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author | Alexander Sulfrian <alexander@sulfrian.net> | 2012-06-06 22:56:07 +0200 |
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committer | Alexander Sulfrian <alexander@sulfrian.net> | 2012-06-06 22:56:07 +0200 |
commit | 3a700aeb1c0f8b4ec2f3ffd3450d918d9597105f (patch) | |
tree | 6ec0373fe542e642b71256b2b3bcc5bfd3477b85 /dev-util/mfcuk/files | |
parent | c8d2fdbaf244111a7888b206c802970d2602e3f0 (diff) | |
download | overlay-3a700aeb1c0f8b4ec2f3ffd3450d918d9597105f.tar.gz overlay-3a700aeb1c0f8b4ec2f3ffd3450d918d9597105f.tar.xz overlay-3a700aeb1c0f8b4ec2f3ffd3450d918d9597105f.zip |
dev-util/mfcuk: add live ebuild
Diffstat (limited to '')
-rw-r--r-- | dev-util/mfcuk/files/mfcuk-new-libnfc-version.patch | 1099 |
1 files changed, 1099 insertions, 0 deletions
diff --git a/dev-util/mfcuk/files/mfcuk-new-libnfc-version.patch b/dev-util/mfcuk/files/mfcuk-new-libnfc-version.patch new file mode 100644 index 0000000..e27f105 --- /dev/null +++ b/dev-util/mfcuk/files/mfcuk-new-libnfc-version.patch @@ -0,0 +1,1099 @@ +Index: src/nfc-utils.c +=================================================================== +--- src/nfc-utils.c (revision 62) ++++ src/nfc-utils.c (working copy) +@@ -33,7 +33,7 @@ + + #include "nfc-utils.h" + +-static const byte_t OddParity[256] = { ++static const uint8_t OddParity[256] = { + 1, 0, 0, 1, 0, 1, 1, 0, 0, 1, 1, 0, 1, 0, 0, 1, + 0, 1, 1, 0, 1, 0, 0, 1, 1, 0, 0, 1, 0, 1, 1, 0, + 0, 1, 1, 0, 1, 0, 0, 1, 1, 0, 0, 1, 0, 1, 1, 0, +@@ -52,14 +52,14 @@ + 1, 0, 0, 1, 0, 1, 1, 0, 0, 1, 1, 0, 1, 0, 0, 1 + }; + +-byte_t +-oddparity (const byte_t bt) ++uint8_t ++oddparity (const uint8_t bt) + { + return OddParity[bt]; + } + + void +-oddparity_bytes_ts (const byte_t * pbtData, const size_t szLen, byte_t * pbtPar) ++oddparity_bytes_ts (const uint8_t * pbtData, const size_t szLen, uint8_t * pbtPar) + { + size_t szByteNr; + // Calculate the parity bits for the command +@@ -69,7 +69,7 @@ + } + + void +-print_hex (const byte_t * pbtData, const size_t szBytes) ++print_hex (const uint8_t * pbtData, const size_t szBytes) + { + size_t szPos; + +@@ -80,7 +80,7 @@ + } + + void +-print_hex_bits (const byte_t * pbtData, const size_t szBits) ++print_hex_bits (const uint8_t * pbtData, const size_t szBits) + { + uint8_t uRemainder; + size_t szPos; +@@ -102,7 +102,7 @@ + } + + void +-print_hex_par (const byte_t * pbtData, const size_t szBits, const byte_t * pbtDataPar) ++print_hex_par (const uint8_t * pbtData, const size_t szBits, const uint8_t * pbtDataPar) + { + uint8_t uRemainder; + size_t szPos; +@@ -133,7 +133,7 @@ + #define SAK_ISO18092_COMPLIANT 0x40 + + void +-print_nfc_iso14443a_info (const nfc_iso14443a_info_t nai, bool verbose) ++print_nfc_iso14443a_info (const nfc_iso14443a_info nai, bool verbose) + { + printf (" ATQA (SENS_RES): "); + print_hex (nai.abtAtqa, 2); +@@ -202,7 +202,7 @@ + + size_t offset = 1; + if (nai.abtAts[0] & 0x10) { // TA(1) present +- byte_t TA = nai.abtAts[offset]; ++ uint8_t TA = nai.abtAts[offset]; + offset++; + printf ("* Bit Rate Capability:\n"); + if (TA == 0) { +@@ -234,7 +234,7 @@ + } + } + if (nai.abtAts[0] & 0x20) { // TB(1) present +- byte_t TB= nai.abtAts[offset]; ++ uint8_t TB= nai.abtAts[offset]; + offset++; + printf ("* Frame Waiting Time: %.4g ms\n",256.0*16.0*(1<<((TB & 0xf0) >> 4))/13560.0); + if ((TB & 0x0f) == 0) { +@@ -244,7 +244,7 @@ + } + } + if (nai.abtAts[0] & 0x40) { // TC(1) present +- byte_t TC = nai.abtAts[offset]; ++ uint8_t TC = nai.abtAts[offset]; + offset++; + if (TC & 0x1) { + printf("* Node ADdress supported\n"); +@@ -260,20 +260,20 @@ + if (nai.szAtsLen > offset) { + printf ("* Historical bytes Tk: " ); + print_hex (nai.abtAts + offset, (nai.szAtsLen - offset)); +- byte_t CIB = nai.abtAts[offset]; ++ uint8_t CIB = nai.abtAts[offset]; + offset++; + if (CIB != 0x00 && CIB != 0x10 && (CIB & 0xf0) != 0x80) { + printf(" * Proprietary format\n"); + if (CIB == 0xc1) { + printf(" * Tag byte: Mifare or virtual cards of various types\n"); +- byte_t L = nai.abtAts[offset]; ++ uint8_t L = nai.abtAts[offset]; + offset++; + if (L != (nai.szAtsLen - offset)) { + printf(" * Warning: Type Identification Coding length (%i)", L); + printf(" not matching Tk length (%zi)\n", (nai.szAtsLen - offset)); + } + if ((nai.szAtsLen - offset - 2) > 0) { // Omit 2 CRC bytes +- byte_t CTC = nai.abtAts[offset]; ++ uint8_t CTC = nai.abtAts[offset]; + offset++; + printf(" * Chip Type: "); + switch (CTC & 0xf0) { +@@ -316,7 +316,7 @@ + } + } + if ((nai.szAtsLen - offset) > 0) { // Omit 2 CRC bytes +- byte_t CVC = nai.abtAts[offset]; ++ uint8_t CVC = nai.abtAts[offset]; + offset++; + printf(" * Chip Status: "); + switch (CVC & 0xf0) { +@@ -350,7 +350,7 @@ + } + } + if ((nai.szAtsLen - offset) > 0) { // Omit 2 CRC bytes +- byte_t VCS = nai.abtAts[offset]; ++ uint8_t VCS = nai.abtAts[offset]; + offset++; + printf(" * Specifics (Virtual Card Selection):\n"); + if ((VCS & 0x09) == 0x00) { +@@ -530,7 +530,7 @@ + } + + void +-print_nfc_felica_info (const nfc_felica_info_t nfi, bool verbose) ++print_nfc_felica_info (const nfc_felica_info nfi, bool verbose) + { + (void) verbose; + printf (" ID (NFCID2): "); +@@ -542,7 +542,7 @@ + } + + void +-print_nfc_jewel_info (const nfc_jewel_info_t nji, bool verbose) ++print_nfc_jewel_info (const nfc_jewel_info nji, bool verbose) + { + (void) verbose; + printf (" ATQA (SENS_RES): "); +@@ -555,7 +555,7 @@ + #define PI_NAD_SUPPORTED 0x01 + #define PI_CID_SUPPORTED 0x02 + void +-print_nfc_iso14443b_info (const nfc_iso14443b_info_t nbi, bool verbose) ++print_nfc_iso14443b_info (const nfc_iso14443b_info nbi, bool verbose) + { + const int iMaxFrameSizes[] = { 16, 24, 32, 40, 48, 64, 96, 128, 256 }; + printf (" PUPI: "); +@@ -610,7 +610,7 @@ + } + + void +-print_nfc_iso14443bi_info (const nfc_iso14443bi_info_t nii, bool verbose) ++print_nfc_iso14443bi_info (const nfc_iso14443bi_info nii, bool verbose) + { + printf (" DIV: "); + print_hex (nii.abtDIV, 4); +@@ -634,7 +634,7 @@ + } + + void +-print_nfc_iso14443b2sr_info (const nfc_iso14443b2sr_info_t nsi, bool verbose) ++print_nfc_iso14443b2sr_info (const nfc_iso14443b2sr_info nsi, bool verbose) + { + (void) verbose; + printf (" UID: "); +@@ -642,7 +642,7 @@ + } + + void +-print_nfc_iso14443b2ct_info (const nfc_iso14443b2ct_info_t nci, bool verbose) ++print_nfc_iso14443b2ct_info (const nfc_iso14443b2ct_info nci, bool verbose) + { + (void) verbose; + uint32_t uid; +@@ -655,7 +655,7 @@ + } + + void +-print_nfc_dep_info (const nfc_dep_info_t ndi, bool verbose) ++print_nfc_dep_info (const nfc_dep_info ndi, bool verbose) + { + (void) verbose; + printf (" NFCID3: "); +@@ -671,7 +671,7 @@ + } + + const char * +-str_nfc_baud_rate (const nfc_baud_rate_t nbr) ++str_nfc_baud_rate (const nfc_baud_rate nbr) + { + switch(nbr) { + case NBR_UNDEFINED: +@@ -694,7 +694,7 @@ + } + + void +-print_nfc_target (const nfc_target_t nt, bool verbose) ++print_nfc_target (const nfc_target nt, bool verbose) + { + switch(nt.nm.nmt) { + case NMT_ISO14443A: +Index: src/mfcuk.c +=================================================================== +--- src/mfcuk.c (revision 62) ++++ src/mfcuk.c (working copy) +@@ -222,9 +222,9 @@ + uint32_t numSpoofEntries = 0; // Actual number of entries in the arrSpoofEntries + uint32_t numAuthAttempts = 0; // Number of authentication attempts for Recovery of keys - used to statistics. TODO: implement proper statistics with timings, number of tries, etc. + bool bfOpts[256] = {false}; // Command line options, indicates their presence, initialize with false +-byte_t verboseLevel = 0; // No verbose level by default ++uint8_t verboseLevel = 0; // No verbose level by default + +-static const nfc_modulation_t nmMifare = { ++static const nfc_modulation nmMifare = { + .nmt = NMT_ISO14443A, + .nbr = NBR_106, + }; +@@ -240,7 +240,7 @@ + } + + // TODO: combine mfcuk_verify_key_block() with mfcuk_recover_key_block(), since a lot of code is duplicate +-uint32_t mfcuk_verify_key_block(nfc_device_t* pnd, uint32_t uiUID, uint64_t ui64Key, mifare_key_type bKeyType, byte_t bTagType, uint32_t uiBlock) ++uint32_t mfcuk_verify_key_block(nfc_device* pnd, uint32_t uiUID, uint64_t ui64Key, mifare_key_type bKeyType, uint8_t bTagType, uint32_t uiBlock) + { + uint32_t pos; + +@@ -254,11 +254,11 @@ + uint64_t lfsr; + + // Communication related variables +- byte_t abtAuth[4] = { 0x00,0x00,0x00,0x00 }; +- byte_t abtArEnc[8] = { 0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00 }; +- byte_t abtArEncPar[8] = { 0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00 }; +- byte_t abtRx[MAX_FRAME_LEN]; +- byte_t abtRxPar[MAX_FRAME_LEN]; ++ uint8_t abtAuth[4] = { 0x00,0x00,0x00,0x00 }; ++ uint8_t abtArEnc[8] = { 0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00 }; ++ uint8_t abtArEncPar[8] = { 0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00 }; ++ uint8_t abtRx[MAX_FRAME_LEN]; ++ uint8_t abtRxPar[MAX_FRAME_LEN]; + size_t szRx; + uint32_t nt, nt_orig; // Supplied tag nonce + +@@ -283,20 +283,20 @@ + iso14443a_crc_append(abtAuth,2); + + // Now we take over, first we need full control over the CRC +- if ( !nfc_configure(pnd,NDO_HANDLE_CRC,false) ) ++ if ( !nfc_device_set_property_bool(pnd,NP_HANDLE_CRC,false) ) + { + return MFCUK_FAIL_COMM; + } + + // We need to disable EASY_FRAMING feature to talk in "raw" mode +- nfc_configure (pnd, NDO_EASY_FRAMING, false); ++ nfc_device_set_property_bool (pnd, NP_EASY_FRAMING, false); + + // Request plain tag-nonce +- if (!nfc_initiator_transceive_bytes(pnd,abtAuth,4,abtRx,&szRx, NULL)) ++ if (!nfc_initiator_transceive_bytes(pnd,abtAuth,4,abtRx,&szRx, 0)) + { + return MFCUK_FAIL_COMM; + } +- nfc_configure (pnd, NDO_EASY_FRAMING, true); ++ nfc_device_set_property_bool (pnd, NP_EASY_FRAMING, true); + + // Save the