#include "subghz_txrx_i.h" #include #include #include #include #define TAG "SubGhzTxRx" static void subghz_txrx_radio_device_power_on(SubGhzTxRx* instance) { UNUSED(instance); uint8_t attempts = 0; while(!furi_hal_power_is_otg_enabled() && attempts++ < 5) { furi_hal_power_enable_otg(); //CC1101 power-up time furi_delay_ms(10); } } static void subghz_txrx_radio_device_power_off(SubGhzTxRx* instance) { UNUSED(instance); if(furi_hal_power_is_otg_enabled()) furi_hal_power_disable_otg(); } SubGhzTxRx* subghz_txrx_alloc() { SubGhzTxRx* instance = malloc(sizeof(SubGhzTxRx)); instance->setting = subghz_setting_alloc(); subghz_setting_load(instance->setting, EXT_PATH("subghz/assets/setting_user")); instance->preset = malloc(sizeof(SubGhzRadioPreset)); instance->preset->name = furi_string_alloc(); subghz_txrx_set_default_preset(instance, 0); instance->txrx_state = SubGhzTxRxStateSleep; subghz_txrx_hopper_set_state(instance, SubGhzHopperStateOFF); subghz_txrx_speaker_set_state(instance, SubGhzSpeakerStateDisable); subghz_txrx_set_debug_pin_state(instance, false); instance->worker = subghz_worker_alloc(); instance->fff_data = flipper_format_string_alloc(); instance->environment = subghz_environment_alloc(); instance->is_database_loaded = subghz_environment_load_keystore(instance->environment, SUBGHZ_KEYSTORE_DIR_NAME); subghz_environment_load_keystore(instance->environment, SUBGHZ_KEYSTORE_DIR_USER_NAME); subghz_environment_set_came_atomo_rainbow_table_file_name( instance->environment, SUBGHZ_CAME_ATOMO_DIR_NAME); subghz_environment_set_alutech_at_4n_rainbow_table_file_name( instance->environment, SUBGHZ_ALUTECH_AT_4N_DIR_NAME); subghz_environment_set_nice_flor_s_rainbow_table_file_name( instance->environment, SUBGHZ_NICE_FLOR_S_DIR_NAME); subghz_environment_set_protocol_registry( instance->environment, (void*)&subghz_protocol_registry); instance->receiver = subghz_receiver_alloc_init(instance->environment); subghz_worker_set_overrun_callback( instance->worker, (SubGhzWorkerOverrunCallback)subghz_receiver_reset); subghz_worker_set_pair_callback( instance->worker, (SubGhzWorkerPairCallback)subghz_receiver_decode); subghz_worker_set_context(instance->worker, instance->receiver); //set default device External subghz_devices_init(); instance->radio_device_type = SubGhzRadioDeviceTypeInternal; instance->radio_device_type = subghz_txrx_radio_device_set(instance, SubGhzRadioDeviceTypeExternalCC1101); return instance; } void subghz_txrx_free(SubGhzTxRx* instance) { furi_assert(instance); if(instance->radio_device_type != SubGhzRadioDeviceTypeInternal) { subghz_txrx_radio_device_power_off(instance); subghz_devices_end(instance->radio_device); } subghz_devices_deinit(); subghz_worker_free(instance->worker); subghz_receiver_free(instance->receiver); subghz_environment_free(instance->environment); flipper_format_free(instance->fff_data); furi_string_free(instance->preset->name); subghz_setting_free(instance->setting); free(instance->preset); free(instance); } bool subghz_txrx_is_database_loaded(SubGhzTxRx* instance) { furi_assert(instance); return instance->is_database_loaded; } void subghz_txrx_set_preset( SubGhzTxRx* instance, const char* preset_name, uint32_t frequency, uint8_t* preset_data, size_t preset_data_size) { furi_assert(instance); furi_string_set(instance->preset->name, preset_name); SubGhzRadioPreset* preset = instance->preset; preset->frequency = frequency; preset->data = preset_data; preset->data_size = preset_data_size; } const char* subghz_txrx_get_preset_name(SubGhzTxRx* instance, const char* preset) { UNUSED(instance); const char* preset_name = ""; if(!strcmp(preset, "FuriHalSubGhzPresetOok270Async")) { preset_name = "AM270"; } else if(!strcmp(preset, "FuriHalSubGhzPresetOok650Async")) { preset_name = "AM650"; } else if(!strcmp(preset, "FuriHalSubGhzPreset2FSKDev238Async")) { preset_name = "FM238"; } else if(!strcmp(preset, "FuriHalSubGhzPreset2FSKDev476Async")) { preset_name = "FM476"; } else if(!strcmp(preset, "FuriHalSubGhzPresetCustom")) { preset_name = "CUSTOM"; } else { FURI_LOG_E(TAG, "Unknown preset"); } return preset_name; } SubGhzRadioPreset subghz_txrx_get_preset(SubGhzTxRx* instance) { furi_assert(instance); return *instance->preset; } void subghz_txrx_get_frequency_and_modulation( SubGhzTxRx* instance, FuriString* frequency, FuriString* modulation, bool long_name) { furi_assert(instance); SubGhzRadioPreset* preset = instance->preset; if(frequency != NULL) { furi_string_printf( frequency, "%03ld.%02ld", preset->frequency / 1000000 % 1000, preset->frequency / 10000 % 100); } if(modulation != NULL) { if(long_name) { furi_string_printf(modulation, "%s", furi_string_get_cstr(preset->name)); } else { furi_string_printf(modulation, "%.2s", furi_string_get_cstr(preset->name)); } } } static void subghz_txrx_begin(SubGhzTxRx* instance, uint8_t* preset_data) { furi_assert(instance); subghz_devices_reset(instance->radio_device); subghz_devices_idle(instance->radio_device); subghz_devices_load_preset(instance->radio_device, FuriHalSubGhzPresetCustom, preset_data); instance->txrx_state = SubGhzTxRxStateIDLE; } static uint32_t subghz_txrx_rx(SubGhzTxRx* instance, uint32_t frequency) { furi_assert(instance); furi_assert( instance->txrx_state != SubGhzTxRxStateRx && instance->txrx_state != SubGhzTxRxStateSleep); subghz_devices_idle(instance->radio_device); uint32_t value = subghz_devices_set_frequency(instance->radio_device, frequency); subghz_devices_flush_rx(instance->radio_device); subghz_txrx_speaker_on(instance); subghz_devices_start_async_rx( instance->radio_device, subghz_worker_rx_callback, instance->worker); subghz_worker_start(instance->worker); instance->txrx_state = SubGhzTxRxStateRx; return value; } static void subghz_txrx_idle(SubGhzTxRx* instance) { furi_assert(instance); furi_assert(instance->txrx_state != SubGhzTxRxStateSleep); subghz_devices_idle(instance->radio_device); subghz_txrx_speaker_off(instance); instance->txrx_state = SubGhzTxRxStateIDLE; } static void subghz_txrx_rx_end(SubGhzTxRx* instance) { furi_assert(instance); furi_assert(instance->txrx_state == SubGhzTxRxStateRx); if(subghz_worker_is_running(instance->worker)) { subghz_worker_stop(instance->worker); subghz_devices_stop_async_rx(instance->radio_device); } subghz_devices_idle(instance->radio_device); subghz_txrx_speaker_off(instance); instance->txrx_state = SubGhzTxRxStateIDLE; } void subghz_txrx_sleep(SubGhzTxRx* instance) { furi_assert(instance); subghz_devices_sleep(instance->radio_device); instance->txrx_state = SubGhzTxRxStateSleep; } static bool subghz_txrx_tx(SubGhzTxRx* instance, uint32_t frequency) { furi_assert(instance); furi_assert(instance->txrx_state != SubGhzTxRxStateSleep); subghz_devices_idle(instance->radio_device); subghz_devices_set_frequency(instance->radio_device, frequency); bool