# Optimize Algorithm Required- Arrays

We have an array A of integers of size N. Given another array B which contains indices, where `size of B <= N` and `0<=B[i]<=N-1`.

Now we have to remove all elements from array A at position `B[i]`.

So with deletion we mean we are also shifting elements in array A.

Can someone help me in reaching to `O(n)` solution for this problem? And possibly O(1) space.

The first solution that comes to my mind is, traversing the array B and deleting elements in A sequentially( including shifting) but it is `O(n^2)`.

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Are the elements of B sorted in some order? If you're also shifting A, the order of elements in B are important. – SubmittedDenied Jun 9 '11 at 15:42
Do you have any limitations of these numbers? I mean, can you use some special value to mark some element as "already deleted"? If so, this would be an easy one. – Kiril Kirov Jun 9 '11 at 15:42
@Kiril, Marking elements as already visited/deleted is not allowed :( – learner Jun 9 '11 at 15:45
@SubmittedDenied, The elements in B array need not be sorted. – learner Jun 9 '11 at 15:47
Well, O(1) space and marking not allowed.. And even more - B is not sorted.. I'm not sure if this is possible at all. – Kiril Kirov Jun 9 '11 at 15:49

Similar to iliaden's solution except you could do the removing of deleted elements in place.

``````int[] a =
int[] b =
int nullValue =
for(int i: b) a[i] = nullValue;
int j=0;
for(int i=0; i < a.length; i++) {
if(a[i] != nullValue)
a[j++] = a[i];
}
// to clear the rest of the array, if required.
for(;j<a.length;j++)
a[j] = nullValue;
``````

note: `a` won't be shorter, but it avoid creating any more space. 'j' will have the number of valid entries in `a`

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Great, O(n) time and O(1) space. Perfect. Thanks a lot :) – learner Jun 9 '11 at 16:06
I think this is about as good as it is possible to get, changing the size of an array is generally `O(n)` memory anyway (create new array, copy everything over). It might be worth going over the remaining elements `N-j` elements and writing nulls in there too. – SubmittedDenied Jun 9 '11 at 16:07
This solution depends on the contents of A having some sort of null value. This isn't typically the case. Without a null value, you have to maintain the information about which elements are deleted separately, in a bit vector of some sort. And the second loop above is simply a less efficient version of `std::remove_if`. – James Kanze Jun 10 '11 at 8:01
@James, The OP has posted that he believes O(1) memory allocation is possible, this implies that it should be done without allocating additional memory proportional to the size. In my experience a null value is always possible in business logic. I don't see how `std::remove_if` is more efficient than the second loop. (Now have I moved the second loop out ;) – Peter Lawrey Jun 10 '11 at 8:07
In my experience, null values aren't always possible; that's why Fallible classes (or `boost::optional`, or Maybe) were invented. But it depends on the application, and the sort of things he's storing in the array (which he didn't tell us). Without null values, I don't think there is a solution without additional memory; you have to store the additional information somewhere. As for `remove_if`, look at it; typically, it uses `std::find_if` to find where to start copying, which avoids some unnecessary self-assignments. – James Kanze Jun 10 '11 at 9:16

in O(n) space, you can do:

1. traverse array A deleting every element at b[i] (no shifting, O(n))

2. create a new array C, copy all the non-empty elements from A into C sequentially (also O(n))

3. return array C or copy it back onto a cleared array A (O(n)) . thus you get to do it in O(n) tim and O(n) space

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Thanks for reply. This will work but I am looking for something in O(1) for space and O(n) for time. – learner Jun 9 '11 at 15:48

No marking, `O(n)` time, but also `O(n)` space, in pseudo-code:

``````// create a boolean array indicating which elements are to be deleted
D = new boolean[N]
fill(D, false)
for (b in B) {
D[b] = true
}

// compact `A in place
src = 0
dest = 0
while (src < N) {
if (!D[src]) {
A[dest++] = A[src]
}
src++
}

new_N = dest
``````
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if you can assume b is sorted you can shift as you iterate (you can sort the b in O(n*log(n)) if not)

``````int[] b;
int[] a;
int first=0,bInd=0;
for(int i = 0;i<a.length;i++){
if(bInd>=b.length || b[bInd]!=i){
a[first]=a[i];
first++;
}else{
bInd++;
}
}
``````
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You can't sort B as the positions of items in A changes when you shift A. B might be `[0, 0]`, indicating that you need to remove the first two elements in A. – SubmittedDenied Jun 9 '11 at 16:03
@submitted I'm assuming here the element in B are exact indices from the array A BEFORE ANY DELETIONS so `b=[0,0]` would be either invalid or mean that only the first should be removed – ratchet freak Jun 9 '11 at 16:10
@submittedDenied, Sorting wont effect the real solution. The indexes in B are wrt initial Array. Shifting wont have any effect on Array B. – learner Jun 9 '11 at 16:13
@learner Sorting will allow you to do the deletions in a back to front order. So a deletion will not affect the indexes of any yet to delete object. – James Kanze Jun 10 '11 at 8:03

Two obvious solutions: sort `B` in reverse order before starting, so you always delete the highest index (and so never shift a deleted element), or iterate through `B` to create a bitmap of elements to delete (and then do those in the reverse order). The first requires an additional `O(lg n)` step beforehand, and the second additional space. But I'm not sure there are any better alternatives.

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The order of B matters, you can't sort it. Also, even if it were in ascending or descending order, you'd need to shift elements that are to the right of the deleted element (ie, that have a higher index) to the left. – SubmittedDenied Jun 9 '11 at 15:59
@SubmittedDenied Whenever you actually remove an element from an `std::vector` (unless it's the last), you have to shift other elements. But functions like `std::remove_if` don't actually remove elements; you remove a block of elements at the end once they've shifted the elements to be kept to the start. The reason for starting from the back is that you don't invalidate unprocessed indexes. If you can't sort `B`, then the only solution is to use the bit vector; after that, you can use `std::remove_if` and `erase`, or `copy_if`. – James Kanze Jun 10 '11 at 7:58