BR112019005317A2 - potn service routing system, and service routing, configuration issuing and protection methods. - Google Patents

Abstract

the present invention relates to the technical field of potn transmission, and a potn service forwarding system and a forwarding method are described. the system comprises an ethernet tax unit, a switching unit, and an otn line unit. in the present invention, pove is instantiated as a multicast in one direction of the uplink to enable the bridge connection, a packet service employs multicast as an outbound port of an uplink service channel, and an otn service employs multicast as a source port of interaction with an oduk channel. in a downlink direction, the pove is instantiated as vlandomain to enable the bridge connection, the otn service maps a backplane port on the line side connected to the oduk channel to vlandomain, and the packet service employs vlandomain as a common physical port to complete the classification to access the package service. also described in the present invention is a potn service forwarding method.

Description

POTN SERVICE FORWARDING SYSTEM, AND SERVICE FORWARDING, CONFIGURATION AND PROTECTION ISSUES

Technical Field [001] The present invention relates to the technical field of POTN transmission and, in particular, to a POTN service forwarding system and methods of service forwarding, configuration emission and protection.

Background of the Invention [002] A POTN integrates the network functions of optical layers (WDM), OTN and SDH layers, and packet transport layers (MPLSTP, ETH). It has the capability of switching and scheduling TDM (ODUk) and MPLS-TP (ETH) packet, and performs a unified and flexible transmission function for various services, such as packet, OTN and SDH.

[003] Traditional POTN devices are designed based on a dual-plane switching architecture TDM (ODUk) / Packet, whereby packet and TDM (ODUk) services are routed through different switching cards. Although the dual-plane switching system is simple in design and easy to implement, due to the need for different switching plans, service organization and scheduling are inflexible, scalability is poor, and devices have shortcomings, such as high energy consumption and high OPEX.

[004] In this particular, for centralized POTN devices, they are restricted by factors, such as the density of the distribution panel, energy consumption and cost; usually, they can use only a single switching card, that is, an individual switching architecture to complete the POTN service routing.

[005] Therefore, a solution is urgently needed to use an individual switching architecture to implement the

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2/22 POTN service forwarding.

Summary of the Invention [006] In view of the defects of the prior art, the purpose of the present invention is to provide a POTN service routing system and service routing methods, issue configuration and protection to achieve POTN service routing through a switching architecture on an individual plane, and improve the efficiency and stability of system operation.

[007] In order to achieve the above purpose, the present invention adopts the following technical solution: a POTN service routing system, comprising an Ethernet branch card (card), a switching card (card) and network cards (cards) OTN line, where:

the Ethernet branch card is configured to transmit a packet service received from an Ethernet network to the switching card in an upward direction, and to transmit a data packet received from the switching card to the Ethernet network in one direction downward;

the switch card is configured to implement data interaction between the Ethernet branch card and the OTN line cards; the switch card comprises at least two backplane ports on the branch side connected to the Ethernet branch card and at least four backplane ports on the line side connected to the OTN line cards; one backplane port on the branch side is connected to an MPLS service forward channel, while the other back plate port on the branch side is connected to an Ethernet service forward channel; the MPLS service forwarding channel is also connected to two virtual bridging ports, each of which is connected to two backplane ports on the line side; the channel of forwarding

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3/22 Ethernet service is connected to one of the two virtual bridging ports; and multiple OTN line cards are configured to map the package service to an ODUK channel in the upward direction, and to demap the package service from the ODUK channel in the downward direction.

[008] Based on the exposed technical solution, the MPLS service forwarding channel comprises a first logical AC interface, a first virtual forwarding instance and a PW logical interface that are connected sequentially, and a pair of active and standby LSP interfaces connected to the PW logic interface; the active and standby LSP interfaces are connected to a virtual bridging port respectively.

[009] The Ethernet service forwarding channel comprises a second logical AC interface, a second virtual forwarding instance and a third logical AC interface that are connected sequentially; the third logical AC interface is connected to one of the two virtual bridging ports.

