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table.go
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table.go
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// package kbucket implements a kademlia 'k-bucket' routing table.
package kbucket
import (
"errors"
"fmt"
"sort"
"sync"
"time"
logging "github.com/ipfs/go-log"
peer "github.com/libp2p/go-libp2p-peer"
pstore "github.com/libp2p/go-libp2p-peerstore"
)
var log = logging.Logger("table")
var ErrPeerRejectedHighLatency = errors.New("peer rejected; latency too high")
var ErrPeerRejectedNoCapacity = errors.New("peer rejected; insufficient capacity")
// RoutingTable defines the routing table.
type RoutingTable struct {
// ID of the local peer
local ID
// Blanket lock, refine later for better performance
tabLock sync.RWMutex
// latency metrics
metrics pstore.Metrics
// Maximum acceptable latency for peers in this cluster
maxLatency time.Duration
// kBuckets define all the fingers to other nodes.
Buckets []*Bucket
bucketsize int
// notification functions
PeerRemoved func(peer.ID)
PeerAdded func(peer.ID)
}
// NewRoutingTable creates a new routing table with a given bucketsize, local ID, and latency tolerance.
func NewRoutingTable(bucketsize int, localID ID, latency time.Duration, m pstore.Metrics) *RoutingTable {
rt := &RoutingTable{
Buckets: []*Bucket{newBucket()},
bucketsize: bucketsize,
local: localID,
maxLatency: latency,
metrics: m,
PeerRemoved: func(peer.ID) {},
PeerAdded: func(peer.ID) {},
}
return rt
}
// Update adds or moves the given peer to the front of its respective bucket
func (rt *RoutingTable) Update(p peer.ID) (evicted peer.ID, err error) {
peerID := ConvertPeerID(p)
cpl := commonPrefixLen(peerID, rt.local)
rt.tabLock.Lock()
defer rt.tabLock.Unlock()
bucketID := cpl
if bucketID >= len(rt.Buckets) {
bucketID = len(rt.Buckets) - 1
}
bucket := rt.Buckets[bucketID]
if bucket.Has(p) {
// If the peer is already in the table, move it to the front.
// This signifies that it it "more active" and the less active nodes
// Will as a result tend towards the back of the list
bucket.MoveToFront(p)
return "", nil
}
if rt.metrics.LatencyEWMA(p) > rt.maxLatency {
// Connection doesnt meet requirements, skip!
return "", ErrPeerRejectedHighLatency
}
// We have enough space in the bucket (whether spawned or grouped).
if bucket.Len() < rt.bucketsize {
bucket.PushFront(p)
rt.PeerAdded(p)
return "", nil
}
if bucketID == len(rt.Buckets)-1 {
// if the bucket is too large and this is the last bucket (i.e. wildcard), unfold it.
rt.nextBucket()
// the structure of the table has changed, so let's recheck if the peer now has a dedicated bucket.
bucketID = cpl
if bucketID >= len(rt.Buckets) {
bucketID = len(rt.Buckets) - 1
}
bucket = rt.Buckets[bucketID]
if bucket.Len() >= rt.bucketsize {
// if after all the unfolding, we're unable to find room for this peer, scrap it.
return "", ErrPeerRejectedNoCapacity
}
bucket.PushFront(p)
rt.PeerAdded(p)
return "", nil
}
return "", ErrPeerRejectedNoCapacity
}
// Remove deletes a peer from the routing table. This is to be used
// when we are sure a node has disconnected completely.
func (rt *RoutingTable) Remove(p peer.ID) {
rt.tabLock.Lock()
defer rt.tabLock.Unlock()
peerID := ConvertPeerID(p)
cpl := commonPrefixLen(peerID, rt.local)
bucketID := cpl
if bucketID >= len(rt.Buckets) {
bucketID = len(rt.Buckets) - 1
}
bucket := rt.Buckets[bucketID]
bucket.Remove(p)
rt.PeerRemoved(p)
}
func (rt *RoutingTable) nextBucket() {
// This is the last bucket, which allegedly is a mixed bag containing peers not belonging in dedicated (unfolded) buckets.
