Firstly, I'd point out that this relies on the ordering of `Union`

, which is unspecified, and only works if the values in the original collection are unique. Changing `Union`

to `Concat`

would fix that.

I suspect it's also frighteningly expensive. Anyway...

You can understand it by induction. It definitely works for a single element collection, based on the `if`

. So, let's go from there.

Suppose we start with the assumption that it works for a collection of size `n`

like this:

```
{ e1, ... en }
```

Now let's see whether it works for a collection of size `n + 1`

. The call will bypass the "if", and go into the recursive return part. So we're left with:

```
list.Select((a, i1) =>
Permute(list.Where((b, i2) => i2 != i1))
.Select(b => (new List<T> { a }).Union(b)))
.SelectMany(c => c);
```

The `SelectMany`

part just flattens a collection of collections - that's straightforward. So let's focus on the `Select`

call. It's saying...

- For each element (
`a`

) in the original collection, which we know has index `i1`

...
- Work out the list
*except* that element (that's the `list.Where(...)`

part)
- For each permutation of that smaller list (that's the
`Permute`

call)...
- ... generate a new list consisting of element
`a`

followed by the "current permutation" (That's the `new List(...).Union(b)`

part.)

So if our collection was { x, y, z } we'd get:

- Every collection of
`{ y, z }`

prefixed by `x`

- Every collection of
`{ x, z }`

prefixed by `y`

- Every collection of
`{ x, y }`

prefixed by `z`

That pretty much defines "every permutation"... so it works for `n + 1`

.

Given the base case and the induction step, it therefore works for collections of any size greater than or equal to 1.

`list.Any() && !list.Skip(1).Any()`

– phoog Oct 4 '12 at 17:45