The following algorithm computes the number of integers from 0 to (n-1) without "3" in their decimal representation quite efficiently. (I have modified the interval from 1 .. n to 0 .. n-1 only to simplify the following calculations slightly.)

*(I am not an expert in complexity calculations, but I think the complexity of this algorithm is *`O(log n)`

, because it does a fixed number of steps for each digit of `n`

.)

The first observation is that the number of integers with at most d digits (i.e. the numbers in the interval 0 .. 10^{d}-1) not having the digit 3 in their decimal representation is exactly 9^{d}, because for each digit you have 9 possible choices 0,1,2,4,5,6,7,8,9.

Now let me demonstrate the algorithm with a 5 digit number n = a_{4}a_{3}a_{2}a_{1}a_{0}.

We compute separately the number of integers with no "3" in their decimal representation for the intervals

- I
_{0}: a_{4}a_{3}a_{2}a_{1} 0 <= i < a_{4}a_{3}a_{2}a_{1}a_{0}
- I
_{1}: a_{4}a_{3}a_{2} 0 0 <= i < a_{4}a_{3}a_{2}a_{1} 0
- I
_{2}: a_{4}a_{3} 0 0 0 <= i < a_{4}a_{3}a_{2} 0 0
- I
_{3}: a_{4} 0 0 0 0 <= i < a_{4}a_{3} 0 0 0
- I
_{4}: 0 0 0 0 0 <= i < a_{4} 0 0 0 0

The number of integers in the interval I_{j} that do not have a "3" in the decimal representation is

- 0, if one of the higher valued digits a
_{j+1}, a_{j+2}, ... is equal to 3,
otherwise:
- a
_{j} * 9^{j}, if 0 <= a_{j} <= 3, (a_{j} choices for the
j^{th} digit, 9 choices for all lower valued digits),
- (a
_{j} - 1) * 9^{j}, if aj > 3 (because 3 is not a valid choice for the j^{th} digit) .

So we have the following function:

```
/*
* Compute number of integers x with 0 <= x < n that do not
* have a 3 in their decimal representation.
*/
int f(int n)
{
int count = 0;
int a; // The current digit a_j
int p = 1; // The current value of 9^j
while (n > 0) {
a = n % 10;
if (a == 3) {
count = 0;
}
if (a <= 3) {
count += a * p;
} else {
count += (a-1) * p;
}
n /= 10;
p *= 9;
}
return count;
}
```