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yggdrasil-go/src/yggdrasil/debug.go

610 lines
15 KiB
Go

// +build debug
package yggdrasil
// These are functions that should not exist
// They are (or were) used during development, to work around missing features
// They're also used to configure things from the outside
// It would be better to define and export a few config functions elsewhere
// Or define some remote API and call it to send/request configuration info
import _ "golang.org/x/net/ipv6" // TODO put this somewhere better
//import "golang.org/x/net/proxy"
import "fmt"
import "net"
import "regexp"
import "encoding/hex"
import _ "net/http/pprof"
import "net/http"
import "runtime"
import "os"
import "github.com/gologme/log"
import "github.com/yggdrasil-network/yggdrasil-go/src/address"
import "github.com/yggdrasil-network/yggdrasil-go/src/config"
import "github.com/yggdrasil-network/yggdrasil-go/src/crypto"
import "github.com/yggdrasil-network/yggdrasil-go/src/defaults"
// Start the profiler in debug builds, if the required environment variable is set.
func init() {
envVarName := "PPROFLISTEN"
hostPort := os.Getenv(envVarName)
switch {
case hostPort == "":
fmt.Printf("DEBUG: %s not set, profiler not started.\n", envVarName)
default:
fmt.Printf("DEBUG: Starting pprof on %s\n", hostPort)
go func() { fmt.Println(http.ListenAndServe(hostPort, nil)) }()
}
}
// Starts the function profiler. This is only supported when built with
// '-tags build'.
func StartProfiler(log *log.Logger) error {
runtime.SetBlockProfileRate(1)
go func() { log.Println(http.ListenAndServe("localhost:6060", nil)) }()
return nil
}
// This function is only called by the simulator to set up a node with random
// keys. It should not be used and may be removed in the future.
func (c *Core) Init() {
bpub, bpriv := crypto.NewBoxKeys()
spub, spriv := crypto.NewSigKeys()
hbpub := hex.EncodeToString(bpub[:])
hbpriv := hex.EncodeToString(bpriv[:])
hspub := hex.EncodeToString(spub[:])
hspriv := hex.EncodeToString(spriv[:])
c.config = config.NodeConfig{
EncryptionPublicKey: hbpub,
EncryptionPrivateKey: hbpriv,
SigningPublicKey: hspub,
SigningPrivateKey: hspriv,
}
c.init( /*bpub, bpriv, spub, spriv*/ )
c.switchTable.start()
c.router.start()
}
////////////////////////////////////////////////////////////////////////////////
// Core
func (c *Core) DEBUG_getSigningPublicKey() crypto.SigPubKey {
return (crypto.SigPubKey)(c.sigPub)
}
func (c *Core) DEBUG_getEncryptionPublicKey() crypto.BoxPubKey {
return (crypto.BoxPubKey)(c.boxPub)
}
func (c *Core) DEBUG_getSend() chan<- []byte {
return c.router.tun.send
}
func (c *Core) DEBUG_getRecv() <-chan []byte {
return c.router.tun.recv
}
// Peer
func (c *Core) DEBUG_getPeers() *peers {
return &c.peers
}
func (ps *peers) DEBUG_newPeer(box crypto.BoxPubKey, sig crypto.SigPubKey, link crypto.BoxSharedKey) *peer {
sim := linkInterface{
name: "(simulator)",
info: linkInfo{
local: "(simulator)",
remote: "(simulator)",
linkType: "sim",
},
}
return ps.newPeer(&box, &sig, &link, &sim, nil)
}
/*
func (ps *peers) DEBUG_startPeers() {
ps.mutex.RLock()
defer ps.mutex.RUnlock()
for _, p := range ps.ports {
if p == nil { continue }
go p.MainLoop()
}
}
*/
func (ps *peers) DEBUG_hasPeer(key crypto.SigPubKey) bool {
ports := ps.ports.Load().(map[switchPort]*peer)
for _, p := range ports {
if p == nil {
continue
}
if p.sig == key {
return true
}
}
return false
}
func (ps *peers) DEBUG_getPorts() map[switchPort]*peer {
ports := ps.ports.Load().(map[switchPort]*peer)
newPeers := make(map[switchPort]*peer)
for port, p := range ports {
newPeers[port] = p
}
return newPeers
}
func (p *peer) DEBUG_getSigKey() crypto.SigPubKey {
return p.sig
}
func (p *peer) DEEBUG_getPort() switchPort {
return p.port
}
// Router
func (c *Core) DEBUG_getSwitchTable() *switchTable {
return &c.switchTable
}
func (c *Core) DEBUG_getLocator() switchLocator {
return c.switchTable.getLocator()
}
func (l *switchLocator) DEBUG_getCoords() []byte {
return l.getCoords()
}
func (c *Core) DEBUG_switchLookup(dest []byte) switchPort {
return c.switchTable.DEBUG_lookup(dest)
}
// This does the switch layer lookups that decide how to route traffic.
