mirror of
https://github.com/urbit/shrub.git
synced 2024-12-30 07:35:19 +03:00
369 lines
9.6 KiB
Haskell
369 lines
9.6 KiB
Haskell
{-# OPTIONS_GHC -O2 #-}
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{-|
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Fast implementation of Jam (Noun → Atom).
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This is based on the implementation of `flat`.
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-}
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module Urbit.Noun.Jam (jam, jamBS) where
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import ClassyPrelude hiding (hash)
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import Urbit.Atom
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import Urbit.Noun.Core
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import Data.Bits (clearBit, setBit, shiftL, shiftR, (.|.))
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import Data.Vector.Primitive ((!))
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import Foreign.Marshal.Alloc (callocBytes, free)
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import Foreign.Ptr (Ptr, castPtr, plusPtr)
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import Foreign.Storable (poke)
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import GHC.Int (Int(I#))
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import GHC.Integer.GMP.Internals (BigNat)
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import GHC.Natural (Natural(NatJ#, NatS#))
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import GHC.Prim (Word#, plusWord#, word2Int#)
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import GHC.Word (Word(W#))
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import System.IO.Unsafe (unsafePerformIO)
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import qualified Urbit.Atom.Fast as Atom
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import qualified Data.ByteString.Unsafe as BS
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import qualified Data.HashTable.IO as H
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import qualified Data.Vector.Primitive as VP
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-- Exports ---------------------------------------------------------------------
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jamBS :: Noun -> ByteString
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jamBS n = doPut bt sz (writeNoun n)
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where
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(sz, bt) = unsafePerformIO (compress n)
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jam :: Noun -> Atom
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jam = bytesAtom . jamBS
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-- Types -----------------------------------------------------------------------
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{-|
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The encoder state.
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- ptr: Pointer into the output buffer.
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- reg: Next 64 bits of output, partially written.
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- off: Number of bits already written into `reg`
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- pos: Total number of bits written.
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-}
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data S = S
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{ ptr :: {-# UNPACK #-} !(Ptr Word)
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, reg :: {-# UNPACK #-} !Word
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, off :: {-# UNPACK #-} !Int
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, pos :: {-# UNPACK #-} !Word
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} deriving (Show,Eq,Ord)
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data PutResult a = PutResult {-# UNPACK #-} !S !a
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deriving Functor
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newtype Put a = Put
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{ runPut :: H.CuckooHashTable Word Word
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-> S
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-> IO (PutResult a)
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}
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--------------------------------------------------------------------------------
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{-# INLINE getRef #-}
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getRef :: Put (Maybe Word)
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getRef = Put $ \tbl s -> PutResult s <$> H.lookup tbl (pos s)
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{-|
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1. Write the register to the output, and increment the output pointer.
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-}
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{-# INLINE flush #-}
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flush :: Put ()
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flush = Put $ \tbl s@S{..} -> do
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poke ptr reg
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pure $ PutResult (s { ptr = ptr `plusPtr` 8 }) ()
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{-# INLINE update #-}
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update :: (S -> S) -> Put ()
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update f = Put $ \tbl s@S{..} -> pure (PutResult (f s) ())
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{-# INLINE setRegOff #-}
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setRegOff :: Word -> Int -> Put ()
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setRegOff r o = update $ \s@S{..} -> (s {reg=r, off=o})
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{-# INLINE setReg #-}
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setReg :: Word -> Put ()
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setReg r = update $ \s@S{..} -> (s { reg=r })
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{-# INLINE getS #-}
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getS :: Put S
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getS = Put $ \tbl s -> pure (PutResult s s)
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{-# INLINE putS #-}
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putS :: S -> Put ()
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putS s = Put $ \tbl _ -> pure (PutResult s ())
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{-|
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To write a bit:
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| reg |= 1 << off
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| off <- (off + 1) % 64
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| if (!off):
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| buf[w++] <- reg
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| reg <- 0
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-}
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{-# INLINE writeBit #-}
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writeBit :: Bool -> Put ()
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writeBit b = Put $ \tbl s@S{..} -> do
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let s' = s { reg = (if b then setBit else clearBit) reg off
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, off = (off + 1) `mod` 64
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, pos = pos + 1
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}
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if off == 63
