//----------------------------------------------------------------------------- // Copyright (C) 2010 iZsh // // This code is licensed to you under the terms of the GNU GPL, version 2 or, // at your option, any later version. See the LICENSE.txt file for the text of // the license. //----------------------------------------------------------------------------- // High frequency Legic commands //----------------------------------------------------------------------------- #include "cmdhflegic.h" #include // for Mingw readline #include // tolower #ifdef HAVE_READLINE #include #endif #include "cmdparser.h" // command_t #include "comms.h" // clearCommandBuffer #include "cmdtrace.h" #include "crc.h" #include "crc16.h" #include "fileutils.h" //saveFile static int CmdHelp(const char *Cmd); #define MAX_LENGTH 1024 static int usage_legic_calccrc(void) { PrintAndLogEx(NORMAL, "Calculates the legic crc8/crc16 on the given data."); PrintAndLogEx(NORMAL, "There must be an even number of hexsymbols as input.\n"); PrintAndLogEx(NORMAL, "Usage: hf legic crc [h] d u c <8|16>\n"); PrintAndLogEx(NORMAL, "Options:"); PrintAndLogEx(NORMAL, " h : this help"); PrintAndLogEx(NORMAL, " d : (hex symbols) bytes to calculate crc over"); PrintAndLogEx(NORMAL, " u : MCC hexbyte"); PrintAndLogEx(NORMAL, " c <8|16> : Crc type"); PrintAndLogEx(NORMAL, ""); PrintAndLogEx(NORMAL, "Examples:"); PrintAndLogEx(NORMAL, _YELLOW_(" hf legic crc d deadbeef1122")); PrintAndLogEx(NORMAL, _YELLOW_(" hf legic crc d deadbeef1122 u 9A c 16")); return PM3_SUCCESS; } static int usage_legic_rdbl(void) { PrintAndLogEx(NORMAL, "Read data from a LEGIC Prime tag\n"); PrintAndLogEx(NORMAL, "Usage: hf legic rdbl [h] [o ] [l ] [iv ]\n"); PrintAndLogEx(NORMAL, "Options:"); PrintAndLogEx(NORMAL, " h : this help"); PrintAndLogEx(NORMAL, " o : (hex) offset in data array to start download from"); PrintAndLogEx(NORMAL, " l : (hex) number of bytes to read"); PrintAndLogEx(NORMAL, " i : (hex) (optional) Initialization vector to use. Must be odd and 7bits max"); PrintAndLogEx(NORMAL, ""); PrintAndLogEx(NORMAL, "Examples:"); PrintAndLogEx(NORMAL, _YELLOW_(" hf legic rdbl o 0 l 16 - reads from byte[0] 0x16 bytes(system header)")); PrintAndLogEx(NORMAL, _YELLOW_(" hf legic rdbl o 0 l 4 iv 55 - reads from byte[0] 0x4 bytes with IV 0x55")); PrintAndLogEx(NORMAL, _YELLOW_(" hf legic rdbl o 0 l 100 iv 55 - reads 0x100 bytes with IV 0x55")); return PM3_SUCCESS; } static int usage_legic_sim(void) { PrintAndLogEx(NORMAL, "Simulates a LEGIC Prime tag. MIM22, MIM256, MIM1024 types can be emulated"); PrintAndLogEx(NORMAL, "Use " _YELLOW_("`hf legic eload`") " to upload a dump into emulator memory\n"); PrintAndLogEx(NORMAL, "Usage: hf legic sim [h] \n"); PrintAndLogEx(NORMAL, "Options:"); PrintAndLogEx(NORMAL, " h : this help"); PrintAndLogEx(NORMAL, " : 0 = MIM22"); PrintAndLogEx(NORMAL, " : 1 = MIM256 (default)"); PrintAndLogEx(NORMAL, " : 2 = MIM1024"); PrintAndLogEx(NORMAL, ""); PrintAndLogEx(NORMAL, "Examples:"); PrintAndLogEx(NORMAL, _YELLOW_(" hf legic sim 2")); return PM3_SUCCESS; } static int usage_legic_wrbl(void) { PrintAndLogEx(NORMAL, "Write data to a LEGIC Prime tag. It autodetects tagsize to make sure size\n"); PrintAndLogEx(NORMAL, "Usage: hf legic wrbl [h] [o ] [d ] [y]\n"); PrintAndLogEx(NORMAL, "Options:"); PrintAndLogEx(NORMAL, " h : this help"); PrintAndLogEx(NORMAL, " o : (hex) offset in data array to start writing"); //PrintAndLogEx(NORMAL, " : (optional) Initialization vector to use (ODD and 7bits)"); PrintAndLogEx(NORMAL, " d : (hex symbols) bytes to write "); PrintAndLogEx(NORMAL, " y : Auto-confirm dangerous operations "); PrintAndLogEx(NORMAL, ""); PrintAndLogEx(NORMAL, "Examples:"); PrintAndLogEx(NORMAL, _YELLOW_(" hf legic wrbl o 10 d 11223344 - Write 0x11223344 starting from offset 0x10")); return PM3_SUCCESS; } static int usage_legic_reader(void) { PrintAndLogEx(NORMAL, "Read UID and type information from a LEGIC Prime tag\n"); PrintAndLogEx(NORMAL, "Usage: hf legic reader [h]\n"); PrintAndLogEx(NORMAL, "Options:"); PrintAndLogEx(NORMAL, " h : this help"); PrintAndLogEx(NORMAL, ""); PrintAndLogEx(NORMAL, "Examples:"); PrintAndLogEx(NORMAL, _YELLOW_(" hf legic reader")); return PM3_SUCCESS; } static int usage_legic_info(void) { PrintAndLogEx(NORMAL, "Reads information from a LEGIC Prime tag like systemarea, user areas etc\n"); PrintAndLogEx(NORMAL, "Usage: hf legic info [h]\n"); PrintAndLogEx(NORMAL, "Options:"); PrintAndLogEx(NORMAL, " h : this help"); PrintAndLogEx(NORMAL, ""); PrintAndLogEx(NORMAL, "Examples:"); PrintAndLogEx(NORMAL, _YELLOW_(" hf legic info")); return PM3_SUCCESS; } static int usage_legic_dump(void) { PrintAndLogEx(NORMAL, "Read all memory from LEGIC Prime MIM22, MIM256, MIM1024"); PrintAndLogEx(NORMAL, "and saves bin/eml/json dump file"); PrintAndLogEx(NORMAL, "It autodetects card type.