JP4815547B2 - Data synchronization system, data synchronization method, and synchronization management server - Google Patents

Description

  The present invention relates to a system for performing data synchronization between remote bases, and more particularly to a data synchronization technique for securing necessary network resources in cooperation with a network management system.

Business systems are provided as Web applications and Web services. By using the Internet or VPN (Virtual Private Network), web applications and web services can be used from anywhere in the world.

  However, when accessing a remote server, the delay of the communication line is large, so the performance is low and difficult to use. Therefore, in order to improve performance, a configuration is adopted in which servers that provide Web applications and Web services are arranged in various places. Users gain access to nearby servers to improve performance. In such a configuration, since there are a plurality of servers that handle the same data and provide the same service, it is necessary to synchronize data between the servers, and data that accommodates a plurality of web applications and web services. The importance of the foundation for synchronization is increasing. In order to ensure synchronization performance in synchronization between servers distributed over a wide area, it is essential to consider the communication performance of WAN (Wide Area Network) lines.

  As a method of synchronizing data between bases distributed over a wide area in consideration of such a communication amount, a method disclosed in Patent Document 1 is known.

JP 2006-59260 A

  However, the above-described conventional technique has a problem that resources (bandwidth, etc.) of the WAN line cannot be effectively used. That is, the bandwidth and delay of the WAN line are fixed, and cannot be handled when the amount of synchronous communication changes greatly. For example, in the case of a narrow-band line, a new application (hereinafter referred to as an application) is added to the synchronization base, so that it is not possible to cope with a large increase in synchronization traffic. On the other hand, if a wide bandwidth line is used due to the increase in the number of applications, an unused bandwidth is created, and resources are wasted.

  Accordingly, an object of the present invention is to secure a WAN line resource (bandwidth, allowable delay) in accordance with the number and arrangement of applications to be accommodated, and to use the resource effectively and a wide area data synchronization system and data synchronization method And providing a synchronization management server.

In order to achieve the above object, in the present invention, a data synchronization system for constructing a path for transferring data, a plurality of synchronization servers to which applications that use data in synchronization are connected, and the plurality of synchronization servers Management server, a transfer device that transfers data, and a path management server that manages the transfer device, the synchronization management server includes a processing unit and a storage unit that stores information on the synchronization server to be managed And the processing unit of the synchronization management server includes setting request information including the identifier of the synchronization server to which the application is connected, the frequency and size of data used by the application, and the delay allowed until the synchronization is completed. Based on the received setting request information, calculate the path bandwidth and allowable delay between multiple synchronization servers, and calculate the calculated path bandwidth. And the allowable delay are transmitted to the path management server as a path setting request, and the path management server includes a processing unit and a storage unit that stores information on the transfer device and the path. In order to receive a path setting request and create a new path, or to change the bandwidth and allowable delay of an existing path, the setting details of the transfer device are generated and transmitted to the transfer device. Provided are a data synchronization system, a method thereof, and a synchronization management server for performing setting based on the above.

  A typical example of the present invention is as follows.

That is, a synchronization server includes a plurality of synchronization servers, a synchronization management server that manages the synchronization server, a plurality of transfer devices that transfer packets, and a path management server that manages the transfer device. The synchronization server and the transfer device is a system for constructing a logical path for transferring the synchronized data between the synchronization servers, and the synchronization management server is synchronized server information to be managed by the synchronization management server The processing unit includes a plurality of synchronization server identifiers to which an application that uses data to be synchronized is connected from the management terminal of the synchronization management server. Receiving the setting request information including the frequency of use, the size of the data to be used, and the delay allowed until the synchronization is completed, and the synchronization request is received from the received setting request information. The bandwidth for each path between paths and the allowable communication delay (allowable delay) are calculated, a path setting request including the calculated path bandwidth and allowable delay is sent to the path management server, and the path management server constructs the path. A storage unit that stores information on the transfer device and connection relation information and path information that has already been constructed, and a processing unit. The processing unit receives a path setting request from the synchronization management server. A configuration of a transfer device for creating a new path or changing a bandwidth and an allowable delay of an existing path, and transmitting the setting content to the transfer device, and each transfer device has a configuration for setting the setting content .

According to the present invention, resources can be used effectively by determining the configuration of the WAN line according to the number, arrangement, and attributes of the applications to be accommodated and securing the resources (bandwidth, allowable delay) to be used. In addition, the synchronization performance requested by the application can be satisfied.

