Here a couple of examples in a pseudocode to show what I mean.

This produces the *combinations* (selections disregarding order without repetition) of 1,...,n taking 3 at a time.

```
Do[Print[i,j,k], {i,1...n-2}, {j,i+1...n-1}, {k,j+1...n}]
```

The loop works from left to right---for each i, the iterator j will go through its values and for each j, the iterator k will go through its. By adding more variables and changing n, we can generalize what we have above.

Question: can we do the same for permutations? In other words, can we find a way to tweak the iterators to produce the P(n,k)=n!/(p-k)! permutations of 1,...,n? For k=3,

```
Do[Print[i,j,k], {i, f_1 , g_1(i,n)}, {j, f_2(i), g_2(i,j,n)}, {k, f_3(i,j), g_3(i,j,k,n)}]
```

Use only basic arithmetic operations and things like modular arithmetic, floor/ceiling fcns.

Because this might smell like a homework problem to you, I'd settle on an answer of "yay" or "nay"; your estimate of the difficulty level would be helpful to me as well.

Thank you.