934 lines
29 KiB
Go
934 lines
29 KiB
Go
// Copyright 2017 The go-ethereum Authors
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// This file is part of the go-ethereum library.
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//
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// The go-ethereum library is free software: you can redistribute it and/or modify
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// it under the terms of the GNU Lesser General Public License as published by
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// the Free Software Foundation, either version 3 of the License, or
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// (at your option) any later version.
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//
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// The go-ethereum library is distributed in the hope that it will be useful,
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// but WITHOUT ANY WARRANTY; without even the implied warranty of
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// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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// GNU Lesser General Public License for more details.
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//
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// You should have received a copy of the GNU Lesser General Public License
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// along with the go-ethereum library. If not, see <http://www.gnu.org/licenses/>.
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package network
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import (
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"bytes"
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"fmt"
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"math/rand"
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"strings"
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"sync"
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"time"
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"github.com/ethereum/go-ethereum/common"
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"github.com/ethereum/go-ethereum/metrics"
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"github.com/ethereum/go-ethereum/swarm/log"
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"github.com/ethereum/go-ethereum/swarm/pot"
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sv "github.com/ethereum/go-ethereum/swarm/version"
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)
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/*
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Taking the proximity order relative to a fix point x classifies the points in
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the space (n byte long byte sequences) into bins. Items in each are at
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most half as distant from x as items in the previous bin. Given a sample of
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uniformly distributed items (a hash function over arbitrary sequence) the
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proximity scale maps onto series of subsets with cardinalities on a negative
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exponential scale.
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It also has the property that any two item belonging to the same bin are at
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most half as distant from each other as they are from x.
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If we think of random sample of items in the bins as connections in a network of
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interconnected nodes then relative proximity can serve as the basis for local
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decisions for graph traversal where the task is to find a route between two
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points. Since in every hop, the finite distance halves, there is
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a guaranteed constant maximum limit on the number of hops needed to reach one
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node from the other.
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*/
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var Pof = pot.DefaultPof(256)
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// KadParams holds the config params for Kademlia
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type KadParams struct {
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// adjustable parameters
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MaxProxDisplay int // number of rows the table shows
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NeighbourhoodSize int // nearest neighbour core minimum cardinality
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MinBinSize int // minimum number of peers in a row
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MaxBinSize int // maximum number of peers in a row before pruning
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RetryInterval int64 // initial interval before a peer is first redialed
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RetryExponent int // exponent to multiply retry intervals with
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MaxRetries int // maximum number of redial attempts
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// function to sanction or prevent suggesting a peer
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Reachable func(*BzzAddr) bool `json:"-"`
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}
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// NewKadParams returns a params struct with default values
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func NewKadParams() *KadParams {
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return &KadParams{
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MaxProxDisplay: 16,
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NeighbourhoodSize: 2,
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MinBinSize: 2,
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MaxBinSize: 4,
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RetryInterval: 4200000000, // 4.2 sec
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MaxRetries: 42,
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RetryExponent: 2,
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}
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}
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// Kademlia is a table of live peers and a db of known peers (node records)
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type Kademlia struct {
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lock sync.RWMutex
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*KadParams // Kademlia configuration parameters
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base []byte // immutable baseaddress of the table
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addrs *pot.Pot // pots container for known peer addresses
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conns *pot.Pot // pots container for live peer connections
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depth uint8 // stores the last current depth of saturation
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nDepth int // stores the last neighbourhood depth
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nDepthC chan int // returned by DepthC function to signal neighbourhood depth change
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addrCountC chan int // returned by AddrCountC function to signal peer count change
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}
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// NewKademlia creates a Kademlia table for base address addr
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// with parameters as in params
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// if params is nil, it uses default values
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func NewKademlia(addr []byte, params *KadParams) *Kademlia {
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if params == nil {
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params = NewKadParams()
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}
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return &Kademlia{
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base: addr,
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KadParams: params,
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addrs: pot.NewPot(nil, 0),
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conns: pot.NewPot(nil, 0),
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}
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}
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// entry represents a Kademlia table entry (an extension of BzzAddr)
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type entry struct {
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*BzzAddr
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conn *Peer
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seenAt time.Time
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retries int
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}
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// newEntry creates a kademlia peer from a *Peer
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func newEntry(p *BzzAddr) *entry {
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return &entry{
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BzzAddr: p,
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seenAt: time.Now(),
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}
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}
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// Label is a short tag for the entry for debug
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func Label(e *entry) string {
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return fmt.Sprintf("%s (%d)", e.Hex()[:4], e.retries)
