# java codility Max-Counters

I have been trying to solve the below task:

You are given N counters, initially set to 0, and you have two possible operations on them:

``````    increase(X) − counter X is increased by 1,
max_counter − all counters are set to the maximum value of any counter.
``````

A non-empty zero-indexed array A of M integers is given. This array represents consecutive operations:

``````    if A[K] = X, such that 1 ≤ X ≤ N, then operation K is increase(X),
if A[K] = N + 1 then operation K is max_counter.
``````

For example, given integer N = 5 and array A such that:

``````A[0] = 3
A[1] = 4
A[2] = 4
A[3] = 6
A[4] = 1
A[5] = 4
A[6] = 4
``````

the values of the counters after each consecutive operation will be:

``````(0, 0, 1, 0, 0)
(0, 0, 1, 1, 0)
(0, 0, 1, 2, 0)
(2, 2, 2, 2, 2)
(3, 2, 2, 2, 2)
(3, 2, 2, 3, 2)
(3, 2, 2, 4, 2)
``````

The goal is to calculate the value of every counter after all operations.

``````struct Results {
int * C;
int L;
};
``````

Write a function:

``````struct Results solution(int N, int A[], int M);
``````

that, given an integer N and a non-empty zero-indexed array A consisting of M integers, returns a sequence of integers representing the values of the counters.

The sequence should be returned as:

``````    a structure Results (in C), or
a vector of integers (in C++), or
a record Results (in Pascal), or
an array of integers (in any other programming language).
``````

For example, given:

``````A[0] = 3
A[1] = 4
A[2] = 4
A[3] = 6
A[4] = 1
A[5] = 4
A[6] = 4
``````

the function should return [3, 2, 2, 4, 2], as explained above.

Assume that:

``````    N and M are integers within the range [1..100,000];
each element of array A is an integer within the range [1..N + 1].
``````

Complexity:

``````    expected worst-case time complexity is O(N+M);
expected worst-case space complexity is O(N), beyond input storage (not counting the storage required for input arguments).
``````

Elements of input arrays can be modified.

Here is my solution:

``````import java.util.Arrays;

class Solution {
public int[] solution(int N, int[] A) {

final int condition = N + 1;
int currentMax = 0;
int countersArray[] = new int[N];

for (int iii = 0; iii < A.length; iii++) {
int currentValue = A[iii];
if (currentValue == condition) {
Arrays.fill(countersArray, currentMax);
} else {
int position = currentValue - 1;
int localValue = countersArray[position] + 1;
countersArray[position] = localValue;

if (localValue > currentMax) {
currentMax = localValue;
}
}

}

return countersArray;
}
}
``````

Here is the code valuation: https://codility.com/demo/results/demo6AKE5C-EJQ/

Can you give me a hint what is wrong with this solution?

-

The problem comes with this piece of code:

``````for (int iii = 0; iii < A.length; iii++) {
...
if (currentValue == condition) {
Arrays.fill(countersArray, currentMax);
}
...
}
``````

Imagine that every element of the array `A` was initialized with the value `N+1`. Since the function call `Arrays.fill(countersArray, currentMax)` has a time complexity of `O(N)` then overall your algorithm will have a time complexity `O(M * N)`. A way to fix this, I think, instead of explicitly updating the whole array `A` when the `max_counter` operation is called you may keep the value of last update as a variable. When first operation (incrementation) is called you just see if the value you try to increment is larger than the `last_update`. If it is you just update the value with 1 otherwise you initialize it to `last_update + 1`. When the second operation is called you just update `last_update` to `current_max`. And finally, when you are finished and try to return the final values you again compare each value to `last_update`. If it is greater you just keep the value otherwise you return `last_update`

``````class Solution {
public int[] solution(int N, int[] A) {

final int condition = N + 1;
int currentMax = 0;
int lastUpdate = 0;
int countersArray[] = new int[N];

for (int iii = 0; iii < A.length; iii++) {
int currentValue = A[iii];
if (currentValue == condition) {
lastUpdate = currentMax
} else {
int position = currentValue - 1;
if (countersArray[position] < lastUpdate)
countersArray[position] = lastUpdate + 1;
else
countersArray[position]++;

if (countersArray[position] > currentMax) {
currentMax = countersArray[position];
}
}

}

for (int iii = 0; iii < N; iii++)
if (countersArray[iii] < lastUpdate)
countersArray[iii] = lastUpdate;

return countersArray;
}
}
``````
-
In theory this sounds right, but I haven't tried it to see if that gives 100 points –  Relequestual Dec 14 '13 at 9:59

The problem is that when you get lots of `max_counter` operations you get lots of calls to `Arrays.fill` which makes your solution slow.

You should keep a `currentMax` and a `currentMin`:

• When you get a `max_counter` you just set `currentMin = currentMax`.
• If you get another value, let's call it `i`:
• If the value at position `i - 1` is smaller or equal to `currentMin` you set it to `currentMin + 1`.
• Otherwise you increment it.

At the end just go through the counters array again and set everything less than `currentMin` to `currentMin`.

-

Another solution that I have developed and might be worth considering: http://codility.com/demo/results/demoM658NU-DYR/

-
While this link may answer the question, it is better to include the essential parts of the answer here and provide the link for reference. Link-only answers can become invalid if the linked page changes. –  Eat Å Peach Nov 16 '13 at 2:07
@moda, do you mind explaining your code? I don't seem to understand how it was able to accomplish the maxcounter mission. While I understand the code, the approach was just so good that I never would think of solving it this way. So, if you could explain abit of why you took that approach? –  helpdesk Mar 6 at 20:03

This is the 100% solution of this question.

``````// you can also use imports, for example:
// import java.math.*;
class Solution {
public int[] solution(int N, int[] A) {
int counter[] = new int[N];
int n = A.length;
int max=-1,current_min=0;

for(int i=0;i<n;i++){
if(A[i]>=1 && A[i]<= N){
if(counter[A[i] - 1] < current_min) counter[A[i] - 1] = current_min;
counter[A[i] - 1] = counter[A[i] - 1] + 1;
if(counter[A[i] - 1] > max) max = counter[A[i] - 1];
}
else if(A[i] == N+1){
current_min = max;
}
}
for(int i=0;i<N;i++){
if(counter[i] < current_min) counter[i] =  current_min;
}
return counter;
}
}
``````
-
``````  vector<int> solution(int N, vector<int> &A)
{
std::vector<int> counter(N, 0);
int max = 0;
int floor = 0;

for(std::vector<int>::iterator i = A.begin();i != A.end(); i++)
{
int index = *i-1;
if(*i<=N && *i >= 1)
{
if(counter[index] < floor)
counter[index] = floor;
counter[index] += 1;
max = std::max(counter[index], max);
}
else
{
floor = std::max(max, floor);
}
}
for(std::vector<int>::iterator i = counter.begin();i != counter.end(); i++)
{
if(*i < floor)
*i = floor;
}
return counter;
}
``````
-

Hera is my AC Java solution. The idea is the same as @Inwvr explained:

``````public int[] solution(int N, int[] A) {
int[] count = new int[N];
int max = 0;
int lastUpdate = 0;
for(int i = 0; i < A.length; i++){
if(A[i] <= N){
if(count[A[i]-1] < lastUpdate){
count[A[i]-1] = lastUpdate+1;
}
else{
count[A[i]-1]++;
}
max = Math.max(max, count[A[i]-1]);
}
else{
lastUpdate = max;
}
}
for(int i = 0; i < N; i++){
if(count[i] < lastUpdate)
count[i] = lastUpdate;
}
return count;
}
``````
-