CN116185381B - Cloud native low-code construction method, system and application based on micro-service architecture - Google Patents

Abstract

The application belongs to the technical field of data processing, and discloses a cloud native low-code construction method, a system and application based on a micro-service architecture. The system comprises: the low-code foreground is used for receiving user demand information input by a user client at a use interface, flexibly creating service applications by using the provided application design capability of the application center, and issuing the applications for online management and use of the users; the low-code back end organizes and constructs micro-service supporting low-code business logic and data flow by using a micro-service architecture; the cloud primary foundation component is used for providing cloud primary low codes based on a micro-service architecture, so that the built software system executes deployment and cloud loading functions, and meanwhile, application software for development executes release and management functions. The application automatically researches a plurality of design components in combination with business requirements of the general industry. In particular, a front-end flow rule design component is added in the flow designer, so that the application of the designed flow is more flexible.

Description

Cloud native low-code construction method, system and application based on micro-service architecture

Technical Field

The application belongs to the technical field of data processing, and particularly relates to a cloud native low-code construction method, a cloud native low-code construction system and application based on a micro-service architecture.

Background

Digitization is taken as a new kinetic energy for the economic development of the current society, and the innovation of various industries is promoted while the work and the life of people are changed, so that digitization transformation is undoubtedly a consensus of most enterprises. Along with the advancement of industrial digital transformation, the current information system of enterprises cannot meet the increasing digital transformation demand, and for large enterprises, a large number of innovative scene application development demands are urgently met, but IT productivity is insufficient, and quick response is difficult; for small and medium enterprises, professional developers are lacked, the custom development process is complex, the cost is high, and the time and the effort are consumed. Therefore, enterprises need to reduce the development threshold by means of the digitizing tool, so that business personnel can directly build the application.

Today, the internet industry is developing at a high rate. The operating cost, the development cost and the maintenance cost of the application are increased, the industry is seriously coiled and the competition is increased, the production profit of the enterprise has no rising space, and the production cost of the enterprise is reduced by technical means. Meanwhile, digitization is used as new kinetic energy for the economic development of the current society, the innovation of each industry is promoted, and along with the promotion of the digitization transformation of the industry, the current information system of enterprises can not meet the increasing digitization transformation requirement, and a large number of innovative scene application development requirements are urgently needed to be met. Gartner (Gao Dena, yet another translation and consultation company) made predictions that by 2021, the market size of the application development needs increased at least 5 times beyond the IT delivery capacity of the enterprise, facing such huge IT gaps, and IT was difficult to imagine that the problem could be completely solved by the continued development of the existing traditional technology system alone without a revolutionary "newborns" system. The low code technology is a powerful weapon for the industry to drive reform, and some applications and demands can be delivered in a short term with high efficiency, high quality and high speed through a low code platform, which can save a great amount of time cost of manpower cost. Therefore, enterprises need to reduce the development threshold by means of low codes, so that business personnel can directly build applications.

In the prior art, most of application development is a traditional waterfall flow customized development mode, a plurality of personnel with highly specialized roles are needed to participate, functional design and coding realization are completed by specialized developers after demand investigation, analysis and confirmation, and then the online application can be realized after test is carried out by testers. The online applications are mostly run on deployment servers in the form of separate program processes or system services.

Through the above analysis, the problems and defects existing in the prior art are as follows: the application development needs to go through the development process of a complete waterfall model, the development period is long, and the realization degree of the requirements is completely dependent on the professional degree of service personnel and developers; most of developed applications are that pages and services are combined together, so that the coupling degree is too high, the flexibility is not enough, and the later expansion is inconvenient; although micro-service architecture is gradually adopted for development, each micro-service is deployed by a separate process, which is inconvenient for operation and maintenance.

Therefore, in the prior art, the development cost is high, the requirement on the specialization degree is high, the labor cost investment is large, and the popularization of the digitization degree is limited for the enterprise digitization program data processing. Moreover, the existing enterprise data processing precision is not high, and accurate theoretical support cannot be provided for the development of enterprises.

Disclosure of Invention

In order to overcome the problems in the related art, the disclosed embodiments of the application provide a cloud native low-code construction method, a system and an application based on a micro-service architecture, in particular to a cloud native low-code development method based on the micro-service architecture.

