# Given Two Lists of Integers, Find Each Pair Within a Distance of Each Other < O(N^2)

I have two sorted lists of integers. I would like to find all pairs of integers from the first and second list, respectively, that are within a certain distance of each other.

The naive approach is to check each pair, resulting in a O(N^2) time. I am sure there is a way to do it in O(N*logN) or maybe shorter.

In python, the naive O(N^2) approach is as follows:

``````def find_items_within(list1, list2, within):
for l1 in list1:
for l2 in list2:
if abs(l1 - l2) <= within:
yield (l1, l2)
``````

Application Note

I just wanted to point out the purpose of this little puzzle. I am searching a document and want to find all the occurrences of one term within a certain distance of another term. First you find the term vectors of both terms, then you can use the algorithms described below to figure out if they are within a given distance of each other.

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This code is O(n*log(n)+m) where m is the size of the answer.

``````def find_items_within(l1, l2, dist):
l1.sort()
l2.sort()
b = 0
e = 0
ans = []
for a in l1:
while b < len(l2) and a - l2[b] > dist:
b += 1
while e < len(l2) and l2[e] - a <= dist:
e += 1
ans.extend([(a,x) for x in l2[b:e]])
return ans
``````

In the worst case, it is possible that `m = n*n`, but if the answer is just a small subset of all possible pairs, this is a lot faster.

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Lots of good suggestions here, but I think this one is the easiest to understand, does not rely on anything too fancy and has algorithmic time as good or better than the others. Although @J.F. Sebastian's answer claims to be faster, I think it's the same when you factor in the O(log(n)) lookups it does. – speedplane Nov 30 '12 at 2:47
@speedplane: `set()` in Python has `O(1)` amortized lookups as the comments in my code explicitly say (think `unordered_set<>` in C++, not `set<>` with `O(log(n))`). btw, the time complexity is not better it is the same if `.sort()` is removed above (my answer assumes that the input is sorted as said in the first sentence of your question and `assert issorted()` statements in the code hint about it too). This answer is 2-3 times faster for the input I've tried on my machine. – J.F. Sebastian Nov 30 '12 at 19:07
@speedplane: btw, Thomash's answer can be made linear time if `ans.extend` is replaced with `yield i, (b,e)` where `l1[i] == a`. You will still need `O(n*n)` to enumerate all pairs explicitly, but you can find pairs (as in: know their indexes range) in `O(n)` for sorted input. – J.F. Sebastian Nov 30 '12 at 19:12
@J.F.Sebastian: It is not possible to have a linear time algorithm because the output is not linear. The best you can do is O(m) where m is the size of the output and that is the complexity of my algorithm if you consider the input to be sorted. – Thomash Nov 30 '12 at 20:20
@Thomash: have you read "You will still need `O(n*n)` (`O(m)` using your terminology) to enumerate all pairs explicitly" part of my comment? A single `yield i, (b, e)` gives you `e-b` pairs at once. – J.F. Sebastian Nov 30 '12 at 20:30

There is no way to do it better then `O(n^2)` because there are `O(n^2)` pairs, and for `within = infinity` you need to yield all of them.

To find the number of these pairs is a different story, and can be done by finding the first index for each element `e` that suffices `within-e < arr[idx]`. The index `idx` can be found efficiently using binary search for example - which will get you `O(nlogn)` solution to find the number of these pairs.

It can also be done in linear time (`O(n)`), since you don't really need to do a binary search for all elements, after the first `[a,b]` range is found, note that for each other range `[a',b']` - if `a>a'` then `b>=b'` - so you actually need to iterate the lists with two pointers and "never look back" to get a linear time complexity.

pseudo code: (for linear time solution)

``````numPairs <- 0
i <- 0
a <- 0
b <- 0
while (i < list1.length):
while (a < i && list1[i] - list2[a] > within):
a <- a+1
while (b < list2.length && list2[b] - list1[i] < within):
b <- b+1
if (b > a):
numPairs <- numPairs + (b-a)
i <- i+1
return numPairs
``````

(I made some fixes from the initial pseudo code - because the first one was aiming to find number of pairs within range in a single list - and not matches between two lists, sorry for that)

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(and for binary search - the OP should look at the `bisect` module) – Jon Clements Nov 29 '12 at 14:20
I think number of pairs can be done in O(n) - just find the window for the first number, and slide it for subsequent numbers. – nhahtdh Nov 29 '12 at 14:21
amit -- You don't need to test them all. since the data is sorted, once you get outside the distance you care about, you can safely break that loop. – mgilson Nov 29 '12 at 14:22
@mgilson: No need for the numbers to be equally spaced. The window can grow and shrink. – nhahtdh Nov 29 '12 at 14:24
@mgilson: Yes, but the 2 pointers will slide exactly n times. We just start from the previous position. – nhahtdh Nov 29 '12 at 14:39

