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/**
* Copyright 2011, Big Switch Networks, Inc.
* Originally created by David Erickson, Stanford University
*
* Licensed under the Apache License, Version 2.0 (the "License"); you may
* not use this file except in compliance with the License. You may obtain
* a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS, WITHOUT
* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the
* License for the specific language governing permissions and limitations
* under the License.
**/
package net.floodlightcontroller.linkdiscovery.internal;
import java.io.IOException;
import java.net.InetAddress;
import java.net.InetSocketAddress;
import java.net.NetworkInterface;
import java.net.SocketAddress;
import java.nio.ByteBuffer;
import java.util.ArrayList;
import java.util.Collection;
import java.util.Collections;
import java.util.HashMap;
import java.util.HashSet;
import java.util.Iterator;
import java.util.List;
import java.util.Map;
import java.util.Map.Entry;
import java.util.Set;
import java.util.concurrent.BlockingQueue;
import java.util.concurrent.LinkedBlockingQueue;
import java.util.concurrent.ScheduledExecutorService;
import java.util.concurrent.TimeUnit;
import java.util.concurrent.locks.ReentrantReadWriteLock;
import net.floodlightcontroller.core.FloodlightContext;
import net.floodlightcontroller.core.IFloodlightProviderService;
import net.floodlightcontroller.core.IFloodlightProviderService.Role;
import net.floodlightcontroller.core.IHAListener;
import net.floodlightcontroller.core.IInfoProvider;
import net.floodlightcontroller.core.INetMapStorage.DM_OPERATION;
import net.floodlightcontroller.core.IOFMessageListener;
import net.floodlightcontroller.core.IOFSwitch;
import net.floodlightcontroller.core.IOFSwitchListener;
import net.floodlightcontroller.core.annotations.LogMessageCategory;
import net.floodlightcontroller.core.annotations.LogMessageDoc;
import net.floodlightcontroller.core.annotations.LogMessageDocs;
import net.floodlightcontroller.core.internal.OFSwitchImpl;
import net.floodlightcontroller.core.module.FloodlightModuleContext;
import net.floodlightcontroller.core.module.FloodlightModuleException;
import net.floodlightcontroller.core.module.IFloodlightModule;
import net.floodlightcontroller.core.module.IFloodlightService;
import net.floodlightcontroller.core.util.SingletonTask;
import net.floodlightcontroller.linkdiscovery.ILinkDiscovery;
import net.floodlightcontroller.linkdiscovery.ILinkDiscovery.LDUpdate;
import net.floodlightcontroller.linkdiscovery.ILinkDiscovery.LinkType;
import net.floodlightcontroller.linkdiscovery.ILinkDiscovery.SwitchType;
import net.floodlightcontroller.linkdiscovery.ILinkDiscovery.UpdateOperation;
import net.floodlightcontroller.linkdiscovery.ILinkDiscoveryListener;
import net.floodlightcontroller.linkdiscovery.ILinkDiscoveryService;
import net.floodlightcontroller.linkdiscovery.LinkInfo;
import net.floodlightcontroller.linkdiscovery.web.LinkDiscoveryWebRoutable;
import net.floodlightcontroller.packet.BSN;
import net.floodlightcontroller.packet.Ethernet;
import net.floodlightcontroller.packet.IPv4;
import net.floodlightcontroller.packet.LLDP;
import net.floodlightcontroller.packet.LLDPTLV;
import net.floodlightcontroller.restserver.IRestApiService;
import net.floodlightcontroller.routing.Link;
import net.floodlightcontroller.storage.IResultSet;
import net.floodlightcontroller.storage.IStorageSourceListener;
import net.floodlightcontroller.storage.IStorageSourceService;
import net.floodlightcontroller.storage.OperatorPredicate;
import net.floodlightcontroller.storage.StorageException;
import net.floodlightcontroller.threadpool.IThreadPoolService;
import net.floodlightcontroller.topology.NodePortTuple;
import net.floodlightcontroller.util.EventHistory;
import net.floodlightcontroller.util.EventHistory.EvAction;
import net.onrc.onos.registry.controller.IControllerRegistryService;
import org.openflow.protocol.OFMessage;
import org.openflow.protocol.OFPacketIn;
import org.openflow.protocol.OFPacketOut;
import org.openflow.protocol.OFPhysicalPort;
import org.openflow.protocol.OFPhysicalPort.OFPortConfig;
import org.openflow.protocol.OFPhysicalPort.OFPortState;
import org.openflow.protocol.OFPort;
import org.openflow.protocol.OFPortStatus;
import org.openflow.protocol.OFPortStatus.OFPortReason;
import org.openflow.protocol.OFType;
import org.openflow.protocol.action.OFAction;
import org.openflow.protocol.action.OFActionOutput;
import org.openflow.util.HexString;
import org.slf4j.Logger;
import org.slf4j.LoggerFactory;
/**
* This class sends out LLDP messages containing the sending switch's datapath
* id as well as the outgoing port number. Received LLrescDP messages that
* match a known switch cause a new LinkTuple to be created according to the
* invariant rules listed below. This new LinkTuple is also passed to routing
* if it exists to trigger updates.
*
* This class also handles removing links that are associated to switch ports
* that go down, and switches that are disconnected.
*
* Invariants:
* -portLinks and switchLinks will not contain empty Sets outside of
* critical sections
* -portLinks contains LinkTuples where one of the src or dst
* SwitchPortTuple matches the map key
* -switchLinks contains LinkTuples where one of the src or dst
* SwitchPortTuple's id matches the switch id
* -Each LinkTuple will be indexed into switchLinks for both
* src.id and dst.id, and portLinks for each src and dst
* -The updates queue is only added to from within a held write lock
*/
@LogMessageCategory("Network Topology")
public class LinkDiscoveryManager
implements IOFMessageListener, IOFSwitchListener,
IStorageSourceListener, ILinkDiscoveryService,
IFloodlightModule, IInfoProvider, IHAListener {
protected static Logger log = LoggerFactory.getLogger(LinkDiscoveryManager.class);
protected enum NetworkMapOperation {
NONE,
INSERT,
UPDATE
}
// Names of table/fields for links in the storage API
private static final String LINK_TABLE_NAME = "controller_link";
private static final String LINK_ID = "id";
private static final String LINK_SRC_SWITCH = "src_switch_id";
private static final String LINK_SRC_PORT = "src_port";
private static final String LINK_SRC_PORT_STATE = "src_port_state";
private static final String LINK_DST_SWITCH = "dst_switch_id";
private static final String LINK_DST_PORT = "dst_port";
private static final String LINK_DST_PORT_STATE = "dst_port_state";
private static final String LINK_VALID_TIME = "valid_time";
private static final String LINK_TYPE = "link_type";
private static final String SWITCH_CONFIG_TABLE_NAME = "controller_switchconfig";
private static final String SWITCH_CONFIG_CORE_SWITCH = "core_switch";
protected IFloodlightProviderService floodlightProvider;
protected IStorageSourceService storageSource;
protected IThreadPoolService threadPool;
protected IRestApiService restApi;
protected IControllerRegistryService registryService;
// LLDP and BDDP fields
private static final byte[] LLDP_STANDARD_DST_MAC_STRING =
HexString.fromHexString("01:80:c2:00:00:0e");
private static final long LINK_LOCAL_MASK = 0xfffffffffff0L;
private static final long LINK_LOCAL_VALUE = 0x0180c2000000L;
// BigSwitch OUI is 5C:16:C7, so 5D:16:C7 is the multicast version
private static final String LLDP_BSN_DST_MAC_STRING = "5d:16:c7:00:00:01";
//private static final String LLDP_BSN_DST_MAC_STRING = "ff:ff:ff:ff:ff:ff";
// Direction TLVs are used to indicate if the LLDPs were sent
// periodically or in response to a recieved LLDP
private static final byte TLV_DIRECTION_TYPE = 0x73;
private static final short TLV_DIRECTION_LENGTH = 1; // 1 byte
private static final byte TLV_DIRECTION_VALUE_FORWARD[] = {0x01};
private static final byte TLV_DIRECTION_VALUE_REVERSE[] = {0x02};
private static final LLDPTLV forwardTLV
= new LLDPTLV().
setType((byte)TLV_DIRECTION_TYPE).
setLength((short)TLV_DIRECTION_LENGTH).
setValue(TLV_DIRECTION_VALUE_FORWARD);
private static final LLDPTLV reverseTLV
= new LLDPTLV().
setType((byte)TLV_DIRECTION_TYPE).
setLength((short)TLV_DIRECTION_LENGTH).
setValue(TLV_DIRECTION_VALUE_REVERSE);
// Link discovery task details.
protected SingletonTask discoveryTask;
protected final int DISCOVERY_TASK_INTERVAL = 1;
protected final int LINK_TIMEOUT = 5; // decreased timeout as part of LLDP process from 35 secs
protected final int LLDP_TO_ALL_INTERVAL = 2 ; //decreased from 15 seconds.
protected long lldpClock = 0;
// This value is intentionally kept higher than LLDP_TO_ALL_INTERVAL.
// If we want to identify link failures faster, we could decrease this
// value to a small number, say 1 or 2 sec.
protected final int LLDP_TO_KNOWN_INTERVAL= 2; // LLDP frequency for known links from 20 secs
protected LLDPTLV controllerTLV;
protected ReentrantReadWriteLock lock;
int lldpTimeCount = 0;
// Storage
ThreadLocal<LinkStorageImpl> store = new ThreadLocal<LinkStorageImpl>() {
@Override
protected LinkStorageImpl initialValue() {
LinkStorageImpl swStore = new LinkStorageImpl();
//TODO: Get the file path from global properties
swStore.init("/tmp/cassandra.titan");
return swStore;
}
};
protected LinkStorageImpl linkStore = store.get();
// protected SwitchStorageImpl swStore;
/**
* Flag to indicate if automatic port fast is enabled or not.
