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694 lines
32 KiB
C
694 lines
32 KiB
C
//-----------------------------------------------------------------------------
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// Copyright (C) 2016, 2017 by piwi
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//
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// This code is licensed to you under the terms of the GNU GPL, version 2 or,
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// at your option, any later version. See the LICENSE.txt file for the text of
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// the license.
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//-----------------------------------------------------------------------------
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// Implements a card only attack based on crypto text (encrypted nonces
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// received during a nested authentication) only. Unlike other card only
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// attacks this doesn't rely on implementation errors but only on the
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// inherent weaknesses of the crypto1 cypher. Described in
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// Carlo Meijer, Roel Verdult, "Ciphertext-only Cryptanalysis on Hardened
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// Mifare Classic Cards" in Proceedings of the 22nd ACM SIGSAC Conference on
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// Computer and Communications Security, 2015
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//-----------------------------------------------------------------------------
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//
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// brute forcing is based on @aczids bitsliced brute forcer
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// https://github.com/aczid/crypto1_bs with some modifications. Mainly:
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// - don't rollback. Start with 2nd byte of nonce instead
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// - reuse results of filter subfunctions
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// - reuse results of previous nonces if some first bits are identical
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//
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//-----------------------------------------------------------------------------
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// aczid's Copyright notice:
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//
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// Bit-sliced Crypto-1 brute-forcing implementation
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// Builds on the data structures returned by CraptEV1 craptev1_get_space(nonces, threshold, uid)
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/*
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Copyright (c) 2015-2016 Aram Verstegen
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Permission is hereby granted, free of charge, to any person obtaining a copy
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of this software and associated documentation files (the "Software"), to deal
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in the Software without restriction, including without limitation the rights
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to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
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copies of the Software, and to permit persons to whom the Software is
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furnished to do so, subject to the following conditions:
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The above copyright notice and this permission notice shall be included in
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all copies or substantial portions of the Software.
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THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
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IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
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FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
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AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
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LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
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OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
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THE SOFTWARE.
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*/
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#include "hardnested_bf_core.h"
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#include <stdint.h>
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#include <stdbool.h>
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#include <stdlib.h>
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#ifndef __APPLE__
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#include <malloc.h>
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#endif
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#include <stdio.h>
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#include <string.h>
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#include "crapto1/crapto1.h"
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#include "parity.h"
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#include "ui.h" // PrintAndLogEx
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//#include "common.h"
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// bitslice type
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// while AVX supports 256 bit vector floating point operations, we need integer operations for boolean logic
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// same for AVX2 and 512 bit vectors
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// using larger vectors works but seems to generate more register pressure
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#if defined(__AVX512F__)
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#define MAX_BITSLICES 512
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#elif defined(__AVX2__)
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#define MAX_BITSLICES 256
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#elif defined(__AVX__)
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#define MAX_BITSLICES 128
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#elif defined(__SSE2__)
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#define MAX_BITSLICES 128
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#elif defined(__ARM_NEON) && !defined(NOSIMD_BUILD)
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#define MAX_BITSLICES 128
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#else // MMX or SSE or NOSIMD
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#define MAX_BITSLICES 64
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#endif
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#define VECTOR_SIZE (MAX_BITSLICES/8)
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typedef uint32_t __attribute__((aligned(VECTOR_SIZE))) __attribute__((vector_size(VECTOR_SIZE))) bitslice_value_t;
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typedef union {
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bitslice_value_t value;
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uint64_t bytes64[MAX_BITSLICES / 64];
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uint8_t bytes[MAX_BITSLICES / 8];
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} bitslice_t;
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// filter function (f20)
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// sourced from ``Wirelessly Pickpocketing a Mifare Classic Card'' by Flavio Garcia, Peter van Rossum, Roel Verdult and Ronny Wichers Schreur
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#define f20a(a,b,c,d) (((a|b)^(a&d))^(c&((a^b)|d)))
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#define f20b(a,b,c,d) (((a&b)|c)^((a^b)&(c|d)))
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#define f20c(a,b,c,d,e) ((a|((b|e)&(d^e)))^((a^(b&d))&((c^d)|(b&e))))
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// bit indexing
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#define get_bit(n, word) (((word) >> (n)) & 1)
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#define get_vector_bit(slice, value) get_bit((slice)&0x3f, value.bytes64[(slice)>>6])
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// size of crypto-1 state
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#define STATE_SIZE 48
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// size of nonce to be decrypted
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#define KEYSTREAM_SIZE 24
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// this needs to be compiled several times for each instruction set.
