// Copyright (c) 2020-2021 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 #include #include #include #include #include #include #include #include #include #include #include namespace { /** The various states a (txhash,peer) pair can be in. * * Note that CANDIDATE is split up into 3 substates (DELAYED, BEST, READY), allowing more efficient implementation. * Also note that the sorting order of ByTxHashView relies on the specific order of values in this enum. * * Expected behaviour is: * - When first announced by a peer, the state is CANDIDATE_DELAYED until reqtime is reached. * - Announcements that have reached their reqtime but not been requested will be either CANDIDATE_READY or * CANDIDATE_BEST. Neither of those has an expiration time; they remain in that state until they're requested or * no longer needed. CANDIDATE_READY announcements are promoted to CANDIDATE_BEST when they're the best one left. * - When requested, an announcement will be in state REQUESTED until expiry is reached. * - If expiry is reached, or the peer replies to the request (either with NOTFOUND or the tx), the state becomes * COMPLETED. */ enum class State : uint8_t { /** A CANDIDATE announcement whose reqtime is in the future. */ CANDIDATE_DELAYED, /** A CANDIDATE announcement that's not CANDIDATE_DELAYED or CANDIDATE_BEST. */ CANDIDATE_READY, /** The best CANDIDATE for a given txhash; only if there is no REQUESTED announcement already for that txhash. * The CANDIDATE_BEST is the highest-priority announcement among all CANDIDATE_READY (and _BEST) ones for that * txhash. */ CANDIDATE_BEST, /** A REQUESTED announcement. */ REQUESTED, /** A COMPLETED announcement. */ COMPLETED, }; //! Type alias for sequence numbers. using SequenceNumber = uint64_t; /** An announcement. This is the data we track for each txid or wtxid that is announced to us by each peer. */ struct Announcement { /** Txid or wtxid that was announced. */ const uint256 m_txhash; /** For CANDIDATE_{DELAYED,BEST,READY} the reqtime; for REQUESTED the expiry. */ std::chrono::microseconds m_time; /** What peer the request was from. */ const NodeId m_peer; /** What sequence number this announcement has. */ const SequenceNumber m_sequence : 59; /** Whether the request is preferred. */ const bool m_preferred : 1; /** Whether this is a wtxid request. */ const bool m_is_wtxid : 1; /** What state this announcement is in. * This is a uint8_t instead of a State to silence a GCC warning in versions prior to 9.3. * See https://gcc.gnu.org/bugzilla/show_bug.cgi?id=61414 */ uint8_t m_state : 3; /** Convert m_state to a State enum. */ State GetState() const { return static_cast(m_state); } /** Convert a State enum to a uint8_t and store it in m_state. */ void SetState(State state) { m_state = static_cast(state); } /** Whether this announcement is selected. There can be at most 1 selected peer per txhash. */ bool IsSelected() const { return GetState() == State::CANDIDATE_BEST || GetState() == State::REQUESTED; } /** Whether this announcement is waiting for a certain time to pass. */ bool IsWaiting() const { return GetState() == State::REQUESTED || GetState() == State::CANDIDATE_DELAYED; } /** Whether this announcement can feasibly be selected if the current IsSelected() one disappears. */ bool IsSelectable() const { return GetState() == State::CANDIDATE_READY || GetState() == State::CANDIDATE_BEST; } /** Construct a new announcement from scratch, initially in CANDIDATE_DELAYED state. */ Announcement(const GenTxid& gtxid, NodeId peer, bool preferred, std::chrono::microseconds reqtime, SequenceNumber sequence) : m_txhash(gtxid.GetHash()), m_time(reqtime), m_peer(peer), m_sequence(sequence), m_preferred(preferred), m_is_wtxid(gtxid.IsWtxid()), m_state(static_cast(State::CANDIDATE_DELAYED)) {} }; //! Type alias for priorities. using Priority = uint64_t; /** A functor with embedded salt that computes priority of an announcement. * * Higher priorities are selected first. */ class PriorityComputer { const uint64_t m_k0, m_k1; public: explicit PriorityComputer(bool deterministic) : m_k0{deterministic ? 