(程序员面试题精选(01))把二元查找树转变成排序的双向链表

把二元查找树转变成排序的双向链表 

程序员面试题精选(01)－把二元查找树转变成排序的双向链表
　　题目：输入一棵二元查找树，将该二元查找树转换成一个排序的双向链表。要求不能创建任何新的结点，只调整指针的指向。
　　比如将二元查找树
                                            10
                                          /    \
                                        6       14
                                      /  \     /　 \
                                   　4     8  12 　  16

转换成双向链表
4=6=8=10=12=14=16。
　　分析：本题是微软的面试题。很多与树相关的题目都是用递归的思路来解决，本题也不例外。下面我们用两种不同的递归思路来分析。
　 　思路一：当我们到达某一结点准备调整以该结点为根结点的子树时，先调整其左子树将左子树转换成一个排好序的左子链表，再调整其右子树转换右子链表。最近 链接左子链表的最右结点（左子树的最大结点）、当前结点和右子链表的最左结点（右子树的最小结点）。从树的根结点开始递归调整所有结点。
　　思路二：我们可以中序遍历整棵树。按照这个方式遍历树，比较小的结点先访问。如果我们每访问一个结点，假设之前访问过的结点已经调整成一个排序双向链表，我们再把调整当前结点的指针将其链接到链表的末尾。当所有结点都访问过之后，整棵树也就转换成一个排序双向链表了。
参考代码：
首先我们定义二元查找树结点的数据结构如下：
    struct BSTreeNode // a node in the binary search tree
    {
        int          m_nValue; // value of node
        BSTreeNode  *m_pLeft;  // left child of node
        BSTreeNode  *m_pRight; // right child of node
    };
思路一对应的代码：
///////////////////////////////////////////////////////////////////////
// Covert a sub binary-search-tree into a sorted double-linked list
// Input: pNode - the head of the sub tree
//        asRight - whether pNode is the right child of its parent
// Output: if asRight is true, return the least node in the sub-tree
//         else return the greatest node in the sub-tree
///////////////////////////////////////////////////////////////////////
BSTreeNode* ConvertNode(BSTreeNode* pNode, bool asRight)
{
      if(!pNode)
            return NULL;
      BSTreeNode *pLeft = NULL;
      BSTreeNode *pRight = NULL;

      // Convert the left sub-tree
      if(pNode->m_pLeft)
            pLeft = ConvertNode(pNode->m_pLeft, false);

      // Connect the greatest node in the left sub-tree to the current node
      if(pLeft)
      {
            pLeft->m_pRight = pNode;
            pNode->m_pLeft = pLeft;
      }
      // Convert the right sub-tree
      if(pNode->m_pRight)
            pRight = ConvertNode(pNode->m_pRight, true);
      // Connect the least node in the right sub-tree to the current node
      if(pRight)
      {
            pNode->m_pRight = pRight;
            pRight->m_pLeft = pNode;
      }

      BSTreeNode *pTemp = pNode;
      // If the current node is the right child of its parent,
      // return the least node in the tree whose root is the current node
      if(asRight)
      {
            while(pTemp->m_pLeft)
                  pTemp = pTemp->m_pLeft;
      }
      // If the current node is the left child of its parent,
      // return the greatest node in the tree whose root is the current node
      else
      {
            while(pTemp->m_pRight)
                  pTemp = pTemp->m_pRight;
      }

      return pTemp;

}

///////////////////////////////////////////////////////////////////////
// Covert a binary search tree into a sorted double-linked list
// Input: the head of tree
// Output: the head of sorted double-linked list
///////////////////////////////////////////////////////////////////////
BSTreeNode* Convert(BSTreeNode* pHeadOfTree)
{
      // As we want to return the head of the sorted double-linked list,
      // we set the second parameter to be true
      return ConvertNode(pHeadOfTree, true);
}
思路二对应的代码：
///////////////////////////////////////////////////////////////////////
// Covert a sub binary-search-tree into a sorted double-linked list
// Input: pNode -           the head of the sub tree
//        pLastNodeInList - the tail of the double-linked list
///////////////////////////////////////////////////////////////////////
void ConvertNode(BSTreeNode* pNode, BSTreeNode*& pLastNodeInList)
{
      if(pNode == NULL)
            return;