\n"); PrintAndLogEx(NORMAL, "Usage: hf legic dump [h] [x] [f ]\n"); PrintAndLogEx(NORMAL, "Options:"); PrintAndLogEx(NORMAL, " h : this help"); PrintAndLogEx(NORMAL, " f : filename w/o '.bin' to dump bytes"); PrintAndLogEx(NORMAL, " x : deobfuscate dump data (xor with MCC)"); PrintAndLogEx(NORMAL, ""); PrintAndLogEx(NORMAL, "Examples:"); PrintAndLogEx(NORMAL, _YELLOW_(" hf legic dump - uses UID as filename")); PrintAndLogEx(NORMAL, _YELLOW_(" hf legic dump f myfile")); PrintAndLogEx(NORMAL, _YELLOW_(" hf legic dump x")); return PM3_SUCCESS; } static int usage_legic_restore(void) { PrintAndLogEx(NORMAL, "Reads binary file and it autodetects card type and verifies that the file has the same size"); PrintAndLogEx(NORMAL, "Then write the data back to card. All bytes except the first 7bytes [UID(4) MCC(1) DCF(2)]\n"); PrintAndLogEx(NORMAL, "Usage: hf legic restore [h] [x] [f ]\n"); PrintAndLogEx(NORMAL, "Options:"); PrintAndLogEx(NORMAL, " h : this help"); PrintAndLogEx(NORMAL, " f : filename w/o '.bin' to restore bytes on to card from"); PrintAndLogEx(NORMAL, " x : obfuscate dump data (xor with MCC)"); PrintAndLogEx(NORMAL, ""); PrintAndLogEx(NORMAL, "Examples:"); PrintAndLogEx(NORMAL, _YELLOW_(" hf legic restore f myfile")); return PM3_SUCCESS; } static int usage_legic_eload(void) { PrintAndLogEx(NORMAL, "It loads a binary dump into emulator memory\n"); PrintAndLogEx(NORMAL, "Usage: hf legic eload [h] [card memory] [f ]\n"); PrintAndLogEx(NORMAL, "Options:"); PrintAndLogEx(NORMAL, " h : this help"); PrintAndLogEx(NORMAL, " [card memory] : 0 = MIM22"); PrintAndLogEx(NORMAL, " : 1 = MIM256 (default)"); PrintAndLogEx(NORMAL, " : 2 = MIM1024"); PrintAndLogEx(NORMAL, " f : filename w/o .bin to load"); PrintAndLogEx(NORMAL, ""); PrintAndLogEx(NORMAL, "Examples:"); PrintAndLogEx(NORMAL, _YELLOW_(" hf legic eload 2 f myfile")); return PM3_SUCCESS; } static int usage_legic_esave(void) { PrintAndLogEx(NORMAL, "It saves bin/eml/json dump file of emulator memory\n"); PrintAndLogEx(NORMAL, "Usage: hf legic esave [h] [card memory] f \n"); PrintAndLogEx(NORMAL, "Options:"); PrintAndLogEx(NORMAL, " h : this help"); PrintAndLogEx(NORMAL, " [card memory] : 0 = MIM22"); PrintAndLogEx(NORMAL, " : 1 = MIM256 (default)"); PrintAndLogEx(NORMAL, " : 2 = MIM1024"); PrintAndLogEx(NORMAL, " f : filename w/o .bin to load"); PrintAndLogEx(NORMAL, ""); PrintAndLogEx(NORMAL, "Examples:"); PrintAndLogEx(NORMAL, _YELLOW_(" hf legic esave 2 - uses UID as filename")); PrintAndLogEx(NORMAL, _YELLOW_(" hf legic esave 2 f myfile")); return PM3_SUCCESS; } static int usage_legic_wipe(void) { PrintAndLogEx(NORMAL, "Fills a LEGIC Prime tags memory with zeros. From byte7 and to the end"); PrintAndLogEx(NORMAL, "It autodetects card type\n"); PrintAndLogEx(NORMAL, "Usage: hf legic wipe [h]\n"); PrintAndLogEx(NORMAL, "Options:"); PrintAndLogEx(NORMAL, " h : this help"); PrintAndLogEx(NORMAL, ""); PrintAndLogEx(NORMAL, "Examples:"); PrintAndLogEx(NORMAL, _YELLOW_(" hf legic wipe")); return PM3_SUCCESS; } static bool legic_xor(uint8_t *data, uint16_t cardsize) { if (cardsize <= 22) { PrintAndLogEx(INFO, "No obsfuscation such small dump"); return false; } uint8_t crc = data[4]; uint32_t calc_crc = CRC8Legic(data, 4); if (crc != calc_crc) { PrintAndLogEx(INFO, "Crc mismatch, obsfuscation not possible"); return false; } for (uint16_t i = 22; i < cardsize; i++) { data[i] ^= crc; } PrintAndLogEx(SUCCESS, "(De)Obsfuscation done"); return true; } /* * Output BigBuf and deobfuscate LEGIC RF tag data. * This is based on information given in the talk held * by Henryk Ploetz and Karsten Nohl at 26c3 */ static int CmdLegicInfo(const char *Cmd) { char cmdp = tolower(param_getchar(Cmd, 0)); if (cmdp == 'h') return usage_legic_info(); int i = 0, k = 0, segmentNum = 0, segment_len = 0, segment_flag = 0; int crc = 0, wrp = 0, wrc = 0; uint8_t stamp_len = 0; uint16_t datalen = 0; char token_type[6] = {0, 0, 0, 0, 0, 0}; int dcf = 0; int bIsSegmented = 0; // tagtype legic_card_select_t card; if (legic_get_type(&card) != PM3_SUCCESS) { PrintAndLogEx(WARNING, "Failed to identify tagtype"); return PM3_ESOFT; } PrintAndLogEx(SUCCESS, "Reading full tag memory of " _YELLOW_("%d") " bytes...", card.cardsize); // allocate receiver buffer uint8_t *data = calloc(card.cardsize, sizeof(uint8_t)); if (!data) { PrintAndLogEx(WARNING, "Cannot allocate memory"); return PM3_EMALLOC; } int status = legic_read_mem(0, card.cardsize, 0x55, data, &datalen); if (status != PM3_SUCCESS) { PrintAndLogEx(WARNING, "Failed reading memory"); free(data); return status; } // Output CDF System area (9 bytes) plus remaining header area (12 bytes) crc = data[4]; uint32_t calc_crc = CRC8Legic(data, 4); PrintAndLogEx(SUCCESS, " " _CYAN_("CDF: System Area")); PrintAndLogEx(NORMAL, "------------------------------------------------------"); PrintAndLogEx(SUCCESS, "MCD: " _GREEN_("%02X") " MSN: " _GREEN_("%s") " MCC: " _GREEN_("%02X") " (%s)", data[0], sprint_hex(data + 1, 3), data[4], (calc_crc == crc) ? _GREEN_("OK") : _RED_("Fail") ); // MCD = Manufacturer ID (should be list meaning something?) token_type[0] = 0; dcf = ((int)data[6] << 8) | (int)data[5]; // New unwritten media? if (dcf == 0xFFFF) { PrintAndLogEx(SUCCESS, "DCF: %d (%02x %02x), Token Type=NM (New Media)", dcf, data[5], data[6] ); } else if (dcf > 60000) { // Master token? int fl = 0; if (data[6] == 0xec) { strncpy(token_type, "XAM", sizeof(token_type) - 1); fl = 1; stamp_len = 0x0c - (data[5] >> 4); } else { switch (data[5] & 0x7f) { case 0x00 ... 