micro/network/node.go

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package network
import (
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"errors"
"fmt"
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"io"
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"net"
"runtime/debug"
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"sort"
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"strconv"
"sync"
"time"
"github.com/google/uuid"
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"github.com/micro/go-micro/network/transport"
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"github.com/micro/go-micro/registry"
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"github.com/micro/go-micro/util/addr"
"github.com/micro/go-micro/util/log"
pb "github.com/micro/go-micro/network/proto"
)
type node struct {
*network
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// closed channel to close our connection to the network
closed chan bool
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sync.RWMutex
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// the nodes unique micro assigned mac address
muid string
// the node id registered in registry
id string
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// address of this node registered in registry
address string
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// our network lease with our network id/address
lease *pb.Lease
// the node registry
registry registry.Registry
// the base level transport
transport transport.Transport
// the listener
listener transport.Listener
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// connected records
// record.Address:true
connected map[string]bool
// leases for connections to us
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// link remote node:link
links map[string][]*link
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// messages received over links
recv chan *Message
// messages received over links
send chan *Message
}
// network methods
func newNode(n *network) (*node, error) {
// create a new node
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node := &node{
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// this nodes unique micro assigned mac address
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muid: fmt.Sprintf("%s-%s", n.name, uuid.New().String()),
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// map of connected records
connected: make(map[string]bool),
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// the links
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links: make(map[string][]*link),
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// closed channel
closed: make(chan bool),
// set the nodes network
network: n,
// set the default transport
transport: transport.DefaultTransport,
// set the default registry
registry: registry.DefaultRegistry,
// receive channel for accepted connections
recv: make(chan *Message, 128),
// send channel for accepted connections
send: make(chan *Message, 128),
}
// get the transport we're going to use for our tunnels
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// TODO: set to quic or tunnel or something else
t, ok := n.Options.Values().Get("network.transport")
if ok {
node.transport = t.(transport.Transport)
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}
// register the node with the registry for the network
// TODO: use a registrar or something else for local things
r, ok := n.Options.Values().Get("network.registry")
if ok {
node.registry = r.(registry.Registry)
}
// we listen on a random address, this is not advertised
// TODO: use util/addr to get something anyone in the same private network can talk to
l, err := node.transport.Listen(":0")
if err != nil {
return nil, err
}
// set the listener
node.listener = l
node.address = l.Addr()
// TODO: start the router and broadcast advertisements
// receive updates and push them to the network in accept(l) below
// chan, err := n.router.Advertise()
// u <- chan
// socket.send("route", u)
// u := socket.recv() => r.router.Update(u)
// process any incoming messages on the listener
// this is our inbound network connection
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go node.accept(l)
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// process any messages being sent by node.Send
// forwards to every link we have
go node.process()
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var port int
// TODO: this should be an overlay address
// ideally received via some dhcp style broadcast
host, pp, err := net.SplitHostPort(l.Addr())
if err == nil {
pt, _ := strconv.Atoi(pp)
port = pt
}
// some horrible things are happening
if host == "::" {
host = ""
}
// set the address
addr, _ := addr.Extract(host)
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// used to register in registry for network resolution
// separate to our lease on the network itself
node.id = uuid.New().String()
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node.address = fmt.Sprintf("%s:%d", addr, port)
// register self with the registry using network: prefix
// this is a local registry of nodes separate to the resolver
// maybe consolidate registry/resolver
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// TODO: find a way to do this via gossip or something like
// a registrar or tld or whatever
if err := node.registry.Register(&registry.Service{
// register with the network id
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Name: n.Name(),
Nodes: []*registry.Node{
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{Id: node.id, Address: node.address},
},
}); err != nil {
node.Close()
return nil, err
}
// create a channel to get links
linkChan := make(chan *link, 1)
// we're going to wait for the first connection
go node.connect(linkChan)
// wait forever to connect
// TODO: do something with the links we receive
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link := <-linkChan
// process this link
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log.Debugf("connect managing link %s", link.id)
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go node.manage(link)
go func() {
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for {
// process any further new links
select {
case l := <-linkChan:
log.Debugf("Managing new link %s", l.id)
go node.manage(l)
case <-node.closed:
return
}
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}
}()
return node, nil
}
// node methods
// Accept processes the incoming messages on its listener.
// This listener was created with the first call to network.Connect.
// Any inbound new socket here is essentially something else attempting
// to connect to the network. So we turn it into a socket, then process it.
func (n *node) accept(l transport.Listener) error {
return l.Accept(func(sock transport.Socket) {
defer func() {
// close socket
sock.Close()
if r := recover(); r != nil {
log.Log("panic recovered: ", r)
log.Log(string(debug.Stack()))
}
}()
// create a new link
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link := newLink(n, sock, nil)
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log.Debugf("Accepting connection from %s", link.socket.Remote())
// wait for the link to be connected
// the remote end will send "Connect"
// and we will return a "Lease"
if err := link.accept(); err != nil {
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log.Debugf("Error accepting connection %v", err)
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return
}
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log.Debugf("Accepted link from %s", link.socket.Remote())
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// save with the muid as the key
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// where we attempt to connect to nodes
// we do not connect to the same thing
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// TODO: figure out why this is an issue
// When we receive a connection from ourself
// we can't maintain the two links separately
// so we don't save it. It's basically some
// weird loopback issue because its our own socket.
if n.muid != link.lease.Node.Muid {
n.Lock()
// get the links
links := n.links[link.lease.Node.Muid]
// append to the current links
links = append(links, link)
// save the links with muid as the key
n.links[link.lease.Node.Muid] = links
n.Unlock()
}
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// manage the link for its lifetime
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log.Debugf("managing the link now %s", link.id)
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n.manage(link)
})
}
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// processes the sends the messages from n.Send into the queue of
// each link. If multiple links exist for a muid it should only
// send on link to figure it out.
