It always helps to think about the problem in terms *how would I do it by hand, with pencil and paper* or even only looking at the row of the numbers on the paper. However, the better solutions may look *overcomplicated* at first, and their advantage may not be *that clear* at first look -- see gnibbler's solution (his answer is my personal winner, see below).

First of all, you need to compare one number against all of the rest. Then second number with the rest, etc. When using the naive approach, there is no way to avoid two nested loops when using a single procesor. Then the time complexity is always O(n^2) where n is the length of the sequence. The truth is that some of the loops may be hidden in the operations like `in`

or `list.index()`

which does not make the solution better in principle.

Imagine the cartesian product of the numbers -- it consists of couples of the numbers. There is n^2 of such couples, but about a half is the same with respect to the comutative nature of the addition operation, and n of them are the pairs with itsef. It means that you need to check only `n^2 / 2 - n`

pairs. It is much better to avoid looping through the unneccessary pairs than to test later if they fit for the testing:

```
for each first element in theList:
for each second element in the rest of theList from the checked one on:
if the first and the second elements give the solution:
report the result
possibly early break if only the first should be reported
```

Use slicing for *the rest of theList from the checked one on*, use the `enumerate()`

in the first (and possibly also in the second) loop to know the index.

It is always good idea to minimize operations in the loops. Think about the inner loop body is done the most times. This way you can compute the searched number before entering the inner loop: `searched = sum - first`

. Then the second loop plus the `if`

can be replaced by `if searched in the rest of theList:`

[Edited after more full solutions appeared here]

Here is the O(n^2) solution to find the first occurence or None (pure Python, simple, no libraires, built-in functions and slicing only, few lines):

```
def sumPair(theList, n):
for index, e in enumerate(theList): # to know the index for the slicing below
complement = n - e # we are searching for the complement
if complement in theList[index+1:]: # only the rest is searched
return e, complement
print sumPair([6,3,6,8,3,2,8,3,2], 11)
```

[added after gnibbler's comment on slicing and copying]

gnibbler is right about slicing. The slice is the copy. (The question is whether slicing is not optimized using "copy on write" technique -- I do not know. If yes, then slicing would be a cheap operation for the purpose.) To avoid copying, the test can be done using the `list.index()`

method that allows to pass the starting index. The only *strange* thing is that it raises the `ValueError`

exception when the item is not found. This way the `if complement...`

must be replaced by the `try ... except`

:

```
def sumPair2(theList, n):
for ind, e in enumerate(theList):
try:
theList.index(n - e, ind + 1)
return e, n - e
except ValueError:
pass
```

Gnibbler's comment made me thinking more about the problem. The truth is that the `set`

can be close to O(1) to test whether it contains the element and O(n) to construct the set. It is not that clear for non-numeric elements (where the set type cannot be implemented as a bit array). When hash arrays comes to the play and possible conflicts should be solved using other techniques, then the quality depends on the implementation.

When in doubt, measure. Here the gnibbler's solution was slightly modified to be as same as the other solutions:

```
import timeit
def sumPair(theList, n):
for index, e in enumerate(theList):
if n - e in theList[index+1:]:
return e, n - e
def sumPair2(theList, n):
for ind, e in enumerate(theList):
try:
theList.index(n - e, ind + 1)
return e, n - e
except ValueError:
pass
def sumPair_gnibbler(theList, n):
# If n is even, check whether n/2 occurs twice or more in theList
if n%2 == 0 and theList.count(n/2) > 1:
return n/2, n/2
theSet = set(theList)
for e in theSet:
if n - e in theSet:
return e, n - e
```

