Difference between revisions of "99 questions/Solutions/31"

Latest revision as of 07:06, 11 May 2016

(**) Determine whether a given integer number is prime.

Well, a natural number k is a prime number if it is larger than 1 and no natural number n >= 2 with n^2 <= k is a divisor of k. However, we don't actually need to check all natural numbers n <= sqrt k. We need only check the primes p <= sqrt k:

isPrime :: Integral a => a -> Bool
isPrime k = k > 1 &&
   foldr (\p r -> p*p > k || k `rem` p /= 0 && r)
      True primesTME

This uses

{-# OPTIONS_GHC -O2 -fno-cse #-}
-- tree-merging Eratosthenes sieve
--  producing infinite list of all prime numbers
primesTME = 2 : gaps 3 (join [[p*p,p*p+2*p..] | p <- primes'])
  where
    primes' = 3 : gaps 5 (join [[p*p,p*p+2*p..] | p <- primes'])
    join  ((x:xs):t)        = x : union xs (join (pairs t))
    pairs ((x:xs):ys:t)     = (x : union xs ys) : pairs t
    gaps k xs@(x:t) | k==x  = gaps (k+2) t 
                    | True  = k : gaps (k+2) xs

The tree-merging Eratosthenes sieve here seems to strike a good balance between efficiency and brevity. More at Prime numbers haskellwiki page. The semi-standard union function is readily available from Data.List.Ordered package, put here just for reference:

-- duplicates-removing union of two ordered increasing lists
union (x:xs) (y:ys) = case (compare x y) of 
           LT -> x : union  xs  (y:ys)
           EQ -> x : union  xs     ys 
           GT -> y : union (x:xs)  ys

Here is another solution, intended to be extremely short while still being reasonably fast.

isPrime :: (Integral a) => a -> Bool
isPrime n | n < 4 = n > 1
isPrime n = all ((/=0).mod n) $ 2:3:[x + i | x <- [6,12..s], i <- [-1,1]]
            where s = floor $ sqrt $ fromIntegral n

This one does not go as far as the previous, but it does observe the fact that you only need to check numbers of the form 6k +/- 1 up to the square root. And according to some quick tests (nothing extensive) this version can run a bit faster in some cases, but slower in others; depending on optimization settings and the size of the input.

There is a subtle bug in the version above. The above version will fail on 25, because the bound of s is incorrect. It is x+i that is bounded by the sqrt of the argument, not x. This version will work correctly:

isPrime n | n < 4 = n /= 1 
isPrime n = all ((/=0) . mod n) $ takeWhile (<= m) candidates 
        where candidates = (2:3:[x + i | x <- [6,12..], i <- [-1,1]])
              m = floor . sqrt $ fromIntegral n

Difference between revisions of "99 questions/Solutions/31"

Latest revision as of 07:06, 11 May 2016

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@@ Line 41: / Line 41: @@
 <haskell>
 isPrime :: (Integral a) => a -> Bool
-isPrime n | (n < 4) = if (n > 1) then True else False
+isPrime n | n < 4 = n > 1
-isPrime n = all ((/=0).mod n)$2:3:[x+i|x<-[6,12..floor$sqrt$fromIntegral n],i<-[-1,1]]
+isPrime n = all ((/=0).mod n) $ 2:3:[x + i | x <- [6,12..s], i <- [-1,1]]
+            where s = floor $ sqrt $ fromIntegral n
 </haskell>
 This one does not go as far as the previous, but it does observe the fact that you only need to check numbers of the form 6k +/- 1 up to the square root. And according to some quick tests (nothing extensive) this version can run a bit faster in some cases, but slower in others; depending on optimization settings and the size of the input.
+There is a subtle bug in the version above. The above version will fail on 25, because the bound of s is incorrect.  It is x+i that is bounded by the sqrt of the argument, not x.  This version will work correctly:
+<haskell>
+isPrime n | n < 4 = n /= 1
+isPrime n = all ((/=0) . mod n) $ takeWhile (<= m) candidates
+        where candidates = (2:3:[x + i | x <- [6,12..], i <- [-1,1]])
+              m = floor . sqrt $ fromIntegral n
+</haskell>
+[[Category:Programming exercise spoilers]]