WO2014136867A1 - 通信システム、統合コントローラ、パケット転送方法及びプログラム - Google Patents
通信システム、統合コントローラ、パケット転送方法及びプログラム Download PDFInfo
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- WO2014136867A1 WO2014136867A1 PCT/JP2014/055754 JP2014055754W WO2014136867A1 WO 2014136867 A1 WO2014136867 A1 WO 2014136867A1 JP 2014055754 W JP2014055754 W JP 2014055754W WO 2014136867 A1 WO2014136867 A1 WO 2014136867A1
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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
- H04L45/58—Association of routers
- H04L45/586—Association of routers of virtual routers
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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
- H04L45/64—Routing or path finding of packets in data switching networks using an overlay routing layer
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L41/00—Arrangements for maintenance, administration or management of data switching networks, e.g. of packet switching networks
- H04L41/08—Configuration management of networks or network elements
- H04L41/0803—Configuration setting
- H04L41/0823—Configuration setting characterised by the purposes of a change of settings, e.g. optimising configuration for enhancing reliability
- H04L41/0826—Configuration setting characterised by the purposes of a change of settings, e.g. optimising configuration for enhancing reliability for reduction of network costs
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L41/00—Arrangements for maintenance, administration or management of data switching networks, e.g. of packet switching networks
- H04L41/12—Discovery or management of network topologies
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04L—TRANSMISSION OF DIGITAL INFORMATION, e.g. TELEGRAPHIC COMMUNICATION
- H04L41/00—Arrangements for maintenance, administration or management of data switching networks, e.g. of packet switching networks
- H04L41/12—Discovery or management of network topologies
- H04L41/122—Discovery or management of network topologies of virtualised topologies, e.g. software-defined networks [SDN] or network function virtualisation [NFV]
Definitions
- the present invention is based on a Japanese patent application: Japanese Patent Application No. 2013-045263 (filed on March 7, 2013), and the entire contents of this application are incorporated herein by reference.
- the present invention relates to a communication system, an integrated controller, a packet transfer method, and a program, and more particularly, to a communication system, an integrated controller, a packet transfer method, and a program for controlling a centralized control type network and an autonomous control type network, respectively.
- OpenFlow a technique called OpenFlow
- the functions of packet transfer and path control are separated, and a network device is in charge of packet transfer, and a controller placed outside the network device is in charge of path control. Thereby, control from the outside becomes easy, and it becomes possible to construct a flexible network.
- FIG. 14 shows a basic configuration example of OpenFlow 1.0.0.
- a switch is shown as an example of a network device.
- the OpenFlow includes a network device that supports the OpenFlow protocol and a controller placed outside.
- the network device and the controller are connected by a secure channel (Secure Channel), and communicate by the OpenFlow protocol.
- Secure Channel secure channel
- packet transfer and route control of the network device are separated, the network device performs packet transfer, and the controller performs route control of the network device.
- the controller sets a flow entry in which a matching condition (Header Field in FIG. 14), statistical information (Counter in FIG. 14), and processing content (Action in FIG. 14) are associated with the switch.
- An entry having a matching condition that matches the received packet is searched from the set flow entries, and when a corresponding entry is found, the processing content of the entry (Action in FIG. 14) is applied to the received packet.
- a matching condition Header Field in FIG. 14
- Statistics information Counter in FIG. 14
- TRILL a technique called TRILL has been proposed as a method for constructing a flexible network
- Non-patent Document 3 network devices have packet transfer and path control functions.
- TRILL an Ethernet (registered trademark) frame received by a network device is encapsulated in another Ethernet frame, and a new destination MAC address (Media Access Control Address), a source MAC address, and a VLAN tag are added.
- TRILL also adds a unique TRILL header for storing information such as an Ingress switch and an Egress switch.
- the TRILL switch A receives a packet from the node A.
- the TRILL switch A searches the forwarding table, and checks the Nickname of the input RBridge (Routing Bridge) and the output RBridge based on the information of the original Ethernet header.
- the TRILL switch A adds a TRILL header in which the nickname of the RBridge is set, encapsulates it with a new Ethernet header, and transmits it to the TRILL switch B that is the next hop.
- the TRILL switch B searches the forwarding table, rewrites the destination MAC address and the transmission source MAC address of the Ethernet header, and transmits to the TRILL switch D that is the next hop.
- the TRILL switch D searches the forwarding table, and if it is found that the destination node B is connected to its own, the TRILL switch D removes the TRILL header and the outer Ethernet header and transmits the result to the node B.
- TRILL uses IS-IS (Intermediate System to Intermediate System) to generate a forwarding table.
- the TRILL switch generates a forwarding table by transmitting and receiving IS-IS packets to each other.
- the OpenFlow controller of Non-Patent Documents 1 and 2 performs route calculation based on the link cost of the OpenFlow switch, and sets a flow entry (control information) that realizes transfer along the route to the OpenFlow switch on the route with the lowest cost. To do. At this time, the OpenFlow controller is not under the control of itself, and the topology and link cost of the switch that does not support OpenFlow cannot be collected from the beginning, so it is not used for route calculation.
- TRILL Transparent Interconnect of Lots of Links
- FIG. 4 shows a physical topology
- FIGS. 5 and 6 show link costs between the switches of FIG.
- the path of the minimum cost from the node C to the node A is “node C ⁇ TRILL switch 50-4 ⁇ TRILL switch 50-1 ⁇ OpenFlow switch 40-5 ⁇ OpenFlow switch 40-3” as shown in FIG. ⁇ OpenFlow switch 40-1 ⁇ Node A ”.
