Actually you may consider that the elevation of the destination square can't be changed either, since there's no need to elevate it.

Now, in classical Dijkstra(-like) algorithm you'd say that every square of your grid has a *price* at which you can reach this square. That is, your source square has *price*=0, Then in a loop you take the next *cheapest* square and try to move from it to all the adjacent squares, whose price is bigger.

In your problem you have an extra degree of freedom: the elevation level of your square. That is, when you move to a square you are allowed to change its height.

The most straightforward "brute-force" solution would be the following:

- Check all the cells, build a set of their elevation levels (i.e. the
spectrum of all the heights). Say you have
**H** distinct heights.
- Define the state of the square as its position
**and** height. The define your problem in terms of Dijkstra graph.
- For every square add a vertex to the graph that represents its actual elevation. Then add extra vertexes that represent it with a bigger elevation (besides source and destination squares). So that you have up to
**H** vertexes for every square.
- Define an
*internal price* of every vertex as its height above its actual position. So that for every square you have a vertex with *internal price*=0 (the actual elevation), plus number of vertexes representing elevated positions with appropriate *internal price*.
- Connected vertexes representing neighbor squares by
**directed** edges. Put an edge only if the source vertex has an elevation at least of the target vertex.

Then find the shortest path by Dijkstra (or A*) algorithm. The *cost* of the move is considered the *internal price* of the target vertex (our edges don't carry the price).

In simple words we've built a "layered" graph, each layer corresponds to an optional height. At each position you're allowed to make a move either at your current layer, or get lower.

Needless to say that the problem complexity increases. The vertex count is increased by the factor of (up to) **H**, the same holds for the edges count.

Basically the path-search has the complexity of `log(N) * N * M`

where **N** is squares cell count, and **M** - is the connectivity orders (number of connected nearest neighbors). After your inflation the complexity grows by (up to) the factor of **H^2**.

So that the efficiency of this algorithm depends on the number of distinct heights. If you have a small number of heights - the algorithm should be efficient. However if all your squares have distinct heights - perhaps another approach should be used.

duringtraversal, so that a square that the path has already passed over may change height during traversal? it's not clear to me that the second case is useful/important, as it is only different from the first for a path that "goes backwards" at some point (i think), but it seems like an important distinction to clarify. – andrew cooke May 24 '12 at 12:05