It is a figure which shows the structure of the data synchronization system of a 1st Example. It is a block diagram of a synchronous management server concerning the 1st example. It is a figure which shows an example of the synchronous server table concerning a 1st Example. It is a figure which shows an example of the application table concerning a 1st Example. It is a figure which shows an example of the weight table between synchronous servers concerning a 1st Example. It is a figure which shows an example of the path table concerning a 1st Example. It is a block diagram of a synchronous server concerning the 1st example. It is a figure which shows an example of the synchronization destination table concerning a 1st Example. It is a figure which shows an example of the application operation | movement information table concerning a 1st Example. It is a block diagram of a path management server concerning the 1st example. It is an example of the NW device table according to the first embodiment. It is a figure which shows an example of the NW topology table concerning a 1st Example. It is a figure which shows an example of the path table concerning a 1st Example. FIG. 7 is a sequence diagram of path setting content generation and setting processing to a synchronization server and an NW device according to the first embodiment. It is a figure explaining the message transmitted / received in the setting process to the path setting content generation and the synchronization server and the NW device according to the first embodiment. It is a figure which shows the information of the process in which the synchronous management server concerning a 1st Example performs the calculation process of a tree calculation process, a zone | band, and an allowable delay. It is a flowchart figure of the tree structure process concerning a 1st Example. FIG. 6 is a flowchart of bandwidth / allowable delay calculation and path setting content generation processing according to the first embodiment. It is a flowchart figure of the NW apparatus setting content production | generation process concerning a 1st Example. FIG. 10 is a sequence diagram of generation of path setting contents during operation and setting processing to a synchronization server and an NW device according to the second embodiment. It is a figure explaining the message transmitted / received in the path setting content production | generation at the time of operation | movement and the setting process to a synchronous server and a NW apparatus concerning a 2nd Example. It is a flowchart figure of a zone | band update and a path setting content production | generation process concerning a 2nd Example.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. Note that the synchronization server in this specification refers to holding data in its own storage unit in response to a data storage request or acquisition request from an application server, reading and retrieving data from the storage unit, and further holding it. Data that is set to the same value as the data of other synchronization servers specified for each application. Therefore, even if the server is given only the authority to read and retrieve data, that is, the reference authority, the synchronization server that synchronizes data with another synchronization server in order to refer to the data stored in the other synchronization server It becomes.

  FIG. 1 is a diagram showing the configuration of the system of the first embodiment.

  The system of the present embodiment includes, for example, NW devices 100A to 100B, bases 2A to 2C, synchronization management server 500, synchronization servers 600A to 600C, path management server 700, application servers (hereinafter referred to as application servers) 800A to 800F, management terminals 900. Hereinafter, as will be sequentially described, each server has a normal computer configuration.

The NW devices 100A to 100B are transfer devices that transfer information communicated in the network to a destination of the information, and are, for example, a switch, a router, or a transmission device. NW devices 100A to 100B may be collectively referred to as NW device 100 in some cases. The NW device 100 is included in the wide area network 1. The synchronization management server 500 is a computer that manages the synchronization server 600. The synchronization management server 500 will be described in detail later with reference to FIG.

  The synchronization servers 600 </ b> A to 600 </ b> C are servers for transmitting the data input from the application server 800 to another registered synchronization server 600 for synchronization. Also, in response to an acquisition request from the application server 800, specified data is returned. The synchronization servers 600A to 600C may be collectively referred to as the synchronization server 600. The path management server 700 manages the NW device 100 and sets the NW device 100 according to the NW setting content requested from the synchronization management server 500. The application server 800 inputs data to the synchronization server 600 and acquires data from the synchronization server 600. The application servers 800A to 800F may be collectively referred to as the application server 800 in some cases. The management terminal 900 is connected to the synchronization management server 500 and controls the synchronization management server 500. Synchronization servers 600A-C and application servers 800A-F are included in bases 2A-C as shown.

  FIG. 2 is a block diagram showing a configuration of the synchronization management server 500 of this embodiment.

The synchronization management server 500 has a normal computer configuration, for example, a memory 510 as a storage unit, a central processing unit (CPU) 550 as a processing unit, an external storage unit 560, an I / O interface (I / F) 570 and a network interface (I / F) 580. The synchronization management server 500 is connected to the synchronization server 600 and the path management server 700 via the network I / F 580.

  The memory 510 includes, for example, a tree configuration program 511, bandwidth / allowable delay calculation, path setting content generation program 512, synchronization server setting program 513, path setting request program 514, application operation information collection program 515, bandwidth update, path setting content generation A program 516, a synchronization server table 521, an application table 522, a synchronization server weight table 523, and a path table 524 are stored. Each of these programs is executed by the CPU 550.

The tree configuration program 511 generates a tree connecting the synchronization server 600. The bandwidth / allowable delay calculation and path setting content generation program 512 calculates the bandwidth and allowable delay of the path connecting the synchronization servers constituting the tree, and generates the path setting content of the calculated value. The synchronization server setting program 513 sets the synchronization server 600 to be the calculated synchronization server tree. The path setting request program 514 transmits the generated path setting contents, that is, the path setting request to the path management server 700, and makes a path setting request. The application operation information collection program 515 collects application operation information from the synchronization server 600. The bandwidth update / path setting content generation program 516 updates the bandwidth based on the collected application operation information and generates the path setting content of the calculated value.

The synchronization server table 521 manages information on the synchronization server 600. Details of the synchronization server table 521 will be described later with reference to FIG. The application table 522 manages information of the synchronization server 600 in which each application is arranged. Details of the application table 522 will be described later with reference to FIG. The inter-synchronization server weight table 523 manages the inter-synchronization server weight information and information about whether the path that can be set in the network between the synchronization servers is bidirectional or unidirectional. Details of the synchronization server weight table 523 will be described later with reference to FIG. The path table 524 manages a list of applications that use paths between synchronization servers and information on allowable delay. Details of the path table 524 will be described later with reference to FIG.

