mirror of
https://github.com/DarkFlippers/unleashed-firmware
synced 2024-11-27 15:00:46 +00:00
64bd2f9c84
* Update saved_info and read_success scenes * Update EM4100 rendering * Update HIDExt rendering * Update Gallagher rendering * Update HidProx rendering * Update IOProx rendering * Update H10301 rendering * Update PAC/Stanley rendering * Add strcasecmp() to API, better manufacturer/name handling * Update Viking rendering * Update FDX-A rendering * Update Pyramid rendering * Update Indala26 rendering * Update Idteck rendering * Update Keri rendering * Update Nexwatch rendering * Update Jablotron rendering * Update Paradox rendering * Truncate long Hex string on scene_read_suceess * Fix formatting * Update AWID rendering * Update FDX-B rendering * Tweak string formatting in various screens * More read_success view tweaks * Fix formatting * Fix Pyramid brief rendering * Reset saved key menu when going back * Reset other menus on back where applicable * Update confirmation scenes * Update emulation scene * Update delete scene * Update raw read info screen * Update raw read scene, fix crash * Update raw read success scene * Update write scene * Always return to SceneSelectKey after saving * Update SceneWriteSuccess and SceneDeleteSuccess * Replace closing parens with dots * FL-3798: Fix special formatting in text_box * Simplify SceneReadSuccess * Fix crash when having a trailing newline in text_box * Bump API symbols version * Make PVS happy * Format sources Co-authored-by: あく <alleteam@gmail.com>
390 lines
12 KiB
C
390 lines
12 KiB
C
#include <furi.h>
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#include <toolbox/protocols/protocol.h>
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#include <lfrfid/tools/fsk_demod.h>
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#include <lfrfid/tools/fsk_osc.h>
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#include "lfrfid_protocols.h"
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#define JITTER_TIME (20)
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#define MIN_TIME (64 - JITTER_TIME)
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#define MAX_TIME (80 + JITTER_TIME)
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#define H10301_DECODED_DATA_SIZE (3)
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#define H10301_ENCODED_DATA_SIZE_U32 (3)
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#define H10301_ENCODED_DATA_SIZE (sizeof(uint32_t) * H10301_ENCODED_DATA_SIZE_U32)
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#define H10301_BIT_SIZE (sizeof(uint32_t) * 8)
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#define H10301_BIT_MAX_SIZE (H10301_BIT_SIZE * H10301_DECODED_DATA_SIZE)
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typedef struct {
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FSKDemod* fsk_demod;
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} ProtocolH10301Decoder;
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typedef struct {
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FSKOsc* fsk_osc;
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uint8_t encoded_index;
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uint32_t pulse;
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} ProtocolH10301Encoder;
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typedef struct {
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ProtocolH10301Decoder decoder;
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ProtocolH10301Encoder encoder;
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uint32_t encoded_data[H10301_ENCODED_DATA_SIZE_U32];
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uint8_t data[H10301_DECODED_DATA_SIZE];
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} ProtocolH10301;
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ProtocolH10301* protocol_h10301_alloc(void) {
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ProtocolH10301* protocol = malloc(sizeof(ProtocolH10301));
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protocol->decoder.fsk_demod = fsk_demod_alloc(MIN_TIME, 6, MAX_TIME, 5);
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protocol->encoder.fsk_osc = fsk_osc_alloc(8, 10, 50);
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return protocol;
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};
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void protocol_h10301_free(ProtocolH10301* protocol) {
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fsk_demod_free(protocol->decoder.fsk_demod);
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fsk_osc_free(protocol->encoder.fsk_osc);
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free(protocol);
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};
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uint8_t* protocol_h10301_get_data(ProtocolH10301* protocol) {
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return protocol->data;
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};
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void protocol_h10301_decoder_start(ProtocolH10301* protocol) {
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memset(protocol->encoded_data, 0, sizeof(uint32_t) * 3);
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};
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static void protocol_h10301_decoder_store_data(ProtocolH10301* protocol, bool data) {
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protocol->encoded_data[0] = (protocol->encoded_data[0] << 1) |
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((protocol->encoded_data[1] >> 31) & 1);
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protocol->encoded_data[1] = (protocol->encoded_data[1] << 1) |
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((protocol->encoded_data[2] >> 31) & 1);
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protocol->encoded_data[2] = (protocol->encoded_data[2] << 1) | data;
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}
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static bool protocol_h10301_can_be_decoded(const uint32_t* card_data) {
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const uint8_t* encoded_data = (const uint8_t*)card_data;
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// packet preamble
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// raw data
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if(*(encoded_data + 3) != 0x1D) {
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return false;
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}
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// encoded company/oem
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// coded with 01 = 0, 10 = 1 transitions
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// stored in word 0
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if((*card_data >> 10 & 0x3FFF) != 0x1556) {
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return false;
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}
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// encoded format/length
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// coded with 01 = 0, 10 = 1 transitions
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// stored in word 0 and word 1