- the minimum cost path from node C to node B is “node C ⁇ TRILL switch 50-4 ⁇ TRILL switch 50-2 ⁇ OpenFlow switch 40-6 ⁇ OpenFlow switch 40-4 ⁇ OpenFlow switch 40-2 ⁇ node B”. It becomes.
- the present invention provides a communication system, an integrated controller, and a packet that contribute to providing route control means in an environment in which a network that forwards packets along the indicated route from the host device and a network that performs route control in an autonomous control type are connected.
- An object is to provide a transfer method and a program.
- information is exchanged with an adjacent switch according to a predetermined routing protocol to generate a forwarding table, and the first switch that forwards a packet with reference to the forwarding table and a predetermined controller
- a second switch for transferring a packet in accordance with the instruction; a controller for giving an instruction to the second switch; a packet transfer instruction for the designated route to the second switch to the controller; and the first switch Instructing generation of a virtual network configured with virtualized switches, and causing information exchange by the predetermined routing protocol between the second switch mapped to the virtual network and the first switch, And an integrated controller that performs packet forwarding along a pre-calculated route.
- Communication system is provided.
- information is exchanged with an adjacent switch using a predetermined routing protocol to generate a forwarding table, and the first switch that forwards the packet with reference to the forwarding table and a predetermined controller
- a second switch that forwards packets in accordance with the instructions; and a controller that gives instructions to the second switch; and based on information collected from the first and second switches,
- the second switch mapped to the virtual network, instructing the packet transfer instruction on the designated route to the switch of 2 and the generation of the virtual network composed of the switch that virtualizes the first switch;
- the first switch for exchanging information with an adjacent switch using a predetermined routing protocol to generate a forwarding table, forwarding the packet with reference to the forwarding table, and a predetermined control device
- a second switch that forwards the packet in accordance with the instruction of the network
- a controller that gives an instruction to the second switch of the network including the packet, a packet transfer instruction on the designated route to the second switch, and the first switch Instructing generation of a virtual network composed of switches obtained by virtualizing switches, and exchanging information by the predetermined routing protocol between the second switch mapped to the virtual network and the first switch
- the first and second switches along the path calculated in advance.
- Packet transfer method for performing the packet forwarding is provided. The method is associated with a specific machine called an integrated controller that controls the network management device and the controller.
- the first switch for exchanging information with an adjacent switch using a predetermined routing protocol to generate a forwarding table, forwarding the packet with reference to the forwarding table, and a predetermined control device
- a second switch that forwards the packet in accordance with the instruction of the packet
- a computer that gives an instruction to the controller that gives an instruction to the second switch of the network including the packet
- a process for instructing generation of a virtual network configured by a switch obtained by virtualizing the first switch, and the predetermined routing between the second switch mapped to the virtual network and the first switch Processing for exchanging information according to a protocol, and executing the first and second switches.
- the program for causing a packet transfer along a precalculated route is provided.
- This program can be recorded on a computer-readable (non-transient) storage medium. That is, the present invention can be embodied as a computer program product.
- route control means in an environment in which a network that transfers packets along a route indicated by a host device and a network that performs route control by an autonomous control type are connected. It becomes.
- FIG. 4 is a diagram in which the minimum cost path between nodes based on the link cost of FIG.
- FIG. 4 is a diagram in which the minimum cost path between nodes based on the link cost of FIG.
- 11 is an example of the network topology which replaced the OpenFlow switch with the virtual network by the instruction
- 11 is a table summarizing link costs between virtual TRILL switches in FIG. 10. It is a figure for demonstrating OpenFlow of a nonpatent literature 1,2. It is a figure for demonstrating TRILL of a nonpatent literature 3.
- FIG. 10 is a figure for demonstrating OpenFlow of a nonpatent literature 1,2. It is a figure for demonstrating TRILL of a nonpatent literature 3.
- a first switch that exchanges information with an adjacent switch by a predetermined routing protocol to generate a forwarding table, and forwards a packet with reference to the forwarding table 50a
- a second switch 40a that transfers a packet in accordance with an instruction from a predetermined controller
- a controller 20a that gives an instruction to the second switch 40a
- an integrated controller 10a provides the controller 20a with a packet transfer instruction to the second switch 40a along a designated route and a virtual switch configured by virtualizing the first switch 50a. Directs network creation. Then, the controller 20a causes the second switch 40a mapped to the virtual network and the first switch 50a to exchange information according to the predetermined routing protocol, so that packets along the previously calculated route are transmitted. Let the transfer occur.
- the controller 20a instructs the second switch 40a to perform transfer through the designated route, and causes the second switch 40a to operate as a virtual first switch. This is because information about the route is exchanged with the first switch 50a.
- FIG. 2 is a diagram for explaining an operation outline of the communication system according to the first embodiment.
- an OpenFlow controller 20 that controls the OpenFlow switch by manipulating the contents of the flow table held by the OpenFlow switch and an SNMP (Simple Network Management Protocol) manager 30 (which collects information on the network management device).
- an integrated controller 10 that controls the OpenFlow controller 20 and the SNMP manager 30, an OpenFlow network in which the OpenFlow switch is arranged, and a TRILL network in which the TRILL switch is arranged.
- the OpenFlow controller 20 collects link cost information and topology information from the OpenFlow switch and stores them in a database.
- the SNMP manager 30 collects link cost information and topology information from the TRILL switch and stores them in a database.
- the integrated controller 10 acquires the OpenFlow network topology information and link cost information from the OpenFlow controller 20, acquires the TRILL network topology information, link cost information, and server information from the SNMP manager 30, and stores them in the database.
