mirror of
https://github.com/RfidResearchGroup/proxmark3.git
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267 lines
8.2 KiB
C
267 lines
8.2 KiB
C
/*****************************************************************************
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* WARNING
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*
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* THIS CODE IS CREATED FOR EXPERIMENTATION AND EDUCATIONAL USE ONLY.
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*
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* USAGE OF THIS CODE IN OTHER WAYS MAY INFRINGE UPON THE INTELLECTUAL
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* PROPERTY OF OTHER PARTIES, SUCH AS INSIDE SECURE AND HID GLOBAL,
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* AND MAY EXPOSE YOU TO AN INFRINGEMENT ACTION FROM THOSE PARTIES.
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*
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* THIS CODE SHOULD NEVER BE USED TO INFRINGE PATENTS OR INTELLECTUAL PROPERTY RIGHTS.
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*
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*****************************************************************************
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*
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* This file is part of loclass. It is a reconstructon of the cipher engine
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* used in iClass, and RFID techology.
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*
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* The implementation is based on the work performed by
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* Flavio D. Garcia, Gerhard de Koning Gans, Roel Verdult and
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* Milosch Meriac in the paper "Dismantling IClass".
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*
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* Copyright (C) 2014 Martin Holst Swende
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*
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* This is free software: you can redistribute it and/or modify
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* it under the terms of the GNU General Public License version 2 as published
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* by the Free Software Foundation.
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*
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* This file is distributed in the hope that it will be useful,
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* but WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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* GNU General Public License for more details.
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*
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* You should have received a copy of the GNU General Public License
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* along with loclass. If not, see <http://www.gnu.org/licenses/>.
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*
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*
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*
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****************************************************************************/
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/**
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This file contains an optimized version of the MAC-calculation algorithm. Some measurements on
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a std laptop showed it runs in about 1/3 of the time:
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Std: 0.428962
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Opt: 0.151609
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Additionally, it is self-reliant, not requiring e.g. bitstreams from the cipherutils, thus can
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be easily dropped into a code base.
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The optimizations have been performed in the following steps:
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* Parameters passed by reference instead of by value.
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* Iteration instead of recursion, un-nesting recursive loops into for-loops.
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* Handling of bytes instead of individual bits, for less shuffling and masking
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* Less creation of "objects", structs, and instead reuse of alloc:ed memory
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* Inlining some functions via #define:s
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As a consequence, this implementation is less generic. Also, I haven't bothered documenting this.
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For a thorough documentation, check out the MAC-calculation within cipher.c instead.
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-- MHS 2015
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**/
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#include "optimized_cipher.h"
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#define opt_T(s) (0x1 & ((s->t >> 15) ^ (s->t >> 14)^ (s->t >> 10)^ (s->t >> 8)^ (s->t >> 5)^ (s->t >> 4)^ (s->t >> 1)^ s->t))
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#define opt_B(s) (((s->b >> 6) ^ (s->b >> 5) ^ (s->b >> 4) ^ (s->b)) & 0x1)
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#define opt__select(x,y,r) (4 & (((r & (r << 2)) >> 5) ^ ((r & ~(r << 2)) >> 4) ^ ( (r | r << 2) >> 3)))\
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|(2 & (((r | r << 2) >> 6) ^ ( (r | r << 2) >> 1) ^ (r >> 5) ^ r ^ ((x^y) << 1)))\
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|(1 & (((r & ~(r << 2)) >> 4) ^ ((r & (r << 2)) >> 3) ^ r ^ x))
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/*
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* Some background on the expression above can be found here...