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}
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// Hex is the hexadecimal serialisation of the entry address
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func (e *entry) Hex() string {
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return fmt.Sprintf("%x", e.Address())
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}
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// Register enters each address as kademlia peer record into the
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// database of known peer addresses
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func (k *Kademlia) Register(peers ...*BzzAddr) error {
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k.lock.Lock()
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defer k.lock.Unlock()
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metrics.GetOrRegisterCounter("kad.register", nil).Inc(1)
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var known, size int
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for _, p := range peers {
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log.Trace("kademlia trying to register", "addr", p)
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// error if self received, peer should know better
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// and should be punished for this
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if bytes.Equal(p.Address(), k.base) {
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return fmt.Errorf("add peers: %x is self", k.base)
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}
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var found bool
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k.addrs, _, found, _ = pot.Swap(k.addrs, p, Pof, func(v pot.Val) pot.Val {
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// if not found
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if v == nil {
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log.Trace("registering new peer", "addr", p)
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// insert new offline peer into conns
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return newEntry(p)
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}
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e := v.(*entry)
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// if underlay address is different, still add
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if !bytes.Equal(e.BzzAddr.UAddr, p.UAddr) {
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log.Trace("underlay addr is different, so add again", "new", p, "old", e.BzzAddr)
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// insert new offline peer into conns
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return newEntry(p)
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}
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return v
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})
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if found {
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known++
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}
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size++
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}
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// send new address count value only if there are new addresses
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if k.addrCountC != nil && size-known > 0 {
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k.addrCountC <- k.addrs.Size()
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}
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k.sendNeighbourhoodDepthChange()
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return nil
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}
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// SuggestPeer returns an unconnected peer address as a peer suggestion for connection
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func (k *Kademlia) SuggestPeer() (suggestedPeer *BzzAddr, saturationDepth int, changed bool) {
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k.lock.Lock()
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defer k.lock.Unlock()
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metrics.GetOrRegisterCounter("kad.suggestpeer", nil).Inc(1)
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radius := neighbourhoodRadiusForPot(k.conns, k.NeighbourhoodSize, k.base)
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// collect undersaturated bins in ascending order of number of connected peers
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// and from shallow to deep (ascending order of PO)
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// insert them in a map of bin arrays, keyed with the number of connected peers
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saturation := make(map[int][]int)
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var lastPO int // the last non-empty PO bin in the iteration
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saturationDepth = -1 // the deepest PO such that all shallower bins have >= k.MinBinSize peers
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var pastDepth bool // whether po of iteration >= depth
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k.conns.EachBin(k.base, Pof, 0, func(po, size int, f func(func(val pot.Val) bool) bool) bool {
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// process skipped empty bins
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for ; lastPO < po; lastPO++ {
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// find the lowest unsaturated bin
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if saturationDepth == -1 {
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saturationDepth = lastPO
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}
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// if there is an empty bin, depth is surely passed
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pastDepth = true
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saturation[0] = append(saturation[0], lastPO)
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}
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lastPO = po + 1
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// past radius, depth is surely passed
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if po >= radius {
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pastDepth = true
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}
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// beyond depth the bin is treated as unsaturated even if size >= k.MinBinSize
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// in order to achieve full connectivity to all neighbours
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if pastDepth && size >= k.MinBinSize {
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size = k.MinBinSize - 1
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}
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// process non-empty unsaturated bins
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if size < k.MinBinSize {
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// find the lowest unsaturated bin
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if saturationDepth == -1 {
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saturationDepth = po
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}
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saturation[size] = append(saturation[size], po)
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}
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return true
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})
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// to trigger peer requests for peers closer than closest connection, include
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// all bins from nearest connection upto nearest address as unsaturated
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var nearestAddrAt int
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k.addrs.EachNeighbour(k.base, Pof, func(_ pot.Val, po int) bool {
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nearestAddrAt = po
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return false
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})
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// including bins as size 0 has the effect that requesting connection
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// is prioritised over non-empty shallower bins
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for ; lastPO <= nearestAddrAt; lastPO++ {
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saturation[0] = append(saturation[0], lastPO)
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}
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// all PO bins are saturated, ie., minsize >= k.MinBinSize, no peer suggested
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if len(saturation) == 0 {
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return nil, 0, false
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}
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// find the first callable peer in the address book
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// starting from the bins with smallest size proceeding from shallow to deep
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// for each bin (up until neighbourhood radius) we find callable candidate peers
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for size := 0; size < k.MinBinSize && suggestedPeer == nil; size++ {
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bins, ok := saturation[size]
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if !ok {
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// no bin with this size
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continue
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}
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cur := 0
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curPO := bins[0]
