Cleanup Code

[proxmark3-svn] / client / emv / emvcore.c

//-----------------------------------------------------------------------------
// Copyright (C) 2017 Merlok
//
// 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.
//-----------------------------------------------------------------------------
// EMV core functions
//-----------------------------------------------------------------------------

#include "emvcore.h"

#include <string.h>
#include "emvjson.h"
#include "util_posix.h"
#include "protocols.h"
#include "ui.h"
#include "util.h"
#include "emv_tags.h"
#include "emv_pk.h"
#include "emv_pki.h"
#include "cmdhf14a.h"
#include "apduinfo.h"
#include "tlv.h"
#include "dump.h"
#include "dol.h"

#ifdef WITH_SMARTCARD
#include "cmdsmartcard.h"
#endif


// Got from here. Thanks)
// https://eftlab.co.uk/index.php/site-map/knowledge-base/211-emv-aid-rid-pix
static const char *PSElist [] = {
	"325041592E5359532E4444463031", // 2PAY.SYS.DDF01 - Visa Proximity Payment System Environment - PPSE
	"315041592E5359532E4444463031"  // 1PAY.SYS.DDF01 - Visa Payment System Environment - PSE
};
//static const size_t PSElistLen = sizeof(PSElist)/sizeof(char*);

char *TransactionTypeStr[] = {
	"MSD",
	"VSDC",
	"qVCDCMCHIP",
	"CDA"
};

typedef struct {
	enum CardPSVendor vendor;
	const char* aid;
} TAIDList;

static const TAIDList AIDlist [] = {
	// Visa International
	{ CV_VISA,  "A00000000305076010"},          // VISA ELO Credit
	{ CV_VISA,  "A0000000031010" },             // VISA Debit/Credit (Classic)
	{ CV_VISA,  "A000000003101001" },           // VISA Credit
	{ CV_VISA,  "A000000003101002" },           // VISA Debit
	{ CV_VISA,  "A0000000032010" },             // VISA Electron
	{ CV_VISA,  "A0000000032020" },             // VISA
	{ CV_VISA,  "A0000000033010" },             // VISA Interlink
	{ CV_VISA,  "A0000000034010" },             // VISA Specific
	{ CV_VISA,  "A0000000035010" },             // VISA Specific
	{ CV_VISA,  "A0000000036010" },             // Domestic Visa Cash Stored Value
	{ CV_VISA,  "A0000000036020" },             // International Visa Cash Stored Value
	{ CV_VISA,  "A0000000038002" },             // VISA Auth, VisaRemAuthen EMV-CAP (DPA)
	{ CV_VISA,  "A0000000038010" },             // VISA Plus
	{ CV_VISA,  "A0000000039010" },             // VISA Loyalty
	{ CV_VISA,  "A000000003999910" },           // VISA Proprietary ATM
	// Visa USA
	{ CV_VISA,  "A000000098" },                 // Debit Card
	{ CV_VISA,  "A0000000980848" },             // Debit Card
	// Mastercard International
	{ CV_MASTERCARD, "A00000000401" },          // MasterCard PayPass
	{ CV_MASTERCARD, "A0000000041010" },        // MasterCard Credit
	{ CV_MASTERCARD, "A00000000410101213" },    // MasterCard Credit
	{ CV_MASTERCARD, "A00000000410101215" },    // MasterCard Credit
	{ CV_MASTERCARD, "A0000000042010" },        // MasterCard Specific
	{ CV_MASTERCARD, "A0000000043010" },        // MasterCard Specific
	{ CV_MASTERCARD, "A0000000043060" },        // Maestro (Debit)
	{ CV_MASTERCARD, "A000000004306001" },      // Maestro (Debit)
	{ CV_MASTERCARD, "A0000000044010" },        // MasterCard Specific
	{ CV_MASTERCARD, "A0000000045010" },        // MasterCard Specific
	{ CV_MASTERCARD, "A0000000046000" },        // Cirrus
	{ CV_MASTERCARD, "A0000000048002" },        // SecureCode Auth EMV-CAP
	{ CV_MASTERCARD, "A0000000049999" },        // MasterCard PayPass
	{ CV_MASTERCARD, "B012345678" },            // Maestro TEST Used for development
	// American Express
	{ CV_AMERICANEXPRESS, "A000000025" },
	{ CV_AMERICANEXPRESS, "A0000000250000" },
	{ CV_AMERICANEXPRESS, "A00000002501" },
	{ CV_AMERICANEXPRESS, "A000000025010402" },
	{ CV_AMERICANEXPRESS, "A000000025010701" },
	{ CV_AMERICANEXPRESS, "A000000025010801" },
	// Groupement des Cartes Bancaires "CB"
	{ CV_CB, "A0000000421010" },                // Cartes Bancaire EMV Card
	{ CV_CB, "A0000000422010" },
	{ CV_CB, "A0000000423010" },
	{ CV_CB, "A0000000424010" },
	{ CV_CB, "A0000000425010" },
	// JCB CO., LTD.
	{ CV_JCB, "A00000006510" },                 // JCB
	{ CV_JCB, "A0000000651010" },               // JCB J Smart Credit
	// Switch Card Services Ltd.
	{ CV_SWITCH, "A0000000050001" },            // Maestro UK
	{ CV_SWITCH, "A0000000050002" },            // Solo
	// Diners Club International Ltd.
	{ CV_DINERS, "A0000001523010" },            // Discover, Pulse D Pas Discover Card
	{ CV_DINERS, "A0000001524010" },            // Discover, Discover Debit Common Card
	// Other
	{ CV_OTHER, "A00000002401" },               // Midland Bank Plc - Self Service
	{ CV_OTHER, "A0000000291010" },             // LINK Interchange Network Ltd - Link / American Express
	{ CV_OTHER, "A00000006900" },               // Société Européenne de Monnaie Electronique SEME - Moneo
	{ CV_OTHER, "A000000077010000021000000000003B" },  // Oberthur Technologies France - Visa AEPN
	{ CV_OTHER, "A0000001211010" },             // PBS Danmark A/S - Denmark - Dankort (VISA GEM Vision) - Danish domestic debit card
	{ CV_OTHER, "A0000001410001" },             // Associazione Bancaria Italiana - Italy - PagoBANCOMAT - CoGeBan Consorzio BANCOMAT (Italian domestic debit card)
	{ CV_OTHER, "A0000001544442" },             // Banricompras Debito - Banrisul - Banco do Estado do Rio Grande do SUL - S.A.
	{ CV_OTHER, "A000000172950001" },           // Financial Information Service Co. Ltd. - Taiwan - BAROC Financial Application Taiwan- The Bankers Association of the Republic of China
	{ CV_OTHER, "A0000001850002" },             // Post Office Limited - United Kingdom - UK Post Office Account card
	{ CV_OTHER, "A0000002281010" },             // Saudi Arabian Monetary Agency (SAMA) - Kingdom of Saudi Arabia - SPAN (M/Chip) - SPAN2 (Saudi Payments Network) - Saudi Arabia domestic credit/debit card (Saudi Arabia Monetary Agency)
	{ CV_OTHER, "A0000002282010" },             // Saudi Arabian Monetary Agency (SAMA) - Kingdom of Saudi Arabia - SPAN (VIS) - SPAN2 (Saudi Payments Network) - Saudi Arabia domestic credit/debit card (Saudi Arabia Monetary Agency)
	{ CV_OTHER, "A0000002771010" },             // Interac Association - Canada - INTERAC - Canadian domestic credit/debit card
	{ CV_OTHER, "A00000031510100528" },         // Currence Holding/PIN BV - The Netherlands- Currence PuC
	{ CV_OTHER, "A0000003156020" },             // Currence Holding/PIN BV - The Netherlands - Chipknip
	{ CV_OTHER, "A0000003591010028001" },       // Euro Alliance of Payment Schemes s.c.r.l. (EAPS) - Belgium - Girocard EAPS - ZKA (Germany)
	{ CV_OTHER, "A0000003710001" },             // Verve - Nigeria - InterSwitch Verve Card - Nigerian local switch company
	{ CV_OTHER, "A0000004540010" },             // eTranzact - Nigeria - Etranzact Genesis Card - Nigerian local switch company
	{ CV_OTHER, "A0000004540011" },             // eTranzact - Nigeria - Etranzact Genesis Card 2 - Nigerian local switch company
	{ CV_OTHER, "A0000004766C" },               // Google - United States - GOOGLE_PAYMENT_AID
	{ CV_OTHER, "A0000005241010" },             // RuPay - India - RuPay - RuPay (India)
	{ CV_OTHER, "A0000006723010" },             // TROY - Turkey - TROY chip credit card - Turkey's Payment Method
	{ CV_OTHER, "A0000006723020" },             // TROY - Turkey - TROY chip debit card - Turkey's Payment Method
	{ CV_OTHER, "A0000007705850" },             // Indian Oil Corporation Limited - India - XTRAPOWER Fleet Card Program - Indian Oil’s Pre Paid Program
	{ CV_OTHER, "D27600002545500100" },         // ZKA - Germany - Girocard - ZKA Girocard (Geldkarte) (Germany)
	{ CV_OTHER, "D5280050218002" },             // The Netherlands - ? - (Netherlands)
	{ CV_OTHER, "D5780000021010" },             // Bankaxept    Norway  Bankaxept   Norwegian domestic debit card
	{ CV_OTHER, "F0000000030001" },             // BRADESCO - Brazilian Bank Banco Bradesco
};
static const size_t AIDlistLen = sizeof(AIDlist)/sizeof(TAIDList);

