derive multisig tx secret keys from an entropy source plus the tx inputs' key images

This commit is contained in:
koe 2022-04-30 16:54:24 -05:00
parent cfdee9ba69
commit edcc094558
6 changed files with 147 additions and 15 deletions

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@ -246,6 +246,8 @@ namespace config
const unsigned char HASH_KEY_CLSAG_AGG_1[] = "CLSAG_agg_1";
const char HASH_KEY_MESSAGE_SIGNING[] = "MoneroMessageSignature";
const unsigned char HASH_KEY_MM_SLOT = 'm';
const constexpr char HASH_KEY_MULTISIG_TX_PRIVKEYS_SEED[] = "multisig_tx_privkeys_seed";
const constexpr char HASH_KEY_MULTISIG_TX_PRIVKEYS[] = "multisig_tx_privkeys";
// Multisig
const uint32_t MULTISIG_MAX_SIGNERS{16};

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@ -34,6 +34,7 @@
#include "cryptonote_basic/cryptonote_basic.h"
#include "cryptonote_basic/account.h"
#include "cryptonote_basic/cryptonote_format_utils.h"
#include "cryptonote_config.h"
#include "cryptonote_core/cryptonote_tx_utils.h"
#include "device/device.hpp"
#include "multisig_clsag_context.h"
@ -47,6 +48,7 @@
#include <cstring>
#include <limits>
#include <set>
#include <string>
#include <unordered_map>
#include <unordered_set>
#include <vector>
@ -242,6 +244,80 @@ static bool set_tx_extra(
}
//----------------------------------------------------------------------------------------------------------------------
//----------------------------------------------------------------------------------------------------------------------
static void make_tx_secret_key_seed(const crypto::secret_key& tx_secret_key_entropy,
const std::vector<cryptonote::tx_source_entry>& sources,
crypto::secret_key& tx_secret_key_seed)
{
// seed = H(H("domain separator"), entropy, {KI})
static const std::string domain_separator{config::HASH_KEY_MULTISIG_TX_PRIVKEYS_SEED};
rct::keyV hash_context;
hash_context.reserve(2 + sources.size());
auto hash_context_wiper = epee::misc_utils::create_scope_leave_handler([&]{
memwipe(hash_context.data(), hash_context.size());
});
hash_context.emplace_back();
rct::cn_fast_hash(hash_context.back(), domain_separator.data(), domain_separator.size()); //domain sep
hash_context.emplace_back(rct::sk2rct(tx_secret_key_entropy)); //entropy
for (const cryptonote::tx_source_entry& source : sources)
hash_context.emplace_back(source.multisig_kLRki.ki); //{KI}
// set the seed
tx_secret_key_seed = rct::rct2sk(rct::cn_fast_hash(hash_context));
}
//----------------------------------------------------------------------------------------------------------------------
//----------------------------------------------------------------------------------------------------------------------
static void make_tx_secret_keys(const crypto::secret_key& tx_secret_key_seed,
const std::size_t num_tx_keys,
std::vector<crypto::secret_key>& tx_secret_keys)
{
// make tx secret keys as a hash chain of the seed
// h1 = H_n(seed || H("domain separator"))
// h2 = H_n(seed || h1)
// h3 = H_n(seed || h2)
// ...
static const std::string domain_separator{config::HASH_KEY_MULTISIG_TX_PRIVKEYS};
rct::keyV hash_context;
hash_context.resize(2);
auto hash_context_wiper = epee::misc_utils::create_scope_leave_handler([&]{
