]> Git — Sourcephile - haskell/symantic-parser.git/blob - src/Symantic/Univariant/Letable.hs
Fix DumpInstr
[haskell/symantic-parser.git] / src / Symantic / Univariant / Letable.hs
1 {-# LANGUAGE DefaultSignatures #-}
2 {-# LANGUAGE ExistentialQuantification #-} -- For SharingName
3 -- {-# LANGUAGE MagicHash #-} -- For unsafeCoerce#
4 module Symantic.Univariant.Letable where
5
6 import Control.Applicative (Applicative(..))
7 import Control.Monad (Monad(..))
8 import Data.Bool (Bool(..))
9 import Data.Eq (Eq(..))
10 import Data.Foldable (foldMap)
11 import Data.Function (($), (.))
12 import Data.Functor ((<$>))
13 import Data.Functor.Compose (Compose(..))
14 import Data.HashMap.Strict (HashMap)
15 import Data.HashSet (HashSet)
16 import Data.Hashable (Hashable, hashWithSalt, hash)
17 import Data.Int (Int)
18 import Data.Maybe (Maybe(..), isNothing)
19 import Data.Monoid (Monoid(..))
20 import Data.Ord (Ord(..))
21 -- import GHC.Exts (Int(..))
22 -- import GHC.Prim (unsafeCoerce#)
23 import GHC.StableName (StableName(..), makeStableName, hashStableName, eqStableName)
24 -- import Numeric (showHex)
25 import Prelude ((+))
26 import System.IO (IO)
27 import System.IO.Unsafe (unsafePerformIO)
28 -- import Text.Show (Show(..))
29 import qualified Control.Monad.Trans.Class as MT
30 import qualified Control.Monad.Trans.Reader as MT
31 import qualified Control.Monad.Trans.State as MT
32 import qualified Data.HashMap.Strict as HM
33 import qualified Data.HashSet as HS
34
35 import Symantic.Univariant.Trans
36
37 -- import Debug.Trace (trace)
38
39 -- * Class 'Letable'
40 -- | This class is not for manual usage like usual symantic operators,
41 -- here 'def' and 'ref' are introduced by 'observeSharing'.
42 class Letable letName repr where
43 -- | @('def' letName x)@ let-binds @(letName)@ to be equal to @(x)@.
44 def :: letName -> repr a -> repr a
45 -- | @('ref' isRec letName)@ is a reference to @(letName)@.
46 -- @(isRec)@ is 'True' iif. this 'ref'erence is recursive,
47 -- ie. is reachable within its 'def'inition.
48 ref :: Bool -> letName -> repr a
49 default def ::
50 Liftable1 repr => Letable letName (Output repr) =>
51 letName -> repr a -> repr a
52 default ref ::
53 Liftable repr => Letable letName (Output repr) =>
54 Bool -> letName -> repr a
55 def n = lift1 (def n)
56 ref r n = lift (ref r n)
57
58 -- * Class 'MakeLetName'
59 class MakeLetName letName where
60 makeLetName :: SharingName -> IO letName
61
62 -- * Type 'SharingName'
63 -- | Note that the observable sharing enabled by 'StableName'
64 -- is not perfect as it will not observe all the sharing explicitely done.
65 --
66 -- Note also that the observed sharing could be different between ghc and ghci.
67 data SharingName = forall a. SharingName (StableName a)
68 -- | @('makeSharingName' x)@ is like @('makeStableName' x)@ but it also forces
69 -- evaluation of @(x)@ to ensure that the 'StableName' is correct first time,
70 -- which avoids to produce a tree bigger than needed.
71 --
72 -- Note that this function uses 'unsafePerformIO' instead of returning in 'IO',
73 -- this is apparently required to avoid infinite loops due to unstable 'StableName'
74 -- in compiled code, and sometimes also in ghci.
75 --
76 -- Note that maybe [pseq should be used here](https://gitlab.haskell.org/ghc/ghc/-/issues/2916).
77 makeSharingName :: a -> SharingName
78 makeSharingName !x = SharingName $ unsafePerformIO $ makeStableName x
79
80 instance Eq SharingName where
81 SharingName x == SharingName y = eqStableName x y
82 instance Hashable SharingName where
83 hash (SharingName n) = hashStableName n
84 hashWithSalt salt (SharingName n) = hashWithSalt salt n
85 {-
86 instance Show SharingName where
87 showsPrec _ (SharingName n) = showHex (I# (unsafeCoerce# n))
88 -}
89
90 -- * Type 'ObserveSharing'
91 -- | Interpreter detecting some (Haskell embedded) @let@ definitions used at
92 -- least once and/or recursively, in order to replace them
93 -- with the 'def' and 'ref' combinators.
