# Count the number of occurrences of 0's in integers from 1 to N

How will you efficiently count number of occurrences of 0's in the decimal representation of integers from 1 to N?

e.g. The number of 0's from 1 to 105 is 16. How?

10,20,30,40,50,60,70,80,90,100,101,102,103,104,105

Count the number of 0's & you will find it 16.

Obviously, a brute force approach won't be appreciated. You have to come up with an approach which doesn't depend on "How many numbers fall between 1 to N". Can we just do by seeing some kind of pattern?

Cannot we extend the logic compiled here to work for this problem?

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I thought you weren't suppose to leak those questions after an interview ;) –  Mateusz Dymczyk Aug 9 '12 at 21:13
It's clearly proportional to n^2, so just do it brute force up to 10k or 100k to derive a constant and you're done. –  Puppy Aug 9 '12 at 21:14
@DeadMG, it is more likely in the order of N log N I'd say. –  Jens Gustedt Aug 9 '12 at 21:18
I love these sorts of questions. Chance of a practical application of the algorithm outside the classroom 0.00000000000000000000000000001%. –  Tony Hopkinson Aug 9 '12 at 21:40
To make a distribution of digits in a range, it helps to count them. en.wikipedia.org/wiki/Benford's_law –  Alex Reynolds Aug 9 '12 at 22:18

My original answer was simple to understand but tricky to code. Here's something that is simpler to code. It's a straight-forward non-recursive solution that works by counting the number of ways zeros can appear in each position.

For example:

x <= 1234. How many numbers are there of the following form?

x = ??0?

There are 12 possibilities for the "hundreds or more" (1,2, ..., 12). Then there must be a zero. Then there are 10 possibilities for the last digit. This gives 12 * 10 = 120 numbers containing a 0 at the third digit.

The solution for the range (1 to 1234) is therefore:

• ?0??: 1 * 100 = 100
• ??0?: 12 * 10 = 120
• ???0: 123
• Total = 343

But an exception is if n contains a zero digit. Consider the following case:

x <= 12034. How many numbers are there of the following form?

x = ??0??

We have 12 ways to pick the "thousands or more". For 1, 2, ... 11 we can choose any two last digits (giving 11 * 100 possibilities). But if we start with 12 we can only choose a number between 00 and 34 for the last two digits. So we get 11 * 100 + 35 possibilities altogether.

Here's an implementation of this algorithm (written in Python, but in a way that should be easy to port to C):

def countZeros(n):
result = 0
i = 1

while True:
b, c = divmod(n, i)
a, b = divmod(b, 10)

if a == 0:
return result

if b == 0:
result += (a - 1) * i + c + 1
else:
result += a * i

i *= 10
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For 1 to 999, your "special handling for the end condition" covers 90% of the range (100 to 999). This is not a very good answer... –  Nemo Aug 9 '12 at 21:19
@Nemo, I think you misinterpreted that part. The rule is to split the number into ranges with equal numbers of digits, so [1,999] becomes ([1,9],[10,99],[100,999]), and then for each segment you do (high-low)*(length-1)/10, and add them together. The "special handling for the end condition" would be if instead of [1,999] we had something like [1,1234], where [1000,1234] doesn't fit in the pattern. It's only that last part that needs special handling. –  Kevin Aug 9 '12 at 21:31
@Kevin: Yes, I was thinking (1,666) or something, but I decided to go for broke and overreached. –  Nemo Aug 9 '12 at 21:40
@Mark: OK, so code it up so we can compare it to the other solutions :-) –  Nemo Aug 9 '12 at 21:53
Now that you have provided code and debugged it, I am removing my downvote. I still think the recursive formulation is simpler, but I agree this works. P.S. @drewk's "expectations" are perhaps better called "giving the correct answer" –  Nemo Aug 10 '12 at 1:13

I would suggest adapting this algorithm from base 2 to base 10:

Number of 1s in the two's complement binary representations of integers in a range

The resulting algorithm is O(log N).

