KR100290673B1 - Signaling protocol processing apparatus and method in atm switch - Google Patents

Abstract

Disclosed are an apparatus and method for processing signaling protocol in an asynchronous transport mode switch. The processing apparatus includes a call processing unit, a call connection control protocol processing unit, a signaling asynchronous transmission mode adaptation layer protocol processing unit, and an asynchronous transmission mode adaptation layer type 5 processing unit, and includes a call processing unit, call connection control protocol processing unit, and signaling asynchronous transmission mode adaptation layer. The protocol processor, the asynchronous transmission mode adaptive layer type 5 processor, respectively, include a processor for processing a message delivered from an upper layer and a processor for processing a message delivered from a lower layer. In the present processing method, the call processing unit, the call connection control protocol processing unit, the signaling asynchronous transmission mode adaptation layer protocol processing unit, and the asynchronous transmission mode adaptation layer type 5 processing unit respectively process the message delivered from the upper layer and the lower layer. Processing the received message. In addition, by configuring each layer of the signaling protocol by the method of the present invention, efficient task scheduling is possible, thereby reducing call establishment failure caused by unnecessarily delaying message processing. Improve overall call processing.

Description

SIGNALING PROTOCOL PROCESSING APPARATUS AND METHOD IN ATM SWITCH}

The present invention relates to a signaling protocol processing unit of an asynchronous transfer mode (ATM) exchange and an apparatus and method for transmitting message information between layers, and more particularly, to an apparatus and a method for processing signaling protocol in an exchange.

As a conventional general method of processing a signaling protocol in an asynchronous transport mode exchange, a processing unit of each layer of the signaling protocol consists of one task having a queue. This transitions the state machine to the same state when each protocol layer consists of one state machine and the message information from the upper layer protocol processor and the message information from the lower layer protocol are the same message information.

1 is a system configuration diagram illustrating a conventional call processing method. The signaling asynchronous transmission mode adaptation layer protocol processing unit 104 processes message information waiting in the queue Q104, and the state of the signaling asynchronous transmission mode adaptation layer protocol processing unit 104 transitions according to the message. The queue Q104 stores the message information from the call / connection control protocol processing unit 103 and the message information from the asynchronous transmission mode adaptive layer type 5 processing unit 105 to wait for processing, and from which layer is the message information. Irrespective of the order stored in the queue Q104, it is processed by the signaling asynchronous transmission mode adaptation layer protocol processing unit 104.

In addition, the processing units constituting each layer of the signaling protocol are scheduled to the next processing unit in the following round robin manner after processing all messages queued. The order in which each processing unit is performed is as follows.

Asynchronous transmission mode cell transmission / reception processing unit 106 → asynchronous transmission mode adaptive layer type 5 processing unit 105 → signaling asynchronous transmission mode adaptive layer protocol processing unit 104 → call / connection control protocol processing unit 103 → call processing unit 102 → asynchronous transmission mode cell transmission / reception processing unit 106 → asynchronous transmission mode adaptive layer type 5 processing unit 105 → signaling asynchronous transmission mode adaptive layer protocol processing unit 104 → call / connection control protocol processing unit 103 → call processing unit (102)

On the contrary, in the order in which the message transmitted from the subscriber station 108 passes through each processing unit and delivered to the called subscriber, as the processing of the message proceeds, more messages are accumulated in the message queue of each processing unit. The order in which messages are delivered to each processing unit in this case is as follows.

Outgoing → asynchronous transmission mode cell transmission / reception processing unit 106 → asynchronous transmission mode adaptive layer type 5 processing unit 105 → signaling asynchronous transmission mode adaptive layer protocol processing unit 104 → call / connection control protocol processing unit 103 → call processing unit (102) → call / connection control protocol processing section 103 → signaling asynchronous transmission mode adaptation layer protocol processing section 104 → asynchronous transmission mode adaptation layer type 5 processing section 105 → asynchronous transmission mode cell transmission / reception processing section 106 → Incoming

For example, at the point in time when a message sent from the subscriber station 108 is passed from the call processing unit 102 to the call / connection control protocol processing unit 103 via each processing unit, asynchronous transmission mode cell transmission / reception by task scheduling is performed. Since the processing unit 106 is performed, the processing of the message delivered to the queue of the call / connection control protocol processing unit 103 is delayed until the call / connection control protocol processing unit is rescheduled. This is a major cause of delayed processing due to the accumulation of messages on the queue.

