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efe4c2d6eb
dash/src/net_processing.cpp
pasta efe4c2d6eb
Merge #6143: backport: bitcoin#19160, #21663, #21669, #21732, #21738, #21750, #21775, #21812 
f4cb0fbfe1 fix: no need to relay quorum commitment in case of block undo (Konstantin Akimov)
0431a33919 fix: follow-up changes for bitcoin#14193. (Konstantin Akimov)
86b76d19b6 Merge bitcoin/bitcoin#21812: ci: Enable D_GLIBCXX_DEBUG for multiprocess task (fanquake)
334496ea7e Merge bitcoin/bitcoin#21775: p2p: Limit m_block_inv_mutex (MarcoFalke)
23b83109ea Merge bitcoin/bitcoin#21750: net: remove unnecessary check of CNode::cs_vSend (MarcoFalke)
b34514191f Merge bitcoin/bitcoin#21738: test: Use clang-12 for ASAN, Add missing suppression (fanquake)
3411577473 Merge bitcoin/bitcoin#19160: multiprocess: Add basic spawn and IPC support (W. J. van der Laan)
970048d917 fix: missing changes from bitcoin#19267 - run multiprocess on CI (Konstantin Akimov)
f2b7ee73db fix: follow-up bitcoin#15402 - removed dead code (Konstantin Akimov)
274068cdbc fix: follow-up bitcoin/bitcoin#21732 - minor missing typo (MarcoFalke)
e9450a8b36 Merge #21669: test: Remove spurious double lock tsan suppressions by bumping to clang-12 (MarcoFalke)
ef92c3065c Merge #21663: ci: Fix macOS brew install command (W. J. van der Laan)

Pull request description:

  ## Issue being fixed or feature implemented
  Just regular backports from v22

  ## What was done?
  See commits for backports.

  Also there're 2 bugs are fixed which became visible after backporting bitcoin#21775 - both are related to possible deadlocks in net_processing

  ## How Has This Been Tested?
  Run unit and functional tests. Enabled multiprocess builds on CI

  ## Breaking Changes
  N/A

  ## Checklist:
  - [x] I have performed a self-review of my own code
  - [ ] I have commented my code, particularly in hard-to-understand areas
  - [ ] I have added or updated relevant unit/integration/functional/e2e tests
  - [ ] I have made corresponding changes to the documentation
  - [x] I have assigned this pull request to a milestone

ACKs for top commit:
  UdjinM6:
    utACK f4cb0fbfe1
  PastaPastaPasta:
    utACK f4cb0fbfe1

Tree-SHA512: 3204c2aa243fa4834ccf4ff4672d183cf9b35f87b857df8543572cd685729e15fca39f85b27194233e57cbc1746e36b556efab95ce20d0aa0a7d4476a9f3c6c0
2024-08-10 19:15:13 +07:00

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// Copyright (c) 2009-2010 Satoshi Nakamoto
// Copyright (c) 2009-2020 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 <net_processing.h>
#include <addrman.h>
#include <banman.h>
#include <blockencodings.h>
#include <blockfilter.h>
#include <chainparams.h>
#include <consensus/validation.h>
#include <hash.h>
#include <index/blockfilterindex.h>
#include <validation.h>
#include <merkleblock.h>
#include <netmessagemaker.h>
#include <netbase.h>
#include <net_types.h>
#include <node/blockstorage.h>
#include <policy/policy.h>
#include <primitives/block.h>
#include <primitives/transaction.h>
#include <random.h>
#include <reverse_iterator.h>
#include <scheduler.h>
#include <streams.h>
#include <tinyformat.h>
#include <index/txindex.h>
#include <txmempool.h>
#include <util/check.h> // For NDEBUG compile time check
#include <util/system.h>
#include <util/strencodings.h>
#include <algorithm>
#include <atomic>
#include <chrono>
#include <future>
#include <list>
#include <memory>
#include <optional>
#include <typeinfo>
#include <spork.h>
#include <governance/governance.h>
#include <masternode/sync.h>
#include <masternode/meta.h>
#ifdef ENABLE_WALLET
#include <coinjoin/client.h>
#endif // ENABLE_WALLET
#include <coinjoin/context.h>
#include <coinjoin/server.h>
#include <evo/deterministicmns.h>
#include <evo/mnauth.h>
#include <evo/simplifiedmns.h>
#include <llmq/blockprocessor.h>
#include <llmq/chainlocks.h>
#include <llmq/commitment.h>
#include <llmq/context.h>
#include <llmq/dkgsessionmgr.h>
#include <llmq/instantsend.h>
#include <llmq/options.h>
#include <llmq/quorums.h>
#include <llmq/signing.h>
#include <llmq/signing_shares.h>
#include <llmq/snapshot.h>
#include <statsd_client.h>
/** Maximum number of in-flight objects from a peer */
static constexpr int32_t MAX_PEER_OBJECT_IN_FLIGHT = 100;
/** Maximum number of announced objects from a peer */
static constexpr int32_t MAX_PEER_OBJECT_ANNOUNCEMENTS = 2 * MAX_INV_SZ;
/** How many microseconds to delay requesting transactions from inbound peers */
static constexpr std::chrono::microseconds INBOUND_PEER_TX_DELAY{std::chrono::seconds{2}};
/** How long to wait (in microseconds) before downloading a transaction from an additional peer */
static constexpr std::chrono::microseconds GETDATA_TX_INTERVAL{std::chrono::seconds{60}};
/** Maximum delay (in microseconds) for transaction requests to avoid biasing some peers over others. */
static constexpr std::chrono::microseconds MAX_GETDATA_RANDOM_DELAY{std::chrono::seconds{2}};
/** How long to wait (expiry * factor microseconds) before expiring an in-flight getdata request to a peer */
static constexpr int64_t TX_EXPIRY_INTERVAL_FACTOR = 10;
static_assert(INBOUND_PEER_TX_DELAY >= MAX_GETDATA_RANDOM_DELAY,
"To preserve security, MAX_GETDATA_RANDOM_DELAY should not exceed INBOUND_PEER_DELAY");
/** Limit to avoid sending big packets. Not used in processing incoming GETDATA for compatibility */
static const unsigned int MAX_GETDATA_SZ = 1000;
/** Expiration time for orphan transactions in seconds */
static constexpr int64_t ORPHAN_TX_EXPIRE_TIME = 20 * 60;
/** Minimum time between orphan transactions expire time checks in seconds */
static constexpr int64_t ORPHAN_TX_EXPIRE_INTERVAL = 5 * 60;
/** How long to cache transactions in mapRelay for normal relay */
static constexpr auto RELAY_TX_CACHE_TIME = 15min;
/** How long a transaction has to be in the mempool before it can unconditionally be relayed (even when not in mapRelay). */
static constexpr auto UNCONDITIONAL_RELAY_DELAY = 2min;
/** Headers download timeout.
* Timeout = base + per_header * (expected number of headers) */
static constexpr auto HEADERS_DOWNLOAD_TIMEOUT_BASE = 15min;
static constexpr auto HEADERS_DOWNLOAD_TIMEOUT_PER_HEADER = 1ms;
/** How long to wait for a peer to respond to a getheaders request */
static constexpr auto HEADERS_RESPONSE_TIME{2min};
/** Protect at least this many outbound peers from disconnection due to slow/
* behind headers chain.
*/
static constexpr int32_t MAX_OUTBOUND_PEERS_TO_PROTECT_FROM_DISCONNECT = 4;
/** Timeout for (unprotected) outbound peers to sync to our chainwork */
static constexpr auto CHAIN_SYNC_TIMEOUT{20min};
/** How frequently to check for stale tips */
static constexpr auto STALE_CHECK_INTERVAL{150s}; // 2.5 minutes (~block interval)
/** How frequently to check for extra outbound peers and disconnect */
static constexpr auto EXTRA_PEER_CHECK_INTERVAL{45s};
/** Minimum time an outbound-peer-eviction candidate must be connected for, in order to evict */
static constexpr std::chrono::seconds MINIMUM_CONNECT_TIME{30};
/** SHA256("main address relay")[0:8] */
static constexpr uint64_t RANDOMIZER_ID_ADDRESS_RELAY = 0x3cac0035b5866b90ULL;
/// Age after which a stale block will no longer be served if requested as
/// protection against fingerprinting. Set to one month, denominated in seconds.
static constexpr int STALE_RELAY_AGE_LIMIT = 30 * 24 * 60 * 60;
/// Age after which a block is considered historical for purposes of rate
/// limiting block relay. Set to one week, denominated in seconds.
static constexpr int HISTORICAL_BLOCK_AGE = 7 * 24 * 60 * 60;
/** Time between pings automatically sent out for latency probing and keepalive */
static constexpr std::chrono::minutes PING_INTERVAL{2};
/** The maximum number of entries in a locator */
static const unsigned int MAX_LOCATOR_SZ = 101;
/** Number of blocks that can be requested at any given time from a single peer. */
static const int MAX_BLOCKS_IN_TRANSIT_PER_PEER = 16;
/** Time during which a peer must stall block download progress before being disconnected. */
static constexpr auto BLOCK_STALLING_TIMEOUT = 2s;
/** Maximum depth of blocks we're willing to serve as compact blocks to peers
* when requested. For older blocks, a regular BLOCK response will be sent. */
static const int MAX_CMPCTBLOCK_DEPTH = 5;
/** Maximum depth of blocks we're willing to respond to GETBLOCKTXN requests for. */
static const int MAX_BLOCKTXN_DEPTH = 10;
/** Size of the "block download window": how far ahead of our current height do we fetch?
* Larger windows tolerate larger download speed differences between peer, but increase the potential
* degree of disordering of blocks on disk (which make reindexing and pruning harder). We'll probably
* want to make this a per-peer adaptive value at some point. */
static const unsigned int BLOCK_DOWNLOAD_WINDOW = 1024;
/** Block download timeout base, expressed in multiples of the block interval (i.e. 10 min) */
static constexpr double BLOCK_DOWNLOAD_TIMEOUT_BASE = 1;
/** Additional block download timeout per parallel downloading peer (i.e. 5 min) */
static constexpr double BLOCK_DOWNLOAD_TIMEOUT_PER_PEER = 0.5;
/** Maximum number of headers to announce when relaying blocks with headers message.*/
static const unsigned int MAX_BLOCKS_TO_ANNOUNCE = 8;
/** Maximum number of unconnecting headers announcements before DoS score */
static const int MAX_UNCONNECTING_HEADERS = 10;
/** Minimum blocks required to signal NODE_NETWORK_LIMITED */
static const unsigned int NODE_NETWORK_LIMITED_MIN_BLOCKS = 288;
/** Average delay between local address broadcasts */
static constexpr auto AVG_LOCAL_ADDRESS_BROADCAST_INTERVAL = 24h;
/** Average delay between peer address broadcasts */
static constexpr auto AVG_ADDRESS_BROADCAST_INTERVAL = 30s;
/** Average delay between trickled inventory transmissions for inbound peers.
* Blocks and peers with NetPermissionFlags::NoBan permission bypass this. */
static constexpr auto INBOUND_INVENTORY_BROADCAST_INTERVAL = 5s;
/** Average delay between trickled inventory transmissions for outbound peers.
* Use a smaller delay as there is less privacy concern for them.
* Blocks and peers with NetPermissionFlags::NoBan permission bypass this.
* Masternode outbound peers get half this delay. */
static constexpr auto OUTBOUND_INVENTORY_BROADCAST_INTERVAL = 2s;
/** Maximum rate of inventory items to send per second.
* Limits the impact of low-fee transaction floods.
* We have 4 times smaller block times in Dash, so we need to push 4 times more invs per 1MB. */
static constexpr unsigned int INVENTORY_BROADCAST_PER_SECOND = 7;
/** Maximum number of inventory items to send per transmission. */
static constexpr unsigned int INVENTORY_BROADCAST_MAX_PER_1MB_BLOCK = 4 * INVENTORY_BROADCAST_PER_SECOND * count_seconds(INBOUND_INVENTORY_BROADCAST_INTERVAL);
/** The number of most recently announced transactions a peer can request. */
static constexpr unsigned int INVENTORY_MAX_RECENT_RELAY = 3500;
/** Verify that INVENTORY_MAX_RECENT_RELAY is enough to cache everything typically
* relayed before unconditional relay from the mempool kicks in. This is only a
* lower bound, and it should be larger to account for higher inv rate to outbound
* peers, and random variations in the broadcast mechanism. */
static_assert(INVENTORY_MAX_RECENT_RELAY >= INVENTORY_BROADCAST_PER_SECOND * UNCONDITIONAL_RELAY_DELAY / std::chrono::seconds{1}, "INVENTORY_RELAY_MAX too low");
/** Maximum number of compact filters that may be requested with one getcfilters. See BIP 157. */
static constexpr uint32_t MAX_GETCFILTERS_SIZE = 1000;
/** Maximum number of cf hashes that may be requested with one getcfheaders. See BIP 157. */
static constexpr uint32_t MAX_GETCFHEADERS_SIZE = 2000;
/** the maximum percentage of addresses from our addrman to return in response to a getaddr message. */
static constexpr size_t MAX_PCT_ADDR_TO_SEND = 23;
/** The maximum number of address records permitted in an ADDR message. */
static constexpr size_t MAX_ADDR_TO_SEND{1000};
/** The maximum rate of address records we're willing to process on average. Can be bypassed using
* the NetPermissionFlags::Addr permission. */
static constexpr double MAX_ADDR_RATE_PER_SECOND{0.1};
/** The soft limit of the address processing token bucket (the regular MAX_ADDR_RATE_PER_SECOND
* based increments won't go above this, but the MAX_ADDR_TO_SEND increment following GETADDR
* is exempt from this limit). */
static constexpr size_t MAX_ADDR_PROCESSING_TOKEN_BUCKET{MAX_ADDR_TO_SEND};
/** The compactblocks version we support. See BIP 152. */
static constexpr uint64_t CMPCTBLOCKS_VERSION{1};
struct COrphanTx {
// When modifying, adapt the copy of this definition in tests/DoS_tests.
CTransactionRef tx;
NodeId fromPeer;
int64_t nTimeExpire;
size_t list_pos;
size_t nTxSize;
};
/** Guards orphan transactions and extra txs for compact blocks */
RecursiveMutex g_cs_orphans;
/** Map from txid to orphan transaction record. Limited by
* -maxorphantx/DEFAULT_MAX_ORPHAN_TRANSACTIONS */
std::map<uint256, COrphanTx> mapOrphanTransactions GUARDED_BY(g_cs_orphans);
size_t nMapOrphanTransactionsSize = 0;
void EraseOrphansFor(NodeId peer);
// Internal stuff
namespace {
/** Blocks that are in flight, and that are in the queue to be downloaded. */
struct QueuedBlock {
uint256 hash;
const CBlockIndex* pindex; //!< Optional.
bool fValidatedHeaders; //!< Whether this block has validated headers at the time of request.
std::unique_ptr<PartiallyDownloadedBlock> partialBlock; //!< Optional, used for CMPCTBLOCK downloads
};
/**
* Data structure for an individual peer. This struct is not protected by
* cs_main since it does not contain validation-critical data.
*
* Memory is owned by shared pointers and this object is destructed when
* the refcount drops to zero.
*
* Mutexes inside this struct must not be held when locking m_peer_mutex.
*
* TODO: move most members from CNodeState to this structure.
* TODO: move remaining application-layer data members from CNode to this structure.
*/
struct Peer {
/** Same id as the CNode object for this peer */
const NodeId m_id{0};
/** Services we offered to this peer.
*
* This is supplied by CConnman during peer initialization. It's const
* because there is no protocol defined for renegotiating services
* initially offered to a peer. The set of local services we offer should
* not change after initialization.
*
* An interesting example of this is NODE_NETWORK and initial block
* download: a node which starts up from scratch doesn't have any blocks
* to serve, but still advertises NODE_NETWORK because it will eventually
* fulfill this role after IBD completes. P2P code is written in such a
* way that it can gracefully handle peers who don't make good on their
* service advertisements. */
const ServiceFlags m_our_services;
/** Services this peer offered to us. */
std::atomic<ServiceFlags> m_their_services{NODE_NONE};
/** Protects misbehavior data members */
Mutex m_misbehavior_mutex;
/** Accumulated misbehavior score for this peer */
int m_misbehavior_score GUARDED_BY(m_misbehavior_mutex){0};
/** Whether this peer should be disconnected and marked as discouraged (unless it has NetPermissionFlags::NoBan permission). */
bool m_should_discourage GUARDED_BY(m_misbehavior_mutex){false};
/** Protects block inventory data members */
Mutex m_block_inv_mutex;
/** List of blocks that we'll anounce via an `inv` message.
* There is no final sorting before sending, as they are always sent
* immediately and in the order requested. */
std::vector<uint256> m_blocks_for_inv_relay GUARDED_BY(m_block_inv_mutex);
/** Unfiltered list of blocks that we'd like to announce via a `headers`
* message. If we can't announce via a `headers` message, we'll fall back to
* announcing via `inv`. */
std::vector<uint256> m_blocks_for_headers_relay GUARDED_BY(m_block_inv_mutex);
/** The final block hash that we sent in an `inv` message to this peer.
* When the peer requests this block, we send an `inv` message to trigger
* the peer to request the next sequence of block hashes.
* Most peers use headers-first syncing, which doesn't use this mechanism */
uint256 m_continuation_block GUARDED_BY(m_block_inv_mutex) {};
/** This peer's reported block height when we connected */
std::atomic<int> m_starting_height{-1};
/** The pong reply we're expecting, or 0 if no pong expected. */
std::atomic<uint64_t> m_ping_nonce_sent{0};
/** When the last ping was sent, or 0 if no ping was ever sent */
std::atomic<std::chrono::microseconds> m_ping_start{0us};
/** Whether a ping has been requested by the user */
std::atomic<bool> m_ping_queued{false};
struct TxRelay {
mutable RecursiveMutex m_bloom_filter_mutex;
// We use m_relay_txs for two purposes -
// a) it allows us to not relay tx invs before receiving the peer's version message
// b) the peer may tell us in its version message that we should not relay tx invs
// unless it loads a bloom filter.
bool m_relay_txs GUARDED_BY(m_bloom_filter_mutex){false};
std::unique_ptr<CBloomFilter> m_bloom_filter PT_GUARDED_BY(m_bloom_filter_mutex) GUARDED_BY(m_bloom_filter_mutex){nullptr};
mutable RecursiveMutex m_tx_inventory_mutex;
// inventory based relay
CRollingBloomFilter m_tx_inventory_known_filter GUARDED_BY(m_tx_inventory_mutex){50000, 0.000001};
// Set of transaction ids we still have to announce.
// They are sorted by the mempool before relay, so the order is not important.
std::set<uint256> m_tx_inventory_to_send GUARDED_BY(m_tx_inventory_mutex);
// List of non-tx/non-block inventory items
std::vector<CInv> vInventoryOtherToSend GUARDED_BY(m_tx_inventory_mutex);
// Used for BIP35 mempool sending, also protected by m_tx_inventory_mutex
bool m_send_mempool GUARDED_BY(m_tx_inventory_mutex){false};
// Last time a "MEMPOOL" request was serviced.
std::atomic<std::chrono::seconds> m_last_mempool_req{0s};
std::chrono::microseconds m_next_inv_send_time{0};
};
// in bitcoin: m_tx_relay == nullptr if we're not relaying transactions with this peer
// in dash: m_tx_relay should never be nullptr, we don't relay transactions if
// `IsBlockOnlyConn() == true` is instead
std::unique_ptr<TxRelay> m_tx_relay{std::make_unique<TxRelay>()};
/** A vector of addresses to send to the peer, limited to MAX_ADDR_TO_SEND. */
std::vector<CAddress> m_addrs_to_send;
/** Probabilistic filter to track recent addr messages relayed with this
* peer. Used to avoid relaying redundant addresses to this peer.
*
* We initialize this filter for outbound peers (other than
* block-relay-only connections) or when an inbound peer sends us an
* address related message (ADDR, ADDRV2, GETADDR).
*
* Presence of this filter must correlate with m_addr_relay_enabled.
**/
std::unique_ptr<CRollingBloomFilter> m_addr_known;
/** Whether we are participating in address relay with this connection.
*
* We set this bool to true for outbound peers (other than
* block-relay-only connections), or when an inbound peer sends us an
* address related message (ADDR, ADDRV2, GETADDR).
*
* We use this bool to decide whether a peer is eligible for gossiping
* addr messages. This avoids relaying to peers that are unlikely to
* forward them, effectively blackholing self announcements. Reasons
* peers might support addr relay on the link include that they connected
* to us as a block-relay-only peer or they are a light client.
*
* This field must correlate with whether m_addr_known has been
* initialized.*/
std::atomic_bool m_addr_relay_enabled{false};
/** Whether a Peer can only be relayed blocks */
const bool m_block_relay_only{false};
/** Whether a getaddr request to this peer is outstanding. */
bool m_getaddr_sent{false};
/** Guards address sending timers. */
mutable Mutex m_addr_send_times_mutex;
/** Time point to send the next ADDR message to this peer. */
std::chrono::microseconds m_next_addr_send GUARDED_BY(m_addr_send_times_mutex){0};
/** Time point to possibly re-announce our local address to this peer. */
std::chrono::microseconds m_next_local_addr_send GUARDED_BY(m_addr_send_times_mutex){0};
/** Whether the peer has signaled support for receiving ADDRv2 (BIP155)
* messages, indicating a preference to receive ADDRv2 instead of ADDR ones. */
std::atomic_bool m_wants_addrv2{false};
/** Whether this peer has already sent us a getaddr message. */
bool m_getaddr_recvd{false};
/** Number of addresses that can be processed from this peer. Start at 1 to
* permit self-announcement. */
double m_addr_token_bucket{1.0};
/** When m_addr_token_bucket was last updated */
std::chrono::microseconds m_addr_token_timestamp{GetTime<std::chrono::microseconds>()};
/** Total number of addresses that were dropped due to rate limiting. */
std::atomic<uint64_t> m_addr_rate_limited{0};
/** Total number of addresses that were processed (excludes rate-limited ones). */
std::atomic<uint64_t> m_addr_processed{0};
/** Set of txids to reconsider once their parent transactions have been accepted **/
std::set<uint256> m_orphan_work_set GUARDED_BY(g_cs_orphans);
/** Whether we've sent this peer a getheaders in response to an inv prior to initial-headers-sync completing */
bool m_inv_triggered_getheaders_before_sync{false};
/** Protects m_getdata_requests **/
Mutex m_getdata_requests_mutex;
/** Work queue of items requested by this peer **/
std::deque<CInv> m_getdata_requests GUARDED_BY(m_getdata_requests_mutex);
/** Time of the last getheaders message to this peer */
std::atomic<std::chrono::seconds> m_last_getheaders_timestamp{0s};
explicit Peer(NodeId id, ServiceFlags our_services, bool block_relay_only)
: m_id(id)
, m_our_services{our_services}
, m_tx_relay(std::make_unique<TxRelay>())
, m_block_relay_only{block_relay_only}
{}
};
using PeerRef = std::shared_ptr<Peer>;
class PeerManagerImpl final : public PeerManager
{
public:
PeerManagerImpl(const CChainParams& chainparams, CConnman& connman, AddrMan& addrman, BanMan* banman,
ChainstateManager& chainman, CTxMemPool& pool,
CMasternodeMetaMan& mn_metaman, CMasternodeSync& mn_sync,
CGovernanceManager& govman, CSporkManager& sporkman,
const CActiveMasternodeManager* const mn_activeman,
const std::unique_ptr<CDeterministicMNManager>& dmnman,
const std::unique_ptr<CJContext>& cj_ctx,
const std::unique_ptr<LLMQContext>& llmq_ctx,
bool ignore_incoming_txs);
/** Overridden from CValidationInterface. */
void BlockConnected(const std::shared_ptr<const CBlock>& pblock, const CBlockIndex* pindexConnected) override
EXCLUSIVE_LOCKS_REQUIRED(!m_peer_mutex, !m_recent_confirmed_transactions_mutex);
void BlockDisconnected(const std::shared_ptr<const CBlock> &block, const CBlockIndex* pindex) override
EXCLUSIVE_LOCKS_REQUIRED(!m_recent_confirmed_transactions_mutex);
void UpdatedBlockTip(const CBlockIndex *pindexNew, const CBlockIndex *pindexFork, bool fInitialDownload) override
EXCLUSIVE_LOCKS_REQUIRED(!m_peer_mutex);
void BlockChecked(const CBlock& block, const BlockValidationState& state) override
EXCLUSIVE_LOCKS_REQUIRED(!m_peer_mutex);
void NewPoWValidBlock(const CBlockIndex *pindex, const std::shared_ptr<const CBlock>& pblock) override;
/** Implement NetEventsInterface */
void InitializeNode(CNode& node, ServiceFlags our_services) override EXCLUSIVE_LOCKS_REQUIRED(!m_peer_mutex);
void FinalizeNode(const CNode& node) override EXCLUSIVE_LOCKS_REQUIRED(!m_peer_mutex);
bool ProcessMessages(CNode* pfrom, std::atomic<bool>& interrupt) override
EXCLUSIVE_LOCKS_REQUIRED(!m_peer_mutex, !m_recent_confirmed_transactions_mutex);
bool SendMessages(CNode* pto) override EXCLUSIVE_LOCKS_REQUIRED(pto->cs_sendProcessing)
EXCLUSIVE_LOCKS_REQUIRED(!m_peer_mutex, !m_recent_confirmed_transactions_mutex);
/** Implement PeerManager */
void StartScheduledTasks(CScheduler& scheduler) override;
void CheckForStaleTipAndEvictPeers() override;
std::optional<std::string> FetchBlock(NodeId peer_id, const CBlockIndex& block_index) override
EXCLUSIVE_LOCKS_REQUIRED(!m_peer_mutex);
bool GetNodeStateStats(NodeId nodeid, CNodeStateStats& stats) const override EXCLUSIVE_LOCKS_REQUIRED(!m_peer_mutex);
bool IgnoresIncomingTxs() override { return m_ignore_incoming_txs; }
void SendPings() override EXCLUSIVE_LOCKS_REQUIRED(!m_peer_mutex);;
void PushInventory(NodeId nodeid, const CInv& inv) override EXCLUSIVE_LOCKS_REQUIRED(!m_peer_mutex);
void RelayInv(CInv &inv, const int minProtoVersion) override EXCLUSIVE_LOCKS_REQUIRED(!m_peer_mutex);
void RelayInvFiltered(CInv &inv, const CTransaction &relatedTx, const int minProtoVersion) override EXCLUSIVE_LOCKS_REQUIRED(!m_peer_mutex);
void RelayInvFiltered(CInv &inv, const uint256 &relatedTxHash, const int minProtoVersion) override EXCLUSIVE_LOCKS_REQUIRED(!m_peer_mutex);
void RelayTransaction(const uint256& txid) override EXCLUSIVE_LOCKS_REQUIRED(!m_peer_mutex);
void SetBestHeight(int height) override { m_best_height = height; };
void Misbehaving(const NodeId pnode, const int howmuch, const std::string& message = "") override EXCLUSIVE_LOCKS_REQUIRED(!m_peer_mutex);
void ProcessMessage(CNode& pfrom, const std::string& msg_type, CDataStream& vRecv,
const std::chrono::microseconds time_received, const std::atomic<bool>& interruptMsgProc) override
EXCLUSIVE_LOCKS_REQUIRED(!m_peer_mutex, !m_recent_confirmed_transactions_mutex);
bool IsBanned(NodeId pnode) override EXCLUSIVE_LOCKS_REQUIRED(cs_main, !m_peer_mutex);
bool IsInvInFilter(NodeId nodeid, const uint256& hash) const override EXCLUSIVE_LOCKS_REQUIRED(!m_peer_mutex);
private:
/** Helper to process result of external handlers of message */
void ProcessPeerMsgRet(const PeerMsgRet& ret, CNode& pfrom) EXCLUSIVE_LOCKS_REQUIRED(!m_peer_mutex);
/** Consider evicting an outbound peer based on the amount of time they've been behind our tip */
void ConsiderEviction(CNode& pto, Peer& peer, std::chrono::seconds time_in_seconds) EXCLUSIVE_LOCKS_REQUIRED(cs_main);
/** If we have extra outbound peers, try to disconnect the one with the oldest block announcement */
void EvictExtraOutboundPeers(std::chrono::seconds now) EXCLUSIVE_LOCKS_REQUIRED(cs_main);
/** Retrieve unbroadcast transactions from the mempool and reattempt sending to peers */
void ReattemptInitialBroadcast(CScheduler& scheduler) EXCLUSIVE_LOCKS_REQUIRED(!m_peer_mutex);
/** Get a shared pointer to the Peer object.
* May return an empty shared_ptr if the Peer object can't be found. */
PeerRef GetPeerRef(NodeId id) const EXCLUSIVE_LOCKS_REQUIRED(!m_peer_mutex);
/** Get a shared pointer to the Peer object and remove it from m_peer_map.
* May return an empty shared_ptr if the Peer object can't be found. */
PeerRef RemovePeer(NodeId id) EXCLUSIVE_LOCKS_REQUIRED(!m_peer_mutex);
/**
* Potentially mark a node discouraged based on the contents of a BlockValidationState object
*
* @param[in] via_compact_block this bool is passed in because net_processing should
* punish peers differently depending on whether the data was provided in a compact
* block message or not. If the compact block had a valid header, but contained invalid
* txs, the peer should not be punished. See BIP 152.
*
* @return Returns true if the peer was punished (probably disconnected)
*/
bool MaybePunishNodeForBlock(NodeId nodeid, const BlockValidationState& state,
bool via_compact_block, const std::string& message = "")
EXCLUSIVE_LOCKS_REQUIRED(!m_peer_mutex);
/**
* Potentially ban a node based on the contents of a TxValidationState object
*
* @return Returns true if the peer was punished (probably disconnected)
*
* Changes here may need to be reflected in TxRelayMayResultInDisconnect().
*/
bool MaybePunishNodeForTx(NodeId nodeid, const TxValidationState& state, const std::string& message = "")
EXCLUSIVE_LOCKS_REQUIRED(!m_peer_mutex);
/** Maybe disconnect a peer and discourage future connections from its address.
*
* @param[in] pnode The node to check.
* @param[in] peer The peer object to check.
* @return True if the peer was marked for disconnection in this function
*/
bool MaybeDiscourageAndDisconnect(CNode& pnode, Peer& peer);
void ProcessOrphanTx(std::set<uint256>& orphan_work_set) EXCLUSIVE_LOCKS_REQUIRED(cs_main, g_cs_orphans)
EXCLUSIVE_LOCKS_REQUIRED(!m_peer_mutex);
/** Process a single headers message from a peer. */
void ProcessHeadersMessage(CNode& pfrom, Peer& peer,
const std::vector<CBlockHeader>& headers,
bool via_compact_block)
EXCLUSIVE_LOCKS_REQUIRED(!m_peer_mutex);
/** Various helpers for headers processing, invoked by ProcessHeadersMessage() */
/** Deal with state tracking and headers sync for peers that send the
* occasional non-connecting header (this can happen due to BIP 130 headers
* announcements for blocks interacting with the 2hr (MAX_FUTURE_BLOCK_TIME) rule). */
void HandleFewUnconnectingHeaders(CNode& pfrom, Peer& peer, const std::vector<CBlockHeader>& headers)
EXCLUSIVE_LOCKS_REQUIRED(!m_peer_mutex);
/** Return true if the headers connect to each other, false otherwise */
bool CheckHeadersAreContinuous(const std::vector<CBlockHeader>& headers) const;
/** Request further headers from this peer with a given locator.
* We don't issue a getheaders message if we have a recent one outstanding.
* This returns true if a getheaders is actually sent, and false otherwise.
*/
bool MaybeSendGetHeaders(CNode& pfrom, const std::string& msg_type, const CBlockLocator& locator, Peer& peer);
/** Potentially fetch blocks from this peer upon receipt of a new headers tip */
void HeadersDirectFetchBlocks(CNode& pfrom, const Peer& peer, const CBlockIndex* pindexLast);
/** Update peer state based on received headers message */
void UpdatePeerStateForReceivedHeaders(CNode& pfrom, const CBlockIndex *pindexLast, bool received_new_header, bool may_have_more_headers);
void SendBlockTransactions(CNode& pfrom, const CBlock& block, const BlockTransactionsRequest& req)
EXCLUSIVE_LOCKS_REQUIRED(!m_peer_mutex);
/** Send a version message to a peer */
void PushNodeVersion(CNode& pnode, const Peer& peer);
/** Send a ping message every PING_INTERVAL or if requested via RPC. May
* mark the peer to be disconnected if a ping has timed out.
* We use mockable time for ping timeouts, so setmocktime may cause pings
* to time out. */
void MaybeSendPing(CNode& node_to, Peer& peer, std::chrono::microseconds now);
/** Send `addr` messages on a regular schedule. */
void MaybeSendAddr(CNode& node, Peer& peer, std::chrono::microseconds current_time);
/** Relay (gossip) an address to a few randomly chosen nodes.
*
* @param[in] originator The id of the peer that sent us the address. We don't want to relay it back.
* @param[in] addr Address to relay.
* @param[in] fReachable Whether the address' network is reachable. We relay unreachable
* addresses less.
*/
void RelayAddress(NodeId originator, const CAddress& addr, bool fReachable) EXCLUSIVE_LOCKS_REQUIRED(!m_peer_mutex);
const CChainParams& m_chainparams;
CConnman& m_connman;
AddrMan& m_addrman;
/** Pointer to this node's banman. May be nullptr - check existence before dereferencing. */
BanMan* const m_banman;
ChainstateManager& m_chainman;
CTxMemPool& m_mempool;
const std::unique_ptr<CDeterministicMNManager>& m_dmnman;
const std::unique_ptr<CJContext>& m_cj_ctx;
const std::unique_ptr<LLMQContext>& m_llmq_ctx;
CMasternodeMetaMan& m_mn_metaman;
CMasternodeSync& m_mn_sync;
CGovernanceManager& m_govman;
CSporkManager& m_sporkman;
const CActiveMasternodeManager* const m_mn_activeman;
/** The height of the best chain */
std::atomic<int> m_best_height{-1};
/** Next time to check for stale tip */
std::chrono::seconds m_stale_tip_check_time GUARDED_BY(cs_main){0s};
/** Whether this node is running in blocks only mode */
const bool m_ignore_incoming_txs;
/** Whether we've completed initial sync yet, for determining when to turn
* on extra block-relay-only peers. */
bool m_initial_sync_finished GUARDED_BY(cs_main){false};
/** Protects m_peer_map. This mutex must not be locked while holding a lock
* on any of the mutexes inside a Peer object. */
mutable Mutex m_peer_mutex;
/**
* Map of all Peer objects, keyed by peer id. This map is protected
* by the m_peer_mutex. Once a shared pointer reference is
* taken, the lock may be released. Individual fields are protected by
* their own locks.