* Default is set to false -- Initialized in the init method as well.
*/
boolean autoPortFastFeature = false;
/**
* Map of remote switches that are not connected to this controller. This
* is used to learn remote switches in a distributed controller.
*/
protected Map<Long, IOFSwitch> remoteSwitches;
/**
* Map from link to the most recent time it was verified functioning
*/
protected Map<Link, LinkInfo> links;
/**
* Map from switch id to a set of all links with it as an endpoint
*/
protected Map<Long, Set<Link>> switchLinks;
/**
* Map from a id:port to the set of links containing it as an endpoint
*/
protected Map<NodePortTuple, Set<Link>> portLinks;
/**
* Set of link tuples over which multicast LLDPs are received
* and unicast LLDPs are not received.
*/
protected Map<NodePortTuple, Set<Link>> portBroadcastDomainLinks;
protected volatile boolean shuttingDown = false;
/* topology aware components are called in the order they were added to the
* the array */
protected ArrayList<ILinkDiscoveryListener> linkDiscoveryAware;
protected BlockingQueue<LDUpdate> updates;
protected Thread updatesThread;
/**
* List of ports through which LLDP/BDDPs are not sent.
*/
protected Set<NodePortTuple> suppressLinkDiscovery;
/** A list of ports that are quarantined for discovering links through
* them. Data traffic from these ports are not allowed until the ports
* are released from quarantine.
*/
protected LinkedBlockingQueue<NodePortTuple> quarantineQueue;
protected LinkedBlockingQueue<NodePortTuple> maintenanceQueue;
/**
* Quarantine task
*/
protected SingletonTask bddpTask;
protected final int BDDP_TASK_INTERVAL = 100; // 100 ms.
protected final int BDDP_TASK_SIZE = 5; // # of ports per iteration
/**
* Map of broadcast domain ports and the last time a BDDP was either
* sent or received on that port.
*/
protected Map<NodePortTuple, Long> broadcastDomainPortTimeMap;
/**
* Get the LLDP sending period in seconds.
* @return LLDP sending period in seconds.
*/
public int getLldpFrequency() {
return LLDP_TO_KNOWN_INTERVAL;
}
/**
* Get the LLDP timeout value in seconds
* @return LLDP timeout value in seconds
*/
public int getLldpTimeout() {
return LINK_TIMEOUT;
}
public Map<NodePortTuple, Set<Link>> getPortLinks() {
return portLinks;
}
public Set<NodePortTuple> getSuppressLLDPsInfo() {
return suppressLinkDiscovery;
}
/**
* Add a switch port to the suppressed LLDP list.
* Remove any known links on the switch port.
*/
public void AddToSuppressLLDPs(long sw, short port)
{
NodePortTuple npt = new NodePortTuple(sw, port);
this.suppressLinkDiscovery.add(npt);
deleteLinksOnPort(npt, "LLDP suppressed.");
}
/**
* Remove a switch port from the suppressed LLDP list.
* Discover links on that switchport.
*/
public void RemoveFromSuppressLLDPs(long sw, short port)
{
NodePortTuple npt = new NodePortTuple(sw, port);
this.suppressLinkDiscovery.remove(npt);
discover(npt);
}
public boolean isShuttingDown() {
return shuttingDown;
}
public boolean isFastPort(long sw, short port) {
return false;
}
public ILinkDiscovery.LinkType getLinkType(Link lt, LinkInfo info) {
if (info.getUnicastValidTime() != null) {
return ILinkDiscovery.LinkType.DIRECT_LINK;
} else if (info.getMulticastValidTime() != null) {
return ILinkDiscovery.LinkType.MULTIHOP_LINK;
}
return ILinkDiscovery.LinkType.INVALID_LINK;
}
@LogMessageDoc(level="ERROR",
message="Error in link discovery updates loop",
explanation="An unknown error occured while dispatching " +
"link update notifications",
recommendation=LogMessageDoc.GENERIC_ACTION)
private void doUpdatesThread() throws InterruptedException {
do {
LDUpdate update = updates.take();
if (linkDiscoveryAware != null) {
if (log.isTraceEnabled()) {
log.trace("Dispatching link discovery update {} {} {} {} {} for {}",
new Object[]{update.getOperation(),
HexString.toHexString(update.getSrc()), update.getSrcPort(),
HexString.toHexString(update.getDst()), update.getDstPort(),
linkDiscoveryAware});
}
try {
for (ILinkDiscoveryListener lda : linkDiscoveryAware) { // order maintained
lda.linkDiscoveryUpdate(update);
}
}
catch (Exception e) {
log.error("Error in link discovery updates loop", e);
}
}
} while (updates.peek() != null);
}
private boolean isLinkDiscoverySuppressed(long sw, short portNumber) {
return this.suppressLinkDiscovery.contains(new NodePortTuple(sw, portNumber));
}
protected void discoverLinks() {
// timeout known links.
timeoutLinks();
//increment LLDP clock
lldpClock = (lldpClock + 1)% LLDP_TO_ALL_INTERVAL;
if (lldpClock == 0) {
log.debug("Sending LLDP out on all ports.");
discoverOnAllPorts();
}
}
/**
* Quarantine Ports.
*/
protected class QuarantineWorker implements Runnable {
@Override
public void run() {
try {
processBDDPLists();
}
catch (Exception e) {
log.error("Error in quarantine worker thread", e);
} finally {
bddpTask.reschedule(BDDP_TASK_INTERVAL,
TimeUnit.MILLISECONDS);
}
}
}
/**
* Add a switch port to the quarantine queue. Schedule the
* quarantine task if the quarantine queue was empty before adding
* this switch port.
* @param npt
*/
protected void addToQuarantineQueue(NodePortTuple npt) {
if (quarantineQueue.contains(npt) == false)
quarantineQueue.add(npt);
}
/**
* Remove a switch port from the quarantine queue.
*/
protected void removeFromQuarantineQueue(NodePortTuple npt) {
// Remove all occurrences of the node port tuple from the list.
while (quarantineQueue.remove(npt));
}
/**
* Add a switch port to maintenance queue.
* @param npt
*/
protected void addToMaintenanceQueue(NodePortTuple npt) {
// TODO We are not checking if the switch port tuple is already
// in the maintenance list or not. This will be an issue for
// really large number of switch ports in the network.
if (maintenanceQueue.contains(npt) == false)
maintenanceQueue.add(npt);
}
/**
* Remove a switch port from maintenance queue.
* @param npt
*/
protected void removeFromMaintenanceQueue(NodePortTuple npt) {
// Remove all occurrences of the node port tuple from the queue.
while (maintenanceQueue.remove(npt));
}
/**
* This method processes the quarantine list in bursts. The task is
* at most once per BDDP_TASK_INTERVAL.
* One each call, BDDP_TASK_SIZE number of switch ports are processed.
* Once the BDDP packets are sent out through the switch ports, the ports
* are removed from the quarantine list.
*/
protected void processBDDPLists() {
int count = 0;
Set<NodePortTuple> nptList = new HashSet<NodePortTuple>();
while(count < BDDP_TASK_SIZE && quarantineQueue.peek() !=null) {
NodePortTuple npt;
npt = quarantineQueue.remove();
sendDiscoveryMessage(npt.getNodeId(), npt.getPortId(), false, false);
nptList.add(npt);
count++;
}
count = 0;
while (count < BDDP_TASK_SIZE && maintenanceQueue.peek() != null) {
NodePortTuple npt;
npt = maintenanceQueue.remove();
sendDiscoveryMessage(npt.getNodeId(), npt.getPortId(), false, false);
count++;
}
for(NodePortTuple npt:nptList) {
generateSwitchPortStatusUpdate(npt.getNodeId(), npt.getPortId());
}
}
public Set<Short> getQuarantinedPorts(long sw) {
Set<Short> qPorts = new HashSet<Short>();
Iterator<NodePortTuple> iter = quarantineQueue.iterator();
while (iter.hasNext()) {
NodePortTuple npt = iter.next();
if (npt.getNodeId() == sw) {
qPorts.add(npt.getPortId());
}
}
return qPorts;
}
private void generateSwitchPortStatusUpdate(long sw, short port) {
UpdateOperation operation;
IOFSwitch iofSwitch = floodlightProvider.getSwitches().get(sw);
if (iofSwitch == null) return;
OFPhysicalPort ofp = iofSwitch.getPort(port);
if (ofp == null) return;
int srcPortState = ofp.getState();
boolean portUp = ((srcPortState &
OFPortState.OFPPS_STP_MASK.getValue()) !=
OFPortState.OFPPS_STP_BLOCK.getValue());
if (portUp) operation = UpdateOperation.PORT_UP;
else operation = UpdateOperation.PORT_DOWN;
updates.add(new LDUpdate(sw, port, operation));
}
/**
* Send LLDP on known ports
*/
protected void discoverOnKnownLinkPorts() {
// Copy the port set.
