# Iterating Lists in Python, Ruby, Haskell (or whatever)

Update: I realize that I put the question very badly. Here's a second run.

Consider the following function:

``````myList = []
optimumList = []

def findOptimumListItems():
n = 5

for i in range (n + 1):
for j in range (n + 1 - i):
myList.append((i, j, n-i-j))

for i in myList:
win = 0.0
draw = 0.0
for j in myList:
score = 0
if (i[0] > j[0]):
score += 1
if (i[0] == j[0]):
score += 0.5
if (i[1] > j[1]):
score += 1
if (i[1] == j[1]):
score += 0.5
if (i[2] > j[2]):
score += 1
if (i[2] == j[2]):
score += 0.5
if (score == 2):
win += 1
if (score == 1.5):
draw += 1
if (win/(len(myList)-win-draw) > 1.0):
optimumList.append(i)

return optimumList
``````

First I make a list. For n = 5 the generated list is:

``````[(0, 0, 5), (0, 1, 4), (0, 2, 3), (0, 3, 2), (0, 4, 1),
(0, 5, 0), (1, 0, 4), (1, 1, 3), (1, 2, 2), (1, 3, 1),
(1, 4, 0), (2, 0, 3), (2, 1, 2), (2, 2, 1), (2, 3, 0),
(3, 0, 2), (3, 1, 1), (3, 2, 0), (4, 0, 1), (4, 1, 0),
(5, 0, 0)]
``````

Then, the function takes each element of the list and compares it with the list itself. This is how you do it: Say I'm comparing [0, 0, 5] against [3, 1, 1]. 0 loses to 3 (so no points), 0 loses to 1, so no points, 5 wins against 1 (1 point for that). A draw gets 0.5 points, a win gets 1 point. For any item, if wins are more than loses then that item is considered optimum and is added to the optimum list.

For n = 5, the optimum list is:

``````[(0, 2, 3), (0, 3, 2), (1, 1, 3), (1, 2, 2), (1, 3, 1), (2, 0, 3),
(2, 1, 2), (2, 2, 1), (2, 3, 0), (3, 0, 2), (3, 1, 1), (3, 2, 0)]
``````

My question is: How can I write the above function in a concise way? I'm especially interested in functional algorithms. Python, Ruby, Java, Haskell answers will be appreciated. (Having said that, if you have a neat solution in any language; that's okay.)

Sorry for repeating the same question. I agree that the original question was messy and hard to understand. I hope it's clear now.

Update (upon rampion's comment): Is there an efficient algorithm for this (or this type) problem?

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Ok, I'm still confused. What are `item_`, `item_0`, and `item_n`? –  senderle Mar 17 '11 at 0:41
This would be clearer if you said things like `myList[0][0]`, `myList[0][1]`, etc -- using normal (for Python) nested list syntax. –  senderle Mar 17 '11 at 0:42
No score for when the different items are equal? –  Dan Burton Mar 17 '11 at 16:47
This is much better. See my new answer below. –  senderle Mar 18 '11 at 20:00

Second Update: Great -- now I understand exactly what you want. This does the same thing as the code in your most recent edit:

``````def optimize(myList):
score_tup = lambda tup_a, tup_b: sum(1.0 if a > b else 0.5 if a == b else 0 for a, b in zip(tup_a, tup_b))
scores = ((tup_a, [score_tup(tup_a, tup_b) for tup_b in myList]) for tup_a in myList)
scores = ((tup, score.count(2), score.count(1.5)) for tup, score in scores)
return [tup for tup, win, draw in scores if (win * 1.0 / (len(myList) - win - draw)) > 1.0]

a = 5
myList = [(i, j, a-i-j) for i in range(a + 1) for j in range(a + 1 - i)]
print myList
print optimize(myList)
``````

If you want to see previous versions of this answer, check the edits; this was getting too long.

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why not just: `myList = [(i, j, a-1-i-j) for i in range(10) for j in range(a - i)]` –  newacct Mar 18 '11 at 5:20
@newacct, yes, I tried that, and it didn't work the way I expected. But I just tried what you typed, and it works. So I must have made a mistake when I tried it the first time. I'll edit... –  senderle Mar 18 '11 at 13:26

``````optimize :: Int -> [(Int,Int,Int)]
optimize n = filter optimal [ (a,b,c) | a <- [0..n], b <- [0..(n-a)], let c = n - a - b ]
where optimal x = (>0) . sum \$ map (comp x) xs
comp (a,b,c) (a',b',c') = signum \$ vs a a' + vs b b' + vs c c'
vs x x' = case compare x x' of
GT -> 1
EQ -> 0
LT -> -1
``````

Though this is fairly concise, it's not very efficient (we compare (0,3,2) with (0,2,3) and vice versa, when we only need to do that once).

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Thanks, rampion. –  blackened Mar 17 '11 at 22:19

This isn't done yet, but it's a good start, I think.

It's written in Ruby.

``````>> l = [1,2,3]
>> l.map {|n| l.map{|i| i > n ? 1 : 0.5 }}.flatten.inject(0){|start, n| start + n}
=> 6.0
``````
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You can also use `.inject(:+)` instead of `.inject(0){|start, n| start += n}`. (and `+=` should be just `+`) –  Guilherme Bernal Mar 17 '11 at 0:13
Thanks, I edited the post. –  Oleander Mar 18 '11 at 20:45

What is this for? Comparing each item in the list with every other item in the list will take an extremely large time ( O(n^2), I believe), especially as the list grows in size. If you give us some context, we may be able to tell you a better way to do this.

Anyway, here's what I came up with for comparing all of your items:

``````>>> for i in range(len(myList)):
...     for x in range(len(myList)):
...             if x != i:
...                     if myList[i][0] > myList[x][0]:
...                             score += 1
...                     if myList[i][0] < myList[x][0]:
...                             score += .5
...
``````

Untested, as it never finished running, so there may be a mistake.

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If I'm doing this correctly the comparison function is non-transformative, and what is returned is the same list you had before the comparison. That being said my functional program for generating the list is

``````def triple_tuple_generator(a):
"""Given an integer 'a', returns a generator of triple tuples of length 'a(a-1), where the tuple values are over the range 'a-1=i' (i,i-1,a-2*i+1)."""
for i in range(a):
for j in range(a-1):
yield (i,j,a-1-i-j)
``````

This is a generator so consume as you wish. If I was good enough at working with summations I would prove my hunch, but I'm a physicist not a mathematician. ;) Let me know if I got this right.

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