As described above, the CPU 550 executes each program stored in the memory 510. The external storage unit 560 is a device that can store programs and various types of data, and can be configured by, for example, a hard disk drive (HDD). An I / O interface (I / F) 570 is an interface for inputting and outputting data. The network I / F 580 is an interface that transmits / receives information to / from other servers connected to the network.

  FIG. 3 is an explanatory diagram of the synchronization server table 521 of this embodiment. The synchronization server table 521 includes, for example, an ID 5211, a management IP address 5212, and a base 5213. The ID 5211 is unique identification information that identifies the synchronization server 600. The management IP address 5212 is an IP address for accessing the synchronization server 600. The base 5213 is information indicating the base 2 where the synchronization server 600 is arranged.

  FIG. 4 is an explanatory diagram of the application table 522 of this embodiment. The application table 522 includes, for example, an ID 5221 and an arrangement synchronization server list 5222. ID 5221 is unique identification information for identifying an application. The arrangement synchronization server list 5222 is information indicating a list of IDs of synchronization servers on which the application is arranged.

FIG. 5 is an explanatory diagram of the inter-synchronization server weight table 523 of this embodiment. The synchronization server weight table 523 includes, for example, ID 5231, synchronization server 1 5232, and synchronization server 2.
5233, weight 5234, and directionality 5235 are included.

ID 5231 is unique identification information that identifies a pair of synchronization servers. Synchronization server 1
Reference numeral 5232 denotes an ID of the synchronization server 600 serving as a base point of the pair of synchronization servers. The synchronization server 2 5233 is the ID of the synchronization server 600 opposite to the synchronization server 1 5232. The weight 5234 is a weight between these synchronization servers, as will be described later. The weight is a value determined from, for example, the number of hops and delay, and the smaller the weight, the better the communication performance. The weight is specified in advance. The directionality 5235 is the directionality of a path that can be set in the network between the synchronization servers. The values that can be set are, for example, “bidirectional” capable of bidirectional communication and “one-way” capable of only one-way communication.

  FIG. 6 is an explanatory diagram of the path table 524 of this embodiment. The path table 524 includes, for example, a path ID 5241, a synchronization server 1 5242, a synchronization server 2 5243, a used application list (application ID, bandwidth) 5244, and an allowable delay 5245.

  The ID 5241 is unique identification information that identifies a path established between the synchronization servers 600. The synchronization server 1 5242 is the ID of the synchronization server 600 that is the base point of this path. The synchronization server 2 5243 is an ID of the synchronization server 600 opposite to the synchronization server 1. The used application list (application ID, bandwidth) 5244 is a list of applications using this path. For each app, the app ID and the band information used by the app are included. An allowable delay 5245 is an allowable delay of this path.

  FIG. 7 is a block diagram showing one configuration of the synchronization server 600 of this embodiment.

The synchronization server 600 includes, for example, a memory 610 that is a storage unit and a CPU 650 that is a processing unit.
, An external storage unit 660, an I / OI / F 670, and a network I / F 680. The synchronization server 600 is connected to another synchronization server 600, the synchronization management server 500, and the application server 800 via the network I / F 680.

  The memory 610 stores, for example, an application operation information acquisition program 611, a synchronization program 612, a synchronization information setting program 613, a synchronization destination table 621, and an application operation information table 622. Each program can be executed by the CPU 650.

  The application operation information acquisition program 611 acquires the data addition / data update request frequency and data size from the connected application server 800 connected to the synchronization server 600 and stores them in the storage unit. When the synchronization program 612 receives a request for adding data from the application server 800, the synchronization program 612 transmits the data to another designated synchronization server 600. Further, data is received from another synchronization server 600 and stored in the external storage unit 660 of the synchronization server. The synchronization information setting program 613 receives the application addition request from the synchronization management server 500, and adds or updates the synchronization destination list of the requested application ID in the synchronization destination table 621 according to the application ID and the synchronization destination list included in the request. .

  The synchronization destination table 621 manages information of another synchronization server 600 that transmits data for synchronization. Details of the synchronization destination table 621 will be described later with reference to FIG. The application operation information table 622 manages data addition / data update request frequency and data size information from the application server 800. Details of the application operation information table 622 will be described later with reference to FIG.

The CPU 650 is a processor that executes each program stored in the memory 610. The external storage unit 660 is a device that can store programs and various types of data, and can be configured by an HDD, for example. The I / OI / F 670 is an interface for inputting / outputting data. The network I / F 680 is an interface that transmits / receives information to / from other servers connected to the network.

  FIG. 8 is an explanatory diagram of the synchronization destination table 621 of the present embodiment. The synchronization destination table 621 includes, for example, an application ID 6211 and a synchronization destination list 6212.

  The application ID 6211 is unique identification information that identifies an application. The synchronization destination list 6212 is a list of synchronization destination synchronization servers 600 to which the synchronization server is connected. The synchronization destination synchronization server 600 differs depending on the application.

