WO2017167275A1 - 设置链路聚合组 - Google Patents
设置链路聚合组 Download PDFInfo
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- WO2017167275A1 WO2017167275A1 PCT/CN2017/079011 CN2017079011W WO2017167275A1 WO 2017167275 A1 WO2017167275 A1 WO 2017167275A1 CN 2017079011 W CN2017079011 W CN 2017079011W WO 2017167275 A1 WO2017167275 A1 WO 2017167275A1
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- port
- aggregation
- extended
- expander
- ports
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L45/00—Routing or path finding of packets in data switching networks
- H04L45/24—Multipath
- H04L45/245—Link aggregation, e.g. trunking
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L12/00—Data switching networks
- H04L12/28—Data switching networks characterised by path configuration, e.g. LAN [Local Area Networks] or WAN [Wide Area Networks]
- H04L12/46—Interconnection of networks
- H04L12/4604—LAN interconnection over a backbone network, e.g. Internet, Frame Relay
- H04L12/462—LAN interconnection over a bridge based backbone
- H04L12/4625—Single bridge functionality, e.g. connection of two networks over a single bridge
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L12/00—Data switching networks
- H04L12/28—Data switching networks characterised by path configuration, e.g. LAN [Local Area Networks] or WAN [Wide Area Networks]
- H04L12/46—Interconnection of networks
- H04L12/4641—Virtual LANs, VLANs, e.g. virtual private networks [VPN]
- H04L12/4645—Details on frame tagging
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L12/00—Data switching networks
- H04L12/28—Data switching networks characterised by path configuration, e.g. LAN [Local Area Networks] or WAN [Wide Area Networks]
- H04L12/46—Interconnection of networks
- H04L12/4641—Virtual LANs, VLANs, e.g. virtual private networks [VPN]
- H04L12/4675—Dynamic sharing of VLAN information amongst network nodes
- H04L12/4679—Arrangements for the registration or de-registration of VLAN attribute values, e.g. VLAN identifiers, port VLAN membership
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L45/00—Routing or path finding of packets in data switching networks
- H04L45/66—Layer 2 routing, e.g. in Ethernet based MAN's
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02D—CLIMATE CHANGE MITIGATION TECHNOLOGIES IN INFORMATION AND COMMUNICATION TECHNOLOGIES [ICT], I.E. INFORMATION AND COMMUNICATION TECHNOLOGIES AIMING AT THE REDUCTION OF THEIR OWN ENERGY USE
- Y02D30/00—Reducing energy consumption in communication networks
- Y02D30/50—Reducing energy consumption in communication networks in wire-line communication networks, e.g. low power modes or reduced link rate
Definitions
- the Extended Bridge is composed of a Control Bridge (CB) and a Port Extender (PE).
- the control bridge can be a single network device or be composed of multiple network devices.
- FIG. 1 is an example of a flow diagram of setting up a link aggregation group of the present disclosure.
- FIGS. 2A and 2B are diagrams showing an example of the structure of an extension bridge in which a link aggregation group of the present disclosure is set.
- 3A and 3B are diagrams showing an example of the structure of another extension bridge of the present invention for setting a link aggregation group.
- FIG. 4 is a diagram showing an example of the structure of an apparatus for setting a link aggregation group of the present disclosure.
- the term “comprising” means including but not limited to; the term “comprising” means including but not limited to; the term “based on” means at least a part thereof. Moreover, the term “a” is intended to mean one of the particular components.
- FIG. 1 is an example of a flow chart of setting a link group aggregation group of the present disclosure, and a control bridge and a port expander to which the example is applied constitute an extension bridge. As shown in Figure 1, the example includes:
- Step 101 Set a link aggregation group.
- Step 102 Associate the aggregation port of the link aggregation group with multiple expansion ports of the port expander; wherein the multiple expansion ports are connected to the same terminal;
- Step 103 Assign an aggregation port identifier to the aggregation port.
- Step 104 Associate an extended port identifier of each extended port of the multiple extended ports with a cascade port of the connection port expander to identify an uplink received by any of the plurality of extended ports.
- the entry port of the text into the extended bridge is an aggregation port;
- the aggregation port is associated with the aggregation port identifier and the cascade port, and is used to determine that the aggregation port identifier is added to the downlink unicast packet of the aggregation port of the extended bridge, and the transmission is determined by the cascade port.
- the downlink unicast packet of the aggregation port identifier is associated with the aggregation port identifier and the cascade port, and is used to determine that the aggregation port identifier is added to the downlink unicast packet of the aggregation port of the extended bridge, and the transmission is determined by the cascade port.
- the example shown in FIG. 1 can be applied to an extended bridge system, so that the port expander of the extended bridge can load the downlink packets sent to the terminal through the link aggregation group load, and can load and receive the uplink packets from the terminal. .
