// Copyright (c) 2018, 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. #include "message_store.h" #include #include #include #include #include #include #include "file_io_utils.h" #include "storages/http_abstract_invoke.h" #include "wallet_errors.h" #include "serialization/binary_utils.h" #include "common/base58.h" #include "common/util.h" #include "string_tools.h" #undef MONERO_DEFAULT_LOG_CATEGORY #define MONERO_DEFAULT_LOG_CATEGORY "wallet.mms" namespace mms { message_store::message_store() { m_active = false; m_auto_send = false; m_next_message_id = 1; m_num_authorized_signers = 0; m_num_required_signers = 0; m_nettype = cryptonote::network_type::UNDEFINED; m_run = true; } namespace { // MMS options handling mirrors what "wallet2" is doing for its options, on-demand init and all // It's not very clean to initialize Bitmessage-specific options here, but going one level further // down still into "message_transporter" for that is a little bit too much struct options { const command_line::arg_descriptor bitmessage_address = {"bitmessage-address", mms::message_store::tr("Use PyBitmessage instance at URL "), "http://localhost:8442/"}; const command_line::arg_descriptor bitmessage_login = {"bitmessage-login", mms::message_store::tr("Specify as username:password for PyBitmessage API"), "username:password"}; }; } void message_store::init_options(boost::program_options::options_description& desc_params) { const options opts{}; command_line::add_arg(desc_params, opts.bitmessage_address); command_line::add_arg(desc_params, opts.bitmessage_login); } void message_store::init(const multisig_wallet_state &state, const std::string &own_label, const std::string &own_transport_address, uint32_t num_authorized_signers, uint32_t num_required_signers) { m_num_authorized_signers = num_authorized_signers; m_num_required_signers = num_required_signers; m_signers.clear(); m_messages.clear(); m_next_message_id = 1; // The vector "m_signers" gets here once the required number of elements, one for each authorized signer, // and is never changed again. The rest of the code relies on "size(m_signers) == m_num_authorized_signers" // without further checks. authorized_signer signer; for (uint32_t i = 0; i < m_num_authorized_signers; ++i) { signer.me = signer.index == 0; // Strict convention: The very first signer is fixed as / must be "me" m_signers.push_back(signer); signer.index++; } set_signer(state, 0, own_label, own_transport_address, state.address); m_nettype = state.nettype; set_active(true); m_filename = state.mms_file; save(state); } void message_store::set_options(const boost::program_options::variables_map& vm) { const options opts{}; std::string bitmessage_address = command_line::get_arg(vm, opts.bitmessage_address); epee::wipeable_string bitmessage_login = command_line::get_arg(vm, opts.bitmessage_login); set_options(bitmessage_address, bitmessage_login); } void message_store::set_options(const std::string &bitmessage_address, const epee::wipeable_string &bitmessage_login) { m_transporter.set_options(bitmessage_address, bitmessage_login); } void message_store::set_signer(const multisig_wallet_state &state, uint32_t index, const boost::optional &label, const boost::optional &transport_address, const boost::optional monero_address) { THROW_WALLET_EXCEPTION_IF(index >= m_num_authorized_signers, tools::error::wallet_internal_error, "Invalid signer index " + std::to_string(index)); authorized_signer &m = m_signers[index]; if (label) { m.label = label.get(); } if (transport_address) { m.transport_address = transport_address.get(); } if (monero_address) { m.monero_address_known = true; m.monero_address = monero_address.get(); } // Save to minimize the chance to loose that info (at least while in beta) save(state); } const authorized_signer &message_store::get_signer(uint32_t index) const { THROW_WALLET_EXCEPTION_IF(index >= m_num_authorized_signers, tools::error::wallet_internal_error, "Invalid signer index " + std::to_string(index)); return m_signers[index]; } bool message_store::signer_config_complete() const { for (uint32_t i = 0; i < m_num_authorized_signers; ++i) { const authorized_signer &m = m_signers[i]; if (m.label.empty() || m.transport_address.empty() || !m.monero_address_known) { return false; } } return true; } // Check if all signers have a label set (as it's a requirement for starting auto-config // by the "manager") bool message_store::signer_labels_complete() const { for (uint32_t i = 0; i < m_num_authorized_signers; ++i) { const authorized_signer &m = m_signers[i]; if (m.label.empty()) { return false; } } return true; } void message_store::get_signer_config(std::string &signer_config) { std::stringstream oss; boost::archive::portable_binary_oarchive ar(oss); ar << m_signers; signer_config = oss.str(); } void message_store::unpack_signer_config(const multisig_wallet_state &state, const std::string &signer_config, std::vector &signers) { try { std::stringstream iss; iss << signer_config; boost::archive::portable_binary_iarchive ar(iss); ar >> signers; } catch (...) { THROW_WALLET_EXCEPTION_IF(true, tools::error::wallet_internal_error, "Invalid structure of signer config"); } uint32_t num_signers = (uint32_t)signers.size(); THROW_WALLET_EXCEPTION_IF(num_signers != m_num_authorized_signers, tools::error::wallet_internal_error, "Wrong number of signers in config: " + std::to_string(num_signers)); } void message_store::process_signer_config(const multisig_wallet_state &state, const std::string &signer_config) { // The signers in "signer_config" and