0 : GetRand(0xFFFFFFFFFFFFFFFF)}, m_k1{deterministic ? 0 : GetRand(0xFFFFFFFFFFFFFFFF)} {} Priority operator()(const uint256& txhash, NodeId peer, bool preferred) const { uint64_t low_bits = CSipHasher(m_k0, m_k1).Write(txhash.begin(), txhash.size()).Write(peer).Finalize() >> 1; return low_bits | uint64_t{preferred} << 63; } Priority operator()(const Announcement& ann) const { return operator()(ann.m_txhash, ann.m_peer, ann.m_preferred); } }; // Definitions for the 3 indexes used in the main data structure. // // Each index has a By* type to identify it, a By*View data type to represent the view of announcement it is sorted // by, and an By*ViewExtractor type to convert an announcement into the By*View type. // See https://www.boost.org/doc/libs/1_58_0/libs/multi_index/doc/reference/key_extraction.html#key_extractors // for more information about the key extraction concept. // The ByPeer index is sorted by (peer, state == CANDIDATE_BEST, txhash) // // Uses: // * Looking up existing announcements by peer/txhash, by checking both (peer, false, txhash) and // (peer, true, txhash). // * Finding all CANDIDATE_BEST announcements for a given peer in GetRequestable. struct ByPeer {}; using ByPeerView = std::tuple; struct ByPeerViewExtractor { using result_type = ByPeerView; result_type operator()(const Announcement& ann) const { return ByPeerView{ann.m_peer, ann.GetState() == State::CANDIDATE_BEST, ann.m_txhash}; } }; // The ByTxHash index is sorted by (txhash, state, priority). // // Note: priority == 0 whenever state != CANDIDATE_READY. // // Uses: // * Deleting all announcements with a given txhash in ForgetTxHash. // * Finding the best CANDIDATE_READY to convert to CANDIDATE_BEST, when no other CANDIDATE_READY or REQUESTED // announcement exists for that txhash. // * Determining when no more non-COMPLETED announcements for a given txhash exist, so the COMPLETED ones can be // deleted. struct ByTxHash {}; using ByTxHashView = std::tuple; class ByTxHashViewExtractor { const PriorityComputer& m_computer; public: explicit ByTxHashViewExtractor(const PriorityComputer& computer) : m_computer(computer) {} using result_type = ByTxHashView; result_type operator()(const Announcement& ann) const { const Priority prio = (ann.GetState() == State::CANDIDATE_READY) ? m_computer(ann) : 0; return ByTxHashView{ann.m_txhash, ann.GetState(), prio}; } }; enum class WaitState { //! Used for announcements that need efficient testing of "is their timestamp in the future?". FUTURE_EVENT, //! Used for announcements whose timestamp is not relevant. NO_EVENT, //! Used for announcements that need efficient testing of "is their timestamp in the past?". PAST_EVENT, }; WaitState GetWaitState(const Announcement& ann) { if (ann.IsWaiting()) return WaitState::FUTURE_EVENT; if (ann.IsSelectable()) return WaitState::PAST_EVENT; return WaitState::NO_EVENT; } // The ByTime index is sorted by (wait_state, time). // // All announcements with a timestamp in the future can be found by iterating the index forward from the beginning. // All announcements with a timestamp in the past can be found by iterating the index backwards from the end. // // Uses: // * Finding CANDIDATE_DELAYED announcements whose reqtime has passed, and REQUESTED announcements whose expiry has // passed. // * Finding CANDIDATE_READY/BEST announcements whose reqtime is in the future (when the clock time went backwards). struct ByTime {}; using