KR100545791B1 - Fault detection method for redundant switch ICs in systems with internal ICs for control - Google Patents

Abstract

The present invention is a system having a control internal IPC for detecting a switch IPC failure by identifying whether there is an abnormality of the IPC communication disconnection or internal communication of the redundant switch using the internal communication between the IPC communication and the redundant switch in the system having the control internal IPC. The redundancy switch of the IPC failure detection method.

According to an embodiment of the present invention, when an upper host transmits a switch IPC request to a first switch of a redundant switch, the first switch responds through the first switch IPC communication path and then the request through an internal communication path with the redundant second switch. In the method of detecting a redundant switch IPC failure in a system having a control internal IPC responding to the request via a second switch IPC communication path to the second switch, Initiating an internal communication state between an IPC communication state and the redundant switch; Requesting switch IPC information from a first switch and a second redundant switch and waiting for a response to the request from a first switch and a second redundant switch through a first switch IPC communication path; And a third step of checking whether to receive a response from the first and second switches, and determining a first and second switch IPC communication state and an internal communication state between the redundant switches according to whether the response is received.

According to the present invention, there is an effect of simplifying the switch management while reducing the load for monitoring the IPC communication sharing the data cell and the control data cell.

Internal IPC, Redundant Switch, Internal Communication, Error Detection, Data Cell, Control Cell

Description

An IPC Error Supervision Method for a Duplicate Switch for a System with a Controllable Internal IPC}

1 is a structure diagram of a switch fabric consisting of a conventional unit switch and a combined switch.

2 is a schematic diagram of a combined switch fabric of an input buffer having a VOQ and a crossbar switch.

3 is a schematic diagram of a distributed switch fabric consisting of a simple switch and a combined switch in a system having an internal IPC for control according to the present invention.

4 is a schematic diagram of a combined switch fabric structure of an input buffer having a VOQ and a crossbar switch in a system having a control internal IPC according to the present invention.

5 is a structural diagram of transmission and reception data using an internal IPC for control according to the present invention.

6 is a flowchart illustrating a process of detecting a redundant switch IPC failure of a system having an internal IPC for controlling according to the present invention.

 Explanation of symbols on the main parts of the drawings

40,42: Input buffer with VOQ 41,43,45: Processor for switch control

44: redundant crossbar switch 47b, c: IPC communication path

40a, 42a: data cell path 48: internal IPC switch for control

The present invention relates to a method for detecting a failure of a redundant switch interprocessor communication (IPC), and particularly, in an IPC communication disconnection switch or an internal switch between the redundant switches in a system having an internal IPC for control. The present invention relates to a redundant switch IPC failure detection method of a system having an internal IPC for controlling a switch IPC failure by detecting an abnormality of communication.

In general, the switch is responsible for the connection and exchange function with the subscriber's module. The switch configuration can be divided into data plane and control plane. The data plane plays the basic role of the switch, exchanging data, multiplexing and demultiplexing, and the control plane is responsible for the operation, status, test, fault and fault detection functions within the switch.

Conventional switch control has been performed centrally by mounting in the same module when the switch is a single structure or a multistage structure. However, as switch capacity increases or becomes a scalable switch fabric, centralized management becomes difficult. Thus, state management of distributed structures was required. The distributed architecture means that there is a controller that controls independent switches. In this case, the controller generally refers to a processor in which an FW driver for controlling a corresponding switch is mounted. The switch FW is responsible for control, state management, and communication with the switch management block. This distributed architecture is handled by the IPC.

1 and 2 are block diagrams of a conventional distributed switch structure. The conventional distributed switch has a structure in which each controller or processor loads or receives an FW to control the corresponding switch and transmits and receives switch state management information using IPC.

First, Figure 1 is a block diagram of a conventional switch fabric structure, showing a switch fabric 100 structure consisting of a unit switch and a combined switch. The plurality of unit switches 10, 12 and combination switch 14 have respective controllers 11, 13, 15, which control the switches. The actual data cell uses the user data paths 10a and 12a and the control cell uses the control unit communication paths 11a and 13a. This structure is a distributed IPC structure in which the cell data path and the control cell path are shared.

2 is a block diagram of an input buffer and crossbar switch coupled switch fabric structure with a conventional VOQ. Referring to FIG. 2, the input buffers 20 and 22 and the crossbar switches 24 with VOQ have respective control processors 21 and 23 and 25 which control the switches. The actual data cell uses switch fabric links 20a and 22a and the control cell uses processor communication paths 21a and 23a. The structure of the conventional combined switch fabric 200 shown in FIG. 2 is a distributed IPC structure in which a cell data path and a control cell path are shared.

