# Max double slice sum

Recently, I tried to solve the Max Double Slice Sum problem in codility which is a variant of max slice problem. My Solution was to look for a slice that has maximum value when its minimum value is taken out. So I implemented max slice, but on the current slice took out the minimum number.

My score was 61 of 100 as it failed during some of the tests, mainly the tests on array including both negative and position numbers.

Could you help me to figure out why the code failed or if there is a better solution for the problem?

The problem is as follows:

``````A non-empty zero-indexed array A consisting of N integers is given.
A triplet (X, Y, Z), such that 0 ≤ X < Y < Z < N, is called a double slice.
The sum of double slice (X, Y, Z) is the total of A[X + 1] + A[X + 2] + ... + A[Y − 1]+ A[Y + 1] + A[Y + 2] + ... + A[Z − 1].
For example, array A such that:
A[0] = 3
A[1] = 2
A[2] = 6
A[3] = -1
A[4] = 4
A[5] = 5
A[6] = -1
A[7] = 2
contains the following example double slices:
double slice (0, 3, 6), sum is 2 + 6 + 4 + 5 = 17,
double slice (0, 3, 7), sum is 2 + 6 + 4 + 5 − 1 = 16,
double slice (3, 4, 5), sum is 0.
The goal is to find the maximal sum of any double slice.
Write a function:
class Solution { public int solution(int[] A); }
that, given a non-empty zero-indexed array A consisting of N integers, returns the maximal sum of any double slice.
For example, given:
A[0] = 3
A[1] = 2
A[2] = 6
A[3] = -1
A[4] = 4
A[5] = 5
A[6] = -1
A[7] = 2
the function should return 17, because no double slice of array A has a sum of greater than 17.
Assume that:
N is an integer within the range [3..100,000];
each element of array A is an integer within the range [−10,000..10,000].
Complexity:
expected worst-case time complexity is O(N);
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.
``````

And my code is as follows:

``````public class Solution {
public int solution(int[] A) {
int currentSliceTotal=0;
Integer currentMin=null, SliceTotalBeforeMin =0;
int maxSliceTotal= Integer.MIN_VALUE;
for(int i= 1; i<A.length-1; i++){
if( currentMin==null || A[i] < currentMin ){
if(currentMin!=null ){
if(SliceTotalBeforeMin+currentMin <0){
currentSliceTotal-=SliceTotalBeforeMin;
} else {
currentSliceTotal += currentMin;
}
}
currentMin = A[i];
SliceTotalBeforeMin  =currentSliceTotal;

if( SliceTotalBeforeMin<0){
SliceTotalBeforeMin = 0;
currentMin = null;
currentSliceTotal = 0;
}
} else {
currentSliceTotal+= A[i];
}

maxSliceTotal = Math.max(maxSliceTotal, currentSliceTotal);
}

return maxSliceTotal;
}
}
``````

If I have understood the problem correctly, you want to calculate the maximum sum subarray with one element missing.

Your algorithm shall not work for the following case:

`````` 1 1 0 10 -100 10 0
``````

In the above case, your algorithm shall identify `1, 1, 0, 10` as the maximum sum sub array and leave out `0` to give `12` as the output. However, you can have `1, 1, 0, 10, -100, 10` as the answer after leaving out `-100`.

You can use a modified form of Kadane's algorithm that calculates the MAX Sum subarray ending at each index.

1. For each index, calculate the `max_sum_ending_at[i]` value by using Kadane's algorithm in forward direction.
2. For each index, calculate the `max_sum_starting_from[i]` value by using Kadane's algorithm in reverse direction.
3. Iterate these arrays simultaneously and choose the 'Y' that has the maximum value of

max_sum_ending_at[Y-1] + max_sum_starting_from[Y+1]

• Thank you Abhishek. That is an elegant solution for the problem. Dec 18, 2013 at 15:13
• Brilliant solution, Abhishek. Searching for a "Y" value by finding the index that maximizes the sum of the max sequences to its left and right. Dec 18, 2013 at 16:27
• Ok.. for { 3, 2, 6, -1, -1, 4, 5, -1, 2 } this will return 16 not 17... is it ok? Where it is said in the task setting that the distance between slices should be 1?? Ok... sorry I see now (0, 3, 6) means 0-3 3-6.. hmm such a speculative task. Mar 29, 2015 at 20:29
• @southerton the problem statement does not specify that the distance between slices be 1. Apr 8, 2019 at 13:54
• It does. See "A[Y − 1] + A[Y + 1]" part. Oct 1, 2020 at 17:13

