二叉树的各种操作
1、树的递归遍历
2、求二叉树中节点的个数
3、求二叉树中叶子节点的个数
4、求二叉树的深度
5、求第k层节点数
6、树的非递归遍历
7、求一棵二叉树的镜像
8、判断两棵树的结构是否相同
9、判断一棵树是否平衡
10、将二叉查找树变为有序的双向链表
下面是树的结构:
1、树的递归遍历
2、求二叉树中节点的个数
3、求二叉树中叶子节点的个数
4、求二叉树的深度
5、求第k层节点数
6、树的非递归遍历
7、求一棵二叉树的镜像
8、判断两棵树的结构是否相同
9、判断一棵树是否平衡
10、将二叉查找树变为有序的双向链表
1、树的递归遍历
2、求二叉树中节点的个数
3、求二叉树中叶子节点的个数
4、求二叉树的深度
5、求第k层节点数
6、树的非递归遍历
7、求一棵二叉树的镜像
8、判断两棵树的结构是否相同
9、判断一棵树是否平衡
10、将二叉查找树变为有序的双向链表
下面是树的结构:
typedef struct treeNode {
int data;
struct treeNode* left;
struct treeNode* right;
}Tree;
#define max(a,b) (((a)>(b))?(a):(b))
1、树的递归遍历
void pre_traverse(Tree *T) //前序遍历
{
if (T)
{
printf("%d",T->data);
if (T->left)
pre_traverse(T->left);
if (T->right)
pre_traverse(T->right);
}
}
void mid_traverse(Tree *T) //中序遍历
{
if (T)
{
if (T->left)
mid_traverse(T->left);
printf("%d",T->data);
if (T->right)
mid_traverse(T->right);
}
}
void beh_traverse(Tree *T) //后序遍历
{
if (T)
{
if (T->left)
beh_traverse(T->left);
if (T->right)
beh_traverse(T->right);
printf("%d",T->data);
}
}
void level_traverse(Tree* T) //层次遍历
{
queue<int>q;
if (T) {
q.push(T->data);
while(!q.empty()) {
printf("%d",q.front());
q.pop();
if (T->left)q.push(T->left->data);
if (T->right)q.push(T->right->data);
}
}
}
2、求二叉树中节点的个数
int getNodes(Tree *T)
{
if (T == NULL)
return 0;
else
return getNodes(T->left) + getNodes(T->right) + 1;
}
3、求二叉树中叶子节点的个数
int getLeafNodes(Tree* T)
{
if (T == NULL)
return 0;
if (T->left == NULL && T->right == NULL)
return 1;
int leftLeafNodes = getLeafNodes(T->left);
int rightLeafNodes = getLeafNodes(T->right);
return leftLeafNodes + rightLeafNodes;
}
4、求二叉树的深度
int Depth(Tree *T)
{
if (T == NULL)
return 0;
else
return max(Depth(T->left), Depth(T->right)) + 1;
}
5、求第k层节点数
int getLevelNodes(Tree *T,int k)
{
if (T == NULL || k==0)
return 0;
if (k == 1)
return 1;
return getLevelNodes(T->left, k - 1) + getLevelNodes(T->right,k-1);
}
6、树的非递归遍历
void preOrdertrvael(Tree *T) //非递归前序遍历
{
if (T == NULL)return;
stack<Tree*>s;
Tree *temp=T;
s.push(temp);
while (!s.empty())
{
temp = s.top();
printf("%d\n",temp->data);
s.pop();
if (T->right)
s.push(T->right);
if (T->left)
s.push(T->left);
}
}
void midOrdertravel(Tree *T) //非递归中序遍历
{
if (T == NULL)return;
stack<Tree*>s;
Tree *temp = T;
while (temp != NULL || !s.empty())
{
if (temp) {
s.push(temp);
temp = temp->left;
}
else {
temp = s.top();
s.pop();
printf("%d",temp->data);
temp = temp->right;
}
}
}
void postOrdertravel(Tree *T) //非递归后序遍历
{
if (T == NULL)return;
stack<Tree*>s1;
stack<Tree*>s2;
Tree *temp = T;
s1.push(temp);
while (!s1.empty())
{
temp = s1.top();
s1.pop();
s2.push(temp);
if (temp->left)
s1.push(temp->left);
if (temp->right)
s1.push(temp->right);
}
while (!s2.empty())
{
temp = s2.top();
printf("%d",temp->data);
s2.pop();
}
}
void levelOrdertravel(Tree *T) //树的非递归层次遍历
{
if (T == NULL)
return;
queue<Tree*>q;
Tree* temp = T;
q.push(temp);
while (!q.empty())
{
temp = q.front();
printf("%d",temp->data);
if (temp->left)
q.push(temp->left);
if (temp->right)
q.push(temp->right);
}
}
7、求一棵二叉树的镜像
Tree* MirrorTree(Tree *T)
{
if (T == NULL)
return;
Tree* pLeft = MirrorTree(T->left);
Tree* pRight = MirrorTree(T->right);
T->left = pRight;
T->right = pLeft;
return T;
}
8、判断两棵树的结构是否相同
bool CompareTreeStruct(Tree *T1, Tree *T2)
{
if (T1 == NULL && T2 == NULL)
return true;
if (T1 != T2)
return false;
bool leftResult = CompareTreeStruct(T1->left,T2->left);
bool rightResult = CompareTreeStruct(T1->right,T2->right);
return leftResult && rightResult;
}
9、判断一棵树是否平衡
bool isAvl(Tree* T)
{
int depth;
return isAvlTree(T,depth);
}
bool isAvlTree(Tree *T,int depth)
{
int leftDepth, rightDepth;
if (T == NULL) {
depth = 0;
return true;
}
if (isAvlTree(T->left, leftDepth) && isAvlTree(T->right, rightDepth))
{
if (abs(leftDepth - rightDepth) <= 1) {
depth = max(leftDepth,rightDepth)+1;
return true;
}
}
return false;
}
10、将二叉查找树变为有序的双向链表
void TreeToList(Tree* T, Tree* &pFirst, Tree* &pLast)
{
Tree* pLeftFirst(NULL), *pLeftLast(NULL), *pRightFirst(NULL), *pRightLast(NULL);
if (T == NULL) {
pFirst = NULL;
pLast = NULL;
return;
}
if (T->left == NULL) {
pFirst = T;
}
else {
TreeToList(T->left, pLeftFirst, pLeftLast);
pLeftLast->right = T;
T->left = pLeftLast;
pFirst = pLeftFirst;
}
if (T->right == NULL) {
pLast = T;
}
else {
TreeToList(T->right, pRightFirst, pRightLast);
pRightFirst->left = T;
T->right = pRightFirst;
pLast = pRightFirst;
}
}