*/
std::map<NodeId, PeerRef> m_peer_map GUARDED_BY(m_peer_mutex);
/** Check whether the last unknown block a peer advertised is not yet known. */
void ProcessBlockAvailability(NodeId nodeid) EXCLUSIVE_LOCKS_REQUIRED(cs_main);
/** Update tracking information about which blocks a peer is assumed to have. */
void UpdateBlockAvailability(NodeId nodeid, const uint256& hash) EXCLUSIVE_LOCKS_REQUIRED(cs_main);
bool CanDirectFetch() EXCLUSIVE_LOCKS_REQUIRED(cs_main);
/**
* To prevent fingerprinting attacks, only send blocks/headers outside of the
* active chain if they are no more than a month older (both in time, and in
* best equivalent proof of work) than the best header chain we know about and
* we fully-validated them at some point.
*/
bool BlockRequestAllowed(const CBlockIndex* pindex) EXCLUSIVE_LOCKS_REQUIRED(cs_main);
bool AlreadyHaveBlock(const uint256& block_hash) EXCLUSIVE_LOCKS_REQUIRED(cs_main);
void ProcessGetBlockData(CNode& pfrom, Peer& peer, const CInv& inv, llmq::CInstantSendManager& isman);
/**
* Validation logic for compact filters request handling.
*
* May disconnect from the peer in the case of a bad request.
*
* @param[in] node The node that we received the request from
* @param[in] peer The peer that we received the request from
* @param[in] filter_type The filter type the request is for. Must be basic filters.
* @param[in] start_height The start height for the request
* @param[in] stop_hash The stop_hash for the request
* @param[in] max_height_diff The maximum number of items permitted to request, as specified in BIP 157
* @param[out] stop_index The CBlockIndex for the stop_hash block, if the request can be serviced.
* @param[out] filter_index The filter index, if the request can be serviced.
* @return True if the request can be serviced.
*/
bool PrepareBlockFilterRequest(CNode& node, Peer& peer,
BlockFilterType filter_type, uint32_t start_height,
const uint256& stop_hash, uint32_t max_height_diff,
const CBlockIndex*& stop_index,
BlockFilterIndex*& filter_index);
/**
* Handle a cfilters request.
*
* May disconnect from the peer in the case of a bad request.
*
* @param[in] node The node that we received the request from
* @param[in] peer The peer that we received the request from
* @param[in] vRecv The raw message received
*/
void ProcessGetCFilters(CNode& node, Peer& peer, CDataStream& vRecv);
/**
* Handle a cfheaders request.
*
* May disconnect from the peer in the case of a bad request.
*
* @param[in] node The node that we received the request from
* @param[in] peer The peer that we received the request from
* @param[in] vRecv The raw message received
*/
void ProcessGetCFHeaders(CNode& node, Peer& peer, CDataStream& vRecv);
/**
* Handle a getcfcheckpt request.
*
* May disconnect from the peer in the case of a bad request.
*
* @param[in] node The node that we received the request from
* @param[in] peer The peer that we received the request from
* @param[in] vRecv The raw message received
*/
void ProcessGetCFCheckPt(CNode& node, Peer& peer, CDataStream& vRecv);
/** Checks if address relay is permitted with peer. If needed, initializes
* the m_addr_known bloom filter and sets m_addr_relay_enabled to true.
*
* @return True if address relay is enabled with peer
* False if address relay is disallowed
*/
bool SetupAddressRelay(const CNode& node, Peer& peer);
/** Number of nodes with fSyncStarted. */
int nSyncStarted GUARDED_BY(cs_main) = 0;
/** Hash of the last block we received via INV */
uint256 m_last_block_inv_triggering_headers_sync{};
/**
* Sources of received blocks, saved to be able punish them when processing
* happens afterwards.
* Set mapBlockSource[hash].second to false if the node should not be
* punished if the block is invalid.
*/
std::map<uint256, std::pair<NodeId, bool>> mapBlockSource GUARDED_BY(cs_main);
/** Number of outbound peers with m_chain_sync.m_protect. */
int m_outbound_peers_with_protect_from_disconnect GUARDED_BY(cs_main) = 0;
bool AlreadyHave(const CInv& inv)
EXCLUSIVE_LOCKS_REQUIRED(cs_main, !m_recent_confirmed_transactions_mutex);
/**
* Filter for transactions that were recently rejected by
* AcceptToMemoryPool. These are not rerequested until the chain tip
* changes, at which point the entire filter is reset.
*
* Without this filter we'd be re-requesting txs from each of our peers,
* increasing bandwidth consumption considerably. For instance, with 100
* peers, half of which relay a tx we don't accept, that might be a 50x
* bandwidth increase. A flooding attacker attempting to roll-over the
* filter using minimum-sized, 60byte, transactions might manage to send
* 1000/sec if we have fast peers, so we pick 120,000 to give our peers a
* two minute window to send invs to us.
*
* Decreasing the false positive rate is fairly cheap, so we pick one in a
* million to make it highly unlikely for users to have issues with this
* filter.
*
* Memory used: 1.3MB
*/
CRollingBloomFilter m_recent_rejects GUARDED_BY(::cs_main){120'000, 0.000'001};
uint256 hashRecentRejectsChainTip GUARDED_BY(cs_main);
/*
* Filter for transactions that have been recently confirmed.
* We use this to avoid requesting transactions that have already been
* confirnmed.
*
* Blocks don't typically have more than 4000 transactions, so this should
* be at least six blocks (~1 hr) worth of transactions that we can store,
* inserting both a txid and wtxid for every observed transaction.
* If the number of transactions appearing in a block goes up, or if we are
* seeing getdata requests more than an hour after initial announcement, we
* can increase this number.
* The false positive rate of 1/1M should come out to less than 1
* transaction per day that would be inadvertently ignored (which is the
* same probability that we have in the reject filter).
*/
Mutex m_recent_confirmed_transactions_mutex;
CRollingBloomFilter m_recent_confirmed_transactions GUARDED_BY(m_recent_confirmed_transactions_mutex){48'000, 0.000'001};
/* Returns a bool indicating whether we requested this block.
* Also used if a block was /not/ received and timed out or started with another peer
*/
bool MarkBlockAsReceived(const uint256& hash) EXCLUSIVE_LOCKS_REQUIRED(cs_main);
/* Mark a block as in flight
* Returns false, still setting pit, if the block was already in flight from the same peer
* pit will only be valid as long as the same cs_main lock is being held
*/
bool MarkBlockAsInFlight(NodeId nodeid, const uint256& hash, const CBlockIndex* pindex = nullptr, std::list<QueuedBlock>::iterator** pit = nullptr) EXCLUSIVE_LOCKS_REQUIRED(cs_main);
bool TipMayBeStale() EXCLUSIVE_LOCKS_REQUIRED(cs_main);
/** Update pindexLastCommonBlock and add not-in-flight missing successors to vBlocks, until it has
* at most count entries.
*/
void FindNextBlocksToDownload(const Peer& peer, unsigned int count, std::vector<const CBlockIndex*>& vBlocks, NodeId& nodeStaller) EXCLUSIVE_LOCKS_REQUIRED(cs_main);
std::map<uint256, std::pair<NodeId, std::list<QueuedBlock>::iterator> > mapBlocksInFlight GUARDED_BY(cs_main);
/** When our tip was last updated. */
std::atomic<std::chrono::seconds> m_last_tip_update{0s};
/** Determine whether or not a peer can request a transaction, and return it (or nullptr if not found or not allowed). */
CTransactionRef FindTxForGetData(const CNode* peer, const uint256& txid, const std::chrono::seconds mempool_req, const std::chrono::seconds now) LOCKS_EXCLUDED(cs_main);
void ProcessGetData(CNode& pfrom, Peer& peer, const std::atomic<bool>& interruptMsgProc) LOCKS_EXCLUDED(cs_main) EXCLUSIVE_LOCKS_REQUIRED(peer.m_getdata_requests_mutex);
void ProcessBlock(CNode& pfrom, const std::shared_ptr<const CBlock>& pblock, bool fForceProcessing);
/** Relay map (txid -> CTransactionRef) */
typedef std::map<uint256, CTransactionRef> MapRelay;
MapRelay mapRelay GUARDED_BY(cs_main);
/** Expiration-time ordered list of (expire time, relay map entry) pairs. */
std::deque<std::pair<std::chrono::microseconds, MapRelay::iterator>> g_relay_expiration GUARDED_BY(cs_main);
/**
* When a peer sends us a valid block, instruct it to announce blocks to us
* using CMPCTBLOCK if possible by adding its nodeid to the end of
* lNodesAnnouncingHeaderAndIDs, and keeping that list under a certain size by
* removing the first element if necessary.
*/
void MaybeSetPeerAsAnnouncingHeaderAndIDs(NodeId nodeid) EXCLUSIVE_LOCKS_REQUIRED(cs_main);
/** Stack of nodes which we have set to announce using compact blocks */
std::list<NodeId> lNodesAnnouncingHeaderAndIDs GUARDED_BY(cs_main);
/** Number of peers from which we're downloading blocks. */
int nPeersWithValidatedDownloads GUARDED_BY(cs_main) = 0;
};
} // namespace
namespace {
/** Number of preferable block download peers. */
int nPreferredDownload GUARDED_BY(cs_main) = 0;
struct IteratorComparator
{
template<typename I>
bool operator()(const I& a, const I& b) const
{
return &(*a) < &(*b);
}
};
/** Index from the parents' COutPoint into the mapOrphanTransactions. Used
* to remove orphan transactions from the mapOrphanTransactions */
std::map<COutPoint, std::set<std::map<uint256, COrphanTx>::iterator, IteratorComparator>> mapOrphanTransactionsByPrev GUARDED_BY(g_cs_orphans);
/** Orphan transactions in vector for quick random eviction */
std::vector<std::map<uint256, COrphanTx>::iterator> g_orphan_list GUARDED_BY(g_cs_orphans);
/** Orphan/conflicted/etc transactions that are kept for compact block reconstruction.
* The last -blockreconstructionextratxn/DEFAULT_BLOCK_RECONSTRUCTION_EXTRA_TXN of
* these are kept in a ring buffer */
static std::vector<std::pair<uint256, CTransactionRef>> vExtraTxnForCompact GUARDED_BY(g_cs_orphans);
/** Offset into vExtraTxnForCompact to insert the next tx */
static size_t vExtraTxnForCompactIt GUARDED_BY(g_cs_orphans) = 0;
} // namespace
namespace {
/**
* Maintain validation-specific state about nodes, protected by cs_main, instead
* by CNode's own locks. This simplifies asynchronous operation, where
* processing of incoming data is done after the ProcessMessage call returns,
* and we're no longer holding the node's locks.
*/
struct CNodeState {
//! The best known block we know this peer has announced.
const CBlockIndex* pindexBestKnownBlock{nullptr};
//! The hash of the last unknown block this peer has announced.
uint256 hashLastUnknownBlock{};
//! The last full block we both have.
const CBlockIndex* pindexLastCommonBlock{nullptr};
//! The best header we have sent our peer.
const CBlockIndex* pindexBestHeaderSent{nullptr};
//! Length of current-streak of unconnecting headers announcements
int nUnconnectingHeaders{0};
//! Whether we've started headers synchronization with this peer.
bool fSyncStarted{false};
//! When to potentially disconnect peer for stalling headers download
std::chrono::microseconds m_headers_sync_timeout{0us};
//! Since when we're stalling block download progress (in microseconds), or 0.
std::chrono::microseconds m_stalling_since{0us};
std::list<QueuedBlock> vBlocksInFlight;
//! When the first entry in vBlocksInFlight started downloading. Don't care when vBlocksInFlight is empty.
std::chrono::microseconds m_downloading_since{0us};
int nBlocksInFlight{0};
int nBlocksInFlightValidHeaders{0};
//! Whether we consider this a preferred download peer.
bool fPreferredDownload{false};
//! Whether this peer wants invs or headers (when possible) for block announcements.
bool fPreferHeaders{false};
//! Whether this peer wants invs or compressed headers (when possible) for block announcements.
bool fPreferHeadersCompressed{false};
/** Whether this peer wants invs or cmpctblocks (when possible) for block announcements. */
bool m_requested_hb_cmpctblocks{false};
/** Whether this peer will send us cmpctblocks if we request them. */
bool m_provides_cmpctblocks{false};
/** State used to enforce CHAIN_SYNC_TIMEOUT and EXTRA_PEER_CHECK_INTERVAL logic.
*
* Both are only in effect for outbound, non-manual, non-protected connections.
* Any peer protected (m_protect = true) is not chosen for eviction. A peer is
* marked as protected if all of these are true:
* - its connection type is IsBlockOnlyConn() == false
* - it gave us a valid connecting header
* - we haven't reached MAX_OUTBOUND_PEERS_TO_PROTECT_FROM_DISCONNECT yet
* - its chain tip has at least as much work as ours
*
* CHAIN_SYNC_TIMEOUT: if a peer's best known block has less work than our tip,
* set a timeout CHAIN_SYNC_TIMEOUT seconds in the future:
* - If at timeout their best known block now has more work than our tip
* when the timeout was set, then either reset the timeout or clear it
* (after comparing against our current tip's work)
* - If at timeout their best known block still has less work than our
* tip did when the timeout was set, then send a getheaders message,
* and set a shorter timeout, HEADERS_RESPONSE_TIME seconds in future.
* If their best known block is still behind when that new timeout is
* reached, disconnect.
*
* EXTRA_PEER_CHECK_INTERVAL: after each interval, if we have too many outbound peers,
* drop the outbound one that least recently announced us a new block.
*/
struct ChainSyncTimeoutState {
//! A timeout used for checking whether our peer has sufficiently synced
std::chrono::seconds m_timeout{0s};
//! A header with the work we require on our peer's chain
const CBlockIndex* m_work_header{nullptr};
//! After timeout is reached, set to true after sending getheaders
bool m_sent_getheaders{false};
//! Whether this peer is protected from disconnection due to a bad/slow chain
bool m_protect{false};
};
ChainSyncTimeoutState m_chain_sync;
//! Time of last new block announcement
int64_t m_last_block_announcement{0};
/*
* State associated with objects download.
*
* Tx download algorithm:
*
* When inv comes in, queue up (process_time, inv) inside the peer's
* CNodeState (m_object_process_time) as long as m_object_announced for the peer
* isn't too big (MAX_PEER_OBJECT_ANNOUNCEMENTS).
*
* The process_time for a objects is set to nNow for outbound peers,
* nNow + 2 seconds for inbound peers. This is the time at which we'll
* consider trying to request the objects from the peer in
* SendMessages(). The delay for inbound peers is to allow outbound peers
* a chance to announce before we request from inbound peers, to prevent
* an adversary from using inbound connections to blind us to a
* objects (InvBlock).
*
* When we call SendMessages() for a given peer,
* we will loop over the objects in m_object_process_time, looking
* at the objects whose process_time <= nNow. We'll request each
* such objects that we don't have already and that hasn't been
* requested from another peer recently, up until we hit the
* MAX_PEER_OBJECT_IN_FLIGHT limit for the peer. Then we'll update
* g_already_asked_for for each requested inv, storing the time of the
* GETDATA request. We use g_already_asked_for to coordinate objects
* requests amongst our peers.
*
* For objects that we still need but we have already recently
* requested from some other peer, we'll reinsert (process_time, inv)
* back into the peer's m_object_process_time at the point in the future at
* which the most recent GETDATA request would time out (ie
* GetObjectInterval + the request time stored in g_already_asked_for).
* We add an additional delay for inbound peers, again to prefer
* attempting download from outbound peers first.
* We also add an extra small random delay up to 2 seconds
* to avoid biasing some peers over others. (e.g., due to fixed ordering
* of peer processing in ThreadMessageHandler).
*
* When we receive a objects from a peer, we remove the inv from the
* peer's m_object_in_flight set and from their recently announced set
* (m_object_announced). We also clear g_already_asked_for for that entry, so
* that if somehow the objects is not accepted but also not added to
* the reject filter, then we will eventually redownload from other
* peers.
*/
struct ObjectDownloadState {
/* Track when to attempt download of announced objects (process
* time in micros -> inv)
*/
std::multimap<std::chrono::microseconds, CInv> m_object_process_time;
//! Store all the objects a peer has recently announced
std::set<CInv> m_object_announced;
//! Store objects which were requested by us, with timestamp
std::map<CInv, std::chrono::microseconds> m_object_in_flight;
//! Periodically check for stuck getdata requests
std::chrono::microseconds m_check_expiry_timer{0};
};
ObjectDownloadState m_object_download;
//! Whether this peer is an inbound connection
const bool m_is_inbound;
//! A rolling bloom filter of all announced tx CInvs to this peer.
CRollingBloomFilter m_recently_announced_invs = CRollingBloomFilter{INVENTORY_MAX_RECENT_RELAY, 0.000001};
CNodeState(bool is_inbound) : m_is_inbound(is_inbound) {}
};
// Keeps track of the time (in microseconds) when transactions were requested last time
unordered_limitedmap<uint256, std::chrono::microseconds, StaticSaltedHasher> g_already_asked_for(MAX_INV_SZ, MAX_INV_SZ * 2);
unordered_limitedmap<uint256, std::chrono::microseconds, StaticSaltedHasher> g_erased_object_requests(MAX_INV_SZ, MAX_INV_SZ * 2);
/** Map maintaining per-node state. */
static std::map<NodeId, CNodeState> mapNodeState GUARDED_BY(cs_main);
static CNodeState *State(NodeId pnode) EXCLUSIVE_LOCKS_REQUIRED(cs_main) {
std::map<NodeId, CNodeState>::iterator it = mapNodeState.find(pnode);
if (it == mapNodeState.end())
return nullptr;
return &it->second;
}
/**
* Whether the peer supports the address. For example, a peer that does not
* implement BIP155 cannot receive Tor v3 addresses because it requires
* ADDRv2 (BIP155) encoding.
*/
static bool IsAddrCompatible(const Peer& peer, const CAddress& addr)
{
return peer.m_wants_addrv2 || addr.IsAddrV1Compatible();
}
static void AddAddressKnown(Peer& peer, const CAddress& addr)
{
assert(peer.m_addr_known);
peer.m_addr_known->insert(addr.GetKey());
}
static void PushAddress(Peer& peer, const CAddress& addr, FastRandomContext& insecure_rand)
{
// Known checking here is only to save space from duplicates.
// Before sending, we'll filter it again for known addresses that were
// added after addresses were pushed.
assert(peer.m_addr_known);
if (addr.IsValid() && !peer.m_addr_known->contains(addr.GetKey()) && IsAddrCompatible(peer, addr)) {
if (peer.m_addrs_to_send.size() >= MAX_ADDR_TO_SEND) {
peer.m_addrs_to_send[insecure_rand.randrange(peer.m_addrs_to_send.size())] = addr;
} else {
peer.m_addrs_to_send.push_back(addr);
}
}
}
static void AddKnownInv(Peer& peer, const uint256& hash)
{
// Dash always initializes m_tx_relay
assert(peer.m_tx_relay != nullptr);
LOCK(peer.m_tx_relay->m_tx_inventory_mutex);
peer.m_tx_relay->m_tx_inventory_known_filter.insert(hash);
}
/** Whether this peer can serve us blocks. */
static bool CanServeBlocks(const Peer& peer)
{
return peer.m_their_services & (NODE_NETWORK|NODE_NETWORK_LIMITED);
}
/* Whether this peer supports compressed headers (DIP 25) */
static bool UsesCompressedHeaders(const Peer& peer)
{
return peer.m_their_services & NODE_HEADERS_COMPRESSED;
}
/** Whether this peer can only serve limited recent blocks (e.g. because
* it prunes old blocks) */
static bool IsLimitedPeer(const Peer& peer)
{
return (!(peer.m_their_services & NODE_NETWORK) &&
(peer.m_their_services & NODE_NETWORK_LIMITED));
}
static void PushInv(Peer& peer, const CInv& inv)
{
// Dash always initializes m_tx_relay
assert(peer.m_tx_relay != nullptr);
ASSERT_IF_DEBUG(inv.type != MSG_BLOCK);
if (inv.type == MSG_BLOCK) {
LogPrintf("%s -- WARNING: using PushInv for BLOCK inv, peer=%d\n", __func__, peer.m_id);
return;
}
LOCK(peer.m_tx_relay->m_tx_inventory_mutex);
if (peer.m_tx_relay->m_tx_inventory_known_filter.contains(inv.hash)) {
LogPrint(BCLog::NET, "%s -- skipping known inv: %s peer=%d\n", __func__, inv.ToString(), peer.m_id);
return;
}
LogPrint(BCLog::NET, "%s -- adding new inv: %s peer=%d\n", __func__, inv.ToString(), peer.m_id);
if (inv.type == MSG_TX || inv.type == MSG_DSTX) {
peer.m_tx_relay->m_tx_inventory_to_send.insert(inv.hash);
return;
}
peer.m_tx_relay->vInventoryOtherToSend.push_back(inv);
}
static void UpdatePreferredDownload(const CNode& node, const Peer& peer, CNodeState* state) EXCLUSIVE_LOCKS_REQUIRED(cs_main)
{
nPreferredDownload -= state->fPreferredDownload;
// Whether this node should be marked as a preferred download node.
state->fPreferredDownload = (!node.IsInboundConn() || node.HasPermission(NetPermissionFlags::NoBan)) && !node.IsAddrFetchConn() && CanServeBlocks(peer);
nPreferredDownload += state->fPreferredDownload;
}
bool PeerManagerImpl::MarkBlockAsReceived(const uint256& hash)
{
std::map<uint256, std::pair<NodeId, std::list<QueuedBlock>::iterator> >::iterator itInFlight = mapBlocksInFlight.find(hash);
if (itInFlight != mapBlocksInFlight.end()) {
CNodeState *state = State(itInFlight->second.first);
assert(state != nullptr);
state->nBlocksInFlightValidHeaders -= itInFlight->second.second->fValidatedHeaders;
if (state->nBlocksInFlightValidHeaders == 0 && itInFlight->second.second->fValidatedHeaders) {
// Last validated block on the queue was received.
nPeersWithValidatedDownloads--;
}
if (state->vBlocksInFlight.begin() == itInFlight->second.second) {
// First block on the queue was received, update the start download time for the next one
state->m_downloading_since = std::max(state->m_downloading_since, GetTime<std::chrono::microseconds>());
}
state->vBlocksInFlight.erase(itInFlight->second.second);
state->nBlocksInFlight--;
state->m_stalling_since = 0us;
mapBlocksInFlight.erase(itInFlight);
return true;
}
return false;
}
bool PeerManagerImpl::MarkBlockAsInFlight(NodeId nodeid, const uint256& hash, const CBlockIndex *pindex, std::list<QueuedBlock>::iterator **pit)
{
CNodeState *state = State(nodeid);
assert(state != nullptr);
// Short-circuit most stuff in case it is from the same node
std::map<uint256, std::pair<NodeId, std::list<QueuedBlock>::iterator> >::iterator itInFlight = mapBlocksInFlight.find(hash);
if (itInFlight != mapBlocksInFlight.end() && itInFlight->second.first == nodeid) {
if (pit) {
*pit = &itInFlight->second.second;
}
return false;
}
// Make sure it's not listed somewhere already.
MarkBlockAsReceived(hash);
std::list<QueuedBlock>::iterator it = state->vBlocksInFlight.insert(state->vBlocksInFlight.end(),
{hash, pindex, pindex != nullptr, std::unique_ptr<PartiallyDownloadedBlock>(pit ? new PartiallyDownloadedBlock(&m_mempool) : nullptr)});
state->nBlocksInFlight++;
state->nBlocksInFlightValidHeaders += it->fValidatedHeaders;
if (state->nBlocksInFlight == 1) {
// We're starting a block download (batch) from this peer.
state->m_downloading_since = GetTime<std::chrono::microseconds>();
}
if (state->nBlocksInFlightValidHeaders == 1 && pindex != nullptr) {
nPeersWithValidatedDownloads++;
}
itInFlight = mapBlocksInFlight.insert(std::make_pair(hash, std::make_pair(nodeid, it))).first;
if (pit)
*pit = &itInFlight->second.second;
return true;
}
void PeerManagerImpl::MaybeSetPeerAsAnnouncingHeaderAndIDs(NodeId nodeid)
{
AssertLockHeld(cs_main);
// Never request high-bandwidth mode from peers if we're blocks-only. Our
// mempool will not contain the transactions necessary to reconstruct the
// compact block.
if (m_ignore_incoming_txs) return;
CNodeState* nodestate = State(nodeid);
if (!nodestate || !nodestate->m_provides_cmpctblocks) {
// Don't request compact blocks if the peer has not signalled support
return;
}
int num_outbound_hb_peers = 0;
for (std::list<NodeId>::iterator it = lNodesAnnouncingHeaderAndIDs.begin(); it != lNodesAnnouncingHeaderAndIDs.end(); it++) {
if (*it == nodeid) {
lNodesAnnouncingHeaderAndIDs.erase(it);
lNodesAnnouncingHeaderAndIDs.push_back(nodeid);
return;
}
CNodeState *state = State(*it);
if (state != nullptr && !state->m_is_inbound) ++num_outbound_hb_peers;
}
if (nodestate->m_is_inbound) {
// If we're adding an inbound HB peer, make sure we're not removing
// our last outbound HB peer in the process.
if (lNodesAnnouncingHeaderAndIDs.size() >= 3 && num_outbound_hb_peers == 1) {
CNodeState *remove_node = State(lNodesAnnouncingHeaderAndIDs.front());
if (remove_node != nullptr && !remove_node->m_is_inbound) {
// Put the HB outbound peer in the second slot, so that it
// doesn't get removed.
std::swap(lNodesAnnouncingHeaderAndIDs.front(), *std::next(lNodesAnnouncingHeaderAndIDs.begin()));
}
}
}
m_connman.ForNode(nodeid, [this](CNode* pfrom) EXCLUSIVE_LOCKS_REQUIRED(::cs_main) {
AssertLockHeld(::cs_main);
if (lNodesAnnouncingHeaderAndIDs.size() >= 3) {
// As per BIP152, we only get 3 of our peers to announce
// blocks using compact encodings.
m_connman.ForNode(lNodesAnnouncingHeaderAndIDs.front(), [this](CNode* pnodeStop){
m_connman.PushMessage(pnodeStop, CNetMsgMaker(pnodeStop->GetCommonVersion()).Make(NetMsgType::SENDCMPCT, /*high_bandwidth=*/false, /*version=*/CMPCTBLOCKS_VERSION));
// save BIP152 bandwidth state: we select peer to be low-bandwidth
pnodeStop->m_bip152_highbandwidth_to = false;
return true;
});
lNodesAnnouncingHeaderAndIDs.pop_front();
}
m_connman.PushMessage(pfrom, CNetMsgMaker(pfrom->GetCommonVersion()).Make(NetMsgType::SENDCMPCT, /*high_bandwidth=*/true, /*version=*/CMPCTBLOCKS_VERSION));
// save BIP152 bandwidth state: we select peer to be high-bandwidth
pfrom->m_bip152_highbandwidth_to = true;
lNodesAnnouncingHeaderAndIDs.push_back(pfrom->GetId());
return true;
});
}
bool PeerManagerImpl::TipMayBeStale()
{
AssertLockHeld(cs_main);
const Consensus::Params& consensusParams = m_chainparams.GetConsensus();
if (m_last_tip_update.load() == 0s) {
m_last_tip_update = GetTime<std::chrono::seconds>();
}
return m_last_tip_update.load() < GetTime<std::chrono::seconds>() - std::chrono::seconds{consensusParams.nPowTargetSpacing * 3} && mapBlocksInFlight.empty();
}
bool PeerManagerImpl::CanDirectFetch()
{
return m_chainman.ActiveChain().Tip()->GetBlockTime() > GetAdjustedTime() - m_chainparams.GetConsensus().nPowTargetSpacing * 20;
}
static bool PeerHasHeader(CNodeState *state, const CBlockIndex *pindex) EXCLUSIVE_LOCKS_REQUIRED(cs_main)
{
if (state->pindexBestKnownBlock && pindex == state->pindexBestKnownBlock->GetAncestor(pindex->nHeight))
return true;
if (state->pindexBestHeaderSent && pindex == state->pindexBestHeaderSent->GetAncestor(pindex->nHeight))
return true;
return false;
}
void PeerManagerImpl::ProcessBlockAvailability(NodeId nodeid)
{
CNodeState *state = State(nodeid);
assert(state != nullptr);
if (!state->hashLastUnknownBlock.IsNull()) {
const CBlockIndex* pindex = m_chainman.m_blockman.LookupBlockIndex(state->hashLastUnknownBlock);
if (pindex && pindex->nChainWork > 0) {
if (state->pindexBestKnownBlock == nullptr || pindex->nChainWork >= state->pindexBestKnownBlock->nChainWork) {
state->pindexBestKnownBlock = pindex;
}
state->hashLastUnknownBlock.SetNull();
}
}
}
void PeerManagerImpl::UpdateBlockAvailability(NodeId nodeid, const uint256 &hash)
{
CNodeState *state = State(nodeid);
assert(state != nullptr);
ProcessBlockAvailability(nodeid);
const CBlockIndex* pindex = m_chainman.m_blockman.LookupBlockIndex(hash);
if (pindex && pindex->nChainWork > 0) {
// An actually better block was announced.
if (state->pindexBestKnownBlock == nullptr || pindex->nChainWork >= state->pindexBestKnownBlock->nChainWork) {
state->pindexBestKnownBlock = pindex;
}
} else {
// An unknown block was announced; just assume that the latest one is the best one.
state->hashLastUnknownBlock = hash;
}
}
void PeerManagerImpl::FindNextBlocksToDownload(const Peer& peer, unsigned int count, std::vector<const CBlockIndex*>& vBlocks, NodeId& nodeStaller)
{
if (count == 0)
return;
vBlocks.reserve(vBlocks.size() + count);
CNodeState *state = State(peer.m_id);
assert(state != nullptr);
// Make sure pindexBestKnownBlock is up to date, we'll need it.
ProcessBlockAvailability(peer.m_id);
if (state->pindexBestKnownBlock == nullptr || state->pindexBestKnownBlock->nChainWork < m_chainman.ActiveChain().Tip()->nChainWork || state->pindexBestKnownBlock->nChainWork < nMinimumChainWork) {
// This peer has nothing interesting.
return;
}
if (state->pindexLastCommonBlock == nullptr) {
// Bootstrap quickly by guessing a parent of our best tip is the forking point.
