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I've written out a recursive algorithm for a little homegrown computer algebra system, where I'm applying pairwise reductions to the list of operands of an algebraic operation (adjacent operands only, as the algebra is non-commutative). I'm trying to get an idea of the runtime complexity of my algorithm (but unfortunately, as a physicist it's been a very long time since I took any undergrad CS courses that dealt with complexity analysis). Without going into details of the specific problem, I think I can formalize the algorithm in terms of a function f that is a "divide" step and a function g that combines the results. My algorithm would then take the following formal representation:

f(1) = 1  # recursion anchor for f
f(n) = g(f(n/2), f(n/2))

g(n, 0) = n, g(0, m) = m            # recursion ...
g(1, 0) = g(0, 1) = 1               # ... anchors for g

           / g(g(n-1, 1), m-1)  if reduction is "non-neutral"
g(n, m) = |  g(n-1, m-1)        if reduction is "neutral"
           \ n + m              if no reduction is possible

In this notation, the functions f and g receive lists as arguments and return lists, with the length of the input/output lists being the argument and the right-hand-side of the equations above.

For the full story, the actual code corresponding to f and g is the following:

def _match_replace_binary(cls, ops: list) -> list:
    """Reduce list of `ops`"""
    n = len(ops)
    if n <= 1:
        return ops
    ops_left = ops[:n//2]
    ops_right = ops[n//2:]
    return _match_replace_binary_combine(
            cls,
            _match_replace_binary(cls, ops_left),
            _match_replace_binary(cls, ops_right))


def _match_replace_binary_combine(cls, a: list, b: list) -> list:
    """combine two fully reduced lists a, b"""
    if len(a) == 0 or len(b) == 0:
        return a + b
    if len(a) == 1 and len(b) == 1:
        return a + b
    r = _get_binary_replacement(a[-1], b[0], cls._binary_rules)
    if r is None:
        return a + b
    if r == cls.neutral_element:
        return _match_replace_binary_combine(cls, a[:-1], b[1:])
    r = [r, ]
    return _match_replace_binary_combine(
            cls,
            _match_replace_binary_combine(cls, a[:-1], r),
            b[1:])

I'm interested in the worst-case number of times get_binary_replacement is called, depending on the size of ops

  • Have you tried to apply the Master Theorem? en.m.wikipedia.org/wiki/Master-Theorem – clemens Nov 10 '16 at 19:38
  • I knew there had to be a theorem about this! From a first glance, it seems to apply exactly to my situation, I'll read through the details and see where that gets me – Michael Goerz Nov 10 '16 at 19:43
  • @macmoonshine I don't think the Master theorem can be applied directly. It deals with the recursions of the type T(n) = aT(n/b) + f(n), however the OP problem is of the type T(n) = g(T(n/b), T(n/c)) + f(n) and I don't see an easy way to reduce this to the first form... In any case the first thing to do is to get the complexity of g, since it does not depend on f. After that you just replace the two arguments in that complexity with f(n/2) and after this you may end up in the form of the Master theorem, assuming it remains linear... – Bakuriu Nov 11 '16 at 15:34
  • In any case I think I have bad news for you Michael. Your g function seems a variation over the Ackermann function which is a computable function that grows more than any primitive recursive function... in other words you can hope to compute it only with extremely small arguments... in other words: the complexity of g is bigger than any: polynomial, exponential and even tower of exponentials! – Bakuriu Nov 11 '16 at 15:38
  • @Bakuriu At first glance it does look like a variation of Ackermann, but it's not (mainly because the condition does not depend on the arguments): there is a worst case of g, namely the "non-neutral" case, so I think we can actually use that. If I code up the function g (using "non-neutral' always and call g(n, m), the resulting number of calls is always 2*(n+m)-1, so that insight should help me a lot in the analysis! – Michael Goerz Nov 11 '16 at 17:04
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So I think I've got it now. To restate the problem: find the number of calls to _get_binary_replacement when calling _match_replace_binary with an input of size n.

  • define function g(n, m) (as in original question) that maps the size of the the two inputs of _match_replace_binary_combine to the size of the output
  • define a function T_g(n, m) that maps the size of the two inputs of _match_replace_binary_combine to the total number of calls to g that is required to obtain the result. This is also the (worst case) number of calls to _get_binary_replacement as each call to _match_replace_binary_combine calls _get_binary_replacement at most once

We can now consider the worst case and best case for g:

  • best case (no reduction): g(n,m) = n + m, T_g(n, m) = 1

  • worst case (all non-neutral reduction): g(n, m) = 1, T_g(n, m) = 2*(n+m) - 1 (I determined this empirically)

Now, the master theorem (WP) applies:

Going through the description on WP:

  • k=1 (the recursion anchor is for size 1)
  • We split into a = 2 subproblems of size n/2 in constant (d = 1) time
  • After solving the subproblems, the amount of work required to combine the results is c = T_g(n/2, n/2). This is n-1 (approximately n) in the worst case and 1 in the best case

Thus, following the examples on the WP page for the master theorem, the worst case complexity is n * log(n), and the best case complexity is n

Empirical trials seem to bear out this result. Any objections to my line of reasoning?

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