In this way, due to inadequate task scheduling, messages are accumulated in the queue, and the processing time of messages is unnecessarily delayed, thereby increasing the possibility of timeout. In addition, when a timeout occurs, the message information for timeout processing is generated again and delivered to the lower layer. Thus, the lower layer protocol processing unit processes the timed useless message information and the message information for timeout processing. This results in a reduction in call processing performance of the transmission mode exchange.

In order to solve this problem, researches for efficient task scheduling and message queue management in each protocol processing unit have been attempted, but this problem has not been solved.

An object of the present invention is to separate each processing unit of a signaling protocol into two tasks, that is, a task for processing a message transmitted from a lower layer and a task for processing a message transmitted from a higher layer, thereby making the existing inefficient task scheduling possible. The present invention provides an apparatus and method for signaling protocol processing in an asynchronous transport mode switch in order to solve a problem of an increase in call setup failure rate caused by a protocol message delivery delay.

Other objects and advantages of the present invention will become more apparent from the following detailed description of the invention and the accompanying drawings.

1 is a system configuration diagram for explaining a conventional call processing method applied to the present invention.

2 is a block diagram of a signaling protocol apparatus according to the present invention.

3 is a flowchart showing a protocol processing scheduling algorithm according to the present invention.

<Brief description of symbols for the main parts of the drawings>

101, 201: system control and management

102, 202, 202 ': call processing unit

103, 203, 203 ': call / connection control protocol processor

104, 204, 204 ': signaling asynchronous transport mode adaptive layer protocol processing unit

105, 205, 205 ': Asynchronous transfer mode adaptive layer type 5 processing unit

106, 206: asynchronous transmission mode cell transmission / reception processing unit

107, 207: switching network

108, 208: signaling protocol processing unit of subscriber station

Q101, Q102, Q103, Q104, Q105, Q106: queue

Hereinafter, with reference to the drawings will be described in detail the operation principle of the present invention.

As shown in FIG. 2, in the present invention, each protocol processing unit excluding the system control and management unit layer 201 processes processing units 202, 203, 204, and 205 for processing messages transmitted from lower layers, and messages transmitted from higher layers. Is divided into processing units 202 ', 203', 204 ', and 205', and each processing unit has one message queue for storing only one direction of messages.

As such, when a message queue is divided so that each processing unit stores only one direction message, when a message to be transmitted in both directions is stored in one queue, a timeout occurs because the message to be processed first is queued unnecessarily. Can be solved. In addition, by separating each protocol layer processing unit into two processing units according to the flow of messages, task scheduling is possible according to the progress of protocol messages, thereby solving a phenomenon in which messages are accumulated in a queue by existing inefficient task scheduling.

Therefore, by configuring each layer of the signaling protocol according to the method of the present invention, efficient task scheduling is possible, thereby reducing call establishment failure caused by unnecessarily delaying message processing, and signaling protocol in an asynchronous transport mode exchange. Improve your overall call processing capabilities.

3 is a task scheduling algorithm according to the present invention. In the signaling protocol according to the present invention, as shown in FIG. 2, the processor for processing a message forwarded in a downward direction and a processor for processing a message forwarded in a downward direction, the call processor 102 of FIG. In the present invention as shown in Figure 2 configured by dividing into 202 and 202 '. Similarly, the conventional call / connection control protocol processing unit 103 is 203 and 203 ', the conventional signaling asynchronous transmission mode adaptation layer protocol processing unit 104 is 204 and 204', and the conventional asynchronous transmission mode adaptation layer type 5 processing unit 105 is divided into two processing units 205 and 205 '.

When the message transmitted from the subscriber station arrives at the asynchronous transmission mode cell transmission / reception processing unit 206, the received message is transferred to the asynchronous transmission mode adaptive layer type 5 processing unit 205, and then the asynchronous transmission mode adaptive layer type 5 processing unit ( 205 is scheduled to begin processing of the signaling protocol message.

After all messages queued in the message queue of the asynchronous transmission mode adaptation layer type 5 processing unit 205 have been processed, the signaling asynchronous transmission mode adaptation layer protocol processing unit 204 is scheduled to perform the asynchronous transmission mode adaptation layer type 5 processing unit 205. Perform the processing of the sent message. In this manner, the protocol message is transmitted to the upper layer direction of the signaling protocol through the call / connection control protocol processing unit 203 and the call processing unit 202, and the message processed by the call processing unit 202 is the call processing unit (in the lower layer direction). 202 '), the call / connection control protocol processing unit 203', the signaling asynchronous transmission mode adaptation layer protocol processing unit 204 ', and the asynchronous transmission mode adaptation layer type 5 processing unit 205' to be transferred in the lower layer direction to the subscriber station. Is delivered to.