// Guessing wrong in either direction is not a problem.
state->pindexLastCommonBlock = m_chainman.ActiveChain()[std::min(state->pindexBestKnownBlock->nHeight, m_chainman.ActiveChain().Height())];
}
// If the peer reorganized, our previous pindexLastCommonBlock may not be an ancestor
// of its current tip anymore. Go back enough to fix that.
state->pindexLastCommonBlock = LastCommonAncestor(state->pindexLastCommonBlock, state->pindexBestKnownBlock);
if (state->pindexLastCommonBlock == state->pindexBestKnownBlock)
return;
std::vector<const CBlockIndex*> vToFetch;
const CBlockIndex *pindexWalk = state->pindexLastCommonBlock;
// Never fetch further than the best block we know the peer has, or more than BLOCK_DOWNLOAD_WINDOW + 1 beyond the last
// linked block we have in common with this peer. The +1 is so we can detect stalling, namely if we would be able to
// download that next block if the window were 1 larger.
int nWindowEnd = state->pindexLastCommonBlock->nHeight + BLOCK_DOWNLOAD_WINDOW;
int nMaxHeight = std::min<int>(state->pindexBestKnownBlock->nHeight, nWindowEnd + 1);
NodeId waitingfor = -1;
while (pindexWalk->nHeight < nMaxHeight) {
// Read up to 128 (or more, if more blocks than that are needed) successors of pindexWalk (towards
// pindexBestKnownBlock) into vToFetch. We fetch 128, because CBlockIndex::GetAncestor may be as expensive
// as iterating over ~100 CBlockIndex* entries anyway.
int nToFetch = std::min(nMaxHeight - pindexWalk->nHeight, std::max<int>(count - vBlocks.size(), 128));
vToFetch.resize(nToFetch);
pindexWalk = state->pindexBestKnownBlock->GetAncestor(pindexWalk->nHeight + nToFetch);
vToFetch[nToFetch - 1] = pindexWalk;
for (unsigned int i = nToFetch - 1; i > 0; i--) {
vToFetch[i - 1] = vToFetch[i]->pprev;
}
// Iterate over those blocks in vToFetch (in forward direction), adding the ones that
// are not yet downloaded and not in flight to vBlocks. In the meantime, update
// pindexLastCommonBlock as long as all ancestors are already downloaded, or if it's
// already part of our chain (and therefore don't need it even if pruned).
for (const CBlockIndex* pindex : vToFetch) {
if (!pindex->IsValid(BLOCK_VALID_TREE)) {
// We consider the chain that this peer is on invalid.
return;
}
if (pindex->nStatus & BLOCK_HAVE_DATA || m_chainman.ActiveChain().Contains(pindex)) {
if (pindex->HaveTxsDownloaded())
state->pindexLastCommonBlock = pindex;
} else if (mapBlocksInFlight.count(pindex->GetBlockHash()) == 0) {
// The block is not already downloaded, and not yet in flight.
if (pindex->nHeight > nWindowEnd) {
// We reached the end of the window.
if (vBlocks.size() == 0 && waitingfor != peer.m_id) {
// We aren't able to fetch anything, but we would be if the download window was one larger.
nodeStaller = waitingfor;
}
return;
}
vBlocks.push_back(pindex);
if (vBlocks.size() == count) {
return;
}
} else if (waitingfor == -1) {
// This is the first already-in-flight block.
waitingfor = mapBlocksInFlight[pindex->GetBlockHash()].first;
}
}
}
}
} // namespace
void PeerManagerImpl::PushNodeVersion(CNode& pnode, const Peer& peer)
{
const auto& params = Params();
uint64_t my_services{peer.m_our_services};
const int64_t nTime{count_seconds(GetTime<std::chrono::seconds>())};
uint64_t nonce = pnode.GetLocalNonce();
const int nNodeStartingHeight{m_best_height};
NodeId nodeid = pnode.GetId();
CAddress addr = pnode.addr;
CService addr_you = addr.IsRoutable() && !IsProxy(addr) && addr.IsAddrV1Compatible() ? addr : CService();
uint64_t your_services{addr.nServices};
uint256 mnauthChallenge;
GetRandBytes({mnauthChallenge.begin(), mnauthChallenge.size()});
pnode.SetSentMNAuthChallenge(mnauthChallenge);
int nProtocolVersion = PROTOCOL_VERSION;
if (params.NetworkIDString() != CBaseChainParams::MAIN && gArgs.IsArgSet("-pushversion")) {
nProtocolVersion = gArgs.GetArg("-pushversion", PROTOCOL_VERSION);
}
const bool tx_relay = !m_ignore_incoming_txs && !pnode.IsBlockOnlyConn();
m_connman.PushMessage(&pnode, CNetMsgMaker(INIT_PROTO_VERSION).Make(NetMsgType::VERSION, nProtocolVersion, my_services, nTime,
your_services, addr_you, // Together the pre-version-31402 serialization of CAddress "addrYou" (without nTime)
my_services, CService(), // Together the pre-version-31402 serialization of CAddress "addrMe" (without nTime)
nonce, strSubVersion, nNodeStartingHeight, tx_relay, mnauthChallenge, pnode.m_masternode_connection.load()));
if (fLogIPs) {
LogPrint(BCLog::NET, "send version message: version %d, blocks=%d, them=%s, txrelay=%d, peer=%d\n", nProtocolVersion, nNodeStartingHeight, addr_you.ToString(), tx_relay, nodeid);
} else {
LogPrint(BCLog::NET, "send version message: version %d, blocks=%d, txrelay=%d, peer=%d\n", nProtocolVersion, nNodeStartingHeight, tx_relay, nodeid);
}
}
void EraseObjectRequest(CNodeState* nodestate, const CInv& inv) EXCLUSIVE_LOCKS_REQUIRED(cs_main)
{
AssertLockHeld(cs_main);
LogPrint(BCLog::NET, "%s -- inv=(%s)\n", __func__, inv.ToString());
g_already_asked_for.erase(inv.hash);
g_erased_object_requests.insert(std::make_pair(inv.hash, GetTime<std::chrono::microseconds>()));
if (nodestate) {
nodestate->m_object_download.m_object_announced.erase(inv);
nodestate->m_object_download.m_object_in_flight.erase(inv);
}
}
void EraseObjectRequest(NodeId nodeId, const CInv& inv) EXCLUSIVE_LOCKS_REQUIRED(cs_main)
{
AssertLockHeld(cs_main);
auto* state = State(nodeId);
if (!state) {
return;
}
EraseObjectRequest(state, inv);
}
std::chrono::microseconds GetObjectRequestTime(const CInv& inv) EXCLUSIVE_LOCKS_REQUIRED(cs_main)
{
AssertLockHeld(cs_main);
auto it = g_already_asked_for.find(inv.hash);
if (it != g_already_asked_for.end()) {
return it->second;
}
return {};
}
void UpdateObjectRequestTime(const CInv& inv, std::chrono::microseconds request_time) EXCLUSIVE_LOCKS_REQUIRED(cs_main)
{
AssertLockHeld(cs_main);
auto it = g_already_asked_for.find(inv.hash);
if (it == g_already_asked_for.end()) {
g_already_asked_for.insert(std::make_pair(inv.hash, request_time));
} else {
g_already_asked_for.update(it, request_time);
}
}
std::chrono::microseconds GetObjectInterval(int invType)
{
// some messages need to be re-requested faster when the first announcing peer did not answer to GETDATA
switch(invType)
{
case MSG_QUORUM_RECOVERED_SIG:
return std::chrono::seconds{15};
case MSG_CLSIG:
return std::chrono::seconds{5};
case MSG_ISDLOCK:
return std::chrono::seconds{10};
default:
return GETDATA_TX_INTERVAL;
}
}
std::chrono::microseconds GetObjectExpiryInterval(int invType)
{
return GetObjectInterval(invType) * TX_EXPIRY_INTERVAL_FACTOR;
}
std::chrono::microseconds GetObjectRandomDelay(int invType)
{
if (invType == MSG_TX) {
return GetRandMicros(MAX_GETDATA_RANDOM_DELAY);
}
return {};
}
std::chrono::microseconds CalculateObjectGetDataTime(const CInv& inv, std::chrono::microseconds current_time, bool is_masternode, bool use_inbound_delay) EXCLUSIVE_LOCKS_REQUIRED(cs_main)
{
AssertLockHeld(cs_main);
std::chrono::microseconds process_time;
const auto last_request_time = GetObjectRequestTime(inv);
// First time requesting this tx
if (last_request_time.count() == 0) {
process_time = current_time;
} else {
// Randomize the delay to avoid biasing some peers over others (such as due to
// fixed ordering of peer processing in ThreadMessageHandler)
process_time = last_request_time + GetObjectInterval(inv.type) + GetObjectRandomDelay(inv.type);
}
// We delay processing announcements from inbound peers
if (inv.IsMsgTx() && !is_masternode && use_inbound_delay) process_time += INBOUND_PEER_TX_DELAY;
return process_time;
}
void RequestObject(CNodeState* state, const CInv& inv, std::chrono::microseconds current_time, bool is_masternode, bool fForce = false) EXCLUSIVE_LOCKS_REQUIRED(cs_main)
{
AssertLockHeld(cs_main);
CNodeState::ObjectDownloadState& peer_download_state = state->m_object_download;
if (peer_download_state.m_object_announced.size() >= MAX_PEER_OBJECT_ANNOUNCEMENTS ||
peer_download_state.m_object_process_time.size() >= MAX_PEER_OBJECT_ANNOUNCEMENTS ||
peer_download_state.m_object_announced.count(inv)) {
// Too many queued announcements from this peer, or we already have
// this announcement
return;
}
peer_download_state.m_object_announced.insert(inv);
// Calculate the time to try requesting this transaction. Use
// fPreferredDownload as a proxy for outbound peers.
std::chrono::microseconds process_time = CalculateObjectGetDataTime(inv, current_time, is_masternode, !state->fPreferredDownload);
peer_download_state.m_object_process_time.emplace(process_time, inv);
if (fForce) {
// make sure this object is actually requested ASAP
g_erased_object_requests.erase(inv.hash);
g_already_asked_for.erase(inv.hash);
}
LogPrint(BCLog::NET, "%s -- inv=(%s), current_time=%d, process_time=%d, delta=%d\n", __func__, inv.ToString(), current_time.count(), process_time.count(), (process_time - current_time).count());
}
void RequestObject(NodeId nodeId, const CInv& inv, std::chrono::microseconds current_time, bool is_masternode, bool fForce) EXCLUSIVE_LOCKS_REQUIRED(cs_main)
{
AssertLockHeld(cs_main);
auto* state = State(nodeId);
if (!state) {
return;
}
RequestObject(state, inv, current_time, is_masternode, fForce);
}
size_t GetRequestedObjectCount(NodeId nodeId)
{
AssertLockHeld(cs_main);
auto* state = State(nodeId);
if (!state) {
return 0;
}
return state->m_object_download.m_object_process_time.size();
}
// This function is used for testing the stale tip eviction logic, see
// denialofservice_tests.cpp
void UpdateLastBlockAnnounceTime(NodeId node, int64_t time_in_seconds)
{
LOCK(cs_main);
CNodeState *state = State(node);
if (state) state->m_last_block_announcement = time_in_seconds;
}
void PeerManagerImpl::InitializeNode(CNode& node, ServiceFlags our_services) {
NodeId nodeid = node.GetId();
{
LOCK(cs_main);
mapNodeState.emplace_hint(mapNodeState.end(), std::piecewise_construct, std::forward_as_tuple(nodeid), std::forward_as_tuple(node.IsInboundConn()));
}
PeerRef peer = std::make_shared<Peer>(nodeid, our_services, /* block_relay_only = */ node.IsBlockOnlyConn());
{
LOCK(m_peer_mutex);
m_peer_map.emplace_hint(m_peer_map.end(), nodeid, peer);
}
if (!node.IsInboundConn()) {
PushNodeVersion(node, *peer);
}
}
void PeerManagerImpl::ReattemptInitialBroadcast(CScheduler& scheduler)
{
std::set<uint256> unbroadcast_txids = m_mempool.GetUnbroadcastTxs();
for (const uint256& txid : unbroadcast_txids) {
CTransactionRef tx = m_mempool.get(txid);
if (tx != nullptr) {
RelayTransaction(txid);
} else {
m_mempool.RemoveUnbroadcastTx(txid, true);
}
}
// Schedule next run for 10-15 minutes in the future.
// We add randomness on every cycle to avoid the possibility of P2P fingerprinting.
const std::chrono::milliseconds delta = std::chrono::minutes{10} + GetRandMillis(std::chrono::minutes{5});
scheduler.scheduleFromNow([&] { ReattemptInitialBroadcast(scheduler); }, delta);
}
void PeerManagerImpl::FinalizeNode(const CNode& node) {
NodeId nodeid = node.GetId();
int misbehavior{0};
LOCK(cs_main);
{
{
// We remove the PeerRef from g_peer_map here, but we don't always
// destruct the Peer. Sometimes another thread is still holding a
// PeerRef, so the refcount is >= 1. Be careful not to do any
// processing here that assumes Peer won't be changed before it's
// destructed.
PeerRef peer = RemovePeer(nodeid);
assert(peer != nullptr);
misbehavior = WITH_LOCK(peer->m_misbehavior_mutex, return peer->m_misbehavior_score);
}
CNodeState *state = State(nodeid);
assert(state != nullptr);
if (state->fSyncStarted)
nSyncStarted--;
for (const QueuedBlock& entry : state->vBlocksInFlight) {
mapBlocksInFlight.erase(entry.hash);
}
EraseOrphansFor(nodeid);
nPreferredDownload -= state->fPreferredDownload;
nPeersWithValidatedDownloads -= (state->nBlocksInFlightValidHeaders != 0);
assert(nPeersWithValidatedDownloads >= 0);
m_outbound_peers_with_protect_from_disconnect -= state->m_chain_sync.m_protect;
assert(m_outbound_peers_with_protect_from_disconnect >= 0);
mapNodeState.erase(nodeid);
if (mapNodeState.empty()) {
// Do a consistency check after the last peer is removed.
assert(mapBlocksInFlight.empty());
assert(nPreferredDownload == 0);
assert(nPeersWithValidatedDownloads == 0);
assert(m_outbound_peers_with_protect_from_disconnect == 0);
}
} // cs_main
if (node.fSuccessfullyConnected && misbehavior == 0 && !node.IsBlockOnlyConn() && !node.IsInboundConn()) {
// Only change visible addrman state for full outbound peers. We don't
// call Connected() for feeler connections since they don't have
// fSuccessfullyConnected set.
m_addrman.Connected(node.addr);
}
LogPrint(BCLog::NET, "Cleared nodestate for peer=%d\n", nodeid);
}
PeerRef PeerManagerImpl::GetPeerRef(NodeId id) const
{
LOCK(m_peer_mutex);
auto it = m_peer_map.find(id);
return it != m_peer_map.end() ? it->second : nullptr;
}
PeerRef PeerManagerImpl::RemovePeer(NodeId id)
{
PeerRef ret;
LOCK(m_peer_mutex);
auto it = m_peer_map.find(id);
if (it != m_peer_map.end()) {
ret = std::move(it->second);
m_peer_map.erase(it);
}
return ret;
}
bool PeerManagerImpl::GetNodeStateStats(NodeId nodeid, CNodeStateStats& stats) const
{
{
LOCK(cs_main);
CNodeState* state = State(nodeid);
if (state == nullptr)
return false;
stats.nSyncHeight = state->pindexBestKnownBlock ? state->pindexBestKnownBlock->nHeight : -1;
stats.nCommonHeight = state->pindexLastCommonBlock ? state->pindexLastCommonBlock->nHeight : -1;
for (const QueuedBlock& queue : state->vBlocksInFlight) {
if (queue.pindex)
stats.vHeightInFlight.push_back(queue.pindex->nHeight);
}
}
PeerRef peer = GetPeerRef(nodeid);
if (peer == nullptr) return false;
stats.m_misbehavior_score = WITH_LOCK(peer->m_misbehavior_mutex, return peer->m_misbehavior_score);
stats.their_services = peer->m_their_services;
stats.m_starting_height = peer->m_starting_height;
// It is common for nodes with good ping times to suddenly become lagged,
// due to a new block arriving or other large transfer.
// Merely reporting pingtime might fool the caller into thinking the node was still responsive,
// since pingtime does not update until the ping is complete, which might take a while.
// So, if a ping is taking an unusually long time in flight,
// the caller can immediately detect that this is happening.
std::chrono::microseconds ping_wait{0};
if ((0 != peer->m_ping_nonce_sent) && (0 != peer->m_ping_start.load().count())) {
ping_wait = GetTime<std::chrono::microseconds>() - peer->m_ping_start.load();
}
if (!peer->m_block_relay_only) {
stats.m_relay_txs = WITH_LOCK(peer->m_tx_relay->m_bloom_filter_mutex, return peer->m_tx_relay->m_relay_txs);
} else {
stats.m_relay_txs = false;
}
stats.m_ping_wait = ping_wait;
stats.m_addr_processed = peer->m_addr_processed.load();
stats.m_addr_rate_limited = peer->m_addr_rate_limited.load();
stats.m_addr_relay_enabled = peer->m_addr_relay_enabled.load();
return true;
}
//////////////////////////////////////////////////////////////////////////////
//
// mapOrphanTransactions
//
static void AddToCompactExtraTransactions(const CTransactionRef& tx) EXCLUSIVE_LOCKS_REQUIRED(g_cs_orphans)
{
size_t max_extra_txn = gArgs.GetArg("-blockreconstructionextratxn", DEFAULT_BLOCK_RECONSTRUCTION_EXTRA_TXN);
if (max_extra_txn <= 0)
return;
if (!vExtraTxnForCompact.size())
vExtraTxnForCompact.resize(max_extra_txn);
vExtraTxnForCompact[vExtraTxnForCompactIt] = std::make_pair(tx->GetHash(), tx);
vExtraTxnForCompactIt = (vExtraTxnForCompactIt + 1) % max_extra_txn;
}
bool AddOrphanTx(const CTransactionRef& tx, NodeId peer) EXCLUSIVE_LOCKS_REQUIRED(g_cs_orphans)
{
const uint256& hash = tx->GetHash();
if (mapOrphanTransactions.count(hash))
return false;
// Ignore big transactions, to avoid a
// send-big-orphans memory exhaustion attack. If a peer has a legitimate
// large transaction with a missing parent then we assume
// it will rebroadcast it later, after the parent transaction(s)
// have been mined or received.
// 100 orphans, each of which is at most 99,999 bytes big is
// at most 10 megabytes of orphans and somewhat more byprev index (in the worst case):
unsigned int sz = GetSerializeSize(*tx, CTransaction::CURRENT_VERSION);
if (sz > MAX_STANDARD_TX_SIZE)
{
LogPrint(BCLog::MEMPOOL, "ignoring large orphan tx (size: %u, hash: %s)\n", sz, hash.ToString());
return false;
}
auto ret = mapOrphanTransactions.emplace(hash, COrphanTx{tx, peer, GetTime() + ORPHAN_TX_EXPIRE_TIME, g_orphan_list.size(), sz});
assert(ret.second);
g_orphan_list.push_back(ret.first);
for (const CTxIn& txin : tx->vin) {
mapOrphanTransactionsByPrev[txin.prevout].insert(ret.first);
}
AddToCompactExtraTransactions(tx);
nMapOrphanTransactionsSize += sz;
LogPrint(BCLog::MEMPOOL, "stored orphan tx %s (mapsz %u outsz %u)\n", hash.ToString(),
mapOrphanTransactions.size(), mapOrphanTransactionsByPrev.size());
statsClient.inc("transactions.orphans.add", 1.0f);
statsClient.gauge("transactions.orphans", mapOrphanTransactions.size());
return true;
}
int static EraseOrphanTx(uint256 hash) EXCLUSIVE_LOCKS_REQUIRED(g_cs_orphans)
{
std::map<uint256, COrphanTx>::iterator it = mapOrphanTransactions.find(hash);
if (it == mapOrphanTransactions.end())
return 0;
for (const CTxIn& txin : it->second.tx->vin)
{
auto itPrev = mapOrphanTransactionsByPrev.find(txin.prevout);
if (itPrev == mapOrphanTransactionsByPrev.end())
continue;
itPrev->second.erase(it);
if (itPrev->second.empty())
mapOrphanTransactionsByPrev.erase(itPrev);
}
size_t old_pos = it->second.list_pos;
assert(g_orphan_list[old_pos] == it);
if (old_pos + 1 != g_orphan_list.size()) {
// Unless we're deleting the last entry in g_orphan_list, move the last
// entry to the position we're deleting.
auto it_last = g_orphan_list.back();
g_orphan_list[old_pos] = it_last;
it_last->second.list_pos = old_pos;
}
g_orphan_list.pop_back();
assert(nMapOrphanTransactionsSize >= it->second.nTxSize);
nMapOrphanTransactionsSize -= it->second.nTxSize;
mapOrphanTransactions.erase(it);
statsClient.inc("transactions.orphans.remove", 1.0f);
statsClient.gauge("transactions.orphans", mapOrphanTransactions.size());
return 1;
}
void EraseOrphansFor(NodeId peer)
{
LOCK(g_cs_orphans);
int nErased = 0;
std::map<uint256, COrphanTx>::iterator iter = mapOrphanTransactions.begin();
while (iter != mapOrphanTransactions.end())
{
std::map<uint256, COrphanTx>::iterator maybeErase = iter++; // increment to avoid iterator becoming invalid
if (maybeErase->second.fromPeer == peer)
{
nErased += EraseOrphanTx(maybeErase->second.tx->GetHash());
}
}
if (nErased > 0) LogPrint(BCLog::MEMPOOL, "Erased %d orphan tx from peer=%d\n", nErased, peer);
}
unsigned int LimitOrphanTxSize(unsigned int nMaxOrphansSize)
{
LOCK(g_cs_orphans);
unsigned int nEvicted = 0;
static int64_t nNextSweep;
int64_t nNow = GetTime();
if (nNextSweep <= nNow) {
// Sweep out expired orphan pool entries:
int nErased = 0;
int64_t nMinExpTime = nNow + ORPHAN_TX_EXPIRE_TIME - ORPHAN_TX_EXPIRE_INTERVAL;
std::map<uint256, COrphanTx>::iterator iter = mapOrphanTransactions.begin();
while (iter != mapOrphanTransactions.end())
{
std::map<uint256, COrphanTx>::iterator maybeErase = iter++;
if (maybeErase->second.nTimeExpire <= nNow) {
nErased += EraseOrphanTx(maybeErase->second.tx->GetHash());
} else {
nMinExpTime = std::min(maybeErase->second.nTimeExpire, nMinExpTime);
}
}
// Sweep again 5 minutes after the next entry that expires in order to batch the linear scan.
nNextSweep = nMinExpTime + ORPHAN_TX_EXPIRE_INTERVAL;
if (nErased > 0) LogPrint(BCLog::MEMPOOL, "Erased %d orphan tx due to expiration\n", nErased);
}
FastRandomContext rng;
while (!mapOrphanTransactions.empty() && nMapOrphanTransactionsSize > nMaxOrphansSize)
{
// Evict a random orphan:
size_t randompos = rng.randrange(g_orphan_list.size());
EraseOrphanTx(g_orphan_list[randompos]->first);
++nEvicted;
}
return nEvicted;
}
void PeerManagerImpl::Misbehaving(const NodeId pnode, const int howmuch, const std::string& message)
{
assert(howmuch > 0);
PeerRef peer = GetPeerRef(pnode);
if (peer == nullptr) return;
LOCK(peer->m_misbehavior_mutex);
const int score_before{peer->m_misbehavior_score};
peer->m_misbehavior_score += howmuch;
const int score_now{peer->m_misbehavior_score};
const std::string message_prefixed = message.empty() ? "" : (": " + message);
std::string warning;
if (score_now >= DISCOURAGEMENT_THRESHOLD && score_before < DISCOURAGEMENT_THRESHOLD) {
warning = " DISCOURAGE THRESHOLD EXCEEDED";
peer->m_should_discourage = true;
statsClient.inc("misbehavior.banned", 1.0f);
} else {
statsClient.count("misbehavior.amount", howmuch, 1.0);
}
LogPrint(BCLog::NET, "Misbehaving: peer=%d (%d -> %d)%s%s\n",
pnode, score_before, score_now, warning, message_prefixed);
}
bool PeerManagerImpl::IsBanned(NodeId pnode)
{
PeerRef peer = GetPeerRef(pnode);
if (peer == nullptr)
return false;
LOCK(peer->m_misbehavior_mutex);
if (peer->m_should_discourage) {
return true;
}
return false;
}
bool PeerManagerImpl::MaybePunishNodeForBlock(NodeId nodeid, const BlockValidationState& state,
bool via_compact_block, const std::string& message)
{
switch (state.GetResult()) {
case BlockValidationResult::BLOCK_RESULT_UNSET:
break;
// The node is providing invalid data:
case BlockValidationResult::BLOCK_CONSENSUS:
case BlockValidationResult::BLOCK_MUTATED:
if (!via_compact_block) {
Misbehaving(nodeid, 100, message);
return true;
}
break;
case BlockValidationResult::BLOCK_CACHED_INVALID:
{
LOCK(cs_main);
CNodeState *node_state = State(nodeid);
if (node_state == nullptr) {
break;
}
// Discourage outbound (but not inbound) peers if on an invalid chain.
// Exempt HB compact block peers. Manual connections are always protected from discouragement.
if (!via_compact_block && !node_state->m_is_inbound) {
Misbehaving(nodeid, 100, message);
return true;
}
break;
}
case BlockValidationResult::BLOCK_INVALID_HEADER:
case BlockValidationResult::BLOCK_CHECKPOINT:
case BlockValidationResult::BLOCK_INVALID_PREV:
Misbehaving(nodeid, 100, message);
return true;
// Conflicting (but not necessarily invalid) data or different policy:
case BlockValidationResult::BLOCK_MISSING_PREV:
case BlockValidationResult::BLOCK_CHAINLOCK:
Misbehaving(nodeid, 10, message);
return true;
case BlockValidationResult::BLOCK_RECENT_CONSENSUS_CHANGE:
case BlockValidationResult::BLOCK_TIME_FUTURE:
break;
}
if (message != "") {
LogPrint(BCLog::NET, "peer=%d: %s\n", nodeid, message);
}
return false;
}
bool PeerManagerImpl::MaybePunishNodeForTx(NodeId nodeid, const TxValidationState& state, const std::string& message) {
switch (state.GetResult()) {
case TxValidationResult::TX_RESULT_UNSET:
break;
// The node is providing invalid data:
case TxValidationResult::TX_CONSENSUS:
{
LOCK(cs_main);
Misbehaving(nodeid, 100, message);
return true;
}
// Conflicting (but not necessarily invalid) data or different policy:
case TxValidationResult::TX_RECENT_CONSENSUS_CHANGE:
case TxValidationResult::TX_INPUTS_NOT_STANDARD:
case TxValidationResult::TX_NOT_STANDARD:
case TxValidationResult::TX_MISSING_INPUTS:
case TxValidationResult::TX_PREMATURE_SPEND:
case TxValidationResult::TX_CONFLICT:
case TxValidationResult::TX_MEMPOOL_POLICY:
// moved from BLOCK
case TxValidationResult::TX_BAD_SPECIAL:
case TxValidationResult::TX_CONFLICT_LOCK:
break;
}
if (message != "") {
LogPrint(BCLog::NET, "peer=%d: %s\n", nodeid, message);
}
return false;
}
bool PeerManagerImpl::BlockRequestAllowed(const CBlockIndex* pindex)
{
AssertLockHeld(cs_main);
if (m_chainman.ActiveChain().Contains(pindex)) return true;
return pindex->IsValid(BLOCK_VALID_SCRIPTS) && (m_chainman.m_best_header != nullptr) &&
(m_chainman.m_best_header->GetBlockTime() - pindex->GetBlockTime() < STALE_RELAY_AGE_LIMIT) &&
(GetBlockProofEquivalentTime(*m_chainman.m_best_header, *pindex, *m_chainman.m_best_header, m_chainparams.GetConsensus()) < STALE_RELAY_AGE_LIMIT);
}
std::optional<std::string> PeerManagerImpl::FetchBlock(NodeId peer_id, const CBlockIndex& block_index)
{
if (fImporting) return "Importing...";
if (fReindex) return "Reindexing...";
// Ensure this peer exists and hasn't been disconnected
PeerRef peer = GetPeerRef(peer_id);
if (peer == nullptr) return "Peer does not exist";
LOCK(cs_main);
// Mark block as in-flight unless it already is (for this peer).
// If a block was already in-flight for a different peer, its BLOCKTXN
// response will be dropped.
const uint256& hash{block_index.GetBlockHash()};
if (!MarkBlockAsInFlight(peer_id, hash, &block_index)) return "Already requested from this peer";
// Construct message to request the block
std::vector<CInv> invs{CInv(MSG_BLOCK, hash)};
// Send block request message to the peer
bool success = m_connman.ForNode(peer_id, [this, &invs](CNode* node) {
const CNetMsgMaker msgMaker(node->GetCommonVersion());
this->m_connman.PushMessage(node, msgMaker.Make(NetMsgType::GETDATA, invs));
return true;
});
if (!success) return "Peer not fully connected";
LogPrint(BCLog::NET, "Requesting block %s from peer=%d\n",
hash.ToString(), peer_id);
return std::nullopt;
}
std::unique_ptr<PeerManager> PeerManager::make(const CChainParams& chainparams, CConnman& connman, AddrMan& addrman, BanMan* banman,
ChainstateManager& chainman, CTxMemPool& pool,
CMasternodeMetaMan& mn_metaman, CMasternodeSync& mn_sync,
CGovernanceManager& govman, CSporkManager& sporkman,
const CActiveMasternodeManager* const mn_activeman,
const std::unique_ptr<CDeterministicMNManager>& dmnman,
const std::unique_ptr<CJContext>& cj_ctx,
const std::unique_ptr<LLMQContext>& llmq_ctx, bool ignore_incoming_txs)
{
return std::make_unique<PeerManagerImpl>(chainparams, connman, addrman, banman, chainman, pool, mn_metaman, mn_sync, govman, sporkman, mn_activeman, dmnman, cj_ctx, llmq_ctx, ignore_incoming_txs);
}
PeerManagerImpl::PeerManagerImpl(const CChainParams& chainparams, CConnman& connman, AddrMan& addrman, BanMan* banman,
ChainstateManager& chainman, CTxMemPool& pool,
CMasternodeMetaMan& mn_metaman, CMasternodeSync& mn_sync,
CGovernanceManager& govman, CSporkManager& sporkman,
const CActiveMasternodeManager* const mn_activeman,
const std::unique_ptr<CDeterministicMNManager>& dmnman,
const std::unique_ptr<CJContext>& cj_ctx,
const std::unique_ptr<LLMQContext>& llmq_ctx,
bool ignore_incoming_txs)
: m_chainparams(chainparams),
m_connman(connman),
m_addrman(addrman),
m_banman(banman),
m_chainman(chainman),
m_mempool(pool),
m_dmnman(dmnman),
m_cj_ctx(cj_ctx),
m_llmq_ctx(llmq_ctx),
m_mn_metaman(mn_metaman),
m_mn_sync(mn_sync),
m_govman(govman),
m_sporkman(sporkman),
m_mn_activeman(mn_activeman),
m_ignore_incoming_txs(ignore_incoming_txs)
{
}
void PeerManagerImpl::StartScheduledTasks(CScheduler& scheduler)
{
// Stale tip checking and peer eviction are on two different timers, but we
// don't want them to get out of sync due to drift in the scheduler, so we
// combine them in one function and schedule at the quicker (peer-eviction)
// timer.
static_assert(EXTRA_PEER_CHECK_INTERVAL < STALE_CHECK_INTERVAL, "peer eviction timer should be less than stale tip check timer");
scheduler.scheduleEvery([this] { this->CheckForStaleTipAndEvictPeers(); }, std::chrono::seconds{EXTRA_PEER_CHECK_INTERVAL});
// schedule next run for 10-15 minutes in the future
const std::chrono::milliseconds delta = std::chrono::minutes{10} + GetRandMillis(std::chrono::minutes{5});
scheduler.scheduleFromNow([&] { ReattemptInitialBroadcast(scheduler); }, delta);
}
/**
* Evict orphan txn pool entries (EraseOrphanTx) based on a newly connected
* block. Also save the time of the last tip update.
*/
void PeerManagerImpl::BlockConnected(const std::shared_ptr<const CBlock>& pblock, const CBlockIndex* pindex)
{
{
LOCK2(cs_main, g_cs_orphans);
std::vector<uint256> vOrphanErase;
std::set<uint256> orphanWorkSet;
for (const CTransactionRef& ptx : pblock->vtx) {
const CTransaction& tx = *ptx;
// Which orphan pool entries we should reprocess and potentially try to accept into mempool again?
for (size_t i = 0; i < tx.vin.size(); i++) {
auto itByPrev = mapOrphanTransactionsByPrev.find(COutPoint(tx.GetHash(), (uint32_t)i));
if (itByPrev == mapOrphanTransactionsByPrev.end()) continue;
for (const auto& elem : itByPrev->second) {
orphanWorkSet.insert(elem->first);
}
}
// Which orphan pool entries must we evict?
for (const auto& txin : tx.vin) {
auto itByPrev = mapOrphanTransactionsByPrev.find(txin.prevout);
if (itByPrev == mapOrphanTransactionsByPrev.end()) continue;
for (auto mi = itByPrev->second.begin(); mi != itByPrev->second.end(); ++mi) {
const CTransaction& orphanTx = *(*mi)->second.tx;
const uint256& orphanHash = orphanTx.GetHash();
vOrphanErase.push_back(orphanHash);
}
}
}
// Erase orphan transactions included or precluded by this block
if (vOrphanErase.size()) {
int nErased = 0;
for (const uint256& orphanHash : vOrphanErase) {
nErased += EraseOrphanTx(orphanHash);
}
LogPrint(BCLog::MEMPOOL, "Erased %d orphan tx included or conflicted by block\n", nErased);
}
while (!orphanWorkSet.empty()) {
LogPrint(BCLog::MEMPOOL, "Trying to process %d orphans\n", orphanWorkSet.size());
ProcessOrphanTx(orphanWorkSet);
}
m_last_tip_update = GetTime<std::chrono::seconds>();
}
{
LOCK(m_recent_confirmed_transactions_mutex);
for (const auto& ptx : pblock->vtx) {
m_recent_confirmed_transactions.insert(ptx->GetHash());
}
}
}
void PeerManagerImpl::BlockDisconnected(const std::shared_ptr<const CBlock> &block, const CBlockIndex* pindex)
{
// To avoid relay problems with transactions that were previously
// confirmed, clear our filter of recently confirmed transactions whenever
// there's a reorg.
// This means that in a 1-block reorg (where 1 block is disconnected and
// then another block reconnected), our filter will drop to having only one
// block's worth of transactions in it, but that should be fine, since
// presumably the most common case of relaying a confirmed transaction
// should be just after a new block containing it is found.
LOCK(m_recent_confirmed_transactions_mutex);
m_recent_confirmed_transactions.reset();
}
// All of the following cache a recent block, and are protected by cs_most_recent_block
static RecursiveMutex cs_most_recent_block;
static std::shared_ptr<const CBlock> most_recent_block GUARDED_BY(cs_most_recent_block);
static std::shared_ptr<const CBlockHeaderAndShortTxIDs> most_recent_compact_block GUARDED_BY(cs_most_recent_block);
static uint256 most_recent_block_hash GUARDED_BY(cs_most_recent_block);
/**
* Maintain state about the best-seen block and fast-announce a compact block
* to compatible peers.
*/
void PeerManagerImpl::NewPoWValidBlock(const CBlockIndex *pindex, const std::shared_ptr<const CBlock>& pblock) {
auto pcmpctblock = std::make_shared<const CBlockHeaderAndShortTxIDs>(*pblock);
const CNetMsgMaker msgMaker(PROTOCOL_VERSION);
LOCK(cs_main);
static int nHighestFastAnnounce = 0;
if (pindex->nHeight <= nHighestFastAnnounce)
return;
nHighestFastAnnounce = pindex->nHeight;
uint256 hashBlock(pblock->GetHash());
const std::shared_future<CSerializedNetMsg> lazy_ser{
std::async(std::launch::deferred, [&] { return msgMaker.Make(NetMsgType::CMPCTBLOCK, *pcmpctblock); })};
{
LOCK(cs_most_recent_block);
most_recent_block_hash = hashBlock;
most_recent_block = pblock;
most_recent_compact_block = pcmpctblock;
}
m_connman.ForEachNode([this, pindex, &lazy_ser, &hashBlock](CNode* pnode) {
LockAssertion lock(::cs_main);
// TODO: Avoid the repeated-serialization here
if (pnode->fDisconnect)
return;
ProcessBlockAvailability(pnode->GetId());
CNodeState &state = *State(pnode->GetId());
// If the peer has, or we announced to them the previous block already,
// but we don't think they have this one, go ahead and announce it
if (state.m_requested_hb_cmpctblocks && !PeerHasHeader(&state, pindex) && PeerHasHeader(&state, pindex->pprev)) {
LogPrint(BCLog::NET, "%s sending header-and-ids %s to peer=%d\n", "PeerManager::NewPoWValidBlock",
hashBlock.ToString(), pnode->GetId());
const CSerializedNetMsg& ser_cmpctblock{lazy_ser.get()};
m_connman.PushMessage(pnode, ser_cmpctblock.Copy());
state.pindexBestHeaderSent = pindex;
}
});
}
/**
* Update our best height and announce any block hashes which weren't previously
* in m_chainman.ActiveChain() to our peers.
*/
void PeerManagerImpl::UpdatedBlockTip(const CBlockIndex *pindexNew, const CBlockIndex *pindexFork, bool fInitialDownload){
m_best_height = pindexNew->nHeight;
SetServiceFlagsIBDCache(!fInitialDownload);
// Don't relay inventory during initial block download.
if (fInitialDownload) return;
// Find the hashes of all blocks that weren't previously in the best chain.
std::vector<uint256> vHashes;
const CBlockIndex *pindexToAnnounce = pindexNew;
while (pindexToAnnounce != pindexFork) {
vHashes.push_back(pindexToAnnounce->GetBlockHash());
pindexToAnnounce = pindexToAnnounce->pprev;
if (vHashes.size() == MAX_BLOCKS_TO_ANNOUNCE) {
// Limit announcements in case of a huge reorganization.
