```
[[max(first[0], second[0]), min(first[1], second[1])]
for first in a for second in b
if max(first[0], second[0]) <= min(first[1], second[1])]
```

A list comprehension which gives the answer:
`[[1, 2], [5, 5], [8, 10], [15, 18], [20, 23], [24, 24]]`

Breaking it down:

```
[[max(first[0], second[0]), min(first[1], second[1])]
```

Maximum of the first term, Min of the 2nd term

```
for first in a for second in b
```

For all combinations of first and second term:

```
if max(first[0], second[0]) <= min(first[1], second[1])]
```

Only if the max of the first does not exceed the minimum of the second.

If you need the output compacted, then the following function does that (In `O(n^2)`

time because deletion from a list is `O(n)`

, a step we perform `O(n)`

times):

```
def reverse_compact(lst):
for index in range(len(lst) - 2,-1,-1):
if lst[index][1] + 1 >= lst[index + 1][0]:
lst[index][1] = lst[index + 1][1]
del lst[index + 1] # remove compacted entry O(n)*
return lst
```

It joins ranges which touch, given they are **in-order**. It does it in reverse because then we can do this operation *in place* and delete the compacted entries as we go. If we didn't do it in reverse, deleting other entries would muck with our index.

```
>>> reverse_compact(comp)
[[1, 2], [5, 5], [8, 10], [15, 18], [20, 24]]
```

- The compacting function can be reduced further to
`O(n)`

by doing a forward in place compaction and copying back the elements, as then each inner step is `O(1)`

(get/set instead of del), but this is less readable:

This runs in `O(n)`

time and space complexity:

```
def compact(lst):
next_index = 0 # Keeps track of the last used index in our result
for index in range(len(lst) - 1):
if lst[next_index][1] + 1 >= lst[index + 1][0]:
lst[next_index][1] = lst[index + 1][1]
else:
next_index += 1
lst[next_index] = lst[index + 1]
return lst[:next_index + 1]
```

Using either compactor, the list comprehension is the dominating term here, with time =`O(n*m)`

, space = `O(m+n)`

, as it compares all possible combinations of the two lists with no early outs. This does **not** take advantage of the ordered structure of the lists given in the prompt: you could exploit that structure to reduce the time complexity to `O(n + m)`

as they always increase and never overlap, meaning you can do all comparisons in a single pass.

Note there is more than one solution and hopefully you can solve the problem and then iteratively improve upon it.

A 100% correct answer which satisfies all possible inputs is not the goal of an interview question. It is to see how a person thinks and handles challenges, and whether they can reason about a solution.

In fact, if you give me a 100% correct, textbook answer, it's probably because you've seen the question before and you already know the solution... and therefore that question isn't helpful to me as an interviewer. *'Check, can regurgitate solutions found on StackOverflow.'* The idea is to watch you solve a problem, not regurgitate a solution.

Too many candidates miss the forest for the trees: Acknowledging shortcomings and suggesting solutions is the right way to go about an answer to an interview questions. You don't have to have a solution, you have to show how you would approach the problem.

Your solution is fine if you can **explain it** and detail potential issues with using it.

I got my current job by failing to answer an interview question: After spending the majority of my time trying, I explained why my approach didn't work and the second approach I would try given more time, along with potential pitfalls I saw in that approach (and why I opted for my first strategy initially).

`[1, 2]`

the union of`[0, 2]`

and`[1, 5]`

? – Eli Sadoff Nov 1 '16 at 19:42`0-2`

and`1-5`

is`1-2`

– TemporalWolf Nov 1 '16 at 19:55