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then runPut (flush >> setRegOff 0 0) tbl s'
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else pure $ PutResult s' ()
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{-|
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To write a 64bit word:
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| reg |= w << off
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| buf[bufI++] = reg
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| reg = w >> (64 - off)
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-}
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{-# INLINE writeWord #-}
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writeWord :: Word -> Put ()
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writeWord wor = do
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S{..} <- getS
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setReg (reg .|. shiftL wor off)
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flush
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update $ \s -> s { pos = 64 + pos
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, reg = shiftR wor (64 - off)
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}
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{-|
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To write some bits (< 64) from a word:
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| wor = takeBits(wid, wor)
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| reg = reg .|. (wor << off)
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| off = (off + wid) % 64
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| if (off + wid >= 64)
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| buf[w] = x
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| reg = wor >> (wid - off)
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-}
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{-# INLINE writeBitsFromWord #-}
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writeBitsFromWord :: Int -> Word -> Put ()
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writeBitsFromWord wid wor = do
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wor <- pure (Atom.takeBitsWord wid wor)
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oldSt <- getS
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let newSt = oldSt { reg = reg oldSt .|. shiftL wor (off oldSt)
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, off = (off oldSt + wid) `mod` 64
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, pos = fromIntegral wid + pos oldSt
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}
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putS newSt
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when (wid + off oldSt >= 64) $ do
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flush
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setReg (shiftR wor (wid - off newSt))
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{-|
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Write all of the the signficant bits of a direct atom.
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-}
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{-# INLINE writeAtomWord# #-}
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writeAtomWord# :: Word# -> Put ()
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writeAtomWord# w = do
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writeBitsFromWord (I# (word2Int# (Atom.wordBitWidth# w))) (W# w)
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{-# INLINE writeAtomWord #-}
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writeAtomWord :: Word -> Put ()
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writeAtomWord (W# w) = writeAtomWord# w
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{-|
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Write all of the the signficant bits of an indirect atom.
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TODO Use memcpy when the bit-offset of the output is divisible by 8.
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-}
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{-# INLINE writeAtomBigNat #-}
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writeAtomBigNat :: BigNat -> Put ()
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writeAtomBigNat !(Atom.bigNatWords -> words) = do
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let lastIdx = VP.length words - 1
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for_ [0..(lastIdx-1)] $ \i ->
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writeWord (words ! i)
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writeAtomWord (words ! lastIdx)
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{-# INLINE writeAtomBits #-}
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writeAtomBits :: Atom -> Put ()
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writeAtomBits = \case NatS# wd -> writeAtomWord# wd
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NatJ# bn -> writeAtomBigNat bn
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-- Put Instances ---------------------------------------------------------------
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instance Functor Put where
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fmap f g = Put $ \tbl s -> do
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PutResult s' a <- runPut g tbl s
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pure $ PutResult s' (f a)
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{-# INLINE fmap #-}
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instance Applicative Put where
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pure x = Put (\_ s -> return $ PutResult s x)
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{-# INLINE pure #-}
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Put f <*> Put g = Put $ \tbl s1 -> do
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PutResult s2 f' <- f tbl s1
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PutResult s3 g' <- g tbl s2
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return $ PutResult s3 (f' g')
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{-# INLINE (<*>) #-}
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Put f *> Put g = Put $ \tbl s1 -> do
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PutResult s2 _ <- f tbl s1
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g tbl s2
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{-# INLINE (*>) #-}
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instance Monad Put where
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return = pure
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{-# INLINE return #-}
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(>>) = (*>)
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{-# INLINE (>>) #-}
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Put x >>= f = Put $ \tbl s -> do
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PutResult s' x' <- x tbl s
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runPut (f x') tbl s'
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{-# INLINE (>>=) #-}
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--------------------------------------------------------------------------------
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doPut :: H.CuckooHashTable Word Word -> Word -> Put () -> ByteString
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doPut !tbl !sz m =
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unsafePerformIO $ do
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-- traceM "doPut"
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buf <- callocBytes (fromIntegral (wordSz*8))
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_ <- runPut (m >> mbFlush) tbl (S buf 0 0 0)
