mirror of
https://github.com/trezor/trezor-firmware.git
synced 2024-11-27 01:48:17 +00:00
ce307c9484
[no changelog]
341 lines
11 KiB
C
341 lines
11 KiB
C
/*
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* This file is part of the Trezor project, https://trezor.io/
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*
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* Copyright (C) 2018 Pavol Rusnak <stick@satoshilabs.com>
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*
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* This library is free software: you can redistribute it and/or modify
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* it under the terms of the GNU Lesser General Public License as published by
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* the Free Software Foundation, either version 3 of the License, or
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* (at your option) any later version.
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*
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* This library is distributed in the hope that it will be useful,
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* but WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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* GNU Lesser General Public License for more details.
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*
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* You should have received a copy of the GNU Lesser General Public License
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* along with this library. If not, see <http://www.gnu.org/licenses/>.
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*/
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static uint8_t cosi_nonce[32] = {0};
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static uint8_t cosi_commitment[32] = {0};
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static bool cosi_nonce_is_set = false;
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void fsm_msgCipherKeyValue(const CipherKeyValue *msg) {
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CHECK_INITIALIZED
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CHECK_PARAM(msg->value.size % 16 == 0,
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_("Value length must be a multiple of 16"));
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CHECK_PIN
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const HDNode *node = fsm_getDerivedNode(SECP256K1_NAME, msg->address_n,
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msg->address_n_count, NULL);
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if (!node) return;
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bool encrypt = msg->has_encrypt && msg->encrypt;
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bool ask_on_encrypt = msg->has_ask_on_encrypt && msg->ask_on_encrypt;
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bool ask_on_decrypt = msg->has_ask_on_decrypt && msg->ask_on_decrypt;
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if ((encrypt && ask_on_encrypt) || (!encrypt && ask_on_decrypt)) {
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layoutCipherKeyValue(encrypt, msg->key);
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if (!protectButton(ButtonRequestType_ButtonRequest_Other, false)) {
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fsm_sendFailure(FailureType_Failure_ActionCancelled, NULL);
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layoutHome();
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return;
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}
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}
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uint8_t data[256 + 4];
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strlcpy((char *)data, msg->key, sizeof(data));
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strlcat((char *)data, ask_on_encrypt ? "E1" : "E0", sizeof(data));
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strlcat((char *)data, ask_on_decrypt ? "D1" : "D0", sizeof(data));
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hmac_sha512(node->private_key, 32, data, strlen((char *)data), data);
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if (msg->iv.size == 16) {
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// override iv if provided
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memcpy(data + 32, msg->iv.bytes, 16);
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}
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RESP_INIT(CipheredKeyValue);
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if (encrypt) {
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aes_encrypt_ctx ctx;
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aes_encrypt_key256(data, &ctx);
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aes_cbc_encrypt(msg->value.bytes, resp->value.bytes, msg->value.size,
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data + 32, &ctx);
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} else {
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aes_decrypt_ctx ctx;
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aes_decrypt_key256(data, &ctx);
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aes_cbc_decrypt(msg->value.bytes, resp->value.bytes, msg->value.size,
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data + 32, &ctx);
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}
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resp->value.size = msg->value.size;
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msg_write(MessageType_MessageType_CipheredKeyValue, resp);
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layoutHome();
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}
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void fsm_msgSignIdentity(const SignIdentity *msg) {
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RESP_INIT(SignedIdentity);
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CHECK_INITIALIZED
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CHECK_PIN
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layoutSignIdentity(&(msg->identity),
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msg->has_challenge_visual ? msg->challenge_visual : 0);
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if (!protectButton(ButtonRequestType_ButtonRequest_ProtectCall, false)) {
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fsm_sendFailure(FailureType_Failure_ActionCancelled, NULL);
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layoutHome();
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return;
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}
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uint8_t hash[32];
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if (cryptoIdentityFingerprint(&(msg->identity), hash) == 0) {
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fsm_sendFailure(FailureType_Failure_DataError, _("Invalid identity"));
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layoutHome();
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return;
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}
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uint32_t address_n[5];
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address_n[0] = PATH_HARDENED | 13;
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address_n[1] = PATH_HARDENED | hash[0] | (hash[1] << 8) | (hash[2] << 16) |
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((uint32_t)hash[3] << 24);
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address_n[2] = PATH_HARDENED | hash[4] | (hash[5] << 8) | (hash[6] << 16) |
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((uint32_t)hash[7] << 24);
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address_n[3] = PATH_HARDENED | hash[8] | (hash[9] << 8) | (hash[10] << 16) |
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((uint32_t)hash[11] << 24);
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address_n[4] = PATH_HARDENED | hash[12] | (hash[13] << 8) | (hash[14] << 16) |
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((uint32_t)hash[15] << 24);
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const char *curve = SECP256K1_NAME;
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if (msg->has_ecdsa_curve_name) {
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curve = msg->ecdsa_curve_name;
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}
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HDNode *node = fsm_getDerivedNode(curve, address_n, 5, NULL);
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if (!node) return;
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bool sign_ssh =
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msg->identity.has_proto && (strcmp(msg->identity.proto, "ssh") == 0);
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bool sign_gpg =
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msg->identity.has_proto && (strcmp(msg->identity.proto, "gpg") == 0);
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bool sign_signify =
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msg->identity.has_proto && (strcmp(msg->identity.proto, "signify") == 0);
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int result = 0;