Hello this implementacion has 100 score

``````int i,n ;

n = A.size();

if (3==n) return 0;

vector<int>  max_sum_end(n,0);
vector<int>  max_sum_start(n,0);

for (i=1; i< (n-1); i++) // i=0 and i=n-1 are not used because x=0,z=n-1
{
max_sum_end[i]   = max ( 0 , max_sum_end[i-1] + A[i]  );
}

for (i=n-2; i > 0; i--) // i=0 and i=n-1 are not used because x=0,z=n-1
{
max_sum_start[i]   = max ( 0 , max_sum_start[i+1] + A[i]  );
}

int maxvalue,temp;
maxvalue = 0;

for (i=1; i< (n-1); i++)
{
temp = max_sum_end[i-1]  + max_sum_start[i+1];
if ( temp >  maxvalue) maxvalue=temp;
}

return maxvalue ;
``````
• I think this doesn't work if array only have negative values. Taking into account that the 2 subarrays must have at least one element, you can't just simply set max_sum to cero. Feb 12, 2015 at 23:07
• The two subarrays can be 0. See `double slice (3, 4, 5), sum is 0.` in the question. Nov 26, 2016 at 19:14

This is a Java 100/100 Solution: https://codility.com/demo/results/demoVUMMR9-JH3/

``````class Solution {
public int solution(int[] A) {
int[] maxStartingHere = new int[A.length];
int[] maxEndingHere = new int[A.length];
int maxSum = 0, len = A.length;

for(int i = len - 2; i > 0; --i ) {
maxSum = Math.max(0, A[i] + maxSum);
maxStartingHere[i] = maxSum;
}
maxSum = 0;
for(int i = 1; i < len - 1; ++i ) {
maxSum = Math.max(0, A[i] + maxSum);
maxEndingHere[i] = maxSum;
}
int maxDoubleSlice = 0;

for(int i = 0; i < len - 2; ++i) {
maxDoubleSlice = Math.max(maxDoubleSlice, maxEndingHere[i] + maxStartingHere[i+2]);
}

return maxDoubleSlice;

}
}
``````

Codility 100% in Python

``````def solution(A):
"""
Idea is use two temporary array and store sum using Kadane’s algorithm
ending_here_sum[i] -  the maximum sum contiguous sub sequence ending at index i
starting_here_sum[i] - the maximum sum contiguous sub sequence starting with index i

Double slice sum should be the maximum sum of ending_here_sum[i-1]+starting_here_sum[i+1]

Reference -
https://rafal.io/posts/codility-max-double-slice-sum.html

The sum of double slice (X, Y, Z) is the total of A[X + 1] + A[X + 2] + ... + A[Y - 1] + A[Y + 1] + A[Y + 2] + ... + A[Z - 1].
A[0] = 3
A[1] = 2
A[2] = 6
A[3] = -1
A[4] = 4
A[5] = 5
A[6] = -1
A[7] = 2
contains the following example double slices:
double slice (0, 3, 6), sum is 2 + 6 + 4 + 5 = 17,
double slice (0, 3, 7), sum is 2 + 6 + 4 + 5 - 1 = 16,
double slice (3, 4, 5), sum is 0.
"""
ar_len = len(A)
ending_here_sum = [0] * ar_len
starting_here_sum = [0] * ar_len

# the maximum sum contiguous sub sequence ending at index i
for index in range(1, ar_len - 2):  # A[X + 1] + A[X + 2] + ... + A[Y - 1]
ending_here_sum[index] = max(ending_here_sum[index - 1] + A[index], 0)

# the maximum sum contiguous sub sequence starting with index i
for index in range(ar_len - 2, 1, -1):  # A[Y + 1] + A[Y + 2] + ... + A[Z - 1]
starting_here_sum[index] = max(starting_here_sum[index + 1] + A[index], 0)

# Double slice sum should be the maximum sum of ending_here_sum[i-1]+starting_here_sum[i+1]
max_slice_sum = ending_here_sum[0] + starting_here_sum[2]
for index in range(1, ar_len - 1):
max_slice_sum = max(max_slice_sum, ending_here_sum[index - 1] + starting_here_sum[index + 1])

return max_slice_sum
``````