Set<NodePortTuple> nptSet = new HashSet<NodePortTuple>();
nptSet.addAll(portLinks.keySet());
// Send LLDP from each of them.
for(NodePortTuple npt: nptSet) {
discover(npt);
}
}
protected void discover(NodePortTuple npt) {
discover(npt.getNodeId(), npt.getPortId());
}
protected void discover(long sw, short port) {
sendDiscoveryMessage(sw, port, true, false);
}
/**
* Learn remote switches when running as a distributed controller
*/
protected IOFSwitch addRemoteSwitch(long sw, short port) {
IOFSwitch remotesw = null;
// add a switch if we have not seen it before
remotesw = remoteSwitches.get(sw);
if (remotesw == null) {
remotesw = new OFSwitchImpl();
remotesw.setupRemoteSwitch(sw);
remoteSwitches.put(remotesw.getId(), remotesw);
log.debug("addRemoteSwitch(): added fake remote sw {}", remotesw);
}
// add the port if we have not seen it before
if (remotesw.getPort(port) == null) {
OFPhysicalPort remoteport = new OFPhysicalPort();
remoteport.setPortNumber(port);
remoteport.setName("fake_" + port);
remoteport.setConfig(0);
remoteport.setState(0);
remotesw.setPort(remoteport);
log.debug("addRemoteSwitch(): added fake remote port {} to sw {}", remoteport, remotesw.getId());
}
return remotesw;
}
/**
* Send link discovery message out of a given switch port.
* The discovery message may be a standard LLDP or a modified
* LLDP, where the dst mac address is set to :ff.
*
* TODO: The modified LLDP will updated in the future and may
* use a different eth-type.
* @param sw
* @param port
* @param isStandard indicates standard or modified LLDP
* @param isReverse indicates whether the LLDP was sent as a response
*/
@LogMessageDoc(level="ERROR",
message="Failure sending LLDP out port {port} on switch {switch}",
explanation="An I/O error occured while sending LLDP message " +
"to the switch.",
recommendation=LogMessageDoc.CHECK_SWITCH)
protected void sendDiscoveryMessage(long sw, short port,
boolean isStandard,
boolean isReverse) {
IOFSwitch iofSwitch = floodlightProvider.getSwitches().get(sw);
if (iofSwitch == null) {
return;
}
if (port == OFPort.OFPP_LOCAL.getValue())
return;
OFPhysicalPort ofpPort = iofSwitch.getPort(port);
if (ofpPort == null) {
if (log.isTraceEnabled()) {
log.trace("Null physical port. sw={}, port={}", sw, port);
}
return;
}
if (isLinkDiscoverySuppressed(sw, port)) {
/* Dont send LLDPs out of this port as suppressLLDPs set
*
*/
return;
}
// For fast ports, do not send forward LLDPs or BDDPs.
if (!isReverse && autoPortFastFeature && isFastPort(sw, port))
return;
if (log.isTraceEnabled()) {
log.trace("Sending LLDP packet out of swich: {}, port: {}",
sw, port);
}
// using "nearest customer bridge" MAC address for broadest possible propagation
// through provider and TPMR bridges (see IEEE 802.1AB-2009 and 802.1Q-2011),
// in particular the Linux bridge which behaves mostly like a provider bridge
byte[] chassisId = new byte[] {4, 0, 0, 0, 0, 0, 0}; // filled in later
byte[] portId = new byte[] {2, 0, 0}; // filled in later
byte[] ttlValue = new byte[] {0, 0x78};
// OpenFlow OUI - 00-26-E1
byte[] dpidTLVValue = new byte[] {0x0, 0x26, (byte) 0xe1, 0, 0, 0, 0, 0, 0, 0, 0, 0};
LLDPTLV dpidTLV = new LLDPTLV().setType((byte) 127).setLength((short) dpidTLVValue.length).setValue(dpidTLVValue);
byte[] dpidArray = new byte[8];
ByteBuffer dpidBB = ByteBuffer.wrap(dpidArray);
ByteBuffer portBB = ByteBuffer.wrap(portId, 1, 2);
Long dpid = sw;
dpidBB.putLong(dpid);
// set the ethernet source mac to last 6 bytes of dpid
System.arraycopy(dpidArray, 2, ofpPort.getHardwareAddress(), 0, 6);
// set the chassis id's value to last 6 bytes of dpid
System.arraycopy(dpidArray, 2, chassisId, 1, 6);
// set the optional tlv to the full dpid
System.arraycopy(dpidArray, 0, dpidTLVValue, 4, 8);
// set the portId to the outgoing port
portBB.putShort(port);
if (log.isTraceEnabled()) {
log.trace("Sending LLDP out of interface: {}/{}",
HexString.toHexString(sw), port);
}
LLDP lldp = new LLDP();
lldp.setChassisId(new LLDPTLV().setType((byte) 1).setLength((short) chassisId.length).setValue(chassisId));
lldp.setPortId(new LLDPTLV().setType((byte) 2).setLength((short) portId.length).setValue(portId));
lldp.setTtl(new LLDPTLV().setType((byte) 3).setLength((short) ttlValue.length).setValue(ttlValue));
lldp.getOptionalTLVList().add(dpidTLV);
// Add the controller identifier to the TLV value.
lldp.getOptionalTLVList().add(controllerTLV);
if (isReverse) {
lldp.getOptionalTLVList().add(reverseTLV);
}else {
lldp.getOptionalTLVList().add(forwardTLV);
}
Ethernet ethernet;
if (isStandard) {
ethernet = new Ethernet()
.setSourceMACAddress(ofpPort.getHardwareAddress())
.setDestinationMACAddress(LLDP_STANDARD_DST_MAC_STRING)
.setEtherType(Ethernet.TYPE_LLDP);
ethernet.setPayload(lldp);
} else {
BSN bsn = new BSN(BSN.BSN_TYPE_BDDP);
bsn.setPayload(lldp);
ethernet = new Ethernet()
.setSourceMACAddress(ofpPort.getHardwareAddress())
.setDestinationMACAddress(LLDP_BSN_DST_MAC_STRING)
.setEtherType(Ethernet.TYPE_BSN);
ethernet.setPayload(bsn);
}
// serialize and wrap in a packet out
byte[] data = ethernet.serialize();
OFPacketOut po = (OFPacketOut) floodlightProvider.getOFMessageFactory().getMessage(OFType.PACKET_OUT);
po.setBufferId(OFPacketOut.BUFFER_ID_NONE);
po.setInPort(OFPort.OFPP_NONE);
// set actions
List<OFAction> actions = new ArrayList<OFAction>();
actions.add(new OFActionOutput(port, (short) 0));
po.setActions(actions);
po.setActionsLength((short) OFActionOutput.MINIMUM_LENGTH);
// set data
po.setLengthU(OFPacketOut.MINIMUM_LENGTH + po.getActionsLength() + data.length);
po.setPacketData(data);
// send
try {
iofSwitch.write(po, null);
iofSwitch.flush();
} catch (IOException e) {
log.error("Failure sending LLDP out port {} on switch {}",
new Object[]{ port, iofSwitch.getStringId() }, e);
}
}
/**
* Send LLDPs to all switch-ports
*/
protected void discoverOnAllPorts() {
if (log.isTraceEnabled()) {
log.trace("Sending LLDP packets out of all the enabled ports on switch {}");
}
Set<Long> switches = floodlightProvider.getSwitches().keySet();
// Send standard LLDPs
for (long sw: switches) {
IOFSwitch iofSwitch = floodlightProvider.getSwitches().get(sw);
if (iofSwitch == null) continue;
if (iofSwitch.getEnabledPorts() != null) {
for (OFPhysicalPort ofp: iofSwitch.getEnabledPorts()) {
if (isLinkDiscoverySuppressed(sw, ofp.getPortNumber()))
continue;
if (autoPortFastFeature && isFastPort(sw, ofp.getPortNumber()))
continue;
// sends forward LLDP only non-fastports.
sendDiscoveryMessage(sw, ofp.getPortNumber(), true, false);
// If the switch port is not alreayd in the maintenance
// queue, add it.
NodePortTuple npt = new NodePortTuple(sw, ofp.getPortNumber());
addToMaintenanceQueue(npt);
}
}
}
}
protected void setControllerTLV() {
//Setting the controllerTLVValue based on current nano time,
//controller's IP address, and the network interface object hash
//the corresponding IP address.
final int prime = 7867;
InetAddress localIPAddress = null;
NetworkInterface localInterface = null;
byte[] controllerTLVValue = new byte[] {0, 0, 0, 0, 0, 0, 0, 0}; // 8 byte value.
ByteBuffer bb = ByteBuffer.allocate(10);
try{
localIPAddress = java.net.InetAddress.getLocalHost();
localInterface = NetworkInterface.getByInetAddress(localIPAddress);
} catch (Exception e) {
e.printStackTrace();
}
long result = System.nanoTime();
if (localIPAddress != null)
result = result * prime + IPv4.toIPv4Address(localIPAddress.getHostAddress());
if (localInterface != null)
result = result * prime + localInterface.hashCode();
// set the first 4 bits to 0.