However, in the conventional distributed IPC structure, management complexity and data inconsistency that control IPC communication between distributed processors may occur. For example, in a structure using a control cell in a data cell, there is a problem in that an IPC communication controller is required separately and a method for separately monitoring an IPC failure function is required.

Meanwhile, Korean Patent Application No. 2000-80741 discloses a method of managing status monitoring of each processor in a distributed processor using IPC communication, and Korean Patent Registration No. 0221525 discloses a failure of an IPC controller of an ATM switch. A detection method is disclosed. In the case of the above patent, the disconnection state of the IPC communication between the switch management system and the redundant switch or the communication abnormality in the switch board in the IPC system has not been determined.

The present invention has been proposed to solve the above-mentioned problems of the prior art, in which a switch is configured in a distributed structure using an internal IPC for control, disconnection of internal processor-to-processor IPC communication or internal communication between redundant switches using redundant communication between redundant switches. It is an object of the present invention to provide a redundant switch IPC failure detection device of a system having an internal IPC for controlling the failure of the switch IPC by detecting an abnormality.

In order to achieve the above object, the present invention transmits a switch IPC request from a higher host to a first switch of a redundant switch, and then the first switch responds through the first switch IPC communication path and then internally with the second redundant switch. In a redundant switch IPC failure detection method in a system having an internal IPC for control that transmits the request to the second switch via a communication path, and the second switch responds to the request via a second switch IPC communication path. In

Initiating an IPC communication state with a redundant switch and an internal communication state between the redundant switch; Requesting switch IPC information from a first switch and a second redundant switch and waiting for a response to the request from a first switch and a second redundant switch through a first switch IPC communication path; And a third step of checking whether to receive a response from the first and second switches, and determining a first and second switch IPC communication state and an internal communication state between the redundant switches according to whether the response is received.

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the present invention will be described in more detail the present invention.

3 is an internal IPC block diagram of a distributed switch fabric consisting of a simple switch and a combined switch in a system having a control internal IPC in accordance with the present invention. 3, the distributed switch fabric 300 according to the present invention has an internal IPC switch 38 for control. The plurality of unit switches 30 and 32 and the coupling switch 34 have respective control units 31 and 33 and 35, each of which controls the corresponding switch. The coupling switch 34 is doubled to an A side and a B side. The actual data cells between the unit switches 30, 32 and the combined switch 34 use user data paths 30a, 32a, respectively, and the control cell uses control internal IPC communication paths 37b, 37c. As shown in the figure, the paths 30a and 32a for data cell transmission and the control internal IPC communication paths 37b and 37c for control cell transmission are separated. The state of the distributed switch using the control internal IPC communication paths 37b and 37c for the control cell separated from the data cell paths 30a and 32a in the system having such a distributed switch fabric 300 structure. Collect information for surveillance. In addition, it is possible to determine whether the combined switch is abnormal by checking whether the IPC communication is disconnected by using the internal communication path of the redundant combined switch 34.

4 is an internal IPC block diagram of a combined switch fabric of an input buffer and crossbar switch with VOQ in a system with an internal IPC for control in accordance with the present invention. As shown in Fig. 4, the combined switch fabric 400 according to the present invention preferably has an internal IPC switch 48 for control. Input buffers 40 and 42 and crossbar switches 34 having a plurality of VOQs have respective control processors 41 and 43 and 45, each of which controls the switch. The crossbar switch 44 is doubled into an A side and a B side. The actual data cells between the input buffers 40 and 42 having the VOQ and the crossbar switch 44 use user data paths 40a and 42a, respectively, and the control cells are internal IPC communication paths 47b for internal control ( 47c). As shown in the figure, the paths 40a and 42a for data cell transmission and the internal IPC communication paths 47b and 47c for control cell transmission are separated. State of the distributed switch using the control internal IPC communication paths 47b and 47c for the control cell separated from the data cell paths 40a and 42a in the system having such a distributed switch fabric 400 structure. Collect information for surveillance. In addition, it is possible to determine whether the combined switch is abnormal by checking whether the IPC communication is disconnected using the internal communication path of the redundant crossbar switch 44. Although not shown in the figure, the switch state management unit collects and manages state information of the switches.

Hereinafter, for convenience of description, the present invention will be described using an input buffer having VOQ and a crossbar switch coupled switch fabric 400 as shown in FIG. 4. However, it is noted that the present invention is not limited and is also applicable to the switch fabric 300 of FIG.

