# How to merge two sorted arrays into a sorted array?

This was asked of me in an interview and this is the solution I provided:

``````public static int[] merge(int[] a, int[] b) {

int[] answer = new int[a.length + b.length];
int i = 0, j = 0, k = 0;
while (i < a.length && j < b.length)
{
if (a[i] < b[j])
{
i++;
}
else
{
j++;
}
k++;
}

while (i < a.length)
{
i++;
k++;
}

while (j < b.length)
{
j++;
k++;
}

}
``````

Is there a more efficient way to do this?

Edit: Corrected length methods.

-
Looks like a pretty good answer to me. This problem will have O(n) complexity at best, and your answer achieves that. Anything else will be microoptimization. – Drew Hall May 11 '11 at 1:19
Reminds me how lazy LINQ makes you (`return a.Union(b).OrderBy(i => i);`) Perhaps with a `.ToArray()` at the end. – Matt Mitchell May 11 '11 at 1:21
You did good! This is essentially a part of merge sort: merging two sorted streams (from tape or disk) into another sorted stream. – Vladimir Dyuzhev May 11 '11 at 2:18
Have you got the job? – Shai Apr 7 '13 at 5:30
Also you can use ternary operator: `while (i < a.length && j < b.length) answer[k++] = a[i] < b[j] ? a[i++] : b[j++];` Java Language Specification: Conditional Operator ? :. – Anton Dozortsev Jan 27 '14 at 16:14

A minor improvement, but after the main loop, you could use `System.arraycopy` to copy the tail of either input array when you get to the end of the other. That won't change the `O(n)` performance characteristics of your solution, though.

-
``````public static int[] merge(int[] a, int[] b) {

int[] answer = new int[a.length + b.length];
int i = 0, j = 0, k = 0;

while (i < a.length && j < b.length)
{
if (a[i] < b[j])

else
}

while (i < a.length)

while (j < b.length)

}
``````

Is a little bit more compact but exactly the same!

-
To the person who said this caused an index out of bounds exception what inputs are you using? It works in all cases for me. – Mike Saull Mar 25 '13 at 4:35

I'm surprised no one has mentioned this much more cool, efficient and compact implementation:

``````public static int[] merge(int[] a, int[] b) {
int[] answer = new int[a.length + b.length]
int i = a.length - 1, j = b.length - 1, k = answer.length;

while (k > 0)
(j < 0 || (i >= 0 && a[i] >= b[j])) ? a[i--] : b[j--];
}
``````

Points of Interests

1. Notice that it does same or less number of operations as any other O(n) algorithm but in literally single statement in a single while loop!
2. If two arrays are of approximately same size then constant for O(n) is same. However if arrays are really imbalanced then versions with `System.arraycopy` would win because internally it can do this with single x86 assembly instruction.
3. Notice `a[i] >= b[j]` instead of `a[i] > b[j]`. This guarantees "stability" that is defined as when elements of a and b are equal, we want elements from a before b.
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This is a really really nice approach. I had trouble getting good benchmarks on my Merge sort algorithms in Swift lang. Converting this gave me what I needed, thanks very much – Chackle Jul 10 '15 at 15:54
What is the point of (j < 0) in the while loop? Btw, +1, This is really cool! Thanks for sharing. – Hengameh Jul 13 '15 at 3:55
Nice. I hope this answer will make it to the top. – Dimitar Tsonev Sep 13 '15 at 12:35

Any improvements that could be made would be micro-optimizations, the overall algorithm is correct.

-
If a is large and b is small then this algorithm is wrong. – jack Mar 20 '13 at 13:35
It is not wrong but not efficient. – jack Mar 20 '13 at 13:44
@jack how can you do it faster than O(n) when you are producing an array of n items? – Will Jun 10 '14 at 9:07

Here is updated function. It removes duplicates, hopefully someone will find this usable:

``````public static long[] merge2SortedAndRemoveDublicates(long[] a, long[] b) {
long[] answer = new long[a.length + b.length];
int i = 0, j = 0, k = 0;
long tmp;
while (i < a.length && j < b.length) {
tmp = a[i] < b[j] ? a[i++] : b[j++];
for ( ; i < a.length && a[i] == tmp; i++);
for ( ; j < b.length && b[j] == tmp; j++);
}
while (i < a.length) {
tmp = a[i++];
for ( ; i < a.length && a[i] == tmp; i++);
}
while (j < b.length) {
tmp = b[j++];
for ( ; j < b.length && b[j] == tmp; j++);
}
}
``````
-
+1, Thanks for sharing. One question: why did you select the type of array and type of variable 'temp', long? – Hengameh Jul 13 '15 at 3:49