94 -- See [Type-safe observable sharing in Haskell](https://doi.org/10.1145/1596638.1596653)
95 newtype ObserveSharing letName repr a = ObserveSharing { unObserveSharing ::
96 MT.ReaderT (HashSet SharingName)
97 (MT.State (ObserveSharingState letName))
98 (CleanDefs letName repr a) }
99
100 observeSharing ::
101 Eq letName =>
102 Hashable letName =>
103 ObserveSharing letName repr a -> repr a
104 observeSharing (ObserveSharing m) = do
105 let (a, st) = MT.runReaderT m mempty `MT.runState`
106 ObserveSharingState
107 { oss_refs = HM.empty
108 , oss_recs = HS.empty
109 }
110 let refs = HS.fromList $
111 foldMap (\(letName, refCount) -> if refCount > 0 then [letName] else []) $
112 HM.elems $ oss_refs st
113 -- trace (show refs) $
114 unCleanDefs a refs
115
116 -- ** Type 'ObserveSharingState'
117 data ObserveSharingState letName = ObserveSharingState
118 { oss_refs :: HashMap SharingName (letName, Int)
119 , oss_recs :: HashSet SharingName
120 -- ^ TODO: unused so far, will it be useful somewhere at a later stage?
121 }
122
123 observeSharingNode ::
124 Eq letName =>
125 Hashable letName =>
126 Letable letName repr =>
127 MakeLetName letName =>
128 ObserveSharing letName repr a -> ObserveSharing letName repr a
129 observeSharingNode (ObserveSharing m) = ObserveSharing $ do
130 let nodeName = makeSharingName m
131 st <- MT.lift MT.get
132 ((letName, before), preds) <- getCompose $ HM.alterF (\before ->
133 Compose $ case before of
134 Nothing -> do
135 let letName = unsafePerformIO $ makeLetName nodeName
136 return ((letName, before), Just (letName, 0))
137 Just (letName, refCount) -> do
138 return ((letName, before), Just (letName, refCount + 1))
139 ) nodeName (oss_refs st)
140 parentNames <- MT.ask
141 if nodeName `HS.member` parentNames
142 then do
143 MT.lift $ MT.put st
144 { oss_refs = preds
145 , oss_recs = HS.insert nodeName (oss_recs st)
146 }
147 return $ ref True letName
148 else do
149 MT.lift $ MT.put st{ oss_refs = preds }
150 if isNothing before
151 then MT.local (HS.insert nodeName) (def letName <$> m)
152 else return $ ref False letName
153
154 type instance Output (ObserveSharing letName repr) = CleanDefs letName repr
155 instance
156 ( Letable letName repr
157 , MakeLetName letName
158 , Eq letName
159 , Hashable letName
160 ) => Trans (CleanDefs letName repr) (ObserveSharing letName repr) where
161 trans = observeSharingNode . ObserveSharing . return
162 instance
163 ( Letable letName repr
164 , MakeLetName letName
165 , Eq letName
166 , Hashable letName
167 ) => Trans1 (CleanDefs letName repr) (ObserveSharing letName repr) where
168 trans1 f x = observeSharingNode $ ObserveSharing $
169 f <$> unObserveSharing x
170 instance
171 ( Letable letName repr
172 , MakeLetName letName
173 , Eq letName
174 , Hashable letName
175 ) => Trans2 (CleanDefs letName repr) (ObserveSharing letName repr) where
176 trans2 f x y = observeSharingNode $ ObserveSharing $
177 f <$> unObserveSharing x
178 <*> unObserveSharing y
179 instance
180 ( Letable letName repr
181 , MakeLetName letName
182 , Eq letName
183 , Hashable letName
184 ) => Trans3 (CleanDefs letName repr) (ObserveSharing letName repr) where
185 trans3 f x y z = observeSharingNode $ ObserveSharing $
186 f <$> unObserveSharing x
187 <*> unObserveSharing y
188 <*> unObserveSharing z
189 instance
190 ( Letable letName repr
191 , MakeLetName letName
192 , Eq letName
193 , Hashable letName
194 ) => Letable letName (ObserveSharing letName repr)
195
196 -- * Type 'CleanDefs'
197 -- | Remove 'def' when non-recursive or unused.
198 newtype CleanDefs letName repr a = CleanDefs { unCleanDefs ::
199 HS.HashSet letName -> repr a }
200
201 type instance Output (CleanDefs _letName repr) = repr
202 instance Trans repr (CleanDefs letName repr) where
203 trans = CleanDefs . pure
204 instance Trans1 repr (CleanDefs letName repr) where
205 trans1 f x = CleanDefs $ f <$> unCleanDefs x
206 instance Trans2 repr (CleanDefs letName repr) where
207 trans2 f x y = CleanDefs $
208 f <$> unCleanDefs x
209 <*> unCleanDefs y
210 instance Trans3 repr (CleanDefs letName repr) where
211 trans3 f x y z = CleanDefs $
212 f <$> unCleanDefs x
213 <*> unCleanDefs y
214 <*> unCleanDefs z
215 instance
216 ( Letable letName repr
217 , Eq letName
218 , Hashable letName
219 ) => Letable letName (CleanDefs letName repr) where
220 def name x = CleanDefs $ \refs ->
221 if name `HS.member` refs
222 then -- Perserve 'def'
223 def name $ unCleanDefs x refs
224 else -- Remove 'def'
225 unCleanDefs x refs