Methods in C#
In this part of the tutorial, you will learn about C# methods.In object oriented programming, we work with objects. Objects are the basic building blocks of a program. Objects consists of data and methods. Methods change the state of the objects created. They are the dynamic part of the objects; data is the static part.
A method is a code block containing a series of statements. Methods must be declared within a class or a structure. It is a good programming practice that methods do only one specific task. Methods bring modularity to programs. Proper use of methods bring the following advantages:
- Reducing duplication of code
- Decomposing complex problems into simpler pieces
- Improving clarity of the code
- Reuse of code
- Information hiding
- Access level
- Return value type
- Method name
- Method parameters
- Parentheses
- Block of statements
void keyword to indicate, that our method does not return values. Method parameters are surrounded by parentheses, and separated by commas. Empty parentheses indicate that the method requires no parameters. The method block is surrounded with { } characters. The block contains one or more statements, that are executed, when the method is invoked. It is legal to have an empty method block. A method signature is a unique identification of a method for the C# compiler. The signature consists of a method name, and the type and kind (value, reference, or output) of each of its formal parameters. Method signature does not include the return type.
Simple example
We start with a simple example.using System;We have a
public class Base
{
public void ShowInfo()
{
Console.WriteLine("This is Base class");
}
}
public class CSharpApp
{
static void Main()
{
Base bs = new Base();
bs.ShowInfo();
}
}
ShowInfo() method, that prints the name of its class. public class BaseEach method must be defined inside a class. Or a struct. It must have a name. In our case the name is ShowInfo. The keywords that precede the name of the method are access specifier and the return type. Parentheses follow the name of the method. They may contain parameters of the method. Our method does not take any parameters.
{
public void ShowInfo()
{
Console.WriteLine("This is Base class");
}
}
static void Main()This is the Main() method. It is the entry point to each console or GUI C# application. It must be declared
{
...
}
static. We will see later why. The return type for a Main() method may be void or int. The access specifier for the Main() method is omitted. In such a case a default one is used, which is private. It is not recommended to use public access specifier for a Main() method. It is not supposed to be called by any other methods in the assemblies. It is only the CLR that should be able to call it when the application starts. Base bs = new Base();We create an instance of the Base class. We call the ShowInfo() method upon the object. We say, that the method is an instance method. Because it needs the instance to be called. The method is called by specifying the object instance, followed by the member access operator, the dot, followed by the method name.
bs.ShowInfo();
Method parameters
Parameters A parameter is a value passed to the method. Methods can take one or more parameters. If methods work with data, we must pass the data to the methods. We do it by specifying them inside the parentheses. In the method definition, we must provide a name and type for each parameter.using System;In the above example, we have two methods. One of them takes two parameters, the other one takes three parameters.
public class Addition
{
public int AddTwoValues(int x, int y)
{
return x + y;
}
public int AddThreeValues(int x, int y, int z)
{
return x + y + z;
}
}
public class CSharpApp
{
static void Main()
{
Addition a = new Addition();
int x = a.AddTwoValues(12, 13);
int y = a.AddThreeValues(12, 13, 14);
Console.WriteLine(x);
Console.WriteLine(y);
}
}
public int AddTwoValues(int x, int y)The AddTwoValues() method takes two parameters. These parameters have
{
return x + y;
}
int type. The method also returns an integer to the caller. We use the return keyword to return a value from the method. public int AddThreeValues(int x, int y, int z)The AddThreeValues() is similar to the previous method. It takes three parameters.
{
return x + y + z;
}
int x = a.AddTwoValues(12, 13);We call the AddTwoValues() method of the addition object. It takes two values. These values are passed to the method. The method returns a value, which is assigned to the x variable.
Variable number of arguments A method can take variable number of arguments. For this we use the
params keyword. No additional parameters are permitted after the params keyword. Only one params keyword is permitted in a method declaration. using System;We create a Sum() method, which can take variable number of arguments. The method will calculate the sum of values passed to the method.
public class CSharpApp
{
static void Main()
{
Sum(1, 2, 3);
Sum(1, 2, 3, 4, 5);
}
static void Sum(params int[] list)
{
Console.WriteLine("There are {0} items", list.Length);
int sum = 0;
foreach (int i in list)
{
sum = sum + i;
}
Console.WriteLine("Their sum is {0}", sum);
}
}
Sum(1, 2, 3);We call the Sum() method twice. In one case, it takes 3 arguments, in the second case 5. We call the same method.
