The fourth programming project involves writing a program that accepts information contained in a file about the class dependencies in a Java program and creates a directed graph from that information. From the directed graph, it produces two different kinds of displays of those dependency relationships.
CMSC 350 Project 4 The fourth programming project involves writing a program that accepts information contained in a file about the class dependencies in a Java program and creates a directed graph from that information. From the directed graph, it produces two different kinds of displays of those dependency relationships. A sample input file is shown below: ClassA ClassC ClassE ClassJ ClassB ClassD ClassG ClassC ClassA ClassE ClassB ClassF ClassH ClassJ ClassB ClassI ClassC The first name of each line of the file is a Java class upon which other classes depend. The remaining names are the classes that depend upon the first class on that line. The first line of the above file, for example, indicates that ClassA has three classes that depend upon it, ClassC, ClassE and ClassJ. A class that have does any classes that depend on it, need not appear at the head of any line. The main method in the class for this project should allow user select the input file from the default directory by using the JFileChooser class. It should then add the edges to a directed graph that defines these class dependencies. A second class, DirectedGraph, should be a generic class, whose generic parameter specifies the type of the labels that are associated with the vertices of the graph. The internal representation of the graph should be the alternate adjacency list representation illustrated in Figure 10.7 of our textbook Object-Oriented Data Structures Using Java. Unlike that graph, however, this graph will not be a weighted graph. It should contain a method that allows edges to be added to the graph, which is how the main method will initially build the graph. It should also contain a method that performs a depth-first search of that graph. The pseudocode for that search is show below: depth_first_search(vertex s) if s is discovered perform cycle detected action return perform add vertex action mark s as discovered perform descend action for all adjacent vertices v depth_first_search(v) perform ascend action mark s as finished When the method in the DirectedGraph class that initiates the depth first search is called, it should first initialize all the vertices to the undiscovered state and begin the search at the vertex that corresponds to the first name in the input file. Another method in the DirectedGraph class should then allow the main method to display any unreachable classes by examining all the vertices of the graph to see which remain undiscovered. This project should contain a generic interface named DFSActions, whose generic parameter again specifies the type of the labels that are associated with the vertices of the graph. It should contain four method signatures that correspond to the four actions performed in the depth first search: cycle detected, process vertex, descend and ascend. There should be two additional classes that both implement the aforementioned interface. The first, Hierarchy, should produce a hierarchical representation of the class dependencies. Circular dependencies should be flagged. For the above input file, the following hierarchical representation should be produced: ClassA ClassC * ClassE ClassB ClassD ClassG ClassF ClassH ClassJ ClassB ClassD ClassG The asterisk after ClassC results from the fact that ClassC depends upon ClassA and ClassA depends upon ClassC. The Hierarchy class should override the toString method, which should return a string that contains the above, after having performed the depth-first search. The other class that implements the DFSActions interface should be ParenthesizedList. It should produce an alternate representation that is also returned by its toString method. For the above input file, the following hierarchical representation should be produced: ( ClassA ( ClassC * ClassE ( ClassB ( ClassD ClassG ) ClassF ClassH ) ClassJ ( ClassB ( ClassD ClassG )))) The main method should produce both representations. In addition it should display the unreachable classes by calling the previously mentioned method. For the above input file, the following unreachable class should be identified: ClassI is unreachable Code duplication should be avoided. In particular, the depth first code should not be duplicated. You are to submit two files. 1. The first is a .zip file that contains all the source code for the project. The .zip file should contain only source code and nothing else, which means only the .java files. If you elect to use a package the .java files should be in a folder whose name is the package name. Every outer class should be in a separate .java file with the same name as the class name. Each file should include a comment block at the top containing your name, the project name, the date, and a short description of the class contained in that file. 2. The second is a Word document (PDF or RTF is also acceptable) that contains the documentation for the project, which should include the following: a. A UML class diagram that includes all classes you wrote. Do not include predefined classes. You need only include the class name for each individual class, not the variables or methods b. A test plan that includes test cases that you have created indicating what aspects of the program each one is testing c. A short paragraph on lessons learned from the project Grading Rubric Criteria Meets Does Not Meet Design 20 points 0 points Includes a generic DirectedGraph class that represents the graph with the alternate adjacency list representation (6) Does not include a generic DirectedGraph class or does not represents the graph with the alternate adjacency list representation (0) Includes a generic class DFSActions that contains methods for four actions performed in the depth first search (4) Does not include a generic class DFSActions that contains methods for four actions performed in the depth first search (0) Includes required two class that implement the DFSActions interface (5) Does not include required two class that implement the DFSActions interface (0) Avoids duplication of the depth-first search code (5) Does not avoid duplication of the depth-first search code (0) Functionality 60 points 0 points Reads in file and produces graph representation as specified (10) Does not read in file or does not produce graph representation as specified (0) Displays correct hierarchical representation of class hierarchy (15) Does not display correct hierarchical representation of class hierarchy (0) Displays correct parenthesized representation of class hierarchy (15) Does not display correct parenthesized representation of class hierarchy (0) Correctly annotates circular dependencies (10) Does not correctly annotate circular dependencies (0) Correctly lists unreachable classes (10) Does not correctly list unreachable classes (0) Test Plan 10 points 0 points Test cases include a graph with circular dependencies (3) Test cases do not include a graph with circular dependencies (0) Test cases include a graph with no circular dependencies (2) Test cases do not include a graph with no circular dependencies (0) Test cases include a graph with unreachable classes (3) Test cases do not include a graph with unreachable classes (0) Test cases include a graph with no unreachable classes (2) Test cases do not include a graph with no unreachable classes (0) Documentation 10 points 0 points Correct UML diagram included (3) Correct UML diagram not included (0) Lessons learned included (4) Lessons learned not included (0) Comment blocks included with each Java file (3) Comment blocks not included with each Java file(0)