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uint8_t xopt__select(bool x, bool y, uint8_t r)
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{
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uint8_t r_ls2 = r << 2;
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uint8_t r_and_ls2 = r & r_ls2;
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uint8_t r_or_ls2 = r | r_ls2;
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//r: r0 r1 r2 r3 r4 r5 r6 r7
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//r_ls2: r2 r3 r4 r5 r6 r7 0 0
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// z0
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// z1
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// uint8_t z0 = (r0 & r2) ^ (r1 & ~r3) ^ (r2 | r4); // <-- original
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uint8_t z0 = (r_and_ls2 >> 5) ^ ((r & ~r_ls2) >> 4) ^ ( r_or_ls2 >> 3);
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// uint8_t z1 = (r0 | r2) ^ ( r5 | r7) ^ r1 ^ r6 ^ x ^ y; // <-- original
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uint8_t z1 = (r_or_ls2 >> 6) ^ ( r_or_ls2 >> 1) ^ (r >> 5) ^ r ^ ((x^y) << 1);
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// uint8_t z2 = (r3 & ~r5) ^ (r4 & r6 ) ^ r7 ^ x; // <-- original
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uint8_t z2 = ((r & ~r_ls2) >> 4) ^ (r_and_ls2 >> 3) ^ r ^ x;
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return (z0 & 4) | (z1 & 2) | (z2 & 1);
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}
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*/
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void opt_successor(const uint8_t* k, State *s, bool y, State* successor) {
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uint8_t Tt = 1 & opt_T(s);
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successor->t = (s->t >> 1);
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successor->t |= (Tt ^ (s->r >> 7 & 0x1) ^ (s->r >> 3 & 0x1)) << 15;
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successor->b = s->b >> 1;
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successor->b |= (opt_B(s) ^ (s->r & 0x1)) << 7;
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successor->r = (k[opt__select(Tt,y,s->r)] ^ successor->b) + s->l ;
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successor->l = successor->r+s->r;
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}
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void opt_suc(const uint8_t* k,State* s, uint8_t *in, uint8_t length, bool add32Zeroes) {
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State x2;
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int i;
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uint8_t head = 0;
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for (i = 0; i < length; i++) {
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head = 1 & (in[i] >> 7);
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opt_successor(k, s, head, &x2);
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head = 1 & (in[i] >> 6);
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opt_successor(k, &x2, head, s);
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head = 1 & (in[i] >> 5);
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opt_successor(k, s, head, &x2);
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head = 1 & (in[i] >> 4);
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opt_successor(k, &x2, head, s);
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head = 1 & (in[i] >> 3);
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opt_successor(k, s, head, &x2);
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head = 1 & (in[i] >> 2);
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opt_successor(k, &x2, head, s);
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head = 1 & (in[i] >> 1);
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opt_successor(k, s, head, &x2);
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head = 1 & in[i];
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opt_successor(k, &x2, head, s);
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}
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//For tag MAC, an additional 32 zeroes
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if (add32Zeroes) {
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for (i = 0; i < 16; i++) {
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opt_successor(k, s, 0, &x2);
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opt_successor(k, &x2, 0, s);
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}
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}
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}
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void opt_output(const uint8_t* k,State* s, uint8_t *buffer) {
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uint8_t times = 0;
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uint8_t bout = 0;
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State temp = {0,0,0,0};
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for ( ; times < 4; times++) {
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bout =0;
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bout |= (s->r & 0x4) << 5;
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opt_successor(k, s, 0, &temp);
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bout |= (temp.r & 0x4) << 4;
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opt_successor(k, &temp, 0, s);
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bout |= (s->r & 0x4) << 3;
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opt_successor(k, s, 0, &temp);
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bout |= (temp.r & 0x4) << 2;
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opt_successor(k, &temp, 0, s);
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bout |= (s->r & 0x4) << 1;
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opt_successor(k, s, 0, &temp);
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bout |= (temp.r & 0x4) ;
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opt_successor(k, &temp, 0, s);
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bout |= (s->r & 0x4) >> 1;
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opt_successor(k, s, 0, &temp);
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bout |= (temp.r & 0x4) >> 2;
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opt_successor(k, &temp, 0, s);
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buffer[times] = bout;
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}
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}
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void opt_MAC(uint8_t* k, uint8_t* input, uint8_t* out) {
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State _init = {
