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mirror of https://github.com/cwinfo/yggdrasil-go.git synced 2024-11-22 10:40:27 +00:00

Merge pull request #252 from Arceliar/refactoring

Refactoring
This commit is contained in:
Arceliar 2018-12-15 18:26:04 -06:00 committed by GitHub
commit 1a1e0553aa
No known key found for this signature in database
GPG Key ID: 4AEE18F83AFDEB23
21 changed files with 623 additions and 573 deletions

View File

@ -12,11 +12,16 @@ This only matters if it's high enough to make you the root of the tree.
*/
package main
import "encoding/hex"
import "flag"
import "fmt"
import "runtime"
import . "github.com/yggdrasil-network/yggdrasil-go/src/yggdrasil"
import (
"encoding/hex"
"flag"
"fmt"
"net"
"runtime"
"github.com/yggdrasil-network/yggdrasil-go/src/address"
"github.com/yggdrasil-network/yggdrasil-go/src/crypto"
)
var doSig = flag.Bool("sig", false, "generate new signing keys instead")
@ -82,12 +87,7 @@ func isBetter(oldID, newID []byte) bool {
}
func doBoxKeys(out chan<- keySet, in <-chan []byte) {
c := Core{}
pub, _ := c.DEBUG_newBoxKeys()
bestID := c.DEBUG_getNodeID(pub)
for idx := range bestID {
bestID[idx] = 0
}
var bestID crypto.NodeID
for {
select {
case newBestID := <-in:
@ -95,22 +95,20 @@ func doBoxKeys(out chan<- keySet, in <-chan []byte) {
copy(bestID[:], newBestID)
}
default:
pub, priv := c.DEBUG_newBoxKeys()
id := c.DEBUG_getNodeID(pub)
pub, priv := crypto.NewBoxKeys()
id := crypto.GetNodeID(pub)
if !isBetter(bestID[:], id[:]) {
continue
}
bestID = id
ip := c.DEBUG_addrForNodeID(id)
bestID = *id
ip := net.IP(address.AddrForNodeID(id)[:]).String()
out <- keySet{priv[:], pub[:], id[:], ip}
}
}
}
func doSigKeys(out chan<- keySet, in <-chan []byte) {
c := Core{}
pub, _ := c.DEBUG_newSigKeys()
bestID := c.DEBUG_getTreeID(pub)
var bestID crypto.TreeID
for idx := range bestID {
bestID[idx] = 0
}
@ -122,12 +120,12 @@ func doSigKeys(out chan<- keySet, in <-chan []byte) {
}
default:
}
pub, priv := c.DEBUG_newSigKeys()
id := c.DEBUG_getTreeID(pub)
pub, priv := crypto.NewSigKeys()
id := crypto.GetTreeID(pub)
if !isBetter(bestID[:], id[:]) {
continue
}
bestID = id
bestID = *id
out <- keySet{priv[:], pub[:], id[:], ""}
}
}

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@ -1,21 +1,26 @@
package yggdrasil
package address
import "github.com/yggdrasil-network/yggdrasil-go/src/crypto"
// address represents an IPv6 address in the yggdrasil address range.
type address [16]byte
type Address [16]byte
// subnet represents an IPv6 /64 subnet in the yggdrasil subnet range.
type subnet [8]byte
type Subnet [8]byte
// address_prefix is the prefix used for all addresses and subnets in the network.
// The current implementation requires this to be a muliple of 8 bits + 7 bits.
// The 8th bit of the last byte is used to signal nodes (0) or /64 prefixes (1).
// Nodes that configure this differently will be unable to communicate with eachother, though routing and the DHT machinery *should* still work.
var address_prefix = [...]byte{0x02}
func GetPrefix() [1]byte {
return [...]byte{0x02}
}
// isValid returns true if an address falls within the range used by nodes in the network.
func (a *address) isValid() bool {
for idx := range address_prefix {
if (*a)[idx] != address_prefix[idx] {
func (a *Address) IsValid() bool {
prefix := GetPrefix()
for idx := range prefix {
if (*a)[idx] != prefix[idx] {
return false
}
}
@ -23,28 +28,29 @@ func (a *address) isValid() bool {
}
// isValid returns true if a prefix falls within the range usable by the network.
func (s *subnet) isValid() bool {
l := len(address_prefix)
for idx := range address_prefix[:l-1] {
if (*s)[idx] != address_prefix[idx] {
func (s *Subnet) IsValid() bool {
prefix := GetPrefix()
l := len(prefix)
for idx := range prefix[:l-1] {
if (*s)[idx] != prefix[idx] {
return false
}
}
return (*s)[l-1] == address_prefix[l-1]|0x01
return (*s)[l-1] == prefix[l-1]|0x01
}
// address_addrForNodeID takes a *NodeID as an argument and returns an *address.
// This subnet begins with the address prefix, with the last bit set to 0 to indicate an address.
// The following 8 bits are set to the number of leading 1 bits in the NodeID.
// The NodeID, excluding the leading 1 bits and the first leading 0 bit, is truncated to the appropriate length and makes up the remainder of the address.
func address_addrForNodeID(nid *NodeID) *address {
func AddrForNodeID(nid *crypto.NodeID) *Address {
// 128 bit address
// Begins with prefix
// Next bit is a 0
// Next 7 bits, interpreted as a uint, are # of leading 1s in the NodeID
// Leading 1s and first leading 0 of the NodeID are truncated off
// The rest is appended to the IPv6 address (truncated to 128 bits total)
var addr address
var addr Address
var temp []byte
done := false
ones := byte(0)
@ -67,9 +73,10 @@ func address_addrForNodeID(nid *NodeID) *address {
temp = append(temp, bits)
}
}
copy(addr[:], address_prefix[:])
addr[len(address_prefix)] = ones
copy(addr[len(address_prefix)+1:], temp)
prefix := GetPrefix()
copy(addr[:], prefix[:])
addr[len(prefix)] = ones
copy(addr[len(prefix)+1:], temp)
return &addr
}
@ -77,14 +84,15 @@ func address_addrForNodeID(nid *NodeID) *address {
// This subnet begins with the address prefix, with the last bit set to 1 to indicate a prefix.
// The following 8 bits are set to the number of leading 1 bits in the NodeID.
// The NodeID, excluding the leading 1 bits and the first leading 0 bit, is truncated to the appropriate length and makes up the remainder of the subnet.
func address_subnetForNodeID(nid *NodeID) *subnet {
func SubnetForNodeID(nid *crypto.NodeID) *Subnet {
// Exactly as the address version, with two exceptions:
// 1) The first bit after the fixed prefix is a 1 instead of a 0
// 2) It's truncated to a subnet prefix length instead of 128 bits
addr := *address_addrForNodeID(nid)
var snet subnet
addr := *AddrForNodeID(nid)
var snet Subnet
copy(snet[:], addr[:])
snet[len(address_prefix)-1] |= 0x01
prefix := GetPrefix()
snet[len(prefix)-1] |= 0x01
return &snet
}
@ -92,17 +100,18 @@ func address_subnetForNodeID(nid *NodeID) *subnet {
// The first is a NodeID with all the bits known from the address set to their correct values.
// The second is a bitmask with 1 bit set for each bit that was known from the address.
// This is used to look up NodeIDs in the DHT and tell if they match an address.
func (a *address) getNodeIDandMask() (*NodeID, *NodeID) {
func (a *Address) GetNodeIDandMask() (*crypto.NodeID, *crypto.NodeID) {
// Mask is a bitmask to mark the bits visible from the address
// This means truncated leading 1s, first leading 0, and visible part of addr
var nid NodeID
var mask NodeID
ones := int(a[len(address_prefix)])
var nid crypto.NodeID
var mask crypto.NodeID
prefix := GetPrefix()
ones := int(a[len(prefix)])
for idx := 0; idx < ones; idx++ {
nid[idx/8] |= 0x80 >> byte(idx%8)
}
nidOffset := ones + 1
addrOffset := 8*len(address_prefix) + 8
addrOffset := 8*len(prefix) + 8
for idx := addrOffset; idx < 8*len(a); idx++ {
bits := a[idx/8] & (0x80 >> byte(idx%8))
bits <<= byte(idx % 8)
@ -110,7 +119,7 @@ func (a *address) getNodeIDandMask() (*NodeID, *NodeID) {
bits >>= byte(nidIdx % 8)
nid[nidIdx/8] |= bits
}
maxMask := 8*(len(a)-len(address_prefix)-1) + ones + 1
maxMask := 8*(len(a)-len(prefix)-1) + ones + 1
for idx := 0; idx < maxMask; idx++ {
mask[idx/8] |= 0x80 >> byte(idx%8)
}
@ -121,16 +130,17 @@ func (a *address) getNodeIDandMask() (*NodeID, *NodeID) {
// The first is a NodeID with all the bits known from the address set to their correct values.
// The second is a bitmask with 1 bit set for each bit that was known from the subnet.
// This is used to look up NodeIDs in the DHT and tell if they match a subnet.
func (s *subnet) getNodeIDandMask() (*NodeID, *NodeID) {
func (s *Subnet) GetNodeIDandMask() (*crypto.NodeID, *crypto.NodeID) {
// As with the address version, but visible parts of the subnet prefix instead
var nid NodeID
var mask NodeID
ones := int(s[len(address_prefix)])
var nid crypto.NodeID
var mask crypto.NodeID
prefix := GetPrefix()
ones := int(s[len(prefix)])
for idx := 0; idx < ones; idx++ {
nid[idx/8] |= 0x80 >> byte(idx%8)
}
nidOffset := ones + 1
addrOffset := 8*len(address_prefix) + 8
addrOffset := 8*len(prefix) + 8
for idx := addrOffset; idx < 8*len(s); idx++ {
bits := s[idx/8] & (0x80 >> byte(idx%8))
bits <<= byte(idx % 8)
@ -138,7 +148,7 @@ func (s *subnet) getNodeIDandMask() (*NodeID, *NodeID) {
bits >>= byte(nidIdx % 8)
nid[nidIdx/8] |= bits
}
maxMask := 8*(len(s)-len(address_prefix)-1) + ones + 1
maxMask := 8*(len(s)-len(prefix)-1) + ones + 1
for idx := 0; idx < maxMask; idx++ {
mask[idx/8] |= 0x80 >> byte(idx%8)
}

187
src/crypto/crypto.go Normal file
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@ -0,0 +1,187 @@
package crypto
/*
This part of the package wraps crypto operations needed elsewhere
In particular, it exposes key generation for ed25519 and nacl box
It also defines NodeID and TreeID as hashes of keys, and wraps hash functions
*/
import (
"crypto/rand"
"crypto/sha512"
"golang.org/x/crypto/ed25519"
"golang.org/x/crypto/nacl/box"
"github.com/yggdrasil-network/yggdrasil-go/src/util"
)
////////////////////////////////////////////////////////////////////////////////
// NodeID and TreeID
const NodeIDLen = sha512.Size
const TreeIDLen = sha512.Size
const handleLen = 8
type NodeID [NodeIDLen]byte
type TreeID [TreeIDLen]byte
type Handle [handleLen]byte
func GetNodeID(pub *BoxPubKey) *NodeID {
h := sha512.Sum512(pub[:])
return (*NodeID)(&h)
}
func GetTreeID(pub *SigPubKey) *TreeID {
h := sha512.Sum512(pub[:])
return (*TreeID)(&h)
}
func NewHandle() *Handle {
var h Handle
_, err := rand.Read(h[:])
if err != nil {
panic(err)
}
return &h
}
////////////////////////////////////////////////////////////////////////////////
// Signatures
const SigPubKeyLen = ed25519.PublicKeySize
const SigPrivKeyLen = ed25519.PrivateKeySize
const SigLen = ed25519.SignatureSize
type SigPubKey [SigPubKeyLen]byte
type SigPrivKey [SigPrivKeyLen]byte
type SigBytes [SigLen]byte
func NewSigKeys() (*SigPubKey, *SigPrivKey) {
var pub SigPubKey
var priv SigPrivKey
pubSlice, privSlice, err := ed25519.GenerateKey(rand.Reader)
if err != nil {
panic(err)
}
copy(pub[:], pubSlice)
copy(priv[:], privSlice)
return &pub, &priv
}
func Sign(priv *SigPrivKey, msg []byte) *SigBytes {
var sig SigBytes
sigSlice := ed25519.Sign(priv[:], msg)
copy(sig[:], sigSlice)
return &sig
}
func Verify(pub *SigPubKey, msg []byte, sig *SigBytes) bool {
// Should sig be an array instead of a slice?...
// It's fixed size, but
return ed25519.Verify(pub[:], msg, sig[:])
}
////////////////////////////////////////////////////////////////////////////////
// NaCl-like crypto "box" (curve25519+xsalsa20+poly1305)
const BoxPubKeyLen = 32
const BoxPrivKeyLen = 32
const BoxSharedKeyLen = 32
const BoxNonceLen = 24
const BoxOverhead = box.Overhead
type BoxPubKey [BoxPubKeyLen]byte
type BoxPrivKey [BoxPrivKeyLen]byte
type BoxSharedKey [BoxSharedKeyLen]byte
type BoxNonce [BoxNonceLen]byte
func NewBoxKeys() (*BoxPubKey, *BoxPrivKey) {
pubBytes, privBytes, err := box.GenerateKey(rand.Reader)
if err != nil {
panic(err)
}
pub := (*BoxPubKey)(pubBytes)
priv := (*BoxPrivKey)(privBytes)
return pub, priv
}
func GetSharedKey(myPrivKey *BoxPrivKey,
othersPubKey *BoxPubKey) *BoxSharedKey {
var shared [BoxSharedKeyLen]byte
priv := (*[BoxPrivKeyLen]byte)(myPrivKey)
pub := (*[BoxPubKeyLen]byte)(othersPubKey)
box.Precompute(&shared, pub, priv)
return (*BoxSharedKey)(&shared)
}
func BoxOpen(shared *BoxSharedKey,
boxed []byte,
nonce *BoxNonce) ([]byte, bool) {
out := util.GetBytes()
s := (*[BoxSharedKeyLen]byte)(shared)
n := (*[BoxNonceLen]byte)(nonce)
unboxed, success := box.OpenAfterPrecomputation(out, boxed, n, s)
return unboxed, success
}
func BoxSeal(shared *BoxSharedKey, unboxed []byte, nonce *BoxNonce) ([]byte, *BoxNonce) {
if nonce == nil {
nonce = NewBoxNonce()
}
nonce.Increment()
out := util.GetBytes()
s := (*[BoxSharedKeyLen]byte)(shared)
n := (*[BoxNonceLen]byte)(nonce)
boxed := box.SealAfterPrecomputation(out, unboxed, n, s)
return boxed, nonce
}
func NewBoxNonce() *BoxNonce {
var nonce BoxNonce
_, err := rand.Read(nonce[:])
for ; err == nil && nonce[0] == 0xff; _, err = rand.Read(nonce[:]) {
// Make sure nonce isn't too high
// This is just to make rollover unlikely to happen
// Rollover is fine, but it may kill the session and force it to reopen
}
if err != nil {
panic(err)
}
return &nonce
}
func (n *BoxNonce) Increment() {
oldNonce := *n
n[len(n)-1] += 2
for i := len(n) - 2; i >= 0; i-- {
if n[i+1] < oldNonce[i+1] {
n[i] += 1
}
}
}
// Used to subtract one nonce from another, staying in the range +- 64.
// This is used by the nonce progression machinery to advance the bitmask of recently received packets (indexed by nonce), or to check the appropriate bit of the bitmask.
// It's basically part of the machinery that prevents replays and duplicate packets.
func (n *BoxNonce) Minus(m *BoxNonce) int64 {
diff := int64(0)
for idx := range n {
diff *= 256
diff += int64(n[idx]) - int64(m[idx])
if diff > 64 {
diff = 64
}
if diff < -64 {
diff = -64
}
}
return diff
}