      BSTreeNode *pCurrent = pNode;

      // Convert the left sub-tree
      if (pCurrent->m_pLeft != NULL)
            ConvertNode(pCurrent->m_pLeft, pLastNodeInList);

      // Put the current node into the double-linked list
      pCurrent->m_pLeft = pLastNodeInList;
      if(pLastNodeInList != NULL)
            pLastNodeInList->m_pRight = pCurrent;

      pLastNodeInList = pCurrent;

      // Convert the right sub-tree
      if (pCurrent->m_pRight != NULL)
            ConvertNode(pCurrent->m_pRight, pLastNodeInList);
}

///////////////////////////////////////////////////////////////////////
// Covert a binary search tree into a sorted double-linked list
// Input: pHeadOfTree - the head of tree
// Output: the head of sorted double-linked list
///////////////////////////////////////////////////////////////////////
BSTreeNode* Convert_Solution1(BSTreeNode* pHeadOfTree)
{
      BSTreeNode *pLastNodeInList = NULL;
      ConvertNode(pHeadOfTree, pLastNodeInList);

      // Get the head of the double-linked list
      BSTreeNode *pHeadOfList = pLastNodeInList;
      while(pHeadOfList && pHeadOfList->m_pLeft)
            pHeadOfList = pHeadOfList->m_pLeft;

      return pHeadOfList;
}

实现代码

// DoubleList.cpp : 定义控制台应用程序的入口点。
//

#include "stdafx.h"
#include "malloc.h"
#include "stdafx.h"
#include "iostream"
using namespace  std;

struct BSTreeNode // a node in the binary search tree
{
  int          m_nValue; // value of node
  BSTreeNode  *m_pLeft;  // left child of node
  BSTreeNode  *m_pRight; // right child of node
};

///////////////////////////////////////////////////////////////////////
// Covert a sub binary-search-tree into a sorted double-linked list
// Input: pNode - the head of the sub tree
//        asRight - whether pNode is the right child of its parent
// Output: if asRight is true, return the least node in the sub-tree
//         else return the greatest node in the sub-tree
///////////////////////////////////////////////////////////////////////
BSTreeNode* ConvertNode(BSTreeNode* pNode, bool asRight)
{
  if(!pNode)
    return NULL;
  BSTreeNode *pLeft = NULL;
  BSTreeNode *pRight = NULL;

  // Convert the left sub-tree
  if(pNode->m_pLeft)
    pLeft = ConvertNode(pNode->m_pLeft, false);

  // Connect the greatest node in the left sub-tree to the current node
  if(pLeft)
  {
    pLeft->m_pRight = pNode;
    pNode->m_pLeft = pLeft;
  }
  // Convert the right sub-tree
  if(pNode->m_pRight)
    pRight = ConvertNode(pNode->m_pRight, true);
  // Connect the least node in the right sub-tree to the current node
  if(pRight)
  {
    pNode->m_pRight = pRight;
    pRight->m_pLeft = pNode;
  }

  BSTreeNode *pTemp = pNode;
  // If the current node is the right child of its parent,
  // return the least node in the tree whose root is the current node
  if(asRight)
  {
    while(pTemp->m_pLeft)
      pTemp = pTemp->m_pLeft;
  }
  // If the current node is the left child of its parent,
  // return the greatest node in the tree whose root is the current node
  else
  {
    while(pTemp->m_pRight)
      pTemp = pTemp->m_pRight;
  }
  pLeft = NULL;
  pRight = NULL;
  return pTemp;

