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@ -70,10 +70,10 @@ bool IsAmiiboValid(const EncryptedNTAG215File& ntag_file) {
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NTAG215File NfcDataToEncodedData(const EncryptedNTAG215File& nfc_data) {
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NTAG215File encoded_data{};
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memcpy(encoded_data.uuid2.data(), nfc_data.uuid.data() + 0x8, 2);
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memcpy(encoded_data.uuid2.data(), nfc_data.uuid.data() + 0x8, sizeof(encoded_data.uuid2));
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encoded_data.static_lock = nfc_data.static_lock;
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encoded_data.compability_container = nfc_data.compability_container;
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encoded_data.unfixed_hash = nfc_data.user_memory.unfixed_hash;
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encoded_data.hmac_data = nfc_data.user_memory.hmac_data;
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encoded_data.constant_value = nfc_data.user_memory.constant_value;
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encoded_data.write_counter = nfc_data.user_memory.write_counter;
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encoded_data.settings = nfc_data.user_memory.settings;
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@ -84,8 +84,8 @@ NTAG215File NfcDataToEncodedData(const EncryptedNTAG215File& nfc_data) {
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encoded_data.unknown = nfc_data.user_memory.unknown;
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encoded_data.hash = nfc_data.user_memory.hash;
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encoded_data.application_area = nfc_data.user_memory.application_area;
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encoded_data.locked_hash = nfc_data.user_memory.locked_hash;
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memcpy(encoded_data.uuid.data(), nfc_data.uuid.data(), 8);
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encoded_data.hmac_tag = nfc_data.user_memory.hmac_tag;
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memcpy(encoded_data.uuid.data(), nfc_data.uuid.data(), sizeof(encoded_data.uuid));
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encoded_data.model_info = nfc_data.user_memory.model_info;
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encoded_data.keygen_salt = nfc_data.user_memory.keygen_salt;
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encoded_data.dynamic_lock = nfc_data.dynamic_lock;
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@ -99,11 +99,11 @@ NTAG215File NfcDataToEncodedData(const EncryptedNTAG215File& nfc_data) {
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EncryptedNTAG215File EncodedDataToNfcData(const NTAG215File& encoded_data) {
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EncryptedNTAG215File nfc_data{};
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memcpy(nfc_data.uuid.data() + 0x8, encoded_data.uuid2.data(), 2);
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memcpy(nfc_data.uuid.data(), encoded_data.uuid.data(), 8);
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memcpy(nfc_data.uuid.data() + 0x8, encoded_data.uuid2.data(), sizeof(encoded_data.uuid2));
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memcpy(nfc_data.uuid.data(), encoded_data.uuid.data(), sizeof(encoded_data.uuid));
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nfc_data.static_lock = encoded_data.static_lock;
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nfc_data.compability_container = encoded_data.compability_container;
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nfc_data.user_memory.unfixed_hash = encoded_data.unfixed_hash;
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nfc_data.user_memory.hmac_data = encoded_data.hmac_data;
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nfc_data.user_memory.constant_value = encoded_data.constant_value;
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nfc_data.user_memory.write_counter = encoded_data.write_counter;
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nfc_data.user_memory.settings = encoded_data.settings;
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@ -114,7 +114,7 @@ EncryptedNTAG215File EncodedDataToNfcData(const NTAG215File& encoded_data) {
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nfc_data.user_memory.unknown = encoded_data.unknown;
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nfc_data.user_memory.hash = encoded_data.hash;
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nfc_data.user_memory.application_area = encoded_data.application_area;
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nfc_data.user_memory.locked_hash = encoded_data.locked_hash;
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nfc_data.user_memory.hmac_tag = encoded_data.hmac_tag;
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nfc_data.user_memory.model_info = encoded_data.model_info;
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nfc_data.user_memory.keygen_salt = encoded_data.keygen_salt;
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nfc_data.dynamic_lock = encoded_data.dynamic_lock;
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@ -136,60 +136,53 @@ u32 GetTagPassword(const TagUuid& uuid) {
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HashSeed GetSeed(const NTAG215File& data) {
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HashSeed seed{
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.data =
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{
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.magic = data.write_counter,
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.padding = {},
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.uuid1 = {},
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.uuid2 = {},
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.keygen_salt = data.keygen_salt,
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},
