C++中运算符重载详解及其作用介绍

概述

运算符重载 (Operator Overloading)

在这里插入图片描述

函数重载

重载: 将同一名字重新赋予新的含义.

函数重载: 对一个函数赋予新的含义, 使之实现新功能. 例如:

int max(int x, int y);

double max(double a, double b, double c);

运算符也有重载: 赋予运算符新的含义, 使之一名多用. 例如

int main() {

int i = 2, j = 3;

int k = i + j;

string s1 = "good ", s2 = "morning";

string s3 = s1 + s2;

cout << k << endl;

cout << s3 << endl;

return 0;

}

输出结果:

5

good morning

运算符重载

通过运算符重载, 扩大了 C++ 已有运算符的作用, 使运算符能用于类对象. 使用运算符重载, 能使程序易于编写, 阅读和维护. 运算符被重载后, 其原有的功能仍然保留, 没有丧失过改变.

运算符重载实质上是函数的重载:

  • 定义一个重载运算符的函数
  • 需要执行被重载的运算符时, 系统就自动调用该函数, 以实现相应的运算

C++ 的运算符

  1. 算数运算符: +(加) -(减) *(乘) %(整除余数) ++(自加) – (自减)
  2. 关系运算符: >(大于) <(小于) ==(等于) >=(大于等于) <=(小于等于) !=(不等于)
  3. 逻辑运算符: &&(逻辑与) ||(逻辑或) !(逻辑非)
  4. 位运算符: <<(按位左移) >>(按位右移) &(按位与) |(按位或) ∧(按位异或) ~(按位取反)
  5. 赋值运算符: = 及其扩展赋值运算符
  6. 条件运算符: ?:
  7. 都好运算符: ,
  8. 指针运算符: *
  9. 引用运算符合地址运算符: &
  10. 求字节数运算符: sizeof
  11. 强制类型转换运算符: (类型) 或 类型()
  12. 成员运算符: .
  13. 指向成员的运算符:->
  14. 下标运算符: []
  15. 其他: 如函数调用运算符 ()

重载运算符的规则

  • 不允许创造新的运算符, 只能对已有 C++ 运算符进行重载.
  • C++ 允许重载运算符: 成员运算符(.), 成员指针访问运算符(.*), 域运算符(:😃, 求字节数运算符(sizeof), 条件运算符(?😃
  • 重载不能改变运算符运算对象 (即操作数) 的个数
  • 重载不能改变运算符的优先级别
  • 重载不能改变运算符的结合性
  • 重载运算符的函数不能有默认的参数
  • 重载的运算符必须和用户定义的自定义类型的对象一起使用. 参数至少有一个是类对象或其 引用

成员函数实现 Complex 加法

Complex 类:

#ifndef PROJECT2_COMPLEX_H

#define PROJECT2_COMPLEX_H

class Complex {

private:

double real;

double imag;

public:

Complex();

Complex(double r, double i);

Complex add(Complex &c2);

void display();

};

#endif //PROJECT2_COMPLEX_H

Complex.cpp:

#include <iostream>

#include "Complex.h"

using namespace std;

Complex::Complex() : real(0), imag(0) {}

Complex::Complex(double r, double i) : real(r), imag(i) {}

Complex Complex::add(Complex &c2) {

Complex c;

c.real = real + c2.real;

c.imag = imag + c2.imag;

return c;

}

void Complex::display() {

cout << "(" << real << ", ";

cout << imag << "i)" << endl;

}

main:

int main() {

Complex c1(3, 4), c2(5, -10), c3;

cout << "c1 =";

c1.display();

cout << "c2 =";

c2.display();

c3 = c1.add(c2);

cout << "c1 + c2 = ";

c3.display();

return 0;

}

输出结果:

c1 =(3, 4i)

c2 =(5, -10i)

c1 + c2 = (8, -6i)

运算符重载的方法

运算符重载格式:

函数类型 operator 运算符名称 (形参流标) {对运算符的重载处理}

Complex 类:

#ifndef PROJECT4_COMPLEX_H

#define PROJECT4_COMPLEX_H

class Complex {

private:

double real;

double imag;

public:

Complex();

Complex(double, double);

void display();

Complex operator+(Complex &c2);

};

#endif //PROJECT4_COMPLEX_H

Complex.cpp:

#include <iostream>

#include "Complex.h"

using namespace std;

Complex::Complex() : real(0), imag(0) {}

Complex::Complex(double r, double i) :real(r), imag(i) {}

void Complex::display() {

cout << "(" << real << ", ";

cout << imag << "i)" << endl;

}

Complex Complex::operator+(Complex &c2) {

Complex c;

c.real = real + c2.real;

c.imag = imag + c2.imag;

return c;

}

main:

#include <iostream>

#include "Complex.h"

using namespace std;

int main() {

Complex c1(3, 4), c2(5, -10), c3;

cout << "c1 =";

c1.display();

cout << "c2 =";

c2.display();

c3 = c1 + c2;

cout << "c1 + c2 = ";

c3.display();

return 0;

}

输出结果:

c1 =(3, 4i)

c2 =(5, -10i)

c3= (8, -6i)

多种实现方法

成员函数实现:

Complex Complex::operator+(Complex &c2) {

Complex c;

c.real = real + c2.real;

c.imag = imag + c2.imag;

return c;

}

简化:

Complex Complex::operator+(Complex &c2){

return Complex(real +c2.real, imag + c2.image);

}

友元函数实现:

Complex operator+(Complex &c1, Complex &c2){

......

}

实现 operator+=

Complex 类:

#ifndef PROJECT4_COMPLEX_H

#define PROJECT4_COMPLEX_H

class Complex {

private:

double real;

double imag;

public:

Complex();

Complex(double, double);

void display();

Complex operator+=(const Complex &c);

};

#endif //PROJECT4_COMPLEX_H

Complex.cpp:

#include <iostream>

#include "Complex.h"

using namespace std;

Complex::Complex() : real(0), imag(0) {}

Complex::Complex(double r, double i) :real(r), imag(i) {}

void Complex::display() {

cout << "(" << real << ", ";

cout << imag << "i)" << endl;

}

Complex Complex::operator+=(const Complex &c) {

real += c.real; // this->real += c.real;

imag += c.imag; // this->imag += c.imag;

return *this;

}

main:

#include <iostream>

#include "Complex.h"

using namespace std;

int main() {

Complex c1(3, 4), c2(5, -10), c3;

cout << "c1 =";

c1.display();

cout << "c2 =";

c2.display();

c1 += c2;

cout << "c1= ";

c1.display();

return 0;

}

输出结果:

c1 =(3, 4i)

c2 =(5, -10i)

c1= (8, -6i)

三种运算符重载函数

运算符重载函数可以是类的成员函数:

  • 它可以通过 this 指针自由地访问本类的数据成员. 少写一个函数的参数, 但有要求.

运算符重载函数可以是类的友元函数:

  • 如果运算符左侧的操作属于 C++ 标准类型 (如 int) 或是一个其他类的对象, 则运算符重载函数不能选用成员函数. 为方便访问类的私有成员, 声明为友元函数为佳.

运算符重载函数还可以是普通函数:

  • 只有极少的情况下才使用 (因普通函数一般不能直接访问类的私有成员)

成员函数实现

Complex 类:

#ifndef PROJECT4_COMPLEX_H

#define PROJECT4_COMPLEX_H

class Complex {

private:

double real;

double imag;

public:

Complex();

Complex(double, double);

void display();

Complex operator+(double d); // 成员函数实现

};

#endif //PROJECT4_COMPLEX_H

Complex.cpp:

#include <iostream>

#include "Complex.h"

using namespace std;