tag nonce (nt) + nt = bswap_32(*((uint32_t *) abtRx)); +@@ -347,12 +347,13 @@ + } + + // Finally we want to send arbitrary parity bits +- if ( !nfc_configure(pnd,NDO_HANDLE_PARITY,false) ) ++ if ( !nfc_device_set_property_bool(pnd,NP_HANDLE_PARITY,false) ) + { + return MFCUK_FAIL_COMM; + } + +- if ( !nfc_initiator_transceive_bits(pnd,abtArEnc,64,abtArEncPar,abtRx,&szRx,abtRxPar) ) ++ szRx = nfc_initiator_transceive_bits(pnd,abtArEnc,64,abtArEncPar,abtRx,abtRxPar); ++ if (szRx <= 0) + { + return MFCUK_FAIL_AUTH; + } +@@ -392,16 +393,16 @@ + return MFCUK_SUCCESS; + } + +-uint32_t mfcuk_key_recovery_block(nfc_device_t* pnd, uint32_t uiUID, uint64_t ui64Key, mifare_key_type bKeyType, byte_t bTagType, uint32_t uiBlock, uint64_t *ui64KeyRecovered) ++uint32_t mfcuk_key_recovery_block(nfc_device* pnd, uint32_t uiUID, uint64_t ui64Key, mifare_key_type bKeyType, uint8_t bTagType, uint32_t uiBlock, uint64_t *ui64KeyRecovered) + { + // Communication variables + uint32_t pos, pos2, nt; + struct Crypto1State* pcs; +- byte_t abtAuth[4] = { 0x60,0x00,0x00,0x00 }; +- byte_t abtArEnc[8] = { 0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00 }; +- byte_t abtArEncPar[8] = { 0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00 }; +- byte_t abtRx[MAX_FRAME_LEN]; +- byte_t abtRxPar[MAX_FRAME_LEN]; ++ uint8_t abtAuth[4] = { 0x60,0x00,0x00,0x00 }; ++ uint8_t abtArEnc[8] = { 0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00 }; ++ uint8_t abtArEncPar[8] = { 0x00,0x00,0x00,0x00,0x00,0x00,0x00,0x00 }; ++ uint8_t abtRx[MAX_FRAME_LEN]; ++ uint8_t abtRxPar[MAX_FRAME_LEN]; + size_t szRx; + + // zveriu +@@ -414,7 +415,7 @@ + struct Crypto1State *current_state; + uint32_t i; + uint64_t key_recovered; +- byte_t flag_key_recovered = 0; // FIXME: fix the {Nr} iteration properly. This a quick fix for cases when 0xDEADBEEF {Nr} is not working ++ uint8_t flag_key_recovered = 0; // FIXME: fix the {Nr} iteration properly. This a quick fix for cases when 0xDEADBEEF {Nr} is not working + + if ( (bKeyType != keyA) && (bKeyType != keyB) ) + { +@@ -437,19 +438,19 @@ + iso14443a_crc_append(abtAuth,2); + + // Now we take over, first we need full control over the CRC +- nfc_configure(pnd,NDO_HANDLE_CRC,false); ++ nfc_device_set_property_bool(pnd,NP_HANDLE_CRC,false); + + // We need to disable EASY_FRAMING feature to talk in "raw" mode +- nfc_configure (pnd, NDO_EASY_FRAMING, false); ++ nfc_device_set_property_bool (pnd, NP_EASY_FRAMING, false); + + // Request plain tag-nonce + //printf("Nt: "); +- if (!nfc_initiator_transceive_bytes(pnd,abtAuth,4,abtRx,&szRx, NULL)) ++ if ( !nfc_initiator_transceive_bytes(pnd,abtAuth,4,abtRx,&szRx, 0)) + { + //printf("\n\nFAILURE - Failed to get TAG NONCE!!!\n\n"); + return MFCUK_FAIL_COMM; + } +- nfc_configure (pnd, NDO_EASY_FRAMING, true); ++ nfc_device_set_property_bool (pnd, NP_EASY_FRAMING, true); + + //print_hex(abtRx,4); + +@@ -631,13 +632,14 @@ + } + + // Finally we want to send arbitrary parity bits +- nfc_configure(pnd,NDO_HANDLE_PARITY,false); ++ nfc_device_set_property_bool(pnd,NP_HANDLE_PARITY,false); + + // Transmit reader-answer + //printf(" Ar: "); + //print_hex_par(abtArEnc,64,abtArEncPar); + +- if (!nfc_initiator_transceive_bits(pnd,abtArEnc,64,abtArEncPar,abtRx,&szRx,abtRxPar)) ++ szRx = nfc_initiator_transceive_bits(pnd,abtArEnc,64,abtArEncPar,abtRx,abtRxPar); ++ if (szRx <= 0) + { + if (sendSpoofAr) + { +@@ -792,7 +794,7 @@ + void print_mifare_classic_tag_actions(const char *title, mifare_classic_tag *tag) + { + uint32_t i, max_blocks, trailer_block; +- byte_t bTagType; ++ uint8_t bTagType; + mifare_classic_block_trailer *ptr_trailer = NULL; + + if (!tag) +@@ -860,26 +862,26 @@ + return; + } + +-bool mfcuk_darkside_reset_advanced(nfc_device_t* pnd) ++bool mfcuk_darkside_reset_advanced(nfc_device* pnd) + { +- if ( !nfc_configure(pnd,NDO_HANDLE_CRC,true) ) ++ if ( !nfc_device_set_property_bool(pnd,NP_HANDLE_CRC,true) ) + { +- //ERR("configuring NDO_HANDLE_CRC"); ++ //ERR("configuring NP_HANDLE_CRC"); + //return false; + } + +- if ( !nfc_configure(pnd,NDO_HANDLE_PARITY,true) ) ++ if ( !nfc_device_set_property_bool(pnd,NP_HANDLE_PARITY,true) ) + { +- //ERR("configuring NDO_HANDLE_PARITY"); ++ //ERR("configuring NP_HANDLE_PARITY"); + //return false; + } + + return true; + } + +-bool mfcuk_darkside_select_tag(nfc_device_t* pnd, int iSleepAtFieldOFF, int iSleepAfterFieldON, nfc_target_info_t* ti) ++bool mfcuk_darkside_select_tag(nfc_device* pnd, int iSleepAtFieldOFF, int iSleepAfterFieldON, nfc_target_info* ti) + { +- nfc_target_t ti_tmp; ++ nfc_target ti_tmp; + + if ( !pnd || !ti ) + { +@@ -888,9 +890,9 @@ + } + + // Drop the field for a while, so the card can reset +- if ( !nfc_configure(pnd,NDO_ACTIVATE_FIELD,false) ) ++ if ( !nfc_device_set_property_bool(pnd,NP_ACTIVATE_FIELD,false) ) + { +- ERR("configuring NDO_ACTIVATE_FIELD"); ++ ERR("configuring NP_ACTIVATE_FIELD"); + return