// Rely on the peer's synchronization mechanism in that case.
break;
}
}
// Relay to all peers
// TODO: Move CanRelay() to Peer and migrate to iteration through m_peer_map
m_connman.ForEachNode([this, &vHashes](CNode* pnode) {
if (!pnode->CanRelay()) return;
PeerRef peer = GetPeerRef(pnode->GetId());
if (peer == nullptr) return;
LOCK(peer->m_block_inv_mutex);
for (const uint256& hash : reverse_iterate(vHashes)) {
peer->m_blocks_for_headers_relay.push_back(hash);
}
});
m_connman.WakeMessageHandler();
}
/**
* Handle invalid block rejection and consequent peer discouragement, maintain which
* peers announce compact blocks.
*/
void PeerManagerImpl::BlockChecked(const CBlock& block, const BlockValidationState& state)
{
LOCK(cs_main);
const uint256 hash(block.GetHash());
std::map<uint256, std::pair<NodeId, bool> >::iterator it = mapBlockSource.find(hash);
// If the block failed validation, we know where it came from and we're still connected
// to that peer, maybe punish.
if (state.IsInvalid() &&
it != mapBlockSource.end() &&
State(it->second.first)) {
MaybePunishNodeForBlock(/*nodeid=*/ it->second.first, state, /*via_compact_block=*/ !it->second.second);
}
// Check that:
// 1. The block is valid
// 2. We're not in initial block download
// 3. This is currently the best block we're aware of. We haven't updated
// the tip yet so we have no way to check this directly here. Instead we
// just check that there are currently no other blocks in flight.
else if (state.IsValid() &&
!m_chainman.ActiveChainstate().IsInitialBlockDownload() &&
mapBlocksInFlight.count(hash) == mapBlocksInFlight.size()) {
if (it != mapBlockSource.end()) {
MaybeSetPeerAsAnnouncingHeaderAndIDs(it->second.first);
}
}
if (it != mapBlockSource.end())
mapBlockSource.erase(it);
}
//////////////////////////////////////////////////////////////////////////////
//
// Messages
//
bool PeerManagerImpl::AlreadyHave(const CInv& inv)
{
switch (inv.type)
{
case MSG_TX:
case MSG_DSTX:
{
if (m_chainman.ActiveChain().Tip()->GetBlockHash() != hashRecentRejectsChainTip)
{
// If the chain tip has changed previously rejected transactions
// might be now valid, e.g. due to a nLockTime'd tx becoming valid,
// or a double-spend. Reset the rejects filter and give those
// txs a second chance.
hashRecentRejectsChainTip = m_chainman.ActiveChain().Tip()->GetBlockHash();
m_recent_rejects.reset();
}
{
LOCK(g_cs_orphans);
if (mapOrphanTransactions.count(inv.hash)) return true;
}
{
LOCK(m_recent_confirmed_transactions_mutex);
if (m_recent_confirmed_transactions.contains(inv.hash)) return true;
}
// When we receive an islock for a previously rejected transaction, we have to
// drop the first-seen tx (which such a locked transaction was conflicting with)
// and re-request the locked transaction (which did not make it into the mempool
// previously due to txn-mempool-conflict rule). This means that we must ignore
// m_recent_rejects filter for such locked txes here.
// We also ignore m_recent_rejects filter for DSTX-es because a malicious peer might
// relay a valid DSTX as a regular TX first which would skip all the specific checks
// but would cause such tx to be rejected by ATMP due to 0 fee. Ignoring it here
// should let DSTX to be propagated by honest peer later. Note, that a malicious
// masternode would not be able to exploit this to spam the network with specially
// crafted invalid DSTX-es and potentially cause high load cheaply, because
// corresponding checks in ProcessMessage won't let it to send DSTX-es too often.
bool fIgnoreRecentRejects = inv.IsMsgDstx() ||
m_llmq_ctx->isman->IsWaitingForTx(inv.hash) ||
m_llmq_ctx->isman->IsLocked(inv.hash);
return (!fIgnoreRecentRejects && m_recent_rejects.contains(inv.hash)) ||
(inv.IsMsgDstx() && static_cast<bool>(m_cj_ctx->dstxman->GetDSTX(inv.hash))) ||
m_mempool.exists(inv.hash) ||
(g_txindex != nullptr && g_txindex->HasTx(inv.hash));
}
/*
Dash Related Inventory Messages
--
We shouldn't update the sync times for each of the messages when we already have it.
We're going to be asking many nodes upfront for the full inventory list, so we'll get duplicates of these.
We want to only update the time on new hits, so that we can time out appropriately if needed.
*/
case MSG_SPORK:
{
return m_sporkman.GetSporkByHash(inv.hash).has_value();
}
case MSG_GOVERNANCE_OBJECT:
case MSG_GOVERNANCE_OBJECT_VOTE:
return !m_govman.ConfirmInventoryRequest(inv);
case MSG_QUORUM_FINAL_COMMITMENT:
return m_llmq_ctx->quorum_block_processor->HasMineableCommitment(inv.hash);
case MSG_QUORUM_CONTRIB:
case MSG_QUORUM_COMPLAINT:
case MSG_QUORUM_JUSTIFICATION:
case MSG_QUORUM_PREMATURE_COMMITMENT:
return m_llmq_ctx->qdkgsman->AlreadyHave(inv);
case MSG_QUORUM_RECOVERED_SIG:
return m_llmq_ctx->sigman->AlreadyHave(inv);
case MSG_CLSIG:
return m_llmq_ctx->clhandler->AlreadyHave(inv);
case MSG_ISDLOCK:
return m_llmq_ctx->isman->AlreadyHave(inv);
}
// Don't know what it is, just say we already got one
return true;
}
bool PeerManagerImpl::AlreadyHaveBlock(const uint256& block_hash)
{
return m_chainman.m_blockman.LookupBlockIndex(block_hash) != nullptr;
}
void PeerManagerImpl::SendPings()
{
LOCK(m_peer_mutex);
for(auto& it : m_peer_map) it.second->m_ping_queued = true;
}
bool PeerManagerImpl::IsInvInFilter(NodeId nodeid, const uint256& hash) const
{
PeerRef peer = GetPeerRef(nodeid);
if (peer == nullptr)
return false;
if (peer->m_block_relay_only)
return false;
LOCK(peer->m_tx_relay->m_tx_inventory_mutex);
return peer->m_tx_relay->m_tx_inventory_known_filter.contains(hash);
}
void PeerManagerImpl::PushInventory(NodeId nodeid, const CInv& inv)
{
// TODO: Get rid of this function at some point
PeerRef peer = GetPeerRef(nodeid);
if (peer == nullptr)
return;
PushInv(*peer, inv);
}
void PeerManagerImpl::RelayInv(CInv &inv, const int minProtoVersion)
{
// TODO: Migrate to iteration through m_peer_map
m_connman.ForEachNode([&](CNode* pnode) {
if (pnode->nVersion < minProtoVersion || !pnode->CanRelay())
return;
PeerRef peer = GetPeerRef(pnode->GetId());
if (peer == nullptr) return;
PushInv(*peer, inv);
});
}
void PeerManagerImpl::RelayInvFiltered(CInv &inv, const CTransaction& relatedTx, const int minProtoVersion)
{
// TODO: Migrate to iteration through m_peer_map
m_connman.ForEachNode([&](CNode* pnode) {
if (pnode->nVersion < minProtoVersion || !pnode->CanRelay() || pnode->IsBlockOnlyConn()) {
return;
}
PeerRef peer = GetPeerRef(pnode->GetId());
if (peer == nullptr) return;
{
LOCK(peer->m_tx_relay->m_bloom_filter_mutex);
if (!peer->m_tx_relay->m_relay_txs) {
return;
}
if (peer->m_tx_relay->m_bloom_filter && !peer->m_tx_relay->m_bloom_filter->IsRelevantAndUpdate(relatedTx)) {
return;
}
}
PushInv(*peer, inv);
});
}
void PeerManagerImpl::RelayInvFiltered(CInv &inv, const uint256& relatedTxHash, const int minProtoVersion)
{
// TODO: Migrate to iteration through m_peer_map
m_connman.ForEachNode([&](CNode* pnode) {
if (pnode->nVersion < minProtoVersion || !pnode->CanRelay() || pnode->IsBlockOnlyConn()) {
return;
}
PeerRef peer = GetPeerRef(pnode->GetId());
if (peer == nullptr) return;
{
LOCK(peer->m_tx_relay->m_bloom_filter_mutex);
if (!peer->m_tx_relay->m_relay_txs) {
return;
}
if (peer->m_tx_relay->m_bloom_filter && !peer->m_tx_relay->m_bloom_filter->contains(relatedTxHash)) {
return;
}
}
PushInv(*peer, inv);
});
}
void PeerManagerImpl::RelayTransaction(const uint256& txid)
{
LOCK(m_peer_mutex);
for(auto& it : m_peer_map) {
Peer& peer = *it.second;
if (!peer.m_tx_relay) continue;
const CInv inv{m_cj_ctx->dstxman->GetDSTX(txid) ? MSG_DSTX : MSG_TX, txid};
PushInv(peer, inv);
};
}
void PeerManagerImpl::RelayAddress(NodeId originator,
const CAddress& addr,
bool fReachable)
{
// We choose the same nodes within a given 24h window (if the list of connected
// nodes does not change) and we don't relay to nodes that already know an
// address. So within 24h we will likely relay a given address once. This is to
// prevent a peer from unjustly giving their address better propagation by sending
// it to us repeatedly.
if (!fReachable && !addr.IsRelayable()) return;
// Relay to a limited number of other nodes
// Use deterministic randomness to send to the same nodes for 24 hours
// at a time so the m_addr_knowns of the chosen nodes prevent repeats
uint64_t hashAddr = addr.GetHash();
const CSipHasher hasher = m_connman.GetDeterministicRandomizer(RANDOMIZER_ID_ADDRESS_RELAY).Write(hashAddr << 32).Write((GetTime() + hashAddr) / (24 * 60 * 60));
FastRandomContext insecure_rand;
// Relay reachable addresses to 2 peers. Unreachable addresses are relayed randomly to 1 or 2 peers.
unsigned int nRelayNodes = (fReachable || (hasher.Finalize() & 1)) ? 2 : 1;
std::array<std::pair<uint64_t, Peer*>, 2> best{{{0, nullptr}, {0, nullptr}}};
assert(nRelayNodes <= best.size());
LOCK(m_peer_mutex);
for (auto& [id, peer] : m_peer_map) {
if (peer->m_addr_relay_enabled && id != originator && IsAddrCompatible(*peer, addr)) {
uint64_t hashKey = CSipHasher(hasher).Write(id).Finalize();
for (unsigned int i = 0; i < nRelayNodes; i++) {
if (hashKey > best[i].first) {
std::copy(best.begin() + i, best.begin() + nRelayNodes - 1, best.begin() + i + 1);
best[i] = std::make_pair(hashKey, peer.get());
break;
}
}
}
};
for (unsigned int i = 0; i < nRelayNodes && best[i].first != 0; i++) {
PushAddress(*best[i].second, addr, insecure_rand);
}
}
void PeerManagerImpl::ProcessGetBlockData(CNode& pfrom, Peer& peer, const CInv& inv, llmq::CInstantSendManager& isman)
{
std::shared_ptr<const CBlock> a_recent_block;
std::shared_ptr<const CBlockHeaderAndShortTxIDs> a_recent_compact_block;
{
LOCK(cs_most_recent_block);
a_recent_block = most_recent_block;
a_recent_compact_block = most_recent_compact_block;
}
bool need_activate_chain = false;
{
LOCK(cs_main);
const CBlockIndex* pindex = m_chainman.m_blockman.LookupBlockIndex(inv.hash);
if (pindex) {
if (pindex->HaveTxsDownloaded() && !pindex->IsValid(BLOCK_VALID_SCRIPTS) &&
pindex->IsValid(BLOCK_VALID_TREE)) {
// If we have the block and all of its parents, but have not yet validated it,
// we might be in the middle of connecting it (ie in the unlock of cs_main
// before ActivateBestChain but after AcceptBlock).
// In this case, we need to run ActivateBestChain prior to checking the relay
// conditions below.
need_activate_chain = true;
}
}
} // release cs_main before calling ActivateBestChain
if (need_activate_chain) {
BlockValidationState state;
if (!m_chainman.ActiveChainstate().ActivateBestChain(state, a_recent_block)) {
LogPrint(BCLog::NET, "failed to activate chain (%s)\n", state.ToString());
}
}
LOCK(cs_main);
const CBlockIndex* pindex = m_chainman.m_blockman.LookupBlockIndex(inv.hash);
if (!pindex) {
return;
}
if (!BlockRequestAllowed(pindex)) {
LogPrint(BCLog::NET, "%s: ignoring request from peer=%i for old block that isn't in the main chain\n", __func__, pfrom.GetId());
return;
}
const CNetMsgMaker msgMaker(pfrom.GetCommonVersion());
// disconnect node in case we have reached the outbound limit for serving historical blocks
if (m_connman.OutboundTargetReached(true) &&
(((m_chainman.m_best_header != nullptr) && (m_chainman.m_best_header->GetBlockTime() - pindex->GetBlockTime() > HISTORICAL_BLOCK_AGE)) || inv.IsMsgFilteredBlk()) &&
!pfrom.HasPermission(NetPermissionFlags::Download) // nodes with the download permission may exceed target
) {
LogPrint(BCLog::NET, "historical block serving limit reached, disconnect peer=%d\n", pfrom.GetId());
pfrom.fDisconnect = true;
return;
}
// Avoid leaking prune-height by never sending blocks below the NODE_NETWORK_LIMITED threshold
if (!pfrom.HasPermission(NetPermissionFlags::NoBan) && (
(((peer.m_our_services & NODE_NETWORK_LIMITED) == NODE_NETWORK_LIMITED) && ((peer.m_our_services & NODE_NETWORK) != NODE_NETWORK) && (m_chainman.ActiveChain().Tip()->nHeight - pindex->nHeight > (int)NODE_NETWORK_LIMITED_MIN_BLOCKS + 2 /* add two blocks buffer extension for possible races */) )
)) {
LogPrint(BCLog::NET, "Ignore block request below NODE_NETWORK_LIMITED threshold, disconnect peer=%d\n", pfrom.GetId());
//disconnect node and prevent it from stalling (would otherwise wait for the missing block)
pfrom.fDisconnect = true;
return;
}
// Pruned nodes may have deleted the block, so check whether
// it's available before trying to send.
if (!(pindex->nStatus & BLOCK_HAVE_DATA)) {
return;
}
std::shared_ptr<const CBlock> pblock;
if (a_recent_block && a_recent_block->GetHash() == pindex->GetBlockHash()) {
pblock = a_recent_block;
} else {
// Send block from disk
std::shared_ptr<CBlock> pblockRead = std::make_shared<CBlock>();
if (!ReadBlockFromDisk(*pblockRead, pindex, m_chainparams.GetConsensus()))
assert(!"cannot load block from disk");
pblock = pblockRead;
}
if (pblock) {
if (inv.IsMsgBlk()) {
m_connman.PushMessage(&pfrom, msgMaker.Make(NetMsgType::BLOCK, *pblock));
} else if (inv.IsMsgFilteredBlk()) {
bool sendMerkleBlock = false;
CMerkleBlock merkleBlock;
if (!pfrom.IsBlockOnlyConn()) {
LOCK(peer.m_tx_relay->m_bloom_filter_mutex);
if (peer.m_tx_relay->m_bloom_filter) {
sendMerkleBlock = true;
merkleBlock = CMerkleBlock(*pblock, *peer.m_tx_relay->m_bloom_filter);
}
}
if (sendMerkleBlock) {
m_connman.PushMessage(&pfrom, msgMaker.Make(NetMsgType::MERKLEBLOCK, merkleBlock));
// CMerkleBlock just contains hashes, so also push any transactions in the block the client did not see
// This avoids hurting performance by pointlessly requiring a round-trip
// Note that there is currently no way for a node to request any single transactions we didn't send here -
// they must either disconnect and retry or request the full block.
// Thus, the protocol spec specified allows for us to provide duplicate txn here,
// however we MUST always provide at least what the remote peer needs
typedef std::pair<unsigned int, uint256> PairType;
for (PairType &pair : merkleBlock.vMatchedTxn) {
m_connman.PushMessage(&pfrom, msgMaker.Make(NetMsgType::TX, *pblock->vtx[pair.first]));
}
for (PairType &pair : merkleBlock.vMatchedTxn) {
auto islock = isman.GetInstantSendLockByTxid(pair.second);
if (islock != nullptr) {
m_connman.PushMessage(&pfrom, msgMaker.Make(NetMsgType::ISDLOCK, *islock));
}
}
}
// else
// no response
} else if (inv.IsMsgCmpctBlk()) {
// If a peer is asking for old blocks, we're almost guaranteed
// they won't have a useful mempool to match against a compact block,
// and we don't feel like constructing the object for them, so
// instead we respond with the full, non-compact block.
if (CanDirectFetch() &&
pindex->nHeight >= m_chainman.ActiveChain().Height() - MAX_CMPCTBLOCK_DEPTH) {
if (a_recent_compact_block &&
a_recent_compact_block->header.GetHash() == pindex->GetBlockHash()) {
m_connman.PushMessage(&pfrom, msgMaker.Make(NetMsgType::CMPCTBLOCK, *a_recent_compact_block));
} else {
CBlockHeaderAndShortTxIDs cmpctblock{*pblock};
m_connman.PushMessage(&pfrom, msgMaker.Make(NetMsgType::CMPCTBLOCK, cmpctblock));
}
} else {
m_connman.PushMessage(&pfrom, msgMaker.Make(NetMsgType::BLOCK, *pblock));
}
}
}
{
LOCK(peer.m_block_inv_mutex);
// Trigger the peer node to send a getblocks request for the next batch of inventory
if (inv.hash == peer.m_continuation_block) {
// Send immediately. This must send even if redundant,
// and we want it right after the last block so they don't
// wait for other stuff first.
std::vector<CInv> vInv;
vInv.push_back(CInv(MSG_BLOCK, m_chainman.ActiveChain().Tip()->GetBlockHash()));
m_connman.PushMessage(&pfrom, msgMaker.Make(NetMsgType::INV, vInv));
peer.m_continuation_block.SetNull();
}
}
}
//! Determine whether or not a peer can request a transaction, and return it (or nullptr if not found or not allowed).
CTransactionRef PeerManagerImpl::FindTxForGetData(const CNode* peer, const uint256& txid, const std::chrono::seconds mempool_req, const std::chrono::seconds now)
{
auto txinfo = m_mempool.info(txid);
if (txinfo.tx) {
// If a TX could have been INVed in reply to a MEMPOOL request,
// or is older than UNCONDITIONAL_RELAY_DELAY, permit the request
// unconditionally.
if ((mempool_req.count() && txinfo.m_time <= mempool_req) || txinfo.m_time <= now - UNCONDITIONAL_RELAY_DELAY) {
return std::move(txinfo.tx);
}
}
{
LOCK(cs_main);
// Otherwise, the transaction must have been announced recently.
if (State(peer->GetId())->m_recently_announced_invs.contains(txid)) {
// If it was, it can be relayed from either the mempool...
if (txinfo.tx) return std::move(txinfo.tx);
// ... or the relay pool.
auto mi = mapRelay.find(txid);
if (mi != mapRelay.end()) return mi->second;
}
}
return {};
}
void PeerManagerImpl::ProcessGetData(CNode& pfrom, Peer& peer, const std::atomic<bool>& interruptMsgProc)
{
AssertLockNotHeld(cs_main);
std::deque<CInv>::iterator it = peer.m_getdata_requests.begin();
std::vector<CInv> vNotFound;
const CNetMsgMaker msgMaker(pfrom.GetCommonVersion());
const std::chrono::seconds now = GetTime<std::chrono::seconds>();
// Get last mempool request time
const std::chrono::seconds mempool_req = !pfrom.IsBlockOnlyConn() ? peer.m_tx_relay->m_last_mempool_req.load()
: std::chrono::seconds::min();
// Process as many TX items from the front of the getdata queue as
// possible, since they're common and it's efficient to batch process
// them.
while (it != peer.m_getdata_requests.end() && it->IsKnownType()) {
if (interruptMsgProc)
return;
// The send buffer provides backpressure. If there's no space in
// the buffer, pause processing until the next call.
if (pfrom.fPauseSend)
break;
const CInv &inv = *it;
if (inv.type == MSG_BLOCK || inv.type == MSG_FILTERED_BLOCK || inv.type == MSG_CMPCT_BLOCK) {
break;
}
++it;
if (peer.m_block_relay_only && NetMessageViolatesBlocksOnly(inv.GetCommand())) {
// Note that if we receive a getdata for non-block messages
// from a block-relay-only outbound peer that violate the policy,
// we skip such getdata messages from this peer
continue;
}
bool push = false;
if (inv.IsGenTxMsg()) {
CTransactionRef tx = FindTxForGetData(&pfrom, inv.hash, mempool_req, now);
if (tx) {
CCoinJoinBroadcastTx dstx;
if (inv.IsMsgDstx()) {
dstx = m_cj_ctx->dstxman->GetDSTX(inv.hash);
}
if (dstx) {
m_connman.PushMessage(&pfrom, msgMaker.Make(NetMsgType::DSTX, dstx));
} else {
m_connman.PushMessage(&pfrom, msgMaker.Make(NetMsgType::TX, *tx));
}
m_mempool.RemoveUnbroadcastTx(tx->GetHash());
push = true;
// As we're going to send tx, make sure its unconfirmed parents are made requestable.
std::vector<uint256> parent_ids_to_add;
{
LOCK(m_mempool.cs);
auto txiter = m_mempool.GetIter(tx->GetHash());
if (txiter) {
const CTxMemPoolEntry::Parents& parents = (*txiter)->GetMemPoolParentsConst();
parent_ids_to_add.reserve(parents.size());
for (const CTxMemPoolEntry& parent : parents) {
if (parent.GetTime() > now - UNCONDITIONAL_RELAY_DELAY) {
parent_ids_to_add.push_back(parent.GetTx().GetHash());
}
}
}
}
for (const uint256& parent_txid : parent_ids_to_add) {
// Relaying a transaction with a recent but unconfirmed parent.
if (WITH_LOCK(peer.m_tx_relay->m_tx_inventory_mutex, return !peer.m_tx_relay->m_tx_inventory_known_filter.contains(parent_txid))) {
LOCK(cs_main);
State(pfrom.GetId())->m_recently_announced_invs.insert(parent_txid);
}
}
}
}
if (!push && inv.type == MSG_SPORK) {
if (auto opt_spork = m_sporkman.GetSporkByHash(inv.hash)) {
m_connman.PushMessage(&pfrom, msgMaker.Make(NetMsgType::SPORK, *opt_spork));
push = true;
}
}
if (!push && inv.type == MSG_GOVERNANCE_OBJECT) {
CDataStream ss(SER_NETWORK, pfrom.GetCommonVersion());
bool topush = false;
if (m_govman.HaveObjectForHash(inv.hash)) {
ss.reserve(1000);
if (m_govman.SerializeObjectForHash(inv.hash, ss)) {
topush = true;
}
}
if (topush) {
m_connman.PushMessage(&pfrom, msgMaker.Make(NetMsgType::MNGOVERNANCEOBJECT, ss));
push = true;
}
}
if (!push && inv.type == MSG_GOVERNANCE_OBJECT_VOTE) {
CDataStream ss(SER_NETWORK, pfrom.GetCommonVersion());
bool topush = false;
if (m_govman.HaveVoteForHash(inv.hash)) {
ss.reserve(1000);
if (m_govman.SerializeVoteForHash(inv.hash, ss)) {
topush = true;
}
}
if (topush) {
m_connman.PushMessage(&pfrom, msgMaker.Make(NetMsgType::MNGOVERNANCEOBJECTVOTE, ss));
push = true;
}
}
if (!push && (inv.type == MSG_QUORUM_FINAL_COMMITMENT)) {
llmq::CFinalCommitment o;
if (m_llmq_ctx->quorum_block_processor->GetMineableCommitmentByHash(
inv.hash, o)) {
m_connman.PushMessage(&pfrom, msgMaker.Make(NetMsgType::QFCOMMITMENT, o));
push = true;
}
}
if (!push && (inv.type == MSG_QUORUM_CONTRIB)) {
llmq::CDKGContribution o;
if (m_llmq_ctx->qdkgsman->GetContribution(inv.hash, o)) {
m_connman.PushMessage(&pfrom, msgMaker.Make(NetMsgType::QCONTRIB, o));
push = true;
}
}
if (!push && (inv.type == MSG_QUORUM_COMPLAINT)) {
llmq::CDKGComplaint o;
if (m_llmq_ctx->qdkgsman->GetComplaint(inv.hash, o)) {
m_connman.PushMessage(&pfrom, msgMaker.Make(NetMsgType::QCOMPLAINT, o));
push = true;
}
}
if (!push && (inv.type == MSG_QUORUM_JUSTIFICATION)) {
llmq::CDKGJustification o;
if (m_llmq_ctx->qdkgsman->GetJustification(inv.hash, o)) {
m_connman.PushMessage(&pfrom, msgMaker.Make(NetMsgType::QJUSTIFICATION, o));
push = true;
}
}
if (!push && (inv.type == MSG_QUORUM_PREMATURE_COMMITMENT)) {
llmq::CDKGPrematureCommitment o;
if (m_llmq_ctx->qdkgsman->GetPrematureCommitment(inv.hash, o)) {
m_connman.PushMessage(&pfrom, msgMaker.Make(NetMsgType::QPCOMMITMENT, o));
push = true;
}
}
if (!push && (inv.type == MSG_QUORUM_RECOVERED_SIG)) {
llmq::CRecoveredSig o;
if (m_llmq_ctx->sigman->GetRecoveredSigForGetData(inv.hash, o)) {
m_connman.PushMessage(&pfrom, msgMaker.Make(NetMsgType::QSIGREC, o));
push = true;
}
}
if (!push && (inv.type == MSG_CLSIG)) {
llmq::CChainLockSig o;
if (m_llmq_ctx->clhandler->GetChainLockByHash(inv.hash, o)) {
m_connman.PushMessage(&pfrom, msgMaker.Make(NetMsgType::CLSIG, o));
push = true;
}
}
if (!push && inv.type == MSG_ISDLOCK) {
llmq::CInstantSendLock o;
if (m_llmq_ctx->isman->GetInstantSendLockByHash(inv.hash, o)) {
m_connman.PushMessage(&pfrom, msgMaker.Make(NetMsgType::ISDLOCK, o));
push = true;
}
}
if (!push) {
vNotFound.push_back(inv);
}
}
// Only process one BLOCK item per call, since they're uncommon and can be
// expensive to process.
if (it != peer.m_getdata_requests.end() && !pfrom.fPauseSend) {
const CInv &inv = *it++;
if (inv.IsGenBlkMsg()) {
ProcessGetBlockData(pfrom, peer, inv, *m_llmq_ctx->isman);
}
// else: If the first item on the queue is an unknown type, we erase it
// and continue processing the queue on the next call.
}
peer.m_getdata_requests.erase(peer.m_getdata_requests.begin(), it);
if (!vNotFound.empty()) {
// Let the peer know that we didn't find what it asked for, so it doesn't
// have to wait around forever.
// SPV clients care about this message: it's needed when they are
// recursively walking the dependencies of relevant unconfirmed
// transactions. SPV clients want to do that because they want to know
// about (and store and rebroadcast and risk analyze) the dependencies
// of transactions relevant to them, without having to download the
// entire memory pool.
// Also, other nodes can use these messages to automatically request a
// transaction from some other peer that annnounced it, and stop
// waiting for us to respond.
// In normal operation, we often send NOTFOUND messages for parents of
// transactions that we relay; if a peer is missing a parent, they may
// assume we have them and request the parents from us.
m_connman.PushMessage(&pfrom, msgMaker.Make(NetMsgType::NOTFOUND, vNotFound));
}
}
void PeerManagerImpl::SendBlockTransactions(CNode& pfrom, const CBlock& block, const BlockTransactionsRequest& req) {
BlockTransactions resp(req);
for (size_t i = 0; i < req.indexes.size(); i++) {
if (req.indexes[i] >= block.vtx.size()) {
Misbehaving(pfrom.GetId(), 100, "getblocktxn with out-of-bounds tx indices");
return;
}
resp.txn[i] = block.vtx[req.indexes[i]];
}
CNetMsgMaker msgMaker(pfrom.GetCommonVersion());
m_connman.PushMessage(&pfrom, msgMaker.Make(NetMsgType::BLOCKTXN, resp));
}
/**
* Special handling for unconnecting headers that might be part of a block
* announcement.
*
* We'll send a getheaders message in response to try to connect the chain.
*
* The peer can send up to MAX_UNCONNECTING_HEADERS in a row that
* don't connect before given DoS points.
*
* Once a headers message is received that is valid and does connect,
* nUnconnectingHeaders gets reset back to 0.
*/
void PeerManagerImpl::HandleFewUnconnectingHeaders(CNode& pfrom, Peer& peer,
const std::vector<CBlockHeader>& headers)
{
const CNetMsgMaker msgMaker(pfrom.GetCommonVersion());
LOCK(cs_main);
CNodeState *nodestate = State(pfrom.GetId());
nodestate->nUnconnectingHeaders++;
// Try to fill in the missing headers.
std::string msg_type = UsesCompressedHeaders(peer) ? NetMsgType::GETHEADERS2 : NetMsgType::GETHEADERS;
if (MaybeSendGetHeaders(pfrom, msg_type, m_chainman.ActiveChain().GetLocator(m_chainman.m_best_header), peer)) {
LogPrint(BCLog::NET, "received header %s: missing prev block %s, sending %s (%d) to end (peer=%d, nUnconnectingHeaders=%d)\n",
headers[0].GetHash().ToString(),
headers[0].hashPrevBlock.ToString(),
msg_type,
m_chainman.m_best_header->nHeight,
pfrom.GetId(), nodestate->nUnconnectingHeaders);
}
// Set hashLastUnknownBlock for this peer, so that if we
// eventually get the headers - even from a different peer -
// we can use this peer to download.
UpdateBlockAvailability(pfrom.GetId(), headers.back().GetHash());
// The peer may just be broken, so periodically assign DoS points if this
// condition persists.
if (nodestate->nUnconnectingHeaders % MAX_UNCONNECTING_HEADERS == 0) {
Misbehaving(pfrom.GetId(), 20, strprintf("%d non-connecting headers", nodestate->nUnconnectingHeaders));
}
}
bool PeerManagerImpl::CheckHeadersAreContinuous(const std::vector<CBlockHeader>& headers) const
{
uint256 hashLastBlock;
for (const CBlockHeader& header : headers) {
if (!hashLastBlock.IsNull() && header.hashPrevBlock != hashLastBlock) {
return false;
}
hashLastBlock = header.GetHash();
}
return true;
}
bool PeerManagerImpl::MaybeSendGetHeaders(CNode& pfrom, const std::string& msg_type, const CBlockLocator& locator, Peer& peer)
{
assert(msg_type == NetMsgType::GETHEADERS || msg_type == NetMsgType::GETHEADERS2);
const CNetMsgMaker msgMaker(pfrom.GetCommonVersion());
const auto current_time = GetTime<std::chrono::seconds>();
// Only allow a new getheaders message to go out if we don't have a recent
// one already in-flight
if (peer.m_last_getheaders_timestamp.load() < current_time - HEADERS_RESPONSE_TIME) {
m_connman.PushMessage(&pfrom, msgMaker.Make(msg_type, locator, uint256()));
peer.m_last_getheaders_timestamp = current_time;
return true;
}
return false;
}
/*
* Given a new headers tip ending in pindexLast, potentially request blocks towards that tip.
* We require that the given tip have at least as much work as our tip, and for
* our current tip to be "close to synced" (see CanDirectFetch()).
*/
void PeerManagerImpl::HeadersDirectFetchBlocks(CNode& pfrom, const Peer& peer, const CBlockIndex* pindexLast)
{
const CNetMsgMaker msgMaker(pfrom.GetCommonVersion());
LOCK(cs_main);
CNodeState *nodestate = State(pfrom.GetId());
if (CanDirectFetch() && pindexLast->IsValid(BLOCK_VALID_TREE) && m_chainman.ActiveChain().Tip()->nChainWork <= pindexLast->nChainWork) {
std::vector<const CBlockIndex*> vToFetch;
const CBlockIndex *pindexWalk = pindexLast;
// Calculate all the blocks we'd need to switch to pindexLast, up to a limit.
while (pindexWalk && !m_chainman.ActiveChain().Contains(pindexWalk) && vToFetch.size() <= MAX_BLOCKS_IN_TRANSIT_PER_PEER) {
if (!(pindexWalk->nStatus & BLOCK_HAVE_DATA) &&
!mapBlocksInFlight.count(pindexWalk->GetBlockHash())) {
// We don't have this block, and it's not yet in flight.
vToFetch.push_back(pindexWalk);
}
pindexWalk = pindexWalk->pprev;
}
// If pindexWalk still isn't on our main chain, we're looking at a
// very large reorg at a time we think we're close to caught up to
// the main chain -- this shouldn't really happen. Bail out on the
// direct fetch and rely on parallel download instead.
if (!m_chainman.ActiveChain().Contains(pindexWalk)) {
LogPrint(BCLog::NET, "Large reorg, won't direct fetch to %s (%d)\n",
pindexLast->GetBlockHash().ToString(),
pindexLast->nHeight);
} else {
std::vector<CInv> vGetData;
// Download as much as possible, from earliest to latest.
for (const CBlockIndex *pindex : reverse_iterate(vToFetch)) {
if (nodestate->nBlocksInFlight >= MAX_BLOCKS_IN_TRANSIT_PER_PEER) {
// Can't download any more from this peer
break;
}
vGetData.push_back(CInv(MSG_BLOCK, pindex->GetBlockHash()));
MarkBlockAsInFlight(pfrom.GetId(), pindex->GetBlockHash(), pindex);
LogPrint(BCLog::NET, "Requesting block %s from peer=%d\n",
pindex->GetBlockHash().ToString(), pfrom.GetId());
}
if (vGetData.size() > 1) {
LogPrint(BCLog::NET, "Downloading blocks toward %s (%d) via headers direct fetch\n",
pindexLast->GetBlockHash().ToString(), pindexLast->nHeight);
}
if (vGetData.size() > 0) {
if (!m_ignore_incoming_txs &&
nodestate->m_provides_cmpctblocks &&
vGetData.size() == 1 &&
mapBlocksInFlight.size() == 1 &&
pindexLast->pprev->IsValid(BLOCK_VALID_CHAIN)) {
// In any case, we want to download using a compact block, not a regular one
vGetData[0] = CInv(MSG_CMPCT_BLOCK, vGetData[0].hash);
}
m_connman.PushMessage(&pfrom, msgMaker.Make(NetMsgType::GETDATA, vGetData));
}
}
}
}
/**
* Given receipt of headers from a peer ending in pindexLast, along with
* whether that header was new and whether the headers message was full,
* update the state we keep for the peer.
