// Copyright (c) 2014-2018, 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.
//
// Parts of this file are originally copyright (c) 2012-2013 The Cryptonote developers
#include <numeric>
#include <random>
#include <tuple>
#include <boost/format.hpp>
#include <boost/optional/optional.hpp>
#include <boost/utility/value_init.hpp>
#include <boost/algorithm/string/classification.hpp>
#include <boost/algorithm/string/trim.hpp>
#include <boost/algorithm/string/split.hpp>
#include <boost/algorithm/string/join.hpp>
#include <boost/range/adaptor/transformed.hpp>
#include "include_base_utils.h"
using namespace epee;
#include "cryptonote_config.h"
#include "wallet2.h"
#include "cryptonote_basic/cryptonote_format_utils.h"
#include "rpc/core_rpc_server_commands_defs.h"
#include "misc_language.h"
#include "cryptonote_basic/cryptonote_basic_impl.h"
#include "multisig/multisig.h"
#include "common/boost_serialization_helper.h"
#include "common/command_line.h"
#include "common/threadpool.h"
#include "profile_tools.h"
#include "crypto/crypto.h"
#include "serialization/binary_utils.h"
#include "serialization/string.h"
#include "cryptonote_basic/blobdatatype.h"
#include "mnemonics/electrum-words.h"
#include "common/i18n.h"
#include "common/util.h"
#include "common/apply_permutation.h"
#include "rapidjson/document.h"
#include "rapidjson/writer.h"
#include "rapidjson/stringbuffer.h"
#include "common/json_util.h"
#include "memwipe.h"
#include "common/base58.h"
#include "common/dns_utils.h"
#include "common/notify.h"
#include "common/perf_timer.h"
#include "ringct/rctSigs.h"
#include "ringdb.h"
#include "device/device_cold.hpp"
#include "device_trezor/device_trezor.hpp"
extern "C"
{
#include "crypto/keccak.h"
#include "crypto/crypto-ops.h"
}
using namespace std;
using namespace crypto;
using namespace cryptonote;
#undef MONERO_DEFAULT_LOG_CATEGORY
#define MONERO_DEFAULT_LOG_CATEGORY "wallet.wallet2"
// used to choose when to stop adding outputs to a tx
#define APPROXIMATE_INPUT_BYTES 80
// used to target a given block weight (additional outputs may be added on top to build fee)
#define TX_WEIGHT_TARGET(bytes) (bytes*2/3)
// arbitrary, used to generate different hashes from the same input
#define CHACHA8_KEY_TAIL 0x8c
#define CACHE_KEY_TAIL 0x8d
#define UNSIGNED_TX_PREFIX "Monero unsigned tx set\004"
#define SIGNED_TX_PREFIX "Monero signed tx set\004"
#define MULTISIG_UNSIGNED_TX_PREFIX "Monero multisig unsigned tx set\001"
#define RECENT_OUTPUT_RATIO (0.5) // 50% of outputs are from the recent zone
#define RECENT_OUTPUT_DAYS (1.8) // last 1.8 day makes up the recent zone (taken from monerolink.pdf, Miller et al)
#define RECENT_OUTPUT_ZONE ((time_t)(RECENT_OUTPUT_DAYS * 86400))
#define RECENT_OUTPUT_BLOCKS (RECENT_OUTPUT_DAYS * 720)
#define FEE_ESTIMATE_GRACE_BLOCKS 10 // estimate fee valid for that many blocks
#define SECOND_OUTPUT_RELATEDNESS_THRESHOLD 0.0f
#define SUBADDRESS_LOOKAHEAD_MAJOR 50
#define SUBADDRESS_LOOKAHEAD_MINOR 200
#define KEY_IMAGE_EXPORT_FILE_MAGIC "Monero key image export\003"
#define MULTISIG_EXPORT_FILE_MAGIC "Monero multisig export\001"
#define OUTPUT_EXPORT_FILE_MAGIC "Monero output export\004"
#define SEGREGATION_FORK_HEIGHT 99999999
#define TESTNET_SEGREGATION_FORK_HEIGHT 99999999
#define STAGENET_SEGREGATION_FORK_HEIGHT 99999999
#define SEGREGATION_FORK_VICINITY 1500 /* blocks */
#define FIRST_REFRESH_GRANULARITY 1024
#define GAMMA_PICK_HALF_WINDOW 5
static const std::string MULTISIG_SIGNATURE_MAGIC = "SigMultisigPkV1";
static const std::string MULTISIG_EXTRA_INFO_MAGIC = "MultisigxV1";
namespace
{
std::string get_default_ringdb_path()
{
boost::filesystem::path dir = tools::get_default_data_dir();
// remove .bitmonero, replace with .shared-ringdb
dir = dir.remove_filename();
dir /= ".shared-ringdb";
return dir.string();
}
std::string pack_multisignature_keys(const std::string& prefix, const std::vector<crypto::public_key>& keys, const crypto::secret_key& signer_secret_key)
{
std::string data;
crypto::public_key signer;
CHECK_AND_ASSERT_THROW_MES(crypto::secret_key_to_public_key(signer_secret_key, signer), "Failed to derive public spend key");
data += std::string((const char *)&signer, sizeof(crypto::public_key));
for (const auto &key: keys)
{
data += std::string((const char *)&key, sizeof(crypto::public_key));
}
data.resize(data.size() + sizeof(crypto::signature));
crypto::hash hash;
crypto::cn_fast_hash(data.data(), data.size() - sizeof(crypto::signature), hash);
crypto::signature &signature = *(crypto::signature*)&data[data.size() - sizeof(crypto::signature)];
crypto::generate_signature(hash, signer, signer_secret_key, signature);
return MULTISIG_EXTRA_INFO_MAGIC + tools::base58::encode(data);
}
std::vector<crypto::public_key> secret_keys_to_public_keys(const std::vector<crypto::secret_key>& keys)
{
std::vector<crypto::public_key> public_keys;
public_keys.reserve(keys.size());
std::transform(keys.begin(), keys.end(), std::back_inserter(public_keys), [] (const crypto::secret_key& k) -> crypto::public_key {
crypto::public_key p;
CHECK_AND_ASSERT_THROW_MES(crypto::secret_key_to_public_key(k, p), "Failed to derive public spend key");
return p;
});
return public_keys;
}
}
namespace
{
// Create on-demand to prevent static initialization order fiasco issues.
struct options {
const command_line::arg_descriptor<std::string> daemon_address = {"daemon-address", tools::wallet2::tr("Use daemon instance at <host>:<port>"), ""};
const command_line::arg_descriptor<std::string> daemon_host = {"daemon-host", tools::wallet2::tr("Use daemon instance at host <arg> instead of localhost"), ""};
const command_line::arg_descriptor<bool> trusted_daemon = {"trusted-daemon", tools::wallet2::tr("Enable commands which rely on a trusted daemon"), false};
const command_line::arg_descriptor<bool> untrusted_daemon = {"untrusted-daemon", tools::wallet2::tr("Disable commands which rely on a trusted daemon"), false};
const command_line::arg_descriptor<std::string> password = {"password", tools::wallet2::tr("Wallet password (escape/quote as needed)"), "", true};
const command_line::arg_descriptor<std::string> password_file = {"password-file", tools::wallet2::tr("Wallet password file"), "", true};
const command_line::arg_descriptor<int> daemon_port = {"daemon-port", tools::wallet2::tr("Use daemon instance at port <arg> instead of 18081"), 0};
const command_line::arg_descriptor<std::string> daemon_login = {"daemon-login", tools::wallet2::tr("Specify username[:password] for daemon RPC client"), "", true};
const command_line::arg_descriptor<bool> testnet = {"testnet", tools::wallet2::tr("For testnet. Daemon must also be launched with --testnet flag"), false};
const command_line::arg_descriptor<bool> stagenet = {"stagenet", tools::wallet2::tr("For stagenet. Daemon must also be launched with --stagenet flag"), false};
const command_line::arg_descriptor<std::string, false, true, 2> shared_ringdb_dir = {
"shared-ringdb-dir", tools::wallet2::tr("Set shared ring database path"),
get_default_ringdb_path(),
{{ &testnet, &stagenet }},
[](std::array<bool, 2> testnet_stagenet, bool defaulted, std::string val)->std::string {
if (testnet_stagenet[0])
return (boost::filesystem::path(val) / "testnet").string();
else if (testnet_stagenet[1])
return (boost::filesystem::path(val) / "stagenet").string();
return val;
}
};
const command_line::arg_descriptor<uint64_t> kdf_rounds = {"kdf-rounds", tools::wallet2::tr("Number of rounds for the key derivation function"), 1};
const command_line::arg_descriptor<std::string> hw_device = {"hw-device", tools::wallet2::tr("HW device to use"), ""};
const command_line::arg_descriptor<std::string> tx_notify = { "tx-notify" , "Run a program for each new incoming transaction, '%s' will be replaced by the transaction hash" , "" };
};
void do_prepare_file_names(const std::string& file_path, std::string& keys_file, std::string& wallet_file)
{
keys_file = file_path;
wallet_file = file_path;
boost::system::error_code e;
if(string_tools::get_extension(keys_file) == "keys")
{//provided keys file name
wallet_file = string_tools::cut_off_extension(wallet_file);
}else
{//provided wallet file name
keys_file += ".keys";
}
}
uint64_t calculate_fee(uint64_t fee_per_kb, size_t bytes, uint64_t fee_multiplier)
{
uint64_t kB = (bytes + 1023) / 1024;
return kB * fee_per_kb * fee_multiplier;
}
uint64_t calculate_fee_from_weight(uint64_t base_fee, uint64_t weight, uint64_t fee_multiplier, uint64_t fee_quantization_mask)
{
uint64_t fee = weight * base_fee * fee_multiplier;
fee = (fee + fee_quantization_mask - 1) / fee_quantization_mask * fee_quantization_mask;
return fee;
}
std::string get_weight_string(size_t weight)
{
return std::to_string(weight) + " weight";
}
std::string get_weight_string(const cryptonote::transaction &tx, size_t blob_size)
{
return get_weight_string(get_transaction_weight(tx, blob_size));
}
std::unique_ptr<tools::wallet2> make_basic(const boost::program_options::variables_map& vm, bool unattended, const options& opts, const std::function<boost::optional<tools::password_container>(const char *, bool)> &password_prompter)
{
const bool testnet = command_line::get_arg(vm, opts.testnet);
const bool stagenet = command_line::get_arg(vm, opts.stagenet);
const network_type nettype = testnet ? TESTNET : stagenet ? STAGENET : MAINNET;
const uint64_t kdf_rounds = command_line::get_arg(vm, opts.kdf_rounds);
THROW_WALLET_EXCEPTION_IF(kdf_rounds == 0, tools::error::wallet_internal_error, "KDF rounds must not be 0");
auto daemon_address = command_line::get_arg(vm, opts.daemon_address);
auto daemon_host = command_line::get_arg(vm, opts.daemon_host);
auto daemon_port = command_line::get_arg(vm, opts.daemon_port);
auto device_name = command_line::get_arg(vm, opts.hw_device);
THROW_WALLET_EXCEPTION_IF(!daemon_address.empty() && !daemon_host.empty() && 0 != daemon_port,
tools::error::wallet_internal_error, tools::wallet2::tr("can't specify daemon host or port more than once"));
boost::optional<epee::net_utils::http::login> login{};
if (command_line::has_arg(vm, opts.daemon_login))
{
auto parsed = tools::login::parse(
command_line::get_arg(vm, opts.daemon_login), false, [password_prompter](bool verify) {
return password_prompter("Daemon client password", verify);
}
);
if (!parsed)
return nullptr;
login.emplace(std::move(parsed->username), std::move(parsed->password).password());
}
if (daemon_host.empty())
daemon_host = "localhost";
if (!daemon_port)
{
daemon_port = get_config(nettype).RPC_DEFAULT_PORT;
}
if (daemon_address.empty())
daemon_address = std::string("http://") + daemon_host + ":" + std::to_string(daemon_port);
boost::optional<bool> trusted_daemon;
if (!command_line::is_arg_defaulted(vm, opts.trusted_daemon) || !command_line::is_arg_defaulted(vm, opts.untrusted_daemon))
trusted_daemon = command_line::get_arg(vm, opts.trusted_daemon) && !command_line::get_arg(vm, opts.untrusted_daemon);
THROW_WALLET_EXCEPTION_IF(!command_line::is_arg_defaulted(vm, opts.trusted_daemon) && !command_line::is_arg_defaulted(vm, opts.untrusted_daemon),
tools::error::wallet_internal_error, tools::wallet2::tr("--trusted-daemon and --untrusted-daemon are both seen, assuming untrusted"));
// set --trusted-daemon if local and not overridden
if (!trusted_daemon)
{
try
{
trusted_daemon = false;
if (tools::is_local_address(daemon_address))
{
MINFO(tools::wallet2::tr("Daemon is local, assuming trusted"));
trusted_daemon = true;
}
}
catch (const std::exception &e) { }
}
std::unique_ptr<tools::wallet2> wallet(new tools::wallet2(nettype, kdf_rounds, unattended));
wallet->init(std::move(daemon_address), std::move(login), 0, false, *trusted_daemon);
boost::filesystem::path ringdb_path = command_line::get_arg(vm, opts.shared_ringdb_dir);
wallet->set_ring_database(ringdb_path.string());
wallet->device_name(device_name);
try
{
if (!command_line::is_arg_defaulted(vm, opts.tx_notify))
wallet->set_tx_notify(std::shared_ptr<tools::Notify>(new tools::Notify(command_line::get_arg(vm, opts.tx_notify).c_str())));
}
catch (const std::exception &e)
{
MERROR("Failed to parse tx notify spec");
}
return wallet;
}
boost::optional<tools::password_container> get_password(const boost::program_options::variables_map& vm, const options& opts, const std::function<boost::optional<tools::password_container>(const char*, bool)> &password_prompter, const bool verify)
{
if (command_line::has_arg(vm, opts.password) && command_line::has_arg(vm, opts.password_file))
{
THROW_WALLET_EXCEPTION(tools::error::wallet_internal_error, tools::wallet2::tr("can't specify more than one of --password and --password-file"));
}
if (command_line::has_arg(vm, opts.password))
{
return tools::password_container{command_line::get_arg(vm, opts.password)};
}
if (command_line::has_arg(vm, opts.password_file))
{
std::string password;
bool r = epee::file_io_utils::load_file_to_string(command_line::get_arg(vm, opts.password_file),
password);
THROW_WALLET_EXCEPTION_IF(!r, tools::error::wallet_internal_error, tools::wallet2::tr("the password file specified could not be read"));
// Remove line breaks the user might have inserted
boost::trim_right_if(password, boost::is_any_of("\r\n"));
return {tools::password_container{std::move(password)}};
}
THROW_WALLET_EXCEPTION_IF(!password_prompter, tools::error::wallet_internal_error, tools::wallet2::tr("no password specified; use --prompt-for-password to prompt for a password"));
return password_prompter(verify ? tools::wallet2::tr("Enter a new password for the wallet") : tools::wallet2::tr("Wallet password"), verify);
}
std::pair<std::unique_ptr<tools::wallet2>, tools::password_container> generate_from_json(const std::string& json_file, const boost::program_options::variables_map& vm, bool unattended, const options& opts, const std::function<boost::optional<tools::password_container>(const char *, bool)> &password_prompter)
{
const bool testnet = command_line::get_arg(vm, opts.testnet);
const bool stagenet = command_line::get_arg(vm, opts.stagenet);
const network_type nettype = testnet ? TESTNET : stagenet ? STAGENET : MAINNET;
/* GET_FIELD_FROM_JSON_RETURN_ON_ERROR Is a generic macro that can return
false. Gcc will coerce this into unique_ptr(nullptr), but clang correctly
fails. This large wrapper is for the use of that macro */
std::unique_ptr<tools::wallet2> wallet;
epee::wipeable_string password;
const auto do_generate = [&]() -> bool {
std::string buf;
if (!epee::file_io_utils::load_file_to_string(json_file, buf)) {
THROW_WALLET_EXCEPTION(tools::error::wallet_internal_error, std::string(tools::wallet2::tr("Failed to load file ")) + json_file);
return false;
}
rapidjson::Document json;
if (json.Parse(buf.c_str()).HasParseError()) {
THROW_WALLET_EXCEPTION(tools::error::wallet_internal_error, tools::wallet2::tr("Failed to parse JSON"));
return false;
}
GET_FIELD_FROM_JSON_RETURN_ON_ERROR(json, version, unsigned, Uint, true, 0);
const int current_version = 1;
THROW_WALLET_EXCEPTION_IF(field_version > current_version, tools::error::wallet_internal_error,
((boost::format(tools::wallet2::tr("Version %u too new, we can only grok up to %u")) % field_version % current_version)).str());
GET_FIELD_FROM_JSON_RETURN_ON_ERROR(json, filename, std::string, String, true, std::string());
GET_FIELD_FROM_JSON_RETURN_ON_ERROR(json, scan_from_height, uint64_t, Uint64, false, 0);
const bool recover = field_scan_from_height_found;
GET_FIELD_FROM_JSON_RETURN_ON_ERROR(json, password, std::string, String, false, std::string());
GET_FIELD_FROM_JSON_RETURN_ON_ERROR(json, viewkey, std::string, String, false, std::string());
crypto::secret_key viewkey;
if (field_viewkey_found)
{
cryptonote::blobdata viewkey_data;
if(!epee::string_tools::parse_hexstr_to_binbuff(field_viewkey, viewkey_data) || viewkey_data.size() != sizeof(crypto::secret_key))
{
THROW_WALLET_EXCEPTION(tools::error::wallet_internal_error, tools::wallet2::tr("failed to parse view key secret key"));
}
viewkey = *reinterpret_cast<const crypto::secret_key*>(viewkey_data.data());
crypto::public_key pkey;
if (!crypto::secret_key_to_public_key(viewkey, pkey)) {
THROW_WALLET_EXCEPTION(tools::error::wallet_internal_error, tools::wallet2::tr("failed to verify view key secret key"));
}
}
GET_FIELD_FROM_JSON_RETURN_ON_ERROR(json, spendkey, std::string, String, false, std::string());
crypto::secret_key spendkey;
if (field_spendkey_found)
{
cryptonote::blobdata spendkey_data;
if(!epee::string_tools::parse_hexstr_to_binbuff(field_spendkey, spendkey_data) || spendkey_data.size() != sizeof(crypto::secret_key))
{
THROW_WALLET_EXCEPTION(tools::error::wallet_internal_error, tools::wallet2::tr("failed to parse spend key secret key"));
}
spendkey = *reinterpret_cast<const crypto::secret_key*>(spendkey_data.data());
crypto::public_key pkey;
if (!crypto::secret_key_to_public_key(spendkey, pkey)) {
THROW_WALLET_EXCEPTION(tools::error::wallet_internal_error, tools::wallet2::tr("failed to verify spend key secret key"));
}
}
GET_FIELD_FROM_JSON_RETURN_ON_ERROR(json, seed, std::string, String, false, std::string());
std::string old_language;
crypto::secret_key recovery_key;
bool restore_deterministic_wallet = false;
if (field_seed_found)
{
if (!crypto::ElectrumWords::words_to_bytes(field_seed, recovery_key, old_language))
{
THROW_WALLET_EXCEPTION(tools::error::wallet_internal_error, tools::wallet2::tr("Electrum-style word list failed verification"));
}
restore_deterministic_wallet = true;
GET_FIELD_FROM_JSON_RETURN_ON_ERROR(json, seed_passphrase, std::string, String, false, std::string());
if (field_seed_passphrase_found)
{
if (!field_seed_passphrase.empty())
recovery_key = cryptonote::decrypt_key(recovery_key, field_seed_passphrase);
}
}
GET_FIELD_FROM_JSON_RETURN_ON_ERROR(json, address, std::string, String, false, std::string());
GET_FIELD_FROM_JSON_RETURN_ON_ERROR(json, create_address_file, int, Int, false, false);
bool create_address_file = field_create_address_file;
// compatibility checks
if (!field_seed_found && !field_viewkey_found && !field_spendkey_found)
{
THROW_WALLET_EXCEPTION(tools::error::wallet_internal_error, tools::wallet2::tr("At least one of either an Electrum-style word list, private view key, or private spend key must be specified"));
}
if (field_seed_found && (field_viewkey_found || field_spendkey_found))
{
THROW_WALLET_EXCEPTION(tools::error::wallet_internal_error, tools::wallet2::tr("Both Electrum-style word list and private key(s) specified"));
}
// if an address was given, we check keys against it, and deduce the spend
// public key if it was not given
if (field_address_found)
{
cryptonote::address_parse_info info;
if(!get_account_address_from_str(info, nettype, field_address))
{
THROW_WALLET_EXCEPTION(tools::error::wallet_internal_error, tools::wallet2::tr("invalid address"));
}
if (field_viewkey_found)
{
crypto::public_key pkey;
if (!crypto::secret_key_to_public_key(viewkey, pkey)) {
THROW_WALLET_EXCEPTION(tools::error::wallet_internal_error, tools::wallet2::tr("failed to verify view key secret key"));
}
if (info.address.m_view_public_key != pkey) {
THROW_WALLET_EXCEPTION(tools::error::wallet_internal_error, tools::wallet2::tr("view key does not match standard address"));
}
}
if (field_spendkey_found)
{
crypto::public_key pkey;
if (!crypto::secret_key_to_public_key(spendkey, pkey)) {
THROW_WALLET_EXCEPTION(tools::error::wallet_internal_error, tools::wallet2::tr("failed to verify spend key secret key"));
}
if (info.address.m_spend_public_key != pkey) {
THROW_WALLET_EXCEPTION(tools::error::wallet_internal_error, tools::wallet2::tr("spend key does not match standard address"));
}
}
}
const bool deprecated_wallet = restore_deterministic_wallet && ((old_language == crypto::ElectrumWords::old_language_name) ||
crypto::ElectrumWords::get_is_old_style_seed(field_seed));
THROW_WALLET_EXCEPTION_IF(deprecated_wallet, tools::error::wallet_internal_error,
tools::wallet2::tr("Cannot generate deprecated wallets from JSON"));
wallet.reset(make_basic(vm, unattended, opts, password_prompter).release());
wallet->set_refresh_from_block_height(field_scan_from_height);
wallet->explicit_refresh_from_block_height(field_scan_from_height_found);
try
{
if (!field_seed.empty())
{
wallet->generate(field_filename, field_password, recovery_key, recover, false, create_address_file);
password = field_password;
}
else if (field_viewkey.empty() && !field_spendkey.empty())
{
wallet->generate(field_filename, field_password, spendkey, recover, false, create_address_file);
password = field_password;
}
else
{
cryptonote::account_public_address address;
if (!crypto::secret_key_to_public_key(viewkey, address.m_view_public_key)) {
THROW_WALLET_EXCEPTION(tools::error::wallet_internal_error, tools::wallet2::tr("failed to verify view key secret key"));
}
if (field_spendkey.empty())
{
// if we have an address but no spend key, we can deduce the spend public key
// from the address
if (field_address_found)
{
cryptonote::address_parse_info info;
if(!get_account_address_from_str(info, nettype, field_address))
{
THROW_WALLET_EXCEPTION(tools::error::wallet_internal_error, std::string(tools::wallet2::tr("failed to parse address: ")) + field_address);
}
address.m_spend_public_key = info.address.m_spend_public_key;
}
else
{
THROW_WALLET_EXCEPTION(tools::error::wallet_internal_error, tools::wallet2::tr("Address must be specified in order to create watch-only wallet"));
}
wallet->generate(field_filename, field_password, address, viewkey, create_address_file);
password = field_password;
}
else
{
if (!crypto::secret_key_to_public_key(spendkey, address.m_spend_public_key)) {
THROW_WALLET_EXCEPTION(tools::error::wallet_internal_error, tools::wallet2::tr("failed to verify spend key secret key"));
}
wallet->generate(field_filename, field_password, address, spendkey, viewkey, create_address_file);
password = field_password;
}
}
}
catch (const std::exception& e)
{
THROW_WALLET_EXCEPTION(tools::error::wallet_internal_error, std::string(tools::wallet2::tr("failed to generate new wallet: ")) + e.what());
}
return true;
};
if (do_generate())
{
return {std::move(wallet), tools::password_container(password)};
}
return {nullptr, tools::password_container{}};
}
static void throw_on_rpc_response_error(const boost::optional<std::string> &status, const char *method)
{
// no error
if (!status)
return;
// empty string -> not connection
THROW_WALLET_EXCEPTION_IF(status->empty(), tools::error::no_connection_to_daemon, method);
THROW_WALLET_EXCEPTION_IF(*status == CORE_RPC_STATUS_BUSY, tools::error::daemon_busy, method);
THROW_WALLET_EXCEPTION_IF(*status != CORE_RPC_STATUS_OK, tools::error::wallet_generic_rpc_error, method, *status);
}
std::string strjoin(const std::vector<size_t> &V, const char *sep)
{
std::stringstream ss;
bool first = true;
for (const auto &v: V)
{
if (!first)
ss << sep;
ss << std::to_string(v);
first = false;
}
return ss.str();
}
static void emplace_or_replace(std::unordered_multimap<crypto::hash, tools::wallet2::pool_payment_details> &container,
const crypto::hash &key, const tools::wallet2::pool_payment_details &pd)
{
auto range = container.equal_range(key);
for (auto i = range.first; i != range.second; ++i)
{
if (i->second.m_pd.m_tx_hash == pd.m_pd.m_tx_hash && i->second.m_pd.m_subaddr_index == pd.m_pd.m_subaddr_index)
{
i->second = pd;
return;
}
}
container.emplace(key, pd);
}
void drop_from_short_history(std::list<crypto::hash> &short_chain_history, size_t N)
{
std::list<crypto::hash>::iterator right;
// drop early N off, skipping the genesis block
if (short_chain_history.size() > N) {
right = short_chain_history.end();
std::advance(right,-1);
std::list<crypto::hash>::iterator left = right;
std::advance(left, -N);
short_chain_history.erase(left, right);
}
}
size_t estimate_rct_tx_size(int n_inputs, int mixin, int n_outputs, size_t extra_size, bool bulletproof)
{
size_t size = 0;
// tx prefix
// first few bytes
size += 1 + 6;
// vin
size += n_inputs * (1+6+(mixin+1)*2+32);
// vout
size += n_outputs * (6+32);
// extra
size += extra_size;
// rct signatures
// type
size += 1;
// rangeSigs
if (bulletproof)
{
size_t log_padded_outputs = 0;
while ((1<<log_padded_outputs) < n_outputs)
++log_padded_outputs;
size += (2 * (6 + log_padded_outputs) + 4 + 5) * 32 + 3;
}
else
size += (2*64*32+32+64*32) * n_outputs;
// MGs
size += n_inputs * (64 * (mixin+1) + 32);
// mixRing - not serialized, can be reconstructed
/* size += 2 * 32 * (mixin+1) * n_inputs; */
// pseudoOuts
size += 32 * n_inputs;
// ecdhInfo
size += 2 * 32 * n_outputs;
// outPk - only commitment is saved
size += 32 * n_outputs;
// txnFee
size += 4;
LOG_PRINT_L2("estimated " << (bulletproof ? "bulletproof" : "borromean") << " rct tx size for " << n_inputs << " inputs with ring size " << (mixin+1) << " and " << n_outputs << " outputs: " << size << " (" << ((32 * n_inputs/*+1*/) + 2 * 32 * (mixin+1) * n_inputs + 32 * n_outputs) << " saved)");
return size;
}
size_t estimate_tx_size(bool use_rct, int n_inputs, int mixin, int n_outputs, size_t extra_size, bool bulletproof)
{
if (use_rct)
return estimate_rct_tx_size(n_inputs, mixin, n_outputs, extra_size, bulletproof);
else
return n_inputs * (mixin+1) * APPROXIMATE_INPUT_BYTES + extra_size;
}
uint64_t estimate_tx_weight(bool use_rct, int n_inputs, int mixin, int n_outputs, size_t extra_size, bool bulletproof)
{
size_t size = estimate_tx_size(use_rct, n_inputs, mixin, n_outputs, extra_size, bulletproof);
if (use_rct && bulletproof && n_outputs > 2)
{
const uint64_t bp_base = 368;
size_t log_padded_outputs = 2;
while ((1<<log_padded_outputs) < n_outputs)
++log_padded_outputs;
uint64_t nlr = 2 * (6 + log_padded_outputs);
const uint64_t bp_size = 32 * (9 + nlr);
const uint64_t bp_clawback = (bp_base * (1<<log_padded_outputs) - bp_size) * 4 / 5;
MDEBUG("clawback on size " << size << ": " << bp_clawback);
size += bp_clawback;
}
return size;
}
uint8_t get_bulletproof_fork()
{
return 8;
}
uint64_t estimate_fee(bool use_per_byte_fee, bool use_rct, int n_inputs, int mixin, int n_outputs, size_t extra_size, bool bulletproof, uint64_t base_fee, uint64_t fee_multiplier, uint64_t fee_quantization_mask)
{
if (use_per_byte_fee)
{
const size_t estimated_tx_weight = estimate_tx_weight(use_rct, n_inputs, mixin, n_outputs, extra_size, bulletproof);
return calculate_fee_from_weight(base_fee, estimated_tx_weight, fee_multiplier, fee_quantization_mask);
}
else
{
const size_t estimated_tx_size = estimate_tx_size(use_rct, n_inputs, mixin, n_outputs, extra_size, bulletproof);
return calculate_fee(base_fee, estimated_tx_size, fee_multiplier);
}
}
uint64_t calculate_fee(bool use_per_byte_fee, const cryptonote::transaction &tx, size_t blob_size, uint64_t base_fee, uint64_t fee_multiplier, uint64_t fee_quantization_mask)
{
if (use_per_byte_fee)
return calculate_fee_from_weight(base_fee, cryptonote::get_transaction_weight(tx, blob_size), fee_multiplier, fee_quantization_mask);
else
return calculate_fee(base_fee, blob_size, fee_multiplier);
}
crypto::hash8 get_short_payment_id(const tools::wallet2::pending_tx &ptx, hw::device &hwdev)
{
crypto::hash8 payment_id8 = null_hash8;
std::vector<tx_extra_field> tx_extra_fields;
parse_tx_extra(ptx.tx.extra, tx_extra_fields); // ok if partially parsed
cryptonote::tx_extra_nonce extra_nonce;
if (find_tx_extra_field_by_type(tx_extra_fields, extra_nonce))
{
if(get_encrypted_payment_id_from_tx_extra_nonce(extra_nonce.nonce, payment_id8))
{
if (ptx.dests.empty())
{
MWARNING("Encrypted payment id found, but no destinations public key, cannot decrypt");
return crypto::null_hash8;
}
hwdev.decrypt_payment_id(payment_id8, ptx.dests[0].addr.m_view_public_key, ptx.tx_key);
}
}
return payment_id8;
}
tools::wallet2::tx_construction_data get_construction_data_with_decrypted_short_payment_id(const tools::wallet2::pending_tx &ptx, hw::device &hwdev)
{
tools::wallet2::tx_construction_data construction_data = ptx.construction_data;
crypto::hash8 payment_id = get_short_payment_id(ptx,hwdev);
if (payment_id != null_hash8)
{
// Remove encrypted
remove_field_from_tx_extra(construction_data.extra, typeid(cryptonote::tx_extra_nonce));
// Add decrypted
std::string extra_nonce;
set_encrypted_payment_id_to_tx_extra_nonce(extra_nonce, payment_id);
THROW_WALLET_EXCEPTION_IF(!add_extra_nonce_to_tx_extra(construction_data.extra, extra_nonce),
tools::error::wallet_internal_error, "Failed to add decrypted payment id to tx extra");
LOG_PRINT_L1("Decrypted payment ID: " << payment_id);
}
return construction_data;
}
uint32_t get_subaddress_clamped_sum(uint32_t idx, uint32_t extra)
{
static constexpr uint32_t uint32_max = std::numeric_limits<uint32_t>::max();
if (idx > uint32_max - extra)
return uint32_max;
return idx + extra;
}
static void setup_shim(hw::wallet_shim * shim, tools::wallet2 * wallet)
{
shim->get_tx_pub_key_from_received_outs = boost::bind(&tools::wallet2::get_tx_pub_key_from_received_outs, wallet, _1);
}
//-----------------------------------------------------------------
} //namespace
namespace tools
{
// for now, limit to 30 attempts. TODO: discuss a good number to limit to.
const size_t MAX_SPLIT_ATTEMPTS = 30;
constexpr const std::chrono::seconds wallet2::rpc_timeout;
const char* wallet2::tr(const char* str) { return i18n_translate(str, "tools::wallet2"); }
wallet_keys_unlocker::wallet_keys_unlocker(wallet2 &w, const boost::optional<tools::password_container> &password):
w(w),
locked(password != boost::none)
{
if (!locked || w.is_unattended() || w.ask_password() != tools::wallet2::AskPasswordToDecrypt)
{
locked = false;
return;
}
const epee::wipeable_string pass = password->password();
w.generate_chacha_key_from_password(pass, key);
w.decrypt_keys(key);
}
wallet_keys_unlocker::wallet_keys_unlocker(wallet2 &w, bool locked, const epee::wipeable_string &password):
w(w),
locked(locked)
{
if (!locked)
return;
w.generate_chacha_key_from_password(password, key);
w.decrypt_keys(key);
}
wallet_keys_unlocker::~wallet_keys_unlocker()
{
if (!locked)
return;
w.encrypt_keys(key);
}
wallet2::wallet2(network_type nettype, uint64_t kdf_rounds, bool unattended):
m_multisig_rescan_info(NULL),
m_multisig_rescan_k(NULL),
m_upper_transaction_weight_limit(0),
m_run(true),
m_callback(0),
m_trusted_daemon(false),
m_nettype(nettype),
m_multisig_rounds_passed(0),
m_always_confirm_transfers(true),
m_print_ring_members(false),
m_store_tx_info(true),
m_default_mixin(0),
m_default_priority(0),
m_refresh_type(RefreshOptimizeCoinbase),
m_auto_refresh(true),
m_first_refresh_done(false),
m_refresh_from_block_height(0),
m_explicit_refresh_from_block_height(true),
m_confirm_missing_payment_id(true),
m_confirm_non_default_ring_size(true),
m_ask_password(AskPasswordToDecrypt),
m_min_output_count(0),
m_min_output_value(0),
m_merge_destinations(false),
m_confirm_backlog(true),
m_confirm_backlog_threshold(0),
m_confirm_export_overwrite(true),
m_auto_low_priority(true),
m_segregate_pre_fork_outputs(true),
m_key_reuse_mitigation2(true),
m_segregation_height(0),
m_ignore_fractional_outputs(true),
m_is_initialized(false),
m_kdf_rounds(kdf_rounds),
is_old_file_format(false),
m_watch_only(false),
m_multisig(false),
m_multisig_threshold(0),
m_node_rpc_proxy(m_http_client, m_daemon_rpc_mutex),
m_subaddress_lookahead_major(SUBADDRESS_LOOKAHEAD_MAJOR),
m_subaddress_lookahead_minor(SUBADDRESS_LOOKAHEAD_MINOR),
m_light_wallet(false),
m_light_wallet_scanned_block_height(0),
m_light_wallet_blockchain_height(0),
m_light_wallet_connected(false),
m_light_wallet_balance(0),
m_light_wallet_unlocked_balance(0),
m_key_device_type(hw::device::device_type::SOFTWARE),
m_ring_history_saved(false),
m_ringdb(),
m_last_block_reward(0),
m_encrypt_keys_after_refresh(boost::none),
m_unattended(unattended)
{
}
wallet2::~wallet2()
{
}
bool wallet2::has_testnet_option(const boost::program_options::variables_map& vm)
{
return command_line::get_arg(vm, options().testnet);
}
bool wallet2::has_stagenet_option(const boost::program_options::variables_map& vm)
{
return command_line::get_arg(vm, options().stagenet);
}
std::string wallet2::device_name_option(const boost::program_options::variables_map& vm)
{
return command_line::get_arg(vm, options().hw_device);
}
void wallet2::init_options(boost::program_options::options_description& desc_params)
{
const options opts{};
command_line::add_arg(desc_params, opts.daemon_address);
command_line::add_arg(desc_params, opts.daemon_host);
command_line::add_arg(desc_params, opts.trusted_daemon);
command_line::add_arg(desc_params, opts.untrusted_daemon);
command_line::add_arg(desc_params, opts.password);
command_line::add_arg(desc_params, opts.password_file);
command_line::add_arg(desc_params, opts.daemon_port);
command_line::add_arg(desc_params, opts.daemon_login);
command_line::add_arg(desc_params, opts.testnet);
command_line::add_arg(desc_params, opts.stagenet);
command_line::add_arg(desc_params, opts.shared_ringdb_dir);
command_line::add_arg(desc_params, opts.kdf_rounds);
command_line::add_arg(desc_params, opts.hw_device);
command_line::add_arg(desc_params, opts.tx_notify);
}
std::pair<std::unique_ptr<wallet2>, tools::password_container> wallet2::make_from_json(const boost::program_options::variables_map& vm, bool unattended, const std::string& json_file, const std::function<boost::optional<tools::password_container>(const char *, bool)> &password_prompter)
{
const options opts{};
return generate_from_json(json_file, vm, unattended, opts, password_prompter);
}
std::pair<std::unique_ptr<wallet2>, password_container> wallet2::make_from_file(
const boost::program_options::variables_map& vm, bool unattended, const std::string& wallet_file, const std::function<boost::optional<tools::password_container>(const char *, bool)> &password_prompter)
{
const options opts{};
auto pwd = get_password(vm, opts, password_prompter, false);
if (!pwd)
{
return {nullptr, password_container{}};
}
auto wallet = make_basic(vm, unattended, opts, password_prompter);
if (wallet)
{
wallet->load(wallet_file, pwd->password());
}
return {std::move(wallet), std::move(*pwd)};
}
std::pair<std::unique_ptr<wallet2>, password_container> wallet2::make_new(const boost::program_options::variables_map& vm, bool unattended, const std::function<boost::optional<password_container>(const char *, bool)> &password_prompter)
{
const options opts{};
auto pwd = get_password(vm, opts, password_prompter, true);
if (!pwd)
{
return {nullptr, password_container{}};
}
return {make_basic(vm, unattended, opts, password_prompter), std::move(*pwd)};
}
std::unique_ptr<wallet2> wallet2::make_dummy(const boost::program_options::variables_map& vm, bool unattended, const std::function<boost::optional<tools::password_container>(const char *, bool)> &password_prompter)
{
const options opts{};
return make_basic(vm, unattended, opts, password_prompter);
}
//----------------------------------------------------------------------------------------------------
bool wallet2::init(std::string daemon_address, boost::optional<epee::net_utils::http::login> daemon_login, uint64_t upper_transaction_weight_limit, bool ssl, bool trusted_daemon)
{
m_checkpoints.init_default_checkpoints(m_nettype);
if(m_http_client.is_connected())
m_http_client.disconnect();
m_is_initialized = true;
m_upper_transaction_weight_limit = upper_transaction_weight_limit;
m_daemon_address = std::move(daemon_address);
m_daemon_login = std::move(daemon_login);
m_trusted_daemon = trusted_daemon;
// When switching from light wallet to full wallet, we need to reset the height we got from lw node.
return m_http_client.set_server(get_daemon_address(), get_daemon_login(), ssl);
}
//----------------------------------------------------------------------------------------------------
bool wallet2::is_deterministic() const
{
crypto::secret_key second;
keccak((uint8_t *)&get_account().get_keys().m_spend_secret_key, sizeof(crypto::secret_key), (uint8_t *)&second, sizeof(crypto::secret_key));
sc_reduce32((uint8_t *)&second);
return memcmp(second.data,get_account().get_keys().m_view_secret_key.data, sizeof(crypto::secret_key)) == 0;
}
//----------------------------------------------------------------------------------------------------
bool wallet2::get_seed(epee::wipeable_string& electrum_words, const epee::wipeable_string &passphrase) const
{
bool keys_deterministic = is_deterministic();
if (!keys_deterministic)
{
std::cout << "This is not a deterministic wallet" << std::endl;
return false;
}
if (seed_language.empty())
{
std::cout << "seed_language not set" << std::endl;
return false;
}
crypto::secret_key key = get_account().get_keys().m_spend_secret_key;
if (!passphrase.empty())
key = cryptonote::encrypt_key(key, passphrase);
if (!crypto::ElectrumWords::bytes_to_words(key, electrum_words, seed_language))
{
std::cout << "Failed to create seed from key for language: " << seed_language << std::endl;
return false;
}
return true;
}
//----------------------------------------------------------------------------------------------------
bool wallet2::get_multisig_seed(epee::wipeable_string& seed, const epee::wipeable_string &passphrase, bool raw) const
{
bool ready;
uint32_t threshold, total;
if (!multisig(&ready, &threshold, &total))
{
std::cout << "This is not a multisig wallet" << std::endl;
return false;
}
if (!ready)
{
std::cout << "This multisig wallet is not yet finalized" << std::endl;
return false;
}
if (!raw && seed_language.empty())
{
std::cout << "seed_language not set" << std::endl;
return false;
}
crypto::secret_key skey;
crypto::public_key pkey;
const account_keys &keys = get_account().get_keys();
epee::wipeable_string data;
data.append((const char*)&threshold, sizeof(uint32_t));
data.append((const char*)&total, sizeof(uint32_t));
skey = keys.m_spend_secret_key;
data.append((const char*)&skey, sizeof(skey));
pkey = keys.m_account_address.m_spend_public_key;
data.append((const char*)&pkey, sizeof(pkey));
skey = keys.m_view_secret_key;
data.append((const char*)&skey, sizeof(skey));
pkey = keys.m_account_address.m_view_public_key;
data.append((const char*)&pkey, sizeof(pkey));
for (const auto &skey: keys.m_multisig_keys)
data.append((const char*)&skey, sizeof(skey));
for (const auto &signer: m_multisig_signers)
data.append((const char*)&signer, sizeof(signer));
if (!passphrase.empty())
{
crypto::secret_key key;
crypto::cn_slow_hash(passphrase.data(), passphrase.size(), (crypto::hash&)key);
sc_reduce32((unsigned char*)key.data);
data = encrypt(data, key, true);
}
if (raw)
{
seed = epee::to_hex::wipeable_string({(const unsigned char*)data.data(), data.size()});
}
else
{
if (!crypto::ElectrumWords::bytes_to_words(data.data(), data.size(), seed, seed_language))
{
std::cout << "Failed to encode seed";
return false;
}
}
return true;
}
//----------------------------------------------------------------------------------------------------
bool wallet2::reconnect_device()
{
bool r = true;
hw::device &hwdev = lookup_device(m_device_name);
hwdev.set_name(m_device_name);
hwdev.set_network_type(m_nettype);
r = hwdev.init();
if (!r){
LOG_PRINT_L2("Could not init device");
return false;
}
r = hwdev.connect();
if (!r){
LOG_PRINT_L2("Could not connect to the device");
return false;
}
m_account.set_device(hwdev);
return true;
}
//----------------------------------------------------------------------------------------------------
/*!
* \brief Gets the seed language
*/
const std::string &wallet2::get_seed_language() const
{
return seed_language;
}
/*!
* \brief Sets the seed language
* \param language Seed language to set to
*/
void wallet2::set_seed_language(const std::string &language)
{
seed_language = language;
}
//----------------------------------------------------------------------------------------------------
cryptonote::account_public_address wallet2::get_subaddress(const cryptonote::subaddress_index& index) const
{
hw::device &hwdev = m_account.get_device();
return hwdev.get_subaddress(m_account.get_keys(), index);
}
//----------------------------------------------------------------------------------------------------
boost::optional<cryptonote::subaddress_index> wallet2::get_subaddress_index(const cryptonote::account_public_address& address) const
{
auto index = m_subaddresses.find(address.m_spend_public_key);
if (index == m_subaddresses.end())
return boost::none;
return index->second;
}
//----------------------------------------------------------------------------------------------------
crypto::public_key wallet2::get_subaddress_spend_public_key(const cryptonote::subaddress_index& index) const
{
hw::device &hwdev = m_account.get_device();
return hwdev.get_subaddress_spend_public_key(m_account.get_keys(), index);
}
//----------------------------------------------------------------------------------------------------
std::string wallet2::get_subaddress_as_str(const cryptonote::subaddress_index& index) const
{
cryptonote::account_public_address address = get_subaddress(index);
return cryptonote::get_account_address_as_str(m_nettype, !index.is_zero(), address);
}
//----------------------------------------------------------------------------------------------------
std::string wallet2::get_integrated_address_as_str(const crypto::hash8& payment_id) const
{
return cryptonote::get_account_integrated_address_as_str(m_nettype, get_address(), payment_id);
}
//----------------------------------------------------------------------------------------------------
void wallet2::add_subaddress_account(const std::string& label)
{
uint32_t index_major = (uint32_t)get_num_subaddress_accounts();
expand_subaddresses({index_major, 0});
m_subaddress_labels[index_major][0] = label;
}
//----------------------------------------------------------------------------------------------------
void wallet2::add_subaddress(uint32_t index_major, const std::string& label)
{
THROW_WALLET_EXCEPTION_IF(index_major >= m_subaddress_labels.size(), error::account_index_outofbound);
uint32_t index_minor = (uint32_t)get_num_subaddresses(index_major);
expand_subaddresses({index_major, index_minor});
m_subaddress_labels[index_major][index_minor] = label;
}
//----------------------------------------------------------------------------------------------------
void wallet2::expand_subaddresses(const cryptonote::subaddress_index& index)
{
hw::device &hwdev = m_account.get_device();
if (m_subaddress_labels.size() <= index.major)
{
// add new accounts
cryptonote::subaddress_index index2;
const uint32_t major_end = get_subaddress_clamped_sum(index.major, m_subaddress_lookahead_major);
for (index2.major = m_subaddress_labels.size(); index2.major < major_end; ++index2.major)
{
const uint32_t end = get_subaddress_clamped_sum((index2.major == index.major ? index.minor : 0), m_subaddress_lookahead_minor);
const std::vector<crypto::public_key> pkeys = hwdev.get_subaddress_spend_public_keys(m_account.get_keys(), index2.major, 0, end);
for (index2.minor = 0; index2.minor < end; ++index2.minor)
{
const crypto::public_key &D = pkeys[index2.minor];
m_subaddresses[D] = index2;
}
}
m_subaddress_labels.resize(index.major + 1, {"Untitled account"});
m_subaddress_labels[index.major].resize(index.minor + 1);
get_account_tags();
}
else if (m_subaddress_labels[index.major].size() <= index.minor)
{
// add new subaddresses
const uint32_t end = get_subaddress_clamped_sum(index.minor, m_subaddress_lookahead_minor);
const uint32_t begin = m_subaddress_labels[index.major].size();
cryptonote::subaddress_index index2 = {index.major, begin};
const std::vector<crypto::public_key> pkeys = hwdev.get_subaddress_spend_public_keys(m_account.get_keys(), index2.major, index2.minor, end);
for (; index2.minor < end; ++index2.minor)
{
const crypto::public_key &D = pkeys[index2.minor - begin];
m_subaddresses[D] = index2;
}
m_subaddress_labels[index.major].resize(index.minor + 1);
}
}
//----------------------------------------------------------------------------------------------------
std::string wallet2::get_subaddress_label(const cryptonote::subaddress_index& index) const
{
if (index.major >= m_subaddress_labels.size() || index.minor >= m_subaddress_labels[index.major].size())
{
MERROR("Subaddress label doesn't exist");
return "";
}
return m_subaddress_labels[index.major][index.minor];
}
//----------------------------------------------------------------------------------------------------
void wallet2::set_subaddress_label(const cryptonote::subaddress_index& index, const std::string &label)
{
THROW_WALLET_EXCEPTION_IF(index.major >= m_subaddress_labels.size(), error::account_index_outofbound);
THROW_WALLET_EXCEPTION_IF(index.minor >= m_subaddress_labels[index.major].size(), error::address_index_outofbound);
m_subaddress_labels[index.major][index.minor] = label;
}
//----------------------------------------------------------------------------------------------------
void wallet2::set_subaddress_lookahead(size_t major, size_t minor)
{
THROW_WALLET_EXCEPTION_IF(major > 0xffffffff, error::wallet_internal_error, "Subaddress major lookahead is too large");
THROW_WALLET_EXCEPTION_IF(minor > 0xffffffff, error::wallet_internal_error, "Subaddress minor lookahead is too large");
m_subaddress_lookahead_major = major;
m_subaddress_lookahead_minor = minor;
}
//----------------------------------------------------------------------------------------------------
/*!
* \brief Tells if the wallet file is deprecated.
*/
bool wallet2::is_deprecated() const
{
return is_old_file_format;
}
//----------------------------------------------------------------------------------------------------
void wallet2::set_spent(size_t idx, uint64_t height)
{
transfer_details &td = m_transfers[idx];
LOG_PRINT_L2("Setting SPENT at " << height << ": ki " << td.m_key_image << ", amount " << print_money(td.m_amount));
td.m_spent = true;
td.m_spent_height = height;
}
//----------------------------------------------------------------------------------------------------
void wallet2::set_unspent(size_t idx)
{
transfer_details &td = m_transfers[idx];
LOG_PRINT_L2("Setting UNSPENT: ki " << td.m_key_image << ", amount " << print_money(td.m_amount));
td.m_spent = false;
td.m_spent_height = 0;
}
//----------------------------------------------------------------------------------------------------
void wallet2::check_acc_out_precomp(const tx_out &o, const crypto::key_derivation &derivation, const std::vector<crypto::key_derivation> &additional_derivations, size_t i, tx_scan_info_t &tx_scan_info) const
{
hw::device &hwdev = m_account.get_device();
boost::unique_lock<hw::device> hwdev_lock (hwdev);
hwdev.set_mode(hw::device::TRANSACTION_PARSE);
if (o.target.type() != typeid(txout_to_key))
{
tx_scan_info.error = true;
LOG_ERROR("wrong type id in transaction out");
return;
}
tx_scan_info.received = is_out_to_acc_precomp(m_subaddresses, boost::get<txout_to_key>(o.target).key, derivation, additional_derivations, i, hwdev);
if(tx_scan_info.received)
{
tx_scan_info.money_transfered = o.amount; // may be 0 for ringct outputs
}
else
{
tx_scan_info.money_transfered = 0;
}
tx_scan_info.error = false;
}
//----------------------------------------------------------------------------------------------------
void wallet2::check_acc_out_precomp(const tx_out &o, const crypto::key_derivation &derivation, const std::vector<crypto::key_derivation> &additional_derivations, size_t i, const is_out_data *is_out_data, tx_scan_info_t &tx_scan_info) const
{
if (!is_out_data || i >= is_out_data->received.size())
return check_acc_out_precomp(o, derivation, additional_derivations, i, tx_scan_info);
tx_scan_info.received = is_out_data->received[i];
if(tx_scan_info.received)
{
tx_scan_info.money_transfered = o.amount; // may be 0 for ringct outputs
}
else
{
tx_scan_info.money_transfered = 0;
}
tx_scan_info.error = false;
}
//----------------------------------------------------------------------------------------------------
void wallet2::check_acc_out_precomp_once(const tx_out &o, const crypto::key_derivation &derivation, const std::vector<crypto::key_derivation> &additional_derivations, size_t i, const is_out_data *is_out_data, tx_scan_info_t &tx_scan_info, bool &already_seen) const
{
tx_scan_info.received = boost::none;
if (already_seen)
return;
check_acc_out_precomp(o, derivation, additional_derivations, i, is_out_data, tx_scan_info);
if (tx_scan_info.received)
already_seen = true;
}
//----------------------------------------------------------------------------------------------------
static uint64_t decodeRct(const rct::rctSig & rv, const crypto::key_derivation &derivation, unsigned int i, rct::key & mask, hw::device &hwdev)
{
crypto::secret_key scalar1;
hwdev.derivation_to_scalar(derivation, i, scalar1);
try
{
switch (rv.type)
{
case rct::RCTTypeSimple:
case rct::RCTTypeBulletproof:
return rct::decodeRctSimple(rv, rct::sk2rct(scalar1), i, mask, hwdev);
case rct::RCTTypeFull:
return rct::decodeRct(rv, rct::sk2rct(scalar1), i, mask, hwdev);
default:
LOG_ERROR("Unsupported rct type: " << rv.type);
return 0;
}
}
catch (const std::exception &e)
{
LOG_ERROR("Failed to decode input " << i);
return 0;
}
}
//----------------------------------------------------------------------------------------------------
void wallet2::scan_output(const cryptonote::transaction &tx, const crypto::public_key &tx_pub_key, size_t i, tx_scan_info_t &tx_scan_info, int &num_vouts_received, std::unordered_map<cryptonote::subaddress_index, uint64_t> &tx_money_got_in_outs, std::vector<size_t> &outs)
{
THROW_WALLET_EXCEPTION_IF(i >= tx.vout.size(), error::wallet_internal_error, "Invalid vout index");
// if keys are encrypted, ask for password
if (m_ask_password == AskPasswordToDecrypt && !m_unattended && !m_watch_only && !m_multisig_rescan_k)
{
static critical_section password_lock;
CRITICAL_REGION_LOCAL(password_lock);
if (!m_encrypt_keys_after_refresh)
{
boost::optional<epee::wipeable_string> pwd = m_callback->on_get_password("output received");
THROW_WALLET_EXCEPTION_IF(!pwd, error::password_needed, tr("Password is needed to compute key image for incoming monero"));
THROW_WALLET_EXCEPTION_IF(!verify_password(*pwd), error::password_needed, tr("Invalid password: password is needed to compute key image for incoming monero"));
decrypt_keys(*pwd);
m_encrypt_keys_after_refresh = *pwd;
}
}
if (m_multisig)
{
tx_scan_info.in_ephemeral.pub = boost::get<cryptonote::txout_to_key>(tx.vout[i].target).key;
tx_scan_info.in_ephemeral.sec = crypto::null_skey;
tx_scan_info.ki = rct::rct2ki(rct::zero());
}
else
{
bool r = cryptonote::generate_key_image_helper_precomp(m_account.get_keys(), boost::get<cryptonote::txout_to_key>(tx.vout[i].target).key, tx_scan_info.received->derivation, i, tx_scan_info.received->index, tx_scan_info.in_ephemeral, tx_scan_info.ki, m_account.get_device());
THROW_WALLET_EXCEPTION_IF(!r, error::wallet_internal_error, "Failed to generate key image");
THROW_WALLET_EXCEPTION_IF(tx_scan_info.in_ephemeral.pub != boost::get<cryptonote::txout_to_key>(tx.vout[i].target).key,
error::wallet_internal_error, "key_image generated ephemeral public key not matched with output_key");
}
outs.push_back(i);
if (tx_scan_info.money_transfered == 0)
{
tx_scan_info.money_transfered = tools::decodeRct(tx.rct_signatures, tx_scan_info.received->derivation, i, tx_scan_info.mask, m_account.get_device());
}
tx_money_got_in_outs[tx_scan_info.received->index] += tx_scan_info.money_transfered;
tx_scan_info.amount = tx_scan_info.money_transfered;
++num_vouts_received;
}
//----------------------------------------------------------------------------------------------------
void wallet2::cache_tx_data(const cryptonote::transaction& tx, const crypto::hash &txid, tx_cache_data &tx_cache_data) const
{
const cryptonote::account_keys& keys = m_account.get_keys();
if(!parse_tx_extra(tx.extra, tx_cache_data.tx_extra_fields))
{
// Extra may only be partially parsed, it's OK if tx_extra_fields contains public key
LOG_PRINT_L0("Transaction extra has unsupported format: " << txid);
tx_cache_data.tx_extra_fields.clear();
return;
}
// Don't try to extract tx public key if tx has no ouputs
const bool is_miner = tx.vin.size() == 1 && tx.vin[0].type() == typeid(cryptonote::txin_gen);
if (!is_miner || m_refresh_type != RefreshType::RefreshNoCoinbase)
{
const size_t rec_size = is_miner && m_refresh_type == RefreshType::RefreshOptimizeCoinbase ? 1 : tx.vout.size();
if (!tx.vout.empty())
{
// if tx.vout is not empty, we loop through all tx pubkeys
const std::vector<boost::optional<cryptonote::subaddress_receive_info>> rec(rec_size, boost::none);
tx_extra_pub_key pub_key_field;
size_t pk_index = 0;
while (find_tx_extra_field_by_type(tx_cache_data.tx_extra_fields, pub_key_field, pk_index++))
tx_cache_data.primary.push_back({pub_key_field.pub_key, {}, rec});
// additional tx pubkeys and derivations for multi-destination transfers involving one or more subaddresses
tx_extra_additional_pub_keys additional_tx_pub_keys;
std::vector<crypto::key_derivation> additional_derivations;
if (find_tx_extra_field_by_type(tx_cache_data.tx_extra_fields, additional_tx_pub_keys))
{
for (size_t i = 0; i < additional_tx_pub_keys.data.size(); ++i)
tx_cache_data.additional.push_back({additional_tx_pub_keys.data[i], {}, {}});
}
}
}
}
//----------------------------------------------------------------------------------------------------
void wallet2::process_new_transaction(const crypto::hash &txid, const cryptonote::transaction& tx, const std::vector<uint64_t> &o_indices, uint64_t height, uint64_t ts, bool miner_tx, bool pool, bool double_spend_seen, const tx_cache_data &tx_cache_data)
{
// In this function, tx (probably) only contains the base information
// (that is, the prunable stuff may or may not be included)
if (!miner_tx && !pool)
process_unconfirmed(txid, tx, height);
std::unordered_map<cryptonote::subaddress_index, uint64_t> tx_money_got_in_outs; // per receiving subaddress index
crypto::public_key tx_pub_key = null_pkey;
bool notify = false;
std::vector<tx_extra_field> local_tx_extra_fields;
if (tx_cache_data.tx_extra_fields.empty())
{
if(!parse_tx_extra(tx.extra, local_tx_extra_fields))
{
// Extra may only be partially parsed, it's OK if tx_extra_fields contains public key
LOG_PRINT_L0("Transaction extra has unsupported format: " << txid);
}
}
const std::vector<tx_extra_field> &tx_extra_fields = tx_cache_data.tx_extra_fields.empty() ? local_tx_extra_fields : tx_cache_data.tx_extra_fields;
// Don't try to extract tx public key if tx has no ouputs
size_t pk_index = 0;
std::vector<tx_scan_info_t> tx_scan_info(tx.vout.size());
std::deque<bool> output_found(tx.vout.size(), false);
uint64_t total_received_1 = 0;
while (!tx.vout.empty())
{
std::vector<size_t> outs;
// if tx.vout is not empty, we loop through all tx pubkeys
tx_extra_pub_key pub_key_field;
if(!find_tx_extra_field_by_type(tx_extra_fields, pub_key_field, pk_index++))
{
if (pk_index > 1)
break;
LOG_PRINT_L0("Public key wasn't found in the transaction extra. Skipping transaction " << txid);
if(0 != m_callback)
m_callback->on_skip_transaction(height, txid, tx);
break;
}
if (!tx_cache_data.primary.empty())
{
THROW_WALLET_EXCEPTION_IF(tx_cache_data.primary.size() < pk_index || pub_key_field.pub_key != tx_cache_data.primary[pk_index - 1].pkey,
error::wallet_internal_error, "tx_cache_data is out of sync");
}
int num_vouts_received = 0;
tx_pub_key = pub_key_field.pub_key;
tools::threadpool& tpool = tools::threadpool::getInstance();
tools::threadpool::waiter waiter;
const cryptonote::account_keys& keys = m_account.get_keys();
crypto::key_derivation derivation;
std::vector<crypto::key_derivation> additional_derivations;
tx_extra_additional_pub_keys additional_tx_pub_keys;
const wallet2::is_out_data *is_out_data_ptr = NULL;
if (tx_cache_data.primary.empty())
{
hw::device &hwdev = m_account.get_device();
boost::unique_lock<hw::device> hwdev_lock (hwdev);
hw::reset_mode rst(hwdev);
hwdev.set_mode(hw::device::TRANSACTION_PARSE);
if (!hwdev.generate_key_derivation(tx_pub_key, keys.m_view_secret_key, derivation))
{
MWARNING("Failed to generate key derivation from tx pubkey in " << txid << ", skipping");
static_assert(sizeof(derivation) == sizeof(rct::key), "Mismatched sizes of key_derivation and rct::key");
memcpy(&derivation, rct::identity().bytes, sizeof(derivation));
}
if (pk_index == 1)
{
// additional tx pubkeys and derivations for multi-destination transfers involving one or more subaddresses
if (find_tx_extra_field_by_type(tx_extra_fields, additional_tx_pub_keys))
{
for (size_t i = 0; i < additional_tx_pub_keys.data.size(); ++i)
{
additional_derivations.push_back({});
if (!hwdev.generate_key_derivation(additional_tx_pub_keys.data[i], keys.m_view_secret_key, additional_derivations.back()))
{
MWARNING("Failed to generate key derivation from additional tx pubkey in " << txid << ", skipping");
memcpy(&additional_derivations.back(), rct::identity().bytes, sizeof(crypto::key_derivation));
}
}
}
}
}
else
{
THROW_WALLET_EXCEPTION_IF(pk_index - 1 >= tx_cache_data.primary.size(),
error::wallet_internal_error, "pk_index out of range of tx_cache_data");
is_out_data_ptr = &tx_cache_data.primary[pk_index - 1];
derivation = tx_cache_data.primary[pk_index - 1].derivation;
if (pk_index == 1)
{
for (size_t n = 0; n < tx_cache_data.additional.size(); ++n)
{
additional_tx_pub_keys.data.push_back(tx_cache_data.additional[n].pkey);
additional_derivations.push_back(tx_cache_data.additional[n].derivation);
}
}
}
if (miner_tx && m_refresh_type == RefreshNoCoinbase)
{
// assume coinbase isn't for us
}
else if (miner_tx && m_refresh_type == RefreshOptimizeCoinbase)
{
check_acc_out_precomp_once(tx.vout[0], derivation, additional_derivations, 0, is_out_data_ptr, tx_scan_info[0], output_found[0]);
THROW_WALLET_EXCEPTION_IF(tx_scan_info[0].error, error::acc_outs_lookup_error, tx, tx_pub_key, m_account.get_keys());
// this assumes that the miner tx pays a single address
if (tx_scan_info[0].received)
{
// process the other outs from that tx
// the first one was already checked
for (size_t i = 1; i < tx.vout.size(); ++i)
{
tpool.submit(&waiter, boost::bind(&wallet2::check_acc_out_precomp_once, this, std::cref(tx.vout[i]), std::cref(derivation), std::cref(additional_derivations), i,
std::cref(is_out_data_ptr), std::ref(tx_scan_info[i]), std::ref(output_found[i])), true);
}
waiter.wait(&tpool);
// then scan all outputs from 0
hw::device &hwdev = m_account.get_device();
boost::unique_lock<hw::device> hwdev_lock (hwdev);
hwdev.set_mode(hw::device::NONE);
for (size_t i = 0; i < tx.vout.size(); ++i)
{
THROW_WALLET_EXCEPTION_IF(tx_scan_info[i].error, error::acc_outs_lookup_error, tx, tx_pub_key, m_account.get_keys());
if (tx_scan_info[i].received)
{
hwdev.conceal_derivation(tx_scan_info[i].received->derivation, tx_pub_key, additional_tx_pub_keys.data, derivation, additional_derivations);
scan_output(tx, tx_pub_key, i, tx_scan_info[i], num_vouts_received, tx_money_got_in_outs, outs);
}
}
}
}
else if (tx.vout.size() > 1 && tools::threadpool::getInstance().get_max_concurrency() > 1 && !is_out_data_ptr)
{
for (size_t i = 0; i < tx.vout.size(); ++i)
{
tpool.submit(&waiter, boost::bind(&wallet2::check_acc_out_precomp_once, this, std::cref(tx.vout[i]), std::cref(derivation), std::cref(additional_derivations), i,
std::cref(is_out_data_ptr), std::ref(tx_scan_info[i]), std::ref(output_found[i])), true);
}
waiter.wait(&tpool);
hw::device &hwdev = m_account.get_device();
boost::unique_lock<hw::device> hwdev_lock (hwdev);
hwdev.set_mode(hw::device::NONE);
for (size_t i = 0; i < tx.vout.size(); ++i)
{
THROW_WALLET_EXCEPTION_IF(tx_scan_info[i].error, error::acc_outs_lookup_error, tx, tx_pub_key, m_account.get_keys());
if (tx_scan_info[i].received)
{
hwdev.conceal_derivation(tx_scan_info[i].received->derivation, tx_pub_key, additional_tx_pub_keys.data, derivation, additional_derivations);
scan_output(tx, tx_pub_key, i, tx_scan_info[i], num_vouts_received, tx_money_got_in_outs, outs);
}
}
}
else
{
for (size_t i = 0; i < tx.vout.size(); ++i)
{
check_acc_out_precomp_once(tx.vout[i], derivation, additional_derivations, i, is_out_data_ptr, tx_scan_info[i], output_found[i]);
THROW_WALLET_EXCEPTION_IF(tx_scan_info[i].error, error::acc_outs_lookup_error, tx, tx_pub_key, m_account.get_keys());
if (tx_scan_info[i].received)
{
hw::device &hwdev = m_account.get_device();
boost::unique_lock<hw::device> hwdev_lock (hwdev);
hwdev.set_mode(hw::device::NONE);
hwdev.conceal_derivation(tx_scan_info[i].received->derivation, tx_pub_key, additional_tx_pub_keys.data, derivation, additional_derivations);
scan_output(tx, tx_pub_key, i, tx_scan_info[i], num_vouts_received, tx_money_got_in_outs, outs);
}
}
}
if(!outs.empty() && num_vouts_received > 0)
{
//good news - got money! take care about it
//usually we have only one transfer for user in transaction
if (!pool)
{
THROW_WALLET_EXCEPTION_IF(tx.vout.size() != o_indices.size(), error::wallet_internal_error,
"transactions outputs size=" + std::to_string(tx.vout.size()) +
" not match with daemon response size=" + std::to_string(o_indices.size()));
}
for(size_t o: outs)
{
THROW_WALLET_EXCEPTION_IF(tx.vout.size() <= o, error::wallet_internal_error, "wrong out in transaction: internal index=" +
std::to_string(o) + ", total_outs=" + std::to_string(tx.vout.size()));
auto kit = m_pub_keys.find(tx_scan_info[o].in_ephemeral.pub);
THROW_WALLET_EXCEPTION_IF(kit != m_pub_keys.end() && kit->second >= m_transfers.size(),
error::wallet_internal_error, std::string("Unexpected transfer index from public key: ")
+ "got " + (kit == m_pub_keys.end() ? "<none>" : boost::lexical_cast<std::string>(kit->second))
+ ", m_transfers.size() is " + boost::lexical_cast<std::string>(m_transfers.size()));
if (kit == m_pub_keys.end())
{
uint64_t amount = tx.vout[o].amount ? tx.vout[o].amount : tx_scan_info[o].amount;
if (!pool)
{
m_transfers.push_back(boost::value_initialized<transfer_details>());
transfer_details& td = m_transfers.back();
td.m_block_height = height;
td.m_internal_output_index = o;
td.m_global_output_index = o_indices[o];
td.m_tx = (const cryptonote::transaction_prefix&)tx;
td.m_txid = txid;
td.m_key_image = tx_scan_info[o].ki;
td.m_key_image_known = !m_watch_only && !m_multisig;
td.m_key_image_requested = false;
td.m_key_image_partial = m_multisig;
td.m_amount = amount;
td.m_pk_index = pk_index - 1;
td.m_subaddr_index = tx_scan_info[o].received->index;
expand_subaddresses(tx_scan_info[o].received->index);
if (tx.vout[o].amount == 0)
{
td.m_mask = tx_scan_info[o].mask;
td.m_rct = true;
}
else if (miner_tx && tx.version == 2)
{
td.m_mask = rct::identity();
td.m_rct = true;
}
else
{
td.m_mask = rct::identity();
td.m_rct = false;
}
set_unspent(m_transfers.size()-1);
if (!m_multisig && !m_watch_only)
m_key_images[td.m_key_image] = m_transfers.size()-1;
m_pub_keys[tx_scan_info[o].in_ephemeral.pub] = m_transfers.size()-1;
if (m_multisig)
{
THROW_WALLET_EXCEPTION_IF(!m_multisig_rescan_k && m_multisig_rescan_info,
error::wallet_internal_error, "NULL m_multisig_rescan_k");
if (m_multisig_rescan_info && m_multisig_rescan_info->front().size() >= m_transfers.size())
update_multisig_rescan_info(*m_multisig_rescan_k, *m_multisig_rescan_info, m_transfers.size() - 1);
}
LOG_PRINT_L0("Received money: " << print_money(td.amount()) << ", with tx: " << txid);
if (0 != m_callback)
m_callback->on_money_received(height, txid, tx, td.m_amount, td.m_subaddr_index);
}
total_received_1 += amount;
notify = true;
}
else if (m_transfers[kit->second].m_spent || m_transfers[kit->second].amount() >= tx_scan_info[o].amount)
{
LOG_ERROR("Public key " << epee::string_tools::pod_to_hex(kit->first)
<< " from received " << print_money(tx_scan_info[o].amount) << " output already exists with "
<< (m_transfers[kit->second].m_spent ? "spent" : "unspent") << " "
<< print_money(m_transfers[kit->second].amount()) << " in tx " << m_transfers[kit->second].m_txid << ", received output ignored");
THROW_WALLET_EXCEPTION_IF(tx_money_got_in_outs[tx_scan_info[o].received->index] < tx_scan_info[o].amount,
error::wallet_internal_error, "Unexpected values of new and old outputs");
tx_money_got_in_outs[tx_scan_info[o].received->index] -= tx_scan_info[o].amount;
}
else
{
LOG_ERROR("Public key " << epee::string_tools::pod_to_hex(kit->first)
<< " from received " << print_money(tx_scan_info[o].amount) << " output already exists with "
<< print_money(m_transfers[kit->second].amount()) << ", replacing with new output");
// The new larger output replaced a previous smaller one
THROW_WALLET_EXCEPTION_IF(tx_money_got_in_outs[tx_scan_info[o].received->index] < tx_scan_info[o].amount,
error::wallet_internal_error, "Unexpected values of new and old outputs");
THROW_WALLET_EXCEPTION_IF(m_transfers[kit->second].amount() > tx_scan_info[o].amount,
error::wallet_internal_error, "Unexpected values of new and old outputs");
tx_money_got_in_outs[tx_scan_info[o].received->index] -= m_transfers[kit->second].amount();
uint64_t amount = tx.vout[o].amount ? tx.vout[o].amount : tx_scan_info[o].amount;
uint64_t extra_amount = amount - m_transfers[kit->second].amount();
if (!pool)
{
transfer_details &td = m_transfers[kit->second];
td.m_block_height = height;
td.m_internal_output_index = o;
td.m_global_output_index = o_indices[o];
td.m_tx = (const cryptonote::transaction_prefix&)tx;
td.m_txid = txid;
td.m_amount = amount;
td.m_pk_index = pk_index - 1;
td.m_subaddr_index = tx_scan_info[o].received->index;
expand_subaddresses(tx_scan_info[o].received->index);
if (tx.vout[o].amount == 0)
{
td.m_mask = tx_scan_info[o].mask;
td.m_rct = true;
}
else if (miner_tx && tx.version == 2)
{
td.m_mask = rct::identity();
td.m_rct = true;
}
else
{
td.m_mask = rct::identity();
td.m_rct = false;
}
if (m_multisig)
{
THROW_WALLET_EXCEPTION_IF(!m_multisig_rescan_k && m_multisig_rescan_info,
error::wallet_internal_error, "NULL m_multisig_rescan_k");
if (m_multisig_rescan_info && m_multisig_rescan_info->front().size() >= m_transfers.size())
update_multisig_rescan_info(*m_multisig_rescan_k, *m_multisig_rescan_info, m_transfers.size() - 1);
}
THROW_WALLET_EXCEPTION_IF(td.get_public_key() != tx_scan_info[o].in_ephemeral.pub, error::wallet_internal_error, "Inconsistent public keys");
THROW_WALLET_EXCEPTION_IF(td.m_spent, error::wallet_internal_error, "Inconsistent spent status");
LOG_PRINT_L0("Received money: " << print_money(td.amount()) << ", with tx: " << txid);
if (0 != m_callback)
m_callback->on_money_received(height, txid, tx, td.m_amount, td.m_subaddr_index);
}
total_received_1 += extra_amount;
notify = true;
}
}
}
}
uint64_t tx_money_spent_in_ins = 0;
// The line below is equivalent to "boost::optional<uint32_t> subaddr_account;", but avoids the GCC warning: ‘*((void*)& subaddr_account +4)’ may be used uninitialized in this function
// It's a GCC bug with boost::optional, see https://gcc.gnu.org/bugzilla/show_bug.cgi?id=47679
auto subaddr_account ([]()->boost::optional<uint32_t> {return boost::none;}());
std::set<uint32_t> subaddr_indices;
// check all outputs for spending (compare key images)
for(auto& in: tx.vin)
{
if(in.type() != typeid(cryptonote::txin_to_key))
continue;
auto it = m_key_images.find(boost::get<cryptonote::txin_to_key>(in).k_image);
if(it != m_key_images.end())
{
transfer_details& td = m_transfers[it->second];
uint64_t amount = boost::get<cryptonote::txin_to_key>(in).amount;
if (amount > 0)
{
if(amount != td.amount())
{
MERROR("Inconsistent amount in tx input: got " << print_money(amount) <<
", expected " << print_money(td.amount()));
// this means:
// 1) the same output pub key was used as destination multiple times,
// 2) the wallet set the highest amount among them to transfer_details::m_amount, and
// 3) the wallet somehow spent that output with an amount smaller than the above amount, causing inconsistency
td.m_amount = amount;
}
}
else
{
amount = td.amount();
}
tx_money_spent_in_ins += amount;
if (subaddr_account && *subaddr_account != td.m_subaddr_index.major)
LOG_ERROR("spent funds are from different subaddress accounts; count of incoming/outgoing payments will be incorrect");
subaddr_account = td.m_subaddr_index.major;
subaddr_indices.insert(td.m_subaddr_index.minor);
if (!pool)
{
LOG_PRINT_L0("Spent money: " << print_money(amount) << ", with tx: " << txid);
set_spent(it->second, height);
if (0 != m_callback)
m_callback->on_money_spent(height, txid, tx, amount, tx, td.m_subaddr_index);
}
}
}
uint64_t fee = miner_tx ? 0 : tx.version == 1 ? tx_money_spent_in_ins - get_outs_money_amount(tx) : tx.rct_signatures.txnFee;
if (tx_money_spent_in_ins > 0 && !pool)
{
uint64_t self_received = std::accumulate<decltype(tx_money_got_in_outs.begin()), uint64_t>(tx_money_got_in_outs.begin(), tx_money_got_in_outs.end(), 0,
[&subaddr_account] (uint64_t acc, const std::pair<cryptonote::subaddress_index, uint64_t>& p)
{
return acc + (p.first.major == *subaddr_account ? p.second : 0);
});
process_outgoing(txid, tx, height, ts, tx_money_spent_in_ins, self_received, *subaddr_account, subaddr_indices);
// if sending to yourself at the same subaddress account, set the outgoing payment amount to 0 so that it's less confusing
if (tx_money_spent_in_ins == self_received + fee)
{
auto i = m_confirmed_txs.find(txid);
THROW_WALLET_EXCEPTION_IF(i == m_confirmed_txs.end(), error::wallet_internal_error,
"confirmed tx wasn't found: " + string_tools::pod_to_hex(txid));
i->second.m_change = self_received;
}
}
// remove change sent to the spending subaddress account from the list of received funds
uint64_t sub_change = 0;
for (auto i = tx_money_got_in_outs.begin(); i != tx_money_got_in_outs.end();)
{
if (subaddr_account && i->first.major == *subaddr_account)
{
sub_change += i->second;
i = tx_money_got_in_outs.erase(i);
}
else
++i;
}
// create payment_details for each incoming transfer to a subaddress index
if (tx_money_got_in_outs.size() > 0)
{
tx_extra_nonce extra_nonce;
crypto::hash payment_id = null_hash;
if (find_tx_extra_field_by_type(tx_extra_fields, extra_nonce))
{
crypto::hash8 payment_id8 = null_hash8;
if(get_encrypted_payment_id_from_tx_extra_nonce(extra_nonce.nonce, payment_id8))
{
// We got a payment ID to go with this tx
LOG_PRINT_L2("Found encrypted payment ID: " << payment_id8);
MINFO("Consider using subaddresses instead of encrypted payment IDs");
if (tx_pub_key != null_pkey)
{
if (!m_account.get_device().decrypt_payment_id(payment_id8, tx_pub_key, m_account.get_keys().m_view_secret_key))
{
LOG_PRINT_L0("Failed to decrypt payment ID: " << payment_id8);
}
else
{
LOG_PRINT_L2("Decrypted payment ID: " << payment_id8);
// put the 64 bit decrypted payment id in the first 8 bytes
memcpy(payment_id.data, payment_id8.data, 8);
// rest is already 0, but guard against code changes above
memset(payment_id.data + 8, 0, 24);
}
}
else
{
LOG_PRINT_L1("No public key found in tx, unable to decrypt payment id");
}
}
else if (get_payment_id_from_tx_extra_nonce(extra_nonce.nonce, payment_id))
{
LOG_PRINT_L2("Found unencrypted payment ID: " << payment_id);
MWARNING("Found unencrypted payment ID: these are bad for privacy, consider using subaddresses instead");
}
}
uint64_t total_received_2 = sub_change;
for (const auto& i : tx_money_got_in_outs)
total_received_2 += i.second;
if (total_received_1 != total_received_2)
{
const el::Level level = el::Level::Warning;
MCLOG_RED(level, "global", "**********************************************************************");
MCLOG_RED(level, "global", "Consistency failure in amounts received");
MCLOG_RED(level, "global", "Check transaction " << txid);
MCLOG_RED(level, "global", "**********************************************************************");
exit(1);
return;
}
for (const auto& i : tx_money_got_in_outs)
{
payment_details payment;
payment.m_tx_hash = txid;
payment.m_fee = fee;
payment.m_amount = i.second;
payment.m_block_height = height;
payment.m_unlock_time = tx.unlock_time;
payment.m_timestamp = ts;
payment.m_coinbase = miner_tx;
payment.m_subaddr_index = i.first;
if (pool) {
emplace_or_replace(m_unconfirmed_payments, payment_id, pool_payment_details{payment, double_spend_seen});
if (0 != m_callback)
m_callback->on_unconfirmed_money_received(height, txid, tx, payment.m_amount, payment.m_subaddr_index);
}
else
m_payments.emplace(payment_id, payment);
LOG_PRINT_L2("Payment found in " << (pool ? "pool" : "block") << ": " << payment_id << " / " << payment.m_tx_hash << " / " << payment.m_amount);
}
}
if (notify)
{
std::shared_ptr<tools::Notify> tx_notify = m_tx_notify;
if (tx_notify)
tx_notify->notify(epee::string_tools::pod_to_hex(txid).c_str());
}
}
//----------------------------------------------------------------------------------------------------
void wallet2::process_unconfirmed(const crypto::hash &txid, const cryptonote::transaction& tx, uint64_t height)
{
if (m_unconfirmed_txs.empty())
return;
auto unconf_it = m_unconfirmed_txs.find(txid);
if(unconf_it != m_unconfirmed_txs.end()) {
if (store_tx_info()) {
try {
m_confirmed_txs.insert(std::make_pair(txid, confirmed_transfer_details(unconf_it->second, height)));
}
catch (...) {
// can fail if the tx has unexpected input types
LOG_PRINT_L0("Failed to add outgoing transaction to confirmed transaction map");
}
}
m_unconfirmed_txs.erase(unconf_it);
}
}
//----------------------------------------------------------------------------------------------------
void wallet2::process_outgoing(const crypto::hash &txid, const cryptonote::transaction &tx, uint64_t height, uint64_t ts, uint64_t spent, uint64_t received, uint32_t subaddr_account, const std::set<uint32_t>& subaddr_indices)
{
std::pair<std::unordered_map<crypto::hash, confirmed_transfer_details>::iterator, bool> entry = m_confirmed_txs.insert(std::make_pair(txid, confirmed_transfer_details()));
// fill with the info we know, some info might already be there
if (entry.second)
{
// this case will happen if the tx is from our outputs, but was sent by another
// wallet (eg, we're a cold wallet and the hot wallet sent it). For RCT transactions,
// we only see 0 input amounts, so have to deduce amount out from other parameters.
