status-go/vendor/github.com/libp2p/go-libp2p-pubsub/peer_gater.go

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package pubsub
import (
"context"
"fmt"
"math/rand"
"sort"
"sync"
"time"
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"github.com/libp2p/go-libp2p/core/host"
"github.com/libp2p/go-libp2p/core/network"
"github.com/libp2p/go-libp2p/core/peer"
"github.com/libp2p/go-libp2p/core/protocol"
manet "github.com/multiformats/go-multiaddr/net"
)
var (
DefaultPeerGaterRetainStats = 6 * time.Hour
DefaultPeerGaterQuiet = time.Minute
DefaultPeerGaterDuplicateWeight = 0.125
DefaultPeerGaterIgnoreWeight = 1.0
DefaultPeerGaterRejectWeight = 16.0
DefaultPeerGaterThreshold = 0.33
DefaultPeerGaterGlobalDecay = ScoreParameterDecay(2 * time.Minute)
DefaultPeerGaterSourceDecay = ScoreParameterDecay(time.Hour)
)
// PeerGaterParams groups together parameters that control the operation of the peer gater
type PeerGaterParams struct {
// when the ratio of throttled/validated messages exceeds this threshold, the gater turns on
Threshold float64
// (linear) decay parameter for gater counters
GlobalDecay float64 // global counter decay
SourceDecay float64 // per IP counter decay
// decay interval
DecayInterval time.Duration
// counter zeroing threshold
DecayToZero float64
// how long to retain stats
RetainStats time.Duration
// quiet interval before turning off the gater; if there are no validation throttle events
// for this interval, the gater turns off
Quiet time.Duration
// weight of duplicate message deliveries
DuplicateWeight float64
// weight of ignored messages
IgnoreWeight float64
// weight of rejected messages
RejectWeight float64
// priority topic delivery weights
TopicDeliveryWeights map[string]float64
}
func (p *PeerGaterParams) validate() error {
if p.Threshold <= 0 {
return fmt.Errorf("invalid Threshold; must be > 0")
}
if p.GlobalDecay <= 0 || p.GlobalDecay >= 1 {
return fmt.Errorf("invalid GlobalDecay; must be between 0 and 1")
}
if p.SourceDecay <= 0 || p.SourceDecay >= 1 {
return fmt.Errorf("invalid SourceDecay; must be between 0 and 1")
}
if p.DecayInterval < time.Second {
return fmt.Errorf("invalid DecayInterval; must be at least 1s")
}
if p.DecayToZero <= 0 || p.DecayToZero >= 1 {
return fmt.Errorf("invalid DecayToZero; must be between 0 and 1")
}
// no need to check stats retention; a value of 0 means we don't retain stats
if p.Quiet < time.Second {
return fmt.Errorf("invalud Quiet interval; must be at least 1s")
}
if p.DuplicateWeight <= 0 {
return fmt.Errorf("invalid DuplicateWeight; must be > 0")
}
if p.IgnoreWeight < 1 {
return fmt.Errorf("invalid IgnoreWeight; must be >= 1")
}
if p.RejectWeight < 1 {
return fmt.Errorf("invalud RejectWeight; must be >= 1")
}
return nil
}
// WithTopicDeliveryWeights is a fluid setter for the priority topic delivery weights
func (p *PeerGaterParams) WithTopicDeliveryWeights(w map[string]float64) *PeerGaterParams {
p.TopicDeliveryWeights = w
return p
}
// NewPeerGaterParams creates a new PeerGaterParams struct, using the specified threshold and decay
// parameters and default values for all other parameters.
func NewPeerGaterParams(threshold, globalDecay, sourceDecay float64) *PeerGaterParams {
return &PeerGaterParams{
Threshold: threshold,
GlobalDecay: globalDecay,
SourceDecay: sourceDecay,
DecayToZero: DefaultDecayToZero,
DecayInterval: DefaultDecayInterval,
RetainStats: DefaultPeerGaterRetainStats,
Quiet: DefaultPeerGaterQuiet,
DuplicateWeight: DefaultPeerGaterDuplicateWeight,
IgnoreWeight: DefaultPeerGaterIgnoreWeight,
RejectWeight: DefaultPeerGaterRejectWeight,
}
}
// DefaultPeerGaterParams creates a new PeerGaterParams struct using default values
func DefaultPeerGaterParams() *PeerGaterParams {
return NewPeerGaterParams(DefaultPeerGaterThreshold, DefaultPeerGaterGlobalDecay, DefaultPeerGaterSourceDecay)
}
// the gater object.