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k.addrs.EachBin(k.base, Pof, curPO, func(po, _ int, f func(func(pot.Val) bool) bool) bool {
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curPO = bins[cur]
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// find the next bin that has size size
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if curPO == po {
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cur++
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} else {
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// skip bins that have no addresses
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for ; cur < len(bins) && curPO < po; cur++ {
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curPO = bins[cur]
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}
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if po < curPO {
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cur--
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return true
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}
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// stop if there are no addresses
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if curPO < po {
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return false
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}
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}
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// curPO found
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// find a callable peer out of the addresses in the unsaturated bin
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// stop if found
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f(func(val pot.Val) bool {
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e := val.(*entry)
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if k.callable(e) {
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suggestedPeer = e.BzzAddr
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return false
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}
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return true
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})
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return cur < len(bins) && suggestedPeer == nil
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})
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}
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if uint8(saturationDepth) < k.depth {
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k.depth = uint8(saturationDepth)
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return suggestedPeer, saturationDepth, true
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}
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return suggestedPeer, 0, false
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}
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// On inserts the peer as a kademlia peer into the live peers
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func (k *Kademlia) On(p *Peer) (uint8, bool) {
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k.lock.Lock()
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defer k.lock.Unlock()
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metrics.GetOrRegisterCounter("kad.on", nil).Inc(1)
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var ins bool
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k.conns, _, _, _ = pot.Swap(k.conns, p, Pof, func(v pot.Val) pot.Val {
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// if not found live
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if v == nil {
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ins = true
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// insert new online peer into conns
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return p
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}
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// found among live peers, do nothing
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return v
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})
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if ins && !p.BzzPeer.LightNode {
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a := newEntry(p.BzzAddr)
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a.conn = p
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// insert new online peer into addrs
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k.addrs, _, _, _ = pot.Swap(k.addrs, p, Pof, func(v pot.Val) pot.Val {
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return a
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})
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// send new address count value only if the peer is inserted
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if k.addrCountC != nil {
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k.addrCountC <- k.addrs.Size()
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}
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}
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// calculate if depth of saturation changed
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depth := uint8(k.saturation())
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var changed bool
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if depth != k.depth {
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changed = true
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k.depth = depth
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}
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k.sendNeighbourhoodDepthChange()
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return k.depth, changed
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}
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// NeighbourhoodDepthC returns the channel that sends a new kademlia
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// neighbourhood depth on each change.
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// Not receiving from the returned channel will block On function
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// when the neighbourhood depth is changed.
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// TODO: Why is this exported, and if it should be; why can't we have more subscribers than one?
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func (k *Kademlia) NeighbourhoodDepthC() <-chan int {
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k.lock.Lock()
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defer k.lock.Unlock()
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if k.nDepthC == nil {
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k.nDepthC = make(chan int)
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}
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return k.nDepthC
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}
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// CloseNeighbourhoodDepthC closes the channel returned by
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// NeighbourhoodDepthC and stops sending neighbourhood change.
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func (k *Kademlia) CloseNeighbourhoodDepthC() {
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k.lock.Lock()
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defer k.lock.Unlock()
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if k.nDepthC != nil {
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close(k.nDepthC)
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k.nDepthC = nil
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}
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}
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// sendNeighbourhoodDepthChange sends new neighbourhood depth to k.nDepth channel
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// if it is initialized.
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func (k *Kademlia) sendNeighbourhoodDepthChange() {
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// nDepthC is initialized when NeighbourhoodDepthC is called and returned by it.
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// It provides signaling of neighbourhood depth change.
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// This part of the code is sending new neighbourhood depth to nDepthC if that condition is met.
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if k.nDepthC != nil {
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nDepth := depthForPot(k.conns, k.NeighbourhoodSize, k.base)
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if nDepth != k.nDepth {
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k.nDepth = nDepth
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k.nDepthC <- nDepth
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}
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}
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}
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// AddrCountC returns the channel that sends a new
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// address count value on each change.
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// Not receiving from the returned channel will block Register function
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// when address count value changes.
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func (k *Kademlia) AddrCountC() <-chan int {
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k.lock.Lock()
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defer k.lock.Unlock()
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if k.addrCountC == nil {
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k.addrCountC = make(chan int)
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}
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return k.addrCountC
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}
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// CloseAddrCountC closes the channel returned by
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// AddrCountC and stops sending address count change.
