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.

`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`N log N`

I'd say. – Jens Gustedt Aug 9 '12 at 21:18