// Copyright (c) 2017-2020, The Monero Project // // All rights reserved. // // Redistribution and use in source and binary forms, with or without modification, are // permitted provided that the following conditions are met: // // 1. Redistributions of source code must retain the above copyright notice, this list of // conditions and the following disclaimer. // // 2. Redistributions in binary form must reproduce the above copyright notice, this list // of conditions and the following disclaimer in the documentation and/or other // materials provided with the distribution. // // 3. Neither the name of the copyright holder nor the names of its contributors may be // used to endorse or promote products derived from this software without specific // prior written permission. // // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY // EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF // MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL // THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, // SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, // PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS // INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, // STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF // THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. // #ifndef MONERO_PROTOCOL_H #define MONERO_PROTOCOL_H #include "trezor_defs.hpp" #include "device/device_cold.hpp" #include "messages_map.hpp" #include "transport.hpp" #include "wallet/wallet2.h" namespace hw{ namespace trezor{ namespace protocol{ std::string key_to_string(const ::crypto::ec_point & key); std::string key_to_string(const ::crypto::ec_scalar & key); std::string key_to_string(const ::crypto::hash & key); std::string key_to_string(const ::rct::key & key); void string_to_key(::crypto::ec_scalar & key, const std::string & str); void string_to_key(::crypto::ec_point & key, const std::string & str); void string_to_key(::rct::key & key, const std::string & str); template void assign_to_repeatable(::google::protobuf::RepeatedField * dst, const InputIterator begin, const InputIterator end){ for (InputIterator it = begin; it != end; it++) { auto s = dst->Add(); *s = *it; } } template void assign_from_repeatable(std::vector * dst, const InputIterator begin, const InputIterator end){ for (InputIterator it = begin; it != end; it++) { dst->push_back(*it); } }; template bool cn_deserialize(const void * buff, size_t len, T & dst){ binary_archive ba{{reinterpret_cast(buff), len}}; bool r = ::serialization::serialize(ba, dst); return r; } template bool cn_deserialize(const std::string & str, T & dst){ return cn_deserialize(str.data(), str.size(), dst); } template std::string cn_serialize(T & obj){ std::ostringstream oss; binary_archive oar(oss); bool success = ::serialization::serialize(oar, obj); if (!success){ throw exc::EncodingException("Could not CN serialize given object"); } return oss.str(); } // Crypto / encryption namespace crypto { namespace chacha { // Constants as defined in RFC 7539. const unsigned IV_SIZE = 12; const unsigned TAG_SIZE = 16; // crypto_aead_chacha20poly1305_IETF_ABYTES; /** * Chacha20Poly1305 decryption with tag verification. RFC 7539. */ void decrypt(const void* ciphertext, size_t length, const uint8_t* key, const uint8_t* iv, char* plaintext, size_t *plaintext_len=nullptr); } } // Cold Key image sync namespace ki { using MoneroTransferDetails = messages::monero::MoneroKeyImageSyncStepRequest_MoneroTransferDetails; using MoneroSubAddressIndicesList = messages::monero::MoneroKeyImageExportInitRequest_MoneroSubAddressIndicesList; using MoneroExportedKeyImage = messages::monero::MoneroKeyImageSyncStepAck_MoneroExportedKeyImage; using exported_key_image = hw::device_cold::exported_key_image; /** * Converts