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CompSci 4 3.1 Data Types & Operations. CompSci 4 3.2 The Plan  Overview  Data Types  Operations  Code Samples  ChangeMaker.java  PolarCoordinate.java.

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Presentation on theme: "CompSci 4 3.1 Data Types & Operations. CompSci 4 3.2 The Plan  Overview  Data Types  Operations  Code Samples  ChangeMaker.java  PolarCoordinate.java."— Presentation transcript:

1 CompSci 4 3.1 Data Types & Operations

2 CompSci 4 3.2 The Plan  Overview  Data Types  Operations  Code Samples  ChangeMaker.java  PolarCoordinate.java

3 CompSci 4 3.3 Overview  Data type – structure of information  Existing/User-defined o Existing include int, String, double, boolean, Rectangle o User defined are user written classes whose variables and methods describe the structure  Primitives/Reference o Primitives store only a single value (and no methods) o References can store many values and methods

4 CompSci 4 3.4 Data Types  Primitives  double – real numbers  int – integers  boolean – true or false  char – single letter, number, space, or punctuation  long – larger range of integers  float – smaller precision real numbers  References (Objects)  String – in java.lang  Rectangle – in java.awt  Greeter – in Horstmann  Purse – in Horstmann  ChangeMaker – going over this today  PolarCoordinate – going over this today

5 CompSci 4 3.5 Operations  Operators  Most are binary (having two operands)  Some are unary (having one operand)  compute a value  Methods  static (do not require an instance, also known as class methods )  instance  may or may not compute a value (non-void or void)  can have zero or more parameters

6 CompSci 4 3.6 Operations  Operators  + add  - subtract/negate  / divide  * multiply  % mod (remainder)  = assignment  == equivalence  Methods  Static o Math.sin – sine o Math.cos – cosine o Math.abs – absolute value  Instance o sayHello of Greeter o getDollars of ChangeMaker o getMagnitude of PolarCoordinate o equals of PolarCoordinate

7 CompSci 4 3.7 ChangeMaker Converts dollars and cents to actual bills and coins. Example: $37.43 can be 1 $20 bill 1 $10 bill 1 $5 bill 2 $1 bills 1 quarter 1 dime 1 nickel 3 pennies

8 CompSci 4 3.8 ChangeMaker.java public class ChangeMaker { int dollars; int cents; public ChangeMaker() { this(0, 0); } public ChangeMaker(int d, int c) { dollars = d; cents = c; } Constructors initialize the instance variables dollars and cents Assignment operators int means integer valued (no fractional parts)

9 CompSci 4 3.9 ChangeMaker.java public class ChangeMaker { int dollars; int cents; public ChangeMaker() { this(0, 0); } public ChangeMaker(int d, int c) { dollars=d; cents=c; } Calls the second constructor from the first.

10 CompSci 4 3.10 ChangeMaker.java public void addCents(int c) { cents = cents + c; dollars = dollars + cents / 100; cents = cents % 100; } public void addDollars(int d) { dollars = dollars + d; } Mutator methods modify instance variables

11 CompSci 4 3.11 ChangeMaker.java public void addCents(int c) { cents = cents + c; dollars = dollars + cents / 100; cents = cents % 100; } public void addDollars(int d) { dollars = dollars + d; } + adds / does division In this case integer division because cents is an integer and 100 is an integer Order of operations gives / precedence over + Integer division truncates – by dropping the fractional part. 120/100 is 1 not 1.2

12 CompSci 4 3.12 ChangeMaker.java public int getDollars() { return dollars; } public int getCents() { return cents; } Accessor methods give access to the instance variables

13 CompSci 4 3.13 ChangeMaker.java public int get20s() { return dollars / 20; } public int get10s() { return (dollars % 20) / 10; } Integer division because dollars and 20 are both integers. Integer division truncates – by dropping the fractional part. 50/20 is 2 not 2.5

14 CompSci 4 3.14 ChangeMaker.java public int get20s() { return dollars/20; } public int get10s() { return (dollars % 20) / 10; } % gets the remainder after integer division. For example 50%20 is 10 7%5 is 2 5%7 is 5 Parenthesis may be used to indicate the desired order of computation.

15 CompSci 4 3.15 ChangeMaker.java public int get20s() { return dollars/20; } public int get10s() { return (dollars%20)/10; } If dollars is 50, what is 50%20? What is (50%20)/10? How many $10 bills are needed when trying to give $50 in the largest denominations possible? (with $20 bills the largest)

16 CompSci 4 3.16 ChangeMaker.java public int get5s() { return (dollars % 10) / 5; } public int get1s() { return dollars % 5; } If dollars is 50, what is The result of calling get5s()? If dollars is 37 what is The result of calling get5s()? Do the get5s() and get1s() instance methods compute the correct answer? Why?

