EP1842343A1

EP1842343A1 - Method for determining the routing direction of ethernet frames

Info

Publication number: EP1842343A1
Application number: EP06700604A
Authority: EP
Inventors: Torsten Langguth
Original assignee: Nokia Siemens Networks GmbH and Co KG
Current assignee: Nokia Solutions and Networks GmbH and Co KG
Priority date: 2005-01-18
Filing date: 2006-01-03
Publication date: 2007-10-10
Also published as: CN101147367A; WO2006077173A1; DE102005002358A1; US20080304480A1; KR20070103435A

Abstract

The invention relates to a method for determining the routing direction of Ethernet frames in order to route them to a destination, e.g. a computer, by means of Ethernet switches, according to which a frame is received by a first switch (Sl). The first switch (Sl) determines that the source address of the frames is not a destination address that has been registered in the switch (Sl) for the routing of frames. The source address is registered by the first switch (Sl) as a new destination address (X) for the routing of frames. The first switch (Sl) then communicates the new destination address (X) to a second Ethernet switch (S2, S3) and when the destination address (X) has been received, the second switch (S2, S3) defines a routing direction for the frames to the new destination in the destination address (X).

Description

description

Method for determining the forwarding direction of Ethernet frames

The invention relates to a method for determining the forwarding direction of Ethernet frames for their forwarding to a destination and adapted for the implementation of such a method most Ethernet switch.

At present, Ethernet technology, which is commonly used in local area networks (LANs), is being developed further for use in metro networks. In order to be able to realize the quality of the networks required for desired services, efforts are being made in the further development of Ethernet networks prior to a training. high availability (fail-safe) necessary. Since metro networks often use RJLnog- pologies (loops), and simple loops are very susceptible to faults - a cable break or a loose plug usually leads to failure or overloading of the network - high availability must also be provided in ring architectures be .

For the high availability of particular interest is the mechanism for determining the forwarding direction in Ethernet switches. A switch examines each passing frame - sometimes the terms frame and packet instead of frame in the literature - on the destination MAC address (MAC: Media Access Control) and forwards it directly in the appropriate direction. This is generally a

Self-learning mechanism used, which extracts the source address in all incoming frames. Traffic to a gelern ^¬ th Adres se is usually sent on the port where the frame from which the source address is extracted, is dripped einge-. If no forwarding information is available, flooding usually takes place; H . the frame is on gesen- al ^¬ len belonging to the corresponding network segment ports det. This makes network dimensioning, traffic engineering and compliance with quality of service difficult.

One known method used in Ethernet networks is the pending tree protocol (STP) method. It allows ei ^¬ ne timer controlled switching of an Ethernet switch to another port in the forwarding of frames, but can only achieve relatively large switching times / interruption of about 30-45 seconds at a recommended and 8-12 seconds with optimized configuration. In addition, avoiding loops in the STP method relies on port blocking. Therefore, the com ^¬ plete network capacity is not available in normal operation.

With the RTSP (Rapid Spanning Tree Protocol) interrup can ^¬ monitoring times are shortened. The interruption time depends on the network size. In addition, flooding is usually carried out immediately after the troubleshooting, which can lead to a violation of the quality of service.

Ring-based loop-avoidance techniques such as EAPS (Ethernet Automatic P-Rotation Switching), RRSTP (Riverstone's Rapid Spanning T_ree) or patented methods by Siemens AG (DE 10 004 432) and Siemens AG / Hirschmann (DE 298 20 587) are also known , In these methods, the loop in the ring in a privileged switch, optionally called redundancy manager or master, is broken by blocking a line.

Through regular signaling messages, the consistency of the ring is checked and possibly. the blocked port reopens. In addition to this error detection, the other switches can report errors and perform a local switchover. However, in these methods, a ring structure is necessary, which is not always assumed in metronets ^¬ who can. In addition, here also occurs the previously described flooding after the interruption. Therefore, a corresponding quality of service in conjunction with high availability can not be guaranteed. Due to the port blocking, the full network capacity is also not available in normal operation.

All previously presented methods have in common that due to the port blocking in normal operation, a distribution of the network load is not possible. New procedures from Nortel Networks (MLT, MuIti L_ine T ^ runcking) and 3COM (XRN, Expandable Resilient Networking) avoid this problem by constantly changing the complete forwarding database (FDB) between the switches. Of course, this exchange leads to a significantly higher network load. Moreover, due to the pairwise design, these methods are only conditionally suitable for access topologies.

It is an object of the invention to determine a forwarding direction of Ethernet frames for forwarding them to a destination while avoiding the disadvantages of conventional methods.