ByTimeView = std::pair; struct ByTimeViewExtractor { using result_type = ByTimeView; result_type operator()(const Announcement& ann) const { return ByTimeView{GetWaitState(ann), ann.m_time}; } }; /** Data type for the main data structure (Announcement objects with ByPeer/ByTxHash/ByTime indexes). */ using Index = boost::multi_index_container< Announcement, boost::multi_index::indexed_by< boost::multi_index::ordered_unique, ByPeerViewExtractor>, boost::multi_index::ordered_non_unique, ByTxHashViewExtractor>, boost::multi_index::ordered_non_unique, ByTimeViewExtractor> > >; /** Helper type to simplify syntax of iterator types. */ template using Iter = typename Index::index::type::iterator; /** Per-peer statistics object. */ struct PeerInfo { size_t m_total = 0; //!< Total number of announcements for this peer. size_t m_completed = 0; //!< Number of COMPLETED announcements for this peer. size_t m_requested = 0; //!< Number of REQUESTED announcements for this peer. }; /** Per-txhash statistics object. Only used for sanity checking. */ struct TxHashInfo { //! Number of CANDIDATE_DELAYED announcements for this txhash. size_t m_candidate_delayed = 0; //! Number of CANDIDATE_READY announcements for this txhash. size_t m_candidate_ready = 0; //! Number of CANDIDATE_BEST announcements for this txhash (at most one). size_t m_candidate_best = 0; //! Number of REQUESTED announcements for this txhash (at most one; mutually exclusive with CANDIDATE_BEST). size_t m_requested = 0; //! The priority of the CANDIDATE_BEST announcement if one exists, or max() otherwise. Priority m_priority_candidate_best = std::numeric_limits::max(); //! The highest priority of all CANDIDATE_READY announcements (or min() if none exist). Priority m_priority_best_candidate_ready = std::numeric_limits::min(); //! All peers we have an announcement for this txhash for. std::vector m_peers; }; /** Compare two PeerInfo objects. Only used for sanity checking. */ bool operator==(const PeerInfo& a, const PeerInfo& b) { return std::tie(a.m_total, a.m_completed, a.m_requested) == std::tie(b.m_total, b.m_completed, b.m_requested); }; /** (Re)compute the PeerInfo map from the index. Only used for sanity checking. */ std::unordered_map RecomputePeerInfo(const Index& index) { std::unordered_map ret; for (const Announcement& ann : index) { PeerInfo& info = ret[ann.m_peer]; ++info.m_total; info.m_requested += (ann.GetState() == State::REQUESTED); info.m_completed += (ann.GetState() == State::COMPLETED); } return ret; } /** Compute the TxHashInfo map. Only used for sanity checking. */ std::map ComputeTxHashInfo(const Index& index, const PriorityComputer& computer) { std::map ret; for (const Announcement& ann : index) { TxHashInfo& info = ret[ann.m_txhash]; // Classify how many announcements of each state we have for this txhash. info.m_candidate_delayed += (ann.GetState() == State::CANDIDATE_DELAYED); info.m_candidate_ready += (ann.GetState() == State::CANDIDATE_READY); info.m_candidate_best += (ann.GetState() == State::CANDIDATE_BEST); info.m_requested += (ann.GetState() == State::REQUESTED); // And track the priority of the best CANDIDATE_READY/CANDIDATE_BEST announcements. if (ann.GetState() == State::CANDIDATE_BEST) { info.m_priority_candidate_best = computer(ann); } if (ann.GetState() == State::CANDIDATE_READY) { info.m_priority_best_candidate_ready = std::max(info.m_priority_best_candidate_ready, computer(ann)); } // Also keep track of which peers this txhash has an announcement for (so we can detect duplicates). info.m_peers.push_back(ann.m_peer); } return ret; } GenTxid ToGenTxid(const Announcement& ann) { return ann.m_is_wtxid ? GenTxid::Wtxid(ann.m_txhash) : GenTxid::Txid(ann.m_txhash); } } // namespace /** Actual implementation for TxRequestTracker's