- port expanders 21 and 22 and control bridge 23 form an extension bridge 24.
- the upstream link port 21 - 1 of the port expander 21 and the cascade port 23-1 of the control bridge 23 are connected by a link.
- the uplink port 22-1 of the port expander 22 and the cascade port 23-2 of the control bridge 23 are connected by a link.
- the port expander 21 can transmit an extended port Create request message to the control bridge 23 for the extension ports 21-2-1 and 21-2-2, respectively.
- the port expander 21 may send the extended port setup request message to the control bridge 23 through the uplink port 21-1.
- the port expander 22 can transmit an extended port setup request message to the control bridge 23 for the extension ports 22-2 and 22-3, respectively. Port expander 22 can send these extended port setup request messages over uplink port 22-1.
- the control bridge 23 can receive the extended port setup request message from the port expander 21 through the cascade port 23-1, and can receive the extended port setup request message from the port expander 22 through the cascade port 23-2.
- the control bridge 23 can establish an E-channel for the expansion ports 21-2-1 and 21-2-2, respectively, and can be based on the port namespace of the cascade port 23-1 as the expansion ports 21-2-1 and 21 -2-2 allocates ECID-21-2-1 and ECID-21-2-2, respectively, for identifying the E-channels established for the expansion ports 21-2-1 and 21-2-2, respectively.
- the control bridge 23 can also set virtual ports VP21-2-1 and VP21-2-2 for the expansion ports 21-2-1 and 21-2-2, respectively, so that the expansion ports 21-2-1 and 21-2-2
- the virtual bridges VP21-2-1 and VP21-2-2 appear on the control bridge 23.
- the control bridge 23 can establish an E-channel for the expansion ports 22-2 and 22-3, respectively, and can assign the ECID-22-2 to the expansion ports 22-2 and 22-3 according to the port namespace of the cascade port 23-2. And ECID-22-3, which are used to identify the E-channels established for the expansion ports 22-2 and 22-3, respectively.
- Control bridge 23 may also set virtual ports VP22-2 and VP22-3 for expansion ports 22-2 and 22-3 such that expansion ports 22-2 and 22-3 appear as virtual ports VP22-2 at control bridge 23, respectively. And VP22-3.
- the control bridge 23 can record the ECID, the cascade port, and the virtual port associated with the ECID and the cascade port in the upstream table. For example, as shown in Table 1-1:
- Control bridge 23 can record each virtual port and its associated ECID and cascade port in the downstream table, as shown in Table 2-1:
- the control bridge 23 can send an Extended Port Create Response message through the cascade port 23-1, respectively notifying the port expander 21 of the ECID-21-2-1 assigned to the expansion port 21-2-1 and Expansion port 21-2-2 assigned ECID-21-2-2.
- the control bridge 23 can transmit an extended port setup response message through the cascade port 23-2, notifying the port expander 22 of the ECID-22-2 assigned to the extension port 22-2 and the ECID-22- assigned to the extension port 22-3.
- the port expander 21 receives the extended port setup response message, and records the extended port and its associated ECID in the uplink table shown in Table 3-1, and records the ECID and its associated extension in the downlink table shown in Table 4-1. port.
- the port expander 22 receives the extended port setup response message, and records each extended port and its associated ECID in the uplink table shown in Table 5-1, and records each ECID in the downlink table shown in Table 6-1. Associated expansion port.
- the control bridge 23 can control the expansion port 21-2-1 of the port expander 21 and the extension port 21-2-2 to establish a link connection with the terminal 25, and can control the expansion port 22-2 and the terminal of the port expander 22.
- a link connection is established between 26, and a link connection between the extension port 22-3 of the port expander 22 and the terminal 27 can be controlled.
- the control bridge 23 can set the link aggregation group 21-2, set the aggregation port LAG21-2 of the link aggregation group 21-2, and associate the aggregation port LAG21-2 with the extension port 21-2-1 and the extension port 21-2- 2.
- the expansion port 21-2-1 and the expansion port 21-2-1 are set as the two member ports of the aggregation port LAG21-2.
- the control bridge 23 can set the virtual port VP21-2 for the aggregation port LAG21-2, so that the aggregation port LAG21-2 can behave as the virtual port VP21-2 on the control bridge 23.
- Control bridge 23 can establish an E-channel for aggregation port LAG21-2.
- the control bridge 23 can allocate an ECID-21-2 to the aggregation port LAG21-2 according to the port namespace of the cascade port 23-1 for identifying the E-channel established for the aggregation port LAG21-2.