result = result & (0x0fffffffffffffffL);
bb.putLong(result);
bb.rewind();
bb.get(controllerTLVValue, 0, 8);
this.controllerTLV = new LLDPTLV().setType((byte) 0x0c).setLength((short) controllerTLVValue.length).setValue(controllerTLVValue);
}
@Override
public String getName() {
return "linkdiscovery";
}
@Override
public Command receive(IOFSwitch sw, OFMessage msg, FloodlightContext cntx) {
switch (msg.getType()) {
case PACKET_IN:
return this.handlePacketIn(sw.getId(), (OFPacketIn) msg, cntx);
case PORT_STATUS:
return this.handlePortStatus(sw.getId(), (OFPortStatus) msg);
default:
break;
}
return Command.CONTINUE;
}
private Command handleLldp(LLDP lldp, long sw, OFPacketIn pi, boolean isStandard, FloodlightContext cntx) {
// If LLDP is suppressed on this port, ignore received packet as well
IOFSwitch iofSwitch = floodlightProvider.getSwitches().get(sw);
if (iofSwitch == null) {
return Command.STOP;
}
if (isLinkDiscoverySuppressed(sw, pi.getInPort()))
return Command.STOP;
// If this is a malformed LLDP, or not from us, exit
if (lldp.getPortId() == null || lldp.getPortId().getLength() != 3)
return Command.CONTINUE;
long myId = ByteBuffer.wrap(controllerTLV.getValue()).getLong();
long otherId = 0;
boolean myLLDP = false;
Boolean isReverse = null;
ByteBuffer portBB = ByteBuffer.wrap(lldp.getPortId().getValue());
portBB.position(1);
Short remotePort = portBB.getShort();
IOFSwitch remoteSwitch = null;
// Verify this LLDP packet matches what we're looking for
for (LLDPTLV lldptlv : lldp.getOptionalTLVList()) {
if (lldptlv.getType() == 127 && lldptlv.getLength() == 12 &&
lldptlv.getValue()[0] == 0x0 && lldptlv.getValue()[1] == 0x26 &&
lldptlv.getValue()[2] == (byte)0xe1 && lldptlv.getValue()[3] == 0x0) {
ByteBuffer dpidBB = ByteBuffer.wrap(lldptlv.getValue());
remoteSwitch = floodlightProvider.getSwitches().get(dpidBB.getLong(4));
if (remoteSwitch == null) {
// floodlight LLDP coming from a remote switch connected to a different controller
// add it to our cache of unconnected remote switches
remoteSwitch = addRemoteSwitch(dpidBB.getLong(4), remotePort);
}
} else if (lldptlv.getType() == 12 && lldptlv.getLength() == 8){
otherId = ByteBuffer.wrap(lldptlv.getValue()).getLong();
if (myId == otherId)
myLLDP = true;
} else if (lldptlv.getType() == TLV_DIRECTION_TYPE &&
lldptlv.getLength() == TLV_DIRECTION_LENGTH) {
if (lldptlv.getValue()[0] == TLV_DIRECTION_VALUE_FORWARD[0])
isReverse = false;
else if (lldptlv.getValue()[0] == TLV_DIRECTION_VALUE_REVERSE[0])
isReverse = true;
}
}
if (myLLDP == false) {
// This is not the LLDP sent by this controller.
// If the LLDP message has multicast bit set, then we need to broadcast
// the packet as a regular packet.
if (isStandard) {
if (log.isTraceEnabled()) {
log.trace("Getting standard LLDP from a different controller and quelching it.");
}
return Command.STOP;
}
else if (myId < otherId) {
if (log.isTraceEnabled()) {
log.trace("Getting BDDP packets from a different controller" +
"and letting it go through normal processing chain.");
}
//XXX Fix the BDDP broadcast issue
//return Command.CONTINUE;
return Command.STOP;
}
}
if (remoteSwitch == null) {
// Ignore LLDPs not generated by Floodlight, or from a switch that has recently
// disconnected, or from a switch connected to another Floodlight instance
if (log.isTraceEnabled()) {
log.trace("Received LLDP from remote switch not connected to the controller");
}
return Command.STOP;
}
if (!remoteSwitch.portEnabled(remotePort)) {
if (log.isTraceEnabled()) {
log.trace("Ignoring link with disabled source port: switch {} port {}", remoteSwitch, remotePort);
}
return Command.STOP;
}
if (suppressLinkDiscovery.contains(new NodePortTuple(remoteSwitch.getId(),
remotePort))) {
if (log.isTraceEnabled()) {
log.trace("Ignoring link with suppressed src port: switch {} port {}",
remoteSwitch, remotePort);
}
return Command.STOP;
}
if (!iofSwitch.portEnabled(pi.getInPort())) {
if (log.isTraceEnabled()) {
log.trace("Ignoring link with disabled dest port: switch {} port {}", sw, pi.getInPort());
}
return Command.STOP;
}
OFPhysicalPort physicalPort = remoteSwitch.getPort(remotePort);
int srcPortState = (physicalPort != null) ? physicalPort.getState() : 0;
physicalPort = iofSwitch.getPort(pi.getInPort());
int dstPortState = (physicalPort != null) ? physicalPort.getState() : 0;
// Store the time of update to this link, and push it out to routingEngine
Link lt = new Link(remoteSwitch.getId(), remotePort, iofSwitch.getId(), pi.getInPort());
Long lastLldpTime = null;
Long lastBddpTime = null;
Long firstSeenTime = System.currentTimeMillis();
if (isStandard)
lastLldpTime = System.currentTimeMillis();
else
lastBddpTime = System.currentTimeMillis();
LinkInfo newLinkInfo =
new LinkInfo(firstSeenTime, lastLldpTime, lastBddpTime,
srcPortState, dstPortState);
addOrUpdateLink(lt, newLinkInfo);
// Check if reverse link exists.
// If it doesn't exist and if the forward link was seen
// first seen within a small interval, send probe on the
// reverse link.
newLinkInfo = links.get(lt);
if (newLinkInfo != null && isStandard && isReverse == false) {
Link reverseLink = new Link(lt.getDst(), lt.getDstPort(),
lt.getSrc(), lt.getSrcPort());
LinkInfo reverseInfo = links.get(reverseLink);
if (reverseInfo == null) {
// the reverse link does not exist.
if (newLinkInfo.getFirstSeenTime() > System.currentTimeMillis() - LINK_TIMEOUT) {
this.sendDiscoveryMessage(lt.getDst(), lt.getDstPort(), isStandard, true);
}
}
}
// If the received packet is a BDDP packet, then create a reverse BDDP
// link as well.
if (!isStandard) {
Link reverseLink = new Link(lt.getDst(), lt.getDstPort(),
lt.getSrc(), lt.getSrcPort());
// srcPortState and dstPort state are reversed.
LinkInfo reverseInfo =
new LinkInfo(firstSeenTime, lastLldpTime, lastBddpTime,
dstPortState, srcPortState);
addOrUpdateLink(reverseLink, reverseInfo);
}
// Remove the node ports from the quarantine and maintenance queues.
NodePortTuple nptSrc = new NodePortTuple(lt.getSrc(), lt.getSrcPort());
NodePortTuple nptDst = new NodePortTuple(lt.getDst(), lt.getDstPort());
removeFromQuarantineQueue(nptSrc);
removeFromMaintenanceQueue(nptSrc);
removeFromQuarantineQueue(nptDst);
removeFromMaintenanceQueue(nptDst);
// Consume this message
return Command.STOP;
}
protected Command handlePacketIn(long sw, OFPacketIn pi,
FloodlightContext cntx) {
Ethernet eth =
IFloodlightProviderService.bcStore.get(cntx,
IFloodlightProviderService.CONTEXT_PI_PAYLOAD);
if(eth.getEtherType() == Ethernet.TYPE_BSN) {
BSN bsn = (BSN) eth.getPayload();
if (bsn == null) return Command.STOP;
if (bsn.getPayload() == null) return Command.STOP;
// It could be a packet other than BSN LLDP, therefore
// continue with the regular processing.
if (bsn.getPayload() instanceof LLDP == false)
return Command.CONTINUE;
return handleLldp((LLDP) bsn.getPayload(), sw, pi, false, cntx);
//return Command.STOP;
} else if (eth.getEtherType() == Ethernet.TYPE_LLDP) {
return handleLldp((LLDP) eth.getPayload(), sw, pi, true, cntx);
} else if (eth.getEtherType() < 1500) {
long destMac = eth.getDestinationMAC().toLong();
if ((destMac & LINK_LOCAL_MASK) == LINK_LOCAL_VALUE){
if (log.isTraceEnabled()) {
log.trace("Ignoring packet addressed to 802.1D/Q " +
"reserved address.");
}
return Command.STOP;
}
}
// If packet-in is from a quarantine port, stop processing.
NodePortTuple npt = new NodePortTuple(sw, pi.getInPort());
if (quarantineQueue.contains(npt)) return Command.STOP;
return Command.CONTINUE;
}
protected UpdateOperation getUpdateOperation(int srcPortState,
int dstPortState) {
boolean added =
(((srcPortState &
OFPortState.OFPPS_STP_MASK.getValue()) !=
OFPortState.OFPPS_STP_BLOCK.getValue()) &&
((dstPortState &
OFPortState.OFPPS_STP_MASK.getValue()) !=
OFPortState.OFPPS_STP_BLOCK.getValue()));
if (added) return UpdateOperation.LINK_UPDATED;
return UpdateOperation.LINK_REMOVED;
}
protected UpdateOperation getUpdateOperation(int srcPortState) {
boolean portUp = ((srcPortState &
OFPortState.OFPPS_STP_MASK.getValue()) !=
OFPortState.OFPPS_STP_BLOCK.getValue());
if (portUp) return UpdateOperation.PORT_UP;
else return UpdateOperation.PORT_DOWN;
}
protected boolean addOrUpdateLink(Link lt, LinkInfo newInfo) {
NodePortTuple srcNpt, dstNpt;
boolean linkChanged = false;
NetworkMapOperation operation = NetworkMapOperation.NONE;
lock.writeLock().lock();
try {
// put the new info. if an old info exists, it will be returned.
