CN113421028B - Resource water level monitoring platform and method, terminal device and readable storage medium - Google Patents

Abstract

The invention provides a resource water level monitoring platform and method, a terminal device and a readable storage medium, wherein the resource water level monitoring method comprises the following steps: establishing a topological structure based on a service system, wherein each node is bound with corresponding resource equipment in the service system in the topological structure, and is configured with node information and a pointing relationship between different levels; configuring corresponding water level grade threshold values aiming at various indexes of the resource equipment; acquiring water level values and water level trends of all resource equipment and statistics of resource numbers of different grades; respectively calculating the average value aggregation of all indexes of the resource equipment in a selected time period, and comparing the calculation result with a configured water level grade threshold value; and judging the use state of the resource equipment according to the comparison result and displaying the use state in a topology water level monitoring display page. The method provides the capability of creating and managing the topological relation of the business application, constructs the relation between the application and the resource from the business dimension which is more concerned by enterprise users, and realizes intuitive and multidimensional resource management and monitoring.

Description

Resource water level monitoring platform and method, terminal device and readable storage medium

Technical Field

The invention relates to the technical field of monitoring, in particular to a resource water level monitoring platform and method, a terminal device and a readable storage medium.

Background

With the development and the improvement of the informatization level of enterprises, the number of IT devices of enterprises and public institutions, particularly servers, network security devices and the like is increasing, so that the management and control of the devices and the monitoring of the resource condition are more and more important, and the health condition, the use condition, the potential problem detection and the like of the devices become the problems of important needs to be controlled by the enterprises. In addition, with the increasing dependence of business on IT support, the intuitive reflection of the facility situation based on the business application level also becomes a monitoring direction more concerned by users.

At present, multiple monitoring modes are provided for IT operation and maintenance monitoring, equipment index monitoring is one of important and widely used monitoring modes, and core indexes of infrastructure are accessed through a monitoring platform, and a series of aggregation calculation is adopted to reflect the water level state of the important indexes. Although the purpose of monitoring can be well achieved, the defects and shortcomings still exist: 1) The traditional equipment monitoring mode is usually only aimed at index monitoring of single equipment, and monitoring data are very thin under the requirement of monitoring based on visual application; 2) Often, users are notified by means of alarms, and improper configuration is very likely to cause alarm storms and has hysteresis.

Disclosure of Invention

Aiming at the problems, the invention provides a resource water level monitoring platform and method, terminal equipment and a readable storage medium, which effectively solve the technical problems of single monitoring data, data lag and the like in the existing monitoring system.

The technical scheme provided by the invention is as follows:

in one aspect, the present invention provides a resource water level monitoring method, including:

establishing a topological structure based on a service system, wherein each node is bound with corresponding resource equipment in the service system and is configured with node information and a pointing relation between different levels;

configuring corresponding water level grade threshold values aiming at various indexes of the resource equipment;

acquiring water level values and water level trends of all resource equipment and statistics of resource numbers of different grades;

respectively calculating the average value aggregation of all indexes of the resource equipment in a selected time period, and comparing the calculation result with a configured water level grade threshold value;

and judging the use state of the resource equipment according to the comparison result and displaying the use state in a topology water level monitoring display page to finish monitoring the resource water level.

Further preferably, the configuring the corresponding water level threshold value for each index of the resource device includes: configuring corresponding water level grade thresholds for each index of the resource equipment according to a topological water level monitoring display mode, wherein the topological water level monitoring display mode comprises water level monitoring display according to products and water level monitoring display according to a system, the water level grade thresholds are configured according to the types of the accessed resource equipment in the water level monitoring display mode according to the products, and the water level grade thresholds are configured for the resource equipment below the products through a screening system in the water level monitoring display mode according to the system.

Preferably, the water level levels configured in two topological water level monitoring display modes of performing water level monitoring display according to products and performing water level monitoring display according to a system comprise busy, normal and idle;

the judging the use state of the resource device according to the comparison result and displaying the use state in the topology water level monitoring display page comprises the following steps:

aiming at a resource device, judging whether at least one index is busy according to a comparison result;

if yes, judging that the resource equipment is in a busy state;

if not, further judging whether at least one index is normal;

if yes, judging the resource equipment to be in a normal state;

if not, judging that the resource equipment is in an idle state;

and displaying the states of the resource devices in the topology water level monitoring display page according to the selected topology water level monitoring display mode to complete the monitoring of the resource water level.