entry.first->second.m_amount_in = spent;
if (tx.version == 1)
entry.first->second.m_amount_out = get_outs_money_amount(tx);
else
entry.first->second.m_amount_out = spent - tx.rct_signatures.txnFee;
entry.first->second.m_change = received;
std::vector<tx_extra_field> tx_extra_fields;
parse_tx_extra(tx.extra, tx_extra_fields); // ok if partially parsed
tx_extra_nonce extra_nonce;
if (find_tx_extra_field_by_type(tx_extra_fields, extra_nonce))
{
// we do not care about failure here
get_payment_id_from_tx_extra_nonce(extra_nonce.nonce, entry.first->second.m_payment_id);
}
entry.first->second.m_subaddr_account = subaddr_account;
entry.first->second.m_subaddr_indices = subaddr_indices;
}
for (const auto &in: tx.vin)
{
if (in.type() != typeid(cryptonote::txin_to_key))
continue;
const auto &txin = boost::get<cryptonote::txin_to_key>(in);
entry.first->second.m_rings.push_back(std::make_pair(txin.k_image, txin.key_offsets));
}
entry.first->second.m_block_height = height;
entry.first->second.m_timestamp = ts;
entry.first->second.m_unlock_time = tx.unlock_time;
add_rings(tx);
}
//----------------------------------------------------------------------------------------------------
void wallet2::process_new_blockchain_entry(const cryptonote::block& b, const cryptonote::block_complete_entry& bche, const parsed_block &parsed_block, const crypto::hash& bl_id, uint64_t height, const std::vector<tx_cache_data> &tx_cache_data, size_t tx_cache_data_offset)
{
THROW_WALLET_EXCEPTION_IF(bche.txs.size() + 1 != parsed_block.o_indices.indices.size(), error::wallet_internal_error,
"block transactions=" + std::to_string(bche.txs.size()) +
" not match with daemon response size=" + std::to_string(parsed_block.o_indices.indices.size()));
//handle transactions from new block
//optimization: seeking only for blocks that are not older then the wallet creation time plus 1 day. 1 day is for possible user incorrect time setup
if(b.timestamp + 60*60*24 > m_account.get_createtime() && height >= m_refresh_from_block_height)
{
TIME_MEASURE_START(miner_tx_handle_time);
if (m_refresh_type != RefreshNoCoinbase)
process_new_transaction(get_transaction_hash(b.miner_tx), b.miner_tx, parsed_block.o_indices.indices[0].indices, height, b.timestamp, true, false, false, tx_cache_data[tx_cache_data_offset]);
++tx_cache_data_offset;
TIME_MEASURE_FINISH(miner_tx_handle_time);
TIME_MEASURE_START(txs_handle_time);
THROW_WALLET_EXCEPTION_IF(bche.txs.size() != b.tx_hashes.size(), error::wallet_internal_error, "Wrong amount of transactions for block");
THROW_WALLET_EXCEPTION_IF(bche.txs.size() != parsed_block.txes.size(), error::wallet_internal_error, "Wrong amount of transactions for block");
for (size_t idx = 0; idx < b.tx_hashes.size(); ++idx)
{
process_new_transaction(b.tx_hashes[idx], parsed_block.txes[idx], parsed_block.o_indices.indices[idx+1].indices, height, b.timestamp, false, false, false, tx_cache_data[tx_cache_data_offset++]);
}
TIME_MEASURE_FINISH(txs_handle_time);
m_last_block_reward = cryptonote::get_outs_money_amount(b.miner_tx);
LOG_PRINT_L2("Processed block: " << bl_id << ", height " << height << ", " << miner_tx_handle_time + txs_handle_time << "(" << miner_tx_handle_time << "/" << txs_handle_time <<")ms");
}else
{
if (!(height % 128))
LOG_PRINT_L2( "Skipped block by timestamp, height: " << height << ", block time " << b.timestamp << ", account time " << m_account.get_createtime());
}
m_blockchain.push_back(bl_id);
if (0 != m_callback)
m_callback->on_new_block(height, b);
}
//----------------------------------------------------------------------------------------------------
void wallet2::get_short_chain_history(std::list<crypto::hash>& ids, uint64_t granularity) const
{
size_t i = 0;
size_t current_multiplier = 1;
size_t blockchain_size = std::max((size_t)(m_blockchain.size() / granularity * granularity), m_blockchain.offset());
size_t sz = blockchain_size - m_blockchain.offset();
if(!sz)
{
ids.push_back(m_blockchain.genesis());
return;
}
size_t current_back_offset = 1;
bool base_included = false;
while(current_back_offset < sz)
{
ids.push_back(m_blockchain[m_blockchain.offset() + sz-current_back_offset]);
if(sz-current_back_offset == 0)
base_included = true;
if(i < 10)
{
++current_back_offset;
}else
{
current_back_offset += current_multiplier *= 2;
}
++i;
}
if(!base_included)
ids.push_back(m_blockchain[m_blockchain.offset()]);
if(m_blockchain.offset())
ids.push_back(m_blockchain.genesis());
}
//----------------------------------------------------------------------------------------------------
void wallet2::parse_block_round(const cryptonote::blobdata &blob, cryptonote::block &bl, crypto::hash &bl_id, bool &error) const
{
error = !cryptonote::parse_and_validate_block_from_blob(blob, bl);
if (!error)
bl_id = get_block_hash(bl);
}
//----------------------------------------------------------------------------------------------------
void wallet2::pull_blocks(uint64_t start_height, uint64_t &blocks_start_height, const std::list<crypto::hash> &short_chain_history, std::vector<cryptonote::block_complete_entry> &blocks, std::vector<cryptonote::COMMAND_RPC_GET_BLOCKS_FAST::block_output_indices> &o_indices)
{
cryptonote::COMMAND_RPC_GET_BLOCKS_FAST::request req = AUTO_VAL_INIT(req);
cryptonote::COMMAND_RPC_GET_BLOCKS_FAST::response res = AUTO_VAL_INIT(res);
req.block_ids = short_chain_history;
req.prune = true;
req.start_height = start_height;
req.no_miner_tx = m_refresh_type == RefreshNoCoinbase;
m_daemon_rpc_mutex.lock();
bool r = net_utils::invoke_http_bin("/getblocks.bin", req, res, m_http_client, rpc_timeout);
m_daemon_rpc_mutex.unlock();
THROW_WALLET_EXCEPTION_IF(!r, error::no_connection_to_daemon, "getblocks.bin");
THROW_WALLET_EXCEPTION_IF(res.status == CORE_RPC_STATUS_BUSY, error::daemon_busy, "getblocks.bin");
THROW_WALLET_EXCEPTION_IF(res.status != CORE_RPC_STATUS_OK, error::get_blocks_error, res.status);
THROW_WALLET_EXCEPTION_IF(res.blocks.size() != res.output_indices.size(), error::wallet_internal_error,
"mismatched blocks (" + boost::lexical_cast<std::string>(res.blocks.size()) + ") and output_indices (" +
boost::lexical_cast<std::string>(res.output_indices.size()) + ") sizes from daemon");
blocks_start_height = res.start_height;
blocks = std::move(res.blocks);
o_indices = std::move(res.output_indices);
}
//----------------------------------------------------------------------------------------------------
void wallet2::pull_hashes(uint64_t start_height, uint64_t &blocks_start_height, const std::list<crypto::hash> &short_chain_history, std::vector<crypto::hash> &hashes)
{
cryptonote::COMMAND_RPC_GET_HASHES_FAST::request req = AUTO_VAL_INIT(req);
cryptonote::COMMAND_RPC_GET_HASHES_FAST::response res = AUTO_VAL_INIT(res);
req.block_ids = short_chain_history;
req.start_height = start_height;
m_daemon_rpc_mutex.lock();
bool r = net_utils::invoke_http_bin("/gethashes.bin", req, res, m_http_client, rpc_timeout);
m_daemon_rpc_mutex.unlock();
THROW_WALLET_EXCEPTION_IF(!r, error::no_connection_to_daemon, "gethashes.bin");
THROW_WALLET_EXCEPTION_IF(res.status == CORE_RPC_STATUS_BUSY, error::daemon_busy, "gethashes.bin");
THROW_WALLET_EXCEPTION_IF(res.status != CORE_RPC_STATUS_OK, error::get_hashes_error, res.status);
blocks_start_height = res.start_height;
hashes = std::move(res.m_block_ids);
}
//----------------------------------------------------------------------------------------------------
void wallet2::process_parsed_blocks(uint64_t start_height, const std::vector<cryptonote::block_complete_entry> &blocks, const std::vector<parsed_block> &parsed_blocks, uint64_t& blocks_added)
{
size_t current_index = start_height;
blocks_added = 0;
THROW_WALLET_EXCEPTION_IF(blocks.size() != parsed_blocks.size(), error::wallet_internal_error, "size mismatch");
THROW_WALLET_EXCEPTION_IF(!m_blockchain.is_in_bounds(current_index), error::out_of_hashchain_bounds_error);
tools::threadpool& tpool = tools::threadpool::getInstance();
tools::threadpool::waiter waiter;
size_t num_txes = 0;
std::vector<tx_cache_data> tx_cache_data;
for (size_t i = 0; i < blocks.size(); ++i)
num_txes += 1 + parsed_blocks[i].txes.size();
tx_cache_data.resize(num_txes);
size_t txidx = 0;
for (size_t i = 0; i < blocks.size(); ++i)
{
THROW_WALLET_EXCEPTION_IF(parsed_blocks[i].txes.size() != parsed_blocks[i].block.tx_hashes.size(),
error::wallet_internal_error, "Mismatched parsed_blocks[i].txes.size() and parsed_blocks[i].block.tx_hashes.size()");
if (m_refresh_type != RefreshNoCoinbase)
tpool.submit(&waiter, [&, i, txidx](){ cache_tx_data(parsed_blocks[i].block.miner_tx, get_transaction_hash(parsed_blocks[i].block.miner_tx), tx_cache_data[txidx]); });
++txidx;
for (size_t idx = 0; idx < parsed_blocks[i].txes.size(); ++idx)
{
tpool.submit(&waiter, [&, i, idx, txidx](){ cache_tx_data(parsed_blocks[i].txes[idx], parsed_blocks[i].block.tx_hashes[idx], tx_cache_data[txidx]); });
++txidx;
}
}
THROW_WALLET_EXCEPTION_IF(txidx != num_txes, error::wallet_internal_error, "txidx does not match tx_cache_data size");
waiter.wait(&tpool);
hw::device &hwdev = m_account.get_device();
hw::reset_mode rst(hwdev);
hwdev.set_mode(hw::device::TRANSACTION_PARSE);
const cryptonote::account_keys &keys = m_account.get_keys();
auto gender = [&](wallet2::is_out_data &iod) {
boost::unique_lock<hw::device> hwdev_lock(hwdev);
if (!hwdev.generate_key_derivation(iod.pkey, keys.m_view_secret_key, iod.derivation))
{
MWARNING("Failed to generate key derivation from tx pubkey, skipping");
static_assert(sizeof(iod.derivation) == sizeof(rct::key), "Mismatched sizes of key_derivation and rct::key");
memcpy(&iod.derivation, rct::identity().bytes, sizeof(iod.derivation));
}
};
for (auto &slot: tx_cache_data)
{
for (auto &iod: slot.primary)
tpool.submit(&waiter, [&gender, &iod]() { gender(iod); }, true);
for (auto &iod: slot.additional)
tpool.submit(&waiter, [&gender, &iod]() { gender(iod); }, true);
}
waiter.wait(&tpool);
auto geniod = [&](const cryptonote::transaction &tx, size_t n_vouts, size_t txidx) {
for (size_t k = 0; k < n_vouts; ++k)
{
const auto &o = tx.vout[k];
if (o.target.type() == typeid(cryptonote::txout_to_key))
{
std::vector<crypto::key_derivation> additional_derivations;
for (const auto &iod: tx_cache_data[txidx].additional)
additional_derivations.push_back(iod.derivation);
const auto &key = boost::get<txout_to_key>(o.target).key;
for (size_t l = 0; l < tx_cache_data[txidx].primary.size(); ++l)
{
THROW_WALLET_EXCEPTION_IF(tx_cache_data[txidx].primary[l].received.size() != n_vouts,
error::wallet_internal_error, "Unexpected received array size");
tx_cache_data[txidx].primary[l].received[k] = is_out_to_acc_precomp(m_subaddresses, key, tx_cache_data[txidx].primary[l].derivation, additional_derivations, k, hwdev);
additional_derivations.clear();
}
}
}
};
txidx = 0;
for (size_t i = 0; i < blocks.size(); ++i)
{
if (m_refresh_type != RefreshType::RefreshNoCoinbase)
{
THROW_WALLET_EXCEPTION_IF(txidx >= tx_cache_data.size(), error::wallet_internal_error, "txidx out of range");
const size_t n_vouts = m_refresh_type == RefreshType::RefreshOptimizeCoinbase ? 1 : parsed_blocks[i].block.miner_tx.vout.size();
tpool.submit(&waiter, [&, i, txidx](){ geniod(parsed_blocks[i].block.miner_tx, n_vouts, txidx); }, true);
}
++txidx;
for (size_t j = 0; j < parsed_blocks[i].txes.size(); ++j)
{
THROW_WALLET_EXCEPTION_IF(txidx >= tx_cache_data.size(), error::wallet_internal_error, "txidx out of range");
tpool.submit(&waiter, [&, i, j, txidx](){ geniod(parsed_blocks[i].txes[j], parsed_blocks[i].txes[j].vout.size(), txidx); }, true);
++txidx;
}
}
THROW_WALLET_EXCEPTION_IF(txidx != tx_cache_data.size(), error::wallet_internal_error, "txidx did not reach expected value");
waiter.wait(&tpool);
hwdev.set_mode(hw::device::NONE);
size_t tx_cache_data_offset = 0;
for (size_t i = 0; i < blocks.size(); ++i)
{
const crypto::hash &bl_id = parsed_blocks[i].hash;
const cryptonote::block &bl = parsed_blocks[i].block;
if(current_index >= m_blockchain.size())
{
process_new_blockchain_entry(bl, blocks[i], parsed_blocks[i], bl_id, current_index, tx_cache_data, tx_cache_data_offset);
++blocks_added;
}
else if(bl_id != m_blockchain[current_index])
{
//split detected here !!!
THROW_WALLET_EXCEPTION_IF(current_index == start_height, error::wallet_internal_error,
"wrong daemon response: split starts from the first block in response " + string_tools::pod_to_hex(bl_id) +
" (height " + std::to_string(start_height) + "), local block id at this height: " +
string_tools::pod_to_hex(m_blockchain[current_index]));
detach_blockchain(current_index);
process_new_blockchain_entry(bl, blocks[i], parsed_blocks[i], bl_id, current_index, tx_cache_data, tx_cache_data_offset);
}
else
{
LOG_PRINT_L2("Block is already in blockchain: " << string_tools::pod_to_hex(bl_id));
}
++current_index;
tx_cache_data_offset += 1 + parsed_blocks[i].txes.size();
}
}
//----------------------------------------------------------------------------------------------------
void wallet2::refresh(bool trusted_daemon)
{
uint64_t blocks_fetched = 0;
refresh(trusted_daemon, 0, blocks_fetched);
}
//----------------------------------------------------------------------------------------------------
void wallet2::refresh(bool trusted_daemon, uint64_t start_height, uint64_t & blocks_fetched)
{
bool received_money = false;
refresh(trusted_daemon, start_height, blocks_fetched, received_money);
}
//----------------------------------------------------------------------------------------------------
void wallet2::pull_and_parse_next_blocks(uint64_t start_height, uint64_t &blocks_start_height, std::list<crypto::hash> &short_chain_history, const std::vector<cryptonote::block_complete_entry> &prev_blocks, const std::vector<parsed_block> &prev_parsed_blocks, std::vector<cryptonote::block_complete_entry> &blocks, std::vector<parsed_block> &parsed_blocks, bool &error)
{
error = false;
try
{
drop_from_short_history(short_chain_history, 3);
THROW_WALLET_EXCEPTION_IF(prev_blocks.size() != prev_parsed_blocks.size(), error::wallet_internal_error, "size mismatch");
// prepend the last 3 blocks, should be enough to guard against a block or two's reorg
std::vector<parsed_block>::const_reverse_iterator i = prev_parsed_blocks.rbegin();
for (size_t n = 0; n < std::min((size_t)3, prev_parsed_blocks.size()); ++n)
{
short_chain_history.push_front(i->hash);
++i;
}
// pull the new blocks
std::vector<cryptonote::COMMAND_RPC_GET_BLOCKS_FAST::block_output_indices> o_indices;
pull_blocks(start_height, blocks_start_height, short_chain_history, blocks, o_indices);
THROW_WALLET_EXCEPTION_IF(blocks.size() != o_indices.size(), error::wallet_internal_error, "Mismatched sizes of blocks and o_indices");
tools::threadpool& tpool = tools::threadpool::getInstance();
tools::threadpool::waiter waiter;
parsed_blocks.resize(blocks.size());
for (size_t i = 0; i < blocks.size(); ++i)
{
tpool.submit(&waiter, boost::bind(&wallet2::parse_block_round, this, std::cref(blocks[i].block),
std::ref(parsed_blocks[i].block), std::ref(parsed_blocks[i].hash), std::ref(parsed_blocks[i].error)), true);
}
waiter.wait(&tpool);
for (size_t i = 0; i < blocks.size(); ++i)
{
if (parsed_blocks[i].error)
{
error = true;
break;
}
parsed_blocks[i].o_indices = std::move(o_indices[i]);
}
boost::mutex error_lock;
for (size_t i = 0; i < blocks.size(); ++i)
{
parsed_blocks[i].txes.resize(blocks[i].txs.size());
for (size_t j = 0; j < blocks[i].txs.size(); ++j)
{
tpool.submit(&waiter, [&, i, j](){
if (!parse_and_validate_tx_base_from_blob(blocks[i].txs[j], parsed_blocks[i].txes[j]))
{
boost::unique_lock<boost::mutex> lock(error_lock);
error = true;
}
}, true);
}
}
waiter.wait(&tpool);
}
catch(...)
{
error = true;
}
}
void wallet2::remove_obsolete_pool_txs(const std::vector<crypto::hash> &tx_hashes)
{
// remove pool txes to us that aren't in the pool anymore
std::unordered_multimap<crypto::hash, wallet2::pool_payment_details>::iterator uit = m_unconfirmed_payments.begin();
while (uit != m_unconfirmed_payments.end())
{
const crypto::hash &txid = uit->second.m_pd.m_tx_hash;
bool found = false;
for (const auto &it2: tx_hashes)
{
if (it2 == txid)
{
found = true;
break;
}
}
auto pit = uit++;
if (!found)
{
MDEBUG("Removing " << txid << " from unconfirmed payments, not found in pool");
m_unconfirmed_payments.erase(pit);
if (0 != m_callback)
m_callback->on_pool_tx_removed(txid);
}
}
}
//----------------------------------------------------------------------------------------------------
void wallet2::update_pool_state(bool refreshed)
{
MDEBUG("update_pool_state start");
auto keys_reencryptor = epee::misc_utils::create_scope_leave_handler([&, this]() {
if (m_encrypt_keys_after_refresh)
{
encrypt_keys(*m_encrypt_keys_after_refresh);
m_encrypt_keys_after_refresh = boost::none;
}
});
// get the pool state
cryptonote::COMMAND_RPC_GET_TRANSACTION_POOL_HASHES_BIN::request req;
cryptonote::COMMAND_RPC_GET_TRANSACTION_POOL_HASHES_BIN::response res;
m_daemon_rpc_mutex.lock();
bool r = epee::net_utils::invoke_http_json("/get_transaction_pool_hashes.bin", req, res, m_http_client, rpc_timeout);
m_daemon_rpc_mutex.unlock();
THROW_WALLET_EXCEPTION_IF(!r, error::no_connection_to_daemon, "get_transaction_pool_hashes.bin");
THROW_WALLET_EXCEPTION_IF(res.status == CORE_RPC_STATUS_BUSY, error::daemon_busy, "get_transaction_pool_hashes.bin");
THROW_WALLET_EXCEPTION_IF(res.status != CORE_RPC_STATUS_OK, error::get_tx_pool_error);
MDEBUG("update_pool_state got pool");
// remove any pending tx that's not in the pool
std::unordered_map<crypto::hash, wallet2::unconfirmed_transfer_details>::iterator it = m_unconfirmed_txs.begin();
while (it != m_unconfirmed_txs.end())
{
const crypto::hash &txid = it->first;
bool found = false;
for (const auto &it2: res.tx_hashes)
{
if (it2 == txid)
{
found = true;
break;
}
}
auto pit = it++;
if (!found)
{
// we want to avoid a false positive when we ask for the pool just after
// a tx is removed from the pool due to being found in a new block, but
// just before the block is visible by refresh. So we keep a boolean, so
// that the first time we don't see the tx, we set that boolean, and only
// delete it the second time it is checked (but only when refreshed, so
// we're sure we've seen the blockchain state first)
if (pit->second.m_state == wallet2::unconfirmed_transfer_details::pending)
{
LOG_PRINT_L1("Pending txid " << txid << " not in pool, marking as not in pool");
pit->second.m_state = wallet2::unconfirmed_transfer_details::pending_not_in_pool;
}
else if (pit->second.m_state == wallet2::unconfirmed_transfer_details::pending_not_in_pool && refreshed)
{
LOG_PRINT_L1("Pending txid " << txid << " not in pool, marking as failed");
pit->second.m_state = wallet2::unconfirmed_transfer_details::failed;
// the inputs aren't spent anymore, since the tx failed
remove_rings(pit->second.m_tx);
for (size_t vini = 0; vini < pit->second.m_tx.vin.size(); ++vini)
{
if (pit->second.m_tx.vin[vini].type() == typeid(txin_to_key))
{
txin_to_key &tx_in_to_key = boost::get<txin_to_key>(pit->second.m_tx.vin[vini]);
for (size_t i = 0; i < m_transfers.size(); ++i)
{
const transfer_details &td = m_transfers[i];
if (td.m_key_image == tx_in_to_key.k_image)
{
LOG_PRINT_L1("Resetting spent status for output " << vini << ": " << td.m_key_image);
set_unspent(i);
break;
}
}
}
}
}
}
}
MDEBUG("update_pool_state done first loop");
// remove pool txes to us that aren't in the pool anymore
// but only if we just refreshed, so that the tx can go in
// the in transfers list instead (or nowhere if it just
// disappeared without being mined)
if (refreshed)
remove_obsolete_pool_txs(res.tx_hashes);
MDEBUG("update_pool_state done second loop");
// gather txids of new pool txes to us
std::vector<std::pair<crypto::hash, bool>> txids;
for (const auto &txid: res.tx_hashes)
{
bool txid_found_in_up = false;
for (const auto &up: m_unconfirmed_payments)
{
if (up.second.m_pd.m_tx_hash == txid)
{
txid_found_in_up = true;
break;
}
}
if (m_scanned_pool_txs[0].find(txid) != m_scanned_pool_txs[0].end() || m_scanned_pool_txs[1].find(txid) != m_scanned_pool_txs[1].end())
{
// if it's for us, we want to keep track of whether we saw a double spend, so don't bail out
if (!txid_found_in_up)
{
LOG_PRINT_L2("Already seen " << txid << ", and not for us, skipped");
continue;
}
}
if (!txid_found_in_up)
{
LOG_PRINT_L1("Found new pool tx: " << txid);
bool found = false;
for (const auto &i: m_unconfirmed_txs)
{
if (i.first == txid)
{
found = true;
// if this is a payment to yourself at a different subaddress account, don't skip it
// so that you can see the incoming pool tx with 'show_transfers' on that receiving subaddress account
const unconfirmed_transfer_details& utd = i.second;
for (const auto& dst : utd.m_dests)
{
auto subaddr_index = m_subaddresses.find(dst.addr.m_spend_public_key);
if (subaddr_index != m_subaddresses.end() && subaddr_index->second.major != utd.m_subaddr_account)
{
found = false;
break;
}
}
break;
}
}
if (!found)
{
// not one of those we sent ourselves
txids.push_back({txid, false});
}
else
{
LOG_PRINT_L1("We sent that one");
}
}
else
{
LOG_PRINT_L1("Already saw that one, it's for us");
txids.push_back({txid, true});
}
}
// get those txes
if (!txids.empty())
{
cryptonote::COMMAND_RPC_GET_TRANSACTIONS::request req;
cryptonote::COMMAND_RPC_GET_TRANSACTIONS::response res;
for (const auto &p: txids)
req.txs_hashes.push_back(epee::string_tools::pod_to_hex(p.first));
MDEBUG("asking for " << txids.size() << " transactions");
req.decode_as_json = false;
req.prune = false;
m_daemon_rpc_mutex.lock();
bool r = epee::net_utils::invoke_http_json("/gettransactions", req, res, m_http_client, rpc_timeout);
m_daemon_rpc_mutex.unlock();
MDEBUG("Got " << r << " and " << res.status);
if (r && res.status == CORE_RPC_STATUS_OK)
{
if (res.txs.size() == txids.size())
{
for (const auto &tx_entry: res.txs)
{
if (tx_entry.in_pool)
{
cryptonote::transaction tx;
cryptonote::blobdata bd;
crypto::hash tx_hash, tx_prefix_hash;
if (epee::string_tools::parse_hexstr_to_binbuff(tx_entry.as_hex, bd))
{
if (cryptonote::parse_and_validate_tx_from_blob(bd, tx, tx_hash, tx_prefix_hash))
{
const std::vector<std::pair<crypto::hash, bool>>::const_iterator i = std::find_if(txids.begin(), txids.end(),
[tx_hash](const std::pair<crypto::hash, bool> &e) { return e.first == tx_hash; });
if (i != txids.end())
{
process_new_transaction(tx_hash, tx, std::vector<uint64_t>(), 0, time(NULL), false, true, tx_entry.double_spend_seen, {});
m_scanned_pool_txs[0].insert(tx_hash);
if (m_scanned_pool_txs[0].size() > 5000)
{
std::swap(m_scanned_pool_txs[0], m_scanned_pool_txs[1]);
m_scanned_pool_txs[0].clear();
}
}
else
{
MERROR("Got txid " << tx_hash << " which we did not ask for");
}
}
else
{
LOG_PRINT_L0("failed to validate transaction from daemon");
}
}
else
{
LOG_PRINT_L0("Failed to parse transaction from daemon");
}
}
else
{
LOG_PRINT_L1("Transaction from daemon was in pool, but is no more");
}
}
}
else
{
LOG_PRINT_L0("Expected " << txids.size() << " tx(es), got " << res.txs.size());
}
}
else
{
LOG_PRINT_L0("Error calling gettransactions daemon RPC: r " << r << ", status " << res.status);
}
}
MDEBUG("update_pool_state end");
}
//----------------------------------------------------------------------------------------------------
void wallet2::fast_refresh(uint64_t stop_height, uint64_t &blocks_start_height, std::list<crypto::hash> &short_chain_history, bool force)
{
std::vector<crypto::hash> hashes;
const uint64_t checkpoint_height = m_checkpoints.get_max_height();
if ((stop_height > checkpoint_height && m_blockchain.size()-1 < checkpoint_height) && !force)
{
// we will drop all these, so don't bother getting them
uint64_t missing_blocks = m_checkpoints.get_max_height() - m_blockchain.size();
while (missing_blocks-- > 0)
m_blockchain.push_back(crypto::null_hash); // maybe a bit suboptimal, but deque won't do huge reallocs like vector
m_blockchain.push_back(m_checkpoints.get_points().at(checkpoint_height));
m_blockchain.trim(checkpoint_height);
short_chain_history.clear();
get_short_chain_history(short_chain_history);
}
size_t current_index = m_blockchain.size();
while(m_run.load(std::memory_order_relaxed) && current_index < stop_height)
{
pull_hashes(0, blocks_start_height, short_chain_history, hashes);
if (hashes.size() <= 3)
return;
if (blocks_start_height < m_blockchain.offset())
{
MERROR("Blocks start before blockchain offset: " << blocks_start_height << " " << m_blockchain.offset());
return;
}
if (hashes.size() + current_index < stop_height) {
drop_from_short_history(short_chain_history, 3);
std::vector<crypto::hash>::iterator right = hashes.end();
// prepend 3 more
for (int i = 0; i<3; i++) {
right--;
short_chain_history.push_front(*right);
}
}
current_index = blocks_start_height;
for(auto& bl_id: hashes)
{
if(current_index >= m_blockchain.size())
{
if (!(current_index % 1024))
LOG_PRINT_L2( "Skipped block by height: " << current_index);
m_blockchain.push_back(bl_id);
if (0 != m_callback)
{ // FIXME: this isn't right, but simplewallet just logs that we got a block.
cryptonote::block dummy;
m_callback->on_new_block(current_index, dummy);
}
}
else if(bl_id != m_blockchain[current_index])
{
//split detected here !!!
return;
}
++current_index;
if (current_index >= stop_height)
return;
}
}
}
bool wallet2::add_address_book_row(const cryptonote::account_public_address &address, const crypto::hash &payment_id, const std::string &description, bool is_subaddress)
{
wallet2::address_book_row a;
a.m_address = address;
a.m_payment_id = payment_id;
a.m_description = description;
a.m_is_subaddress = is_subaddress;
auto old_size = m_address_book.size();
m_address_book.push_back(a);
if(m_address_book.size() == old_size+1)
return true;
return false;
}
bool wallet2::delete_address_book_row(std::size_t row_id) {
if(m_address_book.size() <= row_id)
return false;
m_address_book.erase(m_address_book.begin()+row_id);
return true;
}
//----------------------------------------------------------------------------------------------------
void wallet2::refresh(bool trusted_daemon, uint64_t start_height, uint64_t & blocks_fetched, bool& received_money)
{
if(m_light_wallet) {
// MyMonero get_address_info needs to be called occasionally to trigger wallet sync.
// This call is not really needed for other purposes and can be removed if mymonero changes their backend.
cryptonote::COMMAND_RPC_GET_ADDRESS_INFO::response res;
// Get basic info
if(light_wallet_get_address_info(res)) {
// Last stored block height
uint64_t prev_height = m_light_wallet_blockchain_height;
// Update lw heights
m_light_wallet_scanned_block_height = res.scanned_block_height;
m_light_wallet_blockchain_height = res.blockchain_height;
// If new height - call new_block callback
if(m_light_wallet_blockchain_height != prev_height)
{
MDEBUG("new block since last time!");
m_callback->on_lw_new_block(m_light_wallet_blockchain_height - 1);
}
m_light_wallet_connected = true;
MDEBUG("lw scanned block height: " << m_light_wallet_scanned_block_height);
MDEBUG("lw blockchain height: " << m_light_wallet_blockchain_height);
MDEBUG(m_light_wallet_blockchain_height-m_light_wallet_scanned_block_height << " blocks behind");
// TODO: add wallet created block info
light_wallet_get_address_txs();
} else
m_light_wallet_connected = false;
// Lighwallet refresh done
return;
}
received_money = false;
blocks_fetched = 0;
uint64_t added_blocks = 0;
size_t try_count = 0;
crypto::hash last_tx_hash_id = m_transfers.size() ? m_transfers.back().m_txid : null_hash;
std::list<crypto::hash> short_chain_history;
tools::threadpool& tpool = tools::threadpool::getInstance();
tools::threadpool::waiter waiter;
uint64_t blocks_start_height;
std::vector<cryptonote::block_complete_entry> blocks;
std::vector<parsed_block> parsed_blocks;
bool refreshed = false;
// pull the first set of blocks
get_short_chain_history(short_chain_history, (m_first_refresh_done || trusted_daemon) ? 1 : FIRST_REFRESH_GRANULARITY);
m_run.store(true, std::memory_order_relaxed);
if (start_height > m_blockchain.size() || m_refresh_from_block_height > m_blockchain.size()) {
if (!start_height)
start_height = m_refresh_from_block_height;
// we can shortcut by only pulling hashes up to the start_height
fast_refresh(start_height, blocks_start_height, short_chain_history);
// regenerate the history now that we've got a full set of hashes
short_chain_history.clear();
get_short_chain_history(short_chain_history, (m_first_refresh_done || trusted_daemon) ? 1 : FIRST_REFRESH_GRANULARITY);
start_height = 0;
// and then fall through to regular refresh processing
}
// If stop() is called during fast refresh we don't need to continue
if(!m_run.load(std::memory_order_relaxed))
return;
// always reset start_height to 0 to force short_chain_ history to be used on
// subsequent pulls in this refresh.
start_height = 0;
auto keys_reencryptor = epee::misc_utils::create_scope_leave_handler([&, this]() {
if (m_encrypt_keys_after_refresh)
{
encrypt_keys(*m_encrypt_keys_after_refresh);
m_encrypt_keys_after_refresh = boost::none;
}
});
bool first = true;
while(m_run.load(std::memory_order_relaxed))
{
try
{
// pull the next set of blocks while we're processing the current one
uint64_t next_blocks_start_height;
std::vector<cryptonote::block_complete_entry> next_blocks;
std::vector<parsed_block> next_parsed_blocks;
bool error = false;
added_blocks = 0;
if (!first && blocks.empty())
{
refreshed = false;
break;
}
tpool.submit(&waiter, [&]{pull_and_parse_next_blocks(start_height, next_blocks_start_height, short_chain_history, blocks, parsed_blocks, next_blocks, next_parsed_blocks, error);});
if (!first)
{
try
{
process_parsed_blocks(blocks_start_height, blocks, parsed_blocks, added_blocks);
}
catch (const tools::error::out_of_hashchain_bounds_error&)
{
MINFO("Daemon claims next refresh block is out of hash chain bounds, resetting hash chain");
uint64_t stop_height = m_blockchain.offset();
std::vector<crypto::hash> tip(m_blockchain.size() - m_blockchain.offset());
for (size_t i = m_blockchain.offset(); i < m_blockchain.size(); ++i)
tip[i - m_blockchain.offset()] = m_blockchain[i];
cryptonote::block b;
generate_genesis(b);
m_blockchain.clear();
m_blockchain.push_back(get_block_hash(b));
short_chain_history.clear();
get_short_chain_history(short_chain_history);
fast_refresh(stop_height, blocks_start_height, short_chain_history, true);
THROW_WALLET_EXCEPTION_IF(m_blockchain.size() != stop_height, error::wallet_internal_error, "Unexpected hashchain size");
THROW_WALLET_EXCEPTION_IF(m_blockchain.offset() != 0, error::wallet_internal_error, "Unexpected hashchain offset");
for (const auto &h: tip)
m_blockchain.push_back(h);
short_chain_history.clear();
get_short_chain_history(short_chain_history);
start_height = stop_height;
throw std::runtime_error(""); // loop again
}
blocks_fetched += added_blocks;
}
waiter.wait(&tpool);
if(!first && blocks_start_height == next_blocks_start_height)
{
m_node_rpc_proxy.set_height(m_blockchain.size());
refreshed = true;
break;
}
first = false;
// handle error from async fetching thread
if (error)
{
throw std::runtime_error("proxy exception in refresh thread");
}
// switch to the new blocks from the daemon
blocks_start_height = next_blocks_start_height;
blocks = std::move(next_blocks);
parsed_blocks = std::move(next_parsed_blocks);
}
catch (const tools::error::password_needed&)
{
blocks_fetched += added_blocks;
waiter.wait(&tpool);
throw;
}
catch (const std::exception&)
{
blocks_fetched += added_blocks;
waiter.wait(&tpool);
if(try_count < 3)
{
LOG_PRINT_L1("Another try pull_blocks (try_count=" << try_count << ")...");
first = true;
++try_count;
}
else
{
LOG_ERROR("pull_blocks failed, try_count=" << try_count);
throw;
}
}
}
if(last_tx_hash_id != (m_transfers.size() ? m_transfers.back().m_txid : null_hash))
received_money = true;
try
{
// If stop() is called we don't need to check pending transactions
if(m_run.load(std::memory_order_relaxed))
update_pool_state(refreshed);
}
catch (...)
{
LOG_PRINT_L1("Failed to check pending transactions");
}
m_first_refresh_done = true;
LOG_PRINT_L1("Refresh done, blocks received: " << blocks_fetched << ", balance (all accounts): " << print_money(balance_all()) << ", unlocked: " << print_money(unlocked_balance_all()));
}
//----------------------------------------------------------------------------------------------------
bool wallet2::refresh(bool trusted_daemon, uint64_t & blocks_fetched, bool& received_money, bool& ok)
{
try
{
refresh(trusted_daemon, 0, blocks_fetched, received_money);
ok = true;
}
catch (...)
{
ok = false;
}
return ok;
}
//----------------------------------------------------------------------------------------------------
bool wallet2::get_rct_distribution(uint64_t &start_height, std::vector<uint64_t> &distribution)
{
uint32_t rpc_version;
boost::optional<std::string> result = m_node_rpc_proxy.get_rpc_version(rpc_version);
// no error
if (!!result)
{
// empty string -> not connection
THROW_WALLET_EXCEPTION_IF(result->empty(), tools::error::no_connection_to_daemon, "getversion");
THROW_WALLET_EXCEPTION_IF(*result == CORE_RPC_STATUS_BUSY, tools::error::daemon_busy, "getversion");
if (*result != CORE_RPC_STATUS_OK)
{
MDEBUG("Cannot determine daemon RPC version, not requesting rct distribution");
return false;
}
}
else
{
if (rpc_version >= MAKE_CORE_RPC_VERSION(1, 19))
{
MDEBUG("Daemon is recent enough, requesting rct distribution");
}
else
{
MDEBUG("Daemon is too old, not requesting rct distribution");
return false;
}
}
cryptonote::COMMAND_RPC_GET_OUTPUT_DISTRIBUTION::request req = AUTO_VAL_INIT(req);
cryptonote::COMMAND_RPC_GET_OUTPUT_DISTRIBUTION::response res = AUTO_VAL_INIT(res);
req.amounts.push_back(0);
req.from_height = 0;
req.cumulative = true;
req.binary = true;
m_daemon_rpc_mutex.lock();
bool r = net_utils::invoke_http_json_rpc("/json_rpc", "get_output_distribution", req, res, m_http_client, rpc_timeout);
m_daemon_rpc_mutex.unlock();
if (!r)
{
MWARNING("Failed to request output distribution: no connection to daemon");
return false;
}
if (res.status == CORE_RPC_STATUS_BUSY)
{
MWARNING("Failed to request output distribution: daemon is busy");
return false;
}
if (res.status != CORE_RPC_STATUS_OK)
{
MWARNING("Failed to request output distribution: " << res.status);
return false;
}
if (res.distributions.size() != 1)
{
MWARNING("Failed to request output distribution: not the expected single result");
return false;
}
if (res.distributions[0].amount != 0)
{
MWARNING("Failed to request output distribution: results are not for amount 0");
return false;
}
start_height = res.distributions[0].data.start_height;
distribution = std::move(res.distributions[0].data.distribution);
return true;
}
//----------------------------------------------------------------------------------------------------
void wallet2::detach_blockchain(uint64_t height)
{
LOG_PRINT_L0("Detaching blockchain on height " << height);
// size 1 2 3 4 5 6 7 8 9
// block 0 1 2 3 4 5 6 7 8
// C
THROW_WALLET_EXCEPTION_IF(height < m_blockchain.offset() && m_blockchain.size() > m_blockchain.offset(),
error::wallet_internal_error, "Daemon claims reorg below last checkpoint");
size_t transfers_detached = 0;
for (size_t i = 0; i < m_transfers.size(); ++i)
{
wallet2::transfer_details &td = m_transfers[i];
if (td.m_spent && td.m_spent_height >= height)
{
LOG_PRINT_L1("Resetting spent status for output " << i << ": " << td.m_key_image);
set_unspent(i);
}
}
auto it = std::find_if(m_transfers.begin(), m_transfers.end(), [&](const transfer_details& td){return td.m_block_height >= height;});
size_t i_start = it - m_transfers.begin();
for(size_t i = i_start; i!= m_transfers.size();i++)
{
if (!m_transfers[i].m_key_image_known || m_transfers[i].m_key_image_partial)
continue;
auto it_ki = m_key_images.find(m_transfers[i].m_key_image);
THROW_WALLET_EXCEPTION_IF(it_ki == m_key_images.end(), error::wallet_internal_error, "key image not found: index " + std::to_string(i) + ", ki " + epee::string_tools::pod_to_hex(m_transfers[i].m_key_image) + ", " + std::to_string(m_key_images.size()) + " key images known");
m_key_images.erase(it_ki);
}
for(size_t i = i_start; i!= m_transfers.size();i++)
{
auto it_pk = m_pub_keys.find(m_transfers[i].get_public_key());
THROW_WALLET_EXCEPTION_IF(it_pk == m_pub_keys.end(), error::wallet_internal_error, "public key not found");
m_pub_keys.erase(it_pk);
}
m_transfers.erase(it, m_transfers.end());
size_t blocks_detached = m_blockchain.size() - height;
m_blockchain.crop(height);
for (auto it = m_payments.begin(); it != m_payments.end(); )
{
if(height <= it->second.m_block_height)
it = m_payments.erase(it);
else
++it;
}
for (auto it = m_confirmed_txs.begin(); it != m_confirmed_txs.end(); )
{
if(height <= it->second.m_block_height)
it = m_confirmed_txs.erase(it);
else
++it;
}
LOG_PRINT_L0("Detached blockchain on height " << height << ", transfers detached " << transfers_detached << ", blocks detached " << blocks_detached);
}
//----------------------------------------------------------------------------------------------------
bool wallet2::deinit()
{
m_is_initialized=false;
unlock_keys_file();
m_account.deinit();
return true;
}
//----------------------------------------------------------------------------------------------------
bool wallet2::clear()
{
m_blockchain.clear();
m_transfers.clear();
m_key_images.clear();
m_pub_keys.clear();
m_unconfirmed_txs.clear();
m_payments.clear();
m_tx_keys.clear();
m_additional_tx_keys.clear();
m_confirmed_txs.clear();
m_unconfirmed_payments.clear();
m_scanned_pool_txs[0].clear();
m_scanned_pool_txs[1].clear();
m_address_book.clear();
m_subaddresses.clear();
m_subaddress_labels.clear();
m_multisig_rounds_passed = 0;
return true;
}
/*!
* \brief Stores wallet information to wallet file.
* \param keys_file_name Name of wallet file
* \param password Password of wallet file
* \param watch_only true to save only view key, false to save both spend and view keys
* \return Whether it was successful.
*/
bool wallet2::store_keys(const std::string& keys_file_name, const epee::wipeable_string& password, bool watch_only)
{
std::string account_data;
std::string multisig_signers;
std::string multisig_derivations;
cryptonote::account_base account = m_account;
crypto::chacha_key key;
crypto::generate_chacha_key(password.data(), password.size(), key, m_kdf_rounds);
if (m_ask_password == AskPasswordToDecrypt && !m_unattended && !m_watch_only)
{
account.encrypt_viewkey(key);
account.decrypt_keys(key);
}
if (watch_only)
account.forget_spend_key();
account.encrypt_keys(key);
bool r = epee::serialization::store_t_to_binary(account, account_data);
CHECK_AND_ASSERT_MES(r, false, "failed to serialize wallet keys");
wallet2::keys_file_data keys_file_data = boost::value_initialized<wallet2::keys_file_data>();
// Create a JSON object with "key_data" and "seed_language" as keys.
rapidjson::Document json;
json.SetObject();
rapidjson::Value value(rapidjson::kStringType);
value.SetString(account_data.c_str(), account_data.length());
json.AddMember("key_data", value, json.GetAllocator());
if (!seed_language.empty())
{
value.SetString(seed_language.c_str(), seed_language.length());
json.AddMember("seed_language", value, json.GetAllocator());
}
rapidjson::Value value2(rapidjson::kNumberType);
value2.SetInt(m_key_device_type);
json.AddMember("key_on_device", value2, json.GetAllocator());
value2.SetInt(watch_only ? 1 :0); // WTF ? JSON has different true and false types, and not boolean ??
json.AddMember("watch_only", value2, json.GetAllocator());
value2.SetInt(m_multisig ? 1 :0);
json.AddMember("multisig", value2, json.GetAllocator());
value2.SetUint(m_multisig_threshold);
json.AddMember("multisig_threshold", value2, json.GetAllocator());
if (m_multisig)
{
bool r = ::serialization::dump_binary(m_multisig_signers, multisig_signers);
CHECK_AND_ASSERT_MES(r, false, "failed to serialize wallet multisig signers");
value.SetString(multisig_signers.c_str(), multisig_signers.length());
json.AddMember("multisig_signers", value, json.GetAllocator());
r = ::serialization::dump_binary(m_multisig_derivations, multisig_derivations);
CHECK_AND_ASSERT_MES(r, false, "failed to serialize wallet multisig derivations");
value.SetString(multisig_derivations.c_str(), multisig_derivations.length());
json.AddMember("multisig_derivations", value, json.GetAllocator());
value2.SetUint(m_multisig_rounds_passed);
json.AddMember("multisig_rounds_passed", value2, json.GetAllocator());
}
value2.SetInt(m_always_confirm_transfers ? 1 :0);
json.AddMember("always_confirm_transfers", value2, json.GetAllocator());
value2.SetInt(m_print_ring_members ? 1 :0);
json.AddMember("print_ring_members", value2, json.GetAllocator());
value2.SetInt(m_store_tx_info ? 1 :0);
json.AddMember("store_tx_info", value2, json.GetAllocator());
value2.SetUint(m_default_mixin);
json.AddMember("default_mixin", value2, json.GetAllocator());
value2.SetUint(m_default_priority);
json.AddMember("default_priority", value2, json.GetAllocator());
value2.SetInt(m_auto_refresh ? 1 :0);
json.AddMember("auto_refresh", value2, json.GetAllocator());
value2.SetInt(m_refresh_type);
json.AddMember("refresh_type", value2, json.GetAllocator());
value2.SetUint64(m_refresh_from_block_height);
json.AddMember("refresh_height", value2, json.GetAllocator());
value2.SetInt(m_confirm_missing_payment_id ? 1 :0);
json.AddMember("confirm_missing_payment_id", value2, json.GetAllocator());
value2.SetInt(m_confirm_non_default_ring_size ? 1 :0);
json.AddMember("confirm_non_default_ring_size", value2, json.GetAllocator());
value2.SetInt(m_ask_password);
json.AddMember("ask_password", value2, json.GetAllocator());
value2.SetUint(m_min_output_count);
json.AddMember("min_output_count", value2, json.GetAllocator());
value2.SetUint64(m_min_output_value);
json.AddMember("min_output_value", value2, json.GetAllocator());
value2.SetInt(cryptonote::get_default_decimal_point());
json.AddMember("default_decimal_point", value2, json.GetAllocator());
value2.SetInt(m_merge_destinations ? 1 :0);
json.AddMember("merge_destinations", value2, json.GetAllocator());
value2.SetInt(m_confirm_backlog ? 1 :0);
json.AddMember("confirm_backlog", value2, json.GetAllocator());
value2.SetUint(m_confirm_backlog_threshold);
json.AddMember("confirm_backlog_threshold", value2, json.GetAllocator());
value2.SetInt(m_confirm_export_overwrite ? 1 :0);
json.AddMember("confirm_export_overwrite", value2, json.GetAllocator());
value2.SetInt(m_auto_low_priority ? 1 : 0);
json.AddMember("auto_low_priority", value2, json.GetAllocator());
value2.SetUint(m_nettype);
json.AddMember("nettype", value2, json.GetAllocator());
value2.SetInt(m_segregate_pre_fork_outputs ? 1 : 0);
json.AddMember("segregate_pre_fork_outputs", value2, json.GetAllocator());
value2.SetInt(m_key_reuse_mitigation2 ? 1 : 0);
json.AddMember("key_reuse_mitigation2", value2, json.GetAllocator());
value2.SetUint(m_segregation_height);
json.AddMember("segregation_height", value2, json.GetAllocator());
value2.SetInt(m_ignore_fractional_outputs ? 1 : 0);
json.AddMember("ignore_fractional_outputs", value2, json.GetAllocator());
value2.SetUint(m_subaddress_lookahead_major);
json.AddMember("subaddress_lookahead_major", value2, json.GetAllocator());
value2.SetUint(m_subaddress_lookahead_minor);
json.AddMember("subaddress_lookahead_minor", value2, json.GetAllocator());
value2.SetUint(1);
json.AddMember("encrypted_secret_keys", value2, json.GetAllocator());
value.SetString(m_device_name.c_str(), m_device_name.size());
json.AddMember("device_name", value, json.GetAllocator());
// Serialize the JSON object
rapidjson::StringBuffer buffer;
rapidjson::Writer<rapidjson::StringBuffer> writer(buffer);
json.Accept(writer);
account_data = buffer.GetString();
// Encrypt the entire JSON object.
crypto::generate_chacha_key(password.data(), password.size(), key, m_kdf_rounds);
std::string cipher;
cipher.resize(account_data.size());
keys_file_data.iv = crypto::rand<crypto::chacha_iv>();
crypto::chacha20(account_data.data(), account_data.size(), key, keys_file_data.iv, &cipher[0]);
keys_file_data.account_data = cipher;
std::string tmp_file_name = keys_file_name + ".new";
std::string buf;
r = ::serialization::dump_binary(keys_file_data, buf);
r = r && epee::file_io_utils::save_string_to_file(tmp_file_name, buf);
CHECK_AND_ASSERT_MES(r, false, "failed to generate wallet keys file " << tmp_file_name);
unlock_keys_file();
std::error_code e = tools::replace_file(tmp_file_name, keys_file_name);
lock_keys_file();
if (e) {
boost::filesystem::remove(tmp_file_name);
LOG_ERROR("failed to update wallet keys file " << keys_file_name);
return false;
}
return true;
}
//----------------------------------------------------------------------------------------------------
void wallet2::setup_keys(const epee::wipeable_string &password)
{
crypto::chacha_key key;
crypto::generate_chacha_key(password.data(), password.size(), key, m_kdf_rounds);
// re-encrypt, but keep viewkey unencrypted
if (m_ask_password == AskPasswordToDecrypt && !m_unattended && !m_watch_only)
{
m_account.encrypt_keys(key);
m_account.decrypt_viewkey(key);
}
static_assert(HASH_SIZE == sizeof(crypto::chacha_key), "Mismatched sizes of hash and chacha key");
epee::mlocked<tools::scrubbed_arr<char, HASH_SIZE+1>> cache_key_data;
memcpy(cache_key_data.data(), &key, HASH_SIZE);
cache_key_data[HASH_SIZE] = CACHE_KEY_TAIL;
cn_fast_hash(cache_key_data.data(), HASH_SIZE+1, (crypto::hash&)m_cache_key);
get_ringdb_key();
}
//----------------------------------------------------------------------------------------------------
void wallet2::change_password(const std::string &filename, const epee::wipeable_string &original_password, const epee::wipeable_string &new_password)
{
if (m_ask_password == AskPasswordToDecrypt && !m_unattended && !m_watch_only)
decrypt_keys(original_password);
setup_keys(new_password);
rewrite(filename, new_password);
store();
}
//----------------------------------------------------------------------------------------------------
/*!
