JP2016127321A - Dynamic control system and dynamic control method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To send a control instruction that an execution function unit in a network device arranges a configuration function unit dynamically in response to a control instruction inputted via an execution processing unit, and a control processing unit in a control server arranges the configuration function unit dynamically, to the execution function unit of a module at a virtual node via the execution processing unit.SOLUTION: In a dynamic control system, a network device 30 includes: a virtual node 32 for mutually communicating with a plurality of virtual links and a control server 11 generated previously on a physical network; a module 36 provided in the virtual node 32; an execution processing unit for receiving a control instruction transmitted from a control processing unit; and an execution function unit 37 for arranging a configuration function unit dynamically in response to a control instruction inputted via an execution processing unit. The control server 11 includes a control processing unit for sending to the execution function unit 37 of a module 35 in the virtual node via the execution processing unit.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a base program included in a module provided in a node sliver that is a node resource of a slice, a control program having a function of transmitting a control command to the base program, a dynamic control system, and a dynamic control method.

  In related technology, the setting of a slice that is a virtual network, the application program group on the slice, and each setting file of the application program group are written in advance in module data that takes an expression format such as a virtual machine image. It was deployed and activated in units (see, for example, Patent Document 1). Module data generally includes a lot of basic software that supports development, implementation, verification, and operation, such as library files and middleware, and has a large amount of information.

JP 2011-211466 A

EDDIE KOHRE ET. AL. ACM Transactions on Computer Systems “The Click Modular Router” Vol. 18, no. 3, August 2000, Pages 263-297.

  In the related technology, it is necessary to prepare module data for the number of types of application programs, and the common part included in the module data is held in the storage server in an overlapping manner, so that the storage area of the storage server may be compressed. It becomes issue 1.

  In addition, module replacement is necessary to replace the application program configuration function unit, and the termination and activation of the module accompanying the module replacement is a high-load process. .

  The activation settings of each application program must be held in each module data. In order to read / write the activation settings of each application program, the calculation resources for retrieving the description position of the activation settings from the module data, Problem 3 is that it takes a cost to update the activation setting such as calculation time.

  Furthermore, in related technologies (for example, see Patent Document 1 and Non-Patent Document 1), the application program group on the slice and each setting file of the application program group take a representation format such as a virtual machine image or a program package. It is technical common sense to deploy and start up in units of modules, and it is not assumed that the application program configuration function unit will be changed. In addition, in order to maximize the advantage of changing the application program configuration function unit, a system for specifying the deployment relationship of the application program configuration function unit and the application program start parameters required at necessary locations on the network is provided. It is necessary to. However, it has not been easily considered to have such a method.

  In order to solve the above-described problem, the dynamic control system according to the present invention is configured such that an execution function unit in a network device dynamically arranges a configuration function unit according to a control command input via the execution processing unit, and performs control. It is an object to send a control instruction to the effect that a control processing unit in a server dynamically deploys a configuration function unit to an execution function unit of a module included in a virtual node via the execution processing unit.

  In order to achieve the above object, the present invention analyzes an application program description script describing a deployment relationship between a node sliver and an application program configuration function unit and a start parameter of the application program configuration function unit, and a necessary application program configuration function unit It has a function to dynamically deploy, set, start, update, and stop only.

Specifically, the dynamic control system according to the present invention is:
Network equipment
A virtual node that communicates with a plurality of virtual links and control servers created in advance on a physical network;
A module having an execution function unit and an execution processing unit including a configuration function unit, and provided in the virtual node;
The execution processing unit for receiving a control command transmitted by a control processing unit included in the control server;
The execution function unit dynamically deploying the configuration function unit according to the control command input via the execution processing unit,
The control server
A control processing unit configured to send a control command for dynamically deploying the configuration function unit to the execution function unit of the module included in the virtual node via the execution processing unit;

In the dynamic control system according to the present invention,
The execution function unit is
In response to the control command input via the execution processing unit, the configuration function unit is dynamically deployed and the control server has a notification that the control command has been acquired, and the configuration The function unit may be activated and set.

In the dynamic control system according to the present invention,
The execution function unit is
The control processing unit that the control server has updated the activation setting of the component function unit in response to the control command to update the activation setting input via the execution processing unit and has acquired the control command Notify
The activation setting of the component function unit may be ended in response to a control command for ending the activation setting input via the execution processing unit.

