I can only think of

```
a.mod(n).multiply(b.mod(n)).mod(n)
```

and you seem already to be aware of this.

`BigInteger`

has a `toByteArray()`

but internally `int`

s are used. hence n must be quite large to have an effect. Maybe in key generation cryptographic code there might be such work.

Furhtermore, if you think of short-cutting the multiplication, you'll get something like the following:

```
public static BigInteger multiply(BigInteger a, BigInteger b, int mod) {
if (a.signum() == -1) {
return multiply(a.negate(), b, mod).negate();
}
if (b.signum() == -1) {
return multiply(a, b.negate(), mod).negate();
}
int n = (Integer.bitCount(mod - 1) + 7) / 8; // mod in bytes.
byte[] aa = a.toByteArray(); // Highest byte at [0] !!
int na = Math.min(n, aa.length); // Heuristic.
byte[] bb = b.toByteArray();
int nb = Math.min(n, bb.length); // Heuristic.
byte[] prod = new byte[n];
for (int ia = 0; ia < na; ++ia) {
int m = ia + nb >= n ? n - ia - 1 : nb; // Heuristic.
for (int ib = 0; ib < m; ++ib) {
int p = (0xFF & aa[aa.length - 1 - ia]) * (0xFF & bb[bb.length - 1 - ib]);
addByte(prod, ia + ib, p & 0xFF);
if (ia + ib + 1 < n) {
addByte(prod, ia + ib + 1, (p >> 8) & 0xFF);
}
}
}
// Still need to do an expensive mod:
return new BigInteger(prod).mod(BigInteger.valueOf(mod));
}
private static void addByte(byte[] prod, int i, int value) {
while (value != 0 && i < prod.length) {
value += prod[prod.length - 1 - i] & 0xFF;
prod[prod.length - 1 - i] = (byte) value;
value >>= 8;
++i;
}
}
```

That code does not look appetizing. BigInteger has the problem of exposing the internal value only as big-endian `byte[]`

where the first byte is the most significant one.

**Much better would be to have the digits in base N.** That is not unimaginable: if N is a power of 2 some nice optimizations are feasible.

*(BTW the code is untested - as it does not seem convincingly faster.)*