations -> TcPluginM (PolysemyStuff 'Things) lookupEverything (PolysemyStuff a b c d) = PolysemyStuff <$> doLookup a <*> doLookup b <*> doLookup c <*> doLookup d polysemyStuffLocations :: PolysemyStuff 'Locations polysemyStuffLocations = PolysemyStuff { findClass = ("Polysemy.Internal.Union", "Find") , semTyCon = ("Polysemy.Internal", "Sem") , ifStuckTyCon = ("Polysemy.Internal.CustomErrors.Redefined", "IfStuck") , indexOfTyCon = ("Polysemy.Internal.Union", "IndexOf") } fundepPlugin :: TcPlugin fundepPlugin = TcPlugin { tcPluginInit = (,) <$> tcPluginIO (newIORef S.empty) <*> lookupEverything polysemyStuffLocations , tcPluginSolve = solveFundep , tcPluginStop = const (return ()) } allMonadEffectConstraints :: PolysemyStuff 'Things -> [Ct] -> [(CtLoc, (Type, Type, Type))] allMonadEffectConstraints (findClass -> cls) cts = [ (ctLoc cd, (effName, eff, r)) | cd@CDictCan{cc_class = cls', cc_tyargs = [_, r, eff]} <- cts , cls == cls' , let effName = getEffName eff ] singleListToJust :: [a] -> Maybe a singleListToJust [a] = Just a singleListToJust _ = Nothing findMatchingEffectIfSingular :: (Type, Type, Type) -> [(Type, Type, Type)] -> Maybe Type findMatchingEffectIfSingular (effName, _, mon) ts = singleListToJust [ eff' | (effName', eff', mon') <- ts , eqType effName effName' , eqType mon mon' ] getEffName :: Type -> Type getEffName t = fst $ splitAppTys t canUnifyRecursive :: SolveContext -> Type -> Type -> Bool canUnifyRecursive solve_ctx = go True where -- It's only OK to solve a polymorphic "given" if we're in the context of -- an interpreter, because it's not really a given! poly_given_ok :: Bool poly_given_ok = case solve_ctx of InterpreterUse _ -> True FunctionDef -> False -- On the first go around, we don't want to unify effects with tyvars, but -- we _do_ want to unify their arguments, thus 'is_first'. go :: Bool -> Type -> Type -> Bool go is_first wanted given = let (w, ws) = splitAppTys wanted (g, gs) = splitAppTys given in (&& bool (canUnify poly_given_ok) eqType is_first w g) . flip all (zip ws gs) $ \(wt, gt) -> canUnify poly_given_ok wt gt || go False wt gt canUnify :: Bool -> Type -> Type -> Bool canUnify poly_given_ok wt gt = or [ isTyVarTy wt , isTyVarTy gt && poly_given_ok , eqType wt gt ] ------------------------------------------------------------------------------ -- | Like 'Control.Monad.when', but in the context of an 'Alternative'. whenA :: (Monad m, Alternative z) => Bool -> m a -> m (z a) whenA False _ = pure empty whenA True ma = fmap pure ma mkWanted :: SolveContext -> CtLoc -> Type -> Type -> TcPluginM (Maybe ( (OrdType, OrdType) -- the types we want to unify , Ct -- the constraint )) mkWanted solve_ctx loc wanted given = whenA (not (mustUnify solve_ctx) || canUnifyRecursive solve_ctx wanted given) $ do (ev, _) <- unsafeTcPluginTcM . runTcSDeriveds $ newWantedEq loc Nominal wanted given pure ( (OrdType wanted, OrdType given) , CNonCanonical ev ) thd :: (a, b, c) -> c thd (_, _, c) = c countLength :: (a -> a -> Bool) -> [a] -> [(a, Int)] countLength eq as = let grouped = groupBy eq as in zipWith (curry $ bimap head length) grouped grouped ------------------------------------------------------------------------------ -- | 'Type's don't have 'Eq' or 'Ord' instances by default, even though there -- are functions in GHC that implement these operations. This