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};
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// Copy the first 8 bytes of uuid
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memcpy(seed.data.uuid1.data(), data.uuid.data(), sizeof(seed.data.uuid1));
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memcpy(seed.data.uuid2.data(), data.uuid.data(), sizeof(seed.data.uuid2));
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memcpy(seed.uuid1.data(), data.uuid.data(), sizeof(seed.uuid1));
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memcpy(seed.uuid2.data(), data.uuid.data(), sizeof(seed.uuid2));
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return seed;
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}
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void PreGenerateKey(const InternalKey& key, const HashSeed& seed, u8* output,
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std::size_t& outputLen) {
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std::size_t index = 0;
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std::vector<u8> GenerateInternalKey(const InternalKey& key, const HashSeed& seed) {
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const std::size_t seedPart1Len = sizeof(key.magic_bytes) - key.magic_length;
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const std::size_t string_size = key.type_string.size();
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std::vector<u8> output(string_size + seedPart1Len);
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// Copy whole type string
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memccpy(output + index, key.type_string.data(), '\0', key.type_string.size());
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index += key.type_string.size();
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memccpy(output.data(), key.type_string.data(), '\0', string_size);
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// Append (16 - magic_length) from the input seed
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std::size_t seedPart1Len = 16 - key.magic_length;
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memcpy(output + index, &seed, seedPart1Len);
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index += seedPart1Len;
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memcpy(output.data() + string_size, &seed, seedPart1Len);
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// Append all bytes from magicBytes
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memcpy(output + index, &key.magic_bytes, key.magic_length);
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index += key.magic_length;
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output.insert(output.end(), key.magic_bytes.begin(),
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key.magic_bytes.begin() + key.magic_length);
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// Seed 16 bytes at +0x10
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memcpy(output + index, &seed.raw[0x10], 16);
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index += 16;
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output.insert(output.end(), seed.uuid1.begin(), seed.uuid1.end());
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output.insert(output.end(), seed.uuid2.begin(), seed.uuid2.end());
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// 32 bytes at +0x20 from input seed xored with xor pad
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for (std::size_t i = 0; i < 32; i++)
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output[index + i] = seed.raw[i + 32] ^ key.xor_pad[i];
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index += 32;
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for (std::size_t i = 0; i < sizeof(seed.keygen_salt); i++) {
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output.emplace_back(static_cast<u8>(seed.keygen_salt[i] ^ key.xor_pad[i]));
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}
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outputLen = index;
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return output;
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}
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void CryptoInit(CryptoCtx& ctx, mbedtls_md_context_t& hmac_ctx, const HmacKey& hmac_key,
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const u8* seed, std::size_t seed_size) {
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const std::vector<u8>& seed) {
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// Initialize context
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ctx.used = false;
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ctx.counter = 0;
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ctx.buffer_size = sizeof(ctx.counter) + seed_size;
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memcpy(ctx.buffer.data() + sizeof(u16), seed, seed_size);
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ctx.buffer_size = sizeof(ctx.counter) + seed.size();
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memcpy(ctx.buffer.data() + sizeof(u16), seed.data(), seed.size());
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// Initialize HMAC context
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mbedtls_md_init(&hmac_ctx);
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@ -217,18 +210,15 @@ void CryptoStep(CryptoCtx& ctx, mbedtls_md_context_t& hmac_ctx, DrgbOutput& outp
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}
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DerivedKeys GenerateKey(const InternalKey& key, const NTAG215File& data) {
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constexpr std::size_t OUTPUT_SIZE = 512;
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const auto seed = GetSeed(data);
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// Generate internal seed
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u8 internal_key[OUTPUT_SIZE];
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std::size_t internal_key_lenght = 0;