*/
void PeerManagerImpl::UpdatePeerStateForReceivedHeaders(CNode& pfrom,
const CBlockIndex *pindexLast, bool received_new_header, bool may_have_more_headers)
{
LOCK(cs_main);
CNodeState *nodestate = State(pfrom.GetId());
if (nodestate->nUnconnectingHeaders > 0) {
LogPrint(BCLog::NET, "peer=%d: resetting nUnconnectingHeaders (%d -> 0)\n", pfrom.GetId(), nodestate->nUnconnectingHeaders);
}
nodestate->nUnconnectingHeaders = 0;
assert(pindexLast);
UpdateBlockAvailability(pfrom.GetId(), pindexLast->GetBlockHash());
// From here, pindexBestKnownBlock should be guaranteed to be non-null,
// because it is set in UpdateBlockAvailability. Some nullptr checks
// are still present, however, as belt-and-suspenders.
if (received_new_header && pindexLast->nChainWork > m_chainman.ActiveChain().Tip()->nChainWork) {
nodestate->m_last_block_announcement = GetTime();
}
// If we're in IBD, we want outbound peers that will serve us a useful
// chain. Disconnect peers that are on chains with insufficient work.
if (m_chainman.ActiveChainstate().IsInitialBlockDownload() && !may_have_more_headers) {
// If the peer has no more headers to give us, then we know we have
// their tip.
if (nodestate->pindexBestKnownBlock && nodestate->pindexBestKnownBlock->nChainWork < nMinimumChainWork) {
// This peer has too little work on their headers chain to help
// us sync -- disconnect if it is an outbound disconnection
// candidate.
// Note: We compare their tip to nMinimumChainWork (rather than
// m_chainman.ActiveChain().Tip()) because we won't start block download
// until we have a headers chain that has at least
// nMinimumChainWork, even if a peer has a chain past our tip,
// as an anti-DoS measure.
if (pfrom.IsOutboundOrBlockRelayConn()) {
LogPrintf("Disconnecting outbound peer %d -- headers chain has insufficient work\n", pfrom.GetId());
pfrom.fDisconnect = true;
}
}
}
// If this is an outbound full-relay peer, check to see if we should protect
// it from the bad/lagging chain logic.
// Note that outbound block-relay peers are excluded from this protection, and
// thus always subject to eviction under the bad/lagging chain logic.
// See ChainSyncTimeoutState.
if (!pfrom.fDisconnect && pfrom.IsFullOutboundConn() && nodestate->pindexBestKnownBlock != nullptr) {
if (m_outbound_peers_with_protect_from_disconnect < MAX_OUTBOUND_PEERS_TO_PROTECT_FROM_DISCONNECT && nodestate->pindexBestKnownBlock->nChainWork >= m_chainman.ActiveChain().Tip()->nChainWork && !nodestate->m_chain_sync.m_protect) {
LogPrint(BCLog::NET, "Protecting outbound peer=%d from eviction\n", pfrom.GetId());
nodestate->m_chain_sync.m_protect = true;
++m_outbound_peers_with_protect_from_disconnect;
}
}
}
void PeerManagerImpl::ProcessHeadersMessage(CNode& pfrom, Peer& peer,
const std::vector<CBlockHeader>& headers,
bool via_compact_block)
{
const CNetMsgMaker msgMaker(pfrom.GetCommonVersion());
size_t nCount = headers.size();
if (nCount == 0) {
// Nothing interesting. Stop asking this peers for more headers.
return;
}
const CBlockIndex *pindexLast = nullptr;
// Do these headers connect to something in our block index?
bool headers_connect_blockindex{WITH_LOCK(::cs_main, return m_chainman.m_blockman.LookupBlockIndex(headers[0].hashPrevBlock) != nullptr)};
if (!headers_connect_blockindex) {
if (nCount <= MAX_BLOCKS_TO_ANNOUNCE) {
// If this looks like it could be a BIP 130 block announcement, use
// special logic for handling headers that don't connect, as this
// could be benign.
HandleFewUnconnectingHeaders(pfrom, peer, headers);
} else {
Misbehaving(pfrom.GetId(), 10, "invalid header received");
}
return;
}
// At this point, the headers connect to something in our block index.
if (!CheckHeadersAreContinuous(headers)) {
Misbehaving(pfrom.GetId(), 20, "non-continuous headers sequence");
return;
}
// If we don't have the last header, then this peer will have given us
// something new (if these headers are valid).
bool received_new_header{WITH_LOCK(::cs_main, return m_chainman.m_blockman.LookupBlockIndex(headers.back().GetHash()) == nullptr)};
BlockValidationState state;
if (!m_chainman.ProcessNewBlockHeaders(headers, state, m_chainparams, &pindexLast)) {
if (state.IsInvalid()) {
MaybePunishNodeForBlock(pfrom.GetId(), state, via_compact_block, "invalid header received");
return;
}
}
// Consider fetching more headers.
if (nCount == MAX_HEADERS_RESULTS) {
std::string msg_type = UsesCompressedHeaders(peer) ? NetMsgType::GETHEADERS2 : NetMsgType::GETHEADERS;
// Headers message had its maximum size; the peer may have more headers.
if (MaybeSendGetHeaders(pfrom, msg_type, m_chainman.ActiveChain().GetLocator(pindexLast), peer)) {
LogPrint(BCLog::NET, "more %s (%d) to end to peer=%d (startheight:%d)\n",
msg_type, pindexLast->nHeight, pfrom.GetId(), peer.m_starting_height);
}
}
UpdatePeerStateForReceivedHeaders(pfrom, pindexLast, received_new_header, nCount == MAX_HEADERS_RESULTS);
// Consider immediately downloading blocks.
HeadersDirectFetchBlocks(pfrom, peer, pindexLast);
return;
}
/**
* Reconsider orphan transactions after a parent has been accepted to the mempool.
*
* @param[in,out] orphan_work_set The set of orphan transactions to reconsider. Generally only one
* orphan will be reconsidered on each call of this function. This set
* may be added to if accepting an orphan causes its children to be
* reconsidered.
*/
void PeerManagerImpl::ProcessOrphanTx(std::set<uint256>& orphan_work_set)
{
AssertLockHeld(cs_main);
AssertLockHeld(g_cs_orphans);
while (!orphan_work_set.empty()) {
const uint256 orphanHash = *orphan_work_set.begin();
orphan_work_set.erase(orphan_work_set.begin());
auto orphan_it = mapOrphanTransactions.find(orphanHash);
if (orphan_it == mapOrphanTransactions.end()) continue;
const CTransactionRef porphanTx = orphan_it->second.tx;
const MempoolAcceptResult result = AcceptToMemoryPool(m_chainman.ActiveChainstate(), m_mempool, porphanTx, false /* bypass_limits */);
const TxValidationState& state = result.m_state;
if (result.m_result_type == MempoolAcceptResult::ResultType::VALID) {
LogPrint(BCLog::MEMPOOL, " accepted orphan tx %s\n", orphanHash.ToString());
RelayTransaction(porphanTx->GetHash());
for (unsigned int i = 0; i < porphanTx->vout.size(); i++) {
auto it_by_prev = mapOrphanTransactionsByPrev.find(COutPoint(orphanHash, i));
if (it_by_prev != mapOrphanTransactionsByPrev.end()) {
for (const auto& elem : it_by_prev->second) {
orphan_work_set.insert(elem->first);
}
}
}
EraseOrphanTx(orphanHash);
break;
} else if (state.GetResult() != TxValidationResult::TX_MISSING_INPUTS) {
if (state.IsInvalid()) {
LogPrint(BCLog::MEMPOOL, " invalid orphan tx %s from peer=%d. %s\n",
orphanHash.ToString(),
orphan_it->second.fromPeer,
state.ToString());
// Maybe punish peer that gave us an invalid orphan tx
MaybePunishNodeForTx(orphan_it->second.fromPeer, state);
}
// Has inputs but not accepted to mempool
// Probably non-standard or insufficient fee
LogPrint(BCLog::MEMPOOL, " removed orphan tx %s\n", orphanHash.ToString());
m_recent_rejects.insert(orphanHash);
EraseOrphanTx(orphanHash);
break;
}
}
m_mempool.check(m_chainman.ActiveChainstate());
}
bool PeerManagerImpl::PrepareBlockFilterRequest(CNode& node, Peer& peer,
BlockFilterType filter_type, uint32_t start_height,
const uint256& stop_hash, uint32_t max_height_diff,
const CBlockIndex*& stop_index,
BlockFilterIndex*& filter_index)
{
const bool supported_filter_type =
(filter_type == BlockFilterType::BASIC_FILTER &&
(peer.m_our_services & NODE_COMPACT_FILTERS));
if (!supported_filter_type) {
LogPrint(BCLog::NET, "peer %d requested unsupported block filter type: %d\n",
node.GetId(), static_cast<uint8_t>(filter_type));
node.fDisconnect = true;
return false;
}
{
LOCK(cs_main);
stop_index = m_chainman.m_blockman.LookupBlockIndex(stop_hash);
// Check that the stop block exists and the peer would be allowed to fetch it.
if (!stop_index || !BlockRequestAllowed(stop_index)) {
LogPrint(BCLog::NET, "peer %d requested invalid block hash: %s\n",
node.GetId(), stop_hash.ToString());
node.fDisconnect = true;
return false;
}
}
uint32_t stop_height = stop_index->nHeight;
if (start_height > stop_height) {
LogPrint(BCLog::NET, "peer %d sent invalid getcfilters/getcfheaders with " /* Continued */
"start height %d and stop height %d\n",
node.GetId(), start_height, stop_height);
node.fDisconnect = true;
return false;
}
if (stop_height - start_height >= max_height_diff) {
LogPrint(BCLog::NET, "peer %d requested too many cfilters/cfheaders: %d / %d\n",
node.GetId(), stop_height - start_height + 1, max_height_diff);
node.fDisconnect = true;
return false;
}
filter_index = GetBlockFilterIndex(filter_type);
if (!filter_index) {
LogPrint(BCLog::NET, "Filter index for supported type %s not found\n", BlockFilterTypeName(filter_type));
return false;
}
return true;
}
void PeerManagerImpl::ProcessGetCFilters(CNode& node,Peer& peer, CDataStream& vRecv)
{
uint8_t filter_type_ser;
uint32_t start_height;
uint256 stop_hash;
vRecv >> filter_type_ser >> start_height >> stop_hash;
const BlockFilterType filter_type = static_cast<BlockFilterType>(filter_type_ser);
const CBlockIndex* stop_index;
BlockFilterIndex* filter_index;
if (!PrepareBlockFilterRequest(node, peer, filter_type, start_height, stop_hash,
MAX_GETCFILTERS_SIZE, stop_index, filter_index)) {
return;
}
std::vector<BlockFilter> filters;
if (!filter_index->LookupFilterRange(start_height, stop_index, filters)) {
LogPrint(BCLog::NET, "Failed to find block filter in index: filter_type=%s, start_height=%d, stop_hash=%s\n",
BlockFilterTypeName(filter_type), start_height, stop_hash.ToString());
return;
}
for (const auto& filter : filters) {
CSerializedNetMsg msg = CNetMsgMaker(node.GetCommonVersion())
.Make(NetMsgType::CFILTER, filter);
m_connman.PushMessage(&node, std::move(msg));
}
}
void PeerManagerImpl::ProcessGetCFHeaders(CNode& node, Peer& peer, CDataStream& vRecv)
{
uint8_t filter_type_ser;
uint32_t start_height;
uint256 stop_hash;
vRecv >> filter_type_ser >> start_height >> stop_hash;
const BlockFilterType filter_type = static_cast<BlockFilterType>(filter_type_ser);
const CBlockIndex* stop_index;
BlockFilterIndex* filter_index;
if (!PrepareBlockFilterRequest(node, peer, filter_type, start_height, stop_hash,
MAX_GETCFHEADERS_SIZE, stop_index, filter_index)) {
return;
}
uint256 prev_header;
if (start_height > 0) {
const CBlockIndex* const prev_block =
stop_index->GetAncestor(static_cast<int>(start_height - 1));
if (!filter_index->LookupFilterHeader(prev_block, prev_header)) {
LogPrint(BCLog::NET, "Failed to find block filter header in index: filter_type=%s, block_hash=%s\n",
BlockFilterTypeName(filter_type), prev_block->GetBlockHash().ToString());
return;
}
}
std::vector<uint256> filter_hashes;
if (!filter_index->LookupFilterHashRange(start_height, stop_index, filter_hashes)) {
LogPrint(BCLog::NET, "Failed to find block filter hashes in index: filter_type=%s, start_height=%d, stop_hash=%s\n",
BlockFilterTypeName(filter_type), start_height, stop_hash.ToString());
return;
}
CSerializedNetMsg msg = CNetMsgMaker(node.GetCommonVersion())
.Make(NetMsgType::CFHEADERS,
filter_type_ser,
stop_index->GetBlockHash(),
prev_header,
filter_hashes);
m_connman.PushMessage(&node, std::move(msg));
}
void PeerManagerImpl::ProcessGetCFCheckPt(CNode& node, Peer& peer, CDataStream& vRecv)
{
uint8_t filter_type_ser;
uint256 stop_hash;
vRecv >> filter_type_ser >> stop_hash;
const BlockFilterType filter_type = static_cast<BlockFilterType>(filter_type_ser);
const CBlockIndex* stop_index;
BlockFilterIndex* filter_index;
if (!PrepareBlockFilterRequest(node, peer, filter_type, /*start_height=*/0, stop_hash,
/*max_height_diff=*/std::numeric_limits<uint32_t>::max(),
stop_index, filter_index)) {
return;
}
std::vector<uint256> headers(stop_index->nHeight / CFCHECKPT_INTERVAL);
// Populate headers.
const CBlockIndex* block_index = stop_index;
for (int i = headers.size() - 1; i >= 0; i--) {
int height = (i + 1) * CFCHECKPT_INTERVAL;
block_index = block_index->GetAncestor(height);
if (!filter_index->LookupFilterHeader(block_index, headers[i])) {
LogPrint(BCLog::NET, "Failed to find block filter header in index: filter_type=%s, block_hash=%s\n",
BlockFilterTypeName(filter_type), block_index->GetBlockHash().ToString());
return;
}
}
CSerializedNetMsg msg = CNetMsgMaker(node.GetCommonVersion())
.Make(NetMsgType::CFCHECKPT,
filter_type_ser,
stop_index->GetBlockHash(),
headers);
m_connman.PushMessage(&node, std::move(msg));
}
std::pair<bool /*ret*/, bool /*do_return*/> static ValidateDSTX(CDeterministicMNManager& dmnman, CDSTXManager& dstxman, ChainstateManager& chainman,
CMasternodeMetaMan& mn_metaman, CTxMemPool& mempool, CCoinJoinBroadcastTx& dstx, uint256 hashTx)
{
assert(mn_metaman.IsValid());
if (!dstx.IsValidStructure()) {
LogPrint(BCLog::COINJOIN, "DSTX -- Invalid DSTX structure: %s\n", hashTx.ToString());
return {false, true};
}
if (dstxman.GetDSTX(hashTx)) {
LogPrint(BCLog::COINJOIN, "DSTX -- Already have %s, skipping...\n", hashTx.ToString());
return {true, true}; // not an error
}
const CBlockIndex* pindex{nullptr};
CDeterministicMNCPtr dmn{nullptr};
{
LOCK(cs_main);
pindex = chainman.ActiveChain().Tip();
}
// It could be that a MN is no longer in the list but its DSTX is not yet mined.
// Try to find a MN up to 24 blocks deep to make sure such dstx-es are relayed and processed correctly.
if (dstx.masternodeOutpoint.IsNull()) {
for (int i = 0; i < 24 && pindex; ++i) {
dmn = dmnman.GetListForBlock(pindex).GetMN(dstx.m_protxHash);
if (dmn) {
dstx.masternodeOutpoint = dmn->collateralOutpoint;
break;
}
pindex = pindex->pprev;
}
} else {
for (int i = 0; i < 24 && pindex; ++i) {
dmn = dmnman.GetListForBlock(pindex).GetMNByCollateral(dstx.masternodeOutpoint);
if (dmn) {
dstx.m_protxHash = dmn->proTxHash;
break;
}
pindex = pindex->pprev;
}
}
if (!dmn) {
LogPrint(BCLog::COINJOIN, "DSTX -- Can't find masternode %s to verify %s\n", dstx.masternodeOutpoint.ToStringShort(), hashTx.ToString());
return {false, true};
}
if (!mn_metaman.GetMetaInfo(dmn->proTxHash)->IsValidForMixingTxes()) {
LogPrint(BCLog::COINJOIN, "DSTX -- Masternode %s is sending too many transactions %s\n", dstx.masternodeOutpoint.ToStringShort(), hashTx.ToString());
return {true, true};
// TODO: Not an error? Could it be that someone is relaying old DSTXes
// we have no idea about (e.g we were offline)? How to handle them?
}
if (!dstx.CheckSignature(dmn->pdmnState->pubKeyOperator.Get())) {
LogPrint(BCLog::COINJOIN, "DSTX -- CheckSignature() failed for %s\n", hashTx.ToString());
return {false, true};
}
LogPrint(BCLog::COINJOIN, "DSTX -- Got Masternode transaction %s\n", hashTx.ToString());
mempool.PrioritiseTransaction(hashTx, 0.1*COIN);
mn_metaman.DisallowMixing(dmn->proTxHash);
return {true, false};
}
void PeerManagerImpl::ProcessBlock(CNode& pfrom, const std::shared_ptr<const CBlock>& pblock, bool fForceProcessing)
{
bool fNewBlock = false;
m_chainman.ProcessNewBlock(m_chainparams, pblock, fForceProcessing, &fNewBlock);
if (fNewBlock) {
pfrom.m_last_block_time = GetTime<std::chrono::seconds>();
} else {
LOCK(cs_main);
mapBlockSource.erase(pblock->GetHash());
}
}
void PeerManagerImpl::ProcessPeerMsgRet(const PeerMsgRet& ret, CNode& pfrom)
{
if (!ret) Misbehaving(pfrom.GetId(), ret.error().score, ret.error().message);
}
void PeerManagerImpl::ProcessMessage(
CNode& pfrom,
const std::string& msg_type,
CDataStream& vRecv,
const std::chrono::microseconds time_received,
const std::atomic<bool>& interruptMsgProc)
{
LogPrint(BCLog::NET, "received: %s (%u bytes) peer=%d\n", SanitizeString(msg_type), vRecv.size(), pfrom.GetId());
statsClient.inc("message.received." + SanitizeString(msg_type), 1.0f);
const bool is_masternode = m_mn_activeman != nullptr;
PeerRef peer = GetPeerRef(pfrom.GetId());
if (peer == nullptr) return;
if (msg_type == NetMsgType::VERSION) {
if (pfrom.nVersion != 0) {
LogPrint(BCLog::NET, "redundant version message from peer=%d\n", pfrom.GetId());
return;
}
int64_t nTime;
CService addrMe;
uint64_t nNonce = 1;
ServiceFlags nServices;
int nVersion;
std::string cleanSubVer;
int starting_height = -1;
bool fRelay = true;
vRecv >> nVersion >> Using<CustomUintFormatter<8>>(nServices) >> nTime;
if (nTime < 0) {
nTime = 0;
}
vRecv.ignore(8); // Ignore the addrMe service bits sent by the peer
vRecv >> addrMe;
if (!pfrom.IsInboundConn())
{
m_addrman.SetServices(pfrom.addr, nServices);
}
if (pfrom.ExpectServicesFromConn() && !HasAllDesirableServiceFlags(nServices))
{
LogPrint(BCLog::NET, "peer=%d does not offer the expected services (%08x offered, %08x expected); disconnecting\n", pfrom.GetId(), nServices, GetDesirableServiceFlags(nServices));
pfrom.fDisconnect = true;
return;
}
if (nVersion < MIN_PEER_PROTO_VERSION) {
// disconnect from peers older than this proto version
LogPrint(BCLog::NET, "peer=%d using obsolete version %i; disconnecting\n", pfrom.GetId(), nVersion);
pfrom.fDisconnect = true;
return;
}
if (!vRecv.empty()) {
// The version message includes information about the sending node which we don't use:
// - 8 bytes (service bits)
// - 16 bytes (ipv6 address)
// - 2 bytes (port)
vRecv.ignore(26);
vRecv >> nNonce;
}
if (!vRecv.empty()) {
std::string strSubVer;
vRecv >> LIMITED_STRING(strSubVer, MAX_SUBVERSION_LENGTH);
cleanSubVer = SanitizeString(strSubVer);
}
if (!vRecv.empty()) {
vRecv >> starting_height;
}
if (!vRecv.empty())
vRecv >> fRelay;
if (!vRecv.empty()) {
uint256 receivedMNAuthChallenge;
vRecv >> receivedMNAuthChallenge;
pfrom.SetReceivedMNAuthChallenge(receivedMNAuthChallenge);
}
if (!vRecv.empty()) {
bool fOtherMasternode = false;
vRecv >> fOtherMasternode;
if (pfrom.IsInboundConn()) {
pfrom.m_masternode_connection = fOtherMasternode;
if (fOtherMasternode) {
LogPrint(BCLog::NET_NETCONN, "peer=%d is an inbound masternode connection, not relaying anything to it\n", pfrom.GetId());
if (!is_masternode) {
LogPrint(BCLog::NET_NETCONN, "but we're not a masternode, disconnecting\n");
pfrom.fDisconnect = true;
return;
}
}
}
}
// Disconnect if we connected to ourself
if (pfrom.IsInboundConn() && !m_connman.CheckIncomingNonce(nNonce))
{
LogPrintf("connected to self at %s, disconnecting\n", pfrom.addr.ToString());
pfrom.fDisconnect = true;
return;
}
if (pfrom.IsInboundConn() && addrMe.IsRoutable())
{
SeenLocal(addrMe);
}
// Be shy and don't send version until we hear
if (pfrom.IsInboundConn()) {
PushNodeVersion(pfrom, *peer);
}
if (Params().NetworkIDString() == CBaseChainParams::DEVNET) {
if (cleanSubVer.find(strprintf("devnet.%s", gArgs.GetDevNetName())) == std::string::npos) {
LogPrintf("connected to wrong devnet. Reported version is %s, expected devnet name is %s\n", cleanSubVer, gArgs.GetDevNetName());
if (!pfrom.IsInboundConn())
Misbehaving(pfrom.GetId(), 100); // don't try to connect again
else
Misbehaving(pfrom.GetId(), 1); // whover connected, might just have made a mistake, don't ban him immediately
pfrom.fDisconnect = true;
return;
}
}
// Change version
const int greatest_common_version = std::min(nVersion, PROTOCOL_VERSION);
pfrom.SetCommonVersion(greatest_common_version);
pfrom.nVersion = nVersion;
const CNetMsgMaker msg_maker(greatest_common_version);
// Signal ADDRv2 support (BIP155).
if (greatest_common_version >= ADDRV2_PROTO_VERSION) {
// BIP155 defines addrv2 and sendaddrv2 for all protocol versions, but some
// implementations reject messages they don't know. As a courtesy, don't send
// it to nodes with a version before ADDRV2_PROTO_VERSION.
m_connman.PushMessage(&pfrom, msg_maker.Make(NetMsgType::SENDADDRV2));
}
m_connman.PushMessage(&pfrom, msg_maker.Make(NetMsgType::VERACK));
pfrom.m_has_all_wanted_services = HasAllDesirableServiceFlags(nServices);
peer->m_their_services = nServices;
pfrom.SetAddrLocal(addrMe);
{
LOCK(pfrom.m_subver_mutex);
pfrom.cleanSubVer = cleanSubVer;
}
peer->m_starting_height = starting_height;
if (!pfrom.IsBlockOnlyConn()) {
{
LOCK(peer->m_tx_relay->m_bloom_filter_mutex);
peer->m_tx_relay->m_relay_txs = fRelay; // set to true after we get the first filter* message
}
if (fRelay) pfrom.m_relays_txs = true;
}
// Potentially mark this peer as a preferred download peer.
{
LOCK(cs_main);
UpdatePreferredDownload(pfrom, *peer, State(pfrom.GetId()));
}
// Self advertisement & GETADDR logic
if (!pfrom.IsInboundConn() && SetupAddressRelay(pfrom, *peer)) {
// For outbound peers, we try to relay our address (so that other
// nodes can try to find us more quickly, as we have no guarantee
// that an outbound peer is even aware of how to reach us) and do a
// one-time address fetch (to help populate/update our addrman). If
// we're starting up for the first time, our addrman may be pretty
// empty and no one will know who we are, so these mechanisms are
// important to help us connect to the network.
//
// We skip this for block-relay-only peers. We want to avoid
// potentially leaking addr information and we do not want to
// indicate to the peer that we will participate in addr relay.
if (fListen && !m_chainman.ActiveChainstate().IsInitialBlockDownload())
{
CAddress addr{GetLocalAddress(pfrom.addr), peer->m_our_services, (uint32_t)GetAdjustedTime()};
FastRandomContext insecure_rand;
if (addr.IsRoutable())
{
LogPrint(BCLog::NET, "ProcessMessages: advertising address %s\n", addr.ToString());
PushAddress(*peer, addr, insecure_rand);
} else if (IsPeerAddrLocalGood(&pfrom)) {
// Override just the address with whatever the peer sees us as.
// Leave the port in addr as it was returned by GetLocalAddress()
// above, as this is an outbound connection and the peer cannot
// observe our listening port.
addr.SetIP(addrMe);
LogPrint(BCLog::NET, "ProcessMessages: advertising address %s\n", addr.ToString());
PushAddress(*peer, addr, insecure_rand);
}
}
// Get recent addresses
m_connman.PushMessage(&pfrom, CNetMsgMaker(greatest_common_version).Make(NetMsgType::GETADDR));
peer->m_getaddr_sent = true;
// When requesting a getaddr, accept an additional MAX_ADDR_TO_SEND addresses in response
// (bypassing the MAX_ADDR_PROCESSING_TOKEN_BUCKET limit).
peer->m_addr_token_bucket += MAX_ADDR_TO_SEND;
}
if (!pfrom.IsInboundConn()) {
// For non-inbound connections, we update the addrman to record
// connection success so that addrman will have an up-to-date
// notion of which peers are online and available.
//
// While we strive to not leak information about block-relay-only
// connections via the addrman, not moving an address to the tried
// table is also potentially detrimental because new-table entries
// are subject to eviction in the event of addrman collisions. We
// mitigate the information-leak by never calling
// AddrMan::Connected() on block-relay-only peers; see
// FinalizeNode().
//
// This moves an address from New to Tried table in Addrman,
// resolves tried-table collisions, etc.
m_addrman.Good(pfrom.addr);
}
std::string remoteAddr;
if (fLogIPs)
remoteAddr = ", peeraddr=" + pfrom.addr.ToString();
LogPrint(BCLog::NET, "receive version message: %s: version %d, blocks=%d, us=%s, txrelay=%d, peer=%d%s\n",
cleanSubVer, pfrom.nVersion,
peer->m_starting_height, addrMe.ToString(), fRelay, pfrom.GetId(),
remoteAddr);
int64_t nTimeOffset = nTime - GetTime();
pfrom.nTimeOffset = nTimeOffset;
AddTimeData(pfrom.addr, nTimeOffset);
// Feeler connections exist only to verify if address is online.
if (pfrom.IsFeelerConn()) {
LogPrint(BCLog::NET_NETCONN, "feeler connection completed peer=%d; disconnecting\n", pfrom.GetId());
pfrom.fDisconnect = true;
}
return;
}
if (pfrom.nVersion == 0) {
// Must have a version message before anything else
LogPrint(BCLog::NET, "non-version message before version handshake. Message \"%s\" from peer=%d\n", SanitizeString(msg_type), pfrom.GetId());
return;
}
// At this point, the outgoing message serialization version can't change.
const CNetMsgMaker msgMaker(pfrom.GetCommonVersion());
bool fBlocksOnly = pfrom.IsBlockRelayOnly();
if (msg_type == NetMsgType::VERACK) {
if (pfrom.fSuccessfullyConnected) {
LogPrint(BCLog::NET, "ignoring redundant verack message from peer=%d\n", pfrom.GetId());
return;
}
if (!pfrom.IsInboundConn()) {
LogPrintf("New outbound peer connected: version: %d, blocks=%d, peer=%d%s (%s)\n",
pfrom.nVersion.load(), peer->m_starting_height,
pfrom.GetId(), (fLogIPs ? strprintf(", peeraddr=%s", pfrom.addr.ToString()) : ""),
pfrom.ConnectionTypeAsString());
}
if (is_masternode && !pfrom.m_masternode_probe_connection) {
CMNAuth::PushMNAUTH(pfrom, m_connman, *m_mn_activeman, m_chainman.ActiveChain().Tip());
}
// Tell our peer we prefer to receive headers rather than inv's
// We send this to non-NODE NETWORK peers as well, because even
// non-NODE NETWORK peers can announce blocks (such as pruning
// nodes)
m_connman.PushMessage(&pfrom, msgMaker.Make(UsesCompressedHeaders(*peer) ? NetMsgType::SENDHEADERS2 : NetMsgType::SENDHEADERS));
if (pfrom.CanRelay()) {
// Tell our peer we are willing to provide version 1 cmpctblocks.
// However, we do not request new block announcements using
// cmpctblock messages.
// We send this to non-NODE NETWORK peers as well, because
// they may wish to request compact blocks from us
m_connman.PushMessage(&pfrom, msgMaker.Make(NetMsgType::SENDCMPCT, /*high_bandwidth=*/false, /*version=*/CMPCTBLOCKS_VERSION));
}
if (!fBlocksOnly) {
// Tell our peer that he should send us CoinJoin queue messages
m_connman.PushMessage(&pfrom, msgMaker.Make(NetMsgType::SENDDSQUEUE, true));
// Tell our peer that he should send us intra-quorum messages
const auto tip_mn_list = Assert(m_dmnman)->GetListAtChainTip();
if (llmq::IsWatchQuorumsEnabled() && m_connman.IsMasternodeQuorumNode(&pfrom, tip_mn_list)) {
m_connman.PushMessage(&pfrom, msgMaker.Make(NetMsgType::QWATCH));
}
}
pfrom.fSuccessfullyConnected = true;
return;
}
if (msg_type == NetMsgType::SENDHEADERS) {
LOCK(cs_main);
State(pfrom.GetId())->fPreferHeaders = true;
return;
}
if (msg_type == NetMsgType::SENDHEADERS2) {
LOCK(cs_main);
State(pfrom.GetId())->fPreferHeadersCompressed = true;
return;
}
if (msg_type == NetMsgType::SENDCMPCT) {
bool sendcmpct_hb{false};
uint64_t sendcmpct_version{0};
vRecv >> sendcmpct_hb >> sendcmpct_version;
if (sendcmpct_version != CMPCTBLOCKS_VERSION) return;
LOCK(cs_main);
CNodeState *nodestate = State(pfrom.GetId());
nodestate->m_provides_cmpctblocks = true;
nodestate->m_requested_hb_cmpctblocks = sendcmpct_hb;
// save whether peer selects us as BIP152 high-bandwidth peer
// (receiving sendcmpct(1) signals high-bandwidth, sendcmpct(0) low-bandwidth)
pfrom.m_bip152_highbandwidth_from = sendcmpct_hb;
return;
}
// BIP155 defines feature negotiation of addrv2 and sendaddrv2, which must happen
// between VERSION and VERACK.
if (msg_type == NetMsgType::SENDADDRV2) {
if (pfrom.GetCommonVersion() < ADDRV2_PROTO_VERSION) {
// Ignore previous implementations
return;
}
if (pfrom.fSuccessfullyConnected) {
// Disconnect peers that send a SENDADDRV2 message after VERACK.