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func (k *Kademlia) CloseAddrCountC() {
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k.lock.Lock()
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defer k.lock.Unlock()
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if k.addrCountC != nil {
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close(k.addrCountC)
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k.addrCountC = nil
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}
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}
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// Off removes a peer from among live peers
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func (k *Kademlia) Off(p *Peer) {
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k.lock.Lock()
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defer k.lock.Unlock()
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var del bool
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if !p.BzzPeer.LightNode {
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k.addrs, _, _, _ = pot.Swap(k.addrs, p, Pof, func(v pot.Val) pot.Val {
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// v cannot be nil, must check otherwise we overwrite entry
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if v == nil {
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panic(fmt.Sprintf("connected peer not found %v", p))
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}
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del = true
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return newEntry(p.BzzAddr)
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})
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} else {
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del = true
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}
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if del {
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k.conns, _, _, _ = pot.Swap(k.conns, p, Pof, func(_ pot.Val) pot.Val {
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// v cannot be nil, but no need to check
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return nil
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})
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// send new address count value only if the peer is deleted
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if k.addrCountC != nil {
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k.addrCountC <- k.addrs.Size()
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}
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k.sendNeighbourhoodDepthChange()
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}
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}
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func (k *Kademlia) ListKnown() []*BzzAddr {
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res := []*BzzAddr{}
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k.addrs.Each(func(val pot.Val) bool {
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e := val.(*entry)
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res = append(res, e.BzzAddr)
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return true
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})
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return res
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}
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// EachConn is an iterator with args (base, po, f) applies f to each live peer
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// that has proximity order po or less as measured from the base
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// if base is nil, kademlia base address is used
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func (k *Kademlia) EachConn(base []byte, o int, f func(*Peer, int) bool) {
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k.lock.RLock()
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defer k.lock.RUnlock()
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k.eachConn(base, o, f)
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}
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func (k *Kademlia) eachConn(base []byte, o int, f func(*Peer, int) bool) {
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if len(base) == 0 {
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base = k.base
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}
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k.conns.EachNeighbour(base, Pof, func(val pot.Val, po int) bool {
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if po > o {
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return true
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}
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return f(val.(*Peer), po)
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})
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}
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// EachAddr called with (base, po, f) is an iterator applying f to each known peer
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// that has proximity order o or less as measured from the base
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// if base is nil, kademlia base address is used
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func (k *Kademlia) EachAddr(base []byte, o int, f func(*BzzAddr, int) bool) {
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k.lock.RLock()
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defer k.lock.RUnlock()
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k.eachAddr(base, o, f)
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}
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func (k *Kademlia) eachAddr(base []byte, o int, f func(*BzzAddr, int) bool) {
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if len(base) == 0 {
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base = k.base
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}
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k.addrs.EachNeighbour(base, Pof, func(val pot.Val, po int) bool {
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if po > o {
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return true
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}
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return f(val.(*entry).BzzAddr, po)
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})
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}
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// NeighbourhoodDepth returns the depth for the pot, see depthForPot
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func (k *Kademlia) NeighbourhoodDepth() (depth int) {
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k.lock.RLock()
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defer k.lock.RUnlock()
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return depthForPot(k.conns, k.NeighbourhoodSize, k.base)
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}
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// neighbourhoodRadiusForPot returns the neighbourhood radius of the kademlia
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// neighbourhood radius encloses the nearest neighbour set with size >= neighbourhoodSize
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// i.e., neighbourhood radius is the deepest PO such that all bins not shallower altogether
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// contain at least neighbourhoodSize connected peers
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// if there is altogether less than neighbourhoodSize peers connected, it returns 0
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// caller must hold the lock
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func neighbourhoodRadiusForPot(p *pot.Pot, neighbourhoodSize int, pivotAddr []byte) (depth int) {
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if p.Size() <= neighbourhoodSize {
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return 0
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}
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// total number of peers in iteration
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var size int
|
|
f := func(v pot.Val, i int) bool {
|
|
// po == 256 means that addr is the pivot address(self)
|
|
if i == 256 {
|
|
return true
|
|
}
|
|
size++
|
|
|
|
// this means we have all nn-peers.