LinkInfo oldInfo = links.put(lt, newInfo);
if (oldInfo != null &&
oldInfo.getFirstSeenTime() < newInfo.getFirstSeenTime())
newInfo.setFirstSeenTime(oldInfo.getFirstSeenTime());
if (log.isTraceEnabled()) {
log.trace("addOrUpdateLink: {} {}",
lt,
(newInfo.getMulticastValidTime()!=null) ? "multicast" : "unicast");
}
UpdateOperation updateOperation = null;
linkChanged = false;
srcNpt = new NodePortTuple(lt.getSrc(), lt.getSrcPort());
dstNpt = new NodePortTuple(lt.getDst(), lt.getDstPort());
if (oldInfo == null) {
// index it by switch source
if (!switchLinks.containsKey(lt.getSrc()))
switchLinks.put(lt.getSrc(), new HashSet<Link>());
switchLinks.get(lt.getSrc()).add(lt);
// index it by switch dest
if (!switchLinks.containsKey(lt.getDst()))
switchLinks.put(lt.getDst(), new HashSet<Link>());
switchLinks.get(lt.getDst()).add(lt);
// index both ends by switch:port
if (!portLinks.containsKey(srcNpt))
portLinks.put(srcNpt, new HashSet<Link>());
portLinks.get(srcNpt).add(lt);
if (!portLinks.containsKey(dstNpt))
portLinks.put(dstNpt, new HashSet<Link>());
portLinks.get(dstNpt).add(lt);
// Add to portNOFLinks if the unicast valid time is null
if (newInfo.getUnicastValidTime() == null)
addLinkToBroadcastDomain(lt);
writeLinkToStorage(lt, newInfo);
// Write link to network map
operation = NetworkMapOperation.INSERT;
//linkStore.update(lt, newInfo, DM_OPERATION.INSERT);
updateOperation = UpdateOperation.LINK_UPDATED;
linkChanged = true;
// Add to event history
evHistTopoLink(lt.getSrc(),
lt.getDst(),
lt.getSrcPort(),
lt.getDstPort(),
newInfo.getSrcPortState(), newInfo.getDstPortState(),
getLinkType(lt, newInfo),
EvAction.LINK_ADDED, "LLDP Recvd");
} else {
// Since the link info is already there, we need to
// update the right fields.
if (newInfo.getUnicastValidTime() == null) {
// This is due to a multicast LLDP, so copy the old unicast
// value.
if (oldInfo.getUnicastValidTime() != null) {
newInfo.setUnicastValidTime(oldInfo.getUnicastValidTime());
}
} else if (newInfo.getMulticastValidTime() == null) {
// This is due to a unicast LLDP, so copy the old multicast
// value.
if (oldInfo.getMulticastValidTime() != null) {
newInfo.setMulticastValidTime(oldInfo.getMulticastValidTime());
}
}
Long oldTime = oldInfo.getUnicastValidTime();
Long newTime = newInfo.getUnicastValidTime();
// the link has changed its state between openflow and non-openflow
// if the unicastValidTimes are null or not null
if (oldTime != null & newTime == null) {
// openflow -> non-openflow transition
// we need to add the link tuple to the portNOFLinks
addLinkToBroadcastDomain(lt);
linkChanged = true;
} else if (oldTime == null & newTime != null) {
// non-openflow -> openflow transition
// we need to remove the link from the portNOFLinks
removeLinkFromBroadcastDomain(lt);
linkChanged = true;
}
// Only update the port states if they've changed
if (newInfo.getSrcPortState().intValue() !=
oldInfo.getSrcPortState().intValue() ||
newInfo.getDstPortState().intValue() !=
oldInfo.getDstPortState().intValue())
linkChanged = true;
// Write changes to storage. This will always write the updated
// valid time, plus the port states if they've changed (i.e. if
// they weren't set to null in the previous block of code.
writeLinkToStorage(lt, newInfo);
// Write link to network map
operation = NetworkMapOperation.UPDATE;
//linkStore.update(lt, newInfo, DM_OPERATION.UPDATE);
if (linkChanged) {
updateOperation = getUpdateOperation(newInfo.getSrcPortState(),
newInfo.getDstPortState());
if (log.isTraceEnabled()) {
log.trace("Updated link {}", lt);
}
// Add to event history
evHistTopoLink(lt.getSrc(),
lt.getDst(),
lt.getSrcPort(),
lt.getDstPort(),
newInfo.getSrcPortState(), newInfo.getDstPortState(),
getLinkType(lt, newInfo),
EvAction.LINK_PORT_STATE_UPDATED,
"LLDP Recvd");
}
}
if (linkChanged) {
// find out if the link was added or removed here.
updates.add(new LDUpdate(lt.getSrc(), lt.getSrcPort(),
lt.getDst(), lt.getDstPort(),
getLinkType(lt, newInfo),
updateOperation));
}
} finally {
lock.writeLock().unlock();
}
switch (operation){
case INSERT:
linkStore.update(lt, newInfo, DM_OPERATION.INSERT);
break;
case UPDATE:
linkStore.update(lt, newInfo, DM_OPERATION.UPDATE);
break;
case NONE:
default:
break;
}
return linkChanged;
}
public Map<Long, Set<Link>> getSwitchLinks() {
return this.switchLinks;
}
/**
* Removes links from memory and storage.
* @param links The List of @LinkTuple to delete.
*/
protected void deleteLinks(List<Link> links, String reason) {
deleteLinks(links, reason, Boolean.TRUE);
}
/**
* Removes links from memory and storage.
* @param links The List of @LinkTuple to delete.
*/
protected void deleteLinks(List<Link> links, String reason, Boolean hasControl) {
NodePortTuple srcNpt, dstNpt;
lock.writeLock().lock();
try {
for (Link lt : links) {
srcNpt = new NodePortTuple(lt.getSrc(), lt.getSrcPort());
dstNpt =new NodePortTuple(lt.getDst(), lt.getDstPort());
switchLinks.get(lt.getSrc()).remove(lt);
switchLinks.get(lt.getDst()).remove(lt);
if (switchLinks.containsKey(lt.getSrc()) &&
switchLinks.get(lt.getSrc()).isEmpty())
this.switchLinks.remove(lt.getSrc());
if (this.switchLinks.containsKey(lt.getDst()) &&
this.switchLinks.get(lt.getDst()).isEmpty())
this.switchLinks.remove(lt.getDst());
if (this.portLinks.get(srcNpt) != null) {
this.portLinks.get(srcNpt).remove(lt);
if (this.portLinks.get(srcNpt).isEmpty())
this.portLinks.remove(srcNpt);
}
if (this.portLinks.get(dstNpt) != null) {
this.portLinks.get(dstNpt).remove(lt);
if (this.portLinks.get(dstNpt).isEmpty())
this.portLinks.remove(dstNpt);
}
LinkInfo info = this.links.remove(lt);
updates.add(new LDUpdate(lt.getSrc(), lt.getSrcPort(),
lt.getDst(), lt.getDstPort(),
getLinkType(lt, info),
UpdateOperation.LINK_REMOVED));
// Update Event History
evHistTopoLink(lt.getSrc(),
lt.getDst(),
lt.getSrcPort(),
lt.getDstPort(),
0, 0, // Port states
ILinkDiscovery.LinkType.INVALID_LINK,
EvAction.LINK_DELETED, reason);
// remove link from storage.
removeLinkFromStorage(lt);
// remote link from network map
linkStore.update(lt, DM_OPERATION.DELETE);
// TODO Whenever link is removed, it has to checked if
// the switchports must be added to quarantine.
if (log.isTraceEnabled()) {
log.trace("Deleted link {}", lt);
}
}
} finally {
lock.writeLock().unlock();
}
}
/**
* Handles an OFPortStatus message from a switch. We will add or
* delete LinkTupes as well re-compute the topology if needed.
* @param sw The IOFSwitch that sent the port status message
* @param ps The OFPortStatus message
* @return The Command to continue or stop after we process this message
*/
protected Command handlePortStatus(long sw, OFPortStatus ps) {
IOFSwitch iofSwitch = floodlightProvider.getSwitches().get(sw);
if (iofSwitch == null) return Command.CONTINUE;
// If we do not control this switch, then we should not process its port status messages
if (!registryService.hasControl(iofSwitch.getId())) return Command.CONTINUE;
if (log.isTraceEnabled()) {
log.trace("handlePortStatus: Switch {} port #{} reason {}; " +
"config is {} state is {}",
new Object[] {iofSwitch.getStringId(),
ps.getDesc().getPortNumber(),
ps.getReason(),
ps.getDesc().getConfig(),
ps.getDesc().getState()});
}
short port = ps.getDesc().getPortNumber();
NodePortTuple npt = new NodePortTuple(sw, port);
boolean linkDeleted = false;
boolean linkInfoChanged = false;
lock.writeLock().lock();
try {
// if ps is a delete, or a modify where the port is down or
// configured down
if ((byte)OFPortReason.OFPPR_DELETE.ordinal() == ps.getReason() ||
((byte)OFPortReason.OFPPR_MODIFY.ordinal() ==
ps.getReason() && !portEnabled(ps.getDesc()))) {
deleteLinksOnPort(npt, "Port Status Changed");
//swStore.deletePort(HexString.toHexString(npt.getNodeId()), npt.getPortId());
LDUpdate update = new LDUpdate(sw, port, UpdateOperation.PORT_DOWN);
updates.add(update);
linkDeleted = true;
}
else if (ps.getReason() ==
(byte)OFPortReason.OFPPR_MODIFY.ordinal()) {
// If ps is a port modification and the port state has changed
// that affects links in the topology
if (this.portLinks.containsKey(npt)) {
for (Link lt: this.portLinks.get(npt)) {
LinkInfo linkInfo = links.get(lt);
assert(linkInfo != null);
Integer updatedSrcPortState = null;
Integer updatedDstPortState = null;
if (lt.getSrc() == npt.getNodeId() &&
lt.getSrcPort() == npt.getPortId() &&
(linkInfo.getSrcPortState() !=
ps.getDesc().getState())) {
updatedSrcPortState = ps.getDesc().getState();
linkInfo.setSrcPortState(updatedSrcPortState);
}
if (lt.getDst() == npt.getNodeId() &&
lt.getDstPort() == npt.getPortId() &&
(linkInfo.getDstPortState() !=
ps.getDesc().getState())) {
updatedDstPortState = ps.getDesc().getState();
linkInfo.setDstPortState(updatedDstPortState);
}
if ((updatedSrcPortState != null) ||
(updatedDstPortState != null)) {
// The link is already known to link discovery
// manager and the status has changed, therefore
// send an LDUpdate.
