【C++】朝花夕拾——STL vector
STL之vector篇
N久之前是拿C的数组实现过vector中的一些简单功能,什么深拷贝、增删查找之类的,以为vector的实现也就是这样了,现在想想真是...too young too naive...ORZ
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vector属于顺序容器,它的底层实现就是基于array,所以它可以支持随机访问,但是它比array更有效率,因为它动态分配的内存空间。
动态分配的内存空间:
每当vector的capacity==size,并且有新element需要加入时,vector会申请一段大小等于2*capacity的连续内存空间,将原来的数据深拷贝到新的内存地址,然后释放掉原来的内存,并添加新的element到内存中。(这一系列内存操作大大影响了vector的存储效率)
因为,不同的环境下,vector的实现方式有所出入,所以初始化时的capacity大小不一样,但是capacity一定会大于所需的内存大小,预留一定的空间,已减少内存操作。
以下是简单的测试:
环境如下:
g++ 4.8.4
ubuntu 14.04
test1:
#include <iostream> #include <vector> using namespace std; int main() { vector<int> v1; cout << "v1 size = " << v1.size() << endl; cout << "v1 capacity = " << v1.capacity() << endl; cout << "v1 max_size = " << v1.max_size() << endl; vector<char> v2; cout << "v2 size = " << v2.size() << endl; cout << "v2 capacity = " << v2.capacity() << endl; cout << "v2 max_size = " << v2.max_size() << endl; return 0; }
结果如下:
v1 size = 0
v1 capacity = 0
v1 max_size = 4611686018427387903
v2 size = 0
v2 capacity = 0
v2 max_size = 18446744073709551615
max_size返回vector可以保持的element个数的上限,这个上限与系统的底层实现有关,不一定可以达到(当内存不够时,不能继续分配)
这里可以看出,此时初始化的capacity==0
test2:
#include <iostream> #include <vector> using namespace std; int main() { vector<int> v1; for (int i = 0; i < 1; ++i)v1.push_back(i); cout << "v1 size = " << v1.size() << endl; cout << "v1 capacity = " << v1.capacity() << endl; cout << "v1 max_size = " << v1.max_size() << endl; vector<char> v2; for (int i = 0; i < 1; ++i)v2.push_back(char(i)); cout << "v2 size = " << v2.size() << endl; cout << "v2 capacity = " << v2.capacity() << endl; cout << "v2 max_size = " << v2.max_size() << endl; return 0; }
结果如下:
v1 size = 1
v1 capacity = 1
v1 max_size = 4611686018427387903
v2 size = 1
v2 capacity = 1
v2 max_size = 18446744073709551615
此时,插入一个元素,capacity==1,size也为1
test3:
#include <iostream> #include <vector> using namespace std; int main() { vector<int> v1; for (int i = 0; i < 2; ++i)v1.push_back(i); cout << "v1 size = " << v1.size() << endl; cout << "v1 capacity = " << v1.capacity() << endl; cout << "v1 max_size = " << v1.max_size() << endl; vector<char> v2; for (int i = 0; i < 2; ++i)v2.push_back(char(i)); cout << "v2 size = " << v2.size() << endl; cout << "v2 capacity = " << v2.capacity() << endl; cout << "v2 max_size = " << v2.max_size() << endl; return 0; }
结果如下:
v1 size = 2
v1 capacity = 2
v1 max_size = 4611686018427387903
v2 size = 2
v2 capacity = 2
v2 max_size = 18446744073709551615
当插入两个元素时,capacity = 2 * capacity(即为2),然后拷贝之前的数据到新的内存空间,添加新元素,则size==2
test4:
#include <iostream> #include <vector> using namespace std; int main() { vector<int> v1; for (int i = 0; i < 3; ++i)v1.push_back(i); cout << "v1 size = " << v1.size() << endl; cout << "v1 capacity = " << v1.capacity() << endl; cout << "v1 max_size = " << v1.max_size() << endl; vector<char> v2; for (int i = 0; i < 3; ++i)v2.push_back(char(i)); cout << "v2 size = " << v2.size() << endl; cout << "v2 capacity = " << v2.capacity() << endl; cout << "v2 max_size = " << v2.max_size() << endl; return 0; }
