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Tony Pearson is a Master Inventor, Senior IT Architect and Event Content Manager for [IBM Systems for IBM Systems Technical University] events. With over 30 years with IBM Systems, Tony is frequent traveler, speaking to clients at events throughout the world.
Lloyd Dean is an IBM Senior Certified Executive IT Architect in Infrastructure Architecture. Lloyd has held numerous senior technical roles at IBM during his 19 plus years at IBM. Lloyd most recently has been leading efforts across the Communication/CSI Market as a senior Storage Solution Architect/CTS covering the Kansas City territory. In prior years Lloyd supported the industry accounts as a Storage Solution architect and prior to that as a Storage Software Solutions specialist during his time in the ATS organization.
Lloyd currently supports North America storage sales teams in his Storage Software Solution Architecture SME role in the Washington Systems Center team. His current focus is with IBM Cloud Private and he will be delivering and supporting sessions at Think2019, and Storage Technical University on the Value of IBM storage in this high value IBM solution a part of the IBM Cloud strategy. Lloyd maintains a Subject Matter Expert status across the IBM Spectrum Storage Software solutions. You can follow Lloyd on Twitter @ldean0558 and LinkedIn Lloyd Dean.
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This week, I am presenting at the IBM Systems Technical University in Orlando, Florida, May 22-26, 2017. Here's my recap of the afternoon sessions of Day 2.
IBM Spectrum Protect deep dive into Container Storage Pools
Ron Henkhaus, IBM Certified Consulting IT Specialist, presented the new Spectrum Protect concept of "Container Pools" that can either be "Directory Pools" on SAN or NAS-based disk storage, or "Cloud Pools". Container pools can contain deduplicated and non-dedupe data.
Ron cautioned that directory pools should not be placed on the same file system as your Spectrum Protect database or logs. Also, best practice for any directory pool is to assign an "overflow" pool to any non-directory pool, such as disk, tape or cloud container.
Cloud pools can use either OpenStack Swift, V1 Swift, Amazon S3 protocol, Amazon Web Services, IBM Bluemix, and IBM Cloud Object Storage. You can pre-define the vaults and buckets in the configuration.
For off-premises Cloud pools, the data is encrypted by default. For other container pools, encryption is optional. Performance to Cloud pools have been improved by using "accelerator storage", basically a disk cache to collect data before sending over to the Cloud pool. Backups to Cloud pools can reach 8 TB per hour. Restore times varies from 500 to 1500 GB per hour.
Container Pools were designed for the new "Deduplication 2.0" feature introduced in version 7. Traditional Dedupe 1.0 to Device Class FILE is still available, but not recommended.
Version 7.1.6 changed the compression algorithm from LZW to LZ4. In all cases, Spectrum Protect performs these actions in this order: deduplication, compression, encryption. Data that is encrypted by the Spectrum Protect client is therefore not deduped.
The "Protect Storage Pool" command can replicate a directory pool to either a remote directory pool or Cloud pool. In addition to this remote replication, you can copy a directory pool to tape to offer air-gap protection against ransomware. Such tapes are considered part of the "Copy Container Pool". In the event of directory pool corruption, the data can be repaired from either replication or tape.
IBM Aspera can now be used for replication, using SSL and AES-128 bit encryption. If your latency is greater than 50 msec, and have more than 0.5 percent packet loss, Aspera might help. This is available for Linux on x86 platforms running v7.1.6 or higher.
For existing customers, IBM Spectrum Protect allows you to convert your FILE, VTL and TAPE device class pools to directory or Cloud pools.
Introduction to IBM Cloud Object Storage (powered by Cleversafe)
In 2015, IBM acquired Cleversafe, recognized as the #1 Object Storage vendor. Their flagship product was officially renamed to the IBM Cloud Object Storage System, which some abbreviate informally as IBM COS. IBM offers the IBM Cloud Object Storage System in three ways: as software, as pre-built systems, and as a cloud service on IBM Bluemix (formerly known as SoftLayer).
Since then, IBM has been busy integrating IBM COS into the rest of the storage portfolio. I explained how IBM COS can be used for all kinds of static-and-stable data, but not suited for frequently changed data, such as Virtual machines or Databases.