UpdateOperation operation =
getUpdateOperation(linkInfo.getSrcPortState(),
linkInfo.getDstPortState());
updates.add(new LDUpdate(lt.getSrc(), lt.getSrcPort(),
lt.getDst(), lt.getDstPort(),
getLinkType(lt, linkInfo),
operation));
writeLinkToStorage(lt, linkInfo);
// Write the changed link to the network map
linkStore.update(lt, linkInfo, DM_OPERATION.UPDATE);
linkInfoChanged = true;
}
}
}
UpdateOperation operation =
getUpdateOperation(ps.getDesc().getState());
updates.add(new LDUpdate(sw, port, operation));
}
if (!linkDeleted && !linkInfoChanged){
if (log.isTraceEnabled()) {
log.trace("handlePortStatus: Switch {} port #{} reason {};"+
" no links to update/remove",
new Object[] {HexString.toHexString(sw),
ps.getDesc().getPortNumber(),
ps.getReason()});
}
}
} finally {
lock.writeLock().unlock();
}
if (!linkDeleted) {
// Send LLDP right away when port state is changed for faster
// cluster-merge. If it is a link delete then there is not need
// to send the LLDPs right away and instead we wait for the LLDPs
// to be sent on the timer as it is normally done
// do it outside the write-lock
// sendLLDPTask.reschedule(1000, TimeUnit.MILLISECONDS);
processNewPort(npt.getNodeId(), npt.getPortId());
}
return Command.CONTINUE;
}
/**
* Process a new port.
* If link discovery is disabled on the port, then do nothing.
* If autoportfast feature is enabled and the port is a fast port, then
* do nothing.
* Otherwise, send LLDP message. Add the port to quarantine.
* @param sw
* @param p
*/
private void processNewPort(long sw, short p) {
if (isLinkDiscoverySuppressed(sw, p)) {
// Do nothing as link discovery is suppressed.
}
else if (autoPortFastFeature && isFastPort(sw, p)) {
// Do nothing as the port is a fast port.
}
else {
NodePortTuple npt = new NodePortTuple(sw, p);
discover(sw, p);
// if it is not a fast port, add it to quarantine.
if (!isFastPort(sw, p)) {
addToQuarantineQueue(npt);
} else {
// Add to maintenance queue to ensure that BDDP packets
// are sent out.
addToMaintenanceQueue(npt);
}
}
}
/**
* We send out LLDP messages when a switch is added to discover the topology
* @param sw The IOFSwitch that connected to the controller
*/
@Override
public void addedSwitch(IOFSwitch sw) {
if (sw.getEnabledPorts() != null) {
for (Short p : sw.getEnabledPortNumbers()) {
processNewPort(sw.getId(), p);
}
}
// Update event history
evHistTopoSwitch(sw, EvAction.SWITCH_CONNECTED, "None");
LDUpdate update = new LDUpdate(sw.getId(), null,
UpdateOperation.SWITCH_UPDATED);
updates.add(update);
}
/**
* When a switch disconnects we remove any links from our map and notify.
* @param The id of the switch
*/
@Override
public void removedSwitch(IOFSwitch iofSwitch) {
// Update event history
long sw = iofSwitch.getId();
evHistTopoSwitch(iofSwitch, EvAction.SWITCH_DISCONNECTED, "None");
List<Link> eraseList = new ArrayList<Link>();
lock.writeLock().lock();
try {
if (switchLinks.containsKey(sw)) {
if (log.isTraceEnabled()) {
log.trace("Handle switchRemoved. Switch {}; removing links {}",
HexString.toHexString(sw), switchLinks.get(sw));
}
// add all tuples with an endpoint on this switch to erase list
eraseList.addAll(switchLinks.get(sw));
// We can get called to delete links when we lose mastership. To avoid clearing the network map in that case,
// figure out if we have control of the switch
boolean hasControl = registryService.hasControl(sw);
deleteLinks(eraseList, "Switch Removed", hasControl);
// Send a switch removed update
LDUpdate update = new LDUpdate(sw, null, UpdateOperation.SWITCH_REMOVED);
updates.add(update);
}
} finally {
lock.writeLock().unlock();
}
}
/**
* We don't react the port changed notifications here. we listen for
* OFPortStatus messages directly. Might consider using this notifier
* instead
*/
@Override
public void switchPortChanged(Long switchId) {
// no-op
}
/**
* Delete links incident on a given switch port.
* @param npt
* @param reason
*/
protected void deleteLinksOnPort(NodePortTuple npt, String reason) {
List<Link> eraseList = new ArrayList<Link>();
if (this.portLinks.containsKey(npt)) {
if (log.isTraceEnabled()) {
log.trace("handlePortStatus: Switch {} port #{} " +
"removing links {}",
new Object[] {HexString.toHexString(npt.getNodeId()),
npt.getPortId(),
this.portLinks.get(npt)});
}
eraseList.addAll(this.portLinks.get(npt));
deleteLinks(eraseList, reason);
}
}
/**
* Iterates through the list of links and deletes if the
* last discovery message reception time exceeds timeout values.
*/
protected void timeoutLinks() {
List<Link> eraseList = new ArrayList<Link>();
Long curTime = System.currentTimeMillis();
boolean linkChanged = false;
// reentrant required here because deleteLink also write locks
lock.writeLock().lock();
try {
Iterator<Entry<Link, LinkInfo>> it =
this.links.entrySet().iterator();
while (it.hasNext()) {
Entry<Link, LinkInfo> entry = it.next();
Link lt = entry.getKey();
LinkInfo info = entry.getValue();
// Timeout the unicast and multicast LLDP valid times
// independently.
if ((info.getUnicastValidTime() != null) &&
(info.getUnicastValidTime() + (this.LINK_TIMEOUT * 1000) < curTime)){
info.setUnicastValidTime(null);
if (info.getMulticastValidTime() != null)
addLinkToBroadcastDomain(lt);
// Note that even if mTime becomes null later on,
// the link would be deleted, which would trigger updateClusters().
linkChanged = true;
}
if ((info.getMulticastValidTime()!= null) &&
(info.getMulticastValidTime()+ (this.LINK_TIMEOUT * 1000) < curTime)) {
info.setMulticastValidTime(null);
// if uTime is not null, then link will remain as openflow
// link. If uTime is null, it will be deleted. So, we
// don't care about linkChanged flag here.
removeLinkFromBroadcastDomain(lt);
linkChanged = true;
}
// Add to the erase list only if the unicast
// time is null.
if (info.getUnicastValidTime() == null &&
info.getMulticastValidTime() == null){
eraseList.add(entry.getKey());
} else if (linkChanged) {
UpdateOperation operation;
operation = getUpdateOperation(info.getSrcPortState(),
info.getDstPortState());
updates.add(new LDUpdate(lt.getSrc(), lt.getSrcPort(),
lt.getDst(), lt.getDstPort(),
getLinkType(lt, info),
operation));
}
}
// if any link was deleted or any link was changed.
if ((eraseList.size() > 0) || linkChanged) {
deleteLinks(eraseList, "LLDP timeout");
}
} finally {
lock.writeLock().unlock();
}
}
private boolean portEnabled(OFPhysicalPort port) {
if (port == null)
return false;
if ((OFPortConfig.OFPPC_PORT_DOWN.getValue() & port.getConfig()) > 0)
return false;
if ((OFPortState.OFPPS_LINK_DOWN.getValue() & port.getState()) > 0)
return false;
// Port STP state doesn't work with multiple VLANs, so ignore it for now
// if ((port.getState() & OFPortState.OFPPS_STP_MASK.getValue()) == OFPortState.OFPPS_STP_BLOCK.getValue())
// return false;
return true;
}
public Map<NodePortTuple, Set<Link>> getPortBroadcastDomainLinks() {
return portBroadcastDomainLinks;
}
@Override
public Map<Link, LinkInfo> getLinks() {
lock.readLock().lock();
Map<Link, LinkInfo> result;
try {
result = new HashMap<Link, LinkInfo>(links);
} finally {
lock.readLock().unlock();
}
return result;
}
protected void addLinkToBroadcastDomain(Link lt) {
NodePortTuple srcNpt, dstNpt;
srcNpt = new NodePortTuple(lt.getSrc(), lt.getSrcPort());
dstNpt = new NodePortTuple(lt.getDst(), lt.getDstPort());
if (!portBroadcastDomainLinks.containsKey(lt.getSrc()))
portBroadcastDomainLinks.put(srcNpt, new HashSet<Link>());
portBroadcastDomainLinks.get(srcNpt).add(lt);
if (!portBroadcastDomainLinks.containsKey(lt.getDst()))
portBroadcastDomainLinks.put(dstNpt, new HashSet<Link>());
portBroadcastDomainLinks.get(dstNpt).add(lt);
}
protected void removeLinkFromBroadcastDomain(Link lt) {
NodePortTuple srcNpt, dstNpt;
srcNpt = new NodePortTuple(lt.getSrc(), lt.getSrcPort());
dstNpt = new NodePortTuple(lt.getDst(), lt.getDstPort());
if (portBroadcastDomainLinks.containsKey(srcNpt)) {
portBroadcastDomainLinks.get(srcNpt).remove(lt);
if (portBroadcastDomainLinks.get(srcNpt).isEmpty())
portBroadcastDomainLinks.remove(srcNpt);
}
if (portBroadcastDomainLinks.containsKey(dstNpt)) {
portBroadcastDomainLinks.get(dstNpt).remove(lt);
if (portBroadcastDomainLinks.get(dstNpt).isEmpty())
portBroadcastDomainLinks.remove(dstNpt);
}
}
// STORAGE METHODS
/**
* Deletes all links from storage
*/
void clearAllLinks() {
storageSource.deleteRowsAsync(LINK_TABLE_NAME, null);
}
/**
* Gets the storage key for a LinkTuple
* @param lt The LinkTuple to get
* @return The storage key as a String
*/
private String getLinkId(Link lt) {
return HexString.toHexString(lt.getSrc()) +
"-" + lt.getSrcPort() + "-" +
HexString.toHexString(lt.getDst())+
"-" + lt.getDstPort();
}
/**
* Writes a LinkTuple and corresponding LinkInfo to storage
* @param lt The LinkTuple to write
* @param linkInfo The LinkInfo to write
*/
protected void writeLinkToStorage(Link lt, LinkInfo linkInfo) {
LinkType type = getLinkType(lt, linkInfo);
// Write only direct links. Do not write links to external
// L2 network.