|
|
// depth is by default set to the bin of the farthest nn-peer
|
|
if size == neighbourhoodSize {
|
|
depth = i
|
|
return false
|
|
}
|
|
|
|
return true
|
|
}
|
|
p.EachNeighbour(pivotAddr, Pof, f)
|
|
return depth
|
|
}
|
|
|
|
// depthForPot returns the depth for the pot
|
|
// depth is the radius of the minimal extension of nearest neighbourhood that
|
|
// includes all empty PO bins. I.e., depth is the deepest PO such that
|
|
// - it is not deeper than neighbourhood radius
|
|
// - all bins shallower than depth are not empty
|
|
// caller must hold the lock
|
|
func depthForPot(p *pot.Pot, neighbourhoodSize int, pivotAddr []byte) (depth int) {
|
|
if p.Size() <= neighbourhoodSize {
|
|
return 0
|
|
}
|
|
// determining the depth is a two-step process
|
|
// first we find the proximity bin of the shallowest of the neighbourhoodSize peers
|
|
// the numeric value of depth cannot be higher than this
|
|
maxDepth := neighbourhoodRadiusForPot(p, neighbourhoodSize, pivotAddr)
|
|
|
|
// the second step is to test for empty bins in order from shallowest to deepest
|
|
// if an empty bin is found, this will be the actual depth
|
|
// we stop iterating if we hit the maxDepth determined in the first step
|
|
p.EachBin(pivotAddr, Pof, 0, func(po int, _ int, f func(func(pot.Val) bool) bool) bool {
|
|
if po == depth {
|
|
if maxDepth == depth {
|
|
return false
|
|
}
|
|
depth++
|
|
return true
|
|
}
|
|
return false
|
|
})
|
|
|
|
return depth
|
|
}
|
|
|
|
// callable decides if an address entry represents a callable peer
|
|
func (k *Kademlia) callable(e *entry) bool {
|
|
// not callable if peer is live or exceeded maxRetries
|
|
if e.conn != nil || e.retries > k.MaxRetries {
|
|
return false
|
|
}
|
|
// calculate the allowed number of retries based on time lapsed since last seen
|
|
timeAgo := int64(time.Since(e.seenAt))
|
|
div := int64(k.RetryExponent)
|
|
div += (150000 - rand.Int63n(300000)) * div / 1000000
|
|
var retries int
|
|
for delta := timeAgo; delta > k.RetryInterval; delta /= div {
|
|
retries++
|
|
}
|
|
// this is never called concurrently, so safe to increment
|
|
// peer can be retried again
|
|
if retries < e.retries {
|
|
log.Trace(fmt.Sprintf("%08x: %v long time since last try (at %v) needed before retry %v, wait only warrants %v", k.BaseAddr()[:4], e, timeAgo, e.retries, retries))
|
|
return false
|
|
}
|
|
// function to sanction or prevent suggesting a peer
|
|
if k.Reachable != nil && !k.Reachable(e.BzzAddr) {
|
|
log.Trace(fmt.Sprintf("%08x: peer %v is temporarily not callable", k.BaseAddr()[:4], e))
|
|
return false
|
|
}
|
|
e.retries++
|
|
log.Trace(fmt.Sprintf("%08x: peer %v is callable", k.BaseAddr()[:4], e))
|
|
|
|
return true
|
|
}
|
|
|
|
// BaseAddr return the kademlia base address
|
|
func (k *Kademlia) BaseAddr() []byte {
|
|
return k.base
|
|
}
|
|
|
|
// String returns kademlia table + kaddb table displayed with ascii
|
|
func (k *Kademlia) String() string {
|
|
k.lock.RLock()
|
|
defer k.lock.RUnlock()
|
|
return k.string()
|
|
}
|
|
|
|
// string returns kademlia table + kaddb table displayed with ascii
|
|
// caller must hold the lock
|
|
func (k *Kademlia) string() string {
|
|
wsrow := " "
|
|
var rows []string
|
|
|
|
rows = append(rows, "=========================================================================")
|
|
if len(sv.GitCommit) > 0 {
|
|
rows = append(rows, fmt.Sprintf("commit hash: %s", sv.GitCommit))
|
|
}
|
|
rows = append(rows, fmt.Sprintf("%v KΛÐΞMLIΛ hive: queen's address: %x", time.Now().UTC().Format(time.UnixDate), k.BaseAddr()))
|
|
rows = append(rows, fmt.Sprintf("population: %d (%d), NeighbourhoodSize: %d, MinBinSize: %d, MaxBinSize: %d", k.conns.Size(), k.addrs.Size(), k.NeighbourhoodSize, k.MinBinSize, k.MaxBinSize))
|
|
|
|
liverows := make([]string, k.MaxProxDisplay)
|
|
peersrows := make([]string, k.MaxProxDisplay)
|
|
|
|
depth := depthForPot(k.conns, k.NeighbourhoodSize, k.base)
|
|
rest := k.conns.Size()
|
|
k.conns.EachBin(k.base, Pof, 0, func(po, size int, f func(func(val pot.Val) bool) bool) bool {
|
|
var rowlen int
|
|
if po >= k.MaxProxDisplay {
|
|
