KR950011481B1 - An electronic exchanger - Google Patents

Abstract

The alarm address for nodes in an inter processor communication unit is generated by a software. The method comprises the steps of; (A)reading current reference alarm status information; (B)generating an alarm corresponding to alarm generate request for each nodes; (C)reading alarm information for an alarm generated in the step (B); (D)generating unique alarm address by using alarm information; and (E)recording the unique alarm address on a node table.

Description

Alarm address generation method and system of alarm address generation in interprocessor communication network of exchange

1 is a block diagram of a hardware system applied to the present invention.

2 is a flow chart of generating alert addresses for nodes.

* Explanation of symbols for main parts of the drawings

IPCU: Inter-Processor Communication Unit

CI: Control Interworking (Node)

CIPH: Control Interworking Processor Hardware

FI: Fault Interface

D-bus: Data Bus

M-bus: Maintenance Bus (communication bus between node and node manager)

U-link: Unit Link

N-Alarm: Node Alam (Alarm Signal for Node Failure)

NFF-Alarm: Node Function Fail Alarm Signal

MFF-Alarm: Manager Function Fail

The present invention relates to an alert address generation method and an alert address generation system of a node in an interprocessor communication network.

The present invention is performed in the initialization stage of an inter-processor unit, which is a basic unit constituting an inter-processor communication network, in a large-capacity electronic switching system having a distributed control structure, and is a component of an inter-processor communication unit (IPCU). Create alarm address of each node by using only one alarm signal for each node in IPCU without having a separate hardware alarm address for each node. It aims to do it.

The present invention provides a method for generating an alarm address for each node for the alarm processing of the furnaces in the IPCU constituting the interprocessor communication network in a large-capacity electronic switch having a distributed control structure according to the present invention for achieving the above object, A first step of reading current reference alarm status information for use in an alarm address extraction step, a second step of generating an alarm for each node and an alarm generation request for each node after the first step, and the second step A third step of reading alarm information from the generated alarm, a fourth step of extracting a unique alarm address by performing a series of association processes using the reference alarm status information and the actual alarm status information after the third step, and And a fifth step of recording the unique alarm address extracted in the node table for node management after the fourth step. The.

In addition, the apparatus according to the present invention is a node block means (CI) for the transmission and reception of inter-processor communication (IPC) messages via D-bus and U-link to exchange messages between the high speed processor, the node block means and A node manager which exchanges information through the M-Bus, inputs an alarm signal from the node block means through an alarm signal line in the event of a failure, and sends an alarm when a failure occurs, and an alarm from the node manager. Input through the alarm collection line of, characterized in that the alarm collecting means for collecting the alarm.

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

1 is a hardware configuration diagram for the maintenance function of the interprocessor communication unit. The node block (C1) 1 is connected to the D-Bus (2) and the U-link (3) in order to exchange messages between the high speed processors. It is responsible for the transmission and reception of interprocessor communication (IPC) messages, and monitors the status of IPC transmission and reception channels and exchanges information through NM-Bus (5) with the Node Manager (CIPH) block. The alarm signal is transmitted using the (N-Alarm) signal (6). The CIPH block, which is in charge of network network maintenance and operation, monitors and controls the various states of the nodes in the IPCU and exchanges information when necessary through the IPC communication channel. Alarm (7) is sent out. Regarding the alarm of the node, each node is connected to each N-Alarm signal to CIPH, and in the CIPH block, one alarm signal (NFF-Alarm) (8) is collected for alarms of multiple (32) CIs. It is sent to the alarm collection block. Therefore, since alarm information of multiple CIs in one IPCU is integrated into one hardware signal in CIPH and transmits an alarm, node alarm address is not only checked for the status of the whole node but also to know the alarm status of each node. Take advantage.

