# How to use recursion in creating a binary search algorithm

I have been using my time off university to practice Java through coding algorithms. One of the algorithms I coded was the binary search:

``````public class BinarySearch {

private static int list[] = {3, 6, 7, 8, 9, 10};

public static void main(String[] args) {
BinarySearch b = new BinarySearch();
b.binarySearch(list);

}

public void binarySearch(int[] args) {
System.out.println("Binary search.");

int upperBound = args.length;
int lowerBound = 1;
int midpoint = (upperBound + lowerBound) / 2;
int difference = upperBound - lowerBound;

int search = 7;

for (int i = 0; i < args.length; i++) {
if (search < args[midpoint - 1] && difference != 1) {
upperBound = midpoint - 1;
midpoint = upperBound / 2;
} else if (search > args[midpoint - 1] && difference != 1) {
lowerBound = midpoint + 1;
midpoint = (lowerBound + upperBound) / 2;

} else if (search == args[midpoint - 1]) {
midpoint = midpoint - 1;

System.out.println("We found " + search + " at position " + midpoint + " in the list.");
i = args.length;
} else {
System.out.println("We couldn't find " + search + " in the list.");
i = args.length;
}
}
}
}
``````

I really want to be able to write a much cleaner and efficient binary search algorithm, an alternative to what I've coded. I have seen examples of how recursion is used such as when doing factorial with numbers which I understand. However when coding something of this complexity I am confused on how to use it to my advantage. Therefore my question is how do I apply recursion when coding a binary search algorithm. And if you have any tips for me to perfect my recursion skills even if it has to be something that doesn't regard to binary search then please feel free to post.

• binary search is simple to write using a loop. using recursion is unnecessary.
– DwB
Commented Sep 25, 2013 at 18:45
• If you must use recursion, which I try to avoid because I see it as terrible (note that this is an opinion), the do not pass the array, instead pass the array, a left index and a right index; the indices identify the boundary of the search.
– DwB
Commented Sep 25, 2013 at 18:48
• @DwB Ah okay, though would there be any advantages of using recursion with binary search does it simplify the algorithm more?
– JP24
Commented Sep 25, 2013 at 18:49
• This method would be more useful if it returned the index, instead of printing it Commented Sep 25, 2013 at 18:49
• @DwB Okay I'm slightly confused you said to not pass the array then to instead pass the array and do you mean like list[n...list.length]? In this case n being an integer which is a particular index within the array?
– JP24
Commented Sep 25, 2013 at 18:52

If you really want to use recursion, this should do it.

``````public static int binarySearch(int[] a, int target) {
return binarySearch(a, 0, a.length-1, target);
}

public static int binarySearch(int[] a, int start, int end, int target) {
int middle = (start + end) / 2;
if(end < start) {
return -1;
}

if(target==a[middle]) {
return middle;
} else if(target<a[middle]) {
return binarySearch(a, start, middle - 1, target);
} else {
return binarySearch(a, middle + 1, end, target);
}
}
``````
• This is a great example for recursion, I basically debugged it and ran through how it works. I just managed to make a recursive bubblesort algorithm from scratch. This example has really helped me to get to know how it works. I tried looking over factorial but it didn't really help me that much because it was just too basic.
– JP24
Commented Oct 2, 2013 at 15:10
• @JP24 Glad I could help :). It's interesting that you mentioned the factorial example. That was the first example that I saw for recursion about 5 years ago. I dismissed it as interesting at BEST, mainly because of the overly simple example. The first time time I used recursion, I was writing a minesweeper game. Trying to get the loop to cascade the board when you click a square that is touching no bombs, I was having major problems. And I had a sudden epiphany that recursion would make the problem so easy!. Sorry about the rant, just thought I'd share my "aha!" moment Commented Oct 2, 2013 at 15:15
• what if the array is not sorted? the target < arr[middle] etc won't work here since the elements are unsorted Commented May 19, 2014 at 10:52
• @VasileSurdu if the array is not sorted then you can't do a binary search. The question is about binary search. Commented May 20, 2014 at 12:42
• @MrChasi Probabaly yes. There's not much reason for the outside world to call the second one Commented May 14, 2016 at 14:06

Here is an easier way of doing binary search:

``````public static int binarySearch(int intToSearch, int[] sortedArray) {

int lower = 0;
int upper = sortedArray.length - 1;

while (lower <= upper) {

int mid = lower + (upper - lower) / 2;

if(intToSearch < sortedArray[mid])

upper = mid - 1;

else if (intToSearch > sortedArray[mid])

lower = mid + 1;

else

return mid;
}

return -1; // Returns -1 if no match is found
}
``````
• Ah I guess I went all complicated, but then again Java is my first language and I only done programming in it for just about 9 months mostly picked up the skills during study at university and stamped down on the basics when amatuer through self-study and these algorithms are to increase my development though the experience has really helped and it does make me happy to see it work even though it has a lot going on. :D
– JP24
Commented Sep 25, 2013 at 19:11
• @JP24 That is why programming is so much fun only if you are having fun with it! :)
– Saj
Commented Sep 25, 2013 at 19:12
• Yep it is fun, I hated it to bits the first 3 weeks after that I excelled a lot I managed to have the basics fully understood in a matter of just over a month.
– JP24
Commented Sep 25, 2013 at 19:23