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if((((*card_data & 0x3FF) << 12) | ((*(card_data + 1) >> 20) & 0xFFF)) != 0x155556) {
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return false;
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}
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// data decoding
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uint32_t result = 0;
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// decode from word 1
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// coded with 01 = 0, 10 = 1 transitions
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for(int8_t i = 9; i >= 0; i--) {
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switch((*(card_data + 1) >> (2 * i)) & 0b11) {
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case 0b01:
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result = (result << 1) | 0;
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break;
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case 0b10:
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result = (result << 1) | 1;
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break;
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default:
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return false;
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break;
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}
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}
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// decode from word 2
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// coded with 01 = 0, 10 = 1 transitions
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for(int8_t i = 15; i >= 0; i--) {
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switch((*(card_data + 2) >> (2 * i)) & 0b11) {
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case 0b01:
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result = (result << 1) | 0;
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break;
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case 0b10:
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result = (result << 1) | 1;
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break;
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default:
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return false;
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break;
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}
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}
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// trailing parity (odd) test
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uint8_t parity_sum = 0;
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for(int8_t i = 0; i < 13; i++) {
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if(((result >> i) & 1) == 1) {
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parity_sum++;
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}
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}
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if((parity_sum % 2) != 1) {
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return false;
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}
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// leading parity (even) test
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parity_sum = 0;
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for(int8_t i = 13; i < 26; i++) {
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if(((result >> i) & 1) == 1) {
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parity_sum++;
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}
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}
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if((parity_sum % 2) == 1) {
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return false;
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}
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return true;
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}
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static void protocol_h10301_decode(const uint32_t* card_data, uint8_t* decoded_data) {
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// data decoding
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uint32_t result = 0;
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// decode from word 1
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// coded with 01 = 0, 10 = 1 transitions
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for(int8_t i = 9; i >= 0; i--) {
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switch((*(card_data + 1) >> (2 * i)) & 0b11) {
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case 0b01:
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result = (result << 1) | 0;
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break;
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case 0b10:
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result = (result << 1) | 1;
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break;
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default:
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break;
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}
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}
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// decode from word 2
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// coded with 01 = 0, 10 = 1 transitions
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for(int8_t i = 15; i >= 0; i--) {
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switch((*(card_data + 2) >> (2 * i)) & 0b11) {
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case 0b01:
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result = (result << 1) | 0;
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break;
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case 0b10:
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result = (result << 1) | 1;
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break;
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default:
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break;
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}
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}
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uint8_t data[H10301_DECODED_DATA_SIZE] = {
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(uint8_t)(result >> 17), (uint8_t)(result >> 9), (uint8_t)(result >> 1)};
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memcpy(decoded_data, &data, H10301_DECODED_DATA_SIZE);
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}
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bool protocol_h10301_decoder_feed(ProtocolH10301* protocol, bool level, uint32_t duration) {
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bool value;
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uint32_t count;
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bool result = false;
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fsk_demod_feed(protocol->decoder.fsk_demod, level, duration, &value, &count);
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if(count > 0) {
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for(size_t i = 0; i < count; i++) {