Referring to FIG. 4, when the switch state management unit, which is an upper host, requests information of the A side crossbar switch 44-1, when the internal IPC communication path is normal, the A side crossbar switch 44-1 switches to the switch state management unit. Sends a response and then transmits the information to the B side crossbar switch 44-2 using a redundant internal communication path connected to the redundant B side crossbar switch 44-2, and the redundant internal communication path. When the B side crossbar switch 44-2, which is the receiving side, becomes a cell for the information request, the B side crossbar switch 44-2 transmits the information to the upper side of the corresponding side. That is, when the IPC communication path and the crossbar switch are normal, the first response on the side that made the response request and the second response on the redundant opposite side are returned. At this point, both responses on the A side and B side return to the same value. For example, if a response request is made to the A side and the response is returned only at the B side, the IPC communication path to the A may be normal and it may be determined that an abnormality has occurred when returning.

5 is a structural diagram of transmission and reception data using an internal IPC for control according to the present invention. As shown in FIG. 5, the transmit / receive data structure 50 using the control internal IPC according to the present invention includes A / B side information 51 indicating the A / B side of the redundant crossbar switch 44, and transmit / receive. Message type information 52 indicating the type of message to be displayed, message length information 53 indicating the length of the message payload, and message content information 54 indicating the content of the corresponding message. The message structure 50 shown in FIG. 5 is preferably a message format defined by the switch state manager according to the present invention for the switch IPC. That is, the switch state manager selects the A / B side of the redundant crossbar switch through the message format, selects a corresponding message type, displays a message payload length, and fills a corresponding message content.

6 is a flowchart illustrating a process of detecting a redundant switch IPC failure of a system having an internal IPC for controlling according to the present invention. Referring to Figure 6 describes a redundant switch IPC failure detection process according to the present invention. First, the A / B side IPC communication state and the switch internal communication state are initialized (S1). If there is a response for each side of the A / B side IPC request (S2), the A / B side IPC communication status is set to normal (S3) and the A / B side IPC communication status is normal. It ends. However, when there is no response for each side in the A / B side IPC request in step S2 (S2), it is determined whether there is no response for each side in the A / B side IPC request (S4), and the response is returned. If none is found, the A / B side IPC communication state is set to abnormal (S5). If only one response is returned, it is determined whether the IPC request is a request for the A side (S6). As a result of the determination in step S6, if the IPC request is an A side request, it is determined whether the returned one response is a response of the A side (S7), and if it is an A side response, the process of FIG. 6 (b) is performed. If the A side response is not the B side response, the process of FIG. 6C is performed. In step S7, it is determined whether one response returned when the IPC request is a request for the A side is a response from the A side or a B side. On the other hand, if the determination result in step S6 is that the IPC request is not the A side request, that is, the B side request, it is determined whether the returned one response is the response of the B side (S8). If the process of FIG. 6 (d) is performed and the response is not the B side response, that is, the A side response, the process of FIG. 6 (e) is performed. In the step S8, it is determined whether one response returned when the IPC request is a request for the B side is a response of the B side or an A side.

First, with reference to Fig. 6 (b), the case where only the response of the A side is returned when it is the A side request (S6) will be described (S7). When the response of the A side returns when the A side request is returned, the A side IPC communication state is set to normal (S11), and the B side IPC request is performed to determine the state of the B side (S12). If there is a response from the B side to the request (S13), it is determined that the B-side IPC communication state is normal and the internal communication state of the switch is abnormal (S14). As a result of the determination in step S13, when there is no response of the B side (S13), and when there is an A side response (S15), it is determined that the B side IPC communication state is abnormal and the internal communication state of the switch is normal (S16). If there is no A side response (S15), it is determined that the B side IPC communication state is abnormal and the internal communication state of the switch is abnormal (S17).

Next, with reference to FIG. 6 (c), the case where only the response of the B side is returned at the time of the A side request (S6) will be described (S7). When the response of the A side returns when the A side request is returned, it is determined that the A side IPC communication state is abnormal (S21), and performs the B side IPC request to determine the state of the B side (S22). If there is a response from the B side to the request (S23), the B side IPC communication state is set to normal and the internal communication state of the switch is initialized because it is undeterminable (S24). If there is no response from the B side to the request (S23), the B side IPC communication state is set to abnormal and the internal communication state of the switch is initialized because it is undeterminable (S25).

