CN108614688B - Visual application arrangement system and method applied to hybrid cloud environment - Google Patents

Abstract

The invention discloses a visual application arrangement and a method applied to a mixed cloud environment, wherein the system comprises a software deployment subsystem, a software visual arrangement framework module, a script compiler, a software deployment script executor and a software directory service module, wherein: the software visualization arrangement framework module is used for generating a complete software deployment script as output and providing the output for the background to execute actual deployment; and the script compiler is used for converting the visualization process into a background specific executable script and generating configuration parameters as output and the like. The invention supports self-defined software arrangement logic, self-defined load scheduling strategy, self-defined visual monitoring alarm and real-time display of application deployment and resource occupation on the hybrid cloud platform; the application is simplified, fast and automatically provided with the capability of providing service to the outside; and displaying the resource scheduling condition in a multi-dimensional way in a visual way.

Description

Visual application arrangement system and method applied to hybrid cloud environment

Technical Field

The invention relates to a visual application arrangement and a method, in particular to a visual application arrangement and a method applied to a hybrid cloud environment.

Background

Currently, cloud computing technology is widely deployed in various industries, and a user installs a software application program required by the user to run by using a virtual computer generated by the cloud computing technology, so as to provide the software application program for the user or provide a service for an end user.

With the improvement of software performance requirements of users, under the condition that a single software application for deploying a single computing node cannot meet the use scene of the users, at present, more software architectures are designed into a distributed deployment system, the whole software system is divided into a plurality of sub-modules by the design architecture, and the sub-modules are installed on a plurality of computer nodes in a distributed manner according to a set arrangement and combination mode.

On the other hand, with the deep application of cloud computing platforms in different industries, in the current scenario of using distributed software by a specific user, a private cloud platform built in a user organization structure is included, and meanwhile, considering factors such as external service provision, a great amount of software needs to be correspondingly deployed on a public cloud platform rented by the user. On the other hand, a great number of enterprises use public clouds as a disaster recovery platform of the enterprise cloud, and the main consideration is that for an enterprise cloud environment, the disaster recovery environment is much more expensive, and is not as good as a public cloud, so that the public cloud and the private cloud are well connected.

Therefore, the most common landing scenario of cloud computing we see at present is the application of hybrid cloud, and the technical challenge of hybrid cloud management brought by the same is the problem that we need to solve in an effort.

1) There is a need for flexibility in defining resources in a hybrid cloud environment that should encompass a variety of computing resources.

2) When the software is applied to deployment in a hybrid cloud environment, cross-public network data transmission and corresponding complex network configuration management under the condition of meeting user privacy safety are met.

3) Hybrid cloud management needs dimensional analysis from computation, network, storage, safety and the like, and each application has different loads and needs reasonable scheduling and management control.

4) The method comprises the steps of overall application arrangement and migration of a mixed cloud environment, wherein the arrangement and migration are unified and rapid deployment in private clouds and public clouds, and are not to deploy one set of cloud in advance and then deploy the other set of cloud in a traditional mode.

In summary, the deployment service process of the traditional application software, or what is called as the traditional "application orchestration" manner, cannot meet the management requirement in the hybrid cloud environment involving the simultaneous coexistence of the private cloud and the public cloud, and there are many disadvantages and improvements are necessary.

Disclosure of Invention

The invention aims to solve the technical problem of providing a visual application arrangement and a method applied to a hybrid cloud environment, which support a self-defined software arrangement logic, a self-defined load scheduling strategy and a self-defined visual monitoring alarm and can display the application deployment and resource occupation conditions on a hybrid cloud platform in real time; the application is simplified, fast and automatically provided with the capability of providing service to the outside; and displaying the resource scheduling condition in a multi-dimensional way in a visual way.