memwipe(hash_context.data(), hash_context.size());
});
hash_context[0] = rct::sk2rct(tx_secret_key_seed);
rct::cn_fast_hash(hash_context[1], domain_separator.data(), domain_separator.size());
tx_secret_keys.clear();
tx_secret_keys.resize(num_tx_keys);
for (crypto::secret_key& tx_secret_key : tx_secret_keys)
{
// advance the hash chain
hash_context[1] = rct::hash_to_scalar(hash_context);
// set this key
tx_secret_key = rct::rct2sk(hash_context[1]);
}
}
//----------------------------------------------------------------------------------------------------------------------
//----------------------------------------------------------------------------------------------------------------------
static bool collect_tx_secret_keys(const std::vector<crypto::secret_key>& tx_secret_keys,
crypto::secret_key& tx_secret_key,
std::vector<crypto::secret_key>& tx_aux_secret_keys)
{
if (tx_secret_keys.size() == 0)
return false;
tx_secret_key = tx_secret_keys[0];
tx_aux_secret_keys.clear();
tx_aux_secret_keys.reserve(tx_secret_keys.size() - 1);
for (std::size_t tx_key_index{1}; tx_key_index < tx_secret_keys.size(); ++tx_key_index)
tx_aux_secret_keys.emplace_back(tx_secret_keys[tx_key_index]);
return true;
}
//----------------------------------------------------------------------------------------------------------------------
//----------------------------------------------------------------------------------------------------------------------
static bool compute_keys_for_destinations(
const cryptonote::account_keys& account_keys,
const std::uint32_t subaddr_account,
@ -250,6 +326,7 @@ static bool compute_keys_for_destinations(
const std::vector<std::uint8_t>& extra,
const bool use_view_tags,
const bool reconstruction,
const crypto::secret_key& tx_secret_key_seed,
crypto::secret_key& tx_secret_key,
std::vector<crypto::secret_key>& tx_aux_secret_keys,
rct::keyV& output_public_keys,
@ -288,8 +365,35 @@ static bool compute_keys_for_destinations(
unique_std_recipients.insert(dst_entr.addr);
}
if (not reconstruction) {
tx_secret_key = rct::rct2sk(rct::skGen());
// figure out how many tx secret keys are needed
// - tx aux keys: add if there are > 1 non-change recipients, with at least one to a subaddress
const std::size_t num_destinations = destinations.size();
const bool need_tx_aux_keys = unique_subbaddr_recipients.size() + bool(unique_std_recipients.size()) > 1;
const std::size_t num_tx_keys = 1 + (need_tx_aux_keys ? num_destinations : 0);
// make tx secret keys
std::vector<crypto::secret_key> all_tx_secret_keys;
make_tx_secret_keys(tx_secret_key_seed, num_tx_keys, all_tx_secret_keys);
// split up tx secret keys
crypto::secret_key tx_secret_key_temp;
std::vector<crypto::secret_key> tx_aux_secret_keys_temp;
if (not collect_tx_secret_keys(all_tx_secret_keys, tx_secret_key_temp, tx_aux_secret_keys_temp))
return false;
if (reconstruction)
{
// when reconstructing, the tx secret keys should be reproducible from input seed
if (!(tx_secret_key == tx_secret_key_temp))
return false;
if (!(tx_aux_secret_keys == tx_aux_secret_keys_temp))
return false;
}
else
{
tx_secret_key = tx_secret_key_temp;
tx_aux_secret_keys = std::move(tx_aux_secret_keys_temp);
}
// tx pub key: R
@ -312,17 +416,6 @@ static bool compute_keys_for_destinations(
