I'm trying to implement the D*-Lite pathfinding algorithm, as described in the 2002 article by Koenig and Likhachev, for Boost::Graph. I think I've gotten a decent grasp on the basic ideas and theory behind it, but I'm having a problem understanding when the `Pred`

and `Succ`

sets are updated.

I'm guessing it happens in the `Move to sstart`

step in `Main`

, but then the first call to `ComputeShortestPath`

will be rather pointless? And is the `Succ`

set supposed to be inserted into at the same time as `Pred`

only? Then `Pred`

and `Succ`

could be implented as doubly linked lists?

I've inserted the pseudocode of the algorithm below. The `Pred`

and `Succ`

sets are predecessors and successors respectivly. `g`

, `h`

, `rhs`

and `c`

are different costs and weights. `U`

is a priority queue of vertices to visit.

```
procedure CalculateKey(s)
{01’} return [min(g(s), rhs(s)) + h(sstart, s) + km; min(g(s), rhs(s))];
procedure Initialize()
{02’} U = ∅;
{03’} km = 0;
{04’} for all s ∈ S rhs(s) = g(s) = ∞;
{05’} rhs(sgoal) = 0;
{06’} U.Insert(sgoal, CalculateKey(sgoal));
procedure UpdateVertex(u)
{07’} if (u ≠ sgoal) rhs(u) = min s'∈Succ(u)(c(u, s') + g(s'));
{08’} if (u ∈ U) U.Remove(u);
{09’} if (g(u) ≠ rhs(u)) U.Insert(u, CalculateKey(u));
procedure ComputeShortestPath()
{10’} while (U.TopKey() < CalculateKey(sstart) OR rhs(sstart) ≠ g(sstart))
{11’} kold = U.TopKey();
{12’} u = U.Pop();
{13’} if (kold ˙<CalculateKey(u))
{14’} U.Insert(u, CalculateKey(u));
{15’} else if (g(u) > rhs(u))
{16’} g(u) = rhs(u);
{17’} for all s ∈ Pred(u) UpdateVertex(s);
{18’} else
{19’} g(u) = ∞;
{20’} for all s ∈ Pred(u) ∪ {u} UpdateVertex(s);
procedure Main()
{21’} slast = sstart;
{22’} Initialize();
{23’} ComputeShortestPath();
{24’} while (sstart ≠ sgoal)
{25’} /* if (g(sstart) = ∞) then there is no known path */
{26’} sstart = argmin s'∈Succ(sstart)(c(sstart, s') + g(s'));
{27’} Move to sstart;
{28’} Scan graph for changed edge costs;
{29’} if any edge costs changed
{30’} km = km + h(slast, sstart);
{31’} slast = sstart;
{32’} for all directed edges (u, v) with changed edge costs
{33’} Update the edge cost c(u, v);
{34’} UpdateVertex(u);
{35’} ComputeShortestPath();
```