Object storage can be access via NFS or SMB NAS-protocols using a gateway product, like IBM Spectrum Scale, or those from third-party partners like Ctera, Avere, Nasuni or Panzura. It can also be used as an alternative to tape for backup copies, and is already supported by the major backup software like IBM Spectrum Protect, Commvault Simpana, or Veritas NetBackup.
While other cloud service providers have offered data storage in the cloud, this new offering also allows hybrid configurations with geographically dispersed erasure coding.
Unlike RAID which protects against the loss of one or two drives, erasure coding can protect against a larger number of concurrent failures. For example, using an Information Dispersal Algorithm (IDA) of "7+5", where seven pieces of data are encoded on twelve independent disks, the system can lose up to five disk drives without losing any data.
Combining this with Geographically Dispersed Configuration across three or more sites means that you can lose an entire data center, four of the twelve disks, and still have instant full access to all of your data from eight drives at the other locations. In the graphic, you see two on-premise data centers combined with a third location in IBM SoftLayer.
New Generation of Storage Tiering: Simpler Management, Lower Costs, and Improved Performance
With ever changing amounts of storage, it is hard to find metrics that are consistent year to year. Fortunately, we found I/O density as the metric to focus my efforts, armed with real data from Intelligent Information Lifecycle Management (IILM) studies done at various clients. From that, I was able to talk about storage tiering on three fronts:
Storage tiering between Flash and disk. IBM FlashSystem and IBM Easy Tier on DS8000 and Spectrum Virtualize family for hybrid Flash-and-disk configurations.
Storage tiering between disk, tape, and Cloud. HSM and Information Lifecycle Management (ILM) on Spectrum Scale, Elastic Storage Server (ESS), Spectrum Archive and IBM Cloud Object Storage System.
Storage tiering automation across your entire environment. IILM studies can help identify a target mix of Tier 0, Tier 1, Tier 2 and Tier 3 storage. IBM Spectrum Storage Suite and the Virtual Storage Center (VSC) can recommend or perform the movement of LUNs to more appropriate tiers, based on age and I/O density measurements.
It's hard to say what the correct sequence of presentations should be. Some thought it might have been better for my talk on IBM Cloud Object Storage System prior to Ron's talk on Cloud container pools, but perhaps hearing Ron first helped drive more interest to my session.
I have been involved with Business Continuity and Disaster Recovery my entire career at IBM System Storage. However, with new workloads like Hadoop analytics and new Hybrid Cloud deployments, I thought it would be good to provide a refresh.
The need for Business Continuity and Disaster Recovery has increased recently due to (a) climate change caused by human activity, (b) ransomware and other cyber attacks, and (c) disgruntled employees.
Back in 1983, a task force of IBM clients at a GUIDE conference developed "Seven Business Continuity Tiers for Disaster Recovery", which I refer to as "BC Tiers". I divided the presentation into three sections:
Backup and Restore: BC tiers 1 through 3 are based on backup and restore methodologies. I explained how to backup Hadoop analytics data, all of the various options for IBM Spectrum Protect software, and how to encrypt the tape data that gets sent off premises.
Rapid Data Recovery: BC tiers 4 and 5 reduce the Recovery Point Objective (RPO) and Recovery Time Objective (RTO) with snapshots, database journal shadowing, and IBM Cloud Object Storage.
Continuous Operations: BC tiers 6 and 7 provide data replication mirroring across locations. I covered 2-site, 3-site and 4-site configurations.
IBM Spectrum Virtualize - How it works - Deep dive
Barry Whyte, IBM Master Inventor and ATS for Spectrum Virtualize, covered a variety of internal topics "under the hood" of Spectrum Virtualize. This covers the SAN Volume Controller (SVC), FlashSystem V9000, Storwize V7000 and V5000 products, as well as Spectrum Virtualize sold as software.
In version 7.7, IBM raised the limits. You can now have 10,000 virtual disks per cluster, rather than 2,048 per node-pair. Also, you can now have up to 512 compressed volumes per node-pair. With the new 5U-high 92-drive expansion drawers, Storwize V7000 can now support up to 3,040 drives, and Storwize V5030 can support up to 1,520 drives.
