Csharp/C Sharp/Class Interface/Class Method — различия между версиями

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Текущая версия на 11:38, 26 мая 2010

Add a method that takes two arguments

/*
C#: The Complete Reference 
by Herbert Schildt 
Publisher: Osborne/McGraw-Hill (March 8, 2002)
ISBN: 0072134852
*/
// Add a method that takes two arguments. 
 
using System; 
 
class ChkNum {  
  // Return true if x is prime. 
  public bool isPrime(int x) { 
    for(int i=2; i < x/2 + 1; i++) 
      if((x %i) == 0) return false; 
 
    return true; 
  } 
 
  // Return the least common denominator. 
  public int lcd(int a, int b) { 
    int max; 
 
    if(isPrime(a) | isPrime(b)) return 1; 
 
    max = a < b ? a : b; 
 
    for(int i=2; i < max/2 + 1; i++) 
      if(((a%i) == 0) & ((b%i) == 0)) return i; 
 
    return 1; 
  } 
}  
  
public class ParmDemo1 {  
  public static void Main() {  
    ChkNum ob = new ChkNum(); 
    int a, b; 
 
    for(int i=1; i < 10; i++) 
      if(ob.isPrime(i)) Console.WriteLine(i + " is prime."); 
      else Console.WriteLine(i + " is not prime."); 
 
    a = 7; 
    b = 8; 
    Console.WriteLine("Least common denominator for " + 
                      a + " and " + b + " is " + 
                      ob.lcd(a, b)); 
 
    a = 100; 
    b = 8; 
    Console.WriteLine("Least common denominator for " + 
                      a + " and " + b + " is " + 
                      ob.lcd(a, b)); 
 
    a = 100; 
    b = 75; 
    Console.WriteLine("Least common denominator for " + 
                      a + " and " + b + " is " + 
                      ob.lcd(a, b)); 
 
  }  
}


Add a method to Building

/*
C#: The Complete Reference 
by Herbert Schildt 
Publisher: Osborne/McGraw-Hill (March 8, 2002)
ISBN: 0072134852
*/
// Add a method to Building. 
  
using System;  
  
class Building {   
  public int floors;    // number of floors 
  public int area;      // total square footage of building 
  public int occupants; // number of occupants 
 
  // Display the area per person.  
  public void areaPerPerson() {  
    Console.WriteLine("  " + area / occupants + 
                      " area per person"); 
  }  
}   
 
// Use the areaPerPerson() method. 
public class BuildingDemo2 {   
  public static void Main() {   
    Building house = new Building();   
    Building office = new Building(); 
 
 
    // assign values to fields in house 
    house.occupants = 4;  
    house.area = 2500;  
    house.floors = 2;  
 
    // assign values to fields in office 
    office.occupants = 25;  
    office.area = 4200;  
    office.floors = 3;  
   
 
    Console.WriteLine("house has:\n  " + 
                      house.floors + " floors\n  " + 
                      house.occupants + " occupants\n  " + 
                      house.area + " total area"); 
    house.areaPerPerson(); 
 
    Console.WriteLine(); 
 
    Console.WriteLine("office has:\n  " + 
                      office.floors + " floors\n  " + 
                      office.occupants + " occupants\n  " + 
                      office.area + " total area"); 
    office.areaPerPerson(); 
  }   
}


A simple example of recursion

/*
C#: The Complete Reference 
by Herbert Schildt 
Publisher: Osborne/McGraw-Hill (March 8, 2002)
ISBN: 0072134852
*/

// A simple example of recursion.  
 
using System; 
 
class Factorial {  
  // This is a recursive function.  
  public int factR(int n) {  
    int result;  
  
    if(n==1) return 1;  
    result = factR(n-1) * n;  
    return result;  
  }  
  
  // This is an iterative equivalent.  
  public int factI(int n) {  
    int t, result;  
  
    result = 1;  
    for(t=1; t <= n; t++) result *= t;  
    return result;  
  }  
}  
  
public class Recursion {  
  public static void Main() {  
    Factorial f = new Factorial();  
  
    Console.WriteLine("Factorials using recursive method.");  
    Console.WriteLine("Factorial of 3 is " + f.factR(3));  
    Console.WriteLine("Factorial of 4 is " + f.factR(4));  
    Console.WriteLine("Factorial of 5 is " + f.factR(5));  
    Console.WriteLine();  
 
