JP2010108156A - Hierarchical type resource monitoring system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To obtain a hierarchical type resource monitoring system with which the procedure to acquire resource information from a resource information database of distributed management stations being hierarchical and distributed within a network is simplified. <P>SOLUTION: When desiring to acquire the resource information of a management node N4 belonging to the distributed management station D4 in a separated hierarchy from an administrative management station M1 of the highest level constituting the hierarchy, only by inquiring the resource information to the distributed management station D2 of the second lower level of the administrative management station M1, a request is transmitted from the distributed management station D2 to the distributed management station D4 of the lower level, and the response regarding the resource information of the management node N4 from the distributed management station D4 is transmitted to the administrative management station M1 through the distributed management station D2. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a hierarchical resource monitoring system that collects resource information such as performance information and operation information in personal computers and workstations distributed in a network.

  For example, in the conventional technique described in Patent Document 1, resource information is distributed in a database connected to distributed management stations, and an upper layer management station is assigned to a management node belonging to a lower layer management station. When it is desired to acquire resource information, it is necessary to directly communicate with the management station to which the management node belongs and request the corresponding resource information.

JP 2001-344227 A (pages 3 to 5, FIG. 1)

  In the prior art described in Patent Document 1, resource information of each management node is arranged in a direct management station. For this reason, in order to obtain information, the request source searches for the corresponding direct distributed management station from all the distributed management stations connected hierarchically, and communicates directly with the distributed management station across the hierarchy. There is a problem that a complicated procedure is required.

  The present invention has been made to solve the above-described problems, and simplifies a procedure for acquiring resource information from a resource information database of a distributed management station arranged in a hierarchy in a network. The purpose is to obtain a hierarchical resource monitoring system.

The hierarchical resource monitoring system according to the present invention is a hierarchical resource monitoring system that collects resource information of management nodes distributed and arranged in a network,
Multiple distributed management stations connected to the network and layered
And a plurality of management nodes respectively connected to any of the plurality of distributed management stations,
Each distributed management station is connected to a resource information database storing resource information of a management node connected to the own station and a distributed management database storing hierarchical information of the distributed management station.
A resource information collection unit that collects resource information from a management node connected to its own station and stores it in a resource information database;
A resource information communication unit that requests resource information specifying a target management node and a target resource information type from a lower layer distributed management station, and acquires the requested resource information from the lower layer distributed management station;
A resource information transfer unit that receives a request for resource information in which a target management node and a target resource information type are specified from an upper layer distributed management station, acquires corresponding resource information, and transfers the resource information to an upper layer distributed management station;
In response to a request from the resource information transfer unit, the distributed management database is searched, and if the requested management node is connected to its own station, the corresponding resource information in the resource information database is returned to the resource information transfer unit. In addition, if the requested management node is connected to the lower layer distributed management station, the corresponding resource information is obtained from the corresponding lower layer distributed management station via the resource information communication unit, and the resource A table synthesizing unit that answers the information transfer unit.

As described above, the present invention is a hierarchical resource monitoring system that collects resource information of management nodes distributed in a network.
Multiple distributed management stations connected to the network and layered
And a plurality of management nodes respectively connected to any of the plurality of distributed management stations,
Each distributed management station is connected to a resource information database storing resource information of a management node connected to the own station and a distributed management database storing hierarchical information of the distributed management station.
A resource information collection unit that collects resource information from a management node connected to its own station and stores it in a resource information database;
A resource information communication unit that requests resource information specifying a target management node and a target resource information type from a lower layer distributed management station, and acquires the requested resource information from the lower layer distributed management station;
A resource information transfer unit that receives a request for resource information in which a target management node and a target resource information type are specified from an upper layer distributed management station, acquires corresponding resource information, and transfers the resource information to an upper layer distributed management station;
In response to a request from the resource information transfer unit, the distributed management database is searched, and if the requested management node is connected to its own station, the corresponding resource information in the resource information database is returned to the resource information transfer unit. In addition, if the requested management node is connected to the lower layer distributed management station, the corresponding resource information is obtained from the corresponding lower layer distributed management station via the resource information communication unit, and the resource A table composition unit that responds to the information transfer unit, so that even when a distributed management station at a certain starting point wants to acquire resource information of a management node belonging to a distributed management station at a different level, it is one level lower layer of the starting distributed management station Simply ask the resource information to the distributed management station of each floor. Distributed management station requests propagated in, also responded by following the reverse is sent back, without the need for complex procedures, there is an effect that easily can be obtained.

