# Count the subsequences of length 4 divisible by 9

To count the subsequences of length 4 of a string of length n which are divisible by 9.

For example if the input string is 9999 then cnt=1

My approach is similar to Brute Force and takes O(n^3).Any better approach than this?

-
If the input string is 99999 (5 digits), what would count be? Do only unique subsequences count, or does each duplicate count separately? –  Steve314 Aug 7 '12 at 21:44
@Steve314 Each duplicate count seperately –  Luv Aug 8 '12 at 14:06

If you want to check if a number is divisible by 9, You better look here.

I will describe the method in short:

``````checkDividedByNine(String pNum) :
If pNum.length < 1
return false
If pNum.length == 1
Sum = 0
For c in pNum:
Sum += toInt(pNum)
return checkDividedByNine(toString(Sum))
``````

So you can reduce the running time to less than O(n^3).

EDIT: If you need very fast algorithm, you can use pre-processing in order to save for each possible 4-digit number, if it is divisible by 9. (It will cost you 10000 in memory)

EDIT 2: Better approach: you can use dynamic programming:

For string S in length N:

D[i,j,k] = The number of subsequences of length j in the string S[i..N] that their value modulo 9 == k.

Where 0 <= k <= 8, 1 <= j <= 4, 1 <= i <= N.

``````D[i,1,k] = simply count the number of elements in S[i..N] that = k(mod 9).
D[N,j,k] = if j==1 and (S[N] modulo 9) == k, return 1. Otherwise, 0.
D[i,j,k] = max{ D[i+1,j,k], D[i+1,j-1, (k-S[i]+9) modulo 9]}.
``````

And you return D[1,4,0].

You get a table in size - N x 9 x 4.

Thus, the overall running time, assuming calculating modulo takes O(1), is O(n).

-
That I know. I want to reduce the complexity of the problem. –  Luv Aug 7 '12 at 21:07
If pNum.length < 1 return false; Why? Why not return 0? –  Vikram Aug 7 '12 at 21:10
checkDividedByNine return boolean, not a number. –  barak1412 Aug 7 '12 at 21:21
@Luv look at my dynamic programming solution –  barak1412 Aug 7 '12 at 21:42
@barak1412 See me working code for the above problem using DP –  Luv Aug 8 '12 at 14:01

Assuming that the subsequence has to consist of consecutive digits, you can scan from left to right, keeping track of what order the last 4 digits read are in. That way, you can do a linear scan and just apply divisibility rules.

If the digits are not necessarily consecutive, then you can do some finangling with lookup tables. The idea is that you can create a 3D array named `table` such that `table[i][j][k]` is the number of sums of `i` digits up to index `j` such that the sum leaves a remainder of `k` when divided by 9. The table itself has size 45n (`i` goes from 0 to 4, `j` goes from 0 to `n-1`, and `k` goes from 0 to 8).

For the recursion, each `table[i][j][k]` entry relies on `table[i-1][j-1][x]` and `table[i][j-1][x]` for all `x` from 0 to 8. Since each entry update takes constant time (at least relative to n), that should get you an O(n) runtime.

-
Numbers are not necessarily consecutive in a subsequence –  Luv Aug 7 '12 at 21:11
Any better than O(n^4)?? –  Luv Aug 7 '12 at 21:14
If you're only looking for the total number, you can try some stuff with memoizing; I'll update my answer. (I was being silly earlier) –  Dennis Meng Aug 7 '12 at 21:15
By the way, can you please explain me how is it O(n^3) or O(n^4)? –  Vikram Aug 7 '12 at 21:16
@Vikram Originally I was working under the assumption that we had to generate each group of 4 digits (of which there are n choose 4), which would have made it O(n^4). Then I found the smarter way to approach it. –  Dennis Meng Aug 7 '12 at 21:28

``````/*NOTE: The following holds true, if the subsequences consist of digits in contagious locations */

public int countOccurrences (String s) {
int count=0;
int len = s.length();
String subs = null;
int sum;

if (len < 4)
return 0;
else {
for (int i=0 ; i<len-3 ; i++) {
subs = s.substring(i, i+4);
sum = 0;

for (int j=0; j<=3; j++) {
sum += Integer.parseInt(String.valueOf(subs.charAt(j)));
}

if (sum%9 == 0)
count++;
}
return count;
}
}
``````
-
As mentioned in a comment to my question, the subsequences don't necessarily contain consecutive digits. Otherwise, this should work. –  Dennis Meng Aug 7 '12 at 21:49
@DennisMeng...You are right, my friend! –  Vikram Aug 7 '12 at 22:04

Here is the complete working code for the above problem based on the above discussed ways using lookup tables

``````int fun(int h)
{
return (h/10 + h%10);
}

int main()
{
int t;
scanf("%d",&t);
int i,T;
for(T=0;T<t;T++)
{
char str[10001];
scanf("%s",str);
int len=strlen(str);
int arr[len][5][10];
memset(arr,0,sizeof(int)*(10*5*len));

int j,k,l;
for(j=0;j<len;j++)
{
int y;
y=(str[j]-48)%10;
arr[j][1][y]++;
}

//printarr(arr,len);

for(i=len-2;i>=0;i--)   //represents the starting index of the string
{

int temp[5][10];
//COPYING ARRAY
int a,b,c,d;
for(a=0;a<=4;a++)
for(b=0;b<=9;b++)
temp[a][b]=arr[i][a][b]+arr[i+1][a][b];

for(j=1;j<=4;j++)   //represents the length of the string
{
for(k=0;k<=9;k++)   //represents the no. of ways to make it
{

if(arr[i+1][j][k]!=0)
{
for(c=1;c<=4;c++)
{
for(d=0;d<=9;d++)
{
if(arr[i][c][d]!=0)
{
int h,r;
r=j+c;
if(r>4)
continue;
h=k+d;
h=fun(h);
if(r<=4)
temp[r][h]=( temp[r][h]+(arr[i][c][d]*arr[i+1][j][k]))%1000000007;
}}}
}

//copy back from temp array

}
}
for(a=0;a<=4;a++)
for(b=0;b<=9;b++)
arr[i][a][b]=temp[a][b];
}

printf("%d\n",(arr[0][1][9])%1000000007);

}

return 0;
}
``````
-
It runs in linear time using lookup tables but it takes O(600n) in worst case and space O(n*4*10). Please see if it could be further optimized. Thanks in advance –  Luv Aug 8 '12 at 14:04