CN108809733B - System for multi-node deployment docking OpenStack cloud management platform - Google Patents

Abstract

The invention provides a system for deploying and docking an OpenStack cloud management platform by multiple nodes, wherein each computing node is respectively docked with the OpenStack cloud management platform; the installation package obtaining and executing module is used for obtaining an OpenStack cloud management platform installation package, using an OpenStack cloud management platform mirror image to manufacture a starting disc, and entering the installation package to execute installation; the installation display module is used for deploying installation process monitoring points and displaying installation progress and process on the computing nodes; the node configuration module is used for adding OpenStack virtual control to execute deployment docking after the installation operation is completed; configuring an OpenStack cloud management platform ID, a communication protocol, a user name and a password of a computing node, a port security protocol supported by the computing node and a supported network type; the Openstack cloud platform provides technical support of stable operation, expandability and flexibility for each computing node.

Description

System for multi-node deployment docking OpenStack cloud management platform

Technical Field

The invention relates to the field of cloud computing, in particular to a system for multi-node deployment and docking of an OpenStack cloud management platform.

Background

OpenStack is both a community and a project and an open source software that supports almost all types of cloud environments, providing a solution or toolset for deploying the cloud. The purpose is as follows: the cloud service system helps to organize the cloud which runs as a virtual computing or storage service, and provides extensible and flexible cloud computing for public clouds and private clouds.

There are many public clouds, private clouds and mixed clouds established by using the OpenStack internationally, the heat of the OpenStack in China is gradually increased, and the OpenStack is strongly interested and participates in the Langchao, the Huashengtangcheng, the Goodpasture map, the Jingdong, the Ali baba, the Baidu, the Zhongxing, the Huacheng and the like. OpenStack is likely to take a leading position in future infrastructure as a service (IaaS) resource management, becoming a "cloud operating system" standard for public, private, and hybrid cloud management.

At present, the Langchao computing node also has a wide application prospect, and in order to enable the cloud computing node to have a good storage application field, the cloud computing node occupies a position in the aspect of future infrastructure, namely service resource management, and becomes a public cloud computing, private computing storage and hybrid cloud computing system, so that docking deployment with a cloud computing management platform is required, and how to realize the docking deployment is a technical problem to be solved currently.

Disclosure of Invention

In order to overcome the defects in the prior art, the invention provides a system for multi-node deployment and docking of an OpenStack cloud management platform, which comprises: the OpenStack cloud management platform comprises an OpenStack cloud management platform and a plurality of computing nodes; each computing node is respectively butted with an OpenStack cloud management platform;

the computing node includes: the system comprises an installation package acquisition execution module, an installation display module, a node configuration module and a memory;

the installation package obtaining and executing module is used for obtaining an OpenStack cloud management platform installation package, using an OpenStack cloud management platform mirror image to manufacture a starting disc, and entering the installation package to execute installation;

the installation display module is used for deploying installation process monitoring points and displaying installation progress and process on the computing nodes;

the node configuration module is used for adding OpenStack virtual control to execute deployment docking after the installation operation is completed; configuring an OpenStack cloud management platform ID, a communication protocol, a user name and a password of a computing node, a port security protocol supported by the computing node and a supported network type;

the memory is used for storing data information of the computing node.

Preferably, the computing node further comprises: rgw module configuration module;

rgw module configuration module is used to configure rgw module, create rgw pool, start compute node storage service; creating a metadata service in a pool of memory configurations rgw; creating a data storage pool; a metadata storage pool is created.

Preferably, the rgw module configuration module is further configured to create a compute node file system, and install a cluster management tool on the compute node; configuring a connection client port; creating a manila shared directory; starting a snapshot function of the file system; various hard disks are used for NFS and CIFS startup.

Preferably, the rgw module configuration module is further configured to configure storage capacity supported by a RESTFul HTTP API interface of the compute node, construct the rgw module of each compute node on a librados module, and is compatible with Amazon S3 and Opensack Swift; providing an account and a password for a user to use the computing node rgw module, and storing the account and password files of the user in an/etc/ceph directory; providing a pool of users for each user having access to the computing node rgw module when the user logs into the computing node using rgw module through account and password; the user storage pool includes: a user-specific storage pool and a user-general storage pool.

Preferably, the computing node further comprises: a cloud platform script deployment module;

the cloud platform script deployment module is used for copying a script of the OpenStack cloud management platform deployment node to a preset directory of the computing node; and editing the OpenStack cloud management platform deployment node script copied to the computing node into an open state.

Preferably, the cloud platform script deployment module is further configured to check available data traffic between the OpenStack cloud management platform and the computing node docking port before deploying the OpenStack cloud management platform deployment node script, start docking when the available data traffic is higher than a preset value, and copy the OpenStack cloud management platform deployment node script to a preset directory of the computing node.

