/* * Modular Reducer * (C) 1999-2011 Jack Lloyd * * Botan is released under the Simplified BSD License (see license.txt) */ #include #include namespace Botan { /* * Modular_Reducer Constructor */ Modular_Reducer::Modular_Reducer(const BigInt& mod) { if(mod <= 0) throw Invalid_Argument("Modular_Reducer: modulus must be positive"); modulus = mod; mod_words = modulus.sig_words(); modulus_2 = Botan::square(modulus); mu = BigInt::power_of_2(2 * MP_WORD_BITS * mod_words) / modulus; } /* * Barrett Reduction */ BigInt Modular_Reducer::reduce(const BigInt& x) const { if(mod_words == 0) throw Invalid_State("Modular_Reducer: Never initalized"); if(x.cmp(modulus, false) < 0) { if(x.is_negative()) return x + modulus; // make positive return x; } else if(x.cmp(modulus_2, false) < 0) { BigInt t1 = x; t1.set_sign(BigInt::Positive); t1 >>= (MP_WORD_BITS * (mod_words - 1)); t1 *= mu; t1 >>= (MP_WORD_BITS * (mod_words + 1)); t1 *= modulus; t1.mask_bits(MP_WORD_BITS * (mod_words + 1)); BigInt t2 = x; t2.set_sign(BigInt::Positive); t2.mask_bits(MP_WORD_BITS * (mod_words + 1)); t2 -= t1; if(t2.is_negative()) { t2 += BigInt::power_of_2(MP_WORD_BITS * (mod_words + 1)); } while(t2 >= modulus) t2 -= modulus; if(x.is_positive()) return t2; else return (modulus - t2); } else { // too big, fall back to normal division return (x % modulus); } } }