Embodiment 1 FIG.
Hereinafter, Embodiment 1 will be described in detail with reference to the drawings.
FIG. 1 is a system configuration diagram showing a hierarchical resource monitoring system according to Embodiment 1 of the present invention.
In FIG. 1, an overall management station 101 is a station located at the top of the hierarchical structure, and forms a network with a plurality of distributed management stations 201a, 201b,. A management node 130 to be monitored is connected to the overall management station 101 and each distributed management station 201. The management node 130 is a computer such as a personal computer, a workstation, or a server.

The overall management station 101 and the distributed management station 201 include a resource information display editing unit 102, a resource information transfer unit 103, a table composition unit 104, a resource information communication unit 105, and a resource information collection unit 106, which will be described later. Have.
Further, a resource information database 110 and a distributed management database 112 are connected to the overall management station 101 and the distributed management station 201, respectively.
The resource information database 110 stores a resource information table 111 having resource information of the management node 130, and the distributed management database 112 has a distributed management table having the distributed management station 201 and the management node 130 connected thereto. 113 is stored.
Further, a display unit 121 and an input unit 122 are connected to the overall management station 101 and the distributed management station 201 for displaying and editing resource information, respectively.

  A display unit 121 and an input unit 122 are connected to the resource information display editing unit 102 to display and edit resource information. The resource information transfer unit 103 is connected to the network and transfers resource information to the network. The table composition unit 104 refers to the information in the resource information table 111 and the distribution management table 113 and acquires the requested resource information. The resource information communication unit 105 is communicatively connected to a lower layer distributed management station. The resource information collection unit 106 collects resource information from the management node 130 and updates the resource information table 111.

FIG. 2 is a flowchart showing processing of the resource information display editing unit of the hierarchical resource monitoring system according to Embodiment 1 of the present invention.
FIG. 3 is a flowchart showing processing of the resource information transfer unit of the hierarchical resource monitoring system according to Embodiment 1 of the present invention.
FIG. 4 is a flowchart showing the processing of the table composition unit of the hierarchical resource monitoring system according to the first embodiment of the present invention.

FIG. 5 is a configuration diagram showing a network configuration example of the hierarchical resource monitoring system according to the first embodiment of the present invention.
In FIG. 5, the central management station M1 is the highest level, and distributed management stations D1 to D4 are arranged as lower layers, and the management nodes N1 to N6 are connected to the lower layer distributed management stations D1 to D4, respectively. Has been. A resource information database (DB) is connected to each of these distributed management stations.

FIG. 6 is a diagram showing a resource information table of the distributed management station D4 in the network configuration example shown in FIG.
In FIG. 6, the resource information table of the distributed management station D4 has the management station name D4, shows the management node names N4 and N5 belonging to the management station name, resource information types such as CPU load and memory consumption, and the corresponding information Indicates the resource information value.

FIG. 7 is a diagram showing a distributed management table of the overall management station M1 in the network configuration example shown in FIG.
In FIG. 7, the distributed management table of the overall management station M1 shows the distributed management station in the lower layer of the overall level of the overall management station M1 and the management nodes belonging to it. Not the distributed management stations to which the management node names N1 to N6 belong, but the distributed management station names D1 to D3 at the highest level (one level lower than the overall management station M1) of the distributed management station to which the management node belongs. .

