Come See SNIA at the Software-Defined Infrastructure Summit

Demand for software-defined infrastructure (SDI) is on the rise, and with good reason. SDI helps data centers meet the challenges of cloud computing, big data/analytics, mobility and social media, in an agile and cost-effective way.  I’m pleased to announce that SNIA will be an active participant at next week’s Software-Defined Infrastructure Summit in Santa Clara, CA, December 1-3.

My colleagues and I at the SNIA Cloud Storage Initiative have organized a “Working with OpenStack” Seminar that kicks off the Summit on Tuesday, December 1.

I will keynote an OpenStack fireside chat along with Chris DePuy, VP, at Dell’Oro Group. We’ll be discussing the SNIA Cloud Data Management Interface (CDMI) and its interface with OpenStack, OpenStack implementations, how standards play, and the future of open source in the 21st century.

My keynote will be accompanied by additional SNIA talks in the Introduction to OpenStack session and the Application Management session:

  • Sam Fineberg, PhD, SNIA Cloud Storage Initiative member and Distinguished Technologist at Hewlett Packard Enterprise Storage, will provide an overview of the storage aspects of OpenStack including the core projects for block storage (Cinder) and object storage (Swift), and the new shared file service (Manila). He’ll cover some common configurations and use cases for these technologies, and discuss how they interact with the other parts of OpenStack.
  • Richelle Ahlvers, SNIA Open Source Task Force member and Principal Storage Management Architect at Avago Technologies, will discuss application integration in OpenStack and how SNIA-developed standards enable cross-vendor management interoperability and help open source projects interoperate with more industry solutions.

Tuesday’s Seminar day will include additional sessions from leaders in OpenStack, Ceph, and Software Defined Storage. SDI Summit days 2 and 3 will provide information on hardware, software, and data center technology and applications of software-defined infrastructure featuring keynotes from IBM, Intel, Red Hat, and VMware, all SNIA member companies.  It’s a must attend event.

SNIA will also be exhibiting at the Summit. Please stop by booth #408 to learn how SNIA standards are used in open source projects including cloud data management, non-volatile memory, self-contained information retention, and storage management. We will also have information on SNIA programs such as membership, certification, conformance testing, and conferences.

SNIA members and colleagues can use the code SPGP to receive a $100 discount on any level of SDI Summit registration. I hope to see you in Santa Clara!

Outstanding Keynotes from Leading Storage Experts Make SDC Attendance a Must!

Posted by Marty Foltyn

Tomorrow is the last day to register online for next week’s Storage Developer Conference at the Hyatt Regency Santa Clara. What better incentive to click www.storagedeveloper.org and register than to read about the amazing keynote and featured speakers at this event – I think they’re the best since the event began in 1998! Preview sessions here, and click on the title to download the full description.SDC15_WebHeader3_999x188

Bev Crair, Vice President and General Manager, Storage Group, Intel will present Innovator, Disruptor or Laggard, Where Will Your Storage Applications Live? Next Generation Storage and discuss the leadership role Intel is playing in driving the open source community for software defined storage, server based storage, and upcoming technologies that will shift how storage is architected.

Jim Handy, General Director, Objective Analysis will report on The Long-Term Future of Solid State Storage, examining research of new solid state memory and storage types, and new means of integrating them into highly-optimized computing architectures. This will lead to a discussion of the way that these will impact the market for computing equipment.

Jim Pinkerton, Partner Architect Lead, Microsoft will present Concepts on Moving From SAS connected JBOD to an Ethernet Connected JBOD . This talk examines the advantages of moving to an Ethernet connected JBOD, what infrastructure has to be in place, what performance requirements are needed to be competitive, and examines technical issues in deploying and managing such a product.

Andy Rudoff, SNIA NVM Programming TWG, Intel will discuss Planning for the Next Decade of NVM Programming describing how emerging NVM technologies and related research are causing a change to the software development ecosystem. Andy will describe use cases for load/store accessible NVM, some transparent to applications, others non-transparent.