LogPrint(BCLog::NET_NETCONN, "sendaddrv2 received after verack from peer=%d; disconnecting\n", pfrom.GetId());
pfrom.fDisconnect = true;
return;
}
peer->m_wants_addrv2 = true;
return;
}
if (!pfrom.fSuccessfullyConnected) {
LogPrint(BCLog::NET, "Unsupported message \"%s\" prior to verack from peer=%d\n", SanitizeString(msg_type), pfrom.GetId());
return;
}
if (pfrom.nTimeFirstMessageReceived == 0) {
// First message after VERSION/VERACK
pfrom.nTimeFirstMessageReceived = GetTimeSeconds();
pfrom.fFirstMessageIsMNAUTH = msg_type == NetMsgType::MNAUTH;
// Note: do not break the flow here
if (pfrom.m_masternode_probe_connection && !pfrom.fFirstMessageIsMNAUTH) {
LogPrint(BCLog::NET, "connection is a masternode probe but first received message is not MNAUTH, peer=%d\n", pfrom.GetId());
pfrom.fDisconnect = true;
return;
}
}
// Stop processing non-block data early in blocks only mode and for block-relay-only peers
if (fBlocksOnly && NetMessageViolatesBlocksOnly(msg_type)) {
LogPrint(BCLog::NET, "%s sent in violation of protocol peer=%d\n", msg_type, pfrom.GetId());
pfrom.fDisconnect = true;
return;
}
if (msg_type == NetMsgType::ADDR || msg_type == NetMsgType::ADDRV2) {
int stream_version = vRecv.GetVersion();
if (msg_type == NetMsgType::ADDRV2) {
// Add ADDRV2_FORMAT to the version so that the CNetAddr and CAddress
// unserialize methods know that an address in v2 format is coming.
stream_version |= ADDRV2_FORMAT;
}
OverrideStream<CDataStream> s(&vRecv, vRecv.GetType(), stream_version);
std::vector<CAddress> vAddr;
s >> vAddr;
if (!SetupAddressRelay(pfrom, *peer)) {
LogPrint(BCLog::NET, "ignoring %s message from %s peer=%d\n", msg_type, pfrom.ConnectionTypeAsString(), pfrom.GetId());
return;
}
if (vAddr.size() > MAX_ADDR_TO_SEND)
{
Misbehaving(pfrom.GetId(), 20, strprintf("%s message size = %u", msg_type, vAddr.size()));
return;
}
// Store the new addresses
std::vector<CAddress> vAddrOk;
int64_t nNow = GetAdjustedTime();
int64_t nSince = nNow - 10 * 60;
// Update/increment addr rate limiting bucket.
const auto current_time = GetTime<std::chrono::microseconds>();
if (peer->m_addr_token_bucket < MAX_ADDR_PROCESSING_TOKEN_BUCKET) {
// Don't increment bucket if it's already full
const auto time_diff = std::max(current_time - peer->m_addr_token_timestamp, 0us);
const double increment = CountSecondsDouble(time_diff) * MAX_ADDR_RATE_PER_SECOND;
peer->m_addr_token_bucket = std::min<double>(peer->m_addr_token_bucket + increment, MAX_ADDR_PROCESSING_TOKEN_BUCKET);
}
peer->m_addr_token_timestamp = current_time;
const bool rate_limited = !pfrom.HasPermission(NetPermissionFlags::Addr);
uint64_t num_proc = 0;
uint64_t num_rate_limit = 0;
Shuffle(vAddr.begin(), vAddr.end(), FastRandomContext());
for (CAddress& addr : vAddr)
{
if (interruptMsgProc)
return;
// Apply rate limiting.
if (peer->m_addr_token_bucket < 1.0) {
if (rate_limited) {
++num_rate_limit;
continue;
}
} else {
peer->m_addr_token_bucket -= 1.0;
}
// We only bother storing full nodes, though this may include
// things which we would not make an outbound connection to, in
// part because we may make feeler connections to them.
if (!MayHaveUsefulAddressDB(addr.nServices) && !HasAllDesirableServiceFlags(addr.nServices))
continue;
if (addr.nTime <= 100000000 || addr.nTime > nNow + 10 * 60)
addr.nTime = nNow - 5 * 24 * 60 * 60;
AddAddressKnown(*peer, addr);
if (m_banman && (m_banman->IsDiscouraged(addr) || m_banman->IsBanned(addr))) {
// Do not process banned/discouraged addresses beyond remembering we received them
continue;
}
++num_proc;
bool fReachable = IsReachable(addr);
if (addr.nTime > nSince && !peer->m_getaddr_sent && vAddr.size() <= 10 && addr.IsRoutable()) {
// Relay to a limited number of other nodes
RelayAddress(pfrom.GetId(), addr, fReachable);
}
// Do not store addresses outside our network
if (fReachable)
vAddrOk.push_back(addr);
}
peer->m_addr_processed += num_proc;
peer->m_addr_rate_limited += num_rate_limit;
LogPrint(BCLog::NET, "Received addr: %u addresses (%u processed, %u rate-limited) from peer=%d\n",
vAddr.size(), num_proc, num_rate_limit, pfrom.GetId());
m_addrman.Add(vAddrOk, pfrom.addr, 2 * 60 * 60);
if (vAddr.size() < 1000) peer->m_getaddr_sent = false;
// AddrFetch: Require multiple addresses to avoid disconnecting on self-announcements
if (pfrom.IsAddrFetchConn() && vAddr.size() > 1) {
LogPrint(BCLog::NET_NETCONN, "addrfetch connection completed peer=%d; disconnecting\n", pfrom.GetId());
pfrom.fDisconnect = true;
}
return;
}
if (msg_type == NetMsgType::SENDDSQUEUE)
{
bool b;
vRecv >> b;
pfrom.fSendDSQueue = b;
return;
}
if (msg_type == NetMsgType::QSENDRECSIGS) {
bool b;
vRecv >> b;
pfrom.fSendRecSigs = b;
return;
}
if (msg_type == NetMsgType::INV) {
std::vector<CInv> vInv;
vRecv >> vInv;
if (vInv.size() > MAX_INV_SZ)
{
Misbehaving(pfrom.GetId(), 20, strprintf("inv message size = %u", vInv.size()));
return;
}
LOCK(cs_main);
const auto current_time = GetTime<std::chrono::microseconds>();
uint256* best_block{nullptr};
for (CInv& inv : vInv) {
if(!inv.IsKnownType()) {
LogPrint(BCLog::NET, "got inv of unknown type %d: %s peer=%d\n", inv.type, inv.hash.ToString(), pfrom.GetId());
continue;
}
if (interruptMsgProc) return;
if (inv.IsMsgBlk()) {
const bool fAlreadyHave = AlreadyHaveBlock(inv.hash);
LogPrint(BCLog::NET, "got inv: %s %s peer=%d\n", inv.ToString(), fAlreadyHave ? "have" : "new", pfrom.GetId());
statsClient.inc(strprintf("message.received.inv_%s", inv.GetCommand()), 1.0f);
UpdateBlockAvailability(pfrom.GetId(), inv.hash);
if (!fAlreadyHave && !fImporting && !fReindex && !mapBlocksInFlight.count(inv.hash)) {
// Headers-first is the primary method of announcement on
// the network. If a node fell back to sending blocks by
// inv, it may be for a re-org, or because we haven't
// completed initial headers sync. The final block hash
// provided should be the highest, so send a getheaders and
// then fetch the blocks we need to catch up.
best_block = &inv.hash;
}
} else {
const bool fAlreadyHave = AlreadyHave(inv);
LogPrint(BCLog::NET, "got inv: %s %s peer=%d\n", inv.ToString(), fAlreadyHave ? "have" : "new", pfrom.GetId());
statsClient.inc(strprintf("message.received.inv_%s", inv.GetCommand()), 1.0f);
static std::set<int> allowWhileInIBDObjs = {
MSG_SPORK
};
AddKnownInv(*peer, inv.hash);
if (fBlocksOnly && NetMessageViolatesBlocksOnly(inv.GetCommand())) {
LogPrint(BCLog::NET, "%s (%s) inv sent in violation of protocol, disconnecting peer=%d\n", inv.GetCommand(), inv.hash.ToString(), pfrom.GetId());
pfrom.fDisconnect = true;
return;
} else if (!fAlreadyHave) {
if (fBlocksOnly && inv.type == MSG_ISDLOCK) {
if (pfrom.GetCommonVersion() <= ADDRV2_PROTO_VERSION) {
// It's ok to receive these invs, we just ignore them
// and do not request corresponding objects.
continue;
}
// Peers with newer versions should never send us these invs when we are in blocks-relay-only mode
LogPrint(BCLog::NET, "%s (%s) inv sent in violation of protocol, disconnecting peer=%d\n", inv.GetCommand(), inv.hash.ToString(), pfrom.GetId());
pfrom.fDisconnect = true;
return;
}
bool allowWhileInIBD = allowWhileInIBDObjs.count(inv.type);
if (allowWhileInIBD || !m_chainman.ActiveChainstate().IsInitialBlockDownload()) {
RequestObject(State(pfrom.GetId()), inv, current_time, is_masternode);
}
}
}
}
if (best_block != nullptr) {
// If we haven't started initial headers-sync with this peer, then
// consider sending a getheaders now. On initial startup, there's a
// reliability vs bandwidth tradeoff, where we are only trying to do
// initial headers sync with one peer at a time, with a long
// timeout (at which point, if the sync hasn't completed, we will
// disconnect the peer and then choose another). In the meantime,
// as new blocks are found, we are willing to add one new peer per
// block to sync with as well, to sync quicker in the case where
// our initial peer is unresponsive (but less bandwidth than we'd
// use if we turned on sync with all peers).
CNodeState& state{*Assert(State(pfrom.GetId()))};
if (state.fSyncStarted || (!peer->m_inv_triggered_getheaders_before_sync && *best_block != m_last_block_inv_triggering_headers_sync)) {
std::string msg_type = UsesCompressedHeaders(*peer) ? NetMsgType::GETHEADERS2 : NetMsgType::GETHEADERS;
if (MaybeSendGetHeaders(pfrom, msg_type, m_chainman.ActiveChain().GetLocator(m_chainman.m_best_header), *peer)) {
LogPrint(BCLog::NET, "%s (%d) %s to peer=%d\n",
msg_type, m_chainman.m_best_header->nHeight, best_block->ToString(),
pfrom.GetId());
}
if (!state.fSyncStarted) {
peer->m_inv_triggered_getheaders_before_sync = true;
// Update the last block hash that triggered a new headers
// sync, so that we don't turn on headers sync with more
// than 1 new peer every new block.
m_last_block_inv_triggering_headers_sync = *best_block;
}
}
}
return;
}
if (msg_type == NetMsgType::GETDATA) {
std::vector<CInv> vInv;
vRecv >> vInv;
if (vInv.size() > MAX_INV_SZ)
{
Misbehaving(pfrom.GetId(), 20, strprintf("getdata message size = %u", vInv.size()));
return;
}
LogPrint(BCLog::NET, "received getdata (%u invsz) peer=%d\n", vInv.size(), pfrom.GetId());
if (vInv.size() > 0) {
LogPrint(BCLog::NET, "received getdata for: %s peer=%d\n", vInv[0].ToString(), pfrom.GetId());
}
{
LOCK(peer->m_getdata_requests_mutex);
peer->m_getdata_requests.insert(peer->m_getdata_requests.end(), vInv.begin(), vInv.end());
ProcessGetData(pfrom, *peer, interruptMsgProc);
}
return;
}
if (msg_type == NetMsgType::GETBLOCKS) {
CBlockLocator locator;
uint256 hashStop;
vRecv >> locator >> hashStop;
if (locator.vHave.size() > MAX_LOCATOR_SZ) {
LogPrint(BCLog::NET, "getblocks locator size %lld > %d, disconnect peer=%d\n", locator.vHave.size(), MAX_LOCATOR_SZ, pfrom.GetId());
pfrom.fDisconnect = true;
return;
}
// We might have announced the currently-being-connected tip using a
// compact block, which resulted in the peer sending a getblocks
// request, which we would otherwise respond to without the new block.
// To avoid this situation we simply verify that we are on our best
// known chain now. This is super overkill, but we handle it better
// for getheaders requests, and there are no known nodes which support
// compact blocks but still use getblocks to request blocks.
{
std::shared_ptr<const CBlock> a_recent_block;
{
LOCK(cs_most_recent_block);
a_recent_block = most_recent_block;
}
BlockValidationState state;
if (!m_chainman.ActiveChainstate().ActivateBestChain(state, a_recent_block)) {
LogPrint(BCLog::NET, "failed to activate chain (%s)\n", state.ToString());
}
}
LOCK(cs_main);
// Find the last block the caller has in the main chain
const CBlockIndex* pindex = m_chainman.ActiveChainstate().FindForkInGlobalIndex(locator);
// Send the rest of the chain
if (pindex)
pindex = m_chainman.ActiveChain().Next(pindex);
int nLimit = 500;
LogPrint(BCLog::NET, "getblocks %d to %s limit %d from peer=%d\n", (pindex ? pindex->nHeight : -1), hashStop.IsNull() ? "end" : hashStop.ToString(), nLimit, pfrom.GetId());
for (; pindex; pindex = m_chainman.ActiveChain().Next(pindex))
{
if (pindex->GetBlockHash() == hashStop)
{
LogPrint(BCLog::NET, " getblocks stopping at %d %s\n", pindex->nHeight, pindex->GetBlockHash().ToString());
break;
}
// If pruning, don't inv blocks unless we have on disk and are likely to still have
// for some reasonable time window (1 hour) that block relay might require.
const int nPrunedBlocksLikelyToHave = MIN_BLOCKS_TO_KEEP - 3600 / m_chainparams.GetConsensus().nPowTargetSpacing;
if (fPruneMode && (!(pindex->nStatus & BLOCK_HAVE_DATA) || pindex->nHeight <= m_chainman.ActiveChain().Tip()->nHeight - nPrunedBlocksLikelyToHave))
{
LogPrint(BCLog::NET, " getblocks stopping, pruned or too old block at %d %s\n", pindex->nHeight, pindex->GetBlockHash().ToString());
break;
}
if (pfrom.CanRelay()) {
WITH_LOCK(peer->m_block_inv_mutex, peer->m_blocks_for_inv_relay.push_back(pindex->GetBlockHash()));
}
if (--nLimit <= 0) {
// When this block is requested, we'll send an inv that'll
// trigger the peer to getblocks the next batch of inventory.
LogPrint(BCLog::NET, " getblocks stopping at limit %d %s\n", pindex->nHeight, pindex->GetBlockHash().ToString());
WITH_LOCK(peer->m_block_inv_mutex, {peer->m_continuation_block = pindex->GetBlockHash();});
break;
}
}
return;
}
if (msg_type == NetMsgType::GETBLOCKTXN) {
BlockTransactionsRequest req;
vRecv >> req;
std::shared_ptr<const CBlock> recent_block;
{
LOCK(cs_most_recent_block);
if (most_recent_block_hash == req.blockhash)
recent_block = most_recent_block;
// Unlock cs_most_recent_block to avoid cs_main lock inversion
}
if (recent_block) {
SendBlockTransactions(pfrom, *recent_block, req);
return;
}
{
LOCK(cs_main);
const CBlockIndex* pindex = m_chainman.m_blockman.LookupBlockIndex(req.blockhash);
if (!pindex || !(pindex->nStatus & BLOCK_HAVE_DATA)) {
LogPrint(BCLog::NET, "Peer %d sent us a getblocktxn for a block we don't have\n", pfrom.GetId());
return;
}
if (pindex->nHeight >= m_chainman.ActiveChain().Height() - MAX_BLOCKTXN_DEPTH) {
CBlock block;
bool ret = ReadBlockFromDisk(block, pindex, m_chainparams.GetConsensus());
assert(ret);
SendBlockTransactions(pfrom, block, req);
return;
}
}
// If an older block is requested (should never happen in practice,
// but can happen in tests) send a block response instead of a
// blocktxn response. Sending a full block response instead of a
// small blocktxn response is preferable in the case where a peer
// might maliciously send lots of getblocktxn requests to trigger
// expensive disk reads, because it will require the peer to
// actually receive all the data read from disk over the network.
LogPrint(BCLog::NET, "Peer %d sent us a getblocktxn for a block > %i deep\n", pfrom.GetId(), MAX_BLOCKTXN_DEPTH);
CInv inv{MSG_BLOCK, req.blockhash};
WITH_LOCK(peer->m_getdata_requests_mutex, peer->m_getdata_requests.push_back(inv));
// The message processing loop will go around again (without pausing) and we'll respond then (without cs_main)
return;
}
if (msg_type == NetMsgType::GETHEADERS || msg_type == NetMsgType::GETHEADERS2) {
CBlockLocator locator;
uint256 hashStop;
vRecv >> locator >> hashStop;
if (locator.vHave.size() > MAX_LOCATOR_SZ) {
LogPrint(BCLog::NET, "%s locator size %lld > %d, disconnect peer=%d\n", msg_type, locator.vHave.size(), MAX_LOCATOR_SZ, pfrom.GetId());
pfrom.fDisconnect = true;
return;
}
if (fImporting || fReindex) {
LogPrint(BCLog::NET, "Ignoring %s from peer=%d while importing/reindexing\n", msg_type, pfrom.GetId());
return;
}
LOCK(cs_main);
// Note that if we were to be on a chain that forks from the checkpointed
// chain, then serving those headers to a peer that has seen the
// checkpointed chain would cause that peer to disconnect us. Requiring
// that our chainwork exceed nMinimumChainWork is a protection against
// being fed a bogus chain when we started up for the first time and
// getting partitioned off the honest network for serving that chain to
// others.
if (m_chainman.ActiveTip() == nullptr ||
(m_chainman.ActiveTip()->nChainWork < nMinimumChainWork && !pfrom.HasPermission(NetPermissionFlags::Download))) {
LogPrint(BCLog::NET, "Ignoring %s from peer=%d because active chain has too little work; sending empty response\n", msg_type, pfrom.GetId());
// Just respond with an empty headers message, to tell the peer to
// go away but not treat us as unresponsive.
std::string ret_type = UsesCompressedHeaders(*peer) ? NetMsgType::HEADERS2 : NetMsgType::HEADERS;
m_connman.PushMessage(&pfrom, msgMaker.Make(ret_type, std::vector<CBlock>()));
return;
}
CNodeState *nodestate = State(pfrom.GetId());
const CBlockIndex* pindex = nullptr;
if (locator.IsNull())
{
// If locator is null, return the hashStop block
pindex = m_chainman.m_blockman.LookupBlockIndex(hashStop);
if (!pindex) {
return;
}
if (!BlockRequestAllowed(pindex)) {
LogPrint(BCLog::NET, "%s: ignoring request from peer=%i for old block header that isn't in the main chain\n", __func__, pfrom.GetId());
return;
}
}
else
{
// Find the last block the caller has in the main chain
pindex = m_chainman.ActiveChainstate().FindForkInGlobalIndex(locator);
if (pindex)
pindex = m_chainman.ActiveChain().Next(pindex);
}
const auto send_headers = [this /* for m_connman */, &hashStop, &pindex, &nodestate, &pfrom, &msgMaker](auto msg_type, auto& v_headers, auto callback) {
int nLimit = MAX_HEADERS_RESULTS;
for (; pindex; pindex = m_chainman.ActiveChain().Next(pindex)) {
v_headers.push_back(callback(pindex));
if (--nLimit <= 0 || pindex->GetBlockHash() == hashStop)
break;
}
// pindex can be nullptr either if we sent m_chainman.ActiveChain().Tip() OR
// if our peer has m_chainman.ActiveChain().Tip() (and thus we are sending an empty
// headers message). In both cases it's safe to update
// pindexBestHeaderSent to be our tip.
//
// It is important that we simply reset the BestHeaderSent value here,
// and not max(BestHeaderSent, newHeaderSent). We might have announced
// the currently-being-connected tip using a compact block, which
// resulted in the peer sending a headers request, which we respond to
// without the new block. By resetting the BestHeaderSent, we ensure we
// will re-announce the new block via headers (or compact blocks again)
// in the SendMessages logic.
nodestate->pindexBestHeaderSent = pindex ? pindex : m_chainman.ActiveChain().Tip();
m_connman.PushMessage(&pfrom, msgMaker.Make(msg_type, v_headers));
};
LogPrint(BCLog::NET, "%s %d to %s from peer=%d\n", msg_type, (pindex ? pindex->nHeight : -1), hashStop.IsNull() ? "end" : hashStop.ToString(), pfrom.GetId());
if (msg_type == NetMsgType::GETHEADERS) {
// we must use CBlocks, as CBlockHeaders won't include the 0x00 nTx count at the end
std::vector<CBlock> v_headers;
send_headers(NetMsgType::HEADERS, v_headers, [](const auto block_pindex) { return block_pindex->GetBlockHeader(); });
} else if (msg_type == NetMsgType::GETHEADERS2) {
// Keeps track of the last 7 unique version blocks
std::list<int32_t> last_unique_versions;
std::vector<CompressibleBlockHeader> v_headers;
send_headers(NetMsgType::HEADERS2, v_headers, [&v_headers, &last_unique_versions](const auto block_pindex) {
CompressibleBlockHeader compressible_header{block_pindex->GetBlockHeader()};
if (!v_headers.empty()) compressible_header.Compress(v_headers, last_unique_versions); // first block is always uncompressed
return compressible_header;
});
}
return;
}
if (msg_type == NetMsgType::TX || msg_type == NetMsgType::DSTX) {
CTransactionRef ptx;
CCoinJoinBroadcastTx dstx;
int nInvType = MSG_TX;
// Read data and assign inv type
if(msg_type == NetMsgType::TX) {
vRecv >> ptx;
} else if (msg_type == NetMsgType::DSTX) {
vRecv >> dstx;
ptx = dstx.tx;
nInvType = MSG_DSTX;
}
const CTransaction& tx = *ptx;
const uint256& txid = ptx->GetHash();
AddKnownInv(*peer, txid);
CInv inv(nInvType, tx.GetHash());
{
LOCK(cs_main);
EraseObjectRequest(pfrom.GetId(), inv);
}
// Process custom logic, no matter if tx will be accepted to mempool later or not
if (nInvType == MSG_DSTX) {
// Validate DSTX and return bRet if we need to return from here
uint256 hashTx = tx.GetHash();
const auto& [bRet, bDoReturn] = ValidateDSTX(*m_dmnman, *(m_cj_ctx->dstxman), m_chainman, m_mn_metaman, m_mempool, dstx, hashTx);
if (bDoReturn) {
return;
}
}
LOCK2(cs_main, g_cs_orphans);
if (AlreadyHave(inv)) {
if (pfrom.HasPermission(NetPermissionFlags::ForceRelay)) {
// Always relay transactions received from peers with forcerelay permission, even
// if they were already in the mempool,
// allowing the node to function as a gateway for
// nodes hidden behind it.
if (!m_mempool.exists(tx.GetHash())) {
LogPrintf("Not relaying non-mempool transaction %s from forcerelay peer=%d\n", tx.GetHash().ToString(), pfrom.GetId());
} else {
LogPrintf("Force relaying tx %s from peer=%d\n", tx.GetHash().ToString(), pfrom.GetId());
RelayTransaction(tx.GetHash());
}
}
return;
}
const MempoolAcceptResult result = AcceptToMemoryPool(m_chainman.ActiveChainstate(), m_mempool, ptx, false /* bypass_limits */);
const TxValidationState& state = result.m_state;
if (result.m_result_type == MempoolAcceptResult::ResultType::VALID) {
// Process custom txes, this changes AlreadyHave to "true"
if (nInvType == MSG_DSTX) {
LogPrint(BCLog::COINJOIN, "DSTX -- Masternode transaction accepted, txid=%s, peer=%d\n",
tx.GetHash().ToString(), pfrom.GetId());
m_cj_ctx->dstxman->AddDSTX(dstx);
}
m_mempool.check(m_chainman.ActiveChainstate());
RelayTransaction(tx.GetHash());
for (unsigned int i = 0; i < tx.vout.size(); i++) {
auto it_by_prev = mapOrphanTransactionsByPrev.find(COutPoint(txid, i));
if (it_by_prev != mapOrphanTransactionsByPrev.end()) {
for (const auto& elem : it_by_prev->second) {
peer->m_orphan_work_set.insert(elem->first);
}
}
}
pfrom.m_last_tx_time = GetTime<std::chrono::seconds>();
LogPrint(BCLog::MEMPOOL, "AcceptToMemoryPool: peer=%d: accepted %s (poolsz %u txn, %u kB)\n",
pfrom.GetId(),
tx.GetHash().ToString(),
m_mempool.size(), m_mempool.DynamicMemoryUsage() / 1000);
// Recursively process any orphan transactions that depended on this one
ProcessOrphanTx(peer->m_orphan_work_set);
}
else if (state.GetResult() == TxValidationResult::TX_MISSING_INPUTS)
{
bool fRejectedParents = false; // It may be the case that the orphans parents have all been rejected
// Deduplicate parent txids, so that we don't have to loop over
// the same parent txid more than once down below.
std::vector<uint256> unique_parents;
unique_parents.reserve(tx.vin.size());
for (const CTxIn& txin : tx.vin) {
// We start with all parents, and then remove duplicates below.
unique_parents.push_back(txin.prevout.hash);
}
std::sort(unique_parents.begin(), unique_parents.end());
unique_parents.erase(std::unique(unique_parents.begin(), unique_parents.end()), unique_parents.end());
for (const uint256& parent_txid : unique_parents) {
if (m_recent_rejects.contains(parent_txid)) {
fRejectedParents = true;
break;
}
}
if (!fRejectedParents) {
const auto current_time = GetTime<std::chrono::microseconds>();
for (const uint256& parent_txid : unique_parents) {
CInv _inv(MSG_TX, parent_txid);
AddKnownInv(*peer, _inv.hash);
if (!AlreadyHave(_inv)) RequestObject(State(pfrom.GetId()), _inv, current_time, is_masternode);
// We don't know if the previous tx was a regular or a mixing one, try both
CInv _inv2(MSG_DSTX, parent_txid);
AddKnownInv(*peer, _inv2.hash);
if (!AlreadyHave(_inv2)) RequestObject(State(pfrom.GetId()), _inv2, current_time, is_masternode);
}
AddOrphanTx(ptx, pfrom.GetId());
// DoS prevention: do not allow mapOrphanTransactions to grow unbounded (see CVE-2012-3789)
unsigned int nMaxOrphanTxSize = (unsigned int)std::max((int64_t)0, gArgs.GetArg("-maxorphantxsize", DEFAULT_MAX_ORPHAN_TRANSACTIONS_SIZE)) * 1000000;
unsigned int nEvicted = LimitOrphanTxSize(nMaxOrphanTxSize);
if (nEvicted > 0) {
LogPrint(BCLog::MEMPOOL, "mapOrphan overflow, removed %u tx\n", nEvicted);
}
} else {
LogPrint(BCLog::MEMPOOL, "not keeping orphan with rejected parents %s\n",tx.GetHash().ToString());
// We will continue to reject this tx since it has rejected
// parents so avoid re-requesting it from other peers.
m_recent_rejects.insert(tx.GetHash());
m_llmq_ctx->isman->TransactionRemovedFromMempool(ptx);
}
} else {
m_recent_rejects.insert(tx.GetHash());
if (RecursiveDynamicUsage(*ptx) < 100000) {
AddToCompactExtraTransactions(ptx);
}
}
// If a tx has been detected by m_recent_rejects, we will have reached
// this point and the tx will have been ignored. Because we haven't run
// the tx through AcceptToMemoryPool, we won't have computed a DoS
// score for it or determined exactly why we consider it invalid.
//
// This means we won't penalize any peer subsequently relaying a DoSy
// tx (even if we penalized the first peer who gave it to us) because
// we have to account for m_recent_rejects showing false positives. In
// other words, we shouldn't penalize a peer if we aren't *sure* they
// submitted a DoSy tx.
//
// Note that m_recent_rejects doesn't just record DoSy or invalid
// transactions, but any tx not accepted by the m_mempool, which may be
// due to node policy (vs. consensus). So we can't blanket penalize a
// peer simply for relaying a tx that our m_recent_rejects has caught,
// regardless of false positives.
if (state.IsInvalid()) {
LogPrint(BCLog::MEMPOOLREJ, "%s from peer=%d was not accepted: %s\n", tx.GetHash().ToString(),
pfrom.GetId(),
state.ToString());
MaybePunishNodeForTx(pfrom.GetId(), state);
m_llmq_ctx->isman->TransactionRemovedFromMempool(ptx);
}
return;
}
if (msg_type == NetMsgType::CMPCTBLOCK)
{
// Ignore cmpctblock received while importing
if (fImporting || fReindex) {
LogPrint(BCLog::NET, "Unexpected cmpctblock message received from peer %d\n", pfrom.GetId());
return;
}
CBlockHeaderAndShortTxIDs cmpctblock;
vRecv >> cmpctblock;
bool received_new_header = false;
{
LOCK(cs_main);
if (!m_chainman.m_blockman.LookupBlockIndex(cmpctblock.header.hashPrevBlock)) {
// Doesn't connect (or is genesis), instead of DoSing in AcceptBlockHeader, request deeper headers
if (!m_chainman.ActiveChainstate().IsInitialBlockDownload()) {
std::string ret_val = UsesCompressedHeaders(*peer) ? NetMsgType::GETHEADERS2 : NetMsgType::GETHEADERS;
MaybeSendGetHeaders(pfrom, ret_val, m_chainman.ActiveChain().GetLocator(m_chainman.m_best_header), *peer);
}
return;
}
if (!m_chainman.m_blockman.LookupBlockIndex(cmpctblock.header.GetHash())) {
received_new_header = true;
}
}
const CBlockIndex *pindex = nullptr;
BlockValidationState state;
if (!m_chainman.ProcessNewBlockHeaders({cmpctblock.header}, state, m_chainparams, &pindex)) {
if (state.IsInvalid()) {
MaybePunishNodeForBlock(pfrom.GetId(), state, /*via_compact_block*/ true, "invalid header via cmpctblock");
return;
}
}
// When we succeed in decoding a block's txids from a cmpctblock
// message we typically jump to the BLOCKTXN handling code, with a
// dummy (empty) BLOCKTXN message, to re-use the logic there in
// completing processing of the putative block (without cs_main).
bool fProcessBLOCKTXN = false;
CDataStream blockTxnMsg(SER_NETWORK, PROTOCOL_VERSION);
// If we end up treating this as a plain headers message, call that as well
// without cs_main.
bool fRevertToHeaderProcessing = false;
// Keep a CBlock for "optimistic" compactblock reconstructions (see
// below)
std::shared_ptr<CBlock> pblock = std::make_shared<CBlock>();
bool fBlockReconstructed = false;
{
LOCK2(cs_main, g_cs_orphans);
// If AcceptBlockHeader returned true, it set pindex
assert(pindex);
UpdateBlockAvailability(pfrom.GetId(), pindex->GetBlockHash());
CNodeState *nodestate = State(pfrom.GetId());
// If this was a new header with more work than our tip, update the
// peer's last block announcement time
if (received_new_header && pindex->nChainWork > m_chainman.ActiveChain().Tip()->nChainWork) {
nodestate->m_last_block_announcement = GetTime();
}
std::map<uint256, std::pair<NodeId, std::list<QueuedBlock>::iterator> >::iterator blockInFlightIt = mapBlocksInFlight.find(pindex->GetBlockHash());
bool fAlreadyInFlight = blockInFlightIt != mapBlocksInFlight.end();
if (pindex->nStatus & BLOCK_HAVE_DATA) // Nothing to do here
return;
if (pindex->nChainWork <= m_chainman.ActiveChain().Tip()->nChainWork || // We know something better
pindex->nTx != 0) { // We had this block at some point, but pruned it
if (fAlreadyInFlight) {
// We requested this block for some reason, but our mempool will probably be useless
// so we just grab the block via normal getdata
std::vector<CInv> vInv(1);
vInv[0] = CInv(MSG_BLOCK, cmpctblock.header.GetHash());
m_connman.PushMessage(&pfrom, msgMaker.Make(NetMsgType::GETDATA, vInv));
}
return;
}
// If we're not close to tip yet, give up and let parallel block fetch work its magic
if (!fAlreadyInFlight && !CanDirectFetch())
return;
// We want to be a bit conservative just to be extra careful about DoS
// possibilities in compact block processing...
if (pindex->nHeight <= m_chainman.ActiveChain().Height() + 2) {
if ((!fAlreadyInFlight && nodestate->nBlocksInFlight < MAX_BLOCKS_IN_TRANSIT_PER_PEER) ||
(fAlreadyInFlight && blockInFlightIt->second.first == pfrom.GetId())) {
std::list<QueuedBlock>::iterator *queuedBlockIt = nullptr;
if (!MarkBlockAsInFlight(pfrom.GetId(), pindex->GetBlockHash(), pindex, &queuedBlockIt)) {
if (!(*queuedBlockIt)->partialBlock)
(*queuedBlockIt)->partialBlock.reset(new PartiallyDownloadedBlock(&m_mempool));
else {
// The block was already in flight using compact blocks from the same peer
LogPrint(BCLog::NET, "Peer sent us compact block we were already syncing!\n");
return;
}
}
PartiallyDownloadedBlock& partialBlock = *(*queuedBlockIt)->partialBlock;
ReadStatus status = partialBlock.InitData(cmpctblock, vExtraTxnForCompact);
if (status == READ_STATUS_INVALID) {
MarkBlockAsReceived(pindex->GetBlockHash()); // Reset in-flight state in case Misbehaving does not result in a disconnect
Misbehaving(pfrom.GetId(), 100, "invalid compact block");
return;
} else if (status == READ_STATUS_FAILED) {
// Duplicate txindexes, the block is now in-flight, so just request it
std::vector<CInv> vInv(1);
vInv[0] = CInv(MSG_BLOCK, cmpctblock.header.GetHash());
m_connman.PushMessage(&pfrom, msgMaker.Make(NetMsgType::GETDATA, vInv));
return;
}
BlockTransactionsRequest req;
for (size_t i = 0; i < cmpctblock.BlockTxCount(); i++) {
if (!partialBlock.IsTxAvailable(i))
req.indexes.push_back(i);
}
if (req.indexes.empty()) {
// Dirty hack to jump to BLOCKTXN code (TODO: move message handling into their own functions)
BlockTransactions txn;
txn.blockhash = cmpctblock.header.GetHash();
blockTxnMsg << txn;
fProcessBLOCKTXN = true;
} else {
req.blockhash = pindex->GetBlockHash();
m_connman.PushMessage(&pfrom, msgMaker.Make(NetMsgType::GETBLOCKTXN, req));
}
} else {
// This block is either already in flight from a different
// peer, or this peer has too many blocks outstanding to
// download from.
// Optimistically try to reconstruct anyway since we might be
// able to without any round trips.
PartiallyDownloadedBlock tempBlock(&m_mempool);
ReadStatus status = tempBlock.InitData(cmpctblock, vExtraTxnForCompact);
if (status != READ_STATUS_OK) {
// TODO: don't ignore failures
return;
}
std::vector<CTransactionRef> dummy;
status = tempBlock.FillBlock(*pblock, dummy);
if (status == READ_STATUS_OK) {
fBlockReconstructed = true;
}
}
} else {
if (fAlreadyInFlight) {
// We requested this block, but its far into the future, so our
// mempool will probably be useless - request the block normally
std::vector<CInv> vInv(1);
vInv[0] = CInv(MSG_BLOCK, cmpctblock.header.GetHash());
m_connman.PushMessage(&pfrom, msgMaker.Make(NetMsgType::GETDATA, vInv));
return;
} else {
// If this was an announce-cmpctblock, we want the same treatment as a header message
fRevertToHeaderProcessing = true;
}
}
} // cs_main
if (fProcessBLOCKTXN)
return ProcessMessage(pfrom, NetMsgType::BLOCKTXN, blockTxnMsg, time_received, interruptMsgProc);
if (fRevertToHeaderProcessing) {
// Headers received from HB compact block peers are permitted to be
// relayed before full validation (see BIP 152), so we don't want to disconnect
// the peer if the header turns out to be for an invalid block.
// Note that if a peer tries to build on an invalid chain, that
// will be detected and the peer will be disconnected/discouraged.
return ProcessHeadersMessage(pfrom, *peer, {cmpctblock.header}, /*punish_duplicate_invalid=*/true);
}
if (fBlockReconstructed) {
// If we got here, we were able to optimistically reconstruct a
// block that is in flight from some other peer.
