# Restore a number from several its remainders (chinese remainder theorem)

I have a long integer number, but it is stored not in decimal form, but as set of remainders.

So, I have not the `N` number, but set of such remainders:

``````r_1 = N % 2147483743
r_2 = N % 2147483713
r_3 = N % 2147483693
r_4 = N % 2147483659
r_5 = N % 2147483647
r_6 = N % 2147483629
``````

I know, that N is less than multiplication of these primes, so chinese remainder theorem does work here ( http://en.wikipedia.org/wiki/Chinese_remainder_theorem ).

How can I restore `N` in decimal, if I have this 6 remainders? The wonderful will be any program to do this (C/C+GMP/C++/perl/java/bc).

For example, what minimal N can have this set of remainders:

``````r_1 = 1246736738 (% 2147483743)
r_2 = 748761 (% 2147483713)
r_3 = 1829651881 (% 2147483693)
r_4 = 2008266397 (% 2147483659)
r_5 = 748030137 (% 2147483647)
r_6 = 1460049539 (% 2147483629)
``````
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What? no `dc`? Oh, well ... +1 for `bc` :) –  pmg Mar 13 '11 at 2:13
Why `-1` click? –  osgx Mar 13 '11 at 3:27

The article you link already provides a constructive algorithm to find the solution.

Basically, for each `i` you solve integer equation `ri*ni + si*(N/ni) = 1` where `N = n1*n2*n3*...`. The `ri` and `si` are unknowns here. This can be solved by extended euclidean algorithm. It's very popular and you'll have no problem finding sample implementations in any language.

Then, assuming `ei = si*(N/ni)`, the answer is `sum(ei*ai)` for every `i`.
All this is described in that article, with proof and example.

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But I can't program this algorithm. Can you help? –  osgx Mar 13 '11 at 2:15
@osgx What exactly is the difficulty? Most people here are busy enough and won't write the complete solution for you, but they might help with specific problem areas. –  Nikita Rybak Mar 13 '11 at 2:23

Here the code (C+GMP), based on this LGPL code of Garner algorithm http://www.google.com/codesearch/p?hl=en#GyFNtt_2yyI/guru/indexcalculus.c&q=garner%20mpz_t&sa=N&cd=2&ct=rc&l=38 ( git://github.com/blynn/pbc.git›guru›indexcalculus.c )

Compile with `gcc -std=c99 -lgmp`. Also change size for your case.

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

// Garner's Algorithm.
// See Algorithm 14.71, Handbook of Cryptography.

//    x - result    v residuals    m - primes   t-size of vectors
static void CRT(mpz_t x, mpz_ptr *v, mpz_ptr *m, int t) {
mpz_t u;
mpz_t C[t];
int i, j;

mpz_init(u);
for (i=1; i<t; i++) {
mpz_init(C[i]);
mpz_set_ui(C[i], 1);
for (j=0; j<i; j++) {
mpz_invert(u, m[j], m[i]);
mpz_mul(C[i], C[i], u);
mpz_mod(C[i], C[i], m[i]);
}
}
mpz_set(u, v[0]);
mpz_set(x, u);
for (i=1; i<t; i++) {
mpz_sub(u, v[i], x);
mpz_mul(u, u, C[i]);
mpz_mod(u, u, m[i]);
for (j=0; j<i; j++) {
mpz_mul(u, u, m[j]);
}
}

for (i=1; i<t; i++) mpz_clear(C[i]);
mpz_clear(u);
}

const int size=6; // Change this please

int main()
{
mpz_t res;
mpz_ptr t[size], p[size];
for(int i=0;i<size;i++) {
t[i]=(mpz_ptr)malloc(sizeof(mpz_t));
p[i]=(mpz_ptr)malloc(sizeof(mpz_t));
mpz_init(p[i]);
mpz_init(t[i]);
}
mpz_init(res);

for(int i=0;i<size;i++){
unsigned long rr,pp;
scanf("%*c%*c%*c = %lu (%% %lu)\n",&rr,&pp);
printf("Got %lu res on mod %% %lu \n",rr,pp);
mpz_set_ui(p[i],pp);
mpz_set_ui(t[i],rr);
}

CRT(res,t,p,size);

gmp_printf("N = %Zd\n", res);
}
``````

Example is solved:

``````\$ ./a.out
r_1 = 1246736738 (% 2147483743)
r_2 = 748761 (% 2147483713)
r_3 = 1829651881 (% 2147483693)
r_4 = 2008266397 (% 2147483659)
r_5 = 748030137 (% 2147483647)
r_6 = 1460049539 (% 2147483629)

Got 1246736738 res on mod % 2147483743
Got 748761 res on mod % 2147483713
Got 1829651881 res on mod % 2147483693
Got 2008266397 res on mod % 2147483659
Got 748030137 res on mod % 2147483647
Got 1460049539 res on mod % 2147483629
N = 703066055325632897509116263399480311
``````

N is 703066055325632897509116263399480311

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