- the integrated controller 10 calculates the minimum cost path between the node A (or node B) and the node C (or node D) from the information stored in the database.
- the integrated controller 10 instructs the OpenFlow controller 20 to set a flow for performing communication through the route with the lowest cost.
- the OpenFlow controller 20 sets a flow entry that causes the OpenFlow switch on the minimum cost path to perform packet transfer along the minimum cost path in accordance with an instruction from the integrated controller.
- the integrated controller 10 instructs the OpenFlow controller 20 to generate a virtual network.
- the OpenFlow network replaces one or a plurality of OpenFlow switches with TRILL switches in accordance with an instruction from the integrated controller, and generates a virtual network that does not change the link cost.
- the OpenFlow controller 20 instructs the OpenFlow switch to transmit link cost information of the virtual network.
- the OpenFlow switch transmits virtual network information to the TRILL switch.
- the TRILL switch recognizes the virtual network as a TRILL network and performs route calculation.
- FIG. 3 is a block diagram illustrating a configuration of the communication system according to the first embodiment. Referring to FIG. 3, there is shown a configuration in which an integrated controller 10, an OpenFlow controller 20, an SNMP manager 30, an OpenFlow switch 40, and a TRILL switch 50 are connected.
- the integrated controller 10 includes an OpenFlow controller control unit 11, an SNMP manager control unit 12, a route calculation unit 13, and a switch information storage unit 14. Such an integrated controller 10 can be configured by a server machine or a virtual machine operating on the server machine.
- the integrated controller 10 and the OpenFlow controller 20 or the SNMP manager 30 are connected by a dedicated line or a normal network. In the example of FIGS. 2 and 3, there is one OpenFlow controller 20 or SNMP manager 30, but the integrated controller 10 can manage a plurality of OpenFlow controllers and a plurality of SNMP managers.
- the OpenFlow controller control unit 11 controls the OpenFlow controller 20 via a network.
- the SNMP manager control unit 12 controls the SNMP manager 30 via the network.
- the route calculation unit 13 calculates a route between nodes as shown in FIG.
- the switch information storage unit 14 stores topology and link cost information acquired from the OpenFlow controller 20 and the SNMP manager 30.
- the OpenFlow controller 20 includes an OpenFlow switch control unit 21, a virtual network generation unit 22, and a switch information storage unit 23.
- Such an OpenFlow controller 20 can be configured by a server machine or a virtual machine operating on the server machine. Also, the OpenFlow controller 20 can operate on the same machine as the integrated controller 10.
- the OpenFlow controller 20 can manage a plurality of OpenFlow switches, and is connected to the OpenFlow switch via a dedicated channel or a secure channel (Secure Channel) using a normal network.
- the OpenFlow switch control unit 21 controls the OpenFlow switch 40 by rewriting the contents of the flow table of the OpenFlow switch via a secure channel (Secure Channel).
- the virtual network generation unit 22 generates a virtual network (see FIGS. 8 and 12) reflecting the link cost between the OpenFlow switches according to the instruction of the integrated controller 10.
- the switch information storage unit 23 stores information acquired from the OpenFlow switch 40.
- the SNMP manager 30 includes a TRILL switch control unit 31 and a switch information storage unit 32. Such an SNMP manager 30 can be configured by a server machine or a virtual machine operating on the server machine. The SNMP manager 30 can also operate on the same machine as the integrated controller 10. The SNMP manager 30 can manage a plurality of TRILL switches using SNMP, and is connected to the TRILL switch through a dedicated line or a normal network.
- the TRILL switch control unit 31 controls the TRILL switch 50 via the network.
- the switch information storage unit 32 stores information acquired from the TRILL switch 50.
- the OpenFlow switch 40 includes a packet processing unit 41 and a capsule processing unit 42.
- the packet processing unit 41 refers to a flow entry (control information) set in a flow table (not shown) and transfers the received packet to the physical port of the OpenFlow switch 40 or the OpenFlow controller 20.
- the capsule processing unit 42 encapsulates and decapsulates the TRILL header for packets input / output from the port on the TRILL switch side.
- the TRILL switch 50 includes a packet processing unit 51, a capsule processing unit 52, a route calculation unit 53, and a forwarding table 54.
- the packet processing unit 51 When the packet processing unit 51 receives a packet from the physical port of the TRILL switch 50 or the SNMP manager 30, the packet processing unit 51 refers to the forwarding table 54 and transmits the packet to the physical port of the TRILL switch 50 or the SNMP manager 30.
- the capsule processing unit 52 performs encapsulation and decapsulation of the TRILL header.
- the route calculation unit 53 calculates a route in the network and stores the route information in the forwarding table 54.
- the forwarding table 54 stores route information.
- each unit (processing unit) of the integrated controller 10, the OpenFlow controller 20, and the SNMP manager 30 illustrated in FIG. 3 is a computer that causes a computer that configures these devices to execute the above-described processes using the hardware. It can also be realized by a program.
- FIG. 5 is a table summarizing the link costs between the OpenFlow switches of FIG. 4
- FIG. 6 is a table summarizing the link costs between the OpenFlow switches and the TRILL switches of FIG.
- the OpenFlow controller 20 acquires topology and link cost information from the OpenFlow switches 40-1 to 40-7 managed by the OpenFlow controller 20 and stores the information in the switch information storage unit 23 (see (1) in FIG. 2).
- the SNMP manager 30 acquires topology and link cost information from the TRILL switches 50-1 to 50-5 managed by the SNMP manager 30, and stores the information in the switch information storage unit 32 (see (2) in FIG. 2).
- the integrated controller 10 acquires the topology and link cost information held by the OpenFlow controller 20 and the SNMP manager 30, and stores them in the switch information storage unit 14 (see (3) in FIG. 2).