type peerGater struct {
sync.Mutex
host host.Host
// gater parameters
params *PeerGaterParams
// counters
validate, throttle float64
// time of last validation throttle
lastThrottle time.Time
// stats per peer.ID -- multiple peer IDs may share the same stats object if they are
// colocated in the same IP
peerStats map[peer.ID]*peerGaterStats
// stats per IP
ipStats map[string]*peerGaterStats
// for unit tests
getIP func(peer.ID) string
}
type peerGaterStats struct {
// number of connected peer IDs mapped to this stat object
connected int
// stats expiration time -- only valid if connected = 0
expire time.Time
// counters
deliver, duplicate, ignore, reject float64
}
// WithPeerGater is a gossipsub router option that enables reactive validation queue
// management.
// The Gater is activated if the ratio of throttled/validated messages exceeds the specified
// threshold.
// Once active, the Gater probabilistically throttles peers _before_ they enter the validation
// queue, performing Random Early Drop.
// The throttle decision is randomized, with the probability of allowing messages to enter the
// validation queue controlled by the statistical observations of the performance of all peers
// in the IP address of the gated peer.
// The Gater deactivates if there is no validation throttlinc occurring for the specified quiet
// interval.
func WithPeerGater(params *PeerGaterParams) Option {
return func(ps *PubSub) error {
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gs, ok := ps.rt.(*GossipSubRouter)
if !ok {
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return fmt.Errorf("pubsub router is not gossipsub")
}
err := params.validate()
if err != nil {
return err
}
gs.gate = newPeerGater(ps.ctx, ps.host, params)
// hook the tracer
if ps.tracer != nil {
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ps.tracer.raw = append(ps.tracer.raw, gs.gate)
} else {
ps.tracer = &pubsubTracer{
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raw: []RawTracer{gs.gate},
pid: ps.host.ID(),
idGen: ps.idGen,
}
}
return nil
}
}
func newPeerGater(ctx context.Context, host host.Host, params *PeerGaterParams) *peerGater {
pg := &peerGater{
params: params,
peerStats: make(map[peer.ID]*peerGaterStats),
ipStats: make(map[string]*peerGaterStats),
host: host,
}
go pg.background(ctx)
return pg
}
func (pg *peerGater) background(ctx context.Context) {
tick := time.NewTicker(pg.params.DecayInterval)
defer tick.Stop()
for {
select {
case <-tick.C:
pg.decayStats()
case <-ctx.Done():
return
}
}
}
func (pg *peerGater) decayStats() {
pg.Lock()
defer pg.Unlock()
pg.validate *= pg.params.GlobalDecay
if pg.validate < pg.params.DecayToZero {
pg.validate = 0
}
pg.throttle *= pg.params.GlobalDecay
if pg.throttle < pg.params.DecayToZero {
pg.throttle = 0
}
now := time.Now()
for ip, st := range pg.ipStats {
if st.connected > 0 {
st.deliver *= pg.params.SourceDecay
if st.deliver < pg.params.DecayToZero {
st.deliver = 0
}
st.duplicate *= pg.params.SourceDecay
if st.duplicate < pg.params.DecayToZero {
st.duplicate = 0
}
st.ignore *= pg.params.SourceDecay
if st.ignore < pg.params.DecayToZero {
st.ignore = 0
}
st.reject *= pg.params.SourceDecay
if st.reject < pg.params.DecayToZero {
st.reject = 0
}
} else if st.expire.Before(now) {
delete(pg.ipStats, ip)
}
}
}
func (pg *peerGater) getPeerStats(p peer.ID) *peerGaterStats {
st, ok := pg.peerStats[p]
if !ok {
st = pg.getIPStats(p)
pg.peerStats[p] = st
}
return st
}
func (pg *peerGater) getIPStats(p peer.ID) *peerGaterStats {
ip := pg.getPeerIP(p)
st, ok := pg.ipStats[ip]
if !ok {
st = &peerGaterStats{}
pg.ipStats[ip] = st
}
return st
}
func (pg *peerGater) getPeerIP(p peer.ID) string {
if pg.getIP != nil {
return pg.getIP(p)
}
connToIP := func(c network.Conn) string {
remote := c.RemoteMultiaddr()
ip, err := manet.ToIP(remote)
if err != nil {
log.Warnf("error determining IP for remote peer in %s: %s", remote, err)
return "<unknown>"
}
return ip.String()
}
conns := pg.host.Network().ConnsToPeer(p)
switch len(conns) {
case 0:
return "<unknown>"
case 1:
return connToIP(conns[0])
default:
// we have multiple connections -- order by number of streams and use the one with the
// most streams; it's a nightmare to track multiple IPs per peer, so pick the best one.
