# Merging 2 Binary Search Trees

How do you merge 2 Binary Search Trees in such a way that the resultant tree contains all the elements of both the trees and also maintains the BST property.

I saw the solution provided in how to merge two BST's efficiently?

However that solution involves converting into a Double Linked List. I was wondering if there is a more elegant way of doing this which could be done in place without the conversion. I came up with the following pseudocode. Does it work for all cases? Also I am having trouble with the 3rd case.

``````node* merge(node* head1, node* head2) {
if (!head1)
return head2;
if (!head2)
return head1;

// Case 1.
if (head1->info > head2->info) {
node* temp = head2->right;
head2->right = NULL;
head1->left = merge(head1->left, head2);
head1 = merge(head1, temp);
return head1;
} else if (head1->info < head2->info)  { // Case 2
// Similar to case 1.
} else { // Case 3
// ...
}
}
``````
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Trees are not simple as LinkedLists, so they have to be traversed to retrieve each item, stored in a more 'linear' data structure, and then added to the other tree to do the merge. – SpeedBirdNine Sep 24 '11 at 18:04
Elegance is rather subjective... I find the flatten and rebuild method to be quite elegant! :) – Hari Shankar Sep 24 '11 at 18:08
Are the BSTs provided self-balancing? – MAK Oct 10 '11 at 12:00

## 7 Answers

The two binary search trees (BST) cannot be merged directly during a recursive traversal. Suppose we should merge Tree 1 and Tree 2 shown in the figure.

The recursion should reduce the merging to a simpler situation. We cannot reduce the merging only to the respective left subtrees L1 and L2, because L2 can contain numbers larger than 10, so we would need to include the right subtree R1 into the process. But then we include numbers greater than 10 and possibly greater than 20, so we would need to include the right subtree R2 as well. A similar reasoning shows that we cannot simplify the merging by including subtrees from Tree 1 and from Tree 2 at the same time.

The only possibility for reduction is to simplify only inside the respective trees. So, we can transform the trees to their right spines with sorted nodes:

Now, we can merge the two spines easily into one spine. This spine is in fact a BST, so we could stop here. However, this BST is completely unbalanced, so we transform it to a balanced BST.

The complexity is:

``````Spine 1: time = O(n1),    space = O(1)
Spine 2: time = O(n2),    space = O(1)
Merge:   time = O(n1+n2), space = O(1)
Balance: time = O(n1+n2), space = O(1)
Total:   time = O(n1+n2), space = O(1)
``````

The complete running code is on http://ideone.com/RGBFQ. Here are the essential parts. The top level code is a follows:

``````Node* merge(Node* n1, Node* n2) {
Node *prev, *head1, *head2;
prev = head1 = 0; spine(n1, prev, head1);
prev = head2 = 0; spine(n2, prev, head2);
return balance(mergeSpines(head1, head2));
}
``````

The auxiliary functions are for the tranformation to spines:

``````void spine(Node *p, Node *& prev, Node *& head) {
if (!p) return;
spine(p->left, prev, head);
if (prev) prev->right = p;
else head = p;
prev = p;
p->left = 0;
spine(p->right, prev, head);
}
``````

Merging of the spines:

``````void advance(Node*& last, Node*& n) {
last->right = n;
last = n;
n = n->right;
}

Node* mergeSpines(Node* n1, Node* n2) {
Node head;
Node* last = &head;
while (n1 || n2) {
if (!n1) advance(last, n2);
else if (!n2) advance(last, n1);
else if (n1->info < n2->info) advance(last, n1);
else if (n1->info > n2->info) advance(last, n2);
else {
advance(last, n1);
printf("Duplicate key skipped %d \n", n2->info);
n2 = n2->right;
}
}
return head.right;
}
``````

