CN114237810A - Cloud computing platform based on BIM integrated delivery mode - Google Patents

Abstract

The invention discloses a cloud computing platform based on a BIM integrated delivery mode, which comprises a front-end UI, a background service and a monitoring alarm, wherein the front-end UI, the background service and the monitoring alarm depend on kubernets and harbor third-party open source project management application and service, the platform provides api and devops integration, projects pushed by the devops are created, micro-service components are deployed on the platform in a key mode, the platform adopts a front-end and back-end separation scheme, the front end is in charge of UI page display and interaction control and uses nginx forwarding, the main service of the platform adopts a springmvc mybatis mysql main frame and consists of four-layer structures of a control layer, an interface layer, a service layer and a database, the cloud computing platform based on the BIM integrated delivery mode adopts a container technology to construct the cloud computing platform, adopts a high-reliability Kuberers framework, and integrates cloud core technologies such as elastic computing, distributed deployment, storage, mirror image level safety scanning and graphical cloud operation and maintenance UI, the platform has the characteristics of one-stop service, and is safe, reliable and excellent in performance.

Description

Cloud computing platform based on BIM integrated delivery mode

Technical Field

The invention relates to the technical field of assembly type buildings, in particular to a cloud computing platform based on a BIM (building information modeling) integrated delivery mode.

Background

The assembly type building logistics distribution application 4D/5D BIM implements an integrated project delivery mode, and the BIM needs to be transformed to effectively adapt and support the operation and iteration of IPD technology; meanwhile, deployment, operation, upgrading and perfect full-life-cycle management of BIM need to be supported by a frontier lightweight cloud computing platform, and a cloud development environment, a tool library, and operation, maintenance and safety support of the whole process are provided. The light-weight cloud computing platform can integrate IPD technical ecology, integrates and schedules an operation cost system and an algorithm model, so that the general assembly type building logistics distribution framework can be uniformly deployed and implemented.

Disclosure of Invention

The technical problem to be solved by the invention is to overcome the existing defects, provide a cloud computing platform based on a BIM integrated delivery mode, construct the cloud computing platform by adopting a container technology, adopt a high-reliability Kubernets framework, integrate core cloud technologies such as elastic computing, distributed deployment, storage, software-defined network (SDN), mirror image level safe scanning and graphical cloud operation and maintenance UI and the like, be a safe, reliable and excellent-performance platform with one-stop service characteristics, and effectively solve the problems in the background technology.

In order to achieve the purpose, the invention provides the following technical scheme: a cloud computing platform based on a BIM integrated delivery mode comprises a front-end UI, a background service and a monitoring alarm, wherein the front-end UI, the background service and the monitoring alarm depend on kubernets and harbor third-party open source project management application and service, the platform provides api and devops for integration, projects pushed by the devops are created, micro-service components are deployed on one key of the platform, the platform adopts a front-end and back-end separation scheme, the front end is responsible for UI page display and interaction control, ngin is used for forwarding and requesting background service interaction data, a platform main service adopts a springmvc mybatis mysql main frame, a maven is used for managing project module dependence and consists of a control layer, an interface layer, a service layer and a database four-layer structure, the platform relies on k8s and harbor for service release and management, services are created and managed on a k8s cluster through an http interface of an api server of k8s, and release of the services uses a release type of a deadly resource 8s, during the publishing process, mirroring is carried out from the hardbill according to the mirror name defined by the container, a docker container running service is created, and a pod instance is created on the k8s cluster after the service is successfully published.

As a preferred technical scheme of the invention, the monitoring alarm system adopts a springbootmybatis mysql framework, uses maven to manage project module dependence, comprises two upper-layer modules api and schedule, and depends on a common biz module and can be packed and deployed independently respectively.

As a preferred technical scheme of the invention, the monitoring alarm system is provided with a Heapster, an infiluxdb and an elastic search as auxiliary components of a cluster, and is used for recording the resource use condition and the centralized collection of logs in the service operation process.

As a preferred technical scheme of the invention, the platform has a cluster registration function, a cluster modification function, a cluster maintenance function and a cluster deletion function of multi-cluster life cycle management.

As a preferred technical solution of the present invention, the cluster registration function adds a kubernets cluster to a platform for uniform management, and can register as a development, test, pre-production, and production cluster according to the use requirement.

As a preferred technical solution of the present invention, the cluster modification function allows visual synchronous update after background component information change, and modifies mirror image warehouse, login information, cluster domain name, load balancing, external mount, and cluster template information.

As a preferred technical solution of the present invention, the cluster maintenance function is configured to put the cluster into an operation and maintenance state and to prevent the cluster from being continuously scheduled by other users when the cluster has a sudden problem and needs to be maintained.

