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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

K = \sum_{i=1}^\infty \mu_i (ai + b) = \mu_1 (a + b) + \mu_2 (2a + b) + \ldots

where a and b are fixed, positive integers (neither a multiple of the other), and the μi 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 K‌s ahead of time, but of course this requires me to pick upper cut-offs M and N such that i ≤ N and ∀ μi ≤ M. Worse, its space requirement is O(MN), 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.

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 μi 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
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1 Answer 1

up vote 2 down vote accepted

Solve in two stages.

In stage 1, compute a description of the set {(x, y): x, y in Z and ax + by = K} using standard techniques for handling Diophantine equations. Let g = gcd(a, b); unless g divides K, there are no solutions. Compute g via the extended Euclidean algorithm to solve ax' + by' = g as well as compute g; the first solution is (x', y') * K/g. The other solutions are related additively by integer multiples of (-b/g, a/g).

In stage 2, compute a description of the (x, y) solutions that can be achieved via different choices of µi. Since K ≥ 0 we know that y ≥ 1 is a necessary condition. If n is a variable, then x ≥ 0 and y ≥ 1 is a necessary and sufficient condition (set µ0 = y - 1 and µx = 1 and all other µs to 0).

If n is a parameter, then things are a little stickier. Using the results of stage 1, find the solution (x, y) with x ≥ 0 and y maximum (if no such solution, then K is not feasible). For this solution, check whether x/y ≤ n.

def egcd(A, B):
    """Returns a triple (gcd(A, B), s, t) such that s * A + t * B == gcd(A, B)."""
    a, b, s, t, u, v = A, B, 1, 0, 0, 1
    while True:
        assert s * A + t * B == a
        assert u * A + v * B == b
        if not b:
            break
        q, r = divmod(a, b)
        a, b, s, t, u, v = b, r, u, v, s - q * u, t - q * v
    return a, s, t

def solvable(K, a, b):
    g, s, t = egcd(a, b)
    q, r = divmod(K, g)
    if r:
        return False
    x, y = s * q, t * q
    assert a * x + b * y == K
    d = a // g
    q, r = divmod(y, d)
    if r <= 0:
        q -= 1
        r += d
    assert 0 < r <= d
    x, y = x + q * (b // g), r
    assert a * x + b * y == K
    return x >= y
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This is helpful, but I'm not sure what you mean by the distinction between "n is a variable" and "n is a parameter". It makes me think that I didn't explain myself clearly enough - if I say that I could have replaced n with infinity in the summation and noted an expectation that almost all the &mu;<sub>i</sub> are zero, does that help? –  zwol Dec 8 '11 at 3:10
    
@Zack A little bit. It's actually not too hard to compute the minimum value of n for which µ_n has to be nonzero. –  Per Dec 8 '11 at 3:16
    
@Zack Code added. Note that integer division in Python (//) always rounds down rather than rounding to zero. –  Per Dec 8 '11 at 3:48
1  
@Zack That's the point; all of those were feasible. Anyway, I updated the code slightly for your new equation and tested it against your brute force solution. –  Per Dec 8 '11 at 21:55
1  
@Zack Suppose there exist x ≥ y > 0 such that a * x + b * y = K. If x > y, let µ_1 = y - 1 and µ_{x - (y - 1)} = 1. If x = y, let µ_1 = y. Conversely, given µ_i such that ∑(µ_i * (a * i + b)), derive x = ∑(µ_i * i) and y = ∑µ_i. Since i ≥ 1 and K > 0, x ≥ y > 0. I'm minimizing y subject to the constraints a * x + b * y = K and y > 0 and x and y are integers. Every solution with greater y has lesser x, so it's this one or nothing. –  Per Dec 8 '11 at 22:59

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