po = k.MaxProxDisplay - 1
|
|
}
|
|
row := []string{fmt.Sprintf("%2d", size)}
|
|
rest -= size
|
|
f(func(val pot.Val) bool {
|
|
e := val.(*Peer)
|
|
row = append(row, fmt.Sprintf("%x", e.Address()[:2]))
|
|
rowlen++
|
|
return rowlen < 4
|
|
})
|
|
r := strings.Join(row, " ")
|
|
r = r + wsrow
|
|
liverows[po] = r[:31]
|
|
return true
|
|
})
|
|
|
|
k.addrs.EachBin(k.base, Pof, 0, func(po, size int, f func(func(val pot.Val) bool) bool) bool {
|
|
var rowlen int
|
|
if po >= k.MaxProxDisplay {
|
|
po = k.MaxProxDisplay - 1
|
|
}
|
|
if size < 0 {
|
|
panic("wtf")
|
|
}
|
|
row := []string{fmt.Sprintf("%2d", size)}
|
|
// we are displaying live peers too
|
|
f(func(val pot.Val) bool {
|
|
e := val.(*entry)
|
|
row = append(row, Label(e))
|
|
rowlen++
|
|
return rowlen < 4
|
|
})
|
|
peersrows[po] = strings.Join(row, " ")
|
|
return true
|
|
})
|
|
|
|
for i := 0; i < k.MaxProxDisplay; i++ {
|
|
if i == depth {
|
|
rows = append(rows, fmt.Sprintf("============ DEPTH: %d ==========================================", i))
|
|
}
|
|
left := liverows[i]
|
|
right := peersrows[i]
|
|
if len(left) == 0 {
|
|
left = " 0 "
|
|
}
|
|
if len(right) == 0 {
|
|
right = " 0"
|
|
}
|
|
rows = append(rows, fmt.Sprintf("%03d %v | %v", i, left, right))
|
|
}
|
|
rows = append(rows, "=========================================================================")
|
|
return "\n" + strings.Join(rows, "\n")
|
|
}
|
|
|
|
// PeerPot keeps info about expected nearest neighbours
|
|
// used for testing only
|
|
// TODO move to separate testing tools file
|
|
type PeerPot struct {
|
|
NNSet [][]byte
|
|
PeersPerBin []int
|
|
}
|
|
|
|
// NewPeerPotMap creates a map of pot record of *BzzAddr with keys
|
|
// as hexadecimal representations of the address.
|
|
// the NeighbourhoodSize of the passed kademlia is used
|
|
// used for testing only
|
|
// TODO move to separate testing tools file
|
|
func NewPeerPotMap(neighbourhoodSize int, addrs [][]byte) map[string]*PeerPot {
|
|
|
|
// create a table of all nodes for health check
|
|
np := pot.NewPot(nil, 0)
|
|
for _, addr := range addrs {
|
|
np, _, _ = pot.Add(np, addr, Pof)
|
|
}
|
|
ppmap := make(map[string]*PeerPot)
|
|
|
|
// generate an allknowing source of truth for connections
|
|
// for every kademlia passed
|
|
for i, a := range addrs {
|
|
|
|
// actual kademlia depth
|
|
depth := depthForPot(np, neighbourhoodSize, a)
|
|
|
|
// all nn-peers
|
|
var nns [][]byte
|
|
peersPerBin := make([]int, depth)
|
|
|
|
// iterate through the neighbours, going from the deepest to the shallowest
|
|
np.EachNeighbour(a, Pof, func(val pot.Val, po int) bool {
|
|
addr := val.([]byte)
|
|
// po == 256 means that addr is the pivot address(self)
|
|
// we do not include self in the map
|
|
if po == 256 {
|
|
return true
|
|
}
|
|
// append any neighbors found
|
|
// a neighbor is any peer in or deeper than the depth
|
|
if po >= depth {
|
|
nns = append(nns, addr)
|
|
} else {
|
|
// for peers < depth, we just count the number in each bin
|
|
// the bin is the index of the slice
|
|
peersPerBin[po]++
|
|
}
|
|
return true
|
|
})
|
|
|
|
log.Trace(fmt.Sprintf("%x PeerPotMap NNS: %s, peersPerBin", addrs[i][:4], LogAddrs(nns)))
|
|
ppmap[common.Bytes2Hex(a)] = &PeerPot{
|
|
NNSet: nns,
|
|
PeersPerBin: peersPerBin,
|
|
}
|
|
}
|
|
return ppmap
|
|
}
|
|
|
|
// Saturation returns the smallest po value in which the node has less than MinBinSize peers
|
|
// if the iterator reaches neighbourhood radius, then the last bin + 1 is returned
|
|
func (k *Kademlia) Saturation() int {
|
|
k.lock.RLock()
|
|
defer k.lock.RUnlock()
|
|
|
|
return k.saturation()
|
|
}
|
|
|
|
func (k *Kademlia) saturation() int {
|
|
prev := -1
|
|
radius := neighbourhoodRadiusForPot(k.conns, k.NeighbourhoodSize, k.base)
|
|
k.conns.EachBin(k.base, Pof, 0, func(po, size int, f func(func(val pot.Val) bool) bool) bool {
|
|
prev++
|
|
if po >= radius {
|
|
return false
|
|
}
|
|
return prev == po && size >= k.MinBinSize
|
|
})
|
|
if prev < 0 {
|
|
return 0
|
|
}
|
|
return prev
|
|
}
|
|
|
|
// isSaturated returns true if the kademlia is considered saturated, or false if not.