* \brief Load wallet information from wallet file.
* \param keys_file_name Name of wallet file
* \param password Password of wallet file
*/
bool wallet2::load_keys(const std::string& keys_file_name, const epee::wipeable_string& password)
{
rapidjson::Document json;
wallet2::keys_file_data keys_file_data;
std::string buf;
bool encrypted_secret_keys = false;
bool r = epee::file_io_utils::load_file_to_string(keys_file_name, buf);
THROW_WALLET_EXCEPTION_IF(!r, error::file_read_error, keys_file_name);
// Decrypt the contents
r = ::serialization::parse_binary(buf, keys_file_data);
THROW_WALLET_EXCEPTION_IF(!r, error::wallet_internal_error, "internal error: failed to deserialize \"" + keys_file_name + '\"');
crypto::chacha_key key;
crypto::generate_chacha_key(password.data(), password.size(), key, m_kdf_rounds);
std::string account_data;
account_data.resize(keys_file_data.account_data.size());
crypto::chacha20(keys_file_data.account_data.data(), keys_file_data.account_data.size(), key, keys_file_data.iv, &account_data[0]);
if (json.Parse(account_data.c_str()).HasParseError() || !json.IsObject())
crypto::chacha8(keys_file_data.account_data.data(), keys_file_data.account_data.size(), key, keys_file_data.iv, &account_data[0]);
// The contents should be JSON if the wallet follows the new format.
if (json.Parse(account_data.c_str()).HasParseError())
{
is_old_file_format = true;
m_watch_only = false;
m_multisig = false;
m_multisig_threshold = 0;
m_multisig_signers.clear();
m_multisig_rounds_passed = 0;
m_multisig_derivations.clear();
m_always_confirm_transfers = false;
m_print_ring_members = false;
m_default_mixin = 0;
m_default_priority = 0;
m_auto_refresh = true;
m_refresh_type = RefreshType::RefreshDefault;
m_confirm_missing_payment_id = true;
m_confirm_non_default_ring_size = true;
m_ask_password = AskPasswordToDecrypt;
m_min_output_count = 0;
m_min_output_value = 0;
m_merge_destinations = false;
m_confirm_backlog = true;
m_confirm_backlog_threshold = 0;
m_confirm_export_overwrite = true;
m_auto_low_priority = true;
m_segregate_pre_fork_outputs = true;
m_key_reuse_mitigation2 = true;
m_segregation_height = 0;
m_ignore_fractional_outputs = true;
m_subaddress_lookahead_major = SUBADDRESS_LOOKAHEAD_MAJOR;
m_subaddress_lookahead_minor = SUBADDRESS_LOOKAHEAD_MINOR;
m_device_name = "";
m_key_device_type = hw::device::device_type::SOFTWARE;
encrypted_secret_keys = false;
}
else if(json.IsObject())
{
if (!json.HasMember("key_data"))
{
LOG_ERROR("Field key_data not found in JSON");
return false;
}
if (!json["key_data"].IsString())
{
LOG_ERROR("Field key_data found in JSON, but not String");
return false;
}
const char *field_key_data = json["key_data"].GetString();
account_data = std::string(field_key_data, field_key_data + json["key_data"].GetStringLength());
if (json.HasMember("key_on_device"))
{
GET_FIELD_FROM_JSON_RETURN_ON_ERROR(json, key_on_device, int, Int, false, hw::device::device_type::SOFTWARE);
m_key_device_type = static_cast<hw::device::device_type>(field_key_on_device);
}
GET_FIELD_FROM_JSON_RETURN_ON_ERROR(json, seed_language, std::string, String, false, std::string());
if (field_seed_language_found)
{
set_seed_language(field_seed_language);
}
GET_FIELD_FROM_JSON_RETURN_ON_ERROR(json, watch_only, int, Int, false, false);
m_watch_only = field_watch_only;
GET_FIELD_FROM_JSON_RETURN_ON_ERROR(json, multisig, int, Int, false, false);
m_multisig = field_multisig;
GET_FIELD_FROM_JSON_RETURN_ON_ERROR(json, multisig_threshold, unsigned int, Uint, m_multisig, 0);
m_multisig_threshold = field_multisig_threshold;
GET_FIELD_FROM_JSON_RETURN_ON_ERROR(json, multisig_rounds_passed, unsigned int, Uint, false, 0);
m_multisig_rounds_passed = field_multisig_rounds_passed;
if (m_multisig)
{
if (!json.HasMember("multisig_signers"))
{
LOG_ERROR("Field multisig_signers not found in JSON");
return false;
}
if (!json["multisig_signers"].IsString())
{
LOG_ERROR("Field multisig_signers found in JSON, but not String");
return false;
}
const char *field_multisig_signers = json["multisig_signers"].GetString();
std::string multisig_signers = std::string(field_multisig_signers, field_multisig_signers + json["multisig_signers"].GetStringLength());
r = ::serialization::parse_binary(multisig_signers, m_multisig_signers);
if (!r)
{
LOG_ERROR("Field multisig_signers found in JSON, but failed to parse");
return false;
}
//previous version of multisig does not have this field
if (json.HasMember("multisig_derivations"))
{
if (!json["multisig_derivations"].IsString())
{
LOG_ERROR("Field multisig_derivations found in JSON, but not String");
return false;
}
const char *field_multisig_derivations = json["multisig_derivations"].GetString();
std::string multisig_derivations = std::string(field_multisig_derivations, field_multisig_derivations + json["multisig_derivations"].GetStringLength());
r = ::serialization::parse_binary(multisig_derivations, m_multisig_derivations);
if (!r)
{
LOG_ERROR("Field multisig_derivations found in JSON, but failed to parse");
return false;
}
}
}
GET_FIELD_FROM_JSON_RETURN_ON_ERROR(json, always_confirm_transfers, int, Int, false, true);
m_always_confirm_transfers = field_always_confirm_transfers;
GET_FIELD_FROM_JSON_RETURN_ON_ERROR(json, print_ring_members, int, Int, false, true);
m_print_ring_members = field_print_ring_members;
GET_FIELD_FROM_JSON_RETURN_ON_ERROR(json, store_tx_keys, int, Int, false, true);
GET_FIELD_FROM_JSON_RETURN_ON_ERROR(json, store_tx_info, int, Int, false, true);
m_store_tx_info = ((field_store_tx_keys != 0) || (field_store_tx_info != 0));
GET_FIELD_FROM_JSON_RETURN_ON_ERROR(json, default_mixin, unsigned int, Uint, false, 0);
m_default_mixin = field_default_mixin;
GET_FIELD_FROM_JSON_RETURN_ON_ERROR(json, default_priority, unsigned int, Uint, false, 0);
if (field_default_priority_found)
{
m_default_priority = field_default_priority;
}
else
{
GET_FIELD_FROM_JSON_RETURN_ON_ERROR(json, default_fee_multiplier, unsigned int, Uint, false, 0);
if (field_default_fee_multiplier_found)
m_default_priority = field_default_fee_multiplier;
else
m_default_priority = 0;
}
GET_FIELD_FROM_JSON_RETURN_ON_ERROR(json, auto_refresh, int, Int, false, true);
m_auto_refresh = field_auto_refresh;
GET_FIELD_FROM_JSON_RETURN_ON_ERROR(json, refresh_type, int, Int, false, RefreshType::RefreshDefault);
m_refresh_type = RefreshType::RefreshDefault;
if (field_refresh_type_found)
{
if (field_refresh_type == RefreshFull || field_refresh_type == RefreshOptimizeCoinbase || field_refresh_type == RefreshNoCoinbase)
m_refresh_type = (RefreshType)field_refresh_type;
else
LOG_PRINT_L0("Unknown refresh-type value (" << field_refresh_type << "), using default");
}
GET_FIELD_FROM_JSON_RETURN_ON_ERROR(json, refresh_height, uint64_t, Uint64, false, 0);
m_refresh_from_block_height = field_refresh_height;
GET_FIELD_FROM_JSON_RETURN_ON_ERROR(json, confirm_missing_payment_id, int, Int, false, true);
m_confirm_missing_payment_id = field_confirm_missing_payment_id;
GET_FIELD_FROM_JSON_RETURN_ON_ERROR(json, confirm_non_default_ring_size, int, Int, false, true);
m_confirm_non_default_ring_size = field_confirm_non_default_ring_size;
GET_FIELD_FROM_JSON_RETURN_ON_ERROR(json, ask_password, AskPasswordType, Int, false, AskPasswordToDecrypt);
m_ask_password = field_ask_password;
GET_FIELD_FROM_JSON_RETURN_ON_ERROR(json, default_decimal_point, int, Int, false, CRYPTONOTE_DISPLAY_DECIMAL_POINT);
cryptonote::set_default_decimal_point(field_default_decimal_point);
GET_FIELD_FROM_JSON_RETURN_ON_ERROR(json, min_output_count, uint32_t, Uint, false, 0);
m_min_output_count = field_min_output_count;
GET_FIELD_FROM_JSON_RETURN_ON_ERROR(json, min_output_value, uint64_t, Uint64, false, 0);
m_min_output_value = field_min_output_value;
GET_FIELD_FROM_JSON_RETURN_ON_ERROR(json, merge_destinations, int, Int, false, false);
m_merge_destinations = field_merge_destinations;
GET_FIELD_FROM_JSON_RETURN_ON_ERROR(json, confirm_backlog, int, Int, false, true);
m_confirm_backlog = field_confirm_backlog;
GET_FIELD_FROM_JSON_RETURN_ON_ERROR(json, confirm_backlog_threshold, uint32_t, Uint, false, 0);
m_confirm_backlog_threshold = field_confirm_backlog_threshold;
GET_FIELD_FROM_JSON_RETURN_ON_ERROR(json, confirm_export_overwrite, int, Int, false, true);
m_confirm_export_overwrite = field_confirm_export_overwrite;
GET_FIELD_FROM_JSON_RETURN_ON_ERROR(json, auto_low_priority, int, Int, false, true);
m_auto_low_priority = field_auto_low_priority;
GET_FIELD_FROM_JSON_RETURN_ON_ERROR(json, nettype, uint8_t, Uint, false, static_cast<uint8_t>(m_nettype));
// The network type given in the program argument is inconsistent with the network type saved in the wallet
THROW_WALLET_EXCEPTION_IF(static_cast<uint8_t>(m_nettype) != field_nettype, error::wallet_internal_error,
(boost::format("%s wallet cannot be opened as %s wallet")
% (field_nettype == 0 ? "Mainnet" : field_nettype == 1 ? "Testnet" : "Stagenet")
% (m_nettype == MAINNET ? "mainnet" : m_nettype == TESTNET ? "testnet" : "stagenet")).str());
GET_FIELD_FROM_JSON_RETURN_ON_ERROR(json, segregate_pre_fork_outputs, int, Int, false, true);
m_segregate_pre_fork_outputs = field_segregate_pre_fork_outputs;
GET_FIELD_FROM_JSON_RETURN_ON_ERROR(json, key_reuse_mitigation2, int, Int, false, true);
m_key_reuse_mitigation2 = field_key_reuse_mitigation2;
GET_FIELD_FROM_JSON_RETURN_ON_ERROR(json, segregation_height, int, Uint, false, 0);
m_segregation_height = field_segregation_height;
GET_FIELD_FROM_JSON_RETURN_ON_ERROR(json, ignore_fractional_outputs, int, Int, false, true);
m_ignore_fractional_outputs = field_ignore_fractional_outputs;
GET_FIELD_FROM_JSON_RETURN_ON_ERROR(json, subaddress_lookahead_major, uint32_t, Uint, false, SUBADDRESS_LOOKAHEAD_MAJOR);
m_subaddress_lookahead_major = field_subaddress_lookahead_major;
GET_FIELD_FROM_JSON_RETURN_ON_ERROR(json, subaddress_lookahead_minor, uint32_t, Uint, false, SUBADDRESS_LOOKAHEAD_MINOR);
m_subaddress_lookahead_minor = field_subaddress_lookahead_minor;
GET_FIELD_FROM_JSON_RETURN_ON_ERROR(json, encrypted_secret_keys, uint32_t, Uint, false, false);
encrypted_secret_keys = field_encrypted_secret_keys;
GET_FIELD_FROM_JSON_RETURN_ON_ERROR(json, device_name, std::string, String, false, std::string());
if (m_device_name.empty())
{
if (field_device_name_found)
{
m_device_name = field_device_name;
}
else
{
m_device_name = m_key_device_type == hw::device::device_type::LEDGER ? "Ledger" : "default";
}
}
}
else
{
THROW_WALLET_EXCEPTION(error::wallet_internal_error, "invalid password");
return false;
}
r = epee::serialization::load_t_from_binary(m_account, account_data);
THROW_WALLET_EXCEPTION_IF(!r, error::invalid_password);
if (m_key_device_type == hw::device::device_type::LEDGER || m_key_device_type == hw::device::device_type::TREZOR) {
LOG_PRINT_L0("Account on device. Initing device...");
hw::device &hwdev = lookup_device(m_device_name);
THROW_WALLET_EXCEPTION_IF(!hwdev.set_name(m_device_name), error::wallet_internal_error, "Could not set device name " + m_device_name);
hwdev.set_network_type(m_nettype);
THROW_WALLET_EXCEPTION_IF(!hwdev.init(), error::wallet_internal_error, "Could not initialize the device " + m_device_name);
THROW_WALLET_EXCEPTION_IF(!hwdev.connect(), error::wallet_internal_error, "Could not connect to the device " + m_device_name);
m_account.set_device(hwdev);
account_public_address device_account_public_address;
THROW_WALLET_EXCEPTION_IF(!hwdev.get_public_address(device_account_public_address), error::wallet_internal_error, "Cannot get a device address");
THROW_WALLET_EXCEPTION_IF(device_account_public_address != m_account.get_keys().m_account_address, error::wallet_internal_error, "Device wallet does not match wallet address. "
"Device address: " + cryptonote::get_account_address_as_str(m_nettype, false, device_account_public_address) +
", wallet address: " + m_account.get_public_address_str(m_nettype));
LOG_PRINT_L0("Device inited...");
} else if (key_on_device()) {
THROW_WALLET_EXCEPTION(error::wallet_internal_error, "hardware device not supported");
}
if (r)
{
if (encrypted_secret_keys)
{
m_account.decrypt_keys(key);
}
else
{
// rewrite with encrypted keys, ignore errors
if (m_ask_password == AskPasswordToDecrypt && !m_unattended && !m_watch_only)
encrypt_keys(key);
bool saved_ret = store_keys(keys_file_name, password, m_watch_only);
if (!saved_ret)
{
// just moan a bit, but not fatal
MERROR("Error saving keys file with encrypted keys, not fatal");
}
if (m_ask_password == AskPasswordToDecrypt && !m_unattended && !m_watch_only)
decrypt_keys(key);
m_keys_file_locker.reset();
}
}
const cryptonote::account_keys& keys = m_account.get_keys();
hw::device &hwdev = m_account.get_device();
r = r && hwdev.verify_keys(keys.m_view_secret_key, keys.m_account_address.m_view_public_key);
if(!m_watch_only && !m_multisig && hwdev.device_protocol() != hw::device::PROTOCOL_COLD)
r = r && hwdev.verify_keys(keys.m_spend_secret_key, keys.m_account_address.m_spend_public_key);
THROW_WALLET_EXCEPTION_IF(!r, error::invalid_password);
if (r)
setup_keys(password);
return true;
}
/*!
* \brief verify password for default wallet keys file.
* \param password Password to verify
* \return true if password is correct
*
* for verification only
* should not mutate state, unlike load_keys()
* can be used prior to rewriting wallet keys file, to ensure user has entered the correct password
*
*/
bool wallet2::verify_password(const epee::wipeable_string& password)
{
// this temporary unlocking is necessary for Windows (otherwise the file couldn't be loaded).
unlock_keys_file();
bool r = verify_password(m_keys_file, password, m_account.get_device().device_protocol() == hw::device::PROTOCOL_COLD || m_watch_only || m_multisig, m_account.get_device(), m_kdf_rounds);
lock_keys_file();
return r;
}
/*!
* \brief verify password for specified wallet keys file.
* \param keys_file_name Keys file to verify password for
* \param password Password to verify
* \param no_spend_key If set = only verify view keys, otherwise also spend keys
* \param hwdev The hardware device to use
* \return true if password is correct
*
* for verification only
* should not mutate state, unlike load_keys()
* can be used prior to rewriting wallet keys file, to ensure user has entered the correct password
*
*/
bool wallet2::verify_password(const std::string& keys_file_name, const epee::wipeable_string& password, bool no_spend_key, hw::device &hwdev, uint64_t kdf_rounds)
{
rapidjson::Document json;
wallet2::keys_file_data keys_file_data;
std::string buf;
bool encrypted_secret_keys = false;
bool r = epee::file_io_utils::load_file_to_string(keys_file_name, buf);
THROW_WALLET_EXCEPTION_IF(!r, error::file_read_error, keys_file_name);
// Decrypt the contents
r = ::serialization::parse_binary(buf, keys_file_data);
THROW_WALLET_EXCEPTION_IF(!r, error::wallet_internal_error, "internal error: failed to deserialize \"" + keys_file_name + '\"');
crypto::chacha_key key;
crypto::generate_chacha_key(password.data(), password.size(), key, kdf_rounds);
std::string account_data;
account_data.resize(keys_file_data.account_data.size());
crypto::chacha20(keys_file_data.account_data.data(), keys_file_data.account_data.size(), key, keys_file_data.iv, &account_data[0]);
if (json.Parse(account_data.c_str()).HasParseError() || !json.IsObject())
crypto::chacha8(keys_file_data.account_data.data(), keys_file_data.account_data.size(), key, keys_file_data.iv, &account_data[0]);
// The contents should be JSON if the wallet follows the new format.
if (json.Parse(account_data.c_str()).HasParseError())
{
// old format before JSON wallet key file format
}
else
{
account_data = std::string(json["key_data"].GetString(), json["key_data"].GetString() +
json["key_data"].GetStringLength());
GET_FIELD_FROM_JSON_RETURN_ON_ERROR(json, encrypted_secret_keys, uint32_t, Uint, false, false);
encrypted_secret_keys = field_encrypted_secret_keys;
}
cryptonote::account_base account_data_check;
r = epee::serialization::load_t_from_binary(account_data_check, account_data);
if (encrypted_secret_keys)
account_data_check.decrypt_keys(key);
const cryptonote::account_keys& keys = account_data_check.get_keys();
r = r && hwdev.verify_keys(keys.m_view_secret_key, keys.m_account_address.m_view_public_key);
if(!no_spend_key)
r = r && hwdev.verify_keys(keys.m_spend_secret_key, keys.m_account_address.m_spend_public_key);
return r;
}
void wallet2::encrypt_keys(const crypto::chacha_key &key)
{
m_account.encrypt_keys(key);
m_account.decrypt_viewkey(key);
}
void wallet2::decrypt_keys(const crypto::chacha_key &key)
{
m_account.encrypt_viewkey(key);
m_account.decrypt_keys(key);
}
void wallet2::encrypt_keys(const epee::wipeable_string &password)
{
crypto::chacha_key key;
crypto::generate_chacha_key(password.data(), password.size(), key, m_kdf_rounds);
encrypt_keys(key);
}
void wallet2::decrypt_keys(const epee::wipeable_string &password)
{
crypto::chacha_key key;
crypto::generate_chacha_key(password.data(), password.size(), key, m_kdf_rounds);
decrypt_keys(key);
}
void wallet2::setup_new_blockchain()
{
cryptonote::block b;
generate_genesis(b);
m_blockchain.push_back(get_block_hash(b));
m_last_block_reward = cryptonote::get_outs_money_amount(b.miner_tx);
add_subaddress_account(tr("Primary account"));
}
void wallet2::create_keys_file(const std::string &wallet_, bool watch_only, const epee::wipeable_string &password, bool create_address_file)
{
if (!wallet_.empty())
{
bool r = store_keys(m_keys_file, password, watch_only);
THROW_WALLET_EXCEPTION_IF(!r, error::file_save_error, m_keys_file);
if (create_address_file)
{
r = file_io_utils::save_string_to_file(m_wallet_file + ".address.txt", m_account.get_public_address_str(m_nettype));
if(!r) MERROR("String with address text not saved");
}
}
}
/*!
* \brief determine the key storage for the specified wallet file
* \param device_type (OUT) wallet backend as enumerated in hw::device::device_type
* \param keys_file_name Keys file to verify password for
* \param password Password to verify
* \return true if password correct, else false
*
* for verification only - determines key storage hardware
*
*/
bool wallet2::query_device(hw::device::device_type& device_type, const std::string& keys_file_name, const epee::wipeable_string& password, uint64_t kdf_rounds)
{
rapidjson::Document json;
wallet2::keys_file_data keys_file_data;
std::string buf;
bool r = epee::file_io_utils::load_file_to_string(keys_file_name, buf);
THROW_WALLET_EXCEPTION_IF(!r, error::file_read_error, keys_file_name);
// Decrypt the contents
r = ::serialization::parse_binary(buf, keys_file_data);
THROW_WALLET_EXCEPTION_IF(!r, error::wallet_internal_error, "internal error: failed to deserialize \"" + keys_file_name + '\"');
crypto::chacha_key key;
crypto::generate_chacha_key(password.data(), password.size(), key, kdf_rounds);
std::string account_data;
account_data.resize(keys_file_data.account_data.size());
crypto::chacha20(keys_file_data.account_data.data(), keys_file_data.account_data.size(), key, keys_file_data.iv, &account_data[0]);
if (json.Parse(account_data.c_str()).HasParseError() || !json.IsObject())
crypto::chacha8(keys_file_data.account_data.data(), keys_file_data.account_data.size(), key, keys_file_data.iv, &account_data[0]);
device_type = hw::device::device_type::SOFTWARE;
// The contents should be JSON if the wallet follows the new format.
if (json.Parse(account_data.c_str()).HasParseError())
{
// old format before JSON wallet key file format
}
else
{
account_data = std::string(json["key_data"].GetString(), json["key_data"].GetString() +
json["key_data"].GetStringLength());
if (json.HasMember("key_on_device"))
{
GET_FIELD_FROM_JSON_RETURN_ON_ERROR(json, key_on_device, int, Int, false, hw::device::device_type::SOFTWARE);
device_type = static_cast<hw::device::device_type>(field_key_on_device);
}
}
cryptonote::account_base account_data_check;
r = epee::serialization::load_t_from_binary(account_data_check, account_data);
if (!r) return false;
return true;
}
/*!
* \brief Generates a wallet or restores one.
* \param wallet_ Name of wallet file
* \param password Password of wallet file
* \param multisig_data The multisig restore info and keys
* \param create_address_file Whether to create an address file
*/
void wallet2::generate(const std::string& wallet_, const epee::wipeable_string& password,
const epee::wipeable_string& multisig_data, bool create_address_file)
{
clear();
prepare_file_names(wallet_);
if (!wallet_.empty())
{
boost::system::error_code ignored_ec;
THROW_WALLET_EXCEPTION_IF(boost::filesystem::exists(m_wallet_file, ignored_ec), error::file_exists, m_wallet_file);
THROW_WALLET_EXCEPTION_IF(boost::filesystem::exists(m_keys_file, ignored_ec), error::file_exists, m_keys_file);
}
m_account.generate(rct::rct2sk(rct::zero()), true, false);
THROW_WALLET_EXCEPTION_IF(multisig_data.size() < 32, error::invalid_multisig_seed);
size_t offset = 0;
uint32_t threshold = *(uint32_t*)(multisig_data.data() + offset);
offset += sizeof(uint32_t);
uint32_t total = *(uint32_t*)(multisig_data.data() + offset);
offset += sizeof(uint32_t);
THROW_WALLET_EXCEPTION_IF(threshold < 2, error::invalid_multisig_seed);
THROW_WALLET_EXCEPTION_IF(total != threshold && total != threshold + 1, error::invalid_multisig_seed);
const size_t n_multisig_keys = total == threshold ? 1 : threshold;
THROW_WALLET_EXCEPTION_IF(multisig_data.size() != 8 + 32 * (4 + n_multisig_keys + total), error::invalid_multisig_seed);
std::vector<crypto::secret_key> multisig_keys;
std::vector<crypto::public_key> multisig_signers;
crypto::secret_key spend_secret_key = *(crypto::secret_key*)(multisig_data.data() + offset);
offset += sizeof(crypto::secret_key);
crypto::public_key spend_public_key = *(crypto::public_key*)(multisig_data.data() + offset);
offset += sizeof(crypto::public_key);
crypto::secret_key view_secret_key = *(crypto::secret_key*)(multisig_data.data() + offset);
offset += sizeof(crypto::secret_key);
crypto::public_key view_public_key = *(crypto::public_key*)(multisig_data.data() + offset);
offset += sizeof(crypto::public_key);
for (size_t n = 0; n < n_multisig_keys; ++n)
{
multisig_keys.push_back(*(crypto::secret_key*)(multisig_data.data() + offset));
offset += sizeof(crypto::secret_key);
}
for (size_t n = 0; n < total; ++n)
{
multisig_signers.push_back(*(crypto::public_key*)(multisig_data.data() + offset));
offset += sizeof(crypto::public_key);
}
crypto::public_key calculated_view_public_key;
THROW_WALLET_EXCEPTION_IF(!crypto::secret_key_to_public_key(view_secret_key, calculated_view_public_key), error::invalid_multisig_seed);
THROW_WALLET_EXCEPTION_IF(view_public_key != calculated_view_public_key, error::invalid_multisig_seed);
crypto::public_key local_signer;
THROW_WALLET_EXCEPTION_IF(!crypto::secret_key_to_public_key(spend_secret_key, local_signer), error::invalid_multisig_seed);
THROW_WALLET_EXCEPTION_IF(std::find(multisig_signers.begin(), multisig_signers.end(), local_signer) == multisig_signers.end(), error::invalid_multisig_seed);
rct::key skey = rct::zero();
for (const auto &msk: multisig_keys)
sc_add(skey.bytes, skey.bytes, rct::sk2rct(msk).bytes);
THROW_WALLET_EXCEPTION_IF(!(rct::rct2sk(skey) == spend_secret_key), error::invalid_multisig_seed);
memwipe(&skey, sizeof(rct::key));
m_account.make_multisig(view_secret_key, spend_secret_key, spend_public_key, multisig_keys);
m_account.finalize_multisig(spend_public_key);
m_account_public_address = m_account.get_keys().m_account_address;
m_watch_only = false;
m_multisig = true;
m_multisig_threshold = threshold;
m_multisig_signers = multisig_signers;
m_key_device_type = hw::device::device_type::SOFTWARE;
setup_keys(password);
create_keys_file(wallet_, false, password, m_nettype != MAINNET || create_address_file);
setup_new_blockchain();
if (!wallet_.empty())
store();
}
/*!
* \brief Generates a wallet or restores one.
* \param wallet_ Name of wallet file
* \param password Password of wallet file
* \param recovery_param If it is a restore, the recovery key
* \param recover Whether it is a restore
* \param two_random Whether it is a non-deterministic wallet
* \param create_address_file Whether to create an address file
* \return The secret key of the generated wallet
*/
crypto::secret_key wallet2::generate(const std::string& wallet_, const epee::wipeable_string& password,
const crypto::secret_key& recovery_param, bool recover, bool two_random, bool create_address_file)
{
clear();
prepare_file_names(wallet_);
if (!wallet_.empty())
{
boost::system::error_code ignored_ec;
THROW_WALLET_EXCEPTION_IF(boost::filesystem::exists(m_wallet_file, ignored_ec), error::file_exists, m_wallet_file);
THROW_WALLET_EXCEPTION_IF(boost::filesystem::exists(m_keys_file, ignored_ec), error::file_exists, m_keys_file);
}
crypto::secret_key retval = m_account.generate(recovery_param, recover, two_random);
m_account_public_address = m_account.get_keys().m_account_address;
m_watch_only = false;
m_multisig = false;
m_multisig_threshold = 0;
m_multisig_signers.clear();
m_key_device_type = hw::device::device_type::SOFTWARE;
setup_keys(password);
// calculate a starting refresh height
if(m_refresh_from_block_height == 0 && !recover){
m_refresh_from_block_height = estimate_blockchain_height();
}
create_keys_file(wallet_, false, password, m_nettype != MAINNET || create_address_file);
setup_new_blockchain();
if (!wallet_.empty())
store();
return retval;
}
uint64_t wallet2::estimate_blockchain_height()
{
// -1 month for fluctuations in block time and machine date/time setup.
// avg seconds per block
const int seconds_per_block = DIFFICULTY_TARGET_V2;
// ~num blocks per month
const uint64_t blocks_per_month = 60*60*24*30/seconds_per_block;
// try asking the daemon first
std::string err;
uint64_t height = 0;
// we get the max of approximated height and local height.
// approximated height is the least of daemon target height
// (the max of what the other daemons are claiming is their
// height) and the theoretical height based on the local
// clock. This will be wrong only if both the local clock
// is bad *and* a peer daemon claims a highest height than
// the real chain.
// local height is the height the local daemon is currently
// synced to, it will be lower than the real chain height if
// the daemon is currently syncing.
// If we use the approximate height we subtract one month as
// a safety margin.
height = get_approximate_blockchain_height();
uint64_t target_height = get_daemon_blockchain_target_height(err);
if (err.empty()) {
if (target_height < height)
height = target_height;
} else {
// if we couldn't talk to the daemon, check safety margin.
if (height > blocks_per_month)
height -= blocks_per_month;
else
height = 0;
}
uint64_t local_height = get_daemon_blockchain_height(err);
if (err.empty() && local_height > height)
height = local_height;
return height;
}
/*!
* \brief Creates a watch only wallet from a public address and a view secret key.
* \param wallet_ Name of wallet file
* \param password Password of wallet file
* \param account_public_address The account's public address
* \param viewkey view secret key
* \param create_address_file Whether to create an address file
*/
void wallet2::generate(const std::string& wallet_, const epee::wipeable_string& password,
const cryptonote::account_public_address &account_public_address,
const crypto::secret_key& viewkey, bool create_address_file)
{
clear();
prepare_file_names(wallet_);
if (!wallet_.empty())
{
boost::system::error_code ignored_ec;
THROW_WALLET_EXCEPTION_IF(boost::filesystem::exists(m_wallet_file, ignored_ec), error::file_exists, m_wallet_file);
THROW_WALLET_EXCEPTION_IF(boost::filesystem::exists(m_keys_file, ignored_ec), error::file_exists, m_keys_file);
}
m_account.create_from_viewkey(account_public_address, viewkey);
m_account_public_address = account_public_address;
m_watch_only = true;
m_multisig = false;
m_multisig_threshold = 0;
m_multisig_signers.clear();
m_key_device_type = hw::device::device_type::SOFTWARE;
setup_keys(password);
create_keys_file(wallet_, true, password, m_nettype != MAINNET || create_address_file);
setup_new_blockchain();
if (!wallet_.empty())
store();
}
/*!
* \brief Creates a wallet from a public address and a spend/view secret key pair.
* \param wallet_ Name of wallet file
* \param password Password of wallet file
* \param account_public_address The account's public address
* \param spendkey spend secret key
* \param viewkey view secret key
* \param create_address_file Whether to create an address file
*/
void wallet2::generate(const std::string& wallet_, const epee::wipeable_string& password,
const cryptonote::account_public_address &account_public_address,
const crypto::secret_key& spendkey, const crypto::secret_key& viewkey, bool create_address_file)
{
clear();
prepare_file_names(wallet_);
if (!wallet_.empty())
{
boost::system::error_code ignored_ec;
THROW_WALLET_EXCEPTION_IF(boost::filesystem::exists(m_wallet_file, ignored_ec), error::file_exists, m_wallet_file);
THROW_WALLET_EXCEPTION_IF(boost::filesystem::exists(m_keys_file, ignored_ec), error::file_exists, m_keys_file);
}
m_account.create_from_keys(account_public_address, spendkey, viewkey);
m_account_public_address = account_public_address;
m_watch_only = false;
m_multisig = false;
m_multisig_threshold = 0;
m_multisig_signers.clear();
m_key_device_type = hw::device::device_type::SOFTWARE;
setup_keys(password);
create_keys_file(wallet_, false, password, create_address_file);
setup_new_blockchain();
if (!wallet_.empty())
store();
}
/*!
* \brief Creates a wallet from a device
* \param wallet_ Name of wallet file
* \param password Password of wallet file
* \param device_name device string address
*/
void wallet2::restore(const std::string& wallet_, const epee::wipeable_string& password, const std::string &device_name, bool create_address_file)
{
clear();
prepare_file_names(wallet_);
boost::system::error_code ignored_ec;
if (!wallet_.empty()) {
THROW_WALLET_EXCEPTION_IF(boost::filesystem::exists(m_wallet_file, ignored_ec), error::file_exists, m_wallet_file);
THROW_WALLET_EXCEPTION_IF(boost::filesystem::exists(m_keys_file, ignored_ec), error::file_exists, m_keys_file);
}
auto &hwdev = lookup_device(device_name);
hwdev.set_name(device_name);
hwdev.set_network_type(m_nettype);
m_account.create_from_device(hwdev);
m_key_device_type = m_account.get_device().get_type();
m_account_public_address = m_account.get_keys().m_account_address;
m_watch_only = false;
m_multisig = false;
m_multisig_threshold = 0;
m_multisig_signers.clear();
setup_keys(password);
m_device_name = device_name;
create_keys_file(wallet_, false, password, m_nettype != MAINNET || create_address_file);
if (m_subaddress_lookahead_major == SUBADDRESS_LOOKAHEAD_MAJOR && m_subaddress_lookahead_minor == SUBADDRESS_LOOKAHEAD_MINOR)
{
// the default lookahead setting (50:200) is clearly too much for hardware wallet
m_subaddress_lookahead_major = 5;
m_subaddress_lookahead_minor = 20;
}
setup_new_blockchain();
if (!wallet_.empty()) {
store();
}
}
std::string wallet2::make_multisig(const epee::wipeable_string &password,
const std::vector<crypto::secret_key> &view_keys,
const std::vector<crypto::public_key> &spend_keys,
uint32_t threshold)
{
CHECK_AND_ASSERT_THROW_MES(!view_keys.empty(), "empty view keys");
CHECK_AND_ASSERT_THROW_MES(view_keys.size() == spend_keys.size(), "Mismatched view/spend key sizes");
CHECK_AND_ASSERT_THROW_MES(threshold > 1 && threshold <= spend_keys.size() + 1, "Invalid threshold");
std::string extra_multisig_info;
std::vector<crypto::secret_key> multisig_keys;
rct::key spend_pkey = rct::identity();
rct::key spend_skey;
std::vector<crypto::public_key> multisig_signers;
// decrypt keys
epee::misc_utils::auto_scope_leave_caller keys_reencryptor;
if (m_ask_password == AskPasswordToDecrypt && !m_unattended && !m_watch_only)
{
crypto::chacha_key chacha_key;
crypto::generate_chacha_key(password.data(), password.size(), chacha_key, m_kdf_rounds);
m_account.encrypt_viewkey(chacha_key);
m_account.decrypt_keys(chacha_key);
keys_reencryptor = epee::misc_utils::create_scope_leave_handler([&, this, chacha_key]() { m_account.encrypt_keys(chacha_key); m_account.decrypt_viewkey(chacha_key); });
}
// In common multisig scheme there are 4 types of key exchange rounds:
// 1. First round is exchange of view secret keys and public spend keys.
// 2. Middle round is exchange of derivations: Ki = b * Mj, where b - spend secret key,
// M - public multisig key (in first round it equals to public spend key), K - new public multisig key.
// 3. Secret spend establishment round sets your secret multisig keys as follows: kl = H(Ml), where M - is *your* public multisig key,
// k - secret multisig key used to sign transactions. k and M are sets of keys, of course.
// And secret spend key as the sum of all participant's secret multisig keys
// 4. Last round establishes multisig wallet's public spend key. Participants exchange their public multisig keys
// and calculate common spend public key as sum of all unique participants' public multisig keys.
// Note that N/N scheme has only first round. N-1/N has 2 rounds: first and last. Common M/N has all 4 rounds.
// IMPORTANT: wallet's public spend key is not equal to secret_spend_key * G!
// Wallet's public spend key is the sum of unique public multisig keys of all participants.
// secret_spend_key * G = public signer key
if (threshold == spend_keys.size() + 1)
{
// In N / N case we only need to do one round and calculate secret multisig keys and new secret spend key
MINFO("Creating spend key...");
// Calculates all multisig keys and spend key
cryptonote::generate_multisig_N_N(get_account().get_keys(), spend_keys, multisig_keys, spend_skey, spend_pkey);
// Our signer key is b * G, where b is secret spend key.
multisig_signers = spend_keys;
multisig_signers.push_back(get_multisig_signer_public_key(get_account().get_keys().m_spend_secret_key));
}
else
{
// We just got public spend keys of all participants and deriving multisig keys (set of Mi = b * Bi).
// note that derivations are public keys as DH exchange suppose it to be
auto derivations = cryptonote::generate_multisig_derivations(get_account().get_keys(), spend_keys);
spend_pkey = rct::identity();
multisig_signers = std::vector<crypto::public_key>(spend_keys.size() + 1, crypto::null_pkey);
if (threshold == spend_keys.size())
{
// N - 1 / N case
// We need an extra step, so we package all the composite public keys
// we know about, and make a signed string out of them
MINFO("Creating spend key...");
// Calculating set of our secret multisig keys as follows: mi = H(Mi),
// where mi - secret multisig key, Mi - others' participants public multisig key
multisig_keys = cryptonote::calculate_multisig_keys(derivations);
// calculating current participant's spend secret key as sum of all secret multisig keys for current participant.
// IMPORTANT: participant's secret spend key is not an entire wallet's secret spend!
// Entire wallet's secret spend is sum of all unique secret multisig keys
// among all of participants and is not held by anyone!
spend_skey = rct::sk2rct(cryptonote::calculate_multisig_signer_key(multisig_keys));
// Preparing data for the last round to calculate common public spend key. The data contains public multisig keys.
extra_multisig_info = pack_multisignature_keys(MULTISIG_EXTRA_INFO_MAGIC, secret_keys_to_public_keys(multisig_keys), rct::rct2sk(spend_skey));
}
else
{
// M / N case
MINFO("Preparing keys for next exchange round...");
// Preparing data for middle round - packing new public multisig keys to exchage with others.
extra_multisig_info = pack_multisignature_keys(MULTISIG_EXTRA_INFO_MAGIC, derivations, m_account.get_keys().m_spend_secret_key);
spend_skey = rct::sk2rct(m_account.get_keys().m_spend_secret_key);
// Need to store middle keys to be able to proceed in case of wallet shutdown.
m_multisig_derivations = derivations;
}
}
clear();
MINFO("Creating view key...");
crypto::secret_key view_skey = cryptonote::generate_multisig_view_secret_key(get_account().get_keys().m_view_secret_key, view_keys);
MINFO("Creating multisig address...");
CHECK_AND_ASSERT_THROW_MES(m_account.make_multisig(view_skey, rct::rct2sk(spend_skey), rct::rct2pk(spend_pkey), multisig_keys),
"Failed to create multisig wallet due to bad keys");
memwipe(&spend_skey, sizeof(rct::key));
m_account_public_address = m_account.get_keys().m_account_address;
m_watch_only = false;
m_multisig = true;
m_key_device_type = hw::device::device_type::SOFTWARE;
m_multisig_threshold = threshold;
m_multisig_signers = multisig_signers;
++m_multisig_rounds_passed;
// re-encrypt keys
keys_reencryptor = epee::misc_utils::auto_scope_leave_caller();
create_keys_file(m_wallet_file, false, password, boost::filesystem::exists(m_wallet_file + ".address.txt"));
setup_new_blockchain();
if (!m_wallet_file.empty())
store();
return extra_multisig_info;
}
std::string wallet2::exchange_multisig_keys(const epee::wipeable_string &password,
const std::vector<std::string> &info)
{
THROW_WALLET_EXCEPTION_IF(info.empty(),
error::wallet_internal_error, "Empty multisig info");
if (info[0].substr(0, MULTISIG_EXTRA_INFO_MAGIC.size()) != MULTISIG_EXTRA_INFO_MAGIC)
{
THROW_WALLET_EXCEPTION_IF(false,
error::wallet_internal_error, "Unsupported info string");
}
std::vector<crypto::public_key> signers;
std::unordered_set<crypto::public_key> pkeys;
THROW_WALLET_EXCEPTION_IF(!unpack_extra_multisig_info(info, signers, pkeys),
error::wallet_internal_error, "Bad extra multisig info");
return exchange_multisig_keys(password, pkeys, signers);
}
std::string wallet2::exchange_multisig_keys(const epee::wipeable_string &password,
std::unordered_set<crypto::public_key> derivations,
std::vector<crypto::public_key> signers)
{
CHECK_AND_ASSERT_THROW_MES(!derivations.empty(), "empty pkeys");
CHECK_AND_ASSERT_THROW_MES(!signers.empty(), "empty signers");
bool ready = false;
CHECK_AND_ASSERT_THROW_MES(multisig(&ready), "The wallet is not multisig");
CHECK_AND_ASSERT_THROW_MES(!ready, "Multisig wallet creation process has already been finished");
// keys are decrypted
epee::misc_utils::auto_scope_leave_caller keys_reencryptor;
if (m_ask_password == AskPasswordToDecrypt && !m_unattended && !m_watch_only)
{
crypto::chacha_key chacha_key;
crypto::generate_chacha_key(password.data(), password.size(), chacha_key, m_kdf_rounds);
m_account.encrypt_viewkey(chacha_key);
m_account.decrypt_keys(chacha_key);
keys_reencryptor = epee::misc_utils::create_scope_leave_handler([&, this, chacha_key]() { m_account.encrypt_keys(chacha_key); m_account.decrypt_viewkey(chacha_key); });
}
if (m_multisig_rounds_passed == multisig_rounds_required(m_multisig_signers.size(), m_multisig_threshold) - 1)
{
// the last round is passed and we have to calculate spend public key
// add ours if not included
crypto::public_key local_signer = get_multisig_signer_public_key();
if (std::find(signers.begin(), signers.end(), local_signer) == signers.end())
{
signers.push_back(local_signer);
for (const auto &msk: get_account().get_multisig_keys())
{
derivations.insert(rct::rct2pk(rct::scalarmultBase(rct::sk2rct(msk))));
}
}
CHECK_AND_ASSERT_THROW_MES(signers.size() == m_multisig_signers.size(), "Bad signers size");
// Summing all of unique public multisig keys to calculate common public spend key
crypto::public_key spend_public_key = cryptonote::generate_multisig_M_N_spend_public_key(std::vector<crypto::public_key>(derivations.begin(), derivations.end()));
m_account_public_address.m_spend_public_key = spend_public_key;
m_account.finalize_multisig(spend_public_key);
m_multisig_signers = signers;
std::sort(m_multisig_signers.begin(), m_multisig_signers.end(), [](const crypto::public_key &e0, const crypto::public_key &e1){ return memcmp(&e0, &e1, sizeof(e0)); });
++m_multisig_rounds_passed;
m_multisig_derivations.clear();
// keys are encrypted again
keys_reencryptor = epee::misc_utils::auto_scope_leave_caller();
if (!m_wallet_file.empty())
{
bool r = store_keys(m_keys_file, password, false);
THROW_WALLET_EXCEPTION_IF(!r, error::file_save_error, m_keys_file);
if (boost::filesystem::exists(m_wallet_file + ".address.txt"))
{
r = file_io_utils::save_string_to_file(m_wallet_file + ".address.txt", m_account.get_public_address_str(m_nettype));
if(!r) MERROR("String with address text not saved");
}
}
m_subaddresses.clear();
m_subaddress_labels.clear();
add_subaddress_account(tr("Primary account"));
if (!m_wallet_file.empty())
store();
return {};
}
// Below are either middle or secret spend key establishment rounds
for (const auto& key: m_multisig_derivations)
derivations.erase(key);
// Deriving multisig keys (set of Mi = b * Bi) according to DH from other participants' multisig keys.
auto new_derivations = cryptonote::generate_multisig_derivations(get_account().get_keys(), std::vector<crypto::public_key>(derivations.begin(), derivations.end()));
std::string extra_multisig_info;
if (m_multisig_rounds_passed == multisig_rounds_required(m_multisig_signers.size(), m_multisig_threshold) - 2) // next round is last
{
// Next round is last therefore we are performing secret spend establishment round as described above.
MINFO("Creating spend key...");
// Calculating our secret multisig keys by hashing our public multisig keys.
auto multisig_keys = cryptonote::calculate_multisig_keys(std::vector<crypto::public_key>(new_derivations.begin(), new_derivations.end()));
// And summing it to get personal secret spend key
crypto::secret_key spend_skey = cryptonote::calculate_multisig_signer_key(multisig_keys);
m_account.make_multisig(m_account.get_keys().m_view_secret_key, spend_skey, rct::rct2pk(rct::identity()), multisig_keys);
// Packing public multisig keys to exchange with others and calculate common public spend key in the last round
extra_multisig_info = pack_multisignature_keys(MULTISIG_EXTRA_INFO_MAGIC, secret_keys_to_public_keys(multisig_keys), spend_skey);
}
else
{
// This is just middle round
MINFO("Preparing keys for next exchange round...");
extra_multisig_info = pack_multisignature_keys(MULTISIG_EXTRA_INFO_MAGIC, new_derivations, m_account.get_keys().m_spend_secret_key);
m_multisig_derivations = new_derivations;
}
++m_multisig_rounds_passed;
create_keys_file(m_wallet_file, false, password, boost::filesystem::exists(m_wallet_file + ".address.txt"));
return extra_multisig_info;
}
void wallet2::unpack_multisig_info(const std::vector<std::string>& info,
std::vector<crypto::public_key> &public_keys,
std::vector<crypto::secret_key> &secret_keys) const
{
// parse all multisig info
public_keys.resize(info.size());
secret_keys.resize(info.size());
for (size_t i = 0; i < info.size(); ++i)
{
THROW_WALLET_EXCEPTION_IF(!verify_multisig_info(info[i], secret_keys[i], public_keys[i]),
error::wallet_internal_error, "Bad multisig info: " + info[i]);
}
// remove duplicates
for (size_t i = 0; i < secret_keys.size(); ++i)
{
for (size_t j = i + 1; j < secret_keys.size(); ++j)
{
if (rct::sk2rct(secret_keys[i]) == rct::sk2rct(secret_keys[j]))
{
MDEBUG("Duplicate key found, ignoring");
secret_keys[j] = secret_keys.back();
public_keys[j] = public_keys.back();
secret_keys.pop_back();
public_keys.pop_back();
--j;
}
}
}
// people may include their own, weed it out
const crypto::secret_key local_skey = cryptonote::get_multisig_blinded_secret_key(get_account().get_keys().m_view_secret_key);
const crypto::public_key local_pkey = get_multisig_signer_public_key(get_account().get_keys().m_spend_secret_key);
for (size_t i = 0; i < secret_keys.size(); ++i)
{
if (secret_keys[i] == local_skey)
{
MDEBUG("Local key is present, ignoring");
secret_keys[i] = secret_keys.back();
public_keys[i] = public_keys.back();
secret_keys.pop_back();
public_keys.pop_back();
--i;
}
else
{
THROW_WALLET_EXCEPTION_IF(public_keys[i] == local_pkey, error::wallet_internal_error,
"Found local spend public key, but not local view secret key - something very weird");
}
}
}
std::string wallet2::make_multisig(const epee::wipeable_string &password,
const std::vector<std::string> &info,
uint32_t threshold)
{
std::vector<crypto::secret_key> secret_keys(info.size());
std::vector<crypto::public_key> public_keys(info.size());
unpack_multisig_info(info, public_keys, secret_keys);
return make_multisig(password, secret_keys, public_keys, threshold);
}
bool wallet2::finalize_multisig(const epee::wipeable_string &password, std::unordered_set<crypto::public_key> pkeys, std::vector<crypto::public_key> signers)
{
exchange_multisig_keys(password, pkeys, signers);
return true;
}
bool wallet2::unpack_extra_multisig_info(const std::vector<std::string>& info,
std::vector<crypto::public_key> &signers,
std::unordered_set<crypto::public_key> &pkeys) const
{
// parse all multisig info
signers.resize(info.size(), crypto::null_pkey);
for (size_t i = 0; i < info.size(); ++i)
{
if (!verify_extra_multisig_info(info[i], pkeys, signers[i]))
{
return false;
}
}
return true;
}
bool wallet2::finalize_multisig(const epee::wipeable_string &password, const std::vector<std::string> &info)
{
std::unordered_set<crypto::public_key> public_keys;
std::vector<crypto::public_key> signers;
if (!unpack_extra_multisig_info(info, signers, public_keys))
{
MERROR("Bad multisig info");
return false;
}
return finalize_multisig(password, public_keys, signers);
}
std::string wallet2::get_multisig_info() const
{
// It's a signed package of private view key and public spend key
const crypto::secret_key skey = cryptonote::get_multisig_blinded_secret_key(get_account().get_keys().m_view_secret_key);
const crypto::public_key pkey = get_multisig_signer_public_key(get_account().get_keys().m_spend_secret_key);
crypto::hash hash;
std::string data;
data += std::string((const char *)&skey, sizeof(crypto::secret_key));
data += std::string((const char *)&pkey, sizeof(crypto::public_key));
data.resize(data.size() + sizeof(crypto::signature));
crypto::cn_fast_hash(data.data(), data.size() - sizeof(signature), hash);
crypto::signature &signature = *(crypto::signature*)&data[data.size() - sizeof(crypto::signature)];
crypto::generate_signature(hash, pkey, get_multisig_blinded_secret_key(get_account().get_keys().m_spend_secret_key), signature);
return std::string("MultisigV1") + tools::base58::encode(data);
}
bool wallet2::verify_multisig_info(const std::string &data, crypto::secret_key &skey, crypto::public_key &pkey)
{
const size_t header_len = strlen("MultisigV1");
if (data.size() < header_len || data.substr(0, header_len) != "MultisigV1")
{
MERROR("Multisig info header check error");
return false;
}
std::string decoded;
if (!tools::base58::decode(data.substr(header_len), decoded))
{
MERROR("Multisig info decoding error");
return false;
}
if (decoded.size() != sizeof(crypto::secret_key) + sizeof(crypto::public_key) + sizeof(crypto::signature))
{
MERROR("Multisig info is corrupt");
return false;
}
size_t offset = 0;
skey = *(const crypto::secret_key*)(decoded.data() + offset);
offset += sizeof(skey);
pkey = *(const crypto::public_key*)(decoded.data() + offset);
offset += sizeof(pkey);
const crypto::signature &signature = *(const crypto::signature*)(decoded.data() + offset);
crypto::hash hash;
crypto::cn_fast_hash(decoded.data(), decoded.size() - sizeof(signature), hash);
if (!crypto::check_signature(hash, pkey, signature))
{
MERROR("Multisig info signature is invalid");
return false;
}
return true;
}
bool wallet2::verify_extra_multisig_info(const std::string &data, std::unordered_set<crypto::public_key> &pkeys, crypto::public_key &signer)
{
if (data.size() < MULTISIG_EXTRA_INFO_MAGIC.size() || data.substr(0, MULTISIG_EXTRA_INFO_MAGIC.size()) != MULTISIG_EXTRA_INFO_MAGIC)
{
MERROR("Multisig info header check error");
return false;
}
std::string decoded;
if (!tools::base58::decode(data.substr(MULTISIG_EXTRA_INFO_MAGIC.size()), decoded))
{
MERROR("Multisig info decoding error");
return false;
}
if (decoded.size() < sizeof(crypto::public_key) + sizeof(crypto::signature))
{
MERROR("Multisig info is corrupt");
return false;
}
if ((decoded.size() - (sizeof(crypto::public_key) + sizeof(crypto::signature))) % sizeof(crypto::public_key))
{
MERROR("Multisig info is corrupt");
return false;
}
const size_t n_keys = (decoded.size() - (sizeof(crypto::public_key) + sizeof(crypto::signature))) / sizeof(crypto::public_key);
size_t offset = 0;
signer = *(const crypto::public_key*)(decoded.data() + offset);
offset += sizeof(signer);
const crypto::signature &signature = *(const crypto::signature*)(decoded.data() + offset + n_keys * sizeof(crypto::public_key));
crypto::hash hash;
crypto::cn_fast_hash(decoded.data(), decoded.size() - sizeof(signature), hash);
if (!crypto::check_signature(hash, signer, signature))
{
MERROR("Multisig info signature is invalid");
return false;
}
for (size_t n = 0; n < n_keys; ++n)
{
crypto::public_key mspk = *(const crypto::public_key*)(decoded.data() + offset);
pkeys.insert(mspk);
offset += sizeof(mspk);
}
return true;
}
bool wallet2::multisig(bool *ready, uint32_t *threshold, uint32_t *total) const
{
if (!m_multisig)
return false;
if (threshold)
*threshold = m_multisig_threshold;
if (total)
*total = m_multisig_signers.size();
if (ready)
*ready = !(get_account().get_keys().m_account_address.m_spend_public_key == rct::rct2pk(rct::identity()));
return true;
}
bool wallet2::has_multisig_partial_key_images() const
{
if (!m_multisig)
return false;
for (const auto &td: m_transfers)
if (td.m_key_image_partial)
return true;
return false;
}
bool wallet2::has_unknown_key_images() const
{
for (const auto &td: m_transfers)
if (!td.m_key_image_known)
return true;
return false;
}
/*!
* \brief Rewrites to the wallet file for wallet upgrade (doesn't generate key, assumes it's already there)
* \param wallet_name Name of wallet file (should exist)
* \param password Password for wallet file
*/
void wallet2::rewrite(const std::string& wallet_name, const epee::wipeable_string& password)
{
if (wallet_name.empty())
return;
prepare_file_names(wallet_name);
boost::system::error_code ignored_ec;
THROW_WALLET_EXCEPTION_IF(!boost::filesystem::exists(m_keys_file, ignored_ec), error::file_not_found, m_keys_file);
bool r = store_keys(m_keys_file, password, m_watch_only);
THROW_WALLET_EXCEPTION_IF(!r, error::file_save_error, m_keys_file);
}
/*!
* \brief Writes to a file named based on the normal wallet (doesn't generate key, assumes it's already there)
* \param wallet_name Base name of wallet file
* \param password Password for wallet file
* \param new_keys_filename [OUT] Name of new keys file
*/
void wallet2::write_watch_only_wallet(const std::string& wallet_name, const epee::wipeable_string& password, std::string &new_keys_filename)
{
prepare_file_names(wallet_name);
boost::system::error_code ignored_ec;
new_keys_filename = m_wallet_file + "-watchonly.keys";
bool watch_only_keys_file_exists = boost::filesystem::exists(new_keys_filename, ignored_ec);
THROW_WALLET_EXCEPTION_IF(watch_only_keys_file_exists, error::file_save_error, new_keys_filename);
bool r = store_keys(new_keys_filename, password, true);
THROW_WALLET_EXCEPTION_IF(!r, error::file_save_error, new_keys_filename);
}
//----------------------------------------------------------------------------------------------------
void wallet2::wallet_exists(const std::string& file_path, bool& keys_file_exists, bool& wallet_file_exists)
{
std::string keys_file, wallet_file;
do_prepare_file_names(file_path, keys_file, wallet_file);
boost::system::error_code ignore;
keys_file_exists = boost::filesystem::exists(keys_file, ignore);
wallet_file_exists = boost::filesystem::exists(wallet_file, ignore);
}
//----------------------------------------------------------------------------------------------------
bool wallet2::wallet_valid_path_format(const std::string& file_path)
{
return !file_path.empty();
}
//----------------------------------------------------------------------------------------------------
bool wallet2::parse_long_payment_id(const std::string& payment_id_str, crypto::hash& payment_id)
{
cryptonote::blobdata payment_id_data;
if(!epee::string_tools::parse_hexstr_to_binbuff(payment_id_str, payment_id_data))
return false;
if(sizeof(crypto::hash) != payment_id_data.size())
return false;
payment_id = *reinterpret_cast<const crypto::hash*>(payment_id_data.data());
return true;
}
//----------------------------------------------------------------------------------------------------
bool wallet2::parse_short_payment_id(const std::string& payment_id_str, crypto::hash8& payment_id)
{
cryptonote::blobdata payment_id_data;
if(!epee::string_tools::parse_hexstr_to_binbuff(payment_id_str, payment_id_data))
return false;
if(sizeof(crypto::hash8) != payment_id_data.size())
return false;
payment_id = *reinterpret_cast<const crypto::hash8*>(payment_id_data.data());
return true;
}
//----------------------------------------------------------------------------------------------------
bool wallet2::parse_payment_id(const std::string& payment_id_str, crypto::hash& payment_id)
{
if (parse_long_payment_id(payment_id_str, payment_id))
return true;
crypto::hash8 payment_id8;
if (parse_short_payment_id(payment_id_str, payment_id8))
{
memcpy(payment_id.data, payment_id8.data, 8);
memset(payment_id.data + 8, 0, 24);
return true;
}
return false;
}
//----------------------------------------------------------------------------------------------------
bool wallet2::prepare_file_names(const std::string& file_path)
{
do_prepare_file_names(file_path, m_keys_file, m_wallet_file);
return true;
}
//----------------------------------------------------------------------------------------------------
bool wallet2::check_connection(uint32_t *version, uint32_t timeout)
{
THROW_WALLET_EXCEPTION_IF(!m_is_initialized, error::wallet_not_initialized);
boost::lock_guard<boost::mutex> lock(m_daemon_rpc_mutex);
// TODO: Add light wallet version check.
if(m_light_wallet) {
version = 0;
return m_light_wallet_connected;
}
if(!m_http_client.is_connected())
{
m_node_rpc_proxy.invalidate();
if (!m_http_client.connect(std::chrono::milliseconds(timeout)))
return false;
}
if (version)
{
cryptonote::COMMAND_RPC_GET_VERSION::request req_t = AUTO_VAL_INIT(req_t);
cryptonote::COMMAND_RPC_GET_VERSION::response resp_t = AUTO_VAL_INIT(resp_t);
bool r = net_utils::invoke_http_json_rpc("/json_rpc", "get_version", req_t, resp_t, m_http_client);
if(!r) {
*version = 0;
return false;
}
if (resp_t.status != CORE_RPC_STATUS_OK)
*version = 0;
else
*version = resp_t.version;
}
return true;
}
//----------------------------------------------------------------------------------------------------
bool wallet2::generate_chacha_key_from_secret_keys(crypto::chacha_key &key) const
{
hw::device &hwdev = m_account.get_device();
return hwdev.generate_chacha_key(m_account.get_keys(), key, m_kdf_rounds);
}
//----------------------------------------------------------------------------------------------------
void wallet2::generate_chacha_key_from_password(const epee::wipeable_string &pass, crypto::chacha_key &key) const
{
crypto::generate_chacha_key(pass.data(), pass.size(), key, m_kdf_rounds);
}
//----------------------------------------------------------------------------------------------------
void wallet2::load(const std::string& wallet_, const epee::wipeable_string& password)
{
clear();
prepare_file_names(wallet_);
boost::system::error_code e;
bool exists = boost::filesystem::exists(m_keys_file, e);
THROW_WALLET_EXCEPTION_IF(e || !exists, error::file_not_found, m_keys_file);
lock_keys_file();
THROW_WALLET_EXCEPTION_IF(!is_keys_file_locked(), error::wallet_internal_error, "internal error: \"" + m_keys_file + "\" is opened by another wallet program");
// this temporary unlocking is necessary for Windows (otherwise the file couldn't be loaded).
unlock_keys_file();
if (!load_keys(m_keys_file, password))
{
THROW_WALLET_EXCEPTION_IF(true, error::file_read_error, m_keys_file);
}
LOG_PRINT_L0("Loaded wallet keys file, with public address: " << m_account.get_public_address_str(m_nettype));
lock_keys_file();
wallet_keys_unlocker unlocker(*this, m_ask_password == AskPasswordToDecrypt && !m_unattended && !m_watch_only, password);
//keys loaded ok!
//try to load wallet file. but even if we failed, it is not big problem
if(!boost::filesystem::exists(m_wallet_file, e) || e)
{
LOG_PRINT_L0("file not found: " << m_wallet_file << ", starting with empty blockchain");
m_account_public_address = m_account.get_keys().m_account_address;
}
else
{
wallet2::cache_file_data cache_file_data;
std::string buf;
bool r = epee::file_io_utils::load_file_to_string(m_wallet_file, buf, std::numeric_limits<size_t>::max());
THROW_WALLET_EXCEPTION_IF(!r, error::file_read_error, m_wallet_file);
// try to read it as an encrypted cache
try
{
LOG_PRINT_L1("Trying to decrypt cache data");
r = ::serialization::parse_binary(buf, cache_file_data);
THROW_WALLET_EXCEPTION_IF(!r, error::wallet_internal_error, "internal error: failed to deserialize \"" + m_wallet_file + '\"');
std::string cache_data;
cache_data.resize(cache_file_data.cache_data.size());
crypto::chacha20(cache_file_data.cache_data.data(), cache_file_data.cache_data.size(), m_cache_key, cache_file_data.iv, &cache_data[0]);
try {
std::stringstream iss;
iss << cache_data;
boost::archive::portable_binary_iarchive ar(iss);
ar >> *this;
}
catch(...)
{
// try with previous scheme: direct from keys
crypto::chacha_key key;
generate_chacha_key_from_secret_keys(key);
crypto::chacha20(cache_file_data.cache_data.data(), cache_file_data.cache_data.size(), key, cache_file_data.iv, &cache_data[0]);
try {
std::stringstream iss;
iss << cache_data;
boost::archive::portable_binary_iarchive ar(iss);
ar >> *this;
}
catch (...)
{
crypto::chacha8(cache_file_data.cache_data.data(), cache_file_data.cache_data.size(), key, cache_file_data.iv, &cache_data[0]);
try
{
std::stringstream iss;
iss << cache_data;
boost::archive::portable_binary_iarchive ar(iss);
ar >> *this;
}
catch (...)
{
LOG_PRINT_L0("Failed to open portable binary, trying unportable");
boost::filesystem::copy_file(m_wallet_file, m_wallet_file + ".unportable", boost::filesystem::copy_option::overwrite_if_exists);
std::stringstream iss;
iss.str("");
iss << cache_data;
boost::archive::binary_iarchive ar(iss);
ar >> *this;
}
}
}
}
catch (...)
{
LOG_PRINT_L1("Failed to load encrypted cache, trying unencrypted");
try {
std::stringstream iss;
iss << buf;
boost::archive::portable_binary_iarchive ar(iss);
ar >> *this;
}
catch (...)