false; + } + +@@ -898,29 +900,29 @@ + sleep(iSleepAtFieldOFF); + + // Let the reader only try once to find a tag +- if ( !nfc_configure(pnd,NDO_INFINITE_SELECT,false) ) ++ if ( !nfc_device_set_property_bool(pnd,NP_INFINITE_SELECT,false) ) + { +- ERR("configuring NDO_INFINITE_SELECT"); ++ ERR("configuring NP_INFINITE_SELECT"); + return false; + } + + // Configure the CRC and Parity settings +- if ( !nfc_configure(pnd,NDO_HANDLE_CRC,true) ) ++ if ( !nfc_device_set_property_bool(pnd,NP_HANDLE_CRC,true) ) + { +- ERR("configuring NDO_HANDLE_CRC"); ++ ERR("configuring NP_HANDLE_CRC"); + return false; + } + +- if ( !nfc_configure(pnd,NDO_HANDLE_PARITY,true) ) ++ if ( !nfc_device_set_property_bool(pnd,NP_HANDLE_PARITY,true) ) + { +- ERR("configuring NDO_HANDLE_PARITY"); ++ ERR("configuring NP_HANDLE_PARITY"); + return false; + } + + // Enable field so more power consuming cards can power themselves up +- if ( !nfc_configure(pnd,NDO_ACTIVATE_FIELD,true) ) ++ if ( !nfc_device_set_property_bool(pnd,NP_ACTIVATE_FIELD,true) ) + { +- ERR("configuring NDO_ACTIVATE_FIELD"); ++ ERR("configuring NP_ACTIVATE_FIELD"); + return false; + } + +@@ -931,7 +933,7 @@ + if (!nfc_initiator_select_passive_target(pnd, nmMifare,NULL,0,&ti_tmp)) + { + ERR("connecting to MIFARE Classic tag"); +- //nfc_disconnect(pnd); ++ //nfc_close(pnd); + return false; + } + +@@ -946,15 +948,15 @@ + int ch = 0; + char strOutputFilename[256] = {0}; // Initialize with '\0' character + //char extendedDescription[MFCUK_EXTENDED_DESCRIPTION_LENGTH] = {0}; // Initialize with '\0' character +- byte_t keyOpt[MIFARE_CLASSIC_KEY_BYTELENGTH] = {0}; +- byte_t uidOpt[MIFARE_CLASSIC_UID_BYTELENGTH] = {0}; ++ uint8_t keyOpt[MIFARE_CLASSIC_KEY_BYTELENGTH] = {0}; ++ uint8_t uidOpt[MIFARE_CLASSIC_UID_BYTELENGTH] = {0}; + mifare_classic_block_trailer *ptr_trailer = NULL; + mifare_classic_block_trailer *ptr_trailer_dump = NULL; + int sector = 0; + uint32_t block = 0; +- byte_t action = 0; +- byte_t specific_key_type = 0; +- byte_t max_sectors = MIFARE_CLASSIC_4K_MAX_SECTORS; ++ uint8_t action = 0; ++ uint8_t specific_key_type = 0; ++ uint8_t max_sectors = MIFARE_CLASSIC_4K_MAX_SECTORS; + // Defaults, can be overriden by -S and -s command line arguments + int iSleepAtFieldOFF = SLEEP_AT_FIELD_OFF; // modified with argument -S + int iSleepAfterFieldON = SLEEP_AFTER_FIELD_ON; // modified with argument -s +@@ -965,8 +967,8 @@ + int iter = 0; + + // libnfc related +- nfc_device_t* pnd; +- nfc_target_t ti; ++ nfc_device* pnd; ++ nfc_target ti; + + // mifare and crapto related + uint32_t uiErrCode = MFCUK_SUCCESS; +@@ -1004,7 +1006,7 @@ + int i, j, k; + size_t st; + int numDefKeys = mfcuk_default_keys_num; +- byte_t (*current_default_keys)[MIFARE_CLASSIC_KEY_BYTELENGTH]; ++ uint8_t (*current_default_keys)[MIFARE_CLASSIC_KEY_BYTELENGTH]; + + // At runtime, duplicate the mfcuk_default_keys[], and then add at it's bottom the default keys specified via -d command line options + if ( !(current_default_keys = malloc(numDefKeys * MIFARE_CLASSIC_KEY_BYTELENGTH)) ) +@@ -1588,7 +1590,8 @@ + + // READER INITIALIZATION BLOCK + // Try to open the NFC reader +- pnd = nfc_connect(NULL); ++ nfc_init(NULL); ++ pnd = nfc_open(NULL, NULL); + + if (pnd == NULL) + { +@@ -1598,18 +1601,20 @@ + + if ( !nfc_initiator_init(pnd) ) + { +- ERR("initializing NFC reader: %s", pnd->acName); +- nfc_disconnect(pnd); ++ ERR("initializing NFC reader: %s", nfc_device_get_name(pnd)); ++ nfc_close(pnd); ++ nfc_exit(NULL); + return 1; + } + +- printf("\nINFO: Connected to NFC reader: %s\n\n", pnd->acName); ++ printf("\nINFO: Connected to NFC reader: %s\n\n", nfc_device_get_name(pnd)); + + // Select tag and get tag info + if ( !mfcuk_darkside_select_tag(pnd, iSleepAtFieldOFF, iSleepAfterFieldON, &ti.nti) ) + { +- ERR("selecting tag on the reader %s", pnd->acName); +- nfc_disconnect(pnd); ++ ERR("selecting tag on the reader %s", nfc_device_get_name(pnd)); ++ nfc_close(pnd); ++ nfc_exit(NULL); + return 1; + } + +@@ -1654,13 +1659,13 @@ + for (i=0; i<max_sectors; i++) + { + uint64_t crntVerifKey = 0; +- byte_t crntVerifTagType = tag_recover_verify.type; ++ uint8_t crntVerifTagType = tag_recover_verify.type; + int crntNumVerifKeys = (bfOpts['D'])?