2458. Height of Binary Tree After Subtree Removal Queries
MD ARIFUL HAQUE
Posted on October 26, 2024
2458. Height of Binary Tree After Subtree Removal Queries
Difficulty: Hard
Topics: Array
, Tree
, Depth-First Search
, Breadth-First Search
, Binary Tree
You are given the root
of a binary tree with n
nodes. Each node is assigned a unique value from 1
to n
. You are also given an array queries
of size m
.
You have to perform m
independent queries on the tree where in the ith
query you do the following:
-
Remove the subtree rooted at the node with the value
queries[i]
from the tree. It is guaranteed thatqueries[i]
will not be equal to the value of the root.
Return an array answer
of size m
where answer[i]
is the height of the tree after performing the ith
query.
Note:
- The queries are independent, so the tree returns to its initial state after each query.
- The height of a tree is the number of edges in the longest simple path from the root to some node in the tree.
Example 1:
- Input: root = [1,3,4,2,null,6,5,null,null,null,null,null,7], queries = [4]
- Output: [2]
-
Explanation: The diagram above shows the tree after removing the subtree rooted at node with value 4.
- The height of the tree is 2 (The path 1 -> 3 -> 2).
Example 2:
- Input: root = [5,8,9,2,1,3,7,4,6], queries = [3,2,4,8]
- Output: [3,2,3,2]
-
Explanation: We have the following queries:
- Removing the subtree rooted at node with value 3. The height of the tree becomes 3 (The path 5 -> 8 -> 2 -> 4).
- Removing the subtree rooted at node with value 2. The height of the tree becomes 2 (The path 5 -> 8 -> 1).
- Removing the subtree rooted at node with value 4. The height of the tree becomes 3 (The path 5 -> 8 -> 2 -> 6).
- Removing the subtree rooted at node with value 8. The height of the tree becomes 2 (The path 5 -> 9 -> 3).
Constraints:
- The number of nodes in the tree is
n
. 2 <= n <= 105
1 <= Node.val <= n
- All the values in the tree are unique.
m == queries.length
1 <= m <= min(n, 104)
1 <= queries[i] <= n
queries[i] != root.val
Hint:
- Try pre-computing the answer for each node from 1 to n, and answer each query in O(1).
- The answers can be precomputed in a single tree traversal after computing the height of each subtree.
Solution:
The solution employs a two-pass approach:
- Calculate the height of each node in the tree.
- Determine the maximum height of the tree after removing the subtree rooted at each queried node.
Let's implement this solution in PHP: 2458. Height of Binary Tree After Subtree Removal Queries
Code Breakdown
1. Class Definition and Properties:
class Solution {
private $valToMaxHeight = [];
private $valToHeight = [];
-
valToMaxHeight
: This array will store the maximum height of the tree after removing each node's subtree. -
valToHeight
: This array will store the height of each node's subtree.
2. Main Function:
function treeQueries($root, $queries) {
...
...
...
/**
* go to ./solution.php
*/
}
- The function
treeQueries
takes theroot
of the tree and thequeries
array. - It first calls the
height
function to compute the height of each node. - Then, it calls the
dfs
(depth-first search) function to compute the maximum heights after subtree removals. - Finally, it populates the
answer
array with the results for each query.
3. Height Calculation:
private function height($node) {
...
...
...
/**
* go to ./solution.php
*/
}
- This function computes the height of each node recursively.
- If the node is
null
, it returns 0. - If the height of the node is already computed, it retrieves it from the cache (
valToHeight
). - It calculates the height based on the heights of its left and right children and stores it in
valToHeight
.
4. Depth-First Search for Maximum Height:
private function dfs($node, $depth, $maxHeight) {
...
...
...
/**
* go to ./solution.php
*/
}
- This function performs a DFS to compute the maximum height of the tree after each node's subtree is removed.
- It records the current maximum height in
valToMaxHeight
for the current node. - It calculates the heights of the left and right subtrees and updates the maximum height accordingly.
- It recursively calls itself for the left and right children, updating the depth and maximum height.
Example Walkthrough
Let's go through an example step-by-step.
Example Input:
// Tree Structure
// 1
// / \
// 3 4
// / / \
// 2 6 5
// \
// 7
$root = [1, 3, 4, 2, null, 6, 5, null, null, null, null, null, 7];
$queries = [4];
Initial Height Calculation:
- The height of the tree rooted at 1:
3
- The height of the tree rooted at 3:
2
- The height of the tree rooted at 4:
2
(height of subtrees rooted at 6 and 5) - The height of the tree rooted at 6:
1
(just node 7) - The height of the tree rooted at 2:
0
(leaf node)
After the height computation, valToHeight
would look like this:
$valToHeight = [
1 => 3,
2 => 0,
3 => 2,
4 => 2,
5 => 0,
6 => 1,
7 => 0
];
DFS for Max Heights:
- For the root (1), removing subtree 4 leaves:
- Left Height: 2 (rooted at 3)
- Right Height: 1 (rooted at 5)
- Thus, the maximum height after removing 4 is
2
.
Result Array After Queries:
- For the query
4
, the result would be[2]
.
Final Output
The result for the input provided will be:
// Output
[2]
This structured approach ensures that we efficiently compute the necessary heights and answer each query in constant time after the initial preprocessing. The overall complexity is O(n + m), where n is the number of nodes in the tree and m is the number of queries.
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Posted on October 26, 2024
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