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// For each instruction set, define a dedicated function name:
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#if defined (__AVX512F__)
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#define BITSLICE_TEST_NONCES bitslice_test_nonces_AVX512
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#define CRACK_STATES_BITSLICED crack_states_bitsliced_AVX512
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#elif defined (__AVX2__)
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#define BITSLICE_TEST_NONCES bitslice_test_nonces_AVX2
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#define CRACK_STATES_BITSLICED crack_states_bitsliced_AVX2
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#elif defined (__AVX__)
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#define BITSLICE_TEST_NONCES bitslice_test_nonces_AVX
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#define CRACK_STATES_BITSLICED crack_states_bitsliced_AVX
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#elif defined (__SSE2__)
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#define BITSLICE_TEST_NONCES bitslice_test_nonces_SSE2
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#define CRACK_STATES_BITSLICED crack_states_bitsliced_SSE2
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#elif defined (__MMX__)
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#define BITSLICE_TEST_NONCES bitslice_test_nonces_MMX
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#define CRACK_STATES_BITSLICED crack_states_bitsliced_MMX
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#elif defined (__ARM_NEON) && !defined(NOSIMD_BUILD)
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#define BITSLICE_TEST_NONCES bitslice_test_nonces_NEON
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#define CRACK_STATES_BITSLICED crack_states_bitsliced_NEON
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#else
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#define BITSLICE_TEST_NONCES bitslice_test_nonces_NOSIMD
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#define CRACK_STATES_BITSLICED crack_states_bitsliced_NOSIMD
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#endif
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// typedefs and declaration of functions:
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typedef uint64_t crack_states_bitsliced_t(uint32_t, uint8_t *, statelist_t *, uint32_t *, uint64_t *, uint32_t, const uint8_t *, noncelist_t *);
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crack_states_bitsliced_t crack_states_bitsliced_AVX512;
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crack_states_bitsliced_t crack_states_bitsliced_AVX2;
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crack_states_bitsliced_t crack_states_bitsliced_AVX;
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crack_states_bitsliced_t crack_states_bitsliced_SSE2;
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crack_states_bitsliced_t crack_states_bitsliced_MMX;
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crack_states_bitsliced_t crack_states_bitsliced_NEON;
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crack_states_bitsliced_t crack_states_bitsliced_NOSIMD;
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crack_states_bitsliced_t crack_states_bitsliced_dispatch;
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typedef void bitslice_test_nonces_t(uint32_t, const uint32_t *, const uint8_t *);
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bitslice_test_nonces_t bitslice_test_nonces_AVX512;
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bitslice_test_nonces_t bitslice_test_nonces_AVX2;
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bitslice_test_nonces_t bitslice_test_nonces_AVX;
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bitslice_test_nonces_t bitslice_test_nonces_SSE2;
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bitslice_test_nonces_t bitslice_test_nonces_MMX;
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bitslice_test_nonces_t bitslice_test_nonces_NEON;
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bitslice_test_nonces_t bitslice_test_nonces_NOSIMD;
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bitslice_test_nonces_t bitslice_test_nonces_dispatch;
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#if defined (_WIN32)
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#define malloc_bitslice(x) __builtin_assume_aligned(_aligned_malloc((x), MAX_BITSLICES / 8), MAX_BITSLICES / 8)
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#define free_bitslice(x) _aligned_free(x)
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#elif defined (__APPLE__)
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static void *malloc_bitslice(size_t x) {
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char *allocated_memory;
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if (posix_memalign((void **)&allocated_memory, MAX_BITSLICES / 8, x)) {
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return NULL;
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} else {
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return __builtin_assume_aligned(allocated_memory, MAX_BITSLICES / 8);
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}
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}
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#define free_bitslice(x) free(x)
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#else
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//#define malloc_bitslice(x) memalign(MAX_BITSLICES / 8, (x))
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#define malloc_bitslice(x) __builtin_assume_aligned(memalign(MAX_BITSLICES / 8, (x)), MAX_BITSLICES / 8);
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#define free_bitslice(x) free(x)
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#endif
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typedef enum {
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EVEN_STATE = 0,
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ODD_STATE = 1
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} odd_even_t;
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// arrays of bitsliced states with identical values in all slices
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static bitslice_t bitsliced_encrypted_nonces[256][KEYSTREAM_SIZE];
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static bitslice_t bitsliced_encrypted_parity_bits[256][4];
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// 1 and 0 vectors
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static bitslice_t bs_ones;
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static bitslice_t bs_zeroes;
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void BITSLICE_TEST_NONCES(uint32_t nonces_to_bruteforce, const uint32_t *bf_test_nonce, const uint8_t *bf_test_nonce_par) {
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// initialize 1 and 0 vectors
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memset(bs_ones.bytes, 0xff, VECTOR_SIZE);
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memset(bs_zeroes.bytes, 0x00, VECTOR_SIZE);
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// bitslice nonces' 2nd to 4th byte
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for (uint32_t i = 0; i < nonces_to_bruteforce; i++) {
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for (uint32_t bit_idx = 0; bit_idx < KEYSTREAM_SIZE; bit_idx++) {
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bool bit = get_bit(KEYSTREAM_SIZE - 1 - bit_idx, BSWAP_32(bf_test_nonce[i] << 8));
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if (bit) {
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bitsliced_encrypted_nonces[i][bit_idx].value = bs_ones.value;
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} else {
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bitsliced_encrypted_nonces[i][bit_idx].value = bs_zeroes.value;
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}
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}
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}
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// bitslice nonces' parity (4 bits)
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for (uint32_t i = 0; i < nonces_to_bruteforce; i++) {
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for (uint32_t bit_idx = 0; bit_idx < 4; bit_idx++) {
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bool bit = get_bit(4 - 1 - bit_idx, bf_test_nonce_par[i]);
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if (bit) {
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bitsliced_encrypted_parity_bits[i][bit_idx].value = bs_ones.value;
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} else {
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bitsliced_encrypted_parity_bits[i][bit_idx].value = bs_zeroes.value;
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}
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}
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}
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}
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uint64_t CRACK_STATES_BITSLICED(uint32_t cuid, uint8_t *best_first_bytes, statelist_t *p, uint32_t *keys_found,
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uint64_t *num_keys_tested, uint32_t nonces_to_bruteforce,
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const uint8_t *bf_test_nonce_2nd_byte, noncelist_t *nonces) {
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// Unlike aczid's implementation this doesn't roll back at all when performing bitsliced bruteforce.