ret = subghz_devices_set_tx(instance->radio_device); if(ret) { subghz_txrx_speaker_on(instance); instance->txrx_state = SubGhzTxRxStateTx; } return ret; } SubGhzTxRxStartTxState subghz_txrx_tx_start(SubGhzTxRx* instance, FlipperFormat* flipper_format) { furi_assert(instance); furi_assert(flipper_format); subghz_txrx_stop(instance); SubGhzTxRxStartTxState ret = SubGhzTxRxStartTxStateErrorParserOthers; FuriString* temp_str = furi_string_alloc(); uint32_t repeat = 200; do { if(!flipper_format_rewind(flipper_format)) { FURI_LOG_E(TAG, "Rewind error"); break; } if(!flipper_format_read_string(flipper_format, "Protocol", temp_str)) { FURI_LOG_E(TAG, "Missing Protocol"); break; } if(!flipper_format_insert_or_update_uint32(flipper_format, "Repeat", &repeat, 1)) { FURI_LOG_E(TAG, "Unable Repeat"); break; } ret = SubGhzTxRxStartTxStateOk; SubGhzRadioPreset* preset = instance->preset; instance->transmitter = subghz_transmitter_alloc_init(instance->environment, furi_string_get_cstr(temp_str)); if(instance->transmitter) { if(subghz_transmitter_deserialize(instance->transmitter, flipper_format) == SubGhzProtocolStatusOk) { if(strcmp(furi_string_get_cstr(preset->name), "") != 0) { subghz_txrx_begin( instance, subghz_setting_get_preset_data_by_name( instance->setting, furi_string_get_cstr(preset->name))); if(preset->frequency) { if(!subghz_txrx_tx(instance, preset->frequency)) { FURI_LOG_E(TAG, "Only Rx"); ret = SubGhzTxRxStartTxStateErrorOnlyRx; } } else { ret = SubGhzTxRxStartTxStateErrorParserOthers; } } else { FURI_LOG_E( TAG, "Unknown name preset \" %s \"", furi_string_get_cstr(preset->name)); ret = SubGhzTxRxStartTxStateErrorParserOthers; } if(ret == SubGhzTxRxStartTxStateOk) { //Start TX subghz_devices_start_async_tx( instance->radio_device, subghz_transmitter_yield, instance->transmitter); } } else { ret = SubGhzTxRxStartTxStateErrorParserOthers; } } else { ret = SubGhzTxRxStartTxStateErrorParserOthers; } if(ret != SubGhzTxRxStartTxStateOk) { subghz_transmitter_free(instance->transmitter); if(instance->txrx_state != SubGhzTxRxStateIDLE) { subghz_txrx_idle(instance); } } } while(false); furi_string_free(temp_str); return ret; } void subghz_txrx_rx_start(SubGhzTxRx* instance) { furi_assert(instance); subghz_txrx_stop(instance); subghz_txrx_begin( instance, subghz_setting_get_preset_data_by_name( subghz_txrx_get_setting(instance), furi_string_get_cstr(instance->preset->name))); subghz_txrx_rx(instance, instance->preset->frequency); } void subghz_txrx_set_need_save_callback( SubGhzTxRx* instance, SubGhzTxRxNeedSaveCallback callback, void* context) { furi_assert(instance); instance->need_save_callback = callback; instance->need_save_context = context; } static void subghz_txrx_tx_stop(SubGhzTxRx* instance) { furi_assert(instance); furi_assert(instance->txrx_state == SubGhzTxRxStateTx); //Stop TX subghz_devices_stop_async_tx(instance->radio_device); subghz_transmitter_stop(instance->transmitter); subghz_transmitter_free(instance->transmitter); //if protocol dynamic then we save the last upload if(instance->decoder_result->protocol->type == SubGhzProtocolTypeDynamic) { if(instance->need_save_callback) { instance->need_save_callback(instance->need_save_context); } } subghz_txrx_idle(instance); subghz_txrx_speaker_off(instance); } FlipperFormat* subghz_txrx_get_fff_data(SubGhzTxRx* instance) { furi_assert(instance); return