The object is achieved by a method having the features of patent claim 1. Advantageous further ^¬ formations of the present invention will become apparent from the dependent claims.

To achieve the object, a method for determining the forwarding direction of Ethernet frames for their forwarding to a destination, eg. B. a terminal, presented by means of Ethernet switches, wherein a frame is received by a first switch. The first switch notes that the Ur ^¬ jump address of the frame not registered in the switch destination ^¬ address for forwarding of frames is. The Ur ^¬ jump address is used as a new destination for the further line of frames in the first switch registered. The first switch communicates the new destination address to a second Ethernet switch and checks for the arrival of the destination address. se from the second switch for the forwarding of frames to the specified by the new Zieladres se destination a forwarding direction set.

This method is usually used in a network, e.g. B. a metro network running. The network includes z. B. a plurality of Ethernet switches. The first switch is then the switch of the network from which the frame is first received. Such a switch usually has at least one edge port, i. H . a port where no information from other switches of the network arrives. The first switch can detect by the arrival of the frame at this port that it is the first switch of the network from which the frame is received. The second switch can also communicate the new destination address to another Ethernet switch or. communicate. The new destination is determined by the message je ^¬ Weils of a neighbor switch, z. B. by means of bridge frames, communicated to all the switches of the network except the first switch. A bridge frame is a frame which is sent between the two switches and information, for example, about the destination address of the frame to be determined or a forwarding direction. the address of a switch implies. This then has a similar function to the configuration BPDUs defined in IEEE Standard 802.1 (Bridge P_rotocol .Data Units_). On the arrival of the destination address in a switch towards the network for the transmission of frames is set to the given by the new destination address a target Weiterlei ^¬ power direction of the switches and the destination address to the neighbor's witche communicates.

Since in the course of the network topology, a switch can have multiple witche neighbor's, the new destination is often the net more than one message with the Zielad ^¬ ress from a switch received during propagation. This switch can then register a plurality of forwarding directions and evaluate them in accordance with metric information. For this purpose, when communicating to a neighbor switch Metric information and / or address information related to the first switch, e.g. B. Ethernet address with the destination address ^¬ communicate together. For a determination of a forwarding direction by a switch, which receives a bridge frame, there are then z. B. following two Vorgehenswei ^¬ sen:

® The bridge package contains the destination address and a met ^¬ rikinformation. The switch then registers the direction from which the bridge frame was obtained, as a forwarding direction, which is evaluated by means of Metrikinforma ^¬ tion.

® The Bridge package contains the destination address and the Ad ^¬ ress of the first switches. If the switch is aware of the topology of the network, then the optimal path in terms of the metric and possibly Substitute paths are determined and the associated forwarding direction is registered. Although this procedure places higher demands on the switch, it has the advantage that optimal paths can be determined when a bridge packet arrives. Further, the same addresses communi ^¬ zierende bridge packets can then be discarded.

Each switch can provide a forwarding database for registering multiple forwarding directions. This allows a fast local switching of the forward ^¬ line direction of a frame in case of failure in a switch, as alternative ways to forward the frame are available. The metric information may relate to hop counts and / or transmission costs for transmission between switches of the network. Thus, based on the metric information, an optimal path for forwarding a frame to a destination among all registered forwarding directions can be selected. For the same metric, a distribution can be applied to all. the metric of equivalent ports or a selection of one of the ports. The selection can be made automatically or specified by configuration. As an automatic selection method, for example, the port are selected, over which the address information arrives first. The address information can be used to determine ways or. Alternatively, which substitute paths represent in the event of a switch failure, are evaluated. A forwarding decision can be made for unicast, multicast, and broadcast traffic. For unicast traffic, the forwarding decision is based on the destination address and the corresponding registry in the forwarding database. Routing of multicast and broadcast traffic typically occurs only for frames arriving at the lowest metric port for the source address. Incoming multi ^¬ cast or broadcast frames via other ports clears ge ^¬.

According to one embodiment of the invention is with respect. Propagating the messages on the destination address given a termination criterion to limit the signaling load within the network. The destination address is z. B. not communicated to ei ^¬ NEN neighboring switch when the arrived destination address was sent from the neighbor switch or if ^¬ be züglich the neighboring switches a transmission of Zielad ^¬ ress Affected termination criterion is satisfied. The abort ^¬ criterion can be given by the fact that the destination address is not communicated to a neighboring switch when the neighbor switch already a notification about the accessibility of the Zieladres se has been sent with more favorable Metrikinformati ^¬ on.

