Iface_DEFUN TUNTools_genericIP6Echo(struct Message* msg, struct TUNTools* tt)
{
uint16_t ethertype = TUNMessageType_pop(msg, NULL);
if (ethertype != Ethernet_TYPE_IP6) {
Log_debug(tt->log, "Spurious packet with ethertype [%04x]\n",
Endian_bigEndianToHost16(ethertype));
return 0;
}
struct Headers_IP6Header* header = (struct Headers_IP6Header*) msg->bytes;
if (msg->length != Headers_IP6Header_SIZE + Headers_UDPHeader_SIZE + 12) {
int type = (msg->length >= Headers_IP6Header_SIZE) ? header->nextHeader : -1;
Log_debug(tt->log, "Message of unexpected length [%u] ip6->nextHeader: [%d]\n",
msg->length, type);
return 0;
}
uint8_t* address;
Sockaddr_getAddress(tt->tunDestAddr, &address);
Assert_true(!Bits_memcmp(header->destinationAddr, address, 16));
Sockaddr_getAddress(tt->udpBindTo, &address);
Assert_true(!Bits_memcmp(header->sourceAddr, address, 16));
Sockaddr_getAddress(tt->udpBindTo, &address);
Bits_memcpy(header->destinationAddr, address, 16);
Sockaddr_getAddress(tt->tunDestAddr, &address);
Bits_memcpy(header->sourceAddr, address, 16);
TUNMessageType_push(msg, ethertype, NULL);
return Iface_next(&tt->tunIface, msg);
}
static Iface_DEFUN incomingFromEventIf(struct Message* msg, struct Iface* eventIf)
{
struct UpperDistributor_pvt* ud =
Identity_containerOf(eventIf, struct UpperDistributor_pvt, eventIf);
Assert_true(Message_pop32(msg, NULL) == PFChan_Pathfinder_SENDMSG);
Message_pop32(msg, NULL);
return Iface_next(&ud->pub.sessionManagerIf, msg);
}
static Iface_DEFUN sendToTunIf(struct Message* msg, struct TUNAdapter_pvt* ud)
{
if (!&ud->pub.tunIf.connectedIf) {
Log_debug(ud->log, "DROP message for tun because no device is defined");
return NULL;
}
return Iface_next(&ud->pub.tunIf, msg);
}
// Incoming message which has passed through the cryptoauth and needs to be forwarded to the switch.
static Iface_DEFUN receivedPostCryptoAuth(struct Message* msg,
struct Peer* ep,
struct InterfaceController_pvt* ic)
{
ep->bytesIn += msg->length;
int caState = CryptoAuth_getState(ep->caSession);
if (ep->state < InterfaceController_PeerState_ESTABLISHED) {
// EP states track CryptoAuth states...
ep->state = caState;
SwitchCore_setInterfaceState(&ep->switchIf, SwitchCore_setInterfaceState_ifaceState_UP);
Bits_memcpy(ep->addr.key, ep->caSession->herPublicKey, 32);
Address_getPrefix(&ep->addr);
if (caState == CryptoAuth_ESTABLISHED) {
moveEndpointIfNeeded(ep);
//sendPeer(0xffffffff, PFChan_Core_PEER, ep);// version is not known at this point.
} else {
// prevent some kinds of nasty things which could be done with packet replay.
// This is checking the message switch header and will drop it unless the label
// directs it to *this* router.
if (msg->length < 8 || msg->bytes[7] != 1) {
Log_info(ic->logger, "DROP message because CA is not established.");
return 0;
} else {
// When a "server" gets a new connection from a "client" the router doesn't
// know about that client so if the client sends a packet to the server, the
// server will be unable to handle it until the client has sent inter-router
// communication to the server. Here we will ping the client so when the
// server gets the ping response, it will insert the client into its table
// and know its version.
