I'm going to write a function to do this for a single list, eg

```
>>> compact([6.23234121,6.23246575], tol=.01)
[6.23234121]
```

You can then get it to work on your nested structure through just `[compact(l) for l in lst]`

.

Each of these methods will keep the first element that doesn't have anything closer to it in the list; for @DSM's example of `[0, 0.005, 0.01, 0.015, 0.02]`

they'd all return `[0, 0.0.15]`

(or, if you switch `>`

to `>=`

, `[0, 0.01, 0.02]`

). If you want something different, you'll have to define exactly what it is more carefully.

First, the easy approach, similar to David's answer. This is O(n^2):

```
def compact(lst, tol):
new = []
for el in lst:
if all(abs(el - x) > tol for x in new):
new.append(el)
return compact
```

On three-element lists, that's perfectly nice. If you want to do it on three million-element lists, though, that's not going to cut it. Let's try something different:

```
import collections
import math
def compact(lst, tol):
round_digits = -math.log10(tol) - 1
seen = collections.defaultdict(set)
new = []
for el in lst:
rounded = round(seen, round_digits)
if all(abs(el - x) > tol for x in seen[rounded]):
seen[rounded].add(el)
new.append(el)
return new
```

If your `tol`

is `0.01`

, then `round_digits`

is 1. So `6.23234121`

is indexed in `seen`

as just `6.2`

. When we then see `6.23246575`

, we round it to `6.2`

and look that up in the index, which should contain all numbers that could possibly be within `tol`

of the number we're looking up. Then we still have to check distances to those numbers, but only on the very few numbers that are in that index bin, instead of the entire list.

This approach is O(n k), where k is the average number of elements that'll fall within one such bin. It'll only be helpful if k << n (as it typically would be, but that depends on the distribution of the numbers you're using relative to `tol`

). Note that it also uses probably more than twice as much memory as the other approach, which could be an issue for very large lists.

Another option would be to sort the list first; then you only have to look at the previous and following elements to check for a conflict.

`[0, 0.005, 0.01, 0.015, 0.02]`

to return? Every element has another element which is within 0.01 of it. – DSM Feb 7 '13 at 0:34