the resident wallet signers are matched not by label, but // by Monero address, and ALL labels will be set from "signer_config", even the "me" label. // In the auto-config process as implemented now the auto-config manager is responsible for defining // the labels, and right at the end of the process ALL wallets use the SAME labels. The idea behind this // is preventing problems like duplicate labels and confusion (Bob choosing a label "IamAliceHonest"). // (Of course signers are free to re-define any labels they don't like AFTER auto-config.) // // Usually this method will be called with only the "me" signer defined in the wallet, and may // produce unexpected behaviour if that wallet contains additional signers that have nothing to do with // those arriving in "signer_config". std::vector signers; unpack_signer_config(state, signer_config, signers); uint32_t new_index = 1; for (uint32_t i = 0; i < m_num_authorized_signers; ++i) { const authorized_signer &m = signers[i]; uint32_t index; uint32_t take_index; bool found = get_signer_index_by_monero_address(m.monero_address, index); if (found) { // Redefine existing (probably "me", under usual circumstances) take_index = index; } else { // Add new; neglect that we may erroneously overwrite already defined signers // (but protect "me") take_index = new_index; if ((new_index + 1) < m_num_authorized_signers) { new_index++; } } authorized_signer &modify = m_signers[take_index]; modify.label = m.label; // ALWAYS set label, see comments above if (!modify.me) { modify.transport_address = m.transport_address; modify.monero_address_known = m.monero_address_known; if (m.monero_address_known) { modify.monero_address = m.monero_address; } } } save(state); } void message_store::start_auto_config(const multisig_wallet_state &state) { for (uint32_t i = 0; i < m_num_authorized_signers; ++i) { authorized_signer &m = m_signers[i]; if (!m.me) { setup_signer_for_auto_config(i, create_auto_config_token(), true); } m.auto_config_running = true; } save(state); } // Check auto-config token string and convert to standardized form; // Try to make it as foolproof as possible, with built-in tolerance to make up for // errors in transmission that still leave the token recognizable. bool message_store::check_auto_config_token(const std::string &raw_token, std::string &adjusted_token) const { std::string prefix(AUTO_CONFIG_TOKEN_PREFIX); uint32_t num_hex_digits = (AUTO_CONFIG_TOKEN_BYTES + 1) * 2; uint32_t full_length = num_hex_digits + prefix.length(); uint32_t raw_length = raw_token.length(); std::string hex_digits; if (raw_length == full_length) { // Prefix must be there; accept it in any casing std::string raw_prefix(raw_token.substr(0, 3)); boost::algorithm::to_lower(raw_prefix); if (raw_prefix != prefix) { return false; } hex_digits = raw_token.substr(3); } else if (raw_length == num_hex_digits) { // Accept the token without the prefix if it's otherwise ok hex_digits = raw_token; } else { return false; } // Convert to strict lowercase and correct any common misspellings boost::algorithm::to_lower(hex_digits); std::replace(hex_digits.begin(), hex_digits.end(), 'o', '0'); std::replace(hex_digits.begin(), hex_digits.end(), 'i', '1'); std::replace(hex_digits.begin(), hex_digits.end(), 'l', '1'); // Now it must be correct hex with correct checksum, no further tolerance possible std::string token_bytes; if (!epee::string_tools::parse_hexstr_to_binbuff(hex_digits, token_bytes)) { return false; } const crypto::hash &hash = crypto::cn_fast_hash(token_bytes.data(), token_bytes.size() - 1); if (token_bytes[AUTO_CONFIG_TOKEN_BYTES] != hash.data[0]) { return false; } adjusted_token = prefix + hex_digits; return true; } // Create a new auto-config token with prefix, random 8-hex digits plus 2 checksum digits std::string message_store::create_auto_config_token() { unsigned char random[AUTO_CONFIG_TOKEN_BYTES]; crypto::rand(AUTO_CONFIG_TOKEN_BYTES, random); std::string token_bytes; token_bytes.append((char *)random, AUTO_CONFIG_TOKEN_BYTES); // Add a checksum because technically ANY four bytes are a valid token, and without a checksum we would send // auto-config messages "to nowhere" after the slightest typo without knowing it const crypto::hash &hash = crypto::cn_fast_hash(token_bytes.data(), token_bytes.size()); token_bytes += hash.data[0]; std::string prefix(AUTO_CONFIG_TOKEN_PREFIX); return prefix + epee::string_tools::buff_to_hex_nodelimer(token_bytes); } // Add a message for sending "me" address data to the auto-config transport address // that can be derived from the token and activate auto-config size_t message_store::add_auto_config_data_message(const multisig_wallet_state &state, const std::string &auto_config_token) { authorized_signer &me = m_signers[0]; me.auto_config_token = auto_config_token; setup_signer_for_auto_config(0, auto_config_token, false); me.auto_config_running = true; auto_config_data data; data.label = me.label; data.transport_address = me.transport_address; data.monero_address = me.monero_address; std::stringstream oss; boost::archive::portable_binary_oarchive ar(oss); ar << data; return add_message(state, 0, message_type::auto_config_data, message_direction::out, oss.str()); } // Process a single message with auto-config data, destined for "message.signer_index" void message_store::process_auto_config_data_message(uint32_t id) { // "auto_config_data" contains the label that the auto-config data sender uses for "me", but that's // more for completeness' sake, and right now it's not used. In general, the