CS 2113 Software Engineering - Spring 2025 | CS 2113 Software Engineering.

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Object Oriented Programming #

There is one overarching idea in programming — from small programs, to gigantic systems: Separation of Interface from Implementation i.e. separating what you need to know in order to use a tool from how the tool actually works on the inside. This is behind good coding, it’s behind good system design, it is behind the design of protocols like TCP, HTTP and DNS, it’s behind almost anything that involves computing! This separation allows us to manage the complexity of building big programs. It allows us to reuse in a new program code that was written in some other time and place for some other purpose (and to avoid duplicating code within a program, which is wasteful and leads to errors!). It allows us to make changes to some of our code without having to worry about other parts of the program breaking. It makes collaboration easier and less error-prone. It brings many, many other benefits. In short: separating interface from implementation is a really good thing.

Java Objects #

Java objects are a way to group related data together into a single structure. A Java object also allows you to associate methods (both public and private) with that object to operate over the data.

To review this functionality, let’s build up a working example of defining shapes and lines in the Cartesian plane. Recall that this the x, y coordinate system. For example, perhaps we have three points in the plane.

    y
    ^   p0
    |    * (2.3, 4.8)
    |p1
    | * (1.1, 3.0)
    |          
    |        p2 * (5.8, 0.3)
<---+---------------> x
    |
    v

If we wanted to define these points and some operations over them, say the distances between them, we could write the following program:

public class PointDistances {

    public static void main(String args[]) {
        
        //                  p0   p1   p2
        double Xpoints[] = {2.3, 1.1, 5.8};
        double Ypoints[] = {4.8, 3.0, 0.3};

        System.out.println("dist(p0, p1) = " +
                           Math.sqrt(Math.pow(Xpoints[0] - Xpoints[1], 2) +
                                     Math.pow(Ypoints[0] - Ypoints[1], 2))
                           );
        System.out.println("dist(p0, p2) = " +
                           Math.sqrt(Math.pow(Xpoints[0] - Xpoints[2], 2) +
                                     Math.pow(Ypoints[0] - Ypoints[2], 2))
                           );
        System.out.println("dist(p0, p1) = " +
                           Math.sqrt(Math.pow(Xpoints[1] - Xpoints[2], 2) +
                                     Math.pow(Ypoints[1] - Ypoints[2], 2))
                           );
    }
}

While this provides some structure, it doesn’t quite feel right. Adding another point would require modifying the array and writing a new method. Let’s do better.

Point Object #

Let’s start by defining a new class for storing a point, we’ll place it in a new file called Point.java. A class is a recipe for creating objects. It defines what is stored in the object and what methods operate over.

//Point.java
public class Point {

    double x;
    double y;

    //constructor
    public Point(double X, double Y) {
        this.x = X;
        this.y = Y;
    }

    public double dist(Point other) {
        return Math.sqrt(Math.pow(this.x - other.x, 2) +
                         Math.pow(this.y - other.y, 2));
    }
}

This class defines two data members, x and y to store the coordinates. It also defines a constructor for the Point object, and a method dist.

Constructor #

A constructor for an object is a special method that defines how to “build” an object of the current class. In our case this is rather simple. We only need to the know the x and y coordinate, and we wish to store them.

this #

The this variable is special variable that refers to the current object. Recall that the class is a definition for how to create objects, but within methods, like the constructor, we need a way to differentiate between things that are associated with the class and the current object being operated on.

Within the constructor, the this keyword refers to the new object being constructed. So assigning to this.x or this.y says, store the input values X and Y within the newly created object.

(Aside: You don’t explicly need to use this, its implied due to the scoping. Java will look for the most locally bounded x to use, and in this case that would be the x within the object being constructed. Where this would be strictly necessary is when you have variable shadowing. For example, if the constructor were declared as public Point(double x, double y) — lowercase x and y —then the most locally bound x and y are within the function, not the object. I find this helps disambiguate scoping, so sometimes I use it, but not always.)

dist method #

The dist method is an object that operates over the object, called via the . operator, and another Point object. Via the . operate we get access to the Point object whose method was called, in this case this, and also the Point object passed as an argument. Using both of those we can compute the distance between this point and the other point, returning the result.

main method #

Now we can put it all together, writing a new main method.