static bool APDULogging = false;
void SetAPDULogging(bool logging) {
	APDULogging = logging;
}

void DropFieldEx(EMVCommandChannel channel) {
	if (channel == ECC_CONTACTLESS) {
		DropField();
	}
}

enum CardPSVendor GetCardPSVendor(uint8_t * AID, size_t AIDlen) {
	char buf[100] = {0};
	if (AIDlen < 1)
		return CV_NA;

	hex_to_buffer((uint8_t *)buf, AID, AIDlen, sizeof(buf) - 1, 0, 0, true);

	for(int i = 0; i < AIDlistLen; i ++) {
		if (strncmp(AIDlist[i].aid, buf, strlen(AIDlist[i].aid)) == 0){
			return AIDlist[i].vendor;
		}
	}

	return CV_NA;
}

static bool print_cb(void *data, const struct tlv *tlv, int level, bool is_leaf) {
	emv_tag_dump(tlv, stdout, level);
	if (is_leaf) {
		dump_buffer(tlv->value, tlv->len, stdout, level);
	}

	return true;
}

bool TLVPrintFromBuffer(uint8_t *data, int datalen) {
	struct tlvdb *t = NULL;
	t = tlvdb_parse_multi(data, datalen);
	if (t) {
		PrintAndLogEx(NORMAL, "-------------------- TLV decoded --------------------");

		tlvdb_visit(t, print_cb, NULL, 0);
		tlvdb_free(t);
		return true;
	} else {
		PrintAndLogEx(WARNING, "TLV ERROR: Can't parse response as TLV tree.");
	}
	return false;
}

void TLVPrintFromTLVLev(struct tlvdb *tlv, int level) {
	if (!tlv)
		return;

	tlvdb_visit(tlv, print_cb, NULL, level);
}

void TLVPrintFromTLV(struct tlvdb *tlv) {
	TLVPrintFromTLVLev(tlv, 0);
}

void TLVPrintAIDlistFromSelectTLV(struct tlvdb *tlv) {
	PrintAndLogEx(NORMAL, "|------------------|--------|-------------------------|");
	PrintAndLogEx(NORMAL, "|    AID           |Priority| Name                    |");
	PrintAndLogEx(NORMAL, "|------------------|--------|-------------------------|");

	struct tlvdb *ttmp = tlvdb_find(tlv, 0x6f);
	if (!ttmp)
		PrintAndLogEx(NORMAL, "|                         none                        |");

	while (ttmp) {
		const struct tlv *tgAID = tlvdb_get_inchild(ttmp, 0x84, NULL);
		const struct tlv *tgName = tlvdb_get_inchild(ttmp, 0x50, NULL);
		const struct tlv *tgPrio = tlvdb_get_inchild(ttmp, 0x87, NULL);
		if (!tgAID)
			break;
		PrintAndLogEx(NORMAL, "|%s|   %s  |%s|",
			sprint_hex_inrow_ex(tgAID->value, tgAID->len, 18),
			(tgPrio) ? sprint_hex(tgPrio->value, 1) : "   ",
			(tgName) ? sprint_ascii_ex(tgName->value, tgName->len, 25) : "                         ");

		ttmp = tlvdb_find_next(ttmp, 0x6f);
	}

	PrintAndLogEx(NORMAL, "|------------------|--------|-------------------------|");
}

struct tlvdb *GetPANFromTrack2(const struct tlv *track2) {
	char track2Hex[200] = {0};
	uint8_t PAN[100] = {0};
	int PANlen = 0;
	char *tmp = track2Hex;

	if (!track2)
		return NULL;

	for (int i = 0; i < track2->len; ++i, tmp += 2)
		sprintf(tmp, "%02x", (unsigned int)track2->value[i]);

	int posD = strchr(track2Hex, 'd') - track2Hex;
	if (posD < 1)
		return NULL;

	track2Hex[posD] = 0;
	if (strlen(track2Hex) % 2) {
		track2Hex[posD] = 'F';
		track2Hex[posD + 1] = '\0';
	}