transfer details to the MoneroTransferDetails required for KI sync */ bool key_image_data(wallet_shim * wallet, const std::vector & transfers, std::vector & res, bool need_all_additionals=false); /** * Computes a hash over MoneroTransferDetails. Commitment used in the KI sync. */ std::string compute_hash(const MoneroTransferDetails & rr); /** * Generates KI sync request with commitments computed. */ void generate_commitment(std::vector & mtds, const std::vector & transfers, std::shared_ptr & req, bool need_subaddr_indices=false); /** * Processes Live refresh step response, parses KI, checks the signature */ void live_refresh_ack(const ::crypto::secret_key & view_key_priv, const ::crypto::public_key& out_key, const std::shared_ptr & ack, ::cryptonote::keypair& in_ephemeral, ::crypto::key_image& ki); } // Cold transaction signing namespace tx { using TsxData = messages::monero::MoneroTransactionInitRequest_MoneroTransactionData; using MoneroTransactionDestinationEntry = messages::monero::MoneroTransactionDestinationEntry; using MoneroAccountPublicAddress = messages::monero::MoneroTransactionDestinationEntry_MoneroAccountPublicAddress; using MoneroTransactionSourceEntry = messages::monero::MoneroTransactionSourceEntry; using MoneroMultisigKLRki = messages::monero::MoneroTransactionSourceEntry_MoneroMultisigKLRki; using MoneroOutputEntry = messages::monero::MoneroTransactionSourceEntry_MoneroOutputEntry; using MoneroRctKey = messages::monero::MoneroTransactionSourceEntry_MoneroOutputEntry_MoneroRctKeyPublic; using MoneroRsigData = messages::monero::MoneroTransactionRsigData; using tx_construction_data = tools::wallet2::tx_construction_data; using unsigned_tx_set = tools::wallet2::unsigned_tx_set; void translate_address(MoneroAccountPublicAddress * dst, const cryptonote::account_public_address * src); void translate_dst_entry(MoneroTransactionDestinationEntry * dst, const cryptonote::tx_destination_entry * src); void translate_klrki(MoneroMultisigKLRki * dst, const rct::multisig_kLRki * src); void translate_rct_key(MoneroRctKey * dst, const rct::ctkey * src); std::string hash_addr(const MoneroAccountPublicAddress * addr, boost::optional amount = boost::none, boost::optional is_subaddr = boost::none); std::string hash_addr(const std::string & spend_key, const std::string & view_key, boost::optional amount = boost::none, boost::optional is_subaddr = boost::none); std::string hash_addr(const ::crypto::public_key * spend_key, const ::crypto::public_key * view_key, boost::optional amount = boost::none, boost::optional is_subaddr = boost::none); ::crypto::secret_key compute_enc_key(const ::crypto::secret_key & private_view_key, const std::string & aux, const std::string & salt); std::string compute_sealing_key(const std::string & master_key, size_t idx, bool is_iv=false); typedef boost::variant rsig_v; /** * Transaction signer state holder. */ class TData { public: TsxData tsx_data; tx_construction_data tx_data; cryptonote::transaction tx; unsigned rsig_type; int bp_version; std::vector grouping_vct; std::shared_ptr rsig_param; size_t cur_input_idx; size_t cur_output_idx; size_t cur_batch_idx; size_t cur_output_in_batch_idx; std::vector tx_in_hmacs; std::vector tx_out_entr_hmacs; std::vector tx_out_hmacs; std::vector tx_out_rsigs; std::vector tx_out_pk; std::vector tx_out_ecdh; std::vector source_permutation; std::vector alphas; std::vector spend_encs; std::vector pseudo_outs; std::vector pseudo_outs_hmac; std::vector couts; std::vector couts_dec; std::vector signatures; std::vector rsig_gamma; std::string tx_prefix_hash; std::string enc_salt1; std::string enc_salt2; std::string enc_keys; std::shared_ptr rv; TData(); }; class Signer { private: TData m_ct; wallet_shim * m_wallet2; size_t