public class PointDistances2 {

    public static void main(String args[]) {

        Point p0 = new Point(2.3, 4.8);
        Point p1 = new Point(1.1, 3.0);
        Point p2 = new Point(5.8, 0.3);

        double d01 = p0.dist(p1);
        double d02 = p0.dist(p2);
        double d12 = p1.dist(p2);
        
        System.out.println("dist(p0, p1) = " + d01);
        System.out.println("dist(p0, p2) = " + d02);
        System.out.println("dist(p1, p2) = " + d12);
        
    }
}
$ java PointDistances2.java
dist(p0, p1) = 2.1633307652783933
dist(p0, p2) = 5.70087712549569
dist(p1, p2) = 5.420332093147061

Note that for each Point we have to create a new instance of it. That act of calling new invokes the constructor with the arguments, returning a new object, whose reference is stored in the variable. Later, we can use those objects to calculate distances.

Memory Diagrams in Java #

Just like in C, we should also consider memory diagramming in Java. Let’s look at the last program above PointDistance2 and draw the memory diagram.

    STACK                            HEAP
     
    .-----------------.             .---------.
    | p0    |   .-----+-----------> | x | 2.2 | (Point Objects)
    |-------+---------.             |---+-----|
    | p1    |   .-----+---.         | y | 4.8 | 
    |-------+---------.    \        '---------'
    | p2    |   .-----+--.  '-----> .---------.
    |-------+---------.   \         | x | 1.1 |
    | d01   | 2.16... |    \        |---+-----|
    |-------+---------.     \       | y | 3.0 |
    | d02   | 5.70... |      \      '---------'
    |-------+---------.       '---> .---------.
    | d12   | 5.42... |             | x | 5.8 |
    '-----------------'             |---+-----|
                                    | y | 0.3 |
                                    '---------'

The basic types, in this case double, is stored on the stack, but the objects are allocated on the heap, via new. That means the variables in main reference those objects and thus pointers.

Note to access members of the objects, we always use the . operator, and never the -> operator in Java. That’s because in Java you can never have a stack instance of an object: all objects are allocated on the heap and all variables reference a heap stored object. There is no need for two operators, and thus, as programmers are lazy, we opt for the simpler . operator.

You can also view this through the Java Visualizer for this example.

Encapsulation and Data Hiding #

Java has a strong notion of encapsulation, which means that data and methods within objects should be limited such that they are accessed within scope. For example, the data members x and y are unprotected (default public) – this is typically undesireable.

This means, as in the below example, we can use the . operator to both read the values of p.x and p.y as well as modify them.

public class PointDistances3 {

    public static void main(String args[]) {

        Point p = new Point(2.3, 4.8);

        System.out.println("p = (" + p.x + "," + p.y + ")");

        p.x = 5;
        p.y = 10;

        System.out.println("p = (" + p.x + "," + p.y + ")");
        
    }
}

However, this can be dangerous and violates the principal of encapsulation where only access data where most appropriate.

Public vs. Private Data Members #

Java uses a notion of public and private declarations on both object data and methods to limit how programmers can use the object. (There is also protected but we’ll get to that later.)

Perhaps we want to better control access to the data members, we can declare x and y as private class members.

public class Point {

   private double x;
   private double y;

   //..

And this will cause a compiler error when accessing x and y directly using the . operator.

PointAccess.java:9: error: x has private access in Point
        p.x = 5;
         ^
PointAccess.java:10: error: y has private access in Point
        p.y = 10;

Getter and Setters #

So if we have private members, how do we access these members? We use getter and setter methods.

public class Point {

    private double x;
    private double y;

    public Point(double X, double Y){
        this.x = X;
        this.y = Y;
    }

    public double getX(){
        return this.x;
    }
    
    public double getY(){
        return this.y;
    }

    public void setX(double x){
        this.x = x;
    }

    public void setY(double y){
        this.y = y;
    }
    
    public double dist(Point other){
        return Math.sqrt( Math.pow(this.x - other.x, 2) +
                          Math.pow(this.y - other.y, 2));
    }
}

And then we call those public methods, rather than accessing the data members directly.

public class PointAccess2 {

    public static void main(String args[]) {

        Point p = new Point(2.3, 4.8);

        System.out.println("p = (" + p.getX() + "," + p.getY() + ")");

        p.setX(5);
        p.setY(10);

        System.out.println("p = (" + p.getX() + "," + p.getY() + ")");
        
    }
}

Perhaps, we also want a method in Point to set both X and Y and the same time. So we can add that as well

  public void setXY(double x, double y) {
        this.x = X;
        this.y = Y;
    }

And wait, that’s also very much like the constructor, so why not call that there?!?

 public Point(double x, double y) {
        setXY(x,y);
    }

And now we’re really programming.

toString() #

As we start to develop our Point class, we should still be somewhat unsatisfied with the printing routine.