instance->fff_data; } SubGhzSetting* subghz_txrx_get_setting(SubGhzTxRx* instance) { furi_assert(instance); return instance->setting; } void subghz_txrx_stop(SubGhzTxRx* instance) { furi_assert(instance); switch(instance->txrx_state) { case SubGhzTxRxStateTx: subghz_txrx_tx_stop(instance); subghz_txrx_speaker_unmute(instance); break; case SubGhzTxRxStateRx: subghz_txrx_rx_end(instance); subghz_txrx_speaker_mute(instance); break; default: break; } } void subghz_txrx_hopper_update(SubGhzTxRx* instance) { furi_assert(instance); switch(instance->hopper_state) { case SubGhzHopperStateOFF: case SubGhzHopperStatePause: return; case SubGhzHopperStateRSSITimeOut: if(instance->hopper_timeout != 0) { instance->hopper_timeout--; return; } break; default: break; } // Init value isn't using // float rssi = -127.0f; if(instance->hopper_state != SubGhzHopperStateRSSITimeOut) { // See RSSI Calculation timings in CC1101 17.3 RSSI float rssi = subghz_devices_get_rssi(instance->radio_device); // Stay if RSSI is high enough if(rssi > -90.0f) { instance->hopper_timeout = 10; instance->hopper_state = SubGhzHopperStateRSSITimeOut; return; } } else { instance->hopper_state = SubGhzHopperStateRunning; } // Select next frequency if(instance->hopper_idx_frequency < subghz_setting_get_hopper_frequency_count(instance->setting) - 1) { instance->hopper_idx_frequency++; } else { instance->hopper_idx_frequency = 0; } if(instance->txrx_state == SubGhzTxRxStateRx) { subghz_txrx_rx_end(instance); } if(instance->txrx_state == SubGhzTxRxStateIDLE) { subghz_receiver_reset(instance->receiver); instance->preset->frequency = subghz_setting_get_hopper_frequency(instance->setting, instance->hopper_idx_frequency); subghz_txrx_rx(instance, instance->preset->frequency); } } SubGhzHopperState subghz_txrx_hopper_get_state(SubGhzTxRx* instance) { furi_assert(instance); return instance->hopper_state; } void subghz_txrx_hopper_set_state(SubGhzTxRx* instance, SubGhzHopperState state) { furi_assert(instance); instance->hopper_state = state; } void subghz_txrx_hopper_unpause(SubGhzTxRx* instance) { furi_assert(instance); if(instance->hopper_state == SubGhzHopperStatePause) { instance->hopper_state = SubGhzHopperStateRunning; } } void subghz_txrx_hopper_pause(SubGhzTxRx* instance) { furi_assert(instance); if(instance->hopper_state == SubGhzHopperStateRunning) { instance->hopper_state = SubGhzHopperStatePause; } } void subghz_txrx_speaker_on(SubGhzTxRx* instance) { furi_assert(instance); if(instance->debug_pin_state) { subghz_devices_set_async_mirror_pin(instance->radio_device, &gpio_ibutton); } if(instance->speaker_state == SubGhzSpeakerStateEnable) { if(furi_hal_speaker_acquire(30)) { if(!instance->debug_pin_state) { subghz_devices_set_async_mirror_pin(instance->radio_device, &gpio_speaker); } } else { instance->speaker_state = SubGhzSpeakerStateDisable; } } } void subghz_txrx_speaker_off(SubGhzTxRx* instance) { furi_assert(instance); if(instance->debug_pin_state) { subghz_devices_set_async_mirror_pin(instance->radio_device, NULL); } if(instance->speaker_state != SubGhzSpeakerStateDisable) { if(furi_hal_speaker_is_mine()) { if(!instance->debug_pin_state) { subghz_devices_set_async_mirror_pin(instance->radio_device, NULL); } furi_hal_speaker_release(); if(instance->speaker_state == SubGhzSpeakerStateShutdown) instance->speaker_state = SubGhzSpeakerStateDisable; } } } void