Suppose an array has been given and want to find element in that array , how can you search an element in that array using binary search and that given array is already sorted and size of the array is unknown. Linear search can be applied but I am trying to figure out for faster search than linear algorithm.

The title is not implied in the question body. Don't you know the array size? – leonbloy May 13 '13 at 0:40

sorry for that i have edited the question.. – MrA May 13 '13 at 0:49

"array of unknown size" = array with a special endofarray value? If so, you are practically force to read it in linear order... so I don't see how you'd implement other thing – leonbloy May 13 '13 at 0:52

By unknown you mean "arbitrary" known size, right? – acdcjunior May 13 '13 at 0:55

@leonbloy and @ acdcjunior Unknown means where the number of data is not known. – MrA May 13 '13 at 1:10
If you can test whether you have fallen out of the array range, then you could use a modified binary search (assume 1based array):
 lower = 1, upper = 1;
 while (A[upper] < element) upper *= 2;
 Normal binary search on (lower, upper).
Otherwise, there is no real way to do it: assume you find something somewhere that equals to the element you need, you cannot know if it already falls out of the array.
Assuming the array A is sorted (otherwise you can't do binary search), and the element you're searching for is k, you can find an index i such that k < A[i], and then do binary search from 1 to i (1indexed array). This is because once k < A[i], k is guaranteed to be found (or not found) in the range of sorted elements A[1..i].
To find the index i, you would start at i = 1, then double it if k > A[i]. This is like binary search except you're doubling the search range, so it will still have a O(log n) running time.
The algorithm is something like: Set i = 1, then repeat until k <= A[i]:
 if k > A[i] then let i = i*2
If k == A[i], then you're done, otherwise do binary search as usual on A[1..i].
The following should work (haven't tested), but should have the same bounds as binary search, O(log(n))
:
private bool hasValue(int[] array, int search, int start, int end)
{
int mid = (start+end)/2;
try
{
//Check to see if we can grab the value
int value = array[mid];
//If we are here, we are in the array
//Perform the binary search
if (value==search)
return true;
else if (end <= start)
return false;
else if (value>search)
return hasValue(array, search, start, mid);
else
return hasValue(array, search, mid, end*2);
}
catch(ArrayIndexOutOfBoundsException e)
{
//If we are here, then we were outside the array, so
//loop through the lower half
return hasValue(array, search, start, mid);
}
}
public bool hasValue(int[] array, int search)
{
// 0 is the start of the array (known)
// 1 is the endstart with any number that is greater than max(start, 1)
return hasValue(array, search, 0, 1);
}
Here's an example usage
// 2 is the value you are looking for
bool hasTwo = hasValue(array, 2);
Here's a start:
I might try something like this (in Javaesqe language). (Assumes an integer array)
int endOfArray = 10;
try {
while (true) {
int value = theArray[endOfArray*2];
if (value > requestedValue) // good enough
return doBinarySearch(theArray, 0, endOfArray, requestedValue);
else
endOfArray*=2;
}
}
catch (ArrayIndexOutOfBoundsException aioob) {
// we know that the end of the array is less than endOfArray*2 but > endOfArray
// do something clever here TBD. :)
}
Note added later: If the array is "Clike" and has 0s at the end, you'd also have to check for that. BTW, if anybody has a simple solve for the "something clever here" part, please feel free to edit the answer.
This one is working for me, This is O(log N + log N) i.e still O(log N)? This one is fitting the subarray also in an efficient manner. O(log N)
static int bSearch (int needle, int[] arr)
{
boolean done = false;
int i = 1;
int lower = 0;
int upper = 1;
int temp;
while (!done)
{
try{
if (needle == arr[upper])
return upper;
else if (needle > arr[upper])
{
temp = lower;
lower = upper;
upper = temp + (int) Math.pow(2,i);
i = i + 1;
}
else
{
done = true;
break; //found the upper bounds
}
}
catch (IndexOutOfBoundsException e)
{
upper = (upper lower) / 2;
i = 0;
}
}
if (done == true)
//do normal binary search with bounds lower and upper and length upperlower
else
return 1;
}
import java.util.Scanner;
public class SolutionB {
int size;
int arr[];
int M;
void inputData(){
Scanner in = new Scanner(System.in);
size = in.nextInt();
M = in.nextInt();
arr = new int[size + 1];
for(int i = 1; i <= size; i+=1){
arr[i] = in.nextInt();
}
}
void findMIndex(){
int start = 1;
int end = 2;
int j = 0;
int flag = 0, flag2=0;
for (int i = 2; flag == 0; ) {
try{
if (arr[end] > M) {
flag = 1;
}
else if (arr[end] == M) {
System.out.println(end);
return;
}
else if(start == end) {
flag=1;
flag2=1;
}
else {
i *= 2;
start = end;
end = i;
}
}
catch (ArrayIndexOutOfBoundsException e){
end = start + (end  start)/2;
}
}
if(flag2==0)
{
binary(start, end);
}
else
{
System.out.println("NOT_FOUND");
return;
}
}
void binary(int start, int end){
int index = 1;
while( start <= end ){
int mid = (start + ( end  1 )) / 2 + 1;
if( M == arr[mid] ){
index = mid;
break;
}
else if(M < arr[mid]){
end = mid  1;
}
else {
start = mid + 1;
}
}
if( index == 1 ){
System.out.println("NOT_FOUND");
}
else{
System.out.println(index);
}
}
public static void main(String[] as){
SolutionB obj = new SolutionB();
obj.inputData();
obj.findMIndex();
}
}
This solution is for a 1indexed array. It works for me.