(numDefKeys):(1); + mifare_param mp; + + // Depending on which of keyA or keyB the j value is, the checks and actions below will address exactly that keyA or keyB of current sector +- byte_t action_byte = ACTIONS_KEY_A + 2*(1 - (keyB-k)); +- byte_t result_byte = RESULTS_KEY_A + 2*(1 - (keyB-k)); ++ uint8_t action_byte = ACTIONS_KEY_A + 2*(1 - (keyB-k)); ++ uint8_t result_byte = RESULTS_KEY_A + 2*(1 - (keyB-k)); + + printf(" %x", i); + fflush(stdout); +@@ -1691,7 +1696,8 @@ + /* + // TODO: make this kind of key verification as part of option -a - advanced verification of keys with crapto1 rollback for double verification + // TEST +- nfc_disconnect(pnd); ++ nfc_close(pnd); ++ nfc_exit(NULL); + + // Try to open the NFC reader + pnd = nfc_connect(NULL); +@@ -1705,7 +1711,8 @@ + if ( !nfc_initiator_init(pnd) ) + { + ERR("initializing NFC reader: %s", pnd->acName); +- nfc_disconnect(pnd); ++ nfc_close(pnd); ++ nfc_exit(NULL); + return 1; + } + // TEST +@@ -1775,8 +1782,8 @@ + for (j=keyA; j<=keyB; j++) + { + // Depending on which of keyA or keyB the j value is, the checks and actions below will address exactly that keyA or keyB of current sector +- byte_t action_byte = ACTIONS_KEY_A + 2*(1 - (keyB-j)); +- byte_t result_byte = RESULTS_KEY_A + 2*(1 - (keyB-j)); ++ uint8_t action_byte = ACTIONS_KEY_A + 2*(1 - (keyB-j)); ++ uint8_t result_byte = RESULTS_KEY_A + 2*(1 - (keyB-j)); + + // We have a sector and a key-type of that sector marked for recovery and still the key was not either verified nor recovered + if ( (ptr_trailer->abtAccessBits[action_byte] & ACTIONS_RECOVER) && +@@ -1789,10 +1796,10 @@ + + // TEST + // Before starting a new recovery session, disconnect and reconnect to reader and then tag +- nfc_disconnect(pnd); ++ nfc_close(pnd); + + // Try to open the NFC reader +- pnd = nfc_connect(NULL); ++ pnd = nfc_open(NULL, NULL); + + if (pnd == NULL) + { +@@ -1802,8 +1809,9 @@ + + if ( !nfc_initiator_init(pnd) ) + { +- ERR("initializing NFC reader: %s", pnd->acName); +- nfc_disconnect(pnd); ++ ERR("initializing NFC reader: %s", nfc_device_get_name(pnd)); ++ nfc_close(pnd); ++ nfc_exit(NULL); + return 1; + } + // TEST +@@ -1874,7 +1882,8 @@ + */ + + // Clean up and release device +- nfc_disconnect(pnd); ++ nfc_close(pnd); ++ nfc_exit(NULL); + + // TODO: think which tag to output and make sure it contains all the retreived data + // TODO: make this as a function and call it after each key is verified or recovered (because of reader-locking bug) +Index: src/nfc-utils.h +=================================================================== +--- src/nfc-utils.h (revision 62) ++++ src/nfc-utils.h (working copy) +@@ -79,22 +79,22 @@ + # define ERR(...) warnx ("ERROR: " __VA_ARGS__ ) + #endif + +-byte_t oddparity (const byte_t bt); +-void oddparity_byte_ts (const byte_t * pbtData, const size_t szLen, byte_t * pbtPar); ++uint8_t oddparity (const uint8_t bt); ++void oddparity_uint8_ts (const uint8_t * pbtData, const size_t szLen, uint8_t * pbtPar); + +-void print_hex (const byte_t * pbtData, const size_t szLen); +-void print_hex_bits (const byte_t * pbtData, const size_t szBits); +-void print_hex_par (const byte_t * pbtData, const size_t szBits, const byte_t * pbtDataPar); ++void print_hex (const uint8_t * pbtData, const size_t szLen); ++void print_hex_bits (const uint8_t * pbtData, const size_t szBits); ++void print_hex_par (const uint8_t * pbtData, const size_t szBits, const uint8_t * pbtDataPar); + +-void print_nfc_iso14443a_info (const nfc_iso14443a_info_t nai, bool verbose); +-void print_nfc_iso14443b_info (const nfc_iso14443b_info_t nbi, bool verbose); +-void print_nfc_iso14443bi_info (const nfc_iso14443bi_info_t nii, bool verbose); +-void print_nfc_iso14443b2sr_info (const nfc_iso14443b2sr_info_t nsi, bool verbose); +-void print_nfc_iso14443b2ct_info (const nfc_iso14443b2ct_info_t nci, bool verbose); +-void print_nfc_felica_info (const nfc_felica_info_t nfi, bool verbose); +-void print_nfc_jewel_info (const nfc_jewel_info_t nji, bool verbose); +-void print_nfc_dep_info (const nfc_dep_info_t ndi, bool verbose); ++void print_nfc_iso14443a_info (const nfc_iso14443a_info nai, bool verbose); ++void print_nfc_iso14443b_info (const nfc_iso14443b_info nbi, bool verbose); ++void print_nfc_iso14443bi_info (const nfc_iso14443bi_info nii, bool verbose); ++void print_nfc_iso14443b2sr_info (const nfc_iso14443b2sr_info nsi, bool verbose); ++void print_nfc_iso14443b2ct_info (const nfc_iso14443b2ct_info nci, bool verbose); ++void print_nfc_felica_info (const nfc_felica_info nfi, bool verbose); ++void print_nfc_jewel_info (const nfc_jewel_info nji, bool verbose); ++void print_nfc_dep_info (const nfc_dep_info ndi, bool verbose); + +-void print_nfc_target (const nfc_target_t nt, bool verbose); ++void print_nfc_target (const nfc_target nt, bool verbose); + + #endif +Index: src/mfcuk.h +=================================================================== +--- src/mfcuk.h (revision 62) ++++ src/mfcuk.h (working copy) +@@ -95,7 +95,7 @@ + typedef struct tag_nonce_entry
+ {
+ uint32_t tagNonce; // Tag nonce we target for fixation
+- byte_t spoofFlag; // No spoofing until we have a successful auth with this tagNonce. Once we have, we want to spoof to get the encrypted 0x5 value
++ uint8_t spoofFlag; // No spoofing until we have a successful auth with this tagNonce. Once we have, we want to spoof to get the encrypted 0x5 value
+ uint32_t num_of_appearances; // For statistics, how many times this tag nonce appeared for the given SLEEP_ values
+
+ // STAGE1 data for "dark side" and lsfr_common_prefix()