结果如下:
v1 size = 3
v1 capacity = 4
v1 max_size = 4611686018427387903
v2 size = 3
v2 capacity = 4
v2 max_size = 18446744073709551615
又接着添加一个新元素,capacity翻倍(变成4),size增加1,即3
添加新元素的原理get > <
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以下为删除原理
test5:
#include <iostream> #include <vector> using namespace std; int main() { vector<int> v1; for (int i = 0; i < 129; ++i)v1.push_back(i); cout << "v1 size = " << v1.size() << endl; cout << "v1 capacity = " << v1.capacity() << endl; cout << "v1 max_size = " << v1.max_size() << endl; vector<char> v2; for (int i = 0; i < 129; ++i)v2.push_back(char(i)); cout << "v2 size = " << v2.size() << endl; cout << "v2 capacity = " << v2.capacity() << endl; cout << "v2 max_size = " << v2.max_size() << endl; return 0; }
结果如下:
v1 size = 129
v1 capacity = 256
v1 max_size = 4611686018427387903
v2 size = 129
v2 capacity = 256
v2 max_size = 18446744073709551615
test6:
#include <iostream> #include <vector> using namespace std; int main() { vector<int> v1; for (int i = 0; i < 129; ++i)v1.push_back(i); v1.pop_back(); v1.pop_back(); cout << "v1 size = " << v1.size() << endl; cout << "v1 capacity = " << v1.capacity() << endl; cout << "v1 max_size = " << v1.max_size() << endl; vector<char> v2; for (int i = 0; i < 129; ++i)v2.push_back(char(i)); v2.pop_back(); v2.pop_back(); cout << "v2 size = " << v2.size() << endl; cout << "v2 capacity = " << v2.capacity() << endl; cout << "v2 max_size = " << v2.max_size() << endl; return 0; }
结果如下:
v1 size = 127
v1 capacity = 256
v1 max_size = 4611686018427387903
v2 size = 127
v2 capacity = 256
v2 max_size = 18446744073709551615
(⊙v⊙)嗯,看来内存的动态改变并不会随着size的减小的缩减capacity,避免了不必要的内存操作。
C++手册中也有说明,pop_back的操作只是size减1
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接着,是各个函数的底层理解
assign()
有三种形参形式(iterator begin,iterator end)初始化为迭代器指向的容器之间的内容;(n, value)初始化N个值为value的元素;(initializer_list<value_type> il)深拷贝
back()
返回vector中最后一个值,当vector为空时,调用该函数会报错
front()
返回vector中第一个值,当vector为空时,调用该函数会报错
begin()
返回指向第一个element的迭代器
end()
返回指向past-the-end element的迭代器,past-the-end element是理论上应该跟在最后一个element后面的位置,但是那个位置上并没有存放element
cbegin()
返回一个首个元素的const_iterator迭代器,用该迭代器访问元素是是不可以用来改变元素本身值的(即便元素本身并非const类型)
cend()
返回一个past-the-last element的const_iterator迭代器
crbegin()
r表示逆序,c表示const,此处返回vector中逆序第一个element的const_iterator
crend()
此处返回vector中第一个element的const_iterator,功能与cbegin()相同
rbegin()
返回逆序第一个element的迭代器,即为指向end()的前一个位置的迭代器
rend()
返回逆序的最后一个element的迭代器,即指向第一个element
capacity()
返回vector容器已开辟的内存可存放element的个数
size()
返回当前vector中已有的element个数,size <= capacity
max_size()
返回一个理论上允许的capacity上限值,但不一定能达到
data()
返回一个指向当前容器内存起始地址的指针,由于vector的内存分配是连续的,所以可以直接用指针offset来为容器中的element赋值
std::vector<int> myvector (5);
int* p = myvector.data();
*p = 10;
++p;
*p = 20;
p[2] = 100;emplace()
关于emplace和insert的区别,如下:
(emplace会调用类的构造函数,代码搬运自:http://stackoverflow.com/questions/14788261/c-stdvector-emplace-vs-insert)
struct Foo { Foo(int n, double x); }; std::vector<Foo> v; v.emplace(someIterator, 42, 3.1416); v.insert(someIterator, Foo(42, 3.1416));
emplace_back()
调用构造函数,然后把element加到末尾
insert()
可以把element插入到迭代器指定的element之前的位置。