// prevent DoS by limiting the number of times this can be called per second
// limit it to 7, this will affect innocent packets but it doesn't matter much
// since this is mostly just an optimization and for keeping the tests happy.
if ((ep->pingCount + 1) % 7) {
sendPing(ep);
}
}
}
} else if (ep->state == InterfaceController_PeerState_UNRESPONSIVE
&& caState == CryptoAuth_ESTABLISHED)
{
ep->state = InterfaceController_PeerState_ESTABLISHED;
SwitchCore_setInterfaceState(&ep->switchIf, SwitchCore_setInterfaceState_ifaceState_UP);
} else {
ep->timeOfLastMessage = Time_currentTimeMilliseconds(ic->eventBase);
}
Identity_check(ep);
Assert_true(!(msg->capacity % 4));
return Iface_next(&ep->switchIf, msg);
}
static Iface_DEFUN incomingFromSessionManagerIf(struct Message* msg, struct Iface* sessionManagerIf)
{
struct UpperDistributor_pvt* ud =
Identity_containerOf(sessionManagerIf, struct UpperDistributor_pvt, pub.sessionManagerIf);
Assert_true(msg->length >= RouteHeader_SIZE + DataHeader_SIZE);
struct RouteHeader* hdr = (struct RouteHeader*) msg->bytes;
struct DataHeader* dh = (struct DataHeader*) &hdr[1];
enum ContentType type = DataHeader_getContentType(dh);
if (type <= ContentType_IP6_RAW) {
return Iface_next(&ud->pub.tunAdapterIf, msg);
}
if (type == ContentType_CJDHT) {
Message_push32(msg, 0xffffffff, NULL);
Message_push32(msg, PFChan_Core_MSG, NULL);
return Iface_next(&ud->eventIf, msg);
}
if (type == ContentType_IPTUN) {
return Iface_next(&ud->pub.ipTunnelIf, msg);
}
Log_debug(ud->log, "DROP message with unknown type [%d]", type);
return NULL;
}
static Iface_DEFUN incomingFromUs(struct Message* message, struct Iface* internalIf)
{
struct TUNInterface_Illumos_pvt* ctx =
Identity_containerOf(internalIf, struct TUNInterface_Illumos_pvt, internalIf);
Message_shift(message, -4, NULL);
uint16_t ethertype = ((uint16_t*) message->bytes)[-1];
if (ethertype != Ethernet_TYPE_IP6 && ethertype != Ethernet_TYPE_IP4) {
Assert_true(!"Unsupported ethertype");
}
return Iface_next(&ctx->externalIf, message);
}
static Iface_DEFUN sendToPathfinder(struct Message* msg, struct Pathfinder* pf)
{
if (!pf || pf->state != Pathfinder_state_CONNECTED) { return NULL; }
if (pf->bytesSinceLastPing < 8192 && pf->bytesSinceLastPing + msg->length >= 8192) {
struct Message* ping = Message_new(0, 512, msg->alloc);
Message_push32(ping, pf->bytesSinceLastPing, NULL);
Message_push32(ping, PING_MAGIC, NULL);
Message_push32(ping, PFChan_Core_PING, NULL);
Iface_send(&pf->iface, ping);
}
pf->bytesSinceLastPing += msg->length;
return Iface_next(&pf->iface, msg);
}
static Iface_DEFUN handleError(struct Message* msg,
struct ControlHandler_pvt* ch,
uint64_t label,
uint8_t* labelStr)
{
if (msg->length < handleError_MIN_SIZE) {
Log_info(ch->log, "DROP runt error packet from [%s]", labelStr);
return NULL;
}
Message_shift(msg, SwitchHeader_SIZE + 4, NULL);
Message_push32(msg, 0xffffffff, NULL);
Message_push32(msg, PFChan_Core_SWITCH_ERR, NULL);
return Iface_next(&ch->eventIf, msg);
}
static Iface_DEFUN incoming(struct Message* msg, struct Iface* iface)
{
struct FakeNetwork_UDPIface_pvt* fnip =
Identity_check((struct FakeNetwork_UDPIface_pvt*) iface);
struct FakeNetwork_pvt* fnp = Identity_check(fnip->fnp);
// Swap so that the message contains [dest][src][content]
struct Sockaddr_storage dest;
popSockaddr(msg, &dest);
pushSockaddr(msg, fnip->pub.generic.addr);
pushSockaddr(msg, &dest.addr);
return Iface_next(&fnp->toAsync, msg);
}
static Iface_DEFUN sendNode(struct Message* msg,
struct Address* addr,
uint32_t metric,
struct Pathfinder_pvt* pf)
{
Message_reset(msg);
Message_shift(msg, PFChan_Node_SIZE, NULL);
nodeForAddress((struct PFChan_Node*) msg->bytes, addr, metric);
if (addr->path == UINT64_MAX) {
((struct PFChan_Node*) msg->bytes)->path_be = 0;
}
Message_push32(msg, PFChan_Pathfinder_NODE, NULL);
return Iface_next(&pf->pub.eventIf, msg);
}
static Iface_DEFUN incomingFromWire(struct Message* message, struct Iface* externalIf)
{
struct TUNInterface_Illumos_pvt* ctx =
Identity_containerOf(externalIf, struct TUNInterface_Illumos_pvt, externalIf);
if (message->length < 4) {
return 0;
}
Message_shift(message, 4, NULL);
((uint16_t*) message->bytes)[0] = 0;
((uint16_t*) message->bytes)[1] = ethertypeForPacketType(message->bytes[4]);
return Iface_next(&ctx->internalIf, message);
}
/**
* Handle an incoming control message from a switch.