{
LOCK(cs_main);
mapBlockSource.emplace(pblock->GetHash(), std::make_pair(pfrom.GetId(), false));
}
// Setting fForceProcessing to true means that we bypass some of
// our anti-DoS protections in AcceptBlock, which filters
// unrequested blocks that might be trying to waste our resources
// (eg disk space). Because we only try to reconstruct blocks when
// we're close to caught up (via the CanDirectFetch() requirement
// above, combined with the behavior of not requesting blocks until
// we have a chain with at least nMinimumChainWork), and we ignore
// compact blocks with less work than our tip, it is safe to treat
// reconstructed compact blocks as having been requested.
ProcessBlock(pfrom, pblock, /*fForceProcessing=*/true);
LOCK(cs_main); // hold cs_main for CBlockIndex::IsValid()
if (pindex->IsValid(BLOCK_VALID_TRANSACTIONS)) {
// Clear download state for this block, which is in
// process from some other peer. We do this after calling
// ProcessNewBlock so that a malleated cmpctblock announcement
// can't be used to interfere with block relay.
MarkBlockAsReceived(pblock->GetHash());
}
}
return;
}
if (msg_type == NetMsgType::BLOCKTXN)
{
// Ignore blocktxn received while importing
if (fImporting || fReindex) {
LogPrint(BCLog::NET, "Unexpected blocktxn message received from peer %d\n", pfrom.GetId());
return;
}
BlockTransactions resp;
vRecv >> resp;
std::shared_ptr<CBlock> pblock = std::make_shared<CBlock>();
bool fBlockRead = false;
{
LOCK(cs_main);
std::map<uint256, std::pair<NodeId, std::list<QueuedBlock>::iterator> >::iterator it = mapBlocksInFlight.find(resp.blockhash);
if (it == mapBlocksInFlight.end() || !it->second.second->partialBlock ||
it->second.first != pfrom.GetId()) {
LogPrint(BCLog::NET, "Peer %d sent us block transactions for block we weren't expecting\n", pfrom.GetId());
return;
}
PartiallyDownloadedBlock& partialBlock = *it->second.second->partialBlock;
ReadStatus status = partialBlock.FillBlock(*pblock, resp.txn);
if (status == READ_STATUS_INVALID) {
MarkBlockAsReceived(resp.blockhash); // Reset in-flight state in case Misbehaving does not result in a disconnect
Misbehaving(pfrom.GetId(), 100, "invalid compact block/non-matching block transactions");
return;
} else if (status == READ_STATUS_FAILED) {
// Might have collided, fall back to getdata now :(
std::vector<CInv> invs;
invs.push_back(CInv(MSG_BLOCK, resp.blockhash));
m_connman.PushMessage(&pfrom, msgMaker.Make(NetMsgType::GETDATA, invs));
} else {
// Block is either okay, or possibly we received
// READ_STATUS_CHECKBLOCK_FAILED.
// Note that CheckBlock can only fail for one of a few reasons:
// 1. bad-proof-of-work (impossible here, because we've already
// accepted the header)
// 2. merkleroot doesn't match the transactions given (already
// caught in FillBlock with READ_STATUS_FAILED, so
// impossible here)
// 3. the block is otherwise invalid (eg invalid coinbase,
// block is too big, too many legacy sigops, etc).
// So if CheckBlock failed, #3 is the only possibility.
// Under BIP 152, we don't discourage the peer unless proof of work is
// invalid (we don't require all the stateless checks to have
// been run). This is handled below, so just treat this as
// though the block was successfully read, and rely on the
// handling in ProcessNewBlock to ensure the block index is
// updated, etc.
MarkBlockAsReceived(resp.blockhash); // it is now an empty pointer
fBlockRead = true;
// mapBlockSource is used for potentially punishing peers and
// updating which peers send us compact blocks, so the race
// between here and cs_main in ProcessNewBlock is fine.
// BIP 152 permits peers to relay compact blocks after validating
// the header only; we should not punish peers if the block turns
// out to be invalid.
mapBlockSource.emplace(resp.blockhash, std::make_pair(pfrom.GetId(), false));
}
} // Don't hold cs_main when we call into ProcessNewBlock
if (fBlockRead) {
// Since we requested this block (it was in mapBlocksInFlight), force it to be processed,
// even if it would not be a candidate for new tip (missing previous block, chain not long enough, etc)
// This bypasses some anti-DoS logic in AcceptBlock (eg to prevent
// disk-space attacks), but this should be safe due to the
// protections in the compact block handler -- see related comment
// in compact block optimistic reconstruction handling.
ProcessBlock(pfrom, pblock, /*fForceProcessing=*/true);
}
return;
}
if (msg_type == NetMsgType::HEADERS || msg_type == NetMsgType::HEADERS2) {
// Ignore headers received while importing
if (fImporting || fReindex) {
LogPrint(BCLog::NET, "Unexpected headers message received from peer %d\n", pfrom.GetId());
return;
}
// Assume that this is in response to any outstanding getheaders
// request we may have sent, and clear out the time of our last request
peer->m_last_getheaders_timestamp = 0s;
std::vector<CBlockHeader> headers;
// Bypass the normal CBlock deserialization, as we don't want to risk deserializing 2000 full blocks.
unsigned int nCount = ReadCompactSize(vRecv);
if (nCount > MAX_HEADERS_RESULTS) {
Misbehaving(pfrom.GetId(), 20, strprintf("headers message size = %u", nCount));
return;
}
if (msg_type == NetMsgType::HEADERS) {
headers.resize(nCount);
for (unsigned int n = 0; n < nCount; n++) {
vRecv >> headers[n];
ReadCompactSize(vRecv); // ignore tx count; assume it is 0.
}
} else if (msg_type == NetMsgType::HEADERS2) {
std::list<int32_t> last_unique_versions;
for (unsigned int n = 0; n < nCount; n++) {
CompressibleBlockHeader block_header_compressed;
vRecv >> block_header_compressed;
block_header_compressed.Uncompress(headers, last_unique_versions);
headers.push_back(block_header_compressed);
}
}
return ProcessHeadersMessage(pfrom, *peer, headers, /*via_compact_block=*/false);
}
if (msg_type == NetMsgType::BLOCK)
{
// Ignore block received while importing
if (fImporting || fReindex) {
LogPrint(BCLog::NET, "Unexpected block message received from peer %d\n", pfrom.GetId());
return;
}
std::shared_ptr<CBlock> pblock = std::make_shared<CBlock>();
vRecv >> *pblock;
LogPrint(BCLog::NET, "received block %s peer=%d\n", pblock->GetHash().ToString(), pfrom.GetId());
bool forceProcessing = false;
const uint256 hash(pblock->GetHash());
{
LOCK(cs_main);
// Also always process if we requested the block explicitly, as we may
// need it even though it is not a candidate for a new best tip.
forceProcessing |= MarkBlockAsReceived(hash);
// mapBlockSource is only used for punishing peers and setting
// which peers send us compact blocks, so the race between here and
// cs_main in ProcessNewBlock is fine.
mapBlockSource.emplace(hash, std::make_pair(pfrom.GetId(), true));
}
ProcessBlock(pfrom, pblock, forceProcessing);
return;
}
if (msg_type == NetMsgType::GETADDR) {
// This asymmetric behavior for inbound and outbound connections was introduced
// to prevent a fingerprinting attack: an attacker can send specific fake addresses
// to users' AddrMan and later request them by sending getaddr messages.
// Making nodes which are behind NAT and can only make outgoing connections ignore
// the getaddr message mitigates the attack.
if (!pfrom.IsInboundConn()) {
LogPrint(BCLog::NET, "Ignoring \"getaddr\" from %s connection. peer=%d\n", pfrom.ConnectionTypeAsString(), pfrom.GetId());
return;
}
// Since this must be an inbound connection, SetupAddressRelay will
// never fail.
Assume(SetupAddressRelay(pfrom, *peer));
// Only send one GetAddr response per connection to reduce resource waste
// and discourage addr stamping of INV announcements.
if (peer->m_getaddr_recvd) {
LogPrint(BCLog::NET, "Ignoring repeated \"getaddr\". peer=%d\n", pfrom.GetId());
return;
}
peer->m_getaddr_recvd = true;
peer->m_addrs_to_send.clear();
std::vector<CAddress> vAddr;
if (pfrom.HasPermission(NetPermissionFlags::Addr)) {
vAddr = m_connman.GetAddresses(MAX_ADDR_TO_SEND, MAX_PCT_ADDR_TO_SEND, /* network */ std::nullopt);
} else {
vAddr = m_connman.GetAddresses(pfrom, MAX_ADDR_TO_SEND, MAX_PCT_ADDR_TO_SEND);
}
FastRandomContext insecure_rand;
for (const CAddress &addr : vAddr) {
PushAddress(*peer, addr, insecure_rand);
}
return;
}
if (msg_type == NetMsgType::MEMPOOL) {
if (!(peer->m_our_services & NODE_BLOOM) && !pfrom.HasPermission(NetPermissionFlags::Mempool))
{
if (!pfrom.HasPermission(NetPermissionFlags::NoBan))
{
LogPrint(BCLog::NET, "mempool request with bloom filters disabled, disconnect peer=%d\n", pfrom.GetId());
pfrom.fDisconnect = true;
}
return;
}
if (m_connman.OutboundTargetReached(false) && !pfrom.HasPermission(NetPermissionFlags::Mempool))
{
if (!pfrom.HasPermission(NetPermissionFlags::NoBan))
{
LogPrint(BCLog::NET, "mempool request with bandwidth limit reached, disconnect peer=%d\n", pfrom.GetId());
pfrom.fDisconnect = true;
}
return;
}
if (!pfrom.IsBlockOnlyConn()) {
LOCK(peer->m_tx_relay->m_tx_inventory_mutex);
peer->m_tx_relay->m_send_mempool = true;
}
return;
}
if (msg_type == NetMsgType::PING) {
uint64_t nonce = 0;
vRecv >> nonce;
// Echo the message back with the nonce. This allows for two useful features:
//
// 1) A remote node can quickly check if the connection is operational
// 2) Remote nodes can measure the latency of the network thread. If this node
// is overloaded it won't respond to pings quickly and the remote node can
// avoid sending us more work, like chain download requests.
//
// The nonce stops the remote getting confused between different pings: without
// it, if the remote node sends a ping once per second and this node takes 5
// seconds to respond to each, the 5th ping the remote sends would appear to
// return very quickly.
m_connman.PushMessage(&pfrom, msgMaker.Make(NetMsgType::PONG, nonce));
return;
}
if (msg_type == NetMsgType::PONG) {
const auto ping_end = time_received;
uint64_t nonce = 0;
size_t nAvail = vRecv.in_avail();
bool bPingFinished = false;
std::string sProblem;
if (nAvail >= sizeof(nonce)) {
vRecv >> nonce;
// Only process pong message if there is an outstanding ping (old ping without nonce should never pong)
if (peer->m_ping_nonce_sent != 0) {
if (nonce == peer->m_ping_nonce_sent) {
// Matching pong received, this ping is no longer outstanding
bPingFinished = true;
const auto ping_time = ping_end - peer->m_ping_start.load();
if (ping_time.count() >= 0) {
// Let connman know about this successful ping-pong
pfrom.PongReceived(ping_time);
} else {
// This should never happen
sProblem = "Timing mishap";
}
} else {
// Nonce mismatches are normal when pings are overlapping
sProblem = "Nonce mismatch";
if (nonce == 0) {
// This is most likely a bug in another implementation somewhere; cancel this ping
bPingFinished = true;
sProblem = "Nonce zero";
}
}
} else {
sProblem = "Unsolicited pong without ping";
}
} else {
// This is most likely a bug in another implementation somewhere; cancel this ping
bPingFinished = true;
sProblem = "Short payload";
}
if (!(sProblem.empty())) {
LogPrint(BCLog::NET, "pong peer=%d: %s, %x expected, %x received, %u bytes\n",
pfrom.GetId(),
sProblem,
peer->m_ping_nonce_sent,
nonce,
nAvail);
}
if (bPingFinished) {
peer->m_ping_nonce_sent = 0;
}
return;
}
if (msg_type == NetMsgType::FILTERLOAD) {
if (!(peer->m_our_services & NODE_BLOOM)) {
LogPrint(BCLog::NET_NETCONN, "filterload received despite not offering bloom services from peer=%d; disconnecting\n", pfrom.GetId());
pfrom.fDisconnect = true;
return;
}
CBloomFilter filter;
vRecv >> filter;
if (!filter.IsWithinSizeConstraints())
{
// There is no excuse for sending a too-large filter
Misbehaving(pfrom.GetId(), 100, "too-large bloom filter");
}
else if (!pfrom.IsBlockOnlyConn())
{
{
LOCK(peer->m_tx_relay->m_bloom_filter_mutex);
peer->m_tx_relay->m_bloom_filter.reset(new CBloomFilter(filter));
peer->m_tx_relay->m_relay_txs = true;
}
pfrom.m_bloom_filter_loaded = true;
pfrom.m_relays_txs = true;
}
return;
}
if (msg_type == NetMsgType::FILTERADD) {
if (!(peer->m_our_services & NODE_BLOOM)) {
LogPrint(BCLog::NET_NETCONN, "filteradd received despite not offering bloom services from peer=%d; disconnecting\n", pfrom.GetId());
pfrom.fDisconnect = true;
return;
}
std::vector<unsigned char> vData;
vRecv >> vData;
// Nodes must NEVER send a data item > 520 bytes (the max size for a script data object,
// and thus, the maximum size any matched object can have) in a filteradd message
bool bad = false;
if (vData.size() > MAX_SCRIPT_ELEMENT_SIZE) {
bad = true;
} else if (!pfrom.IsBlockOnlyConn()) {
LOCK(peer->m_tx_relay->m_bloom_filter_mutex);
if (peer->m_tx_relay->m_bloom_filter) {
peer->m_tx_relay->m_bloom_filter->insert(vData);
} else {
bad = true;
}
}
if (bad) {
Misbehaving(pfrom.GetId(), 100, "bad filteradd message");
}
return;
}
if (msg_type == NetMsgType::FILTERCLEAR) {
if (!(peer->m_our_services & NODE_BLOOM)) {
LogPrint(BCLog::NET_NETCONN, "filterclear received despite not offering bloom services from peer=%d; disconnecting\n", pfrom.GetId());
pfrom.fDisconnect = true;
return;
}
if (pfrom.IsBlockOnlyConn()) {
return;
}
{
LOCK(peer->m_tx_relay->m_bloom_filter_mutex);
peer->m_tx_relay->m_bloom_filter = nullptr;
peer->m_tx_relay->m_relay_txs = true;
}
pfrom.m_bloom_filter_loaded = false;
pfrom.m_relays_txs = true;
return;
}
if (msg_type == NetMsgType::GETMNLISTDIFF) {
CGetSimplifiedMNListDiff cmd;
vRecv >> cmd;
LOCK(cs_main);
CSimplifiedMNListDiff mnListDiff;
std::string strError;
if (BuildSimplifiedMNListDiff(*m_dmnman, m_chainman, *m_llmq_ctx->quorum_block_processor, *m_llmq_ctx->qman,
cmd.baseBlockHash, cmd.blockHash, mnListDiff, strError))
{
m_connman.PushMessage(&pfrom, msgMaker.Make(NetMsgType::MNLISTDIFF, mnListDiff));
} else {
strError = strprintf("getmnlistdiff failed for baseBlockHash=%s, blockHash=%s. error=%s", cmd.baseBlockHash.ToString(), cmd.blockHash.ToString(), strError);
Misbehaving(pfrom.GetId(), 1, strError);
}
return;
}
if (msg_type == NetMsgType::GETCFILTERS) {
ProcessGetCFilters(pfrom, *peer, vRecv);
return;
}
if (msg_type == NetMsgType::GETCFHEADERS) {
ProcessGetCFHeaders(pfrom, *peer, vRecv);
return;
}
if (msg_type == NetMsgType::GETCFCHECKPT) {
ProcessGetCFCheckPt(pfrom, *peer, vRecv);
return;
}
if (msg_type == NetMsgType::MNLISTDIFF) {
// we have never requested this
Misbehaving(pfrom.GetId(), 100, strprintf("received not-requested mnlistdiff. peer=%d", pfrom.GetId()));
return;
}
if (msg_type == NetMsgType::GETQUORUMROTATIONINFO) {
llmq::CGetQuorumRotationInfo cmd;
vRecv >> cmd;
LOCK(cs_main);
llmq::CQuorumRotationInfo quorumRotationInfoRet;
std::string strError;
if (BuildQuorumRotationInfo(*m_dmnman, m_chainman, *m_llmq_ctx->qman, *m_llmq_ctx->quorum_block_processor, cmd, quorumRotationInfoRet, strError)) {
m_connman.PushMessage(&pfrom, msgMaker.Make(NetMsgType::QUORUMROTATIONINFO, quorumRotationInfoRet));
} else {
strError = strprintf("getquorumrotationinfo failed for size(baseBlockHashes)=%d, blockRequestHash=%s. error=%s", cmd.baseBlockHashes.size(), cmd.blockRequestHash.ToString(), strError);
Misbehaving(pfrom.GetId(), 1, strError);
}
return;
}
if (msg_type == NetMsgType::QUORUMROTATIONINFO) {
// we have never requested this
Misbehaving(pfrom.GetId(), 100, strprintf("received not-requested quorumrotationinfo. peer=%d", pfrom.GetId()));
return;
}
if (msg_type == NetMsgType::NOTFOUND) {
// Remove the NOTFOUND transactions from the peer
LOCK(cs_main);
CNodeState *state = State(pfrom.GetId());
std::vector<CInv> vInv;
vRecv >> vInv;
if (vInv.size() <= MAX_PEER_OBJECT_IN_FLIGHT + MAX_BLOCKS_IN_TRANSIT_PER_PEER) {
for (CInv &inv : vInv) {
if (inv.IsKnownType()) {
// If we receive a NOTFOUND message for a txid we requested, erase
// it from our data structures for this peer.
auto in_flight_it = state->m_object_download.m_object_in_flight.find(inv);
if (in_flight_it == state->m_object_download.m_object_in_flight.end()) {
// Skip any further work if this is a spurious NOTFOUND
// message.
continue;
}
state->m_object_download.m_object_in_flight.erase(in_flight_it);
state->m_object_download.m_object_announced.erase(inv);
}
}
}
return;
}
bool found = false;
const std::vector<std::string> &allMessages = getAllNetMessageTypes();
for (const std::string& msg : allMessages) {
if(msg == msg_type) {
found = true;
break;
}
}
if (found)
{
//probably one the extensions
#ifdef ENABLE_WALLET
ProcessPeerMsgRet(m_cj_ctx->queueman->ProcessMessage(pfrom, msg_type, vRecv), pfrom);
for (auto& pair : m_cj_ctx->walletman->raw()) {
pair.second->ProcessMessage(pfrom, m_chainman.ActiveChainstate(), m_connman, m_mempool, msg_type, vRecv);
}
#endif // ENABLE_WALLET
ProcessPeerMsgRet(m_cj_ctx->server->ProcessMessage(pfrom, msg_type, vRecv), pfrom);
ProcessPeerMsgRet(m_sporkman.ProcessMessage(pfrom, m_connman, *this, msg_type, vRecv), pfrom);
m_mn_sync.ProcessMessage(pfrom, msg_type, vRecv);
ProcessPeerMsgRet(m_govman.ProcessMessage(pfrom, m_connman, *this, msg_type, vRecv), pfrom);
ProcessPeerMsgRet(CMNAuth::ProcessMessage(pfrom, peer->m_their_services, m_connman, m_mn_metaman, m_mn_activeman, m_chainman.ActiveChain(), m_mn_sync, m_dmnman->GetListAtChainTip(), msg_type, vRecv), pfrom);
ProcessPeerMsgRet(m_llmq_ctx->quorum_block_processor->ProcessMessage(pfrom, msg_type, vRecv), pfrom);
ProcessPeerMsgRet(m_llmq_ctx->qdkgsman->ProcessMessage(pfrom, this, is_masternode, msg_type, vRecv), pfrom);
ProcessPeerMsgRet(m_llmq_ctx->qman->ProcessMessage(pfrom, msg_type, vRecv), pfrom);
m_llmq_ctx->shareman->ProcessMessage(pfrom, m_sporkman, msg_type, vRecv);
ProcessPeerMsgRet(m_llmq_ctx->sigman->ProcessMessage(pfrom, msg_type, vRecv), pfrom);
ProcessPeerMsgRet(m_llmq_ctx->clhandler->ProcessMessage(pfrom, msg_type, vRecv), pfrom);
ProcessPeerMsgRet(m_llmq_ctx->isman->ProcessMessage(pfrom, msg_type, vRecv), pfrom);
return;
}
// Ignore unknown commands for extensibility
LogPrint(BCLog::NET, "Unknown command \"%s\" from peer=%d\n", SanitizeString(msg_type), pfrom.GetId());
return;
}
bool PeerManagerImpl::MaybeDiscourageAndDisconnect(CNode& pnode, Peer& peer)
{
{
LOCK(peer.m_misbehavior_mutex);
// There's nothing to do if the m_should_discourage flag isn't set
if (!peer.m_should_discourage) return false;
peer.m_should_discourage = false;
} // peer.m_misbehavior_mutex
if (pnode.HasPermission(NetPermissionFlags::NoBan)) {
// We never disconnect or discourage peers for bad behavior if they have NetPermissionFlags::NoBan permission
LogPrintf("Warning: not punishing noban peer %d!\n", peer.m_id);
return false;
}
if (pnode.IsManualConn()) {
// We never disconnect or discourage manual peers for bad behavior
LogPrintf("Warning: not punishing manually connected peer %d!\n", peer.m_id);
return false;
}
if (pnode.addr.IsLocal()) {
// We disconnect local peers for bad behavior but don't discourage (since that would discourage
// all peers on the same local address)
LogPrint(BCLog::NET, "Warning: disconnecting but not discouraging %s peer %d!\n",
pnode.m_inbound_onion ? "inbound onion" : "local", peer.m_id);
pnode.fDisconnect = true;
return true;
}
// Normal case: Disconnect the peer and discourage all nodes sharing the address
LogPrint(BCLog::NET, "Disconnecting and discouraging peer %d!\n", peer.m_id);
if (m_banman) m_banman->Discourage(pnode.addr);
m_connman.DisconnectNode(pnode.addr);
return true;
}
bool PeerManagerImpl::ProcessMessages(CNode* pfrom, std::atomic<bool>& interruptMsgProc)
{
bool fMoreWork = false;
PeerRef peer = GetPeerRef(pfrom->GetId());
if (peer == nullptr) return false;
{
LOCK(peer->m_getdata_requests_mutex);
if (!peer->m_getdata_requests.empty()) {
ProcessGetData(*pfrom, *peer, interruptMsgProc);
}
}
{
LOCK2(cs_main, g_cs_orphans);
if (!peer->m_orphan_work_set.empty()) {
ProcessOrphanTx(peer->m_orphan_work_set);
}
}
if (pfrom->fDisconnect)
return false;
// this maintains the order of responses
// and prevents m_getdata_requests to grow unbounded
{
LOCK(peer->m_getdata_requests_mutex);
if (!peer->m_getdata_requests.empty()) return true;
}
{
LOCK(g_cs_orphans);
if (!peer->m_orphan_work_set.empty()) return true;
}
// Don't bother if send buffer is too full to respond anyway
if (pfrom->fPauseSend) return false;
std::list<CNetMessage> msgs;
{
LOCK(pfrom->cs_vProcessMsg);
if (pfrom->vProcessMsg.empty()) return false;
// Just take one message
msgs.splice(msgs.begin(), pfrom->vProcessMsg, pfrom->vProcessMsg.begin());
pfrom->nProcessQueueSize -= msgs.front().m_raw_message_size;
pfrom->fPauseRecv = pfrom->nProcessQueueSize > m_connman.GetReceiveFloodSize();
fMoreWork = !pfrom->vProcessMsg.empty();
}
CNetMessage& msg(msgs.front());
if (gArgs.GetBoolArg("-capturemessages", false)) {
CaptureMessage(pfrom->addr, msg.m_type, MakeUCharSpan(msg.m_recv), /* incoming */ true);
}
msg.SetVersion(pfrom->GetCommonVersion());
try {
ProcessMessage(*pfrom, msg.m_type, msg.m_recv, msg.m_time, interruptMsgProc);
if (interruptMsgProc) return false;
{
LOCK(peer->m_getdata_requests_mutex);
if (!peer->m_getdata_requests.empty()) fMoreWork = true;
}
} catch (const std::exception& e) {
LogPrint(BCLog::NET, "%s(%s, %u bytes): Exception '%s' (%s) caught\n", __func__, SanitizeString(msg.m_type), msg.m_message_size, e.what(), typeid(e).name());
} catch (...) {
LogPrint(BCLog::NET, "%s(%s, %u bytes): Unknown exception caught\n", __func__, SanitizeString(msg.m_type), msg.m_message_size);
}
return fMoreWork;
}
void PeerManagerImpl::ConsiderEviction(CNode& pto, Peer& peer, std::chrono::seconds time_in_seconds)
{
AssertLockHeld(cs_main);
CNodeState &state = *State(pto.GetId());
const CNetMsgMaker msgMaker(pto.GetCommonVersion());
if (!state.m_chain_sync.m_protect && pto.IsOutboundOrBlockRelayConn() && state.fSyncStarted) {
// This is an outbound peer subject to disconnection if they don't
// announce a block with as much work as the current tip within
// CHAIN_SYNC_TIMEOUT + HEADERS_RESPONSE_TIME seconds (note: if
// their chain has more work than ours, we should sync to it,
// unless it's invalid, in which case we should find that out and
// disconnect from them elsewhere).
if (state.pindexBestKnownBlock != nullptr && state.pindexBestKnownBlock->nChainWork >= m_chainman.ActiveChain().Tip()->nChainWork) {
if (state.m_chain_sync.m_timeout != 0s) {
state.m_chain_sync.m_timeout = 0s;
state.m_chain_sync.m_work_header = nullptr;
state.m_chain_sync.m_sent_getheaders = false;
}
} else if (state.m_chain_sync.m_timeout == 0s || (state.m_chain_sync.m_work_header != nullptr && state.pindexBestKnownBlock != nullptr && state.pindexBestKnownBlock->nChainWork >= state.m_chain_sync.m_work_header->nChainWork)) {
// Our best block known by this peer is behind our tip, and we're either noticing
// that for the first time, OR this peer was able to catch up to some earlier point
// where we checked against our tip.
// Either way, set a new timeout based on current tip.
state.m_chain_sync.m_timeout = time_in_seconds + CHAIN_SYNC_TIMEOUT;
state.m_chain_sync.m_work_header = m_chainman.ActiveChain().Tip();
state.m_chain_sync.m_sent_getheaders = false;
} else if (state.m_chain_sync.m_timeout > 0s && time_in_seconds > state.m_chain_sync.m_timeout) {
// No evidence yet that our peer has synced to a chain with work equal to that
// of our tip, when we first detected it was behind. Send a single getheaders
// message to give the peer a chance to update us.
if (state.m_chain_sync.m_sent_getheaders) {
// They've run out of time to catch up!
LogPrintf("Disconnecting outbound peer %d for old chain, best known block = %s\n", pto.GetId(), state.pindexBestKnownBlock != nullptr ? state.pindexBestKnownBlock->GetBlockHash().ToString() : "<none>");
pto.fDisconnect = true;
} else {
assert(state.m_chain_sync.m_work_header);
// Here, we assume that the getheaders message goes out,
// because it'll either go out or be skipped because of a
// getheaders in-flight already, in which case the peer should
// still respond to us with a sufficiently high work chain tip.
std::string msg_type = UsesCompressedHeaders(peer) ? NetMsgType::GETHEADERS2 : NetMsgType::GETHEADERS;
MaybeSendGetHeaders(pto,
msg_type, m_chainman.ActiveChain().GetLocator(state.m_chain_sync.m_work_header->pprev),
peer);
LogPrint(BCLog::NET, "sending %s to outbound peer=%d to verify chain work (current best known block:%s, benchmark blockhash: %s)\n", msg_type, pto.GetId(), state.pindexBestKnownBlock != nullptr ? state.pindexBestKnownBlock->GetBlockHash().ToString() : "<none>", state.m_chain_sync.m_work_header->GetBlockHash().ToString());
state.m_chain_sync.m_sent_getheaders = true;
// Bump the timeout to allow a response, which could clear the timeout
// (if the response shows the peer has synced), reset the timeout (if
// the peer syncs to the required work but not to our tip), or result
// in disconnect (if we advance to the timeout and pindexBestKnownBlock
// has not sufficiently progressed)
state.m_chain_sync.m_timeout = time_in_seconds + HEADERS_RESPONSE_TIME;
}
}
}
}
void PeerManagerImpl::EvictExtraOutboundPeers(std::chrono::seconds now)
{
// If we have any extra block-relay-only peers, disconnect the youngest unless
// it's given us a block -- in which case, compare with the second-youngest, and
// out of those two, disconnect the peer who least recently gave us a block.
// The youngest block-relay-only peer would be the extra peer we connected
// to temporarily in order to sync our tip; see net.cpp.
// Note that we use higher nodeid as a measure for most recent connection.
if (m_connman.GetExtraBlockRelayCount() > 0) {
std::pair<NodeId, std::chrono::seconds> youngest_peer{-1, 0}, next_youngest_peer{-1, 0};
m_connman.ForEachNode([&](CNode* pnode) {
if (!pnode->IsBlockOnlyConn() || pnode->fDisconnect) return;
if (pnode->GetId() > youngest_peer.first) {
next_youngest_peer = youngest_peer;
youngest_peer.first = pnode->GetId();
youngest_peer.second = pnode->m_last_block_time;
}
});
NodeId to_disconnect = youngest_peer.first;
if (youngest_peer.second > next_youngest_peer.second) {
// Our newest block-relay-only peer gave us a block more recently;
// disconnect our second youngest.
to_disconnect = next_youngest_peer.first;
}
m_connman.ForNode(to_disconnect, [&](CNode* pnode) EXCLUSIVE_LOCKS_REQUIRED(::cs_main) {
AssertLockHeld(::cs_main);
// Make sure we're not getting a block right now, and that
// we've been connected long enough for this eviction to happen
// at all.
// Note that we only request blocks from a peer if we learn of a
// valid headers chain with at least as much work as our tip.
CNodeState *node_state = State(pnode->GetId());
if (node_state == nullptr ||
(now - pnode->m_connected >= MINIMUM_CONNECT_TIME && node_state->nBlocksInFlight == 0)) {
pnode->fDisconnect = true;
LogPrint(BCLog::NET, "disconnecting extra block-relay-only peer=%d (last block received at time %d)\n",
pnode->GetId(), count_seconds(pnode->m_last_block_time));
return true;
} else {
LogPrint(BCLog::NET, "keeping block-relay-only peer=%d chosen for eviction (connect time: %d, blocks_in_flight: %d)\n",
pnode->GetId(), count_seconds(pnode->m_connected), node_state->nBlocksInFlight);
}
return false;
});
}
// Check whether we have too many outbound-full-relay peers
if (m_connman.GetExtraFullOutboundCount() > 0) {
// If we have more outbound-full-relay peers than we target, disconnect one.
// Pick the outbound-full-relay peer that least recently announced
// us a new block, with ties broken by choosing the more recent
// connection (higher node id)
NodeId worst_peer = -1;
int64_t oldest_block_announcement = std::numeric_limits<int64_t>::max();
// We want to prevent recently connected to Onion peers from being disconnected here, protect them as long as
// there are more non_onion nodes than onion nodes so far
size_t onion_count = 0;
m_connman.ForEachNode([&](CNode* pnode) {
LockAssertion lock(::cs_main);
if (pnode->addr.IsTor() && ++onion_count <= m_connman.GetMaxOutboundOnionNodeCount()) return;
// Don't disconnect masternodes just because they were slow in block announcement
if (pnode->m_masternode_connection) return;
// Only consider outbound-full-relay peers that are not already
// marked for disconnection
if (!pnode->IsFullOutboundConn() || pnode->fDisconnect) return;
CNodeState *state = State(pnode->GetId());
if (state == nullptr) return; // shouldn't be possible, but just in case
// Don't evict our protected peers
if (state->m_chain_sync.m_protect) return;
if (state->m_last_block_announcement < oldest_block_announcement || (state->m_last_block_announcement == oldest_block_announcement && pnode->GetId() > worst_peer)) {
worst_peer = pnode->GetId();
oldest_block_announcement = state->m_last_block_announcement;
}
});
if (worst_peer != -1) {
bool disconnected = m_connman.ForNode(worst_peer, [&](CNode *pnode) {
LockAssertion lock(::cs_main);
// Only disconnect a peer that has been connected to us for
// some reasonable fraction of our check-frequency, to give
// it time for new information to have arrived.
// Also don't disconnect any peer we're trying to download a
// block from.
CNodeState &state = *State(pnode->GetId());
if (now - pnode->m_connected > MINIMUM_CONNECT_TIME && state.nBlocksInFlight == 0) {
LogPrint(BCLog::NET, "disconnecting extra outbound peer=%d (last block announcement received at time %d)\n", pnode->GetId(), oldest_block_announcement);
pnode->fDisconnect = true;
return true;
} else {
LogPrint(BCLog::NET, "keeping outbound peer=%d chosen for eviction (connect time: %d, blocks_in_flight: %d)\n",
pnode->GetId(), count_seconds(pnode->m_connected), state.nBlocksInFlight);
return false;
}
});
if (disconnected) {
// If we disconnected an extra peer, that means we successfully
// connected to at least one peer after the last time we
// detected a stale tip. Don't try any more extra peers until
// we next detect a stale tip, to limit the load we put on the
// network from these extra connections.
m_connman.SetTryNewOutboundPeer(false);
}
}
}
}
void PeerManagerImpl::CheckForStaleTipAndEvictPeers()
{
LOCK(cs_main);
auto now{GetTime<std::chrono::seconds>()};
EvictExtraOutboundPeers(now);
if (now > m_stale_tip_check_time) {
// Check whether our tip is stale, and if so, allow using an extra
// outbound peer
if (!fImporting && !fReindex && m_connman.GetNetworkActive() && m_connman.GetUseAddrmanOutgoing() && TipMayBeStale()) {
LogPrintf("Potential stale tip detected, will try using extra outbound peer (last tip update: %d seconds ago)\n",
count_seconds(now - m_last_tip_update.load()));
m_connman.SetTryNewOutboundPeer(true);
} else if (m_connman.GetTryNewOutboundPeer()) {
m_connman.SetTryNewOutboundPeer(false);
}
m_stale_tip_check_time = now + STALE_CHECK_INTERVAL;
}
if (!m_initial_sync_finished && CanDirectFetch()) {
m_connman.StartExtraBlockRelayPeers();
m_initial_sync_finished = true;
}
}
void PeerManagerImpl::MaybeSendPing(CNode& node_to, Peer& peer, std::chrono::microseconds now)
{
if (m_connman.ShouldRunInactivityChecks(node_to, std::chrono::duration_cast<std::chrono::seconds>(now)) &&
peer.m_ping_nonce_sent &&
now > peer.m_ping_start.load() + TIMEOUT_INTERVAL)
{
// The ping timeout is using mocktime. To disable the check during
// testing, increase -peertimeout.