In the dynamic control system according to the present invention,
The control processing unit
A plurality of control commands for controlling the component function unit may be selectively read from a description script stored in advance.

In the above-described dynamic control system according to the present invention,
An infrastructure management device for maintaining and managing the connection of the network device;
The network device is:
It further includes basic software that assists the application program,
You may further provide the slice control part which allocates the said network apparatus to the said virtual node.

Specifically, the dynamic control method of the dynamic control system according to the present invention includes:
In a dynamic control method of a dynamic control system in which a plurality of virtual links, network devices, and control servers generated in advance on a physical network are connected to each other,
The network device is:
A communication procedure for communicating with each other a plurality of virtual links generated in advance on a physical network, a virtual node and a control server included in the network device;
The module provided in the virtual node has an execution function procedure and an execution process procedure of the configuration function unit,
The execution processing procedure for receiving a control command transmitted in the control processing procedure of the control server;
Performing the execution function procedure for dynamically deploying the configuration function unit according to the control command input via the execution process procedure;
The control server
A control processing procedure for transmitting a control command for dynamically deploying the configuration function unit to the execution function procedure of the module included in the virtual node via the execution processing procedure is performed.

In the dynamic control method of the dynamic control system according to the present invention,
The execution function procedure is as follows:
In response to the control command input via the execution processing procedure, the configuration function unit is dynamically deployed and the control server has a notification that the control command has been acquired, and the configuration The function unit may be activated and set.

In the dynamic control method of the dynamic control system according to the present invention,
The execution function procedure is as follows:
The control processing procedure that the control server has updated the startup setting of the component function unit in response to the control command to update the startup setting input through the execution processing procedure and has acquired the control command Notify
The activation setting of the component function unit may be ended in response to a control command for ending the activation setting input through the execution processing procedure.

In the dynamic control method of the dynamic control system according to the present invention,
The control processing procedure is as follows:
A plurality of control commands for controlling the component function unit may be selectively read from a description script stored in advance.

In the dynamic control method of the dynamic control system described above according to the present invention,
Further infrastructure management procedures to maintain and manage network device connections,
The network device is:
Further perform application program assistance procedure to assist the application program,
A slice control procedure for assigning the network device to the virtual node may be further performed.

  The above inventions can be combined as much as possible.

  According to the present invention, the application program description script describing the deployment relationship between the node sliver and the application program configuration function unit and the start parameters of the application program configuration function unit is analyzed, and only the necessary application program configuration function unit is dynamically analyzed. It is possible to provide a dynamic control system having functions of deployment, setting, starting, updating, and stopping.

An example of the block diagram of the dynamic control system which concerns on this embodiment is shown. An example of the application program description script which concerns on this embodiment is shown. An example of the analysis processing flow in the data structure of the application program description script concerning this embodiment is shown. An example of the 1st control sequence of the whole dynamic control system concerning this embodiment is shown. An example of the 2nd control sequence of the whole dynamic control system concerning this embodiment is shown. An example of the processing flow of the control program 11 in the control server 10 which concerns on this embodiment is shown. An example of the processing flow of the base program 36 in the network device 30 according to the present embodiment is shown. An example of the block diagram of the dynamic control system which concerns on Embodiment 2 is shown.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. In addition, this invention is not limited to embodiment shown below. These embodiments are merely examples, and the present invention can be implemented in various modifications and improvements based on the knowledge of those skilled in the art. In the present specification and drawings, the same reference numerals denote the same components.

Explanation of terms used in the present embodiment will be described below.
Slice: A subset of network device resources, including node slivers, which are node resources constructed by virtualizing computing devices and storage devices, and link slivers, which are link resources constructed by virtualizing communication lines including physical links Then, a virtual network is formed by combining a node slave and a link slave.
Infrastructure management system: A system for managing network devices, and when the network device has a function of providing a slice, it has a slice control unit.
Slice control unit: a functional unit that controls the slice providing function of the network device. In the present embodiment, the sequence related to slice construction and module deployment is not claimed in the present application and is therefore omitted.
Application program: A generic term for programs developed or deployed by a slice administrator in this embodiment.
Basic software: A generic term for software programs that support development, verification, and operation, such as libraries and middleware in this embodiment.
Module: A virtual machine implemented in a node sliver.
Module data: Data representing a module.
Slice description script: Data structure describing slice topology, sliver identifier, etc.