[0010] The present invention further describes a method of service forwarding using the POTN service forwarding system, which comprises service forwarding in an upward direction, wherein service forwarding in an upward direction specifically comprises the following process:

Al: a packet service is received through a backplane port on the branch side, and an AC logical interface matched with the packet service is acquired according to the backplate port on the branch side through which the package passes and the characteristic value of the package service;

A2: a virtual routing instance connected to the logical AC interface acquired from step A1 is acquired;

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A3: a logical interface in an outgoing direction is acquired according to the virtual routing instance acquired from step A2 and the characteristic value of the packet service; if the service is an Ethernet service, proceed to step A4; if the service is an MPLS service, proceed to step A8;

A4: the logical interface in the output direction is a logical AC interface connected to the virtual routing instance acquired from step A2;

A5: the physical table input information corresponding to the AC logic interface acquired from step A4 is displayed, and a virtual jumper port in the output direction and the AC logic interface encapsulation information are determined;

A6: the entry information of the multicast table corresponding to the virtual jumper port acquired from step A5 is displayed, and a back plate port on the line side in the outgoing direction is determined;

A7: the package service is routed to an ODUK channel through the back plate port on the line side acquired from step A6; end;

A8: the logical interface in the output direction is a PW logical interface connected to the virtual routing instance acquired from step A2;

A9: the physical table entry information corresponding to the PW logic interface acquired from step A8 is displayed, and an LSP interface linked to the PW logic interface and the encapsulation information of the PW logic interface are determined;

A10: the physical table entry information corresponding to the LSP interface acquired from step A9 is displayed, and a rear plate port on the line side in the direction of exit and the information of

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5/22 encapsulation of the LSP interface are determined; and

A1 1: the package service is sent to an ODUK channel through the back plate port on the line side acquired from step A10; end.

[0011] Based on the exposed technical solution, the service routing method comprises service forwarding in a downward direction, where service forwarding in a downward direction specifically comprises the following process:

Bl: a data packet is received through the virtual bridging port; a logical interface corresponding to the virtual bridging port is acquired according to VLANDOMAIN configured by a backplane port on the side of the line corresponding to the virtual bridging port and the characteristic value of the data packet; if the service is an Ethernet service, proceed to step B2; if the service is an MPLS service, proceed to step B8;

B2: the logical interface corresponding to the virtual bridging port is an AC logical interface connected to the virtual bridging port in step B1;

B3: a virtual routing instance connected to the logical AC interface acquired from step B2 is determined;

B4: an AC logic interface and a backplane port on the branch side in the outgoing direction are acquired according to the virtual routing instance acquired from step B3 and the characteristic value of the data packet;

B5: an OTN service is routed to an Ethernet branch card via the AC logic interface and the back plate port on the side of the branch acquired from step B4; end;

B6: the logical interface corresponding to the virtual bridging port is an LSP interface connected to the connecting port in

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6/22 virtual bridge in step B1;

B7: the LSP and PW labels of the LSP interface acquired from step B6 are syntactically analyzed layer by layer to acquire a virtual routing instance linked to the LSP interface;

B8: an AC logic interface and a backplane port on the branch side in the outgoing direction are acquired according to the virtual routing instance acquired from step B7 and the characteristic value of the data packet; and

B9: an OTN service is forwarded to the Ethernet branch card via the AC logic interface and the back plate port on the side of the branch acquired from step B8; end.

[0012] The present invention further describes a method of issuing configuration using the POTN service forwarding system, which comprises issuing configuration in an upward direction, wherein issuing configuration in an upward direction specifically comprises the following process:

Cl: the switching card receives the settings and processes the settings separately according to the type of configuration; if the configuration is an MPLS service configuration, proceed to step C2; if the configuration is an Ethernet service configuration, proceed to step C7; if the configuration is an OTN service configuration, proceed to step Cl2;

C2: a virtual jumper port ID in the outgoing direction is acquired from the configuration received by an LSP interface;

C3: the virtual bridging port ID is converted to a multicast ID according to a pre-set mapping rule, and a trigger interface function is invoked to create the multicast;

C4: whether multicast was created is determined according to

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7/22 with the multicast ID; if yes, proceed directly to step C6; if not, proceed to step C5;

C5: multicast is created, whose association is now empty;

C6: the destination port type of the LSP interface is configured as multicast, and a corresponding trigger interface function is invoked to configure; the MPLS service configuration is completed; end;

C7: a virtual jumper port ID in the output direction is acquired from the configuration received by a logical AC interface;

C8: the virtual bridging port ID is converted to a multicast ID according to a pre-set mapping rule, and a trigger interface function is invoked to create the multicast;

C9: whether multicast was created is determined according to the multicast ID; if yes, proceed directly to step Cl 1; if not, proceed to the CIO step;

CIO: multicast is created, whose association is now empty;

Cll: the destination port type of the AC logical interface is configured as multicast, and a corresponding trigger interface function is invoked to configure; the MPLS service configuration is completed; end;

Cl2: a virtual jumper port ID in an incoming direction and the corresponding backplane port information on the active and standby line side are acquired from the OTN service configuration;

C13: the virtual bridging port ID is converted

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8/22 on a multicast ID according to a pre-set mapping rule, and a trigger interface function is invoked to create the multicast;

C14: whether multicast was created is determined according to the multicast ID; if yes, proceed to step C15; if not, proceed to step C18;

C15: whether the OTN service configuration is configured differently before and after it is determined; if yes, proceed to step S16; if not, proceed to step S17;

C16: multicast association information is updated for the virtual jumper port and the backplane ports on the active and reserve line side corresponding to the virtual jumper port; end;

C17: the present multicast association information is maintained; end; and

Cl8: the new multicast is created, and the virtual bridging port and the corresponding backplane ports on the side of the active and reserve line are added to the multicast; the OTN service configuration is completed; end.