}
// additional tx pubkeys: R_t
// - add if there are > 1 non-change recipients, with at least one to a subaddress
const std::size_t num_destinations = destinations.size();
const bool need_tx_aux_keys = unique_subbaddr_recipients.size() + bool(unique_std_recipients.size()) > 1;
if (not reconstruction and need_tx_aux_keys) {
tx_aux_secret_keys.clear();
tx_aux_secret_keys.reserve(num_destinations);
for(std::size_t i = 0; i < num_destinations; ++i)
tx_aux_secret_keys.push_back(rct::rct2sk(rct::skGen()));
}
output_public_keys.resize(num_destinations);
view_tags.resize(num_destinations);
std::vector<crypto::public_key> tx_aux_public_keys;
@ -738,6 +831,7 @@ bool tx_builder_ringct_t::init(
const bool reconstruction,
crypto::secret_key& tx_secret_key,
std::vector<crypto::secret_key>& tx_aux_secret_keys,
crypto::secret_key& tx_secret_key_entropy,
cryptonote::transaction& unsigned_tx
)
{
@ -765,6 +859,23 @@ bool tx_builder_ringct_t::init(
// sort inputs
sort_sources(sources);
// prepare tx secret key seed (must be AFTER sorting sources)
// - deriving the seed from sources plus entropy ensures uniqueness for every new tx attempt
// - the goal is that two multisig txs added to the chain will never have outputs with the same onetime addresses,
// which would burn funds (embedding the inputs' key images guarantees this)
// - it is acceptable if two tx attempts use the same input set and entropy (only a malicious tx proposer will do
// that, but all it can accomplish is leaking information about the recipients - which a malicious proposer can
// easily do outside the signing ritual anyway)
if (not reconstruction)
tx_secret_key_entropy = rct::rct2sk(rct::skGen());
// expect not null (note: wallet serialization code may set this to null if handling an old partial tx)
if (tx_secret_key_entropy == crypto::null_skey)
return false;
crypto::secret_key tx_secret_key_seed;
make_tx_secret_key_seed(tx_secret_key_entropy, sources, tx_secret_key_seed);
// get secret keys for signing input CLSAGs (multisig: or for the initial partial signature)
rct::keyV input_secret_keys;
auto input_secret_keys_wiper = epee::misc_utils::create_scope_leave_handler([&]{
@ -791,6 +902,7 @@ bool tx_builder_ringct_t::init(
extra,
use_view_tags,
reconstruction,
tx_secret_key_seed,
tx_secret_key,
tx_aux_secret_keys,
output_public_keys,
@ -921,6 +1033,7 @@ bool tx_builder_ringct_t::finalize_tx(
cryptonote::transaction& unsigned_tx
)
{
// checks
const std::size_t num_sources = sources.size();
if (num_sources != unsigned_tx.rct_signatures.p.CLSAGs.size())
return false;
@ -928,6 +1041,8 @@ bool tx_builder_ringct_t::finalize_tx(
return false;
if (num_sources != s.size())
return false;
// finalize tx signatures
for (std::size_t i = 0; i < num_sources; ++i) {
const std::size_t ring_size = unsigned_tx.rct_signatures.p.CLSAGs[i].s.size();
if (sources[i].real_output >= ring_size)
@ -935,6 +1050,7 @@ bool tx_builder_ringct_t::finalize_tx(
unsigned_tx.rct_signatures.p.CLSAGs[i].s[sources[i].real_output] = s[i];
unsigned_tx.rct_signatures.p.CLSAGs[i].c1 = c_0[i];
}
return true;
}
//----------------------------------------------------------------------------------------------------------------------