(Embodiment 1)
An example of a configuration diagram of the dynamic control system according to the present embodiment is shown in FIG. The dynamic control system includes a network device 30 and a control server 10. The network device 30 includes a node sliver 32 that functions as a virtual node, a module 35, a base program 36 that functions as an execution processing unit, an execution function unit 37, and an application program configuration function unit 38 that functions as a configuration function unit. The network device 30 includes a node sliver 32, and the node sliver 32 includes a module 35. The module 35 includes a base program 36 and an execution function unit 37. The execution function unit 37 includes an application program configuration function unit 38.

  The control server 10 also includes a control program 11 that functions as a control processing unit. The control program 11 includes a slice description script 12, an application program description script 13, and application program configuration function unit data 14. Here, a specific operation of the dynamic control system according to the present embodiment will be described below.

  The dynamic control method of the dynamic control system according to the present embodiment performs a communication procedure, an execution processing procedure, an execution function procedure, and a control processing procedure. In the network device 30, the communication procedure communicates with a plurality of virtual links generated in advance on the physical network, the node sliver 32 functioning as a virtual node included in the network device 30, and the control server 10. The module 35 provided in the node sliver 32 has an execution function procedure and an execution process procedure of the configuration function unit. The execution process procedure receives the control command transmitted in the control process procedure of the control server 10. The execution function procedure dynamically deploys the configuration function unit according to the control command input through the execution process procedure. In the control server 10, the control processing procedure sends a control command for dynamically deploying the configuration function unit to the execution function procedure of the module 35 included in the node sliver 32 via the execution processing procedure.

  The upper script shown in FIG. 2 shows a specific script description of the data structure of the application program description script 13 (deployment definition portion) (the upper notation in FIG. 2 is the JSON format). In the application program description script 13, a description of “application-id” that is an identifier of the application program defined by the application program description script 13 is shown in FIG. 2.

  In addition, description of “slice-id” that is an identifier of a slice in which the application program is deployed is shown. This is an array that expresses the correspondence between the node sliver 32 and the configuration definition as a pair of identifiers (node-sliver-id, configuration-id), and the node sliver 32 is retrieved from the one included in the slice where the application program is deployed. The description of “element-map-array” is shown.

  This is an array expressing the configuration definition of the application program configuration function unit 38. In the present embodiment, the configuration definition of the application program configuration function unit 38 is defined as a configuration configuration method described in the configuration definition described in an external file based on the configuration-file-path variable value and a method of directly reading the configuration-script variable value. -Array ".

  The lower script shown in FIG. 2 is the data structure of the application program description script 13 (configuration definition part) (the lower part of FIG. 2 is an example of the above-mentioned “config002.click”, and the notation is the click format of Non-Patent Document 1). . Elements included in this description (for example, FromDevice, splitter, ToDevice) function as the application program configuration function unit 38)

  FIG. 3 shows an analysis processing flow of the data structure of the application program description script 13. Specifically, in step S101 in the application program description script 13, if an already generated application program is identified by the identifier of “application-id” described in the upper part of FIG. 2, the difference (add / delete / update) ) Is calculated and recorded. Further, when newly generated, all are recorded as differences (additions).

  In step S102, the node sliver 32 identified by “node-sliver-id” is retrieved from the slice identified by “slice-id” described in the upper part of FIG. 2, and the infrastructure program 36 corresponding to the node sliver 32 is retrieved. . In step S103, the array of “element-map-array” described in the upper part of FIG. 2 is read, and a set of an identifier (node-sliver-id) of the node sliver 32 and an identifier (configuration-id) of the configuration definition is detected. The base program 36 corresponding to the node sliver 32 is associated with the difference in the configuration definition. By executing the above analysis processing flow, the analysis processing of the data structure of the dynamic control system according to the present embodiment can be executed.