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// We know that the best first byte is already shifted in. Testing with the remaining three bytes of
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// the nonces is sufficient to eliminate most of them. The small rest is tested with a simple unsliced
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// brute forcing (including roll back).
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bitslice_t states[KEYSTREAM_SIZE + STATE_SIZE];
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bitslice_t *restrict state_p;
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uint64_t key = -1;
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uint64_t bucket_states_tested = 0;
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uint32_t bucket_size[(p->len[EVEN_STATE] - 1) / MAX_BITSLICES + 1];
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uint32_t bitsliced_blocks = 0;
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uint32_t const *restrict p_even_end = p->states[EVEN_STATE] + p->len[EVEN_STATE];
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#if defined (DEBUG_BRUTE_FORCE)
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uint32_t elimination_step = 0;
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#define MAX_ELIMINATION_STEP 32
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uint64_t keys_eliminated[MAX_ELIMINATION_STEP] = {0};
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#endif
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#ifdef DEBUG_KEY_ELIMINATION
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bool bucket_contains_test_key[(p->len[EVEN_STATE] - 1) / MAX_BITSLICES + 1];
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#endif
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// constant ones/zeroes
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// bitslice_t bs_ones;
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memset(bs_ones.bytes, 0xff, VECTOR_SIZE);
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// bitslice_t bs_zeroes;
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memset(bs_zeroes.bytes, 0x00, VECTOR_SIZE);
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// bitslice all the even states
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bitslice_t **restrict bitsliced_even_states = (bitslice_t **)calloc(1, ((p->len[EVEN_STATE] - 1) / MAX_BITSLICES + 1) * sizeof(bitslice_t *));
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if (bitsliced_even_states == NULL) {
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PrintAndLogEx(WARNING, "Out of memory error in brute_force. Aborting...");
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exit(4);
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}
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bitslice_value_t *restrict bitsliced_even_feedback = malloc_bitslice(((p->len[EVEN_STATE] - 1) / MAX_BITSLICES + 1) * sizeof(bitslice_value_t));
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if (bitsliced_even_feedback == NULL) {
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PrintAndLogEx(WARNING, "Out of memory error in brute_force. Aborting...");
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exit(4);
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}
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for (uint32_t *restrict p_even = p->states[EVEN_STATE]; p_even < p_even_end; p_even += MAX_BITSLICES) {
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bitslice_t *restrict lstate_p = malloc_bitslice(STATE_SIZE / 2 * sizeof(bitslice_t));
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if (lstate_p == NULL) {
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PrintAndLogEx(WARNING, "Out of memory error in brute_force. Aborting... \n");
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exit(4);
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}
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memset(lstate_p, 0x00, STATE_SIZE / 2 * sizeof(bitslice_t)); // zero even bits
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// bitslice even half-states
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const uint32_t max_slices = (p_even_end - p_even) < MAX_BITSLICES ? p_even_end - p_even : MAX_BITSLICES;
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bucket_size[bitsliced_blocks] = max_slices;
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#ifdef DEBUG_KEY_ELIMINATION
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bucket_contains_test_key[bitsliced_blocks] = false;
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#endif
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uint32_t slice_idx;
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for (slice_idx = 0; slice_idx < max_slices; ++slice_idx) {
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uint32_t e = *(p_even + slice_idx);
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#ifdef DEBUG_KEY_ELIMINATION
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if (known_target_key != -1 && e == test_state[EVEN_STATE]) {
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bucket_contains_test_key[bitsliced_blocks] = true;
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// PrintAndLogEx(INFO, "bucket %d contains test key even state", bitsliced_blocks);
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// PrintAndLogEx(INFO, "in slice %d", slice_idx);
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}
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#endif
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for (uint32_t bit_idx = 0; bit_idx < STATE_SIZE / 2; bit_idx++, e >>= 1) {
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// set even bits
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if (e & 1) {