View File

@ -1,21 +1,21 @@
package yggdrasil
package util
// These are misc. utility functions that didn't really fit anywhere else
import "runtime"
// A wrapper around runtime.Gosched() so it doesn't need to be imported elsewhere.
func util_yield() {
func Yield() {
runtime.Gosched()
}
// A wrapper around runtime.LockOSThread() so it doesn't need to be imported elsewhere.
func util_lockthread() {
func LockThread() {
runtime.LockOSThread()
}
// A wrapper around runtime.UnlockOSThread() so it doesn't need to be imported elsewhere.
func util_unlockthread() {
func UnlockThread() {
runtime.UnlockOSThread()
}
@ -23,15 +23,12 @@ func util_unlockthread() {
// It's used like a sync.Pool, but with a fixed size and typechecked without type casts to/from interface{} (which were making the profiles look ugly).
var byteStore chan []byte
// Initializes the byteStore
func util_initByteStore() {
if byteStore == nil {
byteStore = make(chan []byte, 32)
}
func init() {
byteStore = make(chan []byte, 32)
}
// Gets an empty slice from the byte store, if one is available, or else returns a new nil slice.
func util_getBytes() []byte {
func GetBytes() []byte {
select {
case bs := <-byteStore:
return bs[:0]
@ -41,7 +38,7 @@ func util_getBytes() []byte {
}
// Puts a slice in the store, if there's room, or else returns and lets the slice get collected.
func util_putBytes(bs []byte) {
func PutBytes(bs []byte) {
select {
case byteStore <- bs:
default:

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@ -14,6 +14,8 @@ import (
"sync/atomic"
"time"
"github.com/yggdrasil-network/yggdrasil-go/src/address"
"github.com/yggdrasil-network/yggdrasil-go/src/crypto"
"github.com/yggdrasil-network/yggdrasil-go/src/defaults"
)
@ -314,7 +316,7 @@ func (a *admin) init(c *Core, listenaddr string) {
"box_pub_key": hex.EncodeToString(dinfo.key[:]),
"coords": fmt.Sprintf("%v", dinfo.coords),
}
addr := net.IP(address_addrForNodeID(getNodeID(&dinfo.key))[:]).String()
addr := net.IP(address.AddrForNodeID(crypto.GetNodeID(&dinfo.key))[:]).String()
infos[addr] = info
}
return admin_info{"nodes": infos}, nil
@ -553,7 +555,7 @@ func (a *admin) startTunWithMTU(ifname string, iftapmode bool, ifmtu int) error
_ = a.core.router.tun.close()
// Then reconfigure and start it
addr := a.core.router.addr
straddr := fmt.Sprintf("%s/%v", net.IP(addr[:]).String(), 8*len(address_prefix)-1)
straddr := fmt.Sprintf("%s/%v", net.IP(addr[:]).String(), 8*len(address.GetPrefix())-1)
if ifname != "none" {
err := a.core.router.tun.setup(ifname, iftapmode, straddr, ifmtu)
if err != nil {
@ -607,7 +609,7 @@ func (a *admin) getData_getPeers() []admin_nodeInfo {
sort.Slice(ps, func(i, j int) bool { return ps[i] < ps[j] })
for _, port := range ps {
p := ports[port]
addr := *address_addrForNodeID(getNodeID(&p.box))
addr := *address.AddrForNodeID(crypto.GetNodeID(&p.box))
info := admin_nodeInfo{
{"ip", net.IP(addr[:]).String()},
{"port", port},
@ -632,7 +634,7 @@ func (a *admin) getData_getSwitchPeers() []admin_nodeInfo {
if !isIn {
continue
}
addr := *address_addrForNodeID(getNodeID(&peer.box))
addr := *address.AddrForNodeID(crypto.GetNodeID(&peer.box))
coords := elem.locator.getCoords()
info := admin_nodeInfo{
{"ip", net.IP(addr[:]).String()},
@ -690,7 +692,7 @@ func (a *admin) getData_getDHT() []admin_nodeInfo {
return dht_ordered(&a.core.dht.nodeID, dhtInfos[i].getNodeID(), dhtInfos[j].getNodeID())
})
for _, v := range dhtInfos {
addr := *address_addrForNodeID(v.getNodeID())
addr := *address.AddrForNodeID(v.getNodeID())
info := admin_nodeInfo{
{"ip", net.IP(addr[:]).String()},
{"coords", fmt.Sprint(v.coords)},
@ -740,7 +742,7 @@ func (a *admin) getAllowedEncryptionPublicKeys() []string {
func (a *admin) addAllowedEncryptionPublicKey(bstr string) (err error) {
boxBytes, err := hex.DecodeString(bstr)
if err == nil {
var box boxPubKey
var box crypto.BoxPubKey
copy(box[:], boxBytes)
a.core.peers.addAllowedEncryptionPublicKey(&box)
}
@ -752,7 +754,7 @@ func (a *admin) addAllowedEncryptionPublicKey(bstr string) (err error) {
func (a *admin) removeAllowedEncryptionPublicKey(bstr string) (err error) {
boxBytes, err := hex.DecodeString(bstr)
if err == nil {
var box boxPubKey
var box crypto.BoxPubKey
copy(box[:], boxBytes)
a.core.peers.removeAllowedEncryptionPublicKey(&box)
}
@ -761,7 +763,7 @@ func (a *admin) removeAllowedEncryptionPublicKey(bstr string) (err error) {
// Send a DHT ping to the node with the provided key and coords, optionally looking up the specified target NodeID.
func (a *admin) admin_dhtPing(keyString, coordString, targetString string) (dhtRes, error) {
var key boxPubKey
var key crypto.BoxPubKey
if keyBytes, err := hex.DecodeString(keyString); err != nil {
return dhtRes{}, err
} else {
@ -792,7 +794,7 @@ func (a *admin) admin_dhtPing(keyString, coordString, targetString string) (dhtR
} else if len(targetBytes) != len(target) {
return dhtRes{}, errors.New("Incorrect target NodeID length")
} else {
target = NodeID{}
var target crypto.NodeID
copy(target[:], targetBytes)
}
rq := dhtReqKey{info.key, target}
@ -818,7 +820,7 @@ func (a *admin) admin_dhtPing(keyString, coordString, targetString string) (dhtR
}
func (a *admin) admin_getNodeInfo(keyString, coordString string, nocache bool) (nodeinfoPayload, error) {
var key boxPubKey
var key crypto.BoxPubKey
if keyBytes, err := hex.DecodeString(keyString); err != nil {
return nodeinfoPayload{}, err
} else {

View File

@ -7,6 +7,9 @@ import (
"fmt"
"net"
"sort"
"github.com/yggdrasil-network/yggdrasil-go/src/address"
"github.com/yggdrasil-network/yggdrasil-go/src/crypto"
)
// This module implements crypto-key routing, similar to Wireguard, where we
@ -17,15 +20,15 @@ type cryptokey struct {
enabled bool
ipv4routes []cryptokey_route
ipv6routes []cryptokey_route
ipv4cache map[address]cryptokey_route
ipv6cache map[address]cryptokey_route
ipv4cache map[address.Address]cryptokey_route
ipv6cache map[address.Address]cryptokey_route
ipv4sources []net.IPNet
ipv6sources []net.IPNet
}
type cryptokey_route struct {
subnet net.IPNet
destination boxPubKey
destination crypto.BoxPubKey
}
// Initialise crypto-key routing. This must be done before any other CKR calls.
@ -33,8 +36,8 @@ func (c *cryptokey) init(core *Core) {
c.core = core
c.ipv4routes = make([]cryptokey_route, 0)
c.ipv6routes = make([]cryptokey_route, 0)
c.ipv4cache = make(map[address]cryptokey_route, 0)
c.ipv6cache = make(map[address]cryptokey_route, 0)
c.ipv4cache = make(map[address.Address]cryptokey_route, 0)
c.ipv6cache = make(map[address.Address]cryptokey_route, 0)
c.ipv4sources = make([]net.IPNet, 0)
c.ipv6sources = make([]net.IPNet, 0)
}
@ -52,7 +55,7 @@ func (c *cryptokey) isEnabled() bool {
// Check whether the given address (with the address length specified in bytes)
// matches either the current node's address, the node's routed subnet or the
// list of subnets specified in IPv4Sources/IPv6Sources.
func (c *cryptokey) isValidSource(addr address, addrlen int) bool {
func (c *cryptokey) isValidSource(addr address.Address, addrlen int) bool {
ip := net.IP(addr[:addrlen])
if addrlen == net.IPv6len {
@ -143,7 +146,7 @@ func (c *cryptokey) addRoute(cidr string, dest string) error {
// Build our references to the routing table and cache
var routingtable *[]cryptokey_route
var routingcache *map[address]cryptokey_route
var routingcache *map[address.Address]cryptokey_route
// Check if the prefix is IPv4 or IPv6
if prefixsize == net.IPv6len*8 {
@ -157,11 +160,11 @@ func (c *cryptokey) addRoute(cidr string, dest string) error {
}
// Is the route an Yggdrasil destination?
var addr address
var snet subnet
var addr address.Address
var snet address.Subnet
copy(addr[:], ipaddr)
copy(snet[:], ipnet.IP)
if addr.isValid() || snet.isValid() {
if addr.IsValid() || snet.IsValid() {
return errors.New("Can't specify Yggdrasil destination as crypto-key route")
}
// Do we already have a route for this subnet?
@ -173,11 +176,11 @@ func (c *cryptokey) addRoute(cidr string, dest string) error {
// Decode the public key
if bpk, err := hex.DecodeString(dest); err != nil {
return err
} else if len(bpk) != boxPubKeyLen {
} else if len(bpk) != crypto.BoxPubKeyLen {
return errors.New(fmt.Sprintf("Incorrect key length for %s", dest))
} else {
// Add the new crypto-key route
var key boxPubKey
var key crypto.BoxPubKey
copy(key[:], bpk)
*routingtable = append(*routingtable, cryptokey_route{
subnet: *ipnet,
@ -205,16 +208,16 @@ func (c *cryptokey) addRoute(cidr string, dest string) error {
// Looks up the most specific route for the given address (with the address
// length specified in bytes) from the crypto-key routing table. An error is
// returned if the address is not suitable or no route was found.
func (c *cryptokey) getPublicKeyForAddress(addr address, addrlen int) (boxPubKey, error) {
func (c *cryptokey) getPublicKeyForAddress(addr address.Address, addrlen int) (crypto.BoxPubKey, error) {
// Check if the address is a valid Yggdrasil address - if so it
// is exempt from all CKR checking
if addr.isValid() {
return boxPubKey{}, errors.New("Cannot look up CKR for Yggdrasil addresses")
if addr.IsValid() {
return crypto.BoxPubKey{}, errors.New("Cannot look up CKR for Yggdrasil addresses")
}
// Build our references to the routing table and cache
var routingtable *[]cryptokey_route
var routingcache *map[address]cryptokey_route
var routingcache *map[address.Address]cryptokey_route
// Check if the prefix is IPv4 or IPv6
if addrlen == net.IPv6len {
@ -224,7 +227,7 @@ func (c *cryptokey) getPublicKeyForAddress(addr address, addrlen int) (boxPubKey
routingtable = &c.ipv4routes
routingcache = &c.ipv4cache
} else {
return boxPubKey{}, errors.New("Unexpected prefix size")
return crypto.BoxPubKey{}, errors.New("Unexpected prefix size")
}
// Check if there's a cache entry for this addr
@ -260,7 +263,7 @@ func (c *cryptokey) getPublicKeyForAddress(addr address, addrlen int) (boxPubKey
}
// No route was found if we got to this point
return boxPubKey{}, errors.New(fmt.Sprintf("No route to %s", ip.String()))
return crypto.BoxPubKey{}, errors.New(fmt.Sprintf("No route to %s", ip.String()))
}
// Removes a source subnet, which allows traffic with these source addresses to
@ -312,7 +315,7 @@ func (c *cryptokey) removeRoute(cidr string, dest string) error {
// Build our references to the routing table and cache
var routingtable *[]cryptokey_route
var routingcache *map[address]cryptokey_route
var routingcache *map[address.Address]cryptokey_route
// Check if the prefix is IPv4 or IPv6
if prefixsize == net.IPv6len*8 {
@ -329,7 +332,7 @@ func (c *cryptokey) removeRoute(cidr string, dest string) error {
bpk, err := hex.DecodeString(dest)
if err != nil {
return err
} else if len(bpk) != boxPubKeyLen {
} else if len(bpk) != crypto.BoxPubKeyLen {
return errors.New(fmt.Sprintf("Incorrect key length for %s", dest))
}
netStr := ipnet.String()

