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`

Master Theorem? en.m.wikipedia.org/wiki/Master-Theorem – clemens Nov 10 '16 at 19:38`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`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 itonlywithextremelysmall arguments... in other words: the complexity of`g`

is bigger than any: polynomial, exponential and eventower of exponentials! – Bakuriu Nov 11 '16 at 15:38`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