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layoutProgressSwipe(_("Signing"), 0);
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if (sign_ssh) { // SSH does not sign visual challenge
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result = sshMessageSign(node, msg->challenge_hidden.bytes,
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msg->challenge_hidden.size, resp->signature.bytes);
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} else if (sign_gpg) { // GPG should sign a message digest
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result = gpgMessageSign(node, msg->challenge_hidden.bytes,
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msg->challenge_hidden.size, resp->signature.bytes);
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} else if (sign_signify) { // Signify should sign a message digest
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result =
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signifyMessageSign(node, msg->challenge_hidden.bytes,
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msg->challenge_hidden.size, resp->signature.bytes);
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} else {
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uint8_t digest[64];
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sha256_Raw(msg->challenge_hidden.bytes, msg->challenge_hidden.size, digest);
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sha256_Raw((const uint8_t *)msg->challenge_visual,
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strlen(msg->challenge_visual), digest + 32);
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result = cryptoMessageSign(&(coins[0]), node, InputScriptType_SPENDADDRESS,
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false, digest, 64, resp->signature.bytes);
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}
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if (result == 0) {
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if (hdnode_fill_public_key(node) != 0) {
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fsm_sendFailure(FailureType_Failure_ProcessError,
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_("Failed to derive public key"));
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layoutHome();
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return;
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}
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if (strcmp(curve, SECP256K1_NAME) != 0) {
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resp->has_address = false;
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} else {
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resp->has_address = true;
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// hardcoded Bitcoin address type
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if (hdnode_get_address(node, 0x00, resp->address,
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sizeof(resp->address)) != 0) {
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fsm_sendFailure(FailureType_Failure_ProcessError,
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_("Failed to get address"));
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layoutHome();
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return;
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}
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}
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resp->public_key.size = 33;
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memcpy(resp->public_key.bytes, node->public_key, 33);
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if (node->public_key[0] == 1) {
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/* ed25519 public key */
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resp->public_key.bytes[0] = 0;
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}
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resp->signature.size = 65;
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msg_write(MessageType_MessageType_SignedIdentity, resp);
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} else {
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fsm_sendFailure(FailureType_Failure_ProcessError,
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_("Error signing identity"));
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}
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layoutHome();
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}
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void fsm_msgGetECDHSessionKey(const GetECDHSessionKey *msg) {
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RESP_INIT(ECDHSessionKey);
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CHECK_INITIALIZED
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CHECK_PIN
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layoutDecryptIdentity(&msg->identity);
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if (!protectButton(ButtonRequestType_ButtonRequest_ProtectCall, false)) {
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fsm_sendFailure(FailureType_Failure_ActionCancelled, NULL);
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layoutHome();
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return;
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}
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uint8_t hash[32];
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if (cryptoIdentityFingerprint(&(msg->identity), hash) == 0) {
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fsm_sendFailure(FailureType_Failure_DataError, _("Invalid identity"));
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layoutHome();
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return;
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}
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uint32_t address_n[5];
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address_n[0] = PATH_HARDENED | 17;
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address_n[1] = PATH_HARDENED | hash[0] | (hash[1] << 8) | (hash[2] << 16) |
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((uint32_t)hash[3] << 24);
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address_n[2] = PATH_HARDENED | hash[4] | (hash[5] << 8) | (hash[6] << 16) |
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((uint32_t)hash[7] << 24);
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address_n[3] = PATH_HARDENED | hash[8] | (hash[9] << 8) | (hash[10] << 16) |
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((uint32_t)hash[11] << 24);
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address_n[4] = PATH_HARDENED | hash[12] | (hash[13] << 8) | (hash[14] << 16) |
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((uint32_t)hash[15] << 24);
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const char *curve = SECP256K1_NAME;
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if (msg->has_ecdsa_curve_name) {
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curve = msg->ecdsa_curve_name;
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}
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HDNode *node = fsm_getDerivedNode(curve, address_n, 5, NULL);
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if (!node) return;
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int result_size = 0;
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if (hdnode_get_shared_key(node, msg->peer_public_key.bytes,
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resp->session_key.bytes, &result_size) == 0) {
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resp->session_key.size = result_size;
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if (hdnode_fill_public_key(node) != 0) {
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fsm_sendFailure(FailureType_Failure_ProcessError,
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_("Failed to derive public key"));
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layoutHome();
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return;
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}
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memcpy(resp->public_key.bytes, node->public_key, 33);
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resp->public_key.size = 33;
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resp->has_public_key = true;
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msg_write(MessageType_MessageType_ECDHSessionKey, resp);
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} else {
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fsm_sendFailure(FailureType_Failure_ProcessError,
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_("Error getting ECDH session key"));
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}
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layoutHome();
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}
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static bool fsm_checkCosiPath(uint32_t address_n_count,
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const uint32_t *address_n) {
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// The path should typically match "m / 10018' / [0-9]'", but we allow
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// any path from the SLIP-18 domain "m / 10018' / *".
