# Space-efficient algorithm for finding the largest balanced subarray?

given an array of 0s and 1s, find maximum subarray such that number of zeros and 1s are equal. This needs to be done in O(n) time and O(1) space.

I have an algo which does it in O(n) time and O(n) space. It uses a prefix sum array and exploits the fact that if the number of 0s and 1s are same then sumOfSubarray = lengthOfSubarray/2

``````#include<iostream>
#define M 15

using namespace std;

void getSum(int arr[],int prefixsum[],int size) {
int i;
prefixsum[0]=arr[0]=0;
prefixsum[1]=arr[1];
for (i=2;i<=size;i++) {
prefixsum[i]=prefixsum[i-1]+arr[i];
}
}

void find(int a[],int &start,int &end) {
while(start < end) {
int mid = (start +end )/2;
if((end-start+1) == 2 * (a[end] - a[start-1]))
break;
if((end-start+1) > 2 * (a[end] - a[start-1])) {
if(a[start]==0 && a[end]==1)
start++; else
end--;
} else {
if(a[start]==1 && a[end]==0)
start++; else
end--;
}
}
}

int main() {
int size,arr[M],ps[M],start=1,end,width;
;
cin>>size;
arr[0]=0;
end=size;
for (int i=1;i<=size;i++)
cin>>arr[i];
getSum(arr,ps,size);
find(ps,start,end);
if(start!=end)
cout<<(start-1)<<" "<<(end-1)<<endl; else cout<<"No soln\n";
return 0;
}
``````
-
I wonder whether it's easier to do this if you imagine the zeros have been replaced with minus one. That way the sum of the subarray is zero. –  Neil Sep 11 '11 at 21:16
Can we modify the original array? –  templatetypedef Sep 12 '11 at 9:11
that is an option to get O(1). but is there better way? –  vastutsav Sep 12 '11 at 14:08
Since this is a homework can we assume that there is a O(1) storage solution? –  Paul Rubel Sep 14 '11 at 21:36
I doubt this is possible in O(1) space. –  Tomas Sep 15 '11 at 11:45

Now my algorithm is O(n) time and O(Dn) space where Dn is the total imblance in the list.

This solution doesn't modify the list.

let D be the difference of 1s and 0s found in the list.

First, let's step linearily through the list and calculate D, just to see how it works:

I'm gonna use this list as an example : l=1100111100001110

``````Element   D
null      0
1         1
1         2   <-
0         1
0         0
1         1
1         2
1         3
1         4
0         3
0         2
0         1
0         0
1         1
1         2
1         3
0         2   <-
``````

Finding the longest balanced subarray is equivalent to finding 2 equal elements in D that are the more far appart. (in this example the 2 2s marked with arrows.)

The longest balanced subarray is between first occurence of element +1 and last occurence of element. (first arrow +1 and last arrow : 00111100001110)

Remark:

The longest subarray will always be between 2 elements of D that are between [0,Dn] where Dn is the last element of D. (Dn = 2 in the previous example) Dn is the total imbalance between 1s and 0s in the list. (or [Dn,0] if Dn is negative)

In this example it means that I don't need to "look" at 3s or 4s

Proof:

Let Dn > 0 .

If there is a subarray delimited by P (P > Dn). Since 0 < Dn < P, before reaching the first element of D which is equal to P we reach one element equal to Dn. Thus, since the last element of the list is equal to Dn, there is a longest subarray delimited by Dns than the one delimited by Ps.And therefore we don't need to look at Ps

P cannot be less than 0 for the same reasons

the proof is the same for Dn <0

Now let's work on D, D isn't random, the difference between 2 consecutive element is always 1 or -1. Ans there is an easy bijection between D and the initial list. Therefore I have 2 solutions for this problem:

• the first one is to keep track of first and last appearance of each element in D that are between 0 and Dn (cf remark).
• second is to transform the list into D, and then work on D.

