# How to count numbers between 2 numbers L and R (both included) such that product of the digits of the selected numbers is even?

How to find the count of numbers between 2 numbers L and R (both included) which have product of their digits even? How can we go about it other than brute force?

``````dp[0][0]=4;
dp[0][1]=5;
for(int l=1;l<=9;l++)
{
dp[l][0]=0;
dp[l][1]=0;
dp[l][0]+=(dp[l-1][0])*10;
dp[l][0]+=dp[l-1][1]*5;
dp[l][1]+=dp[l-1][1]*5;
}
``````

Here is a brute force checker I had made,I am trying to develop a more efficient solution

``````bool f(ll n)
{
ll p=1;
if(n==0)
return true;
while(n)
{
p*=n%10;
n/=10;
if(p%2==0) return true;
p=1;
}
if(p%2) return false;
else
return true;
}
ll brute(ll l,ll r)
{
if(l>r) swap(l,r);
ll cnt=0;
for(ll  i=l;i<=r;i++)
{
if(f(i))
{
cnt++;
}
}

return cnt;
``````

}

`dp[l-1][0]` stores count of even product numbers of length l That is what I had thought..? Can this solve the problem ?

-
Did you think of something? –  Maroun Maroun Jan 24 '13 at 17:50
If the product is even that just means that at least one of then is even –  xol Jan 24 '13 at 17:53
@xol:yes I agree –  user1907531 Jan 24 '13 at 17:55
There's a `log10(R)` solution, but I don't think it's necessary for you. –  ipc Jan 24 '13 at 17:58
The title asks for `product of the selected numbers is even` while the question asks for `product of their digits even?` Which one is it? –  amit Jan 24 '13 at 18:40

Brute force is a terribly wasteful approach. We can do much better.

(I apologize for the formatting; I hope the content is still clear enough.)

## First, let's simplify the problem:

``````EvenProductNumbersBetween(RangeStart, RangeEnd) = NumbersBetween(RangeEnd - RangeStart) - AllOddDigitNumbersBetween(RangeStart, RangeEnd)

NumbersBetween(RangeStart, RangeEnd) = (RangeEnd - RangeStart) + 1

AllOddDigitNumbersBetween(RangeStart, RangeEnd) = AllOddDigitNumbersUpTo(RangeEnd) - AllOddDigitNumbersUpTo(RangeStart-1)
``````

## Now we get to the meat: calculating AllOddDigitNumbersUpTo(RangeEnd)

First, consider the simple cases:

(Assume RangeEnd is positive)

If RangeEnd is a single digit (i.e. < 10), then

``````AllOddDigitNumbersUpTo(RangeEnd) = Floor((RangeEnd+1)/2)

E.g.:
AllOddDigitNumbersUpTo(0) = {} = 0
AllOddDigitNumbersUpTo(1) = {1} = 1
AllOddDigitNumbersUpTo(2) = {1} = 1
AllOddDigitNumbersUpTo(3) = {1,3} = 2
AllOddDigitNumbersUpTo(4) = {1,3} = 2
AllOddDigitNumbersUpTo(5) = {1,3,5} = 3
AllOddDigitNumbersUpTo(6) = {1,3,5} = 3
AllOddDigitNumbersUpTo(7) = {1,3,5,7} = 4
AllOddDigitNumbersUpTo(8) = {1,3,5,7} = 4
AllOddDigitNumbersUpTo(9) = {1,3,5,7,9} = 5
``````

If RangeEnd can be any number with a specific number of digits, then

Consider that each digit must have one of the five odd numbers as choices (leading zeroes shorten the length, and are thus excluded), so this is trivial to calculate, directly:

``````AllOddDigitNumbersOfLength(NumberLength) = 5^NumberLength

E.g.:
AllOddDigitNumbersOfLength(1) = {1, 3, 5, 7, 9} = 5
AllOddDigitNumbersOfLength(2) = {1, 3, 5, 7, 9} * {1, 3, 5, 7, 9} = 5*5 = 25
AllOddDigitNumbersOfLength(3) = 5*5*5 = 125
...
``````

Otherwise, break RangeEnd apart:

``````RangeEnd = (FirstDigit * 10^PowerOfFirstDigit) + Remainder

AllOddDigitNumbersUpTo(RangeEnd) = AllOddDigitNumbersUpTo(FirstDigit) * AllOddDigitNumbersOfLength(PowerOfFirstDigit-1) + AllOddDigitNumbersUpTo(Remainder)
``````

Unfortunately, there's a complicating case with leading zeroes. (Thanks to @AndyProwl for pointing me toward this problem with an earlier version of my answer!) If Remainder starts with a zero, then we should NOT add the AllOddDigitNumbersUpTo(Remainder) term, at the end, because the constrained leading zero would make the product even for every smaller number we would try to make.

``````E.g.:

AllOddDigitNumbersUpTo(6300193) =
= AllOddDigitNumbersUpTo(6*(10^7) + 300193)
= AllOddDigitNumbersUpTo(6) * AllOddDigitNumbersOfLength(7-1) + AllOddDigitNumbersUpTo(300193)
= 3 * 5^6 + AllOddDigitNumbersUpTo(300193)
= Trivial * Trivial + LogarithmicallySmallerCase

AllOddDigitNumbersUpTo(300193) =
= AllOddDigitNumbersUpTo(3*(10^6) + 00193)
= AllOddDigitNumbersUpTo(3) * AllOddDigitNumbersOfLength(6-1)
= 2 * 5^5
= Trivial * Trivial
``````
-
If I understand it correctly, shouldn't `AllOddDigitNumbersUpTo(100)` include `AllOddDigitNumbersUpTo(10)`? Or you mean only the numbers with exactly 2 digits? –  Andy Prowl Jan 24 '13 at 20:58
@AndyProwl: You're right! I'm conflating the two things, in that case. I'll fix it. Thanks! –  Mattias Andersson Jan 24 '13 at 21:18
I am still not sure if the decomposition `AllOddDigitNumbersUpTo(RangeEnd) = AllOddDigitNumbersUpTo(FirstDigit) * AllOddDigitNumbersUpTo(PowerOfFirstDigit) + AllOddDigitNumbersUpTo(Remainder)` is correct, but I upvoted anyway because of the idea of inverting the problem: I focused on finding all sequences with at least one even digit, while it's way more clever to search for those with all odd digits –  Andy Prowl Jan 24 '13 at 21:24
@AndyProwl: Thanks, Andy! I had not properly handled leading zeroes, but I think I've fixed the issues, now. –  Mattias Andersson Jan 24 '13 at 21:58
The range `[L,R]` is `L,L+1,...,R-1,R` –  amit Jan 24 '13 at 18:40