LogPrint(BCLog::NET, "ping timeout: %fs peer=%d\n", 0.000001 * count_microseconds(now - peer.m_ping_start.load()), peer.m_id);
node_to.fDisconnect = true;
return;
}
const CNetMsgMaker msgMaker(node_to.GetCommonVersion());
bool pingSend = false;
if (peer.m_ping_queued) {
// RPC ping request by user
pingSend = true;
}
if (peer.m_ping_nonce_sent == 0 && now > peer.m_ping_start.load() + PING_INTERVAL) {
// Ping automatically sent as a latency probe & keepalive.
pingSend = true;
}
if (pingSend) {
uint64_t nonce = 0;
while (nonce == 0) {
GetRandBytes({(unsigned char*)&nonce, sizeof(nonce)});
}
peer.m_ping_queued = false;
peer.m_ping_start = now;
peer.m_ping_nonce_sent = nonce;
m_connman.PushMessage(&node_to, msgMaker.Make(NetMsgType::PING, nonce));
}
}
void PeerManagerImpl::MaybeSendAddr(CNode& node, Peer& peer, std::chrono::microseconds current_time)
{
// Nothing to do for non-address-relay peers
if (!peer.m_addr_relay_enabled) return;
LOCK(peer.m_addr_send_times_mutex);
// Periodically advertise our local address to the peer.
if (fListen && !m_chainman.ActiveChainstate().IsInitialBlockDownload() &&
peer.m_next_local_addr_send < current_time) {
// If we've sent before, clear the bloom filter for the peer, so that our
// self-announcement will actually go out.
// This might be unnecessary if the bloom filter has already rolled
// over since our last self-announcement, but there is only a small
// bandwidth cost that we can incur by doing this (which happens
// once a day on average).
if (peer.m_next_local_addr_send != 0us) {
peer.m_addr_known->reset();
}
if (std::optional<CService> local_service = GetLocalAddrForPeer(node)) {
CAddress local_addr{*local_service, peer.m_our_services, (uint32_t)GetAdjustedTime()};
FastRandomContext insecure_rand;
PushAddress(peer, local_addr, insecure_rand);
}
peer.m_next_local_addr_send = PoissonNextSend(current_time, AVG_LOCAL_ADDRESS_BROADCAST_INTERVAL);
}
// We sent an `addr` message to this peer recently. Nothing more to do.
if (current_time <= peer.m_next_addr_send) return;
peer.m_next_addr_send = PoissonNextSend(current_time, AVG_ADDRESS_BROADCAST_INTERVAL);
if (!Assume(peer.m_addrs_to_send.size() <= MAX_ADDR_TO_SEND)) {
// Should be impossible since we always check size before adding to
// m_addrs_to_send. Recover by trimming the vector.
peer.m_addrs_to_send.resize(MAX_ADDR_TO_SEND);
}
// Remove addr records that the peer already knows about, and add new
// addrs to the m_addr_known filter on the same pass.
auto addr_already_known = [&peer](const CAddress& addr) {
bool ret = peer.m_addr_known->contains(addr.GetKey());
if (!ret) peer.m_addr_known->insert(addr.GetKey());
return ret;
};
peer.m_addrs_to_send.erase(std::remove_if(peer.m_addrs_to_send.begin(), peer.m_addrs_to_send.end(), addr_already_known),
peer.m_addrs_to_send.end());
// No addr messages to send
if (peer.m_addrs_to_send.empty()) return;
const char* msg_type;
int make_flags;
if (peer.m_wants_addrv2) {
msg_type = NetMsgType::ADDRV2;
make_flags = ADDRV2_FORMAT;
} else {
msg_type = NetMsgType::ADDR;
make_flags = 0;
}
m_connman.PushMessage(&node, CNetMsgMaker(node.GetCommonVersion()).Make(make_flags, msg_type, peer.m_addrs_to_send));
peer.m_addrs_to_send.clear();
// we only send the big addr message once
if (peer.m_addrs_to_send.capacity() > 40) {
peer.m_addrs_to_send.shrink_to_fit();
}
}
namespace {
class CompareInvMempoolOrder
{
CTxMemPool *mp;
public:
explicit CompareInvMempoolOrder(CTxMemPool *_mempool)
{
mp = _mempool;
}
bool operator()(std::set<uint256>::iterator a, std::set<uint256>::iterator b)
{
/* As std::make_heap produces a max-heap, we want the entries with the
* fewest ancestors/highest fee to sort later. */
return mp->CompareDepthAndScore(*b, *a);
}
};
}
bool PeerManagerImpl::SetupAddressRelay(const CNode& node, Peer& peer)
{
// We don't participate in addr relay with outbound block-relay-only
// connections to prevent providing adversaries with the additional
// information of addr traffic to infer the link.
if (node.IsBlockOnlyConn()) return false;
if (!peer.m_addr_relay_enabled.exchange(true)) {
// First addr message we have received from the peer, initialize
// m_addr_known
peer.m_addr_known = std::make_unique<CRollingBloomFilter>(5000, 0.001);
}
return true;
}
bool PeerManagerImpl::SendMessages(CNode* pto)
{
assert(m_llmq_ctx);
const bool is_masternode = m_mn_activeman != nullptr;
PeerRef peer = GetPeerRef(pto->GetId());
if (!peer) return false;
const Consensus::Params& consensusParams = m_chainparams.GetConsensus();
// We must call MaybeDiscourageAndDisconnect first, to ensure that we'll
// disconnect misbehaving peers even before the version handshake is complete.
if (MaybeDiscourageAndDisconnect(*pto, *peer)) return true;
// Don't send anything until the version handshake is complete
if (!pto->fSuccessfullyConnected || pto->fDisconnect)
return true;
// If we get here, the outgoing message serialization version is set and can't change.
const CNetMsgMaker msgMaker(pto->GetCommonVersion());
const auto current_time = GetTime<std::chrono::microseconds>();
if (pto->IsAddrFetchConn() && current_time - pto->m_connected > 10 * AVG_ADDRESS_BROADCAST_INTERVAL) {
LogPrint(BCLog::NET_NETCONN, "addrfetch connection timeout; disconnecting peer=%d\n", pto->GetId());
pto->fDisconnect = true;
return true;
}
MaybeSendPing(*pto, *peer, current_time);
// MaybeSendPing may have marked peer for disconnection
if (pto->fDisconnect) return true;
MaybeSendAddr(*pto, *peer, current_time);
{
LOCK(cs_main);
CNodeState &state = *State(pto->GetId());
// Start block sync
if (m_chainman.m_best_header == nullptr) {
m_chainman.m_best_header = m_chainman.ActiveChain().Tip();
}
// Determine whether we might try initial headers sync or parallel
// block download from this peer -- this mostly affects behavior while
// in IBD (once out of IBD, we sync from all peers).
bool sync_blocks_and_headers_from_peer = false;
if (state.fPreferredDownload) {
sync_blocks_and_headers_from_peer = true;
} else if (CanServeBlocks(*peer) && !pto->IsAddrFetchConn()) {
// Typically this is an inbound peer. If we don't have any outbound
// peers, or if we aren't downloading any blocks from such peers,
// then allow block downloads from this peer, too.
// We prefer downloading blocks from outbound peers to avoid
// putting undue load on (say) some home user who is just making
// outbound connections to the network, but if our only source of
// the latest blocks is from an inbound peer, we have to be sure to
// eventually download it (and not just wait indefinitely for an
// outbound peer to have it).
if (nPreferredDownload == 0 || mapBlocksInFlight.empty()) {
sync_blocks_and_headers_from_peer = true;
}
}
if (!state.fSyncStarted && CanServeBlocks(*peer) && !fImporting && !fReindex && pto->CanRelay()) {
// Only actively request headers from a single peer, unless we're close to end of initial download.
if ((nSyncStarted == 0 && sync_blocks_and_headers_from_peer) || m_chainman.m_best_header->GetBlockTime() > GetAdjustedTime() - nMaxTipAge) {
const CBlockIndex* pindexStart = m_chainman.m_best_header;
/* If possible, start at the block preceding the currently
best known header. This ensures that we always get a
non-empty list of headers back as long as the peer
is up-to-date. With a non-empty response, we can initialise
the peer's known best block. This wouldn't be possible
if we requested starting at m_chainman.m_best_header and
got back an empty response. */
if (pindexStart->pprev)
pindexStart = pindexStart->pprev;
std::string msg_type = UsesCompressedHeaders(*peer) ? NetMsgType::GETHEADERS2 : NetMsgType::GETHEADERS;
if (MaybeSendGetHeaders(*pto, msg_type, m_chainman.ActiveChain().GetLocator(pindexStart), *peer)) {
LogPrint(BCLog::NET, "initial %s (%d) to peer=%d (startheight:%d)\n", msg_type, pindexStart->nHeight, pto->GetId(), peer->m_starting_height);
state.fSyncStarted = true;
state.m_headers_sync_timeout = current_time + HEADERS_DOWNLOAD_TIMEOUT_BASE +
(
// Convert HEADERS_DOWNLOAD_TIMEOUT_PER_HEADER to microseconds before scaling
// to maintain precision
std::chrono::microseconds{HEADERS_DOWNLOAD_TIMEOUT_PER_HEADER} *
(GetAdjustedTime() - m_chainman.m_best_header->GetBlockTime()) / consensusParams.nPowTargetSpacing
);
nSyncStarted++;
}
}
}
//
// Try sending block announcements via headers
//
if (pto->CanRelay()) {
// If we have no more than MAX_BLOCKS_TO_ANNOUNCE in our
// list of block hashes we're relaying, and our peer wants
// headers announcements, then find the first header
// not yet known to our peer but would connect, and send.
// If no header would connect, or if we have too many
// blocks, or if the peer doesn't want headers, just
// add all to the inv queue.
LOCK(peer->m_block_inv_mutex);
std::vector<CBlock> vHeaders;
bool fRevertToInv = ((!state.fPreferHeaders && !state.fPreferHeadersCompressed &&
(!state.m_requested_hb_cmpctblocks || peer->m_blocks_for_headers_relay.size() > 1)) ||
peer->m_blocks_for_headers_relay.size() > MAX_BLOCKS_TO_ANNOUNCE);
const CBlockIndex *pBestIndex = nullptr; // last header queued for delivery
ProcessBlockAvailability(pto->GetId()); // ensure pindexBestKnownBlock is up-to-date
if (!fRevertToInv) {
bool fFoundStartingHeader = false;
// Try to find first header that our peer doesn't have, and
// then send all headers past that one. If we come across any
// headers that aren't on m_chainman.ActiveChain(), give up.
for (const uint256& hash : peer->m_blocks_for_headers_relay) {
const CBlockIndex* pindex = m_chainman.m_blockman.LookupBlockIndex(hash);
assert(pindex);
if (m_chainman.ActiveChain()[pindex->nHeight] != pindex) {
// Bail out if we reorged away from this block
fRevertToInv = true;
break;
}
if (pBestIndex != nullptr && pindex->pprev != pBestIndex) {
// This means that the list of blocks to announce don't
// connect to each other.
// This shouldn't really be possible to hit during
// regular operation (because reorgs should take us to
// a chain that has some block not on the prior chain,
// which should be caught by the prior check), but one
// way this could happen is by using invalidateblock /
// reconsiderblock repeatedly on the tip, causing it to
// be added multiple times to m_blocks_for_headers_relay.
// Robustly deal with this rare situation by reverting
// to an inv.
fRevertToInv = true;
break;
}
pBestIndex = pindex;
bool isPrevDevnetGenesisBlock = false;
if (!consensusParams.hashDevnetGenesisBlock.IsNull() &&
pindex->pprev != nullptr &&
pindex->pprev->GetBlockHash() == consensusParams.hashDevnetGenesisBlock) {
// even though the devnet genesis block was never transferred through the wire and thus not
// appear anywhere in the node state where we track what other nodes have or not have, we can
// assume that the other node already knows the devnet genesis block
isPrevDevnetGenesisBlock = true;
}
if (fFoundStartingHeader) {
// add this to the headers message
vHeaders.push_back(pindex->GetBlockHeader());
} else if (PeerHasHeader(&state, pindex)) {
continue; // keep looking for the first new block
} else if (pindex->pprev == nullptr || PeerHasHeader(&state, pindex->pprev) || isPrevDevnetGenesisBlock) {
// Peer doesn't have this header but they do have the prior one.
// Start sending headers.
fFoundStartingHeader = true;
vHeaders.push_back(pindex->GetBlockHeader());
} else {
// Peer doesn't have this header or the prior one -- nothing will
// connect, so bail out.
fRevertToInv = true;
break;
}
}
}
if (!fRevertToInv && !vHeaders.empty()) {
if (vHeaders.size() == 1 && state.m_requested_hb_cmpctblocks) {
// We only send up to 1 block as header-and-ids, as otherwise
// probably means we're doing an initial-ish-sync or they're slow
LogPrint(BCLog::NET, "%s sending header-and-ids %s to peer=%d\n", __func__,
vHeaders.front().GetHash().ToString(), pto->GetId());
bool fGotBlockFromCache = false;
{
LOCK(cs_most_recent_block);
if (most_recent_block_hash == pBestIndex->GetBlockHash()) {
m_connman.PushMessage(pto, msgMaker.Make(NetMsgType::CMPCTBLOCK, *most_recent_compact_block));
fGotBlockFromCache = true;
}
}
if (!fGotBlockFromCache) {
CBlock block;
bool ret = ReadBlockFromDisk(block, pBestIndex, consensusParams);
assert(ret);
CBlockHeaderAndShortTxIDs cmpctblock{block};
m_connman.PushMessage(pto, msgMaker.Make(NetMsgType::CMPCTBLOCK, cmpctblock));
}
state.pindexBestHeaderSent = pBestIndex;
} else if (state.fPreferHeadersCompressed) {
std::vector<CompressibleBlockHeader> vHeadersCompressed;
std::list<int32_t> last_unique_versions;
// Save other headers compressed
std::for_each(vHeaders.cbegin(), vHeaders.cend(), [&vHeadersCompressed, &last_unique_versions](const auto& block) {
CompressibleBlockHeader compressible_header{block.GetBlockHeader()};
compressible_header.Compress(vHeadersCompressed, last_unique_versions);
vHeadersCompressed.push_back(compressible_header);
});
// Push message to peer
m_connman.PushMessage(pto, msgMaker.Make(NetMsgType::HEADERS2, vHeadersCompressed));
state.pindexBestHeaderSent = pBestIndex;
} else if (state.fPreferHeaders) {
if (vHeaders.size() > 1) {
LogPrint(BCLog::NET, "%s: %u headers, range (%s, %s), to peer=%d\n", __func__,
vHeaders.size(),
vHeaders.front().GetHash().ToString(),
vHeaders.back().GetHash().ToString(), pto->GetId());
} else {
LogPrint(BCLog::NET, "%s: sending header %s to peer=%d\n", __func__,
vHeaders.front().GetHash().ToString(), pto->GetId());
}
m_connman.PushMessage(pto, msgMaker.Make(NetMsgType::HEADERS, vHeaders));
state.pindexBestHeaderSent = pBestIndex;
} else
fRevertToInv = true;
}
if (fRevertToInv) {
// If falling back to using an inv, just try to inv the tip.
// The last entry in m_blocks_for_headers_relay was our tip at some point
// in the past.
if (!peer->m_blocks_for_headers_relay.empty()) {
const uint256& hashToAnnounce = peer->m_blocks_for_headers_relay.back();
const CBlockIndex* pindex = m_chainman.m_blockman.LookupBlockIndex(hashToAnnounce);
assert(pindex);
// Warn if we're announcing a block that is not on the main chain.
// This should be very rare and could be optimized out.
// Just log for now.
if (m_chainman.ActiveChain()[pindex->nHeight] != pindex) {
LogPrint(BCLog::NET, "Announcing block %s not on main chain (tip=%s)\n",
hashToAnnounce.ToString(), m_chainman.ActiveChain().Tip()->GetBlockHash().ToString());
}
// If the peer's chain has this block, don't inv it back.
if (!PeerHasHeader(&state, pindex)) {
peer->m_blocks_for_inv_relay.push_back(hashToAnnounce);
LogPrint(BCLog::NET, "%s: sending inv peer=%d hash=%s\n", __func__,
pto->GetId(), hashToAnnounce.ToString());
}
}
}
peer->m_blocks_for_headers_relay.clear();
}
//
// Message: inventory
//
std::vector<CInv> vInv;
{
LOCK(peer->m_block_inv_mutex);
size_t reserve = INVENTORY_BROADCAST_MAX_PER_1MB_BLOCK * MaxBlockSize() / 1000000;
if (!pto->IsBlockOnlyConn()) {
LOCK(peer->m_tx_relay->m_tx_inventory_mutex);
reserve = std::min<size_t>(peer->m_tx_relay->m_tx_inventory_to_send.size(), reserve);
}
reserve = std::max<size_t>(reserve, peer->m_blocks_for_inv_relay.size());
reserve = std::min<size_t>(reserve, MAX_INV_SZ);
vInv.reserve(reserve);
// Add blocks
for (const uint256& hash : peer->m_blocks_for_inv_relay) {
vInv.push_back(CInv(MSG_BLOCK, hash));
if (vInv.size() == MAX_INV_SZ) {
m_connman.PushMessage(pto, msgMaker.Make(NetMsgType::INV, vInv));
vInv.clear();
}
}
peer->m_blocks_for_inv_relay.clear();
}
auto queueAndMaybePushInv = [this, pto, peer, &vInv, &msgMaker](const CInv& invIn) {
AssertLockHeld(peer->m_tx_relay->m_tx_inventory_mutex);
peer->m_tx_relay->m_tx_inventory_known_filter.insert(invIn.hash);
LogPrint(BCLog::NET, "SendMessages -- queued inv: %s index=%d peer=%d\n", invIn.ToString(), vInv.size(), pto->GetId());
// Responses to MEMPOOL requests bypass the m_recently_announced_invs filter.
vInv.push_back(invIn);
if (vInv.size() == MAX_INV_SZ) {
LogPrint(BCLog::NET, "SendMessages -- pushing invs: count=%d peer=%d\n", vInv.size(), pto->GetId());
m_connman.PushMessage(pto, msgMaker.Make(NetMsgType::INV, vInv));
vInv.clear();
}
};
if (!pto->IsBlockOnlyConn()) {
LOCK(peer->m_tx_relay->m_tx_inventory_mutex);
// Check whether periodic sends should happen
// Note: If this node is running in a Masternode mode, it makes no sense to delay outgoing txes
// because we never produce any txes ourselves i.e. no privacy is lost in this case.
bool fSendTrickle = pto->HasPermission(NetPermissionFlags::NoBan) || is_masternode;
if (peer->m_tx_relay->m_next_inv_send_time < current_time) {
fSendTrickle = true;
if (pto->IsInboundConn()) {
peer->m_tx_relay->m_next_inv_send_time = m_connman.PoissonNextSendInbound(current_time, INBOUND_INVENTORY_BROADCAST_INTERVAL);
} else {
// Use half the delay for Masternode outbound peers, as there is less privacy concern for them.
peer->m_tx_relay->m_next_inv_send_time = pto->GetVerifiedProRegTxHash().IsNull() ?
PoissonNextSend(current_time, OUTBOUND_INVENTORY_BROADCAST_INTERVAL) :
PoissonNextSend(current_time, OUTBOUND_INVENTORY_BROADCAST_INTERVAL / 2);
}
}
// Time to send but the peer has requested we not relay transactions.
if (fSendTrickle) {
LOCK(peer->m_tx_relay->m_bloom_filter_mutex);
if (!peer->m_tx_relay->m_relay_txs) peer->m_tx_relay->m_tx_inventory_to_send.clear();
}
// Respond to BIP35 mempool requests
if (fSendTrickle && peer->m_tx_relay->m_send_mempool) {
auto vtxinfo = m_mempool.infoAll();
peer->m_tx_relay->m_send_mempool = false;
LOCK(peer->m_tx_relay->m_bloom_filter_mutex);
// Send invs for txes and corresponding IS-locks
for (const auto& txinfo : vtxinfo) {
const uint256& hash = txinfo.tx->GetHash();
peer->m_tx_relay->m_tx_inventory_to_send.erase(hash);
if (peer->m_tx_relay->m_bloom_filter && !peer->m_tx_relay->m_bloom_filter->IsRelevantAndUpdate(*txinfo.tx)) continue;
int nInvType = m_cj_ctx->dstxman->GetDSTX(hash) ? MSG_DSTX : MSG_TX;
queueAndMaybePushInv(CInv(nInvType, hash));
const auto islock = m_llmq_ctx->isman->GetInstantSendLockByTxid(hash);
if (islock == nullptr) continue;
if (pto->nVersion < ISDLOCK_PROTO_VERSION) continue;
queueAndMaybePushInv(CInv(MSG_ISDLOCK, ::SerializeHash(*islock)));
}
// Send an inv for the best ChainLock we have
const auto& clsig = m_llmq_ctx->clhandler->GetBestChainLock();
if (!clsig.IsNull()) {
uint256 chainlockHash = ::SerializeHash(clsig);
queueAndMaybePushInv(CInv(MSG_CLSIG, chainlockHash));
}
peer->m_tx_relay->m_last_mempool_req = std::chrono::duration_cast<std::chrono::seconds>(current_time);
}
// Determine transactions to relay
if (fSendTrickle) {
LOCK(peer->m_tx_relay->m_bloom_filter_mutex);
// Produce a vector with all candidates for sending
std::vector<std::set<uint256>::iterator> vInvTx;
vInvTx.reserve(peer->m_tx_relay->m_tx_inventory_to_send.size());
for (std::set<uint256>::iterator it = peer->m_tx_relay->m_tx_inventory_to_send.begin(); it != peer->m_tx_relay->m_tx_inventory_to_send.end(); it++) {
vInvTx.push_back(it);
}
// Topologically and fee-rate sort the inventory we send for privacy and priority reasons.
// A heap is used so that not all items need sorting if only a few are being sent.
CompareInvMempoolOrder compareInvMempoolOrder(&m_mempool);
std::make_heap(vInvTx.begin(), vInvTx.end(), compareInvMempoolOrder);
// No reason to drain out at many times the network's capacity,
// especially since we have many peers and some will draw much shorter delays.
unsigned int nRelayedTransactions = 0;
size_t broadcast_max{INVENTORY_BROADCAST_MAX_PER_1MB_BLOCK * MaxBlockSize() / 1000000 + (peer->m_tx_relay->m_tx_inventory_to_send.size()/1000)*5};
broadcast_max = std::min<size_t>(1000, broadcast_max);
while (!vInvTx.empty() && nRelayedTransactions < broadcast_max) {
// Fetch the top element from the heap
std::pop_heap(vInvTx.begin(), vInvTx.end(), compareInvMempoolOrder);
std::set<uint256>::iterator it = vInvTx.back();
vInvTx.pop_back();
uint256 hash = *it;
// Remove it from the to-be-sent set
peer->m_tx_relay->m_tx_inventory_to_send.erase(it);
// Check if not in the filter already
if (peer->m_tx_relay->m_tx_inventory_known_filter.contains(hash)) {
continue;
}
// Not in the mempool anymore? don't bother sending it.
auto txinfo = m_mempool.info(hash);
if (!txinfo.tx) {
continue;
}
if (peer->m_tx_relay->m_bloom_filter && !peer->m_tx_relay->m_bloom_filter->IsRelevantAndUpdate(*txinfo.tx)) continue;
// Send
State(pto->GetId())->m_recently_announced_invs.insert(hash);
nRelayedTransactions++;
{
// Expire old relay messages
while (!g_relay_expiration.empty() && g_relay_expiration.front().first < current_time)
{
mapRelay.erase(g_relay_expiration.front().second);
g_relay_expiration.pop_front();
}
auto ret = mapRelay.emplace(hash, std::move(txinfo.tx));
if (ret.second) {
g_relay_expiration.emplace_back(current_time + RELAY_TX_CACHE_TIME, ret.first);
}
}
int nInvType = m_cj_ctx->dstxman->GetDSTX(hash) ? MSG_DSTX : MSG_TX;
queueAndMaybePushInv(CInv(nInvType, hash));
}
}
}
{
// Send non-tx/non-block inventory items
LOCK2(peer->m_tx_relay->m_tx_inventory_mutex, peer->m_tx_relay->m_bloom_filter_mutex);
bool fSendIS = peer->m_tx_relay->m_relay_txs && !pto->IsBlockRelayOnly();
for (const auto& inv : peer->m_tx_relay->vInventoryOtherToSend) {
if (!peer->m_tx_relay->m_relay_txs && NetMessageViolatesBlocksOnly(inv.GetCommand())) {
continue;
}
if (peer->m_tx_relay->m_tx_inventory_known_filter.contains(inv.hash)) {
continue;
}
if (!fSendIS && inv.type == MSG_ISDLOCK) {
continue;
}
queueAndMaybePushInv(inv);
}
peer->m_tx_relay->vInventoryOtherToSend.clear();
}
if (!vInv.empty())
m_connman.PushMessage(pto, msgMaker.Make(NetMsgType::INV, vInv));
// Detect whether we're stalling
if (state.m_stalling_since.count() && state.m_stalling_since < current_time - BLOCK_STALLING_TIMEOUT) {
// Stalling only triggers when the block download window cannot move. During normal steady state,
// the download window should be much larger than the to-be-downloaded set of blocks, so disconnection
// should only happen during initial block download.
LogPrintf("Peer=%d is stalling block download, disconnecting\n", pto->GetId());
pto->fDisconnect = true;
return true;
}
// In case there is a block that has been in flight from this peer for block_interval * (1 + 0.5 * N)
// (with N the number of peers from which we're downloading validated blocks), disconnect due to timeout.
// We compensate for other peers to prevent killing off peers due to our own downstream link
// being saturated. We only count validated in-flight blocks so peers can't advertise non-existing block hashes
// to unreasonably increase our timeout.
if (state.vBlocksInFlight.size() > 0) {
QueuedBlock &queuedBlock = state.vBlocksInFlight.front();
int nOtherPeersWithValidatedDownloads = nPeersWithValidatedDownloads - (state.nBlocksInFlightValidHeaders > 0);
if (current_time > state.m_downloading_since + std::chrono::seconds{consensusParams.nPowTargetSpacing} * (BLOCK_DOWNLOAD_TIMEOUT_BASE + BLOCK_DOWNLOAD_TIMEOUT_PER_PEER * nOtherPeersWithValidatedDownloads)) {
LogPrintf("Timeout downloading block %s from peer=%d, disconnecting\n", queuedBlock.hash.ToString(), pto->GetId());
pto->fDisconnect = true;
return true;
}
}
// Check for headers sync timeouts
if (state.fSyncStarted && state.m_headers_sync_timeout < std::chrono::microseconds::max()) {
// Detect whether this is a stalling initial-headers-sync peer
if (m_chainman.m_best_header->GetBlockTime() <= GetAdjustedTime() - nMaxTipAge) {
if (current_time > state.m_headers_sync_timeout && nSyncStarted == 1 && (nPreferredDownload - state.fPreferredDownload >= 1)) {
// Disconnect a peer (without NetPermissionFlags::NoBan permission) if it is our only sync peer,
// and we have others we could be using instead.
// Note: If all our peers are inbound, then we won't
// disconnect our sync peer for stalling; we have bigger
// problems if we can't get any outbound peers.
if (!pto->HasPermission(NetPermissionFlags::NoBan)) {
LogPrintf("Timeout downloading headers from peer=%d, disconnecting\n", pto->GetId());
pto->fDisconnect = true;
return true;
} else {
LogPrintf("Timeout downloading headers from noban peer=%d, not disconnecting\n", pto->GetId());
// Reset the headers sync state so that we have a
// chance to try downloading from a different peer.
// Note: this will also result in at least one more
// getheaders message to be sent to
// this peer (eventually).
state.fSyncStarted = false;
nSyncStarted--;
state.m_headers_sync_timeout = 0us;
}
}
} else {
// After we've caught up once, reset the timeout so we can't trigger
// disconnect later.
state.m_headers_sync_timeout = std::chrono::microseconds::max();
}
}
// Check that outbound peers have reasonable chains
// GetTime() is used by this anti-DoS logic so we can test this using mocktime
ConsiderEviction(*pto, *peer, GetTime<std::chrono::seconds>());
//
// Message: getdata (blocks)
//
std::vector<CInv> vGetData;
if (CanServeBlocks(*peer) && pto->CanRelay() && ((sync_blocks_and_headers_from_peer && !IsLimitedPeer(*peer)) || !m_chainman.ActiveChainstate().IsInitialBlockDownload()) && state.nBlocksInFlight < MAX_BLOCKS_IN_TRANSIT_PER_PEER) {
std::vector<const CBlockIndex*> vToDownload;
NodeId staller = -1;
FindNextBlocksToDownload(*peer, MAX_BLOCKS_IN_TRANSIT_PER_PEER - state.nBlocksInFlight, vToDownload, staller);
for (const CBlockIndex *pindex : vToDownload) {
vGetData.push_back(CInv(MSG_BLOCK, pindex->GetBlockHash()));
MarkBlockAsInFlight(pto->GetId(), pindex->GetBlockHash(), pindex);
LogPrint(BCLog::NET, "Requesting block %s (%d) peer=%d\n", pindex->GetBlockHash().ToString(),
pindex->nHeight, pto->GetId());
}
if (state.nBlocksInFlight == 0 && staller != -1) {
if (State(staller)->m_stalling_since == 0us) {
State(staller)->m_stalling_since = current_time;
LogPrint(BCLog::NET, "Stall started peer=%d\n", staller);
}
}
}
//
// Message: getdata (non-blocks)
//
// For robustness, expire old requests after a long timeout, so that
// we can resume downloading objects from a peer even if they
// were unresponsive in the past.
// Eventually we should consider disconnecting peers, but this is
// conservative.
if (state.m_object_download.m_check_expiry_timer <= current_time) {
for (auto it=state.m_object_download.m_object_in_flight.begin(); it != state.m_object_download.m_object_in_flight.end();) {
if (it->second <= current_time - GetObjectExpiryInterval(it->first.type)) {
LogPrint(BCLog::NET, "timeout of inflight object %s from peer=%d\n", it->first.ToString(), pto->GetId());
state.m_object_download.m_object_announced.erase(it->first);
state.m_object_download.m_object_in_flight.erase(it++);
} else {
++it;
}
}
// On average, we do this check every GetObjectExpiryInterval. Randomize
// so that we're not doing this for all peers at the same time.
state.m_object_download.m_check_expiry_timer = current_time + GetObjectExpiryInterval(MSG_TX)/2 + GetRandMicros(GetObjectExpiryInterval(MSG_TX));
}
// DASH this code also handles non-TXs (Dash specific messages)
auto& object_process_time = state.m_object_download.m_object_process_time;
while (!object_process_time.empty() && object_process_time.begin()->first <= current_time && state.m_object_download.m_object_in_flight.size() < MAX_PEER_OBJECT_IN_FLIGHT) {
const CInv inv = object_process_time.begin()->second;
// Erase this entry from object_process_time (it may be added back for
// processing at a later time, see below)
object_process_time.erase(object_process_time.begin());
if (g_erased_object_requests.count(inv.hash)) {
LogPrint(BCLog::NET, "%s -- GETDATA skipping inv=(%s), peer=%d\n", __func__, inv.ToString(), pto->GetId());
state.m_object_download.m_object_announced.erase(inv);
state.m_object_download.m_object_in_flight.erase(inv);
continue;
}
if (!AlreadyHave(inv)) {
// If this object was last requested more than GetObjectInterval ago,
// then request.
const auto last_request_time = GetObjectRequestTime(inv);
if (last_request_time <= current_time - GetObjectInterval(inv.type)) {
LogPrint(BCLog::NET, "Requesting %s peer=%d\n", inv.ToString(), pto->GetId());
vGetData.push_back(inv);
if (vGetData.size() >= MAX_GETDATA_SZ) {
m_connman.PushMessage(pto, msgMaker.Make(NetMsgType::GETDATA, vGetData));
vGetData.clear();
}
UpdateObjectRequestTime(inv, current_time);
state.m_object_download.m_object_in_flight.emplace(inv, current_time);
} else {
// This object is in flight from someone else; queue
// up processing to happen after the download times out
// (with a slight delay for inbound peers, to prefer
// requests to outbound peers).
const auto next_process_time = CalculateObjectGetDataTime(inv, current_time, is_masternode, !state.fPreferredDownload);
object_process_time.emplace(next_process_time, inv);
LogPrint(BCLog::NET, "%s -- GETDATA re-queue inv=(%s), next_process_time=%d, delta=%d, peer=%d\n", __func__, inv.ToString(), next_process_time.count(), (next_process_time - current_time).count(), pto->GetId());
}
} else {
// We have already seen this object, no need to download.
state.m_object_download.m_object_announced.erase(inv);
state.m_object_download.m_object_in_flight.erase(inv);
LogPrint(BCLog::NET, "%s -- GETDATA already seen inv=(%s), peer=%d\n", __func__, inv.ToString(), pto->GetId());
}
}
if (!vGetData.empty()) {
m_connman.PushMessage(pto, msgMaker.Make(NetMsgType::GETDATA, vGetData));
LogPrint(BCLog::NET, "SendMessages -- GETDATA -- pushed size = %lu peer=%d\n", vGetData.size(), pto->GetId());
}
} // release cs_main
return true;
}
class CNetProcessingCleanup
{
public:
CNetProcessingCleanup() {}
~CNetProcessingCleanup() {
// orphan transactions
mapOrphanTransactions.clear();
mapOrphanTransactionsByPrev.clear();
nMapOrphanTransactionsSize = 0;
}
};
static CNetProcessingCleanup instance_of_cnetprocessingcleanup;
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