Object-oriented programming II
In this chapter of the C# tutorial, we continue description of the OOP.Interfaces
A remote control is an interface between the viewer and the TV. It is an interface to this electronic device. Diplomatic protocol guides all activities in the diplomatic field. Rules of the road are rules that motorists, cyclists and pedestrians must follow. Interfaces in programming are analogous to the previous examples.Interfaces are:
- APIs
- Contracts
From the second point of view, interfaces are contracts. If agreed upon, they must be followed. They are used to design an architecture of an application. They help organize the code.
Interfaces are fully abstract types. They are declared using the
interface keyword. Interfaces can only have signatures of methods, properties, events or indexers. All interface members implicitly have public access. Interface members cannot have access modifiers specified. Interfaces cannot have fully implemented methods, nor member fields. A C# class may implement any number of interfaces. A n interface can also extend any number of interfaces. A class that implements an interface must implement all method signatures of an interface. Interfaces are used to simulate multiple inheritance. A C# class can inherit only from one class. A C# class can implement multiple interfaces. Multiple inheritance using the interfaces is not about inheriting methods and variables. It is about inheriting ideas or contracts, which are described by the interfaces.
There is one important distinction between interfaces and abstract classes. Abstract classes provide partial implementation for classes, that are related in the inheritance hierarchy. Interfaces on the other hand can be implemented by classes, that are not related to each other. For example, we have two buttons. A classic button and a round button. Both inherit from an abstract button class, that provides some common functionality to all buttons. Implementing classes are related, since all are buttons. Another example might have classes Database and SignIn. They are not related to each other. We can apply an ILoggable interface, that would force them to create a method to do logging.
using System;This is a simple C# program demonstrating an interface.
public interface IInfo
{
void DoInform();
}
public class Some : IInfo
{
public void DoInform()
{
Console.WriteLine("This is Some Class");
}
}
public class CSharpApp
{
static void Main()
{
Some sm = new Some();
sm.DoInform();
}
}
public interface IInfoThis is an interface
{
void DoInform();
}
IInfo. It has the DoInform()method signature. public class Some : IInfoWe implement the
IInfo interface. To implement a specific interface, we use the colon (:) operator. public void DoInform()The class provides an implementation for the
{
Console.WriteLine("This is Some Class");
}
DoInform()method. The next example shows, how a class can implement multiple interfaces.
using System;We have a
public interface Device
{
void SwitchOn();
void SwitchOff();
}
public interface Volume
{
void VolumeUp();
void VolumeDown();
}
public interface Pluggable
{
void PlugIn();
void PlugOff();
}
public class CellPhone : Device, Volume, Pluggable
{
public void SwitchOn()
{
Console.WriteLine("Switching on");
}
public void SwitchOff()
{
Console.WriteLine("Switching on");
}
public void VolumeUp()
{
Console.WriteLine("Volume up");
}
public void VolumeDown()
{
Console.WriteLine("Volume down");
}
public void PlugIn()
{
Console.WriteLine("Plugging In");
}
public void PlugOff()
{
Console.WriteLine("Plugging Off");
}
}
public class CSharpApp
{
static void Main()
{
CellPhone cp = new CellPhone();
cp.SwitchOn();
cp.VolumeUp();
cp.PlugIn();
}
}
CellPhone class that inherits from three interfaces. public class CellPhone : Device, Volume, PluggableThe class implements all three interfaces, which are divided by a comma. The CellPhone class must implement all method signatures from all three interfaces.
$ ./interface2.exeRunning the program.
Switching on
Volume up
Plugging In
The next example shows how interfaces can inherit from multiple other interfaces.
using System;We define three interfaces. We can organize interfaces in a hierarchy.
public interface IInfo
{
void DoInform();
}
public interface IVersion
{
void GetVersion();
}
public interface ILog : IInfo, IVersion
{
void DoLog();
}
public class DBConnect : ILog
{
public void DoInform()
{
Console.WriteLine("This is DBConnect class");
}
public void GetVersion()
{
Console.WriteLine("Version 1.02");
}
public void DoLog()
{
Console.WriteLine("Logging");
}
public void Connect()
{
Console.WriteLine("Connecting to the database");
}
}
public class CSharpApp
{
static void Main()
{
DBConnect db = new DBConnect();
db.DoInform();
db.GetVersion();
db.DoLog();
db.Connect();
}
}
public interface ILog : IInfo, IVersionThe
ILog interface inherits from two other interfaces. public void DoInform()The
{
Console.WriteLine("This is DBConnect class");
}
DBConnect class implements the DoInform() method. This method was inherited by the ILog interface, which the class implements. $ ./interface3.exeOutput.