  FIG. 4 shows a first control sequence of the entire dynamic control system according to this embodiment. FIG. 4 is an example of the configuration of the dynamic control system according to the present embodiment. The control server 10 includes a control program 11 that functions as a control processing unit. The module 35 includes a base program 36 that functions as an execution processing unit, an execution function unit 37, and application program configuration function units # 1 and # 2 that function as configuration function units.

  Specifically, in the control sequence shown in FIG. 4, in step S <b> 201, the control program 11 sends a control command for the application program configuration function unit 38 to the board program 36. In step S202, an instruction to activate the application program configuration function units # 1 and # 2 is issued via the base program 36. In step S203, the execution function unit 37 acquires the application program configuration function units # 1 and # 2.

  In steps S204 and 205, control commands for starting the application program configuration function units # 1 and # 2 deployed in advance are input via the base program 36, and the application program configuration function units # 1 and # 2 are started. To do. With the above operation, the first control sequence of the entire dynamic control system according to the present embodiment can be executed.

  FIG. 5 shows a second control sequence of the entire dynamic control system according to this embodiment. FIG. 5 is an example of the configuration of the dynamic control system according to the present embodiment. The control server 10 includes a control program 11 that functions as a control processing unit. The module 35 includes a base program 36 that functions as an execution processing unit, an execution function unit 37, and application program configuration function units # 1 and # 2 that function as configuration function units.

  Specifically, in the control sequence shown in FIG. 5, in step S <b> 301, the control program 11 sends a control command for updating the activation setting of the application program configuration function unit 38 to the base program 36. In step S <b> 302, an instruction to update the activation settings of the application program configuration function units # 1 and # 2 is issued via the base program 36. In step S <b> 303, the execution function unit 37 acquires the application program configuration function unit 38.

  In step S304, a control command for updating the application program configuration function unit # 1 deployed in advance is input via the base program 36, and the application program configuration function unit # 1 updates the activation setting. In step S305, a control command for ending the activation setting of the application program configuration function units # 1 and # 2 is sent to the base program 36. In step S306, an instruction to end the activation setting of the application program configuration function units # 1 and # 2 is issued via the base program 36.

  In steps S307 and 308, a control command for ending activation setting is input to the application program configuration function units # 1 and # 2 deployed in advance via the base program 36, and the application program configuration function units # 1 and # 2 are entered. 2 completes the startup setting. With the above operation, the second control sequence of the entire dynamic control system according to the present embodiment can be executed.

  A processing flow of the control program 11 in the control server 10 according to the present embodiment is shown in FIG. In step S401, the operator performs a preparation process in which data information of the slice description script 12 and the application program configuration function unit data 14 is stored. In step S403, a control request for the application program configuration function unit 38 including the application program description script 13 is received from the operator during the request reception waiting state (step S402).

  In step S405 (corresponding to step S201), based on the analysis result (step S404) of analyzing the application program description script 13, the application program configuration function unit 38 including the difference (addition) of the configuration definition corresponding to each base program 36 is displayed. Send a control command. In step S410, during the request reception waiting state (step S407), the type of the control message from the operator is determined (step S407), and if it is a control request of the application program configuration function unit 38 including the application program description script 13, Receive.

  In step S411, the application program description script 13 is analyzed. In step S412 (corresponding to step S301), based on the analysis result, a control command (update) of the application program configuration function unit 38 including the difference (addition / deletion / update) of the configuration definition corresponding to each base program 36 is transmitted. . In step S412, after a control command (update) is transmitted, the process transits to a request reception waiting (step S406) state.

  In step S408, during the request reception waiting state (step S406), the type of the control message from the operator is determined (step S407), and if it is a request for termination of the application program component function unit, it is received. In step S409 (corresponding to step S305), a termination request for the application program configuration function unit 38 is transmitted to the base program 36. In step S409, after the termination request is transmitted, the process proceeds to the preparation process (step S401) state. With the above operation, the process of the control program 11 in the control server 10 according to the present embodiment can be executed.

  FIG. 7 shows a processing flow of the base program 36 in the network device 30 according to the present embodiment. In step S501, the base program 36 is in a control command reception waiting state. In step S <b> 502 (corresponding to step S <b> 201), a control command for the application program configuration function unit 38 including a difference (addition) in configuration definition is received from the control program 11.

