This second assignment lets you practice basic concepts such as encapsulation and abstraction, inheritance, polymorphism, and exceptions.
In this assignment, you will be working with geometrical shapes such as: Circle, Square,Rectangle, Parallelogram, and Triangle. Use the following figure as a reference(you dont need to calculate shapes area for this assignment):
You will need to create geometrical shapes and calculate their perimeters. Therefore, you must develop java classes for all the geometrical shapes mentioned above (put all your classes in a package named shapes). Each class must be able to calculate the shapes perimeter. For each class, you must provide implementations for toString(), at least one constructor, setters/getters, and the documentations for the entire class.You should also provide an interface Shape as the root of the inheritance hierarchy, and design the appropriate is-a relationships among the above-mentioned classes.A text file named shapes.txt has been given to you. The file contains the definitions of some geometrical shapes. Each line might define a geometrical shape with the following format: name,x,y,z. The name is the shapes name and x,y,z are the values needed to define the shapes dimensions. The empty line signals the end of the file.
If a line is not properly formatted or it does not contain the necessary number of values to correctly describe a shape, your program must ignore that line. If you cannot build the geometrical shapes with the given values (ex. zero or negative values for dimensions, wrong values for three sides of a triangle, etc.), you should throw an exception. Therefore, there is a need to define some custom Exception classes for some of your classes. Your program must be capable of storing all the geometrical shapes read from the file in one data structure. Since arrays are the only data structure that we have covered so far, you must use just one array to contain all the shapes in this assignment. In future, while we cover collections in Java, you will figure out that other data structures could ease your programming tasks a lot!
Copy the shapes.txt file in the root folder of your Java project in Eclipse. We would cover exceptions in week 4 and File IO in week 5, but if you want to start ahead of time, you could use the following code snippet to read all the lines from the file. You could also consider using the split() method of class String to split each line to its composing items:try (BufferedReader br = new BufferedReader(new FileReader(fileName))) { while ((s = br.readLine()) != null) {String[] tokens = s.split(,);//your code}} catch (IOException e) {System.out.println(e.getMessage()); }Do the following tasks in different modules (methods) of the Main class of your project:
Task 1: Read the file Shapes.txt, create the shapes and store them in your data structure. Then print the number of shapes you created, and finally, print all the shapes and their calculated perimeters polymorphically. For the sample input file, sample output could be:
->JAC 444 Assignment 1<- ->Task 1 <-Invalid radius!Invalid side(s)! Invalid side!Invalid side(s)!
32 shapes were created:Circle {r=1.0} perimeter = 6.28319
Circle {r=2.111} perimeter = 13.2638
Circle {r=1.1} perimeter = 6.91150
Triangle {s1=3.0, s2=4.0, s3=5.0} perimeter = 12.0000
Triangle {s1=3.9, s2=4.0, s3=5.9} perimeter = 13.8000
Square {s=3.0} perimeter = 12.0000
Parallelogram {w=4.0, h=9.0} perimeter = 26.0000
Rectangle {w=3.0, h=5.1} perimeter = 16.2000
Square {s=5.0} perimeter = 20.0000
Parallelogram {w=3.9, h=9.2} perimeter = 26.2000
Triangle {s1=4.9, s2=5.0, s3=8.9} perimeter = 18.8000 Rectangle {w=8.0, h=2.1} perimeter = 20.2000
Circle {r=3.8} perimeter = 23.8761
Parallelogram {w=3.1, h=9.8} perimeter = 25.8000
Triangle {s1=3.1, s2=4.1, s3=5.1} perimeter = 12.3000Parallelogram {w=0.1, h=0.2} perimeter = 0.600000Triangle {s1=4.0, s2=5.0, s3=6.0} perimeter = 15.0000
Rectangle {w=3.1, h=5.2} perimeter = 16.6000
Circle {r=10.0} perimeter = 62.8319
Square {s=0.1} perimeter = 0.400000
Triangle {s1=3.1, s2=4.0, s3=5.0} perimeter = 12.1000
Circle {r=2.0} perimeter = 12.5664
Parallelogram {w=3.9, h=9.3} perimeter = 26.4000
Parallelogram {w=1.1, h=1.2} perimeter = 4.60000
Rectangle {w=3.0, h=5.2} perimeter = 16.4000
Square {s=100.1} perimeter = 400.400
Square {s=100.2} perimeter = 400.800
Circle {r=10.1} perimeter = 63.4602
Triangle {s1=3.0, s2=4.0, s3=5.0} perimeter = 12.0000
Triangle {s1=3.9, s2=4.8, s3=5.7} perimeter = 14.4000
Parallelogram {w=1.2, h=2.1} perimeter = 6.60000
Square {s=1.0E-5} perimeter = 4.00000e-05
Task 2: Delete the triangle with the minimum perimeter (there could be more than one minimum) and the circle with the maximum perimeter (there could be more than one maximum) from the shapes. Print the all the remaining shapes and their perimeters polymorphically. For the sample input file, sample output could be:
->Task 2 <-Circle {r=1.0} perimeter = 6.28319
Circle {r=2.111} perimeter = 13.2638
Circle {r=1.1} perimeter = 6.91150
Triangle {s1=3.9, s2=4.0, s3=5.9} perimeter = 13.8000 Square {s=3.0} perimeter = 12.0000
Parallelogram {w=4.0, h=9.0} perimeter = 26.0000
Rectangle {w=3.0, h=5.1} perimeter = 16.2000
Square {s=5.0} perimeter = 20.0000
Parallelogram {w=3.9, h=9.2} perimeter = 26.2000
Triangle {s1=4.9, s2=5.0, s3=8.9} perimeter = 18.8000
Rectangle {w=8.0, h=2.1} perimeter = 20.2000
Circle {r=3.8} perimeter = 23.8761
Parallelogram {w=3.1, h=9.8} perimeter = 25.8000
Triangle {s1=3.1, s2=4.1, s3=5.1} perimeter = 12.3000Parallelogram {w=0.1, h=0.2} perimeter = 0.600000Triangle {s1=4.0, s2=5.0, s3=6.0} perimeter = 15.0000
Rectangle {w=3.1, h=5.2} perimeter = 16.6000
Circle {r=10.0} perimeter = 62.8319
Square {s=0.1} perimeter = 0.400000
Triangle {s1=3.1, s2=4.0, s3=5.0} perimeter = 12.1000
Circle {r=2.0} perimeter = 12.5664
Parallelogram {w=3.9, h=9.3} perimeter = 26.4000
Parallelogram {w=1.1, h=1.2} perimeter = 4.60000
Rectangle {w=3.0, h=5.2} perimeter = 16.4000
Square {s=100.1} perimeter = 400.400
Square {s=100.2} perimeter = 400.800
Triangle {s1=3.9, s2=4.8, s3=5.7} perimeter = 14.4000
Parallelogram {w=1.2, h=2.1} perimeter = 6.60000
Square {s=1.0E-5} perimeter = 4.00000e-05
Task 3: Calculate and print the total perimeter of all parallelograms and the total perimeter of all triangles. For the sample input file, sample output could be:
->Task 3 <-Total perimeter of Parallelogram is: 116.19999999999999Total perimeter of Triangle is: 86.4
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