	param_gethex_to_eol(track2Hex, 0, PAN, sizeof(PAN), &PANlen);

  return tlvdb_fixed(0x5a, PANlen, PAN);
}

struct tlvdb *GetdCVVRawFromTrack2(const struct tlv *track2) {
	char track2Hex[200] = {0};
	char dCVVHex[100] = {0};
	uint8_t dCVV[100] = {0};
	int dCVVlen = 0;
	const int PINlen = 5; // must calculated from 9F67 MSD Offset but i have not seen this tag)
	char *tmp = track2Hex;

	if (!track2)
		return NULL;

	for (int i = 0; i < track2->len; ++i, tmp += 2)
		sprintf(tmp, "%02x", (unsigned int)track2->value[i]);

	int posD = strchr(track2Hex, 'd') - track2Hex;
	if (posD < 1)
		return NULL;

	memset(dCVVHex, '0', 32);
	// ATC
	memcpy(dCVVHex + 0, track2Hex + posD + PINlen + 11, 4);
	// PAN 5 hex
	memcpy(dCVVHex + 4, track2Hex, 5);
	// expire date
	memcpy(dCVVHex + 9, track2Hex + posD + 1, 4);
	// service code
	memcpy(dCVVHex + 13, track2Hex + posD + 5, 3);

	param_gethex_to_eol(dCVVHex, 0, dCVV, sizeof(dCVV), &dCVVlen);

  return tlvdb_fixed(0x02, dCVVlen, dCVV);
}


int EMVExchangeEx(EMVCommandChannel channel, bool ActivateField, bool LeaveFieldON, uint8_t *apdu, int apdu_len, uint8_t *Result, size_t MaxResultLen, size_t *ResultLen, uint16_t *sw, struct tlvdb *tlv) 
{
	*ResultLen = 0;
	if (sw)	*sw = 0;
	uint16_t isw = 0;
	int res = 0;

	if (ActivateField) {
		DropFieldEx( channel );
		msleep(50);
	}

	if (APDULogging)
		PrintAndLogEx(SUCCESS, ">>>> %s", sprint_hex(apdu, apdu_len));

#ifdef WITH_SMARTCARD
	switch(channel) {
		case ECC_CONTACTLESS:
			// 6 byes + data = INS + CLA + P1 + P2 + Lc + <data = Nc> + Le(?IncludeLe)
			res = ExchangeAPDU14a(apdu, apdu_len, ActivateField, LeaveFieldON, Result, (int)MaxResultLen, (int *)ResultLen);
			break;
		case ECC_CONTACT:
			res = ExchangeAPDUSC(apdu, apdu_len, ActivateField, LeaveFieldON, Result, (int)MaxResultLen, (int *)ResultLen);
			break;
	}
#else
	res = ExchangeAPDU14a(apdu, apdu_len, ActivateField, LeaveFieldON, Result, (int)MaxResultLen, (int *)ResultLen);
#endif	

	if (res) {
		return res;
	}

	if (APDULogging)
		PrintAndLogEx(SUCCESS, "<<<< %s", sprint_hex(Result, *ResultLen));

	if (*ResultLen < 2) {
		return 200;
	}

	if (Result[*ResultLen-2] == 0x61) {
		uint8_t La = Result[*ResultLen-1];
		uint8_t get_response[5] = {apdu[0], ISO7816_GET_RESPONSE, 0x00, 0x00, La};
		size_t oldlen = *ResultLen;
		res = EMVExchangeEx(channel, false, LeaveFieldON, get_response, sizeof(get_response), &Result[oldlen-2], MaxResultLen-oldlen+2, ResultLen, sw, tlv);
		*ResultLen += oldlen;
	}

	if (res) return res;

	*ResultLen -= 2;
	
	isw = Result[*ResultLen] * 0x0100 + Result[*ResultLen + 1];
	if (sw)
		*sw = isw;

	if (isw != 0x9000) {
		if (APDULogging) {
			PrintAndLogEx(ERR, "APDU(%02x%02x) ERROR: [%4X] %s", apdu[0], apdu[1], isw, GetAPDUCodeDescription(*sw >> 8, *sw & 0xff));
			return 5;
		}
	}

	// add to tlv tree
	if (tlv) {
		struct tlvdb *t = tlvdb_parse_multi(Result, *ResultLen);
		tlvdb_add(tlv, t);
	}

	return 0;
}

static int EMVExchange(EMVCommandChannel channel, bool LeaveFieldON, uint8_t *apdu, int apdu_len, uint8_t *Result, size_t MaxResultLen, size_t *ResultLen, uint16_t *sw, struct tlvdb *tlv) 
{
	uint8_t APDU[APDU_COMMAND_LEN];
	memcpy(APDU, apdu, apdu_len);
	APDU[apdu_len] = 0x00; 
	if (channel == ECC_CONTACTLESS) {
		if (apdu_len == 5) {
			// there is no Lc but an Le already
		} else if (apdu_len > 5 && apdu_len == 5 + apdu[4] + 1) {
			// there is Lc, data and Le
		} else {
			apdu_len++; // no Le, add Le = 0x00 because some vendors require it for contactless
		}
	}
	return EMVExchangeEx(channel, false, LeaveFieldON, APDU, apdu_len, Result, MaxResultLen, ResultLen, sw, tlv);
}

int EMVSelect(EMVCommandChannel channel, bool ActivateField, bool LeaveFieldON, uint8_t *AID, size_t AIDLen, uint8_t *Result, size_t MaxResultLen, size_t *ResultLen, uint16_t *sw, struct tlvdb *tlv) 
{
	uint8_t Select_APDU[APDU_COMMAND_LEN] = {0x00, ISO7816_SELECT_FILE, 0x04, 0x00, AIDLen, 0x00};
	memcpy(Select_APDU + 5, AID, AIDLen);
	int apdulen = 5 + AIDLen;
	if (channel == ECC_CONTACTLESS) {
		apdulen++;  // some vendors require Le = 0x00 for contactless operations
	}
	return EMVExchangeEx(channel, ActivateField, LeaveFieldON, Select_APDU, apdulen, Result, MaxResultLen, ResultLen, sw, tlv);
}

int EMVSelectPSE(EMVCommandChannel channel, bool ActivateField, bool LeaveFieldON, uint8_t PSENum, uint8_t *Result, size_t MaxResultLen, size_t *ResultLen, uint16_t *sw) {
	uint8_t buf[APDU_DATA_LEN] = {0};
	*ResultLen = 0;
	int len = 0;
	int res = 0;
	switch (PSENum) {
		case 1:
			param_gethex_to_eol(PSElist[1], 0, buf, sizeof(buf), &len);
			break;
		case 2:
		
			param_gethex_to_eol(PSElist[0], 0, buf, sizeof(buf), &len);
			break;
		default:
			return -1;
	}