While each Spectrum Virtualize node has redundant components, the architecture is designed to handle entire node failure. The term "I/O Group" was created to refer to the node-pair of Spectrum Virtualize engines and the set of virtual disks it manages. This made sense when virtual disks were dedicated to a single node-pair. Now, virtual disks can be assigned to multiple node-pairs, dynamically adding or removing node-pairs as needed for each virtual disk.
However, even if you have a virtual disk assigned to multiple node-pairs, only one node-pair would manage its cache, causing all other node-pairs to coordinate I/O through the cache-owning node-pair. The other node-pairs are called "access I/O groups".
The architecture allows for linear scalability, double the number of nodes, and you double your performance. Some competitors use n-way caching across four or more nodes, and it is a semi-religious argument on the pros and cons of each approach. Barry feels the 2-way caching implemented by Spectrum Virtualize is the most effective and efficient for performance.
All of the nodes are connected over IP network, but there is one designated as a "config node", and one, often the same, as a "boss node".
A cluster can have up to three physical quorum disks (either drive or mDisk) and optionally up to five IP-based quorums. The IP-based is just a Java program that runs on any server or Cloud, provided it can respond within 80 msec.
Either IP-based or physical quorum can be used for "tie-breaking" a split-brain situations. In the event there is no "active" quorum, the administrator can now serve as the tie-breaker manually. Barry recommends for Storwize clusters, where physical quorum disks are attached to a single node-pair, that you have at least one IP-based quorum for tie-breaking.
However, only physical quorum can be used for T3 Recovery. T3 Recovery happens after power outages. All of the nodes update the quorum disk with critical information of all of the virtual mappings of blocks to volumes, and this is used when bringing up the nodes again.
To protect against one pool consuming all of the cache, Spectrum Virtualize will partition the cache, and prevent any one pool from consuming more than a certain percentage of the total cache. The percentage depends on the number of pools:
Number of Pools
Max percentage of any individual pool
5 or more
Barry explained how failover works in the event of node failure. There is voting involved, and the majority remains in the cluster. In the case of an even split, called a "split brain" situation, the quorum decides. Orphaned nodes in a node-pair go into write-through mode, since the cache is no longer mirrored.
The I/O forwarding layer has been split between upper and lower roles. The upper layer handles access I/O groups. The lower layer handles asymmetric access to drives, mDisks and arrays.
N-port ID Virtualization (NPIV) drastically improves multi-pathing. Perhaps one of the coolest improvements in awhile, NPIV allows us to assign "Virtual" WWPN to other ports. When an I/O sent to a single port fails, it retries one or more times again, then waits 30 seconds, and then invokes multi-pathing to find a completely different path to the data. With NPIV, when a port fails, its WWPN is re-assigned to a different port, so the retries are likely to be successful before having to wait 30 seconds!
Lastly, Barry covered the delicate art of Software upgrades. Software is rolled forward one node at a time, and the "cluster state" is maintained during this time.
Different presentations this week are at different technical levels. My session was meant to be an overview of the concepts of Business Continuity, independent of specific operating system platform, using specific IBM products to help illustrate specific examples. Barry's was a deep dive into a single product family.
This week, I am presenting at the IBM Systems Technical University in Orlando, Florida, May 22-26, 2017. Here's my recap of the afternoon sessions of Day 1.
Storage Brand Opening Session - Craig Nelson
Craig Nelson, Brocade manager for IBM Field Sales Channel, indicated the network equipment is the bridge that brings servers and storage together.
The squeeze -- faster servers and Flash storage causes storage networking to become the bottleneck. Fibre Channel will remain the protocol of choice for the next decade.
"Speed is the net currency of Business" -- Marc Benioff, Salesforce CEO.
Craig drew an analogy. We have been focused on making hard disk drives faster, and then Flash changed the game. Likewise, car manufacturers have focused on making gas engines better, and then Tesla Motors introduces an electric car with insane performance. The early models actually had an "Insane Mode".
The new Gen6 models of IBM b-type SAN equipment will support 32Gbps and 128Gbps ports. That's Insane!
Later models of Tesla Motors offer a "Ludicrous Mode". For flash storage, it is NVMe. NVMe can get storage down to 20 microsecond latency. That's Ludicrous!