The algorithm for performing the scheduling is as follows.

First, each processing unit generates a task in the order in which the messages are delivered (s1). Then, it is checked whether a message arrives in the message queue of the asynchronous transmission mode adaptive layer type 5 processor (s2). If the message has not arrived, the signaling protocol processing unit performs the execution of other tasks and checks whether it arrives again (s3). If the message has arrived, it is checked whether there is a message waiting in the message information queue (s4). As a result of the check, if there is a waiting message, the message information is processed and then the process moves to the step of checking whether there is a message again (s5). If there is no waiting message, the signaling protocol processor to be performed next according to the task generation procedure. After selecting to move to the step of checking the presence of the message (s6).

When each protocol processing unit task is generated in the order in which the protocol messages are delivered, the order in which the messages received by the asynchronous transmission mode cell transmission / reception processing unit 206 are delivered to each processing unit is processed as follows.

Originating → asynchronous transmission mode cell transmission / reception processing unit 206 → asynchronous transmission mode adaptive layer type 5 processing unit 205 → signaling asynchronous transmission mode adaptive layer protocol processing unit 204 → call / connection control protocol processing unit 203 → call processing unit (202) → system control and management unit 201 → call processing unit 202 '→ call / connection control protocol processing unit 203' → signaling asynchronous transmission mode adaptive layer protocol processing unit 204 '→ asynchronous transmission mode adaptive layer type 5 Processing unit 205 '→ Asynchronous transmission mode cell transmission / reception processing unit 206 → Incoming

The scheduling sequence of the protocol processor is as follows.

Asynchronous transmission mode adaptive layer type 5 processing unit 205 → signaling asynchronous transmission mode adaptive layer protocol processing unit 204 → call / connection control protocol processing unit 203 → call processing unit 202 → system control and management unit 201 → call processing unit (202 ') → call / connection control protocol processing unit 203' → signaling asynchronous transmission mode adaptive layer protocol processing unit 204 '→ asynchronous transmission mode adaptive layer type 5 processing unit 205'

As described above, since the operating system generally performs task scheduling in the order in which the tasks are generated, when the protocol processing tasks are generated in the order in which the protocol messages are delivered, they are received by the asynchronous transmission mode cell transmission / reception processing unit 206. Since the order in which the messages are delivered to and processed by each processing unit is consistent with the order in which each processing unit is scheduled and performed, the present invention can solve the existing problem of delaying the processing of messages by stacking messages in a signaling protocol.

In addition, by configuring each layer of the signaling protocol by the method of the present invention, efficient task scheduling is possible, thereby reducing a call setup failure caused by unnecessarily delaying message processing. Improve overall call processing.

Claims (2)

An apparatus for signaling protocol processing in an asynchronous transport mode switch comprising a call processor, a call connection control protocol processor, a signaling asynchronous transport mode adaptation layer protocol processor, and an asynchronous transport mode adaptation layer type 5 processor, The call processor, the call connection control protocol processor, the signaling asynchronous transport mode adaptation layer protocol processor, and the asynchronous transport mode adaptive layer type 5 processor, respectively, A processing unit for processing a message delivered from the upper layer by having a message queue storing only the message delivered from an upper layer; A processing unit configured to process a message delivered from the lower layer by having a message queue storing only the message delivered from the lower layer, And the processing units schedule the execution order of each processing unit in the same order as the message is delivered. A call processing unit, a call connection control protocol processing unit, a signaling asynchronous transmission mode adaptation layer protocol processing unit, and an asynchronous transmission mode adaptation layer type 5 processing unit, each processing unit including a message queue for storing only messages delivered from a higher layer; A signaling protocol processing apparatus in an asynchronous transport mode switch having a processing unit for processing a message delivered from an upper layer, and a processing unit for processing a message delivered in the lower layer by having a message queue storing only a message delivered from a lower layer. In the protocol processing scheduling method used, Generating a task of each processing unit according to the order in which the message is delivered; Checking whether a message arrives in a message queue of the asynchronous transmission mode adaptive layer type 5 processor; If the message does not arrive in the arrival confirmation step, after performing the processing of other tasks other than the signaling protocol processing unit and moving back to the arrival confirmation step, Checking whether there is a message waiting in the message queue when a message arrives in the arrival confirmation step; If there is a message waiting in the message existence check step, processing the message information and then moving back to the message presence check step; And if there is no message waiting in the message existence check step, selecting a signaling protocol processor to be performed next according to a task generation order and moving to the message presence check step.