streams := make(map[string]int)
for _, c := range conns {
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if c.Stat().Limited {
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// ignore transient
continue
}
streams[c.ID()] = len(c.GetStreams())
}
sort.Slice(conns, func(i, j int) bool {
return streams[conns[i].ID()] > streams[conns[j].ID()]
})
return connToIP(conns[0])
}
}
// router interface
func (pg *peerGater) AcceptFrom(p peer.ID) AcceptStatus {
if pg == nil {
return AcceptAll
}
pg.Lock()
defer pg.Unlock()
// check the quiet period; if the validation queue has not throttled for more than the Quiet
// interval, we turn off the circuit breaker and accept.
if time.Since(pg.lastThrottle) > pg.params.Quiet {
return AcceptAll
}
// no throttle events -- or they have decayed; accept.
if pg.throttle == 0 {
return AcceptAll
}
// check the throttle/validate ration; if it is below threshold we accept.
if pg.validate != 0 && pg.throttle/pg.validate < pg.params.Threshold {
return AcceptAll
}
st := pg.getPeerStats(p)
// compute the goodput of the peer; the denominator is the weighted mix of message counters
total := st.deliver + pg.params.DuplicateWeight*st.duplicate + pg.params.IgnoreWeight*st.ignore + pg.params.RejectWeight*st.reject
if total == 0 {
return AcceptAll
}
// we make a randomized decision based on the goodput of the peer.
// the probabiity is biased by adding 1 to the delivery counter so that we don't unconditionally
// throttle in the first negative event; it also ensures that a peer always has a chance of being
// accepted; this is not a sinkhole/blacklist.
threshold := (1 + st.deliver) / (1 + total)
if rand.Float64() < threshold {
return AcceptAll
}
log.Debugf("throttling peer %s with threshold %f", p, threshold)
return AcceptControl
}
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// -- RawTracer interface methods
var _ RawTracer = (*peerGater)(nil)
// tracer interface
func (pg *peerGater) AddPeer(p peer.ID, proto protocol.ID) {
pg.Lock()
defer pg.Unlock()
st := pg.getPeerStats(p)
st.connected++
}
func (pg *peerGater) RemovePeer(p peer.ID) {
pg.Lock()
defer pg.Unlock()
st := pg.getPeerStats(p)
st.connected--
st.expire = time.Now().Add(pg.params.RetainStats)
delete(pg.peerStats, p)
}
func (pg *peerGater) Join(topic string) {}
func (pg *peerGater) Leave(topic string) {}
func (pg *peerGater) Graft(p peer.ID, topic string) {}
func (pg *peerGater) Prune(p peer.ID, topic string) {}
func (pg *peerGater) ValidateMessage(msg *Message) {
pg.Lock()
defer pg.Unlock()
pg.validate++
}
func (pg *peerGater) DeliverMessage(msg *Message) {
pg.Lock()
defer pg.Unlock()
st := pg.getPeerStats(msg.ReceivedFrom)
topic := msg.GetTopic()
weight := pg.params.TopicDeliveryWeights[topic]
if weight == 0 {
weight = 1
}
st.deliver += weight
}
func (pg *peerGater) RejectMessage(msg *Message, reason string) {
pg.Lock()
defer pg.Unlock()
switch reason {
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case RejectValidationQueueFull:
fallthrough
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case RejectValidationThrottled:
pg.lastThrottle = time.Now()
pg.throttle++
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case RejectValidationIgnored:
st := pg.getPeerStats(msg.ReceivedFrom)
st.ignore++
default:
st := pg.getPeerStats(msg.ReceivedFrom)
st.reject++
}
}
func (pg *peerGater) DuplicateMessage(msg *Message) {
pg.Lock()
defer pg.Unlock()
st := pg.getPeerStats(msg.ReceivedFrom)
st.duplicate++
}
func (pg *peerGater) ThrottlePeer(p peer.ID) {}
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func (pg *peerGater) RecvRPC(rpc *RPC) {}
func (pg *peerGater) SendRPC(rpc *RPC, p peer.ID) {}
func (pg *peerGater) DropRPC(rpc *RPC, p peer.ID) {}
func (pg *peerGater) UndeliverableMessage(msg *Message) {}