explicit构造函数

explicit构造函数禁止了隐式的类型转换,防止由于隐式类型转换而造成的问题。

不允许被重载的运算符

不能重载的运算符只有5个:

.             (成员访问运算符)

.*            (成员指针访问运算符)

::             (域运算符)

sizeof    (长度运算符)

?:            (条件运算符)

几个特殊运算符重载的示例

/**
 * 运算符重载
 */
#include <bits/stdc++.h>
using namespace std;

class Counter
{
private:
    /* data */
    int counter;

public:
    Counter(/* args */);
    ~Counter();
    operator int() { return counter; }
    Counter &operator++()
    {
        counter++;
        return *this;
    };
    Counter operator++(int)
    {
        Counter tmp = *this;
        counter++;
        return tmp;
    };

    Counter &operator--()
    {
        this->counter--;
        return *this;
    };

    Counter operator--(int)
    {
        Counter pre(*this);
        counter--;
        return pre;
    };

    friend istream &operator>>(istream &is, Counter &obj)
    {
        is >> obj.counter;
        //允许级联调用
        return is;
    };

    friend ostream &operator<<(ostream &os, Counter &obj)
    {
        os<<obj.counter;
        //允许级联调用
        return os;
    };

};

Counter::Counter(/* args */)
{
    this->counter = 0;
}

Counter::~Counter()
{
}

int main()
{
    Counter c;
    cout << c<< endl;
    cout << c++ << endl;
    cout << c<< endl;
    cout << ++c << endl;
    cout << "--------------------" << endl;
    cout << --c << endl;
    cout << c-- << endl;
    cout << c;
}

多继承中,构造函数与析构函数的调用顺序问题

/**
 * 构造函数调用顺序问题
 */
#include<bits/stdc++.h>
using namespace std;

class base
{
private:
    /* data */
public:
    base(/* args */);
    ~base();
};

base::base(/* args */)
{
    cout<<"base class constructor called"<<endl;
}

base::~base()
{
    cout<<"base class destructor called"<<endl;
}

class mid_a:public base
{
private:
    /* data */
public:
    mid_a(/* args */);
    ~mid_a();
};

mid_a::mid_a(/* args */)
{
    cout<<"class mid_a constructor called"<<endl;
}

mid_a::~mid_a()
{
    cout<<"class mid_a destructor called"<<endl;
}


class mid_b:public base
{
private:
    /* data */
public:
    mid_b(/* args */);
    ~mid_b();
};

mid_b::mid_b(/* args */)
{
    cout<<"class mid_b constructor called"<<endl;
}

mid_b::~mid_b()
{
    cout<<"class mid_b destructor called"<<endl;
}


class C: public mid_a, mid_b
{
private:
    /* data */
public:
    C(/* args */);
    ~C();
};

C::C(/* args */)
{
    cout<<"class C constructor called"<<endl;
}

C::~C()
{
    cout<<"class C destructor called"<<endl;
}



int main()
{
    C aaa;
    
}

输出:

base class constructor called
class mid_a constructor called
base class constructor called
class mid_b constructor called
class C constructor called
class C destructor called
class mid_b destructor called
base class destructor called
class mid_a destructor called
base class destructor called

分析:先尝试实例化mid_a,由于mid_a继承自base,因此调用了base的构造函数,然后调用mid_a的构造函数。然后对mid_b进行同样的操作。

结论:多继承的话,按照写的继承的顺序依次对父类进行实例化,然后每次调用的话都像一个栈一样,把它压进去。析构函数的调用顺序就是把这些对象从栈中弹出。

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