Is it *theoretically possible* to decide, with O(1) space and time complexity, whether a known, positive integer K is a solution of the equation

where *a* and *b* are fixed, positive integers (neither a multiple of the other), and the *μ _{i}* s are

*unknown*nonnegative integers, all but a finite number of which (but not all) are zero? If it is not possible in O(1) space and time, what are the space and time requirements for the best known algorithm?

The only approach to this problem I have found is to enumerate a subset of all possible *K*s ahead of time, but of course this requires me to pick upper cut-offs *M* and *N* such that *i ≤ N* and ∀ *μ _{i} ≤ M*. Worse, its space requirement is O(

*M*), which is likely to be so huge that no lookup algorithm achieves O(1) retrieval performance on real hardware. I have a bad feeling that this is actually the Knapsack Problem in disguise, but I'm not certain enough of that to give up yet.

^{N}I am trying to get all the way to O(1) in both space and time because I need to know if this can be done in real time, in an embedded environment with barely any headroom in either CPU or RAM.

I do *not* need to know the satisfying set of *μ _{i}* values.

**EDIT:** This Python function computes a set object `S`

such that `K in S`

is true if and only if *K* is one of the solutions to the above equation, given *a*, *b*, and cutoffs *M* and *N* as described above.

```
def compute_set(a, b, M, N):
ss = [a*i + b for i in xrange(1,N+1)]
aa = itertools.product(xrange(0,M+1), repeat=N)
rv = set(map(lambda a: sum(a[i]*ss[i] for i in xrange(N)), aa))
rv.remove(0)
return rv
```