I am working with the following exercise from my book:

Shortest path algorithms can be applied in currency trading. Let c1 , c2 , . . . , cn be various cur- rencies; for instance, c1 might be dollars, c2 pounds, and c3 lire. For any two currencies ci and cj , there is an exchange rate ri,j ; this means that you can purchase ri,j units of currency cj in exchange for one unit of ci . These exchange rates satisfy the condition that ri,j · rj,i < 1, so that if you start with a unit of currency ci , change it into currency cj and then convert back to currency ci , you end up with less than one unit of currency ci (the difference is the cost of the transaction). (a) Give an efficient algorithm for the following problem: Given a set of exchange rates r i,j , and two currencies s and t, find the most advantageous sequence of currency exchanges for converting currency s into currency t. Toward this goal, you should represent the currencies and rates by a graph whose edge lengths are real numbers.

So what basically we want to do is instead of minimizing, we need to maximize the profit. Therefore we need to find the longest path from s to t. We are asserted of the existence of a shortest path from s to t.

The way I thought to solve this problem is following this algorithm:

- Negate all the edges of the graph
- Run the shortest path algorithm for directed acyclic graphs.

I believe this would work but I am not sure. On google I found some solutions that include another step: converting the multiplication of the rates to additions using logarithms. I think this step is not necessary her e but still I am not sure.