C# solution 100/100

``````public int solution(int[] A) {
int[] forw = new int[A.Length];
int[] rewi = new int[A.Length];

bool isAllNeg = true;
for (int i = 1; i < A.Length; i++)
{
forw[i] = Math.Max(0, forw[i - 1] + A[i]);
if (A[i] > 0 && isAllNeg) isAllNeg = false;

}

if (isAllNeg)
return 0;

for (int i = A.Length - 2; i >= 0; i--)
{
rewi[i] = Math.Max(0, rewi[i + 1] + A[i]);
}

int maxsum = 0;
for (int i = 1; i < A.Length - 1; i++)
{
maxsum = Math.Max(maxsum, forw[i - 1] + rewi[i + 1]);
}

return maxsum;
}
``````

Without using extra memory, 100/100 C++:

``````#include <algorithm>

int solution(vector<int> &A) {
int max_slice = 0;
int max_slice_i = 0;

int min_val = 0;

int mss = 0;
int mse = 0;

int s = 1;

int msmv = 0;

int max_slice_i_orig = 0;
int os = 1;

for(size_t i = 1;i < A.size() - 1;i++)
{
int v = max_slice_i;

if(max_slice_i > 0 && A[i] < 0)
{
if(A[i] < min_val)
{
v = max_slice_i_orig;
s = os;
min_val = std::max(A[i], -max_slice_i_orig);
} else
{
v = max_slice_i + A[i];
}
} else
{
v = max_slice_i + A[i];
}

int new_orig_v = max_slice_i_orig + A[i];
if(new_orig_v < 0)
{
max_slice_i_orig = 0;
os = i + 1;
} else
{
max_slice_i_orig = new_orig_v;
}

if(v > 0)
{
max_slice_i = v;
} else {
max_slice_i = 0;
min_val = 0;
s = i + 1;
}

if(max_slice_i > max_slice)
{
mss = s;
mse = i;
msmv = min_val;
max_slice = max_slice_i;
}
}

// if all are positive
if(msmv == 0)
{
if(mss == 1 && mse == A.size() - 2)
{
int min = 10001;
for(int j = mss;j <= mse;j++)
{
if(A[j] < min)
min = A[j];
}

max_slice -= min;
}
}

return max_slice;
}
``````

Javascript implementation based on Abhishek Bansal's solution.100/100 on Codility.

``````function solution(A) {

let maxsum=0;
let max_end_at=Array(A.length);
let max_start_at=Array(A.length);
max_end_at[0]=max_start_at[A.length-1]=max_end_at[A.length-1]=max_start_at[0]=0;
let {max}=Math;
for(let i=1;i<A.length-1;i++){

max_end_at[i]=max(0,max_end_at[i-1]+A[i]);
}

for(let n=A.length-2;n>0;n--){

max_start_at[n]=max(0,max_start_at[n+1]+A[n]);
}

for(let m=1;m<A.length-1;m++){

maxsum=max(maxsum,max_end_at[m-1]+max_start_at[m+1]);

}
return maxsum;
}
``````

The most clear Python solution among others:

``````def solution(A):
mid = 1
total = 0
max_slice = 0

for idx, end in enumerate(A[2:-1], start=2):

if total < 0:
mid = idx
total = 0

elif total == 0 and A[idx - 1] > A[mid]:
mid = idx - 1
total = end

else:
if A[mid] > end:
total += A[mid]
mid = idx
else:
total += end

max_slice = max(max_slice, total)

return max_slice
``````
• For the input [89, -7, -56, 20, -47] the function returns 0 but should return 20 because of triplet (1,2,4) Aug 17, 2020 at 12:18

Using the idea from http://en.wikipedia.org/wiki/Maximum_subarray_problem and Abhishek Bansal's answer above. 100% test pass:

``````public class Solution {

public int solution(int[] A) {
int[] maxEndingHere = maxEndingHere(A);
int[] maxStartingHere = maxStartingHere(A);
int maxSlice = 0;
for (int i = 1; i < A.length-1;i++) {
maxSlice = Math.max(maxSlice, maxEndingHere[i-1]+maxStartingHere[i+1]);
}
return maxSlice;
}

/**
* Precalculate ending subarrays. Take into account that first and last element are always 0
* @param input
* @return
*/
public static int[] maxEndingHere(int[] input) {
int[] result = new int[input.length];
result[0] = result[input.length-1] = 0;
for (int i = 1; i < input.length-1; i++) {
result[i] = Math.max(0, result[i-1] + input[i]);
}
return result;
}

/**
* Precalculate starting subarrays. Take into account that first and last element are always 0
* @param input
* @return
*/
public static int[] maxStartingHere(int[] input) {
int[] result = new int[input.length];
result[0] = result[input.length-1] = 0;
for (int i = input.length-2; i >= 1; i--) {
result[i] = Math.max(0, result[i+1] + input[i]);
}
return result;
}
``````