## FIRST SOLUTION

For the time being I cannot find a better approach than the first one:

First calculate Dn (in O(n)) . Dn=2

Second instead of creating D, create a dictionnary where the keys are the value of D (between [0 and Dn]) and the value of each keys is a couple (a,b) where a is the first occurence of the key and b the last.

``````Element   D DICTIONNARY
null      0 {0:(0,0)}
1         1 {0:(0,0) 1:(1,1)}
1         2 {0:(0,0) 1:(1,1) 2:(2,2)}
0         1 {0:(0,0) 1:(1,3) 2:(2,2)}
0         0 {0:(0,4) 1:(1,3) 2:(2,2)}
1         1 {0:(0,4) 1:(1,5) 2:(2,2)}
1         2 {0:(0,4) 1:(1,5) 2:(2,6)}
1         3 { 0:(0,4) 1:(1,5) 2:(2,6)}
1         4 {0:(0,4) 1:(1,5) 2:(2,6)}
0         3{0:(0,4) 1:(1,5) 2:(2,6) }
0         2 {0:(0,4) 1:(1,5) 2:(2,9) }
0         1 {0:(0,4) 1:(1,10) 2:(2,9) }
0         0 {0:(0,11) 1:(1,10) 2:(2,9) }
1         1 {0:(0,11) 1:(1,12) 2:(2,9) }
1         2 {0:(0,11) 1:(1,12) 2:(2,13)}
1         3 {0:(0,11) 1:(1,12) 2:(2,13)}
0         2 {0:(0,11) 1:(1,12) 2:(2,15)}
``````

and you chose the element with the largest difference : 2:(2,15) and is l[3:15]=00111100001110 (with l=1100111100001110).

Time complexity :

2 passes, the first one to caclulate Dn, the second one to build the dictionnary. find the max in the dictionnary.

Total is O(n)

Space complexity:

the current element in D : O(1) the dictionnary O(Dn)

I don't take 3 and 4 in the dictionnary because of the remark

The complexity is O(n) time and O(Dn) space (in average case Dn << n).

I guess there is may be a better way than a dictionnary for this approach.

Any suggestion is welcome.

Hope it helps

## SECOND SOLUTION (JUST AN IDEA NOT THE REAL SOLUTION)

The second way to proceed would be to transform your list into D. (since it's easy to go back from D to the list it's ok). (O(n) time and O(1) space, since I transform the list in place, even though it might not be a "valid" O(1) )

Then from D you need to find the 2 equal element that are the more far appart.

it looks like finding the longest cycle in a linked list, A modification of Richard Brent algorithm might return the longest cycle but I don't know how to do it, and it would take O(n) time and O(1) space.

Once you find the longest cycle, go back to the first list and print it.

This algorithm would take O(n) time and O(1) space complexity.

-
if you need to transform the list then it is NOT O(1) space. –  Tomas Sep 15 '11 at 11:47
@Tomas T. why so? if I modify it in place (that's what i'm doing)? Anyway, my second solution is just a idea, because I don't have an algorithm to find the longest cycle in a linked list yet. For the time being only the first one works, in O(n) time and O(M) space where M << n and is the maximum imbalance in the list. –  Ricky Bobby Sep 15 '11 at 12:24
@Tomas T. and honestly I doubt this is possible in O(1) space too. –  Ricky Bobby Sep 15 '11 at 12:27
I think modifying the input is not allowed, i.e. transforming the input list is not O(1) space. –  Tomas Sep 15 '11 at 14:19
I think modifying the input is allowed, but just within the space of the input. And as you replace a 1 bit entry (or take whatever constant you want here, 8 bit for chars, doenst matter) with (what is the biggest possible number ..., right n) with n times log n the required space is O(n log n). –  flolo Sep 15 '11 at 14:31

Different approach but still O(n) time and memory. Start with Neil's suggestion, treat 0 as -1.

Notation: `A[0, …, N-1]` - your array of size `N`, `f(0)=0, f(x)=A[x-1]+f(x-1)` - a function

If you'd plot `f`, you'll see, that what you look for are points for which `f(m)=f(n), m=n-2k` where k-positive natural. More precisely, only for `x` such that `A[x]!=A[x+1]` (and the last element in an array) you must check whether `f(x)` already occurred. Unfortunately, now I see no improvement over having array `B[-N+1…N-1]` where such information would be stored.