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lstate_p[bit_idx].bytes64[slice_idx >> 6] |= 1ull << (slice_idx & 0x3f);
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}
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}
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}
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// padding with last even state
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for (; slice_idx < MAX_BITSLICES; ++slice_idx) {
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uint32_t e = *(p_even_end - 1);
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for (uint32_t bit_idx = 0; bit_idx < STATE_SIZE / 2; bit_idx++, e >>= 1) {
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// set even bits
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if (e & 1) {
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lstate_p[bit_idx].bytes64[slice_idx >> 6] |= 1ull << (slice_idx & 0x3f);
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}
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}
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}
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bitsliced_even_states[bitsliced_blocks] = lstate_p;
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// bitsliced_even_feedback[bitsliced_blocks] = bs_ones;
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bitsliced_even_feedback[bitsliced_blocks] = lstate_p[(47 - 0) / 2].value ^
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lstate_p[(47 - 10) / 2].value ^ lstate_p[(47 - 12) / 2].value ^ lstate_p[(47 - 14) / 2].value ^
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lstate_p[(47 - 24) / 2].value ^ lstate_p[(47 - 42) / 2].value;
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bitsliced_blocks++;
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}
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// bitslice every odd state to every block of even states
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for (uint32_t const *restrict p_odd = p->states[ODD_STATE]; p_odd < p->states[ODD_STATE] + p->len[ODD_STATE]; ++p_odd) {
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// early abort
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if (*keys_found) {
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goto out;
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}
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// set odd state bits and pre-compute first keystream bit vector. This is the same for all blocks of even states
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state_p = &states[KEYSTREAM_SIZE];
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uint32_t o = *p_odd;
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// pre-compute the odd feedback bit
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bool odd_feedback_bit = evenparity32(o & 0x29ce5c);
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const bitslice_value_t odd_feedback = odd_feedback_bit ? bs_ones.value : bs_zeroes.value;
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// set odd state bits
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for (uint32_t state_idx = 0; state_idx < STATE_SIZE; o >>= 1, state_idx += 2) {
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if (o & 1) {
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state_p[state_idx] = bs_ones;
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} else {
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state_p[state_idx] = bs_zeroes;
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}
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}
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bitslice_value_t crypto1_bs_f20b_2[16];
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bitslice_value_t crypto1_bs_f20b_3[8];
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crypto1_bs_f20b_2[0] = f20b(state_p[47 - 25].value, state_p[47 - 27].value, state_p[47 - 29].value, state_p[47 - 31].value);
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crypto1_bs_f20b_3[0] = f20b(state_p[47 - 41].value, state_p[47 - 43].value, state_p[47 - 45].value, state_p[47 - 47].value);
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bitslice_value_t ksb[8];
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ksb[0] = f20c(f20a(state_p[47 - 9].value, state_p[47 - 11].value, state_p[47 - 13].value, state_p[47 - 15].value),
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f20b(state_p[47 - 17].value, state_p[47 - 19].value, state_p[47 - 21].value, state_p[47 - 23].value),
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crypto1_bs_f20b_2[0],
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f20a(state_p[47 - 33].value, state_p[47 - 35].value, state_p[47 - 37].value, state_p[47 - 39].value),
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crypto1_bs_f20b_3[0]);
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uint32_t *restrict p_even = p->states[EVEN_STATE];
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for (uint32_t block_idx = 0; block_idx < bitsliced_blocks; ++block_idx, p_even += MAX_BITSLICES) {
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#ifdef DEBUG_KEY_ELIMINATION
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// if (known_target_key != -1 && bucket_contains_test_key[block_idx] && *p_odd == test_state[ODD_STATE]) {
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// PrintAndLogEx(INFO, "Now testing known target key.");
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// PrintAndLogEx(INFO, "block_idx = %d/%d", block_idx, bitsliced_blocks);
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// }
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#endif
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// add the even state bits
