modify binary search to find the next bigger item than the key

I want to modify the famous binary search algorithm to return the index of the next bigger item instead of the key being searched.

So we have 4 cases:

1. the key is smaller than all items, return 0.
2. the key is bigger than all items, return items.length.
3. the key is found at index x, return x+1.
4. the key isn't found, return the index of the next bigger one.

e.g:

``````data = { 1, 3, 5, 7, 9, 11 };
``````
• search for 0 returns 0.
• search for 11 or 12 returns 6.
• search for 5 or 6 returns 3.

``````while (low <= high) {
mid = (low + high) / 2;
if (data[mid] < val)
low = mid + 1;
else if (data[mid] > val)
high = mid - 1;
else {
break;
}
}
``````

Currently got it working by examining low and high values. Is there any interesting code to do so!

EDIT !!!

here is how I get it working:

``````    if (low <= high)
found = (low + high) / 2 + 1;
else if (low >= data.length)
found = data.length ;
else if (high < 0)
found = -1;
else
found = low;
``````

I am looking for a more elegant way!

EDIT II !!!

this code works if no duplicates. to handle the case of duplicates we need to modify the first if condition:

``````if (low <= high)
found = (low + high) / 2 + 1;
``````

to iterate until it finds a bigger element.

-
You're implementing the algorithm of `std::upper_bound`. – Mark Ransom Apr 25 '13 at 16:27
"search for 4 or 5 returns 3" wrong! Search for 4 should return 2, and for 5 return 3. – ElKamina Apr 25 '13 at 16:28
@ElKamina corrected search for 5or 6 return 3! – mmohab Apr 25 '13 at 16:35

WARNING - This is a bad answer that I now can't delete because it was accepted. The following code is as described below, but that's not what the question asks for - it looks like I didn't read the question properly. I can't delete this now because it's accepted.

The following code finds the first item with key greater than the target key...

``````while (upperbound > lowerbound)
{
testpos = lowerbound + ((upperbound-lowerbound) / 2);

if (item[testpos] > goal)
{
//  new best-so-far
upperbound = testpos;
}
else
{
lowerbound = testpos + 1;
}
}
``````

It's quoted from this answer, which tries to explain the one-comparison-per-iteration binary search and how to adapt it.

-
This doesn't match the OP's requirements at all. Searching for 1 returns 0, searching for 11 returns 4, etc. – Michaelangelo Feb 3 '15 at 22:23
@Michaelangelo - actually this code doesn't return anything at all, but point taken - it looks like I didn't read the question properly. Now I can't delete because it's accepted. I can't even downvote it because it's my answer. – Steve314 Feb 4 '15 at 0:31

Here is some C code that meet's the OP's requirements for searching:

• value < first item: return 0
• value is contained in the array: return index found+1
• value is not in the array but < first item and < last item: return next largest value's index
• value >= last item: return array size

It also demonstrates 4 different types of binary searching:

• Standard Binary Search
• LessThanEqual Binary Search
• LessThanEqual or Last Binary Search
• NextLargest Binary Search