[0013] Based on the exposed technical solution, the configuration issue method comprises the issue of configuration in a downward direction, in which the issue of configuration in a downward direction specifically comprises the following process:

Dl: the switching card receives the settings and processes the settings separately according to the type of configuration; if the configuration is an MPLS service configuration, proceed to step D2; if the configuration is an Ethernet service configuration, proceed to step D3; if the configuration is an OTN service configuration, proceed to step D6;

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D2: MPLS service configuration is issued according to a normal MPLS service configuration process flow;

D3: a virtual jumper port ID in the incoming direction is acquired from the configuration received by a logical AC interface;

D4: the virtual jumper port ID is converted to a VLANDOMAIN ID according to a pre-set mapping rule;

D5: the configuration rule for the AC logic interface input port is configured as VLANDOMAIN, and the VLANDOMAIN ID acquired from D4 is configured for the AC logic interface input port; a trigger interface function is invoked to complete the Ethernet service configuration; end;

D6: a virtual jumper port ID in the output direction and the corresponding backplane port information on the active and standby line side are acquired from the OTN service configuration; and

D7: the virtual bridging port ID is converted to a VLANDOMAIN ID according to a preset mapping rule, and a trigger interface function is invoked to update the VLANDOMAIN domain of the backplane ports on the line side active and in reserve corresponding to the virtual bridge connection port; the OTN service configuration is completed; end.

[0014] The present invention further describes a method of protection using the POTN service forwarding system, which comprises the processing of protection in an upward direction, wherein the processing of protection in an upward direction specifically comprises the following process:

El: if a channel failure exists it is verified, and the failure is

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10/22 treated separately according to the type of failure; if the failure is an LSP channel failure, treatment proceeds to step E2; if the failure is an ODUK channel failure, the treatment ends;

E2: the active switching logic - in reserve LSP is executed, and a trigger interface function is invoked to perform the active switching - in reserve; and

E3: a service forwarding path is switched, and the system switch is completed; end.

[0015] Based on the exposed technical solution, the protection method comprises protection processing in a downward direction, where protection processing in a downward direction specifically comprises the following process:

Fl: if a channel fault exists, it is checked, and the fault is treated separately according to the type of fault; if the failure is an ODUK channel failure, treatment proceeds to step E2; if the failure is an LSP channel failure, the treatment ends;

F2: the active switching logic - in reserve ODUK is executed, and a trigger interface function is invoked to perform the active switching - in reserve;

F3: the switching direction is determined; if a backplane port on the spare line side is switched to a backplane port on the active line side, proceed to step F4; otherwise, proceed to step F5;

F4: the VLANDOMAIN of the backplane port on the side of the active line corresponding to a virtual jumper port is updated to a value of VLANDOMAIN of the virtual jumper port, and the VLANDOMAIN of the back plate port on the line side in reserve is updated to an invalid value; end; and

F5: the VLANDOMAIN of the rear plate door on the side of the

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11/22 active line corresponding to the virtual jumper port is updated to an invalid value, and the VLANDOMAIN of the backplane port on the spare line side is updated to a value of VLANDOMAIN of the virtual jumper port; end.

[0016] Compared with the prior art, the present invention has the following advantages:

(1) in the present invention, POVE is instantiated to multicast in an upward direction to make a bridged connection, packet services take multicast as an exit from a service channel in the upward direction, and an OTN service takes the multicast as a source port to interact with an ODUK channel; POVE is instantiated to VLANDOMAIN in a downward direction for bridging, the OTN service maps a backplane port on the side of the line connected on the ODUK channel to VLANDOMAIN, and packet services use VLANDOMAIN as a common physical port to complete the classification processing of the package services accessed;

(2) the present invention adds a new type of port configuration, that is, the virtual bridging ports for packet services, while the other configurations are unchanged; for OTN service, virtual bridging ports corresponding to active and standby ODUK are added to complete the OTN service overlay and the active and standby ODUK protection functions; packet services are correlated with overlapping groups of OTN service through the same virtual bridging ports; when the OTN service configuration needs to be updated, only one backplane port on the line side corresponding to the virtual bridging port needs to be modified by incrementally issuing the OTN service configuration; as the virtual bridging port ID remains, the package service configuration does not need to be

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Updated 12/22 in this way; when the package service configuration needs to be updated, the OTN service configuration does not need to be modified, as it does not need to receive the contents of the package service configuration; through this method of service configuration management, the decoupling of the configuration between the packet service and the OTN service is performed, and a timing problem resulting from the incremental issuance of the service configuration is well resolved; and (3) the service forwarding process of the present invention is completed in a single process, without traditional circular processing, thereby improving the efficiency and operating stability of the system; in this particular, the multicast instantiated in POVE is completed by the multicast input, which does not affect the implementation of the QOS functions.