Further preferably, the number of the directories of the resource water level monitoring platform is 4, the types of the directories include organization, department, service system and environment, and the establishing of the topology structure based on the service system includes:

creating a business system, and defining a directory hierarchy according to organization, departments, the business system and environment according to requirements;

establishing a topological hierarchy and a pointing relation between the hierarchies, defining the names of the hierarchies and configuring resource types to be bound under the hierarchies; wherein, each node in the topology is regarded as a hierarchy, and the directions between the hierarchies are all one-way relations,

and binding each node with corresponding resource equipment in the service system.

On the other hand, the invention also provides a resource water level monitoring platform, which comprises:

the system comprises a topological structure establishing module, a resource management module and a resource management module, wherein the topological structure establishing module is used for establishing a topological structure based on a service system, each node in the topological structure is bound with corresponding resource equipment in the service system, and node information and the pointing relationships among different levels are configured;

the water level threshold configuration module is used for configuring corresponding water level thresholds aiming at various indexes of the resource equipment;

the water level data acquisition module is used for acquiring water level values, water level trends and statistics of resource numbers of different levels of each resource device;

the operation module is used for respectively calculating the average value aggregation of all indexes of the resource equipment in a selected time period and comparing the calculation result with the configured water level grade threshold value;

and the water level monitoring display module is used for judging the use state of the resource equipment according to the comparison result and displaying the use state in the topology water level monitoring display page to finish monitoring the resource water level.

Further preferably, in the water level threshold configuration module, configuring corresponding water level thresholds for each index of the resource device according to a topology water level monitoring display mode, where the topology water level monitoring display mode includes performing water level monitoring display according to a product and performing water level monitoring display according to a system, and the water level thresholds are configured according to the type of the accessed resource device in the product water level monitoring display mode and configured according to the system water level monitoring display mode by the screening system for the resource device below the product water level thresholds.

Further preferably, in the water level threshold configuration module, the water level levels configured in two topology water level monitoring display modes of performing water level monitoring display according to products and performing water level monitoring display according to systems both include busy, normal and idle;

the water level monitoring and displaying module comprises:

a resource state judging unit, configured to judge, for a resource device, whether at least one indicator is busy according to a comparison result; if yes, judging that the resource equipment is in a busy state; if not, further judging whether at least one index is normal; if yes, judging the resource equipment to be in a normal state; if not, judging that the resource equipment is in an idle state;

and the water level monitoring display unit is used for displaying the state of each resource device in the topology water level monitoring display page according to the selected topology water level monitoring display mode to complete the monitoring of the resource water level.

Further preferably, the number of the directories of the resource water level monitoring platform is 4, the directory types include organization, department, service system and environment, and the topology structure creating module includes:

the business system creating unit is used for creating a business system and defining the directory hierarchy according to the organization, the department, the business system and the environment according to the requirements;

the topology creating unit is used for creating a topology hierarchy and a pointing relationship between the hierarchies, defining the names of the hierarchies and configuring resource types to be bound under the hierarchies; wherein, each node in the topology is regarded as a hierarchy, and the directions between the hierarchies are all one-way relations,

and the resource binding unit is used for binding each node with the corresponding resource equipment in the service system.

In another aspect, the present invention further provides a terminal device, which includes a memory, a processor, and a computer program stored in the memory and executable on the processor, where the processor implements the steps of the resource level monitoring method when executing the computer program.

In another aspect, the present invention further provides a computer-readable storage medium, which stores a computer program, and when the computer program is executed by a processor, the computer program implements the steps of the resource level monitoring method.

The resource water level monitoring platform and method, the terminal device and the readable storage medium provided by the invention can at least bring the following beneficial effects:

1) The method provides the capability of creating and managing the topological relation of the business application, constructs the relation between the application and the resource from the business dimension which is more concerned by enterprise users, and realizes visual and multidimensional resource management and monitoring.

2) Through self-defined water level grade configuration, the resource water level information is checked at any time, the equipment state is further reflected from the index water level layer, the initial judgment of bottleneck resources or idle resources is assisted, and enterprise resource optimization is assisted.

Drawings

The foregoing features, technical features, advantages and embodiments are further described in the following detailed description of the preferred embodiments, which is to be read in connection with the accompanying drawings.