Sum(1, 2, 3, 4, 5);
static void Sum(params int[] list)The Sum() method can take variable number of integer values. All values are added to the list array.
{
...
}
Console.WriteLine("There are {0} items", list.Length);
We print the length of the list array. int sum = 0;We compute the sum of the values in the list.
foreach (int i in list)
{
sum = sum + i;
}
$ ./variableparams.exeOutput of the example.
There are 3 items
Their sum is 6
There are 5 items
Their sum is 15
Anonymous methods
Anonymous methods are inline methods that do not have a name. Anonymous methods reduce the coding overhead by eliminating the need to create a separate method. Without anonymous methods developers often had to create a class just to call one method.using System;We create a timer object and every 2 seconds we call an anonymous method.
using System.Timers;
public class CSharpApp
{
static void Main()
{
Timer timer = new Timer();
timer.Elapsed += new ElapsedEventHandler(
delegate(object source, ElapsedEventArgs e)
{
Console.WriteLine("Event triggered at {0}", e.SignalTime);
}
);
timer.Interval = 2000;
timer.Enabled = true;
Console.ReadLine();
}
}
Timer timer = new Timer();A
Timer class generates recurring events in an application. timer.Elapsed += new ElapsedEventHandler(Here we plug the anonymous method to the
delegate(object source, ElapsedEventArgs e)
{
Console.WriteLine("Event triggered at {0}", e.SignalTime);
}
);
Elapsed event. The delegate keyword is used to denote an anonymous method. Passing arguments by value, by reference
C# supports two ways of passing arguments to methods. By value and by reference. The default passing of arguments is by value. When we pass arguments by value, the method works only with the copies of the values. This may lead to performance overheads, when we work with large amounts of data.We use the
ref keyword to pass a value by reference. When we pass values by reference, the method receives a reference to the actual values. The original values are affected, when modified. This way of passing values is more time and space efficient. On the other hand, it is more error prone. Which way of passing arguments should we use? It depends on the situation. Say we have a set of data, salaries of employees. If we want to compute some statistics of the data, we do not need to modify them. We pass by values. If we work with large amounts of data and the speed of computation is critical, we pass by reference. If we want to modify the data, e.g. do some reductions or raises to the salaries, we might pass by reference.
Passing by values The following example shows how we pass arguments by values.
using System;The Swap() method swaps the numbers between the a, b variables. The original variables are not affected.
public class CSharpApp
{
static int a = 4;
static int b = 7;
static void Main()
{
Console.WriteLine("Outside Swap method");
Console.WriteLine("a is {0}", a);
Console.WriteLine("b is {0}", b);
Swap(a, b);
Console.WriteLine("Outside Swap method");
Console.WriteLine("a is {0}", a);
Console.WriteLine("b is {0}", b);
}
static void Swap(int a, int b)
{
int temp;
temp = a;
a = b;
b = temp;
Console.WriteLine("Inside Swap method");
Console.WriteLine("a is {0}", a);
Console.WriteLine("b is {0}", b);
}
}
static int a = 4;At the beginning, these two variables are initiated. The variables must be declared
static int b = 7;
static, because they are used from static methods. Swap(a, b);We call the Swap() method. The method takes a, b variables as arguments.
temp = a;Inside the Swap() method, we change the values. Note that the a, b variables are defined locally. They are valid only inside the Swap() method.
a = b;
b = temp;
$ ./swapbyval.exeThe output shows, that the original variables were not affected.