*
* @param context the ducttape context.
* @param message the control message, this should be alligned on the beginning of the content,
* that is to say, after the end of the switch header.
* @param switchHeader the header.
* @param switchIf the interface which leads to the switch.
* @param isFormV8 true if the control message is in the form specified by protocol version 8+
*/
static Iface_DEFUN incomingFromCore(struct Message* msg, struct Iface* coreIf)
{
struct ControlHandler_pvt* ch = Identity_check((struct ControlHandler_pvt*) coreIf);
struct RouteHeader routeHdr;
Message_pop(msg, &routeHdr, RouteHeader_SIZE, NULL);
uint8_t labelStr[20];
uint64_t label = Endian_bigEndianToHost64(routeHdr.sh.label_be);
AddrTools_printPath(labelStr, label);
// happens in benchmark
// Log_debug(ch->log, "ctrl packet from [%s]", labelStr);
if (msg->length < 4 + Control_Header_SIZE) {
Log_info(ch->log, "DROP runt ctrl packet from [%s]", labelStr);
return NULL;
}
Assert_true(routeHdr.flags & RouteHeader_flags_CTRLMSG);
if (Checksum_engine(msg->bytes, msg->length)) {
Log_info(ch->log, "DROP ctrl packet from [%s] with invalid checksum", labelStr);
return NULL;
}
struct Control* ctrl = (struct Control*) msg->bytes;
if (ctrl->header.type_be == Control_ERROR_be) {
return handleError(msg, ch, label, labelStr);
} else if (ctrl->header.type_be == Control_KEYPING_be
|| ctrl->header.type_be == Control_PING_be)
{
return handlePing(msg, ch, label, labelStr, ctrl->header.type_be);
} else if (ctrl->header.type_be == Control_KEYPONG_be
|| ctrl->header.type_be == Control_PONG_be)
{
Log_debug(ch->log, "got switch pong from [%s]", labelStr);
Message_push(msg, &routeHdr, RouteHeader_SIZE, NULL);
return Iface_next(&ch->pub.switchPingerIf, msg);
}
Log_info(ch->log, "DROP control packet of unknown type from [%s], type [%d]",
labelStr, Endian_bigEndianToHost16(ctrl->header.type_be));
return NULL;
}
/**
* Handle an incoming control message from a switch.
*
* @param context the ducttape context.
* @param message the control message, this should be alligned on the beginning of the content,
* that is to say, after the end of the switch header.
* @param switchHeader the header.
* @param switchIf the interface which leads to the switch.
