It is well known that computing a spanning tree that has the minimum possible number of leaves is NP complete. But I cannot figure out a polynomial time reduction of this problem to the hamiltonian path problem.

My exponential reduction:

```
if(hamiltonian path exists for whole graph)
min leaves = 1;
return;
else
for each vertex of the graph
if(hamiltonian path exists for this graph after removing the vertex and its incident edges)
min leaves = 2;
return;
continue similarly for the graph deleting 2 vertices, 3 vertices, 4vertices,... until you get a minimum spanning tree with some minimum number of leaves.
```

So, in the worst case, this algorithm will make a total of

```
(N choose 1) + (N choose 2) + (N choose 3) + ....(N choose N) = 2^N
```

calls to the hamiltonian path problem . Hence reduction is exponential.

Please suggest a polynomial time reduction for this problem.

`computing a spanning tree that has the minimum possible number of trees`

--> Hah? – nhahtdh Feb 10 '13 at 5:00