This solution also very similar to other posts except that it uses System.arrayCopy to copy the remaining array elements.

``````private static int[] sortedArrayMerge(int a[], int b[]) {
int result[] = new int[a.length +b.length];
int i =0; int j = 0;int k = 0;
while(i<a.length && j <b.length) {
if(a[i]<b[j]) {
result[k++] = a[i];
i++;
} else {
result[k++] = b[j];
j++;
}
}
System.arraycopy(a, i, result, k, (a.length -i));
System.arraycopy(b, j, result, k, (b.length -j));
return result;
}
``````
-

It can be done in 4 statements as below

`````` int a[] = {10, 20, 30};
int b[]= {9, 14, 11};
int res[]=new int[a.legth+b.length];
System.arraycopy(a,0, res, 0, a.length);
System.arraycopy(b,0,res,a.length, b.length);
Array.sort(res)
``````

-
I do not understand why this answer got negative votes. It is true that it is not efficient. But sometimes all you need is to get the job done as soon as possible. If you are dealing with very small arrays, say less than 100 elements, I would prefer to use the above code rather than writing a lengthy code that won't make any important performance improvements. So, thanks Sudhir for providing this easy solution and SANN3 for editing it. – Ahmedov Apr 14 '14 at 6:02
The unwritten premise is that a `sort` function can't use itself as a method of sorting. That would be infinite regression instead of recursion. Also the other premise is that merge_array is the function that implements sort. Thus this answer is unusable in the most likely context. – Aki Suihkonen Jul 9 '15 at 7:42
The question asked didn't mention that required code was for only small array. So this answer would be misleading unless it clearly stated its limitation. Also look at my answer below. It takes same number of lines to write efficient code that works for any array size :) – ShitalShah Jul 9 '15 at 7:49

I had to write it in javascript, here it is:

``````function merge(a, b) {
var result = [];
var ai = 0;
var bi = 0;
while (true) {
if ( ai < a.length && bi < b.length) {
if (a[ai] < b[bi]) {
result.push(a[ai]);
ai++;
} else if (a[ai] > b[bi]) {
result.push(b[bi]);
bi++;
} else {
result.push(a[ai]);
result.push(b[bi]);
ai++;
bi++;
}
} else if (ai < a.length) {
result.push.apply(result, a.slice(ai, a.length));
break;
} else if (bi < b.length) {
result.push.apply(result, b.slice(bi, b.length));
break;
} else {
break;
}
}
return result;
}
``````
-

Here's a shortened form written in javascript:

``````function sort( a1, a2 ) {

var i = 0
, j = 0
, l1 = a1.length
, l2 = a2.length
, a = [];

while( i < l1 && j < l2 ) {

a1[i] < a2[j] ? (a.push(a1[i]), i++) : (a.push( a2[j]), j++);
}

i < l1 && ( a = a.concat( a1.splice(i) ));
j < l2 && ( a = a.concat( a2.splice(j) ));

return a;
``````