The invention solves the technical problems through the following technical scheme: a visual application orchestration system for a hybrid cloud environment, comprising:

the software deployment subsystem is used for predefining environment configuration, supporting a user visual operation configuration software deployment process, supporting a self-defined script configuration compiling and executing tool, and providing various parameter indexes of software service through a visual interface, and comprises a software visual arrangement framework module, a script compiler, a software deployment script executor and a software directory service module, wherein:

the software visualization arrangement framework module is used for generating a complete software deployment script as output and providing the output for the background to execute actual deployment;

the script compiler is used for converting the visualization process into a background specific executable script and generating configuration parameters as output;

the software deployment script executor is used for actually executing and deploying the whole set of software application and controlling various resource applications, deployment logic sequences and input parameters in the deployment process;

the software directory service module is used for recording, storing and updating and providing arrangement logic, initialization parameters and integrated scripts of background software application sets of various services;

the universal service subsystem is used for providing front-end user access of the whole system platform, storing log records generated by system use and providing an input interface for system monitoring, and comprises a visual interface module, a database service module and a system monitoring service module, wherein:

the visual interface module is used for providing an access and operation interface of the whole system;

the database service module is used for storing log records, system configuration and user accounts generated during the operation of the system;

the system monitoring service module is used for displaying resource occupation conditions, deployment hierarchy architectures, topological graphs and application running health states of software applications governed by the hybrid cloud environment in a multi-dimensional mode;

the resource scheduling subsystem is used for monitoring the calculation, network and storage resources managed by the system, providing resources to corresponding application operating environments according to a predefined scheduling algorithm, and comprises a resource monitoring module, a resource scheduling algorithm configuration module and a resource scheduling execution module, wherein:

the resource monitoring module is used for monitoring the bottom physical computing, the network, the storage resource and the security configuration strategy group managed by the hybrid cloud platform;

the resource scheduling algorithm configuration module is used for enabling a user to input, configure and store the resource scheduling algorithm through the configuration and setting the triggering condition of the resource scheduling algorithm;

the resource scheduling execution module is used for outputting a resource scheduling control task related to the pre-configured application according to the set triggering condition;

the application migration subsystem is used for configuring and executing a migration process of the software application between different deployment environments and monitoring the integrity and high availability of the software in the migration process in real time, and comprises an application migration configuration module and a migration process execution module, wherein:

the application migration configuration module is used for defining, configuring and debugging the migration logic process of the application and outputting a well-defined application migration configuration file to the database;

a migration process execution module for executing a software application already deployed on an existing hybrid cloud platform,

and executing the migration work of the application according to the parameters provided by the application migration configuration.

The invention also provides a visual application arrangement method applied to the mixed cloud environment, which is characterized by comprising the following steps:

firstly, a user directly knows the existing application deployment condition and the overall resource occupancy rate of a platform through a platform visual interface;

secondly, the system clicks, drags and releases the visual interface through a user, and directly carries out visual editing on the interface by the application needing deployment;

step three, arranging a flow by a service directory module in the system according to a pre-configured application, calling a resource monitoring module, and applying for computing, network and storage resources corresponding to the cloud platform;

step four, the system completes resource allocation required by the software application through the scheduling algorithm allocation module and informs the resource scheduling algorithm allocation module and the resource scheduling execution module to start a software installation process;

fifthly, the software deployment module completes the whole software installation under the cooperation of the resource scheduling module; after checking and confirming, updating corresponding information to the resource monitoring module, and synchronously outputting the corresponding information to the visual interface module in real time;

step six, when the application is migrated due to the intervention of external factors, the system uses a scheduling algorithm configuration module to apply for the required resources; the system calls an application migration configuration module and a migration process execution module to complete the migration of the application configuration across the cloud platform; in the whole process, the resource monitoring module monitors related resources and various information and provides log information.

The positive progress effects of the invention are as follows: the invention relates to a customized visualization method; displaying deployment state, resource occupation and security policy configuration information of the software application on a mixed cloud environment in a multi-dimensional mode; supporting self-defined software arrangement logic; according to the definition logic, allocating computing resources, network resources, storage resources and related security policy groups of the specified software application; supporting a self-defined load scheduling strategy; according to a defined strategy, software application occupies load indexes such as resources in real time, reasonably scheduling management and control platform level resources, and adjusting a plan of occupying related resources by the application; self-defined visual monitoring alarm is supported; monitoring various resource indexes and log alarms of management application services in the migration process among different cloud stacks in a multi-resource dimension visualization mode, and expressing the resource indexes and the log alarms on the whole hybrid cloud management topology layer in a proper form; displaying the application deployment and resource occupation conditions on the hybrid cloud platform in real time through a visual management system; a user can simply, quickly and automatically mix the deployment of software application on the cloud platform through visual operation, and the initialization configuration of the application is completed, so that the application has the capability of providing service to the outside; controlling the application to execute resource scheduling by monitoring the resource use condition of the hybrid cloud and settling a pre-configured application scheduling flow, wherein the resource scheduling condition is displayed in a visual mode in a multi-dimensional mode; in the process of carrying out migration operation between the hybrid cloud platforms by initiating the application, index parameters such as availability, migration progress and the overall health state of the platform are monitored in the whole process in a visual mode.