The technical scheme is as follows: the cloud native low-code construction system based on the micro-service architecture comprises:

the user client provides an operation interface for a user, inputs the requirement information of the user at the use interface, and extracts the prefabricated application micro-service in the application library;

the low-code foreground is used for receiving user demand information input by a user client at a use interface, creating service application through the application design capability provided by the application center, and issuing the application for online management and use of a user;

the low-code back end constructs a micro-service supporting low-code business logic and data flow through a micro-service architecture organization;

the cloud native foundation component provides cloud native low codes based on a micro-service architecture, so that the built software system executes a deployment function and a cloud loading function, and meanwhile, application software for development executes release and management.

In one embodiment, the low code foreground comprises: form designer, flow authority component, application authority component and application publishing component;

the form designer is used for displaying the corresponding form name and the related field name of the service form in real time and recording multi-form data through form association and data linkage;

the flow designer is used for constructing a service flow chart in the actual service;

the flow authority component is used for binding with the designed flow form after the flow chart is constructed, and setting configuration information of each node in the flow;

the application authority component is used for providing form operation authorities, data authorities and default authorities for different service forms or creating custom authority groups according to service requirements to meet different authority service requirements;

the application release component is used for releasing the set forms, the processes and the authorities respectively according to the service requirements, classifying and aggregating different application scenes, and displaying by configuring rendering pages.

In one embodiment, the default permissions include: initiating a new flow, checking all flows and managing all flows;

and the new process is initiated to view the personal data of the user, the whole process is viewed to view the form and the whole data, and the whole process is managed to manage the whole operation process and the whole data.

In one embodiment, the low code backend includes a micro-service one-key deployment installation package; the micro-service one-key deployment and installation package adopts a micro-service architecture, and the application optimization package is packaged into a mirror image through a virtualized container technology, and the container arrangement is carried out;

the cloud native foundation assembly includes a cloud native foundation; the cloud native base is used for carrying out cross-cloud and cross-environment application delivery through a public abstraction layer, and carrying out self-service development and delivery of cloud native applications through an out-of-box extension component.

Another object of the present application is to provide a method for constructing a cloud native low code based on a micro service architecture, which is applied to a user client, and the method for constructing a cloud native low code based on a micro service architecture includes the following steps:

s1, collecting data through a form, wherein the form is divided into a common form and a flow form;

s2, designing a flow chart according to an actual business approval flow through a user node, and setting user information of each node;

s3, setting application permission according to the acquired form and the flow chart;

s4, after the application is released, the application enters an application set to carry out application of corresponding permission;

s5, packaging the required application into a plurality of micro services;

s6, packaging the plurality of micro-services into mirror images through a container technology, and deploying the micro-service-based cloud native low-code platform in a cloud environment through resource allocation.

After step S4, the rendered page is visualized by configuration.

It is another object of the present application to provide a storage medium for receiving a user input program, the stored computer program causing an electronic device to execute the cloud native low code construction method based on the micro-service architecture.

It is a further object of the present application to provide a computer device comprising a memory and a processor, the memory storing a computer program which, when executed by the processor, causes the processor to perform the method of cloud native low code construction based on micro-service architecture.

Another object of the present application is to provide an information data processing terminal that is installed on an electronic device to provide a user input interface to implement the micro-service architecture-based cloud native low-code construction method.

The application further aims to provide a multi-domain internet data information prediction terminal which implements the functions of the cloud native low-code construction system based on the micro-service architecture.

By combining all the technical schemes, the application has the advantages and positive effects that:

first, aiming at the technical problems existing in the prior art and the difficulty of solving the problems, the technical problems solved by the technical scheme of the application to be protected, results and data in the research and development process and the like are closely combined, the technical problems solved by the technical scheme of the application are analyzed in detail and deeply, and some technical effects with creativity brought after the problems are solved are specifically described as follows: the cloud primary low-code platform (intelligent cloud low-code development platform) based on the micro-service technology is designed and developed based on the micro-service technology architecture, a form engine, a flow engine, a report engine, a portal engine and a data engine are built in, the engines are combined in a diversified mode, rich open interfaces are provided, and good compatibility, usability and flexibility are achieved. The platform reduces the use threshold by modularly packaging codes, so that business personnel or implementation personnel can design and build business application on the basis of the platform by themselves, and industrial digital upgrading is enabled.