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@ -82,6 +82,7 @@ public:
const bool reconstruction,
crypto::secret_key& tx_secret_key,
std::vector<crypto::secret_key>& tx_aux_secret_keys,
crypto::secret_key& tx_secret_key_entropy,
cryptonote::transaction& unsigned_tx
);

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@ -7157,6 +7157,7 @@ bool wallet2::sign_multisig_tx(multisig_tx_set &exported_txs, std::vector<crypto
true, //true = we are reconstructing the tx (it was first constructed by the tx proposer)
ptx.tx_key,
ptx.additional_tx_keys,
ptx.multisig_tx_key_entropy,
ptx.tx
),
error::wallet_internal_error,
@ -9006,6 +9007,7 @@ void wallet2::transfer_selected_rct(std::vector<cryptonote::tx_destination_entry
crypto::secret_key tx_key;
std::vector<crypto::secret_key> additional_tx_keys;
crypto::secret_key multisig_tx_key_entropy;
LOG_PRINT_L2("constructing tx");
auto sources_copy = sources;
multisig::signing::tx_builder_ringct_t multisig_tx_builder;
@ -9029,6 +9031,7 @@ void wallet2::transfer_selected_rct(std::vector<cryptonote::tx_destination_entry
false,
tx_key,
additional_tx_keys,
multisig_tx_key_entropy,
tx
),
error::wallet_internal_error,
@ -9155,6 +9158,7 @@ void wallet2::transfer_selected_rct(std::vector<cryptonote::tx_destination_entry
ptx.additional_tx_keys = additional_tx_keys;
ptx.dests = dsts;
ptx.multisig_sigs = multisig_sigs;
ptx.multisig_tx_key_entropy = multisig_tx_key_entropy;
ptx.construction_data.sources = sources_copy;
ptx.construction_data.change_dts = change_dts;
ptx.construction_data.splitted_dsts = splitted_dsts;

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@ -632,10 +632,12 @@ private:
std::vector<crypto::secret_key> additional_tx_keys;
std::vector<cryptonote::tx_destination_entry> dests;
std::vector<multisig_sig> multisig_sigs;
crypto::secret_key multisig_tx_key_entropy;
tx_construction_data construction_data;
BEGIN_SERIALIZE_OBJECT()
VERSION_FIELD(1)
FIELD(tx)
FIELD(dust)
FIELD(fee)
@ -648,6 +650,12 @@ private:
FIELD(dests)
FIELD(construction_data)
FIELD(multisig_sigs)
if (version < 1)
{
multisig_tx_key_entropy = crypto::null_skey;
return true;
}
FIELD(multisig_tx_key_entropy)
END_SERIALIZE()
};

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@ -307,9 +307,10 @@ bool gen_multisig_tx_validation_base::generate_with(std::vector<test_event_entry
transaction tx;
crypto::secret_key tx_key;
std::vector<crypto::secret_key> additional_tx_secret_keys;
crypto::secret_key multisig_tx_key_entropy;
auto sources_copy = sources;
multisig::signing::tx_builder_ringct_t tx_builder;
CHECK_AND_ASSERT_MES(tx_builder.init(miner_account[creator].get_keys(), {}, 0, 0, {0}, sources, destinations, {}, {rct::RangeProofPaddedBulletproof, 4}, true, false, tx_key, additional_tx_secret_keys, tx), false, "error: multisig::signing::tx_builder_t::init");
CHECK_AND_ASSERT_MES(tx_builder.init(miner_account[creator].get_keys(), {}, 0, 0, {0}, sources, destinations, {}, {rct::RangeProofPaddedBulletproof, 4}, true, false, tx_key, additional_tx_secret_keys, multisig_tx_key_entropy, tx), false, "error: multisig::signing::tx_builder_ringct_t::init");
// work out the permutation done on sources
std::vector<size_t> ins_order;
@ -398,7 +399,7 @@ bool gen_multisig_tx_validation_base::generate_with(std::vector<test_event_entry
}
tools::apply_permutation(ins_order, k);
multisig::signing::tx_builder_ringct_t signer_tx_builder;
CHECK_AND_ASSERT_MES(signer_tx_builder.init(miner_account[signer].get_keys(), {}, 0, 0, {0}, sources, destinations, {}, {rct::RangeProofPaddedBulletproof, 4}, true, true, tx_key, additional_tx_secret_keys, tx), false, "error: multisig::signing::tx_builder_t::init");
CHECK_AND_ASSERT_MES(signer_tx_builder.init(miner_account[signer].get_keys(), {}, 0, 0, {0}, sources, destinations, {}, {rct::RangeProofPaddedBulletproof, 4}, true, true, tx_key, additional_tx_secret_keys, multisig_tx_key_entropy, tx), false, "error: multisig::signing::tx_builder_ringct_t::init");
MDEBUG("signing with k size " << k.size());
for (size_t n = 0; n < multisig::signing::kAlphaComponents; ++n)