17 CompSci 4 3.17 ChangeMaker.java public String toString() { if(cents < 10) return "$" + dollars + ".0" + cents; else return "$" + dollars + "." + cents; } The toString() instance method converts instance variable values into a meaningful String. For example, if dollars is 5 and cents is 14 the toString() Method returns the String “$5.14”.

18 CompSci 4 3.18 ChangeMaker.java public String toString() { if(cents < 10) return "$" + dollars + ".0" + cents; else return "$" + dollars + "." + cents; } Why does computing the return value of the toString() method depend on the value of cents?

19 CompSci 4 3.19 ChangeMaker.java public static void main(String[] argv) { ChangeMaker money=new ChangeMaker(37, 43); System.out.println(money + " has:"); System.out.println(money.get20s() + " 20 dollar bills"); System.out.println(money.get10s() + " 10 dollar bills"); System.out.println(money.get5s() + " 5 dollar bills"); System.out.println(money.get1s() + " 1 dollar bills"); System.out.println(money.getQuarters() + " quarters"); System.out.println(money.getDimes() + " dimes"); System.out.println(money.getNickels() + " nickels"); System.out.println(money.getPennies() + " pennies"); } Driver for testing the ChangeMaker class

20 CompSci 4 3.20 ChangeMaker.java public static void main(String[] argv) { ChangeMaker money=new ChangeMaker(37, 43); System.out.println(money + " has:"); System.out.println(money.get20s() + " 20 dollar bills"); System.out.println(money.get10s() + " 10 dollar bills"); System.out.println(money.get5s() + " 5 dollar bills"); System.out.println(money.get1s() + " 1 dollar bills"); System.out.println(money.getQuarters() + " quarters"); System.out.println(money.getDimes() + " dimes"); System.out.println(money.getNickels() + " nickels"); System.out.println(money.getPennies() + " pennies"); } Calls the constructor. public ChangeMaker(int d, int c) { dollars = d; cents = c; }

21 CompSci 4 3.21 ChangeMaker.java public static void main(String[] argv) { ChangeMaker money=new ChangeMaker(37, 43); System.out.println(money + " has:"); System.out.println(money.get20s() + " 20 dollar bills"); System.out.println(money.get10s() + " 10 dollar bills"); System.out.println(money.get5s() + " 5 dollar bills"); System.out.println(money.get1s() + " 1 dollar bills"); System.out.println(money.getQuarters() + " quarters"); System.out.println(money.getDimes() + " dimes"); System.out.println(money.getNickels() + " nickels"); System.out.println(money.getPennies() + " pennies"); } Automatically calls the toString() method public String toString() { if(cents<10) return "$"+dollars+".0"+cents; else return "$"+dollars+"."+cents; }

22 CompSci 4 3.22 ChangeMaker.java public static void main(String[] argv) { ChangeMaker money=new ChangeMaker(37, 43); System.out.println(money + " has:"); System.out.println(money.get20s() + " 20 dollar bills"); System.out.println(money.get10s() + " 10 dollar bills"); System.out.println(money.get5s() + " 5 dollar bills"); System.out.println(money.get1s() + " 1 dollar bills"); System.out.println(money.getQuarters() + " quarters"); System.out.println(money.getDimes() + " dimes"); System.out.println(money.getNickels() + " nickels"); System.out.println(money.getPennies() + " pennies"); } calls the get20s() method public int get20s() { return dollars/20; }

23 CompSci 4 3.23 ChangeMaker.java public static void main(String[] argv) { ChangeMaker money=new ChangeMaker(37, 43); System.out.println(money + " has:"); System.out.println(money.get20s() + " 20 dollar bills"); System.out.println(money.get10s() + " 10 dollar bills"); System.out.println(money.get5s() + " 5 dollar bills"); System.out.println(money.get1s() + " 1 dollar bills"); System.out.println(money.getQuarters() + " quarters"); System.out.println(money.getDimes() + " dimes"); System.out.println(money.getNickels() + " nickels"); System.out.println(money.getPennies() + " pennies"); } main outputs: $37.43 has: 1 20 dollar bills 1 10 dollar bills 1 5 dollar bills 2 1 dollar bills 1 quarters 1 dimes 1 nickels 3 pennies