+Index: src/mifare.c +=================================================================== +--- src/mifare.c (revision 62) ++++ src/mifare.c (working copy) +@@ -48,12 +48,12 @@ + * The MIFARE Classic Specification (http://www.nxp.com/acrobat/other/identification/M001053_MF1ICS50_rev5_3.pdf) explains more about this process. + */ + bool +-nfc_initiator_mifare_cmd (nfc_device_t * pnd, const mifare_cmd mc, const uint8_t ui8Block, mifare_param * pmp) ++nfc_initiator_mifare_cmd (nfc_device * pnd, const mifare_cmd mc, const uint8_t ui8Block, mifare_param * pmp) + { +- byte_t abtRx[265]; ++ uint8_t abtRx[265]; + size_t szRx = sizeof(abtRx); + size_t szParamLen; +- byte_t abtCmd[265]; ++ uint8_t abtCmd[265]; + bool bEasyFraming; + + abtCmd[0] = mc; // The MIFARE Classic command +@@ -92,16 +92,16 @@ + + // When available, copy the parameter bytes + if (szParamLen) +- memcpy (abtCmd + 2, (byte_t *) pmp, szParamLen); ++ memcpy (abtCmd + 2, (uint8_t *) pmp, szParamLen); + +- bEasyFraming = pnd->bEasyFraming; +- if (!nfc_configure (pnd, NDO_EASY_FRAMING, true)) { ++ bEasyFraming = nfc_device_get_easy_framing(pnd); ++ if (!nfc_device_set_property_bool(pnd, NP_EASY_FRAMING, true)) { + nfc_perror (pnd, "nfc_configure"); + return false; + } + // Fire the mifare command +- if (!nfc_initiator_transceive_bytes (pnd, abtCmd, 2 + szParamLen, abtRx, &szRx, NULL)) { +- if (pnd->iLastError == EINVRXFRAM) { ++ if (!nfc_initiator_transceive_bytes (pnd, abtCmd, 2 + szParamLen, abtRx, &szRx, 0)) { ++ if (nfc_device_get_last_error(pnd) == NFC_EINVARG) { + // "Invalid received frame" AKA EINVRXFRAM, usual means we are + // authenticated on a sector but the requested MIFARE cmd (read, write) + // is not permitted by current acces bytes; +@@ -109,10 +109,10 @@ + } else { + nfc_perror (pnd, "nfc_initiator_transceive_bytes"); + } +- nfc_configure (pnd, NDO_EASY_FRAMING, bEasyFraming); ++ nfc_device_set_property_bool (pnd, NP_EASY_FRAMING, bEasyFraming); + return false; + } +- if (!nfc_configure (pnd, NDO_EASY_FRAMING, bEasyFraming)) { ++ if (!nfc_device_set_property_bool (pnd, NP_EASY_FRAMING, bEasyFraming)) { + nfc_perror (pnd, "nfc_configure"); + return false; + } +Index: src/mifare.h +=================================================================== +--- src/mifare.h (revision 62) ++++ src/mifare.h (working copy) +@@ -38,7 +38,7 @@ + + # include <nfc/nfc-types.h> + +-// Compiler directive, set struct alignment to 1 byte_t for compatibility ++// Compiler directive, set struct alignment to 1 uint8_t for compatibility + # pragma pack(1) + + typedef enum { +@@ -54,16 +54,16 @@ + + // MIFARE command params + typedef struct { +- byte_t abtKey[6]; +- byte_t abtUid[4]; ++ uint8_t abtKey[6]; ++ uint8_t abtUid[4]; + } mifare_param_auth; + + typedef struct { +- byte_t abtData[16]; ++ uint8_t abtData[16]; + } mifare_param_data; + + typedef struct { +- byte_t abtValue[4]; ++ uint8_t abtValue[4]; + } mifare_param_value; + + typedef union { +@@ -75,28 +75,28 @@ + // Reset struct alignment to default + # pragma pack() + +-bool nfc_initiator_mifare_cmd (nfc_device_t * pnd, const mifare_cmd mc, const uint8_t ui8Block, mifare_param * pmp); ++bool nfc_initiator_mifare_cmd (nfc_device * pnd, const mifare_cmd mc, const uint8_t ui8Block, mifare_param * pmp); + +-// Compiler directive, set struct alignment to 1 byte_t for compatibility ++// Compiler directive, set struct alignment to 1 uint8_t for compatibility + # pragma pack(1) + + // MIFARE Classic + typedef struct { +- byte_t abtUID[4]; +- byte_t btBCC; +- byte_t btUnknown; +- byte_t abtATQA[2]; +- byte_t abtUnknown[8]; ++ uint8_t abtUID[4]; ++ uint8_t btBCC; ++ uint8_t btUnknown; ++ uint8_t abtATQA[2]; ++ uint8_t abtUnknown[8]; + } mifare_classic_block_manufacturer; + + typedef struct { +- byte_t abtData[16]; ++ uint8_t abtData[16]; + } mifare_classic_block_data; + + typedef struct { +- byte_t abtKeyA[6]; +- byte_t abtAccessBits[4]; +- byte_t abtKeyB[6]; ++ uint8_t abtKeyA[6]; ++ uint8_t abtAccessBits[4]; ++ uint8_t abtKeyB[6]; + } mifare_classic_block_trailer; + + typedef union { +@@ -111,17 +111,17 @@ + + // MIFARE Ultralight + typedef struct { +- byte_t sn0[3]; +- byte_t btBCC0; +- byte_t sn1[4]; +- byte_t btBCC1; +- byte_t internal; +- byte_t lock[2]; +- byte_t otp[4]; ++ uint8_t sn0[3]; ++ uint8_t btBCC0; ++ uint8_t sn1[4]; ++ uint8_t btBCC1; ++ uint8_t internal; ++ uint8_t lock[2]; ++ uint8_t otp[4]; + } mifareul_block_manufacturer; + + typedef struct { +- byte_t abtData[16]; ++ uint8_t abtData[16]; + } mifareul_block_data; + + typedef union { +Index: src/mfcuk_mifare.c +=================================================================== +--- src/mfcuk_mifare.c (revision 62) ++++ src/mfcuk_mifare.c (working copy) +@@ -53,7 +53,7 @@ + #include "mfcuk_mifare.h"
+
+ // Default keys used as a *BIG* mistake in many applications - especially System Integrators should pay attention!
