{-# LANGUAGE CPP, MagicHash #-} -- | Integer logarithm, copied from @arithmoi@ module Math.NumberTheory.Logarithms ( integerLog10' ) where import GHC.Base #if __GLASGOW_HASKELL__ < 705 import GHC.Word #endif import GHC.Integer.Logarithms -- | Only defined for positive inputs! integerLog10' :: Integer -> Int integerLog10' n | n < 10 = 0 | n < 100 = 1 | otherwise = ex + integerLog10' (n `quot` integerPower 10 ex) where ln = I# (integerLog2# n) -- u/v is a good approximation of log 2/log 10 u = 1936274 v = 6432163 -- so ex is a good approximation to integerLogBase 10 n ex = fromInteger ((u * fromIntegral ln) `quot` v) -- | Power of an 'Integer' by the left-to-right repeated squaring algorithm. -- This needs two multiplications in each step while the right-to-left -- algorithm needs only one multiplication for 0-bits, but here the -- two factors always have approximately the same size, which on average -- gains a bit when the result is large. -- -- For small results, it is unlikely to be any faster than '(^)', quite -- possibly slower (though the difference shouldn't be large), and for -- exponents with few bits set, the same holds. But for exponents with -- many bits set, the speedup can be significant. -- -- /Warning:/ No check for the negativity of the exponent is performed, -- a negative exponent is interpreted as a large positive exponent. integerPower :: Integer -> Int -> Integer integerPower b (I# e#) = power b (int2Word# e#) power :: Integer -> Word# -> Integer power b w# | isTrue# (w# `eqWord#` 0##) = 1 | isTrue# (w# `eqWord#` 1##) = b | otherwise = go (wordLog2# w# -# 1#) b (b*b) where go 0# l h = if isTrue# ((w# `and#` 1##) `eqWord#` 0##) then l*l else (l*h) go i# l h | w# `hasBit#` i# = go (i# -# 1#) (l*h) (h*h) | otherwise = go (i# -# 1#) (l*l) (l*h) -- | A raw version of testBit for 'Word#'. hasBit# :: Word# -> Int# -> Bool hasBit# w# i# = isTrue# (((w# `uncheckedShiftRL#` i#) `and#` 1##) `neWord#` 0##) #if __GLASGOW_HASKELL__ < 707 isTrue# :: Bool -> Bool isTrue# = id #endif