package dht
import (
"container/list"
"sort"
"sync"
peer "github.com/jbenet/go-ipfs/peer"
u "github.com/jbenet/go-ipfs/util"
)
// 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
// kBuckets define all the fingers to other nodes.
Buckets []*Bucket
bucketsize int
}
func NewRoutingTable(bucketsize int, local_id ID) *RoutingTable {
rt := new(RoutingTable)
rt.Buckets = []*Bucket{new(Bucket)}
rt.bucketsize = bucketsize
rt.local = local_id
return rt
}
// Update adds or moves the given peer to the front of its respective bucket
// If a peer gets removed from a bucket, it is returned
func (rt *RoutingTable) Update(p *peer.Peer) *peer.Peer {
rt.tabLock.Lock()
defer rt.tabLock.Unlock()
peer_id := convertPeerID(p.ID)
cpl := xor(peer_id, rt.local).commonPrefixLen()
b_id := cpl
if b_id >= len(rt.Buckets) {
b_id = len(rt.Buckets) - 1
}
bucket := rt.Buckets[b_id]
e := bucket.Find(p.ID)
if e == nil {
// New peer, add to bucket
bucket.PushFront(p)
// Are we past the max bucket size?
if bucket.Len() > rt.bucketsize {
if b_id == len(rt.Buckets) - 1 {
new_bucket := bucket.Split(b_id, rt.local)
rt.Buckets = append(rt.Buckets, new_bucket)
if new_bucket.Len() > rt.bucketsize {
// TODO: This is a very rare and annoying case
panic("Case not handled.")
}
// If all elements were on left side of split...
if bucket.Len() > rt.bucketsize {
return bucket.PopBack()
}
} else {
// If the bucket cant split kick out least active node
return bucket.PopBack()
}
}
return nil
} else {
// 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(e)
return nil
}
}
// A helper struct to sort peers by their distance to the local node
type peerDistance struct {
p *peer.Peer
distance ID
}
// peerSorterArr implements sort.Interface to sort peers by xor distance
type peerSorterArr []*peerDistance
func (p peerSorterArr) Len() int {return len(p)}
func (p peerSorterArr) Swap(a, b int) {p[a],p[b] = p[b],p[a]}
func (p peerSorterArr) Less(a, b int) bool {
return p[a].distance.Less(p[b].distance)
}
//
func copyPeersFromList(target ID, peerArr peerSorterArr, peerList *list.List) peerSorterArr {
for e := peerList.Front(); e != nil; e = e.Next() {
p := e.Value.(*peer.Peer)
p_id := convertPeerID(p.ID)
pd := peerDistance{
p: p,
distance: xor(target, p_id),
}
peerArr = append(peerArr, &pd)
if e == nil {
u.POut("list element was nil.")
return peerArr
}
}
return peerArr
}
// Returns a single peer that is nearest to the given ID
func (rt *RoutingTable) NearestPeer(id ID) *peer.Peer {
peers := rt.NearestPeers(id, 1)
if len(peers) > 0 {
return peers[0]
} else {
return nil
}
}
// Returns a list of the 'count' closest peers to the given ID
func (rt *RoutingTable) NearestPeers(id ID, count int) []*peer.Peer {
rt.tabLock.RLock()
defer rt.tabLock.RUnlock()
cpl := xor(id, rt.local).commonPrefixLen()
// 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]
var peerArr peerSorterArr
if bucket.Len() == 0 {
// In the case of an unusual split, one bucket may be empty.
// if this happens, search both surrounding buckets for nearest peer
if cpl > 0 {
plist := (*list.List)(rt.Buckets[cpl - 1])
peerArr = copyPeersFromList(id, peerArr, plist)
}
if cpl < len(rt.Buckets) - 1 {
plist := (*list.List)(rt.Buckets[cpl + 1])
peerArr = copyPeersFromList(id, peerArr, plist)
}
} else {
plist := (*list.List)(bucket)
peerArr = copyPeersFromList(id, peerArr, plist)
}
// Sort by distance to local peer
sort.Sort(peerArr)
var out []*peer.Peer
for i := 0; i < count && i < peerArr.Len(); i++ {
out = append(out, peerArr[i].p)
}
return out
}
// Returns the total number of peers in the routing table
func (rt *RoutingTable) Size() int {
var tot int
for _,buck := range rt.Buckets {
tot += buck.Len()
}
return tot
}
// NOTE: This is potentially unsafe... use at your own risk
func (rt *RoutingTable) listpeers() []*peer.Peer {
var peers []*peer.Peer
for _,buck := range rt.Buckets {
for e := buck.getIter(); e != nil; e = e.Next() {
peers = append(peers, e.Value.(*peer.Peer))
}
}
return peers
}