- the control bridge 23 can replace the virtual port VP21-2-1 associated with the ECID-21-2-1 and the cascade port 23-1 in the upstream table with the virtual port VP21-2, ECID-21-2-2 and cascading.
- the virtual port VP21-2-2 associated with port 23-1 is replaced with the virtual port VP21-2, as shown in Table 1-2.
- the control bridge 22 can be associated with the virtual port VP21-2 through the ECID-21-2-1 and the cascade port 23-1 in the upstream table shown in Table 1-2, and the ECID-21-2-1 and the cascade port 23 -1 is associated with the aggregation port LAG21-2, and the ingress port for identifying the uplink packet received through the extension port 21-2-1 to enter the extension bridge 24 is the aggregation port LAG21-2.
- the control bridge 22 can be associated with the virtual port VP21-2 through the ECID-21-2-2 and the cascade port 23-1 recorded in the upstream table shown in Table 1-2, and the ECID-21-2-2 and the level
- the port 23-1 is associated with the aggregation port LAG21-2, and the ingress port for identifying the uplink packet received through the extension port 21-2-2 to enter the extension bridge 24 is the aggregation port LAG21-2.
- the control bridge 23 can record the virtual port VP21-2 and its associated ECID-21-2 and the cascade port 23-1 in the downstream table, as shown in Table 2-2:
- the control bridge 22 is configured to associate the virtual port VP21-2 with the ECID-21-2 and the cascading port 23-1 to determine that the egress port leaving the extension bridge 24 is a downlink unicast packet of the aggregation port LAG21-2. ECID-21-2 and decided to pass The cascading port 23-1 transmits a downlink unicast packet to which the ECID-21-2 is added.
- the control bridge 23 can send a port extender control and status protocol (PE CSP) message to the port expander 21; wherein the type-length-value (TLV) field of the PE CSP message can be carried
- PE CSP port extender control and status protocol
- TLV type-length-value
- the port expander 21 can record the ECID-21-2 and its associated aggregation port LAG21-2 in the downlink table, as shown in Table 4-2.
- the port expander 21 associates the ECID-21-2 with the aggregation port LAG21-2 to determine that the egress port carrying the ECID21-2 leaving the extended bridge 24 is the aggregation port LAG21-2.
- the port expander 21 can record the aggregation port LAG21-2 and its associated extension ports 21-2-1 and 21-2-2 in the aggregation port table shown in Table 7.
- the port expander 21 can determine the member ports associated with each aggregate port according to the aggregated port table.
- the port expander 21 may select one of the extended port 21-2-1 and the extended port 21-2-2 for the downlink unicast packet whose outgoing port of the extended bridge 24 is the aggregated port LAG21-2 according to the aggregated port table. Send a downlink unicast packet.
- control bridge 23 sets the two physical links of the port expander 21 to the terminal 25 as the link aggregation group 21-2, improving the reliability of the link between the port expander 21 and the terminal 25.
- the terminal 25 can select a connection extension port from the two links connecting the port expander 21 based on the load sharing algorithm.
- the 21-2-1 link sends Ethernet broadcast packets.
- the port expander 21 receives the Ethernet broadcast packet through the extension port 21-2-1, and inserts the extended port virtual local area network identifier (VID, Extended Port VLAN ID) into the Ethernet broadcast message to the ECID-21-2-1.
- VIP Extended Port VLAN ID
- the virtual VLAN tag (ETAG, Extension VLAN Tag) is extended and sent through the uplink port 21-1.
- the control bridge 23 can receive the Ethernet broadcast message with the ETAG through the cascade port 23-1, based on the ECID-21-2-1 and the cascade port 23-1 in the uplink table (Table 1-2)
- the virtual port VP21-2 is found, and it is determined that the aggregation port LAG21-2 is an ingress port of the Ethernet broadcast packet entering the extension bridge 24.
- the control bridge 23 can learn the MAC address entry according to the source MAC address of the Ethernet broadcast message, the VLAN, and the virtual port VP21-2. Control bridge 23 replicates Ethernet broadcast messages.
- the control bridge 23 can set the source extended port VLAN ID (SVID, Source Extended Port VLAN ID) of the ETAG carried in a duplicate Ethernet broadcast message to ECID-21-2, and replace the VID of the ETAG. To broadcast the ECID, it is sent through the cascade port 23-1.
- the link aggregation group 21-2 of the port expander 21 is connected to the terminal 25, and the control bridge 23 determines that the inbound interface is the aggregation port LAG21-2 according to the VID of the uplink Ethernet broadcast message.
- control bridge 23 sets the ECID 21-2 of the aggregation port LAG21-2 in the SVID of the downlink Ethernet broadcast packet, and prevents the port expander 21 from transmitting the downlink broadcast packet from the terminal 25 through the link aggregation group 21-2. .