0x2f: strncpy(token_type, "IAM", sizeof(token_type) - 1); fl = (0x2f - (data[5] & 0x7f)) + 1; break; case 0x30 ... 0x6f: strncpy(token_type, "SAM", sizeof(token_type) - 1); fl = (0x6f - (data[5] & 0x7f)) + 1; break; case 0x70 ... 0x7f: strncpy(token_type, "GAM", sizeof(token_type) - 1); fl = (0x7f - (data[5] & 0x7f)) + 1; break; } stamp_len = 0xfc - data[6]; } PrintAndLogEx(SUCCESS, "DCF: %d (%02x %02x), Token Type=" _YELLOW_("%s") " (OLE=%01u), OL=%02u, FL=%02u", dcf, data[5], data[6], token_type, (data[5] & 0x80) >> 7, stamp_len, fl ); } else { // Is IM(-S) type of card... if (data[7] == 0x9F && data[8] == 0xFF) { bIsSegmented = 1; strncpy(token_type, "IM-S", sizeof(token_type) - 1); } else { strncpy(token_type, "IM", sizeof(token_type) - 1); } PrintAndLogEx(SUCCESS, "DCF: %d (%02x %02x), Token Type = %s (OLE = %01u)", dcf, data[5], data[6], token_type, (data[5] & 0x80) >> 7 ); } // Makes no sence to show this on blank media... if (dcf != 0xFFFF) { if (bIsSegmented) { PrintAndLogEx(SUCCESS, "WRP = %02u, WRC = %01u, RD = %01u, SSC = %02X", data[7] & 0x0f, (data[7] & 0x70) >> 4, (data[7] & 0x80) >> 7, data[8] ); } // Header area is only available on IM-S cards, on master tokens this data is the master token data itself if (bIsSegmented || dcf > 60000) { if (dcf > 60000) { PrintAndLogEx(SUCCESS, "Master token data"); PrintAndLogEx(SUCCESS, "%s", sprint_hex(data + 8, 14)); } else { PrintAndLogEx(SUCCESS, "Remaining Header Area"); PrintAndLogEx(SUCCESS, "%s", sprint_hex(data + 9, 13)); } } } PrintAndLogEx(NORMAL, "------------------------------------------------------"); uint8_t segCrcBytes[8] = {0, 0, 0, 0, 0, 0, 0, 0}; uint32_t segCalcCRC = 0; uint32_t segCRC = 0; // Not Data card? if (dcf > 60000) goto out; PrintAndLogEx(SUCCESS, _CYAN_("ADF: User Area")); PrintAndLogEx(NORMAL, "------------------------------------------------------"); if (bIsSegmented) { // Data start point on segmented cards i = 22; // decode segments for (segmentNum = 1; segmentNum < 128; segmentNum++) { segment_len = ((data[i + 1] ^ crc) & 0x0f) * 256 + (data[i] ^ crc); segment_flag = ((data[i + 1] ^ crc) & 0xf0) >> 4; wrp = (data[i + 2] ^ crc); wrc = ((data[i + 3] ^ crc) & 0x70) >> 4; bool hasWRC = (wrc > 0); bool hasWRP = (wrp > wrc); int wrp_len = (wrp - wrc); int remain_seg_payload_len = (segment_len - wrp - 5); // validate segment-crc segCrcBytes[0] = data[0]; //uid0 segCrcBytes[1] = data[1]; //uid1 segCrcBytes[2] = data[2]; //uid2 segCrcBytes[3] = data[3]; //uid3 segCrcBytes[4] = (data[i] ^ crc); //hdr0 segCrcBytes[5] = (data[i + 1] ^ crc); //hdr1 segCrcBytes[6] = (data[i + 2] ^ crc); //hdr2 segCrcBytes[7] = (data[i + 3] ^ crc); //hdr3 segCalcCRC = CRC8Legic(segCrcBytes, 8); segCRC = data[i + 4] ^ crc; PrintAndLogEx(SUCCESS, "Segment | " _YELLOW_("%02u"), segmentNum); PrintAndLogEx(SUCCESS, "raw header | 0x%02X 0x%02X 0x%02X 0x%02X", data[i] ^ crc, data[i + 1] ^ crc, data[i + 2] ^ crc, data[i + 3] ^ crc ); PrintAndLogEx(SUCCESS, "Segment len | %u, Flag: 0x%X (valid:%01u, last:%01u)", segment_len, segment_flag, (segment_flag & 0x4) >> 2, (segment_flag & 0x8) >> 3 ); PrintAndLogEx(SUCCESS, " | WRP: %02u, WRC: %02u, RD: %01u, CRC: 0x%02X (%s)", wrp, wrc, ((data[i + 3] ^ crc) & 0x80) >> 7, segCRC, (segCRC == segCalcCRC) ? _GREEN_("OK") : _RED_("Fail") ); i += 5; if (hasWRC) { PrintAndLogEx(SUCCESS, "\nWRC protected area: (I %d | K %d| WRC %d)", i, k, wrc); PrintAndLogEx(NORMAL, "\nrow | data"); PrintAndLogEx(NORMAL, "-----+------------------------------------------------"); for (k = i; k < (i + wrc); ++k) data[k] ^= crc; print_hex_break(data + i, wrc, 16); PrintAndLogEx(NORMAL, "-----+------------------------------------------------\n"); i += wrc; } if (hasWRP) { PrintAndLogEx(SUCCESS, "Remaining write protected area: (I %d | K %d | WRC %d | WRP %d WRP_LEN %d)", i, k, wrc, wrp, wrp_len); PrintAndLogEx(NORMAL, "\nrow | data"); PrintAndLogEx(NORMAL, "-----+------------------------------------------------"); for (k = i; k < (i + wrp_len); ++k) data[k] ^= crc; print_hex_break(data + i, wrp_len, 16); PrintAndLogEx(NORMAL, "-----+------------------------------------------------\n"); i += wrp_len; // does this one work? (Answer: Only if KGH/BGH is used with BCD encoded card number! So maybe this will show just garbage...) if (wrp_len == 8) { PrintAndLogEx(SUCCESS, "Card ID: " _YELLOW_("%2X%02X%02X"), data[i - 4] ^ crc, data[i - 3] ^ crc, data[i - 2] ^ crc ); } } if (remain_seg_payload_len > 0) { PrintAndLogEx(SUCCESS, "Remaining segment payload: (I %d | K %d | Remain LEN %d)", i, k, remain_seg_payload_len); PrintAndLogEx(NORMAL, "\nrow | data"); PrintAndLogEx(NORMAL, "-----+------------------------------------------------"); for (k = i; k < (i + remain_seg_payload_len); ++k) data[k] ^= crc; print_hex_break(data + i, remain_seg_payload_len, 16); PrintAndLogEx(NORMAL, "-----+------------------------------------------------\n"); i += remain_seg_payload_len; } // end with last segment if (segment_flag & 0x8) goto out; } // end for loop } else { // Data start point on unsegmented cards i = 8; wrp = data[7] & 0x0F; wrc = (data[7] & 0x70) >> 4; bool hasWRC = (wrc > 0); bool hasWRP = (wrp > wrc); int wrp_len = (wrp - wrc); int remain_seg_payload_len = (card.cardsize - 22 - wrp); PrintAndLogEx(SUCCESS, "Unsegmented card - WRP: %02u, WRC: %02u, RD: %01u", wrp, wrc, (data[7] & 0x80) >> 7 ); if (hasWRC) { PrintAndLogEx(SUCCESS, "WRC protected area: (I %d | WRC %d)", i, wrc); PrintAndLogEx(NORMAL, "\nrow | data"); PrintAndLogEx(NORMAL, "-----+------------------------------------------------"); print_hex_break(data + i, wrc, 16); PrintAndLogEx(NORMAL, "-----+------------------------------------------------\n"); i += wrc; } if (hasWRP) { PrintAndLogEx(SUCCESS, "Remaining write protected area: (I %d | WRC %d | WRP %d | WRP_LEN %d)", i, wrc, wrp, wrp_len); PrintAndLogEx(NORMAL, "\nrow | data"); PrintAndLogEx(NORMAL, "-----+------------------------------------------------"); print_hex_break(data + i, wrp_len, 16); PrintAndLogEx(NORMAL, "-----+------------------------------------------------\n"); i += wrp_len; // Q: does this one work? // A: Only if KGH/BGH is used with BCD encoded card number. Maybe this will show just garbage if (wrp_len == 8) { PrintAndLogEx(SUCCESS, "Card ID: " _YELLOW_("%2X%02X%02X"), data[i - 4], data[i - 3], data[i - 2] ); } } if (remain_seg_payload_len > 0) { PrintAndLogEx(SUCCESS, "Remaining segment payload: (I %d | Remain LEN %d)", i, remain_seg_payload_len); PrintAndLogEx(NORMAL, "\nrow | data"); PrintAndLogEx(NORMAL, "-----+------------------------------------------------"); print_hex_break(data + i, remain_seg_payload_len, 16); PrintAndLogEx(NORMAL, "-----+------------------------------------------------\n"); } } out: free(data); return PM3_SUCCESS; } // params: // offset in data memory // number of bytes to read static int CmdLegicRdbl(const char *Cmd) { uint32_t offset = 0, len = 0, iv = 1; bool errors = false; uint8_t cmdp = 0; while (param_getchar(Cmd, cmdp) != 0x00 && !errors) { switch (tolower(param_getchar(Cmd, cmdp))) { case 'h' : return usage_legic_rdbl(); case 'o' : offset = param_get32ex(Cmd, cmdp + 1, 0, 16); cmdp += 2; break; case 'l' : len = param_get32ex(Cmd, cmdp + 1, 0, 16); cmdp += 2; break; case 'i' : iv = param_get32ex(Cmd, cmdp + 1, 1, 16); cmdp += 2; break; default : PrintAndLogEx(WARNING, "Unknown parameter '%c'", param_getchar(Cmd, cmdp)); errors = true; break; } } //Validations if (errors || strlen(Cmd) == 0) return usage_legic_rdbl(); // sanity checks if (len + offset >= MAX_LENGTH) { PrintAndLogEx(WARNING, "Out-of-bounds, Cardsize = %d, [offset+len = %d ]", MAX_LENGTH, len + offset); return PM3_EOUTOFBOUND; } PrintAndLogEx(SUCCESS, "Reading %d bytes, from offset %d", len, offset); // allocate receiver buffer uint8_t *data = calloc(len, sizeof(uint8_t)); if (!data) { PrintAndLogEx(WARNING, "Cannot allocate memory"); return PM3_EMALLOC; } uint16_t datalen = 0; int status = legic_read_mem(offset, len, iv, data, &datalen); if (status == PM3_SUCCESS) { PrintAndLogEx(NORMAL, "\n ## | 0 1 2 3 4 5 6 7 8 9 A B C D E F 10 11 12 13 14 15 16 17 18 19 1A 1B 1C 1D 1E 1F"); PrintAndLogEx(NORMAL, "-----+------------------------------------------------------------------------------------------------"); print_hex_break(data, datalen, 32); } free(data); return status; } static int CmdLegicSim(const char *Cmd) { char cmdp = tolower(param_getchar(Cmd, 0)); if (strlen(Cmd) == 0 || cmdp == 'h') return usage_legic_sim(); struct { uint8_t tagtype; bool send_reply; } PACKED payload; payload.send_reply = true; payload.tagtype = param_get8ex(Cmd, 0, 1, 10); if (payload.tagtype > 2) { return usage_legic_sim(); } clearCommandBuffer(); SendCommandNG(CMD_HF_LEGIC_SIMULATE, (uint8_t *)&payload, sizeof(payload)); PacketResponseNG resp; PrintAndLogEx(INFO, "Press pm3-button to abort simulation"); bool keypress = kbd_enter_pressed(); while (keypress == false) { keypress = kbd_enter_pressed(); if (WaitForResponseTimeout(CMD_HF_LEGIC_SIMULATE, &resp, 1500)) { break; } } if (keypress) SendCommandNG(CMD_BREAK_LOOP, NULL, 0); PrintAndLogEx(INFO, "Done"); return PM3_SUCCESS; } static int CmdLegicWrbl(const char *Cmd) { uint8_t *data = NULL; uint8_t cmdp = 0; bool errors = false; bool autoconfirm = false; int len = 0, bg, en; uint32_t offset = 0, IV = 0x55; while (param_getchar(Cmd, cmdp) != 0x00 && !errors) { switch (tolower(param_getchar(Cmd, cmdp))) { case 'h': { errors = true; break; } case 'd': { // peek at length of the input string so we can // figure out how many elements to malloc in "data" bg = en = 0; if (param_getptr(Cmd, &bg, &en, cmdp + 1)) { errors = true; break; } len = (en - bg + 1); // check that user entered even number of characters // for hex data string if (len & 1) { errors = true; break; } // limit number of bytes to write. This is not a 'restore' command. if ((len >> 1) > 100) { PrintAndLogEx(WARNING, "Max bound on 100bytes to write a one time."); PrintAndLogEx(WARNING, "Use the 'hf legic restore' command if you want to write the whole tag at once"); errors = true; } // it's possible for user to accidentally enter "b" parameter // more than once - we have to clean previous malloc if (data) free(data); data = calloc(len >> 1, sizeof(uint8_t)); if (data == NULL) { PrintAndLogEx(WARNING, "Can't allocate memory. exiting"); errors = true; break; } if (param_gethex(Cmd, cmdp + 1, data, len)) { errors = true; break; } len >>= 1; cmdp += 2; break; } case 'o': { offset = param_get32ex(Cmd, cmdp + 1, 4, 16); cmdp += 2; break; } case 'y': { autoconfirm = true; break; } default: { PrintAndLogEx(WARNING, "Unknown parameter '%c'", param_getchar(Cmd, cmdp)); errors = true; break; } } } //Validations if (errors || cmdp == 0) { if (data) free(data); return usage_legic_wrbl(); } // OUT-OF-BOUNDS checks // UID 4+1 bytes can't be written to. if (offset < 5) { if (data) free(data); PrintAndLogEx(WARNING, "Out-of-bounds, bytes 0-1-2-3-4 can't be written to. Offset = %d", offset); return PM3_EOUTOFBOUND; } // tagtype legic_card_select_t card; if (legic_get_type(&card) != PM3_SUCCESS) { PrintAndLogEx(WARNING, "Failed to identify tagtype"); return PM3_ESOFT; } legic_print_type(card.cardsize, 0); if (len + offset > card.cardsize) { PrintAndLogEx(WARNING, "Out-of-bounds, Cardsize = %d, [offset+len = %d ]", card.cardsize, len + offset); return PM3_EOUTOFBOUND; } if ((offset == 5 || offset == 6) && (! autoconfirm)) { PrintAndLogEx(NORMAL, "############# DANGER ################"); PrintAndLogEx(NORMAL, "# changing the DCF is irreversible #"); PrintAndLogEx(NORMAL, "#####################################"); const char *confirm = "Do you really want to continue? y(es)/n(o) : "; bool overwrite = false; #ifdef HAVE_READLINE char *answer = readline(confirm); overwrite = (answer[0] == 'y' || answer[0] == 'Y'); #else PrintAndLogEx(NORMAL, "%s" NOLF, confirm); char *answer = NULL; size_t anslen = 0; if (getline(&answer, &anslen, stdin) > 0) { overwrite = (answer[0] == 'y' || answer[0] == 'Y'); } PrintAndLogEx(NORMAL, ""); #endif free(answer); if (overwrite == false) { PrintAndLogEx(WARNING, "command cancelled"); return PM3_EOPABORTED; } } legic_chk_iv(&IV); PrintAndLogEx(SUCCESS, "Writing to tag"); PacketResponseNG resp; clearCommandBuffer(); SendCommandOLD(CMD_HF_LEGIC_WRITER, offset, len, IV, data, len); uint8_t timeout = 0; while (!WaitForResponseTimeout(CMD_ACK, &resp, 2000)) { ++timeout; PrintAndLogEx(NORMAL, "." NOLF); if (timeout > 7) { PrintAndLogEx(WARNING, "\ncommand execution time out"); return PM3_ETIMEOUT; } } PrintAndLogEx(NORMAL, ""); uint8_t isOK = resp.oldarg[0] & 0xFF; if (!isOK) { PrintAndLogEx(WARNING, "Failed writing tag"); return PM3_ERFTRANS; } return PM3_SUCCESS; } static int CmdLegicCalcCrc(const char *Cmd) { uint8_t *data = NULL; uint8_t cmdp = 0, uidcrc = 0, type = 0; bool errors = false; int len = 0; int bg, en; while (param_getchar(Cmd, cmdp) != 0x00 && !errors) { switch (tolower(param_getchar(Cmd, cmdp))) { case 'd': // peek at length of the input string so we can // figure out how many elements to malloc in "data" bg = en = 0; if (param_getptr(Cmd, &bg, &en, cmdp + 1)) { errors = true; break; } len = (en - bg + 1); // check that user entered even number of characters // for hex data string if (len & 1) { errors = true; break; } // it's possible for user to accidentally enter "b" parameter // more than once - we have to clean previous malloc if (data) free(data); data = calloc(len >> 1, sizeof(uint8_t)); if (data == NULL) { PrintAndLogEx(WARNING, "Can't allocate memory. exiting"); errors = true; break; } if (param_gethex(Cmd, cmdp + 1, data, len)) { errors = true; break; } len >>= 1; cmdp += 2; break; case 'u': uidcrc = param_get8ex(Cmd, cmdp + 1, 0, 16); cmdp += 2; break; case 'c': type = param_get8ex(Cmd, cmdp + 1, 0, 10); cmdp += 2; break; case 'h': errors = true; break; default: PrintAndLogEx(WARNING, "Unknown parameter '%c'", param_getchar(Cmd, cmdp)); errors = true; break; } } //Validations if (errors || cmdp == 0) { if (data) free(data); return usage_legic_calccrc(); } switch (type) { case 16: init_table(CRC_LEGIC); PrintAndLogEx(SUCCESS, "Legic crc16: %X", crc16_legic(data, len, uidcrc)); break; default: PrintAndLogEx(SUCCESS, "Legic crc8: %X", CRC8Legic(data, len)); break; } if (data) free(data); return PM3_SUCCESS; } int legic_read_mem(uint32_t offset, uint32_t len, uint32_t iv, uint8_t *out, uint16_t *outlen) { legic_chk_iv(&iv); clearCommandBuffer(); SendCommandMIX(CMD_HF_LEGIC_READER, offset, len, iv, NULL, 0); PacketResponseNG resp; uint8_t timeout = 0; while (!WaitForResponseTimeout(CMD_ACK, &resp, 1000)) { ++timeout; PrintAndLogEx(NORMAL, "." NOLF); if (timeout > 14) { PrintAndLogEx(WARNING, "\ncommand execution time out"); return PM3_ETIMEOUT; } } PrintAndLogEx(NORMAL, ""); uint8_t isOK = resp.oldarg[0] & 0xFF; *outlen = resp.oldarg[1]; if (!isOK) { PrintAndLogEx(WARNING, "Failed reading tag"); return PM3_ESOFT; } if (*outlen != len) PrintAndLogEx(WARNING, "Fail, only managed to read %u bytes", *outlen); // copy data from device if (!GetFromDevice(BIG_BUF_EML, out, *outlen, 0, NULL, 0, NULL, 2500, false)) { PrintAndLogEx(WARNING, "Fail, transfer from device time-out"); return PM3_ETIMEOUT; } return PM3_SUCCESS; } int legic_print_type(uint32_t tagtype, uint8_t spaces) { char spc[11] = " "; spc[10] = 0x00; char *spacer = spc + (10 - spaces); if (tagtype == 22) PrintAndLogEx(SUCCESS, "%sTYPE: " _YELLOW_("MIM%d card (outdated)"), spacer, tagtype); else if (tagtype == 256) PrintAndLogEx(SUCCESS, "%sTYPE: " _YELLOW_("MIM%d card (234 bytes)"), spacer, tagtype); else if (tagtype == 1024) PrintAndLogEx(SUCCESS, "%sTYPE: " _YELLOW_("MIM%d card (1002 bytes)"), spacer, tagtype); else PrintAndLogEx(INFO, "%sTYPE: " _YELLOW_("Unknown %06x"), spacer, tagtype); return PM3_SUCCESS; } int legic_get_type(legic_card_select_t *card) { if (card == NULL) return PM3_EINVARG; clearCommandBuffer(); SendCommandNG(CMD_HF_LEGIC_INFO, NULL, 0); PacketResponseNG resp; if (!WaitForResponseTimeout(CMD_ACK, &resp, 1500)) return PM3_ETIMEOUT; uint8_t isOK = resp.oldarg[0] & 0xFF; if (!isOK) return PM3_ESOFT; memcpy(card, resp.data.asBytes, sizeof(legic_card_select_t)); return PM3_SUCCESS; } void legic_chk_iv(uint32_t *iv) { if ((*iv & 0x7F) != *iv) { *iv &= 0x7F; PrintAndLogEx(INFO, "Truncating IV to 7bits, %u", *iv); } // IV must be odd if ((*iv & 1) == 0) { *iv |= 0x01; PrintAndLogEx(INFO, "LSB of IV must be SET %u", *iv); } } void legic_seteml(uint8_t *src, uint32_t offset, uint32_t numofbytes) { // fast push mode conn.block_after_ACK = true; for (size_t i = offset; i < numofbytes; i += PM3_CMD_DATA_SIZE) { size_t len = MIN((numofbytes - i), PM3_CMD_DATA_SIZE); if (len == numofbytes - i) { // Disable fast mode on last packet conn.block_after_ACK = false; } clearCommandBuffer(); SendCommandOLD(CMD_HF_LEGIC_ESET, i, len, 0, src + i, len); } } static int CmdLegicReader(const char *Cmd) { char cmdp = tolower(param_getchar(Cmd, 0)); if (cmdp == 'h') return usage_legic_reader(); return readLegicUid(true); } static int CmdLegicDump(const char *Cmd) { int fileNameLen = 0; char filename[FILE_PATH_SIZE] = {0x00}; char *fptr = filename; bool errors = false, shall_deobsfuscate = false; uint16_t dumplen; uint8_t cmdp = 0; while (param_getchar(Cmd, cmdp) != 0x00 && !errors) { switch (tolower(param_getchar(Cmd, cmdp))) { case 'h': return usage_legic_dump(); case 'f': fileNameLen = param_getstr(Cmd, cmdp + 1, filename, FILE_PATH_SIZE); if (!fileNameLen) errors = true; if (fileNameLen > FILE_PATH_SIZE - 5) fileNameLen = FILE_PATH_SIZE - 5; cmdp += 2; break; case 'x': shall_deobsfuscate = true; cmdp++; break; default: PrintAndLogEx(WARNING, "Unknown parameter '%c'", param_getchar(Cmd, cmdp)); errors = true; break; } } //Validations if (errors) return usage_legic_dump(); // tagtype legic_card_select_t card; if (legic_get_type(&card) != PM3_SUCCESS) { PrintAndLogEx(WARNING, "Failed to identify tagtype"); return PM3_ESOFT; } dumplen = card.cardsize; legic_print_type(dumplen, 0); PrintAndLogEx(SUCCESS, "Reading tag memory %d b...", dumplen); clearCommandBuffer(); SendCommandMIX(CMD_HF_LEGIC_READER, 0x00, dumplen, 0x55, NULL, 0); PacketResponseNG resp; uint8_t timeout = 0; while (!WaitForResponseTimeout(CMD_ACK, &resp, 2000)) { ++timeout; PrintAndLogEx(NORMAL, "." NOLF); if (timeout > 7) { PrintAndLogEx(WARNING, "\ncommand execution time out"); return PM3_ETIMEOUT; } } PrintAndLogEx(NORMAL, ""); uint8_t isOK = resp.oldarg[0] & 0xFF; if (!isOK) { PrintAndLogEx(WARNING, "Failed dumping tag data"); return PM3_ERFTRANS; } uint16_t readlen = resp.oldarg[1]; uint8_t *data = calloc(readlen, sizeof(uint8_t)); if (!data) { PrintAndLogEx(WARNING, "Fail, cannot allocate memory"); return PM3_EMALLOC; } if (readlen != dumplen) PrintAndLogEx(WARNING, "Fail, only managed to read 0x%02X bytes of 0x%02X", readlen, dumplen); // copy data from device if (!GetFromDevice(BIG_BUF_EML, data, readlen, 0, NULL, 0, NULL, 2500, false)) { PrintAndLogEx(WARNING, "Fail, transfer from device time-out"); free(data); return PM3_ETIMEOUT; } // user supplied filename? if (fileNameLen < 1) { PrintAndLogEx(INFO, "Using UID as filename"); fptr += snprintf(fptr, sizeof(filename), "hf-legic-"); FillFileNameByUID(fptr, data, "-dump", 4); } if (shall_deobsfuscate) { // Deobfuscate the whole dump. Unused data (after the last sector) will be MCC since // 0x00 ^ MCC = MCC. Finding the end of used data is not part of this function. legic_xor(data, dumplen); } saveFile(filename, ".bin", data, readlen); saveFileEML(filename, data, readlen, 8); saveFileJSON(filename, jsfLegic, data, readlen, NULL); free(data); return PM3_SUCCESS; } static int CmdLegicRestore(const char *Cmd) { char filename[FILE_PATH_SIZE] = {0x00}; bool errors = false, shall_obsfuscate = false, have_filename = false; size_t numofbytes; uint8_t cmdp = 0; while (param_getchar(Cmd, cmdp) != 0x00 && !errors) { switch (tolower(param_getchar(Cmd, cmdp))) { case 'h': { errors = true; break; } case 'f': { if (param_getstr(Cmd, cmdp + 1, filename, FILE_PATH_SIZE) >= FILE_PATH_SIZE) { PrintAndLogEx(FAILED, "Filename too long"); break; } have_filename = true; cmdp += 2; break; } case 'x': { shall_obsfuscate = true; cmdp++; break; } default: { PrintAndLogEx(WARNING, "Unknown parameter '%c'", param_getchar(Cmd, cmdp)); errors = true; break; } } } if (have_filename == false) errors = true; //Validations if (errors || cmdp == 0) return usage_legic_restore(); // tagtype legic_card_select_t card; if (legic_get_type(&card) != PM3_SUCCESS) { PrintAndLogEx(WARNING, "Failed to identify tagtype"); return PM3_ESOFT; } legic_print_type(card.cardsize, 0); // set up buffer uint8_t *data = calloc(card.cardsize, sizeof(uint8_t)); if (!data) { PrintAndLogEx(WARNING, "Fail, cannot allocate memory"); return PM3_EMALLOC; } if (loadFile_safe(filename, ".bin", (void **)&data, &numofbytes) != PM3_SUCCESS) { free(data); PrintAndLogEx(WARNING, "Error, reading file"); return PM3_EFILE; } if (card.cardsize != numofbytes) { PrintAndLogEx(WARNING, "Fail, filesize and cardsize is not equal. [%u != %zu]", card.cardsize, numofbytes); free(data); return PM3_EFILE; } if (shall_obsfuscate) { legic_xor(data, card.cardsize); } PrintAndLogEx(SUCCESS, "Restoring to card"); // fast push mode conn.block_after_ACK = true; // transfer to device PacketResponseNG resp; for (size_t i = 7; i < numofbytes; i += PM3_CMD_DATA_SIZE) { size_t len = MIN((numofbytes - i), PM3_CMD_DATA_SIZE); if (len == numofbytes - i) { // Disable fast mode on last packet conn.block_after_ACK = false; } clearCommandBuffer(); SendCommandOLD(CMD_HF_LEGIC_WRITER, i, len, 0x55, data + i, len); uint8_t timeout = 0; while (!WaitForResponseTimeout(CMD_ACK, &resp, 2000)) { ++timeout; PrintAndLogEx(NORMAL, "." NOLF); if (timeout > 7) { PrintAndLogEx(WARNING, "\ncommand execution time out"); free(data); return PM3_ETIMEOUT; } } PrintAndLogEx(NORMAL, ""); uint8_t isOK = resp.oldarg[0] & 0xFF; if (!isOK) { PrintAndLogEx(WARNING, "Failed writing tag [msg = %u]", (uint8_t)(resp.oldarg[1] & 0xFF)); free(data); return PM3_ERFTRANS; } PrintAndLogEx(SUCCESS, "Wrote chunk [offset %zu | len %zu | total %zu", i, len, i + len); } free(data); PrintAndLogEx(SUCCESS, "Done"); return PM3_SUCCESS; } static int CmdLegicELoad(const char *Cmd) { size_t numofbytes = 256; char filename[FILE_PATH_SIZE] = {0x00}; bool errors = false, shall_obsfuscate = false, have_filename = false; uint8_t cmdp = 0; while (param_getchar(Cmd, cmdp) != 0x00 && !errors) { switch (tolower(param_getchar(Cmd, cmdp))) { case 'h' : { return usage_legic_eload(); } case 'f' : { if (param_getstr(Cmd, cmdp + 1, filename, FILE_PATH_SIZE) >= FILE_PATH_SIZE) { PrintAndLogEx(FAILED, "Filename too long"); break; } have_filename = true; cmdp += 2; break; } case 'x': { shall_obsfuscate = true; cmdp++; break; } case '0' : { numofbytes = 22; cmdp++; break; } case '1' : { numofbytes = 256; cmdp++; break; } case '2' : { numofbytes = 1024; cmdp++; break; } default : { PrintAndLogEx(WARNING, "Unknown parameter '%c'", param_getchar(Cmd, cmdp)); errors = true; break; } } } if (have_filename == false) errors = true; //Validations if (errors || strlen(Cmd) == 0) return usage_legic_eload(); // set up buffer uint8_t *data = calloc(numofbytes, sizeof(uint8_t)); if (!data) { PrintAndLogEx(WARNING, "Fail, cannot allocate memory"); return PM3_EMALLOC; } if (loadFile_safe(filename, ".bin", (void **)&data, &numofbytes) != PM3_SUCCESS) { free(data); PrintAndLogEx(WARNING, "Error, reading file"); return PM3_EFILE; } if (shall_obsfuscate) { legic_xor(data, numofbytes); } PrintAndLogEx(SUCCESS, "Uploading to emulator memory"); legic_seteml(data, 0, numofbytes); free(data); PrintAndLogEx(SUCCESS, "Done"); return PM3_SUCCESS; } static int CmdLegicESave(const char *Cmd) { char filename[FILE_PATH_SIZE] = {0}; char *fptr = filename; int fileNameLen = 0; size_t numofbytes = 256; bool errors = false, shall_deobsfuscate = false; uint8_t cmdp = 0; while (param_getchar(Cmd, cmdp) != 0x00 && !errors) { switch (tolower(param_getchar(Cmd, cmdp))) { case 'h' : return usage_legic_esave(); case 'f' : fileNameLen = param_getstr(Cmd, cmdp + 1, filename, FILE_PATH_SIZE); if (!fileNameLen) errors = true; if (fileNameLen > FILE_PATH_SIZE - 5) fileNameLen = FILE_PATH_SIZE - 5; cmdp += 2; break; case 'x': shall_deobsfuscate = true; cmdp++; break; case '0' : numofbytes = 22; cmdp++; break; case '1' : numofbytes = 256; cmdp++; break; case '2' : numofbytes = 1024; cmdp++; break; default : PrintAndLogEx(WARNING, "Unknown parameter '%c'", param_getchar(Cmd, cmdp)); errors = true; break; } } //Validations if (errors || strlen(Cmd) == 0) return usage_legic_esave(); // set up buffer uint8_t *data = calloc(numofbytes, sizeof(uint8_t)); if (!data) { PrintAndLogEx(WARNING, "Fail, cannot allocate memory"); return PM3_EMALLOC; } // download emulator memory PrintAndLogEx(SUCCESS, "Reading emulator memory..."); if (!GetFromDevice(BIG_BUF_EML, data, numofbytes, 0, NULL, 0, NULL, 2500, false)) { PrintAndLogEx(WARNING, "Fail, transfer from device time-out"); free(data); return PM3_ETIMEOUT; } // user supplied filename? if (fileNameLen < 1) { PrintAndLogEx(INFO, "Using UID as filename"); fptr += snprintf(fptr, sizeof(filename), "hf-legic-"); FillFileNameByUID(fptr, data, "-dump", 4); } if (shall_deobsfuscate) { legic_xor(data, numofbytes); } saveFile(filename, ".bin", data, numofbytes); saveFileEML(filename, data, numofbytes, 8); saveFileJSON(filename, jsfLegic, data, numofbytes, NULL); return PM3_SUCCESS; } static int CmdLegicWipe(const char *Cmd) { char cmdp = tolower(param_getchar(Cmd, 0)); if (cmdp == 'h') return usage_legic_wipe(); // tagtype legic_card_select_t card; if (legic_get_type(&card) != PM3_SUCCESS) { PrintAndLogEx(WARNING, "Failed to identify tagtype"); return PM3_ESOFT; } // set up buffer uint8_t *data = calloc(card.cardsize, sizeof(uint8_t)); if (!data) { PrintAndLogEx(WARNING, "Fail, cannot allocate memory"); return PM3_EMALLOC; } legic_print_type(card.cardsize, 0); PrintAndLogEx(SUCCESS, "Erasing"); // fast push mode conn.block_after_ACK = true; // transfer to device PacketResponseNG resp; for (size_t i = 7; i < card.cardsize; i += PM3_CMD_DATA_SIZE) { PrintAndLogEx(NORMAL, "." NOLF); size_t len = MIN((card.cardsize - i), PM3_CMD_DATA_SIZE); if (len == card.cardsize - i) { // Disable fast mode on last packet conn.block_after_ACK = false; } clearCommandBuffer(); SendCommandOLD(CMD_HF_LEGIC_WRITER, i, len, 0x55, data + i, len); uint8_t timeout = 0; while (!WaitForResponseTimeout(CMD_ACK, &resp, 2000)) { ++timeout; PrintAndLogEx(NORMAL, "." NOLF); if (timeout > 7) { PrintAndLogEx(WARNING, "\ncommand execution time out"); free(data); return PM3_ETIMEOUT; } } PrintAndLogEx(NORMAL, ""); uint8_t isOK = resp.oldarg[0] & 0xFF; if (!isOK) { PrintAndLogEx(WARNING, "Failed writing tag [msg = %u]", (uint8_t)(resp.oldarg[1] & 0xFF)); free(data); return PM3_ERFTRANS; } } PrintAndLogEx(SUCCESS, "ok\n"); free(data); return PM3_SUCCESS; } static int CmdLegicList(const char *Cmd) { char args[128] = {0}; if (strlen(Cmd) == 0) { snprintf(args, sizeof(args), "-t legic"); } else { strncpy(args, Cmd, sizeof(args) - 1); } return CmdTraceList(args); } static command_t CommandTable[] = { {"help", CmdHelp, AlwaysAvailable, "This help"}, {"list", CmdLegicList, AlwaysAvailable, "List LEGIC history"}, {"reader", CmdLegicReader, IfPm3Legicrf, "LEGIC Prime Reader UID and tag info"}, {"info", CmdLegicInfo, IfPm3Legicrf, "Display deobfuscated and decoded LEGIC Prime tag data"}, {"dump", CmdLegicDump, IfPm3Legicrf, "Dump LEGIC Prime tag to binary file"}, {"restore", CmdLegicRestore, IfPm3Legicrf, "Restore a dump file onto a LEGIC Prime tag"}, {"rdbl", CmdLegicRdbl, IfPm3Legicrf, "Read bytes from a LEGIC Prime tag"}, {"sim", CmdLegicSim, IfPm3Legicrf, "Start tag simulator"}, {"wrbl", CmdLegicWrbl, IfPm3Legicrf, "Write data to a LEGIC Prime tag"}, {"crc", CmdLegicCalcCrc, AlwaysAvailable, "Calculate Legic CRC over given bytes"}, {"eload", CmdLegicELoad, AlwaysAvailable, "Load binary dump to emulator memory"}, {"esave", CmdLegicESave, AlwaysAvailable, "Save emulator memory to binary file"}, {"wipe", CmdLegicWipe, IfPm3Legicrf, "Wipe a LEGIC Prime tag"}, {NULL, NULL, NULL, NULL} }; static int CmdHelp(const char *Cmd) { (void)Cmd; // Cmd is not used so far CmdsHelp(CommandTable); return PM3_SUCCESS; } int CmdHFLegic(const char *Cmd) { clearCommandBuffer(); return CmdsParse(CommandTable, Cmd); } int readLegicUid(bool verbose) { legic_card_select_t card; switch (legic_get_type(&card)) { case PM3_EINVARG: return PM3_EINVARG; case PM3_ETIMEOUT: if (verbose) PrintAndLogEx(WARNING, "command execution time out"); return PM3_ETIMEOUT; case PM3_ESOFT: if (verbose) PrintAndLogEx(WARNING, "legic card select failed"); return PM3_ESOFT; default: break; } PrintAndLogEx(NORMAL, ""); PrintAndLogEx(SUCCESS, " MCD: " _GREEN_("%02X"), card.uid[0]); PrintAndLogEx(SUCCESS, " MSN: " _GREEN_("%s"), sprint_hex(card.uid + 1, sizeof(card.uid) - 1)); legic_print_type(card.cardsize, 0); return PM3_SUCCESS; }