- the route calculation unit 13 calculates the minimum cost route between the edge switches based on the information stored in the switch information storage unit 14 (see (4) in FIG. 2). 5 and 6, the path of the minimum cost from the OpenFlow switch 40-1 to the TRILL switch 50-4 is “OpenFlow switch 40-1 ⁇ OpenFlow switch 40-3 ⁇ OpenFlow switch 40-5 ⁇ TRILL switch 50-1 ⁇ TRILL switch 50-4 ”. Similarly, the path of the minimum cost from the OpenFlow switch 40-1 to the TRILL switch 50-5 is "OpenFlow switch 40-1 ⁇ OpenFlow switch 40-3 ⁇ OpenFlow switch 40-6 ⁇ TRILL switch 50-2 ⁇ TRILL switch 50. ⁇ 5 ”(see FIG. 7).
- the minimum cost path from the OpenFlow switch 40-2 to the TRILL switch 50-4 is “OpenFlow switch 40-2 ⁇ OpenFlow switch 40-4 ⁇ OpenFlow switch 40-6 ⁇ TRILL switch 50-2 ⁇ TRILL switch 50 ⁇ . 4 ".
- the path of the minimum cost from the OpenFlow switch 40-2 to the TRILL switch 50-5 is “OpenFlow switch 40-2 ⁇ OpenFlow switch 40-4 ⁇ OpenFlow switch 40-7 ⁇ TRILL switch 50-3 ⁇ TRILL switch 50-5”. (See FIG. 7).
- the OpenFlow controller control unit 11 instructs the OpenFlow controller 20 to set a flow entry (control information) that causes the OpenFlow switch 40 to perform packet transfer along the route calculated by the route calculation unit 13 ((5 in FIG. 2). )).
- the OpenFlow switch control unit 21 of the OpenFlow controller 20 sets a flow entry in the OpenFlow switch 40 in accordance with the instruction received from the integrated controller 10. For example, a flow entry (control information) for transferring the packet along the arrow is set in the OpenFlow switch on the shortest path in FIG.
- the OpenFlow controller control unit 11 instructs the OpenFlow controller 20 to generate a virtual network having the topology of FIG. 8 and the link cost of FIG. 9 based on the route calculated by the route calculation unit 13 (FIG. 2). (6)).
- the virtual network generation unit 22 of the OpenFlow controller 20 generates a virtual network in accordance with an instruction from the integrated controller 10.
- the virtual network is composed of virtual TRILL switches as shown in FIG.
- the virtual TRILL switch is a virtual TRILL switch realized by software in the OpenFlow controller 20.
- the virtual TRILL switch has link cost information, and exchanges link cost information with each other by sending and receiving IS-IS packets.
- the virtual TRILL switch may be mapped to the OpenFlow switch, and transmits an IS-IS packet to the mapping destination OpenFlow switch.
- the virtual TRILL switch 60-3 in FIG. 8 is mapped to the OpenFlow switch 40-5.
- the virtual TRILL switch 60-4 in FIG. 8 is mapped to the OpenFlow switch 40-6.
- the virtual TRILL switch 60-5 in FIG. 8 is mapped to the OpenFlow switch 40-7.
- the virtual TRILL switch 60-1 is generated by aggregating OpenFlow 40-1 and OpenFlow 40-3 based on the route calculated by the route calculation unit 13 (link cost is added).
- the virtual TRILL switch 60-2 is generated by aggregating OpenFlow 40-2 and OpenFlow 40-4 based on the route calculated by the route calculation unit 13 (link cost is added).
- the virtual TRILL switches 60-3 to 60-5 request the OpenFlow switch control unit 21 to transmit the generated IS-IS packet to the mapping destination OpenFlow switch.
- the OpenFlow switch control unit 21 sends an OpenFlow protocol packet transmission message (“Packet-Out message” in Non-Patent Document 2) to the OpenFlow switch 40-5 mapped to the virtual TRILL switch 60-3. Send an IS-IS packet.
- Packet-Out message in Non-Patent Document 2
- IS-IS packet Send an IS-IS packet.
- a packet transmission request to the physical port of the OpenFlow switch 40-5 to which the TRILL switch 50-1 is connected is set.
- the OpenFlow switch control unit 21 transmits an IS-IS packet together with a packet transmission message of the OpenFlow protocol to the OpenFlow switch 40-6.
- a packet transmission request to the physical port of the OpenFlow switch 40-6 to which the TRILL switch 50-2 is connected is set in the packet transmission message.
- the OpenFlow switch control unit 21 transmits the IS-IS packet together with the OpenFlow protocol packet transmission message to the OpenFlow switch 40-7.
- the packet transmission message a packet transmission request to the physical port of the OpenFlow switch 40-7 to which the TRILL switch 50-3 is connected is set.
- the packet processing unit 41 of the OpenFlow switch 40-5 When the packet processing unit 41 of the OpenFlow switch 40-5 receives an OpenFlow protocol packet transmission message from the OpenFlow controller 20, the packet processing unit 41 transmits an IS-IS packet to the TRILL switch 50-1 designated by the message.
- the packet processing unit 41 of the OpenFlow switch 40-6 receives an OpenFlow protocol packet transmission message from the OpenFlow controller 20, it transmits an IS-IS packet to the TRILL switch 50-2 designated by the message.
- the packet processing unit 41 of the OpenFlow switch 40-7 When the packet processing unit 41 of the OpenFlow switch 40-7 receives the OpenFlow protocol packet transmission message from the OpenFlow controller 20, the packet processing unit 41 transmits an IS-IS packet to the TRILL switch 50-3 designated in the message ((( 7)).
