#include "furi_hal_nfc.h" #include #include #include #include #include #define TAG "FuriHalNfc" static const uint32_t clocks_in_ms = 64 * 1000; osEventFlagsId_t event = NULL; #define EVENT_FLAG_INTERRUPT (1UL << 0) #define EVENT_FLAG_STATE_CHANGED (1UL << 1) #define EVENT_FLAG_STOP (1UL << 2) #define EVENT_FLAG_ALL (EVENT_FLAG_INTERRUPT | EVENT_FLAG_STATE_CHANGED | EVENT_FLAG_STOP) void furi_hal_nfc_init() { ReturnCode ret = rfalNfcInitialize(); if(ret == ERR_NONE) { furi_hal_nfc_start_sleep(); event = osEventFlagsNew(NULL); FURI_LOG_I(TAG, "Init OK"); } else { FURI_LOG_W(TAG, "Initialization failed, RFAL returned: %d", ret); } } bool furi_hal_nfc_is_busy() { return rfalNfcGetState() != RFAL_NFC_STATE_IDLE; } void furi_hal_nfc_field_on() { furi_hal_nfc_exit_sleep(); st25r3916TxRxOn(); } void furi_hal_nfc_field_off() { st25r3916TxRxOff(); furi_hal_nfc_start_sleep(); } void furi_hal_nfc_start_sleep() { rfalLowPowerModeStart(); } void furi_hal_nfc_exit_sleep() { rfalLowPowerModeStop(); } bool furi_hal_nfc_detect( rfalNfcDevice** dev_list, uint8_t* dev_cnt, uint32_t timeout, bool deactivate) { furi_assert(dev_list); furi_assert(dev_cnt); rfalLowPowerModeStop(); rfalNfcState state = rfalNfcGetState(); if(state == RFAL_NFC_STATE_NOTINIT) { rfalNfcInitialize(); } rfalNfcDiscoverParam params; params.compMode = RFAL_COMPLIANCE_MODE_EMV; params.techs2Find = RFAL_NFC_POLL_TECH_A | RFAL_NFC_POLL_TECH_B | RFAL_NFC_POLL_TECH_F | RFAL_NFC_POLL_TECH_V | RFAL_NFC_POLL_TECH_AP2P | RFAL_NFC_POLL_TECH_ST25TB; params.totalDuration = 1000; params.devLimit = 3; params.wakeupEnabled = false; params.wakeupConfigDefault = true; params.nfcfBR = RFAL_BR_212; params.ap2pBR = RFAL_BR_424; params.maxBR = RFAL_BR_KEEP; params.GBLen = RFAL_NFCDEP_GB_MAX_LEN; params.notifyCb = NULL; uint32_t start = DWT->CYCCNT; rfalNfcDiscover(¶ms); while(state != RFAL_NFC_STATE_ACTIVATED) { rfalNfcWorker(); state = rfalNfcGetState(); FURI_LOG_T(TAG, "Current state %d", state); if(state == RFAL_NFC_STATE_POLL_ACTIVATION) { start = DWT->CYCCNT; continue; } if(state == RFAL_NFC_STATE_POLL_SELECT) { rfalNfcSelect(0); } if(DWT->CYCCNT - start > timeout * clocks_in_ms) { rfalNfcDeactivate(true); FURI_LOG_T(TAG, "Timeout"); return false; } osThreadYield(); } rfalNfcGetDevicesFound(dev_list, dev_cnt); if(deactivate) { rfalNfcDeactivate(false); rfalLowPowerModeStart(); } return true; } bool furi_hal_nfc_listen( uint8_t* uid, uint8_t uid_len, uint8_t* atqa, uint8_t sak, bool activate_after_sak, uint32_t timeout) { rfalNfcState state = rfalNfcGetState(); if(state == RFAL_NFC_STATE_NOTINIT) { rfalNfcInitialize(); } else if(state >= RFAL_NFC_STATE_ACTIVATED) { rfalNfcDeactivate(false); } rfalLowPowerModeStop(); rfalNfcDiscoverParam params = { .compMode = RFAL_COMPLIANCE_MODE_NFC, .techs2Find = RFAL_NFC_LISTEN_TECH_A, .totalDuration = 1000, .devLimit = 1, .wakeupEnabled = false, .wakeupConfigDefault = true, .nfcfBR = RFAL_BR_212, .ap2pBR = RFAL_BR_424, .maxBR = RFAL_BR_KEEP, .GBLen = RFAL_NFCDEP_GB_MAX_LEN, .notifyCb = NULL, .activate_after_sak = activate_after_sak, }; params.lmConfigPA.nfcidLen = uid_len; memcpy(params.lmConfigPA.nfcid, uid, uid_len); params.lmConfigPA.SENS_RES[0] = atqa[0]; params.lmConfigPA.SENS_RES[1] = atqa[1]; params.lmConfigPA.SEL_RES = sak; rfalNfcDiscover(¶ms); uint32_t start = DWT->CYCCNT; while(state != RFAL_NFC_STATE_ACTIVATED) { rfalNfcWorker(); state = rfalNfcGetState(); if(DWT->CYCCNT - start > timeout * clocks_in_ms) { rfalNfcDeactivate(true); return false; } osThreadYield(); } return true; } void rfal_interrupt_callback_handler() { osEventFlagsSet(event, EVENT_FLAG_INTERRUPT); } void rfal_state_changed_callback(void* context) { osEventFlagsSet(event, EVENT_FLAG_STATE_CHANGED); } void furi_hal_nfc_stop() { if(event) { osEventFlagsSet(event, EVENT_FLAG_STOP); } } bool furi_hal_nfc_emulate_nfca( uint8_t* uid, uint8_t uid_len, uint8_t* atqa, uint8_t sak, FuriHalNfcEmulateCallback callback, void* context, uint32_t