This is the question [From CLRS]:

Define the optimization problem LONGEST-PATH-LENGTH as the relation that associates each instance of an undirected graph and two vertices with the number of edges in a longest simple path between the two vertices. Define the decision problem LONGEST-PATH = {: G=(V,E) is an undirected graph, u,v contained in V, k >= 0 is an integer, and there exists a simple path from u to v in G consisting of at least k edges}. Show that the optimization problem LONGEST-PATH-LENGTH can be solved in polynomial time if and only if LONGEST-PATH is contained in P.

My solution: Given an algorith A, that can solve G(u,v) in polytime, so we run the A on G(u,v) if it returns 'YES" and k' such that k' is the longest path in G(u,v), now all we have to do it compare if

```
k =< k'
```

if then the longest path length is solved. If we recieve "NO" or k>=k', then there exists no solution.

so polytime to run A + constant for comparsion, then to find the longest path length it takes poly time. Also this is only possible since G(u,v) runs in Polytime (in P), thus G(u,v,k) runs also in polytime (in P), therefore since longest path can be reduced to longest-path-length, then longest-path-length is in P.

we can solve it the oposite way, what we do is, run G(u,v,k') for k'=0 to n, every time check if the k==k', is so we solved it. run time analysis for this: n*polytime+ n*(constant comparsion)=polytime

Can someone tell me if my answer is reasonable? if not please tell me where i've gone wrong

Also can you give me some advice to how to study algorithms ,and what approch i should take to solve a algorith question (or a graph question)

please and thankyou