//----------------------------------------------------------------------------- // // 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. //----------------------------------------------------------------------------- // Low frequency T55xx commands //----------------------------------------------------------------------------- #include #include #include #include #include "proxmark3.h" #include "ui.h" #include "graph.h" #include "cmdmain.h" #include "cmdparser.h" #include "cmddata.h" #include "cmdlf.h" #include "cmdlft55xx.h" #include "util.h" #include "data.h" #include "lfdemod.h" #include "../common/crc.h" #include "../common/iso14443crc.h" #include "cmdhf14a.h" #define CONFIGURATION_BLOCK 0x00 #define TRACE_BLOCK 0x01 // Default configuration t55xx_conf_block_t config = { .modulation = DEMOD_ASK, .inverted = FALSE, .offset = 0x00, .block0 = 0x00}; int usage_t55xx_config(){ PrintAndLog("Usage: lf t55xx config [d ] [i 1] [o ]"); PrintAndLog("Options: "); PrintAndLog(" h This help"); PrintAndLog(" b <8|16|32|40|50|64|100|128> Set bitrate"); PrintAndLog(" d Set demodulation FSK / ASK / PSK / NZ / Biphase / Biphase A"); PrintAndLog(" i [1] Invert data signal, defaults to normal"); PrintAndLog(" o [offset] Set offset, where data should start decode in bitstream"); PrintAndLog(""); PrintAndLog("Examples:"); PrintAndLog(" lf t55xx config d FSK - FSK demodulation"); PrintAndLog(" lf t55xx config d FSK i 1 - FSK demodulation, inverse data"); PrintAndLog(" lf t55xx config d FSK i 1 o 3 - FSK demodulation, inverse data, offset=3,start from position 3 to decode data"); PrintAndLog(""); return 0; } int usage_t55xx_read(){ PrintAndLog("Usage: lf t55xx read "); PrintAndLog(" , block number to read. Between 0-7"); PrintAndLog(" , OPTIONAL password (8 hex characters)"); PrintAndLog(""); PrintAndLog("Examples:"); PrintAndLog(" lf t55xx read 0 - read data from block 0"); PrintAndLog(" lf t55xx read 0 feedbeef - read data from block 0 password feedbeef"); PrintAndLog(""); return 0; } int usage_t55xx_write(){ PrintAndLog("Usage: lf t55xx wr [password]"); PrintAndLog(" , block number to write. Between 0-7"); PrintAndLog(" , 4 bytes of data to write (8 hex characters)"); PrintAndLog(" [password], OPTIONAL password 4bytes (8 hex characters)"); PrintAndLog(""); PrintAndLog("Examples:"); PrintAndLog(" lf t55xx wr 3 11223344 - write 11223344 to block 3"); PrintAndLog(" lf t55xx wr 3 11223344 feedbeef - write 11223344 to block 3 password feedbeef"); PrintAndLog(""); return 0; } int usage_t55xx_trace() { PrintAndLog("Usage: lf t55xx trace [1]"); PrintAndLog(" [graph buffer data], if set, use Graphbuffer otherwise read data from tag."); PrintAndLog(""); PrintAndLog("Examples:"); PrintAndLog(" lf t55xx trace"); PrintAndLog(" lf t55xx trace 1"); PrintAndLog(""); return 0; } int usage_t55xx_info() { PrintAndLog("Usage: lf t55xx info [1]"); PrintAndLog(" [graph buffer data], if set, use Graphbuffer otherwise read data from tag."); PrintAndLog(""); PrintAndLog("Examples:"); PrintAndLog(" lf t55xx info"); PrintAndLog(" lf t55xx info 1"); PrintAndLog(""); return 0; } int usage_t55xx_dump(){ PrintAndLog("Usage: lf t55xx dump "); PrintAndLog(" , OPTIONAL password 4bytes (8 hex symbols)"); PrintAndLog(""); PrintAndLog("Examples:"); PrintAndLog(" lf t55xx dump"); PrintAndLog(" lf t55xx dump feedbeef"); PrintAndLog(""); return 0; } int usage_t55xx_detect(){ PrintAndLog("Usage: lf t55xx detect"); PrintAndLog(""); PrintAndLog("Examples:"); PrintAndLog(" lf t55xx detect"); PrintAndLog(" lf t55xx detect 1"); PrintAndLog(""); return 0; } static int CmdHelp(const