As a preferred technical solution of the present invention, the cluster deletion function removes the cluster from the current data center, and resources such as partitions, applications, services, and the like of the cluster also move out of the current system along with the cluster.

Compared with the prior art, the invention has the beneficial effects that: the cloud computing platform based on the BIM integrated delivery mode adopts a container technology to construct the cloud computing platform, adopts a high-reliability Kubernetes framework, integrates core cloud technologies such as elastic computing, distributed deployment, storage, software self-defined network (SDN), image level safety scanning and graphical cloud operation and maintenance UI, and is a safe, reliable and excellent-performance platform with one-stop service characteristics.

Drawings

FIG. 1 is a schematic diagram of the framework structure of the present invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1, the present invention provides a technical solution: a cloud computing platform based on a BIM integrated delivery mode comprises three sub-projects, namely a front end UI, a background service and a monitoring alarm, and management application and service of projects of a Kubernets and a harbor third party are relied on.

Providing integration of api with vops, creating items pushed by vops, and one-touch deployment of microservice components on the platform.

The platform adopts a front-end and back-end separation scheme, the front end is responsible for UI page display and interaction control, nginx is used for forwarding, and background service interaction data is requested.

The platform main service adopts a springmvc + mybatis + mysql main frame, uses maven to manage project module dependence, and consists of a control layer, an interface layer, a business layer and a database four-layer structure.

The platform relies on k8s and the harbor for service publishing and management. Services are created and managed on the k8s cluster through an http interface of an api server of the k8s, the services are issued by using a deployment resource type of the k8s, the services are mirrored from a hardhall and created a docker container to run the services according to a mirror name defined by the container in the issuing process, and a pod instance is created on the k8s cluster after the services are successfully issued.

The monitoring alarm system adopts a springboot + mybatis + mysql framework, uses maven to manage project module dependence, comprises two upper-layer modules api and schedule, depends on a common biz module, and can be independently packaged and deployed respectively.

The Heapster, the infiluxdb and the Elasticissearch serve as auxiliary components of the cluster and are used for recording resource use conditions and centralized collection of logs in the service operation process.

The cloud computing platform is constructed by adopting a container technology with independent intellectual property rights, a high-reliability Kubernetes framework is adopted, core cloud technologies such as elastic computing, distributed deployment/storage, Software Defined Network (SDN), image level security scanning and graphical cloud operation and maintenance UI are integrated, and the platform has the advantages of one-stop service characteristics, safety, reliability and excellent performance.

Unified visual management needs to be performed on a Kubernets platform of a public cloud, a private cloud and a physical machine in an assembly type building integrated delivery mode, and core function support such as registration, modification, operation and maintenance, monitoring and the like of multiple clusters is provided. Meanwhile, the multi-cluster management can realize the classified management of the clusters aiming at different data centers.

Cluster registration function for multi-cluster lifecycle management. The Kubernetes cluster is added into a platform for uniform management, and can be registered as a development cluster, a test cluster, a pre-production cluster and a production cluster according to use requirements. The cluster modification function allows visual synchronous update after background component information change, and modification of a mirror warehouse, login information, a cluster domain name, load balancing, external mounting and cluster template information. And the cluster maintenance function is used for putting the cluster into an operation and maintenance state under the condition that the cluster has sudden problems and needs to be maintained, and the cluster cannot be continuously scheduled by other users. The cluster deletion function removes the cluster from the current data center, and resources such as partitions, applications, services and the like of the cluster are also moved out of the current system along with the cluster.

The cluster component monitors the key components, reliability of a cluster of the platform in the operation process is ensured to the maximum extent, and an alarm center alarms events in real time for component operation problems.

The resource management of the cluster has the utilization rate of the total CPU, the memory and the disk, and also has an overview of host resources and partition (namespace) resources inside the cluster. Meanwhile, host online and offline are realized for host resources of the cluster, and addition, deletion and expansion of the capacity are realized for the partitions.

Various types of hosts are provided for integrated project delivery. The host computer carries out type conversion in a specific state to realize flexible scheduling of resources, provides one-key host computer online service to rapidly expand cluster resources, and carries out smooth offline and forced offline of the host computer. The host which is set to be non-schedulable will not be scheduled with new service by the system, and as a fault emergency handling means, the smooth maintenance and offline function of the host can be realized by matching with the application migration function. The label creating and deleting function of the host can set a plurality of labels and perform searching and grouping based on the labels.

The multi-tenant management is used as a software architecture technology of a series of complex resource sets to manage multi-dimensional resources, so that resources are shared in a multi-user environment, and data isolation is guaranteed.