This is DBConnect class
Version 1.02
Logging
Connecting to the database
Polymorphism
The polymorphism is the process of using an operator or function in different ways for different data input. In practical terms, polymorphism means that if class B inherits from class A, it doesn't have to inherit everything about class A; it can do some of the things that class A does differently. (wikipedia)In general, polymorphism is the ability to appear in different forms. Technically, it is the ability to redefine methods for derived classes. Polymorphism is concerned with the application of specific implementations to an interface or a more generic base class.
Polymorphism is the ability to redefine methods for derived classes.
using System;In the above program, we have an abstract
public abstract class Shape
{
protected int x;
protected int y;
public abstract int Area();
}
public class Rectangle : Shape
{
public Rectangle(int x, int y)
{
this.x = x;
this.y = y;
}
public override int Area()
{
return this.x * this.y;
}
}
public class Square : Shape
{
public Square(int x)
{
this.x = x;
}
public override int Area()
{
return this.x * this.x;
}
}
public class CSharpApp
{
static void Main()
{
Shape[] shapes = { new Square(5),
new Rectangle(9, 4), new Square(12) };
foreach (Shape shape in shapes)
{
Console.WriteLine(shape.Area());
}
}
}
Shape class. This class morphs into two descendant classes, Rectangle and Square. Both provide their own implementation of the Area() method. Polymorphism brings flexibility and scalability to the OOP systems. public override int Area()
{
return this.x * this.y;
}
...
public override int Area()
{
return this.x * this.x;
}
Rectangle and Square classes have their own implementations of the Area() method. Shape[] shapes = { new Square(5),
new Rectangle(9, 4), new Square(12) };
We create an array of three Shapes. foreach (Shape shape in shapes)We go through each shape and call
{
Console.WriteLine(shape.Area());
}
Area() method on it. The compiler calls the correct method for each shape. This is the essence of polymorphism. Sealed classes
Thesealed keyword is used to prevent unintended derivation from a class. A sealed class cannot be an abstract class. using System;In the above program, we have a base Math class. The sole purpose of this class is to provide some helpful methods and constants to the programmer. (In our case we have only one method for simplicity reasons.) It is not created to be inherited from. To prevent uninformed other programmers to derive from this class, the creators made the class
sealed class Math
{
public static double GetPI()
{
return 3.141592;
}
}
public class Derived : Math
{
public void Say()
{
Console.WriteLine("Derived class");
}
}
public class CSharpApp
{
static void Main()
{
DerivedMath dm = new DerivedMath();
dm.Say();
}
}
sealed. If you try to compile this program, you get the following error: 'DerivedMath' cannot derive from sealed class `Math'. Deep copy vs shallow copy
Copying of data is an important task in programming. Object is a composite data type in OOP. Member field in an object may be stored by value or by reference. Copying may be performed in two ways.The shallow copy copies all values and references into a new instance. The data to which a reference is pointing is not copied; only the pointer is copied. The new references are pointing to the original objects. Any changes to the reference members affect both objects.
The deep copy copies all values into a new instance. In case of members that are stored as references a deep copy performs a deep copy of data, that is being referenced. A new copy of a referenced object is created. And the pointer to the newly created object is stored. Any changes to those referenced objects will not affect other copies of the object. Deep copies are fully replicated objects.
If a member field is a value type, a bit-by-bit copy of the field is performed. If the field is a reference type, the reference is copied but the referred object is not; therefore, the reference in the original object and the reference in the clone point to the same object. (a clear explanation from programmingcorner.blogspot.com)
The next two examples will perform a shallow and a deep copy on objects.
using System;This is an example of a shallow copy. We define two custom objects. MyObject and Color. The MyObject object will have a reference to the Color object.