FIG. 8 is a diagram showing a distributed management table of the distributed management station D2 in the network configuration example shown in FIG.
In FIG. 8, the distributed management table of the distributed management station D2 shows the management nodes belonging to the distributed management station below the distributed management station D2. D2 as the distributed management station name and D4 which is one level lower layer of D2 are shown, and management node names N3 to N5 belonging to each are shown. That is, the uppermost one of the distributed management stations to which the management nodes N3 to N5 belong (the distributed management station D2 or one stage lower layer than the distributed management station D2) is shown. Here, the management node N3 belongs to the distributed management station D2, and the management nodes N4 and N5 belong to the distributed management station D4.

FIG. 9 is a diagram showing a distributed management table of the distributed management station D4 in the network configuration example shown in FIG.
In FIG. 9, the distributed management table of the distributed management station D4 shows D4 as the name of the distributed management station, and the management node names N4 and N5 belonging to this. Here, since the distributed management station D4 does not have a lower layer, only D4 is shown as the distributed management station name.

FIG. 10 is a diagram showing a display example of resource information of the management node of each management station in the network configuration example shown in FIG.
In FIG. 10, the management nodes N1 to N6 are displayed on the display units of the overall management station M1 and the distributed management stations D1 to D4, respectively. The management node of the own management station and the management node of the lower layer management station are displayed.

Hereinafter, the operation of the first embodiment will be described with reference to FIGS.
First, in the network configuration shown in FIG. 5, an operation when displaying the resource information (CPU load) of the management node N4 belonging to the distributed management station D4 on the display unit 121 of the overall management station M1 will be described.
The operator makes a display request for the resource information of the management node N4 from the input unit 122 of the overall management station M1 (101), and the resource information display editing unit 102 receives this request.

Next, processing of the resource information display editing unit 102 of the overall management station M1 will be described with reference to FIG.
In ST1 of FIG. 2, the resource information request of the management node N4 is acquired from the input unit 122, and the process proceeds to ST2. At this time, resource type = CPU load and management node name = N4 are passed as parameters. In ST2, the table composition unit 104 is requested to acquire resource information, and the process proceeds to ST3. At this time, resource type = CPU load and management node name = N4 are passed as parameters.
In ST3, the resource information acquired by the table combining unit 104 in response to the request is acquired from the table combining unit 104, and the process proceeds to ST4. In ST4, the acquired resource information is displayed on display section 121.

Next, processing of the table composition unit 104 of the overall management station M1 will be described with reference to FIG.
First, in ST21 of FIG. 4, a resource information request is accepted. In this example, resource type = CPU load and management node name = N4 are received as parameters, and the process proceeds to ST22. In ST22, the distributed management table 113 is referred to obtain the name of the distributed management station to which the requested management node belongs, and the process proceeds to ST23.
The distributed management table 113 of the overall management station M1 in this example is as shown in FIG. 7. From FIG. 7, in ST22, D2 is obtained as the name of the management station to which the management node N4 belongs. Here, it should be noted that the management station name of the management nodes N4 and N5 is D2 in the example of the distributed management table in FIG.

In the network configuration diagram shown in FIG. 5, the distributed management station directly belonging to the management nodes N4 and N5 is D4, but D4 belongs to the higher-level distributed management station D2 and is viewed from the central management station M1. The highest distributed management station of the management node N4 is D2, and the name of the highest distributed management station is stored in the distributed management station name of the distributed management table, not the distributed management station to which each management node belongs. ing.
As a result, even if the overall management station M1 wants to know the resource information of the management node N4, it is only necessary to make an inquiry to the distributed management station D2 that is one layer below, and it is not necessary to make an inquiry to the distributed management station D4 that is a lower layer. .

In ST23, it is determined whether or not the distributed management station name is its own distributed management station name. If YES, the process proceeds to ST24, and if NO, the process proceeds to ST26.
In this example, since the self-distributed management station name is M1 and the requested distributed management station name is D2, the process proceeds to ST26. In ST26, the resource information (CPU load) of the management node N4 is requested to the resource information transfer unit 103 of the highest distributed management station D2, and the process proceeds to ST27. In ST27, the resource information is acquired from the distributed management station D2, and the process proceeds to ST25. In ST25, the acquired resource information is returned to the request source.