   System.out.println("p = (" + p.getX() + "," + p.getY() + ")");

This also seems like a violation of encapsulation because the representation of the Point as “(x,y)” string shouldn’t change regardless of the instance of the Point. Instead, it should be part of the class definition of the object. It would make a lot more sense to have a method that returned the string representation. Even better, it would be great if we could just do the following, like we do with basic types?

System.out.println("p=" + p);

If you were to try that, what you’d find is that something does print, but not what you expect

p = Point@5acf9800
p = Point@5acf9800

That string is the Java reference representation. Essentially say that it’s the Point stored at reference 5acf9800. The + operator with a string and a non-string object will automatically convert the non string object to a string by calling a special method toString() on that object. If one isn’t defined, then the default toString() method is called inheritted from the Object class.

But, we can overwrite the default toString() to write our own specific for Point.

public String toString() {
        return "(" + this.x + "," + this.y + ")";
    }

Now, we’ve further simplified our main method

public class PointAccess3 {

    public static void main(String args[]) {

        Point p = new Point(2.3, 4.8);

        System.out.println("p = " + p);

        p.setXY(5, 10);

        System.out.println("p = " + p);
        
    }
}

More advanced object programming #

Line object #

Suppose now we want to extend on our object model and create a new Line class that builds on our notion of Point. A Line can simply be defined as a combination of two points, a start and and end. This is relatively straightforward to write the length() method and toString() method given our work on Point.

public class Line {

    private Point start;
    private Point end;

    public Line(double x1, double y1, double x2, double y2) {
        start = new Point(x1, y1);
        end = new Point(x2, y2);
    }

    public double length() {
        return start.dist(end);
    }

    public String toString() {
        return "[" + start + ":" + end + "]";
    }

}

Here’s an example main method

public class LineExample1 {

    public static void main(String args[]) {

        Line l = new Line(4.0, 6.0, 5.0, 7.0);

        System.out.println("l = " + l);
        System.out.println("l.length = " + l.length());
    }
}

Method and Constructor Overloading #

Looking at the constructor for Line, you might wonder — it’s just taking two Points, why not pass two Points? Yes. Totally true, but it would also be nice to keep the other constructor, based on 4 doubles. Good news everyone! You can do both by overloading the constructor.

In our Line class, let’s define a second constructor. It has the same name of the other constructor, but takes different arguments. Here are the two constructors side by side.

    public Line(Point p1, Point p2) {
        start = p1;
        end = p2;
    }
    public Line(double x1, double y1, double x2, double y2) {
        start = new Point(x1, y1);
        end = new Point(x2, y2);
    }

How does Java choose between these two constructors? It does type inspection on the arguments and matches to the constructor with the right matching types. So you cannot have two constructors (or methods within scope of an object/class) with the same name and the same arguments (unless their ordered types differ – the compiler has to be able to differentiate them), otherwise Java will not know which method to call.

Maintaining Encapsulation with Objects References #

The new Line constructor that takes two Points bring up an interesting new problem regarding encapsulation. Consider the getter method for Line that retrieves one of the points:


    public Point getStart() {
        return start;
    }

If this method were called by the user on a Line instance, than altering the Point start would allow the user to alter the data stored within that Line instance, even though it is set to private. Also, consider the new constructor

    public Line(Point p1, Point p2) {
        start = p1;
        end = p2;
    }

The user passing the point p1 could still alter it, even after using it in the constructor. To see this, let’s look at a memory diagram, where we can see that we only have one object referenced by start, p1 and s at point **A**. Modification by using . from any of these references modifies the same object. After modifying, it prints [(20,10):(2.1,3.4)] despite no calls to l to modify the underlying data it stores.