  In step S503 (corresponding to step S202), an activation command (including configuration definition) of the application program configuration function unit 38 is issued to the execution function unit 37. In step S508 (corresponding to step S301), the control message type from the control program 11 is determined during the control command reception waiting (step S504) state (step S507), and the configuration definition difference (addition / deletion / update) is determined. If it is a control command (update) of the application program configuration function unit 38 including

  In step S509 (corresponding to step S302), an update command (including configuration definition) for the application program configuration function unit 38 is issued to the execution function unit 37. In step S509, after issuing an update command, the process shifts to a control command wait (step S504) state.

  In step S505 (corresponding to step S305), the control message type from the control program 11 is determined during the control command reception waiting (step S504) state (step S507), and the application program configuration function unit 38 termination request is received. If so, receive it. In step S506 (corresponding to step S306), an end command for the application program configuration function unit 38 is issued to the execution function unit. In step S506, after issuing an end command, the process shifts to a control command reception waiting (step S501) state. With the above operation, the processing of the base program 36 in the network device 30 according to the present embodiment can be executed. In the configuration according to the first embodiment, the dynamic control method of the dynamic control system can be realized with a simple configuration having the minimum functions necessary to solve the problem.

(Embodiment 2)
An example of a configuration diagram of the dynamic control system according to the present embodiment is shown in FIG. The dynamic control system includes a plurality of network devices 30, a control server 10, and an infrastructure management device 20. The network device 30 includes a slice control unit 21, a node sliver 32 that functions as a virtual node, a module 35, a base program 36 that functions as an execution processing unit, an execution function unit 37, and an application program 39 that functions as a configuration function unit. And basic software 40. The network device 30 includes a node sliver 32, and the node sliver 32 includes a module 35. The module 35 includes a base program 36, an execution function unit 37, and basic software 40. The execution function unit 37 includes an application program 39.

  The control server 10 also includes a control program 11 that functions as a control processing unit. The control program 11 includes a slice description script 12, an application program description script 13, and application program configuration function unit data 14. The infrastructure management apparatus 20 includes a slice control unit 21. The slice control unit 21 has module data 22. The dynamic control system according to the present embodiment includes basic software 40, a slice control unit 21, and an infrastructure management device 20.

  The dynamic control method of the dynamic control system according to the present embodiment further performs an infrastructure management procedure, an application program auxiliary procedure, and a slice control procedure in addition to each procedure of the dynamic control method in the first embodiment. The infrastructure management procedure maintains and manages the connection of the network device 30. The application program assistance procedure assists the application program. In the slice control procedure, a node sliver 32 that functions as the virtual node is assigned to the network device 30.

  In the configuration according to the second embodiment, in addition to the configuration of the first embodiment having the minimum functions necessary to solve the problem, the slice control unit 21, the infrastructure management device 20, and the basic software 40 are retained. , Dynamic control of slices, replacement of module data 22, a function of assisting an application program by the basic software 40, a slice control unit 21, an allocation function of assigning the network device 30 to the node sliver 32, and the infrastructure management device 20 A function for maintaining and managing the connection relationship of the network device 30 can be provided, and the configuration of slices, module data, and application programs can be easily implemented as compared to the first embodiment.

  According to the above-described embodiment, the base program 36 and the control program 11 have a function of exchanging only the application program configuration function unit 38, and it is not necessary to store the application program configuration function unit 38 in the module data 22. Unlike the technology, it is not necessary to store the module data 22 in the storage server by the number of the application program configuration function units 38, and the storage area of the storage server can be reduced.

  Further, the base program 36 and the control program 11 do not need to end and start the module 35 as in the related art when exchanging the application program configuration function unit 38, and are required to replace the application program configuration function unit 38. You can save time.

  The control program 11 according to the present embodiment reads the activation setting of each application program 39 and each application program configuration function unit 38 from the parameters of the application program description script 13 and transmits it as a control command to the base program 36 according to the present embodiment. Therefore, it is only necessary to store the activation setting of the application program 39 only in the application program description script 13. In order to read / write the activation setting of each application program 39 and each application program configuration function unit 38, an application Only the program description script 13 needs to be directly read and written, and the activation setting can be updated at a lower cost than the related technology.

