# MaxDoubleSliceSum Codility Algorithm

I stumbled upon this problem on Codility Lessons, here is the description:

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 = 3
A = 2
A = 6
A = -1
A = 4
A = 5
A = -1
A = 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:

int solution(vector &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 = 3
A = 2
A = 6
A = -1
A = 4
A = 5
A = -1
A = 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.

I have already read about the algorithm with counting MaxSum starting at index i and ending at index i, but I don't know why my approach sometimes gives bad results. The idea is to compute MaxSum ending at index i, ommiting the minimum value at range 0..i. And here is my code:

``````int solution(vector<int> &A) {
int n = A.size();

int end = 2;

int ret = 0;
int sum = 0;

int min = A;

while (end < n-1)
{
if (A[end] < min)
{
sum = max(0, sum + min);
ret = max(ret, sum);
min = A[end];
++end;
continue;
}
sum = max(0, sum + A[end]);
ret = max(ret, sum);
++end;
}

return ret;
}
``````

I would be glad if you could help me point out the loophole!

• Isn't 4 the sum of (3,4,5) in your examples?
– Tarc
Sep 8, 2014 at 14:41
• @Tarc no because you have to omit A[x], A[y] and A[z]. So you can't sum up anything there. Sep 8, 2014 at 15:01

My solution based on bidirectional Kadane's algorithm. More details on my blog here. Scores 100/100.

``````public int solution(int[] A) {
int N = A.length;
int[] K1 = new int[N];
int[] K2 = new int[N];

for(int i = 1; i < N-1; i++){
K1[i] = Math.max(K1[i-1] + A[i], 0);
}
for(int i = N-2; i > 0; i--){
K2[i] = Math.max(K2[i+1]+A[i], 0);
}

int max = 0;

for(int i = 1; i < N-1; i++){
max = Math.max(max, K1[i-1]+K2[i+1]);
}

return max;
}
``````
• Really nice solution! Very clever use of the Kadane's algorithm Apr 15, 2015 at 19:46

Here is my code:

``````int get_max_sum(const vector<int>& a) {
int n = a.size();
vector<int> best_pref(n);
vector<int> best_suf(n);
//Compute the best sum among all x values assuming that y = i.
int min_pref = 0;
int cur_pref = 0;
for (int i = 1; i < n - 1; i++) {
best_pref[i] = max(0, cur_pref - min_pref);
cur_pref += a[i];
min_pref = min(min_pref, cur_pref);
}
//Compute the best sum among all z values assuming that y = i.
int min_suf = 0;
int cur_suf = 0;
for (int i = n - 2; i > 0; i--) {
best_suf[i] = max(0, cur_suf - min_suf);
cur_suf += a[i];
min_suf = min(min_suf, cur_suf);
}
//Check all y values(y = i) and return the answer.
int res = 0;
for (int i = 1; i < n - 1; i++)
res = max(res, best_pref[i] + best_suf[i]);
return res;
}

int get_max_sum_dummy(const vector<int>& a) {
//Try all possible values of x, y and z.
int res = 0;
int n = a.size();
for (int x = 0; x < n; x++)
for (int y = x + 1; y < n; y++)
for (int z = y + 1; z < n; z++) {
int cur = 0;
for (int i = x + 1; i < z; i++)
if (i != y)
cur += a[i];
res = max(res, cur);
}
return res;
}

bool test() {
//Generate a lot of small test cases and compare the output of
//a brute force and the actual solution.
bool ok = true;
for (int test = 0; test < 10000; test++) {
int size = rand() % 20 + 3;
vector<int> a(size);
for (int i = 0; i < size; i++)
a[i] = rand() % 20 - 10;
if (get_max_sum(a) != get_max_sum_dummy(a))
ok = false;
}
for (int test = 0; test < 10000; test++) {
int size = rand() % 20 + 3;
vector<int> a(size);
for (int i = 0; i < size; i++)
a[i] = rand() % 20;
if (get_max_sum(a) != get_max_sum_dummy(a))
ok = false;
}
return ok;
}
``````

The actual solution is `get_max_sum` function(the other two are a brute force solution and a tester functions that generates a random array and compares the output of a brute force and actual solution, I used them for testing purposes only).

The idea behind my solution is to compute the maximum sum in a sub array that that starts somewhere before `i` and ends in `i - 1`, then do the same thing for suffices(`best_pref[i]` and `best_suf[i]`, respectively). After that I just iterate over all `i` and return the best value of `best_pref[i] + best_suf[i]`. It works correctly because `best_pref[y]` finds the best `x` for a fixed `y`, `best_suf[y]` finds the best `z` for a fixed `y` and all possible values of `y` are checked.

• @LukaRahne As I have said in my answer, the actual solution is get_max_sum function(it obviously has O(n) time and space complexity). Brute force algorithm was used only for testing purposes. Sep 8, 2014 at 19:08
``````def solution(A):
n = len(A)
K1 =  * n
K2 =  * n
for i in range(1,n-1,1):
K1[i] = max(K1[i-1] + A[i], 0)

for i in range(n-2,0,-1):
K2[i] = max(K2[i+1]+A[i], 0)

maximum = 0;
for i in range(1,n-1,1):
maximum = max(maximum, K1[i-1]+K2[i+1])

return maximum

def main():
A = [3,2,6,-1,4,5,-1,2]
print(solution(A))

if __name__ == '__main__': main()
``````

Ruby 100%

``````def solution(a)
max_starting =(a.length - 2).downto(0).each.inject([[],0]) do |(acc,max), i|
[acc, acc[i]= [0, a[i] + max].max ]
end.first

max_ending =1.upto(a.length - 3).each.inject([[],0]) do |(acc,max), i|
[acc, acc[i]= [0, a[i] + max].max ]
end.first

max_ending.each_with_index.inject(0) do |acc, (el,i)|
[acc, el.to_i + max_starting[i+2].to_i].max
end
end
``````