This has a lot in common with my answer to Insert-everywhere procedure. There's a procedure that seems a bit odd until you need it, and then it's incredibly useful, called `revappend`

. `(append '(a b ...) '(x y ...))`

returns a list `(a b ... x y ...)`

, with the elements of `(a b ...)`

. Since it's so easy to collect lists in *reverse* order while traversing a list recursively, it's useful sometimes to have `revappend`

, which *reverses* the first argument, so that `(revappend '(a b ... m n) '(x y ...))`

returns `(n m ... b a x y ...)`

. `revappend`

is easy to implement efficiently:

```
(define (revappend list tail)
(if (null? list)
tail
(revappend (rest list)
(list* (first list) tail))))
```

Now, a direct version of this `insert-everywhere`

is straightforward. This version isn't tail recursive, but it's pretty simple, and doesn't do any unnecessary list copying. The idea is that we walk down the `lst`

to end up with the following `rhead`

and `tail`

:

```
rhead tail (revappend rhead (list* item (append tail ...)))
------- ------- ------------------------------------------------
() (1 2 3) (r 1 2 3 ...)
(1) (2 3) (1 r 2 3 ...)
(2 1) (3) (1 2 r 3 ...)
(3 2 1) () (1 2 3 r ...)
```

If you put the recursive call in the place of the `...`

, then you get the result that you want:

```
(define (insert-everywhere item lst)
(let ie ((rhead '())
(tail lst))
(if (null? tail)
(revappend rhead (list item))
(revappend rhead
(list* item
(append tail
(ie (list* (first tail) rhead)
(rest tail))))))))
```

```
> (insert-everywhere 'a '(1 2 3))
'(a 1 2 3 1 a 2 3 1 2 a 3 1 2 3 a)
```

Now, this isn't tail recursive. If you want a tail recursive (and thus iterative) version, you'll have to construct your result in a slightly backwards way, and then reverse everything at the end. You can do this, but it does mean one extra copy of the list (unless you destructively reverse it).

```
(define (insert-everywhere item lst)
(let ie ((rhead '())
(tail lst)
(result '()))
(if (null? tail)
(reverse (list* item (append rhead result)))
(ie (list* (first tail) rhead)
(rest tail)
(revappend tail
(list* item
(append rhead
result)))))))
```

```
> (insert-everywhere 'a '(1 2 3))
'(a 1 2 3 1 a 2 3 1 2 a 3 1 2 3 a)
```

exactduplicates. After all, the tough part here is generating the sublists, right? If you can create`l == ((a 1 2 3) (1 a 2 3) (1 2 a 3) (1 2 3 a))`

, then`(a 1 2 3 1 a 2 3 1 2 a 3 1 2 3 a)`

is just an`(apply append l)`

away… – Joshua Taylor Dec 2 '13 at 16:25isin deciding on how and when exactlythe appendingis to be performed. This way is also the closest to the original OP code in its approach, so it isthis(appending, that is) that they were struggling with, apparently. – Will Ness Dec 2 '13 at 18:15