A-star is guaranteed to provide the shortest path according to your metric function (not necessarily 'as the bird flies'), provided that your heuristic is "admissible", meaning that it never over-estimates the remaining distance.

Check this link: http://theory.stanford.edu/~amitp/GameProgramming/Heuristics.html

In order to assist in determining your implementation error, we will need details on both your metric, and your heuristic.

**Update**:

OP's metric function is 10 for an orthogonal move, and 14 for a diagonal move.

OP's heuristic only considers orthogonal moves, and so is "inadmissible"; it overestimates by ignoring the cheaper diagonal moves.

The only cost to an overly conservative heuristic is that additional nodes are visited before finding the minimum path; the cost of an overly aggressive heuristic is a non-optimal path possibl e being returned. OP should use a heuristic of:

```
7 * (deltaX + deltaY)
```

which is a very slight underestimate on the possibility of a direct diagonal path, and so should also be performant.

**Update #2:**

To really squeeze out performance, this is close to an optimum while still being very fast:

7 * min(deltaX,deltaY) + 10 * ( max(deltaX,deltaY) -
min(deltaX,deltaY) )

**Update #3:**

The **7** above is derived from 14/2, where 14 is the diagonal cost in the metric.

Only your heuristic changes; the metric is "a business rule" and drives all the rest. If you are interested on A-star for a hexagonal grid, check out my project here: http://hexgridutilities.codeplex.com/

**Update #4 (on performance):**

My impression of A-star is that it staggers between regions of O(N^2) performance and areas of almost O(N) performance. But this is so dependent on the grid or graph, the obstacle placement, and the start and end points, that it is hard to generalize. For grids and graphs of known particular shapes or flavours there are a variety of more efficient algorithms, but they often get more complicated as well; **TANSTAAFL**.