data structure. */ class TxRequestTracker::Impl { //! The current sequence number. Increases for every announcement. This is used to sort txhashes returned by //! GetRequestable in announcement order. SequenceNumber m_current_sequence{0}; //! This tracker's priority computer. const PriorityComputer m_computer; //! This tracker's main data structure. See SanityCheck() for the invariants that apply to it. Index m_index; //! Map with this tracker's per-peer statistics. std::unordered_map m_peerinfo; public: void SanityCheck() const { // Recompute m_peerdata from m_index. This verifies the data in it as it should just be caching statistics // on m_index. It also verifies the invariant that no PeerInfo announcements with m_total==0 exist. assert(m_peerinfo == RecomputePeerInfo(m_index)); // Calculate per-txhash statistics from m_index, and validate invariants. for (auto& item : ComputeTxHashInfo(m_index, m_computer)) { TxHashInfo& info = item.second; // Cannot have only COMPLETED peer (txhash should have been forgotten already) assert(info.m_candidate_delayed + info.m_candidate_ready + info.m_candidate_best + info.m_requested > 0); // Can have at most 1 CANDIDATE_BEST/REQUESTED peer assert(info.m_candidate_best + info.m_requested <= 1); // If there are any CANDIDATE_READY announcements, there must be exactly one CANDIDATE_BEST or REQUESTED // announcement. if (info.m_candidate_ready > 0) { assert(info.m_candidate_best + info.m_requested == 1); } // If there is both a CANDIDATE_READY and a CANDIDATE_BEST announcement, the CANDIDATE_BEST one must be // at least as good (equal or higher priority) as the best CANDIDATE_READY. if (info.m_candidate_ready && info.m_candidate_best) { assert(info.m_priority_candidate_best >= info.m_priority_best_candidate_ready); } // No txhash can have been announced by the same peer twice. std::sort(info.m_peers.begin(), info.m_peers.end()); assert(std::adjacent_find(info.m_peers.begin(), info.m_peers.end()) == info.m_peers.end()); } } void PostGetRequestableSanityCheck(std::chrono::microseconds now) const { for (const Announcement& ann : m_index) { if (ann.IsWaiting()) { // REQUESTED and CANDIDATE_DELAYED must have a time in the future (they should have been converted // to COMPLETED/CANDIDATE_READY respectively). assert(ann.m_time > now); } else if (ann.IsSelectable()) { // CANDIDATE_READY and CANDIDATE_BEST cannot have a time in the future (they should have remained // CANDIDATE_DELAYED, or should have been converted back to it if time went backwards). assert(ann.m_time <= now); } } } private: //! Wrapper around Index::...::erase that keeps m_peerinfo up to date. template Iter Erase(Iter it) { auto peerit = m_peerinfo.find(it->m_peer); peerit->second.m_completed -= it->GetState() == State::COMPLETED; peerit->second.m_requested -= it->GetState() == State::REQUESTED; if (--peerit->second.m_total == 0) m_peerinfo.erase(peerit); return m_index.get().erase(it); } //! Wrapper around Index::...::modify that keeps m_peerinfo up to date. template void Modify(Iter it, Modifier modifier) { auto peerit = m_peerinfo.find(it->m_peer); peerit->second.m_completed -= it->GetState() == State::COMPLETED; peerit->second.m_requested -= it->GetState() == State::REQUESTED; m_index.get().modify(it, std::move(modifier)); peerit->second.m_completed += it->GetState() == State::COMPLETED; peerit->second.m_requested += it->GetState() == State::REQUESTED; } //! Convert a CANDIDATE_DELAYED announcement into a CANDIDATE_READY. If this makes it the new best //! CANDIDATE_READY (and no REQUESTED exists) and better than the CANDIDATE_BEST (if any), it becomes the new //! CANDIDATE_BEST. void PromoteCandidateReady(Iter it) { assert(it != m_index.get().end()); assert(it->GetState() == State::CANDIDATE_DELAYED); // Convert