#include "nord_ice.h" #include "../blocks/const.h" #include "../blocks/decoder.h" #include "../blocks/encoder.h" #include "../blocks/generic.h" #include "../blocks/math.h" #define TAG "SubGhzProtocolNord_Ice" static const SubGhzBlockConst subghz_protocol_nord_ice_const = { .te_short = 300, .te_long = 800, .te_delta = 150, .min_count_bit_for_found = 33, }; struct SubGhzProtocolDecoderNord_Ice { SubGhzProtocolDecoderBase base; SubGhzBlockDecoder decoder; SubGhzBlockGeneric generic; }; struct SubGhzProtocolEncoderNord_Ice { SubGhzProtocolEncoderBase base; SubGhzProtocolBlockEncoder encoder; SubGhzBlockGeneric generic; }; typedef enum { Nord_IceDecoderStepReset = 0, Nord_IceDecoderStepSaveDuration, Nord_IceDecoderStepCheckDuration, } Nord_IceDecoderStep; const SubGhzProtocolDecoder subghz_protocol_nord_ice_decoder = { .alloc = subghz_protocol_decoder_nord_ice_alloc, .free = subghz_protocol_decoder_nord_ice_free, .feed = subghz_protocol_decoder_nord_ice_feed, .reset = subghz_protocol_decoder_nord_ice_reset, .get_hash_data = NULL, .get_hash_data_long = subghz_protocol_decoder_nord_ice_get_hash_data, .serialize = subghz_protocol_decoder_nord_ice_serialize, .deserialize = subghz_protocol_decoder_nord_ice_deserialize, .get_string = subghz_protocol_decoder_nord_ice_get_string, .get_string_brief = NULL, }; const SubGhzProtocolEncoder subghz_protocol_nord_ice_encoder = { .alloc = subghz_protocol_encoder_nord_ice_alloc, .free = subghz_protocol_encoder_nord_ice_free, .deserialize = subghz_protocol_encoder_nord_ice_deserialize, .stop = subghz_protocol_encoder_nord_ice_stop, .yield = subghz_protocol_encoder_nord_ice_yield, }; const SubGhzProtocol subghz_protocol_nord_ice = { .name = SUBGHZ_PROTOCOL_NORD_ICE_NAME, .type = SubGhzProtocolTypeStatic, .flag = SubGhzProtocolFlag_433 | SubGhzProtocolFlag_AM | SubGhzProtocolFlag_Decodable | SubGhzProtocolFlag_Load | SubGhzProtocolFlag_Save | SubGhzProtocolFlag_Send, .decoder = &subghz_protocol_nord_ice_decoder, .encoder = &subghz_protocol_nord_ice_encoder, }; void* subghz_protocol_encoder_nord_ice_alloc(SubGhzEnvironment* environment) { UNUSED(environment); SubGhzProtocolEncoderNord_Ice* instance = malloc(sizeof(SubGhzProtocolEncoderNord_Ice)); instance->base.protocol = &subghz_protocol_nord_ice; instance->generic.protocol_name = instance->base.protocol->name; instance->encoder.repeat = 3; instance->encoder.size_upload = 128; instance->encoder.upload = malloc(instance->encoder.size_upload * sizeof(LevelDuration)); instance->encoder.is_running = false; return instance; } void subghz_protocol_encoder_nord_ice_free(void* context) { furi_assert(context); SubGhzProtocolEncoderNord_Ice* instance = context; free(instance->encoder.upload); free(instance); } /** * Generating an upload from data. * @param instance Pointer to a SubGhzProtocolEncoderNord_Ice instance */ static void subghz_protocol_encoder_nord_ice_get_upload(SubGhzProtocolEncoderNord_Ice* instance) { furi_assert(instance); size_t index = 0; // Send key and GAP for(uint8_t i = instance->generic.data_count_bit; i > 0; i--) { if(bit_read(instance->generic.data, i - 1)) { // Send bit 1 instance->encoder.upload[index++] = level_duration_make(true, (uint32_t)subghz_protocol_nord_ice_const.te_long); if(i == 1) { //Send gap if bit was last instance->encoder.upload[index++] = level_duration_make( false, (uint32_t)subghz_protocol_nord_ice_const.te_short * 25); } else { instance->encoder.upload[index++] = level_duration_make(false, (uint32_t)subghz_protocol_nord_ice_const.te_short); } } else { // Send bit 0 instance->encoder.upload[index++] = level_duration_make(true, (uint32_t)subghz_protocol_nord_ice_const.te_short); if(i == 1) { //Send gap if bit was last instance->encoder.upload[index++] = level_duration_make( false, (uint32_t)subghz_protocol_nord_ice_const.te_short * 25); } else { instance->encoder.upload[index++] = level_duration_make(false, (uint32_t)subghz_protocol_nord_ice_const.te_long); } } } instance->encoder.size_upload = index; return; } /** * Analysis of received data * @param instance Pointer to a SubGhzBlockGeneric* instance */ static void subghz_protocol_nord_ice_check_remote_controller(SubGhzBlockGeneric* instance) { instance->serial = (instance->data >> 15) << 9 | (instance->data & 0x1FF); // 26 bits for serial instance->btn = (instance->data >> 9) & 0x3F; // 6 bits for button } SubGhzProtocolStatus subghz_protocol_encoder_nord_ice_deserialize(void* context, FlipperFormat* flipper_format) { furi_assert(context); SubGhzProtocolEncoderNord_Ice* instance = context; SubGhzProtocolStatus ret = SubGhzProtocolStatusError; do { ret = subghz_block_generic_deserialize_check_count_bit( &instance->generic, flipper_format, subghz_protocol_nord_ice_const.min_count_bit_for_found); if(ret != SubGhzProtocolStatusOk) { break; } // Optional value flipper_format_read_uint32( flipper_format, "Repeat", (uint32_t*)&instance->encoder.repeat, 1); subghz_protocol_nord_ice_check_remote_controller(&instance->generic); subghz_protocol_encoder_nord_ice_get_upload(instance); instance->encoder.is_running = true; } while(false); return ret; } void subghz_protocol_encoder_nord_ice_stop(void* context) { SubGhzProtocolEncoderNord_Ice* instance = context; instance->encoder.is_running = false; } LevelDuration subghz_protocol_encoder_nord_ice_yield(void* context) { SubGhzProtocolEncoderNord_Ice* instance = context; if(instance->encoder.repeat == 0 || !instance->encoder.is_running) { instance->encoder.is_running = false; return level_duration_reset(); } LevelDuration ret = instance->encoder.upload[instance->encoder.front]; if(++instance->encoder.front == instance->encoder.size_upload) { if(!subghz_block_generic_global.endless_tx) instance->encoder.repeat--; instance->encoder.front = 0; } return ret; } void* subghz_protocol_decoder_nord_ice_alloc(SubGhzEnvironment* environment) { UNUSED(environment); SubGhzProtocolDecoderNord_Ice* instance = malloc(sizeof(SubGhzProtocolDecoderNord_Ice)); instance->base.protocol = &subghz_protocol_nord_ice; instance->generic.protocol_name = instance->base.protocol->name; return instance; } void subghz_protocol_decoder_nord_ice_free(void* context) { furi_assert(context); SubGhzProtocolDecoderNord_Ice* instance = context; free(instance); } void subghz_protocol_decoder_nord_ice_reset(void* context) { furi_assert(context); SubGhzProtocolDecoderNord_Ice* instance = context; instance->decoder.parser_step = Nord_IceDecoderStepReset; } void subghz_protocol_decoder_nord_ice_feed(void* context, bool level, volatile uint32_t duration) { furi_assert(context); SubGhzProtocolDecoderNord_Ice* instance = context; // Nord ICE Decoder // 2026.03 - @xMasterX (MMX) // Key samples // // Serial Btn Serial // 0x9467688A btn 1 = 10010100011001110 110100 010001010 // 0x9467308A btn 2 = 10010100011001110 011000 010001010 // 0x9467628A btn 3 = 10010100011001110 110001 010001010 // 0x9467648A btn 4 = 10010100011001110 110010 010001010 switch(instance->decoder.parser_step) { case Nord_IceDecoderStepReset: if((!level) && (DURATION_DIFF(duration, subghz_protocol_nord_ice_const.te_short * 25) < subghz_protocol_nord_ice_const.te_delta * 11)) { //Found GAP instance->decoder.decode_data = 0; instance->decoder.decode_count_bit = 0; instance->decoder.parser_step = Nord_IceDecoderStepSaveDuration; } break; case Nord_IceDecoderStepSaveDuration: if(level) { instance->decoder.te_last = duration; instance->decoder.parser_step = Nord_IceDecoderStepCheckDuration; } else { instance->decoder.parser_step = Nord_IceDecoderStepReset; } break; case Nord_IceDecoderStepCheckDuration: if(!level) { // Bit 0 is short and long timing = 300us HIGH (te_last) and 800us LOW