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crypton-1.0.2: Crypto/Number/Basic.hs

{-# LANGUAGE BangPatterns #-}

-- |
-- Module      : Crypto.Number.Basic
-- License     : BSD-style
-- Maintainer  : Vincent Hanquez <vincent@snarc.org>
-- Stability   : experimental
-- Portability : Good
module Crypto.Number.Basic (
    sqrti,
    gcde,
    areEven,
    log2,
    numBits,
    numBytes,
    asPowerOf2AndOdd,
) where

import Data.Bits

import Crypto.Number.Compat

-- | @sqrti@ returns two integers @(l,b)@ so that @l <= sqrt i <= b@.
-- The implementation is quite naive, use an approximation for the first number
-- and use a dichotomy algorithm to compute the bound relatively efficiently.
sqrti :: Integer -> (Integer, Integer)
sqrti i
    | i < 0 = error "cannot compute negative square root"
    | i == 0 = (0, 0)
    | i == 1 = (1, 1)
    | i == 2 = (1, 2)
    | otherwise = loop x0
  where
    nbdigits = length $ show i
    x0n = (if even nbdigits then nbdigits - 2 else nbdigits - 1) `div` 2
    x0 = if even nbdigits then 2 * 10 ^ x0n else 6 * 10 ^ x0n
    loop x = case compare (sq x) i of
        LT -> iterUp x
        EQ -> (x, x)
        GT -> iterDown x
    iterUp lb = if sq ub >= i then iter lb ub else iterUp ub
      where
        ub = lb * 2
    iterDown ub = if sq lb >= i then iterDown lb else iter lb ub
      where
        lb = ub `div` 2
    iter lb ub
        | lb == ub = (lb, ub)
        | lb + 1 == ub = (lb, ub)
        | otherwise =
            let d = (ub - lb) `div` 2
             in if sq (lb + d) >= i
                    then iter lb (ub - d)
                    else iter (lb + d) ub
    sq a = a * a

-- | Get the extended GCD of two integer using integer divMod
--
-- gcde 'a' 'b' find (x,y,gcd(a,b)) where ax + by = d
gcde :: Integer -> Integer -> (Integer, Integer, Integer)
gcde a b =
    onGmpUnsupported (gmpGcde a b) $
        if d < 0 then (-x, -y, -d) else (x, y, d)
  where
    (d, x, y) = f (a, 1, 0) (b, 0, 1)
    f t (0, _, _) = t
    f (a', sa, ta) t@(b', sb, tb) =
        let (q, r) = a' `divMod` b'
         in f t (r, sa - (q * sb), ta - (q * tb))

-- | Check if a list of integer are all even
areEven :: [Integer] -> Bool
areEven = and . map even

-- | Compute the binary logarithm of a integer
log2 :: Integer -> Int
log2 n = onGmpUnsupported (gmpLog2 n) $ imLog 2 n
  where
    -- http://www.haskell.org/pipermail/haskell-cafe/2008-February/039465.html
    imLog b x = if x < b then 0 else (x `div` b ^ l) `doDiv` l
      where
        l = 2 * imLog (b * b) x
        doDiv x' l' = if x' < b then l' else (x' `div` b) `doDiv` (l' + 1)
{-# INLINE log2 #-}

-- | Compute the number of bits for an integer
numBits :: Integer -> Int
numBits n = gmpSizeInBits n `onGmpUnsupported` (if n == 0 then 1 else computeBits 0 n)
  where
    computeBits !acc i
        | q == 0 =
            if r >= 0x80
                then acc + 8
                else
                    if r >= 0x40
                        then acc + 7
                        else
                            if r >= 0x20
                                then acc + 6
                                else
                                    if r >= 0x10
                                        then acc + 5
                                        else
                                            if r >= 0x08
                                                then acc + 4
                                                else
                                                    if r >= 0x04
                                                        then acc + 3
                                                        else
                                                            if r >= 0x02
                                                                then acc + 2
                                                                else
                                                                    if r >= 0x01
                                                                        then acc + 1
                                                                        else acc -- should be catch by previous loop
        | otherwise = computeBits (acc + 8) q
      where
        (q, r) = i `divMod` 256

-- | Compute the number of bytes for an integer
numBytes :: Integer -> Int
numBytes n = gmpSizeInBytes n `onGmpUnsupported` ((numBits n + 7) `div` 8)

-- | Express an integer as an odd number and a power of 2
asPowerOf2AndOdd :: Integer -> (Int, Integer)
asPowerOf2AndOdd a
    | a == 0 = (0, 0)
    | odd a = (0, a)
    | a < 0 = let (e, a1) = asPowerOf2AndOdd $ abs a in (e, -a1)
    | isPowerOf2 a = (log2 a, 1)
    | otherwise = loop a 0
  where
    isPowerOf2 n = (n /= 0) && ((n .&. (n - 1)) == 0)
    loop n pw =
        if n `mod` 2 == 0
            then loop (n `div` 2) (pw + 1)
            else (pw, n)