FIRST, The ideal path was (in order of importance):

```
1. shortest
```

My heuristic (f) was:

```
manhattan distance (h) + path length (g)
```

This was buggy because it favored paths which veered towards the target then snaked back.

SECOND, The ideal path was:

```
1. shortest
2. approaches the destination from the same y coordinate (if of equal length)
```

My heuristic stayed the same. I checked for the second criteria at the end, after reaching the target. The heuristic was made slightly inefficient (to fix the veering problem) which also resulted in the necessary adjacent coordinates always being searched.

THIRD, The ideal path:

```
1. shortest
2. approaches the destination from the same y coordinate (if of equal length)
3. takes the least number of turns
```

Now I tried making the heuristic (f):

```
manhattan distance (h) + path length (g) * number of turns (t)
```

This of course works for criteria #1 and #3, and fixes the veering problem inherently. Unfortunately it's now so efficient that testing for criteria #2 at the end is not working because the set of nodes explored is not large enough to reconstruct the optimal solution.

Can anyone advise me how to fit criteria #2 into my heuristic (f), or how else to tackle this problem?

CRITERIA 2 example: If the goal is (4,6) and the paths to (3,6) and (4,5) are of identical length, then the ideal solution should go through (3,6) because it approaches from the Y plane instead, of (4,5) which comes from the X plane. However if the length is not identical, then the shortest path must be favored regardless of what plane it approaches in.