unleashed-firmware/lib/nfc/parsers/plantain_parser.c
Astra 9f3b80e606
Add new card parsers (#1503)
* Add the "Two cities" parser
* Add plantain and plantain4k parsers
* Add new parsers to the supported list
* United card PoC
* Fix nfc device not sleeping
* Completely read the 4K troika variants
* Correct naming
* Update to reflect upstream changes
* Add support for MfUl info
* Fix parsers
* Card type detection fixes
* Remove debug info
* Fixes for the verification of cards
* nfc: fix verification for supported cards
* nfc: remove unused vars
* Improve card reading reliability and fix plantain
* plantain: change log level

Co-authored-by: gornekich <n.gorbadey@gmail.com>
2022-09-20 01:05:04 +09:00

147 lines
5.6 KiB
C

#include "nfc_supported_card.h"
#include <gui/modules/widget.h>
#include <nfc_worker_i.h>
#include "furi_hal.h"
static const MfClassicAuthContext plantain_keys[] = {
{.sector = 0, .key_a = 0xffffffffffff, .key_b = 0xffffffffffff},
{.sector = 1, .key_a = 0xffffffffffff, .key_b = 0xffffffffffff},
{.sector = 2, .key_a = 0xffffffffffff, .key_b = 0xffffffffffff},
{.sector = 3, .key_a = 0xffffffffffff, .key_b = 0xffffffffffff},
{.sector = 4, .key_a = 0xe56ac127dd45, .key_b = 0x19fc84a3784b},
{.sector = 5, .key_a = 0x77dabc9825e1, .key_b = 0x9764fec3154a},
{.sector = 6, .key_a = 0xffffffffffff, .key_b = 0xffffffffffff},
{.sector = 7, .key_a = 0xffffffffffff, .key_b = 0xffffffffffff},
{.sector = 8, .key_a = 0x26973ea74321, .key_b = 0xd27058c6e2c7},
{.sector = 9, .key_a = 0xeb0a8ff88ade, .key_b = 0x578a9ada41e3},
{.sector = 10, .key_a = 0xea0fd73cb149, .key_b = 0x29c35fa068fb},
{.sector = 11, .key_a = 0xc76bf71a2509, .key_b = 0x9ba241db3f56},
{.sector = 12, .key_a = 0xacffffffffff, .key_b = 0x71f3a315ad26},
{.sector = 13, .key_a = 0xffffffffffff, .key_b = 0xffffffffffff},
{.sector = 14, .key_a = 0xffffffffffff, .key_b = 0xffffffffffff},
{.sector = 15, .key_a = 0xffffffffffff, .key_b = 0xffffffffffff},
};
bool plantain_parser_verify(NfcWorker* nfc_worker, FuriHalNfcTxRxContext* tx_rx) {
furi_assert(nfc_worker);
UNUSED(nfc_worker);
if(nfc_worker->dev_data->mf_classic_data.type != MfClassicType1k) {
return false;
}
uint8_t sector = 8;
uint8_t block = mf_classic_get_sector_trailer_block_num_by_sector(sector);
FURI_LOG_D("Plant", "Verifying sector %d", sector);
if(mf_classic_authenticate(tx_rx, block, 0x26973ea74321, MfClassicKeyA)) {
FURI_LOG_D("Plant", "Sector %d verified", sector);
return true;
}
return false;
}
bool plantain_parser_read(NfcWorker* nfc_worker, FuriHalNfcTxRxContext* tx_rx) {
furi_assert(nfc_worker);
MfClassicReader reader = {};
FuriHalNfcDevData* nfc_data = &nfc_worker->dev_data->nfc_data;
reader.type = mf_classic_get_classic_type(nfc_data->atqa[0], nfc_data->atqa[1], nfc_data->sak);
for(size_t i = 0; i < COUNT_OF(plantain_keys); i++) {
mf_classic_reader_add_sector(
&reader, plantain_keys[i].sector, plantain_keys[i].key_a, plantain_keys[i].key_b);
}
return mf_classic_read_card(tx_rx, &reader, &nfc_worker->dev_data->mf_classic_data) == 16;
}
void string_push_uint64(uint64_t input, string_t output) {
const uint8_t base = 10;
do {
char c = input % base;
input /= base;
if(c < 10)
c += '0';
else
c += 'A' - 10;
string_push_back(output, c);
} while(input);
// reverse string
for(uint8_t i = 0; i < string_size(output) / 2; i++) {
char c = string_get_char(output, i);
string_set_char(output, i, string_get_char(output, string_size(output) - i - 1));
string_set_char(output, string_size(output) - i - 1, c);
}
}
uint8_t plantain_calculate_luhn(uint64_t number) {
// No.
UNUSED(number);
return 0;
}
bool plantain_parser_parse(NfcDeviceData* dev_data) {
MfClassicData* data = &dev_data->mf_classic_data;
// Verify key
MfClassicSectorTrailer* sec_tr = mf_classic_get_sector_trailer_by_sector(data, 8);
uint64_t key = nfc_util_bytes2num(sec_tr->key_a, 6);
if(key != plantain_keys[8].key_a) return false;
// Point to block 0 of sector 4, value 0
uint8_t* temp_ptr = &data->block[4 * 4].value[0];
// Read first 4 bytes of block 0 of sector 4 from last to first and convert them to uint32_t
// 38 18 00 00 becomes 00 00 18 38, and equals to 6200 decimal
uint32_t balance =
((temp_ptr[3] << 24) | (temp_ptr[2] << 16) | (temp_ptr[1] << 8) | temp_ptr[0]) / 100;
// Read card number
// Point to block 0 of sector 0, value 0
temp_ptr = &data->block[0 * 4].value[0];
// Read first 7 bytes of block 0 of sector 0 from last to first and convert them to uint64_t
// 80 5C 23 8A 16 31 04 becomes 04 31 16 8A 23 5C 80, and equals to 36130104729284868 decimal
uint8_t card_number_arr[7];
for(size_t i = 0; i < 7; i++) {
card_number_arr[i] = temp_ptr[6 - i];
}
// Copy card number to uint64_t
uint64_t card_number = 0;
for(size_t i = 0; i < 7; i++) {
card_number = (card_number << 8) | card_number_arr[i];
}
// Convert card number to string
string_t card_number_str;
string_init(card_number_str);
// Should look like "361301047292848684"
// %llu doesn't work for some reason in sprintf, so we use string_push_uint64 instead
string_push_uint64(card_number, card_number_str);
// Add suffix with luhn checksum (1 digit) to the card number string
string_t card_number_suffix;
string_init(card_number_suffix);
// The number to calculate the checksum on doesn't fit into uint64_t, idk
//uint8_t luhn_checksum = plantain_calculate_luhn(card_number);
// // Convert luhn checksum to string
// string_t luhn_checksum_str;
// string_init(luhn_checksum_str);
// string_push_uint64(luhn_checksum, luhn_checksum_str);
string_cat_printf(card_number_suffix, "-");
// FURI_LOG_D("plant4k", "Card checksum: %d", luhn_checksum);
string_cat_printf(card_number_str, string_get_cstr(card_number_suffix));
// Free all not needed strings
string_clear(card_number_suffix);
// string_clear(luhn_checksum_str);
string_printf(
dev_data->parsed_data,
"\e#Plantain\nN:%s\nBalance:%d\n",
string_get_cstr(card_number_str),
balance);
string_clear(card_number_str);
return true;
}