FIG. 1 is a schematic flow chart of a resource level monitoring method according to the present invention;

FIG. 2 is a schematic view of a resource water level monitoring platform according to the present invention;

fig. 3 is a schematic structural diagram of a terminal device in the present invention.

Reference numerals are as follows:

the method comprises the following steps of 100-a resource water level monitoring platform, 110-a topological structure creating module, 120-a water level grade threshold value configuring module, 130-a water level data obtaining module, 140-an operation module and 150-a water level monitoring display module.

Detailed Description

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the following description will be made with reference to the accompanying drawings. It is obvious that the drawings in the following description are only some examples of the invention, and that for a person skilled in the art, other drawings and embodiments can be derived from them without inventive effort.

In a first embodiment of the present invention, as shown in fig. 1, a resource level monitoring method includes:

s10, establishing a topological structure based on the service system, wherein each node is bound with corresponding resource equipment in the service system in the topological structure, and node information and the pointing relationships among different levels are configured;

s20, configuring corresponding water level grade thresholds for various indexes of the resource equipment;

s30, acquiring water level values, water level trends and statistics of resource numbers of different grades of each resource device;

s40, calculating average values of all indexes of the resource equipment in a selected time period, aggregating the average values, and comparing the calculation results with a configured water level grade threshold value;

and S50, judging the use state of the resource equipment according to the comparison result, displaying the use state in a topology water level monitoring display page, and finishing monitoring the resource water level.

In this embodiment, before monitoring the resource level, a topological relation of accessed resource devices based on service applications is first established, in this process, information and a direction relation of each node are defined for a topology, and corresponding resource devices are bound for each node, that is, a "topological relation definition" and a "hierarchical resource binding" are involved, where the "topological relation definition" specifically defines a hierarchical name and a resource device type involved in a complete service application through a topological interface, and for example, one application system includes a network layer, an application layer, and a data layer. It should be noted that each node is considered as a level in the topology, and all associations are unidirectional, pointing from the source level to the target level, not allowing a closed loop to be formed. The "hierarchical resource binding" firstly needs to define the resource device type allowed to be bound for the hierarchy during creation, so that corresponding resource devices are selected and bound in an open resource list based on the resource device type in the following, and association between the resource devices and the nodes is realized.

In one example, the number of directories provided by the resource water level monitoring platform is 4, the directory types include organization, department, business system and environment, wherein the organization and the department have enterprise organization architecture attributes, the business system defines applications to be created finally, application names such as an OA system, an ERP system and the like can be defined for the business system according to actual application, the environment is further expanded, topologies in different environments such as a production environment, a test environment and the like can be created according to needs, and a specific topological diagram is embodied in the fourth level-environment. Based on this, in establishing a topology structure based on a service system, the method includes: creating a business system, and defining a directory hierarchy according to organization, departments, the business system and environment according to requirements; establishing a topological hierarchy and a pointing relation between the hierarchies, defining the names of the hierarchies and configuring resource types to be bound under the hierarchies; each node in the topology is regarded as a hierarchy, the directions between the hierarchies are all in a one-way relationship, and each node is bound with corresponding resource equipment in the service system. It should be clear that, in other examples, the application topology creation requirements of different enterprises may be adapted by modifying the number of directories and the types of directories in the database table, which is not specifically limited in this embodiment, and may be modified accordingly according to actual applications.

After the creation of the topology structure is completed, immediately setting a threshold value for each resource index according to different grades, and using the threshold value as a logic basis of a subsequent index state and even a resource state, wherein the logic basis comprises the following steps: configuring corresponding water level grade thresholds for each index of the resource equipment according to a topological water level monitoring display mode, wherein the topological water level monitoring display mode comprises water level monitoring display according to a product and water level monitoring display according to a system, and the water level grade thresholds are configured according to the type of the accessed resource equipment in the water level monitoring display mode of the product, such as a cloud server ECS, a database MySQL and the like; and configuring a water level grade threshold value for the resource equipment below the water level monitoring system through a screening system in a water level monitoring display mode according to the system.

