Vector的一种实现(二)
增加了逆置迭代器的实现
以及swap功能
完整代码如下:
#ifndef VECTOR_H_ #define VECTOR_H_ #include <stddef.h> #include <algorithm> #include <memory> template <typename T> class Vector { public: typedef T *iterator; typedef const T *const_iterator; typedef size_t size_type; typedef T value_type; //逆置迭代器 class reverse_iterator { public: reverse_iterator(iterator it = NULL) :current_(it) { } iterator base() const { return current_; } reverse_iterator &operator++() { --current_; return *this; } reverse_iterator operator++(int) { reverse_iterator temp(*this); --current_; return temp; } reverse_iterator &operator--() { ++current_; return *this; } reverse_iterator operator--(int) { reverse_iterator temp(*this); ++current_; return temp; } T &operator*() { iterator temp = current_; return *--temp; } T *operator->() { iterator temp = current_; return --temp; } friend bool operator==(const reverse_iterator &lhs, const reverse_iterator &rhs) { return lhs.current_ == rhs.current_; } friend bool operator!=(const reverse_iterator &lhs, const reverse_iterator &rhs) { return lhs.current_ != rhs.current_; } private: iterator current_; }; //const逆置迭代器 class const_reverse_iterator { public: const_reverse_iterator(const_iterator it = NULL) :current_(it) { } const_iterator base() const { return current_; } const_reverse_iterator &operator++() { --current_; return *this; } const_reverse_iterator operator++(int) { const_iterator temp(*this); --current_; return temp; } const_reverse_iterator &operator--() { ++current_; return *this; } const_reverse_iterator operator--(int) { const_iterator temp(*this); ++current_; return temp; } const T &operator*() const { const_iterator temp = current_; return *(--temp); } const T *operator->() const { const_iterator temp = current_; return --temp; } friend bool operator==(const const_reverse_iterator &lhs, const const_reverse_iterator &rhs) { return lhs.current_ == rhs.current_; } friend bool operator!=(const const_reverse_iterator &lhs, const const_reverse_iterator &rhs) { return lhs.current_ != rhs.current_; } private: const_iterator current_; }; Vector() { create(); } explicit Vector(size_type n, const T &t = T()) { create(n, t); } Vector(const Vector &v) { create(v.begin(), v.end()); } ~Vector() { uncreate(); } Vector &operator=(const Vector &other); T &operator[] (size_type i) { return data_[i]; } const T &operator[] (size_type i) const { return data_[i]; } void push_back(const T &t); void swap(Vector &rhs) { std::swap(data_, rhs.data_); std::swap(avail_, rhs.avail_); std::swap(limit_, rhs.limit_); } size_type size() const { return avail_ - data_; } size_type capacity() const { return limit_ - data_; } iterator begin() { return data_; } const_iterator begin() const { return data_; } iterator end() { return avail_; } const_iterator end() const { return avail_; } reverse_iterator rbegin() { return reverse_iterator(end()); } const_reverse_iterator rbegin() const { return const_reverse_iterator(end()); } reverse_iterator rend() { return reverse_iterator(begin()); } const_reverse_iterator rend() const { return const_reverse_iterator(begin()); } private: iterator data_; //首元素 iterator avail_; //末尾元素的下一个位置 iterator limit_; //内存的后面一个位置 std::allocator<T> alloc_; //内存分配器 void create(); void create(size_type, const T &); void create(const_iterator, const_iterator); void uncreate(); void grow(); void uncheckedAppend(const T &); }; template <typename T> Vector<T> &Vector<T>::operator=(const Vector &rhs) { if(this != &rhs) { uncreate(); //释放原来的内存 create(rhs.begin(), rhs.end()); } return *this; } template <typename T> void Vector<T>::push_back(const T &t) { if(avail_ == limit_) { grow(); } uncheckedAppend(t); } template <typename T> void Vector<T>::create() { //分配空的数组 data_ = avail_ = limit_ = 0; } template <typename T> void Vector<T>::create(size_type n, const T &val) { //分配原始内存 data_ = alloc_.allocate(n); limit_ = avail_ = data_ + n; //向原始内存填充元素 std::uninitialized_fill(data_, limit_, val); } template <typename T> void Vector<T>::create(const_iterator i, const_iterator j) { data_ = alloc_.allocate(j-i); limit_ = avail_ = std::uninitialized_copy(i, j, data_); } template <typename T> void Vector<T>::uncreate() { if(data_) { //逐个进行析构 iterator it = avail_; while(it != data_) { alloc_.destroy(--it); } //真正的释放内存 alloc_.deallocate(data_, limit_ - data_); } //重置指针 data_ = limit_ = avail_ = 0; } template <typename T> void Vector<T>::grow() { //内存变为两倍 size_type new_size = std::max(2 * (limit_ - data_), std::ptrdiff_t(1)); //分配原始内存 iterator new_data = alloc_.allocate(new_size); //复制元素 iterator new_avail = std::uninitialized_copy(data_, avail_, new_data); uncreate(); //释放以前的内存,以及析构元素 data_ = new_data; avail_ = new_avail; limit_ = data_ + new_size; } template <typename T> void Vector<T>::uncheckedAppend(const T &val) { alloc_.construct(avail_++, val); } #endif /* VECTOR_H_ */
测试代码如下:
#include "Vector.hpp" #include <iostream> #include <string> using namespace std; //测试const reverse迭代器 void print(const Vector<string> &vec) { for(Vector<string>::const_reverse_iterator it = vec.rbegin(); it != vec.rend(); ++it) { cout << *it << " "; } cout << endl; } int main(int argc, char const *argv[]) { Vector<string> vec(3, "hello"); for(Vector<string>::const_iterator it = vec.begin(); it != vec.end(); ++it) { cout << *it << " "; } cout << endl; cout << "size = " << vec.size() << endl; cout << "capacity = " << vec.capacity() << endl; vec.push_back("foo"); vec.push_back("bar"); cout << "size = " << vec.size() << endl; cout << "capacity = " << vec.capacity() << endl; for(Vector<string>::reverse_iterator it = vec.rbegin(); it != vec.rend(); ++it) { cout << *it << " "; } cout << endl; print(vec); Vector<string> vec2; vec2.push_back("beijing"); vec2.push_back("shanghai"); vec2.push_back("guangzhou"); print(vec2); vec.swap(vec2); print(vec); print(vec2); return 0; }