subghz_txrx_speaker_mute(SubGhzTxRx* instance) { furi_assert(instance); if(instance->debug_pin_state) { subghz_devices_set_async_mirror_pin(instance->radio_device, NULL); } if(instance->speaker_state == SubGhzSpeakerStateEnable) { if(furi_hal_speaker_is_mine()) { if(!instance->debug_pin_state) { subghz_devices_set_async_mirror_pin(instance->radio_device, NULL); } } } } void subghz_txrx_speaker_unmute(SubGhzTxRx* instance) { furi_assert(instance); if(instance->debug_pin_state) { subghz_devices_set_async_mirror_pin(instance->radio_device, &gpio_ibutton); } if(instance->speaker_state == SubGhzSpeakerStateEnable) { if(furi_hal_speaker_is_mine()) { if(!instance->debug_pin_state) { subghz_devices_set_async_mirror_pin(instance->radio_device, &gpio_speaker); } } } } void subghz_txrx_speaker_set_state(SubGhzTxRx* instance, SubGhzSpeakerState state) { furi_assert(instance); instance->speaker_state = state; } SubGhzSpeakerState subghz_txrx_speaker_get_state(SubGhzTxRx* instance) { furi_assert(instance); return instance->speaker_state; } bool subghz_txrx_load_decoder_by_name_protocol(SubGhzTxRx* instance, const char* name_protocol) { furi_assert(instance); furi_assert(name_protocol); bool res = false; instance->decoder_result = subghz_receiver_search_decoder_base_by_name(instance->receiver, name_protocol); if(instance->decoder_result) { res = true; } return res; } SubGhzProtocolDecoderBase* subghz_txrx_get_decoder(SubGhzTxRx* instance) { furi_assert(instance); return instance->decoder_result; } bool subghz_txrx_protocol_is_serializable(SubGhzTxRx* instance) { furi_assert(instance); return ( (instance->decoder_result->protocol->flag & SubGhzProtocolFlag_Save) == SubGhzProtocolFlag_Save); } bool subghz_txrx_protocol_is_transmittable(SubGhzTxRx* instance, bool check_type) { furi_assert(instance); const SubGhzProtocol* protocol = instance->decoder_result->protocol; if(check_type) { return ( ((protocol->flag & SubGhzProtocolFlag_Send) == SubGhzProtocolFlag_Send) && protocol->encoder->deserialize && protocol->type == SubGhzProtocolTypeStatic); } return ( ((protocol->flag & SubGhzProtocolFlag_Send) == SubGhzProtocolFlag_Send) && protocol->encoder->deserialize); } void subghz_txrx_receiver_set_filter(SubGhzTxRx* instance, SubGhzProtocolFlag filter) { furi_assert(instance); subghz_receiver_set_filter(instance->receiver, filter); } void subghz_txrx_set_rx_callback( SubGhzTxRx* instance, SubGhzReceiverCallback callback, void* context) { subghz_receiver_set_rx_callback(instance->receiver, callback, context); } void subghz_txrx_set_raw_file_encoder_worker_callback_end( SubGhzTxRx* instance, SubGhzProtocolEncoderRAWCallbackEnd callback, void* context) { subghz_protocol_raw_file_encoder_worker_set_callback_end( (SubGhzProtocolEncoderRAW*)subghz_transmitter_get_protocol_instance(instance->transmitter), callback, context); } bool subghz_txrx_radio_device_is_external_connected(SubGhzTxRx* instance, const char* name) { furi_assert(instance); bool is_connect = false; bool is_otg_enabled = furi_hal_power_is_otg_enabled(); if(!is_otg_enabled) { subghz_txrx_radio_device_power_on(instance); } const SubGhzDevice* device = subghz_devices_get_by_name(name); if(device) { is_connect = subghz_devices_is_connect(device); } if(!is_otg_enabled) { subghz_txrx_radio_device_power_off(instance); } return is_connect; } SubGhzRadioDeviceType subghz_txrx_radio_device_set(SubGhzTxRx* instance, SubGhzRadioDeviceType