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The One&Done attack, which is described in a paper to appear in the USENIX Security'18 conference, uses EM emanations to recover the values of the bits that are obtained using BN_is_bit_set while constructing the value of the window in BN_mod_exp_consttime. The EM signal changes slightly depending on the value of the bit, and since the lookup of a bit is surrounded by highly regular execution (constant-time Montgomery multiplications) the attack is able to isolate the (very brief) part of the signal that changes depending on the bit. Although the change is slight, the attack recovers it successfully >90% of the time on several phones and IoT devices (all with ARM processors with clock rates around 1GHz), so after only one RSA decryption more than 90% of the bits in d_p and d_q are recovered correctly, which enables rapid recovery of the full RSA key using an algorithm (also described in the paper) that modifies the branch-and-prune approach for a situation in which the exponents' bits are recovered with errors, i.e. where we do not know a priori which bits are correctly recovered. The mitigation for the attack is relatively simple - all the bits of the window are obtained at once, along with other bits so that an entire integer's worth of bits are obtained together using masking and shifts, without unnecessarily considering each bit in isolation. This improves performance somewhat (one call to bn_get_bits is faster than several calls to BN_is_bit_set), so the attacker now gets one signal snippet per window (rather than one per bit) in which the signal is affected by all bits in the integer (rather than just the one bit). Reviewed-by: Andy Polyakov <appro@openssl.org> Reviewed-by: Rich Salz <rsalz@openssl.org> (Merged from https://github.com/openssl/openssl/pull/6276) |
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|---|---|---|
| .. | ||
| asm | ||
| bn_add.c | ||
| bn_asm.c | ||
| bn_blind.c | ||
| bn_const.c | ||
| bn_ctx.c | ||
| bn_depr.c | ||
| bn_dh.c | ||
| bn_div.c | ||
| bn_err.c | ||
| bn_exp2.c | ||
| bn_exp.c | ||
| bn_gcd.c | ||
| bn_gf2m.c | ||
| bn_intern.c | ||
| bn_kron.c | ||
| bn_lcl.h | ||
| bn_lib.c | ||
| bn_mod.c | ||
| bn_mont.c | ||
| bn_mpi.c | ||
| bn_mul.c | ||
| bn_nist.c | ||
| bn_prime.c | ||
| bn_prime.h | ||
| bn_prime.pl | ||
| bn_print.c | ||
| bn_rand.c | ||
| bn_recp.c | ||
| bn_shift.c | ||
| bn_sqr.c | ||
| bn_sqrt.c | ||
| bn_srp.c | ||
| bn_word.c | ||
| bn_x931p.c | ||
| build.info | ||
| README.pod | ||
| rsaz_exp.c | ||
| rsaz_exp.h | ||
=pod
=head1 NAME
bn_mul_words, bn_mul_add_words, bn_sqr_words, bn_div_words,
bn_add_words, bn_sub_words, bn_mul_comba4, bn_mul_comba8,
bn_sqr_comba4, bn_sqr_comba8, bn_cmp_words, bn_mul_normal,
bn_mul_low_normal, bn_mul_recursive, bn_mul_part_recursive,
bn_mul_low_recursive, bn_sqr_normal, bn_sqr_recursive,
bn_expand, bn_wexpand, bn_expand2, bn_fix_top, bn_check_top,
bn_print, bn_dump, bn_set_max, bn_set_high, bn_set_low - BIGNUM
library internal functions
=head1 SYNOPSIS
#include <openssl/bn.h>
BN_ULONG bn_mul_words(BN_ULONG *rp, BN_ULONG *ap, int num, BN_ULONG w);
BN_ULONG bn_mul_add_words(BN_ULONG *rp, BN_ULONG *ap, int num,
BN_ULONG w);
void bn_sqr_words(BN_ULONG *rp, BN_ULONG *ap, int num);
BN_ULONG bn_div_words(BN_ULONG h, BN_ULONG l, BN_ULONG d);
BN_ULONG bn_add_words(BN_ULONG *rp, BN_ULONG *ap, BN_ULONG *bp,
int num);
BN_ULONG bn_sub_words(BN_ULONG *rp, BN_ULONG *ap, BN_ULONG *bp,
int num);
void bn_mul_comba4(BN_ULONG *r, BN_ULONG *a, BN_ULONG *b);
void bn_mul_comba8(BN_ULONG *r, BN_ULONG *a, BN_ULONG *b);
void bn_sqr_comba4(BN_ULONG *r, BN_ULONG *a);
void bn_sqr_comba8(BN_ULONG *r, BN_ULONG *a);
int bn_cmp_words(BN_ULONG *a, BN_ULONG *b, int n);
void bn_mul_normal(BN_ULONG *r, BN_ULONG *a, int na, BN_ULONG *b,
int nb);
void bn_mul_low_normal(BN_ULONG *r, BN_ULONG *a, BN_ULONG *b, int n);
void bn_mul_recursive(BN_ULONG *r, BN_ULONG *a, BN_ULONG *b, int n2,
int dna, int dnb, BN_ULONG *tmp);
void bn_mul_part_recursive(BN_ULONG *r, BN_ULONG *a, BN_ULONG *b,
int n, int tna, int tnb, BN_ULONG *tmp);
