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package yggdrasil
// This part does most of the work to handle packets to/from yourself
// It also manages crypto and dht info
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// TODO clean up old/unused code, maybe improve comments on whatever is left
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// Send:
// Receive a packet from the tun
// Look up session (if none exists, trigger a search)
// Hand off to session (which encrypts, etc)
// Session will pass it back to router.out, which hands it off to the self peer
// The self peer triggers a lookup to find which peer to send to next
// And then passes it to that's peer's peer.out function
// The peer.out function sends it over the wire to the matching peer
// Recv:
// A packet comes in off the wire, and goes to a peer.handlePacket
// The peer does a lookup, sees no better peer than the self
// Hands it to the self peer.out, which passes it to router.in
// If it's dht/seach/etc. traffic, the router passes it to that part
// If it's an encapsulated IPv6 packet, the router looks up the session for it
// The packet is passed to the session, which decrypts it, router.recvPacket
// The router then runs some sanity checks before passing it to the tun
import "time"
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import "golang.org/x/net/icmp"
import "golang.org/x/net/ipv6"
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//import "fmt"
//import "net"
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// 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.
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type router struct {
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core * Core
addr address
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"
recv chan <- [ ] byte // place where the tun pulls received packets from
send <- chan [ ] byte // place where the tun puts outgoing packets
reset chan struct { } // signal that coords changed (re-init sessions/dht)
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admin chan func ( ) // pass a lambda for the admin socket to query stuff
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}
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// Initializes the router struct, which includes setting up channels to/from the tun/tap.
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func ( r * router ) init ( core * Core ) {
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r . core = core
r . addr = * address_addrForNodeID ( & r . core . dht . nodeID )
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in := make ( chan [ ] byte , 32 ) // TODO something better than this...
p := r . core . peers . newPeer ( & r . core . boxPub , & r . core . sigPub , & boxSharedKey { } )
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p . out = func ( packet [ ] byte ) {
// This is to make very sure it never blocks
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select {
case in <- packet :
return
default :
util_putBytes ( packet )
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}
}
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r . in = in
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r . out = func ( packet [ ] byte ) { p . handlePacket ( packet ) } // The caller is responsible for go-ing if it needs to not block
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recv := make ( chan [ ] byte , 32 )
send := make ( chan [ ] byte , 32 )
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r . recv = recv
r . send = send
r . core . tun . recv = recv
r . core . tun . send = send
r . reset = make ( chan struct { } , 1 )
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r . admin = make ( chan func ( ) )
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// go r.mainLoop()
}
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// Starts the mainLoop goroutine.
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func ( r * router ) start ( ) error {
r . core . log . Println ( "Starting router" )
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go r . mainLoop ( )
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return nil
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}
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// Takes traffic from the tun/tap and passes it to router.send, or from r.in and handles incoming traffic.
// Also adds new peer info to the DHT.
// Also resets the DHT and sesssions in the event of a coord change.
// Also does periodic maintenance stuff.
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func ( r * router ) mainLoop ( ) {
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ticker := time . NewTicker ( time . Second )
defer ticker . Stop ( )
for {
select {
case p := <- r . in :
r . handleIn ( p )
case p := <- r . send :
r . sendPacket ( p )
case info := <- r . core . dht . peers :
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r . core . dht . insertIfNew ( info , false ) // Insert as a normal node
r . core . dht . insertIfNew ( info , true ) // Insert as a peer
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case <- r . reset :
r . core . sessions . resetInits ( )
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r . core . dht . reset ( )
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case <- ticker . C :
{
// Any periodic maintenance stuff goes here
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r . core . switchTable . doMaintenance ( )
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r . core . dht . doMaintenance ( )
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//r.core.peers.sendSwitchMsgs() // FIXME debugging
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util_getBytes ( ) // To slowly drain things
}
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case f := <- r . admin :
f ( )
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}
}
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}
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// Checks a packet's to/from address to make sure it's in the allowed range.
// If a session to the destination exists, gets the session and passes the packet to it.
// If no session exists, it triggers (or continues) a search.
// 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.