Outside Swap method
a is 4
b is 7
Inside Swap method
a is 7
b is 4
Outside Swap method
a is 4
b is 7
Passing by reference The next code example passes values to the method by reference. The original variables are changed inside the Swap() method. Both the method definition and the method call must use the
ref keyword. using System;In this example, calling the Swap() method will change the original values.
public class CSharpApp
{
static int a = 4;
static int b = 7;
static void Main()
{
Console.WriteLine("Outside Swap method");
Console.WriteLine("a is {0}", a);
Console.WriteLine("b is {0}", b);
Swap(ref a, ref b);
Console.WriteLine("Outside Swap method");
Console.WriteLine("a is {0}", a);
Console.WriteLine("b is {0}", b);
}
static void Swap(ref int a, ref int b)
{
int temp;
temp = a;
a = b;
b = temp;
Console.WriteLine("Inside Swap method");
Console.WriteLine("a is {0}", a);
Console.WriteLine("b is {0}", b);
}
}
Swap(ref a, ref b);We call the method with two arguments. They are preceded by the
ref keyword to indicate, that we are passing arguments by reference. static void Swap(ref int a, ref int b)Also in the method declaration, we use the
{
...
}
ref keyword to inform the compiler that we accept references to the parameters, and not values. $ ./swapbyref.exeHere we see, that the Swap() method really changed the values of the variables.
Outside Swap method
a is 4
b is 7
Inside Swap method
a is 7
b is 4
Outside Swap method
a is 7
b is 4
The out keyword The
out keyword is similar to the ref keyword. The difference is that when using the ref keyword, the variable must be initialized before it is being passed. With the out keyword, it may not be initialized. Both the method definition and the method call must use the out keyword. using System;An example shows the usage of the
public class CSharpApp
{
static void Main()
{
int val;
SetValue(out val);
Console.WriteLine(val);
}
static void SetValue(out int i)
{
i = 12;
}
}
out keyword. int val;The val variable is declared, but not initialized. We pass the variable to the SetValue() method.
SetValue(out val);
static void SetValue(out int i)Inside the SetValue() method it is assigned a value, which is later printed to the console.
{
i = 12;
}
Method overloading
Method overloading allows the creation of several methods with the same name which differ from each other in the type of the input.What is method overloading good for? The Qt4 library gives a nice example for the usage. The QPainter class has three methods to draw a rectangle. Their name is drawRect() and their parameters differ. One takes a reference to a floating point rectangle object, another takes a reference to an integer rectangle object and the last one takes four parameters, x, y, width, height. If the C++ language, which is the language in which Qt is developed, didn't have method overloading, the creators of the library would have to name the methods like drawRectRectF(), drawRectRect(), drawRectXYWH(). The solution with method overloading is more elegant.
using System;We have three methods called GetSum(). They differ in input parameters.
public class Sum
{
public int GetSum()
{
return 0;
}
public int GetSum(int x)
{
return x;
}
public int GetSum(int x, int y)
{
return x + y;
}
}
public class CSharpApp
{
public static void Main()
{
Sum s = new Sum();
Console.WriteLine(s.GetSum());
Console.WriteLine(s.GetSum(20));
Console.WriteLine(s.GetSum(20, 30));
}
}
public int GetSum(int x)This one takes one parameter.
{
return x;
}
Console.WriteLine(s.GetSum());We call all three methods.
Console.WriteLine(s.GetSum(20));
Console.WriteLine(s.GetSum(20, 30));
$ ./overloading.exeAnd this is what we get, when we run the example.
0
20
50
Recursion
Recursion, in mathematics and computer science, is a way of defining methods in which the method being defined is applied within its own definition. In other words, a recursive method calls itself to do its job. Recursion is a widely used approach to solve many programming tasks.A typical example is calculation of the factorial.
using System;In this code example, we calculate the factorial of two numbers.
public class CSharpApp
{
static void Main()
{
Console.WriteLine(Factorial(6));
Console.WriteLine(Factorial(10));
}
static int Factorial(int n)
{
if (n == 0)
{
return 1;
} else
{
return n * Factorial(n-1);
}
}
}
return n * Factorial(n-1);Inside the body of the factorial method, we call the factorial method with a modified argument. The function calls itself.
$ ./recursion.exeThese are the results.