void bn_mul_low_recursive(BN_ULONG *r, BN_ULONG *a, BN_ULONG *b,
int n2, BN_ULONG *tmp);
void bn_sqr_normal(BN_ULONG *r, BN_ULONG *a, int n, BN_ULONG *tmp);
void bn_sqr_recursive(BN_ULONG *r, BN_ULONG *a, int n2, BN_ULONG *tmp);
void mul(BN_ULONG r, BN_ULONG a, BN_ULONG w, BN_ULONG c);
void mul_add(BN_ULONG r, BN_ULONG a, BN_ULONG w, BN_ULONG c);
void sqr(BN_ULONG r0, BN_ULONG r1, BN_ULONG a);
BIGNUM *bn_expand(BIGNUM *a, int bits);
BIGNUM *bn_wexpand(BIGNUM *a, int n);
BIGNUM *bn_expand2(BIGNUM *a, int n);
void bn_fix_top(BIGNUM *a);
void bn_check_top(BIGNUM *a);
void bn_print(BIGNUM *a);
void bn_dump(BN_ULONG *d, int n);
void bn_set_max(BIGNUM *a);
void bn_set_high(BIGNUM *r, BIGNUM *a, int n);
void bn_set_low(BIGNUM *r, BIGNUM *a, int n);
=head1 DESCRIPTION
This page documents the internal functions used by the OpenSSL
B<BIGNUM> implementation. They are described here to facilitate
debugging and extending the library. They are I<not> to be used by
applications.
=head2 The BIGNUM structure
typedef struct bignum_st BIGNUM;
struct bignum_st
{
BN_ULONG *d; /* Pointer to an array of 'BN_BITS2' bit chunks. */
int top; /* Index of last used d +1. */
/* The next are internal book keeping for bn_expand. */
int dmax; /* Size of the d array. */
int neg; /* one if the number is negative */
int flags;
};
The integer value is stored in B<d>, a malloc()ed array of words (B<BN_ULONG>),
least significant word first. A B<BN_ULONG> can be either 16, 32 or 64 bits
in size, depending on the 'number of bits' (B<BITS2>) specified in
C<openssl/bn.h>.
B<dmax> is the size of the B<d> array that has been allocated. B<top>
is the number of words being used, so for a value of 4, bn.d[0]=4 and
bn.top=1. B<neg> is 1 if the number is negative. When a B<BIGNUM> is
B<0>, the B<d> field can be B<NULL> and B<top> == B<0>.
B<flags> is a bit field of flags which are defined in C<openssl/bn.h>. The
flags begin with B<BN_FLG_>. The macros BN_set_flags(b, n) and
BN_get_flags(b, n) exist to enable or fetch flag(s) B<n> from B<BIGNUM>
structure B<b>.
Various routines in this library require the use of temporary
B<BIGNUM> variables during their execution. Since dynamic memory
allocation to create B<BIGNUM>s is rather expensive when used in
conjunction with repeated subroutine calls, the B<BN_CTX> structure is
used. This structure contains B<BN_CTX_NUM> B<BIGNUM>s, see
L<BN_CTX_start(3)>.
=head2 Low-level arithmetic operations
These functions are implemented in C and for several platforms in
assembly language:
bn_mul_words(B<rp>, B<ap>, B<num>, B<w>) operates on the B<num> word
arrays B<rp> and B<ap>. It computes B<ap> * B<w>, places the result
in B<rp>, and returns the high word (carry).
bn_mul_add_words(B<rp>, B<ap>, B<num>, B<w>) operates on the B<num>
word arrays B<rp> and B<ap>. It computes B<ap> * B<w> + B<rp>, places
the result in B<rp>, and returns the high word (carry).
bn_sqr_words(B<rp>, B<ap>, B<n>) operates on the B<num> word array
B<ap> and the 2*B<num> word array B<ap>. It computes B<ap> * B<ap>
word-wise, and places the low and high bytes of the result in B<rp>.
bn_div_words(B<h>, B<l>, B<d>) divides the two word number (B<h>, B<l>)
by B<d> and returns the result.
bn_add_words(B<rp>, B<ap>, B<bp>, B<num>) operates on the B<num> word
arrays B<ap>, B<bp> and B<rp>. It computes B<ap> + B<bp>, places the
result in B<rp>, and returns the high word (carry).
bn_sub_words(B<rp>, B<ap>, B<bp>, B<num>) operates on the B<num> word
arrays B<ap>, B<bp> and B<rp>. It computes B<ap> - B<bp>, places the
result in B<rp>, and returns the carry (1 if B<bp> E<gt> B<ap>, 0
otherwise).
bn_mul_comba4(B<r>, B<a>, B<b>) operates on the 4 word arrays B<a> and
B<b> and the 8 word array B<r>. It computes B<a>*B<b> and places the
result in B<r>.
bn_mul_comba8(B<r>, B<a>, B<b>) operates on the 8 word arrays B<a> and
B<b> and the 16 word array B<r>. It computes B<a>*B<b> and places the
result in B<r>.
bn_sqr_comba4(B<r>, B<a>, B<b>) operates on the 4 word arrays B<a> and
B<b> and the 8 word array B<r>.
bn_sqr_comba8(B<r>, B<a>, B<b>) operates on the 8 word arrays B<a> and
B<b> and the 16 word array B<r>.