Has a special function in the inventive procedural ren the switch, gistriert which first the new destination address and then re ^¬ terkommuniziert these to one or more switches wei ^¬. By the uniqueness of this switch ^¬ nen situations in conventional processes that lead to the flooding of frames, be avoided Kings. The identification of the switch takes place, for example, via the port, namely an edge port in which an Ethernet frame arrives with an unknown address. Concerning . This address is provided by the switch then an initiator functionality or. is an initiator switch in the sense that the notification of the new address to other switches is initiated by the initiator switch. It is useful if any removal of the address is also triggered by the initiator switch. In this case, the distance through the initiator switch can be time-controlled as in conventional Ethernet. The Adres se is removed after ei ^¬ nem predetermined time interval when einteffen not be forwarded to the address frames within the time interval. But this aging function performs only the initiator. If a frame is removed, all other switches are informed again via bridge frame.

A further development of the invention is a transmission of the initiator functionality. In this case, the destination address of a frame arrived at an edge port of the first switch, which has previously arrived at another edge port of another switch of the network, is communicated from the first switch to the second switch, if the transmission is the initiator -Functionality on the first switch he ^¬ wishes is. The other switch is notified of the first switch and registers the destination address as a destination address ^¬, which requires a route the frames to another switch in the network. D. H . the first switch becomes the new initiator switch and communicates with the other one

Switch, which includes a different edge port st, the adoption of the initiator functionality or. the switching of the forwarding direction for frames to be sent to the destination address. The further switch, d. H . the old initiator switch removes the registry as an initiator switch and retains only the forwarding information. If the changeover, however undesirable, such a one edge port of the f ^¬ th switches incoming frame are ignored by the first switch. If a forwarding direction for a frame with a destination address can not be determined, it makes sense to select the frame no longer forward, but to remove. Flooding of frames can be avoided.

In this method, it is advantageous that the self-learning / determining the forwarding direction no longer affects the path or the direction of transmission. Way is limited but distributed throughout the network. As a result, all relevant forwarding information (eg destination address) is known in all switches and it is possible to quickly switch to alternative paths. D. H . It is an interruption-free operation of a network in the event of failure of individual or few network components (eg., Switches, lines) allows. This results in very short switching times, which are independent of the network dimension. In addition, the load can be distributed over several paths. There is no blocking of ports, i. H . the entire Netzka ^¬ capacity is fully available. Since the forwarding information is known, flooding can be dispensed with. So no additional traffic is generated. An impairment of the quality of service does not occur. The method enables the highly available use of Ethernet in access networks with different topologies, such as rings and cascades. The process is characterized by its efficiency, speed and autonomy, and thus represents a significant advance interpreting ^¬ is compared to the known processes.

The invention is illustrated below in the context of an embodiment with reference to a figure. The figure shows an Ethernet network structure with switches according to the invention.

The figure shows five switches (Sl, S2, S3, S4, S5) a Net ^¬ zes as well as a with the edge port El: l of the switch Sl ver ^¬-bound computer which is connected to a Ethernetadres se X marked. There are further edge ports, for example El: 2, El: 3, for the switch Sl and E2: l, E2: 2, E3: 2 for the switch S2, etc. shown. If the switch Sl encounters a frame sent from the computer via the edge port El: l, whose source address X is not in the bank Weiterleitungsdaten- of Sl is present, then this address will be added, since ^¬ tenbank in the. Then the switch is called Sl. Initiator for the routing to the address X. This is followed by explicit forwarding information in a bridge frame to the connected neighbor switches, namely switch S2 and switch S3. This bridge frame includes, for example here Informa ^¬ tions about the address X and the address of the switch Sl. The switches S2 and S3 evaluate the incoming bridge frames, add the entries of the forwarding database and also send bridge frames to all other ports of the ^{corresponding} network segment. For example, the switch S2 would process the information received from the switch Sl and forward it to the switches S4 and S5. The bridge frames receive a field that identifies the path length, which is z. B. is described by Hopcount (number of hops) or connection costs. Thus, the switch S4 would be able to deduce from the bridge frame from the switch S2 that a frame forwarded to the address X within the network requires two hops via the switch S2. After insertion into the Weiterleitungsda ^¬ tenbank the switch S4 Bridge frames sends to the switches S3 and S5. The switch S3 now has forwarding information for the frames to be sent to the address X via two different ports. Via port 3: 1, the destination is reachable within the network with a hopcount of 1, via port 3: 4 the destination can be reached with a hopcount of 3 within the network. Both entries are added to the database. In addition, the load can be distributed to paths with the same metric (for example, port 4: 2 and 4: 3 to switch S4). The bridge frames as long as instructed by the switches weiterge ^¬ until there is no need to pass in either direction. For example, the switch S4 would not forward incoming information over port 4: 5 (Hopcount 3) to switches S3 and 2 if the information about the shorter directions has already been forwarded via Swich S2 (Hopcount 2) and S3 (Hopcount 3). When network faults are detected, the switches change their forwarding tables and forward the corresponding information to the other switches. In case of failure of Switch S2 z shares. B. Switch S3 and Switch S5 indicate that the hopcount has changed from 2 (direction switch S2) to 3 (direction switch S4).