	// select
	res = EMVSelect(channel, ActivateField, LeaveFieldON, buf, len, Result, MaxResultLen, ResultLen, sw, NULL);

	return res;
}


int EMVSelectWithRetry(EMVCommandChannel channel, bool ActivateField, bool LeaveFieldON, uint8_t *AID, size_t AIDLen, uint8_t *Result, size_t MaxResultLen, size_t *ResultLen, uint16_t *sw, struct tlvdb *tlv) {
	int retrycnt = 0;
	int res = 0;
	do {
		res = EMVSelect(channel, false, true, AID, AIDLen, Result, MaxResultLen, ResultLen, sw, tlv);

		// retry if error and not returned sw error
		if (res && res != 5) {
			if (++retrycnt < 3){
				continue;
			} else {
				// card select error, proxmark error
				if (res == 1) {
					PrintAndLogEx(WARNING, "Exit...");
					return 1;
				}
				
				retrycnt = 0;
				PrintAndLogEx(NORMAL, "Retry failed [%s]. Skiped...", sprint_hex_inrow(AID, AIDLen));
				return res;
			}	
		}
	} while (res && res != 5);

	return res;
}


int EMVCheckAID(EMVCommandChannel channel, bool decodeTLV, struct tlvdb *tlvdbelm, struct tlvdb *tlv){
	uint8_t data[APDU_RESPONSE_LEN] = {0};
	size_t datalen = 0;
	int res = 0;
	uint16_t sw = 0;

	while (tlvdbelm) {
		const struct tlv *tgAID = tlvdb_get_inchild(tlvdbelm, 0x4f, NULL);
		if (tgAID) {
			res = EMVSelectWithRetry(channel, false, true, (uint8_t *)tgAID->value, tgAID->len, data, sizeof(data), &datalen, &sw, tlv);

			// if returned sw error
			if (res == 5) {
				// next element
				tlvdbelm = tlvdb_find_next(tlvdbelm, 0x61);
				continue;
			}
			
			if (res)
				break;

			// all is ok
			if (decodeTLV){
				PrintAndLogEx(NORMAL, "%s:", sprint_hex_inrow(tgAID->value, tgAID->len));
				TLVPrintFromBuffer(data, datalen);
			}
		}
		tlvdbelm = tlvdb_find_next(tlvdbelm, 0x61);
	}
	return res;
}


int EMVSearchPSE(EMVCommandChannel channel, bool ActivateField, bool LeaveFieldON, uint8_t PSENum, bool decodeTLV, struct tlvdb *tlv) {
	uint8_t data[APDU_RESPONSE_LEN] = {0};
	size_t datalen = 0;
	uint8_t sfidata[0x11][APDU_RESPONSE_LEN] = {0};
	size_t sfidatalen[0x11] = {0};
	uint16_t sw = 0;
	int res;
	bool fileFound = false;

	char *PSE_or_PPSE = PSENum == 1 ? "PSE" : "PPSE";
	
	// select PPSE
	res = EMVSelectPSE(channel, ActivateField, true, PSENum, data, sizeof(data), &datalen, &sw);

	if (!res){
		if (sw != 0x9000) {
			PrintAndLogEx(FAILED, "Select PSE error. APDU error: %04x.", sw);
			return 1;
		}
		
		struct tlvdb *t = NULL;
		t = tlvdb_parse_multi(data, datalen);
		if (t) {
			// PSE/PPSE with SFI
			struct tlvdb *tsfi = tlvdb_find_path(t, (tlv_tag_t[]){0x6f, 0xa5, 0x88, 0x00});
			if (tsfi) {
				uint8_t sfin = 0;
				tlv_get_uint8(tlvdb_get_tlv(tsfi), &sfin);
				PrintAndLogEx(INFO, "* PPSE get SFI: 0x%02x.", sfin);
				
				for (uint8_t ui = 0x01; ui <= 0x10; ui++) {
					PrintAndLogEx(INFO, "* * Get SFI: 0x%02x. num: 0x%02x", sfin, ui);
					res = EMVReadRecord(channel, true, sfin, ui, sfidata[ui], APDU_RESPONSE_LEN, &sfidatalen[ui], &sw, NULL);
					
					// end of records
					if (sw == 0x6a83) {
						sfidatalen[ui] = 0;
						PrintAndLogEx(INFO, "* * PPSE get SFI. End of records.");
						break;
					}
					
					// error catch!
					if (sw != 0x9000) {
						sfidatalen[ui] = 0;
						PrintAndLogEx(FAILED, "PPSE get Error. APDU error: %04x.", sw);
						break;
					}

					if (decodeTLV){
						TLVPrintFromBuffer(sfidata[ui], sfidatalen[ui]);
					}
				}

				for (uint8_t ui = 0x01; ui <= 0x10; ui++) {
					if (sfidatalen[ui]) {
						struct tlvdb *tsfi = NULL;
						tsfi = tlvdb_parse_multi(sfidata[ui], sfidatalen[ui]);
						if (tsfi) {
							struct tlvdb *tsfitmp = tlvdb_find_path(tsfi, (tlv_tag_t[]){0x70, 0x61, 0x00});
							if (!tsfitmp) {
								PrintAndLogEx(FAILED, "SFI 0x%02d doesn't have any records.", sfidatalen[ui]);
								continue;
							}
							res = EMVCheckAID(channel, decodeTLV, tsfitmp, tlv);							
							fileFound = true;
						}
						tlvdb_free(tsfi);
					}
				}
			}


			// PSE/PPSE plain (wo SFI)
			struct tlvdb *ttmp = tlvdb_find_path(t, (tlv_tag_t[]){0x6f, 0xa5, 0xbf0c, 0x61, 0x00});
			if (ttmp) {
				res = EMVCheckAID(channel, decodeTLV, ttmp, tlv);
				fileFound = true;
			}
			
			if (!fileFound)
				PrintAndLogEx(FAILED, "PPSE doesn't have any records.");

			tlvdb_free(t);
		} else {
			PrintAndLogEx(WARNING, "%s ERROR: Can't get TLV from response.", PSE_or_PPSE);
		}
	} else {
		PrintAndLogEx(WARNING, "%s ERROR: Can't select PPSE AID. Error: %d", PSE_or_PPSE, res);
	}

	if (!LeaveFieldON)
		DropFieldEx( channel );

	return res;
}

int EMVSearch(EMVCommandChannel channel, bool ActivateField, bool LeaveFieldON, bool decodeTLV, struct tlvdb *tlv) {
	uint8_t aidbuf[APDU_DATA_LEN] = {0};
	int aidlen = 0;
	uint8_t data[APDU_RESPONSE_LEN] = {0};
	size_t datalen = 0;
	uint16_t sw = 0;