CANDIDATE_DELAYED to CANDIDATE_READY first. Modify(it, [](Announcement& ann){ ann.SetState(State::CANDIDATE_READY); }); // The following code relies on the fact that the ByTxHash is sorted by txhash, and then by state (first // _DELAYED, then _READY, then _BEST/REQUESTED). Within the _READY announcements, the best one (highest // priority) comes last. Thus, if an existing _BEST exists for the same txhash that this announcement may // be preferred over, it must immediately follow the newly created _READY. auto it_next = std::next(it); if (it_next == m_index.get().end() || it_next->m_txhash != it->m_txhash || it_next->GetState() == State::COMPLETED) { // This is the new best CANDIDATE_READY, and there is no IsSelected() announcement for this txhash // already. Modify(it, [](Announcement& ann){ ann.SetState(State::CANDIDATE_BEST); }); } else if (it_next->GetState() == State::CANDIDATE_BEST) { Priority priority_old = m_computer(*it_next); Priority priority_new = m_computer(*it); if (priority_new > priority_old) { // There is a CANDIDATE_BEST announcement already, but this one is better. Modify(it_next, [](Announcement& ann){ ann.SetState(State::CANDIDATE_READY); }); Modify(it, [](Announcement& ann){ ann.SetState(State::CANDIDATE_BEST); }); } } } //! Change the state of an announcement to something non-IsSelected(). If it was IsSelected(), the next best //! announcement will be marked CANDIDATE_BEST. void ChangeAndReselect(Iter it, State new_state) { assert(new_state == State::COMPLETED || new_state == State::CANDIDATE_DELAYED); assert(it != m_index.get().end()); if (it->IsSelected() && it != m_index.get().begin()) { auto it_prev = std::prev(it); // The next best CANDIDATE_READY, if any, immediately precedes the REQUESTED or CANDIDATE_BEST // announcement in the ByTxHash index. if (it_prev->m_txhash == it->m_txhash && it_prev->GetState() == State::CANDIDATE_READY) { // If one such CANDIDATE_READY exists (for this txhash), convert it to CANDIDATE_BEST. Modify(it_prev, [](Announcement& ann){ ann.SetState(State::CANDIDATE_BEST); }); } } Modify(it, [new_state](Announcement& ann){ ann.SetState(new_state); }); } //! Check if 'it' is the only announcement for a given txhash that isn't COMPLETED. bool IsOnlyNonCompleted(Iter it) { assert(it != m_index.get().end()); assert(it->GetState() != State::COMPLETED); // Not allowed to call this on COMPLETED announcements. // This announcement has a predecessor that belongs to the same txhash. Due to ordering, and the // fact that 'it' is not COMPLETED, its predecessor cannot be COMPLETED here. if (it != m_index.get().begin() && std::prev(it)->m_txhash == it->m_txhash) return false; // This announcement has a successor that belongs to the same txhash, and is not COMPLETED. if (std::next(it) != m_index.get().end() && std::next(it)->m_txhash == it->m_txhash && std::next(it)->GetState() != State::COMPLETED) return false; return true; } /** Convert any announcement to a COMPLETED one. If there are no non-COMPLETED announcements left for this * txhash, they are deleted. If this was a REQUESTED announcement, and there are other CANDIDATEs left, the * best one is made CANDIDATE_BEST. Returns whether the announcement still exists. */ bool MakeCompleted(Iter it) { assert(it != m_index.get().end()); // Nothing to be done if it's already COMPLETED. if (it->GetState() == State::COMPLETED) return true; if (IsOnlyNonCompleted(it)) { // This is the last non-COMPLETED announcement for this txhash. Delete all. uint256 txhash = it->m_txhash; do { it = Erase(it); } while (it != m_index.get().end() && it->m_txhash == txhash); return false; } // Mark the announcement COMPLETED, and select the next best announcement (the first CANDIDATE_READY) if // needed. ChangeAndReselect(it, State::COMPLETED); return true; } //! Make the data structure consistent with a given point in time: //! - REQUESTED announcements with expiry <= now are turned into COMPLETED. //! - CANDIDATE_DELAYED announcements with reqtime <= now are turned into CANDIDATE_{READY,BEST}. //! - CANDIDATE_{READY,BEST} announcements with reqtime > now are turned into CANDIDATE_DELAYED. void SetTimePoint(std::chrono::microseconds now, std::vector>* expired) { if (expired) expired->clear(); // Iterate over all CANDIDATE_DELAYED and REQUESTED from old to new, as long as they're in the past, // and convert them to CANDIDATE_READY and COMPLETED respectively. while (!m_index.empty()) { auto it = m_index.get().begin(); if (it->GetState() == State::CANDIDATE_DELAYED && it->m_time <= now) { PromoteCandidateReady(m_index.project(it)); } else if (it->GetState() == State::REQUESTED && it->m_time <= now) { if (expired) expired->emplace_back(it->m_peer, ToGenTxid(*it)); MakeCompleted(m_index.project(it)); } else { break; } } while (!m_index.empty()) { // If time went backwards, we may need to demote CANDIDATE_BEST and CANDIDATE_READY announcements back // to CANDIDATE_DELAYED. This is an unusual edge case, and unlikely to matter in production. However, // it makes it much easier to specify and test TxRequestTracker::Impl's behaviour. auto it = std::prev(m_index.get().end()); if (it->IsSelectable() && it->m_time > now) { ChangeAndReselect(m_index.project(it), State::CANDIDATE_DELAYED); } else { break; } } } public: explicit Impl(bool deterministic) : m_computer(deterministic), // Explicitly initialize m_index as we need to pass a reference to m_computer to ByTxHashViewExtractor. m_index(boost::make_tuple( boost::make_tuple(ByPeerViewExtractor(), std::less()), boost::make_tuple(ByTxHashViewExtractor(m_computer), std::less()), boost::make_tuple(ByTimeViewExtractor(), std::less()) )) {} // Disable copying and assigning (a default copy won't work due the stateful ByTxHashViewExtractor). Impl(const Impl&) = delete; Impl& operator=(const Impl&) = delete; void DisconnectedPeer(NodeId peer) { auto& index = m_index.get(); auto it = index.lower_bound(ByPeerView{peer, false, uint256::ZERO}); while (it != index.end() && it->m_peer == peer) { // Check what to continue with after this iteration. 'it' will be deleted in what follows, so we need to // decide what to continue with afterwards. There are a number of cases to consider: // - std::next(it) is end() or belongs to a different peer. In that case, this is the last iteration // of the loop (denote this by setting it_next to end()). // - 'it' is not the only non-COMPLETED announcement for its txhash. This means it will be deleted, but // no other Announcement objects will be modified. Continue with std::next(it) if it belongs to the // same peer, but decide this ahead of time (as 'it' may change position in what follows). // - 'it' is the only non-COMPLETED announcement for its txhash. This means it will be deleted along // with all other announcements for the same txhash - which may include std::next(it). However, other // than 'it', no announcements for the same peer can be affected (due to (peer, txhash) uniqueness). // In other words, the situation where std::next(it) is deleted can only occur if std::next(it) // belongs to a different peer but the same txhash as 'it'. This is covered by the first bulletpoint // already, and we'll have set it_next to end(). auto it_next = (std::next(it) == index.end() || std::next(it)->m_peer != peer) ? index.end() : std::next(it); // If the announcement isn't already COMPLETED, first make it COMPLETED (which will mark other // CANDIDATEs as CANDIDATE_BEST, or delete all of a txhash's announcements if no non-COMPLETED ones are // left). if (MakeCompleted(m_index.project(it))) { // Then actually delete the announcement (unless it was already deleted by MakeCompleted). Erase(it); } it = it_next; } } void ForgetTxHash(const uint256& txhash) { auto it = m_index.get().lower_bound(ByTxHashView{txhash, State::CANDIDATE_DELAYED, 0}); while (it != m_index.get().end() && it->m_txhash == txhash) { it = Erase(it); } } void ReceivedInv(NodeId peer, const GenTxid& gtxid, bool preferred, std::chrono::microseconds reqtime) { // Bail out if we already have a CANDIDATE_BEST announcement for this (txhash, peer) combination. The case // where there is a non-CANDIDATE_BEST announcement already will be caught by the uniqueness property of the // ByPeer index when we try to emplace the new object below. if (m_index.get().count(ByPeerView{peer, true, gtxid.GetHash()})) return; // Try creating the announcement with CANDIDATE_DELAYED state (which will fail due to the uniqueness // of the ByPeer index if a non-CANDIDATE_BEST announcement already exists with the same txhash and peer). // Bail out in that case. auto ret = m_index.get().emplace(gtxid, peer, preferred, reqtime, m_current_sequence); if (!ret.second) return; // Update accounting metadata. ++m_peerinfo[peer].m_total; ++m_current_sequence; } //! Find the GenTxids to request now from peer. std::vector GetRequestable(NodeId peer, std::chrono::microseconds now, std::vector>* expired) { // Move time. SetTimePoint(now, expired); // Find all CANDIDATE_BEST announcements for this peer. std::vector selected; auto it_peer = m_index.get().lower_bound(ByPeerView{peer, true, uint256::ZERO}); while (it_peer != m_index.get().end() && it_peer->m_peer == peer && it_peer->GetState() == State::CANDIDATE_BEST) { selected.emplace_back(&*it_peer); ++it_peer; } // Sort by sequence number. std::sort(selected.begin(), selected.end(), [](const Announcement* a, const Announcement* b) { return a->m_sequence < b->m_sequence; }); // Convert to GenTxid and return. std::vector ret; ret.reserve(selected.size()); std::transform(selected.begin(), selected.end(), std::back_inserter(ret), [](const Announcement* ann) { return ToGenTxid(*ann); }); return ret; } void RequestedTx(NodeId peer, const uint256& txhash, std::chrono::microseconds expiry) { auto it = m_index.get().find(ByPeerView{peer, true, txhash}); if (it == m_index.get().end()) { // There is no CANDIDATE_BEST announcement, look for a _READY or _DELAYED instead. If the caller only // ever invokes RequestedTx with the values returned by GetRequestable, and no other non-const functions // other than ForgetTxHash and GetRequestable in between, this branch will never execute (as txhashes // returned by GetRequestable always correspond to CANDIDATE_BEST announcements). it = m_index.get().find(ByPeerView{peer, false, txhash}); if (it == m_index.get().end() || (it->GetState() != State::CANDIDATE_DELAYED && it->GetState() != State::CANDIDATE_READY)) { // There is no CANDIDATE announcement tracked for this peer, so we have nothing to do. Either this // txhash wasn't tracked at all (and the caller should have called ReceivedInv), or it was already // requested and/or completed for other reasons and this is just a superfluous RequestedTx call. return; } // Look for an existing CANDIDATE_BEST or REQUESTED with the same txhash. We only need to do this if the // found announcement had a different state than CANDIDATE_BEST. If it did, invariants guarantee that no // other CANDIDATE_BEST or REQUESTED can exist. auto it_old = m_index.get().lower_bound(ByTxHashView{txhash, State::CANDIDATE_BEST, 0}); if (it_old != m_index.get().end() && it_old->m_txhash == txhash) { if (it_old->GetState() == State::CANDIDATE_BEST) { // The data structure's invariants require that there can be at most one CANDIDATE_BEST