In addition, the water level grades configured in two topological water level monitoring display modes of performing water level monitoring display according to products and performing water level monitoring display according to a system respectively comprise busy, normal and idle, wherein the idle indicates that the water level value is low, the resource utilization rate is low and the water level is likely to be idle; "Normal" means that the resource is used well and the resource is reasonably occupied; busy indicates that the resource level is high, and the resource is likely to reach the bottleneck quickly, so that the capacity expansion of the distribution can be considered. The configuration of the water level threshold value can be configured according to the actual situation, and is not specifically limited here, for example, in an example, the value "normal" is set to 25, and the value "busy" is set to 75, that is, when the actual value of the indicator is less than or equal to 25, the indicator is idle, the indicator is normal when the actual value is greater than or equal to 25, and the indicator is busy when the actual value is greater than or equal to 75; in another example, "Normal" is set to 20 and "Busy" is set to 80, i.e., when the true value of the indicator is ≦ 20 indicating idle, >20 and ≦ 80 indicating normal, and >80 indicating Busy.

Here, "performing water level monitoring and displaying according to the system" is to observe the resource use state of the corresponding system from the service topology dimension, and can check the water level value, the water level trend and the statistics of the number of resources in different levels of the bound resource at each node level; the 'water level monitoring and displaying according to products' is that resource water levels, water level trends and statistics of different levels of resources under corresponding types are browsed in a list form from the dimension of equipment types, and busy or idle resource lists can be quickly screened according to the level filtering lists.

And finally, showing the resource water level condition through the service topology dimension, counting the number of resources in different levels, quickly screening resources in busy and idle states, and making preliminary judgment for resource configuration adjustment, so that subsequent targeted analysis is facilitated, and resource optimization is facilitated. Specifically, firstly, acquiring water level values, water level trends and statistics of resource numbers of different levels of each resource device; then, calculating the average value aggregation of all indexes of the resource equipment in a selected time period, and comparing the calculation result with a configured water level grade threshold value; and finally, judging the use state of the resource equipment according to the comparison result and displaying the use state in a topology water level monitoring display page to finish monitoring the resource water level.

Because a resource device uses a plurality of core indexes as monitoring basis, the process of judging the use state of the resource device according to the comparison result and displaying the resource device in the topology water level monitoring display page comprises the following steps: aiming at a resource device, judging whether at least one index is busy according to a comparison result; if yes, judging that the resource equipment is in a busy state; if not, further judging whether at least one index is normal; if yes, judging the resource equipment to be in a normal state; if not, judging that the resource equipment is in an idle state; and displaying the states of the resource devices in a topology water level monitoring display page according to the selected topology water level monitoring display mode to complete the monitoring of the resource water level. When one or more indexes have busy water level average values in all indexes, preliminarily judging that the resource equipment is busy in a corresponding time period; when all the index water level average values are idle, preliminarily judging that the resource equipment is idle in a time period; all other cases are normal. In practical applications, for easy viewing, different states may be displayed by setting different colors, for example, a busy value represents red, an idle value represents green, a normal value represents blue, and the like.

In one example, the resource level monitoring method specifically includes:

step 1: creating a business system, and defining a directory hierarchy according to organization, department, business system and environment according to requirements;

step 2: establishing a topological hierarchy and a directional relation among the hierarchies in a page, defining the names of the hierarchies and selecting resource types to be bound under the hierarchies;

and step 3: binding specific resource equipment for a topological hierarchy in a page;

and 4, step 4: and carrying out water level configuration aiming at each index of the resource. It should be noted that if the configuration mode is "perform water level monitoring display according to product" or there is a system to be selected when "perform water level monitoring display according to system", the water level configuration may be performed at any time, and if the configuration mode is "perform water level monitoring display according to system" there is no system to be selected, the water level configuration needs to be performed after step 3;

and 5: performing average value aggregation calculation for each index of the resource equipment according to the selected time period, comparing the obtained result with a threshold value set by each grade, and judging the water level grade of the index;

step 6: judging all indexes of each resource device, and if at least one index is busy, counting that the resource is busy; if no index is busy and at least one index is normal, the resource is counted as normal; if all the indexes are idle, the resource is counted as idle;

and 7: and checking the resource water level condition under the topology water level monitoring display page based on the service application.

