mirror of
https://github.com/DarkFlippers/unleashed-firmware
synced 2024-11-23 21:13:16 +00:00
22a4bac448
* Core: wipe memory after free. RFID,iButton: fix iterator use after invalidation. * Debug: support unix wildcards for register matching in svd, update MCU description file and minify it. * Toolbox: getter for File in FlipperFile. * Makefile: conditional flashing * SubGhz: keeloq_mfcodes encryption tool. * FuriHal: proper IV handling on CBC in crypto. SubGhz: add support for encrypted keeloq keys. Makefile: move formatting to top Makefile. * SubGhz: rename some function names to match naming scheme. * SubGhz: encryption tool, fix windows line endings Co-authored-by: DrZlo13 <who.just.the.doctor@gmail.com>
317 lines
12 KiB
C
317 lines
12 KiB
C
#include "subghz_keystore.h"
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#include <furi.h>
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#include <furi-hal.h>
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#include <storage/storage.h>
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#include <lib/toolbox/hex.h>
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#include <lib/toolbox/flipper-file.h>
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#define SUBGHZ_KEYSTORE_TAG "SubGhzParser"
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#define FILE_BUFFER_SIZE 64
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#define SUBGHZ_KEYSTORE_FILE_TYPE "Flipper SubGhz Keystore File"
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#define SUBGHZ_KEYSTORE_FILE_VERSION 0
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#define SUBGHZ_KEYSTORE_FILE_ENCRYPTION_KEY_SLOT 1
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#define SUBGHZ_KEYSTORE_FILE_DECRYPTED_LINE_SIZE 512
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#define SUBGHZ_KEYSTORE_FILE_ENCRYPTED_LINE_SIZE (SUBGHZ_KEYSTORE_FILE_DECRYPTED_LINE_SIZE*2)
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typedef enum {
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SubGhzKeystoreEncryptionNone,
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SubGhzKeystoreEncryptionAES256,
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} SubGhzKeystoreEncryption;
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struct SubGhzKeystore {
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SubGhzKeyArray_t data;
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};
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SubGhzKeystore* subghz_keystore_alloc() {
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SubGhzKeystore* instance = furi_alloc(sizeof(SubGhzKeystore));
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SubGhzKeyArray_init(instance->data);
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return instance;
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}
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void subghz_keystore_free(SubGhzKeystore* instance) {
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furi_assert(instance);
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for
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M_EACH(manufacture_code, instance->data, SubGhzKeyArray_t) {
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string_clear(manufacture_code->name);
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manufacture_code->key = 0;
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}
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SubGhzKeyArray_clear(instance->data);
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free(instance);
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}
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static void subghz_keystore_add_key(SubGhzKeystore* instance, const char* name, uint64_t key, uint16_t type) {
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SubGhzKey* manufacture_code = SubGhzKeyArray_push_raw(instance->data);
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string_init_set_str(manufacture_code->name, name);
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manufacture_code->key = key;
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manufacture_code->type = type;
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}
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static bool subghz_keystore_process_line(SubGhzKeystore* instance, char* line) {
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uint64_t key = 0;
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uint16_t type = 0;
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char skey[17] = {0};
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char name[65] = {0};
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int ret = sscanf(line, "%16s:%hu:%64s", skey, &type, name);
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key = strtoull(skey, NULL, 16);
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if (ret == 3) {
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subghz_keystore_add_key(instance, name, key, type);
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return true;
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} else {
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FURI_LOG_E(SUBGHZ_KEYSTORE_TAG, "Failed to load line: %s\r\n", line);
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return false;
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}
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}
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static void subghz_keystore_mess_with_iv(uint8_t* iv) {
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// Please do not share decrypted manufacture keys
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// Sharing them will bring some discomfort to legal owners
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// And potential legal action against you
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// While you reading this code think about your own personal responsibility
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asm volatile(
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"movs r0, #0x0 \n"
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"movs r1, #0x0 \n"
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"movs r2, #0x0 \n"
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"movs r3, #0x0 \n"
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"nani: \n"
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"ldrb r1, [r0, %0]\n"
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"mov r2, r1 \n"
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"add r1, r3 \n"
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"mov r3, r2 \n"
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"strb r1, [r0, %0]\n"
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"adds r0, #0x1 \n"
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"cmp r0, #0xF \n"
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"bls nani \n"
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:
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: "r"(iv)
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: "r0", "r1", "r2", "r3", "memory");
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}
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static bool subghz_keystore_read_file(SubGhzKeystore* instance, File* file, uint8_t* iv) {
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bool result = true;
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char buffer[FILE_BUFFER_SIZE];
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char* decrypted_line = furi_alloc(SUBGHZ_KEYSTORE_FILE_DECRYPTED_LINE_SIZE);
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char* encrypted_line = furi_alloc(SUBGHZ_KEYSTORE_FILE_ENCRYPTED_LINE_SIZE);
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size_t encrypted_line_cursor = 0;
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if (iv) furi_hal_crypto_store_load_key(SUBGHZ_KEYSTORE_FILE_ENCRYPTION_KEY_SLOT, iv);