Following is a code sample extracted from here.

``````public class BinarySearch {

public boolean find(int[] sortedValues, int value) {
return search(sortedValues, value, 0, sortedValues.length - 1);
}

private boolean search(int[] sorted, int value, int leftIndex, int rightIndex) {

// 1. index check
if (leftIndex > rightIndex) {
return false;
}

// 2. middle index
int middle = (rightIndex + leftIndex) / 2;

// 3. recursive invoke
if (sorted[middle] > value) {
return search(sorted, value, leftIndex, middle - 1);
} else if (sorted[middle] < value) {
return search(sorted, value, middle + 1, rightIndex);
} else {
return true;
}
}
}
``````

You can find implementations of the below test cases against the above binary search implementation as well in the reference link.

``````1. shouldReturnFalseIfArrayIsEmpty()
2. shouldReturnFalseIfNotFoundInSortedOddArray()
3. shouldReturnFalseIfNotFoundInSortedEvenArray()
4. shouldReturnTrueIfFoundAsFirstInSortedArray()
5. shouldReturnTrueIfFoundAtEndInSortedArray()
6. shouldReturnTrueIfFoundInMiddleInSortedArray()
7. shouldReturnTrueIfFoundAnywhereInSortedArray()
8. shouldReturnFalseIfNotFoundInSortedArray()
``````

A possible example is :

``````// need extra "helper" method, feed in params
public int binarySearch(int[] a, int x) {
return binarySearch(a, x, 0, a.length - 1);
}

// need extra low and high parameters
private int binarySearch(int[ ] a, int x,
int low, int high) {
if (low > high) return -1;
int mid = (low + high)/2;
if (a[mid] == x) return mid;
else if (a[mid] < x)
return binarySearch(a, x, mid+1, high);
else // last possibility: a[mid] > x
return binarySearch(a, x, low, mid-1);
}
``````

Here you can check in C Binary Search, With and Without Recursion

Here is a algorithm which should get you going. Let your method signature be:

``````public boolean binarysearchRecursion(Array, begin_index,end_index, search_element)
``````
1. Check if your begin_index > end_index if YES then return `false`.
2. Calculate `mid_element` for your input array.
3. Check if your `search_element` is equal to this `mid_element`. if YES return `true`
4. If `mid_element` > `search_element` Call your method with for `range 0 - mid`
5. If `mid_element` < `search_element` Call your method with for range `mid+1 - Length_of_Array`

Also as @DwB said in his comment you are better using loop to get things done. Some problems are recursive in nature(Like binary tree problems). But this one is not one of them.

This is another way of doing recursion:

``````int[] n = {1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16};
@Test
public void testRecursiveSolution() {
Assert.assertEquals(0, recursiveBinarySearch(1,n));
Assert.assertEquals(15, recursiveBinarySearch(16,n));
Assert.assertEquals(14, recursiveBinarySearch(15,n));
Assert.assertEquals(13, recursiveBinarySearch(14,n));
Assert.assertEquals(12, recursiveBinarySearch(13,n));
Assert.assertEquals(11, recursiveBinarySearch(12,n));
Assert.assertEquals(10, recursiveBinarySearch(11,n));
Assert.assertEquals(9, recursiveBinarySearch(10,n));
Assert.assertEquals(-1, recursiveBinarySearch(100,n));
}
private int recursiveBinarySearch(int n, int[] array) {
if(array.length==1) {
if(array[0]==n) {
return 0;
} else {
return -1;
}
} else {
int mid = (array.length-1)/2;
if(array[mid]==n) {
return mid;
} else if(array[mid]>n) {
return recursiveBinarySearch(n, Arrays.copyOfRange(array, 0, mid));
} else {
int returnIndex = recursiveBinarySearch(n, Arrays.copyOfRange(array, mid+1, array.length));
if(returnIndex>=0) {
return returnIndex+mid+1;
} else {
return returnIndex;
}
}
}
}
``````
• I was wondering how to return the right index with a recursive solution that has an array of a single element as the base case. Thanks for posting a different recursive solution. Commented Aug 11, 2017 at 10:29

While it doesn't return the index, this at least returns the idea of 'yes' or 'no' that something is in the collection:

``````public static boolean recursive(int[] input, int valueToFind) {
if (input.length == 0) {
return false;
}

int mid = input.length / 2;
if (input[mid] == valueToFind) {
return true;
} else if (input[mid] > valueToFind) {
int[] smallerInput = Arrays.copyOfRange(input, 0, mid);
return recursive(smallerInput, valueToFind);
} else if (input[mid] < valueToFind) {
int[] smallerInput = Arrays.copyOfRange(input, mid+1, input.length);
return recursive(smallerInput, valueToFind);
}

return false;
}
``````

A recursion BinarySearch with break conditions in case you can not find the value you are looking for

``````public interface Searcher{
public int search(int [] data, int target, int low, int high);
}
``````

The Implementation

``````public class BinarySearch implements Searcher {

public int search(int[] data, int target, int low, int high) {
//The return variable
int retorno = -1;
if(low > high) return retorno;
int middle = (high + low)/2;
if(target == data[middle]){
retorno = data[middle];
}else if(target < data[middle] && (middle - 1 != high)){
//the (middle - 1 != high) avoids beeing locked inside a never ending recursion loop
retorno = search(data, target, low, middle - 1);
}else if(target > data[middle] && (middle - 1 != low)){
//the (middle - 1 != low) avoids beeing locked inside a never ending recursion loop
retorno = search(data, target, middle - 1, high);
}else if(middle - 1 == low || middle - 1 == high){
//Break condition if you can not find the desired balue
retorno =  -1;
}
return retorno;
}
}
``````