- the packet processing unit 51 of the TRILL switches 50-1 to 50-3 receives the IS-IS packet from the OpenFlow switches 40-5 to 40-7, it analyzes the IS-IS packet and acquires link cost information.
- the route calculation unit 53 of the TRILL switches 50-1 to 50-3 performs route calculation based on the link cost and updates the forwarding table 54.
- TRILL switches 50-1 to 50-5 update their forwarding tables by transmitting and receiving IS-IS packets between TRILL switches.
- the path calculation unit 53 of the TRILL switch 50-4 stores in the forwarding table 54, “When the destination switch is the virtual TRILL switch 60-1, the next hop is the TRILL switch 50-1,” and “The destination switch is the virtual TRILL switch 60.
- the next hop in the case of -2 stores the information that the TRILL switch 50-2 ".
- TRILL switch 50-4 searches forwarding table 54, and node A is connected to virtual TRILL switch 60-1, and virtual TRILL switch 60- The content that the next hop when transmitting to 1 is the TRILL switch 50-1 is obtained.
- the capsule processor 52 of the TRILL switch 50-4 encapsulates the packet with the TRILL header and the Ethernet header.
- the packet processing unit 51 transmits the encapsulated packet to the TRILL switch 50-1.
- the TRILL switch 50-1 searches its own forwarding table 54 and transmits the packet received from the TRILL switch 50-4 to the virtual TRILL switch 60-3.
- the virtual TRILL switch 60-3 is a virtual TRILL switch
- the OpenFlow switch 40-5 actually receives a packet from the TRILL switch 50-1.
- the capsule processing unit 42 restores the packet encapsulated by the Ethernet header and the TRILL header.
- the packet processing unit 41 compares the Ethernet header of the original packet with its own flow table and transfers it to the destination.
- TRILL switches 50-1 to 50-3 also transmit IS-IS packets to OpenFlow switches 40-5 to 40-7.
- the packet processing unit 41 of the OpenFlow switches 40-5 to 40-7 transmits the received packet to the OpenFlow controller 20 using an OpenFlow Packet-In message.
- the OpenFlow switch control unit 21 of the OpenFlow controller 20 receives the IS-IS packet from the OpenFlow switches 40-5 to 40-7, the IS-IS packet is analyzed, and the switch information set in the IS-IS packet is obtained. Saved in the switch information storage unit 23.
- the OpenFlow switch control unit 21 When the OpenFlow switch control unit 21 receives a packet whose source MAC address is the MAC address of the node A and whose destination MAC address is the MAC address of the node C based on the information stored in the switch information storage unit 23, the source flow switch control unit 21 The TRILL header in which the RBridge Nickname is set to the RBridge Nickname of the virtual TRILL switch 60-1, the destination RBridge Nickname is the TRILL switch 50-4 to the RBridge Nickname, the MAC address of the virtual TRILL switch 60-3 to the source MAC address, and the destination An encapsulation rule for adding an Ethernet header in which the MAC address of the TRILL switch 50-1 is set to the MAC address is generated.
- the OpenFlow switch control unit 21 sets the encapsulation rule for the capsule processing unit 42 of the OpenFlow switch 40-5.
- node A transmits a packet to node C, and OpenFlow switch 40-5 receives a packet in which the MAC address of node A is set as the source MAC address and the MAC address of node C is set as the destination MAC address. To do.
- the capsule processor 42 of the OpenFlow switch 40-5 performs the RBridge Nickname of the virtual TRILL switch 60-1 on the source RBridge Nickname and the TRILL switch 50-4 on the destination RBridge Nickname according to the encapsulation rule.
- the packet processing unit 41 transmits the encapsulated packet to the TRILL switch 50-1 according to the flow entry set by the controller 20.
- the TRILL switch 50-1 refers to the forwarding table 54 and transmits the packet received from the OpenFlow switch 40-5 to the TRILL switch 50-4 according to the TRILL process.
- the TRILL switch 50-4 checks that the node C, which is the destination MAC address, is connected to itself, removes the Ethernet header and TRILL header from the received packet, and transmits to the node C.
- FIG. 10 is another table in which link costs between the OpenFlow switches in FIG. 4 are summarized.
- the OpenFlow controller control unit 11 of the integrated controller 10 acquires the link cost shown in FIG. 10 from the OpenFlow controller 20 and stores it in the switch information storage unit 14.
- the route calculation unit 13 calculates the minimum cost route using the link cost of FIG. 10 stored in the switch information storage unit 14.
- the path of the minimum cost from the OpenFlow switch 40-1 to the TRILL switch 50-4 is “OpenFlow switch 40-1 ⁇ OpenFlow switch 40-3 ⁇ OpenFlow switch 40-5 ⁇ TRILL switch 50-1 ⁇ TRILL switch 50”. -4 ".
- the path of the minimum cost from the OpenFlow switch 40-1 to the TRILL switch 50-5 is "OpenFlow switch 40-1 ⁇ OpenFlow switch 40-3 ⁇ OpenFlow switch 40-6 ⁇ TRILL switch 50-2 ⁇ TRILL switch 50. ⁇ 5 ”(see FIG. 11).
- the path of the minimum cost from the OpenFlow switch 40-2 to the TRILL switch 50-4 is “OpenFlow switch 40-2 ⁇ OpenFlow switch 40-4 ⁇ OpenFlow switch 40-5 ⁇ TRILL switch 50-1 ⁇ TRILL switch 50-4”. It becomes.