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const bitslice_t *restrict bitsliced_even_state = bitsliced_even_states[block_idx];
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for (uint32_t state_idx = 1; state_idx < STATE_SIZE; state_idx += 2) {
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state_p[state_idx] = bitsliced_even_state[state_idx / 2];
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}
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// pre-compute first feedback bit vector. This is the same for all nonces
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bitslice_value_t fbb[8];
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fbb[0] = odd_feedback ^ bitsliced_even_feedback[block_idx];
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// vector to contain test results (1 = passed, 0 = failed)
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bitslice_t results = bs_ones;
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// parity_bits
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bitslice_value_t par[8];
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par[0] = bs_zeroes.value;
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uint32_t next_common_bits = 0;
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for (uint32_t tests = 0; tests < nonces_to_bruteforce; ++tests) {
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// common bits with preceding test nonce
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uint32_t common_bits = next_common_bits; //tests ? trailing_zeros(bf_test_nonce_2nd_byte[tests] ^ bf_test_nonce_2nd_byte[tests-1]) : 0;
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next_common_bits = (tests < nonces_to_bruteforce - 1) ? trailing_zeros(bf_test_nonce_2nd_byte[tests] ^ bf_test_nonce_2nd_byte[tests + 1]) : 0;
|
|
uint32_t parity_bit_idx = 1; // start checking with the parity of second nonce byte
|
|
bitslice_value_t fb_bits = fbb[common_bits]; // start with precomputed feedback bits from previous nonce
|
|
bitslice_value_t ks_bits = ksb[common_bits]; // dito for first keystream bits
|
|
bitslice_value_t parity_bit_vector = par[common_bits]; // dito for first parity vector
|
|
// bitslice_value_t fb_bits = fbb[0]; // start with precomputed feedback bits from previous nonce
|
|
// bitslice_value_t ks_bits = ksb[0]; // dito for first keystream bits
|
|
// bitslice_value_t parity_bit_vector = par[0]; // dito for first parity vector
|
|
state_p -= common_bits; // and reuse the already calculated state bits
|
|
// highest bit is transmitted/received first. We start with Bit 23 (highest bit of second nonce byte),
|
|
// or the highest bit which differs from the previous nonce
|
|
for (int32_t ks_idx = KEYSTREAM_SIZE - 1 - common_bits; ks_idx >= 0; --ks_idx) {
|
|
|
|
// decrypt nonce bits
|
|
const bitslice_value_t encrypted_nonce_bit_vector = bitsliced_encrypted_nonces[tests][ks_idx].value;
|
|
const bitslice_value_t decrypted_nonce_bit_vector = encrypted_nonce_bit_vector ^ ks_bits;
|
|
|
|
// compute real parity bits on the fly
|
|
parity_bit_vector ^= decrypted_nonce_bit_vector;
|
|
|
|
// update state
|
|
state_p--;
|
|
state_p[0].value = fb_bits ^ decrypted_nonce_bit_vector;
|
|
|
|
// update crypto1 subfunctions
|
|
bitslice_value_t f20a_1, f20b_1, f20b_2, f20a_2, f20b_3;
|
|
f20a_2 = f20a(state_p[47 - 33].value, state_p[47 - 35].value, state_p[47 - 37].value, state_p[47 - 39].value);
|
|
f20b_3 = f20b(state_p[47 - 41].value, state_p[47 - 43].value, state_p[47 - 45].value, state_p[47 - 47].value);
|
|
if (ks_idx > KEYSTREAM_SIZE - 8) {
|
|
f20a_1 = f20a(state_p[47 - 9].value, state_p[47 - 11].value, state_p[47 - 13].value, state_p[47 - 15].value);
|
|
f20b_1 = f20b(state_p[47 - 17].value, state_p[47 - 19].value, state_p[47 - 21].value, state_p[47 - 23].value);
|
|
f20b_2 = f20b(state_p[47 - 25].value, state_p[47 - 27].value, state_p[47 - 29].value, state_p[47 - 31].value);
|
|
crypto1_bs_f20b_2[KEYSTREAM_SIZE - ks_idx] = f20b_2;
|
|
crypto1_bs_f20b_3[KEYSTREAM_SIZE - ks_idx] = f20b_3;
|
|
} else if (ks_idx > KEYSTREAM_SIZE - 16) {
|
|
f20a_1 = f20a(state_p[47 - 9].value, state_p[47 - 11].value, state_p[47 - 13].value, state_p[47 - 15].value);
|
|
f20b_1 = crypto1_bs_f20b_2[KEYSTREAM_SIZE - ks_idx - 8];
|
|
f20b_2 = f20b(state_p[47 - 25].value, state_p[47 - 27].value, state_p[47 - 29].value, state_p[47 - 31].value);
|
|
crypto1_bs_f20b_2[KEYSTREAM_SIZE - ks_idx] = f20b_2;
|
|
} else if (ks_idx > KEYSTREAM_SIZE - 24) {
|
|
f20a_1 = f20a(state_p[47 - 9].value, state_p[47 - 11].value, state_p[47 - 13].value, state_p[47 - 15].value);
|
|
f20b_1 = crypto1_bs_f20b_2[KEYSTREAM_SIZE - ks_idx - 8];
|
|
f20b_2 = crypto1_bs_f20b_3[KEYSTREAM_SIZE - ks_idx - 16];
|
|
} else {
|
|
f20a_1 = f20a(state_p[47 - 9].value, state_p[47 - 11].value, state_p[47 - 13].value, state_p[47 - 15].value);
|
|
f20b_1 = f20b(state_p[47 - 17].value, state_p[47 - 19].value, state_p[47 - 21].value, state_p[47 - 23].value);
|
|
f20b_2 = f20b(state_p[47 - 25].value, state_p[47 - 27].value, state_p[47 - 29].value, state_p[47 - 31].value);
|
|
}
|
|
// update keystream bit
|
|
ks_bits = f20c(f20a_1, f20b_1, f20b_2, f20a_2, f20b_3);
|
|
|
|
// for each completed byte:
|
|
if ((ks_idx & 0x07) == 0) {
|
|
// get encrypted parity bits
|
|
const bitslice_value_t encrypted_parity_bit_vector = bitsliced_encrypted_parity_bits[tests][parity_bit_idx++].value;
|
|
|
|
// decrypt parity bits
|
|
const bitslice_value_t decrypted_parity_bit_vector = encrypted_parity_bit_vector ^ ks_bits;
|
|
|
|
// compare actual parity bits with decrypted parity bits and take count in results vector
|
|
results.value &= ~parity_bit_vector ^ decrypted_parity_bit_vector;
|
|
|
|
// make sure we still have a match in our set
|
|
// if(memcmp(&results, &bs_zeroes, sizeof(bitslice_t)) == 0){
|
|
|
|
// this is much faster on my gcc, because somehow a memcmp needlessly spills/fills all the xmm registers to/from the stack - ???