To complete my thought: `B[x]=-1` initially, `B[x]=p` when `p = min k: f(k)=x` . And the algorithm is (double-check it, as I'm very tired):

``````fx = 0
B = new array[-N+1, …, N-1]
maxlen = 0
B[0]=0
for i=1…N-1 :
fx = fx + A[i-1]
if B[fx]==-1 :
B[fx]=i
else if ((i==N-1) or (A[i-1]!=A[i])) and (maxlen < i-B[fx]):
We found that A[B[fx], …, i] is best than what we found so far
maxlen = i-B[fx]
``````

Edit: Two bed-thoughts (= figured out while laying in bed :P ):

1) You could binary search the result by the length of subarray, which would give O(n log n) time and O(1) memory algorithm. Let's use function `g(x)=x - x mod 2` (because subarrays which sum to 0 are always of even length). Start by checking, if the whole array sums to 0. If yes -- we're done, otherwise continue. We now assume 0 as starting point (we know there's subarray of such length and "summing-to-zero property") and g(N-1) as ending point (we know there's no such subarray). Let's do

``````    a = 0
b = g(N-1)
while a<b :
c = g((a+b)/2)
check if there is such subarray in O(n) time
if yes:
a = c
if no:
b = c
return the result: a (length of maximum subarray)
``````

Checking for subarray with "summing-to-zero property" of some given length L is simple:

``````    a = 0
b = L
fa = fb = 0
for i=0…L-1:
fb = fb + A[i]
while (fa != fb) and (b<N) :
fa = fa + A[a]
fb = fb + A[b]
a = a + 1
b = b + 1
if b==N:
found, starts at a and stops at b
``````

2) …can you modify input array? If yes and if O(1) memory means exactly, that you use no additional space (except for constant number of elements), then just store your prefix table values in your input array. No more space used (except for some variables) :D

And again, double check my algorithms as I'm veeery tired and could've done off-by-one errors.

-

Like Neil, I find it useful to consider the alphabet {±1} instead of {0, 1}. Assume without loss of generality that there are at least as many +1s as -1s. The following algorithm, which uses O(sqrt(n log n)) bits and runs in time O(n), is due to "A.F."

Note: this solution does not cheat by assuming the input is modifiable and/or has wasted bits. As of this edit, this solution is the only one posted that is both O(n) time and o(n) space.

A easier version, which uses O(n) bits, streams the array of prefix sums and marks the first occurrence of each value. It then scans backward, considering for each height between 0 and sum(arr) the maximal subarray at that height. Some thought reveals that the optimum is among these (remember the assumption). In Python:

``````sum = 0
min_so_far = 0
max_so_far = 0
is_first = [True] * (1 + len(arr))
for i, x in enumerate(arr):
sum += x
if sum < min_so_far:
min_so_far = sum
elif sum > max_so_far:
max_so_far = sum
else:
is_first[1 + i] = False

sum_i = 0
i = 0
while sum_i != sum:
sum_i += arr[i]
i += 1
sum_j = sum
j = len(arr)
longest = j - i
for h in xrange(sum - 1, -1, -1):
while sum_i != h or not is_first[i]:
i -= 1
sum_i -= arr[i]
while sum_j != h:
j -= 1
sum_j -= arr[j]
longest = max(longest, j - i)
``````

The trick to get the space down comes from noticing that we're scanning `is_first` sequentially, albeit in reverse order relative to its construction. Since the loop variables fit in O(log n) bits, we'll compute, instead of `is_first`, a checkpoint of the loop variables after each O(√(n log n)) steps. This is O(n/√(n log n)) = O(√(n/log n)) checkpoints, for a total of O(√(n log n)) bits. By restarting the loop from a checkpoint, we compute on demand each O(√(n log n))-bit section of `is_first`.

(P.S.: it may or may not be my fault that the problem statement asks for O(1) space. I sincerely apologize if it was I who pulled a Fermat and suggested that I had a solution to a problem much harder than I thought it was.)

-

If indeed your algorithm is valid in all cases (see my comment to your question noting some corrections to it), notice that the prefix array is the only obstruction to your constant memory goal.

