RU98116258A

RU98116258A - ADVANCED METHOD AND DEVICE FOR DYNAMIC DISPLACEMENT BETWEEN ROUTING AND COMMUTATION PACKAGES IN DATA TRANSFER NETWORK

Info

Publication number: RU98116258A
Application number: RU98116258/09A
Authority: RU
Inventors: Томас Лайон; Питер Ньюмэн; Грег Миншолл; Роберт Хинден; Фонг Чинг Лиав; Эрик Хоффман; Лоуренс Б. Хьюстон; Уилльям А. Роберсон
Original assignee: Ипсилон Нетуоркс, Инк.
Priority date: 1996-01-31
Filing date: 1997-01-30
Publication date: 2000-06-20

Claims

1. A method of transmitting packets between an uplink node and a downlink node, wherein said downlink node is located in the downstream direction relative to the uplink node, characterized in that it includes the steps of establishing default virtual channels between said uplink node and said downlink node, receiving a packet in said downlink node, performing flow classification in a downlink node according to said packet for I determine whether a packet belongs to a specific stream that must be forwarded to an uplink node, select a free label in said downlink node, inform the said uplink node that subsequent packets belonging to the specified upstream stream should transmitted with the selected selected free label.

2. The method according to p. 1, characterized in that the said nodes of the uplink and downlink use an asynchronous transmission mode.

3. The method according to claim 2, characterized in that the said free label contains the identifier of the virtual route and the identifier of the virtual channel.

4. The method according to claim 1, characterized in that the said network includes a local computer network.

5. The method according to claim 4, characterized in that the informing step is performed using the IFMP flow control protocol software, which provides information exchange between said uplink and downlink nodes.

6. The method according to claim 1, characterized in that the step of performing the flow classification includes analyzing the packet flow identifier to determine whether said packet belongs to a specific flow to be forwarded to the uplink node, said flow identifier containing certain fields a header from a given packet, and transmitting said subsequent packets belonging to a particular stream with the said specific header fields removed to provide security.

7. The method according to claim 6, characterized in that the said subsequent packets can be restored using the identifier of the stream at the destination intended to receive the specified specific stream.

8. A method for switching a stream in a first node, said first node having a downlink to a second node and an uplink to a third node, characterized in that it includes the steps of classifying a stream in a first node according to a first packet to determine whether this first a packet to a specific stream to be forwarded in the third node, selecting the first free label in the first node, informing the third node that subsequent packets belonging to the specified the green thread, should be transmitted with the specified first free tag selected, classifying the flow in the second node by the second packet to determine whether this second packet belongs to a specific thread that should be forwarded to the third node, selecting the second free tag in the second node, informing the aforementioned first node that subsequent packets belonging to the aforementioned specific stream should be transmitted with the indicated selected second free label, while A particular stream from said uplink can be switched at layer 2 by a first node to a downlink.

9. The method of claim 8, wherein said second packet is a first packet.

10. The method according to p. 9, characterized in that the said first, second and third nodes use an asynchronous transmission mode.

11. The method according to p. 9, characterized in that the said first and second free labels contain the identifier of the virtual route and the identifier of the virtual channel.

12. The method according to claim 9, characterized in that the informing steps are performed using the IFMP flow control protocol software, which provides information exchange between said nodes.

13. A computer program product that provides dynamic bias between routing and switching in a network having an uplink node and a downlink node located in a downlink relative to said uplink node, characterized in that it contains a computer-readable code that Enables classifying a stream by packet in a downlink node to determine if a packet belongs to a specific stream that should be forwarded to the upstream node. a communication line, a computer-readable code that allows the selection of a free label in said downlink node, a computer-readable code that informs said uplink node that subsequent packets belonging to said specific stream should be transmitted from specified selected free label, and material medium for storing computer-readable codes.

14. The product of the computer program according to item 13, wherein the said material medium contains a hard disk on a computer.

15. The product of the computer program according to item 13, wherein said material medium is selected from the group including CD-ROM, magnetic tape, floppy disk and the like.

16. A basic switching unit in a system for transmitting packets on a network, characterized in that it comprises hardware switching means, a controller associated with said switching hardware means, the controller comprising a processor and memory, and designed to control said switching means, software stored on material carrier that enables the base switching unit to dynamically shift between routing and packet switching to optimize the throughput lities packet traffic.

17. The basic switching unit according to clause 16, wherein the said software uses stream classification.

18. The basic switching unit according to claim 17, wherein said switching hardware uses switching based on an asynchronous transmission mode.

19. The basic switching unit according to claim 18, wherein said flow classification uses a virtual route identifier and a virtual channel identifier as labels.

20. The basic switching unit according to claim 18, wherein said software includes a first software subsystem installed on the controller for exchanging information and controlling said switching hardware.

