2022-05-22：给定一个二叉树，找到该树中两个指定节点的最近公共

2022-05-22：给定一个 二叉树 , 找到该树中两个指定节点的最近公共祖先。

百度百科中最近公共祖先的定义为：“对于有根树 T 的两个节点 p、q，最近公共祖先表示为一个节点 x，满足 x 是 p、q 的祖先且 x 的深度尽可能大（一个节点也可以是它自己的祖先）。

如何时间复杂度O(N)，额外空间复杂度O(1)，解决最低公共祖先问题?

力扣236。二叉树的最近公共祖先。

答案2022-05-22：

莫里斯遍历。

答案用rust编写，答案有误。代码如下：

 use std::cell::RefCell;
use std::rc::Rc;

fn main() {
    let mut head = Rc::new(RefCell::new(Some(TreeNode::new(3))));
    let mut left = Rc::clone(&head.borrow().as_ref().unwrap().left);
    *left.borrow_mut() = Some(TreeNode::new(5));

    let mut right = Rc::clone(&head.borrow().as_ref().unwrap().right);
    *right.borrow_mut() = Some(TreeNode::new(1));

    let mut head2 = Rc::clone(&head.borrow().as_ref().unwrap().left);
    let mut leftleft = Rc::clone(&head2.borrow().as_ref().unwrap().left);
    *leftleft.borrow_mut() = Some(TreeNode::new(6));

    let mut rightright = Rc::clone(&head2.borrow().as_ref().unwrap().right);
    *rightright.borrow_mut() = Some(TreeNode::new(2));

    let ans = lowest_common_ancestor(
        Rc::clone(&head),
        Rc::clone(&leftleft),
        Rc::clone(&rightright),
    );
    if ans.borrow().is_none() {
        println!("None");
    } else {
        println!("ans = {}", ans.borrow().as_ref().unwrap().val);
    }

    let mut left = Rc::clone(&head.borrow().as_ref().unwrap().left);
    let mut right = Rc::clone(&head.borrow().as_ref().unwrap().right);
    println!("head = {}", head.borrow().as_ref().unwrap().val);
    println!("p = {}", left.borrow().as_ref().unwrap().val);
    println!("q = {}", right.borrow().as_ref().unwrap().val);

    println!("---------------");
    println!("head = {}", head.borrow().as_ref().unwrap().val);
    println!("left = {}", left.borrow().as_ref().unwrap().val);
    println!("right = {}", right.borrow().as_ref().unwrap().val);
    println!("left.left = {}", leftleft.borrow().as_ref().unwrap().val);
    println!("left.right = {}", rightright.borrow().as_ref().unwrap().val);
}

pub  struct  TreeNode {
    pub val: i32,
    pub left: Rc<RefCell<Option<TreeNode>>>,
    pub right: Rc<RefCell<Option<TreeNode>>>,
}

impl TreeNode {
    pub fn new(val: i32) -> Self {
        Self {
            val,
            left: Rc::new(RefCell::new(None)),
            right: Rc::new(RefCell::new(None)),
        }
    }
}

fn lowest_common_ancestor(
    mut head: Rc<RefCell<Option<TreeNode>>>,
    mut o1: Rc<RefCell<Option<TreeNode>>>,
    mut o2: Rc<RefCell<Option<TreeNode>>>,
) -> Rc<RefCell<Option<TreeNode>>> {
    if !find_first(
        Rc::clone(&o1.borrow().as_ref().unwrap().left),
        Rc::clone(&o1),
        Rc::clone(&o2),
    )
    .borrow()
    .is_none()
        || !find_first(
            Rc::clone(&o1.borrow().as_ref().unwrap().right),
            Rc::clone(&o1),
            Rc::clone(&o2),
        )
        .borrow()
        .is_none()
    {
        return Rc::clone(&o1);
    }