	int res = 0;
	int retrycnt = 0;
	for(int i = 0; i < AIDlistLen; i ++) {
		param_gethex_to_eol(AIDlist[i].aid, 0, aidbuf, sizeof(aidbuf), &aidlen);
		res = EMVSelect(channel, (i == 0) ? ActivateField : false, (i == AIDlistLen - 1) ? LeaveFieldON : true, aidbuf, aidlen, data, sizeof(data), &datalen, &sw, tlv);
		// retry if error and not returned sw error
		if (res && res != 5) {
			if (++retrycnt < 3){
				i--;
			} else {
				// (1) - card select error, proxmark error OR (200) - result length = 0
				if (res == 1 || res == 200) {
					PrintAndLogEx(WARNING, "Exit...");
					return 1;
				}

				retrycnt = 0;
				PrintAndLogEx(FAILED, "Retry failed [%s]. Skipped...", AIDlist[i].aid);
			}
			continue;
		}
		retrycnt = 0;

		if (res)
			continue;

		if (!datalen)
			continue;

		if (decodeTLV) {
			PrintAndLogEx(SUCCESS, "%s", AIDlist[i].aid);
			TLVPrintFromBuffer(data, datalen);
		}
	}

	return 0;
}

int EMVSelectApplication(struct tlvdb *tlv, uint8_t *AID, size_t *AIDlen) {
	// check priority. 0x00 - highest
	int prio = 0xffff;

	*AIDlen = 0;

	struct tlvdb *ttmp = tlvdb_find(tlv, 0x6f);
	if (!ttmp)
		return 1;

	while (ttmp) {
		const struct tlv *tgAID = tlvdb_get_inchild(ttmp, 0x84, NULL);
		const struct tlv *tgPrio = tlvdb_get_inchild(ttmp, 0x87, NULL);

		if (!tgAID)
			break;

		if (tgPrio) {
			int pt = bytes_to_num((uint8_t*)tgPrio->value, (tgPrio->len < 2) ? tgPrio->len : 2);
			if (pt < prio) {
				prio = pt;

				memcpy(AID, tgAID->value, tgAID->len);
				*AIDlen = tgAID->len;
			}
		} else {
			// takes the first application from list wo priority
			if (!*AIDlen) {
			memcpy(AID, tgAID->value, tgAID->len);
			*AIDlen = tgAID->len;
			}
		}

		ttmp = tlvdb_find_next(ttmp, 0x6f);
	}

	return 0;
}

int EMVGPO(EMVCommandChannel channel, bool LeaveFieldON, uint8_t *PDOL, size_t PDOLLen, uint8_t *Result, size_t MaxResultLen, size_t *ResultLen, uint16_t *sw, struct tlvdb *tlv) 
{
	uint8_t GPO_APDU[APDU_COMMAND_LEN] = {0x80, ISO7816_GET_PROCESSING_OPTIONS, 0x00, 0x00, PDOLLen, 0x00};
	memcpy(GPO_APDU + 5, PDOL, PDOLLen);
	int apdulen = 5 + PDOLLen;
	
	return EMVExchange(channel, LeaveFieldON, GPO_APDU, apdulen, Result, MaxResultLen, ResultLen, sw, tlv);
}

int EMVReadRecord(EMVCommandChannel channel, bool LeaveFieldON, uint8_t SFI, uint8_t SFIrec, uint8_t *Result, size_t MaxResultLen, size_t *ResultLen, uint16_t *sw, struct tlvdb *tlv)
{
	uint8_t read_APDU[5] = {0x00, ISO7816_READ_RECORDS, SFIrec, (SFI << 3) | 0x04, 0x00};
	int res = EMVExchange(channel, LeaveFieldON, read_APDU, sizeof(read_APDU), Result, MaxResultLen, ResultLen, sw, tlv);
	if (*sw == 0x6700) {
		PrintAndLogEx(INFO, ">>> trying to reissue command withouth Le...");
		res = EMVExchangeEx(channel, false, LeaveFieldON, read_APDU, sizeof(read_APDU), Result, MaxResultLen, ResultLen, sw, tlv);
	}
	return res;
}

int EMVAC(EMVCommandChannel channel, bool LeaveFieldON, uint8_t RefControl, uint8_t *CDOL, size_t CDOLLen, uint8_t *Result, size_t MaxResultLen, size_t *ResultLen, uint16_t *sw, struct tlvdb *tlv)
{
	uint8_t CDOL_APDU[APDU_COMMAND_LEN] = {0x80, 0xae, RefControl, 0x00, CDOLLen, 0x00};
	memcpy(CDOL_APDU + 5, CDOL, CDOLLen);
	int apdulen = 5 + CDOLLen;
	
	return EMVExchange(channel, LeaveFieldON, CDOL_APDU, apdulen, Result, MaxResultLen, ResultLen, sw, tlv);
}

int EMVGenerateChallenge(EMVCommandChannel channel, bool LeaveFieldON, uint8_t *Result, size_t MaxResultLen, size_t *ResultLen, uint16_t *sw, struct tlvdb *tlv) 
{
	uint8_t get_challenge_APDU[APDU_COMMAND_LEN] = {0x00, ISO7816_GET_CHALLENGE, 0x00, 0x00};
	
	int res = EMVExchange(channel, LeaveFieldON, get_challenge_APDU, 4, Result, MaxResultLen, ResultLen, sw, tlv);
	if (*sw == 0x6700) {
		PrintAndLogEx(INFO, ">>> trying to reissue command withouth Le...");
		res = EMVExchangeEx(channel, false, LeaveFieldON, get_challenge_APDU, 4, Result, MaxResultLen, ResultLen, sw, tlv);
	}
	return res;
}

int EMVInternalAuthenticate(EMVCommandChannel channel, bool LeaveFieldON, uint8_t *DDOL, size_t DDOLLen, uint8_t *Result, size_t MaxResultLen, size_t *ResultLen, uint16_t *sw, struct tlvdb *tlv) 
{
	uint8_t authenticate_APDU[APDU_COMMAND_LEN] = {0x00, ISO7816_INTERNAL_AUTHENTICATE, 0x00, 0x00, DDOLLen, 0x00};
	memcpy(authenticate_APDU + 5, DDOL, DDOLLen);
	int apdulen = 5 + DDOLLen;
	
	return EMVExchange(channel, LeaveFieldON, authenticate_APDU, apdulen, Result, MaxResultLen, ResultLen, sw, tlv);
}

int MSCComputeCryptoChecksum(EMVCommandChannel channel, bool LeaveFieldON, uint8_t *UDOL, uint8_t UDOLlen, uint8_t *Result, size_t MaxResultLen, size_t *ResultLen, uint16_t *sw, struct tlvdb *tlv)
{
	uint8_t checksum_APDU[APDU_COMMAND_LEN] = {0x80, 0x2a, 0x8e, 0x80, UDOLlen, 0x00};
	memcpy(checksum_APDU + 5, UDOL, UDOLlen);
	int apdulen = 5 + UDOLlen;
	
	return EMVExchange(channel, LeaveFieldON, checksum_APDU, apdulen, Result, MaxResultLen, ResultLen, sw, tlv);
}