View File

@ -8,7 +8,9 @@ import (
"net"
"regexp"
"github.com/yggdrasil-network/yggdrasil-go/src/address"
"github.com/yggdrasil-network/yggdrasil-go/src/config"
"github.com/yggdrasil-network/yggdrasil-go/src/crypto"
"github.com/yggdrasil-network/yggdrasil-go/src/defaults"
)
@ -19,10 +21,10 @@ var buildVersion string
// object for each Yggdrasil node you plan to run.
type Core struct {
// This is the main data structure that holds everything else for a node
boxPub boxPubKey
boxPriv boxPrivKey
sigPub sigPubKey
sigPriv sigPrivKey
boxPub crypto.BoxPubKey
boxPriv crypto.BoxPrivKey
sigPub crypto.SigPubKey
sigPriv crypto.SigPrivKey
switchTable switchTable
peers peers
sessions sessions
@ -37,15 +39,14 @@ type Core struct {
ifceExpr []*regexp.Regexp // the zone of link-local IPv6 peers must match this
}
func (c *Core) init(bpub *boxPubKey,
bpriv *boxPrivKey,
spub *sigPubKey,
spriv *sigPrivKey) {
func (c *Core) init(bpub *crypto.BoxPubKey,
bpriv *crypto.BoxPrivKey,
spub *crypto.SigPubKey,
spriv *crypto.SigPrivKey) {
// TODO separate init and start functions
// Init sets up structs
// Start launches goroutines that depend on structs being set up
// This is pretty much required to completely avoid race conditions
util_initByteStore()
if c.log == nil {
c.log = log.New(ioutil.Discard, "", 0)
}
@ -95,10 +96,10 @@ func (c *Core) Start(nc *config.NodeConfig, log *log.Logger) error {
c.log.Println("Starting up...")
var boxPub boxPubKey
var boxPriv boxPrivKey
var sigPub sigPubKey
var sigPriv sigPrivKey
var boxPub crypto.BoxPubKey
var boxPriv crypto.BoxPrivKey
var sigPub crypto.SigPubKey
var sigPriv crypto.SigPrivKey
boxPubHex, err := hex.DecodeString(nc.EncryptionPublicKey)
if err != nil {
return err
@ -190,7 +191,7 @@ func (c *Core) Start(nc *config.NodeConfig, log *log.Logger) error {
}
ip := net.IP(c.router.addr[:]).String()
if err := c.router.tun.start(nc.IfName, nc.IfTAPMode, fmt.Sprintf("%s/%d", ip, 8*len(address_prefix)-1), nc.IfMTU); err != nil {
if err := c.router.tun.start(nc.IfName, nc.IfTAPMode, fmt.Sprintf("%s/%d", ip, 8*len(address.GetPrefix())-1), nc.IfMTU); err != nil {
c.log.Println("Failed to start TUN/TAP")
return err
}
@ -208,35 +209,35 @@ func (c *Core) Stop() {
// Generates a new encryption keypair. The encryption keys are used to
// encrypt traffic and to derive the IPv6 address/subnet of the node.
func (c *Core) NewEncryptionKeys() (*boxPubKey, *boxPrivKey) {
return newBoxKeys()
func (c *Core) NewEncryptionKeys() (*crypto.BoxPubKey, *crypto.BoxPrivKey) {
return crypto.NewBoxKeys()
}
// Generates a new signing keypair. The signing keys are used to derive the
// structure of the spanning tree.
func (c *Core) NewSigningKeys() (*sigPubKey, *sigPrivKey) {
return newSigKeys()
func (c *Core) NewSigningKeys() (*crypto.SigPubKey, *crypto.SigPrivKey) {
return crypto.NewSigKeys()
}
// Gets the node ID.
func (c *Core) GetNodeID() *NodeID {
return getNodeID(&c.boxPub)
func (c *Core) GetNodeID() *crypto.NodeID {
return crypto.GetNodeID(&c.boxPub)
}
// Gets the tree ID.
func (c *Core) GetTreeID() *TreeID {
return getTreeID(&c.sigPub)
func (c *Core) GetTreeID() *crypto.TreeID {
return crypto.GetTreeID(&c.sigPub)
}
// Gets the IPv6 address of the Yggdrasil node. This is always a /128.
func (c *Core) GetAddress() *net.IP {
address := net.IP(address_addrForNodeID(c.GetNodeID())[:])
address := net.IP(address.AddrForNodeID(c.GetNodeID())[:])
return &address
}
// Gets the routed IPv6 subnet of the Yggdrasil node. This is always a /64.
func (c *Core) GetSubnet() *net.IPNet {
subnet := address_subnetForNodeID(c.GetNodeID())[:]
subnet := address.SubnetForNodeID(c.GetNodeID())[:]
subnet = append(subnet, 0, 0, 0, 0, 0, 0, 0, 0)
return &net.IPNet{IP: subnet, Mask: net.CIDRMask(64, 128)}
}

View File

@ -1,167 +0,0 @@
package yggdrasil
/*
This part of the package wraps crypto operations needed elsewhere
In particular, it exposes key generation for ed25519 and nacl box
It also defines NodeID and TreeID as hashes of keys, and wraps hash functions
*/
import (
"crypto/rand"
"crypto/sha512"
"golang.org/x/crypto/ed25519"
"golang.org/x/crypto/nacl/box"
)
////////////////////////////////////////////////////////////////////////////////
// NodeID and TreeID
const NodeIDLen = sha512.Size
const TreeIDLen = sha512.Size
const handleLen = 8
type NodeID [NodeIDLen]byte
type TreeID [TreeIDLen]byte
type handle [handleLen]byte
func getNodeID(pub *boxPubKey) *NodeID {
h := sha512.Sum512(pub[:])
return (*NodeID)(&h)
}
func getTreeID(pub *sigPubKey) *TreeID {
h := sha512.Sum512(pub[:])
return (*TreeID)(&h)
}
func newHandle() *handle {
var h handle
_, err := rand.Read(h[:])
if err != nil {
panic(err)
}
return &h
}
////////////////////////////////////////////////////////////////////////////////
// Signatures
const sigPubKeyLen = ed25519.PublicKeySize
const sigPrivKeyLen = ed25519.PrivateKeySize
const sigLen = ed25519.SignatureSize
type sigPubKey [sigPubKeyLen]byte
type sigPrivKey [sigPrivKeyLen]byte
type sigBytes [sigLen]byte
func newSigKeys() (*sigPubKey, *sigPrivKey) {
var pub sigPubKey
var priv sigPrivKey
pubSlice, privSlice, err := ed25519.GenerateKey(rand.Reader)
if err != nil {
panic(err)
}
copy(pub[:], pubSlice)
copy(priv[:], privSlice)
return &pub, &priv
}
func sign(priv *sigPrivKey, msg []byte) *sigBytes {
var sig sigBytes
sigSlice := ed25519.Sign(priv[:], msg)
copy(sig[:], sigSlice)
return &sig
}
func verify(pub *sigPubKey, msg []byte, sig *sigBytes) bool {
// Should sig be an array instead of a slice?...
// It's fixed size, but
return ed25519.Verify(pub[:], msg, sig[:])
}
////////////////////////////////////////////////////////////////////////////////
// NaCl-like crypto "box" (curve25519+xsalsa20+poly1305)
const boxPubKeyLen = 32
const boxPrivKeyLen = 32
const boxSharedKeyLen = 32
const boxNonceLen = 24
const boxOverhead = box.Overhead
type boxPubKey [boxPubKeyLen]byte
type boxPrivKey [boxPrivKeyLen]byte
type boxSharedKey [boxSharedKeyLen]byte
type boxNonce [boxNonceLen]byte
func newBoxKeys() (*boxPubKey, *boxPrivKey) {
pubBytes, privBytes, err := box.GenerateKey(rand.Reader)
if err != nil {
panic(err)
}
pub := (*boxPubKey)(pubBytes)
priv := (*boxPrivKey)(privBytes)
return pub, priv
}
func getSharedKey(myPrivKey *boxPrivKey,
othersPubKey *boxPubKey) *boxSharedKey {
var shared [boxSharedKeyLen]byte
priv := (*[boxPrivKeyLen]byte)(myPrivKey)
pub := (*[boxPubKeyLen]byte)(othersPubKey)
box.Precompute(&shared, pub, priv)
return (*boxSharedKey)(&shared)
}
func boxOpen(shared *boxSharedKey,
boxed []byte,
nonce *boxNonce) ([]byte, bool) {
out := util_getBytes()
s := (*[boxSharedKeyLen]byte)(shared)
n := (*[boxNonceLen]byte)(nonce)
unboxed, success := box.OpenAfterPrecomputation(out, boxed, n, s)
return unboxed, success
}
func boxSeal(shared *boxSharedKey, unboxed []byte, nonce *boxNonce) ([]byte, *boxNonce) {
if nonce == nil {
nonce = newBoxNonce()
}
nonce.update()
out := util_getBytes()
s := (*[boxSharedKeyLen]byte)(shared)
n := (*[boxNonceLen]byte)(nonce)
boxed := box.SealAfterPrecomputation(out, unboxed, n, s)
return boxed, nonce
}
func newBoxNonce() *boxNonce {
var nonce boxNonce
_, err := rand.Read(nonce[:])
for ; err == nil && nonce[0] == 0xff; _, err = rand.Read(nonce[:]) {
// Make sure nonce isn't too high
// This is just to make rollover unlikely to happen
// Rollover is fine, but it may kill the session and force it to reopen
}
if err != nil {
panic(err)
}
return &nonce
}
func (n *boxNonce) update() {
oldNonce := *n
n[len(n)-1] += 2
for i := len(n) - 2; i >= 0; i-- {
if n[i+1] < oldNonce[i+1] {
n[i] += 1
}
}
}

View File

@ -22,6 +22,8 @@ import "net/http"
import "runtime"
import "os"
import "github.com/yggdrasil-network/yggdrasil-go/src/address"
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.
@ -48,8 +50,8 @@ func StartProfiler(log *log.Logger) error {
// 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 := newBoxKeys()
spub, spriv := newSigKeys()
bpub, bpriv := crypto.NewBoxKeys()
spub, spriv := crypto.NewSigKeys()
c.init(bpub, bpriv, spub, spriv)
c.switchTable.start()
c.router.start()
@ -59,12 +61,12 @@ func (c *Core) Init() {
// Core
func (c *Core) DEBUG_getSigningPublicKey() sigPubKey {
return (sigPubKey)(c.sigPub)
func (c *Core) DEBUG_getSigningPublicKey() crypto.SigPubKey {
return (crypto.SigPubKey)(c.sigPub)
}
func (c *Core) DEBUG_getEncryptionPublicKey() boxPubKey {
return (boxPubKey)(c.boxPub)
func (c *Core) DEBUG_getEncryptionPublicKey() crypto.BoxPubKey {
return (crypto.BoxPubKey)(c.boxPub)
}
func (c *Core) DEBUG_getSend() chan<- []byte {
@ -81,7 +83,7 @@ func (c *Core) DEBUG_getPeers() *peers {
return &c.peers
}
func (ps *peers) DEBUG_newPeer(box boxPubKey, sig sigPubKey, link boxSharedKey) *peer {
func (ps *peers) DEBUG_newPeer(box crypto.BoxPubKey, sig crypto.SigPubKey, link crypto.BoxSharedKey) *peer {
//in <-chan []byte,
//out chan<- []byte) *peer {
return ps.newPeer(&box, &sig, &link, "(simulator)") //, in, out)
@ -98,7 +100,7 @@ func (ps *peers) DEBUG_startPeers() {
}
*/
func (ps *peers) DEBUG_hasPeer(key sigPubKey) bool {
func (ps *peers) DEBUG_hasPeer(key crypto.SigPubKey) bool {
ports := ps.ports.Load().(map[switchPort]*peer)
for _, p := range ports {
if p == nil {
@ -120,7 +122,7 @@ func (ps *peers) DEBUG_getPorts() map[switchPort]*peer {
return newPeers
}
func (p *peer) DEBUG_getSigKey() sigPubKey {
func (p *peer) DEBUG_getSigKey() crypto.SigPubKey {
return p.sig
}
@ -292,8 +294,8 @@ func (c *Core) DEBUG_startLoopbackUDPInterface() {
////////////////////////////////////////////////////////////////////////////////
func (c *Core) DEBUG_getAddr() *address {
return address_addrForNodeID(&c.dht.nodeID)
func (c *Core) DEBUG_getAddr() *address.Address {
return address.AddrForNodeID(&c.dht.nodeID)
}
func (c *Core) DEBUG_startTun(ifname string, iftapmode bool) {
@ -302,7 +304,7 @@ func (c *Core) DEBUG_startTun(ifname string, iftapmode bool) {
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_prefix))
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 {
@ -320,38 +322,38 @@ func (c *Core) DEBUG_stopTun() {
////////////////////////////////////////////////////////////////////////////////
func (c *Core) DEBUG_newBoxKeys() (*boxPubKey, *boxPrivKey) {
return newBoxKeys()
func (c *Core) DEBUG_newBoxKeys() (*crypto.BoxPubKey, *crypto.BoxPrivKey) {
return crypto.NewBoxKeys()
}
func (c *Core) DEBUG_getSharedKey(myPrivKey *boxPrivKey, othersPubKey *boxPubKey) *boxSharedKey {
return getSharedKey(myPrivKey, othersPubKey)
func (c *Core) DEBUG_getSharedKey(myPrivKey *crypto.BoxPrivKey, othersPubKey *crypto.BoxPubKey) *crypto.BoxSharedKey {
return crypto.GetSharedKey(myPrivKey, othersPubKey)
}
func (c *Core) DEBUG_newSigKeys() (*sigPubKey, *sigPrivKey) {
return newSigKeys()
func (c *Core) DEBUG_newSigKeys() (*crypto.SigPubKey, *crypto.SigPrivKey) {
return crypto.NewSigKeys()
}
func (c *Core) DEBUG_getNodeID(pub *boxPubKey) *NodeID {
return getNodeID(pub)
func (c *Core) DEBUG_getNodeID(pub *crypto.BoxPubKey) *crypto.NodeID {
return crypto.GetNodeID(pub)
}
func (c *Core) DEBUG_getTreeID(pub *sigPubKey) *TreeID {
return getTreeID(pub)
func (c *Core) DEBUG_getTreeID(pub *crypto.SigPubKey) *crypto.TreeID {
return crypto.GetTreeID(pub)
}
func (c *Core) DEBUG_addrForNodeID(nodeID *NodeID) string {
return net.IP(address_addrForNodeID(nodeID)[:]).String()
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 boxPubKey
var boxPriv boxPrivKey
var sigPub sigPubKey
var sigPriv sigPrivKey
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)
@ -553,13 +555,13 @@ func (c *Core) DEBUG_simFixMTU() {
func Util_testAddrIDMask() {
for idx := 0; idx < 16; idx++ {
var orig NodeID
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()
addr := address.AddrForNodeID(&orig)
nid, mask := addr.GetNodeIDandMask()
for b := 0; b < len(mask); b++ {
nid[b] &= mask[b]
orig[b] &= mask[b]