  FIG. 9 is an explanatory diagram of the application operation information table 622 of this embodiment. The application operation information table 622 includes, for example, a period 6221, an application ID 6222, the number of requests 6223, and a data size (average) 6224.

The period 6221 is a period in which the number of data addition / data update requests and the data size from the application server 800 corresponding to the record are acquired. The application ID 6222 is the ID of the application that made the request. The number of requests 6223 is the number of requests for data addition / data update received from the application server 800 during the record period. The data size (average) 624 is an average value of the data size of data addition / data update received from the application server 800 during the period of the record.

  FIG. 10 is a block diagram of a configuration of the path management server 700 according to this embodiment. The path management server 700 includes, for example, a memory 710 as a storage unit, a CPU 750 as a processing unit, an external storage unit 760, an I / OI / F 770, and a network I / F 780. The path management server 700 is connected to the synchronization management server 500 and the NW device 100 via the network I / F 780.

  The memory 710 stores, for example, an NW device setting content generation program 711, an NW device setting program 712, an NW device table 721, an NW topology table 722, and a path table 723. Each program can be executed by the CPU 750.

The NW device setting content generation program 711 generates the setting content of the NW device 100 in accordance with the path setting request transmitted from the path setting request program 514 of the synchronization management server 500. The NW device setting program 712 transmits the generated setting content to the NW device 100 and sets it.

  The NW device table 721 manages information on the NW device 100. Details of the NW device table 721 will be described later with reference to FIG. The NW topology table 722 manages connection information of the NW device 100. Details of the NW topology table 722 will be described later with reference to FIG. The path table 723 manages path information. Details of the path table 723 will be described later with reference to FIG.

  FIG. 11 is an explanatory diagram of the NW device table 721 of this embodiment. The NW device table 721 includes, for example, an ID 7211, a type 7212, and a management IP address 7213. The ID 7211 is unique identification information that identifies the NW device 100. The type 7212 is a type of the NW device 100. The management IP address 7213 is an IP address for accessing the NW device 100.

FIG. 12 is an explanatory diagram of the NW topology table 722 of this embodiment. The NW topology table 722 includes, for example, an ID 7221, an NW device 1 7222, and an NW device 2 7223. The ID 7221 is unique identification information that identifies a connection between a pair of NW devices. The NW device 1 7222 is an ID of the NW device 100 that is a base point of the pair of NW devices. The NW device 2 7223 is an ID of the NW device 100 opposite to the NW device 1 7222.

FIG. 13 is an explanatory diagram of the path table 723 of this embodiment. The path table 723 includes, for example, an ID 7231, a base 1 7232, a base 2 7233, and a relay NW device list 7234.
, Band 7235, allowable delay 7236, and directionality 7237.

  The ID 7231 is unique identification information that identifies a path. The base 1 7232 is a base serving as a base point of this path. The base 2 7233 is a base opposite to the base 1 7232 of this pass. The relay NW device list 7234 is an ID list of NW devices through which this path passes. A band 7235 is a band of this path. An allowable delay 7236 is an allowable delay of this path. Directionality 7237 is the directionality of this path. The values that can be set are, for example, “bidirectional” capable of bidirectional communication and “one-way” capable of only one-way communication.

  FIG. 14 is a sequence diagram of path setting content generation and setting processing to the synchronization server and NW device when an application is newly added in the present embodiment.

  FIG. 15 is a diagram illustrating messages transmitted and received corresponding to each sequence in the path setting content generation and the setting process to the synchronization server and the NW device according to the present embodiment. Each column of the table 1500 in the figure shows a message 1501, a transmission source 1502, a destination 1503, and contents 1504.

In the sequence diagram of FIG. 14, the management terminal 900 makes an application arrangement request to the synchronization management server 500 (S101). The application arrangement request is the contents 1504 of the table 1500 in FIG.
As shown in FIG. 4, setting request information including an application ID, application arrangement / attribute, request frequency, data size, and allowable delay is transmitted. Here, the application ID is an ID of an application to be newly added. The application arrangement / attribute is a list of combinations of IDs and attributes (only with writing authority / reading, only with reference authority, etc.) of the synchronization server 600 where the application to be added is arranged. The request frequency indicates the data addition / update request frequency assumed when the application is operating, that is, the frequency of operation requests for data storage operations and data update operations. The data size is an average value (average data size) of data size of data addition / update assumed when the application is operated. The allowable delay is a time that is allowed until the data is synchronized among all the synchronization servers to be synchronized with the application after the application transmits the data to the synchronization server.

Based on the setting request information received from the management terminal 900, the synchronization management server 500 generates a tree configuration for connecting the synchronization server 600 using the tree configuration program 511 described above (S102). The tree is composed of a link connecting the synchronization server 600 and the synchronization server. Details of the tree configuration process will be described later with reference to FIG. The synchronization management server 500 calculates the bandwidth and allowable delay for each connection link of each synchronization server 600 based on the generated tree information by the bandwidth / allowable delay calculation and path setting content generation program 512 described above. Then, a path setting content for setting the calculated bandwidth and allowable delay path is generated (S103). The details of the bandwidth / allowable delay calculation and path setting content generation processing will be described later with reference to FIG.