// Authentication
struct emv_pk *get_ca_pk(struct tlvdb *db) {
	const struct tlv *df_tlv = tlvdb_get(db, 0x84, NULL);
	const struct tlv *caidx_tlv = tlvdb_get(db, 0x8f, NULL);

	if (!df_tlv || !caidx_tlv || df_tlv->len < 6 || caidx_tlv->len != 1)
		return NULL;

	PrintAndLogEx(NORMAL, "CA Public Key index 0x%0x", caidx_tlv->value[0]);
	return emv_pk_get_ca_pk(df_tlv->value, caidx_tlv->value[0]);
}

int trSDA(struct tlvdb *tlv) {

	struct emv_pk *pk = get_ca_pk(tlv);
	if (!pk) {
		PrintAndLogEx(WARNING, "Error: Key not found. Exit.");
		return 2;
	}

	struct emv_pk *issuer_pk = emv_pki_recover_issuer_cert(pk, tlv);
	if (!issuer_pk) {
		emv_pk_free(pk);
		PrintAndLogEx(WARNING, "Error: Issuer certificate not found. Exit.");
		return 2;
	}

	PrintAndLogEx(SUCCESS, "Issuer PK recovered. RID %02hhx:%02hhx:%02hhx:%02hhx:%02hhx IDX %02hhx CSN %02hhx:%02hhx:%02hhx",
		issuer_pk->rid[0],
		issuer_pk->rid[1],
		issuer_pk->rid[2],
		issuer_pk->rid[3],
		issuer_pk->rid[4],
		issuer_pk->index,
		issuer_pk->serial[0],
		issuer_pk->serial[1],
		issuer_pk->serial[2]
		);

	const struct tlv *sda_tlv = tlvdb_get(tlv, 0x21, NULL);
	if (!sda_tlv || sda_tlv->len < 1) {
		emv_pk_free(issuer_pk);
		emv_pk_free(pk);
		PrintAndLogEx(WARNING, "Can't find input list for Offline Data Authentication. Exit.");
		return 3;
	}

	struct tlvdb *dac_db = emv_pki_recover_dac(issuer_pk, tlv, sda_tlv);
	if (dac_db) {
		const struct tlv *dac_tlv = tlvdb_get(dac_db, 0x9f45, NULL);
		PrintAndLogEx(NORMAL, "SDA verified OK. (Data Authentication Code: %02hhx:%02hhx)\n", dac_tlv->value[0], dac_tlv->value[1]);
		tlvdb_add(tlv, dac_db);
	} else {
		emv_pk_free(issuer_pk);
		emv_pk_free(pk);
		PrintAndLogEx(WARNING, "SSAD verify error");
		return 4;
	}

	emv_pk_free(issuer_pk);
	emv_pk_free(pk);
	return 0;
}

static const unsigned char default_ddol_value[] = {0x9f, 0x37, 0x04};
static struct tlv default_ddol_tlv = {.tag = 0x9f49, .len = 3, .value = default_ddol_value };

int trDDA(EMVCommandChannel channel, bool decodeTLV, struct tlvdb *tlv) {
	uint8_t buf[APDU_RESPONSE_LEN] = {0};
	size_t len = 0;
	uint16_t sw = 0;

	struct emv_pk *pk = get_ca_pk(tlv);
	if (!pk) {
		PrintAndLogEx(WARNING, "Error: Key not found. Exit.");
		return 2;
	}

	const struct tlv *sda_tlv = tlvdb_get(tlv, 0x21, NULL);
/*	if (!sda_tlv || sda_tlv->len < 1) { it may be 0!!!!
		emv_pk_free(pk);
		PrintAndLogEx(WARNING, "Error: Can't find input list for Offline Data Authentication. Exit.");
		return 3;
	}
*/
	struct emv_pk *issuer_pk = emv_pki_recover_issuer_cert(pk, tlv);
	if (!issuer_pk) {
		emv_pk_free(pk);
		PrintAndLogEx(WARNING, "Error: Issuer certificate not found. Exit.");
		return 2;
	}
	PrintAndLogEx(SUCCESS, "Issuer PK recovered. RID %02hhx:%02hhx:%02hhx:%02hhx:%02hhx IDX %02hhx CSN %02hhx:%02hhx:%02hhx\n",
			issuer_pk->rid[0],
			issuer_pk->rid[1],
			issuer_pk->rid[2],
			issuer_pk->rid[3],
			issuer_pk->rid[4],
			issuer_pk->index,
			issuer_pk->serial[0],
			issuer_pk->serial[1],
			issuer_pk->serial[2]
			);

	struct emv_pk *icc_pk = emv_pki_recover_icc_cert(issuer_pk, tlv, sda_tlv);
	if (!icc_pk) {
		emv_pk_free(pk);
		emv_pk_free(issuer_pk);
		PrintAndLogEx(WARNING, "Error: ICC certificate not found. Exit.");
		return 2;
	}
	PrintAndLogEx(SUCCESS, "ICC PK recovered. RID %02hhx:%02hhx:%02hhx:%02hhx:%02hhx IDX %02hhx CSN %02hhx:%02hhx:%02hhx\n",
			icc_pk->rid[0],
			icc_pk->rid[1],
			icc_pk->rid[2],
			icc_pk->rid[3],
			icc_pk->rid[4],
			icc_pk->index,
			icc_pk->serial[0],
			icc_pk->serial[1],
			icc_pk->serial[2]
			);

	if (tlvdb_get(tlv, 0x9f2d, NULL)) {
		struct emv_pk *icc_pe_pk = emv_pki_recover_icc_pe_cert(issuer_pk, tlv);
		if (!icc_pe_pk) {
			PrintAndLogEx(WARNING, "WARNING: ICC PE PK recover error. ");
		} else {
			PrintAndLogEx(SUCCESS, "ICC PE PK recovered. RID %02hhx:%02hhx:%02hhx:%02hhx:%02hhx IDX %02hhx CSN %02hhx:%02hhx:%02hhx\n",
					icc_pe_pk->rid[0],
					icc_pe_pk->rid[1],
					icc_pe_pk->rid[2],
					icc_pe_pk->rid[3],
					icc_pe_pk->rid[4],
					icc_pe_pk->index,
					icc_pe_pk->serial[0],
					icc_pe_pk->serial[1],
					icc_pe_pk->serial[2]
					);
		}
	} else {
		PrintAndLogEx(INFO, "ICC PE PK (PIN Encipherment Public Key Certificate) not found.\n");
	}