Complex::Complex() : real(0), imag(0) {}

Complex::Complex(double r, double i) :real(r), imag(i) {}

void Complex::display() {

cout << "(" << real << ", ";

cout << imag << "i)" << endl;

}

Complex Complex::operator+(double d) {

return Complex(real + d, imag);

}

友元函数实现

Complex 类:

#ifndef PROJECT4_COMPLEX_H

#define PROJECT4_COMPLEX_H

class Complex {

private:

double real;

double imag;

public:

Complex();

Complex(double, double);

void display();

friend Complex operator+(Complex &c, double d); // 友元函数

};

#endif //PROJECT4_COMPLEX_H

Complex.cpp:

#include <iostream>

#include "Complex.h"

using namespace std;

Complex::Complex() : real(0), imag(0) {}

Complex::Complex(double r, double i) :real(r), imag(i) {}

void Complex::display() {

cout << "(" << real << ", ";

cout << imag << "i)" << endl;

}

Complex operator+(Complex &c, double d) {

return Complex(c.real + d, c.imag);

}

输出结果

main:

#include <iostream>

#include "Complex.h"

using namespace std;

int main() {

Complex c1(3, 4), c2(5, -10), c3, c4;

cout << "c1 =";

c1.display();

cout << "c2 =";

c2.display();

c3 = c1 + 3.14;

cout << "c3= ";

c3.display();

return 0;

}

输出结果:

c1 =(3, 4i)

c2 =(5, -10i)

c3= (6.14, 4i)

重载单元运算符

单元运算符 (unary operation), 即只有一个运算量. 如: !a, -b, &c, *p, ++i, i-- 等.

例子

重载单元运算符实现分数对象的相反数.

Fraction 类:

#ifndef PROJECT4_FRACTION_H

#define PROJECT4_FRACTION_H

#include <iostream>

using namespace std;

class Fraction {

private:

int nume; // 分子

int deno; // 分母

public:

Fraction();

Fraction(int, int);

Fraction operator-(const Fraction &c); // 分数相减

Fraction operator-(); // 取反一目运算

friend ostream& operator<<(ostream &output, const Fraction &f);

};

#endif //PROJECT4_FRACTION_H

Fraction.cpp:

#include "Fraction.h"

Fraction::Fraction() : nume(0), deno(0) {}

Fraction::Fraction(int n , int d) : nume(n), deno(d) {}

Fraction Fraction::operator-(const Fraction &c) {

return Fraction(nume*c.deno - c.nume*deno, deno*c.deno);

}

Fraction Fraction::operator-() {

return Fraction(-nume, deno);

}

ostream& operator<<(ostream &output, const Fraction &f) {

double result = (double)f.nume / f.deno;

output << result << endl;

return output;

}

main:

#include <iostream>

#include "Fraction.h"

using namespace std;

int main() {

Fraction f1(1,3), f2(1,5), f3, f4;

f3 = f1 - f2; // 分数相减

f4 = -f1; // 分数取反

cout << f3;

cout << f4;

return 0;

}

输出结果:

0.133333

-0.333333

重载二元运算符

二元运算符 (binary operation).

  • 有两个操作数, 通常在运算符的左右两侧 (例如: 3+2, 5>8, x*=3)
  • 重载双目运算符时, 函数中应该有两个参数

在这里插入图片描述

例子

要求:

  • 定义字符串类 String, 用来存放不定长的字符串
  • 重载关系运算符, 用于两个字符串的比较运算

步骤:

  • 定义类的 “框架”
  • 完善运算符重载

String 类:

#ifndef PROJECT4_STRING_H

#define PROJECT4_STRING_H

#include <cstdlib>

class String {

private:

char *p;

public:

String(){p=nullptr;}

String(char *str);

void display();

};

#endif //PROJECT4_STRING_H

String.cpp:

#include <iostream>

#include <cstring>

#include "String.h"

using namespace std;

String::String(char *str) {

p = new char[sizeof(str)];

strcpy(p, str);

}

void String::display() {

cout << p;

}

main:

#include <iostream>

#include "String.h"

using namespace std;

int main() {

String s1("Hello");

String s2("China");

s1.display( );

cout<<" ";

s2.display( );

cout<<endl;

return 0;

}

输出结果:

Hello China

重载 I/O

通过重载输入流 (input stream) 和输出流 (output stream), 我们可以用来输出用户自己定义的数据.