The tenant management system of the platform for supporting the delivery of the assembly type building integrated project at least has the management functions of three levels of tenants, projects and working spaces. A tenant may be considered a department or a large set of items; the items correspond to a specific set of items; a workspace (Namespace) may run services, and in a multi-cluster scenario a project group may have a different workspace in each cluster.

Tenant resources on the platform are strictly isolated according to business requirements. First, from the perspective of the underlying resources, different applications run in different containers all with Cgroup to achieve isolation and restriction of the underlying resources. For the tenants, different tenants belong to different partitions, namely different linux namespaces, and resources between different namespaces are not shared. And finally, performing resource filtering on resources, except bottom resources, mounted under different tenants, such as storage, log files, templates, alarm information and the like through a background.

Tenant communication and isolation of project delivery are integrated, communication between default tenants cannot be achieved (tenant internal applications can communicate with each other), but in some special cases, the requirement that tenants communicate with each other exists, and a tenant white list needs to be set to solve the requirement. After the tenant sets the white list, the tenant in the white list can communicate with the tenant, the communication is unilateral, and if the tenant wants to communicate with each other, the white list needs to be configured with each other.

Assembly building integration project delivery requires continuous integration and continuous deployment of CI/CDs to satisfy the application pipeline from code to mirror to development test production environment. The method supports direct deployment of application code from a code warehouse to the selected cluster and partition, and can select a trigger condition for deployment, wherein the CI/CD supports customization requirements.

The CICD is required to be in seamless butt joint with other components of the DevOps in the assembly type building integration project delivery, so that the overall efficiency of the DevOps platform is improved, and the assembly line release which can run through development, testing, pre-production and production environments is realized; the development and test environment is quickly set up, and third-party components and applications are deployed, so that the development efficiency is improved; the full containerization technology realizes the compiling, packaging, testing and deploying processes, reduces the cost of testing resources, and completely releases assembly line support, a plurality of code management tools, a quality scanning tool and automatic testing support.

Delivery of the prefabricated building integration project requires that the platform support the management and customized development of a variety of middleware. The middleware and other applications of the platform are operated in a container mode, are managed and scheduled by Kubernets, and are monitored and managed by the platform. Starting from the mirror selection of the middleware, each functional component and layer (layer) of the mirror needs to be scanned safely, and if the functional component with serious level is found, the mirror is repaired and changed until all bugs are repaired. After the mirror image is manufactured, the mirror image of the middleware can perform perfect functional test and high-strength pressure test on the platform, and the platform provides the middleware service with perfect function and excellent performance.

The prefabricated building integration project delivery requires the platform to provide a one-touch launch of middleware, including launching a single instance service or a cluster service. And resource objects such as a CPU, a memory, a disk and the like can be appointed to the middleware in the starting process. If the resource expansion needs to be carried out on the middleware in the using process, the expansion and the capacity reduction of the CPU and the memory are supported. The deletion middleware can select two modes of deleting and retaining the data together with the persistent data.

For most middleware, it is a stateful application. Therefore, data disaster recovery needs to be done. The delivery of the assembly type building integration project has a backup mechanism of NFS with higher reliability for the platform.

The assembled building integrated project delivery requires that a mirror warehouse is based on a Docker native mirror warehouse (registry), and an enterprise-level mirror warehouse with mirror management and operation and maintenance functions has the main functions of mirror warehouse authority control, mirror remote synchronization, high availability under a cluster and the like, and can solve the problems of mirror management confusion, low large-scale mirror publishing efficiency, unstable mirror warehouse service and the like in the integrated project delivery process.

Under the cluster environment of a mirror image warehouse, the Docker Registry needs to be synchronized and backed up with each other; in the process of ultra-large-scale application release, the algorithm and performance of load balancing must be optimized, including: remote copy and synchronization of the Docker Registry; remote copying and synchronizing of the MySQL database; and (4) selecting and optimizing a load balancing algorithm.

The life cycle of the mirror image delivered by the integrated project requires that users with different authorities have different operation authorities for the mirror images of different warehouses, and the method mainly comprises the authorities of read-write deletion, read-write, readability and the like, wherein the read-write deletion authority is the operation of the users for performing mirror image push, pull and delete on the authorized mirror image warehouse; the read-write permission carries out pull and push operations on the mirror images in the mirror image warehouse, but the uploaded mirror images cannot be deleted; the user with readable authority can only view and pull the mirror image, but cannot perform push and other high-level operations.