}

-
``````    public class Merge {

// stably merge a[lo .. mid] with a[mid+1 .. hi] using aux[lo .. hi]
public static void merge(Comparable[] a, Comparable[] aux, int lo, int mid, int hi) {

// precondition: a[lo .. mid] and a[mid+1 .. hi] are sorted subarrays
assert isSorted(a, lo, mid);
assert isSorted(a, mid+1, hi);

// copy to aux[]
for (int k = lo; k <= hi; k++) {
aux[k] = a[k];
}

// merge back to a[]
int i = lo, j = mid+1;
for (int k = lo; k <= hi; k++) {
if      (i > mid)              a[k] = aux[j++];
else if (j > hi)               a[k] = aux[i++];
else if (less(aux[j], aux[i])) a[k] = aux[j++];
else                           a[k] = aux[i++];
}

// postcondition: a[lo .. hi] is sorted
assert isSorted(a, lo, hi);
}

// mergesort a[lo..hi] using auxiliary array aux[lo..hi]
private static void sort(Comparable[] a, Comparable[] aux, int lo, int hi) {
if (hi <= lo) return;
int mid = lo + (hi - lo) / 2;
sort(a, aux, lo, mid);
sort(a, aux, mid + 1, hi);
merge(a, aux, lo, mid, hi);
}

public static void sort(Comparable[] a) {
Comparable[] aux = new Comparable[a.length];
sort(a, aux, 0, a.length-1);
assert isSorted(a);
}

/***********************************************************************
*  Helper sorting functions
***********************************************************************/

// is v < w ?
private static boolean less(Comparable v, Comparable w) {
return (v.compareTo(w) < 0);
}

// exchange a[i] and a[j]
private static void exch(Object[] a, int i, int j) {
Object swap = a[i];
a[i] = a[j];
a[j] = swap;
}

/***********************************************************************
*  Check if array is sorted - useful for debugging
***********************************************************************/
private static boolean isSorted(Comparable[] a) {
return isSorted(a, 0, a.length - 1);
}

private static boolean isSorted(Comparable[] a, int lo, int hi) {
for (int i = lo + 1; i <= hi; i++)
if (less(a[i], a[i-1])) return false;
return true;
}

/***********************************************************************
*  Index mergesort
***********************************************************************/
// stably merge a[lo .. mid] with a[mid+1 .. hi] using aux[lo .. hi]
private static void merge(Comparable[] a, int[] index, int[] aux, int lo, int mid, int hi) {

// copy to aux[]
for (int k = lo; k <= hi; k++) {
aux[k] = index[k];
}

// merge back to a[]
int i = lo, j = mid+1;
for (int k = lo; k <= hi; k++) {
if      (i > mid)                    index[k] = aux[j++];
else if (j > hi)                     index[k] = aux[i++];
else if (less(a[aux[j]], a[aux[i]])) index[k] = aux[j++];
else                                 index[k] = aux[i++];
}
}

// return a permutation that gives the elements in a[] in ascending order
// do not change the original array a[]
public static int[] indexSort(Comparable[] a) {
int N = a.length;
int[] index = new int[N];
for (int i = 0; i < N; i++)
index[i] = i;

int[] aux = new int[N];
sort(a, index, aux, 0, N-1);
return index;
}

// mergesort a[lo..hi] using auxiliary array aux[lo..hi]
private static void sort(Comparable[] a, int[] index, int[] aux, int lo, int hi) {
if (hi <= lo) return;
int mid = lo + (hi - lo) / 2;
sort(a, index, aux, lo, mid);
sort(a, index, aux, mid + 1, hi);
merge(a, index, aux, lo, mid, hi);
}

// print array to standard output
private static void show(Comparable[] a) {
for (int i = 0; i < a.length; i++) {
StdOut.println(a[i]);
}
}

// Read strings from standard input, sort them, and print.
public static void main(String[] args) {
Merge.sort(a);
show(a);
}
}
``````
-