Drawings

FIG. 1 is a system framework diagram of a visualization application orchestration and method applied to a hybrid cloud environment in accordance with the present invention.

FIG. 2 is a flow chart of the present invention.

Detailed Description

The following provides a detailed description of the preferred embodiments of the present invention with reference to the accompanying drawings.

As shown in fig. 1, the visualization application orchestration system applied to the hybrid cloud environment of the present invention includes:

the software deployment subsystem is used for predefining environment configuration, supporting a user visual operation configuration software deployment process, supporting a self-defined script configuration compiling and executing tool, and providing various parameter indexes of the software service through a visual interface, and comprises a software visual arrangement framework module A1, a script compiler A2, a software deployment script executor A3 and a software directory service module A4, wherein:

the software visualization arrangement framework module A1 is used for determining related configurations such as specific calling mixed cloud platform resource types, quantity, initialization parameters, security policies and the like according to action gesture input of a visualization interface and input of the software service directory module A4 and according to the type and scale of specific applications, integrating the data into a script containing parameters required by application deployment, and outputting a script compiler A2 and an application migration configuration module C1 which are core modules of the whole system; the method supports action gestures (such as mouse operation, dragging, moving, clicking, connecting and the like) as input, the system analyzes the input, refers to an operated object (software, middleware, basic setting, resource configuration parameters and the like) and generates a complete software deployment script as output for the background to execute actual deployment. And the functions of generating custom action gestures and drawing and connecting lines are supported.

The script compiler A2 is used for converting the visualization process into a background specific executable script and generating configuration parameters as output;

the software deployment script executor A3 is used for executing deployment, configuration and initialization tasks of the software application on each node of the cloud platform in the process, and is responsible for verifying the completed result and verifying the normal starting and running of the application on the hybrid cloud platform; executing specific application arrangement operation by utilizing API interfaces of all stacks of the hybrid cloud; it should be noted that the functions implemented by the application migration configuration module C1 and the migration process execution module C2 depend on the operations supported by the stack APIs (application programming interfaces) of the hybrid cloud;

the software directory service module a4 is used for managing and configuring various service capabilities provided by the system externally, where "service" specifically refers to a client-oriented software application capability formed by the cooperative running of a set of related software applications. In the specific operation process, the operator control of a visual interface module D1 is used as input, a background service management configuration item is called, a series of software module configuration item confirmation is executed through a software visual arrangement framework A1, a script compiler A2 is output, and the script compiler A outputs a compiling script to a software deployment script executor A3 to execute the script;

and the general service subsystem is used for providing front-end user access of the whole system platform, saving log records generated by system use and providing an input interface for system monitoring. The system comprises a visual interface module D1, a database service module D2 and a system monitoring service module D3, wherein:

the visual interface module D1 is used for providing an access and operation interface of the whole system; different from a common access interface, an operator completes the operations of application configuration, deployment, arrangement, migration and the like of each level on the administered hybrid cloud platform through the interface, and the input mode is a method that a graphical interface is used as a main part in cooperation with mouse gesture actions, and the manual input of individual parameters is used as an auxiliary part; in the system operation process, the system continuously receives monitoring indexes and alarm logs about various resources governed by the hybrid cloud platform, which are output by the resource monitoring module B1, and the monitoring indexes and the alarm logs serve as input of visual display, and outputs integrated data to the software directory service module A4;

and the database service module D2 is used for storing platform-related data information such as log records, system configurations, user accounts and the like generated during the operation of the system.