|
|
// It checks this by checking an array of ints called unsaturatedBins; each item in that array corresponds
|
|
// to the bin which is unsaturated (number of connections < k.MinBinSize).
|
|
// The bin is considered unsaturated only if there are actual peers in that PeerPot's bin (peersPerBin)
|
|
// (if there is no peer for a given bin, then no connection could ever be established;
|
|
// in a God's view this is relevant as no more peers will ever appear on that bin)
|
|
func (k *Kademlia) isSaturated(peersPerBin []int, depth int) bool {
|
|
// depth could be calculated from k but as this is called from `GetHealthInfo()`,
|
|
// the depth has already been calculated so we can require it as a parameter
|
|
|
|
// early check for depth
|
|
if depth != len(peersPerBin) {
|
|
return false
|
|
}
|
|
unsaturatedBins := make([]int, 0)
|
|
k.conns.EachBin(k.base, Pof, 0, func(po, size int, f func(func(val pot.Val) bool) bool) bool {
|
|
|
|
if po >= depth {
|
|
return false
|
|
}
|
|
log.Trace("peers per bin", "peersPerBin[po]", peersPerBin[po], "po", po)
|
|
// if there are actually peers in the PeerPot who can fulfill k.MinBinSize
|
|
if size < k.MinBinSize && size < peersPerBin[po] {
|
|
log.Trace("connections for po", "po", po, "size", size)
|
|
unsaturatedBins = append(unsaturatedBins, po)
|
|
}
|
|
return true
|
|
})
|
|
|
|
log.Trace("list of unsaturated bins", "unsaturatedBins", unsaturatedBins)
|
|
return len(unsaturatedBins) == 0
|
|
}
|
|
|
|
// knowNeighbours tests if all neighbours in the peerpot
|
|
// are found among the peers known to the kademlia
|
|
// It is used in Healthy function for testing only
|
|
// TODO move to separate testing tools file
|
|
func (k *Kademlia) knowNeighbours(addrs [][]byte) (got bool, n int, missing [][]byte) {
|
|
pm := make(map[string]bool)
|
|
depth := depthForPot(k.conns, k.NeighbourhoodSize, k.base)
|
|
// create a map with all peers at depth and deeper known in the kademlia
|
|
k.eachAddr(nil, 255, func(p *BzzAddr, po int) bool {
|
|
// in order deepest to shallowest compared to the kademlia base address
|
|
// all bins (except self) are included (0 <= bin <= 255)
|
|
if po < depth {
|
|
return false
|
|
}
|
|
pk := common.Bytes2Hex(p.Address())
|
|
pm[pk] = true
|
|
return true
|
|
})
|
|
|
|
// iterate through nearest neighbors in the peerpot map
|
|
// if we can't find the neighbor in the map we created above
|
|
// then we don't know all our neighbors
|
|
// (which sadly is all too common in modern society)
|
|
var gots int
|
|
var culprits [][]byte
|
|
for _, p := range addrs {
|
|
pk := common.Bytes2Hex(p)
|
|
if pm[pk] {
|
|
gots++
|
|
} else {
|
|
log.Trace(fmt.Sprintf("%08x: known nearest neighbour %s not found", k.base, pk))
|
|
culprits = append(culprits, p)
|
|
}
|
|
}
|
|
return gots == len(addrs), gots, culprits
|
|
}
|
|
|
|
// connectedNeighbours tests if all neighbours in the peerpot
|
|
// are currently connected in the kademlia
|
|
// It is used in Healthy function for testing only
|
|
func (k *Kademlia) connectedNeighbours(peers [][]byte) (got bool, n int, missing [][]byte) {
|
|
pm := make(map[string]bool)
|
|
|
|
// create a map with all peers at depth and deeper that are connected in the kademlia
|
|
// in order deepest to shallowest compared to the kademlia base address