  When the functions and configurations of related technologies are compared according to the present embodiment, the basic program according to the present embodiment dynamically deploys, sets, starts, updates, and ends only the necessary application program 39 in the node sliver. Since it has the control function to perform, it has a function part which is not in related technology.

  The control program according to the present embodiment includes a function for analyzing a script describing a deployment relationship between the node sliver 32 and the application program 39 and a startup parameter of the application program 39, and a function for transmitting a control command to the base program 36. Since it has the characteristic, it has a function part which is not in related technology.

  The present invention can be applied to the information communication industry.

10: Control server 11: Control program 12: Slice description script 13: Application program description script 14: Application program configuration function unit data 20: Infrastructure management device 21: Slice control unit 22: Module data 30: Network device 32: Node sliver 35: Module 36: Platform program 37: Execution function unit 38: Application program configuration function unit 39: Application program 40: Basic software

Claims (10)

Network equipment
A virtual node that communicates with a plurality of virtual links and control servers created in advance on a physical network;
A module having an execution function unit and an execution processing unit including a configuration function unit, and provided in the virtual node;
The execution processing unit for receiving a control command transmitted by a control processing unit included in the control server;
The execution function unit dynamically deploying the configuration function unit according to the control command input via the execution processing unit,
The control server
A control processing unit for dynamically sending the configuration function unit via the execution processing unit to the execution function unit of the module included in the virtual node;
A dynamic control system comprising: The execution function unit is
In response to the control command input via the execution processing unit, the configuration function unit is dynamically deployed and the control server has a notification that the control command has been acquired, and the configuration The dynamic control system according to claim 1, wherein the function unit is activated and set. The execution function unit includes:
The control processing unit that the control server has updated the activation setting of the component function unit in response to the control command to update the activation setting input via the execution processing unit and has acquired the control command Notify
3. The dynamic control system according to claim 1, wherein the activation setting of the component function unit is terminated in response to a control command for ending the activation setting input via the execution processing unit. The control processing unit
4. The dynamic control system according to claim 1, wherein a plurality of control commands for controlling the constituent function units are selectively read from a description script stored in advance. 5. The dynamic control system according to any one of claims 1 to 4,
An infrastructure management device for maintaining and managing the connection of the network device;
The network device is:
It further includes basic software that assists the application program,
A slice controller that assigns the network device to the virtual node;
The dynamic control system according to claim 1, wherein: In a dynamic control method of a dynamic control system in which a plurality of virtual links, network devices, and control servers generated in advance on a physical network are connected to each other,
The network device is:
A communication procedure for communicating with each other a plurality of virtual links generated in advance on a physical network, a virtual node and a control server included in the network device;
The module provided in the virtual node has an execution function procedure and an execution process procedure of the configuration function unit,
The execution processing procedure for receiving a control command transmitted in the control processing procedure of the control server;
Performing the execution function procedure for dynamically deploying the configuration function unit according to the control command input via the execution process procedure;
The control server
A control processing procedure for sending a control command for dynamically deploying the configuration function unit to the execution function procedure of the module included in the virtual node via the execution processing procedure;
A dynamic control method for a dynamic control system, characterized in that: The execution function procedure is as follows:
In response to the control command input via the execution processing procedure, the configuration function unit is dynamically deployed and the control server has a notification that the control command has been acquired, and the configuration The dynamic control method of the dynamic control system according to claim 6, wherein activation setting of the functional unit is performed. The execution function procedure is as follows:
The control processing procedure that the control server has updated the startup setting of the component function unit in response to the control command to update the startup setting input through the execution processing procedure and has acquired the control command Notify
8. The dynamic control system according to claim 6, wherein the activation setting of the component function unit is terminated in response to a control command for ending the activation setting input through the execution processing procedure. Dynamic control method. The control processing procedure is as follows:
9. The dynamic control method for a dynamic control system according to claim 6, wherein a plurality of control commands for controlling the component function unit are selectively read from a description script stored in advance. . Further infrastructure management procedures to maintain and manage network device connections,
The network device is:
Further perform application program assistance procedure to assist the application program,
Further performing a slice control procedure for assigning the network device to a virtual node;
The dynamic control method of the dynamic control system according to claim 6, wherein the dynamic control system is a dynamic control method.

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