The system monitoring service module D3 is used for displaying resource occupation conditions, deployment hierarchy architectures, topological graphs and application running health states of software applications governed by the hybrid cloud environment in a multi-dimensional manner; supporting a user-defined data display mode and an upper application interface API;

and the resource scheduling subsystem is used for monitoring the calculation, network and storage resources managed by the system and providing the resources to the corresponding application operating environment according to a predefined scheduling algorithm. The resource scheduling method comprises a resource monitoring module B1, a resource scheduling algorithm configuration module B2 and a resource scheduling execution module B3, wherein:

the resource monitoring module B1 is responsible for monitoring the running health status of the whole hybrid cloud platform resources and the deployed applications, and in the specific monitoring process, the system monitoring service module D3 provides the hybrid cloud information of the managed lower layer, receives and integrates data, and provides the data as the whole platform resource occupation information as output to the visual interface module D1 as input for the latter to display the health status of the deployed applications in multiple dimensions. On the other hand, the system executes the corresponding application migration according to the predefined configuration when the platform resource shortage condition occurs, so it will also trigger the defined condition of the application migration configuration module C1, and the migration of the application is operated through the migration process execution module C2.

A resource scheduling algorithm configuration module B2, which is used for the user to input, configure and store the resource scheduling algorithm through the configuration and set the triggering condition; resources include computing, network, storage, and security policies;

the resource scheduling execution module B3 is used for outputting a resource scheduling control task related to the pre-configured application according to the set triggering condition;

and the application migration subsystem is used for configuring and executing a migration process of the software application among different deployment environments, and monitoring the integrity and high availability of the software in the migration process in real time. The system comprises an application migration configuration module C1 and a migration process execution module C2, wherein:

the application migration configuration module C1 is used for defining, configuring and debugging the migration logic process of the application and outputting a defined application migration configuration file to the database;

the migration process execution module C2 is configured to execute migration work of the application according to the parameters provided by the application migration configuration C1 on the software application already deployed on the existing hybrid cloud platform, and the software application remains in a normal operation state and is not affected in the whole application migration process; in order to achieve the above effects, it is required to ensure that the hybrid cloud platform supports a distributed storage architecture, and the network throughput meets the bandwidth requirement required by the related software application program; it is the same as script compiler a2 and software deployment script executor A3 in that it also receives software visualization orchestration framework a1 data output as input for execution parameters; and after the user initiates an application migration application, executing the application migration across the cloud stack according to the defined service logic flow, the related parameter calling and the running script.

As shown in fig. 2, the visualized application orchestration method applied to the hybrid cloud environment of the present invention includes the following steps:

step P101, inputting an application or service set to be deployed by a user through a visual interface module D1 and an operating system, and inputting a related application to a background by the system;

step P102, after the software directory service module a4 responds to the application, the module executes the step to find whether the stored service list and the corresponding software deployment flow list contain the requested service or application deployment;

step P103, judging whether the system has a software editing process, if so, turning to step P105, otherwise, turning to step P104;

step P104, the system requires the user to add the application arrangement flow of the response or the application arrangement flow related to the service, and after the task is completed, the system continues to execute P102 to search the software directory service module A4;

step P105, a system calls a software visualization arrangement framework module A1 to complete collection and integration of information such as configuration parameters, deployment processes, initialization parameters and the like required by the application requested by the user, and the step is responsible for applying corresponding resources to the managed hybrid cloud platform;

step P106, after the hybrid cloud resources are ready, the system calls a script compiler A2 to determine the deployment process of the software application and outputs the deployment process to an API (application programming interface) of the hybrid cloud management platform;

step P107, compiling an installation script;

step P108, according to the applied platform resource and the determined software installation flow, completing software installation;

step P109, after the software installation process is completed, the initialization configuration work of the software is executed, wherein, because the configuration complexity of each software is different, the step P111 provides the relevant script to operate in part of the process;

step 110, in the process from step P106 to step P112, continuously monitoring the overall health status of the hybrid cloud platform, including not only the platform resource usage;

step P111, executing predefined script execution related operations required by the deployed software through the software deployment script executor A3, including not only software installation, but also configuration of software initialization parameters, and the like;

step P112, after the software deployment and initialization are finished, outputting the actual mixed cloud platform resources, the application parameters and the security policy group information occupied by the newly deployed software application to a feedback system;

step P113, changing the information involved in the above steps, and synchronously updating the information in a system visual interface module D1;

step P201, the system monitoring service D3 continuously monitors the service condition of the managed hybrid cloud platform resources;

step P202, the system judges whether the cloud platform resources meet the predefined index threshold limiting condition in real time, if so, the step P203 is carried out, otherwise, the step P201 is carried out, and if so, a corresponding application is submitted and output to an application migration configuration module C1;

step P203, the application migration configuration module C1 triggers the execution of the application migration process C2 to execute specific operations according to the input application migration request; after the application migration operation is completed, the result is output to the software directory service module a4, and the service directory P102 where the application is located is searched.