Balancing:

``````Node* balance(Node *& list, int start, int end) {
if (start > end) return NULL;
int mid = start + (end - start) / 2;
Node *leftChild = balance(list, start, mid-1);
Node *parent = list;
parent->left = leftChild;
list = list->right;
parent->right = balance(list, mid+1, end);
return parent;
}

Node* balance(Node *head) {
int size = 0;
for (Node* n = head; n; n = n->right) ++size;
return balance(head, 0, size-1);
}
``````
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Surely your "spines" are equivalent to flattening the tree into a linked list? – Stobor Oct 13 '11 at 5:41
Yes, the spine is equivalent to a single linked list, where the "right child pointer" is the "next element pointer". The "left child pointer" is "null". So, it is still a tree with only one branch, which is the sorted list. – Jiri Oct 18 '11 at 8:01
Fair enough. I was just pointing it out, because the question suggested wanting an "in place without the conversion" method, and your method (which I like) involves the same conversion. +1 anyway for the detail. – Stobor Oct 20 '11 at 1:15

Assuming we have two trees A and B we insert root of tree A into tree B and using rotations move inserted root to become new root of tree B. Next we recursively merge left and right sub-trees of trees A and B. This algorithm takes into account both trees structure but insertion still depends on how balanced target tree is. You can use this idea to merge the two trees in `O(n+m)` time and `O(1)` space.

The following implementation is due to Dzmitry Huba:

``````// Converts tree to sorted singly linked list and appends it
// to the head of the existing list and returns new head.
// Left pointers are used as next pointer to form singly
// linked list thus basically forming degenerate tree of
// single left oriented branch. Head of the list points
// to the node with greatest element.
static TreeNode<T> ToSortedList<T>(TreeNode<T> tree, TreeNode<T> head)
{
if (tree == null)
// Nothing to convert and append
return head;
// Do conversion using in order traversal
// Convert first left sub-tree and append it to
// existing list
head = ToSortedList(tree.Left, head);
// Append root to the list and use it as new head
tree.Left = head;
// Convert right sub-tree and append it to list
// already containing left sub-tree and root
return ToSortedList(tree.Right, tree);
}

// Merges two sorted singly linked lists into one and
// calculates the size of merged list. Merged list uses
// right pointers to form singly linked list thus forming
// degenerate tree of single right oriented branch.
// Head points to the node with smallest element.
static TreeNode<T> MergeAsSortedLists<T>(TreeNode<T> left, TreeNode<T> right, IComparer<T> comparer, out int size)
{
TreeNode<T> head = null;
size = 0;
// See merge phase of merge sort for linked lists
// with the only difference in that this implementations
// reverts the list during merge
while (left != null || right != null)
{
TreeNode<T> next;
if (left == null)
next = DetachAndAdvance(ref right);
else if (right == null)
next = DetachAndAdvance(ref left);
else
next = comparer.Compare(left.Value, right.Value) > 0
? DetachAndAdvance(ref left)
: DetachAndAdvance(ref right);
next.Right = head;
head = next;
size++;
}
return head;
}

static TreeNode<T> DetachAndAdvance<T>(ref TreeNode<T> node)
{
var tmp = node;
node = node.Left;
tmp.Left = null;
return tmp;
}

// Converts singly linked list into binary search tree
// advancing list head to next unused list node and
// returning created tree root
static TreeNode<T> ToBinarySearchTree<T>(ref TreeNode<T> head, int size)
{
if (size == 0)
// Zero sized list converts to null
return null;

TreeNode<T> root;
if (size == 1)
{
// Unit sized list converts to a node with
// left and right pointers set to null
root = head;
// Advance head to next node in list
head = head.Right;
// Left pointers were so only right needs to
// be nullified
root.Right = null;
return root;
}

var leftSize = size / 2;
var rightSize = size - leftSize - 1;
// Create left substree out of half of list nodes
var leftRoot = ToBinarySearchTree(ref head, leftSize);
// List head now points to the root of the subtree
// being created
root = head;
// Advance list head and the rest of the list will
// be used to create right subtree
head = head.Right;
// Link left subtree to the root
root.Left = leftRoot;
// Create right subtree and link it to the root
root.Right = ToBinarySearchTree(ref head, rightSize);
return root;
}

public static TreeNode<T> Merge<T>(TreeNode<T> left, TreeNode<T> right, IComparer<T> comparer)
{
Contract.Requires(comparer != null);

if (left == null || right == null)
return left ?? right;
// Convert both trees to sorted lists using original tree nodes
var leftList = ToSortedList(left, null);
var rightList = ToSortedList(right, null);
int size;
// Merge sorted lists and calculate merged list size
var list = MergeAsSortedLists(leftList, rightList, comparer, out size);
// Convert sorted list into optimal binary search tree
return ToBinarySearchTree(ref list, size);
}
``````
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The idea you have written is different and code you have given is different. The code if for creating tree y converting both of 'em in sorted LL and then merging and then Creating tree from it – Peter Apr 23 '12 at 17:33