720
3628800
Method scope
Scope A variable declared inside a method has a method scope. The scope of a name is the region of program text within which it is possible to refer to the entity declared by the name without qualification of the name. A variable which is declared inside a method has a method scope. It is also called a local scope. The variable is valid only in this particular method.using System;In the preceding example, we have an x variable defined outside the Show() method. The variable has a class scope. It is valid everywhere inside the definition of the Test class. In other words, between its curly brackets.
public class Test
{
int x = 1;
public void Show()
{
Console.WriteLine(this.x);
Console.WriteLine(x);
}
}
public class CSharpApp
{
static void Main()
{
Test ts = new Test();
ts.Show();
}
}
public void Show()The x variable, also called the x field is an instance variable. And so it is accessible through the
{
Console.WriteLine(this.x);
Console.WriteLine(x);
}
this keyword. It is also valid inside the Show() method and can be referred by its bare name. Both statements refer to the same variable. $ ./methodscope.exeOutput.
1
1
Shadowing A variable defined inside a method has a local/method scope. If a local variable has the same name as a class variable, it shadows the class variable. The class variable is still accessible inside the method by using the
this keyword. using System;In the preceding example, we declare the x variable outside the Show() method and inside the Show() method. Both variables have the same identifiers, but they are not in conflict. Because they live in different scopes.
public class Test
{
int x = 1;
public void Show()
{
int x = 3;
Console.WriteLine(this.x);
Console.WriteLine(x);
}
}
public class CSharpApp
{
static void Main()
{
Base bs = new Base();
bs.Show();
}
}
Console.WriteLine(this.x);The variables are accessed differently. The x variable defined inside the method, also called the local variable is simply accessed by its name. The class variable can be referred by using the
Console.WriteLine(x);
this keyword. $ ./methodscope2.exeOutput.
1
3
Static methods & variables
Static methods Static methods are called without an instance of the object. To call a static method, we use the name of the class and the dot operator. Static methods can only work with static variables. Static methods are often used to represent data or calculations that do not change in response to object state. An example is a math library, which contains static methods for various calculations. We use thestatic keyword to declare a static method or a static variable. When no static modifier is present, the method is said to be an instance method. We cannot use the this keyword in static methods. It can be used in instance methods only. using System;In our code example, we define a static ShowInfo() method.
public class Basic
{
static int Id = 2321;
public static void ShowInfo()
{
Console.WriteLine("This is Basic class");
Console.WriteLine("The Id is: {0}", Id);
}
}
public class CSharpApp
{
static void Main()
{
Basic.ShowInfo();
}
}
static int Id = 2321;A static method can only work with static variables.
public static void ShowInfo()This is our static ShowInfo() method. It works with a static Id member.
{
Console.WriteLine("This is Basic class");
Console.WriteLine("The Id is: {0}", Id);
}
Basic.ShowInfo();To invoke a static method, we do not need an object instance. We call the method by using the name of the class and the dot operator.
$ ./staticmethod.exeOutput of the example.
This is Basic class
The Id is: 2321
Static variable A static variable belongs to the class and not to the object of the class. C# supports only static class members. Static method members are not supported in C#.
using System;The Math is a built-in class which provides some methods and members. One of them is the PI value, which is a static member. It is accessed using the Math class name and the dot operator.
public class CSharpApp
{
static void Main()
{
Console.WriteLine(Math.PI);
}
}
$ ./static.exe
3.14159265358979
Static Main() method The Main() method is an entry point to the C# console and GUI application. In C#, the Main() method is required to be static. Before the application starts, no object is created yet. To invoke non-static methods, we need to have an object instance. Static methods exist before a class is instantiated so static is applied to the main entry point.
Hiding methods
When a derived class inherits from a base class, it can define methods, that are already present in the base class. We say, that we hide the method of the class, that we have derived from. To explicitly inform the compiler about our intention to hide a method, we use thenew keyword. Without this keyword, the compiler issues a warning. using System;We have two classes. The Derived and the Base class. The Derived class inherits from the Base class. Both have a method called Info().
public class Base
{
public void Info()
{
Console.WriteLine("This is Base class");
}
}
public class Derived : Base
{
public new void Info()
{
base.Info();
Console.WriteLine("This is Derived class");
}
}
public class CSharpApp
{
static void Main()
{
Derived d = new Derived();
d.Info();
}
}
public class Derived : BaseThe : character is used to inherit from a class.