// if (type != LinkType.DIRECT_LINK && type != LinkType.TUNNEL) {
// return;
// }
Map<String, Object> rowValues = new HashMap<String, Object>();
String id = getLinkId(lt);
rowValues.put(LINK_ID, id);
rowValues.put(LINK_VALID_TIME, linkInfo.getUnicastValidTime());
String srcDpid = HexString.toHexString(lt.getSrc());
rowValues.put(LINK_SRC_SWITCH, srcDpid);
rowValues.put(LINK_SRC_PORT, lt.getSrcPort());
if (type == LinkType.DIRECT_LINK)
rowValues.put(LINK_TYPE, "internal");
else if (type == LinkType.MULTIHOP_LINK)
rowValues.put(LINK_TYPE, "external");
else if (type == LinkType.TUNNEL)
rowValues.put(LINK_TYPE, "tunnel");
else rowValues.put(LINK_TYPE, "invalid");
if (linkInfo.linkStpBlocked()) {
if (log.isTraceEnabled()) {
log.trace("writeLink, link {}, info {}, srcPortState Blocked",
lt, linkInfo);
}
rowValues.put(LINK_SRC_PORT_STATE,
OFPhysicalPort.OFPortState.OFPPS_STP_BLOCK.getValue());
} else {
if (log.isTraceEnabled()) {
log.trace("writeLink, link {}, info {}, srcPortState {}",
new Object[]{ lt, linkInfo, linkInfo.getSrcPortState() });
}
rowValues.put(LINK_SRC_PORT_STATE, linkInfo.getSrcPortState());
}
String dstDpid = HexString.toHexString(lt.getDst());
rowValues.put(LINK_DST_SWITCH, dstDpid);
rowValues.put(LINK_DST_PORT, lt.getDstPort());
if (linkInfo.linkStpBlocked()) {
if (log.isTraceEnabled()) {
log.trace("writeLink, link {}, info {}, dstPortState Blocked",
lt, linkInfo);
}
rowValues.put(LINK_DST_PORT_STATE,
OFPhysicalPort.OFPortState.OFPPS_STP_BLOCK.getValue());
} else {
if (log.isTraceEnabled()) {
log.trace("writeLink, link {}, info {}, dstPortState {}",
new Object[]{ lt, linkInfo, linkInfo.getDstPortState() });
}
rowValues.put(LINK_DST_PORT_STATE, linkInfo.getDstPortState());
}
storageSource.updateRowAsync(LINK_TABLE_NAME, rowValues);
}
public Long readLinkValidTime(Link lt) {
// FIXME: We're not currently using this right now, but if we start
// to use this again, we probably shouldn't use it in its current
// form, because it's doing synchronous storage calls. Depending
// on the context this may still be OK, but if it's being called
// on the packet in processing thread it should be reworked to
// use asynchronous storage calls.
Long validTime = null;
IResultSet resultSet = null;
try {
String[] columns = { LINK_VALID_TIME };
String id = getLinkId(lt);
resultSet = storageSource.executeQuery(LINK_TABLE_NAME, columns,
new OperatorPredicate(LINK_ID, OperatorPredicate.Operator.EQ, id), null);
if (resultSet.next())
validTime = resultSet.getLong(LINK_VALID_TIME);
}
finally {
if (resultSet != null)
resultSet.close();
}
return validTime;
}
/**
* Removes a link from storage using an asynchronous call.
* @param lt The LinkTuple to delete.
*/
protected void removeLinkFromStorage(Link lt) {
String id = getLinkId(lt);
storageSource.deleteRowAsync(LINK_TABLE_NAME, id);
}
@Override
public void addListener(ILinkDiscoveryListener listener) {
linkDiscoveryAware.add(listener);
}
/**
* Register a link discovery aware component
* @param linkDiscoveryAwareComponent
*/
public void addLinkDiscoveryAware(ILinkDiscoveryListener linkDiscoveryAwareComponent) {
// TODO make this a copy on write set or lock it somehow
this.linkDiscoveryAware.add(linkDiscoveryAwareComponent);
}
/**
* Deregister a link discovery aware component
* @param linkDiscoveryAwareComponent
*/
public void removeLinkDiscoveryAware(ILinkDiscoveryListener linkDiscoveryAwareComponent) {
// TODO make this a copy on write set or lock it somehow
this.linkDiscoveryAware.remove(linkDiscoveryAwareComponent);
}
/**
* Sets the IStorageSource to use for ITology
* @param storageSource the storage source to use
*/
public void setStorageSource(IStorageSourceService storageSource) {
this.storageSource = storageSource;
}
/**
* Gets the storage source for this ITopology
* @return The IStorageSource ITopology is writing to
*/
public IStorageSourceService getStorageSource() {
return storageSource;
}
@Override
public boolean isCallbackOrderingPrereq(OFType type, String name) {
return false;
}
@Override
public boolean isCallbackOrderingPostreq(OFType type, String name) {
return false;
}
@Override
public void rowsModified(String tableName, Set<Object> rowKeys) {
Map<Long, IOFSwitch> switches = floodlightProvider.getSwitches();
ArrayList<IOFSwitch> updated_switches = new ArrayList<IOFSwitch>();
for(Object key: rowKeys) {
Long swId = new Long(HexString.toLong((String)key));
if (switches.containsKey(swId)) {
IOFSwitch sw = switches.get(swId);
boolean curr_status = sw.hasAttribute(IOFSwitch.SWITCH_IS_CORE_SWITCH);
boolean new_status = false;
IResultSet resultSet = null;
try {
resultSet = storageSource.getRow(tableName, key);
for (Iterator<IResultSet> it = resultSet.iterator(); it.hasNext();) {
// In case of multiple rows, use the status in last row?
Map<String, Object> row = it.next().getRow();
if (row.containsKey(SWITCH_CONFIG_CORE_SWITCH)) {
new_status = ((String)row.get(SWITCH_CONFIG_CORE_SWITCH)).equals("true");
}
}
}
finally {
if (resultSet != null)
resultSet.close();
}
if (curr_status != new_status) {
updated_switches.add(sw);
}
} else {
if (log.isTraceEnabled()) {
log.trace("Update for switch which has no entry in switch " +
"list (dpid={}), a delete action.", (String)key);
}
}
}
for (IOFSwitch sw : updated_switches) {
// Set SWITCH_IS_CORE_SWITCH to it's inverse value
if (sw.hasAttribute(IOFSwitch.SWITCH_IS_CORE_SWITCH)) {
sw.removeAttribute(IOFSwitch.SWITCH_IS_CORE_SWITCH);
if (log.isTraceEnabled()) {
log.trace("SWITCH_IS_CORE_SWITCH set to False for {}", sw);
}
updates.add(new LDUpdate(sw.getId(), SwitchType.BASIC_SWITCH,
UpdateOperation.SWITCH_UPDATED));
}
else {
sw.setAttribute(IOFSwitch.SWITCH_IS_CORE_SWITCH, new Boolean(true));
if (log.isTraceEnabled()) {
log.trace("SWITCH_IS_CORE_SWITCH set to True for {}", sw);
}
updates.add(new LDUpdate(sw.getId(), SwitchType.CORE_SWITCH,
UpdateOperation.SWITCH_UPDATED));
}
}
}
@Override
public void rowsDeleted(String tableName, Set<Object> rowKeys) {
// Ignore delete events, the switch delete will do the right thing on it's own
}
// IFloodlightModule classes
@Override
public Collection<Class<? extends IFloodlightService>> getModuleServices() {
Collection<Class<? extends IFloodlightService>> l =
new ArrayList<Class<? extends IFloodlightService>>();
l.add(ILinkDiscoveryService.class);
//l.add(ITopologyService.class);
return l;
}
@Override
public Map<Class<? extends IFloodlightService>, IFloodlightService>
getServiceImpls() {
Map<Class<? extends IFloodlightService>,
IFloodlightService> m =
new HashMap<Class<? extends IFloodlightService>,
IFloodlightService>();
// We are the class that implements the service
m.put(ILinkDiscoveryService.class, this);
return m;
}
@Override
public Collection<Class<? extends IFloodlightService>> getModuleDependencies() {
Collection<Class<? extends IFloodlightService>> l =
new ArrayList<Class<? extends IFloodlightService>>();
l.add(IFloodlightProviderService.class);
l.add(IStorageSourceService.class);
l.add(IThreadPoolService.class);
l.add(IRestApiService.class);
l.add(IControllerRegistryService.class);
return l;
}
@Override
public void init(FloodlightModuleContext context)
throws FloodlightModuleException {
floodlightProvider = context.getServiceImpl(IFloodlightProviderService.class);
storageSource = context.getServiceImpl(IStorageSourceService.class);
threadPool = context.getServiceImpl(IThreadPoolService.class);
restApi = context.getServiceImpl(IRestApiService.class);
registryService = context.getServiceImpl(IControllerRegistryService.class);
// Set the autoportfast feature to false.