char *Cmd); int CmdT55xxSetConfig(const char *Cmd) { uint8_t offset = 0; bool errors = FALSE; uint8_t cmdp = 0; char modulation[5] = {0x00}; char tmp = 0x00; uint8_t bitRate = 0; uint8_t rates[9] = {8,16,32,40,50,64,100,128,0}; while(param_getchar(Cmd, cmdp) != 0x00 && !errors) { tmp = param_getchar(Cmd, cmdp); switch(tmp) { case 'h': case 'H': return usage_t55xx_config(); case 'b': errors |= param_getdec(Cmd, cmdp+1, &bitRate); if ( !errors){ uint8_t i = 0; for (; i < 9; i++){ if (rates[i]==bitRate) { config.bitrate = i; break; } } if (i==9) errors = TRUE; } cmdp+=2; break; case 'd': param_getstr(Cmd, cmdp+1, modulation); cmdp += 2; if ( strcmp(modulation, "FSK" ) == 0) { config.modulation = DEMOD_FSK; } else if ( strcmp(modulation, "FSK1" ) == 0) { config.modulation = DEMOD_FSK1; config.inverted=1; } else if ( strcmp(modulation, "FSK1a" ) == 0) { config.modulation = DEMOD_FSK1a; config.inverted=0; } else if ( strcmp(modulation, "FSK2" ) == 0) { config.modulation = DEMOD_FSK2; config.inverted=0; } else if ( strcmp(modulation, "FSK2a" ) == 0) { config.modulation = DEMOD_FSK2a; config.inverted=1; } else if ( strcmp(modulation, "ASK" ) == 0) { config.modulation = DEMOD_ASK; } else if ( strcmp(modulation, "NRZ" ) == 0) { config.modulation = DEMOD_NRZ; } else if ( strcmp(modulation, "PSK1" ) == 0) { config.modulation = DEMOD_PSK1; } else if ( strcmp(modulation, "PSK2" ) == 0) { config.modulation = DEMOD_PSK2; } else if ( strcmp(modulation, "PSK3" ) == 0) { config.modulation = DEMOD_PSK3; } else if ( strcmp(modulation, "BIa" ) == 0) { config.modulation = DEMOD_BIa; config.inverted=1; } else if ( strcmp(modulation, "BI" ) == 0) { config.modulation = DEMOD_BI; config.inverted=0; } else { PrintAndLog("Unknown modulation '%s'", modulation); errors = TRUE; } break; case 'i': config.inverted = param_getchar(Cmd,cmdp+1) == '1'; cmdp+=2; break; case 'o': errors |= param_getdec(Cmd, cmdp+1, &offset); if ( !errors ) config.offset = offset; cmdp+=2; break; default: PrintAndLog("Unknown parameter '%c'", param_getchar(Cmd, cmdp)); errors = TRUE; break; } } // No args if (cmdp == 0) { printConfiguration( config ); return 0; } //Validations if (errors) return usage_t55xx_config(); config.block0 = 0; printConfiguration ( config ); return 0; } int CmdT55xxReadBlock(const char *Cmd) { int block = -1; int password = 0xFFFFFFFF; //default to blank Block 7 char cmdp = param_getchar(Cmd, 0); if (cmdp == 'h' || cmdp == 'H') return usage_t55xx_read(); int res = sscanf(Cmd, "%d %x", &block, &password); if ( res < 1 || res > 2 ) return usage_t55xx_read(); if ((block < 0) | (block > 7)) { PrintAndLog("Block must be between 0 and 7"); return 1; } UsbCommand c = {CMD_T55XX_READ_BLOCK, {0, block, 0}}; c.d.asBytes[0] = 0x0; //Password mode if ( res == 2 ) { c.arg[2] = password; c.d.asBytes[0] = 0x1; } SendCommand(&c); if ( !WaitForResponseTimeout(CMD_ACK,NULL,2500) ) { PrintAndLog("command execution time out"); return 2; } uint8_t got[12000]; GetFromBigBuf(got,sizeof(got),0); WaitForResponse(CMD_ACK,NULL); setGraphBuf(got, 12000); DemodBufferLen=0; if (!DecodeT55xxBlock()) return 3; char blk[10]={0}; sprintf(blk,"%d", block); printT55xxBlock(blk); return 0; } bool DecodeT55xxBlock(){ char buf[30] = {0x00}; char *cmdStr = buf; int ans = 0; uint8_t bitRate[8] = {8,16,32,40,50,64,100,128}; DemodBufferLen = 0x00; //trim 1/2 a clock from beginning snprintf(cmdStr, sizeof(buf),"%d", bitRate[config.bitrate]/2 ); CmdLtrim(cmdStr); switch( config.modulation ){ case DEMOD_FSK: snprintf(cmdStr, sizeof(buf),"%d %d", bitRate[config.bitrate], config.inverted ); ans = FSKrawDemod(cmdStr, FALSE); break; case DEMOD_FSK1: case DEMOD_FSK1a: snprintf(cmdStr, sizeof(buf),"%d %d 8 5", bitRate[config.bitrate], config.inverted ); ans = FSKrawDemod(cmdStr, FALSE); break; case DEMOD_FSK2: case DEMOD_FSK2a: snprintf(cmdStr, sizeof(buf),"%d %d 10 8", bitRate[config.bitrate], config.inverted ); ans = FSKrawDemod(cmdStr, FALSE); break; case DEMOD_ASK: snprintf(cmdStr, sizeof(buf),"%d %d 0", bitRate[config.bitrate], config.inverted ); ans = ASKDemod(cmdStr, FALSE, FALSE, 1); break; case DEMOD_PSK1: snprintf(cmdStr, sizeof(buf),"%d %d 0", bitRate[config.bitrate], config.inverted ); ans = PSKDemod(cmdStr, FALSE); break; case DEMOD_PSK2: //inverted won't affect this case DEMOD_PSK3: //not fully implemented snprintf(cmdStr, sizeof(buf),"%d 0 1", bitRate[config.bitrate] ); ans = PSKDemod(cmdStr, FALSE); psk1TOpsk2(DemodBuffer, DemodBufferLen); break; case DEMOD_NRZ: snprintf(cmdStr, sizeof(buf),"%d %d 1", bitRate[config.bitrate], config.inverted ); ans = NRZrawDemod(cmdStr, FALSE); break; case DEMOD_BI: case DEMOD_BIa: snprintf(cmdStr, sizeof(buf),"0 %d %d 0", bitRate[config.bitrate], config.inverted ); ans = ASKbiphaseDemod(cmdStr, FALSE); break; default: return FALSE; } return (bool) ans; } int CmdT55xxDetect(const char *Cmd){ char cmdp = param_getchar(Cmd, 0); if (strlen(Cmd) > 1 || cmdp == 'h' || cmdp == 'H') return usage_t55xx_detect(); if (strlen(Cmd)==0) AquireData( CONFIGURATION_BLOCK ); if ( !tryDetectModulation() ) PrintAndLog("Could not detect modulation automatically. Try setting it manually with \'lf t55xx config\'"); return 0; } // detect configuration? bool tryDetectModulation(){ char cmdStr[8] = {0}; uint8_t hits = 0; t55xx_conf_block_t tests[15]; int bitRate=0; uint8_t fc1 = 0, fc2 = 0, clk=0; save_restoreGB(1); if (GetFskClock("", FALSE, FALSE)){ fskClocks(&fc1, &fc2, &clk, FALSE); sprintf(cmdStr,"%d", clk/2); CmdLtrim(cmdStr); if ( FSKrawDemod("0 0", FALSE) && test(DEMOD_FSK, &tests[hits].offset, &bitRate)){ tests[hits].modulation = DEMOD_FSK; if (fc1==8 && fc2 == 5) tests[hits].modulation = DEMOD_FSK1a; else if (fc1==10 && fc2 == 8) tests[hits].modulation = DEMOD_FSK2; tests[hits].bitrate = bitRate; tests[hits].inverted = FALSE; tests[hits].block0 = PackBits(tests[hits].offset, 32, DemodBuffer); ++hits; } if ( FSKrawDemod("0 1", FALSE) && test(DEMOD_FSK, &tests[hits].offset, &bitRate)) { tests[hits].modulation = DEMOD_FSK; if (fc1 == 8 && fc2 == 5) tests[hits].modulation = DEMOD_FSK1; else if (fc1 == 10 && fc2 == 8) tests[hits].modulation = DEMOD_FSK2a; tests[hits].bitrate = bitRate; tests[hits].inverted = TRUE; tests[hits].block0 = PackBits(tests[hits].offset, 32, DemodBuffer); ++hits; } } else { clk = GetAskClock("", FALSE, FALSE); if (clk>0) { sprintf(cmdStr,"%d", clk/2); CmdLtrim(cmdStr); if ( ASKDemod("0 0 0", FALSE, FALSE, 1) && test(DEMOD_ASK, &tests[hits].offset, &bitRate)) { tests[hits].modulation = DEMOD_ASK; tests[hits].bitrate = bitRate; tests[hits].inverted = FALSE; tests[hits].block0 = PackBits(tests[hits].offset, 32, DemodBuffer); ++hits; } if ( ASKDemod("0 1 0", FALSE, FALSE, 1) && test(DEMOD_ASK, &tests[hits].offset, &bitRate)) { tests[hits].modulation = DEMOD_ASK; tests[hits].bitrate = bitRate; tests[hits].inverted = TRUE; tests[hits].block0 = PackBits(tests[hits].offset, 32, DemodBuffer); ++hits; } if ( ASKbiphaseDemod("0 0 0 0", FALSE) && test(DEMOD_BI, &tests[hits].offset, &bitRate) ) { tests[hits].modulation = DEMOD_BI; tests[hits].bitrate = bitRate; tests[hits].inverted = FALSE; tests[hits].block0 = PackBits(tests[hits].offset, 32, DemodBuffer); ++hits; } if ( ASKbiphaseDemod("0 