X-Git-Url: http://git.megacz.com/?a=blobdiff_plain;f=ghc%2Fcompiler%2FbasicTypes%2FUniqSupply.lhs;h=699275196abfd16971182aaf26998601c2675ab0;hb=1f5e55804b97d2b9a77207d568d602ba88d8855d;hp=7c155f326cc4a41ac5d54457707eaefc5c435e44;hpb=f01a8e8c9c53bfb5ab3393ed3457ebf25390efa1;p=ghc-hetmet.git diff --git a/ghc/compiler/basicTypes/UniqSupply.lhs b/ghc/compiler/basicTypes/UniqSupply.lhs index 7c155f3..6992751 100644 --- a/ghc/compiler/basicTypes/UniqSupply.lhs +++ b/ghc/compiler/basicTypes/UniqSupply.lhs @@ -1,32 +1,32 @@ % -% (c) The GRASP/AQUA Project, Glasgow University, 1992-1996 +% (c) The GRASP/AQUA Project, Glasgow University, 1992-1998 % \section[UniqSupply]{The @UniqueSupply@ data type and a (monadic) supply thereof} \begin{code} -#include "HsVersions.h" - module UniqSupply ( UniqSupply, -- Abstractly - getUnique, getUniques, -- basic ops + uniqFromSupply, uniqsFromSupply, -- basic ops - UniqSM(..), -- type: unique supply monad - initUs, thenUs, returnUs, + UniqSM, -- type: unique supply monad + initUs, initUs_, thenUs, thenUs_, returnUs, fixUs, getUs, withUs, + getUniqueUs, getUniquesUs, mapUs, mapAndUnzipUs, mapAndUnzip3Us, thenMaybeUs, mapAccumLUs, + lazyThenUs, lazyMapUs, mkSplitUniqSupply, splitUniqSupply ) where -import Ubiq{-uitous-} +#include "HsVersions.h" import Unique -import Util -import PreludeGlaST +import GLAEXTS +import UNSAFE_IO ( unsafeInterleaveIO ) w2i x = word2Int# x i2w x = int2Word# x @@ -40,12 +40,6 @@ i2w_s x = (x :: Int#) %* * %************************************************************************ -%************************************************************************ -%* * -\subsubsection[UniqSupply-type]{@UniqSupply@ type and operations} -%* * -%************************************************************************ - A value of type @UniqSupply@ is unique, and it can supply {\em one} distinct @Unique@. Also, from the supply, one can also manufacture an arbitrary number of further @UniqueSupplies@, @@ -62,51 +56,42 @@ data UniqSupply mkSplitUniqSupply :: Char -> IO UniqSupply splitUniqSupply :: UniqSupply -> (UniqSupply, UniqSupply) -getUnique :: UniqSupply -> Unique -getUniques :: Int -> UniqSupply -> [Unique] +uniqFromSupply :: UniqSupply -> Unique +uniqsFromSupply :: UniqSupply -> [Unique] -- Infinite \end{code} \begin{code} -mkSplitUniqSupply (MkChar c#) +mkSplitUniqSupply (C# c#) = let +#if __GLASGOW_HASKELL__ >= 503 + mask# = (i2w (ord# c#)) `uncheckedShiftL#` (i2w_s 24#) +#else mask# = (i2w (ord# c#)) `shiftL#` (i2w_s 24#) - +#endif -- here comes THE MAGIC: + -- This is one of the most hammered bits in the whole compiler mk_supply# - = unsafe_interleave ( - mk_unique `thenPrimIO` \ uniq -> - mk_supply# `thenPrimIO` \ s1 -> - mk_supply# `thenPrimIO` \ s2 -> - returnPrimIO (MkSplitUniqSupply uniq s1 s2) + = unsafeInterleaveIO ( + mk_unique >>= \ uniq -> + mk_supply# >>= \ s1 -> + mk_supply# >>= \ s2 -> + return (MkSplitUniqSupply uniq s1 s2) ) - where - -- inlined copy of unsafeInterleavePrimIO; - -- this is the single-most-hammered bit of code - -- in the compiler.... - unsafe_interleave m s - = let - (r, new_s) = m s - in - (r, s) - - mk_unique = _ccall_ genSymZh `thenPrimIO` \ (W# u#) -> - returnPrimIO (MkInt (w2i (mask# `or#` u#))) + + mk_unique = genSymZh >>= \ (W# u#) -> + return (I# (w2i (mask# `or#` u#))) in - mk_supply# `thenPrimIO` \ s -> - return s + mk_supply# + +foreign import ccall "genSymZh" unsafe genSymZh :: IO Word splitUniqSupply (MkSplitUniqSupply _ s1 s2) = (s1, s2) \end{code} \begin{code} -getUnique (MkSplitUniqSupply (MkInt n) _ _) = mkUniqueGrimily n - -getUniques i@(MkInt i#) supply = i# `get_from` supply - where - get_from 0# _ = [] - get_from n# (MkSplitUniqSupply (MkInt u#) _ s2) - = mkUniqueGrimily u# : get_from (n# `minusInt#` 1#) s2 +uniqFromSupply (MkSplitUniqSupply n _ _) = mkUniqueGrimily n +uniqsFromSupply (MkSplitUniqSupply n _ s2) = mkUniqueGrimily n : uniqsFromSupply s2 \end{code} %************************************************************************ @@ -116,43 +101,73 @@ getUniques i@(MkInt i#) supply = i# `get_from` supply %************************************************************************ \begin{code} -type UniqSM result = UniqSupply -> result - --- the initUs function also returns the final UniqSupply +type UniqSM result = UniqSupply -> (result, UniqSupply) -initUs :: UniqSupply -> UniqSM a -> (UniqSupply, a) +-- the initUs function also returns the final UniqSupply; initUs_ drops it +initUs :: UniqSupply -> UniqSM a -> (a,UniqSupply) +initUs init_us m = case m init_us of { (r,us) -> (r,us) } -initUs init_us m - = case (splitUniqSupply init_us) of { (s1, s2) -> - (s2, m s1) } +initUs_ :: UniqSupply -> UniqSM a -> a +initUs_ init_us m = case m init_us of { (r,us) -> r } {-# INLINE thenUs #-} +{-# INLINE lazyThenUs #-} {-# INLINE returnUs #-} {-# INLINE splitUniqSupply #-} \end{code} @thenUs@ is where we split the @UniqSupply@. \begin{code} -thenUs :: UniqSM a -> (a -> UniqSM b) -> UniqSM b +fixUs :: (a -> UniqSM a) -> UniqSM a +fixUs m us + = (r,us') where (r,us') = m r us +thenUs :: UniqSM a -> (a -> UniqSM b) -> UniqSM b thenUs expr cont us - = case (splitUniqSupply us) of { (s1, s2) -> - case (expr s1) of { result -> - cont result s2 }} -\end{code} + = case (expr us) of { (result, us') -> cont result us' } + +lazyThenUs :: UniqSM a -> (a -> UniqSM b) -> UniqSM b +lazyThenUs expr cont us + = let (result, us') = expr us in cont result us' + +thenUs_ :: UniqSM a -> UniqSM b -> UniqSM b +thenUs_ expr cont us + = case (expr us) of { (_, us') -> cont us' } + -\begin{code} returnUs :: a -> UniqSM a -returnUs result us = result +returnUs result us = (result, us) -mapUs :: (a -> UniqSM b) -> [a] -> UniqSM [b] +withUs :: (UniqSupply -> (a, UniqSupply)) -> UniqSM a +withUs f us = f us -- Ha ha! + +getUs :: UniqSM UniqSupply +getUs us = splitUniqSupply us +getUniqueUs :: UniqSM Unique +getUniqueUs us = case splitUniqSupply us of + (us1,us2) -> (uniqFromSupply us1, us2) + +getUniquesUs :: UniqSM [Unique] +getUniquesUs us = case splitUniqSupply us of + (us1,us2) -> (uniqsFromSupply us1, us2) +\end{code} + +\begin{code} +mapUs :: (a -> UniqSM b) -> [a] -> UniqSM [b] mapUs f [] = returnUs [] mapUs f (x:xs) = f x `thenUs` \ r -> mapUs f xs `thenUs` \ rs -> returnUs (r:rs) +lazyMapUs :: (a -> UniqSM b) -> [a] -> UniqSM [b] +lazyMapUs f [] = returnUs [] +lazyMapUs f (x:xs) + = f x `lazyThenUs` \ r -> + lazyMapUs f xs `lazyThenUs` \ rs -> + returnUs (r:rs) + mapAndUnzipUs :: (a -> UniqSM (b,c)) -> [a] -> UniqSM ([b],[c]) mapAndUnzip3Us :: (a -> UniqSM (b,c,d)) -> [a] -> UniqSM ([b],[c],[d])