There is a straightforward way to solve this:

- Run Dijkstra's for
`V - H`

, i.e. all nodes except those in `H`

. Let the output be `dist`

.
- For every node
`i`

in `H`

, the shortest path will be of length `min {dist[j] + w[i][j]}`

, where `min`

is applied across nodes `j`

in `V-H`

(can be made efficient if we have an adjacency list instead of matrix).

So basically, with Dijkstra, find the shortest paths to nodes *not* in `H`

. Then, the shortest path to nodes in `H`

is simply the shortest extension from a node in `V-H`

to itself. (And for nodes in `H`

that are not directly connected to `V-H`

, they'd have ∞ as question states).

Noticed per @jrook's comment that you mentioned all edges are of same length. Then BFS can be used instead of Dijkstra's as well.

Another solution is running BFS on a modified version of the graph:

- Remove all edges within nodes in
`H`

among themselves.
- Make the edges between nodes in
`V-H`

and `H`

directed, with the direction being from `V-H`

to `H`

.
- Make all other edges (i.e. those between nodes in
`V-H`

) directed by adding a directed edge in both directions.

In this modified and directed graph, you can apply BFS or Dijkstra to find the shortest paths of desired condition.