You can figure out how `printList`

behaves by drawing a recursion tree. Each node consists of two elements: an `alist`

and a `blist`

. The root has the `alist`

with the initial sequence of items you want to permute, and an empty `blist`

.
Each node of the tree has one branch for each element of that node's `alist`

; you move from a 'father' node to each one of its 'children' by choosing an element from the father's `alist`

and:

- assigning to the child's
`alist`

the father's `alist`

*minus that element*;
- assigning to the child's
`blist`

the father's `blist`

plus that element *appended to its end*.

The leafs have an empty `alist`

, and since following different paths from the root to the leafs you have to choose elements from the root's `alist`

in different orders, the `blist`

of the leafs themselves contain all the various permutations of the root's `alist`

.

For example (`[abc],[] == alist,blist`

):

```
[abc],[]
/ | \
a/ b| \c
/ | \
[bc],[a] [ac],[b] [ab],[c]
/ \
b/ \c
/ \
[c],[ab] [b],[ac]
| |
c| |b
| |
[],[abc] [],[acb]
def printList(alist, blist=[]):
# if alist is empty, we are in a 'leaf' in the recursion tree;
# then blist contains one permutation; print it
if not len(alist): print ''.join(blist)
# ELSE, for each possible position in alist,
for i in range(len(alist)):
# move the element at that position from alist to the end of blist
blist.append(alist.pop(i))
# go to the 'children' node and do the printing job for its subtree
printList(alist, blist)
# then move back the element from the end of blist to its original
# position in alist, so we can continue with the for loop
# without altering alist
alist.insert(i, blist.pop())
```

`itertools.permutations`

. – ChristopheD Mar 26 '10 at 20:40