红黑树删除的实现与四种情况的证明
🧭 学习重点
- 删除节点的三种情况
- 红黑树如何恢复性质
- 四种修复情况
- 完整可运行的 C++ 实现
一、红黑树删除的基础理解
红黑树删除比插入复杂得多,因为:
- 删除的是黑节点可能会破坏“从根到叶子黑节点数相等”的性质。
- 删除红节点无需修复,直接删。
- 删除黑节点,要么借黑色、要么旋转重构。
二、删除节点的三种基本情况(和 BST 类似)
- 无子节点(叶子节点):直接删。
- 有一个子节点:用子节点替代。
- 有两个子节点:找到中序后继,用其值替换被删节点,然后删除后继。
注意:红黑树中处理的是“颜色破坏”,不是结构本身。
三、红黑树删除修复目标
- 恢复五大性质(尤其是黑高一致性)
- 使用双黑节点表示“临时多了一层黑色”
- 四种修复方式:兄弟红、兄弟黑侄红、兄弟黑侄黑、旋转变色
四、四种删除修复情况(核心)
设 x 为“被提上来”的节点(可能是 NIL)
✅ Case 1:x 的兄弟是红色
P(B) S(B)
/ \ => / \
x(B) S(R) P(R) Sr(B)
/ \ / \
Sl Sr x(B) Sl- 父变红,兄变黑,左旋父节点,变成 Case 2~4。
✅ Case 2:x 的兄弟是黑色,且两个侄子都是黑色
P(?)
/ \
x(B) S(B)
/ \
B B- 把
S变红,x = p,向上传递双黑
✅ Case 3:兄弟黑,近侄子红,远侄子黑
P(?)
/ \
x(B) S(B)
/
R- 先右旋
S,再变成 Case 4
✅ Case 4:兄弟黑,远侄子红
P(?)
/ \
x(B) S(B)
\
R- 左旋
p,交换p和s颜色,把远侄子设为黑,修复完毕
五、完整 C++ 实现:红黑树删除
我们先定义红黑树结构(含旋转、插入、删除等):
✅ 树结构和节点定义
#include <iostream>
using namespace std;enum Color { RED, BLACK };struct Node {
int val;
Color color;
Node *left, *right, *parent;Node(int val): val(val), color(RED), left(nullptr), right(nullptr), parent(nullptr) {}
};✅ 左旋操作
void leftRotate(Node*& root, Node* x) {Node* y = x->right;x->right = y->left;if (y->left) y->left->parent = x;y->parent = x->parent;if (!x->parent) root = y;else if (x == x->parent->left) x->parent->left = y;else x->parent->right = y;y->left = x;x->parent = y;
}✅ 右旋操作
void rightRotate(Node*& root, Node* y) {Node* x = y->left;y->left = x->right;if (x->right) x->right->parent = y;x->parent = y->parent;if (!y->parent) root = x;else if (y == y->parent->left) y->parent->left = x;else y->parent->right = x;x->right = y;y->parent = x;
}✅ 找到最小节点(用于后继替换)
Node* minimum(Node* node) {while (node->left) node = node->left;return node;
}✅ 删除修复函数
void deleteFixUp(Node*& root, Node* x) {while (x != root && (!x || x->color == BLACK)) {if (x == x->parent->left) {Node* w = x->parent->right;if (w->color == RED) {w->color = BLACK;x->parent->color = RED;leftRotate(root, x->parent);w = x->parent->right;}if ((!w->left || w->left->color == BLACK) &&(!w->right || w->right->color == BLACK)) {w->color = RED;x = x->parent;} else {if (!w->right || w->right->color == BLACK) {if (w->left) w->left->color = BLACK;w->color = RED;rightRotate(root, w);w = x->parent->right;}w->color = x->parent->color;x->parent->color = BLACK;if (w->right) w->right->color = BLACK;leftRotate(root, x->parent);x = root;}} else {// 对称处理Node* w = x->parent->left;if (w->color == RED) {w->color = BLACK;x->parent->color = RED;rightRotate(root, x->parent);w = x->parent->left;}if ((!w->left || w->left->color == BLACK) &&(!w->right || w->right->color == BLACK)) {w->color = RED;x = x->parent;} else {if (!w->left || w->left->color == BLACK) {if (w->right) w->right->color = BLACK;w->color = RED;leftRotate(root, w);w = x->parent->left;}w->color = x->parent->color;x->parent->color = BLACK;if (w->left) w->left->color = BLACK;rightRotate(root, x->parent);x = root;}}}if (x) x->color = BLACK;
}✅ 删除操作主函数
void rbDelete(Node*& root, Node* z) {Node* y = z;Node* x;Color yOriginalColor = y->color;if (!z->left) {x = z->right;transplant(root, z, z->right);} else if (!z->right) {x = z->left;transplant(root, z, z->left);} else {y = minimum(z->right);yOriginalColor = y->color;x = y->right;if (y->parent == z) {if (x) x->parent = y;} else {transplant(root, y, y->right);y->right = z->right;y->right->parent = y;}transplant(root, z, y);y->left = z->left;y->left->parent = y;y->color = z->color;}if (yOriginalColor == BLACK)deleteFixUp(root, x);
}✅ 替换子树辅助函数
void transplant(Node*& root, Node* u, Node* v) {if (!u->parent) root = v;else if (u == u->parent->left) u->parent->left = v;else u->parent->right = v;if (v) v->parent = u->parent;
}六、总结与练习建议
- 删除是红黑树最复杂操作,逻辑较多但结构稳定
- 建议多画图分析每种情况
- 自己实现一棵树,从插入到删除,打印中序遍历验证