树形选择排序 (tree selection sort) 具体解释 及 代码(C++)
本文地址: http://blog.csdn.net/caroline_wendy
算法逻辑: 依据节点的大小, 建立树, 输出树的根节点, 并把此重置为最大值, 再重构树.
由于树中保留了一些比較的逻辑, 所以降低了比較次数.
也称锦标赛排序, 时间复杂度为O(nlogn), 由于每一个值(共n个)须要进行树的深度(logn)次比較.
參考<数据结构>(严蔚敏版) 第278-279页.
树形选择排序(tree selection sort)是堆排序的一个过渡, 并非核心算法.
可是全然依照书上算法, 实现起来极其麻烦, 差点儿没有不论什么人实现过.
须要记录建树的顺序, 在重构时, 才干降低比較.
本着娱乐和分享的精神, 应人之邀, 简单的实现了一下.
代码:
/*
* TreeSelectionSort.cpp
*
* Created on: 2014.6.11
* Author: Spike
*/
/*eclipse cdt, gcc 4.8.1*/
#include <iostream>
#include <vector>
#include <stack>
#include <queue>
#include <utility>
#include <climits>
using namespace std;
/*树的结构*/
struct BinaryTreeNode{
bool from; //推断来源, 左true, 右false
int m_nValue;
BinaryTreeNode* m_pLeft;
BinaryTreeNode* m_pRight;
};
/*构建叶子节点*/
BinaryTreeNode* buildList (const std::vector<int>& L)
{
BinaryTreeNode* btnList = new BinaryTreeNode[L.size()];
for (std::size_t i=0; i<L.size(); ++i)
{
btnList[i].from = true;
btnList[i].m_nValue = L[i];
btnList[i].m_pLeft = NULL;
btnList[i].m_pRight = NULL;
}
return btnList;
}
/*不足偶数时, 需补充节点*/
BinaryTreeNode* addMaxNode (BinaryTreeNode* list, int n)
{
/*最大节点*/
BinaryTreeNode* maxNode = new BinaryTreeNode(); //最大节点, 用于填充
maxNode->from = true;
maxNode->m_nValue = INT_MAX;
maxNode->m_pLeft = NULL;
maxNode->m_pRight = NULL;
/*复制数组*/
BinaryTreeNode* childNodes = new BinaryTreeNode[n+1]; //添加一个节点
for (int i=0; i<n; ++i) {
childNodes[i].from = list[i].from;
childNodes[i].m_nValue = list[i].m_nValue;
childNodes[i].m_pLeft = list[i].m_pLeft;
childNodes[i].m_pRight = list[i].m_pRight;
}
childNodes[n] = *maxNode;
delete[] list;
list = NULL;
return childNodes;
}
/*依据左右子树大小, 创建树*/
BinaryTreeNode* buildTree (BinaryTreeNode* childNodes, int n)
{
if (n == 1) {
return childNodes;
}
if (n%2 == 1) {
childNodes = addMaxNode(childNodes, n);
}
int num = n/2 + n%2;
BinaryTreeNode* btnList = new BinaryTreeNode[num];
for (int i=0; i<num; ++i) {
btnList[i].m_pLeft = &childNodes[2*i];
btnList[i].m_pRight = &childNodes[2*i+1];
bool less = btnList[i].m_pLeft->m_nValue <= btnList[i].m_pRight->m_nValue;
btnList[i].from = less;
btnList[i].m_nValue = less ?
btnList[i].m_pLeft->m_nValue : btnList[i].m_pRight->m_nValue;
}
buildTree(btnList, num);
}
/*返回树根, 又一次计算数*/
int rebuildTree (BinaryTreeNode* tree)
{
int result = tree[0].m_nValue;
std::stack<BinaryTreeNode*> nodes;
BinaryTreeNode* node = &tree[0];
nodes.push(node);
while (node->m_pLeft != NULL) {
node = node->from ? node->m_pLeft : node->m_pRight;
nodes.push(node);
}
node->m_nValue = INT_MAX;
nodes.pop();
while (!nodes.empty())
{
node = nodes.top();
nodes.pop();
bool less = node->m_pLeft->m_nValue <= node->m_pRight->m_nValue;
node->from = less;
node->m_nValue = less ?
node->m_pLeft->m_nValue : node->m_pRight->m_nValue;
}
return result;
}
/*从上到下打印树*/
void printTree (BinaryTreeNode* tree) {
BinaryTreeNode* node = &tree[0];
std::queue<BinaryTreeNode*> temp1;
std::queue<BinaryTreeNode*> temp2;
temp1.push(node);
while (!temp1.empty())
{
node = temp1.front();
if (node->m_pLeft != NULL && node->m_pRight != NULL) {
temp2.push(node->m_pLeft);
temp2.push(node->m_pRight);
}
temp1.pop();
if (node->m_nValue == INT_MAX) {
std::cout << "MAX" << " ";
} else {
std::cout << node->m_nValue << " ";
}
if (temp1.empty())
{
std::cout << std::endl;
temp1 = temp2;
std::queue<BinaryTreeNode*> empty;
std::swap(temp2, empty);
}
}
}
int main ()
{
std::vector<int> L = {49, 38, 65, 97, 76, 13, 27, 49};
BinaryTreeNode* tree = buildTree(buildList(L), L.size());
std::cout << "Begin : " << std::endl;
printTree(tree); std::cout << std::endl;
std::vector<int> result;
for (std::size_t i=0; i<L.size(); ++i)
{
int value = rebuildTree (tree);
std::cout << "Round[" << i+1 << "] : " << std::endl;
printTree(tree); std::cout << std::endl;
result.push_back(value);
}
std::cout << "result : ";
for (std::size_t i=0; i<L.size(); ++i) {
std::cout << result[i] << " ";
}
std::cout << std::endl;
return 0;
}
输出:
Begin : 13 38 13 38 65 13 27 49 38 65 97 76 13 27 49 Round[1] : 27 38 27 38 65 76 27 49 38 65 97 76 MAX 27 49 Round[2] : 38 38 49 38 65 76 49 49 38 65 97 76 MAX MAX 49 Round[3] : 49 49 49 49 65 76 49 49 MAX 65 97 76 MAX MAX 49 Round[4] : 49 65 49 MAX 65 76 49 MAX MAX 65 97 76 MAX MAX 49 Round[5] : 65 65 76 MAX 65 76 MAX MAX MAX 65 97 76 MAX MAX MAX Round[6] : 76 97 76 MAX 97 76 MAX MAX MAX MAX 97 76 MAX MAX MAX Round[7] : 97 97 MAX MAX 97 MAX MAX MAX MAX MAX 97 MAX MAX MAX MAX Round[8] : MAX MAX MAX MAX MAX MAX MAX MAX MAX MAX MAX MAX MAX MAX MAX result : 13 27 38 49 49 65 76 97