// Traffic uses greedy routing in a metric space, where the metric distance between nodes is equal to the distance between them on the tree.
// Traffic must be routed to a node that is closer to the destination via the metric space distance.
// In the event that two nodes are equally close, it gets routed to the one with the longest uptime (due to the order that things are iterated over).
// The size of the outgoing packet queue is added to a node's tree distance when the cost of forwarding to a node, subject to the constraint that the real tree distance puts them closer to the destination than ourself.
// Doing so adds a limited form of backpressure routing, based on local information, which allows us to forward traffic around *local* bottlenecks, provided that another greedy path exists.
func (t *switchTable) DEBUG_lookup(dest []byte) switchPort {
table := t.getTable()
myDist := table.self.dist(dest)
if myDist == 0 {
return 0
}
// cost is in units of (expected distance) + (expected queue size), where expected distance is used as an approximation of the minimum backpressure gradient needed for packets to flow
ports := t.core.peers.getPorts()
var best switchPort
bestCost := int64(^uint64(0) >> 1)
for _, info := range table.elems {
dist := info.locator.dist(dest)
if !(dist < myDist) {
continue
}
//p, isIn := ports[info.port]
_, isIn := ports[info.port]
if !isIn {
continue
}
cost := int64(dist) // + p.getQueueSize()
if cost < bestCost {
best = info.port
bestCost = cost
}
}
return best
}
/*
func (t *switchTable) DEBUG_isDirty() bool {
//data := t.data.Load().(*tabledata)
t.mutex.RLock()
defer t.mutex.RUnlock()
data := t.data
return data.dirty
}
*/
func (t *switchTable) DEBUG_dumpTable() {
//data := t.data.Load().(*tabledata)
t.mutex.RLock()
defer t.mutex.RUnlock()
data := t.data
for _, peer := range data.peers {
//fmt.Println("DUMPTABLE:", t.treeID, peer.treeID, peer.port,
// peer.locator.Root, peer.coords,
// peer.reverse.Root, peer.reverse.Coords, peer.forward)
fmt.Println("DUMPTABLE:", t.key, peer.key, peer.locator.coords, peer.port /*, peer.forward*/)
}
}
func (t *switchTable) DEBUG_getReversePort(port switchPort) switchPort {
// Returns Port(0) if it cannot get the reverse peer for any reason
//data := t.data.Load().(*tabledata)
t.mutex.RLock()
defer t.mutex.RUnlock()
data := t.data
if port >= switchPort(len(data.peers)) {
return switchPort(0)
}
pinfo := data.peers[port]
if len(pinfo.locator.coords) < 1 {
return switchPort(0)
}
return pinfo.locator.coords[len(pinfo.locator.coords)-1]
}
// Wire
func DEBUG_wire_encode_coords(coords []byte) []byte {
return wire_encode_coords(coords)
}
// DHT, via core
func (c *Core) DEBUG_getDHTSize() int {
var total int
c.router.doAdmin(func() {
total = len(c.dht.table)
})
return total
}
// TUN defaults
func (c *Core) DEBUG_GetTUNDefaultIfName() string {
return defaults.GetDefaults().DefaultIfName
}
func (c *Core) DEBUG_GetTUNDefaultIfMTU() int {
return defaults.GetDefaults().DefaultIfMTU
}
func (c *Core) DEBUG_GetTUNDefaultIfTAPMode() bool {
return defaults.GetDefaults().DefaultIfTAPMode
}
// udpInterface
// FIXME udpInterface isn't exported
// So debug functions need to work differently...