+-byte_t mfcuk_default_keys[][MIFARE_CLASSIC_KEY_BYTELENGTH] =
++uint8_t mfcuk_default_keys[][MIFARE_CLASSIC_KEY_BYTELENGTH] =
+ {
+ {0x00, 0x00, 0x00, 0x00, 0x00, 0x00}, // Place-holder for current key to verify
+ {0xff, 0xff, 0xff, 0xff, 0xff, 0xff},
+@@ -68,7 +68,7 @@ +
+ int mfcuk_default_keys_num = sizeof(mfcuk_default_keys)/sizeof(mfcuk_default_keys[0]);
+
+-bool is_valid_block(byte_t bTagType, uint32_t uiBlock)
++bool is_valid_block(uint8_t bTagType, uint32_t uiBlock)
+ {
+ if ( IS_MIFARE_CLASSIC_1K(bTagType) && (uiBlock < MIFARE_CLASSIC_1K_MAX_BLOCKS) )
+ {
+@@ -83,7 +83,7 @@ + return false;
+ }
+
+-bool is_valid_sector(byte_t bTagType, uint32_t uiSector)
++bool is_valid_sector(uint8_t bTagType, uint32_t uiSector)
+ {
+ if ( IS_MIFARE_CLASSIC_1K(bTagType) && (uiSector < MIFARE_CLASSIC_1K_MAX_SECTORS) )
+ {
+@@ -98,7 +98,7 @@ + return false;
+ }
+
+-bool is_first_block(byte_t bTagType, uint32_t uiBlock)
++bool is_first_block(uint8_t bTagType, uint32_t uiBlock)
+ {
+ if ( !is_valid_block(bTagType, uiBlock) )
+ {
+@@ -121,7 +121,7 @@ + return false;
+ }
+
+-bool is_trailer_block(byte_t bTagType, uint32_t uiBlock)
++bool is_trailer_block(uint8_t bTagType, uint32_t uiBlock)
+ {
+ if ( !is_valid_block(bTagType, uiBlock) )
+ {
+@@ -144,7 +144,7 @@ + return false;
+ }
+
+-uint32_t get_first_block(byte_t bTagType, uint32_t uiBlock)
++uint32_t get_first_block(uint8_t bTagType, uint32_t uiBlock)
+ {
+ if ( !is_valid_block(bTagType, uiBlock) )
+ {
+@@ -167,7 +167,7 @@ + return MIFARE_CLASSIC_INVALID_BLOCK;
+ }
+
+-uint32_t get_trailer_block(byte_t bTagType, uint32_t uiBlock)
++uint32_t get_trailer_block(uint8_t bTagType, uint32_t uiBlock)
+ {
+ if ( !is_valid_block(bTagType, uiBlock) )
+ {
+@@ -190,7 +190,7 @@ + return MIFARE_CLASSIC_INVALID_BLOCK;
+ }
+
+-bool is_big_sector(byte_t bTagType, uint32_t uiSector)
++bool is_big_sector(uint8_t bTagType, uint32_t uiSector)
+ {
+ if ( !is_valid_sector(bTagType, uiSector) )
+ {
+@@ -205,7 +205,7 @@ + return false;
+ }
+
+-uint32_t get_first_block_for_sector(byte_t bTagType, uint32_t uiSector)
++uint32_t get_first_block_for_sector(uint8_t bTagType, uint32_t uiSector)
+ {
+ if ( !is_valid_sector(bTagType, uiSector) )
+ {
+@@ -228,7 +228,7 @@ + return MIFARE_CLASSIC_INVALID_BLOCK;
+ }
+
+-uint32_t get_trailer_block_for_sector(byte_t bTagType, uint32_t uiSector)
++uint32_t get_trailer_block_for_sector(uint8_t bTagType, uint32_t uiSector)
+ {
+ if ( !is_valid_sector(bTagType, uiSector) )
+ {
+@@ -251,7 +251,7 @@ + return MIFARE_CLASSIC_INVALID_BLOCK;
+ }
+
+-uint32_t get_sector_for_block(byte_t bTagType, uint32_t uiBlock)
++uint32_t get_sector_for_block(uint8_t bTagType, uint32_t uiBlock)
+ {
+ if ( !is_valid_block(bTagType, uiBlock) )
+ {
+@@ -274,44 +274,44 @@ + return MIFARE_CLASSIC_INVALID_BLOCK;
+ }
+
+-bool is_first_sector(byte_t bTagType, uint32_t uiSector)
++bool is_first_sector(uint8_t bTagType, uint32_t uiSector)
+ {
+ // TODO: write code
+ return false;
+ }
+
+-bool is_first_big_sector(byte_t bTagType, uint32_t uiSector)
++bool is_first_big_sector(uint8_t bTagType, uint32_t uiSector)
+ {
+ // TODO: write code
+ return false;
+ }
+
+-bool is_first_small_sector(byte_t bTagType, uint32_t uiSector)
++bool is_first_small_sector(uint8_t bTagType, uint32_t uiSector)
+ {
+ // TODO: write code
+ return false;
+ }
+
+-bool is_last_sector(byte_t bTagType, uint32_t uiSector)
++bool is_last_sector(uint8_t bTagType, uint32_t uiSector)
+ {
+ // TODO: write code
+ return false;
+ }
+
+-bool is_last_big_sector(byte_t bTagType, uint32_t uiSector)
++bool is_last_big_sector(uint8_t bTagType, uint32_t uiSector)
+ {
+ // TODO: write code
+ return false;
+ }
+
+-bool is_last_small_sector(byte_t bTagType, uint32_t uiSector)
++bool is_last_small_sector(uint8_t bTagType, uint32_t uiSector)
+ {
+ // TODO: write code
+ return false;
+ }
+
+ // Test case function for checking correct functionality of the block/sector is_ ang get_ functions
+-void test_mifare_classic_blocks_sectors_functions(byte_t bTagType)
++void test_mifare_classic_blocks_sectors_functions(uint8_t bTagType)
+ {
+ uint32_t i;
+ uint32_t max_blocks, max_sectors;
+@@ -460,7 +460,7 @@ + void print_mifare_classic_tag_keys(const char *title, mifare_classic_tag *tag)
+ {
+ uint32_t i, max_blocks, trailer_block;
+- byte_t bTagType;
++ uint8_t bTagType;
+ mifare_classic_block_trailer *ptr_trailer = NULL;
+
+ if (!tag)
+@@ -521,7 +521,7 @@ + return;
+ }
+
+-bool mfcuk_key_uint64_to_arr(const uint64_t *ui64Key, byte_t *arr6Key)
++bool mfcuk_key_uint64_to_arr(const uint64_t *ui64Key, uint8_t *arr6Key)
+ {
+ int i;
+
+@@ -532,13 +532,13 @@ +