Brief Description of the Drawings [0017] Figure 1 is a schematic structural diagram of a POTN service routing system according to an embodiment of the present invention;

Figure 2 is a structural schematic diagram of a switch card for a POTN service routing system according to an embodiment of the present invention;

figure 3 is a process diagram of a service forwarding method in an upward direction according to an embodiment of the present invention;

figure 4 is a process diagram of a service forwarding method in a downward direction according to an embodiment of the present invention;

figure 5 is a process diagram of a method of emission of configuration in an upward direction according to an embodiment of the present invention;

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13/22 figure 6 is a process diagram of a method of issuing configuration in a downward direction according to an embodiment of the present invention;

figure 7 is a process diagram of a method of protection in an upward direction according to an embodiment of the present invention; and figure 8 is a process diagram of a method of protection in a downward direction according to an embodiment of the present invention.

Detailed Description of Modalities [0018] The present invention is further described in detail below with respect to the drawings and modalities.

[0019] As shown in figure 1, one embodiment of the present invention provides a POTN service routing system, which comprises an Ethernet branch card, a switching card and OTN line cards.

[0020] The Ethernet branch card is configured to transmit a packet service received from an Ethernet network to the switching card in an upward direction, and transmit a data packet received from the switching card to the Ethernet network in a downward direction.

[0021] The switching card is configured to implement the data interaction between the Ethernet branch card and the OTN line cards; the switch card comprises at least two backplane ports on the branch side connected to the Ethernet branch card and at least four backplane ports on the line side connected to the OTN line cards; one back plate port on the branch side is connected to an MPLS service forwarding channel, while the other back plate port on the branch side is

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14/22 connected to an Ethernet service forwarding channel; the MPLS service forwarding channel is also connected to two virtual bridging ports, each of which is connected to two backplane ports on the line side; the Ethernet service forwarding channel is connected to one of the two virtual bridging ports.

[0022] Multiple OTN line cards are configured to map the package service to an ODUK channel in the upward direction, and to demap the package service from the ODUK channel in the downward direction.

[0023] As shown in figure 2, the MPLS service forwarding channel comprises a first logical AC interface, a first virtual forwarding instance and a PW logical interface that are connected sequentially, and a pair of active and standby LSP interfaces connected to the PW logic interface; the active and standby LSP interfaces are connected to a virtual bridging port respectively.

[0024] The Ethernet service forwarding channel comprises a second logical AC interface, a second virtual forwarding instance and a third logical AC interface that are connected sequentially; the third logical AC interface is connected to one of the two virtual bridging ports.

[0025] As shown in figure 3, one embodiment of the present invention further describes a service routing method using the POTN service routing system, which comprises service routing in an upward direction, where service routing in an upward direction specifically comprises the following process:

Al: a packet service is received through a backplane port on the branch side, and an AC logical interface matched to the packet service is acquired according to the

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15/22 back plate on the side of the branch through which the package service passes and the characteristic value of the package service;

A2: a virtual routing instance connected to the logical AC interface acquired from step A1 is acquired;

A3: a logical interface in an outgoing direction is acquired according to the virtual routing instance acquired from step A2 and the characteristic value of the packet service; if the service is an Ethernet service, proceed to step A4; if the service is an MPLS service, proceed to step A8;

A4: the logical interface in the output direction is a logical AC interface connected to the virtual routing instance acquired from step A2;

A5: the physical table input information corresponding to the AC logic interface acquired from step A4 is displayed, and a virtual jumper port in the output direction and the AC logic interface encapsulation information are determined;

A6: the entry information of the multicast table corresponding to the virtual jumper port acquired from step A5 is displayed, and a back plate port on the line side in the outgoing direction is determined;

A7: the package service is routed to an ODUK channel through the back plate port on the line side acquired from step A6; end;

A8: the logical interface in the output direction is a PW logical interface connected to the virtual routing instance acquired from step A2;

A9: the physical table entry information corresponding to the PW logic interface acquired from step A8 is displayed, and an LSP interface linked to the PW logic interface and the encapsulation information of the

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16/22 PW logic interface are determined;

A10: the physical table entry information corresponding to the LSP interface acquired from step A9 is displayed, and a rear plate port on the line side in the output direction and the encapsulation information of the LSP interface is determined; and

A1 1: the package service is sent to an ODUK channel through the back plate port on the line side acquired from step A10; end.