Preferably, the installation package obtaining and executing module is further configured to configure a computing node boot image based on the OpenStack cloud management platform; the OpenStack cloud management platform executes the mirror image port number of the computing node based on the IP of the computing node, calls the computing node to start the mirror image, and if the calling is successful, the starting disk mirror image is successfully manufactured.

Preferably, the computing node further comprises: the PXE module obtains an installation module;

the PXE module acquisition installation module is used for acquiring the PXE module from the OpenStack cloud management platform and carrying out installation configuration.

According to the technical scheme, the invention has the following advantages:

the OpenStack cloud management platform provides technical support of stable operation, expandability and flexibility for each computing node. The structure of uniformly storing metadata and data is adopted, and all the computing equipment nodes form a cluster, so that the functions of file access, capacity management, data protection and the like are provided for the outside. The system comprises a monitoring service, a metadata service, a data service (OSD) and a client, wherein the system provides standard POSIX interface data service externally, and a data service port supports a gigabit network, a gigabit network and an InfiniBand network and supports Linux and Windows client access. The method provided by the invention can conveniently and quickly complete the fusion deployment and butt joint of the computing node and the openstack. The computing node is made to cover various aspects of networks, virtualization, operating systems, servers, and the like. The computing nodes finish virtual fusion, allocation as required and efficient management of bottom-layer physical resources, so that the agility and flexibility of resource delivery can be obviously improved, the use efficiency of the resources is improved, and uninterrupted resource guarantee and telescopic resource supply are provided for upper-layer services.

Drawings

In order to more clearly illustrate the technical solution of the present invention, the drawings used in the description will be briefly introduced, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art that other drawings can be obtained based on these drawings without creative efforts.

FIG. 1 is a schematic system diagram of a multi-node deployment docking OpenStack cloud management platform;

FIG. 2 is a schematic diagram of an embodiment of a system for multi-node deployment interfacing with an OpenStack cloud management platform.

Detailed Description

The invention provides a system for multi-node deployment and docking of an OpenStack cloud management platform, which comprises the following components as shown in figures 1 and 2: the OpenStack cloud management platform comprises an OpenStack cloud management platform and a plurality of computing nodes; each computing node is respectively butted with an OpenStack cloud management platform;

the computing node includes: the system comprises an installation package acquisition execution module, an installation display module, a node configuration module and a memory; the installation package obtaining and executing module is used for obtaining an OpenStack cloud management platform installation package, using an OpenStack cloud management platform mirror image to manufacture a starting disc, and entering the installation package to execute installation; the installation display module is used for deploying installation process monitoring points and displaying installation progress and process on the computing nodes; the node configuration module is used for adding OpenStack virtual control to execute deployment docking after the installation operation is completed; configuring an OpenStack cloud management platform ID, a communication protocol, a user name and a password of a computing node, a port security protocol supported by the computing node and a supported network type; the memory is used for storing data information of the computing node.

The following takes the compute node installation as an example: and (3) manufacturing an optical disk boot disk by using a system image icfs-SDS-linux-3.10.0. iso to boot all computing nodes, wherein the installation scheme comprises an automatic partition and a manual partition which can be selected: the InstallICFS Server and Auto-partition are automatic partition installation Server-side ICFS systems, and the InstallVMware and ICFS Server are manual partition installation Server-side ICFS systems.

Deployment of a storage system comprises deploying a monitoring service ifs-deploy new node01 node02 node 03-cluster-network 100.2.100.0/24-public-network 100.2.100.0/24, initializing a monitoring (mon) service ifs-deploy-overlay-consistent mon create-initial, cleaning disk partitions ifs-deploy disk map node01: sd { b.

In the present invention, the computing node further comprises: rgw module configuration module; rgw module configuration module is used to configure rgw module, create rgw pool, start compute node storage service; creating a metadata service in a pool of memory configurations rgw; creating a data storage pool; a metadata storage pool is created.

rgw module configuration module is also used to create the computing node file system, and install the cluster management tool on the computing node; configuring a connection client port; creating a manila shared directory; starting a snapshot function of the file system; various hard disks are used for NFS and CIFS startup.

The rgw module configuration module is further used for configuring storage capacity supported by a RESTFul HTTP API (application program interface) of the computing nodes, constructing the rgw module of each computing node on a librados module, and being compatible with Amazon S3 and Opensack Swift; providing an account and a password for a user to use the computing node rgw module, and storing the account and password files of the user in an/etc/ceph directory; providing a pool of users for each user having access to the computing node rgw module when the user logs into the computing node using rgw module through account and password; the user storage pool includes: a user-specific storage pool and a user-general storage pool.