0 1 0", FALSE) && test(DEMOD_BIa, &tests[hits].offset, &bitRate) ) { tests[hits].modulation = DEMOD_BIa; tests[hits].bitrate = bitRate; tests[hits].inverted = TRUE; tests[hits].block0 = PackBits(tests[hits].offset, 32, DemodBuffer); ++hits; } } //undo trim from ask save_restoreGB(0); clk = GetNrzClock("", FALSE, FALSE); if (clk>0) { sprintf(cmdStr,"%d", clk/2); CmdLtrim(cmdStr); if ( NRZrawDemod("0 0 1", FALSE) && test(DEMOD_NRZ, &tests[hits].offset, &bitRate)) { tests[hits].modulation = DEMOD_NRZ; tests[hits].bitrate = bitRate; tests[hits].inverted = FALSE; tests[hits].block0 = PackBits(tests[hits].offset, 32, DemodBuffer); ++hits; } if ( NRZrawDemod("0 1 1", FALSE) && test(DEMOD_NRZ, &tests[hits].offset, &bitRate)) { tests[hits].modulation = DEMOD_NRZ; tests[hits].bitrate = bitRate; tests[hits].inverted = TRUE; tests[hits].block0 = PackBits(tests[hits].offset, 32, DemodBuffer); ++hits; } } //undo trim from nrz save_restoreGB(0); clk = GetPskClock("", FALSE, FALSE); if (clk>0) { PrintAndLog("clk %d",clk); sprintf(cmdStr,"%d", clk/2); CmdLtrim(cmdStr); if ( PSKDemod("0 0 1", FALSE) && test(DEMOD_PSK1, &tests[hits].offset, &bitRate)) { tests[hits].modulation = DEMOD_PSK1; tests[hits].bitrate = bitRate; tests[hits].inverted = FALSE; tests[hits].block0 = PackBits(tests[hits].offset, 32, DemodBuffer); ++hits; } if ( PSKDemod("0 1 1", FALSE) && test(DEMOD_PSK1, &tests[hits].offset, &bitRate)) { tests[hits].modulation = DEMOD_PSK1; tests[hits].bitrate = bitRate; tests[hits].inverted = TRUE; tests[hits].block0 = PackBits(tests[hits].offset, 32, DemodBuffer); ++hits; } // PSK2 - needs a call to psk1TOpsk2. if ( PSKDemod("0 0 1", FALSE)) { psk1TOpsk2(DemodBuffer, DemodBufferLen); if (test(DEMOD_PSK2, &tests[hits].offset, &bitRate)){ tests[hits].modulation = DEMOD_PSK2; tests[hits].bitrate = bitRate; tests[hits].inverted = FALSE; tests[hits].block0 = PackBits(tests[hits].offset, 32, DemodBuffer); ++hits; } } // inverse waves does not affect this demod // PSK3 - needs a call to psk1TOpsk2. if ( PSKDemod("0 0 1", FALSE)) { psk1TOpsk2(DemodBuffer, DemodBufferLen); if (test(DEMOD_PSK3, &tests[hits].offset, &bitRate)){ tests[hits].modulation = DEMOD_PSK3; tests[hits].bitrate = bitRate; tests[hits].inverted = FALSE; tests[hits].block0 = PackBits(tests[hits].offset, 32, DemodBuffer); ++hits; } } // inverse waves does not affect this demod } } if ( hits == 1) { config.modulation = tests[0].modulation; config.bitrate = tests[0].bitrate; config.inverted = tests[0].inverted; config.offset = tests[0].offset; config.block0 = tests[0].block0; printConfiguration( config ); return TRUE; } if ( hits > 1) { PrintAndLog("Found [%d] possible matches for modulation.",hits); for(int i=0; i 3 && modread < 8) return TRUE; break; case DEMOD_ASK: if (modread == DEMOD_ASK) return TRUE; break; case DEMOD_PSK1: if (modread == DEMOD_PSK1) return TRUE; break; case DEMOD_PSK2: if (modread == DEMOD_PSK2) return TRUE; break; case DEMOD_PSK3: if (modread == DEMOD_PSK3) return TRUE; break; case DEMOD_NRZ: if (modread == DEMOD_NRZ) return TRUE; break; case DEMOD_BI: if (modread == DEMOD_BI) return TRUE; break; case DEMOD_BIa: if (modread == DEMOD_BIa) return TRUE; break; default: return FALSE; } return FALSE; } bool testBitRate(uint8_t readRate, uint8_t mod){ uint8_t expected[8] = {8, 16, 32, 40, 50, 64, 100, 128}; uint8_t detRate = 0; switch( mod ){ case DEMOD_FSK: case DEMOD_FSK1: case DEMOD_FSK1a: case DEMOD_FSK2: case DEMOD_FSK2a: detRate = GetFskClock("",FALSE, FALSE); if (expected[readRate] == detRate) return TRUE; break; case DEMOD_ASK: case DEMOD_BI: case DEMOD_BIa: detRate = GetAskClock("",FALSE, FALSE); if (expected[readRate] == detRate) return TRUE; break; case DEMOD_PSK1: case DEMOD_PSK2: case DEMOD_PSK3: detRate = GetPskClock("",FALSE, FALSE); if (expected[readRate] == detRate) return TRUE; break; case DEMOD_NRZ: detRate = GetNrzClock("",FALSE, FALSE); if (expected[readRate] == detRate) return TRUE; break; default: return FALSE; } return FALSE; } bool test(uint8_t mode, uint8_t *offset, int *fndBitRate){ if ( DemodBufferLen < 64 ) return FALSE; uint8_t si = 0; for (uint8_t idx = 0; idx < 64; idx++){ si = idx; if ( PackBits(si, 32, DemodBuffer) == 0x00 ) continue; uint8_t safer = PackBits(si, 4, DemodBuffer); si += 4; //master key uint8_t resv = PackBits(si, 4, DemodBuffer); si += 4; //was 7 & +=7+3 //should be only 4 bits if extended mode // 2nibble must be zeroed. // moved test to here, since this gets most faults first. if ( resv > 0x00) continue; uint8_t xtRate = PackBits(si, 3, DemodBuffer); si += 3; //extended mode part of rate int bitRate = PackBits(si, 3, DemodBuffer); si += 3; //bit rate if (bitRate > 7) continue; uint8_t extend = PackBits(si, 1, DemodBuffer); si += 1; //bit 15 extended mode uint8_t modread = PackBits(si, 5, DemodBuffer); si += 5+2+1; //uint8_t pskcr = PackBits(si, 2, DemodBuffer); si += 2+1; //could check psk cr uint8_t nml01 = PackBits(si, 1, DemodBuffer); si += 1+5; //bit 24, 30, 31 could be tested for 0 if not extended mode uint8_t nml02 = PackBits(si, 2, DemodBuffer); si += 2; //if extended mode bool extMode =( (safer == 0x6 || safer == 0x9) && extend) ? TRUE : FALSE; if (!extMode){ if (nml01 || nml02 || xtRate) continue; } //test modulation if (!testModulation(mode, modread)) continue; if (!testBitRate(bitRate, mode)) continue; *fndBitRate = bitRate; *offset = idx; return TRUE; } return FALSE; } void printT55xxBlock(const char *blockNum){ uint8_t i = config.offset; uint8_t endpos = 32 + i; uint32_t blockData = 0; uint8_t bits[64] = {0x00}; if ( !DemodBufferLen) return; if ( endpos > DemodBufferLen){ PrintAndLog("The configured offset %d is too big. Possible offset: %d)", i, DemodBufferLen-32); return; } for (; i < endpos; ++i) bits[i - config.offset]=DemodBuffer[i]; blockData = PackBits(0, 32, bits); PrintAndLog("[%s] 0x%08X %s", blockNum, blockData, sprint_bin(bits,32)); } int special(const char *Cmd) { uint32_t blockData = 0; uint8_t bits[32] = {0x00}; PrintAndLog("[OFFSET] [DATA] [BINARY]"); PrintAndLog("----------------------------------------------------"); int i,j = 0; for (; j < 64; ++j){ for (i = 0; i < 32; ++i) bits[i]=DemodBuffer[j+i]; blockData = PackBits(0, 32, bits); PrintAndLog("[%02d] 0x%08X %s",j , blockData, sprint_bin(bits,32)); } return 0; } void printConfiguration( t55xx_conf_block_t b){ PrintAndLog("Modulation : %s", GetSelectedModulationStr(b.modulation) ); PrintAndLog("Bit Rate : %s", GetBitRateStr(b.bitrate) ); PrintAndLog("Inverted : %s", (b.inverted) ? "Yes" : "No" ); PrintAndLog("Offset : %d", b.offset); PrintAndLog("Block0 : 0x%08X", b.block0); PrintAndLog(""); } int CmdT55xxWriteBlock(const char *Cmd) { int block = 8; //default to invalid block int data = 0xFFFFFFFF; //default to blank Block int password = 0xFFFFFFFF; //default to blank Block 7 char cmdp = param_getchar(Cmd, 0); if (cmdp == 'h' || cmdp == 'H') { usage_t55xx_write(); return 0; } int res = sscanf(Cmd, "%d %x %x",&block, &data, &password); if ( res < 2 || res > 3) { usage_t55xx_write(); return 1; } if (block > 7) { PrintAndLog("Block number must be between 0 and 7"); return 1; } UsbCommand c = {CMD_T55XX_WRITE_BLOCK, {data, block, 0}}; c.d.asBytes[0] = 