2 is a flow chart of a function of generating an alarm address for each node in an IPCU required for initializing a network by software in a CI / CIPH block. In order to generate the alarm address of each node, hardware alarm signal (NFF) related to failure processing of CI to prevent unnecessary node alarm signal that is generated when generating the alarm address of each node to the alarm collection block (FI) -Alarm) (11). In order to use the alarm status of the current nodes as reference alarm status information in the alarm address extraction process, the current alarm status information is read (12), and the node generating the alarm maintains the alarm signal as 'O'. After extracting the address of the node indicated by the current table pointer from the node information table for managing the nodes (13), requesting to send an alarm to the node with the corresponding address through the M-bus (14), and registering a timer. (15), it is in a waiting state until there is a response to the alarm sending request (16), and determines whether there is a response (17), if there is no response, the alarm address of the node has no effect when checking the alarming node. Allocate an address (an alarm tank in which there are no alarm signals, that is, an alarm signal of all nodes with a '1' status) and perform items (18) and (22). If there is a normal response, the alarm status information of the nodes is read (19), and the reference alarm status information and the current alarm status are first read through the calculation process so that the alarm address of each node has a unique alarm address. The alarm address of the node is extracted (20). The operation process of item (20) performs bitwise exclusive OR operation on the reference alarm state information of (12) and the alarm state information of item (19), and then returns the result of '1's complement (1's Complement). do. The result of this operation is that only the alarm signal value of its own value is '0' for each node and '1' for other nodes. Therefore, even if several nodes are in an alarm state at the same time, by performing this operation, only the alarm signal of the node responding to the actual alarm request is masked and the alarm signal of other nodes is masked so that each node can always have its own alarm address. . After performing item (20), the alarm address of the node obtained in item (20) is registered in the node related table (21). If the current node table pointer indicates the last node of the table (22), if it is not the last node, the node table pointer is adjusted to point to the next node (23) and (12). If the current node table pointer points to the last node, and if the table pointer in the node table points to the last node, the hardware associated with the failure of the CI is generated because it generates a unique alarm address for all nodes in the node table. Connect the signal (NFF Alarm) so that it can be delivered normally to the system alarm collection block (24), and finish the alarm address generation process for the nodes.

In the present invention, by using the alarm address generation process as described above, a distributed interprocessor communication unit required at the time of initializing the communication network to perform the failure processing and maintenance function of the interprocessor communication network of a large-capacity electronic switchboard having a distributed control structure ( Regardless of where the node is mounted, unique alarm addresses for multiple (32) nodes accommodated in the IPCU are not affected even when alarms are generated from multiple nodes simultaneously, and separate hardware alarms for each node. Instead of using an address, one alarm signal for each node and software located in the node and node manager can be used to easily generate a unique alarm address for each node, and also one alarm signal for each node. Because only the hardware to implement is simple, you can increase the reliability of the system, Since each node generates unique alarm address by software instead of fixed alarm address by hardware, it has a feature that can easily adapt to the change of network configuration.

As described above, the hardware signal for alarm processing can be reduced as much as possible in the node alarm processing of a communication network accommodating a large number of nodes, and it can be applied to a computer network and a communication network requiring high reliability for failure processing of the communication network.

Claims (2)

A method of generating an alarm address for each node for alarm processing of nodes in an IPCU constituting an interprocessor communication network in a large-scale electronic switch having a distributed control structure, the current reference alarm state for use in an alarm address extraction step A first step of reading information, a second step of generating an alarm for an alarm generation request and an alarm generation request for each node after the first step, and a third step of reading alarm information from an alarm generated after the second step A fourth step of extracting a unique alarm address by performing a series of calculation processes using the reference alarm status information and the actual alarm status information after the third step, and extracting the node table for node management after the fourth step; And a fifth step of recording the unique alarm address. Node block means (CI) 1 for handling transmission and reception of inter-processor communication (IPC) messages via D-Bus 2 and U-link 3 to exchange messages between high-speed processors; Information exchange is performed through the node block means 1 and the M-Bus 5, and when an error occurs, an alarm signal is input from the node block means 1 through an alarm signal line 6, and an alarm is generated when a failure occurs. A node manager 4 having a function of transmitting; And an alarm collecting means (7) for inputting an alarm from the node manager (4) through one alarm collecting line (8) to collect the alarms.