{
LOG_PRINT_L0("Failed to open portable binary, trying unportable");
boost::filesystem::copy_file(m_wallet_file, m_wallet_file + ".unportable", boost::filesystem::copy_option::overwrite_if_exists);
std::stringstream iss;
iss.str("");
iss << buf;
boost::archive::binary_iarchive ar(iss);
ar >> *this;
}
}
THROW_WALLET_EXCEPTION_IF(
m_account_public_address.m_spend_public_key != m_account.get_keys().m_account_address.m_spend_public_key ||
m_account_public_address.m_view_public_key != m_account.get_keys().m_account_address.m_view_public_key,
error::wallet_files_doesnt_correspond, m_keys_file, m_wallet_file);
}
cryptonote::block genesis;
generate_genesis(genesis);
crypto::hash genesis_hash = get_block_hash(genesis);
if (m_blockchain.empty())
{
m_blockchain.push_back(genesis_hash);
m_last_block_reward = cryptonote::get_outs_money_amount(genesis.miner_tx);
}
else
{
check_genesis(genesis_hash);
}
trim_hashchain();
if (get_num_subaddress_accounts() == 0)
add_subaddress_account(tr("Primary account"));
try
{
find_and_save_rings(false);
}
catch (const std::exception &e)
{
MERROR("Failed to save rings, will try again next time");
}
}
//----------------------------------------------------------------------------------------------------
void wallet2::trim_hashchain()
{
uint64_t height = m_checkpoints.get_max_height();
for (const transfer_details &td: m_transfers)
if (td.m_block_height < height)
height = td.m_block_height;
if (!m_blockchain.empty() && m_blockchain.size() == m_blockchain.offset())
{
MINFO("Fixing empty hashchain");
cryptonote::COMMAND_RPC_GET_BLOCK_HEADER_BY_HEIGHT::request req = AUTO_VAL_INIT(req);
cryptonote::COMMAND_RPC_GET_BLOCK_HEADER_BY_HEIGHT::response res = AUTO_VAL_INIT(res);
m_daemon_rpc_mutex.lock();
req.height = m_blockchain.size() - 1;
bool r = net_utils::invoke_http_json_rpc("/json_rpc", "getblockheaderbyheight", req, res, m_http_client, rpc_timeout);
m_daemon_rpc_mutex.unlock();
if (r && res.status == CORE_RPC_STATUS_OK)
{
crypto::hash hash;
epee::string_tools::hex_to_pod(res.block_header.hash, hash);
m_blockchain.refill(hash);
}
else
{
MERROR("Failed to request block header from daemon, hash chain may be unable to sync till the wallet is loaded with a usable daemon");
}
}
if (height > 0 && m_blockchain.size() > height)
{
--height;
MDEBUG("trimming to " << height << ", offset " << m_blockchain.offset());
m_blockchain.trim(height);
}
}
//----------------------------------------------------------------------------------------------------
void wallet2::check_genesis(const crypto::hash& genesis_hash) const {
std::string what("Genesis block mismatch. You probably use wallet without testnet (or stagenet) flag with blockchain from test (or stage) network or vice versa");
THROW_WALLET_EXCEPTION_IF(genesis_hash != m_blockchain.genesis(), error::wallet_internal_error, what);
}
//----------------------------------------------------------------------------------------------------
std::string wallet2::path() const
{
return m_wallet_file;
}
//----------------------------------------------------------------------------------------------------
void wallet2::store()
{
store_to("", epee::wipeable_string());
}
//----------------------------------------------------------------------------------------------------
void wallet2::store_to(const std::string &path, const epee::wipeable_string &password)
{
trim_hashchain();
// if file is the same, we do:
// 1. save wallet to the *.new file
// 2. remove old wallet file
// 3. rename *.new to wallet_name
// handle if we want just store wallet state to current files (ex store() replacement);
bool same_file = true;
if (!path.empty())
{
std::string canonical_path = boost::filesystem::canonical(m_wallet_file).string();
size_t pos = canonical_path.find(path);
same_file = pos != std::string::npos;
}
if (!same_file)
{
// check if we want to store to directory which doesn't exists yet
boost::filesystem::path parent_path = boost::filesystem::path(path).parent_path();
// if path is not exists, try to create it
if (!parent_path.empty() && !boost::filesystem::exists(parent_path))
{
boost::system::error_code ec;
if (!boost::filesystem::create_directories(parent_path, ec))
{
throw std::logic_error(ec.message());
}
}
}
// preparing wallet data
std::stringstream oss;
boost::archive::portable_binary_oarchive ar(oss);
ar << *this;
wallet2::cache_file_data cache_file_data = boost::value_initialized<wallet2::cache_file_data>();
cache_file_data.cache_data = oss.str();
std::string cipher;
cipher.resize(cache_file_data.cache_data.size());
cache_file_data.iv = crypto::rand<crypto::chacha_iv>();
crypto::chacha20(cache_file_data.cache_data.data(), cache_file_data.cache_data.size(), m_cache_key, cache_file_data.iv, &cipher[0]);
cache_file_data.cache_data = cipher;
const std::string new_file = same_file ? m_wallet_file + ".new" : path;
const std::string old_file = m_wallet_file;
const std::string old_keys_file = m_keys_file;
const std::string old_address_file = m_wallet_file + ".address.txt";
// save keys to the new file
// if we here, main wallet file is saved and we only need to save keys and address files
if (!same_file) {
prepare_file_names(path);
bool r = store_keys(m_keys_file, password, false);
THROW_WALLET_EXCEPTION_IF(!r, error::file_save_error, m_keys_file);
if (boost::filesystem::exists(old_address_file))
{
// save address to the new file
const std::string address_file = m_wallet_file + ".address.txt";
r = file_io_utils::save_string_to_file(address_file, m_account.get_public_address_str(m_nettype));
THROW_WALLET_EXCEPTION_IF(!r, error::file_save_error, m_wallet_file);
}
// remove old wallet file
r = boost::filesystem::remove(old_file);
if (!r) {
LOG_ERROR("error removing file: " << old_file);
}
// remove old keys file
r = boost::filesystem::remove(old_keys_file);
if (!r) {
LOG_ERROR("error removing file: " << old_keys_file);
}
// remove old address file
r = boost::filesystem::remove(old_address_file);
if (!r) {
LOG_ERROR("error removing file: " << old_address_file);
}
} else {
// save to new file
#ifdef WIN32
// On Windows avoid using std::ofstream which does not work with UTF-8 filenames
// The price to pay is temporary higher memory consumption for string stream + binary archive
std::ostringstream oss;
binary_archive<true> oar(oss);
bool success = ::serialization::serialize(oar, cache_file_data);
if (success) {
success = epee::file_io_utils::save_string_to_file(new_file, oss.str());
}
THROW_WALLET_EXCEPTION_IF(!success, error::file_save_error, new_file);
#else
std::ofstream ostr;
ostr.open(new_file, std::ios_base::binary | std::ios_base::out | std::ios_base::trunc);
binary_archive<true> oar(ostr);
bool success = ::serialization::serialize(oar, cache_file_data);
ostr.close();
THROW_WALLET_EXCEPTION_IF(!success || !ostr.good(), error::file_save_error, new_file);
#endif
// here we have "*.new" file, we need to rename it to be without ".new"
std::error_code e = tools::replace_file(new_file, m_wallet_file);
THROW_WALLET_EXCEPTION_IF(e, error::file_save_error, m_wallet_file, e);
}
}
//----------------------------------------------------------------------------------------------------
uint64_t wallet2::balance(uint32_t index_major) const
{
uint64_t amount = 0;
if(m_light_wallet)
return m_light_wallet_unlocked_balance;
for (const auto& i : balance_per_subaddress(index_major))
amount += i.second;
return amount;
}
//----------------------------------------------------------------------------------------------------
uint64_t wallet2::unlocked_balance(uint32_t index_major) const
{
uint64_t amount = 0;
if(m_light_wallet)
return m_light_wallet_balance;
for (const auto& i : unlocked_balance_per_subaddress(index_major))
amount += i.second;
return amount;
}
//----------------------------------------------------------------------------------------------------
std::map<uint32_t, uint64_t> wallet2::balance_per_subaddress(uint32_t index_major) const
{
std::map<uint32_t, uint64_t> amount_per_subaddr;
for (const auto& td: m_transfers)
{
if (td.m_subaddr_index.major == index_major && !td.m_spent)
{
auto found = amount_per_subaddr.find(td.m_subaddr_index.minor);
if (found == amount_per_subaddr.end())
amount_per_subaddr[td.m_subaddr_index.minor] = td.amount();
else
found->second += td.amount();
}
}
for (const auto& utx: m_unconfirmed_txs)
{
if (utx.second.m_subaddr_account == index_major && utx.second.m_state != wallet2::unconfirmed_transfer_details::failed)
{
// all changes go to 0-th subaddress (in the current subaddress account)
auto found = amount_per_subaddr.find(0);
if (found == amount_per_subaddr.end())
amount_per_subaddr[0] = utx.second.m_change;
else
found->second += utx.second.m_change;
}
}
return amount_per_subaddr;
}
//----------------------------------------------------------------------------------------------------
std::map<uint32_t, uint64_t> wallet2::unlocked_balance_per_subaddress(uint32_t index_major) const
{
std::map<uint32_t, uint64_t> amount_per_subaddr;
for(const transfer_details& td: m_transfers)
{
if(td.m_subaddr_index.major == index_major && !td.m_spent && is_transfer_unlocked(td))
{
auto found = amount_per_subaddr.find(td.m_subaddr_index.minor);
if (found == amount_per_subaddr.end())
amount_per_subaddr[td.m_subaddr_index.minor] = td.amount();
else
found->second += td.amount();
}
}
return amount_per_subaddr;
}
//----------------------------------------------------------------------------------------------------
uint64_t wallet2::balance_all() const
{
uint64_t r = 0;
for (uint32_t index_major = 0; index_major < get_num_subaddress_accounts(); ++index_major)
r += balance(index_major);
return r;
}
//----------------------------------------------------------------------------------------------------
uint64_t wallet2::unlocked_balance_all() const
{
uint64_t r = 0;
for (uint32_t index_major = 0; index_major < get_num_subaddress_accounts(); ++index_major)
r += unlocked_balance(index_major);
return r;
}
//----------------------------------------------------------------------------------------------------
void wallet2::get_transfers(wallet2::transfer_container& incoming_transfers) const
{
incoming_transfers = m_transfers;
}
//----------------------------------------------------------------------------------------------------
void wallet2::get_payments(const crypto::hash& payment_id, std::list<wallet2::payment_details>& payments, uint64_t min_height, const boost::optional<uint32_t>& subaddr_account, const std::set<uint32_t>& subaddr_indices) const
{
auto range = m_payments.equal_range(payment_id);
std::for_each(range.first, range.second, [&payments, &min_height, &subaddr_account, &subaddr_indices](const payment_container::value_type& x) {
if (min_height < x.second.m_block_height &&
(!subaddr_account || *subaddr_account == x.second.m_subaddr_index.major) &&
(subaddr_indices.empty() || subaddr_indices.count(x.second.m_subaddr_index.minor) == 1))
{
payments.push_back(x.second);
}
});
}
//----------------------------------------------------------------------------------------------------
void wallet2::get_payments(std::list<std::pair<crypto::hash,wallet2::payment_details>>& payments, uint64_t min_height, uint64_t max_height, const boost::optional<uint32_t>& subaddr_account, const std::set<uint32_t>& subaddr_indices) const
{
auto range = std::make_pair(m_payments.begin(), m_payments.end());
std::for_each(range.first, range.second, [&payments, &min_height, &max_height, &subaddr_account, &subaddr_indices](const payment_container::value_type& x) {
if (min_height < x.second.m_block_height && max_height >= x.second.m_block_height &&
(!subaddr_account || *subaddr_account == x.second.m_subaddr_index.major) &&
(subaddr_indices.empty() || subaddr_indices.count(x.second.m_subaddr_index.minor) == 1))
{
payments.push_back(x);
}
});
}
//----------------------------------------------------------------------------------------------------
void wallet2::get_payments_out(std::list<std::pair<crypto::hash,wallet2::confirmed_transfer_details>>& confirmed_payments,
uint64_t min_height, uint64_t max_height, const boost::optional<uint32_t>& subaddr_account, const std::set<uint32_t>& subaddr_indices) const
{
for (auto i = m_confirmed_txs.begin(); i != m_confirmed_txs.end(); ++i) {
if (i->second.m_block_height <= min_height || i->second.m_block_height > max_height)
continue;
if (subaddr_account && *subaddr_account != i->second.m_subaddr_account)
continue;
if (!subaddr_indices.empty() && std::count_if(i->second.m_subaddr_indices.begin(), i->second.m_subaddr_indices.end(), [&subaddr_indices](uint32_t index) { return subaddr_indices.count(index) == 1; }) == 0)
continue;
confirmed_payments.push_back(*i);
}
}
//----------------------------------------------------------------------------------------------------
void wallet2::get_unconfirmed_payments_out(std::list<std::pair<crypto::hash,wallet2::unconfirmed_transfer_details>>& unconfirmed_payments, const boost::optional<uint32_t>& subaddr_account, const std::set<uint32_t>& subaddr_indices) const
{
for (auto i = m_unconfirmed_txs.begin(); i != m_unconfirmed_txs.end(); ++i) {
if (subaddr_account && *subaddr_account != i->second.m_subaddr_account)
continue;
if (!subaddr_indices.empty() && std::count_if(i->second.m_subaddr_indices.begin(), i->second.m_subaddr_indices.end(), [&subaddr_indices](uint32_t index) { return subaddr_indices.count(index) == 1; }) == 0)
continue;
unconfirmed_payments.push_back(*i);
}
}
//----------------------------------------------------------------------------------------------------
void wallet2::get_unconfirmed_payments(std::list<std::pair<crypto::hash,wallet2::pool_payment_details>>& unconfirmed_payments, const boost::optional<uint32_t>& subaddr_account, const std::set<uint32_t>& subaddr_indices) const
{
for (auto i = m_unconfirmed_payments.begin(); i != m_unconfirmed_payments.end(); ++i) {
if ((!subaddr_account || *subaddr_account == i->second.m_pd.m_subaddr_index.major) &&
(subaddr_indices.empty() || subaddr_indices.count(i->second.m_pd.m_subaddr_index.minor) == 1))
unconfirmed_payments.push_back(*i);
}
}
//----------------------------------------------------------------------------------------------------
void wallet2::rescan_spent()
{
// This is RPC call that can take a long time if there are many outputs,
// so we call it several times, in stripes, so we don't time out spuriously
std::vector<int> spent_status;
spent_status.reserve(m_transfers.size());
const size_t chunk_size = 1000;
for (size_t start_offset = 0; start_offset < m_transfers.size(); start_offset += chunk_size)
{
const size_t n_outputs = std::min<size_t>(chunk_size, m_transfers.size() - start_offset);
MDEBUG("Calling is_key_image_spent on " << start_offset << " - " << (start_offset + n_outputs - 1) << ", out of " << m_transfers.size());
COMMAND_RPC_IS_KEY_IMAGE_SPENT::request req = AUTO_VAL_INIT(req);
COMMAND_RPC_IS_KEY_IMAGE_SPENT::response daemon_resp = AUTO_VAL_INIT(daemon_resp);
for (size_t n = start_offset; n < start_offset + n_outputs; ++n)
req.key_images.push_back(string_tools::pod_to_hex(m_transfers[n].m_key_image));
m_daemon_rpc_mutex.lock();
bool r = epee::net_utils::invoke_http_json("/is_key_image_spent", req, daemon_resp, m_http_client, rpc_timeout);
m_daemon_rpc_mutex.unlock();
THROW_WALLET_EXCEPTION_IF(!r, error::no_connection_to_daemon, "is_key_image_spent");
THROW_WALLET_EXCEPTION_IF(daemon_resp.status == CORE_RPC_STATUS_BUSY, error::daemon_busy, "is_key_image_spent");
THROW_WALLET_EXCEPTION_IF(daemon_resp.status != CORE_RPC_STATUS_OK, error::is_key_image_spent_error, daemon_resp.status);
THROW_WALLET_EXCEPTION_IF(daemon_resp.spent_status.size() != n_outputs, error::wallet_internal_error,
"daemon returned wrong response for is_key_image_spent, wrong amounts count = " +
std::to_string(daemon_resp.spent_status.size()) + ", expected " + std::to_string(n_outputs));
std::copy(daemon_resp.spent_status.begin(), daemon_resp.spent_status.end(), std::back_inserter(spent_status));
}
// update spent status
for (size_t i = 0; i < m_transfers.size(); ++i)
{
transfer_details& td = m_transfers[i];
// a view wallet may not know about key images
if (!td.m_key_image_known || td.m_key_image_partial)
continue;
if (td.m_spent != (spent_status[i] != COMMAND_RPC_IS_KEY_IMAGE_SPENT::UNSPENT))
{
if (td.m_spent)
{
LOG_PRINT_L0("Marking output " << i << "(" << td.m_key_image << ") as unspent, it was marked as spent");
set_unspent(i);
td.m_spent_height = 0;
}
else
{
LOG_PRINT_L0("Marking output " << i << "(" << td.m_key_image << ") as spent, it was marked as unspent");
set_spent(i, td.m_spent_height);
// unknown height, if this gets reorged, it might still be missed
}
}
}
}
//----------------------------------------------------------------------------------------------------
void wallet2::rescan_blockchain(bool hard, bool refresh)
{
if(hard)
{
clear();
setup_new_blockchain();
}
else
{
m_blockchain.clear();
m_transfers.clear();
m_key_images.clear();
m_pub_keys.clear();
m_scanned_pool_txs[0].clear();
m_scanned_pool_txs[1].clear();
cryptonote::block b;
generate_genesis(b);
m_blockchain.push_back(get_block_hash(b));
m_last_block_reward = cryptonote::get_outs_money_amount(b.miner_tx);
}
if (refresh)
this->refresh(false);
}
//----------------------------------------------------------------------------------------------------
bool wallet2::is_transfer_unlocked(const transfer_details& td) const
{
return is_transfer_unlocked(td.m_tx.unlock_time, td.m_block_height);
}
//----------------------------------------------------------------------------------------------------
bool wallet2::is_transfer_unlocked(uint64_t unlock_time, uint64_t block_height) const
{
if(!is_tx_spendtime_unlocked(unlock_time, block_height))
return false;
if(block_height + CRYPTONOTE_DEFAULT_TX_SPENDABLE_AGE > get_blockchain_current_height())
return false;
return true;
}
//----------------------------------------------------------------------------------------------------
bool wallet2::is_tx_spendtime_unlocked(uint64_t unlock_time, uint64_t block_height) const
{
if(unlock_time < CRYPTONOTE_MAX_BLOCK_NUMBER)
{
//interpret as block index
if(get_blockchain_current_height()-1 + CRYPTONOTE_LOCKED_TX_ALLOWED_DELTA_BLOCKS >= unlock_time)
return true;
else
return false;
}else
{
//interpret as time
uint64_t current_time = static_cast<uint64_t>(time(NULL));
// XXX: this needs to be fast, so we'd need to get the starting heights
// from the daemon to be correct once voting kicks in
uint64_t v2height = m_nettype == TESTNET ? 624634 : m_nettype == STAGENET ? 32000 : 1009827;
uint64_t leeway = block_height < v2height ? CRYPTONOTE_LOCKED_TX_ALLOWED_DELTA_SECONDS_V1 : CRYPTONOTE_LOCKED_TX_ALLOWED_DELTA_SECONDS_V2;
if(current_time + leeway >= unlock_time)
return true;
else
return false;
}
return false;
}
//----------------------------------------------------------------------------------------------------
namespace
{
template<typename T>
T pop_index(std::vector<T>& vec, size_t idx)
{
CHECK_AND_ASSERT_MES(!vec.empty(), T(), "Vector must be non-empty");
CHECK_AND_ASSERT_MES(idx < vec.size(), T(), "idx out of bounds");
T res = vec[idx];
if (idx + 1 != vec.size())
{
vec[idx] = vec.back();
}
vec.resize(vec.size() - 1);
return res;
}
template<typename T>
T pop_random_value(std::vector<T>& vec)
{
CHECK_AND_ASSERT_MES(!vec.empty(), T(), "Vector must be non-empty");
size_t idx = crypto::rand<size_t>() % vec.size();
return pop_index (vec, idx);
}
template<typename T>
T pop_back(std::vector<T>& vec)
{
CHECK_AND_ASSERT_MES(!vec.empty(), T(), "Vector must be non-empty");
T res = vec.back();
vec.pop_back();
return res;
}
template<typename T>
void pop_if_present(std::vector<T>& vec, T e)
{
for (size_t i = 0; i < vec.size(); ++i)
{
if (e == vec[i])
{
pop_index (vec, i);
return;
}
}
}
}
//----------------------------------------------------------------------------------------------------
// This returns a handwavy estimation of how much two outputs are related
// If they're from the same tx, then they're fully related. From close block
// heights, they're kinda related. The actual values don't matter, just
// their ordering, but it could become more murky if we add scores later.
float wallet2::get_output_relatedness(const transfer_details &td0, const transfer_details &td1) const
{
int dh;
// expensive test, and same tx will fall onto the same block height below
if (td0.m_txid == td1.m_txid)
return 1.0f;
// same block height -> possibly tx burst, or same tx (since above is disabled)
dh = td0.m_block_height > td1.m_block_height ? td0.m_block_height - td1.m_block_height : td1.m_block_height - td0.m_block_height;
if (dh == 0)
return 0.9f;
// adjacent blocks -> possibly tx burst
if (dh == 1)
return 0.8f;
// could extract the payment id, and compare them, but this is a bit expensive too
// similar block heights
if (dh < 10)
return 0.2f;
// don't think these are particularly related
return 0.0f;
}
//----------------------------------------------------------------------------------------------------
size_t wallet2::pop_best_value_from(const transfer_container &transfers, std::vector<size_t> &unused_indices, const std::vector<size_t>& selected_transfers, bool smallest) const
{
std::vector<size_t> candidates;
float best_relatedness = 1.0f;
for (size_t n = 0; n < unused_indices.size(); ++n)
{
const transfer_details &candidate = transfers[unused_indices[n]];
float relatedness = 0.0f;
for (std::vector<size_t>::const_iterator i = selected_transfers.begin(); i != selected_transfers.end(); ++i)
{
float r = get_output_relatedness(candidate, transfers[*i]);
if (r > relatedness)
{
relatedness = r;
if (relatedness == 1.0f)
break;
}
}
if (relatedness < best_relatedness)
{
best_relatedness = relatedness;
candidates.clear();
}
if (relatedness == best_relatedness)
candidates.push_back(n);
}
// we have all the least related outputs in candidates, so we can pick either
// the smallest, or a random one, depending on request
size_t idx;
if (smallest)
{
idx = 0;
for (size_t n = 0; n < candidates.size(); ++n)
{
const transfer_details &td = transfers[unused_indices[candidates[n]]];
if (td.amount() < transfers[unused_indices[candidates[idx]]].amount())
idx = n;
}
}
else
{
idx = crypto::rand<size_t>() % candidates.size();
}
return pop_index (unused_indices, candidates[idx]);
}
//----------------------------------------------------------------------------------------------------
size_t wallet2::pop_best_value(std::vector<size_t> &unused_indices, const std::vector<size_t>& selected_transfers, bool smallest) const
{
return pop_best_value_from(m_transfers, unused_indices, selected_transfers, smallest);
}
//----------------------------------------------------------------------------------------------------
// Select random input sources for transaction.
// returns:
// direct return: amount of money found
// modified reference: selected_transfers, a list of iterators/indices of input sources
uint64_t wallet2::select_transfers(uint64_t needed_money, std::vector<size_t> unused_transfers_indices, std::vector<size_t>& selected_transfers) const
{
uint64_t found_money = 0;
selected_transfers.reserve(unused_transfers_indices.size());
while (found_money < needed_money && !unused_transfers_indices.empty())
{
size_t idx = pop_best_value(unused_transfers_indices, selected_transfers);
const transfer_container::const_iterator it = m_transfers.begin() + idx;
selected_transfers.push_back(idx);
found_money += it->amount();
}
return found_money;
}
//----------------------------------------------------------------------------------------------------
void wallet2::add_unconfirmed_tx(const cryptonote::transaction& tx, uint64_t amount_in, const std::vector<cryptonote::tx_destination_entry> &dests, const crypto::hash &payment_id, uint64_t change_amount, uint32_t subaddr_account, const std::set<uint32_t>& subaddr_indices)
{
unconfirmed_transfer_details& utd = m_unconfirmed_txs[cryptonote::get_transaction_hash(tx)];
utd.m_amount_in = amount_in;
utd.m_amount_out = 0;
for (const auto &d: dests)
utd.m_amount_out += d.amount;
utd.m_amount_out += change_amount; // dests does not contain change
utd.m_change = change_amount;
utd.m_sent_time = time(NULL);
utd.m_tx = (const cryptonote::transaction_prefix&)tx;
utd.m_dests = dests;
utd.m_payment_id = payment_id;
utd.m_state = wallet2::unconfirmed_transfer_details::pending;
utd.m_timestamp = time(NULL);
utd.m_subaddr_account = subaddr_account;
utd.m_subaddr_indices = subaddr_indices;
for (const auto &in: tx.vin)
{
if (in.type() != typeid(cryptonote::txin_to_key))
continue;
const auto &txin = boost::get<cryptonote::txin_to_key>(in);
utd.m_rings.push_back(std::make_pair(txin.k_image, txin.key_offsets));
}
}
//----------------------------------------------------------------------------------------------------
crypto::hash wallet2::get_payment_id(const pending_tx &ptx) const
{
std::vector<tx_extra_field> tx_extra_fields;
parse_tx_extra(ptx.tx.extra, tx_extra_fields); // ok if partially parsed
tx_extra_nonce extra_nonce;
crypto::hash payment_id = null_hash;
if (find_tx_extra_field_by_type(tx_extra_fields, extra_nonce))
{
crypto::hash8 payment_id8 = null_hash8;
if(get_encrypted_payment_id_from_tx_extra_nonce(extra_nonce.nonce, payment_id8))
{
if (ptx.dests.empty())
{
MWARNING("Encrypted payment id found, but no destinations public key, cannot decrypt");
return crypto::null_hash;
}
if (m_account.get_device().decrypt_payment_id(payment_id8, ptx.dests[0].addr.m_view_public_key, ptx.tx_key))
{
memcpy(payment_id.data, payment_id8.data, 8);
}
}
else if (!get_payment_id_from_tx_extra_nonce(extra_nonce.nonce, payment_id))
{
payment_id = crypto::null_hash;
}
}
return payment_id;
}
//----------------------------------------------------------------------------------------------------
// take a pending tx and actually send it to the daemon
void wallet2::commit_tx(pending_tx& ptx)
{
using namespace cryptonote;
if(m_light_wallet)
{
cryptonote::COMMAND_RPC_SUBMIT_RAW_TX::request oreq;
cryptonote::COMMAND_RPC_SUBMIT_RAW_TX::response ores;
oreq.address = get_account().get_public_address_str(m_nettype);
oreq.view_key = string_tools::pod_to_hex(get_account().get_keys().m_view_secret_key);
oreq.tx = epee::string_tools::buff_to_hex_nodelimer(tx_to_blob(ptx.tx));
m_daemon_rpc_mutex.lock();
bool r = epee::net_utils::invoke_http_json("/submit_raw_tx", oreq, ores, m_http_client, rpc_timeout, "POST");
m_daemon_rpc_mutex.unlock();
THROW_WALLET_EXCEPTION_IF(!r, error::no_connection_to_daemon, "submit_raw_tx");
// MyMonero and OpenMonero use different status strings
THROW_WALLET_EXCEPTION_IF(ores.status != "OK" && ores.status != "success" , error::tx_rejected, ptx.tx, ores.status, ores.error);
}
else
{
// Normal submit
COMMAND_RPC_SEND_RAW_TX::request req;
req.tx_as_hex = epee::string_tools::buff_to_hex_nodelimer(tx_to_blob(ptx.tx));
req.do_not_relay = false;
COMMAND_RPC_SEND_RAW_TX::response daemon_send_resp;
m_daemon_rpc_mutex.lock();
bool r = epee::net_utils::invoke_http_json("/sendrawtransaction", req, daemon_send_resp, m_http_client, rpc_timeout);
m_daemon_rpc_mutex.unlock();
THROW_WALLET_EXCEPTION_IF(!r, error::no_connection_to_daemon, "sendrawtransaction");
THROW_WALLET_EXCEPTION_IF(daemon_send_resp.status == CORE_RPC_STATUS_BUSY, error::daemon_busy, "sendrawtransaction");
THROW_WALLET_EXCEPTION_IF(daemon_send_resp.status != CORE_RPC_STATUS_OK, error::tx_rejected, ptx.tx, daemon_send_resp.status, daemon_send_resp.reason);
// sanity checks
for (size_t idx: ptx.selected_transfers)
{
THROW_WALLET_EXCEPTION_IF(idx >= m_transfers.size(), error::wallet_internal_error,
"Bad output index in selected transfers: " + boost::lexical_cast<std::string>(idx));
}
}
crypto::hash txid;
txid = get_transaction_hash(ptx.tx);
crypto::hash payment_id = crypto::null_hash;
std::vector<cryptonote::tx_destination_entry> dests;
uint64_t amount_in = 0;
if (store_tx_info())
{
payment_id = get_payment_id(ptx);
dests = ptx.dests;
for(size_t idx: ptx.selected_transfers)
amount_in += m_transfers[idx].amount();
}
add_unconfirmed_tx(ptx.tx, amount_in, dests, payment_id, ptx.change_dts.amount, ptx.construction_data.subaddr_account, ptx.construction_data.subaddr_indices);
if (store_tx_info())
{
m_tx_keys.insert(std::make_pair(txid, ptx.tx_key));
m_additional_tx_keys.insert(std::make_pair(txid, ptx.additional_tx_keys));
}
LOG_PRINT_L2("transaction " << txid << " generated ok and sent to daemon, key_images: [" << ptx.key_images << "]");
for(size_t idx: ptx.selected_transfers)
{
set_spent(idx, 0);
}
// tx generated, get rid of used k values
for (size_t idx: ptx.selected_transfers)
m_transfers[idx].m_multisig_k.clear();
//fee includes dust if dust policy specified it.
LOG_PRINT_L1("Transaction successfully sent. <" << txid << ">" << ENDL
<< "Commission: " << print_money(ptx.fee) << " (dust sent to dust addr: " << print_money((ptx.dust_added_to_fee ? 0 : ptx.dust)) << ")" << ENDL
<< "Balance: " << print_money(balance(ptx.construction_data.subaddr_account)) << ENDL
<< "Unlocked: " << print_money(unlocked_balance(ptx.construction_data.subaddr_account)) << ENDL
<< "Please, wait for confirmation for your balance to be unlocked.");
}
void wallet2::commit_tx(std::vector<pending_tx>& ptx_vector)
{
for (auto & ptx : ptx_vector)
{
commit_tx(ptx);
}
}
//----------------------------------------------------------------------------------------------------
bool wallet2::save_tx(const std::vector<pending_tx>& ptx_vector, const std::string &filename) const
{
LOG_PRINT_L0("saving " << ptx_vector.size() << " transactions");
std::string ciphertext = dump_tx_to_str(ptx_vector);
if (ciphertext.empty())
return false;
return epee::file_io_utils::save_string_to_file(filename, ciphertext);
}
//----------------------------------------------------------------------------------------------------
std::string wallet2::dump_tx_to_str(const std::vector<pending_tx> &ptx_vector) const
{
LOG_PRINT_L0("saving " << ptx_vector.size() << " transactions");
unsigned_tx_set txs;
for (auto &tx: ptx_vector)
{
// Short payment id is encrypted with tx_key.
// Since sign_tx() generates new tx_keys and encrypts the payment id, we need to save the decrypted payment ID
// Save tx construction_data to unsigned_tx_set
txs.txes.push_back(get_construction_data_with_decrypted_short_payment_id(tx, m_account.get_device()));
}
txs.transfers = export_outputs();
// save as binary
std::ostringstream oss;
boost::archive::portable_binary_oarchive ar(oss);
try
{
ar << txs;
}
catch (...)
{
return std::string();
}
LOG_PRINT_L2("Saving unsigned tx data: " << oss.str());
std::string ciphertext = encrypt_with_view_secret_key(oss.str());
return std::string(UNSIGNED_TX_PREFIX) + ciphertext;
}
//----------------------------------------------------------------------------------------------------
bool wallet2::load_unsigned_tx(const std::string &unsigned_filename, unsigned_tx_set &exported_txs) const
{
std::string s;
boost::system::error_code errcode;
if (!boost::filesystem::exists(unsigned_filename, errcode))
{
LOG_PRINT_L0("File " << unsigned_filename << " does not exist: " << errcode);
return false;
}
if (!epee::file_io_utils::load_file_to_string(unsigned_filename.c_str(), s))
{
LOG_PRINT_L0("Failed to load from " << unsigned_filename);
return false;
}
return parse_unsigned_tx_from_str(s, exported_txs);
}
//----------------------------------------------------------------------------------------------------
bool wallet2::parse_unsigned_tx_from_str(const std::string &unsigned_tx_st, unsigned_tx_set &exported_txs) const
{
std::string s = unsigned_tx_st;
const size_t magiclen = strlen(UNSIGNED_TX_PREFIX) - 1;
if (strncmp(s.c_str(), UNSIGNED_TX_PREFIX, magiclen))
{
LOG_PRINT_L0("Bad magic from unsigned tx");
return false;
}
s = s.substr(magiclen);
const char version = s[0];
s = s.substr(1);
if (version == '\003')
{
try
{
std::istringstream iss(s);
boost::archive::portable_binary_iarchive ar(iss);
ar >> exported_txs;
}
catch (...)
{
LOG_PRINT_L0("Failed to parse data from unsigned tx");
return false;
}
}
else if (version == '\004')
{
try
{
s = decrypt_with_view_secret_key(s);
try
{
std::istringstream iss(s);
boost::archive::portable_binary_iarchive ar(iss);
ar >> exported_txs;
}
catch (...)
{
LOG_PRINT_L0("Failed to parse data from unsigned tx");
return false;
}
}
catch (const std::exception &e)
{
LOG_PRINT_L0("Failed to decrypt unsigned tx: " << e.what());
return false;
}
}
else
{
LOG_PRINT_L0("Unsupported version in unsigned tx");
return false;
}
LOG_PRINT_L1("Loaded tx unsigned data from binary: " << exported_txs.txes.size() << " transactions");
return true;
}
//----------------------------------------------------------------------------------------------------
bool wallet2::sign_tx(const std::string &unsigned_filename, const std::string &signed_filename, std::vector<wallet2::pending_tx> &txs, std::function<bool(const unsigned_tx_set&)> accept_func, bool export_raw)
{
unsigned_tx_set exported_txs;
if(!load_unsigned_tx(unsigned_filename, exported_txs))
return false;
if (accept_func && !accept_func(exported_txs))
{
LOG_PRINT_L1("Transactions rejected by callback");
return false;
}
return sign_tx(exported_txs, signed_filename, txs, export_raw);
}
//----------------------------------------------------------------------------------------------------
bool wallet2::sign_tx(unsigned_tx_set &exported_txs, std::vector<wallet2::pending_tx> &txs, signed_tx_set &signed_txes)
{
import_outputs(exported_txs.transfers);
// sign the transactions
for (size_t n = 0; n < exported_txs.txes.size(); ++n)
{
tools::wallet2::tx_construction_data &sd = exported_txs.txes[n];
THROW_WALLET_EXCEPTION_IF(sd.sources.empty(), error::wallet_internal_error, "Empty sources");
LOG_PRINT_L1(" " << (n+1) << ": " << sd.sources.size() << " inputs, ring size " << sd.sources[0].outputs.size());
signed_txes.ptx.push_back(pending_tx());
tools::wallet2::pending_tx &ptx = signed_txes.ptx.back();
rct::RangeProofType range_proof_type = rct::RangeProofBorromean;
if (sd.use_bulletproofs)
{
range_proof_type = rct::RangeProofPaddedBulletproof;
}
crypto::secret_key tx_key;
std::vector<crypto::secret_key> additional_tx_keys;
rct::multisig_out msout;
bool r = cryptonote::construct_tx_and_get_tx_key(m_account.get_keys(), m_subaddresses, sd.sources, sd.splitted_dsts, sd.change_dts.addr, sd.extra, ptx.tx, sd.unlock_time, tx_key, additional_tx_keys, sd.use_rct, range_proof_type, m_multisig ? &msout : NULL);
THROW_WALLET_EXCEPTION_IF(!r, error::tx_not_constructed, sd.sources, sd.splitted_dsts, sd.unlock_time, m_nettype);
// we don't test tx size, because we don't know the current limit, due to not having a blockchain,
// and it's a bit pointless to fail there anyway, since it'd be a (good) guess only. We sign anyway,
// and if we really go over limit, the daemon will reject when it gets submitted. Chances are it's
// OK anyway since it was generated in the first place, and rerolling should be within a few bytes.
// normally, the tx keys are saved in commit_tx, when the tx is actually sent to the daemon.
// we can't do that here since the tx will be sent from the compromised wallet, which we don't want
// to see that info, so we save it here
if (store_tx_info())
{
const crypto::hash txid = get_transaction_hash(ptx.tx);
m_tx_keys.insert(std::make_pair(txid, tx_key));
m_additional_tx_keys.insert(std::make_pair(txid, additional_tx_keys));
}
std::string key_images;
bool all_are_txin_to_key = std::all_of(ptx.tx.vin.begin(), ptx.tx.vin.end(), [&](const txin_v& s_e) -> bool
{
CHECKED_GET_SPECIFIC_VARIANT(s_e, const txin_to_key, in, false);
key_images += boost::to_string(in.k_image) + " ";
return true;
});
THROW_WALLET_EXCEPTION_IF(!all_are_txin_to_key, error::unexpected_txin_type, ptx.tx);
ptx.key_images = key_images;
ptx.fee = 0;
for (const auto &i: sd.sources) ptx.fee += i.amount;
for (const auto &i: sd.splitted_dsts) ptx.fee -= i.amount;
ptx.dust = 0;
ptx.dust_added_to_fee = false;
ptx.change_dts = sd.change_dts;
ptx.selected_transfers = sd.selected_transfers;
ptx.tx_key = rct::rct2sk(rct::identity()); // don't send it back to the untrusted view wallet
ptx.dests = sd.dests;
ptx.construction_data = sd;
txs.push_back(ptx);
// add tx keys only to ptx
txs.back().tx_key = tx_key;
txs.back().additional_tx_keys = additional_tx_keys;
}
// add key images
signed_txes.key_images.resize(m_transfers.size());
for (size_t i = 0; i < m_transfers.size(); ++i)
{
if (!m_transfers[i].m_key_image_known || m_transfers[i].m_key_image_partial)
LOG_PRINT_L0("WARNING: key image not known in signing wallet at index " << i);
signed_txes.key_images[i] = m_transfers[i].m_key_image;
}
return true;
}
//----------------------------------------------------------------------------------------------------
bool wallet2::sign_tx(unsigned_tx_set &exported_txs, const std::string &signed_filename, std::vector<wallet2::pending_tx> &txs, bool export_raw)
{
// sign the transactions
signed_tx_set signed_txes;
std::string ciphertext = sign_tx_dump_to_str(exported_txs, txs, signed_txes);
if (ciphertext.empty())
{
LOG_PRINT_L0("Failed to sign unsigned_tx_set");
return false;
}
if (!epee::file_io_utils::save_string_to_file(signed_filename, ciphertext))
{
LOG_PRINT_L0("Failed to save file to " << signed_filename);
return false;
}
// export signed raw tx without encryption
if (export_raw)
{
for (size_t i = 0; i < signed_txes.ptx.size(); ++i)
{
std::string tx_as_hex = epee::string_tools::buff_to_hex_nodelimer(tx_to_blob(signed_txes.ptx[i].tx));
std::string raw_filename = signed_filename + "_raw" + (signed_txes.ptx.size() == 1 ? "" : ("_" + std::to_string(i)));
if (!epee::file_io_utils::save_string_to_file(raw_filename, tx_as_hex))
{
LOG_PRINT_L0("Failed to save file to " << raw_filename);
return false;
}
}
}
return true;
}
//----------------------------------------------------------------------------------------------------
std::string wallet2::sign_tx_dump_to_str(unsigned_tx_set &exported_txs, std::vector<wallet2::pending_tx> &ptx, signed_tx_set &signed_txes)
{
// sign the transactions
bool r = sign_tx(exported_txs, ptx, signed_txes);
if (!r)
{
LOG_PRINT_L0("Failed to sign unsigned_tx_set");
return std::string();
}
// save as binary
std::ostringstream oss;
boost::archive::portable_binary_oarchive ar(oss);
try
{
ar << signed_txes;
}
catch(...)
{
return std::string();
}
LOG_PRINT_L3("Saving signed tx data (with encryption): " << oss.str());
std::string ciphertext = encrypt_with_view_secret_key(oss.str());
return std::string(SIGNED_TX_PREFIX) + ciphertext;
}
//----------------------------------------------------------------------------------------------------
bool wallet2::load_tx(const std::string &signed_filename, std::vector<tools::wallet2::pending_tx> &ptx, std::function<bool(const signed_tx_set&)> accept_func)
{
std::string s;
boost::system::error_code errcode;
signed_tx_set signed_txs;
if (!boost::filesystem::exists(signed_filename, errcode))
{
LOG_PRINT_L0("File " << signed_filename << " does not exist: " << errcode);
return false;
}
if (!epee::file_io_utils::load_file_to_string(signed_filename.c_str(), s))
{
LOG_PRINT_L0("Failed to load from " << signed_filename);
return false;
}
return parse_tx_from_str(s, ptx, accept_func);
}
//----------------------------------------------------------------------------------------------------
bool wallet2::parse_tx_from_str(const std::string &signed_tx_st, std::vector<tools::wallet2::pending_tx> &ptx, std::function<bool(const signed_tx_set &)> accept_func)
{
std::string s = signed_tx_st;
boost::system::error_code errcode;
signed_tx_set signed_txs;
const size_t magiclen = strlen(SIGNED_TX_PREFIX) - 1;
if (strncmp(s.c_str(), SIGNED_TX_PREFIX, magiclen))
{
LOG_PRINT_L0("Bad magic from signed transaction");
return false;
}
s = s.substr(magiclen);
const char version = s[0];
s = s.substr(1);
if (version == '\003')
{
try
{
std::istringstream iss(s);
boost::archive::portable_binary_iarchive ar(iss);
ar >> signed_txs;
}
catch (...)
{
LOG_PRINT_L0("Failed to parse data from signed transaction");
return false;
}
}
else if (version == '\004')
{
try
{
s = decrypt_with_view_secret_key(s);
try
{
std::istringstream iss(s);
boost::archive::portable_binary_iarchive ar(iss);
ar >> signed_txs;
}
catch (...)
{
LOG_PRINT_L0("Failed to parse decrypted data from signed transaction");
return false;
}
}
catch (const std::exception &e)
{
LOG_PRINT_L0("Failed to decrypt signed transaction: " << e.what());
return false;
}
}
else
{
LOG_PRINT_L0("Unsupported version in signed transaction");
return false;
}
LOG_PRINT_L0("Loaded signed tx data from binary: " << signed_txs.ptx.size() << " transactions");
for (auto &c_ptx: signed_txs.ptx) LOG_PRINT_L0(cryptonote::obj_to_json_str(c_ptx.tx));
if (accept_func && !accept_func(signed_txs))
{
LOG_PRINT_L1("Transactions rejected by callback");
return false;
}
// import key images
bool r = import_key_images(signed_txs.key_images);
if (!r) return false;
ptx = signed_txs.ptx;
return true;
}
//----------------------------------------------------------------------------------------------------
std::string wallet2::save_multisig_tx(multisig_tx_set txs)
{
LOG_PRINT_L0("saving " << txs.m_ptx.size() << " multisig transactions");
// txes generated, get rid of used k values
for (size_t n = 0; n < txs.m_ptx.size(); ++n)
for (size_t idx: txs.m_ptx[n].construction_data.selected_transfers)
m_transfers[idx].m_multisig_k.clear();
// zero out some data we don't want to share
for (auto &ptx: txs.m_ptx)
{
for (auto &e: ptx.construction_data.sources)
e.multisig_kLRki.k = rct::zero();
}
for (auto &ptx: txs.m_ptx)
{
// Get decrypted payment id from pending_tx
ptx.construction_data = get_construction_data_with_decrypted_short_payment_id(ptx, m_account.get_device());
}
// save as binary
std::ostringstream oss;
boost::archive::portable_binary_oarchive ar(oss);
try
{
ar << txs;
}
catch (...)
{
return std::string();
}
LOG_PRINT_L2("Saving multisig unsigned tx data: " << oss.str());
std::string ciphertext = encrypt_with_view_secret_key(oss.str());
return std::string(MULTISIG_UNSIGNED_TX_PREFIX) + ciphertext;
}
//----------------------------------------------------------------------------------------------------
bool wallet2::save_multisig_tx(const multisig_tx_set &txs, const std::string &filename)
{
std::string ciphertext = save_multisig_tx(txs);
if (ciphertext.empty())
return false;
return epee::file_io_utils::save_string_to_file(filename, ciphertext);
}
//----------------------------------------------------------------------------------------------------
wallet2::multisig_tx_set wallet2::make_multisig_tx_set(const std::vector<pending_tx>& ptx_vector) const
{
multisig_tx_set txs;
txs.m_ptx = ptx_vector;
for (const auto &msk: get_account().get_multisig_keys())
{
crypto::public_key pkey = get_multisig_signing_public_key(msk);
for (auto &ptx: txs.m_ptx) for (auto &sig: ptx.multisig_sigs) sig.signing_keys.insert(pkey);
}
txs.m_signers.insert(get_multisig_signer_public_key());
return txs;
}
std::string wallet2::save_multisig_tx(const std::vector<pending_tx>& ptx_vector)
{
return save_multisig_tx(make_multisig_tx_set(ptx_vector));
}
//----------------------------------------------------------------------------------------------------
bool wallet2::save_multisig_tx(const std::vector<pending_tx>& ptx_vector, const std::string &filename)
{
std::string ciphertext = save_multisig_tx(ptx_vector);
if (ciphertext.empty())
return false;
return epee::file_io_utils::save_string_to_file(filename, ciphertext);
}
//----------------------------------------------------------------------------------------------------
bool wallet2::load_multisig_tx(cryptonote::blobdata s, multisig_tx_set &exported_txs, std::function<bool(const multisig_tx_set&)> accept_func)
{
const size_t magiclen = strlen(MULTISIG_UNSIGNED_TX_PREFIX);
if (strncmp(s.c_str(), MULTISIG_UNSIGNED_TX_PREFIX, magiclen))
{
LOG_PRINT_L0("Bad magic from multisig tx data");
return false;
}
try
{
s = decrypt_with_view_secret_key(std::string(s, magiclen));
}
catch (const std::exception &e)
{
LOG_PRINT_L0("Failed to decrypt multisig tx data: " << e.what());
return false;
}
try
{
std::istringstream iss(s);
boost::archive::portable_binary_iarchive ar(iss);
ar >> exported_txs;
}
catch (...)
{
LOG_PRINT_L0("Failed to parse multisig tx data");
return false;
}
// sanity checks
for (const auto &ptx: exported_txs.m_ptx)
{
CHECK_AND_ASSERT_MES(ptx.selected_transfers.size() == ptx.tx.vin.size(), false, "Mismatched selected_transfers/vin sizes");
for (size_t idx: ptx.selected_transfers)
CHECK_AND_ASSERT_MES(idx < m_transfers.size(), false, "Transfer index out of range");
CHECK_AND_ASSERT_MES(ptx.construction_data.selected_transfers.size() == ptx.tx.vin.size(), false, "Mismatched cd selected_transfers/vin sizes");
for (size_t idx: ptx.construction_data.selected_transfers)
CHECK_AND_ASSERT_MES(idx < m_transfers.size(), false, "Transfer index out of range");
CHECK_AND_ASSERT_MES(ptx.construction_data.sources.size() == ptx.tx.vin.size(), false, "Mismatched sources/vin sizes");
}
LOG_PRINT_L1("Loaded multisig tx unsigned data from binary: " << exported_txs.m_ptx.size() << " transactions");
for (auto &ptx: exported_txs.m_ptx) LOG_PRINT_L0(cryptonote::obj_to_json_str(ptx.tx));
if (accept_func && !accept_func(exported_txs))
{
LOG_PRINT_L1("Transactions rejected by callback");
return false;
}
const bool is_signed = exported_txs.m_signers.size() >= m_multisig_threshold;
if (is_signed)
{
for (const auto &ptx: exported_txs.m_ptx)
{
const crypto::hash txid = get_transaction_hash(ptx.tx);
if (store_tx_info())
{
m_tx_keys.insert(std::make_pair(txid, ptx.tx_key));
m_additional_tx_keys.insert(std::make_pair(txid, ptx.additional_tx_keys));
}
}
}
return true;
}
//----------------------------------------------------------------------------------------------------
bool wallet2::load_multisig_tx_from_file(const std::string &filename, multisig_tx_set &exported_txs, std::function<bool(const multisig_tx_set&)> accept_func)
{
std::string s;
boost::system::error_code errcode;
if (!boost::filesystem::exists(filename, errcode))
{
LOG_PRINT_L0("File " << filename << " does not exist: " << errcode);
return false;
}
if (!epee::file_io_utils::load_file_to_string(filename.c_str(), s))
{
LOG_PRINT_L0("Failed to load from " << filename);
return false;
}
if (!load_multisig_tx(s, exported_txs, accept_func))
{
LOG_PRINT_L0("Failed to parse multisig tx data from " << filename);
return false;
}
return true;
}
//----------------------------------------------------------------------------------------------------
bool wallet2::sign_multisig_tx(multisig_tx_set &exported_txs, std::vector<crypto::hash> &txids)
{
THROW_WALLET_EXCEPTION_IF(exported_txs.m_ptx.empty(), error::wallet_internal_error, "No tx found");
const crypto::public_key local_signer = get_multisig_signer_public_key();
THROW_WALLET_EXCEPTION_IF(exported_txs.m_signers.find(local_signer) != exported_txs.m_signers.end(),
error::wallet_internal_error, "Transaction already signed by this private key");
THROW_WALLET_EXCEPTION_IF(exported_txs.m_signers.size() > m_multisig_threshold,
error::wallet_internal_error, "Transaction was signed by too many signers");
THROW_WALLET_EXCEPTION_IF(exported_txs.m_signers.size() == m_multisig_threshold,
error::wallet_internal_error, "Transaction is already fully signed");
txids.clear();
// sign the transactions
for (size_t n = 0; n < exported_txs.m_ptx.size(); ++n)
{
tools::wallet2::pending_tx &ptx = exported_txs.m_ptx[n];
THROW_WALLET_EXCEPTION_IF(ptx.multisig_sigs.empty(), error::wallet_internal_error, "No signatures found in multisig tx");
tools::wallet2::tx_construction_data &sd = ptx.construction_data;
LOG_PRINT_L1(" " << (n+1) << ": " << sd.sources.size() << " inputs, mixin " << (sd.sources[0].outputs.size()-1) <<
", signed by " << exported_txs.m_signers.size() << "/" << m_multisig_threshold);
cryptonote::transaction tx;
rct::multisig_out msout = ptx.multisig_sigs.front().msout;
auto sources = sd.sources;
rct::RangeProofType range_proof_type = rct::RangeProofBorromean;
if (sd.use_bulletproofs)
{
range_proof_type = rct::RangeProofBulletproof;
for (const rct::Bulletproof &proof: ptx.tx.rct_signatures.p.bulletproofs)
if (proof.V.size() > 1)
range_proof_type = rct::RangeProofPaddedBulletproof;
}
bool r = cryptonote::construct_tx_with_tx_key(m_account.get_keys(), m_subaddresses, sources, sd.splitted_dsts, ptx.change_dts.addr, sd.extra, tx, sd.unlock_time, ptx.tx_key, ptx.additional_tx_keys, sd.use_rct, range_proof_type, &msout, false);
THROW_WALLET_EXCEPTION_IF(!r, error::tx_not_constructed, sd.sources, sd.splitted_dsts, sd.unlock_time, m_nettype);
THROW_WALLET_EXCEPTION_IF(get_transaction_prefix_hash (tx) != get_transaction_prefix_hash(ptx.tx),
error::wallet_internal_error, "Transaction prefix does not match data");
// Tests passed, sign
std::vector<unsigned int> indices;
for (const auto &source: sources)
indices.push_back(source.real_output);
for (auto &sig: ptx.multisig_sigs)
{
if (sig.ignore != local_signer)
{
ptx.tx.rct_signatures = sig.sigs;
rct::keyV k;
for (size_t idx: sd.selected_transfers)
k.push_back(get_multisig_k(idx, sig.used_L));
rct::key skey = rct::zero();
for (const auto &msk: get_account().get_multisig_keys())
{
crypto::public_key pmsk = get_multisig_signing_public_key(msk);
if (sig.signing_keys.find(pmsk) == sig.signing_keys.end())
{
sc_add(skey.bytes, skey.bytes, rct::sk2rct(msk).bytes);
sig.signing_keys.insert(pmsk);
}
}
THROW_WALLET_EXCEPTION_IF(!rct::signMultisig(ptx.tx.rct_signatures, indices, k, sig.msout, skey),
error::wallet_internal_error, "Failed signing, transaction likely malformed");
sig.sigs = ptx.tx.rct_signatures;
}
}
const bool is_last = exported_txs.m_signers.size() + 1 >= m_multisig_threshold;
if (is_last)
{
// when the last signature on a multisig tx is made, we select the right
// signature to plug into the final tx
bool found = false;
for (const auto &sig: ptx.multisig_sigs)
{
if (sig.ignore != local_signer && exported_txs.m_signers.find(sig.ignore) == exported_txs.m_signers.end())
{
THROW_WALLET_EXCEPTION_IF(found, error::wallet_internal_error, "More than one transaction is final");
ptx.tx.rct_signatures = sig.sigs;
found = true;
}
}
THROW_WALLET_EXCEPTION_IF(!found, error::wallet_internal_error,
"Final signed transaction not found: this transaction was likely made without our export data, so we cannot sign it");
const crypto::hash txid = get_transaction_hash(ptx.tx);
if (store_tx_info())
{
m_tx_keys.insert(std::make_pair(txid, ptx.tx_key));
m_additional_tx_keys.insert(std::make_pair(txid, ptx.additional_tx_keys));
}
txids.push_back(txid);
}
}
// txes generated, get rid of used k values
for (size_t n = 0; n < exported_txs.m_ptx.size(); ++n)
for (size_t idx: exported_txs.m_ptx[n].construction_data.selected_transfers)
m_transfers[idx].m_multisig_k.clear();
exported_txs.m_signers.insert(get_multisig_signer_public_key());
return true;
}
//----------------------------------------------------------------------------------------------------
bool wallet2::sign_multisig_tx_to_file(multisig_tx_set &exported_txs, const std::string &filename, std::vector<crypto::hash> &txids)
{
bool r = sign_multisig_tx(exported_txs, txids);
if (!r)
return false;
return save_multisig_tx(exported_txs, filename);
}
//----------------------------------------------------------------------------------------------------
bool wallet2::sign_multisig_tx_from_file(const std::string &filename, std::vector<crypto::hash> &txids, std::function<bool(const multisig_tx_set&)> accept_func)
{
multisig_tx_set exported_txs;
if(!load_multisig_tx_from_file(filename, exported_txs))
return false;
if (accept_func && !accept_func(exported_txs))
{
LOG_PRINT_L1("Transactions rejected by callback");
return false;
}
return sign_multisig_tx_to_file(exported_txs, filename, txids);
}
//----------------------------------------------------------------------------------------------------
uint64_t wallet2::get_fee_multiplier(uint32_t priority, int fee_algorithm) const
{
static const struct
{
size_t count;
uint64_t multipliers[4];
}
multipliers[] =
{
{ 3, {1, 2, 3} },
{ 3, {1, 20, 166} },
{ 4, {1, 4, 20, 166} },
{ 4, {1, 5, 25, 1000} },
};
if (fee_algorithm == -1)
fee_algorithm = get_fee_algorithm();
// 0 -> default (here, x1 till fee algorithm 2, x4 from it)
if (priority == 0)
priority = m_default_priority;
if (priority == 0)
{
if (fee_algorithm >= 2)
priority = 2;
else
priority = 1;
}
THROW_WALLET_EXCEPTION_IF(fee_algorithm < 0 || fee_algorithm > 3, error::invalid_priority);
// 1 to 3/4 are allowed as priorities
const uint32_t max_priority = multipliers[fee_algorithm].count;
if (priority >= 1 && priority <= max_priority)
{
return multipliers[fee_algorithm].multipliers[priority-1];
}
THROW_WALLET_EXCEPTION_IF (false, error::invalid_priority);
return 1;
}
//----------------------------------------------------------------------------------------------------
uint64_t wallet2::get_dynamic_base_fee_estimate() const
{
uint64_t fee;
boost::optional<std::string> result = m_node_rpc_proxy.get_dynamic_base_fee_estimate(FEE_ESTIMATE_GRACE_BLOCKS, fee);
if (!result)
return fee;
const uint64_t base_fee = use_fork_rules(HF_VERSION_PER_BYTE_FEE) ? FEE_PER_BYTE : FEE_PER_KB;
LOG_PRINT_L1("Failed to query base fee, using " << print_money(base_fee));
return base_fee;
}
//----------------------------------------------------------------------------------------------------
uint64_t wallet2::get_base_fee() const
{
if(m_light_wallet)
{
if (use_fork_rules(HF_VERSION_PER_BYTE_FEE))
return m_light_wallet_per_kb_fee / 1024;
else
return m_light_wallet_per_kb_fee;
}
bool use_dyn_fee = use_fork_rules(HF_VERSION_DYNAMIC_FEE, -720 * 1);
if (!use_dyn_fee)
return FEE_PER_KB;
return get_dynamic_base_fee_estimate();
}
//----------------------------------------------------------------------------------------------------
uint64_t wallet2::get_fee_quantization_mask() const
{
if(m_light_wallet)
{
return 1; // TODO
}
bool use_per_byte_fee = use_fork_rules(HF_VERSION_PER_BYTE_FEE, 0);
if (!use_per_byte_fee)
return 1;
uint64_t fee_quantization_mask;
boost::optional<std::string> result = m_node_rpc_proxy.get_fee_quantization_mask(fee_quantization_mask);
if (result)
return 1;
return fee_quantization_mask;
}
//----------------------------------------------------------------------------------------------------
int wallet2::get_fee_algorithm() const
{
// changes at v3, v5, v8
if (use_fork_rules(HF_VERSION_PER_BYTE_FEE, 0))
return 3;
if (use_fork_rules(5, 0))
return 2;
if (use_fork_rules(3, -720 * 14))
return 1;
return 0;
}
//------------------------------------------------------------------------------------------------------------------------------
uint64_t wallet2::get_min_ring_size() const
{
if (use_fork_rules(8, 10))
return 11;
if (use_fork_rules(7, 10))
return 7;
if (use_fork_rules(6, 10))
return 5;
if (use_fork_rules(2, 10))
return 3;
return 0;
}
//------------------------------------------------------------------------------------------------------------------------------
uint64_t wallet2::get_max_ring_size() const
{
if (use_fork_rules(8, 10))
return 11;
return 0;
}
//------------------------------------------------------------------------------------------------------------------------------
uint64_t wallet2::adjust_mixin(uint64_t mixin) const
{
const uint64_t min_ring_size = get_min_ring_size();
if (mixin + 1 < min_ring_size)
{
MWARNING("Requested ring size " << (mixin + 1) << " too low, using " << min_ring_size);
mixin = min_ring_size-1;
}
const uint64_t max_ring_size = get_max_ring_size();
if (max_ring_size && mixin + 1 > max_ring_size)
{
MWARNING("Requested ring size " << (mixin + 1) << " too high, using " << max_ring_size);
mixin = max_ring_size-1;
}
return mixin;
}
//----------------------------------------------------------------------------------------------------
uint32_t wallet2::adjust_priority(uint32_t priority)
{
if (priority == 0 && m_default_priority == 0 && auto_low_priority())
{
try
{
// check if there's a backlog in the tx pool
const bool use_per_byte_fee = use_fork_rules(HF_VERSION_PER_BYTE_FEE, 0);
const uint64_t base_fee = get_base_fee();
const uint64_t fee_multiplier = get_fee_multiplier(1);
const double fee_level = fee_multiplier * base_fee * (use_per_byte_fee ? 1 : (12/(double)13 / (double)1024));
const std::vector<std::pair<uint64_t, uint64_t>> blocks = estimate_backlog({std::make_pair(fee_level, fee_level)});
if (blocks.size() != 1)
{
MERROR("Bad estimated backlog array size");
return priority;
}
else if (blocks[0].first > 0)
{
MINFO("We don't use the low priority because there's a backlog in the tx pool.");
return priority;
}
// get the current full reward zone
uint64_t block_weight_limit = 0;
const auto result = m_node_rpc_proxy.get_block_weight_limit(block_weight_limit);
throw_on_rpc_response_error(result, "get_info");
const uint64_t full_reward_zone = block_weight_limit / 2;
// get the last N block headers and sum the block sizes
const size_t N = 10;
if (m_blockchain.size() < N)
{
MERROR("The blockchain is too short");
return priority;
}
cryptonote::COMMAND_RPC_GET_BLOCK_HEADERS_RANGE::request getbh_req = AUTO_VAL_INIT(getbh_req);
cryptonote::COMMAND_RPC_GET_BLOCK_HEADERS_RANGE::response getbh_res = AUTO_VAL_INIT(getbh_res);
m_daemon_rpc_mutex.lock();
getbh_req.start_height = m_blockchain.size() - N;
getbh_req.end_height = m_blockchain.size() - 1;
bool r = net_utils::invoke_http_json_rpc("/json_rpc", "getblockheadersrange", getbh_req, getbh_res, m_http_client, rpc_timeout);
m_daemon_rpc_mutex.unlock();
THROW_WALLET_EXCEPTION_IF(!r, error::no_connection_to_daemon, "getblockheadersrange");
THROW_WALLET_EXCEPTION_IF(getbh_res.status == CORE_RPC_STATUS_BUSY, error::daemon_busy, "getblockheadersrange");
THROW_WALLET_EXCEPTION_IF(getbh_res.status != CORE_RPC_STATUS_OK, error::get_blocks_error, getbh_res.status);
if (getbh_res.headers.size() != N)
{
MERROR("Bad blockheaders size");
return priority;
}
size_t block_weight_sum = 0;
for (const cryptonote::block_header_response &i : getbh_res.headers)
{
block_weight_sum += i.block_weight;
}
// estimate how 'full' the last N blocks are
const size_t P = 100 * block_weight_sum / (N * full_reward_zone);
MINFO((boost::format("The last %d blocks fill roughly %d%% of the full reward zone.") % N % P).str());
if (P > 80)
{
MINFO("We don't use the low priority because recent blocks are quite full.");
return priority;
}
MINFO("We'll use the low priority because probably it's safe to do so.");
return 1;
}
catch (const std::exception &e)
{
MERROR(e.what());
}
}
return priority;
}
//----------------------------------------------------------------------------------------------------
bool wallet2::set_ring_database(const std::string &filename)
{
m_ring_database = filename;
MINFO("ringdb path set to " << filename);
m_ringdb.reset();
if (!m_ring_database.empty())
{
try
{
cryptonote::block b;
generate_genesis(b);
m_ringdb.reset(new tools::ringdb(m_ring_database, epee::string_tools::pod_to_hex(get_block_hash(b))));
}
catch (const std::exception &e)
{
MERROR("Failed to initialize ringdb: " << e.what());
m_ring_database = "";
return false;
}
}
return true;
}
crypto::chacha_key wallet2::get_ringdb_key()
{
if (!m_ringdb_key)
{
MINFO("caching ringdb key");
crypto::chacha_key key;
generate_chacha_key_from_secret_keys(key);
m_ringdb_key = key;
}
return *m_ringdb_key;
}
void wallet2::register_devices(){
hw::trezor::register_all();
}
hw::device& wallet2::lookup_device(const std::string & device_descriptor){
if (!m_devices_registered){
m_devices_registered = true;
register_devices();
}
return hw::get_device(device_descriptor);
}
bool wallet2::add_rings(const crypto::chacha_key &key, const cryptonote::transaction_prefix &tx)
{
if (!m_ringdb)
return false;
try { return m_ringdb->add_rings(key, tx); }
catch (const std::exception &e) { return false; }
}
bool wallet2::add_rings(const cryptonote::transaction_prefix &tx)
{
try { return add_rings(get_ringdb_key(), tx); }
catch (const std::exception &e) { return false; }
}
bool wallet2::remove_rings(const cryptonote::transaction_prefix &tx)
{
if (!m_ringdb)
return false;
try { return m_ringdb->remove_rings(get_ringdb_key(), tx); }
catch (const std::exception &e) { return false; }
}
bool wallet2::get_ring(const crypto::chacha_key &key, const crypto::key_image &key_image, std::vector<uint64_t> &outs)
{
if (!m_ringdb)
return false;
try { return m_ringdb->get_ring(key, key_image, outs); }
catch (const std::exception &e) { return false; }
}
bool wallet2::get_rings(const crypto::hash &txid, std::vector<std::pair<crypto::key_image, std::vector<uint64_t>>> &outs)
{
for (auto i: m_confirmed_txs)
{
if (txid == i.first)
{
for (const auto &x: i.second.m_rings)
outs.push_back({x.first, cryptonote::relative_output_offsets_to_absolute(x.second)});
return true;
}
}
for (auto i: m_unconfirmed_txs)
{
if (txid == i.first)
{
for (const auto &x: i.second.m_rings)
outs.push_back({x.first, cryptonote::relative_output_offsets_to_absolute(x.second)});
return true;
}
}
return false;
}
bool wallet2::get_ring(const crypto::key_image &key_image, std::vector<uint64_t> &outs)
{
try { return get_ring(get_ringdb_key(), key_image, outs); }
catch (const std::exception &e) { return false; }
}
bool wallet2::set_ring(const crypto::key_image &key_image, const std::vector<uint64_t> &outs, bool relative)
{
if (!m_ringdb)
return false;
try { return m_ringdb->set_ring(get_ringdb_key(), key_image, outs, relative); }
catch (const std::exception &e) { return false; }
}
bool wallet2::find_and_save_rings(bool force)
{
if (!force && m_ring_history_saved)
return true;
if (!m_ringdb)
return false;
COMMAND_RPC_GET_TRANSACTIONS::request req = AUTO_VAL_INIT(req);
COMMAND_RPC_GET_TRANSACTIONS::response res = AUTO_VAL_INIT(res);
MDEBUG("Finding and saving rings...");
// get payments we made
std::vector<crypto::hash> txs_hashes;
std::list<std::pair<crypto::hash,wallet2::confirmed_transfer_details>> payments;
get_payments_out(payments, 0, std::numeric_limits<uint64_t>::max(), boost::none, std::set<uint32_t>());
for (const std::pair<crypto::hash,wallet2::confirmed_transfer_details> &entry: payments)
{
const crypto::hash &txid = entry.first;
txs_hashes.push_back(txid);
}
MDEBUG("Found " << std::to_string(txs_hashes.size()) << " transactions");
// get those transactions from the daemon
static const size_t SLICE_SIZE = 200;
for (size_t slice = 0; slice < txs_hashes.size(); slice += SLICE_SIZE)
{
req.decode_as_json = false;
req.prune = false;
req.txs_hashes.clear();
size_t ntxes = slice + SLICE_SIZE > txs_hashes.size() ? txs_hashes.size() - slice : SLICE_SIZE;
for (size_t s = slice; s < slice + ntxes; ++s)
req.txs_hashes.push_back(epee::string_tools::pod_to_hex(txs_hashes[s]));
bool r;
{
const boost::lock_guard<boost::mutex> lock{m_daemon_rpc_mutex};
r = epee::net_utils::invoke_http_json("/gettransactions", req, res, m_http_client, rpc_timeout);
}
THROW_WALLET_EXCEPTION_IF(!r, error::no_connection_to_daemon, "gettransactions");
THROW_WALLET_EXCEPTION_IF(res.status == CORE_RPC_STATUS_BUSY, error::daemon_busy, "gettransactions");
THROW_WALLET_EXCEPTION_IF(res.status != CORE_RPC_STATUS_OK, error::wallet_internal_error, "gettransactions");
THROW_WALLET_EXCEPTION_IF(res.txs.size() != req.txs_hashes.size(), error::wallet_internal_error,
"daemon returned wrong response for gettransactions, wrong txs count = " +
std::to_string(res.txs.size()) + ", expected " + std::to_string(req.txs_hashes.size()));
MDEBUG("Scanning " << res.txs.size() << " transactions");
THROW_WALLET_EXCEPTION_IF(slice + res.txs.size() > txs_hashes.size(), error::wallet_internal_error, "Unexpected tx array size");
auto it = req.txs_hashes.begin();
for (size_t i = 0; i < res.txs.size(); ++i, ++it)
{
const auto &tx_info = res.txs[i];
THROW_WALLET_EXCEPTION_IF(tx_info.tx_hash != epee::string_tools::pod_to_hex(txs_hashes[slice + i]), error::wallet_internal_error, "Wrong txid received");
THROW_WALLET_EXCEPTION_IF(tx_info.tx_hash != *it, error::wallet_internal_error, "Wrong txid received");
cryptonote::blobdata bd;
THROW_WALLET_EXCEPTION_IF(!epee::string_tools::parse_hexstr_to_binbuff(tx_info.as_hex, bd), error::wallet_internal_error, "failed to parse tx from hexstr");
cryptonote::transaction tx;
crypto::hash tx_hash, tx_prefix_hash;
THROW_WALLET_EXCEPTION_IF(!cryptonote::parse_and_validate_tx_from_blob(bd, tx, tx_hash, tx_prefix_hash), error::wallet_internal_error, "failed to parse tx from blob");
THROW_WALLET_EXCEPTION_IF(epee::string_tools::pod_to_hex(tx_hash) != tx_info.tx_hash, error::wallet_internal_error, "txid mismatch");
THROW_WALLET_EXCEPTION_IF(!add_rings(get_ringdb_key(), tx), error::wallet_internal_error, "Failed to save ring");
}
}
MINFO("Found and saved rings for " << txs_hashes.size() << " transactions");
m_ring_history_saved = true;
return true;
}
bool wallet2::blackball_output(const std::pair<uint64_t, uint64_t> &output)
{
if (!m_ringdb)
return false;
try { return m_ringdb->blackball(output); }
catch (const std::exception &e) { return false; }
}
bool wallet2::set_blackballed_outputs(const std::vector<std::pair<uint64_t, uint64_t>> &outputs, bool add)
{
if (!m_ringdb)
return false;
try
{
bool ret = true;
if (!add)
ret &= m_ringdb->clear_blackballs();
ret &= m_ringdb->blackball(outputs);
return ret;
}
catch (const std::exception &e) { return false; }
}
bool wallet2::unblackball_output(const std::pair<uint64_t, uint64_t> &output)
{
if (!m_ringdb)
return false;
try { return m_ringdb->unblackball(output); }
catch (const std::exception &e) { return false; }
}
bool wallet2::is_output_blackballed(const std::pair<uint64_t, uint64_t> &output) const
{
if (!m_ringdb)
return false;
try { return m_ringdb->blackballed(output); }
catch (const std::exception &e) { return false; }
}
bool wallet2::lock_keys_file()
{
if (m_keys_file_locker)
{
MDEBUG(m_keys_file << " is already locked.");
return false;
}
m_keys_file_locker.reset(new tools::file_locker(m_keys_file));
return true;
}
bool wallet2::unlock_keys_file()
{
if (!m_keys_file_locker)
{
MDEBUG(m_keys_file << " is already unlocked.");
return false;
}
m_keys_file_locker.reset();
return true;
}
bool wallet2::is_keys_file_locked() const
{
return m_keys_file_locker->locked();
}
bool wallet2::tx_add_fake_output(std::vector<std::vector<tools::wallet2::get_outs_entry>> &outs, uint64_t global_index, const crypto::public_key& output_public_key, const rct::key& mask, uint64_t real_index, bool unlocked) const
{
if (!unlocked) // don't add locked outs
return false;
if (global_index == real_index) // don't re-add real one
return false;
auto item = std::make_tuple(global_index, output_public_key, mask);
CHECK_AND_ASSERT_MES(!outs.empty(), false, "internal error: outs is empty");
if (std::find(outs.back().begin(), outs.back().end(), item) != outs.back().end()) // don't add duplicates
return false;
// if (is_output_blackballed(output_public_key)) // don't add blackballed outputs
// return false;
outs.back().push_back(item);
return true;
}
void wallet2::light_wallet_get_outs(std::vector<std::vector<tools::wallet2::get_outs_entry>> &outs, const std::vector<size_t> &selected_transfers, size_t fake_outputs_count) {
MDEBUG("LIGHTWALLET - Getting random outs");
cryptonote::COMMAND_RPC_GET_RANDOM_OUTS::request oreq;
cryptonote::COMMAND_RPC_GET_RANDOM_OUTS::response ores;
size_t light_wallet_requested_outputs_count = (size_t)((fake_outputs_count + 1) * 1.5 + 1);
// Amounts to ask for
// MyMonero api handle amounts and fees as strings
for(size_t idx: selected_transfers) {
const uint64_t ask_amount = m_transfers[idx].is_rct() ? 0 : m_transfers[idx].amount();
std::ostringstream amount_ss;
amount_ss << ask_amount;
oreq.amounts.push_back(amount_ss.str());
}
oreq.count = light_wallet_requested_outputs_count;
m_daemon_rpc_mutex.lock();
bool r = epee::net_utils::invoke_http_json("/get_random_outs", oreq, ores, m_http_client, rpc_timeout, "POST");
m_daemon_rpc_mutex.unlock();
THROW_WALLET_EXCEPTION_IF(!r, error::no_connection_to_daemon, "get_random_outs");
THROW_WALLET_EXCEPTION_IF(ores.amount_outs.empty() , error::wallet_internal_error, "No outputs received from light wallet node. Error: " + ores.Error);
// Check if we got enough outputs for each amount
for(auto& out: ores.amount_outs) {
const uint64_t out_amount = boost::lexical_cast<uint64_t>(out.amount);
THROW_WALLET_EXCEPTION_IF(out.outputs.size() < light_wallet_requested_outputs_count , error::wallet_internal_error, "Not enough outputs for amount: " + boost::lexical_cast<std::string>(out.amount));
MDEBUG(out.outputs.size() << " outputs for amount "+ boost::lexical_cast<std::string>(out.amount) + " received from light wallet node");
}
MDEBUG("selected transfers size: " << selected_transfers.size());
for(size_t idx: selected_transfers)
{
// Create new index
outs.push_back(std::vector<get_outs_entry>());
outs.back().reserve(fake_outputs_count + 1);
// add real output first
const transfer_details &td = m_transfers[idx];
const uint64_t amount = td.is_rct() ? 0 : td.amount();
outs.back().push_back(std::make_tuple(td.m_global_output_index, td.get_public_key(), rct::commit(td.amount(), td.m_mask)));
MDEBUG("added real output " << string_tools::pod_to_hex(td.get_public_key()));
// Even if the lightwallet server returns random outputs, we pick them randomly.