- the control bridge 23 can set the VID of the ETAG of a duplicate Ethernet broadcast message to the broadcast ECID and transmit it through the cascade port 23-2.
- the control bridge 23 allocates ECID-21-2 to the aggregation port LAG21-2 according to the port namespace, and does not need to uplink Ethernet when the uplink Ethernet broadcast packet received by one cascade port is sent through another cascade port.
- the VID of the ETAG of the broadcast message is copied to the SVID of the ETAG of the downlink Ethernet broadcast message.
- the control bridge 23 can also allocate an ECID to the aggregation port LAG21-2 according to the global namespace, so that when the control bridge transmits an uplink Ethernet broadcast message received by one cascade port through another cascade port, the uplink Ethernet will be used.
- the VID of the ETAG of the broadcast message is copied to the SVID of the ETAG of the downlink Ethernet broadcast message.
- the port expander 21 finds that the port list of the broadcast ECID includes the aggregation port LAG21-2, and determines that the ECID-21-2 of the SVID corresponds to the aggregation port LAG21-2 of the port list of the broadcast ECID, and does not transmit the broadcast through the aggregation port LAG21-2. Message.
- the port list that the port expander 22 finds to broadcast the ECID includes the expansion port 22-2 and the expansion port 22-3.
- the port expander removes the ETAG of the received Ethernet broadcast packet and copies the Ethernet broadcast packet through the expansion port 22-2.
- And 22-3 send an Ethernet broadcast message, so that the terminals 26 and 27 respectively receive the Ethernet broadcast message.
- the terminal 27 transmits an Ethernet broadcast message.
- the port expander 22 receives the Ethernet broadcast message through the extension port 22-2, based on the ECID-22-2 associated with the extension port 22-2 in the uplink table (as shown in Table 5-1), in the Ethernet broadcast report.
- the ETAG of the VID is ECID-22-2 is inserted into the text and sent through the uplink port 22-1.
- the control bridge 23 can receive the Ethernet broadcast message with the ETAG through the cascade port 23-2, and look up in the uplink table (as shown in Table 1-2) based on the ECID-22-2 and the cascade port 23-2. To the virtual port VP22-2, the MAC address entry is determined according to the source MAC address of the Ethernet broadcast message, the VLAN, and the virtual port VP22-2. Control bridge 23 replicates Ethernet broadcast messages. The control bridge 23 can copy the ECID-22-2 of the VID of the ETAG of a duplicate Ethernet broadcast message to the SVID, replace the VID of the ETAG with the broadcast ECID, and transmit it through the cascade port 23-2. In the present disclosure, the control bridge 23 determines that the ECID-22-2 is the ECID of a single extended port, and can directly copy the ECID-22 of the VID to the SVID to prevent the Ethernet broadcast message from being sent back to the terminal 27.
- the control bridge 23 can set the VID of the ETAG of a duplicate Ethernet broadcast message to the broadcast ECID and transmit it through the cascade port 23-1.
- the VID of the ETAG of the Ethernet broadcast message received by the port expander 22 through the uplink port 22-1 is the broadcast ECID, and the port list for finding the broadcast ECID includes the extended port 22-2 and the extended port 22-3.
- the port expander 21 may determine that the ECID-22-2 of the SVID corresponds to the expansion port 22-2 included in the port list of the broadcast ECID.
- the port expander 22 can remove the ETAG, transmit an Ethernet broadcast message through the expansion port 22-2, and broadcast the Ethernet broadcast message to the terminal 26.
- the VID of the ETAG of the Ethernet broadcast message received by the port expander 21 through the uplink port 21-1 is the broadcast ECID, and the port list of the broadcast ECID is found to include the LAG 21-2.
- the port expander 21 removes the ETAG, and selects the extension port 21-2-2 from the extension ports 21-2-1 and 21-2-2 associated with the aggregation port LAG21-2 shown in Table 7 based on the load sharing algorithm, by expanding
- the port 21-2-2 transmits an Ethernet broadcast message and transmits the Ethernet broadcast message to the terminal 25.
- the foregoing Ethernet broadcast packet can be a data packet or a protocol packet, such as an ARP request packet.
- the terminal 27 transmits an Ethernet unicast message to the terminal 25, wherein the source MAC address is the MAC address MAC27 of the terminal 27, and the destination MAC address is the MAC address MAC 25 of the terminal 25.
- the port expander 22 can receive the Ethernet unicast packet through the extended port 22-2, and finds the ECID-22-2 in the uplink table (as shown in Table 5-1) based on the extended port 22-2, in the Ethernet unicast report.
- the ETAG with the VID being the ECID-22-2 is inserted, and the ETAG-enabled packet is sent through the uplink port 22-1.