Next, the synchronization management server 500 uses the previously described synchronization server setting program 513 to generate the path setting contents of the synchronization server based on the generated tree configuration (S104). Specifically, for each synchronization server constituting the tree, a list of synchronization servers 600 to which the synchronization server is connected by a link is created. Then, the list of the synchronization server 600 is distributed to the synchronization server as a synchronization destination list.

In other words, the synchronization management server 500 transmits the generated synchronization server setting contents to the synchronization server that configures the tree, and makes an application addition request (S105). The application addition request is shown in FIG.
As shown, the application ID and the synchronization destination list are included. The application ID is an ID of an application to be newly added. The synchronization destination list is a list of synchronization destination synchronization servers generated in S104.

When the synchronization server 600 receives the application addition request, the synchronization information setting program 613 described above sets its own synchronization information based on the received synchronization destination list information (S106).
Then, the processing result is transmitted to the synchronization management server (S107).

The synchronization management server 500 receives the success processing result from all the synchronization servers 600 to be set, and then the path setting request program 514 transmits the path setting content generated in S103 to the path management server 700, and receives the path setting request. Perform (S108). The path setting request is a list of path setting contents as shown in the contents 1504 of the table 1500 in FIG. 15, and the setting contents of a plurality of paths are made with one request. Each path setting content includes whether or not to add, base 1, base 2, bandwidth, allowable delay, and directionality. Whether or not to add is identification information indicating whether to add a new path, or to change the bandwidth and allowable delay of an existing path. The base 1 is one end point connected by a path. The base 2 is an opposite end point of the base 1.

When the path management server 700 receives the path setting request from the synchronization management server 500, the path management server 700 uses the program 711 described above to generate NW device setting contents based on the setting contents included in the request (S109). Details of the NW device setting content generation processing will be described later with reference to FIG.
Then, the NW device setting program 712 transmits the generated NW device setting content to the setting target NW device 100, and makes an NW device setting request (S110).

Upon receiving the NW device setting request, each NW device 100 updates its own information based on the received setting content (S111). Then, the processing result is transmitted to the path management server 700 (S
112).
The path management server 700 transmits a processing result to the synchronization management server 500 after receiving a successful processing result from all the setting target NW devices 100 (S113). The synchronization management server 500 transmits the processing result to the management terminal 900 (S114).

  FIG. 16 illustrates an example of information for the synchronization management server 500 to perform tree calculation processing, bandwidth, and allowable delay calculation processing. The synchronization management server 500 holds information as shown in FIG. 16 in the CPU 550 or the memory 510 and performs processing.

  As shown in the figure, there are managed synchronization servers 2000A to 2000F, and all the servers are connected in full mesh. Here, the connection between the synchronization servers 2000 is called a link. On the synchronization server 2000A, there are applications 2510A and 2530A arranged in the synchronization server 2000. There are applications 2520B and 2530B on the synchronization server 2000B. There are applications 2520C and 2530C on the synchronization server 2000C. There is an application 2510D on the synchronization server 2000D. There are applications 2510E, 2520E, and 2530E on the synchronization server 2000E. There are applications 2510F, 2520F, and 2530F on the synchronization server 2000F.

The links include a normal link 2200 and tree configuration links 2100A to 2100D. Configure a tree for each app. Here, the tree has a graph structure without a loop.

  As shown in FIG. 16, for example, the application AP3 is arranged in the synchronization servers 2000A, B, C, E, and F, and a tree in which these synchronization servers are connected by the tree configuration rings 2100A, B, C, and D is configured. ing.

FIG. 17 is a flowchart of the tree configuration process according to this embodiment. This process corresponds to step S102 shown in FIG. This flowchart will be described by taking an example of a tree structure corresponding to the application AP3 shown in FIG. The requested application arrangement / attribute includes the synchronization server 2000A (write / reference authority), synchronization server 2000B (write / reference authority), synchronization server 2000C (reference authority), synchronization server 2000E (write / reference authority), synchronization The server 2000F (reference authority) is assumed. Whether each synchronization server has only the reference authority or the reference / write authority can be set for each application.

Further, the weight of the link between the synchronization servers is as follows.
Link between synchronization servers AB: 1, Link between synchronization servers AC: 2, Link between synchronization servers AE: 5, Link between synchronization servers AF: 4, Link between synchronization servers BC: 2, Link between synchronization servers BE: 1, Synchronization server Link between BF: 4, Link between synchronization servers CE: 4, Link between synchronization servers CF: 2, Link between synchronization servers EF: 3.

First, the synchronization management server 500 selects all the links between the synchronization servers 600 where the application is arranged as tree configuration link candidates (S201). In FIG. 16, the synchronization server 2000
Select 10 links connecting A, B, C, E, F.