The assembly type building integrated project delivery requirement platform provides manual and command line uploading/downloading functions, the manual and command line uploading/downloading functions can be realized by the manual and command line uploading/downloading functions, the manual and command line uploading/downloading functions are standard mirror image compression files; the latter uploads and downloads containers with a Docker native command line.

The mirror image warehouse of the production level of the assembled building integrated project delivery also needs to provide the safety protection function of the mirror image. The image is the raw material of the entire platform, and its security directly determines the stability and robustness of the services and applications launched on the platform. Therefore, in addition to using Harbor as a tool for image management, Clair with a common vulnerability threat (CVE) scanning function is also required as a reinforcement for image security.

The delivery of the assembly type building integrated project requires project quota monitoring and warehouse loopholes on a mirror image warehouse, wherein the mirror image warehouse distributes a specified quota in the process of creating, and the use amount of the distributed quota is checked through a project overview. The latter analyzes the general situation of the loopholes of the current project, and when a plurality of high-risk loopholes appear, certain measures need to be taken to update the mirror image with a lower version and great potential safety hazards.

The assembly building integration project delivery requirements can create cleaning rules and modify, delete and the like the rules. The method comprises two types of rules, wherein the time rule is to clear all mirror images before the time rule is set except mirror images containing version number keywords; the quantity rule is the version number of each image up to the specified quantity of the retention rule, all images before clean up.

The system setting of the delivery of the assembly type building integrated project requires the presetting of a platform and the setting of role authorities, including the setting of the authority of roles, and different roles access different resources; the platform provides a mail box and short message receiving alarm information, and sets a mail box server and a short message server; user information stored on LDAP can be used directly; setting platform log retention time, audit retention months, pipeline execution record retention number, alarm record retention days and platform operation and maintenance state; setting cluster component alarm and host monitoring alarm; the centralized management platform user performs authority modification, mobile phone number modification and query functions on the user; managing the platform cluster template; the URL is reviewed and managed.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (8)

1. The utility model provides a cloud computing platform based on BIM integrated delivery mode, includes front end UI, backstage service and monitoring alarm, its characterized in that: the front-end UI, the background service and the monitoring alarm depend on the management application and service of the kubernetes and the harbor third-party open source project;

the platform provides integration of api and vops, creates items pushed by vops, and deploys the micro-service components on the platform by one key;

the platform adopts a front-end and back-end separation scheme, the front end is responsible for UI page display and interaction control, and nginx forwarding is used for requesting background service interaction data;

the platform main service adopts a springmvc mybatis mysql main frame, uses maven to manage item module dependence, and consists of a control layer, an interface layer, a business layer and a database four-layer structure;

the platform relies on k8s and a hardor to perform service publishing and management, services are created and managed on a k8s cluster through an http interface of an api server of k8s, the services are published by using a default resource type of k8s, during publishing, the services are mirrored from the hardor pull and a docker container is created to run the services according to a mirror name defined by the container, and after the services are successfully published, a pod instance is created on the k8s cluster.

2. The BIM integrated delivery mode-based cloud computing platform of claim 1, wherein: the monitoring alarm system adopts a springboot mybatis mysql framework, uses maven to manage project module dependence, comprises two upper-layer modules api and schedule, and can independently pack and deploy respectively by relying on a common biz module.

3. The BIM integrated delivery mode-based cloud computing platform of claim 1, wherein: the monitoring alarm system is provided with a Heapster, an infiluxdb and an Elasticissearch as auxiliary components of a cluster, and is used for recording resource use conditions in the service operation process and collecting logs in a centralized manner.

4. The BIM integrated delivery mode-based cloud computing platform of claim 1, wherein: the platform has a cluster registration function, a cluster modification function, a cluster maintenance function and a cluster deletion function of multi-cluster life cycle management.

5. The BIM integrated delivery mode-based cloud computing platform of claim 4, wherein: the cluster registration function adds the Kubernets cluster into the platform for uniform management, and can register the Kubernets cluster into development, test, pre-production and production clusters according to the use requirements.

6. The BIM integrated delivery mode-based cloud computing platform of claim 4, wherein: the cluster modification function allows visual synchronous update after background component information change, and modifies the mirror warehouse, login information, cluster domain name, load balance, external mounting and cluster template information.

7. The BIM integrated delivery mode-based cloud computing platform of claim 4, wherein: the cluster maintenance function is used for putting the cluster into an operation and maintenance state under the condition that the cluster has sudden problems and needs to be maintained, and the cluster cannot be continuously scheduled by other users.

8. The BIM integrated delivery mode-based cloud computing platform of claim 4, wherein: the cluster deleting function removes the cluster from the current data center, and resources such as partitions, applications, services and the like of the cluster can also be moved out of the current system along with the cluster.

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