|
|
// the short-circuiting also helps
|
|
if (results.bytes64[0] == 0
|
|
#if MAX_BITSLICES > 64
|
|
&& results.bytes64[1] == 0
|
|
#endif
|
|
#if MAX_BITSLICES > 128
|
|
&& results.bytes64[2] == 0
|
|
&& results.bytes64[3] == 0
|
|
#endif
|
|
) {
|
|
#if defined (DEBUG_BRUTE_FORCE)
|
|
if (elimination_step < MAX_ELIMINATION_STEP) {
|
|
keys_eliminated[elimination_step] += MAX_BITSLICES;
|
|
}
|
|
#endif
|
|
#ifdef DEBUG_KEY_ELIMINATION
|
|
if (known_target_key != -1 && bucket_contains_test_key[block_idx] && *p_odd == test_state[ODD_STATE]) {
|
|
PrintAndLogEx(INFO, "Known target key eliminated in brute_force.");
|
|
PrintAndLogEx(INFO, "block_idx = %d/%d, nonce = %d/%d", block_idx, bitsliced_blocks, tests, nonces_to_bruteforce);
|
|
}
|
|
#endif
|
|
goto stop_tests;
|
|
}
|
|
// prepare for next nonce byte
|
|
#if defined (DEBUG_BRUTE_FORCE)
|
|
elimination_step++;
|
|
#endif
|
|
parity_bit_vector = bs_zeroes.value;
|
|
}
|
|
// update feedback bit vector
|
|
if (ks_idx != 0) {
|
|
fb_bits =
|
|
(state_p[47 - 0].value ^ state_p[47 - 5].value ^ state_p[47 - 9].value ^
|
|
state_p[47 - 10].value ^ state_p[47 - 12].value ^ state_p[47 - 14].value ^
|
|
state_p[47 - 15].value ^ state_p[47 - 17].value ^ state_p[47 - 19].value ^
|
|
state_p[47 - 24].value ^ state_p[47 - 25].value ^ state_p[47 - 27].value ^
|
|
state_p[47 - 29].value ^ state_p[47 - 35].value ^ state_p[47 - 39].value ^
|
|
state_p[47 - 41].value ^ state_p[47 - 42].value ^ state_p[47 - 43].value);
|
|
}
|
|
// remember feedback and keystream vectors for later use
|
|
uint8_t bit = KEYSTREAM_SIZE - ks_idx;
|
|
if (bit <= MIN(next_common_bits, 7)) { // if needed and not yet stored
|
|
fbb[bit] = fb_bits;
|
|
ksb[bit] = ks_bits;
|
|
par[bit] = parity_bit_vector;
|
|
}
|
|
}
|
|
// prepare for next nonce. Revert to initial state
|
|
state_p = &states[KEYSTREAM_SIZE];
|
|
}
|
|
|
|
// all nonce tests were successful: we've found a possible key in this block!
