After submitting my solution to Project Euler's problem 50 earlier today, I was scrolling through the problem's forums, taking a look at other folks' solutions/execution times.
After a while, I started to feel quite proud of my code which solved it in ~3 seconds (my code used the Primes
library and was compiled with O2
)...
...and then I came across the code below which solved it in ~0.05 seconds...in interpreted mode (i.e., ghci
).
Can someone explain how/why the code below solves this particular problem?
The mind-twisting part is the application of the tails
function to the infinite list of primes (primes
) within a list comprehension. I'm having a hard time understanding how we guarantee that we look at all possible sublists of consecutive primes and not just those generated by tails
.
(My usual strategy of trying bits and pieces of code in ghci
doesn't work in this situation because primes
is infinite...)
The problem: We're asked to find the largest prime number below 1,000,000 which is the result of summing consecutive prime numbers. For example, the largest prime number below 100 which is the sum of consecutive primes is 41 (2 + 3 + 5 + 7 + 11 + 13).
import Data.List (tails)
import Data.Numbers.Primes
under n xs = takeWhile (< n) xs
takeUntil p xs = foldr (\x r-> if p x then [x] else x:r) [] xs
res :: [((Int, Int), (Int, Int))]
-- ((top_length, sums_to), (total_length, starting_prime))
res = [(r,(length s,x)) | (x:xs) <- tails primes
, let s = zip [1..]
$ under 100
$ scanl (+) x xs
, let r = ...]
main = mapM_ print $ takeUntil ...
O2
" mean? Is OBV some sort of special compilation tool?