# Linear merging for lists in Python

I'm working through Google's Python class exercises. One of the exercises is this:

Given two lists sorted in increasing order, create and return a merged list of all the elements in sorted order. You may modify the passed in lists. Ideally, the solution should work in "linear" time, making a single pass of both lists.

The solution I came up with was:

``````    def linear_merge(list1, list2):
list1.extend(list2)
return sorted(list1)
``````

It passed the the test function, but the solution given is this:

``````    def linear_merge(list1, list2):
result = []
# Look at the two lists so long as both are non-empty.
# Take whichever element [0] is smaller.
while len(list1) and len(list2):
if list1[0] < list2[0]:
result.append(list1.pop(0))
else:
result.append(list2.pop(0))

# Now tack on what's left
result.extend(list1)
result.extend(list2)
return result
``````

Note: the solution above is kind of cute, but unfortunately list.pop(0) is not constant time with the standard python list implementation, so the above is not strictly linear time. An alternate approach uses pop(-1) to remove the endmost elements from each list, building a solution list which is backwards. Then use reversed() to put the result back in the correct order. That solution works in linear time, but is more ugly.

Why are these two solutions so different? Am I missing something, or are they being unnecessarily complicated?

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They're encouraging you to think about the actual method (algorithm) of merging two sorted lists. Suppose you had two stacks of paper with names on them, each in alphabetical order, and you wanted to make one sorted stack from them. You wouldn't just lump them together and then sort that from scratch; that would be too much work. You'd make use of the fact that each pile is already sorted, so you can just take the one that comes first off of one pile or the other, and put them into a new stack.

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OK, that makes sense. I guess it just seemed weird that they would expect a n00b to come up with that. Can you give me an example of what result.extend(list1) result.extend(list2) would achieve? –  Megan Taylor Aug 30 '11 at 2:05
`pop` removes an item from a list and returns its value, so you're removing items from each list and putting them onto `result`. The initial loop runs as long as both `list1` and `list2` contain anything. When one runs out, you simply take whatever's left in the other and tack it onto `result`; that's what `extend` does. –  Tom Zych Aug 30 '11 at 2:09
Thanks a lot, I think I get it now. –  Megan Taylor Aug 30 '11 at 2:40
Glad I could help. I guess you're new to programming? It's a cool world, have fun! –  Tom Zych Aug 30 '11 at 2:43
They expect you, as 'a n00b', to come up with that because they expect you to think and do problem solving. If you can figure out that `pop(0)` doesn't run in constant time with the standard Python implementation, then you certainly aren't lacking in thinking skills. With this sort of thing, try starting out by modelling the problem: grab a deck of cards, shuffle it, cut it in half, sort each half, and then take those two halves and sort them together - and think about what you're doing. –  Karl Knechtel Aug 30 '11 at 4:25

As you noted, your solution works perfectly. So why the complexity? Well, for a start

Ideally, the solution should work in "linear" time, making a single pass of both lists.

Well, you're not explicitly passing through any lists, but you are calling `sorted()`. So how many times will `sorted()` pass over the lists?

Well, I don't actually know. Normally, a sorting algorithm would operate in something like `O(n*log(n))` time, though look at this quote from the Python docs:

The Timsort algorithm used in Python does multiple sorts efficiently because it can take advantage of any ordering already present in a dataset.

Maybe someone who knows timsort better can figure it out.

But what they're doing in the solution, is using the fact that they know they have 2 sorted lists. So rather than starting from "scratch" with `sorted`, they're picking off elements 1 by 1.

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Your solution is O(n log n), which means that if your lists were 10 times as long, the program would take (roughly) 30 times as much time. Their solution would only take 10 times as long.

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For the given example (sorted sublists) I believe Python's Timsort (like similar mergesorts) is O(n). –  agf Aug 30 '11 at 2:18
"if your lists were 10 times as long, the program would take (roughly) 30 times as much time." No; the ratio of running-time would approach 10 as the list size increases without limit. The kind of formula you're trying to use really only works with running times of the O(n^k) type. –  Karl Knechtel Aug 30 '11 at 4:27