In another embodiment of the present invention, a resource level monitoring platform 100, as shown in fig. 2, includes: a topology structure creating module 110, configured to create a topology structure based on a service system, where each node is bound to a corresponding resource device in the service system and configured with node information and a pointing relationship between different levels; a water level threshold configuration module 120, configured to configure corresponding water level thresholds for various indexes of the resource device; a water level data obtaining module 130, configured to obtain water level values, water level trends, and statistics of resource numbers of different levels of each resource device; the operation module 140 is configured to calculate an average aggregation of the indexes of the resource device within a selected time period, and compare the calculation result with a configured water level threshold; and the water level monitoring and displaying module 150 is configured to judge the use state of the resource device according to the comparison result, display the use state in the topology water level monitoring and displaying page, and complete monitoring of the resource water level.

In this embodiment, before monitoring the resource level, a topological relation of the accessed resource device based on the service application is first established, in this process, information and a pointing relation of each node are defined for the topology, and a corresponding resource device is bound for each node, that is, a "topological relation definition" and a "hierarchical resource binding" are involved, where the "topological relation definition" specifically defines a hierarchical name and a resource device type related to the complete service application through a topological interface, and for example, one application system includes a network layer, an application layer, and a data layer. It should be noted that each node is considered a level in the topology and all associations are unidirectional, pointing from the source level to the target level, not allowing a closed loop to be formed. The "hierarchical resource binding" firstly needs to define the resource device type allowed to be bound for the hierarchy during creation, so that corresponding resource devices are selected and bound in an open resource list based on the resource device type in the following, and association between the resource devices and the nodes is realized.

In one example, the number of directories provided by the resource water level monitoring platform is 4, the directory types include organizations, departments, business systems and environments, wherein the organizations and the departments have enterprise organization architecture attributes, the business systems define applications to be created finally, application names such as an OA system, an ERP system and the like can be defined for the business systems according to actual applications, the environments are further expanded, topologies under different environments such as a production environment, a test environment and the like can be created according to needs, and a specific topological graph is embodied in a fourth level-environment. Based on this, the topology creating module comprises: the business system creating unit is used for creating a business system and defining the directory hierarchy according to the organization, the department, the business system and the environment according to the requirements; the topology creating unit is used for creating a topology hierarchy and a pointing relationship between the hierarchies, defining the names of the hierarchies and configuring resource types to be bound under the hierarchies; each node in the topology is regarded as a hierarchy, the directions between the hierarchies are all in a one-way relationship, and the resource binding unit is used for binding each node with corresponding resource equipment in the service system. It should be clear that, in other examples, the application topology creation requirements of different enterprises may be adapted by modifying the number of directories and the types of directories in the database table, which is not specifically limited in this embodiment, and may be modified accordingly according to actual applications.

After the establishment of the topological structure is completed, immediately setting thresholds for each resource index according to different levels as a logic basis of a subsequent index state and even a resource state, configuring corresponding water level threshold values for each index of the resource equipment according to a topological water level monitoring display mode in a water level threshold value configuration module, wherein the topological water level monitoring display mode comprises water level monitoring display according to a product and water level monitoring display according to a system, configuring the water level threshold values according to the type of the accessed resource equipment in the water level monitoring display mode according to the product, and configuring the water level threshold values for the resource equipment below the topological water level monitoring display mode according to the water level monitoring display system of the system.

In addition, in the water level grade threshold value configuration module, the water level grades configured in two topological water level monitoring display modes of performing water level monitoring display according to products and performing water level monitoring display according to a system comprise busy, normal and idle, wherein the idle indicates that the water level value is low, the resource utilization rate is low and the water level grade is likely to be idle; "Normal" means that the resource is used well and the resource is reasonably occupied; busy indicates that the resource level is high, and the resource is likely to reach the bottleneck quickly, so that the capacity expansion of the distribution can be considered. The configuration of the water level threshold value can be configured according to the actual situation, and is not specifically limited here, for example, in an example, the value "normal" is set to 25, and the value "busy" is set to 75, that is, when the actual value of the indicator is less than or equal to 25, the indicator is idle, the indicator is normal when the actual value is greater than or equal to 25, and the indicator is busy when the actual value is greater than or equal to 75; in another example, a "normal" value of 20 and a "busy" value of 80 are set, i.e., when the true value of the indicator is ≦ 20 indicating idle, >20 and ≦ 80 indicating normal, and >80 indicating busy.

Here, "performing water level monitoring and displaying according to the system" is to observe the resource use state of the corresponding system from the service topology dimension, and can check the water level value, the water level trend and the statistics of the number of resources in different levels of the bound resource at each node level; the 'water level monitoring and displaying according to products' is that resource water levels, water level trends and statistics of different levels of resources under corresponding types are browsed in a list form from the dimension of equipment types, and busy or idle resource lists can be quickly screened according to the level filtering lists.

