#include "rfid_writer.h" #include #include "protocols/protocol_emmarin.h" #include "protocols/protocol_hid_h10301.h" #include "protocols/protocol_indala_40134.h" extern COMP_HandleTypeDef hcomp1; /** * @brief all timings are specified in field clocks (field clock = 125 kHz, 8 us) * */ class T55xxTiming { public: constexpr static const uint16_t wait_time = 400; constexpr static const uint8_t start_gap = 30; constexpr static const uint8_t write_gap = 18; constexpr static const uint8_t data_0 = 24; constexpr static const uint8_t data_1 = 56; constexpr static const uint16_t program = 700; }; class T55xxCmd { public: constexpr static const uint8_t opcode_page_0 = 0b10; constexpr static const uint8_t opcode_page_1 = 0b11; constexpr static const uint8_t opcode_reset = 0b00; }; RfidWriter::RfidWriter() { } RfidWriter::~RfidWriter() { } void RfidWriter::start() { furi_hal_rfid_tim_read(125000, 0.5); furi_hal_rfid_pins_read(); furi_hal_rfid_tim_read_start(); // do not ground the antenna furi_hal_rfid_pin_pull_release(); } void RfidWriter::stop() { furi_hal_rfid_tim_read_stop(); furi_hal_rfid_tim_reset(); furi_hal_rfid_pins_reset(); } void RfidWriter::write_gap(uint32_t gap_time) { furi_hal_rfid_tim_read_stop(); delay_us(gap_time * 8); furi_hal_rfid_tim_read_start(); } void RfidWriter::write_bit(bool value) { if(value) { delay_us(T55xxTiming::data_1 * 8); } else { delay_us(T55xxTiming::data_0 * 8); } write_gap(T55xxTiming::write_gap); } void RfidWriter::write_byte(uint8_t value) { for(uint8_t i = 0; i < 8; i++) { write_bit((value >> i) & 1); } } void RfidWriter::write_block(uint8_t page, uint8_t block, bool lock_bit, uint32_t data) { delay_us(T55xxTiming::wait_time * 8); // start gap write_gap(T55xxTiming::start_gap); // opcode switch(page) { case 0: write_bit(1); write_bit(0); break; case 1: write_bit(1); write_bit(1); break; default: furi_check(false); break; } // lock bit write_bit(lock_bit); // data for(uint8_t i = 0; i < 32; i++) { write_bit((data >> (31 - i)) & 1); } // block address write_bit((block >> 2) & 1); write_bit((block >> 1) & 1); write_bit((block >> 0) & 1); delay_us(T55xxTiming::program * 8); delay_us(T55xxTiming::wait_time * 8); write_reset(); } void RfidWriter::write_reset() { write_gap(T55xxTiming::start_gap); write_bit(1); write_bit(0); } void RfidWriter::write_em(const uint8_t em_data[5]) { ProtocolEMMarin em_card; uint64_t em_encoded_data; em_card.encode(em_data, 5, reinterpret_cast(&em_encoded_data), sizeof(uint64_t)); const uint32_t em_config_block_data = 0b00000000000101001000000001000000; FURI_CRITICAL_ENTER(); write_block(0, 0, false, em_config_block_data); write_block(0, 1, false, em_encoded_data); write_block(0, 2, false, em_encoded_data >> 32); write_reset(); FURI_CRITICAL_EXIT(); } void RfidWriter::write_hid(const uint8_t hid_data[3]) { ProtocolHID10301 hid_card; uint32_t card_data[3]; hid_card.encode(hid_data, 3, reinterpret_cast(&card_data), sizeof(card_data) * 3); const uint32_t hid_config_block_data = 0b00000000000100000111000001100000; FURI_CRITICAL_ENTER(); write_block(0, 0, false, hid_config_block_data); write_block(0, 1, false, card_data[0]); write_block(0, 2, false, card_data[1]); write_block(0, 3, false, card_data[2]); write_reset(); FURI_CRITICAL_EXIT(); } void RfidWriter::write_indala(const uint8_t indala_data[3]) { ProtocolIndala40134 indala_card; uint32_t card_data[2]; indala_card.encode( indala_data, 3, reinterpret_cast(&card_data), sizeof(card_data) * 2); const uint32_t indala_config_block_data = 0b00000000000010000001000001000000; FURI_CRITICAL_ENTER(); write_block(0, 0, false, indala_config_block_data); write_block(0, 1, false, card_data[0]); write_block(0, 2, false, card_data[1]); write_reset(); FURI_CRITICAL_EXIT(); }