- the minimum cost path from the OpenFlow switch 40-2 to the TRILL switch 50-5 is “OpenFlow switch 40-2 ⁇ OpenFlow switch 40-4 ⁇ OpenFlow switch 40-6 ⁇ TRILL switch 50-2 ⁇ TRILL switch 50”. ⁇ 5 ”(see FIG. 11).
- the path from the OpenFlow switch 40-1 to the TRILL switch 50-4 (the path from the node A to the node C), and the path from the OpenFlow switch 40-2 to the TRILL switch 50-4. Both of the paths (node B-node C) pass through the OpenFlow switch 40-5 and the TRILL switch 50-1. Also, a path from the OpenFlow switch 40-1 to the TRILL switch 50-5 (node A-node D path) and a path from the OpenFlow switch 40-2 to the TRILL switch 50-5 (node B-node D path) Both pass through the OpenFlow switch 40-6 and the TRILL switch 50-2.
- the OpenFlow controller control unit 11 instructs the OpenFlow controller 20 to generate a virtual network having the topology of the virtual TRILL switch shown in FIG. 12 and the link cost shown in FIG. Since the OpenFlow switch 40-1 and the OpenFlow switch 40-2 pass through the same adjacent point on the route to the TRILL switch 50-4 and the TRILL switch 50-5, they can be aggregated into one virtual TRILL switch in the virtual network. it can.
- the virtual network generation unit 22 generates a virtual TRILL switch having the topology of FIG. 12 and the link cost of FIG.
- the virtual TRILL switch 70-2 is mapped to the OpenFlow switch 40-5.
- the virtual TRILL switch 70-3 is mapped to the OpenFlow switch 40-6.
- the virtual TRILL switch 70-4 is mapped to the OpenFlow switch 40-7. Further, based on the idea that the above OpenFlow switch 40-1 and OpenFlow switch 40-2 can be aggregated, the virtual TRILL switch 70-1 is generated by aggregating OpenFlow 40-1 to OpenFlow 40-4 (link cost). Are added).
- the virtual TRILL switches 70-2 to 70-4 in FIG. 12 request the OpenFlow switch control unit 21 to generate an IS-IS packet and send it to the mapping destination OpenFlow switch.
- the OpenFlow switch control unit 21 transmits the IS-IS packet to the OpenFlow switches 40-5 to 40-7 together with a packet transmission request message (“Packet-Out message” in Non-Patent Document 2).
- the packet processing unit 41 of the OpenFlow switch 40-5 transmits the IS-IS packet received from the OpenFlow controller 20 to the TRILL switch 50-1 in accordance with the packet transmission request message.
- the packet processing unit 41 of the OpenFlow switch 40-6 transmits the IS-IS packet received from the OpenFlow controller 20 to the TRILL switch 50-2 in accordance with the packet transmission request message.
- the packet processing unit 41 of the OpenFlow switch 40-7 transmits the IS-IS packet received from the OpenFlow controller 20 to the TRILL switch 50-3 in accordance with the packet transmission request message.
- the packet processing units 51 of the TRILL switches 50-1 to 50-3 that have received the IS-IS packet receive and analyze the IS-IS packets transmitted by the OpenFlow switches 40-5 to 40-7, respectively.
- the route calculation unit 53 calculates a route based on the information set in the IS-IS packet, and updates the route information in the forwarding table 54.
- the packet processing unit 51 of the TRILL switch 50-4 receives a packet addressed to the node A from the node C, the forwarding table 54 is searched, and the node A is connected to the virtual TRILL switch 70-1. Then, it is checked that the next hop when transmitting to the virtual TRILL switch 70-1 is the TRILL switch 50-1.
- the capsule processor 52 of the TRILL switch 50-4 encapsulates the received packet with the TRILL header and the Ethernet header.
- the packet processing unit 51 of the TRILL switch 50-4 transmits the encapsulated packet to the TRILL switch 50-1.
- the TRILL switch 50-1 searches its own forwarding table 54 and transmits the packet received from the TRILL switch 50-4 to the virtual TRILL switch 70-2.
- the virtual TRILL switch 70-2 is a virtual TRILL switch, and actually the OpenFlow switch 40-5 receives a packet from the TRILL switch 50-1.
- the capsule processor 42 of the OpenFlow switch 40-5 restores the packet encapsulated by the Ethernet header and the TRILL header.
- the packet processing unit 41 of the OpenFlow switch 40-5 collates the Ethernet header of the original packet with its own flow table and transfers it to the destination.
- virtual networks can be aggregated to an appropriate size according to the link cost and the route calculation result based on the link cost.
- an advantage is obtained in that the route selection process in the TRILL switch is simplified as compared with the first embodiment. This is also clear from the fact that it is easy to read that the path between the virtual TRILL switch 70-1 and the virtual TRILL switch 70-3 is the minimum cost in the link cost table of FIG.
- the configuration in which the OpenFlow network and the TRILL network are connected has been described as an example.
- the present invention is also applied to a combination of other centralized control type networks and autonomous control type networks. Is possible.
- an SPB (Shortest Path Bridging) network defined by IEEE802.1aq can be applied instead of the TRILL network.
- the route calculation unit 13 is described as calculating the minimum cost route using the link cost.
- a route other than the minimum cost route may be calculated.
- control may be performed such that only a specific user is assigned a route with the lowest cost and other users are assigned other routes.
- the route may be calculated in consideration of flow traffic information (see the center “Counter” in FIG. 14) provided from an OpenFlow switch or the like.
- the second switch is an open flow switch; The communication system in which the integrated controller causes the controller to perform packet transfer along the calculated path by setting a flow entry to the second switch on the calculated path.