And finally, showing the resource water level condition through the service topology dimension, counting the number of resources in different levels, quickly screening resources in busy and idle states, and making preliminary judgment for resource configuration adjustment, so that subsequent targeted analysis is facilitated, and resource optimization is facilitated. Specifically, the water level monitoring and displaying module comprises: a resource state judging unit, configured to judge, for a resource device, whether at least one indicator is busy according to a comparison result; if yes, judging that the resource equipment is in a busy state; if not, further judging whether at least one index is normal; if yes, judging the resource equipment to be in a normal state; if not, judging that the resource equipment is in an idle state; and the water level monitoring display unit is used for displaying the states of the resource devices in the topology water level monitoring display page according to the selected topology water level monitoring display mode to complete the monitoring of the resource water level.

Because a resource device uses a plurality of core indexes as monitoring basis, the process of judging the use state of the resource device according to the comparison result and displaying the resource device in the topology water level monitoring display page comprises the following steps: aiming at a resource device, judging whether at least one index is busy according to a comparison result; if yes, judging that the resource equipment is in a busy state; if not, further judging whether at least one index is normal; if yes, judging that the resource equipment is in a normal state; if not, judging that the resource equipment is in an idle state; and displaying the states of the resource devices in a topology water level monitoring display page according to the selected topology water level monitoring display mode to complete the monitoring of the resource water level. When one or more than one index water level average value is busy in all indexes, preliminarily judging that the resource equipment is busy in a corresponding time period; when all the index water level average values are idle, preliminarily judging that the resource equipment is idle in a time period; all other cases are normal. In practical applications, for easy viewing, different states may be displayed by setting different colors, for example, a busy value represents red, an idle value represents green, a normal value represents blue, and the like.

It will be apparent to those skilled in the art that, for convenience and brevity of description, only the above-described division of program modules is illustrated, and in practical applications, the above-described distribution of functions may be performed by different program modules, that is, the internal structure of the apparatus may be divided into different program units or modules to perform all or part of the above-described functions. Each program module in the embodiments may be integrated in one processing unit, or each unit may exist alone physically, or two or more units are integrated in one processing unit, and the integrated unit may be implemented in a form of hardware, or may be implemented in a form of software program unit. In addition, the specific names of the program modules are only used for distinguishing the program modules from one another, and are not used for limiting the protection scope of the application.

Fig. 3 is a schematic structural diagram of a terminal device provided in an embodiment of the present invention, and as shown, the terminal device 200 includes: a processor 220, a memory 210, and a computer program 211 stored in the memory 210 and executable on the processor 220, such as: the resource water level monitoring method is related to a program. The processor 220 implements the steps of the above embodiments of the resource level monitoring method when executing the computer program 211, or the processor 220 implements the functions of the above modules of the embodiments of the resource level monitoring platform when executing the computer program 211.

The terminal device 200 may be a notebook, a palm computer, a tablet computer, a mobile phone, or the like. Terminal device 200 may include, but is not limited to, processor 220, memory 210. Those skilled in the art will appreciate that fig. 3 is merely an example of the terminal device 200, does not constitute a limitation of the terminal device 200, and may include more or fewer components than those shown, or some of the components may be combined, or different components, such as: terminal device 200 may also include input-output devices, display devices, network access devices, buses, and the like.

Processor 220 may be a Central Processing Unit (CPU), other general purpose Processor, a Digital Signal Processor (DSP), an Application Specific Integrated Circuit (ASIC), a Field Programmable Gate Array (FPGA) or other Programmable logic device, discrete Gate or transistor logic, discrete hardware components, etc. The general purpose processor 220 may be a microprocessor or the processor may be any conventional processor or the like.

The memory 210 may be an internal storage unit of the terminal device 200, such as: a hard disk or a memory of the terminal device 200. The memory 210 may also be an external storage device of the terminal device 200, such as: a plug-in hard disk, an intelligent TF memory Card (SMC), a Secure Digital (SD) Card, a Flash memory Card (Flash Card), etc. provided on the terminal device 200. Further, the memory 210 may also include both an internal storage unit of the terminal device 200 and an external storage device. The memory 210 is used to store the computer program 211 and other programs and data required by the terminal device 200. The memory 210 may also be used to temporarily store data that has been output or is to be output.

