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// Copyright (c) 2022 The Bitcoin Core developers
// Distributed under the MIT software license, see the accompanying
// file COPYING or http://www.opensource.org/licenses/mit-license.php.
#include <node/txreconciliation.h>
#include <util/check.h>
#include <util/system.h>
#include <unordered_map>
#include <variant>
namespace {
/** Static salt component used to compute short txids for sketch construction, see BIP-330. */
const std::string RECON_STATIC_SALT = "Tx Relay Salting";
const HashWriter RECON_SALT_HASHER = TaggedHash(RECON_STATIC_SALT);
/**
* Salt (specified by BIP-330) constructed from contributions from both peers. It is used
* to compute transaction short IDs, which are then used to construct a sketch representing a set
* of transactions we want to announce to the peer.
*/
uint256 ComputeSalt(uint64_t salt1, uint64_t salt2)
{
// According to BIP-330, salts should be combined in ascending order.
return (HashWriter(RECON_SALT_HASHER) << std::min(salt1, salt2) << std::max(salt1, salt2)).GetSHA256();
}
/**
* Keeps track of txreconciliation-related per-peer state.
*/
class TxReconciliationState
{
public:
/**
* TODO: This field is public to ignore -Wunused-private-field. Make private once used in
* the following commits.
*
* Reconciliation protocol assumes using one role consistently: either a reconciliation
* initiator (requesting sketches), or responder (sending sketches). This defines our role,
* based on the direction of the p2p connection.
*
*/
bool m_we_initiate;
/**
* TODO: These fields are public to ignore -Wunused-private-field. Make private once used in
* the following commits.
*
* These values are used to salt short IDs, which is necessary for transaction reconciliations.
*/
uint64_t m_k0, m_k1;
TxReconciliationState(bool we_initiate, uint64_t k0, uint64_t k1) : m_we_initiate(we_initiate), m_k0(k0), m_k1(k1) {}
};
} // namespace
/** Actual implementation for TxReconciliationTracker's data structure. */
class TxReconciliationTracker::Impl
{
private:
mutable Mutex m_txreconciliation_mutex;
// Local protocol version
uint32_t m_recon_version;
/**
* Keeps track of txreconciliation states of eligible peers.
* For pre-registered peers, the locally generated salt is stored.
* For registered peers, the locally generated salt is forgotten, and the state (including
* "full" salt) is stored instead.
*/
std::unordered_map<NodeId, std::variant<uint64_t, TxReconciliationState>> m_states GUARDED_BY(m_txreconciliation_mutex);
public:
explicit Impl(uint32_t recon_version) : m_recon_version(recon_version) {}
uint64_t PreRegisterPeer(NodeId peer_id) EXCLUSIVE_LOCKS_REQUIRED(!m_txreconciliation_mutex)
{
AssertLockNotHeld(m_txreconciliation_mutex);
LOCK(m_txreconciliation_mutex);
LogPrintLevel(BCLog::TXRECONCILIATION, BCLog::Level::Debug, "Pre-register peer=%d\n", peer_id);
const uint64_t local_salt{GetRand(UINT64_MAX)};
// We do this exactly once per peer (which are unique by NodeId, see GetNewNodeId) so it's
// safe to assume we don't have this record yet.
Assume(m_states.emplace(peer_id, local_salt).second);
return local_salt;
}
ReconciliationRegisterResult RegisterPeer(NodeId peer_id, bool is_peer_inbound, uint32_t peer_recon_version,
uint64_t remote_salt) EXCLUSIVE_LOCKS_REQUIRED(!m_txreconciliation_mutex)
{
AssertLockNotHeld(m_txreconciliation_mutex);
LOCK(m_txreconciliation_mutex);
auto recon_state = m_states.find(peer_id);
if (recon_state == m_states.end()) return ReconciliationRegisterResult::NOT_FOUND;
if (std::holds_alternative<TxReconciliationState>(recon_state->second)) {
return ReconciliationRegisterResult::ALREADY_REGISTERED;
}
uint64_t local_salt = *std::get_if<uint64_t>(&recon_state->second);
// If the peer supports the version which is lower than ours, we downgrade to the version
// it supports. For now, this only guarantees that nodes with future reconciliation
// versions have the choice of reconciling with this current version. However, they also
// have the choice to refuse supporting reconciliations if the common version is not
// satisfactory (e.g. too low).
const uint32_t recon_version{std::min(peer_recon_version, m_recon_version)};
// v1 is the lowest version, so suggesting something below must be a protocol violation.
if (recon_version < 1) return ReconciliationRegisterResult::PROTOCOL_VIOLATION;
LogPrintLevel(BCLog::TXRECONCILIATION, BCLog::Level::Debug, "Register peer=%d (inbound=%i)\n",
peer_id, is_peer_inbound);
const uint256 full_salt{ComputeSalt(local_salt, remote_salt)};
recon_state->second = TxReconciliationState(!is_peer_inbound, full_salt.GetUint64(0), full_salt.GetUint64(1));
return ReconciliationRegisterResult::SUCCESS;
}
void ForgetPeer(NodeId peer_id) EXCLUSIVE_LOCKS_REQUIRED(!m_txreconciliation_mutex)
{
AssertLockNotHeld(m_txreconciliation_mutex);
LOCK(m_txreconciliation_mutex);
if (m_states.erase(peer_id)) {
LogPrintLevel(BCLog::TXRECONCILIATION, BCLog::Level::Debug, "Forget txreconciliation state of peer=%d\n", peer_id);
}
}
bool IsPeerRegistered(NodeId peer_id) const EXCLUSIVE_LOCKS_REQUIRED(!m_txreconciliation_mutex)
{
AssertLockNotHeld(m_txreconciliation_mutex);
LOCK(m_txreconciliation_mutex);
auto recon_state = m_states.find(peer_id);
return (recon_state != m_states.end() &&
std::holds_alternative<TxReconciliationState>(recon_state->second));
}
};
TxReconciliationTracker::TxReconciliationTracker(uint32_t recon_version) : m_impl{std::make_unique<TxReconciliationTracker::Impl>(recon_version)} {}
TxReconciliationTracker::~TxReconciliationTracker() = default;
uint64_t TxReconciliationTracker::PreRegisterPeer(NodeId peer_id)
{
return m_impl->PreRegisterPeer(peer_id);
}
ReconciliationRegisterResult TxReconciliationTracker::RegisterPeer(NodeId peer_id, bool is_peer_inbound,
uint32_t peer_recon_version, uint64_t remote_salt)
{
return m_impl->RegisterPeer(peer_id, is_peer_inbound, peer_recon_version, remote_salt);
}
void TxReconciliationTracker::ForgetPeer(NodeId peer_id)
{
m_impl->ForgetPeer(peer_id);
}
bool TxReconciliationTracker::IsPeerRegistered(NodeId peer_id) const
{
return m_impl->IsPeerRegistered(peer_id);
}
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