View File

@ -8,6 +8,8 @@ package yggdrasil
import (
"sort"
"time"
"github.com/yggdrasil-network/yggdrasil-go/src/crypto"
)
const dht_lookup_size = 16
@ -15,8 +17,8 @@ const dht_lookup_size = 16
// dhtInfo represents everything we know about a node in the DHT.
// This includes its key, a cache of it's NodeID, coords, and timing/ping related info for deciding who/when to ping nodes for maintenance.
type dhtInfo struct {
nodeID_hidden *NodeID
key boxPubKey
nodeID_hidden *crypto.NodeID
key crypto.BoxPubKey
coords []byte
recv time.Time // When we last received a message
pings int // Time out if at least 3 consecutive maintenance pings drop
@ -24,9 +26,9 @@ type dhtInfo struct {
}
// Returns the *NodeID associated with dhtInfo.key, calculating it on the fly the first time or from a cache all subsequent times.
func (info *dhtInfo) getNodeID() *NodeID {
func (info *dhtInfo) getNodeID() *crypto.NodeID {
if info.nodeID_hidden == nil {
info.nodeID_hidden = getNodeID(&info.key)
info.nodeID_hidden = crypto.GetNodeID(&info.key)
}
return info.nodeID_hidden
}
@ -34,36 +36,36 @@ func (info *dhtInfo) getNodeID() *NodeID {
// Request for a node to do a lookup.
// Includes our key and coords so they can send a response back, and the destination NodeID we want to ask about.
type dhtReq struct {
Key boxPubKey // Key of whoever asked
Coords []byte // Coords of whoever asked
Dest NodeID // NodeID they're asking about
Key crypto.BoxPubKey // Key of whoever asked
Coords []byte // Coords of whoever asked
Dest crypto.NodeID // NodeID they're asking about
}
// Response to a DHT lookup.
// Includes the key and coords of the node that's responding, and the destination they were asked about.
// The main part is Infos []*dhtInfo, the lookup response.
type dhtRes struct {
Key boxPubKey // key of the sender
Coords []byte // coords of the sender
Dest NodeID
Key crypto.BoxPubKey // key of the sender
Coords []byte // coords of the sender
Dest crypto.NodeID
Infos []*dhtInfo // response
}
// Parts of a DHT req usable as a key in a map.
type dhtReqKey struct {
key boxPubKey
dest NodeID
key crypto.BoxPubKey
dest crypto.NodeID
}
// The main DHT struct.
type dht struct {
core *Core
nodeID NodeID
nodeID crypto.NodeID
peers chan *dhtInfo // other goroutines put incoming dht updates here
reqs map[dhtReqKey]time.Time // Keeps track of recent outstanding requests
callbacks map[dhtReqKey]dht_callbackInfo // Search and admin lookup callbacks
// These next two could be replaced by a single linked list or similar...
table map[NodeID]*dhtInfo
table map[crypto.NodeID]*dhtInfo
imp []*dhtInfo
}
@ -80,12 +82,12 @@ func (t *dht) init(c *Core) {
// This empties all info from the DHT and drops outstanding requests.
func (t *dht) reset() {
t.reqs = make(map[dhtReqKey]time.Time)
t.table = make(map[NodeID]*dhtInfo)
t.table = make(map[crypto.NodeID]*dhtInfo)
t.imp = nil
}
// Does a DHT lookup and returns up to dht_lookup_size results.
func (t *dht) lookup(nodeID *NodeID, everything bool) []*dhtInfo {
func (t *dht) lookup(nodeID *crypto.NodeID, everything bool) []*dhtInfo {
results := make([]*dhtInfo, 0, len(t.table))
for _, info := range t.table {
results = append(results, info)
@ -133,9 +135,9 @@ func (t *dht) insert(info *dhtInfo) {
}
// Return true if first/second/third are (partially) ordered correctly.
func dht_ordered(first, second, third *NodeID) bool {
lessOrEqual := func(first, second *NodeID) bool {
for idx := 0; idx < NodeIDLen; idx++ {
func dht_ordered(first, second, third *crypto.NodeID) bool {
lessOrEqual := func(first, second *crypto.NodeID) bool {
for idx := 0; idx < crypto.NodeIDLen; idx++ {
if first[idx] > second[idx] {
return false
}
@ -190,7 +192,7 @@ func (t *dht) sendRes(res *dhtRes, req *dhtReq) {
// Send a reply for a dhtReq
bs := res.encode()
shared := t.core.sessions.getSharedKey(&t.core.boxPriv, &req.Key)
payload, nonce := boxSeal(shared, bs, nil)
payload, nonce := crypto.BoxSeal(shared, bs, nil)
p := wire_protoTrafficPacket{
Coords: req.Coords,
ToKey: req.Key,
@ -252,7 +254,7 @@ func (t *dht) sendReq(req *dhtReq, dest *dhtInfo) {
// Send a dhtReq to the node in dhtInfo
bs := req.encode()
shared := t.core.sessions.getSharedKey(&t.core.boxPriv, &dest.key)
payload, nonce := boxSeal(shared, bs, nil)
payload, nonce := crypto.BoxSeal(shared, bs, nil)
p := wire_protoTrafficPacket{
Coords: dest.coords,
ToKey: dest.key,
@ -267,7 +269,7 @@ func (t *dht) sendReq(req *dhtReq, dest *dhtInfo) {
}
// Sends a lookup to this info, looking for the target.
func (t *dht) ping(info *dhtInfo, target *NodeID) {
func (t *dht) ping(info *dhtInfo, target *crypto.NodeID) {
// Creates a req for the node at dhtInfo, asking them about the target (if one is given) or themself (if no target is given)
if target == nil {
target = &t.nodeID

View File

@ -17,6 +17,8 @@ import (
"golang.org/x/net/icmp"
"golang.org/x/net/ipv6"
"github.com/yggdrasil-network/yggdrasil-go/src/address"
)
type macAddress [6]byte
@ -27,7 +29,7 @@ type icmpv6 struct {
tun *tunAdapter
mylladdr net.IP
mymac macAddress
peermacs map[address]neighbor
peermacs map[address.Address]neighbor
}
type neighbor struct {
@ -59,7 +61,7 @@ func ipv6Header_Marshal(h *ipv6.Header) ([]byte, error) {
// addresses.
func (i *icmpv6) init(t *tunAdapter) {
i.tun = t
i.peermacs = make(map[address]neighbor)
i.peermacs = make(map[address.Address]neighbor)
// Our MAC address and link-local address
i.mymac = macAddress{
@ -172,7 +174,7 @@ func (i *icmpv6) parse_packet_tun(datain []byte, datamac *[]byte) ([]byte, error
}
case ipv6.ICMPTypeNeighborAdvertisement:
if datamac != nil {
var addr address
var addr address.Address
var mac macAddress
copy(addr[:], ipv6Header.Src[:])
copy(mac[:], (*datamac)[:])
@ -254,7 +256,7 @@ func (i *icmpv6) create_icmpv6_tun(dst net.IP, src net.IP, mtype ipv6.ICMPType,
return responsePacket, nil
}
func (i *icmpv6) create_ndp_tap(dst address) ([]byte, error) {
func (i *icmpv6) create_ndp_tap(dst address.Address) ([]byte, error) {
// Create the ND payload
var payload [28]byte
copy(payload[:4], []byte{0x00, 0x00, 0x00, 0x00})
@ -263,7 +265,7 @@ func (i *icmpv6) create_ndp_tap(dst address) ([]byte, error) {
copy(payload[22:28], i.mymac[:6])
// Create the ICMPv6 solicited-node address
var dstaddr address
var dstaddr address.Address
copy(dstaddr[:13], []byte{
0xFF, 0x02, 0x00, 0x00,
0x00, 0x00, 0x00, 0x00,
@ -296,13 +298,13 @@ func (i *icmpv6) create_ndp_tap(dst address) ([]byte, error) {
// to the Yggdrasil TAP adapter.
func (i *icmpv6) handle_ndp(in []byte) ([]byte, error) {
// Ignore NDP requests for anything outside of fd00::/8
var source address
var source address.Address
copy(source[:], in[8:])
var snet subnet
var snet address.Subnet
copy(snet[:], in[8:])
switch {
case source.isValid():
case snet.isValid():
case source.IsValid():
case snet.IsValid():
default:
return nil, errors.New("Not an NDP for 0200::/7")
}

View File

@ -6,15 +6,17 @@ import (
"runtime"
"sync"
"time"
"github.com/yggdrasil-network/yggdrasil-go/src/crypto"
)
type nodeinfo struct {
core *Core
myNodeInfo nodeinfoPayload
myNodeInfoMutex sync.RWMutex
callbacks map[boxPubKey]nodeinfoCallback
callbacks map[crypto.BoxPubKey]nodeinfoCallback
callbacksMutex sync.Mutex
cache map[boxPubKey]nodeinfoCached
cache map[crypto.BoxPubKey]nodeinfoCached
cacheMutex sync.RWMutex
}
@ -32,8 +34,8 @@ type nodeinfoCallback struct {
// Represents a session nodeinfo packet.
type nodeinfoReqRes struct {
SendPermPub boxPubKey // Sender's permanent key
SendCoords []byte // Sender's coords
SendPermPub crypto.BoxPubKey // Sender's permanent key
SendCoords []byte // Sender's coords
IsResponse bool
NodeInfo nodeinfoPayload
}
@ -42,8 +44,8 @@ type nodeinfoReqRes struct {
// the cache/callback maps clean of stale entries
func (m *nodeinfo) init(core *Core) {
m.core = core
m.callbacks = make(map[boxPubKey]nodeinfoCallback)
m.cache = make(map[boxPubKey]nodeinfoCached)
m.callbacks = make(map[crypto.BoxPubKey]nodeinfoCallback)
m.cache = make(map[crypto.BoxPubKey]nodeinfoCached)
go func() {
for {
@ -67,7 +69,7 @@ func (m *nodeinfo) init(core *Core) {
}
// Add a callback for a nodeinfo lookup
func (m *nodeinfo) addCallback(sender boxPubKey, call func(nodeinfo *nodeinfoPayload)) {
func (m *nodeinfo) addCallback(sender crypto.BoxPubKey, call func(nodeinfo *nodeinfoPayload)) {
m.callbacksMutex.Lock()
defer m.callbacksMutex.Unlock()
m.callbacks[sender] = nodeinfoCallback{
@ -77,7 +79,7 @@ func (m *nodeinfo) addCallback(sender boxPubKey, call func(nodeinfo *nodeinfoPay
}
// Handles the callback, if there is one
func (m *nodeinfo) callback(sender boxPubKey, nodeinfo nodeinfoPayload) {
func (m *nodeinfo) callback(sender crypto.BoxPubKey, nodeinfo nodeinfoPayload) {
m.callbacksMutex.Lock()
defer m.callbacksMutex.Unlock()
if callback, ok := m.callbacks[sender]; ok {
@ -123,7 +125,7 @@ func (m *nodeinfo) setNodeInfo(given interface{}) error {
}
// Add nodeinfo into the cache for a node
func (m *nodeinfo) addCachedNodeInfo(key boxPubKey, payload nodeinfoPayload) {
func (m *nodeinfo) addCachedNodeInfo(key crypto.BoxPubKey, payload nodeinfoPayload) {
m.cacheMutex.Lock()
defer m.cacheMutex.Unlock()
m.cache[key] = nodeinfoCached{
@ -133,7 +135,7 @@ func (m *nodeinfo) addCachedNodeInfo(key boxPubKey, payload nodeinfoPayload) {
}
// Get a nodeinfo entry from the cache
func (m *nodeinfo) getCachedNodeInfo(key boxPubKey) (nodeinfoPayload, error) {
func (m *nodeinfo) getCachedNodeInfo(key crypto.BoxPubKey) (nodeinfoPayload, error) {
m.cacheMutex.RLock()
defer m.cacheMutex.RUnlock()
if nodeinfo, ok := m.cache[key]; ok {
@ -153,7 +155,7 @@ func (m *nodeinfo) handleNodeInfo(nodeinfo *nodeinfoReqRes) {
}
// Send nodeinfo request or response - called from the router
func (m *nodeinfo) sendNodeInfo(key boxPubKey, coords []byte, isResponse bool) {
func (m *nodeinfo) sendNodeInfo(key crypto.BoxPubKey, coords []byte, isResponse bool) {
table := m.core.switchTable.table.Load().(lookupTable)
nodeinfo := nodeinfoReqRes{
SendCoords: table.self.getCoords(),
@ -162,7 +164,7 @@ func (m *nodeinfo) sendNodeInfo(key boxPubKey, coords []byte, isResponse bool) {
}
bs := nodeinfo.encode()
shared := m.core.sessions.getSharedKey(&m.core.boxPriv, &key)
payload, nonce := boxSeal(shared, bs, nil)
payload, nonce := crypto.BoxSeal(shared, bs, nil)
p := wire_protoTrafficPacket{
Coords: coords,
ToKey: key,

