Consider the A* algorithm.
In Google it is possible to find a good pseudo-code:
function A*(start,goal) closedset := the empty set // The set of nodes already evaluated. openset := set containing the initial node // The set of tentative nodes to be evaluated. came_from := the empty map // The map of navigated nodes. g_score[start] := 0 // Distance from start along optimal path. h_score[start] := heuristic_estimate_of_distance(start, goal) f_score[start] := h_score[start] // Estimated total distance from start to goal through y. while openset is not empty x := the node in openset having the lowest f_score value if x = goal return reconstruct_path(came_from, came_from[goal]) remove x from openset add x to closedset foreach y in neighbor_nodes(x) if y in closedset continue tentative_g_score := g_score[x] + dist_between(x,y) if y not in openset add y to openset tentative_is_better := true elseif tentative_g_score < g_score[y] tentative_is_better := true else tentative_is_better := false if tentative_is_better = true came_from[y] := x g_score[y] := tentative_g_score h_score[y] := heuristic_estimate_of_distance(y, goal) f_score[y] := g_score[y] + h_score[y] Update(closedset,y) Update(openset,y) return failure function reconstruct_path(came_from, current_node) if came_from[current_node] is set p = reconstruct_path(came_from, came_from[current_node]) return (p + current_node) else return current_node
Well there is one thing I do not understand: Consider to have the situation in the picture:
How is A* able to change from a->b->c to a->d... ??? Well I mean, A* starts from a node and navigates through nodes. At a certain point a node have more than one neighbour, well, A* is able to follow a path generated by a neighbour, but at a certain point it is able to switch... and come back on its steps starting from a previou node and taking a different road EVEN if the abandoned path did't cross that one...
In the code, what's the condition that enables this envirinment?