public class Color
{
public int red;
public int green;
public int blue;
public Color(int red, int green, int blue)
{
this.red = red;
this.green = green;
this.blue = blue;
}
}
public class MyObject : ICloneable
{
public int id;
public string size;
public Color col;
public MyObject(int id, string size, Color col)
{
this.id = id;
this.size = size;
this.col = col;
}
public object Clone()
{
return new MyObject(this.id, this.size, this.col);
}
public override string ToString()
{
string s;
s = String.Format("id: {0}, size: {1}, color:({2}, {3}, {4})",
this.id, this.size, this.col.red, this.col.green, this.col.blue);
return s;
}
}
public class CSharpApp
{
static void Main()
{
Color col = new Color(23, 42, 223);
MyObject obj1 = new MyObject(23, "small", col);
MyObject obj2 = (MyObject) obj1.Clone();
obj2.id += 1;
obj2.size = "big";
obj2.col.red = 255;
Console.WriteLine(obj1);
Console.WriteLine(obj2);
}
}
public class MyObject : ICloneableWe should implement
ICloneable interface for objects, which we are going to clone. public object Clone()The
{
return new MyObject(this.id, this.size, this.col);
}
ICloneable interface forces us to create a Clone() method. This method returns a new object with copied values. Color col = new Color(23, 42, 223);We create an instance of the Color object.
MyObject obj1 = new MyObject(23, "small", col);An instance of the MyObject object is created. It passes the instance of the Color object to its constructor.
MyObject obj2 = (MyObject) obj1.Clone();We create a shallow copy of the obj1 object and assign it to the obj2 variable. The Clone() method returns an Object and we expect MyObject. This is why we do explicit casting.
obj2.id += 1;Here we modify the member fields of the copied object. We increment the id, change the size to "big" and change the red part of the color object.
obj2.size = "big";
obj2.col.red = 255;
Console.WriteLine(obj1);The
Console.WriteLine(obj2);
Console.WriteLine() method calls the ToString() method of the obj2 object, which returns the string representation of the object. $ ./shallowcopy.exeWe can see, that the ids are different. 23 vs 24. The size is different. "small" vs "big". But the red part of the color object is same for both instances. 255. Changing member values of the cloned object (id, size) did not affect the original object. Changing members of the referenced object (col) has affected the original object too. In other words, both objects refer to the same color object in memory.
id: 23, size: small, color:(255, 42, 223)
id: 24, size: big, color:(255, 42, 223)
Deep Copy To change this behaviour, we will do a deep copy next.
using System;In this program, we perform a deep copy on object.
public class Color : ICloneable
{
public int red;
public int green;
public int blue;
public Color(int red, int green, int blue)
{
this.red = red;
this.green = green;
this.blue = blue;
}
public object Clone()
{
return new Color(this.red, this.green, this.blue);
}
}
public class MyObject : ICloneable
{
public int id;
public string size;
public Color col;
public MyObject(int id, string size, Color col)
{
this.id = id;
this.size = size;
this.col = col;
}
public object Clone()
{
return new MyObject(this.id, this.size,
(Color) this.col.Clone());
}
public override string ToString()
{
string s;
s = String.Format("id: {0}, size: {1}, color:({2}, {3}, {4})",
this.id, this.size, this.col.red, this.col.green, this.col.blue);
return s;
}
}
public class CSharpApp
{
static void Main()
{
Color col = new Color(23, 42, 223);
MyObject obj1 = new MyObject(23, "small", col);
MyObject obj2 = (MyObject) obj1.Clone();
obj2.id += 1;
obj2.size = "big";
obj2.col.red = 255;
Console.WriteLine(obj1);
Console.WriteLine(obj2);
}
}
public class Color : ICloneableNow the Color class implements the
ICloneableinterface. public object Clone()We have a
{
return new Color(this.red, this.green, this.blue);
}
Clone() method for the Color class too. This helps to create a copy of a referenced object. public object Clone()Now, when we clone the MyObject, we call the
{
return new MyObject(this.id, this.size,
(Color) this.col.Clone());
}
Clone()method upon the col reference type. This way we have a copy of a color value too. $ ./deepcopy.exeNow the red part of the referenced Color object is not the same. The original object has retained its previous 23 value.
id: 23, size: small, color:(23, 42, 223)
id: 24, size: big, color:(255, 42, 223)
Exceptions
Exceptions are designed to handle the occurrence of exceptions, special conditions that change the normal flow of program execution. Exceptions are raised or thrown, initiated.During the execution of our application, many things might go wrong. A disk might get full and we cannot save our file. An Internet connection might go down and our application tries to connect to a site. All these might result in a crash of our application. To prevent happening this, we must cope with all possible errors that might occur. For this, we can use the exception handling.
