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I have started looking at the project Euler site as a way to learn haskell (and improve my python and ruby)... I think the haskell and python versions are ok, but I'm sure there must be a cleaner way for ruby. Any suggestions would be welcome! PS. This is not about how can I make one language look like another one! I am open and accepting :)

This is Problem 1:

Q: Add all the natural numbers below one thousand that are multiples of 3 or 5.

Haskell -

sum [ x | x <- [1..999], mod x 3 == 0 || mod x 5 == 0 ]

Python -

sum ( [ x for x in range(1,1000) if x % 3 == 0 or x % 5 == 0 ] )

Ruby -

(1..999) . map {|x| x if x % 3 == 0 || x % 5 == 0 } . compact . inject(:+)

They all give the same answer.


OK, so python can become:

sum ( x for x in range(1,1000) if x % 3 == 0 or x % 5 == 0 )

it is now a generator (a good thing as we are not storing the list)

but even more fun is...

sum( set(range(0,1000,3)) | set(range(0,1000,5)) )

--edit. For some reason I was looking at this again and tried a summation approach which should be constant time. Python 3.

def step_sum(mn,mx,step):
    amax = mx - (mx - mn) % step
    return (mn + amax) * ((1 + ((amax - mn) / step)) / 2)

step_sum(3,999,3) + step_sum(5,999,5) - step_sum(15,999,15)

Ruby can become:

(1..999) . select {|x| x % 3 == 0 || x % 5 == 0} . inject(:+)

or

(1..999) . select {|x| x % 3 == 0 or x % 5 == 0} . reduce(:+)

I am presuming as unlike map, select doesn't produce 'nul' and therefore there is no need to call compact. nice.

Haskell can also be:

let ƒ n = sum [0,n..999] in ƒ 3 + ƒ 5 - ƒ 15

or to be clearer:

let ƒ n = sum [ 0 , n .. 999 ] in ƒ 3 + ƒ 5 - ƒ (lcm 3 5)

as a function that lets us provide the two numbers ourselves:

ƒ :: (Integral a) => a -> a -> a
ƒ x y = let ƒ n = sum [0,n..999] in ƒ x + ƒ y - ƒ (lcm x y)
share|improve this question
2  
Ruby always remind me of Perl... Powerful and compact syntax, but sometimes you have a hard time reading your own code after a few weeks. –  Paulo Scardine Mar 16 '12 at 12:52
1  
Hi, I don't know about ruby, and this doesn't answer your question but... Congrats on picking up Project Euler, it's awesome... there's a constant time solution to that particular problem if you want to optimize a bit ;) If you don't know about Summation, check it out, it'll come very handy further on. –  pcalcao Mar 16 '12 at 12:52
2  
In Python you can remove the square brackets. –  eumiro Mar 16 '12 at 12:53
2  
@Jwosty you mean the code or are you being philosophical about the question? if it is the code... then it is supposed to provide an answer to the question 'Q'. –  The man on the Clapham omnibus Mar 16 '12 at 12:54
1  
@eumiro: removing the square brackets will transform the list comprehension into a generator, which is a very good idea (performance-wise) if you are not going to store the list. –  Paulo Scardine Mar 16 '12 at 12:56

5 Answers 5

For Haskell I like

let s n = sum [0,n..999] in s 3 + s 5 - s 15

or

sum $ filter ((>1).(gcd 15)) [0..999]

For fun the Rube-Goldberg version:

import Data.Bits

sum $ zipWith (*) [1..999] $ zipWith (.|.) (cycle [0,0,1]) (cycle [0,0,0,0,1])

[Edit]

Okay, explanation time.

The first version defines a little function s that sums up all multiples of n up to 999. If we sum all multiples of 3 and all multiples of 5, we included all multiples of 15 twice (once in every list), hence we need to subtract them one time.

The second version uses the fact that 3 and 5 are primes. If a number contains one or both of the factors 3 and 5, the gcd of this number and 15 will be 3, 5 or 15, so in every case the gcd will be bigger than one. For other numbers without a common factor with 15 the gcd becomes 1. This is a nice trick to test both conditions in one step. But be careful, it won't work for arbitrary numbers, e.g. when we had 4 and 9, the test gdc x 36 > 1 won't work, as gcd 6 36 == 6, but neither mod 6 4 == 0 nor 6 mod 9 == 0.