Along with the diversification of information demands of enterprises, the service demands are continuously changed, the traditional development mode has high time and capital cost, poor maintainability, complex deployment and more needed resources, and is not suitable for clouding. The low-code development method has the primary value of realizing the rapid development and deployment of software through the output reusable model for the enterprise application market, and shortening the project delivery cycle. The architecture based on the micro-service makes the development platform more convenient to expand, upgrade and maintain, and the low-code platform consumes fewer resources based on the design of cloud primordia, so that the development platform can be more easily clouded. Through the low-code development platform, the user greatly increases the self-implementation capability, does not depend on heavy outsourcing development work, does not need to establish an expensive software development team, and is not limited by fixed application software. The low-code development platform can connect data required by core business through a convenient data integration function and combining workflow capacity to open up data islands, so that data fusion is realized, further data application value is created, and enterprise digital intelligence business innovation is enabled. In addition, low code development has no inherent data architecture and no fixed business flow, so that the method has important value of flexibility and universality.

Secondly, the technical proposal is regarded as a whole or from the perspective of products, and the technical proposal to be protected has the technical effects and advantages as follows: the application provides a cloud native low code platform for micro services. Therefore, the cloud native low-code development method based on the micro-service architecture is better used for digitally transforming a power-assisted enterprise, realizing cost reduction and synergy, reducing development thresholds and expanding application development labor.

The cloud native low-code platform based on the micro-service comprises a form designer, a flow authority component, an application authority component and a one-key deployment installation package, and the adopted technical scheme is a cloud native low-code development method based on a micro-service architecture. The components adopt more reasonable logic granularity division and richer functions to realize encapsulation, so that the threshold of application development expertise of users is reduced, and business personnel can directly develop and construct the application on a platform. The daily 80% application can be quickly constructed through the existing functions of the platform, so that the development difficulty of the application is greatly reduced, and the application development period is shortened by more than 5 times.

Compared with the traditional low-code development method, the application has the advantages that: the deployment is convenient, and the cloud is easy to get up. Traditional application deployment often has severe requirements on the running environment, and needs to adapt to server hardware and an operating system, which increases the difficulty and time of deployment intangibly. According to the application, the technology base service is packaged into one container by one by using the cloud native container technology, so that the technology base service is more convenient to deploy on the cloud under the condition of saving resources compared with the traditional mode, and the technology base service can be rapidly and flexibly deployed on a container pass platform without considering the limitation of a basic environment. The method comprises the steps of carrying out a first treatment on the surface of the

And the maintenance and the upgrading are easy. Traditional applications, even when developed in a micro-service manner, perform better decoupling on application logic, but are more complex to maintain. The starting, stopping, upgrading of each service is time consuming and mishandling can cause problems for the whole application system. The application packages the technical base service into independent modules based on the micro-service architecture, and can flexibly start and stop the required service according to the actual service scene. And the mode is convenient for maintenance of the module, when a certain module service is maintained and upgraded, a flexible gray level release strategy can be formulated according to an affected interface, and the upgrade module can be started, stopped and rolled back quickly without affecting the normal operation of the whole application service so as to ensure continuous online of the application.

A more flexible front end frame. Although the traditional low-code development method also has to provide the capability of on-line rapid design application, the design capability provided by the application has finer granularity, and is mainly characterized in that a form designer and a flow designer self-researches a plurality of design components on the premise of conforming to the general standard and combining with the business requirements of the general industry, and the functions of the components are enriched to a more reasonable degree based on the development experience accumulated by companies. In particular, a front-end flow rule design component is added in the flow designer, so that the application of the designed flow is more flexible.

Thirdly, as inventive supplementary evidence of the claims of the present application, it is also reflected in the following important aspects:

(1) Expected benefits: the capability of coping with complex application scenes is increased by agilely responding to user demands. Traditional steady-state business processes are relatively mature, and the focus of enterprises on steady-state IT systems is on stability, reliability and safety. The low-code product has high stability, reduces high operation and maintenance cost generated by code quality in the later period by packaging high-quality codes, and is suitable for building steady-state business processes of enterprises. The enterprise digital transformation and adaptation to changeable market demands can generate a large amount of sensitive services, the service change speed is high, an open architecture and an open source technology are needed to ensure the elastic expansion capability of the service, and a low-code platform is suitable for the development requirements of enterprises on the sensitive services. The low-code product reduces the use threshold of users, has no inherent data architecture and no fixed business flow, realizes the rapid development and deployment of software through a reusable model, shortens the project delivery period, does not need to respectively establish expensive software development teams for the adjustment of each system, and has strong flexibility and universality. In addition, the low-code platform can communicate the data required by each system for acquiring the core service, open up the data island and improve the working efficiency of the service department. In conclusion, the low-code product can quickly respond to the user demands through high stability, universality and flexibility and integration of data, and can adapt to various complex application scenes in enterprises.

