The total number of zeros in `n!`

is given by sequence A027869 in the On-line Encyclopedia of Integer Sequences. There really seems to be no way to compute the total number of zeros in `n!`

short of computing `n!`

and counting the number of zeros. With a big int library, this is easy enough. A simple Python example:

```
import math
def zeros(n): return str(math.factorial(n)).count('0')
```

So, for example, `zeros(100)`

evaluates to `30`

. For larger `n`

you might want to skip the relatively expensive conversion to a string and get the 0-count arithmetically by repeatedly dividing by `10`

.

As you have noted, it is far easier to compute the number of trailing zeros. Your code, in Python, is essentially:

```
def trailing_zeros(n):
count = 0
p = 5
while p <= n:
count += n//p
p *= 5
return count
```

As a heuristic way to estimate the total number of zeros, you can first count the number of trailing zeros, subtract that from the number of digits in `n!`

, subtract an additional 2 from this difference (since neither the first digit of `n!`

nor the final digit before the trailing zeros are candidate positions for non-trailing zeros) and guess that 1/10 of these digits will in fact be zeros. You can use Stirling's formula to estimate the number of digits in `n!`

:

```
def num_digits(n):
#uses Striling's formula to estimate the number of digits in n!
#this formula, known as, Kamenetsky's formula, gives the exact count below 5*10^7
if n == 0:
return 1
else:
return math.ceil(math.log10(2*math.pi*n)/2 + n *(math.log10(n/math.e)))
```

Hence:

```
def est_zeros(n):
#first compute the number of candidate postions for non-trailing zerpos:
internal_digits = max(0,num_digits(n) - trailing_zeros(n) - 2)
return trailing_zeros(n) + internal_digits//10
```

For example `est_zeros(100)`

evaluates to 37, which isn't very good, but then there is no reason to think that this estimation is any better than asymptotic (though *proving* that it is asymptotically correct would be very difficult, I don't actually know if it is). For larger numbers it seems to give reasonable results. For example `zeros(10000) == 5803`

and `est_zeros == 5814`

.

allzero digits in a factorial in base ten, including but not limited to the zero digits at theendof the factorial? Also, what is the range of possible values of`n`

when examining`n!`

? – Rory Daulton May 21 at 11:21