Craig put in a plug for two Brocade sessions: "BEWARE - The four potholes on your road to success when deploying flash storage" and "Tune up your storage network! Is it healthy enough for flash storage and next-gen server platforms?"
Storage Brand Opening Session - Clod Barrera
Clod Barrera, IBM Distinguished Engineer and Chief Technical Strategist, presenting storage industry trends.
IDC predicts data capacity to grow 60-80% CAGR. This would require 44 percent drop in $/GB per year to maintain flat budget. Unfortunately, flash media cost is only dropping 25-30 percent per year, and spinning disk only 19 percent per year.
Since storage media will not offset capacity growth, we need other technologies to compensate, including compression, deduplication, defensible disposal, and "cold" storage to tape or optical media.
The smallest persistent storage that IBM has been able to achieve is 12 atoms. Current disk technology is 1200 atoms. Since 1956, IBM and the rest of the IT industry have improved storage 9 orders of magnitude, and now there are only 2 orders of magnitude left.
Clod poked fun at the "Star Wars: Rogue One" movie, indicating that their idea of the future of storage was a huge tape library. See my December 2016 blog post [Has your data gone rogue?]
What does it take to storage information forever? Tape will certainly be around. IBM Zurich demonstrated a 220TB back in 2015 as proof of technology.
A good example of the need for long-term retention are US films. Of those from the silent era, over 90 percent are lost. Over half of the films prior to 1950 are lost. The silver nitrate film stock that the reels were made of have deteriorated. Now that more movies are made digitally, can we do better?
Clouds will move from 10GbE to 25GbE. No slow down for FC in datacenters. Flash storage and object storage are both growing quickly
Move over Software-Defined Storage, Converged and Hyperconverged systems, the new up-and-coming thing are "Composable Systems deployed in Pods" adjustable hourly by workload requirements.
To protect against Ransomware, use "air gap" protection, not on the same network as production workload.
New storage models are needed for Cognitive workloads. Clod put in a plug for Joe Dain's presentation "Introducing cognitive index and search for IBM Cloud Object Storage leveraging Watson"
Storage Brand Opening Session - Axel Koester
Axel Koester, IBM Storage Chief Technologist, presented more storage industry directions.
What will the world look like in 10 years. Today mostly procedural programming, with some statistical big data, and a bit of machine learning. In 10 years, it will be mostly statistical and machine learning, with very little procedural programming. Why? Because it is faster to train computers with Machine Learning, than to program procedurally.
Examples of machine learning are IBM Watson, Google AlphaGo, drive-AI. Axel would rather be a passenger in a machine-learned self-driving car, than a procedurally-programmed one.
Neural networks to interpret hand-written numbers. Welcome to "Unsupervised learning".
A subset of Machine Learning is Deep Learning, a major breakthrough in 2006. Deep Learning is a subset of Machine Learning that uses three or more layers of neural networks. For example, face recognition "deep learning" algorithms can also be used to detect defects through visual inspection of circuit boards.
How does this impact storage?
Procedural -- archive test cases used
Statistical -- store all data for parallel processing
Machine Learning - train sample data, then archive and re-train yearly. Driving 5 minutes = 4 TB of sensor data used for self-driving cars
For Neural processing, x86 CPU are suitable for prototyping. GPU co-processors better, efficient but uncommon. IBM has developed the "TrueNorth" chip does nothing by Neural - 4096 cores with only 70 mW of energy consumption. No clock, instead dendrites, synapses, axons and neurons.
Instead of "Build or Buy?" the new question is "Train or Buy?" Train with confidential data, or buy ready-to-run 100% pre-trained cognitive systems as a service.
AI Frameworks are available on Docker containers with Kubernetes with Persistent storage (Ubiquity) such as Spectrum Scale. These frameworks include DL4J, Chainer, Caffe, torch, theano, tensorflow.
NVMe -- NVM is local only, how to do HA and DR? There are three options:
DB asynchronous shadowing
DB mirroring over NVMeOF
Cluster file system replication of persistent data, such as IBM Spectrum Scale
Example car manufacturer with 50 SAP HANA in memory instances on 4 Spectrum Scale nodes. IBM achieved 50,000 new files per second. Most NAS systems do much less.
