CSC/ECE 517 Fall 2007/wiki1 6 b2: Difference between revisions
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== C++ code == | |||
<pre> | |||
C++ | |||
class Staff{ | |||
public: | |||
string getSta() {return Sta_name;} | |||
void setSta(string a) {Sta_name=a;} | |||
void saySta() {cout<<getSta()<<" is working here!"<<endl;} | |||
private: | |||
string Sta_name; | |||
}; | |||
class Student{ | |||
public: | |||
string getStu() {return Stu_name;} | |||
void setStu(string u) {Stu_name=u;} | |||
void sayStu() {cout<<getStu()<<" is studying here!"<<endl;} | |||
private: | |||
string Stu_name; | |||
}; | |||
class Workstudy: public Student, public Staff{ | |||
public: | |||
string get() {return name;} | |||
void set(string w) {name= w; setSta(name); setStu(name);} | |||
void say() {Staff.saySta(); | |||
Student.sayStu(); | |||
cout<<"So, "<<get()<<" is a work-study student!"<<endl;} | |||
private: | |||
string name; | |||
}; | |||
int main(){ | |||
Workstudy* a=new Workstudy(); | |||
a->set("Moussa"); | |||
a->say(); | |||
return 0; | |||
} | |||
Output: | |||
>>Moussa is working here! | |||
>>Moussa is studying here! | |||
>>So, Moussa is a work-study student! | |||
>> | |||
</pre> | |||
== An example == | == An example == | ||
In Java, we may define “say” method as interface in Staff and Student and then implement them in class WorkStudy. | In Java, we may define “say” method as interface in Staff and Student and then implement them in class WorkStudy. | ||
Revision as of 21:56, 14 September 2007
C++ code
C++
class Staff{
public:
string getSta() {return Sta_name;}
void setSta(string a) {Sta_name=a;}
void saySta() {cout<<getSta()<<" is working here!"<<endl;}
private:
string Sta_name;
};
class Student{
public:
string getStu() {return Stu_name;}
void setStu(string u) {Stu_name=u;}
void sayStu() {cout<<getStu()<<" is studying here!"<<endl;}
private:
string Stu_name;
};
class Workstudy: public Student, public Staff{
public:
string get() {return name;}
void set(string w) {name= w; setSta(name); setStu(name);}
void say() {Staff.saySta();
Student.sayStu();
cout<<"So, "<<get()<<" is a work-study student!"<<endl;}
private:
string name;
};
int main(){
Workstudy* a=new Workstudy();
a->set("Moussa");
a->say();
return 0;
}
Output:
>>Moussa is working here!
>>Moussa is studying here!
>>So, Moussa is a work-study student!
>>
An example
In Java, we may define “say” method as interface in Staff and Student and then implement them in class WorkStudy.
Java solution
Staff.java
public interface staff {
void saySta();
}
Student.java
public interface student {
void sayStu();
}
WorkStudy.java
public class WorkStudy implements staff, student{
private String name;
WorkStudy(String name){
this.name=name;
}
public void saySta(){
System.out.println(name+" is working here!");
}
public void sayStu(){
System.out.println(name+" is studying here!");
}
public void say(){
saySta();
sayStu();
System.out.println("So, "+name+" is work-study student here!");
}
}
mainclass.java
public class mainclass {
/**
* @param args
*/
public static void main(String[] args) {
// TODO Auto-generated method stub
WorkStudy j;
j=new WorkStudy("Ying");
j.say();
}
}
Comparision with Java
Comparing with java, mixins has two advantages.
Firstly, mixins is like a “mix” of interface and abstract class. Interface is designed in Java to perform the act similar to “multiple inheritance” in C++. It is so purely abstract that either any implement of method or instant variable is not allowed. Meanwhile, abstract class may contain abstract method and non-abstract method but one class can only inherited from one super abstract class. Mixin here provides a more flexible way between them. We may implement methods in module or in class inherited from the module to reduce the code redundancy.
Secondly, the namespace provided by module helps dealing with the situation that a class inherits two methods from different modules with the same name. In Java, such act will throw out an error message.