Next, the link between the synchronization servers 600 having only the reference authority included in the application attribute of the application placement request S101 is excluded from the candidates (S202). In FIG. 16, the synchronization server 2000C, F
Since this is only the reference authority, the link between the synchronization servers CF is excluded from the candidates. As described above, in this embodiment, considering that the processing time for the synchronization server that has received the synchronization data to be transferred to other synchronization servers is added to the communication time, the synchronization server with write authority is directly connected to many synchronization servers. In order to establish a connection configuration, the synchronization servers having only the reference authority, for example, the synchronization server 2000C and the synchronization server 2000F in FIG. 16 are excluded from the link candidates.

Further, referring to the inter-synchronization server weight table 523, links are selected from the candidates so that the overall weight becomes a minimum tree (S203). In FIG. 16, the tree having the smallest overall weight is a tree configured by a link between synchronization servers AB, a link between synchronization servers BC, a link between synchronization servers BE, and a link between synchronization servers EF. (The tree weight is 7.)
And let the selected link be a tree structure link. Note that the tree is a graph structure without a loop as described above.
Once the tree is constructed, the process is complete.

  FIG. 18 is a flowchart of bandwidth / allowable delay calculation and path setting content generation processing according to this embodiment. This process corresponds to step S103 shown in FIG.

First, the synchronization management server 500 calculates the communication traffic for synchronization (communication amount W = request frequency f · data size d) of the synchronization server 2000 in which the application is arranged. (S301) The request frequency and data size are information included in the application arrangement request S101 received from the management terminal 900.
The bandwidth is calculated for each tree configuration link to which the synchronization server 2000 is connected. (S302) Accordingly, the bandwidth is calculated at both ends for one link.

  As a calculation method, for example, one synchronization server 2000 on which an application is arranged is selected. One tree configuration link 2100 to which the selected synchronization server 2000 is connected is selected. The total communication amount of the synchronization server 2000 connected to the other end of the tree configuration link 2100 other than the link of the synchronization server 2000 having the selected link is set as the bandwidth of the connection link of the selected synchronization server 2000.

In FIG. 16, for example, the bandwidth of the link 2100A of the synchronization server 2000B is the synchronization server 2000B connected to the end of the tree configuration rings 2100B and 2100C other than the link.
, 2000C, 2000E, and 2000F.

Next, an allowable delay for each tree configuration link is calculated. (S303) For example, the allowable delay calculation method for each link first selects the path with the longest weight in the tree. A unit delay (unit delay = input allowable delay / longest path weight) is calculated, and the product of the unit delay and the weight of each link is set as the allowable delay of the link.
Select an unprocessed link from the tree configuration links. (S304)
Subsequently, referring to the weight table between the synchronization servers, it is determined whether or not the selected link is configured with a one-way path. (S305)
In the case of the one-way path, the calculated bandwidth, that is, the bandwidth of the synchronization server is set for the OUT BOUND path of the synchronization server at both ends of the link. (S306) Accordingly, two paths having opposite directions are set.
In the case of a bidirectional path, the larger band at both ends of the link is set as the path band. (
S307)
An allowable delay of the link is set for the path. (S308)
It is determined whether there is already a path between the synchronization servers of the link. (S309)
If there is already a path, the bandwidth of the existing path is set to a value obtained by adding the bandwidth calculated in S302. When the allowable delay of the existing path is larger than the allowable delay calculated in S303, the allowable delay value calculated in S303 is changed. If it is smaller than the allowable delay calculated in S303, the value is not changed. The path setting contents are generated so that the changed bandwidth and the allowable delay value are obtained. (S310)
If there is no path, the path is added, and the path setting contents that are the bandwidth calculated in S302 and the allowable delay calculated in S303 are generated. (S311)
It is determined whether or not all tree configuration links have been processed. (S312)
If all processing is completed, the bandwidth / allowable delay calculation and path setting content generation processing is completed. If there is an unprocessed link, the process returns to S304 and the subsequent processes are repeated.

  FIG. 19 is a flowchart of NW device setting content generation processing according to this embodiment. This process corresponds to step S109 shown in FIG.

First, the path management server 700 selects one path whose setting is requested. (S401)
It is determined whether or not the selected path is a new path to be added. (S402)
In the case of a path to be added, the NW topology table 722 is referred to calculate the path. As a path calculation method, for example, the shortest path is searched and a path is made. Then, a list of NW devices constituting the path is generated. (S403)
On the other hand, when a path is not added, a list of NW devices constituting the setting target path is acquired with reference to the path table 723. (S404)
Setting information for configuring a path for each NW device in the NW device list is generated. (S405)
With reference to the NW device table 721, setting information is generated based on the type of the NW device to be set.

It is determined whether or not all paths requested for setting have been processed. (S406)
If all processing is completed, the processing is completed.
If all the processes have not been performed, the process returns to S401 and the subsequent processes are repeated.

  As described above, the configuration of performing the path setting content generation and setting processing when there is an application arrangement request from the management terminal or the like has been described in detail as the system of the first embodiment.

  Subsequently, as a second embodiment, a system that realizes path setting content generation and setting processing during operation will be described. Note that the hardware configuration of the system is not changed from that of the first embodiment.

