I need help with java programming homework. I've attached the requirements.
Building a Binary Search Tree & more 1 Objective Build a Java program that will support the creation of a Binary Search Tree, hereinafter referred to as a BST. This program will support reading a command file that supports insertion, deletion, searching, printing, and subtree children and depth counts. All output will be to either STDOUT or STDERR. 2 Requirements 1. Read the input file formatted as follows. The input file will contain at least one command per line, either insert, delete, search, print, or quit. These are defined in detail below. For example, one of the input files, named in5.txt contains the following: 2. The specific commands are i for insert, d for delete, s for search, p for print, and q for quit. 1. (a) Insert The insert command uses the single character i as the command token. The command token will be followed by a single space then an integer. (This command’s success can be verified by using the print command.) • For insertion or realigning operations, less than goes left, equal to or greater than goes right. 2. (b) Delete The delete command uses the single character d as the command token. The command token will be followed by a single space, then an integer. In the event that the integer cannot be found, the program will issue an error message to STDOUT and recover gracefully to continue to accept commands from the input file. command-> d 100: integer 100 NOT found - NOT deleted (This command’s success can be verified by using the print command.) (c) Search The search command uses the single character s as the command token. The command token will be followed by a single space, then an integer. In the event that the integer cannot be located, the program will issue an error message to STDOUT and recover gracefully to continue to accept commands from the input file. command-> s 101: integer 101 NOT found 4. (d) Print The print command uses the single character p as the command token. This command will invoke the print function which will output the data in the tree inorder. This command is critical for verification of all the commands specified above. 5. (e) Quit The quit command uses the single character q as the command token. In the event the quit command is invoked, the program exits. There is no requirement for data persistence. 2.1 Functions While there are no specific design requirements (with one exception), it might be a mean- ingful suggestion to consider breaking this problem into several small classes. For example, a BST class and a Node class would seem to be the minimal set of classes. 2.1.1 Required Function(s) • complexityIndicator Prints to STDERR the following: · – NID · – A difficulty rating of how difficult this assignment was on a scale of 1.0 (easy- peasy) through 5.0 (knuckle busting degree of difficulty). · – Duration, in hours, of the time you spent on this assignment. · – Delimit each field with a semicolon as shown below. · – Sample output: ff210377@eustis:~/COP3503$ ff210377;3.5;18.5 • countChildren which will count all nodes on the left branch of the BST, and then the right branch. • getDepth which will provide the depth of the right and left branches of the BST. 2 · Java Library Support – The goal of this assignment is to build resources for BST. Therefore it is not acceptable to use the many resources built in to Java to streamline Tree manage- ment. For example it is not acceptable to use the java.util.TreeSet or similar libraries. 3 Testing There will be seven (7) input files and seven (7) output files provided for testing your code, they are respectively shown in Table 1 and in Table 2. Filename input01.txt in5.txt in10.txt in100.txt in100m50K.txt in10k-m50K.txt Description Insert 7 integers with 2 searches and a delete the prints the tree. Five integers inserted with no duplicates. Prints the tree. 10 integers inserted with no duplicates. Prints the tree. 100 integers inserted. Prints the tree 100 random integers (all modulo 50,000) in- serted with random deletes. 10,000 integers (all modulo 50,000) inserted with random deletes. The expected output for these test cases will also be provided as defined in Table 2. To compare your output to the expected output you will first need to redirect STDOUT to a text file. Run your code with the following command (substitute the actual names of the input and output file appropriately): java Hw01 inputFileName > inputFileNameSt.txt The run the following command (substitute the actual name of the expected input file name concatenated with either St for the student generated code or with Valid for the validation file: diff output.txt inputFileName St.txt inputFileNameValid.txt If there are any differences the relevant lines will be displayed (note that even a single extra space will cause a difference to be detected). If nothing is displayed, then congratulations - the outputs match! If your code crashes for a particular test case, you will not get credit for that case. 5 Sample output ff210377@eustis:~/COP3503$ java Hw01 in10.txt in10.txt contains: i 888 i 77 i 90 i 990 i 120 i 450 i 7900 i 7000 i 500 i 65 p q 65 77 90 120 450 500 888 990 7000 7900 left children: 6 left depth: 5 right children: 3 right depth: 3 ff210377;3.5;18.5 ff210377@eustis:~/COP3503$ java Hw01 >5in-myOutput.txt ff210377;3.5;18.5 ff210377@eustis:~/COP3503$ diff 5in-myOutput.txt 5in-expectedOutput.txt mi113345@eustis:~/COP3503$ Note The ff210377;3.5;18.5 output shown above is the output from the complexityIndi- cator function to STDERR.