- the control bridge 23 can receive the Ethernet unicast packet with the ETAG through the cascade port 23-2, and find the matching virtual port VP21-2 based on the destination MAC address MAC 25 and the VLAN in the received packet, that is, virtual Port VP21-2
- the associated aggregation port LAG21-2 is an egress port.
- the control bridge 23 can find the ECID-21-2 and the cascade port 23-1 in the downlink table (as shown in Table 2-2) according to the virtual port VP21-2, and determine that the egress port is the aggregation port LAG21-2. Adding ECID-21-2 to the Ethernet unicast packet and determining to send the Ethernet unicast packet with ECID-21-2 added through the cascade port 23-1. The control bridge 23 modifies the VID of the port indicated in the ETAG of the Ethernet unicast packet to ECID-21-2, and transmits it through the cascade port 23-1.
- the VID of the ETAG of the Ethernet unicast packet received by the port expander 21 through the uplink port 21-1 is ECID-21-2, and the LAG21 is found in the downlink table (as shown in Table 4-2) based on the ECID-21-2. -2.
- the port expander 21 can remove the ETAG, and selects the extended port 21-2-1 from the expansion ports 21-2-1 and 21-2-2 associated with the aggregation port LAG21-2 (as shown in Table 7) based on the load sharing algorithm.
- the Ethernet unicast message is transmitted to the terminal 25 through the extension port 21-2-1.
- the Ethernet unicast packet can be either a data packet or a protocol packet, such as an ARP response packet.
- the control bridge 23 can find the virtual port VP21-2 according to the destination MAC address of the Ethernet unicast packet received from the external Layer 2 network, and send the downlink through the cascade port 23-1.
- Ethernet unicast packet, where the VID of the ETAG is ECID-21-2, and the port expander 21 can send the downlink Ethernet unicast packet through the link aggregation group 21-2.
- the control bridge 23 can implement load balancing by setting the link aggregation group 21-2 to enable the uplink packet sent by the terminal 25 to the port expander 21 and the downlink packet sent by the port expander 21 to the terminal 25.
- the uplink packet includes unicast packets and non-unicast packets that enter the extended bridge 24 through the port expander 21 or 22; the downlink packet includes the extension through the port expander 21 or 22. Unicast and non-unicast packets of bridge 24.
- network devices 341 and 342 can form a stacking device 34 through stacking links.
- Network devices 341 and 342 can perform master device elections, and network device 342 can be elected as the master device of stack device 34.
- the stacking device 34 operates as a control bridge 34.
- the port expanders 31 to 33 and the control bridge 34 constitute an extension bridge 35.
- the uplink port of the port expander 31 and the cascade port of the network device 341 can be connected by a link; the uplink port of the port expander 32 and a cascade port of the network device 342 can be connected by a link.
- the uplink port of the port expander 33 and the other cascade port of the network device 342 can be connected by a link.
- the port expander 31 can transmit an extension port setup request message to the control bridge 34 for the extension ports 31-2-1, 31-2-2, and 31-2-3, respectively.
- the port expander 31 can send these extended port setup request messages to the network device 341 through the uplink port.
- Network device 341 can send an extended port setup request message to network device 342 over the stacking link.
- the network device 342 can receive the extended port setup request message from the port expander 31 through the stack link, for these three The expansion ports 31-2-1, 31-2-2, and 31-2-3 respectively establish an E-channel, and the three port extensions are assigned ECID-31 according to the port naming space of the cascade port of the network device 341. 2-1, ECID-31-2-2 and ECID-31-2-3, are used to identify the E-channels established for each of the extension ports 31-2-1, 31-2-2, and 31-2-3.
- the control bridge 34 can set virtual ports for the expansion ports 31-2-1, 31-2-2, and 31-2-3, respectively, so that the expansion ports 31-2-1, 31-2-2, and 31-2-3 These virtual ports are represented on the control bridge 34.
- Control bridge 34 may send an extended port setup response message to port expander 31 informing port expander 31 of the ECIDs assigned to the three extended ports 31-2-1, 31-2-2, and 31-2-3.
- Network device 342 can transmit these extended port setup response messages over a stacking link, and network device 341 can send these extended port setup response messages over the cascaded port.
- the port expander 31 can receive these extended port setup response messages through the uplink port.
- the network device 342 can receive the extended port setup request messages from the port expanders 32 and 33, respectively, through the two cascade ports, and the extended port setup response messages can be sent to the port expanders 32 and 33, respectively, through the cascade ports.
- the way in which the control bridge 34 establishes an expansion port for the port expanders 32 and 33 is the same and will not be described in detail herein.