    Console.WriteLine("Factorials using iterative method.");  
    Console.WriteLine("Factorial of 3 is " + f.factI(3));  
    Console.WriteLine("Factorial of 4 is " + f.factI(4));  
    Console.WriteLine("Factorial of 5 is " + f.factI(5));  
  }  
}


A simple example that uses a parameter

/*
C#: The Complete Reference 
by Herbert Schildt 
Publisher: Osborne/McGraw-Hill (March 8, 2002)
ISBN: 0072134852
*/
// A simple example that uses a parameter. 
 
using System; 
 
class ChkNum {  
  // Return true if x is prime. 
  public bool isPrime(int x) { 
    for(int i=2; i < x/2 + 1; i++) 
      if((x %i) == 0) return false; 
 
    return true; 
  } 
}  
  
public class ParmDemo {  
  public static void Main() {  
    ChkNum ob = new ChkNum(); 
 
    for(int i=1; i < 10; i++) 
      if(ob.isPrime(i)) Console.WriteLine(i + " is prime."); 
      else Console.WriteLine(i + " is not prime."); 
 
  }  
}


Automatic type conversions can affect overloaded method resolution

/*
C#: The Complete Reference 
by Herbert Schildt 
Publisher: Osborne/McGraw-Hill (March 8, 2002)
ISBN: 0072134852
*/

/* Automatic type conversions can affect 
   overloaded method resolution. */ 
 
using System; 
 
class Overload2 { 
  public void f(int x) { 
    Console.WriteLine("Inside f(int): " + x); 
  } 
 
  public void f(double x) { 
    Console.WriteLine("Inside f(double): " + x); 
  } 
} 
 
public class TypeConv { 
  public static void Main() { 
    Overload2 ob = new Overload2(); 
 
    int i = 10; 
    double d = 10.1; 
 
    byte b = 99; 
    short s = 10; 
    float f = 11.5F; 
 
 
    ob.f(i); // calls ob.f(int) 
    ob.f(d); // calls ob.f(double) 
 
    ob.f(b); // calls ob.f(int) -- type conversion 
    ob.f(s); // calls ob.f(int) -- type conversion 
    ob.f(f); // calls ob.f(double) -- type conversion 
  } 
}


Call class methods 2

/*
Learning C# 
by Jesse Liberty
Publisher: O"Reilly 
ISBN: 0596003765
*/
 using System;
 public class MyTime1 {
     // private member variables
     int year;
     int month;
     int date;
     int hour;
     int minute;
     int second;
     // public method
     public void DisplayCurrentTime()
     {
         System.Console.WriteLine("{0}/{1}/{2} {3}:{4}:{5}",
             month, date, year, hour, minute, second);
     }
     // constructor
     public MyTime1(int theYear, int theMonth, int theDate,
         int theHour, int theMinute, int theSecond)
     {
         year = theYear;
         month = theMonth;
         date = theDate;
         hour = theHour;
         minute = theMinute;
         second = theSecond;
     }
     static void Main()
     {
         MyTime1 timeObject = new MyTime1(2005,3,25,9,35,20);
         timeObject.DisplayCurrentTime();
     }
 }


C# Classes Member Functions

using System;
public class MemberFunctions
{
    public static void Main()
    {
        Point myPoint = new Point(10, 15);
        Console.WriteLine("myPoint.X {0}", myPoint.GetX());
        Console.WriteLine("myPoint.Y {0}", myPoint.GetY());
    }
}
class Point
{
    public Point(int x, int y)
    {
        this.x = x;
        this.y = y;
    }
    
    // accessor functions
public int GetX() {return(x);}
public int GetY() {return(y);}
    
    // variables now private
    int x;
    int y;
}


change field value in a method

 
using System;
public class Foo
{
    public int i;
}
   
class RefTest2App
{
    public static void ChangeValue(Foo f)
    {
        f.i = 42;
    }
   
    static void Main(string[] args)
    {
        Foo test = new Foo();
        test.i = 6;
   
        Console.WriteLine("BEFORE METHOD CALL");
        Console.WriteLine("test.i={0}", test.i);
        Console.WriteLine();
   
        ChangeValue(test);
   
        Console.WriteLine("AFTER METHOD CALL");
        Console.WriteLine("test.i={0}", test.i);
    }
}