Faster media on smaller electronics Holmium atoms on Magnesium Oxide on silver base, resulting in "single atom storage." ATM needle tip magnetizes, measured with Tunnel Magneto-resistance. Unfortunately, reading the data causes it to lose its value, so it is not as persistent as the 12-atom method described by Clod earlier.
As the title suggests, I explained why there is so much interest in Software-Defined Storage in the IT industry, what software-defined storage is, and how to deploy these solutions in your existing infrastructure without the full rip-and-replace. I covered which IBM products are available as software, pre-built systems and/or Cloud services.
This week, I am presenting at the IBM Systems Technical University in Orlando, Florida, May 22-26, 2017. Day 1 included keynote sessions. Here is my recap for the morning.
General Session "The Quantum Age"
Amy Hirst, IBM Director of Systems Training, served as emcee for the General Session. The theme this week is "Power of Knowledge, Power of Technology, Power of You. You to the IBM'th power".
Chris Schnabel, IBM Q Offering Manager, explained what "IBM Q" is.
Chris feels "our intuition of what we can compute is wrong". Classical (non-Quantum) computing has evolved over past 100 years.
Consider Molecular geometry. The best supercomputer can only handle the smallest molecules, those with 40 to 50 electrons, and even then are unable to calculate bond lengths within 10 percent accuracy. Quantum computing can.
Another area is what computer scientists call the "Traveling Salesman Problem". If you had a list of 57 cities, what would be the optimal path to minimize the distance traveled to get to all of the cities. Doing an exhaustive search would be 10 to the 76th power. Dynamic Programming techniques provide some shortcuts, reducing this down to 10 to the 20th power, but still, that is impossible on most computers.
Chris mentioned that there are easy problems to solve in polynomial time, and hard problems that are exponential, in that they get worse and worse the bigger the input set. There will always be hard problems.
"Nature isn't classical, dammit, and if you want to make a simulation of nature, you'd better make it quantum mechanical, and by golly it's a wonderful problem, because it doesn't look so easy."
-- Richard Feynman
Nature encodes information, but not in ones and zeros. Quantum computers are measured on the number of Qubits, their error rate, etc. The three factors that IBM focuses on are Coherence, Controllability and Connectivity.
Chris explained how Superposition and Entanglement are used in Quantum Computers. I won't bore you with the details here, but rather save this for a future post.
Today: 5 to 16 Qubits (can be simulated with today's classical computers. 5 Qubits is the power of your typical laptop)
Near future: 50-100 Qubits (too big to simulate on supercomputers), with answers that are approximate or correct only 2/3 of the time.
Future: millions of Qubits, fault-tolerant to provide exact, precise answers consistently.
Quantum Computing opens up a new range of problems, what Chris call "Quantum Easy" problems. Problems that might take years to solve on classical supercomputers could be solved in seconds on a Quantum computer.
Chris showed a picture of [Colossus], the first digital electronic computer used in the 1940s. Quantum computing today is like 1940's of classical computing.
IBM is now working on Hybrid Quantum-Classical algorithms, for example:
Quantum Chemistry - can be used in material design, healthcare pharmaceuticals
Optimization - logistics/shipping, risk analytics
There are different ways to build a quantum computer. IBM chose a single-junction transmon design, using Josephson junctions. While the chips are small, the refrigerators they are contained in are huge, and have to keep the chips at very cold 15 milliKelvin temperature (minus 459 Fahrenheit)!
To get people excited about Quantum computing, IBM created the "IBM Q Experience" [ibm.com/ibmq] that allows the public to run algorithms on a basic 5 Qubit system using a simple drag-and-drop interface to put different transformational gates in sequence.
IBM Research team were shocked to see 17 publications in prestigious journals make practical use of this 5 qubit system! Since then, IBM now offers a Software Developers Kit (SDK) called QISkit (pronounced Cheese-kit) as a text-based alternative to the drag-and-drop interface.
Amy Hirst came back on stage to remind people to use Twitter hashtag #ibmtechu to follow the event. There are two more events like this planned for the end of the year. A Power/Storage conference in New Orleans, October 16-20, and another event focused on z Systems mainframe, November 13-17.