or one // REQUESTED announcement per txhash (but not both simultaneously), so we have to convert any // existing CANDIDATE_BEST to another CANDIDATE_* when constructing another REQUESTED. // It doesn't matter whether we pick CANDIDATE_READY or _DELAYED here, as SetTimePoint() // will correct it at GetRequestable() time. If time only goes forward, it will always be // _READY, so pick that to avoid extra work in SetTimePoint(). Modify(it_old, [](Announcement& ann) { ann.SetState(State::CANDIDATE_READY); }); } else if (it_old->GetState() == State::REQUESTED) { // As we're no longer waiting for a response to the previous REQUESTED announcement, convert it // to COMPLETED. This also helps guaranteeing progress. Modify(it_old, [](Announcement& ann) { ann.SetState(State::COMPLETED); }); } } } Modify(it, [expiry](Announcement& ann) { ann.SetState(State::REQUESTED); ann.m_time = expiry; }); } void ReceivedResponse(NodeId peer, const uint256& txhash) { // We need to search the ByPeer index for both (peer, false, txhash) and (peer, true, txhash). auto it = m_index.get().find(ByPeerView{peer, false, txhash}); if (it == m_index.get().end()) { it = m_index.get().find(ByPeerView{peer, true, txhash}); } if (it != m_index.get().end()) MakeCompleted(m_index.project(it)); } size_t CountInFlight(NodeId peer) const { auto it = m_peerinfo.find(peer); if (it != m_peerinfo.end()) return it->second.m_requested; return 0; } size_t CountCandidates(NodeId peer) const { auto it = m_peerinfo.find(peer); if (it != m_peerinfo.end()) return it->second.m_total - it->second.m_requested - it->second.m_completed; return 0; } size_t Count(NodeId peer) const { auto it = m_peerinfo.find(peer); if (it != m_peerinfo.end()) return it->second.m_total; return 0; } //! Count how many announcements are being tracked in total across all peers and transactions. size_t Size() const { return m_index.size(); } uint64_t ComputePriority(const uint256& txhash, NodeId peer, bool preferred) const { // Return Priority as a uint64_t as Priority is internal. return uint64_t{m_computer(txhash, peer, preferred)}; } }; TxRequestTracker::TxRequestTracker(bool deterministic) : m_impl{std::make_unique(deterministic)} {} TxRequestTracker::~TxRequestTracker() = default; void TxRequestTracker::ForgetTxHash(const uint256& txhash) { m_impl->ForgetTxHash(txhash); } void TxRequestTracker::DisconnectedPeer(NodeId peer) { m_impl->DisconnectedPeer(peer); } size_t TxRequestTracker::CountInFlight(NodeId peer) const { return m_impl->CountInFlight(peer); } size_t TxRequestTracker::CountCandidates(NodeId peer) const { return m_impl->CountCandidates(peer); } size_t TxRequestTracker::Count(NodeId peer) const { return m_impl->Count(peer); } size_t TxRequestTracker::Size() const { return m_impl->Size(); } void TxRequestTracker::SanityCheck() const { m_impl->SanityCheck(); } void TxRequestTracker::PostGetRequestableSanityCheck(std::chrono::microseconds now) const { m_impl->PostGetRequestableSanityCheck(now); } void TxRequestTracker::ReceivedInv(NodeId peer, const GenTxid& gtxid, bool preferred, std::chrono::microseconds reqtime) { m_impl->ReceivedInv(peer, gtxid, preferred, reqtime); } void TxRequestTracker::RequestedTx(NodeId peer, const uint256& txhash, std::chrono::microseconds expiry) { m_impl->RequestedTx(peer, txhash, expiry); } void TxRequestTracker::ReceivedResponse(NodeId peer, const uint256& txhash) { m_impl->ReceivedResponse(peer, txhash); } std::vector TxRequestTracker::GetRequestable(NodeId peer, std::chrono::microseconds now, std::vector>* expired) { return m_impl->GetRequestable(peer, now, expired); } uint64_t TxRequestTracker::ComputePriority(const uint256& txhash, NodeId peer, bool preferred) const { return m_impl->ComputePriority(txhash, peer, preferred); }