}

Vb.net version of the above solution is as below:

``````Private Function solution(A As Integer()) As Integer
' write your code in VB.NET 4.0
Dim Slice1() As Integer = Ending(A)
Dim slice2() As Integer = Starting(A)
Dim maxSUM As Integer = 0
For i As Integer = 1 To A.Length - 2
maxSUM = Math.Max(maxSUM, Slice1(i - 1) + slice2(i + 1))
Next
Return maxSUM
End Function
Public Shared Function Ending(input() As Integer) As Integer()
Dim result As Integer() = New Integer(input.Length - 1) {}
result(0) = InlineAssignHelper(result(input.Length - 1), 0)
For i As Integer = 1 To input.Length - 2
result(i) = Math.Max(0, result(i - 1) + input(i))
Next
Return result
End Function
Public Shared Function Starting(input() As Integer) As Integer()
Dim result As Integer() = New Integer(input.Length - 1) {}
result(0) = InlineAssignHelper(result(input.Length - 1), 0)
For i As Integer = input.Length - 2 To 1 Step -1
result(i) = Math.Max(0, result(i + 1) + input(i))
Next
Return result
End Function
Private Shared Function InlineAssignHelper(Of T)(ByRef target As T, value As T) As T
target = value
Return value
End Function
``````

View result on codility

Here is an alternative solution to the proposed by me before, more readable and understandable:

``````int solution(vector<int> & A){
if(A.size() < 4 )
return 0;
int maxSum = 0;
int sumLeft = 0;
unordered_map<int, int> leftSums;
leftSums[0] = 0;
for(int i = 2; i < A.size()-1; i++){
sumLeft += A[i-1];
if(sumLeft < 0)
sumLeft = 0;
leftSums[i-1] =  sumLeft;
}

int sumRight = 0;
unordered_map<int, int> rightSums;
rightSums[A.size()-1] =  sumRight;
for( int i = A.size() - 3; i >= 1; i--){
sumRight += A[i+1];
if(sumRight < 0)
sumRight = 0;
rightSums[i+1] = sumRight;
}

for(long i = 1; i < A.size() - 1; i++){
if(leftSums[i-1] + rightSums[i+1] > maxSum)
maxSum = leftSums[i-1] + rightSums[i+1];
}
return maxSum;
``````

}

Well, I have my solution, may be not the best one bit 100%/100%, according to codility requierments.

``````#include<vector>
#include<unordered_map>
#include<algorithm>

using namespace std;

int solution(vector<int> &A) {
unordered_map<size_t, int> maxSliceLeftToRight;
maxSliceLeftToRight[1] = 0;
unordered_map<size_t, int> maxSliceRightToLeft;
maxSliceRightToLeft[A.size() - 2] = 0;
int sum = 0;
for (size_t i = 2; i < A.size() - 1; i++) {
int tmpSum = max(sum + A[i - 1], 0);
sum = max(A[i - 1], tmpSum);
maxSliceLeftToRight[i] = sum;
}
sum = 0;
for (size_t i = A.size() - 3; i > 0; i--) {
int tmpSum = max(sum + A[i + 1], 0);
sum = max(A[i + 1], tmpSum);
maxSliceRightToLeft[i] = sum;
}
int maxDoubleSliceSum = 0;
for (auto & entry : maxSliceLeftToRight) {
int maxRight = maxSliceRightToLeft[entry.first];
if (entry.second + maxRight > maxDoubleSliceSum)
maxDoubleSliceSum = entry.second + maxRight;
}
return maxDoubleSliceSum;
}
``````