public class LineExample2 {

    public static void main(String args[]) {

        Point p1 = new Point(4.0, 8.5);
        Point p2 = new Point(2.1, 3.4);
        Line l = new Line(p1, p2); 

        Point s = l.getStart();//**A**

        s.setXY(20.0, 10.0);  //**B**
        System.out.println("l = " + l);// [(20,10):(2.1,3.4)]

    }
}
   **A**                                                
   
   STACK                    HEAP                       
                            
                             .--------.       
                   .-------> | x | 4.0| <-----.
  .----------.    /          |--------|       |
  | p1  |  .-+---'    .----> | y | 8.5|       |
  |-----+----|       /       '--------'       |
  | p2  |  .-+----. /                         |
  |-----+----|     X         .--------.       |
  | l   |  .-+--. / \        | x | 4.0| <-----+--.
  |-----+----|   X   '-----> |--------|       |  |
  | s   |  .-+-./ \          | y | 8.5|       |  |
  '----------'     \         '--------'       |  |
                    \                         |  |
                     \       .----------.     |  |
                      '----> |start | .-+-----'  |
                             |------+---|        |
                             |  end | .-+--------'
                             '----------'           

Now — before solving this problem, you might ask is this really a problem? It really depends on the program. In many cases this may be the desired functionality. Here, though, we want to ensure that only via calls to modifiers within Line can we alter the underlying data storage.

Copy Constructor #

In this case, let’s solve this problem by creating a new overloaded constructor for Point that takes another Point instance as it’s argument, constructing a new Point object based on it’s x and y value. Like in the example below

   public Point(Point other) { 
      this.x = other.getX();
      this.y = other.getY();
   }

And in our Line constructor, that takes two Points, we modify that to call this Point constructor to perform a copy.

   public Line(Point p1, Point p2) {
     this.start = new Point(p1);
     this.end = new Point(p2);
   }

Similarly, when we call getStart() or getEnd(), we also use this constructor

    public Point getStart() {
        return new Point(this.start);
    }
    public Point getEnd() {
        return new Point(this.end);
    }

Looking at the memory diagram for the main method above, with these modication, we see there are no longer shared references (at **B**).

   **B** 
   
   STACK                      HEAP
                            
                             .--------.          .--------.
                   .-------> | x | 4.0|   .----> | x | 4.0|
  .----------.    /          |--------|   |      |--------|
  | p1  |  .-+---'           | y | 8.5|   |      | y | 8.5|
  |-----+----|               '--------'   |      '--------'
  | p2  |  .-+----.                       |              
  |-----+----|     \         .--------.   |      .--------.
  | l   |  .-+--.   \        | x | 4.0|   | .--> | x | 4.0|
  |-----+----|   \   '-----> |--------|   | |    |--------|
  | s   |  .-+-.  \          | y | 8.5|   | |    | y | 8.5|
  '----------'  \  \         '--------'   | |    '--------'
                 \  \                     | |
                  \  \       .----------. | |    .--------.
                   \  '----> |start | .-+-' | .->| x |20.0|
                    \        |------+---|   | |  |--------|
                     \       |  end | .-+---' |  | y |10.0|
                      \      '----------'     |  '--------'
                       '----------------------'      
                             

Deep vs. Shallow copy #

The new Point constructor is called deep copy constructor because it copies the object to a new object, without any references between them. That is relatively straightforward to do here because Point’s data members are both basic types. In contrast, a shallow copy which creates a new object that shares references.

As an example, consider the following method for create a copy of the current line. (Note, this wouldn’t compile due to start and end as private members.)

  public Line(Line other) {
    this.start = other.start;
    this.end = other.end;
  }

Doing so would mean the new Line object (this) and the other Line object (other) would actually share the underlying data storage Points. This is a shallow copy. Alternatively, we can do a deep copy of the line using the facilities already in place.

  public Line(Line other) {
    this.start = other.getStart(); //returns a copy of Point start
    this.end = other.getEnd(); //returns a copy of Point end
  }

With that copy constructor in place, we can write a copy() method really easily

  public Line copy() {
    return new Line(this); //construct new object based on this object
  }

Private Methods #

Just like with data, we can also declare a method private if they shouldn’t be called outside the scope of the object. To see an example of this, let’s consider adding a new data member to the Line class, slope.