- the first switch is a switch that determines a route using IS-IS (Intermediate System to Intermediate System).
- the integrated controller outputs an IS-IS packet between the first and second switches by outputting an IS-IS packet from the second switch to the first switch via the controller.
- the communication system, wherein the first switch is a TRILL switch.
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Abstract
Description
本発明は、日本国特許出願:特願2013-045263号(2013年 3月 7日出願)に基づくものであり、同出願の全記載内容は引用をもって本書に組み込み記載されているものとする。
本発明は、通信システム、統合コントローラ、パケット転送方法及びプログラムに関し、特に、集中制御型のネットワークと自律制御型のネットワークとをそれぞれ制御する通信システム、統合コントローラ、パケット転送方法及びプログラムに関する。
(1)TRILLスイッチAは、ノードAからパケットを受信する。TRILLスイッチAは、フォワーディングテーブルを検索し、元のイーサネットヘッダの情報を基に入力RBridge(Routing Bridge)と出力RBridgeのNicknameを調べる。TRILLスイッチAは、前記RBridgeのNicknameを設定したTRILLヘッダを加え、新しいイーサネットヘッダでカプセル化を行いネクストホップであるTRILLスイッチBへ送信する。
(2)TRILLスイッチBは、フォワーディングテーブルを検索し、イーサネットヘッダの宛先MACアドレスと送信元MACアドレスを書き変えて、ネクストホップであるTRILLスイッチDへ送信する。
(3)TRILLスイッチDは、フォワーディングテーブルを検索し、宛先であるノードBが自身の配下に接続されていることが分かるとTRILLヘッダと外側のイーサネットヘッダを外してからノードBへ送信する。
続いて、第1の実施形態について図面を参照して詳細に説明する。図2は、第1の実施形態の通信システムの動作概要を説明するための図である。図2を参照すると、OpenFlowスイッチが保持するフローテーブルの内容を操作することによりOpenFlowスイッチを制御するOpenFlowコントローラ20とTRILLネットワークの情報を収集するSNMP(Simple Network Management Protocol)マネージャ30(ネットワーク管理装置に相当)と、OpenFlowコントローラ20とSNMPマネージャ30とを制御する統合コントローラ10と、OpenFlowスイッチが配置されたOpenFlowネットワークと、TRILLスイッチが配置されたTRILLネットワークと、を含む構成が示されている。
上記した第1の実施形態では、図5、図6のリンクコストに前提として説明したが、リンクコストによっては、さらに、仮想ネットワークの集約度を高めることも可能である。以下、仮想ネットワークのエッジの仮想TRILLスイッチを集約した第2の実施形態について図面を参照して詳細に説明する。本実施形態の基本的な構成は、第1の実施形態と同様であるので、以下、その相違点を中心に説明する。
[第1の形態]
(上記第1の視点による通信システム参照)
[第2の形態]
第1の形態の通信システムにおいて、
さらに、前記第1のスイッチの情報を収集するネットワーク管理装置を含み、
前記ネットワーク管理装置及び前記コントローラから、前記第1、第2のスイッチによって構成されるネットワークのトポロジ情報を収集し、前記第1、第2のスイッチによって構成されるネットワークをまたがる経路を計算する通信システム。
[第3の形態]
第1又は第2の形態の通信システムにおいて、
前記統合コントローラは、前記コントローラに、前記第1のスイッチを仮想化したスイッチで構成され、かつ、前記第2スイッチ間のリンクコストを反映させた仮想ネットワークを生成させる通信システム。
[第4の形態]
第1から第3いずれか一の形態の通信システムにおいて、
前記第2のスイッチはオープンフロースイッチであり、
前記統合コントローラは、前記コントローラに、前記計算した経路上の前記第2のスイッチへのフローエントリの設定を行わせることで、前記計算した経路に沿ったパケット転送を行わせる通信システム。
[第5の形態]
第1から第4いずれか一の形態の通信システムにおいて、
前記第1のスイッチはIS-IS(Intermediate System to Intermediate System)を用いて経路を決定するスイッチであり、
前記統合コントローラは、前記コントローラを介して、前記第2のスイッチから前記第1のスイッチに宛ててIS-ISパケットを出力させることにより、前記第1、第2のスイッチ間で、IS-ISを用いて情報交換を行わせる通信システム。
[第6の形態]
第5の形態の通信システムにおいて、
前記第1のスイッチはTRILLスイッチである通信システム。
[第7の形態]
(上記第2の視点による統合コントローラ参照)
[第8の形態]
(上記第3の視点によるパケット転送方法参照)
[第9の形態]
(上記第4の視点によるプログラム参照)
なお、上記第7~第9の形態は、第1の形態と同様に、第2~第6の形態に展開することが可能である。
11 OpenFlowコントローラ制御部
12 SNMPマネージャ制御部
13 経路計算部
14 スイッチ情報記憶部
20 OpenFlowコントローラ
20a コントローラ
21 OpenFlowスイッチ制御部
22 仮想ネットワーク生成部
23 スイッチ情報記憶部
30 SNMP(Simple Network Management Protocol)マネージャ
31 TRILLスイッチ制御部
32 スイッチ情報記憶部
40、40-1~40-7 OpenFlowスイッチ
40a 第2のスイッチ
41 パケット処理部