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if (address_n_count >= 1 && address_n[0] == PATH_HARDENED + 10018) {
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return true;
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}
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if (config_getSafetyCheckLevel() == SafetyCheckLevel_Strict) {
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fsm_sendFailure(FailureType_Failure_DataError, _("Forbidden key path"));
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return false;
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}
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return fsm_layoutPathWarning();
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}
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void fsm_msgCosiCommit(const CosiCommit *msg) {
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RESP_INIT(CosiCommitment);
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CHECK_INITIALIZED
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CHECK_PIN
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if (!fsm_checkCosiPath(msg->address_n_count, msg->address_n)) {
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layoutHome();
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return;
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}
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const HDNode *node = fsm_getDerivedNode(ED25519_NAME, msg->address_n,
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msg->address_n_count, NULL);
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if (!node) return;
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if (!cosi_nonce_is_set) {
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ed25519_cosi_commit(cosi_nonce, cosi_commitment);
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cosi_nonce_is_set = true;
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}
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resp->commitment.size = 32;
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resp->pubkey.size = 32;
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memcpy(resp->commitment.bytes, cosi_commitment, sizeof(cosi_commitment));
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ed25519_publickey(node->private_key, resp->pubkey.bytes);
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msg_write(MessageType_MessageType_CosiCommitment, resp);
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layoutHome();
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}
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void fsm_msgCosiSign(const CosiSign *msg) {
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RESP_INIT(CosiSignature);
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CHECK_INITIALIZED
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CHECK_PARAM(msg->global_commitment.size == 32,
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_("Invalid global commitment"));
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CHECK_PARAM(msg->global_pubkey.size == 32, _("Invalid global pubkey"));
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if (!cosi_nonce_is_set) {
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fsm_sendFailure(FailureType_Failure_ProcessError, _("CoSi nonce not set"));
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layoutHome();
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return;
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}
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if (!fsm_checkCosiPath(msg->address_n_count, msg->address_n)) {
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layoutHome();
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return;
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}
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CHECK_PIN
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layoutCosiSign(msg->address_n, msg->address_n_count, msg->data.bytes,
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msg->data.size);
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if (!protectButton(ButtonRequestType_ButtonRequest_ProtectCall, false)) {
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fsm_sendFailure(FailureType_Failure_ActionCancelled, NULL);
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layoutHome();
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return;
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}
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const HDNode *node = fsm_getDerivedNode(ED25519_NAME, msg->address_n,
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msg->address_n_count, NULL);
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if (!node) return;
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resp->signature.size = 32;
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cosi_nonce_is_set = false;
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if (ed25519_cosi_sign(msg->data.bytes, msg->data.size, node->private_key,
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cosi_nonce, msg->global_commitment.bytes,
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msg->global_pubkey.bytes, resp->signature.bytes) == 0) {
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msg_write(MessageType_MessageType_CosiSignature, resp);
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} else {
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fsm_sendFailure(FailureType_Failure_FirmwareError, NULL);
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}
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fsm_clearCosiNonce();
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layoutHome();
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}
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void fsm_clearCosiNonce(void) {
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cosi_nonce_is_set = false;
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memzero(cosi_nonce, sizeof(cosi_nonce));
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}
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