The slope line is calculated as run over rise. For the example two points below (forming a line), the run is the distance between their x components (-4), and the rise is the distance between their y components (8).

    y
    ^   
    |    . (2,9)
    |    :\
    |  8 : \
    |    :  \    
    |    :.... (6,1)
    |     -4
<---+---------------> x
    |
    v

The slope of a line is run divided by rise, or 8/4 = -2. Importantly, to calculate the slope, we need to order the points by their x component.

Adding Slope #

Let’s start by modifying the List class to add a private member slope, and we can set that slope at construction once start and end is established.

public class Line {

    private Point start;
    private Point end;
    private double slope;
    
    public Line(double x1, double y1, double x2, double y2) {
        start = new Point(x1, y1);
        end = new Point(x2, y2);
        slope = calcSlope();
    }

    public Line(Point p1, Point p2) {
        start = new Point(p1);
        end = new Point(p2);
        slope = calcSlope();
    }
    
    \\ ...
    
    public getSlope() {
        return slope;
    }
    
    private double calcSlope() {
        double run, rise;
        
        if(end.getX() > start.getX()) {
            run = end.getX() - start.getX();
            rise = end.getY() - start.getY();
        }else {
            run = start.getX() - end.getX();
            rise = start.getY() - end.getY();
        }
        
        return rise / run;
    }

Looking at the method calcSlope(), it will never need to be called anywhere but in the constructor for the Line. It only needs to be called once, and if the user wishes to learn the slope, they can call getSlope(). As a result, this method doesn’t need to be public, and so it is declared private.

Additionally, we could simplify our calcSlope() with an additional private method that reorders the points during construction such that the start point always has the lower x-value compared to the end point.

   private void orderPoints() {
        if(end.getX() < start.getX()) {
            Point tmp = start;
            start = end;
            end = start;
        }
    }

Again we want this to be a private method; the user shouldn’t call it directly. Instead, it’s called at construction to get the points in order, simplifying the calcSlope() method in the process.

public Line(double x1, double y1, double x2, double y2) {
        start = new Point(x1, y1);
        end = new Point(x2, y2);
        orderPoints();
        slope = calcSlope();
    }

    public Line(Point p1, Point p2) {
        start = new Point(p1);
        end = new Point(p2);
        orderPoints();
        slope = calcSlope();
    }

    
    private double calcSlope() {
        double run = end.getX() - start.getX();
        double rise = end.getY() - start.getY();
        return rise / run;
    }

    private void orderPoints() {
        if(end.getX() < start.getX()) {
            Point tmp = start;
            start = end;
            end = start;
        }
    }

Static Methods #

The static declarations for classes allow functions and data to be accessible within the class without needing to instantiate an object instance of that class.

The classic example of static is the main method. It’s declared static, that’s because when you execute the main method of a class, you’re not instantiating an instance of that class as an object, and then calling main. Instead you’re calling main directly, or statically, without an instance. You can think of this as calling main on the class – infact, this is how static methods are typically called (besides main, which is special).

Within the object oriented model, we use static to provide utility functions or constants that don’t require object instantiating. You are probably familiar with Integer.parseInt(). The Integer class is an object version of the basic type, and it is common to need to create an int by parsing a String, like:


  int a = Integer.parseInt("5"); //a gets then integer 5

You’ll notice that we don’t create a new Integer object to call the member function parseInt(). We call parseInt() directly and statically (on the Integer class with the dot operator, rather than on an Integer object).

Static Slope Calculation #

Calculating the slope of a line is a fairly useful utility that we can attach to our Line class as a static method. Doing so means a user doesn’t have to create a Line in order to calculate the slope of the line that connects two points.

We can write that static method like so, and note that it’s also public because it is called outside the context of the class.

   public static double calcSlope(Point p1, Point p2) {
        if(p1.getX() > p2.getX())
            return (p1.getY() - p2.getY()) / (p1.getX() - p2.getX());
        else
            return (p2.getY() - p1.getY()) / (p2.getX() - p1.getX());
    }

Additionally, we can’t rely on the points to be properly ordered, since we’re not instantiating a Line. So we have to use if/else. Now we can write a main method taking advantage of the new static method.


public class staticSlope {

    public static void main(String args[]) {
        Point p1 = new Point(2, 9);
        Point p2 = new Point(6, 1);

        //Also, java has printf :)
        System.out.printf("p1: %s p2: %s dist(p1,p2): %.2f slope: %.2f\n",
                          p1, p2,
                          p1.dist(p2),
                          Line.calcSlope(p1, p2));
        //%.2f -- says print two decimal points 
        
    }

}

And just for fun — Java also have printf() :) — which, in some cases is easier to use than println() or print().