std::vector<size_t> order;
order.resize(light_wallet_requested_outputs_count);
for (size_t n = 0; n < order.size(); ++n)
order[n] = n;
std::shuffle(order.begin(), order.end(), std::default_random_engine(crypto::rand<unsigned>()));
LOG_PRINT_L2("Looking for " << (fake_outputs_count+1) << " outputs with amounts " << print_money(td.is_rct() ? 0 : td.amount()));
MDEBUG("OUTS SIZE: " << outs.back().size());
for (size_t o = 0; o < light_wallet_requested_outputs_count && outs.back().size() < fake_outputs_count + 1; ++o)
{
// Random pick
size_t i = order[o];
// Find which random output key to use
bool found_amount = false;
size_t amount_key;
for(amount_key = 0; amount_key < ores.amount_outs.size(); ++amount_key)
{
if(boost::lexical_cast<uint64_t>(ores.amount_outs[amount_key].amount) == amount) {
found_amount = true;
break;
}
}
THROW_WALLET_EXCEPTION_IF(!found_amount , error::wallet_internal_error, "Outputs for amount " + boost::lexical_cast<std::string>(ores.amount_outs[amount_key].amount) + " not found" );
LOG_PRINT_L2("Index " << i << "/" << light_wallet_requested_outputs_count << ": idx " << ores.amount_outs[amount_key].outputs[i].global_index << " (real " << td.m_global_output_index << "), unlocked " << "(always in light)" << ", key " << ores.amount_outs[0].outputs[i].public_key);
// Convert light wallet string data to proper data structures
crypto::public_key tx_public_key;
rct::key mask = AUTO_VAL_INIT(mask); // decrypted mask - not used here
rct::key rct_commit = AUTO_VAL_INIT(rct_commit);
THROW_WALLET_EXCEPTION_IF(string_tools::validate_hex(64, ores.amount_outs[amount_key].outputs[i].public_key), error::wallet_internal_error, "Invalid public_key");
string_tools::hex_to_pod(ores.amount_outs[amount_key].outputs[i].public_key, tx_public_key);
const uint64_t global_index = ores.amount_outs[amount_key].outputs[i].global_index;
if(!light_wallet_parse_rct_str(ores.amount_outs[amount_key].outputs[i].rct, tx_public_key, 0, mask, rct_commit, false))
rct_commit = rct::zeroCommit(td.amount());
if (tx_add_fake_output(outs, global_index, tx_public_key, rct_commit, td.m_global_output_index, true)) {
MDEBUG("added fake output " << ores.amount_outs[amount_key].outputs[i].public_key);
MDEBUG("index " << global_index);
}
}
THROW_WALLET_EXCEPTION_IF(outs.back().size() < fake_outputs_count + 1 , error::wallet_internal_error, "Not enough fake outputs found" );
// Real output is the first. Shuffle outputs
MTRACE(outs.back().size() << " outputs added. Sorting outputs by index:");
std::sort(outs.back().begin(), outs.back().end(), [](const get_outs_entry &a, const get_outs_entry &b) { return std::get<0>(a) < std::get<0>(b); });
// Print output order
for(auto added_out: outs.back())
MTRACE(std::get<0>(added_out));
}
}
void wallet2::get_outs(std::vector<std::vector<tools::wallet2::get_outs_entry>> &outs, const std::vector<size_t> &selected_transfers, size_t fake_outputs_count)
{
LOG_PRINT_L2("fake_outputs_count: " << fake_outputs_count);
outs.clear();
if(m_light_wallet && fake_outputs_count > 0) {
light_wallet_get_outs(outs, selected_transfers, fake_outputs_count);
return;
}
if (fake_outputs_count > 0)
{
uint64_t segregation_fork_height = get_segregation_fork_height();
// check whether we're shortly after the fork
uint64_t height;
boost::optional<std::string> result = m_node_rpc_proxy.get_height(height);
throw_on_rpc_response_error(result, "get_info");
bool is_shortly_after_segregation_fork = height >= segregation_fork_height && height < segregation_fork_height + SEGREGATION_FORK_VICINITY;
bool is_after_segregation_fork = height >= segregation_fork_height;
// if we have at least one rct out, get the distribution, or fall back to the previous system
uint64_t rct_start_height;
std::vector<uint64_t> rct_offsets;
bool has_rct = false;
uint64_t max_rct_index = 0;
for (size_t idx: selected_transfers)
if (m_transfers[idx].is_rct())
{
has_rct = true;
max_rct_index = std::max(max_rct_index, m_transfers[idx].m_global_output_index);
}
const bool has_rct_distribution = has_rct && get_rct_distribution(rct_start_height, rct_offsets);
if (has_rct_distribution)
{
// check we're clear enough of rct start, to avoid corner cases below
THROW_WALLET_EXCEPTION_IF(rct_offsets.size() <= CRYPTONOTE_DEFAULT_TX_SPENDABLE_AGE,
error::get_output_distribution, "Not enough rct outputs");
THROW_WALLET_EXCEPTION_IF(rct_offsets.back() <= max_rct_index,
error::get_output_distribution, "Daemon reports suspicious number of rct outputs");
}
// get histogram for the amounts we need
cryptonote::COMMAND_RPC_GET_OUTPUT_HISTOGRAM::request req_t = AUTO_VAL_INIT(req_t);
cryptonote::COMMAND_RPC_GET_OUTPUT_HISTOGRAM::response resp_t = AUTO_VAL_INIT(resp_t);
// request histogram for all outputs, except 0 if we have the rct distribution
for(size_t idx: selected_transfers)
if (!m_transfers[idx].is_rct() || !has_rct_distribution)
req_t.amounts.push_back(m_transfers[idx].is_rct() ? 0 : m_transfers[idx].amount());
if (!req_t.amounts.empty())
{
std::sort(req_t.amounts.begin(), req_t.amounts.end());
auto end = std::unique(req_t.amounts.begin(), req_t.amounts.end());
req_t.amounts.resize(std::distance(req_t.amounts.begin(), end));
req_t.unlocked = true;
req_t.recent_cutoff = time(NULL) - RECENT_OUTPUT_ZONE;
m_daemon_rpc_mutex.lock();
bool r = net_utils::invoke_http_json_rpc("/json_rpc", "get_output_histogram", req_t, resp_t, m_http_client, rpc_timeout);
m_daemon_rpc_mutex.unlock();
THROW_WALLET_EXCEPTION_IF(!r, error::no_connection_to_daemon, "transfer_selected");
THROW_WALLET_EXCEPTION_IF(resp_t.status == CORE_RPC_STATUS_BUSY, error::daemon_busy, "get_output_histogram");
THROW_WALLET_EXCEPTION_IF(resp_t.status != CORE_RPC_STATUS_OK, error::get_histogram_error, resp_t.status);
}
// if we want to segregate fake outs pre or post fork, get distribution
std::unordered_map<uint64_t, std::pair<uint64_t, uint64_t>> segregation_limit;
if (is_after_segregation_fork && (m_segregate_pre_fork_outputs || m_key_reuse_mitigation2))
{
cryptonote::COMMAND_RPC_GET_OUTPUT_DISTRIBUTION::request req_t = AUTO_VAL_INIT(req_t);
cryptonote::COMMAND_RPC_GET_OUTPUT_DISTRIBUTION::response resp_t = AUTO_VAL_INIT(resp_t);
for(size_t idx: selected_transfers)
req_t.amounts.push_back(m_transfers[idx].is_rct() ? 0 : m_transfers[idx].amount());
std::sort(req_t.amounts.begin(), req_t.amounts.end());
auto end = std::unique(req_t.amounts.begin(), req_t.amounts.end());
req_t.amounts.resize(std::distance(req_t.amounts.begin(), end));
req_t.from_height = std::max<uint64_t>(segregation_fork_height, RECENT_OUTPUT_BLOCKS) - RECENT_OUTPUT_BLOCKS;
req_t.to_height = segregation_fork_height + 1;
req_t.cumulative = true;
req_t.binary = true;
m_daemon_rpc_mutex.lock();
bool r = net_utils::invoke_http_json_rpc("/json_rpc", "get_output_distribution", req_t, resp_t, m_http_client, rpc_timeout * 1000);
m_daemon_rpc_mutex.unlock();
THROW_WALLET_EXCEPTION_IF(!r, error::no_connection_to_daemon, "transfer_selected");
THROW_WALLET_EXCEPTION_IF(resp_t.status == CORE_RPC_STATUS_BUSY, error::daemon_busy, "get_output_distribution");
THROW_WALLET_EXCEPTION_IF(resp_t.status != CORE_RPC_STATUS_OK, error::get_output_distribution, resp_t.status);
// check we got all data
for(size_t idx: selected_transfers)
{
const uint64_t amount = m_transfers[idx].is_rct() ? 0 : m_transfers[idx].amount();
bool found = false;
for (const auto &d: resp_t.distributions)
{
if (d.amount == amount)
{
THROW_WALLET_EXCEPTION_IF(d.data.start_height > segregation_fork_height, error::get_output_distribution, "Distribution start_height too high");
THROW_WALLET_EXCEPTION_IF(segregation_fork_height - d.data.start_height >= d.data.distribution.size(), error::get_output_distribution, "Distribution size too small");
THROW_WALLET_EXCEPTION_IF(segregation_fork_height - RECENT_OUTPUT_BLOCKS - d.data.start_height >= d.data.distribution.size(), error::get_output_distribution, "Distribution size too small");
THROW_WALLET_EXCEPTION_IF(segregation_fork_height <= RECENT_OUTPUT_BLOCKS, error::wallet_internal_error, "Fork height too low");
THROW_WALLET_EXCEPTION_IF(segregation_fork_height - RECENT_OUTPUT_BLOCKS < d.data.start_height, error::get_output_distribution, "Bad start height");
uint64_t till_fork = d.data.distribution[segregation_fork_height - d.data.start_height];
uint64_t recent = till_fork - d.data.distribution[segregation_fork_height - RECENT_OUTPUT_BLOCKS - d.data.start_height];
segregation_limit[amount] = std::make_pair(till_fork, recent);
found = true;
break;
}
}
THROW_WALLET_EXCEPTION_IF(!found, error::get_output_distribution, "Requested amount not found in response");
}
}
// we ask for more, to have spares if some outputs are still locked
size_t base_requested_outputs_count = (size_t)((fake_outputs_count + 1) * 1.5 + 1);
LOG_PRINT_L2("base_requested_outputs_count: " << base_requested_outputs_count);
// generate output indices to request
COMMAND_RPC_GET_OUTPUTS_BIN::request req = AUTO_VAL_INIT(req);
COMMAND_RPC_GET_OUTPUTS_BIN::response daemon_resp = AUTO_VAL_INIT(daemon_resp);
struct gamma_engine
{
typedef uint64_t result_type;
static constexpr result_type min() { return 0; }
static constexpr result_type max() { return std::numeric_limits<result_type>::max(); }
result_type operator()() { return crypto::rand<result_type>(); }
} engine;
static const double shape = 19.28/*16.94*/;
//static const double shape = m_testnet ? 17.02 : 17.28;
static const double scale = 1/1.61;
std::gamma_distribution<double> gamma(shape, scale);
auto pick_gamma = [&]()
{
double x = gamma(engine);
x = exp(x);
uint64_t block_offset = x / DIFFICULTY_TARGET_V2; // this assumes constant target over the whole rct range
if (block_offset >= rct_offsets.size() - 1)
return std::numeric_limits<uint64_t>::max(); // bad pick
block_offset = rct_offsets.size() - 2 - block_offset;
THROW_WALLET_EXCEPTION_IF(block_offset >= rct_offsets.size() - 1, error::wallet_internal_error, "Bad offset calculation");
THROW_WALLET_EXCEPTION_IF(rct_offsets[block_offset + 1] < rct_offsets[block_offset],
error::get_output_distribution, "Decreasing offsets in rct distribution: " +
std::to_string(block_offset) + ": " + std::to_string(rct_offsets[block_offset]) + ", " +
std::to_string(block_offset + 1) + ": " + std::to_string(rct_offsets[block_offset + 1]));
uint64_t first_block_offset = block_offset, last_block_offset = block_offset;
for (size_t half_window = 0; half_window < GAMMA_PICK_HALF_WINDOW; ++half_window)
{
// end when we have a non empty block
uint64_t cum0 = first_block_offset > 0 ? rct_offsets[first_block_offset] - rct_offsets[first_block_offset - 1] : rct_offsets[0];
if (cum0 > 1)
break;
uint64_t cum1 = last_block_offset > 0 ? rct_offsets[last_block_offset] - rct_offsets[last_block_offset - 1] : rct_offsets[0];
if (cum1 > 1)
break;
if (first_block_offset == 0 && last_block_offset >= rct_offsets.size() - 2)
break;
// expand up to bounds
if (first_block_offset > 0)
--first_block_offset;
if (last_block_offset < rct_offsets.size() - 1)
++last_block_offset;
}
const uint64_t n_rct = rct_offsets[last_block_offset] - (first_block_offset == 0 ? 0 : rct_offsets[first_block_offset - 1]);
if (n_rct == 0)
return rct_offsets[block_offset] ? rct_offsets[block_offset] - 1 : 0;
MDEBUG("Picking 1/" << n_rct << " in " << (last_block_offset - first_block_offset + 1) << " blocks centered around " << block_offset);
return rct_offsets[first_block_offset] + crypto::rand<uint64_t>() % n_rct;
};
size_t num_selected_transfers = 0;
for(size_t idx: selected_transfers)
{
++num_selected_transfers;
const transfer_details &td = m_transfers[idx];
const uint64_t amount = td.is_rct() ? 0 : td.amount();
std::unordered_set<uint64_t> seen_indices;
// request more for rct in base recent (locked) coinbases are picked, since they're locked for longer
size_t requested_outputs_count = base_requested_outputs_count + (td.is_rct() ? CRYPTONOTE_MINED_MONEY_UNLOCK_WINDOW - CRYPTONOTE_DEFAULT_TX_SPENDABLE_AGE : 0);
size_t start = req.outputs.size();
bool use_histogram = amount != 0 || !has_rct_distribution;
const bool output_is_pre_fork = td.m_block_height < segregation_fork_height;
uint64_t num_outs = 0, num_recent_outs = 0;
uint64_t num_post_fork_outs = 0;
float pre_fork_num_out_ratio = 0.0f;
float post_fork_num_out_ratio = 0.0f;
if (is_after_segregation_fork && m_segregate_pre_fork_outputs && output_is_pre_fork)
{
num_outs = segregation_limit[amount].first;
num_recent_outs = segregation_limit[amount].second;
}
else
{
// if there are just enough outputs to mix with, use all of them.
// Eventually this should become impossible.
for (const auto &he: resp_t.histogram)
{
if (he.amount == amount)
{
LOG_PRINT_L2("Found " << print_money(amount) << ": " << he.total_instances << " total, "
<< he.unlocked_instances << " unlocked, " << he.recent_instances << " recent");
num_outs = he.unlocked_instances;
num_recent_outs = he.recent_instances;
break;
}
}
if (is_after_segregation_fork && m_key_reuse_mitigation2)
{
if (output_is_pre_fork)
{
if (is_shortly_after_segregation_fork)
{
pre_fork_num_out_ratio = 33.4/100.0f * (1.0f - RECENT_OUTPUT_RATIO);
}
else
{
pre_fork_num_out_ratio = 33.4/100.0f * (1.0f - RECENT_OUTPUT_RATIO);
post_fork_num_out_ratio = 33.4/100.0f * (1.0f - RECENT_OUTPUT_RATIO);
}
}
else
{
if (is_shortly_after_segregation_fork)
{
}
else
{
post_fork_num_out_ratio = 67.8/100.0f * (1.0f - RECENT_OUTPUT_RATIO);
}
}
}
num_post_fork_outs = num_outs - segregation_limit[amount].first;
}
if (use_histogram)
{
LOG_PRINT_L1("" << num_outs << " unlocked outputs of size " << print_money(amount));
THROW_WALLET_EXCEPTION_IF(num_outs == 0, error::wallet_internal_error,
"histogram reports no unlocked outputs for " + boost::lexical_cast<std::string>(amount) + ", not even ours");
THROW_WALLET_EXCEPTION_IF(num_recent_outs > num_outs, error::wallet_internal_error,
"histogram reports more recent outs than outs for " + boost::lexical_cast<std::string>(amount));
}
else
{
// the base offset of the first rct output in the first unlocked block (or the one to be if there's none)
num_outs = rct_offsets[rct_offsets.size() - CRYPTONOTE_DEFAULT_TX_SPENDABLE_AGE];
LOG_PRINT_L1("" << num_outs << " unlocked rct outputs");
THROW_WALLET_EXCEPTION_IF(num_outs == 0, error::wallet_internal_error,
"histogram reports no unlocked rct outputs, not even ours");
}
// how many fake outs to draw on a pre-fork distribution
size_t pre_fork_outputs_count = requested_outputs_count * pre_fork_num_out_ratio;
size_t post_fork_outputs_count = requested_outputs_count * post_fork_num_out_ratio;
// how many fake outs to draw otherwise
size_t normal_output_count = requested_outputs_count - pre_fork_outputs_count - post_fork_outputs_count;
size_t recent_outputs_count = 0;
if (use_histogram)
{
// X% of those outs are to be taken from recent outputs
recent_outputs_count = normal_output_count * RECENT_OUTPUT_RATIO;
if (recent_outputs_count == 0)
recent_outputs_count = 1; // ensure we have at least one, if possible
if (recent_outputs_count > num_recent_outs)
recent_outputs_count = num_recent_outs;
if (td.m_global_output_index >= num_outs - num_recent_outs && recent_outputs_count > 0)
--recent_outputs_count; // if the real out is recent, pick one less recent fake out
}
LOG_PRINT_L1("Fake output makeup: " << requested_outputs_count << " requested: " << recent_outputs_count << " recent, " <<
pre_fork_outputs_count << " pre-fork, " << post_fork_outputs_count << " post-fork, " <<
(requested_outputs_count - recent_outputs_count - pre_fork_outputs_count - post_fork_outputs_count) << " full-chain");
uint64_t num_found = 0;
// if we have a known ring, use it
bool existing_ring_found = false;
if (td.m_key_image_known && !td.m_key_image_partial)
{
std::vector<uint64_t> ring;
if (get_ring(get_ringdb_key(), td.m_key_image, ring))
{
MINFO("This output has a known ring, reusing (size " << ring.size() << ")");
THROW_WALLET_EXCEPTION_IF(ring.size() > fake_outputs_count + 1, error::wallet_internal_error,
"An output in this transaction was previously spent on another chain with ring size " +
std::to_string(ring.size()) + ", it cannot be spent now with ring size " +
std::to_string(fake_outputs_count + 1) + " as it is smaller: use a higher ring size");
bool own_found = false;
existing_ring_found = true;
for (const auto &out: ring)
{
MINFO("Ring has output " << out);
if (out < num_outs)
{
MINFO("Using it");
req.outputs.push_back({amount, out});
++num_found;
seen_indices.emplace(out);
if (out == td.m_global_output_index)
{
MINFO("This is the real output");
own_found = true;
}
}
else
{
MINFO("Ignoring output " << out << ", too recent");
}
}
THROW_WALLET_EXCEPTION_IF(!own_found, error::wallet_internal_error,
"Known ring does not include the spent output: " + std::to_string(td.m_global_output_index));
}
}
if (num_outs <= requested_outputs_count && !existing_ring_found)
{
for (uint64_t i = 0; i < num_outs; i++)
req.outputs.push_back({amount, i});
// duplicate to make up shortfall: this will be caught after the RPC call,
// so we can also output the amounts for which we can't reach the required
// mixin after checking the actual unlockedness
for (uint64_t i = num_outs; i < requested_outputs_count; ++i)
req.outputs.push_back({amount, num_outs - 1});
}
else
{
// start with real one
if (num_found == 0)
{
num_found = 1;
seen_indices.emplace(td.m_global_output_index);
req.outputs.push_back({amount, td.m_global_output_index});
LOG_PRINT_L1("Selecting real output: " << td.m_global_output_index << " for " << print_money(amount));
}
std::unordered_map<const char*, std::set<uint64_t>> picks;
// while we still need more mixins
uint64_t num_usable_outs = num_outs;
bool allow_blackballed = false;
while (num_found < requested_outputs_count)
{
// if we've gone through every possible output, we've gotten all we can
if (seen_indices.size() == num_usable_outs)
{
// there is a first pass which rejects blackballed outputs, then a second pass
// which allows them if we don't have enough non blackballed outputs to reach
// the required amount of outputs (since consensus does not care about blackballed
// outputs, we still need to reach the minimum ring size)
if (allow_blackballed)
break;
MINFO("Not enough output not marked as spent, we'll allow outputs marked as spent");
allow_blackballed = true;
num_usable_outs = num_outs;
}
// get a random output index from the DB. If we've already seen it,
// return to the top of the loop and try again, otherwise add it to the
// list of output indices we've seen.
uint64_t i;
const char *type = "";
if (amount == 0 && has_rct_distribution)
{
// gamma distribution
if (num_found -1 < recent_outputs_count + pre_fork_outputs_count)
{
do i = pick_gamma(); while (i >= segregation_limit[amount].first);
type = "pre-fork gamma";
}
else if (num_found -1 < recent_outputs_count + pre_fork_outputs_count + post_fork_outputs_count)
{
do i = pick_gamma(); while (i < segregation_limit[amount].first || i >= num_outs);
type = "post-fork gamma";
}
else
{
do i = pick_gamma(); while (i >= num_outs);
type = "gamma";
}
}
else if (num_found - 1 < recent_outputs_count) // -1 to account for the real one we seeded with
{
// triangular distribution over [a,b) with a=0, mode c=b=up_index_limit
uint64_t r = crypto::rand<uint64_t>() % ((uint64_t)1 << 53);
double frac = std::sqrt((double)r / ((uint64_t)1 << 53));
i = (uint64_t)(frac*num_recent_outs) + num_outs - num_recent_outs;
// just in case rounding up to 1 occurs after calc
if (i == num_outs)
--i;
type = "recent";
}
else if (num_found -1 < recent_outputs_count + pre_fork_outputs_count)
{
// triangular distribution over [a,b) with a=0, mode c=b=up_index_limit
uint64_t r = crypto::rand<uint64_t>() % ((uint64_t)1 << 53);
double frac = std::sqrt((double)r / ((uint64_t)1 << 53));
i = (uint64_t)(frac*segregation_limit[amount].first);
// just in case rounding up to 1 occurs after calc
if (i == num_outs)
--i;
type = " pre-fork";
}
else if (num_found -1 < recent_outputs_count + pre_fork_outputs_count + post_fork_outputs_count)
{
// triangular distribution over [a,b) with a=0, mode c=b=up_index_limit
uint64_t r = crypto::rand<uint64_t>() % ((uint64_t)1 << 53);
double frac = std::sqrt((double)r / ((uint64_t)1 << 53));
i = (uint64_t)(frac*num_post_fork_outs) + segregation_limit[amount].first;
// just in case rounding up to 1 occurs after calc
if (i == num_post_fork_outs+segregation_limit[amount].first)
--i;
type = "post-fork";
}
else
{
// triangular distribution over [a,b) with a=0, mode c=b=up_index_limit
uint64_t r = crypto::rand<uint64_t>() % ((uint64_t)1 << 53);
double frac = std::sqrt((double)r / ((uint64_t)1 << 53));
i = (uint64_t)(frac*num_outs);
// just in case rounding up to 1 occurs after calc
if (i == num_outs)
--i;
type = "triangular";
}
if (seen_indices.count(i))
continue;
if (!allow_blackballed && is_output_blackballed(std::make_pair(amount, i))) // don't add blackballed outputs
{
--num_usable_outs;
continue;
}
seen_indices.emplace(i);
picks[type].insert(i);
req.outputs.push_back({amount, i});
++num_found;
}
for (const auto &pick: picks)
MDEBUG("picking " << pick.first << " outputs: " <<
boost::join(pick.second | boost::adaptors::transformed([](uint64_t out){return std::to_string(out);}), " "));
// if we had enough unusable outputs, we might fall off here and still
// have too few outputs, so we stuff with one to keep counts good, and
// we'll error out later
while (num_found < requested_outputs_count)
{
req.outputs.push_back({amount, 0});
++num_found;
}
}
// sort the subsection, to ensure the daemon doesn't know which output is ours
std::sort(req.outputs.begin() + start, req.outputs.end(),
[](const get_outputs_out &a, const get_outputs_out &b) { return a.index < b.index; });
}
if (ELPP->vRegistry()->allowed(el::Level::Debug, MONERO_DEFAULT_LOG_CATEGORY))
{
std::map<uint64_t, std::set<uint64_t>> outs;
for (const auto &i: req.outputs)
outs[i.amount].insert(i.index);
for (const auto &o: outs)
MDEBUG("asking for outputs with amount " << print_money(o.first) << ": " <<
boost::join(o.second | boost::adaptors::transformed([](uint64_t out){return std::to_string(out);}), " "));
}
// get the keys for those
m_daemon_rpc_mutex.lock();
bool r = epee::net_utils::invoke_http_bin("/get_outs.bin", req, daemon_resp, m_http_client, rpc_timeout);
m_daemon_rpc_mutex.unlock();
THROW_WALLET_EXCEPTION_IF(!r, error::no_connection_to_daemon, "get_outs.bin");
THROW_WALLET_EXCEPTION_IF(daemon_resp.status == CORE_RPC_STATUS_BUSY, error::daemon_busy, "get_outs.bin");
THROW_WALLET_EXCEPTION_IF(daemon_resp.status != CORE_RPC_STATUS_OK, error::get_outs_error, daemon_resp.status);
THROW_WALLET_EXCEPTION_IF(daemon_resp.outs.size() != req.outputs.size(), error::wallet_internal_error,
"daemon returned wrong response for get_outs.bin, wrong amounts count = " +
std::to_string(daemon_resp.outs.size()) + ", expected " + std::to_string(req.outputs.size()));
std::unordered_map<uint64_t, uint64_t> scanty_outs;
size_t base = 0;
outs.reserve(num_selected_transfers);
for(size_t idx: selected_transfers)
{
const transfer_details &td = m_transfers[idx];
size_t requested_outputs_count = base_requested_outputs_count + (td.is_rct() ? CRYPTONOTE_MINED_MONEY_UNLOCK_WINDOW - CRYPTONOTE_DEFAULT_TX_SPENDABLE_AGE : 0);
outs.push_back(std::vector<get_outs_entry>());
outs.back().reserve(fake_outputs_count + 1);
const rct::key mask = td.is_rct() ? rct::commit(td.amount(), td.m_mask) : rct::zeroCommit(td.amount());
uint64_t num_outs = 0;
const uint64_t amount = td.is_rct() ? 0 : td.amount();
const bool output_is_pre_fork = td.m_block_height < segregation_fork_height;
if (is_after_segregation_fork && m_segregate_pre_fork_outputs && output_is_pre_fork)
num_outs = segregation_limit[amount].first;
else for (const auto &he: resp_t.histogram)
{
if (he.amount == amount)
{
num_outs = he.unlocked_instances;
break;
}
}
bool use_histogram = amount != 0 || !has_rct_distribution;
if (!use_histogram)
num_outs = rct_offsets[rct_offsets.size() - CRYPTONOTE_DEFAULT_TX_SPENDABLE_AGE];
// make sure the real outputs we asked for are really included, along
// with the correct key and mask: this guards against an active attack
// where the node sends dummy data for all outputs, and we then send
// the real one, which the node can then tell from the fake outputs,
// as it has different data than the dummy data it had sent earlier
bool real_out_found = false;
for (size_t n = 0; n < requested_outputs_count; ++n)
{
size_t i = base + n;
if (req.outputs[i].index == td.m_global_output_index)
if (daemon_resp.outs[i].key == boost::get<txout_to_key>(td.m_tx.vout[td.m_internal_output_index].target).key)
if (daemon_resp.outs[i].mask == mask)
real_out_found = true;
}
THROW_WALLET_EXCEPTION_IF(!real_out_found, error::wallet_internal_error,
"Daemon response did not include the requested real output");
// pick real out first (it will be sorted when done)
outs.back().push_back(std::make_tuple(td.m_global_output_index, boost::get<txout_to_key>(td.m_tx.vout[td.m_internal_output_index].target).key, mask));
// then pick outs from an existing ring, if any
bool existing_ring_found = false;
if (td.m_key_image_known && !td.m_key_image_partial)
{
std::vector<uint64_t> ring;
if (get_ring(get_ringdb_key(), td.m_key_image, ring))
{
for (uint64_t out: ring)
{
if (out < num_outs)
{
if (out != td.m_global_output_index)
{
bool found = false;
for (size_t o = 0; o < requested_outputs_count; ++o)
{
size_t i = base + o;
if (req.outputs[i].index == out)
{
LOG_PRINT_L2("Index " << i << "/" << requested_outputs_count << ": idx " << req.outputs[i].index << " (real " << td.m_global_output_index << "), unlocked " << daemon_resp.outs[i].unlocked << ", key " << daemon_resp.outs[i].key << " (from existing ring)");
tx_add_fake_output(outs, req.outputs[i].index, daemon_resp.outs[i].key, daemon_resp.outs[i].mask, td.m_global_output_index, daemon_resp.outs[i].unlocked);
found = true;
break;
}
}
THROW_WALLET_EXCEPTION_IF(!found, error::wallet_internal_error, "Falied to find existing ring output in daemon out data");
}
}
}
}
}
// then pick others in random order till we reach the required number
// since we use an equiprobable pick here, we don't upset the triangular distribution
std::vector<size_t> order;
order.resize(requested_outputs_count);
for (size_t n = 0; n < order.size(); ++n)
order[n] = n;
std::shuffle(order.begin(), order.end(), std::default_random_engine(crypto::rand<unsigned>()));
LOG_PRINT_L2("Looking for " << (fake_outputs_count+1) << " outputs of size " << print_money(td.is_rct() ? 0 : td.amount()));
for (size_t o = 0; o < requested_outputs_count && outs.back().size() < fake_outputs_count + 1; ++o)
{
size_t i = base + order[o];
LOG_PRINT_L2("Index " << i << "/" << requested_outputs_count << ": idx " << req.outputs[i].index << " (real " << td.m_global_output_index << "), unlocked " << daemon_resp.outs[i].unlocked << ", key " << daemon_resp.outs[i].key);
tx_add_fake_output(outs, req.outputs[i].index, daemon_resp.outs[i].key, daemon_resp.outs[i].mask, td.m_global_output_index, daemon_resp.outs[i].unlocked);
}
if (outs.back().size() < fake_outputs_count + 1)
{
scanty_outs[td.is_rct() ? 0 : td.amount()] = outs.back().size();
}
else
{
// sort the subsection, so any spares are reset in order
std::sort(outs.back().begin(), outs.back().end(), [](const get_outs_entry &a, const get_outs_entry &b) { return std::get<0>(a) < std::get<0>(b); });
}
base += requested_outputs_count;
}
THROW_WALLET_EXCEPTION_IF(!scanty_outs.empty(), error::not_enough_outs_to_mix, scanty_outs, fake_outputs_count);
}
else
{
for (size_t idx: selected_transfers)
{
const transfer_details &td = m_transfers[idx];
std::vector<get_outs_entry> v;
const rct::key mask = td.is_rct() ? rct::commit(td.amount(), td.m_mask) : rct::zeroCommit(td.amount());
v.push_back(std::make_tuple(td.m_global_output_index, td.get_public_key(), mask));
outs.push_back(v);
}
}
// save those outs in the ringdb for reuse
for (size_t i = 0; i < selected_transfers.size(); ++i)
{
const size_t idx = selected_transfers[i];
THROW_WALLET_EXCEPTION_IF(idx >= m_transfers.size(), error::wallet_internal_error, "selected_transfers entry out of range");
const transfer_details &td = m_transfers[idx];
std::vector<uint64_t> ring;
ring.reserve(outs[i].size());
for (const auto &e: outs[i])
ring.push_back(std::get<0>(e));
if (!set_ring(td.m_key_image, ring, false))
MERROR("Failed to set ring for " << td.m_key_image);
}
}
template<typename T>
void wallet2::transfer_selected(const std::vector<cryptonote::tx_destination_entry>& dsts, const std::vector<size_t>& selected_transfers, size_t fake_outputs_count,
std::vector<std::vector<tools::wallet2::get_outs_entry>> &outs,
uint64_t unlock_time, uint64_t fee, const std::vector<uint8_t>& extra, T destination_split_strategy, const tx_dust_policy& dust_policy, cryptonote::transaction& tx, pending_tx &ptx)
{
using namespace cryptonote;
// throw if attempting a transaction with no destinations
THROW_WALLET_EXCEPTION_IF(dsts.empty(), error::zero_destination);
THROW_WALLET_EXCEPTION_IF(m_multisig, error::wallet_internal_error, "Multisig wallets cannot spend non rct outputs");
uint64_t upper_transaction_weight_limit = get_upper_transaction_weight_limit();
uint64_t needed_money = fee;
LOG_PRINT_L2("transfer: starting with fee " << print_money (needed_money));
// calculate total amount being sent to all destinations
// throw if total amount overflows uint64_t
for(auto& dt: dsts)
{
THROW_WALLET_EXCEPTION_IF(0 == dt.amount, error::zero_destination);
needed_money += dt.amount;
LOG_PRINT_L2("transfer: adding " << print_money(dt.amount) << ", for a total of " << print_money (needed_money));
THROW_WALLET_EXCEPTION_IF(needed_money < dt.amount, error::tx_sum_overflow, dsts, fee, m_nettype);
}
uint64_t found_money = 0;
for(size_t idx: selected_transfers)
{
found_money += m_transfers[idx].amount();
}
LOG_PRINT_L2("wanted " << print_money(needed_money) << ", found " << print_money(found_money) << ", fee " << print_money(fee));
THROW_WALLET_EXCEPTION_IF(found_money < needed_money, error::not_enough_unlocked_money, found_money, needed_money - fee, fee);
uint32_t subaddr_account = m_transfers[*selected_transfers.begin()].m_subaddr_index.major;
for (auto i = ++selected_transfers.begin(); i != selected_transfers.end(); ++i)
THROW_WALLET_EXCEPTION_IF(subaddr_account != m_transfers[*i].m_subaddr_index.major, error::wallet_internal_error, "the tx uses funds from multiple accounts");
if (outs.empty())
get_outs(outs, selected_transfers, fake_outputs_count); // may throw
//prepare inputs
LOG_PRINT_L2("preparing outputs");
typedef cryptonote::tx_source_entry::output_entry tx_output_entry;
size_t i = 0, out_index = 0;
std::vector<cryptonote::tx_source_entry> sources;
for(size_t idx: selected_transfers)
{
sources.resize(sources.size()+1);
cryptonote::tx_source_entry& src = sources.back();
const transfer_details& td = m_transfers[idx];
src.amount = td.amount();
src.rct = td.is_rct();
//paste keys (fake and real)
for (size_t n = 0; n < fake_outputs_count + 1; ++n)
{
tx_output_entry oe;
oe.first = std::get<0>(outs[out_index][n]);
oe.second.dest = rct::pk2rct(std::get<1>(outs[out_index][n]));
oe.second.mask = std::get<2>(outs[out_index][n]);
src.outputs.push_back(oe);
++i;
}
//paste real transaction to the random index
auto it_to_replace = std::find_if(src.outputs.begin(), src.outputs.end(), [&](const tx_output_entry& a)
{
return a.first == td.m_global_output_index;
});
THROW_WALLET_EXCEPTION_IF(it_to_replace == src.outputs.end(), error::wallet_internal_error,
"real output not found");
tx_output_entry real_oe;
real_oe.first = td.m_global_output_index;
real_oe.second.dest = rct::pk2rct(boost::get<txout_to_key>(td.m_tx.vout[td.m_internal_output_index].target).key);
real_oe.second.mask = rct::commit(td.amount(), td.m_mask);
*it_to_replace = real_oe;
src.real_out_tx_key = get_tx_pub_key_from_extra(td.m_tx, td.m_pk_index);
src.real_out_additional_tx_keys = get_additional_tx_pub_keys_from_extra(td.m_tx);
src.real_output = it_to_replace - src.outputs.begin();
src.real_output_in_tx_index = td.m_internal_output_index;
src.multisig_kLRki = rct::multisig_kLRki({rct::zero(), rct::zero(), rct::zero(), rct::zero()});
detail::print_source_entry(src);
++out_index;
}
LOG_PRINT_L2("outputs prepared");
cryptonote::tx_destination_entry change_dts = AUTO_VAL_INIT(change_dts);
if (needed_money < found_money)
{
change_dts.addr = get_subaddress({subaddr_account, 0});
change_dts.amount = found_money - needed_money;
}
std::vector<cryptonote::tx_destination_entry> splitted_dsts, dust_dsts;
uint64_t dust = 0;
destination_split_strategy(dsts, change_dts, dust_policy.dust_threshold, splitted_dsts, dust_dsts);
for(auto& d: dust_dsts) {
THROW_WALLET_EXCEPTION_IF(dust_policy.dust_threshold < d.amount, error::wallet_internal_error, "invalid dust value: dust = " +
std::to_string(d.amount) + ", dust_threshold = " + std::to_string(dust_policy.dust_threshold));
}
for(auto& d: dust_dsts) {
if (!dust_policy.add_to_fee)
splitted_dsts.push_back(cryptonote::tx_destination_entry(d.amount, dust_policy.addr_for_dust, d.is_subaddress));
dust += d.amount;
}
crypto::secret_key tx_key;
std::vector<crypto::secret_key> additional_tx_keys;
rct::multisig_out msout;
LOG_PRINT_L2("constructing tx");
bool r = cryptonote::construct_tx_and_get_tx_key(m_account.get_keys(), m_subaddresses, sources, splitted_dsts, change_dts.addr, extra, tx, unlock_time, tx_key, additional_tx_keys, false, rct::RangeProofBulletproof, m_multisig ? &msout : NULL);
LOG_PRINT_L2("constructed tx, r="<<r);
THROW_WALLET_EXCEPTION_IF(!r, error::tx_not_constructed, sources, splitted_dsts, unlock_time, m_nettype);
THROW_WALLET_EXCEPTION_IF(upper_transaction_weight_limit <= get_transaction_weight(tx), error::tx_too_big, tx, upper_transaction_weight_limit);
std::string key_images;
bool all_are_txin_to_key = std::all_of(tx.vin.begin(), tx.vin.end(), [&](const txin_v& s_e) -> bool
{
CHECKED_GET_SPECIFIC_VARIANT(s_e, const txin_to_key, in, false);
key_images += boost::to_string(in.k_image) + " ";
return true;
});
THROW_WALLET_EXCEPTION_IF(!all_are_txin_to_key, error::unexpected_txin_type, tx);
bool dust_sent_elsewhere = (dust_policy.addr_for_dust.m_view_public_key != change_dts.addr.m_view_public_key
|| dust_policy.addr_for_dust.m_spend_public_key != change_dts.addr.m_spend_public_key);
if (dust_policy.add_to_fee || dust_sent_elsewhere) change_dts.amount -= dust;
ptx.key_images = key_images;
ptx.fee = (dust_policy.add_to_fee ? fee+dust : fee);
ptx.dust = ((dust_policy.add_to_fee || dust_sent_elsewhere) ? dust : 0);
ptx.dust_added_to_fee = dust_policy.add_to_fee;
ptx.tx = tx;
ptx.change_dts = change_dts;
ptx.selected_transfers = selected_transfers;
ptx.tx_key = tx_key;
ptx.additional_tx_keys = additional_tx_keys;
ptx.dests = dsts;
ptx.construction_data.sources = sources;
ptx.construction_data.change_dts = change_dts;
ptx.construction_data.splitted_dsts = splitted_dsts;
ptx.construction_data.selected_transfers = selected_transfers;
ptx.construction_data.extra = tx.extra;
ptx.construction_data.unlock_time = unlock_time;
ptx.construction_data.use_rct = false;
ptx.construction_data.use_bulletproofs = false;
ptx.construction_data.dests = dsts;
// record which subaddress indices are being used as inputs
ptx.construction_data.subaddr_account = subaddr_account;
ptx.construction_data.subaddr_indices.clear();
for (size_t idx: selected_transfers)
ptx.construction_data.subaddr_indices.insert(m_transfers[idx].m_subaddr_index.minor);
LOG_PRINT_L2("transfer_selected done");
}
void wallet2::transfer_selected_rct(std::vector<cryptonote::tx_destination_entry> dsts, const std::vector<size_t>& selected_transfers, size_t fake_outputs_count,
std::vector<std::vector<tools::wallet2::get_outs_entry>> &outs,
uint64_t unlock_time, uint64_t fee, const std::vector<uint8_t>& extra, cryptonote::transaction& tx, pending_tx &ptx, rct::RangeProofType range_proof_type)
{
using namespace cryptonote;
// throw if attempting a transaction with no destinations
THROW_WALLET_EXCEPTION_IF(dsts.empty(), error::zero_destination);
uint64_t upper_transaction_weight_limit = get_upper_transaction_weight_limit();
uint64_t needed_money = fee;
LOG_PRINT_L2("transfer_selected_rct: starting with fee " << print_money (needed_money));
LOG_PRINT_L2("selected transfers: " << strjoin(selected_transfers, " "));
// calculate total amount being sent to all destinations
// throw if total amount overflows uint64_t
for(auto& dt: dsts)
{
THROW_WALLET_EXCEPTION_IF(0 == dt.amount, error::zero_destination);
needed_money += dt.amount;
LOG_PRINT_L2("transfer: adding " << print_money(dt.amount) << ", for a total of " << print_money (needed_money));
THROW_WALLET_EXCEPTION_IF(needed_money < dt.amount, error::tx_sum_overflow, dsts, fee, m_nettype);
}
// if this is a multisig wallet, create a list of multisig signers we can use
std::deque<crypto::public_key> multisig_signers;
size_t n_multisig_txes = 0;
if (m_multisig && !m_transfers.empty())
{
const crypto::public_key local_signer = get_multisig_signer_public_key();
size_t n_available_signers = 1;
for (const crypto::public_key &signer: m_multisig_signers)
{
if (signer == local_signer)
continue;
multisig_signers.push_front(signer);
for (const auto &i: m_transfers[0].m_multisig_info)
{
if (i.m_signer == signer)
{
multisig_signers.pop_front();
multisig_signers.push_back(signer);
++n_available_signers;
break;
}
}
}
multisig_signers.push_back(local_signer);
MDEBUG("We can use " << n_available_signers << "/" << m_multisig_signers.size() << " other signers");
THROW_WALLET_EXCEPTION_IF(n_available_signers+1 < m_multisig_threshold, error::multisig_import_needed);
n_multisig_txes = n_available_signers == m_multisig_signers.size() ? m_multisig_threshold : 1;
MDEBUG("We will create " << n_multisig_txes << " txes");
}
uint64_t found_money = 0;
for(size_t idx: selected_transfers)
{
found_money += m_transfers[idx].amount();
}
LOG_PRINT_L2("wanted " << print_money(needed_money) << ", found " << print_money(found_money) << ", fee " << print_money(fee));
THROW_WALLET_EXCEPTION_IF(found_money < needed_money, error::not_enough_unlocked_money, found_money, needed_money - fee, fee);
uint32_t subaddr_account = m_transfers[*selected_transfers.begin()].m_subaddr_index.major;
for (auto i = ++selected_transfers.begin(); i != selected_transfers.end(); ++i)
THROW_WALLET_EXCEPTION_IF(subaddr_account != m_transfers[*i].m_subaddr_index.major, error::wallet_internal_error, "the tx uses funds from multiple accounts");
if (outs.empty())
get_outs(outs, selected_transfers, fake_outputs_count); // may throw
//prepare inputs
LOG_PRINT_L2("preparing outputs");
size_t i = 0, out_index = 0;
std::vector<cryptonote::tx_source_entry> sources;
std::unordered_set<rct::key> used_L;
for(size_t idx: selected_transfers)
{
sources.resize(sources.size()+1);
cryptonote::tx_source_entry& src = sources.back();
const transfer_details& td = m_transfers[idx];
src.amount = td.amount();
src.rct = td.is_rct();
//paste mixin transaction
THROW_WALLET_EXCEPTION_IF(outs.size() < out_index + 1 , error::wallet_internal_error, "outs.size() < out_index + 1");
THROW_WALLET_EXCEPTION_IF(outs[out_index].size() < fake_outputs_count , error::wallet_internal_error, "fake_outputs_count > random outputs found");
typedef cryptonote::tx_source_entry::output_entry tx_output_entry;
for (size_t n = 0; n < fake_outputs_count + 1; ++n)
{
tx_output_entry oe;
oe.first = std::get<0>(outs[out_index][n]);
oe.second.dest = rct::pk2rct(std::get<1>(outs[out_index][n]));
oe.second.mask = std::get<2>(outs[out_index][n]);
src.outputs.push_back(oe);
}
++i;
//paste real transaction to the random index
auto it_to_replace = std::find_if(src.outputs.begin(), src.outputs.end(), [&](const tx_output_entry& a)
{
return a.first == td.m_global_output_index;
});
THROW_WALLET_EXCEPTION_IF(it_to_replace == src.outputs.end(), error::wallet_internal_error,
"real output not found");
tx_output_entry real_oe;
real_oe.first = td.m_global_output_index;
real_oe.second.dest = rct::pk2rct(td.get_public_key());
real_oe.second.mask = rct::commit(td.amount(), td.m_mask);
*it_to_replace = real_oe;
src.real_out_tx_key = get_tx_pub_key_from_extra(td.m_tx, td.m_pk_index);
src.real_out_additional_tx_keys = get_additional_tx_pub_keys_from_extra(td.m_tx);
src.real_output = it_to_replace - src.outputs.begin();
src.real_output_in_tx_index = td.m_internal_output_index;
src.mask = td.m_mask;
if (m_multisig)
{
crypto::public_key ignore = m_multisig_threshold == m_multisig_signers.size() ? crypto::null_pkey : multisig_signers.front();
src.multisig_kLRki = get_multisig_composite_kLRki(idx, ignore, used_L, used_L);
}
else
src.multisig_kLRki = rct::multisig_kLRki({rct::zero(), rct::zero(), rct::zero(), rct::zero()});
detail::print_source_entry(src);
++out_index;
}
LOG_PRINT_L2("outputs prepared");
// we still keep a copy, since we want to keep dsts free of change for user feedback purposes
std::vector<cryptonote::tx_destination_entry> splitted_dsts = dsts;
cryptonote::tx_destination_entry change_dts = AUTO_VAL_INIT(change_dts);
change_dts.amount = found_money - needed_money;
if (change_dts.amount == 0)
{
if (splitted_dsts.size() == 1)
{
// If the change is 0, send it to a random address, to avoid confusing
// the sender with a 0 amount output. We send a 0 amount in order to avoid
// letting the destination be able to work out which of the inputs is the
// real one in our rings
LOG_PRINT_L2("generating dummy address for 0 change");
cryptonote::account_base dummy;
dummy.generate();
change_dts.addr = dummy.get_keys().m_account_address;
LOG_PRINT_L2("generated dummy address for 0 change");
splitted_dsts.push_back(change_dts);
}
}
else
{
change_dts.addr = get_subaddress({subaddr_account, 0});
splitted_dsts.push_back(change_dts);
}
crypto::secret_key tx_key;
std::vector<crypto::secret_key> additional_tx_keys;
rct::multisig_out msout;
LOG_PRINT_L2("constructing tx");
auto sources_copy = sources;
bool r = cryptonote::construct_tx_and_get_tx_key(m_account.get_keys(), m_subaddresses, sources, splitted_dsts, change_dts.addr, extra, tx, unlock_time, tx_key, additional_tx_keys, true, range_proof_type, m_multisig ? &msout : NULL);
LOG_PRINT_L2("constructed tx, r="<<r);
THROW_WALLET_EXCEPTION_IF(!r, error::tx_not_constructed, sources, dsts, unlock_time, m_nettype);
THROW_WALLET_EXCEPTION_IF(upper_transaction_weight_limit <= get_transaction_weight(tx), error::tx_too_big, tx, upper_transaction_weight_limit);
// work out the permutation done on sources
std::vector<size_t> ins_order;
for (size_t n = 0; n < sources.size(); ++n)
{
for (size_t idx = 0; idx < sources_copy.size(); ++idx)
{
THROW_WALLET_EXCEPTION_IF((size_t)sources_copy[idx].real_output >= sources_copy[idx].outputs.size(),
error::wallet_internal_error, "Invalid real_output");
if (sources_copy[idx].outputs[sources_copy[idx].real_output].second.dest == sources[n].outputs[sources[n].real_output].second.dest)
ins_order.push_back(idx);
}
}
THROW_WALLET_EXCEPTION_IF(ins_order.size() != sources.size(), error::wallet_internal_error, "Failed to work out sources permutation");
std::vector<tools::wallet2::multisig_sig> multisig_sigs;
if (m_multisig)
{
crypto::public_key ignore = m_multisig_threshold == m_multisig_signers.size() ? crypto::null_pkey : multisig_signers.front();
multisig_sigs.push_back({tx.rct_signatures, ignore, used_L, std::unordered_set<crypto::public_key>(), msout});
if (m_multisig_threshold < m_multisig_signers.size())
{
const crypto::hash prefix_hash = cryptonote::get_transaction_prefix_hash(tx);
// create the other versions, one for every other participant (the first one's already done above)
for (size_t signer_index = 1; signer_index < n_multisig_txes; ++signer_index)
{
std::unordered_set<rct::key> new_used_L;
size_t src_idx = 0;
THROW_WALLET_EXCEPTION_IF(selected_transfers.size() != sources.size(), error::wallet_internal_error, "mismatched selected_transfers and sources sixes");
for(size_t idx: selected_transfers)
{
cryptonote::tx_source_entry& src = sources_copy[src_idx];
src.multisig_kLRki = get_multisig_composite_kLRki(idx, multisig_signers[signer_index], used_L, new_used_L);
++src_idx;
}
LOG_PRINT_L2("Creating supplementary multisig transaction");
cryptonote::transaction ms_tx;
auto sources_copy_copy = sources_copy;
bool r = cryptonote::construct_tx_with_tx_key(m_account.get_keys(), m_subaddresses, sources_copy_copy, splitted_dsts, change_dts.addr, extra, ms_tx, unlock_time,tx_key, additional_tx_keys, true, range_proof_type, &msout, false);
LOG_PRINT_L2("constructed tx, r="<<r);
THROW_WALLET_EXCEPTION_IF(!r, error::tx_not_constructed, sources, splitted_dsts, unlock_time, m_nettype);
THROW_WALLET_EXCEPTION_IF(upper_transaction_weight_limit <= get_transaction_weight(tx), error::tx_too_big, tx, upper_transaction_weight_limit);
THROW_WALLET_EXCEPTION_IF(cryptonote::get_transaction_prefix_hash(ms_tx) != prefix_hash, error::wallet_internal_error, "Multisig txes do not share prefix");
multisig_sigs.push_back({ms_tx.rct_signatures, multisig_signers[signer_index], new_used_L, std::unordered_set<crypto::public_key>(), msout});
ms_tx.rct_signatures = tx.rct_signatures;
THROW_WALLET_EXCEPTION_IF(cryptonote::get_transaction_hash(ms_tx) != cryptonote::get_transaction_hash(tx), error::wallet_internal_error, "Multisig txes differ by more than the signatures");
}
}
}
LOG_PRINT_L2("gathering key images");
std::string key_images;
bool all_are_txin_to_key = std::all_of(tx.vin.begin(), tx.vin.end(), [&](const txin_v& s_e) -> bool
{
CHECKED_GET_SPECIFIC_VARIANT(s_e, const txin_to_key, in, false);
key_images += boost::to_string(in.k_image) + " ";
return true;
});
THROW_WALLET_EXCEPTION_IF(!all_are_txin_to_key, error::unexpected_txin_type, tx);
LOG_PRINT_L2("gathered key images");
ptx.key_images = key_images;
ptx.fee = fee;
ptx.dust = 0;
ptx.dust_added_to_fee = false;
ptx.tx = tx;
ptx.change_dts = change_dts;
ptx.selected_transfers = selected_transfers;
tools::apply_permutation(ins_order, ptx.selected_transfers);
ptx.tx_key = tx_key;
ptx.additional_tx_keys = additional_tx_keys;
ptx.dests = dsts;
ptx.multisig_sigs = multisig_sigs;
ptx.construction_data.sources = sources_copy;
ptx.construction_data.change_dts = change_dts;
ptx.construction_data.splitted_dsts = splitted_dsts;
ptx.construction_data.selected_transfers = ptx.selected_transfers;
ptx.construction_data.extra = tx.extra;
ptx.construction_data.unlock_time = unlock_time;
ptx.construction_data.use_rct = true;
ptx.construction_data.use_bulletproofs = !tx.rct_signatures.p.bulletproofs.empty();
ptx.construction_data.dests = dsts;
// record which subaddress indices are being used as inputs
ptx.construction_data.subaddr_account = subaddr_account;
ptx.construction_data.subaddr_indices.clear();
for (size_t idx: selected_transfers)
ptx.construction_data.subaddr_indices.insert(m_transfers[idx].m_subaddr_index.minor);
LOG_PRINT_L2("transfer_selected_rct done");
}
std::vector<size_t> wallet2::pick_preferred_rct_inputs(uint64_t needed_money, uint32_t subaddr_account, const std::set<uint32_t> &subaddr_indices) const
{
std::vector<size_t> picks;
float current_output_relatdness = 1.0f;
LOG_PRINT_L2("pick_preferred_rct_inputs: needed_money " << print_money(needed_money));
// try to find a rct input of enough size
for (size_t i = 0; i < m_transfers.size(); ++i)
{
const transfer_details& td = m_transfers[i];
if (!td.m_spent && td.is_rct() && td.amount() >= needed_money && is_transfer_unlocked(td) && td.m_subaddr_index.major == subaddr_account && subaddr_indices.count(td.m_subaddr_index.minor) == 1)
{
LOG_PRINT_L2("We can use " << i << " alone: " << print_money(td.amount()));
picks.push_back(i);
return picks;
}
}
// then try to find two outputs
// this could be made better by picking one of the outputs to be a small one, since those
// are less useful since often below the needed money, so if one can be used in a pair,
// it gets rid of it for the future
for (size_t i = 0; i < m_transfers.size(); ++i)
{
const transfer_details& td = m_transfers[i];
if (!td.m_spent && !td.m_key_image_partial && td.is_rct() && is_transfer_unlocked(td) && td.m_subaddr_index.major == subaddr_account && subaddr_indices.count(td.m_subaddr_index.minor) == 1)
{
LOG_PRINT_L2("Considering input " << i << ", " << print_money(td.amount()));
for (size_t j = i + 1; j < m_transfers.size(); ++j)
{
const transfer_details& td2 = m_transfers[j];
if (!td2.m_spent && !td.m_key_image_partial && td2.is_rct() && td.amount() + td2.amount() >= needed_money && is_transfer_unlocked(td2) && td2.m_subaddr_index == td.m_subaddr_index)
{
// update our picks if those outputs are less related than any we
// already found. If the same, don't update, and oldest suitable outputs
// will be used in preference.
float relatedness = get_output_relatedness(td, td2);
LOG_PRINT_L2(" with input " << j << ", " << print_money(td2.amount()) << ", relatedness " << relatedness);
if (relatedness < current_output_relatdness)
{
// reset the current picks with those, and return them directly
// if they're unrelated. If they are related, we'll end up returning
// them if we find nothing better
picks.clear();
picks.push_back(i);
picks.push_back(j);
LOG_PRINT_L0("we could use " << i << " and " << j);
if (relatedness == 0.0f)
return picks;
current_output_relatdness = relatedness;
}
}
}
}
}
return picks;
}
bool wallet2::should_pick_a_second_output(bool use_rct, size_t n_transfers, const std::vector<size_t> &unused_transfers_indices, const std::vector<size_t> &unused_dust_indices) const
{
if (!use_rct)
return false;
if (n_transfers > 1)
return false;
if (unused_dust_indices.empty() && unused_transfers_indices.empty())
return false;
// we want at least one free rct output to avoid a corner case where
// we'd choose a non rct output which doesn't have enough "siblings"
// value-wise on the chain, and thus can't be mixed
bool found = false;
for (auto i: unused_dust_indices)
{
if (m_transfers[i].is_rct())
{
found = true;
break;
}
}
if (!found) for (auto i: unused_transfers_indices)
{
if (m_transfers[i].is_rct())
{
found = true;
break;
}
}
if (!found)
return false;
return true;
}
std::vector<size_t> wallet2::get_only_rct(const std::vector<size_t> &unused_dust_indices, const std::vector<size_t> &unused_transfers_indices) const
{
std::vector<size_t> indices;
for (size_t n: unused_dust_indices)
if (m_transfers[n].is_rct())
indices.push_back(n);
for (size_t n: unused_transfers_indices)
if (m_transfers[n].is_rct())
indices.push_back(n);
return indices;
}
static uint32_t get_count_above(const std::vector<wallet2::transfer_details> &transfers, const std::vector<size_t> &indices, uint64_t threshold)
{
uint32_t count = 0;
for (size_t idx: indices)
if (transfers[idx].amount() >= threshold)
++count;
return count;
}
bool wallet2::light_wallet_login(bool &new_address)
{
MDEBUG("Light wallet login request");
m_light_wallet_connected = false;
cryptonote::COMMAND_RPC_LOGIN::request request;
cryptonote::COMMAND_RPC_LOGIN::response response;
request.address = get_account().get_public_address_str(m_nettype);
request.view_key = string_tools::pod_to_hex(get_account().get_keys().m_view_secret_key);
// Always create account if it doesn't exist.
request.create_account = true;
m_daemon_rpc_mutex.lock();
bool connected = epee::net_utils::invoke_http_json("/login", request, response, m_http_client, rpc_timeout, "POST");
m_daemon_rpc_mutex.unlock();
// MyMonero doesn't send any status message. OpenMonero does.
m_light_wallet_connected = connected && (response.status.empty() || response.status == "success");
new_address = response.new_address;
MDEBUG("Status: " << response.status);
MDEBUG("Reason: " << response.reason);
MDEBUG("New wallet: " << response.new_address);
if(m_light_wallet_connected)
{
// Clear old data on successful login.
