-- |
-- Module: GHC.Integer.Logarithms.Compat
-- Copyright: (c) 2011 Daniel Fischer
-- Licence: MIT
-- Maintainer: Daniel Fischer <daniel.is.fischer@googlemail.com>
-- Stability: Provisional
-- Portability: Non-portable (GHC extensions)
--
-- Low level stuff for integer logarithms.
{-# LANGUAGE CPP, MagicHash, UnboxedTuples #-}
module GHC.Integer.Logarithms.Compat
( -- * Functions
integerLogBase#
, integerLog2#
, wordLog2#
) where
#if __GLASGOW_HASKELL__ >= 702
-- Stuff is already there
import GHC.Integer.Logarithms
#else
-- We have to define it here
#include "MachDeps.h"
import GHC.Base
import GHC.Integer.GMP.Internals
#if (WORD_SIZE_IN_BITS != 32) && (WORD_SIZE_IN_BITS != 64)
#error Only word sizes 32 and 64 are supported.
#endif
#if WORD_SIZE_IN_BITS == 32
#define WSHIFT 5
#define MMASK 31
#else
#define WSHIFT 6
#define MMASK 63
#endif
-- Reference implementation only, the algorithm in M.NT.Logarithms is better.
-- | Calculate the integer logarithm for an arbitrary base.
-- The base must be greater than 1, the second argument, the number
-- whose logarithm is sought; should be positive, otherwise the
-- result is meaningless.
--
-- > base ^ integerLogBase# base m <= m < base ^ (integerLogBase# base m + 1)
--
-- for @base > 1@ and @m > 0@.
integerLogBase# :: Integer -> Integer -> Int#
integerLogBase# b m = case step b of
(# _, e #) -> e
where
step pw =
if m < pw
then (# m, 0# #)
else case step (pw * pw) of
(# q, e #) ->
if q < pw
then (# q, 2# *# e #)
else (# q `quot` pw, 2# *# e +# 1# #)
-- | Calculate the integer base 2 logarithm of an 'Integer'.
-- The calculation is much more efficient than for the general case.
--
-- The argument must be strictly positive, that condition is /not/ checked.
integerLog2# :: Integer -> Int#
integerLog2# (S# i) = wordLog2# (int2Word# i)
integerLog2# (J# s ba) = check (s -# 1#)
where
check i = case indexWordArray# ba i of
0## -> check (i -# 1#)
w -> wordLog2# w +# (uncheckedIShiftL# i WSHIFT#)
-- | This function calculates the integer base 2 logarithm of a 'Word#'.
-- @'wordLog2#' 0## = -1#@.
{-# INLINE wordLog2# #-}
wordLog2# :: Word# -> Int#
wordLog2# w =
case leadingZeros of
BA lz ->
let zeros u = indexInt8Array# lz (word2Int# u) in
#if WORD_SIZE_IN_BITS == 64
case uncheckedShiftRL# w 56# of
a ->
if a `neWord#` 0##
then 64# -# zeros a
else
case uncheckedShiftRL# w 48# of
b ->
if b `neWord#` 0##
then 56# -# zeros b
else
case uncheckedShiftRL# w 40# of
c ->
if c `neWord#` 0##
then 48# -# zeros c
else
case uncheckedShiftRL# w 32# of
d ->
if d `neWord#` 0##
then 40# -# zeros d
else
#endif
case uncheckedShiftRL# w 24# of
e ->
if e `neWord#` 0##
then 32# -# zeros e
else
case uncheckedShiftRL# w 16# of
f ->
if f `neWord#` 0##
then 24# -# zeros f
else
case uncheckedShiftRL# w 8# of
g ->
if g `neWord#` 0##
then 16# -# zeros g
else 8# -# zeros w
-- Lookup table
data BA = BA ByteArray#
leadingZeros :: BA
leadingZeros =
let mkArr s =
case newByteArray# 256# s of
(# s1, mba #) ->
case writeInt8Array# mba 0# 9# s1 of
s2 ->
let fillA lim val idx st =
if idx ==# 256#
then st
else if idx <# lim
then case writeInt8Array# mba idx val st of
nx -> fillA lim val (idx +# 1#) nx
else fillA (2# *# lim) (val -# 1#) idx st
in case fillA 2# 8# 1# s2 of
s3 -> case unsafeFreezeByteArray# mba s3 of
(# _, ba #) -> ba
in case mkArr realWorld# of
b -> BA b
#endif