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/*
* Number Theory Functions
* (C) 1999-2011 Jack Lloyd
*
* Botan is released under the Simplified BSD License (see license.txt)
*/
#include <botan/numthry.h>
#include <botan/reducer.h>
#include <botan/internal/bit_ops.h>
#include <botan/internal/mp_core.h>
#include <algorithm>
namespace Botan {
/*
* Return the number of 0 bits at the end of n
*/
size_t low_zero_bits(const BigInt& n)
{
size_t low_zero = 0;
if(n.is_positive() && n.is_nonzero())
{
for(size_t i = 0; i != n.size(); ++i)
{
const word x = n.word_at(i);
if(x)
{
low_zero += ctz(x);
break;
}
else
low_zero += BOTAN_MP_WORD_BITS;
}
}
return low_zero;
}
/*
* Calculate the GCD
*/
BigInt gcd(const BigInt& a, const BigInt& b)
{
if(a.is_zero() || b.is_zero()) return 0;
if(a == 1 || b == 1) return 1;
BigInt x = a, y = b;
x.set_sign(BigInt::Positive);
y.set_sign(BigInt::Positive);
size_t shift = std::min(low_zero_bits(x), low_zero_bits(y));
x >>= shift;
y >>= shift;
while(x.is_nonzero())
{
x >>= low_zero_bits(x);
y >>= low_zero_bits(y);
if(x >= y) { x -= y; x >>= 1; }
else { y -= x; y >>= 1; }
}
return (y << shift);
}
/*
* Calculate the LCM
*/
BigInt lcm(const BigInt& a, const BigInt& b)
{
return ((a * b) / gcd(a, b));
}
namespace {
/*
* If the modulus is odd, then we can avoid computing A and C. This is
* a critical path algorithm in some instances and an odd modulus is
* the common case for crypto, so worth special casing. See note 14.64
* in Handbook of Applied Cryptography for more details.
*/
BigInt inverse_mod_odd_modulus(const BigInt& n, const BigInt& mod)
{
BigInt u = mod, v = n;
BigInt B = 0, D = 1;
while(u.is_nonzero())
{
const size_t u_zero_bits = low_zero_bits(u);
u >>= u_zero_bits;
for(size_t i = 0; i != u_zero_bits; ++i)
{
if(B.is_odd())
{ B -= mod; }
B >>= 1;
}
const size_t v_zero_bits = low_zero_bits(v);
v >>= v_zero_bits;
for(size_t i = 0; i != v_zero_bits; ++i)
{
if(D.is_odd())
{ D -= mod; }
D >>= 1;
}
if(u >= v) { u -= v; B -= D; }
else { v -= u; D -= B; }
}
if(v != 1)
return 0; // no modular inverse
while(D.is_negative()) D += mod;
while(D >= mod) D -= mod;
return D;
}
}
/*
* Find the Modular Inverse
*/
BigInt inverse_mod(const BigInt& n, const BigInt& mod)
{
if(mod.is_zero())
throw BigInt::DivideByZero();
if(mod.is_negative() || n.is_negative())
throw Invalid_Argument("inverse_mod: arguments must be non-negative");
if(n.is_zero() || (n.is_even() && mod.is_even()))
return 0; // fast fail checks
if(mod.is_odd())
return inverse_mod_odd_modulus(n, mod);
BigInt u = mod, v = n;
BigInt A = 1, B = 0, C = 0, D = 1;
while(u.is_nonzero())
{
const size_t u_zero_bits = low_zero_bits(u);
u >>= u_zero_bits;
for(size_t i = 0; i != u_zero_bits; ++i)
{
if(A.is_odd() || B.is_odd())
{ A += n; B -= mod; }
A >>= 1; B >>= 1;
}
const size_t v_zero_bits = low_zero_bits(v);
v >>= v_zero_bits;
for(size_t i = 0; i != v_zero_bits; ++i)
{
if(C.is_odd() || D.is_odd())
{ C += n; D -= mod; }
C >>= 1; D >>= 1;
}
if(u >= v) { u -= v; A -= C; B -= D; }
else { v -= u; C -= A; D -= B; }
}
if(v != 1)
return 0; // no modular inverse
while(D.is_negative()) D += mod;
while(D >= mod) D -= mod;
return D;
}
word monty_inverse(word input)
{
word b = input;
word x2 = 1, x1 = 0, y2 = 0, y1 = 1;
// First iteration, a = n+1
word q = bigint_divop(1, 0, b);
word r = (MP_WORD_MAX - q*b) + 1;
word x = x2 - q*x1;
word y = y2 - q*y1;
word a = b;
b = r;
x2 = x1;
x1 = x;
y2 = y1;
y1 = y;
while(b > 0)
{
q = a / b;
r = a - q*b;
x = x2 - q*x1;
y = y2 - q*y1;
a = b;
b = r;
x2 = x1;
x1 = x;
y2 = y1;
y1 = y;
}
// Now invert in addition space
y2 = (MP_WORD_MAX - y2) + 1;
return y2;
}
/*
* Modular Exponentiation
*/
BigInt power_mod(const BigInt& base, const BigInt& exp, const BigInt& mod)
{
Power_Mod pow_mod(mod);
/*
* Calling set_base before set_exponent means we end up using a
* minimal window. This makes sense given that here we know that any
* precomputation is wasted.
*/
pow_mod.set_base(base);
pow_mod.set_exponent(exp);
return pow_mod.execute();
}
namespace {
bool mr_witness(BigInt&& y,
const Modular_Reducer& reducer_n,
const BigInt& n_minus_1, size_t s)
{
if(y == 1 || y == n_minus_1)
return false;
for(size_t i = 1; i != s; ++i)
{
y = reducer_n.square(y);
if(y == 1) // found a non-trivial square root
return true;
if(y == n_minus_1) // -1, trivial square root, so give up
return false;
}
return true; // fails Fermat test
}
size_t mr_test_iterations(size_t n_bits, size_t prob, bool random)
{
const size_t base = (prob + 2) / 2; // worst case 4^-t error rate
/*
* For randomly chosen numbers we can use the estimates from
* http://www.math.dartmouth.edu/~carlp/PDF/paper88.pdf
*
* These values are derived from the inequality for p(k,t) given on
* the second page.
*/
if(random && prob <= 80)
{
if(n_bits >= 1536)
return 2; // < 2^-89
if(n_bits >= 1024)
return 4; // < 2^-89
if(n_bits >= 512)
return 5; // < 2^-80
if(n_bits >= 256)
return 11; // < 2^-80
}
return base;
}
}
/*
* Test for primaility using Miller-Rabin
*/
bool is_prime(const BigInt& n, RandomNumberGenerator& rng,
size_t prob, bool is_random)
{
if(n == 2)
return true;
if(n <= 1 || n.is_even())
return false;
// Fast path testing for small numbers (<= 65521)
if(n <= PRIMES[PRIME_TABLE_SIZE-1])
{
const u16bit num = n.word_at(0);
return std::binary_search(PRIMES, PRIMES + PRIME_TABLE_SIZE, num);
}
const size_t test_iterations = mr_test_iterations(n.bits(), prob, is_random);
const BigInt n_minus_1 = n - 1;
const size_t s = low_zero_bits(n_minus_1);
Fixed_Exponent_Power_Mod pow_mod(n_minus_1 >> s, n);
Modular_Reducer reducer(n);
for(size_t i = 0; i != test_iterations; ++i)
{
const BigInt a = BigInt::random_integer(rng, 2, n_minus_1);
const BigInt y = pow_mod(a);
if(mr_witness(std::move(y), reducer, n_minus_1, s))
return false;
}
return true;
}
}
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