42 カプセル処理部
50、50-1~50-5 TRILLスイッチ
50a 第1のスイッチ
51 パケット処理部
52 カプセル処理部
53 経路計算部
54 フォワーディングテーブル
60-1~60-5、70-1~70-4 仮想TRILLスイッチ
Claims (13)
- 所定のルーティングプロトコルにより隣接するスイッチと情報交換を行って転送テーブルを生成し、該転送テーブルを参照してパケットを転送する第1のスイッチと、
所定のコントローラからの指示に従いパケットを転送する第2のスイッチと、
前記第2のスイッチに指示を与えるコントローラと、
前記コントローラに、前記第2のスイッチに対する指定した経路でのパケット転送指示と、前記第1のスイッチを仮想化したスイッチで構成された仮想ネットワークの生成とを指示し、前記仮想ネットワークにマッピングされた第2のスイッチと前記第1のスイッチ間で前記所定のルーティングプロトコルによる情報交換を行わせることで、予め計算した経路に沿ったパケット転送を行わせる統合コントローラと、
を含む通信システム。 - さらに、前記第1のスイッチの情報を収集するネットワーク管理装置を含み、
前記ネットワーク管理装置及び前記コントローラから、前記第1、第2のスイッチによって構成されるネットワークのトポロジ情報を収集し、前記第1、第2のスイッチによって構成されるネットワークをまたがる経路を計算する請求項1の通信システム。 - 前記統合コントローラは、前記コントローラに、前記第1のスイッチを仮想化したスイッチで構成され、かつ、前記第2のスイッチ間のリンクコストを反映させた仮想ネットワークを生成させる請求項1又は2の通信システム。
- 前記第2のスイッチはオープンフロースイッチであり、
前記統合コントローラは、前記コントローラに、前記計算した経路上の前記第2のスイッチへのフローエントリの設定を行わせることで、前記計算した経路に沿ったパケット転送を行わせる請求項1から3いずれか一の通信システム。 - 前記第1のスイッチはIS-IS(Intermediate System to Intermediate System)を用いて経路を決定するスイッチであり、
前記統合コントローラは、前記コントローラを介して、前記第2のスイッチから前記第1のスイッチに宛ててIS-ISパケットを出力させることにより、前記第1、第2のスイッチ間で、IS-ISを用いて情報交換を行わせる請求項1から4いずれか一の通信システム。 - 前記第1のスイッチはTRILLスイッチである請求項5の通信システム。
- 所定のルーティングプロトコルにより隣接するスイッチと情報交換を行って転送テーブルを生成し、該転送テーブルを参照してパケットを転送する第1のスイッチと、所定のコントローラからの指示に従いパケットを転送する第2のスイッチと、を含むネットワークの前記第2のスイッチに指示を与えるコントローラに対し、前記第2のスイッチに対する指定した経路でのパケット転送指示と、前記第1のスイッチを仮想化したスイッチで構成された仮想ネットワークの生成とを指示し、前記仮想ネットワークにマッピングされた第2のスイッチと前記第1のスイッチ間で前記所定のルーティングプロトコルによる情報交換を行わせることで、予め計算した経路に沿ったパケット転送を行わせる統合コントローラ。
- 前記第1のスイッチの情報を収集するネットワーク管理装置及び前記コントローラから、前記第1、第2のスイッチによって構成されるネットワークのトポロジ情報を収集し、前記第1、第2のスイッチによって構成されるネットワークをまたがる経路を計算する請求項7の統合コントローラ。
- 前記コントローラに、前記第1のスイッチを仮想化したスイッチで構成され、かつ、前記第2のスイッチ間のリンクコストを反映させた仮想ネットワークを生成させる請求項7又は8の統合コントローラ。
- 前記第2のスイッチはオープンフロースイッチであり、
前記コントローラに、前記計算した経路上の前記第2のスイッチへのフローエントリの設定を行わせることで、前記計算した経路に沿ったパケット転送を行わせる請求項7から9いずれか一の統合コントローラ。 - 前記第1のスイッチはIS-IS(Intermediate System to Intermediate System)を用いて経路を決定するスイッチであり、
前記コントローラを介して、前記第2のスイッチから前記第1のスイッチに宛ててIS-ISパケットを出力させることにより、前記第1、第2のスイッチ間で、IS-ISを用いて情報交換を行わせる請求項7から10いずれか一の統合コントローラ。 - 所定のルーティングプロトコルにより隣接するスイッチと情報交換を行って転送テーブルを生成し、該転送テーブルを参照してパケットを転送する第1のスイッチと、
所定のコントローラからの指示に従いパケットを転送する第2のスイッチと、を含むネットワークの前記第2のスイッチに指示を与えるコントローラに対し、前記第2のスイッチに対する指定した経路でのパケット転送指示と、前記第1のスイッチを仮想化したスイッチで構成された仮想ネットワークの生成とを指示するステップと、
前記仮想ネットワークにマッピングされた第2のスイッチと前記第1のスイッチ間で前記所定のルーティングプロトコルによる情報交換を行わせるステップとを含み、
前記第1、第2のスイッチに、予め計算した経路に沿ったパケット転送を行わせるパケット転送方法。 - 所定のルーティングプロトコルにより隣接するスイッチと情報交換を行って転送テーブルを生成し、該転送テーブルを参照してパケットを転送する第1のスイッチと、
所定のコントローラからの指示に従いパケットを転送する第2のスイッチと、を含むネットワークの前記第2のスイッチに指示を与えるコントローラに対して指示を与えるコンピュータに、
前記第2のスイッチに対する指定した経路でのパケット転送指示と、前記第1のスイッチを仮想化したスイッチで構成された仮想ネットワークの生成とを指示する処理と、
前記仮想ネットワークにマッピングされた第2のスイッチと前記第1のスイッチ間で前記所定のルーティングプロトコルによる情報交換を行わせる処理と、を実行させ、
前記第1、第2のスイッチに、予め計算した経路に沿ったパケット転送を行わせるためのプログラム。
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