- the control bridge 34 can control the expansion port 31-2-1 of the port expander 31, the extension port 31-2-2, and the extension port 31-2-3 to establish a link with the terminal 36.
- terminal 36 can be a server running a virtual machine.
- the control bridge 34 can set the link aggregation group 31-2, set the aggregation port LAG31-2 of the link aggregation group 31-2, and associate the aggregation port LAG31-2 with the extension port 31-2-1, the extension port 31-2- 2.
- the expansion port 31-2-3 that is, the three member ports of the aggregation port LAG31-2, sets the virtual port of the aggregation port LAG31-2, so that the aggregation port LAG31-2 appears as a virtual port on the control bridge 34.
- Control bridge 34 can establish an E-channel for aggregation port LAG31-2.
- the control bridge 34 allocates an ECID-31-2 to the aggregation port LAG31-2 according to the port namespace of the cascade port of the network device 341, and is used to identify the E-channel established for the aggregation port LAG31-2.
- the control bridge 34 can send a PE CSP packet to the port expander 34.
- the TLV field of the PE CSP packet carries the aggregation port LAG31-2, the ECID-31-2 of the aggregation port LAG31-2, and the aggregation port LAG31-2.
- the port expander 31 records the correspondence between the aggregation port LAG31-2 and the extension port 31-2-1, the extension port 31-2-2, and the extension port 31-2-3, and is used to determine the member of the aggregation port LAG31-2. port.
- control bridge 34 sets the three physical links of the port expander 31 to the terminal 36 as the link aggregation group 31-2, improving the reliability of the link between the port expander 31 and the terminal 36. .
- the port expander 31 When the port expander 31 detects the fault of the extended port 31-2-2, it can send a PE CSP message to the control bridge 34, wherein the T-L-V field of the PE CSP message carries the ECID-31-2-2 and the fault indication information.
- the control bridge 34 receives the PE CSP packet that informs the extension port 31-2-2 of the failure, and can send a PE CSP message to the port expander 31 to notify the deletion of the association relationship, wherein the TLV field carries the ECID-31-2 and ECID 31-2-2, and instructions for deleting the association.
- the control bridge 34 receives the PE CSP message indicating that the association relationship is deleted, and the extension port 31-2-2 can be deleted from the three extension ports corresponding to the aggregation port LAG31-2 associated with the ECID-31-2.
- the control bridge 34 can reserve the E-channel and ECID-31-2-2 set for the extension port 31-2-2, and can avoid repeatedly setting the E-channel and ECID when the expansion port 31-2-2 is restored. Alternatively, the control bridge 34 deletes the E-channel and ECID-31-2-2 set for the extension port 31-2-2.
- the port expander 31 detects the expansion port 31-2-2 recovery and can transmit an extended port setup message.
- the control bridge 34 can notify the port expander 31 of these reserved E-channels and ECIDs by extending the port establishment response message.
- the port expander 31 may set an E-channel for the extension port 31-2-2, assign an ECID, and set a virtual port.
- Control bridge 34 may establish a response message through the expansion port informing port expander 31 to retain the ECID or the reassigned ECID.
- Control bridge 34 can control the establishment of a link connection between expansion port 31-2-2 and terminal 36.
- the control bridge 34 determines to associate the aggregation port LAG31-2 with the extension ports 31-2-1, 31-2-2, and 31-2-3 to transmit the PE CSP message.
- the TLV field of the PE CSP packet carries the aggregation port LAG31-2, the ECID-31-2 of the aggregation port LAG31-2, and the extension port 31-2-1 and the extension port 31-2- associated with the aggregation port LAG31-2. 2. Expansion port 31-2-3.
- the port expander 31 receives the PE CSP packet of the link aggregation group 31-2, and the member ports of the aggregation port LAG31-2 include the extension port 31-2-1, the extension port 31-2-2, and the extension port 31-. 2-3.
- the manner in which the control bridge 34 sends the downlink Ethernet broadcast packet and the downlink Ethernet unicast packet is the same as the manner in which the control bridge 23 transmits the downlink Ethernet broadcast packet and the downlink Ethernet unicast packet in FIG. 2B.
- the port expander 31 sends the downlink packet and the uplink packet, and the port expander 21 in FIG. 2B sends the downlink packet, such as the downlink Ethernet broadcast packet, the downlink Ethernet unicast packet, and the uplink packet, such as the uplink Ethernet.
- the broadcast packet is the same as the upstream Ethernet unicast packet. It will not be described in detail here.
- the link aggregation group 31-2 in FIG. 3B improves the reliability of the link between the port expander 31 and the terminal 36.
- the uplink packet sent by the terminal 36 to the port expander 31 and the port expander 31 are sent to the terminal 36. Load balancing can be implemented in downlink packets.