	// 9F4B: Signed Dynamic Application Data
	const struct tlv *sdad_tlv = tlvdb_get(tlv, 0x9f4b, NULL);
	// DDA with internal authenticate OR fDDA with filled 0x9F4B tag (GPO result)
	// EMV kernel3 v2.4, contactless book C-3, C.1., page 147
	if (sdad_tlv) {
		PrintAndLogEx(NORMAL, "\n* * Got Signed Dynamic Application Data (9F4B) form GPO. Maybe fDDA...");

		const struct tlvdb *atc_db = emv_pki_recover_atc_ex(icc_pk, tlv, true);
		if (!atc_db) {
			PrintAndLogEx(WARNING, "Error: Can't recover IDN (ICC Dynamic Number)");
			emv_pk_free(pk);
			emv_pk_free(issuer_pk);
			emv_pk_free(icc_pk);
			return 8;
		}

		// 9f36 Application Transaction Counter (ATC)
		const struct tlv *atc_tlv = tlvdb_get(atc_db, 0x9f36, NULL);
		if(atc_tlv) {
			PrintAndLogEx(NORMAL, "\nATC (Application Transaction Counter) [%zu] %s", atc_tlv->len, sprint_hex_inrow(atc_tlv->value, atc_tlv->len));

			const struct tlv *core_atc_tlv = tlvdb_get(tlv, 0x9f36, NULL);
			if(tlv_equal(core_atc_tlv, atc_tlv)) {
				PrintAndLogEx(SUCCESS, "ATC check OK.");
				PrintAndLogEx(SUCCESS, "fDDA (fast DDA) verified OK.");
			} else {
				PrintAndLogEx(WARNING, "Error: fDDA verified, but ATC in the certificate and ATC in the record not the same.");
			}
		} else {
			PrintAndLogEx(NORMAL, "\nERROR: fDDA (fast DDA) verify error");
			emv_pk_free(pk);
			emv_pk_free(issuer_pk);
			emv_pk_free(icc_pk);
			return 9;
		}
	} else {
		struct tlvdb *dac_db = emv_pki_recover_dac(issuer_pk, tlv, sda_tlv);
		if (dac_db) {
			const struct tlv *dac_tlv = tlvdb_get(dac_db, 0x9f45, NULL);
			PrintAndLogEx(NORMAL, "SDAD verified OK. (Data Authentication Code: %02hhx:%02hhx)\n", dac_tlv->value[0], dac_tlv->value[1]);
			tlvdb_add(tlv, dac_db);
		} else {
			PrintAndLogEx(WARNING, "Error: SSAD verify error");
			emv_pk_free(pk);
			emv_pk_free(issuer_pk);
			emv_pk_free(icc_pk);
			return 4;
		}

		PrintAndLogEx(NORMAL, "\n* Calc DDOL");
		const struct tlv *ddol_tlv = tlvdb_get(tlv, 0x9f49, NULL);
		if (!ddol_tlv) {
			ddol_tlv = &default_ddol_tlv;
			PrintAndLogEx(NORMAL, "DDOL [9f49] not found. Using default DDOL");
		}

		struct tlv *ddol_data_tlv = dol_process(ddol_tlv, tlv, 0);
		if (!ddol_data_tlv) {
			PrintAndLogEx(WARNING, "Error: Can't create DDOL TLV");
			emv_pk_free(pk);
			emv_pk_free(issuer_pk);
			emv_pk_free(icc_pk);
			return 5;
		}

		PrintAndLogEx(NORMAL, "DDOL data[%d]: %s", ddol_data_tlv->len, sprint_hex(ddol_data_tlv->value, ddol_data_tlv->len));

		PrintAndLogEx(NORMAL, "\n* Internal Authenticate");
		int res = EMVInternalAuthenticate(channel, true, (uint8_t *)ddol_data_tlv->value, ddol_data_tlv->len, buf, sizeof(buf), &len, &sw, NULL);
		if (res) {
			PrintAndLogEx(WARNING, "Internal Authenticate error(%d): %4x. Exit...", res, sw);
			free(ddol_data_tlv);
			emv_pk_free(pk);
			emv_pk_free(issuer_pk);
			emv_pk_free(icc_pk);
			return 6;
		}

		struct tlvdb *dda_db = NULL;
		if (buf[0] == 0x80) {
			if (len < 3 ) {
				PrintAndLogEx(WARNING, "Error: Internal Authenticate format1 parsing error. length=%d", len);
			} else {
				// parse response 0x80
				struct tlvdb *t80 = tlvdb_parse_multi(buf, len);
				const struct tlv * t80tlv = tlvdb_get_tlv(t80);
				
				// 9f4b Signed Dynamic Application Data
				dda_db = tlvdb_fixed(0x9f4b, t80tlv->len, t80tlv->value);
				tlvdb_add(tlv, dda_db);
				
				tlvdb_free(t80);
				
				if (decodeTLV){
					PrintAndLogEx(NORMAL, "* * Decode response format 1:");
					TLVPrintFromTLV(dda_db);
				}
			}
		} else {
			dda_db = tlvdb_parse_multi(buf, len);
			if(!dda_db) {
				PrintAndLogEx(WARNING, "Error: Can't parse Internal Authenticate result as TLV");
				free(ddol_data_tlv);
				emv_pk_free(pk);
				emv_pk_free(issuer_pk);
				emv_pk_free(icc_pk);
				return 7;
			}
			tlvdb_add(tlv, dda_db);

			if (decodeTLV)
				TLVPrintFromTLV(dda_db);
		}

		struct tlvdb *idn_db = emv_pki_recover_idn_ex(icc_pk, dda_db, ddol_data_tlv, true);
		free(ddol_data_tlv);
		if (!idn_db) {
			PrintAndLogEx(WARNING, "Error: Can't recover IDN (ICC Dynamic Number)");
			tlvdb_free(dda_db);
			emv_pk_free(pk);
			emv_pk_free(issuer_pk);
			emv_pk_free(icc_pk);
			return 8;
		}
		tlvdb_free(dda_db);