Commercial value: the cost of developing enterprise application software is reduced, because software development is a talent-intensive industry, labor cost is a main component of total cost, salary of software operators is in a significant leading position in a plurality of posts, and reducing labor use has great value in optimizing cost structures.

In addition, the agility of the enterprise is enhanced, the agility is related to the survival problem of the enterprise in an environment filled with uncertainty, and the low-code platform can help the enterprise to construct new products more quickly by improving the efficiency, so that the enterprise is convenient to follow the market rhythm.

(2) The novel technology remodels the industrial pattern, and low-code power-assisted IT service manufacturers reduce the cost, improve the efficiency and improve the quality. The IT service industry has a wider range, including early IT consultation and training, middle-stage custom development, system integration, deployment and implementation, later IT maintenance support, IT operation management, IT security assurance throughout the whole process and the like. For IT service enterprises, the system often has concentrated pain points of high labor cost, difficulty in improving human efficiency, many projects, high impurity, tight customer demand and difficult speed and quality. Driven by technical factors, the industry is in a stage of model innovation and pattern remodeling. The low-code platform can help developers to achieve the aim through modularization and visualization, helps power-assisted IT service enterprises to achieve cost reduction and efficiency improvement, service innovation and customer satisfaction, so that market opportunities are captured at industrial development turning points, and the leap of enterprise brands is achieved.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments consistent with the disclosure and together with the description, serve to explain the principles of the disclosure;

FIG. 1 is a flow chart of a cloud native low-code construction method based on a micro-service architecture provided by an embodiment of the application;

FIG. 2 is a schematic diagram of a cloud native low-code construction method based on a micro-service architecture according to an embodiment of the present application;

FIG. 3 is a flowchart of a low code foreground application method provided by an embodiment of the present application;

FIG. 4 is a schematic diagram of a cloud native low-code building system based on a micro-service architecture according to an embodiment of the present application;

in the figure: 1. a user client; 2. a low code foreground; 2-1, form designer; 2-2, a flow designer; 2-3, a flow authority component; 2-4, an application permission component; 2-5, an application publishing component; 3. a low code backend; 3-1, deploying an installation package by a micro-service one-key; 4. a cloud native foundation component; 4-1, a cloud native base.

Detailed Description

In order that the above objects, features and advantages of the application will be readily understood, a more particular description of the application will be rendered by reference to the appended drawings. In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present application. The application may be embodied in many other forms than described herein and similarly modified by those skilled in the art without departing from the spirit or scope of the application, which is therefore not limited to the specific embodiments disclosed below.

1. Explanation of the examples:

example 1

As shown in fig. 1, the cloud native low-code construction method based on the micro-service architecture provided by the embodiment of the application includes:

s1: collecting data through the form, and providing a form designer 2-1 by the low-code foreground 2, wherein a user designs the form by dragging required fields; the forms are divided into a common form and a flow form;

s2: when the flow form is involved, a flow approval process is required to be designed, the low-code foreground 2 also provides a flow designer 2-2, a user designs a flow chart and sets the processing personnel of each node according to the actual business approval process by dragging user nodes, and a plurality of conditions such as an organization architecture, roles, user groups, form fields and the like are supported to combine and determine personnel information;

s3: when the form and the flow are completed, setting the authority for the application, wherein the authority comprises the release authority and the form control authority;

s4: after the application is released, the application enters an application set, and a person with corresponding authority can use the application;

s5: micro-services: the low-code front-end 2 packages the bottom technical support needed by the low-code rear-end 3 into a plurality of micro services, and enables the corresponding micro services according to the needs during actual deployment, so that the flexibility of deployment is ensured, the later maintenance and upgrading are facilitated, services are provided among the micro services through interfaces, and the services and management service authorization are exposed through a gateway;

s6: cloud primordial: and calling container runtime technologies such as container and the like through a kubsphere graphical container scheduling platform to package micro-service application optimization packages into mirror images, and rapidly deploying a cloud primary low-code platform based on micro-services in a cloud environment through kubsphere allocation of proper resources.

Fig. 2 is a schematic diagram of a cloud native low-code construction method based on a micro-service architecture according to an embodiment of the present application.