/*
func (c *Core) DEBUG_setupLoopbackUDPInterface() {
iface := udpInterface{}
iface.init(c, "[::1]:0")
c.ifaces = append(c.ifaces[:0], &iface)
}
*/
/*
func (c *Core) DEBUG_getLoopbackAddr() net.Addr {
iface := c.ifaces[0]
return iface.sock.LocalAddr()
}
*/
/*
func (c *Core) DEBUG_addLoopbackPeer(addr *net.UDPAddr,
in (chan<- []byte),
out (<-chan []byte)) {
iface := c.ifaces[0]
iface.addPeer(addr, in, out)
}
*/
/*
func (c *Core) DEBUG_startLoopbackUDPInterface() {
iface := c.ifaces[0]
go iface.reader()
for addr, chs := range iface.peers {
udpAddr, err := net.ResolveUDPAddr("udp6", addr)
if err != nil { panic(err) }
go iface.writer(udpAddr, chs.out)
}
}
*/
////////////////////////////////////////////////////////////////////////////////
func (c *Core) DEBUG_getAddr() *address.Address {
return address.AddrForNodeID(&c.dht.nodeID)
}
func (c *Core) DEBUG_startTun(ifname string, iftapmode bool) {
c.DEBUG_startTunWithMTU(ifname, iftapmode, 1280)
}
func (c *Core) DEBUG_startTunWithMTU(ifname string, iftapmode bool, mtu int) {
addr := c.DEBUG_getAddr()
straddr := fmt.Sprintf("%s/%v", net.IP(addr[:]).String(), 8*len(address.GetPrefix()))
if ifname != "none" {
err := c.router.tun.setup(ifname, iftapmode, straddr, mtu)
if err != nil {
panic(err)
}
c.log.Println("Setup TUN/TAP:", c.router.tun.iface.Name(), straddr)
go func() { panic(c.router.tun.read()) }()
}
go func() { panic(c.router.tun.write()) }()
}
func (c *Core) DEBUG_stopTun() {
c.router.tun.close()
}
////////////////////////////////////////////////////////////////////////////////
func (c *Core) DEBUG_newBoxKeys() (*crypto.BoxPubKey, *crypto.BoxPrivKey) {
return crypto.NewBoxKeys()
}
func (c *Core) DEBUG_getSharedKey(myPrivKey *crypto.BoxPrivKey, othersPubKey *crypto.BoxPubKey) *crypto.BoxSharedKey {
return crypto.GetSharedKey(myPrivKey, othersPubKey)
}
func (c *Core) DEBUG_newSigKeys() (*crypto.SigPubKey, *crypto.SigPrivKey) {
return crypto.NewSigKeys()
}
func (c *Core) DEBUG_getNodeID(pub *crypto.BoxPubKey) *crypto.NodeID {
return crypto.GetNodeID(pub)
}
func (c *Core) DEBUG_getTreeID(pub *crypto.SigPubKey) *crypto.TreeID {
return crypto.GetTreeID(pub)
}
func (c *Core) DEBUG_addrForNodeID(nodeID *crypto.NodeID) string {
return net.IP(address.AddrForNodeID(nodeID)[:]).String()
}
func (c *Core) DEBUG_init(bpub []byte,
bpriv []byte,
spub []byte,
spriv []byte) {
/*var boxPub crypto.BoxPubKey
var boxPriv crypto.BoxPrivKey
var sigPub crypto.SigPubKey
var sigPriv crypto.SigPrivKey
copy(boxPub[:], bpub)
copy(boxPriv[:], bpriv)
copy(sigPub[:], spub)
copy(sigPriv[:], spriv)
c.init(&boxPub, &boxPriv, &sigPub, &sigPriv)*/
hbpub := hex.EncodeToString(bpub[:])
hbpriv := hex.EncodeToString(bpriv[:])
hspub := hex.EncodeToString(spub[:])
hspriv := hex.EncodeToString(spriv[:])
c.config = config.NodeConfig{
EncryptionPublicKey: hbpub,
EncryptionPrivateKey: hbpriv,
SigningPublicKey: hspub,
SigningPrivateKey: hspriv,
}
c.init( /*bpub, bpriv, spub, spriv*/ )
if err := c.router.start(); err != nil {
panic(err)
}
}
////////////////////////////////////////////////////////////////////////////////
/*
func (c *Core) DEBUG_setupAndStartGlobalUDPInterface(addrport string) {
if err := c.udp.init(c, addrport); err != nil {
c.log.Println("Failed to start UDP interface:", err)
panic(err)
}
}
func (c *Core) DEBUG_getGlobalUDPAddr() *net.UDPAddr {
return c.udp.sock.LocalAddr().(*net.UDPAddr)
}
func (c *Core) DEBUG_maybeSendUDPKeys(saddr string) {
udpAddr, err := net.ResolveUDPAddr("udp", saddr)
if err != nil {
panic(err)
}
var addr connAddr
addr.fromUDPAddr(udpAddr)
c.udp.mutex.RLock()
_, isIn := c.udp.conns[addr]
c.udp.mutex.RUnlock()
if !isIn {
c.udp.sendKeys(addr)
}
}
*/
