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I have a list of 2 dimensional tuples, unsorted, and of n size. I want to find which tuple has the closest dimensions to X and Y. What's the best way to do this?

target = (75, 75)
values = [
    (38, 61),
    (96, 36),
    (36, 40),
    (99, 83),
    (74, 76),

Using the target and values, the method should produce the answer (74, 76).


The answer below lead me to this exact method, for anyone who lands here:

def distance(item, target):
    return ((item[0] - target[0]) ** 2 + (item[1] - target[1]) ** 2) ** 0.5

best = min(values, key=lambda x: distance(x, target))

This is a Cartesian Distance problem.

  1. First take the square of the test value's x minus the optimal x value.
  2. Then take the square of the test value's y minus the optimal y value.
  3. Finally take the square root of step 1 plus step 2, which gives you the distance.
  4. Apply this to all items in the list, and the lowest number (using the min function) will give you the best fit.
share|improve this question
Cartesian distance, min() – millimoose Oct 2 '12 at 19:28
Tried anything?? – Rohit Jain Oct 2 '12 at 19:28
This question is unanswerable unless you define what you mean by "dimension" and what it means for a "dimension to be close" – ninjagecko Oct 2 '12 at 19:36
up vote 6 down vote accepted
def distance(tup1,tup2):
        This question is unanswerable unless you can specify this

        examples for 2d (you can write more general N-dimensional code if you need):
        cartesian: math.sqrt((tup2[0]-tup1[0])**2 + (tup2[1]-tup1[1])**2)
        manhattan: (tup2[0]-tup1[0]) + (tup2[1]-tup1[1])
    return # YOUR CODE HERE

min(values, key=lambda x:distance(target,x))
share|improve this answer
Oooh, using a lambda here, that's what I was missing. +1. – sberry Oct 2 '12 at 19:39
Thanks, you're correct in assuming that the list elements will always be 2-dimensional. I'll update my question to have the final code, but this is the answer. Thanks again. – blackrobot Oct 2 '12 at 19:43
@sberry: Oops sorry, I should have edited your answer rather than replying. For the record, one could also define a curried function, def distanceToTarget(x): return distance(target,x) (or use functools.partial, which is kind of poorly implemented). If target was a global variable, one could declare it as global target in the keyfunc. – ninjagecko Oct 2 '12 at 19:44
In the 2d case, there's also math.hypot. If you're just finding the minimum, you don't need to take the square root (the value which minimizes d^2 will also minimize d). Those are just tweaks, though, and Python's overhead is significant enough that whenever I guess what'll be fastest without timing I guess wrong.. – DSM Oct 2 '12 at 19:46
@DSM: thank you, never knew about math.hypot! – ninjagecko Oct 2 '12 at 19:46

Just another perspective to the problem. As this is a problem of Cartesian plain, convert it to a complex plain and solve

>>> min((abs(complex(*e)-complex(*target)),e) for e in values)[-1]
(74, 76)
share|improve this answer
closest = min([(abs(val[0]-target[0])+abs(val[1]-target[1]),val) for val in values])[1]

Is one way.

share|improve this answer

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