Arrays #

Java has arrays that store aligned data that is indexable with the [] operator. Arrays are actually objects; an Array object created with a new call. Like other objects, they are dynamically allocated.

Arrays of Basic Types #

To create an array of a basic type, we must first declare the variable to be an array object. This is done by adding [] to the variable name at declaration.

  int intArray1[];
  int[] intArray2;

Then we need to allocate the array object of that type. This works much like calloc() call in C. Java determines the size of each element based on the type (in this case int) and the number of items based on the allocation (in this case 10). As this is a dynamic allocation, we need the new operator.

  intArray = new int[10];

The new array is zero’ed out. The memory diagram looks like the following.

  STACK                    HEAP
  
  .--------------.        .---.
  | intArray | .-+----->  | 0 |  intArray[0]
  '--------------'        |---|
                          | 0 |  intArray[1]
                          |---|
                          :   :
                          :   :
                          |---|
                          | 0 |  intArray[9]
                          '---'

For all basic types, the initial value of the array is always the zero value. For bool, this would be false.

Arrays of Objects #

Arrays of Objects are declared in the same way. For example, an array of Points.

    Point pArray[] =  new Points[10];

And just like with basic types, the new array is zero’ed out. But recall that the value of a object variable is a memory reference. So the zero’ed out value is null. You still have to instantiate each of the Point objects of the array.

   for(int i = 0; i < 10; i++)
      pArray[i] = new Point(i, i);

As a memory diagram, we would have the following

  STACK                    HEAP
                                 .-------.
  .------------.        .---. .->| x | 0 |
  | pArray | .-+----->  | .-+-'  |-------| pArray[0]
  '------------'        |---|    | y | 0 |
                        | .-+-.  '-------' 
                        |---| |  .-------.
                        :   : '->| x | 1 |
                        :   :    |-------| pArray[1]
                        |---|    | y | 1 |
                        | .-+-.  '-------'
                        '---' |     :
                Array Object  |     :
                              |  .-------.
                              '->| x | 9 |
                                 |-------| pArray[9]
                                 | y | 9 |
                                 '-------'
                                 
                                 Point Objects

Using {} to allocate an array #

You can also allocate arrays without a new call by specifying directly using {} and the initial values. This works for both basic array types and object array types.

  int intArray[] = {0, 1, 2, 3, 4};
  Point pArray[] = {new Point(0, 0), new Point(1, 1), new Point(2, 2)};

Even when using initial value allocation, it’s still an allocation. Under the covers, Java calls new, allocates the array, and assigns the initial values for you.

Iterating over an Array #

Arrays, as objects, carry with them data and methods to support different operation. Most immediate is that an array object stores its length, which you can use to assure you do not access beyond the range of the array. If you do, this throws an exception, and if not caught, your program crashes.

Using the length member, we can simply iterate over the array using indexes. Here’s a routine that prints the distance between consecutive points in the array.

    Point lastPoint = null;
    for(int i = 0; i < pArray.length; i++) {
       if (lastPoint != null) {
          System.out.printf("dist(%s, %s) = %.2f\n",
                             lastPoint,
                             pArray[i],
                             lastPoint.dist(pArray[i]));
       }
       lastPoint = pArray[i];
   }

However, you may notice that this is a bit wasteful because i is only used for indexing. Instead, it would be nice to use a for-each semantic, where we say “for each point in the array” without the index. Java provides a way to simplify iteration when the “for-each” semantic is desired.

    Point lastPoint = null;
    for(Point p : pArray) {
       if (lastPoint != null) {
          System.out.printf("dist(%s, %s) = %.2f\n",
                             lastPoint,
                             p,
                             lastPoint.dist(p));
       }
       lastPoint = p;
   }

At each step the iteration, p gets assigned the next Point in the array, without having to use the index feature. Any object that implements Iterable can be used in this syntax.


Material on this page adopted with permission from USNA courses ic211, taught by Nate Chambers, Gavin Taylor, Chris Brown, and many others. Thank you.