If pre-processing is allowed and not counted towards the time complexity, just use that to construct sub-lists so that you can efficiently find the element you're looking for. As with most optimisations, this trades space for time.

Your pre-processing step is to take your original list of `n`

numbers and create a number of *new* sublists.

Each of these sublists is a portion of the original, starting with the `n`

th element, extending for `m`

elements and *then* sorted. So your original list of:

```
{3, 1, 7, 5, 9}
```

gives you:

```
list[0][0] = {3}
list[0][1] = {1, 3}
list[0][2] = {1, 3, 7}
list[0][3] = {1, 3, 5, 7}
list[0][4] = {1, 3, 5, 7, 9}
list[1][0] = {1}
list[1][1] = {1, 7}
list[1][2] = {1, 5, 7}
list[1][3] = {1, 5, 7, 9}
list[2][0] = {7}
list[2][1] = {5, 7}
list[2][2] = {5, 7, 9}
list[3][0] = {5}
list[3][1] = {5,9}
list[4][0] = {9}
```

This isn't a cheap operation (in time *or* space) so you may want to maintain a "dirty" flag on the list so you only perform it the first time after you do an modifying operation (insert, delete, change).

In fact, you can use lazy evaluation for even *more* efficiency. Basically set all sublists to an empty list when you start and whenever you perform a modifying operation. Then, whenever you attempt to access a sublist and it's empty, calculate that sublist (and that one only) before trying to get the `k`

th value out of it.

That ensures sublists are evaluated *only* when needed and cached to prevent unnecessary recalculation. For example, if you never ask for a value from the 3-through-6 sublist, it's never calculated.

The pseudo-code for creating all the sublists is basically (`for`

loops inclusive at both ends):

```
for n = 0 to a.lastindex:
create array list[n]
for m = 0 to a.lastindex - n
create array list[n][m]
for i = 0 to m:
list[n][m][i] = a[n+i]
sort list[n][m]
```

The code for lazy evaluation is a little more complex (but only a little), so I won't provide pseudo-code for that.

Then, in order to find the `k`

th smallest number in the range `i`

through `j`

(where `i`

and `j`

are the original indexes), you simply look up `lists[i][j-i][k-1]`

, a very fast O(1) operation:

```
+--------------------------+
| |
| v
1st in range [3,4] (values 5,9), list[3][4-3=1][1-1-0] = 5
2nd in range [1,3] (values 1,7,5), list[1][3-1=2][2-1=1] = 5
3rd in range [0,2] (values 3,1,7), list[0][2-0=2][3-1=2] = 7
| | ^ ^ ^
| | | | |
| +-------------------------+----+ |
| |
+-------------------------------------------------+
```

Here's some Python code which shows this in action:

```
orig = [3,1,7,5,9]
print orig
print "====="
list = []
for n in range (len(orig)):
list.append([])
for m in range (len(orig) - n):
list[-1].append([])
for i in range (m+1):
list[-1][-1].append(orig[n+i])
list[-1][-1] = sorted(list[-1][-1])
print "(%d,%d)=%s"%(n,m,list[-1][-1])
print "====="
# Gives xth smallest in index range y through z inclusive.
x = 1; y = 3; z = 4; print "(%d,%d,%d)=%d"%(x,y,z,list[y][z-y][x-1])
x = 2; y = 1; z = 3; print "(%d,%d,%d)=%d"%(x,y,z,list[y][z-y][x-1])
x = 3; y = 0; z = 2; print "(%d,%d,%d)=%d"%(x,y,z,list[y][z-y][x-1])
print "====="
```

As expected, the output is:

```
[3, 1, 7, 5, 9]
=====
(0,0)=[3]
(0,1)=[1, 3]
(0,2)=[1, 3, 7]
(0,3)=[1, 3, 5, 7]
(0,4)=[1, 3, 5, 7, 9]
(1,0)=[1]
(1,1)=[1, 7]
(1,2)=[1, 5, 7]
(1,3)=[1, 5, 7, 9]
(2,0)=[7]
(2,1)=[5, 7]
(2,2)=[5, 7, 9]
(3,0)=[5]
(3,1)=[5, 9]
(4,0)=[9]
=====
(1,3,4)=5
(2,1,3)=5
(3,0,2)=7
=====
```

`kth`

in range`[1,n]`

, but what the`kth`

in range`[i, j]`

? Sort elements in`[i,j]`

again? NO – Alcott Mar 6 '13 at 1:31`k`

can change from query to query. – better urbanite Mar 6 '13 at 20:35