Installing a cluster management tool on the computing node; configuring a connection client port; creating a manila shared directory; starting a snapshot function of the file system; various hard disks are used for NFS and CIFS startup.

Wherein, the computing node supports that rgw configuration is added in/etc/icfs/icfs.conf as follows, and synchronously updates/root/icfs-deploy/icfs.conf, [ client

host = inspur01

log file = /var/log/icfs/radosgw.log

rgw_frontends = civetweb port=8009

rgw _ socket _ path =/var/run/icfs. radosgw. gateway. civetweb. sock, create rgw pool, # icfs and pool yield

icfs osd pool create default.rgw.control 64 64

icfs osd pool create default.rgw.data.root 64 64

icfs osd pool create default.rgw.gc 64 64

icfs osd pool create default.rgw.log 64 64

icfs osd pool create default.rgw.users.uid 64 64

icfs osd pool create default.rgw.users.keys 64 64

icfs osd pool create default.rgw.meta 64 64

icfs osd pool create default.rgw.buckets.index 64 64

icfs osd pool create .rgw.root 64 64

icfs osd pool create default.rgw.users.email 64 64

icfs os pool create default, rgw. buckets.non-ec 6464, service start-up system start icfs-radosw @ radosw. gateway, wave AS-13000 File System support, Create metadata service icfs-deployment, metadata pool create 03:0 inpur 04:1, Create data pool icfs os pool create metadata pool 256256, Create metadata pool # icfs os pool create metadata pool 256256

# icfs osd pool set metapool size 3, create file system icfs new inpurfs metapool datapool, cluster management tool install, management software install, Fuse client install, create manila shared root directory icfs-admin-dir-create-p/manila-u root-g root-mod rwrxrwrwrx-pool, start file system snapshot function icfs-fs-snap-on, start NFS, CIFS icfs, icfs-admin-NFS-start, icfs-admin-CIFS-start. Computing nodes use a variety of hard disks.

Configuring the memory capacity supported by the RESTFul HTTP API (application program interface) of each computing node, constructing an rgw module of each computing node on a librados module, and being compatible with Amazon S3 and Opensack Swift; providing an account and a password for a user to use the computing node rgw module, and storing the account and password files of the user in an/etc/ceph directory; providing a pool of users for each user having access to the computing node rgw module when the user logs into the computing node using rgw module through account and password; the user storage pool includes: a user-specific storage pool and a user-general storage pool. Therefore, each computing node can be used based on the OpenStack cloud management platform based on the account number and the password distributed by the user, and the OpenStack cloud management platform can also be used through each computing node.

In the present invention, the computing node further comprises: a cloud platform script deployment module; the cloud platform script deployment module is used for copying a script of the OpenStack cloud management platform deployment node to a preset directory of the computing node; and editing the OpenStack cloud management platform deployment node script copied to the computing node into an open state. The cloud platform script deployment module is further used for checking available data flow between the OpenStack cloud management platform and the computing node docking port before deploying the OpenStack cloud management platform deployment node script, starting docking when the available data flow is higher than a preset value, and copying the OpenStack cloud management platform deployment node script to a preset directory of the computing node.

The approach that can be taken here is to perform an InCloud OpenStack deployment: checking the occupation condition of a port before deployment, and the like kolla-arbitrary caches-i/root/multinode; the service kolla-allowed deployment-i/root/multimode is deployed.

In order to ensure the accuracy of the deployment of the OpenStack cloud management platform deployment node script. Copying the script/root/tools/external-icfs.sh of the Openstack deployment node to a storage cluster deployment node/root directory: sh/root/external-icfs.sh; after the execution is finished, all the generated files in the config directory are copied to the directory corresponding to the/etc/kolla/config of the OpenStack deployment node, and the/etc/kolla/globals.yml of the OpenStack deployment node is edited to start the following parameters: enable _ clipper: "yes"

glance_backend_ceph: "yes"

cinder_backend_ceph: "yes"

nova_backend_ceph: "yes"

enable_cetus: "yes"

cetus_backend_ceph: "yes"

In the invention, the installation package acquisition execution module is also used for configuring a computing node starting mirror image based on the OpenStack cloud management platform; the OpenStack cloud management platform executes the mirror image port number of the computing node based on the IP of the computing node, calls the computing node to start the mirror image, and if the calling is successful, the starting disk mirror image is successfully manufactured.

The method can be used for solving the problem that a deployment node cannot pull a mirror image for an OpenStack cloud management platform deployment node check item systemctl restart locker; the OpenStack cloud management platform checks whether system status docker | grid Active (running) is normal for all nodes, and tests whether mirror image can pull current http:// deployment node IP:4000/v2/_ catalog | python-m json.