Richard McDougall, Big Data and Storage Chief Scientist, VMware will present Software Defined Storage – What Does it Look Like in 3 Years? He will survey and contrast the popular software architectural approaches and investigate the changing hardware architectures upon which these systems are built.

Laz Vekiarides, CTO and Co-founder, ClearSky Data will discuss Why the Storage You Have is Not the Storage Your Data Needs , sharing some of the questions every storage architect should ask.

Donnie Berkholz, Research Director, 451 Research will present Emerging Trends in Software Development drawing on his experience and research to discuss emerging trends in how software across the stack is created and deployed, with a particular focus on relevance to storage development and usage.

Gleb Budman, CEO, Backblaze will discuss Learnings from Nearly a Decade of Building Low-cost Cloud Storage. He will cover the design of the storage hardware, the cloud storage file system software, and the operations processes that currently store over 150 petabytes and 5 petabytes every month.

You could wait and register onsite at the Hyatt, but why? If you need more reasons to attend, check out SNIA on Storage previous blog entries on File Systems, Cloud, Management, New Thinking, Disruptive Technologies, and Security sessions at SDC. See the full agenda and register now for SDC at http://www.storagedeveloper.org.

Upcoming Webcast: Hybrid Clouds Part 2

On June 10, 2015, SNIACloud will be hosting a live Webcast “Hybrid Clouds Part 2: A Case Study on Building a Bridge between Public and Private Clouds.” There are significant differences in how cloud services are delivered to various categories of users. The integration of these services with traditional IT operations will remain an important success factor but also a challenge for IT managers. The key to success is to build a bridge between private and public clouds. I’ll be back to expand upon our earlier SNIA Hybrid Clouds Webcast where we looked at the choices and strategies for picking a cloud provider for public and hybrid solutions. Please join me on June 10th to hear:

  • Best practices to work with multiple public cloud providers
  • The role of SDS in supporting a hybrid data fabric
  • Hybrid cloud decision criteria
  • Key implementation principles
  • Real-world hybrid cloud use case

Please Register now and bring your questions. This will be a live and interactive event. I hope to see you there.

 

 

Hybrid Clouds Webcast Preview

On March 18th, SNIA-CSI will be hosting a live Webcast “Hybrid Clouds: Bridging Private and Public Cloud Infrastructures.”

Every IT consumer is using (or is planning to use) cloud in one form or another. The emphasis on the design and implementation of cloud architectures is often made without consideration of where the cloud storage and compute should be located and the benefits, costs and risks of deciding where the applications will run. Will it be a public cloud? Or a private cloud in the data center or co-location site? Or a hybrid of the two?

This session will be an overview on developing & delivering a cloud architecture with a focus on getting the overall goals correctly specified and defined, understanding the issues that must be addressed, and then making the decision about whether the application is suitable for public, private or some hybrid mixture of the two before undertaking implementation. We’ll also focus on one of the most difficult aspects of the solution, the management of data and storage in the cloud, and present a case study of a successful commercial implementation.

Register now for this live event. I hope you’ll join Alex McDonald and me for what we hope will be an informative and interactive event.

SNIA’s Events Strategy Today and Tomorrow

David Dale, SNIA Chairman

Last month Computerworld/IDG and the SNIA posted a notice to the SNW website stating that they have decided to conclude the production of SNW.  The contract was expiring and both parties declined to renew.  The IT industry has changed significantly in the 15 years since SNW was first launched, and both parties felt that their individual interests would be best served by pursuing separate events strategies.

For the SNIA, events are a strategically important vehicle for fulfilling its mission of developing standards, maintaining an active ecosystem of storage industry experts, and providing vendor-neutral educational materials to enable IT professions to deal with and derive value from constant technology change.  To address the first two categories, SNIA has a strong track record of producing Technical Symposia throughout the year, and the successful Storage Developer Conference in September.