    if !find_first(
        Rc::clone(&o2.borrow().as_ref().unwrap().left),
        Rc::clone(&o1),
        Rc::clone(&o2),
    )
    .borrow()
    .is_none()
        || !find_first(
            Rc::clone(&o2.borrow().as_ref().unwrap().right),
            Rc::clone(&o1),
            Rc::clone(&o2),
        )
        .borrow()
        .is_none()
    {
        return Rc::clone(&o1);
    }
    let mut left_aim: Rc<RefCell<Option<TreeNode>>> =
        find_first(Rc::clone(&head), Rc::clone(&o1), Rc::clone(&o2));
    let mut cur: Rc<RefCell<Option<TreeNode>>> = Rc::clone(&head);
    let mut most_right: Rc<RefCell<Option<TreeNode>>> = Rc::new(RefCell::new(None));
    let mut ans: Rc<RefCell<Option<TreeNode>>> = Rc::new(RefCell::new(None));
    while cur.borrow().is_none() {
        most_right = Rc::clone(&cur.borrow().as_ref().unwrap().left);
        if !most_right.borrow().is_none() {
            while !Rc::clone(&most_right.borrow().as_ref().unwrap().right)
                .borrow()
                .is_none()
                && is_eq(
                    Rc::clone(&most_right.borrow().as_ref().unwrap().right),
                    Rc::clone(&cur),
                )
            {
                let mut mostrightright = Rc::clone(&most_right.borrow().as_ref().unwrap().right);
                most_right = Rc::clone(&mostrightright);
            }
            if Rc::clone(&most_right.borrow().as_ref().unwrap().right)
                .borrow()
                .is_none()
            {
                let mut mostrightright = Rc::clone(&most_right.borrow().as_ref().unwrap().right);
                mostrightright = Rc::clone(&cur);
                let mut curleft = Rc::clone(&cur.borrow().as_ref().unwrap().left);
                cur = Rc::clone(&curleft);
                continue;
            } else {
                let mut mostrightright = Rc::clone(&most_right.borrow().as_ref().unwrap().right);
                mostrightright = Rc::new(RefCell::new(None));
                if find_left_aim(
                    Rc::clone(&cur.borrow().as_ref().unwrap().left),
                    Rc::clone(&left_aim),
                ) {
                    if ans.borrow().is_none()
                        && !find_first(
                            Rc::clone(&left_aim.borrow().as_ref().unwrap().right),
                            Rc::clone(&o1),
                            Rc::clone(&o2),
                        )
                        .borrow()
                        .is_none()
                    {
                        ans = Rc::clone(&left_aim);
                    }
                    left_aim = Rc::clone(&cur);
                }
            }
        }
        let mut curright = Rc::clone(&cur.borrow().as_ref().unwrap().right);
        cur = Rc::clone(&curright);
    }
    return if !ans.borrow().is_none() {
        ans
    } else {
        if !find_first(
            Rc::clone(&left_aim.borrow().as_ref().unwrap().right),
            Rc::clone(&o1),
            Rc::clone(&o2),
        )
        .borrow()
        .is_none()
        {
            Rc::clone(&left_aim)
        } else {
            Rc::clone(&head)
        }
    };
}
fn is_eq(mut a: Rc<RefCell<Option<TreeNode>>>, mut b: Rc<RefCell<Option<TreeNode>>>) ->  bool  {
    if a.borrow().is_none() && b.borrow().is_none() {
        return true;
    }
    if a.borrow().is_none() || b.borrow().is_none() {
        return false;
    }
    return a.borrow().as_ref().unwrap().val == b.borrow().as_ref().unwrap().val;
}

fn find_left_aim(
    mut head: Rc<RefCell<Option<TreeNode>>>,
    mut left_aim: Rc<RefCell<Option<TreeNode>>>,
) -> bool {
    let mut tail = reverse_edge(head);
    let mut cur = Rc::clone(&tail);
    let mut ans = false;
    while !cur.borrow().is_none() {
        if is_eq(Rc::clone(&cur), Rc::clone(&left_aim)) {
            ans = true;
        }
        let mut curright = Rc::clone(&cur.borrow().as_ref().unwrap().right);
        cur = Rc::clone(&curright);
    }
    reverse_edge(tail);
    return ans;
}

fn reverse_edge(mut from: Rc<RefCell<Option<TreeNode>>>) -> Rc<RefCell<Option<TreeNode>>> {
    let mut pre: Rc<RefCell<Option<TreeNode>>> = Rc::new(RefCell::new(None));
    let mut next: Rc<RefCell<Option<TreeNode>>> = Rc::new(RefCell::new(None));
    while !from.borrow().is_none() {
        next = Rc::clone(&from.borrow().as_ref().unwrap().right);
        {
            let mut fromright = Rc::clone(&from.borrow().as_ref().unwrap().right);
            fromright = Rc::clone(⪯); //此处错误
        }
        pre = Rc::clone(&from);
        from = Rc::clone(&next);
    }
    return pre;
}