Next, with reference to Fig. 6 (d), the case where only the response of the B side is returned (S8) when the B side request is made (S6) will be described. If the response of the B side returns when the B side request is returned, it is determined that the B side IPC communication state is normal (S31), and the A side IPC request is performed to determine the state of the A side (S32). If there is a response from the A side to the request (S33), it is determined that the A side IPC communication state is normal and the internal communication state of the switch is abnormal (S34). If there is no response from the A side to the request (S33), it is determined whether there is a B side response (S35). If there is a B side response, it is determined that the A side IPC communication state is abnormal and the internal communication state of the switch is normal (S36). If there is no B side response, it is determined that the A side IPC communication state is abnormal and the internal communication state of the switch is abnormal (S37).

Finally, with reference to Fig. 6E, the case where only the response of the A side is returned when it is the B side request (S6) will be described (S8). If the response of the A side is returned during the B side request, it is determined that the B side IPC communication state is abnormal (S41), and the A side IPC request is performed to determine the state of the A side (S42). If there is a response from the A side to the request (S43), the A side IPC communication state is set to normal and the internal communication state of the switch is initialized because it is undeterminable (S44). If there is no response from the A side to the request (S43), the A side IPC communication state is set to abnormal and the internal communication state of the switch is initialized because it is undeterminable (S45).

Through the process of FIGS. 6 (a) to 6 (e), the switch state manager detects the internal IPC state of the switch and manages it. In addition, by periodically monitoring the state of each switch, the state of each switch is stored in a database, and the stored value is used to communicate with the upper switch state manager.

The detailed description and drawings set forth above disclose the preferred embodiments of the present invention for the convenience of description of the present invention and the present invention is not limited thereto. In addition, the present invention described above may be variously substituted, modified, and changed by those skilled in the art without departing from the technical spirit of the present invention.

Accordingly, the scope of the present invention will be determined by the appended claims rather than by the foregoing description and drawings.

The redundant switch state management method of the system having the internal IPC for the control cell of the present invention as described above, by using switch information collection using the IPC communication path for the control cell and the information using the communication inside the redundant switch Since it is possible to determine whether an IPC communication disconnection or an internal communication error occurs in the redundant switch, there is an effect of simplifying switch management while reducing the load for monitoring IPC communication sharing a data cell and a control data cell.

Claims (5)

When the host transmits the switch IPC request to the first switch of the redundant switches, the first switch responds through the first switch IPC communication path and then sends the request to the second switch through the internal communication path with the redundant second switch. A redundant switch IPC failure detection method in a system having an internal IPC for control that transmits to a switch and the second switch responds to the request through a second switch IPC communication path, Initiating an IPC communication state with a redundant switch and an internal communication state between the redundant switch; Requesting switch IPC information from a first switch and a second redundant switch and waiting for a response to the request from a first switch and a second redundant switch through a first switch IPC communication path; And A third step of checking whether to receive a response from the first and second switches, and determining a first and second switch IPC communication state and an internal communication state between the redundant switches according to whether the response is received; Redundant switch IPC failure detection method in a system having an internal IPC for control comprising a. The method of claim 1, wherein the third step, Redundancy in a system having an internal IPC for control, characterized in that when a response is received from both the first and second switches, the first and second switch IPC communication states and the internal communication state between the redundant switches are determined to be normal. How to detect switch IPC failures. The method of claim 1, wherein the third step, If the response is not received from the first and second switch, the first and second switch IPC communication status of the duplicated switch IPC failure detection method in a system having a control internal IPC characterized in that the abnormal. The method of claim 1, wherein the third step, If a response is received only from the first switch, Determining the state of the first switch IPC communication as normal; Requesting switch IPC information from the second switch and waiting to receive a response to the request from the first and second switches; Determining a second switch IPC communication state as normal when a response is received from the second switch, and determining an internal communication state between the redundant switches as abnormal; And If no response is received from the second switch, check whether there is a response from the first switch. If there is a response from the first switch, the second switch IPC communication status is abnormal, and the internal communication status is determined to be normal, and the first switch is determined. And determining that the second switch IPC communication state is abnormal and the internal communication state is abnormal when there is no response from the control unit. The method of claim 1, wherein the third step, If a response is received only from the second switch, Determining that the first switch IPC communication state is abnormal; Requesting switch IPC information from the second switch and waiting to receive a response to the request from the second switch; Determining a second switch IPC communication state as normal when a response is received from the second switch, and initializing an internal communication state between the redundant switches; And Determining that the second switch IPC communication state is abnormal when the response is not received from the second switch and initializing an internal communication state between the redundant switches. IPC failure detection method.

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