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All Nodes Distance K in Binary Tree

Sar Champagne Bielert edited this page Apr 8, 2024 · 4 revisions

Problem Highlights

1: U-nderstand

Understand what the interviewer is asking for by using test cases and questions about the problem.

  • Established a set (2-3) of test cases to verify their own solution later.
  • Established a set (1-2) of edge cases to verify their solution handles complexities.
  • Have fully understood the problem and have no clarifying questions.
  • Have you verified any Time/Space Constraints for this problem?
  • Can the input tree be Null?
    • No, there will at least be one node
  • Are all values unique?
    • Yes, all values are unique.
  • What is the Time and Space Constraints for this problem?
    • O(N) Time and O(N) Space.
HAPPY CASE
Input: root = [3,5,1,6,2,0,8,null,null,7,4], target = 5, k = 2
Output: [7,4,1]
Explanation: The nodes that are a distance 2 from the target node (with value 5) have values 7, 4, and 1.
Input: root = [1,2,3], target = 1, k = 1
Output: [2,3]

EDGE CASE 
Input: root = [1], target = 1, k = 3
Output: []

2: M-atch

Match what this problem looks like to known categories of problems, e.g. Linked List or Dynamic Programming, and strategies or patterns in those categories.

If you are dealing with Binary Trees some common techniques you can employ to help you solve the problem:

  • Think about appropriate Tree Traversal: Pre-Order, In-Order, Post-Order, Level-Order
    • Choosing a specific tree traversal that follows a general target-to-k away path should help us identify all of the possible routes.
  • Store nodes within a HashMap to refer to later
    • A hashmap is very helpful for traversing back to the parent node. As we have no way of returning back to the parent node and keeping count of k away, without it.
  • Using Binary Search to find an element
    • We are not working with a Binary Search Tree.
  • Applying a level-order traversal with a queue
    • Using this approach may complicate our code

3: P-lan

Plan the solution with appropriate visualizations and pseudocode.

General Idea: Let build a parent map for each node. Then we will recursively traverse from the target node to k nodes away and store those nodes in results

1. Create a helper function to store parentNode in hashmap
    a. Basecase: If node is None, return
    b. Set current node as key and parent as value
    c. Recursively call left child and right child.
2. Create a second helper function to traverse from target node to parent and child nodes and find nodes k away.
    a. Basecase: If node is None, or have been traversed, or node is more than k away, return
    b. Add node to traversed set, so we do not travel down the same path
    c. Upon meeting a node k away from target, add to results
    d. Otherwise continue searching, left child, right child, and parent
3. Create Parent Map, traversed set, and results to retain memory.
4. Call getParent function to populate ParentMap
5. Call getNodes function to populate results
6. Return Results

⚠️ Common Mistakes

  • Choosing the wrong traversal type
    • Try to walk through the problem by hand and see the order in which you are processing the nodes. This will clue you into the type of traversal necessary
  • Not creating a helper function
    • Multiple helper function can help perform multiple dfs calls for solution.

4: I-mplement

Implement the code to solve the algorithm.

# Definition for a binary tree node.
# class TreeNode:
#     def __init__(self, x):
#         self.val = x
#         self.left = None
#         self.right = None

class Solution:
    def distanceK(self, root: TreeNode, target: TreeNode, k: int) -> List[int]:
        # Create a helper function to store parentNode in hashmap
        def populateParentMap(node, parent):
            # Basecase: If node is None, return
            if node is None:
                return 

            # Set current node as key and parent as value
            parentMap[node] = parent 

            # Recursively call left child and right child
            populateParentMap(node.left, node)
            populateParentMap(node.right, node)
        
        # DFS function that gets the nodes at a distance k from the target
        def getNodes(node, numOfNodesAway):
            # Basecase: If node is None, or have been traversed, or node is more than k away, return
            if not node or node in traversed or numOfNodesAway > k:
                return 

            # Add node to traversed set, so we do not travel down the same path
            traversed.add(node)

            # Upon meeting a node k away from target, add to results
            if numOfNodesAway == k:
                results.append(node.val) # append to result when cnt/distance is k
                return 
            
            # Otherwise continue searching, left child, right child, and parent
            getNodes(node.left, numOfNodesAway + 1)
            getNodes(node.right, numOfNodesAway + 1)
            getNodes(parentMap[node], numOfNodesAway + 1)

        # Create Parent Map, traversed set, and results to retain memory.
        parentMap = {}
        traversed = set()
        results = []

        # Call getParent function to populate ParentMap
        populateParentMap(root, None) 

        # Call getNodes function to populate results
        getNodes(target, 0) 

        # Return Results
        return results
class Solution {
    // Create Parent Map, traversed set, and results to retain memory.
    List<Integer> answer = new ArrayList<>();
    Map<TreeNode, TreeNode> childParentMap = new HashMap<>();
    Set<TreeNode> visited = new HashSet<>();
    
    public List<Integer> distanceK(TreeNode root, TreeNode target, int k) {
        // Call getParent function to populate ParentMap
        getParent(root);
        // Call getNodes function to populate results
        getNodes(target, k);

        // Return Results
        return answer;
    }
    
    // Create a helper function to store parentNode in hashmap
    private void getParent(TreeNode node) {
        // Basecase: If node is None, return
        if(node == null) {
            return;
        }

        // Set current node as key and parent as value
        // Recursively call left child and right child
        if(node.left != null) {
            childParentMap.put(node.left, node);
            getParent(node.left);
        }
        if(node.right != null) {
            childParentMap.put(node.right, node);
            getParent(node.right);
        }
    }
    
    // DFS function that gets the nodes at a distance k from the target
    private void getNodes(TreeNode node, int k) {
        // Basecase: If node is None, or have been traversed, or node is more than k away, return
        if(node == null || visited.contains(node)) {
            return;
        }

        // Add node to traversed set, so we do not travel down the same path
        visited.add(node);

        // Upon meeting a node k away from target, add to results
        if(k == 0) {
            answer.add(node.val);
            return;
        }

        // Otherwise continue searching, left child, right child, and parent
        getNodes(node.left, k-1);
        getNodes(node.right, k-1);
        getNodes(childParentMap.get(node), k-1);
    }
}

5: R-eview

Review the code by running specific example(s) and recording values (watchlist) of your code's variables along the way.

  • Trace through your code with an input to check for the expected output
  • Catch possible edge cases and off-by-one errors

6: E-valuate

Evaluate the performance of your algorithm and state any strong/weak or future potential work.

Assume N represents the number nodes in tree

  • Time Complexity: O(N) because we only need to visit each node in binary tree twice. One time to build the parent map and the second to find nodes k away from target.
  • Space Complexity: O(N), by using a hashmap to hold the parent nodes.
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