// _allegedly_ is used here to denote that *all* peers in the last bucket might feasibly belong to another bucket.
// This could happen if e.g. we've unfolded 4 buckets, and all peers in folded bucket 5 really belong in bucket 8.
bucket := rt.Buckets[len(rt.Buckets)-1]
newBucket := bucket.Split(len(rt.Buckets)-1, rt.local)
rt.Buckets = append(rt.Buckets, newBucket)
// The newly formed bucket still contains too many peers. We probably just unfolded a empty bucket.
if newBucket.Len() >= rt.bucketsize {
// Keep unfolding the table until the last bucket is not overflowing.
rt.nextBucket()
}
}
// Find a specific peer by ID or return nil
func (rt *RoutingTable) Find(id peer.ID) peer.ID {
srch := rt.NearestPeers(ConvertPeerID(id), 1)
if len(srch) == 0 || srch[0] != id {
return ""
}
return srch[0]
}
// NearestPeer returns a single peer that is nearest to the given ID
func (rt *RoutingTable) NearestPeer(id ID) peer.ID {
peers := rt.NearestPeers(id, 1)
if len(peers) > 0 {
return peers[0]
}
log.Debugf("NearestPeer: Returning nil, table size = %d", rt.Size())
return ""
}
// NearestPeers returns a list of the 'count' closest peers to the given ID
func (rt *RoutingTable) NearestPeers(id ID, count int) []peer.ID {
cpl := commonPrefixLen(id, rt.local)
rt.tabLock.RLock()
// Get bucket at cpl index or last bucket
var bucket *Bucket
if cpl >= len(rt.Buckets) {
cpl = len(rt.Buckets) - 1
}
bucket = rt.Buckets[cpl]
peerArr := make(peerSorterArr, 0, count)
peerArr = copyPeersFromList(id, peerArr, bucket.list)
if len(peerArr) < count {
// In the case of an unusual split, one bucket may be short or empty.
// if this happens, search both surrounding buckets for nearby peers
if cpl > 0 {
plist := rt.Buckets[cpl-1].list
peerArr = copyPeersFromList(id, peerArr, plist)
}
if cpl < len(rt.Buckets)-1 {
plist := rt.Buckets[cpl+1].list
peerArr = copyPeersFromList(id, peerArr, plist)
}
}
rt.tabLock.RUnlock()
// Sort by distance to local peer
sort.Sort(peerArr)
if count < len(peerArr) {
peerArr = peerArr[:count]
}
out := make([]peer.ID, 0, len(peerArr))
for _, p := range peerArr {
out = append(out, p.p)
}
return out
}
// Size returns the total number of peers in the routing table
func (rt *RoutingTable) Size() int {
var tot int
rt.tabLock.RLock()
for _, buck := range rt.Buckets {
tot += buck.Len()
}
rt.tabLock.RUnlock()
return tot
}
// ListPeers takes a RoutingTable and returns a list of all peers from all buckets in the table.
func (rt *RoutingTable) ListPeers() []peer.ID {
var peers []peer.ID
rt.tabLock.RLock()
for _, buck := range rt.Buckets {
peers = append(peers, buck.Peers()...)
}
rt.tabLock.RUnlock()
return peers
}
// Print prints a descriptive statement about the provided RoutingTable
func (rt *RoutingTable) Print() {
fmt.Printf("Routing Table, bs = %d, Max latency = %d\n", rt.bucketsize, rt.maxLatency)
rt.tabLock.RLock()
for i, b := range rt.Buckets {
fmt.Printf("\tbucket: %d\n", i)
b.lk.RLock()
for e := b.list.Front(); e != nil; e = e.Next() {
p := e.Value.(peer.ID)
fmt.Printf("\t\t- %s %s\n", p.Pretty(), rt.metrics.LatencyEWMA(p).String())
}
b.lk.RUnlock()
}
rt.tabLock.RUnlock()
}