* @param isFormV8 true if the control message is in the form specified by protocol version 8+
*/
static Iface_DEFUN incomingFromCore(struct Message* msg, struct Iface* coreIf)
{
struct ControlHandler_pvt* ch = Identity_check((struct ControlHandler_pvt*) coreIf);
struct SwitchHeader switchHeader;
Message_pop(msg, &switchHeader, SwitchHeader_SIZE, NULL);
uint8_t labelStr[20];
uint64_t label = Endian_bigEndianToHost64(switchHeader.label_be);
AddrTools_printPath(labelStr, label);
Log_debug(ch->log, "ctrl packet from [%s]", labelStr);
if (msg->length < 4 + Control_Header_SIZE) {
Log_info(ch->log, "DROP runt ctrl packet from [%s]", labelStr);
return NULL;
}
Assert_true(Message_pop32(msg, NULL) == 0xffffffff);
if (Checksum_engine(msg->bytes, msg->length)) {
Log_info(ch->log, "DROP ctrl packet from [%s] with invalid checksum", labelStr);
return NULL;
}
struct Control* ctrl = (struct Control*) msg->bytes;
if (ctrl->header.type_be == Control_ERROR_be) {
return handleError(msg, ch, label, labelStr);
} else if (ctrl->header.type_be == Control_KEYPING_be
|| ctrl->header.type_be == Control_PING_be)
{
return handlePing(msg, ch, label, labelStr, ctrl->header.type_be);
} else if (ctrl->header.type_be == Control_KEYPONG_be
|| ctrl->header.type_be == Control_PONG_be)
{
Log_debug(ch->log, "got switch pong from [%s]", labelStr);
// Shift back over the header
Message_shift(msg, 4 + SwitchHeader_SIZE, NULL);
return Iface_next(&ch->pub.switchPingerIf, msg);
}
Log_info(ch->log, "DROP control packet of unknown type from [%s], type [%d]",
labelStr, Endian_bigEndianToHost16(ctrl->header.type_be));
return NULL;
}
static Iface_DEFUN receiveMessage(struct Message* msg, struct Iface* external)
{
struct TAPWrapper_pvt* tw = Identity_containerOf(external, struct TAPWrapper_pvt, external);
if (msg->length < Ethernet_SIZE-2) {
Log_debug(tw->log, "runt");
return 0;
}
// wacky 14 byte headers, back off into outer-space to create the padding...
Message_shift(msg, 2, NULL);
struct Ethernet eth;
Message_pop(msg, ð, sizeof(struct Ethernet), NULL);
// Not for us and not multicast...
if (Bits_memcmp(eth.destAddr, TAPWrapper_LOCAL_MAC, Ethernet_ADDRLEN)
&& !(eth.destAddr[0] & 0x01))
{
if (Defined(Log_DEBUG)) {
uint8_t printedMac[18];
AddrTools_printMac(printedMac, eth.destAddr);
Log_debug(tw->log, "Packet destine for unknown ethernet MAC [%s]", printedMac);
}
//return 0;
}
if (Bits_memcmp(eth.srcAddr, tw->pub.peerAddress, Ethernet_ADDRLEN)) {
if (Bits_isZero(tw->pub.peerAddress, Ethernet_ADDRLEN)) {
Bits_memcpy(tw->pub.peerAddress, eth.srcAddr, Ethernet_ADDRLEN);
} else {
#ifdef Log_DEBUG
uint8_t printedMac[18];
AddrTools_printMac(printedMac, eth.srcAddr);
Log_debug(tw->log, "DROP Packet with unexpected source MAC [%s]", printedMac);
#endif
return 0;
}
}
TUNMessageType_push(msg, eth.ethertype, NULL);
return Iface_next(&tw->pub.internal, msg);
}
static Iface_DEFUN sendMessage(struct Message* msg, struct Iface* internal)
{
struct TAPWrapper_pvt* tw = Identity_containerOf(internal, struct TAPWrapper_pvt, pub.internal);
uint16_t etherType = TUNMessageType_pop(msg, NULL);
struct Ethernet eth = { .ethertype = etherType };
Bits_memcpyConst(eth.srcAddr, TAPWrapper_LOCAL_MAC, Ethernet_ADDRLEN);
Bits_memcpyConst(eth.destAddr, tw->pub.peerAddress, Ethernet_ADDRLEN);
if (Bits_isZero(tw->pub.peerAddress, Ethernet_ADDRLEN)) {
Log_debug(tw->log, "DROP Packet because peers MAC is not yet known");
return NULL;
}
Message_push(msg, ð, sizeof(struct Ethernet), NULL);
// struct Ethernet contains 2 bytes of padding at the beginning.
Message_shift(msg, -2, NULL);
return Iface_next(&tw->external, msg);
}
static Iface_DEFUN fromAsync(struct Message* msg, struct Iface* fnpFromAsync)
{
struct FakeNetwork_pvt* fnp =
Identity_containerOf(fnpFromAsync, struct FakeNetwork_pvt, fromAsync);
struct Sockaddr_storage dest;
struct Sockaddr* dp = &dest.addr;
popSockaddr(msg, &dest);
int idx = Map_OfIfaces_indexForKey(&dp, &fnp->map);
if (idx == -1) {
char* destAddr = Sockaddr_print(dp, msg->alloc);
// hack, the 'dest' becomes the source.