if((DURATION_DIFF(instance->decoder.te_last, subghz_protocol_nord_ice_const.te_short) < subghz_protocol_nord_ice_const.te_delta) && (DURATION_DIFF(duration, subghz_protocol_nord_ice_const.te_long) < subghz_protocol_nord_ice_const.te_delta)) { subghz_protocol_blocks_add_bit(&instance->decoder, 0); instance->decoder.parser_step = Nord_IceDecoderStepSaveDuration; // Bit 1 is long and short timing = 800us HIGH (te_last) and 300us LOW } else if( (DURATION_DIFF(instance->decoder.te_last, subghz_protocol_nord_ice_const.te_long) < subghz_protocol_nord_ice_const.te_delta) && (DURATION_DIFF(duration, subghz_protocol_nord_ice_const.te_short) < subghz_protocol_nord_ice_const.te_delta)) { subghz_protocol_blocks_add_bit(&instance->decoder, 1); instance->decoder.parser_step = Nord_IceDecoderStepSaveDuration; } else if( // End of the key DURATION_DIFF(duration, subghz_protocol_nord_ice_const.te_short * 25) < subghz_protocol_nord_ice_const.te_delta * 11) { //Found next GAP and add bit 0 or 1 (only bit 0 was found on the remotes) if((DURATION_DIFF( instance->decoder.te_last, subghz_protocol_nord_ice_const.te_short) < subghz_protocol_nord_ice_const.te_delta)) { subghz_protocol_blocks_add_bit(&instance->decoder, 0); } if((DURATION_DIFF( instance->decoder.te_last, subghz_protocol_nord_ice_const.te_long) < subghz_protocol_nord_ice_const.te_delta)) { subghz_protocol_blocks_add_bit(&instance->decoder, 1); } // If got 33 bits key reading is finished if(instance->decoder.decode_count_bit == subghz_protocol_nord_ice_const.min_count_bit_for_found) { instance->generic.data = instance->decoder.decode_data; instance->generic.data_count_bit = instance->decoder.decode_count_bit; if(instance->base.callback) instance->base.callback(&instance->base, instance->base.context); } instance->decoder.decode_data = 0; instance->decoder.decode_count_bit = 0; instance->decoder.parser_step = Nord_IceDecoderStepReset; } else { instance->decoder.parser_step = Nord_IceDecoderStepReset; } } else { instance->decoder.parser_step = Nord_IceDecoderStepReset; } break; } } uint32_t subghz_protocol_decoder_nord_ice_get_hash_data(void* context) { furi_assert(context); SubGhzProtocolDecoderNord_Ice* instance = context; return subghz_protocol_blocks_get_hash_data_long( &instance->decoder, (instance->decoder.decode_count_bit / 8) + 1); } SubGhzProtocolStatus subghz_protocol_decoder_nord_ice_serialize( void* context, FlipperFormat* flipper_format, SubGhzRadioPreset* preset) { furi_assert(context); SubGhzProtocolDecoderNord_Ice* instance = context; return subghz_block_generic_serialize(&instance->generic, flipper_format, preset); } SubGhzProtocolStatus subghz_protocol_decoder_nord_ice_deserialize(void* context, FlipperFormat* flipper_format) { furi_assert(context); SubGhzProtocolDecoderNord_Ice* instance = context; return subghz_block_generic_deserialize_check_count_bit( &instance->generic, flipper_format, subghz_protocol_nord_ice_const.min_count_bit_for_found); } void subghz_protocol_decoder_nord_ice_get_string(void* context, FuriString* output) { furi_assert(context); SubGhzProtocolDecoderNord_Ice* instance = context; subghz_protocol_nord_ice_check_remote_controller(&instance->generic); uint64_t code_found_reverse = subghz_protocol_blocks_reverse_key( instance->generic.data, instance->generic.data_count_bit); // for future use // // push protocol data to global variable // subghz_block_generic_global.btn_is_available = false; // subghz_block_generic_global.current_btn = instance->generic.btn; // subghz_block_generic_global.btn_length_bit = 4; // // furi_string_cat_printf( output, "%s %db\r\n" "Key: 0x%08llX\r\n" "Yek: 0x%08llX\r\n" "Serial: 0x%07lX\r\n" "Btn: %02X", instance->generic.protocol_name, instance->generic.data_count_bit, (uint64_t)(instance->generic.data & 0xFFFFFFFFF), (code_found_reverse & 0xFFFFFFFFF), instance->generic.serial, instance->generic.btn); }