Here something with the same interface as you have given:

``````def find_items_within(list1, list2, within):
i2_idx = 0
shared = []
for i1 in list1:
# pop values to small
while shared and abs(shared[0] - i1) > within:
shared.pop(0)
# insert new values
while i2_idx < len(list2) and abs(list2[i2_idx] - i1) <= within:
shared.append(list2[i2_idx])
i2_idx += 1
# return result
for result in zip([i1] * len(shared), shared):
yield result

for item in find_items_within([1,2,3,4,5,6], [3,4,5,6,7], 2):
print item
``````

Not very beautiful but it should do the trick in `O(N*M)`, where `N` is the length of list1 and `M` the list of shared pairs per Item (given that the elements dropped and appended to `shared` is constant on the average).

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Depending on the distribution of the values in your lists, you might be able to speed things up by using binning: take the range in which all your values fall (`min(A+B), max(A+B)`), and divide that range into bins of the same size as the distance `D` you’re considering. Then, to find all pairs, you only need to compare values within a bin or within adjacent bins. If your values are split up between many bins, this is an easy way to avoid doing M*N comparisons.

Another technique that might be just as easy in practice: Do a sort of bounded linear scan. Maintain an index into list A and into list B, starting from the beginning. On each iteration, advance the index into list A (start with the first element), call this element A0. Then, advance the index into list B. Remember the last value of B that’s less than A0-D (this is where we’ll want to start for the next iteration). But keep moving forward while you’re finding values between A0-D and A0+D — these are the pairs you’re looking for. As soon as the values in B become greater than A0+D, stop this iteration and start the next one — advance one element further into A, and start scanning B from the last place where B was < A0-D.

If you have, on average, a constant number of nearby pairs per element, I think this should be O(M+N)?

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This method uses a dictionary whose keys are possible values of `list2`, and whose values are a list of values of `list1` that are within distance of that value of `list2`.

``````def find_items_within(list1, list2, within):
a = {}
for l1 in list1:
for i in range(l1-within, l1+within+1):
if i not in a:
a[i] = []
a[i].append(l1)
for l2 in list2:
if l2 in a:
for l1 in a[l2]:
yield(l1, l2)
``````

The complexity for this one is kind of goofy. for a list1 of size M and a list2 of size N and a within of size W, it's O(log(M*W) * (M*W + N)). In practice I think it works pretty well for small W.

Bonus: this works on unsorted lists too.

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Nice approach using dictionaries. The downside however is that it also allocates a structure of M*W size. – speedplane Nov 29 '12 at 16:12

This seems to work:

``````from itertools import takewhile
def myslice(lst,start,stop,stride=1):
stop = len(lst) if stop is None else stop
for i in xrange(start,stop,stride):
yield lst[i]

def find_items_within(lst1,lst2,within):
l2_start = 0
for l1 in lst1:
try:
l2_start,l2 = next( (i,x) for i,x in enumerate(myslice(lst2,l2_start,None),l2_start) if abs(l1-x) <= within )
yield l1,l2
for l2 in takewhile(lambda x:(abs(l1-x) <= within), myslice(lst2,l2_start+1,None)):
yield l1,l2
except StopIteration:
pass

x = range(10)
y = range(10)
print list(find_items_within(x,y,2.5))
``````
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You can find integers from `list2` that are in `[x - within, x + within]` interval for all `x` from `list1` in linear time (`O(n)`) using "scan line" technique (see How to Find All Overlapping Intervals and Sub O(n^2) algorithm for counting nested intervals?).

To enumerate corresponding intervals from `list1` you need `O(m)` time where `m` is the number of intervals i.e., the overall algorithm is `O(n*m)`:

``````from collections import namedtuple
from heapq import merge

def find_items_within(list1, list2, within):
issorted = lambda L: all(x <= y for x, y in zip(L, L[1:]))
assert issorted(list1) and issorted(list2) and within >= 0

# get sorted endpoints - O(n) (due to list1, list2 are sorted)
Event = namedtuple('Event', "endpoint x type")
def get_events(lst, delta, type):
return (Event(x + delta, x, type) for x in lst)
START, POINT, END = 0, 1, 2
events = merge(get_events(list1, delta=-within, type=START),
get_events(list1, delta=within, type=END),
get_events(list2, delta=0, type=POINT))

# O(n * m), m - number of points in `list1` that are
#               within distance from given point in `list2`
started = set() # started intervals
for e in events:  # O(n)
if e.type is START: # started interval
started.add(e.x) # O(m) is worst case (O(1) amortized)
elif e.type is END: # ended interval
started.remove(e.x)  # O(m) is worst case (O(1) amortized)
else:  # found point
assert e.type is POINT
for x in started:  # O(m)
yield x, e.x
``````

To allow duplicate values in `list1`; you could add index for each `x` in `Event` and use a dictionary `index -> x` instead of the `started` set.

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