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func ( r * router ) sendPacket ( bs [ ] byte ) {
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if len ( bs ) < 40 {
panic ( "Tried to send a packet shorter than a header..." )
}
var sourceAddr address
var sourceSubnet subnet
copy ( sourceAddr [ : ] , bs [ 8 : ] )
copy ( sourceSubnet [ : ] , bs [ 8 : ] )
if ! sourceAddr . isValid ( ) && ! sourceSubnet . isValid ( ) {
return
}
var dest address
copy ( dest [ : ] , bs [ 24 : ] )
var snet subnet
copy ( snet [ : ] , bs [ 24 : ] )
if ! dest . isValid ( ) && ! snet . isValid ( ) {
return
}
doSearch := func ( packet [ ] byte ) {
var nodeID , mask * NodeID
if dest . isValid ( ) {
nodeID , mask = dest . getNodeIDandMask ( )
}
if snet . isValid ( ) {
nodeID , mask = snet . getNodeIDandMask ( )
}
sinfo , isIn := r . core . searches . searches [ * nodeID ]
if ! isIn {
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sinfo = r . core . searches . newIterSearch ( nodeID , mask )
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}
if packet != nil {
sinfo . packet = packet
}
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r . core . searches . continueSearch ( sinfo )
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}
var sinfo * sessionInfo
var isIn bool
if dest . isValid ( ) {
sinfo , isIn = r . core . sessions . getByTheirAddr ( & dest )
}
if snet . isValid ( ) {
sinfo , isIn = r . core . sessions . getByTheirSubnet ( & snet )
}
switch {
case ! isIn || ! sinfo . init :
// No or unintiialized session, so we need to search first
doSearch ( bs )
case time . Since ( sinfo . time ) > 6 * time . Second :
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if sinfo . time . Before ( sinfo . pingTime ) && time . Since ( sinfo . pingTime ) > 6 * time . Second {
// We haven't heard from the dest in a while
// We tried pinging but didn't get a response
// They may have changed coords
// Try searching to discover new coords
// Note that search spam is throttled internally
doSearch ( nil )
} else {
// We haven't heard about the dest in a while
now := time . Now ( )
if ! sinfo . time . Before ( sinfo . pingTime ) {
// Update pingTime to start the clock for searches (above)
sinfo . pingTime = now
}
if time . Since ( sinfo . pingSend ) > time . Second {
// Send at most 1 ping per second
sinfo . pingSend = now
r . core . sessions . sendPingPong ( sinfo , false )
}
}
fallthrough // Also send the packet
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default :
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// Drop packets if the session MTU is 0 - this means that one or other
// side probably has their TUN adapter disabled
if sinfo . getMTU ( ) == 0 {
// Get the size of the oversized payload, up to a max of 900 bytes
window := 900
if len ( bs ) < window {
window = len ( bs )
}
// Create the Destination Unreachable response
ptb := & icmp . DstUnreach {
Data : bs [ : window ] ,
}
// Create the ICMPv6 response from it
icmpv6Buf , err := r . core . tun . icmpv6 . create_icmpv6_tun (
bs [ 8 : 24 ] , bs [ 24 : 40 ] ,
ipv6 . ICMPTypeDestinationUnreachable , 1 , ptb )
if err == nil {
r . recv <- icmpv6Buf
}
// Don't continue - drop the packet
return
}
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// Generate an ICMPv6 Packet Too Big for packets larger than session MTU
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if len ( bs ) > int ( sinfo . getMTU ( ) ) {
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// Get the size of the oversized payload, up to a max of 900 bytes
window := 900
if int ( sinfo . getMTU ( ) ) < window {
window = int ( sinfo . getMTU ( ) )
}
// Create the Packet Too Big response
ptb := & icmp . PacketTooBig {
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MTU : int ( sinfo . getMTU ( ) ) ,
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Data : bs [ : window ] ,
}
// Create the ICMPv6 response from it
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icmpv6Buf , err := r . core . tun . icmpv6 . create_icmpv6_tun (
bs [ 8 : 24 ] , bs [ 24 : 40 ] ,
ipv6 . ICMPTypePacketTooBig , 0 , ptb )
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if err == nil {
r . recv <- icmpv6Buf
}
// Don't continue - drop the packet
return
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}
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sinfo . send <- bs
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}
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}
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// Called for incoming traffic by the session worker for that connection.
// Checks that the IP address is correct (matches the session) and passes the packet to the tun/tap.
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func ( r * router ) recvPacket ( bs [ ] byte , theirAddr * address , theirSubnet * subnet ) {
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// Note: called directly by the session worker, not the router goroutine
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//fmt.Println("Recv packet")
if len ( bs ) < 24 {
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util_putBytes ( bs )
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return
}
var source address
copy ( source [ : ] , bs [ 8 : ] )
var snet subnet
copy ( snet [ : ] , bs [ 8 : ] )
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switch {
case source . isValid ( ) && source == * theirAddr :
case snet . isValid ( ) && snet == * theirSubnet :
default :
util_putBytes ( bs )
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return
}
//go func() { r.recv<-bs }()
r . recv <- bs
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}
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// Checks incoming traffic type and passes it to the appropriate handler.