Example 2

In the cloud native low-code platform based on the micro-service architecture provided by the embodiment of the application, the low-code foreground 2 comprises: the end user's use interface provides the end user with the ability to quickly create web online applications in an application-centric manner. The user can select and use the prefabricated application in the application library, and can also use form design and flow design in the application center to create flexible, complex and changeable personalized application.

As shown in fig. 3, the application method of the low-code foreground 2 specifically performs the following steps:

s301, form design: the data is collected through the form, the front desk provides a form designer 2-1, and a user designs the form by dragging required fields; the forms are divided into a common form and a flow form;

s302, flow design: when the flow forms are involved, a flow designer 2-2 is also provided by a foreground, a user designs the flow diagrams and sets the processing personnel of each node according to the actual business approval flow by dragging user nodes, and a plurality of conditions such as an organization architecture, roles, user groups, form fields and the like are supported to combine and determine personnel information;

s303, application permission: when the form and the flow are completed, setting the authority for the application, wherein the authority comprises the release authority and the form control authority;

s304, application release: after the application is released, the application enters an application set, and a person with corresponding authority can use the application;

s305, rendering the page for the user through configuration.

Example 3

In the cloud native low-code platform based on the micro-service architecture provided by the embodiment of the application, on the technical architecture, the service units under the micro-service framework are characterized in that each service module (the form designer 2-1, the flow designer 2-2, the flow authority component 2-3 and the application authority component 2-4) of the low-code foreground 2 is packaged into one micro-service, so that the technical difficulty is reduced, the reliability is improved, the agile development is easier to realize, the limitation that the single application is difficult to expand is broken, and the performance is greatly improved.

Example 4

In the cloud primary low-code platform based on the micro-service architecture, the cloud primary basic component 4 is adopted, application optimization packaging is packaged into mirror images through a Docker virtualization container technology, and the deployment, the scheduling and the dynamic expansion of containers are realized by the Kubernetes, so that the low-code development platform can be rapidly deployed in a cloud environment by distributing proper resources.

Example 5

As shown in fig. 4, a cloud native low-code platform based on micro services provided by an embodiment of the present application includes:

the user client 1 inputs the requirement information of a user in a use interface and extracts the application micro-service prefabricated in the application library;

the low-code foreground 2 is used for receiving user demand information input by the user client 1 at the use interface, flexibly creating service applications by using the provided application design capability of the application center, and issuing applications for online management and use of users;

the low-code back end 3 constructs micro-service supporting low-code business logic and data flow by using a micro-service architecture;

the cloud native base component 4 is used for providing cloud native low-code based on a micro-service architecture, so that the built software system executes deployment and cloud loading functions, and meanwhile, application software for development executes release and management functions.

Wherein the low code foreground 2, the end user's use interface, provides the end user with the ability to quickly create web online applications in an application centric manner. The user can select and use the prefabricated application in the application library, and can also use form design and flow design in the application center to create flexible, complex and changeable personalized application.

Example 6

The low-code foreground 2, the form designer 2-1, the flow designer 2-2, the flow authority component 2-3, the application authority component 2-4 and the application publishing component 2-5;

in the embodiment of the application, the form designer 2-1 is divided into a left part, a middle part and a right part, wherein the left element comprises a basic control, a custom control and a layout control; the basic control comprises the following components: single line input boxes, multi-line text boxes, number input boxes, drop-down selectors, multi-choice boxes, single choice boxes, date selection boxes, time selection boxes, scoring, sliding input bars, uploading files, uploading pictures, cascading selectors, dynamic forms, selecting input columns, rich text, switches, buttons, warning cues, text, HTML, etc.; custom controls: the secondary development self-defining component is supported, and a department single selection, a department multiple selection, a personnel single selection, a personnel multiple selection and a user group are built in the secondary development self-defining component; layout control: including split lines, card layout, tab page layout, grid layout, and form layout. The right side area is a configuration interface of the form style and each component, wherein the configuration interface comprises form attribute setting and control attribute setting, and the form attribute setting comprises the following steps: relates to field layout, label width, form css style; setting control attributes: to field tag name, data field name, field type, occupancy hint information, width, default value, data verification, and operational attributes.

The form designer 2-1 reduces the dependence on professional software development engineers, and can display the form style in real time as long as the components related to the service form are dragged to the middle area from the left side, and the corresponding form names and the related field names are set, so that the user experience is better improved, the designed form is prevented from being inconsistent with the user expectation, the preview function is provided, the form design condition is checked in real time, and the convenience is brought to correction in time; when the form is issued, a JSON Schema can be generated to generate a database table structure; the functions of adding, editing, modifying, viewing and the like of the table can be met by the complete API service in the background; for further refinement, the platform also provides form view design, the ordering of the list is configurable for the screening conditions of the form.