+ for (i = 0; i<MIFARE_CLASSIC_KEY_BYTELENGTH; i++)
+ {
+- arr6Key[i] = (byte_t) (((*ui64Key) >> 8*(MIFARE_CLASSIC_KEY_BYTELENGTH - i - 1)) & 0xFF);
++ arr6Key[i] = (uint8_t) (((*ui64Key) >> 8*(MIFARE_CLASSIC_KEY_BYTELENGTH - i - 1)) & 0xFF);
+ }
+
+ return true;
+ }
+
+-bool mfcuk_key_arr_to_uint64(const byte_t *arr6Key, uint64_t *ui64Key)
++bool mfcuk_key_arr_to_uint64(const uint8_t *arr6Key, uint64_t *ui64Key)
+ {
+ uint64_t key = 0;
+ int i;
+Index: src/mfcuk_mifare.h +=================================================================== +--- src/mfcuk_mifare.h (revision 62) ++++ src/mfcuk_mifare.h (working copy) +@@ -101,7 +101,7 @@ + // Define an extended type of dump, basically a wrapper dump around basic tag dump
+ typedef struct {
+ uint32_t uid; // looks redundant, but it is easier to use dmp.uid instead of dmp.amb.mbm.abtUID[0]...[3]
+- byte_t type; // ATS/SAK from ti.tia.btSak, example 0x08h for Mifare 1K, 0x18h for Mifare 4K
++ uint8_t type; // ATS/SAK from ti.tia.btSak, example 0x08h for Mifare 1K, 0x18h for Mifare 4K
+ char datetime[14]; // non-zero-terminated date-time of dump in format YYYYMMDDH24MISS, example 20091114231541 - 14 Nov 2009, 11:15:41 PM
+ char description[MFCUK_EXTENDED_DESCRIPTION_LENGTH]; // a description of the tag dump, example "RATB_DUMP_BEFORE_PAY"
+ mifare_classic_tag tag_basic;
+@@ -114,32 +114,32 @@ + } mifare_key_type;
+
+ // Default keys used as a *BIG* mistake in many applications - especially System Integrators should pay attention!
+-extern byte_t mfcuk_default_keys[][MIFARE_CLASSIC_KEY_BYTELENGTH];
++extern uint8_t mfcuk_default_keys[][MIFARE_CLASSIC_KEY_BYTELENGTH];
+ extern int mfcuk_default_keys_num;
+
+-bool is_valid_block(byte_t bTagType, uint32_t uiBlock);
+-bool is_valid_sector(byte_t bTagType, uint32_t uiSector);
+-bool is_first_block(byte_t bTagType, uint32_t uiBlock);
+-bool is_trailer_block(byte_t bTagType, uint32_t uiBlock);
+-uint32_t get_first_block(byte_t bTagType, uint32_t uiBlock);
+-uint32_t get_trailer_block(byte_t bTagType, uint32_t uiBlock);
+-bool is_big_sector(byte_t bTagType, uint32_t uiSector);
+-uint32_t get_first_block_for_sector(byte_t bTagType, uint32_t uiSector);
+-uint32_t get_trailer_block_for_sector(byte_t bTagType, uint32_t uiSector);
+-uint32_t get_sector_for_block(byte_t bTagType, uint32_t uiBlock);
+-bool is_first_sector(byte_t bTagType, uint32_t uiSector);
+-bool is_first_big_sector(byte_t bTagType, uint32_t uiSector);
+-bool is_first_small_sector(byte_t bTagType, uint32_t uiSector);
+-bool is_last_sector(byte_t bTagType, uint32_t uiSector);
+-bool is_last_big_sector(byte_t bTagType, uint32_t uiSector);
+-bool is_last_small_sector(byte_t bTagType, uint32_t uiSector);
+-void test_mifare_classic_blocks_sectors_functions(byte_t bTagType);
++bool is_valid_block(uint8_t bTagType, uint32_t uiBlock);
++bool is_valid_sector(uint8_t bTagType, uint32_t uiSector);
++bool is_first_block(uint8_t bTagType, uint32_t uiBlock);
++bool is_trailer_block(uint8_t bTagType, uint32_t uiBlock);
++uint32_t get_first_block(uint8_t bTagType, uint32_t uiBlock);
++uint32_t get_trailer_block(uint8_t bTagType, uint32_t uiBlock);
++bool is_big_sector(uint8_t bTagType, uint32_t uiSector);
++uint32_t get_first_block_for_sector(uint8_t bTagType, uint32_t uiSector);
++uint32_t get_trailer_block_for_sector(uint8_t bTagType, uint32_t uiSector);
++uint32_t get_sector_for_block(uint8_t bTagType, uint32_t uiBlock);
++bool is_first_sector(uint8_t bTagType, uint32_t uiSector);
++bool is_first_big_sector(uint8_t bTagType, uint32_t uiSector);
++bool is_first_small_sector(uint8_t bTagType, uint32_t uiSector);
++bool is_last_sector(uint8_t bTagType, uint32_t uiSector);
++bool is_last_big_sector(uint8_t bTagType, uint32_t uiSector);
++bool is_last_small_sector(uint8_t bTagType, uint32_t uiSector);
++void test_mifare_classic_blocks_sectors_functions(uint8_t bTagType);
+ bool mfcuk_save_tag_dump(char *filename, mifare_classic_tag *tag);
+ bool mfcuk_save_tag_dump_ext(char *filename, mifare_classic_tag_ext *tag_ext);
+ bool mfcuk_load_tag_dump(char *filename, mifare_classic_tag *tag);
+ bool mfcuk_load_tag_dump_ext(char *filename, mifare_classic_tag_ext *tag_ext);
+ void print_mifare_classic_tag_keys(const char *title, mifare_classic_tag *tag);
+-bool mfcuk_key_uint64_to_arr(const uint64_t *ui64Key, byte_t *arr6Key);
+-bool mfcuk_key_arr_to_uint64(const byte_t *arr6Key, uint64_t *ui64Key);
++bool mfcuk_key_uint64_to_arr(const uint64_t *ui64Key, uint8_t *arr6Key);
++bool mfcuk_key_arr_to_uint64(const uint8_t *arr6Key, uint64_t *ui64Key);
+
+ #endif // _MFCUK_MIFARE_H_
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