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PreGenerateKey(key, seed, internal_key, internal_key_lenght);
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const std::vector<u8> internal_key = GenerateInternalKey(key, seed);
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// Initialize context
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CryptoCtx ctx{};
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mbedtls_md_context_t hmac_ctx;
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CryptoInit(ctx, hmac_ctx, key.hmac_key, internal_key, internal_key_lenght);
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CryptoInit(ctx, hmac_ctx, key.hmac_key, internal_key);
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// Generate derived keys
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DerivedKeys derived_keys{};
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@ -246,27 +236,34 @@ DerivedKeys GenerateKey(const InternalKey& key, const NTAG215File& data) {
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void Cipher(const DerivedKeys& keys, const NTAG215File& in_data, NTAG215File& out_data) {
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mbedtls_aes_context aes;
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std::size_t nc_off = 0;
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std::array<u8, 0x10> nonce_counter{};
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std::array<u8, 0x10> stream_block{};
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std::array<u8, sizeof(keys.aes_iv)> nonce_counter{};
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std::array<u8, sizeof(keys.aes_iv)> stream_block{};
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mbedtls_aes_setkey_enc(&aes, keys.aes_key.data(), 128);
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memcpy(nonce_counter.data(), keys.aes_iv.data(), sizeof(nonce_counter));
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const auto aes_key_size = static_cast<u32>(keys.aes_key.size() * 8);
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mbedtls_aes_setkey_enc(&aes, keys.aes_key.data(), aes_key_size);
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memcpy(nonce_counter.data(), keys.aes_iv.data(), sizeof(keys.aes_iv));
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std::array<u8, sizeof(NTAG215File)> in_data_byes{};
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std::array<u8, sizeof(NTAG215File)> out_data_bytes{};
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memcpy(in_data_byes.data(), &in_data, sizeof(NTAG215File));
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memcpy(out_data_bytes.data(), &out_data, sizeof(NTAG215File));
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constexpr std::size_t encrypted_data_size = HMAC_TAG_START - SETTINGS_START;
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mbedtls_aes_crypt_ctr(&aes, encrypted_data_size, &nc_off, nonce_counter.data(),
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stream_block.data(),
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reinterpret_cast<const unsigned char*>(&in_data.settings),
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reinterpret_cast<unsigned char*>(&out_data.settings));
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mbedtls_aes_crypt_ctr(&aes, 0x188, &nc_off, nonce_counter.data(), stream_block.data(),
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in_data_byes.data() + 0x2c, out_data_bytes.data() + 0x2c);
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// Copy the rest of the data directly
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out_data.uuid2 = in_data.uuid2;
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out_data.static_lock = in_data.static_lock;
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out_data.compability_container = in_data.compability_container;
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memcpy(out_data_bytes.data(), in_data_byes.data(), 0x008);
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// Data signature NOT copied
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memcpy(out_data_bytes.data() + 0x028, in_data_byes.data() + 0x028, 0x004);
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// Tag signature NOT copied
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memcpy(out_data_bytes.data() + 0x1D4, in_data_byes.data() + 0x1D4, 0x048);
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out_data.constant_value = in_data.constant_value;
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out_data.write_counter = in_data.write_counter;
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memcpy(&out_data, out_data_bytes.data(), sizeof(NTAG215File));
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out_data.uuid = in_data.uuid;
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out_data.model_info = in_data.model_info;
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out_data.keygen_salt = in_data.keygen_salt;
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out_data.dynamic_lock = in_data.dynamic_lock;
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out_data.CFG0 = in_data.CFG0;
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out_data.CFG1 = in_data.CFG1;
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out_data.password = in_data.password;
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}
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bool LoadKeys(InternalKey& locked_secret, InternalKey& unfixed_info) {
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@ -309,26 +306,26 @@ bool DecodeAmiibo(const EncryptedNTAG215File& encrypted_tag_data, NTAG215File& t
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// Decrypt
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Cipher(data_keys, encoded_data, tag_data);
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std::array<u8, sizeof(NTAG215File)> out{};
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memcpy(out.data(), &tag_data, sizeof(NTAG215File));
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// Regenerate tag HMAC. Note: order matters, data HMAC depends on tag HMAC!
