# Last nonzero digit of a factorial

I want to determine the last nonzero digit of a factorial.

I tried to solve it using division: Dividing the number by 10 or multiples thereof.

``````Ex : 7! = 5040 => 4
``````

So I divide 5040 by 10 and get 4 as result.

But, let us say, we should use the number 7 in the logic instead of value of the factorial (5040).

Please let me know how can I do it?

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Think of this: - How do you get a zero at the end of some multiplication? Remove them and multiply the rest number to get the last non-zero digit. – Rohit Jain Nov 2 '12 at 13:17
How do you handle multiples of 5? – Aki Suihkonen Nov 2 '12 at 13:19
Is this a Project Euler problem? I feel like I've solved this before, but the solution is buried in my big folder of PE code. – Kevin Nov 2 '12 at 14:10
@Kevin I have been asked this one in interview and i replied by dividing with ten or multiples of the same .. The panel has asked assume you were given a number which factorial value cannot be hold in any java datatypes .. – Mahiz Nov 2 '12 at 14:14

1. Compute the prime decomposition of n! as follows:
• for each prime `p` <= `n`, the exponent of p is
$\sum_{i=1}^{p^i\le n}{\left\lfloor\frac{n}{p^i}\right\rfloor}$
2. Subtract the exponent of `5` from the exponent of `2` and discard all the fives from the prime decomposition.
3. Multiply the remaining prime decomposition modulo 10. Note that when doing this, you can use the following equivalence: $p^{i+1}\bmod 10\equiv (p\bmod 10)^{(i\bmod 4)+1}$ (for i ≥ 0). The individual products can also be done mod 10 if necessary.

I used a bit of spare time to implement this solution in bash. (bash? well, why not?):

``````last_nonzero () {
local n=\$1
local d=\$(power_mod_10 3 \$(count_factors \$n 3))
d=\$((d * \$(power_mod_10 2 \$((\$(count_factors \$n 2)
- \$(count_factors \$n 5))))))
for p in \$(primes 7 \$n)
do
d=\$((d * \$(power_mod_10 \$p \$(count_factors \$n \$p)) % 10))
done
echo \$d
}

count_factors () {
local n=\$1 p=\$2
local d=\$((n/p))
local q=\$d
while ((q >= p)); do
q=\$((q/p)) d=\$((d+q))
done
echo \$d
}

power_mod_10 () {
local mods=..........0161000101012300070901490009010187000309
local p=\$((\$1%10)) exp=\$((\$2%4+1))
echo \${mods:\$exp\$p:1}
}
``````

Yes, the last one is a hack.

Also: There is an even better recursive solution. Search http://math.stackexchange.com, or even google.

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+1 because this works, but 1) is not very clear. – phant0m Nov 2 '12 at 14:32
@AkiSuihkonen: that's step 2, which removes all of the powers of 10, leaving the remaining powers of 2. Since what remains has no powers of 5, it's safe to simply do the product mod 10. – rici Nov 2 '12 at 14:32
@phant0m: how do you insert mathML into an answer? – rici Nov 2 '12 at 14:33
You can't, you have to use an online editor such as this one and include it as a picture. – phant0m Nov 2 '12 at 14:34
I believe the explanation (part 1) is too thick for me, but there's perhaps another way to think it: multiplying by 5 means multiplying by 10 and dividing by 2. Also the number of powers of two is always larger than the number of powers of 5. Thus for every occurance of powers of 5, one can as well not multiply by a power of two. – Aki Suihkonen Nov 2 '12 at 14:38

One needs to keep more than 1 number when the next (modified) number ends with 5.

The first such location comes at 15!, when 14! = 87178291200, and 2*15=30 but 15! = 1307674368000. Instead 12*15 = 180, which gives the correct result.

EDIT: but even adding the digits to two is not enough for a generic case, at 25! one would need 3 last digits of 24! = 936 to get the correct answer, which means that in the end this approach doesn't stand the heat.

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Hoist by your own petard, I think. 25! – rici Nov 2 '12 at 13:53
@rici, I was thinking the same thing. It seems like you can't say, "storing x digits are sufficient for any size factorial". If you're calculating (5^k)! or higher, I suspect you need more than k digits. – Kevin Nov 2 '12 at 14:06
@kevin: you only need one digit, but you also need the difference between the power of 2 and the power of 5 in the prime decomposition of the factorial. (That's easy to compute from `n`, though.) The digit you keep isn't exactly the last non-zero digit, though. – rici Nov 2 '12 at 14:13
For 5^5 one needs 5 digits, but does it go on forever? (for 5^3 and 5^4) 2 or 3 digits are enough... So, the question is if there are shortcuts: is it enough to track the number of powers of 5 modulo 5 perhaps? – Aki Suihkonen Nov 2 '12 at 14:23
@AkiSuihkonen: it's sufficient to track the difference between the number of powers of 5 and the number of powers of 2, and also keep one digit, as I hinted above. However, think outside the box! or see my answer... – rici Nov 2 '12 at 14:27

Lets say D(N) denotes the last non zero digit of factorial, then

D(N)=4*D[N/5]*D(Unit digit of N)[If tens digit of N is odd] D(N)=6*D[N/5]*D(Unit digit of N)[If tens digit of N is even]; Where [N/5] is greatest Integer Function and D(1)=1 D(2)=2 D(3)=6 D(4)=4 D(5)=2 D(6)=2 D(7)=4 D(8)=2 D(9)=8

e.g. D(26)=6*D[26/5]*D(6)=6*D(5)*D(6)=6*2*2=4[D(5) means last non zero digit of 5!=120 which is 2, same for D(6)] D(33)=4*D[33/5]*D(3)=4*D(6)*D(3)=4*2*6=8

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confirmed for N = 1 through 100000 – Tom Sirgedas Jul 16 '13 at 19:41