# Are Haskell List Comprehensions Inefficient?

I started doing Project Euler and got to problem number 9. Since I was using Project Euler to learn Haskell, I decided to use list comprehensions (as shown in Learn You A Haskell). I do that and GHCI takes awhile to figure out the triplet, which I figured is normal because of the calculations involved. Now, at work yesterday (I don't work as a programmer professionally, yet) I was talking to a friend who knows VBA and he wanted to try to find the answers in VBA. I thought it would be a fun challenge as well, and I churn out some basic for loops and if statements, but what got me was that it was much faster than Haskell was.

My question is: are Haskell's list comprehension incredibly inefficient? At first I thought it was just because I was in GHC's interactive mode, but then I realized VBA is interpreted too.

Please note, I didn't post my code because of it being an answer to project euler. If it will answer my question (as in I'm doing something wrong) then I will gladly post the code.

 Here is my Haskell list comprehension:
`[(a,b,c) | c <- [1..1000], b <- [1..c], a <- [1..b], a+b+c=1000, a^2+b^2=c^2]`
I guess I could've lowered the range on c but is that what is really slowing it down?

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List comphreensions don't have to be slow. Probably your list accesses are. It depends largely on your code. –  devoured elysium Mar 18 '11 at 11:55
I used to practice in Haskell at Project Euler and found GHCi good for trying something, but when you need solution than you have to build binary with `ghc -O2`. There is a lot of optimization rules that will be fired only with `-O`. As well you may consider looking at some libraries that do optimization of high-level code (like `stream-fusion`). –  ony Mar 18 '11 at 12:45
Fist: think! Second: code a solution! That is Project Euler. You just coded a solution without thinking. List comprehension in Haskell is not slow. –  knivil Mar 18 '11 at 17:01

There are two things you could be doing with this problem that could make your code slow. One is how you are trying values for a, b and c. If you loop through all possible values for a, b, c from 1 to 1000, you'll be spending a long time. To give a hint, you can make use of a+b+c=1000 if you rearrange it for c. The other is that if you only use a list comprehension, it will process every possible value for a, b and c. The problem tells you that there is only one unique set of numbers that satisfies the problem, so if you change your answer from this:

``````[ a * b * c | .... ]
``````

to:

``````head [ a * b * c | ... ]
``````

then Haskell's lazy evaluation means that it will stop after finding the first answer. This is the Haskell equivalent of breaking out of your VBA loop when you find the first answer. When I used both these tips, I had an answer that completed very quickly (under a second) in ghci.

Addendum: I missed at first the condition a < b < c. You can also make use of this in your list comprehensions; it is valid to say things along the lines of:

``````[(a, b) | b <- [1..100], a <- [1..b-1]]
``````
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I added my list comprehension in my original post. It looks similar to what you had posted so I'm not too sure. –  Jetti Mar 18 '11 at 13:27
The head optimisation helps with your version, to make it finish faster. Your version prints out the answer then keeps going for quite a long time, searching for other answers. Here's a small adaptation of your code with my other suggestion that makes it almost instant: `head [(a,b,c) | c <- [1..1000], b <- [1..c], a <- [1000-b-c], a < b, a^2+b^2==c^2]` That's a slight trick to bind `a` in the comprehension by drawing it from a singleton list, and I check that it's still less than `b`. –  Neil Brown Mar 18 '11 at 14:02
A minor tweak: You don't need to draw `a` from a list. This will do: `head [(a,b,c) | c <- [1..1000], b <- [1..c], let a = 1000-b-c, a < b, a^2+b^2==c^2]` –  sigfpe Mar 18 '11 at 14:15
@user207442 Thanks, I didn't realise you could embed let in a list comprehension like that. –  Neil Brown Mar 18 '11 at 14:18
Thanks for the help Neil and user207442. I'll definitely try that tonight. I have a lot to learn before I can do great good with Haskell :) –  Jetti Mar 18 '11 at 14:20

Consider this simplified version of your list comprehension:

``````[(a,b,c) | a <- [1..1000], b <- [1..1000], c <- [1..1000]]
``````

This will give all possible combinations of a, b, and c. It's kind of like saying, "how many ways can three one-thousand-sided dice land?" The answer is 1000*1000*1000 = 1,000,000,000 different combinations. If it took 0.001 seconds to generate each combination, it would therefore take 1,000,000 seconds (~11.5 days) to finish all combinations. (OK, 0.001 seconds is actually pretty slow for a computer, but you get the idea)

When you add predicates to your list comprehension, it still takes the same amount of time to compute; in fact, it takes longer since it needs to check the predicate for each of the 1 billion combinations it computes.

Now consider your comprehension. It looks like it should be much faster, right?

``````[(a,b,c) | c <- [1..1000], b <- [1..c], a <- [1..b], a+b+c=1000, a^2+b^2=c^2]
``````

There are 1000 choices for c. How many are there for b and a? Well, the average choice for c is 500. For all choices of c, then, there are an average of 500 choices for b (since b can range from 1 to c). Likewise, for all choices of c and b, there are an average of 250 choices for a. That's very hand-wavy, but I'm fairly sure it's accurate. So 1000 choices for c * 1000/2 choices for b * 1000/4 choices for a = 1 billion / 8 ~= 100 million. It's 8x faster, but if you paid attention, you'll notice it's actually the same big-Oh complexity as the simplified version above. If we compared "simplified" vs "improved" versions of the same problem, but from [1..100000] instead of [1..1000], the "improved" would still only be 8x faster than the "simplified".

Don't get me wrong, 8x is a wonderful constant-factor speedup. But unless you want to wait a couple hours to get the solution, you'll need to get a better big-Oh.

As Neil noted, the way to reduce the complexity of this problem is, for a given `b` and `c`, choose the `a` that satisfies `a+b+c=1000`. That way, you're not trying a bunch of `a`s that will fail. This will drop the big-Oh complexity; you'll only be considering approximately 1000 * 500 * 1 = 500,000 combinations, instead of ~100,000,000.

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Thank you for your answer. I appreciate the amount of thought put into it! –  Jetti Mar 18 '11 at 17:43