[0026] As shown in figure 4, the service forwarding method comprises forwarding service in a downward direction, where forwarding service in a downward direction specifically comprises the following process:

Bl: a data packet is received through the virtual bridging port; a logical interface corresponding to the virtual bridging port is acquired according to VLANDOMAIN configured by a backplane port on the side of the line corresponding to the virtual bridging port and the characteristic value of the data packet; if the service is an Ethernet service, proceed to step B2; if the service is an MPLS service, proceed to step B8;

B2: the logical interface corresponding to the virtual bridging port is an AC logical interface connected to the virtual bridging port in step B1;

B3: a virtual routing instance connected to the logical AC interface acquired from step B2 is determined;

B4: an AC logic interface and a backplane port on the branch side in the outgoing direction are acquired according to the virtual routing instance acquired from step B3 and the characteristic value of the data packet;

B5: an OTN service is routed to a credit card

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17/22 Ethernet branch through the AC logic interface and the back plate port on the side of the branch acquired from step B4; end;

B6: the logical interface corresponding to the virtual bridging port is an LSP interface connected to the virtual bridging port in step B1;

B7: the LSP and PW labels of the LSP interface acquired from step B6 are syntactically analyzed layer by layer to acquire a virtual routing instance linked to the LSP interface;

B8: an AC logic interface and a backplane port on the branch side in the outgoing direction are acquired according to the virtual routing instance acquired from step B7 and the characteristic value of the data packet; and

B9: an OTN service is forwarded to the Ethernet branch card via the AC logic interface and the back plate port on the side of the branch acquired from step B8; end.

[0027] As shown in figure 5, one embodiment of the present invention further describes a method of sending a configuration using the POTN service forwarding system, which comprises the sending of a configuration in an upward direction, where the sending of a configuration in an upward direction specifically comprises the following process:

Cl: the switching card receives the settings and processes the settings separately according to the type of configuration; if the configuration is an MPLS service configuration, proceed to step C2; if the configuration is an Ethernet service configuration, proceed to step C7; if the configuration is an OTN service configuration, proceed to step Cl2;

C2: a virtual jumper port ID in the outgoing direction is acquired from the configuration received by an LSP interface;

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C3: the virtual bridging port ID is converted to a multicast ID according to a pre-set mapping rule, and a trigger interface function is invoked to create the multicast;

C4: whether multicast was created is determined according to the multicast ID; if yes, proceed directly to step C6; if not, proceed to step C5;

C5: multicast is created, whose association is now empty;

C6: the destination port type of the LSP interface is configured as multicast, and a corresponding trigger interface function is invoked to configure; the MPLS service configuration is completed; end;

C7: a virtual jumper port ID in the output direction is acquired from the configuration received by a logical AC interface;

C8: the virtual bridging port ID is converted to a multicast ID according to a pre-set mapping rule, and a trigger interface function is invoked to create the multicast;

C9: whether multicast was created is determined according to the multicast ID; if yes, proceed directly to step Cl 1; if not, proceed to the CIO step;

CIO: multicast is created, whose association is now empty;

Cll: the destination port type of the AC logical interface is configured as multicast, and a corresponding trigger interface function is invoked to configure; the MPLS service configuration is completed; end;

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Cl2: a virtual jumper port ID in an incoming direction and the corresponding backplane port information on the active and standby line side are acquired from the OTN service configuration;

C13: the virtual bridging port ID is converted to a multicast ID according to a pre-set mapping rule, and a trigger interface function is invoked to create the multicast;

C14: whether multicast was created is determined according to the multicast ID; if yes, proceed to step C15; if not, proceed to step C18;

C15: whether the OTN service configuration is configured differently before and after it is determined; if yes, proceed to step S16; if not, proceed to step S17;

C16: multicast association information is updated for the virtual jumper port and the backplane ports on the active and reserve line side corresponding to the virtual jumper port; end;

C17: the present multicast association information is maintained; end; and

Cl8: the new multicast is created, and the virtual bridging port and the corresponding backplane ports on the side of the active and reserve line are added to the multicast; the OTN service configuration is completed; end.