auto-config manager // decides/defines the labels, and right after completing auto-config ALL wallets use the SAME labels. const message &m = get_message_ref_by_id(id); auto_config_data data; try { std::stringstream iss; iss << m.content; boost::archive::portable_binary_iarchive ar(iss); ar >> data; } catch (...) { THROW_WALLET_EXCEPTION_IF(true, tools::error::wallet_internal_error, "Invalid structure of auto config data"); } authorized_signer &signer = m_signers[m.signer_index]; // "signer.label" does NOT change, see comment above signer.transport_address = data.transport_address; signer.monero_address_known = true; signer.monero_address = data.monero_address; signer.auto_config_running = false; } void message_store::stop_auto_config() { for (uint32_t i = 0; i < m_num_authorized_signers; ++i) { authorized_signer &m = m_signers[i]; if (!m.auto_config_transport_address.empty()) { // Try to delete the chan that was used for auto-config m_transporter.delete_transport_address(m.auto_config_transport_address); } m.auto_config_token.clear(); m.auto_config_public_key = crypto::null_pkey; m.auto_config_secret_key = crypto::null_skey; m.auto_config_transport_address.clear(); m.auto_config_running = false; } } void message_store::setup_signer_for_auto_config(uint32_t index, const std::string token, bool receiving) { // It may be a little strange to hash the textual hex digits of the auto config token into // 32 bytes and turn that into a Monero public/secret key pair, instead of doing something // much less complicated like directly using the underlying random 40 bits as key for a // symmetric cipher, but everything is there already for encrypting and decrypting messages // with such key pairs, and furthermore it would be trivial to use tokens with a different // number of bytes. // // In the wallet of the auto-config manager each signer except "me" gets set its own // auto-config parameters. In the wallet of somebody using the token to send auto-config // data the auto-config parameters are stored in the "me" signer and taken from there // to send that data. THROW_WALLET_EXCEPTION_IF(index >= m_num_authorized_signers, tools::error::wallet_internal_error, "Invalid signer index " + std::to_string(index)); authorized_signer &m = m_signers[index]; m.auto_config_token = token; crypto::hash_to_scalar(token.data(), token.size(), m.auto_config_secret_key); crypto::secret_key_to_public_key(m.auto_config_secret_key, m.auto_config_public_key); m.auto_config_transport_address = m_transporter.derive_transport_address(m.auto_config_token); } bool message_store::get_signer_index_by_monero_address(const cryptonote::account_public_address &monero_address, uint32_t &index) const { for (uint32_t i = 0; i < m_num_authorized_signers; ++i) { const authorized_signer &m = m_signers[i]; if (m.monero_address == monero_address) { index = m.index; return true; } } MWARNING("No authorized signer with Monero address " << account_address_to_string(monero_address)); return false; } bool message_store::get_signer_index_by_label(const std::string label, uint32_t &index) const { for (uint32_t i = 0; i < m_num_authorized_signers; ++i) { const authorized_signer &m = m_signers[i]; if (m.label == label) { index = m.index; return true; } } MWARNING("No authorized signer with label " << label); return false; } void message_store::process_wallet_created_data(const multisig_wallet_state &state, message_type type, const std::string &content) { switch(type) { case message_type::key_set: // Result of a "prepare_multisig" command in the wallet // Send the key set to all other signers case message_type::additional_key_set: // Result of a "make_multisig" command or a "exchange_multisig_keys" in the wallet in case of M/N multisig // Send the additional key set to all other signers case message_type::multisig_sync_data: // Result of a "export_multisig_info" command in the wallet // Send the sync data to all other signers for (uint32_t i = 1; i < m_num_authorized_signers; ++i) { add_message(state, i, type, message_direction::out, content); } break; case message_type::partially_signed_tx: // Result of a "transfer" command in the wallet, or a "sign_multisig" command // that did not yet result in the minimum number of signatures required // Create a message "from me to me" as a container for the tx data if (m_num_required_signers == 1) { // Probably rare, but possible: The 1 signature is already enough, correct the type // Easier to correct here than asking all callers to detect this rare special case type = message_type::fully_signed_tx; } add_message(state, 0, type, message_direction::in, content); break; case message_type::fully_signed_tx: add_message(state, 0, type, message_direction::in, content); break; default: THROW_WALLET_EXCEPTION(tools::error::wallet_internal_error, "Illegal message type " + std::to_string((uint32_t)type)); break; } } size_t message_store::add_message(const multisig_wallet_state &state, uint32_t signer_index, message_type type, message_direction direction, const std::string &content) { message m; m.id = m_next_message_id++; m.type = type; m.direction = direction; m.content = content; m.created = (uint64_t)time(NULL); m.modified = m.created; m.sent = 0; m.signer_index = signer_index; if (direction == message_direction::out) { m.state = message_state::ready_to_send; } else { m.state = message_state::waiting; }; m.wallet_height = (uint32_t)state.num_transfer_details; if (m.type == message_type::additional_key_set) { m.round = state.multisig_rounds_passed; } else { m.round = 0; } m.signature_count = 0; // Future expansion for signature counting when signing txs m.hash = crypto::null_hash; m_messages.push_back(m); // Save for every new message right away (at least while in beta) save(state); MINFO(boost::format("Added %s message %s for signer %s of type %s") % message_direction_to_string(direction) % m.id % signer_index % message_type_to_string(type)); return m_messages.size() - 1; } // Get the index of the message with id "id", return false if not found bool message_store::get_message_index_by_id(uint32_t id, size_t &index) const { for (size_t i = 0; i < m_messages.size(); ++i) { if (m_messages[i].id == id) { index = i; return true; } } MWARNING("No message found with an id of " << id); return false; } // Get the index of the message with id "id" that must exist size_t message_store::get_message_index_by_id(uint32_t id) const { size_t index; bool found = get_message_index_by_id(id, index); THROW_WALLET_EXCEPTION_IF(!found, tools::error::wallet_internal_error, "Invalid message id " + std::to_string(id)); return index; } // Get the modifiable message with id "id" that must exist; private/internal use! message& message_store::get_message_ref_by_id(uint32_t id) { return m_messages[get_message_index_by_id(id)]; } // Get the message with id "id", return false if not found // This version of the method allows to check whether id is valid without triggering an error bool message_store::get_message_by_id(uint32_t id, message &m) const { size_t index; bool found = get_message_index_by_id(id, index); if (found) { m = m_messages[index]; } return found; } // Get the message with id "id" that must exist message message_store::get_message_by_id(uint32_t id) const { message m; bool found = get_message_by_id(id, m); THROW_WALLET_EXCEPTION_IF(!found, tools::error::wallet_internal_error, "Invalid message id " + std::to_string(id)); return m; } bool message_store::any_message_of_type(message_type type, message_direction direction) const { for (size_t i = 0; i < m_messages.size(); ++i) { if ((m_messages[i].type == type) && (m_messages[i].direction == direction)) { return true; } } return false; } bool message_store::any_message_with_hash(const crypto::hash &hash) const { for (size_t i = 0; i < m_messages.size(); ++i) { if (m_messages[i].hash == hash) { return true; } } return false; } // Count the ids in the vector that are set i.e. not 0, while ignoring index 0 // Mostly used to check whether we have a message for each authorized signer except me, // with the signer index used as index into 'ids'; the element at index 0, for me, // is ignored, to make constant subtractions of 1 for indices when filling the // vector unnecessary size_t message_store::get_other_signers_id_count(const std::vector &ids) const { size_t count = 0; for (size_t i = 1 /* and not 0 */; i < ids.size(); ++i) { if (ids[i] != 0) { count++; } } return count; } // Is in every element of vector 'ids' (except at index 0) a message id i.e. not 0? bool message_store::message_ids_complete(const std::vector &ids) const { return get_other_signers_id_count(ids) == (ids.size() - 1); } void message_store::delete_message(uint32_t id) { delete_transport_message(id); size_t index = get_message_index_by_id(id); m_messages.erase(m_messages.begin() + index); } void message_store::delete_all_messages() { for (size_t i = 0; i < m_messages.size(); ++i) { delete_transport_message(m_messages[i].id); } m_messages.clear(); } // Make a message text, which is "attacker controlled data", reasonably safe to display // This is mostly geared towards the safe display of notes sent by "mms note" with a "mms show" command void message_store::get_sanitized_message_text(const message &m, std::string &sanitized_text) const { sanitized_text.clear(); // Restrict the size to fend of DOS-style attacks with heaps of data size_t length = std::min(m.content.length(), (size_t)1000); for (size_t i = 0; i < length; ++i) { char c = m.content[i]; if ((int)c < 32) { // Strip out any controls, especially ESC for getting rid of potentially dangerous // ANSI escape sequences that a console window might interpret c = ' '; } else if ((c == '<') || (c == '>')) { // Make XML or HTML impossible that e.g. might contain scripts that Qt might execute // when displayed in the GUI wallet c = ' '; } sanitized_text += c; } } void message_store::write_to_file(const multisig_wallet_state &state, const std::string &filename) { std::stringstream oss; boost::archive::portable_binary_oarchive ar(oss); ar << *this; std::string buf = oss.str(); crypto::chacha_key key; crypto::generate_chacha_key(&state.view_secret_key, sizeof(crypto::secret_key), key, 1); file_data write_file_data = {}; write_file_data.magic_string = "MMS"; write_file_data.file_version = 0; write_file_data.iv = crypto::rand(); std::string encrypted_data; encrypted_data.resize(buf.size()); crypto::chacha20(buf.data(), buf.size(), key, write_file_data.iv, &encrypted_data[0]); write_file_data.encrypted_data = encrypted_data; std::stringstream file_oss; boost::archive::portable_binary_oarchive file_ar(file_oss); file_ar << write_file_data; bool success = epee::file_io_utils::save_string_to_file(filename, file_oss.str()); THROW_WALLET_EXCEPTION_IF(!success, tools::error::file_save_error, filename); } void message_store::read_from_file(const multisig_wallet_state &state, const std::string &filename) { boost::system::error_code ignored_ec; bool file_exists = boost::filesystem::exists(filename, ignored_ec); if (!file_exists) { // Simply do nothing if the file is not there; allows e.g. easy recovery // from problems with the MMS by deleting the file MERROR("No message store file found: " << filename); return; } std::string buf; bool success = epee::file_io_utils::load_file_to_string(filename, buf); THROW_WALLET_EXCEPTION_IF(!success, tools::error::file_read_error, filename); file_data read_file_data; try { std::stringstream iss; iss << buf; boost::archive::portable_binary_iarchive ar(iss); ar >> read_file_data; } catch (const std::exception &e) { MERROR("MMS file " << filename << " has bad structure : " << e.what()); THROW_WALLET_EXCEPTION_IF(true, tools::error::file_read_error, filename); } crypto::chacha_key key; crypto::generate_chacha_key(&state.view_secret_key, sizeof(crypto::secret_key), key, 1); std::string decrypted_data; decrypted_data.resize(read_file_data.encrypted_data.size()); crypto::chacha20(read_file_data.encrypted_data.data(), read_file_data.encrypted_data.size(), key, read_file_data.iv, &decrypted_data[0]); try { std::stringstream iss; iss << decrypted_data; boost::archive::portable_binary_iarchive ar(iss); ar >> *this; } catch (const std::exception &e) { MERROR("MMS file " << filename << " has bad structure: " << e.what()); THROW_WALLET_EXCEPTION_IF(true, tools::error::file_read_error, filename); } m_filename = filename; } // Save to the same file this message store was loaded from // Called after changes deemed "important", to make it less probable to lose messages in case of // a crash; a better and long-term solution would of course be to use LMDB ... void message_store::save(const multisig_wallet_state &state) { if (!m_filename.empty()) { write_to_file(state, m_filename); } } bool message_store::get_processable_messages(const multisig_wallet_state &state, bool force_sync, std::vector &data_list, std::string &wait_reason) { uint32_t wallet_height = (uint32_t)state.num_transfer_details; data_list.clear(); wait_reason.clear(); // In all scans over all messages looking for complete sets (1 message for each signer), // if there are duplicates, the OLDEST of them is taken. This may not play a role with // any of the current message types, but may with future ones, and it's probably a good // idea to have a clear and somewhat defensive strategy. std::vector auto_config_messages(m_num_authorized_signers, 0); bool any_auto_config = false; for (size_t i = 0; i < m_messages.size(); ++i) { message &m = m_messages[i]; if ((m.type == message_type::auto_config_data) && (m.state == message_state::waiting)) { if (auto_config_messages[m.signer_index] == 0) { auto_config_messages[m.signer_index] = m.id; any_auto_config = true; } // else duplicate auto config data, ignore } } if (any_auto_config) { bool auto_config_complete = message_ids_complete(auto_config_messages); if (auto_config_complete) { processing_data data; data.processing = message_processing::process_auto_config_data; data.message_ids = auto_config_messages; data.message_ids.erase(data.message_ids.begin()); data_list.push_back(data); return true; } else { wait_reason = tr("Auto-config cannot proceed because auto config data from other signers is not complete"); return false; // With ANY auto config data present but not complete refuse to check for any // other processing. Manually delete those messages to abort such an auto config // phase if needed. } } // Any signer config that arrived will be processed right away, regardless of other things that may wait for (size_t i = 0; i < m_messages.size(); ++i) { message &m = m_messages[i]; if ((m.type == message_type::signer_config) && (m.state == message_state::waiting)) { processing_data data; data.processing = message_processing::process_signer_config; data.message_ids.push_back(m.id); data_list.push_back(data); return true; } } // ALL of the following processings depend on the signer info being complete if (!signer_config_complete()) { wait_reason = tr("The signer config is not complete."); return false; } if (!state.multisig) { if (!any_message_of_type(message_type::key_set, message_direction::out)) { // With the own key set not yet ready we must do "prepare_multisig" first; // Key sets from other signers may be here already, but if we process them now // the wallet will go multisig too early: we can't produce our own key set any more! processing_data data; data.processing = message_processing::prepare_multisig; data_list.push_back(data); return true; } // Ids of key set messages per signer index, to check completeness // Naturally, does not care about the order of the messages and is trivial to secure against // key sets that were received more than once // With full M/N multisig now possible consider only key sets of the right round, i.e. // with not yet multisig the only possible round 0 std::vector key_set_messages(m_num_authorized_signers, 0); for (size_t i = 0; i < m_messages.size(); ++i) { message &m = m_messages[i]; if ((m.type == message_type::key_set) && (m.state == message_state::waiting) && (m.round == 0)) { if (key_set_messages[m.signer_index] == 0) { key_set_messages[m.signer_index] = m.id; } // else duplicate key set, ignore } } bool key_sets_complete = message_ids_complete(key_set_messages); if (key_sets_complete) { // Nothing else can be ready to process earlier than this, ignore everything else and give back processing_data data; data.processing = message_processing::make_multisig; data.message_ids = key_set_messages; data.message_ids.erase(data.message_ids.begin()); data_list.push_back(data); return true; } else { wait_reason = tr("Wallet can't go multisig because key sets from other signers are missing