In the present invention, the computing node further comprises: the PXE module obtains an installation module; the PXE module acquisition installation module is used for acquiring the PXE module from the OpenStack cloud management platform and carrying out installation configuration.

In the invention, the OpenStack cloud management platform provides technical support of stable operation, expandability and flexibility for each computing node. The structure of uniformly storing metadata and data is adopted, and all the computing equipment nodes form a cluster, so that the functions of file access, capacity management, data protection and the like are provided for the outside. The system comprises a monitoring service, a metadata service, a data service (OSD) and a client, wherein the system provides standard POSIX interface data service externally, and a data service port supports a gigabit network, a gigabit network and an InfiniBand network and supports Linux and Windows client access. The method provided by the invention can conveniently and quickly complete the fusion deployment and butt joint of the computing node and the openstack. The computing node is made to cover various aspects of networks, virtualization, operating systems, servers, and the like. The computing nodes finish virtual fusion, allocation as required and efficient management of bottom-layer physical resources, so that the agility and flexibility of resource delivery can be obviously improved, the use efficiency of the resources is improved, and uninterrupted resource guarantee and telescopic resource supply are provided for upper-layer services.

In order to make the objects, features and advantages of the present invention more obvious and understandable, the technical solutions of the present invention will be clearly and completely described below with reference to specific embodiments and drawings. 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 scope of protection of this patent.

Claims (7)

1. A system for multi-node deployment docking of an OpenStack cloud management platform is characterized by comprising: the OpenStack cloud management platform comprises an OpenStack cloud management platform and a plurality of computing nodes; each computing node is respectively butted with an OpenStack cloud management platform;

the computing node includes: the system comprises an installation package acquisition execution module, an installation display module, a node configuration module, an rgw module configuration module and a memory;

the installation package obtaining and executing module is used for obtaining an OpenStack cloud management platform installation package, using an OpenStack cloud management platform mirror image to manufacture a starting disc, and entering the installation package to execute installation;

the installation display module is used for deploying installation process monitoring points and displaying installation progress and process on the computing nodes;

the node configuration module is used for adding OpenStack virtual control to execute deployment docking after the installation operation is completed; configuring an OpenStack cloud management platform ID, a communication protocol, a user name and a password of a computing node, a port security protocol supported by the computing node and a supported network type;

the memory is used for storing data information of the computing node;

rgw module configuration module is used to configure rgw module, create rgw pool, start compute node storage service; creating a metadata service in a pool of memory configurations rgw; creating a data storage pool; a metadata storage pool is created.

2. The system for multi-node deployment interfacing with OpenStack cloud management platform of claim 1,

rgw module configuration module is also used to create the computing node file system, and install the cluster management tool on the computing node; configuring a connection client port; creating a manila shared directory; starting a snapshot function of the file system; and starting the NFS hard disk and the CIFS hard disk.

3. The system for multi-node deployment interfacing with OpenStack cloud management platform of claim 1,

the rgw module configuration module is also used for configuring the storage capacity supported by the RESTFul HTTP API interface of the computing nodes, constructing the rgw module of each computing node on the librados module, and being compatible with Amazon S3 and OpenStack Swift; providing an account and a password for a user to use the computing node rgw module, and storing the account and password files of the user in an/etc/ceph directory; providing a pool of users for each user having access to the computing node rgw module when the user logs into the computing node using rgw module through account and password; the user storage pool includes: a user-specific storage pool and a user-general storage pool.

4. The system for multi-node deployment interfacing with OpenStack cloud management platform of claim 1,

the computing node further comprises: a cloud platform script deployment module;

the cloud platform script deployment module is used for copying a script of the OpenStack cloud management platform deployment node to a preset directory of the computing node; and editing the OpenStack cloud management platform deployment node script copied to the computing node into an open state.

5. The system for multi-node deployment interfacing with OpenStack cloud management platform according to claim 4,

the cloud platform script deployment module is further used for checking available data flow between the OpenStack cloud management platform and the computing node docking port before deploying the OpenStack cloud management platform deployment node script, starting docking when the available data flow is higher than a preset value, and copying the OpenStack cloud management platform deployment node script to a preset directory of the computing node.

6. The system for multi-node deployment interfacing with OpenStack cloud management platform of claim 1,

the installation package obtaining execution module is also used for configuring a computing node starting mirror image based on the OpenStack cloud management platform; the OpenStack cloud management platform executes the mirror image port number of the computing node based on the IP of the computing node, calls the computing node to start the mirror image, and if the calling is successful, the starting disk mirror image is successfully manufactured.

7. The system for multi-node deployment interfacing with OpenStack cloud management platform of claim 1,

the computing node further comprises: the PXE module obtains an installation module;

the PXE module acquisition installation module is used for acquiring the PXE module from the OpenStack cloud management platform and carrying out installation configuration.

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