To address the third category, IT professionals, SNIA has announced a new event, to be held in Santa Clara, CA, from April 22-24 – the Data Storage Innovation Conference. This event is targeted at IT decision-makers, technology implementers, and those expected to influence, implement and support data storage innovation as actual production solutions.  See the press release and call for presentations for more information.  We are excited to embark on developing this contemporary new event into an industry mainstay in the coming years.

Outside of the USA, events are also critically important vehicles for the autonomous SNIA Regional Affiliates to fulfill their mission.  The audience there is typically more biased towards business executives and IT managers, and over the years their events have evolved to incorporate adjacent technology areas, new developments and regional requirements.

As an example of this evolution, SNIA Europe’s events partner, Angel Business Communications, recently announced that its very successful October event, SNW Europe/Datacenter Technologies/Virtualization World, will be simply known as Powering the Cloud starting in 2014, in order to unite the conference program and to be more clearly relevant to today’s IT industry. See the press release for more details.

Other Regional Affiliates have followed a similar path with events such as Implementing Information Infrastructure Summit and Information Infrastructure Conference – both tailored to meet regional needs.

The bottom line on this is that the SNIA is absolutely committed to a global events strategy to enable it to carry out its mission.  We are excited about the evolution of our various events to meet the changing needs of the market and continue to deliver unique vendor-neutral content. IT professionals, partners, vendors and their customers around the globe can continue to rely on SNIA events to inform them about new technologies and developments and help them navigate the rapidly changing world of IT.

Software Defined Networks for SANs?

Previously, I’ve blogged about the VN2VN (virtual node to virtual node) technology coming with the new T11-FC-BB6 specification. In a nutshell, VN2VN enables an “all Ethernet” FCoE network, eliminating the requirement for an expensive Fibre Channel Forwarding (FCF) enabled switch. VN2VN dramatically lowers the barrier of entry for deploying FCoE. Host software is available to support VN2VN, but so far only one major SAN vendor supports VN2VN today. The ecosystem is coming, but are there more immediate alternatives for deploying FCoE without an FCF-enabled switch or VN2VN-enabled target SANs? The answer is that full FC-BB5 FCF services could be provided today using Software Defined Networking (SDN) in conjunction with standard DCB-enabled switches by essentially implementing those services in host-based software running in a virtual machine on the network. This would be an alternative “all Ethernet” storage network supporting Fibre Channel protocols. Just such an approach was presented at SNIA’s Storage Developers Conference 2013 in a presentation entitled, “Software-Defined Network Technology and the Future of Storage,” Stuart Berman, Chief Executive Officer, Jeda Networks. (Note, of course neither approach is relevant to SAN networks using Fibre Channel HBAs, cables, and switches.)

Interest in SDN is spreading like wildfire. Several pioneering companies have released solutions for at least parts of the SDN puzzle, but kerosene hit the wildfire with the $1B acquisition of Nicira by VMware. Now a flood of companies are pursuing an SDN approach to everything from wide area networks to firewalls to wireless networks. Applying SDN technology to storage, or more specifically to Storage Area Networks, is an interesting next step. See Jason Blosil’s blog below, “Ethernet is the right fit for the Software Defined Data Center.”

To review, an SDN abstracts the network switch control plane from the physical hardware. This abstraction is implemented by a software controller, which can be a virtual appliance or virtual machine hosted in a virtualized environment, e.g., a VMware ESXi host. The benefits are many; the abstraction is often behaviorally consistent with the network being virtualized but simpler to manipulate and manage for a user. The SDN controller can automate the numerous configuration steps needed to set up a network, lowering the amount of touch points required by a network engineer. The SDN controller is also network speed agnostic, i.e., it can operate over a 10Gbps Ethernet fabric and seamlessly transition to operate over a 100Gbps Ethernet fabric. And finally, the SDN controller can be given an unlimited amount of CPU and memory resources in the host virtual server, scaling to a much greater magnitude compared to the control planes in switches that are powered by relatively low powered processors.