The third version is quite funny. cycle repeats a list over and over. cycle [0,0,1] codes the "divisibility pattern" for 3, and cycle [0,0,0,0,1] does the same for 5. Then we "or" both lists together using zipWith, which gives us [0,0,1,0,1,1,0,0,1,1,0,1...]. Now we use zipWith again to multiply this with the actual numbers, resulting in [0,0,3,0,5,6,0,0,9,10,0,12...]. Then we just add it up.

Knowing different ways to do the same thing might be wasteful for other languages, but for Haskell it is essential. You need to spot patterns, pick up tricks and idioms, and play around a lot in order to gain the mental flexibility to use this language effectively. Challenges like the project Euler problems are a good opportunity to do so.

share|improve this answer
    
+1 for anything Rube-Goldberg –  The man on the Clapham omnibus Mar 16 '12 at 14:38
    
could you explain you answers a bit (1 day of haskell means everything is new to me)... the first seems to be a recursive function. 15 being the least common multiple? [0,n..999] would be the pattern... ie 0,3,6,9 ... ] and n is provided with a value in s 3 ... s 5 ... –  The man on the Clapham omnibus Mar 16 '12 at 15:07
    
but why - s 15 –  The man on the Clapham omnibus Mar 16 '12 at 15:14
2  
@user969617: Principle of inclusion-exclusion. –  Vitus Mar 16 '12 at 15:56
    
@Vitus I have edited my question to include this Haskell code. It was only after staring at it for a minute that it clicked :) –  The man on the Clapham omnibus Mar 16 '12 at 16:02

Try this for Ruby:

(1..999).select {|x| x % 3 == 0 or x % 5 == 0}.reduce(:+)

Or a little different approach:

(1..999).reduce(0) {|m, x| (x % 3 == 0 or x % 5 == 0) ? m+x : m }
share|improve this answer
    
You beat me to it. I prefer 'reduce' to 'inject' though. –  Mark Thomas Mar 16 '12 at 13:13
    
Yep, reduce is a little shorter and more intuitively named. –  jtbandes Mar 16 '12 at 13:14
1  
select is very clear as long as you don't need to process the selected value (then you need a select + map), that's where list-comprehensions shine. In Ruby you can write a map_select but it's not as beautiful (not to mention nested list-comprehensions). –  tokland Mar 16 '12 at 13:15
    
I'm not that keen on using or and and like this. See devblog.avdi.org/2010/08/02/using-and-and-or-in-ruby –  Jonas Elfström Mar 16 '12 at 13:28
    
Also, you second example adds those that are multiples of both 3 and 5. –  Jonas Elfström Mar 16 '12 at 13:29

Not a list comprehension, I know, but to solve that I would use:

3*((999/3)**2+999/3)/2+5*((999/5)**2+999/5)/2-15*((999/15)**2+999/15)/2

Faster then any list comprehension one might come up with, and works in any language ;)

Only posting to show another way of looking at the same problem using http://en.wikipedia.org/wiki/Summation.

share|improve this answer
8  
That's slow!... what about print 233168? –  6502 Mar 16 '12 at 13:24
    
well... I guess the difference is that only 999 is hard-coded, right? same as the list comprehensions above?... I know it would be really hard to refactor that magic number into a function parameter... –  pcalcao Mar 16 '12 at 13:26
2  
relevant –  danr Mar 16 '12 at 13:27
    
Very good link danr. Extremely complete. –  pcalcao Mar 16 '12 at 13:29
1  
pcalcao is correct. Integer division in haskell is div :: Integral a => a -> a -> a. Compare with (/) :: Fractional a => a -> a -> a. Same thing with (**) :: Fractional a => a -> a -> a vs (^) :: (Num a, Integral b) => a -> b -> a. –  phyrex1an Mar 16 '12 at 14:00

I think the following is a better Ruby one:

(1..999).select{|x| x % 3 == 0 || x % 5 == 0}.reduce(:+)
share|improve this answer
    
detail: reduce(0, :+) makes no assumptions about how many values will be sum. –  tokland Mar 16 '12 at 13:25

Try something like this:

(1...1000).inject(0) do |sum, i|
  if (i % 3 == 0) or (i % 5 == 0)
    sum + i
  else
    sum
  end
share|improve this answer

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