this.autoPortFastFeature = false;
// We create this here because there is no ordering guarantee
this.linkDiscoveryAware = new ArrayList<ILinkDiscoveryListener>();
this.lock = new ReentrantReadWriteLock();
this.updates = new LinkedBlockingQueue<LDUpdate>();
this.links = new HashMap<Link, LinkInfo>();
this.portLinks = new HashMap<NodePortTuple, Set<Link>>();
this.suppressLinkDiscovery =
Collections.synchronizedSet(new HashSet<NodePortTuple>());
this.portBroadcastDomainLinks = new HashMap<NodePortTuple, Set<Link>>();
this.switchLinks = new HashMap<Long, Set<Link>>();
this.quarantineQueue = new LinkedBlockingQueue<NodePortTuple>();
this.maintenanceQueue = new LinkedBlockingQueue<NodePortTuple>();
this.remoteSwitches = new HashMap<Long, IOFSwitch>();
this.evHistTopologySwitch =
new EventHistory<EventHistoryTopologySwitch>("Topology: Switch");
this.evHistTopologyLink =
new EventHistory<EventHistoryTopologyLink>("Topology: Link");
this.evHistTopologyCluster =
new EventHistory<EventHistoryTopologyCluster>("Topology: Cluster");
}
@Override
@LogMessageDocs({
@LogMessageDoc(level="ERROR",
message="No storage source found.",
explanation="Storage source was not initialized; cannot initialize " +
"link discovery.",
recommendation=LogMessageDoc.REPORT_CONTROLLER_BUG),
@LogMessageDoc(level="ERROR",
message="Error in installing listener for " +
"switch config table {table}",
explanation="Failed to install storage notification for the " +
"switch config table",
recommendation=LogMessageDoc.REPORT_CONTROLLER_BUG),
@LogMessageDoc(level="ERROR",
message="No storage source found.",
explanation="Storage source was not initialized; cannot initialize " +
"link discovery.",
recommendation=LogMessageDoc.REPORT_CONTROLLER_BUG),
@LogMessageDoc(level="ERROR",
message="Exception in LLDP send timer.",
explanation="An unknown error occured while sending LLDP " +
"messages to switches.",
recommendation=LogMessageDoc.CHECK_SWITCH)
})
public void startUp(FloodlightModuleContext context) {
// Create our storage tables
if (storageSource == null) {
log.error("No storage source found.");
return;
}
storageSource.createTable(LINK_TABLE_NAME, null);
storageSource.setTablePrimaryKeyName(LINK_TABLE_NAME, LINK_ID);
storageSource.deleteMatchingRows(LINK_TABLE_NAME, null);
// Register for storage updates for the switch table
try {
storageSource.addListener(SWITCH_CONFIG_TABLE_NAME, this);
} catch (StorageException ex) {
log.error("Error in installing listener for " +
"switch table {}", SWITCH_CONFIG_TABLE_NAME);
}
ScheduledExecutorService ses = threadPool.getScheduledExecutor();
// To be started by the first switch connection
discoveryTask = new SingletonTask(ses, new Runnable() {
@Override
public void run() {
try {
discoverLinks();
} catch (StorageException e) {
log.error("Storage exception in LLDP send timer; " +
"terminating process", e);
floodlightProvider.terminate();
} catch (Exception e) {
log.error("Exception in LLDP send timer.", e);
} finally {
if (!shuttingDown) {
// null role implies HA mode is not enabled.
Role role = floodlightProvider.getRole();
if (role == null || role == Role.MASTER) {
log.trace("Rescheduling discovery task as role = {}", role);
discoveryTask.reschedule(DISCOVERY_TASK_INTERVAL,
TimeUnit.SECONDS);
} else {
log.trace("Stopped LLDP rescheduling due to role = {}.", role);
}
}
}
}
});
// null role implies HA mode is not enabled.
Role role = floodlightProvider.getRole();
if (role == null || role == Role.MASTER) {
log.trace("Setup: Rescheduling discovery task. role = {}", role);
discoveryTask.reschedule(DISCOVERY_TASK_INTERVAL, TimeUnit.SECONDS);
} else {
log.trace("Setup: Not scheduling LLDP as role = {}.", role);
}
// Setup the BDDP task. It is invoked whenever switch port tuples
// are added to the quarantine list.
bddpTask = new SingletonTask(ses, new QuarantineWorker());
bddpTask.reschedule(BDDP_TASK_INTERVAL, TimeUnit.MILLISECONDS);
updatesThread = new Thread(new Runnable () {
@Override
public void run() {
while (true) {
try {
doUpdatesThread();
} catch (InterruptedException e) {
return;
}
}
}}, "Topology Updates");
updatesThread.start();
// Register for the OpenFlow messages we want to receive
floodlightProvider.addOFMessageListener(OFType.PACKET_IN, this);
floodlightProvider.addOFMessageListener(OFType.PORT_STATUS, this);
// Register for switch updates
floodlightProvider.addOFSwitchListener(this);
floodlightProvider.addHAListener(this);
floodlightProvider.addInfoProvider("summary", this);
if (restApi != null)
restApi.addRestletRoutable(new LinkDiscoveryWebRoutable());
setControllerTLV();
}
// ****************************************************
// Topology Manager's Event History members and methods
// ****************************************************
// Topology Manager event history
public EventHistory<EventHistoryTopologySwitch> evHistTopologySwitch;
public EventHistory<EventHistoryTopologyLink> evHistTopologyLink;
public EventHistory<EventHistoryTopologyCluster> evHistTopologyCluster;
public EventHistoryTopologySwitch evTopoSwitch;
public EventHistoryTopologyLink evTopoLink;
public EventHistoryTopologyCluster evTopoCluster;
// Switch Added/Deleted
private void evHistTopoSwitch(IOFSwitch sw, EvAction actn, String reason) {
if (evTopoSwitch == null) {
evTopoSwitch = new EventHistoryTopologySwitch();
}
evTopoSwitch.dpid = sw.getId();
if ((sw.getChannel() != null) &&
(SocketAddress.class.isInstance(
sw.getChannel().getRemoteAddress()))) {
evTopoSwitch.ipv4Addr =
IPv4.toIPv4Address(((InetSocketAddress)(sw.getChannel().
getRemoteAddress())).getAddress().getAddress());
evTopoSwitch.l4Port =
((InetSocketAddress)(sw.getChannel().
getRemoteAddress())).getPort();
} else {
evTopoSwitch.ipv4Addr = 0;
evTopoSwitch.l4Port = 0;
}
evTopoSwitch.reason = reason;
evTopoSwitch = evHistTopologySwitch.put(evTopoSwitch, actn);
}
private void evHistTopoLink(long srcDpid, long dstDpid, short srcPort,
short dstPort, int srcPortState, int dstPortState,
ILinkDiscovery.LinkType linkType,
EvAction actn, String reason) {
if (evTopoLink == null) {
evTopoLink = new EventHistoryTopologyLink();
}
evTopoLink.srcSwDpid = srcDpid;
evTopoLink.dstSwDpid = dstDpid;
evTopoLink.srcSwport = srcPort & 0xffff;
evTopoLink.dstSwport = dstPort & 0xffff;
evTopoLink.srcPortState = srcPortState;
evTopoLink.dstPortState = dstPortState;
evTopoLink.reason = reason;
switch (linkType) {
case DIRECT_LINK:
evTopoLink.linkType = "DIRECT_LINK";
break;
case MULTIHOP_LINK:
evTopoLink.linkType = "MULTIHOP_LINK";
break;
case TUNNEL:
evTopoLink.linkType = "TUNNEL";
break;
case INVALID_LINK:
default:
evTopoLink.linkType = "Unknown";
break;
}
evTopoLink = evHistTopologyLink.put(evTopoLink, actn);
}
public void evHistTopoCluster(long dpid, long clusterIdOld,
long clusterIdNew, EvAction action, String reason) {
if (evTopoCluster == null) {
evTopoCluster = new EventHistoryTopologyCluster();
}
evTopoCluster.dpid = dpid;
evTopoCluster.clusterIdOld = clusterIdOld;
evTopoCluster.clusterIdNew = clusterIdNew;
evTopoCluster.reason = reason;
evTopoCluster = evHistTopologyCluster.put(evTopoCluster, action);
}
@Override
public Map<String, Object> getInfo(String type) {
if (!"summary".equals(type)) return null;
Map<String, Object> info = new HashMap<String, Object>();
int num_links = 0;
for (Set<Link> links : switchLinks.values())
num_links += links.size();
info.put("# inter-switch links", num_links / 2);
return info;
}
// IHARoleListener
@Override
public void roleChanged(Role oldRole, Role newRole) {
switch(newRole) {
case MASTER:
if (oldRole == Role.SLAVE) {
if (log.isTraceEnabled()) {
log.trace("Sending LLDPs " +
"to HA change from SLAVE->MASTER");
}
clearAllLinks();
log.debug("Role Change to Master: Rescheduling discovery task.");
discoveryTask.reschedule(1, TimeUnit.MICROSECONDS);
}
break;
case SLAVE:
if (log.isTraceEnabled()) {
log.trace("Clearing links due to " +
"HA change to SLAVE");
}
switchLinks.clear();
links.clear();
portLinks.clear();
portBroadcastDomainLinks.clear();
discoverOnAllPorts();
break;
default:
break;
}
}
@Override
public void controllerNodeIPsChanged(
Map<String, String> curControllerNodeIPs,
Map<String, String> addedControllerNodeIPs,
Map<String, String> removedControllerNodeIPs) {
// ignore
}
public boolean isAutoPortFastFeature() {
return autoPortFastFeature;
}
public void setAutoPortFastFeature(boolean autoPortFastFeature) {
this.autoPortFastFeature = autoPortFastFeature;
}
}