24 CompSci 4 3.24 PolarCoordinate Rectangular coordinates are broken down into horizontal and vertical components pairs, or just (x, y) Polar coordinates are broken down into magnitude and angle from the origin or (r, theta) The conversion exists (r, theta) in polar is equivalent to (r cosine(theta), r sine(theta)) Sometimes polar coordinates are easier to deal with, especially when doing rotations. PolarCoordinate.java provides routines for converting between polar and cartesian coordinates

25 CompSci 4 3.25 PolarCoordinate.java import java.awt.*; import java.awt.geom.*; public class PolarCoordinate { private static final double EPSILON = 1e-10; private double magnitude; private double angle; static final is used to denote constants Note the all capitals Shorthand for scientific notation 1x10 -10

26 CompSci 4 3.26 PolarCoordinate.java public PolarCoordinate() { this(0, 0); } public PolarCoordinate(double pm, double pa) { setMagnitude(pm); setAngle(pa); } Constructors can call instance methods

27 CompSci 4 3.27 PolarCoordinate.java public Point getPoint() { int x=(int)(magnitude*Math.cos(angle)); int y=(int)(magnitude*Math.sin(angle)); return new Point(x, y); } public Point2D.Double getPoint2D() { double x=magnitude*Math.cos(angle); double y=magnitude*Math.sin(angle); return new Point2D.Double(x, y); } Static methods of the Math class Casting the results which are doubles into ints which truncates

28 CompSci 4 3.28 PolarCoordinate.java public double getMagnitude() { return magnitude; } public double getAngle() { return angle; } public void setMagnitude(double pm) { magnitude=pm; } public void setAngle(double pa) { angle=pa; } Which are accessor methods? Which are mutator methods?

29 CompSci 4 3.29 PolarCoordinate.java public boolean equals(Object object) { if(object instanceof PolarCoordinate) { PolarCoordinate polar=(PolarCoordinate)object; if(Math.abs(polar.angle-angle)<EPSILON && Math.abs(polar.magnitude-magnitude)<EPSILON) { return true; } else { return false; } else { return false; } Focus on this part of the code Boolean means true or false

30 CompSci 4 3.30 PolarCoordinate.java if(Math.abs(polar.angle-angle)<EPSILON && Math.abs(polar.magnitude-magnitude)<EPSILON) { return true; } else { return false; } Floating point arithmetic incurs small errors which can cause two numbers which would theoretically be the same to be slightly different. If comparing floating point numbers for equivalence, check to see if they are roughly the same rather than exactly equal.

31 CompSci 4 3.31 PolarCoordinate.java if(Math.abs(polar.angle-angle)<EPSILON && Math.abs(polar.magnitude-magnitude)<EPSILON) { return true; } else { return false; } abs is for absolute value Why is the absolute difference needed? All arguments are computed before Calling the method.

32 CompSci 4 3.32 PolarCoordinate.java if(Math.abs(polar.angle-angle)<EPSILON && Math.abs(polar.magnitude-magnitude)<EPSILON) { return true; } else { return false; } Each PolarCoordinate object has its own angle and magnitude. If there is no object name before an instance variable, the assumed object is this (which means the current object). more explanation about this later.

33 CompSci 4 3.33 PolarCoordinate.java public static double convertToDegrees(double radians) { return radians * 180 / Math.PI; } public static double convertToRadians(double degrees) { return degrees * Math.PI / 180; } static methods do not access or modify any instance variables Notice angle and magnitude are not used in these methods.

34 CompSci 4 3.34 PolarCoordinate.java public static double convertToDegrees(double radians) { return radians * 180 / Math.PI; } public static double convertToRadians(double degrees) { return degrees * Math.PI / 180; } / does floating point division because Math.PI is a double precision floating point number (so are radians and degrees) Floating point division retains the fractional part of the division

35 CompSci 4 3.35 PolarCoordinate.java public static void main(String[] argv) { PolarCoordinate one=new PolarCoordinate(5, Math.PI/2); System.out.println(one+" is "+one.getPoint2D()); PolarCoordinate two=new PolarCoordinate(); two.setCartesian(0, 5); System.out.println(two+" is "+two.getPoint2D()); Driver for PolarCoordinate.java (continued on next slide)

36 CompSci 4 3.36 PolarCoordinate.java if(one==two) { System.out.println("one and two reference the same object"); } else { System.out.println("one and two reference different objects"); } if(one.equals(two)) { System.out.println("one and two have the same contents"); } else { System.out.println("one and two have different contents"); } With Objects, == is true if the two sides reference the same Object With Objects, the equals method checks the Contents of the objects for equality

37 CompSci 4 3.37 Summary  Data types  Primitives  References  Operations  Operators  Methods

38 CompSci 4 3.38 Reminders  Should have read Chapters 1-3 of Horstmann  Homework 1 due on Tuesday

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