blob: 656f979e5f311db1bbd1b01d5e47e34147af7822 [file] [log] [blame]
/*
* Copyright (C) 2012 Michael Brown <mbrown@fensystems.co.uk>.
*
* This program is free software; you can redistribute it and/or
* modify it under the terms of the GNU General Public License as
* published by the Free Software Foundation; either version 2 of the
* License, or any later version.
*
* This program is distributed in the hope that it will be useful, but
* WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
* General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA
* 02110-1301, USA.
*
* You can also choose to distribute this program under the terms of
* the Unmodified Binary Distribution Licence (as given in the file
* COPYING.UBDL), provided that you have satisfied its requirements.
*/
FILE_LICENCE ( GPL2_OR_LATER_OR_UBDL );
#include <stdint.h>
#include <string.h>
#include <assert.h>
#include <ipxe/profile.h>
#include <ipxe/bigint.h>
/** @file
*
* Big integer support
*/
/** Modular multiplication overall profiler */
static struct profiler bigint_mod_multiply_profiler __profiler =
{ .name = "bigint_mod_multiply" };
/** Modular multiplication multiply step profiler */
static struct profiler bigint_mod_multiply_multiply_profiler __profiler =
{ .name = "bigint_mod_multiply.multiply" };
/** Modular multiplication rescale step profiler */
static struct profiler bigint_mod_multiply_rescale_profiler __profiler =
{ .name = "bigint_mod_multiply.rescale" };
/** Modular multiplication subtract step profiler */
static struct profiler bigint_mod_multiply_subtract_profiler __profiler =
{ .name = "bigint_mod_multiply.subtract" };
/**
* Conditionally swap big integers (in constant time)
*
* @v first0 Element 0 of big integer to be conditionally swapped
* @v second0 Element 0 of big integer to be conditionally swapped
* @v size Number of elements in big integers
* @v swap Swap first and second big integers
*/
void bigint_swap_raw ( bigint_element_t *first0, bigint_element_t *second0,
unsigned int size, int swap ) {
bigint_element_t mask;
bigint_element_t xor;
unsigned int i;
/* Construct mask */
mask = ( ( bigint_element_t ) ( ! swap ) - 1 );
/* Conditionally swap elements */
for ( i = 0 ; i < size ; i++ ) {
xor = ( mask & ( first0[i] ^ second0[i] ) );
first0[i] ^= xor;
second0[i] ^= xor;
}
}
/**
* Perform modular multiplication of big integers
*
* @v multiplicand0 Element 0 of big integer to be multiplied
* @v multiplier0 Element 0 of big integer to be multiplied
* @v modulus0 Element 0 of big integer modulus
* @v result0 Element 0 of big integer to hold result
* @v size Number of elements in base, modulus, and result
* @v tmp Temporary working space
*/
void bigint_mod_multiply_raw ( const bigint_element_t *multiplicand0,
const bigint_element_t *multiplier0,
const bigint_element_t *modulus0,
bigint_element_t *result0,
unsigned int size, void *tmp ) {
const bigint_t ( size ) __attribute__ (( may_alias )) *multiplicand =
( ( const void * ) multiplicand0 );
const bigint_t ( size ) __attribute__ (( may_alias )) *multiplier =
( ( const void * ) multiplier0 );
const bigint_t ( size ) __attribute__ (( may_alias )) *modulus =
( ( const void * ) modulus0 );
bigint_t ( size ) __attribute__ (( may_alias )) *result =
( ( void * ) result0 );
struct {
bigint_t ( size * 2 ) result;
bigint_t ( size * 2 ) modulus;
} *temp = tmp;
int rotation;
int i;
/* Start profiling */
profile_start ( &bigint_mod_multiply_profiler );
/* Sanity check */
assert ( sizeof ( *temp ) == bigint_mod_multiply_tmp_len ( modulus ) );
/* Perform multiplication */
profile_start ( &bigint_mod_multiply_multiply_profiler );
bigint_multiply ( multiplicand, multiplier, &temp->result );
profile_stop ( &bigint_mod_multiply_multiply_profiler );
/* Rescale modulus to match result */
profile_start ( &bigint_mod_multiply_rescale_profiler );
bigint_grow ( modulus, &temp->modulus );
rotation = ( bigint_max_set_bit ( &temp->result ) -
bigint_max_set_bit ( &temp->modulus ) );
for ( i = 0 ; i < rotation ; i++ )
bigint_rol ( &temp->modulus );
profile_stop ( &bigint_mod_multiply_rescale_profiler );
/* Subtract multiples of modulus */
profile_start ( &bigint_mod_multiply_subtract_profiler );
for ( i = 0 ; i <= rotation ; i++ ) {
if ( bigint_is_geq ( &temp->result, &temp->modulus ) )
bigint_subtract ( &temp->modulus, &temp->result );
bigint_ror ( &temp->modulus );
}
profile_stop ( &bigint_mod_multiply_subtract_profiler );
/* Resize result */
bigint_shrink ( &temp->result, result );
/* Sanity check */
assert ( bigint_is_geq ( modulus, result ) );
/* Stop profiling */
profile_stop ( &bigint_mod_multiply_profiler );
}
/**
* Perform modular exponentiation of big integers
*
* @v base0 Element 0 of big integer base
* @v modulus0 Element 0 of big integer modulus
* @v exponent0 Element 0 of big integer exponent
* @v result0 Element 0 of big integer to hold result
* @v size Number of elements in base, modulus, and result
* @v exponent_size Number of elements in exponent
* @v tmp Temporary working space
*/
void bigint_mod_exp_raw ( const bigint_element_t *base0,
const bigint_element_t *modulus0,
const bigint_element_t *exponent0,
bigint_element_t *result0,
unsigned int size, unsigned int exponent_size,
void *tmp ) {
const bigint_t ( size ) __attribute__ (( may_alias )) *base =
( ( const void * ) base0 );
const bigint_t ( size ) __attribute__ (( may_alias )) *modulus =
( ( const void * ) modulus0 );
const bigint_t ( exponent_size ) __attribute__ (( may_alias ))
*exponent = ( ( const void * ) exponent0 );
bigint_t ( size ) __attribute__ (( may_alias )) *result =
( ( void * ) result0 );
size_t mod_multiply_len = bigint_mod_multiply_tmp_len ( modulus );
struct {
bigint_t ( size ) base;
bigint_t ( exponent_size ) exponent;
uint8_t mod_multiply[mod_multiply_len];
} *temp = tmp;
static const uint8_t start[1] = { 0x01 };
memcpy ( &temp->base, base, sizeof ( temp->base ) );
memcpy ( &temp->exponent, exponent, sizeof ( temp->exponent ) );
bigint_init ( result, start, sizeof ( start ) );
while ( ! bigint_is_zero ( &temp->exponent ) ) {
if ( bigint_bit_is_set ( &temp->exponent, 0 ) ) {
bigint_mod_multiply ( result, &temp->base, modulus,
result, temp->mod_multiply );
}
bigint_ror ( &temp->exponent );
bigint_mod_multiply ( &temp->base, &temp->base, modulus,
&temp->base, temp->mod_multiply );
}
}