Here 100% in python, might not be as elegant as some other solutions above, but considers all possible cases.

``````def solution(A):
#Trivial cases
if len(A)<=3:
return 0
idx_min=A.index(min(A[1:len(A)-1]))
minval=A[idx_min]
maxval=max(A[1:len(A)-1])
if maxval<0:
return 0
if minval==maxval:
return minval*(len(A)-3)
#Regular max slice if all numbers > 0
if minval>=0:
max_ending=0
max_slice=0
for r in range(1,len(A)-1):
if (r!=idx_min):
max_ending=max(0,A[r]+max_ending)
max_slice = max(max_slice, max_ending)
return max_slice
#Else gets more complicated
else :
#First remove negative numbers at the beginning and at the end
idx_neg=1
while A[idx_neg] <= 0 and idx_neg<len(A) :
A[idx_neg]=0
idx_neg+=1
idx_neg=len(A)-2
#<0 , 0
while A[idx_neg] <= 0 and idx_neg > 0 :
A[idx_neg]=0
idx_neg-=1
#Compute partial positive sum from left
#and store it in Left array
Left=[0]*len(A)
max_left=0
for r in range(1,len(A)-1):
max_left=max(0,A[r]+max_left)
Left[r]=max_left
#Compute partial positive sum from right
#and store it in Right array
max_right=0
Right=[0]*len(A)
for r in range(len(A)-2,0,-1):
max_right=max(0,A[r]+max_right)
Right[r]=max_right
#Compute max of Left[r]+Right[r+2].
#The hole in the middle corresponding
#to Y index of double slice (X, Y, Z)
max_slice=0
for r in range(1,len(A)-3):
max_slice=max(max_slice,Left[r]+Right[r+2])
return max_slice
pass
``````

Think I got it based on Moxis Solution. Tried to point out the Intension.

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

int n = A.length - 1;

// Array with cummulated Sums when the first Subarray ends at Index i
int[] endingAt = new int[A.length];
int helperSum = 0;

// Optimal Subtotal before all possible Values of Y
for(int i = 1; i < n; ++i ) {
helperSum = Math.max(0, A[i] + helperSum);
endingAt[i] = helperSum;
}

// Array with cummulated Sums when the second Subarray starts at Index i
int[] startingAt = new int[A.length];
helperSum = 0;

// Optimal Subtotal behind all possible Values of Y
for(int i = (n - 1); i > 0; --i ) {
helperSum = Math.max(0, A[i] + helperSum);
startingAt[i] = helperSum;
}

//Searching optimal Y
int sum = 0;
for(int i = 0; i < (n - 1); ++i) {
sum = Math.max(sum, endingAt[i] + startingAt[i+2]);
}

return sum;

}
``````

}

Here is the Python version of the proposed solution with complexity O(N) and %100 correctness and performance.

``````#Find the maximal sum of any double slice.
#https://app.codility.com/programmers/lessons/9-
#maximum_slice_problem/max_double_slice_sum/

import sys

def solution(A):

n=len(A)
max_sum_endingat=[0]*n
max_sum_startat=[0]*n

if(n<=3):
return 0
else:

for i in range(1,n-1):
max_sum_endingat[i] =max(0,max_sum_endingat[i-1] + A[i])

for i in range(n-2,0,-1):
max_sum_startat[i] =max(0,max_sum_startat[i+1] + A[i])

max_double=-sys.maxsize

for k in range(1,n-1):
max_double=max(max_double,max_sum_endingat[k-1]+max_sum_startat[k+1])

return max_double
``````

This is my solution. It got 92%. Its a modified version of the original concept except I'm keep track of a minimal value to use as the position `Y`, and I'm shifting the sum of the entire interval accordingly.

Note: If anyone has any idea why it's only 92% feel free to let me know

``````class Solution {
public int solution(int[] A) {
// write your code in Java SE 8
int max = -10001, sum = 0, min=A[1];

for(int i = 1; i < A.length-1; i++){
sum += A[i];

min = Math.min(A[i], min);
max = Math.max(sum-min, max);

if(sum - min < 0){
sum = 0;
min = A[i+1];
}
}

return max;
}
}
``````
• For the input `[0, -1, 1, -1, 1, 0]` your code returns 1 because it never drops the first -1. But the best slice (1, 3, 5) gives 2. Jun 23, 2022 at 16:46

Single-loop, no extra memory dynamic programming solution in Python:

``````def solution(A):
max_gap_sum = 0
gapless_sum, gap_sum = 0, float("-inf")
for v in A[1:-1]:
gapless_sum, gap_sum = max(gapless_sum + v, 0), max(gap_sum + v, gapless_sum)
max_gap_sum = max(max_gap_sum, gap_sum)
return max_gap_sum
``````

Java solution, 100/100

``````    class Solution {
public int solution(int[] A) {
// write your code in Java SE 8
int maxEnd = 0, maxSlice = Integer.MIN_VALUE;

for(int val : A) {
maxEnd = Math.max(val, maxEnd + val);
maxSlice = Math.max(maxSlice, maxEnd);
}

return maxSlice;
}
}
``````