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/**
* (C) Copyright Projet SECRET, INRIA, Rocquencourt
* (C) Bhaskar Biswas and Nicolas Sendrier
*
* (C) 2014 cryptosource GmbH
* (C) 2014 Falko Strenzke fstrenzke@cryptosource.de
*/
#include <botan/gf2m_small_m.h>
#include <botan/code_based_util.h>
#include <string>
namespace Botan {
namespace gf2m_small_m {
#define MAX_EXT_DEG 16
namespace {
unsigned int prim_poly[MAX_EXT_DEG + 1] = {
01, /* extension degree 0 (!) never used */
03, /* extension degree 1 (!) never used */
07, /* extension degree 2 */
013, /* extension degree 3 */
023, /* extension degree 4 */
045, /* extension degree 5 */
0103, /* extension degree 6 */
0203, /* extension degree 7 */
0435, /* extension degree 8 */
01041, /* extension degree 9 */
02011, /* extension degree 10 */
04005, /* extension degree 11 */
010123, /* extension degree 12 */
020033, /* extension degree 13 */
042103, /* extension degree 14 */
0100003, /* extension degree 15 */
0210013 /* extension degree 16 */
};
}
u32bit encode_gf2m(gf2m to_enc, byte* mem)
{
mem[0] = to_enc >> 8;
mem[1] = to_enc & 0xFF;
return sizeof(to_enc);
}
gf2m decode_gf2m(const byte* mem)
{
gf2m result;
result = mem[0] << 8;
result |= mem[1];
return result;
}
// construct the table gf_exp[i]=alpha^i
void Gf2m_Field::init_exp()
{
m_gf_exp_table.resize(1 << get_extension_degree());
m_gf_exp_table[0] = 1;
for(size_t i = 1; i < gf_ord(); ++i)
{
m_gf_exp_table[i] = m_gf_exp_table[i - 1] << 1;
if (m_gf_exp_table[i - 1] & (1 << (get_extension_degree()-1)))
{
m_gf_exp_table[i] ^= prim_poly[get_extension_degree()];
}
}
// hack for the multiplication
m_gf_exp_table[gf_ord()] = 1;
}
// construct the table gf_log[alpha^i]=i
void Gf2m_Field::init_log()
{
m_gf_log_table.resize(1 << get_extension_degree());
m_gf_log_table[0] = gf_ord(); // log of 0 par convention
for (size_t i = 0; i < gf_ord() ; ++i)
{
m_gf_log_table[m_gf_exp_table[i]] = i;
}
}
Gf2m_Field::Gf2m_Field(size_t extdeg)
{
if(extdeg < 2 || extdeg > MAX_EXT_DEG)
throw std::runtime_error("Gf2m_Field does not support degree " + std::to_string(extdeg));
m_gf_extension_degree = extdeg;
m_gf_cardinality = 1 << extdeg;
m_gf_multiplicative_order = m_gf_cardinality - 1;
init_exp();
init_log();
}
gf2m Gf2m_Field::gf_div(gf2m x, gf2m y)
{
s32bit sub_res = ((s32bit)m_gf_log_table[x]) - ((s32bit) m_gf_log_table[y]);
s32bit modq_res = ((s32bit)_gf_modq_1(sub_res));
s32bit div_res = (((s32bit)x) ? ((s32bit) m_gf_exp_table[modq_res]) : 0 );
return (gf2m) div_res;
}
// we suppose i >= 0. Par convention 0^0 = 1
gf2m Gf2m_Field::gf_pow(gf2m x, int i)
{
if (i == 0)
return 1;
else if (x == 0)
return 0;
else
{
// i mod (q-1)
while (i >> get_extension_degree())
i = (i & (gf_ord())) + (i >> get_extension_degree());
i *= m_gf_log_table[x];
while (i >> get_extension_degree())
i = (i & (gf_ord())) + (i >> get_extension_degree());
return m_gf_exp_table[i];
}
}
}
}
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