本题要求实现给定二叉搜索树的5种常用操作。
函数接口定义:
BinTree Insert( BinTree BST, ElementType X );
BinTree Delete( BinTree BST, ElementType X );
Position Find( BinTree BST, ElementType X );
Position FindMin( BinTree BST );
Position FindMax( BinTree BST );
其中BinTree结构定义如下:
typedef struct TNode *Position;
typedef Position BinTree;
struct TNode{
ElementType Data;
BinTree Left;
BinTree Right;
};
函数Insert将X插入二叉搜索树BST并返回结果树的根结点指针;
函数Delete将X从二叉搜索树BST中删除,并返回结果树的根结点指针;如果X不在树中,则打印一行Not Found并返回原树的根结点指针;
函数Find在二叉搜索树BST中找到X,返回该结点的指针;如果找不到则返回空指针;
函数FindMin返回二叉搜索树BST中最小元结点的指针;
函数FindMax返回二叉搜索树BST中最大元结点的指针。
裁判测试程序样例:
#include
#include
typedef int ElementType;
typedef struct TNode *Position;
typedef Position BinTree;
struct TNode{
ElementType Data;
BinTree Left;
BinTree Right;
};
void PreorderTraversal( BinTree BT ); /* 先序遍历,由裁判实现,细节不表 */
void InorderTraversal( BinTree BT ); /* 中序遍历,由裁判实现,细节不表 */
BinTree Insert( BinTree BST, ElementType X );
BinTree Delete( BinTree BST, ElementType X );
Position Find( BinTree BST, ElementType X );
Position FindMin( BinTree BST );
Position FindMax( BinTree BST );
int main()
{
BinTree BST, MinP, MaxP, Tmp;
ElementType X;
int N, i;
BST = NULL;
scanf(“%d”, &N);
for ( i=0; i
if (Tmp==MinP) printf(“%d is the smallest key\n”, Tmp->Data);
if (Tmp==MaxP) printf(“%d is the largest key\n”, Tmp->Data);
}
}
scanf(“%d”, &N);
for( i=0; i
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BinTree Insert(BinTree BST, ElementType X) { if(!BST) { BST = (BinTree)malloc(sizeof(struct TNode)); BST->Left = NULL; BST->Right = NULL; BST->Data = X; } else if (X < BST->Data) { BST->Left = Insert(BST->Left, X); } else if(X > BST->Data){ BST->Right = Insert(BST->Right, X); } return BST; } Position FindMin(BinTree BST) { if (BST) { while (BST->Left != NULL) { BST = BST->Left; } } return BST; } Position FindMax(BinTree BST) { if (BST) { while (BST->Right != NULL) { BST = BST->Right; } } return BST; } Position Find(BinTree BST, ElementType X) { if (!BST) return NULL; if (X < BST->Data) { return Find(BST->Left, X); } else if (X > BST->Data) { return Find(BST->Right, X); } else return BST; } BinTree Delete(BinTree BST, ElementType X) { BinTree p; if (!BST) { printf("Not Found\n"); return BST; } if (X < BST->Data) { BST->Left = Delete(BST->Left, X); } else if (X > BST->Data) { BST->Right = Delete(BST->Right, X); } else { if (BST->Left && BST->Right) { p = FindMax(BST->Left); BST->Data = p->Data; BST->Left = Delete(BST->Left, BST->Data); } else { p = BST; if (!BST->Left) { BST = BST->Right; } else if (!BST->Right) { BST = BST->Left; } free(p); } } return BST; } |