Let's start off with a set of interesting observations. As many others have noted, the goal is to find some linear combination 5x + 7y + 12z = b - a with integer coefficients such that |x| + |y| + |z| is minimized. But there are some very interesting connections between these three numbers that we can exploit:

- If we ever have a combination 5x + 7y + 12z where x and y are both positive or both negative, we can cancel out some number of x's and y's to add an equivalent number of 12s. In other words, no optimal solution has the same sign on both x and y, because we could always make this solution better.
- If we ever have a combination 5x + 7y + 12z where y and z have opposite signs, we can always remove a 7 and 12 and add in a 5 of the appropriate sign to get a better solution. Similarly, if x and z have opposite signs, we can always remove a 5 and 12 and add a 7 of the appropriate sign. This means that we never need to consider any solution where z has the same sign as either x or y, because it means that there would have to be a better solution.

Let's think about what (1) and (2) collectively tell us. (1) says that the signs on x and y can't be the same, since we can always do better. (2) says that if x and z have opposite signs or if y and z have opposite signs, we can always do better. Collectively this means that

*Lemma*: At least one of x, y, or z must be zero in the optimal solution.

To see this, if all three are nonzero, if x and y have the same sign, then we can clearly make the solution better by replacing them with 12s. Otherwise, x and y have opposite signs. Thus if x and z have different signs, by (2) we can replace them with fewer 7's, otherwise y and z have different signs and by (2) we can replace them with fewer 5's.

Okay, this is looking really great! This means that we just need to solve these three integer equations and find which one has the smallest sum of coefficients:

- 5x + 7y = b - a
- 5x + 12z = b - a
- 7y + 12z = b - a

Fortunately, by Bezout's identity, because gcd(5, 7) = gcd(5, 12) = gcd(7, 12) = 1, all of these systems of equations have a solution for any value of b - a.

Now, let's see how to solve each of these equations. Fortunately, we can use some cute tricks to greatly reduce our search space. For example, for 5x + 7y = b - a, the value of x can't be outside of [-6, +6], since if it were we could just replace seven of the 5's with five 7's. This means that we can solve the above equation by doing the following:

For x = -6 to +6, see if 5x + 7y = b - a has an integer solution by computing (b - a) - 5x and seeing if it's divisible by seven. If so, the number of steps required to solve the problem is given by |x| + |((b - a) - 5x) / 7|.

We can use similar tricks to solve the latter two equations - for the second equation, x ranges from -11 to +11, and for the third y ranges from -11 to +11 as well. We can then just take the best answer out of all three equations to see what the answer is.

Here's some pseudocode to record the fewest number of steps possible. This can easily be modified to return what those steps are by just recording which of the solutions was used and then expanding it out into a full path:

```
Let best = infinity
# Solve 5x + 7y = b - a
for x = -6 to +6:
if ((b - a) - 5 * x) mod 7 = 0:
best = min(best, |x| + |((b - a) - 5 * x) / 7|)
# Solve 5x + 12y = b - a
for x = -11 to +11:
if ((b - a) - 5 * x) mod 12 = 0:
best = min(best, |x| + |((b - a) - 5 * x) / 12|)
# Solve 7x + 12y = b - a
for x = -11 to +11:
if ((b - a) - 7 * x) mod 12 = 0:
best = min(best, |x| + |((b - a) - 7 * x) / 12|)
return best;
```

This algorithm is amazingly fast - it runs in O(1) time because the number of iterations required to solve each three of the linear systems is a constant (at most 23). It requires only O(1) memory to hold the possible values, and I think that in practice it's probably the fastest algorithm you'll be able to write.

Hope this helps!