popSockaddr(msg, &dest);
char* srcAddr = Sockaddr_print(dp, msg->alloc);
Log_debug(fnp->log, "Message with unknown dest address [%s] from [%s]", destAddr, srcAddr);
return NULL;
}
struct FakeNetwork_UDPIface_pvt* fnip = Identity_check(fnp->map.values[idx]);
return Iface_next(&fnip->pub.generic.iface, msg);
}
static Iface_DEFUN incomingMsg(struct Message* msg, struct Pathfinder_pvt* pf)
{
struct Address addr;
struct RouteHeader* hdr = (struct RouteHeader*) msg->bytes;
Message_shift(msg, -(RouteHeader_SIZE + DataHeader_SIZE), NULL);
Bits_memcpy(addr.ip6.bytes, hdr->ip6, 16);
Bits_memcpy(addr.key, hdr->publicKey, 32);
addr.protocolVersion = Endian_bigEndianToHost32(hdr->version_be);
addr.padding = 0;
addr.path = Endian_bigEndianToHost64(hdr->sh.label_be);
//Log_debug(pf->log, "Incoming DHT");
struct DHTMessage dht = {
.address = &addr,
.binMessage = msg,
.allocator = msg->alloc
};
DHTModuleRegistry_handleIncoming(&dht, pf->registry);
struct Message* nodeMsg = Message_new(0, 256, msg->alloc);
Iface_CALL(sendNode, nodeMsg, &addr, 0xfffffff0u, pf);
if (dht.pleaseRespond) {
// what a beautiful hack, see incomingFromDHT
return Iface_next(&pf->pub.eventIf, msg);
}
return NULL;
}
static Iface_DEFUN incomingFromEventIf(struct Message* msg, struct Iface* eventIf)
{
struct Pathfinder_pvt* pf = Identity_containerOf(eventIf, struct Pathfinder_pvt, pub.eventIf);
enum PFChan_Core ev = Message_pop32(msg, NULL);
if (Pathfinder_pvt_state_INITIALIZING == pf->state) {
Assert_true(ev == PFChan_Core_CONNECT);
return connected(pf, msg);
}
// Let the PF send another 128 path changes again because it's basically a new tick.
pf->bestPathChanges = 0;
switch (ev) {
case PFChan_Core_SWITCH_ERR: return switchErr(msg, pf);
case PFChan_Core_SEARCH_REQ: return searchReq(msg, pf);
case PFChan_Core_PEER: return peer(msg, pf);
case PFChan_Core_PEER_GONE: return peerGone(msg, pf);
case PFChan_Core_SESSION: return session(msg, pf);
case PFChan_Core_SESSION_ENDED: return sessionEnded(msg, pf);
case PFChan_Core_DISCOVERED_PATH: return discoveredPath(msg, pf);
case PFChan_Core_MSG: return incomingMsg(msg, pf);
case PFChan_Core_PING: return handlePing(msg, pf);
case PFChan_Core_PONG: return handlePong(msg, pf);
case PFChan_Core_UNSETUP_SESSION:
case PFChan_Core_LINK_STATE:
case PFChan_Core_CTRL_MSG: return NULL;
default:;
}
Assert_failure("unexpected event [%d]", ev);
}
static void sendEvent(struct Pathfinder_pvt* pf, enum PFChan_Pathfinder ev, void* data, int size)
{
struct Allocator* alloc = Allocator_child(pf->alloc);
struct Message* msg = Message_new(0, 512+size, alloc);
Message_push(msg, data, size, NULL);
Message_push32(msg, ev, NULL);
Iface_send(&pf->pub.eventIf, msg);
Allocator_free(alloc);
}
static void init(void* vpf)
{
struct Pathfinder_pvt* pf = Identity_check((struct Pathfinder_pvt*) vpf);
struct PFChan_Pathfinder_Connect conn = {
.superiority_be = Endian_hostToBigEndian32(1),
.version_be = Endian_hostToBigEndian32(Version_CURRENT_PROTOCOL)
};
CString_strncpy(conn.userAgent, "Cjdns internal pathfinder", 64);
sendEvent(pf, PFChan_Pathfinder_CONNECT, &conn, PFChan_Pathfinder_Connect_SIZE);
}
struct Pathfinder* Pathfinder_register(struct Allocator* allocator,
struct Log* log,
struct EventBase* base,
struct Random* rand,
struct Admin* admin)
{
struct Allocator* alloc = Allocator_child(allocator);