由于底层实现时array,除了在末尾插入element,在其他的位置插入,都需要将指定插入位置后面的element移位,这将导致效率低下
如果插入之后size>capacity,则参考push_back的重新申请内存空间
erase()
删除指定区间或者位置的element,同样,除了删除末尾的element,删除其他位置的element都需要把后面的element往前移动,也是导致效率低的原因
clear()
把所有element都移除,size=0,此时capacity不一定为0(不一定会有释放内存的操作)//正确的释放内存姿势——swap()
empty()
size >= 0, 返回false;否则返回true
get_allocator()
返回该容器的allocator
operator=
拷贝,STL中的拷贝都是深拷贝
operator[]
访问节点
push_back()
在末尾增加一个element,当size超出时,capacity翻倍(具体看此博文开头),size++
pop_back()
移除末尾一个element, size--
reserve()
v.reserve(n);表示此时V的capacity至少要大于等于300,若capacity<300,则重新申请内存;反之则不用做其他操作;
#include <iostream> #include <vector> using namespace std; int main() { vector<int> v1; for (int i = 0; i < 129; ++i)v1.push_back(i); v1.pop_back(); v1.pop_back(); cout << "v1 size = " << v1.size() << endl; cout << "v1 capacity = " << v1.capacity() << endl; cout << "v1 max_size = " << v1.max_size() << endl; vector<char> v2; for (int i = 0; i < 129; ++i)v2.push_back(char(i)); v2.reserve(300); cout << "v2 size = " << v2.size() << endl; cout << "v2 capacity = " << v2.capacity() << endl; cout << "v2 max_size = " << v2.max_size() << endl; return 0; }
结果为:
v1 size = 127
v1 capacity = 256
v1 max_size = 4611686018427387903
v2 size = 129
v2 capacity = 300
v2 max_size = 18446744073709551615
resize()
v.resize(n)将会把v中的size调整为n大小,若n > size,则用0补足element;若n < size,则取容器中的前n个element,其与元素移除;
v.resize(n,m)将会把v中的size调整为n大小,若n > size,则用m补足element
#include <iostream> #include <vector> using namespace std; int main() { vector<int> v1; for (int i = 0; i < 10; ++i)v1.push_back(i); for (int i = 0; i < v1.size(); i ++)cout << v1[i] << " "; cout << endl; cout << "v1 size = " << v1.size() << endl; cout << "v1 capacity = " << v1.capacity() << endl; cout << "v1 max_size = " << v1.max_size() << endl; v1.resize(7); for (int i = 0; i < v1.size(); i ++)cout << v1[i] << " "; cout << endl; cout << "v1 size = " << v1.size() << endl; cout << "v1 capacity = " << v1.capacity() << endl; cout << "v1 max_size = " << v1.max_size() << endl; v1.resize(20, 200); for (int i = 0; i < v1.size(); i ++)cout << v1[i] << " "; cout << endl; cout << "v1 size = " << v1.size() << endl; cout << "v1 capacity = " << v1.capacity() << endl; cout << "v1 max_size = " << v1.max_size() << endl; v1.resize(50); for (int i = 0; i < v1.size(); i ++)cout << v1[i] << " "; cout << endl; cout << "v1 size = " << v1.size() << endl; cout << "v1 capacity = " << v1.capacity() << endl; cout << "v1 max_size = " << v1.max_size() << endl; return 0; }
结果如下:
0 1 2 3 4 5 6 7 8 9
v1 size = 10
v1 capacity = 16
v1 max_size = 4611686018427387903
0 1 2 3 4 5 6
v1 size = 7
v1 capacity = 16
v1 max_size = 4611686018427387903
0 1 2 3 4 5 6 200 200 200 200 200 200 200 200 200 200 200 200 200
v1 size = 20
v1 capacity = 20
v1 max_size = 4611686018427387903
0 1 2 3 4 5 6 200 200 200 200 200 200 200 200 200 200 200 200 200 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0
v1 size = 50
v1 capacity = 50
v1 max_size = 4611686018427387903
shrink_to_fit()
一般来说capacity满足,capacity>=size;v.shrink_to_fit()操作可以使得,capacity==size,这也是释放内存的操作之一!!!