The
try, catch and finally keywords are used to work with exceptions. using System;In the above program, we intentionally divide a number by zero. This leads to an error.
public class CSharpApp
{
static void Main()
{
int x = 100;
int y = 0;
int z;
try
{
z = x / y;
} catch (Exception e)
{
Console.WriteLine(e.Message);
}
}
}
tryStatements that are error prone are placed after the
{
z = x / y;
} catch (Exception e)
trykeyword. } catch (Exception e)Exception types follow the
{
Console.WriteLine(e.Message);
}
catch keyword. In our case we have a generic Exception which will catch an exception of any type. There are some generic exceptions and some more specific. Statements that follow the catch keyword are executed, when an error occurs. When an exception occurs, an exception object is created. From this object we get the Message property and print it to the console. $ ./zerodivision.exeOutput of the code example.
Division by zero
Any uncaught exception in the current context propagates to a higher context and looks for an appropriate catch block to handle it. If it can't find any suitable catch blocks, the default mechanism of the .NET runtime will terminate the execution of the entire program.
using System;In this program, we divide by zero. There is no no custom exception handling.
public class CSharpApp
{
static void Main()
{
int x = 100;
int y = 0;
int z = x / y;
Console.WriteLine(z);
}
}
$ ./uncaught.exeThe Mono C# compiler gives the above error message.
Unhandled Exception: System.DivideByZeroException: Division by zero
at CSharpApp.Main () [0x00000]
using System;The statements following the
using System.IO;
public class CSharpApp
{
static void Main()
{
FileStream fs = new FileStream("langs", FileMode.OpenOrCreate);
try
{
StreamReader sr = new StreamReader(fs);
string line;
while ((line = sr.ReadLine()) != null)
{
Console.WriteLine(line);
}
} catch (IOException e)
{
Console.WriteLine("IO Error");
Console.WriteLine(e.Message);
} finally
{
Console.WriteLine("finally");
if (fs.CanRead)
{
fs.Close();
}
}
}
}
finally keyword are always executed. It is often used to clean-up tasks, such as closing files or clearing buffers. } catch (IOException e)In this case, we catch for a specific
{
Console.WriteLine("IO Error");
Console.WriteLine(e.Message);
} finally
IOException exception. } finallyThese lines guarantee that the file handler is closed.
{
Console.WriteLine("finally");
if (fs.CanRead)
{
fs.Close();
}
}
$ cat langsWe show the contents of the langs file with the cat command and output of the program.
C#
Python
C++
Java
$ ./finally.exe
C#
Python
C++
Java
finally
using System;In this example, we catch for various exceptions. Note that more specific exceptions should precede the generic ones. We read two numbers from the console and check for zero division error and for wrong format of number.
using System.IO;
public class CSharpApp
{
static void Main()
{
int x;
int y;
double z;
try
{
Console.Write("Enter first number: ");
x = Convert.ToInt32(Console.ReadLine());
Console.Write("Enter second number: ");
y = Convert.ToInt32(Console.ReadLine());
z = x / y;
Console.WriteLine("Result: {0:D} / {1:D} = {2:D}", x, y, z);
} catch (DivideByZeroException e)
{
Console.WriteLine("Cannot divide by zero");
Console.WriteLine(e.Message);
} catch (FormatException e)
{
Console.WriteLine("Wrong format of number.");
Console.WriteLine(e.Message);
} catch (Exception e)
{
Console.WriteLine(e.Message);
}
}
}
$ ./multipleexceptions.exeRunning the example.
Enter first number: we
Wrong format of number.
Input string was not in the correct format
using System;Let's say, we have a situation in which we cannot deal with big numbers.
class BigValueException : Exception
{
public BigValueException(string msg) : base(msg) {}
}
public class CSharpApp
{
static void Main()
{
int x = 340004;
const int LIMIT = 333;
try
{
if (x > LIMIT)
{
throw new BigValueException("Exceeded the maximum value");
}
} catch (BigValueException e)
{
Console.WriteLine(e.Message);
}
}
}
class BigValueException : ExceptionWe have a BigValueException class. This class derives from the built-in
Exception class. const int LIMIT = 333;Numbers bigger than this constant are considered to be "big" by our program.
public BigValueException(string msg) : base(msg) {}
Inside the constructor, we call the parent's constructor. We pass the message to the parent. if (x > LIMIT)If the value is bigger than the limit, we throw our custom exception. We give the exception a message "Exceeded the maximum value".
{
throw new BigValueException("Exceeded the maximum value");
}
} catch (BigValueException e)We catch the exception and print its message to the console.
{
Console.WriteLine(e.Message);
}
In this part of the C# tutorial, we continued the discussion of the object-oriented programming in C#.
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