struct Pathfinder_pvt* pf = Allocator_calloc(alloc, sizeof(struct Pathfinder_pvt), 1);
Identity_set(pf);
pf->alloc = alloc;
pf->log = log;
pf->base = base;
pf->rand = rand;
pf->admin = admin;
pf->pub.eventIf.send = incomingFromEventIf;
pf->dhtModule.context = pf;
pf->dhtModule.handleOutgoing = incomingFromDHT;
// This needs to be done asynchronously so the pf can be plumbed to the core
Timeout_setTimeout(init, pf, 0, base, alloc);
return &pf->pub;
}
static Iface_DEFUN handlePing(struct Message* msg, struct Pathfinder_pvt* pf)
{
Log_debug(pf->log, "Received ping");
Message_push32(msg, PFChan_Pathfinder_PONG, NULL);
return Iface_next(&pf->pub.eventIf, msg);
}
static Iface_DEFUN aliceToBob(struct Message* msg, struct Iface* aliceIf)
{
struct SwitchingContext* sc =
Identity_containerOf(aliceIf, struct SwitchingContext, aliceIf);
return Iface_next(&sc->bobIf, msg);
}
static Iface_DEFUN bobToAlice(struct Message* msg, struct Iface* bobIf)
{
struct SwitchingContext* sc =
Identity_containerOf(bobIf, struct SwitchingContext, bobIf);
return Iface_next(&sc->aliceIf, msg);
}
static Iface_DEFUN incomingFromTunIf(struct Message* msg, struct Iface* tunIf)
{
struct TUNAdapter_pvt* ud = Identity_containerOf(tunIf, struct TUNAdapter_pvt, pub.tunIf);
uint16_t ethertype = TUNMessageType_pop(msg, NULL);
int version = Headers_getIpVersion(msg->bytes);
if ((ethertype == Ethernet_TYPE_IP4 && version != 4)
|| (ethertype == Ethernet_TYPE_IP6 && version != 6))
{
Log_debug(ud->log, "DROP packet because ip version [%d] "
"doesn't match ethertype [%u].", version, Endian_bigEndianToHost16(ethertype));
return NULL;
}
if (ethertype == Ethernet_TYPE_IP4) {
return Iface_next(&ud->pub.ipTunnelIf, msg);
}
if (ethertype != Ethernet_TYPE_IP6) {
Log_debug(ud->log, "DROP packet unknown ethertype [%u]",
Endian_bigEndianToHost16(ethertype));
return NULL;
}
if (msg->length < Headers_IP6Header_SIZE) {
Log_debug(ud->log, "DROP runt");
return NULL;
}
struct Headers_IP6Header* header = (struct Headers_IP6Header*) msg->bytes;
if (!AddressCalc_validAddress(header->destinationAddr)) {
return Iface_next(&ud->pub.ipTunnelIf, msg);
}
if (Bits_memcmp(header->sourceAddr, ud->myIp6, 16)) {
if (Defined(Log_DEBUG)) {
uint8_t expectedSource[40];
AddrTools_printIp(expectedSource, ud->myIp6);
uint8_t packetSource[40];
AddrTools_printIp(packetSource, header->sourceAddr);
Log_debug(ud->log,
"DROP packet from [%s] because all messages must have source address [%s]",
packetSource, expectedSource);
}
return NULL;
}
if (!Bits_memcmp(header->destinationAddr, ud->myIp6, 16)) {
// I'm Gonna Sit Right Down and Write Myself a Letter
TUNMessageType_push(msg, ethertype, NULL);
return Iface_next(tunIf, msg);
}
if (!Bits_memcmp(header->destinationAddr, "\xfc\0\0\0\0\0\0\0\0\0\0\0\0\0\0\x01", 16)) {
return Iface_next(&ud->pub.magicIf, msg);
}
// first move the dest addr to the right place.
Bits_memmoveConst(&header->destinationAddr[-DataHeader_SIZE], header->destinationAddr, 16);
Message_shift(msg, DataHeader_SIZE + RouteHeader_SIZE - Headers_IP6Header_SIZE, NULL);
struct RouteHeader* rh = (struct RouteHeader*) msg->bytes;
struct DataHeader* dh = (struct DataHeader*) &rh[1];
Bits_memset(dh, 0, DataHeader_SIZE);
DataHeader_setContentType(dh, header->nextHeader);
DataHeader_setVersion(dh, DataHeader_CURRENT_VERSION);
// Other than the ipv6 addr at the end, everything is zeros right down the line.
