You need to understand the mathematical theory of permutation cycles, also known as "orbits" (it's important to know both "terms of art" since the mathematical subject, the heart of combinatorics, is quite advanced, and you may need to look up research papers which could use either or both terms).

For a simpler introduction to the theory of permutations, wikipedia can help. Each of the URLs I mentioned offers reasonable bibliography if you get fascinated enough by combinatorics to want to explore it further and gain real understanding (I did, personally -- it's become somewhat of a hobby for me;-).

Once you understand the mathematical theory, the code is still subtle and interesting to "reverse engineer". Clearly, `indices`

is just the current permutation in terms of indices into the pool, given that the items yielded are always given by

```
yield tuple(pool[i] for i in indices[:r])
```

So the heart of this fascinating machinery is `cycles`

, which represents the permutation's orbits and causes `indices`

to be updated, mostly by the statements

```
j = cycles[i]
indices[i], indices[-j] = indices[-j], indices[i]
```

I.e., if `cycles[i]`

is `j`

, this means that the next update to the indices is to swap the i-th one (from the left) with the j-th one **from the right** (e.g., if `j`

is 1, then the *last* element of `indices`

is being swapped -- `indices[-1]`

). And then there's the less frequent "bulk update" when an item of `cycles`

reached 0 during its decrements:

```
indices[i:] = indices[i+1:] + indices[i:i+1]
cycles[i] = n - i
```

this puts the `i`

th item of `indices`

at the very end, shifting all following items of indices one to the left, and indicates that the next time we come to this item of `cycles`

we'll be swapping the new `i`

th item of `indices`

(from the left) with the `n - i`

th one (from the right) -- that would be the `i`

th one again, except of course for the fact that there will be a

```
cycles[i] -= 1
```

before we next examine it;-).

The hard part would of course be **proving** that this works -- i.e., that all permutations are exhaustively generated, with no overlap and a correctly "timed" exit. I think that, instead of a proof, it may be easier to look at how the machinery works when fully exposed in simple cases -- commenting out the `yield`

statements and adding `print`

ones (Python 2.*), we have

```
def permutations(iterable, r=None):
# permutations('ABCD', 2) --> AB AC AD BA BC BD CA CB CD DA DB DC
# permutations(range(3)) --> 012 021 102 120 201 210
pool = tuple(iterable)
n = len(pool)
r = n if r is None else r
if r > n:
return
indices = range(n)
cycles = range(n, n-r, -1)
print 'I', 0, cycles, indices
# yield tuple(pool[i] for i in indices[:r])
print indices[:r]
while n:
for i in reversed(range(r)):
cycles[i] -= 1
if cycles[i] == 0:
print 'B', i, cycles, indices
indices[i:] = indices[i+1:] + indices[i:i+1]
cycles[i] = n - i
print 'A', i, cycles, indices
else:
print 'b', i, cycles, indices
j = cycles[i]
indices[i], indices[-j] = indices[-j], indices[i]
print 'a', i, cycles, indices
# yield tuple(pool[i] for i in indices[:r])
print indices[:r]
break
else:
return
permutations('ABC', 2)
```

Running this shows:

```
I 0 [3, 2] [0, 1, 2]
[0, 1]
b 1 [3, 1] [0, 1, 2]
a 1 [3, 1] [0, 2, 1]
[0, 2]
B 1 [3, 0] [0, 2, 1]
A 1 [3, 2] [0, 1, 2]
b 0 [2, 2] [0, 1, 2]
a 0 [2, 2] [1, 0, 2]
[1, 0]
b 1 [2, 1] [1, 0, 2]
a 1 [2, 1] [1, 2, 0]
[1, 2]
B 1 [2, 0] [1, 2, 0]
A 1 [2, 2] [1, 0, 2]
b 0 [1, 2] [1, 0, 2]
a 0 [1, 2] [2, 0, 1]
[2, 0]
b 1 [1, 1] [2, 0, 1]
a 1 [1, 1] [2, 1, 0]
[2, 1]
B 1 [1, 0] [2, 1, 0]
A 1 [1, 2] [2, 0, 1]
B 0 [0, 2] [2, 0, 1]
A 0 [3, 2] [0, 1, 2]
```

Focus on the `cycles`

: they start as 3, 2 -- then the last one is decremented, so 3, 1 -- the last isn't zero yet so we have a "small" event (one swap in the indices) and break the inner loop. Then we enter it again, this time the decrement of the last gives 3, 0 -- the last is now zero so it's a "big" event -- "mass swap" in the indices (well there's not much of a mass here, but, there might be;-) and the cycles are back to 3, 2. But now we haven't broken off the for loop, so we continue by decrementing the *next*-to-last (in this case, the first) -- which gives a minor event, one swap in the indices, and we break the inner loop again. Back to the loop, yet again the last one is decremented, this time giving 2, 1 -- minor event, etc. Eventually a whole for loop occurs with only major events, no minor ones -- that's when the cycles start as all ones, so the decrement takes each to zero (major event), no `yield`

occurs on that last cycle.

Since no `break`

ever executed in that cycle, we take the `else`

branch of the `for`

, which returns. Note that the `while n`

may be a bit misleading: it actually acts as a `while True`

-- `n`

never changes, the `while`

loop only exits from that `return`

statement; it could equally well be expressed as `if not n: return`

followed by `while True:`

, because of course when `n`

is `0`

(empty "pool") there's nothing more to yield after the first, trivial empty `yield`

. The author just decided to save a couple of lines by collapsing the `if not n:`

check with the `while`

;-).

I suggest you continue by examining a few more concrete cases -- eventually you should perceive the "clockwork" operating. Focus on just `cycles`

at first (maybe edit the `print`

statements accordingly, removing `indices`

from them), since their clockwork-like progress through their orbit is the key to this subtle and deep algorithm; once you grok *that*, the way `indices`

get properly updated in response to the sequencing of `cycles`

is almost an anticlimax!-)