#include "nfca.h" #include #include #include #define NFCA_CMD_RATS (0xE0U) #define NFCA_CRC_INIT (0x6363) #define NFCA_F_SIG (13560000.0) #define NFCA_T_SIG (1.0 / NFCA_F_SIG) #define NFCA_SIGNAL_MAX_EDGES (1350) typedef struct { uint8_t cmd; uint8_t param; } nfca_cmd_rats; static uint8_t nfca_default_ats[] = {0x05, 0x78, 0x80, 0x80, 0x00}; static uint8_t nfca_sleep_req[] = {0x50, 0x00}; uint16_t nfca_get_crc16(uint8_t* buff, uint16_t len) { uint16_t crc = NFCA_CRC_INIT; uint8_t byte = 0; for(uint8_t i = 0; i < len; i++) { byte = buff[i]; byte ^= (uint8_t)(crc & 0xff); byte ^= byte << 4; crc = (crc >> 8) ^ (((uint16_t)byte) << 8) ^ (((uint16_t)byte) << 3) ^ (((uint16_t)byte) >> 4); } return crc; } void nfca_append_crc16(uint8_t* buff, uint16_t len) { uint16_t crc = nfca_get_crc16(buff, len); buff[len] = (uint8_t)crc; buff[len + 1] = (uint8_t)(crc >> 8); } bool nfca_emulation_handler( uint8_t* buff_rx, uint16_t buff_rx_len, uint8_t* buff_tx, uint16_t* buff_tx_len) { bool sleep = false; uint8_t rx_bytes = buff_rx_len / 8; if(rx_bytes == sizeof(nfca_sleep_req) && !memcmp(buff_rx, nfca_sleep_req, rx_bytes)) { sleep = true; } else if(rx_bytes == sizeof(nfca_cmd_rats) && buff_rx[0] == NFCA_CMD_RATS) { memcpy(buff_tx, nfca_default_ats, sizeof(nfca_default_ats)); *buff_tx_len = sizeof(nfca_default_ats) * 8; } return sleep; } static void nfca_add_bit(DigitalSignal* signal, bool bit) { if(bit) { signal->start_level = true; for(size_t i = 0; i < 7; i++) { signal->edge_timings[i] = 8 * NFCA_T_SIG; } signal->edge_timings[7] = 9 * 8 * NFCA_T_SIG; signal->edge_cnt = 8; } else { signal->start_level = false; signal->edge_timings[0] = 8 * 8 * NFCA_T_SIG; for(size_t i = 1; i < 9; i++) { signal->edge_timings[i] = 8 * NFCA_T_SIG; } signal->edge_cnt = 9; } } static void nfca_add_byte(NfcaSignal* nfca_signal, uint8_t byte, bool parity) { for(uint8_t i = 0; i < 8; i++) { if(byte & (1 << i)) { digital_signal_append(nfca_signal->tx_signal, nfca_signal->one); } else { digital_signal_append(nfca_signal->tx_signal, nfca_signal->zero); } } if(parity) { digital_signal_append(nfca_signal->tx_signal, nfca_signal->one); } else { digital_signal_append(nfca_signal->tx_signal, nfca_signal->zero); } } NfcaSignal* nfca_signal_alloc() { NfcaSignal* nfca_signal = malloc(sizeof(NfcaSignal)); nfca_signal->one = digital_signal_alloc(10); nfca_signal->zero = digital_signal_alloc(10); nfca_add_bit(nfca_signal->one, true); nfca_add_bit(nfca_signal->zero, false); nfca_signal->tx_signal = digital_signal_alloc(NFCA_SIGNAL_MAX_EDGES); return nfca_signal; } void nfca_signal_free(NfcaSignal* nfca_signal) { furi_assert(nfca_signal); digital_signal_free(nfca_signal->one); digital_signal_free(nfca_signal->zero); digital_signal_free(nfca_signal->tx_signal); free(nfca_signal); } void nfca_signal_encode(NfcaSignal* nfca_signal, uint8_t* data, uint16_t bits, uint8_t* parity) { furi_assert(nfca_signal); furi_assert(data); furi_assert(parity); nfca_signal->tx_signal->edge_cnt = 0; nfca_signal->tx_signal->start_level = true; // Start of frame digital_signal_append(nfca_signal->tx_signal, nfca_signal->one); if(bits < 8) { for(size_t i = 0; i < bits; i++) { if(FURI_BIT(data[0], i)) { digital_signal_append(nfca_signal->tx_signal, nfca_signal->one); } else { digital_signal_append(nfca_signal->tx_signal, nfca_signal->zero); } } } else { for(size_t i = 0; i < bits / 8; i++) { nfca_add_byte(nfca_signal, data[i], parity[i / 8] & (1 << (7 - (i & 0x07)))); } } }