- FIG. 4 shows an example block diagram of control bridge 40.
- the control bridge 40 can include a processor 401, a non-transitory storage medium 402, a communication interface 403, and an engagement mechanism 404 that engages the processor 401, the non-transitory storage medium 402, and the communication interface 403.
- a plurality of machine executable instruction modules executed by the processor 401 are stored in the non-transitory storage medium 402.
- the machine executable instruction module may include a receiving module 410, a setting module 420, an assigning module 430, and a notification module 440.
- Setting module 420 setting a link aggregation group, associating the aggregation port of the link aggregation group with multiple extensions of the port expander Port; where multiple expansion ports are connected to the same terminal.
- An allocation module 430 assigning an aggregation port identifier to the aggregation port; associating an expansion port identifier of each expansion port of the plurality of expansion ports with a cascade port of the connection port expander to identify the plurality of expansion ports
- the inbound port of the uplink packet received by any of the extended ports is an aggregation port; the aggregation port is associated with the aggregation port identifier and the cascade port to determine that the egress port leaving the extension bridge is an aggregation port.
- the notification module 440 notifies the port expander of the aggregated port and the aggregated port identifier; and notifies the port expander of the plurality of extended ports associated with the aggregated port.
- the receiving module 410 receives a request for establishing a plurality of extended ports sent by the port expander.
- the distribution module 430 assigns an expansion port identifier to each of the plurality of expansion ports.
- the notification module 440 notifies the port expander of the extension port identifier assigned to each expansion port.
- the receiving module 410 receives the failure notification sent by the port expander.
- the distribution module 430 determines that the faulty extended port indicated by the fault notification is one of the plurality of extended ports, and deletes the extended port identifier of the faulty extended port and the association of the cascaded port of the connected port expander with the aggregated port.
- the notification module 440 notifies the port expander to delete the association between the aggregation port and the faulty expansion port.
Abstract
Description
关键字(Key) | 结果值(Value) |
21-2-1 | ECID-21-2-1 |
21-2-2 | ECID-21-2-2 |
关键字(Key) | 结果值(Value) |
ECID-21-2-1 | 21-2-1 |
ECID-21-2-2 | 21-2-2 |
关键字(Key) | 结果值(Value) |
