Your first program is a little vague. I assume `numbers`

is a list of tuples or something? Like `[(1,2), (3,4), (5,6)]`

? If so, your program is pretty good, from a complexity standpoint - it's O(n). Perhaps you want a little more Pythonic solution? The neatest way to clean this up would be to join your conditions:

```
if i != j and i + j == k:
```

But this simply increases readability. I think it may also add an additional boolean operation, so it might not be an optimization.

I am not sure if you intended for your program to return the first pair of numbers which sum to k, but if you wanted all pairs which meet this requirement, you could write a comprehension:

```
def pairsum(numbers, k):
return list(((i, j) for i, j in numbers if i != j and i + j == k))
```

In that example, I used a generator comprehension instead of a list comprehension so as to conserve resources - generators are functions which act like iterators, meaning that they can save memory by only giving you data when you need it. This is called lazy iteration.

You can also use a filter, which is a function which returns only the elements from a set for which a predicate returns `True`

. (That is, the elements which meet a certain requirement.)

```
import itertools
def pairsum(numbers, k):
return list(itertools.ifilter(lambda t: t[0] != t[1] and t[0] + t[1] == k, ((i, j) for i, j in numbers)))
```

But this is less readable in my opinion.

Your second program can be optimized using a set. If you recall from any discrete mathematics you may have learned in grade school or university, a set is a collection of unique elements - in other words, a set has no duplicate elements.

```
def dedup(mystring):
return set(mystring)
```

The algorithm to find the unique elements of a collection is generally going to be O(n^2) in time if it is O(1) in space - if you allow yourself to allocate more memory, you can use a Binary Search Tree to reduce the time complexity to O(n log n), which is likely how Python sets are implemented.

Your solution took O(n^2) time but also O(n) space, because you created a new list which could, if the input was already a string with only unique elements, take up the same amount of space - and, for every character in the string, you iterated over the output. That's essentially O(n^2) (although I think it's actually O(n*m), but whatever). I hope you see why this is. Read the Binary Search Tree article to see how it improves your code. I don't want to re-implement one again... freshman year was so grueling!

`"g"`

in`"abcdefg"`

, if you started from the beginning, it would take you 7 checks, which is the length of that string. Complexity also applies to memory - if I told you to reverse`"abcdefg"`

you might iterate through the string backwards and append to a new string each character, but that would be O(n) in memory because you copied the string once... that's linear growth, each copy increases the memory by n (bytes). Doing it in place would be O(1) (constant space) because you wouldn't make any copies. – 2rs2ts Jun 28 '13 at 23:52