#include <iostream> #include <vector> using namespace std; int main() { vector<int> v1; for (int i = 0; i < 10; ++i)v1.push_back(i); cout << "v1 size = " << v1.size() << endl; cout << "v1 capacity = " << v1.capacity() << endl; cout << "v1 max_size = " << v1.max_size() << endl; v1.resize(7); cout << "v1 size = " << v1.size() << endl; cout << "v1 capacity = " << v1.capacity() << endl; cout << "v1 max_size = " << v1.max_size() << endl; v1.shrink_to_fit(); cout << "v1 size = " << v1.size() << endl; cout << "v1 capacity = " << v1.capacity() << endl; cout << "v1 max_size = " << v1.max_size() << endl; return 0; }
结果如下:
v1 size = 10
v1 capacity = 16
v1 max_size = 4611686018427387903
v1 size = 7
v1 capacity = 16
v1 max_size = 4611686018427387903
v1 size = 7
v1 capacity = 7
v1 max_size = 4611686018427387903
swap()
v.swap(v2)的操作可以将v,和v2中的element交换
#include <iostream> #include <vector> using namespace std; int main() { vector<int> v1; for (int i = 0; i < 10; ++i)v1.push_back(i); cout << "v1 size = " << v1.size() << endl; cout << "v1 capacity = " << v1.capacity() << endl; cout << "v1 max_size = " << v1.max_size() << endl; vector<int> v2; for (int i = 0; i < 20; ++i)v2.push_back(i); cout << "v2 size = " << v2.size() << endl; cout << "v2 capacity = " << v2.capacity() << endl; cout << "v2 max_size = " << v2.max_size() << endl; v1.swap(v2); cout << "v1 size = " << v1.size() << endl; cout << "v1 capacity = " << v1.capacity() << endl; cout << "v1 max_size = " << v1.max_size() << endl; cout << "v2 size = " << v2.size() << endl; cout << "v2 capacity = " << v2.capacity() << endl; cout << "v2 max_size = " << v2.max_size() << endl; return 0; }
结果如下:
v1 size = 10
v1 capacity = 16
v1 max_size = 4611686018427387903
v2 size = 20
v2 capacity = 32
v2 max_size = 4611686018427387903
v1 size = 20
v1 capacity = 32
v1 max_size = 4611686018427387903
v2 size = 10
v2 capacity = 16
v2 max_size = 4611686018427387903
小结:
vector是不会自动释放内存的,但是如果size的极大值很大的话会造成capacity很大,浪费内存。
所以以下有几种方法可以释放vector的内存:
①shrink_to_fit
#include <iostream> #include <vector> using namespace std; int main() { vector<int> v1; for (int i = 0; i < 20; ++i)v1.push_back(i); cout << "v1 size = " << v1.size() << endl; cout << "v1 capacity = " << v1.capacity() << endl; v1.clear(); cout << "v1 size = " << v1.size() << endl; cout << "v1 capacity = " << v1.capacity() << endl; v1.shrink_to_fit(); cout << "v1 size = " << v1.size() << endl; cout << "v1 capacity = " << v1.capacity() << endl; return 0; }
结果:
v1 size = 20
v1 capacity = 32
v1 size = 0
v1 capacity = 32
v1 size = 0
v1 capacity = 0
②swap
#include <iostream> #include <vector> using namespace std; int main() { vector<int> v1; for (int i = 0; i < 20; ++i)v1.push_back(i); cout << "v1 size = " << v1.size() << endl; cout << "v1 capacity = " << v1.capacity() << endl; vector<int>().swap(v1); cout << "v1 size = " << v1.size() << endl; cout << "v1 capacity = " << v1.capacity() << endl; return 0; }
结果如下:
v1 size = 20
v1 capacity = 32
v1 size = 0
v1 capacity = 0
③指针释放
#include <iostream> #include <vector> using namespace std; int main() { vector<int> v; vector<int>* v1 = &v; for (int i = 0; i < 20; ++i)v1->push_back(i); cout << "v size = " << v.size() << endl; cout << "v capacity = " << v.capacity() << endl; delete v1; return 0; }
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C++11的标准中,vector新增加的成员函数:
crbegin
crend
cbegin
cend
emplace
emplace_back
data
shrink_to_fit
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最后简单说说,高效索引之bitset和vector<bool>
bitset 可以进行位操作,但是大小固定
vector<bool> 属于vector的一种特殊形式,用bool类型的allocator构造,但是在实现的时候优化了,所以它的element类型并不是bool,而是bit
