OpenNebula explained

OpenNebula
Developer:OpenNebula Systems, OpenNebula Community
Latest Release Version:6.8.0[1]
Programming Language:C++, Ruby, Shell script, lex, yacc, JavaScript
Operating System:Linux
Platform:Hypervisors (VMware vCenter, KVM, LXD/LXC, and AWS Firecracker)
Language:English, Czech, French, Slovak, Spanish, Chinese, Thai, Turkish, Portuguese, Turkish, Russian, Dutch, Estonian, Japanese
Genre:Cloud computing
License:Apache License version 2

OpenNebula is an open source cloud computing platform for managing heterogeneous data center, public cloud and edge computing infrastructure resources. OpenNebula manages on-premises and remote virtual infrastructure to build private, public, or hybrid implementations of Infrastructure as a Service and multi-tenant Kubernetes deployments. The two primary uses of the OpenNebula platform are data center virtualization and cloud deployments based on the KVM hypervisor, LXD/LXC system containers, and AWS Firecracker microVMs. The platform is also capable of offering the cloud infrastructure necessary to operate a cloud on top of existing VMware infrastructure. In early June 2020, OpenNebula announced the release of a new Enterprise Edition for corporate users, along with a Community Edition.[2] OpenNebula CE is free and open-source software, released under the Apache License version 2. OpenNebula CE comes with free access to patch releases containing critical bug fixes but with no access to the regular EE maintenance releases. Upgrades to the latest minor/major version is only available for CE users with non-commercial deployments or with significant open source contributions to the OpenNebula Community.[3] OpenNebula EE is distributed under a closed-source license and requires a commercial Subscription.[4]

History

The OpenNebula Project was started as a research venture in 2005 by Ignacio M. Llorente and Ruben S. Montero. The first public release of the software occurred in 2008. The goals of the research were to create efficient solutions for managing virtual machines on distributed infrastructures. It was also important that these solutions had the ability to scale at high levels. Open-source development and an active community of developers have since helped mature the project. As the project matured it began to become more and more adopted and in March 2010 the primary writers of the project founded C12G Labs, now known as OpenNebula Systems, which provides value-added professional services to enterprises adopting or utilizing OpenNebula.

Description

OpenNebula orchestrates storage, network, virtualization, monitoring, and security[5] technologies to deploy multi-tier services (e.g. compute clusters[6] [7]) as virtual machines on distributed infrastructures, combining both data center resources and remote cloud resources, according to allocation policies. According to the European Commission's 2010 report "... only few cloud dedicated research projects in the widest sense have been initiated – most prominent amongst them probably OpenNebula ...".[8]

The toolkit includes features for integration, management, scalability, security and accounting. It also claims standardization, interoperability and portability, providing cloud users and administrators with a choice of several cloud interfaces (Amazon EC2 Query, OGF Open Cloud Computing Interface and vCloud) and hypervisors (VMware vCenter, KVM, LXD/LXC and AWS Firecracker), and can accommodate multiple hardware and software combinations in a data center.[9]

OpenNebula is sponsored by OpenNebula Systems (formerly C12G).

OpenNebula is widely used by a variety of industries, including cloud providers, telecommunication, information technology services, government, banking, gaming, media, hosting, supercomputing, research laboratories, and international research projects. The OpenNebula Project is also used by some other cloud solutions as a cloud engine.[10] OpenNebula has grown significantly since going public and now has many notable users from a variety of industries. Notable users from the telecommunications and internet industry include Akamai, Blackberry, Fuze, Telefónica, and INdigital. Users in the information technology industry include CA Technologies, Hewlett Packard Enterprise, Hitachi Vantara, Informatica, CentOS, Netways, Ippon Technologies, Terradue 2.0, Unisys, MAV Technologies, Liberologico, Etnetera, EDS Systems, Inovex, Bosstek, Datera, Saldab, Hash Include, Blackpoint, Deloitte, Sharx dc, Server Storage Solutions, and NTS. Government solutions utilizing the OpenNebula Project include the National Central Library of Florence, bDigital, Deutsch E-Post, RedIRIS, GRNET, Instituto Geografico Nacional, CSIC, Gobex, ASAC Communications, KNAW, Junta De Andalucia, Flanders Environmental Agency, red.es, CENATIC, Milieuinfo, SIGMA, and Computaex. Notable users in the financial sector include TransUnion, Produpan, Axcess Financial, Farm Credit Services of America, and Nasdaq Dubai. Media and gaming users include BBC, Unity, R.U.R., Crytek, iSpot.tv, and Nordeus. Hosting providers include ON VPS, NBSP, Orion VM, CITEC, LibreIT, Quobis, Virtion, OnGrid, Altus, DMEx, LMD, HostColor, Handy Networks, BIT, Good Hosting, Avalon, noosvps, Opulent Cloud, PTisp, Ungleich.ch, TAS France, TeleData, CipherSpace, Nuxit, Cyon, Tentacle Networks, Virtiso BV, METANET, e-tugra, lunacloud, todoencloud, Echelon, Knight Point Systems, 2 Twelve Solutions, and flexyz. SaaS and enterprise users include Scytl, LeadMesh, OptimalPath, RJMetrics, Carismatel, Sigma, GLOBALRAP, Runtastic, MOZ, Rentalia, Vibes, Yuterra, Best Buy, Roke, Intuit, Securitas Direct, trivago, and Booking.com.