格式:

ostream &operator<<(ostream&, const 自定义类&);

istream &operator>>(istream&,自定义类&);

在这里插入图片描述

插入运算符 <<

Complex 类:

#ifndef PROJECT4_COMPLEX_H

#define PROJECT4_COMPLEX_H

#include <iostream>

using namespace std;

class Complex {

private:

double real;

double imag;

public:

Complex();

Complex(double, double);

void display();

Complex operator+(Complex &c);

friend ostream& operator<<(ostream &output, const Complex &c);

};

#endif //PROJECT4_COMPLEX_H

Complex.cpp:

#include <iostream>

#include "Complex.h"

using namespace std;

Complex::Complex() : real(0), imag(0) {}

Complex::Complex(double r, double i) :real(r), imag(i) {}

void Complex::display() {

cout << "(" << real << ", ";

cout << imag << "i)" << endl;

}

Complex Complex::operator+(Complex &c) {

return Complex(real + c.real, imag + c.imag);

}

ostream &operator<<(ostream &output, const Complex &c) {

output<<"("<<c.real<<" + "<<c.imag<<"i)";

return output;

}

main:

#include <iostream>

#include "Complex.h"

using namespace std;

int main() {

Complex c1(2, 4),c2(6, 10),c3;

c3 = c1 + c2;

cout << c1 << " + " << c2 << " = " << c3 << endl;

return 0;

}

输出结果:

(2 + 4i) + (6 + 10i) = (8 + 14i)

提取运算符 >>

Complex 类:

#ifndef PROJECT4_COMPLEX_H

#define PROJECT4_COMPLEX_H

#include <iostream>

using namespace std;

class Complex {

private:

double real;

double imag;

public:

Complex();

Complex(double, double);

void display();

Complex operator+(Complex &c);

friend ostream& operator<<(ostream &output, const Complex &c);

friend istream& operator>>(istream &input, Complex &c);

};

#endif //PROJECT4_COMPLEX_H

Complex.cpp:

#include <iostream>

#include "Complex.h"

using namespace std;

Complex::Complex() : real(0), imag(0) {}

Complex::Complex(double r, double i) :real(r), imag(i) {}

void Complex::display() {

cout << "(" << real << ", ";

cout << imag << "i)" << endl;

}

Complex Complex::operator+(Complex &c) {

return Complex(real + c.real, imag + c.imag);

}

ostream &operator<<(ostream &output, const Complex &c) {

output<<"("<<c.real<<" + "<<c.imag<<"i)";

return output;

}

istream &operator>>(istream &input, Complex &c) {

cout << "input real part and imaginary part:\n";

input >> c.real >> c.imag;

return input;

}

main:

#include <iostream>

#include "Complex.h"

using namespace std;

int main() {

Complex c1, c2;

cin >> c1 >> c2;

cout << "c1=" << c1 << endl;

cout << "c2=" << c2 << endl;

return 0;

}

输出结果:

input real part and imaginary part:

2 4

input real part and imaginary part:

6 10

c1=(2 + 4i)

c2=(6 + 10i)

总结

运算符重载使类的设计更加丰富多彩, 扩大了类的功能和使用范围. 运算符重载使得程序易于理解, 易于对对象进行操作. 有了运算符重载, 在声明了类之后, 我们就可以像使用标准类型一样来使用自己声明的类.

类的声明往往是一劳永逸的. 有了好的类, 用户在程序中就不必定义许多成员函数去完成运算和 I/O 的功能, 使主函数更加简单易读. 好的运算符重载能细心啊面向对象程序设计思想.

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