21. The basic switching unit according to claim 20, characterized in that said software includes a second software subsystem providing information exchange between the two basic switching units and determining a format for flow redirection messages and acknowledgments.

22. The basic switching unit according to item 21, wherein the basic switching unit performs local classification decisions and decisions in response to a forwarding message.

23. The basic switching unit according to clause 16, characterized in that the said network includes a local computer network.

24. The basic switching unit according to claim 20, wherein the first software subsystem includes an IFMP flow control protocol.

25. The basic switching unit according to item 22, wherein the second software subsystem includes a common GSMP switching control protocol.

26. The basic switching unit according to claim 18, wherein said software includes means for processing quality of service.

27. The basic switching unit according to claim 17, wherein said switching means uses high-speed packet technology.

28. The basic switching unit according to 17, characterized in that the said switching means uses a frame relay technology.

29. The basic switching unit according to claim 17, wherein said switching means utilizes Gigabit Ethernet technology.

30. A gateway switching unit in a system for transmitting packets on a network, said system including a base switching unit connected to said gateway switching unit via a communication line, characterized in that it comprises a gateway unit controller comprising a processor, memory and a plurality of network interface cards, software stored on a tangible medium enabling the gateway switching unit to redirect the packet flow to said basic switching unit so that fected dynamic shift between routing and packet switching to optimize packet traffic throughput.

31. The gateway switching unit of claim 30, wherein said software uses stream classification.

32. The gateway switching unit according to claim 30, wherein said basic switching unit uses switching based on an asynchronous transmission mode.

33. The gateway switching unit according to claim 32, wherein said gateway switching unit and said basic switching unit use a virtual route identifier and a virtual channel identifier as labels.

34. The gateway switching unit according to claim 33, wherein said software includes a first software subsystem installed on the controller of the gateway unit for exchanging information between said gateway switching unit and said basic switching unit in said system and determining a format for flow redirection and acknowledgment messages.

35. The gateway switching unit according to claim 34, wherein said gateway switching unit performs local decision-making on the classification of the flow and decisions in response to a forwarding message.

36. The gateway switching unit according to claim 35, wherein the first software subsystem includes an IFMP flow control protocol.

37. The gateway switching unit of claim 30, wherein said basic switching unit uses Gigabit Ethernet technology.

38. The switching actuator in a system for transmitting packets on a network, said system including a base switching unit coupled to said switching actuating device via a communication line, and the basic switching unit comprising a controller and a switching machine, characterized in that it comprises a processor, memory and a plurality of network interface cards, wherein a particular one of said plurality of network interface cards provides said communication line, and at least one of said multiplier The network interface card has the ability to communicate with at least one network node, and a computer-readable program code stored on a tangible computer-readable medium containing said memory, wherein said computer-readable program code enables the base switch unit controller to classify the stream and forward the specified stream of packets from the first node to the second network node, and the aforementioned computer-readable program code enables the controller AZOV switching unit instruct said switching agent to perform forwarding of said flow from the first node to the second node via said switching machine while offloading packet forwarding from the controller to the basic switching unit.

39. The switching actuator according to claim 38, wherein the first node is connected through the first one of the plurality of network interface cards to said switching actuator, and the second node is selected from the group including another switching actuator, another basic switching unit , a gateway switching unit or a host computer, wherein the second node is connected to a switching machine of said basic switching unit.

40. The switching actuator according to claim 38, wherein the first node is selected from the group including another switching actuator, another basic switching unit, a gateway switching unit or a host computer, wherein the second node is connected through the first one of the plurality network interface cards with said switching actuator, and said computer-readable program code enables said controller of the basic switching unit to issue an execution command telnomu switching device on how to handle said packets in the stream received from said switching machines.

41. The switching actuator according to claim 38, wherein said switching machine uses asynchronous transfer mode, frame relay, fast packet switching, Ethernet at 10 Mb / s, Ethernet at 100 Mb / s, or Gigabit Ethernet.

42. The switching actuator according to claim 38, wherein at least one of said plurality of network interface cards is an Ethernet network interface card.

43. The switching actuator according to claim 38, wherein at least one of said plurality of network interface cards is an asynchronous transfer mode network interface card.

44. The switching actuator according to claim 38, wherein said computer-readable program code comprises a first subsystem installed on said controller and a second subsystem installed in the memory of the switching actuator, wherein said first and second subsystems provide information exchange between said switching actuator and a basic switching unit in said system.

45. The switching actuator according to claim 44, characterized in that said switching actuator serves as a subordinate node with respect to the basic switching unit, which makes local decisions on the classification of the flow and decisions in response to the redirect message.

46. The switching actuator of claim 44, wherein said computer-readable program code comprises flow control protocol software for IFMP-C clients.