The following functions are implemented in C:
bn_cmp_words(B<a>, B<b>, B<n>) operates on the B<n> word arrays B<a>
and B<b>. It returns 1, 0 and -1 if B<a> is greater than, equal and
less than B<b>.
bn_mul_normal(B<r>, B<a>, B<na>, B<b>, B<nb>) operates on the B<na>
word array B<a>, the B<nb> word array B<b> and the B<na>+B<nb> word
array B<r>. It computes B<a>*B<b> and places the result in B<r>.
bn_mul_low_normal(B<r>, B<a>, B<b>, B<n>) operates on the B<n> word
arrays B<r>, B<a> and B<b>. It computes the B<n> low words of
B<a>*B<b> and places the result in B<r>.
bn_mul_recursive(B<r>, B<a>, B<b>, B<n2>, B<dna>, B<dnb>, B<t>) operates
on the word arrays B<a> and B<b> of length B<n2>+B<dna> and B<n2>+B<dnb>
(B<dna> and B<dnb> are currently allowed to be 0 or negative) and the 2*B<n2>
word arrays B<r> and B<t>. B<n2> must be a power of 2. It computes
B<a>*B<b> and places the result in B<r>.
bn_mul_part_recursive(B<r>, B<a>, B<b>, B<n>, B<tna>, B<tnb>, B<tmp>)
operates on the word arrays B<a> and B<b> of length B<n>+B<tna> and
B<n>+B<tnb> and the 4*B<n> word arrays B<r> and B<tmp>.
bn_mul_low_recursive(B<r>, B<a>, B<b>, B<n2>, B<tmp>) operates on the
B<n2> word arrays B<r> and B<tmp> and the B<n2>/2 word arrays B<a>
and B<b>.
BN_mul() calls bn_mul_normal(), or an optimized implementation if the
factors have the same size: bn_mul_comba8() is used if they are 8
words long, bn_mul_recursive() if they are larger than
B<BN_MULL_SIZE_NORMAL> and the size is an exact multiple of the word
size, and bn_mul_part_recursive() for others that are larger than
B<BN_MULL_SIZE_NORMAL>.
bn_sqr_normal(B<r>, B<a>, B<n>, B<tmp>) operates on the B<n> word array
B<a> and the 2*B<n> word arrays B<tmp> and B<r>.
The implementations use the following macros which, depending on the
architecture, may use "long long" C operations or inline assembler.
They are defined in C<bn_lcl.h>.
mul(B<r>, B<a>, B<w>, B<c>) computes B<w>*B<a>+B<c> and places the
low word of the result in B<r> and the high word in B<c>.
mul_add(B<r>, B<a>, B<w>, B<c>) computes B<w>*B<a>+B<r>+B<c> and
places the low word of the result in B<r> and the high word in B<c>.
sqr(B<r0>, B<r1>, B<a>) computes B<a>*B<a> and places the low word
of the result in B<r0> and the high word in B<r1>.
=head2 Size changes
bn_expand() ensures that B<b> has enough space for a B<bits> bit
number. bn_wexpand() ensures that B<b> has enough space for an
B<n> word number. If the number has to be expanded, both macros
call bn_expand2(), which allocates a new B<d> array and copies the
data. They return B<NULL> on error, B<b> otherwise.
The bn_fix_top() macro reduces B<a-E<gt>top> to point to the most
significant non-zero word plus one when B<a> has shrunk.
=head2 Debugging
bn_check_top() verifies that C<((a)-E<gt>top E<gt>= 0 && (a)-E<gt>top
E<lt>= (a)-E<gt>dmax)>. A violation will cause the program to abort.
bn_print() prints B<a> to stderr. bn_dump() prints B<n> words at B<d>
(in reverse order, i.e. most significant word first) to stderr.
bn_set_max() makes B<a> a static number with a B<dmax> of its current size.
This is used by bn_set_low() and bn_set_high() to make B<r> a read-only
B<BIGNUM> that contains the B<n> low or high words of B<a>.
If B<BN_DEBUG> is not defined, bn_check_top(), bn_print(), bn_dump()
and bn_set_max() are defined as empty macros.
=head1 SEE ALSO
L<bn(3)>
=head1 COPYRIGHT
Copyright 2000-2016 The OpenSSL Project Authors. All Rights Reserved.
Licensed under the OpenSSL license (the "License"). You may not use
this file except in compliance with the License. You can obtain a copy
in the file LICENSE in the source distribution or at
L<https://www.openssl.org/source/license.html>.
=cut