I think introducing the skip list for the larger sorted array can reduce the number of comparisons and can speed up the process of copying into the third array. This can be good if the array is too huge.

-
``````public int[] merge(int[] a, int[] b) {
int[] result = new int[a.length + b.length];
int aIndex, bIndex = 0;

for (int i = 0; i < result.length; i++) {
if (aIndex < a.length && bIndex < b.length) {
if (a[aIndex] < b[bIndex]) {
result[i] = a[aIndex];
aIndex++;
} else {
result[i] = b[bIndex];
bIndex++;
}
} else if (aIndex < a.length) {
result[i] = a[aIndex];
aIndex++;
} else {
result[i] = b[bIndex];
bIndex++;
}
}

return result;
}
``````
-
Some explanation would be nice. :) – gsamaras Jun 12 '14 at 23:32
``````public static int[] merge(int[] a, int[] b) {
int[] mergedArray = new int[(a.length + b.length)];
int i = 0, j = 0;
int mergedArrayIndex = 0;
for (; i < a.length || j < b.length;) {
if (i < a.length && j < b.length) {
if (a[i] < b[j]) {
mergedArray[mergedArrayIndex] = a[i];
i++;
} else {
mergedArray[mergedArrayIndex] = b[j];
j++;
}
} else if (i < a.length) {
mergedArray[mergedArrayIndex] = a[i];
i++;
} else if (j < b.length) {
mergedArray[mergedArrayIndex] = b[j];
j++;
}
mergedArrayIndex++;
}
return mergedArray;
}
``````
-
``````//How to merge two sorted arrays into a sorted array without duplicates?
//simple C Coding
#include <stdio.h>
#include <stdlib.h>
#include <string.h>

main()
{
int InputArray1[] ={1,4,5,7,8,9,12,13,14,17,40};
int InputArray2[] ={4,5,11,14,15,17,18,19,112,122,122,122,122};
int n=10;
int OutputArray[30];
int i=0,j=0,k=0;
//k=OutputArray
while(i<11 && j<13)
{
if(InputArray1[i]<InputArray2[j])
{
if (k == 0 || InputArray1[i]!= OutputArray[k-1])
{
OutputArray[k++] = InputArray1[i];
}
i=i+1;
}
else if(InputArray1[i]>InputArray2[j])
{
if (k == 0 || InputArray2[j]!= OutputArray[k-1])
{
OutputArray[k++] = InputArray2[j];
}
j=j+1;
}
else
{
if (k == 0 || InputArray1[i]!= OutputArray[k-1])
{
OutputArray[k++] = InputArray1[i];
}
i=i+1;
j=j+1;
}
};
while(i<11)
{
if(InputArray1[i]!= OutputArray[k-1])
OutputArray[k++] = InputArray1[i++];
else
i++;
}
while(j<13)
{
if(InputArray2[j]!= OutputArray[k-1])
OutputArray[k++] = InputArray2[j++];
else
j++;
}
for(i=0; i<k; i++)
{
printf("sorted data:%d\n",OutputArray[i]);
};
}
``````
-

Since the question doesn't assume any specific language. Here is the solution in Python. Assuming the arrays are already sorted.

Approach 1 - using numpy arrays: import numpy

``````arr1 = numpy.asarray([ 1,  2,  3,  4,  5,  6,  7,  8,  9, 11, 14, 15, 55])
arr2 = numpy.asarray([11, 32, 43, 45, 66, 76, 88])

array = numpy.concatenate((arr1,arr2), axis=0)
array.sort()
``````

Approach 2 - Using list, assuming lists are sorted.

``````list_new = list1.extend(list2)
list_new.sort()
``````
-
``````public static int[] merge(int[] listA, int[] listB) {
int[] mergedList = new int[ listA.length + listB.length];
int i = 0; // Counter for listA
int j = 0; // Counter for listB
int k = 0; // Counter for mergedList
while (true) {
if (i >= listA.length && j >= listB.length) {
break;
}
if (i < listA.length && j < listB.length) { // If both counters are valid.
if (listA[i] <= listB[j]) {
mergedList[k] = listA[i];
k++;
i++;
} else {
mergedList[k] = listB[j];
k++;
j++;
}
} else if (i < listA.length && j >= listB.length) { // If only A's counter is valid.
mergedList[k] = listA[i];
k++;
i++;
} else if (i <= listA.length && j < listB.length) { // If only B's counter is valid
mergedList[k] = listB[j];
k++;
j++;
}
}
return mergedList;
}
``````
-

Apache collections supports collate method since version 4; you can do this using the `collate` method in:

``````org.apache.commons.collections4.CollectionUtils
``````

``````collate(Iterable<? extends O> a, Iterable<? extends O> b, Comparator<? super O> c)
``````

Merges two sorted Collections, `a` and `b`, into a single, sorted List such that the ordering of the elements according to Comparator c is retained.