Science and academia implementations include FAS Research Computing at Harvard University, FermiLab, NIKHEF, LAL CNRS, DESY, INFN, IPB Halle, CSIRO, fccn, AIST, KISTI, KIT, ASTI, Fatec Lins, MIMOS, SZTAKI, Ciemat, SurfSARA, ESA, NASA, ScanEX, NCHC, CESGA, CRS4, PDC, CSUC, Tokyo Institute of Technology, CSC, HPCI, Cerit-SC, LRZ, PIC, Telecom SUD Paris, Universidade Federal de Ceara, Instituto Superiore Mario Barella, Academia Sinica, UNACHI, UCM, Universite Catholique de Louvain, Universite de Strasbourg, ECMWF, EWE Tel, INAFTNG, TeideHPC, Cujae, and Kent State University.Cloud products using OpenNebula include ClassCat, HexaGrid, NodeWeaver, Impetus, and ZeroNines.

Development

OpenNebula follows a rapid release cycle to improve user satisfaction by rapidly delivering features and innovations based on user requirements and feedback. In other words, giving customers what they want more quickly, in smaller increments, while additionally increasing technical quality.

Major upgrades generally occur every 3-5 years and each upgrade generally has 3-5 updates. The OpenNebula project is mainly open-source and possible thanks to the active community of developers and translators supporting the project. Since version 5.12 the upgrade scripts are under a closed source license, which makes upgrading between versions impossible without a subscription unless you can prove you are operating a non-profit cloud or made a significant contribution to the project.

Release History

Internal architecture

Basic components

  1. Underlying of physical network infrastructure.
  2. The logical address space available (IPv4, IPv6, dual stack).
  3. Context attributes (e.g. net mask, DNS, gateway). OpenNebula also comes with a Virtual Router appliance to provide networking services like DHCP, DNS etc.

Components and Deployment Model

The OpenNebula Project's deployment model resembles classic cluster architecture which utilizes

Front-end machine

The master node, sometimes referred to as the front-end machine, executes all the OpenNebula services. This is the actual machine where OpenNebula is installed. OpenNebula services on the front-end machine include the management daemon (oned), scheduler (sched), the web interface server (Sunstone server), and other advanced components. These services are responsible for queuing, scheduling, and submitting jobs to other machines in the cluster. The master node also provides the mechanisms to manage the entire system. This includes adding virtual machines, monitoring the status of virtual machines, hosting the repository, and transferring virtual machines when necessary. Much of this is possible due to a monitoring subsystem which gathers information such as host status, performance, and capacity use. The system is highly scalable and is only limited by the performance of the actual server.

Hypervisor enabled-hosts

The worker nodes, or hypervisor enabled-hosts, provide the actual computing resources needed for processing all jobs submitted by the master node. OpenNebula hypervisor enabled-hosts use a virtualization hypervisor such as Vmware, Xen, or KVM. The KVM hypervisor is natively supported and used by default.Virtualization hosts are the physical machines that run the virtual machines and various platforms can be used with OpenNebula. A Virtualization Subsystem interacts with these hosts to take the actions needed by the master node.

Storage

The datastores simply hold the base images of the Virtual Machines. The datastores must be accessible to the front-end; this can be accomplished by using one of a variety of available technologies such as NAS, SAN, or direct attached storage. Three different datastore classes are included with OpenNebula, including system datastores, image datastores, and file datastores. System datastores hold the images used for running the virtual machines. The images can be complete copies of an original image, deltas, or symbolic links depending on the storage technology used. The image datastores are used to store the disk image repository. Images from the image datastores are moved to or from the system datastore when virtual machines are deployed or manipulated. The file datastore is used for regular files and is often used for kernels, ram disks, or context files.

Physical networks

Physical networks are required to support the interconnection of storage servers and virtual machines in remote locations. It is also essential that the front-end machine can connect to all the worker nodes or hosts. At the very least two physical networks are required as OpenNebula requires a service network and an instance network. The instance network allows the virtual machines to connect across different hosts. The network subsystem of OpenNebula is easily customizable to allow easy adaptation to existing data centers.

See also

External links

Notes and References

  1. https://github.com/OpenNebula/one/wiki/Release-Schedule OpenNebula's Release Schedule
  2. Web site: Introducing OpenNebula Enterprise Edition. OpenNebula website. 4 June 2020 . 16 June 2020.
  3. Web site: Get Migration Packages. OpenNebula website. 7 July 2020.
  4. Web site: Upgrade Your OpenNebula Cloud. OpenNebula website. 7 July 2020.
  5. Web site: Key Features about OpenNebula. Discover OpenNebula. 10 December 2019.
  6. R. Moreno-Vozmediano, R. S. Montero, and I. M. Llorente. "Multi-Cloud Deployment of Computing Clusters for Loosely-Coupled MTC Applications", Transactions on Parallel and Distributed Systems. Special Issue on Many Task Computing (in press,)
  7. R. S. Montero, R. Moreno-Vozmediano, and I. M. Llorente. "An Elasticity Model for High Throughput Computing Clusters", J. Parallel and Distributed Computing (in press,)
  8. Web site: The Future of Cloud Computing . European Commission Expert Group Report . 25 January 2010 . 12 December 2017 .
  9. B. Sotomayor, R. S. Montero, I. M. Llorente, I. Foster. "Virtual Infrastructure Management in Private and Hybrid Clouds", IEEE Internet Computing, vol. 13, no. 5, pp. 14-22, September/October 2009.)
  10. Web site: Featured Users. OpenNebula website. 20 December 2017.