[0028] As shown in figure 6, the configuration issue method comprises the issue of configuration in a downward direction, in which the issue of configuration in a downward direction specifically comprises the following process:

Dl: the switching card receives the settings and processes

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20/22 the settings separately according to the type of configuration; if the configuration is an MPLS service configuration, proceed to step D2; if the configuration is an Ethernet service configuration, proceed to step D3; if the configuration is an OTN service configuration, proceed to step D6;

D2: MPLS service configuration is issued according to a normal MPLS service configuration process flow;

D3: a virtual jumper port ID in the incoming direction is acquired from the configuration received by a logical AC interface;

D4: the virtual jumper port ID is converted to a VLANDOMAIN ID according to a pre-set mapping rule;

D5: the configuration rule for the AC logic interface input port is configured as VLANDOMAIN, and the VLANDOMAIN ID acquired from D4 is configured for the AC logic interface input port; a trigger interface function is invoked to complete the Ethernet service configuration; end;

D6: a virtual jumper port ID in the output direction and the corresponding backplane port information on the active and standby line side are acquired from the OTN service configuration; and

D7: the virtual bridging port ID is converted to a VLANDOMAIN ID according to a preset mapping rule, and a trigger interface function is invoked to update the VLANDOMAIN domain of the backplane ports on the line side active and in reserve corresponding to the virtual bridge connection port; the OTN service configuration is completed; end.

[0029] As shown in figure 7, a modality of the present

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The invention further describes a protection method using the POTN service forwarding system, which comprises processing protection in an upward direction, where processing protection in an upward direction specifically comprises the following process:

El: if a channel fault exists, it is checked, and the fault is treated separately according to the type of fault; if the failure is an LSP channel failure, treatment proceeds to step E2; if the failure is an ODUK channel failure, the treatment ends;

E2: the active switching logic - in reserve LSP is executed, and a trigger interface function is invoked to perform the active switching - in reserve; and

E3: a FRR table is recorded, a chip is triggered to switch a service forwarding path, and the switching of the system is completed; end.

[0030] As shown in figure 8, the protection method comprises protection processing in a downward direction, where protection processing in a downward direction specifically comprises the following process:

Fl: if a channel fault exists, it is checked, and the fault is treated separately according to the type of fault; if the failure is an ODUK channel failure, treatment proceeds to step E2; if the failure is an LSP channel failure, the treatment ends;

F2: the active switching logic - in reserve ODUK is executed, and a trigger interface function is invoked to perform the active switching - in reserve;

F3: the switching direction is determined; if a backplane port on the spare line side is switched to a backplane port on the active line side, proceed to step F4; otherwise, proceed to step F5;

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F4: the VLANDOMAIN of the backplane port on the side of the active line corresponding to a virtual jumper port is updated to a value of VLANDOMAIN of the virtual jumper port, and the VLANDOMAIN of the back plate port on the line side in reserve is updated to an invalid value; end; and

F5: the VLANDOMAIN of the back plate port on the side of the active line corresponding to the virtual jumper port is updated to an invalid value, and the VLANDOMAIN of the back plate port on the reserve line side is updated to a value of VLANDOMAIN the virtual jumper port; end.

[0031] The present invention is not limited to the exposed modalities. Those skilled in the art can make improvements and polishes without departing from the principle of the present invention; such improvements and polishes must fall within the scope of protection of the present invention. Those not described in detail in the specification must be an earlier technology known to those skilled in the art.

Claims (9)