0x0; PrintAndLog("Writing to block: %d data : 0x%08X", block, data); //Password mode if (res == 3) { c.arg[2] = password; c.d.asBytes[0] = 0x1; PrintAndLog("pwd : 0x%08X", password); } SendCommand(&c); return 0; } int CmdT55xxReadTrace(const char *Cmd) { char cmdp = param_getchar(Cmd, 0); if (strlen(Cmd) > 1 || cmdp == 'h' || cmdp == 'H') return usage_t55xx_trace(); if (strlen(Cmd)==0) AquireData( TRACE_BLOCK ); if (!DecodeT55xxBlock()) return 1; if ( !DemodBufferLen) return 1; RepaintGraphWindow(); uint8_t repeat = 0; if (config.offset > 5) repeat = 32; uint8_t si = config.offset+repeat; uint32_t bl0 = PackBits(si, 32, DemodBuffer); uint32_t bl1 = PackBits(si+32, 32, DemodBuffer); uint32_t acl = PackBits(si, 8, DemodBuffer); si += 8; uint32_t mfc = PackBits(si, 8, DemodBuffer); si += 8; uint32_t cid = PackBits(si, 5, DemodBuffer); si += 5; uint32_t icr = PackBits(si, 3, DemodBuffer); si += 3; uint32_t year = PackBits(si, 4, DemodBuffer); si += 4; uint32_t quarter = PackBits(si, 2, DemodBuffer); si += 2; uint32_t lotid = PackBits(si, 14, DemodBuffer); si += 14; uint32_t wafer = PackBits(si, 5, DemodBuffer); si += 5; uint32_t dw = PackBits(si, 15, DemodBuffer); time_t t = time(NULL); struct tm tm = *localtime(&t); if ( year > tm.tm_year-110) year += 2000; else year += 2010; if ( acl != 0xE0 ) { PrintAndLog("The modulation is most likely wrong since the ACL is not 0xE0. "); return 1; } PrintAndLog(""); PrintAndLog("-- T55xx Trace Information ----------------------------------"); PrintAndLog("-------------------------------------------------------------"); PrintAndLog(" ACL Allocation class (ISO/IEC 15963-1) : 0x%02X (%d)", acl, acl); PrintAndLog(" MFC Manufacturer ID (ISO/IEC 7816-6) : 0x%02X (%d) - %s", mfc, mfc, getTagInfo(mfc)); PrintAndLog(" CID : 0x%02X (%d) - %s", cid, cid, GetModelStrFromCID(cid)); PrintAndLog(" ICR IC Revision : %d",icr ); PrintAndLog(" Manufactured"); PrintAndLog(" Year/Quarter : %d/%d",year, quarter); PrintAndLog(" Lot ID : %d", lotid ); PrintAndLog(" Wafer number : %d", wafer); PrintAndLog(" Die Number : %d", dw); PrintAndLog("-------------------------------------------------------------"); PrintAndLog(" Raw Data - Page 1"); PrintAndLog(" Block 0 : 0x%08X %s", bl0, sprint_bin(DemodBuffer+config.offset+repeat,32) ); PrintAndLog(" Block 1 : 0x%08X %s", bl1, sprint_bin(DemodBuffer+config.offset+repeat+32,32) ); PrintAndLog("-------------------------------------------------------------"); /* TRACE - BLOCK O Bits Definition HEX 1-8 ACL Allocation class (ISO/IEC 15963-1) 0xE0 9-16 MFC Manufacturer ID (ISO/IEC 7816-6) 0x15 Atmel Corporation 17-21 CID 0x1 = Atmel ATA5577M1 0x2 = Atmel ATA5577M2 22-24 ICR IC revision 25-28 YEAR (BCD encoded) 9 (= 2009) 29-30 QUARTER 1,2,3,4 31-32 LOT ID TRACE - BLOCK 1 1-12 LOT ID 13-17 Wafer number 18-32 DW, die number sequential */ return 0; } int CmdT55xxInfo(const char *Cmd){ /* Page 0 Block 0 Configuration data. Normal mode Extended mode */ char cmdp = param_getchar(Cmd, 0); if (strlen(Cmd) > 1 || cmdp == 'h' || cmdp == 'H') return usage_t55xx_info(); if (strlen(Cmd)==0) AquireData( CONFIGURATION_BLOCK ); if (!DecodeT55xxBlock()) return 1; if ( DemodBufferLen < 32) return 1; uint8_t si = config.offset; uint32_t bl0 = PackBits(si, 32, DemodBuffer); uint32_t safer = PackBits(si, 4, DemodBuffer); si += 4; uint32_t resv = PackBits(si, 7, DemodBuffer); si += 7; uint32_t dbr = PackBits(si, 3, DemodBuffer); si += 3; uint32_t extend = PackBits(si, 1, DemodBuffer); si += 1; uint32_t datamod = PackBits(si, 5, DemodBuffer); si += 5; uint32_t pskcf = PackBits(si, 