Adhering to the declarative style is way too painful, especially when we are porting...

[wavpack.git] / Codec / Audio / WavPack / Words.hs

diff --git a/Codec/Audio/WavPack/Words.hs b/Codec/Audio/WavPack/Words.hs
index 1321c0725808b340aea6e490ebd1817c627cc021..6406d3e91f40b85ef29c7443c31a8d482cd64d89 100644 (file)
--- a/Codec/Audio/WavPack/Words.hs
+++ b/Codec/Audio/WavPack/Words.hs
@@ -23,15 +23,17 @@ efficient with this data and results in about 1.22 bits per sample. -}
 module Codec.Audio.WavPack.Words
     ( WordsData(..)
 
-    , getWordsLossless
+--    , getWordsLossless
     )
     where
 import Codec.Audio.WavPack.Entropy
 import Codec.Audio.WavPack.Internal
+import Control.Monad.ST
 import Data.Bits
 import Data.Bitstream.Generic (Bitstream)
 import qualified Data.Bitstream.Generic as B
 import Data.Int
+import Data.STRef
 import qualified Data.Vector.Generic as GV
 import qualified Data.Vector.Generic.Mutable as MV
 import Data.Vector.Generic.New (New)
@@ -57,6 +59,7 @@ data WordsData
 -- lossless only ('edErrorLimit' ≡ 0). Also, rather than obtaining a
 -- single sample, it can be used to obtain an entire buffer of either
 -- mono or stereo samples.
+{-
 getWordsLossless ∷ ∀bs v. (Bitstream bs, GV.Vector v Int32)
                  ⇒ Bool -- ^ Is the stream monaural?
                  → WordsData
@@ -232,28 +235,37 @@ getWordsLossless isMono w0 bs0 nSamples0
           | isMono        = w { wdEntropyData = (e, snd $ wdEntropyData w) }
           | n `testBit` 0 = w { wdEntropyData = (e, snd $ wdEntropyData w) }
           | otherwise     = w { wdEntropyData = (fst $ wdEntropyData w, e) }
+-}
 
 -- | Read a single unsigned value from the specified bitstream with a
 -- value from 0 to maxCode. If there are exactly a power of two number
 -- of possible codes then this will read a fixed number of bits;
 -- otherwise it reads the minimum number of bits and then determines
 -- whether another bit is needed to define the code.
-readCode ∷ Bitstream bs ⇒ bs → Word32 → (# Word32, bs #)
+readCode ∷ Bitstream bs ⇒ STRef s bs → Word32 → ST s Word32
 {-# INLINEABLE readCode #-}
-readCode bs 0       = (# 0, bs #)
-readCode bs 1       = (# b2n (B.head bs), B.tail bs #)
+readCode bs 0       = return 0
+readCode bs 1       = fmap b2n $ takeHead bs
 readCode bs maxCode
-    = let !bitCount = countBits maxCode
-          !extras   = bit bitCount - maxCode - 1
-          !code     = B.toBits (B.take (bitCount - 1) bs)
-          (# code', bitCount' #)
-                    = if code ≥ extras then
-                          (# (code `shiftL` 1)
-                             - extras
-                             + b2n (bs B.!! bitCount)
-                           , bitCount #)
-                      else
-                          (# code, bitCount - 1 #)
-          !bs'      = B.drop bitCount' bs
-      in
-        (# code', bs' #)
+    = do let bitCount = countBits maxCode
+             extras   = bit bitCount - maxCode - 1
+         code ← takeBits bs (bitCount - 1)
+         if code ≥ extras then
+             do nextBit ← takeHead bs
+                return $ (code `shiftL` 1) - extras + b2n nextBit
+           else
+             return code
+
+takeHead ∷ Bitstream bs ⇒ STRef s bs → ST s Bool
+{-# INLINEABLE takeHead #-}
+takeHead bsr
+    = do bs ← readSTRef bsr
+         writeSTRef bsr (B.tail bs)
+         return (B.head bs)
+
+takeBits ∷ (Integral n, Bitstream bs, Bits a) ⇒ STRef s bs → n → ST s a
+{-# INLINEABLE takeBits #-}
+takeBits bsr n
+    = do bs ← readSTRef bsr
+         writeSTRef bsr (B.drop n bs)
+         return (B.toBits (B.take n bs))