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I went to an interview today where I was asked to serialize a binary tree. I implemented an array-based approach where the children of node i (numbering in level-order traversal) were at the 2*i index for the left child and 2*i + 1 for the right child. The interviewer seemed more or less pleased, but I'm wondering what serialize means exactly? Does it specifically pertain to flattening the tree for writing to disk, or would serializing a tree also include just turning the tree into a linked list, say. Also, how would we go about flattening the tree into a (doubly) linked list, and then reconstructing it? Can you recreate the exact structure of the tree from the linked list?

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Related: stackoverflow.com/questions/2675756/… –  Aryabhatta Jan 6 '11 at 3:54
    
Most of the time interviewers will ask this question to see if you will us a recursive approach. Basically, you write serialize for leaf nodes, and then for parent nodes, you call serialize(left), output current node, serialize(right). It's an elegant solution and you let interviewers know that you have taken a decent algorithms class. –  Zeki Jan 6 '11 at 3:55
    
thanks everyone for the helpful info. –  worker1138 Jan 7 '11 at 4:46

4 Answers 4

Approach 1: Do both Inorder and Preorder traversal to searialize the tree data. On de-serialization use Pre-order and do BST on Inorder to properly form the tree.

You need both because A -> B -> C can be represented as pre-order even though the structure can be different.

Approach 2: Use # as a sentinel whereever the left or right child is null.....

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All those articles talk mostly about the serialization part. The deserialization part is slightly tricky to do in one pass.

I have implemented an efficient solution for deserialization too.

Problem: Serialize and Deserialize a binary tree containing positive numbers.

Serialization part:

  1. Use 0 to represent null.
  2. Serialize to list of integers using preorder traversal.

Deserialization part:

  1. Takes in list of integers and uses recursive helper method for deserialization.
  2. Recursive deserializer returns a pair (BTNode node, int nextIndexToRead) where node is tree node constructed so far, and nextIndexToRead is position of next number to be read in the serialized list of numbers.

Below is the code in Java:

public final class BinaryTreeSerializer
{
    public static List<Integer> Serialize(BTNode root)
    {
        List<Integer> serializedNums = new ArrayList<Integer>();

        SerializeRecursively(root, serializedNums);

        return serializedNums;
    }

    private static void SerializeRecursively(BTNode node, List<Integer> nums)
    {
        if (node == null)
        {
            nums.add(0);
            return;
        }

        nums.add(node.data);
        SerializeRecursively(node.left, nums);
        SerializeRecursively(node.right, nums);
    }

    public static BTNode Deserialize(List<Integer> serializedNums)
    {
        Pair pair = DeserializeRecursively(serializedNums, 0);

        return pair.node;
    }

    private static Pair DeserializeRecursively(List<Integer> serializedNums, int start)
    {        
        int num = serializedNums.get(start);

        if (num == 0)
        {
            return new Pair(null, start + 1);
        }

        BTNode node = new BTNode(num);

        Pair p1 = DeserializeRecursively(serializedNums, start + 1);
        node.left = p1.node;

        Pair p2 = DeserializeRecursively(serializedNums, p1.startIndex);
        node.right = p2.node;

        return new Pair(node, p2.startIndex);
    }

    private static final class Pair
    {
        BTNode node;
        int startIndex;

        private Pair(BTNode node, int index)
        {
            this.node = node;
            this.startIndex = index;
        }
    }
}

public class BTNode 
{
    public int data;
    public BTNode left;
    public BTNode right;

    public BTNode(int data)
    {
        this.data = data;
    }
}
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How about performing an in-order traversal and putting the root key and all node keys into a std::list or other container of your choice which flattens the tree. Then, simply serialize the std::list or container of your choice using the boost library.

The reverse is simple and then rebuild the tree using standard insertion to a binary tree. This may not be entirely efficient for a very large tree but runtime to convert the tree into a std::list is O(n) at most and to rebuild the tree is O(log n) at most.

I am about to do this to serialize a tree I just coded up in c++ as I am converting my database from Java to C++.

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The best way is to use a special char (like # as previous comment mentioned) as sentinel. It's better than constructing an inorder traversal array and a preorder/postorder traversal array, both in space complexity wise and time complexity wise. it's also way easier to implement.

Linked list is not a good fit here since in order to reconstruct the tree, you better have const element access time

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What if tree node value can be '#'? –  Chuntao Lu Feb 4 at 18:26

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