(It assumes there are no duplicates in `data`)

``````#include <stdio.h>

int BinarySearch( int key, int data[], const int len )
{
int low  = 0;
int high = len-1;

while( high >= low )
{
int mid = low + ((high - low) / 2);

/**/ if (data[mid] < key) low  = mid + 1;
else if (data[mid] > key) high = mid - 1;
else return                      mid    ;
}
return -1; // KEY_NOT_FOUND
}

int LessThanEqualBinSearch( int key, int data[], const int len )
{
int min = 0;
int max = len-1;
// var max = data.length - 1; // Javascript, Java conversion

while( min <= max)
{
int mid = min + ((max - min) / 2);

/**/ if (data[mid] < key)  min  = mid + 1;
else if (data[mid] > key)  max  = mid - 1;
else   /*data[mid] = key)*/return mid    ;
}

if( max < 0 )
return 0;  // key < data[0]
else
if( min > (len-1))
return -1; // key >= data[len-1] // KEY_NOT_FOUND
else
return (min < max)
? min
: max + 1;
}

int LessThanEqualOrLastBinSearch( int key, int data[], const int len )
{
int min = 0;
int max = len-1;
// var max = data.length - 1; // Javascript, Java conversion

while( min <= max)
{
int mid = min + ((max - min) / 2);

/**/ if (data[mid] < key)  min  = mid + 1;
else if (data[mid] > key)  max  = mid - 1;
else   /*data[mid] = key)*/return mid    ;
}

if( max < 0 )
return 0;     // key < data[0]
else
if( min > (len-1))
return len-1; // key >= data[len-1]
else
return (min < max)
? min
: max + 1;
}

int NextLargestBinSearch( int key, int data[], const int len )
{
int low  = 0;
int high = len-1;

while( low <= high)
{
// To convert to Javascript:
// var mid = low + ((high - low) / 2) | 0;
int mid = low + ((high - low) / 2);

/**/ if (data[mid] < key) low  = mid + 1;
else if (data[mid] > key) high = mid - 1;
else return                      mid + 1;
}

if( high < 0 )
return 0;   // key < data[0]
else
if( low > (len-1))
return len; // key >= data[len-1]
else
return (low < high)
? low  + 1
: high + 1;
}

int main()
{
int items[] = { 1, 3, 5, 7, 9, 11 };
int LENGTH  = sizeof(items) / sizeof(items[0]);

for( int i = -1; i < 14; ++i )
printf( "[%2d]: == %2d   <= %2d   <| %d   > %d\n", i
, BinarySearch                ( i, items, LENGTH )
, LessThanEqualBinSearch      ( i, items, LENGTH )
, LessThanEqualOrLastBinSearch( i, items, LENGTH )
, NextLargestBinSearch        ( i, items, LENGTH )
);

return 0;
}
``````

Output:

``````[-1]: == -1   <=  0   <| 0   > 0
[ 0]: == -1   <=  0   <| 0   > 0
[ 1]: ==  0   <=  0   <| 0   > 1
[ 2]: == -1   <=  1   <| 1   > 1
[ 3]: ==  1   <=  1   <| 1   > 2
[ 4]: == -1   <=  2   <| 2   > 2
[ 5]: ==  2   <=  2   <| 2   > 3
[ 6]: == -1   <=  3   <| 3   > 3
[ 7]: ==  3   <=  3   <| 3   > 4
[ 8]: == -1   <=  4   <| 4   > 4
[ 9]: ==  4   <=  4   <| 4   > 5
[10]: == -1   <=  5   <| 5   > 5
[11]: ==  5   <=  5   <| 5   > 6
[12]: == -1   <= -1   <| 5   > 6
[13]: == -1   <= -1   <| 5   > 6
``````
• The `1st` column is the standard binary search
• The `2nd` column is the Less Than binary search
• The `3rd` column is the Less Than Or Last binary search
• The `4th` column is the Next Largest binary search
-

Here is what you want. It returns the next bigger element.

``````public int binarySearch(int[] arr, int key) {
int lo = 0;
int hi = arr.length - 1;int mid = 0;
while (lo <= hi) {
mid = (lo + hi) / 2;
if      (key < arr[mid]) hi = mid - 1;
else if (key > arr[mid]) lo = mid + 1;
else return mid;
}
return -Math.min(lo, hi)-2;
}

public int myBinarySearch(int[] arr, int key){
int x = binarySearch(arr, key);
if(x >= arr.length-1 || -x > arr.length){
//whatever you want to return
return Integer.MAX_VALUE;
}
else if(x >= 0)
return arr[x+1] ;
else
return arr[-x-1];
}
public static void main(String args[]) {
Triall tr = new Triall();
int arr[] = { 1, 3, 5, 7, 9, 11 };
for( int i = 0; i < 13; i++ ) {
int n = tr.myBinarySearch( arr,i );
System.out.println(i + " " + n );
}
}
``````
-
actually I want to implement my version of binary search instead of using Collections.binarySearch() – mmohab Apr 25 '13 at 16:38
@smttsp This only works if there are no repeated items in the array. If you have three items that are the same, and the binary search returns the first or second of these, then your approach will not return the next larger item. After the binary search, you have to scan the array upwards to look for a different value. – sfstewman Apr 25 '13 at 16:53
@sfstewman nice catch :) – mmohab Apr 25 '13 at 16:56
I see this doesn't work. At least helps you find out something :) – smttsp Apr 25 '13 at 16:58
I changed it and it is working – smttsp Apr 25 '13 at 17:05