In the above embodiments, the descriptions of the respective embodiments have respective emphasis, and reference may be made to the related descriptions of other embodiments for parts that are not described or recited in detail in a certain embodiment.

Those of ordinary skill in the art will appreciate that the various illustrative elements and algorithm steps described in connection with the embodiments disclosed herein may be implemented as electronic hardware, or combinations of computer software and electronic hardware. Whether such functionality is implemented as hardware or software depends upon the particular application and design constraints imposed on the implementation. Skilled artisans may implement the described functionality in varying ways for each particular application, but such implementation decisions should not be interpreted as causing a departure from the scope of the present application.

In the embodiments provided in the present application, it should be understood that the disclosed apparatus/terminal device and method may be implemented in other ways. For example, the above-described apparatus/terminal device embodiments are merely illustrative, and for example, a module or a unit may be divided into only one type of logic function, and another division manner may be provided in actual implementation, for example, multiple units or components may be combined or integrated into another system, or some features may be omitted, or not executed. In addition, the shown or discussed mutual coupling or direct coupling or communication connection may be an indirect coupling or communication connection of some interfaces, devices or units, and may be in an electrical, mechanical or other form.

Units described as separate parts may or may not be physically separate, and parts displayed as units may or may not be physical units, may be located in one place, or may be distributed on a plurality of network units. Some or all of the units can be selected according to actual needs to achieve the purpose of the solution of the embodiment.

In addition, functional units in the embodiments of the present application may be integrated into one processing unit, or each unit may exist alone physically, or two or more units are integrated into one unit. The integrated unit may be implemented in the form of hardware, or may also be implemented in the form of a software functional unit.

The integrated modules/units, if implemented in the form of software functional units and sold or used as separate products, may be stored in a computer readable storage medium. Based on such understanding, all or part of the flow of the method according to the embodiments of the present invention may also be implemented by sending instructions to relevant hardware by the computer program 211, where the computer program 211 may be stored in a computer-readable storage medium, and when the computer program 211 is executed by the processor 220, the steps of the method embodiments may be implemented. Wherein the computer program 211 comprises: computer program code which may be in the form of source code, object code, an executable file or some intermediate form, etc. The computer-readable storage medium may include: any entity or device capable of carrying computer program 211 code, recording medium, U.S. disk, removable hard disk, magnetic diskette, optical disk, computer Memory, read-Only Memory (ROM), random Access Memory (RAM), electrical carrier wave signal, telecommunications signal, and software distribution medium, etc. It should be noted that the content of the computer readable storage medium can be increased or decreased according to the requirements of the legislation and patent practice in the jurisdiction, for example: in certain jurisdictions, in accordance with legislation and patent practice, the computer-readable medium does not include electrical carrier signals and telecommunications signals.

It should be noted that the above embodiments can be freely combined as necessary. The foregoing is only a preferred embodiment of the present invention, and it should be noted that, for persons skilled in the art, numerous modifications and adaptations can be made without departing from the principle of the present invention, and such modifications and adaptations should be considered as within the scope of the present invention.

Claims (6)

1. A resource water level monitoring method is characterized by comprising the following steps:

establishing a topological structure based on a service system, wherein each node is bound with corresponding resource equipment in the service system and is configured with node information and a pointing relation between different levels;

configuring corresponding water level grade threshold values aiming at various indexes of resource equipment;

acquiring water level values and water level trends of all resource equipment and statistics of resource numbers of different grades;

respectively calculating the average value aggregation of all indexes of the resource equipment in a selected time period, and comparing the calculation result with a configured water level grade threshold value;

judging the use state of the resource equipment according to the comparison result and displaying the use state in a topology water level monitoring display page to complete the monitoring of the resource water level;

the configuring of the corresponding water level threshold value for each index of the resource device includes: configuring corresponding water level grade thresholds for each index of resource equipment according to a topological water level monitoring display mode, wherein the topological water level monitoring display mode comprises water level monitoring display according to products and water level monitoring display according to a system, the water level grade thresholds are configured according to the types of accessed resource equipment in the water level monitoring display mode of the products, and the water level grade thresholds are configured for the resource equipment below the products through a screening system in the water level monitoring display mode of the system;