// m_transfers.clear();
// m_payments.clear();
// m_unconfirmed_payments.clear();
}
return m_light_wallet_connected;
}
bool wallet2::light_wallet_import_wallet_request(cryptonote::COMMAND_RPC_IMPORT_WALLET_REQUEST::response &response)
{
MDEBUG("Light wallet import wallet request");
cryptonote::COMMAND_RPC_IMPORT_WALLET_REQUEST::request oreq;
oreq.address = get_account().get_public_address_str(m_nettype);
oreq.view_key = string_tools::pod_to_hex(get_account().get_keys().m_view_secret_key);
m_daemon_rpc_mutex.lock();
bool r = epee::net_utils::invoke_http_json("/import_wallet_request", oreq, response, m_http_client, rpc_timeout, "POST");
m_daemon_rpc_mutex.unlock();
THROW_WALLET_EXCEPTION_IF(!r, error::no_connection_to_daemon, "import_wallet_request");
return true;
}
void wallet2::light_wallet_get_unspent_outs()
{
MDEBUG("Getting unspent outs");
cryptonote::COMMAND_RPC_GET_UNSPENT_OUTS::request oreq;
cryptonote::COMMAND_RPC_GET_UNSPENT_OUTS::response ores;
oreq.amount = "0";
oreq.address = get_account().get_public_address_str(m_nettype);
oreq.view_key = string_tools::pod_to_hex(get_account().get_keys().m_view_secret_key);
// openMonero specific
oreq.dust_threshold = boost::lexical_cast<std::string>(::config::DEFAULT_DUST_THRESHOLD);
// below are required by openMonero api - but are not used.
oreq.mixin = 0;
oreq.use_dust = true;
m_daemon_rpc_mutex.lock();
bool r = epee::net_utils::invoke_http_json("/get_unspent_outs", oreq, ores, m_http_client, rpc_timeout, "POST");
m_daemon_rpc_mutex.unlock();
THROW_WALLET_EXCEPTION_IF(!r, error::no_connection_to_daemon, "get_unspent_outs");
THROW_WALLET_EXCEPTION_IF(ores.status == "error", error::wallet_internal_error, ores.reason);
m_light_wallet_per_kb_fee = ores.per_kb_fee;
std::unordered_map<crypto::hash,bool> transfers_txs;
for(const auto &t: m_transfers)
transfers_txs.emplace(t.m_txid,t.m_spent);
MDEBUG("FOUND " << ores.outputs.size() <<" outputs");
// return if no outputs found
if(ores.outputs.empty())
return;
// Clear old outputs
m_transfers.clear();
for (const auto &o: ores.outputs) {
bool spent = false;
bool add_transfer = true;
crypto::key_image unspent_key_image;
crypto::public_key tx_public_key = AUTO_VAL_INIT(tx_public_key);
THROW_WALLET_EXCEPTION_IF(string_tools::validate_hex(64, o.tx_pub_key), error::wallet_internal_error, "Invalid tx_pub_key field");
string_tools::hex_to_pod(o.tx_pub_key, tx_public_key);
for (const std::string &ski: o.spend_key_images) {
spent = false;
// Check if key image is ours
THROW_WALLET_EXCEPTION_IF(string_tools::validate_hex(64, ski), error::wallet_internal_error, "Invalid key image");
string_tools::hex_to_pod(ski, unspent_key_image);
if(light_wallet_key_image_is_ours(unspent_key_image, tx_public_key, o.index)){
MTRACE("Output " << o.public_key << " is spent. Key image: " << ski);
spent = true;
break;
} {
MTRACE("Unspent output found. " << o.public_key);
}
}
// Check if tx already exists in m_transfers.
crypto::hash txid;
crypto::public_key tx_pub_key;
crypto::public_key public_key;
THROW_WALLET_EXCEPTION_IF(string_tools::validate_hex(64, o.tx_hash), error::wallet_internal_error, "Invalid tx_hash field");
THROW_WALLET_EXCEPTION_IF(string_tools::validate_hex(64, o.public_key), error::wallet_internal_error, "Invalid public_key field");
THROW_WALLET_EXCEPTION_IF(string_tools::validate_hex(64, o.tx_pub_key), error::wallet_internal_error, "Invalid tx_pub_key field");
string_tools::hex_to_pod(o.tx_hash, txid);
string_tools::hex_to_pod(o.public_key, public_key);
string_tools::hex_to_pod(o.tx_pub_key, tx_pub_key);
for(auto &t: m_transfers){
if(t.get_public_key() == public_key) {
t.m_spent = spent;
add_transfer = false;
break;
}
}
if(!add_transfer)
continue;
m_transfers.push_back(boost::value_initialized<transfer_details>());
transfer_details& td = m_transfers.back();
td.m_block_height = o.height;
td.m_global_output_index = o.global_index;
td.m_txid = txid;
// Add to extra
add_tx_pub_key_to_extra(td.m_tx, tx_pub_key);
td.m_key_image = unspent_key_image;
td.m_key_image_known = !m_watch_only && !m_multisig;
td.m_key_image_requested = false;
td.m_key_image_partial = m_multisig;
td.m_amount = o.amount;
td.m_pk_index = 0;
td.m_internal_output_index = o.index;
td.m_spent = spent;
tx_out txout;
txout.target = txout_to_key(public_key);
txout.amount = td.m_amount;
td.m_tx.vout.resize(td.m_internal_output_index + 1);
td.m_tx.vout[td.m_internal_output_index] = txout;
// Add unlock time and coinbase bool got from get_address_txs api call
std::unordered_map<crypto::hash,address_tx>::const_iterator found = m_light_wallet_address_txs.find(txid);
THROW_WALLET_EXCEPTION_IF(found == m_light_wallet_address_txs.end(), error::wallet_internal_error, "Lightwallet: tx not found in m_light_wallet_address_txs");
bool miner_tx = found->second.m_coinbase;
td.m_tx.unlock_time = found->second.m_unlock_time;
if (!o.rct.empty())
{
// Coinbase tx's
if(miner_tx)
{
td.m_mask = rct::identity();
}
else
{
// rct txs
// decrypt rct mask, calculate commit hash and compare against blockchain commit hash
rct::key rct_commit;
light_wallet_parse_rct_str(o.rct, tx_pub_key, td.m_internal_output_index, td.m_mask, rct_commit, true);
bool valid_commit = (rct_commit == rct::commit(td.amount(), td.m_mask));
if(!valid_commit)
{
MDEBUG("output index: " << o.global_index);
MDEBUG("mask: " + string_tools::pod_to_hex(td.m_mask));
MDEBUG("calculated commit: " + string_tools::pod_to_hex(rct::commit(td.amount(), td.m_mask)));
MDEBUG("expected commit: " + string_tools::pod_to_hex(rct_commit));
MDEBUG("amount: " << td.amount());
}
THROW_WALLET_EXCEPTION_IF(!valid_commit, error::wallet_internal_error, "Lightwallet: rct commit hash mismatch!");
}
td.m_rct = true;
}
else
{
td.m_mask = rct::identity();
td.m_rct = false;
}
if(!spent)
set_unspent(m_transfers.size()-1);
m_key_images[td.m_key_image] = m_transfers.size()-1;
m_pub_keys[td.get_public_key()] = m_transfers.size()-1;
}
}
bool wallet2::light_wallet_get_address_info(cryptonote::COMMAND_RPC_GET_ADDRESS_INFO::response &response)
{
MTRACE(__FUNCTION__);
cryptonote::COMMAND_RPC_GET_ADDRESS_INFO::request request;
request.address = get_account().get_public_address_str(m_nettype);
request.view_key = string_tools::pod_to_hex(get_account().get_keys().m_view_secret_key);
m_daemon_rpc_mutex.lock();
bool r = epee::net_utils::invoke_http_json("/get_address_info", request, response, m_http_client, rpc_timeout, "POST");
m_daemon_rpc_mutex.unlock();
THROW_WALLET_EXCEPTION_IF(!r, error::no_connection_to_daemon, "get_address_info");
// TODO: Validate result
return true;
}
void wallet2::light_wallet_get_address_txs()
{
MDEBUG("Refreshing light wallet");
cryptonote::COMMAND_RPC_GET_ADDRESS_TXS::request ireq;
cryptonote::COMMAND_RPC_GET_ADDRESS_TXS::response ires;
ireq.address = get_account().get_public_address_str(m_nettype);
ireq.view_key = string_tools::pod_to_hex(get_account().get_keys().m_view_secret_key);
m_daemon_rpc_mutex.lock();
bool r = epee::net_utils::invoke_http_json("/get_address_txs", ireq, ires, m_http_client, rpc_timeout, "POST");
m_daemon_rpc_mutex.unlock();
THROW_WALLET_EXCEPTION_IF(!r, error::no_connection_to_daemon, "get_address_txs");
//OpenMonero sends status=success, Mymonero doesn't.
THROW_WALLET_EXCEPTION_IF((!ires.status.empty() && ires.status != "success"), error::no_connection_to_daemon, "get_address_txs");
// Abort if no transactions
if(ires.transactions.empty())
return;
// Create searchable vectors
std::vector<crypto::hash> payments_txs;
for(const auto &p: m_payments)
payments_txs.push_back(p.second.m_tx_hash);
std::vector<crypto::hash> unconfirmed_payments_txs;
for(const auto &up: m_unconfirmed_payments)
unconfirmed_payments_txs.push_back(up.second.m_pd.m_tx_hash);
// for balance calculation
uint64_t wallet_total_sent = 0;
uint64_t wallet_total_unlocked_sent = 0;
// txs in pool
std::vector<crypto::hash> pool_txs;
for (const auto &t: ires.transactions) {
const uint64_t total_received = t.total_received;
uint64_t total_sent = t.total_sent;
// Check key images - subtract fake outputs from total_sent
for(const auto &so: t.spent_outputs)
{
crypto::public_key tx_public_key;
crypto::key_image key_image;
THROW_WALLET_EXCEPTION_IF(string_tools::validate_hex(64, so.tx_pub_key), error::wallet_internal_error, "Invalid tx_pub_key field");
THROW_WALLET_EXCEPTION_IF(string_tools::validate_hex(64, so.key_image), error::wallet_internal_error, "Invalid key_image field");
string_tools::hex_to_pod(so.tx_pub_key, tx_public_key);
string_tools::hex_to_pod(so.key_image, key_image);
if(!light_wallet_key_image_is_ours(key_image, tx_public_key, so.out_index)) {
THROW_WALLET_EXCEPTION_IF(so.amount > t.total_sent, error::wallet_internal_error, "Lightwallet: total sent is negative!");
total_sent -= so.amount;
}
}
// Do not add tx if empty.
if(total_sent == 0 && total_received == 0)
continue;
crypto::hash payment_id = null_hash;
crypto::hash tx_hash;
THROW_WALLET_EXCEPTION_IF(string_tools::validate_hex(64, t.payment_id), error::wallet_internal_error, "Invalid payment_id field");
THROW_WALLET_EXCEPTION_IF(string_tools::validate_hex(64, t.hash), error::wallet_internal_error, "Invalid hash field");
string_tools::hex_to_pod(t.payment_id, payment_id);
string_tools::hex_to_pod(t.hash, tx_hash);
// lightwallet specific info
bool incoming = (total_received > total_sent);
address_tx address_tx;
address_tx.m_tx_hash = tx_hash;
address_tx.m_incoming = incoming;
address_tx.m_amount = incoming ? total_received - total_sent : total_sent - total_received;
address_tx.m_fee = 0; // TODO
address_tx.m_block_height = t.height;
address_tx.m_unlock_time = t.unlock_time;
address_tx.m_timestamp = t.timestamp;
address_tx.m_coinbase = t.coinbase;
address_tx.m_mempool = t.mempool;
m_light_wallet_address_txs.emplace(tx_hash,address_tx);
// populate data needed for history (m_payments, m_unconfirmed_payments, m_confirmed_txs)
// INCOMING transfers
if(total_received > total_sent) {
payment_details payment;
payment.m_tx_hash = tx_hash;
payment.m_amount = total_received - total_sent;
payment.m_fee = 0; // TODO
payment.m_block_height = t.height;
payment.m_unlock_time = t.unlock_time;
payment.m_timestamp = t.timestamp;
payment.m_coinbase = t.coinbase;
if (t.mempool) {
if (std::find(unconfirmed_payments_txs.begin(), unconfirmed_payments_txs.end(), tx_hash) == unconfirmed_payments_txs.end()) {
pool_txs.push_back(tx_hash);
// assume false as we don't get that info from the light wallet server
crypto::hash payment_id;
THROW_WALLET_EXCEPTION_IF(!epee::string_tools::hex_to_pod(t.payment_id, payment_id),
error::wallet_internal_error, "Failed to parse payment id");
emplace_or_replace(m_unconfirmed_payments, payment_id, pool_payment_details{payment, false});
if (0 != m_callback) {
m_callback->on_lw_unconfirmed_money_received(t.height, payment.m_tx_hash, payment.m_amount);
}
}
} else {
if (std::find(payments_txs.begin(), payments_txs.end(), tx_hash) == payments_txs.end()) {
m_payments.emplace(tx_hash, payment);
if (0 != m_callback) {
m_callback->on_lw_money_received(t.height, payment.m_tx_hash, payment.m_amount);
}
}
}
// Outgoing transfers
} else {
uint64_t amount_sent = total_sent - total_received;
cryptonote::transaction dummy_tx; // not used by light wallet
// increase wallet total sent
wallet_total_sent += total_sent;
if (t.mempool)
{
// Handled by add_unconfirmed_tx in commit_tx
// If sent from another wallet instance we need to add it
if(m_unconfirmed_txs.find(tx_hash) == m_unconfirmed_txs.end())
{
unconfirmed_transfer_details utd;
utd.m_amount_in = amount_sent;
utd.m_amount_out = amount_sent;
utd.m_change = 0;
utd.m_payment_id = payment_id;
utd.m_timestamp = t.timestamp;
utd.m_state = wallet2::unconfirmed_transfer_details::pending;
m_unconfirmed_txs.emplace(tx_hash,utd);
}
}
else
{
// Only add if new
auto confirmed_tx = m_confirmed_txs.find(tx_hash);
if(confirmed_tx == m_confirmed_txs.end()) {
// tx is added to m_unconfirmed_txs - move to confirmed
if(m_unconfirmed_txs.find(tx_hash) != m_unconfirmed_txs.end())
{
process_unconfirmed(tx_hash, dummy_tx, t.height);
}
// Tx sent by another wallet instance
else
{
confirmed_transfer_details ctd;
ctd.m_amount_in = amount_sent;
ctd.m_amount_out = amount_sent;
ctd.m_change = 0;
ctd.m_payment_id = payment_id;
ctd.m_block_height = t.height;
ctd.m_timestamp = t.timestamp;
m_confirmed_txs.emplace(tx_hash,ctd);
}
if (0 != m_callback)
{
m_callback->on_lw_money_spent(t.height, tx_hash, amount_sent);
}
}
// If not new - check the amount and update if necessary.
// when sending a tx to same wallet the receiving amount has to be credited
else
{
if(confirmed_tx->second.m_amount_in != amount_sent || confirmed_tx->second.m_amount_out != amount_sent)
{
MDEBUG("Adjusting amount sent/received for tx: <" + t.hash + ">. Is tx sent to own wallet? " << print_money(amount_sent) << " != " << print_money(confirmed_tx->second.m_amount_in));
confirmed_tx->second.m_amount_in = amount_sent;
confirmed_tx->second.m_amount_out = amount_sent;
confirmed_tx->second.m_change = 0;
}
}
}
}
}
// TODO: purge old unconfirmed_txs
remove_obsolete_pool_txs(pool_txs);
// Calculate wallet balance
m_light_wallet_balance = ires.total_received-wallet_total_sent;
// MyMonero doesn't send unlocked balance
if(ires.total_received_unlocked > 0)
m_light_wallet_unlocked_balance = ires.total_received_unlocked-wallet_total_sent;
else
m_light_wallet_unlocked_balance = m_light_wallet_balance;
}
bool wallet2::light_wallet_parse_rct_str(const std::string& rct_string, const crypto::public_key& tx_pub_key, uint64_t internal_output_index, rct::key& decrypted_mask, rct::key& rct_commit, bool decrypt) const
{
// rct string is empty if output is non RCT
if (rct_string.empty())
return false;
// rct_string is a string with length 64+64+64 (<rct commit> + <encrypted mask> + <rct amount>)
rct::key encrypted_mask;
std::string rct_commit_str = rct_string.substr(0,64);
std::string encrypted_mask_str = rct_string.substr(64,64);
THROW_WALLET_EXCEPTION_IF(string_tools::validate_hex(64, rct_commit_str), error::wallet_internal_error, "Invalid rct commit hash: " + rct_commit_str);
THROW_WALLET_EXCEPTION_IF(string_tools::validate_hex(64, encrypted_mask_str), error::wallet_internal_error, "Invalid rct mask: " + encrypted_mask_str);
string_tools::hex_to_pod(rct_commit_str, rct_commit);
string_tools::hex_to_pod(encrypted_mask_str, encrypted_mask);
if (decrypt) {
// Decrypt the mask
crypto::key_derivation derivation;
bool r = generate_key_derivation(tx_pub_key, get_account().get_keys().m_view_secret_key, derivation);
THROW_WALLET_EXCEPTION_IF(!r, error::wallet_internal_error, "Failed to generate key derivation");
crypto::secret_key scalar;
crypto::derivation_to_scalar(derivation, internal_output_index, scalar);
sc_sub(decrypted_mask.bytes,encrypted_mask.bytes,rct::hash_to_scalar(rct::sk2rct(scalar)).bytes);
}
return true;
}
bool wallet2::light_wallet_key_image_is_ours(const crypto::key_image& key_image, const crypto::public_key& tx_public_key, uint64_t out_index)
{
// Lookup key image from cache
std::map<uint64_t, crypto::key_image> index_keyimage_map;
std::unordered_map<crypto::public_key, std::map<uint64_t, crypto::key_image> >::const_iterator found_pub_key = m_key_image_cache.find(tx_public_key);
if(found_pub_key != m_key_image_cache.end()) {
// pub key found. key image for index cached?
index_keyimage_map = found_pub_key->second;
std::map<uint64_t,crypto::key_image>::const_iterator index_found = index_keyimage_map.find(out_index);
if(index_found != index_keyimage_map.end())
return key_image == index_found->second;
}
// Not in cache - calculate key image
crypto::key_image calculated_key_image;
cryptonote::keypair in_ephemeral;
// Subaddresses aren't supported in mymonero/openmonero yet. Roll out the original scheme:
// compute D = a*R
// compute P = Hs(D || i)*G + B
// compute x = Hs(D || i) + b (and check if P==x*G)
// compute I = x*Hp(P)
const account_keys& ack = get_account().get_keys();
crypto::key_derivation derivation;
bool r = crypto::generate_key_derivation(tx_public_key, ack.m_view_secret_key, derivation);
CHECK_AND_ASSERT_MES(r, false, "failed to generate_key_derivation(" << tx_public_key << ", " << ack.m_view_secret_key << ")");
r = crypto::derive_public_key(derivation, out_index, ack.m_account_address.m_spend_public_key, in_ephemeral.pub);
CHECK_AND_ASSERT_MES(r, false, "failed to derive_public_key (" << derivation << ", " << out_index << ", " << ack.m_account_address.m_spend_public_key << ")");
crypto::derive_secret_key(derivation, out_index, ack.m_spend_secret_key, in_ephemeral.sec);
crypto::public_key out_pkey_test;
r = crypto::secret_key_to_public_key(in_ephemeral.sec, out_pkey_test);
CHECK_AND_ASSERT_MES(r, false, "failed to secret_key_to_public_key(" << in_ephemeral.sec << ")");
CHECK_AND_ASSERT_MES(in_ephemeral.pub == out_pkey_test, false, "derived secret key doesn't match derived public key");
crypto::generate_key_image(in_ephemeral.pub, in_ephemeral.sec, calculated_key_image);
index_keyimage_map.emplace(out_index, calculated_key_image);
m_key_image_cache.emplace(tx_public_key, index_keyimage_map);
return key_image == calculated_key_image;
}
// Another implementation of transaction creation that is hopefully better
// While there is anything left to pay, it goes through random outputs and tries
// to fill the next destination/amount. If it fully fills it, it will use the
// remainder to try to fill the next one as well.
// The tx size if roughly estimated as a linear function of only inputs, and a
// new tx will be created when that size goes above a given fraction of the
// max tx size. At that point, more outputs may be added if the fee cannot be
// satisfied.
// If the next output in the next tx would go to the same destination (ie, we
// cut off at a tx boundary in the middle of paying a given destination), the
// fee will be carved out of the current input if possible, to avoid having to
// add another output just for the fee and getting change.
// This system allows for sending (almost) the entire balance, since it does
// not generate spurious change in all txes, thus decreasing the instantaneous
// usable balance.
std::vector<wallet2::pending_tx> wallet2::create_transactions_2(std::vector<cryptonote::tx_destination_entry> dsts, const size_t fake_outs_count, const uint64_t unlock_time, uint32_t priority, const std::vector<uint8_t>& extra, uint32_t subaddr_account, std::set<uint32_t> subaddr_indices)
{
//ensure device is let in NONE mode in any case
hw::device &hwdev = m_account.get_device();
boost::unique_lock<hw::device> hwdev_lock (hwdev);
hw::reset_mode rst(hwdev);
if(m_light_wallet) {
// Populate m_transfers
light_wallet_get_unspent_outs();
}
std::vector<std::pair<uint32_t, std::vector<size_t>>> unused_transfers_indices_per_subaddr;
std::vector<std::pair<uint32_t, std::vector<size_t>>> unused_dust_indices_per_subaddr;
uint64_t needed_money;
uint64_t accumulated_fee, accumulated_outputs, accumulated_change;
struct TX {
std::vector<size_t> selected_transfers;
std::vector<cryptonote::tx_destination_entry> dsts;
cryptonote::transaction tx;
pending_tx ptx;
size_t weight;
uint64_t needed_fee;
std::vector<std::vector<tools::wallet2::get_outs_entry>> outs;
TX() : weight(0), needed_fee(0) {}
void add(const account_public_address &addr, bool is_subaddress, uint64_t amount, unsigned int original_output_index, bool merge_destinations) {
if (merge_destinations)
{
std::vector<cryptonote::tx_destination_entry>::iterator i;
i = std::find_if(dsts.begin(), dsts.end(), [&](const cryptonote::tx_destination_entry &d) { return !memcmp (&d.addr, &addr, sizeof(addr)); });
if (i == dsts.end())
{
dsts.push_back(tx_destination_entry(0,addr,is_subaddress));
i = dsts.end() - 1;
}
i->amount += amount;
}
else
{
THROW_WALLET_EXCEPTION_IF(original_output_index > dsts.size(), error::wallet_internal_error,
std::string("original_output_index too large: ") + std::to_string(original_output_index) + " > " + std::to_string(dsts.size()));
if (original_output_index == dsts.size())
dsts.push_back(tx_destination_entry(0,addr,is_subaddress));
THROW_WALLET_EXCEPTION_IF(memcmp(&dsts[original_output_index].addr, &addr, sizeof(addr)), error::wallet_internal_error, "Mismatched destination address");
dsts[original_output_index].amount += amount;
}
}
};
std::vector<TX> txes;
bool adding_fee; // true if new outputs go towards fee, rather than destinations
uint64_t needed_fee, available_for_fee = 0;
uint64_t upper_transaction_weight_limit = get_upper_transaction_weight_limit();
const bool use_per_byte_fee = use_fork_rules(HF_VERSION_PER_BYTE_FEE, 0);
const bool use_rct = use_fork_rules(4, 0);
const bool bulletproof = use_fork_rules(get_bulletproof_fork(), 0);
const rct::RangeProofType range_proof_type = bulletproof ? rct::RangeProofPaddedBulletproof : rct::RangeProofBorromean;
const uint64_t base_fee = get_base_fee();
const uint64_t fee_multiplier = get_fee_multiplier(priority, get_fee_algorithm());
const uint64_t fee_quantization_mask = get_fee_quantization_mask();
// throw if attempting a transaction with no destinations
THROW_WALLET_EXCEPTION_IF(dsts.empty(), error::zero_destination);
// calculate total amount being sent to all destinations
// throw if total amount overflows uint64_t
needed_money = 0;
for(auto& dt: dsts)
{
THROW_WALLET_EXCEPTION_IF(0 == dt.amount, error::zero_destination);
needed_money += dt.amount;
LOG_PRINT_L2("transfer: adding " << print_money(dt.amount) << ", for a total of " << print_money (needed_money));
THROW_WALLET_EXCEPTION_IF(needed_money < dt.amount, error::tx_sum_overflow, dsts, 0, m_nettype);
}
// throw if attempting a transaction with no money
THROW_WALLET_EXCEPTION_IF(needed_money == 0, error::zero_destination);
std::map<uint32_t, uint64_t> unlocked_balance_per_subaddr = unlocked_balance_per_subaddress(subaddr_account);
std::map<uint32_t, uint64_t> balance_per_subaddr = balance_per_subaddress(subaddr_account);
if (subaddr_indices.empty()) // "index=<N1>[,<N2>,...]" wasn't specified -> use all the indices with non-zero unlocked balance
{
for (const auto& i : balance_per_subaddr)
subaddr_indices.insert(i.first);
}
// early out if we know we can't make it anyway
// we could also check for being within FEE_PER_KB, but if the fee calculation
// ever changes, this might be missed, so let this go through
const uint64_t min_fee = (fee_multiplier * base_fee * estimate_tx_size(use_rct, 1, fake_outs_count, 2, extra.size(), bulletproof));
uint64_t balance_subtotal = 0;
uint64_t unlocked_balance_subtotal = 0;
for (uint32_t index_minor : subaddr_indices)
{
balance_subtotal += balance_per_subaddr[index_minor];
unlocked_balance_subtotal += unlocked_balance_per_subaddr[index_minor];
}
THROW_WALLET_EXCEPTION_IF(needed_money + min_fee > balance_subtotal, error::not_enough_money,
balance_subtotal, needed_money, 0);
// first check overall balance is enough, then unlocked one, so we throw distinct exceptions
THROW_WALLET_EXCEPTION_IF(needed_money + min_fee > unlocked_balance_subtotal, error::not_enough_unlocked_money,
unlocked_balance_subtotal, needed_money, 0);
for (uint32_t i : subaddr_indices)
LOG_PRINT_L2("Candidate subaddress index for spending: " << i);
// determine threshold for fractional amount
const size_t tx_weight_one_ring = estimate_tx_weight(use_rct, 1, fake_outs_count, 2, 0, bulletproof);
const size_t tx_weight_two_rings = estimate_tx_weight(use_rct, 2, fake_outs_count, 2, 0, bulletproof);
THROW_WALLET_EXCEPTION_IF(tx_weight_one_ring > tx_weight_two_rings, error::wallet_internal_error, "Estimated tx weight with 1 input is larger than with 2 inputs!");
const size_t tx_weight_per_ring = tx_weight_two_rings - tx_weight_one_ring;
const uint64_t fractional_threshold = (fee_multiplier * base_fee * tx_weight_per_ring) / (use_per_byte_fee ? 1 : 1024);
// gather all dust and non-dust outputs belonging to specified subaddresses
size_t num_nondust_outputs = 0;
size_t num_dust_outputs = 0;
for (size_t i = 0; i < m_transfers.size(); ++i)
{
const transfer_details& td = m_transfers[i];
if (m_ignore_fractional_outputs && td.amount() < fractional_threshold)
{
MDEBUG("Ignoring output " << i << " of amount " << print_money(td.amount()) << " which is below threshold " << print_money(fractional_threshold));
continue;
}
if (!td.m_spent && !td.m_key_image_partial && (use_rct ? true : !td.is_rct()) && is_transfer_unlocked(td) && td.m_subaddr_index.major == subaddr_account && subaddr_indices.count(td.m_subaddr_index.minor) == 1)
{
const uint32_t index_minor = td.m_subaddr_index.minor;
auto find_predicate = [&index_minor](const std::pair<uint32_t, std::vector<size_t>>& x) { return x.first == index_minor; };
if ((td.is_rct()) || is_valid_decomposed_amount(td.amount()))
{
auto found = std::find_if(unused_transfers_indices_per_subaddr.begin(), unused_transfers_indices_per_subaddr.end(), find_predicate);
if (found == unused_transfers_indices_per_subaddr.end())
{
unused_transfers_indices_per_subaddr.push_back({index_minor, {i}});
}
else
{
found->second.push_back(i);
}
++num_nondust_outputs;
}
else
{
auto found = std::find_if(unused_dust_indices_per_subaddr.begin(), unused_dust_indices_per_subaddr.end(), find_predicate);
if (found == unused_dust_indices_per_subaddr.end())
{
unused_dust_indices_per_subaddr.push_back({index_minor, {i}});
}
else
{
found->second.push_back(i);
}
++num_dust_outputs;
}
}
}
// sort output indices
{
auto sort_predicate = [&unlocked_balance_per_subaddr] (const std::pair<uint32_t, std::vector<size_t>>& x, const std::pair<uint32_t, std::vector<size_t>>& y)
{
return unlocked_balance_per_subaddr[x.first] > unlocked_balance_per_subaddr[y.first];
};
std::sort(unused_transfers_indices_per_subaddr.begin(), unused_transfers_indices_per_subaddr.end(), sort_predicate);
std::sort(unused_dust_indices_per_subaddr.begin(), unused_dust_indices_per_subaddr.end(), sort_predicate);
}
LOG_PRINT_L2("Starting with " << num_nondust_outputs << " non-dust outputs and " << num_dust_outputs << " dust outputs");
if (unused_dust_indices_per_subaddr.empty() && unused_transfers_indices_per_subaddr.empty())
return std::vector<wallet2::pending_tx>();
// if empty, put dummy entry so that the front can be referenced later in the loop
if (unused_dust_indices_per_subaddr.empty())
unused_dust_indices_per_subaddr.push_back({});
if (unused_transfers_indices_per_subaddr.empty())
unused_transfers_indices_per_subaddr.push_back({});
// start with an empty tx
txes.push_back(TX());
accumulated_fee = 0;
accumulated_outputs = 0;
accumulated_change = 0;
adding_fee = false;
needed_fee = 0;
std::vector<std::vector<tools::wallet2::get_outs_entry>> outs;
// for rct, since we don't see the amounts, we will try to make all transactions
// look the same, with 1 or 2 inputs, and 2 outputs. One input is preferable, as
// this prevents linking to another by provenance analysis, but two is ok if we
// try to pick outputs not from the same block. We will get two outputs, one for
// the destination, and one for change.
LOG_PRINT_L2("checking preferred");
std::vector<size_t> preferred_inputs;
uint64_t rct_outs_needed = 2 * (fake_outs_count + 1);
rct_outs_needed += 100; // some fudge factor since we don't know how many are locked
if (use_rct)
{
// this is used to build a tx that's 1 or 2 inputs, and 2 outputs, which
// will get us a known fee.
uint64_t estimated_fee = estimate_fee(use_per_byte_fee, use_rct, 2, fake_outs_count, 2, extra.size(), bulletproof, base_fee, fee_multiplier, fee_quantization_mask);
preferred_inputs = pick_preferred_rct_inputs(needed_money + estimated_fee, subaddr_account, subaddr_indices);
if (!preferred_inputs.empty())
{
string s;
for (auto i: preferred_inputs) s += boost::lexical_cast<std::string>(i) + " (" + print_money(m_transfers[i].amount()) + ") ";
LOG_PRINT_L1("Found preferred rct inputs for rct tx: " << s);
// bring the list of available outputs stored by the same subaddress index to the front of the list
uint32_t index_minor = m_transfers[preferred_inputs[0]].m_subaddr_index.minor;
for (size_t i = 1; i < unused_transfers_indices_per_subaddr.size(); ++i)
{
if (unused_transfers_indices_per_subaddr[i].first == index_minor)
{
std::swap(unused_transfers_indices_per_subaddr[0], unused_transfers_indices_per_subaddr[i]);
break;
}
}
for (size_t i = 1; i < unused_dust_indices_per_subaddr.size(); ++i)
{
if (unused_dust_indices_per_subaddr[i].first == index_minor)
{
std::swap(unused_dust_indices_per_subaddr[0], unused_dust_indices_per_subaddr[i]);
break;
}
}
}
}
LOG_PRINT_L2("done checking preferred");
// while:
// - we have something to send
// - or we need to gather more fee
// - or we have just one input in that tx, which is rct (to try and make all/most rct txes 2/2)
unsigned int original_output_index = 0;
std::vector<size_t>* unused_transfers_indices = &unused_transfers_indices_per_subaddr[0].second;
std::vector<size_t>* unused_dust_indices = &unused_dust_indices_per_subaddr[0].second;
hwdev.set_mode(hw::device::TRANSACTION_CREATE_FAKE);
while ((!dsts.empty() && dsts[0].amount > 0) || adding_fee || !preferred_inputs.empty() || should_pick_a_second_output(use_rct, txes.back().selected_transfers.size(), *unused_transfers_indices, *unused_dust_indices)) {
TX &tx = txes.back();
LOG_PRINT_L2("Start of loop with " << unused_transfers_indices->size() << " " << unused_dust_indices->size() << ", tx.dsts.size() " << tx.dsts.size());
LOG_PRINT_L2("unused_transfers_indices: " << strjoin(*unused_transfers_indices, " "));
LOG_PRINT_L2("unused_dust_indices: " << strjoin(*unused_dust_indices, " "));
LOG_PRINT_L2("dsts size " << dsts.size() << ", first " << (dsts.empty() ? "-" : cryptonote::print_money(dsts[0].amount)));
LOG_PRINT_L2("adding_fee " << adding_fee << ", use_rct " << use_rct);
// if we need to spend money and don't have any left, we fail
if (unused_dust_indices->empty() && unused_transfers_indices->empty()) {
LOG_PRINT_L2("No more outputs to choose from");
THROW_WALLET_EXCEPTION_IF(1, error::tx_not_possible, unlocked_balance(subaddr_account), needed_money, accumulated_fee + needed_fee);
}
// get a random unspent output and use it to pay part (or all) of the current destination (and maybe next one, etc)
// This could be more clever, but maybe at the cost of making probabilistic inferences easier
size_t idx;
if (!preferred_inputs.empty()) {
idx = pop_back(preferred_inputs);
pop_if_present(*unused_transfers_indices, idx);
pop_if_present(*unused_dust_indices, idx);
} else if ((dsts.empty() || dsts[0].amount == 0) && !adding_fee) {
// the "make rct txes 2/2" case - we pick a small value output to "clean up" the wallet too
std::vector<size_t> indices = get_only_rct(*unused_dust_indices, *unused_transfers_indices);
idx = pop_best_value(indices, tx.selected_transfers, true);
// we might not want to add it if it's a large output and we don't have many left
if (m_transfers[idx].amount() >= m_min_output_value) {
if (get_count_above(m_transfers, *unused_transfers_indices, m_min_output_value) < m_min_output_count) {
LOG_PRINT_L2("Second output was not strictly needed, and we're running out of outputs above " << print_money(m_min_output_value) << ", not adding");
break;
}
}
// since we're trying to add a second output which is not strictly needed,
// we only add it if it's unrelated enough to the first one
float relatedness = get_output_relatedness(m_transfers[idx], m_transfers[tx.selected_transfers.front()]);
if (relatedness > SECOND_OUTPUT_RELATEDNESS_THRESHOLD)
{
LOG_PRINT_L2("Second output was not strictly needed, and relatedness " << relatedness << ", not adding");
break;
}
pop_if_present(*unused_transfers_indices, idx);
pop_if_present(*unused_dust_indices, idx);
} else
idx = pop_best_value(unused_transfers_indices->empty() ? *unused_dust_indices : *unused_transfers_indices, tx.selected_transfers);
const transfer_details &td = m_transfers[idx];
LOG_PRINT_L2("Picking output " << idx << ", amount " << print_money(td.amount()) << ", ki " << td.m_key_image);
// add this output to the list to spend
tx.selected_transfers.push_back(idx);
uint64_t available_amount = td.amount();
accumulated_outputs += available_amount;
// clear any fake outs we'd already gathered, since we'll need a new set
outs.clear();
if (adding_fee)
{
LOG_PRINT_L2("We need more fee, adding it to fee");
available_for_fee += available_amount;
}
else
{
while (!dsts.empty() && dsts[0].amount <= available_amount && estimate_tx_weight(use_rct, tx.selected_transfers.size(), fake_outs_count, tx.dsts.size()+1, extra.size(), bulletproof) < TX_WEIGHT_TARGET(upper_transaction_weight_limit))
{
// we can fully pay that destination
LOG_PRINT_L2("We can fully pay " << get_account_address_as_str(m_nettype, dsts[0].is_subaddress, dsts[0].addr) <<
" for " << print_money(dsts[0].amount));
tx.add(dsts[0].addr, dsts[0].is_subaddress, dsts[0].amount, original_output_index, m_merge_destinations);
available_amount -= dsts[0].amount;
dsts[0].amount = 0;
pop_index(dsts, 0);
++original_output_index;
}
if (available_amount > 0 && !dsts.empty() && estimate_tx_weight(use_rct, tx.selected_transfers.size(), fake_outs_count, tx.dsts.size()+1, extra.size(), bulletproof) < TX_WEIGHT_TARGET(upper_transaction_weight_limit)) {
// we can partially fill that destination
LOG_PRINT_L2("We can partially pay " << get_account_address_as_str(m_nettype, dsts[0].is_subaddress, dsts[0].addr) <<
" for " << print_money(available_amount) << "/" << print_money(dsts[0].amount));
tx.add(dsts[0].addr, dsts[0].is_subaddress, available_amount, original_output_index, m_merge_destinations);
dsts[0].amount -= available_amount;
available_amount = 0;
}
}
// here, check if we need to sent tx and start a new one
LOG_PRINT_L2("Considering whether to create a tx now, " << tx.selected_transfers.size() << " inputs, tx limit "
<< upper_transaction_weight_limit);
bool try_tx = false;
// if we have preferred picks, but haven't yet used all of them, continue
if (preferred_inputs.empty())
{
if (adding_fee)
{
/* might not actually be enough if adding this output bumps size to next kB, but we need to try */
try_tx = available_for_fee >= needed_fee;
}
else
{
const size_t estimated_rct_tx_weight = estimate_tx_weight(use_rct, tx.selected_transfers.size(), fake_outs_count, tx.dsts.size()+1, extra.size(), bulletproof);
try_tx = dsts.empty() || (estimated_rct_tx_weight >= TX_WEIGHT_TARGET(upper_transaction_weight_limit));
}
}
if (try_tx) {
cryptonote::transaction test_tx;
pending_tx test_ptx;
needed_fee = estimate_fee(use_per_byte_fee, use_rct ,tx.selected_transfers.size(), fake_outs_count, tx.dsts.size()+1, extra.size(), bulletproof, base_fee, fee_multiplier, fee_quantization_mask);
uint64_t inputs = 0, outputs = needed_fee;
for (size_t idx: tx.selected_transfers) inputs += m_transfers[idx].amount();
for (const auto &o: tx.dsts) outputs += o.amount;
if (inputs < outputs)
{
LOG_PRINT_L2("We don't have enough for the basic fee, switching to adding_fee");
adding_fee = true;
goto skip_tx;
}
LOG_PRINT_L2("Trying to create a tx now, with " << tx.dsts.size() << " outputs and " <<
tx.selected_transfers.size() << " inputs");
if (use_rct)
transfer_selected_rct(tx.dsts, tx.selected_transfers, fake_outs_count, outs, unlock_time, needed_fee, extra,
test_tx, test_ptx, range_proof_type);
else
transfer_selected(tx.dsts, tx.selected_transfers, fake_outs_count, outs, unlock_time, needed_fee, extra,
detail::digit_split_strategy, tx_dust_policy(::config::DEFAULT_DUST_THRESHOLD), test_tx, test_ptx);
auto txBlob = t_serializable_object_to_blob(test_ptx.tx);
needed_fee = calculate_fee(use_per_byte_fee, test_ptx.tx, txBlob.size(), base_fee, fee_multiplier, fee_quantization_mask);
available_for_fee = test_ptx.fee + test_ptx.change_dts.amount + (!test_ptx.dust_added_to_fee ? test_ptx.dust : 0);
LOG_PRINT_L2("Made a " << get_weight_string(test_ptx.tx, txBlob.size()) << " tx, with " << print_money(available_for_fee) << " available for fee (" <<
print_money(needed_fee) << " needed)");
if (needed_fee > available_for_fee && !dsts.empty() && dsts[0].amount > 0)
{
// we don't have enough for the fee, but we've only partially paid the current address,
// so we can take the fee from the paid amount, since we'll have to make another tx anyway
std::vector<cryptonote::tx_destination_entry>::iterator i;
i = std::find_if(tx.dsts.begin(), tx.dsts.end(),
[&](const cryptonote::tx_destination_entry &d) { return !memcmp (&d.addr, &dsts[0].addr, sizeof(dsts[0].addr)); });
THROW_WALLET_EXCEPTION_IF(i == tx.dsts.end(), error::wallet_internal_error, "paid address not found in outputs");
if (i->amount > needed_fee)
{
uint64_t new_paid_amount = i->amount /*+ test_ptx.fee*/ - needed_fee;
LOG_PRINT_L2("Adjusting amount paid to " << get_account_address_as_str(m_nettype, i->is_subaddress, i->addr) << " from " <<
print_money(i->amount) << " to " << print_money(new_paid_amount) << " to accommodate " <<
print_money(needed_fee) << " fee");
dsts[0].amount += i->amount - new_paid_amount;
i->amount = new_paid_amount;
test_ptx.fee = needed_fee;
available_for_fee = needed_fee;
}
}
if (needed_fee > available_for_fee)
{
LOG_PRINT_L2("We could not make a tx, switching to fee accumulation");
adding_fee = true;
}
else
{
LOG_PRINT_L2("We made a tx, adjusting fee and saving it, we need " << print_money(needed_fee) << " and we have " << print_money(test_ptx.fee));
while (needed_fee > test_ptx.fee) {
if (use_rct)
transfer_selected_rct(tx.dsts, tx.selected_transfers, fake_outs_count, outs, unlock_time, needed_fee, extra,
test_tx, test_ptx, range_proof_type);
else
transfer_selected(tx.dsts, tx.selected_transfers, fake_outs_count, outs, unlock_time, needed_fee, extra,
detail::digit_split_strategy, tx_dust_policy(::config::DEFAULT_DUST_THRESHOLD), test_tx, test_ptx);
txBlob = t_serializable_object_to_blob(test_ptx.tx);
needed_fee = calculate_fee(use_per_byte_fee, test_ptx.tx, txBlob.size(), base_fee, fee_multiplier, fee_quantization_mask);
LOG_PRINT_L2("Made an attempt at a final " << get_weight_string(test_ptx.tx, txBlob.size()) << " tx, with " << print_money(test_ptx.fee) <<
" fee and " << print_money(test_ptx.change_dts.amount) << " change");
}
LOG_PRINT_L2("Made a final " << get_weight_string(test_ptx.tx, txBlob.size()) << " tx, with " << print_money(test_ptx.fee) <<
" fee and " << print_money(test_ptx.change_dts.amount) << " change");
tx.tx = test_tx;
tx.ptx = test_ptx;
tx.weight = get_transaction_weight(test_tx, txBlob.size());
tx.outs = outs;
tx.needed_fee = needed_fee;
accumulated_fee += test_ptx.fee;
accumulated_change += test_ptx.change_dts.amount;
adding_fee = false;
if (!dsts.empty())
{
LOG_PRINT_L2("We have more to pay, starting another tx");
txes.push_back(TX());
original_output_index = 0;
}
}
}
skip_tx:
// if unused_*_indices is empty while unused_*_indices_per_subaddr has multiple elements, and if we still have something to pay,
// pop front of unused_*_indices_per_subaddr and have unused_*_indices point to the front of unused_*_indices_per_subaddr
if ((!dsts.empty() && dsts[0].amount > 0) || adding_fee)
{
if (unused_transfers_indices->empty() && unused_transfers_indices_per_subaddr.size() > 1)
{
unused_transfers_indices_per_subaddr.erase(unused_transfers_indices_per_subaddr.begin());
unused_transfers_indices = &unused_transfers_indices_per_subaddr[0].second;
}
if (unused_dust_indices->empty() && unused_dust_indices_per_subaddr.size() > 1)
{
unused_dust_indices_per_subaddr.erase(unused_dust_indices_per_subaddr.begin());
unused_dust_indices = &unused_dust_indices_per_subaddr[0].second;
}
}
}
if (adding_fee)
{
LOG_PRINT_L1("We ran out of outputs while trying to gather final fee");
THROW_WALLET_EXCEPTION_IF(1, error::tx_not_possible, unlocked_balance(subaddr_account), needed_money, accumulated_fee + needed_fee);
}
LOG_PRINT_L1("Done creating " << txes.size() << " transactions, " << print_money(accumulated_fee) <<
" total fee, " << print_money(accumulated_change) << " total change");
hwdev.set_mode(hw::device::TRANSACTION_CREATE_REAL);
for (std::vector<TX>::iterator i = txes.begin(); i != txes.end(); ++i)
{
TX &tx = *i;
cryptonote::transaction test_tx;
pending_tx test_ptx;
if (use_rct) {
transfer_selected_rct(tx.dsts, /* NOMOD std::vector<cryptonote::tx_destination_entry> dsts,*/
tx.selected_transfers, /* const std::list<size_t> selected_transfers */
fake_outs_count, /* CONST size_t fake_outputs_count, */
tx.outs, /* MOD std::vector<std::vector<tools::wallet2::get_outs_entry>> &outs, */
unlock_time, /* CONST uint64_t unlock_time, */
tx.needed_fee, /* CONST uint64_t fee, */
extra, /* const std::vector<uint8_t>& extra, */
test_tx, /* OUT cryptonote::transaction& tx, */
test_ptx, /* OUT cryptonote::transaction& tx, */
range_proof_type);
} else {
transfer_selected(tx.dsts,
tx.selected_transfers,
fake_outs_count,
tx.outs,
unlock_time,
tx.needed_fee,
extra,
detail::digit_split_strategy,
tx_dust_policy(::config::DEFAULT_DUST_THRESHOLD),
test_tx,
test_ptx);
}
auto txBlob = t_serializable_object_to_blob(test_ptx.tx);
tx.tx = test_tx;
tx.ptx = test_ptx;
tx.weight = get_transaction_weight(test_tx, txBlob.size());
}
std::vector<wallet2::pending_tx> ptx_vector;
for (std::vector<TX>::iterator i = txes.begin(); i != txes.end(); ++i)
{
TX &tx = *i;
uint64_t tx_money = 0;
for (size_t idx: tx.selected_transfers)
tx_money += m_transfers[idx].amount();
LOG_PRINT_L1(" Transaction " << (1+std::distance(txes.begin(), i)) << "/" << txes.size() <<
" " << get_transaction_hash(tx.ptx.tx) << ": " << get_weight_string(tx.weight) << ", sending " << print_money(tx_money) << " in " << tx.selected_transfers.size() <<
" outputs to " << tx.dsts.size() << " destination(s), including " <<
print_money(tx.ptx.fee) << " fee, " << print_money(tx.ptx.change_dts.amount) << " change");
ptx_vector.push_back(tx.ptx);
}
// if we made it this far, we're OK to actually send the transactions
return ptx_vector;
}
std::vector<wallet2::pending_tx> wallet2::create_transactions_all(uint64_t below, const cryptonote::account_public_address &address, bool is_subaddress, const size_t outputs, const size_t fake_outs_count, const uint64_t unlock_time, uint32_t priority, const std::vector<uint8_t>& extra, uint32_t subaddr_account, std::set<uint32_t> subaddr_indices)
{
std::vector<size_t> unused_transfers_indices;
std::vector<size_t> unused_dust_indices;
const bool use_rct = use_fork_rules(4, 0);
THROW_WALLET_EXCEPTION_IF(unlocked_balance(subaddr_account) == 0, error::wallet_internal_error, "No unlocked balance in the entire wallet");
std::map<uint32_t, std::pair<std::vector<size_t>, std::vector<size_t>>> unused_transfer_dust_indices_per_subaddr;
// gather all dust and non-dust outputs of specified subaddress (if any) and below specified threshold (if any)
bool fund_found = false;
for (size_t i = 0; i < m_transfers.size(); ++i)
{
const transfer_details& td = m_transfers[i];
if (!td.m_spent && !td.m_key_image_partial && (use_rct ? true : !td.is_rct()) && is_transfer_unlocked(td) && td.m_subaddr_index.major == subaddr_account && (subaddr_indices.empty() || subaddr_indices.count(td.m_subaddr_index.minor) == 1))
{
fund_found = true;
if (below == 0 || td.amount() < below)
{
if ((td.is_rct()) || is_valid_decomposed_amount(td.amount()))
unused_transfer_dust_indices_per_subaddr[td.m_subaddr_index.minor].first.push_back(i);
else
unused_transfer_dust_indices_per_subaddr[td.m_subaddr_index.minor].second.push_back(i);
}
}
}
THROW_WALLET_EXCEPTION_IF(!fund_found, error::wallet_internal_error, "No unlocked balance in the specified subaddress(es)");
THROW_WALLET_EXCEPTION_IF(unused_transfer_dust_indices_per_subaddr.empty(), error::wallet_internal_error, "The smallest amount found is not below the specified threshold");
if (subaddr_indices.empty())
{
// in case subaddress index wasn't specified, choose non-empty subaddress randomly (with index=0 being chosen last)
if (unused_transfer_dust_indices_per_subaddr.count(0) == 1 && unused_transfer_dust_indices_per_subaddr.size() > 1)
unused_transfer_dust_indices_per_subaddr.erase(0);
auto i = unused_transfer_dust_indices_per_subaddr.begin();
std::advance(i, crypto::rand<size_t>() % unused_transfer_dust_indices_per_subaddr.size());
unused_transfers_indices = i->second.first;
unused_dust_indices = i->second.second;
LOG_PRINT_L2("Spending from subaddress index " << i->first);
}
else
{
for (const auto& p : unused_transfer_dust_indices_per_subaddr)
{
unused_transfers_indices.insert(unused_transfers_indices.end(), p.second.first.begin(), p.second.first.end());
unused_dust_indices.insert(unused_dust_indices.end(), p.second.second.begin(), p.second.second.end());
LOG_PRINT_L2("Spending from subaddress index " << p.first);
}
}
return create_transactions_from(address, is_subaddress, outputs, unused_transfers_indices, unused_dust_indices, fake_outs_count, unlock_time, priority, extra);
}
std::vector<wallet2::pending_tx> wallet2::create_transactions_single(const crypto::key_image &ki, const cryptonote::account_public_address &address, bool is_subaddress, const size_t outputs, const size_t fake_outs_count, const uint64_t unlock_time, uint32_t priority, const std::vector<uint8_t>& extra)
{
std::vector<size_t> unused_transfers_indices;
std::vector<size_t> unused_dust_indices;
const bool use_rct = use_fork_rules(4, 0);
// find output with the given key image
for (size_t i = 0; i < m_transfers.size(); ++i)
{
const transfer_details& td = m_transfers[i];
if (td.m_key_image_known && td.m_key_image == ki && !td.m_spent && (use_rct ? true : !td.is_rct()) && is_transfer_unlocked(td))
{
if (td.is_rct() || is_valid_decomposed_amount(td.amount()))
unused_transfers_indices.push_back(i);
else
unused_dust_indices.push_back(i);
break;
}
}
return create_transactions_from(address, is_subaddress, outputs, unused_transfers_indices, unused_dust_indices, fake_outs_count, unlock_time, priority, extra);
}
std::vector<wallet2::pending_tx> wallet2::create_transactions_from(const cryptonote::account_public_address &address, bool is_subaddress, const size_t outputs, std::vector<size_t> unused_transfers_indices, std::vector<size_t> unused_dust_indices, const size_t fake_outs_count, const uint64_t unlock_time, uint32_t priority, const std::vector<uint8_t>& extra)
{
//ensure device is let in NONE mode in any case
hw::device &hwdev = m_account.get_device();
boost::unique_lock<hw::device> hwdev_lock (hwdev);
hw::reset_mode rst(hwdev);
uint64_t accumulated_fee, accumulated_outputs, accumulated_change;
struct TX {
std::vector<size_t> selected_transfers;
std::vector<cryptonote::tx_destination_entry> dsts;
cryptonote::transaction tx;
pending_tx ptx;
size_t weight;
uint64_t needed_fee;
std::vector<std::vector<get_outs_entry>> outs;
TX() : weight(0), needed_fee(0) {}
};
std::vector<TX> txes;
uint64_t needed_fee, available_for_fee = 0;
uint64_t upper_transaction_weight_limit = get_upper_transaction_weight_limit();
std::vector<std::vector<get_outs_entry>> outs;
const bool use_per_byte_fee = use_fork_rules(HF_VERSION_PER_BYTE_FEE);
const bool use_rct = fake_outs_count > 0 && use_fork_rules(4, 0);
const bool bulletproof = use_fork_rules(get_bulletproof_fork(), 0);
const rct::RangeProofType range_proof_type = bulletproof ? rct::RangeProofPaddedBulletproof : rct::RangeProofBorromean;
const uint64_t base_fee = get_base_fee();
const uint64_t fee_multiplier = get_fee_multiplier(priority, get_fee_algorithm());
const uint64_t fee_quantization_mask = get_fee_quantization_mask();
LOG_PRINT_L2("Starting with " << unused_transfers_indices.size() << " non-dust outputs and " << unused_dust_indices.size() << " dust outputs");
if (unused_dust_indices.empty() && unused_transfers_indices.empty())
return std::vector<wallet2::pending_tx>();
// start with an empty tx
txes.push_back(TX());
accumulated_fee = 0;
accumulated_outputs = 0;
accumulated_change = 0;
needed_fee = 0;
// while we have something to send
hwdev.set_mode(hw::device::TRANSACTION_CREATE_FAKE);
while (!unused_dust_indices.empty() || !unused_transfers_indices.empty()) {
TX &tx = txes.back();
// get a random unspent output and use it to pay next chunk. We try to alternate
// dust and non dust to ensure we never get with only dust, from which we might
// get a tx that can't pay for itself
uint64_t fee_dust_threshold;
if (use_fork_rules(HF_VERSION_PER_BYTE_FEE))
{
const uint64_t estimated_tx_weight_with_one_extra_output = estimate_tx_weight(use_rct, tx.selected_transfers.size() + 1, fake_outs_count, tx.dsts.size()+1, extra.size(), bulletproof);
fee_dust_threshold = calculate_fee_from_weight(base_fee, estimated_tx_weight_with_one_extra_output, fee_multiplier, fee_quantization_mask);
}
else
{
fee_dust_threshold = base_fee * fee_multiplier * (upper_transaction_weight_limit + 1023) / 1024;
}
size_t idx =
unused_transfers_indices.empty()
? pop_best_value(unused_dust_indices, tx.selected_transfers)
: unused_dust_indices.empty()
? pop_best_value(unused_transfers_indices, tx.selected_transfers)
: ((tx.selected_transfers.size() & 1) || accumulated_outputs > fee_dust_threshold)
? pop_best_value(unused_dust_indices, tx.selected_transfers)
: pop_best_value(unused_transfers_indices, tx.selected_transfers);
const transfer_details &td = m_transfers[idx];
LOG_PRINT_L2("Picking output " << idx << ", amount " << print_money(td.amount()));
// add this output to the list to spend
tx.selected_transfers.push_back(idx);
uint64_t available_amount = td.amount();
accumulated_outputs += available_amount;
// clear any fake outs we'd already gathered, since we'll need a new set
outs.clear();
// here, check if we need to sent tx and start a new one
LOG_PRINT_L2("Considering whether to create a tx now, " << tx.selected_transfers.size() << " inputs, tx limit "
<< upper_transaction_weight_limit);
const size_t estimated_rct_tx_weight = estimate_tx_weight(use_rct, tx.selected_transfers.size(), fake_outs_count, tx.dsts.size() + 2, extra.size(), bulletproof);
bool try_tx = (unused_dust_indices.empty() && unused_transfers_indices.empty()) || ( estimated_rct_tx_weight >= TX_WEIGHT_TARGET(upper_transaction_weight_limit));
if (try_tx) {
cryptonote::transaction test_tx;
pending_tx test_ptx;
needed_fee = estimate_fee(use_per_byte_fee, use_rct, tx.selected_transfers.size(), fake_outs_count, tx.dsts.size()+1, extra.size(), bulletproof, base_fee, fee_multiplier, fee_quantization_mask);
// add N - 1 outputs for correct initial fee estimation
for (size_t i = 0; i < ((outputs > 1) ? outputs - 1 : outputs); ++i)
tx.dsts.push_back(tx_destination_entry(1, address, is_subaddress));
LOG_PRINT_L2("Trying to create a tx now, with " << tx.dsts.size() << " destinations and " <<
tx.selected_transfers.size() << " outputs");
if (use_rct)
transfer_selected_rct(tx.dsts, tx.selected_transfers, fake_outs_count, outs, unlock_time, needed_fee, extra,
test_tx, test_ptx, range_proof_type);
else
transfer_selected(tx.dsts, tx.selected_transfers, fake_outs_count, outs, unlock_time, needed_fee, extra,
detail::digit_split_strategy, tx_dust_policy(::config::DEFAULT_DUST_THRESHOLD), test_tx, test_ptx);
auto txBlob = t_serializable_object_to_blob(test_ptx.tx);
needed_fee = calculate_fee(use_per_byte_fee, test_ptx.tx, txBlob.size(), base_fee, fee_multiplier, fee_quantization_mask);
available_for_fee = test_ptx.fee + test_ptx.change_dts.amount;
for (auto &dt: test_ptx.dests)
available_for_fee += dt.amount;
LOG_PRINT_L2("Made a " << get_weight_string(test_ptx.tx, txBlob.size()) << " tx, with " << print_money(available_for_fee) << " available for fee (" <<
print_money(needed_fee) << " needed)");
// add last output, missed for fee estimation
if (outputs > 1)
tx.dsts.push_back(tx_destination_entry(1, address, is_subaddress));
THROW_WALLET_EXCEPTION_IF(needed_fee > available_for_fee, error::wallet_internal_error, "Transaction cannot pay for itself");
do {
LOG_PRINT_L2("We made a tx, adjusting fee and saving it");
// distribute total transferred amount between outputs
uint64_t amount_transferred = available_for_fee - needed_fee;
uint64_t dt_amount = amount_transferred / outputs;
// residue is distributed as one atomic unit per output until it reaches zero
uint64_t residue = amount_transferred % outputs;
for (auto &dt: tx.dsts)
{
uint64_t dt_residue = 0;
if (residue > 0)
{
dt_residue = 1;
residue -= 1;
}
dt.amount = dt_amount + dt_residue;
}
if (use_rct)
transfer_selected_rct(tx.dsts, tx.selected_transfers, fake_outs_count, outs, unlock_time, needed_fee, extra,
test_tx, test_ptx, range_proof_type);
else
transfer_selected(tx.dsts, tx.selected_transfers, fake_outs_count, outs, unlock_time, needed_fee, extra,
detail::digit_split_strategy, tx_dust_policy(::config::DEFAULT_DUST_THRESHOLD), test_tx, test_ptx);
txBlob = t_serializable_object_to_blob(test_ptx.tx);
needed_fee = calculate_fee(use_per_byte_fee, test_ptx.tx, txBlob.size(), base_fee, fee_multiplier, fee_quantization_mask);
LOG_PRINT_L2("Made an attempt at a final " << get_weight_string(test_ptx.tx, txBlob.size()) << " tx, with " << print_money(test_ptx.fee) <<
" fee and " << print_money(test_ptx.change_dts.amount) << " change");
} while (needed_fee > test_ptx.fee);
LOG_PRINT_L2("Made a final " << get_weight_string(test_ptx.tx, txBlob.size()) << " tx, with " << print_money(test_ptx.fee) <<
" fee and " << print_money(test_ptx.change_dts.amount) << " change");
tx.tx = test_tx;
tx.ptx = test_ptx;
tx.weight = get_transaction_weight(test_tx, txBlob.size());
tx.outs = outs;
tx.needed_fee = needed_fee;
accumulated_fee += test_ptx.fee;
accumulated_change += test_ptx.change_dts.amount;
if (!unused_transfers_indices.empty() || !unused_dust_indices.empty())
{
LOG_PRINT_L2("We have more to pay, starting another tx");
txes.push_back(TX());
}
}
}
LOG_PRINT_L1("Done creating " << txes.size() << " transactions, " << print_money(accumulated_fee) <<
" total fee, " << print_money(accumulated_change) << " total change");
hwdev.set_mode(hw::device::TRANSACTION_CREATE_REAL);
for (std::vector<TX>::iterator i = txes.begin(); i != txes.end(); ++i)
{
TX &tx = *i;
cryptonote::transaction test_tx;
pending_tx test_ptx;
if (use_rct) {
transfer_selected_rct(tx.dsts, tx.selected_transfers, fake_outs_count, tx.outs, unlock_time, tx.needed_fee, extra,
test_tx, test_ptx, range_proof_type);
} else {
transfer_selected(tx.dsts, tx.selected_transfers, fake_outs_count, tx.outs, unlock_time, tx.needed_fee, extra,
detail::digit_split_strategy, tx_dust_policy(::config::DEFAULT_DUST_THRESHOLD), test_tx, test_ptx);
}
auto txBlob = t_serializable_object_to_blob(test_ptx.tx);
tx.tx = test_tx;
tx.ptx = test_ptx;
tx.weight = get_transaction_weight(test_tx, txBlob.size());
}
std::vector<wallet2::pending_tx> ptx_vector;
for (std::vector<TX>::iterator i = txes.begin(); i != txes.end(); ++i)
{
TX &tx = *i;
uint64_t tx_money = 0;
for (size_t idx: tx.selected_transfers)
tx_money += m_transfers[idx].amount();
LOG_PRINT_L1(" Transaction " << (1+std::distance(txes.begin(), i)) << "/" << txes.size() <<
" " << get_transaction_hash(tx.ptx.tx) << ": " << get_weight_string(tx.weight) << ", sending " << print_money(tx_money) << " in " << tx.selected_transfers.size() <<
" outputs to " << tx.dsts.size() << " destination(s), including " <<
print_money(tx.ptx.fee) << " fee, " << print_money(tx.ptx.change_dts.amount) << " change");
ptx_vector.push_back(tx.ptx);
}
// if we made it this far, we're OK to actually send the transactions
return ptx_vector;
}
//----------------------------------------------------------------------------------------------------
void wallet2::cold_tx_aux_import(const std::vector<pending_tx> & ptx, const std::vector<std::string> & tx_device_aux)
{
CHECK_AND_ASSERT_THROW_MES(ptx.size() == tx_device_aux.size(), "TX aux has invalid size");
for (size_t i = 0; i < ptx.size(); ++i){
crypto::hash txid;
txid = get_transaction_hash(ptx[i].tx);
set_tx_device_aux(txid, tx_device_aux[i]);
}
}
//----------------------------------------------------------------------------------------------------
void wallet2::cold_sign_tx(const std::vector<pending_tx>& ptx_vector, signed_tx_set &exported_txs, std::vector<cryptonote::address_parse_info> &dsts_info, std::vector<std::string> & tx_device_aux)
{
auto & hwdev = get_account().get_device();
if (!hwdev.has_tx_cold_sign()){
throw std::invalid_argument("Device does not support cold sign protocol");
}
unsigned_tx_set txs;
for (auto &tx: ptx_vector)
{
txs.txes.push_back(get_construction_data_with_decrypted_short_payment_id(tx, m_account.get_device()));
}
txs.transfers = std::make_pair(0, m_transfers);
auto dev_cold = dynamic_cast<::hw::device_cold*>(&hwdev);
CHECK_AND_ASSERT_THROW_MES(dev_cold, "Device does not implement cold signing interface");
hw::tx_aux_data aux_data;
hw::wallet_shim wallet_shim;
setup_shim(&wallet_shim, this);
aux_data.tx_recipients = dsts_info;
dev_cold->tx_sign(&wallet_shim, txs, exported_txs, aux_data);
tx_device_aux = aux_data.tx_device_aux;
MDEBUG("Signed tx data from hw: " << exported_txs.ptx.size() << " transactions");
for (auto &c_ptx: exported_txs.ptx) LOG_PRINT_L0(cryptonote::obj_to_json_str(c_ptx.tx));
}
//----------------------------------------------------------------------------------------------------
uint64_t wallet2::cold_key_image_sync(uint64_t &spent, uint64_t &unspent) {
auto & hwdev = get_account().get_device();
if (!hwdev.has_ki_cold_sync()){
throw std::invalid_argument("Device does not support cold ki sync protocol");
}
auto dev_cold = dynamic_cast<::hw::device_cold*>(&hwdev);
CHECK_AND_ASSERT_THROW_MES(dev_cold, "Device does not implement cold signing interface");
std::vector<std::pair<crypto::key_image, crypto::signature>> ski;
hw::wallet_shim wallet_shim;
setup_shim(&wallet_shim, this);
dev_cold->ki_sync(&wallet_shim, m_transfers, ski);
return import_key_images(ski, 0, spent, unspent);
}
//----------------------------------------------------------------------------------------------------
void wallet2::get_hard_fork_info(uint8_t version, uint64_t &earliest_height) const
{
boost::optional<std::string> result = m_node_rpc_proxy.get_earliest_height(version, earliest_height);
throw_on_rpc_response_error(result, "get_hard_fork_info");
}
//----------------------------------------------------------------------------------------------------
bool wallet2::use_fork_rules(uint8_t version, int64_t early_blocks) const
{
// TODO: How to get fork rule info from light wallet node?