m_tx_idx; const unsigned_tx_set * m_unsigned_tx; hw::tx_aux_data * m_aux_data; unsigned m_client_version; bool m_multisig; const tx_construction_data & cur_src_tx() const { CHECK_AND_ASSERT_THROW_MES(m_tx_idx < m_unsigned_tx->txes.size(), "Invalid transaction index"); return m_unsigned_tx->txes[m_tx_idx]; } const tx_construction_data & cur_tx() const { return m_ct.tx_data; } const tools::wallet2::transfer_details & get_transfer(size_t idx) const { CHECK_AND_ASSERT_THROW_MES(idx < m_unsigned_tx->transfers.second.size() + m_unsigned_tx->transfers.first && idx >= m_unsigned_tx->transfers.first, "Invalid transfer index"); return m_unsigned_tx->transfers.second[idx - m_unsigned_tx->transfers.first]; } const tools::wallet2::transfer_details & get_source_transfer(size_t idx) const { const auto & sel_transfers = cur_tx().selected_transfers; CHECK_AND_ASSERT_THROW_MES(idx < m_ct.source_permutation.size(), "Invalid source index - permutation"); CHECK_AND_ASSERT_THROW_MES(m_ct.source_permutation[idx] < sel_transfers.size(), "Invalid source index"); return get_transfer(sel_transfers.at(m_ct.source_permutation[idx])); } void extract_payment_id(); void compute_integrated_indices(TsxData * tsx_data); bool should_compute_bp_now() const; void compute_bproof(messages::monero::MoneroTransactionRsigData & rsig_data); void process_bproof(rct::Bulletproof & bproof); void set_tx_input(MoneroTransactionSourceEntry * dst, size_t idx, bool need_ring_keys=false, bool need_ring_indices=false); public: Signer(wallet_shim * wallet2, const unsigned_tx_set * unsigned_tx, size_t tx_idx = 0, hw::tx_aux_data * aux_data = nullptr); std::shared_ptr step_init(); void step_init_ack(std::shared_ptr ack); std::shared_ptr step_set_input(size_t idx); void step_set_input_ack(std::shared_ptr ack); void sort_ki(); std::shared_ptr step_permutation(); void step_permutation_ack(std::shared_ptr ack); std::shared_ptr step_set_vini_input(size_t idx); void step_set_vini_input_ack(std::shared_ptr ack); std::shared_ptr step_all_inputs_set(); void step_all_inputs_set_ack(std::shared_ptr ack); std::shared_ptr step_set_output(size_t idx); void step_set_output_ack(std::shared_ptr ack); std::shared_ptr step_rsig(size_t idx); void step_set_rsig_ack(std::shared_ptr ack); std::shared_ptr step_all_outs_set(); void step_all_outs_set_ack(std::shared_ptr ack, hw::device &hwdev); std::shared_ptr step_sign_input(size_t idx); void step_sign_input_ack(std::shared_ptr ack); std::shared_ptr step_final(); void step_final_ack(std::shared_ptr ack); std::string store_tx_aux_info(); unsigned client_version() const { return m_client_version; } bool is_simple() const { if (!m_ct.rv){ throw std::invalid_argument("RV not initialized"); } auto tp = m_ct.rv->type; return tp == rct::RCTTypeSimple; } bool is_req_bulletproof() const { return m_ct.tx_data.rct_config.range_proof_type != rct::RangeProofBorromean; } bool is_bulletproof() const { if (!m_ct.rv){ throw std::invalid_argument("RV not initialized"); } auto tp = m_ct.rv->type; return tp == rct::RCTTypeBulletproof || tp == rct::RCTTypeBulletproof2 || tp == rct::RCTTypeCLSAG; } bool is_offloading() const { return m_ct.rsig_param && m_ct.rsig_param->offload_type() != 0; } size_t num_outputs() const { return m_ct.tx_data.splitted_dsts.size(); } size_t num_inputs() const { return m_ct.tx_data.sources.size(); } const TData & tdata() const { return m_ct; } }; // TX Key decryption void load_tx_key_data(hw::device_cold::tx_key_data_t & res, const std::string & data); std::shared_ptr get_tx_key( const hw::device_cold::tx_key_data_t & tx_data); void get_tx_key_ack( std::vector<::crypto::secret_key> & tx_keys, const std::string & tx_prefix_hash, const ::crypto::secret_key & view_key_priv, std::shared_ptr ack ); } } } } #endif //MONERO_PROTOCOL_H