timeout) { rfalSetUpperLayerCallback(rfal_interrupt_callback_handler); rfal_set_state_changed_callback(rfal_state_changed_callback); rfalLmConfPA config; config.nfcidLen = uid_len; memcpy(config.nfcid, uid, uid_len); memcpy(config.SENS_RES, atqa, RFAL_LM_SENS_RES_LEN); config.SEL_RES = sak; uint8_t buff_rx[256]; uint16_t buff_rx_size = 256; uint16_t buff_rx_len = 0; uint8_t buff_tx[256]; uint16_t buff_tx_len = 0; uint32_t data_type = FURI_HAL_NFC_TXRX_DEFAULT; rfalLowPowerModeStop(); if(rfalListenStart( RFAL_LM_MASK_NFCA, &config, NULL, NULL, buff_rx, rfalConvBytesToBits(buff_rx_size), &buff_rx_len)) { rfalListenStop(); FURI_LOG_E(TAG, "Failed to start listen mode"); return false; } while(true) { buff_rx_len = 0; buff_tx_len = 0; uint32_t flag = osEventFlagsWait(event, EVENT_FLAG_ALL, osFlagsWaitAny, timeout); if(flag == osErrorTimeout || flag == EVENT_FLAG_STOP) { break; } bool data_received = false; buff_rx_len = 0; rfalWorker(); rfalLmState state = rfalListenGetState(&data_received, NULL); if(data_received) { rfalTransceiveBlockingRx(); if(nfca_emulation_handler(buff_rx, buff_rx_len, buff_tx, &buff_tx_len)) { if(rfalListenSleepStart( RFAL_LM_STATE_SLEEP_A, buff_rx, rfalConvBytesToBits(buff_rx_size), &buff_rx_len)) { FURI_LOG_E(TAG, "Failed to enter sleep mode"); break; } else { continue; } } if(buff_tx_len) { ReturnCode ret = rfalTransceiveBitsBlockingTx( buff_tx, buff_tx_len, buff_rx, sizeof(buff_rx), &buff_rx_len, data_type, RFAL_FWT_NONE); if(ret) { FURI_LOG_E(TAG, "Tranceive failed with status %d", ret); break; } continue; } if((state == RFAL_LM_STATE_ACTIVE_A || state == RFAL_LM_STATE_ACTIVE_Ax)) { if(callback) { callback(buff_rx, buff_rx_len, buff_tx, &buff_tx_len, &data_type, context); } if(!rfalIsExtFieldOn()) { break; } if(buff_tx_len) { ReturnCode ret = rfalTransceiveBitsBlockingTx( buff_tx, buff_tx_len, buff_rx, sizeof(buff_rx), &buff_rx_len, data_type, RFAL_FWT_NONE); if(ret) { FURI_LOG_E(TAG, "Tranceive failed with status %d", ret); continue; } } else { break; } } } } rfalListenStop(); return true; } bool furi_hal_nfc_get_first_frame(uint8_t** rx_buff, uint16_t** rx_len) { ReturnCode ret = rfalNfcDataExchangeStart(NULL, 0, rx_buff, rx_len, 0, RFAL_TXRX_FLAGS_DEFAULT); return ret == ERR_NONE; } ReturnCode furi_hal_nfc_data_exchange( uint8_t* tx_buff, uint16_t tx_len, uint8_t** rx_buff, uint16_t** rx_len, bool deactivate) { furi_assert(rx_buff); furi_assert(rx_len); ReturnCode ret; rfalNfcState state = RFAL_NFC_STATE_ACTIVATED; ret = rfalNfcDataExchangeStart(tx_buff, tx_len, rx_buff, rx_len, 0, RFAL_TXRX_FLAGS_DEFAULT); if(ret != ERR_NONE) { return ret; } uint32_t start = DWT->CYCCNT; while(state != RFAL_NFC_STATE_DATAEXCHANGE_DONE) { rfalNfcWorker(); state = rfalNfcGetState(); ret = rfalNfcDataExchangeGetStatus(); if(ret > ERR_SLEEP_REQ) { return ret; } if(ret == ERR_BUSY) { if(DWT->CYCCNT - start > 1000 * clocks_in_ms) { return ERR_TIMEOUT; } continue; } else { start = DWT->CYCCNT; } taskYIELD(); } if(deactivate) { rfalNfcDeactivate(false); rfalLowPowerModeStart(); } return ERR_NONE; } ReturnCode furi_hal_nfc_raw_bitstream_exchange( uint8_t* tx_buff, uint16_t tx_bit_len, uint8_t** rx_buff, uint16_t** rx_bit_len, bool deactivate) { furi_assert(rx_buff); furi_assert(rx_bit_len); ReturnCode ret; rfalNfcState state = RFAL_NFC_STATE_ACTIVATED; ret = rfalNfcDataExchangeStart(tx_buff, tx_bit_len, rx_buff, rx_bit_len, 0, RFAL_TXRX_FLAGS_RAW); if(ret != ERR_NONE) { return ret; } uint32_t start = DWT->CYCCNT; while(state != RFAL_NFC_STATE_DATAEXCHANGE_DONE) { rfalNfcWorker(); state = rfalNfcGetState(); ret = rfalNfcDataExchangeGetStatus(); if(ret > ERR_SLEEP_REQ) { return ret; } if(ret == ERR_BUSY) { if(DWT->CYCCNT - start > 1000 * clocks_in_ms) { return ERR_TIMEOUT; } continue; } else { start = DWT->CYCCNT; } taskYIELD(); } if(deactivate) { rfalNfcDeactivate(false); rfalLowPowerModeStart(); } return ERR_NONE; } void furi_hal_nfc_deactivate() { rfalNfcDeactivate(false); rfalLowPowerModeStart(); }