1. POTN service routing system, characterized by the fact that it comprises an Ethernet branch card, a switching card and OTN line cards, in which the Ethernet branch card is configured to transmit a packet service received from an Ethernet network for the switching card in an upward direction, and transmitting a data packet received from the switching card to the Ethernet network in a downward direction; the switch card is configured to implement data interaction between the Ethernet branch card and the OTN line cards; the switch card comprises at least two backplane ports on the branch side connected to the Ethernet branch card and at least four backplane ports on the line side connected to the OTN line cards; one backplane port on the branch side is connected to an MPLS service forward channel, while the other back plate port on the branch side is connected to an Ethernet service forward channel; the MPLS service forwarding channel is also connected to two virtual bridging ports, each of which is connected to two backplane ports on the line side; the Ethernet service forwarding channel is connected to one of the two virtual bridging ports; and multiple OTN line cards are configured to map the package service to an ODUK channel in the upward direction, and to demap the package service from the ODUK channel in the downward direction. 2. POTN service forwarding system according to claim 1, characterized by the fact that the MPLS service forwarding channel comprises a first logical interface Petition 870190025993, of 03/19/2019, p. 34/50 2/9 AC, a first instance of virtual routing and a PW logic interface that are connected sequentially, and a pair of active and standby LSP interfaces connected to the PW logic interface; the active and standby LSP interfaces are respectively connected to a virtual bridging port; and the Ethernet service forwarding channel comprises a second logical AC interface, a second virtual forwarding instance, and a third logical AC interface that are connected sequentially; the third logical AC interface is connected to one of the two virtual bridging ports. 3. Service forwarding method using the POTN service forwarding system as defined in claim 1, characterized by the fact that it comprises service forwarding in an upward direction, where service forwarding in an upward direction specifically comprises the following process: Al: receive a packet service through a backplane port on the branch side, and acquire an AC logical interface matched with the packet service according to the backplate port on the branch side through which the packet service passes and the characteristic value of the package service; A2: acquire a virtual routing instance connected to the AC logical interface acquired from step Al; A3: acquire a logical interface in an outbound direction according to the virtual routing instance acquired from step A2 and the value of the package service characteristic; if the service is an Ethernet service, proceed to step A4; if the service is an MPLS service, proceed to step A8; A4: the logical interface in the output direction is an AC logical interface connected to the virtual routing instance acquired from Petition 870190025993, of 03/19/2019, p. 35/50 3/9 from step A2; A5: view the physical table input information corresponding to the AC logic interface acquired from step A4, and determine a virtual jumper port in the output direction and the encapsulation information of the AC logic interface; A6: view the input information from the multicast table corresponding to the virtual jumper port acquired from step A5, and determine a backplane port on the line side in the outgoing direction; A7: forward the package service to an ODUK channel through the back plate port on the side of the line acquired from step A6, and finish; A8: the logical interface in the output direction is a PW logical interface connected to the virtual routing instance acquired from step A2; A9: view the physical table entry information corresponding to the PW logic interface acquired from step A8, and determine an LSP interface connected to the PW logic interface and the encapsulation information of the PW logic interface; A10: view the physical table input information corresponding to the LSP interface acquired from step A9, and determine a backplane port on the line side in the output direction and the encapsulation information of the LSP interface; and All: forward the package service to an ODUK channel through the back plate port on the line side purchased from step A10, and finish. 4. Service routing method according to claim 3, characterized by the fact that it comprises service routing in a downward direction, in which the Petition 870190025993, of 03/19/2019, p. 36/50 4/9 forwarding service in a downward direction specifically comprises the following process: Bl: receive a data packet via the virtual jumper port, and acquire a logical interface corresponding to the virtual jumper port according to VLANDOMAIN configured by a backplane port on the side of the line corresponding to the connection port virtual bridge and the characteristic value of the data package; if the service is an Ethernet service, proceed to step B2; if the service is an MPLS service, proceed to step B8; B2: the logical interface corresponding to the virtual bridging port is an AC logical interface connected to the virtual bridging port in step B1; B3: determine a virtual routing instance connected to the AC logical interface acquired from step B2; B4: acquire an AC logic interface and a back plate port on the side of the branch in the outgoing direction according to the virtual routing instance acquired from step B3 and the characteristic value of the data packet; B5: forward an OTN service to an Ethernet branch card through the AC logic interface and the back plate port on the side of the branch acquired from step B4, and finish; B6: the logical interface corresponding to the virtual bridging port is an LSP interface connected to the virtual bridging port in step B1; B7: parse the LSP and PW labels of the LSP interface acquired from step B6 layer by layer to acquire a virtual routing instance linked to the LSP interface; B8: acquire an AC logic interface and a back plate port on the branch side in the outgoing direction according to the instance Petition 870190025993, of 03/19/2019, p. 37/50 5/9 of virtual routing acquired from step B7 and the characteristic value of the data packet; and B9: forward an OTN service to the Ethernet branch card via the AC logic interface and the back plate port on the side of the branch acquired from step B8, and finish. 