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BS.unsafePackCStringFinalizer (castPtr buf) byteSz (free buf)
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where
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!wordSz = fromIntegral (sz `divUp` 64)
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!byteSz = fromIntegral (sz `divUp` 8)
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!divUp = \x y -> (x `div` y) + (if x `mod` y == 0 then 0 else 1)
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mbFlush :: Put ()
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mbFlush = do
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shouldFlush <- (/= 0) . off <$> getS
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when shouldFlush flush
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--------------------------------------------------------------------------------
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{-|
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TODO Handle back references
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-}
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writeNoun :: Noun -> Put ()
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writeNoun !n =
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getRef >>= \case
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Just bk -> writeBackRef bk
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Nothing -> case n of Atom a -> writeAtom a
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Cell h t -> writeCell h t
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{-# INLINE writeMat #-}
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writeMat :: Atom -> Put ()
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writeMat 0 = writeBit True
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writeMat atm = do
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writeBitsFromWord (preWid+1) (shiftL 1 preWid)
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writeBitsFromWord (preWid-1) atmWid
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writeAtomBits atm
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where
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atmWid = Atom.atomBitWidth atm
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preWid = fromIntegral (Atom.wordBitWidth atmWid)
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{-# INLINE writeCell #-}
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writeCell :: Noun -> Noun -> Put ()
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writeCell !h !t = do
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writeBit True
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writeBit False
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writeNoun h
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writeNoun t
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{-# INLINE writeAtom #-}
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writeAtom :: Atom -> Put ()
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writeAtom !a = do
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writeBit False
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writeMat a
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{-# INLINE writeBackRef #-}
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writeBackRef :: Word -> Put ()
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writeBackRef !a = do
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p <- pos <$> getS
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writeBit True
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writeBit True
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writeMat (fromIntegral a)
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-- Calculate Jam Size and Backrefs ---------------------------------------------
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{-# INLINE matSz #-}
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matSz :: Atom -> Word
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matSz !a = W# (matSz# a)
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{-# INLINE matSz# #-}
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matSz# :: Atom -> Word#
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matSz# 0 = 1##
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matSz# a = preW `plusWord#` preW `plusWord#` atmW
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where
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atmW = Atom.atomBitWidth# a
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preW = Atom.wordBitWidth# atmW
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{-# INLINE atomSz #-}
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atomSz :: Atom -> Word
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atomSz !w = 1 + matSz w
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{-# INLINE refSz #-}
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refSz :: Word -> Word
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refSz !w = 1 + jamWordSz w
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{-# INLINE jamWordSz #-}
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jamWordSz :: Word -> Word
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jamWordSz 0 = 2
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jamWordSz (W# w) = 1 + 2*(W# preW) + (W# atmW)
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where
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atmW = Atom.wordBitWidth# w
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preW = Atom.wordBitWidth# atmW
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compress :: Noun -> IO (Word, H.CuckooHashTable Word Word)
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compress !top = do
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let sz = max 50
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$ min 10_000_000
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$ (2*) $ (10^) $ floor $ logBase 600 $ fromIntegral $ nounSize top
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nodes :: H.BasicHashTable Noun Word <- H.newSized sz
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backs :: H.CuckooHashTable Word Word <- H.newSized sz
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let proc :: Word -> Noun -> IO Word
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proc !pos = \case
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Atom a -> pure (atomSz a)
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Cell h t -> do !hSz <- go (pos+2) h
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!tSz <- go (pos+2+hSz) t
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pure (2+hSz+tSz)
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go :: Word -> Noun -> IO Word
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go !p !inp = do
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H.lookup nodes inp >>= \case
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Nothing -> do
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H.insert nodes inp p
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proc p inp
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Just bak -> do
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let rs = refSz bak
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doRef = H.insert backs p bak $> rs
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noRef = proc p inp
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case inp of
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Cell _ _ -> doRef
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Atom a | rs < atomSz (fromIntegral a) -> doRef
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_ -> noRef
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res <- go 0 top
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pure (res, backs)
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