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size_t ret = 0;
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do {
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ret = storage_file_read(file, buffer, FILE_BUFFER_SIZE);
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for (uint16_t i=0; i < ret; i++) {
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if (buffer[i] == '\n' && encrypted_line_cursor > 0) {
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// Process line
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if(iv) {
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// Data alignment check, 32 instead of 16 because of hex encoding
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size_t len = strlen(encrypted_line);
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if (len % 32 == 0) {
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// Inplace hex to bin conversion
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for (size_t i=0; i<len; i+=2) {
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uint8_t hi_nibble=0;
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uint8_t lo_nibble=0;
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hex_char_to_hex_nibble(encrypted_line[i], &hi_nibble);
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hex_char_to_hex_nibble(encrypted_line[i+1], &lo_nibble);
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encrypted_line[i/2] = (hi_nibble<<4) | lo_nibble;
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}
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len /= 2;
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if(furi_hal_crypto_decrypt((uint8_t*)encrypted_line, (uint8_t*)decrypted_line, len)) {
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subghz_keystore_process_line(instance, decrypted_line);
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} else {
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FURI_LOG_E(SUBGHZ_KEYSTORE_TAG, "Decryption failed");
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result = false;
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break;
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}
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} else {
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FURI_LOG_E(SUBGHZ_KEYSTORE_TAG, "Invalid encrypted data: %s", encrypted_line);
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}
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} else {
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subghz_keystore_process_line(instance, encrypted_line);
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}
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// reset line buffer
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memset(decrypted_line, 0, SUBGHZ_KEYSTORE_FILE_DECRYPTED_LINE_SIZE);
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memset(encrypted_line, 0, SUBGHZ_KEYSTORE_FILE_ENCRYPTED_LINE_SIZE);
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encrypted_line_cursor = 0;
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} else if (buffer[i] == '\r' || buffer[i] == '\n') {
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// do not add line endings to the buffer
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} else {
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if (encrypted_line_cursor < SUBGHZ_KEYSTORE_FILE_ENCRYPTED_LINE_SIZE) {
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encrypted_line[encrypted_line_cursor] = buffer[i];
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encrypted_line_cursor++;
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} else {
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FURI_LOG_E(SUBGHZ_KEYSTORE_TAG, "Malformed file");
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result = false;
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break;
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}
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}
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}
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} while(ret > 0 && result);
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if (iv) furi_hal_crypto_store_unload_key(SUBGHZ_KEYSTORE_FILE_ENCRYPTION_KEY_SLOT);
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free(encrypted_line);
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free(decrypted_line);
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return result;
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}
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bool subghz_keystore_load(SubGhzKeystore* instance, const char* file_name) {
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furi_assert(instance);
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bool result = false;
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uint8_t iv[16];
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uint32_t version;
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SubGhzKeystoreEncryption encryption;
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string_t filetype;
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string_init(filetype);
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Storage* storage = furi_record_open("storage");
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FlipperFile* flipper_file = flipper_file_alloc(storage);
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do {
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if(!flipper_file_open_read(flipper_file, file_name)) {
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FURI_LOG_E(SUBGHZ_KEYSTORE_TAG, "Unable to open file for read: %s", file_name);
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break;
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}
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if(!flipper_file_read_header(flipper_file, filetype, &version)) {
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FURI_LOG_E(SUBGHZ_KEYSTORE_TAG, "Missing or incorrect header");
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break;
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}
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if(!flipper_file_read_uint32(flipper_file, "Encryption", (uint32_t*)&encryption)) {
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FURI_LOG_E(SUBGHZ_KEYSTORE_TAG, "Missing encryption type");
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break;
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}
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if (strcmp(string_get_cstr(filetype), SUBGHZ_KEYSTORE_FILE_TYPE) != 0
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|| version != SUBGHZ_KEYSTORE_FILE_VERSION) {
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FURI_LOG_E(SUBGHZ_KEYSTORE_TAG, "Type or version mismatch");
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break;
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}
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File* file = flipper_file_get_file(flipper_file);
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if (encryption == SubGhzKeystoreEncryptionNone) {
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result = subghz_keystore_read_file(instance, file, NULL);
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}else if (encryption == SubGhzKeystoreEncryptionAES256) {
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if(!flipper_file_read_hex_array(flipper_file, "IV", iv, 16)) {
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FURI_LOG_E(SUBGHZ_KEYSTORE_TAG, "Missing IV");
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break;
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}
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subghz_keystore_mess_with_iv(iv);
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result = subghz_keystore_read_file(instance, file, iv);
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} else {
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FURI_LOG_E(SUBGHZ_KEYSTORE_TAG, "Unknown encryption");