So why would you apply SDN to a SAN? One reason is SSD technology; storage arrays based on SSDs move the bandwidth bottleneck for the first time in recent memory into the network. An SSD array can load several 10Gbps links, overwhelming many 10G Ethernet fabrics. Applying a Storage SDN to an Ethernet fabric and removing the tight coupling of speed of the switch with the storage control plane will accelerate adoption of higher speed Ethernet fabrics. This will in turn move the network bandwidth bottleneck back into the storage array, where it belongs.

Another reason to apply SDN to Storage Networks is to help move certain application workloads into the Cloud. As compute resources increase in speed and consolidate, workloads require deterministic bandwidth, IOPS and/or resiliency metrics which have not been well served by Cloud infrastructures. Storage SDNs would apply enterprise level SAN best practices to the Cloud, enabling the migration of some applications which would increase the revenue opportunities of the Cloud providers. The ability to provide a highly resilient, high performance, SLA-capable Cloud service is a large market opportunity that is not cost available/realizable with today’s technologies.

So how can SDN technology be applied to the SAN? The most viable candidate would be to leverage a Fibre Channel over Ethernet (FCoE) network. An FCoE network already converges a high performance SAN with the Ethernet LAN. FCoE is a lightweight and efficient protocol that implements flow control in the switch hardware, as long as the switch supports Data Center Bridging (DCB). There are plenty of standard “physical” DCB-enabled Ethernet switches to choose from, so a Storage SDN would give the network engineer freedom of choice. An FCoE based SDN would create a single unified, converged and abstracted SAN fabric. To create this Storage SDN you would need to extract and abstract the FCoE control plane from the switch removing any dependency of a physical FCF. This would include the critical global SAN services such as the Name Server table, the Zoning table and State Change Notification. Containing the global SAN services, the Storage SDN would also have to communicate with initiators and targets, something an SDN controller does not do. Since FCoE is a network-centric technology, i.e., configuration is performed from the network, a Storage SDN can automate large SAN’s from a single appliance. The Storage SDN should be able to create deterministic, end-to-end Ethernet fabric paths due to the global view of the network that an SDN controller typically has.

A Storage SDN would also be network speed agnostic, since Ethernet switches already support 10Gbps, 40Gbps, and 100Gbps this would enable extremely fast SANs not currently attainable. Imagine the workloads, applications and consolidation of physical infrastructure possible with a 100Gbps Storage SDN SAN all controlled by a software FCoE virtual server connecting thousands of servers with terabytes of SSD storage? SDN technology is bursting with solutions around LAN traffic; now we need to tie in the SAN and keep it as non-proprietary to the hardware as possible.

Ethernet is the right fit for the Software Defined Data Center

“Software Defined” is a label being used to define advances in network and storage virtualization and promises to greatly improve infrastructure management and accelerate business agility. Network virtualization itself isn’t a new concept and has been around in various forms for some time (think vLANs). But, the commercialization of server virtualization seems to have paved the path to extend virtualization throughout the data center infrastructure, making the data center an IT environment delivering dynamic and even self-deployed services. The networking stack has been getting most of the recent buzz and I’ll focus on that portion of the infrastructure here.

VirtualizationChangesWhat is driving this trend in data networking? As I mentioned, server virtualization has a lot to do with the new trend. Virtualizing applications makes a lot of things better, and makes some things more complicated. Server virtualization enables you to achieve much higher application density in your data center. Instead of a one-to-one relationship between the application and server, you can host tens of applications on the same physical server. This is great news for data centers that run into space limitations or for businesses looking for greater efficiency out of their existing hardware.

YesteryearThe challenge, however, is that these applications aren’t stationary. They can move from one physical server to another. And this mobility can add complications for the networking guys. Networks must be aware of virtual machines in ways that they don’t have to be aware of physical servers. For network admins of yesteryear, their domain was a black box of “innies” and “outies”. Gone are the days of “set it and forget it” in terms of networking devices. Or is it?