if(m_light_wallet)
return true;
uint64_t height, earliest_height;
boost::optional<std::string> result = m_node_rpc_proxy.get_height(height);
throw_on_rpc_response_error(result, "get_info");
result = m_node_rpc_proxy.get_earliest_height(version, earliest_height);
throw_on_rpc_response_error(result, "get_hard_fork_info");
bool close_enough = height >= earliest_height - early_blocks; // start using the rules that many blocks beforehand
if (close_enough)
LOG_PRINT_L2("Using v" << (unsigned)version << " rules");
else
LOG_PRINT_L2("Not using v" << (unsigned)version << " rules");
return close_enough;
}
//----------------------------------------------------------------------------------------------------
uint64_t wallet2::get_upper_transaction_weight_limit() const
{
if (m_upper_transaction_weight_limit > 0)
return m_upper_transaction_weight_limit;
uint64_t full_reward_zone = use_fork_rules(5, 10) ? CRYPTONOTE_BLOCK_GRANTED_FULL_REWARD_ZONE_V5 : use_fork_rules(2, 10) ? CRYPTONOTE_BLOCK_GRANTED_FULL_REWARD_ZONE_V2 : CRYPTONOTE_BLOCK_GRANTED_FULL_REWARD_ZONE_V1;
if (use_fork_rules(8, 10))
return full_reward_zone / 2 - CRYPTONOTE_COINBASE_BLOB_RESERVED_SIZE;
else
return full_reward_zone - CRYPTONOTE_COINBASE_BLOB_RESERVED_SIZE;
}
//----------------------------------------------------------------------------------------------------
std::vector<size_t> wallet2::select_available_outputs(const std::function<bool(const transfer_details &td)> &f) const
{
std::vector<size_t> outputs;
size_t n = 0;
for (transfer_container::const_iterator i = m_transfers.begin(); i != m_transfers.end(); ++i, ++n)
{
if (i->m_spent)
continue;
if (i->m_key_image_partial)
continue;
if (!is_transfer_unlocked(*i))
continue;
if (f(*i))
outputs.push_back(n);
}
return outputs;
}
//----------------------------------------------------------------------------------------------------
std::vector<uint64_t> wallet2::get_unspent_amounts_vector() const
{
std::set<uint64_t> set;
for (const auto &td: m_transfers)
{
if (!td.m_spent)
set.insert(td.is_rct() ? 0 : td.amount());
}
std::vector<uint64_t> vector;
vector.reserve(set.size());
for (const auto &i: set)
{
vector.push_back(i);
}
return vector;
}
//----------------------------------------------------------------------------------------------------
std::vector<size_t> wallet2::select_available_outputs_from_histogram(uint64_t count, bool atleast, bool unlocked, bool allow_rct)
{
cryptonote::COMMAND_RPC_GET_OUTPUT_HISTOGRAM::request req_t = AUTO_VAL_INIT(req_t);
cryptonote::COMMAND_RPC_GET_OUTPUT_HISTOGRAM::response resp_t = AUTO_VAL_INIT(resp_t);
m_daemon_rpc_mutex.lock();
if (is_trusted_daemon())
req_t.amounts = get_unspent_amounts_vector();
req_t.min_count = count;
req_t.max_count = 0;
req_t.unlocked = unlocked;
req_t.recent_cutoff = 0;
bool r = net_utils::invoke_http_json_rpc("/json_rpc", "get_output_histogram", req_t, resp_t, m_http_client, rpc_timeout);
m_daemon_rpc_mutex.unlock();
THROW_WALLET_EXCEPTION_IF(!r, error::no_connection_to_daemon, "select_available_outputs_from_histogram");
THROW_WALLET_EXCEPTION_IF(resp_t.status == CORE_RPC_STATUS_BUSY, error::daemon_busy, "get_output_histogram");
THROW_WALLET_EXCEPTION_IF(resp_t.status != CORE_RPC_STATUS_OK, error::get_histogram_error, resp_t.status);
std::set<uint64_t> mixable;
for (const auto &i: resp_t.histogram)
{
mixable.insert(i.amount);
}
return select_available_outputs([mixable, atleast, allow_rct](const transfer_details &td) {
if (!allow_rct && td.is_rct())
return false;
const uint64_t amount = td.is_rct() ? 0 : td.amount();
if (atleast) {
if (mixable.find(amount) != mixable.end())
return true;
}
else {
if (mixable.find(amount) == mixable.end())
return true;
}
return false;
});
}
//----------------------------------------------------------------------------------------------------
uint64_t wallet2::get_num_rct_outputs()
{
cryptonote::COMMAND_RPC_GET_OUTPUT_HISTOGRAM::request req_t = AUTO_VAL_INIT(req_t);
cryptonote::COMMAND_RPC_GET_OUTPUT_HISTOGRAM::response resp_t = AUTO_VAL_INIT(resp_t);
m_daemon_rpc_mutex.lock();
req_t.amounts.push_back(0);
req_t.min_count = 0;
req_t.max_count = 0;
req_t.unlocked = true;
req_t.recent_cutoff = 0;
bool r = net_utils::invoke_http_json_rpc("/json_rpc", "get_output_histogram", req_t, resp_t, m_http_client, rpc_timeout);
m_daemon_rpc_mutex.unlock();
THROW_WALLET_EXCEPTION_IF(!r, error::no_connection_to_daemon, "get_num_rct_outputs");
THROW_WALLET_EXCEPTION_IF(resp_t.status == CORE_RPC_STATUS_BUSY, error::daemon_busy, "get_output_histogram");
THROW_WALLET_EXCEPTION_IF(resp_t.status != CORE_RPC_STATUS_OK, error::get_histogram_error, resp_t.status);
THROW_WALLET_EXCEPTION_IF(resp_t.histogram.size() != 1, error::get_histogram_error, "Expected exactly one response");
THROW_WALLET_EXCEPTION_IF(resp_t.histogram[0].amount != 0, error::get_histogram_error, "Expected 0 amount");
return resp_t.histogram[0].total_instances;
}
//----------------------------------------------------------------------------------------------------
const wallet2::transfer_details &wallet2::get_transfer_details(size_t idx) const
{
THROW_WALLET_EXCEPTION_IF(idx >= m_transfers.size(), error::wallet_internal_error, "Bad transfer index");
return m_transfers[idx];
}
//----------------------------------------------------------------------------------------------------
std::vector<size_t> wallet2::select_available_unmixable_outputs()
{
// request all outputs with less instances than the min ring size
return select_available_outputs_from_histogram(get_min_ring_size(), false, true, false);
}
//----------------------------------------------------------------------------------------------------
std::vector<size_t> wallet2::select_available_mixable_outputs()
{
// request all outputs with at least as many instances as the min ring size
return select_available_outputs_from_histogram(get_min_ring_size(), true, true, true);
}
//----------------------------------------------------------------------------------------------------
std::vector<wallet2::pending_tx> wallet2::create_unmixable_sweep_transactions()
{
// From hard fork 1, we don't consider small amounts to be dust anymore
const bool hf1_rules = use_fork_rules(2, 10); // first hard fork has version 2
tx_dust_policy dust_policy(hf1_rules ? 0 : ::config::DEFAULT_DUST_THRESHOLD);
const uint64_t base_fee = get_base_fee();
// may throw
std::vector<size_t> unmixable_outputs = select_available_unmixable_outputs();
size_t num_dust_outputs = unmixable_outputs.size();
if (num_dust_outputs == 0)
{
return std::vector<wallet2::pending_tx>();
}
// split in "dust" and "non dust" to make it easier to select outputs
std::vector<size_t> unmixable_transfer_outputs, unmixable_dust_outputs;
for (auto n: unmixable_outputs)
{
if (m_transfers[n].amount() < base_fee)
unmixable_dust_outputs.push_back(n);
else
unmixable_transfer_outputs.push_back(n);
}
return create_transactions_from(m_account_public_address, false, 1, unmixable_transfer_outputs, unmixable_dust_outputs, 0 /*fake_outs_count */, 0 /* unlock_time */, 1 /*priority */, std::vector<uint8_t>());
}
//----------------------------------------------------------------------------------------------------
void wallet2::discard_unmixable_outputs()
{
// may throw
std::vector<size_t> unmixable_outputs = select_available_unmixable_outputs();
for (size_t idx : unmixable_outputs)
{
m_transfers[idx].m_spent = true;
}
}
bool wallet2::get_tx_key(const crypto::hash &txid, crypto::secret_key &tx_key, std::vector<crypto::secret_key> &additional_tx_keys) const
{
additional_tx_keys.clear();
const std::unordered_map<crypto::hash, crypto::secret_key>::const_iterator i = m_tx_keys.find(txid);
if (i == m_tx_keys.end())
return false;
tx_key = i->second;
const auto j = m_additional_tx_keys.find(txid);
if (j != m_additional_tx_keys.end())
additional_tx_keys = j->second;
return true;
}
//----------------------------------------------------------------------------------------------------
void wallet2::set_tx_key(const crypto::hash &txid, const crypto::secret_key &tx_key, const std::vector<crypto::secret_key> &additional_tx_keys)
{
// fetch tx from daemon and check if secret keys agree with corresponding public keys
COMMAND_RPC_GET_TRANSACTIONS::request req = AUTO_VAL_INIT(req);
req.txs_hashes.push_back(epee::string_tools::pod_to_hex(txid));
req.decode_as_json = false;
req.prune = false;
COMMAND_RPC_GET_TRANSACTIONS::response res = AUTO_VAL_INIT(res);
bool r;
{
const boost::lock_guard<boost::mutex> lock{m_daemon_rpc_mutex};
r = epee::net_utils::invoke_http_json("/gettransactions", req, res, m_http_client, rpc_timeout);
}
THROW_WALLET_EXCEPTION_IF(!r, error::no_connection_to_daemon, "gettransactions");
THROW_WALLET_EXCEPTION_IF(res.status == CORE_RPC_STATUS_BUSY, error::daemon_busy, "gettransactions");
THROW_WALLET_EXCEPTION_IF(res.status != CORE_RPC_STATUS_OK, error::wallet_internal_error, "gettransactions");
THROW_WALLET_EXCEPTION_IF(res.txs.size() != 1, error::wallet_internal_error,
"daemon returned wrong response for gettransactions, wrong txs count = " +
std::to_string(res.txs.size()) + ", expected 1");
cryptonote::blobdata bd;
THROW_WALLET_EXCEPTION_IF(!epee::string_tools::parse_hexstr_to_binbuff(res.txs[0].as_hex, bd), error::wallet_internal_error, "failed to parse tx from hexstr");
cryptonote::transaction tx;
crypto::hash tx_hash, tx_prefix_hash;
THROW_WALLET_EXCEPTION_IF(!cryptonote::parse_and_validate_tx_from_blob(bd, tx, tx_hash, tx_prefix_hash), error::wallet_internal_error, "failed to parse tx from blob");
THROW_WALLET_EXCEPTION_IF(tx_hash != txid, error::wallet_internal_error, "txid mismatch");
std::vector<tx_extra_field> tx_extra_fields;
THROW_WALLET_EXCEPTION_IF(!parse_tx_extra(tx.extra, tx_extra_fields), error::wallet_internal_error, "Transaction extra has unsupported format");
tx_extra_pub_key pub_key_field;
bool found = false;
size_t index = 0;
while (find_tx_extra_field_by_type(tx_extra_fields, pub_key_field, index++))
{
crypto::public_key calculated_pub_key;
crypto::secret_key_to_public_key(tx_key, calculated_pub_key);
if (calculated_pub_key == pub_key_field.pub_key)
{
found = true;
break;
}
}
THROW_WALLET_EXCEPTION_IF(!found, error::wallet_internal_error, "Given tx secret key doesn't agree with the tx public key in the blockchain");
tx_extra_additional_pub_keys additional_tx_pub_keys;
find_tx_extra_field_by_type(tx_extra_fields, additional_tx_pub_keys);
THROW_WALLET_EXCEPTION_IF(additional_tx_keys.size() != additional_tx_pub_keys.data.size(), error::wallet_internal_error, "The number of additional tx secret keys doesn't agree with the number of additional tx public keys in the blockchain" );
m_tx_keys.insert(std::make_pair(txid, tx_key));
m_additional_tx_keys.insert(std::make_pair(txid, additional_tx_keys));
}
//----------------------------------------------------------------------------------------------------
std::string wallet2::get_spend_proof(const crypto::hash &txid, const std::string &message)
{
THROW_WALLET_EXCEPTION_IF(m_watch_only, error::wallet_internal_error,
"get_spend_proof requires spend secret key and is not available for a watch-only wallet");
// fetch tx from daemon
COMMAND_RPC_GET_TRANSACTIONS::request req = AUTO_VAL_INIT(req);
req.txs_hashes.push_back(epee::string_tools::pod_to_hex(txid));
req.decode_as_json = false;
req.prune = false;
COMMAND_RPC_GET_TRANSACTIONS::response res = AUTO_VAL_INIT(res);
bool r;
{
const boost::lock_guard<boost::mutex> lock{m_daemon_rpc_mutex};
r = epee::net_utils::invoke_http_json("/gettransactions", req, res, m_http_client, rpc_timeout);
}
THROW_WALLET_EXCEPTION_IF(!r, error::no_connection_to_daemon, "gettransactions");
THROW_WALLET_EXCEPTION_IF(res.status == CORE_RPC_STATUS_BUSY, error::daemon_busy, "gettransactions");
THROW_WALLET_EXCEPTION_IF(res.status != CORE_RPC_STATUS_OK, error::wallet_internal_error, "gettransactions");
THROW_WALLET_EXCEPTION_IF(res.txs.size() != 1, error::wallet_internal_error,
"daemon returned wrong response for gettransactions, wrong txs count = " +
std::to_string(res.txs.size()) + ", expected 1");
cryptonote::blobdata bd;
THROW_WALLET_EXCEPTION_IF(!epee::string_tools::parse_hexstr_to_binbuff(res.txs[0].as_hex, bd), error::wallet_internal_error, "failed to parse tx from hexstr");
cryptonote::transaction tx;
crypto::hash tx_hash, tx_prefix_hash;
THROW_WALLET_EXCEPTION_IF(!cryptonote::parse_and_validate_tx_from_blob(bd, tx, tx_hash, tx_prefix_hash), error::wallet_internal_error, "failed to parse tx from blob");
THROW_WALLET_EXCEPTION_IF(tx_hash != txid, error::wallet_internal_error, "txid mismatch");
std::vector<std::vector<crypto::signature>> signatures;
// get signature prefix hash
std::string sig_prefix_data((const char*)&txid, sizeof(crypto::hash));
sig_prefix_data += message;
crypto::hash sig_prefix_hash;
crypto::cn_fast_hash(sig_prefix_data.data(), sig_prefix_data.size(), sig_prefix_hash);
for(size_t i = 0; i < tx.vin.size(); ++i)
{
const txin_to_key* const in_key = boost::get<txin_to_key>(std::addressof(tx.vin[i]));
if (in_key == nullptr)
continue;
// check if the key image belongs to us
const auto found = m_key_images.find(in_key->k_image);
if(found == m_key_images.end())
{
THROW_WALLET_EXCEPTION_IF(i > 0, error::wallet_internal_error, "subset of key images belong to us, very weird!");
THROW_WALLET_EXCEPTION_IF(true, error::wallet_internal_error, "This tx wasn't generated by this wallet!");
}
// derive the real output keypair
const transfer_details& in_td = m_transfers[found->second];
const txout_to_key* const in_tx_out_pkey = boost::get<txout_to_key>(std::addressof(in_td.m_tx.vout[in_td.m_internal_output_index].target));
THROW_WALLET_EXCEPTION_IF(in_tx_out_pkey == nullptr, error::wallet_internal_error, "Output is not txout_to_key");
const crypto::public_key in_tx_pub_key = get_tx_pub_key_from_extra(in_td.m_tx, in_td.m_pk_index);
const std::vector<crypto::public_key> in_additionakl_tx_pub_keys = get_additional_tx_pub_keys_from_extra(in_td.m_tx);
keypair in_ephemeral;
crypto::key_image in_img;
THROW_WALLET_EXCEPTION_IF(!generate_key_image_helper(m_account.get_keys(), m_subaddresses, in_tx_out_pkey->key, in_tx_pub_key, in_additionakl_tx_pub_keys, in_td.m_internal_output_index, in_ephemeral, in_img, m_account.get_device()),
error::wallet_internal_error, "failed to generate key image");
THROW_WALLET_EXCEPTION_IF(in_key->k_image != in_img, error::wallet_internal_error, "key image mismatch");
// get output pubkeys in the ring
const std::vector<uint64_t> absolute_offsets = cryptonote::relative_output_offsets_to_absolute(in_key->key_offsets);
const size_t ring_size = in_key->key_offsets.size();
THROW_WALLET_EXCEPTION_IF(absolute_offsets.size() != ring_size, error::wallet_internal_error, "absolute offsets size is wrong");
COMMAND_RPC_GET_OUTPUTS_BIN::request req = AUTO_VAL_INIT(req);
req.outputs.resize(ring_size);
for (size_t j = 0; j < ring_size; ++j)
{
req.outputs[j].amount = in_key->amount;
req.outputs[j].index = absolute_offsets[j];
}
COMMAND_RPC_GET_OUTPUTS_BIN::response res = AUTO_VAL_INIT(res);
bool r;
{
const boost::lock_guard<boost::mutex> lock{m_daemon_rpc_mutex};
r = epee::net_utils::invoke_http_bin("/get_outs.bin", req, res, m_http_client, rpc_timeout);
}
THROW_WALLET_EXCEPTION_IF(!r, error::no_connection_to_daemon, "get_outs.bin");
THROW_WALLET_EXCEPTION_IF(res.status == CORE_RPC_STATUS_BUSY, error::daemon_busy, "get_outs.bin");
THROW_WALLET_EXCEPTION_IF(res.status != CORE_RPC_STATUS_OK, error::wallet_internal_error, "get_outs.bin");
THROW_WALLET_EXCEPTION_IF(res.outs.size() != ring_size, error::wallet_internal_error,
"daemon returned wrong response for get_outs.bin, wrong amounts count = " +
std::to_string(res.outs.size()) + ", expected " + std::to_string(ring_size));
// copy pubkey pointers
std::vector<const crypto::public_key *> p_output_keys;
for (const COMMAND_RPC_GET_OUTPUTS_BIN::outkey &out : res.outs)
p_output_keys.push_back(&out.key);
// figure out real output index and secret key
size_t sec_index = -1;
for (size_t j = 0; j < ring_size; ++j)
{
if (res.outs[j].key == in_ephemeral.pub)
{
sec_index = j;
break;
}
}
THROW_WALLET_EXCEPTION_IF(sec_index >= ring_size, error::wallet_internal_error, "secret index not found");
// generate ring sig for this input
signatures.push_back(std::vector<crypto::signature>());
std::vector<crypto::signature>& sigs = signatures.back();
sigs.resize(in_key->key_offsets.size());
crypto::generate_ring_signature(sig_prefix_hash, in_key->k_image, p_output_keys, in_ephemeral.sec, sec_index, sigs.data());
}
std::string sig_str = "SpendProofV1";
for (const std::vector<crypto::signature>& ring_sig : signatures)
for (const crypto::signature& sig : ring_sig)
sig_str += tools::base58::encode(std::string((const char *)&sig, sizeof(crypto::signature)));
return sig_str;
}
//----------------------------------------------------------------------------------------------------
bool wallet2::check_spend_proof(const crypto::hash &txid, const std::string &message, const std::string &sig_str)
{
const std::string header = "SpendProofV1";
const size_t header_len = header.size();
THROW_WALLET_EXCEPTION_IF(sig_str.size() < header_len || sig_str.substr(0, header_len) != header, error::wallet_internal_error,
"Signature header check error");
// fetch tx from daemon
COMMAND_RPC_GET_TRANSACTIONS::request req = AUTO_VAL_INIT(req);
req.txs_hashes.push_back(epee::string_tools::pod_to_hex(txid));
req.decode_as_json = false;
req.prune = false;
COMMAND_RPC_GET_TRANSACTIONS::response res = AUTO_VAL_INIT(res);
bool r;
{
const boost::lock_guard<boost::mutex> lock{m_daemon_rpc_mutex};
r = epee::net_utils::invoke_http_json("/gettransactions", req, res, m_http_client, rpc_timeout);
}
THROW_WALLET_EXCEPTION_IF(!r, error::no_connection_to_daemon, "gettransactions");
THROW_WALLET_EXCEPTION_IF(res.status == CORE_RPC_STATUS_BUSY, error::daemon_busy, "gettransactions");
THROW_WALLET_EXCEPTION_IF(res.status != CORE_RPC_STATUS_OK, error::wallet_internal_error, "gettransactions");
THROW_WALLET_EXCEPTION_IF(res.txs.size() != 1, error::wallet_internal_error,
"daemon returned wrong response for gettransactions, wrong txs count = " +
std::to_string(res.txs.size()) + ", expected 1");
cryptonote::blobdata bd;
THROW_WALLET_EXCEPTION_IF(!epee::string_tools::parse_hexstr_to_binbuff(res.txs[0].as_hex, bd), error::wallet_internal_error, "failed to parse tx from hexstr");
cryptonote::transaction tx;
crypto::hash tx_hash, tx_prefix_hash;
THROW_WALLET_EXCEPTION_IF(!cryptonote::parse_and_validate_tx_from_blob(bd, tx, tx_hash, tx_prefix_hash), error::wallet_internal_error, "failed to parse tx from blob");
THROW_WALLET_EXCEPTION_IF(tx_hash != txid, error::wallet_internal_error, "txid mismatch");
// check signature size
size_t num_sigs = 0;
for(size_t i = 0; i < tx.vin.size(); ++i)
{
const txin_to_key* const in_key = boost::get<txin_to_key>(std::addressof(tx.vin[i]));
if (in_key != nullptr)
num_sigs += in_key->key_offsets.size();
}
std::vector<std::vector<crypto::signature>> signatures = { std::vector<crypto::signature>(1) };
const size_t sig_len = tools::base58::encode(std::string((const char *)&signatures[0][0], sizeof(crypto::signature))).size();
if( sig_str.size() != header_len + num_sigs * sig_len ) {
return false;
}
// decode base58
signatures.clear();
size_t offset = header_len;
for(size_t i = 0; i < tx.vin.size(); ++i)
{
const txin_to_key* const in_key = boost::get<txin_to_key>(std::addressof(tx.vin[i]));
if (in_key == nullptr)
continue;
signatures.resize(signatures.size() + 1);
signatures.back().resize(in_key->key_offsets.size());
for (size_t j = 0; j < in_key->key_offsets.size(); ++j)
{
std::string sig_decoded;
THROW_WALLET_EXCEPTION_IF(!tools::base58::decode(sig_str.substr(offset, sig_len), sig_decoded), error::wallet_internal_error, "Signature decoding error");
THROW_WALLET_EXCEPTION_IF(sizeof(crypto::signature) != sig_decoded.size(), error::wallet_internal_error, "Signature decoding error");
memcpy(&signatures.back()[j], sig_decoded.data(), sizeof(crypto::signature));
offset += sig_len;
}
}
// get signature prefix hash
std::string sig_prefix_data((const char*)&txid, sizeof(crypto::hash));
sig_prefix_data += message;
crypto::hash sig_prefix_hash;
crypto::cn_fast_hash(sig_prefix_data.data(), sig_prefix_data.size(), sig_prefix_hash);
std::vector<std::vector<crypto::signature>>::const_iterator sig_iter = signatures.cbegin();
for(size_t i = 0; i < tx.vin.size(); ++i)
{
const txin_to_key* const in_key = boost::get<txin_to_key>(std::addressof(tx.vin[i]));
if (in_key == nullptr)
continue;
// get output pubkeys in the ring
COMMAND_RPC_GET_OUTPUTS_BIN::request req = AUTO_VAL_INIT(req);
const std::vector<uint64_t> absolute_offsets = cryptonote::relative_output_offsets_to_absolute(in_key->key_offsets);
req.outputs.resize(absolute_offsets.size());
for (size_t j = 0; j < absolute_offsets.size(); ++j)
{
req.outputs[j].amount = in_key->amount;
req.outputs[j].index = absolute_offsets[j];
}
COMMAND_RPC_GET_OUTPUTS_BIN::response res = AUTO_VAL_INIT(res);
bool r;
{
const boost::lock_guard<boost::mutex> lock{m_daemon_rpc_mutex};
r = epee::net_utils::invoke_http_bin("/get_outs.bin", req, res, m_http_client, rpc_timeout);
}
THROW_WALLET_EXCEPTION_IF(!r, error::no_connection_to_daemon, "get_outs.bin");
THROW_WALLET_EXCEPTION_IF(res.status == CORE_RPC_STATUS_BUSY, error::daemon_busy, "get_outs.bin");
THROW_WALLET_EXCEPTION_IF(res.status != CORE_RPC_STATUS_OK, error::wallet_internal_error, "get_outs.bin");
THROW_WALLET_EXCEPTION_IF(res.outs.size() != req.outputs.size(), error::wallet_internal_error,
"daemon returned wrong response for get_outs.bin, wrong amounts count = " +
std::to_string(res.outs.size()) + ", expected " + std::to_string(req.outputs.size()));
// copy pointers
std::vector<const crypto::public_key *> p_output_keys;
for (const COMMAND_RPC_GET_OUTPUTS_BIN::outkey &out : res.outs)
p_output_keys.push_back(&out.key);
// check this ring
if (!crypto::check_ring_signature(sig_prefix_hash, in_key->k_image, p_output_keys, sig_iter->data()))
return false;
++sig_iter;
}
THROW_WALLET_EXCEPTION_IF(sig_iter != signatures.cend(), error::wallet_internal_error, "Signature iterator didn't reach the end");
return true;
}
//----------------------------------------------------------------------------------------------------
void wallet2::check_tx_key(const crypto::hash &txid, const crypto::secret_key &tx_key, const std::vector<crypto::secret_key> &additional_tx_keys, const cryptonote::account_public_address &address, uint64_t &received, bool &in_pool, uint64_t &confirmations)
{
crypto::key_derivation derivation;
THROW_WALLET_EXCEPTION_IF(!crypto::generate_key_derivation(address.m_view_public_key, tx_key, derivation), error::wallet_internal_error,
"Failed to generate key derivation from supplied parameters");
std::vector<crypto::key_derivation> additional_derivations;
additional_derivations.resize(additional_tx_keys.size());
for (size_t i = 0; i < additional_tx_keys.size(); ++i)
THROW_WALLET_EXCEPTION_IF(!crypto::generate_key_derivation(address.m_view_public_key, additional_tx_keys[i], additional_derivations[i]), error::wallet_internal_error,
"Failed to generate key derivation from supplied parameters");
check_tx_key_helper(txid, derivation, additional_derivations, address, received, in_pool, confirmations);
}
void wallet2::check_tx_key_helper(const crypto::hash &txid, const crypto::key_derivation &derivation, const std::vector<crypto::key_derivation> &additional_derivations, const cryptonote::account_public_address &address, uint64_t &received, bool &in_pool, uint64_t &confirmations)
{
COMMAND_RPC_GET_TRANSACTIONS::request req;
COMMAND_RPC_GET_TRANSACTIONS::response res;
req.txs_hashes.push_back(epee::string_tools::pod_to_hex(txid));
req.decode_as_json = false;
req.prune = false;
m_daemon_rpc_mutex.lock();
bool ok = epee::net_utils::invoke_http_json("/gettransactions", req, res, m_http_client);
m_daemon_rpc_mutex.unlock();
THROW_WALLET_EXCEPTION_IF(!ok || (res.txs.size() != 1 && res.txs_as_hex.size() != 1),
error::wallet_internal_error, "Failed to get transaction from daemon");
cryptonote::blobdata tx_data;
if (res.txs.size() == 1)
ok = string_tools::parse_hexstr_to_binbuff(res.txs.front().as_hex, tx_data);
else
ok = string_tools::parse_hexstr_to_binbuff(res.txs_as_hex.front(), tx_data);
THROW_WALLET_EXCEPTION_IF(!ok, error::wallet_internal_error, "Failed to parse transaction from daemon");
crypto::hash tx_hash, tx_prefix_hash;
cryptonote::transaction tx;
THROW_WALLET_EXCEPTION_IF(!cryptonote::parse_and_validate_tx_from_blob(tx_data, tx, tx_hash, tx_prefix_hash), error::wallet_internal_error,
"Failed to validate transaction from daemon");
THROW_WALLET_EXCEPTION_IF(tx_hash != txid, error::wallet_internal_error,
"Failed to get the right transaction from daemon");
THROW_WALLET_EXCEPTION_IF(!additional_derivations.empty() && additional_derivations.size() != tx.vout.size(), error::wallet_internal_error,
"The size of additional derivations is wrong");
received = 0;
hw::device &hwdev = m_account.get_device();
for (size_t n = 0; n < tx.vout.size(); ++n)
{
const cryptonote::txout_to_key* const out_key = boost::get<cryptonote::txout_to_key>(std::addressof(tx.vout[n].target));
if (!out_key)
continue;
crypto::public_key derived_out_key;
bool r = hwdev.derive_public_key(derivation, n, address.m_spend_public_key, derived_out_key);
THROW_WALLET_EXCEPTION_IF(!r, error::wallet_internal_error, "Failed to derive public key");
bool found = out_key->key == derived_out_key;
crypto::key_derivation found_derivation = derivation;
if (!found && !additional_derivations.empty())
{
r = hwdev.derive_public_key(additional_derivations[n], n, address.m_spend_public_key, derived_out_key);
THROW_WALLET_EXCEPTION_IF(!r, error::wallet_internal_error, "Failed to derive public key");
found = out_key->key == derived_out_key;
found_derivation = additional_derivations[n];
}
if (found)
{
uint64_t amount;
if (tx.version == 1 || tx.rct_signatures.type == rct::RCTTypeNull)
{
amount = tx.vout[n].amount;
}
else
{
crypto::secret_key scalar1;
hwdev.derivation_to_scalar(found_derivation, n, scalar1);
rct::ecdhTuple ecdh_info = tx.rct_signatures.ecdhInfo[n];
hwdev.ecdhDecode(ecdh_info, rct::sk2rct(scalar1));
const rct::key C = tx.rct_signatures.outPk[n].mask;
rct::key Ctmp;
THROW_WALLET_EXCEPTION_IF(sc_check(ecdh_info.mask.bytes) != 0, error::wallet_internal_error, "Bad ECDH input mask");
THROW_WALLET_EXCEPTION_IF(sc_check(ecdh_info.amount.bytes) != 0, error::wallet_internal_error, "Bad ECDH input amount");
rct::addKeys2(Ctmp, ecdh_info.mask, ecdh_info.amount, rct::H);
if (rct::equalKeys(C, Ctmp))
amount = rct::h2d(ecdh_info.amount);
else
amount = 0;
}
received += amount;
}
}
in_pool = res.txs.front().in_pool;
confirmations = (uint64_t)-1;
if (!in_pool)
{
std::string err;
uint64_t bc_height = get_daemon_blockchain_height(err);
if (err.empty())
confirmations = bc_height - (res.txs.front().block_height + 1);
}
}
std::string wallet2::get_tx_proof(const crypto::hash &txid, const cryptonote::account_public_address &address, bool is_subaddress, const std::string &message)
{
// determine if the address is found in the subaddress hash table (i.e. whether the proof is outbound or inbound)
const bool is_out = m_subaddresses.count(address.m_spend_public_key) == 0;
std::string prefix_data((const char*)&txid, sizeof(crypto::hash));
prefix_data += message;
crypto::hash prefix_hash;
crypto::cn_fast_hash(prefix_data.data(), prefix_data.size(), prefix_hash);
std::vector<crypto::public_key> shared_secret;
std::vector<crypto::signature> sig;
std::string sig_str;
if (is_out)
{
crypto::secret_key tx_key;
std::vector<crypto::secret_key> additional_tx_keys;
THROW_WALLET_EXCEPTION_IF(!get_tx_key(txid, tx_key, additional_tx_keys), error::wallet_internal_error, "Tx secret key wasn't found in the wallet file.");
const size_t num_sigs = 1 + additional_tx_keys.size();
shared_secret.resize(num_sigs);
sig.resize(num_sigs);
shared_secret[0] = rct::rct2pk(rct::scalarmultKey(rct::pk2rct(address.m_view_public_key), rct::sk2rct(tx_key)));
crypto::public_key tx_pub_key;
if (is_subaddress)
{
tx_pub_key = rct2pk(rct::scalarmultKey(rct::pk2rct(address.m_spend_public_key), rct::sk2rct(tx_key)));
crypto::generate_tx_proof(prefix_hash, tx_pub_key, address.m_view_public_key, address.m_spend_public_key, shared_secret[0], tx_key, sig[0]);
}
else
{
crypto::secret_key_to_public_key(tx_key, tx_pub_key);
crypto::generate_tx_proof(prefix_hash, tx_pub_key, address.m_view_public_key, boost::none, shared_secret[0], tx_key, sig[0]);
}
for (size_t i = 1; i < num_sigs; ++i)
{
shared_secret[i] = rct::rct2pk(rct::scalarmultKey(rct::pk2rct(address.m_view_public_key), rct::sk2rct(additional_tx_keys[i - 1])));
if (is_subaddress)
{
tx_pub_key = rct2pk(rct::scalarmultKey(rct::pk2rct(address.m_spend_public_key), rct::sk2rct(additional_tx_keys[i - 1])));
crypto::generate_tx_proof(prefix_hash, tx_pub_key, address.m_view_public_key, address.m_spend_public_key, shared_secret[i], additional_tx_keys[i - 1], sig[i]);
}
else
{
crypto::secret_key_to_public_key(additional_tx_keys[i - 1], tx_pub_key);
crypto::generate_tx_proof(prefix_hash, tx_pub_key, address.m_view_public_key, boost::none, shared_secret[i], additional_tx_keys[i - 1], sig[i]);
}
}
sig_str = std::string("OutProofV1");
}
else
{
// fetch tx pubkey from the daemon
COMMAND_RPC_GET_TRANSACTIONS::request req;
COMMAND_RPC_GET_TRANSACTIONS::response res;
req.txs_hashes.push_back(epee::string_tools::pod_to_hex(txid));
req.decode_as_json = false;
req.prune = false;
m_daemon_rpc_mutex.lock();
bool ok = net_utils::invoke_http_json("/gettransactions", req, res, m_http_client);
m_daemon_rpc_mutex.unlock();
THROW_WALLET_EXCEPTION_IF(!ok || (res.txs.size() != 1 && res.txs_as_hex.size() != 1),
error::wallet_internal_error, "Failed to get transaction from daemon");
cryptonote::blobdata tx_data;
if (res.txs.size() == 1)
ok = string_tools::parse_hexstr_to_binbuff(res.txs.front().as_hex, tx_data);
else
ok = string_tools::parse_hexstr_to_binbuff(res.txs_as_hex.front(), tx_data);
THROW_WALLET_EXCEPTION_IF(!ok, error::wallet_internal_error, "Failed to parse transaction from daemon");
crypto::hash tx_hash, tx_prefix_hash;
cryptonote::transaction tx;
THROW_WALLET_EXCEPTION_IF(!cryptonote::parse_and_validate_tx_from_blob(tx_data, tx, tx_hash, tx_prefix_hash), error::wallet_internal_error,
"Failed to validate transaction from daemon");
THROW_WALLET_EXCEPTION_IF(tx_hash != txid, error::wallet_internal_error, "Failed to get the right transaction from daemon");
crypto::public_key tx_pub_key = get_tx_pub_key_from_extra(tx);
THROW_WALLET_EXCEPTION_IF(tx_pub_key == null_pkey, error::wallet_internal_error, "Tx pubkey was not found");
std::vector<crypto::public_key> additional_tx_pub_keys = get_additional_tx_pub_keys_from_extra(tx);
const size_t num_sigs = 1 + additional_tx_pub_keys.size();
shared_secret.resize(num_sigs);
sig.resize(num_sigs);
const crypto::secret_key& a = m_account.get_keys().m_view_secret_key;
shared_secret[0] = rct::rct2pk(rct::scalarmultKey(rct::pk2rct(tx_pub_key), rct::sk2rct(a)));
if (is_subaddress)
{
crypto::generate_tx_proof(prefix_hash, address.m_view_public_key, tx_pub_key, address.m_spend_public_key, shared_secret[0], a, sig[0]);
}
else
{
crypto::generate_tx_proof(prefix_hash, address.m_view_public_key, tx_pub_key, boost::none, shared_secret[0], a, sig[0]);
}
for (size_t i = 1; i < num_sigs; ++i)
{
shared_secret[i] = rct::rct2pk(rct::scalarmultKey(rct::pk2rct(additional_tx_pub_keys[i - 1]), rct::sk2rct(a)));
if (is_subaddress)
{
crypto::generate_tx_proof(prefix_hash, address.m_view_public_key, additional_tx_pub_keys[i - 1], address.m_spend_public_key, shared_secret[i], a, sig[i]);
}
else
{
crypto::generate_tx_proof(prefix_hash, address.m_view_public_key, additional_tx_pub_keys[i - 1], boost::none, shared_secret[i], a, sig[i]);
}
}
sig_str = std::string("InProofV1");
}
const size_t num_sigs = shared_secret.size();
// check if this address actually received any funds
crypto::key_derivation derivation;
THROW_WALLET_EXCEPTION_IF(!crypto::generate_key_derivation(shared_secret[0], rct::rct2sk(rct::I), derivation), error::wallet_internal_error, "Failed to generate key derivation");
std::vector<crypto::key_derivation> additional_derivations(num_sigs - 1);
for (size_t i = 1; i < num_sigs; ++i)
THROW_WALLET_EXCEPTION_IF(!crypto::generate_key_derivation(shared_secret[i], rct::rct2sk(rct::I), additional_derivations[i - 1]), error::wallet_internal_error, "Failed to generate key derivation");
uint64_t received;
bool in_pool;
uint64_t confirmations;
check_tx_key_helper(txid, derivation, additional_derivations, address, received, in_pool, confirmations);
THROW_WALLET_EXCEPTION_IF(!received, error::wallet_internal_error, tr("No funds received in this tx."));
// concatenate all signature strings
for (size_t i = 0; i < num_sigs; ++i)
sig_str +=
tools::base58::encode(std::string((const char *)&shared_secret[i], sizeof(crypto::public_key))) +
tools::base58::encode(std::string((const char *)&sig[i], sizeof(crypto::signature)));
return sig_str;
}
bool wallet2::check_tx_proof(const crypto::hash &txid, const cryptonote::account_public_address &address, bool is_subaddress, const std::string &message, const std::string &sig_str, uint64_t &received, bool &in_pool, uint64_t &confirmations)
{
const bool is_out = sig_str.substr(0, 3) == "Out";
const std::string header = is_out ? "OutProofV1" : "InProofV1";
const size_t header_len = header.size();
THROW_WALLET_EXCEPTION_IF(sig_str.size() < header_len || sig_str.substr(0, header_len) != header, error::wallet_internal_error,
"Signature header check error");
// decode base58
std::vector<crypto::public_key> shared_secret(1);
std::vector<crypto::signature> sig(1);
const size_t pk_len = tools::base58::encode(std::string((const char *)&shared_secret[0], sizeof(crypto::public_key))).size();
const size_t sig_len = tools::base58::encode(std::string((const char *)&sig[0], sizeof(crypto::signature))).size();
const size_t num_sigs = (sig_str.size() - header_len) / (pk_len + sig_len);
THROW_WALLET_EXCEPTION_IF(sig_str.size() != header_len + num_sigs * (pk_len + sig_len), error::wallet_internal_error,
"Wrong signature size");
shared_secret.resize(num_sigs);
sig.resize(num_sigs);
for (size_t i = 0; i < num_sigs; ++i)
{
std::string pk_decoded;
std::string sig_decoded;
const size_t offset = header_len + i * (pk_len + sig_len);
THROW_WALLET_EXCEPTION_IF(!tools::base58::decode(sig_str.substr(offset, pk_len), pk_decoded), error::wallet_internal_error,
"Signature decoding error");
THROW_WALLET_EXCEPTION_IF(!tools::base58::decode(sig_str.substr(offset + pk_len, sig_len), sig_decoded), error::wallet_internal_error,
"Signature decoding error");
THROW_WALLET_EXCEPTION_IF(sizeof(crypto::public_key) != pk_decoded.size() || sizeof(crypto::signature) != sig_decoded.size(), error::wallet_internal_error,
"Signature decoding error");
memcpy(&shared_secret[i], pk_decoded.data(), sizeof(crypto::public_key));
memcpy(&sig[i], sig_decoded.data(), sizeof(crypto::signature));
}
// fetch tx pubkey from the daemon
COMMAND_RPC_GET_TRANSACTIONS::request req;
COMMAND_RPC_GET_TRANSACTIONS::response res;
req.txs_hashes.push_back(epee::string_tools::pod_to_hex(txid));
req.decode_as_json = false;
req.prune = false;
m_daemon_rpc_mutex.lock();
bool ok = net_utils::invoke_http_json("/gettransactions", req, res, m_http_client);
m_daemon_rpc_mutex.unlock();
THROW_WALLET_EXCEPTION_IF(!ok || (res.txs.size() != 1 && res.txs_as_hex.size() != 1),
error::wallet_internal_error, "Failed to get transaction from daemon");
cryptonote::blobdata tx_data;
if (res.txs.size() == 1)
ok = string_tools::parse_hexstr_to_binbuff(res.txs.front().as_hex, tx_data);
else
ok = string_tools::parse_hexstr_to_binbuff(res.txs_as_hex.front(), tx_data);
THROW_WALLET_EXCEPTION_IF(!ok, error::wallet_internal_error, "Failed to parse transaction from daemon");
crypto::hash tx_hash, tx_prefix_hash;
cryptonote::transaction tx;
THROW_WALLET_EXCEPTION_IF(!cryptonote::parse_and_validate_tx_from_blob(tx_data, tx, tx_hash, tx_prefix_hash), error::wallet_internal_error,
"Failed to validate transaction from daemon");
THROW_WALLET_EXCEPTION_IF(tx_hash != txid, error::wallet_internal_error, "Failed to get the right transaction from daemon");
crypto::public_key tx_pub_key = get_tx_pub_key_from_extra(tx);
THROW_WALLET_EXCEPTION_IF(tx_pub_key == null_pkey, error::wallet_internal_error, "Tx pubkey was not found");
std::vector<crypto::public_key> additional_tx_pub_keys = get_additional_tx_pub_keys_from_extra(tx);
THROW_WALLET_EXCEPTION_IF(additional_tx_pub_keys.size() + 1 != num_sigs, error::wallet_internal_error, "Signature size mismatch with additional tx pubkeys");
std::string prefix_data((const char*)&txid, sizeof(crypto::hash));
prefix_data += message;
crypto::hash prefix_hash;
crypto::cn_fast_hash(prefix_data.data(), prefix_data.size(), prefix_hash);
// check signature
std::vector<int> good_signature(num_sigs, 0);
if (is_out)
{
good_signature[0] = is_subaddress ?
crypto::check_tx_proof(prefix_hash, tx_pub_key, address.m_view_public_key, address.m_spend_public_key, shared_secret[0], sig[0]) :
crypto::check_tx_proof(prefix_hash, tx_pub_key, address.m_view_public_key, boost::none, shared_secret[0], sig[0]);
for (size_t i = 0; i < additional_tx_pub_keys.size(); ++i)
{
good_signature[i + 1] = is_subaddress ?
crypto::check_tx_proof(prefix_hash, additional_tx_pub_keys[i], address.m_view_public_key, address.m_spend_public_key, shared_secret[i + 1], sig[i + 1]) :
crypto::check_tx_proof(prefix_hash, additional_tx_pub_keys[i], address.m_view_public_key, boost::none, shared_secret[i + 1], sig[i + 1]);
}
}
else
{
good_signature[0] = is_subaddress ?
crypto::check_tx_proof(prefix_hash, address.m_view_public_key, tx_pub_key, address.m_spend_public_key, shared_secret[0], sig[0]) :
crypto::check_tx_proof(prefix_hash, address.m_view_public_key, tx_pub_key, boost::none, shared_secret[0], sig[0]);
for (size_t i = 0; i < additional_tx_pub_keys.size(); ++i)
{
good_signature[i + 1] = is_subaddress ?
crypto::check_tx_proof(prefix_hash, address.m_view_public_key, additional_tx_pub_keys[i], address.m_spend_public_key, shared_secret[i + 1], sig[i + 1]) :
crypto::check_tx_proof(prefix_hash, address.m_view_public_key, additional_tx_pub_keys[i], boost::none, shared_secret[i + 1], sig[i + 1]);
}
}
if (std::any_of(good_signature.begin(), good_signature.end(), [](int i) { return i > 0; }))
{
// obtain key derivation by multiplying scalar 1 to the shared secret
crypto::key_derivation derivation;
if (good_signature[0])
THROW_WALLET_EXCEPTION_IF(!crypto::generate_key_derivation(shared_secret[0], rct::rct2sk(rct::I), derivation), error::wallet_internal_error, "Failed to generate key derivation");
std::vector<crypto::key_derivation> additional_derivations(num_sigs - 1);
for (size_t i = 1; i < num_sigs; ++i)
if (good_signature[i])
THROW_WALLET_EXCEPTION_IF(!crypto::generate_key_derivation(shared_secret[i], rct::rct2sk(rct::I), additional_derivations[i - 1]), error::wallet_internal_error, "Failed to generate key derivation");
check_tx_key_helper(txid, derivation, additional_derivations, address, received, in_pool, confirmations);
return true;
}
return false;
}
std::string wallet2::get_reserve_proof(const boost::optional<std::pair<uint32_t, uint64_t>> &account_minreserve, const std::string &message)
{
THROW_WALLET_EXCEPTION_IF(m_watch_only || m_multisig, error::wallet_internal_error, "Reserve proof can only be generated by a full wallet");
THROW_WALLET_EXCEPTION_IF(balance_all() == 0, error::wallet_internal_error, "Zero balance");
THROW_WALLET_EXCEPTION_IF(account_minreserve && balance(account_minreserve->first) < account_minreserve->second, error::wallet_internal_error,
"Not enough balance in this account for the requested minimum reserve amount");
// determine which outputs to include in the proof
std::vector<size_t> selected_transfers;
for (size_t i = 0; i < m_transfers.size(); ++i)
{
const transfer_details &td = m_transfers[i];
if (!td.m_spent && (!account_minreserve || account_minreserve->first == td.m_subaddr_index.major))
selected_transfers.push_back(i);
}
if (account_minreserve)
{
THROW_WALLET_EXCEPTION_IF(account_minreserve->second == 0, error::wallet_internal_error, "Proved amount must be greater than 0");
// minimize the number of outputs included in the proof, by only picking the N largest outputs that can cover the requested min reserve amount
std::sort(selected_transfers.begin(), selected_transfers.end(), [&](const size_t a, const size_t b)
{ return m_transfers[a].amount() > m_transfers[b].amount(); });
while (selected_transfers.size() >= 2 && m_transfers[selected_transfers[1]].amount() >= account_minreserve->second)
selected_transfers.erase(selected_transfers.begin());
size_t sz = 0;
uint64_t total = 0;
while (total < account_minreserve->second)
{
total += m_transfers[selected_transfers[sz]].amount();
++sz;
}
selected_transfers.resize(sz);
}
// compute signature prefix hash
std::string prefix_data = message;
prefix_data.append((const char*)&m_account.get_keys().m_account_address, sizeof(cryptonote::account_public_address));
for (size_t i = 0; i < selected_transfers.size(); ++i)
{
prefix_data.append((const char*)&m_transfers[selected_transfers[i]].m_key_image, sizeof(crypto::key_image));
}
crypto::hash prefix_hash;
crypto::cn_fast_hash(prefix_data.data(), prefix_data.size(), prefix_hash);
// generate proof entries
std::vector<reserve_proof_entry> proofs(selected_transfers.size());
std::unordered_set<cryptonote::subaddress_index> subaddr_indices = { {0,0} };
for (size_t i = 0; i < selected_transfers.size(); ++i)
{
const transfer_details &td = m_transfers[selected_transfers[i]];
reserve_proof_entry& proof = proofs[i];
proof.txid = td.m_txid;
proof.index_in_tx = td.m_internal_output_index;
proof.key_image = td.m_key_image;
subaddr_indices.insert(td.m_subaddr_index);
// get tx pub key
const crypto::public_key tx_pub_key = get_tx_pub_key_from_extra(td.m_tx, td.m_pk_index);
THROW_WALLET_EXCEPTION_IF(tx_pub_key == crypto::null_pkey, error::wallet_internal_error, "The tx public key isn't found");
const std::vector<crypto::public_key> additional_tx_pub_keys = get_additional_tx_pub_keys_from_extra(td.m_tx);
// determine which tx pub key was used for deriving the output key
const crypto::public_key *tx_pub_key_used = &tx_pub_key;
for (int i = 0; i < 2; ++i)
{
proof.shared_secret = rct::rct2pk(rct::scalarmultKey(rct::pk2rct(*tx_pub_key_used), rct::sk2rct(m_account.get_keys().m_view_secret_key)));
crypto::key_derivation derivation;
THROW_WALLET_EXCEPTION_IF(!crypto::generate_key_derivation(proof.shared_secret, rct::rct2sk(rct::I), derivation),
error::wallet_internal_error, "Failed to generate key derivation");
crypto::public_key subaddress_spendkey;
THROW_WALLET_EXCEPTION_IF(!derive_subaddress_public_key(td.get_public_key(), derivation, proof.index_in_tx, subaddress_spendkey),
error::wallet_internal_error, "Failed to derive subaddress public key");
if (m_subaddresses.count(subaddress_spendkey) == 1)
break;
THROW_WALLET_EXCEPTION_IF(additional_tx_pub_keys.empty(), error::wallet_internal_error,
"Normal tx pub key doesn't derive the expected output, while the additional tx pub keys are empty");
THROW_WALLET_EXCEPTION_IF(i == 1, error::wallet_internal_error,
"Neither normal tx pub key nor additional tx pub key derive the expected output key");
tx_pub_key_used = &additional_tx_pub_keys[proof.index_in_tx];
}
// generate signature for shared secret
crypto::generate_tx_proof(prefix_hash, m_account.get_keys().m_account_address.m_view_public_key, *tx_pub_key_used, boost::none, proof.shared_secret, m_account.get_keys().m_view_secret_key, proof.shared_secret_sig);
// derive ephemeral secret key
crypto::key_image ki;
cryptonote::keypair ephemeral;
const bool r = cryptonote::generate_key_image_helper(m_account.get_keys(), m_subaddresses, td.get_public_key(), tx_pub_key, additional_tx_pub_keys, td.m_internal_output_index, ephemeral, ki, m_account.get_device());
THROW_WALLET_EXCEPTION_IF(!r, error::wallet_internal_error, "Failed to generate key image");
THROW_WALLET_EXCEPTION_IF(ephemeral.pub != td.get_public_key(), error::wallet_internal_error, "Derived public key doesn't agree with the stored one");
// generate signature for key image
const std::vector<const crypto::public_key*> pubs = { &ephemeral.pub };
crypto::generate_ring_signature(prefix_hash, td.m_key_image, &pubs[0], 1, ephemeral.sec, 0, &proof.key_image_sig);
}
// collect all subaddress spend keys that received those outputs and generate their signatures
std::unordered_map<crypto::public_key, crypto::signature> subaddr_spendkeys;
for (const cryptonote::subaddress_index &index : subaddr_indices)
{
crypto::secret_key subaddr_spend_skey = m_account.get_keys().m_spend_secret_key;
if (!index.is_zero())
{
crypto::secret_key m = m_account.get_device().get_subaddress_secret_key(m_account.get_keys().m_view_secret_key, index);
crypto::secret_key tmp = subaddr_spend_skey;
sc_add((unsigned char*)&subaddr_spend_skey, (unsigned char*)&m, (unsigned char*)&tmp);
}
crypto::public_key subaddr_spend_pkey;
secret_key_to_public_key(subaddr_spend_skey, subaddr_spend_pkey);
crypto::generate_signature(prefix_hash, subaddr_spend_pkey, subaddr_spend_skey, subaddr_spendkeys[subaddr_spend_pkey]);
}
// serialize & encode
std::ostringstream oss;
boost::archive::portable_binary_oarchive ar(oss);
ar << proofs << subaddr_spendkeys;
return "ReserveProofV1" + tools::base58::encode(oss.str());
}
bool wallet2::check_reserve_proof(const cryptonote::account_public_address &address, const std::string &message, const std::string &sig_str, uint64_t &total, uint64_t &spent)
{
uint32_t rpc_version;
THROW_WALLET_EXCEPTION_IF(!check_connection(&rpc_version), error::wallet_internal_error, "Failed to connect to daemon: " + get_daemon_address());
THROW_WALLET_EXCEPTION_IF(rpc_version < MAKE_CORE_RPC_VERSION(1, 0), error::wallet_internal_error, "Daemon RPC version is too old");
static constexpr char header[] = "ReserveProofV1";
THROW_WALLET_EXCEPTION_IF(!boost::string_ref{sig_str}.starts_with(header), error::wallet_internal_error,
"Signature header check error");
std::string sig_decoded;
THROW_WALLET_EXCEPTION_IF(!tools::base58::decode(sig_str.substr(std::strlen(header)), sig_decoded), error::wallet_internal_error,
"Signature decoding error");
std::istringstream iss(sig_decoded);
boost::archive::portable_binary_iarchive ar(iss);
std::vector<reserve_proof_entry> proofs;
std::unordered_map<crypto::public_key, crypto::signature> subaddr_spendkeys;
ar >> proofs >> subaddr_spendkeys;
THROW_WALLET_EXCEPTION_IF(subaddr_spendkeys.count(address.m_spend_public_key) == 0, error::wallet_internal_error,
"The given address isn't found in the proof");
// compute signature prefix hash
std::string prefix_data = message;
prefix_data.append((const char*)&address, sizeof(cryptonote::account_public_address));
for (size_t i = 0; i < proofs.size(); ++i)
{
prefix_data.append((const char*)&proofs[i].key_image, sizeof(crypto::key_image));
}
crypto::hash prefix_hash;
crypto::cn_fast_hash(prefix_data.data(), prefix_data.size(), prefix_hash);
// fetch txes from daemon
COMMAND_RPC_GET_TRANSACTIONS::request gettx_req;
COMMAND_RPC_GET_TRANSACTIONS::response gettx_res;
for (size_t i = 0; i < proofs.size(); ++i)
gettx_req.txs_hashes.push_back(epee::string_tools::pod_to_hex(proofs[i].txid));
gettx_req.decode_as_json = false;
gettx_req.prune = false;
m_daemon_rpc_mutex.lock();
bool ok = net_utils::invoke_http_json("/gettransactions", gettx_req, gettx_res, m_http_client);
m_daemon_rpc_mutex.unlock();
THROW_WALLET_EXCEPTION_IF(!ok || gettx_res.txs.size() != proofs.size(),
error::wallet_internal_error, "Failed to get transaction from daemon");
// check spent status
COMMAND_RPC_IS_KEY_IMAGE_SPENT::request kispent_req;
COMMAND_RPC_IS_KEY_IMAGE_SPENT::response kispent_res;
for (size_t i = 0; i < proofs.size(); ++i)
kispent_req.key_images.push_back(epee::string_tools::pod_to_hex(proofs[i].key_image));
m_daemon_rpc_mutex.lock();
ok = epee::net_utils::invoke_http_json("/is_key_image_spent", kispent_req, kispent_res, m_http_client, rpc_timeout);
m_daemon_rpc_mutex.unlock();
THROW_WALLET_EXCEPTION_IF(!ok || kispent_res.spent_status.size() != proofs.size(),
error::wallet_internal_error, "Failed to get key image spent status from daemon");
total = spent = 0;
for (size_t i = 0; i < proofs.size(); ++i)
{
const reserve_proof_entry& proof = proofs[i];
THROW_WALLET_EXCEPTION_IF(gettx_res.txs[i].in_pool, error::wallet_internal_error, "Tx is unconfirmed");
cryptonote::blobdata tx_data;
ok = string_tools::parse_hexstr_to_binbuff(gettx_res.txs[i].as_hex, tx_data);
THROW_WALLET_EXCEPTION_IF(!ok, error::wallet_internal_error, "Failed to parse transaction from daemon");
crypto::hash tx_hash, tx_prefix_hash;
cryptonote::transaction tx;
THROW_WALLET_EXCEPTION_IF(!cryptonote::parse_and_validate_tx_from_blob(tx_data, tx, tx_hash, tx_prefix_hash), error::wallet_internal_error,
"Failed to validate transaction from daemon");
THROW_WALLET_EXCEPTION_IF(tx_hash != proof.txid, error::wallet_internal_error, "Failed to get the right transaction from daemon");
THROW_WALLET_EXCEPTION_IF(proof.index_in_tx >= tx.vout.size(), error::wallet_internal_error, "index_in_tx is out of bound");
const cryptonote::txout_to_key* const out_key = boost::get<cryptonote::txout_to_key>(std::addressof(tx.vout[proof.index_in_tx].target));
THROW_WALLET_EXCEPTION_IF(!out_key, error::wallet_internal_error, "Output key wasn't found")
// get tx pub key
const crypto::public_key tx_pub_key = get_tx_pub_key_from_extra(tx);
THROW_WALLET_EXCEPTION_IF(tx_pub_key == crypto::null_pkey, error::wallet_internal_error, "The tx public key isn't found");
const std::vector<crypto::public_key> additional_tx_pub_keys = get_additional_tx_pub_keys_from_extra(tx);
// check singature for shared secret
ok = crypto::check_tx_proof(prefix_hash, address.m_view_public_key, tx_pub_key, boost::none, proof.shared_secret, proof.shared_secret_sig);
if (!ok && additional_tx_pub_keys.size() == tx.vout.size())
ok = crypto::check_tx_proof(prefix_hash, address.m_view_public_key, additional_tx_pub_keys[proof.index_in_tx], boost::none, proof.shared_secret, proof.shared_secret_sig);
if (!ok)
return false;
// check signature for key image
const std::vector<const crypto::public_key*> pubs = { &out_key->key };
ok = crypto::check_ring_signature(prefix_hash, proof.key_image, &pubs[0], 1, &proof.key_image_sig);
if (!ok)
return false;
// check if the address really received the fund
crypto::key_derivation derivation;
THROW_WALLET_EXCEPTION_IF(!crypto::generate_key_derivation(proof.shared_secret, rct::rct2sk(rct::I), derivation), error::wallet_internal_error, "Failed to generate key derivation");
crypto::public_key subaddr_spendkey;
crypto::derive_subaddress_public_key(out_key->key, derivation, proof.index_in_tx, subaddr_spendkey);
THROW_WALLET_EXCEPTION_IF(subaddr_spendkeys.count(subaddr_spendkey) == 0, error::wallet_internal_error,
"The address doesn't seem to have received the fund");
// check amount
uint64_t amount = tx.vout[proof.index_in_tx].amount;
if (amount == 0)
{
// decode rct
crypto::secret_key shared_secret;
crypto::derivation_to_scalar(derivation, proof.index_in_tx, shared_secret);
rct::ecdhTuple ecdh_info = tx.rct_signatures.ecdhInfo[proof.index_in_tx];
rct::ecdhDecode(ecdh_info, rct::sk2rct(shared_secret));
amount = rct::h2d(ecdh_info.amount);
}
total += amount;
if (kispent_res.spent_status[i])
spent += amount;
}
// check signatures for all subaddress spend keys
for (const auto &i : subaddr_spendkeys)
{
if (!crypto::check_signature(prefix_hash, i.first, i.second))
return false;
}
return true;
}
std::string wallet2::get_wallet_file() const
{
return m_wallet_file;
}
std::string wallet2::get_keys_file() const
{
return m_keys_file;
}
std::string wallet2::get_daemon_address() const
{
return m_daemon_address;
}
uint64_t wallet2::get_daemon_blockchain_height(string &err) const
{
uint64_t height;
boost::optional<std::string> result = m_node_rpc_proxy.get_height(height);
if (result)
{
err = *result;
return 0;
}
err = "";
return height;
}
uint64_t wallet2::get_daemon_blockchain_target_height(string &err)
{
err = "";
uint64_t target_height = 0;
const auto result = m_node_rpc_proxy.get_target_height(target_height);
if (result && *result != CORE_RPC_STATUS_OK)
{
err= *result;
return 0;
}
return target_height;
}
uint64_t wallet2::get_approximate_blockchain_height() const
{
// time of v2 fork
const time_t fork_time = m_nettype == TESTNET ? 1448285909 : m_nettype == STAGENET ? 1520937818 : 1458748658;
// v2 fork block
const uint64_t fork_block = m_nettype == TESTNET ? 624634 : m_nettype == STAGENET ? 32000 : 1009827;
// avg seconds per block
const int seconds_per_block = DIFFICULTY_TARGET_V2;
// Calculated blockchain height
uint64_t approx_blockchain_height = fork_block + (time(NULL) - fork_time)/seconds_per_block;
// testnet got some huge rollbacks, so the estimation is way off
static const uint64_t approximate_testnet_rolled_back_blocks = 303967;
if (m_nettype == TESTNET && approx_blockchain_height > approximate_testnet_rolled_back_blocks)
approx_blockchain_height -= approximate_testnet_rolled_back_blocks;
LOG_PRINT_L2("Calculated blockchain height: " << approx_blockchain_height);
return approx_blockchain_height;
}
void wallet2::set_tx_note(const crypto::hash &txid, const std::string ¬e)
{
m_tx_notes[txid] = note;
}
std::string wallet2::get_tx_note(const crypto::hash &txid) const
{
std::unordered_map<crypto::hash, std::string>::const_iterator i = m_tx_notes.find(txid);
if (i == m_tx_notes.end())
return std::string();
return i->second;
}
void wallet2::set_tx_device_aux(const crypto::hash &txid, const std::string &aux)
{
m_tx_device[txid] = aux;
}
std::string wallet2::get_tx_device_aux(const crypto::hash &txid) const
{
std::unordered_map<crypto::hash, std::string>::const_iterator i = m_tx_device.find(txid);
if (i == m_tx_device.end())
return std::string();
return i->second;
}
void wallet2::set_attribute(const std::string &key, const std::string &value)
{
m_attributes[key] = value;
}
std::string wallet2::get_attribute(const std::string &key) const
{
std::unordered_map<std::string, std::string>::const_iterator i = m_attributes.find(key);
if (i == m_attributes.end())
return std::string();
return i->second;
}
void wallet2::set_description(const std::string &description)
{
set_attribute(ATTRIBUTE_DESCRIPTION, description);
}
std::string wallet2::get_description() const
{
return get_attribute(ATTRIBUTE_DESCRIPTION);
}
const std::pair<std::map<std::string, std::string>, std::vector<std::string>>& wallet2::get_account_tags()
{
// ensure consistency
if (m_account_tags.second.size() != get_num_subaddress_accounts())
m_account_tags.second.resize(get_num_subaddress_accounts(), "");
for (const std::string& tag : m_account_tags.second)
{
if (!tag.empty() && m_account_tags.first.count(tag) == 0)
m_account_tags.first.insert({tag, ""});
}
for (auto i = m_account_tags.first.begin(); i != m_account_tags.first.end(); )
{
if (std::find(m_account_tags.second.begin(), m_account_tags.second.end(), i->first) == m_account_tags.second.end())
i = m_account_tags.first.erase(i);
else
++i;
}
return m_account_tags;
}
void wallet2::set_account_tag(const std::set<uint32_t> account_indices, const std::string& tag)
{
for (uint32_t account_index : account_indices)
{
THROW_WALLET_EXCEPTION_IF(account_index >= get_num_subaddress_accounts(), error::wallet_internal_error, "Account index out of bound");
if (m_account_tags.second[account_index] == tag)
MDEBUG("This tag is already assigned to this account");
else
m_account_tags.second[account_index] = tag;
}
get_account_tags();
}
void wallet2::set_account_tag_description(const std::string& tag, const std::string& description)
{
THROW_WALLET_EXCEPTION_IF(tag.empty(), error::wallet_internal_error, "Tag must not be empty");
THROW_WALLET_EXCEPTION_IF(m_account_tags.first.count(tag) == 0, error::wallet_internal_error, "Tag is unregistered");
m_account_tags.first[tag] = description;
}
std::string wallet2::sign(const std::string &data) const
{
crypto::hash hash;
crypto::cn_fast_hash(data.data(), data.size(), hash);
const cryptonote::account_keys &keys = m_account.get_keys();
crypto::signature signature;
crypto::generate_signature(hash, keys.m_account_address.m_spend_public_key, keys.m_spend_secret_key, signature);
return std::string("SigV1") + tools::base58::encode(std::string((const char *)&signature, sizeof(signature)));
}
bool wallet2::verify(const std::string &data, const cryptonote::account_public_address &address, const std::string &signature) const
{
const size_t header_len = strlen("SigV1");
if (signature.size() < header_len || signature.substr(0, header_len) != "SigV1") {
LOG_PRINT_L0("Signature header check error");
return false;
}
crypto::hash hash;
crypto::cn_fast_hash(data.data(), data.size(), hash);
std::string decoded;
if (!tools::base58::decode(signature.substr(header_len), decoded)) {
LOG_PRINT_L0("Signature decoding error");
return false;
}
crypto::signature s;
if (sizeof(s) != decoded.size()) {
LOG_PRINT_L0("Signature decoding error");
return false;
}
memcpy(&s, decoded.data(), sizeof(s));
return crypto::check_signature(hash, address.m_spend_public_key, s);
}
std::string wallet2::sign_multisig_participant(const std::string& data) const
{
CHECK_AND_ASSERT_THROW_MES(m_multisig, "Wallet is not multisig");
crypto::hash hash;
crypto::cn_fast_hash(data.data(), data.size(), hash);
const cryptonote::account_keys &keys = m_account.get_keys();
crypto::signature signature;
crypto::generate_signature(hash, get_multisig_signer_public_key(), keys.m_spend_secret_key, signature);
return MULTISIG_SIGNATURE_MAGIC + tools::base58::encode(std::string((const char *)&signature, sizeof(signature)));
}
bool wallet2::verify_with_public_key(const std::string &data, const crypto::public_key &public_key, const std::string &signature) const
{
if (signature.size() < MULTISIG_SIGNATURE_MAGIC.size() || signature.substr(0, MULTISIG_SIGNATURE_MAGIC.size()) != MULTISIG_SIGNATURE_MAGIC) {
MERROR("Signature header check error");
return false;
}
crypto::hash hash;
crypto::cn_fast_hash(data.data(), data.size(), hash);
std::string decoded;
if (!tools::base58::decode(signature.substr(MULTISIG_SIGNATURE_MAGIC.size()), decoded)) {
MERROR("Signature decoding error");
return false;
}
crypto::signature s;
if (sizeof(s) != decoded.size()) {
MERROR("Signature decoding error");
return false;
}
memcpy(&s, decoded.data(), sizeof(s));
return crypto::check_signature(hash, public_key, s);
}
//----------------------------------------------------------------------------------------------------
crypto::public_key wallet2::get_tx_pub_key_from_received_outs(const tools::wallet2::transfer_details &td) const
{
std::vector<tx_extra_field> tx_extra_fields;
if(!parse_tx_extra(td.m_tx.extra, tx_extra_fields))
{
// Extra may only be partially parsed, it's OK if tx_extra_fields contains public key
}
// Due to a previous bug, there might be more than one tx pubkey in extra, one being
// the result of a previously discarded signature.