}

///////////////////////////////////////////////////////////////////////
// Covert a binary search tree into a sorted double-linked list
// Input: the head of tree
// Output: the head of sorted double-linked list
///////////////////////////////////////////////////////////////////////
BSTreeNode* Convert(BSTreeNode* pHeadOfTree)
{
  // As we want to return the head of the sorted double-linked list,
  // we set the second parameter to be true
  return ConvertNode(pHeadOfTree, true);
}

BSTreeNode * Insert_Node(BSTreeNode* root,int nodeValue)
{

  BSTreeNode* newnode=(BSTreeNode *)malloc(sizeof(BSTreeNode));     
  newnode->m_nValue = nodeValue;
  newnode->m_pLeft=NULL;
  newnode->m_pRight=NULL;
  
  if ( root == NULL)
  {
    return newnode;
  }
  
  BSTreeNode * pCurrentNode = root; 
  BSTreeNode * pParentNode;
  while ( pCurrentNode != NULL )
  {
      pParentNode = pCurrentNode;
      if ( pCurrentNode->m_nValue > nodeValue)
      {
          pCurrentNode = pCurrentNode ->m_pLeft;
      } 
      else
      {
          pCurrentNode = pCurrentNode->m_pRight;
      }
  }
  if ( pParentNode->m_nValue > nodeValue )
  {
      pParentNode->m_pLeft = newnode;
  }
  else
  {
      pParentNode->m_pRight = newnode;
  }
  return root;
}

/*创建二叉树*/
BSTreeNode * Create_Btree(int *data, int len)
{
  BSTreeNode *root = NULL;
  int i;
  for ( i = 0; i < len ; i++ )
  {
    root =  Insert_Node( root,data[i] );
  }
  return root;
}

/*中序遍历二叉树*/
void inorder(BSTreeNode * pHead)
{
  if(pHead!=NULL)
  {
    inorder(pHead->m_pLeft);
    printf("  %d  ",pHead->m_nValue);
    inorder(pHead->m_pRight);
  }
}

/*打印二叉树*/
void PrintBSTree(BSTreeNode* pHead)
{
  while (pHead != NULL)
  {
     printf("  %d  ",pHead->m_nValue);
     pHead = pHead->m_pRight;
  }
};

/*通过中序遍历二叉树，并调整顺序*/
void ConvertNode(BSTreeNode* pNode, BSTreeNode* & pLastNodeInList)
{
  if(pNode == NULL)
    return;

  BSTreeNode *pCurrent = pNode;

  // Convert the left sub-tree
  if (pCurrent->m_pLeft != NULL)
    ConvertNode(pCurrent->m_pLeft, pLastNodeInList);

  // Put the current node into the double-linked list
  pCurrent->m_pLeft = pLastNodeInList;
  if(pLastNodeInList != NULL)
    pLastNodeInList->m_pRight = pCurrent;

  pLastNodeInList = pCurrent;

  // Convert the right sub-tree
  if (pCurrent->m_pRight != NULL)
    ConvertNode(pCurrent->m_pRight, pLastNodeInList);
}

BSTreeNode* Convert_Node_DoubleList(BSTreeNode* pHeadOfTree)
{
  BSTreeNode *pLastNodeInList = NULL;
  ConvertNode(pHeadOfTree, pLastNodeInList);

  // Get the head of the double-linked list
  BSTreeNode *pHeadOfList = pLastNodeInList;
  while(pHeadOfList && pHeadOfList->m_pLeft)
    pHeadOfList = pHeadOfList->m_pLeft;

  return pHeadOfList;
}

int _tmain(int argc, _TCHAR* argv[])
{
  BSTreeNode *root = NULL;
  int arry[] = {10,6,4,8,14,12,16};

  //创建二叉树
  root = Create_Btree(arry,sizeof( arry)/ sizeof (int));

  //中序遍历
  inorder( root );

  cout<< endl;

  //第一种方法。
  // root= Convert( root );

  //第二种方法
  root = Convert_Node_DoubleList( root);

  PrintBSTree( root );

  root = NULL;
  
}