////////////////////////////////////////////////////////////////////////////////
func (c *Core) DEBUG_addPeer(addr string) {
err := c.admin.addPeer(addr, "")
if err != nil {
panic(err)
}
}
/*
func (c *Core) DEBUG_addSOCKSConn(socksaddr, peeraddr string) {
go func() {
dialer, err := proxy.SOCKS5("tcp", socksaddr, nil, proxy.Direct)
if err == nil {
conn, err := dialer.Dial("tcp", peeraddr)
if err == nil {
c.tcp.callWithConn(&wrappedConn{
c: conn,
raddr: &wrappedAddr{
network: "tcp",
addr: peeraddr,
},
})
}
}
}()
}
*/
//*
func (c *Core) DEBUG_setupAndStartGlobalTCPInterface(addrport string) {
c.config.Listen = []string{addrport}
if err := c.link.init(c); err != nil {
c.log.Println("Failed to start interfaces:", err)
panic(err)
}
}
func (c *Core) DEBUG_getGlobalTCPAddr() *net.TCPAddr {
return c.link.tcp.getAddr()
}
func (c *Core) DEBUG_addTCPConn(saddr string) {
c.link.tcp.call(saddr, nil, "")
}
//*/
/*
func (c *Core) DEBUG_startSelfPeer() {
c.Peers.mutex.RLock()
defer c.Peers.mutex.RUnlock()
p := c.Peers.ports[0]
go p.MainLoop()
}
*/
////////////////////////////////////////////////////////////////////////////////
/*
func (c *Core) DEBUG_setupAndStartGlobalKCPInterface(addrport string) {
iface := kcpInterface{}
iface.init(c, addrport)
c.kcp = &iface
}
func (c *Core) DEBUG_getGlobalKCPAddr() net.Addr {
return c.kcp.serv.Addr()
}
func (c *Core) DEBUG_addKCPConn(saddr string) {
c.kcp.call(saddr)
}
*/
////////////////////////////////////////////////////////////////////////////////
func (c *Core) DEBUG_setupAndStartAdminInterface(addrport string) {
a := admin{}
c.config.AdminListen = addrport
a.init(c /*, addrport*/)
c.admin = a
}
func (c *Core) DEBUG_setupAndStartMulticastInterface() {
m := multicast{}
m.init(c)
c.multicast = m
m.start()
}
////////////////////////////////////////////////////////////////////////////////
func (c *Core) DEBUG_setLogger(log *log.Logger) {
c.log = log
}
func (c *Core) DEBUG_setIfceExpr(expr *regexp.Regexp) {
c.log.Println("DEBUG_setIfceExpr no longer implemented")
}
func (c *Core) DEBUG_addAllowedEncryptionPublicKey(boxStr string) {
err := c.admin.addAllowedEncryptionPublicKey(boxStr)
if err != nil {
panic(err)
}
}
////////////////////////////////////////////////////////////////////////////////
func DEBUG_simLinkPeers(p, q *peer) {
// Sets q.out() to point to p and starts p.linkLoop()
goWorkers := func(source, dest *peer) {
source.linkOut = make(chan []byte, 1)
send := make(chan []byte, 1)
source.out = func(bs []byte) {
send <- bs
}
go source.linkLoop()
go func() {
var packets [][]byte
for {
select {
case packet := <-source.linkOut:
packets = append(packets, packet)
continue
case packet := <-send:
packets = append(packets, packet)
source.core.switchTable.idleIn <- source.port
continue
default:
}
if len(packets) > 0 {
dest.handlePacket(packets[0])
packets = packets[1:]
continue
}
select {
case packet := <-source.linkOut:
packets = append(packets, packet)
case packet := <-send:
packets = append(packets, packet)
source.core.switchTable.idleIn <- source.port
}
}
}()
}
goWorkers(p, q)
goWorkers(q, p)
p.core.switchTable.idleIn <- p.port
q.core.switchTable.idleIn <- q.port
}
func (c *Core) DEBUG_simFixMTU() {
c.router.tun.mtu = 65535
}
////////////////////////////////////////////////////////////////////////////////
func Util_testAddrIDMask() {
for idx := 0; idx < 16; idx++ {
var orig crypto.NodeID
orig[8] = 42
for bidx := 0; bidx < idx; bidx++ {
orig[bidx/8] |= (0x80 >> uint8(bidx%8))
}
addr := address.AddrForNodeID(&orig)
nid, mask := addr.GetNodeIDandMask()
for b := 0; b < len(mask); b++ {
nid[b] &= mask[b]
orig[b] &= mask[b]
}
if *nid != orig {
fmt.Println(orig)
fmt.Println(*addr)
fmt.Println(*nid)
fmt.Println(*mask)
panic(idx)
}
}
}