LintCode 88. Lowest Common Ancestor (Medium)

LeetCode 236. Lowest Common Ancestor of a Binary Tree (Medium)

今天写了三种解法, 都比较长.

解法1 前序递归DFS, 计数

这个解法的判断比较啰嗦, 但好处就是, 能够根据当前情况选择是否继续向下遍历, 不做无用的搜索. 越早地找到两个节点, 程序就会越早结束.

class Solution {

private:

    TreeNode *lca;

    TreeNode *tA, *tB;

    int findLCA(TreeNode *root) {

        if (!root) return 0;

        int cnt = 0;

        if (root->val == tA->val) ++cnt;

        if (root->val == tB->val) ++cnt;

        if (cnt == 2) {

            lca = root;

            return 2;

        }

        int leftCnt = findLCA(root->left);

        if (leftCnt == 2) return 2;

        cnt += leftCnt;

        if (cnt == 2) {

            lca = root;

        } else {

            int rightCnt = findLCA(root->right);

            if (rightCnt == 2) return 2;

            cnt += rightCnt;

            if (cnt == 2) {

                lca = root;

            }

        }

        return cnt;

    }

public:

    TreeNode *lowestCommonAncestor(TreeNode *root, TreeNode *A, TreeNode *B) {

        if (!root || !A || !B) return NULL;

        lca = NULL;

        tA = A, tB = B;

        findLCA(root);

        return lca;

    }

};

时间复杂度: O(n)

空间复杂度: O(logn) (考虑到递归的堆栈消耗)

解法2 后序非递归DFS

写了递归的, 自然就想写个非递归的.

思路是:

1. 在碰到第一个节点的时候让LCA_PTR指向当前节点, 真正的LCA一定是*LCA_PTR本身或者上游节点.
2. 每次路过*LCA_PTR的父节点的时候, LCA_PTR上移指向父节点. (前序和中序非递归遍历中, 路过就是访问; 后序非递归遍历中, 路过不一定是访问)
3. 当碰到第二个节点的时候, LCA_PTR停留的地方就是真正的LCA.

但是写着写着才注意到, 步骤2决定了必须要用后序遍历才行. 因为前序和中序遍历中, 找到目标节点时, 父节点的遍历可能已经结束了.

要注意的是步骤2中的路过, 即

if (lca && root->left == lca || root->right == lca) {

    lca = root;

}

应该紧随root = s.top(), 而不是放在"访问当前节点"的地方.

class Solution {

public:

    TreeNode *lowestCommonAncestor(TreeNode *root, TreeNode *A, TreeNode *B) {

        if (!root || !A || !B) return NULL;

        TreeNode *lca = NULL;

        stack<TreeNode*> s;

        TreeNode *prev = NULL;

        int cnt = 0;

        while (root || !s.empty()) {

            while (root) {

                s.push(root);

                root = root->left;

            }

            root = s.top();

            if (lca && root->left == lca || root->right == lca) {

                lca = root;

            }

            if (!root->right || root->right == prev) {

                s.pop();

                if (root->val == A->val) {

                    ++cnt;

                    if (cnt == 1) lca = root;

                }

                if (root->val == B->val) {

                    ++cnt;

                    if (cnt == 1) lca = root;

                }

                if (cnt == 2) return lca;

                prev = root;

                root = NULL;

            } else {

                root = root->right;

            }

        }

        return NULL;

    }

};

时间复杂度: O(n)

空间复杂度: O(n)

解法3 单链表的交点

当每个节点有指向父节点的指针时可以用这种方法. 题中的TreeNode结构没有parent指针, 用map构造就好了.

class Solution {

private:

    map<TreeNode*, TreeNode*> parents;

    void buildParents(TreeNode *root) {

        if (root->left) {

            parents[root->left] = root;

            buildParents(root->left);

        }

        if (root->right) {

            parents[root->right] = root;

            buildParents(root->right);

        }

    }

    int depth(TreeNode *node) {

        int d = 0;

        while (node) {

            node = parents[node];

            ++d;

        }

        return d;

    }

public:

    TreeNode *lowestCommonAncestor(TreeNode *root, TreeNode *A, TreeNode *B) {

        if (!root || !A || !B) return NULL;

        parents.clear();

        parents[root] = NULL;

        buildParents(root);

        int da = depth(A), db = depth(B);

        if (da < db) {

            swap(da, db);

            swap(A, B);

        }

        while (da > db) {

            A = parents[A];

            da--;

        }

        while (da && A != B) {

            A = parents[A];

            B = parents[B];

            da--;

        }

        return A;

    }

};

时间复杂度: O(n)

空间复杂度: O(n)

解法4 双堆栈

回顾了一下LeetCode上半年前写的代码, 发现当时思路还蛮清晰. 思路类似解法2, 但是多用一个堆栈表示从root到LCA的路径, 好处就是代码更清晰一些, 而且中序遍历即可.

class Solution {

public:

    TreeNode* lowestCommonAncestor(TreeNode* root, TreeNode* p, TreeNode* q) {

        stack<TreeNode*> s;

        stack<TreeNode*> path;

        bool foundFirst = false;

        TreeNode *lca = NULL;

        while (root || !s.empty()) {

            while (root) {

                if (!foundFirst) {

                    path.push(root);

                }

                s.push(root);

                root = root->left;

            }

            root = s.top();

            if (!path.empty() && root == path.top()) {

                lca = root;

                path.pop();

            }

            s.pop();

            if (root == p || root == q) {

                if (foundFirst) {

                    return lca;

                }

                foundFirst = true;

            }

            root = root->right;

        }

        return NULL;

    }

};

时间复杂度: O(n)

空间复杂度: O(n)

解法5 前序递归DFS, 指针

这代码应该是当初看了LeetCode Discuss中的解答写出来的. 相对于解法1, 代码很简洁, 用指针的回传表达是否找到目标节点. 要说缺陷, 就是扫描的点比解法1多一些.

class Solution {

public:

    TreeNode* lowestCommonAncestor(TreeNode* root, TreeNode* p, TreeNode* q) {

        if (!root || root == p || root == q) return root;

        TreeNode *left = lowestCommonAncestor(root->left, p, q), *right = lowestCommonAncestor(root->right, p, q);

        return left && right ? root : (left ? left : right);

    }

};

时间复杂度: O(n)

空间复杂度: O(logn)