{
...
}
public new void Info()This is an implementation of the Info() method in the Derived class. We use the
{
base.Info();
Console.WriteLine("This is Derived class");
}
new keyword to inform the compiler about hiding a method from the base class. Note, that we can still reach the original Info() method. With the help of the base keyword, we invoke the Info() method of the Base class too. $ ./hidingmethods.exeWe have invoked both methods.
This is Base class
This is Derived class
Overriding methods
Now we will introduce two new keywords. Thevirtualkeyword and the override keyword. They are both method modifiers. They are used to implement polymorphic behaviour of objects. The virtual keyword creates a virtual method. These methods can be redefined in the derived classes. Later in the derived class we use the override keyword to redefine the method in question. If the method in the derived class is preceded with the overridekeyword, objects of the derived class will call that method rather than the base class method. using System;We create an array of the Base and Derived objects. We go through the array and invoke the Info() method upon all of them.
public class Base
{
public virtual void Info()
{
Console.WriteLine("This is Base class");
}
}
public class Derived : Base
{
public override void Info()
{
Console.WriteLine("This is Derived class");
}
}
public class CSharpApp
{
static void Main()
{
Base[] objs = {new Base(), new Derived(), new Base(),
new Base(), new Base(), new Derived() };
foreach (Base obj in objs)
{
obj.Info();
}
}
}
public virtual void Info()This is the virtual method of the Base class. It is expected to be overridden in the derived classes.
{
Console.WriteLine("This is Base class");
}
public override void Info()We override the base Info() method in the Derived class. We use the
{
Console.WriteLine("This is Derived class");
}
override keyword. Base[] objs = {new Base(), new Derived(), new Base(),
new Base(), new Base(), new Derived() };
Here we create an array of Base and Derived objects. Note that we used the Base type in our array declaration. This is because a Derived class can be converted to the Base class, because it inherits from it. The opposite is not true. The only way to have both objects in one array is to use a type which is top most in the inheritance hierarchy for all possible objects. foreach (Base obj in objs)We traverse the array and call Info() on all objects in the array.
{
obj.Info();
}
$ ./virtualmethods.exeThis is the output.
This is Base class
This is Derived class
This is Base class
This is Base class
This is Base class
This is Derived class
Now change the
override keyword for new keyword. Compile the example again and run it. $ ./virtualmethods.exeThis time we have a different output.
This is Base class
This is Base class
This is Base class
This is Base class
This is Base class
This is Base class
Sealed methods
A sealed method overrides an inherited virtual method with the same signature. A sealed method shall also be marked with the override modifier. Use of thesealed modifier prevents a derived class from further overriding the method. The word further is important. First, a method must be virtual. It must be later overridden. And at this point, it can be sealed. using System;In the preceding example, we seal method G() in class B.
public class A
{
public virtual void F()
{
Console.WriteLine("A.F");
}
public virtual void G()
{
Console.WriteLine("A.G");
}
}
public class B : A
{
public override void F()
{
Console.WriteLine("B.F");
}
public sealed override void G()
{
Console.WriteLine("B.G");
}
}
public class C : B
{
public override void F()
{
Console.WriteLine("C.F");
}
/*public override void G()
{
Console.WriteLine("C.G");
}*/
}
public class CSharpApp
{
static void Main()
{
B b = new B();
b.F();
b.G();
C c = new C();
c.F();
c.G();
}
}
public sealed override void G()Method G() overrides a method with the same name in the ancestor of the B class. It is also sealed to prevent from further overriding the method.
{
Console.WriteLine("B.G");
}
/*public override void G()These lines are commented, because otherwise the code example would not compile. The Mono compiler would give the following error: sealedmethods.cs(36,26): error CS0239: `C.G()': cannot override inherited member `B.G()' because it is sealed.
{
Console.WriteLine("C.G");
}*/
c.G();This line prints "B.G()" to the console.
$ ./sealedmethods.exeThis is the output.
B.F
B.G
C.F
B.G
In this part of the C# tutorial, we covered methods.
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