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protocol_h10301_decoder_store_data(protocol, value);
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if(protocol_h10301_can_be_decoded(protocol->encoded_data)) {
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protocol_h10301_decode(protocol->encoded_data, protocol->data);
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result = true;
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break;
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}
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}
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}
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return result;
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};
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static void protocol_h10301_write_raw_bit(bool bit, uint8_t position, uint32_t* card_data) {
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if(bit) {
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card_data[position / H10301_BIT_SIZE] |=
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1UL << (H10301_BIT_SIZE - (position % H10301_BIT_SIZE) - 1);
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} else {
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card_data[position / H10301_BIT_SIZE] &=
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~(1UL << (H10301_BIT_SIZE - (position % H10301_BIT_SIZE) - 1));
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}
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}
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static void protocol_h10301_write_bit(bool bit, uint8_t position, uint32_t* card_data) {
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protocol_h10301_write_raw_bit(bit, position + 0, card_data);
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protocol_h10301_write_raw_bit(!bit, position + 1, card_data);
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}
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void protocol_h10301_encode(const uint8_t* decoded_data, uint8_t* encoded_data) {
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uint32_t card_data[H10301_DECODED_DATA_SIZE] = {0, 0, 0};
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uint32_t fc_cn = (decoded_data[0] << 16) | (decoded_data[1] << 8) | decoded_data[2];
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// even parity sum calculation (high 12 bits of data)
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uint8_t even_parity_sum = 0;
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for(int8_t i = 12; i < 24; i++) {
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if(((fc_cn >> i) & 1) == 1) {
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even_parity_sum++;
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}
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}
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// odd parity sum calculation (low 12 bits of data)
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uint8_t odd_parity_sum = 1;
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for(int8_t i = 0; i < 12; i++) {
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if(((fc_cn >> i) & 1) == 1) {
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odd_parity_sum++;
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}
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}
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// 0x1D preamble
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protocol_h10301_write_raw_bit(0, 0, card_data);
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protocol_h10301_write_raw_bit(0, 1, card_data);
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protocol_h10301_write_raw_bit(0, 2, card_data);
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protocol_h10301_write_raw_bit(1, 3, card_data);
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protocol_h10301_write_raw_bit(1, 4, card_data);
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protocol_h10301_write_raw_bit(1, 5, card_data);
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protocol_h10301_write_raw_bit(0, 6, card_data);
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protocol_h10301_write_raw_bit(1, 7, card_data);
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// company / OEM code 1
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protocol_h10301_write_bit(0, 8, card_data);
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protocol_h10301_write_bit(0, 10, card_data);
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protocol_h10301_write_bit(0, 12, card_data);
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protocol_h10301_write_bit(0, 14, card_data);
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protocol_h10301_write_bit(0, 16, card_data);
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protocol_h10301_write_bit(0, 18, card_data);
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protocol_h10301_write_bit(1, 20, card_data);
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// card format / length 1
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protocol_h10301_write_bit(0, 22, card_data);
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protocol_h10301_write_bit(0, 24, card_data);
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protocol_h10301_write_bit(0, 26, card_data);
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protocol_h10301_write_bit(0, 28, card_data);
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protocol_h10301_write_bit(0, 30, card_data);
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protocol_h10301_write_bit(0, 32, card_data);
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protocol_h10301_write_bit(0, 34, card_data);
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protocol_h10301_write_bit(0, 36, card_data);
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protocol_h10301_write_bit(0, 38, card_data);
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protocol_h10301_write_bit(0, 40, card_data);
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protocol_h10301_write_bit(1, 42, card_data);
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// even parity bit
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protocol_h10301_write_bit((even_parity_sum % 2), 44, card_data);
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// data
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for(uint8_t i = 0; i < 24; i++) {
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protocol_h10301_write_bit((fc_cn >> (23 - i)) & 1, 46 + (i * 2), card_data);
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}
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// odd parity bit
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protocol_h10301_write_bit((odd_parity_sum % 2), 94, card_data);
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memcpy(encoded_data, &card_data, H10301_ENCODED_DATA_SIZE);
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}
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bool protocol_h10301_encoder_start(ProtocolH10301* protocol) {
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protocol_h10301_encode(protocol->data, (uint8_t*)protocol->encoded_data);