View File

@ -8,6 +8,9 @@ import (
"sync"
"sync/atomic"
"time"
"github.com/yggdrasil-network/yggdrasil-go/src/crypto"
"github.com/yggdrasil-network/yggdrasil-go/src/util"
)
// The peers struct represents peers with an active connection.
@ -19,7 +22,7 @@ type peers struct {
mutex sync.Mutex // Synchronize writes to atomic
ports atomic.Value //map[switchPort]*peer, use CoW semantics
authMutex sync.RWMutex
allowedEncryptionPublicKeys map[boxPubKey]struct{}
allowedEncryptionPublicKeys map[crypto.BoxPubKey]struct{}
}
// Initializes the peers struct.
@ -28,11 +31,11 @@ func (ps *peers) init(c *Core) {
defer ps.mutex.Unlock()
ps.putPorts(make(map[switchPort]*peer))
ps.core = c
ps.allowedEncryptionPublicKeys = make(map[boxPubKey]struct{})
ps.allowedEncryptionPublicKeys = make(map[crypto.BoxPubKey]struct{})
}
// Returns true if an incoming peer connection to a key is allowed, either because the key is in the whitelist or because the whitelist is empty.
func (ps *peers) isAllowedEncryptionPublicKey(box *boxPubKey) bool {
func (ps *peers) isAllowedEncryptionPublicKey(box *crypto.BoxPubKey) bool {
ps.authMutex.RLock()
defer ps.authMutex.RUnlock()
_, isIn := ps.allowedEncryptionPublicKeys[*box]
@ -40,24 +43,24 @@ func (ps *peers) isAllowedEncryptionPublicKey(box *boxPubKey) bool {
}
// Adds a key to the whitelist.
func (ps *peers) addAllowedEncryptionPublicKey(box *boxPubKey) {
func (ps *peers) addAllowedEncryptionPublicKey(box *crypto.BoxPubKey) {
ps.authMutex.Lock()
defer ps.authMutex.Unlock()
ps.allowedEncryptionPublicKeys[*box] = struct{}{}
}
// Removes a key from the whitelist.
func (ps *peers) removeAllowedEncryptionPublicKey(box *boxPubKey) {
func (ps *peers) removeAllowedEncryptionPublicKey(box *crypto.BoxPubKey) {
ps.authMutex.Lock()
defer ps.authMutex.Unlock()
delete(ps.allowedEncryptionPublicKeys, *box)
}
// Gets the whitelist of allowed keys for incoming connections.
func (ps *peers) getAllowedEncryptionPublicKeys() []boxPubKey {
func (ps *peers) getAllowedEncryptionPublicKeys() []crypto.BoxPubKey {
ps.authMutex.RLock()
defer ps.authMutex.RUnlock()
keys := make([]boxPubKey, 0, len(ps.allowedEncryptionPublicKeys))
keys := make([]crypto.BoxPubKey, 0, len(ps.allowedEncryptionPublicKeys))
for key := range ps.allowedEncryptionPublicKeys {
keys = append(keys, key)
}
@ -81,10 +84,10 @@ type peer struct {
// BUG: sync/atomic, 32 bit platforms need the above to be the first element
core *Core
port switchPort
box boxPubKey
sig sigPubKey
shared boxSharedKey
linkShared boxSharedKey
box crypto.BoxPubKey
sig crypto.SigPubKey
shared crypto.BoxSharedKey
linkShared crypto.BoxSharedKey
endpoint string
firstSeen time.Time // To track uptime for getPeers
linkOut (chan []byte) // used for protocol traffic (to bypass queues)
@ -95,11 +98,11 @@ type peer struct {
}
// Creates a new peer with the specified box, sig, and linkShared keys, using the lowest unocupied port number.
func (ps *peers) newPeer(box *boxPubKey, sig *sigPubKey, linkShared *boxSharedKey, endpoint string) *peer {
func (ps *peers) newPeer(box *crypto.BoxPubKey, sig *crypto.SigPubKey, linkShared *crypto.BoxSharedKey, endpoint string) *peer {
now := time.Now()
p := peer{box: *box,
sig: *sig,
shared: *getSharedKey(&ps.core.boxPriv, box),
shared: *crypto.GetSharedKey(&ps.core.boxPriv, box),
linkShared: *linkShared,
endpoint: endpoint,
firstSeen: now,
@ -212,7 +215,7 @@ func (p *peer) handlePacket(packet []byte) {
case wire_LinkProtocolTraffic:
p.handleLinkTraffic(packet)
default:
util_putBytes(packet)
util.PutBytes(packet)
}
}
@ -237,13 +240,13 @@ func (p *peer) sendPacket(packet []byte) {
// This wraps the packet in the inner (ephemeral) and outer (permanent) crypto layers.
// It sends it to p.linkOut, which bypasses the usual packet queues.
func (p *peer) sendLinkPacket(packet []byte) {
innerPayload, innerNonce := boxSeal(&p.linkShared, packet, nil)
innerPayload, innerNonce := crypto.BoxSeal(&p.linkShared, packet, nil)
innerLinkPacket := wire_linkProtoTrafficPacket{
Nonce: *innerNonce,
Payload: innerPayload,
}
outerPayload := innerLinkPacket.encode()
bs, nonce := boxSeal(&p.shared, outerPayload, nil)
bs, nonce := crypto.BoxSeal(&p.shared, outerPayload, nil)
linkPacket := wire_linkProtoTrafficPacket{
Nonce: *nonce,
Payload: bs,
@ -259,7 +262,7 @@ func (p *peer) handleLinkTraffic(bs []byte) {
if !packet.decode(bs) {
return
}
outerPayload, isOK := boxOpen(&p.shared, packet.Payload, &packet.Nonce)
outerPayload, isOK := crypto.BoxOpen(&p.shared, packet.Payload, &packet.Nonce)
if !isOK {
return
}
@ -267,7 +270,7 @@ func (p *peer) handleLinkTraffic(bs []byte) {
if !innerPacket.decode(outerPayload) {
return
}
payload, isOK := boxOpen(&p.linkShared, innerPacket.Payload, &innerPacket.Nonce)
payload, isOK := crypto.BoxOpen(&p.linkShared, innerPacket.Payload, &innerPacket.Nonce)
if !isOK {
return
}
@ -279,7 +282,7 @@ func (p *peer) handleLinkTraffic(bs []byte) {
case wire_SwitchMsg:
p.handleSwitchMsg(payload)
default:
util_putBytes(bs)
util.PutBytes(bs)
}
}
@ -293,7 +296,7 @@ func (p *peer) sendSwitchMsg() {
msg.Hops = append(msg.Hops, switchMsgHop{
Port: p.port,
Next: p.sig,
Sig: *sign(&p.core.sigPriv, bs),
Sig: *crypto.Sign(&p.core.sigPriv, bs),
})
packet := msg.encode()
p.sendLinkPacket(packet)
@ -317,7 +320,7 @@ func (p *peer) handleSwitchMsg(packet []byte) {
sigMsg.Hops = msg.Hops[:idx]
loc.coords = append(loc.coords, hop.Port)
bs := getBytesForSig(&hop.Next, &sigMsg)
if !verify(&prevKey, bs, &hop.Sig) {
if !crypto.Verify(&prevKey, bs, &hop.Sig) {
p.core.peers.removePeer(p.port)
}
prevKey = hop.Next
@ -339,7 +342,7 @@ func (p *peer) handleSwitchMsg(packet []byte) {
// This generates the bytes that we sign or check the signature of for a switchMsg.
// It begins with the next node's key, followed by the root and the timetsamp, followed by coords being advertised to the next node.
func getBytesForSig(next *sigPubKey, msg *switchMsg) []byte {
func getBytesForSig(next *crypto.SigPubKey, msg *switchMsg) []byte {
var loc switchLocator
for _, hop := range msg.Hops {
loc.coords = append(loc.coords, hop.Port)

