+ for (i = 0; (state) && ((state + i)->odd != -1); i++) {
+ lfsr_rollback_word(state + i, uid ^ nt, 0);
+ crypto1_get_lfsr(state + i, &key_recovered);
+ *(state_s + i) = key_recovered;
+ }
+
+ if(!state)
+ return 1;
+
+ qsort(state_s, i, sizeof(*state_s), compar_int);
+ *(state_s + i) = -1;
+
+ //Create the intersection:
+ if ( last_keylist != NULL) {
+
+ int64_t *p1, *p2, *p3;
+ p1 = p3 = last_keylist;
+ p2 = state_s;
+
+ while ( *p1 != -1 && *p2 != -1 ) {
+ if (compar_int(p1, p2) == 0) {
+ printf("p1:%"llx" p2:%"llx" p3:%"llx" key:%012"llx"\n",(uint64_t)(p1-last_keylist),(uint64_t)(p2-state_s),(uint64_t)(p3-last_keylist),*p1);
+ *p3++ = *p1++;
+ p2++;
+ }
+ else {
+ while (compar_int(p1, p2) == -1) ++p1;
+ while (compar_int(p1, p2) == 1) ++p2;
+ }
+ }
+ key_count = p3 - last_keylist;
+ PrintAndLog("one A");
+ } else {
+ key_count = 0;
+ PrintAndLog("one B");
+ }
+
+ printf("key_count:%d\n", key_count);
+
+ // The list may still contain several key candidates. Test each of them with mfCheckKeys
+ uint8_t keyBlock[6] = {0,0,0,0,0,0};
+ uint64_t key64;
+ for (i = 0; i < key_count; i++) {
+ key64 = *(last_keylist + i);
+ num_to_bytes(key64, 6, keyBlock);
+ key64 = 0;
+ if (!mfCheckKeys(blockno, keytype, false, 1, keyBlock, &key64)) {
+ *key = key64;
+ free(last_keylist);
+ last_keylist = NULL;
+ free(state);
+ return 0;
+ }
+ }
+
+ free(last_keylist);
+ last_keylist = state_s;
+ return 1;
+}
+
+// 32 bit recover key from 2 nonces
+bool tryMfk32(nonces_t data, uint64_t *outputkey) {
+ struct Crypto1State *s,*t;
+ uint64_t outkey = 0;
+ uint64_t key=0; // recovered key
+ uint32_t uid = data.cuid;
+ uint32_t nt = data.nonce; // first tag challenge (nonce)
+ uint32_t nr0_enc = data.nr; // first encrypted reader challenge
+ uint32_t ar0_enc = data.ar; // first encrypted reader response
+ uint32_t nr1_enc = data.nr2; // second encrypted reader challenge
+ uint32_t ar1_enc = data.ar2; // second encrypted reader response
+ clock_t t1 = clock();
+ bool isSuccess = FALSE;
+ uint8_t counter = 0;
+
+ uint32_t p64 = prng_successor(nt, 64);
+
+ s = lfsr_recovery32(ar0_enc ^ p64, 0);
+
+ for(t = s; t->odd | t->even; ++t) {
+ lfsr_rollback_word(t, 0, 0);
+ lfsr_rollback_word(t, nr0_enc, 1);
+ lfsr_rollback_word(t, uid ^ nt, 0);
+ crypto1_get_lfsr(t, &key);
+ crypto1_word(t, uid ^ nt, 0);
+ crypto1_word(t, nr1_enc, 1);
+ if (ar1_enc == (crypto1_word(t, 0, 0) ^ p64)) {
+ //PrintAndLog("Found Key: [%012"llx"]", key);
+ outkey = key;
+ ++counter;
+ if (counter==20) break;
+ }
+ }
+ isSuccess = (counter > 0);
+ t1 = clock() - t1;
+ if ( t1 > 0 ) PrintAndLog("Time in mfkey32: %.0f ticks - possible keys %d\n", (float)t1, counter);
+
+ *outputkey = ( isSuccess ) ? outkey : 0;
+ crypto1_destroy(s);
+ return isSuccess;
+}
+
+bool tryMfk32_moebius(nonces_t data, uint64_t *outputkey) {
+ struct Crypto1State *s, *t;
+ uint64_t outkey = 0;
+ uint64_t key = 0; // recovered key
+ uint32_t uid = data.cuid;
+ uint32_t nt0 = data.nonce; // first tag challenge (nonce)
+ uint32_t nr0_enc = data.nr; // first encrypted reader challenge
+ uint32_t ar0_enc = data.ar; // first encrypted reader response
+ //uint32_t uid1 = le32toh(data+16);
+ uint32_t nt1 = data.nonce2; // second tag challenge (nonce)
+ uint32_t nr1_enc = data.nr2; // second encrypted reader challenge
+ uint32_t ar1_enc = data.ar2; // second encrypted reader response
+ bool isSuccess = FALSE;
+ int counter = 0;
+
+ //PrintAndLog("Enter mfkey32_moebius");
+ clock_t t1 = clock();
+
+ uint32_t p640 = prng_successor(nt0, 64);
+ uint32_t p641 = prng_successor(nt1, 64);
+
+ s = lfsr_recovery32(ar0_enc ^ p640, 0);