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protocol->encoder.encoded_index = 0;
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protocol->encoder.pulse = 0;
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return true;
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};
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LevelDuration protocol_h10301_encoder_yield(ProtocolH10301* protocol) {
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bool level = 0;
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uint32_t duration = 0;
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// if pulse is zero, we need to output high, otherwise we need to output low
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if(protocol->encoder.pulse == 0) {
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// get bit
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uint8_t bit =
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(protocol->encoded_data[protocol->encoder.encoded_index / H10301_BIT_SIZE] >>
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((H10301_BIT_SIZE - 1) - (protocol->encoder.encoded_index % H10301_BIT_SIZE))) &
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1;
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// get pulse from oscillator
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bool advance = fsk_osc_next(protocol->encoder.fsk_osc, bit, &duration);
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if(advance) {
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protocol->encoder.encoded_index++;
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if(protocol->encoder.encoded_index >= (H10301_BIT_MAX_SIZE)) {
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protocol->encoder.encoded_index = 0;
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}
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}
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// duration diveded by 2 because we need to output high and low
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duration = duration / 2;
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protocol->encoder.pulse = duration;
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level = true;
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} else {
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// output low half and reset pulse
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duration = protocol->encoder.pulse;
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protocol->encoder.pulse = 0;
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level = false;
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}
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return level_duration_make(level, duration);
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};
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bool protocol_h10301_write_data(ProtocolH10301* protocol, void* data) {
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LFRFIDWriteRequest* request = (LFRFIDWriteRequest*)data;
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bool result = false;
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// Correct protocol data by redecoding
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protocol_h10301_encoder_start(protocol);
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protocol_h10301_decode(protocol->encoded_data, protocol->data);
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protocol_h10301_encoder_start(protocol);
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if(request->write_type == LFRFIDWriteTypeT5577) {
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request->t5577.block[0] = LFRFID_T5577_MODULATION_FSK2a | LFRFID_T5577_BITRATE_RF_50 |
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(3 << LFRFID_T5577_MAXBLOCK_SHIFT);
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request->t5577.block[1] = protocol->encoded_data[0];
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request->t5577.block[2] = protocol->encoded_data[1];
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request->t5577.block[3] = protocol->encoded_data[2];
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request->t5577.blocks_to_write = 4;
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result = true;
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}
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return result;
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};
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void protocol_h10301_render_data(ProtocolH10301* protocol, FuriString* result) {
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uint8_t* data = protocol->data;
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furi_string_printf(
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result,
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"FC: %hhu\n"
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"Card: %hu",
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data[0],
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(uint16_t)((data[1] << 8) | (data[2])));
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};
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const ProtocolBase protocol_h10301 = {
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.name = "H10301",
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.manufacturer = "HID",
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.data_size = H10301_DECODED_DATA_SIZE,
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.features = LFRFIDFeatureASK,
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.validate_count = 3,
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.alloc = (ProtocolAlloc)protocol_h10301_alloc,
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.free = (ProtocolFree)protocol_h10301_free,
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.get_data = (ProtocolGetData)protocol_h10301_get_data,
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.decoder =
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{
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.start = (ProtocolDecoderStart)protocol_h10301_decoder_start,
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.feed = (ProtocolDecoderFeed)protocol_h10301_decoder_feed,
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},
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.encoder =
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{
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.start = (ProtocolEncoderStart)protocol_h10301_encoder_start,
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.yield = (ProtocolEncoderYield)protocol_h10301_encoder_yield,
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},
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.render_data = (ProtocolRenderData)protocol_h10301_render_data,
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.render_brief_data = (ProtocolRenderData)protocol_h10301_render_data,
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.write_data = (ProtocolWriteData)protocol_h10301_write_data,
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};
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