In order to meet the requirement of multi-form combination and form data linkage, the platform adds form association and data linkage in the base assembly, and the input of multi-form dependent data can be realized through the simple configuration of the base assembly, so that development work is not needed at all, only business personnel are required to configure in a dragging mode, development cost is greatly reduced, time for constructing a business system is reduced, and cost reduction and synergy are really and positively realized for enterprises.

In the embodiment of the application, the flow designer 2-2 is not only limited to the application of a common form, but also is constructed by a business personnel in a dragging mode aiming at the business requirement of complex cross-department coordination approval flow related to simple flow approval in actual business; compared with the common form service requirement, the flow application has more flow design functions, and is mainly embodied in the drawing of a flow chart and the configuration of flow node authority;

the flow chart drawing interface is also divided into three parts of a left side, a middle side and a right side, wherein the left side provides basic components required by the approval flow, including a start event, an end event, a gateway, a user task, a boundary event, a sequence flow, a sub-flow and the like, and a user drags the required basic components to a middle area according to service requirements to construct a flow chart; after the flow chart is completed, the flow authority component 2-3 binds the flow chart with the designed flow chart, and sets the configuration information of each node in the flow chart, such as the form authority, the approval person setting, the operation authority, the approval opinion and other relevant settings, so that the business flow circulation can be completed, and the whole process can be completed and the dragging configuration can be carried out by relevant business personnel.

In the embodiment of the application, the application authority component 2-4 is an application set, each application contains different service forms, different application authorities are set for people with different authorities, and the authority dimension is mainly embodied in the form operation authorities and the data authorities; the default authority is used for initiating a new flow, checking all flows and managing all flows;

initiating a new flow: the method comprises the steps of having an operation authority of adding a form button and checking the data authority of the user; checking the whole flow: has the right of checking the form button and the right of all data; and (3) managing the whole flow: all button operation authorities and all data authorities are provided; the user can also create custom authority groups according to the service requirements to meet different authority service requirements.

In the embodiment of the application, the application publishing component 2-5 can publish the application after the business personnel respectively set the forms, the processes and the authorities according to the business requirements, the application enters the application set after the application is published, the personnel with the corresponding authorities can use the application, the platform uniformly manages the application set, opens the application market, classifies and aggregates different application scenes, and meets the requirements under different business scenes.

Example 7

The low-code back end 3 comprises a micro-service one-key deployment installation package 3-1;

the micro-service one-key deployment installation package 3-1 adopts a micro-service architecture, packages application optimization packages into mirror images through a virtualized container technology, and performs container arrangement;

the cloud primary base component 4 includes: yun Yuansheng base 4-1;

the Yun Yuansheng base 4-1 is used for carrying out cross-cloud and cross-environment application delivery through a public abstraction layer, and carrying out self-service development and delivery of cloud native applications through an out-of-box extension component.

The micro-service one-key deployment installation package 3-1 adopts a micro-service architecture, an application system is formed by the common combination of a plurality of independent services, each service is independently deployed and runs in the own process, and is in distributed management, each service is an independent service development module, so that isolation is emphasized greatly, the cohesiveness of the service module is enhanced, but the difficulty of deployment implementation is increased at the same time, in order to solve the problem, application optimization packaging is packaged into mirror images through a Docker virtualization container technology, kubernetes realizes container arrangement, a one-key deployment installation package is constructed, and deployment implementation personnel can realize quick deployment of the application only by filling necessary parameters;

yun Yuansheng base 4-1 the trend in cloud native technology is continually advancing towards the use of Kubernetes as a common abstraction layer to achieve highly consistent, cross-cloud, cross-environment application delivery. The application delivery engine which is oriented to the mixed delivery environment and is high in expansibility simultaneously meets the expansion and self-building requirements of platform constructors; meanwhile, a series of expansion components which are used after being unpacked are added, so that a developer can develop and deliver cloud native applications in a self-service mode.

In the foregoing embodiments, the descriptions of the embodiments are emphasized, and in part, not described or illustrated in any particular embodiment, reference is made to the related descriptions of other embodiments.

The content of the information interaction and the execution process between the devices/units and the like is based on the same conception as the method embodiment of the present application, and specific functions and technical effects brought by the content can be referred to in the method embodiment section, and will not be described herein.