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constexpr std::size_t input_length = DYNAMIC_LOCK_START - UUID_START;
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mbedtls_md_hmac(mbedtls_md_info_from_type(MBEDTLS_MD_SHA256), tag_keys.hmac_key.data(),
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sizeof(HmacKey), out.data() + 0x1D4, 0x34, out.data() + HMAC_POS_TAG);
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sizeof(HmacKey), reinterpret_cast<const unsigned char*>(&tag_data.uuid),
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input_length, reinterpret_cast<unsigned char*>(&tag_data.hmac_tag));
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// Regenerate data HMAC
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constexpr std::size_t input_length2 = DYNAMIC_LOCK_START - WRITE_COUNTER_START;
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mbedtls_md_hmac(mbedtls_md_info_from_type(MBEDTLS_MD_SHA256), data_keys.hmac_key.data(),
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sizeof(HmacKey), out.data() + 0x29, 0x1DF, out.data() + HMAC_POS_DATA);
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sizeof(HmacKey),
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reinterpret_cast<const unsigned char*>(&tag_data.write_counter), input_length2,
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reinterpret_cast<unsigned char*>(&tag_data.hmac_data));
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memcpy(&tag_data, out.data(), sizeof(NTAG215File));
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if (memcmp(tag_data.unfixed_hash.data(), encrypted_tag_data.user_memory.unfixed_hash.data(),
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32) != 0) {
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if (tag_data.hmac_data != encrypted_tag_data.user_memory.hmac_data) {
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LOG_ERROR(Service_NFP, "hmac_data doesn't match");
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return false;
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}
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if (memcmp(tag_data.locked_hash.data(), encrypted_tag_data.user_memory.locked_hash.data(),
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32) != 0) {
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if (tag_data.hmac_tag != encrypted_tag_data.user_memory.hmac_tag) {
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LOG_ERROR(Service_NFP, "hmac_tag doesn't match");
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return false;
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}
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@ -347,13 +344,14 @@ bool EncodeAmiibo(const NTAG215File& tag_data, EncryptedNTAG215File& encrypted_t
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const auto data_keys = GenerateKey(unfixed_info, tag_data);
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const auto tag_keys = GenerateKey(locked_secret, tag_data);
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std::array<u8, sizeof(NTAG215File)> plain{};
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std::array<u8, sizeof(NTAG215File)> cipher{};
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memcpy(plain.data(), &tag_data, sizeof(NTAG215File));
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NTAG215File encoded_tag_data{};
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// Generate tag HMAC
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constexpr std::size_t input_length = DYNAMIC_LOCK_START - UUID_START;
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constexpr std::size_t input_length2 = HMAC_TAG_START - WRITE_COUNTER_START;
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mbedtls_md_hmac(mbedtls_md_info_from_type(MBEDTLS_MD_SHA256), tag_keys.hmac_key.data(),
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sizeof(HmacKey), plain.data() + 0x1D4, 0x34, cipher.data() + HMAC_POS_TAG);
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sizeof(HmacKey), reinterpret_cast<const unsigned char*>(&tag_data.uuid),
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input_length, reinterpret_cast<unsigned char*>(&encoded_tag_data.hmac_tag));
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// Init mbedtls HMAC context
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mbedtls_md_context_t ctx;
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@ -362,17 +360,18 @@ bool EncodeAmiibo(const NTAG215File& tag_data, EncryptedNTAG215File& encrypted_t
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// Generate data HMAC
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mbedtls_md_hmac_starts(&ctx, data_keys.hmac_key.data(), sizeof(HmacKey));
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mbedtls_md_hmac_update(&ctx, plain.data() + 0x029, 0x18B); // Data
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mbedtls_md_hmac_update(&ctx, cipher.data() + HMAC_POS_TAG, 0x20); // Tag HMAC
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mbedtls_md_hmac_update(&ctx, plain.data() + 0x1D4, 0x34);
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mbedtls_md_hmac_finish(&ctx, cipher.data() + HMAC_POS_DATA);
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mbedtls_md_hmac_update(&ctx, reinterpret_cast<const unsigned char*>(&tag_data.write_counter),
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input_length2); // Data
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mbedtls_md_hmac_update(&ctx, reinterpret_cast<unsigned char*>(&encoded_tag_data.hmac_tag),
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sizeof(HashData)); // Tag HMAC
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mbedtls_md_hmac_update(&ctx, reinterpret_cast<const unsigned char*>(&tag_data.uuid),
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input_length);
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mbedtls_md_hmac_finish(&ctx, reinterpret_cast<unsigned char*>(&encoded_tag_data.hmac_data));
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// HMAC cleanup
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mbedtls_md_free(&ctx);
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// Encrypt
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NTAG215File encoded_tag_data{};
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memcpy(&encoded_tag_data, cipher.data(), sizeof(NTAG215File));
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Cipher(data_keys, tag_data, encoded_tag_data);
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// Convert back to hardware
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