// If we connected to a record and that link goes down we should
// also remove it from the n.connected map.
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func (n *node) process() {
for {
select {
case <-n.closed:
return
// process outbound messages on the send queue
// these messages are received from n.Send
case m := <-n.send:
// queue the message on each link
// TODO: more than likely use proxy
n.RLock()
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// range over all the links
for _, links := range n.links {
if len(links) == 0 {
continue
}
// sort the links by weight
sort.Slice(links, func(i, j int) bool {
return links[i].Weight() < links[j].Weight()
})
// queue the message
links[0].Send(m)
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}
n.RUnlock()
}
}
}
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// Manage manages the link for its lifetime. It should ideally throw
// away the link in the n.links map if there's any issues or total disconnection
// it should look at link.Status.
// If we connected to a record and that link goes down we should
// also remove it from the n.connected map.
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func (n *node) manage(l *link) {
// now process inbound messages on the link
// assumption is this handles everything else
for {
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// the send side uses a link queue but the receive side immediately sends it
// ideally we should probably have an internal queue on that side as well
// so we can judge link saturation both ways.
m, err := l.Accept()
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if err == io.EOF {
return
}
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if err != nil {
log.Debugf("Error accepting message on link %s: %v", l.id, err)
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// ???
return
}
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// if the node connection is closed bail out
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select {
case <-n.closed:
return
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// send to the network recv channel e.g node.Accept()
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case n.recv <- m:
}
}
}
// connect attempts to periodically connect to new nodes in the network.
// It will only do this if it has less than 3 connections. this method
// is called by network.Connect and fired in a go routine after establishing
// the first connection and creating a node. The node attempts to maintain
// its connection to the network via multiple links.
func (n *node) connect(linkChan chan *link) {
// TODO: adjustable ticker
t := time.NewTicker(time.Second)
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var lease *pb.Lease
for {
select {
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// exit when told to do so
case <-n.closed:
return
// on every tick check the number of links and then attempt
// to connect to new nodes if we don't have sufficient links
case <-t.C:
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n.RLock()
// only start processing if we have less than 3 links
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conns := len(n.links)
if conns > 2 {
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n.RUnlock()
continue
}
// get a list of link addresses so we don't reconnect
// to the ones we're already connected to
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connected := n.connected
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// unlock our read lock
n.RUnlock()
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// lookup records for our network
records := n.network.lookup(n.registry)
// for each record check we haven't already got a connection
// attempt to dial it, create a new socket and call
// connect with our existing network lease.
// if its the first call we don't actually have a lease
// TODO: determine how to prioritise local records
// while still connecting to the global network
for _, record := range records {
// skip existing connections
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if connected[record.Address] {
log.Tracef("Skipping connection to %s", record.Address)
continue
}
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// check how many connections we have
if conns > 2 {
log.Debugf("Made enough connections")
break
}
// attempt to connect and create a link
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log.Debugf("Dialing connection to %s", record.Address)
// connect to the node
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sock, err := n.transport.Dial(record.Address)
if err != nil {
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log.Debugf("Dialing connection error %v", err)
continue
}
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// create a new link with the lease and socket
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link := newLink(n, sock, lease)
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log.Debugf("Connecting link to %s", record.Address)
// connect the link:
// this broadcasts a "connect" request and gets back a "lease"
// this is the tunnel to the outside world and to the network
// then push updates and messages over this link
// first connect will not have a lease so we get one with node id/address
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if err := link.connect(); err != nil {
// shit
continue
}
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log.Debugf("Connected link to %s", record.Address)
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n.Lock()
// set lease for next time we connect to anything else
// we want to use the same lease for that. in future
// we may have to expire the lease
lease = link.lease
// save the new link
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// get existing links using the lease author
links := n.links[lease.Author]
// append to the links
links = append(links, link)
// save the links using the author
n.links[lease.Author] = links
n.Unlock()
// update number of connections
conns++
// save the connection
n.Lock()
n.connected[record.Address] = true
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n.Unlock()
// drop this down the link channel to the network
// so it can manage the links
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linkChan <- link
}
}
}
}
func (n *node) Address() string {
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n.RLock()
defer n.RUnlock()
// we have no address yet
if n.lease == nil {
return ""
}
// return node address in the lease
return n.lease.Node.Address
}
// Close shutdowns all the links and closes the listener
func (n *node) Close() error {
select {
case <-n.closed:
return nil
default:
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// mark as closed, we're now useless and there's no coming back
close(n.closed)
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// shutdown all the links
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n.Lock()
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for muid, links := range n.links {
for _, link := range links {
link.Close()
}
delete(n.links, muid)
}
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// reset connected
n.connected = nil
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n.Unlock()
// deregister self
n.registry.Deregister(&registry.Service{
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Name: n.network.Name(),
Nodes: []*registry.Node{
{Id: n.id, Address: n.address},
},
})
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// shutdown the listener
return n.listener.Close()
}
return nil
}
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// Accept receives the incoming messages from all links
func (n *node) Accept() (*Message, error) {
// process the inbound cruft
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for {
select {
case m, ok := <-n.recv:
if !ok {
return nil, errors.New("connection closed")
}
// return the message
return m, nil
case <-n.closed:
return nil, errors.New("connection closed")
}
}
// we never get here
return nil, nil
}
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func (n *node) Id() string {
n.RLock()
defer n.RUnlock()
if n.lease == nil {
return ""
}
return n.lease.Node.Id
}
func (n *node) Network() string {
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return n.network.Name()
}
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// Send propagates a message over all links. This should probably use its proxy.
func (n *node) Send(m *Message) error {
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select {
case <-n.closed:
return errors.New("connection closed")
case n.send <- m:
// send the message
}
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return nil
}