It will be apparent to those skilled in the art that, for convenience and brevity of description, only the above-described division of the functional units and modules is illustrated, and in practical application, the above-described functional distribution may be performed by different functional units and modules according to needs, i.e. the internal structure of the apparatus is divided into different functional units or modules to perform all or part of the above-described functions. The functional units and modules in the embodiment may be integrated in one processing unit, or each unit may exist alone physically, or two or more units may be integrated in one unit, where the integrated units may be implemented in a form of hardware or a form of a software functional unit. In addition, the specific names of the functional units and modules are only for distinguishing from each other, and are not used for limiting the protection scope of the present application. For specific working processes of the units and modules in the system, reference may be made to corresponding processes in the foregoing method embodiments.

2. Application examples:

application example

The embodiment of the application provides computer equipment, which comprises: at least one processor, a memory, and a computer program stored in the memory and executable on the at least one processor, which when executed by the processor performs the steps of any of the various method embodiments described above.

Embodiments of the present application also provide a computer readable storage medium storing a computer program which, when executed by a processor, performs the steps of the respective method embodiments described above.

The embodiment of the application also provides an information data processing terminal, which is used for providing a user input interface to implement the steps in the method embodiments when being implemented on an electronic device, and the information data processing terminal is not limited to a mobile phone, a computer and a switch.

The embodiment of the application also provides a server, which is used for realizing the steps in the method embodiments when being executed on the electronic device and providing a user input interface.

Embodiments of the present application provide a computer program product which, when run on an electronic device, causes the electronic device to perform the steps of the method embodiments described above.

The integrated units, if implemented in the form of software functional units and sold or used as stand-alone products, may be stored in a computer readable storage medium. Based on such understanding, the present application may implement all or part of the flow of the method of the above embodiments, and may be implemented by a computer program to instruct related hardware, where the computer program may be stored in a computer readable storage medium, and when the computer program is executed by a processor, the computer program may implement the steps of each of the method embodiments described above. Wherein the computer program comprises computer program code which may be in source code form, object code form, executable file or some intermediate form etc. The computer readable medium may include at least: any entity or device capable of carrying computer program code to a photographing device/terminal apparatus, recording medium, computer Memory, read-Only Memory (ROM), random access Memory (Random Access Memory, RAM), electrical carrier signals, telecommunications signals, and software distribution media. Such as a U-disk, removable hard disk, magnetic or optical disk, etc.

In the foregoing embodiments, the descriptions of the embodiments are emphasized, and in part, not described or illustrated in any particular embodiment, reference is made to the related descriptions of other embodiments.

3. Evidence of example related effects:

development efficiency is improved: the mode of graphical dragging is used for replacing the original mode of writing codes, so that the workload can be greatly reduced. Meanwhile, in the way of coding and writing codes, developers often take much time to find and solve code bug.

Cost reduction and synergy: the cost of application development is mainly labor cost, and is usually measured according to the human day or the human month, and can be calculated according to the formula: development cost = personnel daily wages x number of people x number of development days. The improvement of efficiency can proportionally reduce the number of people and development days, simultaneously, reduce the requirement on the development level of developers, and many development works do not need to be completed by high-salary talents for specialized development, so that the development difficulty is reduced, and the daily average wages of personnel are also reduced, thereby reducing the overall cost.

Breaking the data island of the information system: through simple system association, data dependence and intercommunication among applications can be realized, data circulation does not need to be repeatedly led out and led in each system, the data barrier is broken, the working efficiency is greatly improved, and quick iteration is realized, so that the quick-change market environment is responded.

Better flexibility expansion: has more excellent expansion performance. Unlike conventional management systems, there is no need to enter a large-volume code plane to modify from the design of the data table to the creation of the flow. Can realize rapid iteration and help enterprises adapt to market environment of instant change

In terms of deployment implementation operation and maintenance, applications running in a containerized manner, which start and stop very fast, typically on the order of seconds or milliseconds, are extremely flexible. The self-healing of the fault and the autonomous capability of the service can manage thousands of application containers by adopting a container arrangement framework, when a certain application fails, the arrangement system can discover and automatically remove the problem application in time, and meanwhile, the problem application is intelligently scheduled to the effective resource, so that the stable operation of the application system is ensured. The large-scale cross-environment expansion capability can build a PaaS platform based on a container arrangement system, can span and be deployed in different environments, including different network environments, different machine rooms, different data centers or different public clouds, can enable the application to circulate in the cross-cloud environment by utilizing the mode of the federal cluster, can enable the different cloud environments to be used as resource supplement, or can create the same application to the different data centers to be used as disaster recovery backup.