Examining the `find` function reveals that this array can be replaced with two integers, thereby eliminating the dependence on the length of the input and solving your problem. Consider the following:

• You only depend on two values in the prefix array in the `find` function. These are `a[start - 1]` and `a[end]`. Yes, `start` and `end` change, but does this merit the array?
• Look at the progression of your loop. At the end, `start` is incremented or `end` is decremented only by one.
• Considering the previous statement, if you were to replace the value of `a[start - 1]` by an integer, how would you update its value? Put another way, for each transition in the loop that changes the value of `start`, what could you do to update the integer accordingly to reflect the new value of `a[start - 1]`?
• Can this process can be repeated with `a[end]`?
• If, in fact, the values of `a[start - 1]` and `a[end]` can be reflected with two integers, doesn't the whole prefix array no longer serve a purpose? Can't it therefore be removed?

With no need for the prefix array and all storage dependencies on the length of the input removed, your algorithm will use a constant amount of memory to achieve its goal, thereby making it O(n) time and O(1) space.

I would prefer you solve this yourself based on the insights above, as this is homework. Nevertheless, I have included a solution below for reference:

``````#include <iostream>
using namespace std;

void find( int *data, int &start, int &end )
{
// reflects the prefix sum until start - 1
int sumStart = 0;

// reflects the prefix sum until end
int sumEnd = 0;
for( int i = start; i <= end; i++ )
sumEnd += data[i];

while( start < end )
{
int length = end - start + 1;
int sum = 2 * ( sumEnd - sumStart );

if( sum == length )
break;
else if( sum < length )
{
// sum needs to increase; get rid of the lower endpoint
if( data[ start ] == 0 && data[ end ] == 1 )
{
// sumStart must be updated to reflect the new prefix sum
sumStart += data[ start ];
start++;
}
else
{
// sumEnd must be updated to reflect the new prefix sum
sumEnd -= data[ end ];
end--;
}
}
else
{
// sum needs to decrease; get rid of the higher endpoint
if( data[ start ] == 1 && data[ end ] == 0 )
{
// sumStart must be updated to reflect the new prefix sum
sumStart += data[ start ];
start++;
}
else
{
// sumEnd must be updated to reflect the new prefix sum
sumEnd -= data[ end ];
end--;
}
}
}
}

int main() {
int length;
cin >> length;

// get the data
int data[length];
for( int i = 0; i < length; i++ )
cin >> data[i];

// solve and print the solution
int start = 0, end = length - 1;
find( data, start, end );

if( start == end )
puts( "No soln" );
else
printf( "%d %d\n", start, end );

return 0;
}
``````
-

Sum all elements in the array, then diff = (array.length - sum) will be the difference in number of 0s and 1s.

1. If diff is equal to array.length/2, then the maximum subarray = array.
2. If diff is less than array.length/2 then there are more 1s than 0s.
3. If diff is greater than array.length/2 then there are more 0s than 1s.

For cases 2 & 3, initialize two pointers, start & end pointing to beginning and end of array. If we have more 1s, then move the pointers inward (start++ or end--) based on whether array[start] = 1 or array[end] = 1, and update sum accordingly. At each step check if sum = (end - start) / 2. If this condition is true, then start and end represent the bounds of your maximum subarray.

Here we end up doing two passes of the array, once to calculate sum, and once which moving the pointers inward. And we are using constant space as we just need to store sum and two index values.

If anyone wants to knock up some pseudocode, you're more than welcome :)

-
with 0011111111100 how do you decide with pointer to move ? –  Ricky Bobby Sep 13 '11 at 14:37
It's more complicated than what Oceanic and Mark are suggesting. You could easily work out examples where it wont work. –  Nitin Garg Sep 13 '11 at 18:01
@Mark : and with 00011111111100 how do I chose right or left ? –  Ricky Bobby Sep 13 '11 at 19:37
@Ricky, sure, clearly I'm wrong. Mea culpa. –  Mark Elliot Sep 14 '11 at 0:15
yep, this isn't correct. need to think more... –  Oceanic Sep 14 '11 at 18:21

Here's an actionscript solution that looked like it was scaling O(n). Though it might be more like O(n log n). It definitely uses only O(1) memory.

