To learn Clojure, I'm solving the problems at 4clojure. I'm currently cutting my teeth on question 164, where you are to enumerate (part of) the language a DFA accepts. An interesting condition is that the language may be infinite, so the solution has to be lazy (in that case, the test cases for the solution `(take 2000 ...`

.

I have a solution that works on my machine, but when I submit it on the website, it blows the stack (if I increase the amount of acceptable strings to be determined from 2000 to 20000, I also blow the stack locally, so it's a deficiency of my solution).

My solution[1] is:

```
(fn [dfa]
(let [start-state (dfa :start)
accept-states (dfa :accepts)
transitions (dfa :transitions)]
(letfn [
(accept-state? [state] (contains? accept-states state))
(follow-transitions-from [state prefix]
(lazy-seq (mapcat
(fn [pair] (enumerate-language (val pair) (str prefix (key pair))))
(transitions state))))
(enumerate-language [state prefix]
(if (accept-state? state)
(cons prefix (follow-transitions-from state prefix))
(follow-transitions-from state prefix)))
]
(enumerate-language start-state ""))
)
)
```

it accepts the DFA

```
'{:states #{q0 q1 q2 q3}
:alphabet #{a b c}
:start q0
:accepts #{q1 q2 q3}
:transitions {q0 {a q1}
q1 {b q2}
q2 {c q3}}}
```

and returns the language that DFA accepts (`#{a ab abc}`

). However, when determining the first 2000 accepted strings of DFA

```
(take 2000 (f '{:states #{q0 q1}
:alphabet #{0 1}
:start q0
:accepts #{q0}
:transitions {q0 {0 q0, 1 q1}
q1 {0 q1, 1 q0}}}))
```

it blows the stack. Obviously I should restructure the solution to be tail recursive, but I don't see how that is possible. In particular, I don't see how it is even possible to combine laziness with tail-recursiveness (via either `recur`

or `trampoline`

). The `lazy-seq`

function creates a closure, so using `recur`

inside `lazy-seq`

would use the closure as the recursion point. When using `lazy-seq`

inside `recur`

, the `lazy-seq`

is always evaluated, because `recur`

issues a function call that needs to evaluate its arguments.

When using `trampoline`

, I don't see how I can iteratively construct a list whose elements can be lazily evaluated. As I have used it and see it used, `trampoline`

can only return a value when it finally finishes (i.e. one of the trampolining functions does not return a function).

## Other solutions are considered out of scope

I consider a different kind of solution to this 4Clojure problem out of scope of this question. I'm currently working on a solution using `iterate`

, where each step only calculates the strings the 'next step' (following transitions from the current statew) accepts, so it doesn't recurse at all. You then only keep track of current states and the strings that got you into that state (which are the prefixes for the next states). What's proving difficult in that case is detecting when a DFA that accepts a *finite* language will no longer return any results. I haven't yet devised a proper stop-criterion for the `take-while`

surrounding the `iterate`

, but I'm pretty sure I'll manage to get this solution to work. For this question, I'm interested in the fundamental question: can laziness and tail-recursiveness be combined or is that fundamentally impossible?

[1] Note that there are some restrictions on the site, like not being able to use `def`

and `defn`

, which may explain some peculiarities of my code.