  FIG. 20 is a sequence diagram of path setting content generation during operation after adding an application and setting processing to the synchronization server 600 and the NW device 100 in the system of the second embodiment. FIG. 21 is a diagram illustrating messages transmitted and received in the path setting content generation and the setting process to the synchronization server 600 and the NW device 100 according to the present embodiment.

As illustrated in FIG. 20, every time there is a data operation request from the application server 800, the synchronization server 600 collects application operation information using the application operation information collection program 515 described above. (S501)
The synchronization management server 500 starts the bandwidth update process periodically. (S502) It is also possible to give an instruction from the management terminal 900 to the synchronization management server 500 to start the bandwidth update process.

The synchronization management server 500 makes an application operation information acquisition request to the synchronization server 600 in which the update target application is arranged. (S503) The application operation information acquisition request includes an application ID and a period. The period is a period of application operation information to be acquired.

The synchronization server 600 refers to the application operation information table 622 and transmits the application operation information of the specified application for the specified period to the synchronization management server 500. (S504) The application operation information includes a request frequency and an average data size.

The synchronization management server 500 receives the application operation information from all of the synchronization servers 600 that have transmitted the application operation information acquisition request, and then performs bandwidth update and path setting content generation processing to generate the path setting content. (S505) The bandwidth update and path setting content generation processing will be described in detail later with reference to FIG.

  The subsequent processing is the same as the processing after step S108 in FIG.

  FIG. 22 is a flowchart of bandwidth update and path setting content generation processing according to this embodiment. This process corresponds to step S505 shown in FIG.

First, the synchronization management server 500 generates a communication traffic for synchronization (
The communication amount W = request frequency f · data size d) is calculated. (S601) The request frequency and data size are information included in the application operation information collected from the synchronization server 600.

With reference to the path table 723, an unprocessed path that is used by the update target application is selected. (S602)
It is determined whether or not the selected path is a directional path. (S603)
In the case of a directional path, the bandwidth of the selected path is calculated for the update target application. (S6
04) For the synchronization server 600 on the path transmission side, the bandwidth is calculated in the same manner as in the method of S302 of FIG.
If it is not a directional path, the bandwidth is calculated for the synchronization servers 600 at both ends of the path in the same manner as in the method of S302 in FIG. 18, and the larger bandwidth is selected. (S605)
A setting for changing the bandwidth of the path is generated so that the bandwidth of the update target application is changed to the calculated bandwidth. (S606)
It is determined whether or not all paths used by the setting target application have been processed. (S607)
If all processing is completed, the processing is completed.
If not all have been processed, the process returns to S602 and the subsequent processes are repeated.

  The present invention is useful as a data synchronization technique for securing necessary network resources in cooperation with a network management system in a system for synchronizing data between remote sites.

DESCRIPTION OF SYMBOLS 1 ... Wide area network 100 ... NW apparatus 500 ... Synchronization management server 510 ... Memory 511 ... Tree structure program 512 ... Band / allowable delay calculation, path setting content generation program 513 ... Synchronization server setting program 514 ... Path setting request program 515 ... Application operation Information collection program 516 ... Band update, path setting content generation program 521 ... Synchronization server table 522 ... Application table 523 ... Inter-synchronization server weight table 524 ... Path table 550 ... CPU
560 ... External storage device 570 ... I / OI / F
580 ... Network I / F
600 ... Synchronization server 700 ... Path management server 800 ... Application server 900 ... Management terminal.

Claims (15)

