I believe we can reduce the contained maximum manifold problem to boolean satisifiability and show NP-completeness through any dependency on this subproblem. Because of this, the algorithms spinning_plate provided are reasonable as heuristics, precomputing and machine learning is reasonable, and the trick becomes finding the *best* heuristic solution if we wish to blunder forward here.

Consider a board like the following:

```
..S........
#.#..#..###
...........
...........
..........F
```

This has many of the problems that cause greedy and gate-bound solutions to fail. If we look at that second row:

```
#.#..#..###
```

Our logic gates are, in 0-based 2D array ordered as `[row][column]`

:

```
[1][4], [1][5], [1][6], [1][7], [1][8]
```

We can re-render this as an equation to satisfy the block:

```
if ([1][9] AND ([1][10] AND [1][11]) AND ([1][12] AND [1][13]):
traversal_cost = INFINITY; longest = False # Infinity does not qualify
```

Excepting infinity as an unsatisfiable case, we backtrack and rerender this as:

```
if ([1][14] AND ([1][15] AND [1][16]) AND [1][17]:
traversal_cost = 6; longest = True
```

And our hidden boolean relationship falls amongst all of these gates. You can also show that geometric proofs can't fractalize recursively, because we can always create a wall that's exactly `N-1`

width or height long, and this represents a critical part of the solution in all cases (therefore, divide and conquer won't help you).

Furthermore, because perturbations across *different rows* are significant:

```
..S........
#.#........
...#..#....
.......#..#
..........F
```

We can show that, without a complete set of computable geometric identities, the complete search space reduces itself to N-SAT.

By extension, we can also show that this is trivial to verify and non-polynomial to solve as the number of gates approaches infinity. Unsurprisingly, this is why tower defense games remain so fun for humans to play. Obviously, a more rigorous proof is desirable, but this is a skeletal start.

Do note that you can significantly reduce the n term in your n-choose-k relation. Because we can recursively show that each perturbation must lie on the critical path, and because the critical path is always computable in O(V+E) time (with a few optimizations to speed things up for each perturbation), you can significantly reduce your search space at a cost of a breadth-first search for each additional tower added to the board.

Because we may tolerably assume O(n^k) for a deterministic solution, a heuristical approach is reasonable. My advice thus falls somewhere between spinning_plate's answer and Soravux's, with an eye towards machine learning techniques applicable to the problem.

*The 0th solution:* Use a tolerable but suboptimal AI, in which spinning_plate provided two usable algorithms. Indeed, these approximate how many naive players approach the game, and this should be sufficient for simple play, albeit with a high degree of exploitability.

*The 1st-order solution:* Use a database. Given the problem formulation, you haven't quite demonstrated the need to compute the optimal solution on the fly. Therefore, if we relax the constraint of approaching a random board with no information, we can simply precompute the optimum for all `K`

tolerable for each board. Obviously, this only works for a small number of boards: with `V!`

potential board states for each configuration, we cannot tolerably precompute all optimums as `V`

becomes very large.

*The 2nd-order solution:* Use a machine-learning step. Promote each step as you close a gap that results in a very high traversal cost, running until your algorithm converges or no more optimal solution can be found than greedy. A plethora of algorithms are applicable here, so I recommend chasing the classics and the literature for selecting the correct one that works within the constraints of your program.

The *best heuristic* may be a simple heat map generated by a locally state-aware, recursive depth-first traversal, sorting the results by most to least commonly traversed after the O(V^2) traversal. Proceeding through this output greedily identifies all bottlenecks, and doing so without making pathing impossible is entirely possible (checking this is O(V+E)).

Putting it all together, I'd try an intersection of these approaches, combining the heat map and critical path identities. I'd assume there's enough here to come up with a good, functional geometric proof that satisfies all of the constraints of the problem.