Since `[4, 5, 6]`

and `[2, 3, 1]`

serves two different purposes I will make a function taking *two* arguments: the list to be reordered, and the list whose sorting will decide the order. I'll only return the reordered list.

This answer has timings of three different solutions for creating a permutation list for a sort. Using the fastest option gives this solution:

```
def pyargsort(seq):
return sorted(range(len(seq)), key=seq.__getitem__)
def using_pyargsort(a, b):
"Reorder the list a the same way as list b would be reordered by a normal sort"
return [a[i] for i in pyargsort(b)]
print using_pyargsort([4, 5, 6], [2, 3, 1]) # [6, 4, 5]
```

The `pyargsort`

method is inspired by the numpy `argsort`

method, which does the same thing much faster. Numpy also has advanced indexing operations whereby an array can be used as an index, making possible very quick reordering of an array.

So if your need for speed is great, one would assume that this numpy solution would be faster:

```
import numpy as np
def using_numpy(a, b):
"Reorder the list a the same way as list b would be reordered by a normal sort"
return np.array(a)[np.argsort(b)].tolist()
print using_numpy([4, 5, 6], [2, 3, 1]) # [6, 4, 5]
```

However, for short lists (length < 1000), this solution is in fact slower than the first. This is because we're first converting the `a`

and `b`

lists to `array`

and then converting the result back to `list`

before returning. If we instead assume you're using numpy arrays throughout your application so that we do not need to convert back and forth, we get this solution:

```
def all_numpy(a, b):
"Reorder array a the same way as array b would be reordered by a normal sort"
return a[np.argsort(b)]
print all_numpy(np.array([4, 5, 6]), np.array([2, 3, 1])) # array([6, 4, 5])
```

The `all_numpy`

function executes up to 10 times faster than the `using_pyargsort`

function.

The following logaritmic graph compares these three solutions with the two alternative solutions from the other answers. The arguments are two randomly shuffled ranges of equal length, and the functions all receive identically ordered lists. I'm timing only the time the function takes to execute. For illustrative purposes I've added in an extra graph line for each numpy solution where the 60 ms overhead for loading numpy is added to the time.

As we can see, the all-numpy solution beats the others by an order of magnitude. Converting from python `list`

and back slows the `using_numpy`

solution down considerably in comparison, but it still beats pure python for large lists.

For a list length of about 1'000'000, `using_pyargsort`

takes 2.0 seconds, `using_nympy`

+ overhead is only 1.3 seconds, while `all_numpy`

+ overhead is 0.3 seconds.

`basically I am sorting 2,3,1 and maintaining the order of list[0]`

- errr, [6,4,5] != [4,5,6] ? Are you just after`your_list[1].sort()`

? – Jon Clements Sep 11 '12 at 11:05`[4,5,6]`

to`[6,4,5]`

? – Burhan Khalid Sep 11 '12 at 11:09