22-2 | ECID-22-2 |
22-3 | ECID-22-3 |
关键字(Key) | 结果值(Value) |
ECID-22-2 | 22-2 |
ECID-22-3 | 22-3 |
关键字(Key) | 结果值(Value) |
ECID-21-2-1 | 21-2-1 |
ECID-21-2-2 | 21-2-2 |
ECID-21-2 | LAG21-2 |
关键字(Key) | 结果值(Value) |
LAG21-2 | 21-2-1,21-2-2 |
Claims (12)
- 一种设置链路聚合组方法,该方法应用于控制网桥,该控制网桥与端口扩展器构成扩展网桥;其中,所述方法包括:设置链路聚合组;将所述链路聚合组的聚合端口关联于端口扩展器的多个扩展端口;其中,所述多个扩展端口连接同一个终端;为所述聚合端口分配聚合端口标识符;将所述多个扩展端口的每个扩展端口的扩展端口标示符和连接所述端口扩展器的级联端口关联于所述聚合端口,用以识别通过所述多个扩展端口的任一扩展端口接收的上行报文进入所述扩展网桥的入端口是所述聚合端口;将所述聚合端口关联于所述聚合端口标示符和所述级联端口,用以决定为离开扩展网桥的出端口是所述聚合端口的下行单播报文添加所述聚合端口标识符以及决定通过所述级联端口发送添加了聚合端口标示符的所述下行单播报文。
- 根据权利要求1所述的方法,其中,所述方法还包括:将所述聚合端口以及所述聚合端口标识符通知所述端口扩展器;将所述聚合端口关联的多个所述扩展端口通知所述端口扩展器。
- 根据权利要求1所述的方法,其中,在设置链路聚合组之前,所述方法还包括:接收所述端口扩展器发送的建立所述多个扩展端口的请求;为所述多个扩展端口的每个扩展端口分配扩展端口标识符;将每个所述扩展端口及其被分配的所述扩展端口标示符通知所述端口扩展器。
- 根据权利要求1所述的方法,其中,所述方法还包括:接收所述端口扩展器发送的故障通知;确定所述故障通知指示的故障扩展端口是所述多个扩展端口的一个;删除所述故障扩展端口的扩展端口标示符和连接所述端口扩展器的级联端口与所述聚合端口的关联;通知所述端口扩展器删除所述聚合端口与所述故障扩展端口的关联。
- 一种设置链路聚合组的装置,所述装置应用于控制网桥,该控制网桥与端口扩展器构成扩展网桥,其中,所述装置包括:设置模块,设置链路聚合组,将所述链路聚合组的聚合端口关联于所述端口扩展器的多个扩展端口;其中,所述多个扩展端口连接同一个终端;分配模块;为所述聚合端口分配聚合端口标识符;将所述多个扩展端口的每个扩展端口的扩展端口标示符和连接所述端口扩展器的级联端口关联于所述聚合端口,用以识别通过所述多个扩展端口的任一扩展端口接收的上行报文进入所述扩展网桥的入端口是所述聚合端口;将所述聚合端口关联于所述聚合端口标示符和所述级联端口,用以决定为离开扩展网桥的出端口是所述聚合端口的下行单播报文添加所述聚合端口标识符以及决定通过所述级联端口发送添加了聚合端口标示符的所述下行单播报文。
- 根据权利要求5的装置,其中,所述装置还包括:通知模块,将所述聚合端口以及所述聚合端口标识符通知所述端口扩展器;将所述聚合端口关联的多个所述扩展端口通知所述端口扩展器。
- 根据权利要求5的装置,其中,所述装置还包括:接收模块,接收所述端口扩展器发送的建立所述多个扩展端口的请求;所述分配模块,为所述多个扩展端口的每个扩展端口分配所述扩展端口标识符;所述通知模块,将每个所述扩展端口及其被分配的所述扩展端口标示符通知所述端口扩展器。
- 根据权利要求5的装置,其中,所述接收模块,接收所述端口扩展器发送的故障通知;所述分配模块,确定所述故障通知指示的故障扩展端口是所述多个扩展端口中的一个,删除所述故障扩展端口的扩展端口标示符和连接所述端口扩展器的级联端口与所述聚合端口的关联;所述通知模块,通知所述端口扩展器删除所述聚合端口与所述故障扩展端口的关联。
- 一种扩展网桥系统,该扩展网桥系统中控制网桥的级联端口与端口扩展器的上行端口连接,其中,所述端口扩展器的多个扩展端口连接同一个终端;所述控制网桥设置链路聚合组,将所述链路聚合组的聚合端口关联于所述多个扩展端口;为所述聚合端口分配聚合端口标识符;将所述多个扩展端口的每个扩展端口的扩展端口标示符和连接所述端口扩展器的级联端口关联于所述聚合端口,用以识别通过所述多个扩展端口的任一扩展端口接收的上行报文进入所述扩展网桥的入端口是所述聚合端口;将所述聚合端口关联于所述聚合端口标示符和所述级联端口,用以决定为离开扩展网桥的出端口是所述聚合端口的下行单播报文添加所述聚合端口标识符以及决定通过所述级联端口发送添加了聚合端口标示符的所述下行单播报文。
- 根据权利要求9所述的系统,其中,所述控制网桥将所述聚合端口以及所述聚合端口标识符,所述聚合端口关联的所述多个扩展端口通知给所述端口扩展器;所述端口扩展器记录所述聚合端口标识符与所述聚合端口的关联,用以决定携带所述聚合端口标示符的所述下行单播报文的所述出端口是所述聚合端口;所述端口扩展器记录所述多个扩展端口是所述聚合端口的成员端口,用以为离开所述扩展网桥的出端口是所述聚合端口的所述下行单播报文选择所述多个扩展端口中的选择一个用于发送所述下行单播报文以及用以为离开所述扩展网桥的出端口是所述聚合端口的下行非单播报文从所述多个扩展端口中选择一个用于发送所述下行非单播报文。
- 根据权利要求9所述的系统,其中,所述端口扩展器向所述控制网桥发送建立所述多个扩展端口的请求;所述控制网桥接收建立所述多个扩展端口的请求,为所述多个扩展端口的每个扩展端口分配扩展端口标识符;将每个所述扩展端口及其被分配的所述扩展端口标示符通知所述端口扩展器;所述端口扩展器接收每个所述扩展端口及其被分配的所述扩展端口标示符,记录每个所述扩展端口及其被分配的所述扩展端口标示符,用以决定为每个所述扩展端口接收的上行报文添加其被分配的所述扩展端口标示符。
- 根据权利要求9所述的系统,其中,所述端口扩展器发送故障通知;所述控制网桥接收所述故障通知,确定所述故障通知指示的故障扩展端口是所述多个扩展端口中的一个,删除故障扩展端口的扩展端口标示符和连接所述端口扩展器的级联端口与所述聚合端口的关联,通知所述端口扩展器删除所述聚合端口与所述故障扩展端口的关联;所述端口扩展器将所述故障扩展端口从所述聚合端口的成员端口中删除,以删除所述聚合端口与所述故障扩展端口的关联。
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