micro/network/node.go

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package network
import (
"errors"
"sync"
"time"
pbNet "github.com/micro/go-micro/network/proto"
)
var (
// MaxDepth defines max depth of peer topology
MaxDepth = 3
)
// node is network node
type node struct {
sync.RWMutex
// id is node id
id string
// address is node address
address string
// neighbours maps the node neighbourhood
neighbours map[string]*node
// network returns the node network
network Network
// lastSeen stores the time the node has been seen last time
lastSeen time.Time
}
// Id is node ide
func (n *node) Id() string {
return n.id
}
// Address returns node address
func (n *node) Address() string {
return n.address
}
// Network returns node network
func (n *node) Network() Network {
return n.network
}
// Neighbourhood returns node neighbourhood
func (n *node) Neighbourhood() []Node {
var nodes []Node
n.RLock()
for _, neighbourNode := range n.neighbours {
// make a copy of the node
n := &node{
id: neighbourNode.id,
address: neighbourNode.address,
network: neighbourNode.network,
}
// NOTE: we do not care about neighbour's neighbours
nodes = append(nodes, n)
}
n.RUnlock()
return nodes
}
// getNeighbours collects node neighbours up to given depth into pbNeighbours
// NOTE: this method is not thread safe, so make sure you serialize access to it
// NOTE: we should be able to read-Lock this, even though it's recursive
func (n *node) getNeighbours(depth int) (*pbNet.Neighbour, error) {
node := &pbNet.Node{
Id: n.id,
Address: n.address,
}
pbNeighbours := &pbNet.Neighbour{
Node: node,
Neighbours: make([]*pbNet.Neighbour, 0),
}
// return if have either reached the depth or have no more neighbours
if depth == 0 || len(n.neighbours) == 0 {
return pbNeighbours, nil
}
// decrement the depth
depth--
var neighbours []*pbNet.Neighbour
for _, neighbour := range n.neighbours {
// get neighbours of the neighbour
// NOTE: this is [not] a recursive call
pbNodeNeighbour, err := neighbour.getNeighbours(depth)
if err != nil {
return nil, err
}
// add current neighbour to explored neighbours
neighbours = append(neighbours, pbNodeNeighbour)
}
// add neighbours to the parent topology
pbNeighbours.Neighbours = neighbours
return pbNeighbours, nil
}
// unpackNeighbour unpacks pbNet.Neighbour into node of given depth
// NOTE: this method is not thread safe, so make sure you serialize access to it
func unpackNeighbour(pbNeighbour *pbNet.Neighbour, depth int) (*node, error) {
if pbNeighbour == nil {
return nil, errors.New("neighbour not initialized")
}
neighbourNode := &node{
id: pbNeighbour.Node.Id,
address: pbNeighbour.Node.Address,
neighbours: make(map[string]*node),
}
// return if have either reached the depth or have no more neighbours
if depth == 0 || len(pbNeighbour.Neighbours) == 0 {
return neighbourNode, nil
}
// decrement the depth
depth--
neighbours := make(map[string]*node)
for _, pbNode := range pbNeighbour.Neighbours {
node, err := unpackNeighbour(pbNode, depth)
if err != nil {
return nil, err
}
neighbours[pbNode.Node.Id] = node
}
neighbourNode.neighbours = neighbours
return neighbourNode, nil
}
// updateNeighbour updates node neighbour up to given depth
// NOTE: this method is not thread safe, so make sure you serialize access to it
func (n *node) updateNeighbour(neighbour *pbNet.Neighbour, depth int) error {
// unpack neighbour into topology of size MaxDepth-1
// NOTE: we need MaxDepth-1 because node n is the parent adding which
// gives us the max neighbour topology we maintain and propagate
node, err := unpackNeighbour(neighbour, MaxDepth-1)
if err != nil {
return err
}
// update node neighbours with new topology
n.neighbours[neighbour.Node.Id] = node
return nil
}