Next, processing of the resource information transfer unit 103 will be described with reference to FIG. This time, the operation of the resource information transfer unit 103 of the distributed management station D2 will be described.
First, in ST11 of FIG. 3, a resource information request is received from the overall management station M1, and the process proceeds to ST12. The parameters at this time are resource type = CPU load and management node name = N4. In ST12, the table composition unit 104 is requested to acquire resource information, and the process proceeds to ST13. The parameters at this time are resource type = CPU load and management node name = N4.
In ST13, the response of the corresponding resource information is received from the table composition unit 104, and the process proceeds to ST14. In ST14, this resource information is returned to the requesting distributed management station, in this example, the overall management station M1.

Next, the operation of the table composition unit 104 of the distributed management station D2 will be described with reference to FIG.
In ST21, a request from the resource information transfer unit 103 is accepted. In this example, the parameters are resource type = CPU load and management node name = N4. In ST22, the distributed management table 113 is referred to obtain the name of the highest distributed management station to which the corresponding management node belongs, and the process proceeds to ST23. The distributed management table of the distributed management station D2 in this example is as shown in FIG. 8, and in FIG. 8, the name of the distributed management station to which the management node N4 belongs is D4. Since the self management station name is D2, the process proceeds from ST23 to ST26.
In ST26, resource information is requested from the resource information transfer unit 103 of the distributed management station D4, and the process proceeds to ST27. In ST27, the corresponding resource information is acquired from the resource information transfer unit 103 of the distributed management station D4, and the process proceeds to ST25. In ST25, the acquired resource information is returned to the resource information transfer unit 103 of the own distributed management station D2.

Next, the operation of the resource information transfer unit 103 of the distributed management station D4 will be described with reference to FIG.
In ST11 of FIG. 3, the resource information request from the distributed station D2 is received, and the process proceeds to ST12. The parameters at this time are resource type = CPU load and management node name = N4. In ST12, the table composition unit 104 is requested to acquire resource information, and the process proceeds to ST13. The parameters at this time are resource type = CPU load and management node name = N4.
In ST13, the response of the corresponding resource information is received from the table composition unit 104, and the process proceeds to ST14. In ST14, the corresponding resource information is returned to the requesting distributed management station, in this example, to the distributed management station D2.

Next, the operation of the table composition unit 104 of the distributed management station D4 will be described with reference to FIG.
4, in ST21, a request from the resource information transfer unit 103 is accepted. In this example, the parameters are resource type = CPU load and management node name = N4. In ST22, the distributed management table 113 is referred to obtain the name of the highest distributed management station to which the corresponding management node belongs, and the process proceeds to ST23. The distribution management table 113 of the distribution management station D4 is as shown in FIG. 9, and it can be seen from FIG. 9 that the name of the distribution management station to which the management node N4 belongs is D4. In ST23, since the own distributed management station name is D4 and the distributed management station name obtained in ST22 is D4, the condition determination result is YES and the process proceeds to ST24.

In ST24, the value of the resource information (CPU load) of the management node N4 is acquired from the resource information table 111 of the own distributed management station D4. An example of the resource information table 111 of the distributed management station D4 in this example is as shown in FIG. 6, and it can be seen from FIG. 6 that the CPU load of the management node N4 is 15%. In ST25, resource information (15%) is returned to the requesting resource information transfer unit.
Accordingly, the resource information (CPU load = 15%) traces the hierarchy in reverse, and is sequentially returned to the resource information display editing unit 102 of the overall management station M1 that is the first request source, and displayed on the display unit 121.

In summary, as shown in FIG. 10, the central management station M1 can display the resource information of the management nodes N1 to N6, but in reality, N1 to N6 are not directly belonging to the central management station M1. Therefore, the resource information of each management node is requested to the distributed management stations D1, D2 and D3 in the lower layer.
The resource information of the management nodes N1 and N2 is requested from the distributed management station D1. The resource information of the management nodes N3, N4, N5 is requested to the distributed management station D2. The resource information of the management node N6 is requested to the distributed management station D3.