5. Configuration issue method using the POTN service forwarding system as defined in claim 1, characterized by the fact that it comprises configuration issue in an upward direction, wherein the configuration issue in an upward direction specifically comprises the following process: Cl: receive the settings via the switch card and process the settings separately according to the type of configuration; if the configuration is an MPLS service configuration, proceed to step C2; if the configuration is an Ethernet service configuration, proceed to step C7; if the configuration is an OTN service configuration, proceed to step Cl2; C2: acquire a virtual jumper port ID in the direction of output of the configuration received by an LSP interface; C3: convert the virtual bridging port ID into a multicast ID according to a pre-set mapping rule, and invoke a trigger interface function to create multicast; C4: determine if multicast was created according to the multicast ID; if yes, proceed directly to step C6; if not, proceed to step C5; C5: create multicast, whose association is now empty; C6: configure the destination port type of the LSP interface as multicast, and invoke a corresponding trigger interface function to configure; complete the MPLS service configuration, and Petition 870190025993, of 03/19/2019, p. 38/50 6/9 finish; C7: acquire a virtual jumper port ID in the direction of output of the configuration received by a logical AC interface; C8: convert the virtual bridging port ID into a multicast ID according to a pre-set mapping rule, and invoke a trigger interface function to create multicast; C9: determine if multicast was created according to the multicast ID; if so, proceed directly to step Cll; if not, proceed to the CIO step; CIO: create multicast, whose association is now empty; Cll: configure the destination port type of the logical AC interface as multicast, and invoke a corresponding trigger interface function to configure; complete the MPLS service configuration, and finish; Cl2: acquire a virtual jumper port ID in an input direction and the corresponding backplane port information on the side of the active line and in reserve for the OTN service configuration; C13: convert the virtual bridging port ID into a multicast ID according to a pre-set mapping rule, and invoke a trigger interface function to create multicast; C14: determine if multicast was created according to the multicast ID; if yes, proceed to step C15; if not, proceed to step Cl8; C15: determine whether the OTN service configuration is configured differently before and after; if yes, proceed to step S16; if not, proceed to step S17; C16: update multicast association information Petition 870190025993, of 03/19/2019, p. 39/50 7/9 in relation to the virtual bridging port and the back plate ports on the side of the active and reserve line corresponding to the virtual bridging port, and finish; C17: maintain the present multicast association information, and finish; and Cl8: create a new multicast, and add the virtual bridge connection port and the corresponding back plate ports on the side of the active line and in reserve in the multicast; complete the OTN service configuration, and finish. 6. Configuration emission method according to claim 5, characterized in that it comprises configuration emission in a downward direction, in which the configuration emission in a downward direction specifically comprises the following process: DL: receive the settings via the switching card, and process the settings separately according to the type of configuration; if the configuration is an MPLS service configuration, proceed to step D2; if the configuration is an Ethernet service configuration, proceed to step D3; if the configuration is an OTN service configuration, proceed to step D6; D2: issue the MPLS service configuration according to a normal MPLS service configuration process flow; D3: acquire a virtual jumper port ID in the direction of input of the configuration received by a logical AC interface; D4: convert the virtual bridging port ID into a VLANDOMAIN ID according to a pre-set mapping rule; D5: configure the gateway configuration rule for the AC logical interface as VLANDOMAIN, and configure the gateway for the Petition 870190025993, of 03/19/2019, p. 40/50 8/9 AC logical interface with VLANDOMAIN ID; invoke a trigger interface function to complete the Ethernet service configuration, and finish; D6: acquire a virtual jumper port ID in the outgoing direction and the corresponding backplane port information on the side of the active line and in reserve from the OTN service configuration; and D7: convert the virtual bridging port ID into a VLANDOMAIN ID according to a pre-set mapping rule, and invoke a trigger interface function to update the VLANDOMAIN domain of the backplane ports on the active line side and in reserve corresponding to the virtual bridge connection port; complete the OTN service configuration, and finish. 7. Protection method using the POTN service forwarding system as defined in claim 1, characterized by the fact that it comprises protection processing in an upward direction, where protection processing in an upward direction specifically comprises the following process: El: check if a channel fault exists, and treat the fault separately according to the type of fault; if the fault is an LSP channel fault, proceed to step E2; if the failure is an ODUK channel failure, terminate; E2: execute the active switching logic - in reserve LSP, and invoke a trigger interface function to execute the active switching - in reserve; and E3: switching a service routing path, and completing the switching; finish. 8. Protection method using the POTN service forwarding system according to claim 7, characterized by the fact that it comprises protection processing in a downward direction, Petition 870190025993, of 03/19/2019, p. 41/50 9/9 where protection processing in a downward direction specifically comprises the following process: Fl: check if a channel fault exists, and treat the fault separately according to the type of fault; if the failure is an ODUK channel failure, proceed to step E2; if the failure is an LSP channel failure, terminate; F2: execute the active switching logic - in reserve ODUK, and invoke a trigger interface function to carry out the active switching - in reserve; F3: determine the switching direction; if a backplane port on the spare line side is switched to a backplane port on the active line side, proceed to step F4; otherwise, proceed to step F5; F4: update VLANDOMAIN of the backplane port on the side of the active line corresponding to a virtual jumper port to a value of VLANDOMAIN of the virtual jumper port, and update VLANDOMAIN of the backplane port on the reserve line side for an invalid value; finish; and F5: update the VLANDOMAIN of the back plate port on the side of the active line corresponding to the virtual jumper port to an invalid value, and update the VLANDOMAIN of the back plate port on the reserve side to a value of VLANDOMAIN of the port virtual bridge connection; finish.