|
|
// all bins (except self) are included (0 <= bin <= 255)
|
|
depth := depthForPot(k.conns, k.NeighbourhoodSize, k.base)
|
|
k.eachConn(nil, 255, func(p *Peer, po int) bool {
|
|
if po < depth {
|
|
return false
|
|
}
|
|
pk := common.Bytes2Hex(p.Address())
|
|
pm[pk] = true
|
|
return true
|
|
})
|
|
|
|
// iterate through nearest neighbors in the peerpot map
|
|
// if we can't find the neighbor in the map we created above
|
|
// then we don't know all our neighbors
|
|
var gots int
|
|
var culprits [][]byte
|
|
for _, p := range peers {
|
|
pk := common.Bytes2Hex(p)
|
|
if pm[pk] {
|
|
gots++
|
|
} else {
|
|
log.Trace(fmt.Sprintf("%08x: ExpNN: %s not found", k.base, pk))
|
|
culprits = append(culprits, p)
|
|
}
|
|
}
|
|
return gots == len(peers), gots, culprits
|
|
}
|
|
|
|
// Health state of the Kademlia
|
|
// used for testing only
|
|
type Health struct {
|
|
KnowNN bool // whether node knows all its neighbours
|
|
CountKnowNN int // amount of neighbors known
|
|
MissingKnowNN [][]byte // which neighbours we should have known but we don't
|
|
ConnectNN bool // whether node is connected to all its neighbours
|
|
CountConnectNN int // amount of neighbours connected to
|
|
MissingConnectNN [][]byte // which neighbours we should have been connected to but we're not
|
|
// Saturated: if in all bins < depth number of connections >= MinBinsize or,
|
|
// if number of connections < MinBinSize, to the number of available peers in that bin
|
|
Saturated bool
|
|
Hive string
|
|
}
|
|
|
|
// GetHealthInfo reports the health state of the kademlia connectivity
|
|
//
|
|
// The PeerPot argument provides an all-knowing view of the network
|
|
// The resulting Health object is a result of comparisons between
|
|
// what is the actual composition of the kademlia in question (the receiver), and
|
|
// what SHOULD it have been when we take all we know about the network into consideration.
|
|
//
|
|
// used for testing only
|
|
func (k *Kademlia) GetHealthInfo(pp *PeerPot) *Health {
|
|
k.lock.RLock()
|
|
defer k.lock.RUnlock()
|
|
if len(pp.NNSet) < k.NeighbourhoodSize {
|
|
log.Warn("peerpot NNSet < NeighbourhoodSize")
|
|
}
|
|
gotnn, countgotnn, culpritsgotnn := k.connectedNeighbours(pp.NNSet)
|
|
knownn, countknownn, culpritsknownn := k.knowNeighbours(pp.NNSet)
|
|
depth := depthForPot(k.conns, k.NeighbourhoodSize, k.base)
|
|
|
|
// check saturation
|
|
saturated := k.isSaturated(pp.PeersPerBin, depth)
|
|
|
|
log.Trace(fmt.Sprintf("%08x: healthy: knowNNs: %v, gotNNs: %v, saturated: %v\n", k.base, knownn, gotnn, saturated))
|
|
return &Health{
|
|
KnowNN: knownn,
|
|
CountKnowNN: countknownn,
|
|
MissingKnowNN: culpritsknownn,
|
|
ConnectNN: gotnn,
|
|
CountConnectNN: countgotnn,
|
|
MissingConnectNN: culpritsgotnn,
|
|
Saturated: saturated,
|
|
Hive: k.string(),
|
|
}
|
|
}
|
|
|
|
// Healthy return the strict interpretation of `Healthy` given a `Health` struct
|
|
// definition of strict health: all conditions must be true:
|
|
// - we at least know one peer
|
|
// - we know all neighbors
|
|
// - we are connected to all known neighbors
|
|
// - it is saturated
|
|
func (h *Health) Healthy() bool {
|
|
return h.KnowNN && h.ConnectNN && h.CountKnowNN > 0 && h.Saturated
|
|
}
|