While the application has been described with respect to what is presently considered to be the most practical and preferred embodiments, it is to be understood that the application is not limited to the disclosed embodiments, but on the contrary, is intended to cover various modifications, equivalents, and alternatives falling within the spirit and scope of the application.

Claims (8)

1. The cloud native low-code construction method based on the micro-service architecture is characterized in that the cloud native low-code construction method based on the micro-service architecture is realized based on a cloud native low-code construction system of the micro-service architecture;

the cloud native low-code construction system based on the micro-service architecture comprises:

the user client (1) provides an operation interface for a user, inputs the requirement information of the user at the use interface, and extracts the prefabricated application micro-service in the application library;

the low-code foreground (2) is used for receiving user demand information input by the user client (1) at the use interface, creating service application through the provided application design capability of the application center, and issuing application for online management and use of the user;

the low-code back end (3) constructs a micro-service supporting low-code business logic and data flow through a micro-service architecture organization; the low-code back end (3) comprises a micro-service one-key deployment installation package (3-1); the micro-service one-key deployment installation package (3-1) adopts a micro-service architecture, packages application optimization packages into mirror images through a virtualized container technology, and performs container arrangement;

the cloud primary basic component (4) provides cloud primary low codes based on a micro-service architecture, so that the built software system executes a deployment function and a cloud loading function, and meanwhile, application software for development executes release and management; the cloud native base component (4) comprises a cloud native base (4-1); the Yun Yuansheng base (4-1) is used for carrying out cross-cloud and cross-environment application delivery through a public abstraction layer, and carrying out self-service development and delivery of cloud native applications through an out-of-box extension component;

the cloud native low-code construction method based on the micro-service architecture is applied to a user client (1), and comprises the following steps:

s1, collecting data through a form, wherein the form is divided into a common form and a flow form;

s2, designing a flow chart according to an actual business approval flow through a user node, and setting user information of each node;

s3, setting application permission according to the acquired form and the flow chart;

s4, after the application is released, the application enters an application set to carry out application of corresponding permission;

s5, packaging the required application into a plurality of micro services;

s6, packaging the plurality of micro-services into mirror images through a container technology, and deploying the micro-service-based cloud native low-code platform in a cloud environment through resource allocation.

2. The cloud native low-code construction method based on the micro-service architecture according to claim 1, wherein the low-code foreground (2) comprises: a form designer (2-1), a flow designer (2-2), a flow authority component (2-3), an application authority component (2-4) and an application publishing component (2-5);

the form designer (2-1) is used for displaying corresponding form names and related field names of the service forms in real time and recording multi-form data through form association and data linkage;

a flow designer (2-2) for constructing a service flow diagram in the actual service;

the flow authority component (2-3) is used for binding a designed flow form after the flow chart is constructed, and setting configuration information of each node in the flow;

the application authority component (2-4) is used for providing form operation authority, data authority and default authority for different service forms or creating a custom authority group according to service requirements to meet different authority service requirements;

and the application release component (2-5) is used for releasing the set forms, the processes and the authorities according to the service requirements, classifying and aggregating different application scenes, and displaying by configuring the rendering pages.

3. The method for constructing cloud native low-code based on micro-service architecture according to claim 2, wherein the default authority comprises: initiating a new flow, checking all flows and managing all flows;

and the new process is initiated to view the personal data of the user, the whole process is viewed to view the form and the whole data, and the whole process is managed to manage the whole operation process and the whole data.

4. The method for constructing cloud native low-code based on micro-service architecture according to claim 1, wherein after step S4, the rendering page is configured for visual display.

5. A storage medium receiving user input, the stored computer program causing an electronic device to perform the micro-service architecture-based cloud native low-code build method of claim 1.

6. A computer device comprising a memory and a processor, the memory storing a computer program that, when executed by the processor, causes the processor to perform the micro-service architecture-based cloud native low-code building method of claim 1.

7. An information data processing terminal, characterized in that the information data processing terminal is installed on an electronic device to provide a user input interface to implement the cloud native low code construction method based on the micro-service architecture according to any one of claims 1 to 4.

8. The multi-domain internet data information prediction terminal is characterized in that the multi-domain internet data information prediction terminal implements the cloud native low code construction method based on the micro-service architecture according to any one of claims 1 to 4.