Warning I haven't checked how complete it is. I could be missing some cases.

``````protected function findLongest(array:Array, start:int = 0, end:int = -1):int {
if (end < start) {
end = array.length-1;
}

var startDiff:int = 0;
var endDiff:int = 0;
var diff:int = 0;
var length:int = end-start;
for (var i:int = 0; i <= length; i++) {
if (array[i+start] == '1') {
startDiff++;
} else {
startDiff--;
}

if (array[end-i] == '1') {
endDiff++;
} else {
endDiff--;
}

//We can stop when there's no chance of equalizing anymore.
if (Math.abs(startDiff) > length - i) {
diff = endDiff;
start = end - i;
break;
} else if (Math.abs(endDiff) > length - i) {
diff = startDiff;
end = i+start;
break;
}
}

var bit:String = diff > 0 ? '1': '0';
var diffAdjustment:int = diff > 0 ? -1: 1;

//Strip off the bad vars off the ends.
while (diff != 0 && array[start] == bit) {
start++;
}

while(diff != 0 && array[end] == bit) {
end--;
}

//If we have equalized end. Otherwise recurse within the sub-array.
if (diff == 0)
return end-start+1;
else
return findLongest(array, start, end);

}
``````
-
Recursion needs stack - if the stack is not O(1) size, then you don't have O(1) space solution. –  Tomas Sep 15 '11 at 12:17

I would argue that it is impossible, that an algorithm with O(1) exists, in the following way. Assume you iterate ONCE over every bit. This requires a counter which needs the space of O(log n). Possibly one could argue that n itself is part of the problem instance, then you have as input length for a binary string of the length k: k + 2-log k. Regardless how you look over them you need an additional variable, on case you need an index into that array, that already makes it non O(1).

Usually you dont have this problem, because you have for an problem of the size n, an input of n numbers of the size log k, which adds up to nlog k. Here a variable of length log k is just O(1). But here our log k is just 1. So we can only introduce a help variable that has constant length (and I mean really constant, it must be limited regardless how big the n is).

Here one problem is the description of the problem comes visible. In computer theory you have to be very careful about your encoding. E.g. you can make NP problems polynomial if you switch to unary encoding (because then input size is exponential bigger than in a n-ary (n>1) encoding.

As for n the input has just the size 2-log n, one must be careful. When you speak in this case of O(n) - this is really an algorithm that is O(2^n) (This is no point we need to discuss about - because one can argue whether the n itself is part of the description or not).

-
While I understand what you're saying, if you assume that the machine is transdichotomous (as most machines are), then you can assume that each machine word can hold Omega(log n) bits. In that case, you can use O(1) machine words to hold the size of the problem. –  templatetypedef Sep 15 '11 at 19:46
@templatetypedef: I am not sure what you want to say with that. Its right you can use a RAM model that allows you to formulate the problem in O(1). But that says nothing.When you now want O(1) space, this is almost always fullfilled. I would say every of the already presented algorithm has the ability, that when you input a constant sized problem, the answer can be computed in constant (i.e. O(1)) space. Btw. if I think about it, its also not quite right that the input fits into O(1) machine words - e.g. n = 256 would imply 8 bit words, but you cant store 256 elements (bits) in one 8 bit word. –  flolo Sep 15 '11 at 21:08

This algorithm is O(n) time and O(1) space. It may modify the source array, but it restores all the information back. So it is not working with const arrays. If this puzzle has several solutions, this algorithm picks the solution nearest to the array beginning. Or it might be modified to provide all solutions.

Algorithm

Variables:

• `p1` - subarray start
• `p2` - subarray end
• `d` - difference of 1s and 0s in the subarray

1. Calculate `d`, if `d==0`, stop. If `d<0`, invert the array and after balanced subarray is found invert it back.
2. While `d > 0` advance `p2`: if the array element is 1, just decrement both `p2` and `d`. Otherwise `p2` should pass subarray of the form `11*0`, where `*` is some balanced subarray. To make backtracking possible, `11*0?` is changed to `0?*00` (where `?` is the value next to the subarray). Then `d` is decremented.
3. Store `p1` and `p2`.
4. Backtrack `p2`: if the array element is 1, just increment `p2`. Otherwise we found element, changed on step 2. Revert the changes and pass subarray of the form `11*0`.
5. Advance `p1`: if the array element is 1, just increment `p1`. Otherwise `p1` should pass subarray of the form `0*11`.
6. Store `p1` and `p2`, if `p2 - p1` improved.
7. If `p2` is at the end of the array, stop. Otherwise continue with step 4.