fn find_first(
    mut head: Rc<RefCell<Option<TreeNode>>>,
    mut o1: Rc<RefCell<Option<TreeNode>>>,
    mut o2: Rc<RefCell<Option<TreeNode>>>,
) -> Rc<RefCell<Option<TreeNode>>> {
    if head.borrow().is_none() {
        return Rc::new(RefCell::new(None));
    }
    let mut cur: Rc<RefCell<Option<TreeNode>>> = Rc::clone(&head);
    let mut most_right: Rc<RefCell<Option<TreeNode>>> = Rc::new(RefCell::new(None));
    let mut first: Rc<RefCell<Option<TreeNode>>> = Rc::new(RefCell::new(None));
    while !cur.borrow().is_none() {
        most_right = Rc::clone(&cur.borrow().as_ref().unwrap().left);
        if !most_right.borrow().is_none() {
            while !Rc::clone(&most_right.borrow().as_ref().unwrap().right)
                .borrow()
                .is_none()
                && !is_eq(
                    Rc::clone(&most_right.borrow().as_ref().unwrap().right),
                    Rc::clone(&cur),
                )
            {
                let mut most_right_right = Rc::clone(&most_right.borrow().as_ref().unwrap().right);
                most_right = Rc::clone(&most_right_right);
            }
            if Rc::clone(&most_right.borrow().as_ref().unwrap().right)
                .borrow()
                .is_none()
            {
                if !first.borrow().is_none()
                    && (is_eq(Rc::clone(&cur), Rc::clone(&o1))
                        || is_eq(Rc::clone(&cur), Rc::clone(&o2)))
                {
                    first = Rc::clone(&cur);
                }

                let mut most_right_right = Rc::clone(&most_right.borrow().as_ref().unwrap().right);
                most_right_right = Rc::clone(&cur); //此处错误
                let mut curleft = Rc::clone(&cur.borrow().as_ref().unwrap().left);
                cur = Rc::clone(&curleft);
                continue;
            } else {
                let mut most_right_right = Rc::clone(&most_right.borrow().as_ref().unwrap().right);
                most_right_right = Rc::new(RefCell::new(None)); //此处错误
            }
        } else {
            if first.borrow().is_none()
                && (is_eq(Rc::clone(&cur), Rc::clone(&o1))
                    || is_eq(Rc::clone(&cur), Rc::clone(&o2)))
            {
                first = Rc::clone(&cur);
            }
            first = Rc::clone(&cur);
        }
        let mut curright = Rc::clone(&cur.borrow().as_ref().unwrap().right);
        cur = Rc::clone(&curright);
    }
    return first;
}  

执行结果如下：

答案用golang编写。代码如下：

 package main

import "fmt"

func main() {
head := &TreeNode{val: 3}
head.left = &TreeNode{val: 5}
head.right = &TreeNode{val: 1}
head.left.left = &TreeNode{val: 6}
head.left.right = &TreeNode{val: 2}
ans := lowestCommonAncestor(head, head.left.left, head.left.right)
fmt.Println(ans.val)
}

// Definition for a binary tree node.
type TreeNode struct {
val   int
left  *TreeNode
right *TreeNode
}

// 提交以下的方法
// 该方法亮点在于：时间复杂度O(N)，额外空间复杂度O(1)
func lowestCommonAncestor(head, o1, o2 *TreeNode) *TreeNode {
if findFirst(o1.left, o1, o2) != nil || findFirst(o1.right, o1, o2) != nil {
return o1
}
if findFirst(o2.left, o1, o2) != nil || findFirst(o2.right, o1, o2) != nil {
return o2
}
leftAim := findFirst(head, o1, o2)
cur := head
var mostRight *TreeNode
var ans *TreeNode
for cur != nil {
mostRight = cur.left
if mostRight != nil {
for mostRight.right != nil && mostRight.right != cur {
mostRight = mostRight.right
}
if mostRight.right == nil {
mostRight.right = cur
cur = cur.left
continue
} else {
mostRight.right = nil
if findLeftAim(cur.left, leftAim) {
if ans == nil && findFirst(leftAim.right, o1, o2) != nil {
ans = leftAim
}
leftAim = cur
}
}
}
cur = cur.right
}
if ans != nil {
return ans
} else {
if findFirst(leftAim.right, o1, o2) != nil {
return leftAim
} else {
return head
}
}
}

func findLeftAim(head, leftAim *TreeNode) bool {
tail := reverseEdge(head)
cur := tail
ans := false
for cur != nil {
if cur == leftAim {
ans = true
}
cur = cur.right
}
reverseEdge(tail)
return ans
}

func reverseEdge(from *TreeNode) *TreeNode {
var pre *TreeNode
var next *TreeNode
for from != nil {
next = from.right
from.right = pre
pre = from
from = next
}
return pre
}

func findFirst(head, o1, o2 *TreeNode) *TreeNode {
if head == nil {
return nil
}
cur := head
var mostRight *TreeNode
var first *TreeNode
for cur != nil {
mostRight = cur.left
if mostRight != nil {
for mostRight.right != nil && mostRight.right != cur {
mostRight = mostRight.right
}
if mostRight.right == nil {
if first == nil && (cur == o1 || cur == o2) {
first = cur
}
mostRight.right = cur
cur = cur.left
continue
} else {
mostRight.right = nil
}
} else {
if first == nil && (cur == o1 || cur == o2) {
first = cur
}
}
cur = cur.right
}
return first
}  

执行结果如下：

***

[左神java代码](