Do not re-invent the wheel! Document reference: http://commons.apache.org/proper/commons-collections/apidocs/org/apache/commons/collections4/CollectionUtils.html

-
``````var arrCombo = function(arr1, arr2){
return arr1.concat(arr2).sort(function(x, y) {
return x - y;
});
};
``````
-
This answer does not apply to the Java programming language, though it would be a good answer for javascript. – gknicker Feb 9 '15 at 6:20
This was part a job interview. In these cases, you're not really expected to write "normal" code like above. They're looking for "efficient" code and a demonstration that you understand the algorithms involved. – d11wtq Sep 25 '15 at 5:33

My favorite programming language is JavaScript

``````function mergeSortedArrays(a, b){
var result = [];

var sI = 0;
var lI = 0;
var smallArr;
var largeArr;
var temp;

if(typeof b[0] === 'undefined' || a[0]<b[0]){
smallArr = a;
largeArr = b;
} else{
smallArr = b;
largeArr = a;
}

while(typeof smallArr[sI] !== 'undefined'){
result.push(smallArr[sI]);
sI++;

if(smallArr[sI]>largeArr[lI] || typeof smallArr[sI] === 'undefined'){
temp = smallArr;
smallArr = largeArr;
largeArr = temp;
temp = sI;
sI = lI;
lI = temp;
}
}
return result;
}
``````
-

Algorithm could be enhanced in many ways. For instance, it is reasonable to check, if `a[m-1]<b[0]` or `b[n-1]<a[0]`. In any of those cases, there is no need to do more comparisons. Algorithm could just copy source arrays in the resulting one in the right order.

More complicated enhancements may include searching for interleaving parts and run merge algorithm for them only. It could save up much time, when sizes of merged arrays differ in scores of times.

-

This problem is related to the mergesort algorithm, in which two sorted sub-arrays are combined into a single sorted sub-array. The CLRS book gives an example of the algorithm and cleans up the need for checking if the end has been reached by adding a sentinel value (something that compares and "greater than any other value") to the end of each array.

I wrote this in Python, but it should translate nicely to Java too:

``````def func(a, b):
class sentinel(object):
def __lt__(*_):
return False

ax, bx, c = a[:] + [sentinel()], b[:] + [sentinel()], []
i, j = 0, 0

for k in range(len(a) + len(b)):
if ax[i] < bx[j]:
c.append(ax[i])
i += 1
else:
c.append(bx[j])
j += 1

return c
``````
-

Maybe use System.arraycopy

``````public static byte[] merge(byte[] first, byte[] second){
int len = first.length + second.length;
byte[] full = new byte[len];
System.arraycopy(first, 0, full, 0, first.length);
System.arraycopy(second, 0, full, first.length, second.length);
return full;
}
``````
-
``````public static void main(String[] args) {
int[] arr1 = {2,4,6,8,10,999};
int[] arr2 = {1,3,5,9,100,1001};

int[] arr3 = new int[arr1.length + arr2.length];

int temp = 0;

for (int i = 0; i < (arr3.length); i++) {
if(temp == arr2.length){
arr3[i] = arr1[i-temp];
}
else if (((i-temp)<(arr1.length)) && (arr1[i-temp] < arr2[temp])){
arr3[i] = arr1[i-temp];
}
else{
arr3[i] = arr2[temp];
temp++;
}
}

for (int i : arr3) {
System.out.print(i + ", ");
}
}
``````

Output is :

1, 2, 3, 4, 5, 6, 8, 9, 10, 100, 999, 1001,

-
``````import java.util.Arrays;

public class MergeTwoArrays {

static int[] arr1=new int[]{1,3,4,5,7,7,9,11,13,15,17,19};
static int[] arr2=new int[]{2,4,6,8,10,12,14,14,16,18,20,22};

public static void main(String[] args){
int FirstArrayLocation =0 ;
int SecondArrayLocation=0;
int[] mergeArr=new int[arr1.length + arr2.length];

for ( int i=0; i<= arr1.length + arr2.length; i++){
if (( FirstArrayLocation < arr1.length ) && (SecondArrayLocation < arr2.length)){
if ( arr1[FirstArrayLocation] <= arr2[SecondArrayLocation]){
mergeArr[i]=arr1[FirstArrayLocation];
FirstArrayLocation++;
}else{
mergeArr[i]=arr2[SecondArrayLocation];
SecondArrayLocation++;
}
}
else if(SecondArrayLocation < arr2.length){
mergeArr[i]=arr2[SecondArrayLocation];
SecondArrayLocation++;
}else if ( FirstArrayLocation < arr1.length ){
mergeArr[i]=arr1[FirstArrayLocation];
FirstArrayLocation++;
}
}
}
}
``````
-

## protected by Community♦Jun 30 '14 at 12:40

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