# What is the simplest way of implementing bigint in C?

I am trying to calculate 100!

I am looking for the simplest way to accomplish this using C. I have read around but have not found a concrete answer.

If you must know, I program in Xcode in Mac os X.

Thanks!

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there you go: 933[100 digits removed]00000 :-) – Anders K. Jul 27 '10 at 3:24
@Anders: This website is Stack Overflow, not Comment Overflow! :-O – James McNellis Jul 27 '10 at 3:25
lol so true :-) – Anders K. Jul 27 '10 at 3:28
lol, I know I can get the value from like wolframalpha. However, I am learning C and wanted to know how this could be done. – alexBrand Jul 27 '10 at 3:33
Duplicate of "BigInt" in C? – outis Jul 11 '11 at 5:32

If you're looking for a simple library, libtommath (from libtomcrypt) is probably what you want.

If you're looking to write a simple implementation yourself (either as a learning exercise or because you only need a very limited subset of bigint functionality and don't want to tack on a dependency to a large library, namespace pollution, etc.), then I might suggest the following for your problem:

Since you can bound the size of the result based on `n`, simply pre-allocate an array of `uint32_t` of the required size to hold the result. I'm guessing you'll want to print the result, so it makes sense to use a base that's a power of 10 (i.e. base 1000000000) rather than a power of 2. That is to say, each element of your array is allowed to hold a value between 0 and 999999999.

To multiply this number by a (normal, non-big) integer `n`, do something like:

``````uint32_t carry=0;
for(i=0; i<len; i++) {
uint64_t tmp = n*(uint64_t)big[i] + carry;
big[i] = tmp % 1000000000;
carry = tmp / 1000000000;
}
if (carry) big[len++] = carry;
``````

If you know `n` will never be bigger than 100 (or some other small number) and want to avoid going into the 64-bit range (or if you're on a 64-bit platform and want to use `uint64_t` for your bigint array), then make the base a smaller power of 10 so that the multiplication result will always fit in the type.

Now, printing the result is just something like:

``````printf("%lu", (long)big[len-1]);
for(i=len-1; i; i--) printf("%.9lu", (long)big[i-1]);
putchar('\n');
``````

If you want to use a power of 2 as the base, rather than a power of 10, the multiplication becomes much faster:

``````uint32_t carry=0;
for(i=0; i<len; i++) {
uint64_t tmp = n*(uint64_t)big[i] + carry;
big[i] = tmp;
carry = tmp >> 32;
}
if (carry) big[len++] = carry;
``````

However, printing your result in decimal will not be so pleasant... :-) Of course if you want the result in hex, then it's easy:

``````printf("%lx", (long)big[len-1]);
for(i=len-1; i; i--) printf("%.8lx", (long)big[i-1]);
putchar('\n');
``````

Hope this helps! I'll leave implementing other things (like addition, multiplication of 2 bigints, etc) as an exercise for you. Just think back to how you learned to do base-10 addition, multiplication, division, etc. in grade school and teach the computer how to do that (but in base-10^9 or base-2^32 instead) and you should have no problem.

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One comment on the 64-bit types on 32-bit targets: on any sane hardware, a 32x32 multiply inherently generates a 64-bit result, so there is nothing inefficient about casting to a type larger than the system word size. The compiler will generate the correct 32x32->64 multiply instruction if it exists. And at least on i386, 64/32->32 division (when the upper 32 bits are less than the divisor) is an inherent feature of the 32-bit divide instruction, and does not require emulation in software by the compiler. On less intelligent 32-bit targets you might want to use 16-bit units though.. – R.. Jul 27 '10 at 7:17
Doing a library call instead of inlining the whole operation on every instance, which the compiler in my experience always does with 64-bit builtin-operations on a 32-bit platform, may bloat the code size; though the inlined operation will most probably be faster. This is an issue I've encountered many times on 32-bit embedded ARM-platforms. – Morten Jensen Jun 30 '15 at 18:39

If you're willing to use a library implementation the standard one seems to be GMP

``````mpz_t out;
mpz_init(out);
mpz_fac_ui(out,100);
mpz_out_str(stdout,10,out);
``````

should calculate 100! from looking at the docs.

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You can also use OpenSSL bn; it is already installed in Mac OS X.

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You asked for the simplest way to do this. So, here you go:

``````#include <gmp.h>
#include <stdio.h>

int main(int argc, char** argv) {
mpz_t mynum;
mpz_init(mynum);
int i;
for (i = 99; i > 1; i--) {
mpz_mul_si(mynum, mynum, (long)i);
}
mpz_out_str(stdout, 10, mynum);
return 0;
}
``````

I tested this code and it gives the correct answer.

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A link would have been nice. – Matt Joiner Jul 27 '10 at 7:11
There's one in Scott's answer. – JeremyP Jul 27 '10 at 13:16
How do you know it's a correct answer? – Tomasz Posłuszny Dec 15 '13 at 0:10