## Solution that runs in `O(n)`

time

```
def indices_dict(lis):
d = defaultdict(list)
for i,(a,b) in enumerate(lis):
d[a].append(i)
d[b].append(i)
return d
def disjoint_indices(lis):
d = indices_dict(lis)
sets = []
while len(d):
que = set(d.popitem()[1])
ind = set()
while len(que):
ind |= que
que = set([y for i in que
for x in lis[i]
for y in d.pop(x, [])]) - ind
sets += [ind]
return sets
def disjoint_sets(lis):
return [set([x for i in s for x in lis[i]]) for s in disjoint_indices(lis)]
```

## How it works:

```
>>> lis = [(1,2),(2,3),(4,5),(6,7),(1,7)]
>>> indices_dict(lis)
>>> {1: [0, 4], 2: [0, 1], 3: [1], 4: [2], 5: [2], 6: [3], 7: [3, 4]})
```

`indices_dict`

gives a map from an equivalence # to an index in `lis`

. E.g. `1`

is mapped to index `0`

and `4`

in `lis`

.

```
>>> disjoint_indices(lis)
>>> [set([0,1,3,4], set([2])]
```

`disjoint_indices`

gives a list of disjoint sets of indices. Each set corresponds to indices in an equivalence. E.g. `lis[0]`

and `lis[3]`

are in the same equivalence but not `lis[2]`

.

```
>>> disjoint_set(lis)
>>> [set([1, 2, 3, 6, 7]), set([4, 5])]
```

`disjoint_set`

converts disjoint indices into into their proper equivalences.

## Time complexity

The `O(n)`

time complexity is difficult to see but I'll try to explain. Here I will use `n = len(lis)`

.

`indices_dict`

certainly runs in `O(n)`

time because only 1 for-loop

`disjoint_indices`

is the hardest to see. It certainly runs in `O(len(d))`

time since the outer loop stops when `d`

is empty and the inner loop removes an element of `d`

each iteration. now, the `len(d) <= 2n`

since `d`

is a map from equivalence #'s to indices and there are at most `2n`

different equivalence #'s in `lis`

. Therefore, the function runs in `O(n)`

.

`disjoint_sets`

is difficult to see because of the 3 combined for-loops. However, you'll notice that at most `i`

can run over all `n`

indices in `lis`

and `x`

runs over the 2-tuple, so the total complexity is `2n = O(n)`