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func ( r * router ) handleIn ( packet [ ] byte ) {
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pType , pTypeLen := wire_decode_uint64 ( packet )
if pTypeLen == 0 {
return
}
switch pType {
case wire_Traffic :
r . handleTraffic ( packet )
case wire_ProtocolTraffic :
r . handleProto ( packet )
default : /*panic("Should not happen in testing") ;*/
}
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}
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// 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.
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func ( r * router ) handleTraffic ( packet [ ] byte ) {
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defer util_putBytes ( packet )
p := wire_trafficPacket { }
if ! p . decode ( packet ) {
return
}
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sinfo , isIn := r . core . sessions . getSessionForHandle ( & p . Handle )
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if ! isIn {
return
}
//go func () { sinfo.recv<-&p }()
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sinfo . recv <- & p
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}
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// Handles protocol traffic by decrypting it, checking its type, and passing it to the appropriate handler for that traffic type.
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func ( r * router ) handleProto ( packet [ ] byte ) {
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// First parse the packet
p := wire_protoTrafficPacket { }
if ! p . decode ( packet ) {
return
}
// Now try to open the payload
var sharedKey * boxSharedKey
//var theirPermPub *boxPubKey
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if p . ToKey == r . core . boxPub {
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// Try to open using our permanent key
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sharedKey = r . core . sessions . getSharedKey ( & r . core . boxPriv , & p . FromKey )
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} else {
return
}
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bs , isOK := boxOpen ( sharedKey , p . Payload , & p . Nonce )
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if ! isOK {
return
}
// Now do something with the bytes in bs...
// send dht messages to dht, sessionRefresh to sessions, data to tun...
// For data, should check that key and IP match...
bsType , bsTypeLen := wire_decode_uint64 ( bs )
if bsTypeLen == 0 {
return
}
//fmt.Println("RECV bytes:", bs)
switch bsType {
case wire_SessionPing :
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r . handlePing ( bs , & p . FromKey )
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case wire_SessionPong :
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r . handlePong ( bs , & p . FromKey )
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case wire_DHTLookupRequest :
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r . handleDHTReq ( bs , & p . FromKey )
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case wire_DHTLookupResponse :
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r . handleDHTRes ( bs , & p . FromKey )
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default :
util_putBytes ( packet )
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}
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}
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// Decodes session pings from wire format and passes them to sessions.handlePing where they either create or update a session.
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func ( r * router ) handlePing ( bs [ ] byte , fromKey * boxPubKey ) {
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ping := sessionPing { }
if ! ping . decode ( bs ) {
return
}
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ping . SendPermPub = * fromKey
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r . core . sessions . handlePing ( & ping )
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}
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// Handles session pongs (which are really pings with an extra flag to prevent acknowledgement).
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func ( r * router ) handlePong ( bs [ ] byte , fromKey * boxPubKey ) {
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r . handlePing ( bs , fromKey )
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}
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// Decodes dht requests and passes them to dht.handleReq to trigger a lookup/response.
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func ( r * router ) handleDHTReq ( bs [ ] byte , fromKey * boxPubKey ) {
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req := dhtReq { }
if ! req . decode ( bs ) {
return
}
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req . Key = * fromKey
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r . core . dht . handleReq ( & req )
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}
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// Decodes dht responses and passes them to dht.handleRes to update the DHT table and further pass them to the search code (if applicable).
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func ( r * router ) handleDHTRes ( bs [ ] byte , fromKey * boxPubKey ) {
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res := dhtRes { }
if ! res . decode ( bs ) {
return
}
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res . Key = * fromKey
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r . core . dht . handleRes ( & res )
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}
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// Passed a function to call.
// This will send the function to r.admin and block until it finishes.
// It's used by the admin socket to ask the router mainLoop goroutine about information in the session or dht structs, which cannot be read safely from outside that goroutine.
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func ( r * router ) doAdmin ( f func ( ) ) {
// Pass this a function that needs to be run by the router's main goroutine
// It will pass the function to the router and wait for the router to finish
done := make ( chan struct { } )
newF := func ( ) {
f ( )
close ( done )
}
r . admin <- newF
<- done
}