CN110830553B - System integration intermediary supervision method based on relay switching - Google Patents

Abstract

The invention discloses a system integration intermediary supervision method based on relay switching, which comprises the steps of firstly deploying relay switching agents at the front end of an integrated system in a hot-pluggable mode; secondly, the service requests among all service systems are transferred through the relay transfer Agent, and the request sending and request return data are effectively obtained; then, carrying out formatting processing and relational storage on the acquired data; then carrying out real-time statistics and audit analysis processing on the obtained data; and finally, performing system integration steady-state index release and problem prediction according to the data analysis result. The invention relates to a system integration intermediary supervision method based on relay switching, which is feasible in the whole scheme by considering a buried point monitoring method of a server hardware facility, and can greatly reduce the pressure of multi-system integration operation and maintenance personnel.

Description

System integration intermediary supervision method based on relay switching

Technical Field

The invention belongs to the technical field of multi-information system integration, and particularly relates to a system integration intermediary supervision method based on relay switching.

Background

With the high-speed development of informatization in China, the informatization construction stage of most of industries or enterprises is in a key node which is formed by single construction and moves forward to the comprehensive integration stage, and is influenced by the informatization development path of China, and the informatization construction of most of enterprises is built successively according to capital investment and enterprise service requirements, so that the current application situations of data island and chimney type service systems are formed.

Under this background, most enterprises have carried out multisystem integration through the theory of SOA or microservice, most technical staff and user personnel all pay close attention to in the integrated effect, rarely have the analysis of concentrating on integrated process, this leads to the system integration back of coming on the line, the operation and maintenance cost in later stage is very big, and integration generally involves a plurality of producers, can't quick location after the problem takes place, and mutual dereliction between a plurality of producers, stability, efficiency are all very poor. Therefore, the integration process needs to be effectively analyzed, standardized and toolized, the operation state of the system interface after integration is effectively monitored, and the integration and operation efficiency of the service system is improved.

Disclosure of Invention

The invention aims to provide a system integration intermediary supervision method based on relay switching, which is used for effectively analyzing the process of multi-system integration, effectively supervising the running state of an integrated system interface and improving the integration and running efficiency of a service system.

The technical scheme adopted by the invention is that a system integration intermediary monitoring method based on relay switching specifically comprises the following steps:

step 1: deploying a relay transfer Agent at the front end of the integrated system in a hot-pluggable mode;

and 2, step: the service requests among all service systems are transferred through the relay transfer Agent, and the request sending and request returning data are effectively obtained;

and step 3: formatting and relational storage are carried out on the obtained data;

and 4, step 4: carrying out real-time statistics and audit analysis processing on the data obtained in the step 3;

and 5: and performing system integration steady-state index issuing and problem prediction according to the data analysis result.

The invention is also characterized in that:

the specific deployment process of step 1 is:

step 1.1: at the front end of the integrated system, the system needs to effectively arrange and disclose the interface with the interaction request;

step 1.2: and deploying a relay transfer Agent program with the latest version by a Clickence technology, and matching the relevant configuration parameters in the Agent with the interface.

The specific process of step 3 is as follows:

step 3.1: combing the acquired information according to the information of the field attribute;

step 3.2: and storing the acquired information in a preset database table according to the main foreign key relation, and storing by using an SQL Server.

The specific process of step 4 is as follows:

step 4.1: judging the communication state of the interface connection;

and 4.2: judging whether the interface receives the request;

step 4.3: judging whether the returned information after receiving the request is normal or not;

step 4.4: judging whether the basic format and the symbolic information of the returned data are normal or not;

step 4.5: and judging whether the state information of the receiving interface is normal or not.

The process of step 5 is as follows:

step 5.1: the state of each interface and the data receiving condition are reflected in real time in a list form;

step 5.2: issuing the steady-state continuous working time of each interface in a form of a histogram;

step 5.3: and numerically displaying the stability of the interface of the whole system, namely the fault time of the interface from the online of the interface/the normal working time of the interface.

The invention has the beneficial effects that:

1. deploying a relay request transfer interface at the front end of an integrated service bus based on an SOA architecture or the front end of an API based on micro-service integration in an Agent mode to ensure that each request among multiple systems can be filtered through the transfer interface;

2. when a request occurs, the relay requests the switching interface to capture data, and automatically acquires the required data through formatting configuration and analysis;

3. carrying out formatting analysis on the acquired data, and effectively storing the relational data;

4. the system background automatically carries out real-time statistics and audit processing analysis on the relational data in a thread mode;

5. the result of data analysis is released in the form of steady-state index, and the information center operation and maintenance personnel can check the stable state of system integration in real time and perform multiple regression analysis on the integration problem in operation to give a logical prediction result.

Drawings

Fig. 1 is a flow chart of a system integrated intermediary supervision method based on relay switching according to the present invention;

fig. 2 is a schematic diagram of a deployment of the relay transit interface in fig. 1.

Detailed Description

The invention is described in detail below with reference to the drawings and the detailed description.

The invention relates to a system integration intermediary supervision method based on relay switching, which specifically comprises the following steps as shown in figure 1:

step 1: deploying a relay transfer Agent at the front end of the integrated system in a hot-pluggable mode;

the relay transfer interface is deployed as shown in fig. 2, and the relay transfer Agent of the present invention is deployed at the front end of the unified entry of the original integrated system.