or not complete."); return false; } } if (state.multisig && !state.multisig_is_ready) { // In the case of M/N multisig the call 'wallet2::multisig' returns already true // after "make_multisig" but with calls to "exchange_multisig_keys" still needed, and // sets the parameter 'ready' to false to document this particular "in-between" state. // So what may be possible here, with all necessary messages present, is a call to // "exchange_multisig_keys". // Consider only messages belonging to the next round to do, which has the number // "state.multisig_rounds_passed". std::vector additional_key_set_messages(m_num_authorized_signers, 0); for (size_t i = 0; i < m_messages.size(); ++i) { message &m = m_messages[i]; if ((m.type == message_type::additional_key_set) && (m.state == message_state::waiting) && (m.round == state.multisig_rounds_passed)) { if (additional_key_set_messages[m.signer_index] == 0) { additional_key_set_messages[m.signer_index] = m.id; } // else duplicate key set, ignore } } bool key_sets_complete = message_ids_complete(additional_key_set_messages); if (key_sets_complete) { processing_data data; data.processing = message_processing::exchange_multisig_keys; data.message_ids = additional_key_set_messages; data.message_ids.erase(data.message_ids.begin()); data_list.push_back(data); return true; } else { wait_reason = tr("Wallet can't start another key exchange round because key sets from other signers are missing or not complete."); return false; } } // Properly exchanging multisig sync data is easiest and most transparent // for the user if a wallet sends its own data first and processes any received // sync data afterwards so that's the order that the MMS enforces here. // (Technically, it seems to work also the other way round.) // // To check whether a NEW round of syncing is necessary the MMS works with a // "wallet state": new state means new syncing needed. // // The MMS monitors the "wallet state" by recording "wallet heights" as // numbers of transfers present in a wallet at the time of message creation. While // not watertight, this quite simple scheme should already suffice to trigger // and orchestrate a sensible exchange of sync data. if (state.has_multisig_partial_key_images || force_sync) { // Sync is necessary and not yet completed: Processing of transactions // will only be possible again once properly synced // Check first whether we generated already OUR sync info; take note of // any processable sync info from other signers on the way in case we need it bool own_sync_data_created = false; std::vector sync_messages(m_num_authorized_signers, 0); for (size_t i = 0; i < m_messages.size(); ++i) { message &m = m_messages[i]; if ((m.type == message_type::multisig_sync_data) && (force_sync || (m.wallet_height == wallet_height))) // It's data for the same "round" of syncing, on the same "wallet height", therefore relevant // With "force_sync" take ANY waiting sync data, maybe it will work out { if (m.direction == message_direction::out) { own_sync_data_created = true; // Ignore whether sent already or not, and assume as complete if several other signers there } else if ((m.direction == message_direction::in) && (m.state == message_state::waiting)) { if (sync_messages[m.signer_index] == 0) { sync_messages[m.signer_index] = m.id; } // else duplicate sync message, ignore } } } if (!own_sync_data_created) { // As explained above, creating sync data BEFORE processing such data from // other signers reliably works, so insist on that here processing_data data; data.processing = message_processing::create_sync_data; data_list.push_back(data); return true; } uint32_t id_count = (uint32_t)get_other_signers_id_count(sync_messages); // Do we have sync data from ALL other signers? bool all_sync_data = id_count == (m_num_authorized_signers - 1); // Do we have just ENOUGH sync data to have a minimal viable sync set? // In cases like 2/3 multisig we don't need messages from ALL other signers, only // from enough of them i.e. num_required_signers minus 1 messages bool enough_sync_data = id_count >= (m_num_required_signers - 1); bool sync = false; wait_reason = tr("Syncing not done because multisig sync data from other signers are missing or not complete."); if (all_sync_data) { sync = true; } else if (enough_sync_data) { if (force_sync) { sync = true; } else { // Don't sync, but give a hint how this minimal set COULD be synced if really wanted wait_reason += (boost::format("\nUse \"mms next sync\" if you want to sync with just %s out of %s authorized signers and transact just with them") % (m_num_required_signers - 1) % (m_num_authorized_signers - 1)).str(); } } if (sync) { processing_data data; data.processing = message_processing::process_sync_data; for (size_t i = 0; i < sync_messages.size(); ++i) { uint32_t id = sync_messages[i]; if (id != 0) { data.message_ids.push_back(id); } } data_list.push_back(data); return true; } else { // We can't proceed to any transactions until we have synced; "wait_reason" already set above return false; } } bool waiting_found = false; bool note_found = false; bool sync_data_found = false; for (size_t i = 0; i < m_messages.size(); ++i) { message &m = m_messages[i]; if (m.state == message_state::waiting) { waiting_found = true; switch (m.type) { case message_type::fully_signed_tx: { // We can either submit it ourselves, or send it to any other signer for submission processing_data data; data.processing = message_processing::submit_tx; data.message_ids.push_back(m.id); data_list.push_back(data); data.processing = message_processing::send_tx; for (uint32_t j = 1; j < m_num_authorized_signers; ++j) { data.receiving_signer_index = j; data_list.push_back(data); } return true; } case message_type::partially_signed_tx: { if (m.signer_index == 0) { // We started this ourselves, or signed it but with still signatures missing: // We can send it to any other signer for signing / further signing // In principle it does not make sense to send it back to somebody who // already signed, but the MMS does not / not yet keep track of that, // because that would be somewhat complicated. processing_data data; data.processing = message_processing::send_tx; data.message_ids.push_back(m.id); for (uint32_t j = 1; j < m_num_authorized_signers; ++j) { data.receiving_signer_index = j; data_list.push_back(data); } return true; } else { // Somebody else sent this to us: We can sign it // It would be possible to just pass it on, but that's not directly supported here processing_data data; data.processing = message_processing::sign_tx; data.message_ids.push_back(m.id); data_list.push_back(data); return true; } } case message_type::note: note_found = true; break; case message_type::multisig_sync_data: sync_data_found = true; break; default: break; } } } if (waiting_found) { wait_reason = tr("There are waiting messages, but nothing is ready to process under normal circumstances"); if (sync_data_found) { wait_reason += tr("\nUse \"mms next sync\" if you want to force processing of the waiting sync data"); } if (note_found) { wait_reason += tr("\nUse \"mms note\" to display the waiting notes"); } } else { wait_reason = tr("There are no messages waiting to be processed."); } return false; } void message_store::set_messages_processed(const processing_data &data) { for (size_t i = 0; i < data.message_ids.size(); ++i) { set_message_processed_or_sent(data.message_ids[i]); } } void message_store::set_message_processed_or_sent(uint32_t id) { message &m = get_message_ref_by_id(id); if (m.state == message_state::waiting) { // So far a fairly cautious and conservative strategy: Only delete from Bitmessage // when fully processed (and e.g. not already after reception and writing into // the message store file) delete_transport_message(id); m.state = message_state::processed; } else if (m.state == message_state::ready_to_send) { m.state = message_state::sent; } m.modified = (uint64_t)time(NULL); } void message_store::encrypt(crypto::public_key public_key, const std::string &plaintext, std::string &ciphertext, crypto::public_key &encryption_public_key, crypto::chacha_iv &iv) { crypto::secret_key encryption_secret_key; crypto::generate_keys(encryption_public_key, encryption_secret_key); crypto::key_derivation derivation; bool success = crypto::generate_key_derivation(public_key, encryption_secret_key, derivation); THROW_WALLET_EXCEPTION_IF(!success, tools::error::wallet_internal_error, "Failed to generate key derivation for message encryption"); crypto::chacha_key chacha_key; crypto::generate_chacha_key(&derivation, sizeof(derivation), chacha_key, 1); iv = crypto::rand(); ciphertext.resize(plaintext.size()); crypto::chacha20(plaintext.data(), plaintext.size(), chacha_key, iv, &ciphertext[0]); } void message_store::decrypt(const std::string &ciphertext, const crypto::public_key &encryption_public_key, const crypto::chacha_iv &iv, const crypto::secret_key &view_secret_key, std::string &plaintext) { crypto::key_derivation derivation; bool success = crypto::generate_key_derivation(encryption_public_key, view_secret_key, derivation); THROW_WALLET_EXCEPTION_IF(!success, tools::error::wallet_internal_error, "Failed to generate key derivation for message decryption"); crypto::chacha_key chacha_key; crypto::generate_chacha_key(&derivation, sizeof(derivation), chacha_key, 1); plaintext.resize(ciphertext.size()); crypto::chacha20(ciphertext.data(), ciphertext.size(), chacha_key, iv, &plaintext[0]); } void message_store::send_message(const multisig_wallet_state &state, uint32_t id) { message &m = get_message_ref_by_id(id); const authorized_signer &me = m_signers[0]; const authorized_signer &receiver = m_signers[m.signer_index]; transport_message dm; crypto::public_key public_key; dm.timestamp = (uint64_t)time(NULL); dm.subject = "MMS V0 " + tools::get_human_readable_timestamp(dm.timestamp); dm.source_transport_address = me.transport_address; dm.source_monero_address = me.monero_address; if (m.type == message_type::auto_config_data) { // Encrypt with the public key derived from the auto-config token, and send to the // transport address likewise derived from that token public_key = me.auto_config_public_key; dm.destination_transport_address = me.auto_config_transport_address; // The destination Monero address is not yet known memset(&dm.destination_monero_address, 0, sizeof(cryptonote::account_public_address)); } else { // Encrypt with the receiver's view public key public_key = receiver.monero_address.m_view_public_key; const authorized_signer &receiver = m_signers[m.signer_index]; dm.destination_monero_address = receiver.monero_address; dm.destination_transport_address = receiver.transport_address; } encrypt(public_key, m.content, dm.content, dm.encryption_public_key, dm.iv); dm.type = (uint32_t)m.type; dm.hash = crypto::cn_fast_hash(dm.content.data(), dm.content.size()); dm.round = m.round; crypto::generate_signature(dm.hash, me.monero_address.m_view_public_key, state.view_secret_key, dm.signature); m_transporter.send_message(dm); m.state=message_state::sent; m.sent= (uint64_t)time(NULL); } bool