The approach is to write a simple recursive function count(n) that counts the zeroes from 1 to n.

The key observation is that if N ends in 9, e.g.:

123456789

You can put the numbers from 0 to N into 10 equal-sized groups. Group 0 is the numbers ending in 0. Group 1 is the numbers ending in 1. Group 2 is the numbers ending in 2. And so on, all the way through group 9 which is all the numbers ending in 9.

Each group except group 0 contributes count(N/10) zero digits to the total because none of them end in zero. Group 0 contributes count(N/10) (which counts all digits but the last) plus N/10 (which counts the zeroes from the final digits).

Since we are going from 1 to N instead of 0 to N, this logic breaks down for single-digit N, so we just handle that as a special case.

[update]

What the heck, let's generalize and define count(n, d) as how many times the digit d appears among the numbers from 1 to n.

/* Count how many d's occur in a single n */
unsigned
popcount(unsigned n, unsigned d) {
int result = 0;
while (n != 0) {
result += ((n%10) == d);
n /= 10;
}
return result;
}

/* Compute how many d's occur all numbers from 1 to n */
unsigned
count(unsigned n, unsigned d) {
/* Special case single-digit n */
if (n < 10) return (d > 0 && n >= d);

/* If n does not end in 9, recurse until it does */
if ((n % 10) != 9) return popcount(n, d) + count(n-1, d);

return 10*count(n/10, d) + (n/10) + (d > 0);
}

The ugliness for the case n < 10 again comes from the range being 1 to n instead of 0 to n... For any single-digit n greater than or equal to d, the count is 1 except when d is zero.

Converting this solution to a non-recursive loop is (a) trivial, (b) unnecessary, and (c) left as an exercise for the reader.

[Update 2]

The final (d > 0) term also comes from the range being 1 to n instead of 0 to n. When n ends in 9, how many numbers between 1 and n inclusive have final digit d? Well, when d is zero, the answer is n/10; when d is non-zero, it is one more than that, since it includes the value d itself.

For example, if n is 19 and d is 0, there is only one smaller number ending in 0 (i.e. 10). But if n is 19 and d is 2, there are two smaller numbers ending in 2 (i.e. 2 and 12).

Thanks to @Chan for pointing out this bug in the comments; I have fixed it in the code.

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+1: This is very straightforward and correct. –  dawg Aug 10 '12 at 5:34
@Nemo, I posted a solution which I believe is something similar to what you suggested. I'm struggling with generalizing my solution. Can you please help me with it ? Thanks –  brainydexter Aug 10 '12 at 21:14
@Nemo: Have you tested your solution? For n = 20 with d = 2, there are 3 2's (2, 12, 20), but your solution yielded only 2. –  Chan Sep 19 '13 at 2:32
@Chan: Indeed I had a bug whenever d is non-zero. Fixed; thanks. –  Nemo Sep 19 '13 at 6:15
@Nemo: You're welcome ;) –  Chan Sep 19 '13 at 17:41

Let Z(n) = #zero digits in numbers 0 <= k < n. Obviously, Z(0) = 0.

If n = 10*k + r, 0 <= r <= 9, all 10*k numbers 10*j + s, 0 <= j < k, 0 <= s <= 9 are in the range, each tenth last digit is 0, so that's k zeros, and each prefix j (all but the last digit) occurs ten times, but we mustn't count 0, so the number of zeros in the prefixes is 10*(Z(k)-1).

The number of zeros in the r numbers 10*k, ..., 10*k + (r-1) is r*number of zeros in k + (r > 0 ? 1 : 0).