View File

@ -28,14 +28,18 @@ import (
"golang.org/x/net/icmp"
"golang.org/x/net/ipv6"
"github.com/yggdrasil-network/yggdrasil-go/src/address"
"github.com/yggdrasil-network/yggdrasil-go/src/crypto"
"github.com/yggdrasil-network/yggdrasil-go/src/util"
)
// The router struct has channels to/from the tun/tap device and a self peer (0), which is how messages are passed between this node and the peers/switch layer.
// The router's mainLoop goroutine is responsible for managing all information related to the dht, searches, and crypto sessions.
type router struct {
core *Core
addr address
subnet subnet
addr address.Address
subnet address.Subnet
in <-chan []byte // packets we received from the network, link to peer's "out"
out func([]byte) // packets we're sending to the network, link to peer's "in"
toRecv chan router_recvPacket // packets to handle via recvPacket()
@ -57,17 +61,17 @@ type router_recvPacket struct {
// Initializes the router struct, which includes setting up channels to/from the tun/tap.
func (r *router) init(core *Core) {
r.core = core
r.addr = *address_addrForNodeID(&r.core.dht.nodeID)
r.subnet = *address_subnetForNodeID(&r.core.dht.nodeID)
r.addr = *address.AddrForNodeID(&r.core.dht.nodeID)
r.subnet = *address.SubnetForNodeID(&r.core.dht.nodeID)
in := make(chan []byte, 32) // TODO something better than this...
p := r.core.peers.newPeer(&r.core.boxPub, &r.core.sigPub, &boxSharedKey{}, "(self)")
p := r.core.peers.newPeer(&r.core.boxPub, &r.core.sigPub, &crypto.BoxSharedKey{}, "(self)")
p.out = func(packet []byte) {
// This is to make very sure it never blocks
select {
case in <- packet:
return
default:
util_putBytes(packet)
util.PutBytes(packet)
}
}
r.in = in
@ -121,7 +125,7 @@ func (r *router) mainLoop() {
r.core.switchTable.doMaintenance()
r.core.dht.doMaintenance()
r.core.sessions.cleanup()
util_getBytes() // To slowly drain things
util.GetBytes() // To slowly drain things
}
case f := <-r.admin:
f()
@ -135,11 +139,11 @@ func (r *router) mainLoop() {
// If the session hasn't responded recently, it triggers a ping or search to keep things alive or deal with broken coords *relatively* quickly.
// It also deals with oversized packets if there are MTU issues by calling into icmpv6.go to spoof PacketTooBig traffic, or DestinationUnreachable if the other side has their tun/tap disabled.
func (r *router) sendPacket(bs []byte) {
var sourceAddr address
var destAddr address
var destSnet subnet
var destPubKey *boxPubKey
var destNodeID *NodeID
var sourceAddr address.Address
var destAddr address.Address
var destSnet address.Subnet
var destPubKey *crypto.BoxPubKey
var destNodeID *crypto.NodeID
var addrlen int
if bs[0]&0xf0 == 0x60 {
// Check if we have a fully-sized header
@ -169,19 +173,19 @@ func (r *router) sendPacket(bs []byte) {
// configured crypto-key routing source subnets
return
}
if !destAddr.isValid() && !destSnet.isValid() {
if !destAddr.IsValid() && !destSnet.IsValid() {
// The addresses didn't match valid Yggdrasil node addresses so let's see
// whether it matches a crypto-key routing range instead
if key, err := r.cryptokey.getPublicKeyForAddress(destAddr, addrlen); err == nil {
// A public key was found, get the node ID for the search
destPubKey = &key
destNodeID = getNodeID(destPubKey)
destNodeID = crypto.GetNodeID(destPubKey)
// Do a quick check to ensure that the node ID refers to a vaild Yggdrasil
// address or subnet - this might be superfluous
addr := *address_addrForNodeID(destNodeID)
addr := *address.AddrForNodeID(destNodeID)
copy(destAddr[:], addr[:])
copy(destSnet[:], addr[:])
if !destAddr.isValid() && !destSnet.isValid() {
if !destAddr.IsValid() && !destSnet.IsValid() {
return
}
} else {
@ -190,25 +194,25 @@ func (r *router) sendPacket(bs []byte) {
}
}
doSearch := func(packet []byte) {
var nodeID, mask *NodeID
var nodeID, mask *crypto.NodeID
switch {
case destNodeID != nil:
// We already know the full node ID, probably because it's from a CKR
// route in which the public key is known ahead of time
nodeID = destNodeID
var m NodeID
var m crypto.NodeID
for i := range m {
m[i] = 0xFF
}
mask = &m
case destAddr.isValid():
case destAddr.IsValid():
// We don't know the full node ID - try and use the address to generate
// a truncated node ID
nodeID, mask = destAddr.getNodeIDandMask()
case destSnet.isValid():
nodeID, mask = destAddr.GetNodeIDandMask()
case destSnet.IsValid():
// We don't know the full node ID - try and use the subnet to generate
// a truncated node ID
nodeID, mask = destSnet.getNodeIDandMask()
nodeID, mask = destSnet.GetNodeIDandMask()
default:
return
}
@ -223,10 +227,10 @@ func (r *router) sendPacket(bs []byte) {
}
var sinfo *sessionInfo
var isIn bool
if destAddr.isValid() {
if destAddr.IsValid() {
sinfo, isIn = r.core.sessions.getByTheirAddr(&destAddr)
}
if destSnet.isValid() {
if destSnet.IsValid() {
sinfo, isIn = r.core.sessions.getByTheirSubnet(&destSnet)
}
switch {
@ -305,12 +309,12 @@ func (r *router) sendPacket(bs []byte) {
func (r *router) recvPacket(bs []byte, sinfo *sessionInfo) {
// Note: called directly by the session worker, not the router goroutine
if len(bs) < 24 {
util_putBytes(bs)
util.PutBytes(bs)
return
}
var sourceAddr address
var dest address
var snet subnet
var sourceAddr address.Address
var dest address.Address
var snet address.Subnet
var addrlen int
if bs[0]&0xf0 == 0x60 {
// IPv6 address
@ -330,17 +334,17 @@ func (r *router) recvPacket(bs []byte, sinfo *sessionInfo) {
// Check that the packet is destined for either our Yggdrasil address or
// subnet, or that it matches one of the crypto-key routing source routes
if !r.cryptokey.isValidSource(dest, addrlen) {
util_putBytes(bs)
util.PutBytes(bs)
return
}
// See whether the packet they sent should have originated from this session
switch {
case sourceAddr.isValid() && sourceAddr == sinfo.theirAddr:
case snet.isValid() && snet == sinfo.theirSubnet:
case sourceAddr.IsValid() && sourceAddr == sinfo.theirAddr:
case snet.IsValid() && snet == sinfo.theirSubnet:
default:
key, err := r.cryptokey.getPublicKeyForAddress(sourceAddr, addrlen)
if err != nil || key != sinfo.theirPermPub {
util_putBytes(bs)
util.PutBytes(bs)
return
}
}
@ -366,7 +370,7 @@ func (r *router) handleIn(packet []byte) {
// Handles incoming traffic, i.e. encapuslated ordinary IPv6 packets.
// Passes them to the crypto session worker to be decrypted and sent to the tun/tap.
func (r *router) handleTraffic(packet []byte) {
defer util_putBytes(packet)
defer util.PutBytes(packet)
p := wire_trafficPacket{}
if !p.decode(packet) {
return
@ -386,14 +390,14 @@ func (r *router) handleProto(packet []byte) {
return
}
// Now try to open the payload
var sharedKey *boxSharedKey
var sharedKey *crypto.BoxSharedKey
if p.ToKey == r.core.boxPub {
// Try to open using our permanent key
sharedKey = r.core.sessions.getSharedKey(&r.core.boxPriv, &p.FromKey)
} else {
return
}
bs, isOK := boxOpen(sharedKey, p.Payload, &p.Nonce)
bs, isOK := crypto.BoxOpen(sharedKey, p.Payload, &p.Nonce)
if !isOK {
return
}
@ -418,12 +422,12 @@ func (r *router) handleProto(packet []byte) {
case wire_DHTLookupResponse:
r.handleDHTRes(bs, &p.FromKey)
default:
util_putBytes(packet)
util.PutBytes(packet)
}
}
// Decodes session pings from wire format and passes them to sessions.handlePing where they either create or update a session.
func (r *router) handlePing(bs []byte, fromKey *boxPubKey) {
func (r *router) handlePing(bs []byte, fromKey *crypto.BoxPubKey) {
ping := sessionPing{}
if !ping.decode(bs) {
return
@ -433,12 +437,12 @@ func (r *router) handlePing(bs []byte, fromKey *boxPubKey) {
}
// Handles session pongs (which are really pings with an extra flag to prevent acknowledgement).
func (r *router) handlePong(bs []byte, fromKey *boxPubKey) {
func (r *router) handlePong(bs []byte, fromKey *crypto.BoxPubKey) {
r.handlePing(bs, fromKey)
}
// Decodes dht requests and passes them to dht.handleReq to trigger a lookup/response.
func (r *router) handleDHTReq(bs []byte, fromKey *boxPubKey) {
func (r *router) handleDHTReq(bs []byte, fromKey *crypto.BoxPubKey) {
req := dhtReq{}
if !req.decode(bs) {
return
@ -448,7 +452,7 @@ func (r *router) handleDHTReq(bs []byte, fromKey *boxPubKey) {
}
// Decodes dht responses and passes them to dht.handleRes to update the DHT table and further pass them to the search code (if applicable).
func (r *router) handleDHTRes(bs []byte, fromKey *boxPubKey) {
func (r *router) handleDHTRes(bs []byte, fromKey *crypto.BoxPubKey) {
res := dhtRes{}
if !res.decode(bs) {
return
@ -458,7 +462,7 @@ func (r *router) handleDHTRes(bs []byte, fromKey *boxPubKey) {
}
// Decodes nodeinfo request
func (r *router) handleNodeInfo(bs []byte, fromKey *boxPubKey) {
func (r *router) handleNodeInfo(bs []byte, fromKey *crypto.BoxPubKey) {
req := nodeinfoReqRes{}
if !req.decode(bs) {
return

View File

@ -17,6 +17,8 @@ package yggdrasil
import (
"sort"
"time"
"github.com/yggdrasil-network/yggdrasil-go/src/crypto"
)
// This defines the maximum number of dhtInfo that we keep track of for nodes to query in an ongoing search.
@ -30,28 +32,28 @@ const search_RETRY_TIME = time.Second
// Information about an ongoing search.
// Includes the targed NodeID, the bitmask to match it to an IP, and the list of nodes to visit / already visited.
type searchInfo struct {
dest NodeID
mask NodeID
dest crypto.NodeID
mask crypto.NodeID
time time.Time
packet []byte
toVisit []*dhtInfo
visited map[NodeID]bool
visited map[crypto.NodeID]bool
}
// This stores a map of active searches.
type searches struct {
core *Core
searches map[NodeID]*searchInfo
searches map[crypto.NodeID]*searchInfo
}
// Intializes the searches struct.
func (s *searches) init(core *Core) {
s.core = core
s.searches = make(map[NodeID]*searchInfo)
s.searches = make(map[crypto.NodeID]*searchInfo)
}
// Creates a new search info, adds it to the searches struct, and returns a pointer to the info.
func (s *searches) createSearch(dest *NodeID, mask *NodeID) *searchInfo {
func (s *searches) createSearch(dest *crypto.NodeID, mask *crypto.NodeID) *searchInfo {
now := time.Now()
for dest, sinfo := range s.searches {
if now.Sub(sinfo.time) > time.Minute {
@ -102,7 +104,7 @@ func (s *searches) addToSearch(sinfo *searchInfo, res *dhtRes) {
}
}
// Deduplicate
vMap := make(map[NodeID]*dhtInfo)
vMap := make(map[crypto.NodeID]*dhtInfo)
for _, info := range sinfo.toVisit {
vMap[*info.getNodeID()] = info
}
@ -163,10 +165,10 @@ func (s *searches) continueSearch(sinfo *searchInfo) {
}
// Calls create search, and initializes the iterative search parts of the struct before returning it.
func (s *searches) newIterSearch(dest *NodeID, mask *NodeID) *searchInfo {
func (s *searches) newIterSearch(dest *crypto.NodeID, mask *crypto.NodeID) *searchInfo {
sinfo := s.createSearch(dest, mask)
sinfo.toVisit = s.core.dht.lookup(dest, true)
sinfo.visited = make(map[NodeID]bool)
sinfo.visited = make(map[crypto.NodeID]bool)
return sinfo
}
@ -174,10 +176,10 @@ func (s *searches) newIterSearch(dest *NodeID, mask *NodeID) *searchInfo {
// If the response is from the target, get/create a session, trigger a session ping, and return true.
// Otherwise return false.
func (s *searches) checkDHTRes(info *searchInfo, res *dhtRes) bool {
them := getNodeID(&res.Key)
var destMasked NodeID
var themMasked NodeID
for idx := 0; idx < NodeIDLen; idx++ {
them := crypto.GetNodeID(&res.Key)
var destMasked crypto.NodeID
var themMasked crypto.NodeID
for idx := 0; idx < crypto.NodeIDLen; idx++ {
destMasked[idx] = info.dest[idx] & info.mask[idx]
themMasked[idx] = them[idx] & info.mask[idx]
}