Claims

claims

1. A method for determining the forwarding direction of Ethernet frames for forwarding them to a destination by means of Ethernet switches (Sl, S2, _S3? S4, S5), in which

a frame is received by a first switch (Sl),

it is determined that the source address of the frame does not represent a destination address for the forwarding of frames registered in the switch (S1), the source address is registered as a new destination address (X) for the forwarding of frames in the first switch (S1),

- from the first switch (Sl) the new destination address (X) on egg ^¬ NEN second Ethernet switch (S2, S3) is communicated, and - the arrival of the target address (X) out of the second switch (S2, S3) given for the transmission of frames to the se by the new Zieladres (X) a forwarding destination ^¬ direction is determined.

2. The method according to claim 1, characterized in that

the second switch (S2, S3) communicates the new destination address (X) to a further Ethernet switch (S4, S5), and - the further switch (S4, S5) arrives at the destination address (X) given for the transmission of frames to the se by the new Zieladres (X) a forwarding destination ^¬ direction is determined.

3. The method according to any one of claims 1 or 2, characterized in that

a network is provided which comprises a plurality of Ethernet switches (S1, S2, S3, S4, S5),

- the new destination address (X) is communicated to all switches (S2, S3, S4, S5) of the network except the first switch (S1) by notification by a neighbor switch, and - Upon the arrival of the destination address (X) from the switches (Sl, S2, S3, S4, S5) of the network for the transmission of Fra ^¬ mes to the specified by the new Zieladres se (X) target a forwarding direction is set.

4. The method according to claim 3, characterized in that

- At the arrival of the destination address (X) at a switch towards the Zieladres se (X) is communicated to the neighbor switches, except

- if from the neighbor switch the arrived destination address (X) was sent, or

- If with respect to the neighbor switch a transmission of the Zieladres se (X) concerning Abort criterion is met.

5. The method according to any one of claims 1 to 4, characterized in that

a plurality of forwarding directions are registered and evaluated in accordance with metric information.

6. The method according to any one of claims 1 to 5, characterized in that

when communicating to a neighbor switch, metric information is communicated with the destination address (X) together.

7. The method according to claim 6, characterized in that

- metrics information about hop counts and / or connection types are.

8. The method according to any one of the preceding claims, characterized in that

- When communicating to a neighbor switch on the first switch (Sl) related address information, eg. B. Ethernet

Address with which target address is communicated together.

9. The method according to any one of claims 4 to 8, characterized in that

- The abort criterion is given by the fact that the target address (X) is not communicated to a neighboring switch if a notification on the reachability of the destination address (X) with a more favorable metric has already been sent to the neighbor switch.

10. The method according to any one of claims 1 to 4, characterized in that

- The first switch (Sl) is that switch of the network from which the frame is received first.

11. The method according to claim 10, characterized in that

- Edge ports of switches (Sl, S2, S3, S4, S5) of the network are ports in which no information from other switches of the network arrives,

- the first switch (Sl) comprises an edge port (El: l), and - the first switch (Sl) is recognized by the arrival of the frame at this port (El: l) that it is the first switch (Sl) the network from which the frame is received.

12. The method according to claim 11, characterized in that

- A at an edge port (El: l) of the first switch (Sl) a ^¬ struck frame, which has previously arrived at another edge port, is ignored by the first switch (Sl).

13. The method of claim 12, d a c e c e s e c e n e s, d a s s

- The destination address (X) of a at an edge port (El: l) of the first switch (Sl) arrived frame, which has previously arrived at another edge port of another switch (S2) of the network, from the first switch (Sl) is communicated at the second switches (S2, S3), - And the further switch (S2), the destination address (X) registered as a destination address (X), which requires a forwarding of frames to another switch (S3, s4, S5) of the network.

14. Ethernet switch with means for carrying out a method according to one of claims 1 to 13.