Pendulum Swings Back -- Understanding Converged and Hyperconverged Systems
This presentation has an interesting back-story. At a client briefing, I was asked to explain the difference between "Converged" and "Hyperconverged" Systems, which I did with the analogy of a pendulum. I used the whiteboard, and then later made it into a single chart.
At the far left of the pendulum, I start with mainframe systems of the early 1950s that had internal storage. As the pendulum swings to the middle, I discuss the added benefits of external storage, from RAID protection and Cache memory to centralized management and backup.
To the far right of the pendulum, it swings over to networked storage, from NAS to SAN attached devices for flash, disk and tape. This offers excellent advantages, including greater host connectivity, and greater distances supported to help with things like disaster recovery.
Here is where the pendulum swings back. IBM introduced the AS/400 a long while ago, and more recently IBM PureSystems that combined servers, storage and switches into a single rack configuration. Other vendors had similar offerings, such as VCE Vblock, Flexpod from NetApp and Cisco, and Oracle Exadata.
Lately, the pendulum has swung fully back to internal storage, with storage-rich servers running specialized software on commodity servers. There are two kinds:
Pre-built systems like Nutanix, Simplivity or EVO:Rail which are x86 based server systems, pre-installed with software and internal flash and disk storage.
Software that can be deployed on your own choice of hardware, such as IBM Spectrum Accelerate, IBM Spectrum Scale FPO, or VMware VSAN.
So, over time, my single slide has evolved, and fleshed out into a full blown hour-long presentation!
Cloud storage comes in four flavors: persistent, ephemeral, hosted, and reference. The first two I refer to as "Storage for the Computer Cloud" and the latter two I refer to as "Storage as the Storage Cloud".
I also explained the differences between block, file and object access, and why different Cloud storage types use different access methods.
Finally, I covered some of our new public cloud storage offerings, using OpenStack Swift and Amazon S3 protocols to access objects off premises, including the new Cold Vault and Flex pricing on IBM Cloud Object Storage System in IBM Bluemix Cloud.
(FCC Disclosure: I work for IBM. I have no financial interest in SUSE, Scality, or any other storage vendor mentioned in this post. This blog post can be considered a "paid celebrity endorsement" for IBM Storwize, IBM Cloud Object Storage, and IBM Spectrum Storage software mentioned below.)
The study takes a realistic request for 250 TB of storage, at 25 percent compound annual growth rate (CAGR), to store infrequently accessed data in an online archive, and then looks at the Total Cost of Ownership (TCO) over five year period.
The study compares five different Software-Defined Solutions and three pre-built systems. The Software-defined solutions come as software-only, requiring that you purchase the hardware separately and build it yourself. The three pre-built systems were chosen from the top three storage vendors in the marketplace: Dell EMC, IBM and NetApp.
The cost of support is factored in, as it should be. To keep things equal, no data reduction like data deduplication or compression were used.
In an odd approach, the study mixes block, file and object based approaches all in the same study.
You can read the full 14-page study (linked above). I have organized the results into a single table, ranked from best to worst, color coded for the best deals in green ($100K to $200K), moderate solutions in yellow ($200K to $300K) and most expensive in red (over $300K). I put the software-only options on the left and pre-built systems on the right.
SUSE Enterprise Storage 4
IBM Storwize V5010
DataCore SAN Symphony
Red Hat Ceph Storage
Dell EMC Unity 300
I am often asked, "Isn't the software-only, build-it-yourself approach, always the lowest cost option?" Now, I can answer, "Sometimes yes, sometimes no." Fortunately, IBM offers Software-Defined Storage in a variety of packaging options including software-only, pre-built systems, and in the Cloud as a service.
IBM Storwize V5010 is based on IBM Spectrum Virtualize software, which you can deploy as software-only on your own x86 servers. This was not mentioned in the study, and perhaps it is my job to remind people that this option is also available for those who want to build their own storage.
For that matter, IBM Cloud Object Storage System -- available as software-only, pre-built systems, and in the Cloud -- might also be a cost-effective alternative.
Next week I will be in Orlando, Florida for the IBM Systems Technical University. If you are attending, stop by one of my presentations, or look for me at the Solution Center at one of the IBM peds, or attend the "Meet the Experts for IBM Storage" on Thursday!