Bits_memset(rh, 0, RouteHeader_SIZE - 16);
return Iface_next(&ud->pub.upperDistributorIf, msg);
}
static Iface_DEFUN incomingFromMagicIf(struct Message* msg, struct Iface* magicIf)
{
struct TUNAdapter_pvt* ud =
Identity_containerOf(magicIf, struct TUNAdapter_pvt, pub.magicIf);
return Iface_next(&ud->pub.tunIf, msg);
}
static Iface_DEFUN handlePing(struct Message* msg,
struct ControlHandler_pvt* ch,
uint64_t label,
uint8_t* labelStr,
uint16_t messageType_be)
{
if (msg->length < handlePing_MIN_SIZE) {
Log_info(ch->log, "DROP runt ping");
return NULL;
}
struct Control* ctrl = (struct Control*) msg->bytes;
Message_shift(msg, -Control_Header_SIZE, NULL);
// Ping and keyPing share version location
struct Control_Ping* ping = (struct Control_Ping*) msg->bytes;
uint32_t herVersion = Endian_bigEndianToHost32(ping->version_be);
if (!Version_isCompatible(Version_CURRENT_PROTOCOL, herVersion)) {
Log_debug(ch->log, "DROP ping from incompatible version [%d]", herVersion);
return NULL;
}
if (messageType_be == Control_KEYPING_be) {
Log_debug(ch->log, "got switch keyPing from [%s]", labelStr);
if (msg->length < Control_KeyPing_HEADER_SIZE) {
// min keyPing size is longer
Log_debug(ch->log, "DROP runt keyPing");
return NULL;
}
if (msg->length > Control_KeyPing_MAX_SIZE) {
Log_debug(ch->log, "DROP long keyPing");
return NULL;
}
if (ping->magic != Control_KeyPing_MAGIC) {
Log_debug(ch->log, "DROP keyPing (bad magic)");
return NULL;
}
struct Control_KeyPing* keyPing = (struct Control_KeyPing*) msg->bytes;
keyPing->magic = Control_KeyPong_MAGIC;
ctrl->header.type_be = Control_KEYPONG_be;
Bits_memcpy(keyPing->key, ch->myPublicKey, 32);
} else if (messageType_be == Control_PING_be) {
// Happens in benchmark.
//Log_debug(ch->log, "got switch ping from [%s]", labelStr);
if (ping->magic != Control_Ping_MAGIC) {
Log_debug(ch->log, "DROP ping (bad magic)");
return NULL;
}
ping->magic = Control_Pong_MAGIC;
ctrl->header.type_be = Control_PONG_be;
} else {
Assert_failure("2+2=5");
}
ping->version_be = Endian_hostToBigEndian32(Version_CURRENT_PROTOCOL);
Message_shift(msg, Control_Header_SIZE, NULL);
ctrl->header.checksum_be = 0;
ctrl->header.checksum_be = Checksum_engine(msg->bytes, msg->length);
Message_shift(msg, RouteHeader_SIZE, NULL);
struct RouteHeader* routeHeader = (struct RouteHeader*) msg->bytes;
Bits_memset(routeHeader, 0, RouteHeader_SIZE);
SwitchHeader_setVersion(&routeHeader->sh, SwitchHeader_CURRENT_VERSION);
routeHeader->sh.label_be = Endian_hostToBigEndian64(label);
routeHeader->flags |= RouteHeader_flags_CTRLMSG;
return Iface_next(&ch->pub.coreIf, msg);
}
static Iface_DEFUN incomingFromIpTunnelIf(struct Message* msg, struct Iface* ipTunnelIf)
{
struct UpperDistributor_pvt* ud =
Identity_containerOf(ipTunnelIf, struct UpperDistributor_pvt, pub.ipTunnelIf);
return Iface_next(&ud->pub.sessionManagerIf, msg);
}
// Forward from switch pinger directly to core.
static Iface_DEFUN incomingFromSwitchPinger(struct Message* msg, struct Iface* switchPingerIf)
{
struct ControlHandler_pvt* ch =
Identity_containerOf(switchPingerIf, struct ControlHandler_pvt, pub.switchPingerIf);
return Iface_next(&ch->pub.coreIf, msg);
}