View File

@ -8,23 +8,27 @@ import (
"bytes"
"encoding/hex"
"time"
"github.com/yggdrasil-network/yggdrasil-go/src/address"
"github.com/yggdrasil-network/yggdrasil-go/src/crypto"
"github.com/yggdrasil-network/yggdrasil-go/src/util"
)
// All the information we know about an active session.
// This includes coords, permanent and ephemeral keys, handles and nonces, various sorts of timing information for timeout and maintenance, and some metadata for the admin API.
type sessionInfo struct {
core *Core
theirAddr address
theirSubnet subnet
theirPermPub boxPubKey
theirSesPub boxPubKey
mySesPub boxPubKey
mySesPriv boxPrivKey
sharedSesKey boxSharedKey // derived from session keys
theirHandle handle
myHandle handle
theirNonce boxNonce
myNonce boxNonce
theirAddr address.Address
theirSubnet address.Subnet
theirPermPub crypto.BoxPubKey
theirSesPub crypto.BoxPubKey
mySesPub crypto.BoxPubKey
mySesPriv crypto.BoxPrivKey
sharedSesKey crypto.BoxSharedKey // derived from session keys
theirHandle crypto.Handle
myHandle crypto.Handle
theirNonce crypto.BoxNonce
myNonce crypto.BoxNonce
theirMTU uint16
myMTU uint16
wasMTUFixed bool // Was the MTU fixed by a receive error?
@ -45,9 +49,9 @@ type sessionInfo struct {
// Represents a session ping/pong packet, andincludes information like public keys, a session handle, coords, a timestamp to prevent replays, and the tun/tap MTU.
type sessionPing struct {
SendPermPub boxPubKey // Sender's permanent key
Handle handle // Random number to ID session
SendSesPub boxPubKey // Session key to use
SendPermPub crypto.BoxPubKey // Sender's permanent key
Handle crypto.Handle // Random number to ID session
SendSesPub crypto.BoxPubKey // Session key to use
Coords []byte
Tstamp int64 // unix time, but the only real requirement is that it increases
IsPong bool
@ -69,8 +73,8 @@ func (s *sessionInfo) update(p *sessionPing) bool {
if p.SendSesPub != s.theirSesPub {
s.theirSesPub = p.SendSesPub
s.theirHandle = p.Handle
s.sharedSesKey = *getSharedKey(&s.mySesPriv, &s.theirSesPub)
s.theirNonce = boxNonce{}
s.sharedSesKey = *crypto.GetSharedKey(&s.mySesPriv, &s.theirSesPub)
s.theirNonce = crypto.BoxNonce{}
s.nonceMask = 0
}
if p.MTU >= 1280 || p.MTU == 0 {
@ -99,15 +103,15 @@ type sessions struct {
core *Core
lastCleanup time.Time
// Maps known permanent keys to their shared key, used by DHT a lot
permShared map[boxPubKey]*boxSharedKey
permShared map[crypto.BoxPubKey]*crypto.BoxSharedKey
// Maps (secret) handle onto session info
sinfos map[handle]*sessionInfo
sinfos map[crypto.Handle]*sessionInfo
// Maps mySesPub onto handle
byMySes map[boxPubKey]*handle
byMySes map[crypto.BoxPubKey]*crypto.Handle
// Maps theirPermPub onto handle
byTheirPerm map[boxPubKey]*handle
addrToPerm map[address]*boxPubKey
subnetToPerm map[subnet]*boxPubKey
byTheirPerm map[crypto.BoxPubKey]*crypto.Handle
addrToPerm map[address.Address]*crypto.BoxPubKey
subnetToPerm map[address.Subnet]*crypto.BoxPubKey
// Options from the session firewall
sessionFirewallEnabled bool
sessionFirewallAllowsDirect bool
@ -120,12 +124,12 @@ type sessions struct {
// Initializes the session struct.
func (ss *sessions) init(core *Core) {
ss.core = core
ss.permShared = make(map[boxPubKey]*boxSharedKey)
ss.sinfos = make(map[handle]*sessionInfo)
ss.byMySes = make(map[boxPubKey]*handle)
ss.byTheirPerm = make(map[boxPubKey]*handle)
ss.addrToPerm = make(map[address]*boxPubKey)
ss.subnetToPerm = make(map[subnet]*boxPubKey)
ss.permShared = make(map[crypto.BoxPubKey]*crypto.BoxSharedKey)
ss.sinfos = make(map[crypto.Handle]*sessionInfo)
ss.byMySes = make(map[crypto.BoxPubKey]*crypto.Handle)
ss.byTheirPerm = make(map[crypto.BoxPubKey]*crypto.Handle)
ss.addrToPerm = make(map[address.Address]*crypto.BoxPubKey)
ss.subnetToPerm = make(map[address.Subnet]*crypto.BoxPubKey)
ss.lastCleanup = time.Now()
}
@ -154,18 +158,18 @@ func (ss *sessions) setSessionFirewallBlacklist(blacklist []string) {
// Determines whether the session with a given publickey is allowed based on
// session firewall rules.
func (ss *sessions) isSessionAllowed(pubkey *boxPubKey, initiator bool) bool {
func (ss *sessions) isSessionAllowed(pubkey *crypto.BoxPubKey, initiator bool) bool {
// Allow by default if the session firewall is disabled
if !ss.sessionFirewallEnabled {
return true
}
// Prepare for checking whitelist/blacklist
var box boxPubKey
var box crypto.BoxPubKey
// Reject blacklisted nodes
for _, b := range ss.sessionFirewallBlacklist {
key, err := hex.DecodeString(b)
if err == nil {
copy(box[:boxPubKeyLen], key)
copy(box[:crypto.BoxPubKeyLen], key)
if box == *pubkey {
return false
}
@ -175,7 +179,7 @@ func (ss *sessions) isSessionAllowed(pubkey *boxPubKey, initiator bool) bool {
for _, b := range ss.sessionFirewallWhitelist {
key, err := hex.DecodeString(b)
if err == nil {
copy(box[:boxPubKeyLen], key)
copy(box[:crypto.BoxPubKeyLen], key)
if box == *pubkey {
return true
}
@ -208,7 +212,7 @@ func (ss *sessions) isSessionAllowed(pubkey *boxPubKey, initiator bool) bool {
}
// Gets the session corresponding to a given handle.
func (ss *sessions) getSessionForHandle(handle *handle) (*sessionInfo, bool) {
func (ss *sessions) getSessionForHandle(handle *crypto.Handle) (*sessionInfo, bool) {
sinfo, isIn := ss.sinfos[*handle]
if isIn && sinfo.timedout() {
// We have a session, but it has timed out
@ -218,7 +222,7 @@ func (ss *sessions) getSessionForHandle(handle *handle) (*sessionInfo, bool) {
}
// Gets a session corresponding to an ephemeral session key used by this node.
func (ss *sessions) getByMySes(key *boxPubKey) (*sessionInfo, bool) {
func (ss *sessions) getByMySes(key *crypto.BoxPubKey) (*sessionInfo, bool) {
h, isIn := ss.byMySes[*key]
if !isIn {
return nil, false
@ -228,7 +232,7 @@ func (ss *sessions) getByMySes(key *boxPubKey) (*sessionInfo, bool) {
}
// Gets a session corresponding to a permanent key used by the remote node.
func (ss *sessions) getByTheirPerm(key *boxPubKey) (*sessionInfo, bool) {
func (ss *sessions) getByTheirPerm(key *crypto.BoxPubKey) (*sessionInfo, bool) {
h, isIn := ss.byTheirPerm[*key]
if !isIn {
return nil, false
@ -238,7 +242,7 @@ func (ss *sessions) getByTheirPerm(key *boxPubKey) (*sessionInfo, bool) {
}
// Gets a session corresponding to an IPv6 address used by the remote node.
func (ss *sessions) getByTheirAddr(addr *address) (*sessionInfo, bool) {
func (ss *sessions) getByTheirAddr(addr *address.Address) (*sessionInfo, bool) {
p, isIn := ss.addrToPerm[*addr]
if !isIn {
return nil, false
@ -248,7 +252,7 @@ func (ss *sessions) getByTheirAddr(addr *address) (*sessionInfo, bool) {
}
// Gets a session corresponding to an IPv6 /64 subnet used by the remote node/network.
func (ss *sessions) getByTheirSubnet(snet *subnet) (*sessionInfo, bool) {
func (ss *sessions) getByTheirSubnet(snet *address.Subnet) (*sessionInfo, bool) {
p, isIn := ss.subnetToPerm[*snet]
if !isIn {
return nil, false
@ -259,7 +263,7 @@ func (ss *sessions) getByTheirSubnet(snet *subnet) (*sessionInfo, bool) {
// Creates a new session and lazily cleans up old/timedout existing sessions.
// This includse initializing session info to sane defaults (e.g. lowest supported MTU).
func (ss *sessions) createSession(theirPermKey *boxPubKey) *sessionInfo {
func (ss *sessions) createSession(theirPermKey *crypto.BoxPubKey) *sessionInfo {
if ss.sessionFirewallEnabled {
if !ss.isSessionAllowed(theirPermKey, true) {
return nil
@ -268,10 +272,10 @@ func (ss *sessions) createSession(theirPermKey *boxPubKey) *sessionInfo {
sinfo := sessionInfo{}
sinfo.core = ss.core
sinfo.theirPermPub = *theirPermKey
pub, priv := newBoxKeys()
pub, priv := crypto.NewBoxKeys()
sinfo.mySesPub = *pub
sinfo.mySesPriv = *priv
sinfo.myNonce = *newBoxNonce()
sinfo.myNonce = *crypto.NewBoxNonce()
sinfo.theirMTU = 1280
sinfo.myMTU = uint16(ss.core.router.tun.mtu)
now := time.Now()
@ -295,9 +299,9 @@ func (ss *sessions) createSession(theirPermKey *boxPubKey) *sessionInfo {
// lower => even nonce
sinfo.myNonce[len(sinfo.myNonce)-1] &= 0xfe
}
sinfo.myHandle = *newHandle()
sinfo.theirAddr = *address_addrForNodeID(getNodeID(&sinfo.theirPermPub))
sinfo.theirSubnet = *address_subnetForNodeID(getNodeID(&sinfo.theirPermPub))
sinfo.myHandle = *crypto.NewHandle()
sinfo.theirAddr = *address.AddrForNodeID(crypto.GetNodeID(&sinfo.theirPermPub))
sinfo.theirSubnet = *address.SubnetForNodeID(crypto.GetNodeID(&sinfo.theirPermPub))
sinfo.send = make(chan []byte, 32)
sinfo.recv = make(chan *wire_trafficPacket, 32)
go sinfo.doWorker()
@ -324,32 +328,32 @@ func (ss *sessions) cleanup() {
s.close()
}
}
permShared := make(map[boxPubKey]*boxSharedKey, len(ss.permShared))
permShared := make(map[crypto.BoxPubKey]*crypto.BoxSharedKey, len(ss.permShared))
for k, v := range ss.permShared {
permShared[k] = v
}
ss.permShared = permShared
sinfos := make(map[handle]*sessionInfo, len(ss.sinfos))
sinfos := make(map[crypto.Handle]*sessionInfo, len(ss.sinfos))
for k, v := range ss.sinfos {
sinfos[k] = v
}
ss.sinfos = sinfos
byMySes := make(map[boxPubKey]*handle, len(ss.byMySes))
byMySes := make(map[crypto.BoxPubKey]*crypto.Handle, len(ss.byMySes))
for k, v := range ss.byMySes {
byMySes[k] = v
}
ss.byMySes = byMySes
byTheirPerm := make(map[boxPubKey]*handle, len(ss.byTheirPerm))
byTheirPerm := make(map[crypto.BoxPubKey]*crypto.Handle, len(ss.byTheirPerm))
for k, v := range ss.byTheirPerm {
byTheirPerm[k] = v
}
ss.byTheirPerm = byTheirPerm
addrToPerm := make(map[address]*boxPubKey, len(ss.addrToPerm))
addrToPerm := make(map[address.Address]*crypto.BoxPubKey, len(ss.addrToPerm))
for k, v := range ss.addrToPerm {
addrToPerm[k] = v
}
ss.addrToPerm = addrToPerm
subnetToPerm := make(map[subnet]*boxPubKey, len(ss.subnetToPerm))
subnetToPerm := make(map[address.Subnet]*crypto.BoxPubKey, len(ss.subnetToPerm))
for k, v := range ss.subnetToPerm {
subnetToPerm[k] = v
}
@ -380,15 +384,15 @@ func (ss *sessions) getPing(sinfo *sessionInfo) sessionPing {
Coords: coords,
MTU: sinfo.myMTU,
}
sinfo.myNonce.update()
sinfo.myNonce.Increment()
return ref
}
// Gets the shared key for a pair of box keys.
// Used to cache recently used shared keys for protocol traffic.
// This comes up with dht req/res and session ping/pong traffic.
func (ss *sessions) getSharedKey(myPriv *boxPrivKey,
theirPub *boxPubKey) *boxSharedKey {
func (ss *sessions) getSharedKey(myPriv *crypto.BoxPrivKey,
theirPub *crypto.BoxPubKey) *crypto.BoxSharedKey {
if skey, isIn := ss.permShared[*theirPub]; isIn {
return skey
}
@ -401,7 +405,7 @@ func (ss *sessions) getSharedKey(myPriv *boxPrivKey,
}
delete(ss.permShared, key)
}
ss.permShared[*theirPub] = getSharedKey(myPriv, theirPub)
ss.permShared[*theirPub] = crypto.GetSharedKey(myPriv, theirPub)
return ss.permShared[*theirPub]
}
@ -417,7 +421,7 @@ func (ss *sessions) sendPingPong(sinfo *sessionInfo, isPong bool) {
ping.IsPong = isPong
bs := ping.encode()
shared := ss.getSharedKey(&ss.core.boxPriv, &sinfo.theirPermPub)
payload, nonce := boxSeal(shared, bs, nil)
payload, nonce := crypto.BoxSeal(shared, bs, nil)
p := wire_protoTrafficPacket{
Coords: sinfo.coords,
ToKey: sinfo.theirPermPub,
@ -468,24 +472,6 @@ func (ss *sessions) handlePing(ping *sessionPing) {
}
}
// Used to subtract one nonce from another, staying in the range +- 64.
// This is used by the nonce progression machinery to advance the bitmask of recently received packets (indexed by nonce), or to check the appropriate bit of the bitmask.
// It's basically part of the machinery that prevents replays and duplicate packets.
func (n *boxNonce) minus(m *boxNonce) int64 {
diff := int64(0)
for idx := range n {
diff *= 256
diff += int64(n[idx]) - int64(m[idx])
if diff > 64 {
diff = 64
}
if diff < -64 {
diff = -64
}
}
return diff
}
// Get the MTU of the session.
// Will be equal to the smaller of this node's MTU or the remote node's MTU.
// If sending over links with a maximum message size (this was a thing with the old UDP code), it could be further lowered, to a minimum of 1280.
@ -500,9 +486,9 @@ func (sinfo *sessionInfo) getMTU() uint16 {
}
// Checks if a packet's nonce is recent enough to fall within the window of allowed packets, and not already received.
func (sinfo *sessionInfo) nonceIsOK(theirNonce *boxNonce) bool {
func (sinfo *sessionInfo) nonceIsOK(theirNonce *crypto.BoxNonce) bool {
// The bitmask is to allow for some non-duplicate out-of-order packets
diff := theirNonce.minus(&sinfo.theirNonce)
diff := theirNonce.Minus(&sinfo.theirNonce)
if diff > 0 {
return true
}
@ -510,10 +496,10 @@ func (sinfo *sessionInfo) nonceIsOK(theirNonce *boxNonce) bool {
}
// Updates the nonce mask by (possibly) shifting the bitmask and setting the bit corresponding to this nonce to 1, and then updating the most recent nonce
func (sinfo *sessionInfo) updateNonce(theirNonce *boxNonce) {
func (sinfo *sessionInfo) updateNonce(theirNonce *crypto.BoxNonce) {
// Shift nonce mask if needed
// Set bit
diff := theirNonce.minus(&sinfo.theirNonce)
diff := theirNonce.Minus(&sinfo.theirNonce)
if diff > 0 {
// This nonce is newer, so shift the window before setting the bit, and update theirNonce in the session info.
sinfo.nonceMask <<= uint64(diff)
@ -559,7 +545,7 @@ func (sinfo *sessionInfo) doWorker() {
// This encrypts a packet, creates a trafficPacket struct, encodes it, and sends it to router.out to pass it to the switch layer.
func (sinfo *sessionInfo) doSend(bs []byte) {
defer util_putBytes(bs)
defer util.PutBytes(bs)
if !sinfo.init {
// To prevent using empty session keys
return
@ -593,8 +579,8 @@ func (sinfo *sessionInfo) doSend(bs []byte) {
coords = wire_put_uint64(flowkey, coords) // Then variable-length encoded flowkey
}
// Prepare the payload
payload, nonce := boxSeal(&sinfo.sharedSesKey, bs, &sinfo.myNonce)
defer util_putBytes(payload)
payload, nonce := crypto.BoxSeal(&sinfo.sharedSesKey, bs, &sinfo.myNonce)
defer util.PutBytes(payload)
p := wire_trafficPacket{
Coords: coords,
Handle: sinfo.theirHandle,
@ -612,13 +598,13 @@ func (sinfo *sessionInfo) doSend(bs []byte) {
// If a packet does not decrypt successfully, it assumes the packet was truncated, and updates the MTU accordingly.
// TODO? remove the MTU updating part? That should never happen with TCP peers, and the old UDP code that caused it was removed (and if replaced, should be replaced with something that can reliably send messages with an arbitrary size).
func (sinfo *sessionInfo) doRecv(p *wire_trafficPacket) {
defer util_putBytes(p.Payload)
defer util.PutBytes(p.Payload)
if !sinfo.nonceIsOK(&p.Nonce) {
return
}
bs, isOK := boxOpen(&sinfo.sharedSesKey, p.Payload, &p.Nonce)
bs, isOK := crypto.BoxOpen(&sinfo.sharedSesKey, p.Payload, &p.Nonce)
if !isOK {
util_putBytes(bs)
util.PutBytes(bs)
return
}
sinfo.updateNonce(&p.Nonce)