|
|
uint32_t *p_even_test = p_even;
|
|
for (uint32_t results_word = 0; results_word < MAX_BITSLICES / 64; ++results_word) {
|
|
uint64_t results64 = results.bytes64[results_word];
|
|
for (uint32_t results_bit = 0; results_bit < 64; results_bit++) {
|
|
if (results64 & 0x01) {
|
|
if (verify_key(cuid, nonces, best_first_bytes, *p_odd, *p_even_test)) {
|
|
struct Crypto1State pcs;
|
|
pcs.odd = *p_odd;
|
|
pcs.even = *p_even_test;
|
|
lfsr_rollback_byte(&pcs, (cuid >> 24) ^ best_first_bytes[0], true);
|
|
crypto1_get_lfsr(&pcs, &key);
|
|
bucket_states_tested += 64 * results_word + results_bit;
|
|
goto out;
|
|
}
|
|
#ifdef DEBUG_KEY_ELIMINATION
|
|
if (known_target_key != -1 && *p_even_test == test_state[EVEN_STATE] && *p_odd == test_state[ODD_STATE]) {
|
|
PrintAndLogEx(INFO, "Known target key eliminated in brute_force verification.");
|
|
PrintAndLogEx(INFO, "block_idx = %d/%d", block_idx, bitsliced_blocks);
|
|
}
|
|
#endif
|
|
}
|
|
#ifdef DEBUG_KEY_ELIMINATION
|
|
if (known_target_key != -1 && *p_even_test == test_state[EVEN_STATE] && *p_odd == test_state[ODD_STATE]) {
|
|
PrintAndLogEx(INFO, "Known target key eliminated in brute_force (results_bit == 0).");
|
|
PrintAndLogEx(INFO, "block_idx = %d/%d", block_idx, bitsliced_blocks);
|
|
}
|
|
#endif
|
|
results64 >>= 1;
|
|
p_even_test++;
|
|
if (p_even_test == p_even_end) {
|
|
goto stop_tests;
|
|
}
|
|
}
|
|
}
|
|
stop_tests:
|
|
#if defined (DEBUG_BRUTE_FORCE)
|
|
elimination_step = 0;
|
|
#endif
|
|
bucket_states_tested += bucket_size[block_idx];
|
|
// prepare to set new states
|
|
state_p = &states[KEYSTREAM_SIZE];
|
|
}
|
|
}
|
|
out:
|
|
for (uint32_t block_idx = 0; block_idx < bitsliced_blocks; ++block_idx) {
|
|
free_bitslice(bitsliced_even_states[block_idx]);
|
|
}
|
|
free(bitsliced_even_states);
|
|
free_bitslice(bitsliced_even_feedback);
|
|
__sync_fetch_and_add(num_keys_tested, bucket_states_tested);
|
|
|
|
#if defined (DEBUG_BRUTE_FORCE)
|
|
for (uint32_t i = 0; i < MAX_ELIMINATION_STEP; i++) {
|
|
PrintAndLogEx(INFO, "Eliminated after %2u test_bytes: %5.2f%%", i + 1, (float)keys_eliminated[i] / bucket_states_tested * 100);
|
|
}
|
|
#endif
|
|
return key;
|
|
}
|
|
|
|
|
|
|
|
#ifdef NOSIMD_BUILD
|
|
|
|
// pointers to functions:
|
|
crack_states_bitsliced_t *crack_states_bitsliced_function_p = &crack_states_bitsliced_dispatch;
|
|
bitslice_test_nonces_t *bitslice_test_nonces_function_p = &bitslice_test_nonces_dispatch;
|
|
|
|
static SIMDExecInstr intSIMDInstr = SIMD_AUTO;
|
|
|
|
void SetSIMDInstr(SIMDExecInstr instr) {
|
|
intSIMDInstr = instr;
|
|
|
|
crack_states_bitsliced_function_p = &crack_states_bitsliced_dispatch;
|
|
bitslice_test_nonces_function_p = &bitslice_test_nonces_dispatch;
|
|
}
|
|
|
|
static SIMDExecInstr GetSIMDInstr(void) {
|
|
SIMDExecInstr instr;
|
|
|
|
#if defined(COMPILER_HAS_SIMD_X86)
|
|
__builtin_cpu_init();
|
|
#endif
|
|
|
|
#if defined(COMPILER_HAS_SIMD_AVX512)
|
|
if (__builtin_cpu_supports("avx512f"))
|
|
instr = SIMD_AVX512;
|
|
else
|
|
#endif
|
|
#if defined(COMPILER_HAS_SIMD_X86)
|
|
if (__builtin_cpu_supports("avx2"))
|
|
instr = SIMD_AVX2;
|
|
else if (__builtin_cpu_supports("avx"))
|
|
instr = SIMD_AVX;
|
|
else if (__builtin_cpu_supports("sse2"))
|
|
instr = SIMD_SSE2;
|
|
else if (__builtin_cpu_supports("mmx"))
|
|
instr = SIMD_MMX;
|
|
else
|
|
#endif
|
|
#if defined(COMPILER_HAS_SIMD_NEON)
|
|
if (arm_has_neon())
|
|
instr = SIMD_NEON;
|
|
else
|
|
#endif
|
|
instr = SIMD_NONE;
|
|
|
|
return instr;
|
|
}
|
|
|
|