message_store::check_for_messages(const multisig_wallet_state &state, std::vector &messages) { m_run.store(true, std::memory_order_relaxed); const authorized_signer &me = m_signers[0]; std::vector destinations; destinations.push_back(me.transport_address); for (uint32_t i = 1; i < m_num_authorized_signers; ++i) { const authorized_signer &m = m_signers[i]; if (m.auto_config_running) { destinations.push_back(m.auto_config_transport_address); } } std::vector transport_messages; bool r = m_transporter.receive_messages(destinations, transport_messages); if (!m_run.load(std::memory_order_relaxed)) { // Stop was called, don't waste time processing the messages // (but once started processing them, don't react to stop request anymore, avoid receiving them "partially)" return false; } bool new_messages = false; for (size_t i = 0; i < transport_messages.size(); ++i) { transport_message &rm = transport_messages[i]; if (any_message_with_hash(rm.hash)) { // Already seen, do not take again } else { uint32_t sender_index; bool take = false; message_type type = static_cast(rm.type); crypto::secret_key decrypt_key = state.view_secret_key; if (type == message_type::auto_config_data) { // Find out which signer sent it by checking which auto config transport address // the message was sent to for (uint32_t i = 1; i < m_num_authorized_signers; ++i) { const authorized_signer &m = m_signers[i]; if (m.auto_config_transport_address == rm.destination_transport_address) { take = true; sender_index = i; decrypt_key = m.auto_config_secret_key; break; } } } else if (type == message_type::signer_config) { // Typically we can't check yet whether we know the sender, so take from any // and pretend it's from "me" because we might have nothing else yet take = true; sender_index = 0; } else { // Only accept from senders that are known as signer here, otherwise just ignore take = get_signer_index_by_monero_address(rm.source_monero_address, sender_index); } if (take && (type != message_type::auto_config_data)) { // If the destination address is known, check it as well; this additional filter // allows using the same transport address for multiple signers take = rm.destination_monero_address == me.monero_address; } if (take) { crypto::hash actual_hash = crypto::cn_fast_hash(rm.content.data(), rm.content.size()); THROW_WALLET_EXCEPTION_IF(actual_hash != rm.hash, tools::error::wallet_internal_error, "Message hash mismatch"); bool signature_valid = crypto::check_signature(actual_hash, rm.source_monero_address.m_view_public_key, rm.signature); THROW_WALLET_EXCEPTION_IF(!signature_valid, tools::error::wallet_internal_error, "Message signature not valid"); std::string plaintext; decrypt(rm.content, rm.encryption_public_key, rm.iv, decrypt_key, plaintext); size_t index = add_message(state, sender_index, (message_type)rm.type, message_direction::in, plaintext); message &m = m_messages[index]; m.hash = rm.hash; m.transport_id = rm.transport_id; m.sent = rm.timestamp; m.round = rm.round; m.signature_count = rm.signature_count; messages.push_back(m); new_messages = true; } } } return new_messages; } void message_store::delete_transport_message(uint32_t id) { const message &m = get_message_by_id(id); if (!m.transport_id.empty()) { m_transporter.delete_message(m.transport_id); } } std::string message_store::account_address_to_string(const cryptonote::account_public_address &account_address) const { return get_account_address_as_str(m_nettype, false, account_address); } const char* message_store::message_type_to_string(message_type type) { switch (type) { case message_type::key_set: return tr("key set"); case message_type::additional_key_set: return tr("additional key set"); case message_type::multisig_sync_data: return tr("multisig sync data"); case message_type::partially_signed_tx: return tr("partially signed tx"); case message_type::fully_signed_tx: return tr("fully signed tx"); case message_type::note: return tr("note"); case message_type::signer_config: return tr("signer config"); case message_type::auto_config_data: return tr("auto-config data"); default: return tr("unknown message type"); } } const char* message_store::message_direction_to_string(message_direction direction) { switch (direction) { case message_direction::in: return tr("in"); case message_direction::out: return tr("out"); default: return tr("unknown message direction"); } } const char* message_store::message_state_to_string(message_state state) { switch (state) { case message_state::ready_to_send: return tr("ready to send"); case message_state::sent: return tr("sent"); case message_state::waiting: return tr("waiting"); case message_state::processed: return tr("processed"); case message_state::cancelled: return tr("cancelled"); default: return tr("unknown message state"); } } // Convert a signer to string suitable for a column in a list, with 'max_width' // Format: label: transport_address std::string message_store::signer_to_string(const authorized_signer &signer, uint32_t max_width) { std::string s = ""; s.reserve(max_width); uint32_t avail = max_width; uint32_t label_len = signer.label.length(); if (label_len > avail) { s.append(signer.label.substr(0, avail - 2)); s.append(".."); return s; } s.append(signer.label); avail -= label_len; uint32_t transport_addr_len = signer.transport_address.length(); if ((transport_addr_len > 0) && (avail > 10)) { s.append(": "); avail -= 2; if (transport_addr_len <= avail) { s.append(signer.transport_address); } else { s.append(signer.transport_address.substr(0, avail-2)); s.append(".."); } } return s; } }