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((k[0] ^ 0x4c) + 0xEC) & 0xFF,// l
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((k[0] ^ 0x4c) + 0x21) & 0xFF,// r
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0x4c, // b
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0xE012 // t
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};
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opt_suc(k,&_init,input,12, false);
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opt_output(k,&_init, out);
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}
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uint8_t rev_byte(uint8_t b) {
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b = (b & 0xF0) >> 4 | (b & 0x0F) << 4;
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b = (b & 0xCC) >> 2 | (b & 0x33) << 2;
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b = (b & 0xAA) >> 1 | (b & 0x55) << 1;
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return b;
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}
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void opt_reverse_arraybytecpy(uint8_t* dest, uint8_t *src, size_t len) {
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uint8_t i;
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for ( i =0; i< len ; i++)
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dest[i] = rev_byte(src[i]);
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}
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void opt_doReaderMAC(uint8_t *cc_nr_p, uint8_t *div_key_p, uint8_t mac[4]) {
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static uint8_t cc_nr[12];
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opt_reverse_arraybytecpy(cc_nr, cc_nr_p, 12);
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uint8_t dest [] = {0,0,0,0,0,0,0,0};
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opt_MAC(div_key_p, cc_nr, dest);
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//The output MAC must also be reversed
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opt_reverse_arraybytecpy(mac, dest, 4);
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return;
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}
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void opt_doTagMAC(uint8_t *cc_p, const uint8_t *div_key_p, uint8_t mac[4]) {
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static uint8_t cc_nr[8+4+4];
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opt_reverse_arraybytecpy(cc_nr, cc_p, 12);
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State _init = {
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((div_key_p[0] ^ 0x4c) + 0xEC) & 0xFF,// l
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((div_key_p[0] ^ 0x4c) + 0x21) & 0xFF,// r
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0x4c, // b
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0xE012 // t
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};
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opt_suc(div_key_p, &_init, cc_nr, 12, true);
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uint8_t dest [] = {0,0,0,0};
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opt_output(div_key_p, &_init, dest);
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//The output MAC must also be reversed
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opt_reverse_arraybytecpy(mac, dest,4);
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return;
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}
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/**
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* The tag MAC can be divided (both can, but no point in dividing the reader mac) into
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* two functions, since the first 8 bytes are known, we can pre-calculate the state
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* reached after feeding CC to the cipher.
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* @param cc_p
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* @param div_key_p
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* @return the cipher state
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*/
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State opt_doTagMAC_1(uint8_t *cc_p, const uint8_t *div_key_p) {
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static uint8_t cc_nr[8];
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opt_reverse_arraybytecpy(cc_nr, cc_p, 8);
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State _init = {
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((div_key_p[0] ^ 0x4c) + 0xEC) & 0xFF,// l
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((div_key_p[0] ^ 0x4c) + 0x21) & 0xFF,// r
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0x4c, // b
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0xE012 // t
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};
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opt_suc(div_key_p, &_init, cc_nr, 8, false);
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return _init;
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}
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/**
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* The second part of the tag MAC calculation, since the CC is already calculated into the state,
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* this function is fed only the NR, and internally feeds the remaining 32 0-bits to generate the tag
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* MAC response.
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* @param _init - precalculated cipher state
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* @param nr - the reader challenge
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* @param mac - where to store the MAC
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* @param div_key_p - the key to use
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*/
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void opt_doTagMAC_2(State _init, uint8_t* nr, uint8_t mac[4], const uint8_t* div_key_p) {
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static uint8_t _nr[4];
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opt_reverse_arraybytecpy(_nr, nr, 4);
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opt_suc(div_key_p, &_init,_nr, 4, true);
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uint8_t dest [] = {0,0,0,0};
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opt_output(div_key_p, &_init, dest);
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//The output MAC must also be reversed
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opt_reverse_arraybytecpy(mac, dest,4);
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return;
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}
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