One possible approach would be creating it in reverse.

- Generate a random board, which leaves some spots open so you can insert the red car into the board.
- Move the cars around randomly.
- You have a solvable problem now.

Remains the problem of evaluating the difficulty. Certainly the number of random moves is not equal to the minimal number of moves required generally. You could translate the problem to a planning problem in PDDL and use an automated planner for solving the problem optimally. I have no idea how hard these problems truly are, but I suppose it will be feasible. As planner you can try FastDownward.

You can also implement a A* search yourself if you can come up with a good heuristic. *Fastdownward* comes with many sophisticated general purpose heuristics.

# How to create hard instances

The second step of above algorithm will resemble a Markov Chain with some equilibrium distribution (Markov Chain Monte Carlo method). Running the chain for long enough will result drawing boards from this equilibrium distribution. It is very well possible that most boards generated this way are solved very easily. Also your initial placement of cars influences the possible final boards you can obtain.

In order to obtain harder instances you can simply throw more CPU at the problem:

- repeat step 2 for long enough (you have to figure out yourself what
*long enough* means in this case)
- reject easy problems; this means generating very many problems (from different initial positions, and from running step 2 with different random seeds), then
- check the difficulty of the problem (e.g. using a planner) and reject the problem if it is too easy
- if it takes too long to find a good problem you might consider some simpler initial check before solving the problem with search (A* or planner); since this will probably be the bottleneck

Note that it is quite possible that some initial positions will yield only trivial instances, no matter how long you run the MC step.

Another possibility is using some kind of guided version of MCMC, like simulated annealing. But then you have to compute some energy function, some feature of your board that tends to be higher for boards that are potentially more difficult to solve.