SIMDExecInstr GetSIMDInstrAuto(void) {
|
|
SIMDExecInstr instr = intSIMDInstr;
|
|
if (instr == SIMD_AUTO)
|
|
return GetSIMDInstr();
|
|
|
|
return instr;
|
|
}
|
|
|
|
// determine the available instruction set at runtime and call the correct function
|
|
uint64_t crack_states_bitsliced_dispatch(uint32_t cuid, uint8_t *best_first_bytes, statelist_t *p,
|
|
uint32_t *keys_found, uint64_t *num_keys_tested,
|
|
uint32_t nonces_to_bruteforce, const uint8_t *bf_test_nonce_2nd_byte,
|
|
noncelist_t *nonces) {
|
|
switch (GetSIMDInstrAuto()) {
|
|
#if defined(COMPILER_HAS_SIMD_AVX512)
|
|
case SIMD_AVX512:
|
|
crack_states_bitsliced_function_p = &crack_states_bitsliced_AVX512;
|
|
break;
|
|
#endif
|
|
#if defined(COMPILER_HAS_SIMD_X86)
|
|
case SIMD_AVX2:
|
|
crack_states_bitsliced_function_p = &crack_states_bitsliced_AVX2;
|
|
break;
|
|
case SIMD_AVX:
|
|
crack_states_bitsliced_function_p = &crack_states_bitsliced_AVX;
|
|
break;
|
|
case SIMD_SSE2:
|
|
crack_states_bitsliced_function_p = &crack_states_bitsliced_SSE2;
|
|
break;
|
|
case SIMD_MMX:
|
|
crack_states_bitsliced_function_p = &crack_states_bitsliced_MMX;
|
|
break;
|
|
#endif
|
|
#if defined(COMPILER_HAS_SIMD_NEON)
|
|
case SIMD_NEON:
|
|
crack_states_bitsliced_function_p = &crack_states_bitsliced_NEON;
|
|
break;
|
|
#endif
|
|
case SIMD_AUTO:
|
|
case SIMD_NONE:
|
|
crack_states_bitsliced_function_p = &crack_states_bitsliced_NOSIMD;
|
|
break;
|
|
}
|
|
|
|
// call the most optimized function for this CPU
|
|
return (*crack_states_bitsliced_function_p)(cuid, best_first_bytes, p, keys_found, num_keys_tested, nonces_to_bruteforce, bf_test_nonce_2nd_byte, nonces);
|
|
}
|
|
|
|
void bitslice_test_nonces_dispatch(uint32_t nonces_to_bruteforce, const uint32_t *bf_test_nonce, const uint8_t *bf_test_nonce_par) {
|
|
switch (GetSIMDInstrAuto()) {
|
|
#if defined(COMPILER_HAS_SIMD_AVX512)
|
|
case SIMD_AVX512:
|
|
bitslice_test_nonces_function_p = &bitslice_test_nonces_AVX512;
|
|
break;
|
|
#endif
|
|
#if defined(COMPILER_HAS_SIMD_X86)
|
|
case SIMD_AVX2:
|
|
bitslice_test_nonces_function_p = &bitslice_test_nonces_AVX2;
|
|
break;
|
|
case SIMD_AVX:
|
|
bitslice_test_nonces_function_p = &bitslice_test_nonces_AVX;
|
|
break;
|
|
case SIMD_SSE2:
|
|
bitslice_test_nonces_function_p = &bitslice_test_nonces_SSE2;
|
|
break;
|
|
case SIMD_MMX:
|
|
bitslice_test_nonces_function_p = &bitslice_test_nonces_MMX;
|
|
break;
|
|
#endif
|
|
#if defined(COMPILER_HAS_SIMD_NEON)
|
|
case SIMD_NEON:
|
|
bitslice_test_nonces_function_p = &bitslice_test_nonces_NEON;
|
|
break;
|
|
#endif
|
|
case SIMD_AUTO:
|
|
case SIMD_NONE:
|
|
bitslice_test_nonces_function_p = &bitslice_test_nonces_NOSIMD;
|
|
break;
|
|
}
|
|
|
|
// call the most optimized function for this CPU
|
|
(*bitslice_test_nonces_function_p)(nonces_to_bruteforce, bf_test_nonce, bf_test_nonce_par);
|
|
}
|
|
|
|
// Entries to dispatched function calls
|
|
uint64_t crack_states_bitsliced(uint32_t cuid, uint8_t *best_first_bytes, statelist_t *p, uint32_t *keys_found, uint64_t *num_keys_tested, uint32_t nonces_to_bruteforce, uint8_t *bf_test_nonce_2nd_byte, noncelist_t *nonces) {
|
|
return (*crack_states_bitsliced_function_p)(cuid, best_first_bytes, p, keys_found, num_keys_tested, nonces_to_bruteforce, bf_test_nonce_2nd_byte, nonces);
|
|
}
|
|
|
|
void bitslice_test_nonces(uint32_t nonces_to_bruteforce, uint32_t *bf_test_nonce, uint8_t *bf_test_nonce_par) {
|
|
(*bitslice_test_nonces_function_p)(nonces_to_bruteforce, bf_test_nonce, bf_test_nonce_par);
|
|
}
|
|
|
|
#endif
|