Class a class method

/*
Learning C# 
by Jesse Liberty
Publisher: O"Reilly 
ISBN: 0596003765
*/
 using System;
 class MyClass
 {
     public void SomeMethod(int firstParam, float secondParam)
     {
         Console.WriteLine(
             "Here are the parameters received: {0}, {1}",
             firstParam, secondParam);
     }
 }
 public class Tester111
 {
     static void Main()
     {
         int howManyPeople = 5;
         float pi = 3.14f;
         MyClass mc = new MyClass();
         mc.SomeMethod(howManyPeople, pi);
     }
 }


Define methods that return a value and accept parameters

/*
Mastering Visual C# .NET
by Jason Price, Mike Gunderloy
Publisher: Sybex;
ISBN: 0782129110
*/
/*
  Example5_3.cs illustrates how to define methods
  that return a value and accept parameters
*/

// declare the Car class
class Car
{
  public int yearBuilt;
  public double maximumSpeed;
  // the Age() method calculates and returns the
  // age of the car in years
  public int Age(int currentYear)
  {
    int age = currentYear - yearBuilt;
    return age;
  }
  // the Distance() method calculates and returns the
  // distance traveled by the car, given its initial speed,
  // maximum speed, and time for the journey
  // (assuming constant acceleration of the car)
  public double Distance(double initialSpeed, double time)
  {
    return (initialSpeed + maximumSpeed) / 2 * time;
  }
}

public class Example5_3
{
  public static void Main()
  {
    // declare a Car object reference and
    // create a Car object
    System.Console.WriteLine("Creating a Car object and " +
      "assigning its memory location to redPorsche");
    Car redPorsche = new Car();
    // assign values to the fields
    redPorsche.yearBuilt = 2000;
    redPorsche.maximumSpeed = 150;
    // call the methods
    int age = redPorsche.Age(2001);
    System.Console.WriteLine("redPorsche is " + age + " year old.");
    System.Console.WriteLine("redPorsche travels " +
      redPorsche.Distance(31, .25) + " miles.");
  }
}


Demonstrate method overloading

/*
C#: The Complete Reference 
by Herbert Schildt 
Publisher: Osborne/McGraw-Hill (March 8, 2002)
ISBN: 0072134852
*/

// Demonstrate method overloading.  
 
using System; 
 
class Overload {  
  public void ovlDemo() {  
    Console.WriteLine("No parameters");  
  }  
  
  // Overload ovlDemo for one integer parameter.  
  public void ovlDemo(int a) {  
    Console.WriteLine("One parameter: " + a);  
  }  
  
  // Overload ovlDemo for two integer parameters.  
  public int ovlDemo(int a, int b) {  
    Console.WriteLine("Two parameters: " + a + " " + b);  
    return a + b; 
  }  
  
  // Overload ovlDemo for two double parameters.  
  public double ovlDemo(double a, double b) { 
    Console.WriteLine("Two double parameters: " + 
                       a + " "+ b);  
    return a + b;  
  }  
}  
  
public class OverloadDemo {  
  public static void Main() {  
    Overload ob = new Overload();  
    int resI; 
    double resD;      
  
    // call all versions of ovlDemo()  
    ob.ovlDemo();   
    Console.WriteLine(); 
 
    ob.ovlDemo(2);  
    Console.WriteLine(); 
 
    resI = ob.ovlDemo(4, 6);  
    Console.WriteLine("Result of ob.ovlDemo(4, 6): " + 
                       resI);  
    Console.WriteLine(); 
 
 
    resD = ob.ovlDemo(1.1, 2.32);  
    Console.WriteLine("Result of ob.ovlDemo(1.1, 2.2): " + 
                       resD);  
  }  
}


Method Attributes

 
using System;
using System.Reflection;
public class TransactionableAttribute : Attribute {
    public TransactionableAttribute() {
    }
}
class SomeClass {
    [Transactionable]
    public void Foo() { }
    public void Bar() { }
    [Transactionable]
    public void Goo() { }
}
class Test {
    [STAThread]
    static void Main(string[] args) {
        Type type = Type.GetType("SomeClass");
        foreach (MethodInfo method in type.GetMethods()) {
            foreach (Attribute attr in
                method.GetCustomAttributes(true)) {
                if (attr is TransactionableAttribute) {
                    Console.WriteLine(method.Name);
                }
            }
        }
    }
}


