#include <cmath>
#include <cstdio>
#include <vector>
#include <iostream>
#include <algorithm>
using namespace std;
long long choose_mod_two(long long n, long long k, long long p);
long long choose_mod_one(long long n, long long k, long long p);
long long invert_mod(long long k, long long m);
int main() {
int n;
cin >> n;
long long a[20];
long long b[20];
for (int i = 0; i < n; ++i)
{
cin >> a[i];
cin >> b[i];
}
for (int i = 0; i < n; ++i)
{
cout << choose_mod_one(a[i]-b[i]+1, b[i], 100003) << endl;
}
}
long long choose_mod_one(long long n, long long k, long long p)
{
// For small k, no recursion is necessary
if (k < p) return choose_mod_two(n,k,p);
long long q_n, r_n, q_k, r_k, choose;
q_n = n / p;
r_n = n % p;
q_k = k / p;
r_k = k % p;
choose = choose_mod_two(r_n, r_k, p);
// If the exponent of p in choose(n,k) isn't determined to be 0
// before the calculation gets serious, short-cut here:
/* if (choose == 0) return 0; */
choose *= choose_mod_one(q_n, q_k, p);
return choose % p;
}
// Preconditions: 0 <= k <= min(n,p-1); p > 1 prime
long long choose_mod_two(long long n, long long k, long long p)
{
// reduce n modulo p
n %= p;
// Trivial checks
if (n < k) return 0;
if (k == 0 || k == n) return 1;
// Now 0 < k < n, save a bit of work if k > n/2
if (k > n/2) k = n-k;
// calculate numerator and denominator modulo p
long long num = n, den = 1;
for(n = n-1; k > 1; --n, --k)
{
num = (num * n) % p;
den = (den * k) % p;
}
// Invert denominator modulo p
den = invert_mod(den,p);
return (num * den) % p;
}
long long invert_mod(long long k, long long m)
{
if (m == 0) return (k == 1 || k == -1) ? k : 0;
if (m < 0) m = -m;
k %= m;
if (k < 0) k += m;
int neg = 1;
long long p1 = 1, p2 = 0, k1 = k, m1 = m, q, r, temp;
while(k1 > 0) {
q = m1 / k1;
r = m1 % k1;
temp = q*p1 + p2;
p2 = p1;
p1 = temp;
m1 = k1;
k1 = r;
neg = !neg;
}
return neg ? m - p2 : p2;
}