Model the problem as a graph:

- Nodes are numbers
- Your root node is 1
- Links between nodes are
`*5`

or `+3`

.

Then run Dijkstra's algorithm to get the shortest path. If you exhaust all links from nodes `<N`

without getting to `N`

then you can't generate `N`

. (Alternatively, use @obourgain's answer to decide in advance whether the problem can be solved, and only attempt to work out how to solve the problem if it *can* be solved.)

So essentially, you enqueue the node (1, null path). You need a dictionary storing {node(i.e. number) => best path found so far for that node}. Then, so long as the queue isn't empty, in each pass of the loop you

- Dequeue the head (node,path) from the queue.
- If the number of this node is
`>N`

, or you've already seen this node before with fewer steps in the path, then don't do any more on this pass.
- Add (node => path) to the dictionary.
- Enqueue nodes reachable from this node with
`*5`

and `+3`

(together with the paths that get you to those nodes)

When the loop terminates, look up `N`

in the dictionary to get the path, or output "Can't generate it".

*Edit*: note, this is really Breadth-first search rather than Dijkstra's algorithm, as the cost of traversing a link is fixed at 1.