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break;
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}
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} while(0);
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flipper_file_close(flipper_file);
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flipper_file_free(flipper_file);
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furi_record_close("storage");
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string_clear(filetype);
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return result;
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}
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bool subghz_keystore_save(SubGhzKeystore* instance, const char* file_name, uint8_t* iv) {
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furi_assert(instance);
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bool result = false;
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Storage* storage = furi_record_open("storage");
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char* decrypted_line = furi_alloc(SUBGHZ_KEYSTORE_FILE_DECRYPTED_LINE_SIZE);
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char* encrypted_line = furi_alloc(SUBGHZ_KEYSTORE_FILE_ENCRYPTED_LINE_SIZE);
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FlipperFile* flipper_file = flipper_file_alloc(storage);
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do {
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if(!flipper_file_new_write(flipper_file, file_name)) {
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FURI_LOG_E(SUBGHZ_KEYSTORE_TAG, "Unable to open file for write: %s", file_name);
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break;
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}
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if(!flipper_file_write_header_cstr(flipper_file, SUBGHZ_KEYSTORE_FILE_TYPE, SUBGHZ_KEYSTORE_FILE_VERSION)) {
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FURI_LOG_E(SUBGHZ_KEYSTORE_TAG, "Unable to add header");
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break;
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}
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if(!flipper_file_write_uint32(flipper_file, "Encryption", SubGhzKeystoreEncryptionAES256)) {
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FURI_LOG_E(SUBGHZ_KEYSTORE_TAG, "Unable to add Encryption");
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break;
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}
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if(!flipper_file_write_hex_array(flipper_file, "IV", iv, 16)) {
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FURI_LOG_E(SUBGHZ_KEYSTORE_TAG, "Unable to add IV");
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break;
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}
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subghz_keystore_mess_with_iv(iv);
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if(!furi_hal_crypto_store_load_key(SUBGHZ_KEYSTORE_FILE_ENCRYPTION_KEY_SLOT, iv)) {
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FURI_LOG_E(SUBGHZ_KEYSTORE_TAG, "Unable to load encryption key");
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break;
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}
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File* file = flipper_file_get_file(flipper_file);
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size_t encrypted_line_count = 0;
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for
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M_EACH(
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key,
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instance->data,
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SubGhzKeyArray_t) {
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// Wipe buffer before packing
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memset(decrypted_line, 0, SUBGHZ_KEYSTORE_FILE_DECRYPTED_LINE_SIZE);
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memset(encrypted_line, 0, SUBGHZ_KEYSTORE_FILE_ENCRYPTED_LINE_SIZE);
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// Form unecreypted line
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int len = snprintf(
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decrypted_line, SUBGHZ_KEYSTORE_FILE_DECRYPTED_LINE_SIZE,
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"%08lX%08lX:%hu:%s",
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(uint32_t)(key->key>>32), (uint32_t)key->key, key->type, string_get_cstr(key->name));
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// Verify length and align
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furi_assert(len > 0);
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if (len % 16 != 0) {
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len += (16 - len % 16);
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}
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furi_assert(len % 16 == 0);
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furi_assert(len <= SUBGHZ_KEYSTORE_FILE_DECRYPTED_LINE_SIZE);
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// Form encrypted line
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if(!furi_hal_crypto_encrypt((uint8_t*)decrypted_line, (uint8_t*)encrypted_line, len)) {
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FURI_LOG_E(SUBGHZ_KEYSTORE_TAG, "Encryption failed");
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break;
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}
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// HEX Encode encrypted line
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const char xx[]= "0123456789ABCDEF";
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for (size_t i=0; i<len; i++) {
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size_t cursor = len - i - 1;
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size_t hex_cursor = len*2 - i*2 - 1;
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encrypted_line[hex_cursor] = xx[encrypted_line[cursor] & 0xF];
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encrypted_line[hex_cursor-1] = xx[(encrypted_line[cursor]>>4) & 0xF];
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}
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storage_file_write(file, encrypted_line, strlen(encrypted_line));
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storage_file_write(file, "\n", 1);
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encrypted_line_count++;
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FURI_LOG_I(SUBGHZ_KEYSTORE_TAG, "Encrypted: `%s` -> `%s`", decrypted_line, encrypted_line);
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}
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furi_hal_crypto_store_unload_key(SUBGHZ_KEYSTORE_FILE_ENCRYPTION_KEY_SLOT);
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result = encrypted_line_count == SubGhzKeyArray_size(instance->data);
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} while(0);
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flipper_file_close(flipper_file);
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flipper_file_free(flipper_file);
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free(encrypted_line);
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free(decrypted_line);
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furi_record_close("storage");
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return result;
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}
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SubGhzKeyArray_t* subghz_keystore_get_data(SubGhzKeystore* instance) {
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furi_assert(instance);
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return &instance->data;
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}
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