2, DemodBuffer); si += 2; uint32_t aor = PackBits(si, 1, DemodBuffer); si += 1; uint32_t otp = PackBits(si, 1, DemodBuffer); si += 1; uint32_t maxblk = PackBits(si, 3, DemodBuffer); si += 3; uint32_t pwd = PackBits(si, 1, DemodBuffer); si += 1; uint32_t sst = PackBits(si, 1, DemodBuffer); si += 1; uint32_t fw = PackBits(si, 1, DemodBuffer); si += 1; uint32_t inv = PackBits(si, 1, DemodBuffer); si += 1; uint32_t por = PackBits(si, 1, DemodBuffer); si += 1; PrintAndLog(""); PrintAndLog("-- T55xx Configuration & Tag Information --------------------"); PrintAndLog("-------------------------------------------------------------"); PrintAndLog(" Safer key : %s", GetSaferStr(safer)); PrintAndLog(" reserved : %d", resv); PrintAndLog(" Data bit rate : %s", GetBitRateStr(dbr)); PrintAndLog(" eXtended mode : %s", (extend) ? "Yes - Warning":"No"); PrintAndLog(" Modulation : %s", GetModulationStr(datamod)); PrintAndLog(" PSK clock frequency : %d", pskcf); PrintAndLog(" AOR - Answer on Request : %s", (aor) ? "Yes":"No"); PrintAndLog(" OTP - One Time Pad : %s", (otp) ? "Yes - Warning":"No" ); PrintAndLog(" Max block : %d", maxblk); PrintAndLog(" Password mode : %s", (pwd) ? "Yes":"No"); PrintAndLog(" Sequence Start Terminator : %s", (sst) ? "Yes":"No"); PrintAndLog(" Fast Write : %s", (fw) ? "Yes":"No"); PrintAndLog(" Inverse data : %s", (inv) ? "Yes":"No"); PrintAndLog(" POR-Delay : %s", (por) ? "Yes":"No"); PrintAndLog("-------------------------------------------------------------"); PrintAndLog(" Raw Data - Page 0"); PrintAndLog(" Block 0 : 0x%08X %s", bl0, sprint_bin(DemodBuffer+config.offset,32) ); PrintAndLog("-------------------------------------------------------------"); return 0; } int CmdT55xxDump(const char *Cmd){ char s[20] = {0x00}; uint8_t pwd[4] = {0x00}; char cmdp = param_getchar(Cmd, 0); if ( cmdp == 'h' || cmdp == 'H') { usage_t55xx_dump(); return 0; } bool hasPwd = ( strlen(Cmd) > 0); if ( hasPwd ){ if (param_gethex(Cmd, 0, pwd, 8)) { PrintAndLog("password must include 8 HEX symbols"); return 1; } } for ( int i = 0; i <8; ++i){ memset(s,0,sizeof(s)); if ( hasPwd ) { sprintf(s,"%d %02x%02x%02x%02x", i, pwd[0],pwd[1],pwd[2],pwd[3]); } else { sprintf(s,"%d", i); } CmdT55xxReadBlock(s); } return 0; } int AquireData( uint8_t block ){ UsbCommand c; if ( block == CONFIGURATION_BLOCK ) c.cmd = CMD_T55XX_READ_BLOCK; else if (block == TRACE_BLOCK ) c.cmd = CMD_T55XX_READ_TRACE; c.arg[0] = 0x00; c.arg[1] = 0x00; c.arg[2] = 0x00; c.d.asBytes[0] = 0x0; //Password mode // if ( res == 2 ) { // c.arg[2] = password; // c.d.asBytes[0] = 0x1; // } SendCommand(&c); if ( !WaitForResponseTimeout(CMD_ACK,NULL,2500) ) { PrintAndLog("command execution time out"); return 1; } uint8_t got[12000]; GetFromBigBuf(got,sizeof(got),0); WaitForResponse(CMD_ACK,NULL); setGraphBuf(got, 12000); return 0; } char * GetBitRateStr(uint32_t id){ static char buf[25]; char *retStr = buf; switch (id){ case 0: snprintf(retStr,sizeof(buf),"%d - RF/8",id); break; case 1: snprintf(retStr,sizeof(buf),"%d - RF/16",id); break; case 2: snprintf(retStr,sizeof(buf),"%d - RF/32",id); break; case 3: snprintf(retStr,sizeof(buf),"%d - RF/40",id); break; case 4: snprintf(retStr,sizeof(buf),"%d - RF/50",id); break; case 5: snprintf(retStr,sizeof(buf),"%d - RF/64",id); break; case 6: snprintf(retStr,sizeof(buf),"%d - RF/100",id); break; case 7: snprintf(retStr,sizeof(buf),"%d - RF/128",id); break; default: snprintf(retStr,sizeof(buf),"%d - (Unknown)",id); break; } return buf; } char * GetSaferStr(uint32_t id){ static char buf[40]; char *retStr = buf; snprintf(retStr,sizeof(buf),"%d",id); if (id == 6) { snprintf(retStr,sizeof(buf),"%d - passwd",id); } if (id == 9 ){ snprintf(retStr,sizeof(buf),"%d - testmode",id); } return buf; } char * GetModulationStr( uint32_t id){ static char buf[60]; char *retStr = buf; switch (id){ case 0: snprintf(retStr,sizeof(buf),"%d - DIRECT (ASK/NRZ)",id); break; case 1: snprintf(retStr,sizeof(buf),"%d - PSK 1 phase change when input changes",id); break; case 2: snprintf(retStr,sizeof(buf),"%d - PSK 2 phase change on bitclk if input high",id); break; case 3: snprintf(retStr,sizeof(buf),"%d - PSK 3 phase change on rising edge of input",id); break; case 4: snprintf(retStr,sizeof(buf),"%d - FSK 1 RF/8 RF/5",id); break; case 5: snprintf(retStr,sizeof(buf),"%d - FSK 2 RF/8 RF/10",id); break; case 6: snprintf(retStr,sizeof(buf),"%d - FSK 1a RF/5 RF/8",id); break; case 7: snprintf(retStr,sizeof(buf),"%d - FSK 2a RF/10 RF/8",id); break; case 8: snprintf(retStr,sizeof(buf),"%d - Manchester",id); break; case 16: snprintf(retStr,sizeof(buf),"%d - Biphase",id); break; case 0x18: snprintf(retStr,sizeof(buf),"%d - Biphase a - AKA Conditional Dephase Encoding(CDP)",id); break; case 17: snprintf(retStr,sizeof(buf),"%d - Reserved",id); break; default: snprintf(retStr,sizeof(buf),"0x%02X (Unknown)",id); break; } return buf; } char * GetModelStrFromCID(uint32_t cid){ static char buf[10]; char *retStr = buf; if (cid == 1) snprintf(retStr, sizeof(buf),"ATA5577M1"); if (cid == 2) snprintf(retStr, sizeof(buf),"ATA5577M2"); return buf; } char * GetSelectedModulationStr( uint8_t id){ static char buf[20]; char *retStr = buf; switch (id){ case DEMOD_FSK: snprintf(retStr,sizeof(buf),"FSK"); break; case DEMOD_FSK1: snprintf(retStr,sizeof(buf),"FSK1"); break; case DEMOD_FSK1a: snprintf(retStr,sizeof(buf),"FSK1a"); break; case DEMOD_FSK2: snprintf(retStr,sizeof(buf),"FSK2"); break; case DEMOD_FSK2a: snprintf(retStr,sizeof(buf),"FSK2a"); break; case DEMOD_ASK: snprintf(retStr,sizeof(buf),"ASK"); break; case DEMOD_NRZ: snprintf(retStr,sizeof(buf),"DIRECT/NRZ"); break; case DEMOD_PSK1: snprintf(retStr,sizeof(buf),"PSK1"); break; case DEMOD_PSK2: snprintf(retStr,sizeof(buf),"PSK2"); break; case DEMOD_PSK3: snprintf(retStr,sizeof(buf),"PSK3"); break; case DEMOD_BI: snprintf(retStr,sizeof(buf),"BIPHASE"); break; case DEMOD_BIa: snprintf(retStr,sizeof(buf),"BIPHASEa - (CDP)"); break; default: snprintf(retStr,sizeof(buf),"(Unknown)"); break; } return buf; } /* uint32_t PackBits(uint8_t start, uint8_t len, uint8_t* bits){ int i = start; int j = len-1; if (len > 32) return 0; uint32_t tmp = 0; for (; j >= 0; --j, ++i) tmp |= bits[i] << j; return tmp; } */ static command_t CommandTable[] = { {"help", CmdHelp, 1, "This help"}, {"config", CmdT55xxSetConfig, 1, "Set/Get T55XX configuration (modulation, inverted, offset, rate)"}, {"detect", CmdT55xxDetect, 0, "[1] Try detecting the tag modulation from reading the configuration block."}, {"read", CmdT55xxReadBlock, 0, " [password] -- Read T55xx block data (page 0) [optional password]"}, {"write", CmdT55xxWriteBlock,0, " [password] -- Write T55xx block data (page 0) [optional password]"}, {"trace", CmdT55xxReadTrace, 0, "[1] Show T55xx traceability data (page 1/ blk 0-1)"}, {"info", CmdT55xxInfo, 0, "[1] Show T55xx configuration data (page 0/ blk 0)"}, {"dump", CmdT55xxDump, 0, "[password] Dump T55xx card block 0-7. [optional password]"}, {"special", special, 0, "Show block changes with 64 different offsets"}, {NULL, NULL, 0, NULL} }; int CmdLFT55XX(const char *Cmd) { CmdsParse(CommandTable, Cmd); return 0; } int CmdHelp(const char *Cmd) { CmdsHelp(CommandTable); return 0; }