How does it work

Algorithm iterates through all possible positions of the balanced subarray in the input array. For each subarray position `p1` and `p2` are kept as far from each other as possible, providing locally longest subarray. Subarray with maximum length is chosen between all these subarrays.

To determine the next best position for `p1`, it is advanced to the first position where the balance between 1s and 0s is changed by one. (Step 5).

To determine the next best position for `p2`, it is advanced to the last position where the balance between 1s and 0s is changed by one. To make it possible, step 2 detects all such positions (starting from the array's end) and modifies the array in such a way, that it is possible to iterate through these positions with linear search. (Step 4).

While performing step 2, two possible conditions may be met. Simple one: when value '1' is found; pointer `p2` is just advanced to the next value, no special treatment needed. But when value '0' is found, balance is going in wrong direction, it is necessary to pass through several bits until correct balance is found. All these bits are of no interest to the algorithm, stopping `p2` there will give either a balanced subarray, which is too short, or a disbalanced subarray. As a result, `p2` should pass subarray of the form `11*0` (from right to left, `*` means any balanced subarray). There is no chance to go the same way in other direction. But it is possible to temporary use some bits from the pattern `11*0` to allow backtracking. If we change first '1' to '0', second '1' to the value next to the rightmost '0', and clear the value next to the rightmost '0': `11*0? -> 0?*00`, then we get the possibility to (first) notice the pattern on the way back, since it starts with '0', and (second) find the next good position for `p2`.

C++ code:

``````#include <cstddef>
#include <bitset>

static const size_t N = 270;

void findLargestBalanced(std::bitset<N>& a, size_t& p1s, size_t& p2s)
{
// Step 1
size_t p1 = 0;
size_t p2 = N;
int d = 2 * a.count() - N;
bool flip = false;

if (d == 0) {
p1s = 0;
p2s = N;
return;
}

if (d < 0) {
flip = true;
d = -d;
a.flip();
}

// Step 2
bool next = true;
while (d > 0) {
if (p2 < N) {
next = a[p2];
}

--d;
--p2;

if (a[p2] == false) {
if (p2+1 < N) {
a[p2+1] = false;
}

int dd = 2;
while (dd > 0) {
dd += (a[--p2]? -1: 1);
}

a[p2+1] = next;
a[p2] = false;
}
}

// Step 3
p2s = p2;
p1s = p1;

do {
// Step 4
if (a[p2] == false) {
a[p2++] = true;
bool nextToRestore = a[p2];
a[p2++] = true;

int dd = 2;
while (dd > 0 && p2 < N) {
dd += (a[p2++]? 1: -1);
}

if (dd == 0) {
a[--p2] = nextToRestore;
}
}
else {
++p2;
}

// Step 5
if (a[p1++] == false) {
int dd = 2;
while (dd > 0) {
dd += (a[p1++]? -1: 1);
}
}

// Step 6
if (p2 - p1 > p2s - p1s) {
p2s = p2;
p1s = p1;
}
} while (p2 < N);

if (flip) {
a.flip();
}
}
``````
-

linear time, constant space. Let me know if there is any bug I missed.
tested in python3.

``````def longestBalancedSubarray(A):
lo,hi = 0,len(A)-1
ones = sum(A);zeros = len(A) - ones
while lo < hi:
if ones == zeros: break
else:
if ones > zeros:
if A[lo] == 1: lo+=1; ones-=1
elif A[hi] == 1: hi+=1; ones-=1
else: lo+=1; zeros -=1
else:
if A[lo] == 0: lo+=1; zeros-=1
elif A[hi] == 0: hi+=1; zeros-=1
else: lo+=1; ones -=1
return(A[lo:hi+1])
``````
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