Method overloading test

/*
Learning C# 
by Jesse Liberty
Publisher: O"Reilly 
ISBN: 0596003765
*/
 using System;
 namespace MethodOverloading
 {
     public class Time1
     {
         // private member variables
         private int Year;
         private int Month;
         private int Date;
         private int Hour;
         private int Minute;
         private int Second;
         // public accessor methods
         public void DisplayCurrentTime()
         {
             System.Console.WriteLine("{0}/{1}/{2} {3}:{4}:{5}",
                 Month, Date, Year, Hour, Minute, Second);
         }
         // constructors
         public Time1(System.DateTime dt)
         {
             Year =      dt.Year;
             Month =     dt.Month;
             Date =      dt.Day;
             Hour =      dt.Hour;
             Minute =    dt.Minute;
             Second =    dt.Second;
         }
         public Time1(int Year, int Month, int Date,
             int Hour, int Minute, int Second)
         {
             this.Year =     Year;
             this.Month =    Month;
             this.Date =     Date;
             this.Hour =     Hour;
             this.Minute =   Minute;
             this.Second =   Second;
         }
     }
    public class MethodOverloadingTester
    {
       public void Run()
       {
           System.DateTime currentTime = System.DateTime.Now;
           Time1 time1 = new Time1(currentTime);
           time1.DisplayCurrentTime();
           Time1 time2 = new Time1(2000,11,18,11,03,30);
           time2.DisplayCurrentTime();
       }
       static void Main()
       {
          MethodOverloadingTester t = new MethodOverloadingTester();
          t.Run();
       }
    }
 }


Overloading Classes

/*
 * C# Programmers Pocket Consultant
 * Author: Gregory S. MacBeth
 * Email: gmacbeth@comporium.net
 * Create Date: June 27, 2003
 * Last Modified Date:
 */
using System;
namespace Client.Chapter_5___Building_Your_Own_Classes
{
  public class OverloadingClasses
  {
    static void Main(string[] args)
    {
      A MyA = new A();
      MyA.Display();
      MyA.Display(10);
    }
  }
  class A
  {
    public void Display()
    {
      Console.WriteLine("No Params Display Method");
    }
    public void Display(int A)
    {
      Console.WriteLine("Overloaded Display {0}", A);
    }
  }
}


Return an array

/*
C#: The Complete Reference 
by Herbert Schildt 
Publisher: Osborne/McGraw-Hill (March 8, 2002)
ISBN: 0072134852
*/

// Return an array. 
 
using System; 
 
class Factor { 
  /* Return an array containing the factors of num. 
     On return, numfactors will contain the number of 
     factors found. */ 
  public int[] findfactors(int num, out int numfactors) { 
    int[] facts = new int[80]; // size of 80 is arbitrary 
    int i, j; 
 
    // find factors and put them in the facts array 
    for(i=2, j=0; i < num/2 + 1; i++)  
      if( (num%i)==0 ) { 
        facts[j] = i; 
        j++; 
      } 
     
    numfactors = j; 
    return facts; 
  } 
} 
  
public class FindFactors { 
  public static void Main() {   
    Factor f = new Factor(); 
    int numfactors; 
    int[] factors; 
 
    factors = f.findfactors(1000, out numfactors); 
 
    Console.WriteLine("Factors for 1000 are: "); 
    for(int i=0; i < numfactors; i++) 
      Console.Write(factors[i] + " "); 
       
    Console.WriteLine();    
  } 
}


Use a class factory

/*
C#: The Complete Reference 
by Herbert Schildt 
Publisher: Osborne/McGraw-Hill (March 8, 2002)
ISBN: 0072134852
*/

// Use a class factory. 
 
using System; 
 
class MyClass { 
  int a, b; // private 
 
  // Create a class factory for MyClass. 
  public MyClass factory(int i, int j) { 
    MyClass t = new MyClass(); 
    
    t.a = i; 
    t.b = j; 
 
    return t; // return an object 
  } 
 
  public void show() { 
    Console.WriteLine("a and b: " + a + " " + b); 
  } 
 
} 
  
public class MakeObjects { 
  public static void Main() {   
    MyClass ob = new MyClass(); 
    int i, j; 
 
    // generate objects using the factory 
    for(i=0, j=10; i < 10; i++, j--) { 
      MyClass anotherOb = ob.factory(i, j); // make an object 
      anotherOb.show(); 
    } 
       
    Console.WriteLine();    
  } 
}