Since the requested management nodes N1 and N2 belong directly, the distributed management station D1 returns the resource information of the management nodes N1 and N2 stored in its own resource information table to the overall management station M1.
Similarly, since the management node N6 belongs directly to the distributed management station D3, the information of N6 stored in its own resource information table is returned to the overall management station M1.
On the other hand, the distributed management station D2 can return the resource information stored in its own resource information table because the management node N3 belongs directly, but since the management nodes N4 and N5 are not directly attached, the distributed management station D2 has 1 The resource information of the management nodes N4 and N5 is inquired to the distributed management station D4 in the lower layer.
Since the requested management nodes N4 and N5 belong directly, the distributed management station D4 acquires corresponding resource information from its own resource information table and returns it to the upper layer.

  According to the first embodiment, in a configuration in which a plurality of management stations are hierarchically distributed in the network, the resource information of the management node belonging to the lowest level distributed management station is obtained from a certain distributed management station. Even if you want to do so, simply request the resource information to the distributed management station in the lower layer of the starting distributed management station, and the request will be propagated to the distributed management station in each layer, and the answer will be returned in reverse order Thus, there is an effect that it is not necessary to take a complicated procedure even for resource information of a management node in a remote hierarchy and can be easily obtained.

1 is a system configuration diagram showing a hierarchical resource monitoring system according to Embodiment 1 of the present invention. FIG. It is a flowchart which shows the process of the resource information display edit part of the hierarchical resource monitoring system by Embodiment 1 of this invention. It is a flowchart which shows the process of the resource information transfer part of the hierarchical resource monitoring system by Embodiment 1 of this invention. It is a flowchart which shows the process of the table synthetic | combination part of the hierarchical resource monitoring system by Embodiment 1 of this invention. It is a block diagram which shows the network structural example of the hierarchical resource monitoring system by Embodiment 1 of this invention. FIG. 6 is a diagram showing a resource information table of a distributed management station D4 in the network configuration example shown in FIG. FIG. 6 is a diagram showing a distributed management table of a central management station M1 in the network configuration example shown in FIG. It is a figure which shows the dispersion | distribution management table of dispersion | distribution management station D2 in the network structural example shown in FIG. It is a figure which shows the dispersion | distribution management table of the dispersion | distribution management station D4 in the network structural example shown in FIG. It is a figure which shows the example of a display of the resource information of the management node of each management station in the network structural example shown in FIG.

Explanation of symbols

101 Central management station 102 Resource information display editing unit 103 Resource information transfer unit 104 Table composition unit
105 Resource Information Communication Unit 106 Resource Information Collection Unit 110 Resource Information Database 111 Resource Information Table 112 Distributed Management Database 113 Distributed Management Table 121 Display Unit 122 Input Unit 130 Management Node 201 Distributed Management Station

Claims (1)

A hierarchical resource monitoring system for collecting resource information of management nodes distributed in a network,
A plurality of distributed management stations connected to the network and layered;
And a plurality of management nodes respectively connected to any of the plurality of distributed management stations,
Each of the distributed management stations is connected to a resource information database storing resource information of the management node connected to the own station and a distributed management database storing hierarchical information of the distributed management station.
A resource information collection unit that collects resource information from the management node connected to the own station and stores it in the resource information database;
A resource information communication unit for requesting resource information specifying a target management node and a target resource information type to the lower layer distributed management station, and acquiring the requested resource information from the lower layer distributed management station;
A resource information transfer unit that receives a request for resource information in which a target management node and a target resource information type are specified from the upper layer distributed management station, acquires corresponding resource information, and transfers the resource information to the upper layer distributed management station; ,
In response to a request from the resource information transfer unit, the distributed management database is searched, and when the requested management node is connected to its own station, the corresponding resource information in the resource information database is In response to the information transfer unit, if the management node to be requested is connected to the lower layer distributed management station, the corresponding lower layer distributed management station is connected via the resource information communication unit. And a table composition unit that obtains resource information to be sent and answers the resource information transfer unit.