		// 9f4c ICC Dynamic Number
		const struct tlv *idn_tlv = tlvdb_get(idn_db, 0x9f4c, NULL);
		if(idn_tlv) {
			PrintAndLogEx(NORMAL, "\nIDN (ICC Dynamic Number) [%zu] %s", idn_tlv->len, sprint_hex_inrow(idn_tlv->value, idn_tlv->len));
			PrintAndLogEx(NORMAL, "DDA verified OK.");
			tlvdb_add(tlv, idn_db);
			tlvdb_free(idn_db);
		} else {
			PrintAndLogEx(NORMAL, "\nERROR: DDA verify error");
			tlvdb_free(idn_db);

			emv_pk_free(pk);
			emv_pk_free(issuer_pk);
			emv_pk_free(icc_pk);
			return 9;
		}
	}

	emv_pk_free(pk);
	emv_pk_free(issuer_pk);
	emv_pk_free(icc_pk);
	return 0;
}

int trCDA(struct tlvdb *tlv, struct tlvdb *ac_tlv, struct tlv *pdol_data_tlv, struct tlv *ac_data_tlv) {

	struct emv_pk *pk = get_ca_pk(tlv);
	if (!pk) {
		PrintAndLogEx(WARNING, "Error: Key not found. Exit.");
		return 2;
	}

	const struct tlv *sda_tlv = tlvdb_get(tlv, 0x21, NULL);
	if (!sda_tlv || sda_tlv->len < 1) {
		PrintAndLogEx(WARNING, "Error: Can't find input list for Offline Data Authentication. Exit.");
		emv_pk_free(pk);
		return 3;
	}

	struct emv_pk *issuer_pk = emv_pki_recover_issuer_cert(pk, tlv);
	if (!issuer_pk) {
		PrintAndLogEx(WARNING, "Error: Issuer certificate not found. Exit.");
		emv_pk_free(pk);
		return 2;
	}
	PrintAndLogEx(SUCCESS, "Issuer PK recovered. RID %02hhx:%02hhx:%02hhx:%02hhx:%02hhx IDX %02hhx CSN %02hhx:%02hhx:%02hhx\n",
			issuer_pk->rid[0],
			issuer_pk->rid[1],
			issuer_pk->rid[2],
			issuer_pk->rid[3],
			issuer_pk->rid[4],
			issuer_pk->index,
			issuer_pk->serial[0],
			issuer_pk->serial[1],
			issuer_pk->serial[2]
			);

	struct emv_pk *icc_pk = emv_pki_recover_icc_cert(issuer_pk, tlv, sda_tlv);
	if (!icc_pk) {
		PrintAndLogEx(WARNING, "Error: ICC certificate not found. Exit.");
		emv_pk_free(pk);
		emv_pk_free(issuer_pk);
		return 2;
	}
	PrintAndLogEx(SUCCESS, "ICC PK recovered. RID %02hhx:%02hhx:%02hhx:%02hhx:%02hhx IDX %02hhx CSN %02hhx:%02hhx:%02hhx\n",
			icc_pk->rid[0],
			icc_pk->rid[1],
			icc_pk->rid[2],
			icc_pk->rid[3],
			icc_pk->rid[4],
			icc_pk->index,
			icc_pk->serial[0],
			icc_pk->serial[1],
			icc_pk->serial[2]
			);

	struct tlvdb *dac_db = emv_pki_recover_dac(issuer_pk, tlv, sda_tlv);
	if (dac_db) {
		const struct tlv *dac_tlv = tlvdb_get(dac_db, 0x9f45, NULL);
		PrintAndLogEx(NORMAL, "SSAD verified OK. (%02hhx:%02hhx)", dac_tlv->value[0], dac_tlv->value[1]);
		tlvdb_add(tlv, dac_db);
	} else {
		PrintAndLogEx(WARNING, "Error: SSAD verify error");
		emv_pk_free(pk);
		emv_pk_free(issuer_pk);
		emv_pk_free(icc_pk);
		return 4;
	}

	PrintAndLogEx(NORMAL, "\n* * Check Signed Dynamic Application Data (SDAD)");
	struct tlvdb *idn_db = emv_pki_perform_cda_ex(icc_pk, tlv, ac_tlv,
			pdol_data_tlv, // pdol
			ac_data_tlv,   // cdol1
			NULL,          // cdol2
			true);
	if (idn_db) {
		const struct tlv *idn_tlv = tlvdb_get(idn_db, 0x9f4c, NULL);
		PrintAndLogEx(NORMAL, "\nIDN (ICC Dynamic Number) [%zu] %s", idn_tlv->len, sprint_hex_inrow(idn_tlv->value, idn_tlv->len));
		PrintAndLogEx(NORMAL, "CDA verified OK.");
		tlvdb_add(tlv, idn_db);
	} else {
		PrintAndLogEx(NORMAL, "\nERROR: CDA verify error");
	}

	emv_pk_free(pk);
	emv_pk_free(issuer_pk);
	emv_pk_free(icc_pk);
	return 0;
}

int RecoveryCertificates(struct tlvdb *tlvRoot, json_t *root) {

	struct emv_pk *pk = get_ca_pk(tlvRoot);
	if (!pk) {
		PrintAndLog("ERROR: Key not found. Exit.");
		return 1;
	}

	struct emv_pk *issuer_pk = emv_pki_recover_issuer_cert(pk, tlvRoot);
	if (!issuer_pk) {
		emv_pk_free(pk);
		PrintAndLog("WARNING: Issuer certificate not found. Exit.");
		return 2;
	}
	PrintAndLogEx(SUCCESS, "Issuer PK recovered. RID %02hhx:%02hhx:%02hhx:%02hhx:%02hhx IDX %02hhx CSN %02hhx:%02hhx:%02hhx",
			issuer_pk->rid[0],
			issuer_pk->rid[1],
			issuer_pk->rid[2],
			issuer_pk->rid[3],
			issuer_pk->rid[4],
			issuer_pk->index,
			issuer_pk->serial[0],
			issuer_pk->serial[1],
			issuer_pk->serial[2]
			);

	JsonSaveBufAsHex(root, "$.ApplicationData.RID", issuer_pk->rid, 5);

	char *issuer_pk_c = emv_pk_dump_pk(issuer_pk);
	JsonSaveStr(root, "$.ApplicationData.IssuerPublicKeyDec", issuer_pk_c);
	JsonSaveBufAsHex(root, "$.ApplicationData.IssuerPublicKeyModulus", issuer_pk->modulus, issuer_pk->mlen);
	free(issuer_pk_c);

	struct emv_pk *icc_pk = emv_pki_recover_icc_cert(issuer_pk, tlvRoot, NULL);
	if (!icc_pk) {
		emv_pk_free(pk);
		emv_pk_free(issuer_pk);
		PrintAndLogEx(WARNING, "WARNING: ICC certificate not found. Exit.");
		return 2;
	}
	PrintAndLogEx(SUCCESS, "ICC PK recovered. RID %02hhx:%02hhx:%02hhx:%02hhx:%02hhx IDX %02hhx CSN %02hhx:%02hhx:%02hhx\n",
			icc_pk->rid[0],
			icc_pk->rid[1],
			icc_pk->rid[2],
			icc_pk->rid[3],
			icc_pk->rid[4],
			icc_pk->index,
			icc_pk->serial[0],
			icc_pk->serial[1],
			icc_pk->serial[2]
			);

	char *icc_pk_c = emv_pk_dump_pk(icc_pk);
	JsonSaveStr(root, "$.ApplicationData.ICCPublicKeyDec", icc_pk_c);
	JsonSaveBufAsHex(root, "$.ApplicationData.ICCPublicKeyModulus", icc_pk->modulus, icc_pk->mlen);
	free(issuer_pk_c);

	return 0;
}