# Finding solutions to a single linear equation in n variables, or determine that no solution exists

Suppose you have a linear equation in n variables. The goal is to either determine that no integer solution is possible, or determine the smallest coefficient vector, for an integer solution.

In other words, let `ax=b` where `x` is the vector you want to find, and `a` is a vector of coefficients. `b` is a scalar constant. Find `x` such that the sum of `x1, ... ,xn` is minimized, and all `xi`s are integers. Or, determine that no such `x` exists. From now on, I will say that `|x|` is the sum of the `xi`'s.

What is an efficient way to solve this? I feel like this is similar to the Knapsack problem, but I'm not entirely sure.

My Solution

The way I tried to solve this was doing a Breadth-First Search on the space of vectors, where the breadth would be the sum of the vector entries.

At first I did this naively, starting from `|x| = 0`, but when `n` is even moderately large, and the solution is non-trivial, the number of vectors generated is enormous (`n ^ |x|` for each `|x|` you go through). Even worse, I was generating many duplicates. Even when I found a way to generate almost no duplicates, this way is too slow.

Next, I tried starting from a higher `|x|` from the beginning, by putting a lower bound on the optimal `|x|`. I sorted `a` to have it in decreasing order, then removed all `ai > b`. Then a lower bound on `|x|` is `b / a[0]`. However, from this point, I had difficulty quickly generating all the vectors of size `|x|`. From here, my code is mostly hacky.

In the code, `b = distance`, `x = clubs`, `n = numClubs`

Here is what it looks like:

``````short getNumStrokes (unsigned short distance, unsigned short numClubs, vector<unsigned short> clubs) {
if (distance == 0)
return 0;

numClubs = pruneClubs(distance, &clubs, numClubs);
//printClubs (clubs, numClubs);

valarray<unsigned short> a(numClubs), b(numClubs);
queue<valarray<unsigned short> > Q;

unsigned short floor = distance / clubs[0];

if (numClubs > 1) {
for (int i = 0; i < numClubs; i++) {
a[i] = floor / numClubs;
}

Q.push (a);
}

// starter vectors
for (int i = 0; i < numClubs; i++) {
for (int j = 0; j < numClubs; j++) {
if (i == j)
a[j] = distance / clubs[0];
else
a[j] = 0;
}

if (dot_product (a, clubs) == distance)
return count_strokes(a);

Q.push (a);
}

bool sawZero = false;

while (! Q.empty ()) {
a = Q.front(); // take first element from Q
Q.pop(); // apparently need to do this in 2 operations >_<

sawZero = false;

for (unsigned int i = 0; i < numClubs; i++) {
// only add numbers past right-most non-zero digit
//if (sawZero || (a[i] != 0 && (i + 1 == numClubs || a[i + 1] == 0))) {
//    sawZero = true;

b = a; // deep copy
b[i] += 1;

if (dot_product (b, clubs) == distance) {
return count_strokes(b);
} else if (dot_product (b, clubs) < distance) {
//printValArray (b, clubs, numClubs);
Q.push (b);
}
//}
}
}

return -1;
}
``````

EDIT: I'm using valarray because my compiler isn't C++ 11 compliant, so I can't use array. Other code suggestions much appreciated.

-
Just use the pseudoinverse? –  Oliver Charlesworth Sep 22 '13 at 22:04
@OliCharlesworth Don't think we covered that in Numerical Computing; can you explain like I'm 5? –  BlackSheep Sep 22 '13 at 22:07
Linear equations exist in linear spaces. Vectors made of natural numbers don't form a linear space. –  n.m. Sep 22 '13 at 22:11
@BlackSheep: Ah, you should probably make that explicit in your question! –  Oliver Charlesworth Sep 22 '13 at 22:14
"Bread-First Search" - my daily morning routine. –  IInspectable Sep 22 '13 at 22:15

Your problem is an equality constrained integer knapsack problem:

``````min |x|
s.t. ax = b
x integer
``````

If you have access, CPLEX or GUROBI can generally solve such problems quite easily.

Otherwise, consider some reductions of the constraint set

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glpk, the GNU Linear Programming Kit, is a free solution. –  Paul Rubel Sep 26 '13 at 15:21
@ Paul Rubel great point. I think coin-or has some open source solutions as well –  Tom Swifty Sep 26 '13 at 15:27