The original numbers from the question were used for the first time test. The `n = 1`

causes the worst case when the solution cannot be found:

```
theList = [6,3,6,8,3,2,8,3,2]
n = 11
print '---------------------', n
print sumPair(theList, n),
print timeit.timeit('sumPair(theList, n)', 'from __main__ import sumPair, theList, n', number = 1000)
print sumPair2(theList, n),
print timeit.timeit('sumPair2(theList, n)', 'from __main__ import sumPair2, theList, n', number = 1000)
print sumPair_gnibbler(theList, n),
print timeit.timeit('sumPair_gnibbler(theList, n)', 'from __main__ import sumPair_gnibbler, theList, n', number = 1000)
n = 1
print '---------------------', n
print sumPair(theList, n),
print timeit.timeit('sumPair(theList, n)', 'from __main__ import sumPair, theList, n', number = 1000)
print sumPair2(theList, n),
print timeit.timeit('sumPair2(theList, n)', 'from __main__ import sumPair2, theList, n', number = 1000)
print sumPair_gnibbler(theList, n),
print timeit.timeit('sumPair_gnibbler(theList, n)', 'from __main__ import sumPair_gnibbler, theList, n', number = 1000)
```

It produces the following output on my console:

```
--------------------- 11
(3, 8) 0.00180958639191
(3, 8) 0.00594907526295
(8, 3) 0.00124991060067
--------------------- 1
None 0.00502748219333
None 0.026334041968
None 0.00150958864789
```

It is impossible to say anything about the quality in the sense of the time complexity from that short sequence of numbers and one special case. Anyway, gnibbler's solution won.

The gnibbler's solution uses the most memory in cases when the sequence contains unique values. Let's try much longer sequence containing 0, 1, 2, ..., 9999. The n equal to 11 and 3000 represents the task with a solution. For the case with n equal to 30000, the couple of numbers cannot be found. All elements must be checked -- worst case:

```
theList = range(10000)
n = 11
print '---------------------', n
print sumPair(theList, n),
print timeit.timeit('sumPair(theList, n)', 'from __main__ import sumPair, theList, n', number = 100)
print sumPair2(theList, n),
print timeit.timeit('sumPair2(theList, n)', 'from __main__ import sumPair2, theList, n', number = 100)
print sumPair_gnibbler(theList, n),
print timeit.timeit('sumPair_gnibbler(theList, n)', 'from __main__ import sumPair_gnibbler, theList, n', number = 100)
n = 3000
print '---------------------', n
print sumPair(theList, n),
print timeit.timeit('sumPair(theList, n)', 'from __main__ import sumPair, theList, n', number = 100)
print sumPair2(theList, n),
print timeit.timeit('sumPair2(theList, n)', 'from __main__ import sumPair2, theList, n', number = 100)
print sumPair_gnibbler(theList, n),
print timeit.timeit('sumPair_gnibbler(theList, n)', 'from __main__ import sumPair_gnibbler, theList, n', number = 100)
n = 30000
print '---------------------', n
print sumPair(theList, n),
print timeit.timeit('sumPair(theList, n)', 'from __main__ import sumPair, theList, n', number = 100)
print sumPair2(theList, n),
print timeit.timeit('sumPair2(theList, n)', 'from __main__ import sumPair2, theList, n', number = 100)
print sumPair_gnibbler(theList, n),
print timeit.timeit('sumPair_gnibbler(theList, n)', 'from __main__ import sumPair_gnibbler, theList, n', number = 100)
```

Notice that the sequence is much longer. The test is repeated only 100 times to get the results in reasonable time. (The time cannot be compared with the previous test unless you divide it by the `number`

.) It displays the following on my console:

```
--------------------- 11
(0, 11) 0.00840137682165
(0, 11) 0.00015695881967
(0, 11) 0.089894683992
--------------------- 3000
(0, 3000) 0.0166750746034
(0, 3000) 0.00966040735374
(0, 3000) 0.12532849753
--------------------- 30000
None 180.328006493
None 163.651082944
None 0.204691100723
```

Here the gnibbler's solution seems to be slow for the non-worst case. The reason is that it needs the preparation phase that goes through all the sequence. The naive solutions found the numbers in about one third of the first pass. What tells anythig is the worst case. The gnibbler's solution is about 1000 times faster, and the difference would increase for longer sequences. **Gnibbler's solution is the clear winner.**

`(8, 3)`

because those add to 11. Will a correct answer always have the numbers next to each other, or could the numbers be any two numbers in the list? – steveha Jun 12 '12 at 6:10