Software defined networks (aka SDN) promise to greatly simplify the network environment. By decoupling the control plane from the data plane, SDN allows administrators to treat a collection of networking devices as a single entity and can then use policies to configure and deploy networking resources more dynamically. Additionally, moving to a software defined infrastructure means that you can move control and management of physical devices to different applications within the infrastructure, which give you flexibility to launch and deploy virtual infrastructures in a more agile way.

network virtualizationSoftware defined networks aren’t limited to a specific physical transport. The theory, and I believe implementation, will be universal in concept. However, the more that hardware can be deployed in a consistent manner, the greater flexibility for the enterprise. As server virtualization becomes the norm, servers hosting applications with mixed protocol needs (block and file) will be more common. In this scenario, Ethernet networks offer advantages, especially as software defined networks come to play. Following is a list of some of the benefits of Ethernet in a software defined network environment.

Ubiquitous

Ethernet is a very familiar technology and is present in almost every compute and mobile device in an enterprise. From IP telephony to mobile devices, Ethernet is a networking standard commonly deployed and as a result, is very cost effective. The number of devices and engineering resources focused on Ethernet drives the economics in favor of Ethernet.

Compatibility

Ethernet has been around for so long and has proven to “just work.” Interoperability is really a non-issue and this extends to inter-vendor interoperability. Some other networking technologies require same vendor components throughout the data path. Not the case with Ethernet. With the rare exception, you can mix and match switch and adapter devices within the same infrastructure. Obviously, best practices would suggest that at least a single vendor within the switch infrastructure would simplify the environment with a common set of management tools, features, and support plans. But, that might change with advances in SDN.

Highly Scalable

Ethernet is massively scalable. The use of routing technology allows for broad geographic networks. The recent adoption of IPv6 extends IP addressing way beyond what is conceivable at this point in time. As we enter the “internet of things” period in IT history, we will not lack for network scale. At least, in theory.

Overlay Networks

Overlay Networksallow you to extend L2 networks beyond traditional geographic boundaries. Two proposed standards are under review by the Internet Engineering Task Force (IETF). These include Virtual eXtensible Local Area Networks (VXLAN) from VMware and Network Virtualization using Generic Routing Encapsulation (NVGRE) from Microsoft. Overlay networks combine L2 and L3 technologies to extend the L2 network beyond traditional geographic boundaries, as with hybrid clouds. You can think of overlay networks as essentially a generalization of a vLAN. Unlike with routing, overlay networks permit you to retain visibility and accessibility of your L2 network across larger geographies.

Unified Protocol Access

Ethernet has the ability to support mixed storage protocols, including iSCSI, FCoE, NFS, and CIFS/SMB. Support for mixed or unified environments can be more efficiently deployed using 10 Gigabit Ethernet (10GbE) and Data Center Bridging (required for FCoE traffic) as IP and FCoE traffic can share the same ports. 10GbE simplifies network deployment as the data center can be wired once and protocols can be reconfigured with software, rather than hardware changes.

Virtualization

Ethernet does very well in virtualized environments. IP address can easily be abstracted from physical ports to facilitate port mobility. As a result, networks built on an Ethernet infrastructure leveraging network virtualization can benefit from increased flexibility and uptime as hardware can be serviced or upgraded while applications are online.

Roadmap

For years, Ethernet has increased performance, but the transition from Gigabit Ethernet to 10 Gigabit Ethernet was a slow one. Delays in connector standards complicated matters. But, those days are over and the roadmap remains robust and product advances are accelerating. We are starting to see 40GbE devices on the market today, and will see 100GbE devices in the near future. As more and more data traffic is consolidated onto a shared infrastructure, these performance increases will provide the headroom for more efficient infrastructure deployments.

Some of the benefits listed above can be found with other networking technologies. But, Ethernet technology offers a unique combination of technology and economic value across a broad ecosystem of vendors that make it an ideal infrastructure for next generation data centers. And as these data centers are designed more and more around application services, software will be the lead conversation. To enable the vision of a software defined infrastructure, there is no better network technology than Ethernet.