So we have an O(log n) algorithm for computing Z(n)

unsigned long long Z(unsigned long long n)
{
if (n == 0) {
return 0;
}
if (n <= 10) {
return 1;
}
unsigned long long k = n/10, r = n%10;
unsigned long long zeros = k + 10*(Z(k)-1);
if (r > 0) {
zeros += r*zeroCount(k) + 1;
}
return zeros;
}

unsigned zeroCount(unsigned long long k)
{
unsigned zeros = 0;
while(k) {
zeros += (k % 10) == 0;
k /= 10;
}
return zeros;
}

To compute the number for an arbitrary range,

unsigned long long zeros_in_range(unsigned long long low, unsigned long long high)
{
return Z(high+1) - Z(low); // beware of overflow if high is ULLONG_MAX
}
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your function Z(105) is 26, Incorrect. –  BLUEPIXY Aug 10 '12 at 7:01
@BLUEPIXY Forgot to subtract the 0-prefixes, thanks for the heads-up. –  Daniel Fischer Aug 10 '12 at 11:19
@BLUEPIXY No, 344 is correct, Prelude> length . filter (== '0') \$ [0 .. 1233] >>= show gives 344. Z(n) counts the zeros in 0, 1, ..., n-1, so it must be at least 1 for all n > 0. –  Daniel Fischer Aug 10 '12 at 11:45
It is starting from 0. All right. –  BLUEPIXY Aug 10 '12 at 11:57

The way I approached this problem:

numbers can be in the range 1 to N:

So, I broke this into ranges like this:

Rangle      : #Digits   :   #Zeros
1   -   9   :   1       :   0
10  -   99  :   2       :   9 (number of all the possible digits when zero is at units place=> _0 ie, 1,2,3,4,5,6,7,8,9
100 -   199 :   3       :   20 => 10 (#digits when zero is at units place) + 10 (#digits when zero is at tens place)
200 -   276 :   3       :   18 => 8 (#digits when zero is at units place) + 10 (#digits when zero is at tens place)
300 -   308 :   3       :   10 => 1 (#digits when zero is at units place) + 9 (#digits when zero is at tens place)
1000-   1008:   4       :   19 => 1 + 9 + 9

Now for any given range 1 - N, I want to be able to break the number into these ranges and use the above logic to compute the number of zeros.

Test run:

for a given number N:

- compute number of digits: len
- if len = 1 : d1: return 0
- len = 2: d2_temp: count # of digits that can possibly occur when 0 is at unit's place
: for e.g. 76: so numbers can be between 10 - 76: (7 - 1) + 1 = 7
: d2: sum(d2_temp, d1)
- len = 3: return d3 : sum(d3_temp, d2)
: compute d3_temp:
: for e.g. n = 308 : get digit at 10^(len-1) : loopMax 3
: d3_temp1: count number of zeros for this loop: 1 * 100 to (loopMax -1) * 100 : (loopMax-1) * 20
: d3_temp2: for n count (#digits when zero is at units place) + (#digits when zero is at tens place)
: d3_temp = d3_temp1 + d3_temp2

Lets try to generalise:

99 : sum( , )
: d3_temp:
: loopMax: n = 99 : n/(10^1) : 9
: d3_temp1: 8 : (9-1) * (10*(len-1)) : (loopMax - 1) * 10 * (len-1)
: d3_temp2: 1 : for len, count #0s in range (loopMax * 10 * (len-1)) to n : count(90, 99)
: d3_temp = 8 + 1
: sum(9, 0)
: 9

I'm having some trouble proceeding from here, but this would work.

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@Nemo: I think this is similar to what you suggested. Can you please help me come up with generalising this to make a function out of it ? –  brainydexter Aug 10 '12 at 21:11
class FindZero{

public int findZero(int lastNumber){

int count=1,k;
if(lastNumber<10)
return 0;
else if(lastNumber==10)
return 1;
else{

for(int i=11;i<=lastNumber;i++){
k=i;
while(k>0){

if(k%10==0)
count++;
k=k/10;
}
}
return count;
}
}
public static void main(String args[]){
FindZero obj = new FindZero();
System.out.println(obj.findZero(1234));
}
}
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