上一节分析了stack实现, stack是修改了deque的接口而实现的一个功能简单的结构, 本节分析的queue也是用deque为底层容器封装.
queue数据都是在头部进行操作的, 之允许进行push和pop操作.
queue结构
#ifndef __STL_LIMITED_DEFAULT_TEMPLATES
template <class T, class Sequence = deque<T> >
#else
template <class T, class Sequence>
#endif
class queue {
// 定义友元函数
friend bool operator== __STL_NULL_TMPL_ARGS (const queue& x, const queue& y);
friend bool operator< __STL_NULL_TMPL_ARGS (const queue& x, const queue& y);
public:
typedef typename Sequence::value_type value_type;
typedef typename Sequence::size_type size_type;
typedef typename Sequence::reference reference;
typedef typename Sequence::const_reference const_reference;
protected:
Sequence c;
public:
bool empty() const { return c.empty(); }
size_type size() const { return c.size(); }
// 调用deque的front函数
reference front() { return c.front(); }
const_reference front() const { return c.front(); }
reference back() { return c.back(); }
const_reference back() const { return c.back(); }
// 只封装push_back, pop_front函数
void push(const value_type& x) { c.push_back(x); }
void pop() { c.pop_front(); }
};友元函数
// 实现重载
template <class T, class Sequence>
bool operator==(const queue<T, Sequence>& x, const queue<T, Sequence>& y) {
return x.c == y.c;
}
template <class T, class Sequence>
bool operator<(const queue<T, Sequence>& x, const queue<T, Sequence>& y) {
return x.c < y.c;
}int main()
{
std::queue<int> qu;
qu.push(1);
qu.push(2);
qu.push(3);
qu.size();
while(!qu.empty())
{
std::cout << qu.front() << " "; // 1 2 3
qu.pop();
}
exit(0);
}queue与stack都是使用底层接口封装的结构, 他们是被称为配接器而不是容器.