// For speed, since scanning for outputs is a slow process, we check whether extra
// contains more than one pubkey. If not, the first one is returned. If yes, they're
// checked for whether they yield at least one output
tx_extra_pub_key pub_key_field;
THROW_WALLET_EXCEPTION_IF(!find_tx_extra_field_by_type(tx_extra_fields, pub_key_field, 0), error::wallet_internal_error,
"Public key wasn't found in the transaction extra");
const crypto::public_key tx_pub_key = pub_key_field.pub_key;
bool two_found = find_tx_extra_field_by_type(tx_extra_fields, pub_key_field, 1);
if (!two_found) {
// easy case, just one found
return tx_pub_key;
}
// more than one, loop and search
const cryptonote::account_keys& keys = m_account.get_keys();
size_t pk_index = 0;
hw::device &hwdev = m_account.get_device();
const std::vector<crypto::public_key> additional_tx_pub_keys = get_additional_tx_pub_keys_from_extra(td.m_tx);
std::vector<crypto::key_derivation> additional_derivations;
for (size_t i = 0; i < additional_tx_pub_keys.size(); ++i)
{
additional_derivations.push_back({});
bool r = hwdev.generate_key_derivation(additional_tx_pub_keys[i], keys.m_view_secret_key, additional_derivations.back());
THROW_WALLET_EXCEPTION_IF(!r, error::wallet_internal_error, "Failed to generate key derivation");
}
while (find_tx_extra_field_by_type(tx_extra_fields, pub_key_field, pk_index++)) {
const crypto::public_key tx_pub_key = pub_key_field.pub_key;
crypto::key_derivation derivation;
bool r = hwdev.generate_key_derivation(tx_pub_key, keys.m_view_secret_key, derivation);
THROW_WALLET_EXCEPTION_IF(!r, error::wallet_internal_error, "Failed to generate key derivation");
for (size_t i = 0; i < td.m_tx.vout.size(); ++i)
{
tx_scan_info_t tx_scan_info;
check_acc_out_precomp(td.m_tx.vout[i], derivation, additional_derivations, i, tx_scan_info);
if (!tx_scan_info.error && tx_scan_info.received)
return tx_pub_key;
}
}
// we found no key yielding an output
THROW_WALLET_EXCEPTION_IF(true, error::wallet_internal_error,
"Public key yielding at least one output wasn't found in the transaction extra");
return crypto::null_pkey;
}
bool wallet2::export_key_images(const std::string &filename) const
{
PERF_TIMER(export_key_images);
std::pair<size_t, std::vector<std::pair<crypto::key_image, crypto::signature>>> ski = export_key_images();
std::string magic(KEY_IMAGE_EXPORT_FILE_MAGIC, strlen(KEY_IMAGE_EXPORT_FILE_MAGIC));
const cryptonote::account_public_address &keys = get_account().get_keys().m_account_address;
const uint32_t offset = ski.first;
std::string data;
data.reserve(4 + ski.second.size() * (sizeof(crypto::key_image) + sizeof(crypto::signature)) + 2 * sizeof(crypto::public_key));
data.resize(4);
data[0] = offset & 0xff;
data[1] = (offset >> 8) & 0xff;
data[2] = (offset >> 16) & 0xff;
data[3] = (offset >> 24) & 0xff;
data += std::string((const char *)&keys.m_spend_public_key, sizeof(crypto::public_key));
data += std::string((const char *)&keys.m_view_public_key, sizeof(crypto::public_key));
for (const auto &i: ski.second)
{
data += std::string((const char *)&i.first, sizeof(crypto::key_image));
data += std::string((const char *)&i.second, sizeof(crypto::signature));
}
// encrypt data, keep magic plaintext
PERF_TIMER(export_key_images_encrypt);
std::string ciphertext = encrypt_with_view_secret_key(data);
return epee::file_io_utils::save_string_to_file(filename, magic + ciphertext);
}
//----------------------------------------------------------------------------------------------------
std::pair<size_t, std::vector<std::pair<crypto::key_image, crypto::signature>>> wallet2::export_key_images() const
{
PERF_TIMER(export_key_images_raw);
std::vector<std::pair<crypto::key_image, crypto::signature>> ski;
size_t offset = 0;
while (offset < m_transfers.size() && !m_transfers[offset].m_key_image_requested)
++offset;
ski.reserve(m_transfers.size() - offset);
for (size_t n = offset; n < m_transfers.size(); ++n)
{
const transfer_details &td = m_transfers[n];
crypto::hash hash;
crypto::cn_fast_hash(&td.m_key_image, sizeof(td.m_key_image), hash);
// get ephemeral public key
const cryptonote::tx_out &out = td.m_tx.vout[td.m_internal_output_index];
THROW_WALLET_EXCEPTION_IF(out.target.type() != typeid(txout_to_key), error::wallet_internal_error,
"Output is not txout_to_key");
const cryptonote::txout_to_key &o = boost::get<const cryptonote::txout_to_key>(out.target);
const crypto::public_key pkey = o.key;
// get tx pub key
std::vector<tx_extra_field> tx_extra_fields;
if(!parse_tx_extra(td.m_tx.extra, tx_extra_fields))
{
// Extra may only be partially parsed, it's OK if tx_extra_fields contains public key
}
crypto::public_key tx_pub_key = get_tx_pub_key_from_received_outs(td);
const std::vector<crypto::public_key> additional_tx_pub_keys = get_additional_tx_pub_keys_from_extra(td.m_tx);
// generate ephemeral secret key
crypto::key_image ki;
cryptonote::keypair in_ephemeral;
bool r = cryptonote::generate_key_image_helper(m_account.get_keys(), m_subaddresses, pkey, tx_pub_key, additional_tx_pub_keys, td.m_internal_output_index, in_ephemeral, ki, m_account.get_device());
THROW_WALLET_EXCEPTION_IF(!r, error::wallet_internal_error, "Failed to generate key image");
THROW_WALLET_EXCEPTION_IF(td.m_key_image_known && !td.m_key_image_partial && ki != td.m_key_image,
error::wallet_internal_error, "key_image generated not matched with cached key image");
THROW_WALLET_EXCEPTION_IF(in_ephemeral.pub != pkey,
error::wallet_internal_error, "key_image generated ephemeral public key not matched with output_key");
// sign the key image with the output secret key
crypto::signature signature;
std::vector<const crypto::public_key*> key_ptrs;
key_ptrs.push_back(&pkey);
crypto::generate_ring_signature((const crypto::hash&)td.m_key_image, td.m_key_image, key_ptrs, in_ephemeral.sec, 0, &signature);
ski.push_back(std::make_pair(td.m_key_image, signature));
}
return std::make_pair(offset, ski);
}
uint64_t wallet2::import_key_images(const std::string &filename, uint64_t &spent, uint64_t &unspent)
{
PERF_TIMER(import_key_images_fsu);
std::string data;
bool r = epee::file_io_utils::load_file_to_string(filename, data);
THROW_WALLET_EXCEPTION_IF(!r, error::wallet_internal_error, std::string(tr("failed to read file ")) + filename);
const size_t magiclen = strlen(KEY_IMAGE_EXPORT_FILE_MAGIC);
if (data.size() < magiclen || memcmp(data.data(), KEY_IMAGE_EXPORT_FILE_MAGIC, magiclen))
{
THROW_WALLET_EXCEPTION(error::wallet_internal_error, std::string("Bad key image export file magic in ") + filename);
}
try
{
PERF_TIMER(import_key_images_decrypt);
data = decrypt_with_view_secret_key(std::string(data, magiclen));
}
catch (const std::exception &e)
{
THROW_WALLET_EXCEPTION(error::wallet_internal_error, std::string("Failed to decrypt ") + filename + ": " + e.what());
}
const size_t headerlen = 4 + 2 * sizeof(crypto::public_key);
THROW_WALLET_EXCEPTION_IF(data.size() < headerlen, error::wallet_internal_error, std::string("Bad data size from file ") + filename);
const uint32_t offset = (uint8_t)data[0] | (((uint8_t)data[1]) << 8) | (((uint8_t)data[2]) << 16) | (((uint8_t)data[3]) << 24);
const crypto::public_key &public_spend_key = *(const crypto::public_key*)&data[4];
const crypto::public_key &public_view_key = *(const crypto::public_key*)&data[4 + sizeof(crypto::public_key)];
const cryptonote::account_public_address &keys = get_account().get_keys().m_account_address;
if (public_spend_key != keys.m_spend_public_key || public_view_key != keys.m_view_public_key)
{
THROW_WALLET_EXCEPTION(error::wallet_internal_error, std::string( "Key images from ") + filename + " are for a different account");
}
THROW_WALLET_EXCEPTION_IF(offset > m_transfers.size(), error::wallet_internal_error, "Offset larger than known outputs");
const size_t record_size = sizeof(crypto::key_image) + sizeof(crypto::signature);
THROW_WALLET_EXCEPTION_IF((data.size() - headerlen) % record_size,
error::wallet_internal_error, std::string("Bad data size from file ") + filename);
size_t nki = (data.size() - headerlen) / record_size;
std::vector<std::pair<crypto::key_image, crypto::signature>> ski;
ski.reserve(nki);
for (size_t n = 0; n < nki; ++n)
{
crypto::key_image key_image = *reinterpret_cast<const crypto::key_image*>(&data[headerlen + n * record_size]);
crypto::signature signature = *reinterpret_cast<const crypto::signature*>(&data[headerlen + n * record_size + sizeof(crypto::key_image)]);
ski.push_back(std::make_pair(key_image, signature));
}
return import_key_images(ski, offset, spent, unspent);
}
//----------------------------------------------------------------------------------------------------
uint64_t wallet2::import_key_images(const std::vector<std::pair<crypto::key_image, crypto::signature>> &signed_key_images, size_t offset, uint64_t &spent, uint64_t &unspent, bool check_spent)
{
PERF_TIMER(import_key_images_lots);
COMMAND_RPC_IS_KEY_IMAGE_SPENT::request req = AUTO_VAL_INIT(req);
COMMAND_RPC_IS_KEY_IMAGE_SPENT::response daemon_resp = AUTO_VAL_INIT(daemon_resp);
THROW_WALLET_EXCEPTION_IF(offset > m_transfers.size(), error::wallet_internal_error, "Offset larger than known outputs");
THROW_WALLET_EXCEPTION_IF(signed_key_images.size() > m_transfers.size() - offset, error::wallet_internal_error,
"The blockchain is out of date compared to the signed key images");
if (signed_key_images.empty() && offset == 0)
{
spent = 0;
unspent = 0;
return 0;
}
req.key_images.reserve(signed_key_images.size());
PERF_TIMER_START(import_key_images_A);
for (size_t n = 0; n < signed_key_images.size(); ++n)
{
const transfer_details &td = m_transfers[n + offset];
const crypto::key_image &key_image = signed_key_images[n].first;
const crypto::signature &signature = signed_key_images[n].second;
// get ephemeral public key
const cryptonote::tx_out &out = td.m_tx.vout[td.m_internal_output_index];
THROW_WALLET_EXCEPTION_IF(out.target.type() != typeid(txout_to_key), error::wallet_internal_error,
"Non txout_to_key output found");
const cryptonote::txout_to_key &o = boost::get<cryptonote::txout_to_key>(out.target);
const crypto::public_key pkey = o.key;
if (!td.m_key_image_known || !(key_image == td.m_key_image))
{
std::vector<const crypto::public_key*> pkeys;
pkeys.push_back(&pkey);
THROW_WALLET_EXCEPTION_IF(!(rct::scalarmultKey(rct::ki2rct(key_image), rct::curveOrder()) == rct::identity()),
error::wallet_internal_error, "Key image out of validity domain: input " + boost::lexical_cast<std::string>(n + offset) + "/"
+ boost::lexical_cast<std::string>(signed_key_images.size()) + ", key image " + epee::string_tools::pod_to_hex(key_image));
THROW_WALLET_EXCEPTION_IF(!crypto::check_ring_signature((const crypto::hash&)key_image, key_image, pkeys, &signature),
error::signature_check_failed, boost::lexical_cast<std::string>(n + offset) + "/"
+ boost::lexical_cast<std::string>(signed_key_images.size()) + ", key image " + epee::string_tools::pod_to_hex(key_image)
+ ", signature " + epee::string_tools::pod_to_hex(signature) + ", pubkey " + epee::string_tools::pod_to_hex(*pkeys[0]));
}
req.key_images.push_back(epee::string_tools::pod_to_hex(key_image));
}
PERF_TIMER_STOP(import_key_images_A);
PERF_TIMER_START(import_key_images_B);
for (size_t n = 0; n < signed_key_images.size(); ++n)
{
m_transfers[n + offset].m_key_image = signed_key_images[n].first;
m_key_images[m_transfers[n + offset].m_key_image] = n + offset;
m_transfers[n + offset].m_key_image_known = true;
m_transfers[n + offset].m_key_image_requested = false;
m_transfers[n + offset].m_key_image_partial = false;
}
PERF_TIMER_STOP(import_key_images_B);
if(check_spent)
{
PERF_TIMER(import_key_images_RPC);
m_daemon_rpc_mutex.lock();
bool r = epee::net_utils::invoke_http_json("/is_key_image_spent", req, daemon_resp, m_http_client, rpc_timeout);
m_daemon_rpc_mutex.unlock();
THROW_WALLET_EXCEPTION_IF(!r, error::no_connection_to_daemon, "is_key_image_spent");
THROW_WALLET_EXCEPTION_IF(daemon_resp.status == CORE_RPC_STATUS_BUSY, error::daemon_busy, "is_key_image_spent");
THROW_WALLET_EXCEPTION_IF(daemon_resp.status != CORE_RPC_STATUS_OK, error::is_key_image_spent_error, daemon_resp.status);
THROW_WALLET_EXCEPTION_IF(daemon_resp.spent_status.size() != signed_key_images.size(), error::wallet_internal_error,
"daemon returned wrong response for is_key_image_spent, wrong amounts count = " +
std::to_string(daemon_resp.spent_status.size()) + ", expected " + std::to_string(signed_key_images.size()));
for (size_t n = 0; n < daemon_resp.spent_status.size(); ++n)
{
transfer_details &td = m_transfers[n + offset];
td.m_spent = daemon_resp.spent_status[n] != COMMAND_RPC_IS_KEY_IMAGE_SPENT::UNSPENT;
}
}
spent = 0;
unspent = 0;
std::unordered_set<crypto::hash> spent_txids; // For each spent key image, search for a tx in m_transfers that uses it as input.
std::vector<size_t> swept_transfers; // If such a spending tx wasn't found in m_transfers, this means the spending tx
// was created by sweep_all, so we can't know the spent height and other detailed info.
std::unordered_map<crypto::key_image, crypto::hash> spent_key_images;
PERF_TIMER_START(import_key_images_C);
for (const transfer_details &td: m_transfers)
{
for (const cryptonote::txin_v& in : td.m_tx.vin)
{
if (in.type() == typeid(cryptonote::txin_to_key))
spent_key_images.insert(std::make_pair(boost::get<cryptonote::txin_to_key>(in).k_image, td.m_txid));
}
}
PERF_TIMER_STOP(import_key_images_C);
PERF_TIMER_START(import_key_images_D);
for(size_t i = 0; i < signed_key_images.size(); ++i)
{
const transfer_details &td = m_transfers[i + offset];
uint64_t amount = td.amount();
if (td.m_spent)
spent += amount;
else
unspent += amount;
LOG_PRINT_L2("Transfer " << i << ": " << print_money(amount) << " (" << td.m_global_output_index << "): "
<< (td.m_spent ? "spent" : "unspent") << " (key image " << req.key_images[i] << ")");
if (i < daemon_resp.spent_status.size() && daemon_resp.spent_status[i] == COMMAND_RPC_IS_KEY_IMAGE_SPENT::SPENT_IN_BLOCKCHAIN)
{
const std::unordered_map<crypto::key_image, crypto::hash>::const_iterator skii = spent_key_images.find(td.m_key_image);
if (skii == spent_key_images.end())
swept_transfers.push_back(i);
else
spent_txids.insert(skii->second);
}
}
PERF_TIMER_STOP(import_key_images_D);
MDEBUG("Total: " << print_money(spent) << " spent, " << print_money(unspent) << " unspent");
if (check_spent)
{
// query outgoing txes
COMMAND_RPC_GET_TRANSACTIONS::request gettxs_req;
COMMAND_RPC_GET_TRANSACTIONS::response gettxs_res;
gettxs_req.decode_as_json = false;
gettxs_req.prune = false;
gettxs_req.txs_hashes.reserve(spent_txids.size());
for (const crypto::hash& spent_txid : spent_txids)
gettxs_req.txs_hashes.push_back(epee::string_tools::pod_to_hex(spent_txid));
PERF_TIMER_START(import_key_images_E);
m_daemon_rpc_mutex.lock();
bool r = epee::net_utils::invoke_http_json("/gettransactions", gettxs_req, gettxs_res, m_http_client, rpc_timeout);
m_daemon_rpc_mutex.unlock();
THROW_WALLET_EXCEPTION_IF(!r, error::no_connection_to_daemon, "gettransactions");
THROW_WALLET_EXCEPTION_IF(gettxs_res.status == CORE_RPC_STATUS_BUSY, error::daemon_busy, "gettransactions");
THROW_WALLET_EXCEPTION_IF(gettxs_res.txs.size() != spent_txids.size(), error::wallet_internal_error,
"daemon returned wrong response for gettransactions, wrong count = " + std::to_string(gettxs_res.txs.size()) + ", expected " + std::to_string(spent_txids.size()));
PERF_TIMER_STOP(import_key_images_E);
// process each outgoing tx
PERF_TIMER_START(import_key_images_F);
auto spent_txid = spent_txids.begin();
hw::device &hwdev = m_account.get_device();
for (const COMMAND_RPC_GET_TRANSACTIONS::entry& e : gettxs_res.txs)
{
THROW_WALLET_EXCEPTION_IF(e.in_pool, error::wallet_internal_error, "spent tx isn't supposed to be in txpool");
// parse tx
cryptonote::blobdata bd;
THROW_WALLET_EXCEPTION_IF(!epee::string_tools::parse_hexstr_to_binbuff(e.as_hex, bd), error::wallet_internal_error, "parse_hexstr_to_binbuff failed");
cryptonote::transaction spent_tx;
crypto::hash spnet_txid_parsed, spent_txid_prefix;
THROW_WALLET_EXCEPTION_IF(!cryptonote::parse_and_validate_tx_from_blob(bd, spent_tx, spnet_txid_parsed, spent_txid_prefix), error::wallet_internal_error, "parse_and_validate_tx_from_blob failed");
THROW_WALLET_EXCEPTION_IF(*spent_txid != spnet_txid_parsed, error::wallet_internal_error, "parsed txid mismatch");
// get received (change) amount
uint64_t tx_money_got_in_outs = 0;
const cryptonote::account_keys& keys = m_account.get_keys();
const crypto::public_key tx_pub_key = get_tx_pub_key_from_extra(spent_tx);
crypto::key_derivation derivation;
bool r = hwdev.generate_key_derivation(tx_pub_key, keys.m_view_secret_key, derivation);
THROW_WALLET_EXCEPTION_IF(!r, error::wallet_internal_error, "Failed to generate key derivation");
const std::vector<crypto::public_key> additional_tx_pub_keys = get_additional_tx_pub_keys_from_extra(spent_tx);
std::vector<crypto::key_derivation> additional_derivations;
for (size_t i = 0; i < additional_tx_pub_keys.size(); ++i)
{
additional_derivations.push_back({});
r = hwdev.generate_key_derivation(additional_tx_pub_keys[i], keys.m_view_secret_key, additional_derivations.back());
THROW_WALLET_EXCEPTION_IF(!r, error::wallet_internal_error, "Failed to generate key derivation");
}
size_t output_index = 0;
for (const cryptonote::tx_out& out : spent_tx.vout)
{
tx_scan_info_t tx_scan_info;
check_acc_out_precomp(out, derivation, additional_derivations, output_index, tx_scan_info);
THROW_WALLET_EXCEPTION_IF(tx_scan_info.error, error::wallet_internal_error, "check_acc_out_precomp failed");
if (tx_scan_info.received)
{
if (tx_scan_info.money_transfered == 0)
{
rct::key mask;
tx_scan_info.money_transfered = tools::decodeRct(spent_tx.rct_signatures, tx_scan_info.received->derivation, output_index, mask, hwdev);
}
tx_money_got_in_outs += tx_scan_info.money_transfered;
}
++output_index;
}
// get spent amount
uint64_t tx_money_spent_in_ins = 0;
uint32_t subaddr_account = (uint32_t)-1;
std::set<uint32_t> subaddr_indices;
for (const cryptonote::txin_v& in : spent_tx.vin)
{
if (in.type() != typeid(cryptonote::txin_to_key))
continue;
auto it = m_key_images.find(boost::get<cryptonote::txin_to_key>(in).k_image);
if (it != m_key_images.end())
{
const transfer_details& td = m_transfers[it->second];
uint64_t amount = boost::get<cryptonote::txin_to_key>(in).amount;
if (amount > 0)
{
THROW_WALLET_EXCEPTION_IF(amount != td.amount(), error::wallet_internal_error,
std::string("Inconsistent amount in tx input: got ") + print_money(amount) +
std::string(", expected ") + print_money(td.amount()));
}
amount = td.amount();
tx_money_spent_in_ins += amount;
LOG_PRINT_L0("Spent money: " << print_money(amount) << ", with tx: " << *spent_txid);
set_spent(it->second, e.block_height);
if (m_callback)
m_callback->on_money_spent(e.block_height, *spent_txid, spent_tx, amount, spent_tx, td.m_subaddr_index);
if (subaddr_account != (uint32_t)-1 && subaddr_account != td.m_subaddr_index.major)
LOG_PRINT_L0("WARNING: This tx spends outputs received by different subaddress accounts, which isn't supposed to happen");
subaddr_account = td.m_subaddr_index.major;
subaddr_indices.insert(td.m_subaddr_index.minor);
}
}
// create outgoing payment
process_outgoing(*spent_txid, spent_tx, e.block_height, e.block_timestamp, tx_money_spent_in_ins, tx_money_got_in_outs, subaddr_account, subaddr_indices);
// erase corresponding incoming payment
for (auto j = m_payments.begin(); j != m_payments.end(); ++j)
{
if (j->second.m_tx_hash == *spent_txid)
{
m_payments.erase(j);
break;
}
}
++spent_txid;
}
PERF_TIMER_STOP(import_key_images_F);
PERF_TIMER_START(import_key_images_G);
for (size_t n : swept_transfers)
{
const transfer_details& td = m_transfers[n];
confirmed_transfer_details pd;
pd.m_change = (uint64_t)-1; // change is unknown
pd.m_amount_in = pd.m_amount_out = td.amount(); // fee is unknown
pd.m_block_height = 0; // spent block height is unknown
const crypto::hash &spent_txid = crypto::null_hash; // spent txid is unknown
m_confirmed_txs.insert(std::make_pair(spent_txid, pd));
}
PERF_TIMER_STOP(import_key_images_G);
}
return m_transfers[signed_key_images.size() - 1].m_block_height;
}
bool wallet2::import_key_images(std::vector<crypto::key_image> key_images)
{
if (key_images.size() > m_transfers.size())
{
LOG_PRINT_L1("More key images returned that we know outputs for");
return false;
}
for (size_t i = 0; i < key_images.size(); ++i)
{
transfer_details &td = m_transfers[i];
if (td.m_key_image_known && !td.m_key_image_partial && td.m_key_image != key_images[i])
LOG_PRINT_L0("WARNING: imported key image differs from previously known key image at index " << i << ": trusting imported one");
td.m_key_image = key_images[i];
m_key_images[m_transfers[i].m_key_image] = i;
td.m_key_image_known = true;
td.m_key_image_requested = false;
td.m_key_image_partial = false;
m_pub_keys[m_transfers[i].get_public_key()] = i;
}
return true;
}
wallet2::payment_container wallet2::export_payments() const
{
payment_container payments;
for (auto const &p : m_payments)
{
payments.emplace(p);
}
return payments;
}
void wallet2::import_payments(const payment_container &payments)
{
m_payments.clear();
for (auto const &p : payments)
{
m_payments.emplace(p);
}
}
void wallet2::import_payments_out(const std::list<std::pair<crypto::hash,wallet2::confirmed_transfer_details>> &confirmed_payments)
{
m_confirmed_txs.clear();
for (auto const &p : confirmed_payments)
{
m_confirmed_txs.emplace(p);
}
}
std::tuple<size_t,crypto::hash,std::vector<crypto::hash>> wallet2::export_blockchain() const
{
std::tuple<size_t, crypto::hash, std::vector<crypto::hash>> bc;
std::get<0>(bc) = m_blockchain.offset();
std::get<1>(bc) = m_blockchain.empty() ? crypto::null_hash: m_blockchain.genesis();
for (size_t n = m_blockchain.offset(); n < m_blockchain.size(); ++n)
{
std::get<2>(bc).push_back(m_blockchain[n]);
}
return bc;
}
void wallet2::import_blockchain(const std::tuple<size_t, crypto::hash, std::vector<crypto::hash>> &bc)
{
m_blockchain.clear();
if (std::get<0>(bc))
{
for (size_t n = std::get<0>(bc); n > 0; --n)
m_blockchain.push_back(std::get<1>(bc));
m_blockchain.trim(std::get<0>(bc));
}
for (auto const &b : std::get<2>(bc))
{
m_blockchain.push_back(b);
}
cryptonote::block genesis;
generate_genesis(genesis);
crypto::hash genesis_hash = get_block_hash(genesis);
check_genesis(genesis_hash);
m_last_block_reward = cryptonote::get_outs_money_amount(genesis.miner_tx);
}
//----------------------------------------------------------------------------------------------------
std::pair<size_t, std::vector<tools::wallet2::transfer_details>> wallet2::export_outputs() const
{
PERF_TIMER(export_outputs);
std::vector<tools::wallet2::transfer_details> outs;
size_t offset = 0;
while (offset < m_transfers.size() && m_transfers[offset].m_key_image_known)
++offset;
outs.reserve(m_transfers.size() - offset);
for (size_t n = offset; n < m_transfers.size(); ++n)
{
const transfer_details &td = m_transfers[n];
outs.push_back(td);
}
return std::make_pair(offset, outs);
}
//----------------------------------------------------------------------------------------------------
std::string wallet2::export_outputs_to_str() const
{
PERF_TIMER(export_outputs_to_str);
std::stringstream oss;
boost::archive::portable_binary_oarchive ar(oss);
const auto& outputs = export_outputs();
ar << outputs;
std::string magic(OUTPUT_EXPORT_FILE_MAGIC, strlen(OUTPUT_EXPORT_FILE_MAGIC));
const cryptonote::account_public_address &keys = get_account().get_keys().m_account_address;
std::string header;
header += std::string((const char *)&keys.m_spend_public_key, sizeof(crypto::public_key));
header += std::string((const char *)&keys.m_view_public_key, sizeof(crypto::public_key));
PERF_TIMER(export_outputs_encryption);
std::string ciphertext = encrypt_with_view_secret_key(header + oss.str());
return magic + ciphertext;
}
//----------------------------------------------------------------------------------------------------
size_t wallet2::import_outputs(const std::pair<size_t, std::vector<tools::wallet2::transfer_details>> &outputs)
{
PERF_TIMER(import_outputs);
THROW_WALLET_EXCEPTION_IF(outputs.first > m_transfers.size(), error::wallet_internal_error,
"Imported outputs omit more outputs that we know of");
const size_t offset = outputs.first;
const size_t original_size = m_transfers.size();
m_transfers.resize(offset + outputs.second.size());
for (size_t i = 0; i < offset; ++i)
m_transfers[i].m_key_image_requested = false;
for (size_t i = 0; i < outputs.second.size(); ++i)
{
transfer_details td = outputs.second[i];
// skip those we've already imported, or which have different data
if (i + offset < original_size)
{
// compare the data used to create the key image below
const transfer_details &org_td = m_transfers[i + offset];
if (!org_td.m_key_image_known)
goto process;
#define CMPF(f) if (!(td.f == org_td.f)) goto process
CMPF(m_txid);
CMPF(m_key_image);
CMPF(m_internal_output_index);
#undef CMPF
if (!(get_transaction_prefix_hash(td.m_tx) == get_transaction_prefix_hash(org_td.m_tx)))
goto process;
// copy anyway, since the comparison does not include ancillary fields which may have changed
m_transfers[i + offset] = std::move(td);
continue;
}
process:
// the hot wallet wouldn't have known about key images (except if we already exported them)
cryptonote::keypair in_ephemeral;
THROW_WALLET_EXCEPTION_IF(td.m_tx.vout.empty(), error::wallet_internal_error, "tx with no outputs at index " + boost::lexical_cast<std::string>(i + offset));
crypto::public_key tx_pub_key = get_tx_pub_key_from_received_outs(td);
const std::vector<crypto::public_key> additional_tx_pub_keys = get_additional_tx_pub_keys_from_extra(td.m_tx);
THROW_WALLET_EXCEPTION_IF(td.m_tx.vout[td.m_internal_output_index].target.type() != typeid(cryptonote::txout_to_key),
error::wallet_internal_error, "Unsupported output type");
const crypto::public_key& out_key = boost::get<cryptonote::txout_to_key>(td.m_tx.vout[td.m_internal_output_index].target).key;
bool r = cryptonote::generate_key_image_helper(m_account.get_keys(), m_subaddresses, out_key, tx_pub_key, additional_tx_pub_keys, td.m_internal_output_index, in_ephemeral, td.m_key_image, m_account.get_device());
THROW_WALLET_EXCEPTION_IF(!r, error::wallet_internal_error, "Failed to generate key image");
expand_subaddresses(td.m_subaddr_index);
td.m_key_image_known = true;
td.m_key_image_requested = true;
td.m_key_image_partial = false;
THROW_WALLET_EXCEPTION_IF(in_ephemeral.pub != out_key,
error::wallet_internal_error, "key_image generated ephemeral public key not matched with output_key at index " + boost::lexical_cast<std::string>(i + offset));
m_key_images[td.m_key_image] = i + offset;
m_pub_keys[td.get_public_key()] = i + offset;
m_transfers[i + offset] = std::move(td);
}
return m_transfers.size();
}
//----------------------------------------------------------------------------------------------------
size_t wallet2::import_outputs_from_str(const std::string &outputs_st)
{
PERF_TIMER(import_outputs_from_str);
std::string data = outputs_st;
const size_t magiclen = strlen(OUTPUT_EXPORT_FILE_MAGIC);
if (data.size() < magiclen || memcmp(data.data(), OUTPUT_EXPORT_FILE_MAGIC, magiclen))
{
THROW_WALLET_EXCEPTION(error::wallet_internal_error, std::string("Bad magic from outputs"));
}
try
{
PERF_TIMER(import_outputs_decrypt);
data = decrypt_with_view_secret_key(std::string(data, magiclen));
}
catch (const std::exception &e)
{
THROW_WALLET_EXCEPTION(error::wallet_internal_error, std::string("Failed to decrypt outputs: ") + e.what());
}
const size_t headerlen = 2 * sizeof(crypto::public_key);
if (data.size() < headerlen)
{
THROW_WALLET_EXCEPTION(error::wallet_internal_error, std::string("Bad data size for outputs"));
}
const crypto::public_key &public_spend_key = *(const crypto::public_key*)&data[0];
const crypto::public_key &public_view_key = *(const crypto::public_key*)&data[sizeof(crypto::public_key)];
const cryptonote::account_public_address &keys = get_account().get_keys().m_account_address;
if (public_spend_key != keys.m_spend_public_key || public_view_key != keys.m_view_public_key)
{
THROW_WALLET_EXCEPTION(error::wallet_internal_error, std::string("Outputs from are for a different account"));
}
size_t imported_outputs = 0;
try
{
std::string body(data, headerlen);
std::stringstream iss;
iss << body;
std::pair<size_t, std::vector<tools::wallet2::transfer_details>> outputs;
try
{
boost::archive::portable_binary_iarchive ar(iss);
ar >> outputs;
}
catch (...)
{
iss.str("");
iss << body;
boost::archive::binary_iarchive ar(iss);
ar >> outputs;
}
imported_outputs = import_outputs(outputs);
}
catch (const std::exception &e)
{
THROW_WALLET_EXCEPTION(error::wallet_internal_error, std::string("Failed to import outputs") + e.what());
}
return imported_outputs;
}
//----------------------------------------------------------------------------------------------------
crypto::public_key wallet2::get_multisig_signer_public_key(const crypto::secret_key &spend_skey) const
{
crypto::public_key pkey;
crypto::secret_key_to_public_key(get_multisig_blinded_secret_key(spend_skey), pkey);
return pkey;
}
//----------------------------------------------------------------------------------------------------
crypto::public_key wallet2::get_multisig_signer_public_key() const
{
CHECK_AND_ASSERT_THROW_MES(m_multisig, "Wallet is not multisig");
crypto::public_key signer;
CHECK_AND_ASSERT_THROW_MES(crypto::secret_key_to_public_key(get_account().get_keys().m_spend_secret_key, signer), "Failed to generate signer public key");
return signer;
}
//----------------------------------------------------------------------------------------------------
crypto::public_key wallet2::get_multisig_signing_public_key(const crypto::secret_key &msk) const
{
CHECK_AND_ASSERT_THROW_MES(m_multisig, "Wallet is not multisig");
crypto::public_key pkey;
CHECK_AND_ASSERT_THROW_MES(crypto::secret_key_to_public_key(msk, pkey), "Failed to derive public key");
return pkey;
}
//----------------------------------------------------------------------------------------------------
crypto::public_key wallet2::get_multisig_signing_public_key(size_t idx) const
{
CHECK_AND_ASSERT_THROW_MES(m_multisig, "Wallet is not multisig");
CHECK_AND_ASSERT_THROW_MES(idx < get_account().get_multisig_keys().size(), "Multisig signing key index out of range");
return get_multisig_signing_public_key(get_account().get_multisig_keys()[idx]);
}
//----------------------------------------------------------------------------------------------------
rct::key wallet2::get_multisig_k(size_t idx, const std::unordered_set<rct::key> &used_L) const
{
CHECK_AND_ASSERT_THROW_MES(m_multisig, "Wallet is not multisig");
CHECK_AND_ASSERT_THROW_MES(idx < m_transfers.size(), "idx out of range");
for (const auto &k: m_transfers[idx].m_multisig_k)
{
rct::key L;
rct::scalarmultBase(L, k);
if (used_L.find(L) != used_L.end())
return k;
}
THROW_WALLET_EXCEPTION(tools::error::multisig_export_needed);
return rct::zero();
}
//----------------------------------------------------------------------------------------------------
rct::multisig_kLRki wallet2::get_multisig_kLRki(size_t n, const rct::key &k) const
{
CHECK_AND_ASSERT_THROW_MES(n < m_transfers.size(), "Bad m_transfers index");
rct::multisig_kLRki kLRki;
kLRki.k = k;
cryptonote::generate_multisig_LR(m_transfers[n].get_public_key(), rct::rct2sk(kLRki.k), (crypto::public_key&)kLRki.L, (crypto::public_key&)kLRki.R);
kLRki.ki = rct::ki2rct(m_transfers[n].m_key_image);
return kLRki;
}
//----------------------------------------------------------------------------------------------------
rct::multisig_kLRki wallet2::get_multisig_composite_kLRki(size_t n, const crypto::public_key &ignore, std::unordered_set<rct::key> &used_L, std::unordered_set<rct::key> &new_used_L) const
{
CHECK_AND_ASSERT_THROW_MES(n < m_transfers.size(), "Bad transfer index");
const transfer_details &td = m_transfers[n];
rct::multisig_kLRki kLRki = get_multisig_kLRki(n, rct::skGen());
// pick a L/R pair from every other participant but one
size_t n_signers_used = 1;
for (const auto &p: m_transfers[n].m_multisig_info)
{
if (p.m_signer == ignore)
continue;
for (const auto &lr: p.m_LR)
{
if (used_L.find(lr.m_L) != used_L.end())
continue;
used_L.insert(lr.m_L);
new_used_L.insert(lr.m_L);
rct::addKeys(kLRki.L, kLRki.L, lr.m_L);
rct::addKeys(kLRki.R, kLRki.R, lr.m_R);
++n_signers_used;
break;
}
}
CHECK_AND_ASSERT_THROW_MES(n_signers_used >= m_multisig_threshold, "LR not found for enough participants");
return kLRki;
}
//----------------------------------------------------------------------------------------------------
crypto::key_image wallet2::get_multisig_composite_key_image(size_t n) const
{
CHECK_AND_ASSERT_THROW_MES(n < m_transfers.size(), "Bad output index");
const transfer_details &td = m_transfers[n];
const crypto::public_key tx_key = get_tx_pub_key_from_received_outs(td);
const std::vector<crypto::public_key> additional_tx_keys = cryptonote::get_additional_tx_pub_keys_from_extra(td.m_tx);
crypto::key_image ki;
std::vector<crypto::key_image> pkis;
for (const auto &info: td.m_multisig_info)
for (const auto &pki: info.m_partial_key_images)
pkis.push_back(pki);
bool r = cryptonote::generate_multisig_composite_key_image(get_account().get_keys(), m_subaddresses, td.get_public_key(), tx_key, additional_tx_keys, td.m_internal_output_index, pkis, ki);
THROW_WALLET_EXCEPTION_IF(!r, error::wallet_internal_error, "Failed to generate key image");
return ki;
}
//----------------------------------------------------------------------------------------------------
cryptonote::blobdata wallet2::export_multisig()
{
std::vector<tools::wallet2::multisig_info> info;
const crypto::public_key signer = get_multisig_signer_public_key();
info.resize(m_transfers.size());
for (size_t n = 0; n < m_transfers.size(); ++n)
{
transfer_details &td = m_transfers[n];
const std::vector<crypto::public_key> additional_tx_pub_keys = get_additional_tx_pub_keys_from_extra(td.m_tx);
crypto::key_image ki;
td.m_multisig_k.clear();
info[n].m_LR.clear();
info[n].m_partial_key_images.clear();
for (size_t m = 0; m < get_account().get_multisig_keys().size(); ++m)
{
// we want to export the partial key image, not the full one, so we can't use td.m_key_image
bool r = generate_multisig_key_image(get_account().get_keys(), m, td.get_public_key(), ki);
CHECK_AND_ASSERT_THROW_MES(r, "Failed to generate key image");
info[n].m_partial_key_images.push_back(ki);
}
size_t nlr = m_multisig_threshold < m_multisig_signers.size() ? m_multisig_threshold - 1 : 1;
for (size_t m = 0; m < nlr; ++m)
{
td.m_multisig_k.push_back(rct::skGen());
const rct::multisig_kLRki kLRki = get_multisig_kLRki(n, td.m_multisig_k.back());
info[n].m_LR.push_back({kLRki.L, kLRki.R});
}
info[n].m_signer = signer;
}
std::stringstream oss;
boost::archive::portable_binary_oarchive ar(oss);
ar << info;
std::string magic(MULTISIG_EXPORT_FILE_MAGIC, strlen(MULTISIG_EXPORT_FILE_MAGIC));
const cryptonote::account_public_address &keys = get_account().get_keys().m_account_address;
std::string header;
header += std::string((const char *)&keys.m_spend_public_key, sizeof(crypto::public_key));
header += std::string((const char *)&keys.m_view_public_key, sizeof(crypto::public_key));
header += std::string((const char *)&signer, sizeof(crypto::public_key));
std::string ciphertext = encrypt_with_view_secret_key(header + oss.str());
return MULTISIG_EXPORT_FILE_MAGIC + ciphertext;
}
//----------------------------------------------------------------------------------------------------
void wallet2::update_multisig_rescan_info(const std::vector<std::vector<rct::key>> &multisig_k, const std::vector<std::vector<tools::wallet2::multisig_info>> &info, size_t n)
{
CHECK_AND_ASSERT_THROW_MES(n < m_transfers.size(), "Bad index in update_multisig_info");
CHECK_AND_ASSERT_THROW_MES(multisig_k.size() >= m_transfers.size(), "Mismatched sizes of multisig_k and info");
MDEBUG("update_multisig_rescan_info: updating index " << n);
transfer_details &td = m_transfers[n];
td.m_multisig_info.clear();
for (const auto &pi: info)
{
CHECK_AND_ASSERT_THROW_MES(n < pi.size(), "Bad pi size");
td.m_multisig_info.push_back(pi[n]);
}
m_key_images.erase(td.m_key_image);
td.m_key_image = get_multisig_composite_key_image(n);
td.m_key_image_known = true;
td.m_key_image_requested = false;
td.m_key_image_partial = false;
td.m_multisig_k = multisig_k[n];
m_key_images[td.m_key_image] = n;
}
//----------------------------------------------------------------------------------------------------
size_t wallet2::import_multisig(std::vector<cryptonote::blobdata> blobs)
{
CHECK_AND_ASSERT_THROW_MES(m_multisig, "Wallet is not multisig");
std::vector<std::vector<tools::wallet2::multisig_info>> info;
std::unordered_set<crypto::public_key> seen;
for (cryptonote::blobdata &data: blobs)
{
const size_t magiclen = strlen(MULTISIG_EXPORT_FILE_MAGIC);
THROW_WALLET_EXCEPTION_IF(data.size() < magiclen || memcmp(data.data(), MULTISIG_EXPORT_FILE_MAGIC, magiclen),
error::wallet_internal_error, "Bad multisig info file magic in ");
data = decrypt_with_view_secret_key(std::string(data, magiclen));
const size_t headerlen = 3 * sizeof(crypto::public_key);
THROW_WALLET_EXCEPTION_IF(data.size() < headerlen, error::wallet_internal_error, "Bad data size");
const crypto::public_key &public_spend_key = *(const crypto::public_key*)&data[0];
const crypto::public_key &public_view_key = *(const crypto::public_key*)&data[sizeof(crypto::public_key)];
const crypto::public_key &signer = *(const crypto::public_key*)&data[2*sizeof(crypto::public_key)];
const cryptonote::account_public_address &keys = get_account().get_keys().m_account_address;
THROW_WALLET_EXCEPTION_IF(public_spend_key != keys.m_spend_public_key || public_view_key != keys.m_view_public_key,
error::wallet_internal_error, "Multisig info is for a different account");
if (get_multisig_signer_public_key() == signer)
{
MINFO("Multisig info from this wallet ignored");
continue;
}
if (seen.find(signer) != seen.end())
{
MINFO("Duplicate multisig info ignored");
continue;
}
seen.insert(signer);
std::string body(data, headerlen);
std::istringstream iss(body);
std::vector<tools::wallet2::multisig_info> i;
boost::archive::portable_binary_iarchive ar(iss);
ar >> i;
MINFO(boost::format("%u outputs found") % boost::lexical_cast<std::string>(i.size()));
info.push_back(std::move(i));
}
CHECK_AND_ASSERT_THROW_MES(info.size() + 1 <= m_multisig_signers.size() && info.size() + 1 >= m_multisig_threshold, "Wrong number of multisig sources");
std::vector<std::vector<rct::key>> k;
k.reserve(m_transfers.size());
for (const auto &td: m_transfers)
k.push_back(td.m_multisig_k);
// how many outputs we're going to update
size_t n_outputs = m_transfers.size();
for (const auto &pi: info)
if (pi.size() < n_outputs)
n_outputs = pi.size();
if (n_outputs == 0)
return 0;
// check signers are consistent
for (const auto &pi: info)
{
CHECK_AND_ASSERT_THROW_MES(std::find(m_multisig_signers.begin(), m_multisig_signers.end(), pi[0].m_signer) != m_multisig_signers.end(),
"Signer is not a member of this multisig wallet");
for (size_t n = 1; n < n_outputs; ++n)
CHECK_AND_ASSERT_THROW_MES(pi[n].m_signer == pi[0].m_signer, "Mismatched signers in imported multisig info");
}
// trim data we don't have info for from all participants
for (auto &pi: info)
pi.resize(n_outputs);
// sort by signer
if (!info.empty() && !info.front().empty())
{
std::sort(info.begin(), info.end(), [](const std::vector<tools::wallet2::multisig_info> &i0, const std::vector<tools::wallet2::multisig_info> &i1){ return memcmp(&i0[0].m_signer, &i1[0].m_signer, sizeof(i0[0].m_signer)); });
}
// first pass to determine where to detach the blockchain
for (size_t n = 0; n < n_outputs; ++n)
{
const transfer_details &td = m_transfers[n];
if (!td.m_key_image_partial)
continue;
MINFO("Multisig info importing from block height " << td.m_block_height);
detach_blockchain(td.m_block_height);
break;
}
for (size_t n = 0; n < n_outputs && n < m_transfers.size(); ++n)
{
update_multisig_rescan_info(k, info, n);
}
m_multisig_rescan_k = &k;
m_multisig_rescan_info = &info;
try
{
refresh(false);
}
catch (...)
{
m_multisig_rescan_info = NULL;
m_multisig_rescan_k = NULL;
throw;
}
m_multisig_rescan_info = NULL;
m_multisig_rescan_k = NULL;
return n_outputs;
}
//----------------------------------------------------------------------------------------------------
std::string wallet2::encrypt(const char *plaintext, size_t len, const crypto::secret_key &skey, bool authenticated) const
{
crypto::chacha_key key;
crypto::generate_chacha_key(&skey, sizeof(skey), key, m_kdf_rounds);
std::string ciphertext;
crypto::chacha_iv iv = crypto::rand<crypto::chacha_iv>();
ciphertext.resize(len + sizeof(iv) + (authenticated ? sizeof(crypto::signature) : 0));
crypto::chacha20(plaintext, len, key, iv, &ciphertext[sizeof(iv)]);
memcpy(&ciphertext[0], &iv, sizeof(iv));
if (authenticated)
{
crypto::hash hash;
crypto::cn_fast_hash(ciphertext.data(), ciphertext.size() - sizeof(signature), hash);
crypto::public_key pkey;
crypto::secret_key_to_public_key(skey, pkey);
crypto::signature &signature = *(crypto::signature*)&ciphertext[ciphertext.size() - sizeof(crypto::signature)];
crypto::generate_signature(hash, pkey, skey, signature);
}
return ciphertext;
}
//----------------------------------------------------------------------------------------------------
std::string wallet2::encrypt(const epee::span<char> &plaintext, const crypto::secret_key &skey, bool authenticated) const
{
return encrypt(plaintext.data(), plaintext.size(), skey, authenticated);
}
//----------------------------------------------------------------------------------------------------
std::string wallet2::encrypt(const std::string &plaintext, const crypto::secret_key &skey, bool authenticated) const
{
return encrypt(plaintext.data(), plaintext.size(), skey, authenticated);
}
//----------------------------------------------------------------------------------------------------
std::string wallet2::encrypt(const epee::wipeable_string &plaintext, const crypto::secret_key &skey, bool authenticated) const
{
return encrypt(plaintext.data(), plaintext.size(), skey, authenticated);
}
//----------------------------------------------------------------------------------------------------
std::string wallet2::encrypt_with_view_secret_key(const std::string &plaintext, bool authenticated) const
{
return encrypt(plaintext, get_account().get_keys().m_view_secret_key, authenticated);
}
//----------------------------------------------------------------------------------------------------
template<typename T>
T wallet2::decrypt(const std::string &ciphertext, const crypto::secret_key &skey, bool authenticated) const
{
const size_t prefix_size = sizeof(chacha_iv) + (authenticated ? sizeof(crypto::signature) : 0);
THROW_WALLET_EXCEPTION_IF(ciphertext.size() < prefix_size,
error::wallet_internal_error, "Unexpected ciphertext size");
crypto::chacha_key key;
crypto::generate_chacha_key(&skey, sizeof(skey), key, m_kdf_rounds);
const crypto::chacha_iv &iv = *(const crypto::chacha_iv*)&ciphertext[0];
if (authenticated)
{
crypto::hash hash;
crypto::cn_fast_hash(ciphertext.data(), ciphertext.size() - sizeof(signature), hash);
crypto::public_key pkey;
crypto::secret_key_to_public_key(skey, pkey);
const crypto::signature &signature = *(const crypto::signature*)&ciphertext[ciphertext.size() - sizeof(crypto::signature)];
THROW_WALLET_EXCEPTION_IF(!crypto::check_signature(hash, pkey, signature),
error::wallet_internal_error, "Failed to authenticate ciphertext");
}
std::unique_ptr<char[]> buffer{new char[ciphertext.size() - prefix_size]};
auto wiper = epee::misc_utils::create_scope_leave_handler([&]() { memwipe(buffer.get(), ciphertext.size() - prefix_size); });
crypto::chacha20(ciphertext.data() + sizeof(iv), ciphertext.size() - prefix_size, key, iv, buffer.get());
return T(buffer.get(), ciphertext.size() - prefix_size);
}
//----------------------------------------------------------------------------------------------------
template epee::wipeable_string wallet2::decrypt(const std::string &ciphertext, const crypto::secret_key &skey, bool authenticated) const;
//----------------------------------------------------------------------------------------------------
std::string wallet2::decrypt_with_view_secret_key(const std::string &ciphertext, bool authenticated) const
{
return decrypt(ciphertext, get_account().get_keys().m_view_secret_key, authenticated);
}
//----------------------------------------------------------------------------------------------------
std::string wallet2::make_uri(const std::string &address, const std::string &payment_id, uint64_t amount, const std::string &tx_description, const std::string &recipient_name, std::string &error) const
{
cryptonote::address_parse_info info;
if(!get_account_address_from_str(info, nettype(), address))
{
error = std::string("wrong address: ") + address;
return std::string();
}
// we want only one payment id
if (info.has_payment_id && !payment_id.empty())
{
error = "A single payment id is allowed";
return std::string();
}
if (!payment_id.empty())
{
crypto::hash pid32;
crypto::hash8 pid8;
if (!wallet2::parse_long_payment_id(payment_id, pid32) && !wallet2::parse_short_payment_id(payment_id, pid8))
{
error = "Invalid payment id";
return std::string();
}
}
std::string uri = "monero:" + address;
unsigned int n_fields = 0;
if (!payment_id.empty())
{
uri += (n_fields++ ? "&" : "?") + std::string("tx_payment_id=") + payment_id;
}
if (amount > 0)
{
// URI encoded amount is in decimal units, not atomic units
uri += (n_fields++ ? "&" : "?") + std::string("tx_amount=") + cryptonote::print_money(amount);
}
if (!recipient_name.empty())
{
uri += (n_fields++ ? "&" : "?") + std::string("recipient_name=") + epee::net_utils::conver_to_url_format(recipient_name);
}
if (!tx_description.empty())
{
uri += (n_fields++ ? "&" : "?") + std::string("tx_description=") + epee::net_utils::conver_to_url_format(tx_description);
}
return uri;
}
//----------------------------------------------------------------------------------------------------
bool wallet2::parse_uri(const std::string &uri, std::string &address, std::string &payment_id, uint64_t &amount, std::string &tx_description, std::string &recipient_name, std::vector<std::string> &unknown_parameters, std::string &error)
{
if (uri.substr(0, 7) != "monero:")
{
error = std::string("URI has wrong scheme (expected \"monero:\"): ") + uri;
return false;
}
std::string remainder = uri.substr(7);
const char *ptr = strchr(remainder.c_str(), '?');
address = ptr ? remainder.substr(0, ptr-remainder.c_str()) : remainder;
cryptonote::address_parse_info info;
if(!get_account_address_from_str(info, nettype(), address))
{
error = std::string("URI has wrong address: ") + address;
return false;
}
if (!strchr(remainder.c_str(), '?'))
return true;
std::vector<std::string> arguments;
std::string body = remainder.substr(address.size() + 1);
if (body.empty())
return true;
boost::split(arguments, body, boost::is_any_of("&"));
std::set<std::string> have_arg;
for (const auto &arg: arguments)
{
std::vector<std::string> kv;
boost::split(kv, arg, boost::is_any_of("="));
if (kv.size() != 2)
{
error = std::string("URI has wrong parameter: ") + arg;
return false;
}
if (have_arg.find(kv[0]) != have_arg.end())
{
error = std::string("URI has more than one instance of " + kv[0]);
return false;
}
have_arg.insert(kv[0]);
if (kv[0] == "tx_amount")
{
amount = 0;
if (!cryptonote::parse_amount(amount, kv[1]))
{
error = std::string("URI has invalid amount: ") + kv[1];
return false;
}
}
else if (kv[0] == "tx_payment_id")
{
if (info.has_payment_id)
{
error = "Separate payment id given with an integrated address";
return false;
}
crypto::hash hash;
crypto::hash8 hash8;
if (!wallet2::parse_long_payment_id(kv[1], hash) && !wallet2::parse_short_payment_id(kv[1], hash8))
{
error = "Invalid payment id: " + kv[1];
return false;
}
payment_id = kv[1];
}
else if (kv[0] == "recipient_name")
{
recipient_name = epee::net_utils::convert_from_url_format(kv[1]);
}
else if (kv[0] == "tx_description")
{
tx_description = epee::net_utils::convert_from_url_format(kv[1]);
}
else
{
unknown_parameters.push_back(arg);
}
}
return true;
}
//----------------------------------------------------------------------------------------------------
uint64_t wallet2::get_blockchain_height_by_date(uint16_t year, uint8_t month, uint8_t day)
{
uint32_t version;
if (!check_connection(&version))
{
throw std::runtime_error("failed to connect to daemon: " + get_daemon_address());
}
if (version < MAKE_CORE_RPC_VERSION(1, 6))
{
throw std::runtime_error("this function requires RPC version 1.6 or higher");
}
std::tm date = { 0, 0, 0, 0, 0, 0, 0, 0 };
date.tm_year = year - 1900;
date.tm_mon = month - 1;
date.tm_mday = day;
if (date.tm_mon < 0 || 11 < date.tm_mon || date.tm_mday < 1 || 31 < date.tm_mday)
{
throw std::runtime_error("month or day out of range");
}
uint64_t timestamp_target = std::mktime(&date);
std::string err;
uint64_t height_min = 0;
uint64_t height_max = get_daemon_blockchain_height(err) - 1;
if (!err.empty())
{
throw std::runtime_error("failed to get blockchain height");
}
while (true)
{
COMMAND_RPC_GET_BLOCKS_BY_HEIGHT::request req;
COMMAND_RPC_GET_BLOCKS_BY_HEIGHT::response res;
uint64_t height_mid = (height_min + height_max) / 2;
req.heights =
{
height_min,
height_mid,
height_max
};
bool r = net_utils::invoke_http_bin("/getblocks_by_height.bin", req, res, m_http_client, rpc_timeout);
if (!r || res.status != CORE_RPC_STATUS_OK)
{
std::ostringstream oss;
oss << "failed to get blocks by heights: ";
for (auto height : req.heights)
oss << height << ' ';
oss << endl << "reason: ";
if (!r)
oss << "possibly lost connection to daemon";
else if (res.status == CORE_RPC_STATUS_BUSY)
oss << "daemon is busy";
else
oss << res.status;
throw std::runtime_error(oss.str());
}
cryptonote::block blk_min, blk_mid, blk_max;
if (res.blocks.size() < 3) throw std::runtime_error("Not enough blocks returned from daemon");
if (!parse_and_validate_block_from_blob(res.blocks[0].block, blk_min)) throw std::runtime_error("failed to parse blob at height " + std::to_string(height_min));
if (!parse_and_validate_block_from_blob(res.blocks[1].block, blk_mid)) throw std::runtime_error("failed to parse blob at height " + std::to_string(height_mid));
if (!parse_and_validate_block_from_blob(res.blocks[2].block, blk_max)) throw std::runtime_error("failed to parse blob at height " + std::to_string(height_max));
uint64_t timestamp_min = blk_min.timestamp;
uint64_t timestamp_mid = blk_mid.timestamp;
uint64_t timestamp_max = blk_max.timestamp;
if (!(timestamp_min <= timestamp_mid && timestamp_mid <= timestamp_max))
{
// the timestamps are not in the chronological order.
// assuming they're sufficiently close to each other, simply return the smallest height
return std::min({height_min, height_mid, height_max});
}
if (timestamp_target > timestamp_max)
{
throw std::runtime_error("specified date is in the future");
}
if (timestamp_target <= timestamp_min + 2 * 24 * 60 * 60) // two days of "buffer" period
{
return height_min;
}
if (timestamp_target <= timestamp_mid)
height_max = height_mid;
else
height_min = height_mid;
if (height_max - height_min <= 2 * 24 * 30) // don't divide the height range finer than two days
{
return height_min;
}
}
}
//----------------------------------------------------------------------------------------------------
bool wallet2::is_synced() const
{
uint64_t height;
boost::optional<std::string> result = m_node_rpc_proxy.get_target_height(height);
if (result && *result != CORE_RPC_STATUS_OK)
return false;
return get_blockchain_current_height() >= height;
}
//----------------------------------------------------------------------------------------------------
std::vector<std::pair<uint64_t, uint64_t>> wallet2::estimate_backlog(const std::vector<std::pair<double, double>> &fee_levels)
{
for (const auto &fee_level: fee_levels)
{
THROW_WALLET_EXCEPTION_IF(fee_level.first == 0.0, error::wallet_internal_error, "Invalid 0 fee");
THROW_WALLET_EXCEPTION_IF(fee_level.second == 0.0, error::wallet_internal_error, "Invalid 0 fee");
}
// get txpool backlog
cryptonote::COMMAND_RPC_GET_TRANSACTION_POOL_BACKLOG::request req = AUTO_VAL_INIT(req);
cryptonote::COMMAND_RPC_GET_TRANSACTION_POOL_BACKLOG::response res = AUTO_VAL_INIT(res);
m_daemon_rpc_mutex.lock();
bool r = net_utils::invoke_http_json_rpc("/json_rpc", "get_txpool_backlog", req, res, m_http_client, rpc_timeout);
m_daemon_rpc_mutex.unlock();
THROW_WALLET_EXCEPTION_IF(!r, error::no_connection_to_daemon, "Failed to connect to daemon");
THROW_WALLET_EXCEPTION_IF(res.status == CORE_RPC_STATUS_BUSY, error::daemon_busy, "get_txpool_backlog");
THROW_WALLET_EXCEPTION_IF(res.status != CORE_RPC_STATUS_OK, error::get_tx_pool_error);
uint64_t block_weight_limit = 0;
const auto result = m_node_rpc_proxy.get_block_weight_limit(block_weight_limit);
throw_on_rpc_response_error(result, "get_info");
uint64_t full_reward_zone = block_weight_limit / 2;
THROW_WALLET_EXCEPTION_IF(full_reward_zone == 0, error::wallet_internal_error, "Invalid block weight limit from daemon");
std::vector<std::pair<uint64_t, uint64_t>> blocks;
for (const auto &fee_level: fee_levels)
{
const double our_fee_byte_min = fee_level.first;
const double our_fee_byte_max = fee_level.second;
uint64_t priority_weight_min = 0, priority_weight_max = 0;
for (const auto &i: res.backlog)
{
if (i.weight == 0)
{
MWARNING("Got 0 weight tx from txpool, ignored");
continue;
}
double this_fee_byte = i.fee / (double)i.weight;
if (this_fee_byte >= our_fee_byte_min)
priority_weight_min += i.weight;
if (this_fee_byte >= our_fee_byte_max)
priority_weight_max += i.weight;
}
uint64_t nblocks_min = priority_weight_min / full_reward_zone;
uint64_t nblocks_max = priority_weight_max / full_reward_zone;
MDEBUG("estimate_backlog: priority_weight " << priority_weight_min << " - " << priority_weight_max << " for "
<< our_fee_byte_min << " - " << our_fee_byte_max << " piconero byte fee, "
<< nblocks_min << " - " << nblocks_max << " blocks at block weight " << full_reward_zone);
blocks.push_back(std::make_pair(nblocks_min, nblocks_max));
}
return blocks;
}
//----------------------------------------------------------------------------------------------------
std::vector<std::pair<uint64_t, uint64_t>> wallet2::estimate_backlog(uint64_t min_tx_weight, uint64_t max_tx_weight, const std::vector<uint64_t> &fees)
{
THROW_WALLET_EXCEPTION_IF(min_tx_weight == 0, error::wallet_internal_error, "Invalid 0 fee");
THROW_WALLET_EXCEPTION_IF(max_tx_weight == 0, error::wallet_internal_error, "Invalid 0 fee");
for (uint64_t fee: fees)
{
THROW_WALLET_EXCEPTION_IF(fee == 0, error::wallet_internal_error, "Invalid 0 fee");
}
std::vector<std::pair<double, double>> fee_levels;
for (uint64_t fee: fees)
{
double our_fee_byte_min = fee / (double)min_tx_weight, our_fee_byte_max = fee / (double)max_tx_weight;
fee_levels.emplace_back(our_fee_byte_min, our_fee_byte_max);
}
return estimate_backlog(fee_levels);
}
//----------------------------------------------------------------------------------------------------
uint64_t wallet2::get_segregation_fork_height() const
{
if (m_nettype == TESTNET)
return TESTNET_SEGREGATION_FORK_HEIGHT;
if (m_nettype == STAGENET)
return STAGENET_SEGREGATION_FORK_HEIGHT;
THROW_WALLET_EXCEPTION_IF(m_nettype != MAINNET, tools::error::wallet_internal_error, "Invalid network type");
if (m_segregation_height > 0)
return m_segregation_height;
static const bool use_dns = true;
if (use_dns)
{
// All four MoneroPulse domains have DNSSEC on and valid
static const std::vector<std::string> dns_urls = {
"segheights.moneropulse.org",
"segheights.moneropulse.net",
"segheights.moneropulse.co",
"segheights.moneropulse.se"
};
const uint64_t current_height = get_blockchain_current_height();
uint64_t best_diff = std::numeric_limits<uint64_t>::max(), best_height = 0;
std::vector<std::string> records;
if (tools::dns_utils::load_txt_records_from_dns(records, dns_urls))
{
for (const auto& record : records)
{
std::vector<std::string> fields;
boost::split(fields, record, boost::is_any_of(":"));
if (fields.size() != 2)
continue;
uint64_t height;
if (!string_tools::get_xtype_from_string(height, fields[1]))
continue;
MINFO("Found segregation height via DNS: " << fields[0] << " fork height at " << height);
uint64_t diff = height > current_height ? height - current_height : current_height - height;
if (diff < best_diff)
{
best_diff = diff;
best_height = height;
}
}
if (best_height)
return best_height;
}
}
return SEGREGATION_FORK_HEIGHT;
}
//----------------------------------------------------------------------------------------------------
void wallet2::generate_genesis(cryptonote::block& b) const {
cryptonote::generate_genesis_block(b, get_config(m_nettype).GENESIS_TX, get_config(m_nettype).GENESIS_NONCE);
}
}