the water level grades configured in two topological water level monitoring display modes of performing water level monitoring display according to products and performing water level monitoring display according to a system comprise busy, normal and idle;

the judging the use state of the resource device according to the comparison result and displaying the use state in the topology water level monitoring display page comprises the following steps:

aiming at a resource device, judging whether at least one index is busy according to a comparison result;

if yes, judging that the resource equipment is in a busy state;

if not, further judging whether at least one index is normal;

if yes, judging that the resource equipment is in a normal state;

if not, judging that the resource equipment is in an idle state;

and displaying the states of the resource devices in a topology water level monitoring display page according to the selected topology water level monitoring display mode to complete the monitoring of the resource water level.

2. The method for monitoring the resource water level according to claim 1, wherein the number of the directories of the resource water level monitoring platform is 4, the directory types include organization, department, service system and environment, and the establishing of the topology structure based on the service system includes:

creating a business system, and defining a directory hierarchy according to organization, departments, the business system and environment according to requirements;

establishing a topological hierarchy and a pointing relation between the hierarchies, defining the names of the hierarchies and configuring resource types to be bound under the hierarchies; wherein, each node in the topology is regarded as a hierarchy, and the directions between the hierarchies are all one-way relations,

and binding each node with corresponding resource equipment in the service system.

3. A resource water level monitoring platform, comprising:

the system comprises a topological structure establishing module, a resource management module and a resource management module, wherein the topological structure establishing module is used for establishing a topological structure based on a service system, each node in the topological structure is bound with corresponding resource equipment in the service system, and node information and the pointing relationships among different levels are configured;

the water level grade threshold configuration module is used for configuring corresponding water level grade thresholds aiming at all indexes of the resource equipment;

the water level data acquisition module is used for acquiring water level values, water level trends and statistics of resource numbers of different levels of each resource device;

the operation module is used for respectively calculating the average value aggregation of all indexes of the resource equipment in a selected time period and comparing the calculation result with the configured water level grade threshold value;

the water level monitoring display module is used for judging the use state of the resource equipment according to the comparison result and displaying the use state in a topological water level monitoring display page to complete the monitoring of the resource water level;

in the water level grade threshold value configuration module, configuring corresponding water level grade threshold values for all indexes of resource equipment according to a topological water level monitoring display mode, wherein the topological water level monitoring display mode comprises water level monitoring display according to products and water level monitoring display according to a system, the water level grade threshold values are configured according to the types of accessed resource equipment in the water level monitoring display mode according to the products, and the water level grade threshold values of the resource equipment below the product are configured through a screening system in the water level monitoring display mode according to the system;

in the water level grade threshold value configuration module, the water level grades configured in two topological water level monitoring display modes of performing water level monitoring display according to products and performing water level monitoring display according to a system comprise busy, normal and idle;

the water level monitoring and displaying module comprises:

a resource state judging unit, configured to judge, for a resource device, whether at least one indicator is busy according to a comparison result; if yes, judging that the resource equipment is in a busy state; if not, further judging whether at least one index is normal; if yes, judging that the resource equipment is in a normal state; if not, judging that the resource equipment is in an idle state;

and the water level monitoring display unit is used for displaying the state of each resource device in the topology water level monitoring display page according to the selected topology water level monitoring display mode to complete the monitoring of the resource water level.

4. The resource water level monitoring platform according to claim 3, wherein the number of the directories of the resource water level monitoring platform is 4, the directory types include organization, department, business system and environment, and the topology creating module comprises:

the business system creating unit is used for creating a business system and defining the directory hierarchy according to the organization, the department, the business system and the environment according to the requirements;

the topology creating unit is used for creating a topology hierarchy and a pointing relationship among the hierarchies, defining the names of the hierarchies and configuring resource types to be bound under the hierarchies; wherein each node in the topology is regarded as a hierarchy, and the directions between the hierarchies are all in a one-way relationship,

and the resource binding unit is used for binding each node with the corresponding resource equipment in the service system.

5. A terminal device comprising a memory, a processor and a computer program stored in said memory and executable on said processor, characterized in that said processor implements the steps of the resource level monitoring method according to claim 1 or 2 when executing said computer program.

6. A computer-readable storage medium, in which a computer program is stored which, when being executed by a processor, carries out the steps of the resource level monitoring method according to claim 1 or 2.

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