# Convert normal recursion to tail recursion

I was wondering if there is some general method to convert a "normal" recursion with `foo(...) + foo(...)` as the last call to a tail-recursion.

For example (scala):

``````def pascal(c: Int, r: Int): Int = {
if (c == 0 || c == r) 1
else pascal(c - 1, r - 1) + pascal(c, r - 1)
}
``````
-

In cases where there is a simple modification to the value of a recursive call, that operation can be moved to the front of the recursive function. The classic example of this is Tail recursion modulo cons, where a simple recursive function in this form:

``````def recur[A](...):List[A] = {
...
x :: recur(...)
}
``````

which is not tail recursive, is transformed into

``````def recur[A]{...): List[A] = {
def consRecur(..., consA: A): List[A] = {
consA :: ...
...
consrecur(..., ...)
}
...
consrecur(...,...)
}
``````

Alexlv's example is a variant of this.

This is such a well known situation that some compilers (I know of Prolog and Scheme examples but Scalac does not do this) can detect simple cases and perform this optimisation automatically.

Problems combining multiple calls to recursive functions have no such simple solution. TMRC optimisatin is useless, as you are simply moving the first recursive call to another non-tail position. The only way to reach a tail-recursive solution is remove all but one of the recursive calls; how to do this is entirely context dependent but requires finding an entirely different approach to solving the problem.

As it happens, in some ways your example is similar to the classic Fibonnaci sequence problem; in that case the naive but elegant doubly-recursive solution can be replaced by one which loops forward from the 0th number.

``````def fib (n: Long): Long = n match {
case 0 | 1 => n
case _ => fib( n - 2) + fib( n - 1 )
}

def fib (n: Long): Long = {
def loop(current: Long, next: => Long, iteration: Long): Long = {
if (n == iteration)
current
else
loop(next, current + next, iteration + 1)
}
loop(0, 1, 0)
}
``````

For the Fibonnaci sequence, this is the most efficient approach (a streams based solution is just a different expression of this solution that can cache results for subsequent calls). Now, you can also solve your problem by looping forward from c0/r0 (well, c0/r2) and calculating each row in sequence - the difference being that you need to cache the entire previous row. So while this has a similarity to fib, it differs dramatically in the specifics and is also significantly less efficient than your original, doubly-recursive solution.

Here's an approach for your pascal triangle example which can calculate `pascal(30,60)` efficiently:

``````def pascal(column: Long, row: Long):Long = {
type Point = (Long, Long)
type Points = List[Point]
type Triangle = Map[Point,Long]
def above(p: Point) = (p._1, p._2 - 1)
def aboveLeft(p: Point) = (p._1 - 1, p._2 - 1)
def find(ps: Points, t: Triangle): Long = ps match {
// Found the ultimate goal
case (p :: Nil) if t contains p => t(p)
// Found an intermediate point: pop the stack and carry on
case (p :: rest) if t contains p => find(rest, t)
// Hit a triangle edge, add it to the triangle
case ((c, r) :: _) if (c == 0) || (c == r) => find(ps, t + ((c,r) -> 1))
// Triangle contains (c - 1, r - 1)...
case (p :: _) if t contains aboveLeft(p) => if (t contains above(p))
// And it contains (c, r - 1)!  Add to the triangle
find(ps, t + (p -> (t(aboveLeft(p)) + t(above(p)))))
else
// Does not contain(c, r -1).  So find that
find(above(p) :: ps, t)
// If we get here, we don't have (c - 1, r - 1).  Find that.
case (p :: _) => find(aboveLeft(p) :: ps, t)
}
require(column >= 0 && row >= 0 && column <= row)
(column, row) match {
case (c, r) if (c == 0) || (c == r) => 1
case p => find(List(p), Map())
}
}
``````

It's efficient, but I think it shows how ugly complex recursive solutions can become as you deform them to become tail recursive. At this point, it may be worth moving to a different model entirely. Continuations or monadic gymnastics might be better.

You want a generic way to transform your function. There isn't one. There are helpful approaches, that's all.

-
Nice answer. Rúnar's paper was especially informative, although it may contradict your final claim (depending on exactly what transforms you had in mind). His Trampoline transformation would yield a stack-friendly implementation, even though the exponential runtime would still be a problem. –  Aaron Novstrup Sep 23 '13 at 19:19

I don't know how theoretical this question is, but a recursive implementation won't be efficient even with tail-recursion. Try computing `pascal(30, 60)`, for example. I don't think you'll get a stack overflow, but be prepared to take a long coffee break.

Instead, consider using a `Stream` or memoization:

``````val pascal: Stream[Stream[Long]] =
(Stream(1L)
#:: (Stream from 1 map { i =>
// compute row i
(1L
#:: (pascal(i-1) // take the previous row
collect { case Stream(a,b) => a + b }).toStream
++ Stream(1L))
}))
``````
-
I realize this doesn't directly answer your question, but I decided to post it as an answer rather than a comment anyway because you're likely to run into the same efficiency issue with any non-trivial recurrence of that form. –  Aaron Novstrup Sep 22 '13 at 21:47
If we're doing alternative Pascal's Triangle implementations, how about `val pascal = Stream.iterate(Seq(1))(a=>(0+:a,a:+0).zipped.map(_+_))` –  Luigi Plinge Sep 23 '13 at 10:24
@LuigiPlinge Beautiful! –  Aaron Novstrup Sep 23 '13 at 15:47

I'm pretty sure it's not possible in the simple way you're looking for the general case, but it would depend on how elaborate you permit the changes to be.

A tail-recursive function must be re-writable as a while-loop, but try implementing for example a Fractal Tree using while-loops. It's possble, but you need to use an array or collection to store the state for each point, which susbstitutes for the data otherwise stored in the call-stack.

It's also possible to use trampolining.

-
Yes trampolines are the easiest way to force a non tail recursive function to be tail recursive. See scala-lang.org/api/current/… and blog.richdougherty.com/2009/04/… –  iain Sep 23 '13 at 13:37

Yes it's possible. Usually it's done with accumulator pattern through some internally defined function, which has one additional argument with so called accumulator logic, example with counting length of a list.

For example normal recursive version would look like this:

``````def length[A](xs: List[A]): Int = if (xs.isEmpty) 0 else 1 + length(xs.tail)
``````

that's not a tail recursive version, in order to eliminate last addition operation we have to accumulate values while somehow, for example with accumulator pattern:

``````def length[A](xs: List[A]) = {
def inner(ys: List[A], acc: Int): Int = {
if (ys.isEmpty) acc else inner(ys.tail, acc + 1)
}
inner(xs, 0)
}
``````

a bit longer to code, but i think the idea i clear. Of cause you can do it without inner function, but in such case you should provide `acc` initial value manually.

-
One major difference is that in the pascal example, you have to recurse twice. You could stick the result of the first one into an accumulator, but getting it in the first place won't be TCO'ed. How would one get around that? –  yshavit Sep 22 '13 at 15:44
@yshavit can't check this solution, but maybe with two accumulators, return tuple from tailrec inner function and then sum? –  4lex1v Sep 22 '13 at 16:25
My gut is that it's not possible through an accumulator (without, as Luigi mentions below, simulating a call stack Ina local variable). –  yshavit Sep 22 '13 at 20:53
@AlexIv but that doesn't make it an answer to this particular question, which you do not appear to have read carefully enough. –  itsbruce Sep 22 '13 at 22:28
It's a question with a test case which your answer appears to ignore. Without showing how you might solve the test case, you're not really answering the question. –  itsbruce Sep 22 '13 at 23:12