newtype gives us -- those instances. newtype OrdType = OrdType { getOrdType :: Type } instance Eq OrdType where (==) = eqType `on` getOrdType instance Ord OrdType where compare = nonDetCmpType `on` getOrdType ------------------------------------------------------------------------------ -- | The context in which we're attempting to solve a constraint. data SolveContext = -- | In the context of a function definition. FunctionDef -- | In the context of running an interpreter. The 'Bool' corresponds to -- whether we are only trying to solve a single 'Member' constraint right -- now. If so, we *must* produce a unification wanted. | InterpreterUse Bool deriving (Eq, Ord, Show) mustUnify :: SolveContext -> Bool mustUnify FunctionDef = True mustUnify (InterpreterUse b) = b ------------------------------------------------------------------------------ -- | Given a list of 'Ct's, find any that are of the form -- @[Irred] Sem r a ~ Something@, and return their @r@s. getBogusRs :: PolysemyStuff 'Things -> [Ct] -> [Type] getBogusRs stuff wanteds = do CIrredCan ct _ <- wanteds case splitAppTys $ ctev_pred ct of (_, [_, _, a, b]) -> maybeToList (getRIfSem stuff a) ++ maybeToList (getRIfSem stuff b) (_, _) -> [] ------------------------------------------------------------------------------ -- | Take the @r@ out of @Sem r a@. getRIfSem :: PolysemyStuff 'Things -> Type -> Maybe Type getRIfSem (semTyCon -> sem) ty = case splitTyConApp_maybe ty of Just (tycon, [r, _]) | tycon == sem -> pure r _ -> Nothing ------------------------------------------------------------------------------ -- | Given a list of bogus @r@s, and the wanted constraints, produce bogus -- evidence terms that will prevent @IfStuck (IndexOf r _) _ _@ error messsages. solveBogusError :: PolysemyStuff 'Things -> [Type] -> [Ct] -> [(EvTerm, Ct)] solveBogusError stuff bogus wanteds = do ct@(CIrredCan ce _) <- wanteds case splitTyConApp_maybe $ ctev_pred ce of Just (stuck, [_, _, expr, _, _]) | stuck == ifStuckTyCon stuff -> do case splitTyConApp_maybe expr of Just (idx, [_, r, _]) | idx == indexOfTyCon stuff -> do case elem @[] (OrdType r) $ coerce bogus of True -> pure (error "bogus proof for stuck type family", ct) False -> [] _ -> [] _ -> [] solveFundep :: (IORef (S.Set (OrdType, OrdType)), PolysemyStuff 'Things) -> [Ct] -> [Ct] -> [Ct] -> TcPluginM TcPluginResult solveFundep _ _ _ [] = pure $ TcPluginOk [] [] solveFundep (ref, stuff) giv _ want = do let bogus = getBogusRs stuff want solved_bogus = solveBogusError stuff bogus want let wantedEffs = allMonadEffectConstraints stuff want givenEffs = snd <$> allMonadEffectConstraints stuff giv num_wanteds_by_r = countLength eqType $ fmap (thd . snd) wantedEffs must_unify r = let Just num_wanted = find (eqType r . fst) num_wanteds_by_r in snd num_wanted /= 1 eqs <- forM wantedEffs $ \(loc, e@(_, eff, r)) -> do case findMatchingEffectIfSingular e givenEffs of Nothing -> do case splitAppTys r of (_, [_, eff', _]) -> mkWanted (InterpreterUse $ must_unify r) loc eff eff' _ -> pure Nothing Just eff' -> mkWanted FunctionDef loc eff eff' already_emitted <- tcPluginIO $ readIORef ref let new_wanteds = filter (not . flip S.member already_emitted . fst) $ catMaybes eqs tcPluginIO $ modifyIORef ref $ S.union $ S.fromList $ fmap fst new_wanteds pure . TcPluginOk solved_bogus $ fmap snd new_wanteds