A data synchronization system for building a path for transferring data,
A plurality of synchronization servers to which applications that use the data in synchronization are connected;
A synchronization management server for managing a plurality of the synchronization servers;
A transfer device for transferring the data;
A path management server for managing the transfer device;
The synchronization management server includes a processing unit and a storage unit that stores information on the synchronization server that is a management target.
The processing unit of the synchronization management server includes setting request information including an identifier of the synchronization server to which the application is connected, a frequency and size of the data used by the application, and a delay allowed until the synchronization is completed. Receive
Based on the received setting request information, calculate the bandwidth and allowable delay of the path between the plurality of synchronization servers, and transmit the calculated bandwidth and allowable delay of the path to the path management server as a path setting request,
The path management server includes a processing unit, a storage unit that stores information on the transfer device and the path,
The processing unit of the path management server receives the path setting request, generates a setting content of the transfer device in order to newly construct the path or change a bandwidth and an allowable delay of the existing path, and To the transfer device,
The transfer device performs setting based on the received setting content.
A data synchronization system characterized by that. The data synchronization system according to claim 1,
The storage unit of the synchronization management server further stores an identifier of the application using the path, and information on its bandwidth and allowable delay,
When the processing unit of the synchronization management server receives the setting request information, the processing unit calculates a bandwidth and an allowable delay of the application to be set, updates the information stored in the storage unit, and Sent to the path management server as a setting request;
A data synchronization system characterized by that. The data synchronization system according to claim 1,
The storage unit of the synchronization management server further stores weight information between the synchronization servers,
When receiving the setting request information, the processing unit of the synchronization management server uses the weight information to select a path to connect all the synchronization servers to which the application included in the setting request information is connected. To
A data synchronization system characterized by that. The data synchronization system according to claim 3, wherein
The processing unit of the synchronization management server selects a path connecting the synchronization servers so that weight information between the synchronization servers is minimized.
A data synchronization system characterized by that. The data synchronization system according to claim 3, wherein
The setting request information further includes information on write and read authority of the application for each synchronization server to which the application is connected,
The processing unit of the synchronization management server selects a path for connecting the synchronization servers so as not to connect the synchronization servers to which the application having only the read authority is connected.
A data synchronization system characterized by that. The data synchronization system according to claim 1,
The storage unit of the synchronization management server further stores path direction information that can be set between the synchronization servers,
The processing unit of the synchronization management server determines whether the path selected to connect the synchronization servers can be constructed in one direction or in both directions based on the information on the direction of the path, In the case of one-way, select another path having a different direction, and set the bandwidth and allowable delay of the source synchronization server for each of the selected paths.
A data synchronization system characterized by that. The data synchronization system according to claim 1,
The synchronization server includes a processing unit, and a storage unit that stores the number of data operation requests and data size for each application as application operation information for each predetermined period,
When the processing unit of the synchronization server receives a data use operation request from the application, it updates the stored application operation information,
The processing unit of the synchronization management server periodically acquires the application operation information from the synchronization server, and calculates the bandwidth of the path between the synchronization servers based on the acquired application operation information.
A data synchronization system characterized by that. A plurality of synchronization servers to which applications that use data in synchronization are connected; a synchronization management server that manages the plurality of synchronization servers; a transfer device that transfers the data; and a path management server that manages the transfer device A data synchronization method in a system provided on a network,
The synchronization management server stores information on the synchronization server to be managed,
Receiving setting request information including an identifier of the synchronization server to which the application is connected, a frequency and size of the data used by the application, and a delay allowed until the synchronization is completed;
Based on the received setting request information, calculate the bandwidth and allowable delay of the path between the plurality of synchronization servers, and transmit the calculated bandwidth and allowable delay of the path to the path management server as a path setting request,
The path management server
Storing the transfer device and the path information;
Receiving the path setting request, creating a new path, or changing the bandwidth and allowable delay of the existing path, generating the setting contents of the transfer apparatus and transmitting the settings to the transfer apparatus;
The transfer device performs setting based on the received setting content.
A data synchronization method characterized by the above. The data synchronization method according to claim 8, wherein
The synchronization management server further stores an identifier of the application that uses the path between the synchronization servers, and information on its bandwidth and allowable delay,
When receiving the setting request information, the synchronization management server calculates a bandwidth and an allowable delay for the application to be set, updates the stored information, and uses the path management server as the path setting request. Send to
A data synchronization method characterized by the above. The data synchronization method according to claim 8, wherein
The synchronization management server further stores weight information between the synchronization servers,
When receiving the setting request information, the synchronization management server connects all the synchronization servers to which the application included in the setting request information is connected so that weight information between the synchronization servers is minimized. Select a path,
A data synchronization method characterized by the above. The data synchronization method according to claim 10, comprising:
The setting request information further includes information on write and read authority of the application for each synchronization server to which the application is connected,
The synchronization management server selects the path to connect the synchronization servers so as not to connect the synchronization servers to which the application having only the read authority is connected.
A data synchronization method characterized by the above. The data synchronization method according to claim 8, wherein
The synchronization management server further stores information on the directionality of the path that can be set between the synchronization servers,
The synchronization management server determines whether the path selected for connecting the synchronization server can be constructed in one direction or in two directions based on the information on the directionality of the path. Selects another path in a different direction, and sets the bandwidth and allowable delay of the source synchronization server for each of the selected paths.
A data synchronization method characterized by the above. The data synchronization method according to claim 8, wherein
The synchronization server stores, as application operation information, the number of data operation requests and the data size for each application for each predetermined period,
When receiving an operation request for data use from the application, update the application operation information,
The synchronization management server periodically acquires the application operation information from the synchronization server, and calculates a bandwidth of the path between the synchronization servers based on the acquired application operation information.
A data synchronization method characterized by the above. A synchronization management server of a system that constructs a path for transferring the data between a plurality of synchronization servers to which an application that uses data in synchronization is connected,
A processing unit, and a storage unit that stores information of the synchronization server that is a management target,
The processing unit receives setting request information including an identifier of the synchronization server to which the application is connected, a frequency and size of the data used by the application, and a delay allowed until the synchronization is completed,
Based on the received setting request information, calculates the bandwidth and allowable delay of a path between the plurality of synchronization servers, and manages the transfer device that transfers the data using the calculated bandwidth and allowable delay of the path as a path setting request. Send to the path management server
A synchronization management server characterized by that. The synchronization management server according to claim 14,
The storage unit of the synchronization management server stores, for the path between the synchronization servers, an identifier of the application that uses the path, and information on its bandwidth and allowable delay, and the processing unit stores the setting When request information is received, the bandwidth and allowable delay for the application to be set are calculated, stored in the storage unit, and transmitted to the path management server as the path setting request.
A synchronization management server characterized by that.

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