programming-examples/java/Data_Structures/Arbitrage.java

 

import edu.princeton.cs.introcs.StdIn;
import edu.princeton.cs.introcs.StdOut;

/*************************************************************************
 *  Compilation:  javac Arbitrage.java
 *  Execution:    java Arbitrage < input.txt
 *  Dependencies: EdgeWeightedDigraph.java DirectedEdge.java
 *                BellmanFordSP.java
 *  Data file:    http://algs4.cs.princeton.edu/44sp/rates.txt
 *
 *  Arbitrage detection.
 *
 *  % more rates.txt
 *  5
 *  USD 1      0.741  0.657  1.061  1.005
 *  EUR 1.349  1      0.888  1.433  1.366
 *  GBP 1.521  1.126  1      1.614  1.538
 *  CHF 0.942  0.698  0.619  1      0.953
 *  CAD 0.995  0.732  0.650  1.049  1
 *
 *  % java Arbitrage < rates.txt
 *  1000.00000 USD =  741.00000 EUR
 *   741.00000 EUR = 1012.20600 CAD
 *  1012.20600 CAD = 1007.14497 USD
 *
 *************************************************************************/

/**
 *  The  Arbitrage  class provides a client that finds an arbitrage
 *  opportunity in a currency exchange table by constructing a
 *  complete-digraph representation of the exchange table and then finding
 *  a negative cycle in the digraph.
 *   
 *  This implementation uses the Bellman-Ford algorithm to find a
 *  negative cycle in the complete digraph.
 *  The running time is proportional to  V <sup>3</sup> in the
 *  worst case, where  V  is the number of currencies.
 *   
 *  For additional documentation,
 *  see <a href="http://algs4.cs.princeton.edu/44sp">Section 4.4</a> of
 *   Algorithms, 4th Edition  by Robert Sedgewick and Kevin Wayne.
 *
 *  @author Robert Sedgewick
 *  @author Kevin Wayne
 */
public class Arbitrage {

    // this class cannot be instantiated
    private Arbitrage() { }

    /**
     *  Reads the currency exchange table from standard input and
     *  prints an arbitrage opportunity to standard output (if one exists).
     */
    public static void main(String[] args) {

        // V currencies
        int V = StdIn.readInt();
        String[] name = new String[V];

        // create complete network
        EdgeWeightedDigraph G = new EdgeWeightedDigraph(V);
        for (int v = 0; v < V; v++) {
            name[v] = StdIn.readString();
            for (int w = 0; w < V; w++) {
                double rate = StdIn.readDouble();
                DirectedEdge e = new DirectedEdge(v, w, -Math.log(rate));
                G.addEdge(e);
            }
        }

        // find negative cycle
        BellmanFordSP spt = new BellmanFordSP(G, 0);
        if (spt.hasNegativeCycle()) {
            double stake = 1000.0;
            for (DirectedEdge e : spt.negativeCycle()) {
                StdOut.printf("%10.5f %s ", stake, name[e.from()]);
                stake *= Math.exp(-e.weight());
                StdOut.printf("= %10.5f %s\n", stake, name[e.to()]);
            }
        }
        else {
            StdOut.println("No arbitrage opportunity");
        }
    }

}
Initial commit 5 years ago

			`import edu.princeton.cs.introcs.StdIn;`
			`import edu.princeton.cs.introcs.StdOut;`

			`/*************************************************************************`
			`* Compilation: javac Arbitrage.java`
			`* Execution: java Arbitrage < input.txt`
			`* Dependencies: EdgeWeightedDigraph.java DirectedEdge.java`
			`* BellmanFordSP.java`
			`* Data file: http://algs4.cs.princeton.edu/44sp/rates.txt`
			`*`
			`* Arbitrage detection.`
			`*`
			`* % more rates.txt`
			`* 5`
			`* USD 1 0.741 0.657 1.061 1.005`
			`* EUR 1.349 1 0.888 1.433 1.366`
			`* GBP 1.521 1.126 1 1.614 1.538`
			`* CHF 0.942 0.698 0.619 1 0.953`
			`* CAD 0.995 0.732 0.650 1.049 1`
			`*`
			`* % java Arbitrage < rates.txt`
			`* 1000.00000 USD = 741.00000 EUR`
			`* 741.00000 EUR = 1012.20600 CAD`
			`* 1012.20600 CAD = 1007.14497 USD`
			`*`
			`*************************************************************************/`

			`/**`
			`* The Arbitrage class provides a client that finds an arbitrage`
			`* opportunity in a currency exchange table by constructing a`
			`* complete-digraph representation of the exchange table and then finding`
			`* a negative cycle in the digraph.`
			`*`
			`* This implementation uses the Bellman-Ford algorithm to find a`
			`* negative cycle in the complete digraph.`
			`* The running time is proportional to V <sup>3</sup> in the`
			`* worst case, where V is the number of currencies.`
			`*`
			`* For additional documentation,`
			`* see <a href="http://algs4.cs.princeton.edu/44sp">Section 4.4</a> of`
			`* Algorithms, 4th Edition by Robert Sedgewick and Kevin Wayne.`
			`*`
			`* @author Robert Sedgewick`
			`* @author Kevin Wayne`
			`*/`
			`public class Arbitrage {`

			`// this class cannot be instantiated`
			`private Arbitrage() { }`

			`/**`
			`* Reads the currency exchange table from standard input and`
			`* prints an arbitrage opportunity to standard output (if one exists).`
			`*/`
			`public static void main(String[] args) {`

			`// V currencies`
			`int V = StdIn.readInt();`
			`String[] name = new String[V];`

			`// create complete network`
			`EdgeWeightedDigraph G = new EdgeWeightedDigraph(V);`
			`for (int v = 0; v < V; v++) {`
			`name[v] = StdIn.readString();`
			`for (int w = 0; w < V; w++) {`
			`double rate = StdIn.readDouble();`
			`DirectedEdge e = new DirectedEdge(v, w, -Math.log(rate));`
			`G.addEdge(e);`
			`}`
			`}`

			`// find negative cycle`
			`BellmanFordSP spt = new BellmanFordSP(G, 0);`
			`if (spt.hasNegativeCycle()) {`
			`double stake = 1000.0;`
			`for (DirectedEdge e : spt.negativeCycle()) {`
			`StdOut.printf("%10.5f %s ", stake, name[e.from()]);`
			`stake *= Math.exp(-e.weight());`
			`StdOut.printf("= %10.5f %s\n", stake, name[e.to()]);`
			`}`
			`}`
			`else {`
			`StdOut.println("No arbitrage opportunity");`
			`}`
			`}`

			`}`