View File

@ -16,6 +16,9 @@ import (
"sync"
"sync/atomic"
"time"
"github.com/yggdrasil-network/yggdrasil-go/src/crypto"
"github.com/yggdrasil-network/yggdrasil-go/src/util"
)
const (
@ -30,16 +33,16 @@ const (
// The coords represent a path from the root to a node.
// This path is generally part of a spanning tree, except possibly the last hop (it can loop when sending coords to your parent, but they see this and know not to use a looping path).
type switchLocator struct {
root sigPubKey
root crypto.SigPubKey
tstamp int64
coords []switchPort
}
// Returns true if the first sigPubKey has a higher TreeID.
func firstIsBetter(first, second *sigPubKey) bool {
func firstIsBetter(first, second *crypto.SigPubKey) bool {
// Higher TreeID is better
ftid := getTreeID(first)
stid := getTreeID(second)
ftid := crypto.GetTreeID(first)
stid := crypto.GetTreeID(second)
for idx := 0; idx < len(ftid); idx++ {
if ftid[idx] == stid[idx] {
continue
@ -121,7 +124,7 @@ func (x *switchLocator) isAncestorOf(y *switchLocator) bool {
// Information about a peer, used by the switch to build the tree and eventually make routing decisions.
type peerInfo struct {
key sigPubKey // ID of this peer
key crypto.SigPubKey // ID of this peer
locator switchLocator // Should be able to respond with signatures upon request
degree uint64 // Self-reported degree
time time.Time // Time this node was last seen
@ -159,26 +162,26 @@ type switchData struct {
// All the information stored by the switch.
type switchTable struct {
core *Core
key sigPubKey // Our own key
time time.Time // Time when locator.tstamp was last updated
drop map[sigPubKey]int64 // Tstamp associated with a dropped root
mutex sync.RWMutex // Lock for reads/writes of switchData
parent switchPort // Port of whatever peer is our parent, or self if we're root
data switchData //
updater atomic.Value // *sync.Once
table atomic.Value // lookupTable
packetIn chan []byte // Incoming packets for the worker to handle
idleIn chan switchPort // Incoming idle notifications from peer links
admin chan func() // Pass a lambda for the admin socket to query stuff
queues switch_buffers // Queues - not atomic so ONLY use through admin chan
queueTotalMaxSize uint64 // Maximum combined size of queues
key crypto.SigPubKey // Our own key
time time.Time // Time when locator.tstamp was last updated
drop map[crypto.SigPubKey]int64 // Tstamp associated with a dropped root
mutex sync.RWMutex // Lock for reads/writes of switchData
parent switchPort // Port of whatever peer is our parent, or self if we're root
data switchData //
updater atomic.Value // *sync.Once
table atomic.Value // lookupTable
packetIn chan []byte // Incoming packets for the worker to handle
idleIn chan switchPort // Incoming idle notifications from peer links
admin chan func() // Pass a lambda for the admin socket to query stuff
queues switch_buffers // Queues - not atomic so ONLY use through admin chan
queueTotalMaxSize uint64 // Maximum combined size of queues
}
// Minimum allowed total size of switch queues.
const SwitchQueueTotalMinSize = 4 * 1024 * 1024
// Initializes the switchTable struct.
func (t *switchTable) init(core *Core, key sigPubKey) {
func (t *switchTable) init(core *Core, key crypto.SigPubKey) {
now := time.Now()
t.core = core
t.key = key
@ -187,7 +190,7 @@ func (t *switchTable) init(core *Core, key sigPubKey) {
t.data = switchData{locator: locator, peers: peers}
t.updater.Store(&sync.Once{})
t.table.Store(lookupTable{})
t.drop = make(map[sigPubKey]int64)
t.drop = make(map[crypto.SigPubKey]int64)
t.packetIn = make(chan []byte, 1024)
t.idleIn = make(chan switchPort, 1024)
t.admin = make(chan func())
@ -302,7 +305,7 @@ func (t *switchTable) cleanDropped() {
// This is exchanged with peers to construct the spanning tree.
// A subset of this information, excluding the signatures, is used to construct locators that are used elsewhere in the code.
type switchMsg struct {
Root sigPubKey
Root crypto.SigPubKey
TStamp int64
Hops []switchMsgHop
}
@ -310,8 +313,8 @@ type switchMsg struct {
// This represents the signed information about the path leading from the root the Next node, via the Port specified here.
type switchMsgHop struct {
Port switchPort
Next sigPubKey
Sig sigBytes
Next crypto.SigPubKey
Sig crypto.SigBytes
}
// This returns a *switchMsg to a copy of this node's current switchMsg, which can safely have additional information appended to Hops and sent to a peer.
@ -690,7 +693,7 @@ func (b *switch_buffers) cleanup(t *switchTable) {
coords := switch_getPacketCoords(packet.bytes)
if t.selfIsClosest(coords) {
for _, packet := range buf.packets {
util_putBytes(packet.bytes)
util.PutBytes(packet.bytes)
}
b.size -= buf.size
delete(b.bufs, streamID)
@ -710,7 +713,7 @@ func (b *switch_buffers) cleanup(t *switchTable) {
packet, buf.packets = buf.packets[0], buf.packets[1:]
buf.size -= uint64(len(packet.bytes))
b.size -= uint64(len(packet.bytes))
util_putBytes(packet.bytes)
util.PutBytes(packet.bytes)
if len(buf.packets) == 0 {
delete(b.bufs, streamID)
} else {

View File

@ -25,6 +25,10 @@ import (
"time"
"golang.org/x/net/proxy"
"github.com/yggdrasil-network/yggdrasil-go/src/address"
"github.com/yggdrasil-network/yggdrasil-go/src/crypto"
"github.com/yggdrasil-network/yggdrasil-go/src/util"
)
const tcp_msgSize = 2048 + 65535 // TODO figure out what makes sense
@ -44,8 +48,8 @@ type tcpInterface struct {
// This is used as the key to a map that tracks existing connections, to prevent multiple connections to the same keys and local/remote address pair from occuring.
// Different address combinations are allowed, so multi-homing is still technically possible (but not necessarily advisable).
type tcpInfo struct {
box boxPubKey
sig sigPubKey
box crypto.BoxPubKey
sig crypto.SigPubKey
localAddr string
remoteAddr string
}
@ -211,7 +215,7 @@ func (iface *tcpInterface) handler(sock net.Conn, incoming bool) {
defer sock.Close()
iface.setExtraOptions(sock)
// Get our keys
myLinkPub, myLinkPriv := newBoxKeys() // ephemeral link keys
myLinkPub, myLinkPriv := crypto.NewBoxKeys() // ephemeral link keys
meta := version_getBaseMetadata()
meta.box = iface.core.boxPub
meta.sig = iface.core.sigPub
@ -292,7 +296,7 @@ func (iface *tcpInterface) handler(sock net.Conn, incoming bool) {
}()
// Note that multiple connections to the same node are allowed
// E.g. over different interfaces
p := iface.core.peers.newPeer(&info.box, &info.sig, getSharedKey(myLinkPriv, &meta.link), sock.RemoteAddr().String())
p := iface.core.peers.newPeer(&info.box, &info.sig, crypto.GetSharedKey(myLinkPriv, &meta.link), sock.RemoteAddr().String())
p.linkOut = make(chan []byte, 1)
in := func(bs []byte) {
p.handlePacket(bs)
@ -306,7 +310,7 @@ func (iface *tcpInterface) handler(sock net.Conn, incoming bool) {
buf := net.Buffers{tcp_msg[:], msgLen, msg}
buf.WriteTo(sock)
atomic.AddUint64(&p.bytesSent, uint64(len(tcp_msg)+len(msgLen)+len(msg)))
util_putBytes(msg)
util.PutBytes(msg)
}
timerInterval := tcp_ping_interval
timer := time.NewTimer(timerInterval)
@ -354,8 +358,8 @@ func (iface *tcpInterface) handler(sock net.Conn, incoming bool) {
}()
us, _, _ := net.SplitHostPort(sock.LocalAddr().String())
them, _, _ := net.SplitHostPort(sock.RemoteAddr().String())
themNodeID := getNodeID(&info.box)
themAddr := address_addrForNodeID(themNodeID)
themNodeID := crypto.GetNodeID(&info.box)
themAddr := address.AddrForNodeID(themNodeID)
themAddrString := net.IP(themAddr[:]).String()
themString := fmt.Sprintf("%s@%s", themAddrString, them)
iface.core.log.Println("Connected:", themString, "source", us)
@ -390,9 +394,9 @@ func (iface *tcpInterface) reader(sock net.Conn, in func([]byte)) error {
// We didn't get the whole message yet
break
}
newMsg := append(util_getBytes(), msg...)
newMsg := append(util.GetBytes(), msg...)
in(newMsg)
util_yield()
util.Yield()
}
frag = append(bs[:0], frag...)
}

View File

@ -10,7 +10,9 @@ import (
"github.com/songgao/packets/ethernet"
"github.com/yggdrasil-network/water"
"github.com/yggdrasil-network/yggdrasil-go/src/address"
"github.com/yggdrasil-network/yggdrasil-go/src/defaults"
"github.com/yggdrasil-network/yggdrasil-go/src/util"
)
const tun_IPv6_HEADER_LENGTH = 40
@ -80,7 +82,7 @@ func (tun *tunAdapter) write() error {
continue
}
if tun.iface.IsTAP() {
var destAddr address
var destAddr address.Address
if data[0]&0xf0 == 0x60 {
if len(data) < 40 {
panic("Tried to send a packet shorter than an IPv6 header...")
@ -94,7 +96,7 @@ func (tun *tunAdapter) write() error {
} else {
return errors.New("Invalid address family")
}
sendndp := func(destAddr address) {
sendndp := func(destAddr address.Address) {
neigh, known := tun.icmpv6.peermacs[destAddr]
known = known && (time.Since(neigh.lastsolicitation).Seconds() < 30)
if !known {
@ -154,7 +156,7 @@ func (tun *tunAdapter) write() error {
panic(err)
}
}
util_putBytes(data)
util.PutBytes(data)
}
}
@ -191,7 +193,7 @@ func (tun *tunAdapter) read() error {
// tun.icmpv6.recv <- b
go tun.icmpv6.parse_packet(b)
}
packet := append(util_getBytes(), buf[o:n]...)
packet := append(util.GetBytes(), buf[o:n]...)
tun.send <- packet
}
}

View File

@ -4,6 +4,8 @@ package yggdrasil
// Used in the inital connection setup and key exchange
// Some of this could arguably go in wire.go instead
import "github.com/yggdrasil-network/yggdrasil-go/src/crypto"
// This is the version-specific metadata exchanged at the start of a connection.
// It must always beign with the 4 bytes "meta" and a wire formatted uint64 major version number.
// The current version also includes a minor version number, and the box/sig/link keys that need to be exchanged to open an connection.
@ -12,9 +14,9 @@ type version_metadata struct {
ver uint64 // 1 byte in this version
// Everything after this point potentially depends on the version number, and is subject to change in future versions
minorVer uint64 // 1 byte in this version
box boxPubKey
sig sigPubKey
link boxPubKey
box crypto.BoxPubKey
sig crypto.SigPubKey
link crypto.BoxPubKey
}
// Gets a base metadata with no keys set, but with the correct version numbers.
@ -28,12 +30,12 @@ func version_getBaseMetadata() version_metadata {
// Gest the length of the metadata for this version, used to know how many bytes to read from the start of a connection.
func version_getMetaLength() (mlen int) {
mlen += 4 // meta
mlen += 1 // ver, as long as it's < 127, which it is in this version
mlen += 1 // minorVer, as long as it's < 127, which it is in this version
mlen += boxPubKeyLen // box
mlen += sigPubKeyLen // sig
mlen += boxPubKeyLen // link
mlen += 4 // meta
mlen += 1 // ver, as long as it's < 127, which it is in this version
mlen += 1 // minorVer, as long as it's < 127, which it is in this version
mlen += crypto.BoxPubKeyLen // box
mlen += crypto.SigPubKeyLen // sig
mlen += crypto.BoxPubKeyLen // link
return
}

View File

@ -7,6 +7,11 @@ package yggdrasil
// Packet types, as wire_encode_uint64(type) at the start of each packet
import (
"github.com/yggdrasil-network/yggdrasil-go/src/crypto"
"github.com/yggdrasil-network/yggdrasil-go/src/util"
)
const (
wire_Traffic = iota // data being routed somewhere, handle for crypto
wire_ProtocolTraffic // protocol traffic, pub keys for crypto
@ -193,14 +198,14 @@ func wire_chop_uint64(toUInt64 *uint64, fromSlice *[]byte) bool {
// The wire format for ordinary IPv6 traffic encapsulated by the network.
type wire_trafficPacket struct {
Coords []byte
Handle handle
Nonce boxNonce
Handle crypto.Handle
Nonce crypto.BoxNonce
Payload []byte
}
// Encodes a wire_trafficPacket into its wire format.
func (p *wire_trafficPacket) encode() []byte {
bs := util_getBytes()
bs := util.GetBytes()
bs = wire_put_uint64(wire_Traffic, bs)
bs = wire_put_coords(p.Coords, bs)
bs = append(bs, p.Handle[:]...)
@ -224,16 +229,16 @@ func (p *wire_trafficPacket) decode(bs []byte) bool {
case !wire_chop_slice(p.Nonce[:], &bs):
return false
}
p.Payload = append(util_getBytes(), bs...)
p.Payload = append(util.GetBytes(), bs...)
return true
}
// The wire format for protocol traffic, such as dht req/res or session ping/pong packets.
type wire_protoTrafficPacket struct {
Coords []byte
ToKey boxPubKey
FromKey boxPubKey
Nonce boxNonce
ToKey crypto.BoxPubKey
FromKey crypto.BoxPubKey
Nonce crypto.BoxNonce
Payload []byte
}
@ -275,7 +280,7 @@ func (p *wire_protoTrafficPacket) decode(bs []byte) bool {
// The keys themselves are exchanged as part of the connection setup, and then omitted from the packets.
// The two layer logic is handled in peers.go, but it's kind of ugly.
type wire_linkProtoTrafficPacket struct {
Nonce boxNonce
Nonce crypto.BoxNonce
Payload []byte
}