The specific deployment process of step 1 is:

step 1.1: at the front end of the integrated system, the system needs to effectively arrange and disclose the interface with the interaction request;

step 1.2: deploying a relay transfer Agent program of the latest version through a Clickocen technology, and matching relevant configuration parameters in the Agent with an interface.

For example: the integrated system is a food and drug supervision platform in Shaanxi province, 8 systems are totally used for administrative permission, supervision and inspection, sampling inspection and test, credit management and the like, 1-2 interfaces may be disclosed for each system, and agents can carry out standardized processing on requests and parameters of each interface, so that free communication among a plurality of systems can be ensured, communication contents can be supervised, and the communication quality can be ensured.

Step 2: the service requests among all the service systems are transferred through the relay transfer Agent, and the request sending and request returning data are effectively obtained, wherein after the Agent interface is deployed, all the requests firstly pass through the relay Agent and then are distributed to the original integrated system by the Agent or are transferred to all the service systems; acquiring necessary service field information according to the interpretation of the interface of the original integrated system, and acquiring interface connection state information according to connection information preset by the system.

The data acquisition technology is the prior art, the method is mainly based on HTTP requests, and necessary acquisition information comprises the following steps: a request address, a request parameter string in JSon format, etc.

And step 3: formatting and relational storage are carried out on the obtained data;

step 3.1: combing the acquired information according to the information of the field attribute;

step 3.2: and storing the acquired information in a preset database table according to the main foreign key relation, and storing by using an SQL Server.

Wherein, the field attribute comprises: sequence number, time, request address, request parameters, return information, etc.

And 4, step 4: carrying out real-time statistics and audit analysis processing on the data obtained in the step 3;

step 4.1: judging the communication state of the interface connection;

step 4.2: judging whether the interface receives the request;

step 4.3: judging whether the returned information after receiving the request is normal or not;

step 4.4: judging whether the basic format and the symbolic information of the returned data are normal or not;

step 4.5: and judging whether the state information of the receiving interface is normal or not.

If an interface is abnormal, the problem does not necessarily directly occur on the interface, and a problem may occur on an interface depending on or called by the interface, so that successive recursive analysis is required until a root cause is found, and the step of the recursive analysis is as follows: starting from the interface with the problem, analyzing upwards successively according to the calling logic of the interface; for example: the interface calling logic is A-B-C-D-E-F, if the monitoring program finds that the interface F has a problem, the monitoring program firstly analyzes whether the interface F has the problem, if the interface F has the problem, the monitoring program stops analyzing, otherwise, the interface F continues to analyze upwards E, and so on.

And 5: and performing system integration steady-state index release and problem prediction according to the data analysis result.

Step 5.1: the state of each interface and the data receiving condition are reflected in real time in a list form;

step 5.2: issuing the steady-state continuous working time of each interface in a form of a histogram;

step 5.3: and numerically displaying the stability of the interface of the whole system, namely the fault time of the interface/the normal working time of the interface since the interface is on line.

The method has the advantages that the method can be widely applied to the problem analysis of the prior art, the problem analysis is carried out in advance, the real-time performance is high, and the problem recursive analysis can be carried out in a deep level.

The method of the invention is feasible in the whole scheme by considering the embedded point monitoring method of the server hardware facility, and the pressure of multi-system integration operation and maintenance personnel can be greatly reduced by the method.

Claims (1)

1. A system integration intermediary supervision method based on relay switching is characterized by comprising the following steps:

step 1: deploying a relay transfer Agent at the front end of the integrated system in a hot-pluggable mode;

and 2, step: the service request among all service systems is transferred through the relay transfer Agent, and the request sending and request return data are effectively obtained;

and step 3: formatting and relational storage are carried out on the obtained data;

and 4, step 4: carrying out real-time statistics and audit analysis processing on the data obtained in the step 3;

and 5: performing system integration steady-state index issuing and problem prediction according to the data analysis result;

the specific deployment process of the step 1 is as follows:

step 1.1: at the front end of the integrated system, the system needs to effectively arrange and disclose the interface with the interaction request;

step 1.2: deploying a relay transfer Agent program with the latest version by a Clickence technology, and matching relevant configuration parameters in the Agent with an interface;

the specific process of the step 3 is as follows:

step 3.1: combing the acquired information according to the information of the field attribute;

step 3.2: storing the acquired information in a preset database table according to the main foreign key relation, and storing the information by using an SQL Server;

the specific process of the step 4 is as follows:

step 4.1: judging the communication state of the interface connection;

step 4.2: judging whether the interface receives the request;

step 4.3: judging whether the returned information after receiving the request is normal or not;

step 4.4: judging whether the basic format and the symbolic information of the returned data are normal or not;

step 4.5: judging whether the state information of the receiving interface is normal or not;

the process of the step 5 is as follows:

step 5.1: the state of each interface and the data receiving condition are reflected in real time in a list form;

step 5.2: issuing the steady-state continuous working time of each interface in a form of a histogram;

step 5.3: and numerically displaying the stability of the interface of the whole system, namely the fault time of the interface/the normal working time of the interface since the interface is on line.

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