radio_device_type) { furi_assert(instance); if(radio_device_type == SubGhzRadioDeviceTypeExternalCC1101 && subghz_txrx_radio_device_is_external_connected(instance, SUBGHZ_DEVICE_CC1101_EXT_NAME)) { subghz_txrx_radio_device_power_on(instance); instance->radio_device = subghz_devices_get_by_name(SUBGHZ_DEVICE_CC1101_EXT_NAME); subghz_devices_begin(instance->radio_device); instance->radio_device_type = SubGhzRadioDeviceTypeExternalCC1101; } else { subghz_txrx_radio_device_power_off(instance); if(instance->radio_device_type != SubGhzRadioDeviceTypeInternal) { subghz_devices_end(instance->radio_device); } instance->radio_device = subghz_devices_get_by_name(SUBGHZ_DEVICE_CC1101_INT_NAME); instance->radio_device_type = SubGhzRadioDeviceTypeInternal; } return instance->radio_device_type; } SubGhzRadioDeviceType subghz_txrx_radio_device_get(SubGhzTxRx* instance) { furi_assert(instance); return instance->radio_device_type; } float subghz_txrx_radio_device_get_rssi(SubGhzTxRx* instance) { furi_assert(instance); return subghz_devices_get_rssi(instance->radio_device); } const char* subghz_txrx_radio_device_get_name(SubGhzTxRx* instance) { furi_assert(instance); return subghz_devices_get_name(instance->radio_device); } bool subghz_txrx_radio_device_is_frequency_valid(SubGhzTxRx* instance, uint32_t frequency) { furi_assert(instance); return subghz_devices_is_frequency_valid(instance->radio_device, frequency); } bool subghz_txrx_radio_device_is_tx_allowed(SubGhzTxRx* instance, uint32_t frequency) { // TODO: Remake this function to check if the frequency is allowed on specific module - for modules not based on CC1101 furi_assert(instance); UNUSED(frequency); /* furi_assert(instance->txrx_state != SubGhzTxRxStateSleep); subghz_devices_idle(instance->radio_device); subghz_devices_set_frequency(instance->radio_device, frequency); bool ret = subghz_devices_set_tx(instance->radio_device); subghz_devices_idle(instance->radio_device); return ret; */ return true; } void subghz_txrx_set_debug_pin_state(SubGhzTxRx* instance, bool state) { furi_assert(instance); instance->debug_pin_state = state; } bool subghz_txrx_get_debug_pin_state(SubGhzTxRx* instance) { furi_assert(instance); return instance->debug_pin_state; } void subghz_txrx_reset_dynamic_and_custom_btns(SubGhzTxRx* instance) { furi_assert(instance); subghz_environment_reset_keeloq(instance->environment); subghz_custom_btns_reset(); } SubGhzReceiver* subghz_txrx_get_receiver(SubGhzTxRx* instance) { furi_assert(instance); return instance->receiver; } void subghz_txrx_set_default_preset(SubGhzTxRx* instance, uint32_t frequency) { furi_assert(instance); const char* default_modulation = "AM650"; if(frequency == 0) { frequency = subghz_setting_get_default_frequency(subghz_txrx_get_setting(instance)); } subghz_txrx_set_preset(instance, default_modulation, frequency, NULL, 0); } const char* subghz_txrx_set_preset_internal(SubGhzTxRx* instance, uint32_t frequency, uint8_t index) { furi_assert(instance); SubGhzSetting* setting = subghz_txrx_get_setting(instance); const char* preset_name = subghz_setting_get_preset_name(setting, index); subghz_setting_set_default_frequency(setting, frequency); subghz_txrx_set_preset( instance, preset_name, frequency, subghz_setting_get_preset_data(setting, index), subghz_setting_get_preset_data_size(setting, index)); return preset_name; }