A BST is a ordered or sorted binary tree. My algorithm would be to simple :

• traverse through both trees
• compare the values
• insert the smaller of the two into a new BST.

The python code for traversing is as follows:

``````def traverse_binary_tree(node, callback):
if node is None:
return
traverse_binary_tree(node.leftChild, callback)
callback(node.value)
traverse_binary_tree(node.rightChild, callback)
``````

The cost for traversing through the BST and building a new merged BST would remain O(n)

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Wouldn't the new tree be awfully unbalanced (essentially a linked list), unless it is a self-balancing tree (AVL, Red-Black, etc.)? – Omri Barel Sep 24 '11 at 20:13
Also how about the 2 remaining trees? You would need to delete them. And note that your pseudo code is visiting a single tree, visiting both trees for a merge operation would be much more different. – Atacan Sep 25 '11 at 3:53
@OmriBarel in which case also it would be O(nlogn) – Shahbaz Sep 27 '11 at 23:07
Hmm.. I was thinking the same thing and was also gonna answer, but then saw yours ;) – BlackBear Oct 7 '11 at 18:12
You will want to measure this with more than one variable. E.g. `n` for the size of the first tree and `m` for the second. The best algorithm so far seams to run in `O(min(m+n, m*logn, n*logm))` – Thomas Ahle Oct 7 '11 at 23:54

The best way we could merge the trees in place is something like:

``````For each node n in first BST {
Go down the 2nd tree and find the appropriate place to insert n
Insert n there
}
``````

Each iteration in the for loop is O(log n) since we are dealing with trees, and the for loop will be iterated n times, so in total we have O(n log n).

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Not the best way! But it is indeed one way of doing it. – Evan Leis Apr 10 '14 at 17:24

The following algorithm is from Algorithms in C++.

The idea is almost the same as in the algorithm posted by PengOne. This algorithm does in place merging, time complexity is O(n+m).

``````link join(link a, link b) {
if (b == 0) return a;
if (a == 0) return b;
insert(b, a->item);
b->left = join(a->left, b->left);
b->right = join(a->right, b->right);
delete a;
return b;
}
``````

`insert` just inserts an item in the right place in the tree.

``````void insert(link &h, Item x) {
if (h == 0) {
h = new node(x);
return;
}
if (x.key() < h->item.key()) {
insert(h->left, x);
rotateRight(h);
}
else {
insert(h->right, x);
rotateLeft(h);
}
}
``````

`rotateRight` and `rotateLeft` keep tree in the right order.

``````void rotateRight(link &h) {
link x = h->left;
h->left = x->right;
x->right = h;
h = x;
}

void rotateLeft(link &h) {
link x = h->right;
h->right = x->left;
x->left = h;
h = x;
}
``````

Here `link` is `node *`.

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Assuming the question is just to print sorted from both BSTs. Then the easier way is,

1. Store inorder traversal of 2 BSTs in 2 seperate arrays.
2. Now the problem reduces to merging\printing elements from 2 sorted arrays, which we got from step one. This merging can be done in o(m) when m>n or o(n) when m

Complexity: o(m+n) Aux space: o(m+n) for the 2 arrays

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This blog post provides a solution to the problem with O(logn) space complexity. (Pay attention that the given approach does not modify input trees.)

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