The above embodiments are described in further detail to solve the technical problems, technical solutions and advantages of the present invention, and it should be understood that the above embodiments are only examples of the present invention and are not intended to limit the present invention, and any modifications, equivalent substitutions, improvements and the like made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (2)

1. A visual application orchestration system for a hybrid cloud environment, comprising:

the software deployment subsystem is used for predefining environment configuration, supporting a user visual operation configuration software deployment process, supporting a self-defined script configuration compiling and executing tool, and providing various parameter indexes of software service through a visual interface, and comprises a software visual arrangement framework module, a script compiler, a software deployment script executor and a software directory service module, wherein:

the software visualization arrangement framework module is used for generating a complete software deployment script as output and providing the output for the background to execute actual deployment;

the script compiler is used for converting the visualization process into a background specific executable script and generating configuration parameters as output;

the software deployment script executor is used for actually executing and deploying the whole set of software application and controlling various resource applications, deployment logic sequences and input parameters in the deployment process;

the software directory service module is used for recording, storing and updating and providing arrangement logic, initialization parameters and integrated scripts of background software application sets of various services;

the universal service subsystem is used for providing front-end user access of the whole system platform, storing log records generated by system use and providing an input interface for system monitoring, and comprises a visual interface module, a database service module and a system monitoring service module, wherein:

the visual interface module is used for providing an access and operation interface of the whole system;

the database service module is used for storing log records, system configuration and user accounts generated during the operation of the system;

the system monitoring service module is used for displaying resource occupation conditions, deployment hierarchy architectures, topological graphs and application running health states of software applications governed by the hybrid cloud environment in a multi-dimensional mode;

the resource scheduling subsystem is used for monitoring the calculation, network and storage resources managed by the system, providing resources to corresponding application operating environments according to a predefined scheduling algorithm, and comprises a resource monitoring module, a resource scheduling algorithm configuration module and a resource scheduling execution module, wherein:

the resource monitoring module is used for monitoring the bottom physical computing, the network, the storage resource and the security configuration strategy group managed by the hybrid cloud platform;

the resource scheduling algorithm configuration module is used for enabling a user to input, configure and store the resource scheduling algorithm through the configuration and setting the triggering condition of the resource scheduling algorithm;

the resource scheduling execution module is used for outputting a resource scheduling control task related to the pre-configured application according to the set triggering condition;

the application migration subsystem is used for configuring and executing a migration process of the software application between different deployment environments and monitoring the integrity and high availability of the software in the migration process in real time, and comprises an application migration configuration module and a migration process execution module, wherein:

the application migration configuration module is used for defining, configuring and debugging the migration logic process of the application and outputting a well-defined application migration configuration file to the database;

a migration process execution module for executing a software application already deployed on an existing hybrid cloud platform,

and executing the migration work of the application according to the parameters provided by the application migration configuration.

2. A visual application arranging method applied to a hybrid cloud environment is characterized by comprising the following steps:

firstly, a user directly knows the existing application deployment condition and the overall resource occupancy rate of a platform through a platform visual interface;

secondly, the system clicks, drags and releases the visual interface through a user, and directly carries out visual editing on the interface by the application needing deployment;

step three, arranging a flow by a service directory module in the system according to a pre-configured application, calling a resource monitoring module, and applying for computing, network and storage resources corresponding to the cloud platform;

step four, the system completes resource allocation required by the software application through the scheduling algorithm allocation module and informs the resource scheduling algorithm allocation module and the resource scheduling execution module to start a software installation process;

fifthly, the software deployment module completes the whole software installation under the cooperation of the resource scheduling module; after checking and confirming, updating corresponding information to the resource monitoring module, and synchronously outputting the corresponding information to the visual interface module in real time;

step six, when the application is migrated due to the intervention of external factors, the system uses a scheduling algorithm configuration module to apply for the required resources; the system calls an application migration configuration module and a migration process execution module to complete the migration of the application across the cloud platform; in the whole process, the resource monitoring module monitors related resources and various information and provides log information.

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